/* Part of SWI-Prolog Author: Jan Wielemaker E-mail: J.Wielemaker@vu.nl WWW: http://www.swi-prolog.org Copyright (c) 2012-2023, 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(prolog_codewalk, [ prolog_walk_code/1, % +Options prolog_program_clause/2 % -ClauseRef, +Options ]). :- use_module(library(record),[(record)/1, op(_,_,record)]). :- use_module(library(debug),[debug/3,debugging/1,assertion/1]). :- autoload(library(apply),[maplist/2]). :- autoload(library(error),[must_be/2]). :- autoload(library(listing),[portray_clause/1]). :- autoload(library(lists),[member/2,nth1/3,append/3]). :- autoload(library(option),[meta_options/3]). :- autoload(library(prolog_clause), [clause_info/4,initialization_layout/4,clause_name/2]). :- autoload(library(prolog_metainference), [inferred_meta_predicate/2,infer_meta_predicate/2]). /** Prolog code walker This module walks over the loaded program, searching for callable predicates. It started as part of library(prolog_autoload) and has been turned into a separate module to facilitate operations that require the same reachability analysis, such as finding references to a predicate, finding unreachable code, etc. For example, the following determins the call graph of the loaded program. By using source(true), The exact location of the call in the source file is passed into _Where. == :- dynamic calls/2. assert_call_graph :- retractall(calls(_, _)), prolog_walk_code([ trace_reference(_), on_trace(assert_edge), source(false) ]), predicate_property(calls(_,_), number_of_clauses(N)), format('Got ~D edges~n', [N]). assert_edge(Callee, Caller, _Where) :- calls(Caller, Callee), !. assert_edge(Callee, Caller, _Where) :- assertz(calls(Caller, Callee)). == */ :- meta_predicate prolog_walk_code(:). :- multifile prolog:called_by/4, prolog:called_by/2. :- predicate_options(prolog_walk_code/1, 1, [ undefined(oneof([ignore,error,trace])), autoload(boolean), clauses(list), module(atom), module_class(list(oneof([user,system,library, test,development]))), source(boolean), trace_reference(any), trace_condition(callable), on_trace(callable), on_edge(callable), infer_meta_predicates(oneof([false,true,all])), walk_meta_predicates(boolean), evaluate(boolean), verbose(boolean) ]). :- record walk_option(undefined:oneof([ignore,error,trace])=ignore, autoload:boolean=true, source:boolean=true, module:atom, % Only analyse given module module_class:list(oneof([user,system,library, test,development]))=[user,library], infer_meta_predicates:oneof([false,true,all])=true, walk_meta_predicates:boolean=true, clauses:list, % Walk only these clauses trace_reference:any=(-), trace_condition:callable, % Call-back condition on_edge:callable, % Call-back on trace hits on_trace:callable, % Call-back on trace hits % private stuff clause, % Processed clause caller, % Head of the caller initialization, % Initialization source undecided, % Error to throw error evaluate:boolean, % Do partial evaluation verbose:boolean=false). % Report progress :- thread_local multifile_predicate/3. % Name, Arity, Module %! prolog_walk_code(+Options) is det. % % Walk over all loaded (user) Prolog code. The following code is % processed: % % 1. The bodies of all clauses in all user and library modules. % This steps collects, but does not scan multifile predicates % to avoid duplicate work. % 2. All multi-file predicates collected. % 3. All goals registered with initialization/1 % % Options processed: % % * undefined(+Action) % Action defines what happens if the analysis finds a % definitely undefined predicate. One of `ignore` or % `error` (default is `ignore`). % % * autoload(+Boolean) % Try to autoload code while walking. This is enabled by default % to obtain as much as possible information about goals and find % references from autoloaded libraries. % % * clauses(+ListOfClauseReferences) % Only process the given clauses. Can be used to find clauses % quickly using source(false) and then process only interesting % clauses with source information. % % * module(+Module) % Only process the given module % % * module_class(+ModuleClassList) % Limit processing to modules of the given classes. See % module_property/2 for details on module classes. Default % is to scan the classes =user= and =library=. % % * infer_meta_predicates(+BooleanOrAll) % Use