Modules/FAT - Fixed unneeded memcpy in LFN, made more robust too

[tpg/acess2.git] / Modules / Filesystems / FAT / fat.c

/*\r
 * Acess 2\r
 * FAT12/16/32 Driver Version (Incl LFN)\r
 * \r
 * NOTE: This driver will only support _reading_ long file names, not\r
 * writing. I don't even know why I'm adding write-support. FAT sucks.\r
 * \r
 * Known Bugs:\r
 * - LFN Is buggy in FAT_ReadDir\r
 * \r
 * Notes:\r
 * - There's hard-coded 512 byte sectors everywhere, that needs to be\r
 *   cleaned.\r
 * - Thread safety is out the window with the write and LFN code\r
 */\r
/**\r
 * \todo Implement changing of the parent directory when a file is written to\r
 * \todo Implement file creation / deletion\r
 */\r
#define DEBUG   0\r
#define VERBOSE 1\r
\r
#define CACHE_FAT       0       //!< Caches the FAT in memory\r
#define USE_LFN         1       //!< Enables the use of Long File Names\r
#define SUPPORT_WRITE   0       //!< Enables write support\r
\r
#include <acess.h>\r
#include <modules.h>\r
#include <vfs.h>\r
#include "fs_fat.h"\r
\r
#define FAT_FLAG_DIRTY  0x10000\r
#define FAT_FLAG_DELETE 0x20000\r
\r
// === TYPES ===\r
#if USE_LFN\r
/**\r
 * \brief Long-Filename cache entry\r
 */\r
typedef struct sFAT_LFNCacheEnt\r
{\r
         int    ID;\r
        // TODO: Handle UTF16 names correctly\r
        char    Data[256];\r
}       tFAT_LFNCacheEnt;\r
/**\r
 * \brief Long-Filename cache\r
 */\r
typedef struct sFAT_LFNCache\r
{\r
         int    NumEntries;\r
        tFAT_LFNCacheEnt        Entries[];\r
}       tFAT_LFNCache;\r
#endif\r
\r
// === PROTOTYPES ===\r
// --- Driver Core\r
 int    FAT_Install(char **Arguments);\r
tVFS_Node       *FAT_InitDevice(const char *device, const char **options);\r
void    FAT_Unmount(tVFS_Node *Node);\r
// --- Helpers\r
 int    FAT_int_GetAddress(tVFS_Node *Node, Uint64 Offset, Uint64 *Addr, Uint32 *Cluster);\r
Uint32  FAT_int_GetFatValue(tFAT_VolInfo *Disk, Uint32 Cluster);\r
#if SUPPORT_WRITE\r
Uint32  FAT_int_AllocateCluster(tFAT_VolInfo *Disk, Uint32 Previous);\r
Uint32  FAT_int_FreeCluster(tFAT_VolInfo *Disk, Uint32 Cluster);\r
#endif\r
void    FAT_int_ReadCluster(tFAT_VolInfo *Disk, Uint32 Cluster, int Length, void *Buffer);\r
// --- File IO\r
Uint64  FAT_Read(tVFS_Node *Node, Uint64 Offset, Uint64 Length, void *Buffer);\r
#if SUPPORT_WRITE\r
void    FAT_int_WriteCluster(tFAT_VolInfo *Disk, Uint32 Cluster, void *Buffer);\r
Uint64  FAT_Write(tVFS_Node *Node, Uint64 Offset, Uint64 Length, void *Buffer);\r
#endif\r
// --- Directory IO\r
char    *FAT_ReadDir(tVFS_Node *Node, int ID);\r
tVFS_Node       *FAT_FindDir(tVFS_Node *Node, const char *Name);\r
tVFS_Node       *FAT_GetNodeFromINode(tVFS_Node *Root, Uint64 Inode);\r
#if SUPPORT_WRITE\r
 int    FAT_Mknod(tVFS_Node *Node, const char *Name, Uint Flags);\r
 int    FAT_Relink(tVFS_Node *node, const char *OldName, const char *NewName);\r
#endif\r
void    FAT_CloseFile(tVFS_Node *node);\r
\r
// === Options ===\r
 int    giFAT_MaxCachedClusters = 1024*512/4;\r
\r
// === SEMI-GLOBALS ===\r
MODULE_DEFINE(0, (0<<8)|50 /*v0.50*/, VFAT, FAT_Install, NULL, NULL);\r
tFAT_VolInfo    gFAT_Disks[8];\r
 int    giFAT_PartCount = 0;\r
tVFS_Driver     gFAT_FSInfo = {"fat", 0, FAT_InitDevice, FAT_Unmount, FAT_GetNodeFromINode, NULL};\r
\r
// === CODE ===\r
/**\r
 * \fn int FAT_Install(char **Arguments)\r
 * \brief Install the FAT Driver\r
 */\r
int FAT_Install(char **Arguments)\r
{\r
        VFS_AddDriver( &gFAT_FSInfo );\r
        return MODULE_ERR_OK;\r
}\r
\r
/**\r
 * \brief Reads the boot sector of a disk and prepares the structures for it\r
 */\r
tVFS_Node *FAT_InitDevice(const char *Device, const char **Options)\r
{\r
        fat_bootsect *bs;\r
         int    i;\r
        Uint32  FATSz, RootDirSectors, TotSec;\r
        tVFS_Node       *node = NULL;\r
        tFAT_VolInfo    *diskInfo = &gFAT_Disks[giFAT_PartCount];\r
        \r
        // Temporary Pointer\r
        bs = &diskInfo->bootsect;\r
        \r
        // Open device and read boot sector\r
        diskInfo->fileHandle = VFS_Open(Device, VFS_OPENFLAG_READ|VFS_OPENFLAG_WRITE);\r
        if(diskInfo->fileHandle == -1) {\r
                Log_Notice("FAT", "Unable to open device '%s'", Device);\r
                return NULL;\r
        }\r
        \r
        VFS_ReadAt(diskInfo->fileHandle, 0, 512, bs);\r
        \r
        if(bs->bps == 0 || bs->spc == 0) {\r
                Log_Notice("FAT", "Error in FAT Boot Sector");\r
                return NULL;\r
        }\r
        \r
        // FAT Type Determining\r
        // - From Microsoft FAT Specifcation\r
        RootDirSectors = ((bs->files_in_root*32) + (bs->bps - 1)) / bs->bps;\r
        \r
        if(bs->fatSz16 != 0)\r
                FATSz = bs->fatSz16;\r
        else\r
                FATSz = bs->spec.fat32.fatSz32;\r
        \r
        if(bs->totalSect16 != 0)\r
                TotSec = bs->totalSect16;\r
        else\r
                TotSec = bs->totalSect32;\r
        \r
        diskInfo->ClusterCount = (TotSec - (bs->resvSectCount + (bs->fatCount * FATSz) + RootDirSectors)) / bs->spc;\r
        \r
        if(diskInfo->ClusterCount < 4085)\r
                diskInfo->type = FAT12;\r
        else if(diskInfo->ClusterCount < 65525)\r
                diskInfo->type = FAT16;\r
        else\r
                diskInfo->type = FAT32;\r
        \r
        #if VERBOSE\r
        {\r
                char    *sFatType, *sSize;\r
                Uint    iSize = diskInfo->ClusterCount * bs->spc * bs->bps / 1024;\r
                \r
                switch(diskInfo->type)\r
                {\r
                case FAT12:     sFatType = "FAT12";     break;\r
                case FAT16:     sFatType = "FAT16";     break;\r
                case FAT32:     sFatType = "FAT32";     break;\r
                default:        sFatType = "UNKNOWN";   break;\r
                }\r
                if(iSize <= 2*1024) {\r
                        sSize = "KiB";\r
                }\r
                else if(iSize <= 2*1024*1024) {\r
                        sSize = "MiB";\r
                        iSize >>= 10;\r
                }\r
                else {\r
                        sSize = "GiB";\r
                        iSize >>= 20;\r
                }\r
                Log_Notice("FAT", "'%s' %s, %i %s", Device, sFatType, iSize, sSize);\r
        }\r
        #endif\r
        \r
        // Get Name\r
        if(diskInfo->type == FAT32) {\r
                for(i=0;i<11;i++)\r
                        diskInfo->name[i] = (bs->spec.fat32.label[i] == ' ' ? '\0' : bs->spec.fat32.label[i]);\r
        }\r
        else {\r
                for(i=0;i<11;i++)\r
                        diskInfo->name[i] = (bs->spec.fat16.label[i] == ' ' ? '\0' : bs->spec.fat16.label[i]);\r
        }\r
        diskInfo->name[11] = '\0';\r
        \r
        // Compute Root directory offset\r
        if(diskInfo->type == FAT32)\r
                diskInfo->rootOffset = bs->spec.fat32.rootClust;\r
        else\r
                diskInfo->rootOffset = (FATSz * bs->fatCount) / bs->spc;\r
        \r
        diskInfo->firstDataSect = bs->resvSectCount + (bs->fatCount * FATSz) + RootDirSectors;\r
