void CreateGraph::way(const osmium::Way& way)
{
  const char* highway = way.get_value_by_key("highway");
  if (!highway || !strcmp(highway, "footway"))
  {
    return;
  }

  vertex_type u = -1;
  for (const auto& node_ref : way.nodes())
  {
    node_id_map_type::iterator pos;
    bool inserted;
    boost::tie(pos, inserted) = node_id_map.emplace(node_ref.positive_ref(), vertex_type());

    if (inserted)
    {
      double x = osmium::geom::detail::lon_to_x(node_ref.lon());
      double y = osmium::geom::detail::lat_to_y(node_ref.lat());
      Location loc(x, y);

      pos->second = boost::add_vertex(vertex_property(loc), graph);
    }

    const vertex_type v = pos->second;

    if (u+1)
    {
      const char* street_name = way.get_value_by_key("name", "");

      const Location& a = boost::get(boost::vertex_name, graph, u);
      const Location& b = boost::get(boost::vertex_name, graph, v);
      const double length = dist(a, b);

      edge_property prop;
      boost::get_property_value(prop, boost::edge_name) = street_name;
      boost::get_property_value(prop, boost::edge_weight) = length;

      boost::add_edge(u, v, prop, graph);
    }

    u = v;
  }
}
Пример #2
0
/**
 * Takes the geometry contained in the ```input_way``` and the tags computed
 * by the lua profile inside ```parsed_way``` and computes all edge segments.
 *
 * Depending on the forward/backwards weights the edges are split into forward
 * and backward edges.
 *
 * warning: caller needs to take care of synchronization!
 */
void ExtractorCallbacks::ProcessWay(const osmium::Way &input_way, const ExtractionWay &parsed_way)
{
    if (((0 >= parsed_way.forward_speed) ||
         (TRAVEL_MODE_INACCESSIBLE == parsed_way.forward_travel_mode)) &&
        ((0 >= parsed_way.backward_speed) ||
         (TRAVEL_MODE_INACCESSIBLE == parsed_way.backward_travel_mode)) &&
        (0 >= parsed_way.duration))
    { // Only true if the way is specified by the speed profile
        return;
    }

    if (input_way.nodes().size() <= 1)
    { // safe-guard against broken data
        return;
    }

    if (std::numeric_limits<decltype(input_way.id())>::max() == input_way.id())
    {
        util::SimpleLogger().Write(logDEBUG) << "found bogus way with id: " << input_way.id()
                                             << " of size " << input_way.nodes().size();
        return;
    }

    InternalExtractorEdge::WeightData forward_weight_data;
    InternalExtractorEdge::WeightData backward_weight_data;

    if (0 < parsed_way.duration)
    {
        const unsigned num_edges = (input_way.nodes().size() - 1);
        // FIXME We devide by the numer of nodes here, but should rather consider
        // the length of each segment. We would eigther have to compute the length
        // of the whole way here (we can't: no node coordinates) or push that back
        // to the container and keep a reference to the way.
        forward_weight_data.duration = parsed_way.duration / num_edges;
        forward_weight_data.type = InternalExtractorEdge::WeightType::WAY_DURATION;
        backward_weight_data.duration = parsed_way.duration / num_edges;
        backward_weight_data.type = InternalExtractorEdge::WeightType::WAY_DURATION;
    }
    else
    {
        if (parsed_way.forward_speed > 0 &&
            parsed_way.forward_travel_mode != TRAVEL_MODE_INACCESSIBLE)
        {
            forward_weight_data.speed = parsed_way.forward_speed;
            forward_weight_data.type = InternalExtractorEdge::WeightType::SPEED;
        }
        if (parsed_way.backward_speed > 0 &&
            parsed_way.backward_travel_mode != TRAVEL_MODE_INACCESSIBLE)
        {
            backward_weight_data.speed = parsed_way.backward_speed;
            backward_weight_data.type = InternalExtractorEdge::WeightType::SPEED;
        }
    }

    if (forward_weight_data.type == InternalExtractorEdge::WeightType::INVALID &&
        backward_weight_data.type == InternalExtractorEdge::WeightType::INVALID)
    {
        util::SimpleLogger().Write(logDEBUG) << "found way with bogus speed, id: "
                                             << input_way.id();
        return;
    }

