/** * Navit, a modular navigation system. * Copyright (C) 2005-2018 Navit Team * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * version 2 as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the * Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, * Boston, MA 02110-1301, USA. */ /** @file * @brief Contains code related to finding a route from a position to a destination * * Routing uses segments, points and items. Items are items from the map: Streets, highways, etc. * Segments represent such items, or parts of it. Generally, a segment is a driveable path. An item * can be represented by more than one segment - in that case it is "segmented". Each segment has an * "offset" associated, that indicates at which position in a segmented item this segment is - a * segment representing a not-segmented item always has the offset 1. * A point is located at the end of segments, often connecting several segments. * * The code in this file will make navit find a route between a position and a destination. * It accomplishes this by first building a "route graph". This graph contains segments and * points. * * Routing now relies on the Lifelong Planning A* (LPA*) algorithm, which builds upon the A* algorithm but allows for * partial updates after the cost of some segments has changed. (With A*, one would need to recalculate the entire * route graph from scratch.) A*, in turn, is an extension of the Dijkstra algorithm, with the added improvement that * A* introduces a heuristic (essentially, a lower boundary for the yet-to-be-calculated remainder of the route from a * given point onwards) and chooses the next point to analyze based on the sum of its cost and its heuristic, where * Dijkstra uses simply the cost of the node. This makes A* more efficient than Dijkstra in some scenarios. (Navit, * however, is not one of them, as we currently analyze only a subset of the entire map, and calculating the heuristic * for each node turned out to cost more than it saved in tests.) * * Wikipedia has articles on all three algorithms; refer to these for an in-depth discussion of the algorithms. * * If the heuristic is assumed to be zero in all cases, A* behaves exactly as Dijkstra would. Similarly, LPA* behaves * identically to A* if all segment costs are known prior to route calculation and do not change once route calculation * has started. * * Earlier versions of Navit used Dijkstra for routing. This was upgraded to LPA* when the traffic module was * introduced, as it became necessary to do fast partial recalculations of the route when the traffic situation * changes. Navit’s LPA* implementation differs from the canonical implementation in two important ways: * * \li The heuristic is not used (or assumed to be zero), for the reasons discussed above. However, this is not set in * stone and can be revisited if we find using a heuristic provides a true benefit. * \li Since the destination point may be off-road, Navit may initialize the route graph with multiple candidates for * the destination point, each of which will get a nonzero cost (which may still decrease if routing later determines * that it is cheaper to route from that candidate point to a different candidate point). * * The cost of a node is always the cost to reach the destination, and route calculation is done “backwards”, i.e. * starting at the destination and working its way to the current position (or previous waypoint). This is mandatory * in LPA*, while A* and Dijkstra can also work from the start to the destination. The latter is found in most textbook * descriptions of these algorithms. Navit has always calculated routes from destination to start, even with Dijkstra, * as this made it easier to react to changes in the vehicle position (the start of the route). * * A route graph first needs to be built with `route_graph_build()`, which fetches the segments from the map. Next * `route_graph_init()` is called to initialize the destination point candidates. Then * `route_graph_compute_shortest_path()` is called to assign a `value` to each node, which represents the cost of * traveling from this point to the destination. Each point is also assigned a “next segment” to take in order to reach * the destination from this point. Eventually a “route path” is created, i.e. the sequence of segments from the * current position to the destination are extracted from the route graph and turn instructions are added where * necessary. * * When segment costs change, `route_graph_point_update()` is called for each end point which may have changed. Then * `route_graph_compute_shortest_path()` is called to update parts of the route which may have changed, and finally the * route path is recreated. This is used by the traffic module when traffic reports change the cost of individual * segments. * * A completely new route can be created from an existing graph, which happens e.g. between sections of a route when * waypoints are used. This is done by calling `route_graph_reset()`, which resets all nodes to their initial state. * Then `route_graph_init()` is called, followed by `route_graph_compute_shortest_path()` and eventually creation of * the route path. */ #include #include #include #include #include "navit_nls.h" #include "glib_slice.h" #include "config.h" #include "point.h" #include "graphics.h" #include "profile.h" #include "coord.h" #include "projection.h" #include "item.h" #include "xmlconfig.h" #include "map.h" #include "mapset.h" #include "route_protected.h" #include "route.h" #include "track.h" #include "transform.h" #include "plugin.h" #include "fib.h" #include "event.h" #include "callback.h" #include "vehicle.h" #include "vehicleprofile.h" #include "roadprofile.h" #include "debug.h" struct map_priv { struct route *route; }; int debug_route=0; #define RSD_OFFSET(x) *((int *)route_segment_data_field_pos((x), attr_offset)) #define RSD_SIZE_WEIGHT(x) *((struct size_weight_limit *)route_segment_data_field_pos((x), attr_vehicle_width)) #define RSD_DANGEROUS_GOODS(x) *((int *)route_segment_data_field_pos((x), attr_vehicle_dangerous_goods)) /** * @brief A traffic distortion * * Traffic distortions represent delays or closures on the route, which can occur for a variety of * reasons such as roadworks, accidents or heavy traffic. They are also used internally by Navit to * avoid using a particular segment. * * A traffic distortion can limit the speed on a segment, or introduce a delay. If both are given, * at the same time, they are cumulative. */ struct route_traffic_distortion { int maxspeed; /**< Maximum speed possible in km/h. Use {@code INT_MAX} to leave the speed unchanged, or 0 to mark the segment as impassable. */ int delay; /**< Delay in tenths of seconds (0 for no delay) */ }; /** * @brief A segment in the route path * * This is a segment in the route path. */ struct route_path_segment { struct route_path_segment *next; /**< Pointer to the next segment in the path */ struct route_segment_data *data; /**< The segment data */ int direction; /**< Order in which the coordinates are ordered. >0 means "First * coordinate of the segment is the first coordinate of the item", <=0 * means reverse. */ unsigned ncoords; /**< How many coordinates does this segment have? */ struct coord c[0]; /**< Pointer to the ncoords coordinates of this segment */ /* WARNING: There will be coordinates following here, so do not create new fields after c! */ }; /** * @brief Usually represents a destination or position * * This struct usually represents a destination or position */ struct route_info { struct coord c; /**< The actual destination / position */ struct coord lp; /**< The nearest point on a street to c */ int pos; /**< The position of lp within the coords of the street */ int lenpos; /**< Distance between lp and the end of the street */ int lenneg; /**< Distance between lp and the start of the street */ int lenextra; /**< Distance between lp and c */ int percent; /**< ratio of lenneg to lenght of whole street in percent */ struct street_data *street; /**< The street lp is on */ int street_direction; /**< Direction of vehicle on street -1 = Negative direction, 1 = Positive direction, 0 = Unknown */ int dir; /**< Direction to take when following the route -1 = Negative direction, 1 = Positive direction */ }; /** * @brief A complete route path * * A route path is an ordered set of segments describing the route from the current position (or previous * destination) to the next destination. */ struct route_path { int in_use; /**< The path is in use and can not be updated */ int update_required; /**< The path needs to be updated after it is no longer in use */ int updated; /**< The path has only been updated */ int path_time; /**< Time to pass the path */ int path_len; /**< Length of the path */ struct route_path_segment *path; /**< The first segment in the path, i.e. the segment one should * drive in next */ struct route_path_segment *path_last; /**< The last segment in the path */ /* XXX: path_hash is not necessery now */ struct item_hash *path_hash; /**< A hashtable of all the items represented by this route's segements */ struct route_path *next; /**< Next route path in case of intermediate destinations */ }; /** * @brief A complete route * * This struct holds all information about a route. */ struct route { NAVIT_OBJECT struct mapset *ms; /**< The mapset this route is built upon */ enum route_path_flags flags; struct route_info *pos; /**< Current position within this route */ GList *destinations; /**< Destinations of the route */ int reached_destinations_count; /**< Used as base to calculate waypoint numbers */ struct route_info *current_dst; /**< Current destination */ struct route_graph *graph; /**< Pointer to the route graph */ struct route_path *path2; /**< Pointer to the route path */ struct map *map; /**< The map containing the route path */ struct map *graph_map; /**< The map containing the route graph */ struct callback * route_graph_done_cb ; /**< Callback when route graph is done */ struct callback * route_graph_flood_done_cb ; /**< Callback when route graph flooding is done */ struct callback_list *cbl2; /**< Callback list to call when route changes */ int destination_distance; /**< Distance to the destination at which the destination is considered "reached" */ struct vehicleprofile *vehicleprofile; /**< Routing preferences */ int route_status; /**< Route Status */ int link_path; /**< Link paths over multiple waypoints together */ struct pcoord pc; struct vehicle *v; }; #define HASHCOORD(c) ((((c)->x +(c)->y) * 2654435761UL) & (HASH_SIZE-1)) /** * @brief Iterator to iterate through all route graph segments in a route graph point * * This structure can be used to iterate through all route graph segments connected to a * route graph point. Use this with the rp_iterator_* functions. */ struct route_graph_point_iterator { struct route_graph_point *p; /**< The route graph point whose segments should be iterated */ int end; /**< Indicates if we have finished iterating through the "start" segments */ struct route_graph_segment *next; /**< The next segment to be returned */ }; struct attr_iter { union { GList *list; } u; }; static struct route_info * route_find_nearest_street(struct vehicleprofile *vehicleprofile, struct mapset *ms, struct pcoord *c); static void route_graph_update(struct route *this, struct callback *cb, int async); static struct route_path *route_path_new(struct route_graph *this, struct route_path *oldpath, struct route_info *pos, struct route_info *dst, struct vehicleprofile *profile); static void route_graph_add_street(struct route_graph *this, struct item *item, struct vehicleprofile *profile); static void route_graph_destroy(struct route_graph *this); static void route_path_update(struct route *this, int cancel, int async); static int route_time_seg(struct vehicleprofile *profile, struct route_segment_data *over, struct route_traffic_distortion *dist); static void route_graph_compute_shortest_path(struct route_graph * graph, struct vehicleprofile * profile, struct callback *cb); static int route_graph_is_path_computed(struct route_graph *this_); static struct route_graph_segment *route_graph_get_segment(struct route_graph *graph, struct street_data *sd, struct route_graph_segment *last); static int route_value_seg(struct vehicleprofile *profile, struct route_graph_point *from, struct route_graph_segment *over, int dir); static void route_graph_init(struct route_graph *this, struct route_info *dst, struct vehicleprofile *profile); static void route_graph_reset(struct route_graph *this); /** * @brief Returns the projection used for this route * * @param route The route to return the projection for * @return The projection used for this route */ static enum projection route_projection(struct route *route) { struct street_data *street; struct route_info *dst=route_get_dst(route); if (!route->pos && !dst) return projection_none; street = route->pos ? route->pos->street : dst->street; if (!street || !street->item.map) return projection_none; return map_projection(street->item.map); } /** * @brief Creates a new graph point iterator * * This function creates a new route graph point iterator, that can be used to * iterate through all segments connected to the point. * * @param p The route graph point to create the iterator from * @return A new iterator. */ static struct route_graph_point_iterator rp_iterator_new(struct route_graph_point *p) { struct route_graph_point_iterator it; it.p = p; if (p->start) { it.next = p->start; it.end = 0; } else { it.next = p->end; it.end = 1; } return it; } /** * @brief Gets the next segment connected to a route graph point from an iterator * * @param it The route graph point iterator to get the segment from * @return The next segment or NULL if there are no more segments */ static struct route_graph_segment *rp_iterator_next(struct route_graph_point_iterator *it) { struct route_graph_segment *ret; ret = it->next; if (!ret) { return NULL; } if (!it->end) { if (ret->start_next) { it->next = ret->start_next; } else { it->next = it->p->end; it->end = 1; } } else { it->next = ret->end_next; } return ret; } /** * @brief Checks if the last segment returned from a route_graph_point_iterator comes from the end * * @param it The route graph point iterator to be checked * @return 1 if the last segment returned comes from the end of the route graph point, 0 otherwise */ static int rp_iterator_end(struct route_graph_point_iterator *it) { if (it->end && (it->next != it->p->end)) { return 1; } else { return 0; } } static void route_path_get_distances(struct route_path *path, struct coord *c, int count, int *distances) { int i; for (i = 0 ; i < count ; i++) distances[i]=INT_MAX; while (path) { struct route_path_segment *seg=path->path; while (seg) { for (i = 0 ; i < count ; i++) { int dist=transform_distance_polyline_sq(seg->c, seg->ncoords, &c[i], NULL, NULL); if (dist < distances[i]) distances[i]=dist; } seg=seg->next; } path=path->next; } for (i = 0 ; i < count ; i++) { if (distances[i] != INT_MAX) distances[i]=sqrt(distances[i]); } } void route_get_distances(struct route *this, struct coord *c, int count, int *distances) { return route_path_get_distances(this->path2, c, count, distances); } /** * @brief Destroys a route_path * * @param this The route_path to be destroyed */ static void route_path_destroy(struct route_path *this, int recurse) { struct route_path_segment *c,*n; struct route_path *next; while (this) { next=this->next; if (this->path_hash) { item_hash_destroy(this->path_hash); this->path_hash=NULL; } c=this->path; while (c) { n=c->next; g_free(c); c=n; } this->in_use--; if (!this->in_use) g_free(this); if (!recurse) break; this=next; } } /** * @brief Creates a completely new route structure * * @param attrs Not used * @return The newly created route */ struct route * route_new(struct attr *parent, struct attr **attrs) { struct route *this=g_new0(struct route, 1); struct attr dest_attr; this->func=&route_func; navit_object_ref((struct navit_object *)this); if (attr_generic_get_attr(attrs, NULL, attr_destination_distance, &dest_attr, NULL)) { this->destination_distance = dest_attr.u.num; } else { this->destination_distance = 50; // Default value } this->cbl2=callback_list_new(); return this; } /** * @brief Duplicates a route object * * @return The duplicated route */ struct route * route_dup(struct route *orig) { struct route *this=g_new0(struct route, 1); this->func=&route_func; navit_object_ref((struct navit_object *)this); this->cbl2=callback_list_new(); this->destination_distance=orig->destination_distance; this->ms=orig->ms; this->flags=orig->flags; this->vehicleprofile=orig->vehicleprofile; return this; } /** * @brief Checks if a segment is part of a roundabout * * This function checks if a segment is part of a roundabout. * * @param seg The segment to be checked * @param level How deep to scan the route graph * @param direction Set this to 1 if we're entering the segment through its end, to 0 otherwise * @param origin Used internally, set to NULL * @return 1 If a roundabout was detected, 0 otherwise */ static int route_check_roundabout(struct route_graph_segment *seg, int level, int direction, struct route_graph_segment *origin) { struct route_graph_point_iterator it,it2; struct route_graph_segment *cur; int count=0; if (!level) { return 0; } if (!direction && !