/* * 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.cpp Base of all NewGRF support. */ #include "stdafx.h" #include #include "newgrf_internal.h" #include "debug.h" #include "fileio_func.h" #include "engine_func.h" #include "engine_base.h" #include "bridge.h" #include "town.h" #include "newgrf_engine.h" #include "newgrf_text.h" #include "fontcache.h" #include "currency.h" #include "landscape.h" #include "newgrf_cargo.h" #include "newgrf_house.h" #include "newgrf_sound.h" #include "newgrf_station.h" #include "industrytype.h" #include "industry_map.h" #include "newgrf_canal.h" #include "newgrf_townname.h" #include "newgrf_industries.h" #include "newgrf_airporttiles.h" #include "newgrf_airport.h" #include "newgrf_object.h" #include "newgrf_newsignals.h" #include "newgrf_newlandscape.h" #include "newgrf_extension.h" #include "rev.h" #include "fios.h" #include "strings_func.h" #include "date_func.h" #include "string_func.h" #include "network/core/config.h" #include "smallmap_gui.h" #include "genworld.h" #include "error.h" #include "vehicle_func.h" #include "language.h" #include "vehicle_base.h" #include "road.h" #include "newgrf_roadstop.h" #include "debug_settings.h" #include "table/strings.h" #include "table/build_industry.h" #include "3rdparty/cpp-btree/btree_map.h" #include #include "safeguards.h" /* TTDPatch extended GRF format codec * (c) Petr Baudis 2004 (GPL'd) * Changes by Florian octo Forster are (c) by the OpenTTD development team. * * Contains portions of documentation by TTDPatch team. * Thanks especially to Josef Drexler for the documentation as well as a lot * of help at #tycoon. Also thanks to Michael Blunck for his GRF files which * served as subject to the initial testing of this codec. */ /** List of all loaded GRF files */ static std::vector _grf_files; const std::vector &GetAllGRFFiles() { return _grf_files; } static btree::btree_map _callback_result_cache; /** Miscellaneous GRF features, set by Action 0x0D, parameter 0x9E */ byte _misc_grf_features = 0; /** 32 * 8 = 256 flags. Apparently TTDPatch uses this many.. */ static uint32 _ttdpatch_flags[8]; /** Indicates which are the newgrf features currently loaded ingame */ GRFLoadedFeatures _loaded_newgrf_features; GrfProcessingState _cur; /** * Helper to check whether an image index is valid for a particular NewGRF vehicle. * @tparam T The type of vehicle. * @param image_index The image index to check. * @return True iff the image index is valid, or 0xFD (use new graphics). */ template static inline bool IsValidNewGRFImageIndex(uint8 image_index) { return image_index == 0xFD || IsValidImageIndex(image_index); } class OTTDByteReaderSignal { }; /** Class to read from a NewGRF file */ class ByteReader { protected: byte *data; byte *end; public: ByteReader(byte *data, byte *end) : data(data), end(end) { } inline byte *ReadBytes(size_t size) { if (data + size >= end) { /* Put data at the end, as would happen if every byte had been individually read. */ data = end; throw OTTDByteReaderSignal(); } byte *ret = data; data += size; return ret; } inline byte ReadByte() { if (data < end) return *(data)++; throw OTTDByteReaderSignal(); } uint16 ReadWord() { uint16 val = ReadByte(); return val | (ReadByte() << 8); } uint16 ReadExtendedByte() { uint16 val = ReadByte(); return val == 0xFF ? ReadWord() : val; } uint32 ReadDWord() { uint32 val = ReadWord(); return val | (ReadWord() << 16); } uint32 ReadVarSize(byte size) { switch (size) { case 1: return ReadByte(); case 2: return ReadWord(); case 4: return ReadDWord(); default: NOT_REACHED(); return 0; } } const char *ReadString() { char *string = reinterpret_cast(data); size_t string_length = ttd_strnlen(string, Remaining()); if (string_length == Remaining()) { /* String was not NUL terminated, so make sure it is now. */ string[string_length - 1] = '\0'; grfmsg(7, "String was not terminated with a zero byte."); } else { /* Increase the string length to include the NUL byte. */ string_length++; } Skip(string_length); return string; } inline size_t Remaining() const { return end - data; } inline bool HasData(size_t count = 1) const { return data + count <= end; } inline byte *Data() { return data; } inline void Skip(size_t len) { data += len; /* It is valid to move the buffer to exactly the end of the data, * as there may not be any more data read. */ if (data > end) throw OTTDByteReaderSignal(); } }; typedef void (*SpecialSpriteHandler)(ByteReader *buf); static const uint NUM_STATIONS_PER_GRF = 255; ///< Number of StationSpecs per NewGRF; limited to 255 to allow extending Action3 with an extended byte later on. /** Temporary engine data used when loading only */ struct GRFTempEngineData { /** Summary state of refittability properties */ enum Refittability { UNSET = 0, ///< No properties assigned. Default refit masks shall be activated. EMPTY, ///< GRF defined vehicle as not-refittable. The vehicle shall only carry the default cargo. NONEMPTY, ///< GRF defined the vehicle as refittable. If the refitmask is empty after translation (cargotypes not available), disable the vehicle. }; uint16 cargo_allowed; uint16 cargo_disallowed; RailTypeLabel railtypelabel; uint8 roadtramtype; const GRFFile *defaultcargo_grf; ///< GRF defining the cargo translation table to use if the default cargo is the 'first refittable'. Refittability refittability; ///< Did the newgrf set any refittability property? If not, default refittability will be applied. bool prop27_set; ///< Did the NewGRF set property 27 (misc flags)? uint8 rv_max_speed; ///< Temporary storage of RV prop 15, maximum speed in mph/0.8 CargoTypes ctt_include_mask; ///< Cargo types always included in the refit mask. CargoTypes ctt_exclude_mask; ///< Cargo types always excluded from the refit mask. /** * Update the summary refittability on setting a refittability property. * @param non_empty true if the GRF sets the vehicle to be refittable. */ void UpdateRefittability(bool non_empty) { if (non_empty) { this->refittability = NONEMPTY; } else if (this->refittability == UNSET) { this->refittability = EMPTY; } } }; static GRFTempEngineData *_gted; ///< Temporary engine data used during NewGRF loading /** * Contains the GRF ID of the owner of a vehicle if it has been reserved. * GRM for vehicles is only used if dynamic engine allocation is disabled, * so 256 is the number of original engines. */ static uint32 _grm_engines[256]; /** Contains the GRF ID of the owner of a cargo if it has been reserved */ static uint32 _grm_cargoes[NUM_CARGO * 2]; struct GRFLocation { uint32 grfid; uint32 nfoline; GRFLocation() { } GRFLocation(uint32 grfid, uint32 nfoline) : grfid(grfid), nfoline(nfoline) { } bool operator<(const GRFLocation &other) const { return this->grfid < other.grfid || (this->grfid == other.grfid && this->nfoline < other.nfoline); } bool operator == (const GRFLocation &other) const { return this->grfid == other.grfid && this->nfoline == other.nfoline; } }; static btree::btree_map _grm_sprites; typedef btree::btree_map GRFLineToSpriteOverride; static GRFLineToSpriteOverride _grf_line_to_action6_sprite_override; static bool _action6_override_active = false; /** * DEBUG() function dedicated to newGRF debugging messages * Function is essentially the same as DEBUG(grf, severity, ...) with the * addition of file:line information when parsing grf files. * NOTE: for the above reason(s) grfmsg() should ONLY be used for * loading/parsing grf files, not for runtime debug messages as there * is no file information available during that time. * @param severity debugging severity level, see debug.h * @param str message in printf() format */ void CDECL _intl_grfmsg(int severity, const char *str, ...) { char buf[1024]; va_list va; va_start(va, str); vseprintf(buf, lastof(buf), str, va); va_end(va); DEBUG(grf, severity, "[%s:%d] %s", _cur.grfconfig->GetDisplayPath(), _cur.nfo_line, buf); } /** * Obtain a NewGRF file by its grfID * @param grfid The grfID to obtain the file for * @return The file. */ GRFFile *GetFileByGRFID(uint32 grfid) { for (GRFFile * const file : _grf_files) { if (file->grfid == grfid) return file; } return nullptr; } /** * Obtain a NewGRF file by its grfID, expect it to usually be the current GRF's grfID * @param grfid The grfID to obtain the file for * @return The file. */ GRFFile *GetFileByGRFIDExpectCurrent(uint32 grfid) { if (_cur.grffile->grfid == grfid) return _cur.grffile; return GetFileByGRFID(grfid); } /** * Obtain a NewGRF file by its filename * @param filename The filename to obtain the file for. * @return The file. */ static GRFFile *GetFileByFilename(const char *filename) { for (GRFFile * const file : _grf_files) { if (strcmp(file->filename, filename) == 0) return file; } return nullptr; } /** Reset all NewGRFData that was used only while processing data */ static void ClearTemporaryNewGRFData(GRFFile *gf) { /* Clear the GOTO labels used for GRF processing */ for (GRFLabel *l = gf->label; l != nullptr;) { GRFLabel *l2 = l->next; free(l); l = l2; } gf->label = nullptr; } /** * Disable a GRF * @param message Error message or STR_NULL. * @param config GRFConfig to disable, nullptr for current. * @return Error message of the GRF for further customisation. */ static GRFError *DisableGrf(StringID message = STR_NULL, GRFConfig *config = nullptr) { GRFFile *file; if (config != nullptr) { file = GetFileByGRFID(config->ident.grfid); } else { config = _cur.grfconfig; file = _cur.grffile; } config->status = GCS_DISABLED; if (file != nullptr) ClearTemporaryNewGRFData(file); if (config == _cur.grfconfig) _cur.skip_sprites = -1; if (message != STR_NULL) { delete config->error; config->error = new GRFError(STR_NEWGRF_ERROR_MSG_FATAL, message); if (config == _cur.grfconfig) config->error->param_value[0] = _cur.nfo_line; } return config->error; } /** * Information for mapping static StringIDs. */ struct StringIDMapping { uint32 grfid; ///< Source NewGRF. StringID source; ///< Source StringID (GRF local). StringID *target; ///< Destination for mapping result. }; typedef std::vector StringIDMappingVector; static StringIDMappingVector _string_to_grf_mapping; /** * Record a static StringID for getting translated later. * @param source Source StringID (GRF local). * @param target Destination for the mapping result. */ static void AddStringForMapping(StringID source, StringID *target) { *target = STR_UNDEFINED; _string_to_grf_mapping.push_back({_cur.grffile->grfid, source, target}); } /** * Perform a mapping from TTDPatch's string IDs to OpenTTD's * string IDs, but only for the ones we are aware off; the rest * like likely unused and will show a warning. * @param str the string ID to convert * @return the converted string ID */ static StringID TTDPStringIDToOTTDStringIDMapping(StringID str) { /* StringID table for TextIDs 0x4E->0x6D */ static const StringID units_volume[] = { STR_ITEMS, STR_PASSENGERS, STR_TONS, STR_BAGS, STR_LITERS, STR_ITEMS, STR_CRATES, STR_TONS, STR_TONS, STR_TONS, STR_TONS, STR_BAGS, STR_TONS, STR_TONS, STR_TONS, STR_BAGS, STR_TONS, STR_TONS, STR_BAGS, STR_LITERS, STR_TONS, STR_LITERS, STR_TONS, STR_ITEMS, STR_BAGS, STR_LITERS, STR_TONS, STR_ITEMS, STR_TONS, STR_ITEMS, STR_LITERS, STR_ITEMS }; /* A string straight from a NewGRF; this was already translated by MapGRFStringID(). */ assert(!IsInsideMM(str, 0xD000, 0xD7FF)); #define TEXTID_TO_STRINGID(begin, end, stringid, stringend) \ static_assert(stringend - stringid == end - begin); \ if (str >= begin && str <= end) return str + (stringid - begin) /* We have some changes in our cargo strings, resulting in some missing. */ TEXTID_TO_STRINGID(0x000E, 0x002D, STR_CARGO_PLURAL_NOTHING, STR_CARGO_PLURAL_FIZZY_DRINKS); TEXTID_TO_STRINGID(0x002E, 0x004D, STR_CARGO_SINGULAR_NOTHING, STR_CARGO_SINGULAR_FIZZY_DRINK); if (str >= 0x004E && str <= 0x006D) return units_volume[str - 0x004E]; TEXTID_TO_STRINGID(0x006E, 0x008D, STR_QUANTITY_NOTHING, STR_QUANTITY_FIZZY_DRINKS); TEXTID_TO_STRINGID(0x008E, 0x00AD, STR_ABBREV_NOTHING, STR_ABBREV_FIZZY_DRINKS); TEXTID_TO_STRINGID(0x00D1, 0x00E0, STR_COLOUR_DARK_BLUE, STR_COLOUR_WHITE); /* Map building names according to our lang file changes. There are several * ranges of house ids, all of which need to be remapped to allow newgrfs * to use original house names. */ TEXTID_TO_STRINGID(0x200F, 0x201F, STR_TOWN_BUILDING_NAME_TALL_OFFICE_BLOCK_1, STR_TOWN_BUILDING_NAME_OLD_HOUSES_1); TEXTID_TO_STRINGID(0x2036, 0x2041, STR_TOWN_BUILDING_NAME_COTTAGES_1, STR_TOWN_BUILDING_NAME_SHOPPING_MALL_1); TEXTID_TO_STRINGID(0x2059, 0x205C, STR_TOWN_BUILDING_NAME_IGLOO_1, STR_TOWN_BUILDING_NAME_PIGGY_BANK_1); /* Same thing for industries */ TEXTID_TO_STRINGID(0x4802, 0x4826, STR_INDUSTRY_NAME_COAL_MINE, STR_INDUSTRY_NAME_SUGAR_MINE); TEXTID_TO_STRINGID(0x482D, 0x482E, STR_NEWS_INDUSTRY_CONSTRUCTION, STR_NEWS_INDUSTRY_PLANTED); TEXTID_TO_STRINGID(0x4832, 0x4834, STR_NEWS_INDUSTRY_CLOSURE_GENERAL, STR_NEWS_INDUSTRY_CLOSURE_LACK_OF_TREES); TEXTID_TO_STRINGID(0x4835, 0x4838, STR_NEWS_INDUSTRY_PRODUCTION_INCREASE_GENERAL, STR_NEWS_INDUSTRY_PRODUCTION_INCREASE_FARM); TEXTID_TO_STRINGID(0x4839, 0x483A, STR_NEWS_INDUSTRY_PRODUCTION_DECREASE_GENERAL, STR_NEWS_INDUSTRY_PRODUCTION_DECREASE_FARM); switch (str) { case 0x4830: return STR_ERROR_CAN_T_CONSTRUCT_THIS_INDUSTRY; case 0x4831: return STR_ERROR_FOREST_CAN_ONLY_BE_PLANTED; case 0x483B: return STR_ERROR_CAN_ONLY_BE_POSITIONED; } #undef TEXTID_TO_STRINGID if (str == STR_NULL) return STR_EMPTY; DEBUG(grf, 0, "Unknown StringID 0x%04X remapped to STR_EMPTY. Please open a Feature Request if you need it", str); return STR_EMPTY; } /** * Used when setting an object's property to map to the GRF's strings * while taking in consideration the "drift" between TTDPatch string system and OpenTTD's one * @param grfid Id of the grf file. * @param str StringID that we want to have the equivalent in OoenTTD. * @return The properly adjusted StringID. */ StringID MapGRFStringID(uint32 grfid, StringID str) { if (IsInsideMM(str, 0xD800, 0xE000)) { /* General text provided by NewGRF. * In the specs this is called the 0xDCxx range (misc persistent texts), * but we meanwhile extended the range to 0xD800-0xDFFF. * Note: We are not involved in the "persistent" business, since we do not store * any NewGRF strings in savegames. */ return GetGRFStringID(grfid, str); } else if (IsInsideMM(str, 0xD000, 0xD800)) { /* Callback text provided by NewGRF. * In the specs this is called the 0xD0xx range (misc graphics texts). * These texts can be returned by various callbacks. * * Due to how TTDP implements the GRF-local- to global-textid translation * texts included via 0x80 or 0x81 control codes have to add 0x400 to the textid. * We do not care about that difference and just mask out the 0x400 bit. */ str &= ~0x400; return GetGRFStringID(grfid, str); } else { /* The NewGRF wants to include/reference an original TTD string. * Try our best to find an equivalent one. */ return TTDPStringIDToOTTDStringIDMapping(str); } } static std::map _grf_id_overrides; /** * Set the override for a NewGRF * @param source_grfid The grfID which wants to override another NewGRF. * @param target_grfid The grfID which is being overridden. */ static void SetNewGRFOverride(uint32 source_grfid, uint32 target_grfid) { _grf_id_overrides[source_grfid] = target_grfid; grfmsg(5, "SetNewGRFOverride: Added override of 0x%X to 0x%X", BSWAP32(source_grfid), BSWAP32(target_grfid)); } /** * Returns the engine associated to a certain internal_id, resp. allocates it. * @param file NewGRF that wants to change the engine. * @param type Vehicle type. * @param internal_id Engine ID inside the NewGRF. * @param static_access If the engine is not present, return nullptr instead of allocating a new engine. (Used for static Action 0x04). * @return The requested engine. */ static Engine *GetNewEngine(const GRFFile *file, VehicleType type, uint16 internal_id, bool static_access = false) { /* Hack for add-on GRFs that need to modify another GRF's engines. This lets * them use the same engine slots. */ uint32 scope_grfid = INVALID_GRFID; // If not using dynamic_engines, all newgrfs share their ID range if (_settings_game.vehicle.dynamic_engines) { /* If dynamic_engies is enabled, there can be multiple independent ID ranges. */ scope_grfid = file->grfid; uint32 override = _grf_id_overrides[file->grfid]; if (override != 0) { scope_grfid = override; const GRFFile *grf_match = GetFileByGRFID(override); if (grf_match == nullptr) { grfmsg(5, "Tried mapping from GRFID %x to %x but target is not loaded", BSWAP32(file->grfid), BSWAP32(override)); } else { grfmsg(5, "Mapping from GRFID %x to %x", BSWAP32(file->grfid), BSWAP32(override)); } } /* Check if the engine is registered in the override manager */ EngineID engine = _engine_mngr.GetID(type, internal_id, scope_grfid); if (engine != INVALID_ENGINE) { Engine *e = Engine::Get(engine); if (e->grf_prop.grffile == nullptr) e->grf_prop.grffile = file; return e; } } /* Check if there is an unreserved slot */ EngineID engine = _engine_mngr.GetID(type, internal_id, INVALID_GRFID); if (engine != INVALID_ENGINE) { Engine *e = Engine::Get(engine); if (e->grf_prop.grffile == nullptr) { e->grf_prop.grffile = file; grfmsg(5, "Replaced engine at index %d for GRFID %x, type %d, index %d", e->index, BSWAP32(file->grfid), type, internal_id); } /* Reserve the engine slot */ if (!static_access) { EngineIDMapping *eid = _engine_mngr.data() + engine; eid->grfid = scope_grfid; // Note: this is INVALID_GRFID if dynamic_engines is disabled, so no reservation } return e; } if (static_access) return nullptr; if (!Engine::CanAllocateItem()) { grfmsg(0, "Can't allocate any more engines"); return nullptr; } size_t engine_pool_size = Engine::GetPoolSize(); /* ... it's not, so create a new one based off an existing engine */ Engine *e = new Engine(type, internal_id); e->grf_prop.grffile = file; /* Reserve the engine slot */ assert(_engine_mngr.size() == e->index); _engine_mngr.push_back({ scope_grfid, // Note: this is INVALID_GRFID if dynamic_engines is disabled, so no reservation internal_id, type, std::min(internal_id, _engine_counts[type]) // substitute_id == _engine_counts[subtype] means "no substitute" }); if (engine_pool_size != Engine::GetPoolSize()) { /* Resize temporary engine data ... */ _gted = ReallocT(_gted, Engine::GetPoolSize()); /* and blank the new block. */ size_t len = (Engine::GetPoolSize() - engine_pool_size) * sizeof(*_gted); memset(_gted + engine_pool_size, 0, len); } if (type == VEH_TRAIN) { _gted[e->index].railtypelabel = GetRailTypeInfo(e->u.rail.railtype)->label; } grfmsg(5, "Created new engine at index %d for GRFID %x, type %d, index %d", e->index, BSWAP32(file->grfid), type, internal_id); return e; } /** * Return the ID of a new engine * @param file The NewGRF file providing the engine. * @param type The Vehicle type. * @param internal_id NewGRF-internal ID of the engine. * @return The new EngineID. * @note depending on the dynamic_engine setting and a possible override * property the grfID may be unique or overwriting or partially re-defining * properties of an existing engine. */ EngineID GetNewEngineID(const GRFFile *file, VehicleType type, uint16 internal_id) { uint32 scope_grfid = INVALID_GRFID; // If not using dynamic_engines, all newgrfs share their ID range if (_settings_game.vehicle.dynamic_engines) { scope_grfid = file->grfid; uint32 override = _grf_id_overrides[file->grfid]; if (override != 0) scope_grfid = override; } return _engine_mngr.GetID(type, internal_id, scope_grfid); } /** * Map the colour modifiers of TTDPatch to those that Open is using. * @param grf_sprite Pointer to the structure been modified. */ static void MapSpriteMappingRecolour(PalSpriteID *grf_sprite) { if (HasBit(grf_sprite->pal, 14)) { ClrBit(grf_sprite->pal, 14); SetBit(grf_sprite->sprite, SPRITE_MODIFIER_OPAQUE); } if (HasBit(grf_sprite->sprite, 14)) { ClrBit(grf_sprite->sprite, 14); SetBit(grf_sprite->sprite, PALETTE_MODIFIER_TRANSPARENT); } if (HasBit(grf_sprite->sprite, 15)) { ClrBit(grf_sprite->sprite, 15); SetBit(grf_sprite->sprite, PALETTE_MODIFIER_COLOUR); } } /** * Read a sprite and a palette from the GRF and convert them into a format * suitable to OpenTTD. * @param buf Input stream. * @param read_flags Whether to read TileLayoutFlags. * @param invert_action1_flag Set to true, if palette bit 15 means 'not from action 1'. * @param use_cur_spritesets Whether to use currently referenceable action 1 sets. * @param feature GrfSpecFeature to use spritesets from. * @param[out] grf_sprite Read sprite and palette. * @param[out] max_sprite_offset Optionally returns the number of sprites in the spriteset of the sprite. (0 if no spritset) * @param[out] max_palette_offset Optionally returns the number of sprites in the spriteset of the palette. (0 if no spritset) * @return Read TileLayoutFlags. */ static TileLayoutFlags ReadSpriteLayoutSprite(ByteReader *buf, bool read_flags, bool invert_action1_flag, bool use_cur_spritesets, int feature, PalSpriteID *grf_sprite, uint16 *max_sprite_offset = nullptr, uint16 *max_palette_offset = nullptr) { grf_sprite->sprite = buf->ReadWord(); grf_sprite->pal = buf->ReadWord(); TileLayoutFlags flags = read_flags ? (TileLayoutFlags)buf->ReadWord() : TLF_NOTHING; MapSpriteMappingRecolour(grf_sprite); bool custom_sprite = HasBit(grf_sprite->pal, 15) != invert_action1_flag; ClrBit(grf_sprite->pal, 15); if (custom_sprite) { /* Use sprite from Action 1 */ uint index = GB(grf_sprite->sprite, 0, 14); if (use_cur_spritesets && (!_cur.IsValidSpriteSet(feature, index) || _cur.GetNumEnts(feature, index) == 0)) { grfmsg(1, "ReadSpriteLayoutSprite: Spritelayout uses undefined custom spriteset %d", index); grf_sprite->sprite = SPR_IMG_QUERY; grf_sprite->pal = PAL_NONE; } else { SpriteID sprite = use_cur_spritesets ? _cur.GetSprite(feature, index) : index; if (max_sprite_offset != nullptr) *max_sprite_offset = use_cur_spritesets ? _cur.GetNumEnts(feature, index) : UINT16_MAX; SB(grf_sprite->sprite, 0, SPRITE_WIDTH, sprite); SetBit(grf_sprite->sprite, SPRITE_MODIFIER_CUSTOM_SPRITE); } } else if ((flags & TLF_SPRITE_VAR10) && !(flags & TLF_SPRITE_REG_FLAGS)) { grfmsg(1, "ReadSpriteLayoutSprite: Spritelayout specifies var10 value for non-action-1 sprite"); DisableGrf(STR_NEWGRF_ERROR_INVALID_SPRITE_LAYOUT); return flags; } if (flags & TLF_CUSTOM_PALETTE) { /* Use palette from Action 1 */ uint index = GB(grf_sprite->pal, 0, 14); if (use_cur_spritesets && (!_cur.IsValidSpriteSet(feature, index) || _cur.GetNumEnts(feature, index) == 0)) { grfmsg(1, "ReadSpriteLayoutSprite: Spritelayout uses undefined custom spriteset %d for 'palette'", index); grf_sprite->pal = PAL_NONE; } else { SpriteID sprite = use_cur_spritesets ? _cur.GetSprite(feature, index) : index; if (max_palette_offset != nullptr) *max_palette_offset = use_cur_spritesets ? _cur.GetNumEnts(feature, index) : UINT16_MAX; SB(grf_sprite->pal, 0, SPRITE_WIDTH, sprite); SetBit(grf_sprite->pal, SPRITE_MODIFIER_CUSTOM_SPRITE); } } else if ((flags & TLF_PALETTE_VAR10) && !(flags & TLF_PALETTE_REG_FLAGS)) { grfmsg(1, "ReadSpriteLayoutRegisters: Spritelayout specifies var10 value for non-action-1 palette"); DisableGrf(STR_NEWGRF_ERROR_INVALID_SPRITE_LAYOUT); return flags; } return flags; } /** * Preprocess the TileLayoutFlags and read register modifiers from the GRF. * @param buf Input stream. * @param flags TileLayoutFlags to process. * @param is_parent Whether the sprite is a parentsprite with a bounding box. * @param dts Sprite layout to insert data into. * @param index Sprite index to process; 0 for ground sprite. */ static void ReadSpriteLayoutRegisters(ByteReader *buf, TileLayoutFlags flags, bool is_parent, NewGRFSpriteLayout *dts, uint index) { if (!(flags & TLF_DRAWING_FLAGS)) return; if (dts->registers == nullptr) dts->AllocateRegisters(); TileLayoutRegisters ®s = const_cast(dts->registers[index]); regs.flags = flags & TLF_DRAWING_FLAGS; if (flags & TLF_DODRAW) regs.dodraw = buf->ReadByte(); if (flags & TLF_SPRITE) regs.sprite = buf->ReadByte(); if (flags & TLF_PALETTE) regs.palette = buf->ReadByte(); if (is_parent) { if (flags & TLF_BB_XY_OFFSET) { regs.delta.parent[0] = buf->ReadByte(); regs.delta.parent[1] = buf->ReadByte(); } if (flags & TLF_BB_Z_OFFSET) regs.delta.parent[2] = buf->ReadByte(); } else { if (flags & TLF_CHILD_X_OFFSET) regs.delta.child[0] = buf->ReadByte(); if (flags & TLF_CHILD_Y_OFFSET) regs.delta.child[1] = buf->ReadByte(); } if (flags & TLF_SPRITE_VAR10) { regs.sprite_var10 = buf->ReadByte(); if (regs.sprite_var10 > TLR_MAX_VAR10) { grfmsg(1, "ReadSpriteLayoutRegisters: Spritelayout specifies var10 (%d) exceeding the maximal allowed value %d", regs.sprite_var10, TLR_MAX_VAR10); DisableGrf(STR_NEWGRF_ERROR_INVALID_SPRITE_LAYOUT); return; } } if (flags & TLF_PALETTE_VAR10) { regs.palette_var10 = buf->ReadByte(); if (regs.palette_var10 > TLR_MAX_VAR10) { grfmsg(1, "ReadSpriteLayoutRegisters: Spritelayout specifies var10 (%d) exceeding the maximal allowed value %d", regs.palette_var10, TLR_MAX_VAR10); DisableGrf(STR_NEWGRF_ERROR_INVALID_SPRITE_LAYOUT); return; } } } /** * Read a spritelayout from the GRF. * @param buf Input * @param num_building_sprites Number of building sprites to read * @param use_cur_spritesets Whether to use currently referenceable action 1 sets. * @param feature GrfSpecFeature to use spritesets from. * @param allow_var10 Whether the spritelayout may specify var10 values for resolving multiple action-1-2-3 chains * @param no_z_position Whether bounding boxes have no Z offset * @param dts Layout container to output into * @return True on error (GRF was disabled). */ static bool ReadSpriteLayout(ByteReader *buf, uint num_building_sprites, bool use_cur_spritesets, byte feature, bool allow_var10, bool no_z_position, NewGRFSpriteLayout *dts) { bool has_flags = HasBit(num_building_sprites, 6); ClrBit(num_building_sprites, 6); TileLayoutFlags valid_flags = TLF_KNOWN_FLAGS; if (!allow_var10) valid_flags &= ~TLF_VAR10_FLAGS; dts->Allocate(num_building_sprites); // allocate before reading groundsprite flags uint16 *max_sprite_offset = AllocaM(uint16, num_building_sprites + 1); uint16 *max_palette_offset = AllocaM(uint16, num_building_sprites + 1); MemSetT(max_sprite_offset, 0, num_building_sprites + 1); MemSetT(max_palette_offset, 0, num_building_sprites + 1); /* Groundsprite */ TileLayoutFlags flags = ReadSpriteLayoutSprite(buf, has_flags, false, use_cur_spritesets, feature, &dts->ground, max_sprite_offset, max_palette_offset); if (_cur.skip_sprites < 0) return true; if (flags & ~(valid_flags & ~TLF_NON_GROUND_FLAGS)) { grfmsg(1, "ReadSpriteLayout: Spritelayout uses invalid flag 0x%x for ground sprite", flags & ~(valid_flags & ~TLF_NON_GROUND_FLAGS)); DisableGrf(STR_NEWGRF_ERROR_INVALID_SPRITE_LAYOUT); return true; } ReadSpriteLayoutRegisters(buf, flags, false, dts, 0); if (_cur.skip_sprites < 0) return true; for (uint i = 0; i < num_building_sprites; i++) { DrawTileSeqStruct *seq = const_cast(&dts->seq[i]); flags = ReadSpriteLayoutSprite(buf, has_flags, false, use_cur_spritesets, feature, &seq->image, max_sprite_offset + i + 1, max_palette_offset + i + 1); if (_cur.skip_sprites < 0) return true; if (flags & ~valid_flags) { grfmsg(1, "ReadSpriteLayout: Spritelayout uses unknown flag 0x%x", flags & ~valid_flags); DisableGrf(STR_NEWGRF_ERROR_INVALID_SPRITE_LAYOUT); return true; } seq->delta_x = buf->ReadByte(); seq->delta_y = buf->ReadByte(); if (!no_z_position) seq->delta_z = buf->ReadByte(); if (seq->IsParentSprite()) { seq->size_x = buf->ReadByte(); seq->size_y = buf->ReadByte(); seq->size_z = buf->ReadByte(); } ReadSpriteLayoutRegisters(buf, flags, seq->IsParentSprite(), dts, i + 1); if (_cur.skip_sprites < 0) return true; } /* Check if the number of sprites per spriteset is consistent */ bool is_consistent = true; dts->consistent_max_offset = 0; for (uint i = 0; i < num_building_sprites + 1; i++) { if (max_sprite_offset[i] > 0) { if (dts->consistent_max_offset == 0) { dts->consistent_max_offset = max_sprite_offset[i]; } else if (dts->consistent_max_offset != max_sprite_offset[i]) { is_consistent = false; break; } } if (max_palette_offset[i] > 0) { if (dts->consistent_max_offset == 0) { dts->consistent_max_offset = max_palette_offset[i]; } else if (dts->consistent_max_offset != max_palette_offset[i]) { is_consistent = false; break; } } } /* When the Action1 sets are unknown, everything should be 0 (no spriteset usage) or UINT16_MAX (some spriteset usage) */ assert(use_cur_spritesets || (is_consistent && (dts->consistent_max_offset == 0 || dts->consistent_max_offset == UINT16_MAX))); if (!is_consistent || dts->registers != nullptr) { dts->consistent_max_offset = 0; if (dts->registers == nullptr) dts->AllocateRegisters(); for (uint i = 0; i < num_building_sprites + 1; i++) { TileLayoutRegisters ®s = const_cast(dts->registers[i]); regs.max_sprite_offset = max_sprite_offset[i]; regs.max_palette_offset = max_palette_offset[i]; } } return false; } /** * Translate the refit mask. refit_mask is uint32 as it has not been mapped to CargoTypes. */ static CargoTypes TranslateRefitMask(uint32 refit_mask) { CargoTypes result = 0; for (uint8 bit : SetBitIterator(refit_mask)) { CargoID cargo = GetCargoTranslation(bit, _cur.grffile, true); if (cargo != CT_INVALID) SetBit(result, cargo); } return result; } /** * Converts TTD(P) Base Price pointers into the enum used by OTTD * See http://wiki.ttdpatch.net/tiki-index.php?page=BaseCosts * @param base_pointer TTD(P) Base Price Pointer * @param error_location Function name for grf error messages * @param[out] index If \a base_pointer is valid, \a index is assigned to the matching price; else it is left unchanged */ static void ConvertTTDBasePrice(uint32 base_pointer, const char *error_location, Price *index) { /* Special value for 'none' */ if (base_pointer == 0) { *index = INVALID_PRICE; return; } static const uint32 start = 0x4B34; ///< Position of first base price static const uint32 size = 6; ///< Size of each base price record if (base_pointer < start || (base_pointer - start) % size != 0 || (base_pointer - start) / size >= PR_END) { grfmsg(1, "%s: Unsupported running cost base 0x%04X, ignoring", error_location, base_pointer); return; } *index = (Price)((base_pointer - start) / size); } /** Possible return values for the FeatureChangeInfo functions */ enum ChangeInfoResult { CIR_SUCCESS, ///< Variable was parsed and read CIR_DISABLED, ///< GRF was disabled due to error CIR_UNHANDLED, ///< Variable was parsed but unread CIR_UNKNOWN, ///< Variable is unknown CIR_INVALID_ID, ///< Attempt to modify an invalid ID }; typedef ChangeInfoResult (*VCI_Handler)(uint engine, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf); static ChangeInfoResult HandleAction0PropertyDefault(ByteReader *buf, int prop) { switch (prop) { case A0RPI_UNKNOWN_IGNORE: buf->Skip(buf->ReadExtendedByte()); return CIR_SUCCESS; case A0RPI_UNKNOWN_ERROR: return CIR_DISABLED; default: return CIR_UNKNOWN; } } static bool MappedPropertyLengthMismatch(ByteReader *buf, uint expected_size, const GRFFilePropertyRemapEntry *mapping_entry) { uint length = buf->ReadExtendedByte(); if (length != expected_size) { if (mapping_entry != nullptr) { grfmsg(2, "Ignoring use of mapped property: %s, feature: %s, mapped to: %X, with incorrect data size: %u instead of %u", mapping_entry->name, GetFeatureString(mapping_entry->feature), mapping_entry->property_id, length, expected_size); } buf->Skip(length); return true; } else { return false; } } /** * Define properties common to all vehicles * @param ei Engine info. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult CommonVehicleChangeInfo(EngineInfo *ei, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { switch (prop) { case 0x00: // Introduction date ei->base_intro = buf->ReadWord() + DAYS_TILL_ORIGINAL_BASE_YEAR; break; case 0x02: // Decay speed ei->decay_speed = buf->ReadByte(); break; case 0x03: // Vehicle life ei->lifelength = buf->ReadByte(); break; case 0x04: // Model life ei->base_life = buf->ReadByte(); break; case 0x06: // Climates available ei->climates = buf->ReadByte(); break; case PROP_VEHICLE_LOAD_AMOUNT: // 0x07 Loading speed /* Amount of cargo loaded during a vehicle's "loading tick" */ ei->load_amount = buf->ReadByte(); break; default: return HandleAction0PropertyDefault(buf, prop); } return CIR_SUCCESS; } /** * Define properties for rail vehicles * @param engine :ocal ID of the first vehicle. * @param numinfo Number of subsequent IDs to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult RailVehicleChangeInfo(uint engine, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; for (int i = 0; i < numinfo; i++) { Engine *e = GetNewEngine(_cur.grffile, VEH_TRAIN, engine + i); if (e == nullptr) return CIR_INVALID_ID; // No engine could be allocated, so neither can any next vehicles EngineInfo *ei = &e->info; RailVehicleInfo *rvi = &e->u.rail; switch (prop) { case 0x05: { // Track type uint8 tracktype = buf->ReadByte(); if (tracktype < _cur.grffile->railtype_list.size()) { _gted[e->index].railtypelabel = _cur.grffile->railtype_list[tracktype]; break; } switch (tracktype) { case 0: _gted[e->index].railtypelabel = rvi->engclass >= 2 ? RAILTYPE_ELECTRIC_LABEL : RAILTYPE_RAIL_LABEL; break; case 1: _gted[e->index].railtypelabel = RAILTYPE_MONO_LABEL; break; case 2: _gted[e->index].railtypelabel = RAILTYPE_MAGLEV_LABEL; break; default: grfmsg(1, "RailVehicleChangeInfo: Invalid track type %d specified, ignoring", tracktype); break; } break; } case 0x08: // AI passenger service /* Tells the AI that this engine is designed for * passenger services and shouldn't be used for freight. */ rvi->ai_passenger_only = buf->ReadByte(); break; case PROP_TRAIN_SPEED: { // 0x09 Speed (1 unit is 1 km-ish/h) uint16 speed = buf->ReadWord(); if (speed == 0xFFFF) speed = 0; rvi->max_speed = speed; break; } case PROP_TRAIN_POWER: // 0x0B Power rvi->power = buf->ReadWord(); /* Set engine / wagon state based on power */ if (rvi->power != 0) { if (rvi->railveh_type == RAILVEH_WAGON) { rvi->railveh_type = RAILVEH_SINGLEHEAD; } } else { rvi->railveh_type = RAILVEH_WAGON; } break; case PROP_TRAIN_RUNNING_COST_FACTOR: // 0x0D Running cost factor rvi->running_cost = buf->ReadByte(); break; case 0x0E: // Running cost base ConvertTTDBasePrice(buf->ReadDWord(), "RailVehicleChangeInfo", &rvi->running_cost_class); break; case 0x12: { // Sprite ID uint8 spriteid = buf->ReadByte(); uint8 orig_spriteid = spriteid; /* TTD sprite IDs point to a location in a 16bit array, but we use it * as an array index, so we need it to be half the original value. */ if (spriteid < 0xFD) spriteid >>= 1; if (IsValidNewGRFImageIndex(spriteid)) { rvi->image_index = spriteid; } else { grfmsg(1, "RailVehicleChangeInfo: Invalid Sprite %d specified, ignoring", orig_spriteid); rvi->image_index = 0; } break; } case 0x13: { // Dual-headed uint8 dual = buf->ReadByte(); if (dual != 0) { rvi->railveh_type = RAILVEH_MULTIHEAD; } else { rvi->railveh_type = rvi->power == 0 ? RAILVEH_WAGON : RAILVEH_SINGLEHEAD; } break; } case PROP_TRAIN_CARGO_CAPACITY: // 0x14 Cargo capacity rvi->capacity = buf->ReadByte(); break; case 0x15: { // Cargo type _gted[e->index].defaultcargo_grf = _cur.grffile; uint8 ctype = buf->ReadByte(); if (ctype == 0xFF) { /* 0xFF is specified as 'use first refittable' */ ei->cargo_type = CT_INVALID; } else if (_cur.grffile->grf_version >= 8) { /* Use translated cargo. Might result in CT_INVALID (first refittable), if cargo is not defined. */ ei->cargo_type = GetCargoTranslation(ctype, _cur.grffile); } else if (ctype < NUM_CARGO) { /* Use untranslated cargo. */ ei->cargo_type = ctype; } else { ei->cargo_type = CT_INVALID; grfmsg(2, "RailVehicleChangeInfo: Invalid cargo type %d, using first refittable", ctype); } break; } case PROP_TRAIN_WEIGHT: // 0x16 Weight SB(rvi->weight, 0, 8, buf->ReadByte()); break; case PROP_TRAIN_COST_FACTOR: // 0x17 Cost factor rvi->cost_factor = buf->ReadByte(); break; case 0x18: // AI rank grfmsg(2, "RailVehicleChangeInfo: Property 0x18 'AI rank' not used by NoAI, ignored."); buf->ReadByte(); break; case 0x19: { // Engine traction type /* What do the individual numbers mean? * 0x00 .. 0x07: Steam * 0x08 .. 0x27: Diesel * 0x28 .. 0x31: Electric * 0x32 .. 0x37: Monorail * 0x38 .. 0x41: Maglev */ uint8 traction = buf->ReadByte(); EngineClass engclass; if (traction <= 0x07) { engclass = EC_STEAM; } else if (traction <= 0x27) { engclass = EC_DIESEL; } else if (traction <= 0x31) { engclass = EC_ELECTRIC; } else if (traction <= 0x37) { engclass = EC_MONORAIL; } else if (traction <= 0x41) { engclass = EC_MAGLEV; } else { break; } if (_cur.grffile->railtype_list.size() == 0) { /* Use traction type to select between normal and electrified * rail only when no translation list is in place. */ if (_gted[e->index].railtypelabel == RAILTYPE_RAIL_LABEL && engclass >= EC_ELECTRIC) _gted[e->index].railtypelabel = RAILTYPE_ELECTRIC_LABEL; if (_gted[e->index].railtypelabel == RAILTYPE_ELECTRIC_LABEL && engclass < EC_ELECTRIC) _gted[e->index].railtypelabel = RAILTYPE_RAIL_LABEL; } rvi->engclass = engclass; break; } case 0x1A: // Alter purchase list sort order AlterVehicleListOrder(e->index, buf->ReadExtendedByte()); break; case 0x1B: // Powered wagons power bonus rvi->pow_wag_power = buf->ReadWord(); break; case 0x1C: // Refit cost ei->refit_cost = buf->ReadByte(); break; case 0x1D: { // Refit cargo uint32 mask = buf->ReadDWord(); _gted[e->index].UpdateRefittability(mask != 0); ei->refit_mask = TranslateRefitMask(mask); _gted[e->index].defaultcargo_grf = _cur.grffile; break; } case 0x1E: // Callback ei->callback_mask = buf->ReadByte(); break; case PROP_TRAIN_TRACTIVE_EFFORT: // 0x1F Tractive effort coefficient rvi->tractive_effort = buf->ReadByte(); break; case 0x20: // Air drag rvi->air_drag = buf->ReadByte(); break; case PROP_TRAIN_SHORTEN_FACTOR: // 0x21 Shorter vehicle rvi->shorten_factor = buf->ReadByte(); break; case 0x22: // Visual effect rvi->visual_effect = buf->ReadByte(); /* Avoid accidentally setting visual_effect to the default value * Since bit 6 (disable effects) is set anyways, we can safely erase some bits. */ if (rvi->visual_effect == VE_DEFAULT) { assert(HasBit(rvi->visual_effect, VE_DISABLE_EFFECT)); SB(rvi->visual_effect, VE_TYPE_START, VE_TYPE_COUNT, 0); } break; case 0x23: // Powered wagons weight bonus rvi->pow_wag_weight = buf->ReadByte(); break; case 0x24: { // High byte of vehicle weight byte weight = buf->ReadByte(); if (weight > 4) { grfmsg(2, "RailVehicleChangeInfo: Nonsensical weight of %d tons, ignoring", weight << 8); } else { SB(rvi->weight, 8, 8, weight); } break; } case PROP_TRAIN_USER_DATA: // 0x25 User-defined bit mask to set when checking veh. var. 42 rvi->user_def_data = buf->ReadByte(); break; case 0x26: // Retire vehicle early ei->retire_early = buf->ReadByte(); break; case 0x27: // Miscellaneous flags ei->misc_flags = buf->ReadByte(); _loaded_newgrf_features.has_2CC |= HasBit(ei->misc_flags, EF_USES_2CC); _gted[e->index].prop27_set = true; break; case 0x28: // Cargo classes allowed _gted[e->index].cargo_allowed = buf->ReadWord(); _gted[e->index].UpdateRefittability(_gted[e->index].cargo_allowed != 0); _gted[e->index].defaultcargo_grf = _cur.grffile; break; case 0x29: // Cargo classes disallowed _gted[e->index].cargo_disallowed = buf->ReadWord(); _gted[e->index].UpdateRefittability(false); break; case 0x2A: // Long format introduction date (days since year 0) ei->base_intro = buf->ReadDWord(); break; case PROP_TRAIN_CARGO_AGE_PERIOD: // 0x2B Cargo aging period ei->cargo_age_period = buf->ReadWord(); break; case 0x2C: // CTT refit include list case 0x2D: { // CTT refit exclude list uint8 count = buf->ReadByte(); _gted[e->index].UpdateRefittability(prop == 0x2C && count != 0); if (prop == 0x2C) _gted[e->index].defaultcargo_grf = _cur.grffile; CargoTypes &ctt = prop == 0x2C ? _gted[e->index].ctt_include_mask : _gted[e->index].ctt_exclude_mask; ctt = 0; while (count--) { CargoID ctype = GetCargoTranslation(buf->ReadByte(), _cur.grffile); if (ctype == CT_INVALID) continue; SetBit(ctt, ctype); } break; } case PROP_TRAIN_CURVE_SPEED_MOD: // 0x2E Curve speed modifier rvi->curve_speed_mod = buf->ReadWord(); break; default: ret = CommonVehicleChangeInfo(ei, prop, mapping_entry, buf); break; } } return ret; } /** * Define properties for road vehicles * @param engine Local ID of the first vehicle. * @param numinfo Number of subsequent IDs to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult RoadVehicleChangeInfo(uint engine, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; for (int i = 0; i < numinfo; i++) { Engine *e = GetNewEngine(_cur.grffile, VEH_ROAD, engine + i); if (e == nullptr) return CIR_INVALID_ID; // No engine could be allocated, so neither can any next vehicles EngineInfo *ei = &e->info; RoadVehicleInfo *rvi = &e->u.road; switch (prop) { case 0x05: // Road/tram type /* RoadTypeLabel is looked up later after the engine's road/tram * flag is set, however 0 means the value has not been set. */ _gted[e->index].roadtramtype = buf->ReadByte() + 1; break; case 0x08: // Speed (1 unit is 0.5 kmh) rvi->max_speed = buf->ReadByte(); break; case PROP_ROADVEH_RUNNING_COST_FACTOR: // 0x09 Running cost factor rvi->running_cost = buf->ReadByte(); break; case 0x0A: // Running cost base ConvertTTDBasePrice(buf->ReadDWord(), "RoadVehicleChangeInfo", &rvi->running_cost_class); break; case 0x0E: { // Sprite ID uint8 spriteid = buf->ReadByte(); uint8 orig_spriteid = spriteid; /* cars have different custom id in the GRF file */ if (spriteid == 0xFF) spriteid = 0xFD; if (spriteid < 0xFD) spriteid >>= 1; if (IsValidNewGRFImageIndex(spriteid)) { rvi->image_index = spriteid; } else { grfmsg(1, "RoadVehicleChangeInfo: Invalid Sprite %d specified, ignoring", orig_spriteid); rvi->image_index = 0; } break; } case PROP_ROADVEH_CARGO_CAPACITY: // 0x0F Cargo capacity rvi->capacity = buf->ReadByte(); break; case 0x10: { // Cargo type _gted[e->index].defaultcargo_grf = _cur.grffile; uint8 ctype = buf->ReadByte(); if (ctype == 0xFF) { /* 0xFF is specified as 'use first refittable' */ ei->cargo_type = CT_INVALID; } else if (_cur.grffile->grf_version >= 8) { /* Use translated cargo. Might result in CT_INVALID (first refittable), if cargo is not defined. */ ei->cargo_type = GetCargoTranslation(ctype, _cur.grffile); } else if (ctype < NUM_CARGO) { /* Use untranslated cargo. */ ei->cargo_type = ctype; } else { ei->cargo_type = CT_INVALID; grfmsg(2, "RailVehicleChangeInfo: Invalid cargo type %d, using first refittable", ctype); } break; } case PROP_ROADVEH_COST_FACTOR: // 0x11 Cost factor rvi->cost_factor = buf->ReadByte(); break; case 0x12: // SFX rvi->sfx = GetNewGRFSoundID(_cur.grffile, buf->ReadByte()); break; case PROP_ROADVEH_POWER: // Power in units of 10 HP. rvi->power = buf->ReadByte(); break; case PROP_ROADVEH_WEIGHT: // Weight in units of 1/4 tons. rvi->weight = buf->ReadByte(); break; case PROP_ROADVEH_SPEED: // Speed in mph/0.8 _gted[e->index].rv_max_speed = buf->ReadByte(); break; case 0x16: { // Cargoes available for refitting uint32 mask = buf->ReadDWord(); _gted[e->index].UpdateRefittability(mask != 0); ei->refit_mask = TranslateRefitMask(mask); _gted[e->index].defaultcargo_grf = _cur.grffile; break; } case 0x17: // Callback mask ei->callback_mask = buf->ReadByte(); break; case PROP_ROADVEH_TRACTIVE_EFFORT: // Tractive effort coefficient in 1/256. rvi->tractive_effort = buf->ReadByte(); break; case 0x19: // Air drag rvi->air_drag = buf->ReadByte(); break; case 0x1A: // Refit cost ei->refit_cost = buf->ReadByte(); break; case 0x1B: // Retire vehicle early ei->retire_early = buf->ReadByte(); break; case 0x1C: // Miscellaneous flags ei->misc_flags = buf->ReadByte(); _loaded_newgrf_features.has_2CC |= HasBit(ei->misc_flags, EF_USES_2CC); break; case 0x1D: // Cargo classes allowed _gted[e->index].cargo_allowed = buf->ReadWord(); _gted[e->index].UpdateRefittability(_gted[e->index].cargo_allowed != 0); _gted[e->index].defaultcargo_grf = _cur.grffile; break; case 0x1E: // Cargo classes disallowed _gted[e->index].cargo_disallowed = buf->ReadWord(); _gted[e->index].UpdateRefittability(false); break; case 0x1F: // Long format introduction date (days since year 0) ei->base_intro = buf->ReadDWord(); break; case 0x20: // Alter purchase list sort order AlterVehicleListOrder(e->index, buf->ReadExtendedByte()); break; case 0x21: // Visual effect rvi->visual_effect = buf->ReadByte(); /* Avoid accidentally setting visual_effect to the default value * Since bit 6 (disable effects) is set anyways, we can safely erase some bits. */ if (rvi->visual_effect == VE_DEFAULT) { assert(HasBit(rvi->visual_effect, VE_DISABLE_EFFECT)); SB(rvi->visual_effect, VE_TYPE_START, VE_TYPE_COUNT, 0); } break; case PROP_ROADVEH_CARGO_AGE_PERIOD: // 0x22 Cargo aging period ei->cargo_age_period = buf->ReadWord(); break; case PROP_ROADVEH_SHORTEN_FACTOR: // 0x23 Shorter vehicle rvi->shorten_factor = buf->ReadByte(); break; case 0x24: // CTT refit include list case 0x25: { // CTT refit exclude list uint8 count = buf->ReadByte(); _gted[e->index].UpdateRefittability(prop == 0x24 && count != 0); if (prop == 0x24) _gted[e->index].defaultcargo_grf = _cur.grffile; CargoTypes &ctt = prop == 0x24 ? _gted[e->index].ctt_include_mask : _gted[e->index].ctt_exclude_mask; ctt = 0; while (count--) { CargoID ctype = GetCargoTranslation(buf->ReadByte(), _cur.grffile); if (ctype == CT_INVALID) continue; SetBit(ctt, ctype); } break; } default: ret = CommonVehicleChangeInfo(ei, prop, mapping_entry, buf); break; } } return ret; } /** * Define properties for ships * @param engine Local ID of the first vehicle. * @param numinfo Number of subsequent IDs to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult ShipVehicleChangeInfo(uint engine, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; for (int i = 0; i < numinfo; i++) { Engine *e = GetNewEngine(_cur.grffile, VEH_SHIP, engine + i); if (e == nullptr) return CIR_INVALID_ID; // No engine could be allocated, so neither can any next vehicles EngineInfo *ei = &e->info; ShipVehicleInfo *svi = &e->u.ship; switch (prop) { case 0x08: { // Sprite ID uint8 spriteid = buf->ReadByte(); uint8 orig_spriteid = spriteid; /* ships have different custom id in the GRF file */ if (spriteid == 0xFF) spriteid = 0xFD; if (spriteid < 0xFD) spriteid >>= 1; if (IsValidNewGRFImageIndex(spriteid)) { svi->image_index = spriteid; } else { grfmsg(1, "ShipVehicleChangeInfo: Invalid Sprite %d specified, ignoring", orig_spriteid); svi->image_index = 0; } break; } case 0x09: // Refittable svi->old_refittable = (buf->ReadByte() != 0); break; case PROP_SHIP_COST_FACTOR: // 0x0A Cost factor svi->cost_factor = buf->ReadByte(); break; case PROP_SHIP_SPEED: // 0x0B Speed (1 unit is 0.5 km-ish/h) svi->max_speed = buf->ReadByte(); break; case 0x0C: { // Cargo type _gted[e->index].defaultcargo_grf = _cur.grffile; uint8 ctype = buf->ReadByte(); if (ctype == 0xFF) { /* 0xFF is specified as 'use first refittable' */ ei->cargo_type = CT_INVALID; } else if (_cur.grffile->grf_version >= 8) { /* Use translated cargo. Might result in CT_INVALID (first refittable), if cargo is not defined. */ ei->cargo_type = GetCargoTranslation(ctype, _cur.grffile); } else if (ctype < NUM_CARGO) { /* Use untranslated cargo. */ ei->cargo_type = ctype; } else { ei->cargo_type = CT_INVALID; grfmsg(2, "RailVehicleChangeInfo: Invalid cargo type %d, using first refittable", ctype); } break; } case PROP_SHIP_CARGO_CAPACITY: // 0x0D Cargo capacity svi->capacity = buf->ReadWord(); break; case PROP_SHIP_RUNNING_COST_FACTOR: // 0x0F Running cost factor svi->running_cost = buf->ReadByte(); break; case 0x10: // SFX svi->sfx = GetNewGRFSoundID(_cur.grffile, buf->ReadByte()); break; case 0x11: { // Cargoes available for refitting uint32 mask = buf->ReadDWord(); _gted[e->index].UpdateRefittability(mask != 0); ei->refit_mask = TranslateRefitMask(mask); _gted[e->index].defaultcargo_grf = _cur.grffile; break; } case 0x12: // Callback mask ei->callback_mask = buf->ReadByte(); break; case 0x13: // Refit cost ei->refit_cost = buf->ReadByte(); break; case 0x14: // Ocean speed fraction svi->ocean_speed_frac = buf->ReadByte(); break; case 0x15: // Canal speed fraction svi->canal_speed_frac = buf->ReadByte(); break; case 0x16: // Retire vehicle early ei->retire_early = buf->ReadByte(); break; case 0x17: // Miscellaneous flags ei->misc_flags = buf->ReadByte(); _loaded_newgrf_features.has_2CC |= HasBit(ei->misc_flags, EF_USES_2CC); break; case 0x18: // Cargo classes allowed _gted[e->index].cargo_allowed = buf->ReadWord(); _gted[e->index].UpdateRefittability(_gted[e->index].cargo_allowed != 0); _gted[e->index].defaultcargo_grf = _cur.grffile; break; case 0x19: // Cargo classes disallowed _gted[e->index].cargo_disallowed = buf->ReadWord(); _gted[e->index].UpdateRefittability(false); break; case 0x1A: // Long format introduction date (days since year 0) ei->base_intro = buf->ReadDWord(); break; case 0x1B: // Alter purchase list sort order AlterVehicleListOrder(e->index, buf->ReadExtendedByte()); break; case 0x1C: // Visual effect svi->visual_effect = buf->ReadByte(); /* Avoid accidentally setting visual_effect to the default value * Since bit 6 (disable effects) is set anyways, we can safely erase some bits. */ if (svi->visual_effect == VE_DEFAULT) { assert(HasBit(svi->visual_effect, VE_DISABLE_EFFECT)); SB(svi->visual_effect, VE_TYPE_START, VE_TYPE_COUNT, 0); } break; case PROP_SHIP_CARGO_AGE_PERIOD: // 0x1D Cargo aging period ei->cargo_age_period = buf->ReadWord(); break; case 0x1E: // CTT refit include list case 0x1F: { // CTT refit exclude list uint8 count = buf->ReadByte(); _gted[e->index].UpdateRefittability(prop == 0x1E && count != 0); if (prop == 0x1E) _gted[e->index].defaultcargo_grf = _cur.grffile; CargoTypes &ctt = prop == 0x1E ? _gted[e->index].ctt_include_mask : _gted[e->index].ctt_exclude_mask; ctt = 0; while (count--) { CargoID ctype = GetCargoTranslation(buf->ReadByte(), _cur.grffile); if (ctype == CT_INVALID) continue; SetBit(ctt, ctype); } break; } default: ret = CommonVehicleChangeInfo(ei, prop, mapping_entry, buf); break; } } return ret; } /** * Define properties for aircraft * @param engine Local ID of the aircraft. * @param numinfo Number of subsequent IDs to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult AircraftVehicleChangeInfo(uint engine, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; for (int i = 0; i < numinfo; i++) { Engine *e = GetNewEngine(_cur.grffile, VEH_AIRCRAFT, engine + i); if (e == nullptr) return CIR_INVALID_ID; // No engine could be allocated, so neither can any next vehicles EngineInfo *ei = &e->info; AircraftVehicleInfo *avi = &e->u.air; switch (prop) { case 0x08: { // Sprite ID uint8 spriteid = buf->ReadByte(); uint8 orig_spriteid = spriteid; /* aircraft have different custom id in the GRF file */ if (spriteid == 0xFF) spriteid = 0xFD; if (spriteid < 0xFD) spriteid >>= 1; if (IsValidNewGRFImageIndex(spriteid)) { avi->image_index = spriteid; } else { grfmsg(1, "AircraftVehicleChangeInfo: Invalid Sprite %d specified, ignoring", orig_spriteid); avi->image_index = 0; } break; } case 0x09: // Helicopter if (buf->ReadByte() == 0) { avi->subtype = AIR_HELI; } else { SB(avi->subtype, 0, 1, 1); // AIR_CTOL } break; case 0x0A: // Large SB(avi->subtype, 1, 1, (buf->ReadByte() != 0 ? 1 : 0)); // AIR_FAST break; case PROP_AIRCRAFT_COST_FACTOR: // 0x0B Cost factor avi->cost_factor = buf->ReadByte(); break; case PROP_AIRCRAFT_SPEED: // 0x0C Speed (1 unit is 8 mph, we translate to 1 unit is 1 km-ish/h) avi->max_speed = (buf->ReadByte() * 128) / 10; break; case 0x0D: // Acceleration avi->acceleration = buf->ReadByte(); break; case PROP_AIRCRAFT_RUNNING_COST_FACTOR: // 0x0E Running cost factor avi->running_cost = buf->ReadByte(); break; case PROP_AIRCRAFT_PASSENGER_CAPACITY: // 0x0F Passenger capacity avi->passenger_capacity = buf->ReadWord(); break; case PROP_AIRCRAFT_MAIL_CAPACITY: // 0x11 Mail capacity avi->mail_capacity = buf->ReadByte(); break; case 0x12: // SFX avi->sfx = GetNewGRFSoundID(_cur.grffile, buf->ReadByte()); break; case 0x13: { // Cargoes available for refitting uint32 mask = buf->ReadDWord(); _gted[e->index].UpdateRefittability(mask != 0); ei->refit_mask = TranslateRefitMask(mask); _gted[e->index].defaultcargo_grf = _cur.grffile; break; } case 0x14: // Callback mask ei->callback_mask = buf->ReadByte(); break; case 0x15: // Refit cost ei->refit_cost = buf->ReadByte(); break; case 0x16: // Retire vehicle early ei->retire_early = buf->ReadByte(); break; case 0x17: // Miscellaneous flags ei->misc_flags = buf->ReadByte(); _loaded_newgrf_features.has_2CC |= HasBit(ei->misc_flags, EF_USES_2CC); break; case 0x18: // Cargo classes allowed _gted[e->index].cargo_allowed = buf->ReadWord(); _gted[e->index].UpdateRefittability(_gted[e->index].cargo_allowed != 0); _gted[e->index].defaultcargo_grf = _cur.grffile; break; case 0x19: // Cargo classes disallowed _gted[e->index].cargo_disallowed = buf->ReadWord(); _gted[e->index].UpdateRefittability(false); break; case 0x1A: // Long format introduction date (days since year 0) ei->base_intro = buf->ReadDWord(); break; case 0x1B: // Alter purchase list sort order AlterVehicleListOrder(e->index, buf->ReadExtendedByte()); break; case PROP_AIRCRAFT_CARGO_AGE_PERIOD: // 0x1C Cargo aging period ei->cargo_age_period = buf->ReadWord(); break; case 0x1D: // CTT refit include list case 0x1E: { // CTT refit exclude list uint8 count = buf->ReadByte(); _gted[e->index].UpdateRefittability(prop == 0x1D && count != 0); if (prop == 0x1D) _gted[e->index].defaultcargo_grf = _cur.grffile; CargoTypes &ctt = prop == 0x1D ? _gted[e->index].ctt_include_mask : _gted[e->index].ctt_exclude_mask; ctt = 0; while (count--) { CargoID ctype = GetCargoTranslation(buf->ReadByte(), _cur.grffile); if (ctype == CT_INVALID) continue; SetBit(ctt, ctype); } break; } case PROP_AIRCRAFT_RANGE: // 0x1F Max aircraft range avi->max_range = buf->ReadWord(); break; default: ret = CommonVehicleChangeInfo(ei, prop, mapping_entry, buf); break; } } return ret; } /** * Define properties for stations * @param stid StationID of the first station tile. * @param numinfo Number of subsequent station tiles to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult StationChangeInfo(uint stid, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; if (stid + numinfo > NUM_STATIONS_PER_GRF) { grfmsg(1, "StationChangeInfo: Station %u is invalid, max %u, ignoring", stid + numinfo, NUM_STATIONS_PER_GRF); return CIR_INVALID_ID; } /* Allocate station specs if necessary */ if (_cur.grffile->stations == nullptr) _cur.grffile->stations = CallocT(NUM_STATIONS_PER_GRF); for (int i = 0; i < numinfo; i++) { StationSpec *statspec = _cur.grffile->stations[stid + i]; /* Check that the station we are modifying is defined. */ if (statspec == nullptr && prop != 0x08) { grfmsg(2, "StationChangeInfo: Attempt to modify undefined station %u, ignoring", stid + i); return CIR_INVALID_ID; } switch (prop) { case 0x08: { // Class ID StationSpec **spec = &_cur.grffile->stations[stid + i]; /* Property 0x08 is special; it is where the station is allocated */ if (*spec == nullptr) *spec = new StationSpec(); /* Swap classid because we read it in BE meaning WAYP or DFLT */ uint32 classid = buf->ReadDWord(); (*spec)->cls_id = StationClass::Allocate(BSWAP32(classid)); break; } case 0x09: { // Define sprite layout uint16 tiles = buf->ReadExtendedByte(); statspec->renderdata.clear(); // delete earlier loaded stuff statspec->renderdata.reserve(tiles); for (uint t = 0; t < tiles; t++) { NewGRFSpriteLayout *dts = &statspec->renderdata.emplace_back(); dts->consistent_max_offset = UINT16_MAX; // Spritesets are unknown, so no limit. if (buf->HasData(4) && *(unaligned_uint32*)buf->Data() == 0) { buf->Skip(4); extern const DrawTileSprites _station_display_datas_rail[8]; dts->Clone(&_station_display_datas_rail[t % 8]); continue; } ReadSpriteLayoutSprite(buf, false, false, false, GSF_STATIONS, &dts->ground); /* On error, bail out immediately. Temporary GRF data was already freed */ if (_cur.skip_sprites < 0) return CIR_DISABLED; static std::vector tmp_layout; tmp_layout.clear(); for (;;) { /* no relative bounding box support */ DrawTileSeqStruct &dtss = tmp_layout.emplace_back(); MemSetT(&dtss, 0); dtss.delta_x = buf->ReadByte(); if (dtss.IsTerminator()) break; dtss.delta_y = buf->ReadByte(); dtss.delta_z = buf->ReadByte(); dtss.size_x = buf->ReadByte(); dtss.size_y = buf->ReadByte(); dtss.size_z = buf->ReadByte(); ReadSpriteLayoutSprite(buf, false, true, false, GSF_STATIONS, &dtss.image); /* On error, bail out immediately. Temporary GRF data was already freed */ if (_cur.skip_sprites < 0) return CIR_DISABLED; } dts->Clone(tmp_layout.data()); } /* Number of layouts must be even, alternating X and Y */ if (statspec->renderdata.size() & 1) { grfmsg(1, "StationChangeInfo: Station %u defines an odd number of sprite layouts, dropping the last item", stid + i); statspec->renderdata.pop_back(); } break; } case 0x0A: { // Copy sprite layout byte srcid = buf->ReadByte(); const StationSpec *srcstatspec = _cur.grffile->stations[srcid]; if (srcstatspec == nullptr) { grfmsg(1, "StationChangeInfo: Station %u is not defined, cannot copy sprite layout to %u.", srcid, stid + i); continue; } statspec->renderdata.clear(); // delete earlier loaded stuff statspec->renderdata.reserve(srcstatspec->renderdata.size()); for (const auto &it : srcstatspec->renderdata) { NewGRFSpriteLayout *dts = &statspec->renderdata.emplace_back(); dts->Clone(&it); } break; } case 0x0B: // Callback mask statspec->callback_mask = buf->ReadByte(); break; case 0x0C: // Disallowed number of platforms statspec->disallowed_platforms = buf->ReadByte(); break; case 0x0D: // Disallowed platform lengths statspec->disallowed_lengths = buf->ReadByte(); break; case 0x0E: // Define custom layout while (buf->HasData()) { byte length = buf->ReadByte(); byte number = buf->ReadByte(); if (length == 0 || number == 0) break; if (statspec->layouts.size() < length) statspec->layouts.resize(length); if (statspec->layouts[length - 1].size() < number) statspec->layouts[length - 1].resize(number); const byte *layout = buf->ReadBytes(length * number); statspec->layouts[length - 1][number - 1].assign(layout, layout + length * number); /* Validate tile values are only the permitted 00, 02, 04 and 06. */ for (auto &tile : statspec->layouts[length - 1][number - 1]) { if ((tile & 6) != tile) { grfmsg(1, "StationChangeInfo: Invalid tile %u in layout %ux%u", tile, length, number); tile &= 6; } } } break; case 0x0F: { // Copy custom layout byte srcid = buf->ReadByte(); const StationSpec *srcstatspec = _cur.grffile->stations[srcid]; if (srcstatspec == nullptr) { grfmsg(1, "StationChangeInfo: Station %u is not defined, cannot copy tile layout to %u.", srcid, stid + i); continue; } statspec->layouts = srcstatspec->layouts; break; } case 0x10: // Little/lots cargo threshold statspec->cargo_threshold = buf->ReadWord(); break; case 0x11: // Pylon placement statspec->pylons = buf->ReadByte(); break; case 0x12: // Cargo types for random triggers if (_cur.grffile->grf_version >= 7) { statspec->cargo_triggers = TranslateRefitMask(buf->ReadDWord()); } else { statspec->cargo_triggers = (CargoTypes)buf->ReadDWord(); } break; case 0x13: // General flags statspec->flags = buf->ReadByte(); break; case 0x14: // Overhead wire placement statspec->wires = buf->ReadByte(); break; case 0x15: // Blocked tiles statspec->blocked = buf->ReadByte(); break; case 0x16: // Animation info statspec->animation.frames = buf->ReadByte(); statspec->animation.status = buf->ReadByte(); break; case 0x17: // Animation speed statspec->animation.speed = buf->ReadByte(); break; case 0x18: // Animation triggers statspec->animation.triggers = buf->ReadWord(); break; case 0x1A: { // Advanced sprite layout uint16 tiles = buf->ReadExtendedByte(); statspec->renderdata.clear(); // delete earlier loaded stuff statspec->renderdata.reserve(tiles); for (uint t = 0; t < tiles; t++) { NewGRFSpriteLayout *dts = &statspec->renderdata.emplace_back(); uint num_building_sprites = buf->ReadByte(); /* On error, bail out immediately. Temporary GRF data was already freed */ if (ReadSpriteLayout(buf, num_building_sprites, false, GSF_STATIONS, true, false, dts)) return CIR_DISABLED; } /* Number of layouts must be even, alternating X and Y */ if (statspec->renderdata.size() & 1) { grfmsg(1, "StationChangeInfo: Station %u defines an odd number of sprite layouts, dropping the last item", stid + i); statspec->renderdata.pop_back(); } break; } case A0RPI_STATION_MIN_BRIDGE_HEIGHT: if (MappedPropertyLengthMismatch(buf, 8, mapping_entry)) break; FALLTHROUGH; case 0x1B: // Minimum height for a bridge above SetBit(statspec->internal_flags, SSIF_BRIDGE_HEIGHTS_SET); for (uint i = 0; i < 8; i++) { statspec->bridge_height[i] = buf->ReadByte(); } break; case A0RPI_STATION_DISALLOWED_BRIDGE_PILLARS: if (MappedPropertyLengthMismatch(buf, 8, mapping_entry)) break; SetBit(statspec->internal_flags, SSIF_BRIDGE_DISALLOWED_PILLARS_SET); for (uint i = 0; i < 8; i++) { statspec->bridge_disallowed_pillars[i] = buf->ReadByte(); } break; default: ret = HandleAction0PropertyDefault(buf, prop); break; } } return ret; } /** * Define properties for water features * @param id Type of the first water feature. * @param numinfo Number of subsequent water feature ids to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult CanalChangeInfo(uint id, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; if (id + numinfo > CF_END) { grfmsg(1, "CanalChangeInfo: Canal feature 0x%02X is invalid, max %u, ignoring", id + numinfo, CF_END); return CIR_INVALID_ID; } for (int i = 0; i < numinfo; i++) { CanalProperties *cp = &_cur.grffile->canal_local_properties[id + i]; switch (prop) { case 0x08: cp->callback_mask = buf->ReadByte(); break; case 0x09: cp->flags = buf->ReadByte(); break; default: ret = HandleAction0PropertyDefault(buf, prop); break; } } return ret; } /** * Define properties for bridges * @param brid BridgeID of the bridge. * @param numinfo Number of subsequent bridgeIDs to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult BridgeChangeInfo(uint brid, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; if (brid + numinfo > MAX_BRIDGES) { grfmsg(1, "BridgeChangeInfo: Bridge %u is invalid, max %u, ignoring", brid + numinfo, MAX_BRIDGES); return CIR_INVALID_ID; } for (int i = 0; i < numinfo; i++) { BridgeSpec *bridge = &_bridge[brid + i]; switch (prop) { case 0x08: { // Year of availability /* We treat '0' as always available */ byte year = buf->ReadByte(); bridge->avail_year = (year > 0 ? ORIGINAL_BASE_YEAR + year : 0); break; } case 0x09: // Minimum length bridge->min_length = buf->ReadByte(); break; case 0x0A: // Maximum length bridge->max_length = buf->ReadByte(); if (bridge->max_length > 16) bridge->max_length = 0xFFFF; break; case 0x0B: // Cost factor bridge->price = buf->ReadByte(); break; case 0x0C: // Maximum speed bridge->speed = buf->ReadWord(); break; case 0x0D: { // Bridge sprite tables byte tableid = buf->ReadByte(); byte numtables = buf->ReadByte(); if (bridge->sprite_table == nullptr) { /* Allocate memory for sprite table pointers and zero out */ bridge->sprite_table = CallocT(7); } for (; numtables-- != 0; tableid++) { if (tableid >= 7) { // skip invalid data grfmsg(1, "BridgeChangeInfo: Table %d >= 7, skipping", tableid); for (byte sprite = 0; sprite < 32; sprite++) buf->ReadDWord(); continue; } if (bridge->sprite_table[tableid] == nullptr) { bridge->sprite_table[tableid] = MallocT(32); } for (byte sprite = 0; sprite < 32; sprite++) { SpriteID image = buf->ReadWord(); PaletteID pal = buf->ReadWord(); bridge->sprite_table[tableid][sprite].sprite = image; bridge->sprite_table[tableid][sprite].pal = pal; MapSpriteMappingRecolour(&bridge->sprite_table[tableid][sprite]); } } if (!HasBit(bridge->ctrl_flags, BSCF_CUSTOM_PILLAR_FLAGS)) SetBit(bridge->ctrl_flags, BSCF_INVALID_PILLAR_FLAGS); break; } case 0x0E: // Flags; bit 0 - disable far pillars bridge->flags = buf->ReadByte(); break; case 0x0F: // Long format year of availability (year since year 0) bridge->avail_year = Clamp(buf->ReadDWord(), MIN_YEAR, MAX_YEAR); break; case 0x10: { // purchase string StringID newone = GetGRFStringID(_cur.grffile->grfid, buf->ReadWord()); if (newone != STR_UNDEFINED) bridge->material = newone; break; } case 0x11: // description of bridge with rails or roads case 0x12: { StringID newone = GetGRFStringID(_cur.grffile->grfid, buf->ReadWord()); if (newone != STR_UNDEFINED) bridge->transport_name[prop - 0x11] = newone; break; } case 0x13: // 16 bits cost multiplier bridge->price = buf->ReadWord(); break; case A0RPI_BRIDGE_MENU_ICON: if (MappedPropertyLengthMismatch(buf, 4, mapping_entry)) break; FALLTHROUGH; case 0x14: // purchase sprite bridge->sprite = buf->ReadWord(); bridge->pal = buf->ReadWord(); break; case A0RPI_BRIDGE_PILLAR_FLAGS: if (MappedPropertyLengthMismatch(buf, 12, mapping_entry)) break; for (uint i = 0; i < 12; i++) { bridge->pillar_flags[i] = buf->ReadByte(); } ClrBit(bridge->ctrl_flags, BSCF_INVALID_PILLAR_FLAGS); SetBit(bridge->ctrl_flags, BSCF_CUSTOM_PILLAR_FLAGS); break; case A0RPI_BRIDGE_AVAILABILITY_FLAGS: { if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; byte flags = buf->ReadByte(); SB(bridge->ctrl_flags, BSCF_NOT_AVAILABLE_TOWN, 1, HasBit(flags, 0) ? 1 : 0); SB(bridge->ctrl_flags, BSCF_NOT_AVAILABLE_AI_GS, 1, HasBit(flags, 1) ? 1 : 0); break; } default: ret = HandleAction0PropertyDefault(buf, prop); break; } } return ret; } /** * Ignore a house property * @param prop Property to read. * @param buf Property value. * @return ChangeInfoResult. */ static ChangeInfoResult IgnoreTownHouseProperty(int prop, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; switch (prop) { case 0x09: case 0x0B: case 0x0C: case 0x0D: case 0x0E: case 0x0F: case 0x11: case 0x14: case 0x15: case 0x16: case 0x18: case 0x19: case 0x1A: case 0x1B: case 0x1C: case 0x1D: case 0x1F: buf->ReadByte(); break; case 0x0A: case 0x10: case 0x12: case 0x13: case 0x21: case 0x22: buf->ReadWord(); break; case 0x1E: buf->ReadDWord(); break; case 0x17: for (uint j = 0; j < 4; j++) buf->ReadByte(); break; case 0x20: { byte count = buf->ReadByte(); for (byte j = 0; j < count; j++) buf->ReadByte(); break; } case 0x23: buf->Skip(buf->ReadByte() * 2); break; default: ret = HandleAction0PropertyDefault(buf, prop); break; } return ret; } /** * Define properties for houses * @param hid HouseID of the house. * @param numinfo Number of subsequent houseIDs to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult TownHouseChangeInfo(uint hid, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; if (hid + numinfo > NUM_HOUSES_PER_GRF) { grfmsg(1, "TownHouseChangeInfo: Too many houses loaded (%u), max (%u). Ignoring.", hid + numinfo, NUM_HOUSES_PER_GRF); return CIR_INVALID_ID; } /* Allocate house specs if they haven't been allocated already. */ if (_cur.grffile->housespec == nullptr) { _cur.grffile->housespec = CallocT(NUM_HOUSES_PER_GRF); } for (int i = 0; i < numinfo; i++) { HouseSpec *housespec = _cur.grffile->housespec[hid + i]; if (prop != 0x08 && housespec == nullptr) { /* If the house property 08 is not yet set, ignore this property */ ChangeInfoResult cir = IgnoreTownHouseProperty(prop, buf); if (cir > ret) ret = cir; continue; } switch (prop) { case 0x08: { // Substitute building type, and definition of a new house HouseSpec **house = &_cur.grffile->housespec[hid + i]; byte subs_id = buf->ReadByte(); if (subs_id == 0xFF) { /* Instead of defining a new house, a substitute house id * of 0xFF disables the old house with the current id. */ HouseSpec::Get(hid + i)->enabled = false; continue; } else if (subs_id >= NEW_HOUSE_OFFSET) { /* The substitute id must be one of the original houses. */ grfmsg(2, "TownHouseChangeInfo: Attempt to use new house %u as substitute house for %u. Ignoring.", subs_id, hid + i); continue; } /* Allocate space for this house. */ if (*house == nullptr) *house = CallocT(1); housespec = *house; MemCpyT(housespec, HouseSpec::Get(subs_id)); housespec->enabled = true; housespec->grf_prop.local_id = hid + i; housespec->grf_prop.subst_id = subs_id; housespec->grf_prop.grffile = _cur.grffile; housespec->random_colour[0] = 0x04; // those 4 random colours are the base colour housespec->random_colour[1] = 0x08; // for all new houses housespec->random_colour[2] = 0x0C; // they stand for red, blue, orange and green housespec->random_colour[3] = 0x06; /* Make sure that the third cargo type is valid in this * climate. This can cause problems when copying the properties * of a house that accepts food, where the new house is valid * in the temperate climate. */ if (!CargoSpec::Get(housespec->accepts_cargo[2])->IsValid()) { housespec->cargo_acceptance[2] = 0; } break; } case 0x09: // Building flags housespec->building_flags = (BuildingFlags)buf->ReadByte(); break; case 0x0A: { // Availability years uint16 years = buf->ReadWord(); housespec->min_year = GB(years, 0, 8) > 150 ? MAX_YEAR : ORIGINAL_BASE_YEAR + GB(years, 0, 8); housespec->max_year = GB(years, 8, 8) > 150 ? MAX_YEAR : ORIGINAL_BASE_YEAR + GB(years, 8, 8); break; } case 0x0B: // Population housespec->population = buf->ReadByte(); break; case 0x0C: // Mail generation multiplier housespec->mail_generation = buf->ReadByte(); break; case 0x0D: // Passenger acceptance case 0x0E: // Mail acceptance housespec->cargo_acceptance[prop - 0x0D] = buf->ReadByte(); break; case 0x0F: { // Goods/candy, food/fizzy drinks acceptance int8 goods = buf->ReadByte(); /* If value of goods is negative, it means in fact food or, if in toyland, fizzy_drink acceptance. * Else, we have "standard" 3rd cargo type, goods or candy, for toyland once more */ CargoID cid = (goods >= 0) ? ((_settings_game.game_creation.landscape == LT_TOYLAND) ? CT_CANDY : CT_GOODS) : ((_settings_game.game_creation.landscape == LT_TOYLAND) ? CT_FIZZY_DRINKS : CT_FOOD); /* Make sure the cargo type is valid in this climate. */ if (!CargoSpec::Get(cid)->IsValid()) goods = 0; housespec->accepts_cargo[2] = cid; housespec->cargo_acceptance[2] = abs(goods); // but we do need positive value here break; } case 0x10: // Local authority rating decrease on removal housespec->remove_rating_decrease = buf->ReadWord(); break; case 0x11: // Removal cost multiplier housespec->removal_cost = buf->ReadByte(); break; case 0x12: // Building name ID AddStringForMapping(buf->ReadWord(), &housespec->building_name); break; case 0x13: // Building availability mask housespec->building_availability = (HouseZones)buf->ReadWord(); break; case 0x14: // House callback mask housespec->callback_mask |= buf->ReadByte(); break; case 0x15: { // House override byte byte override = buf->ReadByte(); /* The house being overridden must be an original house. */ if (override >= NEW_HOUSE_OFFSET) { grfmsg(2, "TownHouseChangeInfo: Attempt to override new house %u with house id %u. Ignoring.", override, hid + i); continue; } _house_mngr.Add(hid + i, _cur.grffile->grfid, override); break; } case 0x16: // Periodic refresh multiplier housespec->processing_time = std::min(buf->ReadByte(), 63u); break; case 0x17: // Four random colours to use for (uint j = 0; j < 4; j++) housespec->random_colour[j] = buf->ReadByte(); break; case 0x18: // Relative probability of appearing housespec->probability = buf->ReadByte(); break; case 0x19: // Extra flags housespec->extra_flags = (HouseExtraFlags)buf->ReadByte(); break; case 0x1A: // Animation frames housespec->animation.frames = buf->ReadByte(); housespec->animation.status = GB(housespec->animation.frames, 7, 1); SB(housespec->animation.frames, 7, 1, 0); break; case 0x1B: // Animation speed housespec->animation.speed = Clamp(buf->ReadByte(), 2, 16); break; case 0x1C: // Class of the building type housespec->class_id = AllocateHouseClassID(buf->ReadByte(), _cur.grffile->grfid); break; case 0x1D: // Callback mask part 2 housespec->callback_mask |= (buf->ReadByte() << 8); break; case 0x1E: { // Accepted cargo types uint32 cargotypes = buf->ReadDWord(); /* Check if the cargo types should not be changed */ if (cargotypes == 0xFFFFFFFF) break; for (uint j = 0; j < 3; j++) { /* Get the cargo number from the 'list' */ uint8 cargo_part = GB(cargotypes, 8 * j, 8); CargoID cargo = GetCargoTranslation(cargo_part, _cur.grffile); if (cargo == CT_INVALID) { /* Disable acceptance of invalid cargo type */ housespec->cargo_acceptance[j] = 0; } else { housespec->accepts_cargo[j] = cargo; } } break; } case 0x1F: // Minimum life span housespec->minimum_life = buf->ReadByte(); break; case 0x20: { // Cargo acceptance watch list byte count = buf->ReadByte(); for (byte j = 0; j < count; j++) { CargoID cargo = GetCargoTranslation(buf->ReadByte(), _cur.grffile); if (cargo != CT_INVALID) SetBit(housespec->watched_cargoes, cargo); } break; } case 0x21: // long introduction year housespec->min_year = buf->ReadWord(); break; case 0x22: // long maximum year housespec->max_year = buf->ReadWord(); break; case 0x23: { // variable length cargo types accepted uint count = buf->ReadByte(); if (count > lengthof(housespec->accepts_cargo)) { GRFError *error = DisableGrf(STR_NEWGRF_ERROR_LIST_PROPERTY_TOO_LONG); error->param_value[1] = prop; return CIR_DISABLED; } /* Always write the full accepts_cargo array, and check each index for being inside the * provided data. This ensures all values are properly initialized, and also avoids * any risks of array overrun. */ for (uint i = 0; i < lengthof(housespec->accepts_cargo); i++) { if (i < count) { housespec->accepts_cargo[i] = GetCargoTranslation(buf->ReadByte(), _cur.grffile); housespec->cargo_acceptance[i] = buf->ReadByte(); } else { housespec->accepts_cargo[i] = CT_INVALID; housespec->cargo_acceptance[i] = 0; } } break; } default: ret = HandleAction0PropertyDefault(buf, prop); break; } } return ret; } /** * Get the language map associated with a given NewGRF and language. * @param grfid The NewGRF to get the map for. * @param language_id The (NewGRF) language ID to get the map for. * @return The LanguageMap, or nullptr if it couldn't be found. */ /* static */ const LanguageMap *LanguageMap::GetLanguageMap(uint32 grfid, uint8 language_id) { /* LanguageID "MAX_LANG", i.e. 7F is any. This language can't have a gender/case mapping, but has to be handled gracefully. */ const GRFFile *grffile = GetFileByGRFID(grfid); return (grffile != nullptr && grffile->language_map != nullptr && language_id < MAX_LANG) ? &grffile->language_map[language_id] : nullptr; } /** * Load a cargo- or railtype-translation table. * @param gvid ID of the global variable. This is basically only checked for zerones. * @param numinfo Number of subsequent IDs to change the property for. * @param buf The property value. * @param[in,out] translation_table Storage location for the translation table. * @param name Name of the table for debug output. * @return ChangeInfoResult. */ template static ChangeInfoResult LoadTranslationTable(uint gvid, int numinfo, ByteReader *buf, T &translation_table, const char *name) { if (gvid != 0) { grfmsg(1, "LoadTranslationTable: %s translation table must start at zero", name); return CIR_INVALID_ID; } translation_table.clear(); for (int i = 0; i < numinfo; i++) { uint32 item = buf->ReadDWord(); translation_table.push_back(BSWAP32(item)); } return CIR_SUCCESS; } /** * Helper to read a DWord worth of bytes from the reader * and to return it as a valid string. * @param reader The source of the DWord. * @return The read DWord as string. */ static std::string ReadDWordAsString(ByteReader *reader) { char output[5]; for (int i = 0; i < 4; i++) output[i] = reader->ReadByte(); output[4] = '\0'; StrMakeValidInPlace(output, lastof(output)); return std::string(output); } /** * Define properties for global variables * @param gvid ID of the global variable. * @param numinfo Number of subsequent IDs to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult GlobalVarChangeInfo(uint gvid, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { /* Properties which are handled as a whole */ switch (prop) { case 0x09: // Cargo Translation Table; loading during both reservation and activation stage (in case it is selected depending on defined cargos) return LoadTranslationTable(gvid, numinfo, buf, _cur.grffile->cargo_list, "Cargo"); case 0x12: // Rail type translation table; loading during both reservation and activation stage (in case it is selected depending on defined railtypes) return LoadTranslationTable(gvid, numinfo, buf, _cur.grffile->railtype_list, "Rail type"); case 0x16: // Road type translation table; loading during both reservation and activation stage (in case it is selected depending on defined railtypes) return LoadTranslationTable(gvid, numinfo, buf, _cur.grffile->roadtype_list, "Road type"); case 0x17: // Tram type translation table; loading during both reservation and activation stage (in case it is selected depending on defined railtypes) return LoadTranslationTable(gvid, numinfo, buf, _cur.grffile->tramtype_list, "Tram type"); default: break; } /* Properties which are handled per item */ ChangeInfoResult ret = CIR_SUCCESS; for (int i = 0; i < numinfo; i++) { switch (prop) { case 0x08: { // Cost base factor int factor = buf->ReadByte(); uint price = gvid + i; if (price < PR_END) { _cur.grffile->price_base_multipliers[price] = std::min(factor - 8, MAX_PRICE_MODIFIER); } else { grfmsg(1, "GlobalVarChangeInfo: Price %d out of range, ignoring", price); } break; } case 0x0A: { // Currency display names uint curidx = GetNewgrfCurrencyIdConverted(gvid + i); StringID newone = GetGRFStringID(_cur.grffile->grfid, buf->ReadWord()); if ((newone != STR_UNDEFINED) && (curidx < CURRENCY_END)) { _currency_specs[curidx].name = newone; } break; } case 0x0B: { // Currency multipliers uint curidx = GetNewgrfCurrencyIdConverted(gvid + i); uint32 rate = buf->ReadDWord(); if (curidx < CURRENCY_END) { /* TTDPatch uses a multiple of 1000 for its conversion calculations, * which OTTD does not. For this reason, divide grf value by 1000, * to be compatible */ _currency_specs[curidx].rate = rate / 1000; } else { grfmsg(1, "GlobalVarChangeInfo: Currency multipliers %d out of range, ignoring", curidx); } break; } case 0x0C: { // Currency options uint curidx = GetNewgrfCurrencyIdConverted(gvid + i); uint16 options = buf->ReadWord(); if (curidx < CURRENCY_END) { _currency_specs[curidx].separator.clear(); _currency_specs[curidx].separator.push_back(GB(options, 0, 8)); /* By specifying only one bit, we prevent errors, * since newgrf specs said that only 0 and 1 can be set for symbol_pos */ _currency_specs[curidx].symbol_pos = GB(options, 8, 1); } else { grfmsg(1, "GlobalVarChangeInfo: Currency option %d out of range, ignoring", curidx); } break; } case 0x0D: { // Currency prefix symbol uint curidx = GetNewgrfCurrencyIdConverted(gvid + i); std::string prefix = ReadDWordAsString(buf); if (curidx < CURRENCY_END) { _currency_specs[curidx].prefix = prefix; } else { grfmsg(1, "GlobalVarChangeInfo: Currency symbol %d out of range, ignoring", curidx); } break; } case 0x0E: { // Currency suffix symbol uint curidx = GetNewgrfCurrencyIdConverted(gvid + i); std::string suffix = ReadDWordAsString(buf); if (curidx < CURRENCY_END) { _currency_specs[curidx].suffix = suffix; } else { grfmsg(1, "GlobalVarChangeInfo: Currency symbol %d out of range, ignoring", curidx); } break; } case 0x0F: { // Euro introduction dates uint curidx = GetNewgrfCurrencyIdConverted(gvid + i); Year year_euro = buf->ReadWord(); if (curidx < CURRENCY_END) { _currency_specs[curidx].to_euro = year_euro; } else { grfmsg(1, "GlobalVarChangeInfo: Euro intro date %d out of range, ignoring", curidx); } break; } case 0x10: // Snow line height table if (numinfo > 1 || IsSnowLineSet()) { grfmsg(1, "GlobalVarChangeInfo: The snowline can only be set once (%d)", numinfo); } else if (buf->Remaining() < SNOW_LINE_MONTHS * SNOW_LINE_DAYS) { grfmsg(1, "GlobalVarChangeInfo: Not enough entries set in the snowline table (" PRINTF_SIZE ")", buf->Remaining()); } else { byte table[SNOW_LINE_MONTHS][SNOW_LINE_DAYS]; for (uint i = 0; i < SNOW_LINE_MONTHS; i++) { for (uint j = 0; j < SNOW_LINE_DAYS; j++) { table[i][j] = buf->ReadByte(); if (_cur.grffile->grf_version >= 8) { if (table[i][j] != 0xFF) table[i][j] = table[i][j] * (1 + _settings_game.construction.map_height_limit) / 256; } else { if (table[i][j] >= 128) { /* no snow */ table[i][j] = 0xFF; } else { table[i][j] = table[i][j] * (1 + _settings_game.construction.map_height_limit) / 128; } } } } SetSnowLine(table); } break; case 0x11: // GRF match for engine allocation /* This is loaded during the reservation stage, so just skip it here. */ /* Each entry is 8 bytes. */ buf->Skip(8); break; case 0x13: // Gender translation table case 0x14: // Case translation table case 0x15: { // Plural form translation uint curidx = gvid + i; // The current index, i.e. language. const LanguageMetadata *lang = curidx < MAX_LANG ? GetLanguage(curidx) : nullptr; if (lang == nullptr) { grfmsg(1, "GlobalVarChangeInfo: Language %d is not known, ignoring", curidx); /* Skip over the data. */ if (prop == 0x15) { buf->ReadByte(); } else { while (buf->ReadByte() != 0) { buf->ReadString(); } } break; } if (_cur.grffile->language_map == nullptr) _cur.grffile->language_map = new LanguageMap[MAX_LANG]; if (prop == 0x15) { uint plural_form = buf->ReadByte(); if (plural_form >= LANGUAGE_MAX_PLURAL) { grfmsg(1, "GlobalVarChanceInfo: Plural form %d is out of range, ignoring", plural_form); } else { _cur.grffile->language_map[curidx].plural_form = plural_form; } break; } byte newgrf_id = buf->ReadByte(); // The NewGRF (custom) identifier. while (newgrf_id != 0) { const char *name = buf->ReadString(); // The name for the OpenTTD identifier. /* We'll just ignore the UTF8 identifier character. This is (fairly) * safe as OpenTTD's strings gender/cases are usually in ASCII which * is just a subset of UTF8, or they need the bigger UTF8 characters * such as Cyrillic. Thus we will simply assume they're all UTF8. */ WChar c; size_t len = Utf8Decode(&c, name); if (c == NFO_UTF8_IDENTIFIER) name += len; LanguageMap::Mapping map; map.newgrf_id = newgrf_id; if (prop == 0x13) { map.openttd_id = lang->GetGenderIndex(name); if (map.openttd_id >= MAX_NUM_GENDERS) { grfmsg(1, "GlobalVarChangeInfo: Gender name %s is not known, ignoring", name); } else { _cur.grffile->language_map[curidx].gender_map.push_back(map); } } else { map.openttd_id = lang->GetCaseIndex(name); if (map.openttd_id >= MAX_NUM_CASES) { grfmsg(1, "GlobalVarChangeInfo: Case name %s is not known, ignoring", name); } else { _cur.grffile->language_map[curidx].case_map.push_back(map); } } newgrf_id = buf->ReadByte(); } break; } case A0RPI_GLOBALVAR_EXTRA_STATION_NAMES: { if (MappedPropertyLengthMismatch(buf, 4, mapping_entry)) break; uint16 str = buf->ReadWord(); uint16 flags = buf->ReadWord(); if (_extra_station_names_used < MAX_EXTRA_STATION_NAMES) { ExtraStationNameInfo &info = _extra_station_names[_extra_station_names_used]; AddStringForMapping(str, &info.str); info.flags = flags; _extra_station_names_used++; } break; } case A0RPI_GLOBALVAR_EXTRA_STATION_NAMES_PROBABILITY: { if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; _extra_station_names_probability = buf->ReadByte(); break; } case A0RPI_GLOBALVAR_LIGHTHOUSE_GENERATE_AMOUNT: case A0RPI_GLOBALVAR_TRANSMITTER_GENERATE_AMOUNT: { if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; extern ObjectSpec _object_specs[NUM_OBJECTS]; ObjectType type = (prop == A0RPI_GLOBALVAR_LIGHTHOUSE_GENERATE_AMOUNT) ? OBJECT_LIGHTHOUSE : OBJECT_TRANSMITTER; _object_specs[type].generate_amount = buf->ReadByte(); break; } default: ret = HandleAction0PropertyDefault(buf, prop); break; } } return ret; } static ChangeInfoResult GlobalVarReserveInfo(uint gvid, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { /* Properties which are handled as a whole */ switch (prop) { case 0x09: // Cargo Translation Table; loading during both reservation and activation stage (in case it is selected depending on defined cargos) return LoadTranslationTable(gvid, numinfo, buf, _cur.grffile->cargo_list, "Cargo"); case 0x12: // Rail type translation table; loading during both reservation and activation stage (in case it is selected depending on defined railtypes) return LoadTranslationTable(gvid, numinfo, buf, _cur.grffile->railtype_list, "Rail type"); case 0x16: // Road type translation table; loading during both reservation and activation stage (in case it is selected depending on defined roadtypes) return LoadTranslationTable(gvid, numinfo, buf, _cur.grffile->roadtype_list, "Road type"); case 0x17: // Tram type translation table; loading during both reservation and activation stage (in case it is selected depending on defined tramtypes) return LoadTranslationTable(gvid, numinfo, buf, _cur.grffile->tramtype_list, "Tram type"); default: break; } /* Properties which are handled per item */ ChangeInfoResult ret = CIR_SUCCESS; for (int i = 0; i < numinfo; i++) { switch (prop) { case 0x08: // Cost base factor case 0x15: // Plural form translation buf->ReadByte(); break; case 0x0A: // Currency display names case 0x0C: // Currency options case 0x0F: // Euro introduction dates buf->ReadWord(); break; case 0x0B: // Currency multipliers case 0x0D: // Currency prefix symbol case 0x0E: // Currency suffix symbol buf->ReadDWord(); break; case 0x10: // Snow line height table buf->Skip(SNOW_LINE_MONTHS * SNOW_LINE_DAYS); break; case 0x11: { // GRF match for engine allocation uint32 s = buf->ReadDWord(); uint32 t = buf->ReadDWord(); SetNewGRFOverride(s, t); break; } case 0x13: // Gender translation table case 0x14: // Case translation table while (buf->ReadByte() != 0) { buf->ReadString(); } break; case A0RPI_GLOBALVAR_EXTRA_STATION_NAMES: case A0RPI_GLOBALVAR_EXTRA_STATION_NAMES_PROBABILITY: case A0RPI_GLOBALVAR_LIGHTHOUSE_GENERATE_AMOUNT: case A0RPI_GLOBALVAR_TRANSMITTER_GENERATE_AMOUNT: buf->Skip(buf->ReadExtendedByte()); break; default: ret = HandleAction0PropertyDefault(buf, prop); break; } } return ret; } /** * Define properties for cargoes * @param cid Local ID of the cargo. * @param numinfo Number of subsequent IDs to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult CargoChangeInfo(uint cid, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; if (cid + numinfo > NUM_CARGO) { grfmsg(2, "CargoChangeInfo: Cargo type %d out of range (max %d)", cid + numinfo, NUM_CARGO - 1); return CIR_INVALID_ID; } for (int i = 0; i < numinfo; i++) { CargoSpec *cs = CargoSpec::Get(cid + i); switch (prop) { case 0x08: // Bit number of cargo cs->bitnum = buf->ReadByte(); if (cs->IsValid()) { cs->grffile = _cur.grffile; SetBit(_cargo_mask, cid + i); } else { ClrBit(_cargo_mask, cid + i); } break; case 0x09: // String ID for cargo type name AddStringForMapping(buf->ReadWord(), &cs->name); break; case 0x0A: // String for 1 unit of cargo AddStringForMapping(buf->ReadWord(), &cs->name_single); break; case 0x0B: // String for singular quantity of cargo (e.g. 1 tonne of coal) case 0x1B: // String for cargo units /* String for units of cargo. This is different in OpenTTD * (e.g. tonnes) to TTDPatch (e.g. {COMMA} tonne of coal). * Property 1B is used to set OpenTTD's behaviour. */ AddStringForMapping(buf->ReadWord(), &cs->units_volume); break; case 0x0C: // String for plural quantity of cargo (e.g. 10 tonnes of coal) case 0x1C: // String for any amount of cargo /* Strings for an amount of cargo. This is different in OpenTTD * (e.g. {WEIGHT} of coal) to TTDPatch (e.g. {COMMA} tonnes of coal). * Property 1C is used to set OpenTTD's behaviour. */ AddStringForMapping(buf->ReadWord(), &cs->quantifier); break; case 0x0D: // String for two letter cargo abbreviation AddStringForMapping(buf->ReadWord(), &cs->abbrev); break; case 0x0E: // Sprite ID for cargo icon cs->sprite = buf->ReadWord(); break; case 0x0F: // Weight of one unit of cargo cs->weight = buf->ReadByte(); break; case 0x10: // Used for payment calculation cs->transit_days[0] = buf->ReadByte(); break; case 0x11: // Used for payment calculation cs->transit_days[1] = buf->ReadByte(); break; case 0x12: // Base cargo price cs->initial_payment = buf->ReadDWord(); break; case 0x13: // Colour for station rating bars cs->rating_colour = buf->ReadByte(); break; case 0x14: // Colour for cargo graph cs->legend_colour = buf->ReadByte(); break; case 0x15: // Freight status cs->is_freight = (buf->ReadByte() != 0); break; case 0x16: // Cargo classes cs->classes = buf->ReadWord(); break; case 0x17: // Cargo label cs->label = buf->ReadDWord(); cs->label = BSWAP32(cs->label); break; case 0x18: { // Town growth substitute type uint8 substitute_type = buf->ReadByte(); switch (substitute_type) { case 0x00: cs->town_effect = TE_PASSENGERS; break; case 0x02: cs->town_effect = TE_MAIL; break; case 0x05: cs->town_effect = TE_GOODS; break; case 0x09: cs->town_effect = TE_WATER; break; case 0x0B: cs->town_effect = TE_FOOD; break; default: grfmsg(1, "CargoChangeInfo: Unknown town growth substitute value %d, setting to none.", substitute_type); FALLTHROUGH; case 0xFF: cs->town_effect = TE_NONE; break; } break; } case 0x19: // Town growth coefficient buf->ReadWord(); break; case 0x1A: // Bitmask of callbacks to use cs->callback_mask = buf->ReadByte(); break; case 0x1D: // Vehicle capacity muliplier cs->multiplier = std::max(1u, buf->ReadWord()); break; default: ret = HandleAction0PropertyDefault(buf, prop); break; } } return ret; } /** * Define properties for sound effects * @param sid Local ID of the sound. * @param numinfo Number of subsequent IDs to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult SoundEffectChangeInfo(uint sid, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; if (_cur.grffile->sound_offset == 0) { grfmsg(1, "SoundEffectChangeInfo: No effects defined, skipping"); return CIR_INVALID_ID; } if (sid + numinfo - ORIGINAL_SAMPLE_COUNT > _cur.grffile->num_sounds) { grfmsg(1, "SoundEffectChangeInfo: Attempting to change undefined sound effect (%u), max (%u). Ignoring.", sid + numinfo, ORIGINAL_SAMPLE_COUNT + _cur.grffile->num_sounds); return CIR_INVALID_ID; } for (int i = 0; i < numinfo; i++) { SoundEntry *sound = GetSound(sid + i + _cur.grffile->sound_offset - ORIGINAL_SAMPLE_COUNT); switch (prop) { case 0x08: // Relative volume sound->volume = buf->ReadByte(); break; case 0x09: // Priority sound->priority = buf->ReadByte(); break; case 0x0A: { // Override old sound SoundID orig_sound = buf->ReadByte(); if (orig_sound >= ORIGINAL_SAMPLE_COUNT) { grfmsg(1, "SoundEffectChangeInfo: Original sound %d not defined (max %d)", orig_sound, ORIGINAL_SAMPLE_COUNT); } else { SoundEntry *old_sound = GetSound(orig_sound); /* Literally copy the data of the new sound over the original */ *old_sound = *sound; } break; } default: ret = HandleAction0PropertyDefault(buf, prop); break; } } return ret; } /** * Ignore an industry tile property * @param prop The property to ignore. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult IgnoreIndustryTileProperty(int prop, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; switch (prop) { case 0x09: case 0x0D: case 0x0E: case 0x10: case 0x11: case 0x12: buf->ReadByte(); break; case 0x0A: case 0x0B: case 0x0C: case 0x0F: buf->ReadWord(); break; case 0x13: buf->Skip(buf->ReadByte() * 2); break; default: ret = HandleAction0PropertyDefault(buf, prop); break; } return ret; } /** * Define properties for industry tiles * @param indtid Local ID of the industry tile. * @param numinfo Number of subsequent industry tile IDs to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult IndustrytilesChangeInfo(uint indtid, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; if (indtid + numinfo > NUM_INDUSTRYTILES_PER_GRF) { grfmsg(1, "IndustryTilesChangeInfo: Too many industry tiles loaded (%u), max (%u). Ignoring.", indtid + numinfo, NUM_INDUSTRYTILES_PER_GRF); return CIR_INVALID_ID; } /* Allocate industry tile specs if they haven't been allocated already. */ if (_cur.grffile->indtspec == nullptr) { _cur.grffile->indtspec = CallocT(NUM_INDUSTRYTILES_PER_GRF); } for (int i = 0; i < numinfo; i++) { IndustryTileSpec *tsp = _cur.grffile->indtspec[indtid + i]; if (prop != 0x08 && tsp == nullptr) { ChangeInfoResult cir = IgnoreIndustryTileProperty(prop, buf); if (cir > ret) ret = cir; continue; } switch (prop) { case 0x08: { // Substitute industry tile type IndustryTileSpec **tilespec = &_cur.grffile->indtspec[indtid + i]; byte subs_id = buf->ReadByte(); if (subs_id >= NEW_INDUSTRYTILEOFFSET) { /* The substitute id must be one of the original industry tile. */ grfmsg(2, "IndustryTilesChangeInfo: Attempt to use new industry tile %u as substitute industry tile for %u. Ignoring.", subs_id, indtid + i); continue; } /* Allocate space for this industry. */ if (*tilespec == nullptr) { *tilespec = CallocT(1); tsp = *tilespec; memcpy(tsp, &_industry_tile_specs[subs_id], sizeof(_industry_tile_specs[subs_id])); tsp->enabled = true; /* A copied tile should not have the animation infos copied too. * The anim_state should be left untouched, though * It is up to the author to animate them */ tsp->anim_production = INDUSTRYTILE_NOANIM; tsp->anim_next = INDUSTRYTILE_NOANIM; tsp->grf_prop.local_id = indtid + i; tsp->grf_prop.subst_id = subs_id; tsp->grf_prop.grffile = _cur.grffile; _industile_mngr.AddEntityID(indtid + i, _cur.grffile->grfid, subs_id); // pre-reserve the tile slot } break; } case 0x09: { // Industry tile override byte ovrid = buf->ReadByte(); /* The industry being overridden must be an original industry. */ if (ovrid >= NEW_INDUSTRYTILEOFFSET) { grfmsg(2, "IndustryTilesChangeInfo: Attempt to override new industry tile %u with industry tile id %u. Ignoring.", ovrid, indtid + i); continue; } _industile_mngr.Add(indtid + i, _cur.grffile->grfid, ovrid); break; } case 0x0A: // Tile acceptance case 0x0B: case 0x0C: { uint16 acctp = buf->ReadWord(); tsp->accepts_cargo[prop - 0x0A] = GetCargoTranslation(GB(acctp, 0, 8), _cur.grffile); tsp->acceptance[prop - 0x0A] = Clamp(GB(acctp, 8, 8), 0, 16); break; } case 0x0D: // Land shape flags tsp->slopes_refused = (Slope)buf->ReadByte(); break; case 0x0E: // Callback mask tsp->callback_mask = buf->ReadByte(); break; case 0x0F: // Animation information tsp->animation.frames = buf->ReadByte(); tsp->animation.status = buf->ReadByte(); break; case 0x10: // Animation speed tsp->animation.speed = buf->ReadByte(); break; case 0x11: // Triggers for callback 25 tsp->animation.triggers = buf->ReadByte(); break; case 0x12: // Special flags tsp->special_flags = (IndustryTileSpecialFlags)buf->ReadByte(); break; case 0x13: { // variable length cargo acceptance byte num_cargoes = buf->ReadByte(); if (num_cargoes > lengthof(tsp->acceptance)) { GRFError *error = DisableGrf(STR_NEWGRF_ERROR_LIST_PROPERTY_TOO_LONG); error->param_value[1] = prop; return CIR_DISABLED; } for (uint i = 0; i < lengthof(tsp->acceptance); i++) { if (i < num_cargoes) { tsp->accepts_cargo[i] = GetCargoTranslation(buf->ReadByte(), _cur.grffile); /* Tile acceptance can be negative to counteract the INDTILE_SPECIAL_ACCEPTS_ALL_CARGO flag */ tsp->acceptance[i] = (int8)buf->ReadByte(); } else { tsp->accepts_cargo[i] = CT_INVALID; tsp->acceptance[i] = 0; } } break; } default: ret = HandleAction0PropertyDefault(buf, prop); break; } } return ret; } /** * Ignore an industry property * @param prop The property to ignore. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult IgnoreIndustryProperty(int prop, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; switch (prop) { case 0x09: case 0x0B: case 0x0F: case 0x12: case 0x13: case 0x14: case 0x17: case 0x18: case 0x19: case 0x21: case 0x22: buf->ReadByte(); break; case 0x0C: case 0x0D: case 0x0E: case 0x10: case 0x1B: case 0x1F: case 0x24: buf->ReadWord(); break; case 0x11: case 0x1A: case 0x1C: case 0x1D: case 0x1E: case 0x20: case 0x23: buf->ReadDWord(); break; case 0x0A: { byte num_table = buf->ReadByte(); for (byte j = 0; j < num_table; j++) { for (uint k = 0;; k++) { byte x = buf->ReadByte(); if (x == 0xFE && k == 0) { buf->ReadByte(); buf->ReadByte(); break; } byte y = buf->ReadByte(); if (x == 0 && y == 0x80) break; byte gfx = buf->ReadByte(); if (gfx == 0xFE) buf->ReadWord(); } } break; } case 0x16: for (byte j = 0; j < 3; j++) buf->ReadByte(); break; case 0x15: case 0x25: case 0x26: case 0x27: buf->Skip(buf->ReadByte()); break; case 0x28: { int num_inputs = buf->ReadByte(); int num_outputs = buf->ReadByte(); buf->Skip(num_inputs * num_outputs * 2); break; } default: ret = HandleAction0PropertyDefault(buf, prop); break; } return ret; } /** * Validate the industry layout; e.g. to prevent duplicate tiles. * @param layout The layout to check. * @return True if the layout is deemed valid. */ static bool ValidateIndustryLayout(const IndustryTileLayout &layout) { const size_t size = layout.size(); if (size == 0) return false; for (size_t i = 0; i < size - 1; i++) { for (size_t j = i + 1; j < size; j++) { if (layout[i].ti.x == layout[j].ti.x && layout[i].ti.y == layout[j].ti.y) { return false; } } } bool have_regular_tile = false; for (size_t i = 0; i < size; i++) { if (layout[i].gfx != GFX_WATERTILE_SPECIALCHECK) { have_regular_tile = true; break; } } return have_regular_tile; } /** * Define properties for industries * @param indid Local ID of the industry. * @param numinfo Number of subsequent industry IDs to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult IndustriesChangeInfo(uint indid, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; if (indid + numinfo > NUM_INDUSTRYTYPES_PER_GRF) { grfmsg(1, "IndustriesChangeInfo: Too many industries loaded (%u), max (%u). Ignoring.", indid + numinfo, NUM_INDUSTRYTYPES_PER_GRF); return CIR_INVALID_ID; } /* Allocate industry specs if they haven't been allocated already. */ if (_cur.grffile->industryspec == nullptr) { _cur.grffile->industryspec = CallocT(NUM_INDUSTRYTYPES_PER_GRF); } for (int i = 0; i < numinfo; i++) { IndustrySpec *indsp = _cur.grffile->industryspec[indid + i]; if (prop != 0x08 && indsp == nullptr) { ChangeInfoResult cir = IgnoreIndustryProperty(prop, buf); if (cir > ret) ret = cir; continue; } switch (prop) { case 0x08: { // Substitute industry type IndustrySpec **indspec = &_cur.grffile->industryspec[indid + i]; byte subs_id = buf->ReadByte(); if (subs_id == 0xFF) { /* Instead of defining a new industry, a substitute industry id * of 0xFF disables the old industry with the current id. */ _industry_specs[indid + i].enabled = false; continue; } else if (subs_id >= NEW_INDUSTRYOFFSET) { /* The substitute id must be one of the original industry. */ grfmsg(2, "_industry_specs: Attempt to use new industry %u as substitute industry for %u. Ignoring.", subs_id, indid + i); continue; } /* Allocate space for this industry. * Only need to do it once. If ever it is called again, it should not * do anything */ if (*indspec == nullptr) { *indspec = new IndustrySpec; indsp = *indspec; *indsp = _origin_industry_specs[subs_id]; indsp->enabled = true; indsp->grf_prop.local_id = indid + i; indsp->grf_prop.subst_id = subs_id; indsp->grf_prop.grffile = _cur.grffile; /* If the grf industry needs to check its surrounding upon creation, it should * rely on callbacks, not on the original placement functions */ indsp->check_proc = CHECK_NOTHING; } break; } case 0x09: { // Industry type override byte ovrid = buf->ReadByte(); /* The industry being overridden must be an original industry. */ if (ovrid >= NEW_INDUSTRYOFFSET) { grfmsg(2, "IndustriesChangeInfo: Attempt to override new industry %u with industry id %u. Ignoring.", ovrid, indid + i); continue; } indsp->grf_prop.override = ovrid; _industry_mngr.Add(indid + i, _cur.grffile->grfid, ovrid); break; } case 0x0A: { // Set industry layout(s) byte new_num_layouts = buf->ReadByte(); uint32 definition_size = buf->ReadDWord(); uint32 bytes_read = 0; std::vector new_layouts; IndustryTileLayout layout; for (byte j = 0; j < new_num_layouts; j++) { layout.clear(); for (uint k = 0;; k++) { if (bytes_read >= definition_size) { grfmsg(3, "IndustriesChangeInfo: Incorrect size for industry tile layout definition for industry %u.", indid); /* Avoid warning twice */ definition_size = UINT32_MAX; } layout.push_back(IndustryTileLayoutTile{}); IndustryTileLayoutTile &it = layout.back(); it.ti.x = buf->ReadByte(); // Offsets from northermost tile ++bytes_read; if (it.ti.x == 0xFE && k == 0) { /* This means we have to borrow the layout from an old industry */ IndustryType type = buf->ReadByte(); byte laynbr = buf->ReadByte(); bytes_read += 2; if (type >= lengthof(_origin_industry_specs)) { grfmsg(1, "IndustriesChangeInfo: Invalid original industry number for layout import, industry %u", indid); DisableGrf(STR_NEWGRF_ERROR_INVALID_ID); return CIR_DISABLED; } if (laynbr >= _origin_industry_specs[type].layouts.size()) { grfmsg(1, "IndustriesChangeInfo: Invalid original industry layout index for layout import, industry %u", indid); DisableGrf(STR_NEWGRF_ERROR_INVALID_ID); return CIR_DISABLED; } layout = _origin_industry_specs[type].layouts[laynbr]; break; } it.ti.y = buf->ReadByte(); // Or table definition finalisation ++bytes_read; if (it.ti.x == 0 && it.ti.y == 0x80) { /* Terminator, remove and finish up */ layout.pop_back(); break; } it.gfx = buf->ReadByte(); ++bytes_read; if (it.gfx == 0xFE) { /* Use a new tile from this GRF */ int local_tile_id = buf->ReadWord(); bytes_read += 2; /* Read the ID from the _industile_mngr. */ int tempid = _industile_mngr.GetID(local_tile_id, _cur.grffile->grfid); if (tempid == INVALID_INDUSTRYTILE) { grfmsg(2, "IndustriesChangeInfo: Attempt to use industry tile %u with industry id %u, not yet defined. Ignoring.", local_tile_id, indid); } else { /* Declared as been valid, can be used */ it.gfx = tempid; } } else if (it.gfx == GFX_WATERTILE_SPECIALCHECK) { it.ti.x = (int8)GB(it.ti.x, 0, 8); it.ti.y = (int8)GB(it.ti.y, 0, 8); /* When there were only 256x256 maps, TileIndex was a uint16 and * it.ti was just a TileIndexDiff that was added to it. * As such negative "x" values were shifted into the "y" position. * x = -1, y = 1 -> x = 255, y = 0 * Since GRF version 8 the position is interpreted as pair of independent int8. * For GRF version < 8 we need to emulate the old shifting behaviour. */ if (_cur.grffile->grf_version < 8 && it.ti.x < 0) it.ti.y += 1; } } if (!ValidateIndustryLayout(layout)) { /* The industry layout was not valid, so skip this one. */ grfmsg(1, "IndustriesChangeInfo: Invalid industry layout for industry id %u. Ignoring", indid); new_num_layouts--; j--; } else { new_layouts.push_back(layout); } } /* Install final layout construction in the industry spec */ indsp->layouts = new_layouts; break; } case 0x0B: // Industry production flags indsp->life_type = (IndustryLifeType)buf->ReadByte(); break; case 0x0C: // Industry closure message AddStringForMapping(buf->ReadWord(), &indsp->closure_text); break; case 0x0D: // Production increase message AddStringForMapping(buf->ReadWord(), &indsp->production_up_text); break; case 0x0E: // Production decrease message AddStringForMapping(buf->ReadWord(), &indsp->production_down_text); break; case 0x0F: // Fund cost multiplier indsp->cost_multiplier = buf->ReadByte(); break; case 0x10: // Production cargo types for (byte j = 0; j < 2; j++) { indsp->produced_cargo[j] = GetCargoTranslation(buf->ReadByte(), _cur.grffile); } break; case 0x11: // Acceptance cargo types for (byte j = 0; j < 3; j++) { indsp->accepts_cargo[j] = GetCargoTranslation(buf->ReadByte(), _cur.grffile); } buf->ReadByte(); // Unnused, eat it up break; case 0x12: // Production multipliers case 0x13: indsp->production_rate[prop - 0x12] = buf->ReadByte(); break; case 0x14: // Minimal amount of cargo distributed indsp->minimal_cargo = buf->ReadByte(); break; case 0x15: { // Random sound effects indsp->number_of_sounds = buf->ReadByte(); uint8 *sounds = MallocT(indsp->number_of_sounds); try { for (uint8 j = 0; j < indsp->number_of_sounds; j++) { sounds[j] = buf->ReadByte(); } } catch (...) { free(sounds); throw; } if (HasBit(indsp->cleanup_flag, CLEAN_RANDOMSOUNDS)) { free(indsp->random_sounds); } indsp->random_sounds = sounds; SetBit(indsp->cleanup_flag, CLEAN_RANDOMSOUNDS); break; } case 0x16: // Conflicting industry types for (byte j = 0; j < 3; j++) indsp->conflicting[j] = buf->ReadByte(); break; case 0x17: // Probability in random game indsp->appear_creation[_settings_game.game_creation.landscape] = buf->ReadByte(); break; case 0x18: // Probability during gameplay indsp->appear_ingame[_settings_game.game_creation.landscape] = buf->ReadByte(); break; case 0x19: // Map colour indsp->map_colour = buf->ReadByte(); break; case 0x1A: // Special industry flags to define special behavior indsp->behaviour = (IndustryBehaviour)buf->ReadDWord(); break; case 0x1B: // New industry text ID AddStringForMapping(buf->ReadWord(), &indsp->new_industry_text); break; case 0x1C: // Input cargo multipliers for the three input cargo types case 0x1D: case 0x1E: { uint32 multiples = buf->ReadDWord(); indsp->input_cargo_multiplier[prop - 0x1C][0] = GB(multiples, 0, 16); indsp->input_cargo_multiplier[prop - 0x1C][1] = GB(multiples, 16, 16); break; } case 0x1F: // Industry name AddStringForMapping(buf->ReadWord(), &indsp->name); break; case 0x20: // Prospecting success chance indsp->prospecting_chance = buf->ReadDWord(); break; case 0x21: // Callback mask case 0x22: { // Callback additional mask byte aflag = buf->ReadByte(); SB(indsp->callback_mask, (prop - 0x21) * 8, 8, aflag); break; } case 0x23: // removal cost multiplier indsp->removal_cost_multiplier = buf->ReadDWord(); break; case 0x24: { // name for nearby station uint16 str = buf->ReadWord(); if (str == 0) { indsp->station_name = STR_NULL; } else { AddStringForMapping(str, &indsp->station_name); } break; } case 0x25: { // variable length produced cargoes byte num_cargoes = buf->ReadByte(); if (num_cargoes > lengthof(indsp->produced_cargo)) { GRFError *error = DisableGrf(STR_NEWGRF_ERROR_LIST_PROPERTY_TOO_LONG); error->param_value[1] = prop; return CIR_DISABLED; } for (uint i = 0; i < lengthof(indsp->produced_cargo); i++) { if (i < num_cargoes) { CargoID cargo = GetCargoTranslation(buf->ReadByte(), _cur.grffile); indsp->produced_cargo[i] = cargo; } else { indsp->produced_cargo[i] = CT_INVALID; } } break; } case 0x26: { // variable length accepted cargoes byte num_cargoes = buf->ReadByte(); if (num_cargoes > lengthof(indsp->accepts_cargo)) { GRFError *error = DisableGrf(STR_NEWGRF_ERROR_LIST_PROPERTY_TOO_LONG); error->param_value[1] = prop; return CIR_DISABLED; } for (uint i = 0; i < lengthof(indsp->accepts_cargo); i++) { if (i < num_cargoes) { CargoID cargo = GetCargoTranslation(buf->ReadByte(), _cur.grffile); indsp->accepts_cargo[i] = cargo; } else { indsp->accepts_cargo[i] = CT_INVALID; } } break; } case 0x27: { // variable length production rates byte num_cargoes = buf->ReadByte(); if (num_cargoes > lengthof(indsp->production_rate)) { GRFError *error = DisableGrf(STR_NEWGRF_ERROR_LIST_PROPERTY_TOO_LONG); error->param_value[1] = prop; return CIR_DISABLED; } for (uint i = 0; i < lengthof(indsp->production_rate); i++) { if (i < num_cargoes) { indsp->production_rate[i] = buf->ReadByte(); } else { indsp->production_rate[i] = 0; } } break; } case 0x28: { // variable size input/output production multiplier table byte num_inputs = buf->ReadByte(); byte num_outputs = buf->ReadByte(); if (num_inputs > lengthof(indsp->accepts_cargo) || num_outputs > lengthof(indsp->produced_cargo)) { GRFError *error = DisableGrf(STR_NEWGRF_ERROR_LIST_PROPERTY_TOO_LONG); error->param_value[1] = prop; return CIR_DISABLED; } for (uint i = 0; i < lengthof(indsp->accepts_cargo); i++) { for (uint j = 0; j < lengthof(indsp->produced_cargo); j++) { uint16 mult = 0; if (i < num_inputs && j < num_outputs) mult = buf->ReadWord(); indsp->input_cargo_multiplier[i][j] = mult; } } break; } default: ret = HandleAction0PropertyDefault(buf, prop); break; } } return ret; } /** * Create a copy of the tile table so it can be freed later * without problems. * @param as The AirportSpec to copy the arrays of. */ static void DuplicateTileTable(AirportSpec *as) { AirportTileTable **table_list = MallocT(as->num_table); for (int i = 0; i < as->num_table; i++) { uint num_tiles = 1; const AirportTileTable *it = as->table[0]; do { num_tiles++; } while ((++it)->ti.x != -0x80); table_list[i] = MallocT(num_tiles); MemCpyT(table_list[i], as->table[i], num_tiles); } as->table = table_list; HangarTileTable *depot_table = nullptr; if (as->nof_depots > 0) { depot_table = MallocT(as->nof_depots); MemCpyT(depot_table, as->depot_table, as->nof_depots); } as->depot_table = depot_table; Direction *rotation = MallocT(as->num_table); MemCpyT(rotation, as->rotation, as->num_table); as->rotation = rotation; } /** * Define properties for airports * @param airport Local ID of the airport. * @param numinfo Number of subsequent airport IDs to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult AirportChangeInfo(uint airport, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; if (airport + numinfo > NUM_AIRPORTS_PER_GRF) { grfmsg(1, "AirportChangeInfo: Too many airports, trying id (%u), max (%u). Ignoring.", airport + numinfo, NUM_AIRPORTS_PER_GRF); return CIR_INVALID_ID; } /* Allocate industry specs if they haven't been allocated already. */ if (_cur.grffile->airportspec == nullptr) { _cur.grffile->airportspec = CallocT(NUM_AIRPORTS_PER_GRF); } for (int i = 0; i < numinfo; i++) { AirportSpec *as = _cur.grffile->airportspec[airport + i]; if (as == nullptr && prop != 0x08 && prop != 0x09) { grfmsg(2, "AirportChangeInfo: Attempt to modify undefined airport %u, ignoring", airport + i); return CIR_INVALID_ID; } switch (prop) { case 0x08: { // Modify original airport byte subs_id = buf->ReadByte(); if (subs_id == 0xFF) { /* Instead of defining a new airport, an airport id * of 0xFF disables the old airport with the current id. */ AirportSpec::GetWithoutOverride(airport + i)->enabled = false; continue; } else if (subs_id >= NEW_AIRPORT_OFFSET) { /* The substitute id must be one of the original airports. */ grfmsg(2, "AirportChangeInfo: Attempt to use new airport %u as substitute airport for %u. Ignoring.", subs_id, airport + i); continue; } AirportSpec **spec = &_cur.grffile->airportspec[airport + i]; /* Allocate space for this airport. * Only need to do it once. If ever it is called again, it should not * do anything */ if (*spec == nullptr) { *spec = MallocT(1); as = *spec; memcpy(as, AirportSpec::GetWithoutOverride(subs_id), sizeof(*as)); as->enabled = true; as->grf_prop.local_id = airport + i; as->grf_prop.subst_id = subs_id; as->grf_prop.grffile = _cur.grffile; /* override the default airport */ _airport_mngr.Add(airport + i, _cur.grffile->grfid, subs_id); /* Create a copy of the original tiletable so it can be freed later. */ DuplicateTileTable(as); } break; } case 0x0A: { // Set airport layout byte old_num_table = as->num_table; as->num_table = buf->ReadByte(); // Number of layouts free(as->rotation); as->rotation = MallocT(as->num_table); uint32 defsize = buf->ReadDWord(); // Total size of the definition AirportTileTable **tile_table = CallocT(as->num_table); // Table with tiles to compose the airport AirportTileTable *att = CallocT(defsize); // Temporary array to read the tile layouts from the GRF int size; const AirportTileTable *copy_from; try { for (byte j = 0; j < as->num_table; j++) { const_cast(as->rotation[j]) = (Direction)buf->ReadByte(); for (int k = 0;; k++) { att[k].ti.x = buf->ReadByte(); // Offsets from northermost tile att[k].ti.y = buf->ReadByte(); if (att[k].ti.x == 0 && att[k].ti.y == 0x80) { /* Not the same terminator. The one we are using is rather * x = -80, y = 0 . So, adjust it. */ att[k].ti.x = -0x80; att[k].ti.y = 0; att[k].gfx = 0; size = k + 1; copy_from = att; break; } att[k].gfx = buf->ReadByte(); if (att[k].gfx == 0xFE) { /* Use a new tile from this GRF */ int local_tile_id = buf->ReadWord(); /* Read the ID from the _airporttile_mngr. */ uint16 tempid = _airporttile_mngr.GetID(local_tile_id, _cur.grffile->grfid); if (tempid == INVALID_AIRPORTTILE) { grfmsg(2, "AirportChangeInfo: Attempt to use airport tile %u with airport id %u, not yet defined. Ignoring.", local_tile_id, airport + i); } else { /* Declared as been valid, can be used */ att[k].gfx = tempid; } } else if (att[k].gfx == 0xFF) { att[k].ti.x = (int8)GB(att[k].ti.x, 0, 8); att[k].ti.y = (int8)GB(att[k].ti.y, 0, 8); } if (as->rotation[j] == DIR_E || as->rotation[j] == DIR_W) { as->size_x = std::max(as->size_x, att[k].ti.y + 1); as->size_y = std::max(as->size_y, att[k].ti.x + 1); } else { as->size_x = std::max(as->size_x, att[k].ti.x + 1); as->size_y = std::max(as->size_y, att[k].ti.y + 1); } } tile_table[j] = CallocT(size); memcpy(tile_table[j], copy_from, sizeof(*copy_from) * size); } /* Free old layouts in the airport spec */ for (int j = 0; j < old_num_table; j++) { /* remove the individual layouts */ free(as->table[j]); } free(as->table); /* Install final layout construction in the airport spec */ as->table = tile_table; free(att); } catch (...) { for (int i = 0; i < as->num_table; i++) { free(tile_table[i]); } free(tile_table); free(att); throw; } break; } case 0x0C: as->min_year = buf->ReadWord(); as->max_year = buf->ReadWord(); if (as->max_year == 0xFFFF) as->max_year = MAX_YEAR; break; case 0x0D: as->ttd_airport_type = (TTDPAirportType)buf->ReadByte(); break; case 0x0E: as->catchment = Clamp(buf->ReadByte(), 1, MAX_CATCHMENT); break; case 0x0F: as->noise_level = buf->ReadByte(); break; case 0x10: AddStringForMapping(buf->ReadWord(), &as->name); break; case 0x11: // Maintenance cost factor as->maintenance_cost = buf->ReadWord(); break; default: ret = HandleAction0PropertyDefault(buf, prop); break; } } return ret; } /** * Define properties for signals * @param id Local ID (unused). * @param numinfo Number of subsequent IDs to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult SignalsChangeInfo(uint id, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { /* Properties which are handled per item */ ChangeInfoResult ret = CIR_SUCCESS; for (int i = 0; i < numinfo; i++) { switch (prop) { case A0RPI_SIGNALS_ENABLE_PROGRAMMABLE_SIGNALS: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; SB(_cur.grffile->new_signal_ctrl_flags, NSCF_PROGSIG, 1, (buf->ReadByte() != 0 ? 1 : 0)); break; case A0RPI_SIGNALS_ENABLE_NO_ENTRY_SIGNALS: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; SB(_cur.grffile->new_signal_ctrl_flags, NSCF_NOENTRYSIG, 1, (buf->ReadByte() != 0 ? 1 : 0)); break; case A0RPI_SIGNALS_ENABLE_RESTRICTED_SIGNALS: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; SB(_cur.grffile->new_signal_ctrl_flags, NSCF_RESTRICTEDSIG, 1, (buf->ReadByte() != 0 ? 1 : 0)); break; case A0RPI_SIGNALS_ENABLE_SIGNAL_RECOLOUR: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; SB(_cur.grffile->new_signal_ctrl_flags, NSCF_RECOLOUR_ENABLED, 1, (buf->ReadByte() != 0 ? 1 : 0)); break; case A0RPI_SIGNALS_EXTRA_ASPECTS: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; _cur.grffile->new_signal_extra_aspects = std::min(buf->ReadByte(), NEW_SIGNALS_MAX_EXTRA_ASPECT); break; case A0RPI_SIGNALS_NO_DEFAULT_STYLE: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; SB(_cur.grffile->new_signal_style_mask, 0, 1, (buf->ReadByte() != 0 ? 0 : 1)); break; case A0RPI_SIGNALS_DEFINE_STYLE: { if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; uint8 local_id = buf->ReadByte(); if (_num_new_signal_styles < MAX_NEW_SIGNAL_STYLES) { NewSignalStyle &style = _new_signal_styles[_num_new_signal_styles]; style = {}; _num_new_signal_styles++; SetBit(_cur.grffile->new_signal_style_mask, _num_new_signal_styles); style.grf_local_id = local_id; style.grffile = _cur.grffile; _cur.grffile->current_new_signal_style = &style; } else { _cur.grffile->current_new_signal_style = nullptr; } break; } case A0RPI_SIGNALS_STYLE_NAME: { if (MappedPropertyLengthMismatch(buf, 2, mapping_entry)) break; uint16 str = buf->ReadWord(); if (_cur.grffile->current_new_signal_style != nullptr) { AddStringForMapping(str, &(_cur.grffile->current_new_signal_style->name)); } break; } case A0RPI_SIGNALS_STYLE_NO_ASPECT_INCREASE: { if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; uint8 value = buf->ReadByte(); if (_cur.grffile->current_new_signal_style != nullptr) { SB(_cur.grffile->current_new_signal_style->style_flags, NSSF_NO_ASPECT_INC, 1, (value != 0 ? 1 : 0)); } break; } case A0RPI_SIGNALS_STYLE_ALWAYS_RESERVE_THROUGH: { if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; uint8 value = buf->ReadByte(); if (_cur.grffile->current_new_signal_style != nullptr) { SB(_cur.grffile->current_new_signal_style->style_flags, NSSF_ALWAYS_RESERVE_THROUGH, 1, (value != 0 ? 1 : 0)); } break; } case A0RPI_SIGNALS_STYLE_LOOKAHEAD_EXTRA_ASPECTS: { if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; uint8 value = std::min(buf->ReadByte(), NEW_SIGNALS_MAX_EXTRA_ASPECT); if (_cur.grffile->current_new_signal_style != nullptr) { SetBit(_cur.grffile->current_new_signal_style->style_flags, NSSF_LOOKAHEAD_ASPECTS_SET); _cur.grffile->current_new_signal_style->lookahead_extra_aspects = value; } break; } case A0RPI_SIGNALS_STYLE_LOOKAHEAD_SINGLE_SIGNAL_ONLY: { if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; uint8 value = buf->ReadByte(); if (_cur.grffile->current_new_signal_style != nullptr) { SB(_cur.grffile->current_new_signal_style->style_flags, NSSF_LOOKAHEAD_SINGLE_SIGNAL, 1, (value != 0 ? 1 : 0)); } break; } case A0RPI_SIGNALS_STYLE_SEMAPHORE_ENABLED: { if (MappedPropertyLengthMismatch(buf, 4, mapping_entry)) break; uint32 mask = buf->ReadDWord(); if (_cur.grffile->current_new_signal_style != nullptr) { _cur.grffile->current_new_signal_style->semaphore_mask = (uint8)mask; } break; } case A0RPI_SIGNALS_STYLE_ELECTRIC_ENABLED: { if (MappedPropertyLengthMismatch(buf, 4, mapping_entry)) break; uint32 mask = buf->ReadDWord(); if (_cur.grffile->current_new_signal_style != nullptr) { _cur.grffile->current_new_signal_style->electric_mask = (uint8)mask; } break; } case A0RPI_SIGNALS_STYLE_OPPOSITE_SIDE: { if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; uint8 value = buf->ReadByte(); if (_cur.grffile->current_new_signal_style != nullptr) { SB(_cur.grffile->current_new_signal_style->style_flags, NSSF_OPPOSITE_SIDE, 1, (value != 0 ? 1 : 0)); } break; } case A0RPI_SIGNALS_STYLE_COMBINED_NORMAL_SHUNT: { if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; uint8 value = buf->ReadByte(); if (_cur.grffile->current_new_signal_style != nullptr) { SB(_cur.grffile->current_new_signal_style->style_flags, NSSF_COMBINED_NORMAL_SHUNT, 1, (value != 0 ? 1 : 0)); } break; } case A0RPI_SIGNALS_STYLE_REALISTIC_BRAKING_ONLY: { if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; uint8 value = buf->ReadByte(); if (_cur.grffile->current_new_signal_style != nullptr) { SB(_cur.grffile->current_new_signal_style->style_flags, NSSF_REALISTIC_BRAKING_ONLY, 1, (value != 0 ? 1 : 0)); } break; } default: ret = HandleAction0PropertyDefault(buf, prop); break; } } return ret; } /** * Ignore properties for objects * @param prop The property to ignore. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult IgnoreObjectProperty(uint prop, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; switch (prop) { case 0x0B: case 0x0C: case 0x0D: case 0x12: case 0x14: case 0x16: case 0x17: buf->ReadByte(); break; case 0x09: case 0x0A: case 0x10: case 0x11: case 0x13: case 0x15: buf->ReadWord(); break; case 0x08: case 0x0E: case 0x0F: buf->ReadDWord(); break; default: ret = HandleAction0PropertyDefault(buf, prop); break; } return ret; } /** * Define properties for objects * @param id Local ID of the object. * @param numinfo Number of subsequent objectIDs to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult ObjectChangeInfo(uint id, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; if (id + numinfo > NUM_OBJECTS_PER_GRF) { grfmsg(1, "ObjectChangeInfo: Too many objects loaded (%u), max (%u). Ignoring.", id + numinfo, NUM_OBJECTS_PER_GRF); return CIR_INVALID_ID; } /* Allocate object specs if they haven't been allocated already. */ if (_cur.grffile->objectspec == nullptr) { _cur.grffile->objectspec = CallocT(NUM_OBJECTS_PER_GRF); } for (int i = 0; i < numinfo; i++) { ObjectSpec *spec = _cur.grffile->objectspec[id + i]; if (prop != 0x08 && spec == nullptr) { /* If the object property 08 is not yet set, ignore this property */ ChangeInfoResult cir = IgnoreObjectProperty(prop, buf); if (cir > ret) ret = cir; continue; } switch (prop) { case 0x08: { // Class ID ObjectSpec **ospec = &_cur.grffile->objectspec[id + i]; /* Allocate space for this object. */ if (*ospec == nullptr) { *ospec = CallocT(1); (*ospec)->views = 1; // Default for NewGRFs that don't set it. (*ospec)->size = 0x11; // Default for NewGRFs that manage to not set it (1x1) } /* Swap classid because we read it in BE. */ uint32 classid = buf->ReadDWord(); (*ospec)->cls_id = ObjectClass::Allocate(BSWAP32(classid)); (*ospec)->enabled = true; break; } case 0x09: { // Class name ObjectClass *objclass = ObjectClass::Get(spec->cls_id); AddStringForMapping(buf->ReadWord(), &objclass->name); break; } case 0x0A: // Object name AddStringForMapping(buf->ReadWord(), &spec->name); break; case 0x0B: // Climate mask spec->climate = buf->ReadByte(); break; case 0x0C: // Size spec->size = buf->ReadByte(); if (GB(spec->size, 0, 4) == 0 || GB(spec->size, 4, 4) == 0) { grfmsg(0, "ObjectChangeInfo: Invalid object size requested (0x%x) for object id %u. Ignoring.", spec->size, id + i); spec->size = 0x11; // 1x1 } break; case 0x0D: // Build cost multipler spec->build_cost_multiplier = buf->ReadByte(); spec->clear_cost_multiplier = spec->build_cost_multiplier; break; case 0x0E: // Introduction date spec->introduction_date = buf->ReadDWord(); break; case 0x0F: // End of life spec->end_of_life_date = buf->ReadDWord(); break; case 0x10: // Flags spec->flags = (ObjectFlags)buf->ReadWord(); _loaded_newgrf_features.has_2CC |= (spec->flags & OBJECT_FLAG_2CC_COLOUR) != 0; break; case 0x11: // Animation info spec->animation.frames = buf->ReadByte(); spec->animation.status = buf->ReadByte(); break; case 0x12: // Animation speed spec->animation.speed = buf->ReadByte(); break; case 0x13: // Animation triggers spec->animation.triggers = buf->ReadWord(); break; case 0x14: // Removal cost multiplier spec->clear_cost_multiplier = buf->ReadByte(); break; case 0x15: // Callback mask spec->callback_mask = buf->ReadWord(); break; case 0x16: // Building height spec->height = buf->ReadByte(); break; case 0x17: // Views spec->views = buf->ReadByte(); if (spec->views != 1 && spec->views != 2 && spec->views != 4) { grfmsg(2, "ObjectChangeInfo: Invalid number of views (%u) for object id %u. Ignoring.", spec->views, id + i); spec->views = 1; } break; case 0x18: // Amount placed on 256^2 map on map creation spec->generate_amount = buf->ReadByte(); break; case A0RPI_OBJECT_USE_LAND_GROUND: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; spec->ctrl_flags &= ~OBJECT_CTRL_FLAG_USE_LAND_GROUND; if (buf->ReadByte() != 0) spec->ctrl_flags |= OBJECT_CTRL_FLAG_USE_LAND_GROUND; break; case A0RPI_OBJECT_EDGE_FOUNDATION_MODE: if (MappedPropertyLengthMismatch(buf, 4, mapping_entry)) break; spec->ctrl_flags |= OBJECT_CTRL_FLAG_EDGE_FOUNDATION; for (int i = 0; i < 4; i++) { spec->edge_foundation[i] = buf->ReadByte(); } break; case A0RPI_OBJECT_FLOOD_RESISTANT: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; spec->ctrl_flags &= ~OBJECT_CTRL_FLAG_FLOOD_RESISTANT; if (buf->ReadByte() != 0) spec->ctrl_flags |= OBJECT_CTRL_FLAG_FLOOD_RESISTANT; break; case A0RPI_OBJECT_VIEWPORT_MAP_TYPE: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; spec->vport_map_type = (ObjectViewportMapType)buf->ReadByte(); spec->ctrl_flags |= OBJECT_CTRL_FLAG_VPORT_MAP_TYPE; break; case A0RPI_OBJECT_VIEWPORT_MAP_SUBTYPE: if (MappedPropertyLengthMismatch(buf, 2, mapping_entry)) break; spec->vport_map_subtype = buf->ReadWord(); break; default: ret = HandleAction0PropertyDefault(buf, prop); break; } } return ret; } /** * Define properties for railtypes * @param id ID of the railtype. * @param numinfo Number of subsequent IDs to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult RailTypeChangeInfo(uint id, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; extern RailtypeInfo _railtypes[RAILTYPE_END]; if (id + numinfo > RAILTYPE_END) { grfmsg(1, "RailTypeChangeInfo: Rail type %u is invalid, max %u, ignoring", id + numinfo, RAILTYPE_END); return CIR_INVALID_ID; } for (int i = 0; i < numinfo; i++) { RailType rt = _cur.grffile->railtype_map[id + i]; if (rt == INVALID_RAILTYPE) return CIR_INVALID_ID; RailtypeInfo *rti = &_railtypes[rt]; switch (prop) { case 0x08: // Label of rail type /* Skipped here as this is loaded during reservation stage. */ buf->ReadDWord(); break; case 0x09: { // Toolbar caption of railtype (sets name as well for backwards compatibility for grf ver < 8) uint16 str = buf->ReadWord(); AddStringForMapping(str, &rti->strings.toolbar_caption); if (_cur.grffile->grf_version < 8) { AddStringForMapping(str, &rti->strings.name); } break; } case 0x0A: // Menu text of railtype AddStringForMapping(buf->ReadWord(), &rti->strings.menu_text); break; case 0x0B: // Build window caption AddStringForMapping(buf->ReadWord(), &rti->strings.build_caption); break; case 0x0C: // Autoreplace text AddStringForMapping(buf->ReadWord(), &rti->strings.replace_text); break; case 0x0D: // New locomotive text AddStringForMapping(buf->ReadWord(), &rti->strings.new_loco); break; case 0x0E: // Compatible railtype list case 0x0F: // Powered railtype list case 0x18: // Railtype list required for date introduction case 0x19: // Introduced railtype list { /* Rail type compatibility bits are added to the existing bits * to allow multiple GRFs to modify compatibility with the * default rail types. */ int n = buf->ReadByte(); for (int j = 0; j != n; j++) { RailTypeLabel label = buf->ReadDWord(); RailType rt = GetRailTypeByLabel(BSWAP32(label), false); if (rt != INVALID_RAILTYPE) { switch (prop) { case 0x0F: SetBit(rti->powered_railtypes, rt); FALLTHROUGH; // Powered implies compatible. case 0x0E: SetBit(rti->compatible_railtypes, rt); break; case 0x18: SetBit(rti->introduction_required_railtypes, rt); break; case 0x19: SetBit(rti->introduces_railtypes, rt); break; } } } break; } case 0x10: // Rail Type flags rti->flags = (RailTypeFlags)buf->ReadByte(); break; case 0x11: // Curve speed advantage rti->curve_speed = buf->ReadByte(); break; case 0x12: // Station graphic rti->fallback_railtype = Clamp(buf->ReadByte(), 0, 2); break; case 0x13: // Construction cost factor rti->cost_multiplier = buf->ReadWord(); break; case 0x14: // Speed limit rti->max_speed = buf->ReadWord(); break; case 0x15: // Acceleration model rti->acceleration_type = Clamp(buf->ReadByte(), 0, 2); break; case 0x16: // Map colour rti->map_colour = buf->ReadByte(); break; case 0x17: // Introduction date rti->introduction_date = buf->ReadDWord(); break; case 0x1A: // Sort order rti->sorting_order = buf->ReadByte(); break; case 0x1B: // Name of railtype (overridden by prop 09 for grf ver < 8) AddStringForMapping(buf->ReadWord(), &rti->strings.name); break; case 0x1C: // Maintenance cost factor rti->maintenance_multiplier = buf->ReadWord(); break; case 0x1D: // Alternate rail type label list /* Skipped here as this is loaded during reservation stage. */ for (int j = buf->ReadByte(); j != 0; j--) buf->ReadDWord(); break; case A0RPI_RAILTYPE_ENABLE_PROGRAMMABLE_SIGNALS: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; SB(rti->ctrl_flags, RTCF_PROGSIG, 1, (buf->ReadByte() != 0 ? 1 : 0)); break; case A0RPI_RAILTYPE_ENABLE_NO_ENTRY_SIGNALS: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; SB(rti->ctrl_flags, RTCF_NOENTRYSIG, 1, (buf->ReadByte() != 0 ? 1 : 0)); break; case A0RPI_RAILTYPE_ENABLE_RESTRICTED_SIGNALS: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; SB(rti->ctrl_flags, RTCF_RESTRICTEDSIG, 1, (buf->ReadByte() != 0 ? 1 : 0)); break; case A0RPI_RAILTYPE_DISABLE_REALISTIC_BRAKING: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; SB(rti->ctrl_flags, RTCF_NOREALISTICBRAKING, 1, (buf->ReadByte() != 0 ? 1 : 0)); break; case A0RPI_RAILTYPE_ENABLE_SIGNAL_RECOLOUR: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; SB(rti->ctrl_flags, RTCF_RECOLOUR_ENABLED, 1, (buf->ReadByte() != 0 ? 