Running and debugging Logtalk programs

Running a Logtalk session

We run Logtalk inside a normal Prolog session, after loading the necessary files. Logtalk extends but does not modify your Prolog compiler. We can freely mix Prolog queries with the sending of messages and our programs can be made of both normal Prolog clauses and object definitions.

Starting Logtalk

To start a Logtalk session just:

  1. Start your Prolog compiler.
  2. Load the appropriate configuration file for your compiler. Configuration files for most common Prolog compilers can be found in the configs subdirectory.
  3. Load the Logtalk compiler/runtime files contained in the compiler subdirectory.
  4. Load the library paths configuration file corresponding to your Logtalk installation contained in the libpaths subdirectory.

Note that the configuration files, compiler/runtime files, and library paths file are Prolog source files. The predicate called to load (and compile) them depends on your Prolog compiler. In case of doubt, consult your Prolog compiler reference manual or take a look at the definition of the predicate '$lgt_load_prolog_code'/1 in the corresponding configuration file.

Most Prolog compilers support automatic loading of an initialization file, which can include the necessary directives to load both the Prolog configuration file and the Logtalk compiler. This feature, when available, allows automatic loading of Logtalk when you start your Prolog compiler.

Compiling and loading your programs

Your programs will be made of source files containing your objects, protocols, and categories. After changing the Prolog working directory to the one containing your files, you can compile them to disk by calling the Logtalk built-in predicate logtalk_compile/1:

    | ?- logtalk_compile([source_file1, source_file2, ...]).

This predicate runs the preprocessor on each argument file and, if no fatal errors are found, outputs Prolog source files that can then be consulted or compiled in the usual way by your Prolog compiler. Note that the predicate argument must be either an entity name or a list of entity names.

To compile to disk and also load into memory the source files we can use the Logtalk built-in predicate logtalk_load/1:

    | ?- logtalk_load([source_file1, source_file2, ...]).

This predicate works in the same way of the predicate logtalk_compile/1 but also loads the compiled files to memory.

Both predicates expect an entity name, a source metafile, or a list of entity names and source metafiles as an argument. The Logtalk source file name extension, as defined in the configuration file, should be omitted.

If you have more than a few source files then you may want to use a loader helper file containing the calls to the logtalk_load/1 predicate. Consulting or compiling the loader file will then compile and load all your Logtalk entities into memory (see the next section for details).

Compiler flags

The logtalk_load/1 and logtalk_compile/1 always use the set of default compiler flags specified in the Logtalk configuration files. Although the default flag values cover the usual cases, you may want to use a different set of flag values while compiling or loading some of your Logtalk source files. This can be accomplished by using the logtalk_load/2 or the logtalk_compile/2 built-in predicates. These two predicates accept a list of flag values affecting how a Logtalk source file is compiled and loaded:

    | ?- logtalk_compile(Files, Flags).

or:

    | ?- logtalk_load(Files, Flags).

In fact, the logtalk_load/1 and logtalk_compile/1 predicates are just shortcuts to the extended versions called with the default compiler flag values.

You can use the following flags:

