257 lines
12 KiB
Perl
257 lines
12 KiB
Perl
.\" $NetBSD: 2.t,v 1.5 2004/02/13 11:36:08 wiz Exp $
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.\"
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.\" Copyright (c) 1985 The Regents of the University of California.
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.\" 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. 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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.\" @(#)2.t 5.1 (Berkeley) 4/17/91
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.\"
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.ds RH Observation techniques
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.NH
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Observation techniques
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.PP
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There are many tools available for monitoring the performance
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of the system.
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Those that we found most useful are described below.
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.NH 2
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System maintenance tools
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.PP
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Several standard maintenance programs are invaluable in
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observing the basic actions of the system.
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The \fIvmstat\fP(1)
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program is designed to be an aid to monitoring
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systemwide activity. Together with the
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\fIps\fP\|(1)
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command (as in ``ps av''), it can be used to investigate systemwide
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virtual memory activity.
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By running \fIvmstat\fP
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when the system is active you can judge the system activity in several
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dimensions: job distribution, virtual memory load, paging and swapping
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activity, disk and CPU utilization.
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Ideally, to have a balanced system in activity,
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there should be few blocked (b) jobs,
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there should be little paging or swapping activity, there should
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be available bandwidth on the disk devices (most single arms peak
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out at 25-35 tps in practice), and the user CPU utilization (us) should
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be high (above 50%).
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.PP
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If the system is busy, then the count of active jobs may be large,
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and several of these jobs may often be blocked (b). If the virtual
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memory is active, then the paging demon will be running (sr will
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be non-zero). It is healthy for the paging demon to free pages when
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the virtual memory gets active; it is triggered by the amount of free
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memory dropping below a threshold and increases its pace as free memory
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goes to zero.
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.PP
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If you run \fIvmstat\fP
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when the system is busy (a ``vmstat 5'' gives all the
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numbers computed by the system), you can find
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imbalances by noting abnormal job distributions. If many
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processes are blocked (b), then the disk subsystem
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is overloaded or imbalanced. If you have several non-DMA
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devices or open teletype lines that are ``ringing'', or user programs
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that are doing high-speed non-buffered input/output, then the system
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time may go high (60-80% or higher).
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It is often possible to pin down the cause of high system time by
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looking to see if there is excessive context switching (cs), interrupt
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activity (in) or system call activity (sy). Long term measurements
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on one of
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our large machines show
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an average of 60 context switches and interrupts
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per second and an average of 90 system calls per second.
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.PP
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If the system is heavily loaded, or if you have little memory
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for your load (1 megabyte is little in our environment), then the system
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may be forced to swap. This is likely to be accompanied by a noticeable
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reduction in the system responsiveness and long pauses when interactive
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jobs such as editors swap out.
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.PP
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A second important program is \fIiostat\fP\|(1).
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\fIIostat\fP
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iteratively reports the number of characters read and written to terminals,
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and, for each disk, the number of transfers per second, kilobytes
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transferred per second,
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and the milliseconds per average seek.
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It also gives the percentage of time the system has
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spent in user mode, in user mode running low priority (niced) processes,
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in system mode, and idling.
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.PP
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To compute this information, for each disk, seeks and data transfer completions
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and the number of words transferred are counted;
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for terminals collectively, the number
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of input and output characters are counted.
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Also, every 100 ms,
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the state of each disk is examined
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and a tally is made if the disk is active.
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From these numbers and the transfer rates
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of the devices it is possible to determine
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average seek times for each device.
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.PP
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When filesystems are poorly placed on the available
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disks, figures reported by \fIiostat\fP can be used
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to pinpoint bottlenecks. Under heavy system load, disk
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traffic should be spread out among the drives with
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higher traffic expected to the devices where the root, swap, and
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/tmp filesystems are located. When multiple disk drives are
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attached to the same controller, the system will
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attempt to overlap seek operations with I/O transfers. When
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seeks are performed, \fIiostat\fP will show
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non-zero average seek times. Most modern disk drives should
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exhibit an average seek time of 25-35 ms.
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.PP
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Terminal traffic reported by \fIiostat\fP should be heavily
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output oriented unless terminal lines are being used for
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data transfer by programs such as \fIuucp\fP. Input and
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output rates are system specific. Screen editors
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such as \fIvi\fP and \fIemacs\fP tend to exhibit output/input
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ratios of anywhere from 5/1 to 8/1. On one of our largest
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systems, 88 terminal lines plus 32 pseudo terminals, we observed
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an average of 180 characters/second input and 450 characters/second
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output over 4 days of operation.
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.NH 2
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Kernel profiling
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.PP
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It is simple to build a 4.2BSD kernel that will automatically
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collect profiling information as it operates simply by specifying the
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.B \-p
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option to \fIconfig\fP\|(8) when configuring a kernel.
