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/*
 * fat.c
 *
 * Low-level operations on a volume with FAT filesystem
 *
 * Copyright (C) 2001 OKTET Ltd., St.-Petersburg, Russia
 * Author: Eugeny S. Mints <Eugeny.Mints@oktet.ru>
 *
 * @(#) $Id$
 */

#if HAVE_CONFIG_H
#include "config.h"
#endif

#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <unistd.h>
#include <errno.h>
#include <stdlib.h>
#include <assert.h>

#include <rtems/libio_.h>

#include "fat.h"
#include "fat_fat_operations.h"

/* _fat_block_read --
 *     This function reads 'count' bytes from device filesystem is mounted on,
 *     starts at 'start+offset' position where 'start' computed in sectors 
 *     and 'offset' is offset inside sector (reading may cross sectors 
 *     boundary; in this case assumed we want to read sequential sector(s))
 *
 * PARAMETERS:
 *     mt_entry - mount table entry
 *     start    - sector num to start read from
 *     offset   - offset inside sector 'start'
 *     count    - count of bytes to read
 *     buff     - buffer provided by user
 *
 * RETURNS:
 *     bytes read on success, or -1 if error occured
 *     and errno set appropriately
 */
ssize_t
_fat_block_read(
    rtems_filesystem_mount_table_entry_t *mt_entry, 
    unsigned32                            start, 
    unsigned32                            offset,
    unsigned32                            count, 
    void                                 *buff
    )
{
    int                     rc = RC_OK;
    register fat_fs_info_t *fs_info = mt_entry->fs_info;
    ssize_t                 cmpltd = 0;
    unsigned32              blk = start;
    unsigned32              ofs = offset;
    bdbuf_buffer           *block = NULL;
    unsigned32              c = 0;
  
    while (count > 0)
    {
        rc = fat_buf_access(fs_info, blk, FAT_OP_TYPE_READ, &block);
        if (rc != RC_OK)
            return rc;
    
        c = MIN(count, (fs_info->vol.bps - ofs));
        memcpy((buff + cmpltd), (block->buffer + ofs), c);

        count -= c;
        cmpltd += c;
        blk++;
        ofs = 0;
    }
    return cmpltd;
}

/* _fat_block_write --
 *     This function write 'count' bytes to device filesystem is mounted on, 
 *     starts at 'start+offset' position where 'start' computed in sectors 
 *     and 'offset' is offset inside sector (writing may cross sectors 
 *     boundary; in this case assumed we want to write sequential sector(s))
 *
 * PARAMETERS:
 *     mt_entry - mount table entry
 *     start    - sector num to start read from
 *     offset   - offset inside sector 'start'
 *     count    - count of bytes to write
 *     buff     - buffer provided by user
 *
 * RETURNS:
 *     bytes written on success, or -1 if error occured
 *     and errno set appropriately
 */
ssize_t
_fat_block_write(
    rtems_filesystem_mount_table_entry_t *mt_entry, 
    unsigned32                            start, 
    unsigned32                            offset,
    unsigned32                            count, 
    const void                           *buff)
{
    int            rc = RC_OK;
    fat_fs_info_t *fs_info = mt_entry->fs_info;
    ssize_t        cmpltd = 0;
    unsigned32     blk  = start;
    unsigned32     ofs = offset;
    bdbuf_buffer  *block = NULL;
    unsigned32     c = 0;
  
    while(count > 0)
    {
        c = MIN(count, (fs_info->vol.bps - ofs));

        if (c == fs_info->vol.bps)
            rc = fat_buf_access(fs_info, blk, FAT_OP_TYPE_GET, &block);
        else
            rc = fat_buf_access(fs_info, blk, FAT_OP_TYPE_READ, &block);
        if (rc != RC_OK)
            return rc;
    
        memcpy((block->buffer + ofs), (buff + cmpltd), c);

        fat_buf_mark_modified(fs_info);

        count -= c;
        cmpltd +=c;
        blk++;
        ofs = 0;
    }
    return cmpltd;
}