1 : 0)); break; case A0RPI_RAILTYPE_EXTRA_ASPECTS: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; rti->signal_extra_aspects = std::min(buf->ReadByte(), NEW_SIGNALS_MAX_EXTRA_ASPECT); break; default: ret = HandleAction0PropertyDefault(buf, prop); break; } } return ret; } static ChangeInfoResult RailTypeReserveInfo(uint id, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; extern RailtypeInfo _railtypes[RAILTYPE_END]; if (id + numinfo > RAILTYPE_END) { grfmsg(1, "RailTypeReserveInfo: Rail type %u is invalid, max %u, ignoring", id + numinfo, RAILTYPE_END); return CIR_INVALID_ID; } for (int i = 0; i < numinfo; i++) { switch (prop) { case 0x08: // Label of rail type { RailTypeLabel rtl = buf->ReadDWord(); rtl = BSWAP32(rtl); RailType rt = GetRailTypeByLabel(rtl, false); if (rt == INVALID_RAILTYPE) { /* Set up new rail type */ rt = AllocateRailType(rtl); } _cur.grffile->railtype_map[id + i] = rt; break; } case 0x09: // Toolbar caption of railtype case 0x0A: // Menu text case 0x0B: // Build window caption case 0x0C: // Autoreplace text case 0x0D: // New loco case 0x13: // Construction cost case 0x14: // Speed limit case 0x1B: // Name of railtype case 0x1C: // Maintenance cost factor buf->ReadWord(); break; case 0x1D: // Alternate rail type label list if (_cur.grffile->railtype_map[id + i] != INVALID_RAILTYPE) { int n = buf->ReadByte(); for (int j = 0; j != n; j++) { _railtypes[_cur.grffile->railtype_map[id + i]].alternate_labels.push_back(BSWAP32(buf->ReadDWord())); } break; } grfmsg(1, "RailTypeReserveInfo: Ignoring property 1D for rail type %u because no label was set", id + i); FALLTHROUGH; case 0x0E: // Compatible railtype list case 0x0F: // Powered railtype list case 0x18: // Railtype list required for date introduction case 0x19: // Introduced railtype list for (int j = buf->ReadByte(); j != 0; j--) buf->ReadDWord(); break; case 0x10: // Rail Type flags case 0x11: // Curve speed advantage case 0x12: // Station graphic case 0x15: // Acceleration model case 0x16: // Map colour case 0x1A: // Sort order buf->ReadByte(); break; case 0x17: // Introduction date buf->ReadDWord(); break; case A0RPI_RAILTYPE_ENABLE_PROGRAMMABLE_SIGNALS: case A0RPI_RAILTYPE_ENABLE_NO_ENTRY_SIGNALS: case A0RPI_RAILTYPE_ENABLE_RESTRICTED_SIGNALS: case A0RPI_RAILTYPE_DISABLE_REALISTIC_BRAKING: case A0RPI_RAILTYPE_ENABLE_SIGNAL_RECOLOUR: case A0RPI_RAILTYPE_EXTRA_ASPECTS: buf->Skip(buf->ReadExtendedByte()); break; default: ret = HandleAction0PropertyDefault(buf, prop); break; } } return ret; } /** * Define properties for roadtypes * @param id ID of the roadtype. * @param numinfo Number of subsequent IDs to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult RoadTypeChangeInfo(uint id, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf, RoadTramType rtt) { ChangeInfoResult ret = CIR_SUCCESS; extern RoadTypeInfo _roadtypes[ROADTYPE_END]; RoadType *type_map = (rtt == RTT_TRAM) ? _cur.grffile->tramtype_map : _cur.grffile->roadtype_map; if (id + numinfo > ROADTYPE_END) { grfmsg(1, "RoadTypeChangeInfo: Road type %u is invalid, max %u, ignoring", id + numinfo, ROADTYPE_END); return CIR_INVALID_ID; } for (int i = 0; i < numinfo; i++) { RoadType rt = type_map[id + i]; if (rt == INVALID_ROADTYPE) return CIR_INVALID_ID; RoadTypeInfo *rti = &_roadtypes[rt]; switch (prop) { case 0x08: // Label of road type /* Skipped here as this is loaded during reservation stage. */ buf->ReadDWord(); break; case 0x09: { // Toolbar caption of roadtype (sets name as well for backwards compatibility for grf ver < 8) uint16 str = buf->ReadWord(); AddStringForMapping(str, &rti->strings.toolbar_caption); break; } case 0x0A: // Menu text of roadtype AddStringForMapping(buf->ReadWord(), &rti->strings.menu_text); break; case 0x0B: // Build window caption AddStringForMapping(buf->ReadWord(), &rti->strings.build_caption); break; case 0x0C: // Autoreplace text AddStringForMapping(buf->ReadWord(), &rti->strings.replace_text); break; case 0x0D: // New engine text AddStringForMapping(buf->ReadWord(), &rti->strings.new_engine); break; case 0x0F: // Powered roadtype list case 0x18: // Roadtype list required for date introduction case 0x19: { // Introduced roadtype list /* Road type compatibility bits are added to the existing bits * to allow multiple GRFs to modify compatibility with the * default road types. */ int n = buf->ReadByte(); for (int j = 0; j != n; j++) { RoadTypeLabel label = buf->ReadDWord(); RoadType rt = GetRoadTypeByLabel(BSWAP32(label), false); if (rt != INVALID_ROADTYPE) { switch (prop) { case 0x0F: SetBit(rti->powered_roadtypes, rt); break; case 0x18: SetBit(rti->introduction_required_roadtypes, rt); break; case 0x19: SetBit(rti->introduces_roadtypes, rt); break; } } } break; } case 0x10: // Road Type flags rti->flags = (RoadTypeFlags)buf->ReadByte(); break; case 0x13: // Construction cost factor rti->cost_multiplier = buf->ReadWord(); break; case 0x14: // Speed limit rti->max_speed = buf->ReadWord(); break; case 0x16: // Map colour rti->map_colour = buf->ReadByte(); break; case 0x17: // Introduction date rti->introduction_date = buf->ReadDWord(); break; case 0x1A: // Sort order rti->sorting_order = buf->ReadByte(); break; case 0x1B: // Name of roadtype AddStringForMapping(buf->ReadWord(), &rti->strings.name); break; case 0x1C: // Maintenance cost factor rti->maintenance_multiplier = buf->ReadWord(); break; case 0x1D: // Alternate road type label list /* Skipped here as this is loaded during reservation stage. */ for (int j = buf->ReadByte(); j != 0; j--) buf->ReadDWord(); break; case A0RPI_ROADTYPE_EXTRA_FLAGS: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; rti->extra_flags = (RoadTypeExtraFlags)buf->ReadByte(); break; default: ret = CIR_UNKNOWN; break; } } return ret; } static ChangeInfoResult RoadTypeChangeInfo(uint id, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { return RoadTypeChangeInfo(id, numinfo, prop, mapping_entry, buf, RTT_ROAD); } static ChangeInfoResult TramTypeChangeInfo(uint id, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { return RoadTypeChangeInfo(id, numinfo, prop, mapping_entry, buf, RTT_TRAM); } static ChangeInfoResult RoadTypeReserveInfo(uint id, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf, RoadTramType rtt) { ChangeInfoResult ret = CIR_SUCCESS; extern RoadTypeInfo _roadtypes[ROADTYPE_END]; RoadType *type_map = (rtt == RTT_TRAM) ? _cur.grffile->tramtype_map : _cur.grffile->roadtype_map; if (id + numinfo > ROADTYPE_END) { grfmsg(1, "RoadTypeReserveInfo: Road type %u is invalid, max %u, ignoring", id + numinfo, ROADTYPE_END); return CIR_INVALID_ID; } for (int i = 0; i < numinfo; i++) { switch (prop) { case 0x08: { // Label of road type RoadTypeLabel rtl = buf->ReadDWord(); rtl = BSWAP32(rtl); RoadType rt = GetRoadTypeByLabel(rtl, false); if (rt == INVALID_ROADTYPE) { /* Set up new road type */ rt = AllocateRoadType(rtl, rtt); } else if (GetRoadTramType(rt) != rtt) { grfmsg(1, "RoadTypeReserveInfo: Road type %u is invalid type (road/tram), ignoring", id + numinfo); return CIR_INVALID_ID; } type_map[id + i] = rt; break; } case 0x09: // Toolbar caption of roadtype case 0x0A: // Menu text case 0x0B: // Build window caption case 0x0C: // Autoreplace text case 0x0D: // New loco case 0x13: // Construction cost case 0x14: // Speed limit case 0x1B: // Name of roadtype case 0x1C: // Maintenance cost factor buf->ReadWord(); break; case 0x1D: // Alternate road type label list if (type_map[id + i] != INVALID_ROADTYPE) { int n = buf->ReadByte(); for (int j = 0; j != n; j++) { _roadtypes[type_map[id + i]].alternate_labels.push_back(BSWAP32(buf->ReadDWord())); } break; } grfmsg(1, "RoadTypeReserveInfo: Ignoring property 1D for road type %u because no label was set", id + i); /* FALL THROUGH */ case 0x0F: // Powered roadtype list case 0x18: // Roadtype list required for date introduction case 0x19: // Introduced roadtype list for (int j = buf->ReadByte(); j != 0; j--) buf->ReadDWord(); break; case 0x10: // Road Type flags case 0x16: // Map colour case 0x1A: // Sort order buf->ReadByte(); break; case 0x17: // Introduction date buf->ReadDWord(); break; case A0RPI_ROADTYPE_EXTRA_FLAGS: buf->Skip(buf->ReadExtendedByte()); break; default: ret = CIR_UNKNOWN; break; } } return ret; } static ChangeInfoResult RoadTypeReserveInfo(uint id, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { return RoadTypeReserveInfo(id, numinfo, prop, mapping_entry, buf, RTT_ROAD); } static ChangeInfoResult TramTypeReserveInfo(uint id, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { return RoadTypeReserveInfo(id, numinfo, prop, mapping_entry, buf, RTT_TRAM); } static ChangeInfoResult AirportTilesChangeInfo(uint airtid, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; if (airtid + numinfo > NUM_AIRPORTTILES_PER_GRF) { grfmsg(1, "AirportTileChangeInfo: Too many airport tiles loaded (%u), max (%u). Ignoring.", airtid + numinfo, NUM_AIRPORTTILES_PER_GRF); return CIR_INVALID_ID; } /* Allocate airport tile specs if they haven't been allocated already. */ if (_cur.grffile->airtspec == nullptr) { _cur.grffile->airtspec = CallocT(NUM_AIRPORTTILES_PER_GRF); } for (int i = 0; i < numinfo; i++) { AirportTileSpec *tsp = _cur.grffile->airtspec[airtid + i]; if (prop != 0x08 && tsp == nullptr) { grfmsg(2, "AirportTileChangeInfo: Attempt to modify undefined airport tile %u. Ignoring.", airtid + i); return CIR_INVALID_ID; } switch (prop) { case 0x08: { // Substitute airport tile type AirportTileSpec **tilespec = &_cur.grffile->airtspec[airtid + i]; byte subs_id = buf->ReadByte(); if (subs_id >= NEW_AIRPORTTILE_OFFSET) { /* The substitute id must be one of the original airport tiles. */ grfmsg(2, "AirportTileChangeInfo: Attempt to use new airport tile %u as substitute airport tile for %u. Ignoring.", subs_id, airtid + i); continue; } /* Allocate space for this airport tile. */ if (*tilespec == nullptr) { *tilespec = CallocT(1); tsp = *tilespec; memcpy(tsp, AirportTileSpec::Get(subs_id), sizeof(AirportTileSpec)); tsp->enabled = true; tsp->animation.status = ANIM_STATUS_NO_ANIMATION; tsp->grf_prop.local_id = airtid + i; tsp->grf_prop.subst_id = subs_id; tsp->grf_prop.grffile = _cur.grffile; _airporttile_mngr.AddEntityID(airtid + i, _cur.grffile->grfid, subs_id); // pre-reserve the tile slot } break; } case 0x09: { // Airport tile override byte override = buf->ReadByte(); /* The airport tile being overridden must be an original airport tile. */ if (override >= NEW_AIRPORTTILE_OFFSET) { grfmsg(2, "AirportTileChangeInfo: Attempt to override new airport tile %u with airport tile id %u. Ignoring.", override, airtid + i); continue; } _airporttile_mngr.Add(airtid + i, _cur.grffile->grfid, override); break; } case 0x0E: // Callback mask tsp->callback_mask = buf->ReadByte(); break; case 0x0F: // Animation information tsp->animation.frames = buf->ReadByte(); tsp->animation.status = buf->ReadByte(); break; case 0x10: // Animation speed tsp->animation.speed = buf->ReadByte(); break; case 0x11: // Animation triggers tsp->animation.triggers = buf->ReadByte(); break; default: ret = HandleAction0PropertyDefault(buf, prop); break; } } return ret; } /** * Ignore properties for roadstops * @param prop The property to ignore. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult IgnoreRoadStopProperty(uint prop, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; switch (prop) { case 0x09: case 0x0C: buf->ReadByte(); break; case 0x0A: case 0x0B: buf->ReadWord(); break; case 0x08: case 0x0D: buf->ReadDWord(); break; default: ret = HandleAction0PropertyDefault(buf, prop); break; } return ret; } static ChangeInfoResult RoadStopChangeInfo(uint id, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { ChangeInfoResult ret = CIR_SUCCESS; if (id + numinfo > 255) { grfmsg(1, "RoadStopChangeInfo: RoadStop %u is invalid, max %u, ignoring", id + numinfo, 255); return CIR_INVALID_ID; } if (_cur.grffile->roadstops == nullptr) _cur.grffile->roadstops = CallocT(255); for (int i = 0; i < numinfo; i++) { RoadStopSpec *rs = _cur.grffile->roadstops[id + i]; if (rs == nullptr && prop != 0x08 && prop != A0RPI_ROADSTOP_CLASS_ID) { grfmsg(1, "RoadStopChangeInfo: Attempt to modify undefined road stop %u, ignoring", id + i); ChangeInfoResult cir = IgnoreRoadStopProperty(prop, buf); if (cir > ret) ret = cir; continue; } switch (prop) { case A0RPI_ROADSTOP_CLASS_ID: if (MappedPropertyLengthMismatch(buf, 4, mapping_entry)) break; FALLTHROUGH; case 0x08: { // Road Stop Class ID RoadStopSpec **spec = &_cur.grffile->roadstops[id + i]; if (*spec == nullptr) { *spec = CallocT(1); new (*spec) RoadStopSpec(); } uint32 classid = buf->ReadDWord(); (*spec)->cls_id = RoadStopClass::Allocate(BSWAP32(classid)); (*spec)->spec_id = id + i; break; } case A0RPI_ROADSTOP_STOP_TYPE: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; FALLTHROUGH; case 0x09: // Road stop type rs->stop_type = (RoadStopAvailabilityType)buf->ReadByte(); break; case A0RPI_ROADSTOP_STOP_NAME: if (MappedPropertyLengthMismatch(buf, 2, mapping_entry)) break; FALLTHROUGH; case 0x0A: // Road Stop Name AddStringForMapping(buf->ReadWord(), &rs->name); break; case A0RPI_ROADSTOP_CLASS_NAME: if (MappedPropertyLengthMismatch(buf, 2, mapping_entry)) break; FALLTHROUGH; case 0x0B: // Road Stop Class name AddStringForMapping(buf->ReadWord(), &RoadStopClass::Get(rs->cls_id)->name); break; case A0RPI_ROADSTOP_DRAW_MODE: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; FALLTHROUGH; case 0x0C: // The draw mode rs->draw_mode = (RoadStopDrawMode)buf->ReadByte(); break; case A0RPI_ROADSTOP_TRIGGER_CARGOES: if (MappedPropertyLengthMismatch(buf, 4, mapping_entry)) break; FALLTHROUGH; case 0x0D: // Cargo types for random triggers rs->cargo_triggers = TranslateRefitMask(buf->ReadDWord()); break; case A0RPI_ROADSTOP_ANIMATION_INFO: if (MappedPropertyLengthMismatch(buf, 2, mapping_entry)) break; FALLTHROUGH; case 0x0E: // Animation info rs->animation.frames = buf->ReadByte(); rs->animation.status = buf->ReadByte(); break; case A0RPI_ROADSTOP_ANIMATION_SPEED: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; FALLTHROUGH; case 0x0F: // Animation speed rs->animation.speed = buf->ReadByte(); break; case A0RPI_ROADSTOP_ANIMATION_TRIGGERS: if (MappedPropertyLengthMismatch(buf, 2, mapping_entry)) break; FALLTHROUGH; case 0x10: // Animation triggers rs->animation.triggers = buf->ReadWord(); break; case A0RPI_ROADSTOP_CALLBACK_MASK: if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; FALLTHROUGH; case 0x11: // Callback mask rs->callback_mask = buf->ReadByte(); break; case A0RPI_ROADSTOP_GENERAL_FLAGS: if (MappedPropertyLengthMismatch(buf, 4, mapping_entry)) break; FALLTHROUGH; case 0x12: // General flags rs->flags = (uint8)buf->ReadDWord(); // Future-proofing, size this as 4 bytes, but we only need one byte's worth of flags at present break; case A0RPI_ROADSTOP_MIN_BRIDGE_HEIGHT: if (MappedPropertyLengthMismatch(buf, 6, mapping_entry)) break; FALLTHROUGH; case 0x13: // Minimum height for a bridge above SetBit(rs->internal_flags, RSIF_BRIDGE_HEIGHTS_SET); for (uint i = 0; i < 6; i++) { rs->bridge_height[i] = buf->ReadByte(); } break; case A0RPI_ROADSTOP_DISALLOWED_BRIDGE_PILLARS: if (MappedPropertyLengthMismatch(buf, 6, mapping_entry)) break; FALLTHROUGH; case 0x14: // Disallowed bridge pillars SetBit(rs->internal_flags, RSIF_BRIDGE_DISALLOWED_PILLARS_SET); for (uint i = 0; i < 6; i++) { rs->bridge_disallowed_pillars[i] = buf->ReadByte(); } break; case A0RPI_ROADSTOP_COST_MULTIPLIERS: if (MappedPropertyLengthMismatch(buf, 2, mapping_entry)) break; FALLTHROUGH; case 0x15: // Cost multipliers rs->build_cost_multiplier = buf->ReadByte(); rs->clear_cost_multiplier = buf->ReadByte(); break; default: ret = CIR_UNKNOWN; break; } } return ret; } /** * Define properties for new landscape * @param id Landscape type. * @param numinfo Number of subsequent IDs to change the property for. * @param prop The property to change. * @param buf The property value. * @return ChangeInfoResult. */ static ChangeInfoResult NewLandscapeChangeInfo(uint id, int numinfo, int prop, const GRFFilePropertyRemapEntry *mapping_entry, ByteReader *buf) { /* Properties which are handled per item */ ChangeInfoResult ret = CIR_SUCCESS; for (int i = 0; i < numinfo; i++) { switch (prop) { case A0RPI_NEWLANDSCAPE_ENABLE_RECOLOUR: { if (MappedPropertyLengthMismatch(buf, 1, mapping_entry)) break; bool enabled = (buf->ReadByte() != 0 ? 1 : 0); if (id == NLA3ID_CUSTOM_ROCKS) { SB(_cur.grffile->new_landscape_ctrl_flags, NLCF_ROCKS_RECOLOUR_ENABLED, 1, enabled); } break; } default: ret = HandleAction0PropertyDefault(buf, prop); break; } } return ret; } static bool HandleChangeInfoResult(const char *caller, ChangeInfoResult cir, GrfSpecFeature feature, int property) { switch (cir) { default: NOT_REACHED(); case CIR_DISABLED: /* Error has already been printed; just stop parsing */ return true; case CIR_SUCCESS: return false; case CIR_UNHANDLED: grfmsg(1, "%s: Ignoring property 0x%02X of feature %s (not implemented)", caller, property, GetFeatureString(feature)); return false; case CIR_UNKNOWN: grfmsg(0, "%s: Unknown property 0x%02X of feature %s, disabling", caller, property, GetFeatureString(feature)); FALLTHROUGH; case CIR_INVALID_ID: { /* No debug message for an invalid ID, as it has already been output */ GRFError *error = DisableGrf(cir == CIR_INVALID_ID ? STR_NEWGRF_ERROR_INVALID_ID : STR_NEWGRF_ERROR_UNKNOWN_PROPERTY); if (cir != CIR_INVALID_ID) error->param_value[1] = property; return true; } } } static GrfSpecFeatureRef ReadFeature(uint8 raw_byte, bool allow_48 = false) { if (unlikely(HasBit(_cur.grffile->ctrl_flags, GFCF_HAVE_FEATURE_ID_REMAP))) { const GRFFeatureMapRemapSet &remap = _cur.grffile->feature_id_remaps; if (remap.remapped_ids[raw_byte]) { auto iter = remap.mapping.find(raw_byte); const GRFFeatureMapRemapEntry &def = iter->second; if (def.feature == GSF_ERROR_ON_USE) { grfmsg(0, "Error: Unimplemented mapped feature: %s, mapped to: %02X", def.name, raw_byte); GRFError *error = DisableGrf(STR_NEWGRF_ERROR_UNIMPLEMETED_MAPPED_FEATURE_ID); error->data = stredup(def.name); error->param_value[1] = GSF_INVALID; error->param_value[2] = raw_byte; } else if (def.feature == GSF_INVALID) { grfmsg(2, "Ignoring unimplemented mapped feature: %s, mapped to: %02X", def.name, raw_byte); } return { def.feature, raw_byte }; } } GrfSpecFeature feature; if (raw_byte >= GSF_REAL_FEATURE_END && !(allow_48 && raw_byte == 0x48)) { feature = GSF_INVALID; } else { feature = static_cast(raw_byte); } return { feature, raw_byte }; } static const char *_feature_names[] = { "TRAINS", "ROADVEHICLES", "SHIPS", "AIRCRAFT", "STATIONS", "CANALS", "BRIDGES", "HOUSES", "GLOBALVAR", "INDUSTRYTILES", "INDUSTRIES", "CARGOES", "SOUNDFX", "AIRPORTS", "SIGNALS", "OBJECTS", "RAILTYPES", "AIRPORTTILES", "ROADTYPES", "TRAMTYPES", "ROADSTOPS", "NEWLANDSCAPE", }; static_assert(lengthof(_feature_names) == GSF_END); const char *GetFeatureString(GrfSpecFeatureRef feature) { static char buffer[32]; if (feature.id < GSF_END) { seprintf(buffer, lastof(buffer), "0x%02X (%s)", feature.raw_byte, _feature_names[feature.id]); } else { if (unlikely(HasBit(_cur.grffile->ctrl_flags, GFCF_HAVE_FEATURE_ID_REMAP))) { const GRFFeatureMapRemapSet &remap = _cur.grffile->feature_id_remaps; if (remap.remapped_ids[feature.raw_byte]) { auto iter = remap.mapping.find(feature.raw_byte); const GRFFeatureMapRemapEntry &def = iter->second; seprintf(buffer, lastof(buffer), "0x%02X (%s)", feature.raw_byte, def.name); return buffer; } } seprintf(buffer, lastof(buffer), "0x%02X", feature.raw_byte); } return buffer; } const char *GetFeatureString(GrfSpecFeature feature) { uint8 raw_byte = feature; if (feature >= GSF_REAL_FEATURE_END) { for (const auto &entry : _cur.grffile->feature_id_remaps.mapping) { if (entry.second.feature == feature) { raw_byte = entry.second.raw_id; break; } } } return GetFeatureString(GrfSpecFeatureRef{ feature, raw_byte }); } struct GRFFilePropertyDescriptor { int prop; const GRFFilePropertyRemapEntry *entry; GRFFilePropertyDescriptor(int prop, const GRFFilePropertyRemapEntry *entry) : prop(prop), entry(entry) {} }; static GRFFilePropertyDescriptor ReadAction0PropertyID(ByteReader *buf, uint8 feature) { uint8 raw_prop = buf->ReadByte(); const GRFFilePropertyRemapSet &remap = _cur.grffile->action0_property_remaps[feature]; if (remap.remapped_ids[raw_prop]) { auto iter = remap.mapping.find(raw_prop); assert(iter != remap.mapping.end()); const GRFFilePropertyRemapEntry &def = iter->second; int prop = def.id; if (prop == A0RPI_UNKNOWN_ERROR) { grfmsg(0, "Error: Unimplemented mapped property: %s, feature: %s, mapped to: %X", def.name, GetFeatureString(def.feature), raw_prop); GRFError *error = DisableGrf(STR_NEWGRF_ERROR_UNIMPLEMETED_MAPPED_PROPERTY); error->data = stredup(def.name); error->param_value[1] = def.feature; error->param_value[2] = raw_prop; } else if (prop == A0RPI_UNKNOWN_IGNORE) { grfmsg(2, "Ignoring unimplemented mapped property: %s, feature: %s, mapped to: %X", def.name, GetFeatureString(def.feature), raw_prop); } return GRFFilePropertyDescriptor(prop, &def); } else { return GRFFilePropertyDescriptor(raw_prop, nullptr); } } /* Action 0x00 */ static void FeatureChangeInfo(ByteReader *buf) { /* <00>

()... * * B feature * B num-props how many properties to change per vehicle/station * B num-info how many vehicles/stations to change * E id ID of first vehicle/station to change, if num-info is * greater than one, this one and the following * vehicles/stations will be changed * B property what property to change, depends on the feature * V new-info new bytes of info (variable size; depends on properties) */ static const VCI_Handler handler[] = { /* GSF_TRAINS */ RailVehicleChangeInfo, /* GSF_ROADVEHICLES */ RoadVehicleChangeInfo, /* GSF_SHIPS */ ShipVehicleChangeInfo, /* GSF_AIRCRAFT */ AircraftVehicleChangeInfo, /* GSF_STATIONS */ StationChangeInfo, /* GSF_CANALS */ CanalChangeInfo, /* GSF_BRIDGES */ BridgeChangeInfo, /* GSF_HOUSES */ TownHouseChangeInfo, /* GSF_GLOBALVAR */ GlobalVarChangeInfo, /* GSF_INDUSTRYTILES */ IndustrytilesChangeInfo, /* GSF_INDUSTRIES */ IndustriesChangeInfo, /* GSF_CARGOES */ nullptr, // Cargo is handled during reservation /* GSF_SOUNDFX */ SoundEffectChangeInfo, /* GSF_AIRPORTS */ AirportChangeInfo, /* GSF_SIGNALS */ SignalsChangeInfo, /* GSF_OBJECTS */ ObjectChangeInfo, /* GSF_RAILTYPES */ RailTypeChangeInfo, /* GSF_AIRPORTTILES */ AirportTilesChangeInfo, /* GSF_ROADTYPES */ RoadTypeChangeInfo, /* GSF_TRAMTYPES */ TramTypeChangeInfo, /* GSF_ROADSTOPS */ RoadStopChangeInfo, /* GSF_NEWLANDSCAPE */ NewLandscapeChangeInfo, }; static_assert(GSF_END == lengthof(handler)); static_assert(lengthof(handler) == lengthof(_cur.grffile->action0_property_remaps), "Action 0 feature list length mismatch"); GrfSpecFeatureRef feature_ref = ReadFeature(buf->ReadByte()); GrfSpecFeature feature = feature_ref.id; uint8 numprops = buf->ReadByte(); uint numinfo = buf->ReadByte(); uint engine = buf->ReadExtendedByte(); if (feature >= GSF_END) { grfmsg(1, "FeatureChangeInfo: Unsupported feature %s skipping", GetFeatureString(feature_ref)); return; } grfmsg(6, "FeatureChangeInfo: Feature %s, %d properties, to apply to %d+%d", GetFeatureString(feature_ref), numprops, engine, numinfo); if (handler[feature] == nullptr) { if (feature != GSF_CARGOES) grfmsg(1, "FeatureChangeInfo: Unsupported feature %s, skipping", GetFeatureString(feature_ref)); return; } /* Mark the feature as used by the grf */ SetBit(_cur.grffile->grf_features, feature); while (numprops-- && buf->HasData()) { GRFFilePropertyDescriptor desc = ReadAction0PropertyID(buf, feature); ChangeInfoResult cir = handler[feature](engine, numinfo, desc.prop, desc.entry, buf); if (HandleChangeInfoResult("FeatureChangeInfo", cir, feature, desc.prop)) return; } } /* Action 0x00 (GLS_SAFETYSCAN) */ static void SafeChangeInfo(ByteReader *buf) { GrfSpecFeatureRef feature = ReadFeature(buf->ReadByte()); uint8 numprops = buf->ReadByte(); uint numinfo = buf->ReadByte(); buf->ReadExtendedByte(); // id if (feature.id == GSF_BRIDGES && numprops == 1) { GRFFilePropertyDescriptor desc = ReadAction0PropertyID(buf, feature.id); /* Bridge property 0x0D is redefinition of sprite layout tables, which * is considered safe. */ if (desc.prop == 0x0D) return; } else if (feature.id == GSF_GLOBALVAR && numprops == 1) { GRFFilePropertyDescriptor desc = ReadAction0PropertyID(buf, feature.id); /* Engine ID Mappings are safe, if the source is static */ if (desc.prop == 0x11) { bool is_safe = true; for (uint i = 0; i < numinfo; i++) { uint32 s = buf->ReadDWord(); buf->ReadDWord(); // dest const GRFConfig *grfconfig = GetGRFConfig(s); if (grfconfig != nullptr && !HasBit(grfconfig->flags, GCF_STATIC)) { is_safe = false; break; } } if (is_safe) return; } } SetBit(_cur.grfconfig->flags, GCF_UNSAFE); /* Skip remainder of GRF */ _cur.skip_sprites = -1; } /* Action 0x00 (GLS_RESERVE) */ static void ReserveChangeInfo(ByteReader *buf) { GrfSpecFeatureRef feature_ref = ReadFeature(buf->ReadByte()); GrfSpecFeature feature = feature_ref.id; if (feature != GSF_CARGOES && feature != GSF_GLOBALVAR && feature != GSF_RAILTYPES && feature != GSF_ROADTYPES && feature != GSF_TRAMTYPES) return; uint8 numprops = buf->ReadByte(); uint8 numinfo = buf->ReadByte(); uint8 index = buf->ReadExtendedByte(); while (numprops-- && buf->HasData()) { GRFFilePropertyDescriptor desc = ReadAction0PropertyID(buf, feature); ChangeInfoResult cir = CIR_SUCCESS; switch (feature) { default: NOT_REACHED(); case GSF_CARGOES: cir = CargoChangeInfo(index, numinfo, desc.prop, desc.entry, buf); break; case GSF_GLOBALVAR: cir = GlobalVarReserveInfo(index, numinfo, desc.prop, desc.entry, buf); break; case GSF_RAILTYPES: cir = RailTypeReserveInfo(index, numinfo, desc.prop, desc.entry, buf); break; case GSF_ROADTYPES: cir = RoadTypeReserveInfo(index, numinfo, desc.prop, desc.entry, buf); break; case GSF_TRAMTYPES: cir = TramTypeReserveInfo(index, numinfo, desc.prop, desc.entry, buf); break; } if (HandleChangeInfoResult("ReserveChangeInfo", cir, feature, desc.prop)) return; } } /* Action 0x01 */ static void NewSpriteSet(ByteReader *buf) { /* Basic format: <01>

* Extended format: <01> 00

* * B feature feature to define sprites for * 0, 1, 2, 3: veh-type, 4: train stations * E first-set first sprite set to define * B num-sets number of sprite sets (extended byte in extended format) * E num-ent how many entries per sprite set * For vehicles, this is the number of different * vehicle directions in each sprite set * Set num-dirs=8, unless your sprites are symmetric. * In that case, use num-dirs=4. */ GrfSpecFeatureRef feature_ref = ReadFeature(buf->ReadByte()); GrfSpecFeature feature = feature_ref.id; uint16 num_sets = buf->ReadByte(); uint16 first_set = 0; if (num_sets == 0 && buf->HasData(3)) { /* Extended Action1 format. * Some GRFs define zero sets of zero sprites, though there is actually no use in that. Ignore them. */ first_set = buf->ReadExtendedByte(); num_sets = buf->ReadExtendedByte(); } uint16 num_ents = buf->ReadExtendedByte(); if (feature >= GSF_END) { _cur.skip_sprites = num_sets * num_ents; grfmsg(1, "NewSpriteSet: Unsupported feature %s, skipping %d sprites", GetFeatureString(feature_ref), _cur.skip_sprites); return; } _cur.AddSpriteSets(feature, _cur.spriteid, first_set, num_sets, num_ents); grfmsg(7, "New sprite set at %d of feature %s, consisting of %d sets with %d views each (total %d)", _cur.spriteid, GetFeatureString(feature), num_sets, num_ents, num_sets * num_ents ); for (int i = 0; i < num_sets * num_ents; i++) { _cur.nfo_line++; LoadNextSprite(_cur.spriteid++, *_cur.file, _cur.nfo_line); } } /* Action 0x01 (SKIP) */ static void SkipAct1(ByteReader *buf) { buf->ReadByte(); uint16 num_sets = buf->ReadByte(); if (num_sets == 0 && buf->HasData(3)) { /* Extended Action1 format. * Some GRFs define zero sets of zero sprites, though there is actually no use in that. Ignore them. */ buf->ReadExtendedByte(); // first_set num_sets = buf->ReadExtendedByte(); } uint16 num_ents = buf->ReadExtendedByte(); _cur.skip_sprites = num_sets * num_ents; grfmsg(3, "SkipAct1: Skipping %d sprites", _cur.skip_sprites); } const CallbackResultSpriteGroup *NewCallbackResultSpriteGroupNoTransform(uint16 result) { const CallbackResultSpriteGroup *&ptr = _callback_result_cache[result]; if (ptr == nullptr) { assert(CallbackResultSpriteGroup::CanAllocateItem()); ptr = new CallbackResultSpriteGroup(result); } return ptr; } static const CallbackResultSpriteGroup *NewCallbackResultSpriteGroup(uint16 groupid) { uint16 result = CallbackResultSpriteGroup::TransformResultValue(groupid, _cur.grffile->grf_version >= 8); return NewCallbackResultSpriteGroupNoTransform(result); } /* Helper function to either create a callback or link to a previously * defined spritegroup. */ static const SpriteGroup *GetGroupFromGroupID(byte setid, byte type, uint16 groupid) { if (HasBit(groupid, 15)) { return NewCallbackResultSpriteGroup(groupid); } if (groupid > MAX_SPRITEGROUP || _cur.spritegroups[groupid] == nullptr) { grfmsg(1, "GetGroupFromGroupID(0x%02X:0x%02X): Groupid 0x%04X does not exist, leaving empty", setid, type, groupid); return nullptr; } const SpriteGroup *result = _cur.spritegroups[groupid]; if (likely(!HasBit(_misc_debug_flags, MDF_NEWGRF_SG_SAVE_RAW))) result = PruneTargetSpriteGroup(result); return result; } static const SpriteGroup *GetGroupByID(uint16 groupid) { const SpriteGroup *result = _cur.spritegroups[groupid]; return result; } /** * Helper function to either create a callback or a result sprite group. * @param feature GrfSpecFeature to define spritegroup for. * @param setid SetID of the currently being parsed Action2. (only for debug output) * @param type Type of the currently being parsed Action2. (only for debug output) * @param spriteid Raw value from the GRF for the new spritegroup; describes either the return value or the referenced spritegroup. * @return Created spritegroup. */ static const SpriteGroup *CreateGroupFromGroupID(byte feature, byte setid, byte type, uint16 spriteid) { if (HasBit(spriteid, 15)) { return NewCallbackResultSpriteGroup(spriteid); } if (!_cur.IsValidSpriteSet(feature, spriteid)) { grfmsg(1, "CreateGroupFromGroupID(0x%02X:0x%02X): Sprite set %u invalid", setid, type, spriteid); return nullptr; } SpriteID spriteset_start = _cur.GetSprite(feature, spriteid); uint num_sprites = _cur.GetNumEnts(feature, spriteid); /* Ensure that the sprites are loeded */ assert(spriteset_start + num_sprites <= _cur.spriteid); assert(ResultSpriteGroup::CanAllocateItem()); return new ResultSpriteGroup(spriteset_start, num_sprites); } static void ProcessDeterministicSpriteGroupRanges(const std::vector &ranges, std::vector &ranges_out, const SpriteGroup *default_group) { /* Sort ranges ascending. When ranges overlap, this may required clamping or splitting them */ std::vector bounds; for (uint i = 0; i < ranges.size(); i++) { bounds.push_back(ranges[i].low); if (ranges[i].high != UINT32_MAX) bounds.push_back(ranges[i].high + 1); } std::sort(bounds.begin(), bounds.end()); bounds.erase(std::unique(bounds.begin(), bounds.end()), bounds.end()); std::vector target; for (uint j = 0; j < bounds.size(); ++j) { uint32 v = bounds[j]; const SpriteGroup *t = default_group; for (uint i = 0; i < ranges.size(); i++) { if (ranges[i].low <= v && v <= ranges[i].high) { t = ranges[i].group; break; } } target.push_back(t); } assert(target.size() == bounds.size()); for (uint j = 0; j < bounds.size(); ) { if (target[j] != default_group) { DeterministicSpriteGroupRange &r = ranges_out.emplace_back(); r.group = target[j]; r.low = bounds[j]; while (j < bounds.size() && target[j] == r.group) { j++; } r.high = j < bounds.size() ? bounds[j] - 1 : UINT32_MAX; } else { j++; } } } /* Action 0x02 */ static void NewSpriteGroup(ByteReader *buf) { /* <02>

* * B feature see action 1 * B set-id ID of this particular definition * B type/num-entries * if 80 or greater, this is a randomized or variational * list definition, see below * otherwise it specifies a number of entries, the exact * meaning depends on the feature * V feature-specific-data (huge mess, don't even look it up --pasky) */ const SpriteGroup *act_group = nullptr; GrfSpecFeatureRef feature_ref = ReadFeature(buf->ReadByte()); GrfSpecFeature feature = feature_ref.id; if (feature >= GSF_END) { grfmsg(1, "NewSpriteGroup: Unsupported feature %s, skipping", GetFeatureString(feature_ref)); return; } uint8 setid = buf->ReadByte(); uint8 type = buf->ReadByte(); /* Sprite Groups are created here but they are allocated from a pool, so * we do not need to delete anything if there is an exception from the * ByteReader. */ switch (type) { /* Deterministic Sprite Group */ case 0x81: // Self scope, byte case 0x82: // Parent scope, byte case 0x85: // Self scope, word case 0x86: // Parent scope, word case 0x89: // Self scope, dword case 0x8A: // Parent scope, dword { byte varadjust; byte varsize; bool first_adjust = true; assert(DeterministicSpriteGroup::CanAllocateItem()); DeterministicSpriteGroup *group = new DeterministicSpriteGroup(); group->nfo_line = _cur.nfo_line; group->feature = feature; if (_action6_override_active) group->sg_flags |= SGF_ACTION6; act_group = group; group->var_scope = HasBit(type, 1) ? VSG_SCOPE_PARENT : VSG_SCOPE_SELF; switch (GB(type, 2, 2)) { default: NOT_REACHED(); case 0: group->size = DSG_SIZE_BYTE; varsize = 1; break; case 1: group->size = DSG_SIZE_WORD; varsize = 2; break; case 2: group->size = DSG_SIZE_DWORD; varsize = 4; break; } DeterministicSpriteGroupShadowCopy *shadow = nullptr; if (unlikely(HasBit(_misc_debug_flags, MDF_NEWGRF_SG_SAVE_RAW))) { shadow = &(_deterministic_sg_shadows[group]); } VarAction2OptimiseState va2_opt_state; /* The initial value is always the constant 0 */ va2_opt_state.inference = VA2AIF_SIGNED_NON_NEGATIVE | VA2AIF_ONE_OR_ZERO | VA2AIF_HAVE_CONSTANT; va2_opt_state.current_constant = 0; /* Loop through the var adjusts. Unfortunately we don't know how many we have * from the outset, so we shall have to keep reallocing. */ do { DeterministicSpriteGroupAdjust &adjust = group->adjusts.emplace_back(); /* The first var adjust doesn't have an operation specified, so we set it to add. */ adjust.operation = first_adjust ? DSGA_OP_ADD : (DeterministicSpriteGroupAdjustOperation)buf->ReadByte(); first_adjust = false; if (adjust.operation > DSGA_OP_END) adjust.operation = DSGA_OP_END; adjust.variable = buf->ReadByte(); if (adjust.variable == 0x7E) { /* Link subroutine group */ adjust.subroutine = GetGroupFromGroupID(setid, type, buf->ReadByte()); } else { adjust.parameter = IsInsideMM(adjust.variable, 0x60, 0x80) ? buf->ReadByte() : 0; } varadjust = buf->ReadByte(); adjust.shift_num = GB(varadjust, 0, 5); adjust.type = (DeterministicSpriteGroupAdjustType)GB(varadjust, 6, 2); adjust.and_mask = buf->ReadVarSize(varsize); if (adjust.variable == 0x11) { for (const GRFVariableMapEntry &remap : _cur.grffile->grf_variable_remaps) { if (remap.feature == feature && remap.input_shift == adjust.shift_num && remap.input_mask == adjust.and_mask) { adjust.variable = remap.id; adjust.shift_num = remap.output_shift; adjust.and_mask = remap.output_mask; adjust.parameter = remap.output_param; break; } } } else if (adjust.variable == 0x7B && adjust.parameter == 0x11) { for (const GRFVariableMapEntry &remap : _cur.grffile->grf_variable_remaps) { if (remap.feature == feature && remap.input_shift == adjust.shift_num && remap.input_mask == adjust.and_mask) { adjust.parameter = remap.id; adjust.shift_num = remap.output_shift; adjust.and_mask = remap.output_mask; break; } } } if (adjust.type != DSGA_TYPE_NONE) { adjust.add_val = buf->ReadVarSize(varsize); adjust.divmod_val = buf->ReadVarSize(varsize); } else { adjust.add_val = 0; adjust.divmod_val = 0; } if (unlikely(shadow != nullptr)) { shadow->adjusts.push_back(adjust); /* Pruning was turned off so that the unpruned target could be saved in the shadow, prune now */ if (adjust.subroutine != nullptr) adjust.subroutine = PruneTargetSpriteGroup(adjust.subroutine); } OptimiseVarAction2Adjust(va2_opt_state, feature, varsize, group, adjust); /* Continue reading var adjusts while bit 5 is set. */ } while (HasBit(varadjust, 5)); std::vector ranges; ranges.resize(buf->ReadByte()); for (uint i = 0; i < ranges.size(); i++) { ranges[i].group = GetGroupFromGroupID(setid, type, buf->ReadWord()); ranges[i].low = buf->ReadVarSize(varsize); ranges[i].high = buf->ReadVarSize(varsize); } group->default_group = GetGroupFromGroupID(setid, type, buf->ReadWord()); if (unlikely(shadow != nullptr)) { shadow->calculated_result = ranges.size() == 0; ProcessDeterministicSpriteGroupRanges(ranges, shadow->ranges, group->default_group); shadow->default_group = group->default_group; /* Pruning was turned off so that the unpruned targets could be saved in the shadow ranges, prune now */ for (DeterministicSpriteGroupRange &range : ranges) { range.group = PruneTargetSpriteGroup(range.group); } group->default_group = PruneTargetSpriteGroup(group->default_group); } group->error_group = ranges.size() > 0 ? ranges[0].group : group->default_group; /* nvar == 0 is a special case -- we turn our value into a callback result */ group->calculated_result = ranges.size() == 0; ProcessDeterministicSpriteGroupRanges(ranges, group->ranges, group->default_group); OptimiseVarAction2DeterministicSpriteGroup(va2_opt_state, feature, varsize, group); break; } /* Randomized Sprite Group */ case 0x80: // Self scope case 0x83: // Parent scope case 0x84: // Relative scope { assert(RandomizedSpriteGroup::CanAllocateItem()); RandomizedSpriteGroup *group = new RandomizedSpriteGroup(); group->nfo_line = _cur.nfo_line; if (_action6_override_active) group->sg_flags |= SGF_ACTION6; act_group = group; group->var_scope = HasBit(type, 1) ? VSG_SCOPE_PARENT : VSG_SCOPE_SELF; if (HasBit(type, 2)) { if (feature <= GSF_AIRCRAFT) group->var_scope = VSG_SCOPE_RELATIVE; group->count = buf->ReadByte(); } uint8 triggers = buf->ReadByte(); group->triggers = GB(triggers, 0, 7); group->cmp_mode = HasBit(triggers, 7) ? RSG_CMP_ALL : RSG_CMP_ANY; group->lowest_randbit = buf->ReadByte(); byte num_groups = buf->ReadByte(); if (!HasExactlyOneBit(num_groups)) { grfmsg(1, "NewSpriteGroup: Random Action 2 nrand should be power of 2"); } for (uint i = 0; i < num_groups; i++) { group->groups.push_back(GetGroupFromGroupID(setid, type, buf->ReadWord())); } if (unlikely(HasBit(_misc_debug_flags, MDF_NEWGRF_SG_SAVE_RAW))) { RandomizedSpriteGroupShadowCopy *shadow = &(_randomized_sg_shadows[group]); shadow->groups = group->groups; /* Pruning was turned off so that the unpruned targets could be saved in the shadow groups, prune now */ for (const SpriteGroup *&group : group->groups) { group = PruneTargetSpriteGroup(group); } } break; } /* Neither a variable or randomized sprite group... must be a real group */ default: { switch (feature) { case GSF_TRAINS: case GSF_ROADVEHICLES: case GSF_SHIPS: case GSF_AIRCRAFT: case GSF_STATIONS: case GSF_CANALS: case GSF_CARGOES: case GSF_AIRPORTS: case GSF_RAILTYPES: case GSF_ROADTYPES: case GSF_TRAMTYPES: case GSF_SIGNALS: case GSF_NEWLANDSCAPE: { byte num_loaded = type; byte num_loading = buf->ReadByte(); if (!