        \r
        //Allow for Caching the FAT\r
        #if CACHE_FAT\r
        if( diskInfo->ClusterCount <= giFAT_MaxCachedClusters )\r
        {\r
                Uint32  Ofs;\r
                diskInfo->FATCache = (Uint32*)malloc(sizeof(Uint32)*diskInfo->ClusterCount);\r
                if(diskInfo->FATCache == NULL) {\r
                        Log_Warning("FAT", "Heap Exhausted");\r
                        return NULL;\r
                }\r
                Ofs = bs->resvSectCount*512;\r
                if(diskInfo->type == FAT12)\r
                {\r
                        Uint32  val;\r
                         int    j;\r
                        char    buf[1536];\r
                        for(i = 0; i < diskInfo->ClusterCount/2; i++) {\r
                                j = i & 511;    //%512\r
                                if( j == 0 ) {\r
                                        VFS_ReadAt(diskInfo->fileHandle, Ofs, 3*512, buf);\r
                                        Ofs += 3*512;\r
                                }\r
                                val = *((int*)(buf+j*3));\r
                                diskInfo->FATCache[i*2] = val & 0xFFF;\r
                                diskInfo->FATCache[i*2+1] = (val>>12) & 0xFFF;\r
                        }\r
                }\r
                else if(diskInfo->type == FAT16)\r
                {\r
                        Uint16  buf[256];\r
                        for(i=0;i<diskInfo->ClusterCount;i++) {\r
                                if( (i & 255) == 0 ) {\r
                                        VFS_ReadAt(diskInfo->fileHandle, Ofs, 512, buf);\r
                                        Ofs += 512;\r
                                }\r
                                diskInfo->FATCache[i] = buf[i&255];\r
                        }\r
                }\r
                else if(diskInfo->type == FAT32)\r
                {\r
                        Uint32  buf[128];\r
                        for(i=0;i<diskInfo->ClusterCount;i++) {\r
                                if( (i & 127) == 0 ) {\r
                                        VFS_ReadAt(diskInfo->fileHandle, Ofs, 512, buf);\r
                                        Ofs += 512;\r
                                }\r
                                diskInfo->FATCache[i] = buf[i&127];\r
                        }\r
                }\r
                LOG("FAT Fully Cached");\r
        }\r
        #endif /*CACHE_FAT*/\r
        \r
        diskInfo->BytesPerCluster = bs->spc * bs->bps;\r
        \r
        // Initalise inode cache for filesystem\r
        diskInfo->inodeHandle = Inode_GetHandle();\r
        LOG("Inode Cache handle is %i", diskInfo->inodeHandle);\r
        \r
        // == VFS Interface\r
        node = &diskInfo->rootNode;\r
        //node->Size = bs->files_in_root;\r
        node->Size = -1;\r
        node->Inode = diskInfo->rootOffset;     // 0:31 - Cluster, 32:63 - Parent Directory Cluster\r
        node->ImplPtr = diskInfo;       // Disk info pointer\r
        node->ImplInt = 0;      // 0:15 - Directory Index, 16: Dirty Flag, 17: Deletion Flag\r
        \r
        node->ReferenceCount = 1;\r
        \r
        node->UID = 0;  node->GID = 0;\r
        node->NumACLs = 1;\r
        node->ACLs = &gVFS_ACL_EveryoneRWX;\r
        node->Flags = VFS_FFLAG_DIRECTORY;\r
        node->CTime = node->MTime = node->ATime = now();\r
        \r
        node->Read = node->Write = NULL;\r
        node->ReadDir = FAT_ReadDir;\r
        node->FindDir = FAT_FindDir;\r
        #if SUPPORT_WRITE\r
        node->Relink = FAT_Relink;\r
        node->MkNod = FAT_Mknod;\r
        #else\r
        node->Relink = NULL;\r
        node->MkNod = NULL;\r
        #endif\r
        //node->Close = FAT_Unmount;\r
        \r
        giFAT_PartCount ++;\r
        return node;\r
}\r
\r
/**\r
 * \brief Closes a mount and marks it as free\r
 * \param Node  Mount Root\r
 * \r
 * \todo Remove FAT Cache\r
 * \todo Clear LFN Cache\r
 * \todo Check that all files are closed and flushed\r
 */\r
void FAT_Unmount(tVFS_Node *Node)\r
{\r
        tFAT_VolInfo    *disk = Node->ImplPtr;\r
        \r
        // Close Disk Handle\r
        VFS_Close( disk->fileHandle );\r
        // Clear Node Cache\r
        Inode_ClearCache(disk->inodeHandle);\r
        // Mark as unused\r
        disk->fileHandle = -2;\r
        return;\r
}\r
\r
/**\r
 * \brief Converts an offset in a file into a disk address\r
 * \param Node  File (or directory) node\r
 * \param Offset        Offset in the file\r
 * \param Addr  Return Address\r
 * \param Cluster       Set to the current cluster (or the last one if \a Offset\r
 *                  is past EOC) - Not touched if the node is the root\r
 *                  directory.\r
 * \return Zero on success, non-zero on error\r
 */\r
int FAT_int_GetAddress(tVFS_Node *Node, Uint64 Offset, Uint64 *Addr, Uint32 *Cluster)\r
{\r
        Uint32  cluster;\r
        Uint64  addr;\r
         int    skip;\r
        tFAT_VolInfo    *disk = Node->ImplPtr;\r
        \r
        ENTER("pNode XOffset", Node, Offset);\r
        \r
        cluster = Node->Inode & 0xFFFFFFF;      // Cluster ID\r
        LOG("cluster = 0x%07x", cluster);\r
        \r
        // Do Cluster Skip\r
        // - Pre FAT32 had a reserved area for the root.\r
        if( disk->type == FAT32 || cluster != disk->rootOffset )\r
        {\r
                skip = Offset / disk->BytesPerCluster;\r
                LOG("skip = %i", skip);\r
                // Skip previous clusters\r
                for(; skip-- ; )\r
                {\r
                        if(Cluster)     *Cluster = cluster;\r
                        cluster = FAT_int_GetFatValue(disk, cluster);\r
                        // Check for end of cluster chain\r
                        if(cluster == 0xFFFFFFFF) {     LEAVE('i', 1);  return 1;}\r
                }\r
                if(Cluster)     *Cluster = cluster;\r
        }\r
        else {\r
                // Increment by clusters in offset\r
                cluster += Offset / disk->BytesPerCluster;\r
        }\r
        \r
        LOG("cluster = %08x", cluster);\r
        \r
        // Bounds Checking (Used to spot corruption)\r
        if(cluster > disk->ClusterCount + 2)\r
        {\r
                Log_Warning("FAT", "Cluster ID is over cluster count (0x%x>0x%x)",\r
                        cluster, disk->ClusterCount+2);\r
                LEAVE('i', 1);\r
                return 1;\r
        }\r
        \r
        // Compute Offsets\r
        // - Pre FAT32 cluster base (in sectors)\r
        if( cluster == disk->rootOffset && disk->type != FAT32 ) {\r
                addr = disk->bootsect.resvSectCount * disk->bootsect.bps;\r
                addr += cluster * disk->BytesPerCluster;\r
        }\r
        else {\r
                addr = disk->firstDataSect * disk->bootsect.bps;\r
                addr += (cluster - 2) * disk->BytesPerCluster;\r
        }\r
        // In-cluster offset\r
        addr += Offset % disk->BytesPerCluster;\r
        \r
        LOG("addr = 0x%08x", addr);\r
        *Addr = addr;\r
        LEAVE('i', 0);\r
