/* (c) Magnus Auvinen. See licence.txt in the root of the distribution for more information. */ /* If you are missing that file, acquire a complete release at teeworlds.com. */ #include "datafile.h" #include #include #include #include #include "uuid_manager.h" static const int DEBUG = 0; enum { OFFSET_UUID_TYPE = 0x8000, ITEMTYPE_EX = 0xffff, }; struct CItemEx { int m_aUuid[sizeof(CUuid) / 4]; static CItemEx FromUuid(CUuid Uuid) { CItemEx Result; for(int i = 0; i < (int)sizeof(CUuid) / 4; i++) { Result.m_aUuid[i] = (Uuid.m_aData[i * 4 + 0] << 24) | (Uuid.m_aData[i * 4 + 1] << 16) | (Uuid.m_aData[i * 4 + 2] << 8) | (Uuid.m_aData[i * 4 + 3]); } return Result; } CUuid ToUuid() const { CUuid Result; for(int i = 0; i < (int)sizeof(CUuid) / 4; i++) { Result.m_aData[i * 4 + 0] = m_aUuid[i] >> 24; Result.m_aData[i * 4 + 1] = m_aUuid[i] >> 16; Result.m_aData[i * 4 + 2] = m_aUuid[i] >> 8; Result.m_aData[i * 4 + 3] = m_aUuid[i]; } return Result; } }; static int GetTypeFromIndex(int Index) { return ITEMTYPE_EX - Index - 1; } struct CDatafileItemType { int m_Type; int m_Start; int m_Num; }; struct CDatafileItem { int m_TypeAndID; int m_Size; }; struct CDatafileHeader { char m_aID[4]; int m_Version; int m_Size; int m_Swaplen; int m_NumItemTypes; int m_NumItems; int m_NumRawData; int m_ItemSize; int m_DataSize; }; struct CDatafileData { int m_NumItemTypes; int m_NumItems; int m_NumRawData; int m_ItemSize; int m_DataSize; char m_aStart[4]; }; struct CDatafileInfo { CDatafileItemType *m_pItemTypes; int *m_pItemOffsets; int *m_pDataOffsets; int *m_pDataSizes; char *m_pItemStart; char *m_pDataStart; }; struct CDatafile { IOHANDLE m_File; SHA256_DIGEST m_Sha256; unsigned m_Crc; CDatafileInfo m_Info; CDatafileHeader m_Header; int m_DataStartOffset; char **m_ppDataPtrs; char *m_pData; }; bool CDataFileReader::Open(class IStorage *pStorage, const char *pFilename, int StorageType) { dbg_msg("datafile", "loading. filename='%s'", pFilename); IOHANDLE File = pStorage->OpenFile(pFilename, IOFLAG_READ, StorageType); if(!File) { dbg_msg("datafile", "could not open '%s'", pFilename); return false; } // take the CRC of the file and store it unsigned Crc = 0; SHA256_DIGEST Sha256; { enum { BUFFER_SIZE = 64 * 1024 }; SHA256_CTX Sha256Ctxt; sha256_init(&Sha256Ctxt); unsigned char aBuffer[BUFFER_SIZE]; while(1) { unsigned Bytes = io_read(File, aBuffer, BUFFER_SIZE); if(Bytes <= 0) break; Crc = crc32(Crc, aBuffer, Bytes); // ignore_convention sha256_update(&Sha256Ctxt, aBuffer, Bytes); } Sha256 = sha256_finish(&Sha256Ctxt); io_seek(File, 0, IOSEEK_START); } // TODO: change this header CDatafileHeader Header; if(sizeof(Header) != io_read(File, &Header, sizeof(Header))) { dbg_msg("datafile", "couldn't load header"); return 0; } if(Header.m_aID[0] != 'A' || Header.m_aID[1] != 'T' || Header.m_aID[2] != 'A' || Header.m_aID[3] != 'D') { if(Header.m_aID[0] != 'D' || Header.m_aID[1] != 'A' || Header.m_aID[2] != 'T' || Header.m_aID[3] != 'A') { dbg_msg("datafile", "wrong signature. %x %x %x %x", Header.m_aID[0], Header.m_aID[1], Header.m_aID[2], Header.m_aID[3]); return 0; } } #if