Example #1
0
void create_terrain_maps(const config::const_child_itors &cfgs,
                         t_translation::t_list& terrain_list,
                         std::map<t_translation::t_terrain, terrain_type>& letter_to_terrain)
{
	foreach (const config &t, cfgs)
	{
		terrain_type terrain(t);
		DBG_G << "create_terrain_maps: " << terrain.number() << " "
			<< terrain.id() << " " << terrain.name() << " : " << terrain.editor_group() << "\n";

		std::pair<std::map<t_translation::t_terrain, terrain_type>::iterator, bool> res;
		res = letter_to_terrain.insert(std::make_pair(terrain.number(), terrain));
		if (!res.second) {
			terrain_type& curr = res.first->second;
			WRN_G << "Duplicate terrain code definition found for " << terrain.number() << "\n";
			WRN_G << "Trying to add terrain "
				<< terrain.id() << " (" << terrain.name() << ") "
				<< "[" << terrain.editor_group() << "]" << "\n";
			WRN_G << "which conflicts with  "
				<< curr.id() << " (" << curr.name() << ") "
				<< "[" << curr.editor_group() << "]" << "\n";
			std::vector<std::string> eg1 = utils::split(curr.editor_group());
			std::vector<std::string> eg2 = utils::split(terrain.editor_group());
			std::set<std::string> egs;
			std::copy(eg1.begin(), eg1.end(), std::inserter(egs, egs.begin()));
			std::copy(eg2.begin(), eg2.end(), std::inserter(egs, egs.begin()));
			std::string joined = utils::join(egs);
			curr.set_editor_group(joined);
			WRN_G << "Editor groups merged to: " << joined << "\n";
		} else {
			terrain_list.push_back(terrain.number());
		}
	}
Example #2
0
static int placing_score(const config& side, const gamemap& map, const map_location& pos)
{
	int positions = 0, liked = 0;
	const t_translation::t_list terrain = t_translation::read_list(side["terrain_liked"]);

	for(int i = pos.x-8; i != pos.x+8; ++i) {
		for(int j = pos.y-8; j != pos.y+8; ++j) {
			const map_location pos(i,j);
			if(map.on_board(pos)) {
				++positions;
				if(std::count(terrain.begin(),terrain.end(),map[pos])) {
					++liked;
				}
			}
		}
	}

	return (100*liked)/positions;
}
Example #3
0
void create_terrain_maps(const config::const_child_itors &cfgs,
                         t_translation::t_list& terrain_list,
                         std::map<t_translation::t_terrain, terrain_type>& letter_to_terrain)
{
	BOOST_FOREACH(const config &t, cfgs)
	{
		terrain_type terrain(t);
		DBG_G << "create_terrain_maps: " << terrain.number() << " "
			<< terrain.id() << " " << terrain.name() << " : " << terrain.editor_group() << "\n";

		std::pair<std::map<t_translation::t_terrain, terrain_type>::iterator, bool> res;
		res = letter_to_terrain.insert(std::make_pair(terrain.number(), terrain));
		if (!res.second) {
			terrain_type& curr = res.first->second;
			if(terrain == curr) {
				LOG_G << "Merging terrain " << terrain.number()
					<< ": " << terrain.id() << " (" << terrain.name() << ")\n";
				std::vector<std::string> eg1 = utils::split(curr.editor_group());
				std::vector<std::string> eg2 = utils::split(terrain.editor_group());
				std::set<std::string> egs;
				bool clean_merge = true;
				BOOST_FOREACH(std::string& t, eg1)
					clean_merge &= egs.insert(t).second;
				BOOST_FOREACH(std::string& t, eg2)
					clean_merge &= egs.insert(t).second;

