1998-01-09 09:54:57 +03:00
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.\" $NetBSD: 4.t,v 1.2 1998/01/09 06:55:32 perry Exp $
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.\"
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1994-06-19 04:07:16 +04:00
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.\" Copyright (c) 1986, 1993
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.\" The Regents of the University of California. All rights reserved.
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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. All advertising materials mentioning features or use of this software
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.\" must display the following acknowledgement:
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.\" This product includes software developed by the University of
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.\" California, Berkeley and its contributors.
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.\" 4. Neither the name of the University nor the names of its contributors
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.\" may be used to endorse or promote products derived from this software
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.\" without specific prior written permission.
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.\"
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.\" THIS SOFTWARE IS PROVIDED BY THE REGENTS 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 REGENTS 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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.\" @(#)4.t 8.1 (Berkeley) 6/8/93
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.\"
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.ds RH Performance
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.NH
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Performance
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.PP
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Ultimately, the proof of the effectiveness of the
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algorithms described in the previous section
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is the long term performance of the new file system.
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.PP
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Our empirical studies have shown that the inode layout policy has
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been effective.
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When running the ``list directory'' command on a large directory
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that itself contains many directories (to force the system
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to access inodes in multiple cylinder groups),
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the number of disk accesses for inodes is cut by a factor of two.
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The improvements are even more dramatic for large directories
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containing only files,
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disk accesses for inodes being cut by a factor of eight.
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This is most encouraging for programs such as spooling daemons that
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access many small files,
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since these programs tend to flood the
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disk request queue on the old file system.
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.PP
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Table 2 summarizes the measured throughput of the new file system.
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Several comments need to be made about the conditions under which these
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tests were run.
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The test programs measure the rate at which user programs can transfer
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data to or from a file without performing any processing on it.
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These programs must read and write enough data to
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insure that buffering in the
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operating system does not affect the results.
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They are also run at least three times in succession;
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the first to get the system into a known state
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and the second two to insure that the
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experiment has stabilized and is repeatable.
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The tests used and their results are
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discussed in detail in [Kridle83]\(dg.
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.FS
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\(dg A UNIX command that is similar to the reading test that we used is
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``cp file /dev/null'', where ``file'' is eight megabytes long.
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.FE
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The systems were running multi-user but were otherwise quiescent.
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There was no contention for either the CPU or the disk arm.
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The only difference between the UNIBUS and MASSBUS tests
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was the controller.
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All tests used an AMPEX Capricorn 330 megabyte Winchester disk.
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As Table 2 shows, all file system test runs were on a VAX 11/750.
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All file systems had been in production use for at least
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a month before being measured.
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The same number of system calls were performed in all tests;
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the basic system call overhead was a negligible portion of
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the total running time of the tests.
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.KF
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.DS B
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.TS
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box;
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c c|c s s
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c c|c c c.
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Type of Processor and Read
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File System Bus Measured Speed Bandwidth % CPU
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_
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old 1024 750/UNIBUS 29 Kbytes/sec 29/983 3% 11%
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new 4096/1024 750/UNIBUS 221 Kbytes/sec 221/983 22% 43%
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new 8192/1024 750/UNIBUS 233 Kbytes/sec 233/983 24% 29%
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new 4096/1024 750/MASSBUS 466 Kbytes/sec 466/983 47% 73%
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new 8192/1024 750/MASSBUS 466 Kbytes/sec 466/983 47% 54%
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.TE
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.ce 1
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Table 2a \- Reading rates of the old and new UNIX file systems.
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.TS
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box;
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c c|c s s
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c c|c c c.
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Type of Processor and Write
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File System Bus Measured Speed Bandwidth % CPU
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_
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old 1024 750/UNIBUS 48 Kbytes/sec 48/983 5% 29%
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new 4096/1024 750/UNIBUS 142 Kbytes/sec 142/983 14% 43%
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new 8192/1024 750/UNIBUS 215 Kbytes/sec 215/983 22% 46%
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new 4096/1024 750/MASSBUS 323 Kbytes/sec 323/983 33% 94%
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new 8192/1024 750/MASSBUS 466 Kbytes/sec 466/983 47% 95%
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.TE
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.ce 1
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Table 2b \- Writing rates of the old and new UNIX file systems.
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.DE
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.KE
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.PP
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Unlike the old file system,
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the transfer rates for the new file system do not
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appear to change over time.
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The throughput rate is tied much more strongly to the
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amount of free space that is maintained.
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The measurements in Table 2 were based on a file system
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with a 10% free space reserve.
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Synthetic work loads suggest that throughput deteriorates
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to about half the rates given in Table 2 when the file
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systems are full.
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.PP
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The percentage of bandwidth given in Table 2 is a measure
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of the effective utilization of the disk by the file system.