(seg->data.flags & AF_ONEWAY)) { return 0; } if (direction && !(seg->data.flags & AF_ONEWAYREV)) { return 0; } if (seg->data.flags & AF_ROUNDABOUT_VALID) return 0; if (!origin) { origin = seg; } if (!direction) { it = rp_iterator_new(seg->end); } else { it = rp_iterator_new(seg->start); } it2=it; while ((cur = rp_iterator_next(&it2))) count++; if (count > 3) return 0; cur = rp_iterator_next(&it); while (cur) { if (cur == seg) { cur = rp_iterator_next(&it); continue; } if (cur->data.item.type != origin->data.item.type) { // This street is of another type, can't be part of the roundabout cur = rp_iterator_next(&it); continue; } if (cur == origin) { seg->data.flags |= AF_ROUNDABOUT; return 1; } if (route_check_roundabout(cur, (level-1), rp_iterator_end(&it), origin)) { seg->data.flags |= AF_ROUNDABOUT; return 1; } cur = rp_iterator_next(&it); } return 0; } /** * @brief Sets the mapset of the route passwd * * @param this The route to set the mapset for * @param ms The mapset to set for this route */ void route_set_mapset(struct route *this, struct mapset *ms) { this->ms=ms; } /** * @brief Sets the vehicle profile of a route * * @param this The route to set the profile for * @param prof The vehicle profile */ void route_set_profile(struct route *this, struct vehicleprofile *prof) { if (this->vehicleprofile != prof) { int dest_count = g_list_length(this->destinations); struct pcoord *pc; this->vehicleprofile = prof; pc = g_alloca(dest_count*sizeof(struct pcoord)); route_get_destinations(this, pc, dest_count); route_set_destinations(this, pc, dest_count, 1); } } /** * @brief Returns the mapset of the route passed * * @param this The route to get the mapset of * @return The mapset of the route passed */ struct mapset * route_get_mapset(struct route *this) { return this->ms; } /** * @brief Returns the current position within the route passed * * @param this The route to get the position for * @return The position within the route passed */ struct route_info * route_get_pos(struct route *this) { return this->pos; } /** * @brief Returns the destination of the route passed * * @param this The route to get the destination for * @return The destination of the route passed */ struct route_info * route_get_dst(struct route *this) { struct route_info *dst=NULL; if (this->destinations) dst=g_list_last(this->destinations)->data; return dst; } /** * @brief Checks if the path is calculated for the route passed * * @param this The route to check * @return True if the path is calculated, false if not */ int route_get_path_set(struct route *this) { return this->path2 != NULL; } /** * @brief Checks if the route passed contains a certain item within the route path * * This function checks if a certain items exists in the path that navit will guide * the user to his destination. It does *not* check if this item exists in the route * graph! * * @param this The route to check for this item * @param item The item to search for * @return True if the item was found, false if the item was not found or the route was not calculated */ int route_contains(struct route *this, struct item *item) { if (! this->path2 || !this->path2->path_hash) return 0; if (item_hash_lookup(this->path2->path_hash, item)) return 1; if (! this->pos || !this->pos->street) return 0; return item_is_equal(this->pos->street->item, *item); } static struct route_info *route_next_destination(struct route *this) { if (!this->destinations) return NULL; return this->destinations->data; } /** * @brief Checks if a route has reached its destination * * @param this The route to be checked * @return True if the destination is "reached", false otherwise. */ int route_destination_reached(struct route *this) { struct street_data *sd = NULL; enum projection pro; struct route_info *dst=route_next_destination(this); if (!this->pos) return 0; if (!dst) return 0; sd = this->pos->street; if (!this->path2) { return 0; } if (!item_is_equal(this->pos->street->item, dst->street->item)) { return 0; } if ((sd->flags & AF_ONEWAY) && (this->pos->lenneg >= dst->lenneg)) { // We would have to drive against the one-way road return 0; } if ((sd->flags & AF_ONEWAYREV) && (this->pos->lenpos >= dst->lenpos)) { return 0; } pro=route_projection(this); if (pro == projection_none) return 0; if (transform_distance(pro, &this->pos->c, &dst->lp) > this->destination_distance) { return 0; } if (g_list_next(this->destinations)) return 1; else return 2; } /** * @brief Returns the position from which to route to the current destination of the route. * * This function examines the destination list of the route. If present, it returns the destination * which precedes the one indicated by the {@code current_dst} member of the route. Failing that, * the current position of the route is returned. * * @param this The route object * @return The previous destination or current position, see description */ static struct route_info *route_previous_destination(struct route *this) { GList *l=g_list_find(this->destinations, this->current_dst); if (!l) return this->pos; l=g_list_previous(l); if (!l) return this->pos; return l->data; } /** * @brief Updates or recreates the route graph. * * This function is called after the route graph has been changed or rebuilt and flooding has * completed. It then updates the route path to reflect these changes. * * If multiple destinations are set, this function will reset and re-flood the route graph for each * destination, thus recursively calling itself for each destination. * * @param this The route object * @param new_graph FIXME Whether the route graph has been rebuilt from scratch */ /* FIXME Should we rename this function to route_graph_flood_done, in order to avoid confusion? */ static void route_path_update_done(struct route *this, int new_graph) { struct route_path *oldpath=this->path2; struct attr route_status; struct route_info *prev_dst; /* previous destination or current position */ route_status.type=attr_route_status; if (this->path2 && (this->path2->in_use>1)) { this->path2->update_required=1+new_graph; return; } route_status.u.num=route_status_building_path; route_set_attr(this, &route_status); prev_dst=route_previous_destination(this); if (this->link_path) { this->path2=route_path_new(this->graph, NULL, prev_dst, this->current_dst, this->vehicleprofile); if (this->path2) this->path2->next=oldpath; else route_path_destroy(oldpath,0); } else { this->path2=route_path_new(this->graph, oldpath, prev_dst, this->current_dst, this->vehicleprofile); if (oldpath && this->path2) { this->path2->next=oldpath->next; route_path_destroy(oldpath,0); } } if (this->path2) { struct route_path_segment *seg=this->path2->path; int path_time=0,path_len=0; while (seg) { /* FIXME */ int seg_time=route_time_seg(this->vehicleprofile, seg->data, NULL); if (seg_time == INT_MAX) { dbg(lvl_debug,"error"); } else path_time+=seg_time; path_len+=seg->data->len; seg=seg->next; } this->path2->path_time=path_time; this->path2->path_len=path_len; if (prev_dst != this->pos) { this->link_path=1; this->current_dst=prev_dst; route_graph_reset(this->graph); route_graph_init(this->graph, this->current_dst, this->vehicleprofile); route_graph_compute_shortest_path(this->graph, this->vehicleprofile, this->route_graph_flood_done_cb); return; } if (!new_graph && this->path2->updated) route_status.u.num=route_status_path_done_incremental; else route_status.u.num=route_status_path_done_new; } else route_status.u.num=route_status_not_found; this->link_path=0; route_set_attr(this, &route_status); } /** * @brief Updates the route graph and the route path if something changed with the route * * This will update the route graph and the route path of the route if some of the * route's settings (destination, position) have changed. * * The behavior of this function can be controlled via flags: *
    *
  • {@code route_path_flag_cancel}: Cancel navigation, clear route graph and route path
    • *
  • {@code route_path_flag_async}: Perform operations asynchronously
    • *
  • {@code route_path_flag_no_rebuild}: Do not rebuild the route graph
    • *
* * These flags will be stored in the {@code flags} member of the route object. * * @attention For this to work the route graph has to be destroyed if the route's * @attention destination is changed somewhere! * * @param this The route to update * @param flags Flags to control the behavior of this function, see description */ static void route_path_update_flags(struct route *this, enum route_path_flags flags) { dbg(lvl_debug,"enter %d", flags); this->flags = flags; if (! this->pos || ! this->destinations) { dbg(lvl_debug,"destroy"); route_path_destroy(this->path2,1); this->path2 = NULL; return; } if (flags & route_path_flag_cancel) { route_graph_destroy(this->graph); this->graph=NULL; } /* the graph is destroyed when setting the destination */ if (this->graph) { if (this->graph->busy) { dbg(lvl_debug,"busy building graph"); return; } // we can try to update dbg(lvl_debug,"try update"); route_path_update_done(this, 0); } else { route_path_destroy(this->path2,1); this->path2 = NULL; } if (!this->graph || (!this->path2 && !(flags & route_path_flag_no_rebuild))) { dbg(lvl_debug,"rebuild graph %p %p",this->graph,this->path2); if (! this->route_graph_flood_done_cb) this->route_graph_flood_done_cb=callback_new_2(callback_cast(route_path_update_done), this, (long)1); dbg(lvl_debug,"route_graph_update"); route_graph_update(this, this->route_graph_flood_done_cb, !!(flags & route_path_flag_async)); } } /** * @brief Updates the route graph and the route path if something changed with the route * * This function is a wrapper around {@link route_path_update_flags(route *, enum route_path)}. * * @param this The route to update * @param cancel If true, cancel navigation, clear route graph and route path * @param async If true, perform processing asynchronously */ static void route_path_update(struct route *this, int cancel, int async) { enum route_path_flags flags=(cancel ? route_path_flag_cancel:0)|(async ? route_path_flag_async:0); route_path_update_flags(this, flags); } /** * @brief This will calculate all the distances stored in a route_info * * @param ri The route_info to calculate the distances for * @param pro The projection used for this route */ static void route_info_distances(struct route_info *ri, enum projection pro) { int npos=ri->pos+1; struct street_data *sd=ri->street; /* 0 1 2 X 3 4 5 6 pos=2 npos=3 count=7 0,1,2 3,4,5,6*/ ri->lenextra=transform_distance(pro, &ri->lp, &ri->c); ri->lenneg=transform_polyline_length(pro, sd->c, npos)+transform_distance(pro, &sd->c[ri->pos], &ri->lp); ri->lenpos=transform_polyline_length(pro, sd->c+npos, sd->count-npos)+transform_distance(pro, &sd->c[npos], &ri->lp); if (ri->lenneg || ri->lenpos) ri->percent=(ri->lenneg*100)/(ri->lenneg+ri->lenpos); else ri->percent=50; } /** * @brief This sets the current position of the route passed * * This will set the current position of the route passed to the street that is nearest to the * passed coordinates. It also automatically updates the route. * * @param this The route to set the position of * @param pos Coordinates to set as position * @param flags Flags to use for building the graph */ static int route_set_position_flags(struct route *this, struct pcoord *pos, enum route_path_flags flags) { if (this->pos) route_info_free(this->pos); this->pos=NULL; this->pos=route_find_nearest_street(this->vehicleprofile, this->ms, pos); // If there is no nearest street, bail out. if (!this->pos) return 0; this->pos->street_direction=0; dbg(lvl_debug,"this->pos=%p", this->pos); route_info_distances(this->pos, pos->pro); route_path_update_flags(this, flags); return 1; } /** * @brief This sets the current position of the route passed * * This will set the current position of the route passed to the street that is nearest to the * passed coordinates. It also automatically updates the route. * * @param this The route to set the position of * @param pos Coordinates to set as position */ void route_set_position(struct route *this, struct pcoord *pos) { route_set_position_flags(this, pos, route_path_flag_async); } /** * @brief Sets a route's current position based on coordinates from tracking * * @param this The route to set the current position of * @param tracking The tracking to get the coordinates from */ void route_set_position_from_tracking(struct route *this, struct tracking *tracking, enum projection pro) { struct coord *c; struct route_info *ret; struct street_data *sd; dbg(lvl_info,"enter"); c=tracking_get_pos(tracking); ret=g_new0(struct route_info, 1); if (!ret) { printf("%s:Out of memory\n", __FUNCTION__); return; } if (this->pos) route_info_free(this->pos); this->pos=NULL; ret->c=*c; ret->lp=*c; ret->pos=tracking_get_segment_pos(tracking); ret->street_direction=tracking_get_street_direction(tracking); sd=tracking_get_street_data(tracking); if (sd) { ret->street=street_data_dup(sd); route_info_distances(ret, pro); } dbg(lvl_debug,"position 0x%x,0x%x item 0x%x,0x%x direction %d pos %d lenpos %d lenneg %d",c->x,c->y,sd?sd->item.id_hi:0, sd?sd->item.id_lo:0,ret->street_direction,ret->pos,ret->lenpos,ret->lenneg); dbg(lvl_debug,"c->x=0x%x, c->y=0x%x pos=%d item=(0x%x,0x%x)", c->x, c->y, ret->pos, ret->street?ret->street->item.id_hi:0, ret->street?ret->street->item.id_lo:0); dbg(lvl_debug,"street 0=(0x%x,0x%x) %d=(0x%x,0x%x)", ret->street?ret->street->c[0].x:0, ret->street?ret->street->c[0].y:0, ret->street?ret->street->count-1:0, ret->street?ret->street->c[ret->street->count-1].x:0, ret->street?ret->street->c[ret->street->count-1].y:0); this->pos=ret; if (this->destinations) route_path_update(this, 0, 1); dbg(lvl_info,"ret"); } /* Used for debuging of route_rect, what routing sees */ struct map_selection *route_selection; /** * @brief Returns a single map selection * * The boundaries of the selection are determined as follows: First a rectangle spanning `c1` and `c2` is * built (the two coordinates can be any two opposite corners of the rectangle). Then its maximum extension * (height or width) is determined and multiplied with the percentage specified by `rel`. The resulting * amount of padding is added to each edge. After that, the amount specified by `abs` is added to each edge. * * @param order Map order (deepest tile level) to select * @param c1 First coordinate * @param c2 Second coordinate * @param rel Relative padding to add to the selection rectangle, in percent * @param abs Absolute padding to add to the selection rectangle */ struct map_selection * route_rect(int order, struct coord *c1, struct coord *c2, int rel, int abs) { int dx,dy,sx=1,sy=1,d,m; struct map_selection *sel=g_new(struct map_selection, 1); if (!sel) { printf("%s:Out of memory\n", __FUNCTION__); return sel; } sel->order=order; sel->range.min=route_item_first; sel->range.max=route_item_last; dbg(lvl_debug,"%p %p", c1, c2); dx=c1->x-c2->x; dy=c1->y-c2->y; if (dx < 0) { sx=-1; sel->u.c_rect.lu.x=c1->x; sel->u.c_rect.rl.x=c2->x; } else { sel->u.c_rect.lu.x=c2->x; sel->u.c_rect.rl.x=c1->x; } if (dy < 0) { sy=-1; sel->u.c_rect.lu.y=c2->y; sel->u.c_rect.rl.y=c1->y; } else { sel->u.c_rect.lu.y=c1->y; sel->u.c_rect.rl.y=c2->y; } if (dx*sx > dy*sy) d=dx*sx; else d=dy*sy; m=d*rel/100+abs; sel->u.c_rect.lu.x-=m; sel->u.c_rect.rl.x+=m; sel->u.c_rect.lu.y+=m; sel->u.c_rect.rl.y-=m; sel->next=NULL; return sel; } /** * @brief Appends a map selection to the selection list. Selection list may be NULL. */ static struct map_selection *route_rect_add(struct map_selection *sel, int order, struct coord *c1, struct coord *c2, int rel, int abs) { struct map_selection *ret; ret=route_rect(order, c1, c2, rel, abs); ret->next=sel; return ret; } /** * @brief Returns a list of map selections useable to create a route graph * * Returns a list of map selections useable to get a map rect from which items can be * retrieved to build a route graph. * * @param c Array containing route points, including start, intermediate and destination ones. * @param count number of route points * @param proifle vehicleprofile */ static struct map_selection *route_calc_selection(struct coord *c, int count, struct vehicleprofile *profile) { struct map_selection *ret=NULL; int i; struct coord_rect r; char *depth, *str, *tok; if (!count) return NULL; r.lu=c[0]; r.rl=c[0]; for (i = 1 ; i < count ; i++) coord_rect_extend(&r, &c[i]); depth=profile->route_depth; if (!depth) depth="4:25%,8:40000,18:10000"; depth=str=g_strdup(depth); while((tok=strtok(str,","))!