    // FIXME this need to be moved into the profiles
    const char *data = input_way.get_value_by_key("highway");
    guidance::RoadClassificationData road_classification;
    if (data)
    {
        road_classification.road_class = guidance::functionalRoadClassFromTag(data);
    }

    const auto laneStringToDescription = [](std::string lane_string) -> TurnLaneDescription {
        if (lane_string.empty())
            return {};

        TurnLaneDescription lane_description;

        typedef boost::tokenizer<boost::char_separator<char>> tokenizer;
        boost::char_separator<char> sep("|", "", boost::keep_empty_tokens);
        boost::char_separator<char> inner_sep(";", "");
        tokenizer tokens(lane_string, sep);

        const constexpr std::size_t num_osm_tags = 11;
        const constexpr char *osm_lane_strings[num_osm_tags] = {"none",
                                                                "through",
                                                                "sharp_left",
                                                                "left",
                                                                "slight_left",
                                                                "slight_right",
                                                                "right",
                                                                "sharp_right",
                                                                "reverse",
                                                                "merge_to_left",
                                                                "merge_to_right"};
        const constexpr TurnLaneType::Mask masks_by_osm_string[num_osm_tags + 1] = {
            TurnLaneType::none,
            TurnLaneType::straight,
            TurnLaneType::sharp_left,
            TurnLaneType::left,
            TurnLaneType::slight_left,
            TurnLaneType::slight_right,
            TurnLaneType::right,
            TurnLaneType::sharp_right,
            TurnLaneType::uturn,
            TurnLaneType::merge_to_left,
            TurnLaneType::merge_to_right,
            TurnLaneType::empty}; // fallback, if string not found

        for (auto iter = tokens.begin(); iter != tokens.end(); ++iter)
        {
            tokenizer inner_tokens(*iter, inner_sep);
            guidance::TurnLaneType::Mask lane_mask = inner_tokens.begin() == inner_tokens.end()
                                                         ? TurnLaneType::none
                                                         : TurnLaneType::empty;
            for (auto token_itr = inner_tokens.begin(); token_itr != inner_tokens.end();
                 ++token_itr)
            {
                auto position = std::find(osm_lane_strings, osm_lane_strings + num_osm_tags, *token_itr);
                const auto translated_mask =
                    masks_by_osm_string[std::distance(osm_lane_strings, position)];
                if (translated_mask == TurnLaneType::empty)
                {
                    // if we have unsupported tags, don't handle them
                    util::SimpleLogger().Write(logDEBUG) << "Unsupported lane tag found: \""
                                                         << *token_itr << "\"";
                    return {};
                }
                BOOST_ASSERT((lane_mask & translated_mask) == 0); // make sure the mask is valid
                lane_mask |= translated_mask;
            }
            // add the lane to the description
            lane_description.push_back(lane_mask);
        }
        return lane_description;
    };

    // convert the lane description into an ID and, if necessary, remembr the description in the
    // description_map
    const auto requestId = [&](std::string lane_string) {
        if (lane_string.empty())
            return INVALID_LANE_DESCRIPTIONID;
        TurnLaneDescription lane_description = laneStringToDescription(std::move(lane_string));

        const auto lane_description_itr = lane_description_map.find(lane_description);
        if (lane_description_itr == lane_description_map.end())
        {
            const LaneDescriptionID new_id =
                boost::numeric_cast<LaneDescriptionID>(lane_description_map.size());
            lane_description_map[lane_description] = new_id;

            // since we are getting a new ID, we can augment the current offsets

            // and store the turn lane masks, sadly stxxl does not support insert
            for (const auto mask : lane_description)
                external_memory.turn_lane_masks.push_back(mask);

            external_memory.turn_lane_offsets.push_back(external_memory.turn_lane_offsets.back() +
                                                        lane_description.size());

            return new_id;
        }
        else
        {
            return lane_description_itr->second;
        }
    };

