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android / device / linaro / bootloader / edk2 / c593450051e106ff6ef19df964b40afb7da8e7cd / . / FatPkg / EnhancedFatDxe / FileSpace.c
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/** @file
Routines dealing with disk spaces and FAT table entries.
Copyright (c) 2005 - 2013, Intel Corporation. All rights reserved.<BR>
This program and the accompanying materials are licensed and made available
under the terms and conditions of the BSD License which accompanies this
distribution. The full text of the license may be found at
http://opensource.org/licenses/bsd-license.php
THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,
WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.
**/
#include "Fat.h"
/**
Get the FAT entry of the volume, which is identified with the Index.
@param Volume - FAT file system volume.
@param Index - The index of the FAT entry of the volume.
@return The buffer of the FAT entry
**/
STATIC
VOID *
FatLoadFatEntry (
IN FAT_VOLUME *Volume,
IN UINTN Index
)
{
UINTN Pos;
EFI_STATUS Status;
if (Index > (Volume->MaxCluster + 1)) {
Volume->FatEntryBuffer = (UINT32) -1;
return &Volume->FatEntryBuffer;
}
//
// Compute buffer position needed
//
switch (Volume->FatType) {
case Fat12:
Pos = FAT_POS_FAT12 (Index);
break;
case Fat16:
Pos = FAT_POS_FAT16 (Index);
break;
default:
Pos = FAT_POS_FAT32 (Index);
}
//
// Set the position and read the buffer
//
Volume->FatEntryPos = Volume->FatPos + Pos;
Status = FatDiskIo (
Volume,
ReadFat,
Volume->FatEntryPos,
Volume->FatEntrySize,
&Volume->FatEntryBuffer,
NULL
);
if (EFI_ERROR (Status)) {
Volume->FatEntryBuffer = (UINT32) -1;
}
return &Volume->FatEntryBuffer;
}
/**
Get the FAT entry value of the volume, which is identified with the Index.
@param Volume - FAT file system volume.
@param Index - The index of the FAT entry of the volume.
@return The value of the FAT entry.
**/
STATIC
UINTN
FatGetFatEntry (
IN FAT_VOLUME *Volume,
IN UINTN Index
)
{
VOID *Pos;
UINT8 *En12;
UINT16 *En16;
UINT32 *En32;
UINTN Accum;
Pos = FatLoadFatEntry (Volume, Index);
if (Index > (Volume->MaxCluster + 1)) {
return (UINTN) -1;
}
switch (Volume->FatType) {
case Fat12:
En12 = Pos;
Accum = En12[0] | (En12[1] << 8);
Accum = FAT_ODD_CLUSTER_FAT12 (Index) ? (Accum >> 4) : (Accum & FAT_CLUSTER_MASK_FAT12);
Accum = Accum | ((Accum >= FAT_CLUSTER_SPECIAL_FAT12) ? FAT_CLUSTER_SPECIAL_EXT : 0);
break;
case Fat16:
En16 = Pos;
Accum = *En16;
Accum = Accum | ((Accum >= FAT_CLUSTER_SPECIAL_FAT16) ? FAT_CLUSTER_SPECIAL_EXT : 0);
break;
default:
En32 = Pos;
Accum = *En32 & FAT_CLUSTER_MASK_FAT32;
Accum = Accum | ((Accum >= FAT_CLUSTER_SPECIAL_FAT32) ? FAT_CLUSTER_SPECIAL_EXT : 0);
}
return Accum;
}
/**
Set the FAT entry value of the volume, which is identified with the Index.
@param Volume - FAT file system volume.
@param Index - The index of the FAT entry of the volume.
@param Value - The new value of the FAT entry.
@retval EFI_SUCCESS - Set the new FAT entry value sucessfully.
@retval EFI_VOLUME_CORRUPTED - The FAT type of the volume is error.
@return other - An error occurred when operation the FAT entries.
