OpenTTD-patches/src/zoning_cmd.cpp

/*
 * This file is part of OpenTTD.
 * OpenTTD is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, version 2.
 * OpenTTD 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 OpenTTD. If not, see <http://www.gnu.org/licenses/>.
 */

/** @file zoning_cmd.cpp */

#include "stdafx.h"
#include "openttd.h"
#include "station_type.h"
#include "station_base.h"
#include "industry.h"
#include "gfx_func.h"
#include "viewport_func.h"
#include "map_func.h"
#include "company_func.h"
#include "town_map.h"
#include "table/sprites.h"
#include "station_func.h"
#include "station_map.h"
#include "town.h"
#include "tracerestrict.h"
#include "window_func.h"
#include "zoning.h"
#include "viewport_func.h"
#include "road_map.h"
#include "animated_tile.h"
#include "3rdparty/cpp-btree/btree_set.h"

Zoning _zoning;
static const SpriteID ZONING_INVALID_SPRITE_ID = UINT_MAX;

static btree::btree_set<uint32_t> _zoning_cache_inner;
static btree::btree_set<uint32_t> _zoning_cache_outer;

/**
 * Draw the zoning sprites.
 *
 * @param SpriteID image
 *        the image
 * @param SpriteID colour
 *        the colour of the zoning
 * @param TileInfo ti
 *        the tile
 */
void DrawZoningSprites(SpriteID image, SpriteID colour, const TileInfo *ti)
{
	if (colour != ZONING_INVALID_SPRITE_ID) {
		AddSortableSpriteToDraw(image + ti->tileh, colour, ti->x, ti->y, 0x10, 0x10, 1, ti->z + 7);
	}
}

/**
 * Detect whether this area is within the acceptance of any station.
 *
 * @param TileArea area
 *        the area to search by
 * @param Owner owner
 *        the owner of the stations which we need to match again
  * @param StationFacility facility_mask
 *        one or more facilities in the mask must be present for a station to be used
 * @return true if a station is found
 */
bool IsAreaWithinAcceptanceZoneOfStation(TileArea area, Owner owner, StationFacility facility_mask)
{
	StationFinder morestations(area);

	for (const Station *st : *morestations.GetStations()) {
		if (st->owner != owner || !(st->facilities & facility_mask)) continue;
		Rect rect = st->GetCatchmentRect();
		return TileArea(TileXY(rect.left, rect.top), TileXY(rect.right, rect.bottom)).Intersects(area);
	}

	return false;
}

/**
 * Check whether the player can build in tile.
 *
 * @param TileIndex tile
 * @param Owner owner
 * @return red if they cannot
 */
SpriteID TileZoneCheckBuildEvaluation(TileIndex tile, Owner owner)
{
	/* Let's first check for the obvious things you cannot build on */
	switch (GetTileType(tile)) {
		case MP_INDUSTRY:
		case MP_OBJECT:
		case MP_STATION:
		case MP_HOUSE:
		case MP_TUNNELBRIDGE:
			return SPR_ZONING_INNER_HIGHLIGHT_RED;

		/* There are only two things you can own (or some else
		 * can own) that you can still build on. i.e. roads and
		 * railways.
		 * @todo
		 * Add something more intelligent, check what tool the
		 * user is currently using (and if none, assume some
		 * standards), then check it against if owned by some-
		 * one else (e.g. railway on someone else's road).
		 * While that being said, it should also check if it
		 * is not possible to build railway/road on someone
		 * else's/your own road/railway (e.g. the railway track
		 * is curved or a cross).
		 */
		case MP_ROAD:
		case MP_RAILWAY:
			if (GetTileOwner(tile) != owner) {
				return SPR_ZONING_INNER_HIGHLIGHT_RED;
			} else {
				return ZONING_INVALID_SPRITE_ID;
			}

		default:
			return ZONING_INVALID_SPRITE_ID;
	}
}

/**
 * Check the opinion of the local authority in the tile.
 *
 * @param TileIndex tile
 * @param Owner owner
 * @return black if no opinion, orange if bad,
 *         light blue if good or invalid if no town
 */
SpriteID TileZoneCheckOpinionEvaluation(TileIndex tile, Owner owner)
{
	int opinion = 0; // 0: no town, 1: no opinion, 2: bad, 3: good
	Town *town = ClosestTownFromTile(tile, _settings_game.economy.dist_local_authority);

