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Operating Systems CMPSC 473

Operating Systems CMPSC 473. I/O Management (3) December 07, 2010 - Lecture 24 Instructor: Bhuvan Urgaonkar. File System. Read Sectors. Write Sectors. Block Interface. Controller (FTL). RAM. Flash Memory. Flash Solid State Drive (SSD). Basics of NAND Flash Memory. Data. OOB. Page.

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Operating Systems CMPSC 473

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  1. Operating SystemsCMPSC 473 I/O Management (3) December 07, 2010 - Lecture 24 Instructor: Bhuvan Urgaonkar

  2. File System Read Sectors Write Sectors Block Interface Controller (FTL) RAM Flash Memory Flash Solid State Drive (SSD)

  3. Basics of NAND Flash Memory Data OOB Page Page Page Page …… Page Data OOB Data OOB Data OOB Page Page Page Page Page Page …… …… …… …… Page Page Page NAND Flash Block Block Block • Three operations: read, write, erase • Reads and writes are done at the granularity of a page (2KB or 4KB) • Erases are done at the granularity of a block • Block: A collection of physically contiguous pages (64 or 128) • Block erase is the slowest operation requiring about 2ms • Writes can only be done on erased pages

  4. Out-of-Place Updates Update Data LPN=A, V LPN=A, V Free Invalid LPN=B, V LPN=C, V OOB LPN PPN (PBN, Offset) (0, 3) A A (0, 0) B (0, 1) C (0, 2) Flash Mapping Table Block 0 • Over-writes on the same location (page) are expensive • Updates are written to a free page • OOB area • Keeps valid/free/invalid status • Stores LPN, used to reconstruct mapping table upon power failure

  5. Garbage Collection • Reclaims invalid pages • Typically, called when free space falls below a threshold • Victim block selection • Small # valid pages (reduce copying overhead) • Small # overall erases (wear level) 5

  6. Flash Translation Layer (FTL) • Flash Translation Layer • Emulates a normal block device interface • Hides the presence of erase operation/erase-before-write • Address translation, garbage collection, and wear-leveling • Address Translation • Mapping table present in small RAM within the flash device

  7. Latencies compared

  8. Cost • Main memory is much more expensive than disk storage • The cost per megabyte of hard disk storage is competitive with magnetic tape if only one tape is used per drive. • The cheapest tape drives and the cheapest disk drives have had about the same storage capacity over the years. • Tertiary storage gives a cost savings only when the number of cartridges is considerably larger than the number of drives.

  9. Memory, Disk Price Trends Compared

  10. CPU/Memory Sub-system

  11. Disk Scheduling • Ordering of requests issued to disk • In OS: Device driver: order requests sent to controller • In controller: order requests executed by disk arm • Typical goal: Minimize seek time (our focus) • Seek time dependent on seek distance • More advanced • Incorporate rotational latency as well • Incorporate notions of fairness

  12. Disk Scheduling (Cont.) • Several algorithms exist to schedule servicing of disk I/O requests. • We illustrate them with a request queue (0-199). 98, 183, 37, 122, 14, 124, 65, 67 Head pointer 53

  13. FCFS Illustration shows total head movement of 640 cylinders.

  14. SSTF • Selects the request with the minimum seek time from the current head position. • SSTF scheduling is a form of SJF scheduling; may cause starvation of some requests. • Illustration shows total head movement of 236 cylinders.

  15. SSTF (Cont.)

  16. SCAN • The disk arm starts at one end of the disk, and moves toward the other end, servicing requests until it gets to the other end of the disk, where the head movement is reversed and servicing continues. • Sometimes called the elevator algorithm. • Illustration shows total head movement of 208 cylinders.

  17. SCAN (Cont.)

  18. C-SCAN • Provides a more uniform wait time than SCAN. • The head moves from one end of the disk to the other. servicing requests as it goes. When it reaches the other end, however, it immediately returns to the beginning of the disk, without servicing any requests on the return trip. • Treats the cylinders as a circular list that wraps around from the last cylinder to the first one.

  19. C-SCAN (Cont.)

  20. C-LOOK • Version of C-SCAN • Arm only goes as far as the last request in each direction, then reverses direction immediately, without first going all the way to the end of the disk.