/* fat_cluster_read --
 *     wrapper for reading a whole cluster at once
 *
 * PARAMETERS:
 *     mt_entry - mount table entry
 *     cln      - number of cluster to read
 *     buff     - buffer provided by user
 *
 * RETURNS:
 *     bytes read on success, or -1 if error occured
 *     and errno set appropriately
 */
ssize_t 
fat_cluster_read(
    rtems_filesystem_mount_table_entry_t *mt_entry,
    unsigned32                            cln,
    void                                 *buff
    )
{
    fat_fs_info_t *fs_info = mt_entry->fs_info;
    unsigned32     fsec = 0; 
  
    fsec = fat_cluster_num_to_sector_num(mt_entry, cln); 

    return _fat_block_read(mt_entry, fsec, 0, 
                           fs_info->vol.spc << fs_info->vol.sec_log2, buff); 
}                 

/* fat_cluster_write --
 *     wrapper for writting a whole cluster at once
 *
 * PARAMETERS:
 *     mt_entry - mount table entry
 *     cln      - number of cluster to write
 *     buff     - buffer provided by user
 *
 * RETURNS:
 *     bytes written on success, or -1 if error occured
 *     and errno set appropriately
 */
ssize_t 
fat_cluster_write(
    rtems_filesystem_mount_table_entry_t *mt_entry,
    unsigned32                            cln,
    const void                           *buff
    )
{
    fat_fs_info_t *fs_info = mt_entry->fs_info;
    unsigned32     fsec = 0;
  
    fsec = fat_cluster_num_to_sector_num(mt_entry, cln); 
 
    return _fat_block_write(mt_entry, fsec, 0,
                          fs_info->vol.spc << fs_info->vol.sec_log2, buff); 
}                 

/* fat_init_volume_info --
 *     Get inforamtion about volume on which filesystem is mounted on
 *
 * PARAMETERS:
 *     mt_entry - mount table entry
 *
 * RETURNS:
 *     RC_OK on success, or -1 if error occured
 *     and errno set appropriately
 */
int
fat_init_volume_info(rtems_filesystem_mount_table_entry_t *mt_entry)
{
    int                 rc = RC_OK;
    fat_fs_info_t      *fs_info = mt_entry->fs_info;     
    register fat_vol_t *vol = &fs_info->vol;
    unsigned32          data_secs = 0;
    char                boot_rec[FAT_MAX_BPB_SIZE];
    char                fs_info_sector[FAT_USEFUL_INFO_SIZE];
    ssize_t             ret = 0;
    int                 fd;
    struct stat         stat_buf;
    int                 i = 0;

    rc = stat(mt_entry->dev, &stat_buf);
    if (rc == -1)
        return rc;

    /* rtmes feature: no block devices, all are character devices */   
    if (!S_ISCHR(stat_buf.st_mode))
        set_errno_and_return_minus_one(ENOTBLK);    

    /* check that  device is registred as block device and lock it */
    vol->dd = rtems_disk_lookup(stat_buf.st_dev);
    if (vol->dd == NULL) 
        set_errno_and_return_minus_one(ENOTBLK);
        
    vol->dev = stat_buf.st_dev;

    fd = open(mt_entry->dev, O_RDONLY);
    if (fd == -1)
    {
        rtems_disk_release(vol->dd);
        return -1;
    }    
  
    ret = read(fd, (void *)boot_rec, FAT_MAX_BPB_SIZE);
    if ( ret != FAT_MAX_BPB_SIZE )
    {
        close(fd);
        rtems_disk_release(vol->dd);
        set_errno_and_return_minus_one( EIO );
    }
    close(fd);

    vol->bps = FAT_BR_BYTES_PER_SECTOR(boot_rec);
 
    if ( (vol->bps != 512)  && 
         (vol->bps != 1024) && 
         (vol->bps != 2048) &&
         (vol->bps != 4096))
    {     
        rtems_disk_release(vol->dd);
        set_errno_and_return_minus_one( EINVAL );
    }    

