/* $Id$
Part of SWI-Prolog
Author: Jan Wielemaker
E-mail: J.Wielemaker@cs.vu.nl
WWW: http://www.swi-prolog.org
Copyright (C): 1985-2010, University of Amsterdam, VU University Amsterdam
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License
as published by the Free Software Foundation; either version 2
of the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the Free Software
Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
As a special exception, if you link this library with other files,
compiled with a Free Software compiler, to produce an executable, this
library does not by itself cause the resulting executable to be covered
by the GNU General Public License. This exception does not however
invalidate any other reasons why the executable file might be covered by
the GNU General Public License.
*/
:- module(prolog_explain,
[ explain/1,
explain/2
]).
:- use_module(library(helpidx)).
:- use_module(library(lists)).
:- use_module(library(apply)).
/** <module> Describe Prolog Terms
The library(explain) describes prolog-terms. The most useful
functionality is its cross-referencing function.
==
?- explain(subset(_,_)).
"subset(_, _)" is a compound term
Referenced from 2-th clause of lists:subset/2
Referenced from 46-th clause of prolog_xref:imported/3
Referenced from 68-th clause of prolog_xref:imported/3
lists:subset/2 is a predicate defined in
/staff/jan/lib/pl-5.6.17/library/lists.pl:307
Referenced from 2-th clause of lists:subset/2
Possibly referenced from 2-th clause of lists:subset/2
==
Note that the help-tool for XPCE provides a nice graphical
cross-referencer.
*/
%% explain(@Term) is det
%
% Write all information known about Term to the current output.
explain(Item) :-
explain(Item, Explanation),
writeln(Explanation),
fail.
explain(_).
/********************************
* BASIC TYPES *
*********************************/
%% explain(@Term, -Explanation) is nondet.
%
% Explanation describes information about Term.
explain(Var, Explanation) :-
var(Var), !,
utter(Explanation, '"~w" is an unbound variable', [Var]).
explain(I, Explanation) :-
integer(I), !,
utter(Explanation, '"~w" is an integer', [I]).
explain(F, Explanation) :-
float(F), !,
utter(Explanation, '"~w" is a floating point number', [F]).
explain(S, Explanation) :-
string(S), !,
utter(Explanation, '"~w" is a string', S).
explain([], Explanation) :- !,
utter(Explanation, '"[]" is a special constant denoting an empty list', []).
explain(A, Explanation) :-
atom(A),
utter(Explanation, '"~w" is an atom', [A]).
explain(A, Explanation) :-
atom(A),
current_op(Pri, F, A),
op_type(F, Type),
utter(Explanation, '"~w" is a ~w (~w) operator of priority ~d',
[A, Type, F, Pri]).
explain(A, Explanation) :-
atom(A), !,
explain_atom(A, Explanation).
explain([H|T], Explanation) :-
is_list(T), !,
List = [H|T],
length(List, L),
( utter(Explanation, '"~p" is a proper list with ~d elements',
[List, L])
; maplist(printable, List),
utter(Explanation, '~t~8|Text is "~s"', [List])
).
explain([H|T], Explanation) :- !,
length([H|T], L), !,
utter(Explanation, '"~p" is a not-closed list with ~d elements',
[[H|T], L]).
explain(Name/Arity, Explanation) :-
atom(Name),
integer(Arity), !,
functor(Head, Name, Arity),
known_predicate(Module:Head),
( Module == system
-> true
; \+ predicate_property(Module:Head, imported_from(_))
),
explain_predicate(Module:Head, Explanation).
explain(Module:Name/Arity, Explanation) :-
atom(Module), atom(Name), integer(Arity), !,
functor(Head, Name, Arity),
explain_predicate(Module:Head, Explanation).
explain(Module:Head, Explanation) :-
callable(Head), !,
explain_predicate(Module:Head, Explanation).
explain(Term, Explanation) :-
numbervars(Term, 0, _, [singletons(true)]),
utter(Explanation, '"~W" is a compound term',
[Term, [quoted(true), numbervars(true)]]).
explain(Term, Explanation) :-
explain_functor(Term, Explanation).
%% known_predicate(:Head)
%
% Succeeds if we know anything about this predicate. Undefined
% predicates are considered `known' for this purpose, so we can
% provide referenced messages on them.
known_predicate(Pred) :-
current_predicate(_, Pred), !.
known_predicate(Pred) :-
predicate_property(Pred, undefined).
known_predicate(_:Head) :-
functor(Head, Name, Arity),
'$in_library'(Name, Arity, _Path).
op_type(X, prefix) :-
atom_chars(X, [f, _]).
op_type(X, infix) :-
atom_chars(X, [_, f, _]).
op_type(X, postfix) :-
atom_chars(X, [_, f]).
printable(C) :-
integer(C),
between(32, 126, C).
/********************************
* ATOMS *
*********************************/
explain_atom(A, Explanation) :-
referenced(A, Explanation).
explain_atom(A, Explanation) :-
current_predicate(A, Module:Head),
( Module == system
-> true
; \+ predicate_property(Module:Head, imported_from(_))
),
explain_predicate(Module:Head, Explanation).
explain_atom(A, Explanation) :-
predicate_property(Module:Head, undefined),
functor(Head, A, _),
explain_predicate(Module:Head, Explanation).
