32bit value indicating the total number of inodes, both used and free, in the file system. This value must be lower or equal to (s_inodes_per_group * number of block groups). It must be equal to the sum of the inodes defined in each block group.

32bit value indicating the total number of blocks in the system including all used, free and reserved. This value must be lower or equal to (s_blocks_per_group * number of block groups). It can be lower than the previous calculation if the last block group has a smaller number of blocks than s_blocks_per_group du to volume size. It must be equal to the sum of the blocks defined in each block group.

32bit value indicating the total number of blocks reserved for the usage of the super user. This is most useful if for some reason a user, maliciously or not, fill the file system to capacity; the super user will have this specified amount of free blocks at his disposal so he can edit and save configuration files.

32bit value indicating the total number of free blocks, including the number of reserved blocks (see s_r_blocks_count). This is a sum of all free blocks of all the block groups.

32bit value indicating the total number of free inodes. This is a sum of all free inodes of all the block groups.

32bit value identifying the first data block, in other word the id of the block containing the superblock structure.

Note that this value is always 0 for file systems with a block size larger than 1KB, and always 1 for file systems with a block size of 1KB. The superblock is always starting at the 1024th byte of the disk, which normally happens to be the first byte of the 3rd sector.

The block size is computed using this 32bit value as the number of bits to shift left the value 1024. This value may only be non-negative.

block size = 1024 << s_log_block_size;
    

Common block sizes include 1KiB, 2KiB, 4KiB and 8Kib. For information about the impact of selecting a block size, see Impact of Block Sizes.

The fragment size is computed using this 32bit value as the number of bits to shift left the value 1024. Note that a negative value would shift the bit right rather than left.

if( positive )
  fragmnet size = 1024 << s_log_frag_size;
else
  framgnet size = 1024 >> -s_log_frag_size;
    

32bit value indicating the total number of blocks per group. This value in combination with s_first_data_block can be used to determine the block groups boundaries. Due to volume size boundaries, the last block group might have a smaller number of blocks than what is specified in this field.

32bit value indicating the total number of fragments per group. It is also used to determine the size of the block bitmap of each block group.

32bit value indicating the total number of inodes per group. This is also used to determine the size of the inode bitmap of each block group. Note that you cannot have more than (block size in bytes * 8) inodes per group as the inode bitmap must fit within a single block. This value must be a perfect multiple of the number of inodes that can fit in a block ((1024<<s_log_block_size)/s_inode_size).

Unix time, as defined by POSIX, of the last time the file system was mounted.

Unix time, as defined by POSIX, of the last write access to the file system.

16bit value indicating how many time the file system was mounted since the last time it was fully verified.

16bit value indicating the maximum number of times that the file system may be mounted before a full check is performed.

16bit value identifying the file system as Ext2. The value is currently fixed to EXT2_SUPER_MAGIC of value 0xEF53.

16bit value indicating the file system state. When the file system is mounted, this state is set to EXT2_ERROR_FS. After the file system was cleanly unmounted, this value is set to EXT2_VALID_FS.

When mounting the file system, if a valid of EXT2_ERROR_FS is encountered it means the file system was not cleanly unmounted and most likely contain errors that will need to be fixed. Typically under Linux this means running fsck.

16bit value indicating what the file system driver should do when an error is detected. The following values have been defined:

16bit value identifying the minor revision level within its revision level.

Unix time, as defined by POSIX, of the last file system check.

Maximum Unix time interval, as defined by POSIX, allowed between file system checks.

32bit identifier of the os that created the file system. Defined values are:

32bit revision level value.

16bit value used as the default user id for reserved blocks.

16bit value used as the default group id for reserved blocks.

32bit value used as index to the first inode useable for standard files. In revision 0, the first non-reserved inode is fixed to 11 (EXT2_GOOD_OLD_FIRST_INO). In revision 1 and later this value may be set to any value.

16bit value indicating the size of the inode structure. In revision 0, this value is always 128 (EXT2_GOOD_OLD_INODE_SIZE). In revision 1 and later, this value must be a perfect power of 2 and must be smaller or equal to the block size (1<<s_log_block_size).

16bit value used to indicate the block group number hosting this superblock structure. This can be used to rebuild the file system from any superblock backup.

