BOOL MoveDefragmentedFilesToStartOfBlock(RDWRHandle handle,
CLUSTER lowerbound,
CLUSTER upperbound)
{
CLUSTER i, j, cluster;
BOOL IsPartOfFF;
for (i = lowerbound; i < upperbound; i++)
{
if (!IsPartOfFragmentedFile(handle, i, &IsPartOfFF))
return FALSE;
if (!IsPartOfFF)
continue;
/* See if we haven't already reached to free space in this
block */
if (!GetNthCluster(handle, i, cluster))
return FALSE;
if (FAT_FREE(cluster))
break;
for (j = i; j <= upperbound; j++)
{
/* See if we haven't already reached to free space in this
block */
if (!GetNthCluster(handle, j, cluster))
return FALSE;
if (FAT_FREE(cluster))
break;
if (!IsPartOfFragmentedFile(handle, j, &IsPartOfFF))
return FALSE;
if (!IsPartOfFF)
break;
}
if (j > upperbound)
break;
if (FAT_FREE(cluster))
continue;
if (!SwapClusters(handle, i, j));
return FALSE;
}
return TRUE;
}
CLUSTER random_freeSpace(RDWRHandle handle, unsigned long labelsinfat)
{
unsigned long randomnumber;
unsigned random1, random2;
CLUSTER label;
random1 = rand() * (labelsinfat % 65536L);
random2 = rand() * (labelsinfat / 65536L);
randomnumber = random1 * 65536L + random2;
randomnumber = (randomnumber % (labelsinfat-2))+2;
while (TRUE)
{
if (!GetNthCluster(handle, randomnumber, &label))
return FALSE;
if (FAT_FREE(label))
{
return randomnumber;
}
randomnumber++;
if (randomnumber == labelsinfat)
randomnumber = 2;
}
}
static BOOL LargestFreeSpaceFinder(RDWRHandle handle,
CLUSTER label,
SECTOR datasector,
void** structure)
{
struct Pipe* pipe = (struct Pipe*) *structure;
if (FAT_FREE(label))
{
if (!PreviousFilled)
{
pipe->count++;
}
else
{
LastFreeBlock = DataSectorToCluster(handle, datasector);
if (!LastFreeBlock)
{
pipe.error = TRUE;
return FALSE;
}
}
PreviousFilled = FALSE;
}
else
{
if (!PreviousFilled)
{
if (pipe->count > pipe->FoundMax)
{
pipe->FoundMax = pipe->count;
pipe->count = 0;
pipe->FoundCluster = DataSectorToCluster(handle, datasector);
if (!pipe->FoundCluster)
{
pipe->error = TRUE;
return FALSE;
}
}
PreviousFilled = TRUE;
}
}
return TRUE;
}
static BOOL OnlyFilledRead(RDWRHandle handle, SECTOR lsect,
unsigned numsectors, char* buf)
{
unsigned i;
SECTOR start = lsect;
CLUSTER cluster, label;
for (i = 0; i < numsectors; i++)
{
cluster = DataSectorToCluster(handle, lsect+i);
if (!cluster) return FALSE;
if (!GetNthCluster(handle, cluster, &label))
{
return FALSE;
}
if (FAT_FREE(label) || FAT_BAD(label))
{
if (i)
{
if (ReadSectors(handle, i, start, buf) == -1)
{
return FALSE;
}
}
start = lsect+i+1;
}
}
if (start < lsect+numsectors)
{
if (ReadSectors(handle, numsectors - (unsigned)(start - lsect),
start, buf) == -1)
{
return FALSE;
}
}
return TRUE;
}
static BOOL Relocate1Cluster(RDWRHandle handle,
CLUSTER source,
CLUSTER destination,
CLUSTER pSource)
{
int labelsize;
CLUSTER fatpos=0, freecluster, label;
//BOOL IsInFAT = FALSE;
SECTOR srcsector, destsector;
unsigned long sectorspercluster;
CLUSTER clustervalue;
BOOL DOTSprocessed=FALSE;
struct FSInfoStruct FSInfo;
/* See wether the destination is actually free. */
if (!GetNthCluster(handle, destination, &label))
