StereoCameraModel.cpp
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1 /*
2 Copyright (c) 2010-2016, Mathieu Labbe - IntRoLab - Universite de Sherbrooke
3 All rights reserved.
4 
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27 
29 #include <rtabmap/core/Version.h>
32 #include <rtabmap/utilite/UFile.h>
34 #include <opencv2/imgproc/imgproc.hpp>
35 
36 #if CV_MAJOR_VERSION > 2 or (CV_MAJOR_VERSION == 2 and (CV_MINOR_VERSION >4 or (CV_MINOR_VERSION == 4 and CV_SUBMINOR_VERSION >=10)))
38 #endif
39 
40 namespace rtabmap {
41 
43  const std::string & name,
44  const cv::Size & imageSize1,
45  const cv::Mat & K1, const cv::Mat & D1, const cv::Mat & R1, const cv::Mat & P1,
46  const cv::Size & imageSize2,
47  const cv::Mat & K2, const cv::Mat & D2, const cv::Mat & R2, const cv::Mat & P2,
48  const cv::Mat & R, const cv::Mat & T, const cv::Mat & E, const cv::Mat & F,
49  const Transform & localTransform) :
50  leftSuffix_("left"),
51  rightSuffix_("right"),
52  left_(name+"_"+leftSuffix_, imageSize1, K1, D1, R1, P1, localTransform),
53  right_(name+"_"+rightSuffix_, imageSize2, K2, D2, R2, P2, localTransform),
54  name_(name),
55  R_(R),
56  T_(T),
57  E_(E),
58  F_(F)
59 {
60  UASSERT(R_.empty() || (R_.rows == 3 && R_.cols == 3 && R_.type() == CV_64FC1));
61  UASSERT(T_.empty() || (T_.rows == 3 && T_.cols == 1 && T_.type() == CV_64FC1));
62  UASSERT(E_.empty() || (E_.rows == 3 && E_.cols == 3 && E_.type() == CV_64FC1));
63  UASSERT(F_.empty() || (F_.rows == 3 && F_.cols == 3 && F_.type() == CV_64FC1));
64 }
65 
67  const std::string & name,
68  const CameraModel & leftCameraModel,
69  const CameraModel & rightCameraModel,
70  const cv::Mat & R,
71  const cv::Mat & T,
72  const cv::Mat & E,
73  const cv::Mat & F) :
74  leftSuffix_("left"),
75  rightSuffix_("right"),
76  left_(leftCameraModel),
77  right_(rightCameraModel),
78  name_(name),
79  R_(R),
80  T_(T),
81  E_(E),
82  F_(F)
83 {
86  UASSERT(R_.empty() || (R_.rows == 3 && R_.cols == 3 && R_.type() == CV_64FC1));
87  UASSERT(T_.empty() || (T_.rows == 3 && T_.cols == 1 && T_.type() == CV_64FC1));
88  UASSERT(E_.empty() || (E_.rows == 3 && E_.cols == 3 && E_.type() == CV_64FC1));
89  UASSERT(F_.empty() || (F_.rows == 3 && F_.cols == 3 && F_.type() == CV_64FC1));
90 
91  if(!R_.empty() && !T_.empty())
92  {
93  UASSERT(leftCameraModel.isValidForRectification() && rightCameraModel.isValidForRectification());
94 
96  {
98  }
99  }
100 }
101 
103  const std::string & name,
104  const CameraModel & leftCameraModel,
105  const CameraModel & rightCameraModel,
106  const Transform & extrinsics) :
107  leftSuffix_("left"),
108  rightSuffix_("right"),
109  left_(leftCameraModel),
110  right_(rightCameraModel),
111  name_(name)
112 {
115 
116  if(!extrinsics.isNull())
117  {
118  UASSERT(leftCameraModel.isValidForRectification() && rightCameraModel.isValidForRectification());
119 
120  extrinsics.rotationMatrix().convertTo(R_, CV_64FC1);
121  extrinsics.translationMatrix().convertTo(T_, CV_64FC1);
122 
124  {
126  }
127  }
128 }
129 
131  double fx,
132  double fy,
133  double cx,
134  double cy,
135  double baseline,
136  const Transform & localTransform,
