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yap-6.3/packages/ProbLog/learning.yap
Vítor Manuel de Morais Santos Costa 69caa6d5df upgrade to more recent version of ProbLog.
2010-01-14 15:46:46 +00:00

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48 KiB
Prolog

%%% -*- Mode: Prolog; -*-
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%
% $Date: 2009-06-17 22:22:00 +0200 (Mi, 17 Jun 2009) $
% $Revision: 1550 $
%
% This file is part of ProbLog
% http://dtai.cs.kuleuven.be/problog
%
% Copyright 2009 Katholieke Universiteit Leuven
%
% Authors: Luc De Raedt, Bernd Gutmann, Angelika Kimmig,
% Vitor Santos Costa
%
%
% Main authors of this file:
% Bernd Gutmann
%
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%
% Artistic License 2.0
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
:- module(learning,[do_learning/1,
do_learning/2,
set_learning_flag/2,
save_model/1,
problog_help/0,
set_problog_flag/2,
problog_flag/2,
problog_flags/0
]).
% switch on all the checks to reduce bug searching time
:- style_check(all).
:- yap_flag(unknown,error).
% load modules from the YAP library
:- use_module(library(lists)).
:- use_module(library(random),[random/1]).
:- use_module(library(system),[file_exists/1,
file_property/2,
delete_file/1,
make_directory/1,
working_directory/2,
shell/1,
shell/2]).
% load our own modules
:- use_module(library('problog_learning/logger')).
:- use_module(library(problog)).
% used to indicate the state of the system
:- dynamic values_correct/0.
:- dynamic learning_initialized/0.
:- dynamic current_iteration/1.
:- dynamic example_count/1.
:- dynamic query_probability_intern/2.
:- dynamic query_gradient_intern/3.
:- dynamic last_mse/1.
% used to identify queries which have identical proofs
:- dynamic query_is_similar/2.
:- dynamic query_md5/2.
% used by set_learning_flag
:- dynamic init_method/5.
:- dynamic rebuild_bdds/1.
:- dynamic rebuild_bdds_it/1.
:- dynamic reuse_initialized_bdds/1.
:- dynamic learning_rate/1.
:- dynamic probability_initializer/3.
:- dynamic check_duplicate_bdds/1.
:- dynamic output_directory/1.
:- dynamic query_directory/1.
:- dynamic log_frequency/1.
:- dynamic alpha/1.
:- dynamic sigmoid_slope/1.
:- dynamic line_search/1.
:- dynamic line_search_tolerance/1.
:- dynamic line_search_tau/1.
:- dynamic line_search_never_stop/1.
:- dynamic line_search_interval/2.
%==========================================================================
%= You can set some flags and parameters
%=
%= init_method/5 specifies which ProbLog inference mechanism is used
%= to answer queries
%=
%=
%= if rebuild_bdds(true) is set, the bdds are rebuild after
%= each N iterations for rebuild_bdds_it(N)
%=
%= if reuse_initialized_bdds(true) is set, the bdds which are on the
%= harddrive from the previous run of LeProbLog are reused.
%= do not use this, when you changed the init method in the meantime
%=
%==========================================================================
set_learning_flag(init_method,(Query,Probability,BDDFile,ProbFile,Call)) :-
retractall(init_method(_,_,_,_,_)),
assert(init_method(Query,Probability,BDDFile,ProbFile,Call)).
set_learning_flag(rebuild_bdds,Flag) :-
(Flag=true;Flag=false),
!,
retractall(rebuild_bdds(_)),
assert(rebuild_bdds(Flag)).
set_learning_flag(rebuild_bdds_it,Flag) :-
integer(Flag),
retractall(rebuild_bdds_it(_)),
assert(rebuild_bdds_it(Flag)).
set_learning_flag(reuse_initialized_bdds,Flag) :-
(Flag=true;Flag=false),
!,
retractall(reuse_initialized_bdds(_)),
assert(reuse_initialized_bdds(Flag)).
set_learning_flag(learning_rate,V) :-
(V=examples -> true;(number(V),V>=0)),
!,
retractall(learning_rate(_)),
assert(learning_rate(V)).
set_learning_flag(probability_initializer,(FactID,Probability,Query)) :-
var(FactID),
var(Probability),
callable(Query),
retractall(probability_initializer(_,_,_)),
assert(probability_initializer(FactID,Probability,Query)).
set_learning_flag(check_duplicate_bdds,Flag) :-
(Flag=true;Flag=false),
!,
retractall(check_duplicate_bdds(_)),
assert(check_duplicate_bdds(Flag)).