RETURN_FTEERROR(FALSE);
if (!FAT_FREE(label))
RETURN_FTEERROR(FALSE);
/* Do some preliminary calculations. */
srcsector = ConvertToDataSector(handle, source);
if (!srcsector)
RETURN_FTEERROR(FALSE);
destsector = ConvertToDataSector(handle, destination);
if (!destsector)
RETURN_FTEERROR(FALSE);
sectorspercluster = GetSectorsPerCluster(handle);
if (!sectorspercluster)
RETURN_FTEERROR(FALSE);
/* Get the value that is stored at the source position in the FAT */
if (!ReadFatLabel(handle, source, &clustervalue))
RETURN_FTEERROR(FALSE);
/* Copy all sectors in this cluster to the new position */
if (!CopySectors(handle, srcsector, destsector, sectorspercluster))
{
RETURN_FTEERROR(FALSE);
}
if (!WriteFatLabel(handle, destination, clustervalue))
{
RETURN_FTEERROR(FALSE);
}
/* Adjust the pointer to the relocated cluster */
if (!WriteFatLabel(handle, pSource, destination))
{
RETURN_FTEERROR(FALSE);
}
if (!WriteFatLabel(handle, source, FAT_FREE_LABEL))
{
if (DOTSprocessed)
AdaptCurrentAndPreviousDirs(handle, source, source);
RETURN_FTEERROR(FALSE);
}
/* Adjust FSInfo on FAT32 */
labelsize = GetFatLabelSize(handle);
if (labelsize == FAT32)
{
if (!GetFreeClusterSearchStart(handle, &freecluster))
RETURN_FTEERROR(FALSE);
if (source < freecluster) /* source cluster became available */
{
if (!ReadFSInfo(handle, &FSInfo))
RETURN_FTEERROR(FALSE);
WriteFreeClusterStart(&FSInfo, source);
if (!WriteFSInfo(handle, &FSInfo))
RETURN_FTEERROR(FALSE);
}
if ((freecluster == destination) && /* We are relocating to the first */
(destination < source)) /* free cluster */
{
CLUSTER dummy;
if (!FindFirstFreeSpace(handle, &dummy, &dummy))
RETURN_FTEERROR(FALSE);
}
}
return TRUE;
}
BOOL ScanFileChain(RDWRHandle handle, CLUSTER firstcluster,
struct DirectoryPosition* pos,
struct DirectoryEntry* entry,
char* filename,
BOOL fixit)
{
char* bitfield;
unsigned long labelsinfat;
BOOL breakoff = FALSE;
CLUSTER current = firstcluster, label, breakingcluster, lengthBreakingCluster=0;
unsigned long length = 0, calculatedsize, bytespercluster;
static char tempbuf[255];
BOOL retVal = TRUE;
/* If it is a root directory that we have to scan see wether it is
a FAT32 volume and if it is get the root cluster */
if (!firstcluster)
{
switch (GetFatLabelSize(handle))
{
case FAT12:
case FAT16:
return TRUE;
case FAT32:
current = GetFAT32RootCluster(handle);
break;
default:
return FAIL;
}
}
else
{
bytespercluster = GetSectorsPerCluster(handle) * BYTESPERSECTOR;
if (!bytespercluster) return FAIL;
calculatedsize = (entry->filesize / bytespercluster) +
((entry->filesize % bytespercluster) > 0);
}
labelsinfat = GetLabelsInFat(handle);
if (!labelsinfat) return FAIL;
bitfield = CreateBitField(labelsinfat);
if (!bitfield)
{
DestroyBitfield(bitfield);
return FAIL;
}
SetBitfieldBit(bitfield, current);
/* Initialise the checks on the directory entries */
if (entry->attribute & FA_DIREC)
{
InitClusterEntryChecking(handle, current, filename);
switch (PreProcessClusterEntryChecking(handle, current, filename, fixit))
{
case FALSE:
retVal = FALSE;
break;
case FAIL:
