/* ScummVM - Scumm Interpreter * Copyright (C) 2005-2006 The ScummVM project * * 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 is a utility for extracting needed resource data from the Lure of the Temptress * lure.exe file into a new file lure.dat - this file is required for the ScummVM * Lure of the Temptress module to work properly * * TODO: * Some of the field values, such as hotspot tick proc offsets, will vary with * different language versions. These will need to be remapped to a language independant * value once I've fully implemented the English version. * Some areas of the data segment are still to be decoded */ #include #include #include #include "create_lure_dat.h" File lure_exe; uint16 animOffsets[MAX_NUM_ANIM_RECORDS]; int animIndex = 0; uint16 actionOffsets[MAX_NUM_ACTION_RECORDS]; int actionIndex = 0; void add_anim_record(uint16 offset) { for (int ctr = 0; ctr < animIndex; ++ctr) if (animOffsets[ctr] == offset) return; if (animIndex == MAX_NUM_ANIM_RECORDS) { printf("Animation record offset table size exceeded\n"); exit(1); } animOffsets[animIndex++] = offset; } void add_action_list(uint16 offset) { for (int ctr = 0; ctr < actionIndex; ++ctr) if (actionOffsets[ctr] == offset) return; if (actionIndex == MAX_NUM_ACTION_RECORDS) { printf("Action record offset table size exceeded\n"); exit(1); } actionOffsets[actionIndex++] = offset; } void read_basic_palette(byte *&data, uint16 &totalSize) { totalSize = PALETTE_SIZE; lure_exe.seek(PALETTE_OFFSET); data = (byte *) malloc(PALETTE_SIZE); lure_exe.read(data, totalSize); } #define ALT_PALETTE_1 0x1757 #define ALT_PALETTE_1_SIZE 180 #define ALT_PALETTE_2 0x180B #define ALT_PALETTE_2_SIZE 24 void read_replacement_palette(byte *&data, uint16 &totalSize) { totalSize = ALT_PALETTE_1_SIZE + ALT_PALETTE_2_SIZE; data = (byte *) malloc(totalSize); lure_exe.seek(DATA_SEGMENT + ALT_PALETTE_1); lure_exe.read(data, ALT_PALETTE_1_SIZE); lure_exe.seek(DATA_SEGMENT + ALT_PALETTE_2); lure_exe.read(data + ALT_PALETTE_1_SIZE, ALT_PALETTE_2_SIZE); } void read_dialog_data(byte *&data, uint16 &totalSize) { totalSize = DIALOG_SIZE; lure_exe.seek(DIALOG_OFFSET); data = (byte *) malloc(DIALOG_SIZE); lure_exe.read(data, totalSize); } void read_talk_dialog_data(byte *&data, uint16 &totalSize) { totalSize = TALK_DIALOG_SIZE; lure_exe.seek(TALK_DIALOG_OFFSET, SEEK_SET); data = (byte *) malloc(TALK_DIALOG_SIZE); lure_exe.read(data, totalSize); } void read_room_data(byte *&data, uint16 &totalSize) { data = (byte *) malloc(MAX_DATA_SIZE); memset(data, 0, MAX_DATA_SIZE); uint16 *offsetPtr = (uint16 *) data; uint16 offset = (ROOM_NUM_ENTRIES + 1) * sizeof(uint16); uint16 pixelOffset; RoomResource buffer; int outputIndex = 0; RoomHeaderEntry headerEntry; RoomRectIn bounds; for (int index = 0; index < ROOM_NUM_ENTRIES; ++index) { lure_exe.seek(DATA_SEGMENT + ROOM_TABLE + index * 9); lure_exe.read(&headerEntry, sizeof(RoomHeaderEntry)); if ((FROM_LE_16(headerEntry.offset) != 0) && (FROM_LE_16(headerEntry.offset) != 0xffff) && (FROM_LE_16(headerEntry.roomNumber) != 0xc09) && (FROM_LE_16(headerEntry.roomNumber) != 0)) { // Store offset of room entry *offsetPtr++ = TO_LE_16(offset); // Copy over basic room details lure_exe.seek(DATA_SEGMENT + headerEntry.offset); lure_exe.read(&buffer, sizeof(RoomResource)); RoomResourceOutput *rec = (RoomResourceOutput *) (data + offset); rec->hdrFlags = headerEntry.hdrFlags; rec->actions = FROM_LE_32(buffer.actions); rec->roomNumber = headerEntry.roomNumber; rec->descId = headerEntry.descId; rec->numLayers = buffer.numLayers; memcpy(rec->layers, buffer.layers, 8); rec->sequenceOffset = buffer.sequenceOffset; rec->clippingXStart = TO_LE_16(FROM_LE_16(buffer.clippingXStart) - 0x80); rec->clippingXEnd = (FROM_LE_16(buffer.clippingXEnd) == 0) ? 