	if (town != nullptr) {
		if (HasBit(town->have_ratings, owner)) {
			opinion = (town->ratings[owner] > 0) ? 3 : 2;
		} else {
			opinion = 1;
		}
	}

	switch (opinion) {
		case 1:  return SPR_ZONING_INNER_HIGHLIGHT_BLACK;      // no opinion
		case 2:  return SPR_ZONING_INNER_HIGHLIGHT_ORANGE;     // bad
		case 3:  return SPR_ZONING_INNER_HIGHLIGHT_LIGHT_BLUE; // good
		default: return ZONING_INVALID_SPRITE_ID;              // no town
	}
}

/**
 * Detect whether the tile is within the catchment zone of a station.
 *
 * @param TileIndex tile
 * @param Owner owner
 * @param open_window_only
 *        only use stations which have their station window open
 * @return black if within, light blue if only in acceptance zone
 *         and nothing if no nearby station.
 */
SpriteID TileZoneCheckStationCatchmentEvaluation(TileIndex tile, Owner owner, bool open_window_only)
{
	// Never on a station.
	if (IsTileType(tile, MP_STATION)) {
		return ZONING_INVALID_SPRITE_ID;
	}

	StationFinder stations(TileArea(tile, 1, 1));

	for (const Station *st : *stations.GetStations()) {
		if (st->owner == owner) {
			if (!open_window_only || FindWindowById(WC_STATION_VIEW, st->index) != nullptr) {
				return SPR_ZONING_INNER_HIGHLIGHT_LIGHT_BLUE;
			}
		}
	}

	return ZONING_INVALID_SPRITE_ID;
}

/**
 * Detect whether a building is unserved by a station of owner.
 *
 * @param TileIndex tile
 * @param Owner owner
 * @return red if unserved, orange if only accepting, nothing if served or not
 *         a building
 */
SpriteID TileZoneCheckUnservedBuildingsEvaluation(TileIndex tile, Owner owner)
{
	if (!IsTileType(tile, MP_HOUSE)) {
		return ZONING_INVALID_SPRITE_ID;
	}

	auto has_town_cargo = [&](const CargoArray &dat) {
		for (CargoID cid : SetCargoBitIterator(CargoSpec::town_production_cargo_mask[TPE_PASSENGERS] | CargoSpec::town_production_cargo_mask[TPE_MAIL])) {
			if (dat[cid] > 0) return true;
		}
		return false;
	};

	CargoArray dat{};
	dat.Clear();
	AddAcceptedCargo(tile, dat, nullptr);
	if (!has_town_cargo(dat)) {
		/* nothing is accepted, so now test if cargo is produced */
		AddProducedCargo(tile, dat);
		if (!has_town_cargo(dat)) {
			/* still don't have town cargo, so give up */
			return ZONING_INVALID_SPRITE_ID;
		}
	}

	StationFinder stations(TileArea(tile, 1, 1));

	for (const Station *st : *stations.GetStations()) {
		if (st->owner == owner) {
			return ZONING_INVALID_SPRITE_ID;
		}
	}

	return SPR_ZONING_INNER_HIGHLIGHT_RED;
}

/**
 * Detect whether an industry is unserved by a station of owner.
 *
 * @param TileIndex tile
 * @param Owner owner
 * @return red if unserved, orange if only accepting, nothing if served or not
 *         a building
 */
SpriteID TileZoneCheckUnservedIndustriesEvaluation(TileIndex tile, Owner owner)
{
	if (IsTileType(tile, MP_INDUSTRY)) {
		const Industry *ind = Industry::GetByTile(tile);
		if (ind->neutral_station != nullptr) return ZONING_INVALID_SPRITE_ID;

