/* Part of SWI-Prolog Author: Jan Wielemaker E-mail: J.Wielemaker@vu.nl WWW: http://www.swi-prolog.org Copyright (c) 2009-2024, University of Amsterdam VU University Amsterdam CWI, Amsterdam SWI-Prolog Solutions b.v. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ :- module('$expand', [ expand_term/2, % +Term0, -Term expand_goal/2, % +Goal0, -Goal expand_term/4, % +Term0, ?Pos0, -Term, -Pos expand_goal/4, % +Goal0, ?Pos0, -Goal, -Pos var_property/2, % +Var, ?Property '$including'/0, '$expand_closure'/3 % +GoalIn, +Extra, -GoalOut ]). /** Prolog source-code transformation This module specifies, together with dcg.pl, the transformation of terms as they are read from a file before they are processed by the compiler. The toplevel is expand_term/2. This uses three other translators: * Conditional compilation * term_expansion/2 rules provided by the user * DCG expansion Note that this ordering implies that conditional compilation directives cannot be generated by term_expansion/2 rules: they must literally appear in the source-code. Term-expansion may choose to overrule DCG expansion. If the result of term-expansion is a DCG rule, the rule is subject to translation into a predicate. Next, the result is passed to expand_bodies/2, which performs goal expansion. */ :- dynamic system:term_expansion/2, system:goal_expansion/2, user:term_expansion/2, user:goal_expansion/2, system:term_expansion/4, system:goal_expansion/4, user:term_expansion/4, user:goal_expansion/4. :- multifile system:term_expansion/2, system:goal_expansion/2, user:term_expansion/2, user:goal_expansion/2, system:term_expansion/4, system:goal_expansion/4, user:term_expansion/4, user:goal_expansion/4. :- '$notransact'((system:term_expansion/2, system:goal_expansion/2, user:term_expansion/2, user:goal_expansion/2, system:term_expansion/4, system:goal_expansion/4, user:term_expansion/4, user:goal_expansion/4)). :- meta_predicate expand_terms(4, +, ?, -, -). %! expand_term(+Input, -Output) is det. %! expand_term(+Input, +Pos0, -Output, -Pos) is det. % % This predicate is used to translate terms as they are read from % a source-file before they are added to the Prolog database. expand_term(Term0, Term) :- expand_term(Term0, _, Term, _). expand_term(Var, Pos, Expanded, Pos) :- var(Var), !, Expanded = Var. expand_term(Term, Pos0, [], Pos) :- cond_compilation(Term, X), X == [], !, atomic_pos(Pos0, Pos). expand_term(Term, Pos0, Expanded, Pos) :- setup_call_cleanup( '$push_input_context'(expand_term), expand_term_keep_source_loc(Term, Pos0, Expanded, Pos), '$pop_input_context'). expand_term_keep_source_loc(Term, Pos0, Expanded, Pos) :- b_setval('$term', Term), prepare_directive(Term), '$def_modules'([term_expansion/4,term_expansion/2], MList), call_term_expansion(MList, Term, Pos0, Term1, Pos1), expand_terms(expand_term_2, Term1, Pos1, Expanded, Pos), b_setval('$term', []). %! prepare_directive(+Directive) is det. % % Try to autoload goals associated with a directive such that we can % allow for term expansion of autoloaded directives such as setting/4. % Trying to do so shall raise no errors nor fail as the directive may % be further expanded. prepare_directive((:- Directive)) :- '$current_source_module'(M), prepare_directive(Directive, M), !. prepare_directive(_). prepare_directive(Goal, _) :- \+ callable(Goal), !. prepare_directive((A,B), Module) :- !, prepare_directive(A, Module), prepare_directive(B, Module). prepare_directive(module(_,_), _) :- !. prepare_directive(Goal, Module) :- '$get_predicate_attribute'(Module:Goal, defined, 1), !. prepare_directive(Goal, Module) :- \+ current_prolog_flag(autoload, false), ( compound(Goal) -> compound_name_arity(Goal, Name, Arity) ; Name = Goal, Arity = 0 ), '$autoload'(Module:Name/Arity), !. prepare_directive(_, _). call_term_expansion([], Term, Pos, Term, Pos). call_term_expansion([M-Preds|T], Term0, Pos0, Term, Pos) :- current_prolog_flag(sandboxed_load, false), !, ( '$member'(Pred, Preds), ( Pred == term_expansion/2 -> M:term_expansion(Term0, Term1), Pos1 = Pos0 ; M:term_expansion(Term0, Pos0, Term1, Pos1) ) -> expand_terms(call_term_expansion(T), Term1, Pos1, Term, Pos) ; call_term_expansion(T, Term0, Pos0, Term, Pos) ). call_term_expansion([M-Preds|T], Term0, Pos0, Term, Pos) :- ( '$member'(Pred, Preds), ( Pred == term_expansion/2 -> allowed_expansion(M:term_expansion(Term0, Term1)), call(M:term_expansion(Term0, Term1)), Pos1 = Pos ; allowed_expansion(M:term_expansion(Term0, Pos0, Term1, Pos1)), call(M:term_expansion(Term0, Pos0, Term1, Pos1)) ) -> expand_terms(call_term_expansion(T), Term1, Pos1, Term, Pos) ; call_term_expansion(T, Term0, Pos0, Term, Pos) ). expand_term_2(DCGRule, Pos0, Expanded, Pos) :- is_dcg(DCGRule), dcg_translate_rule(DCGRule, Pos0, Expanded0, Pos1), !, expand_bodies(Expanded0, Pos1, Expanded1, Pos), non_terminal_decl(Expanded1, Expanded). expand_term_2(Term0, Pos0, Term, Pos) :- nonvar(Term0), !, expand_bodies(Term0, Pos0, Term, Pos). expand_term_2(Term, Pos, Term, Pos). is_dcg(_-->_) => true. is_dcg(_==>_) => true. is_dcg(_) => fail. non_terminal_decl(Clause, Decl) :- \+ current_prolog_flag(xref, true), clause_head(Clause, Head), '$current_source_module'(M), ( '$get_predicate_attribute'(M:Head, non_terminal, NT) -> NT == 