				std::string joined = utils::join(egs);
				curr.set_editor_group(joined);
				if(clean_merge) {
					LOG_G << "Editor groups merged to: " << joined << "\n";
				} else {
					ERR_G << "Merged terrain " << terrain.number()
					<< ": " << terrain.id() << " (" << terrain.name() << ") "
					<< "with duplicate editor groups [" << terrain.editor_group() << "] "
					<< "and [" << curr.editor_group() << "]\n";
				}
			} else {
				ERR_G << "Duplicate terrain code definition found for " << terrain.number() << "\n";
				ERR_G << "Failed to add terrain "
					<< terrain.id() << " (" << terrain.name() << ") "
					<< "[" << terrain.editor_group() << "]" << "\n";
				ERR_G << "which conflicts with  "
					<< curr.id() << " (" << curr.name() << ") "
					<< "[" << curr.editor_group() << "]" << "\n";
			}
		} else {
			terrain_list.push_back(terrain.number());
		}
	}
Example #4
0
	/**
	 * Checks whether a terrain code matches a given list of terrain codes.
	 *
	 * @param tcode 	The terrain to check
	 * @param terrains	The terrain list agains which to check the terrain.
	 *	May contain the metacharacters
	 *	- '*' STAR, meaning "all terrains"
	 *	- '!' NOT,  meaning "all terrains except those present in the list."
	 *
	 * @return			returns true if "tcode" matches the list or the list is empty,
	 *					else false.
	 */
	bool terrain_matches(t_translation::t_terrain tcode, const t_translation::t_list& terrains) const
		{ return terrains.empty()? true : t_translation::terrain_matches(tcode, terrains); }
Example #5
0
std::string default_generate_map(size_t width, size_t height, size_t island_size, size_t island_off_center,
                                 size_t iterations, size_t hill_size,
						         size_t max_lakes, size_t nvillages, size_t castle_size, size_t nplayers, bool roads_between_castles,
								 std::map<map_location,std::string>* labels, const config& cfg)
{
	log_scope("map generation");

	// Odd widths are nasty
	VALIDATE(is_even(width), _("Random maps with an odd width aren't supported."));

	int ticks = SDL_GetTicks();

	// Find out what the 'flatland' on this map is, i.e. grassland.
	std::string flatland = cfg["default_flatland"];
	if(flatland == "") {
		flatland = t_translation::write_terrain_code(t_translation::GRASS_LAND);
	}

	const t_translation::t_terrain grassland = t_translation::read_terrain_code(flatland);

	// We want to generate a map that is 9 times bigger
	// than the actual size desired.
	// Only the middle part of the map will be used,
	// but the rest is so that the map we end up using
	// can have a context (e.g. rivers flowing from
	// out of the map into the map, same for roads, etc.)
	width *= 3;
	height *= 3;

	LOG_NG << "generating height map...\n";
	// Generate the height of everything.
	const height_map heights = generate_height_map(width,height,iterations,hill_size,island_size,island_off_center);
	LOG_NG << "done generating height map...\n";
	LOG_NG << (SDL_GetTicks() - ticks) << "\n"; ticks = SDL_GetTicks();

	config naming = cfg.child_or_empty("naming");
	// HACK: dummy names to satisfy unit_race requirements
	naming["id"] = "village_naming";
	naming["plural_name"] = "villages";

	// Make a dummy race for generating names
	const unit_race name_generator(naming);

	std::vector<terrain_height_mapper> height_conversion;

	BOOST_FOREACH(const config &h, cfg.child_range("height")) {
		height_conversion.push_back(terrain_height_mapper(h));
	}

	terrain_map terrain(width, t_translation::t_list(height, grassland));
	size_t x, y;
	for(x = 0; x != heights.size(); ++x) {
		for(y = 0; y != heights[x].size(); ++y) {
			for(std::vector<terrain_height_mapper>::const_iterator i = height_conversion.begin();
			    i != height_conversion.end(); ++i) {
				if(i->convert_terrain(heights[x][y])) {
					terrain[x][y] = i->convert_to();
					break;
				}
			}
		}
	}

	std::map<int, t_translation::coordinate> starting_positions;
	LOG_NG << output_map(terrain, starting_positions);
	LOG_NG << "placed land forms\n";
	LOG_NG << (SDL_GetTicks() - ticks) << "\n"; ticks = SDL_GetTicks();

	// Now that we have our basic set of flatland/hills/mountains/water,
	// we can place lakes and rivers on the map.
	// All rivers are sourced at a lake.
	// Lakes must be in high land - at least 'min_lake_height'.
	// (Note that terrain below a certain altitude may be made
	// into bodies of water in the code above - i.e. 'sea',
	// but these are not considered 'lakes', because
	// they are not sources of rivers).
	//
	// We attempt to place 'max_lakes' lakes.
	// Each lake will be placed at a random location,
	// if that random location meets the minimum terrain requirements for a lake.
	// We will also attempt to source a river from each lake.
	std::set<location> lake_locs;

	std::map<location, std::string> river_names, lake_names, road_names, bridge_names, mountain_names, forest_names, swamp_names;

