/* 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. * * $URL$ * $Id$ * */ /* * This code is based on original Hugo Trilogy source code * * Copyright (c) 1989-1995 David P. Gray * */ #include "common/system.h" #include "common/file.h" #include "common/savefile.h" #include "hugo/game.h" #include "hugo/hugo.h" #include "hugo/file.h" #include "hugo/global.h" #include "hugo/schedule.h" #include "hugo/display.h" #include "hugo/util.h" namespace Hugo { FileManager::FileManager(HugoEngine &vm) : _vm(vm) { } FileManager::~FileManager() { } byte *FileManager::convertPCC(byte *p, uint16 y, uint16 bpl, image_pt dataPtr) { // Convert 4 planes (RGBI) data to 8-bit DIB format // Return original plane data ptr uint16 r, g, b, i; // Byte index within each plane int8 bit; // Bit index within a byte debugC(2, kDebugFile, "convertPCC(byte *p, %d, %d, image_pt data_p)", y, bpl); dataPtr += y * bpl * 8; // Point to correct DIB line for (r = 0, g = bpl, b = g + bpl, i = b + bpl; r < bpl; r++, g++, b++, i++) // Each byte in all planes for (bit = 7; bit >= 0; bit--) // Each bit in byte *dataPtr++ = (((p[r] >> bit & 1) << 0) | ((p[g] >> bit & 1) << 1) | ((p[b] >> bit & 1) << 2) | ((p[i] >> bit & 1) << 3)); return p; } seq_t *FileManager::readPCX(Common::File &f, seq_t *seqPtr, byte *imagePtr, bool firstFl, const char *name) { // Read a pcx file of length len. Use supplied seq_p and image_p or // allocate space if NULL. Name used for errors. Returns address of seq_p // Set first TRUE to initialize b_index (i.e. not reading a sequential image in file). struct { // Structure of PCX file header byte mfctr, vers, enc, bpx; uint16 x1, y1, x2, y2; // bounding box uint16 xres, yres; byte palette[48]; // EGA color palette byte vmode, planes; uint16 bytesPerLine; // Bytes per line byte fill2[60]; } PCC_header; // Header of a PCC file byte c, d; // code and data bytes from PCX file byte pline[XPIX]; // Hold 4 planes of data byte *p = pline; // Ptr to above byte i; // PCX repeat count uint16 bytesPerLine4; // BPL in 4-bit format uint16 size; // Size of image uint16 y = 0; // Current line index debugC(1, kDebugFile, "readPCX(..., %s)", name); // Read in the PCC header and check consistency PCC_header.mfctr = f.readByte(); PCC_header.vers = f.readByte(); PCC_header.enc = f.readByte(); PCC_header.bpx = f.readByte(); PCC_header.x1 = f.readUint16LE(); PCC_header.y1 = f.readUint16LE(); PCC_header.x2 = f.readUint16LE(); PCC_header.y2 = f.readUint16LE(); PCC_header.xres = f.readUint16LE(); PCC_header.yres = f.readUint16LE(); f.read(PCC_header.palette, sizeof(PCC_header.palette)); PCC_header.vmode = f.readByte(); PCC_header.planes = f.readByte(); PCC_header.bytesPerLine = f.readUint16LE(); f.read(PCC_header.fill2, sizeof(PCC_header.fill2)); if (PCC_header.mfctr != 10) Utils::Error(PCCH_ERR, "%s", name); // Allocate memory for seq_t if NULL if (seqPtr == NULL) if ((seqPtr = (seq_t *)malloc(sizeof(seq_t))) == NULL) Utils::Error(HEAP_ERR, "%s", name); // Find size of image data in 8-bit DIB format // Note save of x2 - marks end of valid data before garbage bytesPerLine4 = PCC_header.bytesPerLine * 4; // 4-bit bpl seqPtr->bytesPerLine8 = bytesPerLine4 * 2; // 8-bit bpl seqPtr->lines = PCC_header.y2 - PCC_header.y1 + 1; seqPtr->x2 = PCC_header.x2 - PCC_header.x1 + 1; size = seqPtr->lines * seqPtr->bytesPerLine8; // Allocate memory for image data if NULL if (imagePtr == NULL) if ((imagePtr = (byte *)malloc((size_t) size)) == NULL) Utils::Error(HEAP_ERR, "%s", name); seqPtr->imagePtr = imagePtr; // Process the image data, converting to 8-bit DIB format while (y < seqPtr->lines) { c = f.readByte(); if ((c & REP_MASK) == REP_MASK) { d = f.readByte(); // Read data byte for (i = 0; i < (c & LEN_MASK); i++) { *p++ = d; if ((uint16)(p - pline) == bytesPerLine4) p = convertPCC(pline, y++, PCC_header.bytesPerLine, imagePtr); } } else { *p++ = c; if ((uint16)(p - pline) == bytesPerLine4) p = convertPCC(pline, y++, PCC_header.bytesPerLine, imagePtr); } } return seqPtr; } void FileManager::readImage(int objNum, object_t *objPtr) { // Read object file of PCC images into object supplied byte x, y, j, k; uint16 x2; // Limit on x in image data seq_t *seqPtr = 0; // Ptr to sequence structure image_pt dibPtr; // Ptr to DIB data objBlock_t objBlock; // Info on file within database bool firstFl = true; // Initializes pcx read function debugC(1, kDebugFile, "readImage(%d, object_t *objPtr)", objNum); if (!objPtr->seqNumb) // This object has no images return; if (_vm.isPacked()) { _objectsArchive.seek((uint32)objNum * sizeof(objBlock_t), SEEK_SET); objBlock.objOffset = _objectsArchive.readUint32LE(); objBlock.objLength = _objectsArchive.readUint32LE(); _objectsArchive.seek(objBlock.objOffset, SEEK_SET); } else { char *buf = (char *) malloc(2048 + 1); // Buffer for file access strcat(strcat(strcpy(buf, _vm._picDir), _vm._arrayNouns[objPtr->nounIndex][0]), OBJEXT); if (!_objectsArchive.open(buf)) { warning("File %s not found, trying again with %s%s", buf, _vm._arrayNouns[objPtr->nounIndex][0], OBJEXT); strcat(strcpy(buf, _vm._arrayNouns[objPtr->nounIndex][0]), OBJEXT); if (!_objectsArchive.open(buf)) Utils::Error(FILE_ERR, "%s", buf); } } // Now read the images into an images list for (j = 0; j < objPtr->seqNumb; j++) { // for each sequence for (k = 0; k < objPtr->seqList[j].imageNbr; k++) { // each image if (k == 0) { // First image // Read this image - allocate both seq and image memory seqPtr = readPCX(_objectsArchive, NULL, NULL, firstFl, _vm._arrayNouns[objPtr->nounIndex][0]); objPtr->seqList[j].seqPtr = seqPtr; firstFl = false; } else { // Subsequent image // Read this image - allocate both seq and image memory seqPtr->nextSeqPtr = readPCX(_objectsArchive, NULL, NULL, firstFl, _vm._arrayNouns[objPtr->nounIndex][0]); seqPtr = seqPtr->nextSeqPtr; } // Compute the bounding box - x1, x2, y1, y2 // Note use of x2 - marks end of valid data in row x2 = seqPtr->x2; seqPtr->x1 = seqPtr->x2; seqPtr->x2 = 0; seqPtr->y1 = seqPtr->lines; seqPtr->y2 = 0; dibPtr = seqPtr->imagePtr; for (y = 0; y < seqPtr->lines; y++, dibPtr += seqPtr->bytesPerLine8 - x2) for (x = 0; x < x2; x++) if (*dibPtr++) { // Some data found if (x < seqPtr->x1) seqPtr->x1 = x; if (x > seqPtr->x2) seqPtr->x2 = x; if (y < seqPtr->y1) seqPtr->y1 = y; if (y > seqPtr->y2) seqPtr->y2 = y; } } seqPtr->nextSeqPtr = objPtr->seqList[j].seqPtr; // loop linked list to head } // Set the current image sequence to first or last switch (objPtr->cycling) { case INVISIBLE: // (May become visible later) case ALMOST_INVISIBLE: case NOT_CYCLING: case CYCLE_FORWARD: objPtr->currImagePtr = objPtr->seqList[0].seqPtr; break; case CYCLE_BACKWARD: objPtr->currImagePtr = seqPtr; break; default: warning("Unexpected cycling: %d", objPtr->cycling); } if (!_vm.isPacked()) _objectsArchive.close(); } sound_pt FileManager::getSound(int16 sound, uint16 *size) { // Read sound (or music) file data. Call with SILENCE to free-up // any allocated memory. Also returns size of data static sound_hdr_t s_hdr[MAX_SOUNDS]; // Sound lookup table sound_pt soundPtr; // Ptr to sound data Common::File fp; // Handle to SOUND_FILE // bool music = sound < NUM_TUNES; // TRUE if music, else sound file debugC(1, kDebugFile, "getSound(%d, %d)", sound, *size); // No more to do if SILENCE (called for cleanup purposes) if (sound == _vm._soundSilence) return(NULL); // Open sounds file if (!fp.open(SOUND_FILE)) { // Error(FILE_ERR, "%s", SOUND_FILE); warning("Hugo Error: File not found %s", SOUND_FILE); return(NULL); } // If this is the first call, read the lookup table static bool has_read_header = false; if (!has_read_header) { if (fp.read(s_hdr, sizeof(s_hdr)) != sizeof(s_hdr)) Utils::Error(FILE_ERR, "%s", SOUND_FILE); has_read_header = true; } *size = s_hdr[sound].size; if (*size == 0) Utils::Error(SOUND_ERR, "%s", SOUND_FILE); // Allocate memory for sound