  21. C-LOOK (Cont.)

  22. File-System Structure • File structure • Logical storage unit • Collection of related information • File system resides on secondary storage (disks) • File system organized into layers • File control block – storage structure consisting of information about a file

  23. Layered File System

  24. A Typical File Control Block

  25. In-Memory FS Structures • Opening a file • Reading a file

  26. File-System Structure • File structure • Logical storage unit • Collection of related information • File system resides on secondary storage (disks) • File system organized into layers • File control block – storage structure consisting of information about a file

  27. Virtual File Systems • Virtual File Systems (VFS) provide an object-oriented way of implementing file systems. • VFS allows the same system call interface (the API) to be used for different types of file systems. • The API is to the VFS interface, rather than any specific type of file system.

  28. Schematic View of Virtual File System

  29. Directory Implementation • Linear list of file names with pointer to the data blocks. • simple to program • time-consuming to execute • Hash Table – linear list with hash data structure. • decreases directory search time • collisions – situations where two file names hash to the same location • fixed size

  30. Allocation Methods • An allocation method refers to how disk blocks are allocated for files: • Contiguous allocation • Linked allocation • Indexed allocation

  31. Contiguous Allocation • Each file occupies a set of contiguous blocks on the disk • Simple – only starting location (block #) and length (number of blocks) are required • Wasteful of space (dynamic storage-allocation problem) • Files cannot grow

  32. Contiguous Allocation of Disk Space

  33. pointer block = Linked Allocation • Each file is a linked list of disk blocks: blocks may be scattered anywhere on the disk.

  34. Linked Allocation (Cont.) • Simple – need only starting address • Free-space management system – no waste of space • Mapping Q LA/508 R Block to be accessed is the Qth block in the linked chain of blocks representing the file. Displacement into block = R + 4 File-allocation table (FAT) – disk-space allocation used by MS-DOS and OS/2.

  35. Linked Allocation

  36. File-Allocation Table

  37. Indexed Allocation • Brings all pointers together into the index block. • Logical view: index table

  38. Example of Indexed Allocation

  39. Indexed Allocation (Cont.) • Need index table • Random access • Dynamic access without external fragmentation, but have overhead of index block. • Mapping from logical to physical in a file of maximum size of 256K words and block size of 512 words. We need only 1 block for index table. Q LA/512 R Q = displacement into index table R = displacement into block

  40. Indexed Allocation – Mapping (Cont.) • Mapping from logical to physical in a file of unbounded length (block size of 512 words). • Linked scheme – Link blocks of index table (no limit on size). Q1 LA / (512 x 508) R1 Q1= block of index table R1is used as follows: Q2 R1 / 512 R2 Q2 = displacement into block of index table R2 displacement into block of file:

  41. Indexed Allocation – Mapping (Cont.) • Two-level index (maximum file size is 5123) Q1 LA / (512 x 512) R1 Q1 = displacement into outer-index R1 is used as follows: Q2 R1 / 512 R2 Q2 = displacement into block of index table R2 displacement into block of file

  42. Indexed Allocation – Mapping (Cont.)  outer-index file index table

  43. Combined Scheme: UNIX (4K bytes per block)

  44. Free-Space Management • Bit vector (n blocks) 0 1 2 n-1 … 0  block[i] free 1  block[i] occupied bit[i] =  Block number calculation (number of bits per word) * (number of 0-value words) + offset of first 1 bit

  45. Free-Space Management (Cont.) • Bit map requires extra space • Example: block size = 212 bytes disk size = 230 bytes (1 gigabyte) n = 230/212 = 218 bits (or 32K bytes) • Easy to get contiguous files • Linked list (free list) • Cannot get contiguous space easily • No waste of space

  46. Linked Free Space List on Disk

  47. Efficiency and Performance • Efficiency dependent on: • disk allocation and directory algorithms • types of data kept in file’s directory entry • Performance • disk cache – separate section of main memory for frequently used blocks • free-behind and read-ahead – techniques to optimize sequential access • improve PC performance by dedicating section of memory as virtual disk, or RAM disk

  48. Page Cache • A page cache caches pages rather than disk blocks using virtual memory techniques • Memory-mapped I/O uses a page cache • Routine I/O through the file system uses the buffer (disk) cache • This leads to the following figure

  49. I/O W/O a Unified Buffer Cache

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