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MethodPyAdaBoost.cxx
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1// @(#)root/tmva/pymva $Id$
2// Authors: Omar Zapata, Lorenzo Moneta, Sergei Gleyzer 2015
3
4/**********************************************************************************
5 * Project: TMVA - a Root-integrated toolkit for multivariate data analysis *
6 * Package: TMVA *
7 * Class : MethodPyAdaBoost *
8 * Web : http://oproject.org *
9 * *
10 * Description: *
11 * AdaBoost Classifier from Scikit learn *
12 * *
13 * *
14 * Redistribution and use in source and binary forms, with or without *
15 * modification, are permitted according to the terms listed in LICENSE *
16 * (http://tmva.sourceforge.net/LICENSE) *
17 * *
18 **********************************************************************************/
19
20#include <Python.h> // Needs to be included first to avoid redefinition of _POSIX_C_SOURCE
22
23#define NPY_NO_DEPRECATED_API NPY_1_7_API_VERSION
24#include <numpy/arrayobject.h>
25
26#include "TMVA/Config.h"
27#include "TMVA/Configurable.h"
29#include "TMVA/DataSet.h"
30#include "TMVA/Event.h"
31#include "TMVA/IMethod.h"
32#include "TMVA/MsgLogger.h"
33#include "TMVA/PDF.h"
34#include "TMVA/Ranking.h"
35#include "TMVA/Tools.h"
36#include "TMVA/Types.h"
37#include "TMVA/Timer.h"
39#include "TMVA/Results.h"
40
41#include "TMatrix.h"
42
43using namespace TMVA;
44
45namespace TMVA {
46namespace Internal {
47class PyGILRAII {
48 PyGILState_STATE m_GILState;
49
50public:
51 PyGILRAII() : m_GILState(PyGILState_Ensure()) {}
52 ~PyGILRAII() { PyGILState_Release(m_GILState); }
53};
54} // namespace Internal
55} // namespace TMVA
56
57REGISTER_METHOD(PyAdaBoost)
58
60
61//_______________________________________________________________________
63 const TString &methodTitle,
64 DataSetInfo &dsi,
65 const TString &theOption) :
66 PyMethodBase(jobName, Types::kPyAdaBoost, methodTitle, dsi, theOption),
67 fBaseEstimator("None"),
68 fNestimators(50),
69 fLearningRate(1.0),
70 fAlgorithm("SAMME.R"),
71 fRandomState("None")
72{
73}
74
75//_______________________________________________________________________
77 const TString &theWeightFile) :
78 PyMethodBase(Types::kPyAdaBoost, theData, theWeightFile),
79 fBaseEstimator("None"),
80 fNestimators(50),
81 fLearningRate(1.0),
82 fAlgorithm("SAMME.R"),
83 fRandomState("None")
84{
85}
86
87//_______________________________________________________________________
89{
90}
91
92//_______________________________________________________________________
94{
95 if (type == Types::kClassification && numberClasses == 2) return kTRUE;
96 if (type == Types::kMulticlass && numberClasses >= 2) return kTRUE;
97 return kFALSE;
98}
99
100//_______________________________________________________________________
102{
104
105 DeclareOptionRef(fBaseEstimator, "BaseEstimator", "object, optional (default=DecisionTreeClassifier)\
106 The base estimator from which the boosted ensemble is built.\
107 Support for sample weighting is required, as well as proper `classes_`\
108 and `n_classes_` attributes.");
109
110 DeclareOptionRef(fNestimators, "NEstimators", "integer, optional (default=50)\
111 The maximum number of estimators at which boosting is terminated.\
112 In case of perfect fit, the learning procedure is stopped early.");
113
114 DeclareOptionRef(fLearningRate, "LearningRate", "float, optional (default=1.)\
115 Learning rate shrinks the contribution of each classifier by\
116 ``learning_rate``. There is a trade-off between ``learning_rate`` and\
117 ``n_estimators``.");
118
119 DeclareOptionRef(fAlgorithm, "Algorithm", "{'SAMME', 'SAMME.R'}, optional (default='SAMME.R')\
120 If 'SAMME.R' then use the SAMME.R real boosting algorithm.\
121 ``base_estimator`` must support calculation of class probabilities.\
122 If 'SAMME' then use the SAMME discrete boosting algorithm.\
123 The SAMME.R algorithm typically converges faster than SAMME,\
