/*++ Copyright (c) 1989-2000 Microsoft Corporation Module Name: Fat.h Abstract: This module defines the on-disk structure of the Fat file system. --*/ #ifndef _FAT_ #define _FAT_ // // The following nomenclature is used to describe the Fat on-disk // structure: // // LBN - is the number of a sector relative to the start of the disk. // // VBN - is the number of a sector relative to the start of a file, // directory, or allocation. // // LBO - is a byte offset relative to the start of the disk. // // VBO - is a byte offset relative to the start of a file, directory // or allocation. // typedef LONGLONG LBO; /* for Fat32, LBO is >32 bits */ typedef LBO *PLBO; typedef ULONG32 VBO; typedef VBO *PVBO; // // The boot sector is the first physical sector (LBN == 0) on the volume. // Part of the sector contains a BIOS Parameter Block. The BIOS in the // sector is packed (i.e., unaligned) so we'll supply a unpacking macro // to translate a packed BIOS into its unpacked equivalent. The unpacked // BIOS structure is already defined in ntioapi.h so we only need to define // the packed BIOS. // // // Define the Packed and Unpacked BIOS Parameter Block // typedef struct _PACKED_BIOS_PARAMETER_BLOCK { UCHAR BytesPerSector[2]; // offset = 0x000 0 UCHAR SectorsPerCluster[1]; // offset = 0x002 2 UCHAR ReservedSectors[2]; // offset = 0x003 3 UCHAR Fats[1]; // offset = 0x005 5 UCHAR RootEntries[2]; // offset = 0x006 6 UCHAR Sectors[2]; // offset = 0x008 8 UCHAR Media[1]; // offset = 0x00A 10 UCHAR SectorsPerFat[2]; // offset = 0x00B 11 UCHAR SectorsPerTrack[2]; // offset = 0x00D 13 UCHAR Heads[2]; // offset = 0x00F 15 UCHAR HiddenSectors[4]; // offset = 0x011 17 UCHAR LargeSectors[4]; // offset = 0x015 21 } PACKED_BIOS_PARAMETER_BLOCK; // sizeof = 0x019 25 typedef PACKED_BIOS_PARAMETER_BLOCK *PPACKED_BIOS_PARAMETER_BLOCK; typedef struct _PACKED_BIOS_PARAMETER_BLOCK_EX { UCHAR BytesPerSector[2]; // offset = 0x000 0 UCHAR SectorsPerCluster[1]; // offset = 0x002 2 UCHAR ReservedSectors[2]; // offset = 0x003 3 UCHAR Fats[1]; // offset = 0x005 5 UCHAR RootEntries[2]; // offset = 0x006 6 UCHAR Sectors[2]; // offset = 0x008 8 UCHAR Media[1]; // offset = 0x00A 10 UCHAR SectorsPerFat[2]; // offset = 0x00B 11 UCHAR SectorsPerTrack[2]; // offset = 0x00D 13 UCHAR Heads[2]; // offset = 0x00F 15 UCHAR HiddenSectors[4]; // offset = 0x011 17 UCHAR LargeSectors[4]; // offset = 0x015 21 UCHAR LargeSectorsPerFat[4]; // offset = 0x019 25 UCHAR ExtendedFlags[2]; // offset = 0x01D 29 UCHAR FsVersion[2]; // offset = 0x01F 31 UCHAR RootDirFirstCluster[4]; // offset = 0x021 33 UCHAR FsInfoSector[2]; // offset = 0x025 37 UCHAR BackupBootSector[2]; // offset = 0x027 39 UCHAR Reserved[12]; // offset = 0x029 41 } PACKED_BIOS_PARAMETER_BLOCK_EX; // sizeof = 0x035 53 typedef PACKED_BIOS_PARAMETER_BLOCK_EX *PPACKED_BIOS_PARAMETER_BLOCK_EX; // // The