        return 0;\r
}\r
\r
/*\r
 * ====================\r
 *   FAT Manipulation\r
 * ====================\r
 */\r
/**\r
 * \fn Uint32 FAT_int_GetFatValue(tFAT_VolInfo *Disk, Uint32 cluster)\r
 * \brief Fetches a value from the FAT\r
 */\r
Uint32 FAT_int_GetFatValue(tFAT_VolInfo *Disk, Uint32 cluster)\r
{\r
        Uint32  val = 0;\r
        Uint32  ofs;\r
        ENTER("pDisk xCluster", Disk, cluster);\r
        Mutex_Acquire( &Disk->lFAT );\r
        #if CACHE_FAT\r
        if( Disk->ClusterCount <= giFAT_MaxCachedClusters )\r
        {\r
                val = Disk->FATCache[cluster];\r
                if(Disk->type == FAT12 && val == EOC_FAT12)     val = -1;\r
                if(Disk->type == FAT16 && val == EOC_FAT16)     val = -1;\r
                if(Disk->type == FAT32 && val == EOC_FAT32)     val = -1;\r
        }\r
        else\r
        {\r
        #endif\r
                ofs = Disk->bootsect.resvSectCount*512;\r
                if(Disk->type == FAT12) {\r
                        VFS_ReadAt(Disk->fileHandle, ofs+(cluster/2)*3, 3, &val);\r
                        val = (cluster & 1 ? val>>12 : val & 0xFFF);\r
                        if(val == EOC_FAT12)    val = -1;\r
                } else if(Disk->type == FAT16) {\r
                        VFS_ReadAt(Disk->fileHandle, ofs+cluster*2, 2, &val);\r
                        if(val == EOC_FAT16)    val = -1;\r
                } else {\r
                        VFS_ReadAt(Disk->fileHandle, ofs+cluster*4, 4, &val);\r
                        if(val == EOC_FAT32)    val = -1;\r
                }\r
        #if CACHE_FAT\r
        }\r
        #endif /*CACHE_FAT*/\r
        Mutex_Release( &Disk->lFAT );\r
        LEAVE('x', val);\r
        return val;\r
}\r
\r
#if SUPPORT_WRITE\r
/**\r
 * \brief Allocate a new cluster\r
 */\r
Uint32 FAT_int_AllocateCluster(tFAT_VolInfo *Disk, Uint32 Previous)\r
{\r
        Uint32  ret = Previous;\r
        #if CACHE_FAT\r
        if( Disk->ClusterCount <= giFAT_MaxCachedClusters )\r
        {\r
                Uint32  eoc;\r
                \r
                LOCK(Disk->lFAT);\r
                for(ret = Previous; ret < Disk->ClusterCount; ret++)\r
                {\r
                        if(Disk->FATCache[ret] == 0)\r
                                goto append;\r
                }\r
                for(ret = 0; ret < Previous; ret++)\r
                {\r
                        if(Disk->FATCache[ret] == 0)\r
                                goto append;\r
                }\r
                \r
                RELEASE(Disk->lFAT);\r
                return 0;\r
        \r
        append:\r
                switch(Disk->type)\r
                {\r
                case FAT12:     eoc = EOC_FAT12;        break;\r
                case FAT16:     eoc = EOC_FAT16;        break;\r
                case FAT32:     eoc = EOC_FAT32;        break;\r
                default:        return 0;\r
                }\r
                \r
                Disk->FATCache[ret] = eoc;\r
                Disk->FATCache[Previous] = ret;\r
                \r
                RELEASE(Disk->lFAT);\r
                return ret;\r
        }\r
        else\r
        {\r
        #endif\r
                Uint32  val;\r
                Uint32  ofs = Disk->bootsect.resvSectCount*512;\r
                Log_Warning("FAT", "TODO: Implement cluster allocation with non cached FAT");\r
                return 0;\r
                \r
                switch(Disk->type)\r
                {\r
                case FAT12:\r
                        VFS_ReadAt(Disk->fileHandle, ofs+(Previous>>1)*3, 3, &val);\r
                        if( Previous & 1 ) {\r
                                val &= 0xFFF000;\r
                                val |= ret;\r
                        }\r
                        else {\r
                                val &= 0xFFF;\r
                                val |= ret<<12;\r
                        }\r
                        VFS_WriteAt(Disk->fileHandle, ofs+(Previous>>1)*3, 3, &val);\r
                        \r
                        VFS_ReadAt(Disk->fileHandle, ofs+(ret>>1)*3, 3, &val);\r
                        if( Cluster & 1 ) {\r
                                val &= 0xFFF000;\r
                                val |= eoc;\r
                        }\r
                        else {\r
                                val &= 0x000FFF;\r
                                val |= eoc<<12;\r
                        }\r
                        VFS_WriteAt(Disk->fileHandle, ofs+(ret>>1)*3, 3, &val);\r
                        break;\r
                case FAT16:\r
                        VFS_ReadAt(Disk->fileHandle, ofs+Previous*2, 2, &ret);\r
                        VFS_WriteAt(Disk->fileHandle, ofs+ret*2, 2, &eoc);\r
                        break;\r
                case FAT32:\r
                        VFS_ReadAt(Disk->fileHandle, ofs+Previous*4, 4, &ret);\r
                        VFS_WriteAt(Disk->fileHandle, ofs+ret*4, 4, &eoc);\r
                        break;\r
                }\r
                return ret;\r
        #if CACHE_FAT\r
        }\r
        #endif\r
}\r
\r
/**\r
 * \brief Free's a cluster\r
 * \return The original contents of the cluster\r
 */\r
Uint32 FAT_int_FreeCluster(tFAT_VolInfo *Disk, Uint32 Cluster)\r
{\r
        Uint32  ret;\r
        #if CACHE_FAT\r
        if( Disk->ClusterCount <= giFAT_MaxCachedClusters )\r
        {\r
                LOCK(Disk->lFAT);\r
                \r
                ret = Disk->FATCache[Cluster];\r
                Disk->FATCache[Cluster] = 0;\r
                \r
                RELEASE(Disk->lFAT);\r
        }\r
        else\r
        {\r
        #endif\r
                Uint32  val;\r
                Uint32  ofs = Disk->bootsect.resvSectCount*512;\r
                LOCK(Disk->lFAT);\r
                switch(Disk->type)\r
                {\r
                case FAT12:\r
                        VFS_ReadAt(Disk->fileHandle, ofs+(Cluster>>1)*3, 3, &val);\r
                        if( Cluster & 1 ) {\r
                                ret = val & 0xFFF0000;\r
                                val &= 0xFFF;\r
                        }\r
                        else {\r
                                ret = val & 0xFFF;\r
                                val &= 0xFFF000;\r
                        }\r
                        VFS_WriteAt(Disk->fileHandle, ofs+(Previous>>1)*3, 3, &val);\r
                        break;\r
                case FAT16:\r
                        VFS_ReadAt(Disk->fileHandle, ofs+Previous*2, 2, &ret);\r
                        val = 0;\r
                        VFS_WriteAt(Disk->fileHandle, ofs+Cluster*2, 2, &val);\r
                        break;\r
                case FAT32:\r
                        VFS_ReadAt(Disk->fileHandle, ofs+Previous*4, 4, &ret);\r
                        val = 0;\r
                        VFS_WriteAt(Disk->fileHandle, ofs+Cluster*2, 2, &val);\r
                        break;\r
                }\r
                RELEASE(Disk->lFAT);\r
        #if CACHE_FAT\r
        }\r
        #endif\r
        if(Disk->type == FAT12 && ret == EOC_FAT12)     ret = -1;\r