DestroyBitfield(bitfield);
DestroyClusterEntryChecking(handle, current, filename);
return FAIL;
}
}
while (TRUE)
{
length++;
if (!GetNthCluster(handle, current, &label))
{
DestroyBitfield(bitfield);
if (entry->attribute & FA_DIREC)
DestroyClusterEntryChecking(handle, current, filename);
return FAIL;
}
/* Check the read cluster: */
/* the last cluster */
if (FAT_LAST(label))
{
if (entry->attribute & FA_DIREC) /* Here the current cluster is valid */
{
switch (CheckEntriesInCluster(handle, current, filename, fixit))
{
case FALSE:
retVal = FALSE;
break;
case FAIL:
DestroyBitfield(bitfield);
if (entry->attribute & FA_DIREC)
DestroyClusterEntryChecking(handle, current, filename);
return FAIL;
}
}
break;
}
/* Check wether it is in range */
if (FAT_NORMAL(label) && !IsLabelValid(handle, label))
{
if (firstcluster)
{
ShowFileNameViolation(handle, filename,
"%s contains an invalid cluster");
}
else
{
ShowFileNameViolation(handle, filename,
"The root directory contains an invalid cluster");
}
breakoff = TRUE;
breakingcluster = current;
retVal = FALSE;
}
/* bad cluster */
if (FAT_BAD(label))
{
if (firstcluster)
{
ShowFileNameViolation(handle, filename,
"%s contains a bad cluster");
}
else
{
ShowFileNameViolation(handle, filename,
"The root directory contains a bad cluster");
}
breakingcluster = current;
breakoff = TRUE;
retVal = FALSE;
}
if (FAT_FREE(label))
{
if (firstcluster)
{
ShowFileNameViolation(handle, filename,
"%s contains a free cluster");
}
else
{
ShowFileNameViolation(handle, filename,
"The root directory contains a free cluster");
}
breakoff = TRUE;
breakingcluster = current;
retVal = FALSE;
}
/* Check wether there is a loop */
if (!breakoff && GetBitfieldBit(bitfield, label))
{
if (firstcluster)
{
ShowFileNameViolation(handle, filename,
"%s contains a loop");
}
else
{
ShowFileNameViolation(handle, filename,
"The root directory contains a loop");
}
breakoff = TRUE;
breakingcluster = current;
retVal = FALSE;
}
/*
if ((firstcluster && ((entry->attribute & FA_DIREC) == 0)) &&
(length > calculatedsize) &&
(lengthBreakingCluster == 0))
{
lengthBreakingCluster = current;
}
*/
if (breakoff)
{
if (fixit)
{
if (!WriteFatLabel(handle, breakingcluster, FAT_LAST_LABEL))
{
DestroyBitfield(bitfield);
if (entry->attribute & FA_DIREC)
DestroyClusterEntryChecking(handle, current, filename);
return FAIL;
}
}
break;
}
SetBitfieldBit(bitfield, label);
if (entry->attribute & FA_DIREC) /* Here the current cluster is valid */
{
switch (CheckEntriesInCluster(handle, current, filename, fixit))
{
case FALSE:
retVal = FALSE;
break;
case FAIL:
DestroyBitfield(bitfield);
if (entry->attribute & FA_DIREC)
DestroyClusterEntryChecking(handle, current, filename);
return FAIL;
}
}
current = label;
}
/* Check the length of the file */
if (firstcluster)
{
/*
if (((entry->attribute & FA_DIREC) == 0) && (length > calculatedsize))
{
sprintf(tempbuf,
"%%s has an invalid size, the size should be about %lu, but the entry says it's %lu",
length * bytespercluster, entry->filesize);
ShowFileNameViolation(handle, filename, tempbuf);
