Objects

The main goal of Logtalk objects is the encapsulation and reuse of predicates. Instead of a single database containing all your code, Logtalk objects provide separated namespaces or databases allowing the partitioning of code in more manageable parts. Logtalk is a declarative programming language and does not aim to bring some sort of new dynamic state change concept to Logic Programming or Prolog.

Logtalk, defines two built-in objects, user and logtalk, which are described at the end of this section.

Objects, prototypes, classes, and instances

There are only three kinds of encapsulation entities in Logtalk: objects, protocols, and categories. Logtalk uses the term object in a broad sense. The terms prototype, parent, class, subclass, superclass, metaclass, and instance always designate an object. Different names are used to emphasize the role played by an object in a particular context. I.e. we use a term other than object when we want to make the relationship with other objects explicit. For example, an object with an instantiation relation with other object plays the role of an instance, while the instantiated object plays the role of a class; an object with a specialization relation with other object plays the role of a subclass, while the specialized object plays the role of a superclass; an object with an extension relation with other object plays the role of a prototype, the same for the extended object. A stand-alone object, i.e. an object with no relations with other objects, is always interpreted as a prototype. In Logtalk, entity relations essentially define patterns of code reuse. An entity is compiled accordingly to the roles it plays.

Logtalk allows you to work from standalone objects to any kind of hierarchy, either class-based or prototype-based. You may use single or multiple inheritance, use or forgo metaclasses, implement reflective designs, use parametric objects, and take advantage of protocols and categories (think components).

Prototypes

Prototypes are either self-defined objects or objects defined as extensions to other prototypes with whom they share common properties. Prototypes are ideal for representing one-of-a-kind objects. Prototypes usually represent concrete objects in the application domain. When linking prototypes using extension relations, Logtalk uses the term prototype hierarchies although most authors prefer to use the term hierarchy only with class generalization/specialization relations. In the context of logic programming, prototypes are often the ideal replacement for modules.

Classes

Classes are used to represent abstractions of common properties of sets of objects. Classes often provide an ideal structuring solution when you want to express hierarchies of abstractions or work with many similar objects. Classes are used indirectly through instantiation. Contrary to most object-oriented programming languages, instances can be created both dynamically at runtime or defined in a source file like other objects. Using classes in requires defining at least one metaclass, as explained below.

Defining a new object

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 object. By default, all Logtalk source files use the extension .lgt but this is optional and can be set in the adapter files. Intermediate Prolog source files (generated by the Logtalk compiler) have, by default, a _lgt suffix and a .pl extension. Again, this can be set to match the needs of a particular Prolog compiler in the corresponding adapter file. For instance, we may define an object named vehicle and save it in a vehicle.lgt source file which will be compiled to a vehicle_lgt.pl Prolog file (depending on the backend compiler, the names of the intermediate Prolog files may include a directory hash and a process identifier to prevent file name clashes when embedding Logtalk applications or running parallel Logtalk processes).

Object names can be atoms or compound terms (when defining parametric objects, see below). Objects, categories, and protocols share the same name space: we cannot have an object with the same name as a protocol or a category.

Object code (directives and predicates) is textually encapsulated by using two Logtalk directives: object/1-5 and end_object/0. The most simple object will be one that is self-contained, not depending on any other Logtalk entity:

:- object(Object).
    ...
:- end_object.

If an object implements one or more protocols then the opening directive will be:

:- object(Object,
    implements([Protocol1, Protocol2, ...])).
    ...
:- end_object.

An object can import one or more categories:

:- object(Object,
    imports([Category1, Category2, ...])).
    ...
:- end_object.

If an object both implements protocols and imports categories then we will write:

:- object(Object,
    implements([Protocol1, Protocol2, ...]),
    imports([Category1, Category2, ...])).
    ...
:- end_object.

In object-oriented programming objects are usually organized in hierarchies that enable interface and code sharing by inheritance. In Logtalk, we can construct prototype-based hierarchies by writing:

:- object(Prototype,
    extends(Parent)).
    ...
:- end_object.

We can also have class-based hierarchies by defining instantiation and specialization relations between objects. To define an object as a class instance we will write:

:- object(Object,
    instantiates(Class)).
    ...
:- end_object.

A class may specialize another class, its superclass:

:- object(Class,
    specializes(Superclass)).
    ...
:- end_object.