=NULL) { int order=0, dist=0; sscanf(tok,"%d:%d",&order,&dist); if(strchr(tok,'%')) ret=route_rect_add(ret, order, &r.lu, &r.rl, dist, 0); else for (i = 0 ; i < count ; i++) { ret=route_rect_add(ret, order, &c[i], &c[i], 0, dist); } str=NULL; } g_free(depth); return ret; } /** * @brief Retrieves the map selection for the route. */ struct map_selection * route_get_selection(struct route * this_) { struct coord *c = g_alloca(sizeof(struct coord) * (1 + g_list_length(this_->destinations))); int i = 0; GList *tmp; if (this_->pos) c[i++] = this_->pos->c; tmp = this_->destinations; while (tmp) { struct route_info *dst = tmp->data; c[i++] = dst->c; tmp = g_list_next(tmp); } return route_calc_selection(c, i, this_->vehicleprofile); } /** * @brief Destroys a list of map selections * * @param sel Start of the list to be destroyed */ void route_free_selection(struct map_selection *sel) { struct map_selection *next; while (sel) { next=sel->next; g_free(sel); sel=next; } } /* for compatibility to GFunc */ static void route_info_free_g(struct route_info *inf, void * unused) { route_info_free(inf); } static void route_clear_destinations(struct route *this_) { g_list_foreach(this_->destinations, (GFunc)route_info_free_g, NULL); g_list_free(this_->destinations); this_->destinations=NULL; } /** * @brief Sets the destination of a route * * This sets the destination of a route to the street nearest to the coordinates passed * and updates the route. * * @param this The route to set the destination for * @param dst Points to an array of coordinates to set as destinations, which will be visited in the * order in which they appear in the array (the last one is the final destination) * @param count Number of items in {@code dst}, 0 to clear all destinations * @param async If set, do routing asynchronously */ void route_set_destinations(struct route *this, struct pcoord *dst, int count, int async) { struct attr route_status; struct route_info *dsti; int i; route_status.type=attr_route_status; profile(0,NULL); route_clear_destinations(this); if (dst && count) { for (i = 0 ; i < count ; i++) { dsti=route_find_nearest_street(this->vehicleprofile, this->ms, &dst[i]); if(dsti) { route_info_distances(dsti, dst->pro); this->destinations=g_list_append(this->destinations, dsti); } } route_status.u.num=route_status_destination_set; } else { this->reached_destinations_count=0; route_status.u.num=route_status_no_destination; } callback_list_call_attr_1(this->cbl2, attr_destination, this); route_set_attr(this, &route_status); profile(1,"find_nearest_street"); /* The graph has to be destroyed and set to NULL, otherwise route_path_update() doesn't work */ route_graph_destroy(this->graph); this->graph=NULL; this->current_dst=route_get_dst(this); route_path_update(this, 1, async); profile(0,"end"); } /** * @brief Retrieves destinations from the route * * Prior to calling this method, you may want to retrieve the number of destinations by calling * {@link route_get_destination_count(struct route *)} and assigning a buffer of sufficient capacity. * * If the return value equals `count`, the buffer was either just large enough or too small to hold the * entire list of destinations; there is no way to tell from the result which is the case. * * @param this The route instance * @param pc Pointer to an array of projected coordinates which will receive the destination coordinates * @param count Capacity of `pc` * @return The number of destinations stored in `pc`, never greater than `count` */ int route_get_destinations(struct route *this, struct pcoord *pc, int count) { int ret=0; GList *l=this->destinations; while (l && ret < count) { struct route_info *dst=l->data; pc->x=dst->c.x; pc->y=dst->c.y; pc->pro=projection_mg; /* FIXME */ pc++; ret++; l=g_list_next(l); } return ret; } /** * @brief Get the destinations count for the route * * @param this The route instance * @return destination count for the route */ int route_get_destination_count(struct route *this) { return g_list_length(this->destinations); } /** * @brief Returns a description for a waypoint as (type or street_name_systematic) + (label or WayID[osm_wayid]) * * @param this The route instance * @param n The nth waypoint * @return The description */ char* route_get_destination_description(struct route *this, int n) { struct route_info *dst; struct map_rect *mr=NULL; struct item *item; struct attr attr; char *type=NULL; char *label=NULL; char *desc=NULL; if(!this->destinations) return NULL; dst=g_list_nth_data(this->destinations,n); mr=map_rect_new(dst->street->item.map, NULL); item = map_rect_get_item_byid(mr, dst->street->item.id_hi, dst->street->item.id_lo); type=g_strdup(item_to_name(dst->street->item.type)); while(item_attr_get(item, attr_any, &attr)) { if (attr.type==attr_street_name_systematic ) { g_free(type); type=attr_to_text(&attr, item->map, 1); } else if (attr.type==attr_label) { g_free(label); label=attr_to_text(&attr, item->map, 1); } else if (attr.type==attr_osm_wayid && !label) { char *tmp=attr_to_text(&attr, item->map, 1); label=g_strdup_printf("WayID %s", tmp); g_free(tmp); } } if(!label && !type) { desc=g_strdup(_("unknown street")); } else if (!label || strcmp(type, label)==0) { desc=g_strdup(type); } else { desc=g_strdup_printf("%s %s", type, label); } g_free(label); g_free(type); if (mr) map_rect_destroy(mr); return desc; } /** * @brief Start a route given set of coordinates * * @param this The route instance * @param dst The coordinate to start routing to * @param async Set to 1 to do route calculation asynchronously * @return nothing */ void route_set_destination(struct route *this, struct pcoord *dst, int async) { route_set_destinations(this, dst, dst?1:0, async); } /** * @brief Append a waypoint to the route. * * This appends a waypoint to the current route, targetting the street * nearest to the coordinates passed, and updates the route. * * @param this The route to set the destination for * @param dst Coordinates of the new waypoint * @param async: If set, do routing asynchronously */ void route_append_destination(struct route *this, struct pcoord *dst, int async) { if (dst) { struct route_info *dsti; dsti=route_find_nearest_street(this->vehicleprofile, this->ms, &dst[0]); if(dsti) { route_info_distances(dsti, dst->pro); this->destinations=g_list_append(this->destinations, dsti); } /* The graph has to be destroyed and set to NULL, otherwise route_path_update() doesn't work */ route_graph_destroy(this->graph); this->graph=NULL; this->current_dst=route_get_dst(this); route_path_update(this, 1, async); } else { route_set_destinations(this, NULL, 0, async); } } /** * @brief Remove the nth waypoint of the route * * @param this The route instance * @param n The waypoint to remove * @return nothing */ void route_remove_nth_waypoint(struct route *this, int n) { struct route_info *ri=g_list_nth_data(this->destinations, n); this->destinations=g_list_remove(this->destinations,ri); route_info_free(ri); /* The graph has to be destroyed and set to NULL, otherwise route_path_update() doesn't work */ route_graph_destroy(this->graph); this->graph=NULL; this->current_dst=route_get_dst(this); route_path_update(this, 1, 1); } void route_remove_waypoint(struct route *this) { if (this->path2) { struct route_path *path = this->path2; struct route_info *ri = this->destinations->data; this->destinations = g_list_remove(this->destinations, ri); route_info_free(ri); this->path2 = this->path2->next; route_path_destroy(path, 0); if (!this->destinations) { this->route_status=route_status_no_destination; this->reached_destinations_count=0; return; } this->reached_destinations_count++; route_graph_reset(this->graph); this->current_dst = this->destinations->data; route_graph_init(this->graph, this->current_dst, this->vehicleprofile); route_graph_compute_shortest_path(this->graph, this->vehicleprofile, this->route_graph_flood_done_cb); } } /** * @brief Gets the next route_graph_point with the specified coordinates * * @param this The route in which to search * @param c Coordinates to search for * @param last The last route graph point returned to iterate over multiple points with the same coordinates, * or {@code NULL} to return the first point * @return The point at the specified coordinates or NULL if not found */ struct route_graph_point *route_graph_get_point_next(struct route_graph *this, struct coord *c, struct route_graph_point *last) { struct route_graph_point *p; int seen=0,hashval=HASHCOORD(c); p=this->hash[hashval]; while (p) { if (p->c.x == c->x && p->c.y == c->y) { if (!last || seen) return p; if (p == last) seen=1; } p=p->hash_next; } return NULL; } /** * @brief Gets the first route_graph_point with the specified coordinates * * @param this The route in which to search * @param c Coordinates to search for * @return The point at the specified coordinates or NULL if not found */ struct route_graph_point * route_graph_get_point(struct route_graph *this, struct coord *c) { return route_graph_get_point_next(this, c, NULL); } /** * @brief Gets the last route_graph_point with the specified coordinates * * @param this The route in which to search * @param c Coordinates to search for * @return The point at the specified coordinates or NULL if not found */ static struct route_graph_point *route_graph_get_point_last(struct route_graph *this, struct coord *c) { struct route_graph_point *p,*ret=NULL; int hashval=HASHCOORD(c); p=this->hash[hashval]; while (p) { if (p->c.x == c->x && p->c.y == c->y) ret=p; p=p->hash_next; } return ret; } /** * @brief Create a new point for the route graph with the specified coordinates * * @param this The route to insert the point into * @param f The coordinates at which the point should be created * @return The point created */ static struct route_graph_point *route_graph_point_new(struct route_graph *this, struct coord *f) { int hashval; struct route_graph_point *p; hashval=HASHCOORD(f); if (debug_route) printf("p (0x%x,0x%x)\n", f->x, f->y); p=g_slice_new0(struct route_graph_point); p->hash_next=this->hash[hashval]; this->hash[hashval]=p; p->value=INT_MAX; p->dst_val = INT_MAX; p->c=*f; return p; } /** * @brief Inserts a point into the route graph at the specified coordinates * * This will insert a point into the route graph at the coordinates passed in f. * Note that the point is not yet linked to any segments. * * If the route graph already contains a point at the specified coordinates, the existing point * will be returned. * * @param this The route graph to insert the point into * @param f The coordinates at which the point should be inserted * @return The point inserted or NULL on failure */ struct route_graph_point * route_graph_add_point(struct route_graph *this, struct coord *f) { struct route_graph_point *p; p=route_graph_get_point(this,f); if (!p) p=route_graph_point_new(this,f); return p; } /** * @brief Frees all the memory used for points in the route graph passed * * @param this The route graph to delete all points from */ void route_graph_free_points(struct route_graph *this) { struct route_graph_point *curr,*next; int i; for (i = 0 ; i < HASH_SIZE ; i++) { curr=this->hash[i]; while (curr) { next=curr->hash_next; g_slice_free(struct route_graph_point, curr); curr=next; } this->hash[i]=NULL; } } /** * @brief Initializes potential destination nodes. * * This method is normally called after building a fresh route graph, or resetting an existing one. It iterates over * all potential destination nodes (i.e. all nodes which are part of the destination’s street) and initializes them: * The `dst_val` and `rhs` values are set according to their cost to reach the destination. * * @param this The route graph to initialize * @param dst The destination of the route * @param profile The vehicle profile to use for routing. This determines which ways are passable * and how their costs are calculated. */ static void route_graph_init(struct route_graph *this, struct route_info *dst, struct vehicleprofile *profile) { struct route_graph_segment *s = NULL; int val; while ((s = route_graph_get_segment(this, dst->street, s))) { val = route_value_seg(profile, NULL, s, -1); if (val != INT_MAX) { val = val*(100-dst->percent)/100; s->end->seg = s; s->end->dst_seg = s; s->end->rhs = val; s->end->dst_val = val; s->end->el = fh_insertkey(this->heap, MIN(s->end->rhs, s->end->value), s->end); } val = route_value_seg(profile, NULL, s, 1); if (val != INT_MAX) { val = val*dst->percent/100; s->start->seg = s; s->start->dst_seg = s; s->start->rhs = val; s->start->dst_val = val; s->start->el = fh_insertkey(this->heap, MIN(s->start->rhs, s->start->value), s->start); } } } /** * @brief Resets all nodes * * This iterates through all the points in the route graph, resetting them to their initial state. * The `value` (cost to reach the destination via `seg`) and `dst_val` (cost to destination if this point is the last * in the route) members of each point are reset to`INT_MAX`, the `seg` member (cheapest way to destination) is reset * to `NULL` and the `el` member (pointer to element in Fibonacci heap) is also reset to `NULL`. * * The Fibonacci heap is also cleared. Inconsistencies between `el` and Fibonacci heap membership are handled * gracefully, i.e. `el` is reset even if it is invalid, and points are removed from the heap regardless of their `el` * value. * * After this method returns, the caller should call * {@link route_graph_init(struct route_graph *, struct route_info *, struct vehicleprofile *)} to initialize potential * end points. After that a route can be calculated. * * References to elements of the route graph which were obtained prior to calling this function * remain valid after it returns. * * @param this The route graph to reset */ static void route_graph_reset(struct route_graph *this) { struct route_graph_point *curr; int i; for (i = 0 ; i < HASH_SIZE ; i++) { curr=this->hash[i]; while (curr) { curr->value=INT_MAX; curr->dst_val = INT_MAX; curr->rhs = INT_MAX; curr->seg=NULL; curr->dst_seg = NULL; curr->el=NULL; curr=curr->hash_next; } } while (fh_extractmin(this->heap)) { // no operation, just remove all items (`el` has already been reset) } } /** * @brief Returns the position of a certain field appended to a route graph segment * * This function returns a pointer to a field that is appended to a route graph * segment. * * @param seg The route graph segment the field is appended to * @param type Type of the field that should be returned * @return A pointer to a field of a certain type, or NULL if no such field is present */ void * route_segment_data_field_pos(struct route_segment_data *seg, enum attr_type type) { unsigned char *ptr; ptr = ((unsigned char*)seg) + sizeof(struct route_segment_data); if (seg->flags & AF_SPEED_LIMIT) { if (type == attr_maxspeed) return (void*)ptr; ptr += sizeof(int); } if (seg->flags & AF_SEGMENTED) { if (type == attr_offset) return (void*)ptr; ptr += sizeof(int); } if (seg->flags & AF_SIZE_OR_WEIGHT_LIMIT) { if (type == attr_vehicle_width) return (void*)ptr; ptr += sizeof(struct size_weight_limit); } if (seg->flags & AF_DANGEROUS_GOODS) { if (type == attr_vehicle_dangerous_goods) return (void*)ptr; ptr += sizeof(int); } return