1. A FAST FILE SYSTEM FOR UNIX Marshall K. Mckusick William N. Joy Samuel J. Leffler Robert S. Fabry CSRG, UC Berkeley

2. PAPER HIGHLIGHTS Main objective of FFS was to improve file system bandwidth Key ideas were: –Subdividing disk partitions into cylinder groups, each having both i-nodes and data blocks –Using larger blocks but managing block fragments –Replicating the superblock

3. THE OLD UNIX FILE SYSTEM Each disk partition contains: –a superblock containing the parameters of the file system disk partition –an i-list with one i-node for each file or directory in the disk partition and a free list. –the data blocks (512 bytes)

4. More details File systems cannot span multiple partitions –Must use mount() to merge several file systems into a single tree S uperblock contains –The number of data blocks in the file system – A count of the maximum number of files – A pointer to the free list

5. File types Three types of files – ordinary files : uninterpreted sequences of bytes – directories : accessed through special system calls – special files : allow access to hardware devices but are not really files

6. Ordinary files (I) Five basic file operations are implemented: –open() returns a file descriptor –read() reads so many bytes –write() writes so many bytes –lseek() changes position of current byte –close() destroys the file descriptor

7. Ordinary files (II) All reading and writing are sequential. The effect of direct access is achieved by manipulating the offset through lseek() Files are stored into fixed-size blocks Block boundaries are hidden from the users Same as in FAT and NTFS file systems

8. The file metadata Include file size, file owner, access rights, last time the file was modified, … but not the file name Stored in the file i-node Accessed through special system calls: chmod(), chown(),...

9. I/O buffering UNIX caches in main memory –I-nodes of opened files –Recently accessed file blocks Delayed write policy –Increases the I/O throughput –Will result in lost writes whenever a process or the system crashes Terminal I/O are buffered one line at a time

10. Map file names with i-node addresses Do not contain any other information! Directories (I)

11. Directories (II) Two or more directory entries can point to the same i-node –A file can have several names Directory subtrees cannot cross file system boundaries To avoid loops in directory structure, directory files cannot have more than one pathname

12. “Mounting” a file system Root partition bin usr / Other partition mount After mount, root of second partition can be accessed as /usr

13. Special files Map file names with system devices: – /dev/tty your terminal screen – /dev/kmem the kernel memory – /dev/fd0 the floppy drive Main motivation is to allow accessing these devices as if they were files: –no separate I/O constructs for devices

14. A file system Superblock I-nodes Data Blocks

15. The i-node (I) Each i-node contains: –The user-id and the group-id of the file owner –The file protection bits –The file size –The times of file creation, last usage and last modification

16. The i-node (II) –The number of directory entries pointing to the file, and –A flag indicating if the file is a directory, an ordinary file, or a special file. –Thirteen block addresses The file name(s) can be found in the directory entries pointing to the i-node.

17. Storing block addresses

18. Addressing file contents I-node has ten direct block addresses –First 5,120 bytes of a file are directly accessible from the i-node Next block address contains address of a block containing 512/4 = 128 blockaddresses –Next 64K of a file require one level of indirection

19. Addressing file contents Next block address allows to access a total of (512/4) 2 = 16K data blocks –Next 8 MB of a file require two levels of indirection Last block address allows to access a total of (512/4) 3 = 2M blocks –Next GB of a file requires one level of indirection

20. Explanation File sizes can vary from a few hundred bytes to a few gigabytes with a hard limit of 4 gigabytes The designers of UNIX selected an i-node organization that –Wasted little space for small files –Allowed very large files

21. Discussion What is the true cost of accessing large files? –UNIX caches i-nodes and data blocks –When we access sequentially a very large file we fetch only once each block of pointers Very small overhead –Random access will result in more overhead if we cannot cache all blocks of pointers

22. First Berkeley modifications Staging modifications to critical file system information so that they could either be completed or repaired cleanly after a crash Increasing the block size to 1,024 bytes –Improved performance by a factor of more than two – Did not let file system use more than four percent of the disk bandwidth

