408 lines
11 KiB
Prolog
408 lines
11 KiB
Prolog
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:- source.
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:- style_check(all).
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:- yap_flag(unknown,error).
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:- yap_flag(open_expands_filename,false).
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% redefines stuff in prolog module.
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:- module(swi, []).
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:- load_foreign_files([plstream], [], initIO).
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:- ensure_loaded(library(atts)).
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:- use_module(library(charsio),[write_to_chars/2,read_from_chars/2]).
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:- use_module(library(lists),[append/2,
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append/3,
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delete/3,
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member/2,
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min_list/2,
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nth1/3,
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nth0/3]).
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:- use_module(library(system),
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[datime/1,
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mktime/2,
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sleep/1]).
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:- use_module(library(arg),
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[genarg/3]).
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:- use_module(library(apply_macros),
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[]).
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:- use_module(library(terms),
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[subsumes/2,
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term_hash/2,
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unifiable/3,
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variant/2]).
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:- unhide('$system_library_directories'),
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unhide('$dir_separator').
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% make sure we also use
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:- user:library_directory(X),
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atom(X),
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atom_concat([X,'/swi'],SwiDir),
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\+ user:library_directory(SwiDir),
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asserta(user:library_directory(SwiDir)),
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fail
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;
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true.
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:- multifile user:term_expansion/2.
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:- multifile user:goal_expansion/3.
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:- multifile user:goal_expansion/2.
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:- dynamic user:goal_expansion/2.
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:- multifile swi_predicate_table/4.
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swi_predicate_table(_,append(X,Y),lists,append(X,Y)).
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swi_predicate_table(_,append(X,Y,Z),lists,append(X,Y,Z)).
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swi_predicate_table(_,member(X,Y),lists,member(X,Y)).
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swi_predicate_table(_,nextto(X,Y,Z),lists,nextto(X,Y,Z)).
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swi_predicate_table(_,delete(X,Y,Z),lists,delete(X,Y,Z)).
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swi_predicate_table(_,select(X,Y,Z),lists,select(X,Y,Z)).
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swi_predicate_table(_,selectchk(X,Y,Z),lists,selectchk(X,Y,Z)).
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swi_predicate_table(_,nth0(X,Y,Z),lists,nth0(X,Y,Z)).
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swi_predicate_table(_,nth1(X,Y,Z),lists,nth1(X,Y,Z)).
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swi_predicate_table(_,last(X,Y),lists,last(X,Y)).
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swi_predicate_table(_,reverse(X,Y),lists,reverse(X,Y)).
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swi_predicate_table(_,permutation(X,Y),lists,permutation(X,Y)).
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swi_predicate_table(_,flatten(X,Y),lists,flatten(X,Y)).
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swi_predicate_table(_,sumlist(X,Y),lists,sumlist(X,Y)).
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swi_predicate_table(_,min_list(X,Y),lists,min_list(X,Y)).
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swi_predicate_table(_,max_list(X,Y),lists,max_list(X,Y)).
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swi_predicate_table(_,memberchk(X,Y),lists,memberchk(X,Y)).
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swi_predicate_table(_,flatten(X,Y),lists,flatten(X,Y)).
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swi_predicate_table(_,select(X,Y,Z),lists,select(X,Y,Z)).
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swi_predicate_table(_,sublist(X,Y),lists,sublist(X,Y)).
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swi_predicate_table(_,hash_term(X,Y),terms,term_hash(X,Y)).
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swi_predicate_table(_,term_hash(X,Y),terms,term_hash(X,Y)).
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swi_predicate_table(_,subsumes(X,Y),terms,subsumes(X,Y)).
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swi_predicate_table(_,unifiable(X,Y,Z),terms,unifiable(X,Y,Z)).
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swi_predicate_table(_,genarg(X,Y,Z),arg,genarg(X,Y,Z)).
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swi_predicate_table(_,tmp_file(X,Y),system,tmp_file(X,Y)).
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swi_mchk(X,Y) :- lists:memberchk(X,Y).
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prolog:memberchk(X,Y) :- swi_mchk(X,Y).
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:- dynamic
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prolog:message/3.
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:- multifile
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prolog:message/3.
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:- multifile
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user:file_search_path/2.
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:- dynamic
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user:file_search_path/2.
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user:file_search_path(swi, Home) :-
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current_prolog_flag(home, Home).
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user:file_search_path(foreign, swi(ArchLib)) :-
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current_prolog_flag(arch, Arch),
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atom_concat('lib/', Arch, ArchLib).
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user:file_search_path(foreign, swi(lib)).
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:- meta_predicate prolog:predsort(:,+,-).
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prolog:plus(X, Y, Z) :-
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integer(X),
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integer(Y), !,
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Z is X + Y.
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prolog:plus(X, Y, Z) :-
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integer(X),
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integer(Z), !,
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Y is Z - X.
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prolog:plus(X, Y, Z) :-
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integer(Y),
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integer(Z), !,
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X is Z - Y.
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%% predsort(:Compare, +List, -Sorted) is det.