		for (const Station *st : ind->stations_near) {
			if (st->owner == owner) {
				if (st->facilities & (~(FACIL_BUS_STOP | FACIL_TRUCK_STOP)) || st->facilities == (FACIL_BUS_STOP | FACIL_TRUCK_STOP)) {
					return ZONING_INVALID_SPRITE_ID;
				} else if (st->facilities & (FACIL_BUS_STOP | FACIL_TRUCK_STOP)) {
					for (uint i = 0; i < std::size(ind->produced_cargo); i++) {
						if (ind->produced_cargo[i] != INVALID_CARGO && st->facilities & (IsCargoInClass(ind->produced_cargo[i], CC_PASSENGERS) ? FACIL_BUS_STOP : FACIL_TRUCK_STOP)) {
							return ZONING_INVALID_SPRITE_ID;
						}
					}
					for (uint i = 0; i < std::size(ind->accepts_cargo); i++) {
						if (ind->accepts_cargo[i] != INVALID_CARGO && st->facilities & (IsCargoInClass(ind->accepts_cargo[i], CC_PASSENGERS) ? FACIL_BUS_STOP : FACIL_TRUCK_STOP)) {
							return ZONING_INVALID_SPRITE_ID;
						}
					}
				}
			}
		}

		return SPR_ZONING_INNER_HIGHLIGHT_RED;
	}

	return ZONING_INVALID_SPRITE_ID;
}

/**
 * Detect whether a tile is a restricted signal tile
 *
 * @param TileIndex tile
 * @param Owner owner
 * @return red if a restricted signal, nothing otherwise
 */
SpriteID TileZoneCheckTraceRestrictEvaluation(TileIndex tile, Owner owner)
{
	if (IsTileType(tile, MP_RAILWAY) && HasSignals(tile) && IsRestrictedSignal(tile)) {
		return SPR_ZONING_INNER_HIGHLIGHT_RED;
	}
	if (IsTunnelBridgeWithSignalSimulation(tile) && IsTunnelBridgeRestrictedSignal(tile)) {
		return SPR_ZONING_INNER_HIGHLIGHT_RED;
	}

	return ZONING_INVALID_SPRITE_ID;
}

/**
 * Detect whether a tile is a restricted signal tile
 *
 * @param TileIndex tile
 * @param Owner owner
 * @return red if a restricted signal, nothing otherwise
 */
inline SpriteID TileZoneCheckRoadGridEvaluation(TileIndex tile, uint grid_size)
{
	const bool x_grid = (TileX(tile) % grid_size == 0);
	const bool y_grid = (TileY(tile) % grid_size == 0);
	if (x_grid || y_grid) {
		return SPR_ZONING_INNER_HIGHLIGHT_LIGHT_BLUE;
	} else {
		return ZONING_INVALID_SPRITE_ID;
	}
}

/**
 * Detect whether a tile is a one way road
 *
 * @param TileIndex tile
 * @param Owner owner
 * @return red if a restricted signal, nothing otherwise
 */
inline SpriteID TileZoneCheckOneWayRoadEvaluation(TileIndex tile)
{
	if (!MayHaveRoad(tile)) return ZONING_INVALID_SPRITE_ID;

	RoadCachedOneWayState rcows = GetRoadCachedOneWayState(tile);
	switch (rcows) {
		default:
			return ZONING_INVALID_SPRITE_ID;
		case RCOWS_NO_ACCESS:
			return SPR_ZONING_INNER_HIGHLIGHT_RED;
		case RCOWS_NON_JUNCTION_A:
		case RCOWS_NON_JUNCTION_B:
			if (IsTileType(tile, MP_STATION)) {
				return SPR_ZONING_INNER_HIGHLIGHT_GREEN;
			} else if (IsNormalRoadTile(tile) && GetDisallowedRoadDirections(tile) != DRD_NONE) {
				return SPR_ZONING_INNER_HIGHLIGHT_LIGHT_BLUE;
			} else {
				return SPR_ZONING_INNER_HIGHLIGHT_PURPLE;
			}
		case RCOWS_SIDE_JUNCTION:
			return SPR_ZONING_INNER_HIGHLIGHT_ORANGE;
		case RCOWS_SIDE_JUNCTION_NO_EXIT:
			return SPR_ZONING_INNER_HIGHLIGHT_YELLOW;
	}
}