infer_meta_predicate/2 on predicates with clauses that % call known meta-predicates. The analysis is restarted until % a fixed point is reached. If =true= (default), analysis is % only restarted if the inferred meta-predicate contains a % callable argument. If =all=, it will be restarted until no % more new meta-predicates can be found. % % * walk_meta_predicates(Boolean) % When `false` (default `true`), do not analyse the arguments % of meta predicates. Standard Prolog control structures are % always analysed. % % * trace_reference(Callable) % Print all calls to goals that subsume Callable. Goals are % represented as Module:Callable (i.e., they are always % qualified). See also subsumes_term/2. % % * trace_condition(:Cond) % Additional filter condition applied after `trace_reference`. % Called as call(Cond, Callee, Context), where `Context` is a % dict containing the following keys: % % - Context:caller % Qualified term representing the caller or the atom % ''. % - Context:module % Module being processed % - Context:clause % If we are processing a normal clause, the clause reference % to this clause. % - Context:initialization % If we are processing an initialization/1 directive, a term % `File:Line` representing the location of the declaration. % % * on_edge(:OnEdge) % If a reference to `trace_reference` is found, call % call(OnEdge, Callee, Caller, Location), where `Location` is a % dict containing a subset of the keys `clause`, `file`, % `character_count`, `line_count` and `line_position`. If % full position information is available all keys are present. % If the clause layout is unknown the only the `clause`, `file` % and `line_count` are available and the line is the start line % of the clause. For a dynamic clause, only the `clause` is % present. If the position is associated to a _directive_, % the `clause` is missing. If nothing is known the `Location` % is an empty dict. % % * on_trace(:OnTrace) % As `on_edge`, but location is not translated and is one % of these: % % - clause_term_position(+ClauseRef, +TermPos) % - clause(+ClauseRef) % - file_term_position(+Path, +TermPos) % - file(+File, +Line, -1, _) % - a variable (unknown) % % Caller is the qualified head of the calling clause or the % atom ''. % % * source(+Boolean) % If `false` (default `true`), to not try to obtain detailed % source information for printed messages. % % * verbose(+Boolean) % If `true` (default `false`), report derived meta-predicates % and iterations. % % @compat OnTrace was called using Caller-Location in older % versions. prolog_walk_code(Options) :- meta_options(is_meta, Options, QOptions), prolog_walk_code(1, QOptions). prolog_walk_code(Iteration, Options) :- statistics(cputime, CPU0), make_walk_option(Options, OTerm, _), ( walk_option_clauses(OTerm, Clauses), nonvar(Clauses) -> walk_clauses(Clauses, OTerm) ; forall(( walk_option_module(OTerm, M0), copy_term(M0, M), current_module(M), scan_module(M, OTerm) ), find_walk_from_module(M, OTerm)), walk_from_multifile(OTerm), walk_from_initialization(OTerm) ), infer_new_meta_predicates(New, OTerm), statistics(cputime, CPU1), ( New \== [] -> CPU is CPU1-CPU0, ( walk_option_verbose(OTerm, true) -> Level = informational ; Level = silent ), print_message(Level, codewalk(reiterate(New, Iteration, CPU))), succ(Iteration, Iteration2), prolog_walk_code(Iteration2, Options) ; true ). is_meta(on_edge). is_meta(on_trace). is_meta(trace_condition). %! walk_clauses(+Clauses, +OTerm) is det. % % Walk the given clauses. walk_clauses(Clauses, OTerm) :- must_be(list, Clauses), forall(member(ClauseRef, Clauses), ( user:clause(CHead, Body, ClauseRef), ( CHead = Module:Head -> true ; Module = user, Head = CHead ), walk_option_clause(OTerm, ClauseRef), walk_option_caller(OTerm, Module:Head), walk_called_by_body(Body, Module, OTerm) )). %! scan_module(+Module, +OTerm) is semidet. % % True if we must scan Module according to OTerm. scan_module(M, OTerm) :- walk_option_module(OTerm, M1), nonvar(M1), !, \+ M \= M1. scan_module(M, OTerm) :- walk_option_module_class(OTerm, Classes), module_property(M, class(Class)), memberchk(Class, Classes), !. %! walk_from_initialization(+OTerm) % % Find initialization/1,2 directives and process what they are % calling. Skip % % @bug Relies on private '$init_goal'/3 