If we are defining a reflexive system where every class is also an instance, we will probably be using the following pattern:

:- object(Class,
    instantiates(Metaclass),
    specializes(Superclass)).
    ...
:- end_object.

In short, an object can be a stand-alone object or be part of an object hierarchy. The hierarchy can be prototype-based (defined by extending other objects) or class-based (with instantiation and specialization relations). An object may also implement one or more protocols or import one or more categories.

A stand-alone object (i.e. an object with no extension, instantiation, or specialization relations with other objects) always plays the role of a prototype, that is, a self-describing object. If we want to use classes and instances, then we will need to specify at least one instantiation or specialization relation. The best way to do this is to define a set of objects that provide the basis of a reflective system [Cointe87], [Moura94]. For example:

% avoid the inevitable unknown entity warnings as in a
% reflective system there will always be references to
% an entity that will be defined after the reference

:- set_logtalk_flag(unknown_entities, silent).


% default root of the inheritance graph
% providing predicates common to all objects

:- object(object,
    instantiates(class)).
    ...
:- end_object.


% default metaclass for all classes providing
% predicates common to all instantiable classes

:- object(class,
    instantiates(class),
    specializes(abstract_class)).
    ...
:- end_object.


% default metaclass for all abstract classes
% providing predicates common to all classes

:- object(abstract_class,
    instantiates(class),
    specializes(object)).
    ...
:- end_object.

Note that with these instantiation and specialization relations, object, class, and abstract_class are, at the same time, classes and instances of some class. In addition, each object inherits its own predicates and the predicates of the other two objects without any inheritance loop.

When a full-blown reflective system solution is not needed, the above scheme can be simplified by making an object an instance of itself, i.e. by making a class its own metaclass. For example:

:- object(class,
    instantiates(class)).
    ...
:- end_object.

We can use, in the same application, both prototype and class-based hierarchies (and freely exchange messages between all objects). We cannot however mix the two types of hierarchies by, e.g., specializing an object that extends another object in this current Logtalk version.

Logtalk also supports public, protected, and private inheritance. See the inheritance section for details.

Parametric objects

Parametric objects have a compound term as identifier where all the arguments of the compound term are variables. These variables can be bound when sending a message or become bound when a message to the object succeeds, thus acting as object parameters. The object predicates can be coded to depend on those parameters, which are logical variables shared by all object predicates. When an object state is set at object creation and never changed, parameters provide a better solution than using the object’s database via asserts. Parametric objects can also be used to associate a set of predicates to terms that share a common functor and arity.

Accessing object parameters

Object parameters can be accessed using parameter variables or built-in execution context methods. Parameter variables is the recommended solution to access object parameters. Although they introduce a concept of entity global variables, their unique syntax (_ParameterName_) avoids conflicts, makes them easily recognizable, and distinguishes them from other named anonymous variables. For example:

:- object(foo(_Bar_, _Baz_, ...)).

    ...
    bar(_Bar_).

    baz :-
        baz(_Baz_),
        ... .

Note that using parameter variables doesn’t change the fact that entity parameters are logical variables. Parameter variables simplify code maintenance by allowing parameters to be added, reordered, or removed without having to specify or update parameter indexes.

Logtalk provides also a parameter/2 built-in local method to access individual parameters:

:- object(foo(_Bar, _Baz, ...)).

    ...
    bar(Bar) :-
        parameter(1, Bar).

    baz :-
        parameter(2, Baz),
        baz(Baz),
        ... .

An alternative solution is to use the built-in local method this/1, which allows to access all parameters with a single call. For example:

:- object(foo(_Bar, _Baz, ...)).

    ...
    baz :-
        this(foo(_, Baz, ...)),
        baz(Baz),
        ... .

Both solutions are equally efficient as calls to the methods this/1 and parameter/2 are usually compiled inline into a clause head unification. The drawback of this second solution is that we must check all calls of this/1 if we change the object name. Note that we can’t use these method with the message sending operators ((::)/2, (::)/1, or (^^)/1).

When storing a parametric object in its own source file, the convention is to name the file after the object, with the object arity appended. For instance, when defining an object named sort(Type), we may save it in a sort_1.lgt text file. This way it is easy to avoid file name clashes when saving Logtalk entities that have the same functor but different arity.

