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*
*
* \brief Maximum-likelihood model selection for binary support vector machines.
*
*
*
* \author M.Tuma, T.Glasmachers
* \date 2009-2012
*
*
* \par Copyright 1995-2015 Shark Development Team
*
* <BR><HR>
* This file is part of Shark.
* <http://image.diku.dk/shark/>
*
* Shark is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as published
* by the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* Shark is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with Shark. If not, see <http://www.gnu.org/licenses/>.
*
*/
#ifndef SHARK_ML_SVMLOGISTICINTERPRETATION_H
#define SHARK_ML_SVMLOGISTICINTERPRETATION_H
#include <shark/Data/CVDatasetTools.h>
#include <shark/Models/Kernels/CSvmDerivative.h>
#include <shark/Algorithms/Trainers/SigmoidFit.h>
#include <shark/Algorithms/Trainers/CSvmTrainer.h>
#include <shark/ObjectiveFunctions/AbstractObjectiveFunction.h>
#include <shark/ObjectiveFunctions/ErrorFunction.h>
#include <boost/math/special_functions/log1p.hpp>
namespace shark {
///
/// \brief Maximum-likelihood model selection score for binary support vector machines
///
/// \par
/// This class implements the maximum-likelihood based SVM model selection
/// procedure presented in the article "Glasmachers and C. Igel. Maximum
/// Likelihood Model Selection for 1-Norm Soft Margin SVMs with Multiple
/// Parameters. IEEE Transactions on Pattern Analysis and Machine Intelligence, 2010."
/// At this point, only binary C-SVMs are supported.
/// \par
/// This class implements an AbstactObjectiveFunction. In detail, it provides
/// a differentiable measure of how well a C-SVM with given hyperparameters fulfills
/// the maximum-likelihood score presented in the paper. This error measure can then
/// be optimized for externally via gradient-based optimizers. In other words, this
/// class provides a score, not an optimization method or a training algorithm. The
/// C-SVM parameters have to be optimized with regard to this measure
///
template<class InputType = RealVector>
class SvmLogisticInterpretation : public SingleObjectiveFunction {
public:
typedef CVFolds< LabeledData<InputType, unsigned int> > FoldsType;
typedef AbstractKernelFunction<InputType> KernelType;
protected:
FoldsType m_folds; ///< the underlying partitioned dataset.
KernelType *mep_kernel; ///< the kernel with which to run the SVM
std::size_t m_nhp; ///< for convenience, the Number of Hyper Parameters
std::size_t m_nkp; ///< for convenience, the Number of Kernel Parameters
std::size_t m_numFolds; ///< the number of folds to be used in cross-validation
std::size_t m_numSamples; ///< overall number of samples in the dataset
std::size_t m_inputDims; ///< input dimensionality
bool m_svmCIsUnconstrained; ///< the SVM regularization parameter C is passed for unconstrained optimization, and the derivative should compensate for that
QpStoppingCondition *mep_svmStoppingCondition; ///< the stopping criterion that is to be passed to the SVM trainer.
bool m_sigmoidSlopeIsUnconstrained; ///< whether or not to use the unconstrained variant of the sigmoid. currently always true, not user-settable, existing for safety.
public:
//! constructor.
//! \param folds an already partitioned dataset (i.e., a CVFolds object)
//! \param kernel pointer to the kernel to be used within the SVMs.
//! \param unconstrained whether or not the C-parameter of/for the C-SVM is passed for unconstrained optimization mode.
//! \param stop_cond the stopping conditions which are to be passed to the
SvmLogisticInterpretation(
FoldsType const &folds, KernelType *kernel,
bool unconstrained = true, QpStoppingCondition *stop_cond = NULL
)
: mep_kernel(kernel)
, m_nhp(kernel->parameterVector().size()+1)
, m_nkp(kernel->parameterVector().size())
, m_numFolds(folds.size()) //gets number of folds!