database. walk_from_initialization(OTerm) :- walk_option_caller(OTerm, ''), forall(init_goal_in_scope(Goal, SourceLocation, OTerm), ( walk_option_initialization(OTerm, SourceLocation), walk_from_initialization(Goal, OTerm))). init_goal_in_scope(Goal, SourceLocation, OTerm) :- '$init_goal'(_When, Goal, SourceLocation), SourceLocation = File:_Line, ( walk_option_module(OTerm, M), nonvar(M) -> module_property(M, file(File)) ; walk_option_module_class(OTerm, Classes), source_file_property(File, module(MF)) -> module_property(MF, class(Class)), memberchk(Class, Classes), walk_option_module(OTerm, MF) ; true ). walk_from_initialization(M:Goal, OTerm) :- scan_module(M, OTerm), !, walk_called_by_body(Goal, M, OTerm). walk_from_initialization(_, _). %! find_walk_from_module(+Module, +OTerm) is det. % % Find undefined calls from the bodies of all clauses that belong % to Module. find_walk_from_module(M, OTerm) :- debug(autoload, 'Analysing module ~q', [M]), walk_option_module(OTerm, M), forall(predicate_in_module(M, PI), walk_called_by_pred(M:PI, OTerm)). walk_called_by_pred(Module:Name/Arity, _) :- multifile_predicate(Name, Arity, Module), !. walk_called_by_pred(Module:Name/Arity, _) :- functor(Head, Name, Arity), predicate_property(Module:Head, multifile), !, assertz(multifile_predicate(Name, Arity, Module)). walk_called_by_pred(Module:Name/Arity, OTerm) :- functor(Head, Name, Arity), ( no_walk_property(Property), predicate_property(Module:Head, Property) -> true ; walk_option_caller(OTerm, Module:Head), walk_option_clause(OTerm, ClauseRef), forall(catch(clause(Module:Head, Body, ClauseRef), _, fail), walk_called_by_body(Body, Module, OTerm)) ). no_walk_property(number_of_rules(0)). % no point walking only facts no_walk_property(foreign). % cannot walk foreign code %! walk_from_multifile(+OTerm) % % Process registered multifile predicates. walk_from_multifile(OTerm) :- forall(retract(multifile_predicate(Name, Arity, Module)), walk_called_by_multifile(Module:Name/Arity, OTerm)). walk_called_by_multifile(Module:Name/Arity, OTerm) :- functor(Head, Name, Arity), forall(catch(clause_not_from_development( Module:Head, Body, ClauseRef, OTerm), _, fail), ( walk_option_clause(OTerm, ClauseRef), walk_option_caller(OTerm, Module:Head), walk_called_by_body(Body, Module, OTerm) )). %! clause_not_from_development(:Head, -Body, ?Ref, +Options) is nondet. % % Enumerate clauses for a multifile predicate, but omit those from % a module that is specifically meant to support development. clause_not_from_development(Module:Head, Body, Ref, OTerm) :- clause(Module:Head, Body, Ref), \+ ( clause_property(Ref, file(File)), module_property(LoadModule, file(File)), \+ scan_module(LoadModule, OTerm) ). %! walk_called_by_body(+Body, +Module, +OTerm) is det. % % Check the Body term when executed in the context of Module. % Options: % % - undefined(+Action) % One of =ignore=, =error= walk_called_by_body(True, _, _) :- True == true, !. % quickly deal with facts walk_called_by_body(Body, Module, OTerm) :- set_undecided_of_walk_option(error, OTerm, OTerm1), set_evaluate_of_walk_option(false, OTerm1, OTerm2), catch(walk_called(Body, Module, _TermPos, OTerm2), missing(Missing), walk_called_by_body(Missing, Body, Module, OTerm)), !. walk_called_by_body(Body, Module, OTerm) :- format(user_error, 'Failed to analyse:~n', []), portray_clause(('' :- Body)), debug_walk(Body, Module, OTerm). % recompile this library after `debug(codewalk(trace))` and re-try % for debugging failures. :- if(debugging(codewalk(trace))). debug_walk(Body, Module, OTerm) :- gtrace, walk_called_by_body(Body, Module, OTerm). :- else. debug_walk(_,_,_). :- endif. %! walk_called_by_body(+Missing, +Body, +Module, +OTerm) % % Restart the analysis because the previous analysis provided % insufficient information. walk_called_by_body(Missing, Body, _, OTerm) :- debugging(codewalk), format(user_error, 'Retrying due to ~w (~p)~n', [Missing, OTerm]), portray_clause(('' :- Body)), fail. walk_called_by_body(undecided_call, Body, Module, OTerm) :- catch(forall(walk_called(Body, Module, _TermPos, OTerm), true), missing(Missing), walk_called_by_body(Missing, Body, Module, OTerm)). walk_called_by_body(subterm_positions, Body, Module, OTerm) :- ( ( walk_option_clause(OTerm, ClauseRef), nonvar(ClauseRef), clause_info(ClauseRef, _, TermPos, _NameOffset), TermPos = term_position(_,_,_,_,[_,BodyPos]) -> WBody = Body ; walk_option_initialization(OTerm, SrcLoc), ground(SrcLoc), SrcLoc = _File:_Line, initialization_layout(SrcLoc, Module:Body, WBody, BodyPos) ) -> catch(forall(walk_called(WBody, Module, BodyPos, OTerm), true), missing(subterm_positions), walk_called_by_body(no_positions, Body, Module, OTerm)) ; set_source_of_walk_option(false, OTerm, OTerm2), forall(walk_called(Body, Module, _BodyPos, OTerm2), true) ). walk_called_by_body(no_positions, Body, Module, OTerm) :- set_source_of_walk_option(false, OTerm, OTerm2), forall(walk_called(Body, Module, _NoPos, OTerm2), true). %! walk_called(+Goal, +Module, +TermPos, +OTerm) is multi. % % Perform abstract interpretation of Goal, touching all sub-goals % that are directly called or immediately reachable through % meta-calls. The actual auto-loading is performed by the % predicate_property/2 call for meta-predicates. % % If Goal is disjunctive, walk_called succeeds with a % choice-point. Backtracking analyses the alternative control % path(s). % % Options: % % * undecided(+Action) % How to deal with insifficiently instantiated terms in the % call-tree. Values are: % % - ignore % Silently ignore such goals % - error % Throw =undecided_call= % % * evaluate(+Boolean) % If =true= (default), evaluate some goals. Notably =/2. % % @tbd Analyse e.g. assert((Head:-Body))? walk_called(Term, Module, parentheses_term_position(_,_,Pos), OTerm) :- nonvar(Pos), !, walk_called(Term, Module, Pos, OTerm). walk_called(Var, _, TermPos, OTerm) :- var(Var), % Incomplete analysis !, undecided(Var, TermPos, OTerm). walk_called(M:G, _, term_position(_,_,_,_,[MPos,Pos]), OTerm) :- !, ( nonvar(M) -> walk_called(G, M, Pos, OTerm) ; undecided(M, MPos, OTerm) ). walk_called((A,B), M, term_position(_,_,_,_,[PA,PB]), OTerm) :- !, walk_called(A, M, PA, OTerm), walk_called(B, M, PB, OTerm). walk_called((A->B), M, term_position(_,_,_,_,[PA,PB]), OTerm) :- !, walk_called(A, M, PA, OTerm), walk_called(B, M, PB, OTerm). walk_called((A*->B), M, term_position(_,_,_,_,[PA,PB]), OTerm) :- !, walk_called(A, M, PA, OTerm), walk_called(B, M, PB, OTerm). walk_called(\+(A), M, term_position(_,_,_,_,[PA]), OTerm) :- !, \+ \+ walk_called(A, M, PA, OTerm). walk_called((A;B), M, term_position(_,_,_,_,[PA,PB]), OTerm) :- !, ( walk_option_evaluate(OTerm, Eval), Eval == true -> Goal = (A;B), setof(Goal, ( walk_called(A, M, PA, OTerm) ; walk_called(B, M, PB, OTerm) ), Alts0), variants(Alts0, Alts), member(Goal, Alts) ; \+ \+ walk_called(A, M, PA, OTerm), % do not propagate bindings \+ \+ walk_called(B, M, PB, OTerm) ). walk_called(Goal, Module, TermPos, OTerm) :- walk_option_trace_reference(OTerm, To), To \== (-), ( subsumes_term(To, Module:Goal) -> M2 = Module ; predicate_property(Module:Goal, imported_from(M2)), subsumes_term(To, M2:Goal) ), trace_condition(M2:Goal, TermPos, OTerm), print_reference(M2:Goal, TermPos, trace, OTerm), fail. % Continue search walk_called(Goal, Module, _, OTerm) :- evaluate(Goal, Module, OTerm), !. walk_called(Goal, M, TermPos, OTerm) :- ( ( predicate_property(M:Goal, imported_from(IM)) -> true ; IM = M ), prolog:called_by(Goal, IM, M, Called) ; prolog:called_by(Goal, Called) ), Called \== [], !, walk_called_by(Called, M, Goal, TermPos, OTerm). walk_called(Meta, M, term_position(_,E,_,_,ArgPosList), OTerm) :- walk_option_walk_meta_predicates(OTerm, true), ( walk_option_autoload(OTerm, false) -> nonvar(M), '$get_predicate_attribute'(M:Meta, defined, 1) ; true ), ( predicate_property(M:Meta, meta_predicate(Head)) ; inferred_meta_predicate(M:Meta, Head) ), !, walk_option_clause(OTerm, ClauseRef), register_possible_meta_clause(ClauseRef), walk_meta_call(1, Head, Meta, M, ArgPosList, E-E, OTerm). walk_called(Closure, _, _, _) :- blob(Closure, closure), !, '$closure_predicate'(Closure, Module:Name/Arity), functor(Head, Name, Arity), '$get_predicate_attribute'(Module:Head, defined, 1). walk_called(ClosureCall, _, _, _) :- compound(ClosureCall), compound_name_arity(ClosureCall, Closure, _), blob(Closure, closure), !, '$closure_predicate'(Closure, Module:Name/Arity), functor(Head, Name, Arity), '$get_predicate_attribute'(Module:Head, defined, 1). walk_called(Goal, Module, _, _) :- nonvar(Module), '$get_predicate_attribute'(Module:Goal, defined, 