or music, if possible if ((soundPtr = (byte *)malloc(s_hdr[sound].size)) == 0) { Utils::Warn(false, "%s", "Low on memory"); return(NULL); } // Seek to data and read it fp.seek(s_hdr[sound].offset, SEEK_SET); if (fp.read(soundPtr, s_hdr[sound].size) != s_hdr[sound].size) Utils::Error(FILE_ERR, "%s", SOUND_FILE); fp.close(); return soundPtr; } bool FileManager::fileExists(char *filename) { // Return whether file exists or not Common::File f; if (f.open(filename)) { f.close(); return true; } return false; } void FileManager::saveSeq(object_t *obj) { // Save sequence number and image number in given object byte j, k; seq_t *q; bool found; debugC(1, kDebugFile, "saveSeq"); for (j = 0, found = false; !found && (j < obj->seqNumb); j++) { q = obj->seqList[j].seqPtr; for (k = 0; !found && (k < obj->seqList[j].imageNbr); k++) { if (obj->currImagePtr == q) { found = true; obj->curSeqNum = j; obj->curImageNum = k; } else q = q->nextSeqPtr; } } } void FileManager::restoreSeq(object_t *obj) { // Set up cur_seq_p from stored sequence and image number in object int j; seq_t *q; debugC(1, kDebugFile, "restoreSeq"); q = obj->seqList[obj->curSeqNum].seqPtr; for (j = 0; j < obj->curImageNum; j++) q = q->nextSeqPtr; obj->currImagePtr = q; } void FileManager::saveGame(int16 slot, const char *descrip) { // Save game to supplied slot (-1 is INITFILE) int i; char path[256]; // Full path of saved game debugC(1, kDebugFile, "saveGame(%d, %s)", slot, descrip); // Get full path of saved game file - note test for INITFILE if (slot == -1) sprintf(path, "%s", _vm._initFilename); else sprintf(path, _vm._saveFilename, slot); Common::WriteStream *out = 0; if (!(out = _vm.getSaveFileManager()->openForSaving(path))) { warning("Can't create file '%s', game not saved", path); return; } // Write version. We can't restore from obsolete versions out->write(&kSavegameVersion, sizeof(kSavegameVersion)); // Save description of saved game out->write(descrip, DESCRIPLEN); // Save objects for (i = 0; i < _vm._numObj; i++) { // Save where curr_seq_p is pointing to saveSeq(&_vm._objects[i]); out->write(&_vm._objects[i], sizeof(object_t)); } const status_t &gameStatus = _vm.getGameStatus(); // Save whether hero image is swapped out->write(&_vm._heroImage, sizeof(_vm._heroImage)); // Save score int score = _vm.getScore(); out->write(&score, sizeof(score)); // Save story mode out->write(&gameStatus.storyModeFl, sizeof(gameStatus.storyModeFl)); // Save jumpexit mode out->write(&gameStatus.jumpExitFl, sizeof(gameStatus.jumpExitFl)); // Save gameover status out->write(&gameStatus.gameOverFl, sizeof(gameStatus.gameOverFl)); // Save screen states out->write(_vm._screenStates, sizeof(*_vm._screenStates) * _vm._numScreens); // Save points table out->write(_vm._points, sizeof(point_t) * _vm._numBonuses); // Now save current time and all current events in event queue _vm.scheduler().saveEvents(out); // Save palette table _vm.screen().savePal(out); // Save maze status out->write(&_maze, sizeof(maze_t)); out->finalize(); delete out; } void FileManager::restoreGame(int16 slot) { // Restore game from supplied slot number (-1 is INITFILE) int i; char path[256]; // Full path of saved game object_t *p; seqList_t seqList[MAX_SEQUENCES]; // cmdList *cmds; // Save command list pointer uint16 cmdIndex; // Save command list pointer // char ver[sizeof(VER)]; // Compare versions debugC(1, kDebugFile, "restoreGame(%d)", slot); // Initialize new-game status _vm.initStatus(); // Get full path of saved game file - note test for INITFILE if (slot == -1) sprintf(path, "%s", _vm._initFilename); else sprintf(path, _vm._saveFilename, slot); Common::SeekableReadStream *in = 0; if (!