NULL; } /** * @brief Calculates the size of a route_segment_data struct with given flags * * @param flags The flags of the route_segment_data */ static int route_segment_data_size(int flags) { int ret=sizeof(struct route_segment_data); if (flags & AF_SPEED_LIMIT) ret+=sizeof(int); if (flags & AF_SEGMENTED) ret+=sizeof(int); if (flags & AF_SIZE_OR_WEIGHT_LIMIT) ret+=sizeof(struct size_weight_limit); if (flags & AF_DANGEROUS_GOODS) ret+=sizeof(int); return ret; } /** * @brief Checks if the route graph already contains a particular segment. * * This function compares the item IDs of both segments. If the item is segmented, the segment offset is * also compared. * * @param start The starting point of the segment * @param data The data for the segment */ int route_graph_segment_is_duplicate(struct route_graph_point *start, struct route_graph_segment_data *data) { struct route_graph_segment *s; s=start->start; while (s) { if (item_is_equal(*data->item, s->data.item)) { if (data->flags & AF_SEGMENTED) { if (RSD_OFFSET(&s->data) == data->offset) { return 1; } } else return 1; } s=s->start_next; } return 0; } /** * @brief Inserts a new segment into the route graph * * @param this The route graph to insert the segment into * @param start The graph point which should be connected to the start of this segment * @param end The graph point which should be connected to the end of this segment * @param data The segment data */ void route_graph_add_segment(struct route_graph *this, struct route_graph_point *start, struct route_graph_point *end, struct route_graph_segment_data *data) { struct route_graph_segment *s; int size; size = sizeof(struct route_graph_segment)-sizeof(struct route_segment_data)+route_segment_data_size(data->flags); s = g_slice_alloc0(size); if (!s) { printf("%s:Out of memory\n", __FUNCTION__); return; } s->start=start; s->start_next=start->start; start->start=s; s->end=end; s->end_next=end->end; end->end=s; dbg_assert(data->len >= 0); s->data.len=data->len; s->data.item=*data->item; s->data.flags=data->flags; s->data.score = data->score; if (data->flags & AF_SPEED_LIMIT) RSD_MAXSPEED(&s->data)=data->maxspeed; if (data->flags & AF_SEGMENTED) RSD_OFFSET(&s->data)=data->offset; if (data->flags & AF_SIZE_OR_WEIGHT_LIMIT) RSD_SIZE_WEIGHT(&s->data)=data->size_weight; if (data->flags & AF_DANGEROUS_GOODS) RSD_DANGEROUS_GOODS(&s->data)=data->dangerous_goods; s->next=this->route_segments; this->route_segments=s; if (debug_route) printf("l (0x%x,0x%x)-(0x%x,0x%x)\n", start->c.x, start->c.y, end->c.x, end->c.y); } /** * @brief Returns and removes one segment from a path * * @param path The path to take the segment from * @param item The item whose segment to remove * @param offset Offset of the segment within the item to remove. If the item is not segmented this should be 1. * @return The segment removed */ static struct route_path_segment *route_extract_segment_from_path(struct route_path *path, struct item *item, int offset) { int soffset; struct route_path_segment *sp = NULL, *s; s = path->path; while (s) { if (item_is_equal(s->data->item,*item)) { if (s->data->flags & AF_SEGMENTED) soffset=RSD_OFFSET(s->data); else soffset=1; if (soffset == offset) { if (sp) { sp->next = s->next; break; } else { path->path = s->next; break; } } } sp = s; s = s->next; } if (s) item_hash_remove(path->path_hash, item); return s; } /** * @brief Adds a segment and the end of a path * * @param this The path to add the segment to * @param segment The segment to add */ static void route_path_add_segment(struct route_path *this, struct route_path_segment *segment) { if (!this->path) this->path=segment; if (this->path_last) this->path_last->next=segment; this->path_last=segment; } /** * @brief Adds a two coordinate line to a path * * This adds a new line to a path, creating a new segment for it. * * @param this The path to add the item to * @param start coordinate to add to the start of the item. If none should be added, make this NULL. * @param end coordinate to add to the end of the item. If none should be added, make this NULL. * @param len The length of the item */ static void route_path_add_line(struct route_path *this, struct coord *start, struct coord *end, int len) { int ccnt=2; struct route_path_segment *segment; int seg_size,seg_dat_size; dbg(lvl_debug,"line from 0x%x,0x%x-0x%x,0x%x", start->x, start->y, end->x, end->y); seg_size=sizeof(*segment) + sizeof(struct coord) * ccnt; seg_dat_size=sizeof(struct route_segment_data); segment=g_malloc0(seg_size + seg_dat_size); segment->data=(struct route_segment_data *)((char *)segment+seg_size); segment->ncoords=ccnt; segment->direction=0; segment->c[0]=*start; segment->c[1]=*end; segment->data->len=len; route_path_add_segment(this, segment); } /** * @brief Inserts a new segment into the path * * This function adds a new segment to the route path. The segment is copied from the route graph. If * `rgs` is part of a segmented item, only `rgs` will be added to the route path, not the other segments. * * The function can be sped up by passing an old path already containing this segment in oldpath - * the segment will then be extracted from this old path. Please note that in this case the direction * parameter has no effect. * * @param this The path to add the item to * @param oldpath Old path containing the segment to be added. Speeds up the function, but can be NULL. * @param rgs Segment of the route graph that should be "copied" to the route path * @param dir Order in which to add the coordinates. See route_path_add_item() * @param pos Information about start point if this is the first segment * @param dst Information about end point if this is the last segment */ static int route_path_add_item_from_graph(struct route_path *this, struct route_path *oldpath, struct route_graph_segment *rgs, int dir, struct route_info *pos, struct route_info *dst) { struct route_path_segment *segment=NULL; int i, ccnt, extra=0, ret=0; struct coord *c,*cd,ca[2048]; int offset=1; int seg_size,seg_dat_size; int len=rgs->data.len; if (rgs->data.flags & AF_SEGMENTED) offset=RSD_OFFSET(&rgs->data); dbg(lvl_debug,"enter (0x%x,0x%x) dir=%d pos=%p dst=%p", rgs->data.item.id_hi, rgs->data.item.id_lo, dir, pos, dst); if (oldpath) { segment=item_hash_lookup(oldpath->path_hash, &rgs->data.item); if (segment && segment->direction == dir) { segment = route_extract_segment_from_path(oldpath, &rgs->data.item, offset); if (segment) { ret=1; if (!pos) goto linkold; } g_free(segment); } } if (pos) { if (dst) { extra=2; if (dst->lenneg >= pos->lenneg) { dir=1; ccnt=dst->pos-pos->pos; c=pos->street->c+pos->pos+1; len=dst->lenneg-pos->lenneg; } else { dir=-1; ccnt=pos->pos-dst->pos; c=pos->street->c+dst->pos+1; len=pos->lenneg-dst->lenneg; } } else { extra=1; dbg(lvl_debug,"pos dir=%d", dir); dbg(lvl_debug,"pos pos=%d", pos->pos); dbg(lvl_debug,"pos count=%d", pos->street->count); if (dir > 0) { c=pos->street->c+pos->pos+1; ccnt=pos->street->count-pos->pos-1; len=pos->lenpos; } else { c=pos->street->c; ccnt=pos->pos+1; len=pos->lenneg; } } pos->dir=dir; } else if (dst) { extra=1; dbg(lvl_debug,"dst dir=%d", dir); dbg(lvl_debug,"dst pos=%d", dst->pos); if (dir > 0) { c=dst->street->c; ccnt=dst->pos+1; len=dst->lenneg; } else { c=dst->street->c+dst->pos+1; ccnt=dst->street->count-dst->pos-1; len=dst->lenpos; } } else { ccnt=item_coord_get_within_range(&rgs->data.item, ca, 2047, &rgs->start->c, &rgs->end->c); c=ca; } seg_size=sizeof(*segment) + sizeof(struct coord) * (ccnt + extra); seg_dat_size=route_segment_data_size(rgs->data.flags); segment=g_malloc0(seg_size + seg_dat_size); segment->data=(struct route_segment_data *)((char *)segment+seg_size); segment->direction=dir; cd=segment->c; if (pos && (c[0].x != pos->lp.x || c[0].y != pos->lp.y)) *cd++=pos->lp; if (dir < 0) c+=ccnt-1; for (i = 0 ; i < ccnt ; i++) { *cd++=*c; c+=dir; } segment->ncoords+=ccnt; if (dst && (cd[-1].x != dst->lp.x || cd[-1].y != dst->lp.y)) *cd++=dst->lp; segment->ncoords=cd-segment->c; if (segment->ncoords <= 1) { g_free(segment); return 1; } /* We check if the route graph segment is part of a roundabout here, because this * only matters for route graph segments which form parts of the route path */ if (!(rgs->data.flags & AF_ROUNDABOUT)) { // We identified this roundabout earlier route_check_roundabout(rgs, 13, (dir < 1), NULL); } memcpy(segment->data, &rgs->data, seg_dat_size); linkold: segment->data->len=len; segment->next=NULL; item_hash_insert(this->path_hash, &rgs->data.item, segment); route_path_add_segment(this, segment); return ret; } /** * @brief Destroys all segments of a route graph * * @param this The graph to destroy all segments from */ void route_graph_free_segments(struct route_graph *this) { struct route_graph_segment *curr,*next; int size; curr=this->route_segments; while (curr) { next=curr->next; size = sizeof(struct route_graph_segment)-sizeof(struct route_segment_data)+route_segment_data_size(curr->data.flags); g_slice_free1(size, curr); curr=next; } this->route_segments=NULL; } /** * @brief Destroys a route graph * * @param this The route graph to be destroyed */ static void route_graph_destroy(struct route_graph *this) { if (this) { route_graph_build_done(this, 1); route_graph_free_points(this); route_graph_free_segments(this); fh_deleteheap(this->heap); g_free(this); } } /** * @brief Returns the estimated speed on a segment, or 0 for an impassable segment * * This function returns the estimated speed to be driven on a segment, calculated as follows: *
    *
  • Initially the route weight of the vehicle profile for the given item type is used. If the * item type does not have a route weight in the vehicle profile given, it is considered impassable * and 0 is returned.
    • *
  • If the {@code maxspeed} attribute of the segment's item is set, either it or the previous * speed estimate for the segment is used, as governed by the vehicle profile's * {@code maxspeed_handling} attribute.
    • *
  • If a traffic distortion is present, its {@code maxspeed} is taken into account in a similar * manner. Unlike the regular {@code maxspeed}, a {@code maxspeed} resulting from a traffic * distortion is always considered if it limits the speed, regardless of {@code maxspeed_handling}. *
    • *
  • Access restrictions for dangerous goods, size or weight are evaluated, and 0 is returned if * the given vehicle profile violates one of them.
    • *
* * @param profile The routing preferences * @param over The segment which is passed * @param dist A traffic distortion if applicable, or {@code NULL} * @return The estimated speed in km/h, or 0 if the segment is impassable */ static int route_seg_speed(struct vehicleprofile *profile, struct route_segment_data *over, struct route_traffic_distortion *dist) { struct roadprofile *roadprofile=vehicleprofile_get_roadprofile(profile, over->item.type); int speed,maxspeed; if (!roadprofile || !roadprofile->route_weight) return 0; speed=roadprofile->route_weight; if (profile->maxspeed_handling != maxspeed_ignore) { if (over->flags & AF_SPEED_LIMIT) { maxspeed=RSD_MAXSPEED(over); if (profile->maxspeed_handling == maxspeed_enforce) speed=maxspeed; } else maxspeed=INT_MAX; if (dist && maxspeed > dist->maxspeed) maxspeed=dist->maxspeed; if (maxspeed != INT_MAX && (profile->maxspeed_handling != maxspeed_restrict || maxspeed < speed)) speed=maxspeed; } if (over->flags & AF_DANGEROUS_GOODS) { if (profile->dangerous_goods & RSD_DANGEROUS_GOODS(over)) return 0; } if (over->flags & AF_SIZE_OR_WEIGHT_LIMIT) { struct size_weight_limit *size_weight=&RSD_SIZE_WEIGHT(over); if (size_weight->width != -1 && profile->width != -1 && profile->width > size_weight->width) return 0; if (size_weight->height != -1 && profile->height != -1 && profile->height > size_weight->height) return 0; if (size_weight->length != -1 && profile->length != -1 && profile->length > size_weight->length) return 0; if (size_weight->weight != -1 && profile->weight != -1 && profile->weight > size_weight->weight) return 0; if (size_weight->axle_weight != -1 && profile->axle_weight != -1 && profile->axle_weight > size_weight->axle_weight) return 0; } return speed; } /** * @brief Returns the time needed to travel along a segment, or {@code INT_MAX} if the segment is impassable. * * This function returns the time needed to travel along the entire length of {@code over} in * tenths of seconds. Restrictions for dangerous goods, weight or size are taken into account. * Traffic distortions are also taken into account if a valid {@code dist} argument is given. * * @param profile The vehicle profile (routing preferences) * @param over The segment which is passed * @param dist A traffic distortion if applicable, or {@code NULL} * @return The time needed in tenths of seconds */ static int route_time_seg(struct vehicleprofile *profile, struct route_segment_data *over, struct route_traffic_distortion *dist) { int speed=route_seg_speed(profile, over, dist); if (!speed) return INT_MAX; return over->len*36/speed+(dist ? dist->delay : 0); } /** * @brief Returns the traffic distortion for a segment. * * If multiple traffic distortions match a segment, the return value will report the lowest speed limit * and greatest delay of all matching segments. * * @param seg The segment for which the traffic distortion is to be returned * @param dir The direction of `seg` for which to return traffic distortions. Positive values indicate * travel in the direction of the segment, negative values indicate travel against it. * @param profile The current vehicle profile * @param ret Points to a {@code struct route_traffic_distortion}, whose members will be filled with the * distortion data * * @return true if a traffic distortion was found, 0 if not */ static int route_get_traffic_distortion(struct route_graph_segment *seg, int dir, struct vehicleprofile *profile, struct route_traffic_distortion *ret) { struct route_graph_point *start=seg->start; struct route_graph_point *end=seg->end; struct route_graph_segment *tmp,*found=NULL; struct route_traffic_distortion result; if (!dir) { dbg(lvl_warning, "dir is zero, assuming positive"); dir = 1; } result.delay = 0; result.maxspeed = INT_MAX; for (tmp = start->start; tmp; tmp = tmp->start_next) { if (tmp->data.item.type == type_traffic_distortion && tmp->start == start && tmp->end == end) { if ((tmp->data.flags & (dir > 0 ? profile->flags_forward_mask : profile->flags_reverse_mask)) != profile->flags) continue; if (tmp->data.len > result.delay) result.delay = tmp->data.len; if ((tmp->data.flags & AF_SPEED_LIMIT) && (RSD_MAXSPEED(&tmp->data) < result.maxspeed)) result.maxspeed = RSD_MAXSPEED(&tmp->data); found=tmp; } } for (tmp = start->end; tmp; tmp = tmp->end_next) { if (tmp->data.item.type == type_traffic_distortion && tmp->end == start && tmp->start == end) { if ((tmp->data.flags & (dir < 0 ? profile->flags_forward_mask : profile->flags_reverse_mask)) != profile->flags) continue; if (tmp->data.len > result.delay) result.delay = tmp->data.len; if ((tmp->data.flags & AF_SPEED_LIMIT) && (RSD_MAXSPEED(&tmp->data) < result.maxspeed)) result.maxspeed = RSD_MAXSPEED(&tmp->data); found=tmp; } } if (found) { ret->delay = result.delay; ret->maxspeed = result.maxspeed; return 1; } return 0; } static int route_through_traffic_allowed(struct vehicleprofile *profile, struct route_graph_segment *seg) { return (seg->data.flags & AF_THROUGH_TRAFFIC_LIMIT) == 0; } /** * @brief Returns the "cost" of traveling along segment `over` in direction `dir` * * Cost is relative to time, indicated in tenths of seconds. * * This function considers traffic distortions as well as penalties. If the segment is impassable due to traffic * distortions or restrictions, `INT_MAX` is returned in order to prevent use of this segment for routing. * * If `from` is specified, it must be the point at which we leave the segment (`over->end` if `dir` is positive, * `over->start` if `dir` is negative); anything else will produce invalid results. If `from` is non-NULL, additional * checks are done on `from->seg` (the next segment to follow after `over`): * \li If `from->seg` equals `over` (indicating that, after traversing `over` in direction `dir`, we would immediately * traverse it again in the opposite direction), `INT_MAX` is returned. * \li If `over` loops back to itself (i.e. its `start` and `end` members are