Parametric object proxies

Compound terms with the same functor and with the same number of arguments as a parametric object identifier may act as proxies to a parametric object. Proxies may be stored on the database as Prolog facts and be used to represent different instantiations of a parametric object identifier. For example:

:- object(circle(_Id_, _Radius_, _Color_)).

    :- public(area/1).
    ...

:- end_object.

% parametric object proxies:
circle('#1', 1.23, blue).
circle('#2', 3.71, yellow).
circle('#3', 0.39, green).
circle('#4', 5.74, black).
circle('#5', 8.32, cyan).

Logtalk provides a convenient notation for accessing proxies represented as Prolog facts when sending a message:

..., {Proxy}::Message, ...

For example, using the circle/3 parametric object above, we can compute a list with the areas of all circles using the following goal:

| ?- findall(Area, {circle(_, _, _)}::area(Area), Areas).

Areas = [4.75291, 43.2412, 0.477836, 103.508, 217.468].

In this context, the proxy argument is proved as a plain Prolog goal. If successful, the message is sent to the corresponding parametric object. Typically, the proof allows retrieving of parameter instantiations. This construct can either be used with a proxy argument that is sufficiently instantiated in order to unify with a single Prolog fact or with a proxy argument that unifies with several facts on backtracking.

Finding defined objects

We can find, by backtracking, all defined objects by calling the current_object/1 built-in predicate with a unbound argument:

| ?- current_object(Object).
Object = logtalk ;
Object = user ;
...

This predicate can also be used to test if an object is defined by calling it with a valid object identifier (an atom or a compound term).

Creating a new object in runtime

An object can be dynamically created at runtime by using the create_object/4 built-in predicate:

| ?- create_object(Object, Relations, Directives, Clauses).

The first argument should be either a variable or the name of the new object (a Prolog atom or compound term, which must not match any existing entity name). The remaining three arguments correspond to the relations described in the opening object directive and to the object code contents (directives and clauses).

For example, the call:

| ?- create_object(
         foo,
         [extends(bar)],
         [public(foo/1)],
         [foo(1), foo(2)]
     ).

is equivalent to compiling and loading the object:

:- object(foo,
    extends(bar)).

    :- dynamic.

    :- public(foo/1).
    foo(1).
    foo(2).

:- end_object.

If we need to create a lot of (dynamic) objects at runtime, then is best to define a metaclass or a prototype with a predicate that will call this built-in predicate to make new objects. This predicate may provide automatic object name generation, name checking, and accept object initialization options.

Abolishing an existing object

Dynamic objects can be abolished using the abolish_object/1 built-in predicate:

| ?- abolish_object(Object).

The argument must be an identifier of a defined dynamic object, otherwise an error will be thrown.

Object directives

Object directives are used to set initialization goals, define object properties, to document an object dependencies on other Logtalk entities, and to load the contents of files into an object.

Object initialization

We can define a goal to be executed as soon as an object is (compiled and) loaded to memory with the initialization/1 directive:

:- initialization(Goal).

The argument can be any valid Logtalk goal. For example, a call to a local predicate:

:- object(foo).

    :- initialization(init).
    :- private(init/0).

    init :-
        ... .

    ...

:- end_object.

Or a message to another object:

:- object(assembler).

    :- initialization(control::start).
    ...

:- end_object.

Another common initialization goal is a message to self in order to call an inherited or imported predicate. For example, assuming that we have a monitor category defining a reset/0 predicate, we could write:

:- object(profiler,
    imports(monitor)).

    :- initialization(::reset).
    ...

:- end_object.

Note, however, that descendant objects do not inherit initialization directives. In this context, self denotes the object that contains the directive. Also note that object initialization does not necessarily mean setting an object dynamic state.

Dynamic objects

Similar to Prolog predicates, an object can be either static or dynamic. An object created during the execution of a program is always dynamic. An object defined in a file can be either dynamic or static. Dynamic objects are declared by using the dynamic/0 directive in the object source code:

:- dynamic.

The directive must precede any predicate directives or clauses. Please be aware that using dynamic code results in a performance hit when compared to static code. We should only use dynamic objects when these need to be abolished during program execution. In addition, note that we can declare and define dynamic predicates within a static object.