(in = _vm.getSaveFileManager()->openForLoading(path))) return; // Check version, can't restore from different versions int saveVersion; in->read(&saveVersion, sizeof(saveVersion)); if (saveVersion != kSavegameVersion) { Utils::Error(GEN_ERR, "%s", "Savegame of incompatible version"); return; } // Skip over description in->seek(DESCRIPLEN, SEEK_CUR); // If hero image is currently swapped, swap it back before restore if (_vm._heroImage != HERO) _vm.scheduler().swapImages(HERO, _vm._heroImage); // Restore objects, retain current seqList which points to dynamic mem // Also, retain cmnd_t pointers for (i = 0; i < _vm._numObj; i++) { p = &_vm._objects[i]; memcpy(seqList, p->seqList, sizeof(seqList_t)); cmdIndex = p->cmdIndex; in->read(p, sizeof(object_t)); p->cmdIndex = cmdIndex; memcpy(p->seqList, seqList, sizeof(seqList_t)); } in->read(&_vm._heroImage, sizeof(_vm._heroImage)); // If hero swapped in saved game, swap it if ((i = _vm._heroImage) != HERO) _vm.scheduler().swapImages(HERO, _vm._heroImage); _vm._heroImage = i; status_t &gameStatus = _vm.getGameStatus(); int score; in->read(&score, sizeof(score)); _vm.setScore(score); in->read(&gameStatus.storyModeFl, sizeof(gameStatus.storyModeFl)); in->read(&gameStatus.jumpExitFl, sizeof(gameStatus.jumpExitFl)); in->read(&gameStatus.gameOverFl, sizeof(gameStatus.gameOverFl)); in->read(_vm._screenStates, sizeof(*_vm._screenStates) * _vm._numScreens); // Restore points table in->read(_vm._points, sizeof(point_t) * _vm._numBonuses); // Restore ptrs to currently loaded objects for (i = 0; i < _vm._numObj; i++) restoreSeq(&_vm._objects[i]); // Now restore time of the save and the event queue _vm.scheduler().restoreEvents(in); // Restore palette and change it if necessary _vm.screen().restorePal(in); // Restore maze status in->read(&_maze, sizeof(maze_t)); delete in; } void FileManager::initSavedGame() { // Initialize the size of a saved game (from the fixed initial game). // If status.initsave is TRUE, or the initial saved game is not found, // force a save to create one. Normally the game will be shipped with // the initial game file but useful to force a write during development // when the size is changeable. // The net result is a valid INITFILE, with status.savesize initialized. Common::File f; // Handle of saved game file char path[256]; // Full path of INITFILE debugC(1, kDebugFile, "initSavedGame"); // Get full path of INITFILE sprintf(path, "%s", _vm._initFilename); // Force save of initial game if (_vm.getGameStatus().initSaveFl) saveGame(-1, ""); // If initial game doesn't exist, create it Common::SeekableReadStream *in = 0; if (!(in = _vm.getSaveFileManager()->openForLoading(path))) { saveGame(-1, ""); if (!(in = _vm.getSaveFileManager()->openForLoading(path))) { Utils::Error(WRITE_ERR, "%s", path); return; } } // Must have an open saved game now _vm.getGameStatus().saveSize = in->size(); delete in; // Check sanity - maybe disk full or path set to read-only drive? if (_vm.getGameStatus().saveSize == -1) Utils::Error(WRITE_ERR, "%s", path); } // Record and playback handling stuff: typedef struct { // int key; // Character uint32 time; // Time at which character was pressed } pbdata_t; static pbdata_t pbdata; FILE *fpb; void FileManager::openPlaybackFile(bool playbackFl, bool recordFl) { debugC(1, kDebugFile, "openPlaybackFile(%d, %d)", (playbackFl) ? 1 : 0, (recordFl) ? 1 : 0); if (playbackFl) { if (!(fpb = fopen(PBFILE, "r+b"))) Utils::Error(FILE_ERR, "%s", PBFILE); } else if (recordFl) fpb = fopen(PBFILE, "wb"); pbdata.time = 0; // Say no key available } void FileManager::closePlaybackFile() { fclose(fpb); } void FileManager::printBootText() { // Read the encrypted text from the boot file and print it Common::File ofp; int i; char *buf; debugC(1, kDebugFile, "printBootText"); if (!ofp.open(BOOTFILE)) { if (_vm._gameVariant == 3) { //TODO initialize properly _boot structure warning("printBootText - Skipping as H1 Dos may be a freeware"); return; } else Utils::Error(FILE_ERR, "%s", BOOTFILE); } // Allocate space for the text and print it buf = (char *)malloc(_boot.exit_len + 1); if (buf) { // Skip over the boot structure (already read) and read exit text