Formatting

2014-05-25 10:49:59 -04:00 · 2014-05-25 10:49:59 -04:00 · 7aa0bd332a
parent 87c386d77f
commit 7aa0bd332a
1 changed files with 144 additions and 128 deletions
--- a/matlab.h
+++ b/matlab.h
@ -32,134 +32,150 @@
 namespace gtsam {
-  namespace utilities {
+namespace utilities {
    /// Extract all Point2 values into a single matrix [x y]
    Matrix extractPoint2(const Values& values) {
      size_t j=0;
      Values::ConstFiltered<Point2> points = values.filter<Point2>();
      Matrix result(points.size(),2);
      BOOST_FOREACH(const Values::ConstFiltered<Point2>::KeyValuePair& key_value, points)
        result.row(j++) = key_value.value.vector();
      return result;
    }
    /// Extract all Point3 values into a single matrix [x y z]
    Matrix extractPoint3(const Values& values) {
      Values::ConstFiltered<Point3> points = values.filter<Point3>();
      Matrix result(points.size(),3);
      size_t j=0;
      BOOST_FOREACH(const Values::ConstFiltered<Point3>::KeyValuePair& key_value, points)
        result.row(j++) = key_value.value.vector();
      return result;
    }
    /// Extract all Pose2 values into a single matrix [x y theta]
    Matrix extractPose2(const Values& values) {
      Values::ConstFiltered<Pose2> poses = values.filter<Pose2>();
      Matrix result(poses.size(),3);
      size_t j=0;
      BOOST_FOREACH(const Values::ConstFiltered<Pose2>::KeyValuePair& key_value, poses)
        result.row(j++) << key_value.value.x(), key_value.value.y(), key_value.value.theta();
      return result;
    }
    /// Extract all Pose3 values
    Values allPose3s(const Values& values) {
      return values.filter<Pose3>();
    }
    /// Extract all Pose3 values into a single matrix [r11 r12 r13 r21 r22 r23 r31 r32 r33 x y z]
    Matrix extractPose3(const Values& values) {
      Values::ConstFiltered<Pose3> poses = values.filter<Pose3>();
      Matrix result(poses.size(),12);
      size_t j=0;
      BOOST_FOREACH(const Values::ConstFiltered<Pose3>::KeyValuePair& key_value, poses) {
        result.row(j).segment(0, 3) << key_value.value.rotation().matrix().row(0);
        result.row(j).segment(3, 3) << key_value.value.rotation().matrix().row(1);
        result.row(j).segment(6, 3) << key_value.value.rotation().matrix().row(2);
        result.row(j).tail(3) = key_value.value.translation().vector();
        j++;
      }
      return result;
    }
    /// Perturb all Point2 values using normally distributed noise
    void perturbPoint2(Values& values, double sigma, int32_t seed = 42u) {
      noiseModel::Isotropic::shared_ptr model = noiseModel::Isotropic::Sigma(2,sigma);
      Sampler sampler(model, seed);
      BOOST_FOREACH(const Values::ConstFiltered<Point2>::KeyValuePair& key_value, values.filter<Point2>()) {
        values.update(key_value.key, key_value.value.retract(sampler.sample()));
      }
    }
    /// Perturb all Pose2 values using normally distributed noise
    void perturbPose2(Values& values, double sigmaT, double sigmaR, int32_t seed = 42u) {
      noiseModel::Diagonal::shared_ptr model = noiseModel::Diagonal::Sigmas(
          Vector3(sigmaT, sigmaT, sigmaR));
      Sampler sampler(model, seed);
      BOOST_FOREACH(const Values::ConstFiltered<Pose2>::KeyValuePair& key_value, values.filter<Pose2>()) {
        values.update(key_value.key, key_value.value.retract(sampler.sample()));
      }
    }
    /// Perturb all Point3 values using normally distributed noise
    void perturbPoint3(Values& values, double sigma, int32_t seed = 42u) {
      noiseModel::Isotropic::shared_ptr model = noiseModel::Isotropic::Sigma(3,sigma);
      Sampler sampler(model, seed);
      BOOST_FOREACH(const Values::ConstFiltered<Point3>::KeyValuePair& key_value, values.filter<Point3>()) {
        values.update(key_value.key, key_value.value.retract(sampler.sample()));
      }
    }
    /// Insert a number of initial point values by backprojecting