if (fixit &&
!WriteFatLabel(handle, lengthBreakingCluster, FAT_LAST_LABEL))
{
DestroyBitfield(bitfield);
if (entry->attribute & FA_DIREC)
DestroyClusterEntryChecking(handle, current, filename);
return FAIL;
}
retVal = FALSE;
}
*/
if (((entry->attribute & FA_DIREC) == 0) && (length != calculatedsize))
{
sprintf(tempbuf,
"%%s has an invalid size, the size should be about %lu, but the entry says it's %lu",
length * bytespercluster, entry->filesize);
ShowFileNameViolation(handle, filename, tempbuf);
if (fixit)
{
/* Notice that we are modifying the filesize of the same entry in chkentrs.c,
the entry shall be written to disk there. */
entry->filesize = length * bytespercluster;
}
retVal = FALSE;
}
}
/* Destroy the checks on the directory entries */
if (entry->attribute & FA_DIREC)
{
switch (PostProcessClusterEntryChecking(handle, current, filename, fixit))
{
case FALSE:
retVal = FALSE;
break;
case FAIL:
retVal = FAIL;
}
DestroyClusterEntryChecking(handle, current, filename);
}
DestroyBitfield(bitfield);
return retVal;
}
/* This function returns FALSE if the destination is not free. */
BOOL RelocateCluster(RDWRHandle handle, CLUSTER source, CLUSTER destination)
{
int labelsize, value;
CLUSTER fatpos=0, freecluster, dircluster, label;
struct DirectoryPosition dirpos;
struct DirectoryEntry entry;
BOOL IsInFAT = FALSE;
SECTOR srcsector, destsector;
unsigned long sectorspercluster;
CLUSTER clustervalue;
BOOL found, DOTSprocessed=FALSE;
struct FSInfoStruct FSInfo;
if (!FatReferedMap)
{
if (!CreateFatReferedMap(handle))
return FALSE;
}
/* See wether the destination is actually free. */
if (!GetNthCluster(handle, destination, &label))
RETURN_FTEERROR(FALSE);
if (!FAT_FREE(label))
RETURN_FTEERROR(FALSE);
/* Do some preliminary calculations. */
srcsector = ConvertToDataSector(handle, source);
if (!srcsector)
RETURN_FTEERROR(FALSE);
destsector = ConvertToDataSector(handle, destination);
if (!destsector)
RETURN_FTEERROR(FALSE);
sectorspercluster = GetSectorsPerCluster(handle);
if (!sectorspercluster)
RETURN_FTEERROR(FALSE);
/* Get the value that is stored at the source position in the FAT */
if (!ReadFatLabel(handle, source, &clustervalue))
RETURN_FTEERROR(FALSE);
/* See where the cluster is refered */
if (!GetVFSBitfieldBit(FatReferedMap, source, &value))
return FALSE;
if (value)
{//CLUSTER fatpos1;
if (!FindClusterInFAT(handle, source, &fatpos))
RETURN_FTEERROR(FALSE);
/*
if (!FindClusterInFAT1(handle, source, &fatpos1))
RETURN_FTEERROR(FALSE);
if (fatpos != fatpos1)
printf("hola");
*/
}
if (!fatpos)
{
if (!FindClusterInDirectories(handle, source, &dirpos, &found))
RETURN_FTEERROR(FALSE);
if (!found)
{
/* Note: on FAT32 this cluster may be pointing to the root directory.
We do not support relocating the root cluster at this time.
*/
RETURN_FTEERROR(FALSE); /* Non valid cluster! */
}
else
{
/*
This is the first cluster of some file. See if it is a directory
and if it is, adjust the '.' entry of this directory and all
of the '..' entries of all the (direct) subdirectories to point
to the new cluster.
