source: gpfs_3.1_ker2.6.20/lpp/mmfs/samples/mmfs.cfg.sample @ 195

Last change on this file since 195 was 16, checked in by rock, 17 years ago
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[16]1## Sample configuration file
2
3## Numbers may end with a single letter:
4##   k or K meaning 1024
5##   m or M meaning 1048576 (1024*1024)
6##
7## The '#' character is the comment character.  Any parameter
8## modified herein should have any preceding '#' removed.
9##
10
11########  Memory / Shared Segment Configuration  ########
12
13## The pagepool is used for I/O buffers.  It is always pinned.
14## The allowable range is 4M to 512M (AIX).
15## The allowable range is 4M to 1300M (LINUX).
16#pagepool 64M
17
18## maxblocksize controls the maximum file system block size allowed.
19## File systems with larger block sizes cannot be mounted or created
20## unless the value of maxblocksize is increased.
21## The allowable range is 16K to 16M
22## default: maxblocksize 1M
23#maxblocksize
24
25## Maximum number of files to cache. If the number of concurrently open
26## files is bigger, then the number of cached files will exceed this value.
27## The allowable range is 1 to 100000
28#maxFilesToCache 1000
29
30## The maximum number of stat cache entries.
31## The default is 4 times the value of the maxFilesToCache parameter.
32## The allowable range is 0 to 10000000
33#maxStatCache
34
35########  DMAPI configuration  ########
36
37## The dmapiEventTimeout parameter controls the blocking of file operation
38## threads of NFS and DFS, while in the kernel waiting for the handling of
39## a DMAPI synchronous event. The parameter value is the maximum time, in
40## milliseconds, the thread will block. When this time expires, the file
41## operation returns ENOTREADY, and the event continues asynchronously.
42## The NFS/DFS server is expected to repeatedly retry the operation, which
43## eventually will find the response of the original event and continue.
44## This mechanism applies only to read, write and truncate events, and only
45## when such events come from NFS and DFS server threads. The timeout value
46## is given in milliseconds. The value 0 indicates immediate timeout (fully
47## asynchronous event). A value greater or equal 86400000 (which is 24 hours)
48## is considered "infinity" (no timeout, fully synchronous event).
49## The default value is 86400000.
50#dmapiEventTimeout 86400000
51
52## The dmapiSessionFailureTimeout parameter controls the blocking of file
53## operation threads, while in the kernel, waiting for the handling of a DMAPI
54## synchronous event that is enqueued on a session that has suffered a failure.
55## The parameter value is the maximum time, in seconds, the thread will wait
56## for the recovery of the failed session. When this time expires and the
57## session has not yet recovered, the event is aborted and the file operation
58## fails, returning the EIO error. The timeout value is given in full seconds.
59## The value 0 indicates immediate timeout (immediate failure of the file
60## operation). A value greater or equal 86400 (which is 24 hours) is considered
61## "infinity" (no timeout, indefinite blocking until the session recovers).
62## The default value is 0.
63#dmapiSessionFailureTimeout 0
64
65## The dmapiMountTimeout parameter controls the blocking of mount operations,
66## waiting for a disposition for the mount event to be set. This timeout is
67## activated at most once on each node, by the first external mount of a
68## file system which has DMAPI enabled, and only if there has never before
69## been a mount disposition. Any mount operation on this node that starts
70## while the timeout period is active will wait for the mount disposition. The
71## parameter value is the maximum time, in seconds, that the mount operation
72## will wait for a disposition. When this time expires and there is still no
73## disposition for the mount event, the mount operation fails, returning the
74## EIO error. The timeout value is given in full seconds. The value 0 indicates
75## immediate timeout (immediate failure of the mount operation). A value
76## greater or equal 86400 (which is 24 hours) is considered "infinity" (no
77## timeout, indefinite blocking until the there is a disposition).
78## The default value is 60.
79#dmapiMountTimeout 60
80
81########  Prefetch tuning ##########
82
83## The value of the 'prefetchThreads' parameter controls the maximum
84## possible number of threads dedicated to prefetching data for
85## files that are read sequentially, or to handle sequential writebehind. 
86## The actual degree of parallelism for prefetching is determined
87## dynamically in the daemon. 
88## (minimum 2, maximum 104)
89#prefetchThreads 72
90
91## The 'worker1Threads' parameter controls the maximum number of threads
92## that are used to handle other operations associated with data access.