inline SpriteID TileZoneDebugWaterFlood(TileIndex tile)
{
	if (IsNonFloodingWaterTile(tile)) {
		return SPR_ZONING_INNER_HIGHLIGHT_YELLOW;
	}
	return ZONING_INVALID_SPRITE_ID;
}

inline SpriteID TileZoneDebugWaterRegion(TileIndex tile)
{
	extern uint GetWaterRegionTileDebugColourIndex(TileIndex tile);
	uint colour_index = GetWaterRegionTileDebugColourIndex(tile);
	if (colour_index == 0) {
		return ZONING_INVALID_SPRITE_ID;
	} else {
		return std::min<SpriteID>(SPR_ZONING_INNER_HIGHLIGHT_RED + colour_index - 1, SPR_ZONING_INNER_HIGHLIGHT_YELLOW);
	}
}

inline SpriteID TileZoneDebugTropicZone(TileIndex tile)
{
	switch (GetTropicZone(tile)) {
		case TROPICZONE_DESERT:
			return SPR_ZONING_INNER_HIGHLIGHT_YELLOW;
		case TROPICZONE_RAINFOREST:
			return SPR_ZONING_INNER_HIGHLIGHT_LIGHT_BLUE;
		default:
			return ZONING_INVALID_SPRITE_ID;
	}
}

inline SpriteID TileZoneDebugAnimatedTile(TileIndex tile)
{
	if (_animated_tiles.find(tile) != _animated_tiles.end()) {
		return SPR_ZONING_INNER_HIGHLIGHT_YELLOW;
	}
	return ZONING_INVALID_SPRITE_ID;
}

/**
 * General evaluation function; calls all the other functions depending on
 * evaluation mode.
 *
 * @param TileIndex tile
 *        Tile to be evaluated.
 * @param Owner owner
 *        The current player
 * @param ZoningEvaluationMode ev_mode
 *        The current evaluation mode.
 * @return The colour returned by the evaluation functions (none if no ev_mode).
 */
SpriteID TileZoningSpriteEvaluation(TileIndex tile, Owner owner, ZoningEvaluationMode ev_mode)
{
	switch (ev_mode) {
		case ZEM_CAN_BUILD:     return TileZoneCheckBuildEvaluation(tile, owner);
		case ZEM_AUTHORITY:     return TileZoneCheckOpinionEvaluation(tile, owner);
		case ZEM_STA_CATCH:     return TileZoneCheckStationCatchmentEvaluation(tile, owner, false);
		case ZEM_STA_CATCH_WIN: return TileZoneCheckStationCatchmentEvaluation(tile, owner, true);
		case ZEM_BUL_UNSER:     return TileZoneCheckUnservedBuildingsEvaluation(tile, owner);
		case ZEM_IND_UNSER:     return TileZoneCheckUnservedIndustriesEvaluation(tile, owner);
		case ZEM_TRACERESTRICT: return TileZoneCheckTraceRestrictEvaluation(tile, owner);
		case ZEM_2x2_GRID:      return TileZoneCheckRoadGridEvaluation(tile, 3);
		case ZEM_3x3_GRID:      return TileZoneCheckRoadGridEvaluation(tile, 4);
		case ZEM_ONE_WAY_ROAD:  return TileZoneCheckOneWayRoadEvaluation(tile);

		case ZEM_DBG_WATER_FLOOD:   return TileZoneDebugWaterFlood(tile);
		case ZEM_DBG_WATER_REGION:  return TileZoneDebugWaterRegion(tile);
		case ZEM_DBG_TROPIC_ZONE:   return TileZoneDebugTropicZone(tile);
		case ZEM_DBG_ANIMATED_TILE: return TileZoneDebugAnimatedTile(tile);

