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// Copyright 2019 The gVisor Authors.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package disklayout
// SuperBlock should be implemented by structs representing ext4 superblock.
// The superblock holds a lot of information about the enclosing filesystem.
// This interface aims to provide access methods to important information held
// by the superblock. It does NOT expose all fields of the superblock, only the
// ones necessary. This can be expanded when need be.
//
// Location and replication:
// - The superblock is located at offset 1024 in block group 0.
// - Redundant copies of the superblock and group descriptors are kept in
// all groups if sparse_super feature flag is NOT set. If it is set, the
// replicas only exist in groups whose group number is either 0 or a
// power of 3, 5, or 7.
// - There is also a sparse superblock feature v2 in which there are just
// two replicas saved in block groups pointed by the s_backup_bgs field.
//
// Replicas should eventually be updated if the superblock is updated.
//
// See https://www.kernel.org/doc/html/latest/filesystems/ext4/globals.html#super-block.
type SuperBlock interface {
// InodesCount returns the total number of inodes in this filesystem.
InodesCount() uint32
// BlocksCount returns the total number of data blocks in this filesystem.
BlocksCount() uint64
// FreeBlocksCount returns the number of free blocks in this filesystem.
FreeBlocksCount() uint64
// FreeInodesCount returns the number of free inodes in this filesystem.
FreeInodesCount() uint32
// MountCount returns the number of mounts since the last fsck.
MountCount() uint16
// MaxMountCount returns the number of mounts allowed beyond which a fsck is
// needed.
MaxMountCount() uint16
// FirstDataBlock returns the absolute block number of the first data block,
// which contains the super block itself.
//
// If the filesystem has 1kb data blocks then this should return 1. For all
// other configurations, this typically returns 0.
//
// The first block group descriptor is in (FirstDataBlock() + 1)th block.
FirstDataBlock() uint32
// BlockSize returns the size of one data block in this filesystem.
// This can be calculated by 2^(10 + sb.s_log_block_size). This ensures that
// the smallest block size is 1kb.
BlockSize() uint64
// BlocksPerGroup returns the number of data blocks in a block group.
BlocksPerGroup() uint32
// ClusterSize returns block cluster size (set during mkfs time by admin).
// This can be calculated by 2^(10 + sb.s_log_cluster_size). This ensures that
// the smallest cluster size is 1kb.
//
// sb.s_log_cluster_size must equal sb.s_log_block_size if bigalloc feature
// is NOT set and consequently BlockSize() = ClusterSize() in that case.
ClusterSize() uint64
// ClustersPerGroup returns:
// - number of clusters per group if bigalloc is enabled.
// - BlocksPerGroup() otherwise.
ClustersPerGroup() uint32
// InodeSize returns the size of the inode disk record size in bytes. Use this
// to iterate over inode arrays on disk.
//
// In ext2 and ext3:
// - Each inode had a disk record of 128 bytes.
// - The inode struct size was fixed at 128 bytes.
//
// In ext4 its possible to allocate larger on-disk inodes:
// - Inode disk record size = sb.s_inode_size (function return value).
// = 256 (default)
// - Inode struct size = 128 + inode.i_extra_isize.
// = 128 + 28 = 156 (default)
InodeSize() uint16
// InodesPerGroup returns the number of inodes in a block group.
InodesPerGroup() uint32
// BgDescSize returns the size of the block group descriptor struct.
//
// In ext2, ext3, ext4 (without 64-bit feature), the block group descriptor
// is only 32 bytes long.
// In ext4 with 64-bit feature, the block group descriptor expands to AT LEAST
// 64 bytes. It might be bigger than that.
BgDescSize() uint16
// CompatibleFeatures returns the CompatFeatures struct which holds all the
// compatible features this fs supports.
CompatibleFeatures() CompatFeatures
// IncompatibleFeatures returns the CompatFeatures struct which holds all the
// incompatible features this fs supports.
IncompatibleFeatures() IncompatFeatures
// ReadOnlyCompatibleFeatures returns the CompatFeatures struct which holds all the
// readonly compatible features this fs supports.
ReadOnlyCompatibleFeatures() RoCompatFeatures
// Magic() returns the magic signature which must be 0xef53.
Magic() uint16
// Revision returns the superblock revision. Superblock struct fields from
// offset 0x54 till 0x150 should only be used if superblock has DynamicRev.
Revision() SbRevision
}
// SbRevision is the type for superblock revisions.
type SbRevision int
// Super block revisions.
const (
// OldRev is the good old (original) format.
OldRev SbRevision = 0
// DynamicRev is v2 format w/ dynamic inode sizes.
DynamicRev SbRevision = 1
)
// Superblock compatible features.
// This is not exhaustive, unused features are not listed.
const (
// SbDirPrealloc indicates directory preallocation.