set_learning_flag(output_directory,Directory) :-
(
file_exists(Directory)
->
file_property(Directory,type(directory));
make_directory(Directory)
),
working_directory(PWD,PWD),
atomic_concat([PWD,'/',Directory,'/'],Path),
atomic_concat([Directory,'/log.dat'],Logfile),
retractall(output_directory(_)),
assert(output_directory(Path)),
logger_set_filename(Logfile),
set_problog_flag(dir,Directory).
set_learning_flag(query_directory,Directory) :-
(
file_exists(Directory)
->
file_property(Directory,type(directory));
make_directory(Directory)
),
working_directory(PWD,PWD),
atomic_concat([PWD,'/',Directory,'/'],Path),
retractall(query_directory(_)),
assert(query_directory(Path)).
set_learning_flag(log_frequency,Frequency) :-
integer(Frequency),
Frequency>=0,
retractall(log_frequency(_)),
assert(log_frequency(Frequency)).
set_learning_flag(alpha,Alpha) :-
number(Alpha),
retractall(alpha(_)),
assert(alpha(Alpha)).
set_learning_flag(sigmoid_slope,Slope) :-
number(Slope),
Slope>0,
retractall(sigmoid_slope(_)),
assert(sigmoid_slope(Slope)).
set_learning_flag(line_search,Flag) :-
(Flag=true;Flag=false),
!,
retractall(line_search(_)),
assert(line_search(Flag)).
set_learning_flag(line_search_tolerance,Number) :-
number(Number),
Number>0,
retractall(line_search_tolerance(_)),
assert(line_search_tolerance(Number)).
set_learning_flag(line_search_interval,(L,R)) :-
number(L),
number(R),
L<R,
retractall(line_search_interval(_,_)),
assert(line_search_interval(L,R)).
set_learning_flag(line_search_tau,Number) :-
number(Number),
Number>0,
retractall(line_search_tau(_)),
assert(line_search_tau(Number)).
set_learning_flag(line_search_never_stop,Flag) :-
(Flag=true;Flag=false),
!,
retractall(line_search_nerver_stop(_)),
assert(line_search_never_stop(Flag)).
%========================================================================
%= store the facts with the learned probabilities to a file
%= if F is a variable, a filename based on the current iteration is used
%=
%========================================================================
save_model(F) :-
(
var(F)
->
(
current_iteration(Iteration),
output_directory(Directory),
atomic_concat([Directory,'factprobs_',Iteration,'.pl'],F)
);true
),
export_facts(F).
%========================================================================
%= store the probabilities for all training and test examples
%= if F is a variable, a filename based on the current iteration is used
%=
%========================================================================
save_predictions(F) :-
update_values,
current_iteration(Iteration),
(
var(F)
->
(
current_iteration(Iteration),
output_directory(Directory),
atomic_concat([Directory,'predictions_',Iteration,'.pl'],F)
);true
),
open(F,'append',Handle),
format(Handle,"%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%\n",[]),
format(Handle,"% Iteration, train/test, QueryID, Query, GroundTruth, Prediction %\n",[]),
format(Handle,"%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%\n",[]),
!,
( % go over all training examples
current_predicate(user:example/3),
user:example(Query_ID,Query,TrueQueryProb),
query_probability(Query_ID,LearnedQueryProb),
format(Handle,'ex(~q,train,~q,~q,~10f,~10f).\n',
[Iteration,Query_ID,Query,TrueQueryProb,LearnedQueryProb]),
fail; % go to next training example
true
),
( % go over all test examples
current_predicate(user:test_example/3),
user:test_example(Query_ID,Query,TrueQueryProb),
query_probability(Query_ID,LearnedQueryProb),
format(Handle,'ex(~q,test,~q,~q,~10f,~10f).\n',
[Iteration,Query_ID,Query,TrueQueryProb,LearnedQueryProb]),
fail; % go to next test example
true
),
format(Handle,'~3n',[]),
close(Handle).
%========================================================================
%= find out whether some example IDs are used more than once
%= if so, complain and stop
%=
%========================================================================
check_examples :-
(
(
(current_predicate(user:example/3),user:example(ID,_,_), \+ atomic(ID)) ;
(current_predicate(user:test_example/3),user:test_example(ID,_,_), \+ atomic(ID))
)
->
(
format(user_error,'The example id of example ~q is not atomic (e.g foo42, 23, bar, ...).~n',[ID]),
throw(error(examples))
); true
),
(
(
(current_predicate(user:example/3),user:example(ID,_,P), (\+ number(P); P>1 ; P<0));
(current_predicate(user:test_example/3),user:test_example(ID,_,P), (\+ number(P) ; P>1 ; P<0))
)
->
(
format(user_error,'The example ~q does not have a valid probaility value (~q).~n',[ID,P]),
throw(error(examples))
); true
),
(
(
(
current_predicate(user:example/3),
user:example(ID,QueryA,_),
user:example(ID,QueryB,_),
QueryA \= QueryB
) ;
(
current_predicate(user:test_example/3),
user:test_example(ID,QueryA,_),
user:test_example(ID,QueryB,_),
QueryA \= QueryB
);
(
current_predicate(user:example/3),
current_predicate(user:test_example/3),
user:example(ID,QueryA,_),
user:test_example(ID,QueryB,_),
QueryA \= QueryB
)
)
->
(
format(user_error,'The example id ~q is used several times.~n',[ID]),
throw(error(examples))
); true
).
