/* $Id$ */
/*
* 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 .
*/
/** @file newgrf_object.cpp Handling of object NewGRFs. */
#include "stdafx.h"
#include "company_base.h"
#include "company_func.h"
#include "debug.h"
#include "genworld.h"
#include "newgrf_class_func.h"
#include "newgrf_object.h"
#include "newgrf_sound.h"
#include "object_base.h"
#include "object_map.h"
#include "tile_cmd.h"
#include "town.h"
#include "water.h"
#include "newgrf_animation_base.h"
/** The override manager for our objects. */
ObjectOverrideManager _object_mngr(NEW_OBJECT_OFFSET, NUM_OBJECTS, INVALID_OBJECT_TYPE);
extern const ObjectSpec _original_objects[NEW_OBJECT_OFFSET];
/** All the object specifications. */
ObjectSpec _object_specs[NUM_OBJECTS];
/**
* Get the specification associated with a specific ObjectType.
* @param index The object type to fetch.
* @return The specification.
*/
/* static */ const ObjectSpec *ObjectSpec::Get(ObjectType index)
{
assert(index < NUM_OBJECTS);
return &_object_specs[index];
}
/**
* Get the specification associated with a tile.
* @param tile The tile to fetch the data for.
* @return The specification.
*/
/* static */ const ObjectSpec *ObjectSpec::GetByTile(TileIndex tile)
{
return ObjectSpec::Get(GetObjectType(tile));
}
/**
* Check whether the object might be available at some point in this game with the current game mode.
* @return true if it might be available.
*/
bool ObjectSpec::IsEverAvailable() const
{
return this->enabled && HasBit(this->climate, _settings_game.game_creation.landscape) &&
(this->flags & ((_game_mode != GM_EDITOR && !_generating_world) ? OBJECT_FLAG_ONLY_IN_SCENEDIT : OBJECT_FLAG_ONLY_IN_GAME)) == 0;
}
/**
* Check whether the object was available at some point in the past or present in this game with the current game mode.
* @return true if it was ever or is available.
*/
bool ObjectSpec::WasEverAvailable() const
{
return this->IsEverAvailable() && _date > this->introduction_date;
}
/**
* Check whether the object is available at this time.
* @return true if it is available.
*/
bool ObjectSpec::IsAvailable() const
{
return this->WasEverAvailable() &&
(_date < this->end_of_life_date || this->end_of_life_date < this->introduction_date + 365);
}
/**
* Gets the index of this spec.
* @return The index.
*/
uint ObjectSpec::Index() const
{
return this - _object_specs;
}
/** This function initialize the spec arrays of objects. */
void ResetObjects()
{
/* Clean the pool. */
MemSetT(_object_specs, 0, lengthof(_object_specs));
/* And add our originals. */
MemCpyT(_object_specs, _original_objects, lengthof(_original_objects));
for (uint16 i = 0; i < lengthof(_original_objects); i++) {
_object_specs[i].grf_prop.local_id = i;
}
}
template
/* static */ void NewGRFClass::InsertDefaults()
{
ObjectClassID cls = ObjectClass::Allocate('LTHS');
ObjectClass::Get(cls)->name = STR_OBJECT_CLASS_LTHS;
_object_specs[OBJECT_LIGHTHOUSE].cls_id = cls;
ObjectClass::Assign(&_object_specs[OBJECT_LIGHTHOUSE]);
cls = ObjectClass::Allocate('TRNS');
ObjectClass::Get(cls)->name = STR_OBJECT_CLASS_TRNS;
_object_specs[OBJECT_TRANSMITTER].cls_id = cls;
ObjectClass::Assign(&_object_specs[OBJECT_TRANSMITTER]);
}
template
bool NewGRFClass::IsUIAvailable(uint index) const
{
return this->GetSpec(index)->IsEverAvailable();
}
INSTANTIATE_NEWGRF_CLASS_METHODS(ObjectClass, ObjectSpec, ObjectClassID, OBJECT_CLASS_MAX)
/**
* Constructor of an object scope resolver.
* @param ro Surrounding resolver.
