// Copyright (C) 2011 Davis E. King (davis@dlib.net) // License: Boost Software License See LICENSE.txt for the full license. #undef DLIB_STRUCTURAL_SEQUENCE_LABELING_TRAiNER_ABSTRACT_Hh_ #ifdef DLIB_STRUCTURAL_SEQUENCE_LABELING_TRAiNER_ABSTRACT_Hh_ #include "../algs.h" #include "../optimization.h" #include "structural_svm_sequence_labeling_problem_abstract.h" #include "sequence_labeler_abstract.h" namespace dlib { // ---------------------------------------------------------------------------------------- template < typename feature_extractor > class structural_sequence_labeling_trainer { /*! REQUIREMENTS ON feature_extractor It must be an object that implements an interface compatible with the example_feature_extractor defined in dlib/svm/sequence_labeler_abstract.h. WHAT THIS OBJECT REPRESENTS This object is a tool for learning to do sequence labeling based on a set of training data. The training procedure produces a sequence_labeler object which can be used to predict the labels of new data sequences. Note that this is just a convenience wrapper around the structural_svm_sequence_labeling_problem to make it look similar to all the other trainers in dlib. !*/ public: typedef typename feature_extractor::sequence_type sample_sequence_type; typedef std::vector labeled_sequence_type; typedef sequence_labeler trained_function_type; structural_sequence_labeling_trainer ( ); /*! ensures - #get_c() == 100 - this object isn't verbose - #get_epsilon() == 0.1 - #get_max_iterations() == 10000 - #get_num_threads() == 2 - #get_max_cache_size() == 5 - #get_feature_extractor() == a default initialized feature_extractor !*/ explicit structural_sequence_labeling_trainer ( const feature_extractor& fe ); /*! ensures - #get_c() == 100 - this object isn't verbose - #get_epsilon() == 0.1 - #get_max_iterations() == 10000 - #get_num_threads() == 2 - #get_max_cache_size() == 5 - #get_feature_extractor() == fe !*/ const feature_extractor& get_feature_extractor ( ) const; /*! ensures - returns the feature extractor used by this object !*/ unsigned long num_labels ( ) const; /*! ensures - returns get_feature_extractor().num_labels() (i.e. returns the number of possible output labels for each element of a sequence) !*/ void set_num_threads ( unsigned long num ); /*! ensures - #get_num_threads() == num !*/ unsigned long get_num_threads ( ) const; /*! ensures - returns the number of threads used during training. You should usually set this equal to the number of processing cores on your machine. !*/ void set_epsilon ( double eps ); /*! requires - eps > 0 ensures - #get_epsilon() == eps !*/ const double get_epsilon ( ) const; /*! ensures - returns the error epsilon that determines when training should stop. Smaller values may result in a more accurate solution but take longer to train. You can think of this epsilon value as saying "solve the optimization problem until the average number of labeling mistakes per training sample is within epsilon of its optimal value". !*/ void set_max_iterations ( unsigned long max_iter ); /*! ensures - #get_max_iterations() == max_iter !*/ unsigned long get_max_iterations ( ); /*! ensures - returns the maximum number of iterations the SVM optimizer is allowed to run before it is required to stop and return a result. !*/ void set_max_cache_size ( unsigned long max_size ); /*! ensures - #get_max_cache_size() == max_size !*/ unsigned long get_max_cache_size ( ) const; /*! ensures - During training, this object basically runs the sequence_labeler on each training sample, over and over. To speed this up, it is possible to cache the results of these labeler invocations. This function returns the number of cache elements per training sample kept in the cache. Note that a value of 0 means caching is not used at all. !*/ void be_verbose ( ); /*! ensures - This object will print status messages to standard out so that a user can observe the progress of the algorithm. !*/ void be_quiet ( ); /*! ensures - this object will not print anything to standard out !*/ void set_oca ( const oca& item ); /*! ensures - #get_oca() == item !*/ const oca get_oca ( ) const; /*! ensures - returns a copy of the optimizer used to solve the structural SVM problem. !*/ void set_c ( double C ); /*! requires - C > 0 ensures - #get_c() = C !*/ double get_c ( ) const; /*! ensures - returns the SVM regularization parameter. It is the parameter that determines the trade-off between trying to fit the training data (i.e. minimize the loss) or allowing more errors but hopefully improving the generalization of the resulting sequence labeler. Larger values encourage exact fitting while smaller values of C may encourage better generalization. !*/ double get_loss ( unsigned long label ) const; /*! requires - label < num_labels() ensures - returns the loss incurred when a sequence element with the given label is misclassified. This value controls how much we care about correctly classifying this type of label. Larger loss values indicate that we care more strongly than smaller values. !*/ void set_loss ( unsigned long label, double value ); /*! requires - label < num_labels() - value >= 0 ensures - #get_loss(label) == value !*/ const sequence_labeler train( const std::vector& x, const std::vector& y ) const; /*! requires - is_sequence_labeling_problem(x, y) == true - contains_invalid_labeling(get_feature_extractor(), x, y) == false - for all valid i and j: y[i][j] < num_labels() ensures - Uses the structural_svm_sequence_labeling_problem to train a sequence_labeler on the given x/y training pairs. The idea is to learn to predict a y given an input x. - returns a function F with the following properties: - F(new_x) == A sequence of predicted labels for the elements of new_x. - F(new_x).size() == new_x.size() - for all valid i: - F(new_x)[i] == the predicted label of new_x[i] !*/ }; // ---------------------------------------------------------------------------------------- } #endif // DLIB_STRUCTURAL_SEQUENCE_LABELING_TRAiNER_ABSTRACT_Hh_