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https://github.com/JGRennison/OpenTTD-patches.git
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a6ea1ea408
Add setting
361 lines
12 KiB
C++
361 lines
12 KiB
C++
/* $Id$ */
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/*
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* This file is part of OpenTTD.
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* 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.
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* 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.
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* 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/>.
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*/
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/** @file src/roadveh.h Road vehicle states */
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#ifndef ROADVEH_H
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#define ROADVEH_H
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#include "ground_vehicle.hpp"
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#include "engine_base.h"
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#include "cargotype.h"
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#include "track_func.h"
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#include "road_type.h"
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#include "newgrf_engine.h"
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#include <deque>
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struct RoadVehicle;
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/** Road vehicle states */
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enum RoadVehicleStates {
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/*
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* Lower 4 bits are used for vehicle track direction. (Trackdirs)
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* When in a road stop (bit 5 or bit 6 set) these bits give the
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* track direction of the entry to the road stop.
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* As the entry direction will always be a diagonal
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* direction (X_NE, Y_SE, X_SW or Y_NW) only bits 0 and 3
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* are needed to hold this direction. Bit 1 is then used to show
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* that the vehicle is using the second road stop bay.
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* Bit 2 is then used for drive-through stops to show the vehicle
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* is stopping at this road stop.
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*/
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/* Numeric values */
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RVSB_IN_DEPOT = 0xFE, ///< The vehicle is in a depot
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RVSB_WORMHOLE = 0xFF, ///< The vehicle is in a tunnel and/or bridge
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/* Bit numbers */
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RVS_USING_SECOND_BAY = 1, ///< Only used while in a road stop
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RVS_ENTERED_STOP = 2, ///< Only set when a vehicle has entered the stop
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RVS_DRIVE_SIDE = 4, ///< Only used when retrieving move data
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RVS_IN_ROAD_STOP = 5, ///< The vehicle is in a road stop
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RVS_IN_DT_ROAD_STOP = 6, ///< The vehicle is in a drive-through road stop
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/* Bit sets of the above specified bits */
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RVSB_IN_ROAD_STOP = 1 << RVS_IN_ROAD_STOP, ///< The vehicle is in a road stop
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RVSB_IN_ROAD_STOP_END = RVSB_IN_ROAD_STOP + TRACKDIR_END,
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RVSB_IN_DT_ROAD_STOP = 1 << RVS_IN_DT_ROAD_STOP, ///< The vehicle is in a drive-through road stop
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RVSB_IN_DT_ROAD_STOP_END = RVSB_IN_DT_ROAD_STOP + TRACKDIR_END,
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RVSB_DRIVE_SIDE = 1 << RVS_DRIVE_SIDE, ///< The vehicle is at the opposite side of the road
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RVSB_TRACKDIR_MASK = 0x0F, ///< The mask used to extract track dirs
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RVSB_ROAD_STOP_TRACKDIR_MASK = 0x09, ///< Only bits 0 and 3 are used to encode the trackdir for road stops
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};
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/** State information about the Road Vehicle controller */
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static const uint RDE_NEXT_TILE = 0x80; ///< We should enter the next tile
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static const uint RDE_TURNED = 0x40; ///< We just finished turning
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/* Start frames for when a vehicle enters a tile/changes its state.
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* The start frame is different for vehicles that turned around or
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* are leaving the depot as the do not start at the edge of the tile.
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* For trams there are a few different start frames as there are two
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* places where trams can turn. */
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static const uint RVC_DEFAULT_START_FRAME = 0;
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static const uint RVC_TURN_AROUND_START_FRAME = 1;
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static const uint RVC_DEPOT_START_FRAME = 6;
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static const uint RVC_START_FRAME_AFTER_LONG_TRAM = 21;
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static const uint RVC_TURN_AROUND_START_FRAME_SHORT_TRAM = 16;
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/* Stop frame for a vehicle in a drive-through stop */
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static const uint RVC_DRIVE_THROUGH_STOP_FRAME = 11;
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static const uint RVC_DEPOT_STOP_FRAME = 11;
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/** The number of ticks a vehicle has for overtaking. */
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static const byte RV_OVERTAKE_TIMEOUT = 35;
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void RoadVehUpdateCache(RoadVehicle *v, bool same_length = false);
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void GetRoadVehSpriteSize(EngineID engine, uint &width, uint &height, int &xoffs, int &yoffs, EngineImageType image_type);
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struct RoadVehPathCache {
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std::deque<TrackdirByte> td;
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std::deque<TileIndex> tile;
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inline bool empty() const { return this->td.empty(); }
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inline size_t size() const
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{
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assert(this->td.size() == this->tile.size());
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return this->td.size();
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}
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inline void clear()
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{
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this->td.clear();
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this->tile.clear();
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}
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};
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/**
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* Buses, trucks and trams belong to this class.