137  const cv::Size & imageSize) :
138  leftSuffix_("left"),
139  rightSuffix_("right"),
140  left_(fx, fy, cx, cy, localTransform, 0, imageSize),
141  right_(fx, fy, cx, cy, localTransform, baseline*-fx, imageSize)
142 {
143 }
144 
145 //minimal to be saved
147  const std::string & name,
148  double fx,
149  double fy,
150  double cx,
151  double cy,
152  double baseline,
153  const Transform & localTransform,
154  const cv::Size & imageSize) :
155  leftSuffix_("left"),
156  rightSuffix_("right"),
157  left_(name+"_"+getLeftSuffix(), fx, fy, cx, cy, localTransform, 0, imageSize),
158  right_(name+"_"+getRightSuffix(), fx, fy, cx, cy, localTransform, baseline*-fx, imageSize),
159  name_(name)
160 {
161 }
162 
163 void StereoCameraModel::setName(const std::string & name, const std::string & leftSuffix, const std::string & rightSuffix)
164 {
165  name_=name;
166  leftSuffix_ = leftSuffix;
167  rightSuffix_ = rightSuffix;
170 }
171 
173 {
174  cv::Mat R1,R2,P1,P2,Q;
175  #if CV_MAJOR_VERSION > 2 or (CV_MAJOR_VERSION == 2 and (CV_MINOR_VERSION >4 or (CV_MINOR_VERSION == 4 and CV_SUBMINOR_VERSION >=10)))
176  bool fishEye = left_.D_raw().cols == 6;
177  // calibrate extrinsic
178  if(fishEye)
179  {
180  cv::Vec4d D_left(left_.D_raw().at<double>(0,0), left_.D_raw().at<double>(0,1), left_.D_raw().at<double>(0,4), left_.D_raw().at<double>(0,5));
181  cv::Vec4d D_right(right_.D_raw().at<double>(0,0), right_.D_raw().at<double>(0,1), right_.D_raw().at<double>(0,4), right_.D_raw().at<double>(0,5));
182 
184  left_.K_raw(), D_left,
185  right_.K_raw(), D_right,
186  left_.imageSize(), R_, T_, R1, R2, P1, P2, Q,
187  cv::CALIB_ZERO_DISPARITY, 0, left_.imageSize());
188 
189  // Re-zoom to original focal distance
190  if(P1.at<double>(0,0) < 0)
191  {
192  P1.at<double>(0,0) *= -1;
193  P1.at<double>(1,1) *= -1;
194  }
195  if(P2.at<double>(0,0) < 0)
196  {
197  P2.at<double>(0,0) *= -1;
198  P2.at<double>(1,1) *= -1;
199  }
200  if(P2.at<double>(0,3) > 0)
201  {
202  P2.at<double>(0,3) *= -1;
203  }
204  P2.at<double>(0,3) = P2.at<double>(0,3) * left_.K_raw().at<double>(0,0) / P2.at<double>(0,0);
205  P1.at<double>(0,0) = P1.at<double>(1,1) = left_.K_raw().at<double>(0,0);
206  P2.at<double>(0,0) = P2.at<double>(1,1) = left_.K_raw().at<double>(0,0);
207  }
208  else
209 #endif
210  {
211 
212  cv::stereoRectify(
213  left_.K_raw(), left_.D_raw(),
214  right_.K_raw(), right_.D_raw(),
215  left_.imageSize(), R_, T_, R1, R2, P1, P2, Q,
216  cv::CALIB_ZERO_DISPARITY, 0, left_.imageSize());
217  }
218 
221 }
222 
223 bool StereoCameraModel::load(const std::string & directory, const std::string & cameraName, bool ignoreStereoTransform)
224 {
225  name_ = cameraName;
226  bool leftLoaded = left_.load(directory, cameraName+"_"+getLeftSuffix());
227  bool rightLoaded = right_.load(directory, cameraName+"_"+getRightSuffix());
228  if(leftLoaded && rightLoaded)
229  {
230  if(ignoreStereoTransform)
231  {
232  return true;
233  }
234  //load rotation, translation
235  R_ = cv::Mat();
236  T_ = cv::Mat();
237  E_ = cv::Mat();
238  F_ = cv::Mat();
239 
240  std::string filePath = directory+"/"+cameraName+"_pose.yaml";
241  if(UFile::exists(filePath))