0 ; true ), !, '$pi_head'(PI, Head), Decl = [:-(non_terminal(M:PI)), Clause]. non_terminal_decl(Clause, Clause). clause_head(Head:-_, Head) :- !. clause_head((Head,_=>_), Head) :- !. clause_head(Head=>_, Head) :- !. clause_head(Head, Head). %! expand_bodies(+Term, +Pos0, -Out, -Pos) is det. % % Find the body terms in Term and give them to expand_goal/2 for % further processing. Note that we maintain status information % about variables. Currently we only detect whether variables are % _fresh_ or not. See var_info/3. expand_bodies(Terms, Pos0, Out, Pos) :- '$def_modules'([goal_expansion/4,goal_expansion/2], MList), expand_terms(expand_body(MList), Terms, Pos0, Out, Pos), remove_attributes(Out, '$var_info'). expand_body(MList, Clause0, Pos0, Clause, Pos) :- clause_head_body(Clause0, Left0, Neck, Body0), !, clause_head_body(Clause, Left, Neck, Body), f2_pos(Pos0, LPos0, BPos0, Pos, LPos, BPos), ( head_guard(Left0, Neck, Head0, Guard0) -> f2_pos(LPos0, HPos, GPos0, LPos, HPos, GPos), mark_head_variables(Head0), expand_goal(Guard0, GPos0, Guard, GPos, MList, Clause0), Left = (Head,Guard) ; LPos = LPos0, Head0 = Left0, Left = Head, mark_head_variables(Head0) ), expand_goal(Body0, BPos0, Body1, BPos, MList, Clause0), expand_head_functions(Head0, Head, Body1, Body). expand_body(MList, (:- Body), Pos0, (:- ExpandedBody), Pos) :- !, f1_pos(Pos0, BPos0, Pos, BPos), expand_goal(Body, BPos0, ExpandedBody, BPos, MList, (:- Body)). clause_head_body((Head :- Body), Head, :-, Body). clause_head_body((Head => Body), Head, =>, Body). clause_head_body(?=>(Head, Body), Head, ?=>, Body). head_guard(Left, Neck, Head, Guard) :- nonvar(Left), Left = (Head,Guard), ( Neck == (=>) -> true ; Neck == (?=>) ). mark_head_variables(Head) :- term_variables(Head, HVars), mark_vars_non_fresh(HVars). expand_head_functions(Head0, Head, Body0, Body) :- compound(Head0), '$current_source_module'(M), replace_functions(Head0, Eval, Head, M), Eval \== true, !, Body = (Eval,Body0). expand_head_functions(Head, Head, Body, Body). expand_body(_MList, Head0, Pos, Clause, Pos) :- % TBD: Position handling compound(Head0), '$current_source_module'(M), replace_functions(Head0, Eval, Head, M), Eval \== true, !, Clause = (Head :- Eval). expand_body(_, Head, Pos, Head, Pos). %! expand_terms(:Closure, +In, +Pos0, -Out, -Pos) % % Loop over two constructs that can be added by term-expansion % rules in order to run the next phase: calling term_expansion/2 % can return a list and terms may be preceded with a % source-location. expand_terms(_, X, P, X, P) :- var(X), !. expand_terms(C, List0, Pos0, List, Pos) :- nonvar(List0), List0 = [_|_], !, ( is_list(List0) -> list_pos(Pos0, Elems0, Pos, Elems), expand_term_list(C, List0, Elems0, List, Elems) ; '$type_error'(list, List0) ). expand_terms(C, '$source_location'(File, Line):Clause0, Pos0, Clause, Pos) :- !, expand_terms(C, Clause0, Pos0, Clause1, Pos), add_source_location(Clause1, '$source_location'(File, Line), Clause). expand_terms(C, Term0, Pos0, Term, Pos) :- call(C, Term0, Pos0, Term, Pos). %! add_source_location(+Term, +SrcLoc, -SrcTerm) % % Re-apply source location after term expansion. If the result is % a list, claim all terms to originate from this location. add_source_location(Clauses0, SrcLoc, Clauses) :- ( is_list(Clauses0) -> add_source_location_list(Clauses0, SrcLoc, Clauses) ; Clauses = SrcLoc:Clauses0 ). add_source_location_list([], _, []). add_source_location_list([Clause|Clauses0], SrcLoc, [SrcLoc:Clause|Clauses]) :- add_source_location_list(Clauses0, SrcLoc, Clauses). %! expand_term_list(:Expander, +TermList, +Pos, -NewTermList, -PosList) expand_term_list(_, [], _, [], []) :- !. expand_term_list(C, [H0|T0], [PH0], Terms, PosL) :- !, expand_terms(C, H0, PH0, H, PH), add_term(H, PH, Terms, TT, PosL, PT), expand_term_list(C, T0, [PH0], TT, PT). expand_term_list(C, [H0|T0], [PH0|PT0], Terms, PosL) :- !, expand_terms(C, H0, PH0, H, PH), add_term(H, PH, Terms, TT, PosL, PT), expand_term_list(C, T0, PT0, TT, PT). expand_term_list(C, [H0|T0], PH0, Terms, PosL) :- expected_layout(list, PH0), expand_terms(C, H0, PH0, H, PH), add_term(H, PH, Terms, TT, PosL, PT), expand_term_list(C, T0, [PH0], TT, PT). %! add_term(+ExpandOut, ?ExpandPosOut, -Terms, ?TermsT, -PosL, ?PosLT) add_term(List, Pos, Terms, TermT, PosL, PosT) :- nonvar(List), List = [_|_], !, ( is_list(List) -> append_tp(List, Terms, TermT, Pos, PosL, PosT) ; '$type_error'(list, List) ). add_term(Term, Pos, [Term|Terms], Terms, [Pos|PosT], PosT). append_tp([], Terms, Terms, _, PosL, PosL). append_tp([H|T0], [H|T1], Terms, [HP], [HP|TP1], PosL) :- !, append_tp(T0, T1, Terms, [HP], TP1, PosL). append_tp([H|T0], [H|T1], Terms, [HP0|TP0], [HP0|TP1], PosL) :- !, append_tp(T0, T1, Terms, TP0, TP1, PosL). append_tp([H|T0], [H|T1], Terms, Pos, [Pos|TP1], PosL) :- expected_layout(list, Pos), append_tp(T0, T1, Terms, [Pos], TP1, PosL). list_pos(Var, _, _, _) :- var(Var), !. list_pos(list_position(F,T,Elems0,none), Elems0, list_position(F,T,Elems,none), Elems) :- !. list_pos(Pos, [Pos], Elems, Elems). /******************************* * VAR_INFO/3 SUPPORT * *******************************/ %! var_intersection(+List1, +List2, -Shared) is det. % % Shared is the ordered intersection of List1 and