* @param obj Object being resolved.
* @param tile %Tile of the object.
* @param view View of the object.
*/
ObjectScopeResolver::ObjectScopeResolver(ResolverObject &ro, Object *obj, TileIndex tile, uint8 view)
: ScopeResolver(ro)
{
this->obj = obj;
this->tile = tile;
this->view = view;
}
/* virtual */ uint32 ObjectScopeResolver::GetRandomBits() const
{
return IsValidTile(this->tile) && IsTileType(this->tile, MP_OBJECT) ? GetObjectRandomBits(this->tile) : 0;
}
/**
* Make an analysis of a tile and get the object type.
* @param tile TileIndex of the tile to query
* @param cur_grfid GRFID of the current callback chain
* @return value encoded as per NFO specs
*/
static uint32 GetObjectIDAtOffset(TileIndex tile, uint32 cur_grfid)
{
if (!IsTileType(tile, MP_OBJECT)) {
return 0xFFFF;
}
const Object *o = Object::GetByTile(tile);
const ObjectSpec *spec = ObjectSpec::Get(o->type);
/* Default objects have no associated NewGRF file */
if (spec->grf_prop.grffile == NULL) {
return 0xFFFE; // Defined in another grf file
}
if (spec->grf_prop.grffile->grfid == cur_grfid) { // same object, same grf ?
return spec->grf_prop.local_id | o->view << 16;
}
return 0xFFFE; // Defined in another grf file
}
/**
* Based on newhouses equivalent, but adapted for newobjects
* @param parameter from callback. It's in fact a pair of coordinates
* @param tile TileIndex from which the callback was initiated
* @param index of the object been queried for
* @param grf_version8 True, if we are dealing with a new NewGRF which uses GRF version >= 8.
* @return a construction of bits obeying the newgrf format
*/
static uint32 GetNearbyObjectTileInformation(byte parameter, TileIndex tile, ObjectID index, bool grf_version8)
{
if (parameter != 0) tile = GetNearbyTile(parameter, tile); // only perform if it is required
bool is_same_object = (IsTileType(tile, MP_OBJECT) && GetObjectIndex(tile) == index);
return GetNearbyTileInformation(tile, grf_version8) | (is_same_object ? 1 : 0) << 8;
}
/**
* Get the closest object of a given type.
* @param tile The tile to start searching from.
* @param type The type of the object to search for.
* @param current The current object (to ignore).
* @return The distance to the closest object.
*/
static uint32 GetClosestObject(TileIndex tile, ObjectType type, const Object *current)
{
uint32 best_dist = UINT32_MAX;
const Object *o;
FOR_ALL_OBJECTS(o) {
if (o->type != type || o == current) continue;
best_dist = min(best_dist, DistanceManhattan(tile, o->location.tile));
}
return best_dist;
}
/**
* Implementation of var 65
* @param local_id Parameter given to the callback, which is the set id, or the local id, in our terminology.
* @param grfid The object's GRFID.
* @param tile The tile to look from.
* @param current Object for which the inquiry is made
* @return The formatted answer to the callback : rr(reserved) cc(count) dddd(manhattan distance of closest sister)
*/
static uint32 GetCountAndDistanceOfClosestInstance(byte local_id, uint32 grfid, TileIndex tile, const Object *current)
{
uint32 grf_id = GetRegister(0x100); // Get the GRFID of the definition to look for in register 100h
uint32 idx;
/* Determine what will be the object type to look for */
switch (grf_id) {
case 0: // this is a default object type
idx = local_id;
break;
case 0xFFFFFFFF: // current grf
grf_id = grfid;
/* FALL THROUGH */
default: // use the grfid specified in register 100h
idx = _object_mngr.GetID(local_id, grf_id);
break;
}
/* If the object type is invalid, there is none and the closest is far away. */
if (idx >= NUM_OBJECTS) return 0 | 0xFFFF;
return Object::GetTypeCount(idx) << 16 | min(GetClosestObject(tile, idx, current), 0xFFFF);
}
/** Used by the resolver to get values for feature 0F deterministic spritegroups. */
/* virtual */ uint32 ObjectScopeResolver::GetVariable(byte variable, uint32 parameter, bool *available) const
{
/* We get the town from the object, or we calculate the closest
* town if we need to when there's no object. */
const Town *t = NULL;
if (this->obj == NULL) {
switch (variable) {
/* Allow these when there's no object. */
case 0x41:
case 0x60:
case 0x61:
case 0x62:
case 0x64:
break;
/* Allow these, but find the closest town. */
case 0x45:
case 0x46:
if (!IsValidTile(this->tile)) goto unhandled;
t = ClosestTownFromTile(this->tile, UINT_MAX);
break;
/* Construction date */
case 0x42: return _date;
/* Object founder information */
case 0x44: return _current_company;
/* Object view */
case 0x48: return this->view;
/*
* Disallow the rest:
* 0x40: Relative position is passed as parameter during construction.