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*/
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struct RoadVehicle FINAL : public GroundVehicle<RoadVehicle, VEH_ROAD> {
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RoadVehPathCache path; ///< Cached path.
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byte state; ///< @see RoadVehicleStates
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byte frame;
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uint16 blocked_ctr;
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byte overtaking; ///< Set to #RVSB_DRIVE_SIDE when overtaking, otherwise 0.
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byte overtaking_ctr; ///< The length of the current overtake attempt.
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uint16 crashed_ctr; ///< Animation counter when the vehicle has crashed. @see RoadVehIsCrashed
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byte reverse_ctr;
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RoadType roadtype;
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RoadTypes compatible_roadtypes;
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byte critical_breakdown_count; ///< Counter for the number of critical breakdowns since last service
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/** We don't want GCC to zero our struct! It already is zeroed and has an index! */
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RoadVehicle() : GroundVehicleBase() {}
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/** We want to 'destruct' the right class. */
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virtual ~RoadVehicle() { this->PreDestructor(); }
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friend struct GroundVehicle<RoadVehicle, VEH_ROAD>; // GroundVehicle needs to use the acceleration functions defined at RoadVehicle.
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void MarkDirty();
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void UpdateDeltaXY();
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ExpensesType GetExpenseType(bool income) const { return income ? EXPENSES_ROADVEH_INC : EXPENSES_ROADVEH_RUN; }
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bool IsPrimaryVehicle() const { return this->IsFrontEngine(); }
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void GetImage(Direction direction, EngineImageType image_type, VehicleSpriteSeq *result) const;
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int GetDisplaySpeed() const { return this->gcache.last_speed / 2; }
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int GetDisplayMaxSpeed() const { return this->vcache.cached_max_speed / 2; }
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Money GetRunningCost() const;
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int GetDisplayImageWidth(Point *offset = nullptr) const;
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bool IsInDepot() const { return this->state == RVSB_IN_DEPOT; }
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bool Tick();
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void OnNewDay();
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uint Crash(bool flooded = false);
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Trackdir GetVehicleTrackdir() const;
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TileIndex GetOrderStationLocation(StationID station);
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bool FindClosestDepot(TileIndex *location, DestinationID *destination, bool *reverse);
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bool IsBus() const;
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int GetCurrentMaxSpeed() const;
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int GetEffectiveMaxSpeed() const;
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int GetDisplayEffectiveMaxSpeed() const { return this->GetEffectiveMaxSpeed() / 2; }
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int UpdateSpeed();
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void SetDestTile(TileIndex tile);
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inline bool IsRoadVehicleOnLevelCrossing() const
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{
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for (const RoadVehicle *u = this; u != nullptr; u = u->Next()) {
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if (IsLevelCrossingTile(u->tile)) return true;
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}
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return false;
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}
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inline bool IsRoadVehicleStopped() const
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{
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if (!(this->vehstatus & VS_STOPPED)) return false;
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return !this->IsRoadVehicleOnLevelCrossing();
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}
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inline uint GetOvertakingCounterThreshold() const
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{
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return RV_OVERTAKE_TIMEOUT + (this->gcache.cached_total_length / 2) - (VEHICLE_LENGTH / 2);
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}
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inline void SetRoadVehicleOvertaking(byte overtaking)
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{
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for (RoadVehicle *u = this; u != nullptr; u = u->Next()) {
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u->overtaking = overtaking;
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}
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}
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protected: // These functions should not be called outside acceleration code.
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/**
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* Allows to know the power value that this vehicle will use.
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* @return Power value from the engine in HP, or zero if the vehicle is not powered.
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*/
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inline uint16 GetPower() const
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{
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/* Power is not added for articulated parts */
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if (!this->IsArticulatedPart()) {
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/* Road vehicle power is in units of 10 HP. */
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return 10 * GetVehicleProperty(this, PROP_ROADVEH_POWER, RoadVehInfo(this->engine_type)->power);
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}
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return 0;
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}
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/**
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* Returns a value if this articulated part is powered.
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* @return Zero, because road vehicles don't have powered parts.
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*/
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inline uint16 GetPoweredPartPower(const RoadVehicle *head) const
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{
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return 0;
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}
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/**
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* Allows to know the weight value that this vehicle will use.
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* @return Weight value from the engine in tonnes.
