/* ScummVM - Graphic Adventure Engine * * ScummVM is the legal property of its developers, whose names * are too numerous to list here. Please refer to the COPYRIGHT * file distributed with this source distribution. * * This program 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; either version 2 * of the License, or (at your option) any later version. * This program 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 this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. * * $URL$ * $Id$ * */ #include "common/stream.h" #include "common/system.h" #include "common/func.h" #include "common/serializer.h" #include "graphics/thumbnail.h" #include "sci/sci.h" #include "sci/gfx/menubar.h" #ifdef INCLUDE_OLDGFX #include "sci/gfx/gfx_state_internal.h" // required for GfxPort, GfxContainer #endif #include "sci/sfx/audio.h" #include "sci/sfx/core.h" #include "sci/sfx/iterator.h" #include "sci/engine/state.h" #include "sci/engine/message.h" #include "sci/engine/savegame.h" #include "sci/gui/gui.h" namespace Sci { #define VER(x) Common::Serializer::Version(x) // OBSOLETE: This const is used for backward compatibility only. const uint32 INTMAPPER_MAGIC_KEY = 0xDEADBEEF; // from ksound.cpp: SongIterator *build_iterator(EngineState *s, int song_nr, SongIteratorType type, songit_id_t id); #pragma mark - // TODO: Many of the following sync_*() methods should be turned into member funcs // of the classes they are syncing. static void sync_songlib_t(Common::Serializer &s, SongLibrary &obj); static void sync_reg_t(Common::Serializer &s, reg_t &obj) { s.syncAsUint16LE(obj.segment); s.syncAsUint16LE(obj.offset); } static void sync_song_t(Common::Serializer &s, Song &obj) { s.syncAsSint32LE(obj._handle); s.syncAsSint32LE(obj._resourceNum); s.syncAsSint32LE(obj._priority); s.syncAsSint32LE(obj._status); s.syncAsSint32LE(obj._restoreBehavior); s.syncAsSint32LE(obj._restoreTime); s.syncAsSint32LE(obj._loops); s.syncAsSint32LE(obj._hold); if (s.isLoading()) { obj._it = 0; obj._delay = 0; obj._next = 0; obj._nextPlaying = 0; obj._nextStopping = 0; } } // Experimental hack: Use syncWithSerializer to sync. By default, this assume // the object to be synced is a subclass of Serializable and thus tries to invoke // the saveLoadWithSerializer() method. But it is possible to specialize this // template function to handle stuff that is not implementing that interface. template void syncWithSerializer(Common::Serializer &s, T &obj) { obj.saveLoadWithSerializer(s); } // By default, sync using syncWithSerializer, which in turn can easily be overloaded. template struct DefaultSyncer : Common::BinaryFunction { void operator()(Common::Serializer &s, T &obj) const { //obj.saveLoadWithSerializer(s); syncWithSerializer(s, obj); } }; /** * Sync a Common::Array using a Common::Serializer. * When saving, this writes the length of the array, then syncs (writes) all entries. * When loading, it loads the length of the array, then resizes it accordingly, before * syncing all entries. * * Note: This shouldn't be in common/array.h nor in common/serializer.h, after * all, not all code using arrays wants to use the serializer, and vice versa. * But we could put this into a separate header file in common/ at some point. * Something like common/serializer-extras.h or so. * * TODO: Add something like this for lists, queues.... */ template > struct ArraySyncer : Common::BinaryFunction { void operator()(Common::Serializer &s, Common::Array &arr) const { uint len = arr.size(); s.syncAsUint32LE(len); Syncer sync; // Resize the array if loading. if (s.isLoading()) arr.resize(len); typename