    // Deduplicates street names and street destination names based on the street_map map.
    // In case we do not already store the name, inserts (name, id) tuple and return id.
    // Otherwise fetches the id based on the name and returns it without insertion.
    const auto turn_lane_id_forward = requestId(parsed_way.turn_lanes_forward);
    const auto turn_lane_id_backward = requestId(parsed_way.turn_lanes_backward);

    const constexpr auto MAX_STRING_LENGTH = 255u;
    // Get the unique identifier for the street name
    // Get the unique identifier for the street name and destination
    const auto name_iterator = string_map.find(MapKey(parsed_way.name, parsed_way.destinations));
    unsigned name_id = EMPTY_NAMEID;
    if (string_map.end() == name_iterator)
    {
        const auto name_length = std::min<unsigned>(MAX_STRING_LENGTH, parsed_way.name.size());
        const auto destinations_length =
            std::min<unsigned>(MAX_STRING_LENGTH, parsed_way.destinations.size());
        const auto pronunciation_length =
            std::min<unsigned>(MAX_STRING_LENGTH, parsed_way.pronunciation.size());

        // name_offsets already has an offset of a new name, take the offset index as the name id
        name_id = external_memory.name_offsets.size() - 1;

        external_memory.name_char_data.reserve(external_memory.name_char_data.size() + name_length
                                               + destinations_length + pronunciation_length);

        std::copy(parsed_way.name.c_str(),
                  parsed_way.name.c_str() + name_length,
                  std::back_inserter(external_memory.name_char_data));
        external_memory.name_offsets.push_back(external_memory.name_char_data.size());

        std::copy(parsed_way.destinations.c_str(),
                  parsed_way.destinations.c_str() + destinations_length,
                  std::back_inserter(external_memory.name_char_data));
        external_memory.name_offsets.push_back(external_memory.name_char_data.size());

        std::copy(parsed_way.pronunciation.c_str(),
                  parsed_way.pronunciation.c_str() + pronunciation_length,
                  std::back_inserter(external_memory.name_char_data));
        external_memory.name_offsets.push_back(external_memory.name_char_data.size());

        auto k = MapKey{parsed_way.name, parsed_way.destinations};
        auto v = MapVal{name_id};
        string_map.emplace(std::move(k), std::move(v));
    }
    else
    {
        name_id = name_iterator->second;
    }

    const bool split_edge = (parsed_way.forward_speed > 0) &&
                            (TRAVEL_MODE_INACCESSIBLE != parsed_way.forward_travel_mode) &&
                            (parsed_way.backward_speed > 0) &&
                            (TRAVEL_MODE_INACCESSIBLE != parsed_way.backward_travel_mode) &&
                            ((parsed_way.forward_speed != parsed_way.backward_speed) ||
                             (parsed_way.forward_travel_mode != parsed_way.backward_travel_mode) ||
                             (turn_lane_id_forward != turn_lane_id_backward));

    external_memory.used_node_id_list.reserve(external_memory.used_node_id_list.size() +
                                              input_way.nodes().size());

    std::transform(input_way.nodes().begin(),
                   input_way.nodes().end(),
                   std::back_inserter(external_memory.used_node_id_list),
                   [](const osmium::NodeRef &ref) { return OSMNodeID{static_cast<std::uint64_t>(ref.ref())}; });

    const bool is_opposite_way = TRAVEL_MODE_INACCESSIBLE == parsed_way.forward_travel_mode;

