/usr/include/shogun/structure/DualLibQPBMSOSVM.h is in libshogun-dev 3.2.0-7.3build4.
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* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 3 of the License, or
* (at your option) any later version.
*
* Written (W) 2012 Michal Uricar
* Copyright (C) 2012 Michal Uricar
*/
#ifndef _DUALLIBQPBMSOSVM__H__
#define _DUALLIBQPBMSOSVM__H__
#include <shogun/machine/LinearStructuredOutputMachine.h>
#include <shogun/features/DotFeatures.h>
#include <shogun/structure/BmrmStatistics.h>
namespace shogun
{
/**
* Enum
* Training method selection
*/
enum ESolver
{
BMRM=1, /**< Standard BMRM algorithm. */
PPBMRM=2, /**< Proximal Point BMRM (BMRM with prox-term) */
P3BMRM=3, /**< Proximal Point P-BMRM (multiple cutting plane models) */
NCBM=4
};
/**
* @brief Class DualLibQPBMSOSVM that uses Bundle Methods for Regularized Risk
* Minimization algorithms for structured output (SO) problems [1] presented
* in [2].
*
* [1] Tsochantaridis, I., Hofmann, T., Joachims, T., Altun, Y.
* Support Vector Machine Learning for Interdependent and Structured Ouput
* Spaces.
* http://www.cs.cornell.edu/People/tj/publications/tsochantaridis_etal_04a.pdf
*
* [2] Teo, C.H., Vishwanathan, S.V.N, Smola, A. and Quoc, V.Le.
* Bundle Methods for Regularized Risk Minimization
* http://users.cecs.anu.edu.au/~chteo/pub/TeoVisSmoLe10.pdf
*/
class CDualLibQPBMSOSVM : public CLinearStructuredOutputMachine
{
public:
/** default constructor */
CDualLibQPBMSOSVM();
/** constructor
*
* @param model Structured Model
* @param labs Structured labels
* @param _lambda Regularization constant
* @param W initial solution of weight vector
*/
CDualLibQPBMSOSVM(
CStructuredModel* model,
CStructuredLabels* labs,
float64_t _lambda,
SGVector< float64_t > W=0);
/** destructor */
virtual ~CDualLibQPBMSOSVM();
/** @return name of SGSerializable */
virtual const char* get_name() const { return "DualLibQPBMSOSVM"; }
/** set lambda
*
* @param _lambda Regularization constant
*/
inline void set_lambda(float64_t _lambda) { m_lambda=_lambda; }
/** get lambda
*
* @return Regularization constant
*/
inline float64_t get_lambda() { return m_lambda; }
/** set relative tolerance
*
* @param TolRel Relative tolerance
*/
inline void set_TolRel(float64_t TolRel) { m_TolRel=TolRel; }
/** get relative tolerance
*
* @return Relative tolerance
*/
inline float64_t get_TolRel() { return m_TolRel; }
/** set absolute tolerance
*
* @param TolAbs Absolute tolerance
*/
inline void set_TolAbs(float64_t TolAbs) { m_TolAbs=TolAbs; }
/** get absolute tolerance
*
* @return Absolute tolerance
*/
inline float64_t get_TolAbs() { return m_TolAbs; }
/** set size of cutting plane buffer
*
* @param BufSize Size of the cutting plane buffer (i.e. maximal number of
* iterations)
*/
inline void set_BufSize(uint32_t BufSize) { m_BufSize=BufSize; }
/** get size of cutting plane buffer
*
* @return Size of the cutting plane buffer
*/
inline uint32_t get_BufSize() { return m_BufSize; }
/** set ICP removal flag
*
* @param cleanICP Flag that enables/disables inactive cutting plane removal
* feature
*/
inline void set_cleanICP(bool cleanICP) { m_cleanICP=cleanICP; }
/** get ICP removal flag
*
* @return Status of inactive cutting plane removal feature (enabled/disabled)
*/
inline bool get_cleanICP() { return m_cleanICP; }
/** set number of iterations for cleaning ICP
*
* @param cleanAfter Specifies number of iterations that inactive cutting
* planes has to be inactive for to be removed
*/
inline void set_cleanAfter(uint32_t cleanAfter) { m_cleanAfter=cleanAfter; }
/** get number of iterations for cleaning ICP
*
* @return Number of iterations that inactive cutting planes has to be
* inactive for to be removed
*/
inline uint32_t get_cleanAfter() { return m_cleanAfter; }
/** set K
*
* @param K Parameter K
*/
inline void set_K(float64_t K) { m_K=K; }
/** get K
*
* @return K
*/
inline float64_t get_K() { return m_K; }
/** set Tmax
*
* @param Tmax Parameter Tmax
*/
inline void set_Tmax(uint32_t Tmax) { m_Tmax=Tmax; }
/** get Tmax
*
* @return Tmax
*/
inline uint32_t get_Tmax() { return m_Tmax; }
/** set number of cutting plane models
*
* @param cp_models Number of cutting plane models
*/
inline void set_cp_models(uint32_t cp_models) { m_cp_models=cp_models; }
/** get number of cutting plane models
*
* @return Number of cutting plane models
*/
inline uint32_t get_cp_models() { return m_cp_models; }
/** get bmrm result
*
* @return Result returned from Bundle Method algorithm
*/
inline BmrmStatistics get_result() { return m_result; }
/** get training algorithm
*
* @return Type of Bundle Method solver used for training
*/
inline ESolver get_solver() { return m_solver; }
/** set training algorithm
*
* @param solver Type of Bundle Method solver used for training
*/
inline void set_solver(ESolver solver) { m_solver=solver; }
/** set initial value of weight vector w
*
* @param W initial weight vector
*/
inline void set_w(SGVector< float64_t > W)
{
REQUIRE(W.vlen == m_model->get_dim(), "Dimension of the initial "
"solution must match the model's dimension!\n");
m_w=W;
}
/** get classifier type
*
* @return classifier type CT_LIBQPSOSVM
*/
virtual EMachineType get_classifier_type();
protected:
/** train dual SO-SVM
*
*/
bool train_machine(CFeatures* data=NULL);
private:
/** init parameters
*
*/
void init();
private:
/** lambda */
float64_t m_lambda;
/** TolRel */
float64_t m_TolRel;
/** TolAbs */
float64_t m_TolAbs;
/** BufSize */
uint32_t m_BufSize;
/** Clean ICP */
bool m_cleanICP;
/** Clean ICP after n-th iteration */
uint32_t m_cleanAfter;
/** K */
float64_t m_K;
/** Tmax */
uint32_t m_Tmax;
/** number of cutting plane models */
uint32_t m_cp_models;
/** BMRM result */
BmrmStatistics m_result;
/** training algorithm */
ESolver m_solver;
}; /* class CDualLibQPBMSOSVM */
} /* namespace shogun */
#endif /* _DUALLIBQPBMSOSVM__H__ */
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