23. What is disk bandwidth? Maximum throughput of a file system if disk drive was continuously transferring data Actual bandwidths are much lower because of –Disk seeks –Disk rotational latency

24. Major issue As files were created and deleted, free list became “entirely random” – Files were allocated random blocks that could be anywhere on the disk – Caused a very significant degradation of file system performance (factor of 5!) Problem is not unique to old UNIX file system –Still present in FAT and NTFS file systems

25. THE FAST FILE SYSTEM BSD 4.2 introduced the “fast file system” – Superblock is replicated on different cylinders of disk –Have one i-node table per group of cylinders It minimizes disk arm motions –I-node has now 15 block addresses –Minimum block size is 4K 15 th block address is never used

26. Cylinder groups Each disk partition is subdivided into groups of consecutive cylinders Each cylinder group contains a bit map of all available blocks in the cylinder group –Better than linked list The file system will attempt to keep consecutive blocks of the same file on the same cylinder group

27. Larger block sizes FFS uses larger blocks –At least 4 KB Blocks can be subdivided into 2, 4, or 8 fragments that can be used to store – Small files – The tails of larger files

28. Replicating the superblock Each cylinder group has Ensures that a single head crash would never delete all copies of the superblock

29. Explanations (I) Increasing the block size to 4K eliminates the third level of indirection Keeping consecutive blocks of the same file on the same cylinder group reduces disk arm motions

30. Internal fragmentation issues Since UNIX file systems typically store many very small files, increasing the block size results in an unacceptably high level of internal fragmentation

31. The solution Using 4K blocks without allowing fragments would have wasted 45.6% of the disk space –This would be less true today FFS solution is to allocate block fragments to small files and tail end or large files –Allows efficient sequential access to large files – Minimizes disk fragmentation

32. Layout policies (I) FFS tries to place all data blocks for a file in the same cylinder group, preferably –At rotationally optimal positions –In the same cylinder. Large files could quickly use up all available space in the cylinder group

33. Layout policies (II) FFS redirects block allocation to a different cylinder group –a file exceeds 48 kilobytes –at every megabyte thereafter

34. PERFORMANCE IMPROVEMENTS Read rates improved by a factor of seven Write rates improved by a factor of almost three Transfer rates for FFS do not deteriorate over time –No need to “defragment” the file system from time to time –Must keep a reasonable amount of free space Ten percent would be ideal

35. Limitations of approach (I) Even FFS does not utilize full disk bandwidth –Log-structured file systems do most writes in sequential fashion Crashes may leave the file system in an inconsistent state –Must check the consistency of the file system at boot time

36. Limitations of approach (II) Most of the good performance of FFS is due to its extensive use of I/O buffering – Physical writes are totally asynchronous Metadata updates must follow a strict order –Cannot create new directory entry before new i-node it points to –Cannot delete old i-node before deleting last directory entry pointing to it

37. Example: Creating a file (I) abc ghi i-node-1 i-node-3 Assume we want to create new file “tuv”

38. Example: Creating a file (II) abc ghi tuv i-node-1 i-node-3 Cannot write directory entry “tuv” before i-node ?

39. Limitations of approach (III) Out-of-order metadata updates can leave the file system in temporary inconsistent state –Not a problem as long as the system does not crash between the two updates –Systems are known to crash FFS performs synchronous updates of directories and i-nodes – Solution is safe but costly

40. OTHER ENHANCEMENTS Longer file names –256 characters File locking Symbolic links Disk quotas

41. File locking Allows to control shared access to a file We want a one writer/multiple readers policy Older versions of UNIX did not allow file locking System V allows file and record locking at a byte-level granularity through fcntl() Berkeley UNIX has purely advisory file locks: like asking people to knock before entering

42. Symbolic links With Berkeley UNIX, symbolic links you can write ln -s /usr/bin/programs /bin/programs even tough /usr/bin/programs and /bin/programs are in two different partitions Symbolic links point to another directory entry instead of the i-node.