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335 lines
14 KiB
Groff
335 lines
14 KiB
Groff
.\"
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.\" Copyright (c) 2002 Poul-Henning Kamp
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.\" Copyright (c) 2002 Networks Associates Technology, Inc.
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.\" All rights reserved.
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.\"
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.\" This software was developed for the FreeBSD Project by Poul-Henning Kamp
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.\" and NAI Labs, the Security Research Division of Network Associates, Inc.
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.\" under DARPA/SPAWAR contract N66001-01-C-8035 ("CBOSS"), as part of the
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.\" DARPA CHATS research program.
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.\"
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.\" Redistribution and use in source and binary forms, with or without
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.\" modification, are permitted provided that the following conditions
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.\" are met:
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.\" 1. Redistributions of source code must retain the above copyright
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.\" notice, this list of conditions and the following disclaimer.
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.\" 2. Redistributions in binary form must reproduce the above copyright
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.\" notice, this list of conditions and the following disclaimer in the
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.\" documentation and/or other materials provided with the distribution.
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.\" 3. The names of the authors may not be used to endorse or promote
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.\" products derived from this software without specific prior written
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.\" permission.
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.\"
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.\" THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
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.\" ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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.\" IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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.\" ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
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.\" FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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.\" DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
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.\" OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
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.\" HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
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.\" LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
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.\" OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
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.\" SUCH DAMAGE.
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.\"
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.\" $FreeBSD$
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.\"
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.Dd March 27, 2002
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.Os
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.Dt GEOM 4
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.Sh NAME
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.Nm GEOM
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.Nd modular disk I/O request transformation framework.
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.Sh DESCRIPTION
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The GEOM framework provides an infrastructure in which "classes"
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can perform transformations on disk I/O requests on their path from
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the upper kernel to the device drivers and back.
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.Pp
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Transformations in a GEOM context range from the simple geometric
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displacement performed in typical disk partitioning modules over RAID
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algorithms and device multipath resolution to full blown cryptographic
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protection of the stored data.
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.Pp
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Compared to traditional "volume management", GEOM differs from most
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and in some cases all previous implementations in the following ways:
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.Bl -bullet
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.It
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GEOM is extensible. It is trivially simple to write a new class
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of transformation and it will not be given stepchild treatment. If
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someone for some reason wanted to mount IBM MVS diskpacks, a class
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recognizing and configuring their VTOC information would be a trivial
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matter.
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.It
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GEOM is topologically agnostic. Most volume management implementations
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have very strict notions of how classes can fit together, very often
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one fixed hierarchy is provided for instance subdisk - plex -
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volume.
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.El
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.Pp
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Being extensible means that new transformations are treated no differently
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than existing transformations.
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.Pp
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Fixed hierarchies are bad because they make it impossible to express
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the intent efficiently.
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In the fixed hierarchy above it is not possible to mirror two
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physical disks and then partition the mirror into subdisks, instead
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one is forced to make subdisks on the physical volumes and to mirror
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these two and two resulting in a much more complex configuration.
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GEOM on the other hand does not care in which order things are done,
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the only restriction is that cycles in the graph will not be allowed.
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.Pp
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.Sh "TERMINOLOGY and TOPOLOGY"
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Geom is quite object oriented and consequently the terminology
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borrows a lot of context and semantics from the OO vocabulary:
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.Pp
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A "class", represented by the data structure g_class implements one
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particular kind of transformation. Typical examples are MBR disk
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partition, BSD disklabel, and RAID5 classes.
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.Pp
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An instance of a class is called a "geom" and represented by the
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data structure "g_geom". In a typical i386 FreeBSD system, there
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will be one geom of class MBR for each disk.
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.Pp
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A "provider", represented by the data structure "g_provider", is
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the front gate at which a geom offers service.
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A provider is "a disk-like thing which appears in /dev" - a logical
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disk in other words.
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All providers have three main properties: name, sectorsize and size.
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.Pp
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A "consumer" is the backdoor through which a geom connects to another
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geom provider and through which I/O requests are sent.
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.Pp
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The topological relationship between these entities are as follows:
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.Bl -bullet
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.It
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A class has zero or more geom instances.
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.It
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A geom has exactly one class it is derived from.
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.It
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A geom has zero or more consumers.