242  {
243  UINFO("Reading stereo calibration file \"%s\"", filePath.c_str());
244  cv::FileStorage fs(filePath, cv::FileStorage::READ);
245 
246  cv::FileNode n;
247 
248  n = fs["camera_name"];
249  if(n.type() != cv::FileNode::NONE)
250  {
251  name_ = (int)n;
252  }
253  else
254  {
255  UWARN("Missing \"camera_name\" field in \"%s\"", filePath.c_str());
256  }
257 
258  // import from ROS calibration format
259  n = fs["rotation_matrix"];
260  if(n.type() != cv::FileNode::NONE)
261  {
262  int rows = (int)n["rows"];
263  int cols = (int)n["cols"];
264  std::vector<double> data;
265  n["data"] >> data;
266  UASSERT(rows*cols == (int)data.size());
267  UASSERT(rows == 3 && cols == 3);
268  R_ = cv::Mat(rows, cols, CV_64FC1, data.data()).clone();
269  }
270  else
271  {
272  UWARN("Missing \"rotation_matrix\" field in \"%s\"", filePath.c_str());
273  }
274 
275  n = fs["translation_matrix"];
276  if(n.type() != cv::FileNode::NONE)
277  {
278  int rows = (int)n["rows"];
279  int cols = (int)n["cols"];
280  std::vector<double> data;
281  n["data"] >> data;
282  UASSERT(rows*cols == (int)data.size());
283  UASSERT(rows == 3 && cols == 1);
284  T_ = cv::Mat(rows, cols, CV_64FC1, data.data()).clone();
285  }
286  else
287  {
288  UWARN("Missing \"translation_matrix\" field in \"%s\"", filePath.c_str());
289  }
290 
291  n = fs["essential_matrix"];
292  if(n.type() != cv::FileNode::NONE)
293  {
294  int rows = (int)n["rows"];
295  int cols = (int)n["cols"];
296  std::vector<double> data;
297  n["data"] >> data;
298  UASSERT(rows*cols == (int)data.size());
299  UASSERT(rows == 3 && cols == 3);
300  E_ = cv::Mat(rows, cols, CV_64FC1, data.data()).clone();
301  }
302  else
303  {
304  UWARN("Missing \"essential_matrix\" field in \"%s\"", filePath.c_str());
305  }
306 
307  n = fs["fundamental_matrix"];
308  if(n.type() != cv::FileNode::NONE)
309  {
310  int rows = (int)n["rows"];
311  int cols = (int)n["cols"];
312  std::vector<double> data;
313  n["data"] >> data;
314  UASSERT(rows*cols == (int)data.size());
315  UASSERT(rows == 3 && cols == 3);
316  F_ = cv::Mat(rows, cols, CV_64FC1, data.data()).clone();
317  }
318  else
319  {
320  UWARN("Missing \"fundamental_matrix\" field in \"%s\"", filePath.c_str());
321  }
322 
323  fs.release();
324 
325  return true;
326  }
327  else
328  {
329  UWARN("Could not load stereo calibration file \"%s\".", filePath.c_str());
330  }
331  }
332  return false;
333 }
334 bool StereoCameraModel::save(const std::string & directory, bool ignoreStereoTransform) const
335 {
336  if(left_.save(directory) && right_.save(directory))
337  {
338  if(ignoreStereoTransform)
339  {
340  return true;
341  }
342  return saveStereoTransform(directory);
343  }
344  return false;
345 }
346 
347 bool StereoCameraModel::saveStereoTransform(const std::string & directory) const
348 {
349  std::string filePath = directory+"/"+name_+"_pose.yaml";
350  if(!filePath.empty() && (!R_.empty() && !T_.empty()))
351  {
352  UINFO("Saving stereo calibration to file \"%s\"", filePath.c_str());
353  cv::FileStorage fs(filePath, cv::FileStorage::WRITE);
354 
355  // export in ROS calibration format
