mirror of
https://git.hardenedbsd.org/hardenedbsd/HardenedBSD.git
synced 2024-12-30 15:38:06 +01:00
291 lines
11 KiB
Perl
291 lines
11 KiB
Perl
.\" Copyright (c) 1984 M. K. McKusick
|
|
.\" Copyright (c) 1984 The Regents of the University of California.
|
|
.\" All rights reserved.
|
|
.\"
|
|
.\" Redistribution and use in source and binary forms, with or without
|
|
.\" modification, are permitted provided that the following conditions
|
|
.\" are met:
|
|
.\" 1. Redistributions of source code must retain the above copyright
|
|
.\" notice, this list of conditions and the following disclaimer.
|
|
.\" 2. Redistributions in binary form must reproduce the above copyright
|
|
.\" notice, this list of conditions and the following disclaimer in the
|
|
.\" documentation and/or other materials provided with the distribution.
|
|
.\" 3. All advertising materials mentioning features or use of this software
|
|
.\" must display the following acknowledgement:
|
|
.\" This product includes software developed by the University of
|
|
.\" California, Berkeley and its contributors.
|
|
.\" 4. Neither the name of the University nor the names of its contributors
|
|
.\" may be used to endorse or promote products derived from this software
|
|
.\" without specific prior written permission.
|
|
.\"
|
|
.\" THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
|
|
.\" ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
|
|
.\" IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
|
|
.\" ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
|
|
.\" FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
|
|
.\" DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
|
|
.\" OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
|
|
.\" HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
|
|
.\" LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
|
|
.\" OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
|
|
.\" SUCH DAMAGE.
|
|
.\"
|
|
.\" @(#)3.t 1.2 (Berkeley) 11/8/90
|
|
.\"
|
|
.ds RH Techniques for Improving Performance
|
|
.NH 1
|
|
Techniques for Improving Performance
|
|
.PP
|
|
This section gives several hints on general optimization techniques.
|
|
It then proceeds with an example of how they can be
|
|
applied to the 4.2BSD kernel to improve its performance.
|
|
.NH 2
|
|
Using the Profiler
|
|
.PP
|
|
The profiler is a useful tool for improving
|
|
a set of routines that implement an abstraction.
|
|
It can be helpful in identifying poorly coded routines,
|
|
and in evaluating the new algorithms and code that replace them.
|
|
Taking full advantage of the profiler
|
|
requires a careful examination of the call graph profile,
|
|
and a thorough knowledge of the abstractions underlying
|
|
the kernel.
|
|
.PP
|
|
The easiest optimization that can be performed
|
|
is a small change
|
|
to a control construct or data structure.
|
|
An obvious starting point
|
|
is to expand a small frequently called routine inline.
|
|
The drawback to inline expansion is that the data abstractions
|
|
in the kernel may become less parameterized,
|
|
hence less clearly defined.
|
|
The profiling will also become less useful since the loss of
|
|
routines will make its output more granular.
|
|
.PP
|
|
Further potential for optimization lies in routines that
|
|
implement data abstractions whose total execution
|
|
time is long.
|
|
If the data abstraction function cannot easily be speeded up,
|
|
it may be advantageous to cache its results,
|
|
and eliminate the need to rerun
|
|
it for identical inputs.
|
|
These and other ideas for program improvement are discussed in
|
|
[Bentley81].
|
|
.PP
|
|
This tool is best used in an iterative approach:
|
|
profiling the kernel,
|
|
eliminating one bottleneck,
|
|
then finding some other part of the kernel
|
|
that begins to dominate execution time.
|
|
.PP
|
|
A completely different use of the profiler is to analyze the control
|
|
flow of an unfamiliar section of the kernel.
|
|
By running an example that exercises the unfamiliar section of the kernel,
|
|
and then using \fIgprof\fR, you can get a view of the
|
|
control structure of the unfamiliar section.
|
|
.NH 2
|
|
An Example of Tuning
|
|
.PP
|
|
The first step is to come up with a method for generating
|
|
profile data.
|
|
We prefer to run a profiling system for about a one day
|
|
period on one of our general timesharing machines.