**/
STATIC
EFI_STATUS
FatSetFatEntry (
IN FAT_VOLUME *Volume,
IN UINTN Index,
IN UINTN Value
)
{
VOID *Pos;
UINT8 *En12;
UINT16 *En16;
UINT32 *En32;
UINTN Accum;
EFI_STATUS Status;
UINTN OriginalVal;
if (Index < FAT_MIN_CLUSTER) {
return EFI_VOLUME_CORRUPTED;
}
OriginalVal = FatGetFatEntry (Volume, Index);
if (Value == FAT_CLUSTER_FREE && OriginalVal != FAT_CLUSTER_FREE) {
Volume->FatInfoSector.FreeInfo.ClusterCount += 1;
if (Index < Volume->FatInfoSector.FreeInfo.NextCluster) {
Volume->FatInfoSector.FreeInfo.NextCluster = (UINT32) Index;
}
} else if (Value != FAT_CLUSTER_FREE && OriginalVal == FAT_CLUSTER_FREE) {
if (Volume->FatInfoSector.FreeInfo.ClusterCount != 0) {
Volume->FatInfoSector.FreeInfo.ClusterCount -= 1;
}
}
//
// Make sure the entry is in memory
//
Pos = FatLoadFatEntry (Volume, Index);
//
// Update the value
//
switch (Volume->FatType) {
case Fat12:
En12 = Pos;
Accum = En12[0] | (En12[1] << 8);
Value = Value & FAT_CLUSTER_MASK_FAT12;
if (FAT_ODD_CLUSTER_FAT12 (Index)) {
Accum = (Value << 4) | (Accum & 0xF);
} else {
Accum = Value | (Accum & FAT_CLUSTER_UNMASK_FAT12);
}
En12[0] = (UINT8) (Accum & 0xFF);
En12[1] = (UINT8) (Accum >> 8);
break;
case Fat16:
En16 = Pos;
*En16 = (UINT16) Value;
break;
default:
En32 = Pos;
*En32 = (*En32 & FAT_CLUSTER_UNMASK_FAT32) | (UINT32) (Value & FAT_CLUSTER_MASK_FAT32);
}
//
// If the volume's dirty bit is not set, set it now
//
if (!Volume->FatDirty && Volume->FatType != Fat12) {
Volume->FatDirty = TRUE;
FatAccessVolumeDirty (Volume, WriteFat, &Volume->DirtyValue);
}
//
// Write the updated fat entry value to the volume
// The fat is the first fat, and other fat will be in sync
// when the FAT cache flush back.
//
Status = FatDiskIo (
Volume,
WriteFat,
Volume->FatEntryPos,
Volume->FatEntrySize,
&Volume->FatEntryBuffer,
NULL
);
return Status;
}
/**
Free the cluster clain.
@param Volume - FAT file system volume.
@param Cluster - The first cluster of cluster chain.
@retval EFI_SUCCESS - The cluster chain is freed successfully.
@retval EFI_VOLUME_CORRUPTED - There are errors in the file's clusters.
**/
STATIC
EFI_STATUS
FatFreeClusters (
IN FAT_VOLUME *Volume,
IN UINTN Cluster
)
{
UINTN LastCluster;
while (!FAT_END_OF_FAT_CHAIN (Cluster)) {
if (Cluster == FAT_CLUSTER_FREE || Cluster >= FAT_CLUSTER_SPECIAL) {
DEBUG ((EFI_D_INIT | EFI_D_ERROR, "FatShrinkEof: cluster chain corrupt\n"));
return EFI_VOLUME_CORRUPTED;
}
LastCluster = Cluster;
Cluster = FatGetFatEntry (Volume, Cluster);
FatSetFatEntry (Volume, LastCluster, FAT_CLUSTER_FREE);
}
return EFI_SUCCESS;
}
/**
Allocate a free cluster and return the cluster index.
@param Volume - FAT file system volume.