defined(CONF_ARCH_ENDIAN_BIG) swap_endian(&Header, sizeof(int), sizeof(Header) / sizeof(int)); #endif if(Header.m_Version != 3 && Header.m_Version != 4) { dbg_msg("datafile", "wrong version. version=%x", Header.m_Version); return 0; } // read in the rest except the data unsigned Size = 0; Size += Header.m_NumItemTypes * sizeof(CDatafileItemType); Size += (Header.m_NumItems + Header.m_NumRawData) * sizeof(int); if(Header.m_Version == 4) Size += Header.m_NumRawData * sizeof(int); // v4 has uncompressed data sizes as well Size += Header.m_ItemSize; unsigned AllocSize = Size; AllocSize += sizeof(CDatafile); // add space for info structure AllocSize += Header.m_NumRawData * sizeof(void *); // add space for data pointers CDatafile *pTmpDataFile = (CDatafile *)malloc(AllocSize); pTmpDataFile->m_Header = Header; pTmpDataFile->m_DataStartOffset = sizeof(CDatafileHeader) + Size; pTmpDataFile->m_ppDataPtrs = (char **)(pTmpDataFile + 1); pTmpDataFile->m_pData = (char *)(pTmpDataFile + 1) + Header.m_NumRawData * sizeof(char *); pTmpDataFile->m_File = File; pTmpDataFile->m_Sha256 = Sha256; pTmpDataFile->m_Crc = Crc; // clear the data pointers mem_zero(pTmpDataFile->m_ppDataPtrs, Header.m_NumRawData * sizeof(void *)); // read types, offsets, sizes and item data unsigned ReadSize = io_read(File, pTmpDataFile->m_pData, Size); if(ReadSize != Size) { io_close(pTmpDataFile->m_File); free(pTmpDataFile); pTmpDataFile = 0; dbg_msg("datafile", "couldn't load the whole thing, wanted=%d got=%d", Size, ReadSize); return false; } Close(); m_pDataFile = pTmpDataFile; #if defined(CONF_ARCH_ENDIAN_BIG) swap_endian(m_pDataFile->m_pData, sizeof(int), minimum(static_cast(Header.m_Swaplen), Size) / sizeof(int)); #endif //if(DEBUG) { dbg_msg("datafile", "allocsize=%d", AllocSize); dbg_msg("datafile", "readsize=%d", ReadSize); dbg_msg("datafile", "swaplen=%d", Header.m_Swaplen); dbg_msg("datafile", "item_size=%d", m_pDataFile->m_Header.m_ItemSize); } m_pDataFile->m_Info.m_pItemTypes = (CDatafileItemType *)m_pDataFile->m_pData; m_pDataFile->m_Info.m_pItemOffsets = (int *)&m_pDataFile->m_Info.m_pItemTypes[m_pDataFile->m_Header.m_NumItemTypes]; m_pDataFile->m_Info.m_pDataOffsets = &m_pDataFile->m_Info.m_pItemOffsets[m_pDataFile->m_Header.m_NumItems]; m_pDataFile->m_Info.m_pDataSizes = &m_pDataFile->m_Info.m_pDataOffsets[m_pDataFile->m_Header.m_NumRawData]; if(Header.m_Version == 4) m_pDataFile->m_Info.m_pItemStart = (char *)&m_pDataFile->m_Info.m_pDataSizes[m_pDataFile->m_Header.m_NumRawData]; else m_pDataFile->m_Info.m_pItemStart = (char *)&m_pDataFile->m_Info.m_pDataOffsets[m_pDataFile->m_Header.m_NumRawData]; m_pDataFile->m_Info.m_pDataStart = m_pDataFile->m_Info.m_pItemStart + m_pDataFile->m_Header.m_ItemSize; dbg_msg("datafile", "loading done. datafile='%s'", pFilename); if(DEBUG) { /* for(int i = 0; i < m_pDataFile->data.num_raw_data; i++) { void *p = datafile_get_data(df, i); dbg_msg("datafile", "%d %d", (int)((char*)p - (char*)(&m_pDataFile->data)), size); } for(int i = 0; i < datafile_num_items(df); i++) { int type, id; void *data = datafile_get_item(df, i, &type, &id); dbg_msg("map", "\t%d: type=%x id=%x p=%p