%========================================================================
%= initialize everything and perform Iterations times gradient descent
%= can be called several times
%= if it is called with an epsilon parameter, it stops when the change
%= in the MSE is smaller than epsilon
%========================================================================
do_learning(Iterations) :-
integer(Iterations),
(
current_predicate(user:example/3)
->
true;
format(user_error,'~n~nWarning: No training examples specified !!!~n~n',[])
),
do_learning_intern(Iterations,-1).
do_learning(Iterations,Epsilon) :-
integer(Iterations),
float(Epsilon),
Iterations>0,
Epsilon>0.0,
(
current_predicate(user:example/3)
->
true;
format(user_error,'~n~nWarning: No training examples specified !!!~n~n',[])
),
do_learning_intern(Iterations,Epsilon).
do_learning_intern(Iterations,Epsilon) :-
(
Iterations=0
->
true;
(
Iterations>0,
% nothing will happen, if we're already initialized
init_learning,
current_iteration(OldIteration),
!,
retractall(current_iteration(_)),
!,
CurrentIteration is OldIteration+1,
assert(current_iteration(CurrentIteration)),
EndIteration is OldIteration+Iterations,
format('~n Iteration ~d of ~d~n',[CurrentIteration,EndIteration]),
logger_set_variable(iteration,CurrentIteration),
logger_start_timer(duration),
gradient_descent,
(
(rebuild_bdds(true),rebuild_bdds_it(BDDFreq),0 =:= CurrentIteration mod BDDFreq)
->
(
once(delete_all_queries),
once(init_queries)
); true
),
mse_trainingset,
mse_testset,
(
last_mse(Last_MSE)
->
(
retractall(last_mse(_)),
logger_get_variable(mse_trainingset,Current_MSE),
assert(last_mse(Current_MSE)),
!,
MSE_Diff is abs(Last_MSE-Current_MSE)
); (
logger_get_variable(mse_trainingset,Current_MSE),
assert(last_mse(Current_MSE)),
MSE_Diff is Epsilon+1
)
),
!,
logger_stop_timer(duration),
once(ground_truth_difference),
logger_write_data,
log_frequency(Log_Frequency),
(
( Log_Frequency=0; 0 =:= CurrentIteration mod Log_Frequency)
->
(
save_predictions(_X),
save_model(_Y)
);
true
),
RemainingIterations is Iterations-1,
(
MSE_Diff>Epsilon
->
do_learning_intern(RemainingIterations,Epsilon);
true
)
)
).
%========================================================================
%= find proofs and build bdds for all training and test examples
%=
%=
%========================================================================
init_learning :-
(
learning_initialized
->
true;
(
check_examples,
format('Delete previous logs (if existing) from output directory~2n',[]),
empty_output_directory,
format('Initializing everything~n',[]),
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% Delete the BDDs from the previous run if they should
% not be reused
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
(
(reuse_initialized_bdds(false);rebuild_bdds(true))
->
delete_all_queries;
true
),
logger_write_header,
logger_start_timer(duration),
logger_set_variable(iteration,0),
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% start count examples
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
bb_put(training_examples,0),
( % go over all training examples
current_predicate(user:example/3),
user:example(_,_,_),
bb_get(training_examples, OldCounter),
NewCounter is OldCounter+1,
bb_put(training_examples,NewCounter),
fail;
true
),
bb_put(test_examples,0),
( % go over all test examples
current_predicate(user:test_example/3),
user:test_example(_,_,_),
bb_get(test_examples, OldCounter),
NewCounter is OldCounter+1,
bb_put(test_examples,NewCounter),
fail;
true
),
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% stop count examples
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
!,
bb_delete(training_examples,TrainingExampleCount),
bb_delete(test_examples,TestExampleCount),
assert(example_count(TrainingExampleCount)),
(
learning_rate(examples)
->
set_learning_flag(learning_rate,TrainingExampleCount);
true
),
learning_rate(Learning_Rate),
format('~q training examples found.~n~q test examples found.~nlearning rate=~f~n~n',
[TrainingExampleCount,TestExampleCount,Learning_Rate]),
format('Generate BDDs for all queries in the training and test set~n',[]),
initialize_fact_probabilities,
init_queries,
format('All Queries have been generated~n',[]),
mse_trainingset,
mse_testset,
!,
logger_stop_timer(duration),
ground_truth_difference,
logger_write_data,
assert(current_iteration(0)),
assert(learning_initialized),
save_model(_),save_predictions(_)
)
).