    for (vol->sec_mul = 0, i = (vol->bps >> FAT_SECTOR512_BITS); (i & 1) == 0; 
         i >>= 1, vol->sec_mul++);
    for (vol->sec_log2 = 0, i = vol->bps; (i & 1) == 0; 
         i >>= 1, vol->sec_log2++);

    vol->spc = FAT_BR_SECTORS_PER_CLUSTER(boot_rec);
    /*
     * "sectors per cluster" of zero is invalid
     * (and would hang the following loop)
     */
    if (vol->spc == 0)
    {
        rtems_disk_release(vol->dd);
        set_errno_and_return_minus_one(EINVAL);
    }    

    for (vol->spc_log2 = 0, i = vol->spc; (i & 1) == 0; 
         i >>= 1, vol->spc_log2++);
  
    /* 
     * "bytes per cluster" value greater than 32K is invalid
     */
    if ((vol->bpc = vol->bps << vol->spc_log2) > MS_BYTES_PER_CLUSTER_LIMIT)
    {
        rtems_disk_release(vol->dd);
        set_errno_and_return_minus_one(EINVAL);
    }    

    for (vol->bpc_log2 = 0, i = vol->bpc; (i & 1) == 0; 
         i >>= 1, vol->bpc_log2++);

    vol->fats = FAT_BR_FAT_NUM(boot_rec);
    vol->fat_loc = FAT_BR_RESERVED_SECTORS_NUM(boot_rec);

    vol->rdir_entrs = FAT_BR_FILES_PER_ROOT_DIR(boot_rec);
    
    /* calculate the count of sectors occupied by the root directory */
    vol->rdir_secs = ((vol->rdir_entrs * FAT_DIRENTRY_SIZE) + (vol->bps - 1)) /
                     vol->bps;

    vol->rdir_size = vol->rdir_secs << vol->sec_log2;

    if ( (FAT_BR_SECTORS_PER_FAT(boot_rec)) != 0)
        vol->fat_length = FAT_BR_SECTORS_PER_FAT(boot_rec);
    else
        vol->fat_length = FAT_BR_SECTORS_PER_FAT32(boot_rec);
  
    vol->data_fsec = vol->fat_loc + vol->fats * vol->fat_length + 
                     vol->rdir_secs;

    /* for  FAT12/16 root dir starts at(sector) */
    vol->rdir_loc = vol->fat_loc + vol->fats * vol->fat_length;
  
    if ( (FAT_BR_TOTAL_SECTORS_NUM16(boot_rec)) != 0)
        vol->tot_secs = FAT_BR_TOTAL_SECTORS_NUM16(boot_rec);
    else
        vol->tot_secs = FAT_BR_TOTAL_SECTORS_NUM32(boot_rec);
  
    data_secs = vol->tot_secs - vol->data_fsec;
  
    vol->data_cls = data_secs / vol->spc;

    /* determine FAT type at least */
    if ( vol->data_cls < FAT_FAT12_MAX_CLN)
    {
        vol->type = FAT_FAT12;
        vol->mask = FAT_FAT12_MASK;
        vol->eoc_val = FAT_FAT12_EOC;
    }
    else 
    {
        if ( vol->data_cls < FAT_FAT16_MAX_CLN)
        {
            vol->type = FAT_FAT16;
            vol->mask = FAT_FAT16_MASK;
            vol->eoc_val = FAT_FAT16_EOC;
        }
        else
        {
            vol->type = FAT_FAT32;
            vol->mask = FAT_FAT32_MASK;
            vol->eoc_val = FAT_FAT32_EOC;
        }
    }
  
    if (vol->type == FAT_FAT32)
    {
        vol->rdir_cl = FAT_BR_FAT32_ROOT_CLUSTER(boot_rec);
      
