ports_profiler
ï
This tool counts and reports the number of times each port in the
procedure box model is traversed during the execution of queries. It
can also report the number of times each clause (or grammar rule) is
used. It is inspired by the ECLiPSe port_profiler
tool.
The procedure box model is the same as the one used in the debugger
tool. This is an extended version of the original Byrdâs four-port
model. Besides the standard call
, exit
, fail
, and redo
ports, Logtalk also defines two post-unification ports, fact
and
rule
, and an exception
port. This tool can also distinguish
between deterministic exits (reported in the exit
column in the
profiling result tables) and exits that leave choice-points (reported in
the *exit
column).
API documentationï
This tool API documentation is available at:
../../docs/library_index.html#ports-profiler
For sample queries, please see the SCRIPT.txt
file in the tool
directory.
Loadingï
| ?- logtalk_load(ports_profiler(loader)).
Testingï
To test this tool, load the tester.lgt
file:
| ?- logtalk_load(ports_profiler(tester)).
Compiling source files for port profilingï
To compile source files for port profiling, simply compile them in debug
mode and with the source_data
flag turned on. For example:
| ?- logtalk_load(my_source_file, [debug(on), source_data(on)]).
Alternatively, you can also simply turn on the debug
and
source_data
flags globally before compiling your source files:
| ?- set_logtalk_flag(debug, on), set_logtalk_flag(source_data, on).
Be aware, however, that loader files (e.g., library loader files) may override the default flag values, and thus the loaded files may not be compiled in debug mode. In this case, you will need to modify the loader files themselves.
Generating profiling dataï
After loading this tool and compiling the source files that you want to
profile in debug mode, simply call the ports_profiler::start
goal
followed by the goals to be profiled. Use the ports_profiler::stop
goal to stop profiling.
Note that the ports_profiler::start/0
predicate implicitly selects
the ports_profiler
tool as the active debug handler. If you have
additional debug handlers loaded (e.g., the debugger
tool), those
would no longer be active (there can be only one active debug handler at
any given time).
Printing profiling data reportsï
After calling the goals that you want to profile, you can print a table with all profile data by typing:
| ?- ports_profiler::data.
To print a table with data for a single entity, use the query:
| ?- ports_profiler::data(Entity).
To print a table with data for a single entity predicate, use the query:
| ?- ports_profiler::data(Entity, Predicate).
In this case, the second argument must be either a predicate indicator,
Name/Arity
, or a non-terminal indicator, Name//Arity
.
The profiling data can be reset using the query:
| ?- ports_profiler::reset.
To reset only the data for a specific entity, use the query:
| ?- ports_profiler::reset(Entity).
To illustrate the tool output, consider the family
example in the
Logtalk distribution:
| ?- {ports_profiler(loader)}.
...
yes
| ?- set_logtalk_flag(debug, on).
yes
| ?- logtalk_load(family(loader)).
...
yes
| ?- ports_profiler::start.
yes
| ?- addams::sister(Sister, Sibling).
Sister = wednesday,
Sibling = pubert ;
Sister = wednesday,
Sibling = pugsley ;
Sister = wednesday,
Sibling = pubert ;
Sister = wednesday,
Sibling = pugsley ;
no
| ?- ports_profiler::data.
----------------------------------------------------------------------
Entity Predicate Fact Rule Call Exit *Exit Fail Redo Error
----------------------------------------------------------------------
addams female/1 2 0 1 1 1 0 1 0
addams parent/2 8 0 4 3 5 1 5 0
relations sister/2 0 1 1 0 4 1 4 0
----------------------------------------------------------------------
yes
| ?- ports_profiler::data(addams).
-----------------------------------------------------------
Predicate Fact Rule Call Exit *Exit Fail Redo Error
-----------------------------------------------------------
female/1 2 0 1 1 1 0 1 0
parent/2 8 0 4 3 5 1 5 0
-----------------------------------------------------------
yes
| ?- ports_profiler::data(addams, parent/2).
-------------
Clause Count
-------------
1 1
2 1
3 2
4 1
5 1
6 2
-------------
yes
Interpreting profiling dataï
Some useful information that can be inferred from the profiling data include:
which predicates are called more often (from the
call
port)unexpected failures (from the
fail
port)unwanted non-determinism (from the
*exit
port)performance issues due to backtracking (from the
*exit
andredo
ports)predicates acting like a generator of possible solutions (from the
*exit
andredo
ports)inefficient indexing of predicate clauses (from the
fact
,rule
, andcall
ports)clauses that are never used or seldom used
The profiling data should be analyzed by taking into account the expected behavior for the profiled predicates.
Profiling Prolog modulesï
This tool can also be applied to Prolog modules that Logtalk is able to
compile as objects. For example, if the Prolog module file is named
module.pl
, try:
| ?- logtalk_load(module, [debug(on), source_data(on)]).
Due to the lack of standardization of module systems and the abundance of proprietary extensions, this solution is not expected to work for all cases.
Profiling plain Prolog codeï
This tool can also be applied to plain Prolog code. For example, if the
Prolog file is named code.pl
, simply define an object including its
code and declaring as public any predicates that you want to use as
messages to the object. For example:
:- object(code).
:- public(foo/2).
:- include('code.pl').
:- end_object.
Save the object to an e.g. code.lgt
file in the same directory as
the Prolog file and then load it in debug mode:
| ?- logtalk_load(code, [debug(on), source_data(on)]).
In alternative, use the object_wrapper_hook
provided by the
hook_objects
library:
| ?- logtalk_load(hook_objects(loader)).
...
| ?- logtalk_load(
code,
[hook(object_wrapper_hook), debug(on),
source_data(on), context_switching_calls(allow)]
).
In this second alternative, you can then use the (<<)/2
context
switch control construct to call the wrapped predicates. E.g.
| ?- code<<foo(X, Y).
With either wrapping solution, pay special attention to any compilation
warnings that may signal issues that could prevent the plain Prolog code
from working as-is when wrapped by an object. Often any required changes
are straightforward (e.g., adding use_module/2
directives for called
module library predicates).
Known issuesï
Determinism information is currently not available when using Quintus Prolog as the backend compiler.