Protocols enable the separation between interface and implementation: several objects can implement the same protocol and an object can implement several protocols. There are no pre-defined protocols in Logtalk.
We can define a new object in the same way we write Prolog code: by using a text editor. Logtalk source files may contain one or more objects, categories, or protocols. If you prefer to define each entity in its own source file, it is recommended that the file be named after the protocol. By default, all Logtalk source files use the extension .lgt
but this is optional and can be set in the configuration files. Compiled source files (by the Logtalk preprocessor) have, by default, a .pl
extension. Again, this can be set to match the needs of a particular Prolog compiler in the corresponding configuration file. For example, we may define a protocol named listp
and save it in a listp.lgt
source file that will be compiled to a listp.pl
Prolog file.
Protocol names must be atoms. Objects, categories and protocols share the same name space: we can not have a protocol with the same name as an object or a category.
Protocol directives are textually encapsulated by using two Logtalk directives: protocol/1-2
and end_protocol/0
. The most simple protocol will be one that is self-contained, not depending on any other Logtalk entity:
:- protocol(Protocol). ... :- end_protocol.
If a protocol extends one or more protocols, then the opening directive will be:
:- protocol(Protocol, extends(OtherProtocol)). ... :- end_protocol.
We can find, by backtracking, all defined protocols by using the current_protocol/1
built-in predicate with an uninstantiated variable:
| ?- current_protocol(Protocol).
This predicate can also be used to test if a protocol is defined by calling it with a valid protocol identifier (an atom).
We can create a new (dynamic) protocol in runtime by calling the Logtalk built-in predicate create_protocol/3
:
| ?- create_protocol(Protocol, Relations, Directives).
The first argument, the name of the new protocol (a Prolog atom), should not match an existing entity name. The remaining two arguments correspond to the relations described in the opening protocol directive and to the protocol directives.
For instance, the call:
| ?- create_protocol(ppp, [extends(qqq)], [public(foo/1, bar/1)]).
is equivalent to compiling and loading the protocol:
:- protocol(ppp, extends(qqq)). :- dynamic. :- public(foo/1, bar/1). :- end_protocol.
If we need to create a lot of (dynamic) protocols at runtime, then is best to define a metaclass or a prototype with a predicate that will call this built-in predicate in order to provide more sophisticated behaviour.
Dynamic protocols can be abolished using the abolish_protocol/1
built-in predicate:
| ?- abolish_protocol(Protocol).
The argument must be an identifier of a defined dynamic protocol, otherwise an error will be thrown.
Protocol directives are used to set initialization goals and protocol properties.
We can define a goal to be executed as soon as a protocol is (compiled and) loaded to memory with the initialization/1
directive:
:- initialization(Goal).
The argument can be any valid Prolog or Logtalk goal, including a message sending call.
As usually happens with Prolog code, a protocol can be either static or dynamic. A protocol created during the execution of a program is always dynamic. A protocol defined in a file can be either dynamic or static. Dynamic protocols are declared by using the dynamic/0
directive in the protocol source code:
:- dynamic.
Let us just remember that the loss of performance of the dynamic code is usually of considerable importance to the static code. We should only use dynamic protocols when these need to be abolished during program execution.
A protocol can be documented with arbitrary user-defined information by using the info/1
directive:
:- info(List).
See the Documenting Logtalk programs session for details.
Logtalk provides two sets of built-in predicates that enable us to query the system about the possible relationships that a protocol have with other entities.
The built-in predicates extends_protocol/2
and extends_protocol/3
return all pairs of protocols so that the first one extends the second:
| ?- extends_protocol(Protocol1, Protocol2).
or, if we want to know the extension scope:
| ?- extends_protocol(Protocol1, Protocol2, Scope).
To find which objects or categories implement which protocols we can call the implements_protocol/2
or implements_protocol/2
built-in predicates:
| ?- implements_protocol(ObjectOrCategory, Protocol).
or, if we want to know the implementation scope:
| ?- implements_protocol(ObjectOrCategory, Protocol, Scope).
Note that, if we use an uninstantiated variable for the first argument, we will need to use the current_object/1
or current_category/1
built-in predicates to identify the kind of entity returned.
We can find the properties of defined protocols by calling the protocol_property/2
built-in predicate:
| ?- protocol_property(Protocol, Property).
A protocol may have the property static
, dynamic
, or built_in
. Dynamic protocols can be abolished in runtime by calling the abolish_protocol/1
built-in predicate.
Any number of objects or categories can implement a protocol. The syntax is very simple:
:- object(Object, implements(Protocol)). ... :- end_object.
or, in the case of a category:
:- category(Object, implements(Protocol)). ... :- end_category.
To make all public predicates declared via an implemented protocol protected or to make all public and protected predicates private we prefix the protocol's name with the corresponding keyword. For instance:
:- object(Object, implements(private::Protocol)). ... :- end_object.
or:
:- object(Object, implements(protected::Protocol)). ... :- end_object.
Omitting the scope keyword is equivalent to writing:
:- object(Object, implements(public::Protocol)). ... :- end_object.
The same rules applies to protocols implemented by categories.