%========================================================================
%=
%=
%=
%========================================================================
delete_all_queries :-
query_directory(Directory),
atomic_concat(['rm -f ',Directory,'query_*'],Command),
(shell(Command) -> true; true),
retractall(query_is_similar(_,_)),
retractall(query_md5(_,_)).
empty_output_directory :-
output_directory(Directory),
atomic_concat(['rm -f ',Directory,'log.dat ',
Directory,'factprobs_*.pl ',
Directory,'predictions_*.pl'],Command),
(shell(Command) -> true; true).
%========================================================================
%= This predicate goes over all training and test examples,
%= calls the inference method of ProbLog and stores the resulting
%= BDDs
%========================================================================
init_queries :-
( % go over all training examples
current_predicate(user:example/3),
user:example(ID,Query,Prob),
format('~n~n training example ~q: ~q~n',[ID,Query]),
flush_output(user),
init_one_query(ID,Query),
fail; %go to next training example
true
),
( % go over all test examples
current_predicate(user:test_example/3),
user:test_example(ID,Query,Prob),
format('~n~n test example ~q: ~q~n',[ID,Query]),
flush_output(user),
init_one_query(ID,Query),
fail; % go to next test example
true
).
init_one_query(QueryID,Query) :-
output_directory(Output_Directory),
query_directory(Query_Directory),
atomic_concat([Query_Directory,'query_',QueryID],Filename),
atomic_concat([Output_Directory,'input.txt'],Filename2),
atomic_concat([Output_Directory,'tmp_md5'],Filename3),
(
file_exists(Filename)
->
format('Reuse existing BDD ~q~n~n',[Filename]);
(
init_method(Query,_Prob,Filename,Filename2,InitCall),
once(call(InitCall)),
delete_file(Filename2)
)
),
(
check_duplicate_bdds(true)
->
(
% calculate the md5sum of the bdd script file
atomic_concat(['cat ',Filename,' | md5sum | sed "s/ .*$/\')./" | sed "s/^/md5(\'/"> ',Filename3],MD5Command),
(shell(MD5Command,0) -> true; throw(error("Something wrong with calculating the MD5 value"))),
open(Filename3, read, Handle),
read(Handle,md5(Query_MD5)),
close(Handle),
delete_file(Filename3),
% Does another query exists which already has this MD5?
(
query_md5(OtherQueryID,Query_MD5)
->
% yippie! we can save a lot of work
(
assert(query_is_similar(QueryID,OtherQueryID)),
format('~q is similar to ~q~2n', [QueryID,OtherQueryID])
); assert(query_md5(QueryID,Query_MD5))
)
);
true
).
%========================================================================
%= set all unknown fact probabilities to random values
%=
%=
%========================================================================
initialize_fact_probabilities :-
( % go over all tunable facts
tunable_fact(FactID,_),
probability_initializer(FactID,Probability,Query),
once(call(Query)),
set_fact_probability(FactID,Probability),
fail; % go to next tunable fact
true
).
random_probability(_FactID,Probability) :-
% use probs around 0.5 to not confuse k-best search
random(Random),
Probability is 0.5+(Random-0.5)/100.
%========================================================================
%= updates all values of query_probability/2 and query_gradient/3
%= should be called always before these predicates are accessed
%= if the old values are still valid, nothing happens
%========================================================================
update_values :-
update_values(all).
update_values(_) :-
values_correct,
!.
update_values(What_To_Update) :-
\+ values_correct,
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% delete old values
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
once(retractall(query_probability_intern(_,_))),
once(retractall(query_gradient_intern(_,_,_))),
output_directory(Directory),
atomic_concat(Directory,'input.txt',Input_Filename),
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% start write current probabilities to file
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
open(Input_Filename,'write',Handle),
( % go over all probabilistic fact
get_fact_probability(ID,Prob),
inv_sigmoid(Prob,Value),
(
non_ground_fact(ID)
->
format(Handle,'@x~q_*~n~10f~n',[ID,Value]);
format(Handle,'@x~q~n~10f~n',[ID,Value])
),
fail; % go to next probabilistic fact
true
),
close(Handle),
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% stop write current probabilities to file
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
!,
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% start update values for all test examples
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
( What_To_Update = all
->
( % go over all training examples
current_predicate(user:test_example/3),
user:test_example(QueryID,_Query,_QueryProb),
once(call_bdd_tool(QueryID,'+',all)),
fail; % go to next training example
true
); true
),
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% stop update values for all test examples
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
!,
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% start update values for all training examples
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
( % go over all training examples
current_predicate(user:example/3),
user:example(QueryID,_Query,_QueryProb),
once(call_bdd_tool(QueryID,'.',What_To_Update)),
fail; % go to next training example
true
),
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% stop update values for all training examples
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
!,
nl,
delete_file(Input_Filename),
assert(values_correct).