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An upper bound on the transfer rate from the disk is calculated
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by multiplying the number of bytes on a track by the number
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of revolutions of the disk per second.
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The bandwidth is calculated by comparing the data rates
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the file system is able to achieve as a percentage of this rate.
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Using this metric, the old file system is only
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able to use about 3\-5% of the disk bandwidth,
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while the new file system uses up to 47%
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of the bandwidth.
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.PP
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Both reads and writes are faster in the new system than in the old system.
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The biggest factor in this speedup is because of the larger
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block size used by the new file system.
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The overhead of allocating blocks in the new system is greater
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than the overhead of allocating blocks in the old system,
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however fewer blocks need to be allocated in the new system
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because they are bigger.
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The net effect is that the cost per byte allocated is about
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the same for both systems.
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.PP
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In the new file system, the reading rate is always at least
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as fast as the writing rate.
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This is to be expected since the kernel must do more work when
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allocating blocks than when simply reading them.
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Note that the write rates are about the same
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as the read rates in the 8192 byte block file system;
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the write rates are slower than the read rates in the 4096 byte block
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file system.
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The slower write rates occur because
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the kernel has to do twice as many disk allocations per second,
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making the processor unable to keep up with the disk transfer rate.
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.PP
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In contrast the old file system is about 50%
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faster at writing files than reading them.
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This is because the write system call is asynchronous and
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the kernel can generate disk transfer
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requests much faster than they can be serviced,
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hence disk transfers queue up in the disk buffer cache.
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Because the disk buffer cache is sorted by minimum seek distance,
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the average seek between the scheduled disk writes is much
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less than it would be if the data blocks were written out
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in the random disk order in which they are generated.
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However when the file is read,
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the read system call is processed synchronously so
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the disk blocks must be retrieved from the disk in the
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non-optimal seek order in which they are requested.
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This forces the disk scheduler to do long
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seeks resulting in a lower throughput rate.
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.PP
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In the new system the blocks of a file are more optimally
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ordered on the disk.
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Even though reads are still synchronous,
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the requests are presented to the disk in a much better order.
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Even though the writes are still asynchronous,
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they are already presented to the disk in minimum seek
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order so there is no gain to be had by reordering them.
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Hence the disk seek latencies that limited the old file system
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have little effect in the new file system.
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The cost of allocation is the factor in the new system that
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causes writes to be slower than reads.
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.PP
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The performance of the new file system is currently
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limited by memory to memory copy operations
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required to move data from disk buffers in the
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system's address space to data buffers in the user's
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address space. These copy operations account for
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about 40% of the time spent performing an input/output operation.
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If the buffers in both address spaces were properly aligned,
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this transfer could be performed without copying by
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using the VAX virtual memory management hardware.
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This would be especially desirable when transferring
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large amounts of data.
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We did not implement this because it would change the
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user interface to the file system in two major ways:
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user programs would be required to allocate buffers on page boundaries,
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and data would disappear from buffers after being written.
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.PP
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Greater disk throughput could be achieved by rewriting the disk drivers
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to chain together kernel buffers.
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This would allow contiguous disk blocks to be read
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in a single disk transaction.
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Many disks used with UNIX systems contain either
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32 or 48 512 byte sectors per track.
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Each track holds exactly two or three 8192 byte file system blocks,
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or four or six 4096 byte file system blocks.
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The inability to use contiguous disk blocks
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effectively limits the performance
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on these disks to less than 50% of the available bandwidth.
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If the next block for a file cannot be laid out contiguously,
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then the minimum spacing to the next allocatable
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block on any platter is between a sixth and a half a revolution.
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The implication of this is that the best possible layout without
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contiguous blocks uses only half of the bandwidth of any given track.
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If each track contains an odd number of sectors,
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then it is possible to resolve the rotational delay to any number of sectors
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by finding a block that begins at the desired
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rotational position on another track.
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The reason that block chaining has not been implemented is because it
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would require rewriting all the disk drivers in the system,
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and the current throughput rates are already limited by the
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speed of the available processors.
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.PP
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Currently only one block is allocated to a file at a time.
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A technique used by the DEMOS file system
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when it finds that a file is growing rapidly,
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is to preallocate several blocks at once,
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releasing them when the file is closed if they remain unused.
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By batching up allocations, the system can reduce the
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overhead of allocating at each write,
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and it can cut down on the number of disk writes needed to
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keep the block pointers on the disk
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synchronized with the block allocation [Powell79].
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This technique was not included because block allocation
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currently accounts for less than 10% of the time spent in
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a write system call and, once again, the
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current throughput rates are already limited by the speed
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of the available processors.
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.ds RH Functional enhancements
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.sp 2
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.ne 1i
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