	const size_t nlakes = max_lakes > 0 ? (rand()%max_lakes) : 0;
	for(size_t lake = 0; lake != nlakes; ++lake) {
		for(int tries = 0; tries != 100; ++tries) {
			const int x = rand()%width;
			const int y = rand()%height;
			if (heights[x][y] > cfg["min_lake_height"].to_int()) {
				std::vector<location> river = generate_river(heights,
					terrain, x, y, cfg["river_frequency"]);

				if(river.empty() == false && labels != NULL) {
					std::string base_name;
					LOG_NG << "generating name for river...\n";
					const std::string& name = generate_name(name_generator,"river_name",&base_name);
					LOG_NG << "named river '" << name << "'\n";
					size_t name_frequency = 20;
					for(std::vector<location>::const_iterator r = river.begin(); r != river.end(); ++r) {

						const map_location loc(r->x-width/3,r->y-height/3);

						if(((r - river.begin())%name_frequency) == name_frequency/2) {
							labels->insert(std::pair<map_location,std::string>(loc,name));
						}

						river_names.insert(std::pair<location,std::string>(loc,base_name));
					}

					LOG_NG << "put down river name...\n";
				}

				LOG_NG << "generating lake...\n";
				std::set<location> locs;
				bool res = generate_lake(terrain, x, y, cfg["lake_size"], locs);
				if(res && labels != NULL) {
					bool touches_other_lake = false;

					std::string base_name;
					const std::string& name = generate_name(name_generator,"lake_name",&base_name);

					std::set<location>::const_iterator i;

					// Only generate a name if the lake hasn't touched any other lakes,
					// so that we don't end up with one big lake with multiple names.
					for(i = locs.begin(); i != locs.end(); ++i) {
						if(lake_locs.count(*i) != 0) {
							touches_other_lake = true;

							// Reassign the name of this lake to be the same as the other lake
							const location loc(i->x-width/3,i->y-height/3);
							const std::map<location,std::string>::const_iterator other_name = lake_names.find(loc);
							if(other_name != lake_names.end()) {
								base_name = other_name->second;
							}
						}

						lake_locs.insert(*i);
					}

					if(!touches_other_lake) {
						const map_location loc(x-width/3,y-height/3);
						labels->erase(loc);
						labels->insert(std::pair<map_location,std::string>(loc,name));
					}

					for(i = locs.begin(); i != locs.end(); ++i) {
						const location loc(i->x-width/3,i->y-height/3);
						lake_names.insert(std::pair<location, std::string>(loc, base_name));
					}
				}

				break;
			}
		}
	}

	LOG_NG << "done generating rivers...\n";
	LOG_NG << (SDL_GetTicks() - ticks) << "\n"; ticks = SDL_GetTicks();

	const size_t default_dimensions = 40*40*9;

	/*
	 * Convert grassland terrain to other types of flat terrain.
	 *
	 * We generate a 'temperature map' which uses the height generation
	 * algorithm to generate the temperature levels all over the map.  Then we
	 * can use a combination of height and terrain to divide terrain up into
	 * more interesting types than the default.
	 */
	const height_map temperature_map = generate_height_map(width,height,
		cfg["temperature_iterations"].to_int() * width * height / default_dimensions,
		cfg["temperature_size"], 0, 0);

	LOG_NG << "generated temperature map...\n";
	LOG_NG << (SDL_GetTicks() - ticks) << "\n"; ticks = SDL_GetTicks();

	std::vector<terrain_converter> converters;
	BOOST_FOREACH(const config &cv, cfg.child_range("convert")) {
		converters.push_back(terrain_converter(cv));
	}

	LOG_NG << "created terrain converters\n";
	LOG_NG << (SDL_GetTicks() - ticks) << "\n"; ticks = SDL_GetTicks();


	// Iterate over every flatland tile, and determine
	// what type of flatland it is, based on our [convert] tags.
	for(x = 0; x != width; ++x) {
		for(y = 0; y != height; ++y) {
			for(std::vector<terrain_converter>::const_iterator i = converters.begin(); i != converters.end(); ++i) {
				if(i->convert_terrain(terrain[x][y],heights[x][y],temperature_map[x][y])) {
					terrain[x][y] = i->convert_to();
					break;
				}
			}
		}
	}

	LOG_NG << "placing villages...\n";
	LOG_NG << (SDL_GetTicks() - ticks) << "\n"; ticks = SDL_GetTicks();