    // traverse way in reverse in this case
    if (is_opposite_way)
    {
        BOOST_ASSERT(split_edge == false);
        BOOST_ASSERT(parsed_way.backward_travel_mode != TRAVEL_MODE_INACCESSIBLE);
        util::for_each_pair(
            input_way.nodes().crbegin(),
            input_way.nodes().crend(),
            [&](const osmium::NodeRef &first_node, const osmium::NodeRef &last_node) {
                external_memory.all_edges_list.push_back(
                    InternalExtractorEdge(OSMNodeID{static_cast<std::uint64_t>(first_node.ref())},
                                          OSMNodeID{static_cast<std::uint64_t>(last_node.ref())},
                                          name_id,
                                          backward_weight_data,
                                          true,
                                          false,
                                          parsed_way.roundabout,
                                          parsed_way.is_access_restricted,
                                          parsed_way.is_startpoint,
                                          parsed_way.backward_travel_mode,
                                          false,
                                          turn_lane_id_backward,
                                          road_classification));
            });

        external_memory.way_start_end_id_list.push_back(
            {OSMWayID{static_cast<std::uint32_t>(input_way.id())},
             OSMNodeID{static_cast<std::uint64_t>(input_way.nodes().back().ref())},
             OSMNodeID{static_cast<std::uint64_t>(input_way.nodes()[input_way.nodes().size() - 2].ref())},
             OSMNodeID{static_cast<std::uint64_t>(input_way.nodes()[1].ref())},
             OSMNodeID{static_cast<std::uint64_t>(input_way.nodes()[0].ref())}});
    }
    else
    {
        const bool forward_only =
            split_edge || TRAVEL_MODE_INACCESSIBLE == parsed_way.backward_travel_mode;
        util::for_each_pair(
            input_way.nodes().cbegin(),
            input_way.nodes().cend(),
            [&](const osmium::NodeRef &first_node, const osmium::NodeRef &last_node) {
                external_memory.all_edges_list.push_back(
                    InternalExtractorEdge(OSMNodeID{static_cast<std::uint64_t>(first_node.ref())},
                                          OSMNodeID{static_cast<std::uint64_t>(last_node.ref())},
                                          name_id,
                                          forward_weight_data,
                                          true,
                                          !forward_only,
                                          parsed_way.roundabout,
                                          parsed_way.is_access_restricted,
                                          parsed_way.is_startpoint,
                                          parsed_way.forward_travel_mode,
                                          split_edge,
                                          turn_lane_id_forward,
                                          road_classification));
            });
        if (split_edge)
        {
            BOOST_ASSERT(parsed_way.backward_travel_mode != TRAVEL_MODE_INACCESSIBLE);
            util::for_each_pair(
                input_way.nodes().cbegin(),
                input_way.nodes().cend(),
                [&](const osmium::NodeRef &first_node, const osmium::NodeRef &last_node) {
                    external_memory.all_edges_list.push_back(
                        InternalExtractorEdge(OSMNodeID{static_cast<std::uint64_t>(first_node.ref())},
                                              OSMNodeID{static_cast<std::uint64_t>(last_node.ref())},
                                              name_id,
                                              backward_weight_data,
                                              false,
                                              true,
                                              parsed_way.roundabout,
                                              parsed_way.is_access_restricted,
                                              parsed_way.is_startpoint,
                                              parsed_way.backward_travel_mode,
                                              true,
                                              turn_lane_id_backward,
                                              road_classification));
                });
        }

        external_memory.way_start_end_id_list.push_back(
            {OSMWayID{static_cast<std::uint32_t>(input_way.id())},
             OSMNodeID{static_cast<std::uint64_t>(input_way.nodes().back().ref())},
             OSMNodeID{static_cast<std::uint64_t>(input_way.nodes()[input_way.nodes().size() - 2].ref())},
             OSMNodeID{static_cast<std::uint64_t>(input_way.nodes()[1].ref())},
             OSMNodeID{static_cast<std::uint64_t>(input_way.nodes()[0].ref())}});
    }
}
/**
 * Takes the geometry contained in the ```input_way``` and the tags computed
 * by the lua profile inside ```parsed_way``` and computes all edge segments.
 *
 * Depending on the forward/backwards weights the edges are split into forward
 * and backward edges.
 *
 * warning: caller needs to take care of synchronization!
 */
void ExtractorCallbacks::ProcessWay(const osmium::Way &input_way, const ExtractionWay &parsed_way)
{
    if (((0 >= parsed_way.forward_speed) ||
         (TRAVEL_MODE_INACCESSIBLE == parsed_way.forward_travel_mode)) &&
        ((0 >= parsed_way.backward_speed) ||
         (TRAVEL_MODE_INACCESSIBLE == parsed_way.backward_travel_mode)) &&
        (0 >= parsed_way.duration))
    { // Only true if the way is specified by the speed profile
        return;
    }