    void insertBackprojections(Values& values, const SimpleCamera& camera, const Vector& J, const Matrix& Z, double depth) {
      if (Z.rows() != 2) throw std::invalid_argument("insertBackProjections: Z must be 2*K");
      if (Z.cols() != J.size()) throw std::invalid_argument("insertBackProjections: J and Z must have same number of entries");
      for(int k=0;k<Z.cols();k++) {
        Point2 p(Z(0,k),Z(1,k));
        Point3 P = camera.backproject(p, depth);
        values.insert(J(k), P);
      }
    }
    /// Insert multiple projection factors for a single pose key
    void insertProjectionFactors(NonlinearFactorGraph& graph, Key i, const Vector& J, const Matrix& Z,
        const SharedNoiseModel& model, const Cal3_S2::shared_ptr K, const Pose3& body_P_sensor = Pose3()) {
      if (Z.rows() != 2) throw std::invalid_argument("addMeasurements: Z must be 2*K");
      if (Z.cols() != J.size()) throw std::invalid_argument(
            "addMeasurements: J and Z must have same number of entries");
      for (int k = 0; k < Z.cols(); k++) {
        graph.push_back(
            boost::make_shared<GenericProjectionFactor<Pose3, Point3> >
            (Point2(Z(0, k), Z(1, k)), model, i, Key(J(k)), K, body_P_sensor));
      }
    }
    /// Calculate the errors of all projection factors in a graph
    Matrix reprojectionErrors(const NonlinearFactorGraph& graph, const Values& values) {
      // first count
      size_t K = 0, k=0;
      BOOST_FOREACH(const NonlinearFactor::shared_ptr& f, graph)
        if (boost::dynamic_pointer_cast<const GenericProjectionFactor<Pose3, Point3> >(f)) ++K;
      // now fill
      Matrix errors(2,K);
      BOOST_FOREACH(const NonlinearFactor::shared_ptr& f, graph) {
        boost::shared_ptr<const GenericProjectionFactor<Pose3, Point3> > p = boost::dynamic_pointer_cast<const GenericProjectionFactor<Pose3, Point3> >(f);
        if (p) errors.col(k++) = p->unwhitenedError(values);
      }
      return errors;
    }
    // Create a Keyset from indices
    FastSet<Key> createKeySet(string s, const Vector& I) {
      FastSet<Key> set;
      char c = s[0];
      for(int i=0;i<I.size();i++)
        set.insert(symbol(c,I[i]));
      return set;
    }
  }
 /// Extract all Point2 values into a single matrix [x y]
 Matrix extractPoint2(const Values& values) {
  size_t j = 0;
  Values::ConstFiltered<Point2> points = values.filter<Point2>();
  Matrix result(points.size(), 2);
  BOOST_FOREACH(const Values::ConstFiltered<Point2>::KeyValuePair& key_value, points)
    result.row(j++) = key_value.value.vector();
  return result;
 }
 /// Extract all Point3 values into a single matrix [x y z]
 Matrix extractPoint3(const Values& values) {
  Values::ConstFiltered<Point3> points = values.filter<Point3>();
  Matrix result(points.size(), 3);
  size_t j = 0;
  BOOST_FOREACH(const Values::ConstFiltered<Point3>::KeyValuePair& key_value, points)
    result.row(j++) = key_value.value.vector();
  return result;
 }
 /// Extract all Pose2 values into a single matrix [x y theta]
 Matrix extractPose2(const Values& values) {
  Values::ConstFiltered<Pose2> poses = values.filter<Pose2>();
  Matrix result(poses.size(), 3);
  size_t j = 0;
  BOOST_FOREACH(const Values::ConstFiltered<Pose2>::KeyValuePair& key_value, poses)
    result.row(j++) << key_value.value.x(), key_value.value.y(), key_value.value.theta();
  return result;
 }
 /// Extract all Pose3 values
 Values allPose3s(const Values& values) {
  return values.filter<Pose3>();
 }
 /// Extract all Pose3 values into a single matrix [r11 r12 r13 r21 r22 r23 r31 r32 r33 x y z]
 Matrix extractPose3(const Values& values) {
  Values::ConstFiltered<Pose3> poses = values.filter<Pose3>();
  Matrix result(poses.size(), 12);
  size_t j = 0;
  BOOST_FOREACH(const Values::ConstFiltered<Pose3>::KeyValuePair& key_value, poses) {
    result.row(j).segment(0, 3) << key_value.value.rotation().matrix().row(0);