%========================================================================
%=
%=
%=
%========================================================================
call_bdd_tool(QueryID,Symbol,What_To_Update) :-
output_directory(Output_Directory),
query_directory(Query_Directory),
(
query_is_similar(QueryID,_)
->
% we don't have to evaluate the BDD
write('#');
(
sigmoid_slope(Slope),
problog_dir(PD),
(What_To_Update=all -> Method='g' ; Method='l'),
atomic_concat([PD,
'/ProblogBDD -i "',
Output_Directory,
'input.txt',
'" -l "',
Query_Directory,
'query_',
QueryID,
'" -m ',Method,' -id ',
QueryID,
' -sl ',Slope,
' > "',
Output_Directory,
'values.pl"'],Command),
shell(Command,Error),
atomic_concat([' cat "',
Output_Directory,
'values.pl" >> ~/all_results'],Command2),
shell(Command2),
(
Error = 2
->
throw(error('SimpleCUDD has been interrupted.'));
true
),
(
Error \= 0
->
throw(bdd_error(QueryID,Error));
true
),
atomic_concat([Output_Directory,'values.pl'],Values_Filename),
(
file_exists(Values_Filename)
->
(
(
once(my_load(Values_Filename))
->
true;
(
format(user_error,'ERROR: Tried to read the file ~q but my_load/1 fails.~n~q.~2n',[Values_Filename,call_bdd_tool(QueryID,Symbol,What_To_Update)]),
throw(error(my_load_fails))
)
);
(
format(user_error,'ERROR: Tried to read the file ~q but it does not exist.~n~q.~2n',[Values_Filename,call_bdd_tool(QueryID,Symbol,What_To_Update)]),
throw(error(output_file_does_not_exist))
)
)
),
delete_file(Values_Filename),
write(Symbol)
)
),
flush_output(user).
%========================================================================
%=
%=
%=
%========================================================================
my_load(File) :-
see(File),
read(X),
my_load_intern(X),
seen.
my_load_intern(end_of_file) :-
!.
my_load_intern(query_probability(QueryID,Prob)) :-
!,
assert(query_probability_intern(QueryID,Prob)),
read(X2),
my_load_intern(X2).
my_load_intern(query_gradient(QueryID,XFactID,Value)) :-
!,
atomic_concat(x,StringFactID,XFactID),
atom_number(StringFactID,FactID),
assert(query_gradient_intern(QueryID,FactID,Value)),
read(X2),
my_load_intern(X2).
my_load_intern(X) :-
format(user_error,'Unknown atom ~q in results file.~n',[X]),
read(X2),
my_load_intern(X2).
%========================================================================
%=
%=
%=
%========================================================================
query_probability(QueryID,Prob) :-
(
query_probability_intern(QueryID,Prob)
->
true;
(
query_is_similar(QueryID,OtherQueryID),
query_probability_intern(OtherQueryID,Prob)
)
).
query_gradient(QueryID,Fact,Value) :-
(
query_gradient_intern(QueryID,Fact,Value)
->
true;
(
query_is_similar(QueryID,OtherQueryID),
query_gradient_intern(OtherQueryID,Fact,Value)
)
).
%========================================================================
%=
%=
%=
%========================================================================
ground_truth_difference :-
findall(Diff,(tunable_fact(FactID,GroundTruth),
\+ var(GroundTruth),
get_fact_probability(FactID,Prob),
Diff is abs(GroundTruth-Prob)),AllDiffs),
% if no ground truth was specified for facts
% set everything to zero
(
AllDiffs=[]
->
(
MinDiff=0.0,
MaxDiff=0.0,
DiffMean=0.0
) ; (
length(AllDiffs,Len),
sum_list(AllDiffs,AllDiffsSum),
min_list(AllDiffs,MinDiff),
max_list(AllDiffs,MaxDiff),
DiffMean is AllDiffsSum/Len
)
),
logger_set_variable(ground_truth_diff,DiffMean),
logger_set_variable(ground_truth_mindiff,MinDiff),
logger_set_variable(ground_truth_maxdiff,MaxDiff).
%========================================================================
%= Calculates the mse of training and test data
%=
%= -Float
%========================================================================
mse_trainingset_only_for_linesearch(MSE) :-
(
current_predicate(user:example/3)
->
(
update_values(probabilities),
findall(SquaredError,
(user:example(QueryID,_Query,QueryProb),
query_probability(QueryID,CurrentProb),
SquaredError is (CurrentProb-QueryProb)**2),
AllSquaredErrors),
length(AllSquaredErrors,Length),
sum_list(AllSquaredErrors,SumAllSquaredErrors),
MSE is SumAllSquaredErrors/Length
); true
),
retractall(values_correct).
