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OpenTTD/src/vehicle_base.h

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/*
* 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 vehicle_base.h Base class for all vehicles. */
#ifndef VEHICLE_BASE_H
#define VEHICLE_BASE_H
#include "track_type.h"
#include "command_type.h"
#include "order_base.h"
#include "cargopacket.h"
#include "texteff.hpp"
#include "engine_type.h"
#include "order_func.h"
#include "transport_type.h"
#include "group_type.h"
#include "base_consist.h"
#include "network/network.h"
#include "saveload/saveload.h"
#include "timer/timer_game_calendar.h"
#include "core/mem_func.hpp"
const uint TILE_AXIAL_DISTANCE = 192; // Logical length of the tile in any DiagDirection used in vehicle movement.
const uint TILE_CORNER_DISTANCE = 128; // Logical length of the tile corner crossing in any non-diagonal direction used in vehicle movement.
/** Vehicle status bits in #Vehicle::vehstatus. */
enum VehStatus {
VS_HIDDEN = 0x01, ///< Vehicle is not visible.
VS_STOPPED = 0x02, ///< Vehicle is stopped by the player.
VS_UNCLICKABLE = 0x04, ///< Vehicle is not clickable by the user (shadow vehicles).
VS_DEFPAL = 0x08, ///< Use default vehicle palette. @see DoDrawVehicle
VS_TRAIN_SLOWING = 0x10, ///< Train is slowing down.
VS_SHADOW = 0x20, ///< Vehicle is a shadow vehicle.
VS_AIRCRAFT_BROKEN = 0x40, ///< Aircraft is broken down.
VS_CRASHED = 0x80, ///< Vehicle is crashed.
};
/** Bit numbers in #Vehicle::vehicle_flags. */
enum VehicleFlags {
VF_LOADING_FINISHED, ///< Vehicle has finished loading.
VF_CARGO_UNLOADING, ///< Vehicle is unloading cargo.
VF_BUILT_AS_PROTOTYPE, ///< Vehicle is a prototype (accepted as exclusive preview).
VF_TIMETABLE_STARTED, ///< Whether the vehicle has started running on the timetable yet.
VF_AUTOFILL_TIMETABLE, ///< Whether the vehicle should fill in the timetable automatically.
VF_AUTOFILL_PRES_WAIT_TIME, ///< Whether non-destructive auto-fill should preserve waiting times
VF_STOP_LOADING, ///< Don't load anymore during the next load cycle.
VF_PATHFINDER_LOST, ///< Vehicle's pathfinder is lost.
VF_SERVINT_IS_CUSTOM, ///< Service interval is custom.
VF_SERVINT_IS_PERCENT, ///< Service interval is percent.
};
/** Bit numbers used to indicate which of the #NewGRFCache values are valid. */
enum NewGRFCacheValidValues {
NCVV_POSITION_CONSIST_LENGTH = 0, ///< This bit will be set if the NewGRF var 40 currently stored is valid.
NCVV_POSITION_SAME_ID_LENGTH = 1, ///< This bit will be set if the NewGRF var 41 currently stored is valid.
NCVV_CONSIST_CARGO_INFORMATION = 2, ///< This bit will be set if the NewGRF var 42 currently stored is valid.
NCVV_COMPANY_INFORMATION = 3, ///< This bit will be set if the NewGRF var 43 currently stored is valid.
NCVV_POSITION_IN_VEHICLE = 4, ///< This bit will be set if the NewGRF var 4D currently stored is valid.
NCVV_END, ///< End of the bits.
};
/** Cached often queried (NewGRF) values */
struct NewGRFCache {
/* Values calculated when they are requested for the first time after invalidating the NewGRF cache. */
uint32_t position_consist_length; ///< Cache for NewGRF var 40.
uint32_t position_same_id_length; ///< Cache for NewGRF var 41.
uint32_t consist_cargo_information; ///< Cache for NewGRF var 42. (Note: The cargotype is untranslated in the cache because the accessing GRF is yet unknown.)
uint32_t company_information; ///< Cache for NewGRF var 43.
uint32_t position_in_vehicle; ///< Cache for NewGRF var 4D.
uint8_t cache_valid; ///< Bitset that indicates which cache values are valid.
auto operator<=>(const NewGRFCache &) const = default;
};
/** Meaning of the various bits of the visual effect. */
enum VisualEffect {
VE_OFFSET_START = 0, ///< First bit that contains the offset (0 = front, 8 = centre, 15 = rear)
VE_OFFSET_COUNT = 4, ///< Number of bits used for the offset
VE_OFFSET_CENTRE = 8, ///< Value of offset corresponding to a position above the centre of the vehicle
VE_TYPE_START = 4, ///< First bit used for the type of effect
VE_TYPE_COUNT = 2, ///< Number of bits used for the effect type
VE_TYPE_DEFAULT = 0, ///< Use default from engine class
VE_TYPE_STEAM = 1, ///< Steam plumes
VE_TYPE_DIESEL = 2, ///< Diesel fumes
VE_TYPE_ELECTRIC = 3, ///< Electric sparks
VE_DISABLE_EFFECT = 6, ///< Flag to disable visual effect
VE_ADVANCED_EFFECT = VE_DISABLE_EFFECT, ///< Flag for advanced effects
VE_DISABLE_WAGON_POWER = 7, ///< Flag to disable wagon power
VE_DEFAULT = 0xFF, ///< Default value to indicate that visual effect should be based on engine class
};
/** Models for spawning visual effects. */
enum VisualEffectSpawnModel {
VESM_NONE = 0, ///< No visual effect
VESM_STEAM, ///< Steam model
VESM_DIESEL, ///< Diesel model
VESM_ELECTRIC, ///< Electric model
VESM_END
};
/**
* Enum to handle ground vehicle subtypes.
