|author||Michael Tokarev <email@example.com>||2014-12-20 08:48:44 +0000|
|committer||Michael Tokarev <firstname.lastname@example.org>||2014-12-20 08:48:44 +0000|
mdadm (3.3.2-5) unstable; urgency=medium
* use-tempnode-not-devnode.patch: change udev rules file to use $tempnode which works both on wheezy and jessie udev, instead of $devnode which only works in jessie. At this stage it is better to make rules file compatible with old version instead of adding versioned dependency. Should be removed for jessie+1. (Closes: #770883) * fix Closes: list in previous entry (Closes: #771852) # imported from the archive
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+When managing a RAID1 array which uses metadata other than the
+"native" metadata understood by the kernel, mdadm makes use of a
+partner program named 'mdmon' to manage some aspects of updating
+that metadata and synchronising the metadata with the array state.
+This document provides some details on how mdmon works.
+As background: mdadm makes a distinction between an 'array' and a
+'container'. Other sources sometimes use the term 'volume' or
+'device' for an 'array', and may use the term 'array' for a
+For our purposes:
+ - a 'container' is a collection of devices which are described by a
+ single set of metadata. The metadata may be stored equally
+ on all devices, or different devices may have quite different
+ subsets of the total metadata. But there is conceptually one set
+ of metadata that unifies the devices.
+ - an 'array' is a set of datablock from various devices which
+ together are used to present the abstraction of a single linear
+ sequence of block, which may provide data redundancy or enhanced
+So a container has some metadata and provides a number of arrays which
+are described by that metadata.
+Sometimes this model doesn't work perfectly. For example, global
+spares may have their own metadata which is quite different from the
+metadata from any device that participates in one or more arrays.
+Such a global spare might still need to belong to some container so
+that it is available to be used should a failure arise. In that case
+we consider the 'metadata' to be the union of the metadata on the
+active devices which describes the arrays, and the metadata on the
+global spares which only describes the spares. In this case different
+devices in the one container will have quite different metadata.
+The main purpose of mdmon is to update the metadata in response to
+changes to the array which need to be reflected in the metadata before
+futures writes to the array can safely be performed.
+ - transitions from 'clean' to 'dirty'.
+ - recording the devices have failed.
+ - recording the progress of a 'reshape'
+This requires mdmon to be running at any time that the array is
+writable (a read-only array does not require mdmon to be running).
+Because mdmon must be able to process these metadata updates at any
+time, it must (when running) have exclusive write access to the
+metadata. Any other changes (e.g. reconfiguration of the array) must
+go through mdmon.
+A secondary role for mdmon is to activate spares when a device fails.
+This role is much less time-critical than the other metadata updates,
+so it could be performed by a separate process, possibly
+"mdadm --monitor" which has a related role of moving devices between
+arrays. A main reason for including this functionality in mdmon is
+that in the native-metadata case this function is handled in the
+kernel, and mdmon's reason for existence to provide functionality
+which is otherwise handled by the kernel.
+mdmon is structured as two threads with a common address space and
+common data structures. These threads are know as the 'monitor' and
+The 'monitor' has the primary role of monitoring the array for
+important state changes and updating the metadata accordingly. As
+writes to the array can be blocked until 'monitor' completes and
+acknowledges the update, it much be very careful not to block itself.
+In particular it must not block waiting for any write to complete else
+it could deadlock. This means that it must not allocate memory as
+doing this can require dirty memory to be written out and if the
+system choose to write to the array that mdmon is monitoring, the
+memory allocation could deadlock.
+So 'monitor' must never allocate memory and must limit the number of
+other system call it performs. It may:
+ - use select (or poll) to wait for activity on a file descriptor
+ - read from a sysfs file descriptor
+ - write to a sysfs file descriptor
+ - write the metadata out to the block devices using O_DIRECT
+ - send a signal (kill) to the manager thread
+It must not e.g. open files or do anything similar that might allocate
+The 'manager' thread does everything else that is needed. If any
+files are to be opened (e.g. because a device has been added to the
+array), the manager does that. If any memory needs to be allocated
+(e.g. to hold data about a new array as can happen when one set of
+metadata describes several arrays), the manager performs that
+The 'manager' is also responsible for communicating with mdadm and
+assigning spares to replace failed devices.
+Handling metadata updates
+There are a number of cases in which mdadm needs to update the
+metdata which mdmon is managing. These include:
+ - creating a new array in an active container
+ - adding a device to a container
+ - reconfiguring an array
+To complete these updates, mdadm must send a message to mdmon which
+will merge the update into the metadata as it is at that moment.
+To achieve this, mdmon creates a Unix Domain Socket which the manager
+thread listens on. mdadm sends a message over this socket. The
+manager thread examines the message to see if it will require
+allocating any memory and allocates it. This is done in the
+'prepare_update' metadata method.
+The update message is then queued for handling by the monitor thread
+which it will do when convenient. The monitor thread calls
+->process_update which should atomically make the required changes to
+the metadata, making use of the pre-allocate memory as required. Any
+memory the is no-longer needed can be placed back in the request and
+the manager thread will free it.
+The exact format of a metadata update is up to the implementer of the
+metadata handlers. It will simply describe a change that needs to be
+made. It will sometimes contain fragments of the metadata to be
+copied in to place. However the ->process_update routine must make
+sure not to over-write any field that the monitor thread might have
+updated, such as a 'device failed' or 'array is dirty' state.
+When the monitor thread has completed the update and written it to the
+devices, an acknowledgement message is sent back over the socket so
+that mdadm knows it is complete.