% calculate the mse of the training data
mse_trainingset :-
(
current_predicate(user:example/3)
->
(
update_values,
findall(SquaredError,
(user:example(QueryID,_Query,QueryProb),
query_probability(QueryID,CurrentProb),
SquaredError is (CurrentProb-QueryProb)**2),
AllSquaredErrors),
length(AllSquaredErrors,Length),
sum_list(AllSquaredErrors,SumAllSquaredErrors),
min_list(AllSquaredErrors,MinError),
max_list(AllSquaredErrors,MaxError),
MSE is SumAllSquaredErrors/Length,
logger_set_variable(mse_trainingset,MSE),
logger_set_variable(mse_min_trainingset,MinError),
logger_set_variable(mse_max_trainingset,MaxError)
); true
).
mse_testset :-
(
current_predicate(user:test_example/3)
->
(
update_values,
findall(SquaredError,
(user:test_example(QueryID,_Query,QueryProb),
query_probability(QueryID,CurrentProb),
SquaredError is (CurrentProb-QueryProb)**2),
AllSquaredErrors),
length(AllSquaredErrors,Length),
sum_list(AllSquaredErrors,SumAllSquaredErrors),
min_list(AllSquaredErrors,MinError),
max_list(AllSquaredErrors,MaxError),
MSE is SumAllSquaredErrors/Length,
logger_set_variable(mse_testset,MSE),
logger_set_variable(mse_min_testset,MinError),
logger_set_variable(mse_max_testset,MaxError)
); true
).
%========================================================================
%= Calculates the sigmoid function respectivly the inverse of it
%= warning: applying inv_sigmoid to 0.0 or 1.0 will yield +/-inf
%=
%= +Float, -Float
%========================================================================
sigmoid(T,Sig) :-
sigmoid_slope(Slope),
Sig is 1/(1+exp(-T*Slope)).
inv_sigmoid(T,InvSig) :-
sigmoid_slope(Slope),
InvSig is -log(1/T-1)/Slope.
%========================================================================
%= this functions truncates probabilities too close to 1.0 or 0.0
%= the reason is, applying the inverse sigmoid function would yield +/- inf
%= for such extreme values
%=
%= +Float, -Float
%========================================================================
secure_probability(Prob,Prob_Secure) :-
TMP is max(0.000000001,Prob),
Prob_Secure is min(0.999999999,TMP).
%========================================================================
%= Perform one iteration of gradient descent
%=
%= assumes that everything is initialized, if the current values
%= of query_probability/2 and query_gradient/3 are not up to date
%= they will be recalculated
%= finally, the values_correct/0 is retracted to signal that the
%= probabilities of the examples have to be recalculated
%========================================================================
save_old_probabilities :-
( % go over all tunable facts
tunable_fact(FactID,_),
get_fact_probability(FactID,OldProbability),
atomic_concat(['old_prob_',FactID],Key),
bb_put(Key,OldProbability),
fail; % go to next tunable fact
true
).
forget_old_values :-
( % go over all tunable facts
tunable_fact(FactID,_),
atomic_concat(['old_prob_',FactID],Key),
atomic_concat(['grad_',FactID],Key2),
bb_delete(Key,_),
bb_delete(Key2,_),
fail; % go to next tunable fact
true
).
add_gradient(Learning_Rate) :-
( % go over all tunable facts
tunable_fact(FactID,_),
atomic_concat(['old_prob_',FactID],Key),
atomic_concat(['grad_',FactID],Key2),
bb_get(Key,OldProbability),
bb_get(Key2,GradValue),
inv_sigmoid(OldProbability,OldValue),
NewValue is OldValue -Learning_Rate*GradValue,
sigmoid(NewValue,NewProbability),
% Prevent "inf" by using values too close to 1.0
secure_probability(NewProbability,NewProbabilityS),
set_fact_probability(FactID,NewProbabilityS),
fail; % go to next tunable fact
true
),
retractall(values_correct).
simulate :-
L = [0.6,1.0,2.0,3.0,10,50,100,200,300],
findall((X,Y),(member(X,L),line_search_evaluate_point(X,Y)),List),
write(List),nl.