SbDirPrealloc = 0x1
// SbHasJournal indicates the presence of a journal. jbd2 should only work
// with this being set.
SbHasJournal = 0x4
// SbExtAttr indicates extended attributes support.
SbExtAttr = 0x8
// SbResizeInode indicates that the fs has reserved GDT blocks (right after
// group descriptors) for fs expansion.
SbResizeInode = 0x10
// SbDirIndex indicates that the fs has directory indices.
SbDirIndex = 0x20
// SbSparseV2 stands for Sparse superblock version 2.
SbSparseV2 = 0x200
)
// CompatFeatures represents a superblock's compatible feature set. If the
// kernel does not understand any of these feature, it can still read/write
// to this fs.
type CompatFeatures struct {
DirPrealloc bool
HasJournal bool
ExtAttr bool
ResizeInode bool
DirIndex bool
SparseV2 bool
}
// ToInt converts superblock compatible features back to its 32-bit rep.
func (f CompatFeatures) ToInt() uint32 {
var res uint32
if f.DirPrealloc {
res |= SbDirPrealloc
}
if f.HasJournal {
res |= SbHasJournal
}
if f.ExtAttr {
res |= SbExtAttr
}
if f.ResizeInode {
res |= SbResizeInode
}
if f.DirIndex {
res |= SbDirIndex
}
if f.SparseV2 {
res |= SbSparseV2
}
return res
}
// CompatFeaturesFromInt converts the integer representation of superblock
// compatible features to CompatFeatures struct.
func CompatFeaturesFromInt(f uint32) CompatFeatures {
return CompatFeatures{
DirPrealloc: f&SbDirPrealloc > 0,
HasJournal: f&SbHasJournal > 0,
ExtAttr: f&SbExtAttr > 0,
ResizeInode: f&SbResizeInode > 0,
DirIndex: f&SbDirIndex > 0,
SparseV2: f&SbSparseV2 > 0,
}
}
// Superblock incompatible features.
// This is not exhaustive, unused features are not listed.
const (
// SbDirentFileType indicates that directory entries record the file type.
// We should use struct ext4_dir_entry_2 for dirents then.
SbDirentFileType = 0x2
// SbRecovery indicates that the filesystem needs recovery.
SbRecovery = 0x4
// SbJournalDev indicates that the filesystem has a separate journal device.
SbJournalDev = 0x8
// SbMetaBG indicates that the filesystem is using Meta block groups. Moves
// the group descriptors from the congested first block group into the first
// group of each metablock group to increase the maximum block groups limit
// and hence support much larger filesystems.
//
// See https://www.kernel.org/doc/html/latest/filesystems/ext4/overview.html#meta-block-groups.
SbMetaBG = 0x10
// SbExtents indicates that the filesystem uses extents. Must be set in ext4
// filesystems.
SbExtents = 0x40
// SbIs64Bit indicates that this filesystem addresses blocks with 64-bits.
// Hence can support 2^64 data blocks.
SbIs64Bit = 0x80
// SbMMP indicates that this filesystem has multiple mount protection.
//
// See https://www.kernel.org/doc/html/latest/filesystems/ext4/globals.html#multiple-mount-protection.
SbMMP = 0x100
// SbFlexBg indicates that this filesystem has flexible block groups. Several
// block groups are tied into one logical block group so that all the metadata
// for the block groups (bitmaps and inode tables) are close together for
// faster loading. Consequently, large files will be continuous on disk.
// However, this does not affect the placement of redundant superblocks and
// group descriptors.
//
// See https://www.kernel.org/doc/html/latest/filesystems/ext4/overview.html#flexible-block-groups.
SbFlexBg = 0x200
// SbLargeDir shows that large directory enabled. Directory htree can be 3
// levels deep. Directory htrees are allowed to be 2 levels deep otherwise.
SbLargeDir = 0x4000
// SbInlineData allows inline data in inodes for really small files.
SbInlineData = 0x8000
// SbEncrypted indicates that this fs contains encrypted inodes.
SbEncrypted = 0x10000
)
// IncompatFeatures represents a superblock's incompatible feature set. If the
// kernel does not understand any of these feature, it should refuse to mount.
type IncompatFeatures struct {
DirentFileType bool
Recovery bool
JournalDev bool
MetaBG bool
Extents bool
Is64Bit bool
MMP bool
FlexBg bool
LargeDir bool
InlineData bool
Encrypted bool
}
// ToInt converts superblock incompatible features back to its 32-bit rep.