124 achieving a lower test error with fewer boosting iterations.");
125
126 DeclareOptionRef(fRandomState, "RandomState", "int, RandomState instance or None, optional (default=None)\
127 If int, random_state is the seed used by the random number generator;\
128 If RandomState instance, random_state is the random number generator;\
129 If None, the random number generator is the RandomState instance used\
130 by `np.random`.");
131
132 DeclareOptionRef(fFilenameClassifier, "FilenameClassifier",
133 "Store trained classifier in this file");
134}
135
136//_______________________________________________________________________
137// Check options and load them to local python namespace
139{
141 if (!pBaseEstimator) {
142 Log() << kFATAL << Form("BaseEstimator = %s ... that does not work!", fBaseEstimator.Data())
143 << " The options are Object or None." << Endl;
144 }
145 PyDict_SetItemString(fLocalNS, "baseEstimator", pBaseEstimator);
146
147 if (fNestimators <= 0) {
148 Log() << kFATAL << "NEstimators <=0 ... that does not work!" << Endl;
149 }
151 PyDict_SetItemString(fLocalNS, "nEstimators", pNestimators);
152
153 if (fLearningRate <= 0) {
154 Log() << kFATAL << "LearningRate <=0 ... that does not work!" << Endl;
155 }
157 PyDict_SetItemString(fLocalNS, "learningRate", pLearningRate);
158
159 if (fAlgorithm != "SAMME" && fAlgorithm != "SAMME.R") {
160 Log() << kFATAL << Form("Algorithm = %s ... that does not work!", fAlgorithm.Data())
161 << " The options are SAMME of SAMME.R." << Endl;
162 }
163 pAlgorithm = Eval(Form("'%s'", fAlgorithm.Data()));
164 PyDict_SetItemString(fLocalNS, "algorithm", pAlgorithm);
165
167 if (!pRandomState) {
168 Log() << kFATAL << Form(" RandomState = %s... that does not work !! ", fRandomState.Data())
169 << "If int, random_state is the seed used by the random number generator;"
170 << "If RandomState instance, random_state is the random number generator;"
171 << "If None, the random number generator is the RandomState instance used by `np.random`." << Endl;
172 }
173 PyDict_SetItemString(fLocalNS, "randomState", pRandomState);
174
175 // If no filename is given, set default
177 fFilenameClassifier = GetWeightFileDir() + "/PyAdaBoostModel_" + GetName() + ".PyData";
178 }
179}
180
181//_______________________________________________________________________
183{
184 TMVA::Internal::PyGILRAII raii;
185 _import_array(); //require to use numpy arrays
186
187 // Check options and load them to local python namespace
189
190 // Import module for ada boost classifier
191 PyRunString("import sklearn.ensemble");
192
193 // Get data properties
196}
197
198//_______________________________________________________________________
200{
201 // Load training data (data, classes, weights) to python arrays
202 int fNrowsTraining = Data()->GetNTrainingEvents(); //every row is an event, a class type and a weight
203 npy_intp dimsData[2];
204 dimsData[0] = fNrowsTraining;
205 dimsData[1] = fNvars;
206 PyArrayObject * fTrainData = (PyArrayObject *)PyArray_SimpleNew(2, dimsData, NPY_FLOAT);
207 PyDict_SetItemString(fLocalNS, "trainData", (PyObject*)fTrainData);
208 float *TrainData = (float *)(PyArray_DATA(fTrainData));
209
210 npy_intp dimsClasses = (npy_intp) fNrowsTraining;
211 PyArrayObject * fTrainDataClasses = (PyArrayObject *)PyArray_SimpleNew(1, &dimsClasses, NPY_FLOAT);
212 PyDict_SetItemString(fLocalNS, "trainDataClasses", (PyObject*)fTrainDataClasses);
213 float *TrainDataClasses = (float *)(PyArray_DATA(fTrainDataClasses));
214
215 PyArrayObject * fTrainDataWeights = (PyArrayObject *)PyArray_SimpleNew(1, &dimsClasses, NPY_FLOAT);
216 PyDict_SetItemString(fLocalNS, "trainDataWeights", (PyObject*)fTrainDataWeights);
217 float *TrainDataWeights = (float *)(PyArray_DATA(fTrainDataWeights));
218
219 for (int i = 0; i < fNrowsTraining; i++) {
220 // Fill training data matrix
221 const TMVA::Event *e = Data()->GetTrainingEvent(i);
222 for (UInt_t j = 0; j < fNvars; j++) {
223 TrainData[j + i * fNvars] = e->GetValue(j);