@return The index of the free cluster
**/
STATIC
UINTN
FatAllocateCluster (
IN FAT_VOLUME *Volume
)
{
UINTN Cluster;
//
// Start looking at FatFreePos for the next unallocated cluster
//
if (Volume->DiskError) {
return (UINTN) FAT_CLUSTER_LAST;
}
for (;;) {
//
// If the end of the list, return no available cluster
//
if (Volume->FatInfoSector.FreeInfo.NextCluster > (Volume->MaxCluster + 1)) {
if (Volume->FreeInfoValid && 0 < (INT32) (Volume->FatInfoSector.FreeInfo.ClusterCount)) {
Volume->FreeInfoValid = FALSE;
}
FatComputeFreeInfo (Volume);
if (Volume->FatInfoSector.FreeInfo.NextCluster > (Volume->MaxCluster + 1)) {
return (UINTN) FAT_CLUSTER_LAST;
}
}
Cluster = FatGetFatEntry (Volume, Volume->FatInfoSector.FreeInfo.NextCluster);
if (Cluster == FAT_CLUSTER_FREE) {
break;
}
//
// Try the next cluster
//
Volume->FatInfoSector.FreeInfo.NextCluster += 1;
}
Cluster = Volume->FatInfoSector.FreeInfo.NextCluster;
Volume->FatInfoSector.FreeInfo.NextCluster += 1;
return Cluster;
}
/**
Count the number of clusters given a size.
@param Volume - The file system volume.
@param Size - The size in bytes.
@return The number of the clusters.
**/
STATIC
UINTN
FatSizeToClusters (
IN FAT_VOLUME *Volume,
IN UINTN Size
)
{
UINTN Clusters;
Clusters = Size >> Volume->ClusterAlignment;
if ((Size & (Volume->ClusterSize - 1)) > 0) {
Clusters += 1;
}
return Clusters;
}
/**
Shrink the end of the open file base on the file size.
@param OFile - The open file.
@retval EFI_SUCCESS - Shrinked sucessfully.
@retval EFI_VOLUME_CORRUPTED - There are errors in the file's clusters.
**/
EFI_STATUS
FatShrinkEof (
IN FAT_OFILE *OFile
)
{
FAT_VOLUME *Volume;
UINTN NewSize;
UINTN CurSize;
UINTN Cluster;
UINTN LastCluster;
Volume = OFile->Volume;
ASSERT_VOLUME_LOCKED (Volume);
NewSize = FatSizeToClusters (Volume, OFile->FileSize);
//
// Find the address of the last cluster
//
Cluster = OFile->FileCluster;
LastCluster = FAT_CLUSTER_FREE;
if (NewSize != 0) {
for (CurSize = 0; CurSize < NewSize; CurSize++) {
if (Cluster == FAT_CLUSTER_FREE || Cluster >= FAT_CLUSTER_SPECIAL) {
DEBUG ((EFI_D_INIT | EFI_D_ERROR, "FatShrinkEof: cluster chain corrupt\n"));
return EFI_VOLUME_CORRUPTED;
}
LastCluster = Cluster;
Cluster = FatGetFatEntry (Volume, Cluster);
}
FatSetFatEntry (Volume, LastCluster, (UINTN) FAT_CLUSTER_LAST);
} else {
//
// Check to see if the file is already completely truncated
//
if (Cluster == FAT_CLUSTER_FREE) {
return EFI_SUCCESS;
}
//
// The file is being completely truncated.
//
OFile->FileCluster = FAT_CLUSTER_FREE;
}
//
// Set CurrentCluster == FileCluster
// to force a recalculation of Position related stuffs
//
OFile->FileCurrentCluster = OFile->FileCluster;
OFile->FileLastCluster = LastCluster;
OFile->Dirty = TRUE;
//
// Free the remaining cluster chain
//
return FatFreeClusters (Volume, Cluster);
}
/**
Grow the end of the open file base on the NewSizeInBytes.
@param OFile - The open file.
@param NewSizeInBytes - The new size in bytes of the open file.
@retval EFI_SUCCESS - The file is grown sucessfully.
@retval EFI_UNSUPPORTED - The file size is larger than 4GB.
@retval EFI_VOLUME_CORRUPTED - There are errors in the files' clusters.
@retval EFI_VOLUME_FULL - The volume is full and can not grow the file.
**/
EFI_STATUS
FatGrowEof (
IN FAT_OFILE *OFile,
IN UINT64 NewSizeInBytes
)
{
FAT_VOLUME *Volume;
EFI_STATUS Status;
UINTN Cluster;
UINTN CurSize;
UINTN NewSize;
UINTN LastCluster;
UINTN NewCluster;
UINTN ClusterCount;
//
// For FAT file system, the max file is 4GB.