* This is defined here instead of at #GroundVehicle because some common function require access to these flags.
* Do not access it directly unless you have to. Use the subtype access functions.
*/
enum GroundVehicleSubtypeFlags {
GVSF_FRONT = 0, ///< Leading engine of a consist.
GVSF_ARTICULATED_PART = 1, ///< Articulated part of an engine.
GVSF_WAGON = 2, ///< Wagon (not used for road vehicles).
GVSF_ENGINE = 3, ///< Engine that can be front engine, but might be placed behind another engine (not used for road vehicles).
GVSF_FREE_WAGON = 4, ///< First in a wagon chain (in depot) (not used for road vehicles).
GVSF_MULTIHEADED = 5, ///< Engine is multiheaded (not used for road vehicles).
};
/** Cached often queried values common to all vehicles. */
struct VehicleCache {
uint16_t cached_max_speed; ///< Maximum speed of the consist (minimum of the max speed of all vehicles in the consist).
uint16_t cached_cargo_age_period; ///< Number of ticks before carried cargo is aged.
uint8_t cached_vis_effect; ///< Visual effect to show (see #VisualEffect)
auto operator<=>(const VehicleCache &) const = default;
};
/** Sprite sequence for a vehicle part. */
struct VehicleSpriteSeq {
PalSpriteID seq[8];
uint count;
bool operator==(const VehicleSpriteSeq &other) const
{
return this->count == other.count && MemCmpT<PalSpriteID>(this->seq, other.seq, this->count) == 0;
}
bool operator!=(const VehicleSpriteSeq &other) const
{
return !this->operator==(other);
}
/**
* Check whether the sequence contains any sprites.
*/
bool IsValid() const
{
return this->count != 0;
}
/**
* Clear all information.
*/
void Clear()
{
this->count = 0;
}
/**
* Assign a single sprite to the sequence.
*/
void Set(SpriteID sprite)
{
this->count = 1;
this->seq[0].sprite = sprite;
this->seq[0].pal = 0;
}
/**
* Copy data from another sprite sequence, while dropping all recolouring information.
*/
void CopyWithoutPalette(const VehicleSpriteSeq &src)
{
this->count = src.count;
for (uint i = 0; i < src.count; ++i) {
this->seq[i].sprite = src.seq[i].sprite;
this->seq[i].pal = 0;
}
}
void GetBounds(Rect *bounds) const;
void Draw(int x, int y, PaletteID default_pal, bool force_pal) const;
};
/**
* Cache for vehicle sprites and values relating to whether they should be updated before drawing,
* or calculating the viewport.
*/
struct MutableSpriteCache {
Direction last_direction; ///< Last direction we obtained sprites for
bool revalidate_before_draw; ///< We need to do a GetImage() and check bounds before drawing this sprite
bool is_viewport_candidate; ///< This vehicle can potentially be drawn on a viewport
Rect old_coord; ///< Co-ordinates from the last valid bounding box
VehicleSpriteSeq sprite_seq; ///< Vehicle appearance.
};
/** A vehicle pool for a little over 1 million vehicles. */
typedef Pool<Vehicle, VehicleID, 512, 0xFF000> VehiclePool;
extern VehiclePool _vehicle_pool;
/* Some declarations of functions, so we can make them friendly */
struct GroundVehicleCache;
struct LoadgameState;
extern bool LoadOldVehicle(LoadgameState *ls, int num);
extern void FixOldVehicles();
struct GRFFile;
/**
* Simulated cargo type and capacity for prediction of future links.
*/
struct RefitDesc {
CargoID cargo; ///< Cargo type the vehicle will be carrying.
uint16_t capacity; ///< Capacity the vehicle will have.
uint16_t remaining; ///< Capacity remaining from before the previous refit.
RefitDesc(CargoID cargo, uint16_t capacity, uint16_t remaining) :
cargo(cargo), capacity(capacity), remaining(remaining) {}
};
/**
* Structure to return information about the closest depot location,
* and whether it could be found.
*/
struct ClosestDepot {
TileIndex location;
DestinationID destination; ///< The DestinationID as used for orders.
bool reverse;
bool found;
ClosestDepot() :
location(INVALID_TILE), destination(0), reverse(false), found(false) {}
ClosestDepot(TileIndex location, DestinationID destination, bool reverse = false) :
location(location), destination(destination), reverse(reverse), found(true) {}
};
/** %Vehicle data structure. */
struct Vehicle : VehiclePool::PoolItem<&_vehicle_pool>, BaseVehicle, BaseConsist {
private:
typedef std::list<RefitDesc> RefitList;
Vehicle *next; ///< pointer to the next vehicle in the chain
Vehicle *previous; ///< NOSAVE: pointer to the previous vehicle in the chain
Vehicle *first; ///< NOSAVE: pointer to the first vehicle in the chain
Vehicle *next_shared; ///< pointer to the next vehicle that shares the order
Vehicle *previous_shared; ///< NOSAVE: pointer to the previous vehicle in the shared order chain
public:
friend void FixOldVehicles();
friend void AfterLoadVehicles(bool part_of_load); ///< So we can set the #previous and #first pointers while loading
friend bool LoadOldVehicle(LoadgameState *ls, int num); ///< So we can set the proper next pointer while loading
/* So we can use private/protected variables in the saveload code */
friend class SlVehicleCommon;
friend class SlVehicleDisaster;
friend void Ptrs_VEHS();
TileIndex tile; ///< Current tile index
/**
* Heading for this tile.