*/
if (!GetDirectory(handle, &dirpos, &entry))
RETURN_FTEERROR(FALSE);
if (entry.attribute & FA_DIREC)
{
dircluster = GetFirstCluster(&entry);
if (!AdaptCurrentAndPreviousDirs(handle, dircluster, destination))
{
RETURN_FTEERROR(FALSE);
}
DOTSprocessed = TRUE;
}
}
}
else
{
IsInFAT = TRUE;
}
/* Copy all sectors in this cluster to the new position */
if (!CopySectors(handle, srcsector, destsector, sectorspercluster))
{
if (DOTSprocessed)
AdaptCurrentAndPreviousDirs(handle, dircluster, source);
RETURN_FTEERROR(FALSE);
}
/* Write the entry in the FAT */
if (!WriteFatReference(handle, destination, clustervalue))
{
if (DOTSprocessed)
AdaptCurrentAndPreviousDirs(handle, dircluster, source);
RETURN_FTEERROR(FALSE);
}
if (!WriteFatLabel(handle, destination, clustervalue))
{
if (DOTSprocessed)
AdaptCurrentAndPreviousDirs(handle, dircluster, source);
RETURN_FTEERROR(FALSE);
}
/* Adjust the pointer to the relocated cluster */
if (IsInFAT)
{
if (!WriteFatReference(handle, fatpos, destination))
{
RETURN_FTEERROR(FALSE);
}
if (!WriteFatLabel(handle, fatpos, destination))
{
RETURN_FTEERROR(FALSE);
}
if (!ClearVFSBitfieldBit(FatReferedMap, source))
return FALSE;
if (!SetVFSBitfieldBit(FatReferedMap, destination))
return FALSE;
//if (!IndicateFatClusterMoved(fatpos, source, destination))
// return FALSE;
}
else
{
CLUSTER label;
if (!GetDirectory(handle, &dirpos, &entry))
{
if (DOTSprocessed)
AdaptCurrentAndPreviousDirs(handle, dircluster, source);
RETURN_FTEERROR(FALSE);
}
SetFirstCluster(destination, &entry);
if (!WriteDirectory(handle, &dirpos, &entry))
{
if (DOTSprocessed)
AdaptCurrentAndPreviousDirs(handle, dircluster, source);
RETURN_FTEERROR(FALSE);
}
if (!IndicateDirEntryMoved(source, destination))
return FALSE;
if (!GetNthCluster(handle, source, &label))
return FALSE;
//if (!IndicateFatClusterMoved(label, source, destination))
// return FALSE;
}
if (!WriteFatReference(handle, source, FAT_FREE_LABEL))
{
if (DOTSprocessed)
AdaptCurrentAndPreviousDirs(handle, dircluster, source);
RETURN_FTEERROR(FALSE);
}
if (!WriteFatLabel(handle, source, FAT_FREE_LABEL))
{
if (DOTSprocessed)
AdaptCurrentAndPreviousDirs(handle, dircluster, source);
RETURN_FTEERROR(FALSE);
}
if (!IndicateDirClusterMoved(handle, source, destination))
RETURN_FTEERROR(FALSE);
/* Adjust FSInfo on FAT32 */
labelsize = GetFatLabelSize(handle);
if (labelsize == FAT32)
{
if (!GetFreeClusterSearchStart(handle, &freecluster))
RETURN_FTEERROR(FALSE);
if (source < freecluster) /* source cluster became available */
{
if (!ReadFSInfo(handle, &FSInfo))
RETURN_FTEERROR(FALSE);
WriteFreeClusterStart(&FSInfo, source);
if (!WriteFSInfo(handle, &FSInfo))
RETURN_FTEERROR(FALSE);
}
if ((freecluster == destination) && /* We are relocating to the first */
(destination < source)) /* free cluster */
{
CLUSTER dummy;
if (!FindFirstFreeSpace(handle, &dummy, &dummy))
RETURN_FTEERROR(FALSE);
}
}
return TRUE;
}
/*
Beware of circular references:
fatpos1 = cluster2
cluster1 = clustervalue2
A -> B -> C
D -> A -> B
D -> A -> B -> C => D -> B -> A -> C
A: C
A: A /
B: B A
D: B
cluster1 = fatpos2