//
if (NewSizeInBytes > 0x0FFFFFFFFL) {
return EFI_UNSUPPORTED;
}
Volume = OFile->Volume;
ASSERT_VOLUME_LOCKED (Volume);
//
// If the file is already large enough, do nothing
//
CurSize = FatSizeToClusters (Volume, OFile->FileSize);
NewSize = FatSizeToClusters (Volume, (UINTN) NewSizeInBytes);
if (CurSize < NewSize) {
//
// If we haven't found the files last cluster do it now
//
if ((OFile->FileCluster != 0) && (OFile->FileLastCluster == 0)) {
Cluster = OFile->FileCluster;
ClusterCount = 0;
while (!FAT_END_OF_FAT_CHAIN (Cluster)) {
if (Cluster == FAT_CLUSTER_FREE || Cluster >= FAT_CLUSTER_SPECIAL) {
DEBUG (
(EFI_D_INIT | EFI_D_ERROR,
"FatGrowEof: cluster chain corrupt\n")
);
Status = EFI_VOLUME_CORRUPTED;
goto Done;
}
ClusterCount++;
OFile->FileLastCluster = Cluster;
Cluster = FatGetFatEntry (Volume, Cluster);
}
if (ClusterCount != CurSize) {
DEBUG (
(EFI_D_INIT | EFI_D_ERROR,
"FatGrowEof: cluster chain size does not match file size\n")
);
Status = EFI_VOLUME_CORRUPTED;
goto Done;
}
}
//
// Loop until we've allocated enough space
//
LastCluster = OFile->FileLastCluster;
while (CurSize < NewSize) {
NewCluster = FatAllocateCluster (Volume);
if (FAT_END_OF_FAT_CHAIN (NewCluster)) {
if (LastCluster != FAT_CLUSTER_FREE) {
FatSetFatEntry (Volume, LastCluster, (UINTN) FAT_CLUSTER_LAST);
OFile->FileLastCluster = LastCluster;
}
Status = EFI_VOLUME_FULL;
goto Done;
}
if (LastCluster != 0) {
FatSetFatEntry (Volume, LastCluster, NewCluster);
} else {
OFile->FileCluster = NewCluster;
OFile->FileCurrentCluster = NewCluster;
}
LastCluster = NewCluster;
CurSize += 1;
}
//
// Terminate the cluster list
//
FatSetFatEntry (Volume, LastCluster, (UINTN) FAT_CLUSTER_LAST);
OFile->FileLastCluster = LastCluster;
}
OFile->FileSize = (UINTN) NewSizeInBytes;
OFile->Dirty = TRUE;
return EFI_SUCCESS;
Done:
FatShrinkEof (OFile);
return Status;
}
/**
Seek OFile to requested position, and calculate the number of
consecutive clusters from the position in the file
@param OFile - The open file.
@param Position - The file's position which will be accessed.
@param PosLimit - The maximum length current reading/writing may access
@retval EFI_SUCCESS - Set the info successfully.
@retval EFI_VOLUME_CORRUPTED - Cluster chain corrupt.
**/
EFI_STATUS
FatOFilePosition (
IN FAT_OFILE *OFile,
IN UINTN Position,
IN UINTN PosLimit
)
{
FAT_VOLUME *Volume;
UINTN ClusterSize;
UINTN Cluster;
UINTN StartPos;
UINTN Run;
Volume = OFile->Volume;
ClusterSize = Volume->ClusterSize;
ASSERT_VOLUME_LOCKED (Volume);
//
// If this is the fixed root dir, then compute it's position
// from it's fixed info in the fat bpb
//
if (OFile->IsFixedRootDir) {
OFile->PosDisk = Volume->RootPos + Position;
Run = OFile->FileSize - Position;
} else {
//
// Run the file's cluster chain to find the current position
// If possible, run from the current cluster rather than
// start from beginning
// Assumption: OFile->Position is always consistent with
// OFile->FileCurrentCluster.
