1. Outline File Management Structured files
Low-level file implementations

2. Operating System Components
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3. Why Programmers Need Files
Persistent storage
Shared device
HTML
Editor
<head> …
</head>
<body>
</body>
Web
Browser
Structured information
Can be read by any application
Accessibility
Protocol
foo.html
File
Manager
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4. File system context
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5. Fig 13-2: The External View of the File Manager
Application
Program
CreateFile()
ReadFile()
CloseHandle()
SetFilePointer()
WriteFile()
mount()
write()
open()
close()
read()
lseek()
File Mgr
Device Mgr
Memory Mgr
Process Mgr
File Mgr
Device Mgr
Memory Mgr
Process Mgr
UNIX
Windows
Hardware
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6. Levels in a file system
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7. Information Structure
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8. Logical structures in a file
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9. Low-Level Files
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10. File systems File system
A data structure on a disk that holds files
actually a file system is in a disk partition
a technical term different from a “file system” as the part of the OS that implements files
File systems in different OSs have different internal structures
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11. A file system layout
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12. File system descriptor
The data structure that defines the file system
Typical fields
size of the file system (in blocks)
size of the file descriptor area
first block in the free block list
location of the file descriptor of the root directory of the file system
times the file system was created, last modified, and last used
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13. File system layout variations
MS/DOS uses a FAT (file allocation table) file system
so does the Macintosh OS (although the MacOS layout is different)
New UNIX file systems use cylinder groups (mini-file systems) to achieve better locality of file data
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14. Locating file data The logical file is divided into logical blocks
Each logical block is mapped to a physical disk block
The file descriptor contains data on how to perform this mapping
there are many methods for performing this mapping
we will look at several of them
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15. Dividing a file into blocks
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16. Contiguous Allocation
Each file occupies a set of contiguous blocks on the disk
Simple – only starting location and length are required
Random access
Wasteful of space (dynamic storage-allocation problem)
Files cannot grow
Mapping from logical to physical
Block to be accessed = Q + starting address
Displacement into block = R R
LA/512 Q
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17. A contiguous file
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18. A contiguous file – cont.
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19. Keeping a file in pieces
We need a block pointer for each logical block, an array of block pointers
block mapping indexes into this array
Each file is a linked list of disk blocks
But where do we keep this array?
usually it is not kept as contiguous array
the array of disk pointers is like a second related file (that is 1/1024 as big)
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20. Block pointers in the file descriptor
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21. Block pointers in contiguous disk blocks
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22. Block pointers in the blocks
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23. Block pointers in the blocks – cont.
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24. Block pointers in an index block
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25. Block pointers in an index block – cont.
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26. Chained index blocks
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27. Two-level index blocks
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28. Two-level index blocks – cont.
primary index
secondary index table
data blocks
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29. The UNIX hybrid method
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30. The UNIX hybrid method – cont.
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31. Inverted disk block index (FAT)
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32. DOS FAT Files … File Descriptor File Access Table (FAT) 43 254 107
Disk
Block
File Descriptor … 43
107
254
File Access Table (FAT)
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33. Free-Space Management
Bit vector (n blocks) 1 2
n-1 …
1  block[i] free
0  block[i] occupied
bit[i] =

First free block number
(number of bits per word) *
(number of 0-value words) +
offset of first 1 bit
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34. 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
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35. Free list organization
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36. Free-Space Management - cont.
Need to protect:
Pointer to free list
Bit map
Must be kept on disk
Copy in memory and disk may differ.
Cannot allow for block[i] to have a situation where bit[i] = 0 in memory and bit[i] = 1 on disk.
Solution:
Set bit[i] = 0 in disk.
Allocate block[i]
Set bit[i] = 0 in memory
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37. Implementing Low Level Files
Secondary storage device contains:
Volume directory (sometimes a root directory for a file system)
External file descriptor for each file
The file contents
Manages blocks
Assigns blocks to files (descriptor keeps track)
Keeps track of available blocks
Maps to/from byte stream
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38. Disk Organization … … … … … … … … Boot Sector Volume Directory
Blk0
Blk1 …
Blkk-1
Track 0, Cylinder 0 …
Blkk
Blkk+1
Blk2k-1
Track 0, Cylinder 1 … …
Blk
Blk
Blk
Track 1, Cylinder 0 … …
Blk
Blk
Blk
Track N-1, Cylinder 0 … …
Blk
Blk
Blk
Track N-1, Cylinder M-1
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39. Low-level File System Architecture
Block 0
b0 b1 b2 b3 … …
bn-1 . . .
