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FitData.h
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1// @(#)root/mathcore:$Id: FitData.h 45076 2012-07-16 13:45:18Z mborinsk $
2// Author: M. Borinsky
3
4/**********************************************************************
5 * *
6 * Copyright (c) 2006 LCG ROOT Math Team, CERN/PH-SFT *
7 * *
8 * *
9 **********************************************************************/
10
11// Header file for class DataVector
12
13#ifndef ROOT_Fit_FitData
14#define ROOT_Fit_FitData
15
16/**
17@defgroup FitData Fit Data Classes
18
19Classes for describing the input data for fitting
20
21@ingroup Fit
22*/
23
24
25#include "Fit/DataOptions.h"
26#include "Fit/DataRange.h"
27#include "Math/Types.h"
28
29#include <vector>
30#include <cassert>
31#include <iostream>
32
33
34namespace ROOT {
35
36 namespace Fit {
37
38 //class used for making shared_ptr of data classes managed by the user (i.e. when we don;t want to delete the contained object)
39 template <class T>
40 struct DummyDeleter {
41 // a deleter not deleting the contained object
42 // used to avoid shared_ptr deleting the contained objects if managed externally
43 void operator()(T * /* p */)
44 {
45 //printf("ROOT::Fit::DummyDeleter called - do not delete object %x \n", p);
46 }
47 };
48
49 /**
50 * Base class for all the fit data types:
51 * Stores the coordinates and the DataOptions
52
53 @ingroup FitData
54 */
55
56
57 /**
58 class holding the fit data points. It is template on the type of point,
59 which can be for example a binned or unbinned point.
60 It is basicaly a wrapper on an std::vector
61
62 @ingroup FitData
63
64 */
65
66 class FitData {
67 public:
68
69 /// construct with default option and data range
70 explicit FitData(unsigned int maxpoints = 0, unsigned int dim = 1);
71
72 /// construct passing options and default data range
73 explicit FitData(const DataOptions &opt, unsigned int maxpoints = 0, unsigned int dim = 1);
74
75
76 /// construct passing range and default options
77 explicit FitData(const DataRange &range, unsigned int maxpoints = 0, unsigned int dim = 1);
78
79 /// construct passing options and data range
80 FitData(const DataOptions &opt, const DataRange &range,
81 unsigned int maxpoints = 0, unsigned int dim = 1);
82
83 /// constructor from external data for 1D data
84 FitData(unsigned int n, const double *dataX);
85
86 /// constructor from external data for 2D data
87 FitData(unsigned int n, const double *dataX, const double *dataY);
88
89 /// constructor from external data for 3D data
90 FitData(unsigned int n, const double *dataX, const double *dataY,
91 const double *dataZ);
92
93 /**
94 constructor for multi-dim external data and a range (data are copied inside according to the range)
95 Uses as argument an iterator of a list (or vector) containing the const double * of the data
96 An example could be the std::vector<const double *>::begin
97 */
98 FitData(const DataRange &range, unsigned int maxpoints, const double *dataX);
99
100 /**
101 constructor for multi-dim external data and a range (data are copied inside according to the range)
102 Uses as argument an iterator of a list (or vector) containing the const double * of the data
103 An example could be the std::vector<const double *>::begin
104 */
105 FitData(const DataRange &range, unsigned int maxpoints, const double *dataX, const double *dataY);
106
107 /**
108 constructor for multi-dim external data and a range (data are copied inside according to the range)
109 Uses as argument an iterator of a list (or vector) containing the const double * of the data
110 An example could be the std::vector<const double *>::begin
111 */