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.It
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A geom has zero or more providers.
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.It
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A consumer can be attached to zero or one providers.
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.It
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A provider can have zero or more consumers attached.
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.El
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.Pp
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All geoms have a rank-number assigned, which is used to detect and
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prevent loops in the acyclic directed graph. This rank number is
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assigned as follows:
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.Bl -enum
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.It
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A geom with no attached consumers has rank=1
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.It
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A geom with attached consumers has a rank one higher than the
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highest rank of the geoms of the providers its consumers are
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attached to.
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.El
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.Sh "SPECIAL TOPOLOGICAL MANEUVERS"
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In addition to the straightforward attach, which attaches a consumer
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to a provider, and detach, which breaks the bond, a number of special
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topological maneuvers exists to facilitate configuration and to
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improve the overall flexibility.
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.Pp
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.Em TASTING
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is a process that happens whenever a new class or new provider
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is created and it provides the class a chance to automatically configure an
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instance on providers, which it recognize as its own.
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A typical example is the MBR disk-partition class which will look for
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the MBR table in the first sector and if found and validated it will
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instantiate a geom to multiplex according to the contents of the MBR.
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.Pp
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A new class will be offered to all existing providers in turn and a new
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provider will be offered to all classes in turn.
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.Pp
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Exactly what a class does to recognize if it should accept the offered
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provider is not defined by GEOM, but the sensible set of options are:
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.Bl -bullet
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.It
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Examine specific data structures on the disk.
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.It
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Examine properties like sectorsize or mediasize for the provider.
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.It
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Examine the rank number of the provider's geom.
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.It
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Examine the method name of the provider's geom.
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.El
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.Pp
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.Em ORPHANIZATION
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is the process by which a provider is removed while
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it potentially is still being used.
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.Pp
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When a geom orphans a provider, all future I/O requests will
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"bounce" on the provider with an error code set by the geom. Any
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consumers attached to the provider will receive notification about
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the orphanization when the eventloop gets around to it, and they
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can take appropriate action at that time.
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.Pp
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A geom which came into being as a result of a normal taste operation
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should selfdestruct unless it has a way to keep functioning lacking
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the orphaned provider.
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Geoms like diskslicers should therefore selfdestruct whereas
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RAID5 or mirror geoms will be able to continue, as long as they do
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not loose quorum.
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.Pp
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When a provider is orphaned, this does not necessarily result in any
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immediate change in the topology: any attached consumers are still
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attached, any opened paths are still open, any outstanding I/O
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requests are still outstanding.
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.Pp
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The typical scenario is
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.Bl -bullet -offset indent -compact
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.It
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A device driver detects a disk has departed and orphans the provider for it.
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.It
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The geoms on top of the disk receive the orphanization event and
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orphans all their providers in turn.
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Providers, which are not attached to, will typically self-destruct
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right away.
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This process continues in a quasi-recursive fashion until all
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relevant pieces of the tree has heard the bad news.
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.It
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Eventually the buck stops when it reaches geom_dev at the top
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of the stack.
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.It
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Geom_dev will call destroy_dev(9) to stop any more request from
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coming in.
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It will sleep until all (if any) outstanding I/O requests have
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been returned.
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It will explicitly close (ie: zero the access counts), a change
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which will propagate all the way down through the mesh.
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It will then detach and destroy its geom.
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.It
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The geom whose provider is now attached will destroy the provider,
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detach and destroy its consumer and destroy its geom.
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.It
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This process percolates all the way down through the mesh, until
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the cleanup is complete.
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.El
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.Pp
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While this approach seems byzantine, it does provide the maximum
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flexibility and robustness in handling disappearing devices.
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.Pp
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The one absolutely crucial detail to be aware is that if the
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device driver does not return all I/O requests, the tree will
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not unravel.
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.Pp
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.Em SPOILING
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is a special case of orphanization used to protect
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against stale metadata.
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It is probably easiest to understand spoiling by going through
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an example.
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.Pp
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Imagine a disk, "da0" on top of which a MBR geom provides
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"da0s1" and "da0s2" and on top of "da0s1" a BSD geom provides
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"da0s1a" through "da0s1e", both the MBR and BSD geoms have
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autoconfigured based on data structures on the disk media.