* 0x43: Animation counter is only for actual tiles.
* 0x47: Object colour is only valid when its built.
* 0x63: Animation counter of nearby tile, see above.
*/
default:
goto unhandled;
}
/* If there's an invalid tile, then we don't have enough information at all. */
if (!IsValidTile(this->tile)) goto unhandled;
} else {
t = this->obj->town;
}
switch (variable) {
/* Relative position. */
case 0x40: {
uint offset = this->tile - this->obj->location.tile;
uint offset_x = TileX(offset);
uint offset_y = TileY(offset);
return offset_y << 20 | offset_x << 16 | offset_y << 8 | offset_x;
}
/* Tile information. */
case 0x41: return GetTileSlope(this->tile) << 8 | GetTerrainType(this->tile);
/* Construction date */
case 0x42: return this->obj->build_date;
/* Animation counter */
case 0x43: return GetAnimationFrame(this->tile);
/* Object founder information */
case 0x44: return GetTileOwner(this->tile);
/* Get town zone and Manhattan distance of closest town */
case 0x45: return GetTownRadiusGroup(t, this->tile) << 16 | min(DistanceManhattan(this->tile, t->xy), 0xFFFF);
/* Get square of Euclidian distance of closes town */
case 0x46: return GetTownRadiusGroup(t, this->tile) << 16 | min(DistanceSquare(this->tile, t->xy), 0xFFFF);
/* Object colour */
case 0x47: return this->obj->colour;
/* Object view */
case 0x48: return this->obj->view;
/* Get object ID at offset param */
case 0x60: return GetObjectIDAtOffset(GetNearbyTile(parameter, this->tile), this->ro.grffile->grfid);
/* Get random tile bits at offset param */
case 0x61: {
TileIndex tile = GetNearbyTile(parameter, this->tile);
return (IsTileType(tile, MP_OBJECT) && Object::GetByTile(tile) == this->obj) ? GetObjectRandomBits(tile) : 0;
}
/* Land info of nearby tiles */
case 0x62: return GetNearbyObjectTileInformation(parameter, this->tile, this->obj == NULL ? INVALID_OBJECT : this->obj->index, this->ro.grffile->grf_version >= 8);
/* Animation counter of nearby tile */
case 0x63: {
TileIndex tile = GetNearbyTile(parameter, this->tile);
return (IsTileType(tile, MP_OBJECT) && Object::GetByTile(tile) == this->obj) ? GetAnimationFrame(tile) : 0;
}
/* Count of object, distance of closest instance */
case 0x64: return GetCountAndDistanceOfClosestInstance(parameter, this->ro.grffile->grfid, this->tile, this->obj);
}
unhandled:
DEBUG(grf, 1, "Unhandled object variable 0x%X", variable);
*available = false;
return UINT_MAX;
}
/**
* Constructor of the object resolver.
* @param obj Object being resolved.
* @param tile %Tile of the object.
* @param view View of the object.
* @param callback Callback ID.
* @param callback_param1 First parameter (var 10) of the callback.
* @param callback_param2 Second parameter (var 18) of the callback.