_cur.HasValidSpriteSets(feature)) { grfmsg(0, "NewSpriteGroup: No sprite set to work on! Skipping"); return; } if (num_loaded + num_loading == 0) { grfmsg(1, "NewSpriteGroup: no result, skipping invalid RealSpriteGroup"); break; } grfmsg(6, "NewSpriteGroup: New SpriteGroup 0x%02X, %u loaded, %u loading", setid, num_loaded, num_loading); if (num_loaded + num_loading == 0) { grfmsg(1, "NewSpriteGroup: no result, skipping invalid RealSpriteGroup"); break; } if (num_loaded + num_loading == 1) { /* Avoid creating 'Real' sprite group if only one option. */ uint16 spriteid = buf->ReadWord(); act_group = CreateGroupFromGroupID(feature, setid, type, spriteid); grfmsg(8, "NewSpriteGroup: one result, skipping RealSpriteGroup = subset %u", spriteid); break; } std::vector loaded; std::vector loading; for (uint i = 0; i < num_loaded; i++) { loaded.push_back(buf->ReadWord()); grfmsg(8, "NewSpriteGroup: + rg->loaded[%i] = subset %u", i, loaded[i]); } for (uint i = 0; i < num_loading; i++) { loading.push_back(buf->ReadWord()); grfmsg(8, "NewSpriteGroup: + rg->loading[%i] = subset %u", i, loading[i]); } if (std::adjacent_find(loaded.begin(), loaded.end(), std::not_equal_to<>()) == loaded.end() && std::adjacent_find(loading.begin(), loading.end(), std::not_equal_to<>()) == loading.end() && loaded[0] == loading[0]) { /* Both lists only contain the same value, so don't create 'Real' sprite group */ act_group = CreateGroupFromGroupID(feature, setid, type, loaded[0]); grfmsg(8, "NewSpriteGroup: same result, skipping RealSpriteGroup = subset %u", loaded[0]); break; } assert(RealSpriteGroup::CanAllocateItem()); RealSpriteGroup *group = new RealSpriteGroup(); group->nfo_line = _cur.nfo_line; if (_action6_override_active) group->sg_flags |= SGF_ACTION6; act_group = group; for (uint16 spriteid : loaded) { const SpriteGroup *t = CreateGroupFromGroupID(feature, setid, type, spriteid); group->loaded.push_back(t); } for (uint16 spriteid : loading) { const SpriteGroup *t = CreateGroupFromGroupID(feature, setid, type, spriteid); group->loading.push_back(t); } break; } case GSF_HOUSES: case GSF_AIRPORTTILES: case GSF_OBJECTS: case GSF_INDUSTRYTILES: case GSF_ROADSTOPS: { byte num_building_sprites = std::max((uint8)1, type); assert(TileLayoutSpriteGroup::CanAllocateItem()); TileLayoutSpriteGroup *group = new TileLayoutSpriteGroup(); group->nfo_line = _cur.nfo_line; if (_action6_override_active) group->sg_flags |= SGF_ACTION6; act_group = group; /* On error, bail out immediately. Temporary GRF data was already freed */ if (ReadSpriteLayout(buf, num_building_sprites, true, feature, false, type == 0, &group->dts)) return; break; } case GSF_INDUSTRIES: { if (type > 2) { grfmsg(1, "NewSpriteGroup: Unsupported industry production version %d, skipping", type); break; } assert(IndustryProductionSpriteGroup::CanAllocateItem()); IndustryProductionSpriteGroup *group = new IndustryProductionSpriteGroup(); group->nfo_line = _cur.nfo_line; if (_action6_override_active) group->sg_flags |= SGF_ACTION6; act_group = group; group->version = type; if (type == 0) { group->num_input = 3; for (uint i = 0; i < 3; i++) { group->subtract_input[i] = (int16)buf->ReadWord(); // signed } group->num_output = 2; for (uint i = 0; i < 2; i++) { group->add_output[i] = buf->ReadWord(); // unsigned } group->again = buf->ReadByte(); } else if (type == 1) { group->num_input = 3; for (uint i = 0; i < 3; i++) { group->subtract_input[i] = buf->ReadByte(); } group->num_output = 2; for (uint i = 0; i < 2; i++) { group->add_output[i] = buf->ReadByte(); } group->again = buf->ReadByte(); } else if (type == 2) { group->num_input = buf->ReadByte(); if (group->num_input > lengthof(group->subtract_input)) { GRFError *error = DisableGrf(STR_NEWGRF_ERROR_INDPROD_CALLBACK); error->data = "too many inputs (max 16)"; return; } for (uint i = 0; i < group->num_input; i++) { byte rawcargo = buf->ReadByte(); CargoID cargo = GetCargoTranslation(rawcargo, _cur.grffile); if (cargo == CT_INVALID) { /* The mapped cargo is invalid. This is permitted at this point, * as long as the result is not used. Mark it invalid so this * can be tested later. */ group->version = 0xFF; } else if (std::find(group->cargo_input, group->cargo_input + i, cargo) != group->cargo_input + i) { GRFError *error = DisableGrf(STR_NEWGRF_ERROR_INDPROD_CALLBACK); error->data = "duplicate input cargo"; return; } group->cargo_input[i] = cargo; group->subtract_input[i] = buf->ReadByte(); } group->num_output = buf->ReadByte(); if (group->num_output > lengthof(group->add_output)) { GRFError *error = DisableGrf(STR_NEWGRF_ERROR_INDPROD_CALLBACK); error->data = "too many outputs (max 16)"; return; } for (uint i = 0; i < group->num_output; i++) { byte rawcargo = buf->ReadByte(); CargoID cargo = GetCargoTranslation(rawcargo, _cur.grffile); if (cargo == CT_INVALID) { /* Mark this result as invalid to use */ group->version = 0xFF; } else if (std::find(group->cargo_output, group->cargo_output + i, cargo) != group->cargo_output + i) { GRFError *error = DisableGrf(STR_NEWGRF_ERROR_INDPROD_CALLBACK); error->data = "duplicate output cargo"; return; } group->cargo_output[i] = cargo; group->add_output[i] = buf->ReadByte(); } group->again = buf->ReadByte(); } else { NOT_REACHED(); } break; } /* Loading of Tile Layout and Production Callback groups would happen here */ default: grfmsg(1, "NewSpriteGroup: Unsupported feature %s, skipping", GetFeatureString(feature)); } } } _cur.spritegroups[setid] = act_group; } static CargoID TranslateCargo(uint8 feature, uint8 ctype) { if (feature == GSF_OBJECTS) { switch (ctype) { case 0: return 0; case 0xFF: return CT_PURCHASE_OBJECT; default: grfmsg(1, "TranslateCargo: Invalid cargo bitnum %d for objects, skipping.", ctype); return CT_INVALID; } } /* Special cargo types for purchase list and stations */ if ((feature == GSF_STATIONS || feature == GSF_ROADSTOPS) && ctype == 0xFE) return CT_DEFAULT_NA; if (ctype == 0xFF) return CT_PURCHASE; if (_cur.grffile->cargo_list.size() == 0) { /* No cargo table, so use bitnum values */ if (ctype >= 32) { grfmsg(1, "TranslateCargo: Cargo bitnum %d out of range (max 31), skipping.", ctype); return CT_INVALID; } for (const CargoSpec *cs : CargoSpec::Iterate()) { if (cs->bitnum == ctype) { grfmsg(6, "TranslateCargo: Cargo bitnum %d mapped to cargo type %d.", ctype, cs->Index()); return cs->Index(); } } grfmsg(5, "TranslateCargo: Cargo bitnum %d not available in this climate, skipping.", ctype); return CT_INVALID; } /* Check if the cargo type is out of bounds of the cargo translation table */ if (ctype >= _cur.grffile->cargo_list.size()) { grfmsg(1, "TranslateCargo: Cargo type %d out of range (max %d), skipping.", ctype, (unsigned int)_cur.grffile->cargo_list.size() - 1); return CT_INVALID; } /* Look up the cargo label from the translation table */ CargoLabel cl = _cur.grffile->cargo_list[ctype]; if (cl == 0) { grfmsg(5, "TranslateCargo: Cargo type %d not available in this climate, skipping.", ctype); return CT_INVALID; } ctype = GetCargoIDByLabel(cl); if (ctype == CT_INVALID) { grfmsg(5, "TranslateCargo: Cargo '%c%c%c%c' unsupported, skipping.", GB(cl, 24, 8), GB(cl, 16, 8), GB(cl, 8, 8), GB(cl, 0, 8)); return CT_INVALID; } grfmsg(6, "TranslateCargo: Cargo '%c%c%c%c' mapped to cargo type %d.", GB(cl, 24, 8), GB(cl, 16, 8), GB(cl, 8, 8), GB(cl, 0, 8), ctype); return ctype; } static bool IsValidGroupID(uint16 groupid, const char *function) { if (groupid > MAX_SPRITEGROUP || _cur.spritegroups[groupid] == nullptr) { grfmsg(1, "%s: Spritegroup 0x%04X out of range or empty, skipping.", function, groupid); return false; } return true; } static void VehicleMapSpriteGroup(ByteReader *buf, byte feature, uint8 idcount) { static EngineID *last_engines; static uint last_engines_count; bool wagover = false; /* Test for 'wagon override' flag */ if (HasBit(idcount, 7)) { wagover = true; /* Strip off the flag */ idcount = GB(idcount, 0, 7); if (last_engines_count == 0) { grfmsg(0, "VehicleMapSpriteGroup: WagonOverride: No engine to do override with"); return; } grfmsg(6, "VehicleMapSpriteGroup: WagonOverride: %u engines, %u wagons", last_engines_count, idcount); } else { if (last_engines_count != idcount) { last_engines = ReallocT(last_engines, idcount); last_engines_count = idcount; } } EngineID *engines = AllocaM(EngineID, idcount); for (uint i = 0; i < idcount; i++) { Engine *e = GetNewEngine(_cur.grffile, (VehicleType)feature, buf->ReadExtendedByte()); if (e == nullptr) { /* No engine could be allocated?!? Deal with it. Okay, * this might look bad. Also make sure this NewGRF * gets disabled, as a half loaded one is bad. */ HandleChangeInfoResult("VehicleMapSpriteGroup", CIR_INVALID_ID, (GrfSpecFeature)0, 0); return; } engines[i] = e->index; if (!wagover) last_engines[i] = engines[i]; } uint8 cidcount = buf->ReadByte(); for (uint c = 0; c < cidcount; c++) { uint8 ctype = buf->ReadByte(); uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "VehicleMapSpriteGroup")) continue; grfmsg(8, "VehicleMapSpriteGroup: * [%d] Cargo type 0x%X, group id 0x%02X", c, ctype, groupid); ctype = TranslateCargo(feature, ctype); if (ctype == CT_INVALID) continue; for (uint i = 0; i < idcount; i++) { EngineID engine = engines[i]; grfmsg(7, "VehicleMapSpriteGroup: [%d] Engine %d...", i, engine); if (wagover) { SetWagonOverrideSprites(engine, ctype, GetGroupByID(groupid), last_engines, last_engines_count); } else { SetCustomEngineSprites(engine, ctype, GetGroupByID(groupid)); } } } uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "VehicleMapSpriteGroup")) return; grfmsg(8, "-- Default group id 0x%04X", groupid); for (uint i = 0; i < idcount; i++) { EngineID engine = engines[i]; if (wagover) { SetWagonOverrideSprites(engine, CT_DEFAULT, GetGroupByID(groupid), last_engines, last_engines_count); } else { SetCustomEngineSprites(engine, CT_DEFAULT, GetGroupByID(groupid)); SetEngineGRF(engine, _cur.grffile); } } } static void CanalMapSpriteGroup(ByteReader *buf, uint8 idcount) { CanalFeature *cfs = AllocaM(CanalFeature, idcount); for (uint i = 0; i < idcount; i++) { cfs[i] = (CanalFeature)buf->ReadByte(); } uint8 cidcount = buf->ReadByte(); buf->Skip(cidcount * 3); uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "CanalMapSpriteGroup")) return; for (uint i = 0; i < idcount; i++) { CanalFeature cf = cfs[i]; if (cf >= CF_END) { grfmsg(1, "CanalMapSpriteGroup: Canal subset %d out of range, skipping", cf); continue; } _water_feature[cf].grffile = _cur.grffile; _water_feature[cf].group = GetGroupByID(groupid); } } static void StationMapSpriteGroup(ByteReader *buf, uint8 idcount) { uint8 *stations = AllocaM(uint8, idcount); for (uint i = 0; i < idcount; i++) { stations[i] = buf->ReadByte(); } uint8 cidcount = buf->ReadByte(); for (uint c = 0; c < cidcount; c++) { uint8 ctype = buf->ReadByte(); uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "StationMapSpriteGroup")) continue; ctype = TranslateCargo(GSF_STATIONS, ctype); if (ctype == CT_INVALID) continue; for (uint i = 0; i < idcount; i++) { StationSpec *statspec = _cur.grffile->stations == nullptr ? nullptr : _cur.grffile->stations[stations[i]]; if (statspec == nullptr) { grfmsg(1, "StationMapSpriteGroup: Station with ID 0x%02X does not exist, skipping", stations[i]); continue; } statspec->grf_prop.spritegroup[ctype] = GetGroupByID(groupid); } } uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "StationMapSpriteGroup")) return; for (uint i = 0; i < idcount; i++) { StationSpec *statspec = _cur.grffile->stations == nullptr ? nullptr : _cur.grffile->stations[stations[i]]; if (statspec == nullptr) { grfmsg(1, "StationMapSpriteGroup: Station with ID 0x%02X does not exist, skipping", stations[i]); continue; } if (statspec->grf_prop.grffile != nullptr) { grfmsg(1, "StationMapSpriteGroup: Station with ID 0x%02X mapped multiple times, skipping", stations[i]); continue; } statspec->grf_prop.spritegroup[CT_DEFAULT] = GetGroupByID(groupid); statspec->grf_prop.grffile = _cur.grffile; statspec->grf_prop.local_id = stations[i]; StationClass::Assign(statspec); } } static void TownHouseMapSpriteGroup(ByteReader *buf, uint8 idcount) { uint8 *houses = AllocaM(uint8, idcount); for (uint i = 0; i < idcount; i++) { houses[i] = buf->ReadByte(); } /* Skip the cargo type section, we only care about the default group */ uint8 cidcount = buf->ReadByte(); buf->Skip(cidcount * 3); uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "TownHouseMapSpriteGroup")) return; if (_cur.grffile->housespec == nullptr) { grfmsg(1, "TownHouseMapSpriteGroup: No houses defined, skipping"); return; } for (uint i = 0; i < idcount; i++) { HouseSpec *hs = _cur.grffile->housespec[houses[i]]; if (hs == nullptr) { grfmsg(1, "TownHouseMapSpriteGroup: House %d undefined, skipping.", houses[i]); continue; } hs->grf_prop.spritegroup[0] = GetGroupByID(groupid); } } static void IndustryMapSpriteGroup(ByteReader *buf, uint8 idcount) { uint8 *industries = AllocaM(uint8, idcount); for (uint i = 0; i < idcount; i++) { industries[i] = buf->ReadByte(); } /* Skip the cargo type section, we only care about the default group */ uint8 cidcount = buf->ReadByte(); buf->Skip(cidcount * 3); uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "IndustryMapSpriteGroup")) return; if (_cur.grffile->industryspec == nullptr) { grfmsg(1, "IndustryMapSpriteGroup: No industries defined, skipping"); return; } for (uint i = 0; i < idcount; i++) { IndustrySpec *indsp = _cur.grffile->industryspec[industries[i]]; if (indsp == nullptr) { grfmsg(1, "IndustryMapSpriteGroup: Industry %d undefined, skipping", industries[i]); continue; } indsp->grf_prop.spritegroup[0] = GetGroupByID(groupid); } } static void IndustrytileMapSpriteGroup(ByteReader *buf, uint8 idcount) { uint8 *indtiles = AllocaM(uint8, idcount); for (uint i = 0; i < idcount; i++) { indtiles[i] = buf->ReadByte(); } /* Skip the cargo type section, we only care about the default group */ uint8 cidcount = buf->ReadByte(); buf->Skip(cidcount * 3); uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "IndustrytileMapSpriteGroup")) return; if (_cur.grffile->indtspec == nullptr) { grfmsg(1, "IndustrytileMapSpriteGroup: No industry tiles defined, skipping"); return; } for (uint i = 0; i < idcount; i++) { IndustryTileSpec *indtsp = _cur.grffile->indtspec[indtiles[i]]; if (indtsp == nullptr) { grfmsg(1, "IndustrytileMapSpriteGroup: Industry tile %d undefined, skipping", indtiles[i]); continue; } indtsp->grf_prop.spritegroup[0] = GetGroupByID(groupid); } } static void CargoMapSpriteGroup(ByteReader *buf, uint8 idcount) { CargoID *cargoes = AllocaM(CargoID, idcount); for (uint i = 0; i < idcount; i++) { cargoes[i] = buf->ReadByte(); } /* Skip the cargo type section, we only care about the default group */ uint8 cidcount = buf->ReadByte(); buf->Skip(cidcount * 3); uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "CargoMapSpriteGroup")) return; for (uint i = 0; i < idcount; i++) { CargoID cid = cargoes[i]; if (cid >= NUM_CARGO) { grfmsg(1, "CargoMapSpriteGroup: Cargo ID %d out of range, skipping", cid); continue; } CargoSpec *cs = CargoSpec::Get(cid); cs->grffile = _cur.grffile; cs->group = GetGroupByID(groupid); } } static void SignalsMapSpriteGroup(ByteReader *buf, uint8 idcount) { uint8 *ids = AllocaM(uint8, idcount); for (uint i = 0; i < idcount; i++) { ids[i] = buf->ReadByte(); } /* Skip the cargo type section, we only care about the default group */ uint8 cidcount = buf->ReadByte(); buf->Skip(cidcount * 3); uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "SignalsMapSpriteGroup")) return; for (uint i = 0; i < idcount; i++) { uint8 id = ids[i]; switch (id) { case NSA3ID_CUSTOM_SIGNALS: _cur.grffile->new_signals_group = GetGroupByID(groupid); if (!HasBit(_cur.grffile->new_signal_ctrl_flags, NSCF_GROUPSET)) { SetBit(_cur.grffile->new_signal_ctrl_flags, NSCF_GROUPSET); _new_signals_grfs.push_back(_cur.grffile); } break; default: grfmsg(1, "SignalsMapSpriteGroup: ID not implemented: %d", id); break; } } } static void ObjectMapSpriteGroup(ByteReader *buf, uint8 idcount) { if (_cur.grffile->objectspec == nullptr) { grfmsg(1, "ObjectMapSpriteGroup: No object tiles defined, skipping"); return; } uint8 *objects = AllocaM(uint8, idcount); for (uint i = 0; i < idcount; i++) { objects[i] = buf->ReadByte(); } uint8 cidcount = buf->ReadByte(); for (uint c = 0; c < cidcount; c++) { uint8 ctype = buf->ReadByte(); uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "ObjectMapSpriteGroup")) continue; ctype = TranslateCargo(GSF_OBJECTS, ctype); if (ctype == CT_INVALID) continue; for (uint i = 0; i < idcount; i++) { ObjectSpec *spec = _cur.grffile->objectspec[objects[i]]; if (spec == nullptr) { grfmsg(1, "ObjectMapSpriteGroup: Object with ID 0x%02X undefined, skipping", objects[i]); continue; } spec->grf_prop.spritegroup[ctype] = GetGroupByID(groupid); } } uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "ObjectMapSpriteGroup")) return; for (uint i = 0; i < idcount; i++) { ObjectSpec *spec = _cur.grffile->objectspec[objects[i]]; if (spec == nullptr) { grfmsg(1, "ObjectMapSpriteGroup: Object with ID 0x%02X undefined, skipping", objects[i]); continue; } if (spec->grf_prop.grffile != nullptr) { grfmsg(1, "ObjectMapSpriteGroup: Object with ID 0x%02X mapped multiple times, skipping", objects[i]); continue; } spec->grf_prop.spritegroup[0] = GetGroupByID(groupid); spec->grf_prop.grffile = _cur.grffile; spec->grf_prop.local_id = objects[i]; } } static void RailTypeMapSpriteGroup(ByteReader *buf, uint8 idcount) { uint8 *railtypes = AllocaM(uint8, idcount); for (uint i = 0; i < idcount; i++) { uint8 id = buf->ReadByte(); railtypes[i] = id < RAILTYPE_END ? _cur.grffile->railtype_map[id] : INVALID_RAILTYPE; } uint8 cidcount = buf->ReadByte(); for (uint c = 0; c < cidcount; c++) { uint8 ctype = buf->ReadByte(); uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "RailTypeMapSpriteGroup")) continue; if (ctype >= RTSG_END) continue; extern RailtypeInfo _railtypes[RAILTYPE_END]; for (uint i = 0; i < idcount; i++) { if (railtypes[i] != INVALID_RAILTYPE) { RailtypeInfo *rti = &_railtypes[railtypes[i]]; rti->grffile[ctype] = _cur.grffile; rti->group[ctype] = GetGroupByID(groupid); } } } /* Railtypes do not use the default group. */ buf->ReadWord(); } static void RoadTypeMapSpriteGroup(ByteReader *buf, uint8 idcount, RoadTramType rtt) { RoadType *type_map = (rtt == RTT_TRAM) ? _cur.grffile->tramtype_map : _cur.grffile->roadtype_map; uint8 *roadtypes = AllocaM(uint8, idcount); for (uint i = 0; i < idcount; i++) { uint8 id = buf->ReadByte(); roadtypes[i] = id < ROADTYPE_END ? type_map[id] : INVALID_ROADTYPE; } uint8 cidcount = buf->ReadByte(); for (uint c = 0; c < cidcount; c++) { uint8 ctype = buf->ReadByte(); uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "RoadTypeMapSpriteGroup")) continue; if (ctype >= ROTSG_END) continue; extern RoadTypeInfo _roadtypes[ROADTYPE_END]; for (uint i = 0; i < idcount; i++) { if (roadtypes[i] != INVALID_ROADTYPE) { RoadTypeInfo *rti = &_roadtypes[roadtypes[i]]; rti->grffile[ctype] = _cur.grffile; rti->group[ctype] = GetGroupByID(groupid); } } } /* Roadtypes do not use the default group. */ buf->ReadWord(); } static void AirportMapSpriteGroup(ByteReader *buf, uint8 idcount) { uint8 *airports = AllocaM(uint8, idcount); for (uint i = 0; i < idcount; i++) { airports[i] = buf->ReadByte(); } /* Skip the cargo type section, we only care about the default group */ uint8 cidcount = buf->ReadByte(); buf->Skip(cidcount * 3); uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "AirportMapSpriteGroup")) return; if (_cur.grffile->airportspec == nullptr) { grfmsg(1, "AirportMapSpriteGroup: No airports defined, skipping"); return; } for (uint i = 0; i < idcount; i++) { AirportSpec *as = _cur.grffile->airportspec[airports[i]]; if (as == nullptr) { grfmsg(1, "AirportMapSpriteGroup: Airport %d undefined, skipping", airports[i]); continue; } as->grf_prop.spritegroup[0] = GetGroupByID(groupid); } } static void AirportTileMapSpriteGroup(ByteReader *buf, uint8 idcount) { uint8 *airptiles = AllocaM(uint8, idcount); for (uint i = 0; i < idcount; i++) { airptiles[i] = buf->ReadByte(); } /* Skip the cargo type section, we only care about the default group */ uint8 cidcount = buf->ReadByte(); buf->Skip(cidcount * 3); uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "AirportTileMapSpriteGroup")) return; if (_cur.grffile->airtspec == nullptr) { grfmsg(1, "AirportTileMapSpriteGroup: No airport tiles defined, skipping"); return; } for (uint i = 0; i < idcount; i++) { AirportTileSpec *airtsp = _cur.grffile->airtspec[airptiles[i]]; if (airtsp == nullptr) { grfmsg(1, "AirportTileMapSpriteGroup: Airport tile %d undefined, skipping", airptiles[i]); continue; } airtsp->grf_prop.spritegroup[0] = GetGroupByID(groupid); } } static void RoadStopMapSpriteGroup(ByteReader *buf, uint8 idcount) { uint8 *roadstops = AllocaM(uint8, idcount); for (uint i = 0; i < idcount; i++) { roadstops[i] = buf->ReadByte(); } uint8 cidcount = buf->ReadByte(); for (uint c = 0; c < cidcount; c++) { uint8 ctype = buf->ReadByte(); uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "RoadStopMapSpriteGroup")) continue; ctype = TranslateCargo(GSF_ROADSTOPS, ctype); if (ctype == CT_INVALID) continue; for (uint i = 0; i < idcount; i++) { RoadStopSpec *roadstopspec = _cur.grffile->roadstops == nullptr ? nullptr : _cur.grffile->roadstops[roadstops[i]]; if (roadstopspec == nullptr) { grfmsg(1, "RoadStopMapSpriteGroup: Road stop with ID 0x%02X does not exist, skipping", roadstops[i]); continue; } roadstopspec->grf_prop.spritegroup[ctype] = GetGroupByID(groupid); } } uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "RoadStopMapSpriteGroup")) return; if (_cur.grffile->roadstops == nullptr) { grfmsg(0, "RoadStopMapSpriteGroup: No roadstops defined, skipping."); return; } for (uint i = 0; i < idcount; i++) { RoadStopSpec *roadstopspec = _cur.grffile->roadstops == nullptr ? nullptr : _cur.grffile->roadstops[roadstops[i]]; if (roadstopspec == nullptr) { grfmsg(1, "RoadStopMapSpriteGroup: Road stop with ID 0x%02X does not exist, skipping.", roadstops[i]); continue; } if (roadstopspec->grf_prop.grffile != nullptr) { grfmsg(1, "RoadStopMapSpriteGroup: Road stop with ID 0x%02X mapped multiple times, skipping", roadstops[i]); continue; } roadstopspec->grf_prop.spritegroup[CT_DEFAULT] = GetGroupByID(groupid); roadstopspec->grf_prop.grffile = _cur.grffile; roadstopspec->grf_prop.local_id = roadstops[i]; RoadStopClass::Assign(roadstopspec); } } static void NewLandscapeMapSpriteGroup(ByteReader *buf, uint8 idcount) { uint8 *ids = AllocaM(uint8, idcount); for (uint i = 0; i < idcount; i++) { ids[i] = buf->ReadByte(); } /* Skip the cargo type section, we only care about the default group */ uint8 cidcount = buf->ReadByte(); buf->Skip(cidcount * 3); uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "NewLandscapeMapSpriteGroup")) return; for (uint i = 0; i < idcount; i++) { uint8 id = ids[i]; switch (id) { case NLA3ID_CUSTOM_ROCKS: _cur.grffile->new_rocks_group = GetGroupByID(groupid); if (!HasBit(_cur.grffile->new_landscape_ctrl_flags, NLCF_ROCKS_SET)) { SetBit(_cur.grffile->new_landscape_ctrl_flags, NLCF_ROCKS_SET); _new_landscape_rocks_grfs.push_back(_cur.grffile); } break; default: grfmsg(1, "NewLandscapeMapSpriteGroup: ID not implemented: %d", id); break; } } } /* Action 0x03 */ static void FeatureMapSpriteGroup(ByteReader *buf) { /* <03>

... [ ]... * id-list := [] [id-list] * cargo-list := [cargo-list] * * B feature see action 0 * B n-id bits 0-6: how many IDs this definition applies to * bit 7: if set, this is a wagon override definition (see below) * B ids the IDs for which this definition applies * B num-cid number of cargo IDs (sprite group IDs) in this definition * can be zero, in that case the def-cid is used always * B cargo-type type of this cargo type (e.g. mail=2, wood=7, see below) * W cid cargo ID (sprite group ID) for this type of cargo * W def-cid default cargo ID (sprite group ID) */ GrfSpecFeatureRef feature_ref = ReadFeature(buf->ReadByte()); GrfSpecFeature feature = feature_ref.id; uint8 idcount = buf->ReadByte(); if (feature >= GSF_END) { grfmsg(1, "FeatureMapSpriteGroup: Unsupported feature %s, skipping", GetFeatureString(feature_ref)); return; } /* If idcount is zero, this is a feature callback */ if (idcount == 0) { /* Skip number of cargo ids? */ buf->ReadByte(); uint16 groupid = buf->ReadWord(); if (!IsValidGroupID(groupid, "FeatureMapSpriteGroup")) return; grfmsg(6, "FeatureMapSpriteGroup: Adding generic feature callback for feature %s", GetFeatureString(feature_ref)); AddGenericCallback(feature, _cur.grffile, GetGroupByID(groupid)); return; } /* Mark the feature as used by the grf (generic callbacks do not count) */ SetBit(_cur.grffile->grf_features, feature); grfmsg(6, "FeatureMapSpriteGroup: Feature %s, %d ids", GetFeatureString(feature_ref), idcount); switch (feature) { case GSF_TRAINS: case GSF_ROADVEHICLES: case GSF_SHIPS: case GSF_AIRCRAFT: VehicleMapSpriteGroup(buf, feature, idcount); return; case GSF_CANALS: CanalMapSpriteGroup(buf, idcount); return; case GSF_STATIONS: StationMapSpriteGroup(buf, idcount); return; case GSF_HOUSES: TownHouseMapSpriteGroup(buf, idcount); return; case GSF_INDUSTRIES: IndustryMapSpriteGroup(buf, idcount); return; case GSF_INDUSTRYTILES: IndustrytileMapSpriteGroup(buf, idcount); return; case GSF_CARGOES: CargoMapSpriteGroup(buf, idcount); return; case GSF_AIRPORTS: AirportMapSpriteGroup(buf, idcount); return; case GSF_SIGNALS: SignalsMapSpriteGroup(buf, idcount); break; case GSF_OBJECTS: ObjectMapSpriteGroup(buf, idcount); break; case GSF_RAILTYPES: RailTypeMapSpriteGroup(buf, idcount); break; case GSF_ROADTYPES: RoadTypeMapSpriteGroup(buf, idcount, RTT_ROAD); break; case GSF_TRAMTYPES: RoadTypeMapSpriteGroup(buf, idcount, RTT_TRAM); break; case GSF_AIRPORTTILES: AirportTileMapSpriteGroup(buf, idcount); return; case GSF_ROADSTOPS: RoadStopMapSpriteGroup(buf, idcount); return; case GSF_NEWLANDSCAPE: NewLandscapeMapSpriteGroup(buf, idcount); return; default: grfmsg(1, "FeatureMapSpriteGroup: Unsupported feature %s, skipping", GetFeatureString(feature_ref)); return; } } /* Action 0x04 */ static void FeatureNewName(ByteReader *buf) { /* <04>

* * B veh-type see action 0 (as 00..07, + 0A * But IF veh-type = 48, then generic text * B language-id If bit 6 is set, This is the extended language scheme, * with up to 64 language. * Otherwise, it is a mapping where set bits have meaning * 0 = american, 1 = english, 2 = german, 3 = french, 4 = spanish * Bit 7 set means this is a generic text, not a vehicle one (or else) * B num-veh number of vehicles which are getting a new name * B/W offset number of the first vehicle that gets a new name * Byte : ID of vehicle to change * Word : ID of string to change/add * S data new texts, each of them zero-terminated, after * which the next name begins. */ bool new_scheme = _cur.grffile->grf_version >= 7; GrfSpecFeatureRef feature_ref = ReadFeature(buf->ReadByte(), true); GrfSpecFeature feature = feature_ref.id; if (feature >= GSF_END && feature != 0x48) { grfmsg(1, "FeatureNewName: Unsupported feature %s, skipping", GetFeatureString(feature_ref)); return; } uint8 lang = buf->ReadByte(); uint8 num = buf->ReadByte(); bool generic = HasBit(lang, 7); uint16 id; if (generic) { id = buf->ReadWord(); } else if (feature <= GSF_AIRCRAFT) { id = buf->ReadExtendedByte(); } else { id = buf->ReadByte(); } ClrBit(lang, 7); uint16 endid = id + num; grfmsg(6, "FeatureNewName: About to rename engines %d..%d (feature %s) in language 0x%02X", id, endid, GetFeatureString(feature), lang); for (; id < endid && buf->HasData(); id++) { const char *name = buf->ReadString(); grfmsg(8, "FeatureNewName: 0x%04X <- %s", id, name); switch (feature) { case GSF_TRAINS: case GSF_ROADVEHICLES: case GSF_SHIPS: case GSF_AIRCRAFT: if (!generic) { Engine *e = GetNewEngine(_cur.grffile, (VehicleType)feature, id, HasBit(_cur.grfconfig->flags, GCF_STATIC)); if (e == nullptr) break; StringID string = AddGRFString(_cur.grffile->grfid, e->index, lang, new_scheme, false, name, e->info.string_id); e->info.string_id = string; } else { AddGRFString(_cur.grffile->grfid, id, lang, new_scheme, true, name, STR_UNDEFINED); } break; default: if (IsInsideMM(id, 0xD000, 0xD400) || IsInsideMM(id, 0xD800, 0xE000)) { AddGRFString(_cur.grffile->grfid, id, lang, new_scheme, true, name, STR_UNDEFINED); break; } switch (GB(id, 8, 8)) { case 0xC4: // Station class name if (_cur.grffile->stations == nullptr || _cur.grffile->stations[GB(id, 0, 8)] == nullptr) { grfmsg(1, "FeatureNewName: Attempt to name undefined station 0x%X, ignoring", GB(id, 0, 8)); } else { StationClassID cls_id = _cur.grffile->stations[GB(id, 0, 8)]->cls_id; StationClass::Get(cls_id)->name = AddGRFString(_cur.grffile->grfid, id, lang, new_scheme, false, name, STR_UNDEFINED); } break; case 0xC5: // Station name if (_cur.grffile->stations == nullptr || _cur.grffile->stations[GB(id, 0, 8)] == nullptr) { grfmsg(1, "FeatureNewName: Attempt to name undefined station 0x%X, ignoring", GB(id, 0, 8)); } else { _cur.grffile->stations[GB(id, 0, 8)]->name = AddGRFString(_cur.grffile->grfid, id, lang, new_scheme, false, name, STR_UNDEFINED); } break; case 0xC7: // Airporttile name if (_cur.grffile->airtspec == nullptr || _cur.grffile->airtspec[GB(id, 0, 8)] == nullptr) { grfmsg(1, "FeatureNewName: Attempt to name undefined airport tile 0x%X, ignoring", GB(id, 0, 8)); } else { _cur.grffile->airtspec[GB(id, 0, 8)]->name = AddGRFString(_cur.grffile->grfid, id, lang, new_scheme, false, name, STR_UNDEFINED); } break; case 0xC9: // House name if (_cur.grffile->housespec == nullptr || _cur.grffile->housespec[GB(id, 0, 8)] == nullptr) { grfmsg(1, "FeatureNewName: Attempt to name undefined house 0x%X, ignoring.", GB(id, 0, 8)); } else { _cur.grffile->housespec[GB(id, 0, 8)]->building_name = AddGRFString(_cur.grffile->grfid, id, lang, new_scheme, false, name, STR_UNDEFINED); } break; default: grfmsg(7, "FeatureNewName: Unsupported ID (0x%04X)", id); break; } break; } } } /** * Sanitize incoming sprite offsets for Action 5 graphics replacements. * @param num The number of sprites to load. * @param offset Offset from the base. * @param max_sprites The maximum number of sprites that can be loaded in this action 5. * @param name Used for error warnings. * @return The number of sprites that is going to be skipped. */ static uint16 SanitizeSpriteOffset(uint16& num, uint16 offset, int max_sprites, const char *name) { if (offset >= max_sprites) { grfmsg(1, "GraphicsNew: %s sprite offset must be less than %i, skipping", name, max_sprites); uint orig_num = num; num = 0; return orig_num; } if (offset + num > max_sprites) { grfmsg(4, "GraphicsNew: %s sprite overflow, truncating...", name); uint orig_num = num; num = std::max(max_sprites - offset, 0); return orig_num - num; } return 0; } /** The information about action 5 types. */ static const Action5Type _action5_types[] = { /* Note: min_sprites should not be changed. Therefore these constants are directly here and not in sprites.h */ /* 0x00 */ { A5BLOCK_INVALID, 0, 0, 0, "Type 0x00" }, /* 0x01 */ { A5BLOCK_INVALID, 0, 0, 0, "Type 0x01" }, /* 0x02 */ { A5BLOCK_INVALID, 0, 0, 0, "Type 0x02" }, /* 0x03 */ { A5BLOCK_INVALID, 0, 0, 0, "Type 0x03" }, /* 0x04 */ { A5BLOCK_ALLOW_OFFSET, SPR_SIGNALS_BASE, 1, PRESIGNAL_SEMAPHORE_AND_PBS_SPRITE_COUNT, "Signal graphics" }, /* 0x05 */ { A5BLOCK_ALLOW_OFFSET, SPR_ELRAIL_BASE, 1, ELRAIL_SPRITE_COUNT, "Rail catenary graphics" }, /* 0x06 */ { A5BLOCK_ALLOW_OFFSET, SPR_SLOPES_BASE, 1, NORMAL_AND_HALFTILE_FOUNDATION_SPRITE_COUNT, "Foundation graphics" }, /* 0x07 */ { A5BLOCK_INVALID, 0, 75, 0, "TTDP GUI graphics" }, // Not used by OTTD. /* 0x08 */ { A5BLOCK_ALLOW_OFFSET, SPR_CANALS_BASE, 1, CANALS_SPRITE_COUNT, "Canal graphics" }, /* 0x09 */ { A5BLOCK_ALLOW_OFFSET, SPR_ONEWAY_BASE, 1, ONEWAY_SPRITE_COUNT, "One way road graphics" }, /* 0x0A */ { A5BLOCK_ALLOW_OFFSET, SPR_2CCMAP_BASE, 1, TWOCCMAP_SPRITE_COUNT, "2CC colour maps" }, /* 0x0B */ { A5BLOCK_ALLOW_OFFSET, SPR_TRAMWAY_BASE, 1, TRAMWAY_SPRITE_COUNT, "Tramway graphics" }, /* 0x0C */ { A5BLOCK_INVALID, 0, 133, 0, "Snowy temperate tree" }, // Not yet used by OTTD. /* 0x0D */ { A5BLOCK_FIXED, SPR_SHORE_BASE, 16, SPR_SHORE_SPRITE_COUNT, "Shore graphics" }, /* 0x0E */ { A5BLOCK_INVALID, 0, 0, 0, "New Signals graphics" }, // Not yet used by OTTD. /* 0x0F */ { A5BLOCK_ALLOW_OFFSET, SPR_TRACKS_FOR_SLOPES_BASE, 1, TRACKS_FOR_SLOPES_SPRITE_COUNT, "Sloped rail track" }, /* 0x10 */ { A5BLOCK_ALLOW_OFFSET, SPR_AIRPORTX_BASE, 1, AIRPORTX_SPRITE_COUNT, "Airport graphics" }, /* 0x11 */ { A5BLOCK_ALLOW_OFFSET, SPR_ROADSTOP_BASE, 1, ROADSTOP_SPRITE_COUNT, "Road stop graphics" }, /* 0x12 */ { A5BLOCK_ALLOW_OFFSET, SPR_AQUEDUCT_BASE, 1, AQUEDUCT_SPRITE_COUNT, "Aqueduct graphics" }, /* 0x13 */ { A5BLOCK_ALLOW_OFFSET, SPR_AUTORAIL_BASE, 1, AUTORAIL_SPRITE_COUNT, "Autorail graphics" }, /* 0x14 */ { A5BLOCK_ALLOW_OFFSET, SPR_FLAGS_BASE, 1, FLAGS_SPRITE_COUNT, "Flag graphics" }, /* 0x15 */ { A5BLOCK_ALLOW_OFFSET, SPR_OPENTTD_BASE, 1, OPENTTD_SPRITE_COUNT, "OpenTTD GUI graphics" }, /* 0x16 */ { A5BLOCK_ALLOW_OFFSET, SPR_AIRPORT_PREVIEW_BASE, 1, SPR_AIRPORT_PREVIEW_COUNT, "Airport preview graphics" }, /* 0x17 */ { A5BLOCK_ALLOW_OFFSET, SPR_RAILTYPE_TUNNEL_BASE, 1, RAILTYPE_TUNNEL_BASE_COUNT, "Railtype tunnel base" }, /* 0x18 */ { A5BLOCK_ALLOW_OFFSET, SPR_PALETTE_BASE, 1, PALETTE_SPRITE_COUNT, "Palette" }, }; /* Action 0x05 */ static void GraphicsNew(ByteReader *buf) { /* <05>

* * B graphics-type What set of graphics the sprites define. * E num-sprites How many sprites are in this set? * V other data Graphics type specific data. Currently unused. */ uint8 type = buf->ReadByte(); uint16 num = buf->ReadExtendedByte(); uint16 offset = HasBit(type, 7) ? buf->ReadExtendedByte() : 0; ClrBit(type, 7); // Clear the high bit as that only indicates whether there is an offset. const Action5Type *action5_type; const Action5TypeRemapSet &remap = _cur.grffile->action5_type_remaps; if (remap.remapped_ids[type]) { auto iter = remap.mapping.find(type); assert(iter != remap.mapping.end()); const Action5TypeRemapEntry &def = iter->second; if (def.info == nullptr) { if (def.fallback_mode == GPMFM_ERROR_ON_USE) { grfmsg(0, "Error: Unimplemented action 5 type: %s, mapped to: %X", def.name, type); GRFError *error = DisableGrf(STR_NEWGRF_ERROR_UNIMPLEMETED_MAPPED_ACTION5_TYPE); error->data = stredup(def.name); error->param_value[1] = type; } else if (def.fallback_mode == GPMFM_IGNORE) { grfmsg(2, "Ignoring unimplemented action 5 type: %s, mapped to: %X", def.name, type); } _cur.skip_sprites = num; return; } else { action5_type = def.info; } } else { if ((type == 0x0D) && (num == 10) && HasBit(_cur.grfconfig->flags, GCF_SYSTEM)) { /* Special not-TTDP-compatible case used in openttd.grf * Missing shore sprites and initialisation of SPR_SHORE_BASE */ grfmsg(2, "GraphicsNew: Loading 10 missing shore sprites from extra grf."); LoadNextSprite(SPR_SHORE_BASE + 0, *_cur.file, _cur.nfo_line++); // SLOPE_STEEP_S LoadNextSprite(SPR_SHORE_BASE + 5, *_cur.file, _cur.nfo_line++); // SLOPE_STEEP_W LoadNextSprite(SPR_SHORE_BASE + 7, *_cur.file, _cur.nfo_line++); // SLOPE_WSE LoadNextSprite(SPR_SHORE_BASE + 10, *_cur.file, _cur.nfo_line++); // SLOPE_STEEP_N LoadNextSprite(SPR_SHORE_BASE + 11, *_cur.file, _cur.nfo_line++); // SLOPE_NWS LoadNextSprite(SPR_SHORE_BASE + 13, *_cur.file, _cur.nfo_line++); // SLOPE_ENW LoadNextSprite(SPR_SHORE_BASE + 14, *_cur.file, _cur.nfo_line++); // SLOPE_SEN LoadNextSprite(SPR_SHORE_BASE + 15, *_cur.file, _cur.nfo_line++); // SLOPE_STEEP_E LoadNextSprite(SPR_SHORE_BASE + 16, *_cur.file, _cur.nfo_line++); // SLOPE_EW LoadNextSprite(SPR_SHORE_BASE + 17, *_cur.file, _cur.nfo_line++); // SLOPE_NS if (_loaded_newgrf_features.shore == SHORE_REPLACE_NONE) _loaded_newgrf_features.shore = SHORE_REPLACE_ONLY_NEW; return; } /* Supported type? */ if ((type >= lengthof(_action5_types)) || (_action5_types[type].block_type == A5BLOCK_INVALID)) { grfmsg(2, "GraphicsNew: Custom graphics (type 0x%02X) sprite block of length %u (unimplemented, ignoring)", type, num); _cur.skip_sprites = num; return; } action5_type = &_action5_types[type]; } /* Contrary to TTDP we allow always to specify too few sprites as we allow always an offset, * except for the long version of the shore type: * Ignore offset if not allowed */ if ((action5_type->block_type != A5BLOCK_ALLOW_OFFSET) && (offset != 0)) { grfmsg(1, "GraphicsNew: %s (type 0x%02X) do not allow an field. Ignoring offset.", action5_type->name, type); offset = 0; } /* Ignore action5 if too few sprites are specified. (for TTDP compatibility) * This does not make sense, if is allowed */ if ((action5_type->block_type == A5BLOCK_FIXED) && (num < action5_type->min_sprites)) { grfmsg(1, "GraphicsNew: %s (type 0x%02X) count must be at least %d. Only %d were specified. Skipping.", action5_type->name, type, action5_type->min_sprites, num); _cur.skip_sprites = num; return; } /* Load at most max_sprites sprites. Skip remaining sprites. (for compatibility with TTDP and future extensions) */ uint16 skip_num = SanitizeSpriteOffset(num, offset, action5_type->max_sprites, action5_type->name); SpriteID replace = action5_type->sprite_base + offset; /* Load sprites starting from , then skip sprites. */ grfmsg(2, "GraphicsNew: Replacing sprites %d to %d of %s (type 0x%02X) at SpriteID 0x%04X", offset, offset + num - 1, action5_type->name, type, replace); if (type == 0x0D) _loaded_newgrf_features.shore = SHORE_REPLACE_ACTION_5; if (type == 0x0B) { static const SpriteID depot_with_track_offset = SPR_TRAMWAY_DEPOT_WITH_TRACK - SPR_TRAMWAY_BASE; static const SpriteID depot_no_track_offset = SPR_TRAMWAY_DEPOT_NO_TRACK - SPR_TRAMWAY_BASE; if (offset <= depot_with_track_offset && offset + num > depot_with_track_offset) _loaded_newgrf_features.tram = TRAMWAY_REPLACE_DEPOT_WITH_TRACK; if (offset <= depot_no_track_offset && offset + num > depot_no_track_offset) _loaded_newgrf_features.tram = TRAMWAY_REPLACE_DEPOT_NO_TRACK; } for (uint16 n = num; n > 0; n--) { _cur.nfo_line++; LoadNextSprite(replace == 0 ? _cur.spriteid++ : replace++, *_cur.file, _cur.nfo_line); } if (type == 0x04 && ((_cur.grfconfig->ident.grfid & 0x00FFFFFF) == OPENTTD_GRAPHICS_BASE_GRF_ID || _cur.grfconfig->ident.grfid == BSWAP32(0xFF4F4701))) { /* Signal graphics action 5: Fill duplicate signal sprite block if this is a baseset GRF or OpenGFX */ const SpriteID end = offset + num; for (SpriteID i = offset; i < end; i++) { DupSprite(SPR_SIGNALS_BASE + i, SPR_DUP_SIGNALS_BASE + i); } } _cur.skip_sprites = skip_num; } /* Action 0x05 (SKIP) */ static void SkipAct5(ByteReader *buf) { /* Ignore type byte */ buf->ReadByte(); /* Skip the sprites of this action */ _cur.skip_sprites = buf->ReadExtendedByte(); grfmsg(3, "SkipAct5: Skipping %d sprites", _cur.skip_sprites); } /** * Reads a variable common to VarAction2 and Action7/9/D. * * Returns VarAction2 variable 'param' resp. Action7/9/D variable '0x80 + param'. * If a variable is not accessible from all four actions, it is handled in the action specific functions. * * @param param variable number (as for VarAction2, for Action7/9/D you have to subtract 0x80 first). * @param value returns the value of the variable. * @param grffile NewGRF querying the variable * @return true iff the variable is known and the value is returned in 'value'. */ bool GetGlobalVariable(byte param, uint32 *value, const GRFFile *grffile) { if (_sprite_group_resolve_check_veh_check) { switch (param) { case 0x00: case 0x02: case 0x09: case 0x0A: case 0x20: case 0x23: _sprite_group_resolve_check_veh_check = false; break; } } switch (param) { case 0x00: // current date *value = std::max(_date - DAYS_TILL_ORIGINAL_BASE_YEAR, 0); return true; case 0x01: // current year *value = Clamp(_cur_year, ORIGINAL_BASE_YEAR, ORIGINAL_MAX_YEAR) - ORIGINAL_BASE_YEAR; return true; case 0x02: { // detailed date information: month of year (bit 0-7), day of month (bit 8-12), leap year (bit 15), day of year (bit 16-24) Date start_of_year = ConvertYMDToDate(_cur_date_ymd.year, 0, 1); *value = _cur_date_ymd.month | (_cur_date_ymd.day - 1) << 8 | (IsLeapYear(_cur_date_ymd.year) ? 1 << 15 : 0) | (_date - start_of_year) << 16; return true; } case 0x03: // current climate, 0=temp, 1=arctic, 2=trop, 3=toyland *value = _settings_game.game_creation.landscape; return true; case 0x06: // road traffic side, bit 4 clear=left, set=right *value = _settings_game.vehicle.road_side << 4; return true; case 0x09: // date fraction *value = _date_fract * 885; return true; case 0x0A: // animation counter *value = _tick_counter; return true; case 0x0B: { // TTDPatch version uint major = 2; uint minor = 6; uint revision = 1; // special case: 2.0.1 is 2.0.10 uint build = 1382; *value = (major << 24) | (minor << 20) | (revision << 16) | build; return true; } case 0x0D: // TTD Version, 00=DOS, 01=Windows *value = (_cur.grfconfig->palette & GRFP_USE_MASK) | grffile->var8D_overlay; return true; case 0x0E: // Y-offset for train sprites *value = _cur.grffile->traininfo_vehicle_pitch; return true; case 0x0F: // Rail track type cost factors *value = 0; SB(*value, 0, 8, GetRailTypeInfo(RAILTYPE_RAIL)->cost_multiplier); // normal rail if (_settings_game.vehicle.disable_elrails) { /* skip elrail multiplier - disabled */ SB(*value, 8, 8, GetRailTypeInfo(RAILTYPE_MONO)->cost_multiplier); // monorail } else { SB(*value, 8, 8, GetRailTypeInfo(RAILTYPE_ELECTRIC)->cost_multiplier); // electified railway /* Skip monorail multiplier - no space in result */ } SB(*value, 16, 8, GetRailTypeInfo(RAILTYPE_MAGLEV)->cost_multiplier); // maglev return true; case 0x11: // current rail tool type *value = 0; // constant fake value to avoid desync return true; case 0x12: // Game mode *value = _game_mode; return true; /* case 0x13: // Tile refresh offset to left not implemented */ /* case 0x14: // Tile refresh offset to right not implemented */ /* case 0x15: // Tile refresh offset upwards not implemented */ /* case 0x16: // Tile refresh offset downwards not implemented */ /* case 0x17: // temperate snow line not implemented */ case 0x1A: // Always -1 *value = UINT_MAX; return true; case 0x1B: // Display options *value = 0x3F; // constant fake value to avoid desync return true; case 0x1D: // TTD Platform, 00=TTDPatch, 01=OpenTTD, also used for feature tests (bits 31..4) *value = 1 | grffile->var9D_overlay; return true; case 0x1E: // Miscellaneous GRF features *value = _misc_grf_features; /* Add the local flags */ assert(!HasBit(*value, GMB_TRAIN_WIDTH_32_PIXELS)); if (_cur.grffile->traininfo_vehicle_width == VEHICLEINFO_FULL_VEHICLE_WIDTH) SetBit(*value, GMB_TRAIN_WIDTH_32_PIXELS); return true; /* case 0x1F: // locale dependent settings not implemented to avoid desync */ case 0x20: { // snow line height byte snowline = GetSnowLine(); if (_settings_game.game_creation.landscape == LT_ARCTIC && snowline <= _settings_game.construction.map_height_limit) { *value = Clamp(snowline * (grffile->grf_version >= 8 ? 1 : TILE_HEIGHT), 0, 0xFE); } else { /* No snow */ *value = 0xFF; } return true; } case 0x21: // OpenTTD version *value = _openttd_newgrf_version; return true; case 0x22: // difficulty level *value = SP_CUSTOM; return true; case 0x23: // long format date *value = _date; return true; case 0x24: // long format year *value = _cur_year; return true; default: return false; } } static uint32 GetParamVal(byte param, uint32 *cond_val) { /* First handle variable common with VarAction2 */ uint32 value; if (GetGlobalVariable(param - 0x80, &value, _cur.grffile)) return value; /* Non-common variable */ switch (param) { case 0x84: { // GRF loading stage uint32 res = 0; if (_cur.stage > GLS_INIT) SetBit(res, 0); if (_cur.stage == GLS_RESERVE) SetBit(res, 8); if (_cur.stage == GLS_ACTIVATION) SetBit(res, 9); return res; } case 0x85: // TTDPatch flags, only for bit tests if (cond_val == nullptr) { /* Supported in Action 0x07 and 0x09, not 0x0D */ return 0; } else { uint32 index = *cond_val / 0x20; uint32 param_val = index < lengthof(_ttdpatch_flags) ? _ttdpatch_flags[index] : 0; *cond_val %= 0x20; return param_val; } case 0x88: // GRF ID check return 0; /* case 0x99: Global ID offset not implemented */ default: /* GRF Parameter */ if (param < 0x80) return _cur.grffile->GetParam(param); /* In-game variable. */ grfmsg(1, "Unsupported in-game variable 0x%02X", param); return UINT_MAX; } } /* Action 0x06 */ static void CfgApply(ByteReader *buf) { /* <06>

... * * B param-num Number of parameter to substitute (First = "zero") * Ignored if that parameter was not specified in newgrf.cfg * B param-size How many bytes to replace. If larger than 4, the * bytes of the following parameter are used. In that * case, nothing is applied unless *all* parameters * were specified. * B offset Offset into data from beginning of next sprite * to place where parameter is to be stored. */ /* Preload the next sprite */ SpriteFile &file = *_cur.file; size_t pos = file.GetPos(); uint32 num = file.GetContainerVersion() >= 2 ? file.ReadDword() : file.ReadWord(); uint8 type = file.ReadByte(); byte *preload_sprite = nullptr; /* Check if the sprite is a pseudo sprite. We can't operate on real sprites. */ if (type == 0xFF) { preload_sprite = MallocT(num); file.ReadBlock(preload_sprite, num); } /* Reset the file position to the start of the next sprite */ file.SeekTo(pos, SEEK_SET); if (type != 0xFF) { grfmsg(2, "CfgApply: Ignoring (next sprite is real, unsupported)"); free(preload_sprite); return; } GRFLocation location(_cur.grfconfig->ident.grfid, _cur.nfo_line + 1); GRFLineToSpriteOverride::iterator it = _grf_line_to_action6_sprite_override.find(location); if (it != _grf_line_to_action6_sprite_override.end()) { free(preload_sprite); preload_sprite = it->second; } else { _grf_line_to_action6_sprite_override[location] = preload_sprite; } /* Now perform the Action 0x06 on our data. */ for (;;) { uint i; uint param_num; uint param_size; uint offset; bool add_value; /* Read the parameter to apply. 0xFF indicates no more data to change. */ param_num = buf->ReadByte(); if (param_num == 0xFF) break; /* Get the size of the parameter to use. If the size covers multiple * double words, sequential parameter values are used. */ param_size = buf->ReadByte(); /* Bit 7 of param_size indicates we should add to the original value * instead of replacing it. */ add_value = HasBit(param_size, 7); param_size = GB(param_size, 0, 7); /* Where to apply the data to within the pseudo sprite data. */ offset = buf->ReadExtendedByte(); /* If the parameter is a GRF parameter (not an internal variable) check * if it (and all further sequential parameters) has been defined. */ if (param_num < 0x80 && (param_num + (param_size - 1) / 4) >= _cur.grffile->param_end) { grfmsg(2, "CfgApply: Ignoring (param %d not set)", (param_num + (param_size - 1) / 4)); break; } grfmsg(8, "CfgApply: Applying %u bytes from parameter 0x%02X at offset 0x%04X", param_size, param_num, offset); bool carry = false; for (i = 0; i < param_size && offset + i < num; i++) { uint32 value = GetParamVal(param_num + i / 4, nullptr); /* Reset carry flag for each iteration of the variable (only really * matters if param_size is greater than 4) */ if (i % 4 == 0) carry = false; if (add_value) { uint new_value = preload_sprite[offset + i] + GB(value, (i % 4) * 8, 8) + (carry ? 1 : 0); preload_sprite[offset + i] = GB(new_value, 0, 8); /* Check if the addition overflowed */ carry = new_value >= 256; } else { preload_sprite[offset + i] = GB(value, (i % 4) * 8, 8); } } } } /** * Disable a static NewGRF when it is influencing another (non-static) * NewGRF as this could cause desyncs. * * We could just tell the NewGRF querying that the file doesn't exist, * but that might give unwanted results. Disabling the NewGRF gives the * best result as no NewGRF author can complain about that. * @param c The NewGRF to disable. */ static void DisableStaticNewGRFInfluencingNonStaticNewGRFs(GRFConfig *c) { GRFError *error = DisableGrf(STR_NEWGRF_ERROR_STATIC_GRF_CAUSES_DESYNC, c); error->data = _cur.grfconfig->GetName(); } /* Action 0x07 * Action 0x09 */ static void SkipIf(ByteReader *buf) { /* <07/09>