* For airports and train stations this tile does not necessarily belong to the destination station,
* but it can be used for heuristic purposes to estimate the distance.
*/
TileIndex dest_tile;
Money profit_this_year; ///< Profit this year << 8, low 8 bits are fract
Money profit_last_year; ///< Profit last year << 8, low 8 bits are fract
Money value; ///< Value of the vehicle
CargoPayment *cargo_payment; ///< The cargo payment we're currently in
mutable Rect coord; ///< NOSAVE: Graphical bounding box of the vehicle, i.e. what to redraw on moves.
Vehicle *hash_viewport_next; ///< NOSAVE: Next vehicle in the visual location hash.
Vehicle **hash_viewport_prev; ///< NOSAVE: Previous vehicle in the visual location hash.
Vehicle *hash_tile_next; ///< NOSAVE: Next vehicle in the tile location hash.
Vehicle **hash_tile_prev; ///< NOSAVE: Previous vehicle in the tile location hash.
Vehicle **hash_tile_current; ///< NOSAVE: Cache of the current hash chain.
SpriteID colourmap; ///< NOSAVE: cached colour mapping
/* Related to age and service time */
TimerGameCalendar::Year build_year; ///< Year the vehicle has been built.
TimerGameCalendar::Date age; ///< Age in calendar days.
TimerGameEconomy::Date economy_age; ///< Age in economy days.
TimerGameCalendar::Date max_age; ///< Maximum age
TimerGameEconomy::Date date_of_last_service; ///< Last economy date the vehicle had a service at a depot.
TimerGameCalendar::Date date_of_last_service_newgrf; ///< Last calendar date the vehicle had a service at a depot, unchanged by the date cheat to protect against unsafe NewGRF behavior.
uint16_t reliability; ///< Reliability.
uint16_t reliability_spd_dec; ///< Reliability decrease speed.
uint8_t breakdown_ctr; ///< Counter for managing breakdown events. @see Vehicle::HandleBreakdown
uint8_t breakdown_delay; ///< Counter for managing breakdown length.
uint8_t breakdowns_since_last_service; ///< Counter for the amount of breakdowns.
uint8_t breakdown_chance; ///< Current chance of breakdowns.
int32_t x_pos; ///< x coordinate.
int32_t y_pos; ///< y coordinate.
int32_t z_pos; ///< z coordinate.
Direction direction; ///< facing
Owner owner; ///< Which company owns the vehicle?
/**
* currently displayed sprite index
* 0xfd == custom sprite, 0xfe == custom second head sprite
* 0xff == reserved for another custom sprite
*/
uint8_t spritenum;
uint8_t x_extent; ///< x-extent of vehicle bounding box
uint8_t y_extent; ///< y-extent of vehicle bounding box
uint8_t z_extent; ///< z-extent of vehicle bounding box
int8_t x_bb_offs; ///< x offset of vehicle bounding box
int8_t y_bb_offs; ///< y offset of vehicle bounding box
int8_t x_offs; ///< x offset for vehicle sprite
int8_t y_offs; ///< y offset for vehicle sprite
EngineID engine_type; ///< The type of engine used for this vehicle.
TextEffectID fill_percent_te_id; ///< a text-effect id to a loading indicator object
UnitID unitnumber; ///< unit number, for display purposes only
uint16_t cur_speed; ///< current speed
uint8_t subspeed; ///< fractional speed
uint8_t acceleration; ///< used by train & aircraft
uint32_t motion_counter; ///< counter to occasionally play a vehicle sound.
uint8_t progress; ///< The percentage (if divided by 256) this vehicle already crossed the tile unit.
uint8_t waiting_triggers; ///< Triggers to be yet matched before rerandomizing the random bits.
uint16_t random_bits; ///< Bits used for randomized variational spritegroups.
StationID last_station_visited; ///< The last station we stopped at.
StationID last_loading_station; ///< Last station the vehicle has stopped at and could possibly leave from with any cargo loaded.
TimerGameTick::TickCounter last_loading_tick; ///< Last TimerGameTick::counter tick that the vehicle has stopped at a station and could possibly leave with any cargo loaded.
VehicleCargoList cargo; ///< The cargo this vehicle is carrying
CargoID cargo_type; ///< type of cargo this vehicle is carrying
uint8_t cargo_subtype; ///< Used for livery refits (NewGRF variations)
uint16_t cargo_cap; ///< total capacity
uint16_t refit_cap; ///< Capacity left over from before last refit.
uint16_t cargo_age_counter; ///< Ticks till cargo is aged next.
int8_t trip_occupancy; ///< NOSAVE: Occupancy of vehicle of the current trip (updated after leaving a station).
uint8_t day_counter; ///< Increased by one for each day
uint8_t tick_counter; ///< Increased by one for each tick
uint8_t running_ticks; ///< Number of ticks this vehicle was not stopped this day
uint16_t load_unload_ticks; ///< Ticks to wait before starting next cycle.
uint8_t vehstatus; ///< Status
uint8_t subtype; ///< subtype (Filled with values from #AircraftSubType/#DisasterSubType/#EffectVehicleType/#GroundVehicleSubtypeFlags)
Order current_order; ///< The current order (+ status, like: loading)
union {
OrderList *orders; ///< Pointer to the order list for this vehicle
Order *old_orders; ///< Only used during conversion of old save games
};
NewGRFCache grf_cache; ///< Cache of often used calculated NewGRF values
VehicleCache vcache; ///< Cache of often used vehicle values.
GroupID group_id; ///< Index of group Pool array
mutable MutableSpriteCache sprite_cache; ///< Cache of sprites and values related to recalculating them, see #MutableSpriteCache
/**
* Calculates the weight value that this vehicle will have when fully loaded with its current cargo.