equal), `INT_MAX` is returned. * \li Otherwise, if `over` does not allow through traffic but `from->seg` does, the through traffic penalty of the * vehicle profile (`profile`) is applied. * * @param profile The routing preferences * @param from The point currently being visited (or NULL), see description * @param over The segment we are using * @param dir The direction of segment which we are traveling. Positive values indicate we are traveling in the * direction of the segment (from `over->start` to `over->end`), negative values indicate we are traveling in the * opposite direction. Values of +2 or -2 cause the function to ignore traffic distortions. * * @return The "cost" needed to travel along the segment */ /* FIXME `from` as a name is highly misleading, find a better one */ static int route_value_seg(struct vehicleprofile *profile, struct route_graph_point *from, struct route_graph_segment *over, int dir) { int ret; struct route_traffic_distortion dist,*distp=NULL; if (!dir) { dbg(lvl_warning, "dir is zero, assuming positive"); dir = 1; } if (from && (over->start == over->end)) return INT_MAX; if ((over->data.flags & (dir >= 0 ? profile->flags_forward_mask : profile->flags_reverse_mask)) != profile->flags) return INT_MAX; if (dir > 0 && (over->start->flags & RP_TURN_RESTRICTION)) return INT_MAX; if (dir < 0 && (over->end->flags & RP_TURN_RESTRICTION)) return INT_MAX; if (from && from->seg == over) return INT_MAX; if (over->data.item.type == type_traffic_distortion) return INT_MAX; if ((over->start->flags & RP_TRAFFIC_DISTORTION) && (over->end->flags & RP_TRAFFIC_DISTORTION) && route_get_traffic_distortion(over, dir, profile, &dist) && dir != 2 && dir != -2) { /* we have a traffic distortion */ distp=&dist; } ret=route_time_seg(profile, &over->data, distp); if (ret == INT_MAX) return ret; if (!route_through_traffic_allowed(profile, over) && from && from->seg && route_through_traffic_allowed(profile, from->seg)) ret+=profile->through_traffic_penalty; return ret; } /** * @brief Whether two route graph segments match. * * Two segments match if both start and end at the exact same points. Other points are not considered. * * @param s1 The first segment * @param s2 The second segment * @return true if both segments match, false if not */ static int route_graph_segment_match(struct route_graph_segment *s1, struct route_graph_segment *s2) { if (!s1 || !s2) return 0; return (s1->start->c.x == s2->start->c.x && s1->start->c.y == s2->start->c.y && s1->end->c.x == s2->end->c.x && s1->end->c.y == s2->end->c.y); } /** * @brief Adds two route values with protection against integer overflows. * * Unlike regular addition, this function is safe to use if one of the two arguments is `INT_MAX` * (which Navit uses to express that a segment cannot be traversed or a point cannot be reached): * If any of the two arguments is `INT_MAX`, then `INT_MAX` is returned; else the sum of the two * arguments is returned. * * Note that this currently does not cover cases in which both arguments are less than `INT_MAX` but add * up to `val1 + val2 >= INT_MAX`. With Navit’s internal cost definition, `INT_MAX` (2^31) is equivalent * to approximately 7 years, making this unlikely to become a real issue. */ static int route_value_add(int val1, int val2) { if (val1 == INT_MAX) return INT_MAX; if (val2 == INT_MAX) return INT_MAX; return val1 + val2; } /** * @brief Updates the lookahead value of a point in the route graph and updates its heap membership. * * This recalculates the lookahead value (the `rhs` member) of point `p`, based on the `value` of each neighbor and the * cost to reach that neighbor. If the resulting `p->rhs` differs from `p->value`, `p` is inserted into `heap` using * the lower of the two as its key (if `p` is already a member of `heap`, its key is changed accordingly). If the * resulting `p->rhs` is equal to `p->value` and `p` is a member of `heap`, it is removed. * * This is part of a modified LPA* implementation. * * @param profile The vehicle profile to use for routing. This determines which ways are passable and how their costs * are calculated. * @param p The point to evaluate * @param heap The heap */ static void route_graph_point_update(struct vehicleprofile *profile, struct route_graph_point * p, struct fibheap * heap) { struct route_graph_segment *s = NULL; int new, val; p->rhs = p->dst_val; p->seg = p->dst_seg; for (s = p->start; s; s = s->start_next) { /* Iterate over all the segments leading away from our point */ val = route_value_seg(profile, s->end, s, 1); if (val != INT_MAX && s->end->seg && item_is_equal(s->data.item, s->end->seg->data.item)) { if (profile->turn_around_penalty2) val += profile->turn_around_penalty2; else val = INT_MAX; } if (val != INT_MAX) { new = route_value_add(val, s->end->value); if (new < p->rhs) { p->rhs = new; p->seg = s; } } } for (s = p->end; s; s = s->end_next) { /* Iterate over all the segments leading towards our point */ val = route_value_seg(profile, s->start, s, -1); if (val != INT_MAX && s->start->seg && item_is_equal(s->data.item, s->start->seg->data.item)) { if (profile->turn_around_penalty2) val += profile->turn_around_penalty2; else val = INT_MAX; } if (val != INT_MAX) { new = route_value_add(val, s->start->value); if (new < p->rhs) { p->rhs = new; p->seg = s; } } } if (p->el) { /* Due to a limitation of the Fibonacci heap implementation, which causes fh_replacekey() to fail if the new * key is greater than the current one, we always remove the point from the heap (and, if locally inconsistent, * re-add it afterwards). */ fh_delete(heap, p->el); p->el = NULL; } if (p->rhs != p->value) /* The point is locally inconsistent, add (or re-add) it to the heap */ p->el = fh_insertkey(heap, MIN(p->rhs, p->value), p); } /** * @brief Expands (i.e. calculates the costs for) the points on the route graph’s heap. * * This calculates the cost for every point on the route graph’s heap, as well as any neighbors affected by the cost * change, and sets the next segment. * * This is part of a modified LPA* implementation. * * @param graph The route graph * @param profile The vehicle profile to use for routing. This determines which ways are passable and how their costs * are calculated. * @param cb The callback function to call when flooding is complete (can be NULL) */ static void route_graph_compute_shortest_path(struct route_graph * graph, struct vehicleprofile * profile, struct callback *cb) { struct route_graph_point *p_min; struct route_graph_segment *s = NULL; while (!route_graph_is_path_computed(graph) && (p_min = fh_extractmin(graph->heap))) { p_min->el = NULL; if (p_min->value > p_min->rhs) /* cost has decreased, update point value */ p_min->value = p_min->rhs; else { /* cost has increased, re-evaluate */ p_min->value = INT_MAX; route_graph_point_update(profile, p_min, graph->heap); } /* in any case, update rhs of predecessors (nodes from which we can reach p_min via a single segment) */ for (s = p_min->start; s; s = s->start_next) if ((s->start == s->end) || (s->data.item.type < route_item_first) || (s->data.item.type > route_item_last)) continue; else if (route_value_seg(profile, NULL, s, -2) != INT_MAX) route_graph_point_update(profile, s->end, graph->heap); for (s = p_min->end; s; s = s->end_next) if ((s->start == s->end) || (s->data.item.type < route_item_first) || (s->data.item.type > route_item_last)) continue; else if (route_value_seg(profile, NULL, s, 2) != INT_MAX) route_graph_point_update(profile, s->start, graph->heap); } if (cb) callback_call_0(cb); } /** * @brief Sets or clears a traffic distortion for a segment. * * This sets a delay (setting speed is not supported) or clears an existing traffic distortion. * Note that, although setting a speed is not supported, calling this function with a delay of 0 * will also clear an existing speed constraint. * * @param this The route graph * @param seg The segment to which the traffic distortion applies * @param delay Delay in tenths of a second, or 0 to clear an existing traffic distortion */ static void route_graph_set_traffic_distortion(struct route_graph *this, struct route_graph_segment *seg, int delay) { struct route_graph_point *start=NULL; struct route_graph_segment *s; while ((start=route_graph_get_point_next(this, &seg->start->c, start))) { s=start->start; while (s) { if (route_graph_segment_match(s, seg)) { if (s->data.item.type != type_none && s->data.item.type != type_traffic_distortion && delay) { struct route_graph_segment_data data; struct item item; memset(&data, 0, sizeof(data)); memset(&item, 0, sizeof(item)); item.type=type_traffic_distortion; data.item=&item; data.len=delay; data.flags = seg->data.flags & AF_DISTORTIONMASK; s->start->flags |= RP_TRAFFIC_DISTORTION; s->end->flags |= RP_TRAFFIC_DISTORTION; route_graph_add_segment(this, s->start, s->end, &data); } else if (s->data.item.type == type_traffic_distortion && !delay) { s->data.item.type = type_none; } } s=s->start_next; } } } /** * @brief Adds a traffic distortion item to the route graph * * If `update` is true, the end points of the traffic distortion will have their cost recalculated. Set this to true * for a partial recalculation of an existing route, false when initially building the route graph. * * @param this The route graph to add to * @param profile The vehicle profile to use for cost calculations * @param item The item to add, must be of {@code type_traffic_distortion} * @param update Whether to update the end points */ static void route_graph_add_traffic_distortion(struct route_graph *this, struct vehicleprofile *profile, struct item *item, int update) { struct route_graph_point *s_pnt,*e_pnt; struct coord c,l; struct attr flags_attr, delay_attr, maxspeed_attr; struct route_graph_segment_data data; data.item=item; data.len=0; data.offset=1; data.maxspeed = INT_MAX; item_attr_rewind(item); if (item_attr_get(item, attr_flags, &flags_attr)) data.flags = flags_attr.u.num & AF_DISTORTIONMASK; else data.flags = 0; item_coord_rewind(item); if (item_coord_get(item, &l, 1)) { s_pnt=route_graph_add_point(this,&l); while (item_coord_get(item, &c, 1)) { l=c; } e_pnt=route_graph_add_point(this,&l); s_pnt->flags |= RP_TRAFFIC_DISTORTION; e_pnt->flags |= RP_TRAFFIC_DISTORTION; item_attr_rewind(item); if (item_attr_get(item, attr_maxspeed, &maxspeed_attr)) { data.flags |= AF_SPEED_LIMIT; data.maxspeed=maxspeed_attr.u.num; } item_attr_rewind(item); if (item_attr_get(item, attr_delay, &delay_attr)) data.len=delay_attr.u.num; route_graph_add_segment(this, s_pnt, e_pnt, &data); if (update) { if (!(data.flags & AF_ONEWAYREV)) route_graph_point_update(profile, s_pnt, this->heap); if (!(data.flags & AF_ONEWAY)) route_graph_point_update(profile, e_pnt, this->heap); } } } /** * @brief Removes a traffic distortion item from the route graph * * Removing a traffic distortion which is not in the graph is a no-op. * * @param this The route graph to remove from * @param profile The vehicle profile to use for cost calculations * @param item The item to remove, must be of {@code type_traffic_distortion} */ static void route_graph_remove_traffic_distortion(struct route_graph *this, struct vehicleprofile *profile, struct item *item) { struct route_graph_point *s_pnt = NULL, *e_pnt = NULL; struct coord c, l; struct route_graph_segment *curr; item_coord_rewind(item); if (item_coord_get(item, &l, 1)) { s_pnt = route_graph_get_point(this, &l); while (item_coord_get(item, &c, 1)) l = c; e_pnt = route_graph_get_point(this, &l); } if (s_pnt && e_pnt) { #if 1 curr = s_pnt->start; s_pnt->flags &= ~RP_TRAFFIC_DISTORTION; for (curr = s_pnt->start; curr; curr = curr->start_next) { if ((curr->end == e_pnt) && item_is_equal(curr->data.item, *item)) curr->data.item.type = type_none; else if (curr->data.item.type == type_traffic_distortion) s_pnt->flags |= RP_TRAFFIC_DISTORTION; } e_pnt->flags &= ~RP_TRAFFIC_DISTORTION; for (curr = e_pnt->end; curr; curr = curr->end_next) if (curr->data.item.type == type_traffic_distortion) e_pnt->flags |= RP_TRAFFIC_DISTORTION; #else struct route_graph_segment *found = NULL, *prev; /* this frees up memory but is slower */ /* remove from global list */ curr = this->route_segments; prev = NULL; while (curr && !found) { if ((curr->start == s_pnt) && (curr->end == e_pnt) && (curr->data.item == item)) { if (prev) prev->next = curr->next; else this->route_segments = curr->next; found = curr; } else { prev = curr; curr = prev->next; } } if (!found) return; /* remove from s_pnt list */ curr = s_pnt->start; prev = NULL; s_pnt->flags &= ~RP_TRAFFIC_DISTORTION; while (curr) { if (curr == found) { if (prev) prev->start_next = curr->start_next; else s_pnt->start = curr->start_next; } else { if (curr->data.item.type == type_traffic_distortion) s_pnt->flags |= RP_TRAFFIC_DISTORTION; prev = curr; } curr = prev->start_next; } /* remove from e_pnt list */ curr = e_pnt->end; prev = NULL; e_pnt->flags &= ~RP_TRAFFIC_DISTORTION; while (curr) { if (curr == found) { if (prev) prev->end_next = curr->end_next; else s_pnt->end = curr->end_next; } else { if (curr->data.item.type == type_traffic_distortion) e_pnt->flags |= RP_TRAFFIC_DISTORTION; prev = curr; } curr = prev->end_next; } size = sizeof(struct route_graph_segment) - sizeof(struct route_segment_data) + route_segment_data_size(found->data.flags); g_slice_free1(size, found); #endif /* TODO figure out if we need to update both points */ route_graph_point_update(profile, s_pnt, this->heap); route_graph_point_update(profile, e_pnt, this->heap); } } /** * @brief Changes a traffic distortion item in the route graph * * Attempting to change an idem which is not in the route graph will add it. * * @param this The route graph to change * @param profile The vehicle profile to use for cost calculations * @param item The item to change, must be of {@code type_traffic_distortion} */ static void route_graph_change_traffic_distortion(struct route_graph *this, struct vehicleprofile *profile, struct item *item) { /* TODO is there a more elegant way of doing this? */ route_graph_remove_traffic_distortion(this, profile, item); route_graph_add_traffic_distortion(this, profile, item, 1); } /** * @brief Adds a turn restriction item to the route graph * * @param this The route graph to add to * @param item The item to add, must be of `type_street_turn_restriction_no` or `type_street_turn_restriction_only` */ void route_graph_add_turn_restriction(struct route_graph *this, struct item *item) { struct route_graph_point *pnt[4]; struct coord c[5]; int i,count; struct route_graph_segment_data data; item_coord_rewind(item); count=item_coord_get(item, c, 5); if (count != 3 && count != 4) { dbg(lvl_debug,"wrong count %d",count); return; } if (count == 4) return; for (i = 0 ; i < count ; i++) pnt[i]=route_graph_add_point(this,&c[i]); dbg(lvl_debug,"%s: (0x%x,0x%x)-(0x%x,0x%x)-(0x%x,0x%x) %p-%p-%p",item_to_name(item->type),c[0].x,c[0].y,c[1].x,c[1].y, c[2].x,c[2].y,pnt[0],pnt[1],pnt[2]); data.item=item; data.flags=0; data.len=0; data.score = 0; route_graph_add_segment(this, pnt[0], pnt[1], &data); route_graph_add_segment(this, pnt[1], pnt[2], &data); #if 1 if (count == 4) { pnt[1]->flags |= RP_TURN_RESTRICTION; pnt[2]->flags |= RP_TURN_RESTRICTION; route_graph_add_segment(this, pnt[2], pnt[3], &data); } else pnt[1]->flags |= RP_TURN_RESTRICTION; #endif } /** * @brief Adds an item to the route graph * * This adds an item (e.g. a street) to the route graph, creating as many segments as needed for a * segmented item. * * @param this The route graph to add to * @param item The item to add * @param profile The vehicle profile currently in use */ static void route_graph_add_street(struct route_graph *this, struct item *item, struct vehicleprofile *profile) { #ifdef AVOID_FLOAT int len=0; #else double len=0; #endif int segmented = 0; struct roadprofile *roadp; int default_flags_value = AF_ALL; int *default_flags; struct route_graph_point *s_pnt,*e_pnt; /* Start and end point */ struct coord c,l; /* Current and previous point */ struct attr attr; struct route_graph_segment_data data; data.flags=0; data.offset=1; data.maxspeed=-1; data.item=item; roadp = vehicleprofile_get_roadprofile(profile, item->type); if (!roadp) { /* Don't include any roads that don't have a road profile in our vehicle profile */ return; } item_coord_rewind(item); if (item_coord_get(item, &l, 1)) { if (!