112 FitData(const DataRange &range, unsigned int maxpoints, const double *dataX, const double *dataY,
113 const double *dataZ);
114
115 /**
116 constructor for multi-dim external data (data are not copied inside)
117 Uses as argument an iterator of a list (or vector) containing the const double * of the data
118 An example could be the std::vector<const double *>::begin
119 In case of weighted data, the external data must have a dim+1 lists of data
120 The apssed dim refers just to the coordinate size
121 */
122 template<class Iterator>
123 FitData(unsigned int n, unsigned int dim, Iterator dataItr) :
124 fWrapped(true),
125 fMaxPoints(n),
127 fDim(dim),
129 fpTmpCoordVector(nullptr)
130 {
131 assert(fDim >= 1);
132 for (unsigned int i = 0; i < fDim; i++) {
133 fCoordsPtr[i] = *dataItr++;
134 }
135
136 if (fpTmpCoordVector) {
137 delete[] fpTmpCoordVector;
138 fpTmpCoordVector = nullptr;
139 }
140
141 fpTmpCoordVector = new double [fDim];
142 }
143
144 /**
145 constructor for multi-dim external data and a range (data are copied inside according to the range)
146 Uses as argument an iterator of a list (or vector) containing the const double * of the data
147 An example could be the std::vector<const double *>::begin
148 */
149 template<class Iterator>
150 FitData(const DataRange &range, unsigned int maxpoints, unsigned int dim, Iterator dataItr) :
151 fWrapped(false),
152 fRange(range),
153 fMaxPoints(maxpoints),
154 fNPoints(0),
155 fDim(dim),
156 fpTmpCoordVector(nullptr)
157 {
158 assert(fDim >= 1);
160
161 InitFromRange(dataItr);
162 }
163
164 /// dummy virtual destructor
165 virtual ~FitData();
166
167 FitData(const FitData &rhs);
168
169 FitData &operator= (const FitData &rhs);
170
171 void Append(unsigned int newPoints, unsigned int dim = 1);
172
173 protected:
174 /**
175 * initializer routines to set the corresponding pointers right
176 * The vectors must NOT be resized after this initialization
177 * without setting the corresponding pointers in the
178 * same moment ( has to be an atomic operation in case
179 * of multithreading ).
180 */
182 {
183 fCoords.resize(fDim);
184 fCoordsPtr.resize(fDim);
185
186 for (unsigned int i = 0; i < fDim; i++) {
188 fCoordsPtr[i] = fCoords[i].empty() ? nullptr : &fCoords[i].front();
189 }
190
191 if (fpTmpCoordVector) {
192 delete[] fpTmpCoordVector;
193 fpTmpCoordVector = nullptr;
194 }
195
196 fpTmpCoordVector = new double [fDim];
197 }
198
199 template<class Iterator>
200 void InitFromRange(Iterator dataItr)
201 {
202 for (unsigned int i = 0; i < fMaxPoints; i++) {
203 bool isInside = true;
204 Iterator tmpItr = dataItr;
205
206 for (unsigned int j = 0; j < fDim; j++)
207 isInside &= fRange.IsInside((*tmpItr++)[i], j);
208
209 if (isInside) {
210 tmpItr = dataItr;
211
212 for (unsigned int k = 0; k < fDim; k++)
213 fpTmpCoordVector[k] = (*tmpItr++)[i];
214
216 }
217 }
218 }
219
220
221 public:
222
223 /**
224 returns a single coordinate component of a point.
225 This function is threadsafe in contrast to Coords(...)
226 and can easily get vectorized by the compiler in loops
227 running over the ipoint-index.
228 */
229 const double *GetCoordComponent(unsigned int ipoint, unsigned int icoord) const
230 {
231 assert(ipoint < fMaxPoints + VectorPadding(fMaxPoints));
232 assert(icoord < fDim);
233 assert(fCoordsPtr.size() == fDim);
234 assert(fCoordsPtr[icoord]);
235 assert(fCoords.empty() || &fCoords[icoord].front() == fCoordsPtr[icoord]);
236
237 return &fCoordsPtr[icoord][ipoint];
238 }
239
240 /**
241 return a pointer to the coordinates data for the given fit point
242 */
243 // not threadsafe, to be replaced with never constructs!
244 // for example: just return std::array or std::vector, there's
245 // is going to be only minor overhead in c++11.