, m_numSamples(folds.dataset().numberOfElements())
, m_inputDims(inputDimension(folds.dataset()))
, m_svmCIsUnconstrained(unconstrained)
, mep_svmStoppingCondition(stop_cond)
, m_sigmoidSlopeIsUnconstrained(true)
{
SHARK_CHECK(kernel != NULL, "[SvmLogisticInterpretation::SvmLogisticInterpretation] kernel is not allowed to be NULL"); //mtq: necessary despite indirect check via call in initialization list?
SHARK_CHECK(m_numFolds > 1, "[SvmLogisticInterpretation::SvmLogisticInterpretation] please provide a meaningful number of folds for cross validation");
if (!m_svmCIsUnconstrained) //mtq: important: we additionally need to deal with kernel feasibility indicators! important!
m_features|=IS_CONSTRAINED_FEATURE;
m_features|=HAS_VALUE;
if (mep_kernel->hasFirstParameterDerivative())
m_features|=HAS_FIRST_DERIVATIVE;
m_folds = folds;
}
/// \brief From INameable: return the class name.
std::string name() const
{ return "SvmLogisticInterpretation"; }
//! checks whether the search point provided is feasible
//! \param input the point to test for feasibility
bool isFeasible(const SearchPointType &input) const {
SHARK_ASSERT(input.size() == m_nhp);
//throw SHARKEXCEPTION("[SvmLogisticInterpretation::isFeasible] Please first clarify how the kernel parameter feasibility should be dealt with. Afterwards, please write a test for this method. Thanks.");
if (input(0) <= 0.0 && !m_svmCIsUnconstrained) {
return false;
}
return true;
}
std::size_t numberOfVariables()const{
return m_nhp;
}
//! train a number of SVMs in a cross-validation setting using the hyperparameters passed to this method.
//! the output scores from all validations sets are then concatenated. together with the true labels, these
//! scores can then be used to fit a sigmoid such that it becomes as good as possible a model for the
//! class membership probabilities given the SVM output scores. This method returns the negative likelihood
//! of the best fitting sigmoid, given a set of SVM hyperparameters.
//! \param parameters the SVM hyperparameters to use for all C-SVMs
double eval(SearchPointType const ¶meters) const {
SHARK_CHECK(m_nhp == parameters.size(), "[SvmLogisticInterpretation::eval] wrong number of parameters");
// initialize, copy parameters
double C_reg = (m_svmCIsUnconstrained ? std::exp(parameters(m_nkp)) : parameters(m_nkp)); //set up regularization parameter
mep_kernel->setParameterVector(subrange(parameters, 0, m_nkp)); //set up kernel parameters
// these two will be filled in order corresp. to all CV validation partitions stacked
// behind one another, and then used to create datasets with
std::vector< unsigned int > tmp_helper_labels(m_numSamples);
std::vector< RealVector > tmp_helper_preds(m_numSamples);
unsigned int next_label = 0; //helper index counter to monitor the next position to be filled in the above vectors
// for each fold, train an svm and get predictions on the validation data
for (std::size_t i=0; i<m_numFolds; i++) {
// get current train/validation partitions as well as corresponding labels
ClassificationDataset cur_train_data = m_folds.training(i);
ClassificationDataset cur_valid_data = m_folds.validation(i);
std::size_t cur_vsize = cur_valid_data.numberOfElements();
Data< unsigned int > cur_vlabels = cur_valid_data.labels(); //validation labels of this fold
Data< RealVector > cur_vscores; //will hold SVM output scores for current validation partition
// init SVM
KernelClassifier<InputType> svm;
CSvmTrainer<InputType, double> csvm_trainer(mep_kernel, C_reg, true, m_svmCIsUnconstrained); //the trainer
csvm_trainer.sparsify() = false;
if (mep_svmStoppingCondition != NULL) {
csvm_trainer.stoppingCondition() = *mep_svmStoppingCondition;
} else {
csvm_trainer.stoppingCondition().minAccuracy = 1e-3; //mtq: is this necessary? i think it could be set via long chain of default ctors..