IsBpbFat32 macro is defined to work with both packed and unpacked // BPB structures. Since we are only checking for zero, the byte order // does not matter. // #define IsBpbFat32(bpb) (*(USHORT *)(&(bpb)->SectorsPerFat) == 0) typedef struct BIOS_PARAMETER_BLOCK { USHORT BytesPerSector; UCHAR SectorsPerCluster; USHORT ReservedSectors; UCHAR Fats; USHORT RootEntries; USHORT Sectors; UCHAR Media; USHORT SectorsPerFat; USHORT SectorsPerTrack; USHORT Heads; ULONG32 HiddenSectors; ULONG32 LargeSectors; ULONG32 LargeSectorsPerFat; union { USHORT ExtendedFlags; struct { ULONG ActiveFat:4; ULONG Reserved0:3; ULONG MirrorDisabled:1; ULONG Reserved1:8; }; }; USHORT FsVersion; ULONG32 RootDirFirstCluster; USHORT FsInfoSector; USHORT BackupBootSector; } BIOS_PARAMETER_BLOCK, *PBIOS_PARAMETER_BLOCK; // // This macro takes a Packed BIOS and fills in its Unpacked equivalent // #define FatUnpackBios(Bios,Pbios) { \ CopyUchar2(&(Bios)->BytesPerSector, &(Pbios)->BytesPerSector[0] ); \ CopyUchar1(&(Bios)->SectorsPerCluster, &(Pbios)->SectorsPerCluster[0]); \ CopyUchar2(&(Bios)->ReservedSectors, &(Pbios)->ReservedSectors[0] ); \ CopyUchar1(&(Bios)->Fats, &(Pbios)->Fats[0] ); \ CopyUchar2(&(Bios)->RootEntries, &(Pbios)->RootEntries[0] ); \ CopyUchar2(&(Bios)->Sectors, &(Pbios)->Sectors[0] ); \ CopyUchar1(&(Bios)->Media, &(Pbios)->Media[0] ); \ CopyUchar2(&(Bios)->SectorsPerFat, &(Pbios)->SectorsPerFat[0] ); \ CopyUchar2(&(Bios)->SectorsPerTrack, &(Pbios)->SectorsPerTrack[0] ); \ CopyUchar2(&(Bios)->Heads, &(Pbios)->Heads[0] ); \ CopyUchar4(&(Bios)->HiddenSectors, &(Pbios)->HiddenSectors[0] ); \ CopyUchar4(&(Bios)->LargeSectors, &(Pbios)->LargeSectors[0] ); \ CopyUchar4(&(Bios)->LargeSectorsPerFat,&((PPACKED_BIOS_PARAMETER_BLOCK_EX)Pbios)->LargeSectorsPerFat[0] ); \ CopyUchar2(&(Bios)->ExtendedFlags, &((PPACKED_BIOS_PARAMETER_BLOCK_EX)Pbios)->ExtendedFlags[0] ); \ CopyUchar2(&(Bios)->FsVersion, &((PPACKED_BIOS_PARAMETER_BLOCK_EX)Pbios)->FsVersion[0] ); \ CopyUchar4(&(Bios)->RootDirFirstCluster, \ &((PPACKED_BIOS_PARAMETER_BLOCK_EX)Pbios)->RootDirFirstCluster[0] ); \ CopyUchar2(&(Bios)->FsInfoSector, &((PPACKED_BIOS_PARAMETER_BLOCK_EX)Pbios)->FsInfoSector[0] ); \ CopyUchar2(&(Bios)->BackupBootSector, &((PPACKED_BIOS_PARAMETER_BLOCK_EX)Pbios)->BackupBootSector[0] ); \ } // // Define the boot sector // typedef struct _PACKED_BOOT_SECTOR { UCHAR Jump[3]; // offset = 0x000 0 UCHAR Oem[8]; // offset = 0x003 3 PACKED_BIOS_PARAMETER_BLOCK PackedBpb; // offset = 0x00B 11 UCHAR PhysicalDriveNumber; // offset = 0x024 36 UCHAR CurrentHead; // offset = 0x025 37 UCHAR Signature; // offset = 0x026 38 UCHAR Id[4]; // offset = 0x027 39 UCHAR VolumeLabel[11]; // offset = 0x02B 43 UCHAR SystemId[8]; // offset = 0x036 54 } PACKED_BOOT_SECTOR; // sizeof = 0x03E 62 typedef PACKED_BOOT_SECTOR *PPACKED_BOOT_SECTOR; typedef struct _PACKED_BOOT_SECTOR_EX { UCHAR Jump[3]; // offset = 0x000 0 UCHAR Oem[8]; // offset = 0x003 3 PACKED_BIOS_PARAMETER_BLOCK_EX PackedBpb; // offset = 0x00B 11 UCHAR PhysicalDriveNumber; // offset = 0x040 64 UCHAR CurrentHead; // offset = 0x041 65 UCHAR Signature; // offset = 0x042 66 UCHAR Id[4]; // offset = 0x043 67 UCHAR VolumeLabel[11]; // offset = 0x047 71 UCHAR SystemId[8]; // offset = 0x058 88 } PACKED_BOOT_SECTOR_EX; // sizeof = 0x060 96 typedef PACKED_BOOT_SECTOR_EX *PPACKED_BOOT_SECTOR_EX; // // Define the FAT32 FsInfo sector. // typedef struct _FSINFO_SECTOR { ULONG SectorBeginSignature; // offset = 0x000 0 UCHAR ExtraBootCode[480]; // offset = 0x004 4 ULONG FsInfoSignature; // offset = 0x1e4 484 ULONG FreeClusterCount; // offset = 0x1e8 488 ULONG NextFreeCluster; // offset = 0x1ec 492 UCHAR Reserved[12]; // offset = 0x1f0 496 ULONG SectorEndSignature; // offset = 0x1fc 508 } FSINFO_SECTOR, *PFSINFO_SECTOR; #define FSINFO_SECTOR_BEGIN_SIGNATURE 0x41615252 #define FSINFO_SECTOR_END_SIGNATURE 0xAA550000 #define FSINFO_SIGNATURE 0x61417272 // // We use the CurrentHead field for our dirty partition info. // #define FAT_BOOT_SECTOR_DIRTY 0x01 #define FAT_BOOT_SECTOR_TEST_SURFACE 0x02 // // Define a Fat Entry type. // // This type is used when representing a fat table entry. It also used // to be used when dealing with a fat table index and a count of entries, // but the ensuing type casting nightmare sealed this fate. These other // two types are represented as ULONGs. // typedef ULONG32 FAT_ENTRY; #define FAT32_ENTRY_MASK 0x0FFFFFFFUL // // We use these special index values to set the dirty info for // DOS/Win9x compatibility. // #define FAT_CLEAN_VOLUME (~FAT32_ENTRY_MASK | 0) #define FAT_DIRTY_VOLUME (~FAT32_ENTRY_MASK | 1) #define FAT_DIRTY_BIT_INDEX 1 // // Physically, the entry is fully set if clean, and the high // bit knocked out if it is dirty (i.e., it is really a clean // bit). This means it is different per-FAT size. // #define FAT_CLEAN_ENTRY (~0) #define FAT12_DIRTY_ENTRY 0x7ff #define FAT16_DIRTY_ENTRY 0x7fff #define FAT32_DIRTY_ENTRY 0x7fffffff // // The following constants the are the valid Fat index values. // #define FAT_CLUSTER_AVAILABLE (FAT_ENTRY)0x00000000 #define FAT_CLUSTER_RESERVED (FAT_ENTRY)0x0ffffff0 #define FAT_CLUSTER_BAD (FAT_ENTRY)0x0ffffff7 #define FAT_CLUSTER_LAST (FAT_ENTRY)0x0fffffff // // Fat files have the following time/date structures. Note that the // following structure is a 32 bits long but USHORT aligned. // typedef struct _FAT_TIME { USHORT DoubleSeconds : 5; USHORT Minute : 6; USHORT Hour : 5; } FAT_TIME; typedef FAT_TIME *PFAT_TIME; typedef struct _FAT_DATE { USHORT Day : 5; USHORT Month : 4; USHORT Year : 7; // Relative to 1980 } FAT_DATE; typedef FAT_DATE *PFAT_DATE; typedef struct _FAT_TIME_STAMP { FAT_TIME Time; FAT_DATE Date; } FAT_TIME_STAMP; typedef FAT_TIME_STAMP *PFAT_TIME_STAMP; // // Fat files have 8 character file names and 3 character extensions // typedef UCHAR FAT8DOT3[11]; typedef FAT8DOT3 *PFAT8DOT3; // // The directory entry record exists for every file/directory on the // disk except for the root directory. // typedef struct _PACKED_DIRENT { FAT8DOT3 FileName; // offset = 0 UCHAR Attributes; // offset = 11 UCHAR NtByte; // offset = 12 UCHAR CreationMSec; // offset = 13 FAT_TIME_STAMP CreationTime; // offset = 14 FAT_DATE LastAccessDate; // offset = 18 union { USHORT ExtendedAttributes; // offset = 20 USHORT FirstClusterOfFileHi; // offset = 20 }; FAT_TIME_STAMP LastWriteTime; // offset = 22 USHORT FirstClusterOfFile; // offset = 26 ULONG32 FileSize; // offset = 28 } PACKED_DIRENT; // sizeof = 32 typedef PACKED_DIRENT *PPACKED_DIRENT; // // A packed dirent is already quadword aligned so simply declare a dirent as a // packed dirent // typedef PACKED_DIRENT DIRENT; typedef DIRENT *PDIRENT; // // The first byte of a dirent describes the dirent. There is also a routine // to help in deciding how to interpret the dirent. // #define FAT_DIRENT_NEVER_USED 0x00 #define FAT_DIRENT_REALLY_0E5 0x05 #define FAT_DIRENT_DIRECTORY_ALIAS 0x2e #define FAT_DIRENT_DELETED 0xe5 // // Define the NtByte bits. // // // These two bits are used for EFS on FAT // 0x1 means the file contents are encrypted // // 0x2 means the EFS metadata header is big. // (this optimization means we don't have to read // in the first sector of the file stream to get // the normal header size) // #define FAT_DIRENT_NT_BYTE_ENCRYPTED 0x01 #define FAT_DIRENT_NT_BYTE_BIG_HEADER 0x02 // // These two bits optimize the case in which either the name // or extension are all lower case. // #define FAT_DIRENT_NT_BYTE_8_LOWER_CASE 0x08 #define FAT_DIRENT_NT_BYTE_3_LOWER_CASE 0x10 // // Define the various dirent attributes // #define FAT_DIRENT_ATTR_READ_ONLY 0x01 #define FAT_DIRENT_ATTR_HIDDEN 0x02 #define FAT_DIRENT_ATTR_SYSTEM 0x04 #define FAT_DIRENT_ATTR_VOLUME_ID 0x08 #define FAT_DIRENT_ATTR_DIRECTORY 0x10 #define FAT_DIRENT_ATTR_ARCHIVE 0x20 #define FAT_DIRENT_ATTR_DEVICE 0x40 #define FAT_DIRENT_ATTR_LFN (FAT_DIRENT_ATTR_READ_ONLY | \ FAT_DIRENT_ATTR_HIDDEN | \ FAT_DIRENT_ATTR_SYSTEM | \ FAT_DIRENT_ATTR_VOLUME_ID) // // On-disk extension for EFS files. // #define FAT_EFS_EXTENSION L".PFILE" #define FAT_EFS_EXTENSION_CHARCOUNT (6) #define FAT_EFS_EXTENSION_BYTECOUNT (12) // // These macros convert a number of fields in the Bpb to bytes from sectors // // ULONG // FatBytesPerCluster ( // IN PBIOS_PARAMETER_BLOCK Bios // ); // // ULONG // FatBytesPerFat ( // IN PBIOS_PARAMETER_BLOCK Bios // ); // // ULONG // FatReservedBytes ( // IN PBIOS_PARAMETER_BLOCK Bios // ); // #define FatBytesPerCluster(B) ((ULONG)((B)->BytesPerSector * (B)->SectorsPerCluster)) #define FatBytesPerFat(B) (IsBpbFat32(B)? \ ((ULONG)((B)->BytesPerSector * (B)->LargeSectorsPerFat)) : \ ((ULONG)((B)->BytesPerSector * (B)->SectorsPerFat))) #define FatReservedBytes(B) ((ULONG)((B)->BytesPerSector * (B)->ReservedSectors)) // // This macro returns the size of the root directory dirent area in bytes // For Fat32, the root directory is variable in length. This macro returns // 0 because it is also used to determine the location of cluster 2. // // ULONG // FatRootDirectorySize ( // IN PBIOS_PARAMETER_BLOCK Bios // ); // #define FatRootDirectorySize(B) ((ULONG)((B)->RootEntries * sizeof(DIRENT))) // // This macro returns the first Lbo (zero based) of the root directory on // the device. This area is after the reserved and fats. // // For Fat32, the root directory is moveable. This macro returns the LBO // for cluster 2 because it is used to determine the location of cluster 2. // FatRootDirectoryLbo32() returns the actual LBO of the beginning of the // actual root directory. // // LBO // FatRootDirectoryLbo ( // IN PBIOS_PARAMETER_BLOCK Bios // ); // #define FatRootDirectoryLbo(B) (FatReservedBytes(B) + ((B)->Fats * FatBytesPerFat(B))) #define FatRootDirectoryLbo32(B) (FatFileAreaLbo(B)+((B)->RootDirFirstCluster-2)*FatBytesPerCluster(B)) // // This macro returns the first Lbo (zero based) of the file area on the // the device. This area is after the reserved, fats, and root directory. // // LBO // FatFirstFileAreaLbo ( // IN PBIOS_PARAMTER_BLOCK Bios // ); // #define FatFileAreaLbo(B) (FatRootDirectoryLbo(B) + FatRootDirectorySize(B)) // // This macro returns the number of clusters on the disk. This value is // computed by taking the total sectors on the disk subtracting up to the // first file area sector and then dividing by the sectors per cluster count. // Note that I don't use any of the above macros since far too much // superfluous sector/byte conversion would take place. // // ULONG // FatNumberOfClusters ( // IN PBIOS_PARAMETER_BLOCK Bios // ); // // // for prior to MS-DOS Version 3.2 // // After DOS 4.0, at least one of these, Sectors or LargeSectors, will be zero. // but DOS version 3.2 case, both of these value might contains some value, // because, before 3.2, we don't have Large Sector entry, some disk might have // unexpected value in the field, we will use LargeSectors if Sectors eqaul to zero. // #define FatNumberOfClusters(B) ( \ \ IsBpbFat32(B) ? \ \ ((((B)->Sectors ? (B)->Sectors : (B)->LargeSectors) \ \ - ((B)->ReservedSectors + \ (B)->Fats * (B)->LargeSectorsPerFat )) \ \ / \ \ (B)->SectorsPerCluster) \ : \ ((((B)->Sectors ? (B)->Sectors : (B)->LargeSectors) \ \ - ((B)->ReservedSectors + \ (B)->Fats * (B)->SectorsPerFat + \ (B)->RootEntries * sizeof(DIRENT) / (B)->BytesPerSector ) ) \ \ / \ \ (B)->SectorsPerCluster) \ ) // // This macro returns the fat table bit size (i.e., 12 or 16 bits) // // ULONG // FatIndexBitSize ( // IN PBIOS_PARAMETER_BLOCK Bios // ); // #define FatIndexBitSize(B) \ ((UCHAR)(IsBpbFat32(B) ? 