246 const double *Coords(unsigned int ipoint) const
247 {
248 assert(fpTmpCoordVector);
249 assert(ipoint < fMaxPoints + VectorPadding(fMaxPoints));
250
251 for (unsigned int i = 0; i < fDim; i++) {
252 assert(fCoordsPtr[i]);
253 assert(fCoords.empty() || &fCoords[i].front() == fCoordsPtr[i]);
254
255 fpTmpCoordVector[i] = fCoordsPtr[i][ipoint];
256 }
257
258 return fpTmpCoordVector;
259 }
260
261 /**
262 add one dim data with only coordinate and values
263 */
264 void Add(double x)
265 {
266 assert(!fWrapped);
267 assert(!fCoordsPtr.empty() && fCoordsPtr.size() == 1 && fCoordsPtr[0]);
268 assert(1 == fDim);
269 assert(fNPoints < fMaxPoints);
270
271 fCoords[0][ fNPoints ] = x;
272
273 fNPoints++;
274 }
275
276 /**
277 add multi-dim coordinate data with only value
278 */
279 void Add(const double *x)
280 {
281 assert(!fWrapped);
282 assert(!fCoordsPtr.empty() && fCoordsPtr.size() == fDim);
283 assert(fNPoints < fMaxPoints);
284
285 for (unsigned int i = 0; i < fDim; i++) {
286 fCoords[i][ fNPoints ] = x[i];
287 }
288
289 fNPoints++;
290 }
291
292 /**
293 return number of fit points
294 */
295 unsigned int NPoints() const
296 {
297 return fNPoints;
298 }
299
300 /**
301 return number of fit points
302 */
303 unsigned int Size() const
304 {
305 return fNPoints;
306 }
307
308 /**
309 return coordinate data dimension
310 */
311 unsigned int NDim() const
312 {
313 return fDim;
314 }
315
316 /**
317 access to options
318 */
319 const DataOptions &Opt() const
320 {
321 return fOptions;
322 }
324 {
325 return fOptions;
326 }
327
328 /**
329 access to range
330 */
331 const DataRange &Range() const
332 {
333 return fRange;
334 }
335
336 /**
337 direct access to coord data ptrs
338 */
339 const std::vector< const double * > &GetCoordDataPtrs() const
340 {
341 return fCoordsPtr;
342 }
343
344
345 protected:
346 void UnWrap()
347 {
348 assert(fWrapped);
349 assert(fCoords.empty());
350
351 fCoords.resize(fDim);
352 for (unsigned int i = 0; i < fDim; i++) {
353 assert(fCoordsPtr[i]);
354 unsigned padding = VectorPadding(fNPoints);
355 fCoords[i].resize(fNPoints + padding);
356 std::copy(fCoordsPtr[i], fCoordsPtr[i] + fNPoints + padding, fCoords[i].begin());
357 fCoordsPtr[i] = fCoords[i].empty() ? nullptr : &fCoords[i].front();
358 }
359
360 fWrapped = false;
361 }
362
363#ifdef R__HAS_VECCORE
364 /**
365 * Compute the number that should be added to dataSize in order to have a
366 * multiple of SIMD vector size.
367 */
368 static unsigned VectorPadding(unsigned dataSize)
369 {
370 unsigned padding = 0;
371 unsigned modP = (dataSize) % vecCore::VectorSize<ROOT::Double_v>();
372 if (modP > 0)
373 padding = vecCore::VectorSize<ROOT::Double_v>() - modP;
374 return padding;
375 }
376#else
377 /**
378 * If VecCore is not defined, there is no vectorization available and the SIMD vector
379 * size will always be one. Then, as every number is a multiple of SIMD vector size, the
380 * padding will always be zero.
381 */
382 static constexpr unsigned VectorPadding(const unsigned) { return 0; }
383#endif
384
385 protected:
387
388 private:
389
392
393 protected:
394 unsigned int fMaxPoints;
395 unsigned int fNPoints;
396 unsigned int fDim;
397
398 private:
399 /**
400 * This vector stores the vectorizable data:
401 * The inner vectors contain the coordinates data
402 * fCoords[0] is the vector for the x-coords
403 * fCoords[1] is the vector for the y-coords
404 * etc.
405 * The vector of pointers stores the pointers
406 * to the first elements of the corresponding
407 * elements
408 *
409 * If fWrapped is true, fCoords is empty.
410 * the data can only be accessed by using
411 * fCoordsPtr.
