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Signed-off-by: Evgeniy Polyakov <zbr@ioremap.net> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
71 lines
4.5 KiB
Text
71 lines
4.5 KiB
Text
POHMELFS: Parallel Optimized Host Message Exchange Layered File System.
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Evgeniy Polyakov <zbr@ioremap.net>
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Homepage: http://www.ioremap.net/projects/pohmelfs
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POHMELFS first began as a network filesystem with coherent local data and
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metadata caches but is now evolving into a parallel distributed filesystem.
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Main features of this FS include:
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* Locally coherent cache for data and metadata with (potentially) byte-range locks.
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Since all Linux filesystems lock the whole inode during writing, algorithm
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is very simple and does not use byte-ranges, although they are sent in
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locking messages.
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* Completely async processing of all events except creation of hard and symbolic
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links, and rename events.
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Object creation and data reading and writing are processed asynchronously.
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* Flexible object architecture optimized for network processing.
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Ability to create long paths to objects and remove arbitrarily huge
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directories with a single network command.
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(like removing the whole kernel tree via a single network command).
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* Very high performance.
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* Fast and scalable multithreaded userspace server. Being in userspace it works
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with any underlying filesystem and still is much faster than async in-kernel NFS one.
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* Client is able to switch between different servers (if one goes down, client
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automatically reconnects to second and so on).
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* Transactions support. Full failover for all operations.
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Resending transactions to different servers on timeout or error.
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* Read request (data read, directory listing, lookup requests) balancing between multiple servers.
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* Write requests are replicated to multiple servers and completed only when all of them are acked.
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* Ability to add and/or remove servers from the working set at run-time.
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* Strong authentification and possible data encryption in network channel.
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* Extended attributes support.
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POHMELFS is based on transactions, which are potentially long-standing objects that live
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in the client's memory. Each transaction contains all the information needed to process a given
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command (or set of commands, which is frequently used during data writing: single transactions
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can contain creation and data writing commands). Transactions are committed by all the servers
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to which they are sent and, in case of failures, are eventually resent or dropped with an error.
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For example, reading will return an error if no servers are available.
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POHMELFS uses a asynchronous approach to data processing. Courtesy of transactions, it is
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possible to detach replies from requests and, if the command requires data to be received, the
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caller sleeps waiting for it. Thus, it is possible to issue multiple read commands to different
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servers and async threads will pick up replies in parallel, find appropriate transactions in the
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system and put the data where it belongs (like the page or inode cache).
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The main feature of POHMELFS is writeback data and the metadata cache.
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Only a few non-performance critical operations use the write-through cache and
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are synchronous: hard and symbolic link creation, and object rename. Creation,
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removal of objects and data writing are asynchronous and are sent to
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the server during system writeback. Only one writer at a time is allowed for any
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given inode, which is guarded by an appropriate locking protocol.
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Because of this feature, POHMELFS is extremely fast at metadata intensive
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workloads and can fully utilize the bandwidth to the servers when doing bulk
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data transfers.
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POHMELFS clients operate with a working set of servers and are capable of balancing read-only
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operations (like lookups or directory listings) between them according to IO priorities.
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Administrators can add or remove servers from the set at run-time via special commands (described
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in Documentation/pohmelfs/info.txt file). Writes are replicated to all servers, which are connected
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with write permission turned on. IO priority and permissions can be changed in run-time.
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POHMELFS is capable of full data channel encryption and/or strong crypto hashing.
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One can select any kernel supported cipher, encryption mode, hash type and operation mode
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(hmac or digest). It is also possible to use both or neither (default). Crypto configuration
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is checked during mount time and, if the server does not support it, appropriate capabilities
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will be disabled or mount will fail (if 'crypto_fail_unsupported' mount option is specified).
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Crypto performance heavily depends on the number of crypto threads, which asynchronously perform
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crypto operations and send the resulting data to server or submit it up the stack. This number
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can be controlled via a mount option.
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