1), !. walk_called(Goal, Module, TermPos, OTerm) :- callable(Goal), !, undefined(Module:Goal, TermPos, OTerm). walk_called(Goal, _Module, TermPos, OTerm) :- not_callable(Goal, TermPos, OTerm). %! trace_condition(:Callee, +TermPos, +OTerm) is semidet. % % Call call(Condition, Callee, Dict) trace_condition(Callee, TermPos, OTerm) :- walk_option_trace_condition(OTerm, Cond), nonvar(Cond), !, cond_location_context(OTerm, TermPos, Context0), walk_option_caller(OTerm, Caller), walk_option_module(OTerm, Module), put_dict(#{caller:Caller, module:Module}, Context0, Context), call(Cond, Callee, Context). trace_condition(_, _, _). cond_location_context(OTerm, _TermPos, Context) :- walk_option_clause(OTerm, Clause), nonvar(Clause), !, Context = #{clause:Clause}. cond_location_context(OTerm, _TermPos, Context) :- walk_option_initialization(OTerm, Init), nonvar(Init), !, Context = #{initialization:Init}. %! undecided(+Variable, +TermPos, +OTerm) undecided(Var, TermPos, OTerm) :- walk_option_undecided(OTerm, Undecided), ( var(Undecided) -> Action = ignore ; Action = Undecided ), undecided(Action, Var, TermPos, OTerm). undecided(ignore, _, _, _) :- !. undecided(error, _, _, _) :- throw(missing(undecided_call)). %! evaluate(Goal, Module, OTerm) is nondet. evaluate(Goal, Module, OTerm) :- walk_option_evaluate(OTerm, Evaluate), Evaluate \== false, evaluate(Goal, Module). evaluate(A=B, _) :- unify_with_occurs_check(A, B). %! undefined(:Goal, +TermPos, +OTerm) % % The analysis trapped a definitely undefined predicate. undefined(_, _, OTerm) :- walk_option_undefined(OTerm, ignore), !. undefined(Goal, _, _) :- predicate_property(Goal, autoload(_)), !. undefined(Goal, TermPos, OTerm) :- ( walk_option_undefined(OTerm, trace) -> Why = trace ; Why = undefined ), print_reference(Goal, TermPos, Why, OTerm). %! not_callable(+Goal, +TermPos, +OTerm) % % We found a reference to a non-callable term not_callable(Goal, TermPos, OTerm) :- print_reference(Goal, TermPos, not_callable, OTerm). %! print_reference(+Goal, +TermPos, +Why, +OTerm) % % Print a reference to Goal, found at TermPos. % % @arg Why is one of `trace` or `undefined` print_reference(Goal, TermPos, Why, OTerm) :- walk_option_clause(OTerm, Clause), nonvar(Clause), !, ( compound(TermPos), arg(1, TermPos, CharCount), integer(CharCount) % test it is valid -> From = clause_term_position(Clause, TermPos) ; walk_option_source(OTerm, false) -> From = clause(Clause) ; From = _, throw(missing(subterm_positions)) ), print_reference2(Goal, From, Why, OTerm). print_reference(Goal, TermPos, Why, OTerm) :- walk_option_initialization(OTerm, Init), nonvar(Init), Init = File:Line, !, ( compound(TermPos), arg(1, TermPos, CharCount), integer(CharCount) % test it is valid -> From = file_term_position(File, TermPos) ; walk_option_source(OTerm, false) -> From = file(File, Line, -1, _) ; From = _, throw(missing(subterm_positions)) ), print_reference2(Goal, From, Why, OTerm). print_reference(Goal, _, Why, OTerm) :- print_reference2(Goal, _, Why, OTerm). print_reference2(Goal, From, trace, OTerm) :- walk_option_on_trace(OTerm, Closure), nonvar(Closure), walk_option_caller(OTerm, Caller), call(Closure, Goal, Caller, From), !. print_reference2(Goal, From, trace, OTerm) :- walk_option_on_edge(OTerm, Closure), nonvar(Closure), walk_option_caller(OTerm, Caller), translate_location(From, Dict), call(Closure, Goal, Caller, Dict), !. print_reference2(Goal, From, Why, _OTerm) :- make_message(Why, Goal, From, Message, Level), print_message(Level, Message). make_message(undefined, Goal, Context, error(existence_error(procedure, PI), Context), error) :- goal_pi(Goal, PI). make_message(not_callable, Goal, Context, error(type_error(callable, Goal), Context), error). make_message(trace, Goal, Context, trace_call_to(PI, Context), informational) :- goal_pi(Goal, PI). goal_pi(Goal, M:Name/Arity) :- strip_module(Goal, M, Head), callable(Head), !, functor(Head, Name, Arity). goal_pi(Goal, Goal). :- dynamic possible_meta_predicate/2. %! register_possible_meta_clause(+ClauseRef) is det. % % ClausesRef contains as call to a meta-predicate. Remember to % analyse this predicate. We only analyse the predicate if it is % loaded from a user module. I.e., system and library modules are % trusted. register_possible_meta_clause(ClausesRef) :- nonvar(ClausesRef), clause_property(ClausesRef, predicate(PI)), pi_head(PI, Head, Module), module_property(Module, class(user)), \+ predicate_property(Module:Head, meta_predicate(_)), \+ inferred_meta_predicate(Module:Head, _), \+ possible_meta_predicate(Head, Module), !, assertz(possible_meta_predicate(Head, Module)). register_possible_meta_clause(_). pi_head(Module:Name/Arity, Head, Module) :- !, functor(Head, Name, Arity). pi_head(_, _, _) :- assertion(fail). %! infer_new_meta_predicates(-MetaSpecs, +OTerm) is det. infer_new_meta_predicates([], OTerm) :- walk_option_infer_meta_predicates(OTerm, false), !. infer_new_meta_predicates(MetaSpecs, OTerm) :- findall(Module:MetaSpec, ( retract(possible_meta_predicate(Head, Module)), infer_meta_predicate(Module:Head, MetaSpec), ( walk_option_infer_meta_predicates(OTerm, all) -> true ; calling_metaspec(MetaSpec) ) ), MetaSpecs). %! calling_metaspec(+Head) is semidet. % % True if this is a meta-specification that makes a difference to % the code walker. calling_metaspec(Head) :- arg(_, Head, Arg), calling_metaarg(Arg), !. calling_metaarg(I) :- integer(I), !. calling_metaarg(^). calling_metaarg(//). %! walk_meta_call(+Index, +GoalHead, +MetaHead, +Module, %! +ArgPosList, +EndPos, +OTerm) % % Walk a call to a meta-predicate. This walks all meta-arguments % labeled with an integer, ^ or //. % % @arg EndPos reflects the end of the term. This is used if the % number of arguments in the compiled form exceeds the % number of arguments in the term read. walk_meta_call(I, Head, Meta, M, ArgPosList, EPos, OTerm) :- arg(I, Head, AS), !, ( ArgPosList = [ArgPos|ArgPosTail] -> true ; ArgPos = EPos, ArgPosTail = [] ), ( integer(AS) -> arg(I, Meta, MA), extend(MA, AS, Goal, ArgPos, ArgPosEx, OTerm), walk_called(Goal, M, ArgPosEx, OTerm) ; AS == (^) -> arg(I, Meta, MA), remove_quantifier(MA, Goal, ArgPos, ArgPosEx, M, MG, OTerm), walk_called(Goal, MG, ArgPosEx, OTerm) ; AS == (//) -> arg(I, Meta, DCG), walk_dcg_body(DCG, M, ArgPos, OTerm) ; true ), succ(I, I2), walk_meta_call(I2, Head, Meta, M, ArgPosTail, EPos, OTerm). walk_meta_call(_, _, _, _, _, _, _). remove_quantifier(Goal, _, TermPos, TermPos, M, M, OTerm) :- var(Goal), !, undecided(Goal, TermPos, OTerm). remove_quantifier(_^Goal0, Goal, term_position(_,_,_,_,[_,GPos]), TermPos, M0, M, OTerm) :- !, remove_quantifier(Goal0, Goal, GPos, TermPos, M0, M, OTerm). remove_quantifier(M1:Goal0, Goal, term_position(_,_,_,_,[_,GPos]), TermPos, _, M, OTerm) :- !, remove_quantifier(Goal0, Goal, GPos, TermPos, M1, M, OTerm). remove_quantifier(Goal, Goal, TermPos, TermPos, M, M, _). %! walk_called_by(+Called:list, +Module, +Goal, +TermPos, +OTerm) % % Walk code explicitly mentioned to be called through the hook % prolog:called_by/2. walk_called_by([], _, _, _, _). walk_called_by([H|T], M, Goal, TermPos, OTerm) :- ( H = G0+N -> subterm_pos(G0, M, Goal, TermPos, G, GPos), ( extend(G, N, G2, GPos, GPosEx, OTerm) -> walk_called(G2, M, GPosEx, OTerm) ; true ) ; subterm_pos(H, M, Goal, TermPos, G, GPos), walk_called(G, M, GPos, OTerm) ), walk_called_by(T, M, Goal, TermPos, OTerm). subterm_pos(Sub, _, Term, TermPos, Sub, SubTermPos) :- subterm_pos(Sub, Term, TermPos, SubTermPos), !. subterm_pos(Sub, M, Term, TermPos, G, SubTermPos) :- nonvar(Sub), Sub = M:H, !, subterm_pos(H, M, Term, TermPos, G, SubTermPos). subterm_pos(Sub, _, _, _, Sub, _). subterm_pos(Sub, Term, TermPos, SubTermPos) :- subterm_pos(Sub, Term, same_term, TermPos, SubTermPos), !. subterm_pos(Sub, Term, TermPos, SubTermPos) :- subterm_pos(Sub, Term, ==, TermPos, SubTermPos), !. subterm_pos(Sub, Term, TermPos, SubTermPos) :- subterm_pos(Sub, Term, =@=, TermPos, SubTermPos), !. subterm_pos(Sub, Term, TermPos, SubTermPos) :- subterm_pos(Sub, Term, subsumes_term, TermPos, SubTermPos), !. %! walk_dcg_body(+Body, +Module, +TermPos, +OTerm) % % Walk a DCG body that is