*/
ObjectResolverObject::ObjectResolverObject(const ObjectSpec *spec, Object *obj, TileIndex tile, uint8 view,
CallbackID callback, uint32 param1, uint32 param2)
: ResolverObject(spec->grf_prop.grffile, callback, param1, param2), object_scope(*this, obj, tile, view)
{
this->town_scope = NULL;
this->root_spritegroup = (obj == NULL && spec->grf_prop.spritegroup[CT_PURCHASE_OBJECT] != NULL) ?
spec->grf_prop.spritegroup[CT_PURCHASE_OBJECT] : spec->grf_prop.spritegroup[0];
}
ObjectResolverObject::~ObjectResolverObject()
{
delete this->town_scope;
}
/**
* Get the town resolver scope that belongs to this object resolver.
* On the first call, the town scope is created (if possible).
* @return Town scope, if available.
*/
TownScopeResolver *ObjectResolverObject::GetTown()
{
if (this->town_scope == NULL) {
Town *t;
if (this->object_scope.obj != NULL) {
t = this->object_scope.obj->town;
} else {
t = ClosestTownFromTile(this->object_scope.tile, UINT_MAX);
}
if (t == NULL) return NULL;
this->town_scope = new TownScopeResolver(*this, t, this->object_scope.obj == NULL);
}
return this->town_scope;
}
/**
* Perform a callback for an object.
* @param callback The callback to perform.
* @param param1 The first parameter to pass to the NewGRF.
* @param param2 The second parameter to pass to the NewGRF.
* @param spec The specification of the object / the entry point.
* @param o The object to call the callback for.
* @param tile The tile the callback is called for.
* @param view The view of the object (only used when o == NULL).
* @return The result of the callback.
*/
uint16 GetObjectCallback(CallbackID callback, uint32 param1, uint32 param2, const ObjectSpec *spec, Object *o, TileIndex tile, uint8 view)
{
ObjectResolverObject object(spec, o, tile, view, callback, param1, param2);
return object.ResolveCallback();
}
/**
* Draw an group of sprites on the map.
* @param ti Information about the tile to draw on.
* @param group The group of sprites to draw.
* @param spec Object spec to draw.
*/
static void DrawTileLayout(const TileInfo *ti, const TileLayoutSpriteGroup *group, const ObjectSpec *spec)
{
const DrawTileSprites *dts = group->ProcessRegisters(NULL);
PaletteID palette = ((spec->flags & OBJECT_FLAG_2CC_COLOUR) ? SPR_2CCMAP_BASE : PALETTE_RECOLOUR_START) + Object::GetByTile(ti->tile)->colour;
SpriteID image = dts->ground.sprite;
PaletteID pal = dts->ground.pal;
if (GB(image, 0, SPRITE_WIDTH) != 0) {
/* If the ground sprite is the default flat water sprite, draw also canal/river borders
* Do not do this if the tile's WaterClass is 'land'. */
if ((image == SPR_FLAT_WATER_TILE || spec->flags & OBJECT_FLAG_DRAW_WATER) && IsTileOnWater(ti->tile)) {
DrawWaterClassGround(ti);
} else {
DrawGroundSprite(image, GroundSpritePaletteTransform(image, pal, palette));
}
}
DrawNewGRFTileSeq(ti, dts, TO_STRUCTURES, 0, palette);
}
/**
* Draw an object on the map.
* @param ti Information about the tile to draw on.
* @param spec Object spec to draw.
*/
void DrawNewObjectTile(TileInfo *ti, const ObjectSpec *spec)
{
Object *o = Object::GetByTile(ti->tile);
ObjectResolverObject object(spec, o, ti->tile);
const SpriteGroup *group = object.Resolve();
if (group == NULL || group->type != SGT_TILELAYOUT) return;
DrawTileLayout(ti, (const TileLayoutSpriteGroup *)group, spec);
}
/**
* Draw representation of an object (tile) for GUI purposes.
* @param x Position x of image.
* @param y Position y of image.
* @param spec Object spec to draw.
* @param view The object's view.