* * B param-num * B param-size * B condition-type * V value * B num-sprites */ uint32 cond_val = 0; uint32 mask = 0; bool result; uint8 param = buf->ReadByte(); uint8 paramsize = buf->ReadByte(); uint8 condtype = buf->ReadByte(); if (condtype < 2) { /* Always 1 for bit tests, the given value should be ignored. */ paramsize = 1; } switch (paramsize) { case 8: cond_val = buf->ReadDWord(); mask = buf->ReadDWord(); break; case 4: cond_val = buf->ReadDWord(); mask = 0xFFFFFFFF; break; case 2: cond_val = buf->ReadWord(); mask = 0x0000FFFF; break; case 1: cond_val = buf->ReadByte(); mask = 0x000000FF; break; default: break; } if (param < 0x80 && _cur.grffile->param_end <= param) { grfmsg(7, "SkipIf: Param %d undefined, skipping test", param); return; } grfmsg(7, "SkipIf: Test condtype %d, param 0x%02X, condval 0x%08X", condtype, param, cond_val); /* condtypes that do not use 'param' are always valid. * condtypes that use 'param' are either not valid for param 0x88, or they are only valid for param 0x88. */ if (condtype >= 0x0B) { /* Tests that ignore 'param' */ switch (condtype) { case 0x0B: result = GetCargoIDByLabel(BSWAP32(cond_val)) == CT_INVALID; break; case 0x0C: result = GetCargoIDByLabel(BSWAP32(cond_val)) != CT_INVALID; break; case 0x0D: result = GetRailTypeByLabel(BSWAP32(cond_val)) == INVALID_RAILTYPE; break; case 0x0E: result = GetRailTypeByLabel(BSWAP32(cond_val)) != INVALID_RAILTYPE; break; case 0x0F: { RoadType rt = GetRoadTypeByLabel(BSWAP32(cond_val)); result = rt == INVALID_ROADTYPE || !RoadTypeIsRoad(rt); break; } case 0x10: { RoadType rt = GetRoadTypeByLabel(BSWAP32(cond_val)); result = rt != INVALID_ROADTYPE && RoadTypeIsRoad(rt); break; } case 0x11: { RoadType rt = GetRoadTypeByLabel(BSWAP32(cond_val)); result = rt == INVALID_ROADTYPE || !RoadTypeIsTram(rt); break; } case 0x12: { RoadType rt = GetRoadTypeByLabel(BSWAP32(cond_val)); result = rt != INVALID_ROADTYPE && RoadTypeIsTram(rt); break; } default: grfmsg(1, "SkipIf: Unsupported condition type %02X. Ignoring", condtype); return; } } else if (param == 0x88) { /* GRF ID checks */ GRFConfig *c = GetGRFConfig(cond_val, mask); if (c != nullptr && HasBit(c->flags, GCF_STATIC) && !HasBit(_cur.grfconfig->flags, GCF_STATIC) && _networking) { DisableStaticNewGRFInfluencingNonStaticNewGRFs(c); c = nullptr; } if (condtype != 10 && c == nullptr) { grfmsg(7, "SkipIf: GRFID 0x%08X unknown, skipping test", BSWAP32(cond_val)); return; } switch (condtype) { /* Tests 0x06 to 0x0A are only for param 0x88, GRFID checks */ case 0x06: // Is GRFID active? result = c->status == GCS_ACTIVATED; break; case 0x07: // Is GRFID non-active? result = c->status != GCS_ACTIVATED; break; case 0x08: // GRFID is not but will be active? result = c->status == GCS_INITIALISED; break; case 0x09: // GRFID is or will be active? result = c->status == GCS_ACTIVATED || c->status == GCS_INITIALISED; break; case 0x0A: // GRFID is not nor will be active /* This is the only condtype that doesn't get ignored if the GRFID is not found */ result = c == nullptr || c->status == GCS_DISABLED || c->status == GCS_NOT_FOUND; break; default: grfmsg(1, "SkipIf: Unsupported GRF condition type %02X. Ignoring", condtype); return; } } else { /* Tests that use 'param' and are not GRF ID checks. */ uint32 param_val = GetParamVal(param, &cond_val); // cond_val is modified for param == 0x85 switch (condtype) { case 0x00: result = !!(param_val & (1 << cond_val)); break; case 0x01: result = !(param_val & (1 << cond_val)); break; case 0x02: result = (param_val & mask) == cond_val; break; case 0x03: result = (param_val & mask) != cond_val; break; case 0x04: result = (param_val & mask) < cond_val; break; case 0x05: result = (param_val & mask) > cond_val; break; default: grfmsg(1, "SkipIf: Unsupported condition type %02X. Ignoring", condtype); return; } } if (!result) { grfmsg(2, "SkipIf: Not skipping sprites, test was false"); return; } uint8 numsprites = buf->ReadByte(); /* numsprites can be a GOTO label if it has been defined in the GRF * file. The jump will always be the first matching label that follows * the current nfo_line. If no matching label is found, the first matching * label in the file is used. */ GRFLabel *choice = nullptr; for (GRFLabel *label = _cur.grffile->label; label != nullptr; label = label->next) { if (label->label != numsprites) continue; /* Remember a goto before the current line */ if (choice == nullptr) choice = label; /* If we find a label here, this is definitely good */ if (label->nfo_line > _cur.nfo_line) { choice = label; break; } } if (choice != nullptr) { grfmsg(2, "SkipIf: Jumping to label 0x%0X at line %d, test was true", choice->label, choice->nfo_line); _cur.file->SeekTo(choice->pos, SEEK_SET); _cur.nfo_line = choice->nfo_line; return; } grfmsg(2, "SkipIf: Skipping %d sprites, test was true", numsprites); _cur.skip_sprites = numsprites; if (_cur.skip_sprites == 0) { /* Zero means there are no sprites to skip, so * we use -1 to indicate that all further * sprites should be skipped. */ _cur.skip_sprites = -1; /* If an action 8 hasn't been encountered yet, disable the grf. */ if (_cur.grfconfig->status != (_cur.stage < GLS_RESERVE ? GCS_INITIALISED : GCS_ACTIVATED)) { DisableGrf(); } } } /* Action 0x08 (GLS_FILESCAN) */ static void ScanInfo(ByteReader *buf) { uint8 grf_version = buf->ReadByte(); uint32 grfid = buf->ReadDWord(); const char *name = buf->ReadString(); _cur.grfconfig->ident.grfid = grfid; if (grf_version < 2 || grf_version > 8) { SetBit(_cur.grfconfig->flags, GCF_INVALID); DEBUG(grf, 0, "%s: NewGRF \"%s\" (GRFID %08X) uses GRF version %d, which is incompatible with this version of OpenTTD.", _cur.grfconfig->GetDisplayPath(), name, BSWAP32(grfid), grf_version); } /* GRF IDs starting with 0xFF are reserved for internal TTDPatch use */ if (GB(grfid, 0, 8) == 0xFF) SetBit(_cur.grfconfig->flags, GCF_SYSTEM); AddGRFTextToList(_cur.grfconfig->name, 0x7F, grfid, false, name); if (buf->HasData()) { const char *info = buf->ReadString(); AddGRFTextToList(_cur.grfconfig->info, 0x7F, grfid, true, info); } /* GLS_INFOSCAN only looks for the action 8, so we can skip the rest of the file */ _cur.skip_sprites = -1; } /* Action 0x08 */ static void GRFInfo(ByteReader *buf) { /* <08>

* * B version newgrf version, currently 06 * 4*B grf-id globally unique ID of this .grf file * S name name of this .grf set * S info string describing the set, and e.g. author and copyright */ uint8 version = buf->ReadByte(); uint32 grfid = buf->ReadDWord(); const char *name = buf->ReadString(); if (_cur.stage < GLS_RESERVE && _cur.grfconfig->status != GCS_UNKNOWN) { DisableGrf(STR_NEWGRF_ERROR_MULTIPLE_ACTION_8); return; } if (_cur.grffile->grfid != grfid) { DEBUG(grf, 0, "GRFInfo: GRFID %08X in FILESCAN stage does not match GRFID %08X in INIT/RESERVE/ACTIVATION stage", BSWAP32(_cur.grffile->grfid), BSWAP32(grfid)); _cur.grffile->grfid = grfid; } _cur.grffile->grf_version = version; _cur.grfconfig->status = _cur.stage < GLS_RESERVE ? GCS_INITIALISED : GCS_ACTIVATED; /* Do swap the GRFID for displaying purposes since people expect that */ DEBUG(grf, 1, "GRFInfo: Loaded GRFv%d set %08X - %s (palette: %s, version: %i)", version, BSWAP32(grfid), name, (_cur.grfconfig->palette & GRFP_USE_MASK) ? "Windows" : "DOS", _cur.grfconfig->version); } /* Action 0x0A */ static void SpriteReplace(ByteReader *buf) { /* <0A> [ ...] * :

* * B num-sets How many sets of sprites to replace. * Each set: * B num-sprites How many sprites are in this set * W first-sprite First sprite number to replace */ uint8 num_sets = buf->ReadByte(); for (uint i = 0; i < num_sets; i++) { uint8 num_sprites = buf->ReadByte(); uint16 first_sprite = buf->ReadWord(); grfmsg(2, "SpriteReplace: [Set %d] Changing %d sprites, beginning with %d", i, num_sprites, first_sprite ); for (uint j = 0; j < num_sprites; j++) { int load_index = first_sprite + j; _cur.nfo_line++; if (load_index < (int)SPR_PROGSIGNAL_BASE || load_index >= (int)SPR_NEWGRFS_BASE) { LoadNextSprite(load_index, *_cur.file, _cur.nfo_line); // XXX } else { /* Skip sprite */ grfmsg(0, "SpriteReplace: Ignoring attempt to replace protected sprite ID: %d", load_index); LoadNextSprite(-1, *_cur.file, _cur.nfo_line); } /* Shore sprites now located at different addresses. * So detect when the old ones get replaced. */ if (IsInsideMM(load_index, SPR_ORIGINALSHORE_START, SPR_ORIGINALSHORE_END + 1)) { if (_loaded_newgrf_features.shore != SHORE_REPLACE_ACTION_5) _loaded_newgrf_features.shore = SHORE_REPLACE_ACTION_A; } } } } /* Action 0x0A (SKIP) */ static void SkipActA(ByteReader *buf) { uint8 num_sets = buf->ReadByte(); for (uint i = 0; i < num_sets; i++) { /* Skip the sprites this replaces */ _cur.skip_sprites += buf->ReadByte(); /* But ignore where they go */ buf->ReadWord(); } grfmsg(3, "SkipActA: Skipping %d sprites", _cur.skip_sprites); } /* Action 0x0B */ static void GRFLoadError(ByteReader *buf) { /* <0B>

[ 00] [] 00 [] * * B severity 00: notice, continue loading grf file * 01: warning, continue loading grf file * 02: error, but continue loading grf file, and attempt * loading grf again when loading or starting next game * 03: error, abort loading and prevent loading again in * the future (only when restarting the patch) * B language-id see action 4, use 1F for built-in error messages * B message-id message to show, see below * S message for custom messages (message-id FF), text of the message * not present for built-in messages. * V data additional data for built-in (or custom) messages * B parnum parameter numbers to be shown in the message (maximum of 2) */ static const StringID msgstr[] = { STR_NEWGRF_ERROR_VERSION_NUMBER, STR_NEWGRF_ERROR_DOS_OR_WINDOWS, STR_NEWGRF_ERROR_UNSET_SWITCH, STR_NEWGRF_ERROR_INVALID_PARAMETER, STR_NEWGRF_ERROR_LOAD_BEFORE, STR_NEWGRF_ERROR_LOAD_AFTER, STR_NEWGRF_ERROR_OTTD_VERSION_NUMBER, }; static const StringID sevstr[] = { STR_NEWGRF_ERROR_MSG_INFO, STR_NEWGRF_ERROR_MSG_WARNING, STR_NEWGRF_ERROR_MSG_ERROR, STR_NEWGRF_ERROR_MSG_FATAL }; byte severity = buf->ReadByte(); byte lang = buf->ReadByte(); byte message_id = buf->ReadByte(); /* Skip the error if it isn't valid for the current language. */ if (!CheckGrfLangID(lang, _cur.grffile->grf_version)) return; /* Skip the error until the activation stage unless bit 7 of the severity * is set. */ if (!HasBit(severity, 7) && _cur.stage == GLS_INIT) { grfmsg(7, "GRFLoadError: Skipping non-fatal GRFLoadError in stage %d", _cur.stage); return; } ClrBit(severity, 7); if (severity >= lengthof(sevstr)) { grfmsg(7, "GRFLoadError: Invalid severity id %d. Setting to 2 (non-fatal error).", severity); severity = 2; } else if (severity == 3) { /* This is a fatal error, so make sure the GRF is deactivated and no * more of it gets loaded. */ DisableGrf(); /* Make sure we show fatal errors, instead of silly infos from before */ delete _cur.grfconfig->error; _cur.grfconfig->error = nullptr; } if (message_id >= lengthof(msgstr) && message_id != 0xFF) { grfmsg(7, "GRFLoadError: Invalid message id."); return; } if (buf->Remaining() <= 1) { grfmsg(7, "GRFLoadError: No message data supplied."); return; } /* For now we can only show one message per newgrf file. */ if (_cur.grfconfig->error != nullptr) return; GRFError *error = new GRFError(sevstr[severity]); if (message_id == 0xFF) { /* This is a custom error message. */ if (buf->HasData()) { const char *message = buf->ReadString(); error->custom_message = TranslateTTDPatchCodes(_cur.grffile->grfid, lang, true, message, SCC_RAW_STRING_POINTER); } else { grfmsg(7, "GRFLoadError: No custom message supplied."); error->custom_message.clear(); } } else { error->message = msgstr[message_id]; } if (buf->HasData()) { const char *data = buf->ReadString(); error->data = TranslateTTDPatchCodes(_cur.grffile->grfid, lang, true, data); } else { grfmsg(7, "GRFLoadError: No message data supplied."); error->data.clear(); } /* Only two parameter numbers can be used in the string. */ for (uint i = 0; i < lengthof(error->param_value) && buf->HasData(); i++) { uint param_number = buf->ReadByte(); error->param_value[i] = _cur.grffile->GetParam(param_number); } _cur.grfconfig->error = error; } /* Action 0x0C */ static void GRFComment(ByteReader *buf) { /* <0C> [] * * V ignored Anything following the 0C is ignored */ if (!buf->HasData()) return; const char *text = buf->ReadString(); grfmsg(2, "GRFComment: %s", text); } /* Action 0x0D (GLS_SAFETYSCAN) */ static void SafeParamSet(ByteReader *buf) { uint8 target = buf->ReadByte(); /* Writing GRF parameters and some bits of 'misc GRF features' are safe. */ if (target < 0x80 || target == 0x9E) return; /* GRM could be unsafe, but as here it can only happen after other GRFs * are loaded, it should be okay. If the GRF tried to use the slots it * reserved, it would be marked unsafe anyway. GRM for (e.g. bridge) * sprites is considered safe. */ SetBit(_cur.grfconfig->flags, GCF_UNSAFE); /* Skip remainder of GRF */ _cur.skip_sprites = -1; } static uint32 GetPatchVariable(uint8 param) { switch (param) { /* start year - 1920 */ case 0x0B: return std::max(_settings_game.game_creation.starting_year, ORIGINAL_BASE_YEAR) - ORIGINAL_BASE_YEAR; /* freight trains weight factor */ case 0x0E: return _settings_game.vehicle.freight_trains; /* empty wagon speed increase */ case 0x0F: return 0; /* plane speed factor; our patch option is reversed from TTDPatch's, * the following is good for 1x, 2x and 4x (most common?) and... * well not really for 3x. */ case 0x10: switch (_settings_game.vehicle.plane_speed) { default: case 4: return 1; case 3: return 2; case 2: return 2; case 1: return 4; } /* 2CC colourmap base sprite */ case 0x11: return SPR_2CCMAP_BASE; /* map size: format = -MABXYSS * M : the type of map * bit 0 : set : squared map. Bit 1 is now not relevant * clear : rectangle map. Bit 1 will indicate the bigger edge of the map * bit 1 : set : Y is the bigger edge. Bit 0 is clear * clear : X is the bigger edge. * A : minimum edge(log2) of the map * B : maximum edge(log2) of the map * XY : edges(log2) of each side of the map. * SS : combination of both X and Y, thus giving the size(log2) of the map */ case 0x13: { byte map_bits = 0; byte log_X = MapLogX() - 6; // subtraction is required to make the minimal size (64) zero based byte log_Y = MapLogY() - 6; byte max_edge = std::max(log_X, log_Y); if (log_X == log_Y) { // we have a squared map, since both edges are identical SetBit(map_bits, 0); } else { if (max_edge == log_Y) SetBit(map_bits, 1); // edge Y been the biggest, mark it } return (map_bits << 24) | (std::min(log_X, log_Y) << 20) | (max_edge << 16) | (log_X << 12) | (log_Y << 8) | (log_X + log_Y); } /* The maximum height of the map. */ case 0x14: return _settings_game.construction.map_height_limit; /* Extra foundations base sprite */ case 0x15: return SPR_SLOPES_BASE; /* Shore base sprite */ case 0x16: return SPR_SHORE_BASE; /* Game map seed */ case 0x17: return _settings_game.game_creation.generation_seed; default: grfmsg(2, "ParamSet: Unknown Patch variable 0x%02X.", param); return 0; } } static uint32 PerformGRM(uint32 *grm, uint16 num_ids, uint16 count, uint8 op, uint8 target, const char *type) { uint start = 0; uint size = 0; if (op == 6) { /* Return GRFID of set that reserved ID */ return grm[_cur.grffile->GetParam(target)]; } /* With an operation of 2 or 3, we want to reserve a specific block of IDs */ if (op == 2 || op == 3) start = _cur.grffile->GetParam(target); for (uint i = start; i < num_ids; i++) { if (grm[i] == 0) { size++; } else { if (op == 2 || op == 3) break; start = i + 1; size = 0; } if (size == count) break; } if (size == count) { /* Got the slot... */ if (op == 0 || op == 3) { grfmsg(2, "ParamSet: GRM: Reserving %d %s at %d", count, type, start); for (uint i = 0; i < count; i++) grm[start + i] = _cur.grffile->grfid; } return start; } /* Unable to allocate */ if (op != 4 && op != 5) { /* Deactivate GRF */ grfmsg(0, "ParamSet: GRM: Unable to allocate %d %s, deactivating", count, type); DisableGrf(STR_NEWGRF_ERROR_GRM_FAILED); return UINT_MAX; } grfmsg(1, "ParamSet: GRM: Unable to allocate %d %s", count, type); return UINT_MAX; } /** Action 0x0D: Set parameter */ static void ParamSet(ByteReader *buf) { /* <0D> [] * * B target parameter number where result is stored * B operation operation to perform, see below * B source1 first source operand * B source2 second source operand * D data data to use in the calculation, not necessary * if both source1 and source2 refer to actual parameters * * Operations * 00 Set parameter equal to source1 * 01 Addition, source1 + source2 * 02 Subtraction, source1 - source2 * 03 Unsigned multiplication, source1 * source2 (both unsigned) * 04 Signed multiplication, source1 * source2 (both signed) * 05 Unsigned bit shift, source1 by source2 (source2 taken to be a * signed quantity; left shift if positive and right shift if * negative, source1 is unsigned) * 06 Signed bit shift, source1 by source2 * (source2 like in 05, and source1 as well) */ uint8 target = buf->ReadByte(); uint8 oper = buf->ReadByte(); uint32 src1 = buf->ReadByte(); uint32 src2 = buf->ReadByte(); uint32 data = 0; if (buf->Remaining() >= 4) data = buf->ReadDWord(); /* You can add 80 to the operation to make it apply only if the target * is not defined yet. In this respect, a parameter is taken to be * defined if any of the following applies: * - it has been set to any value in the newgrf(w).cfg parameter list * - it OR A PARAMETER WITH HIGHER NUMBER has been set to any value by * an earlier action D */ if (HasBit(oper, 7)) { if (target < 0x80 && target < _cur.grffile->param_end) { grfmsg(7, "ParamSet: Param %u already defined, skipping", target); return; } oper = GB(oper, 0, 7); } if (src2 == 0xFE) { if (GB(data, 0, 8) == 0xFF) { if (data == 0x0000FFFF) { /* Patch variables */ src1 = GetPatchVariable(src1); } else { /* GRF Resource Management */ uint8 op = src1; GrfSpecFeatureRef feature_ref = ReadFeature(GB(data, 8, 8)); GrfSpecFeature feature = feature_ref.id; uint16 count = GB(data, 16, 16); if (_cur.stage == GLS_RESERVE) { if (feature == 0x08) { /* General sprites */ if (op == 0) { /* Check if the allocated sprites will fit below the original sprite limit */ if (_cur.spriteid + count >= 16384) { grfmsg(0, "ParamSet: GRM: Unable to allocate %d sprites; try changing NewGRF order", count); DisableGrf(STR_NEWGRF_ERROR_GRM_FAILED); return; } /* Reserve space at the current sprite ID */ grfmsg(4, "ParamSet: GRM: Allocated %d sprites at %d", count, _cur.spriteid); _grm_sprites[GRFLocation(_cur.grffile->grfid, _cur.nfo_line)] = _cur.spriteid; _cur.spriteid += count; } } /* Ignore GRM result during reservation */ src1 = 0; } else if (_cur.stage == GLS_ACTIVATION) { switch (feature) { case 0x00: // Trains case 0x01: // Road Vehicles case 0x02: // Ships case 0x03: // Aircraft if (!_settings_game.vehicle.dynamic_engines) { src1 = PerformGRM(&_grm_engines[_engine_offsets[feature]], _engine_counts[feature], count, op, target, "vehicles"); if (_cur.skip_sprites == -1) return; } else { /* GRM does not apply for dynamic engine allocation. */ switch (op) { case 2: case 3: src1 = _cur.grffile->GetParam(target); break; default: src1 = 0; break; } } break; case 0x08: // General sprites switch (op) { case 0: /* Return space reserved during reservation stage */ src1 = _grm_sprites[GRFLocation(_cur.grffile->grfid, _cur.nfo_line)]; grfmsg(4, "ParamSet: GRM: Using pre-allocated sprites at %d", src1); break; case 1: src1 = _cur.spriteid; break; default: grfmsg(1, "ParamSet: GRM: Unsupported operation %d for general sprites", op); return; } break; case 0x0B: // Cargo /* There are two ranges: one for cargo IDs and one for cargo bitmasks */ src1 = PerformGRM(_grm_cargoes, NUM_CARGO * 2, count, op, target, "cargoes"); if (_cur.skip_sprites == -1) return; break; default: grfmsg(1, "ParamSet: GRM: Unsupported feature %s", GetFeatureString(feature_ref)); return; } } else { /* Ignore GRM during initialization */ src1 = 0; } } } else { /* Read another GRF File's parameter */ const GRFFile *file = GetFileByGRFID(data); GRFConfig *c = GetGRFConfig(data); if (c != nullptr && HasBit(c->flags, GCF_STATIC) && !HasBit(_cur.grfconfig->flags, GCF_STATIC) && _networking) { /* Disable the read GRF if it is a static NewGRF. */ DisableStaticNewGRFInfluencingNonStaticNewGRFs(c); src1 = 0; } else if (file == nullptr || c == nullptr || c->status == GCS_DISABLED) { src1 = 0; } else if (src1 == 0xFE) { src1 = c->version; } else { src1 = file->GetParam(src1); } } } else { /* The source1 and source2 operands refer to the grf parameter number * like in action 6 and 7. In addition, they can refer to the special * variables available in action 7, or they can be FF to use the value * of . If referring to parameters that are undefined, a value * of 0 is used instead. */ src1 = (src1 == 0xFF) ? data : GetParamVal(src1, nullptr); src2 = (src2 == 0xFF) ? data : GetParamVal(src2, nullptr); } uint32 res; switch (oper) { case 0x00: res = src1; break; case 0x01: res = src1 + src2; break; case 0x02: res = src1 - src2; break; case 0x03: res = src1 * src2; break; case 0x04: res = (int32)src1 * (int32)src2; break; case 0x05: if ((int32)src2 < 0) { res = src1 >> -(int32)src2; } else { res = src1 << (src2 & 0x1F); // Same behaviour as in EvalAdjustT, mask 'value' to 5 bits, which should behave the same on all architectures. } break; case 0x06: if ((int32)src2 < 0) { res = (int32)src1 >> -(int32)src2; } else { res = (int32)src1 << (src2 & 0x1F); // Same behaviour as in EvalAdjustT, mask 'value' to 5 bits, which should behave the same on all architectures. } break; case 0x07: // Bitwise AND res = src1 & src2; break; case 0x08: // Bitwise OR res = src1 | src2; break; case 0x09: // Unsigned division if (src2 == 0) { res = src1; } else { res = src1 / src2; } break; case 0x0A: // Signed division if (src2 == 0) { res = src1; } else { res = (int32)src1 / (int32)src2; } break; case 0x0B: // Unsigned modulo if (src2 == 0) { res = src1; } else { res = src1 % src2; } break; case 0x0C: // Signed modulo if (src2 == 0) { res = src1; } else { res = (int32)src1 % (int32)src2; } break; default: grfmsg(0, "ParamSet: Unknown operation %d, skipping", oper); return; } switch (target) { case 0x8E: // Y-Offset for train sprites _cur.grffile->traininfo_vehicle_pitch = res; break; case 0x8F: { // Rail track type cost factors extern RailtypeInfo _railtypes[RAILTYPE_END]; _railtypes[RAILTYPE_RAIL].cost_multiplier = GB(res, 0, 8); if (_settings_game.vehicle.disable_elrails) { _railtypes[RAILTYPE_ELECTRIC].cost_multiplier = GB(res, 0, 8); _railtypes[RAILTYPE_MONO].cost_multiplier = GB(res, 8, 8); } else { _railtypes[RAILTYPE_ELECTRIC].cost_multiplier = GB(res, 8, 8); _railtypes[RAILTYPE_MONO].cost_multiplier = GB(res, 16, 8); } _railtypes[RAILTYPE_MAGLEV].cost_multiplier = GB(res, 16, 8); break; } /* not implemented */ case 0x93: // Tile refresh offset to left -- Intended to allow support for larger sprites, not necessary for OTTD case 0x94: // Tile refresh offset to right case 0x95: // Tile refresh offset upwards case 0x96: // Tile refresh offset downwards case 0x97: // Snow line height -- Better supported by feature 8 property 10h (snow line table) TODO: implement by filling the entire snow line table with the given value case 0x99: // Global ID offset -- Not necessary since IDs are remapped automatically grfmsg(7, "ParamSet: Skipping unimplemented target 0x%02X", target); break; case 0x9E: // Miscellaneous GRF features /* Set train list engine width */ _cur.grffile->traininfo_vehicle_width = HasBit(res, GMB_TRAIN_WIDTH_32_PIXELS) ? VEHICLEINFO_FULL_VEHICLE_WIDTH : TRAININFO_DEFAULT_VEHICLE_WIDTH; /* Remove the local flags from the global flags */ ClrBit(res, GMB_TRAIN_WIDTH_32_PIXELS); /* Only copy safe bits for static grfs */ if (HasBit(_cur.grfconfig->flags, GCF_STATIC)) { uint32 safe_bits = 0; SetBit(safe_bits, GMB_SECOND_ROCKY_TILE_SET); _misc_grf_features = (_misc_grf_features & ~safe_bits) | (res & safe_bits); } else { _misc_grf_features = res; } break; case 0x9F: // locale-dependent settings grfmsg(7, "ParamSet: Skipping unimplemented target 0x%02X", target); break; default: if (target < 0x80) { _cur.grffile->param[target] = res; /* param is zeroed by default */ if (target + 1U > _cur.grffile->param_end) _cur.grffile->param_end = target + 1; } else { grfmsg(7, "ParamSet: Skipping unknown target 0x%02X", target); } break; } } /* Action 0x0E (GLS_SAFETYSCAN) */ static void SafeGRFInhibit(ByteReader *buf) { /* <0E> * * B num Number of GRFIDs that follow * D grfids GRFIDs of the files to deactivate */ uint8 num = buf->ReadByte(); for (uint i = 0; i < num; i++) { uint32 grfid = buf->ReadDWord(); /* GRF is unsafe it if tries to deactivate other GRFs */ if (grfid != _cur.grfconfig->ident.grfid) { SetBit(_cur.grfconfig->flags, GCF_UNSAFE); /* Skip remainder of GRF */ _cur.skip_sprites = -1; return; } } } /* Action 0x0E */ static void GRFInhibit(ByteReader *buf) { /* <0E> * * B num Number of GRFIDs that follow * D grfids GRFIDs of the files to deactivate */ uint8 num = buf->ReadByte(); for (uint i = 0; i < num; i++) { uint32 grfid = buf->ReadDWord(); GRFConfig *file = GetGRFConfig(grfid); /* Unset activation flag */ if (file != nullptr && file != _cur.grfconfig) { grfmsg(2, "GRFInhibit: Deactivating file '%s'", file->GetDisplayPath()); GRFError *error = DisableGrf(STR_NEWGRF_ERROR_FORCEFULLY_DISABLED, file); error->data = _cur.grfconfig->GetName(); } } } /** Action 0x0F - Define Town names */ static void FeatureTownName(ByteReader *buf) { /* <0F>

* * B id ID of this definition in bottom 7 bits (final definition if bit 7 set) * V style-name Name of the style (only for final definition) * B num-parts Number of parts in this definition * V parts The parts */ uint32 grfid = _cur.grffile->grfid; GRFTownName *townname = AddGRFTownName(grfid); byte id = buf->ReadByte(); grfmsg(6, "FeatureTownName: definition 0x%02X", id & 0x7F); if (HasBit(id, 7)) { /* Final definition */ ClrBit(id, 7); bool new_scheme = _cur.grffile->grf_version >= 7; byte lang = buf->ReadByte(); byte nb_gen = townname->nb_gen; do { ClrBit(lang, 7); const char *name = buf->ReadString(); std::string lang_name = TranslateTTDPatchCodes(grfid, lang, false, name); grfmsg(6, "FeatureTownName: lang 0x%X -> '%s'", lang, lang_name.c_str()); townname->name[nb_gen] = AddGRFString(grfid, id, lang, new_scheme, false, name, STR_UNDEFINED); lang = buf->ReadByte(); } while (lang != 0); townname->id[nb_gen] = id; townname->nb_gen++; } byte nb = buf->ReadByte(); grfmsg(6, "FeatureTownName: %u parts", nb); townname->nbparts[id] = nb; townname->partlist[id] = CallocT(nb); for (int i = 0; i < nb; i++) { byte nbtext = buf->ReadByte(); townname->partlist[id][i].bitstart = buf->ReadByte(); townname->partlist[id][i].bitcount = buf->ReadByte(); townname->partlist[id][i].maxprob = 0; townname->partlist[id][i].partcount = nbtext; townname->partlist[id][i].parts = CallocT(nbtext); grfmsg(6, "FeatureTownName: part %d contains %d texts and will use GB(seed, %d, %d)", i, nbtext, townname->partlist[id][i].bitstart, townname->partlist[id][i].bitcount); for (int j = 0; j < nbtext; j++) { byte prob = buf->ReadByte(); if (HasBit(prob, 7)) { byte ref_id = buf->ReadByte(); if (townname->nbparts[ref_id] == 0) { grfmsg(0, "FeatureTownName: definition 0x%02X doesn't exist, deactivating", ref_id); DelGRFTownName(grfid); DisableGrf(STR_NEWGRF_ERROR_INVALID_ID); return; } grfmsg(6, "FeatureTownName: part %d, text %d, uses intermediate definition 0x%02X (with probability %d)", i, j, ref_id, prob & 0x7F); townname->partlist[id][i].parts[j].data.id = ref_id; } else { const char *text = buf->ReadString(); townname->partlist[id][i].parts[j].data.text = stredup(TranslateTTDPatchCodes(grfid, 0, false, text).c_str()); grfmsg(6, "FeatureTownName: part %d, text %d, '%s' (with probability %d)", i, j, townname->partlist[id][i].parts[j].data.text, prob); } townname->partlist[id][i].parts[j].prob = prob; townname->partlist[id][i].maxprob += GB(prob, 0, 7); } grfmsg(6, "FeatureTownName: part %d, total probability %d", i, townname->partlist[id][i].maxprob); } } /** Action 0x10 - Define goto label */ static void DefineGotoLabel(ByteReader *buf) { /* <10> [] * * B label The label to define * V comment Optional comment - ignored */ byte nfo_label = buf->ReadByte(); GRFLabel *label = MallocT(1); label->label = nfo_label; label->nfo_line = _cur.nfo_line; label->pos = _cur.file->GetPos(); label->next = nullptr; /* Set up a linked list of goto targets which we will search in an Action 0x7/0x9 */ if (_cur.grffile->label == nullptr) { _cur.grffile->label = label; } else { /* Attach the label to the end of the list */ GRFLabel *l; for (l = _cur.grffile->label; l->next != nullptr; l = l->next) {} l->next = label; } grfmsg(2, "DefineGotoLabel: GOTO target with label 0x%02X", label->label); } /** * Process a sound import from another GRF file. * @param sound Destination for sound. */ static void ImportGRFSound(SoundEntry *sound) { const GRFFile *file; uint32 grfid = _cur.file->ReadDword(); SoundID sound_id = _cur.file->ReadWord(); file = GetFileByGRFID(grfid); if (file == nullptr || file->sound_offset == 0) { grfmsg(1, "ImportGRFSound: Source file not available"); return; } if (sound_id >= file->num_sounds) { grfmsg(1, "ImportGRFSound: Sound effect %d is invalid", sound_id); return; } grfmsg(2, "ImportGRFSound: Copying sound %d (%d) from file %X", sound_id, file->sound_offset + sound_id, grfid); *sound = *GetSound(file->sound_offset + sound_id); /* Reset volume and priority, which TTDPatch doesn't copy */ sound->volume = 128; sound->priority = 0; } /** * Load a sound from a file. * @param offs File offset to read sound from. * @param sound Destination for sound. */ static void LoadGRFSound(size_t offs, SoundEntry *sound) { /* Set default volume and priority */ sound->volume = 0x80; sound->priority = 0; if (offs != SIZE_MAX) { /* Sound is present in the NewGRF. */ sound->file = _cur.file; sound->file_offset = offs; sound->grf_container_ver = _cur.file->GetContainerVersion(); } } /* Action 0x11 */ static void GRFSound(ByteReader *buf) { /* <11> * * W num Number of sound files that follow */ uint16 num = buf->ReadWord(); if (num == 0) return; SoundEntry *sound; if (_cur.grffile->sound_offset == 0) { _cur.grffile->sound_offset = GetNumSounds(); _cur.grffile->num_sounds = num; sound = AllocateSound(num); } else { sound = GetSound(_cur.grffile->sound_offset); } SpriteFile &file = *_cur.file; byte grf_container_version = file.GetContainerVersion(); for (int i = 0; i < num; i++) { _cur.nfo_line++; /* Check whether the index is in range. This might happen if multiple action 11 are present. * While this is invalid, we do not check for this. But we should prevent it from causing bigger trouble */ bool invalid = i >= _cur.grffile->num_sounds; size_t offs = file.GetPos(); uint32 len = grf_container_version >= 2 ? file.ReadDword() : file.ReadWord(); byte type = file.ReadByte(); if (grf_container_version >= 2 && type == 0xFD) { /* Reference to sprite section. */ if (invalid) { grfmsg(1, "GRFSound: Sound index out of range (multiple Action 11?)"); file.SkipBytes(len); } else if (len != 4) { grfmsg(1, "GRFSound: Invalid sprite section import"); file.SkipBytes(len); } else { uint32 id = file.ReadDword(); if (_cur.stage == GLS_INIT) LoadGRFSound(GetGRFSpriteOffset(id), sound + i); } continue; } if (type != 0xFF) { grfmsg(1, "GRFSound: Unexpected RealSprite found, skipping"); file.SkipBytes(7); SkipSpriteData(*_cur.file, type, len - 8); continue; } if (invalid) { grfmsg(1, "GRFSound: Sound index out of range (multiple Action 11?)"); file.SkipBytes(len); } byte action = file.ReadByte(); switch (action) { case 0xFF: /* Allocate sound only in init stage. */ if (_cur.stage == GLS_INIT) { if (grf_container_version >= 2) { grfmsg(1, "GRFSound: Inline sounds are not supported for container version >= 2"); } else { LoadGRFSound(offs, sound + i); } } file.SkipBytes(len - 1); // already read break; case 0xFE: if (_cur.stage == GLS_ACTIVATION) { /* XXX 'Action 0xFE' isn't really specified. It is only mentioned for * importing sounds, so this is probably all wrong... */ if (file.ReadByte() != 0) grfmsg(1, "GRFSound: Import type mismatch"); ImportGRFSound(sound + i); } else { file.SkipBytes(len - 1); // already read } break; default: grfmsg(1, "GRFSound: Unexpected Action %x found, skipping", action); file.SkipBytes(len - 1); // already read break; } } } /* Action 0x11 (SKIP) */ static void SkipAct11(ByteReader *buf) { /* <11> * * W num Number of sound files that follow */ _cur.skip_sprites = buf->ReadWord(); grfmsg(3, "SkipAct11: Skipping %d sprites", _cur.skip_sprites); } /** Action 0x12 */ static void LoadFontGlyph(ByteReader *buf) { /* <12> * * B num_def Number of definitions * B font_size Size of font (0 = normal, 1 = small, 2 = large, 3 = mono) * B num_char Number of consecutive glyphs * W base_char First character index */ uint8 num_def = buf->ReadByte(); for (uint i = 0; i < num_def; i++) { FontSize size = (FontSize)buf->ReadByte(); uint8 num_char = buf->ReadByte(); uint16 base_char = buf->ReadWord(); if (size >= FS_END) { grfmsg(1, "LoadFontGlyph: Size %u is not supported, ignoring", size); } grfmsg(7, "LoadFontGlyph: Loading %u glyph(s) at 0x%04X for size %u", num_char, base_char, size); for (uint c = 0; c < num_char; c++) { if (size < FS_END) SetUnicodeGlyph(size, base_char + c, _cur.spriteid); _cur.nfo_line++; LoadNextSprite(_cur.spriteid++, *_cur.file, _cur.nfo_line); } } } /** Action 0x12 (SKIP) */ static void SkipAct12(ByteReader *buf) { /* <12> * * B num_def Number of definitions * B font_size Size of font (0 = normal, 1 = small, 2 = large) * B num_char Number of consecutive glyphs * W base_char First character index */ uint8 num_def = buf->ReadByte(); for (uint i = 0; i < num_def; i++) { /* Ignore 'size' byte */ buf->ReadByte(); /* Sum up number of characters */ _cur.skip_sprites += buf->ReadByte(); /* Ignore 'base_char' word */ buf->ReadWord(); } grfmsg(3, "SkipAct12: Skipping %d sprites", _cur.skip_sprites); } /** Action 0x13 */ static void TranslateGRFStrings(ByteReader *buf) { /* <13>

* * 4*B grfid The GRFID of the file whose texts are to be translated * B num-ent Number of strings * W offset First text ID * S text... Zero-terminated strings */ uint32 grfid = buf->ReadDWord(); const GRFConfig *c = GetGRFConfig(grfid); if (c == nullptr || (c->status != GCS_INITIALISED && c->status != GCS_ACTIVATED)) { grfmsg(7, "TranslateGRFStrings: GRFID 0x%08x unknown, skipping action 13", BSWAP32(grfid)); return; } if (c->status == GCS_INITIALISED) { /* If the file is not active but will be activated later, give an error * and disable this file. */ GRFError *error = DisableGrf(STR_NEWGRF_ERROR_LOAD_AFTER); error->data = GetString(STR_NEWGRF_ERROR_AFTER_TRANSLATED_FILE); return; } /* Since no language id is supplied for with version 7 and lower NewGRFs, this string has * to be added as a generic string, thus the language id of 0x7F. For this to work * new_scheme has to be true as well, which will also be implicitly the case for version 8 * and higher. A language id of 0x7F will be overridden by a non-generic id, so this will * not change anything if a string has been provided specifically for this language. */ byte language = _cur.grffile->grf_version >= 8 ? buf->ReadByte() : 0x7F; byte num_strings = buf->ReadByte(); uint16 first_id = buf->ReadWord(); if (!((first_id >= 0xD000 && first_id + num_strings <= 0xD400) || (first_id >= 0xD800 && first_id + num_strings <= 0xE000))) { grfmsg(7, "TranslateGRFStrings: Attempting to set out-of-range string IDs in action 13 (first: 0x%4X, number: 0x%2X)", first_id, num_strings); return; } for (uint i = 0; i < num_strings && buf->HasData(); i++) { const char *string = buf->ReadString(); if (StrEmpty(string)) { grfmsg(7, "TranslateGRFString: Ignoring empty string."); continue; } AddGRFString(grfid, first_id + i, language, true, true, string, STR_UNDEFINED); } } /** Callback function for 'INFO'->'NAME' to add a translation to the newgrf name. */ static bool ChangeGRFName(byte langid, const char *str) { AddGRFTextToList(_cur.grfconfig->name, langid, _cur.grfconfig->ident.grfid, false, str); return true; } /** Callback function for 'INFO'->'DESC' to add a translation to the newgrf description. */ static bool ChangeGRFDescription(byte langid, const char *str) { AddGRFTextToList(_cur.grfconfig->info, langid, _cur.grfconfig->ident.grfid, true, str); return true; } /** Callback function for 'INFO'->'URL_' to set the newgrf url. */ static bool ChangeGRFURL(byte langid, const char *str) { AddGRFTextToList(_cur.grfconfig->url, langid, _cur.grfconfig->ident.grfid, false, str); return true; } /** Callback function for 'INFO'->'NPAR' to set the number of valid parameters. */ static bool ChangeGRFNumUsedParams(size_t len, ByteReader *buf) { if (len != 1) { grfmsg(2, "StaticGRFInfo: expected only 1 byte for 'INFO'->'NPAR' but got " PRINTF_SIZE ", ignoring this field", len); buf->Skip(len); } else { _cur.grfconfig->num_valid_params = std::min(buf->ReadByte(), lengthof(_cur.grfconfig->param)); } return true; } /** Callback function for 'INFO'->'PALS' to set the number of valid parameters. */ static bool ChangeGRFPalette(size_t len, ByteReader *buf) { if (len != 1) { grfmsg(2, "StaticGRFInfo: expected only 1 byte for 'INFO'->'PALS' but got " PRINTF_SIZE ", ignoring this field", len); buf->Skip(len); } else { char data = buf->ReadByte(); GRFPalette pal = GRFP_GRF_UNSET; switch (data) { case '*': case 'A': pal = GRFP_GRF_ANY; break; case 'W': pal = GRFP_GRF_WINDOWS; break; case 'D': pal = GRFP_GRF_DOS; break; default: grfmsg(2, "StaticGRFInfo: unexpected value '%02x' for 'INFO'->'PALS', ignoring this field", data); break; } if (pal != GRFP_GRF_UNSET) { _cur.grfconfig->palette &= ~GRFP_GRF_MASK; _cur.grfconfig->palette |= pal; } } return true; } /** Callback function for 'INFO'->'BLTR' to set the blitter info. */ static bool ChangeGRFBlitter(size_t len, ByteReader *buf) { if (len != 1) { grfmsg(2, "StaticGRFInfo: expected only 1 byte for 'INFO'->'BLTR' but got " PRINTF_SIZE ", ignoring this field", len); buf->Skip(len); } else { char data = buf->ReadByte(); GRFPalette pal = GRFP_BLT_UNSET; switch (data) { case '8': pal = GRFP_BLT_UNSET; break; case '3': pal = GRFP_BLT_32BPP; break; default: grfmsg(2, "StaticGRFInfo: unexpected value '%02x' for 'INFO'->'BLTR', ignoring this field", data); return true; } _cur.grfconfig->palette &= ~GRFP_BLT_MASK; _cur.grfconfig->palette |= pal; } return true; } /** Callback function for 'INFO'->'VRSN' to the version of the NewGRF. */ static bool ChangeGRFVersion(size_t len, ByteReader *buf) { if (len != 4) { grfmsg(2, "StaticGRFInfo: expected 4 bytes for 'INFO'->'VRSN' but got " PRINTF_SIZE ", ignoring this field", len); buf->Skip(len); } else { /* Set min_loadable_version as well (default to minimal compatibility) */ _cur.grfconfig->version = _cur.grfconfig->min_loadable_version = buf->ReadDWord(); } return true; } /** Callback function for 'INFO'->'MINV' to the minimum compatible version of the NewGRF. */ static bool ChangeGRFMinVersion(size_t len, ByteReader *buf) { if (len != 4) { grfmsg(2, "StaticGRFInfo: expected 4 bytes for 'INFO'->'MINV' but got " PRINTF_SIZE ", ignoring this field", len); buf->Skip(len); } else { _cur.grfconfig->min_loadable_version = buf->ReadDWord(); if (_cur.grfconfig->version == 0) { grfmsg(2, "StaticGRFInfo: 'MINV' defined before 'VRSN' or 'VRSN' set to 0, ignoring this field"); _cur.grfconfig->min_loadable_version = 0; } if (_cur.grfconfig->version < _cur.grfconfig->min_loadable_version) { grfmsg(2, "StaticGRFInfo: 'MINV' defined as %d, limiting it to 'VRSN'", _cur.grfconfig->min_loadable_version); _cur.grfconfig->min_loadable_version = _cur.grfconfig->version; } } return true; } static GRFParameterInfo *_cur_parameter; ///< The parameter which info is currently changed by the newgrf. /** Callback function for 'INFO'->'PARAM'->param_num->'NAME' to set the name of a parameter. */ static bool ChangeGRFParamName(byte langid, const char *str) { AddGRFTextToList(_cur_parameter->name, langid, _cur.grfconfig->ident.grfid, false, str); return true; } /** Callback function for 'INFO'->'PARAM'->param_num->'DESC' to set the description of a parameter. */ static bool ChangeGRFParamDescription(byte langid, const char *str) { AddGRFTextToList(_cur_parameter->desc, langid, _cur.grfconfig->ident.grfid, true, str); return true; } /** Callback function for 'INFO'->'PARAM'->param_num->'TYPE' to set the typeof a parameter. */ static bool ChangeGRFParamType(size_t len, ByteReader *buf) { if (len != 1) { grfmsg(2, "StaticGRFInfo: expected 1 byte for 'INFO'->'PARA'->'TYPE' but got " PRINTF_SIZE ", ignoring this field", len); buf->Skip(len); } else { GRFParameterType type = (GRFParameterType)buf->ReadByte(); if (type < PTYPE_END) { _cur_parameter->type = type; } else { grfmsg(3, "StaticGRFInfo: unknown parameter type %d, ignoring this field", type); } } return true; } /** Callback function for 'INFO'->'PARAM'->param_num->'LIMI' to set the min/max value of a parameter. */ static bool ChangeGRFParamLimits(size_t len, ByteReader *buf) { if (_cur_parameter->type != PTYPE_UINT_ENUM) { grfmsg(2, "StaticGRFInfo: 'INFO'->'PARA'->'LIMI' is only valid for parameters with type uint/enum, ignoring this field"); buf->Skip(len); } else if (len != 8) { grfmsg(2, "StaticGRFInfo: expected 8 bytes for 'INFO'->'PARA'->'LIMI' but got " PRINTF_SIZE ", ignoring this field", len); buf->Skip(len); } else { uint32 min_value = buf->ReadDWord(); uint32 max_value = buf->ReadDWord(); if (min_value <= max_value) { _cur_parameter->min_value = min_value; _cur_parameter->max_value = max_value; } else { grfmsg(2, "StaticGRFInfo: 'INFO'->'PARA'->'LIMI' values are incoherent, ignoring this field"); } } return true; } /** Callback function for 'INFO'->'PARAM'->param_num->'MASK' to set the parameter and bits to use. */ static bool ChangeGRFParamMask(size_t len, ByteReader *buf) { if (len < 1 || len > 3) { grfmsg(2, "StaticGRFInfo: expected 1 to 3 bytes for 'INFO'->'PARA'->'MASK' but got " PRINTF_SIZE ", ignoring this field", len); buf->Skip(len); } else { byte param_nr = buf->ReadByte(); if (param_nr >= lengthof(_cur.grfconfig->param)) { grfmsg(2, "StaticGRFInfo: invalid parameter number in 'INFO'->'PARA'->'MASK', param %d, ignoring this field", param_nr); buf->Skip(len - 1); } else { _cur_parameter->param_nr = param_nr; if (len >= 2) _cur_parameter->first_bit = std::min(buf->ReadByte(), 31); if (len >= 3) _cur_parameter->num_bit = std::min(buf->ReadByte(), 32 - _cur_parameter->first_bit); } } return true; } /** Callback function for 'INFO'->'PARAM'->param_num->'DFLT' to set the default value. */ static bool ChangeGRFParamDefault(size_t len, ByteReader *buf) { if (len != 4) { grfmsg(2, "StaticGRFInfo: expected 4 bytes for 'INFO'->'PARA'->'DEFA' but got " PRINTF_SIZE ", ignoring this field", len); buf->Skip(len); } else { _cur_parameter->def_value = buf->ReadDWord(); } _cur.grfconfig->has_param_defaults = true; return true; } typedef bool (*DataHandler)(size_t, ByteReader *); ///< Type of callback function for binary nodes typedef bool (*TextHandler)(byte, const