csvm_trainer.stoppingCondition().maxIterations = 200 * m_inputDims; //mtq: need good/better heuristics to determine a good value for this
}
// train SVM on current fold
csvm_trainer.train(svm, cur_train_data);
cur_vscores = svm.decisionFunction()(cur_valid_data.inputs()); //will result in a dataset of RealVector as output
// copy the scores and corresponding labels to the dataset-wide storage
for (std::size_t j=0; j<cur_vsize; j++) {
tmp_helper_labels[next_label] = cur_vlabels.element(j);
tmp_helper_preds[next_label] = cur_vscores.element(j);
++next_label;
}
}
Data< unsigned int > all_validation_labels = createDataFromRange(tmp_helper_labels);
Data< RealVector > all_validation_predictions = createDataFromRange(tmp_helper_preds);
// now we got it all: the predictions across the validation folds, plus the correct corresponding
// labels. so we go ahead and fit a sigmoid to be as good as possible a model between the two:
SigmoidModel sigmoid_model(m_sigmoidSlopeIsUnconstrained); //use the unconstrained variant?
SigmoidFitRpropNLL sigmoid_trainer(100); //number of rprop iterations
ClassificationDataset validation_dataset(all_validation_predictions, all_validation_labels);
sigmoid_trainer.train(sigmoid_model, validation_dataset);
// we're basically done. now only get the final cost value of the best fit, and return it:
Data< RealVector > sigmoid_predictions = sigmoid_model(all_validation_predictions);
double error = 0;
for (std::size_t i=0; i<m_numSamples; i++) {
double p = sigmoid_predictions.element(i)(0);
if (all_validation_labels.element(i) == 1){ //positive class
error -= std::log(p);
}
else{ //negative class
error -= boost::math::log1p(-p);
}
}
return error/m_numSamples;
}
//! the derivative of the error() function above w.r.t. the parameters.
//! \param parameters the SVM hyperparameters to use for all C-SVMs
//! \param derivative will store the computed derivative w.r.t. the current hyperparameters
// mtq: should this also follow the first-call-error()-then-call-deriv() paradigm?
double evalDerivative(SearchPointType const ¶meters, FirstOrderDerivative &derivative) const {
SHARK_CHECK(m_nhp == parameters.size(), "[SvmLogisticInterpretation::evalDerivative] wrong number of parameters");
// initialize, copy parameters
double C_reg = (m_svmCIsUnconstrained ? std::exp(parameters(m_nkp)) : parameters(m_nkp)); //set up regularization parameter
mep_kernel->setParameterVector(subrange(parameters, 0, m_nkp)); //set up kernel parameters
// these two will be filled in order corresp. to all CV validation partitions stacked
// behind one another, and then used to create datasets with
std::vector< unsigned int > tmp_helper_labels(m_numSamples);
std::vector< RealVector > tmp_helper_preds(m_numSamples);
unsigned int next_label = 0; //helper index counter to monitor the next position to be filled in the above vectors
// init variables especially for derivative
RealMatrix all_validation_predict_derivs(m_numSamples, m_nhp); //will hold derivatives of all output scores w.r.t. all hyperparameters
RealVector der; //temporary helper for derivative calls
// for each fold, train an svm and get predictions on the validation data
for (std::size_t i=0; i<m_numFolds; i++) {
// get current train/validation partitions as well as corresponding labels
ClassificationDataset cur_train_data = m_folds.training(i);
ClassificationDataset cur_valid_data = m_folds.validation(i);
std::size_t cur_vsize = cur_valid_data.numberOfElements();
Data< unsigned int > cur_vlabels = cur_valid_data.labels(); //validation labels of this fold
Data< RealVector > cur_vinputs = cur_valid_data.inputs(); //validation inputs of this fold