32 : (FatNumberOfClusters(B) < 4087 ? 12 : 16))) // // This macro raises STATUS_FILE_CORRUPT and marks the Fcb bad if an // index value is not within the proper range. // Note that the first two index values are invalid (0, 1), so we must // add two from the top end to make sure the everything is within range // // VOID // FatVerifyIndexIsValid ( // IN PIRP_CONTEXT IrpContext, // IN PVCB Vcb, // IN ULONG Index // ); // #define FatVerifyIndexIsValid(IC,V,I) { \ if (((I) < 2) || ((I) > ((V)->AllocationSupport.NumberOfClusters + 1))) { \ FatRaiseStatus(IC,STATUS_FILE_CORRUPT_ERROR); \ } \ } // // These two macros are used to translate between Logical Byte Offsets, // and fat entry indexes. Note the use of variables stored in the Vcb. // These two macros are used at a higher level than the other macros // above. // // Note, these indexes are true cluster numbers. // // LBO // GetLboFromFatIndex ( // IN FAT_ENTRY Fat_Index, // IN PVCB Vcb // ); // // FAT_ENTRY // GetFatIndexFromLbo ( // IN LBO Lbo, // IN PVCB Vcb // ); // #define FatGetLboFromIndex(VCB,FAT_INDEX) ( \ ( (LBO) \ (VCB)->AllocationSupport.FileAreaLbo + \ (((LBO)((FAT_INDEX) - 2)) << (VCB)->AllocationSupport.LogOfBytesPerCluster) \ ) \ ) #define FatGetIndexFromLbo(VCB,LBO) ( \ (ULONG) ( \ (((LBO) - (VCB)->AllocationSupport.FileAreaLbo) >> \ (VCB)->AllocationSupport.LogOfBytesPerCluster) + 2 \ ) \ ) // // The following macro does the shifting and such to lookup an entry // // VOID // FatLookup12BitEntry( // IN PVOID Fat, // IN FAT_ENTRY Index, // OUT PFAT_ENTRY Entry // ); // #define FatLookup12BitEntry(FAT,INDEX,ENTRY) { \ \ CopyUchar2((PUCHAR)(ENTRY), (PUCHAR)(FAT) + (INDEX) * 3 / 2); \ \ *ENTRY = (FAT_ENTRY)(0xfff & (((INDEX) & 1) ? (*(ENTRY) >> 4) : \ *(ENTRY))); \ } // // The following macro does the tmp shifting and such to store an entry // // VOID // FatSet12BitEntry( // IN PVOID Fat, // IN FAT_ENTRY Index, // IN FAT_ENTRY Entry // ); // #define FatSet12BitEntry(FAT,INDEX,ENTRY) { \ \ FAT_ENTRY TmpFatEntry; \ \ CopyUchar2((PUCHAR)&TmpFatEntry, (PUCHAR)(FAT) + (INDEX) * 3 / 2); \ \ TmpFatEntry = (FAT_ENTRY) \ (((INDEX) & 1) ? ((ENTRY) << 4) | (TmpFatEntry & 0xf) \ : (ENTRY) | (TmpFatEntry & 0xf000)); \ \ *((UNALIGNED UCHAR2 *)((PUCHAR)(FAT) + (INDEX) * 3 / 2)) = *((UNALIGNED UCHAR2 *)(&TmpFatEntry)); \ } // // The following macro compares two FAT_TIME_STAMPs // #define FatAreTimesEqual(TIME1,TIME2) ( \ RtlEqualMemory((TIME1),(TIME2), sizeof(FAT_TIME_STAMP)) \ ) #define EA_FILE_SIGNATURE (0x4445) // "ED" #define EA_SET_SIGNATURE (0x4145) // "EA" // // If the volume contains any ea data then there is one EA file called // "EA DATA. SF" located in the root directory as Hidden, System and // ReadOnly. // typedef struct _EA_FILE_HEADER { USHORT Signature; // offset = 0 USHORT FormatType; // offset = 2 USHORT LogType; // offset = 4 USHORT Cluster1; // offset = 6 USHORT NewCValue1; // offset = 8 USHORT Cluster2; // offset = 10 USHORT NewCValue2; // offset = 12 USHORT Cluster3; // offset = 14 USHORT NewCValue3; // offset = 16 USHORT Handle; // offset = 18 USHORT NewHOffset; // offset = 20 UCHAR Reserved[10]; // offset = 22 USHORT EaBaseTable[240]; // offset = 32 } EA_FILE_HEADER; // sizeof = 512 typedef EA_FILE_HEADER *PEA_FILE_HEADER; typedef USHORT EA_OFF_TABLE[128]; typedef EA_OFF_TABLE *PEA_OFF_TABLE; // // Every file with an extended attribute contains in its dirent an index // into the EaMapTable. The map table contains an offset within the ea // file (cluster aligned) of the ea data for the file. The individual // ea data for each file is prefaced with an Ea Data Header. // typedef struct _EA_SET_HEADER { USHORT Signature; // offset = 0 USHORT OwnEaHandle; // offset = 2 ULONG32 NeedEaCount; // offset = 4 UCHAR OwnerFileName[14]; // offset = 8 UCHAR Reserved[4]; // offset = 22 UCHAR cbList[4]; // offset = 26 UCHAR PackedEas[1]; // offset = 30 } EA_SET_HEADER; // sizeof = 30 typedef EA_SET_HEADER *PEA_SET_HEADER; #define SIZE_OF_EA_SET_HEADER 30 #define MAXIMUM_EA_SIZE 0x0000ffff #define GetcbList(EASET) (((EASET)->cbList[0] << 0) + \ ((EASET)->cbList[1] << 8) + \ ((EASET)->cbList[2] << 16) + \ ((EASET)->cbList[3] << 24)) #define SetcbList(EASET,CB) { \ (EASET)->cbList[0] = (CB >> 0) & 0x0ff; \ (EASET)->cbList[1] = (CB >> 8) & 0x0ff; \ (EASET)->cbList[2] = (CB >> 16) & 0x0ff; \ (EASET)->cbList[3] = (CB >> 24) & 0x0ff; \ } // // Every individual ea in an ea set is declared the following packed ea // typedef struct _PACKED_EA { UCHAR Flags; UCHAR EaNameLength; UCHAR EaValueLength[2]; CHAR EaName[1]; } PACKED_EA; typedef PACKED_EA *PPACKED_EA; // // The following two macros are used to get and set the ea value length // field of a packed ea // // VOID // GetEaValueLength ( // IN PPACKED_EA Ea, // OUT PUSHORT ValueLength // ); // // VOID // SetEaValueLength ( // IN PPACKED_EA Ea, // IN USHORT ValueLength // ); // #define GetEaValueLength(EA,LEN) { \ *(LEN) = 0; \ CopyUchar2( (LEN), (EA)->EaValueLength ); \ } #define SetEaValueLength(EA,LEN) { \ CopyUchar2( &((EA)->EaValueLength), (LEN) ); \ } // // The following macro is used to get the size of a packed ea // // VOID // SizeOfPackedEa ( // IN PPACKED_EA Ea, // OUT PUSHORT EaSize // ); // #define SizeOfPackedEa(EA,SIZE) { \ ULONG _NL,_DL; _NL = 0; _DL = 0; \ CopyUchar1(&_NL, &(EA)->EaNameLength); \ GetEaValueLength(EA, &_DL); \ *(SIZE) = 1 + 1 + 2 + _NL + 1 + _DL; \ } #define EA_NEED_EA_FLAG 0x80 #define MIN_EA_HANDLE 1 #define MAX_EA_HANDLE 30719 #define UNUSED_EA_HANDLE 0xffff #define EA_CBLIST_OFFSET 0x1a #define MAX_EA_BASE_INDEX 240 #define MAX_EA_OFFSET_INDEX 128 #endif // _FAT_