events(Option)
Allows Logtalk event-driven programming support to be turned off when not needed in order to increase message sending performance. Possible option values are on (the usual default) and off. Objects (and categories) compiled with this option set to off use optimized code for message-sending that does not trigger events. As such, this option can be used on a per-object (or per-category) basis. Note that turning off this option is of no consequence for objects and categories already compiled and loaded.
unknown(Option)
Controls the unknown entity warnings, resulting from loading an entity that references some other entity that is not currently loaded. Possible option values are warning (the usual default) and silent.
singletons(Option)
Controls the singleton variable warnings. Possible option values are warning (the usual default) and silent (not recommended).
underscore_vars(Option)
Controls the interpretation of variables that start with an underscore (excluding the anonymous variable) that occur once in a term as either don't care variables or singleton variables. Possible option values are dont_care and singletons (the usual default). Note that, depending on your Prolog compiler, the read_term/3 built-in predicate may report variables that start with an underscore as singleton variables. There is no standard behavior, hence this option.
misspelt(Option)
Controls the misspelt predicate call warnings. A misspelt call is a call to a predicate which is not defined in the object or category containing the call, is not declared as dynamic, and is not a Logtalk/Prolog built-in predicate. Possible option values are warning (the usual default) and silent (not recommended).
lgtredef(Option)
Controls the Logtalk built-in predicates redefinition warnings. Possible option values are warning (the usual default) and silent.
plredef(Option)
Controls the Prolog built-in predicates redefinition warnings. Possible option values are warning (can be very verbose if your code redefines a lot of Prolog built-in predicates) and silent (the usual default).
portability(Option)
Controls the non-ISO specified built-in predicate calls warnings. Possible option values are warning and silent (the usual default).
xml(Option)
Controls the automatic generation of documenting files in XML format. Possible option values are on (the usual default) and off.
xmlspec(Option)
Defines the XML documenting files specification format. Possible option values are dtd (for the DTD specification; the usual default) and xsd (for the XML Schema specification). Most XSL processors support DTDs but only some of them support XML Schemes.
doctype(Option)
Sets the DOCTYPE reference in the automatically generated XML documenting files. The default value is local, that is, the DOCTYPE reference points to a local DTD or XSD file (respectively, logtalk.dtd or logtalk.xsd), residing in the same directory as the XML file. Other possible values are web (DOCTYPE reference points to an web location, either http://www.logtalk.org/xml/1.2/logtalk.dtd or http://www.logtalk.org/xml/1.2/logtalk.xsd), and standalone (no DOCTYPE reference in the XML documenting files). The most appropriated option value depends on the XSL processor you intend to use. Some of them are buggy an may not work with the default option value.
xsl(File)
Sets the XSLT file to be used with the automatically generated XML documenting files. The default value is lgtxml.xsl, which allows the XML files to be viewed by simply opening them with recent versions of web navigators which support XSLT transformations (after copying the lgtxml.xsl and of the logtalk.css files to the directory containing the XML files).
report(Option)
Controls reporting of each compiled or loaded object, category, or protocol (including compilation and loading warnings). Possible option values are on (the usual default) and off (silent compilation and loading).
smart_compilation(Option)
Controls the use of smart compilation of source files to avoid recompiling files that are unchanged since the last time they are compiled. Possible option values are on and off (the usual default). This option is only supported in some Prolog compilers. It should not be used when compiling source files in debug mode (see debug/1 option below).
code_prefix(Option)
Enables the definition of prefix for all functors of Logtalk generated Prolog code. Option value must be an atom. Default value is ''. Specifying a code prefix provides a way to solve possible conflicts between Logtalk compiled code and other Prolog code. In addition, some Prolog compilers automatically hide predicates whose functor start with a specific prefix such as $.
debug(Option)
Controls the compilation of source files in debug mode (the Logtalk built-in debugger can only be used with files compiled in this mode). Possible option values are on and off (the usual default).

We may also change the default flag values from the ones loaded from the config file by using the set_logtalk_flag/2 built-in predicate. For example:

    | ?- set_logtalk_flag(xml, off).

The current default flags values can be enumerated using the current_logtalk_flag/2 built-in predicate:

    | ?- current_logtalk_flag(xml, Value).

    Value = off
    yes

Smart compilation of source files

If the Prolog compiler that you are using supports retrieving of file modification dates, then you can turn on smart compilation of source files to avoid recompiling files that have not been modified since last compilation.

Smart compilation of source files is usually off by default. You can turn it on by changing the default flag value in the configuration file, by using the corresponding compiler flag with the compiling and loading built-in predicates, or, for the remaining of a working session, by using the call:

    | ?- set_logtalk_flag(smart_compilation, on).

Some caveats that you should be aware. First, some warnings that might be produced when compiling a source file will not show up if the corresponding object file is up-to-date because the source file is not being (re)compiled. Second, if you are using several Prolog compilers with Logtalk, be sure to perform the first compilation of your source files with smart compilation turned off: the intermediate Prolog files generated by the Logtalk preprocessor may be not compatible across Prolog compilers or even for the same Prolog compiler across operating systems (due to the use of different end-of-line characters).

Using Logtalk for batch processing

If you use Logtalk for batch processing, you probably want to supress most, if not all, banners, messages, and warnings that are normally printed by the system.

To supress printing of the Logtalk startup banner and default flags, set the option startup_message in the config file that you are using to none.

To supress printing of compiling and loading messages (including compiling warnings but not compiling error messages), turn off the option report in the used config file.

Debugging Logtalk programs

Logtalk defines a built-in pseudo-object named debugger, which implements debugging features similar to those found on most Prolog compilers. However, there are some differences between the usual implementation of Prolog debuggers and the current implementation of the Logtalk debugger that you should be aware. First, unlikely most Prolog debuggers, the Logtalk debugger is not implemented as a meta-interpreter. This translates to a different, although similar, set of debugging features with some limitations when compared with some Prolog debuggers. Second, debugging is only possible for objects compiled in debug mode. When compiling an object in this mode, Logtalk keeps each clause goal in both source form and compiled form in order to allow tracing of the goal execution. Third, implementation of spy points allows the user to specify the execution context for entering the debugger. This feature is a consequence of the encapsulation of predicates inside objects.

Compiling objects in debug mode

Compilation of source files in debug mode is controlled by the compiler flag debug. The default value for this flag, usually off, is defined in the config files. Its value may be changed at runtime by writing:

    | ?- set_logtalk_flag(debug, on).

    yes

In alternative, if we want to compile only some objects in debug mode, we may instead write:

    | ?- logtalk_load([file1, file2, ...], [debug(on)]).

The compiler flag smart_compilation is automatically turned off whenever the debug flag is turned on at runtime. This is necessary because debug code would not be generated for files previously compiled in normal mode if there is no changes to the source files. However, note that you should be carefull to not turn both flags on at the same time in a config file.

