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<small>''(Updated: Sep 2010)''</small>
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__TOC__
 
This document describes the design of the clustered metadata handling
 
This document describes the design of the clustered metadata handling
for Lustre.  This material depends on other Lustre designs, such as:  
+
for Lustre™.  This material depends on other Lustre designs, such as:  
  
 
* General recovery
 
* General recovery
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The ''fid'' contains a new 32 bit integer to name the inode group.   
 
The ''fid'' contains a new 32 bit integer to name the inode group.   
 
Directory entries contain a new 32 bit integer to name the inode
 
group.
 
  
 
Directory inodes on the MDS, when large, contain a new EA which is a
 
Directory inodes on the MDS, when large, contain a new EA which is a
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residing on other MDSs.  This EA is subject to ordinary concurrency
 
residing on other MDSs.  This EA is subject to ordinary concurrency
 
control by the MDS holding the inode.  The EA is virtually identical
 
control by the MDS holding the inode.  The EA is virtually identical
to the LOV EA.  
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to the LOV EA.
  
 
== The clustered metadata client (CMC) ==
 
== The clustered metadata client (CMC) ==
 
Client systems will have the write back client (WBD) or client file
 
system directly communicate with the CMC driver. It offers the
 
metadata API to the file system and uses the metadata API offered by a
 
collection of MDC drivers.  [[Each MDC driver managed the metadata traffic to one]]. '''[[Is this OK?]]'''
 
  
 
The function of the CMC is to figure out from the command issued which MDC to use.  This is based on:  
 
The function of the CMC is to figure out from the command issued which MDC to use.  This is based on:  
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* ''mkdir'' always creates the new directory on another MDS.
 
* ''mkdir'' always creates the new directory on another MDS.
 
* ''unlink'', ''rmdir'', and ''rename'' may involve more than one MDS.
 
* ''unlink'', ''rmdir'', and ''rename'' may involve more than one MDS.
* For ''large directories'', all operations making updates to directories can cause a directory split. The directory split is discussed below.
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* For ''large directories'', all operations making updates to directories can cause a [[#Directory_Split|directory split]].
* For ''other operations'', [[if no splits large directories]] '''[[Is a word missing here?]]''' are encountered, all other operations proceed as they are executed on one MDS.
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* For ''other operations'', if no splits in large directories are encountered, all other operations proceed as they are executed on one MDS.
  
 
=== Directory Split ===
 
=== Directory Split ===
  
A directory that is growing larger will be split. A fairly heavy penalty is associated with splitting the directory and also with renames within split directories.  Moreover, at the point of splitting, inodes become remote and will incur a penalty upon ''unlink''.
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A directory can be striped over several MDTs as files over several OSTs. Then the directory will be split into several objects and each one will be located in different MDTs. The layout information(stripe EA) will be stored in the extend attributes of all split objects.
 
 
Probably it is best to delay the split until the directory is fairly large, and then to split over several nodes to avoid further splits being necessary soon afterward.
 
  
 
== Recovery ==
 
== Recovery ==
  
=== Transaction Replay ===
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Initially, metadata operations that span multiple MDSs (MDTs) will be ordered and  synchronous to simplify recovery from a system crash. This may impact the performance of operations involving several MDTsAlso, an inode leak may occur after MDS recovery, but only in such a way that data is never lost.  These leaked inodes will be deleted by lfsck verification of the MDT filesystems.
 
 
The MDS - MDS interaction is managed as follows.  The node approached
 
with a request change is made the coordinator of the transaction.
 
 
 
==== Mechanisms ====
 
 
 
The coordinator will first establish that the transaction can commit on all nodes by acquiring locks on directories and checking for ''available space existing entries with the same name etc''. '''[[Is a word missing here?]]'''  It may also first perform a directory split if the size is becoming too large and more MDS nodes are still available. 
 
 
 
All nodes involved in the transaction need to have a transaction sequence number to place the transaction into their sequence and allow correctly replay.
 
 
 
At this point the coordinator will:
 
* Start a transaction locally.
 
* It will then report the transaction sequence number to all other nodes involved in the transaction. 
 
* These nodes will commit (in memory as usual), write a journal record for replay and reply to the coordinator. 
 
* The coordinator will then commit its own transaction.
 
* The replay log records are subject to normal log commit cancellation messages, but, on the coordinator commit, messages must be received from all other nodes before the record will be canceled.
 
 
 
In this way if the results of the transaction survive on any of the nodes, they can be replayed on all.
 
 
 
==== Cluster crashes and the transaction sequence ====
 
 
 
If the cluster crashes abruptly, there is the opportunity for transactions to be in progress affecting multiple nodes. Dependencies between the transactions must be managed to ensure serialize-ability of the protocol.
 
 
 
''Example:'' In transaction one, a node X creates directories ''a''. Then in transaction 2 a cross MDS node rename moves a file with a directory entry on node Y into this directory.  It is now possible for this file to lose its directory entry on Y and for the transaction on X not to commit. More complex examples exist.
 
 
 
Four possible solutions are:
 
 
 
* Disk commit delay locks: dependent transactions many not commit before the parent transaction commits.
 
* Commit ''ack''s: transactions may not proceed until previous pre-requisite transactions have committed.
 
* Synchronous NVRAM journal on all MDS nodes.
 
* Shared journal among all MDS nodes.
 
 
 
The first and last method offer the most opportunity to proceed without synchronous disk writes. The last method involves contention on a shared resource.
 