412 */
413 std::vector< std::vector< double > > fCoords;
414 std::vector< const double * > fCoordsPtr;
415
416 double *fpTmpCoordVector; // non threadsafe stuff!
417
418 };
419
420 } // end namespace Fit
421
422} // end namespace ROOT
423
424
425
426#endif /* ROOT_Fit_Data */
class describing the range in the coordinates it supports multiple range in a coordinate.
Definition: DataRange.h:34
bool IsInside(double x, unsigned int icoord=0) const
check if a point is inside the range for the given coordinate
Definition: DataRange.cxx:146
Base class for all the fit data types: Stores the coordinates and the DataOptions.
Definition: FitData.h:66
double * fpTmpCoordVector
Definition: FitData.h:416
DataOptions & Opt()
Definition: FitData.h:323
FitData(unsigned int n, unsigned int dim, Iterator dataItr)
constructor for multi-dim external data (data are not copied inside) Uses as argument an iterator of ...
Definition: FitData.h:123
unsigned int Size() const
return number of fit points
Definition: FitData.h:303
FitData(unsigned int maxpoints=0, unsigned int dim=1)
construct with default option and data range
Definition: FitData.cxx:20
void InitCoordsVector()
initializer routines to set the corresponding pointers right The vectors must NOT be resized after th...
Definition: FitData.h:181
DataRange fRange
Definition: FitData.h:391
void Add(double x)
add one dim data with only coordinate and values
Definition: FitData.h:264
void Append(unsigned int newPoints, unsigned int dim=1)
Definition: FitData.cxx:248
std::vector< std::vector< double > > fCoords
This vector stores the vectorizable data: The inner vectors contain the coordinates data fCoords[0] i...
Definition: FitData.h:413
unsigned int fMaxPoints
Definition: FitData.h:394
std::vector< const double * > fCoordsPtr
Definition: FitData.h:414
static constexpr unsigned VectorPadding(const unsigned)
If VecCore is not defined, there is no vectorization available and the SIMD vector size will always b...
Definition: FitData.h:382
const double * GetCoordComponent(unsigned int ipoint, unsigned int icoord) const
returns a single coordinate component of a point.
Definition: FitData.h:229
void InitFromRange(Iterator dataItr)
Definition: FitData.h:200
DataOptions fOptions
Definition: FitData.h:390
unsigned int NPoints() const
return number of fit points
Definition: FitData.h:295
unsigned int fDim
Definition: FitData.h:396
void Add(const double *x)
add multi-dim coordinate data with only value
Definition: FitData.h:279
const std::vector< const double * > & GetCoordDataPtrs() const
direct access to coord data ptrs
Definition: FitData.h:339
FitData(const DataRange &range, unsigned int maxpoints, unsigned int dim, Iterator dataItr)
constructor for multi-dim external data and a range (data are copied inside according to the range) U...
Definition: FitData.h:150
unsigned int NDim() const
return coordinate data dimension
Definition: FitData.h:311
FitData & operator=(const FitData &rhs)
Definition: FitData.cxx:216
unsigned int fNPoints
Definition: FitData.h:395
const DataOptions & Opt() const
access to options
Definition: FitData.h:319
const double * Coords(unsigned int ipoint) const
return a pointer to the coordinates data for the given fit point
Definition: FitData.h:246
const DataRange & Range() const
access to range
Definition: FitData.h:331
virtual ~FitData()
dummy virtual destructor
Definition: FitData.cxx:201
Double_t x[n]
Definition: legend1.C:17
const Int_t n
Definition: legend1.C:16
TFitResultPtr Fit(FitObject *h1, TF1 *f1, Foption_t &option, const ROOT::Math::MinimizerOptions &moption, const char *goption, ROOT::Fit::DataRange &range)
Definition: HFitImpl.cxx:134
double T(double x)
Definition: ChebyshevPol.h:34
Namespace for new ROOT classes and functions.
Definition: StringConv.hxx:21
DataOptions : simple structure holding the options on how the data are filled.
Definition: DataOptions.h:28
void operator()(T *)
Definition: FitData.h:43