224 }
225
226 // Fill target classes
227 TrainDataClasses[i] = e->GetClass();
228
229 // Get event weight
230 TrainDataWeights[i] = e->GetWeight();
231 }
232
233 // Create classifier object
234 PyRunString("classifier = sklearn.ensemble.AdaBoostClassifier(base_estimator=baseEstimator, n_estimators=nEstimators, learning_rate=learningRate, algorithm=algorithm, random_state=randomState)",
235 "Failed to setup classifier");
236
237 // Fit classifier
238 // NOTE: We dump the output to a variable so that the call does not pollute stdout
239 PyRunString("dump = classifier.fit(trainData, trainDataClasses, trainDataWeights)", "Failed to train classifier");
240
241 // Store classifier
242 fClassifier = PyDict_GetItemString(fLocalNS, "classifier");
243 if(fClassifier == 0) {
244 Log() << kFATAL << "Can't create classifier object from AdaBoostClassifier" << Endl;
245 Log() << Endl;
246 }
247
248 if (IsModelPersistence()) {
249 Log() << Endl;
250 Log() << gTools().Color("bold") << "Saving state file: " << gTools().Color("reset") << fFilenameClassifier << Endl;
251 Log() << Endl;
253 }
254}
255
256//_______________________________________________________________________
258{
260}
261
262//_______________________________________________________________________
263std::vector<Double_t> MethodPyAdaBoost::GetMvaValues(Long64_t firstEvt, Long64_t lastEvt, Bool_t logProgress)
264{
265 // Load model if not already done
266 if (fClassifier == 0) ReadModelFromFile();
267
268 // Determine number of events
269 Long64_t nEvents = Data()->GetNEvents();
270 if (firstEvt > lastEvt || lastEvt > nEvents) lastEvt = nEvents;
271 if (firstEvt < 0) firstEvt = 0;
272 nEvents = lastEvt-firstEvt;
273
274 // use timer
275 Timer timer( nEvents, GetName(), kTRUE );
276
277 if (logProgress)
278 Log() << kHEADER << Form("[%s] : ",DataInfo().GetName())
279 << "Evaluation of " << GetMethodName() << " on "
280 << (Data()->GetCurrentType() == Types::kTraining ? "training" : "testing")
281 << " sample (" << nEvents << " events)" << Endl;
282
283 // Get data
284 npy_intp dims[2];
285 dims[0] = nEvents;
286 dims[1] = fNvars;
287 PyArrayObject *pEvent= (PyArrayObject *)PyArray_SimpleNew(2, dims, NPY_FLOAT);
288 float *pValue = (float *)(PyArray_DATA(pEvent));
289
290 for (Int_t ievt=0; ievt<nEvents; ievt++) {
291 Data()->SetCurrentEvent(ievt);
292 const TMVA::Event *e = Data()->GetEvent();
293 for (UInt_t i = 0; i < fNvars; i++) {
294 pValue[ievt * fNvars + i] = e->GetValue(i);
295 }
296 }
297
298 // Get prediction from classifier
299 PyArrayObject *result = (PyArrayObject *)PyObject_CallMethod(fClassifier, const_cast<char *>("predict_proba"), const_cast<char *>("(O)"), pEvent);
300 double *proba = (double *)(PyArray_DATA(result));
301
302 // Return signal probabilities
303 if(Long64_t(mvaValues.size()) != nEvents) mvaValues.resize(nEvents);
304 for (int i = 0; i < nEvents; ++i) {
306 }
307
308 Py_DECREF(pEvent);
309 Py_DECREF(result);
310
311 if (logProgress) {
312 Log() << kINFO
313 << "Elapsed time for evaluation of " << nEvents << " events: "
314 << timer.GetElapsedTime() << " " << Endl;
315 }
316
317 return mvaValues;
318}
319
320//_______________________________________________________________________
322{
323 // cannot determine error
324 NoErrorCalc(errLower, errUpper);
325
326 // Load model if not already done
327 if (fClassifier == 0) ReadModelFromFile();
328
329 // Get current event and load to python array
330 const TMVA::Event *e = Data()->GetEvent();
331 npy_intp dims[2];
332 dims[0] = 1;
333 dims[1] = fNvars;
334 PyArrayObject *pEvent= (PyArrayObject *)PyArray_SimpleNew(2, dims, NPY_FLOAT);
335 float *pValue = (float *)(PyArray_DATA(pEvent));
336 for (UInt_t i = 0; i < fNvars; i++) pValue[i] = e->GetValue(i);
337
338 // Get prediction from classifier
339 PyArrayObject *result = (PyArrayObject *)PyObject_CallMethod(fClassifier, const_cast<char *>("predict_proba"), const_cast<char *>("(O)"), pEvent);