meta-called. walk_dcg_body(Var, _Module, TermPos, OTerm) :- var(Var), !, undecided(Var, TermPos, OTerm). walk_dcg_body([], _Module, _, _) :- !. walk_dcg_body([_|_], _Module, _, _) :- !. walk_dcg_body(String, _Module, _, _) :- string(String), !. walk_dcg_body(!, _Module, _, _) :- !. walk_dcg_body(M:G, _, term_position(_,_,_,_,[MPos,Pos]), OTerm) :- !, ( nonvar(M) -> walk_dcg_body(G, M, Pos, OTerm) ; undecided(M, MPos, OTerm) ). walk_dcg_body((A,B), M, term_position(_,_,_,_,[PA,PB]), OTerm) :- !, walk_dcg_body(A, M, PA, OTerm), walk_dcg_body(B, M, PB, OTerm). walk_dcg_body((A->B), M, term_position(_,_,_,_,[PA,PB]), OTerm) :- !, walk_dcg_body(A, M, PA, OTerm), walk_dcg_body(B, M, PB, OTerm). walk_dcg_body((A*->B), M, term_position(_,_,_,_,[PA,PB]), OTerm) :- !, walk_dcg_body(A, M, PA, OTerm), walk_dcg_body(B, M, PB, OTerm). walk_dcg_body((A;B), M, term_position(_,_,_,_,[PA,PB]), OTerm) :- !, ( walk_dcg_body(A, M, PA, OTerm) ; walk_dcg_body(B, M, PB, OTerm) ). walk_dcg_body((A|B), M, term_position(_,_,_,_,[PA,PB]), OTerm) :- !, ( walk_dcg_body(A, M, PA, OTerm) ; walk_dcg_body(B, M, PB, OTerm) ). walk_dcg_body({G}, M, brace_term_position(_,_,PG), OTerm) :- !, walk_called(G, M, PG, OTerm). walk_dcg_body(G, M, TermPos, OTerm) :- extend(G, 2, G2, TermPos, TermPosEx, OTerm), walk_called(G2, M, TermPosEx, OTerm). %! subterm_pos(+SubTerm, +Term, :Cmp, %! +TermPosition, -SubTermPos) is nondet. % % True when SubTerm is a sub term of Term, compared using Cmp, % TermPosition describes the term layout of Term and SubTermPos % describes the term layout of SubTerm. Cmp is typically one of % =same_term=, =|==|=, =|=@=|= or =|subsumes_term|= :- meta_predicate subterm_pos(+, +, 2, +, -), sublist_pos(+, +, +, +, 2, -). :- public subterm_pos/5. % used in library(check). subterm_pos(_, _, _, Pos, _) :- var(Pos), !, fail. subterm_pos(Sub, Term, Cmp, Pos, Pos) :- call(Cmp, Sub, Term), !. subterm_pos(Sub, Term, Cmp, term_position(_,_,_,_,ArgPosList), Pos) :- is_list(ArgPosList), compound(Term), nth1(I, ArgPosList, ArgPos), arg(I, Term, Arg), subterm_pos(Sub, Arg, Cmp, ArgPos, Pos). subterm_pos(Sub, Term, Cmp, list_position(_,_,ElemPosList,TailPos), Pos) :- sublist_pos(ElemPosList, TailPos, Sub, Term, Cmp, Pos). subterm_pos(Sub, {Arg}, Cmp, brace_term_position(_,_,ArgPos), Pos) :- subterm_pos(Sub, Arg, Cmp, ArgPos, Pos). sublist_pos([EP|TP], TailPos, Sub, [H|T], Cmp, Pos) :- ( subterm_pos(Sub, H, Cmp, EP, Pos) ; sublist_pos(TP, TailPos, Sub, T, Cmp, Pos) ). sublist_pos([], TailPos, Sub, Tail, Cmp, Pos) :- TailPos \== none, subterm_pos(Sub, Tail, Cmp, TailPos, Pos). %! extend(+Goal, +ExtraArgs, +TermPosIn, -TermPosOut, +OTerm) % % @bug: extend(Goal, 0, Goal, TermPos, TermPos, _) :- !. extend(Goal, _, _, TermPos, TermPos, OTerm) :- var(Goal), !, undecided(Goal, TermPos, OTerm). extend(M:Goal, N, M:GoalEx, term_position(F,T,FT,TT,[MPos,GPosIn]), term_position(F,T,FT,TT,[MPos,GPosOut]), OTerm) :- !, ( var(M) -> undecided(N, MPos, OTerm) ; true ), extend(Goal, N, GoalEx, GPosIn, GPosOut, OTerm). extend(Goal, N, GoalEx, TermPosIn, TermPosOut, _) :- callable(Goal), !, Goal =.. List, length(Extra, N), extend_term_pos(TermPosIn, N, TermPosOut), append(List, Extra, ListEx), GoalEx =.. ListEx. extend(Closure, N, M:GoalEx, TermPosIn, TermPosOut, OTerm) :- blob(Closure, closure), % call(Closure, A1, ...) !, '$closure_predicate'(Closure, M:Name/Arity), length(Extra, N), extend_term_pos(TermPosIn, N, TermPosOut), GoalEx =.. [Name|Extra], ( N =:= Arity -> true ; print_reference(Closure, TermPosIn, closure_arity_mismatch, OTerm) ). extend(Goal, _, _, TermPos, _, OTerm) :- print_reference(Goal, TermPos, not_callable, OTerm). extend_term_pos(Var, _, _) :- var(Var), !. extend_term_pos(term_position(F,T,FT,TT,ArgPosIn), N, term_position(F,T,FT,TT,ArgPosOut)) :- !, length(Extra, N), maplist(=(0-0), Extra), append(ArgPosIn, Extra, ArgPosOut). extend_term_pos(F-T, N, term_position(F,T,F,T,Extra)) :- length(Extra, N), maplist(=(0-0), Extra). %! variants(+SortedList, -Variants) is det. variants([], []). variants([H|T], List) :- variants(T, H, List). variants([], H, [H]). variants([H|T], V, List) :- ( H =@= V -> variants(T, V, List) ; List = [V|List2], variants(T, H, List2) ). %! predicate_in_module(+Module, ?PI) is nondet. % % True if PI is a predicate locally defined in Module. predicate_in_module(Module, PI) :- current_predicate(Module:PI), PI = Name/Arity, \+ hidden_predicate(Name, Arity), functor(Head, Name, Arity), \+ predicate_property(Module:Head, imported_from(_)). hidden_predicate(Name, _) :- atom(Name), % []/N is not hidden sub_atom(Name, 0, _, _, '$wrap$'). /******************************* * ENUMERATE CLAUSES * *******************************/ %! prolog_program_clause(-ClauseRef, +Options) is nondet. % % True when