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The program counter sampling can be driven by the system clock,
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or by an alternate real time clock.
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The latter is highly recommended as use of the system clock results
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in statistical anomalies in accounting for
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the time spent in the kernel clock routine.
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.PP
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Once a profiling system has been booted statistic gathering is
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handled by \fIkgmon\fP\|(8).
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\fIKgmon\fP allows profiling to be started and stopped
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and the internal state of the profiling buffers to be dumped.
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\fIKgmon\fP can also be used to reset the state of the internal
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buffers to allow multiple experiments to be run without
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rebooting the machine.
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.PP
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The profiling data is processed with \fIgprof\fP\|(1)
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to obtain information regarding the system's operation.
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Profiled systems maintain histograms of the kernel program counter,
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the number of invocations of each routine,
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and a dynamic call graph of the executing system.
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The postprocessing propagates the time spent in each
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routine along the arcs of the call graph.
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\fIGprof\fP then generates a listing for each routine in the kernel,
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sorted according to the time it uses
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including the time of its call graph descendents.
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Below each routine entry is shown its (direct) call graph children,
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and how their times are propagated to this routine.
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A similar display above the routine shows how this routine's time and the
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time of its descendents is propagated to its (direct) call graph parents.
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.PP
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A profiled system is about 5-10% larger in its text space because of
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the calls to count the subroutine invocations.
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When the system executes,
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the profiling data is stored in a buffer that is 1.2
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times the size of the text space.
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All the information is summarized in memory,
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it is not necessary to have a trace file
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being continuously dumped to disk.
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The overhead for running a profiled system varies;
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under normal load we see anywhere from 5-25%
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of the system time spent in the profiling code.
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Thus the system is noticeably slower than an unprofiled system,
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yet is not so bad that it cannot be used in a production environment.
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This is important since it allows us to gather data
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in a real environment rather than trying to
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devise synthetic work loads.
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.NH 2
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Kernel tracing
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.PP
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The kernel can be configured to trace certain operations by
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specifying ``options TRACE'' in the configuration file. This
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forces the inclusion of code that records the occurrence of
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events in \fItrace records\fP in a circular buffer in kernel
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memory. Events may be enabled/disabled selectively while the
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system is operating. Each trace record contains a time stamp
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(taken from the VAX hardware time of day clock register), an
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event identifier, and additional information that is interpreted
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according to the event type. Buffer cache operations, such as
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initiating a read, include
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the disk drive, block number, and transfer size in the trace record.
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Virtual memory operations, such as a pagein completing, include
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the virtual address and process id in the trace record. The circular
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buffer is normally configured to hold 256 16-byte trace records.\**
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.FS
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\** The standard trace facilities distributed with 4.2
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differ slightly from those described here. The time stamp in the
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distributed system is calculated from the kernel's time of day
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variable instead of the VAX hardware register, and the buffer cache
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trace points do not record the transfer size.
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.FE
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.PP
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Several user programs were written to sample and interpret the
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tracing information. One program runs in the background and
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periodically reads the circular buffer of trace records. The
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trace information is compressed, in some instances interpreted
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to generate additional information, and a summary is written to a
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file. In addition, the sampling program can also record
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information from other kernel data structures, such as those
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interpreted by the \fIvmstat\fP program. Data written out to
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a file is further buffered to minimize I/O load.
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.PP
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Once a trace log has been created, programs that compress
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and interpret the data may be run to generate graphs showing the
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data and relationships between traced events and
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system load.
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.PP
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The trace package was used mainly to investigate the operation of
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the file system buffer cache. The sampling program maintained a
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history of read-ahead blocks and used the trace information to
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calculate, for example, percentage of read-ahead blocks used.
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.NH 2
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Benchmark programs
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.PP
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Benchmark programs were used in two ways. First, a suite of
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programs was constructed to calculate the cost of certain basic
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system operations. Operations such as system call overhead and
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context switching time are critically important in evaluating the
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overall performance of a system. Because of the drastic changes in
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the system between 4.1BSD and 4.2BSD, it was important to verify
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the overhead of these low level operations had not changed appreciably.
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.PP
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The second use of benchmarks was in exercising
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suspected bottlenecks.
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When we suspected a specific problem with the system,
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a small benchmark program was written to repeatedly use
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the facility.
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While these benchmarks are not useful as a general tool
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they can give quick feedback on whether a hypothesized
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improvement is really having an effect.
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It is important to realize that the only real assurance
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that a change has a beneficial effect is through
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long term measurements of general timesharing.
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We have numerous examples where a benchmark program
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suggests vast improvements while the change
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in the long term system performance is negligible,
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and conversely examples in which the benchmark program run more slowly,
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but the long term system performance improves significantly.
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