Common::Array::iterator i; for (i = arr.begin(); i != arr.end(); ++i) { sync(s, *i); } } }; // Convenience wrapper template void syncArray(Common::Serializer &s, Common::Array &arr) { ArraySyncer sync; sync(s, arr); } template <> void syncWithSerializer(Common::Serializer &s, reg_t &obj) { sync_reg_t(s, obj); } void MenuItem::saveLoadWithSerializer(Common::Serializer &s) { s.syncAsSint32LE(_type); s.syncString(_keytext); s.skip(4, VER(9), VER(9)); // OBSOLETE: Used to be keytext_size s.syncAsSint32LE(_flags); s.syncBytes(_said, MENU_SAID_SPEC_SIZE); sync_reg_t(s, _saidPos); s.syncString(_text); sync_reg_t(s, _textPos); s.syncAsSint32LE(_modifiers); s.syncAsSint32LE(_key); s.syncAsSint32LE(_enabled); s.syncAsSint32LE(_tag); } void Menu::saveLoadWithSerializer(Common::Serializer &s) { s.syncString(_title); s.syncAsSint32LE(_titleWidth); s.syncAsSint32LE(_width); syncArray(s, _items); } void Menubar::saveLoadWithSerializer(Common::Serializer &s) { syncArray(s, _menus); } void SegManager::saveLoadWithSerializer(Common::Serializer &s) { s.skip(4, VER(9), VER(9)); // OBSOLETE: Used to be reserved_id s.syncAsSint32LE(_exportsAreWide); s.skip(4, VER(9), VER(9)); // OBSOLETE: Used to be gc_mark_bits if (s.isLoading()) { // Reset _scriptSegMap, to be restored below _scriptSegMap.clear(); if (s.getVersion() <= 9) { // OBSOLETE: Skip over the old id_seg_map when loading (we now // regenerate the equivalent data, in _scriptSegMap, from scratch). s.skip(4); // base_value while (true) { uint32 key = 0; s.syncAsSint32LE(key); if (key == INTMAPPER_MAGIC_KEY) break; s.skip(4); // idx } } } uint sync_heap_size = _heap.size(); s.syncAsUint32LE(sync_heap_size); _heap.resize(sync_heap_size); for (uint i = 0; i < sync_heap_size; ++i) { SegmentObj *&mobj = _heap[i]; // Sync the segment type SegmentType type = (s.isSaving() && mobj) ? mobj->getType() : SEG_TYPE_INVALID; s.syncAsUint32LE(type); // If we were saving and mobj == 0, or if we are loading and this is an // entry marked as empty -> skip to next if (type == SEG_TYPE_INVALID) { continue; } s.skip(4, VER(9), VER(9)); // OBSOLETE: Used to be _segManagerId // Don't save or load HunkTable segments if (type == SEG_TYPE_HUNK) { continue; } // Handle the OBSOLETE type SEG_TYPE_STRING_FRAG -- just ignore it if (s.isLoading() && type == SEG_TYPE_STRING_FRAG) { continue; } if (s.isLoading()) { mobj = SegmentObj::createSegmentObj(type); } assert(mobj); // Let the object sync custom data mobj->saveLoadWithSerializer(s); // If we are loading a script, hook it up in the script->segment map. if (s.isLoading() && type == SEG_TYPE_SCRIPT) { _scriptSegMap[((Script *)mobj)->_nr] = i; } } s.syncAsSint32LE(Clones_seg_id); s.syncAsSint32LE(Lists_seg_id); s.syncAsSint32LE(Nodes_seg_id); } static void sync_SegManagerPtr(Common::Serializer &s, ResourceManager *&resMan, SegManager *&obj) { s.skip(1, VER(9), VER(9)); // obsolete: used to be a flag indicating if we got sci11 or not if (s.isLoading()) obj->resetSegMan(); obj->saveLoadWithSerializer(s); } template <> void syncWithSerializer(Common::Serializer &s, Class &obj) { s.syncAsSint32LE(obj.script); sync_reg_t(s, obj.reg); } static void sync_sfx_state_t(Common::Serializer &s, SfxState &obj) { sync_songlib_t(s, obj._songlib); } static void sync_SavegameMetadata(Common::Serializer &s, SavegameMetadata &obj) { // TODO: It would be a good idea to store a magic number & a header size here, // so that we can implement backward compatibility if the savegame format changes. s.syncString(obj.savegame_name); s.syncVersion(CURRENT_SAVEGAME_VERSION); obj.savegame_version = s.getVersion(); s.syncString(obj.game_version); s.skip(4, VER(9), VER(9)); // obsolete: used to be game version s.syncAsSint32LE(obj.savegame_date); s.syncAsSint32LE(obj.savegame_time); } void EngineState::saveLoadWithSerializer(Common::Serializer &s) { s.skip(4, VER(9), VER(9)); // OBSOLETE: Used to be savegame_version Common::String tmp; s.syncString(tmp); // OBSOLETE: Used to be game_version s.skip(4, VER(9), VER(9)); // OBSOLETE: Used to be version if (s.isLoading()) { //free(menubar); _menubar = new Menubar(); } else assert(_menubar); _menubar->saveLoadWithSerializer(s); s.skip(4, VER(12), VER(12)); // obsolete: used to be status_bar_foreground s.skip(4, VER(12), VER(12)); // obsolete: used to be status_bar_background sync_SegManagerPtr(s, resMan, _segMan); syncArray(s, _segMan->_classtable); sync_sfx_state_t(s, _sound); } void LocalVariables::saveLoadWithSerializer(Common::Serializer &s) { s.syncAsSint32LE(script_id); syncArray(s, _locals); } void Object::saveLoadWithSerializer(Common::Serializer &s) { s.syncAsSint32LE(_flags); sync_reg_t(s, _pos); s.skip(4, VER(9), VER(12)); // OBSOLETE: Used to be variable_names_nr s.syncAsSint32LE(_methodCount); // that's actually a uint16 syncArray(s, _variables); } template <> void syncWithSerializer(Common::Serializer &s, Table::Entry &obj) { s.syncAsSint32LE(obj.next_free); syncWithSerializer(s, obj); } template <> void syncWithSerializer(Common::Serializer &s, Table::Entry &obj) { s.syncAsSint32LE(obj.next_free); sync_reg_t(s, obj.first); sync_reg_t(s, obj.last); } template <> void syncWithSerializer(Common::Serializer &s, Table::Entry &obj) { s.syncAsSint32LE(obj.next_free); sync_reg_t(s, obj.pred); sync_reg_t(s, obj.succ); sync_reg_t(s, obj.key); sync_reg_t(s, obj.value); } template void sync_Table(Common::Serializer &s, T &obj) { s.syncAsSint32LE(obj.first_free); s.syncAsSint32LE(obj.entries_used); syncArray(s, obj._table); } void CloneTable::saveLoadWithSerializer(Common::Serializer &s) { sync_Table(s, *this); } void NodeTable::saveLoadWithSerializer(Common::Serializer &s) { sync_Table(s, *this); } void ListTable::saveLoadWithSerializer(Common::Serializer &s) { sync_Table(s, *this); } void HunkTable::saveLoadWithSerializer(Common::Serializer &s) { // Do nothing, hunk tables are not actually saved nor loaded. } void Script::saveLoadWithSerializer(Common::Serializer &s) { s.syncAsSint32LE(_nr); s.syncAsUint32LE(_bufSize); s.syncAsUint32LE(_scriptSize); s.syncAsUint32LE(_heapSize); if (s.getVersion() <= 10) { assert((s.isLoading())); // OBSOLETE: Skip over the old _objIndices data when loading s.skip(4); // base_value while (true) { uint32 key = 0; s.syncAsSint32LE(key); if (key == INTMAPPER_MAGIC_KEY) break; s.skip(4); // idx } } s.syncAsSint32LE(_numExports); s.syncAsSint32LE(_numSynonyms); s.syncAsSint32LE(_lockers); // Sync _objects. This is a hashmap, and we use the following on disk format: // First we store the number of items in the hashmap, then we store each // object (which is an 'Object' instance). For loading, we take advantage // of the fact that the key of each Object obj is just obj._pos.offset ! // By "chance" this format is identical to the format used to sync Common::Array<>, // hence we can still old savegames with identical code :). uint numObjs = _objects.size(); s.syncAsUint32LE(numObjs); if (s.isLoading()) { _objects.clear(); Object tmp; for (uint i = 0; i < numObjs; ++i) { syncWithSerializer(s, tmp); _objects[tmp.getPos().offset] = tmp; } } else { ObjMap::iterator it; const ObjMap::iterator end = _objects.end(); for (it = _objects.begin(); it != end; ++it) { syncWithSerializer(s, it->_value); } } s.syncAsSint32LE(_localsOffset); s.syncAsSint32LE(_localsSegment); s.syncAsSint32LE(_markedAsDeleted); } static void sync_SystemString(Common::Serializer &s, SystemString &obj) { s.syncString(obj._name); s.syncAsSint32LE(obj._maxSize); // Sync obj._value. We cannot use syncCStr as we must make sure that // the allocated buffer has the correct size, i.e., obj._maxSize Common::String tmp; if (s.isSaving() && obj._value) tmp = obj._value; s.syncString(tmp); if (s.isLoading()) { //free(*str); obj._value = (char *)calloc(obj._maxSize, sizeof(char)); strncpy(obj._value, tmp.c_str(), obj._maxSize); } } void SystemStrings::saveLoadWithSerializer(Common::Serializer &s) { for (int i = 0; i < SYS_STRINGS_MAX; ++i) sync_SystemString(s, _strings[i]); } void DynMem::saveLoadWithSerializer(Common::Serializer &s) { s.syncAsSint32LE(_size); s.syncString(_description); if (!_buf && _size) { _buf = (byte *)calloc(_size, 1); } if (_size) s.syncBytes(_buf, _size); } void DataStack::saveLoadWithSerializer(Common::Serializer &s) { s.syncAsUint32LE(_capacity); if (s.isLoading()) { //free(entries); _entries = (reg_t *)calloc(_capacity, sizeof(reg_t)); } } #pragma mark - static void sync_songlib_t(Common::Serializer &s, SongLibrary &obj) { int songcount = 0; if (s.isSaving()) songcount = obj.countSongs(); s.syncAsUint32LE(songcount); if (s.isLoading()) { obj._lib = 0; while (songcount--) { Song *newsong = new Song; sync_song_t(s, *newsong); obj.addSong(newsong); } } else { Song *seeker = obj._lib; while (seeker) { seeker->_restoreTime = seeker->_it->getTimepos(); sync_song_t(s, *seeker); seeker = seeker->_next; } } } #pragma mark - int gamestate_save(EngineState *s, Common::WriteStream *fh, const char* savename, const char *version) { TimeDate curTime; g_system->getTimeAndDate(curTime); SavegameMetadata meta; meta.savegame_version = CURRENT_SAVEGAME_VERSION; meta.savegame_name = savename; meta.game_version = version; meta.savegame_date = ((curTime.tm_mday & 0xFF) << 24) | (((curTime.tm_mon + 1) & 0xFF) << 16) | ((curTime.tm_year + 1900) & 0xFFFF); meta.savegame_time = ((curTime.tm_hour & 0xFF) << 16) | (((curTime.tm_min) & 0xFF) << 8) | ((curTime.tm_sec) & 0xFF); if (s->execution_stack_base) { warning("Cannot save from below kernel function"); return 1; } /* if (s->sound_server) { if ((s->sound_server->save)(s, dirname)) { warning("Saving failed for the sound subsystem"); //chdir(".."); return 1; } } */ Common::Serializer ser(0, fh); sync_SavegameMetadata(ser, meta); Graphics::saveThumbnail(*fh); s->saveLoadWithSerializer(ser); // FIXME: Error handling? return 0; } static byte *find_unique_script_block(EngineState *s, byte *buf, int type) { bool oldScriptHeader = (getSciVersion() == SCI_VERSION_0_EARLY); if (oldScriptHeader) buf += 2; do { int seeker_type = READ_LE_UINT16(buf); if (seeker_type == 0) break; if (seeker_type == type) return buf; int seeker_size = READ_LE_UINT16(buf + 2); assert(seeker_size > 0); buf += seeker_size; } while (1); return NULL; } // TODO: This should probably be turned into an EngineState or DataStack method. static void reconstruct_stack(EngineState *retval) { SegmentId stack_seg = retval->_segMan->findSegmentByType(SEG_TYPE_STACK); DataStack *stack = (DataStack *)(retval->_segMan->_heap[stack_seg]); retval->stack_segment = stack_seg; retval->stack_base = stack->_entries; retval->stack_top = stack->_entries + stack->_capacity; } static void load_script(EngineState *s, Script *scr) { Resource *script, *heap = NULL; scr->_buf = (byte *)malloc(scr->_bufSize); assert(scr->_buf); script = s->resMan->findResource(ResourceId(kResourceTypeScript, scr->_nr), 0); if (getSciVersion() >= SCI_VERSION_1_1) heap = s->resMan->findResource(ResourceId(kResourceTypeHeap, scr->_nr), 0); memcpy(scr->_buf, script->data, script->size); if (getSciVersion() >= SCI_VERSION_1_1) { scr->_heapStart = scr->_buf + scr->_scriptSize; memcpy(scr->_heapStart, heap->data, heap->size); } } void SegManager::reconstructScripts(EngineState *s) { uint i; SegmentObj *mobj; for (i = 0; i < _heap.size(); i++) { mobj = _heap[i]; if (!mobj || mobj->getType() != SEG_TYPE_SCRIPT) continue; Script *scr = (Script *)mobj; // FIXME: Unify this code with script_instantiate_* ? load_script(s, scr); scr->_localsBlock = (scr->_localsSegment == 0) ? NULL : (LocalVariables *)(_heap[scr->_localsSegment]); if (getSciVersion() >= SCI_VERSION_1_1) { scr->_exportTable = 0; scr->_synonyms = 0; if (READ_LE_UINT16(scr->_buf + 6) > 0) { scr->setExportTableOffset(6); s->_segMan->scriptRelocateExportsSci11(i); } } else { scr->_exportTable = (uint16 *) find_unique_script_block(s, scr->_buf, SCI_OBJ_EXPORTS); scr->_synonyms = find_unique_script_block(s, scr->_buf, SCI_OBJ_SYNONYMS); scr->_exportTable += 3; } scr->_codeBlocks.clear(); ObjMap::iterator it; const ObjMap::iterator end = scr->_objects.end(); for (it = scr->_objects.begin(); it != end; ++it) { byte *data = scr->_buf + it->_value.getPos().offset; it->_value._baseObj = data; } } for (i = 0; i < _heap.size(); i++) { mobj = _heap[i]; if (!mobj || mobj->getType() != SEG_TYPE_SCRIPT) continue; Script *scr = (Script *)mobj; // FIXME: Unify this code with Script::scriptObjInit ? ObjMap::iterator it; const ObjMap::iterator end = scr->_objects.end(); for (it = scr->_objects.begin(); it != end; ++it) { byte *data = scr->_buf + it->_value.getPos().offset; if (getSciVersion() >= SCI_VERSION_1_1) { uint16 *funct_area = (uint16 *)(scr->_buf + READ_LE_UINT16( data + 6 )); uint16 *prop_area = (uint16 *)(scr->_buf + READ_LE_UINT16( data + 4 )); it->_value._baseMethod = funct_area; it->_value._baseVars = prop_area; } else { int funct_area = READ_LE_UINT16(data + SCRIPT_FUNCTAREAPTR_OFFSET); Object *_baseObj; _baseObj = s->_segMan->getObject(it->_value.getSpeciesSelector()); if (!_baseObj) { warning("Object without a base class: Script %d, index %d (reg address %04x:%04x", scr->_nr, i, PRINT_REG(it->_value.getSpeciesSelector())); continue; } it->_value.setVarCount(_baseObj->getVarCount()); it->_value._baseObj = _baseObj->_baseObj; it->_value._baseMethod = (uint16 *)(data + funct_area); it->_value._baseVars = (uint16 *)(data + it->_value.getVarCount() * 2 + SCRIPT_SELECTOR_OFFSET); } } } } #ifdef INCLUDE_OLDGFX int _reset_graphics_input(EngineState *s); #endif static void reconstruct_sounds(EngineState *s) { Song *seeker; SongIteratorType it_type; if (getSciVersion() > SCI_VERSION_01) it_type = SCI_SONG_ITERATOR_TYPE_SCI1; else it_type = SCI_SONG_ITERATOR_TYPE_SCI0; seeker = s->_sound._songlib._lib; while (seeker) { SongIterator *base, *ff; int oldstatus; SongIterator::Message msg; base = ff = build_iterator(s, seeker->_resourceNum, it_type, seeker->_handle); if (seeker->_restoreBehavior == RESTORE_BEHAVIOR_CONTINUE) ff = new_fast_forward_iterator(base, seeker->_restoreTime); ff->init(); msg = SongIterator::Message(seeker->_handle, SIMSG_SET_LOOPS(seeker->_loops)); songit_handle_message(&ff, msg); msg = SongIterator::Message(seeker->_handle, SIMSG_SET_HOLD(seeker->_hold)); songit_handle_message(&ff, msg); oldstatus = seeker->_status; seeker->_status = SOUND_STATUS_STOPPED; seeker->_it = ff; s->_sound.sfx_song_set_status(seeker->_handle, oldstatus); seeker = seeker->_next; } } EngineState *gamestate_restore(EngineState *s, Common::SeekableReadStream *fh) { EngineState *retval; SongLibrary temp; /* if (s->sound_server) { if ((s->sound_server->restore)(s, dirname)) { warning("Restoring failed for the sound subsystem"); return NULL; } } */ SavegameMetadata meta; Common::Serializer ser(fh, 0); sync_SavegameMetadata(ser, meta); if (fh->eos()) return false; if ((meta.savegame_version < MINIMUM_SAVEGAME_VERSION) || (meta.savegame_version > CURRENT_SAVEGAME_VERSION)) { if (meta.savegame_version < MINIMUM_SAVEGAME_VERSION) warning("Old savegame version detected- can't load"); else warning("Savegame version is %d- maximum supported is %0d", meta.savegame_version, CURRENT_SAVEGAME_VERSION); return NULL; } if (meta.savegame_version >= 12) { // We don't need the thumbnail here, so just read it and discard it Graphics::Surface *thumbnail = new Graphics::Surface(); assert(thumbnail); Graphics::loadThumbnail(*fh, *thumbnail); delete thumbnail; thumbnail = 0; } // Create a new EngineState object retval = new EngineState(s->resMan, s->_kernel, s->_voc, s->_segMan, s->_gui, s->_audio); // Copy some old data retval->gfx_state = s->gfx_state; retval->saveLoadWithSerializer(ser); // FIXME: Error handling? s->_sound.sfx_exit(); // Set exec stack base to zero retval->execution_stack_base = 0; // Now copy all current state information #ifdef INCLUDE_OLDGFX // Graphics and input state: retval->old_screen = 0; #endif temp = retval->_sound._songlib; retval->_sound.sfx_init(retval->resMan, s->sfx_init_flags); retval->sfx_init_flags = s->sfx_init_flags; retval->_sound._songlib.freeSounds(); retval->_sound._songlib = temp; reconstruct_stack(retval); retval->_segMan->reconstructScripts(retval); retval->_segMan->reconstructClones(); retval->_gameObj = s->_gameObj; retval->script_000 = retval->_segMan->getScript(retval->_segMan->getScriptSegment(0, SCRIPT_GET_DONT_LOAD)); retval->gc_countdown = GC_INTERVAL - 1; retval->sys_strings_segment = retval->_segMan->findSegmentByType(SEG_TYPE_SYS_STRINGS); retval->sys_strings = (SystemStrings *)GET_SEGMENT(*retval->_segMan, retval->sys_strings_segment, SEG_TYPE_SYS_STRINGS); #ifdef INCLUDE_OLDGFX _reset_graphics_input(retval); #endif // Time state: retval->last_wait_time = g_system->getMillis(); retval->game_start_time = g_system->getMillis(); // static parser information: retval->parser_base = make_reg(s->sys_strings_segment, SYS_STRING_PARSER_BASE); // Copy breakpoint information from current game instance retval->have_bp = s->have_bp; retval->bp_list = s->bp_list; retval->successor = NULL; #ifdef INCLUDE_OLDGFX retval->pic_priority_table = (int *)(retval->gfx_state->pic) ? retval->gfx_state->pic->priorityTable : NULL; #endif retval->_gameName = s->_gameName; retval->_sound._it = NULL; retval->_sound._flags = s->_sound._flags; retval->_sound._song = NULL; retval->_sound._suspended = s->_sound._suspended; reconstruct_sounds(retval); // Message state: retval->_msgState = new MessageState(retval->_segMan); retval->_gui->resetEngineState(retval); return retval; } bool get_savegame_metadata(Common::SeekableReadStream *stream, SavegameMetadata *meta) { assert(stream); assert(meta); Common::Serializer ser(stream, 0); sync_SavegameMetadata(ser, *meta); if (stream->eos()) return false; if ((meta->savegame_version < MINIMUM_SAVEGAME_VERSION) || (meta->savegame_version > CURRENT_SAVEGAME_VERSION)) { if (meta->savegame_version < MINIMUM_SAVEGAME_VERSION) warning("Old savegame version detected- can't load"); else warning("Savegame version is %d- maximum supported is %0d", meta->savegame_version, CURRENT_SAVEGAME_VERSION); return false; } return true; } } // End of namespace Sci