	/*
	 * Place villages in a 'grid', to make placing fair, but with villages
	 * displaced from their position according to terrain and randomness, to
	 * add some variety.
	 */
	std::set<location> villages;

	LOG_NG << "placing castles...\n";

	/** Try to find configuration for castles. */
	const config &castle_config = cfg.child("castle");
	if (!castle_config) {
		LOG_NG << "Could not find castle configuration\n";
		return std::string();
	}

	/*
	 * Castle configuration tag contains a 'valid_terrain' attribute which is a
	 * list of terrains that the castle may appear on.
	 */
	const t_translation::t_list list =
		t_translation::read_list(castle_config["valid_terrain"]);

	const is_valid_terrain terrain_tester(terrain, list);

	/*
	 * Attempt to place castles at random.
	 *
	 * Once we have placed castles, we run a sanity check to make sure that the
	 * castles are well-placed.  If the castles are not well-placed, we try
	 * again.  Definition of 'well-placed' is if no two castles are closer than
	 * 'min_distance' hexes from each other, and the castles appear on a
	 * terrain listed in 'valid_terrain'.
	 */
	std::vector<location> castles;
	std::set<location> failed_locs;

	for(size_t player = 0; player != nplayers; ++player) {
		LOG_NG << "placing castle for " << player << "\n";
		log_scope("placing castle");
		const int min_x = width/3 + 3;
		const int min_y = height/3 + 3;
		const int max_x = (width/3)*2 - 4;
		const int max_y = (height/3)*2 - 4;
		int min_distance = castle_config["min_distance"];

		location best_loc;
		int best_ranking = 0;
		for(int x = min_x; x != max_x; ++x) {
			for(int y = min_y; y != max_y; ++y) {
				const location loc(x,y);
				if(failed_locs.count(loc)) {
					continue;
				}

				const int ranking = rank_castle_location(x,y,terrain_tester,min_x,max_x,min_y,max_y,min_distance,castles,best_ranking);
				if(ranking <= 0) {
					failed_locs.insert(loc);
				}

				if(ranking > best_ranking) {
					best_ranking = ranking;
					best_loc = loc;
				}
			}
		}
		if(best_ranking == 0) {
			ERR_NG << "No castle location found, aborting.\n";
			std::string error = _("No valid castle location found. Too many or too few mountain hexes? (please check the 'max hill size' parameter)");
			throw mapgen_exception(error);
		}
		assert(std::find(castles.begin(), castles.end(), best_loc) == castles.end());
		castles.push_back(best_loc);
		// Make sure the location can't get a second castle.
		failed_locs.insert(best_loc);
	}

	LOG_NG << "placing roads...\n";
	LOG_NG << (SDL_GetTicks() - ticks) << "\n"; ticks = SDL_GetTicks();

	// Place roads.
	// We select two tiles at random locations on the borders
	// of the map, and try to build roads between them.
	int nroads = cfg["roads"];
	if(roads_between_castles) {
		nroads += castles.size()*castles.size();
	}

	std::set<location> bridges;

	road_path_calculator calc(terrain,cfg);
	for (int road = 0; road != nroads; ++road) {
		log_scope("creating road");

		/*
		 * We want the locations to be on the portion of the map we're actually
		 * going to use, since roads on other parts of the map won't have any
		 * influence, and doing it like this will be quicker.
		 */
		location src = random_point_at_side(width/3 + 2,height/3 + 2);
		location dst = random_point_at_side(width/3 + 2,height/3 + 2);

		src.x += width/3 - 1;
		src.y += height/3 - 1;
		dst.x += width/3 - 1;
		dst.y += height/3 - 1;

		if (roads_between_castles && road < int(castles.size() * castles.size())) {
			const size_t src_castle = road/castles.size();
			const size_t dst_castle = road%castles.size();
			if(src_castle >= dst_castle) {
				continue;
			}

			src = castles[src_castle];
			dst = castles[dst_castle];
		}

		// If the road isn't very interesting (on the same border), don't draw it.
		else if(src.x == dst.x || src.y == dst.y) {
			continue;
		}

		if (calc.cost(src, 0.0) >= 1000.0 || calc.cost(dst, 0.0) >= 1000.0) {
			continue;
		}

		// Search a path out for the road
		pathfind::plain_route rt = pathfind::a_star_search(src, dst, 10000.0, &calc, width, height);

		std::string road_base_name;
		const std::string& name = generate_name(name_generator, "road_name", &road_base_name);
		const int name_frequency = 20;
		int name_count = 0;

		bool on_bridge = false;

