/* $Id: chr_translate_bootstrap.pl,v 1.5 2008-02-23 01:32:30 vsc Exp $ Part of CHR (Constraint Handling Rules) Author: Tom Schrijvers E-mail: Tom.Schrijvers@cs.kuleuven.be WWW: http://www.swi-prolog.org Copyright (C): 2003-2004, K.U. Leuven 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 Lesser General Public License along with this library; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 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. */ %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% %% ____ _ _ ____ ____ _ _ %% / ___| | | | _ \ / ___|___ _ __ ___ _ __ (_) | ___ _ __ %% | | | |_| | |_) | | | / _ \| '_ ` _ \| '_ \| | |/ _ \ '__| %% | |___| _ | _ < | |__| (_) | | | | | | |_) | | | __/ | %% \____|_| |_|_| \_\ \____\___/|_| |_| |_| .__/|_|_|\___|_| %% |_| %% %% hProlog CHR compiler: %% %% * by Tom Schrijvers, K.U. Leuven, Tom.Schrijvers@cs.kuleuven.be %% %% * based on the SICStus CHR compilation by Christian Holzbaur %% %% First working version: 6 June 2003 %% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% To Do %% %% * SICStus compatibility %% - rules/1 declaration %% - options %% - pragmas %% - tell guard %% %% %% * do not suspend on variables that don't matter %% * make difference between cheap guards for reordering %% and non-binding guards for lock removal %% %% * unqiue -> once/[] transformation for propagation %% %% * cheap guards interleaved with head retrieval + faster %% via-retrieval + non-empty checking for propagation rules %% redo for simpagation_head2 prelude %% %% * intelligent backtracking for simplification/simpagation rule %% generator_1(X),'_$savecp'(CP_1), %% ... %% if( ( %% generator_n(Y), %% test(X,Y) %% ), %% true, %% ('_$cutto'(CP_1), fail) %% ), %% ... %% %% or recently developped cascading-supported approach %% %% * intelligent backtracking for propagation rule %% use additional boolean argument for each possible smart backtracking %% when boolean at end of list true -> no smart backtracking %% false -> smart backtracking %% only works for rules with at least 3 constraints in the head %% %% * mutually exclusive rules %% %% * constraints that can never be attached / always simplified away %% -> need not be considered in diverse operations %% %% * (set semantics + functional dependency) declaration + resolution %% %% * type and instantiation declarations + optimisations %% + better indexes %% %% * disable global store option %% %% Done %% %% * clean up generated code %% * input verification: pragmas %% * SICStus compatibility: handler/1, constraints/1 %% * optimise variable passing for propagation rule %% * reordering of head constraints for passive head search %% * unique inference for simpagation rules %% * unique optimisation for simpagation and simplification rules %% * cheap guards interleaved with head retrieval + faster %% via-retrieval + non-empty checking for simplification / simpagation rules %% * transform %% C \ C <=> true %% into %% C # ID \ C <=> true pragma passive. %% * valid to disregard body in uniqueness inference? %% * unique inference for simplification rules %% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% :- module(chr_translate, [ chr_translate/2 % +Decls, -TranslatedDecls ]). %% SWI begin :- use_module(library(lists),[member/2,append/3,permutation/2,reverse/2]). :- use_module(library(ordsets)). %% SWI end :- use_module(hprolog). :- use_module(pairlist). :- include(chr_op). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% %% Translation chr_translate(Declarations,NewDeclarations) :- init_chr_pp_flags, partition_clauses(Declarations,Decls,Rules,OtherClauses,Mod), default(Mod,user), ( Decls == [] -> NewDeclarations = OtherClauses ; check_rules(Rules,Decls), unique_analyse_optimise(Rules,1,[],NRules), generate_attach_a_constraint_all(Decls,Mod,AttachAConstraintClauses), generate_detach_a_constraint_all(Decls,Mod,DettachAConstraintClauses), generate_attach_increment(Decls,Mod,AttachIncrementClauses), generate_attr_unify_hook(Decls,Mod,AttrUnifyHookClauses), constraints_code(Decls,NRules,Mod,ConstraintClauses), append([ OtherClauses, AttachAConstraintClauses, DettachAConstraintClauses, AttachIncrementClauses, AttrUnifyHookClauses, ConstraintClauses ], NewDeclarations) ). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% %% Partitioning of clauses into constraint declarations, chr rules and other %% clauses partition_clauses([],[],[],[],_). partition_clauses([C|Cs],Ds,Rs,OCs,Mod) :- ( rule(C,R) -> Ds = RDs, Rs = [R | RRs], OCs = ROCs ; is_declaration(C,D) -> append(D,RDs,Ds), Rs = RRs, OCs = ROCs ; is_module_declaration(C,Mod) -> Ds = RDs, Rs = RRs, OCs = [C|ROCs] ; C = (handler _) -> format('CHR compiler WARNING: ~w.\n',[C]), format(' `--> SICStus compatibility: ignoring handler/1 declaration.\n',[]), Ds = RDs, Rs = RRs, OCs = ROCs ; C = (rules _) -> format('CHR compiler WARNING: ~w.\n',[C]), format(' `--> SICStus compatibility: ignoring rules/1 declaration.\n',[]), Ds = RDs, Rs = RRs, OCs = ROCs ; C = (:- chr_option(OptionName,OptionValue)) -> handle_option(OptionName,OptionValue), Ds = RDs, Rs = RRs, OCs = ROCs ; Ds = RDs, Rs = RRs, OCs = [C|ROCs] ), partition_clauses(Cs,RDs,RRs,ROCs,Mod). is_declaration(D, Constraints) :- %% constraint declaration D = (:- Decl), ( Decl =.. [chr_constraint,Cs] ; Decl =.. [chr_constraint,Cs]), conj2list(Cs,Constraints). %% Data Declaration %% %% pragma_rule %% -> pragma( %% rule, %% ids, %% list(pragma), %% yesno(string) %% ) %% %% ids -> ids( %% list(int), %% list(int) %% ) %% %% rule -> rule( %% list(constraint), :: constraints to be removed %% list(constraint), :: surviving constraints %% goal, :: guard %% goal :: body %% ) rule(RI,R) :- %% name @ rule RI = (Name @ RI2), !, rule(RI2,yes(Name),R). rule(RI,R) :- rule(RI,no,R). rule(RI,Name,R) :- RI = (RI2 pragma P), !, %% pragmas is_rule(RI2,R1,IDs), conj2list(P,Ps), R = pragma(R1,IDs,Ps,Name). rule(RI,Name,R) :- is_rule(RI,R1,IDs), R = pragma(R1,IDs,[],Name). is_rule(RI,R,IDs) :- %% propagation rule RI = (H ==> B), !, conj2list(H,Head2i), get_ids(Head2i,IDs2,Head2), IDs = ids([],IDs2), ( B = (G | RB) -> R = rule([],Head2,G,RB) ; R = rule([],Head2,true,B) ). is_rule(RI,R,IDs) :- %% simplification/simpagation rule RI = (H <=> B), !, ( B = (G | RB) -> Guard = G, Body = RB ; Guard = true, Body = B ), ( H = (H1 \ H2) -> conj2list(H1,Head2i), conj2list(H2,Head1i), get_ids(Head2i,IDs2,Head2,0,N), get_ids(Head1i,IDs1,Head1,N,_), IDs = ids(IDs1,IDs2) ; conj2list(H,Head1i), Head2 = [], get_ids(Head1i,IDs1,Head1), IDs = ids(IDs1,[]) ), R = rule(Head1,Head2,Guard,Body). get_ids(Cs,IDs,NCs) :- get_ids(Cs,IDs,NCs,0,_). get_ids([],[],[],N,N). get_ids([C|Cs],[N|IDs],[NC|NCs],N,NN) :- ( C = (NC # N) -> true ; NC = C ), M is N + 1, get_ids(Cs,IDs,NCs, M,NN). is_module_declaration((:- module(Mod)),Mod). is_module_declaration((:- module(Mod,_)),Mod). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% Some input verification: %% - all constraints in heads are declared constraints check_rules(Rules,Decls) :- check_rules(Rules,Decls,1). check_rules([],_,_). check_rules([PragmaRule|Rest],Decls,N) :- check_rule(PragmaRule,Decls,N), N1 is N + 1, check_rules(Rest,Decls,N1). check_rule(PragmaRule,Decls,N) :- PragmaRule = pragma(Rule,_IDs,Pragmas,_Name), Rule = rule(H1,H2,_,_), append(H1,H2,HeadConstraints), check_head_constraints(HeadConstraints,Decls,PragmaRule,N), check_pragmas(Pragmas,PragmaRule,N). check_head_constraints([],_,_,_). check_head_constraints([Constr|Rest],Decls,PragmaRule,N) :- functor(Constr,F,A), ( member(F/A,Decls) -> check_head_constraints(Rest,Decls,PragmaRule,N) ; format('CHR compiler ERROR: Undeclared constraint ~w in head of ~@.\n', [F/A,format_rule(PragmaRule,N)]), format(' `--> Constraint should be on of ~w.\n',[Decls]), fail ). check_pragmas([],_,_). check_pragmas([Pragma|Pragmas],PragmaRule,N) :- check_pragma(Pragma,PragmaRule,N), check_pragmas(Pragmas,PragmaRule,N). check_pragma(Pragma,PragmaRule,N) :- var(Pragma), !, format('CHR compiler ERROR: invalid pragma ~w in ~@.\n', [Pragma,format_rule(PragmaRule,N)]), format(' `--> Pragma should not be a variable!\n',[]), fail. check_pragma(passive(ID), PragmaRule, N) :- !, PragmaRule = pragma(_,ids(IDs1,IDs2),_,_), ( memberchk_eq(ID,IDs1) -> true ; memberchk_eq(ID,IDs2) -> true ; format('CHR compiler ERROR: invalid identifier ~w in pragma passive in ~@.\n', [ID,format_rule(PragmaRule,N)]), fail ). check_pragma(Pragma, PragmaRule, N) :- Pragma = unique(_,_), !, format('CHR compiler WARNING: undocumented pragma ~w in ~@.\n',[Pragma,format_rule(PragmaRule,N)]), format(' `--> Only use this pragma if you know what you are doing.