        if(Disk->type == FAT16 && ret == EOC_FAT16)     ret = -1;\r
        if(Disk->type == FAT32 && ret == EOC_FAT32)     ret = -1;\r
        return ret;\r
}\r
#endif\r
\r
/*\r
 * ====================\r
 *      Cluster IO\r
 * ====================\r
 */\r
/**\r
 * \brief Read a cluster\r
 * \param Disk  Disk (Volume) to read from\r
 * \param Length        Length to read\r
 * \param Buffer        Destination for read data\r
 */\r
void FAT_int_ReadCluster(tFAT_VolInfo *Disk, Uint32 Cluster, int Length, void *Buffer)\r
{\r
        ENTER("pDisk xCluster iLength pBuffer", Disk, Cluster, Length, Buffer);\r
        VFS_ReadAt(\r
                Disk->fileHandle,\r
                (Disk->firstDataSect + (Cluster-2)*Disk->bootsect.spc )\r
                        * Disk->bootsect.bps,\r
                Length,\r
                Buffer\r
                );\r
        LEAVE('-');\r
}\r
\r
/* ====================\r
 *       File IO\r
 * ====================\r
 */\r
/**\r
 * \fn Uint64 FAT_Read(tVFS_Node *node, Uint64 offset, Uint64 length, void *buffer)\r
 * \brief Reads data from a specified file\r
 */\r
Uint64 FAT_Read(tVFS_Node *Node, Uint64 Offset, Uint64 Length, void *Buffer)\r
{\r
         int    preSkip, count;\r
         int    i, cluster, pos;\r
        tFAT_VolInfo    *disk = Node->ImplPtr;\r
        char    tmpBuf[disk->BytesPerCluster];\r
         int    bpc = disk->BytesPerCluster;\r
        \r
        ENTER("pNode Xoffset Xlength pbuffer", Node, Offset, Length, Buffer);\r
        \r
        // Sanity Check offset\r
        if(Offset > Node->Size) {\r
                LOG("Reading past EOF (%i > %i)", Offset, Node->Size);\r
                LEAVE('i', 0);\r
                return 0;\r
        }\r
        \r
        // Cluster is stored in the low 32-bits of the Inode field\r
        cluster = Node->Inode & 0xFFFFFFFF;\r
        \r
        // Clamp Size\r
        if(Offset >= Node->Size || Offset + Length > Node->Size) {\r
                LOG("Reading past EOF (%lli + %lli > %lli), clamped to %lli",\r
                        Offset, Length, Node->Size, Node->Size - Offset);\r
                Length = Node->Size - Offset;\r
        }\r
        \r
        // Reading from within the first cluster only?\r
        if((int)Offset + (int)Length < bpc)\r
        {\r
                LOG("First cluster only");\r
                FAT_int_ReadCluster(disk, cluster, bpc, tmpBuf);\r
                memcpy( Buffer, (void*)( tmpBuf + Offset%bpc ), Length );\r
                #if DEBUG\r
                //Debug_HexDump("FAT_Read", Buffer, Length);\r
                #endif\r
                LEAVE('i', 1);\r
                return Length;\r
        }\r
        \r
        // Skip previous clusters\r
        preSkip = Offset / bpc;\r
        for(i = preSkip; i--; ) {\r
                cluster = FAT_int_GetFatValue(disk, cluster);\r
                if(cluster == -1) {\r
                        Log_Warning("FAT", "Offset is past end of cluster chain mark");\r
                        LEAVE('i', 0);\r
                        return 0;\r
                }\r
        }\r
        \r
        // Get Count of Clusters to read\r
        count = ((Offset%bpc + Length) / bpc) + 1;\r
        \r
        // Get buffer Position after 1st cluster\r
        pos = bpc - Offset%bpc;\r
        \r
        // Read 1st Cluster (performs alignment for us)\r
        if( pos == bpc && (int)Length >= bpc ) {\r
                FAT_int_ReadCluster(disk, cluster, bpc, Buffer);\r
        }\r
        else {\r
                FAT_int_ReadCluster(disk, cluster, bpc, tmpBuf);\r
                memcpy(\r
                        Buffer,\r
                        (void*)( tmpBuf + (bpc-pos) ),\r
                        (pos < (int)Length ? (Uint)pos : Length)\r
                        );\r
        }\r
        \r
        // Simple return\r
        if( count == 1 ) {\r
                #if DEBUG\r
                //Debug_HexDump("FAT_Read", Buffer, Length);\r
                #endif\r
                LEAVE('i', 1);\r
                return Length;\r
        }\r
        \r
        #if DEBUG\r
        LOG("pos = %i", pos);\r
        LOG("Reading the rest of the clusters");\r
        #endif\r
        \r
        // Read the rest of the cluster data\r
        for( i = 1; i < count-1; i++ )\r
        {\r
                // Get next cluster in the chain\r
                cluster = FAT_int_GetFatValue(disk, cluster);\r
                if(cluster == -1) {\r
                        Log_Warning("FAT", "FAT_Read: Read past End of Cluster Chain");\r
                        LEAVE('i', 0);\r
                        return 0;\r
                }\r
                // Read cluster\r
                FAT_int_ReadCluster(disk, cluster, bpc, (void*)(Buffer+pos));\r
                pos += bpc;\r
        }\r
        \r
        // Get next cluster in the chain\r
        cluster = FAT_int_GetFatValue(disk, cluster);\r
        if(cluster == -1) {\r
                Log_Warning("FAT", "FAT_Read: Read past End of Cluster Chain");\r
                LEAVE('i', 0);\r
                return 0;\r
        }\r
        \r
        // Read final cluster\r
        if( (int)Length - pos == bpc )\r
        {\r
                FAT_int_ReadCluster( disk, cluster, bpc, (void*)(Buffer+pos) );\r
        }\r
        else {\r
                FAT_int_ReadCluster( disk, cluster, bpc, tmpBuf );\r
                memcpy( (void*)(Buffer+pos), tmpBuf, Length-pos );\r
        }\r
        \r
        #if DEBUG\r
        LOG("Free tmpBuf(0x%x) and Return", tmpBuf);\r
        //Debug_HexDump("FAT_Read", Buffer, Length);\r
        #endif\r
        \r
        LEAVE('X', Length);\r
        return Length;\r
}\r
\r
#if SUPPORT_WRITE\r
/**\r
 * \brief Write a cluster to disk\r
 */\r
void FAT_int_WriteCluster(tFAT_VolInfo *Disk, Uint32 Cluster, void *Buffer)\r
{\r
        ENTER("pDisk xCluster pBuffer", Disk, Cluster, Buffer);\r
        VFS_ReadAt(\r
                Disk->fileHandle,\r
                (Disk->firstDataSect + (Cluster-2)*Disk->bootsect.spc )\r
                        * Disk->bootsect.bps,\r
                Disk->BytesPerCluster,\r
                Buffer\r
                );\r
        LEAVE('-');\r
}\r
\r
/**\r
 * \brief Write to a file\r
 * \param Node  File Node\r
 * \param Offset        Offset within file\r
 * \param Length        Size of data to write\r
 * \param Buffer        Data source\r
 */\r
Uint64 FAT_Write(tVFS_Node *Node, Uint64 Offset, Uint64 Length, void *Buffer)\r
{\r
        tFAT_VolInfo    *disk = Node->ImplPtr;\r
        char    tmpBuf[disk->BytesPerCluster];\r
         int    remLength = Length;\r
        Uint32  cluster, tmpCluster;\r
         int    bNewCluster = 0;\r
        \r
        if(Offset > Node->Size) return 0;\r
        \r
        // Seek Clusters\r
        cluster = Node->Inode & 0xFFFFFFFF;\r
        while( Offset > disk->BytesPerCluster )\r
        {\r
                cluster = FAT_int_GetFatValue( disk, cluster );\r
                if(cluster == -1) {\r
                        Log_Warning("FAT", "EOC Unexpectedly Reached");\r
                        return 0;\r
                }\r