Object documentation

An object can be documented with arbitrary user-defined information by using the info/1 entity directive. See the Documenting section for details.

Loading files into an object

The include/1 directive can be used to load the contents of a file into an object. A typical usage scenario is to load a plain Prolog file into an object thus providing a simple way to encapsulate its contents. For example, assume a cities.pl file defining facts for a city/4 predicate. We could define a wrapper for this database by writing:

:- object(cities).

    :- public(city/4).

    :- include(dbs('cities.pl')).

:- end_object.

The include/1 directive can also be used when creating an object dynamically. For example:

| ?- create_object(cities, [], [public(city/4), include(dbs('cities.pl'))], []).

Declaring object aliases

The uses/1 directive can be used to declare object aliases. The typical uses of this directive include shortening long object names, working consistently with specific parameterizations of parametric objects, and simplifying experimenting with different object implementations of the same protocol when using explicit message sending.

Object relationships

Logtalk provides six sets of built-in predicates that enable us to query the system about the possible relationships that an object may have with other entities.

The instantiates_class/2-3 built-in predicates can be used to query all instantiation relations:

| ?- instantiates_class(Instance, Class).

or, if we also want to know the instantiation scope:

| ?- instantiates_class(Instance, Class, Scope).

Specialization relations can be found by using the specializes_class/2-3 built-in predicates:

| ?- specializes_class(Class, Superclass).

or, if we also want to know the specialization scope:

| ?- specializes_class(Class, Superclass, Scope).

For prototypes, we can query extension relations using with the extends_object/2-3 built-in predicates:

| ?- extends_object(Object, Parent).

or, if we also want to know the extension scope:

| ?- extends_object(Object, Parent, Scope).

In order to find which objects import which categories we can use the imports_category/2-3 built-in predicates:

| ?- imports_category(Object, Category).

or, if we also want to know the importation scope:

| ?- imports_category(Object, Category, Scope).

To find which objects implements which protocols we can use the implements_protocol/2-3 and conforms_to_protocol/2-3 built-in predicates:

| ?- implements_protocol(Object, Protocol, Scope).

or, if we also want to consider inherited protocols:

| ?- conforms_to_protocol(Object, Protocol, Scope).

Note that, if we use a unbound first argument, we will need to use the current_object/1 built-in predicate to ensure that the entity returned is an object and not a category.

To find which objects are explicitly complemented by categories we can use the complements_object/2 built-in predicate:

| ?- complements_object(Category, Object).

Note that more than one category may explicitly complement a single object and a single category can complement several objects.

Object properties

We can find the properties of defined objects by calling the built-in predicate object_property/2:

| ?- object_property(Object, Property).

The following object properties are supported:

static

The object is static

dynamic

The object is dynamic (and thus can be abolished in runtime by calling the abolish_object/1 built-in predicate)

built_in

The object is a built-in object (and thus always available)

threaded

The object supports/makes multi-threading calls

file(Path)

Absolute path of the source file defining the object (if applicable)

file(Basename, Directory)

Basename and directory of the source file defining the object (if applicable); Directory always ends with a /

lines(BeginLine, EndLine)

Source file begin and end lines of the object definition (if applicable)

directive(BeginLine, EndLine)

Source file begin and end lines of the object opening directive (if applicable)

context_switching_calls

The object supports context switching calls (i.e. can be used with the (<<)/2 debugging control construct)

dynamic_declarations

The object supports dynamic declarations of predicates

events

Messages sent from the object generate events

source_data

Source data available for the object

complements(Permission)

The object supports complementing categories with the specified permission (allow or restrict)

complements

The object supports complementing categories

public(Resources)

List of public predicates and operators declared by the object

protected(Resources)

List of protected predicates and operators declared by the object

private(Resources)

List of private predicates and operators declared by the object

declares(Predicate, Properties)

List of properties for a predicate declared by the object

defines(Predicate, Properties)

List of properties for a predicate defined by the object

includes(Predicate, Entity, Properties)

List of properties for an object multifile predicate that are defined in the specified entity (the properties include number_of_clauses(Number), number_of_rules(Number), lines(Start,End), and line_count(Start) with Start being the begin line of the first multifile predicate clause)

provides(Predicate, Entity, Properties)