ClauseRef is a reference for clause in the program. % Options is a subset of the options processed by % prolog_walk_code/1. The logic for deciding on which clauses to % enumerate is shared with prolog_walk_code/1. % % * module(?Module) % * module_class(+list(Classes)) prolog_program_clause(ClauseRef, Options) :- make_walk_option(Options, OTerm, _), setup_call_cleanup( true, ( current_module(Module), scan_module(Module, OTerm), module_clause(Module, ClauseRef, OTerm) ; retract(multifile_predicate(Name, Arity, MM)), multifile_clause(ClauseRef, MM:Name/Arity, OTerm) ; initialization_clause(ClauseRef, OTerm) ), retractall(multifile_predicate(_,_,_))). module_clause(Module, ClauseRef, _OTerm) :- predicate_in_module(Module, Name/Arity), \+ multifile_predicate(Name, Arity, Module), functor(Head, Name, Arity), ( predicate_property(Module:Head, multifile) -> assertz(multifile_predicate(Name, Arity, Module)), fail ; predicate_property(Module:Head, Property), no_enum_property(Property) -> fail ; catch(nth_clause(Module:Head, _, ClauseRef), _, fail) ). no_enum_property(foreign). multifile_clause(ClauseRef, M:Name/Arity, OTerm) :- functor(Head, Name, Arity), catch(clauseref_not_from_development(M:Head, ClauseRef, OTerm), _, fail). clauseref_not_from_development(Module:Head, Ref, OTerm) :- nth_clause(Module:Head, _N, Ref), \+ ( clause_property(Ref, file(File)), module_property(LoadModule, file(File)), \+ scan_module(LoadModule, OTerm) ). initialization_clause(ClauseRef, OTerm) :- catch(clause(system:'$init_goal'(_File, M:_Goal, SourceLocation), true, ClauseRef), _, fail), walk_option_initialization(OTerm, SourceLocation), scan_module(M, OTerm). %! translate_location(+Loc, -Dict) is det. translate_location(clause_term_position(ClauseRef, TermPos), Dict), clause_property(ClauseRef, file(File)) => arg(1, TermPos, CharCount), filepos_line(File, CharCount, Line, LinePos), Dict = _{ clause: ClauseRef, file: File, character_count: CharCount, line_count: Line, line_position: LinePos }. translate_location(clause(ClauseRef), Dict), clause_property(ClauseRef, file(File)), clause_property(ClauseRef, line_count(Line)) => Dict = _{ clause: ClauseRef, file: File, line_count: Line }. translate_location(clause(ClauseRef), Dict) => Dict = _{ clause: ClauseRef }. translate_location(file_term_position(Path, TermPos), Dict) => arg(1, TermPos, CharCount), filepos_line(Path, CharCount, Line, LinePos), Dict = _{ file: Path, character_count: CharCount, line_count: Line, line_position: LinePos }. translate_location(Var, Dict), var(Var) => Dict = _{}. /******************************* * MESSAGES * *******************************/ :- multifile prolog:message//1, prolog:message_location//1. prolog:message(trace_call_to(PI, Context)) --> [ 'Call to ~q at '-[PI] ], '$messages':swi_location(Context). prolog:message_location(clause_term_position(ClauseRef, TermPos)) --> { clause_property(ClauseRef, file(File)) }, message_location_file_term_position(File, TermPos). prolog:message_location(clause(ClauseRef)) --> { clause_property(ClauseRef, file(File)), clause_property(ClauseRef, line_count(Line)) }, !, [ url(File:Line), ': ' ]. prolog:message_location(clause(ClauseRef)) --> { clause_name(ClauseRef, Name) }, [ '~w: '-[Name] ]. prolog:message_location(file_term_position(Path, TermPos)) --> message_location_file_term_position(Path, TermPos). prolog:message(codewalk(reiterate(New, Iteration, CPU))) --> [ 'Found new meta-predicates in iteration ~w (~3f sec)'- [Iteration, CPU], nl ], meta_decls(New), [ 'Restarting analysis ...'-[], nl ]. meta_decls([]) --> []. meta_decls([H|T]) --> [ ':- meta_predicate ~q.'-[H], nl ], meta_decls(T). message_location_file_term_position(File, TermPos) --> { arg(1, TermPos, CharCount), filepos_line(File, CharCount, Line, LinePos) }, [ url(File:Line:LinePos), ': ' ]. %! filepos_line(+File, +CharPos, -Line, -Column) is det. % % @arg CharPos is 0-based character offset in the file. % @arg Column is the current column, counting tabs as 8 spaces. filepos_line(File, CharPos, Line, LinePos) :- setup_call_cleanup( ( open(File, read, In), open_null_stream(Out) ), ( copy_stream_data(In, Out, CharPos), stream_property(In, position(Pos)), stream_position_data(line_count, Pos, Line), stream_position_data(line_position, Pos, LinePos) ), ( close(Out), close(In) )).