                Offset -= disk->BytesPerCluster;\r
        }\r
        if( Offset == disk->BytesPerCluster )\r
        {\r
                Uint32  tmp = FAT_int_AllocateCluster(disk, cluster);\r
                if(!tmp)        return 0;\r
                cluster = tmp;\r
                Offset -= disk->BytesPerCluster;\r
        }\r
        \r
        if( Offset + Length < disk->BytesPerCluster )\r
        {\r
                char    tmpBuf[disk->BytesPerCluster];\r
                \r
                // Read-Modify-Write\r
                FAT_int_ReadCluster( disk, cluster, disk->BytesPerCluster, tmpBuf );\r
                memcpy( tmpBuf + Offset, Buffer, Length );\r
                FAT_int_WriteCluster( disk, cluster, tmpBuf );\r
                \r
                return Length;\r
        }\r
        \r
        // Clean up changes within a cluster\r
        if( Offset )\r
        {       \r
                // Read-Modify-Write\r
                FAT_int_ReadCluster( disk, cluster, disk->BytesPerCluster, tmpBuf );\r
                memcpy( tmpBuf + Offset, Buffer, disk->BytesPerCluster - Offset );\r
                FAT_int_WriteCluster( disk, cluster, tmpBuf );\r
                \r
                remLength -= disk->BytesPerCluster - Offset;\r
                Buffer += disk->BytesPerCluster - Offset;\r
                \r
                // Get next cluster (allocating if needed)\r
                tmpCluster = FAT_int_GetFatValue(disk, cluster);\r
                if(tmpCluster == -1) {\r
                        tmpCluster = FAT_int_AllocateCluster(disk, cluster);\r
                        if( tmpCluster == 0 ) {\r
                                return Length - remLength;\r
                        }\r
                }\r
                cluster = tmpCluster;\r
        }\r
        \r
        while( remLength > disk->BytesPerCluster )\r
        {\r
                FAT_int_WriteCluster( disk, cluster, Buffer );\r
                Buffer += disk->BytesPerCluster;\r
                \r
                // Get next cluster (allocating if needed)\r
                tmpCluster = FAT_int_GetFatValue(disk, cluster);\r
                if(tmpCluster == -1) {\r
                        bNewCluster = 1;\r
                        tmpCluster = FAT_int_AllocateCluster(disk, cluster);\r
                        if( tmpCluster == 0 ) {\r
                                return Length - remLength;\r
                        }\r
                }\r
                cluster = tmpCluster;\r
        }\r
        \r
        // Finish off\r
        tmpBuf = malloc( disk->BytesPerCluster );\r
        if( bNewCluster )\r
                memset(tmpBuf, 0, disk->BytesPerCluster);\r
        else\r
                FAT_int_ReadCluster( disk, cluster, disk->BytesPerCluster, tmpBuf );\r
        memcpy( tmpBuf, Buffer, remLength );\r
        FAT_int_WriteCluster( disk, cluster, tmpBuf );\r
        free( tmpBuf );\r
        \r
        return Length;\r
}\r
#endif\r
\r
/* ====================\r
 *  File Names & Nodes\r
 * ====================\r
 */\r
/**\r
 * \brief Converts a FAT directory entry name into a proper filename\r
 * \param dest  Destination array (must be at least 13 bytes in size)\r
 * \param src   8.3 filename (concatenated, e.g 'FILE1   TXT')\r
 */\r
void FAT_int_ProperFilename(char *dest, const char *src)\r
{\r
         int    inpos, outpos;\r
        \r
        // Name\r
        outpos = 0;\r
        for( inpos = 0; inpos < 8; inpos++ ) {\r
                if(src[inpos] == ' ')   break;\r
                dest[outpos++] = src[inpos];\r
        }\r
        inpos = 8;\r
        // Check for empty extensions\r
        if(src[8] != ' ')\r
        {\r
                dest[outpos++] = '.';\r
                for( ; inpos < 11; inpos++)     {\r
                        if(src[inpos] == ' ')   break;\r
                        dest[outpos++] = src[inpos];\r
                }\r
        }\r
        dest[outpos++] = '\0';\r
        \r
        //LOG("dest='%s'", dest);\r
}\r
\r
/**\r
 * \fn char *FAT_int_CreateName(fat_filetable *ft, char *LongFileName)\r
 * \brief Converts either a LFN or a 8.3 Name into a proper name\r
 * \param ft    Pointer to the file's entry in the parent directory\r
 * \param LongFileName  Long file name pointer\r
 * \return Filename as a heap string\r
 */\r
char *FAT_int_CreateName(fat_filetable *ft, char *LongFileName)\r
{\r
        char    *ret;\r
        ENTER("pft sLongFileName", ft, LongFileName);\r
        //Log_Debug("FAT", "FAT_int_CreateName(ft=%p, LongFileName=%p'%s')", ft, LongFileName);\r
        #if USE_LFN\r
        if(LongFileName && LongFileName[0] != '\0')\r
        {       \r
                ret = strdup(LongFileName);\r
        }\r
        else\r
        {\r
        #endif\r
                ret = (char*) malloc(13);\r
                if( !ret ) {\r
                        Log_Warning("FAT", "FAT_int_CreateName: malloc(13) failed");\r
                        return NULL;\r
                }\r
                FAT_int_ProperFilename(ret, ft->name);\r
        #if USE_LFN\r
        }\r
        #endif\r
        LEAVE('s', ret);\r
        return ret;\r
}\r
\r
/**\r
 * \brief Creates a tVFS_Node structure for a given file entry\r
 * \param Parent        Parent directory VFS node\r
 * \param Entry File table entry for the new node\r
 * \param Pos   Position in the parent of the new node\r
 */\r
tVFS_Node *FAT_int_CreateNode(tVFS_Node *Parent, fat_filetable *Entry, int Pos)\r
{\r
        tVFS_Node       node;\r
        tVFS_Node       *ret;\r
        tFAT_VolInfo    *disk = Parent->ImplPtr;\r
        \r
        ENTER("pParent pFT", Parent, Entry);\r
        LOG("disk = %p", disk);\r
        \r
        memset(&node, 0, sizeof(tVFS_Node));\r
        \r
        // Set Other Data\r
        // 0-27: Cluster, 32-59: Parent Cluster\r
        node.Inode = Entry->cluster | (Entry->clusterHi<<16) | (Parent->Inode << 32);\r
        LOG("node.Inode = %llx", node.Inode);\r
        // Position in parent directory\r
        node.ImplInt = Pos & 0xFFFF;\r
        // Disk Pointer\r
        node.ImplPtr = disk;\r
        node.Size = Entry->size;\r
        LOG("Entry->size = %i", Entry->size);\r
        // root:root\r
        node.UID = 0;   node.GID = 0;\r
        node.NumACLs = 1;\r
        \r
        node.Flags = 0;\r
        if(Entry->attrib & ATTR_DIRECTORY)      node.Flags |= VFS_FFLAG_DIRECTORY;\r
        if(Entry->attrib & ATTR_READONLY) {\r
                node.Flags |= VFS_FFLAG_READONLY;\r
                node.ACLs = &gVFS_ACL_EveryoneRX;       // R-XR-XR-X\r
        }\r
        else {\r
                node.ACLs = &gVFS_ACL_EveryoneRWX;      // RWXRWXRWX\r
        }\r
        \r
        // Create timestamps\r
        node.ATime = timestamp(0,0,0,\r
                        ((Entry->adate&0x1F) - 1),      // Days\r
                        ((Entry->adate&0x1E0) - 1),     // Months\r
                        1980+((Entry->adate&0xFF00)>>8) // Years\r
                        );\r
        \r
        node.CTime = Entry->ctimems * 10;       // Miliseconds\r
        node.CTime += timestamp(\r
                        ((Entry->ctime&0x1F)<<1),       // Seconds\r