List2. var_intersection(List1, List2, Intersection) :- sort(List1, Set1), sort(List2, Set2), ord_intersection(Set1, Set2, Intersection). %! ord_intersection(+OSet1, +OSet2, -Int) % % Ordered list intersection. Copied from the library. ord_intersection([], _Int, []). ord_intersection([H1|T1], L2, Int) :- isect2(L2, H1, T1, Int). isect2([], _H1, _T1, []). isect2([H2|T2], H1, T1, Int) :- compare(Order, H1, H2), isect3(Order, H1, T1, H2, T2, Int). isect3(<, _H1, T1, H2, T2, Int) :- isect2(T1, H2, T2, Int). isect3(=, H1, T1, _H2, T2, [H1|Int]) :- ord_intersection(T1, T2, Int). isect3(>, H1, T1, _H2, T2, Int) :- isect2(T2, H1, T1, Int). %! ord_subtract(+Set, +Subtract, -Diff) ord_subtract([], _Not, []). ord_subtract(S1, S2, Diff) :- S1 == S2, !, Diff = []. ord_subtract([H1|T1], L2, Diff) :- diff21(L2, H1, T1, Diff). diff21([], H1, T1, [H1|T1]). diff21([H2|T2], H1, T1, Diff) :- compare(Order, H1, H2), diff3(Order, H1, T1, H2, T2, Diff). diff12([], _H2, _T2, []). diff12([H1|T1], H2, T2, Diff) :- compare(Order, H1, H2), diff3(Order, H1, T1, H2, T2, Diff). diff3(<, H1, T1, H2, T2, [H1|Diff]) :- diff12(T1, H2, T2, Diff). diff3(=, _H1, T1, _H2, T2, Diff) :- ord_subtract(T1, T2, Diff). diff3(>, H1, T1, _H2, T2, Diff) :- diff21(T2, H1, T1, Diff). %! merge_variable_info(+Saved) % % Merge info from two branches. The info in Saved is the saved % info from the first branch, while the info in the actual % variables is the info in the second branch. Only if both % branches claim the variable to be fresh, we can consider it % fresh. merge_variable_info(State) :- catch(merge_variable_info_(State), error(uninstantiation_error(Term),_), throw(error(goal_expansion_error(bound, Term), _))). merge_variable_info_([]). merge_variable_info_([Var=State|States]) :- ( get_attr(Var, '$var_info', CurrentState) -> true ; CurrentState = (-) ), merge_states(Var, State, CurrentState), merge_variable_info_(States). merge_states(_Var, State, State) :- !. merge_states(_Var, -, _) :- !. merge_states(Var, State, -) :- !, put_attr(Var, '$var_info', State). merge_states(Var, Left, Right) :- ( get_dict(fresh, Left, false) -> put_dict(fresh, Right, false) ; get_dict(fresh, Right, false) -> put_dict(fresh, Left, false) ), !, ( Left >:< Right -> put_dict(Left, Right, State), put_attr(Var, '$var_info', State) ; print_message(warning, inconsistent_variable_properties(Left, Right)), put_dict(Left, Right, State), put_attr(Var, '$var_info', State) ). save_variable_info([], []). save_variable_info([Var|Vars], [Var=State|States]):- ( get_attr(Var, '$var_info', State) -> true ; State = (-) ), save_variable_info(Vars, States). restore_variable_info(State) :- catch(restore_variable_info_(State), error(uninstantiation_error(Term),_), throw(error(goal_expansion_error(bound, Term), _))). restore_variable_info_([]). restore_variable_info_([Var=State|States]) :- ( State == (-) -> del_attr(Var, '$var_info') ; put_attr(Var, '$var_info', State) ), restore_variable_info_(States). %! var_property(+Var, ?Property) % % True when Var has a property Key with Value. Defined properties % are: % % - fresh(Fresh) % Variable is first introduced in this goal and thus guaranteed % to be unbound. This property is always present. % - singleton(Bool) % It `true` indicate that the variable appears once in the source. % Note this doesn't mean it is a semantic singleton. % - name(-Name) % True when Name is the name of the variable. var_property(Var, Property) :- prop_var(Property, Var). prop_var(fresh(Fresh), Var) :- ( get_attr(Var, '$var_info', Info), get_dict(fresh, Info, Fresh0) -> Fresh = Fresh0 ; Fresh = true ). prop_var(singleton(Singleton), Var) :- nb_current('$term', Term), term_singletons(Term, Singletons), ( '$member'(V, Singletons), V == Var -> Singleton = true ; Singleton = false ). prop_var(name(Name), Var) :- ( nb_current('$variable_names', Bindings), '$member'(Name0=Var0, Bindings), Var0 == Var -> Name = Name0 ). mark_vars_non_fresh([]) :- !. mark_vars_non_fresh([Var|Vars]) :- ( get_attr(Var, '$var_info', Info) -> ( get_dict(fresh, Info, false) -> true ; put_dict(fresh, Info, false, Info1), put_attr(Var, '$var_info', Info1) ) ; put_attr(Var, '$var_info', '$var_info'{fresh:false}) ), mark_vars_non_fresh(Vars). %! remove_attributes(+Term, +Attribute) is det. % % Remove all variable attributes Attribute from Term. This is used % to make term_expansion end with a clean term. This is currently % _required_ for saving directives in QLF files. The compiler % ignores attributes, but I think it is cleaner to remove them % anyway. remove_attributes(Term, Attr) :- term_variables(Term, Vars), remove_var_attr(Vars, Attr). remove_var_attr([], _):- !. remove_var_attr([Var|Vars], Attr):- del_attr(Var, Attr), remove_var_attr(Vars, Attr). %! '$var_info':attr_unify_hook(_,_) is det. % % Dummy unification hook for attributed variables. Just succeeds. '$var_info':attr_unify_hook(_, _). /******************************* * GOAL_EXPANSION/2 SUPPORT * *******************************/ %! expand_goal(+BodyTerm, +Pos0, -Out, -Pos) is det. %! expand_goal(+BodyTerm, -Out) is det. % % Perform macro-expansion on body terms by calling % goal_expansion/2. expand_goal(A, B) :- expand_goal(A, _, B, _). expand_goal(A, P0, B, P) :- '$def_modules'([goal_expansion/4, goal_expansion/2], MList), ( expand_goal(A, P0, B, P, MList, _) -> remove_attributes(B, '$var_info'), A \== B ), !. expand_goal(A, P, A, P). %! '$expand_closure'(+BodyIn, +ExtraArgs, -BodyOut) is semidet. %! '$expand_closure'(+BodyIn, +PIn, +ExtraArgs, -BodyOut, -POut) is semidet. % % Expand a closure using goal expansion for some extra arguments. % Note that the extra argument must remain at the end. If this is % not the case, '$expand_closure'/3,5 fail. '$expand_closure'(G0, N, G) :- '$expand_closure'(G0, _, N, G, _). '$expand_closure'(G0, P0, N, G, P) :- length(Ex, N), mark_vars_non_fresh(Ex), extend_arg_pos(G0, P0, Ex, G1, P1), expand_goal(G1, P1, G2, P2), term_variables(G0, VL), remove_arg_pos(G2, P2, [], VL, Ex, G, P). expand_goal(G0, P0, G, P, MList, Term) :- '$current_source_module'(M), expand_goal(G0, P0, G, P, M, MList, Term, []). %! expand_goal(+GoalIn, ?PosIn, -GoalOut, -PosOut, %! +Module, -ModuleList, +Term, +Done) is det. % % @arg Module is the current module to consider % @arg ModuleList are the other expansion modules % @arg Term is the overall term that is being translated % @arg Done is a list of terms that have already been expanded % (*) This is needed because call_goal_expansion may introduce extra % context variables. Consider the code below, where the variable % E is introduced. Is there a better representation for the % context? % % == % goal_expansion(catch_and_print(Goal), catch(Goal, E, print(E))). % % test :- % catch_and_print(true). % == expand_goal(G, P, G, P, _, _, _, _) :- var(G), !. expand_goal(M:G, P, M:G, P, _M, _MList, _Term, _) :- var(M), var(G), !. expand_goal(M:G, P0, M:EG, P, _M, _MList, Term, Done) :- atom(M), !, f2_pos(P0, PA, PB0, P, PA, PB), '$def_modules'(M:[goal_expansion/4,goal_expansion/2], MList), setup_call_cleanup( '$set_source_module'(Old, M), '$expand':expand_goal(G, PB0, EG, PB, M, MList, Term, Done), '$set_source_module'(Old)). expand_goal(G0, P0, G, P, M, MList, Term, Done) :- ( already_expanded(G0, Done, Done1) -> expand_control(G0, P0, G, P, M, MList, Term, Done1) ; call_goal_expansion(MList, G0, P0, G1, P1) -> expand_goal(G1, P1, G, P, M, MList, Term/G1, [G0|Done]) % (*) ; expand_control(G0, P0, G, P, M, MList, Term, Done) ). expand_control((A,B), P0, Conj, P, M, MList, Term, Done) :- !, f2_pos(P0, PA0, PB0, P1, PA, PB), expand_goal(A, PA0, EA, PA, M, MList, Term, Done), expand_goal(B, PB0, EB, PB, M, MList, Term, Done), simplify((EA,EB), P1, Conj, P). expand_control((A;B), P0, Or, P, M, MList, Term, Done) :- !, f2_pos(P0, PA0, PB0, P1, PA1, PB), term_variables(A, AVars), term_variables(B, BVars), var_intersection(AVars, BVars, SharedVars), save_variable_info(SharedVars, SavedState), expand_goal(A, PA0, EA, PA, M, MList, Term, Done), save_variable_info(SharedVars, SavedState2), restore_variable_info(SavedState), expand_goal(B, PB0, EB, PB, M, MList, Term, Done), merge_variable_info(SavedState2), fixup_or_lhs(A, EA, PA, EA1, PA1), simplify((EA1;EB), P1, Or, P). expand_control((A->B), P0, Goal, P, M, MList, Term, Done) :- !, f2_pos(P0, PA0, PB0, P1, PA, PB), expand_goal(A, PA0, EA, PA, M, MList, Term, Done), expand_goal(B, PB0, EB, PB, M, MList, Term, Done), simplify((EA->EB), P1, Goal, P). expand_control((A*->B), P0, Goal, P, M, MList, Term, Done) :- !, f2_pos(P0, PA0, PB0, P1, PA, PB), expand_goal(A, PA0, EA, PA, M, MList, Term, Done), expand_goal(B, PB0, EB, PB, M, MList, Term, Done), simplify((EA*->EB), P1, Goal, P). expand_control((\+A), P0, Goal, P, M, MList, Term, Done) :- !, f1_pos(P0, PA0, P1, PA), term_variables(A, AVars), save_variable_info(AVars, SavedState), expand_goal(A, PA0, EA, PA, M, MList, Term, Done), restore_variable_info(SavedState), simplify(\+(EA), P1, Goal, P). expand_control(call(A), P0, call(EA), P, M, MList, Term, Done) :- !, f1_pos(P0, PA0, P, PA), expand_goal(A, PA0, EA, PA, M, MList, Term, Done). expand_control($(A), P0, $(EA), P, M, MList, Term, Done) :- !, f1_pos(P0, PA0, P, PA), expand_goal(A, PA0, EA, PA, M, MList, Term, Done). expand_control(G0, P0, G, P, M, MList, Term, Done) :- is_meta_call(G0, M, Head), !, term_variables(G0, Vars), mark_vars_non_fresh(Vars), expand_meta(Head, G0, P0, G, P, M, MList, Term, Done). expand_control(G0, P0, G, P, M, MList, Term, _Done) :- term_variables(G0, Vars), mark_vars_non_fresh(Vars), expand_functions(G0, P0, G, P, M, MList, Term). %! already_expanded(+Goal, +Done, -RestDone) is semidet. already_expanded(Goal, Done, Done1) :- '$select'(G, Done, Done1), G == Goal, !. %! fixup_or_lhs(+OldLeft, -ExpandedLeft, +ExpPos, -Fixed, -FixedPos) is det. % % The semantics of (A;B) is different if A is (If->Then). We need % to keep the same semantics if -> is introduced or removed by the % expansion. If -> is introduced, we make sure that the whole % thing remains a disjunction by creating ((EA,true);B) fixup_or_lhs(Old, New, PNew, Fix, PFixed) :- nonvar(Old), nonvar(New), ( Old = (_ -> _) -> New \= (_ -> _), Fix = (New -> true) ; New = (_ -> _), Fix = (New, true) ), !, lhs_pos(PNew, PFixed). fixup_or_lhs(_Old, New, P, New, P). lhs_pos(P0, _) :- var(P0), !. lhs_pos(P0, term_position(F,T,T,T,[P0,T-T])) :- arg(1, P0, F), arg(2, P0, T). %! is_meta_call(+G0, +M, -Head) is semidet. % % True if M:G0 resolves to a real meta-goal as