(default_flags = item_get_default_flags(item->type))) default_flags = &default_flags_value; item_attr_rewind(item); if (item_attr_get(item, attr_flags, &attr)) { data.flags = attr.u.num; segmented = (data.flags & AF_SEGMENTED); } else data.flags = *default_flags; item_attr_rewind(item); if ((data.flags & AF_SPEED_LIMIT) && (item_attr_get(item, attr_maxspeed, &attr))) data.maxspeed = attr.u.num; if (data.flags & AF_DANGEROUS_GOODS) { item_attr_rewind(item); if (item_attr_get(item, attr_vehicle_dangerous_goods, &attr)) data.dangerous_goods = attr.u.num; else data.flags &= ~AF_DANGEROUS_GOODS; } if (data.flags & AF_SIZE_OR_WEIGHT_LIMIT) { item_attr_rewind(item); if (item_attr_get(item, attr_vehicle_width, &attr)) data.size_weight.width=attr.u.num; else data.size_weight.width=-1; item_attr_rewind(item); if (item_attr_get(item, attr_vehicle_height, &attr)) data.size_weight.height=attr.u.num; else data.size_weight.height=-1; item_attr_rewind(item); if (item_attr_get(item, attr_vehicle_length, &attr)) data.size_weight.length=attr.u.num; else data.size_weight.length=-1; item_attr_rewind(item); if (item_attr_get(item, attr_vehicle_weight, &attr)) data.size_weight.weight=attr.u.num; else data.size_weight.weight=-1; item_attr_rewind(item); if (item_attr_get(item, attr_vehicle_axle_weight, &attr)) data.size_weight.axle_weight=attr.u.num; else data.size_weight.axle_weight=-1; } s_pnt=route_graph_add_point(this,&l); if (!segmented) { while (item_coord_get(item, &c, 1)) { len+=transform_distance(map_projection(item->map), &l, &c); l=c; } e_pnt=route_graph_add_point(this,&l); dbg_assert(len >= 0); data.len=len; if (!route_graph_segment_is_duplicate(s_pnt, &data)) route_graph_add_segment(this, s_pnt, e_pnt, &data); } else { int isseg,rc; int sc = 0; do { isseg = item_coord_is_node(item); rc = item_coord_get(item, &c, 1); if (rc) { len+=transform_distance(map_projection(item->map), &l, &c); l=c; if (isseg) { e_pnt=route_graph_add_point(this,&l); data.len=len; if (!route_graph_segment_is_duplicate(s_pnt, &data)) route_graph_add_segment(this, s_pnt, e_pnt, &data); data.offset++; s_pnt=route_graph_add_point(this,&l); len = 0; } } } while(rc); e_pnt=route_graph_add_point(this,&l); dbg_assert(len >= 0); sc++; data.len=len; if (!route_graph_segment_is_duplicate(s_pnt, &data)) route_graph_add_segment(this, s_pnt, e_pnt, &data); } } } /** * @brief Gets the next route_graph_segment belonging to the specified street * * @param graph The route graph in which to search * @param sd The street to search for * @param last The last route graph segment returned to iterate over multiple segments of the same * item. If {@code NULL}, the first matching segment will be returned. * * @return The route graph segment, or {@code NULL} if none was found. */ static struct route_graph_segment *route_graph_get_segment(struct route_graph *graph, struct street_data *sd, struct route_graph_segment *last) { struct route_graph_point *start=NULL; struct route_graph_segment *s; int seen=0; while ((start=route_graph_get_point_next(graph, &sd->c[0], start))) { s=start->start; while (s) { if (item_is_equal(sd->item, s->data.item)) { if (!last || seen) return s; if (last == s) seen=1; } s=s->start_next; } } return NULL; } /** * @brief Whether cost (re)calculation of route graph points has reached the start point * * This method serves as the exit criterion for cost calculation in our LPA* implementation. When it returns true, it * means that calculation of node cost has proceeded far enough to determine the cost of, and cheapest path from, the * start point. * * The current implementation returns true only when the heap is empty, i.e. all points have been calculated. This is * not optimal in terms of efficiency, as the cost of the start point and the cheapest path from there no longer * change during the last few cycles. Future versions may report true before the heap is completely empty, as soon as * the cost of the start point and the cheapest path are final. However, this needs to be considered for recalculations * which happen when the vehicle leaves the cheapest path: right now, any point in the route graph has its final cost * and cheapest path, thus no recalculation is needed if the vehicle leaves the cheapest path. In the future, however, * a (partial) recalculation may be needed if the vehicle deviates from the cheapest path. * * @param this_ The route graph * * @return true if calculation is complete, false if not */ static int route_graph_is_path_computed(struct route_graph *this_) { /* TODO refine exit criterion */ if (!fh_min(this_->heap)) return 1; else return 0; } /** * @brief Triggers partial recalculation of the route, based on the existing route graph. * * This is currently used when traffic distortions have been added, changed or removed. Future versions may also use * it if the current position has changed to a portion of the route graph which has not been flooded (which is * currently not necessary because the route graph is always flooded completely). * * This tends to be faster than full recalculation, as only a subset of all points in the graph needs to be evaluated. * * If segment costs have changed (as is the case with traffic distortions), all affected segments must have been added * to, removed from or updated in the route graph before this method is called. * * After recalculation, the route path is updated. * * The function uses a modified LPA* algorithm for recalculations. Most modifications were made for compatibility with * the old routing algorithm: * \li The heuristic is always assumed to be zero (which would turn A* into Dijkstra, formerly the basis of the routing * algorithm, and makes our keys one-dimensional) * \li Currently, each pass evaluates all locally inconsistent points, leaving an empty heap at the end (though this * may change in the future). * * @param this_ The route */ /* TODO This is absolutely not thread-safe and will wreak havoc if run concurrently with route_graph_flood(). This is * not an issue as long as the two never overlap: Currently both this function and route_graph_flood() run without * interruption until they finish, and are both on the main thread. If that changes, we need to revisit this. */ void route_recalculate_partial(struct route *this_) { struct attr route_status; /* do nothing if we don’t have a route graph */ if (!route_has_graph(this_)) return; /* if the route graph is still being built, it will be calculated from scratch after that, nothing to do here */ if (this_->graph->busy) return; /* exit if there is no need to recalculate */ if (route_graph_is_path_computed(this_->graph)) return; route_status.type = attr_route_status; route_status.u.num = route_status_building_graph; route_set_attr(this_, &route_status); printf("Expanding points which have changed\n"); route_graph_compute_shortest_path(this_->graph, this_->vehicleprofile, NULL); printf("Point expansion complete, recalculating route path\n"); route_path_update_done(this_, 0); } /** * @brief Starts an "offroad" path * * This starts a path that is not located on a street. It creates a new route path * adding only one segment, that leads from pos to dest, and which is not associated with an item. * * @param this Not used * @param pos The starting position for the new path * @param dst The destination of the new path * @param dir Not used * @return The new path */ static struct route_path *route_path_new_offroad(struct route_graph *this, struct route_info *pos, struct route_info *dst) { struct route_path *ret; ret=g_new0(struct route_path, 1); ret->in_use=1; ret->path_hash=item_hash_new(); route_path_add_line(ret, &pos->c, &dst->c, pos->lenextra+dst->lenextra); ret->updated=1; return ret; } /** * @brief Returns a coordinate at a given distance * * This function returns the coordinate, where the user will be if he * follows the current route for a certain distance. * * @param this_ The route we're driving upon * @param dist The distance in meters * @return The coordinate where the user will be in that distance */ struct coord route_get_coord_dist(struct route *this_, int dist) { int d,l,i,len; int dx,dy; double frac; struct route_path_segment *cur; struct coord ret; enum projection pro=route_projection(this_); struct route_info *dst=route_get_dst(this_); d = dist; if (!this_->path2 || pro == projection_none) { return this_->pos->c; } ret = this_->pos->c; cur = this_->path2->path; while (cur) { if (cur->data->len < d) { d -= cur->data->len; } else { for (i=0; i < (cur->ncoords-1); i++) { l = d; len = (int)transform_polyline_length(pro, (cur->c + i), 2); d -= len; if (d <= 0) { // We interpolate a bit here... frac = (double)l / len; dx = (cur->c + i + 1)->x - (cur->c + i)->x; dy = (cur->c + i + 1)->y - (cur->c + i)->y; ret.x = (cur->c + i)->x + (frac * dx); ret.y = (cur->c + i)->y + (frac * dy); return ret; } } return cur->c[(cur->ncoords-1)]; } cur = cur->next; } return dst->c; } /** * @brief Creates a new route path * * This creates a new non-trivial route. It therefore needs the routing information created by route_graph_flood, so * make sure to run route_graph_flood() after changing the destination before using this function. * * @param this The route graph to create the route from * @param oldpath (Optional) old path which may contain parts of the new part - this speeds things up a bit. May be NULL. * @param pos The starting position of the route * @param dst The destination of the route * @param preferences The routing preferences * @return The new route path */ static struct route_path *route_path_new(struct route_graph *this, struct route_path *oldpath, struct route_info *pos, struct route_info *dst, struct vehicleprofile *profile) { struct route_graph_segment *s=NULL,*s1=NULL,*s2=NULL; /* candidate segments for cheapest path */ struct route_graph_point *start; /* point at which the next segment starts, i.e. up to which the path is complete */ struct route_info *posinfo, *dstinfo; /* same as pos and dst, but NULL if not part of current segment */ int segs=0,dir; /* number of segments added to graph, direction of first segment */ int val1=INT_MAX,val2=INT_MAX; /* total cost for s1 and s2, respectively */ int val,val1_new,val2_new; struct route_path *ret; if (! pos->street || ! dst->street) { dbg(lvl_error,"pos or dest not set"); return NULL; } if (profile->mode == 2 || (profile->mode == 0 && pos->lenextra + dst->lenextra > transform_distance(map_projection(pos->street->item.map), &pos->c, &dst->c))) return route_path_new_offroad(this, pos, dst); while ((s=route_graph_get_segment(this, pos->street, s))) { val=route_value_seg(profile, NULL, s, 2); if (val != INT_MAX && s->end->value != INT_MAX) { val=val*(100-pos->percent)/100; dbg(lvl_debug,"val1 %d",val); if (route_graph_segment_match(s,this->avoid_seg) && pos->street_direction < 0) val+=profile->turn_around_penalty; dbg(lvl_debug,"val1 %d",val); val1_new=s->end->value+val; dbg(lvl_debug,"val1 +%d=%d",s->end->value,val1_new); if (val1_new < val1) { val1=val1_new; s1=s; } } val=route_value_seg(profile, NULL, s, -2); if (val != INT_MAX && s->start->value != INT_MAX) { val=val*pos->percent/100; dbg(lvl_debug,"val2 %d",val); if (route_graph_segment_match(s,this->avoid_seg) && pos->street_direction > 0) val+=profile->turn_around_penalty; dbg(lvl_debug,"val2 %d",val); val2_new=s->start->value+val; dbg(lvl_debug,"val2 +%d=%d",s->start->value,val2_new); if (val2_new < val2) { val2=val2_new; s2=s; } } } if (val1 == INT_MAX && val2 == INT_MAX) { dbg(lvl_error,"no route found, pos blocked"); return NULL; } if (val1 == val2) { val1=s1->end->value; val2=s2->start->value; } if (val1 < val2) { start=s1->start; s=s1; dir=1; } else { start=s2->end; s=s2; dir=-1; } if (pos->street_direction && dir != pos->street_direction && profile->turn_around_penalty) { if (!route_graph_segment_match(this->avoid_seg,s)) { dbg(lvl_debug,"avoid current segment"); if (this->avoid_seg) route_graph_set_traffic_distortion(this, this->avoid_seg, 0); this->avoid_seg=s; route_graph_set_traffic_distortion(this, this->avoid_seg, profile->turn_around_penalty); route_graph_reset(this); route_graph_init(this, dst, profile); route_graph_compute_shortest_path(this, profile, NULL); return route_path_new(this, oldpath, pos, dst, profile); } } ret=g_new0(struct route_path, 1); ret->in_use=1; ret->updated=1; if (pos->lenextra) route_path_add_line(ret, &pos->c, &pos->lp, pos->lenextra); ret->path_hash=item_hash_new(); dstinfo=NULL; posinfo=pos; while (s && !dstinfo) { /* following start->seg, which indicates the least costly way to reach our destination */ segs++; if (s->start == start) { if (item_is_equal(s->data.item, dst->street->item) && (s->end->seg == s || !posinfo)) dstinfo=dst; if (!route_path_add_item_from_graph(ret, oldpath, s, 1, posinfo, dstinfo)) ret->updated=0; start=s->end; } else { if (item_is_equal(s->data.item, dst->street->item) && (s->start->seg == s || !posinfo)) dstinfo=dst; if (!route_path_add_item_from_graph(ret, oldpath, s, -1, posinfo, dstinfo)) ret->updated=0; start=s->start; } posinfo=NULL; s=start->seg; } if (dst->lenextra) route_path_add_line(ret, &dst->lp, &dst->c, dst->lenextra); dbg(lvl_debug, "%d segments", segs); return ret; } static int route_graph_build_next_map(struct route_graph *rg) { do { rg->m=mapset_next(rg->h, 2); if (! rg->m) return 0; map_rect_destroy(rg->mr); rg->mr=map_rect_new(rg->m, rg->sel); } while (!rg->mr); return 1; } static int is_turn_allowed(struct route_graph_point *p, struct route_graph_segment *from, struct route_graph_segment *to) { struct route_graph_point *prev,*next; struct route_graph_segment *tmp1,*tmp2; if (item_is_equal(from->data.item, to->data.item)) return 0; if (from->start == p) prev=from->end; else prev=from->start; if (to->start == p) next=to->end; else next=to->start; tmp1=p->end; while (tmp1) { if (tmp1->start->c.x == prev->c.x && tmp1->start->c.y == prev->c.y && (tmp1->data.item.type == type_street_turn_restriction_no || tmp1->data.item.type == type_street_turn_restriction_only)) { tmp2=p->start; dbg(lvl_debug,"found %s (0x%x,0x%x) (0x%x,0x%x)-(0x%x,0x%x) %p-%p",item_to_name(tmp1->data.item.type), tmp1->data.item.id_hi,tmp1->data.item.id_lo,tmp1->start->c.x,tmp1->start->c.y,tmp1->end->c.x,tmp1->end->c.y,tmp1->start, tmp1->end); while (tmp2) { dbg(lvl_debug,"compare %s (0x%x,0x%x) (0x%x,0x%x)-(0x%x,0x%x) %p-%p",item_to_name(tmp2->data.item.type), tmp2->data.item.id_hi,tmp2->data.item.id_lo,tmp2->start->c.x,tmp2->start->c.y,tmp2->end->c.x,tmp2->end->c.y,tmp2->start, tmp2->end); if (item_is_equal(tmp1->data.item, tmp2->data.item)) break; tmp2=tmp2->start_next; } dbg(lvl_debug,"tmp2=%p",tmp2); if (tmp2) { dbg(lvl_debug,"%s tmp2->end=%p next=%p",item_to_name(tmp1->data.item.type),tmp2->end,next); } if (tmp1->data.item.type == type_street_turn_restriction_no && tmp2 && tmp2->end->c.x == next->c.x && tmp2->end->c.y == next->c.y) { dbg(lvl_debug,"from 0x%x,0x%x over 0x%x,0x%x to 0x%x,0x%x not allowed (no)",prev->c.x,prev->c.y,p->c.x,p->c.y,next->c.x, next->c.y); return 0; } if (tmp1->data.item.type == type_street_turn_restriction_only && tmp2 && (tmp2->end->c.x != next->c.x || tmp2->end->c.y != next->c.y)) { dbg(lvl_debug,"from 0x%x,0x%x over 0x%x,0x%x to 0x%x,0x%x not allowed (only)",prev->c.x,prev->c.y,p->c.x,p->c.y, next->c.x,next->c.y); return 0; } } tmp1=tmp1->end_next; } dbg(lvl_debug,"from 0x%x,0x%x over 0x%x,0x%x to 0x%x,0x%x allowed",prev->c.x,prev->c.y,p->c.x,p->c.y,next->c.x, next->c.y); return 1; } static void route_graph_clone_segment(struct route_graph *this, struct route_graph_segment *s, struct route_graph_point *start, struct route_graph_point *end, int flags) { struct route_graph_segment_data data; data.item=&s->data.item; data.offset=1; data.flags=s->data.flags|flags; data.len=s->data.len+1; data.maxspeed=-1; data.dangerous_goods=0; data.score = s->data.score; if (s->data.flags & AF_SPEED_LIMIT) data.maxspeed=RSD_MAXSPEED(&s->data); if (s->data.flags & AF_SEGMENTED) data.offset=RSD_OFFSET(&s->data); dbg(lvl_debug,"cloning segment from %p (0x%x,0x%x) to %p (0x%x,0x%x)",start,start->c.x,start->c.y, end, end->c.x, end->c.y); route_graph_add_segment(this, start, end, &data); } static void route_graph_process_restriction_segment(struct route_graph *this, struct route_graph_point *p, struct route_graph_segment *s, int dir) { struct route_graph_segment *tmp; struct route_graph_point *pn; struct coord c=p->c; int dx=0; int dy=0; c.x+=dx; c.y+=dy; dbg(lvl_debug,"From %s %d,%d",item_to_name(s->data.item.type),dx,dy); pn=route_graph_point_new(this, &c); if (dir > 0) { /* going away */ dbg(lvl_debug,"other 0x%x,0x%x",s->end->c.x,s->end->c.y); if (s->data.flags & AF_ONEWAY) { dbg(lvl_debug,"Not possible"); return; } route_graph_clone_segment(this, s, pn, s->end, AF_ONEWAYREV); } else { /* coming in */ dbg(lvl_debug,"other 0x%x,0x%x",s->start->c.x,s->start->c.y); if (s->data.flags & AF_ONEWAYREV) { dbg(lvl_debug,"Not possible"); return; } route_graph_clone_segment(this, s, s->start, pn, AF_ONEWAY); } tmp=p->start; while (tmp) { if (tmp != s && tmp->data.item.type != type_street_turn_restriction_no && tmp->data.item.type != type_street_turn_restriction_only && !