    result.row(j).segment(3, 3) << key_value.value.rotation().matrix().row(1);
    result.row(j).segment(6, 3) << key_value.value.rotation().matrix().row(2);
    result.row(j).tail(3) = key_value.value.translation().vector();
    j++;
  }
  return result;
 }
 /// Perturb all Point2 values using normally distributed noise
 void perturbPoint2(Values& values, double sigma, int32_t seed = 42u) {
  noiseModel::Isotropic::shared_ptr model = noiseModel::Isotropic::Sigma(2,
      sigma);
  Sampler sampler(model, seed);
  BOOST_FOREACH(const Values::ConstFiltered<Point2>::KeyValuePair& key_value, values.filter<Point2>()) {
    values.update(key_value.key, key_value.value.retract(sampler.sample()));
  }
 }
 /// Perturb all Pose2 values using normally distributed noise
 void perturbPose2(Values& values, double sigmaT, double sigmaR, int32_t seed =
    42u) {
  noiseModel::Diagonal::shared_ptr model = noiseModel::Diagonal::Sigmas(
      Vector3(sigmaT, sigmaT, sigmaR));
  Sampler sampler(model, seed);
  BOOST_FOREACH(const Values::ConstFiltered<Pose2>::KeyValuePair& key_value, values.filter<Pose2>()) {
    values.update(key_value.key, key_value.value.retract(sampler.sample()));
  }
 }
 /// Perturb all Point3 values using normally distributed noise
 void perturbPoint3(Values& values, double sigma, int32_t seed = 42u) {
  noiseModel::Isotropic::shared_ptr model = noiseModel::Isotropic::Sigma(3,
      sigma);
  Sampler sampler(model, seed);
  BOOST_FOREACH(const Values::ConstFiltered<Point3>::KeyValuePair& key_value, values.filter<Point3>()) {
    values.update(key_value.key, key_value.value.retract(sampler.sample()));
  }
 }
 /// Insert a number of initial point values by backprojecting
 void insertBackprojections(Values& values, const SimpleCamera& camera,
    const Vector& J, const Matrix& Z, double depth) {
  if (Z.rows() != 2)
    throw std::invalid_argument("insertBackProjections: Z must be 2*K");
  if (Z.cols() != J.size())
    throw std::invalid_argument(
        "insertBackProjections: J and Z must have same number of entries");
  for (int k = 0; k < Z.cols(); k++) {
    Point2 p(Z(0, k), Z(1, k));
    Point3 P = camera.backproject(p, depth);
    values.insert(J(k), P);
  }
 }
 /// Insert multiple projection factors for a single pose key
 void insertProjectionFactors(NonlinearFactorGraph& graph, Key i,
    const Vector& J, const Matrix& Z, const SharedNoiseModel& model,
    const Cal3_S2::shared_ptr K, const Pose3& body_P_sensor = Pose3()) {
  if (Z.rows() != 2)
    throw std::invalid_argument("addMeasurements: Z must be 2*K");
  if (Z.cols() != J.size())
    throw std::invalid_argument(
        "addMeasurements: J and Z must have same number of entries");
  for (int k = 0; k < Z.cols(); k++) {
    graph.push_back(
        boost::make_shared<GenericProjectionFactor<Pose3, Point3> >(
            Point2(Z(0, k), Z(1, k)), model, i, Key(J(k)), K, body_P_sensor));
  }
 }
 /// Calculate the errors of all projection factors in a graph
 Matrix reprojectionErrors(const NonlinearFactorGraph& graph,
    const Values& values) {
  // first count
  size_t K = 0, k = 0;
  BOOST_FOREACH(const NonlinearFactor::shared_ptr& f, graph)
    if (boost::dynamic_pointer_cast<const GenericProjectionFactor<Pose3, Point3> >(
        f))
      ++K;
  // now fill
  Matrix errors(2, K);
  BOOST_FOREACH(const NonlinearFactor::shared_ptr& f, graph) {
    boost::shared_ptr<const GenericProjectionFactor<Pose3, Point3> > p =
        boost::dynamic_pointer_cast<const GenericProjectionFactor<Pose3, Point3> >(
            f);
    if (p)
      errors.col(k++) = p->unwhitenedError(values);
  }
  return errors;
 }
 // Create a Keyset from indices
 FastSet<Key> createKeySet(string s, const Vector& I) {
  FastSet<Key> set;
  char c = s[0];
  for (int i = 0; i < I.size(); i++)
    set.insert(symbol(c, I[i]));
  return set;
 }
 }
 }