		default: return ZONING_INVALID_SPRITE_ID;
	}
}

inline SpriteID TileZoningSpriteEvaluationCached(TileIndex tile, Owner owner, ZoningEvaluationMode ev_mode, bool is_inner)
{
	if (owner == COMPANY_SPECTATOR && (ev_mode == ZEM_CAN_BUILD || (ev_mode >= ZEM_STA_CATCH && ev_mode <= ZEM_IND_UNSER))) return ZONING_INVALID_SPRITE_ID;
	if (ev_mode == ZEM_BUL_UNSER && !IsTileType(tile, MP_HOUSE)) return ZONING_INVALID_SPRITE_ID;
	if (ev_mode == ZEM_IND_UNSER && !IsTileType(tile, MP_INDUSTRY)) return ZONING_INVALID_SPRITE_ID;
	if (ev_mode >= ZEM_STA_CATCH && ev_mode <= ZEM_IND_UNSER) {
		// cacheable
		btree::btree_set<uint32_t> &cache = is_inner ? _zoning_cache_inner : _zoning_cache_outer;
		auto iter = cache.lower_bound(tile << 3);
		if (iter != cache.end() && *iter >> 3 == tile) {
			switch (*iter & 7) {
				case 0: return ZONING_INVALID_SPRITE_ID;
				case 1: return SPR_ZONING_INNER_HIGHLIGHT_RED;
				case 2: return SPR_ZONING_INNER_HIGHLIGHT_ORANGE;
				case 3: return SPR_ZONING_INNER_HIGHLIGHT_BLACK;
				case 4: return SPR_ZONING_INNER_HIGHLIGHT_LIGHT_BLUE;
				default: NOT_REACHED();
			}
		} else {
			SpriteID s = TileZoningSpriteEvaluation(tile, owner, ev_mode);
			uint val = tile << 3;
			switch (s) {
				case ZONING_INVALID_SPRITE_ID:              val |= 0; break;
				case SPR_ZONING_INNER_HIGHLIGHT_RED:        val |= 1; break;
				case SPR_ZONING_INNER_HIGHLIGHT_ORANGE:     val |= 2; break;
				case SPR_ZONING_INNER_HIGHLIGHT_BLACK:      val |= 3; break;
				case SPR_ZONING_INNER_HIGHLIGHT_LIGHT_BLUE: val |= 4; break;
				default: NOT_REACHED();
			}
			cache.insert(iter, val);
			return s;
		}
	} else {
		return TileZoningSpriteEvaluation(tile, owner, ev_mode);
	}
}

/**
 * Draw the the zoning on the tile.
 *
 * @param TileInfo ti
 *        the tile to draw on.
 */
void DrawTileZoning(const TileInfo *ti)
{
	if (IsTileType(ti->tile, MP_VOID) || _game_mode != GM_NORMAL) {
		return;
	}

	if (_zoning.outer != ZEM_NOTHING) {
		const SpriteID colour = TileZoningSpriteEvaluationCached(ti->tile, _local_company, _zoning.outer, false);

		if (colour != ZONING_INVALID_SPRITE_ID) {
			DrawTileSelectionRect(ti, colour);
		}
	}

	if (_zoning.inner != ZEM_NOTHING) {
		const SpriteID colour = TileZoningSpriteEvaluationCached(ti->tile, _local_company, _zoning.inner, true);

		if (colour != ZONING_INVALID_SPRITE_ID) {
			SpriteID sprite = SPR_ZONING_INNER_HIGHLIGHT_BASE;

			if (IsHalftileSlope(ti->tileh)) {
				const int INF = 1000;
				static const SubSprite sub_sprites[4] = {
					{ -INF    , -INF   , 32 - 33, INF     }, // CORNER_W, clip 33 pixels from right
					{ -INF    ,  0 + 22, INF    , INF     }, // CORNER_S, clip 22 pixels from top
					{ -31 + 34, -INF   , INF    , INF     }, // CORNER_E, clip 34 pixels from left
					{ -INF    , -INF   , INF    , 30 - 8  }  // CORNER_N, clip  8 pixels from bottom
				};