\n',[]). check_pragma(Pragma, PragmaRule, N) :- Pragma = already_in_heads, !, format('CHR compiler WARNING: currently unsupported pragma ~w in ~@.\n',[Pragma,format_rule(PragmaRule,N)]), format(' `--> Pragma is ignored. Termination and correctness may be affected \n',[]). check_pragma(Pragma, PragmaRule, N) :- Pragma = already_in_head(_), !, format('CHR compiler WARNING: currently unsupported pragma ~w in ~@.\n',[Pragma,format_rule(PragmaRule,N)]), format(' `--> Pragma is ignored. Termination and correctness may be affected \n',[]). check_pragma(Pragma,PragmaRule,N) :- format('CHR compiler ERROR: invalid pragma ~w in ~@.\n',[Pragma,format_rule(PragmaRule,N)]), format(' `--> Pragma should be one of passive/1!\n',[]), fail. format_rule(PragmaRule,N) :- PragmaRule = pragma(_,_,_,MaybeName), ( MaybeName = yes(Name) -> write('rule '), write(Name) ; write('rule number '), write(N) ). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Global Options % handle_option(Var,Value) :- var(Var), !, format('CHR compiler ERROR: ~w.\n',[option(Var,Value)]), format(' `--> First argument should be an atom, not a variable.\n',[]), fail. handle_option(Name,Value) :- var(Value), !, format('CHR compiler ERROR: ~w.\n',[option(Name,Value)]), format(' `--> Second argument should be a nonvariable.\n',[]), fail. handle_option(Name,Value) :- option_definition(Name,Value,Flags), !, set_chr_pp_flags(Flags). handle_option(Name,Value) :- \+ option_definition(Name,_,_), !, setof(N,_V ^ _F ^ (option_definition(N,_V,_F)),Ns), format('CHR compiler ERROR: ~w.\n',[option(Name,Value)]), format(' `--> Invalid option name ~w: should be one of ~w.\n',[Name,Ns]), fail. handle_option(Name,Value) :- findall(V,option_definition(Name,V,_),Vs), format('CHR compiler ERROR: ~w.\n',[option(Name,Value)]), format(' `--> Invalid value ~w: should be one of ~w.\n',[Value,Vs]), fail. option_definition(optimize,full,Flags) :- Flags = [ unique_analyse_optimise - on, check_unnecessary_active - full, reorder_heads - on, set_semantics_rule - on, guard_via_reschedule - on ]. option_definition(optimize,sicstus,Flags) :- Flags = [ unique_analyse_optimise - off, check_unnecessary_active - simplification, reorder_heads - off, set_semantics_rule - off, guard_via_reschedule - off ]. option_definition(optimize,off,Flags) :- Flags = [ unique_analyse_optimise - off, check_unnecessary_active - off, reorder_heads - off, set_semantics_rule - off, guard_via_reschedule - off ]. option_definition(check_guard_bindings,on,Flags) :- Flags = [ guard_locks - on ]. option_definition(check_guard_bindings,off,Flags) :- Flags = [ guard_locks - off ]. init_chr_pp_flags :- chr_pp_flag_definition(Name,[DefaultValue|_]), set_chr_pp_flag(Name,DefaultValue), fail. init_chr_pp_flags. set_chr_pp_flags([]). set_chr_pp_flags([Name-Value|Flags]) :- set_chr_pp_flag(Name,Value), set_chr_pp_flags(Flags). set_chr_pp_flag(Name,Value) :- atom_concat('$chr_pp_',Name,GlobalVar), nb_setval(GlobalVar,Value). chr_pp_flag_definition(unique_analyse_optimise,[on,off]). chr_pp_flag_definition(check_unnecessary_active,[full,simplification,off]). chr_pp_flag_definition(reorder_heads,[on,off]). chr_pp_flag_definition(set_semantics_rule,[on,off]). chr_pp_flag_definition(guard_via_reschedule,[on,off]). chr_pp_flag_definition(guard_locks,[on,off]). chr_pp_flag(Name,Value) :- atom_concat('$chr_pp_',Name,GlobalVar), nb_getval(GlobalVar,V), ( V == [] -> chr_pp_flag_definition(Name,[Value|_]) ; V = Value ). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% %% Generated predicates %% attach_$CONSTRAINT %% attach_increment %% detach_$CONSTRAINT %% attr_unify_hook %% attach_$CONSTRAINT generate_attach_a_constraint_all(Constraints,Mod,Clauses) :- length(Constraints,Total), generate_attach_a_constraint_all(Constraints,1,Total,Mod,Clauses). generate_attach_a_constraint_all([],_,_,_,[]). generate_attach_a_constraint_all([Constraint|Constraints],Position,Total,Mod,Clauses) :- generate_attach_a_constraint(Total,Position,Constraint,Mod,Clauses1), NextPosition is Position + 1, generate_attach_a_constraint_all(Constraints,NextPosition,Total,Mod,Clauses2), append(Clauses1,Clauses2,Clauses). generate_attach_a_constraint(Total,Position,Constraint,Mod,[Clause1,Clause2]) :- generate_attach_a_constraint_empty_list(Constraint,Clause1), ( Total == 1 -> generate_attach_a_constraint_1_1(Constraint,Mod,Clause2) ; generate_attach_a_constraint_t_p(Total,Position,Constraint,Mod,Clause2) ). generate_attach_a_constraint_empty_list(CFct / CAty,Clause) :- atom_concat_list(['attach_',CFct, (/) ,CAty],Fct), Args = [[],_], Head =.. [Fct | Args], Clause = ( Head :- true). generate_attach_a_constraint_1_1(CFct / CAty,Mod,Clause) :- atom_concat_list(['attach_',CFct, (/) ,CAty],Fct), Args = [[Var|Vars],Susp], Head =.. [Fct | Args], RecursiveCall =.. [Fct,Vars,Susp], Body = ( ( get_attr(Var, Mod, Susps) -> NewSusps=[Susp|Susps], put_attr(Var, Mod, NewSusps) ; put_attr(Var, Mod, [Susp]) ), RecursiveCall ), Clause = (Head :- Body). generate_attach_a_constraint_t_p(Total,Position,CFct / CAty ,Mod,Clause) :- atom_concat_list(['attach_',CFct, (/) ,CAty],Fct), Args = [[Var|Vars],Susp], Head =.. [Fct | Args], RecursiveCall =.. [Fct,Vars,Susp], or_pattern(Position,Pattern), make_attr(Total,Mask,SuspsList,Attr), nth(Position,SuspsList,Susps), substitute_eq(Susps,SuspsList,[Susp|Susps],SuspsList1), make_attr(Total,Mask,SuspsList1,NewAttr1), substitute_eq(Susps,SuspsList,[Susp],SuspsList2), make_attr(Total,NewMask,SuspsList2,NewAttr2), copy_term_nat(SuspsList,SuspsList3), nth(Position,SuspsList3,[Susp]), chr_delete(SuspsList3,[Susp],RestSuspsList), set_elems(RestSuspsList,[]), make_attr(Total,Pattern,SuspsList3,NewAttr3), Body = ( ( get_attr(Var,Mod,TAttr) -> TAttr = Attr, ( Mask /\ Pattern =:= Pattern -> put_attr(Var, Mod, NewAttr1) ; NewMask is Mask \/ Pattern, put_attr(Var, Mod, NewAttr2) ) ; put_attr(Var,Mod,NewAttr3) ), RecursiveCall ), Clause = (Head :- Body). %% detach_$CONSTRAINT generate_detach_a_constraint_all(Constraints,Mod,Clauses) :- length(Constraints,Total), generate_detach_a_constraint_all(Constraints,1,Total,Mod,Clauses). generate_detach_a_constraint_all([],_,_,_,[]). generate_detach_a_constraint_all([Constraint|Constraints],Position,Total,Mod,Clauses) :- generate_detach_a_constraint(Total,Position,Constraint,Mod,Clauses1), NextPosition is Position + 1, generate_detach_a_constraint_all(Constraints,NextPosition,Total,Mod,Clauses2), append(Clauses1,Clauses2,Clauses). generate_detach_a_constraint(Total,Position,Constraint,Mod,[Clause1,Clause2]) :- generate_detach_a_constraint_empty_list(Constraint,Clause1), ( Total == 1 -> generate_detach_a_constraint_1_1(Constraint,Mod,Clause2) ; generate_detach_a_constraint_t_p(Total,Position,Constraint,Mod,Clause2) ). generate_detach_a_constraint_empty_list(CFct / CAty,Clause) :- atom_concat_list(['detach_',CFct, (/) ,CAty],Fct), Args = [[],_], Head =.. [Fct | Args], Clause = ( Head :- true). generate_detach_a_constraint_1_1(CFct / CAty,Mod,Clause) :- atom_concat_list(['detach_',CFct, (/) ,CAty],Fct), Args = [[Var|Vars],Susp], Head =.. [Fct | Args], RecursiveCall =.. [Fct,Vars,Susp], Body = ( ( get_attr(Var,Mod,Susps) -> 'chr sbag_del_element'(Susps,Susp,NewSusps), ( NewSusps == [] -> del_attr(Var,Mod) ; put_attr(Var,Mod,NewSusps) ) ; true ), RecursiveCall ), Clause = (Head :- Body). generate_detach_a_constraint_t_p(Total,Position,CFct / CAty ,Mod,Clause) :- atom_concat_list(['detach_',CFct, (/) ,CAty],Fct), Args = [[Var|Vars],Susp], Head =.. [Fct | Args], RecursiveCall =.. [Fct,Vars,Susp], or_pattern(Position,Pattern), and_pattern(Position,DelPattern), make_attr(Total,Mask,SuspsList,Attr), nth(Position,SuspsList,Susps), substitute_eq(Susps,SuspsList,[],SuspsList1), make_attr(Total,NewMask,SuspsList1,Attr1), substitute_eq(Susps,SuspsList,NewSusps,SuspsList2), make_attr(Total,Mask,SuspsList2,Attr2), Body = ( ( get_attr(Var,Mod,TAttr) -> TAttr = Attr, ( Mask /\ Pattern =:= Pattern -> 'chr sbag_del_element'(Susps,Susp,NewSusps), ( NewSusps == [] -> NewMask is Mask /\ DelPattern, ( NewMask == 0 -> del_attr(Var,Mod) ; put_attr(Var,Mod,Attr1) ) ; put_attr(Var,Mod,Attr2) ) ; true ) ; true ), RecursiveCall ), Clause = (Head :- Body). %% detach_$CONSTRAINT generate_attach_increment(Constraints,Mod,[Clause1,Clause2]) :- generate_attach_increment_empty(Clause1), length(Constraints,N), ( N == 1 -> generate_attach_increment_one(Mod,Clause2) ; generate_attach_increment_many(N,Mod,Clause2) ). generate_attach_increment_empty((attach_increment([],_) :- true)). generate_attach_increment_one(Mod,Clause) :- Head = attach_increment([Var|Vars],Susps), Body = ( 'chr not_locked'(Var), ( get_attr(Var,Mod,VarSusps) -> sort(VarSusps,SortedVarSusps), merge(Susps,SortedVarSusps,MergedSusps), put_attr(Var,Mod,MergedSusps) ; put_attr(Var,Mod,Susps) ), attach_increment(Vars,Susps) ), Clause = (Head :- Body). generate_attach_increment_many(N,Mod,Clause) :- make_attr(N,Mask,SuspsList,Attr), make_attr(N,OtherMask,OtherSuspsList,OtherAttr), Head = attach_increment([Var|Vars],Attr), bagof(G,X ^ Y ^ SY ^ M ^ (member2(SuspsList,OtherSuspsList,X-Y),G = (sort(Y,SY),'chr merge_attributes'(X,SY,M))),Gs), list2conj(Gs,SortGoals), bagof(MS,A ^ B ^ C ^ member((A,'chr merge_attributes'(B,C,MS)),Gs), MergedSuspsList), make_attr(N,MergedMask,MergedSuspsList,NewAttr), Body = ( 'chr not_locked'(Var), ( get_attr(Var,Mod,TOtherAttr) -> TOtherAttr = OtherAttr, SortGoals, MergedMask is Mask \/ OtherMask, put_attr(Var,Mod,NewAttr) ; put_attr(Var,Mod,Attr) ), attach_increment(Vars,Attr) ), Clause = (Head :- Body). %% attr_unify_hook generate_attr_unify_hook(Constraints,Mod,[Clause]) :- length(Constraints,N), ( N == 1 -> generate_attr_unify_hook_one(Mod,Clause) ; generate_attr_unify_hook_many(N,Mod,Clause) ). generate_attr_unify_hook_one(Mod,Clause) :- Head = attr_unify_hook(Susps,Other), Body = ( sort(Susps, SortedSusps), ( var(Other) -> ( get_attr(Other,Mod,OtherSusps) -> true ; OtherSusps = [] ), sort(OtherSusps,SortedOtherSusps), 'chr merge_attributes'(SortedSusps,SortedOtherSusps,NewSusps), put_attr(Other,Mod,NewSusps), 'chr run_suspensions'(NewSusps) ; ( compound(Other) -> term_variables(Other,OtherVars), attach_increment(OtherVars, SortedSusps) ; true ), 'chr run_suspensions'(Susps) ) ), Clause = (Head :- Body). generate_attr_unify_hook_many(N,Mod,Clause) :- make_attr(N,Mask,SuspsList,Attr), make_attr(N,OtherMask,OtherSuspsList,OtherAttr), bagof(Sort,A ^ B ^ ( member(A,SuspsList) , Sort = sort(A,B) ) , SortGoalList), list2conj(SortGoalList,SortGoals), bagof(B, A ^ member(sort(A,B),SortGoalList), SortedSuspsList), bagof(C, D ^ E ^ F ^ G ^ (member2(SortedSuspsList,OtherSuspsList,D-E), C = (sort(E,F), 'chr merge_attributes'(D,F,G)) ), SortMergeGoalList), bagof(G, D ^ F ^ H ^ member((H,'chr merge_attributes'(D,F,G)),SortMergeGoalList) , MergedSuspsList), list2conj(SortMergeGoalList,SortMergeGoals), make_attr(N,MergedMask,MergedSuspsList,MergedAttr), make_attr(N,Mask,SortedSuspsList,SortedAttr), Head = attr_unify_hook(Attr,Other), Body = ( SortGoals, ( var(Other) -> ( get_attr(Other,Mod,TOtherAttr) -> TOtherAttr = OtherAttr, SortMergeGoals, MergedMask is Mask \/ OtherMask, put_attr(Other,Mod,MergedAttr), 'chr run_suspensions_loop'(MergedSuspsList) ; put_attr(Other,Mod,SortedAttr), 'chr run_suspensions_loop'(SortedSuspsList) ) ; ( compound(Other) -> term_variables(Other,OtherVars), attach_increment(OtherVars,SortedAttr) ; true ), 'chr run_suspensions_loop'(SortedSuspsList) ) ), Clause = (Head :- Body). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% ____ _ ____ _ _ _ _ %% | _ \ _ _| | ___ / ___|___ _ __ ___ _ __ (_) | __ _| |_(_) ___ _ __ %% | |_) | | | | |/ _ \ | | / _ \| '_ ` _ \| '_ \| | |/ _` | __| |/ _ \| '_ \ %% | _ <| |_| | | __/ | |__| (_) | | | | | | |_) | | | (_| | |_| | (_) | | | | %% |_| \_\\__,_|_|\___| \____\___/|_| |_| |_| .__/|_|_|\__,_|\__|_|\___/|_| |_| %% |_| constraints_code(Constraints,Rules,Mod,Clauses) :- constraints_code(Constraints,Rules,Mod,L,[]), clean_clauses(L,Clauses). %% Generate code for all the CHR constraints constraints_code(Constraints,Rules,Mod,L,T) :- length(Constraints,N), constraints_code(Constraints,1,N,Constraints,Rules,Mod,L,T). constraints_code([],_,_,_,_,_,L,L). constraints_code([Constr|Constrs],I,N,Constraints,Rules,Mod,L,T) :- constraint_code(Constr,I,N,Constraints,Rules,Mod,L,T1), J is I + 1, constraints_code(Constrs,J,N,Constraints,Rules,Mod,T1,T). %% Generate code for a single CHR constraint constraint_code(Constraint, I, N, Constraints, Rules, Mod, L, T) :- constraint_prelude(Constraint,Mod,Clause), L = [Clause | L1], Id1 = [0], rules_code(Rules,1,Constraint,I,N,Constraints,Mod,Id1,Id2,L1,L2), gen_cond_attach_clause(Mod,Constraint,I,N,Constraints,Id2,L2,T). %% Generate prelude predicate for a constraint. %% f(...) :- f/a_0(...,Susp). constraint_prelude(F/A, _Mod, Clause) :- vars_susp(A,Vars,_Susp,VarsSusp), Head =.. [ F | Vars], build_head(F,A,[0],VarsSusp,Delegate), Clause = ( Head :- Delegate ). gen_cond_attach_clause(Mod,F/A,_I,_N,_Constraints,Id,L,T) :- ( Id == [0] -> gen_cond_attach_goal(Mod,F/A,Body,AllArgs) ; vars_susp(A,_Args,Susp,AllArgs), gen_uncond_attach_goal(F/A,Susp,Mod,Body,_) ), build_head(F,A,Id,AllArgs,Head), Clause = ( Head :- Body ), L = [Clause | T]. gen_cond_attach_goal(Mod,F/A,Goal,AllArgs) :- vars_susp(A,Args,Susp,AllArgs), build_head(F,A,[0],AllArgs,Closure), atom_concat_list(['attach_',F, (/) ,A],AttachF), Attach =.. [AttachF,Vars,Susp], Goal = ( ( var(Susp) -> 'chr insert_constraint_internal'(Vars,Susp,Mod:Closure,F,Args) ; 'chr activate_constraint'(Vars,Susp,_) ), Attach ). gen_uncond_attach_goal(F/A,Susp,_Mod,AttachGoal,Generation) :- atom_concat_list(['attach_',F, (/) ,A],AttachF), Attach =.. [AttachF,Vars,Susp], AttachGoal = ( 'chr activate_constraint'(Vars, Susp, Generation), Attach ). %% Generate all the code for a constraint based on all CHR rules rules_code([],_,_,_,_,_,_,Id,Id,L,L). rules_code([R |Rs],RuleNb,FA,I,N,Constraints,Mod,Id1,Id3,L,T) :- rule_code(R,RuleNb,FA,I,N,Constraints,Mod,Id1,Id2,L,T1), NextRuleNb is RuleNb + 1, rules_code(Rs,NextRuleNb,FA,I,N,Constraints,Mod,Id2,Id3,T1,T). %% Generate code for a constraint based on a single CHR rule rule_code(PragmaRule,RuleNb,FA,I,N,Constraints,Mod,Id1,Id2,L,T) :- PragmaRule = pragma(Rule,HeadIDs,_Pragmas,_Name), HeadIDs = ids(Head1IDs,Head2IDs), Rule = rule(Head1,Head2,_,_), heads1_code(Head1,[],Head1IDs,[],PragmaRule,FA,I,N,Constraints,Mod,Id1,L,L1), heads2_code(Head2,[],Head2IDs,[],PragmaRule,RuleNb,FA,I,N,Constraints,Mod,Id1,Id2,L1,T). %% Generate code based on all the removed heads of a CHR rule heads1_code([],_,_,_,_,_,_,_,_,_,_,L,L). heads1_code([Head|Heads],RestHeads,[HeadID|HeadIDs],RestIDs,PragmaRule,F/A,I,N,Constraints,Mod,Id,L,T) :- PragmaRule = pragma(Rule,_,Pragmas,_Name), ( functor(Head,F,A), \+ check_unnecessary_active(Head,RestHeads,Rule), \+ memberchk_eq(passive(HeadID),Pragmas) -> append(Heads,RestHeads,OtherHeads), append(HeadIDs,RestIDs,OtherIDs), head1_code(Head,OtherHeads,OtherIDs,PragmaRule,F/A,I,N,Constraints,Mod,Id,L,L1) ; L = L1 ), heads1_code(Heads,[Head|RestHeads],HeadIDs,[HeadID|RestIDs],PragmaRule,F/A,I,N,Constraints,Mod,Id,L1,T). %% Generate code based on one removed head of a CHR rule head1_code(Head,OtherHeads,OtherIDs,PragmaRule,FA,I,N,Constraints,Mod,Id,L,T) :- PragmaRule = pragma(Rule,_,_,_Name), Rule = rule(_,Head2,_,_), ( Head2 == [] -> reorder_heads(Head,OtherHeads,OtherIDs,NOtherHeads,NOtherIDs), simplification_code(Head,NOtherHeads,NOtherIDs,PragmaRule,FA,I,N,Constraints,Mod,Id,L,T) ; simpagation_head1_code(Head,OtherHeads,OtherIDs,PragmaRule,FA,I,N,Constraints,Mod,Id,L,T) ). %% Generate code based on all the persistent heads of a CHR rule heads2_code([],_,_,_,_,_,_,_,_,_,_,Id,Id,L,L). heads2_code([Head|Heads],RestHeads,[HeadID|HeadIDs],RestIDs,PragmaRule,RuleNb,F/A,I,N,Constraints,Mod,Id1,Id3,L,T) :- PragmaRule = pragma(Rule,_,Pragmas,_Name), ( functor(Head,F,A), \+ check_unnecessary_active(Head,RestHeads,Rule), \+ memberchk_eq(passive(HeadID),Pragmas), \+ set_semantics_rule(PragmaRule) -> append(Heads,RestHeads,OtherHeads), append(HeadIDs,RestIDs,OtherIDs), length(Heads,RestHeadNb), head2_code(Head,OtherHeads,OtherIDs,PragmaRule,RuleNb,RestHeadNb,F/A,I,N,Constraints,Mod,Id1,L,L0), inc_id(Id1,Id2), gen_alloc_inc_clause(F/A,Mod,Id1,L0,L1) ; L = L1, Id2 = Id1 ), heads2_code(Heads,[Head|RestHeads],HeadIDs,[HeadID|RestIDs],PragmaRule,RuleNb,F/A,I,N,Constraints,Mod,Id2,Id3,L1,T). %% Generate code based on one persistent head of a CHR rule head2_code(Head,OtherHeads,OtherIDs,PragmaRule,RuleNb,RestHeadNb,FA,I,N,Constraints,Mod,Id,L,T) :- PragmaRule = pragma(Rule,_,_,_Name), Rule = rule(Head1,_,_,_), ( Head1 == [] -> reorder_heads(Head,OtherHeads,NOtherHeads), propagation_code(Head,NOtherHeads,Rule,RuleNb,RestHeadNb,FA,N,Constraints,Mod,Id,L,T) ; simpagation_head2_code(Head,OtherHeads,OtherIDs,PragmaRule,FA,I,N,Constraints,Mod,Id,L,T) ). gen_alloc_inc_clause(F/A,Mod,Id,L,T) :- vars_susp(A,Vars,Susp,VarsSusp), build_head(F,A,Id,VarsSusp,Head), inc_id(Id,IncId), build_head(F,A,IncId,VarsSusp,CallHead), ( Id == [0] -> gen_cond_allocation(Vars,Susp,F/A,VarsSusp,Mod,ConditionalAlloc) ; ConditionalAlloc = true ), Clause = ( Head :- ConditionalAlloc, CallHead ), L = [Clause|T]. gen_cond_allocation(Vars,Susp,F/A,VarsSusp,Mod,ConstraintAllocationGoal) :- build_head(F,A,[0],VarsSusp,Term), ConstraintAllocationGoal = ( var(Susp) -> 'chr allocate_constraint'(Mod : Term, Susp, F, Vars) ; true ). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% guard_via_reschedule(Retrievals,GuardList,Prelude,Goal) :- ( chr_pp_flag(guard_via_reschedule,on) -> guard_via_reschedule_main(Retrievals,GuardList,Prelude,Goal) ; append(Retrievals,GuardList,GoalList), list2conj(GoalList,Goal) ). guard_via_reschedule_main(Retrievals,GuardList,Prelude,Goal) :- initialize_unit_dictionary(Prelude,Dict), build_units(Retrievals,GuardList,Dict,Units), dependency_reorder(Units,NUnits), units2goal(NUnits,Goal). units2goal([],true). units2goal([unit(_,Goal,_,_)|Units],(Goal,Goals)) :- units2goal(Units,Goals). dependency_reorder(Units,NUnits) :- dependency_reorder(Units,[],NUnits). dependency_reorder([],Acc,Result) :- reverse(Acc,Result). dependency_reorder([Unit|Units],Acc,Result) :- Unit = unit(_GID,_Goal,Type,GIDs), ( Type == fixed -> NAcc = [Unit|Acc] ; dependency_insert(Acc,Unit,GIDs,NAcc) ), dependency_reorder(Units,NAcc,Result). dependency_insert([],Unit,_,[Unit]). dependency_insert([X|Xs],Unit,GIDs,L) :- X = unit(GID,_,_,_), ( memberchk(GID,GIDs) -> L = [Unit,X|Xs] ; L = [X | T], dependency_insert(Xs,Unit,GIDs,T) ). build_units(Retrievals,Guard,InitialDict,Units) :- build_retrieval_units(Retrievals,1,N,InitialDict,Dict,Units,Tail), build_guard_units(Guard,N,Dict,Tail). build_retrieval_units([],N,N,Dict,Dict,L,L). build_retrieval_units([U|Us],N,M,Dict,NDict,L,T) :- term_variables(U,Vs), update_unit_dictionary(Vs,N,Dict,Dict1,[],GIDs), L = [unit(N,U,movable,GIDs)|L1], N1 is N + 1, build_retrieval_units2(Us,N1,M,Dict1,NDict,L1,T). build_retrieval_units2([],N,N,Dict,Dict,L,L). build_retrieval_units2([U|Us],N,M,Dict,NDict,L,T) :- term_variables(U,Vs), update_unit_dictionary(Vs,N,Dict,Dict1,[],GIDs), L = [unit(N,U,fixed,GIDs)|L1], N1 is N + 1, build_retrieval_units(Us,N1,M,Dict1,NDict,L1,T). initialize_unit_dictionary(Term,Dict) :- term_variables(Term,Vars), pair_all_with(Vars,0,Dict). update_unit_dictionary([],_,Dict,Dict,GIDs,GIDs). update_unit_dictionary([V|Vs],This,Dict,NDict,GIDs,NGIDs) :- ( lookup_eq(Dict,V,GID) -> ( (GID == This ; memberchk(GID,GIDs) ) -> GIDs1 = GIDs ; GIDs1 = [GID|GIDs] ), Dict1 = Dict ; Dict1 = [V - This|Dict], GIDs1 = GIDs ), update_unit_dictionary(Vs,This,Dict1,NDict,GIDs1,NGIDs). build_guard_units(Guard,N,Dict,Units) :- ( Guard = [Goal] -> Units = [unit(N,Goal,fixed,[])] ; Guard = [Goal|Goals] -> term_variables(Goal,Vs), update_unit_dictionary2(Vs,N,Dict,NDict,[],GIDs), Units = [unit(N,Goal,movable,GIDs)|RUnits], N1 is N + 1, build_guard_units(Goals,N1,NDict,RUnits) ). update_unit_dictionary2([],_,Dict,Dict,GIDs,GIDs). update_unit_dictionary2([V|Vs],This,Dict,NDict,GIDs,NGIDs) :- ( lookup_eq(Dict,V,GID) -> ( (GID == This ; memberchk(GID,GIDs) ) -> GIDs1 = GIDs ; GIDs1 = [GID|GIDs] ), Dict1 = [V - This|Dict] ; Dict1 = [V - This|Dict], GIDs1 = GIDs ), update_unit_dictionary2(Vs,This,Dict1,NDict,GIDs1,NGIDs). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% ____ _ ____ _ _ %% / ___| ___| |_ / ___| ___ _ __ ___ __ _ _ __ | |_(_) ___ ___ _ %% \___ \ / _ \ __| \___ \ / _ \ '_ ` _ \ / _` | '_ \| __| |/ __/ __(_) %% ___) | __/ |_ ___) | __/ | | | | | (_| | | | | |_| | (__\__ \_ %% |____/ \___|\__| |____/ \___|_| |_| |_|\__,_|_| |_|\__|_|\___|___(_) %% %% _ _ _ ___ __ %% | | | |_ __ (_) __ _ _ _ ___ |_ _|_ __ / _| ___ _ __ ___ _ __ ___ ___ %% | | | | '_ \| |/ _` | | | |/ _ \ | || '_ \| |_ / _ \ '__/ _ \ '_ \ / __/ _ \ %% | |_| | | | | | (_| | |_| | __/ | || | | | _| __/ | | __/ | | | (_| __/ %% \___/|_| |_|_|\__, |\__,_|\___| |___|_| |_|_| \___|_| \___|_| |_|\___\___| %% |_| unique_analyse_optimise(Rules,N,PatternList,NRules) :- ( chr_pp_flag(unique_analyse_optimise,on) -> unique_analyse_optimise_main(Rules,N,PatternList,NRules) ; NRules = Rules ). unique_analyse_optimise_main([],_,_,[]). unique_analyse_optimise_main([PRule|PRules],N,PatternList,[NPRule|NPRules]) :- ( discover_unique_pattern(PRule,N,Pattern) -> NPatternList = [Pattern|PatternList] ; NPatternList = PatternList ), PRule = pragma(Rule,Ids,Pragmas,Name), Rule = rule(H1,H2,_,_), Ids = ids(Ids1,Ids2), apply_unique_patterns_to_constraints(H1,Ids1,NPatternList,MorePragmas1), apply_unique_patterns_to_constraints(H2,Ids2,NPatternList,MorePragmas2), append([MorePragmas1,MorePragmas2,Pragmas],NPragmas), NPRule = pragma(Rule,Ids,NPragmas,Name), N1 is N + 1, unique_analyse_optimise_main(PRules,N1,NPatternList,NPRules). apply_unique_patterns_to_constraints([],_,_,[]). apply_unique_patterns_to_constraints([C|Cs],[Id|Ids],Patterns,Pragmas) :- ( member(Pattern,Patterns), apply_unique_pattern(C,Id,Pattern,Pragma) -> Pragmas = [Pragma | RPragmas] ; Pragmas = RPragmas ), apply_unique_patterns_to_constraints(Cs,Ids,Patterns,RPragmas). apply_unique_pattern(Constraint,Id,Pattern,Pragma) :- Pattern = unique(PatternConstraint,PatternKey), subsumes(Constraint,PatternConstraint,Unifier), ( setof( V, T^Term^Vs^( member(T,PatternKey), lookup_eq(Unifier,T,Term), term_variables(Term,Vs), member(V,Vs) ), Vars) -> true ; Vars = [] ), Pragma = unique(Id,Vars). % subsumes(+Term1, +Term2, -Unifier) % % If Term1 is a more general term than Term2 (e.g. has a larger % part instantiated), unify Unifier with a list Var-Value of % variables from Term2 and their corresponding values in Term1. subsumes(Term1,Term2,Unifier) :- empty_ds(S0), subsumes_aux(Term1,Term2,S0,S), ds_to_list(S,L), build_unifier(L,Unifier). subsumes_aux(Term1, Term2, S0, S) :- ( compound(Term2), functor(Term2, F, N) -> compound(Term1), functor(Term1, F, N), subsumes_aux(N, Term1, Term2, S0, S) ; Term1 == Term2 -> S = S0 ; var(Term2), get_ds(Term1,S0,V) -> V == Term2, S = S0 ; var(Term2), put_ds(Term1, S0, Term2, S) ). subsumes_aux(0, _, _, S, S) :- ! . subsumes_aux(N, T1, T2, S0, S) :- arg(N, T1, T1x), arg(N, T2, T2x), subsumes_aux(T1x, T2x, S0, S1), M is N-1, subsumes_aux(M, T1, T2, S1, S). build_unifier([],[]). build_unifier([X-V|R],[V - X | T]) :- build_unifier(R,T). discover_unique_pattern(PragmaRule,RuleNb,Pattern) :- PragmaRule = pragma(Rule,_,Pragmas,Name), ( Rule = rule([C1],[C2],Guard,Body) -> true ; Rule = rule([C1,C2],[],Guard,Body) ), check_unique_constraints(C1,C2,Guard,Body,Pragmas,List), term_variables(C1,Vs), select_pragma_unique_variables(List,Vs,Key), Pattern0 = unique(C1,Key), copy_term_nat(Pattern0,Pattern), ( verbosity_on -> format('Found unique pattern ~w in rule ~d~@\n', [Pattern,RuleNb,(Name=yes(N) -> write(": "),write(N) ; true)]) ; true ). select_pragma_unique_variables([],_,[]). select_pragma_unique_variables([X-Y|R],Vs,L) :- ( X == Y -> L = [X|T] ; once(( \+ memberchk_eq(X,Vs) ; \+ memberchk_eq(Y,Vs) )), L = T ), select_pragma_unique_variables(R,Vs,T). check_unique_constraints(C1,C2,G,_Body,Pragmas,List) :- \+ member(passive(_),Pragmas), variable_replacement(C1-C2,C2-C1,List), copy_with_variable_replacement(G,OtherG,List), negate(G,NotG), once(entails(NotG,OtherG)). negate(true,fail). negate(fail,true). negate(X =< Y, Y < X). negate(X > Y, Y >= X). negate(X >= Y, Y > X). negate(X < Y, Y =< X). negate(var(X),nonvar(X)). negate(nonvar(X),var(X)). entails(X,X1) :- X1 == X. entails(fail,_). entails(X > Y, X1 >= Y1) :- X1 == X, Y1 == Y. entails(X < Y, X1 =< Y1) :- X1 == X, Y1 == Y. entails(ground(X),var(X1)) :- X1 == X. check_unnecessary_active(Constraint,Previous,Rule) :- ( chr_pp_flag(check_unnecessary_active,full) -> check_unnecessary_active_main(Constraint,Previous,Rule) ; chr_pp_flag(check_unnecessary_active,simplification), Rule = rule(_,[],_,_) -> check_unnecessary_active_main(Constraint,Previous,Rule) ; fail ). check_unnecessary_active_main(Constraint,Previous,Rule) :- member(Other,Previous), variable_replacement(Other,Constraint,List), copy_with_variable_replacement(Rule,Rule2,List), identical_rules(Rule,Rule2), ! . set_semantics_rule(PragmaRule) :- ( chr_pp_flag(set_semantics_rule,on) -> set_semantics_rule_main(PragmaRule) ; fail ). set_semantics_rule_main(PragmaRule) :- PragmaRule = pragma(Rule,IDs,Pragmas,_), Rule = rule([C1],[C2],true,true), C1 == C2, IDs = ids([ID1],_), \+ memberchk_eq(passive(ID1),Pragmas). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% ____ _ _____ _ _ %% | _ \ _ _| | ___ | ____|__ _ _ _(_)_ ____ _| | ___ _ __ ___ ___ %% | |_) | | | | |/ _ \ | _| / _` | | | | \ \ / / _` | |/ _ \ '_ \ / __/ _ \ %% | _ <| |_| | | __/ | |__| (_| | |_| | |\ V / (_| | | __/ | | | (_| __/ %% |_| \_\\__,_|_|\___| |_____\__, |\__,_|_| \_/ \__,_|_|\___|_| |_|\___\___| %% |_| % have to check for no duplicates in value list % check wether two rules are identical identical_rules(rule(H11,H21,G1,B1),rule(H12,H22,G2,B2)) :- G1 == G2, identical_bodies(B1,B2), permutation(H11,P1), P1 == H12, permutation(H21,P2), P2 == H22. identical_bodies(B1,B2) :- ( B1 = (X1 = Y1), B2 = (X2 = Y2) -> ( X1 == X2, Y1 == Y2 ; X1 == Y2, X2 == Y1 ), ! ; B1 == B2 ). % replace variables in list copy_with_variable_replacement(X,Y,L) :- ( var(X) -> ( lookup_eq(L,X,Y) -> true ; X = Y ) ; functor(X,F,A), functor(Y,F,A), X =.. [_|XArgs], Y =.. [_|YArgs], copy_with_variable_replacement_l(XArgs,YArgs,L) ). copy_with_variable_replacement_l([],[],_). copy_with_variable_replacement_l([X|Xs],[Y|Ys],L) :- copy_with_variable_replacement(X,Y,L), copy_with_variable_replacement_l(Xs,Ys,L). %% build variable replacement list variable_replacement(X,Y,L) :- variable_replacement(X,Y,[],L). variable_replacement(X,Y,L1,L2) :- ( var(X) -> var(Y), ( lookup_eq(L1,X,Z) -> Z == Y, L2 = L1 ; L2 = [X-Y|L1] ) ; X =.. [F|XArgs], nonvar(Y), Y =.. [F|YArgs], variable_replacement_l(XArgs,YArgs,L1,L2) ). variable_replacement_l([],[],L,L). variable_replacement_l([X|Xs],[Y|Ys],L1,L3) :- variable_replacement(X,Y,L1,L2), variable_replacement_l(Xs,Ys,L2,L3). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% ____ _ _ _ __ _ _ _ %% / ___|(_)_ __ ___ _ __ | (_)/ _(_) ___ __ _| |_(_) ___ _ __ %% \___ \| | '_ ` _ \| '_ \| | | |_| |/ __/ _` | __| |/ _ \| '_ \ %% ___) | | | | | | | |_) | | | _| | (_| (_| | |_| | (_) | | | | %% |____/|_|_| |_| |_| .__/|_|_|_| |_|\___\__,_|\__|_|\___/|_| |_| %% |_| simplification_code(Head,RestHeads,RestIDs,PragmaRule,F/A,_I,N,Constraints,Mod,Id,L,T) :- PragmaRule = pragma(Rule,_,Pragmas,_), head_info(Head,A,_Vars,Susp,HeadVars,HeadPairs), build_head(F,A,Id,HeadVars,ClauseHead), head_arg_matches(HeadPairs,[],FirstMatching,VarDict1), ( RestHeads == [] -> Susps = [], VarDict = VarDict1, GetRestHeads = [] ; rest_heads_retrieval_and_matching(RestHeads,RestIDs,Pragmas,Head,Mod,N,Constraints,GetRestHeads,Susps,VarDict1,VarDict) ), guard_body_copies2(Rule,VarDict,GuardCopyList,BodyCopy), guard_via_reschedule(GetRestHeads,GuardCopyList,ClauseHead-FirstMatching,RescheduledTest), gen_uncond_susps_detachments(Susps,RestHeads,SuspsDetachments), gen_cond_susp_detachment(Susp,F/A,SuspDetachment), Clause = ( ClauseHead :- FirstMatching, RescheduledTest, !, SuspsDetachments, SuspDetachment, BodyCopy ), L = [Clause | T]. head_arg_matches(Pairs,VarDict,Goal,NVarDict) :- head_arg_matches_(Pairs,VarDict,GoalList,NVarDict), list2conj(GoalList,Goal). head_arg_matches_([],VarDict,[],VarDict). head_arg_matches_([Arg-Var| Rest],VarDict,GoalList,NVarDict) :- ( var(Arg) -> ( lookup_eq(VarDict,Arg,OtherVar) -> GoalList = [Var == OtherVar | RestGoalList], VarDict1 = VarDict ; VarDict1 = [Arg-Var | VarDict], GoalList = RestGoalList ), Pairs = Rest ; atomic(Arg) -> GoalList = [ Var == Arg | RestGoalList], VarDict = VarDict1, Pairs = Rest ; Arg =.. [_|Args], functor(Arg,Fct,N), functor(Term,Fct,N), Term =.. [_|Vars], GoalList =[ nonvar(Var), Var = Term | RestGoalList ], pairup(Args,Vars,NewPairs), append(NewPairs,Rest,Pairs), VarDict1 = VarDict ), head_arg_matches_(Pairs,VarDict1,RestGoalList,NVarDict). rest_heads_retrieval_and_matching(Heads,IDs,Pragmas,ActiveHead,Mod,N,Constraints,GoalList,Susps,VarDict,NVarDict):- rest_heads_retrieval_and_matching(Heads,IDs,Pragmas,ActiveHead,Mod,N,Constraints,GoalList,Susps,VarDict,NVarDict,[],[],[]). rest_heads_retrieval_and_matching(Heads,IDs,Pragmas,ActiveHead,Mod,N,Constraints,GoalList,Susps,VarDict,NVarDict,PrevHs,PrevSusps,AttrDict) :- ( Heads = [_|_] -> rest_heads_retrieval_and_matching_n(Heads,IDs,Pragmas,PrevHs,PrevSusps,ActiveHead,Mod,N,Constraints,GoalList,Susps,VarDict,NVarDict,AttrDict) ; GoalList = [], Susps = [], VarDict = NVarDict ). rest_heads_retrieval_and_matching_n([],_,_,_,_,_,_,N,_,[],[],VarDict,VarDict,AttrDict) :- instantiate_pattern_goals(AttrDict,N). rest_heads_retrieval_and_matching_n([H|Hs],[ID|IDs],Pragmas,PrevHs,PrevSusps,ActiveHead,Mod,N,Constraints,[ViaGoal,Goal|Goals],[Susp|Susps],VarDict,NVarDict,AttrDict) :- passive_head_via(H,[ActiveHead|PrevHs],AttrDict,Constraints,Mod,VarDict,ViaGoal,Attr,NewAttrDict), functor(H,Fct,Aty), head_info(H,Aty,Vars,_,_,Pairs), head_arg_matches(Pairs,VarDict,MatchingGoal,VarDict1), Suspension =.. [suspension,_,State,_,_,_,_|Vars], ( N == 1 -> VarSusps = Attr ; nth(Pos,Constraints,Fct/Aty), !, make_attr(N,_Mask,SuspsList,Attr), nth(Pos,SuspsList,VarSusps) ), different_from_other_susps(H,Susp,PrevHs,PrevSusps,DiffSuspGoals), create_get_mutable_ref(active,State,GetMutable), Goal1 = ( 'chr sbag_member'(Susp,VarSusps), Susp = Suspension, GetMutable, DiffSuspGoals, MatchingGoal ), ( member(unique(ID,UniqueKeus),Pragmas), check_unique_keys(UniqueKeus,VarDict) -> Goal = (Goal1 -> true) % once(Goal1) ; Goal = Goal1 ), rest_heads_retrieval_and_matching_n(Hs,IDs,Pragmas,[H|PrevHs],[Susp|PrevSusps],ActiveHead,Mod,N,Constraints,Goals,Susps,VarDict1,NVarDict,NewAttrDict). instantiate_pattern_goals([],_). instantiate_pattern_goals([_-attr(Attr,Bits,Goal)|Rest],N) :- ( N == 1 -> Goal = true ; make_attr(N,Mask,_,Attr), or_list(Bits,Pattern), !, Goal = (Mask /\ Pattern =:= Pattern) ), instantiate_pattern_goals(Rest,N). check_unique_keys([],_). check_unique_keys([V|Vs],Dict) :- lookup_eq(Dict,V,_), check_unique_keys(Vs,Dict). % Generates tests to ensure the found constraint differs from previously found constraints different_from_other_susps(Head,Susp,Heads,Susps,DiffSuspGoals) :- ( bagof(DiffSuspGoal, Pos ^ ( nth(Pos,Heads,PreHead), \+ Head \= PreHead, nth(Pos,Susps,PreSusp), DiffSuspGoal = (Susp \== PreSusp) ),DiffSuspGoalList) -> list2conj(DiffSuspGoalList,DiffSuspGoals) ; DiffSuspGoals = true ). passive_head_via(Head,PrevHeads,AttrDict,Constraints,Mod,VarDict,Goal,Attr,NewAttrDict) :- functor(Head,F,A), nth(Pos,Constraints,F/A),!, common_variables(Head,PrevHeads,CommonVars), translate(CommonVars,VarDict,Vars), or_pattern(Pos,Bit), ( permutation(Vars,PermutedVars), lookup_eq(AttrDict,PermutedVars,attr(Attr,Positions,_)) -> member(Bit,Positions), !, NewAttrDict = AttrDict, Goal = true ; Goal = (Goal1, PatternGoal), gen_get_mod_constraints(Mod,Vars,Goal1,Attr), NewAttrDict = [Vars - attr(Attr,[Bit|_],PatternGoal) | AttrDict] ). common_variables(T,Ts,Vs) :- term_variables(T,V1), term_variables(Ts,V2), intersect_eq(V1,V2,Vs). gen_get_mod_constraints(Mod,L,Goal,Susps) :- ( L == [] -> Goal = ( 'chr default_store'(Global), get_attr(Global,Mod,TSusps), TSusps = Susps ) ; ( L = [A] -> VIA = 'chr via_1'(A,V) ; ( L = [A,B] -> VIA = 'chr via_2'(A,B,V) ; VIA = 'chr via'(L,V) ) ), Goal = ( VIA, get_attr(V,Mod,TSusps), TSusps = Susps ) ). guard_body_copies(Rule,VarDict,GuardCopy,BodyCopy) :- guard_body_copies2(Rule,VarDict,GuardCopyList,BodyCopy), list2conj(GuardCopyList,GuardCopy). guard_body_copies2(Rule,VarDict,GuardCopyList,BodyCopy) :- Rule = rule(_,_,Guard,Body), conj2list(Guard,GuardList), split_off_simple_guard(GuardList,VarDict,GuardPrefix,RestGuardList), my_term_copy(GuardPrefix-RestGuardList,VarDict,VarDict2,GuardPrefixCopy-RestGuardListCopyCore), append(GuardPrefixCopy,[RestGuardCopy],GuardCopyList), term_variables(RestGuardList,GuardVars), term_variables(RestGuardListCopyCore,GuardCopyVars), ( chr_pp_flag(guard_locks,on), bagof(('chr lock'(Y)) - ('chr unlock'(Y)), X ^ (member(X,GuardVars), % X is a variable appearing in the original guard lookup_eq(VarDict,X,Y), % translate X into new variable memberchk_eq(Y,GuardCopyVars) % redundant check? or multiple entries for X possible? ), LocksUnlocks) -> once(pairup(Locks,Unlocks,LocksUnlocks)) ; Locks = [], Unlocks = [] ), list2conj(Locks,LockPhase), list2conj(Unlocks,UnlockPhase), list2conj(RestGuardListCopyCore,RestGuardCopyCore), RestGuardCopy = (LockPhase,(RestGuardCopyCore,UnlockPhase)), my_term_copy(Body,VarDict2,BodyCopy). split_off_simple_guard([],_,[],[]). split_off_simple_guard([G|Gs],VarDict,S,C) :- ( simple_guard(G,VarDict) -> S = [G|Ss], split_off_simple_guard(Gs,VarDict,Ss,C) ; S = [], C = [G|Gs] ). % simple guard: cheap and benign (does not bind variables) simple_guard(var(_), _). simple_guard(nonvar(_), _). simple_guard(ground(_), _). simple_guard(number(_), _). simple_guard(atom(_), _). simple_guard(integer(_), _). simple_guard(float(_), _). simple_guard(_ > _ , _). simple_guard(_ < _ , _). simple_guard(_ =< _, _). simple_guard(_ >= _, _). simple_guard(_ =:= _, _). simple_guard(_ == _, _). simple_guard(X is _, VarDict) :- \+ lookup_eq(VarDict,X,_). simple_guard((G1,G2),VarDict) :- simple_guard(G1,VarDict), simple_guard(G2,VarDict). simple_guard(\+ G, VarDict) :- simple_guard(G, VarDict). my_term_copy(X,Dict,Y) :- my_term_copy(X,Dict,_,Y). my_term_copy(X,Dict1,Dict2,Y) :- ( var(X) -> ( lookup_eq(Dict1,X,Y) -> Dict2 = Dict1 ; Dict2 = [X-Y|Dict1] ) ; functor(X,XF,XA), functor(Y,XF,XA), X =.. [_|XArgs], Y =.. [_|YArgs], my_term_copy_list(XArgs,Dict1,Dict2,YArgs) ). my_term_copy_list([],Dict,Dict,[]). my_term_copy_list([X|Xs],Dict1,Dict3,[Y|Ys]) :- my_term_copy(X,Dict1,Dict2,Y), my_term_copy_list(Xs,Dict2,Dict3,Ys). gen_cond_susp_detachment(Susp,FA,SuspDetachment) :- gen_uncond_susp_detachment(Susp,FA,UnCondSuspDetachment), SuspDetachment = ( var(Susp) -> true ; UnCondSuspDetachment ). gen_uncond_susp_detachment(Susp,CFct/CAty,SuspDetachment) :- atom_concat_list(['detach_',CFct, (/) ,CAty],Fct), Detach =.. [Fct,Vars,Susp], SuspDetachment = ( 'chr remove_constraint_internal'(Susp, Vars), Detach ). gen_uncond_susps_detachments([],[],true). gen_uncond_susps_detachments([Susp|Susps],[Term|Terms],(SuspDetachment,SuspsDetachments)) :- functor(Term,F,A), gen_uncond_susp_detachment(Susp,F/A,SuspDetachment), gen_uncond_susps_detachments(Susps,Terms,SuspsDetachments). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% ____ _ _ _ _ %% / ___|(_)_ __ ___ _ __ __ _ __ _ __ _| |_(_) ___ _ __ / | %% \___ \| | '_ ` _ \| '_ \ / _` |/ _` |/ _` | __| |/ _ \| '_ \ | | %% ___) | | | | | | | |_) | (_| | (_| | (_| | |_| | (_) | | | | | | %% |____/|_|_| |_| |_| .__/ \__,_|\__, |\__,_|\__|_|\___/|_| |_| |_| %% |_| |___/ simpagation_head1_code(Head,RestHeads,OtherIDs,PragmaRule,F/A,_I,N,Constraints,Mod,Id,L,T) :- PragmaRule = pragma(Rule,ids(_,Heads2IDs),Pragmas,_Name), Rule = rule(_Heads,Heads2,_Guard,_Body), head_info(Head,A,_Vars,Susp,HeadVars,HeadPairs), head_arg_matches(HeadPairs,[],FirstMatching,VarDict1), build_head(F,A,Id,HeadVars,ClauseHead), append(RestHeads,Heads2,Heads), append(OtherIDs,Heads2IDs,IDs), reorder_heads(Head,Heads,IDs,NHeads,NIDs), rest_heads_retrieval_and_matching(NHeads,NIDs,Pragmas,Head,Mod,N,Constraints,GetRestHeads,Susps,VarDict1,VarDict), length(RestHeads,RN), take(RN,Susps,Susps1), guard_body_copies2(Rule,VarDict,GuardCopyList,BodyCopy), guard_via_reschedule(GetRestHeads,GuardCopyList,ClauseHead-FirstMatching,RescheduledTest), gen_uncond_susps_detachments(Susps1,RestHeads,SuspsDetachments), gen_cond_susp_detachment(Susp,F/A,SuspDetachment), Clause = ( ClauseHead :- FirstMatching, RescheduledTest, !, SuspsDetachments, SuspDetachment, BodyCopy ), L = [Clause | T]. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% ____ _ _ _ ____ %% / ___|(_)_ __ ___ _ __ __ _ __ _ __ _| |_(_) ___ _ __ |___ \ %% \___ \| | '_ ` _ \| '_ \ / _` |/ _` |/ _` | __| |/ _ \| '_ \ __) | %% ___) | | | | | | | |_) | (_| | (_| | (_| | |_| | (_) | | | | / __/ %% |____/|_|_| |_| |_| .__/ \__,_|\__, |\__,_|\__|_|\___/|_| |_| |_____| %% |_| |___/ %% Genereate prelude + worker predicate %% prelude calls worker %% worker iterates over one type of removed constraints simpagation_head2_code(Head2,RestHeads2,RestIDs,PragmaRule,FA,I,N,Constraints,Mod,Id,L,T) :- PragmaRule = pragma(Rule,ids(IDs1,_),Pragmas,_Name), Rule = rule(Heads1,_,Guard,Body), reorder_heads(Head2,Heads1,IDs1,[Head1|RestHeads1],[ID1|RestIDs1]), % Heads1 = [Head1|RestHeads1], % IDs1 = [ID1|RestIDs1], simpagation_head2_prelude(Head2,Head1,[RestHeads2,Heads1,Guard,Body],FA,I,N,Constraints,Mod,Id,L,L1), extend_id(Id,Id2), simpagation_head2_worker(Head2,Head1,ID1,RestHeads1,RestIDs1,RestHeads2,RestIDs,Rule,Pragmas,FA,I,N,Constraints,Mod,Id2,L1,T). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% simpagation_head2_prelude(Head,Head1,Rest,F/A,_I,N,Constraints,Mod,Id1,L,T) :- head_info(Head,A,Vars,Susp,VarsSusp,HeadPairs), build_head(F,A,Id1,VarsSusp,ClauseHead), head_arg_matches(HeadPairs,[],FirstMatching,VarDict), passive_head_via(Head1,[Head],[],Constraints,Mod,VarDict,ModConstraintsGoal,Attr,AttrDict), instantiate_pattern_goals(AttrDict,N), ( N == 1 -> AllSusps = Attr ; functor(Head1,F1,A1), nth(Pos,Constraints,F1/A1), !, make_attr(N,_,SuspsList,Attr), nth(Pos,SuspsList,AllSusps) ), ( Id1 == [0] -> % create suspension gen_cond_allocation(Vars,Susp,F/A,VarsSusp,Mod,ConstraintAllocationGoal) ; ConstraintAllocationGoal = true ), extend_id(Id1,DelegateId), extra_active_delegate_variables(Head,Rest,VarDict,ExtraVars), append([AllSusps|VarsSusp],ExtraVars,DelegateCallVars), build_head(F,A,DelegateId,DelegateCallVars,Delegate), PreludeClause = ( ClauseHead :- FirstMatching, ModConstraintsGoal, !, ConstraintAllocationGoal, Delegate ), L = [PreludeClause|T]. extra_active_delegate_variables(Term,Terms,VarDict,Vars) :- Term =.. [_|Args], delegate_variables(Term,Terms,VarDict,Args,Vars). passive_delegate_variables(Term,PrevTerms,NextTerms,VarDict,Vars) :- term_variables(PrevTerms,PrevVars), delegate_variables(Term,NextTerms,VarDict,PrevVars,Vars). delegate_variables(Term,Terms,VarDict,PrevVars,Vars) :- term_variables(Term,V1), term_variables(Terms,V2), intersect_eq(V1,V2,V3), list_difference_eq(V3,PrevVars,V4), translate(V4,VarDict,Vars). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% simpagation_head2_worker(Head2,Head1,ID1,RestHeads1,IDs1,RestHeads2,IDs2,Rule,Pragmas,FA,I,N,Constraints,Mod,Id,L,T) :- Rule = rule(_,_,Guard,Body), simpagation_head2_worker_end(Head2,[Head1,RestHeads1,RestHeads2,Guard,Body],FA,Id,L,L1), simpagation_head2_worker_body(Head2,Head1,ID1,RestHeads1,IDs1,RestHeads2,IDs2,Rule,Pragmas,FA,I,N,Constraints,Mod,Id,L1,T). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% simpagation_head2_worker_body(Head2,Head1,ID1,RestHeads1,IDs1,RestHeads2,IDs2,Rule,Pragmas,F/A,_I,N,Constraints,Mod,Id,L,T) :- gen_var(OtherSusp), gen_var(OtherSusps), head_info(Head2,A,_Vars,Susp,VarsSusp,Head2Pairs), head_arg_matches(Head2Pairs,[],_,VarDict1), Rule = rule(_,_,Guard,Body), extra_active_delegate_variables(Head2,[Head1,RestHeads1,RestHeads2,Guard,Body],VarDict1,ExtraVars), append([[OtherSusp|OtherSusps]|VarsSusp],ExtraVars,HeadVars), build_head(F,A,Id,HeadVars,ClauseHead), functor(Head1,_OtherF,OtherA), head_info(Head1,OtherA,OtherVars,_,_,Head1Pairs), head_arg_matches(Head1Pairs,VarDict1,FirstMatching,VarDict2), OtherSuspension =.. [suspension,_,OtherState,_,_,_,_|OtherVars], create_get_mutable_ref(active,OtherState,GetMutable), IteratorSuspTest = ( OtherSusp = OtherSuspension, GetMutable ), ( (RestHeads1 \== [] ; RestHeads2 \== []) -> append(RestHeads1,RestHeads2,RestHeads), append(IDs1,IDs2,IDs), reorder_heads(Head1-Head2,RestHeads,IDs,NRestHeads,NIDs), rest_heads_retrieval_and_matching(NRestHeads,NIDs,Pragmas,[Head1,Head2],Mod,N,Constraints,RestSuspsRetrieval,Susps,VarDict2,VarDict,[Head1],[OtherSusp],[]), length(RestHeads1,RH1N), take(RH1N,Susps,Susps1) ; RestSuspsRetrieval = [], Susps1 = [], VarDict = VarDict2 ), gen_uncond_susps_detachments([OtherSusp | Susps1],[Head1|RestHeads1],Susps1Detachments), append([OtherSusps|VarsSusp],ExtraVars,RecursiveVars), build_head(F,A,Id,RecursiveVars,RecursiveCall), append([[]|VarsSusp],ExtraVars,RecursiveVars2), build_head(F,A,Id,RecursiveVars2,RecursiveCall2), guard_body_copies2(Rule,VarDict,GuardCopyList,BodyCopy), guard_via_reschedule(RestSuspsRetrieval,GuardCopyList,v(ClauseHead,IteratorSuspTest,FirstMatching),RescheduledTest), ( BodyCopy \== true -> gen_uncond_attach_goal(F/A,Susp,Mod,Attachment,Generation), gen_state_cond_call(Susp,A,RecursiveCall,Generation,ConditionalRecursiveCall), gen_state_cond_call(Susp,A,RecursiveCall2,Generation,ConditionalRecursiveCall2) ; Attachment = true, ConditionalRecursiveCall = RecursiveCall, ConditionalRecursiveCall2 = RecursiveCall2 ), ( member(unique(ID1,UniqueKeys), Pragmas), check_unique_keys(UniqueKeys,VarDict1) -> Clause = ( ClauseHead :- ( IteratorSuspTest, FirstMatching -> ( RescheduledTest -> Susps1Detachments, Attachment, BodyCopy, ConditionalRecursiveCall2 ; RecursiveCall2 ) ; RecursiveCall ) ) ; Clause = ( ClauseHead :- ( IteratorSuspTest, FirstMatching, RescheduledTest -> Susps1Detachments, Attachment, BodyCopy, ConditionalRecursiveCall ; RecursiveCall ) ) ), L = [Clause | T]. gen_state_cond_call(Susp,N,Call,Generation,ConditionalCall) :- length(Args,N), Suspension =.. [suspension,_,State,_,NewGeneration,_,_|Args], create_get_mutable_ref(active,State,GetState), create_get_mutable_ref(Generation,NewGeneration,GetGeneration), ConditionalCall = ( Susp = Suspension, GetState, GetGeneration -> 'chr update_mutable'(inactive,State), Call ; true ). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% simpagation_head2_worker_end(Head,Rest,F/A,Id,L,T) :- head_info(Head,A,_Vars,_Susp,VarsSusp,Pairs), head_arg_matches(Pairs,[],_,VarDict), extra_active_delegate_variables(Head,Rest,VarDict,ExtraVars), append([[]|VarsSusp],ExtraVars,HeadVars), build_head(F,A,Id,HeadVars,ClauseHead), next_id(Id,ContinuationId), build_head(F,A,ContinuationId,VarsSusp,ContinuationHead), Clause = ( ClauseHead :- ContinuationHead ), L = [Clause | T]. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% ____ _ _ %% | _ \ _ __ ___ _ __ __ _ __ _ __ _| |_(_) ___ _ __ %% | |_) | '__/ _ \| '_ \ / _` |/ _` |/ _` | __| |/ _ \| '_ \ %% | __/| | | (_) | |_) | (_| | (_| | (_| | |_| | (_) | | | | %% |_| |_| \___/| .__/ \__,_|\__, |\__,_|\__|_|\___/|_| |_| %% |_| |___/ propagation_code(Head,RestHeads,Rule,RuleNb,RestHeadNb,FA,N,Constraints,Mod,Id,L,T) :- ( RestHeads == [] -> propagation_single_headed(Head,Rule,RuleNb,FA,Mod,Id,L,T) ; propagation_multi_headed(Head,RestHeads,Rule,RuleNb,RestHeadNb,FA,N,Constraints,Mod,Id,L,T) ). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% Single headed propagation %% everything in a single clause propagation_single_headed(Head,Rule,RuleNb,F/A,Mod,Id,L,T) :- head_info(Head,A,Vars,Susp,VarsSusp,HeadPairs), build_head(F,A,Id,VarsSusp,ClauseHead), inc_id(Id,NextId), build_head(F,A,NextId,VarsSusp,NextHead), NextCall = NextHead, head_arg_matches(HeadPairs,[],HeadMatching,VarDict), guard_body_copies(Rule,VarDict,GuardCopy,BodyCopy), ( Id == [0] -> gen_cond_allocation(Vars,Susp,F/A,VarsSusp,Mod,Allocation), Allocation1 = Allocation ; Allocation1 = true ), gen_uncond_attach_goal(F/A,Susp,Mod,Attachment,Generation), gen_state_cond_call(Susp,A,NextCall,Generation,ConditionalNextCall), Clause = ( ClauseHead :- HeadMatching, Allocation1, 'chr novel_production'(Susp,RuleNb), % optimisation of t(RuleNb,Susp) GuardCopy, !, 'chr extend_history'(Susp,RuleNb), Attachment, BodyCopy, ConditionalNextCall ), L = [Clause | T]. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% multi headed propagation %% prelude + predicates to accumulate the necessary combinations of suspended %% constraints + predicate to execute the body propagation_multi_headed(Head,RestHeads,Rule,RuleNb,RestHeadNb,FA,N,Constraints,Mod,Id,L,T) :- RestHeads = [First|Rest], propagation_prelude(Head,RestHeads,Rule,FA,N,Constraints,Mod,Id,L,L1), extend_id(Id,ExtendedId), propagation_nested_code(Rest,[First,Head],Rule,RuleNb,RestHeadNb,FA,N,Constraints,Mod,ExtendedId,L1,T). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% propagation_prelude(Head,[First|Rest],Rule,F/A,N,Constraints,Mod,Id,L,T) :- head_info(Head,A,Vars,Susp,VarsSusp,HeadPairs), build_head(F,A,Id,VarsSusp,PreludeHead), head_arg_matches(HeadPairs,[],FirstMatching,VarDict), Rule = rule(_,_,Guard,Body), extra_active_delegate_variables(Head,[First,Rest,Guard,Body],VarDict,ExtraVars), passive_head_via(First,[Head],[],Constraints,Mod,VarDict,FirstSuspGoal,Attr,AttrDict), instantiate_pattern_goals(AttrDict,N), ( N == 1 -> Susps = Attr ; functor(First,FirstFct,FirstAty), make_attr(N,_Mask,SuspsList,Attr), nth(Pos,Constraints,FirstFct/FirstAty), !, nth(Pos,SuspsList,Susps) ), ( Id == [0] -> gen_cond_allocation(Vars,Susp,F/A,VarsSusp,Mod,CondAllocation) ; CondAllocation = true ), extend_id(Id,NestedId), append([Susps|VarsSusp],ExtraVars,NestedVars), build_head(F,A,NestedId,NestedVars,NestedHead), NestedCall = NestedHead, Prelude = ( PreludeHead :- FirstMatching, FirstSuspGoal, !, CondAllocation, NestedCall ), L = [Prelude|T]. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% propagation_nested_code([],[CurrentHead|PreHeads],Rule,RuleNb,RestHeadNb,FA,_,_Constraints,Mod,Id,L,T) :- propagation_end([CurrentHead|PreHeads],[],Rule,FA,Id,L,L1), propagation_body(CurrentHead,PreHeads,Rule,RuleNb,RestHeadNb,FA,Mod,Id,L1,T). propagation_nested_code([Head|RestHeads],PreHeads,Rule,RuleNb,RestHeadNb,FA,N,Constraints,Mod,Id,L,T) :- propagation_end(PreHeads,[Head|RestHeads],Rule,FA,Id,L,L1), propagation_accumulator([Head|RestHeads],PreHeads,Rule,FA,N,Constraints,Mod,Id,L1,L2), inc_id(Id,IncId), propagation_nested_code(RestHeads,[Head|PreHeads],Rule,RuleNb,RestHeadNb,FA,N,Constraints,Mod,IncId,L2,T). propagation_body(CurrentHead,PreHeads,Rule,RuleNb,RestHeadNb,F/A,Mod,Id,L,T) :- Rule = rule(_,_,Guard,Body), get_prop_inner_loop_vars(PreHeads,[CurrentHead,Guard,Body],PreVarsAndSusps,VarDict1,Susp,RestSusps), gen_var(OtherSusp), gen_var(OtherSusps), functor(CurrentHead,_OtherF,OtherA), gen_vars(OtherA,OtherVars), Suspension =.. [suspension,_,State,_,_,_,_|OtherVars], create_get_mutable_ref(active,State,GetMutable), CurrentSuspTest = ( OtherSusp = Suspension, GetMutable ), ClauseVars = [[OtherSusp|OtherSusps]|PreVarsAndSusps], build_head(F,A,Id,ClauseVars,ClauseHead), RecursiveVars = [OtherSusps|PreVarsAndSusps], build_head(F,A,Id,RecursiveVars,RecursiveHead), RecursiveCall = RecursiveHead, CurrentHead =.. [_|OtherArgs], pairup(OtherArgs,OtherVars,OtherPairs), head_arg_matches(OtherPairs,VarDict1,Matching,VarDict), different_from_other_susps(CurrentHead,OtherSusp,PreHeads,RestSusps,DiffSuspGoals), guard_body_copies(Rule,VarDict,GuardCopy,BodyCopy), gen_uncond_attach_goal(F/A,Susp,Mod,Attach,Generation), gen_state_cond_call(Susp,A,RecursiveCall,Generation,ConditionalRecursiveCall), history_susps(RestHeadNb,[OtherSusp|RestSusps],Susp,[],HistorySusps), bagof('chr novel_production'(X,Y),( member(X,HistorySusps), Y = TupleVar) ,NovelProductionsList), list2conj(NovelProductionsList,NovelProductions), Tuple =.. [t,RuleNb|HistorySusps], Clause = ( ClauseHead :- ( CurrentSuspTest, DiffSuspGoals, Matching, TupleVar = Tuple, NovelProductions, GuardCopy -> 'chr extend_history'(Susp,TupleVar), Attach, BodyCopy, ConditionalRecursiveCall ; RecursiveCall ) ), L = [Clause|T]. history_susps(Count,OtherSusps,Susp,Acc,HistorySusps) :- ( Count == 0 -> reverse(OtherSusps,ReversedSusps), append(ReversedSusps,[Susp|Acc],HistorySusps) ; OtherSusps = [OtherSusp|RestOtherSusps], NCount is Count - 1, history_susps(NCount,RestOtherSusps,Susp,[OtherSusp|Acc],HistorySusps) ). get_prop_inner_loop_vars([Head],Terms,HeadVars,VarDict,Susp,[]) :- !, functor(Head,_F,A), head_info(Head,A,_Vars,Susp,VarsSusp,Pairs), head_arg_matches(Pairs,[],_,VarDict), extra_active_delegate_variables(Head,Terms,VarDict,ExtraVars), append(VarsSusp,ExtraVars,HeadVars). get_prop_inner_loop_vars([Head|Heads],Terms,VarsSusps,NVarDict,MainSusp,[Susp|RestSusps]) :- get_prop_inner_loop_vars(Heads,[Head|Terms],RestVarsSusp,VarDict,MainSusp,RestSusps), functor(Head,_F,A), gen_var(Susps), head_info(Head,A,_Vars,Susp,_VarsSusp,Pairs), head_arg_matches(Pairs,VarDict,_,NVarDict), passive_delegate_variables(Head,Heads,Terms,NVarDict,HeadVars), append(HeadVars,[Susp,Susps|RestVarsSusp],VarsSusps). propagation_end([CurrentHead|PrevHeads],NextHeads,Rule,F/A,Id,L,T) :- Rule = rule(_,_,Guard,Body), gen_var_susp_list_for(PrevHeads,[CurrentHead,NextHeads,Guard,Body],_,VarsAndSusps,AllButFirst,FirstSusp), Vars = [ [] | VarsAndSusps], build_head(F,A,Id,Vars,Head), ( Id = [0|_] -> next_id(Id,PrevId), PrevVarsAndSusps = AllButFirst ; dec_id(Id,PrevId), PrevVarsAndSusps = [FirstSusp|AllButFirst] ), build_head(F,A,PrevId,PrevVarsAndSusps,PrevHead), PredecessorCall = PrevHead, Clause = ( Head :- PredecessorCall ), L = [Clause | T]. gen_var_susp_list_for([Head],Terms,VarDict,HeadVars,VarsSusp,Susp) :- !, functor(Head,_F,A), head_info(Head,A,_Vars,Susp,VarsSusp,HeadPairs), head_arg_matches(HeadPairs,[],_,VarDict), extra_active_delegate_variables(Head,Terms,VarDict,ExtraVars), append(VarsSusp,ExtraVars,HeadVars). gen_var_susp_list_for([Head|Heads],Terms,NVarDict,VarsSusps,Rest,Susps) :- gen_var_susp_list_for(Heads,[Head|Terms],VarDict,Rest,_,_), functor(Head,_F,A), gen_var(Susps), head_info(Head,A,_Vars,Susp,_VarsSusp,HeadPairs), head_arg_matches(HeadPairs,VarDict,_,NVarDict), passive_delegate_variables(Head,Heads,Terms,NVarDict,HeadVars), append(HeadVars,[Susp,Susps|Rest],VarsSusps). propagation_accumulator([NextHead|RestHeads],[CurrentHead|PreHeads],Rule,F/A,N,Constraints,Mod,Id,L,T) :- Rule = rule(_,_,Guard,Body), pre_vars_and_susps(PreHeads,[CurrentHead,NextHead,RestHeads,Guard,Body],PreVarsAndSusps,VarDict,PreSusps), gen_var(OtherSusps), functor(CurrentHead,_OtherF,OtherA), gen_vars(OtherA,OtherVars), head_info(CurrentHead,OtherA,OtherVars,OtherSusp,_VarsSusp,HeadPairs), head_arg_matches(HeadPairs,VarDict,FirstMatching,VarDict1), OtherSuspension =.. [suspension,_,State,_,_,_,_|OtherVars], different_from_other_susps(CurrentHead,OtherSusp,PreHeads,PreSusps,DiffSuspGoals), create_get_mutable_ref(active,State,GetMutable), CurrentSuspTest = ( OtherSusp = OtherSuspension, GetMutable, DiffSuspGoals, FirstMatching ), functor(NextHead,NextF,NextA), passive_head_via(NextHead,[CurrentHead|PreHeads],[],Constraints,Mod,VarDict1,NextSuspGoal,Attr,AttrDict), instantiate_pattern_goals(AttrDict,N), ( N == 1 -> NextSusps = Attr ; nth(Position,Constraints,NextF/NextA), !, make_attr(N,_Mask,SuspsList,Attr), nth(Position,SuspsList,NextSusps) ), inc_id(Id,NestedId), ClauseVars = [[OtherSusp|OtherSusps]|PreVarsAndSusps], build_head(F,A,Id,ClauseVars,ClauseHead), passive_delegate_variables(CurrentHead,PreHeads,[NextHead,RestHeads,Guard,Body],VarDict1,CurrentHeadVars), append([NextSusps|CurrentHeadVars],[OtherSusp,OtherSusps|PreVarsAndSusps],NestedVars), build_head(F,A,NestedId,NestedVars,NestedHead), RecursiveVars = [OtherSusps|PreVarsAndSusps], build_head(F,A,Id,RecursiveVars,RecursiveHead), Clause = ( ClauseHead :- ( CurrentSuspTest, NextSuspGoal -> NestedHead ; RecursiveHead ) ), L = [Clause|T]. pre_vars_and_susps([Head],Terms,HeadVars,VarDict,[]) :- !, functor(Head,_F,A), head_info(Head,A,_Vars,_Susp,VarsSusp,HeadPairs), head_arg_matches(HeadPairs,[],_,VarDict), extra_active_delegate_variables(Head,Terms,VarDict,ExtraVars), append(VarsSusp,ExtraVars,HeadVars). pre_vars_and_susps([Head|Heads],Terms,NVSs,NVarDict,[Susp|Susps]) :- pre_vars_and_susps(Heads,[Head|Terms],VSs,VarDict,Susps), functor(Head,_F,A), gen_var(NextSusps), head_info(Head,A,_Vars,Susp,_VarsSusp,HeadPairs), head_arg_matches(HeadPairs,VarDict,_,NVarDict), passive_delegate_variables(Head,Heads,Terms,NVarDict,HeadVars), append(HeadVars,[Susp,NextSusps|VSs],NVSs). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% ____ _ _ _ _ %% | _ \ __ _ ___ ___(_)_ _____ | | | | ___ __ _ __| | %% | |_) / _` / __/ __| \ \ / / _ \ | |_| |/ _ \/ _` |/ _` | %% | __/ (_| \__ \__ \ |\ V / __/ | _ | __/ (_| | (_| | %% |_| \__,_|___/___/_| \_/ \___| |_| |_|\___|\__,_|\__,_| %% %% ____ _ _ _ %% | _ \ ___| |_ _ __(_) _____ ____ _| | %% | |_) / _ \ __| '__| |/ _ \ \ / / _` | | %% | _ < __/ |_| | | | __/\ V / (_| | | %% |_| \_\___|\__|_| |_|\___| \_/ \__,_|_| %% %% ____ _ _ %% | _ \ ___ ___ _ __ __| | ___ _ __(_)_ __ __ _ %% | |_) / _ \/ _ \| '__/ _` |/ _ \ '__| | '_ \ / _` | %% | _ < __/ (_) | | | (_| | __/ | | | | | | (_| | %% |_| \_\___|\___/|_| \__,_|\___|_| |_|_| |_|\__, | %% |___/ reorder_heads(Head,RestHeads,RestIDs,NRestHeads,NRestIDs) :- ( chr_pp_flag(reorder_heads,on) -> reorder_heads_main(Head,RestHeads,RestIDs,NRestHeads,NRestIDs) ; NRestHeads = RestHeads, NRestIDs = RestIDs ). reorder_heads_main(Head,RestHeads,RestIDs,NRestHeads,NRestIDs) :- term_variables(Head,KnownVars), reorder_heads1(RestHeads,RestIDs,KnownVars,NRestHeads,NRestIDs). reorder_heads1(Heads,IDs,KnownVars,NHeads,NIDs) :- ( Heads == [] -> NHeads = [], NIDs = [] ; NHeads = [BestHead|BestTail], NIDs = [BestID | BestIDs], select_best_head(Heads,IDs,KnownVars,BestHead,BestID,RestHeads,RestIDs,NKnownVars), reorder_heads1(RestHeads,RestIDs,NKnownVars,BestTail,BestIDs) ). select_best_head(Heads,IDs,KnownVars,BestHead,BestID,RestHeads,RestIDs,NKnownVars) :- ( bagof(tuple(Score,Head,ID,Rest,RIDs), ( select2(Head,ID, Heads,IDs,Rest,RIDs) , order_score(Head,KnownVars,Rest,Score) ), Scores) -> true ; Scores = []), max_go_list(Scores,tuple(_,BestHead,BestID,RestHeads,RestIDs)), term_variables(BestHead,BestHeadVars), ( setof(V, ( member(V,BestHeadVars), \+ memberchk_eq(V,KnownVars) ), NewVars) -> true ; NewVars = []), append(NewVars,KnownVars,NKnownVars). reorder_heads(Head,RestHeads,NRestHeads) :- term_variables(Head,KnownVars), reorder_heads1(RestHeads,KnownVars,NRestHeads). reorder_heads1(Heads,KnownVars,NHeads) :- ( Heads == [] -> NHeads = [] ; NHeads = [BestHead|BestTail], select_best_head(Heads,KnownVars,BestHead,RestHeads,NKnownVars), reorder_heads1(RestHeads,NKnownVars,BestTail) ). select_best_head(Heads,KnownVars,BestHead,RestHeads,NKnownVars) :- ( bagof(tuple(Score,Head,Rest), ( select(Head,Heads,Rest) , order_score(Head,KnownVars,Rest,Score) ), Scores) -> true ; Scores = []), max_go_list(Scores,tuple(_,BestHead,RestHeads)), term_variables(BestHead,BestHeadVars), ( setof(V, ( member(V,BestHeadVars), \+ memberchk_eq(V,KnownVars) ), NewVars) -> true ; NewVars = []), append(NewVars,KnownVars,NKnownVars). order_score(Head,KnownVars,Rest,Score) :- term_variables(Head,HeadVars), term_variables(Rest,RestVars), order_score_vars(HeadVars,KnownVars,RestVars,0,Score). order_score_vars([],_,_,Score,NScore) :- ( Score == 0 -> NScore = 99999 ; NScore = Score ). order_score_vars([V|Vs],KnownVars,RestVars,Score,NScore) :- ( memberchk_eq(V,KnownVars) -> TScore is Score + 1 ; memberchk_eq(V,RestVars) -> TScore is Score + 1 ; TScore = Score ), order_score_vars(Vs,KnownVars,RestVars,TScore,NScore). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% ___ _ _ _ %% |_ _|_ __ | (_)_ __ (_)_ __ __ _ %% | || '_ \| | | '_ \| | '_ \ / _` | %% | || | | | | | | | | | | | | (_| | %% |___|_| |_|_|_|_| |_|_|_| |_|\__, | %% |___/ %% SWI begin create_get_mutable_ref(V,M,GM) :- GM = (M = mutable(V)). %% SWI end %% SICStus begin %% create_get_mutable_ref(V,M,GM) :- GM = (get_mutable(V,M)). %% SICStus end %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% ____ _ ____ _ _ %% / ___|___ __| | ___ / ___| | ___ __ _ _ __ (_)_ __ __ _ %% | | / _ \ / _` |/ _ \ | | | |/ _ \/ _` | '_ \| | '_ \ / _` | %% | |__| (_) | (_| | __/ | |___| | __/ (_| | | | | | | | | (_| | %% \____\___/ \__,_|\___| \____|_|\___|\__,_|_| |_|_|_| |_|\__, | %% |___/ %% %% removes redundant 'true's and other trivial but potentially non-free constructs clean_clauses([],[]). clean_clauses([C|Cs],[NC|NCs]) :- clean_clause(C,NC), clean_clauses(Cs,NCs). clean_clause(Clause,NClause) :- ( Clause = (Head :- Body) -> clean_goal(Body,NBody), ( NBody == true -> NClause = Head ; NClause = (Head :- NBody) ) ; NClause = Clause ). clean_goal(Goal,NGoal) :- var(Goal), !, NGoal = Goal. clean_goal((G1,G2),NGoal) :- !, clean_goal(G1,NG1), clean_goal(G2,NG2), ( NG1 == true -> NGoal = NG2 ; NG2 == true -> NGoal = NG1 ; NGoal = (NG1,NG2) ). clean_goal((If -> Then ; Else),NGoal) :- !, clean_goal(If,NIf), ( NIf == true -> clean_goal(Then,NThen), NGoal = NThen ; NIf == fail -> clean_goal(Else,NElse), NGoal = NElse ; clean_goal(Then,NThen), clean_goal(Else,NElse), NGoal = (NIf -> NThen; NElse) ). clean_goal((G1 ; G2),NGoal) :- !, clean_goal(G1,NG1), clean_goal(G2,NG2), ( NG1 == fail -> NGoal = NG2 ; NG2 == fail -> NGoal = NG1 ; NGoal = (NG1 ; NG2) ). clean_goal(once(G),NGoal) :- !, clean_goal(G,NG), ( NG == true -> NGoal = true ; NG == fail -> NGoal = fail ; NGoal = once(NG) ). clean_goal((G1 -> G2),NGoal) :- !, clean_goal(G1,NG1), ( NG1 == true -> clean_goal(G2,NGoal) ; NG1 == fail -> NGoal = fail ; clean_goal(G2,NG2), NGoal = (NG1 -> NG2) ). clean_goal(Goal,Goal). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% _ _ _ _ _ _ _ %% | | | | |_(_) (_) |_ _ _ %% | | | | __| | | | __| | | | %% | |_| | |_| | | | |_| |_| | %% \___/ \__|_|_|_|\__|\__, | %% |___/ gen_var(_). gen_vars(N,Xs) :- length(Xs,N). head_info(Head,A,Vars,Susp,VarsSusp,HeadPairs) :- vars_susp(A,Vars,Susp,VarsSusp), Head =.. [_|Args], pairup(Args,Vars,HeadPairs). inc_id([N|Ns],[O|Ns]) :- O is N + 1. dec_id([N|Ns],[M|Ns]) :- M is N - 1. extend_id(Id,[0|Id]). next_id([_,N|Ns],[O|Ns]) :- O is N + 1. build_head(F,A,Id,Args,Head) :- buildName(F,A,Id,Name), Head =.. [Name|Args]. buildName(Fct,Aty,List,Result) :- atom_concat(Fct, (/) ,FctSlash), atomic_concat(FctSlash,Aty,FctSlashAty), buildName_(List,FctSlashAty,Result). buildName_([],Name,Name). buildName_([N|Ns],Name,Result) :- buildName_(Ns,Name,Name1), atom_concat(Name1,'__',NameDash), % '_' is a char :-( atomic_concat(NameDash,N,Result). vars_susp(A,Vars,Susp,VarsSusp) :- length(Vars,A), append(Vars,[Susp],VarsSusp). make_attr(N,Mask,SuspsList,Attr) :- length(SuspsList,N), Attr =.. [v,Mask|SuspsList]. or_pattern(Pos,Pat) :- Pow is Pos - 1, Pat is 1 << Pow. % was 2 ** X and_pattern(Pos,Pat) :- X is Pos - 1, Y is 1 << X, % was 2 ** X Pat is -(Y + 1). conj2list(Conj,L) :- %% transform conjunctions to list conj2list(Conj,L,[]). conj2list(Conj,L,T) :- Conj = (G1,G2), !, conj2list(G1,L,T1), conj2list(G2,T1,T). conj2list(G,[G | T],T). list2conj([],true). list2conj([G],X) :- !, X = G. list2conj([G|Gs],C) :- ( G == true -> %% remove some redundant trues list2conj(Gs,C) ; C = (G,R), list2conj(Gs,R) ). atom_concat_list([X],X) :- ! . atom_concat_list([X|Xs],A) :- atom_concat_list(Xs,B), atomic_concat(X,B,A). atomic_concat(A,B,C) :- make_atom(A,AA), make_atom(B,BB), atom_concat(AA,BB,C). make_atom(A,AA) :- ( atom(A) -> AA = A ; number(A) -> number_codes(A,AL), atom_codes(AA,AL) ). set_elems([],_). set_elems([X|Xs],X) :- set_elems(Xs,X). member2([X|_],[Y|_],X-Y). member2([_|Xs],[_|Ys],P) :- member2(Xs,Ys,P). select2(X, Y, [X|Xs], [Y|Ys], Xs, Ys). select2(X, Y, [X1|Xs], [Y1|Ys], [X1|NXs], [Y1|NYs]) :- select2(X, Y, Xs, Ys, NXs, NYs). pair_all_with([],_,[]). pair_all_with([X|Xs],Y,[X-Y|Rest]) :- pair_all_with(Xs,Y,Rest). default(X,Def) :- ( var(X) -> X = Def ; true). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% SWI begin verbosity_on :- prolog_flag(verbose,V), V == yes. %% SWI end %% SICStus begin %% verbosity_on. % at the moment %% SICStus end