32bit bitmask of compatible features. The file system implementation is free to support them or not without risk of damaging the meta-data.

32bit bitmask of incompatible features. The file system implementation should refuse to mount the file system if any of the indicated feature is unsupported.

An implementation not supporting these features would be unable to properly use the file system. For example, if compression is being used and an executable file would be unusable after being read from the disk if the system does not know how to uncompress it.

32bit bitmask of “read-only” features. The file system implementation should mount as read-only if any of the indicated feature is unsupported.

128bit value used as the volume id. This should, as much as possible, be unique for each file system formatted.

16 bytes volume name, mostly unusued. A valid volume name would consist of only ISO-Latin-1 characters and be 0 terminated.

64 bytes directory path where the file system was last mounted. While not normally used, it could serve for auto-finding the mountpoint when not indicated on the command line. Again the path should be zero terminated for compatibility reasons. Valid path is constructed from ISO-Latin-1 characters.

32bit value used by compression algorithms to determine the compression method(s) used.

8-bit value representing the number of blocks the implementation should attempt to pre-allocate when creating a new regular file.

Linux 2.6.28 will only perform pre-allocation using Ext4 although no problem is expected if any version of Linux encounters a file with more blocks present than required.

8-bit value representing the number of blocks the implementation should attempt to pre-allocate when creating a new directory.

Linux 2.6.28 will only perform pre-allocation using Ext4 and only if the EXT4_FEATURE_COMPAT_DIR_PREALLOC flag is present. Since Linux does not de-allocate blocks from directories after they were allocated, it should be safe to perform pre-allocation and maintain compatibility with Linux.

16-byte value containing the uuid of the journal superblock. See Ext3 Journaling for more information.

32-bit inode number of the journal file. See Ext3 Journaling for more information.

32-bit device number of the journal file. See Ext3 Journaling for more information.

32-bit inode number, pointing to the first inode in the list of inodes to delete. See Ext3 Journaling for more information.

An array of 4 32bit values containing the seeds used for the hash algorithm for directory indexing.

An 8bit value containing the default hash version used for directory indexing.

A 32bit value containing the default mount options for this file system. TODO: Add more information here!

A 32bit value indicating the block group ID of the first meta block group. TODO: Research if this is an Ext3-only extension.

32bit block id of the first block of the “block bitmap” for the group represented.

The actual block bitmap is located within its own allocated blocks starting at the block ID specified by this value.

32bit block id of the first block of the “inode bitmap” for the group represented.

32bit block id of the first block of the “inode table” for the group represented.

16bit value indicating the total number of free blocks for the represented group.

16bit value indicating the total number of free inodes for the represented group.

16bit value indicating the number of inodes allocated to directories for the represented group.

16bit value used for padding the structure on a 32bit boundary.

12 bytes of reserved space for future revisions.

16bit value used to indicate the format of the described file and the access rights. Here are the possible values, which can be combined in various ways:

16bit user id associated with the file.

In revision 0, (signed) 32bit value indicating the size of the file in bytes. In revision 1 and later revisions, and only for regular files, this represents the lower 32-bit of the file size; the upper 32-bit is located in the i_dir_acl.

32bit value representing the number of seconds since january 1st 1970 of the last time this inode was accessed.

32bit value representing the number of seconds since january 1st 1970, of when the inode was created.

32bit value representing the number of seconds since january 1st 1970, of the last time this inode was modified.

32bit value representing the number of seconds since january 1st 1970, of when the inode was deleted.

16bit value of the POSIX group having access to this file.

16bit value indicating how many times this particular inode is linked (referred to). Most files will have a link count of 1. Files with hard links pointing to them will have an additional count for each hard link.

Symbolic links do not affect the link count of an inode. When the link count reaches 0 the inode and all its associated blocks are freed.

32-bit value representing the total number of 512-bytes blocks reserved to contain the data of this inode, regardless if these blocks are used or not. The block numbers of these reserved blocks are contained in the i_block array.

Since this value represents 512-byte blocks and not file system blocks, this value should not be directly used as an index to the i_block array. Rather, the maximum index of the i_block array should be computed from i_blocks / ((1024<<s_log_block_size)/512), or once simplified, i_blocks/(2<<s_log_block_size).