    if (input_way.nodes().size() <= 1)
    { // safe-guard against broken data
        return;
    }

    if (std::numeric_limits<decltype(input_way.id())>::max() == input_way.id())
    {
        util::SimpleLogger().Write(logDEBUG) << "found bogus way with id: " << input_way.id()
                                             << " of size " << input_way.nodes().size();
        return;
    }

    InternalExtractorEdge::WeightData forward_weight_data;
    InternalExtractorEdge::WeightData backward_weight_data;

    if (0 < parsed_way.duration)
    {
        const unsigned num_edges = (input_way.nodes().size() - 1);
        // FIXME We devide by the numer of nodes here, but should rather consider
        // the length of each segment. We would eigther have to compute the length
        // of the whole way here (we can't: no node coordinates) or push that back
        // to the container and keep a reference to the way.
        forward_weight_data.duration = parsed_way.duration / num_edges;
        forward_weight_data.type = InternalExtractorEdge::WeightType::WAY_DURATION;
        backward_weight_data.duration = parsed_way.duration / num_edges;
        backward_weight_data.type = InternalExtractorEdge::WeightType::WAY_DURATION;
    }
    else
    {
        if (parsed_way.forward_speed > 0 &&
            parsed_way.forward_travel_mode != TRAVEL_MODE_INACCESSIBLE)
        {
            forward_weight_data.speed = parsed_way.forward_speed;
            forward_weight_data.type = InternalExtractorEdge::WeightType::SPEED;
        }
        if (parsed_way.backward_speed > 0 &&
            parsed_way.backward_travel_mode != TRAVEL_MODE_INACCESSIBLE)
        {
            backward_weight_data.speed = parsed_way.backward_speed;
            backward_weight_data.type = InternalExtractorEdge::WeightType::SPEED;
        }
    }

    if (forward_weight_data.type == InternalExtractorEdge::WeightType::INVALID &&
        backward_weight_data.type == InternalExtractorEdge::WeightType::INVALID)
    {
        util::SimpleLogger().Write(logDEBUG) << "found way with bogus speed, id: "
                                             << input_way.id();
        return;
    }

    // FIXME this need to be moved into the profiles
    const char *data = input_way.get_value_by_key("highway");
    guidance::RoadClassificationData road_classification;
    if (data)
    {
        road_classification.road_class = guidance::functionalRoadClassFromTag(data);
    }

    // Deduplicates street names and street destination names based on the street_map map.
    // In case we do not already store the name, inserts (name, id) tuple and return id.
    // Otherwise fetches the id based on the name and returns it without insertion.

    const constexpr auto MAX_STRING_LENGTH = 255u;

    // Get the unique identifier for the street name
    const auto string_map_iterator = string_map.find(parsed_way.name);
    unsigned name_id = external_memory.name_lengths.size();
    if (string_map.end() == string_map_iterator)
    {
        auto name_length = std::min<unsigned>(MAX_STRING_LENGTH, parsed_way.name.size());

        external_memory.name_char_data.reserve(name_id + name_length);
        std::copy(parsed_way.name.c_str(),
                  parsed_way.name.c_str() + name_length,
                  std::back_inserter(external_memory.name_char_data));

        external_memory.name_lengths.push_back(name_length);
        string_map.insert(std::make_pair(parsed_way.name, name_id));
    }
    else
    {
        name_id = string_map_iterator->second;
    }

