double compute_max_distance(const IMP::algebra::Vector3Ds& coordinates) { double max_dist2 = 0; for (unsigned int i = 0; i < coordinates.size(); i++) { for (unsigned int j = i + 1; j < coordinates.size(); j++) { double dist2 = IMP::algebra::get_squared_distance(coordinates[i], coordinates[j]); if (dist2 > max_dist2) max_dist2 = dist2; } } return sqrt(max_dist2); }
void ProjectionSphere::get_adjacent_rotations_and_axes(const IMP::algebra::Vector3Ds& curr_axes, double angle_thr, IMP::algebra::Rotation3Ds& rotations, IMP::algebra::Vector3Ds& axes) const { // convert angle threshold into euclidean distance double radius = 2*sin(angle_thr/2); double radius2 = radius*radius; for (unsigned int i = 0; i < curr_axes.size(); i++) { IMP::algebra::BoundingBox3D bb(curr_axes[i]); bb += radius; Grid::ExtendedIndex lb = grid_.get_extended_index(bb.get_corner(0)), ub = grid_.get_extended_index(bb.get_corner(1)); for (Grid::IndexIterator it = grid_.indexes_begin(lb, ub); it != grid_.indexes_end(lb, ub); ++it) { for (unsigned int vIndex = 0; vIndex < grid_[*it].size(); vIndex++) { int direction_index = grid_[*it][vIndex]; double dist2 = algebra::get_squared_distance(curr_axes[i], axes_[direction_index]); if (dist2 <= radius2) { rotations.push_back(rotations_[direction_index]); axes.push_back(axes_[direction_index]); } } } } }
void Projection::init(const IMP::algebra::Vector3Ds& points, double max_radius, int axis_size) { // determine the image size needed to store the projection x_min_ = y_min_ = std::numeric_limits<float>::max(); x_max_ = y_max_ = std::numeric_limits<float>::min(); // determine translation to center algebra::Vector3D center(0.0, 0.0, 0.0); for (unsigned int i = 0; i < points.size(); i++) { x_min_ = std::min(x_min_, points[i][0]); y_min_ = std::min(y_min_, points[i][1]); x_max_ = std::max(x_max_, points[i][0]); y_max_ = std::max(y_max_, points[i][1]); center += points[i]; } center /= points.size(); static IMP::em::KernelParameters kp(resolution_); const IMP::em::RadiusDependentKernelParameters& params = kp.get_params(max_radius); double wrap_length = 2 * params.get_kdist() + 1.0; x_min_ = x_min_ - wrap_length - scale_; y_min_ = y_min_ - wrap_length - scale_; x_max_ = x_max_ + wrap_length + scale_; y_max_ = y_max_ + wrap_length + scale_; int width = (int)((x_max_ - x_min_) / scale_ + 2); int height = (int)((y_max_ - y_min_) / scale_ + 2); int size = std::max(width, height); // the determined size should be below axis size if specified if (axis_size > 0 && size <= axis_size) size = axis_size; else { IMP_WARN("wrong size estimate " << size << " vs. estimate " << axis_size << std::endl); } this->resize(boost::extents[size][size]); int i = 0, j = 0; get_index_for_point(center, i, j); t_i_ = size / 2 - i; t_j_ = size / 2 - j; }
int Projector::estimate_image_size(const IMP::algebra::Vector3Ds& points) const { // estimate max image size IMP::algebra::Vector3D centroid = IMP::algebra::get_centroid(points); double max_rad2 = 0; for (unsigned int i = 0; i < points.size(); i++) { double dist2 = IMP::algebra::get_squared_distance(points[i], centroid); if (dist2 > max_rad2) max_rad2 = dist2; } // estimate max image size double max_dist = 2*sqrt(max_rad2); //compute_max_distance(points); static IMP::em::KernelParameters kp(resolution_); double wrap_length = 2 * kp.get_rkdist() + 1.0; int axis_size = (int)((max_dist + 2 * wrap_length + 2 * pixel_size_) / pixel_size_ + 2); return axis_size; }
void Projection::project(const IMP::algebra::Vector3Ds& points, const std::vector<double>& mass) { // get mask const std::vector<MaskCell>& mask = get_sphere_mask(); int i, j; for (unsigned int p_index = 0; p_index < points.size(); p_index++) { // project if (get_index_for_point(points[p_index], i, j)) { for (unsigned int mask_index = 0; mask_index < mask.size(); mask_index++) { int i_shift = mask[mask_index].i; int j_shift = mask[mask_index].j; double density = mask[mask_index].d; (*this)[i + i_shift][j + j_shift] += mass[i] * density; } } } }