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%
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% Sorts similar to sort/2, but determines the order of two terms
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% by calling Compare(-Delta, +E1, +E2). This call must unify
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% Delta with one of <, > or =. If built-in predicate compare/3 is
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% used, the result is the same as sort/2. See also keysort/2.
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prolog:predsort(P, L, R) :-
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length(L, N),
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predsort(P, N, L, _, R1), !,
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R = R1.
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predsort(P, 2, [X1, X2|L], L, R) :- !,
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call(P, Delta, X1, X2),
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sort2(Delta, X1, X2, R).
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predsort(_, 1, [X|L], L, [X]) :- !.
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predsort(_, 0, L, L, []) :- !.
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predsort(P, N, L1, L3, R) :-
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N1 is N // 2,
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plus(N1, N2, N),
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predsort(P, N1, L1, L2, R1),
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predsort(P, N2, L2, L3, R2),
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predmerge(P, R1, R2, R).
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sort2(<, X1, X2, [X1, X2]).
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sort2(=, X1, _, [X1]).
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sort2(>, X1, X2, [X2, X1]).
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predmerge(_, [], R, R) :- !.
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predmerge(_, R, [], R) :- !.
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predmerge(P, [H1|T1], [H2|T2], Result) :-
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call(P, Delta, H1, H2),
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predmerge(Delta, P, H1, H2, T1, T2, Result).
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predmerge(>, P, H1, H2, T1, T2, [H2|R]) :-
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predmerge(P, [H1|T1], T2, R).
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predmerge(=, P, H1, _, T1, T2, [H1|R]) :-
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predmerge(P, T1, T2, R).
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predmerge(<, P, H1, H2, T1, T2, [H1|R]) :-
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predmerge(P, T1, [H2|T2], R).
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%
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% maybe a good idea to eventually support this in YAP.
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% but for now just ignore it.
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%
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:- meta_predicate prolog:volatile(:).
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:- op(1150, fx, 'volatile').
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prolog:volatile(P) :- var(P),
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throw(error(instantiation_error,volatile(P))).
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prolog:volatile(M:P) :-
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do_volatile(P,M).
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prolog:volatile((G1,G2)) :-
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prolog:volatile(G1),
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prolog:volatile(G2).
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prolog:volatile(P) :-
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prolog_load_context(module, M),
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do_volatile(P,M).
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prolog:load_foreign_library(P,Command) :-
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absolute_file_name(P,[file_type(executable),solutions(first),file_errors(fail)],Lib),
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load_foreign_files([Lib],[],Command).
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prolog:load_foreign_library(P) :-
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prolog:load_foreign_library(P,install).
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do_volatile(P,M) :- dynamic(M:P).
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:- use_module(library(lists)).
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prolog:term_to_atom(Term,Atom) :-
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nonvar(Atom), !,
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atom_codes(Atom,S),
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read_from_chars(S,Term).
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prolog:term_to_atom(Term,Atom) :-
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write_to_chars(Term,S),
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atom_codes(Atom,S).
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prolog:concat_atom([A|List], Separator, New) :- var(List), !,
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atom_codes(Separator,[C]),
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atom_codes(New, NewChars),
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split_atom_by_chars(NewChars,C,L,L,A,List).
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prolog:concat_atom(List, Separator, New) :-
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add_separator_to_list(List, Separator, NewList),
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atomic_concat(NewList, New).
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prolog:concat_atom(List, New) :-
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atomic_concat(List, New).
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split_atom_by_chars([],_,[],L,A,[]):-
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atom_codes(A,L).
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split_atom_by_chars([C|NewChars],C,[],L,A,[NA|Atoms]) :- !,
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atom_codes(A,L),
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split_atom_by_chars(NewChars,C,NL,NL,NA,Atoms).
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split_atom_by_chars([C1|NewChars],C,[C1|LF],LAtom,Atom,Atoms) :-
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split_atom_by_chars(NewChars,C,LF,LAtom,Atom,Atoms).
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add_separator_to_list([], _, []).
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add_separator_to_list([T], _, [T]) :- !.
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add_separator_to_list([H|T], Separator, [H,Separator|NT]) :-
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add_separator_to_list(T, Separator, NT).
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prolog:setenv(X,Y) :- unix(putenv(X,Y)).
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prolog:prolog_to_os_filename(X,X).
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prolog:is_absolute_file_name(X) :-
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absolute_file_name(X,X).
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prolog:read_clause(X,Y) :-
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read_term(X,Y,[singetons(warning)]).
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prolog:string(_) :- fail.
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slp(T) :- sleep(T).
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prolog:sleep(T) :-
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slp(T).
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% SWI has a dynamic attribute scheme
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prolog:get_attr(Var, Mod, Att) :-
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AttTerm =.. [Mod,_,Att],
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attributes:get_module_atts(Var, AttTerm).
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prolog:put_attr(Var, Mod, Att) :-
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AttTerm =.. [Mod,_,Att],
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attributes:put_module_atts(Var, AttTerm).
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prolog:del_attr(Var, Mod) :-
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AttTerm =.. [Mod,_,_],
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attributes:del_all_module_atts(Var, AttTerm).