356 
357  if(!name_.empty())
358  {
359  fs << "camera_name" << name_;
360  }
361 
362  if(!R_.empty())
363  {
364  fs << "rotation_matrix" << "{";
365  fs << "rows" << R_.rows;
366  fs << "cols" << R_.cols;
367  fs << "data" << std::vector<double>((double*)R_.data, ((double*)R_.data)+(R_.rows*R_.cols));
368  fs << "}";
369  }
370 
371  if(!T_.empty())
372  {
373  fs << "translation_matrix" << "{";
374  fs << "rows" << T_.rows;
375  fs << "cols" << T_.cols;
376  fs << "data" << std::vector<double>((double*)T_.data, ((double*)T_.data)+(T_.rows*T_.cols));
377  fs << "}";
378  }
379 
380  if(!E_.empty())
381  {
382  fs << "essential_matrix" << "{";
383  fs << "rows" << E_.rows;
384  fs << "cols" << E_.cols;
385  fs << "data" << std::vector<double>((double*)E_.data, ((double*)E_.data)+(E_.rows*E_.cols));
386  fs << "}";
387  }
388 
389  if(!F_.empty())
390  {
391  fs << "fundamental_matrix" << "{";
392  fs << "rows" << F_.rows;
393  fs << "cols" << F_.cols;
394  fs << "data" << std::vector<double>((double*)F_.data, ((double*)F_.data)+(F_.rows*F_.cols));
395  fs << "}";
396  }
397 
398  fs.release();
399 
400  return true;
401  }
402  else
403  {
404  UERROR("Failed saving stereo extrinsics (they are null):");
405  std::cout << "R= " << R_ << std::endl;
406  std::cout << "T= " << T_ << std::endl;
407  std::cout << "E= " << T_ << std::endl;
408  std::cout << "F= " << F_ << std::endl;
409  }
410  return false;
411 }
412 
413 std::vector<unsigned char> StereoCameraModel::serialize() const
414 {
415  std::vector<unsigned char> leftData = left_.serialize();
416  std::vector<unsigned char> rightData = right_.serialize();
417 
418  const int headerSize = 10;
419  int header[headerSize] = {
420  RTABMAP_VERSION_MAJOR, RTABMAP_VERSION_MINOR, RTABMAP_VERSION_PATCH, // 0,1,2
421  1, //stereo // 3
422  (int)R_.total(), (int)T_.total(), (int)E_.total(), (int)F_.total(), // 4,5,6,7
423  (int)leftData.size(), (int)rightData.size()}; // 8,9
424  UDEBUG("Header: %d %d %d %d %d %d %d %d %d %d", header[0],header[1],header[2],header[3],header[4],header[5],header[6],header[7],header[8],header[9]);
425  std::vector<unsigned char> data(
426  sizeof(int)*headerSize +
427  sizeof(double)*(R_.total()+T_.total()+E_.total()+F_.total()) +
428  leftData.size() + rightData.size());
429  memcpy(data.data(), header, sizeof(int)*headerSize);
430  int index = sizeof(int)*headerSize;
431  if(!R_.empty())
432  {
433  memcpy(data.data()+index, R_.data, sizeof(double)*(R_.total()));
434  index+=sizeof(double)*(R_.total());
435  }
436  if(!T_.empty())
437  {
438  memcpy(data.data()+index, T_.data, sizeof(double)*(T_.total()));
439  index+=sizeof(double)*(T_.total());
440  }
441  if(!E_.empty())
442  {
443  memcpy(data.data()+index, E_.data, sizeof(double)*(E_.total()));
444  index+=sizeof(double)*(E_.total());
445  }
446  if(!F_.empty())
447  {
448  memcpy(data.data()+index, F_.data, sizeof(double)*(F_.total()));
449  index+=sizeof(double)*(F_.total());
450  }
451  if(leftData.size())
452  {
453  memcpy(data.data()+index, leftData.data(), leftData.size());
454  index+=leftData.size();
455  }
456  if(rightData.size())
457  {