* @return Weight value in tonnes.
*/
virtual uint16_t GetMaxWeight() const
{
return 0;
}
Vehicle(VehicleType type = VEH_INVALID);
void PreDestructor();
/** We want to 'destruct' the right class. */
virtual ~Vehicle();
void BeginLoading();
void CancelReservation(StationID next, Station *st);
void LeaveStation();
GroundVehicleCache *GetGroundVehicleCache();
const GroundVehicleCache *GetGroundVehicleCache() const;
uint16_t &GetGroundVehicleFlags();
const uint16_t &GetGroundVehicleFlags() const;
void DeleteUnreachedImplicitOrders();
void HandleLoading(bool mode = false);
/**
* Marks the vehicles to be redrawn and updates cached variables
*
* This method marks the area of the vehicle on the screen as dirty.
* It can be use to repaint the vehicle.
*
* @ingroup dirty
*/
virtual void MarkDirty() {}
/**
* Updates the x and y offsets and the size of the sprite used
* for this vehicle.
*/
virtual void UpdateDeltaXY() {}
/**
* Determines the effective direction-specific vehicle movement speed.
*
* This method belongs to the old vehicle movement method:
* A vehicle moves a step every 256 progress units.
* The vehicle speed is scaled by 3/4 when moving in X or Y direction due to the longer distance.
*
* However, this method is slightly wrong in corners, as the leftover progress is not scaled correctly
* when changing movement direction. #GetAdvanceSpeed() and #GetAdvanceDistance() are better wrt. this.
*
* @param speed Direction-independent unscaled speed.
* @return speed scaled by movement direction. 256 units are required for each movement step.
*/
inline uint GetOldAdvanceSpeed(uint speed)
{
return (this->direction & 1) ? speed : speed * 3 / 4;
}
/**
* Determines the effective vehicle movement speed.
*
* Together with #GetAdvanceDistance() this function is a replacement for #GetOldAdvanceSpeed().
*
* A vehicle progresses independent of it's movement direction.
* However different amounts of "progress" are needed for moving a step in a specific direction.
* That way the leftover progress does not need any adaption when changing movement direction.
*
* @param speed Direction-independent unscaled speed.
* @return speed, scaled to match #GetAdvanceDistance().
*/
static inline uint GetAdvanceSpeed(uint speed)
{
return speed * 3 / 4;
}
/**
* Determines the vehicle "progress" needed for moving a step.
*
* Together with #GetAdvanceSpeed() this function is a replacement for #GetOldAdvanceSpeed().
*
* @return distance to drive for a movement step on the map.
*/
inline uint GetAdvanceDistance()
{
return (this->direction & 1) ? TILE_AXIAL_DISTANCE : TILE_CORNER_DISTANCE * 2;
}
/**
* Sets the expense type associated to this vehicle type
* @param income whether this is income or (running) expenses of the vehicle
*/
virtual ExpensesType GetExpenseType([[maybe_unused]] bool income) const { return EXPENSES_OTHER; }
/**
* Play the sound associated with leaving the station
* @param force Should we play the sound even if sound effects are muted? (horn hotkey)
*/
virtual void PlayLeaveStationSound([[maybe_unused]] bool force = false) const {}
/**
* Whether this is the primary vehicle in the chain.
*/
virtual bool IsPrimaryVehicle() const { return false; }
const Engine *GetEngine() const;
/**
* Gets the sprite to show for the given direction
* @param direction the direction the vehicle is facing
* @param[out] result Vehicle sprite sequence.
*/
virtual void GetImage([[maybe_unused]] Direction direction, [[maybe_unused]] EngineImageType image_type, [[maybe_unused]] VehicleSpriteSeq *result) const { result->Clear(); }
const GRFFile *GetGRF() const;
uint32_t GetGRFID() const;
/**
* Invalidates cached NewGRF variables
* @see InvalidateNewGRFCacheOfChain
*/
inline void InvalidateNewGRFCache()
{
this->grf_cache.cache_valid = 0;
}
/**
* Invalidates cached NewGRF variables of all vehicles in the chain (after the current vehicle)
* @see InvalidateNewGRFCache
*/
inline void InvalidateNewGRFCacheOfChain()
{
for (Vehicle *u = this; u != nullptr; u = u->Next()) {
u->InvalidateNewGRFCache();
}
}
/**
* Check if the vehicle is a ground vehicle.
* @return True iff the vehicle is a train or a road vehicle.
*/
debug_inline bool IsGroundVehicle() const
{
return this->type == VEH_TRAIN || this->type == VEH_ROAD;
}
/**
* Gets the speed in km-ish/h that can be sent into SetDParam for string processing.
* @return the vehicle's speed
*/
virtual int GetDisplaySpeed() const { return 0; }
/**
* Gets the maximum speed in km-ish/h that can be sent into SetDParam for string processing.
* @return the vehicle's maximum speed
*/
virtual int GetDisplayMaxSpeed() const { return 0; }
/**
* Calculates the maximum speed of the vehicle under its current conditions.
* @return Current maximum speed in native units.
*/
virtual int GetCurrentMaxSpeed() const { return 0; }
/**
* Gets the running cost of a vehicle
* @return the vehicle's running cost
*/
virtual Money GetRunningCost() const { return 0; }
/**
* Check whether the vehicle is in the depot.
* @return true if and only if the vehicle is in the depot.
*/
virtual bool IsInDepot() const { return false; }
/**
* Check whether the whole vehicle chain is in the depot.
* @return true if and only if the whole chain is in the depot.
*/
virtual bool IsChainInDepot() const { return this->IsInDepot(); }
/**
* Check whether the vehicle is in the depot *and* stopped.