32bit value indicating how the ext2 implementation should behave when accessing the data for this inode.

32bit OS dependant value.

15 x 32bit block numbers pointing to the blocks containing the data for this inode. The first 12 blocks are direct blocks. The 13th entry in this array is the block number of the first indirect block; which is a block containing an array of block ID containing the data. Therefore, the 13th block of the file will be the first block ID contained in the indirect block. With a 1KiB block size, blocks 13 to 268 of the file data are contained in this indirect block.

The 14th entry in this array is the block number of the first doubly-indirect block; which is a block containing an array of indirect block IDs, with each of those indirect blocks containing an array of blocks containing the data. In a 1KiB block size, there would be 256 indirect blocks per doubly-indirect block, with 256 direct blocks per indirect block for a total of 65536 blocks per doubly-indirect block.

The 15th entry in this array is the block number of the triply-indirect block; which is a block containing an array of doubly-indrect block IDs, with each of those doubly-indrect block containing an array of indrect block, and each of those indirect block containing an array of direct block. In a 1KiB file system, this would be a total of 16777216 blocks per triply-indirect block.

In the original implementation of Ext2, a value of 0 in this array effectively terminated it with no further block defined. In sparse files, it is possible to have some blocks allocated and some others not yet allocated with the value 0 being used to indicate which blocks are not yet allocated for this file.

32bit value used to indicate the file version (used by NFS).

32bit value indicating the block number containing the extended attributes. In revision 0 this value is always 0.

In revision 0 this 32bit value is always 0. In revision 1, for regular files this 32bit value contains the high 32 bits of the 64bit file size.

32bit value indicating the location of the file fragment.

96bit OS dependant structure.

32bit inode number of the file entry. A value of 0 indicate that the entry is not used.

16bit unsigned displacement to the next directory entry from the start of the current directory entry. This field must have a value at least equal to the length of the current record.

The directory entries must be aligned on 4 bytes boundaries and there cannot be any directory entry spanning multiple data blocks. If an entry cannot completely fit in one block, it must be pushed to the next data block and the rec_len of the previous entry properly adjusted.

8bit unsigned value indicating how many bytes of character data are contained in the name.

8bit unsigned value used to indicate file type.

Name of the entry. The ISO-Latin-1 character set is expected in most system. The name must be no longer than 255 bytes after encoding.

Here's a sample of the home directory of one user on my system:

$ ls -1a ~
.
..
.bash_profile
.bashrc
mbox
public_html
tmp
    

For which the following data representation can be found on the storage device:

The indexed directory entries are used to quickly lookup the inode number associated with the hash of a filename. These entries are located immediately following the fake linked directory entry of the directory data blocks, or immediately following the the section called “Indexed Directory Root”.

The first indexed directory entry, rather than containing an actual hash and block number, contains the maximum number of indexed directory entries that can fit in the block and the actual number of indexed directory entries stored in the block. The format of this special entry is detailed in Table 4.7, “Indexed Directory Entry Count and Limit Structure”.

The other directory entries are sorted by hash value starting from the smallest to the largest numerical value.

Lookup is straightforword:

- Compute a hash of the name
- Read the index root
- Use binary search (linear in the current code) to find the
  first index or leaf block that could contain the target hash
  (in tree order)
- Repeat the above until the lowest tree level is reached
- Read the leaf directory entry block and do a normal Ext2
  directory block search in it.
- If the name is found, return its directory entry and buffer
- Otherwise, if the collision bit of the next directory entry is
  set, continue searching in the successor block
    

Normally, two logical blocks of the file will need to be accessed, and one or two metadata index blocks. The effect of the metadata index blocks can largely be ignored in terms of disk access time since these blocks are unlikely to be evicted from cache. There is some small CPU cost that can be addressed by moving the whole directory into the page cache.

Insertion of new entries into the directory is considerably more complex than lookup, due to the need to split leaf blocks when they become full, and to satisfy the conditions that allow hash key collisions to be handled reliably and efficiently. I'll just summarize here:

- Probe the index as for lookup
- If the target leaf block is full, split it and note the block
  that will receive the new entry
- Insert the new entry in the leaf block using the normal Ext2
  directory entry insertion code.
    