gradient_descent :-
save_old_probabilities,
update_values,
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% start set gradient to zero
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
( % go over all tunable facts
tunable_fact(FactID,_),
atomic_concat(['grad_',FactID],Key),
bb_put(Key,0.0),
fail; % go to next tunable fact
true
),
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% stop gradient to zero
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
!,
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% start calculate gradient
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
alpha(Alpha),
example_count(ExampleCount),
( % go over all training examples
current_predicate(user:example/3),
user:example(QueryID,_Query,QueryProb),
query_probability(QueryID,BDDProb),
(
QueryProb=:=0.0
->
Y2=Alpha;
Y2=1.0
),
Y is Y2*2/ExampleCount * (BDDProb-QueryProb),
( % go over all tunable facts
tunable_fact(FactID,_),
atomic_concat(['grad_',FactID],Key),
% if the following query fails,
% it means, the fact is not used in the proof
% of QueryID, and the gradient is 0.0 and will
% not contribute to NewValue either way
% DON'T FORGET THIS IF YOU CHANGE SOMETHING HERE!
query_gradient(QueryID,FactID,GradValue),
bb_get(Key,OldValue),
NewValue is OldValue + Y*GradValue,
bb_put(Key,NewValue),
fail; % go to next fact
true
),
fail; % go to next training example
true
),
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% stop calculate gradient
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
!,
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% start statistics on gradient
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
findall(V,(tunable_fact(FactID,_),atomic_concat(['grad_',FactID],Key),bb_get(Key,V)),GradientValues),
sum_list(GradientValues,GradSum),
max_list(GradientValues,GradMax),
min_list(GradientValues,GradMin),
length(GradientValues,GradLength),
GradMean is GradSum/GradLength,
logger_set_variable(gradient_mean,GradMean),
logger_set_variable(gradient_min,GradMin),
logger_set_variable(gradient_max,GradMax),
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% stop statistics on gradient
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% start add gradient to current probabilities
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
(
line_search(false)
->
learning_rate(LearningRate);
lineSearch(LearningRate,_)
),
format('learning rate = ~12f~n',[LearningRate]),
add_gradient(LearningRate),
logger_set_variable(learning_rate,LearningRate),
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% stop add gradient to current probabilities
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
!,
forget_old_values.
%========================================================================
%=
%=
%========================================================================
line_search_evaluate_point(Learning_Rate,MSE) :-
add_gradient(Learning_Rate),
mse_trainingset_only_for_linesearch(MSE).
lineSearch(Final_X,Final_Value) :-
% Get Parameters for line search
line_search_tolerance(Tol),
line_search_tau(Tau),
line_search_interval(A,B),
format(' Running line search in interval (~5f,~5f)~n',[A,B]),
% init values
Acc is Tol * (B-A),
InitRight is A + Tau*(B-A),
InitLeft is A + B - InitRight,
line_search_evaluate_point(A,Value_A),
line_search_evaluate_point(B,Value_B),
line_search_evaluate_point(InitRight,Value_InitRight),
line_search_evaluate_point(InitLeft,Value_InitLeft),
bb_put(line_search_a,A),
bb_put(line_search_b,B),
bb_put(line_search_left,InitLeft),
bb_put(line_search_right,InitRight),
bb_put(line_search_value_a,Value_A),
bb_put(line_search_value_b,Value_B),
bb_put(line_search_value_left,Value_InitLeft),
bb_put(line_search_value_right,Value_InitRight),
bb_put(line_search_iteration,1),
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%% BEGIN BACK TRACKING
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
(
repeat,
bb_get(line_search_iteration,Iteration),
bb_get(line_search_a,Ak),
bb_get(line_search_b,Bk),
bb_get(line_search_left,Left),
bb_get(line_search_right,Right),
bb_get(line_search_value_a,Fl),
bb_get(line_search_value_b,Fr),
bb_get(line_search_value_left,FLeft),
bb_get(line_search_value_right,FRight),
write(lineSearch(Iteration,Ak,Fl,Bk,Fr,Left,FLeft,Right,FRight)),nl,
(
% check for infinity, if there is, go to the left
( FLeft >= FRight, \+ FLeft = (+inf), \+ FRight = (+inf) )
->
(
AkNew=Left,
FlNew=FLeft,
LeftNew=Right,
FLeftNew=FRight,
RightNew is AkNew + Bk - LeftNew,
line_search_evaluate_point(RightNew,FRightNew),
BkNew=Bk,
FrNew=Fr
);
(
BkNew=Right,
FrNew=FRight,
RightNew=Left,
FRightNew=FLeft,
LeftNew is Ak + BkNew - RightNew,
line_search_evaluate_point(LeftNew,FLeftNew),
AkNew=Ak,
FlNew=Fl
)
),
Next_Iteration is Iteration + 1,
ActAcc is BkNew -AkNew,
bb_put(line_search_iteration,Next_Iteration),
bb_put(line_search_a,AkNew),
bb_put(line_search_b,BkNew),
bb_put(line_search_left,LeftNew),
bb_put(line_search_right,RightNew),
bb_put(line_search_value_a,FlNew),
bb_put(line_search_value_b,FrNew),
bb_put(line_search_value_left,FLeftNew),
bb_put(line_search_value_right,FRightNew),
% is the search interval smaller than the tolerance level?