char *str); ///< Type of callback function for text nodes typedef bool (*BranchHandler)(ByteReader *); ///< Type of callback function for branch nodes /** * Data structure to store the allowed id/type combinations for action 14. The * data can be represented as a tree with 3 types of nodes: * 1. Branch nodes (identified by 'C' for choice). * 2. Binary leaf nodes (identified by 'B'). * 3. Text leaf nodes (identified by 'T'). */ struct AllowedSubtags { /** Create empty subtags object used to identify the end of a list. */ AllowedSubtags() : id(0), type(0) {} /** * Create a binary leaf node. * @param id The id for this node. * @param handler The callback function to call. */ AllowedSubtags(uint32 id, DataHandler handler) : id(id), type('B') { this->handler.data = handler; } /** * Create a text leaf node. * @param id The id for this node. * @param handler The callback function to call. */ AllowedSubtags(uint32 id, TextHandler handler) : id(id), type('T') { this->handler.text = handler; } /** * Create a branch node with a callback handler * @param id The id for this node. * @param handler The callback function to call. */ AllowedSubtags(uint32 id, BranchHandler handler) : id(id), type('C') { this->handler.call_handler = true; this->handler.u.branch = handler; } /** * Create a branch node with a list of sub-nodes. * @param id The id for this node. * @param subtags Array with all valid subtags. */ AllowedSubtags(uint32 id, AllowedSubtags *subtags) : id(id), type('C') { this->handler.call_handler = false; this->handler.u.subtags = subtags; } uint32 id; ///< The identifier for this node byte type; ///< The type of the node, must be one of 'C', 'B' or 'T'. union { DataHandler data; ///< Callback function for a binary node, only valid if type == 'B'. TextHandler text; ///< Callback function for a text node, only valid if type == 'T'. struct { union { BranchHandler branch; ///< Callback function for a branch node, only valid if type == 'C' && call_handler. AllowedSubtags *subtags; ///< Pointer to a list of subtags, only valid if type == 'C' && !call_handler. } u; bool call_handler; ///< True if there is a callback function for this node, false if there is a list of subnodes. }; } handler; }; static bool SkipUnknownInfo(ByteReader *buf, byte type); static bool HandleNodes(ByteReader *buf, AllowedSubtags *tags); /** * Try to skip the current branch node and all subnodes. * This is suitable for use with AllowedSubtags. * @param buf Buffer. * @return True if we could skip the node, false if an error occurred. */ static bool SkipInfoChunk(ByteReader *buf) { byte type = buf->ReadByte(); while (type != 0) { buf->ReadDWord(); // chunk ID if (!SkipUnknownInfo(buf, type)) return false; type = buf->ReadByte(); } return true; } /** * Callback function for 'INFO'->'PARA'->param_num->'VALU' to set the names * of some parameter values (type uint/enum) or the names of some bits * (type bitmask). In both cases the format is the same: * Each subnode should be a text node with the value/bit number as id. */ static bool ChangeGRFParamValueNames(ByteReader *buf) { byte type = buf->ReadByte(); while (type != 0) { uint32 id = buf->ReadDWord(); if (type != 'T' || id > _cur_parameter->max_value) { grfmsg(2, "StaticGRFInfo: all child nodes of 'INFO'->'PARA'->param_num->'VALU' should have type 't' and the value/bit number as id"); if (!SkipUnknownInfo(buf, type)) return false; type = buf->ReadByte(); continue; } byte langid = buf->ReadByte(); const char *name_string = buf->ReadString(); std::pair *val_name = _cur_parameter->value_names.Find(id); if (val_name != _cur_parameter->value_names.End()) { AddGRFTextToList(val_name->second, langid, _cur.grfconfig->ident.grfid, false, name_string); } else { GRFTextList list; AddGRFTextToList(list, langid, _cur.grfconfig->ident.grfid, false, name_string); _cur_parameter->value_names.Insert(id, list); } type = buf->ReadByte(); } return true; } /** Action14 parameter tags */ AllowedSubtags _tags_parameters[] = { AllowedSubtags('NAME', ChangeGRFParamName), AllowedSubtags('DESC', ChangeGRFParamDescription), AllowedSubtags('TYPE', ChangeGRFParamType), AllowedSubtags('LIMI', ChangeGRFParamLimits), AllowedSubtags('MASK', ChangeGRFParamMask), AllowedSubtags('VALU', ChangeGRFParamValueNames), AllowedSubtags('DFLT', ChangeGRFParamDefault), AllowedSubtags() }; /** * Callback function for 'INFO'->'PARA' to set extra information about the * parameters. Each subnode of 'INFO'->'PARA' should be a branch node with * the parameter number as id. The first parameter has id 0. The maximum * parameter that can be changed is set by 'INFO'->'NPAR' which defaults to 80. */ static bool HandleParameterInfo(ByteReader *buf) { byte type = buf->ReadByte(); while (type != 0) { uint32 id = buf->ReadDWord(); if (type != 'C' || id >= _cur.grfconfig->num_valid_params) { grfmsg(2, "StaticGRFInfo: all child nodes of 'INFO'->'PARA' should have type 'C' and their parameter number as id"); if (!SkipUnknownInfo(buf, type)) return false; type = buf->ReadByte(); continue; } if (id >= _cur.grfconfig->param_info.size()) { _cur.grfconfig->param_info.resize(id + 1); } if (_cur.grfconfig->param_info[id] == nullptr) { _cur.grfconfig->param_info[id] = new GRFParameterInfo(id); } _cur_parameter = _cur.grfconfig->param_info[id]; /* Read all parameter-data and process each node. */ if (!HandleNodes(buf, _tags_parameters)) return false; type = buf->ReadByte(); } return true; } /** Action14 tags for the INFO node */ AllowedSubtags _tags_info[] = { AllowedSubtags('NAME', ChangeGRFName), AllowedSubtags('DESC', ChangeGRFDescription), AllowedSubtags('URL_', ChangeGRFURL), AllowedSubtags('NPAR', ChangeGRFNumUsedParams), AllowedSubtags('PALS', ChangeGRFPalette), AllowedSubtags('BLTR', ChangeGRFBlitter), AllowedSubtags('VRSN', ChangeGRFVersion), AllowedSubtags('MINV', ChangeGRFMinVersion), AllowedSubtags('PARA', HandleParameterInfo), AllowedSubtags() }; /** Action14 feature test instance */ struct GRFFeatureTest { const GRFFeatureInfo *feature; uint16 min_version; uint16 max_version; uint8 platform_var_bit; void Reset() { this->feature = nullptr; this->min_version = 1; this->max_version = UINT16_MAX; this->platform_var_bit = 0; } void ExecuteTest() { uint16 version = (this->feature != nullptr) ? this->feature->version : 0; bool has_feature = (version >= this->min_version && version <= this->max_version); if (this->platform_var_bit > 0) { SB(_cur.grffile->var9D_overlay, this->platform_var_bit, 1, has_feature ? 1 : 0); grfmsg(2, "Action 14 feature test: feature test: setting bit %u of var 0x9D to %u, %u", platform_var_bit, has_feature ? 1 : 0, _cur.grffile->var9D_overlay); } else { grfmsg(2, "Action 14 feature test: feature test: doing nothing: %u", has_feature ? 1 : 0); } } }; static GRFFeatureTest _current_grf_feature_test; /** Callback function for 'FTST'->'NAME' to set the name of the feature being tested. */ static bool ChangeGRFFeatureTestName(byte langid, const char *str) { extern const GRFFeatureInfo _grf_feature_list[]; for (const GRFFeatureInfo *info = _grf_feature_list; info->name != nullptr; info++) { if (strcmp(info->name, str) == 0) { _current_grf_feature_test.feature = info; grfmsg(2, "Action 14 feature test: found feature named: '%s' (version: %u) in 'FTST'->'NAME'", str, info->version); return true; } } grfmsg(2, "Action 14 feature test: could not find feature named: '%s' in 'FTST'->'NAME'", str); _current_grf_feature_test.feature = nullptr; return true; } /** Callback function for 'FTST'->'MINV' to set the minimum version of the feature being tested. */ static bool ChangeGRFFeatureMinVersion(size_t len, ByteReader *buf) { if (len != 2) { grfmsg(2, "Action 14 feature test: expected 2 bytes for 'FTST'->'MINV' but got " PRINTF_SIZE ", ignoring this field", len); buf->Skip(len); } else { _current_grf_feature_test.min_version = buf->ReadWord(); } return true; } /** Callback function for 'FTST'->'MAXV' to set the maximum version of the feature being tested. */ static bool ChangeGRFFeatureMaxVersion(size_t len, ByteReader *buf) { if (len != 2) { grfmsg(2, "Action 14 feature test: expected 2 bytes for 'FTST'->'MAXV' but got " PRINTF_SIZE ", ignoring this field", len); buf->Skip(len); } else { _current_grf_feature_test.max_version = buf->ReadWord(); } return true; } /** Callback function for 'FTST'->'SETP' to set the bit number of global variable 9D (platform version) to set/unset with the result of the feature test. */ static bool ChangeGRFFeatureSetPlatformVarBit(size_t len, ByteReader *buf) { if (len != 1) { grfmsg(2, "Action 14 feature test: expected 1 byte for 'FTST'->'SETP' but got " PRINTF_SIZE ", ignoring this field", len); buf->Skip(len); } else { uint8 bit_number = buf->ReadByte(); if (bit_number >= 4 && bit_number <= 31) { _current_grf_feature_test.platform_var_bit = bit_number; } else { grfmsg(2, "Action 14 feature test: expected a bit number >= 4 and <= 32 for 'FTST'->'SETP' but got %u, ignoring this field", bit_number); } } return true; } /** Action14 tags for the FTST node */ AllowedSubtags _tags_ftst[] = { AllowedSubtags('NAME', ChangeGRFFeatureTestName), AllowedSubtags('MINV', ChangeGRFFeatureMinVersion), AllowedSubtags('MAXV', ChangeGRFFeatureMaxVersion), AllowedSubtags('SETP', ChangeGRFFeatureSetPlatformVarBit), AllowedSubtags() }; /** * Callback function for 'FTST' (feature test) */ static bool HandleFeatureTestInfo(ByteReader *buf) { _current_grf_feature_test.Reset(); HandleNodes(buf, _tags_ftst); _current_grf_feature_test.ExecuteTest(); return true; } /** Action14 Action0 property map action instance */ struct GRFPropertyMapAction { const char *tag_name = nullptr; const char *descriptor = nullptr; GrfSpecFeature feature; int prop_id; std::string name; GRFPropertyMapFallbackMode fallback_mode; uint8 ttd_ver_var_bit; uint8 input_shift; uint8 output_shift; uint input_mask; uint output_mask; uint output_param; void Reset(const char *tag, const char *desc) { this->tag_name = tag; this->descriptor = desc; this->feature = GSF_INVALID; this->prop_id = -1; this->name.clear(); this->fallback_mode = GPMFM_IGNORE; this->ttd_ver_var_bit = 0; this->input_shift = 0; this->output_shift = 0; this->input_mask = 0; this->output_mask = 0; this->output_param = 0; } void ExecuteFeatureIDRemapping() { if (this->prop_id < 0) { grfmsg(2, "Action 14 %s remapping: no feature ID defined, doing nothing", this->descriptor); return; } if (this->name.empty()) { grfmsg(2, "Action 14 %s remapping: no name defined, doing nothing", this->descriptor); return; } SetBit(_cur.grffile->ctrl_flags, GFCF_HAVE_FEATURE_ID_REMAP); bool success = false; const char *str = this->name.c_str(); extern const GRFFeatureMapDefinition _grf_remappable_features[]; for (const GRFFeatureMapDefinition *info = _grf_remappable_features; info->name != nullptr; info++) { if (strcmp(info->name, str) == 0) { GRFFeatureMapRemapEntry &entry = _cur.grffile->feature_id_remaps.Entry(this->prop_id); entry.name = info->name; entry.feature = info->feature; entry.raw_id = this->prop_id; success = true; break; } } if (this->ttd_ver_var_bit > 0) { SB(_cur.grffile->var8D_overlay, this->ttd_ver_var_bit, 1, success ? 1 : 0); } if (!success) { if (this->fallback_mode == GPMFM_ERROR_ON_DEFINITION) { grfmsg(0, "Error: Unimplemented mapped %s: %s, mapped to: 0x%02X", this->descriptor, str, this->prop_id); GRFError *error = DisableGrf(STR_NEWGRF_ERROR_UNIMPLEMETED_MAPPED_FEATURE_ID); error->data = stredup(str); error->param_value[1] = GSF_INVALID; error->param_value[2] = this->prop_id; } else { const char *str_store = stredup(str); grfmsg(2, "Unimplemented mapped %s: %s, mapped to: %X, %s on use", this->descriptor, str, this->prop_id, (this->fallback_mode == GPMFM_IGNORE) ? "ignoring" : "error"); _cur.grffile->remap_unknown_property_names.emplace_back(str_store); GRFFeatureMapRemapEntry &entry = _cur.grffile->feature_id_remaps.Entry(this->prop_id); entry.name = str_store; entry.feature = (this->fallback_mode == GPMFM_IGNORE) ? GSF_INVALID : GSF_ERROR_ON_USE; entry.raw_id = this->prop_id; } } } void ExecutePropertyRemapping() { if (this->feature == GSF_INVALID) { grfmsg(2, "Action 14 %s remapping: no feature defined, doing nothing", this->descriptor); return; } if (this->prop_id < 0) { grfmsg(2, "Action 14 %s remapping: no property ID defined, doing nothing", this->descriptor); return; } if (this->name.empty()) { grfmsg(2, "Action 14 %s remapping: no name defined, doing nothing", this->descriptor); return; } bool success = false; const char *str = this->name.c_str(); extern const GRFPropertyMapDefinition _grf_action0_remappable_properties[]; for (const GRFPropertyMapDefinition *info = _grf_action0_remappable_properties; info->name != nullptr; info++) { if (info->feature == this->feature && strcmp(info->name, str) == 0) { GRFFilePropertyRemapEntry &entry = _cur.grffile->action0_property_remaps[this->feature].Entry(this->prop_id); entry.name = info->name; entry.id = info->id; entry.feature = this->feature; entry.property_id = this->prop_id; success = true; break; } } if (this->ttd_ver_var_bit > 0) { SB(_cur.grffile->var8D_overlay, this->ttd_ver_var_bit, 1, success ? 1 : 0); } if (!success) { if (this->fallback_mode == GPMFM_ERROR_ON_DEFINITION) { grfmsg(0, "Error: Unimplemented mapped %s: %s, feature: %s, mapped to: %X", this->descriptor, str, GetFeatureString(this->feature), this->prop_id); GRFError *error = DisableGrf(STR_NEWGRF_ERROR_UNIMPLEMETED_MAPPED_PROPERTY); error->data = stredup(str); error->param_value[1] = this->feature; error->param_value[2] = this->prop_id; } else { const char *str_store = stredup(str); grfmsg(2, "Unimplemented mapped %s: %s, feature: %s, mapped to: %X, %s on use", this->descriptor, str, GetFeatureString(this->feature), this->prop_id, (this->fallback_mode == GPMFM_IGNORE) ? "ignoring" : "error"); _cur.grffile->remap_unknown_property_names.emplace_back(str_store); GRFFilePropertyRemapEntry &entry = _cur.grffile->action0_property_remaps[this->feature].Entry(this->prop_id); entry.name = str_store; entry.id = (this->fallback_mode == GPMFM_IGNORE) ? A0RPI_UNKNOWN_IGNORE : A0RPI_UNKNOWN_ERROR; entry.feature = this->feature; entry.property_id = this->prop_id; } } } void ExecuteVariableRemapping() { if (this->feature == GSF_INVALID) { grfmsg(2, "Action 14 %s remapping: no feature defined, doing nothing", this->descriptor); return; } if (this->name.empty()) { grfmsg(2, "Action 14 %s remapping: no name defined, doing nothing", this->descriptor); return; } bool success = false; const char *str = this->name.c_str(); extern const GRFVariableMapDefinition _grf_action2_remappable_variables[]; for (const GRFVariableMapDefinition *info = _grf_action2_remappable_variables; info->name != nullptr; info++) { if (info->feature == this->feature && strcmp(info->name, str) == 0) { _cur.grffile->grf_variable_remaps.push_back({ (uint16)info->id, (uint8)this->feature, this->input_shift, this->output_shift, this->input_mask, this->output_mask, this->output_param }); success = true; break; } } if (this->ttd_ver_var_bit > 0) { SB(_cur.grffile->var8D_overlay, this->ttd_ver_var_bit, 1, success ? 1 : 0); } if (!success) { grfmsg(2, "Unimplemented mapped %s: %s, feature: %s, mapped to 0", this->descriptor, str, GetFeatureString(this->feature)); } } void ExecuteAction5TypeRemapping() { if (this->prop_id < 0) { grfmsg(2, "Action 14 %s remapping: no type ID defined, doing nothing", this->descriptor); return; } if (this->name.empty()) { grfmsg(2, "Action 14 %s remapping: no name defined, doing nothing", this->descriptor); return; } bool success = false; const char *str = this->name.c_str(); extern const Action5TypeRemapDefinition _grf_action5_remappable_types[]; for (const Action5TypeRemapDefinition *info = _grf_action5_remappable_types; info->name != nullptr; info++) { if (strcmp(info->name, str) == 0) { Action5TypeRemapEntry &entry = _cur.grffile->action5_type_remaps.Entry(this->prop_id); entry.name = info->name; entry.info = &(info->info); entry.type_id = this->prop_id; success = true; break; } } if (this->ttd_ver_var_bit > 0) { SB(_cur.grffile->var8D_overlay, this->ttd_ver_var_bit, 1, success ? 1 : 0); } if (!success) { if (this->fallback_mode == GPMFM_ERROR_ON_DEFINITION) { grfmsg(0, "Error: Unimplemented mapped %s: %s, mapped to: %X", this->descriptor, str, this->prop_id); GRFError *error = DisableGrf(STR_NEWGRF_ERROR_UNIMPLEMETED_MAPPED_ACTION5_TYPE); error->data = stredup(str); error->param_value[1] = this->prop_id; } else { const char *str_store = stredup(str); grfmsg(2, "Unimplemented mapped %s: %s, mapped to: %X, %s on use", this->descriptor, str, this->prop_id, (this->fallback_mode == GPMFM_IGNORE) ? "ignoring" : "error"); _cur.grffile->remap_unknown_property_names.emplace_back(str_store); Action5TypeRemapEntry &entry = _cur.grffile->action5_type_remaps.Entry(this->prop_id); entry.name = str_store; entry.info = nullptr; entry.type_id = this->prop_id; entry.fallback_mode = this->fallback_mode; } } } }; static GRFPropertyMapAction _current_grf_property_map_action; /** Callback function for ->'NAME' to set the name of the item to be mapped. */ static bool ChangePropertyRemapName(byte langid, const char *str) { _current_grf_property_map_action.name = str; return true; } /** Callback function for ->'FEAT' to set which feature this mapping applies to. */ static bool ChangePropertyRemapFeature(size_t len, ByteReader *buf) { GRFPropertyMapAction &action = _current_grf_property_map_action; if (len != 1) { grfmsg(2, "Action 14 %s mapping: expected 1 byte for '%s'->'FEAT' but got " PRINTF_SIZE ", ignoring this field", action.descriptor, action.tag_name, len); buf->Skip(len); } else { GrfSpecFeatureRef feature = ReadFeature(buf->ReadByte()); if (feature.id >= GSF_END) { grfmsg(2, "Action 14 %s mapping: invalid feature ID: %s, in '%s'->'FEAT', ignoring this field", action.descriptor, GetFeatureString(feature), action.tag_name); } else { action.feature = feature.id; } } return true; } /** Callback function for ->'PROP' to set the property ID to which this item is being mapped. */ static bool ChangePropertyRemapPropertyId(size_t len, ByteReader *buf) { GRFPropertyMapAction &action = _current_grf_property_map_action; if (len != 1) { grfmsg(2, "Action 14 %s mapping: expected 1 byte for '%s'->'PROP' but got " PRINTF_SIZE ", ignoring this field", action.descriptor, action.tag_name, len); buf->Skip(len); } else { action.prop_id = buf->ReadByte(); } return true; } /** Callback function for ->'FTID' to set the feature ID to which this feature is being mapped. */ static bool ChangePropertyRemapFeatureId(size_t len, ByteReader *buf) { GRFPropertyMapAction &action = _current_grf_property_map_action; if (len != 1) { grfmsg(2, "Action 14 %s mapping: expected 1 byte for '%s'->'FTID' but got " PRINTF_SIZE ", ignoring this field", action.descriptor, action.tag_name, len); buf->Skip(len); } else { action.prop_id = buf->ReadByte(); } return true; } /** Callback function for ->'TYPE' to set the property ID to which this item is being mapped. */ static bool ChangePropertyRemapTypeId(size_t len, ByteReader *buf) { GRFPropertyMapAction &action = _current_grf_property_map_action; if (len != 1) { grfmsg(2, "Action 14 %s mapping: expected 1 byte for '%s'->'TYPE' but got " PRINTF_SIZE ", ignoring this field", action.descriptor, action.tag_name, len); buf->Skip(len); } else { uint8 prop = buf->ReadByte(); if (prop < 128) { action.prop_id = prop; } else { grfmsg(2, "Action 14 %s mapping: expected a type < 128 for '%s'->'TYPE' but got %u, ignoring this field", action.descriptor, action.tag_name, prop); } } return true; } /** Callback function for ->'FLBK' to set the fallback mode. */ static bool ChangePropertyRemapSetFallbackMode(size_t len, ByteReader *buf) { GRFPropertyMapAction &action = _current_grf_property_map_action; if (len != 1) { grfmsg(2, "Action 14 %s mapping: expected 1 byte for '%s'->'FLBK' but got " PRINTF_SIZE ", ignoring this field", action.descriptor, action.tag_name, len); buf->Skip(len); } else { GRFPropertyMapFallbackMode mode = (GRFPropertyMapFallbackMode) buf->ReadByte(); if (mode < GPMFM_END) action.fallback_mode = mode; } return true; } /** Callback function for ->'SETT' to set the bit number of global variable 8D (TTD version) to set/unset with whether the remapping was successful. */ static bool ChangePropertyRemapSetTTDVerVarBit(size_t len, ByteReader *buf) { GRFPropertyMapAction &action = _current_grf_property_map_action; if (len != 1) { grfmsg(2, "Action 14 %s mapping: expected 1 byte for '%s'->'SETT' but got " PRINTF_SIZE ", ignoring this field", action.descriptor, action.tag_name, len); buf->Skip(len); } else { uint8 bit_number = buf->ReadByte(); if (bit_number >= 4 && bit_number <= 31) { action.ttd_ver_var_bit = bit_number; } else { grfmsg(2, "Action 14 %s mapping: expected a bit number >= 4 and <= 32 for '%s'->'SETT' but got %u, ignoring this field", action.descriptor, action.tag_name, bit_number); } } return true; } /** Callback function for ->'RSFT' to set the input shift value for variable remapping. */ static bool ChangePropertyRemapSetInputShift(size_t len, ByteReader *buf) { GRFPropertyMapAction &action = _current_grf_property_map_action; if (len != 1) { grfmsg(2, "Action 14 %s mapping: expected 1 byte for '%s'->'RSFT' but got " PRINTF_SIZE ", ignoring this field", action.descriptor, action.tag_name, len); buf->Skip(len); } else { uint8 input_shift = buf->ReadByte(); if (input_shift < 0x20) { action.input_shift = input_shift; } else { grfmsg(2, "Action 14 %s mapping: expected a shift value < 0x20 for '%s'->'RSFT' but got %u, ignoring this field", action.descriptor, action.tag_name, input_shift); } } return true; } /** Callback function for ->'VSFT' to set the output shift value for variable remapping. */ static bool ChangePropertyRemapSetOutputShift(size_t len, ByteReader *buf) { GRFPropertyMapAction &action = _current_grf_property_map_action; if (len != 1) { grfmsg(2, "Action 14 %s mapping: expected 1 byte for '%s'->'VSFT' but got " PRINTF_SIZE ", ignoring this field", action.descriptor, action.tag_name, len); buf->Skip(len); } else { uint8 output_shift = buf->ReadByte(); if (output_shift < 0x20) { action.output_shift = output_shift; } else { grfmsg(2, "Action 14 %s mapping: expected a shift value < 0x20 for '%s'->'VSFT' but got %u, ignoring this field", action.descriptor, action.tag_name, output_shift); } } return true; } /** Callback function for ->'RMSK' to set the input mask value for variable remapping. */ static bool ChangePropertyRemapSetInputMask(size_t len, ByteReader *buf) { GRFPropertyMapAction &action = _current_grf_property_map_action; if (len != 4) { grfmsg(2, "Action 14 %s mapping: expected 4 bytes for '%s'->'RMSK' but got " PRINTF_SIZE ", ignoring this field", action.descriptor, action.tag_name, len); buf->Skip(len); } else { action.input_mask = buf->ReadDWord(); } return true; } /** Callback function for ->'VMSK' to set the output mask value for variable remapping. */ static bool ChangePropertyRemapSetOutputMask(size_t len, ByteReader *buf) { GRFPropertyMapAction &action = _current_grf_property_map_action; if (len != 4) { grfmsg(2, "Action 14 %s mapping: expected 4 bytes for '%s'->'VMSK' but got " PRINTF_SIZE ", ignoring this field", action.descriptor, action.tag_name, len); buf->Skip(len); } else { action.output_mask = buf->ReadDWord(); } return true; } /** Callback function for ->'VPRM' to set the output parameter value for variable remapping. */ static bool ChangePropertyRemapSetOutputParam(size_t len, ByteReader *buf) { GRFPropertyMapAction &action = _current_grf_property_map_action; if (len != 4) { grfmsg(2, "Action 14 %s mapping: expected 4 bytes for '%s'->'VPRM' but got " PRINTF_SIZE ", ignoring this field", action.descriptor, action.tag_name, len); buf->Skip(len); } else { action.output_param = buf->ReadDWord(); } return true; } /** Action14 tags for the FIDM node */ AllowedSubtags _tags_fidm[] = { AllowedSubtags('NAME', ChangePropertyRemapName), AllowedSubtags('FTID', ChangePropertyRemapFeatureId), AllowedSubtags('FLBK', ChangePropertyRemapSetFallbackMode), AllowedSubtags('SETT', ChangePropertyRemapSetTTDVerVarBit), AllowedSubtags() }; /** * Callback function for 'FIDM' (feature ID mapping) */ static bool HandleFeatureIDMap(ByteReader *buf) { _current_grf_property_map_action.Reset("FIDM", "feature"); HandleNodes(buf, _tags_fidm); _current_grf_property_map_action.ExecuteFeatureIDRemapping(); return true; } /** Action14 tags for the A0PM node */ AllowedSubtags _tags_a0pm[] = { AllowedSubtags('NAME', ChangePropertyRemapName), AllowedSubtags('FEAT', ChangePropertyRemapFeature), AllowedSubtags('PROP', ChangePropertyRemapPropertyId), AllowedSubtags('FLBK', ChangePropertyRemapSetFallbackMode), AllowedSubtags('SETT', ChangePropertyRemapSetTTDVerVarBit), AllowedSubtags() }; /** * Callback function for 'A0PM' (action 0 property mapping) */ static bool HandleAction0PropertyMap(ByteReader *buf) { _current_grf_property_map_action.Reset("A0PM", "property"); HandleNodes(buf, _tags_a0pm); _current_grf_property_map_action.ExecutePropertyRemapping(); return true; } /** Action14 tags for the A2VM node */ AllowedSubtags _tags_a2vm[] = { AllowedSubtags('NAME', ChangePropertyRemapName), AllowedSubtags('FEAT', ChangePropertyRemapFeature), AllowedSubtags('RSFT', ChangePropertyRemapSetInputShift), AllowedSubtags('RMSK', ChangePropertyRemapSetInputMask), AllowedSubtags('VSFT', ChangePropertyRemapSetOutputShift), AllowedSubtags('VMSK', ChangePropertyRemapSetOutputMask), AllowedSubtags('VPRM', ChangePropertyRemapSetOutputParam), AllowedSubtags('SETT', ChangePropertyRemapSetTTDVerVarBit), AllowedSubtags() }; /** * Callback function for 'A2VM' (action 2 variable mapping) */ static bool HandleAction2VariableMap(ByteReader *buf) { _current_grf_property_map_action.Reset("A2VM", "variable"); HandleNodes(buf, _tags_a2vm); _current_grf_property_map_action.ExecuteVariableRemapping(); return true; } /** Action14 tags for the A5TM node */ AllowedSubtags _tags_a5tm[] = { AllowedSubtags('NAME', ChangePropertyRemapName), AllowedSubtags('TYPE', ChangePropertyRemapTypeId), AllowedSubtags('FLBK', ChangePropertyRemapSetFallbackMode), AllowedSubtags('SETT', ChangePropertyRemapSetTTDVerVarBit), AllowedSubtags() }; /** * Callback function for 'A5TM' (action 5 type mapping) */ static bool HandleAction5TypeMap(ByteReader *buf) { _current_grf_property_map_action.Reset("A5TM", "Action 5 type"); HandleNodes(buf, _tags_a5tm); _current_grf_property_map_action.ExecuteAction5TypeRemapping(); return true; } /** Action14 root tags */ AllowedSubtags _tags_root_static[] = { AllowedSubtags('INFO', _tags_info), AllowedSubtags('FTST', SkipInfoChunk), AllowedSubtags('FIDM', SkipInfoChunk), AllowedSubtags('A0PM', SkipInfoChunk), AllowedSubtags('A2VM', SkipInfoChunk), AllowedSubtags('A5TM', SkipInfoChunk), AllowedSubtags() }; /** Action14 root tags */ AllowedSubtags _tags_root_feature_tests[] = { AllowedSubtags('INFO', SkipInfoChunk), AllowedSubtags('FTST', HandleFeatureTestInfo), AllowedSubtags('FIDM', HandleFeatureIDMap), AllowedSubtags('A0PM', HandleAction0PropertyMap), AllowedSubtags('A2VM', HandleAction2VariableMap), AllowedSubtags('A5TM', HandleAction5TypeMap), AllowedSubtags() }; /** * Try to skip the current node and all subnodes (if it's a branch node). * @param buf Buffer. * @param type The node type to skip. * @return True if we could skip the node, false if an error occurred. */ static bool SkipUnknownInfo(ByteReader *buf, byte type) { /* type and id are already read */ switch (type) { case 'C': { byte new_type = buf->ReadByte(); while (new_type != 0) { buf->ReadDWord(); // skip the id if (!SkipUnknownInfo(buf, new_type)) return false; new_type = buf->ReadByte(); } break; } case 'T': buf->ReadByte(); // lang buf->ReadString(); // actual text break; case 'B': { uint16 size = buf->ReadWord(); buf->Skip(size); break; } default: return false; } return true; } /** * Handle the nodes of an Action14 * @param type Type of node. * @param id ID. * @param buf Buffer. * @param subtags Allowed subtags. * @return Whether all tags could be handled. */ static bool HandleNode(byte type, uint32 id, ByteReader *buf, AllowedSubtags subtags[]) { uint i = 0; AllowedSubtags *tag; while ((tag = &subtags[i++])->type != 0) { if (tag->id != BSWAP32(id) || tag->type != type) continue; switch (type) { default: NOT_REACHED(); case 'T': { byte langid = buf->ReadByte(); return tag->handler.text(langid, buf->ReadString()); } case 'B': { size_t len = buf->ReadWord(); if (buf->Remaining() < len) return false; return tag->handler.data(len, buf); } case 'C': { if (tag->handler.call_handler) { return tag->handler.u.branch(buf); } return HandleNodes(buf, tag->handler.u.subtags); } } } grfmsg(2, "StaticGRFInfo: unknown type/id combination found, type=%c, id=%x", type, id); return SkipUnknownInfo(buf, type); } /** * Handle the contents of a 'C' choice of an Action14 * @param buf Buffer. * @param subtags List of subtags. * @return Whether the nodes could all be handled. */ static bool HandleNodes(ByteReader *buf, AllowedSubtags subtags[]) { byte type = buf->ReadByte(); while (type != 0) { uint32 id = buf->ReadDWord(); if (!HandleNode(type, id, buf, subtags)) return false; type = buf->ReadByte(); } return true; } /** * Handle Action 0x14 (static info) * @param buf Buffer. */ static void StaticGRFInfo(ByteReader *buf) { /* <14> */ HandleNodes(buf, _tags_root_static); } /** * Handle Action 0x14 (feature tests) * @param buf Buffer. */ static void Act14FeatureTest(ByteReader *buf) { /* <14> */ HandleNodes(buf, _tags_root_feature_tests); } /** * Set the current NewGRF as unsafe for static use * @param buf Unused. * @note Used during safety scan on unsafe actions. */ static void GRFUnsafe(ByteReader *buf) { SetBit(_cur.grfconfig->flags, GCF_UNSAFE); /* Skip remainder of GRF */ _cur.skip_sprites = -1; } /** Initialize the TTDPatch flags */ static void InitializeGRFSpecial() { _ttdpatch_flags[0] = ((_settings_game.station.never_expire_airports ? 1 : 0) << 0x0C) // keepsmallairport | (1 << 0x0D) // newairports | (1 << 0x0E) // largestations | ((_settings_game.construction.max_bridge_length > 16 ? 1 : 0) << 0x0F) // longbridges | (0 << 0x10) // loadtime | (1 << 0x12) // presignals | (1 << 0x13) // extpresignals | ((_settings_game.vehicle.never_expire_vehicles ? 1 : 0) << 0x16) // enginespersist | (1 << 0x1B) // multihead | (1 << 0x1D) // lowmemory | (1 << 0x1E); // generalfixes _ttdpatch_flags[1] = ((_settings_game.economy.station_noise_level ? 1 : 0) << 0x07) // moreairports - based on units of noise | (1 << 0x08) // mammothtrains | (1 << 0x09) // trainrefit | (0 << 0x0B) // subsidiaries | ((_settings_game.order.gradual_loading ? 1 : 0) << 0x0C) // gradualloading | (1 << 0x12) // unifiedmaglevmode - set bit 0 mode. Not revelant to OTTD | (1 << 0x13) // unifiedmaglevmode - set bit 1 mode | (1 << 0x14) // bridgespeedlimits | (1 << 0x16) // eternalgame | (1 << 0x17) // newtrains | (1 << 0x18) // newrvs | (1 << 0x19) // newships | (1 << 0x1A) // newplanes | ((_settings_game.construction.train_signal_side == 1 ? 1 : 0) << 0x1B) // signalsontrafficside | ((_settings_game.vehicle.disable_elrails ? 0 : 1) << 0x1C); // electrifiedrailway _ttdpatch_flags[2] = (1 << 0x01) // loadallgraphics - obsolote | (1 << 0x03) // semaphores | (1 << 0x0A) // newobjects | (0 << 0x0B) // enhancedgui | (0 << 0x0C) // newagerating | ((_settings_game.construction.build_on_slopes ? 1 : 0) << 0x0D) // buildonslopes | (1 << 0x0E) // fullloadany | (1 << 0x0F) // planespeed | (0 << 0x10) // moreindustriesperclimate - obsolete | (0 << 0x11) // moretoylandfeatures | (1 << 0x12) // newstations | (1 << 0x13) // tracktypecostdiff | (1 << 0x14) // manualconvert | ((_settings_game.construction.build_on_slopes ? 1 : 0) << 0x15) // buildoncoasts | (1 << 0x16) // canals | (1 << 0x17) // newstartyear | ((_settings_game.vehicle.freight_trains > 1 ? 1 : 0) << 0x18) // freighttrains | (1 << 0x19) // newhouses | (1 << 0x1A) // newbridges | (1 << 0x1B) // newtownnames | (1 << 0x1C) // moreanimation | ((_settings_game.vehicle.wagon_speed_limits ? 1 : 0) << 0x1D) // wagonspeedlimits | (1 << 0x1E) // newshistory | (0 << 0x1F); // custombridgeheads _ttdpatch_flags[3] = (0 << 0x00) // newcargodistribution | (1 << 0x01) // windowsnap | ((_settings_game.economy.allow_town_roads || _generating_world ? 0 : 1) << 0x02) // townbuildnoroad | (1 << 0x03) // pathbasedsignalling | (0 << 0x04) // aichoosechance | (1 << 0x05) // resolutionwidth | (1 << 0x06) // resolutionheight | (1 << 0x07) // newindustries | ((_settings_game.order.improved_load ? 1 : 0) << 0x08) // fifoloading | (0 << 0x09) // townroadbranchprob | (0 << 0x0A) // tempsnowline | (1 << 0x0B) // newcargo | (1 << 0x0C) // enhancemultiplayer | (1 << 0x0D) // onewayroads | (1 << 0x0E) // irregularstations | (1 << 0x0F) // statistics | (1 << 0x10) // newsounds | (1 << 0x11) // autoreplace | (1 << 0x12) // autoslope | (0 << 0x13) // followvehicle | (1 << 0x14) // trams | (0 << 0x15) // enhancetunnels | (1 << 0x16) // shortrvs | (1 << 0x17) // articulatedrvs | ((_settings_game.vehicle.dynamic_engines ? 1 : 0) << 0x18) // dynamic engines | (1 << 0x1E) // variablerunningcosts | (1 << 0x1F); // any switch is on _ttdpatch_flags[4] = (1 << 0x00) // larger persistent storage | ((_settings_game.economy.inflation ? 1 : 0) << 0x01); // inflation is on } /** Reset and clear all NewGRF stations */ static void ResetCustomStations() { for (GRFFile * const file : _grf_files) { StationSpec **&stations = file->stations; if (stations == nullptr) continue; for (uint i = 0; i < NUM_STATIONS_PER_GRF; i++) { if (stations[i] == nullptr) continue; StationSpec *statspec = stations[i]; /* Release this station */ delete statspec; } /* Free and reset the station data */ free(stations); stations = nullptr; } } /** Reset and clear all NewGRF houses */ static void ResetCustomHouses() { for (GRFFile * const file : _grf_files) { HouseSpec **&housespec = file->housespec; if (housespec == nullptr) continue; for (uint i = 0; i < NUM_HOUSES_PER_GRF; i++) { free(housespec[i]); } free(housespec); housespec = nullptr; } } /** Reset and clear all NewGRF airports */ static void ResetCustomAirports() { for (GRFFile * const file : _grf_files) { AirportSpec **aslist = file->airportspec; if (aslist != nullptr) { for (uint i = 0; i < NUM_AIRPORTS_PER_GRF; i++) { AirportSpec *as = aslist[i]; if (as != nullptr) { /* We need to remove the tiles layouts */ for (int j = 0; j < as->num_table; j++) { /* remove the individual layouts */ free(as->table[j]); } free(as->table); free(as->depot_table); free(as->rotation); free(as); } } free(aslist); file->airportspec = nullptr; } AirportTileSpec **&airporttilespec = file->airtspec; if (airporttilespec != nullptr) { for (uint i = 0; i < NUM_AIRPORTTILES_PER_GRF; i++) { free(airporttilespec[i]); } free(airporttilespec); airporttilespec = nullptr; } } } /** Reset and clear all NewGRF industries */ static void ResetCustomIndustries() { for (GRFFile * const file : _grf_files) { IndustrySpec **&industryspec = file->industryspec; IndustryTileSpec **&indtspec = file->indtspec; /* We are verifiying both tiles and industries specs loaded from the grf file * First, let's deal with industryspec */ if (industryspec != nullptr) { for (uint i = 0; i < NUM_INDUSTRYTYPES_PER_GRF; i++) { IndustrySpec *ind = industryspec[i]; delete ind; } free(industryspec); industryspec = nullptr; } if (indtspec == nullptr) continue; for (uint i = 0; i < NUM_INDUSTRYTILES_PER_GRF; i++) { free(indtspec[i]); } free(indtspec); indtspec = nullptr; } } /** Reset and clear all NewObjects */ static void ResetCustomObjects() { for (GRFFile * const file : _grf_files) { ObjectSpec **&objectspec = file->objectspec; if (objectspec == nullptr) continue; for (uint i = 0; i < NUM_OBJECTS_PER_GRF; i++) { free(objectspec[i]); } free(objectspec); objectspec = nullptr; } } static void ResetCustomRoadStops() { for (auto file : _grf_files) { RoadStopSpec **&roadstopspec = file->roadstops; if (roadstopspec == nullptr) continue; for (uint i = 0; i < NUM_ROADSTOPS_PER_GRF; i++) { free(roadstopspec[i]); } free(roadstopspec); roadstopspec = nullptr; } } /** Reset and clear all NewGRFs */ static void ResetNewGRF() { for (GRFFile * const file : _grf_files) { delete file; } _grf_files.clear(); _cur.grffile = nullptr; _new_signals_grfs.clear(); MemSetT(_new_signal_styles.data(), 0, MAX_NEW_SIGNAL_STYLES); _num_new_signal_styles = 0; _new_landscape_rocks_grfs.clear(); } /** Clear all NewGRF errors */ static void ResetNewGRFErrors() { for (GRFConfig *c = _grfconfig; c != nullptr; c = c->next) { if (!HasBit(c->flags, GCF_COPY) && c->error != nullptr) { delete c->error; c->error = nullptr; } } } /** * Reset all NewGRF loaded data */ void ResetNewGRFData() { CleanUpStrings(); CleanUpGRFTownNames(); /* Copy/reset original engine info data */ SetupEngines(); /* Copy/reset original bridge info data */ ResetBridges(); /* Reset rail type information */ ResetRailTypes(); /* Copy/reset original road type info data */ ResetRoadTypes(); /* Allocate temporary refit/cargo class data */ _gted = CallocT(Engine::GetPoolSize()); /* Fill rail type label temporary data for default trains */ for (const Engine *e : Engine::IterateType(VEH_TRAIN)) { _gted[e->index].railtypelabel = GetRailTypeInfo(e->u.rail.railtype)->label; } /* Reset GRM reservations */ memset(&_grm_engines, 0, sizeof(_grm_engines)); memset(&_grm_cargoes, 0, sizeof(_grm_cargoes)); /* Reset generic feature callback lists */ ResetGenericCallbacks(); /* Reset price base data */ ResetPriceBaseMultipliers(); /* Reset the curencies array */ ResetCurrencies(); /* Reset the house array */ ResetCustomHouses(); ResetHouses(); /* Reset the industries structures*/ ResetCustomIndustries(); ResetIndustries(); /* Reset the objects. */ ObjectClass::Reset(); ResetCustomObjects(); ResetObjects(); /* Reset station classes */ StationClass::Reset(); ResetCustomStations(); /* Reset airport-related structures */ AirportClass::Reset(); ResetCustomAirports(); AirportSpec::ResetAirports(); AirportTileSpec::ResetAirportTiles(); /* Reset road stop classes */ RoadStopClass::Reset(); ResetCustomRoadStops(); /* Reset canal sprite groups and flags */ memset(_water_feature, 0, sizeof(_water_feature)); /* Reset the snowline table. */ ClearSnowLine(); /* Reset NewGRF files */ ResetNewGRF(); /* Reset NewGRF errors. */ ResetNewGRFErrors(); /* Set up the default cargo types */ SetupCargoForClimate(_settings_game.game_creation.landscape); /* Reset misc GRF features and train list display variables */ _misc_grf_features = 0; _loaded_newgrf_features.has_2CC = false; _loaded_newgrf_features.used_liveries = 1 << LS_DEFAULT; _loaded_newgrf_features.shore = SHORE_REPLACE_NONE; _loaded_newgrf_features.tram = TRAMWAY_REPLACE_DEPOT_NONE; /* Clear all GRF overrides */ _grf_id_overrides.clear(); InitializeSoundPool(); _spritegroup_pool.CleanPool(); _callback_result_cache.clear(); _deterministic_sg_shadows.clear(); _randomized_sg_shadows.clear(); _grfs_loaded_with_sg_shadow_enable = HasBit(_misc_debug_flags, MDF_NEWGRF_SG_SAVE_RAW); } /** * Reset NewGRF data which is stored persistently in savegames. */ void ResetPersistentNewGRFData() { /* Reset override managers */ _engine_mngr.ResetToDefaultMapping(); _house_mngr.ResetMapping(); _industry_mngr.ResetMapping(); _industile_mngr.ResetMapping(); _airport_mngr.ResetMapping(); _airporttile_mngr.ResetMapping(); } /** * Construct the Cargo Mapping * @note This is the reverse of a cargo translation table */ static void BuildCargoTranslationMap() { memset(_cur.grffile->cargo_map, 0xFF, sizeof(_cur.grffile->cargo_map)); for (CargoID c = 0; c < NUM_CARGO; c++) { const CargoSpec *cs = CargoSpec::Get(c); if (!cs->IsValid()) continue; if (_cur.grffile->cargo_list.size() == 0) { /* Default translation table, so just a straight mapping to bitnum */ _cur.grffile->cargo_map[c] = cs->bitnum; } else { /* Check the translation table for this cargo's label */ int idx = find_index(_cur.grffile->cargo_list, {cs->label}); if (idx >= 0) _cur.grffile->cargo_map[c] = idx; } } } /** * Prepare loading a NewGRF file with its config * @param config The NewGRF configuration struct with name, id, parameters and alike. */ static void InitNewGRFFile(const GRFConfig *config) { GRFFile *newfile = GetFileByFilename(config->filename); if (newfile != nullptr) { /* We already loaded it once. */ _cur.grffile = newfile; return; } newfile = new GRFFile(config); _grf_files.push_back(_cur.grffile = newfile); } /** * Constructor for GRFFile * @param config GRFConfig to copy name, grfid and parameters from. */ GRFFile::GRFFile(const GRFConfig *config) { this->filename = stredup(config->filename); this->grfid = config->ident.grfid; /* Initialise local settings to defaults */ this->traininfo_vehicle_pitch = 0; this->traininfo_vehicle_width = TRAININFO_DEFAULT_VEHICLE_WIDTH; this->new_signals_group = nullptr; this->new_signal_ctrl_flags = 0; this->new_signal_extra_aspects = 0; this->new_signal_style_mask = 1; this->current_new_signal_style = nullptr; this->new_rocks_group = nullptr; this->new_landscape_ctrl_flags = 0; /* Mark price_base_multipliers as 'not set' */ for (Price i = PR_BEGIN; i < PR_END; i++) { this->price_base_multipliers[i] = INVALID_PRICE_MODIFIER; } /* Initialise rail type map with default rail types */ std::fill(std::begin(this->railtype_map), std::end(this->railtype_map), INVALID_RAILTYPE); this->railtype_map[0] = RAILTYPE_RAIL; this->railtype_map[1] = RAILTYPE_ELECTRIC; this->railtype_map[2] = RAILTYPE_MONO; this->railtype_map[3] = RAILTYPE_MAGLEV; /* Initialise road type map with default road types */ std::fill(std::begin(this->roadtype_map), std::end(this->roadtype_map), INVALID_ROADTYPE); this->roadtype_map[0] = ROADTYPE_ROAD; /* Initialise tram type map with default tram types */ std::fill(std::begin(this->tramtype_map), std::end(this->tramtype_map), INVALID_ROADTYPE); this->tramtype_map[0] = ROADTYPE_TRAM; /* Copy the initial parameter list * 'Uninitialised' parameters are zeroed as that is their default value when dynamically creating them. */ static_assert(lengthof(this->param) == lengthof(config->param) && lengthof(this->param) == 0x80); assert(config->num_params <= lengthof(config->param)); this->param_end = config->num_params; if (this->param_end > 0) { MemCpyT(this->param, config->param, this->param_end); } } GRFFile::~GRFFile() { free(this->filename); delete[] this->language_map; } /** * Precalculate refit masks from cargo classes for all vehicles. */ static void CalculateRefitMasks() { CargoTypes original_known_cargoes = 0; for (int ct = 0; ct != NUM_ORIGINAL_CARGO; ++ct) { CargoID cid = GetDefaultCargoID(_settings_game.game_creation.landscape, static_cast(ct)); if (cid != CT_INVALID) SetBit(original_known_cargoes, cid); } for (Engine *e : Engine::Iterate()) { EngineID engine = e->index; EngineInfo *ei = &e->info; bool only_defaultcargo; ///< Set if the vehicle shall carry only the default cargo /* If the NewGRF did not set any cargo properties, we apply default values. */ if (_gted[engine].defaultcargo_grf == nullptr) { /* If the vehicle has any capacity, apply the default refit masks */ if (e->type != VEH_TRAIN || e->u.rail.capacity != 0) { static constexpr byte T = 1 << LT_TEMPERATE; static constexpr byte A = 1 << LT_ARCTIC; static constexpr byte S = 1 << LT_TROPIC; static constexpr byte Y = 1 << LT_TOYLAND; static const struct DefaultRefitMasks { byte climate; CargoType cargo_type; CargoTypes cargo_allowed; CargoTypes cargo_disallowed; } _default_refit_masks[] = { {T | A | S | Y, CT_PASSENGERS, CC_PASSENGERS, 0}, {T | A | S , CT_MAIL, CC_MAIL, 0}, {T | A | S , CT_VALUABLES, CC_ARMOURED, CC_LIQUID}, { Y, CT_MAIL, CC_MAIL | CC_ARMOURED, CC_LIQUID}, {T | A , CT_COAL, CC_BULK, 0}, { S , CT_COPPER_ORE, CC_BULK, 0}, { Y, CT_SUGAR, CC_BULK, 0}, {T | A | S , CT_OIL, CC_LIQUID, 0}, { Y, CT_COLA, CC_LIQUID, 0}, {T , CT_GOODS, CC_PIECE_GOODS | CC_EXPRESS, CC_LIQUID | CC_PASSENGERS}, { A | S , CT_GOODS, CC_PIECE_GOODS | CC_EXPRESS, CC_LIQUID | CC_PASSENGERS | CC_REFRIGERATED}, { A | S , CT_FOOD, CC_REFRIGERATED, 0}, { Y, CT_CANDY, CC_PIECE_GOODS | CC_EXPRESS, CC_LIQUID | CC_PASSENGERS}, }; if (e->type == VEH_AIRCRAFT) { /* Aircraft default to "light" cargoes */ _gted[engine].cargo_allowed = CC_PASSENGERS | CC_MAIL | CC_ARMOURED | CC_EXPRESS; _gted[engine].cargo_disallowed = CC_LIQUID; } else if (e->type == VEH_SHIP) { switch (ei->cargo_type) { case CT_PASSENGERS: /* Ferries */ _gted[engine].cargo_allowed = CC_PASSENGERS; _gted[engine].cargo_disallowed = 0; break; case CT_OIL: /* Tankers */ _gted[engine].cargo_allowed = CC_LIQUID; _gted[engine].cargo_disallowed = 0; break; default: /* Cargo ships */ if (_settings_game.game_creation.landscape == LT_TOYLAND) { /* No tanker in toyland :( */ _gted[engine].cargo_allowed = CC_MAIL | CC_ARMOURED | CC_EXPRESS | CC_BULK | CC_PIECE_GOODS | CC_LIQUID; _gted[engine].cargo_disallowed = CC_PASSENGERS; } else { _gted[engine].cargo_allowed = CC_MAIL | CC_ARMOURED | CC_EXPRESS | CC_BULK | CC_PIECE_GOODS; _gted[engine].cargo_disallowed = CC_LIQUID | CC_PASSENGERS; } break; } e->u.ship.old_refittable = true; } else if (e->type == VEH_TRAIN && e->u.rail.railveh_type != RAILVEH_WAGON) { /* Train engines default to all cargoes, so you can build single-cargo consists with fast engines. * Trains loading multiple cargoes may start stations accepting unwanted cargoes. */ _gted[engine].cargo_allowed = CC_PASSENGERS | CC_MAIL | CC_ARMOURED | CC_EXPRESS | CC_BULK | CC_PIECE_GOODS | CC_LIQUID; _gted[engine].cargo_disallowed = 0; } else { /* Train wagons and road vehicles are classified by their default cargo type */ for (const auto &drm : _default_refit_masks) { if (!HasBit(drm.climate, _settings_game.game_creation.landscape)) continue; if (drm.cargo_type != ei->cargo_type) continue; _gted[engine].cargo_allowed = drm.cargo_allowed; _gted[engine].cargo_disallowed = drm.cargo_disallowed; break; } /* All original cargoes have specialised vehicles, so exclude them */ _gted[engine].ctt_exclude_mask = original_known_cargoes; } } _gted[engine].UpdateRefittability(_gted[engine].cargo_allowed != 0); /* Translate cargo_type using the original climate-specific cargo table. */ ei->cargo_type = GetDefaultCargoID(_settings_game.game_creation.landscape, static_cast(ei->cargo_type)); if (ei->cargo_type != CT_INVALID) ClrBit(_gted[engine].ctt_exclude_mask, ei->cargo_type); } /* Compute refittability */ { CargoTypes mask = 0; CargoTypes not_mask = 0; CargoTypes xor_mask = ei->refit_mask; /* If the original masks set by the grf are zero, the vehicle shall only carry the default cargo. * Note: After applying the translations, the vehicle may end up carrying no defined cargo. It becomes unavailable in that case. */ only_defaultcargo = _gted[engine].refittability != GRFTempEngineData::NONEMPTY; if (_gted[engine].cargo_allowed != 0) { /* Build up the list of cargo types from the set cargo classes. */ for (const CargoSpec *cs : CargoSpec::Iterate()) { if (_gted[engine].cargo_allowed & cs->classes) SetBit(mask, cs->Index()); if (_gted[engine].cargo_disallowed & cs->classes) SetBit(not_mask, cs->Index()); } } ei->refit_mask = ((mask & ~not_mask) ^ xor_mask) & _cargo_mask; /* Apply explicit refit includes/excludes. */ ei->refit_mask |= _gted[engine].ctt_include_mask; ei->refit_mask &= ~_gted[engine].ctt_exclude_mask; } /* Clear invalid cargoslots (from default vehicles or pre-NewCargo GRFs) */ if (ei->cargo_type != CT_INVALID && !HasBit(_cargo_mask, ei->cargo_type)) ei->cargo_type = CT_INVALID; /* Ensure that the vehicle is either not refittable, or that the default cargo is one of the refittable cargoes. * Note: Vehicles refittable to no cargo are handle differently to vehicle refittable to a single cargo. The latter might have subtypes. */ if (!only_defaultcargo && (e->type != VEH_SHIP || e->u.ship.old_refittable) && ei->cargo_type != CT_INVALID && !HasBit(ei->refit_mask, ei->cargo_type)) { ei->cargo_type = CT_INVALID; } /* Check if this engine's cargo type is valid. If not, set to the first refittable * cargo type. Finally disable the vehicle, if there is still no cargo. */ if (ei->cargo_type == CT_INVALID && ei->refit_mask != 0) { /* Figure out which CTT to use for the default cargo, if it is 'first refittable'. */ const uint8 *cargo_map_for_first_refittable = nullptr; { const GRFFile *file = _gted[engine].defaultcargo_grf; if (file == nullptr) file = e->GetGRF(); if (file != nullptr && file->grf_version >= 8 && file->cargo_list.size() != 0) { cargo_map_for_first_refittable = file->cargo_map; } } if (cargo_map_for_first_refittable != nullptr) { /* Use first refittable cargo from cargo translation table */ byte best_local_slot = 0xFF; for (CargoID cargo_type : SetCargoBitIterator(ei->refit_mask)) { byte local_slot = cargo_map_for_first_refittable[cargo_type]; if (local_slot < best_local_slot) { best_local_slot = local_slot; ei->cargo_type = cargo_type; } } } if (ei->cargo_type == CT_INVALID) { /* Use first refittable cargo slot */ ei->cargo_type = (CargoID)FindFirstBit(ei->refit_mask); } } if (ei->cargo_type == CT_INVALID) ei->climates = 0; /* Clear refit_mask for not refittable ships */ if (e->type == VEH_SHIP && !e->u.ship.old_refittable) { ei->refit_mask = 0; } } } /** Set to use the correct action0 properties for each canal feature */ static void FinaliseCanals() { for (uint i = 0; i < CF_END; i++) { if (_water_feature[i].grffile != nullptr) { _water_feature[i].callback_mask = _water_feature[i].grffile->canal_local_properties[i].callback_mask; _water_feature[i].flags = _water_feature[i].grffile->canal_local_properties[i].flags; } } } /** Check for invalid engines */ static void FinaliseEngineArray() { for (Engine *e : Engine::Iterate()) { if (e->GetGRF() == nullptr) { const EngineIDMapping &eid = _engine_mngr[e->index]; if (eid.grfid != INVALID_GRFID || eid.internal_id != eid.substitute_id) { e->info.string_id = STR_NEWGRF_INVALID_ENGINE; } } if (!HasBit(e->info.climates, _settings_game.game_creation.landscape)) continue; /* When the train does not set property 27 (misc flags), but it * is overridden by a NewGRF graphically we want to disable the * flipping possibility. */ if (e->type == VEH_TRAIN && !_gted[e->index].prop27_set && e->GetGRF() != nullptr && is_custom_sprite(e->u.rail.image_index)) { ClrBit(e->info.misc_flags, EF_RAIL_FLIPS); } /* Skip wagons, there livery is defined via the engine */ if (e->type != VEH_TRAIN || e->u.rail.railveh_type != RAILVEH_WAGON) { LiveryScheme ls = GetEngineLiveryScheme(e->index, INVALID_ENGINE, nullptr); SetBit(_loaded_newgrf_features.used_liveries, ls); /* Note: For ships and roadvehicles we assume that they cannot be refitted between passenger and freight */ if (e->type == VEH_TRAIN) { SetBit(_loaded_newgrf_features.used_liveries, LS_FREIGHT_WAGON); switch (ls) { case LS_STEAM: case LS_DIESEL: case LS_ELECTRIC: case LS_MONORAIL: case LS_MAGLEV: SetBit(_loaded_newgrf_features.used_liveries, LS_PASSENGER_WAGON_STEAM + ls - LS_STEAM); break; case LS_DMU: case LS_EMU: SetBit(_loaded_newgrf_features.used_liveries, LS_PASSENGER_WAGON_DIESEL + ls - LS_DMU); break; default: NOT_REACHED(); } } } } } /** Check for invalid cargoes */ static void FinaliseCargoArray() { for (CargoID c = 0; c < NUM_CARGO; c++) { CargoSpec *cs = CargoSpec::Get(c); if (!cs->IsValid()) { cs->name = cs->name_single = cs->units_volume = STR_NEWGRF_INVALID_CARGO; cs->quantifier = STR_NEWGRF_INVALID_CARGO_QUANTITY; cs->abbrev = STR_NEWGRF_INVALID_CARGO_ABBREV; } } } /** * Check if a given housespec is valid and disable it if it's not. * The housespecs that follow it are used to check the validity of * multitile houses. * @param hs The housespec to check. * @param next1 The housespec that follows \c hs. * @param next2 The housespec that follows \c next1. * @param next3 The housespec that follows \c next2. * @param filename The filename of the newgrf this house was defined in. * @return Whether the given housespec is valid. */ static bool IsHouseSpecValid(HouseSpec *hs, const HouseSpec *next1, const HouseSpec *next2, const HouseSpec *next3, const char *filename) { if (((hs->building_flags & BUILDING_HAS_2_TILES) != 0 && (next1 == nullptr || !next1->enabled || (next1->building_flags & BUILDING_HAS_1_TILE) != 0)) || ((hs->building_flags & BUILDING_HAS_4_TILES) != 0 && (next2 == nullptr || !next2->enabled || (next2->building_flags & BUILDING_HAS_1_TILE) != 0 || next3 == nullptr || !next3->enabled || (next3->building_flags & BUILDING_HAS_1_TILE) != 0))) { hs->enabled = false; if (filename != nullptr) DEBUG(grf, 1, "FinaliseHouseArray: %s defines house %d as multitile, but no suitable tiles follow. Disabling house.", filename, hs->grf_prop.local_id); return false; } /* Some places sum population by only counting north tiles. Other places use all tiles causing desyncs. * As the newgrf specs define population to be zero for non-north tiles, we just disable the offending house. * If you want to allow non-zero populations somewhen, make sure to sum the population of all tiles in all places. */ if (((hs->building_flags & BUILDING_HAS_2_TILES) != 0 && next1->population != 0) || ((hs->building_flags & BUILDING_HAS_4_TILES) != 0 && (next2->population != 0 || next3->population != 0))) { hs->enabled = false; if (filename != nullptr) DEBUG(grf, 1, "FinaliseHouseArray: %s defines multitile house %d with non-zero population on additional tiles. Disabling house.", filename, hs->grf_prop.local_id); return false; } /* Substitute type is also used for override, and having an override with a different size causes crashes. * This check should only be done for NewGRF houses because grf_prop.subst_id is not set for original houses.*/ if (filename != nullptr && (hs->building_flags & BUILDING_HAS_1_TILE) != (HouseSpec::Get(hs->grf_prop.subst_id)->building_flags & BUILDING_HAS_1_TILE)) { hs->enabled = false; DEBUG(grf, 1, "FinaliseHouseArray: %s defines house %d with different house size then it's substitute type. Disabling house.", filename, hs->grf_prop.local_id); return false; } /* Make sure that additional parts of multitile houses are not available. */ if ((hs->building_flags & BUILDING_HAS_1_TILE) == 0 && (hs->building_availability & HZ_ZONALL) != 0 && (hs->building_availability & HZ_CLIMALL) != 0) { hs->enabled = false; if (filename != nullptr) DEBUG(grf, 1, "FinaliseHouseArray: %s defines house %d without a size but marked it as available. Disabling house.", filename, hs->grf_prop.local_id); return false; } return true; } /** * Make sure there is at least one house available in the year 0 for the given * climate / housezone combination. * @param bitmask The climate and housezone to check for. Exactly one climate * bit and one housezone bit should be set. */ static void EnsureEarlyHouse(HouseZones bitmask) { Year min_year = MAX_YEAR; for (int i = 0; i < NUM_HOUSES; i++) { HouseSpec *hs = HouseSpec::Get(i); if (hs == nullptr || !hs->enabled) continue; if ((hs->building_availability & bitmask) != bitmask) continue; if (hs->min_year < min_year) min_year = hs->min_year; } if (min_year == 0) return; for (int i = 0; i < NUM_HOUSES; i++) { HouseSpec *hs = HouseSpec::Get(i); if (hs == nullptr || !hs->enabled) continue; if ((hs->building_availability & bitmask) != bitmask) continue; if (hs->min_year == min_year) hs->min_year = 0; } } /** * Add all new houses to the house array. House properties can be set at any * time in the GRF file, so we can only add a house spec to the house array * after the file has finished loading. We also need to check the dates, due to * the TTDPatch behaviour described below that we need to emulate. */ static void FinaliseHouseArray() { /* If there are no houses with start dates before 1930, then all houses * with start dates of 1930 have them reset to 0. This is in order to be * compatible with TTDPatch, where if no houses have start dates before * 1930 and the date is before 1930, the game pretends that this is 1930. * If there have been any houses defined with start dates before 1930 then * the dates are left alone. * On the other hand, why 1930? Just 'fix' the houses with the lowest * minimum introduction date to 0. */ for (GRFFile * const file : _grf_files) { HouseSpec **&housespec = file->housespec; if (housespec == nullptr) continue; for (int i = 0; i < NUM_HOUSES_PER_GRF; i++) { HouseSpec *hs = housespec[i]; if (hs == nullptr) continue; const HouseSpec *next1 = (i + 1 < NUM_HOUSES_PER_GRF ? housespec[i + 1] : nullptr); const HouseSpec *next2 = (i + 2 < NUM_HOUSES_PER_GRF ? housespec[i + 2] : nullptr); const HouseSpec *next3 = (i + 3 < NUM_HOUSES_PER_GRF ? housespec[i + 3] : nullptr); if (!IsHouseSpecValid(hs, next1, next2, next3, file->filename)) continue; _house_mngr.SetEntitySpec(hs); } } for (int i = 0; i < NUM_HOUSES; i++) { HouseSpec *hs = HouseSpec::Get(i); const HouseSpec *next1 = (i + 1 < NUM_HOUSES ? HouseSpec::Get(i + 1) : nullptr); const HouseSpec *next2 = (i + 2 < NUM_HOUSES ? HouseSpec::Get(i + 2) : nullptr); const HouseSpec *next3 = (i + 3 < NUM_HOUSES ? HouseSpec::Get(i + 3) : nullptr); /* We need to check all houses again to we are sure that multitile houses * did get consecutive IDs and none of the parts are missing. */ if (!IsHouseSpecValid(hs, next1, next2, next3, nullptr)) { /* GetHouseNorthPart checks 3 houses that are directly before * it in the house pool. If any of those houses have multi-tile * flags set it assumes it's part of a multitile house. Since * we can have invalid houses in the pool marked as disabled, we * don't want to have them influencing valid tiles. As such set * building_flags to zero here to make sure any house following * this one in the pool is properly handled as 1x1 house. */ hs->building_flags = TILE_NO_FLAG; } } HouseZones climate_mask = (HouseZones)(1 << (_settings_game.game_creation.landscape + 12)); EnsureEarlyHouse(HZ_ZON1 | climate_mask); EnsureEarlyHouse(HZ_ZON2 | climate_mask); EnsureEarlyHouse(HZ_ZON3 | climate_mask); EnsureEarlyHouse(HZ_ZON4 | climate_mask); EnsureEarlyHouse(HZ_ZON5 | climate_mask); if (_settings_game.game_creation.landscape == LT_ARCTIC) { EnsureEarlyHouse(HZ_ZON1 | HZ_SUBARTC_ABOVE); EnsureEarlyHouse(HZ_ZON2 | HZ_SUBARTC_ABOVE); EnsureEarlyHouse(HZ_ZON3 | HZ_SUBARTC_ABOVE); EnsureEarlyHouse(HZ_ZON4 | HZ_SUBARTC_ABOVE); EnsureEarlyHouse(HZ_ZON5 | HZ_SUBARTC_ABOVE); } } /** * Add all new industries to the industry array. Industry properties can be set at any * time in the GRF file, so we can only add a industry spec to the industry array * after the file has finished loading. */ static void FinaliseIndustriesArray() { for (GRFFile * const file : _grf_files) { IndustrySpec **&industryspec = file->industryspec; IndustryTileSpec **&indtspec = file->indtspec; if (industryspec != nullptr) { for (int i = 0; i < NUM_INDUSTRYTYPES_PER_GRF; i++) { IndustrySpec *indsp = industryspec[i]; if (indsp != nullptr && indsp->enabled) { StringID strid; /* process the conversion of text at the end, so to be sure everything will be fine * and available. Check if it does not return undefind marker, which is a very good sign of a * substitute industry who has not changed the string been examined, thus using it as such */ strid = GetGRFStringID(indsp->grf_prop.grffile->grfid, indsp->name); if (strid != STR_UNDEFINED) indsp->name = strid; strid = GetGRFStringID(indsp->grf_prop.grffile->grfid, indsp->closure_text); if (strid != STR_UNDEFINED) indsp->closure_text = strid; strid = GetGRFStringID(indsp->grf_prop.grffile->grfid, indsp->production_up_text); if (strid != STR_UNDEFINED) indsp->production_up_text = strid; strid = GetGRFStringID(indsp->grf_prop.grffile->grfid, indsp->production_down_text); if (strid != STR_UNDEFINED) indsp->production_down_text = strid; strid = GetGRFStringID(indsp->grf_prop.grffile->grfid, indsp->new_industry_text); if (strid != STR_UNDEFINED) indsp->new_industry_text = strid; if (indsp->station_name != STR_NULL) { /* STR_NULL (0) can be set by grf. It has a meaning regarding assignation of the * station's name. Don't want to lose the value, therefore, do not process. */ strid = GetGRFStringID(indsp->grf_prop.grffile->grfid, indsp->station_name); if (strid != STR_UNDEFINED) indsp->station_name = strid; } _industry_mngr.SetEntitySpec(indsp); } } } if (indtspec != nullptr) { for (int i = 0; i < NUM_INDUSTRYTILES_PER_GRF; i++) { IndustryTileSpec *indtsp = indtspec[i]; if (indtsp != nullptr) { _industile_mngr.SetEntitySpec(indtsp); } } } } for (uint j = 0; j < NUM_INDUSTRYTYPES; j++) { IndustrySpec *indsp = &_industry_specs[j]; if (indsp->enabled && indsp->grf_prop.grffile != nullptr) { for (uint i = 0; i < 3; i++) { indsp->conflicting[i] = MapNewGRFIndustryType(indsp->conflicting[i], indsp->grf_prop.grffile->grfid); } } if (!indsp->enabled) { indsp->name = STR_NEWGRF_INVALID_INDUSTRYTYPE; } } } /** * Add all new objects to the object array. Object properties can be set at any * time in the GRF file, so we can only add an object spec to the object array * after the file has finished loading. */ static void FinaliseObjectsArray() { for (GRFFile * const file : _grf_files) { ObjectSpec **&objectspec = file->objectspec; if (objectspec != nullptr) { for (int i = 0; i < NUM_OBJECTS_PER_GRF; i++) { if (objectspec[i] != nullptr && objectspec[i]->grf_prop.grffile != nullptr && objectspec[i]->enabled) { _object_mngr.SetEntitySpec(objectspec[i]); } } } } } /** * Add all new airports to the airport array. Airport properties can be set at any * time in the GRF file, so we can only add a airport spec to the airport array * after the file has finished loading. */ static void FinaliseAirportsArray() { for (GRFFile * const file : _grf_files) { AirportSpec **&airportspec = file->airportspec; if (airportspec != nullptr) { for (int i = 0; i < NUM_AIRPORTS_PER_GRF; i++) { if (airportspec[i] != nullptr && airportspec[i]->enabled) { _airport_mngr.SetEntitySpec(airportspec[i]); } } } AirportTileSpec **&airporttilespec = file->airtspec; if (airporttilespec != nullptr) { for (uint i = 0; i < NUM_AIRPORTTILES_PER_GRF; i++) { if (airporttilespec[i] != nullptr && airporttilespec[i]->enabled) { _airporttile_mngr.SetEntitySpec(airporttilespec[i]); } } } } } /* Here we perform initial decoding of some special sprites (as are they * described at http://www.ttdpatch.net/src/newgrf.txt, but this is only a very * partial implementation yet). * XXX: We consider GRF files trusted. It would be trivial to exploit OTTD by * a crafted invalid GRF file. We should tell that to the user somehow, or * better make this more robust in the future. */ static void DecodeSpecialSprite(byte *buf, uint num, GrfLoadingStage stage) { /* XXX: There is a difference between staged loading in TTDPatch and * here. In TTDPatch, for some reason actions 1 and 2 are carried out * during stage 1, whilst action 3 is carried out during stage 2 (to * "resolve" cargo IDs... wtf). This is a little problem, because cargo * IDs are valid only within a given set (action 1) block, and may be * overwritten after action 3 associates them. But overwriting happens * in an earlier stage than associating, so... We just process actions * 1 and 2 in stage 2 now, let's hope that won't get us into problems. * --pasky * We need a pre-stage to set up GOTO labels of Action 0x10 because the grf * is not in memory and scanning the file every time would be too expensive. * In other stages we skip action 0x10 since it's already dealt with. */ static const SpecialSpriteHandler handlers[][GLS_END] = { /* 0x00 */ { nullptr, SafeChangeInfo, nullptr, nullptr, ReserveChangeInfo, FeatureChangeInfo, }, /* 0x01 */ { SkipAct1, SkipAct1, SkipAct1, SkipAct1, SkipAct1, NewSpriteSet, }, /* 0x02 */ { nullptr, nullptr, nullptr, nullptr, nullptr, NewSpriteGroup, }, /* 0x03 */ { nullptr, GRFUnsafe, nullptr, nullptr, nullptr, FeatureMapSpriteGroup, }, /* 0x04 */ { nullptr, nullptr, nullptr, nullptr, nullptr, FeatureNewName, }, /* 0x05 */ { SkipAct5, SkipAct5, SkipAct5, SkipAct5, SkipAct5, GraphicsNew, }, /* 0x06 */ { nullptr, nullptr, nullptr, CfgApply, CfgApply, CfgApply, }, /* 0x07 */ { nullptr, nullptr, nullptr, nullptr, SkipIf, SkipIf, }, /* 0x08 */ { ScanInfo, nullptr, nullptr, GRFInfo, GRFInfo, GRFInfo, }, /* 0x09 */ { nullptr, nullptr, nullptr, SkipIf, SkipIf, SkipIf, }, /* 0x0A */ { SkipActA, SkipActA, SkipActA, SkipActA, SkipActA, SpriteReplace, }, /* 0x0B */ { nullptr, nullptr, nullptr, GRFLoadError, GRFLoadError, GRFLoadError, }, /* 0x0C */ { nullptr, nullptr, nullptr, GRFComment, nullptr, GRFComment, }, /* 0x0D */ { nullptr, SafeParamSet, nullptr, ParamSet, ParamSet, ParamSet, }, /* 0x0E */ { nullptr, SafeGRFInhibit, nullptr, GRFInhibit, GRFInhibit, GRFInhibit, }, /* 0x0F */ { nullptr, GRFUnsafe, nullptr, FeatureTownName, nullptr, nullptr, }, /* 0x10 */ { nullptr, nullptr, DefineGotoLabel, nullptr, nullptr, nullptr, }, /* 0x11 */ { SkipAct11, GRFUnsafe, SkipAct11, GRFSound, SkipAct11, GRFSound, }, /* 0x12 */ { SkipAct12, SkipAct12, SkipAct12, SkipAct12, SkipAct12, LoadFontGlyph, }, /* 0x13 */ { nullptr, nullptr, nullptr, nullptr, nullptr, TranslateGRFStrings, }, /* 0x14 */ { StaticGRFInfo, nullptr, nullptr, Act14FeatureTest,nullptr, nullptr, }, }; GRFLocation location(_cur.grfconfig->ident.grfid, _cur.nfo_line); GRFLineToSpriteOverride::iterator it = _grf_line_to_action6_sprite_override.find(location); _action6_override_active = (it != _grf_line_to_action6_sprite_override.end()); if (it == _grf_line_to_action6_sprite_override.end()) { /* No preloaded sprite to work with; read the * pseudo sprite content. */ _cur.file->ReadBlock(buf, num); } else { /* Use the preloaded sprite data. */ buf = it->second; grfmsg(7, "DecodeSpecialSprite: Using preloaded pseudo sprite data"); /* Skip the real (original) content of this action. */ _cur.file->SeekTo(num, SEEK_CUR); } ByteReader br(buf, buf + num); ByteReader *bufp = &br; try { byte action = bufp->ReadByte(); if (action == 0xFF) { grfmsg(2, "DecodeSpecialSprite: Unexpected data block, skipping"); } else if (action == 0xFE) { grfmsg(2, "DecodeSpecialSprite: Unexpected import block, skipping"); } else if (action >= lengthof(handlers)) { grfmsg(7, "DecodeSpecialSprite: Skipping unknown action 0x%02X", action); } else if (handlers[action][stage] == nullptr) { grfmsg(7, "DecodeSpecialSprite: Skipping action 0x%02X in stage %d", action, stage); } else { grfmsg(7, "DecodeSpecialSprite: Handling action 0x%02X in stage %d", action, stage); handlers[action][stage](bufp); } } catch (...) { grfmsg(1, "DecodeSpecialSprite: Tried to read past end of pseudo-sprite data"); DisableGrf(STR_NEWGRF_ERROR_READ_BOUNDS); } } /** * Load a particular NewGRF from a SpriteFile. * @param config The configuration of the to be loaded NewGRF. * @param stage The loading stage of the NewGRF. * @param file The file to load the GRF data from. */ static void LoadNewGRFFileFromFile(GRFConfig *config, GrfLoadingStage stage, SpriteFile &file) { _cur.file = &file; _cur.grfconfig = config; DEBUG(grf, 2, "LoadNewGRFFile: Reading NewGRF-file '%s'", config->GetDisplayPath()); byte grf_container_version = file.GetContainerVersion(); if (grf_container_version == 0) { DEBUG(grf, 7, "LoadNewGRFFile: Custom .grf has invalid format"); return; } if (stage == GLS_INIT || stage == GLS_ACTIVATION) { /* We need the sprite offsets in the init stage for NewGRF sounds * and in the activation stage for real sprites. */ ReadGRFSpriteOffsets(file); } else { /* Skip sprite section offset if present. */ if (grf_container_version >= 2) file.ReadDword(); } if (grf_container_version >= 2) { /* Read compression value. */ byte compression = file.ReadByte(); if (compression != 0) { DEBUG(grf, 7, "LoadNewGRFFile: Unsupported compression format"); return; } } /* Skip the first sprite; we don't care about how many sprites this * does contain; newest TTDPatches and George's longvehicles don't * neither, apparently. */ uint32 num = grf_container_version >= 2 ? file.ReadDword() : file.ReadWord(); if (num == 4 && file.ReadByte() == 0xFF) { file.ReadDword(); } else { DEBUG(grf, 7, "LoadNewGRFFile: Custom .grf has invalid format"); return; } _cur.ClearDataForNextFile(); ReusableBuffer buf; while ((num = (grf_container_version >= 2 ? file.ReadDword() : file.ReadWord())) != 0) { byte type = file.ReadByte(); _cur.nfo_line++; if (type == 0xFF) { if (_cur.skip_sprites == 0) { DecodeSpecialSprite(buf.Allocate(num), num, stage); /* Stop all processing if we are to skip the remaining sprites */ if (_cur.skip_sprites == -1) break; continue; } else { file.SkipBytes(num); } } else { if (_cur.skip_sprites == 0) { grfmsg(0, "LoadNewGRFFile: Unexpected sprite, disabling"); DisableGrf(STR_NEWGRF_ERROR_UNEXPECTED_SPRITE); break; } if (grf_container_version >= 2 && type == 0xFD) { /* Reference to data section. Container version >= 2 only. */ file.SkipBytes(num); } else { file.SkipBytes(7); SkipSpriteData(file, type, num - 8); } } if (_cur.skip_sprites > 0) _cur.skip_sprites--; } } /** * Load a particular NewGRF. * @param config The configuration of the to be loaded NewGRF. * @param stage The loading stage of the NewGRF. * @param subdir The sub directory to find the NewGRF in. * @param temporary The NewGRF/sprite file is to be loaded temporarily and should be closed immediately, * contrary to loading the SpriteFile and having it cached by the SpriteCache. */ void LoadNewGRFFile(GRFConfig *config, GrfLoadingStage stage, Subdirectory subdir, bool temporary) { const char *filename = config->filename; /* A .grf file is activated only if it was active when the game was * started. If a game is loaded, only its active .grfs will be * reactivated, unless "loadallgraphics on" is used. A .grf file is * considered active if its action 8 has been processed, i.e. its * action 8 hasn't been skipped using an action 7. * * During activation, only actions 0, 1, 2, 3, 4, 5, 7, 8, 9, 0A and 0B are * carried out. All others are ignored, because they only need to be * processed once at initialization. */ if (stage != GLS_FILESCAN && stage != GLS_SAFETYSCAN && stage != GLS_LABELSCAN) { _cur.grffile = GetFileByFilename(filename); if (_cur.grffile == nullptr) usererror("File '%s' lost in cache.\n", filename); if (stage == GLS_RESERVE && config->status != GCS_INITIALISED) return; if (stage == GLS_ACTIVATION && !HasBit(config->flags, GCF_RESERVED)) return; } bool needs_palette_remap = config->palette & GRFP_USE_MASK; if (temporary) { SpriteFile temporarySpriteFile(filename, subdir, needs_palette_remap); LoadNewGRFFileFromFile(config, stage, temporarySpriteFile); } else { SpriteFile &file = OpenCachedSpriteFile(filename, subdir, needs_palette_remap); LoadNewGRFFileFromFile(config, stage, file); file.flags |= SFF_USERGRF; if (config->ident.grfid == BSWAP32(0xFF4F4701)) file.flags |= SFF_OGFX; } } /** * Relocates the old shore sprites at new positions. * * 1. If shore sprites are neither loaded by Action5 nor ActionA, the extra sprites from openttd(w/d).grf are used. (SHORE_REPLACE_ONLY_NEW) * 2. If a newgrf replaces some shore sprites by ActionA. The (maybe also replaced) grass tiles are used for corner shores. (SHORE_REPLACE_ACTION_A) * 3. If a newgrf replaces shore sprites by Action5 any shore replacement by ActionA has no effect. (SHORE_REPLACE_ACTION_5) */ static void ActivateOldShore() { /* Use default graphics, if no shore sprites were loaded. * Should not happen, as the base set's extra grf should include some. */ if (_loaded_newgrf_features.shore == SHORE_REPLACE_NONE) _loaded_newgrf_features.shore = SHORE_REPLACE_ACTION_A; if (_loaded_newgrf_features.shore != SHORE_REPLACE_ACTION_5) { DupSprite(SPR_ORIGINALSHORE_START + 1, SPR_SHORE_BASE + 1); // SLOPE_W DupSprite(SPR_ORIGINALSHORE_START + 2, SPR_SHORE_BASE + 2); // SLOPE_S DupSprite(SPR_ORIGINALSHORE_START + 6, SPR_SHORE_BASE + 3); // SLOPE_SW DupSprite(SPR_ORIGINALSHORE_START + 0, SPR_SHORE_BASE + 4); // SLOPE_E DupSprite(SPR_ORIGINALSHORE_START + 4, SPR_SHORE_BASE + 6); // SLOPE_SE DupSprite(SPR_ORIGINALSHORE_START + 3, SPR_SHORE_BASE + 8); // SLOPE_N DupSprite(SPR_ORIGINALSHORE_START + 7, SPR_SHORE_BASE + 9); // SLOPE_NW DupSprite(SPR_ORIGINALSHORE_START + 5, SPR_SHORE_BASE + 12); // SLOPE_NE } if (_loaded_newgrf_features.shore == SHORE_REPLACE_ACTION_A) { DupSprite(SPR_FLAT_GRASS_TILE + 16, SPR_SHORE_BASE + 0); // SLOPE_STEEP_S DupSprite(SPR_FLAT_GRASS_TILE + 17, SPR_SHORE_BASE + 5); // SLOPE_STEEP_W DupSprite(SPR_FLAT_GRASS_TILE + 7, SPR_SHORE_BASE + 7); // SLOPE_WSE DupSprite(SPR_FLAT_GRASS_TILE + 15, SPR_SHORE_BASE + 10); // SLOPE_STEEP_N DupSprite(SPR_FLAT_GRASS_TILE + 11, SPR_SHORE_BASE + 11); // SLOPE_NWS DupSprite(SPR_FLAT_GRASS_TILE + 13, SPR_SHORE_BASE + 13); // SLOPE_ENW DupSprite(SPR_FLAT_GRASS_TILE + 14, SPR_SHORE_BASE + 14); // SLOPE_SEN DupSprite(SPR_FLAT_GRASS_TILE + 18, SPR_SHORE_BASE + 15); // SLOPE_STEEP_E /* XXX - SLOPE_EW, SLOPE_NS are currently not used. * If they would be used somewhen, then these grass tiles will most like not look as needed */ DupSprite(SPR_FLAT_GRASS_TILE + 5, SPR_SHORE_BASE + 16); // SLOPE_EW DupSprite(SPR_FLAT_GRASS_TILE + 10, SPR_SHORE_BASE + 17); // SLOPE_NS } } /** * Replocate the old tram depot sprites to the new position, if no new ones were loaded. */ static void ActivateOldTramDepot() { if (_loaded_newgrf_features.tram == TRAMWAY_REPLACE_DEPOT_WITH_TRACK) { DupSprite(SPR_ROAD_DEPOT + 0, SPR_TRAMWAY_DEPOT_NO_TRACK + 0); // use road depot graphics for "no tracks" DupSprite(SPR_TRAMWAY_DEPOT_WITH_TRACK + 1, SPR_TRAMWAY_DEPOT_NO_TRACK + 1); DupSprite(SPR_ROAD_DEPOT + 2, SPR_TRAMWAY_DEPOT_NO_TRACK + 2); // use road depot graphics for "no tracks" DupSprite(SPR_TRAMWAY_DEPOT_WITH_TRACK + 3, SPR_TRAMWAY_DEPOT_NO_TRACK + 3); DupSprite(SPR_TRAMWAY_DEPOT_WITH_TRACK + 4, SPR_TRAMWAY_DEPOT_NO_TRACK + 4); DupSprite(SPR_TRAMWAY_DEPOT_WITH_TRACK + 5, SPR_TRAMWAY_DEPOT_NO_TRACK + 5); } } /** * Decide whether price base multipliers of grfs shall apply globally or only to the grf specifying them */ static void FinalisePriceBaseMultipliers() { extern const PriceBaseSpec _price_base_specs[]; /** Features, to which '_grf_id_overrides' applies. Currently vehicle features only. */ static const uint32 override_features = (1 << GSF_TRAINS) | (1 << GSF_ROADVEHICLES) | (1 << GSF_SHIPS) | (1 << GSF_AIRCRAFT); /* Evaluate grf overrides */ int num_grfs = (uint)_grf_files.size(); int *grf_overrides = AllocaM(int, num_grfs); for (int i = 0; i < num_grfs; i++) { grf_overrides[i] = -1; GRFFile *source = _grf_files[i]; uint32 override = _grf_id_overrides[source->grfid]; if (override == 0) continue; GRFFile *dest = GetFileByGRFID(override); if (dest == nullptr) continue; grf_overrides[i] = find_index(_grf_files, dest); assert(grf_overrides[i] >= 0); } /* Override features and price base multipliers of earlier loaded grfs */ for (int i = 0; i < num_grfs; i++) { if (grf_overrides[i] < 0 || grf_overrides[i] >= i) continue; GRFFile *source = _grf_files[i]; GRFFile *dest = _grf_files[grf_overrides[i]]; uint32 features = (source->grf_features | dest->grf_features) & override_features; source->grf_features |= features; dest->grf_features |= features; for (Price p = PR_BEGIN; p < PR_END; p++) { /* No price defined -> nothing to do */ if (!HasBit(features, _price_base_specs[p].grf_feature) || source->price_base_multipliers[p] == INVALID_PRICE_MODIFIER) continue; DEBUG(grf, 3, "'%s' overrides price base multiplier %d of '%s'", source->filename, p, dest->filename); dest->price_base_multipliers[p] = source->price_base_multipliers[p]; } } /* Propagate features and price base multipliers of afterwards loaded grfs, if none is present yet */ for (int i = num_grfs - 1; i >= 0; i--) { if (grf_overrides[i] < 0 || grf_overrides[i] <= i) continue; GRFFile *source = _grf_files[i]; GRFFile *dest = _grf_files[grf_overrides[i]]; uint32 features = (source->grf_features | dest->grf_features) & override_features; source->grf_features |= features; dest->grf_features |= features; for (Price p = PR_BEGIN; p < PR_END; p++) { /* Already a price defined -> nothing to do */ if (!HasBit(features, _price_base_specs[p].grf_feature) || dest->price_base_multipliers[p] != INVALID_PRICE_MODIFIER) continue; DEBUG(grf, 3, "Price base multiplier %d from '%s' propagated to '%s'", p, source->filename, dest->filename); dest->price_base_multipliers[p] = source->price_base_multipliers[p]; } } /* The 'master grf' now have the correct multipliers. Assign them to the 'addon grfs' to make everything consistent. */ for (int i = 0; i < num_grfs; i++) { if (grf_overrides[i] < 0) continue; GRFFile *source = _grf_files[i]; GRFFile *dest = _grf_files[grf_overrides[i]]; uint32 features = (source->grf_features | dest->grf_features) & override_features; source->grf_features |= features; dest->grf_features |= features; for (Price p = PR_BEGIN; p < PR_END; p++) { if (!HasBit(features, _price_base_specs[p].grf_feature)) continue; if (source->price_base_multipliers[p] != dest->price_base_multipliers[p]) { DEBUG(grf, 3, "Price base multiplier %d from '%s' propagated to '%s'", p, dest->filename, source->filename); } source->price_base_multipliers[p] = dest->price_base_multipliers[p]; } } /* Apply fallback prices for grf version < 8 */ for (GRFFile * const file : _grf_files) { if (file->grf_version >= 8) continue; PriceMultipliers &price_base_multipliers = file->price_base_multipliers; for (Price p = PR_BEGIN; p < PR_END; p++) { Price fallback_price = _price_base_specs[p].fallback_price; if (fallback_price != INVALID_PRICE && price_base_multipliers[p] == INVALID_PRICE_MODIFIER) { /* No price multiplier has been set. * So copy the multiplier from the fallback price, maybe a multiplier was set there. */ price_base_multipliers[p] = price_base_multipliers[fallback_price]; } } } /* Decide local/global scope of price base multipliers */ for (GRFFile * const file : _grf_files) { PriceMultipliers &price_base_multipliers = file->price_base_multipliers; for (Price p = PR_BEGIN; p < PR_END; p++) { if (price_base_multipliers[p] == INVALID_PRICE_MODIFIER) { /* No multiplier was set; set it to a neutral value */ price_base_multipliers[p] = 0; } else { if (!HasBit(file->grf_features, _price_base_specs[p].grf_feature)) { /* The grf does not define any objects of the feature, * so it must be a difficulty setting. Apply it globally */ DEBUG(grf, 3, "'%s' sets global price base multiplier %d", file->filename, p); SetPriceBaseMultiplier(p, price_base_multipliers[p]); price_base_multipliers[p] = 0; } else { DEBUG(grf, 3, "'%s' sets local price base multiplier %d", file->filename, p); } } } } } extern void InitGRFTownGeneratorNames(); /** Finish loading NewGRFs and execute needed post-processing */ static void AfterLoadGRFs() { for (StringIDMapping &it : _string_to_grf_mapping) { *it.target = MapGRFStringID(it.grfid, it.source); } _string_to_grf_mapping.clear(); /* Free the action 6 override sprites. */ for (GRFLineToSpriteOverride::iterator it = _grf_line_to_action6_sprite_override.begin(); it != _grf_line_to_action6_sprite_override.end(); it++) { free((*it).second); } _grf_line_to_action6_sprite_override.clear(); /* Polish cargoes */ FinaliseCargoArray(); /* Pre-calculate all refit masks after loading GRF files. */ CalculateRefitMasks(); /* Polish engines */ FinaliseEngineArray(); /* Set the actually used Canal properties */ FinaliseCanals(); /* Add all new houses to the house array. */ FinaliseHouseArray(); /* Add all new industries to the industry array. */ FinaliseIndustriesArray(); /* Add all new objects to the object array. */ FinaliseObjectsArray(); InitializeSortedCargoSpecs(); /* Sort the list of industry types. */ SortIndustryTypes(); /* Create dynamic list of industry legends for smallmap_gui.cpp */ BuildIndustriesLegend(); /* Build the routemap legend, based on the available cargos */ BuildLinkStatsLegend(); /* Add all new airports to the airports array. */ FinaliseAirportsArray(); BindAirportSpecs(); /* Update the townname generators list */ InitGRFTownGeneratorNames(); /* Run all queued vehicle list order changes */ CommitVehicleListOrderChanges(); /* Load old shore sprites in new position, if they were replaced by ActionA */ ActivateOldShore(); /* Load old tram depot sprites in new position, if no new ones are present */ ActivateOldTramDepot(); /* Set up custom rail types */ InitRailTypes(); InitRoadTypes(); for (Engine *e : Engine::IterateType(VEH_ROAD)) { if (_gted[e->index].rv_max_speed != 0) { /* Set RV maximum speed from the mph/0.8 unit value */ e->u.road.max_speed = _gted[e->index].rv_max_speed * 4; } RoadTramType rtt = HasBit(e->info.misc_flags, EF_ROAD_TRAM) ? RTT_TRAM : RTT_ROAD; const GRFFile *file = e->GetGRF(); if (file == nullptr || _gted[e->index].roadtramtype == 0) { e->u.road.roadtype = (rtt == RTT_TRAM) ? ROADTYPE_TRAM : ROADTYPE_ROAD; continue; } /* Remove +1 offset. */ _gted[e->index].roadtramtype--; const std::vector *list = (rtt == RTT_TRAM) ? &file->tramtype_list : &file->roadtype_list; if (_gted[e->index].roadtramtype < list->size()) { RoadTypeLabel rtl = (*list)[_gted[e->index].roadtramtype]; RoadType rt = GetRoadTypeByLabel(rtl); if (rt != INVALID_ROADTYPE && GetRoadTramType(rt) == rtt) { e->u.road.roadtype = rt; continue; } } /* Road type is not available, so disable this engine */ e->info.climates = 0; } for (Engine *e : Engine::IterateType(VEH_TRAIN)) { RailType railtype = GetRailTypeByLabel(_gted[e->index].railtypelabel); if (railtype == INVALID_RAILTYPE) { /* Rail type is not available, so disable this engine */ e->info.climates = 0; } else { e->u.rail.railtype = railtype; } } SetYearEngineAgingStops(); FinalisePriceBaseMultipliers(); /* Deallocate temporary loading data */ free(_gted); _grm_sprites.clear(); } /** * Load all the NewGRFs. * @param load_index The offset for the first sprite to add. * @param num_baseset Number of NewGRFs at the front of the list to look up in the baseset dir instead of the newgrf dir. */ void LoadNewGRF(uint load_index, uint num_baseset) { /* In case of networking we need to "sync" the start values * so all NewGRFs are loaded equally. For this we use the * start date of the game and we set the counters, etc. to * 0 so they're the same too. */ YearMonthDay date_ymd = _cur_date_ymd; Date date = _date; DateFract date_fract = _date_fract; uint16 tick_counter = _tick_counter; uint8 tick_skip_counter = _tick_skip_counter; byte display_opt = _display_opt; if (_networking) { _cur_date_ymd = { _settings_game.game_creation.starting_year, 0, 1}; _date = ConvertYMDToDate(_cur_date_ymd); _date_fract = 0; _tick_counter = 0; _tick_skip_counter = 0; _display_opt = 0; UpdateCachedSnowLine(); SetScaledTickVariables(); } InitializeGRFSpecial(); ResetNewGRFData(); /* * Reset the status of all files, so we can 'retry' to load them. * This is needed when one for example rearranges the NewGRFs in-game * and a previously disabled NewGRF becomes usable. If it would not * be reset, the NewGRF would remain disabled even though it should * have been enabled. */ for (GRFConfig *c = _grfconfig; c != nullptr; c = c->next) { if (c->status != GCS_NOT_FOUND) c->status = GCS_UNKNOWN; if (_settings_client.gui.newgrf_disable_big_gui && c->ident.grfid == BSWAP32(0x52577801)) { c->status = GCS_DISABLED; } } _cur.spriteid = load_index; /* Load newgrf sprites * in each loading stage, (try to) open each file specified in the config * and load information from it. */ for (GrfLoadingStage stage = GLS_LABELSCAN; stage <= GLS_ACTIVATION; stage++) { /* Set activated grfs back to will-be-activated between reservation- and activation-stage. * This ensures that action7/9 conditions 0x06 - 0x0A work correctly. */ for (GRFConfig *c = _grfconfig; c != nullptr; c = c->next) { if (c->status == GCS_ACTIVATED) c->status = GCS_INITIALISED; } if (stage == GLS_RESERVE) { static const uint32 overrides[][2] = { { 0x44442202, 0x44440111 }, // UKRS addons modifies UKRS { 0x6D620402, 0x6D620401 }, // DBSetXL ECS extension modifies DBSetXL { 0x4D656f20, 0x4D656F17 }, // LV4cut modifies LV4 }; for (size_t i = 0; i < lengthof(overrides); i++) { SetNewGRFOverride(BSWAP32(overrides[i][0]), BSWAP32(overrides[i][1])); } } uint num_grfs = 0; uint num_non_static = 0; _cur.stage = stage; for (GRFConfig *c = _grfconfig; c != nullptr; c = c->next) { if (c->status == GCS_DISABLED || c->status == GCS_NOT_FOUND) continue; if (stage > GLS_INIT && HasBit(c->flags, GCF_INIT_ONLY)) continue; Subdirectory subdir = num_grfs < num_baseset ? BASESET_DIR : NEWGRF_DIR; if (!FioCheckFileExists(c->filename, subdir)) { DEBUG(grf, 0, "NewGRF file is missing '%s'; disabling", c->filename); c->status = GCS_NOT_FOUND; continue; } if (stage == GLS_LABELSCAN) InitNewGRFFile(c); if (!HasBit(c->flags, GCF_STATIC) && !HasBit(c->flags, GCF_SYSTEM)) { if (num_non_static == MAX_NON_STATIC_GRF_COUNT) { DEBUG(grf, 0, "'%s' is not loaded as the maximum number of non-static GRFs has been reached", c->filename); c->status = GCS_DISABLED; c->error = new GRFError(STR_NEWGRF_ERROR_MSG_FATAL, STR_NEWGRF_ERROR_TOO_MANY_NEWGRFS_LOADED); continue; } num_non_static++; } num_grfs++; LoadNewGRFFile(c, stage, subdir, false); if (stage == GLS_RESERVE) { SetBit(c->flags, GCF_RESERVED); } else if (stage == GLS_ACTIVATION) { ClrBit(c->flags, GCF_RESERVED); assert(GetFileByGRFID(c->ident.grfid) == _cur.grffile); ClearTemporaryNewGRFData(_cur.grffile); BuildCargoTranslationMap(); HandleVarAction2OptimisationPasses(); DEBUG(sprite, 2, "LoadNewGRF: Currently %i sprites are loaded", _cur.spriteid); } else if (stage == GLS_INIT && HasBit(c->flags, GCF_INIT_ONLY)) { /* We're not going to activate this, so free whatever data we allocated */ ClearTemporaryNewGRFData(_cur.grffile); } } } /* Pseudo sprite processing is finished; free temporary stuff */ _cur.ClearDataForNextFile(); _callback_result_cache.clear(); /* Call any functions that should be run after GRFs have been loaded. */ AfterLoadGRFs(); /* Now revert back to the original situation */ _cur_date_ymd = date_ymd; _date = date; _date_fract = date_fract; _tick_counter = tick_counter; _tick_skip_counter = tick_skip_counter; _display_opt = display_opt; UpdateCachedSnowLine(); SetScaledTickVariables(); } /** * Returns amount of user selected NewGRFs files. */ uint CountSelectedGRFs(GRFConfig *grfconf) { uint i = 0; /* Find last entry in the list */ for (const GRFConfig *list = grfconf; list != nullptr; list = list->next) { if (!HasBit(list->flags, GCF_STATIC) && !HasBit(list->flags, GCF_SYSTEM)) i++; } return i; }