File Systems: Difference between revisions
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{{Filesystems}}
File systems are the
For details on specific filesystems, browse [[:Category:Filesystems|this list]] of filesystems.
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{{In Progress}}
A filesystem provides a generalized structure over persistent storage, allowing the low-level structure of the devices (e.g., disk, tape, flash memory storage) to be abstracted away. Generally speaking, the goal of a filesystem is
* Tracking the available storage space
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=== "Beginners" filesystems ===
There are only five filesystems that are both relatively easy to implement and worth to consider. There is no general recommendation as the choice depends largely on style and OS design. Instead you can read the comparison and make your own educated decision.
'''[[USTAR]]'''▼
* <code>+</code> Of these beginner "filesystems", this is the simplest by far to implement
* <code>+</code> Widely used
* <code>+</code> Supports special files (like devices and symlinks)▼
* <code>+</code> Supports Unix permissions▼
* <code>-</code> Not a filesystem in the common understanding of the term
* <code>-</code> Generally read-only, was never designed for in-place modifications
* <code>-</code> No support for fragmentation▼
* <code>-</code> No standard partition type for it
* <code>-</code> Not actually the format used for ramdisks by things like Linux - that's CPIO
'''RAMFS/TMPFS'''
* <code>+</code> High flexibility of implementation
* <code>+</code> Will allow you to test out your VFS API without having to rely on filesystem specifics
* <code>+</code> *Highly* recommended as a starter filesystem to avoid morphing your VFS interface around a specific filesystem
* <code>+</code> Ideal to unpack a [[USTAR]] or [[CPIO]] [[initrd]] image into
* <code>-</code> Changes are, obviously, not persistent, and only in memory, to be wiped after a reboot
'''[[FAT]]'''
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* <code>-</code> No support for large (>4 GB) files
* <code>-</code> No support for Unix permissions
'''[[Ext2]]'''
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* <code>-</code> Very large overhead
* <code>-</code> Of these beginner filesystems, this is the most complex
* <code>+</code> Supports large files▼
* <code>+</code> By far the easiest to implement▼
▲* <code>+</code> Minimal overhead
▲* <code>-</code> No support for fragmentation
* <code>-</code> No support for Unix permissions▼
'''[[BMFS]]'''
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* <code>-</code> Does not support fragmentation
* <code>-</code> Less control over the source code
▲'''[[USTAR]]'''
▲* <code>+</code> Incredibly simple, a sector with meta data followed by data sectors
▲* <code>+</code> Widely used, utility to create tar images are available for every mainstream OS
▲* <code>+</code> Supports special files (like devices and symlinks)
▲* <code>+</code> Supports Unix permissions
* <code>-</code> No support for fragmentation▼
▲* <code>-</code> No standard partition type for it, you'll have to pick one on your own
'''[[ISO 9660]]'''
The defined standard for CDs. If you boot from CD then this is the way to go. If not, don't make it your first filesystem.
▲* <code>+</code> Supports large files
* <code>+</code> Supports nested directories
▲* <code>-</code> No support for Unix permissions
* <code>-</code> It can be journalable, provided that the OS takes care of this task itself
* <code>-</code> The maximum length of the file name is 255 characters
* <code>-</code> The maximum number of volumes is 40
* <code>-</code> Takes up a lot of space
=== Rolling your own ===
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==== Guidelines if you do decide to roll your own ====
* Consider carefully what it will be used for.
* Use a program to figure out the layout (e.g. a spreadsheet). The basic areas needed are:
** Bootsector. This is essential for booting on some systems such as BIOS-x86 and Atari ST, unnecessary for others such as UEFI and OpenFirmware. Even if you don't intend to boot on systems which require it, reserving the first sector will allow your OS to be ported to them at a later time. Note that reserving space for a MBR-like partition table is needed to allow the filesystem to work in "logical partitions".
** Partition metadata. This could fit into the first sector with the boot code, or be a separate group of sectors at a specific location. (FAT puts it in the first sector, calling it the FAT parameter block. ext* use a separate location, calling it the superblock.) At a minimum, this should contain the filesystem size, location of the file table, and a version number. Leave plenty of reserved space for features you don't think of. If you put it in the first sector, don't forget to leave space for a jmp instruction, the boot code, and a partition table!
** File table. Don't think of this as just a simple table containing a list of files and their locations. One idea
** Data area. Files will be stored here.
* Create a program to read and write disk images with your filesystem. Parts of this will be portable into the fs driver.
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Once you have a beginner's file system under your belt you might want support for more advanced ones. Here are some:
*[[NTFS]] - (Windows) New Technologies File System. It's hard to find documentation. Try [http://www.opensource.apple.com/source/ntfs/ Apple NTFS (open source)].
*Btrfs - B-tree file system. It's a Linux file system with features such as copy-on-write and transparent compression.
== See Also ==
* [[I use a Custom Filesystem - What Bootloader Solution is right for me%3F]]▼
=== Wiki Pages ===▼
▲[[I use a Custom Filesystem - What Bootloader Solution is right for me%3F]]
* [https://blog.koehntopp.info/2023/05/05/50-years-in-filesystems-1974.html 50 years in filesystems] -- an approachable account of the history of file systems. Includes, among other information, some real-world examples of heuristics one can use to avoid fragmentation.
[[Category:OS theory]]
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