Doc: module related

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Ulrich Neumerkel 2009-06-09 00:32:01 +02:00 committed by Costa Vitor
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@ -2089,13 +2089,12 @@ are global to the system. Moreover, the module system is flat, meaning
that we do not support a hierarchy of modules. Modules can
automatically import other modules, though. For compatibility with other
module systems the YAP module system is non-strict, meaning both that
there is both a way to access predicates private to a module and that it
there is a way to access predicates private to a module and that it
is possible to declare predicates for a module from some other module.
YAP allows one to ignore the module system if one does not want to use
it. Last note that using the module system does not introduce any
significant overheads: only meta-calls that cross module boundaries are
slowed down by the presence of modules.
significant overheads.
@menu
@ -2145,7 +2144,7 @@ module. Otherwise, it is the module the file is being loaded into or the
type-in module.
One can override this rule by prefixing a goal with the module it is
supposed to be executed into, say:
supposed to be executed in, say:
@example
nasa:launch(apollo,13).
@end example
@ -2165,17 +2164,18 @@ A new module is defined by a @code{module} declaration:
@findex module/2 (directive)
@syindex module/2 (directive)
@cnindex module/2 (directive)
This predicate defines the file where it appears as a module file; it
This directive defines the file where it appears as a module file; it
must be the first declaration in the file.
@var{M} must be an atom specifying the module name; @var{L} must be a list
containing the module's public predicates specification, in the form
@code{[predicate_name/arity,...]}.
The public predicates of a module file can be made accessible by other
files through the predicates @code{consult/1}, @code{reconsult/1},
@code{ensure_loaded/1} or @code{use_module/2}. The non-public predicates
files through the directives @code{use_module/1}, @code{use_module/2},
@code{ensure_loaded/1} and the predicates @code{consult/1} or
@code{reconsult/1}. The non-public predicates
of a module file are not visible by other files; they can, however, be
accessed if the module name is prefixed to the file name through the
accessed by prefixing the module name with the
@code{:/2} operator.
@end table
@ -2187,8 +2187,8 @@ The built-in @code{module/1} sets the current source module:
@findex module/3 (directive)
@syindex module/3 (directive)
@cnindex module/3 (directive)
Similar to @code{module/2}, this predicate defines the file where it
appears as a module file; it must be the first declaration in the file.
Similar to @code{module/2}, this directive defines the file where it
appears in as a module file; it must be the first declaration in the file.
@var{M} must be an atom specifying the module name; @var{L} must be a
list containing the module's public predicates specification, in the
form @code{[predicate_name/arity,...]}.
@ -2264,27 +2264,22 @@ importing the predicates specified in the list @var{L}.
The module system must know whether predicates operate on goals or
clauses. Otherwise, such predicates would call a goal in the module they
were defined, instead of calling it in the module they are currently
executing. So, for instance:
executing. So, for instance, consider a file example.pl:
@example
:- module(example,[a/1]).
...
a(G) :- call(G)
...
@end example
The expected behavior for this procedure is to execute goal @var{G}
within the current module, that is, within @code{example}.
On the other hand, when executing @code{call/1} the system only knows
where @code{call/1} was defined, that is, it only knows of
@code{primitives}. A similar problem arises for @code{assert/1} and
friends.
We import this module with @code{use_module(example)} into module
@code{user}. The expected behavior for a goal @code{a(p)} is to
execute goal @code{p} within the module @code{user}. However,
@code{a/1} will call @code{p} within module @code{example}.
The @code{meta_predicate/1} declaration informs the system that some
arguments of a procedure are goals, clauses or clauses heads, and that
these arguments must be expanded to receive the current source module:
arguments of a predicate are goals, clauses, clauses heads or other
terms related to a module, and that these arguments must be prefixed
with the current source module:
@table @code
@ -2292,35 +2287,44 @@ these arguments must be expanded to receive the current source module:
@findex meta_predicate/1 (directive)
@syindex meta_predicate/1 (directive)
@cnindex meta_predicate/1 (directive)
Each @var{Gi} is a mode specification. For example, a declaration for
@code{call/1} and @code{setof/3} would be of the form:
Each @var{Gi} is a mode specification.
If the argument is @code{:} or an integer, the argument is a call and
must be expanded. Otherwise, the argument is not expanded. Note
that the system already includes declarations for all built-ins.
For example, the declaration for @code{call/1} and @code{setof/3} are:
@example
:- meta_predicate call(:), setof(?,:,?).
@end example
If the argument is @code{:} or an integer, the argument is a call and
must be expanded. Otherwise, the argument should not be expanded. Note
that the system already includes declarations for all built-ins.
@end table
In the previous example, the only argument to @code{call/1} must be
expanded, resulting in the following code:
The previous example is expanded to the following code which explains,
why the goal @code{a(p)} calls @code{p} in @code{example} and not in
@code{user}. The goal @code{call(G)} is expanded because of the
meta-predicate declaration for @code{call/1}.
@example
:- module(example,[a/1]).
...
a(G) :- call(example:G)
...
@end example
You can avoid goal expansion by using @code{module_transparent/1}.
By adding a meta-predicate declaration for @code{a/1}, the goal
@code{a(p)} in module user will be expanded to @code{a(user:p)}
thereby preserving the module information.
@example
:- module(example,[a/1]).
:- meta_predicate a(:).
a(G) :- call(G)
@end example
An alternate mechanism is the directive @code{module_transparent/1}
offered for compatibility with SWI-Prolog.
@table @code
@ -2328,7 +2332,8 @@ You can avoid goal expansion by using @code{module_transparent/1}.
@findex module_transparent/1 (directive)
@syindex module_transparent/1 (directive)
@cnindex module_transparent/1 (directive)
@var{Preds} is a comma separated list of name/arity pairs (like
@var{Preds} is a comma separated sequence of name/arity predicate
indicators (like
@code{dynamic/1}). Each goal associated with a transparent declared
predicate will inherit the context module from its parent goal.
@end table