        vol->mirror = FAT_BR_EXT_FLAGS(boot_rec) & FAT_BR_EXT_FLAGS_MIRROR;
        if (vol->mirror)
            vol->afat = FAT_BR_EXT_FLAGS(boot_rec) & FAT_BR_EXT_FLAGS_FAT_NUM;
        else
            vol->afat = 0; 

        vol->info_sec = FAT_BR_FAT32_FS_INFO_SECTOR(boot_rec);
        if( vol->info_sec == 0 )
        { 
            rtems_disk_release(vol->dd);
            set_errno_and_return_minus_one( EINVAL );
        }    
        else 
        {
            ret = _fat_block_read(mt_entry, vol->info_sec , 0, 
                                  FAT_FSI_LEADSIG_SIZE, fs_info_sector);
            if ( ret < 0 )
            {
                rtems_disk_release(vol->dd);
                return -1;
            }    
      
            if (FAT_FSINFO_LEAD_SIGNATURE(fs_info_sector) != 
                FAT_FSINFO_LEAD_SIGNATURE_VALUE)
            {    
                rtems_disk_release(vol->dd);
                set_errno_and_return_minus_one( EINVAL );
            }    
            else
            {
                ret = _fat_block_read(mt_entry, vol->info_sec , FAT_FSI_INFO, 
                                      FAT_USEFUL_INFO_SIZE, fs_info_sector);
                if ( ret < 0 )
                {
                    rtems_disk_release(vol->dd);
                    return -1;
                }    
                    
                vol->free_cls = FAT_FSINFO_FREE_CLUSTER_COUNT(fs_info_sector);
                vol->next_cl = FAT_FSINFO_NEXT_FREE_CLUSTER(fs_info_sector);
                rc = fat_fat32_update_fsinfo_sector(mt_entry, 0xFFFFFFFF, 
                                                    0xFFFFFFFF);
                if ( rc != RC_OK )
                {
                    rtems_disk_release(vol->dd); 
                    return rc; 
                }    
            }
        }
    }
    else
    {
        vol->rdir_cl = 0;
        vol->mirror = 0;
        vol->afat = 0;
        vol->free_cls = 0xFFFFFFFF;
        vol->next_cl = 0xFFFFFFFF;
    }
    vol->afat_loc = vol->fat_loc + vol->fat_length * vol->afat;

    /* set up collection of fat-files fd */
    fs_info->vhash = calloc(FAT_HASH_SIZE, sizeof(Chain_Control));
    if ( fs_info->vhash == NULL ) 
    {
        rtems_disk_release(vol->dd);
        set_errno_and_return_minus_one( ENOMEM );
    }    

    for (i = 0; i < FAT_HASH_SIZE; i++)
        _Chain_Initialize_empty(fs_info->vhash + i);

    fs_info->rhash = calloc(FAT_HASH_SIZE, sizeof(Chain_Control));
    if ( fs_info->rhash == NULL ) 
    {
        rtems_disk_release(vol->dd);
        free(fs_info->vhash);
        set_errno_and_return_minus_one( ENOMEM );
    }
    for (i = 0; i < FAT_HASH_SIZE; i++)
        _Chain_Initialize_empty(fs_info->rhash + i);
  
    fs_info->uino_pool_size = FAT_UINO_POOL_INIT_SIZE;
    fs_info->uino_base = (vol->tot_secs << vol->sec_mul) << 4;
    fs_info->index = 0;
    fs_info->uino = (char *)calloc(fs_info->uino_pool_size, sizeof(char));
    if ( fs_info->uino == NULL )
    {
        rtems_disk_release(vol->dd);
        free(fs_info->vhash);
        free(fs_info->rhash);
        set_errno_and_return_minus_one( ENOMEM );
    }
    fs_info->sec_buf = (char *)calloc(vol->bps, sizeof(char));
    if (fs_info->sec_buf == NULL)
    {
        rtems_disk_release(vol->dd);
        free(fs_info->vhash);
        free(fs_info->rhash);
        free(fs_info->uino);
        set_errno_and_return_minus_one( ENOMEM );
    }
    