List of properties for other entity multifile predicate that are defined in the object (the properties include number_of_clauses(Number), number_of_rules(Number), and lines(Start,End), and line_count(Start) with Start being the begin line of the first multifile predicate clause)

alias(Entity, Properties)

List of properties for an entity alias declared by the object (the properties include object in case of an object alias, module in case of a module alias, for(Original), lines(Start,End), and line_count(Start) with Start being the begin line of the uses/1 or use_module/1 directive)

alias(Predicate, Properties)

List of properties for a predicate alias declared by the object (the properties include predicate, for(Original), from(Entity), non_terminal(NonTerminal), lines(Start,End), and line_count(Start) with Start being the begin line of the alias directive)

calls(Call, Properties)

List of properties for predicate calls made by the object (Call is either a predicate indicator or a control construct such as (::)/1-2 or (^^)/1 with a predicate indicator as argument; note that Call may not be ground in case of a call to a control construct where its argument is only know at runtime; the properties include caller(Caller), alias(Alias), non_terminal(NonTerminal), lines(Start,End), line_count(Start) with Caller, Alias, and NonTerminal being predicate indicators and Start being the begin line of the predicate clause or directive making the call)

updates(Predicate, Properties)

List of properties for dynamic predicate updates (and also access using the clause/2 predicate) made by the object (Predicate is either a predicate indicator or a control construct such as (::)/1-2 or (:)/2 with a predicate indicator as argument; note that Predicate may not be ground in case of a control construct argument only know at runtime; the properties include updater(Updater), alias(Alias), non_terminal(NonTerminal), lines(Start,End), and line_count(Start) with Updater being a (possibly multifile) predicate indicator, Alias and NonTerminal being predicate indicators, and Start being the begin line of the predicate clause or directive updating the predicate)

number_of_clauses(Number)

Total number of predicate clauses defined in the object at compilation time (includes both user-defined clauses and auxiliary clauses generated by the compiler or by the expansion hooks but does not include clauses for multifile predicates defined for other entities or clauses for the object own multifile predicates contributed by other entities)

number_of_rules(Number)

Total number of predicate rules defined in the object at compilation time (includes both user-defined rules and auxiliary rules generated by the compiler or by the expansion hooks but does not include rules for multifile predicates defined for other entities or rules for the object own multifile predicates contributed by other entities)

number_of_user_clauses(Number)

Total number of user-defined predicate clauses defined in the object at compilation time (does not include clauses for multifile predicates defined for other entities or clauses for the object own multifile predicates contributed by other entities)

number_of_user_rules(Number)

Total number of user-defined predicate rules defined in the object at compilation time (does not include rules for multifile predicates defined for other entities or rules for the object own multifile predicates contributed by other entities)

debugging

The object is compiled in debug mode

module

The object resulted from the compilation of a Prolog module

When a predicate is called from an initialization/1 directive, the argument of the caller/1 property is (:-)/1.

Some properties such as line numbers are only available when the object is defined in a source file compiled with the source_data flag turned on. Moreover, line numbers are only supported in backend Prolog compilers that provide access to the start line of a read term. When such support is not available, the value -1 is returned for the start and end lines.

The properties that return the number of clauses (rules) report the clauses (rules) textually defined in the object for both multifile and non-multifile predicates. Thus, these numbers exclude clauses (rules) for multifile predicates contributed by other entities.

Built-in objects

Logtalk defines some built-in objects that are always available for any application.

The built-in pseudo-object user

The built-in user pseudo-object virtually contains all user predicate definitions not encapsulated in a Logtalk entity (or a Prolog module for backends supporting a module system). These predicates are assumed to be implicitly declared public. Messages sent from this pseudo-object, which includes messages sent from the top-level interpreter, generate events when the default value of the events flag is set to allow. Defining complementing categories for this pseudo-object is not supported.

With some of the backend Prolog compilers that support a module system, it is possible to load (the) Logtalk (compiler/runtime) into a module other than the pseudo-module user. In this case, the Logtalk pseudo-object user virtually contains all user predicate definitions defined in the module where Logtalk was loaded.

The built-in object logtalk

The built-in logtalk object provides message printing predicates, question asking predicates, debug and trace event predicates, predicates for accessing the internal database of loaded files and their properties, and also a set of low-level utility predicates normally used when defining hook objects. Consult its API documentation for details.