offset=%d", i, type, id, data, m_pDataFile->info.item_offsets[i]); int *idata = (int*)data; for(int k = 0; k < 3; k++) dbg_msg("datafile", "\t\t%d=%d (%x)", k, idata[k], idata[k]); } for(int i = 0; i < m_pDataFile->data.num_m_aItemTypes; i++) { dbg_msg("map", "\t%d: type=%x start=%d num=%d", i, m_pDataFile->info.m_aItemTypes[i].type, m_pDataFile->info.m_aItemTypes[i].start, m_pDataFile->info.m_aItemTypes[i].num); for(int k = 0; k < m_pDataFile->info.m_aItemTypes[i].num; k++) { int type, id; datafile_get_item(df, m_pDataFile->info.m_aItemTypes[i].start+k, &type, &id); if(type != m_pDataFile->info.m_aItemTypes[i].type) dbg_msg("map", "\tERROR"); } } */ } return true; } int CDataFileReader::NumData() const { if(!m_pDataFile) { return 0; } return m_pDataFile->m_Header.m_NumRawData; } // returns the size in the file int CDataFileReader::GetFileDataSize(int Index) { if(!m_pDataFile) { return 0; } if(Index == m_pDataFile->m_Header.m_NumRawData - 1) return m_pDataFile->m_Header.m_DataSize - m_pDataFile->m_Info.m_pDataOffsets[Index]; return m_pDataFile->m_Info.m_pDataOffsets[Index + 1] - m_pDataFile->m_Info.m_pDataOffsets[Index]; } // returns the size of the resulting data int CDataFileReader::GetDataSize(int Index) { if(!m_pDataFile) { return 0; } if(m_pDataFile->m_Header.m_Version == 4) return m_pDataFile->m_Info.m_pDataSizes[Index]; else return GetFileDataSize(Index); } void *CDataFileReader::GetDataImpl(int Index, int Swap) { if(!m_pDataFile) { return 0; } if(Index < 0 || Index >= m_pDataFile->m_Header.m_NumRawData) return 0; // load it if needed if(!m_pDataFile->m_ppDataPtrs[Index]) { // fetch the data size int DataSize = GetFileDataSize(Index); #if defined(CONF_ARCH_ENDIAN_BIG) int SwapSize = DataSize; #endif if(m_pDataFile->m_Header.m_Version == 4) { // v4 has compressed data void *pTemp = malloc(DataSize); unsigned long UncompressedSize = m_pDataFile->m_Info.m_pDataSizes[Index]; unsigned long s; dbg_msg("datafile", "loading data index=%d size=%d uncompressed=%lu", Index, DataSize, UncompressedSize); m_pDataFile->m_ppDataPtrs[Index] = (char *)malloc(UncompressedSize); // read the compressed data io_seek(m_pDataFile->m_File, m_pDataFile->m_DataStartOffset + m_pDataFile->m_Info.m_pDataOffsets[Index], IOSEEK_START); io_read(m_pDataFile->m_File, pTemp, DataSize); // decompress the data, TODO: check for errors s = UncompressedSize; uncompress((Bytef *)m_pDataFile->m_ppDataPtrs[Index], &s, (Bytef *)pTemp, DataSize); // ignore_convention #if defined(CONF_ARCH_ENDIAN_BIG) SwapSize = s; #endif // clean up the temporary buffers free(pTemp); } else { // load the data dbg_msg("datafile", "loading data index=%d size=%d", Index, DataSize); m_pDataFile->m_ppDataPtrs[Index] = (char *)malloc(DataSize); io_seek(m_pDataFile->m_File, m_pDataFile->m_DataStartOffset + m_pDataFile->m_Info.m_pDataOffsets[Index], IOSEEK_START); io_read(m_pDataFile->m_File, m_pDataFile->m_ppDataPtrs[Index], DataSize); } #if defined(CONF_ARCH_ENDIAN_BIG) if(Swap && SwapSize) swap_endian(m_pDataFile->m_ppDataPtrs[Index], sizeof(int), SwapSize / sizeof(int)); #endif } return m_pDataFile->m_ppDataPtrs[Index]; } void *CDataFileReader::GetData(int