 
 
Although exhaustive analysis remains, it is clear that rename and splitting the directories are the primary culprits. Hence, we wonder about the following policy related issues:
 
* Only split really large directories, say after 1M entries.
 
* Do not needlessly create subdirectories on other nodes.  A much better policy is likely to keep directories with one owner, or possibly one client system generating them together.
 
 
 
==== Replay ====
 
 
 
To order transaction sequences, Lustre uses reply ''ack''s: the ''acks''
 
serve only one purpose, to release a lock that enforces ordering of
 
the transaction sequenceIn the case where MDS operations involve
 
more than server, the reply ''ack'' from the primary to secondary
 
servers should only be sent after the client has sent the ''ack'' to the
 
first server.  This MDS-MDS reply ''ack'' is now not really an ''ack'' anymore
 
but a simple lock cancellation review.
 
 
 
Clients will replay lost transactions to the MDS that they originally
 
engaged for the request.   
 
 
 
Orphaned children will be cleaned up only after replay completes to allow orphaned objects to be re-used during replay.
 
 
 
=== Failover ===
 
  
The configuration data can designate a standby MDS that will take over
+
In the long term, CMD recovery will rely on global epochs, which will allow distributed asynchronous updates to multiple MDTs.
from a failed MDS.  By organizing the servers in one or more rings,
 
the nearest working left neighbor MDS can be the failover node.  This
 
leads to a simple scheme with multiple failover nodes, avoiding quorum
 
and other complications beyond what is needed for two node clusters.
 
  
 
== Locking ==
 
== Locking ==
  
 
We believe locking can be done in ''fid'' order as it is currently done on the MDS.
 
We believe locking can be done in ''fid'' order as it is currently done on the MDS.

Latest revision as of 11:36, 10 September 2010

(Updated: Sep 2010)

This document describes the design of the clustered metadata handling for Lustre™. This material depends on other Lustre designs, such as:

  • General recovery
  • Orphan Recovery
  • Metadata Write Back caching

For a draft of the design document, see Clustered Metadata Design.

Introduction

Overall, the clustered metadata handling is structured as follows:

  • A cluster of metadata servers manage a collection of inode groups. Each inode group is a Lustre device exporting the usual metadata API augmented with a few operations specifically crafted for metadata clustering. We call these collections of inodes inode groups.
  • Directory formats for file systems used on the MDS devices are changed to allow directory entries to contain an inode group and identifier of the inode.
  • A logical clustered metadata driver is introduced below the client Lustre file system write back cache driver that maintains connections with the MDS servers.
  • A single metadata protocol is used by the client file system to make updates on the MDSs and by the MDSs to make updates involving other MDSs.
  • A single recovery protocol is used by the clients - MDS and MDS-MDS service.
  • Directories can be split across multiple MDS nodes. In this case, a primary MDS directory inode contains an extended attribute that points at other MDS inodes, which we call directory objects.

Configuration management and startup

The configuration will name an MDS server, and optionally a failover node, which hold the root inode for a fileset. Clients will contact that MDS for the root inode during mount, as they do already.

They will also fetch from it a clustering descriptor. The clustering descriptor contains a header, and an array lists which inode groups are served by which server.

Through normal mechanisms, clients will wait and probe for available metadata servers, during startup and cluster transitions. When new servers are found or configurations have changed, they can update their clustering descriptor as they update the LOV striping descriptor for OSTs.

Data Structures

The fid contains a new 32 bit integer to name the inode group.

Directory inodes on the MDS, when large, contain a new EA which is a descriptor of how the directory is split over directory objects, residing on other MDSs. This EA is subject to ordinary concurrency control by the MDS holding the inode. The EA is virtually identical to the LOV EA.

The clustered metadata client (CMC)

The function of the CMC is to figure out from the command issued which MDC to use. This is based on:

  • The inode groups in the request
  • A hash value of names used in the request, combined with the EA of a primary inode involved in the request
  • For readdir, the directory offset combined with the EA of the primary inode
  • The clustering descriptor

In any case, every command is dispatched to a single metadata server and the clients will not engage more than one metadata server for a single request.

The API changes here are minimal and the client part of the implementation is trivial.

MDS implementation

For the most part, operations are similar or identical to what they were before. In some cases, multiple MDS servers are involved in updates.

getattr, open, readdir, setattr and lookup methods are unaffected.

Methods adding entries to directories are modified in some cases:

  • mkdir always creates the new directory on another MDS.
  • unlink, rmdir, and rename may involve more than one MDS.
  • For large directories, all operations making updates to directories can cause a directory split.
  • For other operations, if no splits in large directories are encountered, all other operations proceed as they are executed on one MDS.

Directory Split

A directory can be striped over several MDTs as files over several OSTs. Then the directory will be split into several objects and each one will be located in different MDTs. The layout information(stripe EA) will be stored in the extend attributes of all split objects.

Recovery

Initially, metadata operations that span multiple MDSs (MDTs) will be ordered and synchronous to simplify recovery from a system crash. This may impact the performance of operations involving several MDTs. Also, an inode leak may occur after MDS recovery, but only in such a way that data is never lost. These leaked inodes will be deleted by lfsck verification of the MDT filesystems.

In the long term, CMD recovery will rely on global epochs, which will allow distributed asynchronous updates to multiple MDTs.

Locking

We believe locking can be done in fid order as it is currently done on the MDS.