clustervalue1 = cluster2
A -> B -> C
B -> C -> D
A -> B -> C -> D => A -> C -> B -> D
C: C B
A: C
B: D
B: B /
*/
BOOL SwapClusters (RDWRHandle handle, CLUSTER clust1, CLUSTER clust2)
{
BOOL found, IsInFAT1 = FALSE, IsInFAT2 = FALSE, error = FALSE;
CLUSTER freeclust, clustervalue1, fatpos1, fatpos2;
CLUSTER clustervalue2, dircluster1, dircluster2;
unsigned char sectorspercluster;
SECTOR startsector;
struct DirectoryPosition dirpos1, dirpos2;
struct DirectoryEntry entry;
unsigned long neededmem;
void *MemCluster;
BOOL DOTSProcessed1, DOTSProcessed2;
SECTOR srcsector, destsector;
/* First check wether we shouldn't be using RelocateCluster instead. */
if (!ReadFatLabel (handle, clust1, &clustervalue1))
return FALSE;
if (!ReadFatLabel (handle, clust2, &clustervalue2))
return FALSE;
if (FAT_FREE (clustervalue1) && (FAT_FREE (clustervalue2)))
{
return TRUE;
}
if (FAT_FREE (clustervalue1))
{
return RelocateCluster (handle, clust2, clust1);
}
if (FAT_FREE (clustervalue2))
{
return RelocateCluster (handle, clust1, clust2);
}
/* See if we have enough memory to load the data for one cluster
into memory. */
sectorspercluster = GetSectorsPerCluster (handle);
if (!sectorspercluster)
return FALSE;
neededmem = sectorspercluster * BYTESPERSECTOR;
MemCluster = malloc (neededmem);
if (MemCluster)
{
/* First prepare the first cluster. */
/* See where the cluster is refered */
/* In FAT? */
if (!FindClusterInFAT (handle, clust1, &fatpos1))
{
free (MemCluster);
return FALSE;
}
/* No, then look if this is the first cluster of a file. */
if (!fatpos1)
{
if (!FindClusterInDirectories (handle, clust1, &dirpos1, &found))
{
free (MemCluster);
return FALSE;
}
if (!found)
{
free (MemCluster);
return FALSE; /* Non valid cluster! */
}
else
{
/*
Special case: if this is the first cluster of a directory
then adjust all the . and .. pointers to
reflect the new position on the volume.
*/
if (!GetDirectory (handle, &dirpos1, &entry))
{
free (MemCluster);
return FALSE;
}
if (entry.attribute & FA_DIREC)
{
dircluster1 = GetFirstCluster (&entry);
if (!AdaptCurrentAndPreviousDirs(handle, dircluster1, clust2))
{
AdaptCurrentAndPreviousDirs (handle, dircluster1,
clust1);
free (MemCluster);
return FALSE;
}
DOTSProcessed1 = TRUE;
}
}
}
else
{
IsInFAT1 = TRUE;
}
/* Then prepare the second cluster. */
/* See where the cluster is refered */
/* In FAT? */
if (!FindClusterInFAT (handle, clust2, &fatpos2))
{
if (DOTSProcessed1)
AdaptCurrentAndPreviousDirs (handle, dircluster1, clust1);
free (MemCluster);
return FALSE;
}
/* No, then look if this is the first cluster of a file. */
if (!fatpos2)
{
if (!FindClusterInDirectories (handle, clust2, &dirpos2, &found))
{
if (DOTSProcessed1)
AdaptCurrentAndPreviousDirs (handle, dircluster1, clust1);
free (MemCluster);
return FALSE;
}
if (!found)
{
if (DOTSProcessed1)
AdaptCurrentAndPreviousDirs (handle, dircluster1, clust1);
free (MemCluster);
return FALSE; /* Non valid cluster! */
}
else
{
/*
Special case: if this is the first cluster of a directory
then adjust all the . and .. pointers to
reflect the new position on the volume.