(tmp->data.flags & AF_ONEWAYREV) && is_turn_allowed(p, s, tmp)) { route_graph_clone_segment(this, tmp, pn, tmp->end, AF_ONEWAY); dbg(lvl_debug,"To start %s",item_to_name(tmp->data.item.type)); } tmp=tmp->start_next; } tmp=p->end; while (tmp) { if (tmp != s && tmp->data.item.type != type_street_turn_restriction_no && tmp->data.item.type != type_street_turn_restriction_only && !(tmp->data.flags & AF_ONEWAY) && is_turn_allowed(p, s, tmp)) { route_graph_clone_segment(this, tmp, tmp->start, pn, AF_ONEWAYREV); dbg(lvl_debug,"To end %s",item_to_name(tmp->data.item.type)); } tmp=tmp->end_next; } } static void route_graph_process_restriction_point(struct route_graph *this, struct route_graph_point *p) { struct route_graph_segment *tmp; tmp=p->start; dbg(lvl_debug,"node 0x%x,0x%x",p->c.x,p->c.y); while (tmp) { if (tmp->data.item.type != type_street_turn_restriction_no && tmp->data.item.type != type_street_turn_restriction_only) route_graph_process_restriction_segment(this, p, tmp, 1); tmp=tmp->start_next; } tmp=p->end; while (tmp) { if (tmp->data.item.type != type_street_turn_restriction_no && tmp->data.item.type != type_street_turn_restriction_only) route_graph_process_restriction_segment(this, p, tmp, -1); tmp=tmp->end_next; } p->flags |= RP_TURN_RESTRICTION_RESOLVED; } static void route_graph_process_restrictions(struct route_graph *this) { struct route_graph_point *curr; int i; dbg(lvl_debug,"enter"); for (i = 0 ; i < HASH_SIZE ; i++) { curr=this->hash[i]; while (curr) { if (curr->flags & RP_TURN_RESTRICTION) route_graph_process_restriction_point(this, curr); curr=curr->hash_next; } } } /** * @brief Releases all resources needed to build the route graph. * * If `cancel` is false, this function will start processing restrictions and ultimately call the route * graph's `done_cb` callback. * * The traffic module will always call this method with `cancel` set to true, as it does not process * restrictions and has no callback. Inside the routing module, `cancel` will be true if, and only if, * navigation has been aborted. * * @param rg Points to the route graph * @param cancel True if the process was aborted before completing, false if it completed normally */ void route_graph_build_done(struct route_graph *rg, int cancel) { dbg(lvl_debug,"cancel=%d",cancel); if (rg->idle_ev) event_remove_idle(rg->idle_ev); if (rg->idle_cb) callback_destroy(rg->idle_cb); map_rect_destroy(rg->mr); mapset_close(rg->h); route_free_selection(rg->sel); rg->idle_ev=NULL; rg->idle_cb=NULL; rg->mr=NULL; rg->h=NULL; rg->sel=NULL; if (! cancel) { route_graph_process_restrictions(rg); if (rg->done_cb) callback_call_0(rg->done_cb); } rg->busy=0; } static void route_graph_build_idle(struct route_graph *rg, struct vehicleprofile *profile) { int count=1000; struct item *item; while (count > 0) { for (;;) { item=map_rect_get_item(rg->mr); if (item) break; if (!route_graph_build_next_map(rg)) { route_graph_build_done(rg, 0); return; } } if (item->type == type_traffic_distortion) route_graph_add_traffic_distortion(rg, profile, item, 0); else if (item->type == type_street_turn_restriction_no || item->type == type_street_turn_restriction_only) route_graph_add_turn_restriction(rg, item); else route_graph_add_street(rg, item, profile); count--; } } /** * @brief Builds a new route graph from a mapset * * This function builds a new route graph from a map. Please note that this function does not * add any routing information to the route graph - this has to be done via the route_graph_flood() * function. * * @param ms The mapset to build the route graph from * @param c An array of coordinates for the current position, waypoints (if any) and destination * @param count Number of coordinates in `c` * @param done_cb The callback which will be called when graph is complete * @return The new route graph. */ static struct route_graph *route_graph_build(struct mapset *ms, struct coord *c, int count, struct callback *done_cb, int async, struct vehicleprofile *profile) { struct route_graph *ret=g_new0(struct route_graph, 1); dbg(lvl_debug,"enter"); ret->sel=route_calc_selection(c, count, profile); ret->h=mapset_open(ms); ret->done_cb=done_cb; ret->busy=1; ret->heap = fh_makekeyheap(); if (route_graph_build_next_map(ret)) { if (async) { ret->idle_cb=callback_new_2(callback_cast(route_graph_build_idle), ret, profile); ret->idle_ev=event_add_idle(50, ret->idle_cb); } } else route_graph_build_done(ret, 0); return ret; } static void route_graph_update_done(struct route *this, struct callback *cb) { route_graph_init(this->graph, this->current_dst, this->vehicleprofile); route_graph_compute_shortest_path(this->graph, this->vehicleprofile, cb); } /** * @brief Updates the route graph * * This updates the route graph after settings in the route have changed. It also * adds routing information afterwards by calling route_graph_flood(). * * @param this The route to update the graph for * @param cb The callback function to call when the route graph update is complete (used only in asynchronous mode) * @param async Set to nonzero in order to update the route graph asynchronously */ static void route_graph_update(struct route *this, struct callback *cb, int async) { struct attr route_status; struct coord *c=g_alloca(sizeof(struct coord)*(1+g_list_length(this->destinations))); int i=0; GList *tmp; route_status.type=attr_route_status; route_graph_destroy(this->graph); this->graph=NULL; callback_destroy(this->route_graph_done_cb); this->route_graph_done_cb=callback_new_2(callback_cast(route_graph_update_done), this, cb); route_status.u.num=route_status_building_graph; route_set_attr(this, &route_status); c[i++]=this->pos->c; tmp=this->destinations; while (tmp) { struct route_info *dst=tmp->data; c[i++]=dst->c; tmp=g_list_next(tmp); } this->graph=route_graph_build(this->ms, c, i, this->route_graph_done_cb, async, this->vehicleprofile); if (! async) { while (this->graph->busy) route_graph_build_idle(this->graph, this->vehicleprofile); } } /** * @brief Gets street data for an item * * @param item The item to get the data for * @return Street data for the item */ struct street_data * street_get_data (struct item *item) { int count=0,*flags; struct street_data *ret = NULL, *ret1; struct attr flags_attr, maxspeed_attr; const int step = 128; int c; do { ret1=g_realloc(ret, sizeof(struct street_data)+(count+step)*sizeof(struct coord)); if (!ret1) { if (ret) g_free(ret); return NULL; } ret = ret1; c = item_coord_get(item, &ret->c[count], step); count += c; } while (c && c == step); ret1=g_realloc(ret, sizeof(struct street_data)+count*sizeof(struct coord)); if (ret1) ret = ret1; ret->item=*item; ret->count=count; if (item_attr_get(item, attr_flags, &flags_attr)) ret->flags=flags_attr.u.num; else { flags=item_get_default_flags(item->type); if (flags) ret->flags=*flags; else ret->flags=0; } ret->maxspeed = -1; if (ret->flags & AF_SPEED_LIMIT) { if (item_attr_get(item, attr_maxspeed, &maxspeed_attr)) { ret->maxspeed = maxspeed_attr.u.num; } } return ret; } /** * @brief Copies street data * * @param orig The street data to copy * @return The copied street data */ struct street_data * street_data_dup(struct street_data *orig) { struct street_data *ret; int size=sizeof(struct street_data)+orig->count*sizeof(struct coord); ret=g_malloc(size); memcpy(ret, orig, size); return ret; } /** * @brief Frees street data * * @param sd Street data to be freed */ void street_data_free(struct street_data *sd) { g_free(sd); } /** * @brief Finds the nearest street to a given coordinate * * @param ms The mapset to search in for the street * @param pc The coordinate to find a street nearby * @return The nearest street */ static struct route_info *route_find_nearest_street(struct vehicleprofile *vehicleprofile, struct mapset *ms, struct pcoord *pc) { struct route_info *ret=NULL; int max_dist=1000; struct map_selection *sel; int dist,mindist=0,pos; struct mapset_handle *h; struct map *m; struct map_rect *mr; struct item *item; struct coord lp; struct street_data *sd; struct coord c; struct coord_geo g; if(!vehicleprofile) return NULL; ret=g_new0(struct route_info, 1); mindist = INT_MAX; h=mapset_open(ms); while ((m=mapset_next(h,2))) { c.x = pc->x; c.y = pc->y; if (map_projection(m) != pc->pro) { transform_to_geo(pc->pro, &c, &g); transform_from_geo(map_projection(m), &g, &c); } sel = route_rect(18, &c, &c, 0, max_dist); if (!sel) continue; mr=map_rect_new(m, sel); if (!mr) { map_selection_destroy(sel); continue; } while ((item=map_rect_get_item(mr))) { if (item_get_default_flags(item->type)) { sd=street_get_data(item); if (!sd) continue; dist=transform_distance_polyline_sq(sd->c, sd->count, &c, &lp, &pos); if (dist < mindist && ( (sd->flags & vehicleprofile->flags_forward_mask) == vehicleprofile->flags || (sd->flags & vehicleprofile->flags_reverse_mask) == vehicleprofile->flags)) { mindist = dist; if (ret->street) { street_data_free(ret->street); } ret->c=c; ret->lp=lp; ret->pos=pos; ret->street=sd; dbg(lvl_debug,"dist=%d id 0x%x 0x%x pos=%d", dist, item->id_hi, item->id_lo, pos); } else { street_data_free(sd); } } } map_selection_destroy(sel); map_rect_destroy(mr); } mapset_close(h); if (!ret->street || mindist > max_dist*max_dist) { if (ret->street) { street_data_free(ret->street); dbg(lvl_debug,"Much too far %d > %d", mindist, max_dist); } g_free(ret); ret = NULL; } return ret; } /** * @brief Destroys a route_info * * @param info The route info to be destroyed */ void route_info_free(struct route_info *inf) { if (!inf) return; if (inf->street) street_data_free(inf->street); g_free(inf); } #include "point.h" /** * @brief Returns street data for a route info * * @param rinf The route info to return the street data for * @return Street data for the route info */ struct street_data * route_info_street(struct route_info *rinf) { return rinf->street; } /** * @brief Implementation-specific map rect data */ struct map_rect_priv { struct route_info_handle *ri; enum attr_type attr_next; int pos; struct map_priv *mpriv; /**< The map to which this map rect refers */ struct item item; /**< The current item, i.e. the last item returned by the `map_rect_get_item` method */ unsigned int last_coord; struct route_path *path; struct route_path_segment *seg,*seg_next; struct route_graph_point *point; struct route_graph_segment *rseg; char *str; int hash_bucket; struct coord *coord_sel; /**< Set this to a coordinate if you want to filter for just a single route graph point */ struct route_graph_point_iterator it; /* Pointer to current waypoint element of route->destinations */ GList *dest; }; static void rm_coord_rewind(void *priv_data) { struct map_rect_priv *mr = priv_data; mr->last_coord = 0; } static void rm_attr_rewind(void *priv_data) { struct map_rect_priv *mr = priv_data; mr->attr_next = attr_street_item; } static int rm_attr_get(void *priv_data, enum attr_type attr_type, struct attr *attr) { struct map_rect_priv *mr = priv_data; struct route_path_segment *seg=mr->seg; struct route *route=mr->mpriv->route; if (mr->item.type != type_street_route && mr->item.type != type_waypoint && mr->item.type != type_route_end) return 0; attr->type=attr_type; switch (attr_type) { case attr_any: while (mr->attr_next != attr_none) { if (rm_attr_get(priv_data, mr->attr_next, attr)) return 1; } return 0; case attr_maxspeed: mr->attr_next = attr_street_item; if (seg && (seg->data->flags & AF_SPEED_LIMIT)) { attr->u.num=RSD_MAXSPEED(seg->data); } else { return 0; } return 1; case attr_street_item: mr->attr_next=attr_direction; if (seg && seg->data->item.map) attr->u.item=&seg->data->item; else return 0; return 1; case attr_direction: mr->attr_next=attr_route; if (seg) attr->u.num=seg->direction; else return 0; return 1; case attr_route: mr->attr_next=attr_length; attr->u.route = mr->mpriv->route; return 1; case attr_length: mr->attr_next=attr_time; if (seg) attr->u.num=seg->data->len; else return 0; return 1; case attr_time: /* TODO This ignores access flags on traffic distortions, but the attribute does not seem * to be used anywhere */ mr->attr_next=attr_speed; if (seg) attr->u.num=route_time_seg(route->vehicleprofile, seg->data, NULL); else return 0; return 1; case attr_speed: /* TODO This ignores access flags on traffic distortions, but the attribute does not seem * to be used anywhere */ mr->attr_next=attr_label; if (seg) attr->u.num=route_seg_speed(route->vehicleprofile, seg->data, NULL); else return 0; return 1; case attr_label: mr->attr_next=attr_none; if(mr->item.type==type_waypoint || mr->item.type == type_route_end) { if(mr->str) g_free(mr->str); /* Build the text displayed close to the destination cursor. * It will contain the sequence number of the waypoint (1, 2...) */ mr->str=g_strdup_printf("%d",route->reached_destinations_count+g_list_position(route->destinations,mr->dest)+1); attr->u.str=mr->str; return 1; } return 0; default: mr->attr_next=attr_none; attr->type=attr_none; return 0; } return 0; } static int rm_coord_get(void *priv_data, struct coord *c, int count) { struct map_rect_priv *mr = priv_data; struct route_path_segment *seg = mr->seg; int i,rc=0; struct route *r = mr->mpriv->route; enum projection pro = route_projection(r); if (pro == projection_none) return 0; if (mr->item.type == type_route_start || mr->item.type == type_route_start_reverse || mr->item.type == type_route_end || mr->item.type == type_waypoint ) { if (! count || mr->last_coord) return 0; mr->last_coord=1; if (mr->item.type == type_route_start || mr->item.type == type_route_start_reverse) c[0]=r->pos->c; else if (mr->item.type == type_waypoint) { c[0]=((struct route_info *)mr->dest->data)->c; } else { /*type_route_end*/ c[0]=route_get_dst(r)->c; } return 1; } if (! seg) return 0; for (i=0; i < count; i++) { if (mr->last_coord >= seg->ncoords) break; if (i >= seg->ncoords) break; if (pro != projection_mg) transform_from_to(&seg->c[mr->last_coord++], pro, &c[i],projection_mg); else c[i] = seg->c[mr->last_coord++]; rc++; } dbg(lvl_debug,"return %d",rc); return rc; } static struct item_methods methods_route_item = { rm_coord_rewind, rm_coord_get, rm_attr_rewind, rm_attr_get, }; static void rp_attr_rewind(void *priv_data) { struct map_rect_priv *mr = priv_data; mr->attr_next = attr_label; } static int rp_attr_get(void *priv_data, enum attr_type attr_type, struct attr *attr) { struct map_rect_priv *mr = priv_data; struct route_graph_point *p = mr->point; struct route_graph_segment *seg = mr->rseg; struct route *route=mr->mpriv->route; attr->type=attr_type; switch (attr_type) { case attr_any: // works only with rg_points for now while (mr->attr_next != attr_none) { dbg(lvl_debug,"querying %s", attr_to_name(mr->attr_next)); if (rp_attr_get(priv_data, mr->attr_next, attr)) return 1; } return 0; case attr_maxspeed: mr->attr_next = attr_label; if (mr->item.type != type_rg_segment) return 0; if (seg && (seg->data.flags & AF_SPEED_LIMIT)) { attr->type = attr_maxspeed; attr->u.num=RSD_MAXSPEED(&seg->data); return 1; } else { return 0; } case attr_label: mr->attr_next=attr_street_item; attr->type = attr_label; if (mr->str) g_free(mr->str); if (mr->item.type == type_rg_point) { if (p->value != INT_MAX) mr->str=g_strdup_printf("%d", p->value); else mr->str=g_strdup("-"); } else { int len=seg->data.len; int speed=route_seg_speed(route->vehicleprofile, &seg->data, NULL); int time=route_time_seg(route->vehicleprofile, &seg->data, NULL); if (speed) mr->str=g_strdup_printf("%dm %dkm/h %d.