0 : TO_LE_16(FROM_LE_16(buffer.clippingXEnd) - 0x80); rec->numExits = 0; offset += sizeof(RoomResourceOutput); // Copy over room exits for (;;) { RoomResourceExit1 *p = (RoomResourceExit1 *) (data + offset); lure_exe.read(p, sizeof(RoomResourceExit1)); if (FROM_LE_16(p->xs) == 0xffff) break; rec->numExits = TO_LE_16(FROM_LE_16(rec->numExits) + 1); p->xs = TO_LE_16(FROM_LE_16(p->xs) - 0x80); p->ys = TO_LE_16(FROM_LE_16(p->ys) - 0x80); p->xe = TO_LE_16(FROM_LE_16(p->xe) - 0x80); p->ye = TO_LE_16(FROM_LE_16(p->ye) - 0x80); offset += sizeof(RoomResourceExit1); RoomResourceExit2 *p2 = (RoomResourceExit2 *) (data + offset); if (FROM_LE_16(p->sequenceOffset) == 0xffff) { lure_exe.read(p2, sizeof(RoomResourceExit2)); p2->newRoomX = TO_LE_16(FROM_LE_16(p2->newRoomX) - 0x80); p2->newRoomY = TO_LE_16(FROM_LE_16(p2->newRoomY) - 0x80); } else { p2->newRoom = 0; p2->direction = 0; p2->newRoomX = 0; p2->newRoomY = 0; } offset += sizeof(RoomResourceExit2); } // Handle the random destination walk bounds for the room lure_exe.seek(DATA_SEGMENT + WALK_AREAS_OFFSET + buffer.walkBoundsIndex * sizeof(RoomRectIn)); lure_exe.read(&bounds, sizeof(RoomRectIn)); rec->walkBounds.xs = TO_LE_16(FROM_LE_16(bounds.xs) - 0x80); rec->walkBounds.xe = TO_LE_16(FROM_LE_16(bounds.xe) - 0x80); rec->walkBounds.ys = TO_LE_16(FROM_LE_16(bounds.ys) - 0x80); rec->walkBounds.ye = TO_LE_16(FROM_LE_16(bounds.ye) - 0x80); // If the room has a default pixel blocks list, add the references if (buffer.pixelListOffset != 0) { lure_exe.seek(DATA_SEGMENT + FROM_LE_16(buffer.pixelListOffset)); pixelOffset = lure_exe.readWord(); while (pixelOffset != 0) { add_anim_record(pixelOffset); pixelOffset = lure_exe.readWord(); } } } } WRITE_LE_UINT16(offsetPtr, 0xffff); totalSize = offset; } void read_hotspot_data(byte *&data, uint16 &totalSize) { uint16 offsets[4] = {0x5d98, 0x5eb8, 0x623e, 0x63b1}; uint16 startId[4] = {0x3e8, 0x408, 0x2710, 0x7530}; int walkNumEntries = 0; int walkCtr; int numEntries; HotspotWalkToRecord rec; HotspotWalkToRecord *walkList; HotspotHeaderEntry entryHeader; HotspotResource entry; uint16 dataSize; HotspotResourceOutput *r; CurrentActionInput action; // Allocate enough space for output hotspot list data = (byte *) malloc(MAX_HOTSPOTS * sizeof(HotspotResourceOutput)); // Determine number of hotspot walk to entries lure_exe.seek(DATA_SEGMENT + HOTSPOT_WALK_TO_OFFSET); do { ++walkNumEntries; lure_exe.read(&rec, sizeof(HotspotWalkToRecord)); } while (TO_LE_16(rec.hotspotId) != 0); --walkNumEntries; dataSize = walkNumEntries * sizeof(HotspotWalkToRecord); walkList = (HotspotWalkToRecord *) malloc(dataSize); lure_exe.seek(DATA_SEGMENT + HOTSPOT_WALK_TO_OFFSET); lure_exe.read(walkList, sizeof(HotspotWalkToRecord) * walkNumEntries); // Main code for creating the hotspot list r = (HotspotResourceOutput *) data; numEntries = 0; for (int tableNum = 0; tableNum < 4; ++tableNum) { uint16 hotspotIndex = 0; for (;;) { lure_exe.seek(DATA_SEGMENT + offsets[tableNum] + hotspotIndex * 9); lure_exe.read(&entryHeader, sizeof(HotspotHeaderEntry)); if (FROM_LE_16(entryHeader.offset) == 0xffff) break; memset(r, 0, sizeof(HotspotResourceOutput)); r->hotspotId = TO_LE_16(startId[tableNum] + hotspotIndex); r->nameId = entryHeader.resourceId; r->descId = entryHeader.descId; //TO_LE_16(FROM_LE_16(entryHeader.descId) & 0x1fff); r->descId2 = entryHeader.descId2; //TO_LE_16(FROM_LE_16(entryHeader.descId2) & 0x1fff); r->hdrFlags = entryHeader.hdrFlags; // Get the hotspot data lure_exe.seek(DATA_SEGMENT + entryHeader.offset); lure_exe.read(&entry, sizeof(HotspotResource)); r->actions = entry.actions; r->roomNumber = entry.roomNumber; r->startX = TO_LE_16(FROM_LE_16(entry.startX) - 0x80); r->startY = TO_LE_16(FROM_LE_16(entry.startY) - 0x80); r->width = entry.width; r->height = entry.height; r->widthCopy = entry.widthCopy; r->heightCopy = entry.heightCopy; r->yCorrection = entry.yCorrection; r->talkX = entry.talkX; r->talkY = entry.talkY; r->characterMode = entry.characterMode; r->delayCtr = entry.delayCtr; r->tickSequenceOffset = entry.tickSequenceOffset; r->layer = entry.layer; r->scriptLoadFlag = entry.scriptLoadFlag; r->loadOffset = entry.loadOffset; r->colourOffset = entry.colourOffset; r->sequenceOffset = entry.sequenceOffset; r->tickProcOffset = entry.tickProcOffset; r->flags = entry.flags; // Find the walk-to coordinates for the hotspot walkCtr = 0; while ((walkCtr < walkNumEntries) && (FROM_LE_16(walkList[walkCtr].hotspotId) != FROM_LE_16(r->hotspotId))) ++walkCtr; if (walkCtr == walkNumEntries) { r->walkX = 0; r->walkY = 0; } else { r->walkX = TO_LE_16(FROM_LE_16(walkList[walkCtr].x) - 0x80); uint16 y = FROM_LE_16(walkList[walkCtr].y); r->walkY = TO_LE_16((y & 0x8000) | (uint16) ((int16) (y & 0x7fff) - 0x80)); } // Use the offset of the animation data as a dummy Id for the data r->animRecordId = entry.animOffset; r->tickTimeout = entry.tickTimeout; add_anim_record(FROM_LE_16(entry.animOffset)); // Add in the actions offset table r->actionsOffset = entry.actionsOffset; if (FROM_LE_16(entry.actionsOffset) != 0) add_action_list(FROM_LE_16(entry.actionsOffset)); if (FROM_LE_16(r->hotspotId) >= 0x408) { // Hotspot is not an NPC r->npcSchedule = 0; } else { // Check for an NPC schedule lure_exe.seek(DATA_SEGMENT + entryHeader.offset + 0x63); lure_exe.read(&action, sizeof(CurrentActionInput)); if (action.action != 2) r->npcSchedule = 0; else { r->npcSchedule = get_sequence_index(FROM_LE_16(action.dataOffset)); } } ++hotspotIndex; ++r; ++numEntries; if (numEntries == MAX_HOTSPOTS) { printf("Ran out of stack spaces for hotspot copying\n"); exit(1); } } } r->hotspotId = TO_LE_16(0xffff); totalSize = numEntries * sizeof(HotspotResourceOutput) + 2; // Dispose of hotspot walk-to co-ordinate list free(walkList); } void read_hotspot_override_data(byte *&data, uint16 &totalSize) { lure_exe.seek(DATA_SEGMENT + HOTSPOT_OVERRIDE_OFFSET); int numOverrides = 0; HotspotOverride rec; // Determine number of hotspot overrides do { ++numOverrides; lure_exe.read(&rec, sizeof(HotspotOverride)); } while (FROM_LE_16(rec.hotspotId) != 0); --numOverrides; // Prepare output data and read in all entries at once totalSize = numOverrides * sizeof(HotspotOverride) + 2; data = (byte *) malloc(totalSize); lure_exe.seek(DATA_SEGMENT + HOTSPOT_OVERRIDE_OFFSET); lure_exe.read(data, totalSize - 2); WRITE_LE_UINT16(data + totalSize - 2, 0xffff); // Post-process the coordinates HotspotOverride *p = (HotspotOverride *) data; for (int overrideCtr = 0; overrideCtr < numOverrides; ++overrideCtr, ++p) { p->xs = TO_LE_16(FROM_LE_16(p->xs) - 0x80); p->xe = TO_LE_16(FROM_LE_16(p->xe) - 0x80); p->ys = TO_LE_16(FROM_LE_16(p->ys) - 0x80); p->ye = TO_LE_16(FROM_LE_16(p->ye) - 0x80); } } void read_room_exits(byte *&data, uint16 &totalSize) { RoomExitHotspotRecord rec; uint16 offsets[NUM_ROOM_EXITS]; uint16 numEntries[NUM_ROOM_EXITS]; int roomCtr; totalSize = (NUM_ROOM_EXITS + 1) * sizeof(uint16); lure_exe.seek(DATA_SEGMENT + ROOM_EXITS_OFFSET); for (roomCtr = 0; roomCtr < NUM_ROOM_EXITS; ++roomCtr) offsets[roomCtr] = lure_exe.readWord(); // First loop to find total of room exit records there are for (roomCtr = 0; roomCtr < NUM_ROOM_EXITS; ++roomCtr) { numEntries[roomCtr] = 0; if (offsets[roomCtr] == 0) continue; // Get number of exits for the room lure_exe.seek(DATA_SEGMENT + offsets[roomCtr]); lure_exe.read(&rec, sizeof(RoomExitHotspotRecord)); while (FROM_LE_16(rec.xs) != 0) { totalSize += sizeof(RoomExitHotspotOutputRecord); numEntries[roomCtr]++; lure_exe.read(&rec, sizeof(RoomExitHotspotRecord)); } totalSize += sizeof(uint16); // save room for room list end flag } // Alloacte the total needed space data = (byte *) malloc(totalSize); uint16 *offset = (uint16 *) data; uint16 destIndex = (NUM_ROOM_EXITS + 1) * sizeof(uint16); uint16 entryCtr; // Loop to build up the result table for (roomCtr = 0; roomCtr < NUM_ROOM_EXITS; ++roomCtr) { if (offsets[roomCtr] == 0) { *offset++ = 0; // No entries } else { // Read in the entries for the room *offset++ = TO_LE_16(destIndex); RoomExitHotspotOutputRecord *destP = (RoomExitHotspotOutputRecord *) (data + destIndex); lure_exe.seek(DATA_SEGMENT + offsets[roomCtr]); for (entryCtr = 0; entryCtr < numEntries[roomCtr]; ++entryCtr, ++destP) { lure_exe.read(&rec, sizeof(RoomExitHotspotRecord)); // Copy over the record destP->xs = TO_LE_16(FROM_LE_16(rec.xs) - 0x80); destP->xe = TO_LE_16(FROM_LE_16(rec.xe) - 0x80); destP->ys = TO_LE_16(FROM_LE_16(rec.ys) - 0x80); destP->ye = TO_LE_16(FROM_LE_16(rec.ye) - 0x80); destP->hotspotId = rec.hotspotId; destP->cursorNum = rec.cursorNum; destP->destRoomNumber = rec.destRoomNumber; } destIndex += numEntries[roomCtr] * sizeof(RoomExitHotspotOutputRecord); WRITE_LE_UINT16(data + destIndex, 0xffff); destIndex += sizeof(uint16); } } WRITE_LE_UINT16(offset, 0xffff); } void read_room_exit_joins(byte *&data, uint16 &totalSize) { RoomExitHotspotJoinRecord rec, *p; lure_exe.seek(DATA_SEGMENT + ROOM_EXIT_JOINS_OFFSET); int numRecords = 0; uint32 unused; lure_exe.seek(DATA_SEGMENT + ROOM_EXIT_JOINS_OFFSET); do { lure_exe.read(&rec, sizeof(RoomExitHotspotJoinRecord)); lure_exe.read(&unused, sizeof(uint32)); ++numRecords; } while (FROM_LE_16(rec.hotspot1Id) != 0); --numRecords; // Allocate the data and read in all the records totalSize = (numRecords * sizeof(RoomExitHotspotJoinRecord)) + 2; data = (byte *) malloc(totalSize); lure_exe.seek(DATA_SEGMENT + ROOM_EXIT_JOINS_OFFSET); p = (RoomExitHotspotJoinRecord *) data; for (int recordCtr = 0; recordCtr < numRecords; ++recordCtr) { lure_exe.read(p, sizeof(RoomExitHotspotJoinRecord)); lure_exe.read(&unused, sizeof(uint32)); ++p; } WRITE_LE_UINT16(p, 0xffff); } // This next method reads in the animation and movement data. At the moment I // figure out which animations have valid movement record sets by finding // animations whose four direction offsets are near each other. There's // probably a better method than this, but it'll do for now void read_anim_data(byte *&data, uint16 &totalSize) { // Add special pixel records add_anim_record(0x5c95); // Get the animation data records AnimRecord inRec; MovementRecord move; MovementRecord *destMove; uint16 offset, moveOffset; uint16 startOffset; int ctr, dirCtr; int movementSize = 0; bool *includeAnim = (bool *) malloc(animIndex); // Loop to figure out the total number of movement records there are for (ctr = 0; ctr < animIndex; ++ctr) { lure_exe.seek(DATA_SEGMENT + animOffsets[ctr]); lure_exe.read(&inRec, sizeof(AnimRecord)); if ((FROM_LE_16(inRec.leftOffset) < 0x5000) || (FROM_LE_16(inRec.rightOffset) < 0x5000) || (abs(FROM_LE_16(inRec.leftOffset)-FROM_LE_16(inRec.rightOffset)) > 0x800) || (abs(FROM_LE_16(inRec.rightOffset)-FROM_LE_16(inRec.upOffset)) > 0x800) || (abs(FROM_LE_16(inRec.upOffset)-FROM_LE_16(inRec.downOffset)) > 0x800)) { // Animation doesn't have valid movement data includeAnim[ctr] = false; } else { includeAnim[ctr] = true; for (dirCtr=0; dirCtr<4; ++dirCtr) { switch (dirCtr) { case 0: offset = FROM_LE_16(inRec.leftOffset); break; case 1: offset = FROM_LE_16(inRec.rightOffset); break; case 2: offset = FROM_LE_16(inRec.upOffset); break; default: offset = FROM_LE_16(inRec.downOffset); } if (offset != 0) { lure_exe.seek(DATA_SEGMENT + offset); lure_exe.read(&move, sizeof(MovementRecord)); while (FROM_LE_16(move.frameNumber) != 0xffff) { movementSize += sizeof(MovementRecord); lure_exe.read(&move, sizeof(MovementRecord)); } movementSize += 2; } } } } totalSize = animIndex * sizeof(AnimRecordOutput) + 2 + movementSize; AnimRecordOutput *rec = (AnimRecordOutput *) malloc(totalSize); data = (byte *) rec; moveOffset = animIndex * sizeof(AnimRecordOutput) + 2; // Loop to get in the animation records for (ctr = 0; ctr < animIndex; ++ctr, ++rec) { lure_exe.seek(DATA_SEGMENT + animOffsets[ctr]); lure_exe.read(&inRec, sizeof(AnimRecord)); rec->animRecordId = animOffsets[ctr]; rec->animId = inRec.animId; rec->flags = TO_LE_16(inRec.flags); rec->leftOffset = 0; rec->rightOffset = 0; rec->upOffset = 0; rec->downOffset = 0; rec->upFrame = inRec.upFrame; rec->downFrame = inRec.downFrame; rec->leftFrame = inRec.leftFrame; rec->rightFrame = inRec.rightFrame; if (includeAnim[ctr]) { // Loop to get movement records uint16 *inDirs[4] = {&inRec.leftOffset, &inRec.rightOffset, &inRec.upOffset, &inRec.downOffset}; uint16 *outDirs[4] = {&rec->leftOffset, &rec->rightOffset, &rec->upOffset, &rec->downOffset}; for (dirCtr=0; dirCtr<4; ++dirCtr) { offset = READ_LE_UINT16(inDirs[dirCtr]); if (offset == 0) { startOffset = 0; } else { startOffset = moveOffset; lure_exe.seek(DATA_SEGMENT + offset); lure_exe.read(&move, sizeof(MovementRecord)); destMove = (MovementRecord *) (data + moveOffset); while (FROM_LE_16(move.frameNumber) != 0xffff) { destMove->frameNumber = move.frameNumber; destMove->xChange = move.xChange; destMove->yChange = move.yChange; moveOffset += sizeof(MovementRecord); ++destMove; lure_exe.read(&move, sizeof(MovementRecord)); } destMove->frameNumber = TO_LE_16(0xffff); moveOffset += 2; } WRITE_LE_UINT16(outDirs[dirCtr], startOffset); } } } rec->animRecordId = TO_LE_16(0xffff); delete includeAnim; } void read_script_data(byte *&data, uint16 &totalSize) { lure_exe.seek(SCRIPT_SEGMENT); totalSize = SCRIPT_SEGMENT_SIZE; data = (byte *) malloc(totalSize); lure_exe.read(data, totalSize); } void read_script2_data(byte *&data, uint16 &totalSize) { lure_exe.seek(SCRIPT2_SEGMENT); totalSize = SCRIPT2_SEGMENT_SIZE; data = (byte *) malloc(totalSize); lure_exe.read(data, totalSize); } void read_hotspot_script_offsets(byte *&data, uint16 &totalSize) { lure_exe.seek(DATA_SEGMENT + HOTSPOT_SCRIPT_LIST); totalSize = HOTSPOT_SCRIPT_SIZE; data = (byte *) malloc(totalSize); lure_exe.read(data, totalSize); } void read_messages_segment(byte *&data, uint16 &totalSize) { lure_exe.seek(MESSAGES_SEGMENT); totalSize = MESSAGES_SEGMENT_SIZE; data = (byte *) malloc(totalSize); lure_exe.read(data, totalSize); } // Reads in the list of actions used void read_actions_list(byte *&data, uint16 &totalSize) { // Allocate enough space for output action list data = (byte *) malloc(MAX_DATA_SIZE); HotspotActionsRecord *header = (HotspotActionsRecord *) data; uint16 offset = actionIndex * sizeof(HotspotActionsRecord) + sizeof(uint16); for (int ctr = 0; ctr < actionIndex; ++ctr) { header->recordId = actionOffsets[ctr]; header->offset = offset; ++header; lure_exe.seek(DATA_SEGMENT + actionOffsets[ctr]); uint16 *numItems = (uint16 *) (data + offset); lure_exe.read(numItems, sizeof(uint16)); offset += 2; if (READ_UINT16(numItems) > 0) { lure_exe.read(data + offset, READ_UINT16(numItems) * 3); offset += READ_UINT16(numItems) * 3; } } header->recordId = TO_LE_16(0xffff); } // Reads in the talk data #define TALK_OFFSET 0x505c #define TALK_NUM_ENTRIES 28 #define MAX_TALK_LISTS 300 uint16 talkOffsets[MAX_TALK_LISTS]; int talkOffsetIndex = 0; void add_talk_offset(uint16 offset) { for (int ctr = 0; ctr < talkOffsetIndex; ++ctr) if (talkOffsets[ctr] == offset) return; if (talkOffsetIndex == MAX_TALK_LISTS) { printf("Exceeded maximum talk offset list size\n"); exit(1); } talkOffsets[talkOffsetIndex++] = offset; } struct TalkEntry { uint16 hotspotId; uint16 offset; }; void read_talk_headers(byte *&data, uint16 &totalSize) { TalkEntry entries[TALK_NUM_ENTRIES]; uint16 sortedOffsets[TALK_NUM_ENTRIES+1]; int entryCtr, subentryCtr; lure_exe.seek(DATA_SEGMENT + TALK_OFFSET); lure_exe.read(&entries[0], sizeof(TalkEntry) * TALK_NUM_ENTRIES); // Sort the entry offsets into a list - this is used to figure out each entry's size int currVal, prevVal = 0; for (entryCtr = 0; entryCtr < TALK_NUM_ENTRIES; ++entryCtr) { currVal = 0xffff; for (subentryCtr = 0; subentryCtr < TALK_NUM_ENTRIES; ++subentryCtr) { if ((FROM_LE_16(entries[subentryCtr].offset) < currVal) && (FROM_LE_16(entries[subentryCtr].offset) > prevVal)) currVal = FROM_LE_16(entries[subentryCtr].offset); } if (currVal == 0xffff) break; sortedOffsets[entryCtr] = currVal; prevVal = currVal; } sortedOffsets[entryCtr] = 0x5540; // end for end record data = (byte *) malloc(MAX_DATA_SIZE); TalkEntry *entry = (TalkEntry *) data; uint16 offset = TALK_NUM_ENTRIES * sizeof(TalkEntry) + sizeof(uint16); for (int entryCtr = 0; entryCtr < TALK_NUM_ENTRIES; ++entryCtr) { entry->hotspotId = entries[entryCtr].hotspotId; entry->offset = TO_LE_16(offset); ++entry; // Find the following offset in a sorted list int startOffset = FROM_LE_16(entries[entryCtr].offset); int nextOffset = 0; for (subentryCtr = 0; subentryCtr < TALK_NUM_ENTRIES; ++subentryCtr) { if (sortedOffsets[subentryCtr] == startOffset) { nextOffset = sortedOffsets[subentryCtr+1]; break; } } if (nextOffset == 0) exit(1); // Read in line entries into the data lure_exe.seek(DATA_SEGMENT + startOffset); int size = nextOffset - startOffset; uint16 *talkOffset = (uint16 *) (data + offset); lure_exe.read(talkOffset, size); while (size > 0) { if (READ_UINT16(talkOffset) != 0) add_talk_offset(READ_UINT16(talkOffset)); size -= sizeof(uint16); offset += sizeof(uint16); talkOffset++; } WRITE_LE_UINT16(talkOffset, 0xffff); offset += 2; } add_talk_offset(0xffff); entry->hotspotId = TO_LE_16(0xffff); totalSize = offset + 2; } // Reads in the contents of the previously loaded talk lists struct TalkRecord { uint16 recordId; uint16 listOffset; uint16 responsesOffset; }; uint16 giveTalkIds[6] = {0xCF5E, 0xCF14, 0xCF90, 0xCFAA, 0xCFD0, 0xCFF6}; void read_talk_data(byte *&data, uint16 &totalSize) { uint16 responseOffset; int talkCtr, subentryCtr; uint16 size; for (talkCtr = 0; talkCtr < 6; ++talkCtr) add_talk_offset(giveTalkIds[talkCtr]); data = (byte *) malloc(MAX_DATA_SIZE); TalkRecord *header = (TalkRecord *) data; uint16 offset = talkOffsetIndex * sizeof(TalkRecord) + sizeof(uint16); uint16 *sortedList = (uint16 *) malloc((talkOffsetIndex+1) * sizeof(uint16)); memset(sortedList, 0, (talkOffsetIndex+1) * sizeof(uint16)); // Sort the entry offsets into a list - this is used to figure out each entry's size int currVal, prevVal = 0; for (talkCtr = 0; talkCtr < talkOffsetIndex; ++talkCtr) { currVal = 0xffff; for (subentryCtr = 0; subentryCtr < talkOffsetIndex; ++subentryCtr) { if ((talkOffsets[subentryCtr] < currVal) && (talkOffsets[subentryCtr] > prevVal)) currVal = talkOffsets[subentryCtr]; } if (currVal == 0xffff) break; sortedList[talkCtr] = currVal; prevVal = currVal; } sortedList[talkCtr] = 0xf010; int numTalks = talkCtr; // Loop through the talk list for (talkCtr = 0; talkCtr < numTalks; ++talkCtr) { uint16 startOffset = sortedList[talkCtr]; uint16 nextOffset = sortedList[talkCtr+1]; header->recordId = startOffset; header->listOffset = offset; lure_exe.seek(DATA_SEGMENT + startOffset); responseOffset = lure_exe.readWord(); startOffset += 2; // Special handling for entry at 0d930h if (responseOffset == 0x8000) continue; // Calculate talk data size - if response is within record range, // use simple calculation size. Otherwise, read in full data until // end of record if ((responseOffset < startOffset) || (responseOffset >= nextOffset)) size = nextOffset - startOffset; else size = responseOffset - startOffset; if ((size % 6) == 2) size -= 2; if ((size % 6) != 0) { printf("Failure reading talk data\n"); exit(1); } // Read in the list of talk entries lure_exe.read(data + offset, size); offset += size; memset(data + offset, 0xff, 2); offset += 2; // Handle the response data header->responsesOffset = offset; // Scan through the list of record offsets and find the offset of // the following record. This is done because although the talk // records and responses are normally sequential, it can also // point into another record's talk responses nextOffset = 0; for (subentryCtr = 0; subentryCtr < numTalks; ++subentryCtr) { if ((responseOffset >= sortedList[subentryCtr]) && (responseOffset < sortedList[subentryCtr+1])) { // Found a record nextOffset = sortedList[subentryCtr+1]; break; } } if (nextOffset < responseOffset) { printf("Failure reading talk data\n"); exit(1); } size = nextOffset - responseOffset; if ((size % 6) != 0) size -= (size % 6); if ((size % 6) != 0) { printf("Failure reading talk data\n"); exit(1); } lure_exe.read(data + offset, size); offset += size; WRITE_LE_UINT16(data + offset, 0xffff); offset += 2; ++header; } header->recordId = TO_LE_16(0xffff); totalSize = offset; free(sortedList); } void read_room_pathfinding_data(byte *&data, uint16 &totalSize) { lure_exe.seek(DATA_SEGMENT + PATHFIND_OFFSET); totalSize = PATHFIND_SIZE; data = (byte *) malloc(totalSize); lure_exe.read(data, totalSize); } void read_room_exit_coordinate_data(byte *&data, uint16 &totalSize) { // Read in the exit coordinates list int roomNum, entryNum; totalSize = EXIT_COORDINATES_NUM_ROOMS * sizeof(RoomExitCoordinateEntryResource) + 2; data = (byte *) malloc(totalSize); lure_exe.seek(DATA_SEGMENT + EXIT_COORDINATES_OFFSET); lure_exe.read(data, totalSize - 2); WRITE_LE_UINT16(data + totalSize - 2, 0xffff); // Post process the list to adjust data RoomExitCoordinateEntryResource *rec = (RoomExitCoordinateEntryResource *) data; for (roomNum = 0; roomNum < EXIT_COORDINATES_NUM_ROOMS; ++roomNum, ++rec) { for (entryNum = 0; entryNum < ROOM_EXIT_COORDINATES_NUM_ENTRIES; ++entryNum) { if ((rec->entries[entryNum].x != 0) || (rec->entries[entryNum].y != 0)) { rec->entries[entryNum].x = TO_LE_16(FROM_LE_16(rec->entries[entryNum].x) - 0x80); uint16 tempY = FROM_LE_16(rec->entries[entryNum].y); rec->entries[entryNum].y = TO_LE_16( ((tempY & 0xfff) - 0x80) | (tempY & 0xf000)); } } for (entryNum = 0; entryNum < ROOM_EXIT_COORDINATES_ENTRY_NUM_ROOMS; ++entryNum) { rec->roomIndex[entryNum] = TO_LE_16(FROM_LE_16(rec->roomIndex[entryNum]) / 6); } } } void read_room_exit_hotspots_data(byte *&data, uint16 &totalSize) { totalSize = 0; data = (byte *) malloc(MAX_DATA_SIZE); RoomExitIndexedHotspotResource *rec = (RoomExitIndexedHotspotResource *) data; lure_exe.seek(DATA_SEGMENT + EXIT_HOTSPOTS_OFFSET); lure_exe.read(rec, sizeof(RoomExitIndexedHotspotResource)); while (FROM_LE_16(rec->roomNumber) != 0) { ++rec; totalSize += sizeof(RoomExitIndexedHotspotResource); lure_exe.read(rec, sizeof(RoomExitIndexedHotspotResource)); } WRITE_LE_UINT16(rec, 0xffff); totalSize += sizeof(uint16); } void read_ratpouch_schedules(byte *&data, uint16 &totalSize) { // TODO: Parse out the schedules Ratpouch has for each room data = (byte *) malloc(1); totalSize = 1; } #define NUM_TEXT_ENTRIES 40 const char *text_strings[NUM_TEXT_ENTRIES] = { "Get", NULL, "Push", "Pull", "Operate", "Open", "Close", "Lock", "Unlock", "Use", "Give", "Talk to", "Tell", "Buy", "Look", "Look at", "Look through", "Ask", NULL, "Drink", "Status", "Go to", "Return", "Bribe", "Examine", "Credits", "Restart game", "Save game", "Restore game", "Quit", "Fast Text", "Slow Text", "Sound on", "Sound off", "(nothing)", " for ", " to ", " on ", "and then", "finish"}; void save_text_strings(byte *&data, uint16 &totalSize) { int index; // Calculate the total needed space totalSize = sizeof(uint16); for (index = 0; index < NUM_TEXT_ENTRIES; ++index) { if (text_strings[index] != NULL) totalSize += strlen(text_strings[index]); ++totalSize; } // Duplicate the text strings list into a data buffer data = (byte *) malloc(totalSize); *((uint16 *) data) = TO_LE_16(NUM_TEXT_ENTRIES); char *p = (char *) data + sizeof(uint16); for (index = 0; index < NUM_TEXT_ENTRIES; ++index) { if (text_strings[index] == NULL) *p++ = '\0'; else { strcpy(p, text_strings[index]); p += strlen(p) + 1; } } } void getEntry(uint8 entryIndex, uint16 &resourceId, byte *&data, uint16 &size) { resourceId = 0x3f01 + entryIndex; switch (entryIndex) { case 0: // Copy the default palette to file read_basic_palette(data, size); break; case 1: // Copy the replacement palette fragments to file read_replacement_palette(data, size); break; case 2: // Copy the dialog segment data into the new vga file read_dialog_data(data, size); break; case 3: // Copy the talk dialog segment data into the new vga file read_talk_dialog_data(data, size); break; case 4: // Get the room info data read_room_data(data, size); break; case 5: // Get the action sequence set for NPC characters read_action_sequence(data, size); break; case 6: // Get the hotspot info data read_hotspot_data(data, size); break; case 7: // Get the hotspot override info data