340 double *proba = (double *)(PyArray_DATA(result));
341
342 // Return MVA value
343 Double_t mvaValue;
344 mvaValue = proba[TMVA::Types::kSignal]; // getting signal probability
345
346 Py_DECREF(result);
347 Py_DECREF(pEvent);
348
349 return mvaValue;
350}
351
352//_______________________________________________________________________
354{
355 // Load model if not already done
356 if (fClassifier == 0) ReadModelFromFile();
357
358 // Get current event and load to python array
359 const TMVA::Event *e = Data()->GetEvent();
360 npy_intp dims[2];
361 dims[0] = 1;
362 dims[1] = fNvars;
363 PyArrayObject *pEvent= (PyArrayObject *)PyArray_SimpleNew(2, dims, NPY_FLOAT);
364 float *pValue = (float *)(PyArray_DATA(pEvent));
365 for (UInt_t i = 0; i < fNvars; i++) pValue[i] = e->GetValue(i);
366
367 // Get prediction from classifier
368 PyArrayObject *result = (PyArrayObject *)PyObject_CallMethod(fClassifier, const_cast<char *>("predict_proba"), const_cast<char *>("(O)"), pEvent);
369 double *proba = (double *)(PyArray_DATA(result));
370
371 // Return MVA values
372 if(UInt_t(classValues.size()) != fNoutputs) classValues.resize(fNoutputs);
373 for(UInt_t i = 0; i < fNoutputs; i++) classValues[i] = proba[i];
374
375 return classValues;
376}
377
378//_______________________________________________________________________
380{
381 if (!PyIsInitialized()) {
382 PyInitialize();
383 }
384
385 Log() << Endl;
386 Log() << gTools().Color("bold") << "Loading state file: " << gTools().Color("reset") << fFilenameClassifier << Endl;
387 Log() << Endl;
388
389 // Load classifier from file
391 if(err != 0)
392 {
393 Log() << kFATAL << Form("Failed to load classifier from file (error code: %i): %s", err, fFilenameClassifier.Data()) << Endl;
394 }
395
396 // Book classifier object in python dict
397 PyDict_SetItemString(fLocalNS, "classifier", fClassifier);
398
399 // Load data properties
400 // NOTE: This has to be repeated here for the reader application
403}
404
405//_______________________________________________________________________
407{
408 // Get feature importance from classifier as an array with length equal
409 // number of variables, higher value signals a higher importance
410 PyArrayObject* pRanking = (PyArrayObject*) PyObject_GetAttrString(fClassifier, "feature_importances_");
411 // The python object is null if the base estimator does not support
412 // variable ranking. Then, return NULL, which disables ranking.
413 if(pRanking == 0) return NULL;
414
415 // Fill ranking object and return it
416 fRanking = new Ranking(GetName(), "Variable Importance");
417 Double_t* rankingData = (Double_t*) PyArray_DATA(pRanking);
418 for(UInt_t iVar=0; iVar<fNvars; iVar++){
419 fRanking->AddRank(Rank(GetInputLabel(iVar), rankingData[iVar]));
420 }
421
422 Py_DECREF(pRanking);
423
424 return fRanking;
425}
426
427//_______________________________________________________________________
429{
430 // typical length of text line:
431 // "|--------------------------------------------------------------|"
432 Log() << "An AdaBoost classifier is a meta-estimator that begins by fitting" << Endl;
433 Log() << "a classifier on the original dataset and then fits additional copies" << Endl;
434 Log() << "of the classifier on the same dataset but where the weights of incorrectly" << Endl;
435 Log() << "classified instances are adjusted such that subsequent classifiers focus" << Endl;
436 Log() << "more on difficult cases." << Endl;
437 Log() << Endl;
438 Log() << "Check out the scikit-learn documentation for more information." << Endl;
439}
#define REGISTER_METHOD(CLASS)
for example
_object PyObject
#define e(i)
Definition RSha256.hxx:103
unsigned int UInt_t
Definition RtypesCore.h:46
const Bool_t kFALSE
Definition RtypesCore.h:92
long long Long64_t
Definition RtypesCore.h:73
const Bool_t kTRUE
Definition RtypesCore.h:91
#define ClassImp(name)
Definition Rtypes.h:364
int type
Definition TGX11.cxx:121
char * Form(const char *fmt,...)