// OFile->Position is not modified outside this function;
// OFile->FileCurrentCluster is modified outside this function
// to be the same as OFile->FileCluster
// when OFile->FileCluster is updated, so make a check of this
// and invalidate the original OFile->Position in this case
//
Cluster = OFile->FileCurrentCluster;
StartPos = OFile->Position;
if (Position < StartPos || OFile->FileCluster == Cluster) {
StartPos = 0;
Cluster = OFile->FileCluster;
}
while (StartPos + ClusterSize <= Position) {
StartPos += ClusterSize;
if (Cluster == FAT_CLUSTER_FREE || (Cluster >= FAT_CLUSTER_SPECIAL)) {
DEBUG ((EFI_D_INIT | EFI_D_ERROR, "FatOFilePosition:"" cluster chain corrupt\n"));
return EFI_VOLUME_CORRUPTED;
}
Cluster = FatGetFatEntry (Volume, Cluster);
}
if (Cluster < FAT_MIN_CLUSTER) {
return EFI_VOLUME_CORRUPTED;
}
OFile->PosDisk = Volume->FirstClusterPos +
LShiftU64 (Cluster - FAT_MIN_CLUSTER, Volume->ClusterAlignment) +
Position - StartPos;
OFile->FileCurrentCluster = Cluster;
OFile->Position = StartPos;
//
// Compute the number of consecutive clusters in the file
//
Run = StartPos + ClusterSize - Position;
if (!FAT_END_OF_FAT_CHAIN (Cluster)) {
while ((FatGetFatEntry (Volume, Cluster) == Cluster + 1) && Run < PosLimit) {
Run += ClusterSize;
Cluster += 1;
}
}
}
OFile->PosRem = Run;
return EFI_SUCCESS;
}
/**
Get the size of directory of the open file.
@param Volume - The File System Volume.
@param Cluster - The Starting cluster.
@return The physical size of the file starting at the input cluster, if there is error in the
cluster chain, the return value is 0.
**/
UINTN
FatPhysicalDirSize (
IN FAT_VOLUME *Volume,
IN UINTN Cluster
)
{
UINTN Size;
ASSERT_VOLUME_LOCKED (Volume);
//
// Run the cluster chain for the OFile
//
Size = 0;
//
// N.B. ".." directories on some media do not contain a starting
// cluster. In the case of "." or ".." we don't need the size anyway.
//
if (Cluster != 0) {
while (!FAT_END_OF_FAT_CHAIN (Cluster)) {
if (Cluster == FAT_CLUSTER_FREE || Cluster >= FAT_CLUSTER_SPECIAL) {
DEBUG (
(EFI_D_INIT | EFI_D_ERROR,
"FATDirSize: cluster chain corrupt\n")
);
return 0;
}
Size += Volume->ClusterSize;
Cluster = FatGetFatEntry (Volume, Cluster);
}
}
return Size;
}
/**
Get the physical size of a file on the disk.
@param Volume - The file system volume.
@param RealSize - The real size of a file.
@return The physical size of a file on the disk.
**/
UINT64
FatPhysicalFileSize (
IN FAT_VOLUME *Volume,
IN UINTN RealSize
)
{
UINTN ClusterSizeMask;
UINT64 PhysicalSize;
ClusterSizeMask = Volume->ClusterSize - 1;
PhysicalSize = (RealSize + ClusterSizeMask) & (~((UINT64) ClusterSizeMask));
return PhysicalSize;
}
/**
Update the free cluster info of FatInfoSector of the volume.
@param Volume - FAT file system volume.
**/
VOID
FatComputeFreeInfo (
IN FAT_VOLUME *Volume
)
{
UINTN Index;
//
// If we don't have valid info, compute it now
//
if (!Volume->FreeInfoValid) {
Volume->FreeInfoValid = TRUE;
Volume->FatInfoSector.FreeInfo.ClusterCount = 0;
for (Index = Volume->MaxCluster + 1; Index >= FAT_MIN_CLUSTER; Index--) {
if (Volume->DiskError) {
break;
}
if (FatGetFatEntry (Volume, Index) == FAT_CLUSTER_FREE) {
Volume->FatInfoSector.FreeInfo.ClusterCount += 1;
Volume->FatInfoSector.FreeInfo.NextCluster = (UINT32) Index;
}
}
Volume->FatInfoSector.Signature = FAT_INFO_SIGNATURE;
Volume->FatInfoSector.InfoBeginSignature = FAT_INFO_BEGIN_SIGNATURE;
Volume->FatInfoSector.InfoEndSignature = FAT_INFO_END_SIGNATURE;
}
}