/** @file Routines dealing with disk spaces and FAT table entries. Copyright (c) 2005 - 2013, Intel Corporation. All rights reserved.
SPDX-License-Identifier: BSD-2-Clause-Patent **/ #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 successfully. @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 chain. @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 ((DEBUG_INIT | DEBUG_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 successfully. @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 ((DEBUG_INIT | DEBUG_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 successfully. @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_MIN_CLUSTER || Cluster > Volume->MaxCluster + 1) { DEBUG ( (DEBUG_INIT | DEBUG_ERROR, "FatGrowEof: cluster chain corrupt\n") ); Status = EFI_VOLUME_CORRUPTED; goto Done; } ClusterCount++; OFile->FileLastCluster = Cluster; Cluster = FatGetFatEntry (Volume, Cluster); } if (ClusterCount != CurSize) { DEBUG ( (DEBUG_INIT | DEBUG_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 (NewCluster < FAT_MIN_CLUSTER || NewCluster > Volume->MaxCluster + 1) { Status = EFI_VOLUME_CORRUPTED; goto Done; } if (LastCluster != 0) { FatSetFatEntry (Volume, LastCluster, NewCluster); } else { OFile->FileCluster = NewCluster; OFile->FileCurrentCluster = NewCluster; } LastCluster = NewCluster; CurSize += 1; // // Terminate the cluster list // // Note that we must do this EVERY time we allocate a cluster, because // FatAllocateCluster scans the FAT looking for a free cluster and // "LastCluster" is no longer free! Usually, FatAllocateCluster will // start looking with the cluster after "LastCluster"; however, when // there is only one free cluster left, it will find "LastCluster" // a second time. There are other, less predictable scenarios // where this could happen, as well. // 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 its position // from its 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 ((DEBUG_INIT | DEBUG_ERROR, "FatOFilePosition:"" cluster chain corrupt\n")); return EFI_VOLUME_CORRUPTED; } Cluster = FatGetFatEntry (Volume, Cluster); } if (Cluster < FAT_MIN_CLUSTER || Cluster > Volume->MaxCluster + 1) { 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 ( (DEBUG_INIT | DEBUG_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; } }