				DrawSelectionSprite(sprite, colour, ti, 7 + TILE_HEIGHT, FOUNDATION_PART_HALFTILE, 0, 0, &(sub_sprites[GetHalftileSlopeCorner(ti->tileh)]));
			} else {
				sprite += SlopeToSpriteOffset(ti->tileh);
			}
			DrawSelectionSprite(sprite, colour, ti, 7, FOUNDATION_PART_NORMAL);
		}
	}
}

static uint GetZoningModeDependantStationCoverageRadius(const Station *st, ZoningEvaluationMode ev_mode)
{
	switch (ev_mode) {
		case ZEM_STA_CATCH:      return st->GetCatchmentRadius();
		case ZEM_STA_CATCH_WIN:  return st->GetCatchmentRadius();
		case ZEM_BUL_UNSER:      return st->GetCatchmentRadius();
		case ZEM_IND_UNSER:      return st->GetCatchmentRadius() + 10; // this is to wholly update industries partially within the region
		default:                 return 0;
	}
}

/**
 * Mark dirty the coverage area around a station if the current zoning mode depends on station coverage
 *
 * @param const Station *st
 *        The station to use
 */
void ZoningMarkDirtyStationCoverageArea(const Station *st, ZoningModeMask mask)
{
	if (st->rect.IsEmpty()) return;

	uint outer_radius = mask & ZMM_OUTER ? GetZoningModeDependantStationCoverageRadius(st, _zoning.outer) : 0;
	uint inner_radius = mask & ZMM_INNER ? GetZoningModeDependantStationCoverageRadius(st, _zoning.inner) : 0;
	uint radius = std::max<uint>(outer_radius, inner_radius);

	extern const Station *_viewport_highlight_station;
	if (_viewport_highlight_station == st) {
		radius = std::max<uint>(radius, st->GetCatchmentRadius());
	}

	if (radius > 0) {
		Rect rect = st->GetCatchmentRectUsingRadius(radius);
		for (int y = rect.top; y <= rect.bottom; y++) {
			for (int x = rect.left; x <= rect.right; x++) {
				MarkTileDirtyByTile(TileXY(x, y), VMDF_NOT_MAP_MODE);
			}
		}
		auto invalidate_cache_rect = [&](btree::btree_set<uint32_t> &cache) {
			for (int y = rect.top; y <= rect.bottom; y++) {
				auto iter = cache.lower_bound(TileXY(rect.left, y) << 3);
				auto end_iter = iter;
				uint end = (TileXY(rect.right, y) + 1) << 3;
				while (end_iter != cache.end() && *end_iter < end) ++end_iter;
				cache.erase(iter, end_iter);
			}
		};
		if (outer_radius) invalidate_cache_rect(_zoning_cache_outer);
		if (inner_radius) invalidate_cache_rect(_zoning_cache_inner);
	}
}

void ZoningStationWindowOpenClose(const Station *st)
{
	ZoningModeMask mask = ZMM_NOTHING;
	if (_zoning.inner == ZEM_STA_CATCH_WIN) mask |= ZMM_INNER;
	if (_zoning.outer == ZEM_STA_CATCH_WIN) mask |= ZMM_OUTER;
	if (mask != ZMM_NOTHING) ZoningMarkDirtyStationCoverageArea(st, mask);
}

void ZoningTownAuthorityRatingChange()
{
	ZoningModeMask mask = ZMM_NOTHING;
	if (_zoning.inner == ZEM_AUTHORITY) mask |= ZMM_INNER;
	if (_zoning.outer == ZEM_AUTHORITY) mask |= ZMM_OUTER;
	if (mask != ZMM_NOTHING) {
		MarkWholeNonMapViewportsDirty();
	}
}

void ClearZoningCaches()
{
	_zoning_cache_inner.clear();
	_zoning_cache_outer.clear();
}

void SetZoningMode(bool inner, ZoningEvaluationMode mode)
{
	ZoningEvaluationMode &current_mode = inner ? _zoning.inner : _zoning.outer;
	btree::btree_set<uint32_t> &cache = inner ? _zoning_cache_inner : _zoning_cache_outer;

	if (current_mode == mode) return;

	current_mode = mode;
	cache.clear();
	MarkWholeNonMapViewportsDirty();
	PostZoningModeChange();
}

void PostZoningModeChange()
{
	extern bool _mark_tile_dirty_on_road_cache_one_way_state_update;
	_mark_tile_dirty_on_road_cache_one_way_state_update = (_zoning.inner == ZEM_ONE_WAY_ROAD) || (_zoning.outer == ZEM_ONE_WAY_ROAD);
}