    return RC_OK;  
}

/* fat_shutdown_drive --
 *     Free all allocated resources and synchronize all necessary data 
 *
 * PARAMETERS:
 *     mt_entry - mount table entry
 *
 * RETURNS:
 *     RC_OK on success, or -1 if error occured
 *     and errno set appropriately
 */
int
fat_shutdown_drive(rtems_filesystem_mount_table_entry_t *mt_entry)
{
    int            rc = RC_OK;
    fat_fs_info_t *fs_info = mt_entry->fs_info;
    int            i = 0;

    if (fs_info->vol.type & FAT_FAT32)
    {
        rc = fat_fat32_update_fsinfo_sector(mt_entry, fs_info->vol.free_cls,
                                            fs_info->vol.next_cl);
        if ( rc != RC_OK )
            rc = -1;
    }  

    fat_buf_release(fs_info);
    
    if (rtems_bdbuf_syncdev(fs_info->vol.dev) != RTEMS_SUCCESSFUL)
        rc = -1;

    for (i = 0; i < FAT_HASH_SIZE; i++)
    {
        Chain_Node    *node = NULL;
        Chain_Control *the_chain = fs_info->vhash + i;
   
        while ( (node = _Chain_Get(the_chain)) != NULL )
            free(node);
    }    

    for (i = 0; i < FAT_HASH_SIZE; i++)
    {
        Chain_Node    *node = NULL;
        Chain_Control *the_chain = fs_info->rhash + i;

        while ( (node = _Chain_Get(the_chain)) != NULL )
            free(node);
    }    

    free(fs_info->vhash);
    free(fs_info->rhash);  

    free(fs_info->uino);
    free(fs_info->sec_buf);
    rtems_disk_release(fs_info->vol.dd);

    if (rc)
        errno = EIO;
    return rc;
}

/* fat_init_clusters_chain --
 *     Zeroing contents of all clusters in the chain
 *
 * PARAMETERS:
 *     mt_entry          - mount table entry
 *     start_cluster_num - num of first cluster in the chain 
 *
 * RETURNS:
 *     RC_OK on success, or -1 if error occured
 *     and errno set appropriately
 */
int
fat_init_clusters_chain(
    rtems_filesystem_mount_table_entry_t *mt_entry,
    unsigned32                            start_cln
    )
{
    int                     rc = RC_OK;
    ssize_t                 ret = 0;
    register fat_fs_info_t *fs_info = mt_entry->fs_info;
    unsigned32              cur_cln = start_cln;
    char                   *buf;
  
    buf = calloc(fs_info->vol.bpc, sizeof(char));
    if ( buf == NULL )
        set_errno_and_return_minus_one( EIO );

    while ((cur_cln & fs_info->vol.mask) < fs_info->vol.eoc_val)
    {
        ret = fat_cluster_write(mt_entry, cur_cln, buf);
        if ( ret == -1 )
        {
            free(buf);
            return -1;
        }

        rc  = fat_get_fat_cluster(mt_entry, cur_cln, &cur_cln);
        if ( rc != RC_OK )
        {
            free(buf);
            return rc;
        }
        
    }
    free(buf);
    return rc;
}                       
 
#define FAT_UNIQ_INO_BASE 0x0FFFFF00 

#define FAT_UNIQ_INO_IS_BUSY(index, arr) \
  (((arr)[((index)>>3)]>>((index) & (8-1))) & 0x01)

#define FAT_SET_UNIQ_INO_BUSY(index, arr) \
  ((arr)[((index)>>3)] |= (0x01<<((index) & (8-1))))

#define FAT_SET_UNIQ_INO_FREE(index, arr) \
  ((arr)[((index)>>3)] &= (~(0x01<<((index) & (8-1)))))