Index) { return GetDataImpl(Index, 0); } void *CDataFileReader::GetDataSwapped(int Index) { return GetDataImpl(Index, 1); } void CDataFileReader::UnloadData(int Index) { if(Index < 0 || Index >= m_pDataFile->m_Header.m_NumRawData) return; // free(m_pDataFile->m_ppDataPtrs[Index]); m_pDataFile->m_ppDataPtrs[Index] = 0x0; } int CDataFileReader::GetItemSize(int Index) const { if(!m_pDataFile) return 0; if(Index == m_pDataFile->m_Header.m_NumItems - 1) return m_pDataFile->m_Header.m_ItemSize - m_pDataFile->m_Info.m_pItemOffsets[Index] - sizeof(CDatafileItem); return m_pDataFile->m_Info.m_pItemOffsets[Index + 1] - m_pDataFile->m_Info.m_pItemOffsets[Index] - sizeof(CDatafileItem); } int CDataFileReader::GetExternalItemType(int InternalType) { if(InternalType <= OFFSET_UUID_TYPE || InternalType == ITEMTYPE_EX) { return InternalType; } int TypeIndex = FindItemIndex(ITEMTYPE_EX, InternalType); if(TypeIndex < 0 || GetItemSize(TypeIndex) < (int)sizeof(CItemEx)) { return InternalType; } const CItemEx *pItemEx = (const CItemEx *)GetItem(TypeIndex, 0, 0); // Propagate UUID_UNKNOWN, it doesn't hurt. return g_UuidManager.LookupUuid(pItemEx->ToUuid()); } int CDataFileReader::GetInternalItemType(int ExternalType) { if(ExternalType < OFFSET_UUID) { return ExternalType; } CUuid Uuid = g_UuidManager.GetUuid(ExternalType); int Start, Num; GetType(ITEMTYPE_EX, &Start, &Num); for(int i = Start; i < Start + Num; i++) { if(GetItemSize(i) < (int)sizeof(CItemEx)) { continue; } int ID; if(Uuid == ((const CItemEx *)GetItem(i, 0, &ID))->ToUuid()) { return ID; } } return -1; } void *CDataFileReader::GetItem(int Index, int *pType, int *pID) { if(!m_pDataFile) { if(pType) *pType = 0; if(pID) *pID = 0; return 0; } CDatafileItem *i = (CDatafileItem *)(m_pDataFile->m_Info.m_pItemStart + m_pDataFile->m_Info.m_pItemOffsets[Index]); if(pType) { // remove sign extension *pType = GetExternalItemType((i->m_TypeAndID >> 16) & 0xffff); } if(pID) { *pID = i->m_TypeAndID & 0xffff; } return (void *)(i + 1); } void CDataFileReader::GetType(int Type, int *pStart, int *pNum) { *pStart = 0; *pNum = 0; if(!m_pDataFile) return; Type = GetInternalItemType(Type); for(int i = 0; i < m_pDataFile->m_Header.m_NumItemTypes; i++) { if(m_pDataFile->m_Info.m_pItemTypes[i].m_Type == Type) { *pStart = m_pDataFile->m_Info.m_pItemTypes[i].m_Start; *pNum = m_pDataFile->m_Info.m_pItemTypes[i].m_Num; return; } } } int CDataFileReader::FindItemIndex(int Type, int ID) { if(!m_pDataFile) { return -1; } int Start, Num; GetType(Type, &Start, &Num); for(int i = 0; i < Num; i++) { int ItemID; GetItem(Start + i, 0, &ItemID); if(ID == ItemID) { return Start + i; } } return -1; } void *CDataFileReader::FindItem(int Type, int ID) { int Index = FindItemIndex(Type, ID); if(Index < 0) { return 0; } return GetItem(Index, 0, 0); } int CDataFileReader::NumItems() const { if(!m_pDataFile) return 0; return m_pDataFile->m_Header.m_NumItems; } bool CDataFileReader::Close() { if(!m_pDataFile) return true; // free the data that is loaded int i; for(i = 0; i < m_pDataFile->m_Header.m_NumRawData; i++) free(m_pDataFile->m_ppDataPtrs[i]); io_close(m_pDataFile->m_File); free(m_pDataFile); m_pDataFile = 0; return true; } SHA256_DIGEST CDataFileReader::Sha256() const { if(!m_pDataFile) { SHA256_DIGEST Result; for(unsigned char &d : Result.data) { d = 0xff; } return Result; } return m_pDataFile->m_Sha256; } unsigned CDataFileReader::Crc() const { if(!m_pDataFile) return 0xFFFFFFFF; return m_pDataFile->m_Crc; } int CDataFileReader::MapSize() const { if(!m_pDataFile) return 0; return m_pDataFile->m_Header.m_Size + 16; } IOHANDLE CDataFileReader::File() { if(!m_pDataFile) return 0; return m_pDataFile->m_File; } CDataFileWriter::CDataFileWriter() { m_File = 0; m_pItemTypes = static_cast(calloc(MAX_ITEM_TYPES, sizeof(CItemTypeInfo))); m_pItems = static_cast(calloc(MAX_ITEMS, sizeof(CItemInfo))); m_pDatas = static_cast(calloc(MAX_DATAS, sizeof(CDataInfo))); } CDataFileWriter::~CDataFileWriter() { free(m_pItemTypes); m_pItemTypes = 0; for(int i = 0; i < m_NumItems; i++) if(m_pItems[i].m_pData) free(m_pItems[i].m_pData); for(int i = 0; i < m_NumDatas; ++i) if(m_pDatas[i].m_pCompressedData) free(m_pDatas[i].m_pCompressedData); free(m_pItems); m_pItems = 0; free(m_pDatas); m_pDatas = 0; } bool CDataFileWriter::OpenFile(class IStorage *pStorage, const char *pFilename, int StorageType) { dbg_assert(!m_File, "a file already exists"); m_File = pStorage->OpenFile(pFilename, IOFLAG_WRITE, StorageType); return m_File != 0; } void CDataFileWriter::Init() { dbg_assert(!m_File, "a file already exists"); m_NumItems = 0; m_NumDatas = 0; m_NumItemTypes = 0; m_NumExtendedItemTypes = 0; mem_zero(m_pItemTypes, sizeof(CItemTypeInfo) * MAX_ITEM_TYPES); mem_zero(m_aExtendedItemTypes, sizeof(m_aExtendedItemTypes)); for(int i = 0; i < MAX_ITEM_TYPES; i++) { m_pItemTypes[i].m_First = -1; m_pItemTypes[i].m_Last = -1; } } bool CDataFileWriter::Open(class IStorage *pStorage, const char *pFilename, int StorageType) { Init(); return OpenFile(pStorage, pFilename, StorageType); } int CDataFileWriter::GetExtendedItemTypeIndex(int Type) { for(int i = 0; i < m_NumExtendedItemTypes; i++) { if(m_aExtendedItemTypes[i] == Type) { return i; } } // Type not found, add it. dbg_assert(m_NumExtendedItemTypes < MAX_EXTENDED_ITEM_TYPES, "too many extended item types"); int Index = m_NumExtendedItemTypes++; m_aExtendedItemTypes[Index] = Type; CItemEx ExtendedType = CItemEx::FromUuid(g_UuidManager.GetUuid(Type)); AddItem(ITEMTYPE_EX, GetTypeFromIndex(Index), sizeof(ExtendedType), &ExtendedType); return Index; } int CDataFileWriter::AddItem(int Type, int ID, int Size, void *pData) { dbg_assert((Type >= 0 && Type < MAX_ITEM_TYPES) || Type >= OFFSET_UUID, "incorrect type"); dbg_assert(m_NumItems < 1024, "too many items"); dbg_assert(Size % sizeof(int) == 0, "incorrect boundary"); if(Type >= OFFSET_UUID) { Type = GetTypeFromIndex(GetExtendedItemTypeIndex(Type)); } m_pItems[m_NumItems].m_Type = Type; m_pItems[m_NumItems].m_ID = ID; m_pItems[m_NumItems].m_Size = Size; // copy data m_pItems[m_NumItems].m_pData = malloc(Size); mem_copy(m_pItems[m_NumItems].m_pData, pData, Size); if(!m_pItemTypes[Type].m_Num) // count item types m_NumItemTypes++; // link m_pItems[m_NumItems].m_Prev = m_pItemTypes[Type].m_Last; m_pItems[m_NumItems].m_Next = -1; if(m_pItemTypes[Type].m_Last != -1) m_pItems[m_pItemTypes[Type].m_Last].m_Next = m_NumItems; m_pItemTypes[Type].m_Last = m_NumItems; if(m_pItemTypes[Type].m_First == -1) m_pItemTypes[Type].m_First = m_NumItems; m_pItemTypes[Type].m_Num++; m_NumItems++; return m_NumItems - 1; } int CDataFileWriter::AddData(int Size, void *pData, int CompressionLevel) { dbg_assert(m_NumDatas < 1024, "too much data"); CDataInfo *pInfo = &m_pDatas[m_NumDatas]; unsigned long s = compressBound(Size); void *pCompData = malloc(s); // temporary buffer that we use during compression int Result = compress2((Bytef *)pCompData, &s, (Bytef *)pData, Size, CompressionLevel); // ignore_convention if(Result != Z_OK) { dbg_msg("datafile", "compression error %d", Result); dbg_assert(0, "zlib error"); } pInfo->m_UncompressedSize = Size; pInfo->m_CompressedSize = (int)s; pInfo->m_pCompressedData = malloc(pInfo->m_CompressedSize); mem_copy(pInfo->m_pCompressedData, pCompData, pInfo->m_CompressedSize); free(pCompData); m_NumDatas++; return m_NumDatas - 1; } int CDataFileWriter::AddDataSwapped(int Size, void *pData) { dbg_assert(Size % sizeof(int) == 0, "incorrect boundary"); #if defined(CONF_ARCH_ENDIAN_BIG) void *pSwapped = malloc(Size); // temporary buffer that we use during compression mem_copy(pSwapped, pData, Size); swap_endian(pSwapped, sizeof(int), Size / sizeof(int)); int Index = AddData(Size, pSwapped); free(pSwapped); return Index; #else return AddData(Size, pData); #endif } int CDataFileWriter::Finish() { if(!m_File) return 1; int ItemSize = 0; int TypesSize, HeaderSize, OffsetSize, FileSize, SwapSize; int DataSize = 0; CDatafileHeader Header; // we should now write this file! if(DEBUG) dbg_msg("datafile", "writing"); // calculate sizes for(int i = 0; i < m_NumItems; i++) { if(DEBUG) dbg_msg("datafile", "item=%d size=%d (%d)", i, m_pItems[i].m_Size, m_pItems[i].m_Size + (int)sizeof(CDatafileItem)); ItemSize += m_pItems[i].m_Size + sizeof(CDatafileItem); } for(int i = 0; i < m_NumDatas; i++) DataSize += m_pDatas[i].m_CompressedSize; // calculate the complete size TypesSize = m_NumItemTypes * sizeof(CDatafileItemType); HeaderSize = sizeof(CDatafileHeader); OffsetSize = (m_NumItems + m_NumDatas + m_NumDatas) * sizeof(int); // ItemOffsets, DataOffsets, DataUncompressedSizes FileSize = HeaderSize + TypesSize + OffsetSize + ItemSize + DataSize; SwapSize = FileSize - DataSize; (void)SwapSize; if(DEBUG) dbg_msg("datafile", "num_m_aItemTypes=%d TypesSize=%d m_aItemsize=%d DataSize=%d", m_NumItemTypes, TypesSize, ItemSize, DataSize); // construct Header { Header.m_aID[0] = 'D'; Header.m_aID[1] = 'A'; Header.m_aID[2] = 'T'; Header.m_aID[3] = 'A'; Header.m_Version = 4; Header.m_Size = FileSize - 16; Header.m_Swaplen = SwapSize - 16; Header.m_NumItemTypes = m_NumItemTypes; Header.m_NumItems = m_NumItems; Header.m_NumRawData = m_NumDatas; Header.m_ItemSize = ItemSize; Header.m_DataSize = DataSize; // write Header if(DEBUG) dbg_msg("datafile", "HeaderSize=%d", (int)sizeof(Header)); #if defined(CONF_ARCH_ENDIAN_BIG) swap_endian(&Header, sizeof(int), sizeof(Header) / sizeof(int)); #endif