                        ((Entry->ctime&0x3F0)>>5),      // Minutes\r
                        ((Entry->ctime&0xF800)>>11),    // Hours\r
                        ((Entry->cdate&0x1F)-1),                // Days\r
                        ((Entry->cdate&0x1E0)-1),               // Months\r
                        1980+((Entry->cdate&0xFF00)>>8) // Years\r
                        );\r
                        \r
        node.MTime = timestamp(\r
                        ((Entry->mtime&0x1F)<<1),       // Seconds\r
                        ((Entry->mtime&0x3F0)>>5),      // Minutes\r
                        ((Entry->mtime&0xF800)>>11),    // Hours\r
                        ((Entry->mdate&0x1F)-1),                // Days\r
                        ((Entry->mdate&0x1E0)-1),               // Months\r
                        1980+((Entry->mdate&0xFF00)>>8) // Years\r
                        );\r
        \r
        // Set pointers\r
        if(node.Flags & VFS_FFLAG_DIRECTORY) {\r
                //Log_Debug("FAT", "Directory %08x has size 0x%x", node.Inode, node.Size);\r
                node.ReadDir = FAT_ReadDir;\r
                node.FindDir = FAT_FindDir;\r
                #if SUPPORT_WRITE\r
                node.MkNod = FAT_Mknod;\r
                node.Relink = FAT_Relink;\r
                #endif\r
                node.Size = -1;\r
        }\r
        else {\r
                node.Read = FAT_Read;\r
                #if SUPPORT_WRITE\r
                node.Write = FAT_Write;\r
                #endif\r
        }\r
        node.Close = FAT_CloseFile;\r
        \r
        ret = Inode_CacheNode(disk->inodeHandle, &node);\r
        LEAVE('p', ret);\r
        return ret;\r
}\r
\r
/* \r
 * ====================\r
 *     Directory IO\r
 * ====================\r
 */\r
\r
/**\r
 * \brief Reads a sector from the disk\r
 * \param Node  Directory node to read\r
 * \param Sector        Sector number in the directory to read\r
 * \param Buffer        Destination buffer for the read data\r
 */\r
int FAT_int_ReadDirSector(tVFS_Node *Node, int Sector, fat_filetable *Buffer)\r
{\r
        Uint64  addr;\r
        tFAT_VolInfo    *disk = Node->ImplPtr;\r
        \r
        ENTER("pNode iSector pEntry", Node, Sector, Buffer);\r
        \r
        // Parse address\r
        if(FAT_int_GetAddress(Node, Sector * 512, &addr, NULL))\r
        {\r
                LEAVE('i', 1);\r
                return 1;\r
        }\r
        \r
        LOG("addr = 0x%llx", addr);\r
        // Read Sector\r
        if(VFS_ReadAt(disk->fileHandle, addr, 512, Buffer) != 512)\r
        {\r
                LEAVE('i', 1);\r
                return 1;\r
        }\r
        \r
        LEAVE('i', 0);\r
        return 0;\r
}\r
\r
#if SUPPORT_WRITE\r
/**\r
 * \brief Writes an entry to the disk\r
 * \todo Support expanding a directory\r
 * \param Node  Directory node\r
 * \param ID    ID of entry to update\r
 * \param Entry Entry data\r
 * \return Zero on success, non-zero on error\r
 */\r
int FAT_int_WriteDirEntry(tVFS_Node *Node, int ID, fat_filetable *Entry)\r
{\r
        Uint64  addr = 0;\r
         int    tmp;\r
        Uint32  cluster = 0;\r
        tFAT_VolInfo    *disk = Node->ImplPtr;\r
        \r
        ENTER("pNode iID pEntry", Node, ID, Entry);\r
        \r
        tmp = FAT_int_GetAddress(Node, ID * sizeof(fat_filetable), &addr, &cluster);\r
        if( tmp )\r
        {\r
                //TODO: Allocate a cluster\r
                cluster = FAT_int_AllocateCluster(Node->ImplPtr, cluster);\r
                if(cluster == -1) {\r
                        Log_Warning("FAT", "Unable to allocate an other cluster for %p", Node);\r
                        LEAVE('i', 1);\r
                        return 1;\r
                }\r
                FAT_int_GetAddress(Node, ID * sizeof(fat_filetable), &addr, &cluster);\r
        }\r
        \r
\r
        LOG("addr = 0x%llx", addr);\r
        \r
        // Read Sector\r
        VFS_WriteAt(disk->fileHandle, addr, sizeof(fat_filetable), Entry);      // Read Dir Data\r
        \r
        LEAVE('i', 0);\r
        return 0;\r
}\r
#endif\r
\r
#if USE_LFN     \r
/**\r
 * \fn char *FAT_int_GetLFN(tVFS_Node *node)\r
 * \brief Return pointer to LFN cache entry\r
 * \param Node  Directory node\r
 * \param ID    ID of the short name\r
 * \return Pointer to the LFN cache entry\r
 */\r
char *FAT_int_GetLFN(tVFS_Node *Node, int ID)\r
{\r
        tFAT_LFNCache   *cache;\r
         int    i, firstFree;\r
        \r
        Mutex_Acquire( &Node->Lock );\r
        \r
        // TODO: Thread Safety (Lock things)\r
        cache = Node->Data;\r
        \r
        // Create a cache if it isn't there\r
        if(!cache) {\r
                cache = Node->Data = malloc( sizeof(tFAT_LFNCache) + sizeof(tFAT_LFNCacheEnt) );\r
                cache->NumEntries = 1;\r
                cache->Entries[0].ID = ID;\r
                cache->Entries[0].Data[0] = '\0';\r
                Mutex_Release( &Node->Lock );\r
                //Log_Debug("FAT", "Return = %p (new)", cache->Entries[0].Data);\r
                return cache->Entries[0].Data;\r
        }\r
        \r
        // Scan for this entry\r
        firstFree = -1;\r
        for( i = 0; i < cache->NumEntries; i++ )\r
        {\r
                if( cache->Entries[i].ID == ID ) {\r
                        Mutex_Release( &Node->Lock );\r
                        //Log_Debug("FAT", "Return = %p (match)", cache->Entries[i].Data);\r
                        return cache->Entries[i].Data;\r
                }\r
                if( cache->Entries[i].ID == -1 && firstFree == -1 )\r
                        firstFree = i;\r
        }\r
        \r
        if(firstFree == -1) {\r
                // Use `i` for temp length\r
                i = sizeof(tFAT_LFNCache) + (cache->NumEntries+1)*sizeof(tFAT_LFNCacheEnt);\r
                Node->Data = realloc( Node->Data, i );\r
                if( !Node->Data ) {\r
                        Log_Error("FAT", "realloc() fail, unable to allocate %i for LFN cache", i);\r
                        Mutex_Release( &Node->Lock );\r
                        return NULL;\r
                }\r
                //Log_Debug("FAT", "Realloc (%i)\n", i);\r
                cache = Node->Data;\r
                i = cache->NumEntries;\r
                cache->NumEntries ++;\r
        }\r
        else {\r
                i = firstFree;\r
        }\r
        \r
        // Create new entry\r
        cache->Entries[ i ].ID = ID;\r
        cache->Entries[ i ].Data[0] = '\0';\r
        \r
        Mutex_Release( &Node->Lock );\r
        //Log_Debug("FAT", "Return = %p (firstFree, i = %i)", cache->Entries[i].Data, i);\r
        return cache->Entries[ i ].Data;\r
}\r
\r
/**\r
 * \fn void FAT_int_DelLFN(tVFS_Node *node)\r
 * \brief Delete a LFN cache entry\r
 * \param Node  Directory node\r
 * \param ID    File Entry ID\r
 */\r
void FAT_int_DelLFN(tVFS_Node *Node, int ID)\r
{\r
        tFAT_LFNCache   *cache = Node->Data;\r
         int    i;\r
        \r
        // Fast return\r
        if(!cache)      return;\r
        \r
        // Scan for a current entry\r
        for( i = 0; i < cache->NumEntries; i++ )\r