    const bool split_edge = (parsed_way.forward_speed > 0) &&
                            (TRAVEL_MODE_INACCESSIBLE != parsed_way.forward_travel_mode) &&
                            (parsed_way.backward_speed > 0) &&
                            (TRAVEL_MODE_INACCESSIBLE != parsed_way.backward_travel_mode) &&
                            ((parsed_way.forward_speed != parsed_way.backward_speed) ||
                             (parsed_way.forward_travel_mode != parsed_way.backward_travel_mode));

    std::transform(input_way.nodes().begin(),
                   input_way.nodes().end(),
                   std::back_inserter(external_memory.used_node_id_list),
                   [](const osmium::NodeRef &ref) { return OSMNodeID(ref.ref()); });

    const bool is_opposite_way = TRAVEL_MODE_INACCESSIBLE == parsed_way.forward_travel_mode;

    // traverse way in reverse in this case
    if (is_opposite_way)
    {
        BOOST_ASSERT(split_edge == false);
        BOOST_ASSERT(parsed_way.backward_travel_mode != TRAVEL_MODE_INACCESSIBLE);
        util::for_each_pair(
            input_way.nodes().crbegin(),
            input_way.nodes().crend(),
            [&](const osmium::NodeRef &first_node, const osmium::NodeRef &last_node) {
                external_memory.all_edges_list.push_back(
                    InternalExtractorEdge(OSMNodeID(first_node.ref()),
                                          OSMNodeID(last_node.ref()),
                                          name_id,
                                          backward_weight_data,
                                          true,
                                          false,
                                          parsed_way.roundabout,
                                          parsed_way.is_access_restricted,
                                          parsed_way.is_startpoint,
                                          parsed_way.backward_travel_mode,
                                          false,
                                          road_classification));
            });

        external_memory.way_start_end_id_list.push_back(
            {OSMWayID(input_way.id()),
             OSMNodeID(input_way.nodes().back().ref()),
             OSMNodeID(input_way.nodes()[input_way.nodes().size() - 2].ref()),
             OSMNodeID(input_way.nodes()[1].ref()),
             OSMNodeID(input_way.nodes()[0].ref())});
    }
    else
    {
        const bool forward_only =
            split_edge || TRAVEL_MODE_INACCESSIBLE == parsed_way.backward_travel_mode;
        util::for_each_pair(
            input_way.nodes().cbegin(),
            input_way.nodes().cend(),
            [&](const osmium::NodeRef &first_node, const osmium::NodeRef &last_node) {
                external_memory.all_edges_list.push_back(
                    InternalExtractorEdge(OSMNodeID(first_node.ref()),
                                          OSMNodeID(last_node.ref()),
                                          name_id,
                                          forward_weight_data,
                                          true,
                                          !forward_only,
                                          parsed_way.roundabout,
                                          parsed_way.is_access_restricted,
                                          parsed_way.is_startpoint,
                                          parsed_way.forward_travel_mode,
                                          split_edge,
                                          road_classification));
            });
        if (split_edge)
        {
            BOOST_ASSERT(parsed_way.backward_travel_mode != TRAVEL_MODE_INACCESSIBLE);
            util::for_each_pair(
                input_way.nodes().cbegin(),
                input_way.nodes().cend(),
                [&](const osmium::NodeRef &first_node, const osmium::NodeRef &last_node) {
                    external_memory.all_edges_list.push_back(
                        InternalExtractorEdge(OSMNodeID(first_node.ref()),
                                              OSMNodeID(last_node.ref()),
                                              name_id,
                                              backward_weight_data,
                                              false,
                                              true,
                                              parsed_way.roundabout,
                                              parsed_way.is_access_restricted,
                                              parsed_way.is_startpoint,
                                              parsed_way.backward_travel_mode,
                                              true,
                                              road_classification));
                });
        }

        external_memory.way_start_end_id_list.push_back(
            {OSMWayID(input_way.id()),
             OSMNodeID(input_way.nodes().back().ref()),
             OSMNodeID(input_way.nodes()[input_way.nodes().size() - 2].ref()),
             OSMNodeID(input_way.nodes()[1].ref()),
             OSMNodeID(input_way.nodes()[0].ref())});
    }
}