*/
if (!GetDirectory (handle, &dirpos2, &entry))
{
if (DOTSProcessed1)
AdaptCurrentAndPreviousDirs (handle, dircluster1,
clust1);
free (MemCluster);
return FALSE;
}
if (entry.attribute & FA_DIREC)
{
dircluster2 = GetFirstCluster (&entry);
if (!AdaptCurrentAndPreviousDirs(handle, dircluster2, clust1))
{
AdaptCurrentAndPreviousDirs (handle, dircluster2, clust2);
AdaptCurrentAndPreviousDirs (handle, dircluster1, clust1);
free (MemCluster);
return FALSE;
}
DOTSProcessed2 = TRUE;
}
}
}
else
{
IsInFAT2 = TRUE;
}
startsector = ConvertToDataSector (handle, clust1);
if (!startsector)
{
if (DOTSProcessed1)
AdaptCurrentAndPreviousDirs (handle, dircluster1, clust1);
if (DOTSProcessed2)
AdaptCurrentAndPreviousDirs (handle, dircluster2, clust2);
free (MemCluster);
return FALSE;
}
/* Then copy the data of the second cluster to the new position */
/* Copy all sectors in this cluster to the new position */
srcsector = ConvertToDataSector (handle, clust2);
if (!srcsector)
{
if (DOTSProcessed1)
AdaptCurrentAndPreviousDirs (handle, dircluster1, clust1);
if (DOTSProcessed2)
AdaptCurrentAndPreviousDirs (handle, dircluster2, clust2);
free (MemCluster);
return FALSE;
}
destsector = ConvertToDataSector (handle, clust1);
if (!startsector)
{
if (DOTSProcessed1)
AdaptCurrentAndPreviousDirs (handle, dircluster1, clust1);
if (DOTSProcessed2)
AdaptCurrentAndPreviousDirs (handle, dircluster2, clust2);
free (MemCluster);
return FALSE;
}
/* AS OF THIS POINT WE WILL NOT BE ABLE TO BACKTRACK,
THEREFORE WE KEEP ON GOING EVEN IF THERE WERE ERRORS. */
/* Change the pointers of the first cluster that has to be moved
to the second cluster. */
/* Write the entry in the FAT */
if (clust2 == clustervalue1) /* Beware of circular references */
{
if (!WriteFatLabel (handle, clust2, clust1))
error = TRUE;
}
else
{
if (!WriteFatLabel (handle, clust2, clustervalue1))
error = TRUE;
}
/* Adjust the pointer to the relocated cluster */
if (IsInFAT1) /* the previous one in the file */
{
if (fatpos1 != clust2) /* Beware of circular references */
{
if (!WriteFatLabel (handle, fatpos1, clust2))
error = TRUE;
}
}
else /* or the directory entry to the file */
{
if (!GetDirectory (handle, &dirpos1, &entry))
error = TRUE;
if (GetFirstCluster (&entry) != clust2)
{
SetFirstCluster (clust2, &entry);
if (!WriteDirectory (handle, &dirpos1, &entry))
error = TRUE;
}
}
/* Change the pointers of the second cluster that has to be moved
to the first cluster. */
/* Write the entry in the FAT */
if (clust1 == clustervalue2) /* Beware of circular references */
{
if (!WriteFatLabel (handle, clust1, clustervalue1))
error = TRUE;
}
else
{
if (!WriteFatLabel (handle, clust1, clustervalue2))
error = TRUE;
}
/* Adjust the pointer to the relocated cluster */
if (IsInFAT2) /* the previous one in the file */
{
if (fatpos2 != clust1) /* Beware of circular references */
{
if (!WriteFatLabel (handle, fatpos2, clust1))
error = TRUE;
}
}
else /* or the directory entry to the file */
{
if (!GetDirectory (handle, &dirpos2, &entry))
error = TRUE;
if (GetFirstCluster (&entry) != clust1) /* Beware of circular references */
{
SetFirstCluster (clust1, &entry);
if (!WriteDirectory (handle, &dirpos2, &entry))
error = TRUE;
}