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Now imagine the case where "da0" is opened for writing and those
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data structures are modified or overwritten: Now the geoms would
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be operating on stale metadata unless some notification system
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can inform them otherwise.
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.Pp
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To avoid this situation, when the open of "da0" for write happens,
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all attached consumers are told about this, and geoms like
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MBR and BSD will selfdestruct as a result.
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When "da0" is closed again, it will be offered for tasting again
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and if the data structures for MBR and BSD are still there, new
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geoms will instantiate themselves anew.
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.Pp
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Now for the fine print:
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.Pp
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If any of the paths through the MBR or BSD module were open, they
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would have opened downwards with an exclusive bit rendering it
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impossible to open "da0" for writing in that case and conversely
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the requested exclusive bit would render it impossible to open a
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path through the MBR geom while "da0" is open for writing.
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.Pp
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From this it also follows that changing the size of open geoms can
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only be done with their cooperation.
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.Pp
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Finally: the spoiling only happens when the write count goes from
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zero to non-zero and the retasting only when the write count goes
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from non-zero to zero.
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.Pp
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.Em INSERT/DELETE
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are a very special operation which allows a new geom
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to be instantiated between a consumer and a provider attached to
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each other and to remove it again.
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.Pp
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To understand the utility of this, imagine a provider with
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being mounted as a file system.
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Between the DEVFS geoms consumer and its provider we insert
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a mirror module which configures itself with one mirror
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copy and consequently is transparent to the I/O requests
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on the path.
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We can now configure yet a mirror copy on the mirror geom,
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request a synchronization, and finally drop the first mirror
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copy.
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We have now in essence moved a mounted file system from one
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disk to another while it was being used.
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At this point the mirror geom can be deleted from the path
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again, it has served its purpose.
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.Pp
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.Em CONFIGURE
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is the process where the administrator issues instructions
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for a particular class to instantiate itself. There are multiple
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ways to express intent in this case, a particular provider can be
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specified with a level of override forcing for instance a BSD
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disklabel module to attach to a provider which was not found palatable
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during the TASTE operation.
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.Pp
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Finally IO is the reason we even do this: it concerns itself with
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sending I/O requests through the graph.
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.Pp
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.Em "I/O REQUESTS
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represented by struct bio, originate at a consumer,
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are scheduled on its attached provider, and when processed, returned
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to the consumer.
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It is important to realize that the struct bio which
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enters through the provider of a particular geom does not "come
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out on the other side".
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Even simple transformations like MBR and BSD will clone the
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struct bio, modify the clone, and schedule the clone on their
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own consumer.
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Note that cloning the struct bio does not involve cloning the
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actual data area specified in the IO request.
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.Pp
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In total four different IO requests exist in GEOM: read, write,
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delete, and get attribute.
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.Pp
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Read and write are self explanatory.
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.Pp
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Delete indicates that a certain range of data is no longer used
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and that it can be erased or freed as the underlying technology
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supports.
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Technologies like flash adaptation layers can arrange to erase
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the relevant blocks before they will become reassigned and
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cryptographic devices may want to fill random bits into the
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range to reduce the amount of data available for attack.
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.Pp
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It is important to recognize that a delete indication is not a
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request and consequently there is no guarantee that the data actually
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will be erased or made unavailable unless guaranteed by specific
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geoms in the graph. If "secure delete" semantics are required, a
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geom should be pushed which converts delete indications into (a
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sequence of) write requests.
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.Pp
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Get attribute supports inspection and manipulation
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of out-of-band attributes on a particular provider or path.
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Attributes are named by ascii strings and they will be discussed in
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a separate section below.
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.Pp
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(stay tuned while the author rests his brain and fingers: more to come.)
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.Sh HISTORY
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This software was developed for the FreeBSD Project by Poul-Henning Kamp
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and NAI Labs, the Security Research Division of Network Associates, Inc.
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under DARPA/SPAWAR contract N66001-01-C-8035 ("CBOSS"), as part of the
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DARPA CHATS research program.
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.Pp
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The first precursor for GEOM was a gruesome hack to Minix 1.2 and was
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never distributed. An earlier attempt to implement a less general scheme
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in FreeBSD never succeeded.
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.Sh AUTHORS
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.An "Poul-Henning Kamp" Aq phk@FreeBSD.org
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