		// Draw the road.
		// If the search failed, rt.steps will simply be empty.
		for(std::vector<location>::const_iterator step = rt.steps.begin();
				step != rt.steps.end(); ++step) {

			const int x = step->x;
			const int y = step->y;

			if(x < 0 || y < 0 || x >= static_cast<long>(width) ||
					y >= static_cast<long>(height)) {

				continue;
			}

			// Find the configuration which tells us
			// what to convert this tile to, to make it into a road.
			if (const config &child = cfg.find_child("road_cost", "terrain",
					t_translation::write_terrain_code(terrain[x][y])))
			{
				// Convert to bridge means that we want to convert
				// depending upon the direction the road is going.
				// Typically it will be in a format like,
				// convert_to_bridge=\,|,/
				// '|' will be used if the road is going north-south
				// '/' will be used if the road is going south west-north east
				// '\' will be used if the road is going south east-north west
				// The terrain will be left unchanged otherwise
				// (if there is no clear direction).
				const std::string &convert_to_bridge = child["convert_to_bridge"];
				if(convert_to_bridge.empty() == false) {
					if(step == rt.steps.begin() || step+1 == rt.steps.end())
						continue;

					const location& last = *(step-1);
					const location& next = *(step+1);

					location adj[6];
					get_adjacent_tiles(*step,adj);

					int direction = -1;

					// If we are going north-south
					if((last == adj[0] && next == adj[3]) || (last == adj[3] && next == adj[0])) {
						direction = 0;
					}

					// If we are going south west-north east
					else if((last == adj[1] && next == adj[4]) || (last == adj[4] && next == adj[1])) {
						direction = 1;
					}

					// If we are going south east-north west
					else if((last == adj[2] && next == adj[5]) || (last == adj[5] && next == adj[2])) {
						direction = 2;
					}

					if(labels != NULL && on_bridge == false) {
						on_bridge = true;
						std::string bridge_base_name;
						const std::string& name = generate_name(name_generator, "bridge_name", &bridge_base_name);
						const location loc(x - width / 3, y-height/3);
						labels->insert(std::pair<map_location,std::string>(loc,name));
						bridge_names.insert(std::pair<location,std::string>(loc, bridge_base_name)); //add to use for village naming
						bridges.insert(loc);
					}

					if(direction != -1) {
						const std::vector<std::string> items = utils::split(convert_to_bridge);
						if(size_t(direction) < items.size() && items[direction].empty() == false) {
							terrain[x][y] = t_translation::read_terrain_code(items[direction]);
						}

						continue;
					}
				} else {
					on_bridge = false;
				}

				// Just a plain terrain substitution for a road
				const std::string &convert_to = child["convert_to"];
				if(convert_to.empty() == false) {
					const t_translation::t_terrain letter =
						t_translation::read_terrain_code(convert_to);
					if(labels != NULL && terrain[x][y] != letter && name_count++ == name_frequency && on_bridge == false) {
						labels->insert(std::pair<map_location,std::string>(map_location(x-width/3,y-height/3),name));
						name_count = 0;
					}

					terrain[x][y] = letter;
					const location loc(x - width / 3, y - height / 3); //add to use for village naming
					road_names.insert(std::pair<location,std::string>(loc, road_base_name));
				}
			}
		}

		LOG_NG << "looked at " << calc.calls << " locations\n";
	}


	// Now that road drawing is done, we can plonk down the castles.
	for(std::vector<location>::const_iterator c = castles.begin(); c != castles.end(); ++c) {
		if(c->valid() == false) {
			continue;
		}

		const int x = c->x;
		const int y = c->y;
		const int player = c - castles.begin() + 1;
		const struct t_translation::coordinate coord(x, y);
		starting_positions.insert(std::pair<int, t_translation::coordinate>(player, coord));
		terrain[x][y] = t_translation::HUMAN_KEEP;

		const int castles[13][2] = {
		  {-1, 0}, {-1, -1}, {0, -1}, {1, -1}, {1, 0}, {0, 1}, {-1, 1},
		  {-2, 1}, {-2, 0}, {-2, -1}, {-1, -2}, {0, -2}, {1, -2}
		};

		for (size_t i = 0; i < castle_size - 1; i++) {
		  terrain[x+castles[i][0]][y+castles[i][1]] = t_translation::HUMAN_CASTLE;
		}