        {\r
                if( cache->Entries[i].ID == ID )\r
                        cache->Entries[i].ID = -1;\r
        }\r
        return ;\r
}\r
#endif\r
\r
/**\r
 * \fn char *FAT_ReadDir(tVFS_Node *Node, int ID)\r
 * \param Node  Node structure of directory\r
 * \param ID    Directory position\r
 * \return Filename as a heap string, NULL or VFS_SKIP\r
 */\r
char *FAT_ReadDir(tVFS_Node *Node, int ID)\r
{\r
        fat_filetable   fileinfo[16];   // sizeof(fat_filetable)=32, so 16 per sector\r
         int    a = 0;\r
        char    *ret;\r
        #if USE_LFN\r
        char    *lfn = NULL;\r
        #endif\r
        \r
        ENTER("pNode iID", Node, ID);\r
        \r
        if(FAT_int_ReadDirSector(Node, ID/16, fileinfo))\r
        {\r
                LOG("End of chain, end of dir");\r
                LEAVE('n');\r
                return NULL;\r
        }\r
        \r
        // Offset in sector\r
        a = ID % 16;\r
\r
        LOG("fileinfo[%i].name[0] = 0x%x", a, (Uint8)fileinfo[a].name[0]);\r
        \r
        // Check if this is the last entry\r
        if( fileinfo[a].name[0] == '\0' ) {\r
                Node->Size = ID;\r
                LOG("End of list");\r
                LEAVE('n');\r
                return NULL;    // break\r
        }\r
        \r
        // Check for empty entry\r
        if( (Uint8)fileinfo[a].name[0] == 0xE5 ) {\r
                LOG("Empty Entry");\r
                #if 0   // Stop on empty entry?\r
                LEAVE('n');\r
                return NULL;    // Stop\r
                #else\r
                LEAVE('p', VFS_SKIP);\r
                return VFS_SKIP;        // Skip\r
                #endif\r
        }\r
        \r
        #if USE_LFN\r
        // Get Long File Name Cache\r
        if(fileinfo[a].attrib == ATTR_LFN)\r
        {\r
                fat_longfilename        *lfnInfo;\r
                \r
                lfnInfo = (fat_longfilename *) &fileinfo[a];\r
                \r
                // Get cache for corresponding file\r
                // > ID + Index gets the corresponding short node\r
                lfn = FAT_int_GetLFN( Node, ID + (lfnInfo->id & 0x3F) );\r
                \r
                // Bit 6 indicates the start of an entry\r
                if(lfnInfo->id & 0x40)  memset(lfn, 0, 256);\r
                \r
                a = ((lfnInfo->id & 0x3F) - 1) * 13;\r
                //Log_Debug("FAT", "ID = 0x%02x, a = %i", lfnInfo->id, a);\r
                \r
                // Sanity Check (FAT implementations should not allow >255 character names)\r
                if(a > 255)     return VFS_SKIP;\r
                \r
                // Append new bytes\r
                lfn[a+ 0] = lfnInfo->name1[0];  lfn[a+ 1] = lfnInfo->name1[1];\r
                lfn[a+ 2] = lfnInfo->name1[2];  lfn[a+ 3] = lfnInfo->name1[3];\r
                lfn[a+ 4] = lfnInfo->name1[4];  \r
                lfn[a+ 5] = lfnInfo->name2[0];  lfn[a+ 6] = lfnInfo->name2[1];\r
                lfn[a+ 7] = lfnInfo->name2[2];  lfn[a+ 8] = lfnInfo->name2[3];\r
                lfn[a+ 9] = lfnInfo->name2[4];  lfn[a+10] = lfnInfo->name2[5];\r
                lfn[a+11] = lfnInfo->name3[0];  lfn[a+12] = lfnInfo->name3[1];\r
                LOG("lfn = '%s'", lfn);\r
                //Log_Debug("FAT", "lfn = '%s'", lfn);\r
                LEAVE('p', VFS_SKIP);\r
                return VFS_SKIP;\r
        }\r
        #endif\r
        \r
        // Check if it is a volume entry\r
        if(fileinfo[a].attrib & 0x08) {\r
                LEAVE('p', VFS_SKIP);\r
                return VFS_SKIP;\r
        }\r
        // Ignore .\r
        if(fileinfo[a].name[0] == '.' && fileinfo[a].name[1] == ' ') {\r
                LEAVE('p', VFS_SKIP);\r
                return VFS_SKIP;\r
        }\r
        // and ..\r
        if(fileinfo[a].name[0] == '.' && fileinfo[a].name[1] == '.' && fileinfo[a].name[2] == ' ') {\r
                LEAVE('p', VFS_SKIP);\r
                return VFS_SKIP;\r
        }\r
        \r
        LOG("name='%c%c%c%c%c%c%c%c.%c%c%c'",\r
                fileinfo[a].name[0], fileinfo[a].name[1], fileinfo[a].name[2], fileinfo[a].name[3],\r
                fileinfo[a].name[4], fileinfo[a].name[5], fileinfo[a].name[6], fileinfo[a].name[7],\r
                fileinfo[a].name[8], fileinfo[a].name[9], fileinfo[a].name[10] );\r
        \r
        #if USE_LFN\r
        lfn = FAT_int_GetLFN(Node, ID);\r
        //Log_Debug("FAT", "lfn = %p'%s'", lfn, lfn);\r
        ret = FAT_int_CreateName(&fileinfo[a], lfn);\r
        #else\r
        ret = FAT_int_CreateName(&fileinfo[a], NULL);\r
        #endif\r
        \r
        LEAVE('s', ret);\r
        return ret;\r
}\r
\r
/**\r
 * \fn tVFS_Node *FAT_FindDir(tVFS_Node *node, char *name)\r
 * \brief Finds an entry in the current directory\r
 */\r
tVFS_Node *FAT_FindDir(tVFS_Node *Node, const char *Name)\r
{\r
        fat_filetable   fileinfo[16];\r
        char    tmpName[13];\r
        #if USE_LFN\r
        fat_longfilename        *lfnInfo;\r
        char    lfn[256];\r
         int    lfnPos=255, lfnId = -1;\r
        #endif\r
         int    i;\r
        tVFS_Node       *tmpNode;\r
        tFAT_VolInfo    *disk = Node->ImplPtr;\r
        Uint32  cluster;\r
        \r
        ENTER("pNode sname", Node, Name);\r
        \r
        // Fast Returns\r
        if(!Name || Name[0] == '\0') {\r
                LEAVE('n');\r
                return NULL;\r
        }\r
        \r
        for( i = 0; ; i++ )\r
        {\r
                if((i & 0xF) == 0) {\r
                        if(FAT_int_ReadDirSector(Node, i/16, fileinfo))\r
                        {\r
                                LEAVE('n');\r
                                return NULL;\r
                        }\r
                }\r
                \r
                //Check if the files are free\r
                if(fileinfo[i&0xF].name[0] == '\0')     break;  // End of List marker\r
                if(fileinfo[i&0xF].name[0] == '\xE5')   continue;       // Free entry\r
                \r
                \r
                #if USE_LFN\r
                // Long File Name Entry\r
                if(fileinfo[i & 0xF].attrib == ATTR_LFN)\r
                {\r
                        lfnInfo = (fat_longfilename *) &fileinfo[i&0xF];\r
                        if(lfnInfo->id & 0x40) {\r
                                memset(lfn, 0, 256);\r
                                lfnPos = (lfnInfo->id & 0x3F) * 13 - 1;\r
                        }\r
                        // Sanity check the position so we don't overflow\r
                        if( lfnPos < 12 )\r
                                continue ;\r
                        lfn[lfnPos--] = lfnInfo->name3[1];      lfn[lfnPos--] = lfnInfo->name3[0];\r
                        lfn[lfnPos--] = lfnInfo->name2[5];      lfn[lfnPos--] = lfnInfo->name2[4];\r
                        lfn[lfnPos--] = lfnInfo->name2[3];      lfn[lfnPos--] = lfnInfo->name2[2];\r
                        lfn[lfnPos--] = lfnInfo->name2[1];      lfn[lfnPos--] = lfnInfo->name2[0];\r
                        lfn[lfnPos--] = lfnInfo->name1[4];      lfn[lfnPos--] = lfnInfo->name1[3];\r