|
|
While this is not as reproducible as a synthetic workload,
|
|
it certainly represents a realistic test.
|
|
We have run one day profiles on several
|
|
occasions over a three month period.
|
|
Despite the long period of time that elapsed
|
|
between the test runs the shape of the profiles,
|
|
as measured by the number of times each system call
|
|
entry point was called, were remarkably similar.
|
|
.PP
|
|
A second alternative is to write a small benchmark
|
|
program to repeated exercise a suspected bottleneck.
|
|
While these benchmarks are not useful as a long term profile
|
|
they can give quick feedback on whether a hypothesized
|
|
improvement is really having an effect.
|
|
It is important to realize that the only real assurance
|
|
that a change has a beneficial effect is through
|
|
long term measurements of general timesharing.
|
|
We have numerous examples where a benchmark program
|
|
suggests vast improvements while the change
|
|
in the long term system performance is negligible,
|
|
and conversely examples in which the benchmark program run more slowly,
|
|
but the long term system performance improves significantly.
|
|
.PP
|
|
An investigation of our long term profiling showed that
|
|
the single most expensive function performed by the kernel
|
|
is path name translation.
|
|
We find that our general time sharing systems do about
|
|
500,000 name translations per day.
|
|
The cost of doing name translation in the original 4.2BSD
|
|
is 24.2 milliseconds,
|
|
representing 40% of the time processing system calls,
|
|
which is 19% of the total cycles in the kernel,
|
|
or 11% of all cycles executed on the machine.
|
|
The times are shown in Figure 3.
|
|
.KF
|
|
.DS L
|
|
.TS
|
|
center box;
|
|
l r r.
|
|
part time % of kernel
|
|
_
|
|
self 14.3 ms/call 11.3%
|
|
child 9.9 ms/call 7.9%
|
|
_
|
|
total 24.2 ms/call 19.2%
|
|
.TE
|
|
.ce
|
|
Figure 3. Call times for \fInamei\fP.
|
|
.DE
|
|
.KE
|
|
.PP
|
|
The system measurements collected showed the
|
|
pathname translation routine, \fInamei\fP,
|
|
was clearly worth optimizing.
|
|
An inspection of \fInamei\fP shows that
|
|
it consists of two nested loops.
|
|
The outer loop is traversed once per pathname component.
|
|
The inner loop performs a linear search through a directory looking
|
|
for a particular pathname component.
|
|
.PP
|
|
Our first idea was to observe that many programs
|
|
step through a directory performing an operation on
|
|
each entry in turn.
|
|
This caused us to modify \fInamei\fP to cache
|
|
the directory offset of the last pathname
|
|
component looked up by a process.
|
|
The cached offset is then used
|
|
as the point at which a search in the same directory
|
|
begins. Changing directories invalidates the cache, as
|
|
does modifying the directory.
|
|
For programs that step sequentially through a directory with
|
|
$N$ files, search time decreases from $O ( N sup 2 )$
|
|
to $O(N)$.
|
|
.PP
|
|
The cost of the cache is about 20 lines of code
|
|
(about 0.2 kilobytes)
|
|
and 16 bytes per process, with the cached data
|
|
stored in a process's \fIuser\fP vector.
|
|
.PP
|
|
As a quick benchmark to verify the effectiveness of the
|
|
cache we ran ``ls \-l''
|
|
on a directory containing 600 files.
|
|
Before the per-process cache this command
|
|
used 22.3 seconds of system time.
|
|
After adding the cache the program used the same amount
|
|
of user time, but the system time dropped to 3.3 seconds.
|
|
.PP
|
|
This change prompted our rerunning a profiled system
|
|
on a machine containing the new \fInamei\fP.
|
|
The results showed that the time in \fInamei\fP
|
|
dropped by only 2.6 ms/call and
|
|
still accounted for 36% of the system call time,
|
|
18% of the kernel, or about 10% of all the machine cycles.
|
|
This amounted to a drop in system time from 57% to about 55%.
|
|
The results are shown in Figure 4.
|
|
.KF
|
|
.DS L
|
|
.TS
|
|
center box;
|
|
l r r.