Logtalk Procedure Box model

Logtalk uses a Procedure Box model similar to those found on most Prolog compilers. The traditional Prolog procedure box model uses four ports (call, exit, redo, and fail) for describing control flow when a predicate clause is used during program execution:

call
predicate call
exit
success of a predicate call
redo
backtraking into a predicate
fail
failure of a predicate call

Logtalk, as found on some recent Prolog compilers, adds a port for dealing with exceptions thrown when calling a predicate:

exception
predicate call throws an exception

In addition to the ports described above, Logtalk adds two more ports, fact and rule, which show the result of the unification of a goal with, respectively, a fact and a rule head:

fact
unification success between a goal and a fact
rule
unification success between a goal and a rule head

The user may define for which ports the debugger should pause for user interaction by specifiying a list of leashed ports. For example:

    | ?- debugger::leash([call, exit, fail]).

Alternatively, the user may use an atom abbreviation for a pre-defined set of ports. For example:

    | ?- debugger::leash(loose).

The abbreviations defined in Logtalk are similar to those defined on some Prolog compilers:

none
[]
loose
[fact, rule, call]
half
[fact, rule, call, redo]
tight
[fact, rule, call, redo, fail, exception]
full
[fact, rule, call, exit, redo, fail, exception]

Defining spy points

Logtalk spy points can be defined by simply stating which predicates should be spied, as in most Prolog debuggers, or by fully specifying the context for activating a spy point.

Defining predicate spy points

Predicate spy points are specified using the method spy/1. The argument can be either a predicate indicator (Functor/Arity) or a list of predicate indicators. For example:

    | ?- debugger::spy(foo/2).
    
    Spy points set.
    yes

    | ?- debugger::spy([foo/4, bar/1]).
    
    Spy points set.
    yes

Predicate spy points can be removed by using the method nospy/1. The argument can be a predicate indicator, a list of predicate indicators, or a non-instantiated variable in which case all predicate spy points will be removed. For example:

    | ?- debugger::nospy(_).
    
    All matching predicate spy points removed.
    yes

Defining context spy points

A context spy point is a term describing a message execution context and a goal:

    (Sender, This, Self, Goal)

The debugger is evoked whenever the execution context is true and when the spy point goal unifies with the goal currently being executed. Variable bindings resulting from the unification between the current goal and the goal argument are discarded. The user may establish any number of context spy points as necessary. For example, in order to call the debugger whenever a predicate defined on an object named foo is called we may define the following spy point:

    | ?- debugger::spy(_, foo, _, _).
    
    Spy point set.
    yes

For example, we can spy all calls to a foo/2 predicate by setting the condition:

    | ?- debugger::spy(_, _, _, foo(_, _)).
    
    Spy point set.
    yes

The method nospy/4 may be used to remove all matching spy points. For example, the call:

    | ?- debugger::nospy(_, _, foo, _).
    
    All matching context spy points removed.
    yes

will remove all context spy points where the value of Self matches the name foo.

Removing all spy points

We may remove all predicate spy points and all context spy points by using the method nospyall/0:

    | ?- debugger::nospyall.
    
    All predicate spy points removed.
    All context spy points removed.
    yes

Tracing program execution

Logtalk allows tracing of execution for all objects compiled in debug mode. To start the debugger in trace mode, write:

    | ?- debugger::trace.

    yes

Note that, when tracing, spy points will be ignored. While tracing, the debugger will pause for user input at each leashed port.

To stop tracing and turning off the debugger, write:

    | ?- debugger::notrace.

    yes

Debugging using spy points

Tracing a program execution may generate large amounts of debugging data. Debugging using spy points allows the user to concentrate its attention in specific points of its code. To start a debugging session using spy points, write:

    | ?- debugger::debug.

    yes

At the beginning of a port description, the debugger will print a + or a * before the current goal if there is, respectively, a predicate spy point or a context spy point defined.

To stop the debugger, write:

    | ?- debugger::nodebug.

    yes

Note that stopping the debugger does not remove any defined spy points.

Debugging commands

The debugger pauses at leashed posts when tracing or when finding a spy point for user interaction. The commands available are as follows:

c — creep
go on; you may use the spacebar in alternative
l — leep
continues execution until the next spy point is found
s — skip
skips debugging for the current goal; only valid at call and redo ports
f — fail
forces backtracking
n — nodebug
turns off debugging
@ — command
reads and executes a query
b — break
suspends execution and starts new interpreter; type end_of_file to terminate
a — abort
returns to top level interpreter
d — display
writes current goal without using operator notation
x — context
prints execution context
e — exception
prints exception term thrown by the current goal
= — debugging
prints debugging information
* — add
adds a context spy point for the current goal
+ — add
adds a predicate spy point for the current goal
- — remove
removes a predicate spy point for the current goal
h — help
prints list of command options; ? can be used in alternative