ofp.seek((long)sizeof(_boot), SEEK_SET); if (ofp.read(buf, _boot.exit_len) != (size_t)_boot.exit_len) Utils::Error(FILE_ERR, "%s", BOOTFILE); // Decrypt the exit text, using CRYPT substring for (i = 0; i < _boot.exit_len; i++) buf[i] ^= CRYPT[i % strlen(CRYPT)]; buf[i] = '\0'; //Box(BOX_OK, "%s", buf_p); //MessageBox(hwnd, buf_p, "License", MB_ICONINFORMATION); warning("printBootText(): License: %s", buf); } free(buf); ofp.close(); } void FileManager::readBootFile() { // Reads boot file for program environment. Fatal error if not there or // file checksum is bad. De-crypts structure while checking checksum byte checksum; byte *p; Common::File ofp; uint32 i; debugC(1, kDebugFile, "readBootFile"); if (!ofp.open(BOOTFILE)) { if (_vm._gameVariant == 3) { //TODO initialize properly _boot structure warning("readBootFile - Skipping as H1 Dos may be a freeware"); return; } else Utils::Error(FILE_ERR, "%s", BOOTFILE); } if (ofp.size() < (int32)sizeof(_boot)) Utils::Error(FILE_ERR, "%s", BOOTFILE); _boot.checksum = ofp.readByte(); _boot.registered = ofp.readByte(); ofp.read(_boot.pbswitch, sizeof(_boot.pbswitch)); ofp.read(_boot.distrib, sizeof(_boot.distrib)); _boot.exit_len = ofp.readUint16LE(); p = (byte *)&_boot; for (i = 0, checksum = 0; i < sizeof(_boot); i++) { checksum ^= p[i]; p[i] ^= CRYPT[i % strlen(CRYPT)]; } ofp.close(); if (checksum) Utils::Error(GEN_ERR, "%s", "Program startup file invalid"); } uif_hdr_t *FileManager::getUIFHeader(uif_t id) { // Returns address of uif_hdr[id], reading it in if first call static uif_hdr_t UIFHeader[MAX_UIFS]; // Lookup for uif fonts/images static bool firstFl = true; Common::File ip; // Image data file debugC(1, kDebugFile, "getUIFHeader(%d)", id); // Initialize offset lookup if not read yet if (firstFl) { firstFl = false; // Open unbuffered to do far read if (!ip.open(UIF_FILE)) Utils::Error(FILE_ERR, "%s", UIF_FILE); if (ip.size() < (int32)sizeof(UIFHeader)) Utils::Error(FILE_ERR, "%s", UIF_FILE); for (int i = 0; i < MAX_UIFS; ++i) { UIFHeader[i].size = ip.readUint16LE(); UIFHeader[i].offset = ip.readUint32LE(); } ip.close(); } return &UIFHeader[id]; } void FileManager::readUIFItem(int16 id, byte *buf) { // Read uif item into supplied buffer. Common::File ip; // UIF_FILE handle uif_hdr_t *UIFHeaderPtr; // Lookup table of items seq_t seq; // Dummy seq_t for image data debugC(1, kDebugFile, "readUIFItem(%d, ...)", id); // Open uif file to read data if (!ip.open(UIF_FILE)) Utils::Error(FILE_ERR, "%s", UIF_FILE); // Seek to data UIFHeaderPtr = getUIFHeader((uif_t)id); ip.seek(UIFHeaderPtr->offset, SEEK_SET); // We support pcx images and straight data switch (id) { case UIF_IMAGES: // Read uif images file readPCX(ip, &seq, buf, true, UIF_FILE); break; default: // Read file data into supplied array if (ip.read(buf, UIFHeaderPtr->size) != UIFHeaderPtr->size) Utils::Error(FILE_ERR, "%s", UIF_FILE); break; } ip.close(); } void FileManager::instructions() { // Simple instructions given when F1 pressed twice in a row // Only in DOS versions Common::File f; char line[1024], *wrkLine; char readBuf[2]; wrkLine = line; if (!f.open(HELPFILE)) { warning("help.dat not found"); return; } while (f.read(readBuf, 1)) { wrkLine[0] = readBuf[0]; wrkLine++; do { f.read(wrkLine, 1); } while (*wrkLine++ != EOP); wrkLine[-2] = '\0'; /* Remove EOP and previous CR */ Utils::Box(BOX_ANY, "%s", line); wrkLine = line; f.read(readBuf, 2); /* Remove CRLF after EOP */ } f.close(); } FileManager_v1d::FileManager_v1d(HugoEngine &vm) : FileManager(vm) { } FileManager_v1d::~FileManager_v1d() { } void FileManager_v1d::openDatabaseFiles() { debugC(1, kDebugFile, "openDatabaseFiles"); } void FileManager_v1d::closeDatabaseFiles() { debugC(1, kDebugFile, "closeDatabaseFiles"); } void FileManager_v1d::readOverlay(int screenNum, image_pt image, ovl_t overlayType) { // Open and read in an overlay file, close file uint32 i = 0; image_pt tmpImage = image; // temp ptr to overlay file debugC(1, kDebugFile, "readOverlay(%d, ...)", screenNum); const char *ovl_ext[] = {".b", ".o", ".ob"}; char *buf = (char *) malloc(2048 + 1); // Buffer for file access strcat(strcpy(buf, _vm._screenNames[screenNum]), ovl_ext[overlayType]); if (!fileExists(buf)) { for (i = 0; i < OVL_SIZE; i++) image[i] = 0; return; } if (!