		// Remove all labels under the castle tiles
		if(labels != NULL) {
		  labels->erase(location(x-width/3,y-height/3));
		  for (size_t i = 0; i < castle_size - 1; i++) {
		    labels->erase(location(x+castles[i][0]-width/3,
					   y+castles[i][1]-height/3));
		  }

		}

	}

	LOG_NG << "placed castles\n";
	LOG_NG << (SDL_GetTicks() - ticks) << "\n"; ticks = SDL_GetTicks();

	/*Random naming for landforms: mountains, forests, swamps, hills
	 *we name these now that everything else is placed (as e.g., placing
	 * roads could split a forest)
	 */
	for (x = width / 3; x < (width / 3)*2; x++) {
		for (y = height / 3; y < (height / 3) * 2;y++) {
		//check the terrain of the tile
		const location loc(x - width / 3, y - height / 3);
		const t_translation::t_terrain terr = terrain[x][y];
		std::string name, base_name;
		std::set<std::string> used_names;
		if (t_translation::terrain_matches(terr, t_translation::ALL_MOUNTAINS)) {
			//name every 15th mountain
			if ((rand()%15) == 0) {
				for(size_t ntry = 0; ntry != 30 && (ntry == 0 || used_names.count(name) > 0); ++ntry) {
					name = generate_name(name_generator, "mountain_name", &base_name);
				}
				labels->insert(std::pair<map_location, std::string>(loc, name));
				mountain_names.insert(std::pair<location, std::string>(loc, base_name));
			}
		}
		else if (t_translation::terrain_matches(terr, t_translation::ALL_FORESTS)) {
			//if the forest tile is not named yet, name it
			const std::map<location, std::string>::const_iterator forest_name = forest_names.find(loc);
			if(forest_name == forest_names.end()) {
				for(size_t ntry = 0; ntry != 30 && (ntry == 0 || used_names.count(name) > 0); ++ntry) {
					name = generate_name(name_generator, "forest_name", &base_name);
				}
				forest_names.insert(std::pair<location, std::string>(loc, base_name));
				// name all connected forest tiles accordingly
				flood_name(loc, base_name, forest_names, t_translation::ALL_FORESTS, terrain, width, height, 0, labels, name);
			}
		}
		else if (t_translation::terrain_matches(terr, t_translation::ALL_SWAMPS)) {
			//if the swamp tile is not named yet, name it
			const std::map<location, std::string>::const_iterator swamp_name = swamp_names.find(loc);
			if(swamp_name == swamp_names.end()) {
				for(size_t ntry = 0; ntry != 30 && (ntry == 0 || used_names.count(name) > 0); ++ntry) {
					name = generate_name(name_generator, "swamp_name", &base_name);
				}
				swamp_names.insert(std::pair<location, std::string>(loc, base_name));
				// name all connected swamp tiles accordingly
				flood_name(loc, base_name, swamp_names, t_translation::ALL_SWAMPS, terrain, width, height, 0, labels, name);
			}
		}

		}
	}

	if (nvillages > 0)
	{
		config naming_cfg = cfg.child_or_empty("village_naming");
		// HACK: dummy names to satisfy unit_race requirements
		naming_cfg["id"] = "village_naming";
		naming_cfg["plural_name"] = "villages";

		const unit_race village_names_generator(naming_cfg);

		// First we work out the size of the x and y distance between villages
		const size_t tiles_per_village = ((width*height)/9)/nvillages;
		size_t village_x = 1, village_y = 1;

		// Alternate between incrementing the x and y value.
		// When they are high enough to equal or exceed the tiles_per_village,
		// then we have them to the value we want them at.
		while(village_x*village_y < tiles_per_village) {
			if(village_x < village_y) {
				++village_x;
			} else {
				++village_y;
			}
		}

		std::set<std::string> used_names;
		tcode_list_cache adj_liked_cache;

		for(size_t vx = 0; vx < width; vx += village_x) {
			LOG_NG << "village at " << vx << "\n";
			for(size_t vy = rand()%village_y; vy < height; vy += village_y) {

				const size_t add_x = rand()%3;
				const size_t add_y = rand()%3;
				const size_t x = (vx + add_x) - 1;
				const size_t y = (vy + add_y) - 1;

				const map_location res = place_village(terrain,x,y,2,cfg,adj_liked_cache);