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prolog:get_attrs(AttVar, SWIAtts) :-
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get_all_swi_atts(AttVar,SWIAtts).
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prolog:put_attrs(_, []).
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prolog:put_attrs(V, Atts) :-
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cvt_to_swi_atts(Atts, YapAtts),
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attributes:put_att_term(V, YapAtts).
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cvt_to_swi_atts([], _).
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cvt_to_swi_atts(att(Mod,Attribute,Atts), ModAttribute) :-
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ModAttribute =.. [Mod, YapAtts, Attribute],
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cvt_to_swi_atts(Atts, YapAtts).
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bindings_message(V) -->
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{ cvt_bindings(V, Bindings) },
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prolog:message(query(_YesNo,Bindings)), !.
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cvt_bindings([],[]).
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cvt_bindings([[Name|Value]|L],[AName=Value|Bindings]) :-
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atom_codes(AName, Name),
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cvt_bindings(L,Bindings).
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prolog:working_directory(OCWD,NCWD) :-
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getcwd(OCWD),
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(var(NCWD) -> true ; cd(NCWD)).
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prolog:chdir(X) :- cd(X).
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% Time is given as int, not as float.
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prolog:get_time(Secs) :- datime(Datime), mktime(Datime, Secs).
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% Time is received as int, and converted to "..."
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prolog:convert_time(X,Y) :- swi:ctime(X,Y).
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:- hide(atom_concat).
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prolog:atom_concat(A,B) :- atomic_concat(A,B).
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prolog:atom_concat(A,B,C) :- atomic_concat(A,B,C).
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:- hide(create_mutable).
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:- hide(get_mutable).
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:- hide(update_mutable).
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prolog:make.
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prolog:source_location(File,Line) :-
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prolog_load_context(file, File),
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prolog_load_context(term_position, '$stream_position'(_,Line,_)).
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% copied from SWI lists library.
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lists:intersection([], _, []) :- !.
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lists:intersection([X|T], L, Intersect) :-
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memberchk(X, L), !,
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Intersect = [X|R],
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lists:intersection(T, L, R).
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lists:intersection([_|T], L, R) :-
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lists:intersection(T, L, R).
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:- op(700, xfx, '=@=').
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prolog:(Term1 =@= Term2) :-
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variant(Term1, Term2), !.
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% copied from SWI's boot/apply library
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:- module_transparent
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prolog:maplist/2,
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maplist2/2,
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prolog:maplist/3,
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maplist2/3,
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prolog:maplist/4,
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maplist2/4,
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prolog:maplist/5,
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maplist2/5.
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% maplist(:Goal, +List)
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%
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% True if Goal can succesfully be applied on all elements of List.
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% Arguments are reordered to gain performance as well as to make
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% the predicate deterministic under normal circumstances.
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prolog:maplist(Goal, List) :-
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apply_macros:maplist(List, Goal).
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% maplist(:Goal, ?List1, ?List2)
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%
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% True if Goal can succesfully be applied to all succesive pairs
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% of elements of List1 and List2.
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prolog:maplist(Goal, List1, List2) :-
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apply_macros:maplist(List1, Goal, List2).
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% maplist(:Goal, ?List1, ?List2, ?List3)
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%
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% True if Goal can succesfully be applied to all succesive triples
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% of elements of List1..List3.
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prolog:maplist(Goal, List1, List2, List3) :-
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apply_macros:maplist(List1, Goal, List2, List3).
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% maplist(:Goal, ?List1, ?List2, ?List3, List4)
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%
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% True if Goal can succesfully be applied to all succesive
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% quadruples of elements of List1..List4
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prolog:maplist(Goal, List1, List2, List3, List4) :-
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apply_macros:maplist(List1, Goal, List2, List3, List4).
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prolog:compile_aux_clauses([]).
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prolog:compile_aux_clauses([(:- G)|Cls]) :-
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prolog_load_context(module, M),
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once(M:G),
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prolog:compile_aux_clauses(Cls).
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prolog:compile_aux_clauses([Cl|Cls]) :-
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prolog_load_context(module, M),
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assert_static(M:Cl),
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prolog:compile_aux_clauses(Cls).
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% fix different semantics for arg/3.
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user:goal_expansion(arg(X,Y,Z),_,arg:genarg(X,Y,Z)) :-
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nonvar(X), !.
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%
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% convert from SWI's goal expansion to YAP/SICStus old style goal
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% expansion.
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%
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user:term_expansion(goal_expansion(A,B),O) :-
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prolog_load_context(module, user), !,
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O = goal_expansion(A,user,B).
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user:term_expansion(user:goal_expansion(A,B),O) :- !,
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O = user:goal_expansion(A,_,B).
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user:term_expansion((goal_expansion(A,B) :- G), O) :-
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prolog_load_context(module, user), !,
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O = (goal_expansion(A,user,B) :- G).
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user:term_expansion((user:goal_expansion(A,B) :- G),O) :-
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O = (user:goal_expansion(A,_,B) :- G).
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