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*/
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inline uint16 GetWeight() const
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{
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uint16 weight = (CargoSpec::Get(this->cargo_type)->weight * this->cargo.StoredCount()) / 16;
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/* Vehicle weight is not added for articulated parts. */
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if (!this->IsArticulatedPart()) {
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/* Road vehicle weight is in units of 1/4 t. */
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weight += GetVehicleProperty(this, PROP_ROADVEH_WEIGHT, RoadVehInfo(this->engine_type)->weight) / 4;
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/*
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* TODO: DIRTY HACK: at least 1 for realistic accelerate
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*/
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if (weight == 0) weight = 1;
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}
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return weight;
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}
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/**
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* Allows to know the tractive effort value that this vehicle will use.
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* @return Tractive effort value from the engine.
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*/
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inline byte GetTractiveEffort() const
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{
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/* The tractive effort coefficient is in units of 1/256. */
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return GetVehicleProperty(this, PROP_ROADVEH_TRACTIVE_EFFORT, RoadVehInfo(this->engine_type)->tractive_effort);
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}
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/**
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* Gets the area used for calculating air drag.
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* @return Area of the engine in m^2.
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*/
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inline byte GetAirDragArea() const
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{
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return 6;
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}
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/**
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* Gets the air drag coefficient of this vehicle.
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* @return Air drag value from the engine.
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*/
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inline byte GetAirDrag() const
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{
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return RoadVehInfo(this->engine_type)->air_drag;
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}
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/**
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* Checks the current acceleration status of this vehicle.
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* @return Acceleration status.
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*/
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inline AccelStatus GetAccelerationStatus() const
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{
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return this->IsRoadVehicleStopped() ? AS_BRAKE : AS_ACCEL;
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}
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/**
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* Calculates the current speed of this vehicle.
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* @return Current speed in km/h-ish.
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*/
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inline uint16 GetCurrentSpeed() const
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{
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return this->cur_speed / 2;
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}
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/**
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* Returns the rolling friction coefficient of this vehicle.
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* @return Rolling friction coefficient in [1e-4].
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*/
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inline uint32 GetRollingFriction() const
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{
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/* Trams have a slightly greater friction coefficient than trains.
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* The rest of road vehicles have bigger values. */
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uint32 coeff = (this->roadtype == ROADTYPE_TRAM) ? 40 : 75;
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/* The friction coefficient increases with speed in a way that
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* it doubles at 128 km/h, triples at 256 km/h and so on. */
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return coeff * (128 + this->GetCurrentSpeed()) / 128;
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}
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/**
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* Allows to know the acceleration type of a vehicle.
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* @return Zero, road vehicles always use a normal acceleration method.
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*/
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inline int GetAccelerationType() const
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{
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return 0;
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}
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/**
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* Returns the slope steepness used by this vehicle.
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* @return Slope steepness used by the vehicle.
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*/
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inline uint32 GetSlopeSteepness() const
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{
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return _settings_game.vehicle.roadveh_slope_steepness;
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}
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/**
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* Gets the maximum speed allowed by the track for this vehicle.
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* @return Since roads don't limit road vehicle speed, it returns always zero.
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*/
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inline uint16 GetMaxTrackSpeed() const
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{
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return 0;
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}
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/**
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* Checks if the vehicle is at a tile that can be sloped.
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* @return True if the tile can be sloped.
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*/
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inline bool TileMayHaveSlopedTrack() const
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{
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TrackStatus ts = GetTileTrackStatus(this->tile, TRANSPORT_ROAD, this->compatible_roadtypes);
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TrackBits trackbits = TrackStatusToTrackBits(ts);
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return trackbits == TRACK_BIT_X || trackbits == TRACK_BIT_Y;
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}
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/**
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* Road vehicles have to use GetSlopePixelZ() to compute their height
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* if they are reversing because in that case, their direction
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* is not parallel with the road. It is safe to return \c true
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* even if it is not reversing.
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* @return are we (possibly) reversing?
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*/
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inline bool HasToUseGetSlopePixelZ()
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{
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const RoadVehicle *rv = this->First();
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/* Check if this vehicle is in the same direction as the road under.
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* We already know it has either GVF_GOINGUP_BIT or GVF_GOINGDOWN_BIT set. */
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if (rv->state <= RVSB_TRACKDIR_MASK && IsReversingRoadTrackdir((Trackdir)rv->state)) {
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/* If the first vehicle is reversing, this vehicle may be reversing too
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* (especially if this is the first, and maybe the only, vehicle).*/
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return true;
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}
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while (rv != this) {
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/* If any previous vehicle has different direction,
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* we may be in the middle of reversing. */
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if (this->direction != rv->direction) return true;
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rv = rv->Next();
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}
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return false;
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}
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};
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#define FOR_ALL_ROADVEHICLES(var) FOR_ALL_VEHICLES_OF_TYPE(RoadVehicle, var)
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#endif /* ROADVEH_H */
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