_sceneryArchive1.open(buf)) Utils::Error(FILE_ERR, "%s", buf); _sceneryArchive1.read(tmpImage, OVL_SIZE); _sceneryArchive1.close(); } void FileManager_v1d::readBackground(int screenIndex) { // Read a PCX image into dib_a seq_t seq; // Image sequence structure for Read_pcx debugC(1, kDebugFile, "readBackground(%d)", screenIndex); char *buf = (char *) malloc(2048 + 1); // Buffer for file access strcat(strcpy(buf, _vm._screenNames[screenIndex]), ".ART"); if (!_sceneryArchive1.open(buf)) Utils::Error(FILE_ERR, "%s", buf); // Read the image into dummy seq and static dib_a readPCX(_sceneryArchive1, &seq, _vm.screen().getFrontBuffer(), true, _vm._screenNames[screenIndex]); _sceneryArchive1.close(); } char *FileManager_v1d::fetchString(int index) { debugC(1, kDebugFile, "fetchString(%d)", index); return _vm._stringtData[index]; } FileManager_v2d::FileManager_v2d(HugoEngine &vm) : FileManager(vm) { } FileManager_v2d::~FileManager_v2d() { } void FileManager_v2d::openDatabaseFiles() { debugC(1, kDebugFile, "openDatabaseFiles"); if (!_stringArchive.open(STRING_FILE)) Utils::Error(FILE_ERR, "%s", STRING_FILE); if (!_sceneryArchive1.open("scenery.dat")) Utils::Error(FILE_ERR, "%s", "scenery.dat"); if (!_objectsArchive.open(OBJECTS_FILE)) Utils::Error(FILE_ERR, "%s", OBJECTS_FILE); } void FileManager_v2d::closeDatabaseFiles() { debugC(1, kDebugFile, "closeDatabaseFiles"); _stringArchive.close(); _sceneryArchive1.close(); _objectsArchive.close(); } void FileManager_v2d::readBackground(int screenIndex) { // Read a PCX image into dib_a seq_t seq; // Image sequence structure for Read_pcx sceneBlock_t sceneBlock; // Read a database header entry debugC(1, kDebugFile, "readBackground(%d)", screenIndex); _sceneryArchive1.seek((uint32) screenIndex * sizeof(sceneBlock_t), SEEK_SET); sceneBlock.scene_off = _sceneryArchive1.readUint32LE(); sceneBlock.scene_len = _sceneryArchive1.readUint32LE(); sceneBlock.b_off = _sceneryArchive1.readUint32LE(); sceneBlock.b_len = _sceneryArchive1.readUint32LE(); sceneBlock.o_off = _sceneryArchive1.readUint32LE(); sceneBlock.o_len = _sceneryArchive1.readUint32LE(); sceneBlock.ob_off = _sceneryArchive1.readUint32LE(); sceneBlock.ob_len = _sceneryArchive1.readUint32LE(); _sceneryArchive1.seek(sceneBlock.scene_off, SEEK_SET); // Read the image into dummy seq and static dib_a readPCX(_sceneryArchive1, &seq, _vm.screen().getFrontBuffer(), true, _vm._screenNames[screenIndex]); } void FileManager_v2d::readOverlay(int screenNum, image_pt image, ovl_t overlayType) { // Open and read in an overlay file, close file uint32 i = 0; int16 j, k; int8 data; // Must be 8 bits signed image_pt tmpImage = image; // temp ptr to overlay file sceneBlock_t sceneBlock; // Database header entry debugC(1, kDebugFile, "readOverlay(%d, ...)", screenNum); _sceneryArchive1.seek((uint32)screenNum * sizeof(sceneBlock_t), SEEK_SET); sceneBlock.scene_off = _sceneryArchive1.readUint32LE(); sceneBlock.scene_len = _sceneryArchive1.readUint32LE(); sceneBlock.b_off = _sceneryArchive1.readUint32LE(); sceneBlock.b_len = _sceneryArchive1.readUint32LE(); sceneBlock.o_off = _sceneryArchive1.readUint32LE(); sceneBlock.o_len = _sceneryArchive1.readUint32LE(); sceneBlock.ob_off = _sceneryArchive1.readUint32LE(); sceneBlock.ob_len = _sceneryArchive1.readUint32LE(); switch (overlayType) { case BOUNDARY: _sceneryArchive1.seek(sceneBlock.b_off, SEEK_SET); i = sceneBlock.b_len; break; case OVERLAY: _sceneryArchive1.seek(sceneBlock.o_off, SEEK_SET); i = sceneBlock.o_len; break; case OVLBASE: _sceneryArchive1.seek(sceneBlock.ob_off, SEEK_SET); i = sceneBlock.ob_len; break; default: Utils::Error(FILE_ERR, "%s", "Bad ovl_type"); break; } if (i == 0) { for (i = 0; i < OVL_SIZE; i++) image[i] = 0; return; } // Read in the overlay file using MAC Packbits. (We're not proud!) k = 0; // byte count do { data = _sceneryArchive1.readByte(); // Read a code byte if ((byte)data == 0x80) // Noop k = k; else if (data >= 0) { // Copy next data+1 literally for (i = 0; i <= (byte)data; i++, k++) *tmpImage++ = _sceneryArchive1.readByte(); } else { // Repeat next byte -data+1 times j = _sceneryArchive1.readByte(); for (i = 0; i < (byte)(-data + 1); i++, k++) *tmpImage++ = j; } } while (k < OVL_SIZE); } char *FileManager_v2d::fetchString(int index) { // Fetch string from file, decode and return ptr to string in memory uint32 off1, off2; debugC(1, kDebugFile, "fetchString(%d)", index); // Get offset to string[index] (and next for length calculation) _stringArchive.seek((uint32)index * sizeof(uint32), SEEK_SET); if (_stringArchive.read((char *)&off1, sizeof(uint32)) == 0) Utils::Error(FILE_ERR, "%s", "String offset"); if (_stringArchive.read((char *)&off2, sizeof(uint32)) == 0) Utils::Error(FILE_ERR, "%s", "String offset"); // Check size of string if ((off2 - off1) >= MAX_BOX) Utils::Error(FILE_ERR, "%s", "Fetched string too long!"); // Position to string and read it into gen purpose _textBoxBuffer _stringArchive.seek(off1, SEEK_SET); if (_stringArchive.read(_textBoxBuffer, (uint16)(off2 - off1)) == 0) Utils::Error(FILE_ERR, "%s", "Fetch_string"); // Null terminate, decode and return it _textBoxBuffer[off2-off1] = '\0'; _vm.scheduler().decodeString(_textBoxBuffer); return _textBoxBuffer; } FileManager_v1w::FileManager_v1w(HugoEngine &vm) : FileManager_v2d(vm) { } FileManager_v1w::~FileManager_v1w() { } void FileManager_v1w::readOverlay(int screenNum, image_pt image, ovl_t overlayType) { // Open and read in an overlay file, close file uint32 i = 0; image_pt tmpImage = image; // temp ptr to overlay file sceneBlock_t sceneBlock; // Database header entry debugC(1, kDebugFile, "readOverlay(%d, ...)", screenNum); _sceneryArchive1.seek((uint32)screenNum * sizeof(sceneBlock_t), SEEK_SET); sceneBlock.scene_off = _sceneryArchive1.readUint32LE(); sceneBlock.scene_len = _sceneryArchive1.readUint32LE(); sceneBlock.b_off = _sceneryArchive1.readUint32LE(); sceneBlock.b_len = _sceneryArchive1.readUint32LE(); sceneBlock.o_off = _sceneryArchive1.readUint32LE(); sceneBlock.o_len = _sceneryArchive1.readUint32LE(); sceneBlock.ob_off = _sceneryArchive1.readUint32LE(); sceneBlock.ob_len = _sceneryArchive1.readUint32LE(); switch (overlayType) { case BOUNDARY: _sceneryArchive1.seek(sceneBlock.b_off, SEEK_SET); i = sceneBlock.b_len; break; case OVERLAY: _sceneryArchive1.seek(sceneBlock.o_off, SEEK_SET); i = sceneBlock.o_len; break; case OVLBASE: _sceneryArchive1.seek(sceneBlock.ob_off, SEEK_SET); i = sceneBlock.ob_len; break; default: Utils::Error(FILE_ERR, "%s", "Bad ovl_type"); break; } if (i == 0) { for (i = 0; i < OVL_SIZE; i++) image[i] = 0; return; } _sceneryArchive1.read(tmpImage, OVL_SIZE); } FileManager_v3d::FileManager_v3d(HugoEngine &vm) : FileManager_v2d(vm) { } FileManager_v3d::~FileManager_v3d() { } void FileManager_v3d::readBackground(int screenIndex) { // Read a PCX image into dib_a seq_t seq; // Image sequence structure for Read_pcx sceneBlock_t sceneBlock; // Read a database header entry Common::File sceneryArchive; debugC(1, kDebugFile, "readBackground(%d)", screenIndex); _sceneryArchive1.seek((uint32) screenIndex * sizeof(sceneBlock_t), SEEK_SET); sceneBlock.scene_off = _sceneryArchive1.readUint32LE(); sceneBlock.scene_len = _sceneryArchive1.readUint32LE(); sceneBlock.b_off = _sceneryArchive1.readUint32LE(); sceneBlock.b_len = _sceneryArchive1.readUint32LE(); sceneBlock.o_off = _sceneryArchive1.readUint32LE(); sceneBlock.o_len = _sceneryArchive1.readUint32LE(); sceneBlock.ob_off = _sceneryArchive1.readUint32LE(); sceneBlock.ob_len = _sceneryArchive1.readUint32LE(); if (screenIndex < 20) { _sceneryArchive1.seek(sceneBlock.scene_off, SEEK_SET); // Read the image into dummy seq and static dib_a readPCX(_sceneryArchive1, &seq, _vm.screen().getFrontBuffer(), true, _vm._screenNames[screenIndex]); } else { _sceneryArchive2.seek(sceneBlock.scene_off, SEEK_SET); // Read the image into dummy seq and static dib_a readPCX(_sceneryArchive2, &seq, _vm.screen().getFrontBuffer(), true, _vm._screenNames[screenIndex]); } } void FileManager_v3d::openDatabaseFiles() { debugC(1, kDebugFile, "openDatabaseFiles"); if (!