func (f IncompatFeatures) ToInt() uint32 {
var res uint32
if f.DirentFileType {
res |= SbDirentFileType
}
if f.Recovery {
res |= SbRecovery
}
if f.JournalDev {
res |= SbJournalDev
}
if f.MetaBG {
res |= SbMetaBG
}
if f.Extents {
res |= SbExtents
}
if f.Is64Bit {
res |= SbIs64Bit
}
if f.MMP {
res |= SbMMP
}
if f.FlexBg {
res |= SbFlexBg
}
if f.LargeDir {
res |= SbLargeDir
}
if f.InlineData {
res |= SbInlineData
}
if f.Encrypted {
res |= SbEncrypted
}
return res
}
// IncompatFeaturesFromInt converts the integer representation of superblock
// incompatible features to IncompatFeatures struct.
func IncompatFeaturesFromInt(f uint32) IncompatFeatures {
return IncompatFeatures{
DirentFileType: f&SbDirentFileType > 0,
Recovery: f&SbRecovery > 0,
JournalDev: f&SbJournalDev > 0,
MetaBG: f&SbMetaBG > 0,
Extents: f&SbExtents > 0,
Is64Bit: f&SbIs64Bit > 0,
MMP: f&SbMMP > 0,
FlexBg: f&SbFlexBg > 0,
LargeDir: f&SbLargeDir > 0,
InlineData: f&SbInlineData > 0,
Encrypted: f&SbEncrypted > 0,
}
}
// Superblock readonly compatible features.
// This is not exhaustive, unused features are not listed.
const (
// SbSparse indicates sparse superblocks. Only groups with number either 0 or
// a power of 3, 5, or 7 will have redundant copies of the superblock and
// block descriptors.
SbSparse = 0x1
// SbLargeFile indicates that this fs has been used to store a file >= 2GiB.
SbLargeFile = 0x2
// SbHugeFile indicates that this fs contains files whose sizes are
// represented in units of logicals blocks, not 512-byte sectors.
SbHugeFile = 0x8
// SbGdtCsum indicates that group descriptors have checksums.
SbGdtCsum = 0x10
// SbDirNlink indicates that the new subdirectory limit is 64,999. Ext3 has a
// 32,000 subdirectory limit.
SbDirNlink = 0x20
// SbExtraIsize indicates that large inodes exist on this filesystem.
SbExtraIsize = 0x40
// SbHasSnapshot indicates the existence of a snapshot.
SbHasSnapshot = 0x80
// SbQuota enables usage tracking for all quota types.
SbQuota = 0x100
// SbBigalloc maps to the bigalloc feature. When set, the minimum allocation
// unit becomes a cluster rather than a data block. Then block bitmaps track
// clusters, not data blocks.
//
// See https://www.kernel.org/doc/html/latest/filesystems/ext4/overview.html#bigalloc.
SbBigalloc = 0x200
// SbMetadataCsum indicates that the fs supports metadata checksumming.
SbMetadataCsum = 0x400
// SbReadOnly marks this filesystem as readonly. Should refuse to mount in
// read/write mode.
SbReadOnly = 0x1000
)
// RoCompatFeatures represents a superblock's readonly compatible feature set.
// If the kernel does not understand any of these feature, it can still mount
// readonly. But if the user wants to mount read/write, the kernel should
// refuse to mount.
type RoCompatFeatures struct {
Sparse bool
LargeFile bool
HugeFile bool
GdtCsum bool
DirNlink bool
ExtraIsize bool
HasSnapshot bool
Quota bool
Bigalloc bool
MetadataCsum bool
ReadOnly bool
}
// ToInt converts superblock readonly compatible features to its 32-bit rep.
func (f RoCompatFeatures) ToInt() uint32 {
var res uint32
if f.Sparse {
res |= SbSparse
}
if f.LargeFile {
res |= SbLargeFile
}
if f.HugeFile {
res |= SbHugeFile
}
if f.GdtCsum {
res |= SbGdtCsum
}
if f.DirNlink {
res |= SbDirNlink
}
if f.ExtraIsize {
res |= SbExtraIsize
}
if f.HasSnapshot {
res |= SbHasSnapshot
}
if f.Quota {
res |= SbQuota
}
if f.Bigalloc {
res |= SbBigalloc
}
if f.MetadataCsum {
res |= SbMetadataCsum
}
if f.ReadOnly {
res |= SbReadOnly
}
return res
}
// RoCompatFeaturesFromInt converts the integer representation of superblock
// readonly compatible features to RoCompatFeatures struct.
func RoCompatFeaturesFromInt(f uint32) RoCompatFeatures {
return RoCompatFeatures{
Sparse: f&SbSparse > 0,
LargeFile: f&SbLargeFile > 0,
HugeFile: f&SbHugeFile > 0,
GdtCsum: f&SbGdtCsum > 0,
DirNlink: f&SbDirNlink > 0,
ExtraIsize: f&SbExtraIsize > 0,
HasSnapshot: f&SbHasSnapshot > 0,
Quota: f&SbQuota > 0,
Bigalloc: f&SbBigalloc > 0,
MetadataCsum: f&SbMetadataCsum > 0,
ReadOnly: f&SbReadOnly > 0,
}
}
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