bool Receiver::operator() (const Tractography::Streamline<>& in) { auto display_func = [&](){ return printf ("%8" PRIu64 " read, %8" PRIu64 " written", total_count, count); }; if (number && (count == number)) return false; ++total_count; if (in.empty()) { writer (in); progress.update (display_func); return true; } if (in[0].valid()) { if (skip) { --skip; progress.update (display_func); return true; } writer (in); } else { // Explicitly handle case where the streamline has been cropped into multiple components // Worker class separates track segments using invalid points as delimiters Tractography::Streamline<> temp; temp.index = in.index; temp.weight = in.weight; for (Tractography::Streamline<>::const_iterator p = in.begin(); p != in.end(); ++p) { if (p->valid()) { temp.push_back (*p); } else if (temp.size()) { writer (temp); temp.clear(); } } } ++count; progress.update (display_func); return (!(number && (count == number))); }
bool Worker::operator() (const Tractography::Streamline<>& in, Tractography::Streamline<>& out) const { out.clear(); out.index = in.index; out.weight = in.weight; if (!thresholds (in)) { // Want to test thresholds before wasting time on upsampling; but if -inverse is set, // still need to apply both the upsampler and downsampler before writing to output if (inverse) { std::vector< Point<float> > tck (in); upsampler (tck); downsampler (tck); tck.swap (out); } return true; } // Upsample track before mapping to ROIs std::vector< Point<float> > tck (in); upsampler (tck); // Assign to ROIs if (properties.include.size() || properties.exclude.size()) { include_visited.assign (properties.include.size(), false); for (std::vector< Point<float> >::const_iterator p = tck.begin(); p != tck.end(); ++p) { properties.include.contains (*p, include_visited); if (properties.exclude.contains (*p)) { if (inverse) { downsampler (tck); tck.swap (out); } return true; } } // Make sure all of the include regions were visited for (std::vector<bool>::const_iterator i = include_visited.begin(); i != include_visited.end(); ++i) { if (!*i) { if (inverse) { downsampler (tck); tck.swap (out); } return true; } } } if (properties.mask.size()) { // Split tck into separate tracks based on the mask std::vector< std::vector< Point<float> > > cropped_tracks; std::vector< Point<float> > temp; for (std::vector< Point<float> >::const_iterator p = tck.begin(); p != tck.end(); ++p) { const bool contains = properties.mask.contains (*p); if (contains == inverse) { if (temp.size() >= 2) cropped_tracks.push_back (temp); temp.clear(); } else { temp.push_back (*p); } } if (temp.size() >= 2) cropped_tracks.push_back (temp); if (cropped_tracks.empty()) return true; // Apply downsampler independently to each for (std::vector< std::vector< Point<float> > >::iterator i = cropped_tracks.begin(); i != cropped_tracks.end(); ++i) downsampler (*i); if (cropped_tracks.size() == 1) { cropped_tracks[0].swap (out); return true; } // Stitch back together in preparation for sending down queue as a single track out.push_back (Point<float>()); for (std::vector< std::vector< Point<float> > >::const_iterator i = cropped_tracks.begin(); i != cropped_tracks.end(); ++i) { for (std::vector< Point<float> >::const_iterator p = i->begin(); p != i->end(); ++p) out.push_back (*p); out.push_back (Point<float>()); } out.push_back (Point<float>()); return true; } else { if (!inverse) { downsampler (tck); tck.swap (out); } return true; } }