                        lfn[lfnPos--] = lfnInfo->name1[2];      lfn[lfnPos--] = lfnInfo->name1[1];\r
                        lfn[lfnPos--] = lfnInfo->name1[0];\r
                        if((lfnInfo->id&0x3F) == 1)\r
                        {\r
                                lfnId = i+1;\r
                        }\r
                }\r
                else\r
                {\r
                        // Remove LFN if it does not apply\r
                        if(lfnId != i)  lfn[0] = '\0';\r
                #else\r
                if(fileinfo[i&0xF].attrib == ATTR_LFN)  continue;\r
                #endif\r
                        // Get Real Filename\r
                        FAT_int_ProperFilename(tmpName, fileinfo[i&0xF].name);\r
                        LOG("tmpName = '%s'", tmpName);\r
                \r
                        // Only the long name is case sensitive, 8.3 is not\r
                        #if USE_LFN\r
                        if(strucmp(tmpName, Name) == 0 || strcmp(lfn, Name) == 0)\r
                        #else\r
                        if(strucmp(tmpName, Name) == 0)\r
                        #endif\r
                        {\r
                                cluster = fileinfo[i&0xF].cluster | (fileinfo[i&0xF].clusterHi << 16);\r
                                tmpNode = Inode_GetCache(disk->inodeHandle, cluster);\r
                                if(tmpNode == NULL)     // Node is not cached\r
                                {\r
                                        tmpNode = FAT_int_CreateNode(Node, &fileinfo[i&0xF], i);\r
                                }\r
                                LEAVE('p', tmpNode);\r
                                return tmpNode;\r
                        }\r
                #if USE_LFN\r
                }\r
                #endif\r
        }\r
        \r
        LEAVE('n');\r
        return NULL;\r
}\r
\r
tVFS_Node *FAT_GetNodeFromINode(tVFS_Node *Root, Uint64 Inode)\r
{\r
        tFAT_VolInfo    *disk = Root->ImplPtr;\r
         int    ents_per_sector = 512 / sizeof(fat_filetable); \r
        fat_filetable   fileinfo[ents_per_sector];\r
         int    sector = 0, i;\r
        tVFS_Node       stub_node;\r
\r
        ENTER("pRoot XInode", Root, Inode);\r
\r
        stub_node.ImplPtr = disk;\r
        stub_node.Size = -1;\r
        stub_node.Inode = Inode >> 32;\r
\r
        for( i = 0; ; i ++ )\r
        {\r
                if( i == 0 || i == ents_per_sector )\r
                {\r
                        if(FAT_int_ReadDirSector(&stub_node, sector, fileinfo))\r
                        {\r
                                LOG("ReadDirSector failed");\r
                                LEAVE('n');\r
                                return NULL;\r
                        }\r
                        i = 0;\r
                        sector ++;\r
                }\r
        \r
                // Check for free/end of list\r
                if(fileinfo[i].name[0] == '\0') break;  // End of List marker\r
                if(fileinfo[i].name[0] == '\xE5')       continue;       // Free entry\r
                \r
                if(fileinfo[i].attrib == ATTR_LFN)      continue;\r
\r
                LOG("fileinfo[i].cluster = %x %04x", fileinfo[i].clusterHi, fileinfo[i].cluster);\r
                #if DEBUG\r
                {\r
                        char    tmpName[13];\r
                        FAT_int_ProperFilename(tmpName, fileinfo[i].name);\r
                        LOG("tmpName = '%s'", tmpName);\r
                }\r
                #endif\r
                \r
        \r
                if(fileinfo[i].cluster != (Inode & 0xFFFF))     continue;\r
                if(fileinfo[i].clusterHi != ((Inode >> 16) & 0xFFFF))   continue;\r
\r
                LEAVE_RET('p', FAT_int_CreateNode(&stub_node, &fileinfo[i], sector*ents_per_sector+i));\r
        }\r
        LOG("sector = %i, i = %i", sector, i);\r
        LEAVE('n');\r
        return NULL;\r
}\r
\r
#if SUPPORT_WRITE\r
/**\r
 * \fn int FAT_Mknod(tVFS_Node *Node, char *Name, Uint Flags)\r
 * \brief Create a new node\r
 */\r
int FAT_Mknod(tVFS_Node *Node, char *Name, Uint Flags)\r
{\r
        return 0;\r
}\r
\r
/**\r
 * \fn int FAT_Relink(tVFS_Node *Node, char *OldName, char *NewName)\r
 * \brief Rename / Delete a file\r
 */\r
int FAT_Relink(tVFS_Node *Node, char *OldName, char *NewName)\r
{\r
        tVFS_Node       *child;\r
        fat_filetable   ft = {0};\r
         int    ret;\r
        \r
        child = FAT_FindDir(Node, OldName);\r
        if(!child)      return ENOTFOUND;\r
        \r
        // Delete?\r
        if( NewName == NULL )\r
        {\r
                child->ImplInt |= FAT_FLAG_DELETE;      // Mark for deletion on close\r
                \r
                // Delete from the directory\r
                ft.name[0] = '\xE9';\r
                FAT_int_WriteDirEntry(Node, child->ImplInt & 0xFFFF, &ft);\r
                \r
                // Return success\r
                ret = EOK;\r
        }\r
        // Rename\r
        else\r
        {\r
                Log_Warning("FAT", "Renaming no yet supported %p ('%s' => '%s')",\r
                        Node, OldName, NewName);\r
                ret = ENOTIMPL;\r
        }\r
        \r
        // Close child\r
        child->Close( child );\r
        return ret;\r
}\r
#endif\r
\r
/**\r
 * \fn void FAT_CloseFile(tVFS_Node *Node)\r
 * \brief Close an open file\r
 */\r
void FAT_CloseFile(tVFS_Node *Node)\r
{\r
        tFAT_VolInfo    *disk = Node->ImplPtr;\r
        if(Node == NULL)        return ;\r
        \r
        #if SUPPORT_WRITE\r
        // Update the node if it's dirty (don't bother if it's marked for\r
        // deletion)\r
        if( (Node->ImplInt & FAT_FLAG_DIRTY) && !(Node->ImplInt & FAT_FLAG_DELETE) )\r
        {\r
                tFAT_VolInfo    buf[16];\r
                tFAT_VolInfo    *ft = &buf[ (Node->ImplInt & 0xFFFF) % 16 ];\r
                \r
                FAT_int_ReadDirSector(Node, (Node->ImplInt & 0xFFFF)/16, buf);\r
                ft->size = Node->Size;\r
                // TODO: update adate, mtime, mdate\r
                FAT_int_WriteDirEntry(Node, Node->ImplInt & 0xFFFF, ft);\r
                \r
                Node->ImplInt &= ~FAT_FLAG_DIRTY;\r
        }\r
        #endif\r
        \r
        // TODO: Make this more thread safe somehow, probably by moving the\r
        // Inode_UncacheNode higher up and saving the cluster value somewhere\r
        if( Node->ReferenceCount == 1 )\r
        {               \r
                #if SUPPORT_WRITE\r
                // Delete File\r
                if( Node->ImplInt & FAT_FLAG_DELETE ) {\r
                        // Since the node is marked, we only need to remove it's data\r
                        Uint32  cluster = Node->Inode & 0xFFFFFFFF;\r
                        while( cluster != -1 )\r
                                cluster = FAT_int_FreeCluster(Node->ImplPtr, cluster);\r
                }\r
                #endif\r
        }\r
        \r
        Inode_UncacheNode(disk->inodeHandle, Node->Inode);\r
        return ;\r
}\r