* @return true if and only if the vehicle is in the depot and stopped.
*/
bool IsStoppedInDepot() const
{
assert(this == this->First());
/* Free wagons have no VS_STOPPED state */
if (this->IsPrimaryVehicle() && !(this->vehstatus & VS_STOPPED)) return false;
return this->IsChainInDepot();
}
/**
* Calls the tick handler of the vehicle
* @return is this vehicle still valid?
*/
virtual bool Tick() { return true; };
/**
* Calls the new calendar day handler of the vehicle.
*/
virtual void OnNewCalendarDay() {};
/**
* Calls the new economy day handler of the vehicle.
*/
virtual void OnNewEconomyDay() {};
void ShiftDates(TimerGameEconomy::Date interval);
/**
* Crash the (whole) vehicle chain.
* @param flooded whether the cause of the crash is flooding or not.
* @return the number of lost souls.
*/
virtual uint Crash(bool flooded = false);
/**
* Returns the Trackdir on which the vehicle is currently located.
* Works for trains and ships.
* Currently works only sortof for road vehicles, since they have a fuzzy
* concept of being "on" a trackdir. Dunno really what it returns for a road
* vehicle that is halfway a tile, never really understood that part. For road
* vehicles that are at the beginning or end of the tile, should just return
* the diagonal trackdir on which they are driving. I _think_.
* For other vehicles types, or vehicles with no clear trackdir (such as those
* in depots), returns 0xFF.
* @return the trackdir of the vehicle
*/
virtual Trackdir GetVehicleTrackdir() const { return INVALID_TRACKDIR; }
/**
* Gets the running cost of a vehicle that can be sent into SetDParam for string processing.
* @return the vehicle's running cost
*/
Money GetDisplayRunningCost() const { return (this->GetRunningCost() >> 8); }
/**
* Gets the profit vehicle had this year. It can be sent into SetDParam for string processing.
* @return the vehicle's profit this year
*/
Money GetDisplayProfitThisYear() const { return (this->profit_this_year >> 8); }
/**
* Gets the profit vehicle had last year. It can be sent into SetDParam for string processing.
* @return the vehicle's profit last year
*/
Money GetDisplayProfitLastYear() const { return (this->profit_last_year >> 8); }
void SetNext(Vehicle *next);
/**
* Get the next vehicle of this vehicle.
* @note articulated parts are also counted as vehicles.
* @return the next vehicle or nullptr when there isn't a next vehicle.
*/
inline Vehicle *Next() const { return this->next; }
/**
* Get the previous vehicle of this vehicle.
* @note articulated parts are also counted as vehicles.
* @return the previous vehicle or nullptr when there isn't a previous vehicle.
*/
inline Vehicle *Previous() const { return this->previous; }
/**
* Get the first vehicle of this vehicle chain.
* @return the first vehicle of the chain.
*/
inline Vehicle *First() const { return this->first; }
/**
* Get the last vehicle of this vehicle chain.
* @return the last vehicle of the chain.
*/
inline Vehicle *Last()
{
Vehicle *v = this;
while (v->Next() != nullptr) v = v->Next();
return v;
}
/**
* Get the last vehicle of this vehicle chain.
* @return the last vehicle of the chain.
*/
inline const Vehicle *Last() const
{
const Vehicle *v = this;
while (v->Next() != nullptr) v = v->Next();
return v;
}
/**
* Get the vehicle at offset \a n of this vehicle chain.
* @param n Offset from the current vehicle.
* @return The new vehicle or nullptr if the offset is out-of-bounds.
*/
inline Vehicle *Move(int n)
{
Vehicle *v = this;
if (n < 0) {
for (int i = 0; i != n && v != nullptr; i--) v = v->Previous();
} else {
for (int i = 0; i != n && v != nullptr; i++) v = v->Next();
}
return v;
}
/**
* Get the vehicle at offset \a n of this vehicle chain.
* @param n Offset from the current vehicle.
* @return The new vehicle or nullptr if the offset is out-of-bounds.
*/
inline const Vehicle *Move(int n) const
{
const Vehicle *v = this;
if (n < 0) {
for (int i = 0; i != n && v != nullptr; i--) v = v->Previous();
} else {
for (int i = 0; i != n && v != nullptr; i++) v = v->Next();
}
return v;
}
/**
* Get the first order of the vehicles order list.
* @return first order of order list.
*/
inline Order *GetFirstOrder() const { return (this->orders == nullptr) ? nullptr : this->orders->GetFirstOrder(); }
void AddToShared(Vehicle *shared_chain);
void RemoveFromShared();
/**
* Get the next vehicle of the shared vehicle chain.
* @return the next shared vehicle or nullptr when there isn't a next vehicle.
*/
inline Vehicle *NextShared() const { return this->next_shared; }
/**
* Get the previous vehicle of the shared vehicle chain
* @return the previous shared vehicle or nullptr when there isn't a previous vehicle.
*/
inline Vehicle *PreviousShared() const { return this->previous_shared; }
/**
* Get the first vehicle of this vehicle chain.
* @return the first vehicle of the chain.
*/
inline Vehicle *FirstShared() const { return (this->orders == nullptr) ? this->First() : this->orders->GetFirstSharedVehicle(); }
/**
* Check if we share our orders with another vehicle.
* @return true if there are other vehicles sharing the same order
*/
inline bool IsOrderListShared() const { return this->orders != nullptr && this->orders->IsShared(); }
/**
* Get the number of orders this vehicle has.
* @return the number of orders this vehicle has.