				if(res.x >= static_cast<long>(width) / 3 &&
						res.x  < static_cast<long>(width * 2) / 3 &&
						res.y >= static_cast<long>(height) / 3 &&
						res.y  < static_cast<long>(height * 2) / 3) {

					const std::string str =
						t_translation::write_terrain_code(terrain[res.x][res.y]);
					if (const config &child = cfg.find_child("village", "terrain", str))
					{
						const std::string &convert_to = child["convert_to"];
						if(convert_to != "") {
							terrain[res.x][res.y] =
								t_translation::read_terrain_code(convert_to);

							villages.insert(res);

							if(labels != NULL && naming_cfg.empty() == false) {
								const map_location loc(res.x-width/3,res.y-height/3);

								map_location adj[6];
								get_adjacent_tiles(loc,adj);

								std::string name_type = "village_name";
								const t_translation::t_list
									field    = t_translation::t_list(1, t_translation::GRASS_LAND),
									forest   = t_translation::t_list(1, t_translation::FOREST),
									mountain = t_translation::t_list(1, t_translation::MOUNTAIN),
									hill     = t_translation::t_list(1, t_translation::HILL);

								size_t field_count = 0, forest_count = 0, mountain_count = 0, hill_count = 0;

								utils::string_map symbols;

								size_t n;
								for(n = 0; n != 6; ++n) {
									const std::map<location,std::string>::const_iterator road_name = road_names.find(adj[n]);
									if(road_name != road_names.end()) {
										symbols["road"] = road_name->second;
										name_type = "village_name_road";
										break;
									}

									const std::map<location,std::string>::const_iterator river_name = river_names.find(adj[n]);
									if(river_name != river_names.end()) {
										symbols["river"] = river_name->second;
										name_type = "village_name_river";

										const std::map<location,std::string>::const_iterator bridge_name = bridge_names.find(adj[n]);
										if(bridge_name != bridge_names.end()) {
										//we should always end up here, since if there is an adjacent bridge, there has to be an adjacent river too
										symbols["bridge"] = bridge_name->second;
										name_type = "village_name_river_bridge";
										}

										break;
									}

									const std::map<location,std::string>::const_iterator forest_name = forest_names.find(adj[n]);
									if(forest_name != forest_names.end()) {
										symbols["forest"] = forest_name->second;
										name_type = "village_name_forest";
										break;
									}

									const std::map<location,std::string>::const_iterator lake_name = lake_names.find(adj[n]);
									if(lake_name != lake_names.end()) {
										symbols["lake"] = lake_name->second;
										name_type = "village_name_lake";
										break;
									}

									const std::map<location,std::string>::const_iterator mountain_name = mountain_names.find(adj[n]);
									if(mountain_name != mountain_names.end()) {
										symbols["mountain"] = mountain_name->second;
										name_type = "village_name_mountain";
										break;
									}

									const std::map<location,std::string>::const_iterator swamp_name = swamp_names.find(adj[n]);
									if(swamp_name != swamp_names.end()) {
										symbols["swamp"] = swamp_name->second;
										name_type = "village_name_swamp";
										break;
									}

									const t_translation::t_terrain terr =
										terrain[adj[n].x+width/3][adj[n].y+height/3];

									if(std::count(field.begin(),field.end(),terr) > 0) {
										++field_count;
									} else if(std::count(forest.begin(),forest.end(),terr) > 0) {
										++forest_count;
									} else if(std::count(hill.begin(),hill.end(),terr) > 0) {
										++hill_count;
									} else if(std::count(mountain.begin(),mountain.end(),terr) > 0) {
										++mountain_count;
									}
								}

								if(n == 6) {
									if(field_count == 6) {
										name_type = "village_name_grassland";
									} else if(forest_count >= 2) {
										name_type = "village_name_forest";
									} else if(mountain_count >= 1) {
										name_type = "village_name_mountain_anonymous";
									} else if(hill_count >= 2) {
										name_type = "village_name_hill";
									}
								}

								std::string name;
								for(size_t ntry = 0; ntry != 30 && (ntry == 0 || used_names.count(name) > 0); ++ntry) {
									name = generate_name(village_names_generator,name_type,NULL,&symbols);
								}

								used_names.insert(name);
								labels->insert(std::pair<map_location,std::string>(loc,name));
							}
						}
					}
				}
			}
		}
	}

	LOG_NG << "placed villages\n";
	LOG_NG << (SDL_GetTicks() - ticks) << "\n"; ticks = SDL_GetTicks();

	return output_map(terrain, starting_positions);
}