The details of splitting and hash collision handling are somewhat messy, but I will be happy to dwell on them at length if anyone is interested.

In brief, when a leaf node fills up and we want to put a new entry into it the leaf has to be split, and its share of the hash space has to be partitioned. The most straightforward way to do this is to sort the entrys by hash value and split somewhere in the middle of the sorted list. This operation is log(number_of_entries_in_leaf) and is not a great cost so long as an efficient sorter is used. I used Combsort for this, although Quicksort would have been just as good in this case since average case performance is more important than worst case.

An alternative approach would be just to guess a median value for the hash key, and the partition could be done in linear time, but the resulting poorer partitioning of hash key space outweighs the small advantage of the linear partition algorithm. In any event, the number of entries needing sorting is bounded by the number that fit in a leaf.

Some complexity is introduced by the need to handle sequences of hash key collisions. It is desireable to avoid splitting such sequences between blocks, so the split point of a block is adjusted with this in mind. But the possibility still remains that if the block fills up with identically-hashed entries, the sequence may still have to be split. This situation is flagged by placing a 1 in the low bit of the index entry that points at the sucessor block, which is naturally interpreted by the index probe as an intermediate value without any special coding. Thus, handling the collision problem imposes no real processing overhead, just come extra code and a slight reduction in the hash key space. The hash key space remains sufficient for any conceivable number of directory entries, up into the billions.

The exact properties of the hash function critically affect the performance of this indexing strategy, as I learned by trying a number of poor hash functions, at times intentionally. A poor hash function will result in many collisions or poor partitioning of the hash space. To illustrate why the latter is a problem, consider what happens when a block is split such that it covers just a few distinct hash values. The probability of later index entries hashing into the same, small hash space is very small. In practice, once a block is split, if its hash space is too small it tends to stay half full forever, an effect I observed in practice.

After some experimentation I came up with a hash function that gives reasonably good dispersal of hash keys across the entire 31 bit key space. This improved the average fullness of leaf blocks considerably, getting much closer to the theoretical average of 3/4 full.

But the current hash function is just a place holder, waiting for an better version based on some solid theory. I currently favor the idea of using crc32 as the default hash function, but I welcome suggestions.

Inevitably, no matter how good a hash function I come up with, somebody will come up with a better one later. For this reason the design allows for additional hash functiones to be added, with backward compatibility. This is accomplished simply, by including a hash function number in the index root. If a new, improved hash function is added, all the previous versions remain available, and previously created indexes remain readable.

Of course, the best strategy is to have a good hash function right from the beginning. The initial, quick hack has produced results that certainly have not been disappointing.

OK, if you have read this far then this is no doubt the part you've been waiting for. In short, the performance improvement over normal Ext2 has been stunning. With very small directories performance is similar to standard Ext2, but as directory size increases standard Ext2 quickly blows up quadratically, while htree-enhanced Ext2 continues to scale linearly.

Uli Luckas ran benchmarks for file creation in various sizes of directories ranging from 10,000 to 90,000 files. The results are pleasing: total file creation time stays very close to linear, versus quadratic increase with normal Ext2.

Time to create:

		Indexed		Normal
		=======		======
10000 Files:	0m1.350s	0m23.670s
20000 Files:	0m2.720s	1m20.470s
30000 Files:	0m4.330s	3m9.320s
40000 Files:	0m5.890s	5m48.750s
50000 Files:	0m7.040s	9m31.270s
60000 Files:	0m8.610s	13m52.250s
70000 Files:	0m9.980s	19m24.070s
80000 Files:	0m12.060s	25m36.730s
90000 Files:	0m13.400s	33m18.550s
    

The original paper by Daniel Phillips is at https://www.kernel.org/doc/ols/2002/ols2002-pages-425-438.pdf

All of these tests are CPU-bound, which may come as a surprise. The directories fit easily in cache, and the limiting factor in the case of standard Ext2 is the looking up of directory blocks in buffer cache, and the low level scan of directory entries. In the case of htree indexing there are a number of costs to be considered, all of them pretty well bounded. Notwithstanding, there are a few obvious optimizations to be done:

- Use binary search instead of linear search in the interior index
  nodes.