*/
inline VehicleOrderID GetNumOrders() const { return (this->orders == nullptr) ? 0 : this->orders->GetNumOrders(); }
/**
* Get the number of manually added orders this vehicle has.
* @return the number of manually added orders this vehicle has.
*/
inline VehicleOrderID GetNumManualOrders() const { return (this->orders == nullptr) ? 0 : this->orders->GetNumManualOrders(); }
/**
* Get the next station the vehicle will stop at.
* @return ID of the next station the vehicle will stop at or INVALID_STATION.
*/
inline StationIDStack GetNextStoppingStation() const
{
return (this->orders == nullptr) ? INVALID_STATION : this->orders->GetNextStoppingStation(this);
}
void ResetRefitCaps();
void ReleaseUnitNumber();
/**
* Copy certain configurations and statistics of a vehicle after successful autoreplace/renew
* The function shall copy everything that cannot be copied by a command (like orders / group etc),
* and that shall not be resetted for the new vehicle.
* @param src The old vehicle
*/
inline void CopyVehicleConfigAndStatistics(Vehicle *src)
{
this->CopyConsistPropertiesFrom(src);
this->ReleaseUnitNumber();
this->unitnumber = src->unitnumber;
this->current_order = src->current_order;
this->dest_tile = src->dest_tile;
this->profit_this_year = src->profit_this_year;
this->profit_last_year = src->profit_last_year;
src->unitnumber = 0;
}
bool HandleBreakdown();
bool NeedsAutorenewing(const Company *c, bool use_renew_setting = true) const;
bool NeedsServicing() const;
bool NeedsAutomaticServicing() const;
/**
* Determine the location for the station where the vehicle goes to next.
* Things done for example are allocating slots in a road stop or exact
* location of the platform is determined for ships.
* @param station the station to make the next location of the vehicle.
* @return the location (tile) to aim for.
*/
virtual TileIndex GetOrderStationLocation([[maybe_unused]] StationID station) { return INVALID_TILE; }
virtual TileIndex GetCargoTile() const { return this->tile; }
/**
* Find the closest depot for this vehicle and tell us the location,
* DestinationID and whether we should reverse.
* @return A structure with information about the closest depot, if found.
*/
virtual ClosestDepot FindClosestDepot() { return {}; }
virtual void SetDestTile(TileIndex tile) { this->dest_tile = tile; }
CommandCost SendToDepot(DoCommandFlag flags, DepotCommand command);
void UpdateVisualEffect(bool allow_power_change = true);
void ShowVisualEffect() const;
void UpdatePosition();
void UpdateViewport(bool dirty);
void UpdateBoundingBoxCoordinates(bool update_cache) const;
void UpdatePositionAndViewport();
bool MarkAllViewportsDirty() const;
inline uint16_t GetServiceInterval() const { return this->service_interval; }
inline void SetServiceInterval(uint16_t interval) { this->service_interval = interval; }
inline bool ServiceIntervalIsCustom() const { return HasBit(this->vehicle_flags, VF_SERVINT_IS_CUSTOM); }
inline bool ServiceIntervalIsPercent() const { return HasBit(this->vehicle_flags, VF_SERVINT_IS_PERCENT); }
inline void SetServiceIntervalIsCustom(bool on) { SB(this->vehicle_flags, VF_SERVINT_IS_CUSTOM, 1, on); }
inline void SetServiceIntervalIsPercent(bool on) { SB(this->vehicle_flags, VF_SERVINT_IS_PERCENT, 1, on); }
bool HasFullLoadOrder() const;
bool HasConditionalOrder() const;
bool HasUnbunchingOrder() const;
void LeaveUnbunchingDepot();
bool IsWaitingForUnbunching() const;
private:
/**
* Advance cur_real_order_index to the next real order.
* cur_implicit_order_index is not touched.
*/
void SkipToNextRealOrderIndex()
{
if (this->GetNumManualOrders() > 0) {
/* Advance to next real order */
do {
this->cur_real_order_index++;
if (this->cur_real_order_index >= this->GetNumOrders()) this->cur_real_order_index = 0;
} while (this->GetOrder(this->cur_real_order_index)->IsType(OT_IMPLICIT));
} else {
this->cur_real_order_index = 0;
}
}
public:
/**
* Increments cur_implicit_order_index, keeps care of the wrap-around and invalidates the GUI.
* cur_real_order_index is incremented as well, if needed.
* Note: current_order is not invalidated.
*/
void IncrementImplicitOrderIndex()
{
if (this->cur_implicit_order_index == this->cur_real_order_index) {
/* Increment real order index as well */
this->SkipToNextRealOrderIndex();
}
assert(this->cur_real_order_index == 0 || this->cur_real_order_index < this->GetNumOrders());
/* Advance to next implicit order */
do {
this->cur_implicit_order_index++;
if (this->cur_implicit_order_index >= this->GetNumOrders()) this->cur_implicit_order_index = 0;
} while (this->cur_implicit_order_index != this->cur_real_order_index && !this->GetOrder(this->cur_implicit_order_index)->IsType(OT_IMPLICIT));
InvalidateVehicleOrder(this, 0);
}
/**
* Advanced cur_real_order_index to the next real order, keeps care of the wrap-around and invalidates the GUI.
* cur_implicit_order_index is incremented as well, if it was equal to cur_real_order_index, i.e. cur_real_order_index is skipped
* but not any implicit orders.
* Note: current_order is not invalidated.
*/
void IncrementRealOrderIndex()
{
if (this->cur_implicit_order_index == this->cur_real_order_index) {
/* Increment both real and implicit order */
this->IncrementImplicitOrderIndex();
} else {
/* Increment real order only */
this->SkipToNextRealOrderIndex();
InvalidateVehicleOrder(this, 0);
}
}
/**
* Skip implicit orders until cur_real_order_index is a non-implicit order.