/********************************
* FUNCTOR *
*********************************/
explain_functor(Head, Explanation) :-
referenced(Head, Explanation).
explain_functor(Head, Explanation) :-
current_predicate(_, Module:Head),
\+ predicate_property(Module:Head, imported_from(_)),
explain_predicate(Module:Head, Explanation).
explain_functor(Head, Explanation) :-
predicate_property(M:Head, undefined),
( functor(Head, N, A),
utter(Explanation,
'~w:~w/~d is an undefined predicate', [M,N,A])
; referenced(M:Head, Explanation)
).
/********************************
* PREDICATE *
*********************************/
lproperty(built_in, ' built-in', []).
lproperty(dynamic, ' dynamic', []).
lproperty(multifile, ' multifile', []).
lproperty(transparent, ' meta', []).
tproperty(imported_from(Module), ' imported from module ~w', [Module]).
tproperty(file(File), ' defined in~n~t~8|~w', [File]).
tproperty(line_count(Number), ':~d', [Number]).
tproperty(autoload, ' that can be autoloaded', []).
combine_utterances(Pairs, Explanation) :-
maplist(first, Pairs, Fmts),
atomic_list_concat(Fmts, Format),
maplist(second, Pairs, ArgList),
flatten(ArgList, Args),
utter(Explanation, Format, Args).
first(A-_B, A).
second(_A-B, B).
%% explain_predicate(:Head, -Explanation) is det.
explain_predicate(Pred, Explanation) :-
Pred = Module:Head,
functor(Head, Name, Arity),
( predicate_property(Pred, undefined)
-> utter(Explanation,
'~w:~w/~d is an undefined predicate', [Module,Name,Arity])
; ( var(Module)
-> U0 = '~w/~d is a' - [Name, Arity]
; U0 = '~w:~w/~d is a' - [Module, Name, Arity]
),
findall(Fmt-Arg, (lproperty(Prop, Fmt, Arg),
predicate_property(Pred, Prop)),
U1),
U2 = ' predicate' - [],
findall(Fmt-Arg, (tproperty(Prop, Fmt, Arg),
predicate_property(Pred, Prop)),
U3),
flatten([U0, U1, U2, U3], Utters),
combine_utterances(Utters, Explanation)
).
explain_predicate(Pred, Explanation) :-
predicate_property(Pred, built_in),
Pred = _Module:Head,
functor(Head, Name, Arity),
predicate(Name, Arity, Summary, _, _),
utter(Explanation, '~t~8|Summary: ``~w''''', [Summary]).
explain_predicate(Pred, Explanation) :-
referenced(Pred, Explanation).
/********************************
* REFERENCES *
*********************************/
referenced(Term, Explanation) :-
current_predicate(_, Module:Head),
( predicate_property(Module:Head, built_in)
-> current_prolog_flag(access_level, system)
; true
),
\+ predicate_property(Module:Head, imported_from(_)),
Module:Head \= help_index:predicate(_,_,_,_,_),
nth_clause(Module:Head, N, Ref),
'$xr_member'(Ref, Term),
utter_referenced(Module:Head, N, Ref,
'Referenced', Explanation).
referenced(_:Head, Explanation) :-
current_predicate(_, Module:Head),
( predicate_property(Module:Head, built_in)
-> current_prolog_flag(access_level, system)
; true
),
\+ predicate_property(Module:Head, imported_from(_)),
nth_clause(Module:Head, N, Ref),
'$xr_member'(Ref, Head),
utter_referenced(Module:Head, N, Ref,
'Possibly referenced', Explanation).
utter_referenced(_Module:class(_,_,_,_,_,_), _, _, _, _) :-
current_prolog_flag(xpce, true), !,
fail.
utter_referenced(_Module:lazy_send_method(_,_,_), _, _, _, _) :-
current_prolog_flag(xpce, true), !,
fail.
utter_referenced(_Module:lazy_get_method(_,_,_), _, _, _, _) :-
current_prolog_flag(xpce, true), !,
fail.
utter_referenced(pce_xref:exported(_,_), _, _, _, _) :- !,
fail.
utter_referenced(pce_xref:defined(_,_,_), _, _, _, _) :- !,
fail.
utter_referenced(pce_xref:called(_,_,_), _, _, _, _) :- !,
fail.
utter_referenced(pce_principal:send_implementation(_, _, _),
_, Ref, Text, Explanation) :-
current_prolog_flag(xpce, true), !,
xpce_method_id(Ref, Id),
utter(Explanation, '~t~8|~w from ~w', [Text, Id]).
utter_referenced(pce_principal:get_implementation(Id, _, _, _),
_, Ref, Text, Explanation) :-
current_prolog_flag(xpce, true), !,
xpce_method_id(Ref, Id),
utter(Explanation, '~t~8|~w from ~w', [Text, Id]).
utter_referenced(Module:Head, N, _Ref, Text, Explanation) :-
functor(Head, Name, Arity),
utter(Explanation,
'~t~8|~w from ~d-th clause of ~w:~w/~d',
[Text, N, Module, Name, Arity]).
xpce_method_id(Ref, Id) :-
clause(Head, _Body, Ref),
strip_module(Head, _, H),
arg(1, H, Id).
/********************************
* UTTER *
*********************************/
utter(Explanation, Fmt, Args) :-
format(string(Explanation), Fmt, Args).