File Systems: Difference between revisions

Latest revision as of 18:02, 15 April 2024

There are several common ways to store binary information:

Database or key-value store (e.g. PostgreSQL, SQLite) - Good for small files or a finite amount of files which fit within the confines of a database.
Object store (e.g. S3) - same as a key-value store but typically designed to scale lots of files across multiple HDDs and hosts.
File systems (e.g. EXT4) - good for files where certain operations benefit from a hierarchical data structure, e.g. list, delete. File systems typically come with metadata such as permissions and owners.
Block storage - you get raw disk access but need to layout your binary data manually and in fixed block sizes.

Standard File Systems

BTRFS
ZFS
EXT4
XFS
NTFS

Overlay File Systems

MergerFS - a union file system to combine multiple folders on a single computer.

Block Overlays

The create a view of one or more block storage, typically using one or more block storage.

LUKS - encrypts a partition
LVM - joins multiple blocks into a pool from which to allocate blocks
mdraid

Object Stores

Minio - S3-compatible object store
Ceph - joins drives across multiple computers. Has block, file, and object storage APIs.
Rook - deployment of Ceph using Kubernetes
SeaweedFS - joins drives across multiple computers to object storage APIs (incl. S3). Has file storage when paired with a database using the SeaweedFS Filer.

Distributed File Systems

GlusterFS - joins filesystem directories across multiple computers
Ceph - joins drives across multiple computers. Has block, file, and object storage APIs.
JuiceFS - creates a POSIX-compatable file storage using an S3 object storage and metadata database.

Databases

SQL

PostgreSQL
MySQL
SQLite

NoSQL

MongoDB

Cloud Providers

See Cloud Providers

@@ Line 1: / Line 1: @@
-List of file systems
+There are several common ways to store binary information:
+* Database or key-value store (e.g. PostgreSQL, SQLite) - Good for small files or a finite amount of files which fit within the confines of a database.
+* Object store (e.g. S3) - same as a key-value store but typically designed to scale lots of files across multiple HDDs and hosts.
+* File systems (e.g. EXT4) - good for files where certain operations benefit from a hierarchical data structure, e.g. list, delete. File systems typically come with metadata such as permissions and owners.
+* Block storage - you get raw disk access but need to layout your binary data manually and in fixed block sizes.
 ==Standard File Systems==
@@ Line 13: / Line 16: @@
 ==Block Overlays==
+The create a view of one or more block storage, typically using one or more block storage.
 * [[LUKS]] - encrypts a partition
 * [[LVM]] - joins multiple blocks into a pool from which to allocate blocks
 * [[mdraid]]
+==Object Stores==
+* Minio - S3-compatible object store
+* Ceph - joins drives across multiple computers. Has block, file, and object storage APIs.
+* Rook - deployment of Ceph using Kubernetes
+* SeaweedFS - joins drives across multiple computers to object storage APIs (incl. S3). Has file storage when paired with a database using the SeaweedFS Filer.
 ==Distributed File Systems==
-* GlusterFS - joins directories across multiple computers
+* GlusterFS - joins filesystem directories across multiple computers
-* CephFS - joins drives across multiple computers. Has block, file, and object storage APIs.
+* Ceph - joins drives across multiple computers. Has block, file, and object storage APIs.
-* SeaweedFS - joins drives across multiple computers. Has file (with filer extension) and object storage APIs.
+* JuiceFS - creates a POSIX-compatable file storage using an S3 object storage and metadata database.
-* JuiceFS - creates a POSIX-compatable file storage using a object storage and metadata database.
+==Databases==
+===SQL===
+* PostgreSQL
+* MySQL
+* SQLite
+===NoSQL===
+* MongoDB
+==Cloud Providers==
+See [[Cloud Providers]]