*/
void UpdateRealOrderIndex()
{
/* Make sure the index is valid */
if (this->cur_real_order_index >= this->GetNumOrders()) this->cur_real_order_index = 0;
if (this->GetNumManualOrders() > 0) {
/* Advance to next real order */
while (this->GetOrder(this->cur_real_order_index)->IsType(OT_IMPLICIT)) {
this->cur_real_order_index++;
if (this->cur_real_order_index >= this->GetNumOrders()) this->cur_real_order_index = 0;
}
} else {
this->cur_real_order_index = 0;
}
}
/**
* Returns order 'index' of a vehicle or nullptr when it doesn't exists
* @param index the order to fetch
* @return the found (or not) order
*/
inline Order *GetOrder(int index) const
{
return (this->orders == nullptr) ? nullptr : this->orders->GetOrderAt(index);
}
/**
* Returns the last order of a vehicle, or nullptr if it doesn't exists
* @return last order of a vehicle, if available
*/
inline Order *GetLastOrder() const
{
return (this->orders == nullptr) ? nullptr : this->orders->GetLastOrder();
}
bool IsEngineCountable() const;
bool HasEngineType() const;
bool HasDepotOrder() const;
void HandlePathfindingResult(bool path_found);
/**
* Check if the vehicle is a front engine.
* @return Returns true if the vehicle is a front engine.
*/
debug_inline bool IsFrontEngine() const
{
return this->IsGroundVehicle() && HasBit(this->subtype, GVSF_FRONT);
}
/**
* Check if the vehicle is an articulated part of an engine.
* @return Returns true if the vehicle is an articulated part.
*/
inline bool IsArticulatedPart() const
{
return this->IsGroundVehicle() && HasBit(this->subtype, GVSF_ARTICULATED_PART);
}
/**
* Check if an engine has an articulated part.
* @return True if the engine has an articulated part.
*/
inline bool HasArticulatedPart() const
{
return this->Next() != nullptr && this->Next()->IsArticulatedPart();
}
/**
* Get the next part of an articulated engine.
* @return Next part of the articulated engine.
* @pre The vehicle is an articulated engine.
*/
inline Vehicle *GetNextArticulatedPart() const
{
assert(this->HasArticulatedPart());
return this->Next();
}
/**
* Get the first part of an articulated engine.
* @return First part of the engine.
*/
inline Vehicle *GetFirstEnginePart()
{
Vehicle *v = this;
while (v->IsArticulatedPart()) v = v->Previous();
return v;
}
/**
* Get the first part of an articulated engine.
* @return First part of the engine.
*/
inline const Vehicle *GetFirstEnginePart() const
{
const Vehicle *v = this;
while (v->IsArticulatedPart()) v = v->Previous();
return v;
}
/**
* Get the last part of an articulated engine.
* @return Last part of the engine.
*/
inline Vehicle *GetLastEnginePart()
{
Vehicle *v = this;
while (v->HasArticulatedPart()) v = v->GetNextArticulatedPart();
return v;
}
/**
* Get the next real (non-articulated part) vehicle in the consist.
* @return Next vehicle in the consist.
*/
inline Vehicle *GetNextVehicle() const
{
const Vehicle *v = this;
while (v->HasArticulatedPart()) v = v->GetNextArticulatedPart();
/* v now contains the last articulated part in the engine */
return v->Next();
}
/**
* Get the previous real (non-articulated part) vehicle in the consist.
* @return Previous vehicle in the consist.
*/
inline Vehicle *GetPrevVehicle() const
{
Vehicle *v = this->Previous();
while (v != nullptr && v->IsArticulatedPart()) v = v->Previous();
return v;
}
/**
* Iterator to iterate orders
* Supports deletion of current order
*/
struct OrderIterator {
typedef Order value_type;
typedef Order *pointer;
typedef Order &reference;
typedef size_t difference_type;
typedef std::forward_iterator_tag iterator_category;
explicit OrderIterator(OrderList *list) : list(list), prev(nullptr)
{
this->order = (this->list == nullptr) ? nullptr : this->list->GetFirstOrder();
}
bool operator==(const OrderIterator &other) const { return this->order == other.order; }
bool operator!=(const OrderIterator &other) const { return !(*this == other); }
Order * operator*() const { return this->order; }
OrderIterator & operator++()
{
this->prev = (this->prev == nullptr) ? this->list->GetFirstOrder() : this->prev->next;
this->order = (this->prev == nullptr) ? nullptr : this->prev->next;
return *this;
}
private:
OrderList *list;
Order *order;
Order *prev;
};
/**
* Iterable ensemble of orders
*/
struct IterateWrapper {
OrderList *list;
IterateWrapper(OrderList *list = nullptr) : list(list) {}
OrderIterator begin() { return OrderIterator(this->list); }
OrderIterator end() { return OrderIterator(nullptr); }
bool empty() { return this->begin() == this->end(); }
};
/**
* Returns an iterable ensemble of orders of a vehicle
* @return an iterable ensemble of orders of a vehicle
*/
IterateWrapper Orders() const { return IterateWrapper(this->orders); }
uint32_t GetDisplayMaxWeight() const;
uint32_t GetDisplayMinPowerToWeight() const;
};
/**
* Class defining several overloaded accessors so we don't
* have to cast vehicle types that often
*/
template <class T, VehicleType Type>
struct SpecializedVehicle : public Vehicle {
static const VehicleType EXPECTED_TYPE = Type; ///< Specialized type
typedef SpecializedVehicle<T, Type> SpecializedVehicleBase; ///< Our type
/**
* Set vehicle type correctly
*/
inline SpecializedVehicle<T, Type>() : Vehicle(Type)
{
this->sprite_cache.sprite_seq.count = 1;
}
/**
* Get the first vehicle in the chain
* @return first vehicle in the chain
*/
inline T *First() const { return (T *)this->Vehicle::First(); }
/**
* Get the last vehicle in the chain
* @return last vehicle in the chain
*/
inline T *Last() { return (T *)this->Vehicle::Last(); }
/**
* Get the last vehicle in the chain
* @return last vehicle in the chain
*/
inline const T *Last() const { return (const T *)this->Vehicle::Last(); }
/**
* Get next vehicle in the chain
* @return next vehicle in the chain
*/
inline T *Next() const { return (T *)this->Vehicle::Next(); }
/**
* Get previous vehicle in the chain
* @return previous vehicle in the chain
*/
inline T *Previous() const { return (T *)this->Vehicle::Previous(); }
/**
* Get the next part of an articulated engine.