|
|
part time % of kernel
|
|
_
|
|
self 11.0 ms/call 9.2%
|
|
child 10.6 ms/call 8.9%
|
|
_
|
|
total 21.6 ms/call 18.1%
|
|
.TE
|
|
.ce
|
|
Figure 4. Call times for \fInamei\fP with per-process cache.
|
|
.DE
|
|
.KE
|
|
.PP
|
|
The small performance improvement
|
|
was caused by a low cache hit ratio.
|
|
Although the cache was 90% effective when hit,
|
|
it was only usable on about 25% of the names being translated.
|
|
An additional reason for the small improvement was that
|
|
although the amount of time spent in \fInamei\fP itself
|
|
decreased substantially,
|
|
more time was spent in the routines that it called
|
|
since each directory had to be accessed twice;
|
|
once to search from the middle to the end,
|
|
and once to search from the beginning to the middle.
|
|
.PP
|
|
Most missed names were caused by path name components
|
|
other than the last.
|
|
Thus Robert Elz introduced a system wide cache of most recent
|
|
name translations.
|
|
The cache is keyed on a name and the
|
|
inode and device number of the directory that contains it.
|
|
Associated with each entry is a pointer to the corresponding
|
|
entry in the inode table.
|
|
This has the effect of short circuiting the outer loop of \fInamei\fP.
|
|
For each path name component,
|
|
\fInamei\fP first looks in its cache of recent translations
|
|
for the needed name.
|
|
If it exists, the directory search can be completely eliminated.
|
|
If the name is not recognized,
|
|
then the per-process cache may still be useful in
|
|
reducing the directory search time.
|
|
The two cacheing schemes complement each other well.
|
|
.PP
|
|
The cost of the name cache is about 200 lines of code
|
|
(about 1.2 kilobytes)
|
|
and 44 bytes per cache entry.
|
|
Depending on the size of the system,
|
|
about 200 to 1000 entries will normally be configured,
|
|
using 10-44 kilobytes of physical memory.
|
|
The name cache is resident in memory at all times.
|
|
.PP
|
|
After adding the system wide name cache we reran ``ls \-l''
|
|
on the same directory.
|
|
The user time remained the same,
|
|
however the system time rose slightly to 3.7 seconds.
|
|
This was not surprising as \fInamei\fP
|
|
now had to maintain the cache,
|
|
but was never able to make any use of it.
|
|
.PP
|
|
Another profiled system was created and measurements
|
|
were collected over a one day period. These measurements
|
|
showed a 6 ms/call decrease in \fInamei\fP, with
|
|
\fInamei\fP accounting for only 31% of the system call time,
|
|
16% of the time in the kernel,
|
|
or about 7% of all the machine cycles.
|
|
System time dropped from 55% to about 49%.
|
|
The results are shown in Figure 5.
|
|
.KF
|
|
.DS L
|
|
.TS
|
|
center box;
|
|
l r r.
|
|
part time % of kernel
|
|
_
|
|
self 9.5 ms/call 9.6%
|
|
child 6.1 ms/call 6.1%
|
|
_
|
|
total 15.6 ms/call 15.7%
|
|
.TE
|
|
.ce
|
|
Figure 5. Call times for \fInamei\fP with both caches.
|
|
.DE
|
|
.KE
|
|
.PP
|
|
Statistics on the performance of both caches show
|
|
the large performance improvement is
|
|
caused by the high hit ratio.
|
|
On the profiled system a 60% hit rate was observed in
|
|
the system wide cache. This, coupled with the 25%
|
|
hit rate in the per-process offset cache yielded an
|
|
effective cache hit rate of 85%.
|
|
While the system wide cache reduces both the amount of time in
|
|
the routines that \fInamei\fP calls as well as \fInamei\fP itself
|
|
(since fewer directories need to be accessed or searched),
|
|
it is interesting to note that the actual percentage of system
|
|
time spent in \fInamei\fP itself increases even though the
|
|
actual time per call decreases.
|
|
This is because less total time is being spent in the kernel,
|
|
hence a smaller absolute time becomes a larger total percentage.
|