io_write(m_File, &Header, sizeof(Header)); } // write types for(int i = 0, Count = 0; i < MAX_ITEM_TYPES; i++) { if(m_pItemTypes[i].m_Num) { // write info CDatafileItemType Info; Info.m_Type = i; Info.m_Start = Count; Info.m_Num = m_pItemTypes[i].m_Num; if(DEBUG) dbg_msg("datafile", "writing type=%x start=%d num=%d", Info.m_Type, Info.m_Start, Info.m_Num); #if defined(CONF_ARCH_ENDIAN_BIG) swap_endian(&Info, sizeof(int), sizeof(CDatafileItemType) / sizeof(int)); #endif io_write(m_File, &Info, sizeof(Info)); Count += m_pItemTypes[i].m_Num; } } // write item offsets for(int i = 0, Offset = 0; i < MAX_ITEM_TYPES; i++) { if(m_pItemTypes[i].m_Num) { // write all m_pItems in of this type int k = m_pItemTypes[i].m_First; while(k != -1) { if(DEBUG) dbg_msg("datafile", "writing item offset num=%d offset=%d", k, Offset); int Temp = Offset; #if defined(CONF_ARCH_ENDIAN_BIG) swap_endian(&Temp, sizeof(int), sizeof(Temp) / sizeof(int)); #endif io_write(m_File, &Temp, sizeof(Temp)); Offset += m_pItems[k].m_Size + sizeof(CDatafileItem); // next k = m_pItems[k].m_Next; } } } // write data offsets for(int i = 0, Offset = 0; i < m_NumDatas; i++) { if(DEBUG) dbg_msg("datafile", "writing data offset num=%d offset=%d", i, Offset); int Temp = Offset; #if defined(CONF_ARCH_ENDIAN_BIG) swap_endian(&Temp, sizeof(int), sizeof(Temp) / sizeof(int)); #endif io_write(m_File, &Temp, sizeof(Temp)); Offset += m_pDatas[i].m_CompressedSize; } // write data uncompressed sizes for(int i = 0; i < m_NumDatas; i++) { if(DEBUG) dbg_msg("datafile", "writing data uncompressed size num=%d size=%d", i, m_pDatas[i].m_UncompressedSize); int UncompressedSize = m_pDatas[i].m_UncompressedSize; #if defined(CONF_ARCH_ENDIAN_BIG) swap_endian(&UncompressedSize, sizeof(int), sizeof(UncompressedSize) / sizeof(int)); #endif io_write(m_File, &UncompressedSize, sizeof(UncompressedSize)); } // write m_pItems for(int i = 0; i < MAX_ITEM_TYPES; i++) { if(m_pItemTypes[i].m_Num) { // write all m_pItems in of this type int k = m_pItemTypes[i].m_First; while(k != -1) { CDatafileItem Item; Item.m_TypeAndID = (i << 16) | m_pItems[k].m_ID; Item.m_Size = m_pItems[k].m_Size; if(DEBUG) dbg_msg("datafile", "writing item type=%x idx=%d id=%d size=%d", i, k, m_pItems[k].m_ID, m_pItems[k].m_Size); #if defined(CONF_ARCH_ENDIAN_BIG) swap_endian(&Item, sizeof(int), sizeof(Item) / sizeof(int)); swap_endian(m_pItems[k].m_pData, sizeof(int), m_pItems[k].m_Size / sizeof(int)); #endif io_write(m_File, &Item, sizeof(Item)); io_write(m_File, m_pItems[k].m_pData, m_pItems[k].m_Size); // next k = m_pItems[k].m_Next; } } } // write data for(int i = 0; i < m_NumDatas; i++) { if(DEBUG) dbg_msg("datafile", "writing data id=%d size=%d", i, m_pDatas[i].m_CompressedSize); io_write(m_File, m_pDatas[i].m_pCompressedData, m_pDatas[i].m_CompressedSize); } // free data for(int i = 0; i < m_NumItems; i++) { free(m_pItems[i].m_pData); m_pItems[i].m_pData = 0; } for(int i = 0; i < m_NumDatas; ++i) { free(m_pDatas[i].m_pCompressedData); m_pDatas[i].m_pCompressedData = 0; } io_close(m_File); m_File = 0; if(DEBUG) dbg_msg("datafile", "done"); return 0; }