*/
void DrawNewObjectTileInGUI(int x, int y, const ObjectSpec *spec, uint8 view)
{
ObjectResolverObject object(spec, NULL, INVALID_TILE, view);
const SpriteGroup *group = object.Resolve();
if (group == NULL || group->type != SGT_TILELAYOUT) return;
const DrawTileSprites *dts = ((const TileLayoutSpriteGroup *)group)->ProcessRegisters(NULL);
PaletteID palette;
if (Company::IsValidID(_local_company)) {
/* Get the colours of our company! */
if (spec->flags & OBJECT_FLAG_2CC_COLOUR) {
const Livery *l = Company::Get(_local_company)->livery;
palette = SPR_2CCMAP_BASE + l->colour1 + l->colour2 * 16;
} else {
palette = COMPANY_SPRITE_COLOUR(_local_company);
}
} else {
/* There's no company, so just take the base palette. */
palette = (spec->flags & OBJECT_FLAG_2CC_COLOUR) ? SPR_2CCMAP_BASE : PALETTE_RECOLOUR_START;
}
SpriteID image = dts->ground.sprite;
PaletteID pal = dts->ground.pal;
if (GB(image, 0, SPRITE_WIDTH) != 0) {
DrawSprite(image, GroundSpritePaletteTransform(image, pal, palette), x, y);
}
DrawNewGRFTileSeqInGUI(x, y, dts, 0, palette);
}
/**
* Perform a callback for an object.
* @param callback The callback to perform.
* @param param1 The first parameter to pass to the NewGRF.
* @param param2 The second parameter to pass to the NewGRF.
* @param spec The specification of the object / the entry point.
* @param o The object to call the callback for.
* @param tile The tile the callback is called for.
* @param extra_data Ignored.
* @return The result of the callback.
*/
uint16 StubGetObjectCallback(CallbackID callback, uint32 param1, uint32 param2, const ObjectSpec *spec, Object *o, TileIndex tile, int extra_data)
{
return GetObjectCallback(callback, param1, param2, spec, o, tile);
}
/** Helper class for animation control. */
struct ObjectAnimationBase : public AnimationBase {
static const CallbackID cb_animation_speed = CBID_OBJECT_ANIMATION_SPEED;
static const CallbackID cb_animation_next_frame = CBID_OBJECT_ANIMATION_NEXT_FRAME;
static const ObjectCallbackMask cbm_animation_speed = CBM_OBJ_ANIMATION_SPEED;
static const ObjectCallbackMask cbm_animation_next_frame = CBM_OBJ_ANIMATION_NEXT_FRAME;
};
/**
* Handle the animation of the object tile.
* @param tile The tile to animate.
*/
void AnimateNewObjectTile(TileIndex tile)
{
const ObjectSpec *spec = ObjectSpec::GetByTile(tile);
if (spec == NULL || !(spec->flags & OBJECT_FLAG_ANIMATION)) return;
ObjectAnimationBase::AnimateTile(spec, Object::GetByTile(tile), tile, (spec->flags & OBJECT_FLAG_ANIM_RANDOM_BITS) != 0);
}
/**
* Trigger the update of animation on a single tile.
* @param o The object that got triggered.
* @param tile The location of the triggered tile.
* @param trigger The trigger that is triggered.
* @param spec The spec associated with the object.
*/
void TriggerObjectTileAnimation(Object *o, TileIndex tile, ObjectAnimationTrigger trigger, const ObjectSpec *spec)
{
if (!HasBit(spec->animation.triggers, trigger)) return;
ObjectAnimationBase::ChangeAnimationFrame(CBID_OBJECT_ANIMATION_START_STOP, spec, o, tile, Random(), trigger);
}
/**
* Trigger the update of animation on a whole object.
* @param o The object that got triggered.
* @param trigger The trigger that is triggered.
* @param spec The spec associated with the object.
*/
void TriggerObjectAnimation(Object *o, ObjectAnimationTrigger trigger, const ObjectSpec *spec)
{
if (!HasBit(spec->animation.triggers, trigger)) return;
TILE_AREA_LOOP(tile, o->location) {
TriggerObjectTileAnimation(o, tile, trigger, spec);
}
}