specified by Head. is_meta_call(G0, M, Head) :- compound(G0), default_module(M, M2), '$c_current_predicate'(_, M2:G0), !, '$get_predicate_attribute'(M2:G0, meta_predicate, Head), has_meta_arg(Head). %! expand_meta(+MetaSpec, +G0, ?P0, -G, -P, +M, +Mlist, +Term, +Done) expand_meta(Spec, G0, P0, G, P, M, MList, Term, Done) :- functor(Spec, _, Arity), functor(G0, Name, Arity), functor(G1, Name, Arity), f_pos(P0, ArgPos0, G1P, ArgPos), expand_meta(1, Arity, Spec, G0, ArgPos0, Eval, EvalPos, G1, ArgPos, M, MList, Term, Done), conj(Eval, EvalPos, G1, G1P, G, P). expand_meta(I, Arity, Spec, G0, ArgPos0, Eval, EvalPos, G, [P|PT], M, MList, Term, Done) :- I =< Arity, !, arg_pos(ArgPos0, P0, PT0), arg(I, Spec, Meta), arg(I, G0, A0), arg(I, G, A), expand_meta_arg(Meta, A0, P0, EvalA, EPA, A, P, M, MList, Term, Done), I2 is I + 1, expand_meta(I2, Arity, Spec, G0, PT0, EvalB,EPB, G, PT, M, MList, Term, Done), conj(EvalA, EPA, EvalB, EPB, Eval, EvalPos). expand_meta(_, _, _, _, _, true, _, _, [], _, _, _, _). arg_pos(List, _, _) :- var(List), !. % no position info arg_pos([H|T], H, T) :- !. % argument list arg_pos([], _, []). % new has more mapex([], _). mapex([E|L], E) :- mapex(L, E). %! extended_pos(+Pos0, +N, -Pos) is det. %! extended_pos(-Pos0, +N, +Pos) is det. % % Pos is the result of adding N extra positions to Pos0. extended_pos(Var, _, Var) :- var(Var), !. extended_pos(parentheses_term_position(O,C,Pos0), N, parentheses_term_position(O,C,Pos)) :- !, extended_pos(Pos0, N, Pos). extended_pos(term_position(F,T,FF,FT,Args), _, term_position(F,T,FF,FT,Args)) :- var(Args), !. extended_pos(term_position(F,T,FF,FT,Args0), N, term_position(F,T,FF,FT,Args)) :- length(Ex, N), mapex(Ex, T-T), '$append'(Args0, Ex, Args), !. extended_pos(F-T, N, term_position(F,T,F,T,Ex)) :- !, length(Ex, N), mapex(Ex, T-T). extended_pos(Pos, N, Pos) :- '$print_message'(warning, extended_pos(Pos, N)). %! expand_meta_arg(+MetaSpec, +Arg0, +ArgPos0, -Eval, -EvalPos, %! -Arg, -ArgPos, +ModuleList, +Term, +Done) is det. % % Goal expansion for a meta-argument. % % @arg Eval is always `true`. Future versions should allow for % functions on such positions. This requires proper % position management for function expansion. expand_meta_arg(0, A0, PA0, true, _, A, PA, M, MList, Term, Done) :- !, expand_goal(A0, PA0, A1, PA, M, MList, Term, Done), compile_meta_call(A1, A, M, Term). expand_meta_arg(N, A0, P0, true, _, A, P, M, MList, Term, Done) :- integer(N), callable(A0), replace_functions(A0, true, _, M), !, length(Ex, N), mark_vars_non_fresh(Ex), extend_arg_pos(A0, P0, Ex, A1, PA1), expand_goal(A1, PA1, A2, PA2, M, MList, Term, Done), compile_meta_call(A2, A3, M, Term), term_variables(A0, VL), remove_arg_pos(A3, PA2, M, VL, Ex, A, P). expand_meta_arg(^, A0, PA0, true, _, A, PA, M, MList, Term, Done) :- !, expand_setof_goal(A0, PA0, A, PA, M, MList, Term, Done). expand_meta_arg(S, A0, PA0, Eval, EPA, A, PA, M, _MList, _Term, _Done) :- replace_functions(A0, PA0, Eval, EPA, A, PA, M), ( Eval == true -> true ; same_functor(A0, A) -> true ; meta_arg(S) -> throw(error(context_error(function, meta_arg(S)), _)) ; true ). same_functor(T1, T2) :- compound(T1), !, compound(T2), compound_name_arity(T1, N, A), compound_name_arity(T2, N, A). same_functor(T1, T2) :- atom(T1), T1 == T2. variant_sha1_nat(Term, Hash) :- copy_term_nat(Term, TNat), variant_sha1(TNat, Hash). wrap_meta_arguments(A0, M, VL, Ex, A) :- '$append'(VL, Ex, AV), variant_sha1_nat(A0+AV, Hash), atom_concat('__aux_wrapper_', Hash, AuxName), H =.. [AuxName|AV], compile_auxiliary_clause(M, (H :- A0)), A =.. [AuxName|VL]. %! extend_arg_pos(+A0, +P0, +Ex, -A, -P) is det. % % Adds extra arguments Ex to A0, and extra subterm positions to P % for such arguments. extend_arg_pos(A, P, _, A, P) :- var(A), !. extend_arg_pos(M:A0, P0, Ex, M:A, P) :- !, f2_pos(P0, PM, PA0, P, PM, PA), extend_arg_pos(A0, PA0, Ex, A, PA). extend_arg_pos(A0, P0, Ex, A, P) :- callable(A0), !, extend_term(A0, Ex, A), length(Ex, N), extended_pos(P0, N, P). extend_arg_pos(A, P, _, A, P). extend_term(Atom, Extra, Term) :- atom(Atom), !, Term =.. [Atom|Extra]. extend_term(Term0, Extra, Term) :- compound_name_arguments(Term0, Name, Args0), '$append'(Args0, Extra, Args), compound_name_arguments(Term, Name, Args). %! remove_arg_pos(+A0, +P0, +M, +Ex, +VL, -A, -P) is det. % % Removes the Ex arguments from A0 and the respective extra % positions from P0. Note that if they are not at the end, a % wrapper with the elements of VL as arguments is generated to put % them in order. % % @see wrap_meta_arguments/5 remove_arg_pos(A, P, _, _, _, A, P) :- var(A), !. remove_arg_pos(M:A0, P0, _, VL, Ex, M:A, P) :- !, f2_pos(P, PM, PA0, P0, PM, PA), remove_arg_pos(A0, PA, M, VL, Ex, A, PA0). remove_arg_pos(A0, P0, M, VL, Ex0, A, P) :- callable(A0), !, length(Ex0, N), ( A0 =.. [F|Args], length(Ex, N), '$append'(Args0, Ex, Args), Ex==Ex0 -> extended_pos(P, N, P0), A =.. [F|Args0] ; M \== [], wrap_meta_arguments(A0, M, VL, Ex0, A), wrap_meta_pos(P0, P) ). remove_arg_pos(A, P, _, _, _, A, P). wrap_meta_pos(P0, P) :- ( nonvar(P0) -> P = term_position(F,T,_,_,_), atomic_pos(P0, F-T) ; true ). has_meta_arg(Head) :- arg(_, Head, Arg), direct_call_meta_arg(Arg), !. direct_call_meta_arg(I) :- integer(I). direct_call_meta_arg(^). meta_arg(:). meta_arg(//). meta_arg(I) :- integer(I). expand_setof_goal(Var, Pos, Var, Pos, _, _, _, _) :- var(Var), !. expand_setof_goal(V^G, P0, V^EG, P, M, MList, Term, Done) :- !, f2_pos(P0, PA0, PB, P, PA, PB), expand_setof_goal(G, PA0, EG, PA, M, MList, Term, Done). expand_setof_goal(M0:G, P0, M0:EG, P, M, MList, Term, Done) :- !, f2_pos(P0, PA0, PB, P, PA, PB), expand_setof_goal(G, PA0, EG, PA, M, MList, Term, Done). expand_setof_goal(G, P0, EG, P, M, MList, Term, Done) :- !, expand_goal(G, P0, EG0, P, M, MList, Term, Done), compile_meta_call(EG0, EG1, M, Term), ( extend_existential(G, EG1, V) -> EG = V^EG1 ; EG = EG1 ). %! extend_existential(+G0, +G1, -V) is semidet. % % Extend the variable template to compensate for intermediate % variables introduced during goal expansion (notably for functional % notation). extend_existential(G0, G1, V) :- term_variables(G0, GV0), sort(GV0, SV0), term_variables(G1, GV1), sort(GV1, SV1), ord_subtract(SV1, SV0, New), New \== [], V =.. [v|New]. %! call_goal_expansion(+ExpandModules, %! +Goal0, ?Pos0, -Goal, -Pos, +Done) is semidet. % % Succeeds if the context has a module that defines % goal_expansion/2 this rule succeeds and Goal is not equal to % Goal0. Note that the translator is called recursively until a % fixed-point is reached. call_goal_expansion(MList, G0, P0, G, P) :- current_prolog_flag(sandboxed_load, false), !, ( '$member'(M-Preds, MList), '$member'(Pred, Preds), ( Pred == goal_expansion/4 -> M:goal_expansion(G0, P0, G, P) ; M:goal_expansion(G0, G), P = P0 ), G0 \== G -> true ). call_goal_expansion(MList, G0, P0, G, P) :- ( '$member'(M-Preds, MList), '$member'(Pred, Preds), ( Pred == goal_expansion/4 -> Expand = M:goal_expansion(G0, P0, G, P) ; Expand = M:goal_expansion(G0, G) ), allowed_expansion(Expand), call(Expand), G0 \== G -> true ). %! allowed_expansion(:Goal) is semidet. % % Calls prolog:sandbox_allowed_expansion(:Goal) prior to calling % Goal for the purpose of term or goal expansion. This hook can % prevent the expansion to take place by raising an exception. % % @throws exceptions from prolog:sandbox_allowed_expansion/1. :- multifile prolog:sandbox_allowed_expansion/1. allowed_expansion(QGoal) :- strip_module(QGoal, M, Goal), E = error(Formal,_), catch(prolog:sandbox_allowed_expansion(M:Goal), E, true), ( var(Formal) -> fail ; !, print_message(error, E), fail ). allowed_expansion(_). /******************************* * FUNCTIONAL NOTATION * *******************************/ %! expand_functions(+G0, +P0, -G, -P, +M, +MList, +Term) is det. % % Expand functional notation and arithmetic functions. % % @arg MList is the list of modules defining goal_expansion/2 in % the expansion context. expand_functions(G0, P0, G, P, M, MList, Term) :- expand_functional_notation(G0, P0, G1, P1, M, MList, Term), ( expand_arithmetic(G1, P1, G, P, Term) -> true ; G = G1, P = P1 ). %! expand_functional_notation(+G0, +P0, -G, -P, +M, +MList, +Term) is det. % % @tbd: position logic % @tbd: make functions module-local expand_functional_notation(G0, P0, G, P, M, _MList, _Term) :- contains_functions(G0), replace_functions(G0, P0, Eval, EvalPos, G1, G1Pos, M), Eval \== true, !, wrap_var(G1, G1Pos, G2, G2Pos), conj(Eval, EvalPos, G2, G2Pos, G, P). expand_functional_notation(G, P, G, P, _, _, _). wrap_var(G, P, G, P) :- nonvar(G), !. wrap_var(G, P0, call(G), P) :- ( nonvar(P0) -> P = term_position(F,T,F,T,[P0]), atomic_pos(P0, F-T) ; true ). %! contains_functions(@Term) is semidet. % % True when Term contains a function reference. contains_functions(Term) :- \+ \+ ( '$factorize_term'(Term, Skeleton, Assignments), ( contains_functions2(Skeleton) ; contains_functions2(Assignments) )). contains_functions2(Term) :- compound(Term), ( function(Term, _) -> true ; arg(_, Term, Arg), contains_functions2(Arg) -> true ). %! replace_functions(+GoalIn, +PosIn, %! -Eval, -EvalPos, %! -GoalOut, -PosOut, %! +ContextTerm) is det. % % @tbd Proper propagation of list, dict and brace term positions. :- public replace_functions/4. % used in dicts.pl replace_functions(GoalIn, Eval, GoalOut, Context) :- replace_functions(GoalIn, _, Eval, _, GoalOut, _, Context). replace_functions(Var, Pos, true, _, Var, Pos, _Ctx) :- var(Var), !. replace_functions(F, FPos, Eval, EvalPos, Var, VarPos, Ctx) :- function(F, Ctx), !, compound_name_arity(F, Name, Arity), PredArity is Arity+1, compound_name_arity(G, Name, PredArity), arg(PredArity, G, Var), extend_1_pos(FPos, FArgPos, GPos, GArgPos, VarPos), map_functions(0, Arity, F, FArgPos, G, GArgPos, Eval0, EP0, Ctx), conj(Eval0, EP0, G, GPos, Eval, EvalPos). replace_functions(Term0, Term0Pos, Eval, EvalPos, Term, TermPos, Ctx) :- compound(Term0), !, compound_name_arity(Term0, Name, Arity), compound_name_arity(Term, Name, Arity), f_pos(Term0Pos, Args0Pos, TermPos, ArgsPos), map_functions(0, Arity, Term0, Args0Pos, Term, ArgsPos, Eval, EvalPos, Ctx). replace_functions(Term, Pos, true, _, Term, Pos, _). %! map_functions(+Arg, +Arity, %! +TermIn, +ArgInPos, -Term, -ArgPos, -Eval, -EvalPos, %! +Context) map_functions(Arity, Arity, _, LPos0, _, LPos, true, _, _) :- !, pos_nil(LPos0, LPos). map_functions(I0, Arity, Term0, LPos0, Term, LPos, Eval, EP, Ctx) :- pos_list(LPos0, AP0, APT0, LPos, AP, APT), I is I0+1, arg(I, Term0, Arg0), arg(I, Term, Arg), replace_functions(Arg0, AP0, Eval0, EP0, Arg, AP, Ctx), map_functions(I, Arity, Term0, APT0, Term, APT, Eval1, EP1, Ctx), conj(Eval0, EP0, Eval1, EP1, Eval, EP). %! conj(+G1, +P1, +G2, +P2, -G, -P) conj(true, _, X, P, X, P) :- !. conj(X, P, true, _, X, P) :- !. conj(X, PX, Y, PY, (X,Y), _) :- var(PX), var(PY), !. conj(X, PX, Y, PY, (X,Y), P) :- P = term_position(F,T,FF,FT,[PX,PY]), atomic_pos(PX, F-FF), atomic_pos(PY, FT-T). %! function(?Term, +Context) % % True if function expansion needs to be applied for the given % term. :- multifile function/2. function(.