Data< RealVector > cur_vscores; //will hold SVM output scores for current validation partition
// init SVM
KernelClassifier<InputType> svm; //the SVM
CSvmTrainer<InputType, double> csvm_trainer(mep_kernel, C_reg, true, m_svmCIsUnconstrained); //the trainer
csvm_trainer.sparsify() = false;
if (mep_svmStoppingCondition != NULL) {
csvm_trainer.stoppingCondition() = *mep_svmStoppingCondition;
} else {
csvm_trainer.stoppingCondition().maxIterations = 200 * m_inputDims; //mtq: need good/better heuristics to determine a good value for this
}
// train SVM on current fold
csvm_trainer.train(svm, cur_train_data);
CSvmDerivative<InputType> svm_deriv(&svm, &csvm_trainer);
cur_vscores = svm.decisionFunction()(cur_valid_data.inputs()); //will result in a dataset of RealVector as output
// copy the scores and corresponding labels to the dataset-wide storage
for (std::size_t j=0; j<cur_vsize; j++) {
// copy label and prediction score
tmp_helper_labels[next_label] = cur_vlabels.element(j);
tmp_helper_preds[next_label] = cur_vscores.element(j);
// get and store the derivative of the score w.r.t. the hyperparameters
svm_deriv.modelCSvmParameterDerivative(cur_vinputs.element(j), der);
noalias(row(all_validation_predict_derivs, next_label)) = der; //fast assignment of the derivative to the correct matrix row
++next_label;
}
}
Data< unsigned int > all_validation_labels = createDataFromRange(tmp_helper_labels);
Data< RealVector > all_validation_predictions = createDataFromRange(tmp_helper_preds);
// now we got it all: the predictions across the validation folds, plus the correct corresponding
// labels. so we go ahead and fit a sigmoid to be as good as possible a model between the two:
SigmoidModel sigmoid_model(m_sigmoidSlopeIsUnconstrained); //use the unconstrained variant?
SigmoidFitRpropNLL sigmoid_trainer(100); //number of rprop iterations
ClassificationDataset validation_dataset(all_validation_predictions, all_validation_labels);
sigmoid_trainer.train(sigmoid_model, validation_dataset);
// we're basically done. now only get the final cost value of the best fit, and return it:
Data< RealVector > sigmoid_predictions = sigmoid_model(all_validation_predictions);
// finally compute the derivative of the sigmoid model predictions:
// (we're here a bit un-shark-ish in that we do some of the derivative calculations by hand where they
// would also and more consistently be offered by their respective classes. one reason we're doing it
// like this might be the missing batch processing for the evalDerivatives)
derivative.resize(m_nhp);
derivative.clear();
double ss = (m_sigmoidSlopeIsUnconstrained ? std::exp(sigmoid_model.parameterVector()(0)) : sigmoid_model.parameterVector()(0));
double error = 0;
for (std::size_t i=0; i<m_numSamples; i++) {
double p = sigmoid_predictions.element(i)(0);
// compute derivative of the negative log likelihood
double dL_dsp; //derivative of likelihood wrt sigmoid predictions
if (all_validation_labels.element(i) == 1){ //positive class
error -= std::log(p);
dL_dsp = -1.0/p;
}
else{ //negative class
error -= boost::math::log1p(-p);
dL_dsp = 1.0/(1.0-p);
}
// compute derivative of the sigmoid
// derivative of sigmoid predictions wrt svm predictions
double dsp_dsvmp = ss * p * (1.0-p); //severe sign confusion potential: p(1-p) is deriv. w.r.t. t in 1/(1+e**(-t))!
for (std::size_t j=0; j<m_nhp; j++) {
derivative(j) += dL_dsp * dsp_dsvmp * all_validation_predict_derivs(i,j);
}
}
derivative /= m_numSamples;
return error / m_numSamples;
}
};
}
#endif
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