ActAcc < Acc,
% apperantly it is, so get me out of here and
% cut away the choice point from repeat
!
),
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%% END BACK TRACKING
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% clean up the blackboard mess
bb_delete(line_search_iteration,_),
bb_delete(line_search_a,_),
bb_delete(line_search_b,_),
bb_delete(line_search_left,_),
bb_delete(line_search_right,_),
bb_delete(line_search_value_a,_),
bb_delete(line_search_value_b,_),
bb_delete(line_search_value_left,_),
bb_delete(line_search_value_right,_),
% it doesn't harm to check also the value in the middle
% of the current search interval
Middle is (AkNew + BkNew) / 2.0,
line_search_evaluate_point(Middle,Value_Middle),
% return the optimal value
my_5_min(Value_Middle,FlNew,FrNew,FLeftNew,FRightNew,
Middle,AkNew,BkNew,LeftNew,RightNew,
Optimal_Value,Optimal_X),
line_search_postcheck(Optimal_Value,Optimal_X,Final_Value,Final_X).
line_search_postcheck(V,X,V,X) :-
X>0,
!.
line_search_postcheck(V,X,V,X) :-
line_search_never_stop(false),
!.
line_search_postcheck(_,_, LLH, FinalPosition) :-
line_search_tolerance(Tolerance),
line_search_interval(Left,Right),
Offset is (Right - Left) * Tolerance,
bb_put(line_search_offset,Offset),
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
(
repeat,
bb_get(line_search_offset,OldOffset),
NewOffset is OldOffset * Tolerance,
bb_put(line_search_offset,NewOffset),
Position is Left + NewOffset,
set_linesearch_weights_calc_llh(Position,LLH),
bb_put(line_search_llh,LLH),
write(logAtom(lineSearchPostCheck(Position,LLH))),nl,
\+ LLH = (+inf),
!
), % cut away choice point from repeat
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
bb_delete(line_search_llh,LLH),
bb_delete(line_search_offset,FinalOffset),
FinalPosition is Left + FinalOffset.
my_5_min(V1,V2,V3,V4,V5,F1,F2,F3,F4,F5,VMin,FMin) :-
(
V1<V2
->
(VTemp1=V1,FTemp1=F1);
(VTemp1=V2,FTemp1=F2)
),
(
V3<V4
->
(VTemp2=V3,FTemp2=F3);
(VTemp2=V4,FTemp2=F4)
),
(
VTemp1<VTemp2
->
(VTemp3=VTemp1,FTemp3=FTemp1);
(VTemp3=VTemp2,FTemp3=FTemp2)
),
(
VTemp3<V5
->
(VMin=VTemp3,FMin=FTemp3);
(VMin=V5,FMin=F5)
).
%========================================================================
%= initialize the logger module and set the flags for learning
%=
%========================================================================
global_initialize :-
set_learning_flag(output_directory,'./output'),
set_learning_flag(query_directory,'./queries'),
set_learning_flag(log_frequency,5),
set_learning_flag(rebuild_bdds,false),
set_learning_flag(rebuild_bdds_it,1),
set_learning_flag(reuse_initialized_bdds,false),
set_learning_flag(learning_rate,examples),
set_learning_flag(check_duplicate_bdds,true),
set_learning_flag(probability_initializer,(FactID,P,random_probability(FactID,P))),
set_learning_flag(alpha,1.0),
set_learning_flag(sigmoid_slope,1.0), % 1.0 gives standard sigmoid
set_learning_flag(init_method,(Query,Probability,BDDFile,ProbFile,
problog_kbest_save(Query,100,Probability,_Status,BDDFile,ProbFile))),
set_learning_flag(line_search,false),
set_learning_flag(line_search_never_stop,true),
set_learning_flag(line_search_tau,0.618033988749895),
set_learning_flag(line_search_tolerance,0.05),
set_learning_flag(line_search_interval,(0,100)),
logger_define_variable(iteration, int),
logger_define_variable(duration,time),
logger_define_variable(mse_trainingset,float),
logger_define_variable(mse_min_trainingset,float),
logger_define_variable(mse_max_trainingset,float),
logger_define_variable(mse_testset,float),
logger_define_variable(mse_min_testset,float),
logger_define_variable(mse_max_testset,float),
logger_define_variable(gradient_mean,float),
logger_define_variable(gradient_min,float),
logger_define_variable(gradient_max,float),
logger_define_variable(ground_truth_diff,float),
logger_define_variable(ground_truth_mindiff,float),
logger_define_variable(ground_truth_maxdiff,float),
logger_define_variable(learning_rate,float).
%========================================================================
%=
%=
%========================================================================
:- initialization(global_initialize).