/* fat_get_unique_ino --
 *     Allocate unique ino from unique ino pool
 *
 * PARAMETERS:
 *     mt_entry - mount table entry
 *
 * RETURNS:
 *     unique inode number on success, or 0 if there is no free unique inode
 *     number in the pool
 *
 * ATTENTION:
 *     0 means FAILED !!!
 *     
 */
unsigned32
fat_get_unique_ino(rtems_filesystem_mount_table_entry_t *mt_entry)
{
    register fat_fs_info_t *fs_info = mt_entry->fs_info;
    unsigned32              j = 0;
    rtems_boolean           resrc_unsuff = FALSE;

    while (!resrc_unsuff)
    {  
        for (j = 0; j < fs_info->uino_pool_size; j++)
        {
            if (!FAT_UNIQ_INO_IS_BUSY(fs_info->index, fs_info->uino))
            {
                FAT_SET_UNIQ_INO_BUSY(fs_info->index, fs_info->uino);
                return (fs_info->uino_base + fs_info->index);            
            }
            fs_info->index++;
            if (fs_info->index >= fs_info->uino_pool_size)
                fs_info->index = 0;
        }

        if ((fs_info->uino_pool_size << 1) < (0x0FFFFFFF - fs_info->uino_base))
        {
            fs_info->uino_pool_size <<= 1;
            fs_info->uino = realloc(fs_info->uino, fs_info->uino_pool_size);
            if (fs_info->uino != NULL)
                fs_info->index = fs_info->uino_pool_size;
            else    
                resrc_unsuff = TRUE;
        }
        else
            resrc_unsuff = TRUE;
    }    
    return 0;
}

/* fat_free_unique_ino --
 *     Return unique ino to unique ino pool
 *
 * PARAMETERS:
 *     mt_entry - mount table entry
 *     ino      - inode number to free
 *
 * RETURNS:
 *     None
 */
void
fat_free_unique_ino(
    rtems_filesystem_mount_table_entry_t *mt_entry,
    unsigned32                            ino
    )
{
    fat_fs_info_t *fs_info = mt_entry->fs_info;
   
    FAT_SET_UNIQ_INO_FREE((ino - fs_info->uino_base), fs_info->uino);
}

/* fat_ino_is_unique --
 *     Test whether ino is from unique ino pool
 *
 * PARAMETERS:
 *     mt_entry - mount table entry
 *     ino   - ino to be tested
 *
 * RETURNS:
 *     TRUE if ino is allocated from unique ino pool, FALSE otherwise
 */
inline rtems_boolean
fat_ino_is_unique(
    rtems_filesystem_mount_table_entry_t *mt_entry,
    unsigned32                            ino
    )
{
    fat_fs_info_t *fs_info = mt_entry->fs_info;
    
    return (ino >= fs_info->uino_base);
}

/* fat_fat32_update_fsinfo_sector --
 *     Synchronize fsinfo sector for FAT32 volumes
 *
 * PARAMETERS:
 *     mt_entry   - mount table entry
 *     free_count - count of free clusters
 *     next_free  - the next free cluster num
 *
 * RETURNS:
 *     RC_OK on success, or -1 if error occured (errno set appropriately)
 */
int
fat_fat32_update_fsinfo_sector(
    rtems_filesystem_mount_table_entry_t *mt_entry,
    unsigned32                            free_count,
    unsigned32                            next_free
    )
{
    ssize_t                 ret1 = 0, ret2 = 0;
    register fat_fs_info_t *fs_info = mt_entry->fs_info;
    unsigned32              le_free_count = 0;
    unsigned32              le_next_free = 0;

    le_free_count = CT_LE_L(free_count);
    le_next_free = CT_LE_L(next_free);

    ret1 = _fat_block_write(mt_entry,
                            fs_info->vol.info_sec,
                            FAT_FSINFO_FREE_CLUSTER_COUNT_OFFSET,
                            4,
                            (char *)(&le_free_count));

    ret2 = _fat_block_write(mt_entry,
                            fs_info->vol.info_sec,
                            FAT_FSINFO_NEXT_FREE_CLUSTER_OFFSET,
                            4,
                            (char *)(&le_next_free));

    if ( (ret1 < 0) || (ret2 < 0) )
        return -1;

    return RC_OK;
}