(_,_), _) :- \+ functor([_|_], ., _). /******************************* * ARITHMETIC * *******************************/ %! expand_arithmetic(+G0, +P0, -G, -P, +Term) is semidet. % % Expand arithmetic expressions in is/2, (>)/2, etc. This is % currently a dummy. The idea is to call rules similar to % goal_expansion/2,4 that allow for rewriting an arithmetic % expression. The system rules will perform evaluation of constant % expressions. expand_arithmetic(_G0, _P0, _G, _P, _Term) :- fail. /******************************* * POSITION LOGIC * *******************************/ %! f2_pos(?TermPos0, ?PosArg10, ?PosArg20, %! ?TermPos, ?PosArg1, ?PosArg2) is det. %! f1_pos(?TermPos0, ?PosArg10, ?TermPos, ?PosArg1) is det. %! f_pos(?TermPos0, ?PosArgs0, ?TermPos, ?PosArgs) is det. %! atomic_pos(?TermPos0, -AtomicPos) is det. % % Position progapation routines. f2_pos(Var, _, _, _, _, _) :- var(Var), !. f2_pos(term_position(F,T,FF,FT,[A10,A20]), A10, A20, term_position(F,T,FF,FT,[A1, A2 ]), A1, A2) :- !. f2_pos(parentheses_term_position(O,C,Pos0), A10, A20, parentheses_term_position(O,C,Pos), A1, A2) :- !, f2_pos(Pos0, A10, A20, Pos, A1, A2). f2_pos(Pos, _, _, _, _, _) :- expected_layout(f2, Pos). f1_pos(Var, _, _, _) :- var(Var), !. f1_pos(term_position(F,T,FF,FT,[A10]), A10, term_position(F,T,FF,FT,[A1 ]), A1) :- !. f1_pos(parentheses_term_position(O,C,Pos0), A10, parentheses_term_position(O,C,Pos), A1) :- !, f1_pos(Pos0, A10, Pos, A1). f1_pos(Pos, _, _, _) :- expected_layout(f1, Pos). f_pos(Var, _, _, _) :- var(Var), !. f_pos(term_position(F,T,FF,FT,ArgPos0), ArgPos0, term_position(F,T,FF,FT,ArgPos), ArgPos) :- !. f_pos(parentheses_term_position(O,C,Pos0), A10, parentheses_term_position(O,C,Pos), A1) :- !, f_pos(Pos0, A10, Pos, A1). f_pos(Pos, _, _, _) :- expected_layout(compound, Pos). atomic_pos(Pos, _) :- var(Pos), !. atomic_pos(Pos, F-T) :- arg(1, Pos, F), arg(2, Pos, T). %! pos_nil(+Nil, -Nil) is det. %! pos_list(+List0, -H0, -T0, -List, -H, -T) is det. % % Position propagation for lists. pos_nil(Var, _) :- var(Var), !. pos_nil([], []) :- !. pos_nil(Pos, _) :- expected_layout(nil, Pos). pos_list(Var, _, _, _, _, _) :- var(Var), !. pos_list([H0|T0], H0, T0, [H|T], H, T) :- !. pos_list(Pos, _, _, _, _, _) :- expected_layout(list, Pos). %! extend_1_pos(+FunctionPos, -FArgPos, -EvalPos, -EArgPos, -VarPos) % % Deal with extending a function to include the return value. extend_1_pos(Pos, _, _, _, _) :- var(Pos), !. extend_1_pos(term_position(F,T,FF,FT,FArgPos), FArgPos, term_position(F,T,FF,FT,GArgPos), GArgPos0, FT-FT1) :- integer(FT), !, FT1 is FT+1, '$same_length'(FArgPos, GArgPos0), '$append'(GArgPos0, [FT-FT1], GArgPos). extend_1_pos(F-T, [], term_position(F,T,F,T,[T-T1]), [], T-T1) :- integer(T), !, T1 is T+1. extend_1_pos(Pos, _, _, _, _) :- expected_layout(callable, Pos). '$same_length'(List, List) :- var(List), !. '$same_length'([], []). '$same_length'([_|T0], [_|T]) :- '$same_length'(T0, T). %! expected_layout(+Expected, +Found) % % Print a message if the layout term does not satisfy our % expectations. This means that the transformation requires % support from term_expansion/4 and/or goal_expansion/4 to achieve % proper source location information. :- create_prolog_flag(debug_term_position, false, []). expected_layout(Expected, Pos) :- current_prolog_flag(debug_term_position, true), !, '$print_message'(warning, expected_layout(Expected, Pos)). expected_layout(_, _). /******************************* * SIMPLIFICATION ROUTINES * *******************************/ %! simplify(+ControlIn, +Pos0, -ControlOut, -Pos) is det. % % Simplify control structures % % @tbd Much more analysis % @tbd Turn this into a separate module simplify(Control, P, Control, P) :- current_prolog_flag(optimise, false), !. simplify(Control, P0, Simple, P) :- simple(Control, P0, Simple, P), !. simplify(Control, P, Control, P). %! simple(+Goal, +GoalPos, -Simple, -SimplePos) % % Simplify a control structure. Note that we do not simplify % (A;fail). Logically, this is the same as `A` if `A` is not % `_->_` or `_*->_`, but the choice point may be created on % purpose. simple((X,Y), P0, Conj, P) :- ( true(X) -> Conj = Y, f2_pos(P0, _, P, _, _, _) ; false(X) -> Conj = fail, f2_pos(P0, P1, _, _, _, _), atomic_pos(P1, P) ; true(Y) -> Conj = X, f2_pos(P0, P, _, _, _, _) ). simple((I->T;E), P0, ITE, P) :- % unification with _->_ is fine ( true(I) % because nothing happens if I and T -> ITE = T, % are unbound. f2_pos(P0, P1, _, _, _, _), f2_pos(P1, _, P, _, _, _) ; false(I) -> ITE = E, f2_pos(P0, _, P, _, _, _) ). simple((X;Y), P0, Or, P) :- false(X), Or = Y, f2_pos(P0, _, P, _, _, _). true(X) :- nonvar(X), eval_true(X). false(X) :- nonvar(X), eval_false(X). %! eval_true(+Goal) is semidet. %! eval_false(+Goal) is semidet. eval_true(true). eval_true(otherwise). eval_false(fail). eval_false(false). /******************************* * META CALLING * *******************************/ :- create_prolog_flag(compile_meta_arguments, false, [type(atom)]). %! compile_meta_call(+CallIn, -CallOut, +Module, +Term) is det. % % Compile (complex) meta-calls into a clause. compile_meta_call(CallIn, CallIn, _, Term) :- var(Term), !. % explicit call; no context compile_meta_call(CallIn, CallIn, _, _) :- var(CallIn), !. compile_meta_call(CallIn, CallIn, _, _) :- ( current_prolog_flag(compile_meta_arguments, false) ; current_prolog_flag(xref, true) ), !. compile_meta_call(CallIn, CallIn, _, _) :- strip_module(CallIn, _, Call), ( is_aux_meta(Call) ; \+ control(Call), ( '$c_current_predicate'(_, system:Call), \+ current_prolog_flag(compile_meta_arguments, always) ; current_prolog_flag(compile_meta_arguments, control) ) ), !. compile_meta_call(M:CallIn, CallOut, _, Term) :- !, ( atom(M), callable(CallIn) -> compile_meta_call(CallIn, CallOut, M, Term) ; CallOut = M:CallIn ). compile_meta_call(CallIn, CallOut, Module, Term) :- compile_meta(CallIn, CallOut, Module, Term, Clause), compile_auxiliary_clause(Module, Clause). compile_auxiliary_clause(Module, Clause) :- Clause = (Head:-Body), '$current_source_module'(SM), ( predicate_property(SM:Head, defined) -> true ; SM == Module -> compile_aux_clauses([Clause]) ; compile_aux_clauses([Head:-Module:Body]) ). control((_,_)). control((_;_)). control((_->_)). control((_*->_)). control(\+(_)). control($(_)). is_aux_meta(Term) :- callable(Term), functor(Term, Name, _), sub_atom(Name, 0, _, _, '__aux_meta_call_'). compile_meta(CallIn, CallOut, M, Term, (CallOut :- Body)) :- replace_subterm(CallIn, true, Term, Term2), term_variables(Term2, AllVars), term_variables(CallIn, InVars), intersection_eq(InVars, AllVars, HeadVars), copy_term_nat(CallIn+HeadVars, NAT), variant_sha1(NAT, Hash), atom_concat('__aux_meta_call_', Hash, AuxName), expand_goal(CallIn, _Pos0, Body, _Pos, M, [], (CallOut:-CallIn), []), length(HeadVars, Arity), ( Arity > 256 % avoid 1024 arity limit -> HeadArgs = [v(HeadVars)] ; HeadArgs = HeadVars ), CallOut =.. [AuxName|HeadArgs]. %! replace_subterm(From, To, TermIn, TermOut) % % Replace instances (==/2) of From inside TermIn by To. replace_subterm(From, To, TermIn, TermOut) :- From == TermIn, !, TermOut = To. replace_subterm(From, To, TermIn, TermOut) :- compound(TermIn), compound_name_arity(TermIn, Name, Arity), Arity > 0, !, compound_name_arity(TermOut, Name, Arity), replace_subterm_compound(1, Arity, From, To, TermIn, TermOut). replace_subterm(_, _, Term, Term). replace_subterm_compound(I, Arity, From, To, TermIn, TermOut) :- I =< Arity, !, arg(I, TermIn, A1), arg(I, TermOut, A2), replace_subterm(From, To, A1, A2), I2 is I+1, replace_subterm_compound(I2, Arity, From, To, TermIn, TermOut). replace_subterm_compound(_I, _Arity, _From, _To, _TermIn, _TermOut). %! intersection_eq(+Small, +Big, -Shared) is det. % % Shared are the variables in Small that also appear in Big. The % variables in Shared are in the same order as Small. intersection_eq([], _, []). intersection_eq([H|T0], L, List) :- ( member_eq(H, L) -> List = [H|T], intersection_eq(T0, L, T) ; intersection_eq(T0, L, List) ). member_eq(E, [H|T]) :- ( E == H -> true ; member_eq(E, T) ). /******************************* * :- IF ... :- ENDIF * *******************************/ :- thread_local '$include_code'/3. '$including' :- '$include_code'(X, _, _), !, X == true. '$including'. cond_compilation((:- if(G)), []) :- source_location(File, Line), ( '$including' -> ( catch('$eval_if'(G), E, (print_message(error, E), fail)) -> asserta('$include_code'(true, File, Line)) ; asserta('$include_code'(false, File, Line)) ) ; asserta('$include_code'(else_false, File, Line)) ). cond_compilation((:- elif(G)), []) :- source_location(File, Line), ( clause('$include_code'(Old, File, _), _, Ref) -> erase(Ref), ( Old == true -> asserta('$include_code'(else_false, File, Line)) ; Old == false, catch('$eval_if'(G), E, (print_message(error, E), fail)) -> asserta('$include_code'(true, File, Line)) ; asserta('$include_code'(Old, File, Line)) ) ; throw(error(conditional_compilation_error(no_if, elif), _)) ). cond_compilation((:- else), []) :- source_location(File, Line), ( clause('$include_code'(X, File, _), _, Ref) -> erase(Ref), ( X == true -> X2 = false ; X == false -> X2 = true ; X2 = X ), asserta('$include_code'(X2, File, Line)) ; throw(error(conditional_compilation_error(no_if, else), _)) ). cond_compilation(end_of_file, end_of_file) :- % TBD: Check completeness !, source_location(File, _), ( clause('$include_code'(_, OF, OL), _) -> ( File == OF -> throw(error(conditional_compilation_error( unterminated,OF:OL), _)) ; true ) ; true ). cond_compilation((:- endif), []) :- !, source_location(File, _), ( ( clause('$include_code'(_, File, _), _, Ref) -> erase(Ref) ) -> true ; throw(error(conditional_compilation_error(no_if, endif), _)) ). cond_compilation(_, []) :- \+ '$including'. '$eval_if'(G) :- expand_goal(G, G2), '$current_source_module'(Module), Module:G2.