Sequential Device
Randomly Accessed Device
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40. File Descriptors External name Current state Sharable Owner User Locks
Protection settings
Length
Time of creation
Time of last modification
Time of last access
Reference count
Storage device details
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41. An open() Operation Locate the on-device (external) file descriptor
Extract info needed to read/write file
Authenticate that process can access the file
Create an internal file descriptor in primary memory
Create an entry in a “per process” open file status table
Allocate resources, e.g., buffers, to support file usage
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42. File Manager Data Structures
Keep the state of the process-file session 2
Copy info from external to the open file descriptor 1
Open File
Descriptor
Process-File
Session 3
Return a reference to the data structure
External File Descriptor
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43. Opening a UNIX File On-Device File Descriptor Open File Table
fid = open(“fileA”, flags); …
read(fid, buffer, len);
0 stdin
1 stdout
2 stderr
3 ...
Open File Table
File structure
inode
Internal File Descriptor
On-Device File Descriptor
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44. Reading and Writing the Byte Stream
Two stages
Reading bytes into or writing bytes out of the memory copy of the block
Reading the physical blocks into or writing them out of memory from/to storage devices
Packing or unmarshalling procedure converts secondary storage blocks into a byte stream
Unpacking or marshalling procedure converts a byte stream into blocks
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45. Marshalling the Byte Stream
Must read at least one buffer ahead on input
Must write at least one buffer behind on output
Seek  flushing the current buffer and finding the correct one to load into memory
Inserting/deleting bytes in the interior of the stream
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46. Full Block Buffering Storage devices use block I/O
Files place an explicit order on the bytes
Therefore, it is possible to predict what is likely to be read after a byte
When file is opened, manager reads as many blocks ahead as feasible
After a block is logically written, it is queued for writing behind, whenever the disk is available
Buffer pool – usually variably sized, depending on virtual memory needs
Interaction with the device manager and memory manager
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47. Supporting Other Storage Abstractions
Low-level file systems avoid encoding record-level functionality
If applications use very large or very small records, a generic file manager may not be efficient
Some operating systems provide a higher-layer file system to support applications with large or small files
Database management systems and multimedia documents are examples
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48. Structured Files
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49. Record-Oriented Sequential Files
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50. Electronic Mail Example
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51. Indexed Sequential Files
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52. Database Management Systems
A database is a very highly structured set of information
Stored across different files
Optimized to minimize access time
DBMSs implementation
Some DBMSs use the normal files provided by the OS for generic use
Some use their own storage device block
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53. Disk compaction
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54. Memory-mapped Files
A file’s contents are mapped directly into the virtual address space
Files can be read from or written to by referencing the corresponding virtual addresses
Memory-mapped files are very useful when a file is shared or accessed repeatedly
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55. Memory-mapped Files – cont.
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56. Directories
A directory is a set of logically associated files and other directories of files
Directories are the mechanism we use to organize files
The file manager provides a set of commands to manage directories
Traverse a directory
Enumerate a list of all files and nested directories
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57. Directory Structures How should files be organized within directory?
Flat name space
All files appear in a single directory
Hierarchical name space
Directory contains files and subdirectories
Each file/directory appears as an entry in exactly one other directory -- a tree
Popular variant: All directories form a tree, but a file can have multiple parents.
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58. Directory Structures
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59. Directory Structures – cont.
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60. A directory tree
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61. Directory Implementation
Device Directory
A device can contain a collection of files
Easier to manage if there is a root for every file on the device -- the device root directory
File Directory
Typical implementations have directories implemented as a file with a special format
Entries in a file directory are handles for other files (which can be files or subdirectories)
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62. 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
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63. Mounting file systems Each file system has a root directory
We can combine file systems by mounting
that is, link a directory in one file system to the root directory of another file system
This allows us to build a single tree out of several file systems
This can also be done across a network, mounting file systems on other machines
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64. UNIX mount Command FS mount FS at foo / bin usr etc foo bill nutt abc
blah
cde
xyz FS
mount FS at foo
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65. Mounting a file system
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66. VFS-based File Manager
File System Independent
Part of File Manager
Exports OS-specific API
Virtual File System Switch
MS-DOS Part of
File Manager
ISO 9660 Part of
ext2 Part of …
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67. NFS Architecture
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68. Summary of File Storage Methods
Contiguous files
Interleaved files
File pointers in the file descriptor
Contiguous file pointers
Chained data blocks
Chained single index blocks
Double index blocks
Triple index blocks
Hybrid solutions
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