93## The primary use is for random read/write requests that cannot be prefetched.
94## random IO requests or small file activity.
95## (minimum 1, maximum 64)
96#worker1Threads 48
97
98## maxMBpS is an estimate of how many MB per sec of data can be transferred
99## in or out of a single node. The value is used in calculating the
100## amount of IO that can be done to effectively prefetch data for readers
101## and/or or write-behind data from writers. The maximum number of IOs in
102## progress concurrantly will be 2 * min(nDisks, maxMBpS*avgIOtime/blockSize),
103## where nDisks is the number disks that make a filesystem,
104## avgIOtime is a measured average of the last 16 full block IO times, and
105## blockSize is the block size for a full block in the filesystem (e.g. 256K).
106## By lowering this value, you can artificially limit how much IO one node
107## can put on all the VSD servers, if there are lots of nodes that
108## can overrun a few VSD servers. Setting this too high will usually
109## not hurt because of other limiting factors such as the size of the
110## pagepool, or the number of prefetchThreads or worker1Threads.
111#maxMBpS 150
112
113########  Problem determination Configuration  ########
114
115## Tracing of individual classes of events/operations can be activated by
116## adding "trace <trace-class> <trace level>" lines below.
117trace all 0
118
119## The 'unmountOnDiskFail' keyword controls how the daemon will respond when
120## a disk failure is detected.
121##
122## When it is set to "no", the daemon will mark the disk as failed and
123## continue as long as it can without using the disk. All nodes that are
124## using this disk will be notified of the disk failure.  The disk can be
125## made active again by using the "mmchdisk" command.  This is the
126## suggested setting when metadata and data replication is used because
127## the replica can be used until the disk can be brought online again.
128##
129## When this is set to "yes", any disk failure will cause only the local
130## node to panic (force-unmount) the filesystem that contains that disk.
131## Other filesystems on this node and other nodes will continue to function
132## normally (if they can. The local node can try and remount the filesystem
133## when the disk problem has been resolved. This is the suggested setting
134## when using VSD disks in large multinode configurations and replication is
135## not being used.
136##
137## When it is set to "meta", the daemon will mark the disk as failed and
138## continue as long as it can without using the disk. All nodes that are
139## using this disk will be notified of the disk failure.  The disk can be
140## made active again by using the "mmchdisk" command.  This is the
141## suggested setting when metadata replication is used and there are lots of
142## dataOnly disks because the replica can be used until the disk can be
143## brought online again. The filesystem will remain mounted over dataOnly disk
144## failures, at the expense of user applications getting EIO errors when
145## trying to use disks that have been marked down.
146#unmountOnDiskFail no
147
148## The 'dataStructDump' keyword controls whether mmfs will produce a
149## formatted dump of its internal data structures into a file named
150## internaldump.<daemon pid>.signal whenever it aborts.
151## The following entry can either be a directory name in which the file
152## will reside, or otherwise a boolean value. When given a positive
153## boolean value the directory defaults to /tmp/mmfs.
154#dataStructureDump yes
155
156######## Node Override Configuration  ########
157##
158##   In a multi-node configuration, it may be desirable to configure some
159##   nodes differently than others.  This can be accomplished by placing
160##   separate, potentially different, copies of the mmfs.cfg file on each
161##   node.  However, since maintaining separate copies of the configuration
162##   file on each node will likely be more difficult and error prone,
163##   the same effect can be achieved via node overrides wherein a single
164##   mmfs.cfg file is replicated on every node.
165##
166##   A node override is introduced by a line containing a node name or list
167##   of node names in square brackets.  All parameter specifications
168##   that follow will apply only to the listed nodes.  A "[common]" line
169##   ends a section of node overrides.  For example the following fragment:
170##
171##     pagepool 30M
172##
173##     [tiger5,tiger6]
174##     pagepool 10M
175##
176##     [tiger9]
177##     pagepool 64M
178##
179##     [common]
180##     maxFilesToCache 200
181##
182##   configures the page pool on most nodes as 30 megabytes.  However,
183##   on tiger5 and tiger6 the page pool is configured with a smaller
184##   page pool of 10 megabytes.  On tiger9 the page pool is configured
185##   with a larger page pool of 64 megabytes.  Lines after the "[common]" line
186##   again apply to all nodes, i.e. every node will have a maxFilesToCache
187##   of 200.
188
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