OptionBase * DeclareOptionRef(T &ref, const TString &name, const TString &desc="")
MsgLogger & Log() const
Class that contains all the data information.
Definition DataSetInfo.h:62
UInt_t GetNClasses() const
const Event * GetEvent() const
Definition DataSet.cxx:202
Types::ETreeType GetCurrentType() const
Definition DataSet.h:194
Long64_t GetNEvents(Types::ETreeType type=Types::kMaxTreeType) const
Definition DataSet.h:206
Long64_t GetNTrainingEvents() const
Definition DataSet.h:68
void SetCurrentEvent(Long64_t ievt) const
Definition DataSet.h:88
const Event * GetTrainingEvent(Long64_t ievt) const
Definition DataSet.h:74
Float_t GetValue(UInt_t ivar) const
return value of i'th variable
Definition Event.cxx:236
virtual void DeclareCompatibilityOptions()
options that are used ONLY for the READER to ensure backward compatibility they are hence without any...
const char * GetName() const
Definition MethodBase.h:333
Bool_t IsModelPersistence() const
Definition MethodBase.h:382
const TString & GetWeightFileDir() const
Definition MethodBase.h:490
const TString & GetMethodName() const
Definition MethodBase.h:330
DataSetInfo & DataInfo() const
Definition MethodBase.h:409
virtual void TestClassification()
initialization
UInt_t GetNVariables() const
Definition MethodBase.h:344
void NoErrorCalc(Double_t *const err, Double_t *const errUpper)
const TString & GetInputLabel(Int_t i) const
Definition MethodBase.h:349
Ranking * fRanking
Definition MethodBase.h:585
DataSet * Data() const
Definition MethodBase.h:408
std::vector< Double_t > GetMvaValues(Long64_t firstEvt=0, Long64_t lastEvt=-1, Bool_t logProgress=false)
get all the MVA values for the events of the current Data type
Double_t GetMvaValue(Double_t *errLower=0, Double_t *errUpper=0)
std::vector< Double_t > mvaValues
const Ranking * CreateRanking()
std::vector< Float_t > classValues
MethodPyAdaBoost(const TString &jobName, const TString &methodTitle, DataSetInfo &theData, const TString &theOption="")
Bool_t HasAnalysisType(Types::EAnalysisType type, UInt_t numberClasses, UInt_t numberTargets)
virtual void TestClassification()
initialization
std::vector< Float_t > & GetMulticlassValues()
static int PyIsInitialized()
Check Python interpreter initialization status.
PyObject * Eval(TString code)
Evaluate Python code.
static void PyInitialize()
Initialize Python interpreter.
static void Serialize(TString file, PyObject *classifier)
Serialize Python object.
static Int_t UnSerialize(TString file, PyObject **obj)
Unserialize Python object.
PyObject * fClassifier
void PyRunString(TString code, TString errorMessage="Failed to run python code", int start=Py_single_input)
Execute Python code from string.
Ranking for variables in method (implementation)
Definition Ranking.h:48
virtual void AddRank(const Rank &rank)
Add a new rank take ownership of it.
Definition Ranking.cxx:86
Timing information for training and evaluation of MVA methods.
Definition Timer.h:58
TString GetElapsedTime(Bool_t Scientific=kTRUE)
returns pretty string with elapsed time
Definition Timer.cxx:146
const TString & Color(const TString &)
human readable color strings
Definition Tools.cxx:840
Singleton class for Global types used by TMVA.
Definition Types.h:73
@ kMulticlass
Definition Types.h:131
@ kClassification
Definition Types.h:129
@ kTraining
Definition Types.h:145
Basic string class.
Definition TString.h:136
const char * Data() const
Definition TString.h:369
Bool_t IsNull() const
Definition TString.h:407
create variable transformations
Tools & gTools()
MsgLogger & Endl(MsgLogger &ml)
Definition MsgLogger.h:158