- If there is only one leaf block in a directory, bypass the index
  probe, go straight to the block.

- Map the directory into the page cache instead of the buffer cache.
    

Each of these optimizations will produce a noticeable improvement in performance, but naturally it will never be anything like the big jump going from N**2 to Log512(N), ~= N. In time the optimizations will be applied and we can expect to see another doubling or so in performance.

There will be a very slight performance hit when the directory gets big enough to need a second level. Because of caching this will be very small. Traversing the directories metadata index blocks will be a bigger cost, and once again, this cost can be reduced by moving the directory blocks into the page cache.

Typically, we will traverse 3 blocks to read or write a directory entry, and that number increases to 4-5 with really huge directories. But this is really nothing compared to normal Ext2, which traverses several hundred blocks in the same situation.

There isn't much to say about those, they are located with the SGID and SUID bits in ext2_inode.i_mode.

The size of a file can be determined by looking at the ext2_inode.i_size field.

Under most implementations, the owner and group are 16bit values, but on some recent Linux and Hurd implementations the owner and group id are 32bit. When 16bit values are used, only the “low” part should be used as valid, while when using 32bit value, both the “low” and “high” part should be used, the high part being shifted left 16 places then added to the low part.

The low part of owner and group are located in ext2_inode.i_uid and ext2_inode.i_gid respectively.

The high part of owner and group are located in ext2_inode.osd2.hurd.h_i_uid_high and ext2_inode.osd2.hurd.h_i_gid_high, respectively, for Hurd and located in ext2_inode.osd2.linux.l_i_uid_high and ext2_inode.osd2.linux.l_i_gid_high, respectively, for Linux.

The block header is followed by multiple entry descriptors. These entry descriptors are variable in size, and aligned to EXT2_XATTR_PAD (4) byte boundaries. The entry descriptors are sorted by attribute name, so that two extended attribute blocks can be compared efficiently.

Attribute values are aligned to the end of the block, stored in no specific order. They are also padded to EXT2_XATTR_PAD (4) byte boundaries. No additional gaps are left between them.

offset  size    description
------- ------- -----------
      0       1 e_name_len
      1       1 e_name_index
      2       2 e_value_offs
      4       4 e_value_block
      8       4 e_value_size
     12       4 e_hash
     16     ... e_name
    

The total size of an attribute entry is always rounded to the next 4-bytes boundary.

Enabling this bit will cause random data to be written over the file's content several times before the blocks are unlinked. Note that this is highly implementation dependant and as such, it should not be assumed to be 100% secure. Make sure to study the implementation notes before relying on this option.

When supported by the implementation, setting this bit will cause the deleted data to be moved to a temporary location, where the user can restore the original file without any risk of data lost. This is most useful when using ext2 on a desktop or workstation.

The file's content is compressed. There is no note about the particular algorithm used other than maybe the s_algo_bitmap field of the superblock structure.

The file's content in memory will be constantly synchronized with the content on disk. This is mostly used for very sensitive boot files or encryption keys that you do not want to lose in case of a crash.

The blocks associated with the file will not be exchanged. If for any reason a file system defragmentation is launched, such files will not be moved. Mostly used for stage2 and stage1.5 boot loaders.

Writing can only be used to append content at the end of the file and not modify the current content. Example of such use could be mailboxes, where anybody could send a message to a user but not modify any already present.

Setting this bit will protect the file from deletion. As long as this bit is set, even if the i_links_count is 0, the file will not be removed.

The i_atime field of the inode structure will not be modified when the file is accessed if this bit is set. The only good use I can think of that are related to security.

I do not have information at this moment about the use of this bit.

This flag is set if one or more blocks are compressed. You can have more information about compression on ext2 at http://www.netspace.net.au/~reiter/e2compr/ Note that the project has not been updated since 1999.

When this flag is set, the file system implementation will not uncompress the data before fowarding it to the application but will rather give it as is.

This flag is set if an error was detected when trying to uncompress the file.

When this bit is set, the format of the directory file is hash indexed. This is covered in details in the section called “Indexed Directory Format”.