read_hotspot_override_data(data, size); break; case 8: // Get the list of room exits read_room_exits(data, size); break; case 9: // Get the list of room exit joins read_room_exit_joins(data, size); break; case 10: // Get the hotspot animation record data read_anim_data(data, size); break; case 11: // Get the script segment data read_script_data(data, size); break; case 12: // Get the second script segment data read_script2_data(data, size); break; case 13: // Get a list of hotspot script offsets read_hotspot_script_offsets(data, size); break; case 14: // Get the messages segment read_messages_segment(data, size); break; case 15: // Get the actions list read_actions_list(data, size); break; case 16: // Get the talk header information read_talk_headers(data, size); break; case 17: // Get the talk data read_talk_data(data, size); break; case 18: // Get the pathfinding data read_room_pathfinding_data(data, size); break; case 19: // Get the room exit coordinate list read_room_exit_coordinate_data(data, size); break; case 20: // Read the room exit hotspot list read_room_exit_hotspots_data(data, size); break; case 21: // Read in Ratpouch's room specific schedules read_ratpouch_schedules(data, size); break; case 22: // Set up the list of text strings used by the game save_text_strings(data, size); break; default: data = NULL; size = 0; resourceId = 0xffff; break; } } void createFile(const char *outFilename) { FileEntry rec; uint32 startOffset, numBytes; uint16 resourceId; uint16 resourceSize; byte *resourceData; bool resourceFlag; byte tempBuffer[32]; File f; f.open(outFilename, kFileWriteMode); memset(tempBuffer, 0, 32); // Write header f.write("heywow", 6); f.writeWord(0); startOffset = 0x600; resourceFlag = true; for (int resIndex=0; resIndex<0xBE; ++resIndex) { resourceData = NULL; // Get next data entry if (resourceFlag) // Get resource details getEntry(resIndex, resourceId, resourceData, resourceSize); // Write out the next header entry f.seek(8 + resIndex * 8); if (resourceSize == 0) { // Unused entry memset(&rec, 0xff, sizeof(FileEntry)); resourceFlag = false; } else { rec.id = TO_LE_16(resourceId); rec.offset = TO_LE_16(startOffset >> 5); rec.sizeExtension = (uint8) ((resourceSize >> 16) & 0xff); rec.size = TO_LE_16(resourceSize & 0xffff); rec.unused = 0xff; } f.write(&rec, sizeof(FileEntry)); // Write out the resource if (resourceFlag) { f.seek(startOffset); f.write(resourceData, resourceSize); startOffset += resourceSize; free(resourceData); // Free the data block // Write out enough bytes to move to the next 32 byte boundary numBytes = 0x20 * ((startOffset + 0x1f) / 0x20) - startOffset; if (numBytes != 0) { f.write(tempBuffer, numBytes); startOffset += numBytes; } } } // Store file version in final file slot f.seek(0xBF * 8); FileEntry fileVersion; memset(&fileVersion, 0xff, sizeof(FileEntry)); fileVersion.unused = VERSION_MAJOR; fileVersion.sizeExtension = VERSION_MINOR; f.write(&fileVersion, sizeof(FileEntry)); f.close(); } // validate_executable // Validates that the correct executable is being used to generate the // resource file. Eventually the resource file creator will need to work // with the other language executables, but for now just make #define NUM_BYTES_VALIDATE 1024 #define FILE_CHECKSUM 64880 void validate_executable() { uint32 sumTotal = 0; byte buffer[NUM_BYTES_VALIDATE]; lure_exe.read(buffer, NUM_BYTES_VALIDATE); for (int ctr = 0; ctr < NUM_BYTES_VALIDATE; ++ctr) sumTotal += buffer[ctr]; if (sumTotal != FILE_CHECKSUM) { printf("Lure executable not correct English version\n"); exit(1); } } int main(int argc, char *argv[]) { const char *inFilename = (argc >= 2) ? argv[1] : "c:\\games\\lure\\lure.exe"; const char *outFilename = (argc == 3) ? argv[2] : "c:\\games\\lure\\lure.dat"; if (!lure_exe.open(inFilename)) { if (argc == 1) printf("Format: %s input_exe_filename output_filename\n"); else printf("Could not open file: %s\n", inFilename); } else { validate_executable(); createFile(outFilename); lure_exe.close(); } }