* @return Next part of the articulated engine.
* @pre The vehicle is an articulated engine.
*/
inline T *GetNextArticulatedPart() { return (T *)this->Vehicle::GetNextArticulatedPart(); }
/**
* Get the next part of an articulated engine.
* @return Next part of the articulated engine.
* @pre The vehicle is an articulated engine.
*/
inline T *GetNextArticulatedPart() const { return (T *)this->Vehicle::GetNextArticulatedPart(); }
/**
* Get the first part of an articulated engine.
* @return First part of the engine.
*/
inline T *GetFirstEnginePart() { return (T *)this->Vehicle::GetFirstEnginePart(); }
/**
* Get the first part of an articulated engine.
* @return First part of the engine.
*/
inline const T *GetFirstEnginePart() const { return (const T *)this->Vehicle::GetFirstEnginePart(); }
/**
* Get the last part of an articulated engine.
* @return Last part of the engine.
*/
inline T *GetLastEnginePart() { return (T *)this->Vehicle::GetLastEnginePart(); }
/**
* Get the next real (non-articulated part) vehicle in the consist.
* @return Next vehicle in the consist.
*/
inline T *GetNextVehicle() const { return (T *)this->Vehicle::GetNextVehicle(); }
/**
* Get the previous real (non-articulated part) vehicle in the consist.
* @return Previous vehicle in the consist.
*/
inline T *GetPrevVehicle() const { return (T *)this->Vehicle::GetPrevVehicle(); }
/**
* Tests whether given index is a valid index for vehicle of this type
* @param index tested index
* @return is this index valid index of T?
*/
static inline bool IsValidID(size_t index)
{
return Vehicle::IsValidID(index) && Vehicle::Get(index)->type == Type;
}
/**
* Gets vehicle with given index
* @return pointer to vehicle with given index casted to T *
*/
static inline T *Get(size_t index)
{
return (T *)Vehicle::Get(index);
}
/**
* Returns vehicle if the index is a valid index for this vehicle type
* @return pointer to vehicle with given index if it's a vehicle of this type
*/
static inline T *GetIfValid(size_t index)
{
return IsValidID(index) ? Get(index) : nullptr;
}
/**
* Converts a Vehicle to SpecializedVehicle with type checking.
* @param v Vehicle pointer
* @return pointer to SpecializedVehicle
*/
static inline T *From(Vehicle *v)
{
assert(v->type == Type);
return (T *)v;
}
/**
* Converts a const Vehicle to const SpecializedVehicle with type checking.
* @param v Vehicle pointer
* @return pointer to SpecializedVehicle
*/
static inline const T *From(const Vehicle *v)
{
assert(v->type == Type);
return (const T *)v;
}
/**
* Update vehicle sprite- and position caches
* @param force_update Force updating the vehicle on the viewport.
* @param update_delta Also update the delta?
*/
inline void UpdateViewport(bool force_update, bool update_delta)
{
bool sprite_has_changed = false;
/* Skip updating sprites on dedicated servers without screen */
if (_network_dedicated) return;
/* Explicitly choose method to call to prevent vtable dereference -
* it gives ~3% runtime improvements in games with many vehicles */
if (update_delta) ((T *)this)->T::UpdateDeltaXY();
/*
* Only check for a new sprite sequence if the vehicle direction
* has changed since we last checked it, assuming that otherwise
* there won't be enough change in bounding box or offsets to need
* to resolve a new sprite.
*/
if (this->direction != this->sprite_cache.last_direction || this->sprite_cache.is_viewport_candidate) {
VehicleSpriteSeq seq;
((T*)this)->T::GetImage(this->direction, EIT_ON_MAP, &seq);
if (this->sprite_cache.sprite_seq != seq) {
sprite_has_changed = true;
this->sprite_cache.sprite_seq = seq;
}
this->sprite_cache.last_direction = this->direction;
this->sprite_cache.revalidate_before_draw = false;
} else {
/*
* A change that could potentially invalidate the sprite has been
* made, signal that we should still resolve it before drawing on a
* viewport.
*/
this->sprite_cache.revalidate_before_draw = true;
}
if (force_update || sprite_has_changed) {
this->Vehicle::UpdateViewport(true);
}
}
/**
* Returns an iterable ensemble of all valid vehicles of type T
* @param from index of the first vehicle to consider
* @return an iterable ensemble of all valid vehicles of type T
*/
static Pool::IterateWrapper<T> Iterate(size_t from = 0) { return Pool::IterateWrapper<T>(from); }
};
/** Sentinel for an invalid coordinate. */
static const int32_t INVALID_COORD = 0x7fffffff;
#endif /* VEHICLE_BASE_H */
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