458  memcpy(data.data()+index, rightData.data(), rightData.size());
459  index+=rightData.size();
460  }
461  return data;
462 }
463 
464 unsigned int StereoCameraModel::deserialize(const std::vector<unsigned char>& data)
465 {
466  return deserialize(data.data(), data.size());
467 }
468 unsigned int StereoCameraModel::deserialize(const unsigned char * data, unsigned int dataSize)
469 {
470  *this = StereoCameraModel();
471  int headerSize = 10;
472  if(dataSize >= sizeof(int)*headerSize)
473  {
474  int iR = 4;
475  int iT = 5;
476  int iE = 6;
477  int iF = 7;
478  int iLeft = 8;
479  int iRight = 9;
480  const int * header = (const int *)data;
481  UDEBUG("Header: %d %d %d %d %d %d %d %d %d %d", header[0],header[1],header[2],header[3],header[4],header[5],header[6],header[7],header[8],header[9]);
482  int type = header[3];
483  if(type==1)
484  {
485  unsigned int requiredDataSize = sizeof(int)*headerSize +
486  sizeof(double)*(header[iR]+header[iT]+header[iE]+header[iF]) +
487  header[iLeft] + header[iRight];
488  UASSERT_MSG(dataSize >= requiredDataSize,
489  uFormat("dataSize=%d != required=%d (header: version %d.%d.%d type=%d R=%d T=%d E=%d F=%d Left=%d Right=%d)",
490  dataSize,
491  requiredDataSize,
492  header[0], header[1], header[2], header[3],
493  header[iR], header[iT], header[iE],header[iF], header[iLeft], header[iRight]).c_str());
494 
495  unsigned int index = sizeof(int)*headerSize;
496 
497  if(header[iR] != 0)
498  {
499  UASSERT(header[iR] == 9);
500  R_ = cv::Mat(3, 3, CV_64FC1, (void*)(data+index)).clone();
501  index+=sizeof(double)*(R_.total());
502  }
503 
504  if(header[iT] != 0)
505  {
506  UASSERT(header[iT] == 3);
507  T_ = cv::Mat(3, 1, CV_64FC1, (void*)(data+index)).clone();
508  index+=sizeof(double)*(T_.total());
509  }
510 
511  if(header[iE] != 0)
512  {
513  UASSERT(header[iE] == 9);
514  E_ = cv::Mat(3, 3, CV_64FC1, (void*)(data+index)).clone();
515  index+=sizeof(double)*(E_.total());
516  }
517 
518  if(header[iF] != 0)
519  {
520  UASSERT(header[iF] == 9);
521  F_ = cv::Mat(3, 3, CV_64FC1, (void*)(data+index)).clone();
522  index+=sizeof(double)*(F_.total());
523  }
524 
525  if(header[iLeft] != 0)
526  {
527  index += left_.deserialize((data+index), header[iLeft]);
528  }
529 
530  if(header[iRight] != 0)
531  {
532  index += right_.deserialize((data+index), header[iRight]);
533  }
534 
535  UASSERT(index <= dataSize);
536 
537  return index;
538  }
539  else
540  {
541  UERROR("Serialized calibration is not stereo (type=%d), use the appropriate class matching the type to deserialize.", type);
542  }
543  }
544  UERROR("Wrong serialized calibration data format detected (size in bytes=%d)! Cannot deserialize the data.", (int)dataSize);
545  return 0;
546 }
547 
548 void StereoCameraModel::scale(double scale)
549 {
550  left_ = left_.scaled(scale);
552 }
553 
554 void StereoCameraModel::roi(const cv::Rect & roi)
555 {
556  left_ = left_.roi(roi);
557  right_ = right_.roi(roi);
558 }
559 
560 float StereoCameraModel::computeDepth(float disparity) const
561 {
562  //depth = baseline * f / (disparity + cx1-cx0);
563  UASSERT(this->isValidForProjection());
564  if(disparity == 0.0f)
565  {
566  return 0.0f;