%ds",len,speed,time/10,time%10); else if (len) mr->str=g_strdup_printf("%dm",len); else { mr->str=NULL; return 0; } } attr->u.str = mr->str; return 1; case attr_street_item: mr->attr_next=attr_flags; if (mr->item.type != type_rg_segment) return 0; if (seg && seg->data.item.map) attr->u.item=&seg->data.item; else return 0; return 1; case attr_flags: mr->attr_next = attr_direction; if (mr->item.type != type_rg_segment) return 0; if (seg) { attr->u.num = seg->data.flags; } else { return 0; } return 1; case attr_direction: mr->attr_next = attr_debug; // This only works if the map has been opened at a single point, and in that case indicates if the // segment returned last is connected to this point via its start (1) or its end (-1) if (!mr->coord_sel || (mr->item.type != type_rg_segment)) return 0; if (seg->start == mr->point) { attr->u.num=1; } else if (seg->end == mr->point) { attr->u.num=-1; } else { return 0; } return 1; case attr_debug: mr->attr_next=attr_none; if (mr->str) g_free(mr->str); mr->str=NULL; switch (mr->item.type) { case type_rg_point: { struct route_graph_segment *tmp; int start=0; int end=0; tmp=p->start; while (tmp) { start++; tmp=tmp->start_next; } tmp=p->end; while (tmp) { end++; tmp=tmp->end_next; } mr->str=g_strdup_printf("%d %d %p (0x%x,0x%x)", start, end, p, p->c.x, p->c.y); attr->u.str = mr->str; } return 1; case type_rg_segment: if (! seg) return 0; mr->str=g_strdup_printf("len %d time %d start %p end %p",seg->data.len, route_time_seg(route->vehicleprofile, &seg->data, NULL), seg->start, seg->end); attr->u.str = mr->str; return 1; break; default: return 0; } break; default: mr->attr_next=attr_none; attr->type=attr_none; return 0; } } /** * @brief Returns the coordinates of a route graph item * * @param priv_data The route graph item's private data * @param c Pointer where to store the coordinates * @param count How many coordinates to get at a max? * @return The number of coordinates retrieved */ static int rp_coord_get(void *priv_data, struct coord *c, int count) { struct map_rect_priv *mr = priv_data; struct route_graph_point *p = mr->point; struct route_graph_segment *seg = mr->rseg; int rc = 0,i,dir; struct route *r = mr->mpriv->route; enum projection pro = route_projection(r); if (pro == projection_none) return 0; for (i=0; i < count; i++) { if (mr->item.type == type_rg_point) { if (mr->last_coord >= 1) break; if (pro != projection_mg) transform_from_to(&p->c, pro, &c[i],projection_mg); else c[i] = p->c; } else { if (mr->last_coord >= 2) break; dir=0; if (seg->end->seg == seg) dir=1; if (mr->last_coord) dir=1-dir; if (dir) { if (pro != projection_mg) transform_from_to(&seg->end->c, pro, &c[i],projection_mg); else c[i] = seg->end->c; } else { if (pro != projection_mg) transform_from_to(&seg->start->c, pro, &c[i],projection_mg); else c[i] = seg->start->c; } } mr->last_coord++; rc++; } return rc; } static struct item_methods methods_point_item = { rm_coord_rewind, rp_coord_get, rp_attr_rewind, rp_attr_get, }; static void rp_destroy(struct map_priv *priv) { g_free(priv); } static void rm_destroy(struct map_priv *priv) { g_free(priv); } static struct map_rect_priv *rm_rect_new(struct map_priv *priv, struct map_selection *sel) { struct map_rect_priv * mr; dbg(lvl_debug,"enter"); mr=g_new0(struct map_rect_priv, 1); mr->mpriv = priv; mr->item.priv_data = mr; mr->item.type = type_none; mr->item.meth = &methods_route_item; if (priv->route->path2) { mr->path=priv->route->path2; mr->seg_next=mr->path->path; mr->path->in_use++; } else mr->seg_next=NULL; return mr; } /** * @brief Opens a new map rectangle on the route graph's map * * This function opens a new map rectangle on the route graph's map. * The "sel" parameter enables you to only search for a single route graph * point on this map (or exactly: open a map rectangle that only contains * this one point). To do this, pass here a single map selection, whose * c_rect has both coordinates set to the same point. Otherwise this parameter * has no effect. * * @param priv The route graph map's private data * @param sel Here it's possible to specify a point for which to search. Please read the function's description. * @return A new map rect's private data */ static struct map_rect_priv *rp_rect_new(struct map_priv *priv, struct map_selection *sel) { struct map_rect_priv * mr; dbg(lvl_debug,"enter"); if (! priv->route->graph) return NULL; mr=g_new0(struct map_rect_priv, 1); mr->mpriv = priv; mr->item.priv_data = mr; mr->item.type = type_rg_point; mr->item.meth = &methods_point_item; if (sel) { if ((sel->u.c_rect.lu.x == sel->u.c_rect.rl.x) && (sel->u.c_rect.lu.y == sel->u.c_rect.rl.y)) { mr->coord_sel = g_malloc(sizeof(struct coord)); *(mr->coord_sel) = sel->u.c_rect.lu; } } return mr; } static void rm_rect_destroy(struct map_rect_priv *mr) { if (mr->str) g_free(mr->str); if (mr->coord_sel) { g_free(mr->coord_sel); } if (mr->path) { mr->path->in_use--; if (mr->path->update_required && (mr->path->in_use==1) && (mr->mpriv->route->route_status & ~route_status_destination_set)) route_path_update_done(mr->mpriv->route, mr->path->update_required-1); else if (!mr->path->in_use) g_free(mr->path); } g_free(mr); } static struct item *rp_get_item(struct map_rect_priv *mr) { struct route *r = mr->mpriv->route; struct route_graph_point *p = mr->point; struct route_graph_segment *seg = mr->rseg; if (mr->item.type == type_rg_point) { if (mr->coord_sel) { // We are supposed to return only the point at one specified coordinate... if (!p) { p = route_graph_get_point_last(r->graph, mr->coord_sel); if (!p) { mr->point = NULL; // This indicates that no point has been found } else { mr->it = rp_iterator_new(p); } } else { p = NULL; } } else { if (!p) { mr->hash_bucket=0; p = r->graph->hash[0]; } else p=p->hash_next; while (!p) { mr->hash_bucket++; if (mr->hash_bucket >= HASH_SIZE) break; p = r->graph->hash[mr->hash_bucket]; } } if (p) { mr->point = p; mr->item.id_lo++; rm_coord_rewind(mr); rp_attr_rewind(mr); return &mr->item; } else mr->item.type = type_rg_segment; } if (mr->coord_sel) { if (!mr->point) { /* This means that no point has been found */ return NULL; } seg = rp_iterator_next(&(mr->it)); } else { if (!seg) seg=r->graph->route_segments; else seg=seg->next; } if (seg) { mr->rseg = seg; mr->item.id_lo++; rm_coord_rewind(mr); rp_attr_rewind(mr); return &mr->item; } return NULL; } static struct item *rp_get_item_byid(struct map_rect_priv *mr, int id_hi, int id_lo) { struct item *ret=NULL; while (id_lo-- > 0) ret=rp_get_item(mr); return ret; } static struct item *rm_get_item(struct map_rect_priv *mr) { struct route *route=mr->mpriv->route; void *id=0; switch (mr->item.type) { case type_none: if (route->pos && route->pos->street_direction && route->pos->street_direction != route->pos->dir) mr->item.type=type_route_start_reverse; else mr->item.type=type_route_start; if (route->pos) { id=route->pos; break; } /* FALLTHRU */ case type_route_start: case type_route_start_reverse: mr->seg=NULL; mr->dest=mr->mpriv->route->destinations; /* FALLTHRU */ default: if (mr->item.type == type_waypoint) mr->dest=g_list_next(mr->dest); mr->item.type=type_street_route; mr->seg=mr->seg_next; if (!mr->seg && mr->path && mr->path->next) { struct route_path *p=NULL; mr->path->in_use--; if (!mr->path->in_use) p=mr->path; mr->path=mr->path->next; mr->path->in_use++; mr->seg=mr->path->path; if (p) g_free(p); if (mr->dest) { id=mr->dest; mr->item.type=type_waypoint; mr->seg_next=mr->seg; break; } } if (mr->seg) { mr->seg_next=mr->seg->next; id=mr->seg; break; } if (mr->dest && g_list_next(mr->dest)) { id=mr->dest; mr->item.type=type_waypoint; break; } mr->item.type=type_route_end; id=&(mr->mpriv->route->destinations); if (mr->mpriv->route->destinations) break; /* FALLTHRU */ case type_route_end: return NULL; } mr->last_coord = 0; item_id_from_ptr(&mr->item,id); rm_attr_rewind(mr); return &mr->item; } static struct item *rm_get_item_byid(struct map_rect_priv *mr, int id_hi, int id_lo) { struct item *ret=NULL; do { ret=rm_get_item(mr); } while (ret && (ret->id_lo!=id_lo || ret->id_hi!=id_hi)); return ret; } static struct map_methods route_meth = { projection_mg, "utf-8", rm_destroy, rm_rect_new, rm_rect_destroy, rm_get_item, rm_get_item_byid, NULL, NULL, NULL, }; static struct map_methods route_graph_meth = { projection_mg, "utf-8", rp_destroy, rp_rect_new, rm_rect_destroy, rp_get_item, rp_get_item_byid, NULL, NULL, NULL, }; static struct map_priv *route_map_new_helper(struct map_methods *meth, struct attr **attrs, int graph) { struct map_priv *ret; struct attr *route_attr; route_attr=attr_search(attrs, attr_route); if (! route_attr) return NULL; ret=g_new0(struct map_priv, 1); if (graph) *meth=route_graph_meth; else *meth=route_meth; ret->route=route_attr->u.route; return ret; } static struct map_priv *route_map_new(struct map_methods *meth, struct attr **attrs, struct callback_list *cbl) { return route_map_new_helper(meth, attrs, 0); } static struct map_priv *route_graph_map_new(struct map_methods *meth, struct attr **attrs, struct callback_list *cbl) { return route_map_new_helper(meth, attrs, 1); } static struct map *route_get_map_helper(struct route *this_, struct map **map, char *type, char *description) { struct attr *attrs[5]; struct attr a_type,navigation,data,a_description; a_type.type=attr_type; a_type.u.str=type; navigation.type=attr_route; navigation.u.route=this_; data.type=attr_data; data.u.str=""; a_description.type=attr_description; a_description.u.str=description; attrs[0]=&a_type; attrs[1]=&navigation; attrs[2]=&data; attrs[3]=&a_description; attrs[4]=NULL; if (! *map) { *map=map_new(NULL, attrs); navit_object_ref((struct navit_object *)*map); } return *map; } /** * @brief Adds a traffic distortion item to the route * * @param this_ The route * @param item The item to add, must be of {@code type_traffic_distortion} */ void route_add_traffic_distortion(struct route *this_, struct item *item) { if (route_has_graph(this_)) route_graph_add_traffic_distortion(this_->graph, this_->vehicleprofile, item, 1); } /** * @brief Changes a traffic distortion item on the route * * Attempting to change an idem which is not in the route graph will add it. * * @param this_ The route * @param item The item to change, must be of {@code type_traffic_distortion} */ void route_change_traffic_distortion(struct route *this_, struct item *item) { if (route_has_graph(this_)) route_graph_change_traffic_distortion(this_->graph, this_->vehicleprofile, item); } /** * @brief Returns a new map containing the route path * * This function returns a new map containing the route path. * * @important Do not map_destroy() this! * * @param this_ The route to get the map of * @return A new map containing the route path */ struct map * route_get_map(struct route *this_) { return route_get_map_helper(this_, &this_->map, "route","Route"); } /** * @brief Returns a new map containing the route graph * * This function returns a new map containing the route graph. * * @important Do not map_destroy() this! * * @param this_ The route to get the map of * @return A new map containing the route graph */ struct map * route_get_graph_map(struct route *this_) { return route_get_map_helper(this_, &this_->graph_map, "route_graph","Route Graph"); } /** * @brief Returns the flags for the route. */ enum route_path_flags route_get_flags(struct route *this_) { return this_->flags; } /** * @brief Retrieves the route graph. * * @return The route graph, or NULL if the route has no valid graph */ struct route_graph * route_get_graph(struct route *this_) { return this_->graph; } /** * @brief Whether the route has a valid graph. * * @return True if the route has a graph, false if not. */ int route_has_graph(struct route *this_) { return (this_->graph != NULL); } /** * @brief Removes a traffic distortion item from the route * * Removing a traffic distortion which is not in the route graph is a no-op. * * @param this_ The route * @param item The item to remove, must be of {@code type_traffic_distortion} */ void route_remove_traffic_distortion(struct route *this_, struct item *item) { if (route_has_graph(this_)) route_graph_remove_traffic_distortion(this_->graph, this_->vehicleprofile, item); } void route_set_projection(struct route *this_, enum projection pro) { } int route_set_attr(struct route *this_, struct attr *attr) { int attr_updated=0; switch (attr->type) { case attr_route_status: attr_updated = (this_->route_status != attr->u.num); this_->route_status = attr->u.num; break; case attr_destination: route_set_destination(this_, attr->u.pcoord, 1); return 1; case attr_position: route_set_position_flags(this_, attr->u.pcoord, route_path_flag_async); return 1; case attr_position_test: return route_set_position_flags(this_, attr->u.pcoord, route_path_flag_no_rebuild); case attr_vehicle: attr_updated = (this_->v != attr->u.vehicle); this_->v=attr->u.vehicle; if (attr_updated) { struct attr g; struct pcoord pc; struct coord c; if (vehicle_get_attr(this_->v, attr_position_coord_geo, &g, NULL)) { pc.pro=projection_mg; transform_from_geo(projection_mg, g.u.coord_geo, &c); pc.x=c.x; pc.y=c.y; route_set_position(this_, &pc); } } break; default: dbg(lvl_error,"unsupported attribute: %s",attr_to_name(attr->type)); return 0; } if (attr_updated) callback_list_call_attr_2(this_->cbl2, attr->type, this_, attr); return 1; } int route_add_attr(struct route *this_, struct attr *attr) { switch (attr->type) { case attr_callback: callback_list_add(this_->cbl2, attr->u.callback); return 1; default: return 0; } } int route_remove_attr(struct route *this_, struct attr *attr) { dbg(lvl_debug,"enter"); switch (attr->type) { case attr_callback: callback_list_remove(this_->cbl2, attr->u.callback); return 1; case attr_vehicle: this_->v=NULL; return 1; default: return 0; } } int route_get_attr(struct route *this_, enum attr_type type, struct attr *attr, struct attr_iter *iter) { int ret=1; switch (type) { case attr_map: attr->u.map=route_get_map(this_); ret=(attr->u.map != NULL); break; case attr_destination: if (this_->destinations) { struct route_info *dst; if (iter) { if (iter->u.list) { iter->u.list=g_list_next(iter->u.list); } else { iter->u.list=this_->destinations; } if (!iter->u.list) { return 0; } dst = (struct route_info*)iter->u.list->data; } else { //No iter handling dst=route_get_dst(this_); } attr->u.pcoord=&this_->pc; this_->pc.pro=projection_mg; /* fixme */ this_->pc.x=dst->c.x; this_->pc.y=dst->c.y; } else ret=0; break; case attr_vehicle: attr->u.vehicle=this_->v; ret=(this_->v != NULL); dbg(lvl_debug,"get vehicle %p",this_->v); break; case attr_vehicleprofile: attr->u.vehicleprofile=this_->vehicleprofile; ret=(this_->vehicleprofile != NULL); break; case attr_route_status: attr->u.num=this_->route_status; break; case attr_destination_time: if (this_->path2 && (this_->route_status == route_status_path_done_new || this_->route_status == route_status_path_done_incremental)) { struct route_path *path=this_->path2; attr->u.num=0; while (path) { attr->u.num+=path->path_time; path=path->next; } dbg(lvl_debug,"path_time %ld",attr->u.num); } else ret=0; break; case attr_destination_length: if (this_->path2 && (this_->route_status == route_status_path_done_new || this_->route_status == route_status_path_done_incremental)) { struct route_path *path=this_->path2; attr->u.num=0; while (path) { attr->u.num+=path->path_len; path=path->next; } } else ret=0; break; default: return 0; } attr->type=type; return ret; } struct attr_iter * route_attr_iter_new(void) { return g_new0(struct attr_iter, 1); } void route_attr_iter_destroy(struct attr_iter *iter) { g_free(iter); } void route_init(void) { plugin_register_category_map("route", route_map_new); plugin_register_category_map("route_graph", route_graph_map_new); } void route_destroy(struct route *this_) { this_->refcount++; /* avoid recursion */ route_path_destroy(this_->path2,1); route_graph_destroy(this_->graph); route_clear_destinations(this_); route_info_free(this_->pos); map_destroy(this_->map); map_destroy(this_->graph_map); g_free(this_); } struct object_func route_func = { attr_route, (object_func_new)route_new, (object_func_get_attr)route_get_attr, (object_func_iter_new)NULL, (object_func_iter_destroy)NULL, (object_func_set_attr)route_set_attr, (object_func_add_attr)route_add_attr, (object_func_remove_attr)route_remove_attr, (object_func_init)NULL, (object_func_destroy)route_destroy, (object_func_dup)route_dup, (object_func_ref)navit_object_ref, (object_func_unref)navit_object_unref, };