_stringArchive.open(STRING_FILE)) Utils::Error(FILE_ERR, "%s", STRING_FILE); if (!_sceneryArchive1.open("scenery1.dat")) Utils::Error(FILE_ERR, "%s", "scenery1.dat"); if (!_sceneryArchive2.open("scenery2.dat")) Utils::Error(FILE_ERR, "%s", "scenery2.dat"); if (!_objectsArchive.open(OBJECTS_FILE)) Utils::Error(FILE_ERR, "%s", OBJECTS_FILE); } void FileManager_v3d::closeDatabaseFiles() { debugC(1, kDebugFile, "closeDatabaseFiles"); _stringArchive.close(); _sceneryArchive1.close(); _sceneryArchive2.close(); _objectsArchive.close(); } void FileManager_v3d::readOverlay(int screenNum, image_pt image, ovl_t overlayType) { // Open and read in an overlay file, close file uint32 i = 0; int16 j, k; int8 data; // Must be 8 bits signed image_pt tmpImage = image; // temp ptr to overlay file sceneBlock_t sceneBlock; // Database header entry Common::File sceneryArchive; debugC(1, kDebugFile, "readOverlay(%d, ...)", screenNum); _sceneryArchive1.seek((uint32)screenNum * sizeof(sceneBlock_t), SEEK_SET); sceneBlock.scene_off = _sceneryArchive1.readUint32LE(); sceneBlock.scene_len = _sceneryArchive1.readUint32LE(); sceneBlock.b_off = _sceneryArchive1.readUint32LE(); sceneBlock.b_len = _sceneryArchive1.readUint32LE(); sceneBlock.o_off = _sceneryArchive1.readUint32LE(); sceneBlock.o_len = _sceneryArchive1.readUint32LE(); sceneBlock.ob_off = _sceneryArchive1.readUint32LE(); sceneBlock.ob_len = _sceneryArchive1.readUint32LE(); if (screenNum < 20) { switch (overlayType) { case BOUNDARY: _sceneryArchive1.seek(sceneBlock.b_off, SEEK_SET); i = sceneBlock.b_len; break; case OVERLAY: _sceneryArchive1.seek(sceneBlock.o_off, SEEK_SET); i = sceneBlock.o_len; break; case OVLBASE: _sceneryArchive1.seek(sceneBlock.ob_off, SEEK_SET); i = sceneBlock.ob_len; break; default: Utils::Error(FILE_ERR, "%s", "Bad ovl_type"); break; } if (i == 0) { for (i = 0; i < OVL_SIZE; i++) image[i] = 0; return; } // Read in the overlay file using MAC Packbits. (We're not proud!) k = 0; // byte count do { data = _sceneryArchive1.readByte(); // Read a code byte if ((byte)data == 0x80) // Noop k = k; else if (data >= 0) { // Copy next data+1 literally for (i = 0; i <= (byte)data; i++, k++) *tmpImage++ = _sceneryArchive1.readByte(); } else { // Repeat next byte -data+1 times j = _sceneryArchive1.readByte(); for (i = 0; i < (byte)(-data + 1); i++, k++) *tmpImage++ = j; } } while (k < OVL_SIZE); } else { switch (overlayType) { case BOUNDARY: _sceneryArchive2.seek(sceneBlock.b_off, SEEK_SET); i = sceneBlock.b_len; break; case OVERLAY: _sceneryArchive2.seek(sceneBlock.o_off, SEEK_SET); i = sceneBlock.o_len; break; case OVLBASE: _sceneryArchive2.seek(sceneBlock.ob_off, SEEK_SET); i = sceneBlock.ob_len; break; default: Utils::Error(FILE_ERR, "%s", "Bad ovl_type"); break; } if (i == 0) { for (i = 0; i < OVL_SIZE; i++) image[i] = 0; return; } // Read in the overlay file using MAC Packbits. (We're not proud!) k = 0; // byte count do { data = _sceneryArchive2.readByte(); // Read a code byte if ((byte)data == 0x80) // Noop k = k; else if (data >= 0) { // Copy next data+1 literally for (i = 0; i <= (byte)data; i++, k++) *tmpImage++ = _sceneryArchive2.readByte(); } else { // Repeat next byte -data+1 times j = _sceneryArchive2.readByte(); for (i = 0; i < (byte)(-data + 1); i++, k++) *tmpImage++ = j; } } while (k < OVL_SIZE); } } } // End of namespace Hugo