567  }
568  return baseline() * left().fx() / (disparity + right().cx() - left().cx());
569 }
570 
571 float StereoCameraModel::computeDisparity(float depth) const
572 {
573  // disparity = (baseline * fx / depth) - (cx1-cx0);
574  UASSERT(this->isValidForProjection());
575  if(depth == 0.0f)
576  {
577  return 0.0f;
578  }
579  return baseline() * left().fx() / depth - right().cx() + left().cx();
580 }
581 
582 float StereoCameraModel::computeDisparity(unsigned short depth) const
583 {
584  // disparity = (baseline * fx / depth) - (cx1-cx0);
585  UASSERT(this->isValidForProjection());
586  if(depth == 0)
587  {
588  return 0.0f;
589  }
590  return baseline() * left().fx() / (float(depth)/1000.0f) - right().cx() + left().cx();
591 }
592 
594 {
595  if(!R_.empty() && !T_.empty())
596  {
597  return Transform(
598  R_.at<double>(0,0), R_.at<double>(0,1), R_.at<double>(0,2), T_.at<double>(0),
599  R_.at<double>(1,0), R_.at<double>(1,1), R_.at<double>(1,2), T_.at<double>(1),
600  R_.at<double>(2,0), R_.at<double>(2,1), R_.at<double>(2,2), T_.at<double>(2));
601  }
602  return Transform();
603 }
604 
605 std::ostream& operator<<(std::ostream& os, const StereoCameraModel& model)
606 {
607  os << "Left Camera " << model.left() << std::endl
608  << "Right Camera " << model.right() << std::endl
609  << "Stereo Extrinsics:" << std::endl
610  << "R= " << model.R() << std::endl
611  << "T= " << model.T() << std::endl
612  << "E= " << model.E() << std::endl
613  << "F= "<< model.F() << std::endl
614  << "baseline= " << model.baseline() << std::endl;
615  return os;
616 }
617 
618 } /* namespace rtabmap */
int
int
rtabmap::CameraModel::fx
double fx() const
Definition: CameraModel.h:102
rtabmap::CameraModel::cx
double cx() const
Definition: CameraModel.h:104
rtabmap::CameraModel::load
bool load(const std::string &filePath)
Definition: CameraModel.cpp:215
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int imageWidth() const
Definition: CameraModel.h:120
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cv::Mat translationMatrix() const
Definition: Transform.cpp:253
stereoRectifyFisheye.h
UINFO
#define UINFO(...)
name
rtabmap::StereoCameraModel
Definition: StereoCameraModel.h:35
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cv::Mat D_raw() const
Definition: CameraModel.h:109
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const double cy
rtabmap::StereoCameraModel::getLeftSuffix
const std::string & getLeftSuffix() const
Definition: StereoCameraModel.h:125
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void roi(const cv::Rect &roi)
Definition: StereoCameraModel.cpp:554
rtabmap::CameraModel::setName
void setName(const std::string &name)
Definition: CameraModel.h:99
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Definition: StereoCameraModel.h:138
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Definition: StereoCameraModel.cpp:223
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Definition: StereoCameraModel.h:136
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Definition: StereoCameraModel.h:38
R
R


rtabmap
Author(s): Mathieu Labbe
autogenerated on Thu Jul 25 2024 02:50:22