733 lines
26 KiB
Groff
733 lines
26 KiB
Groff
.\" Copyright (C) 2001 Matthew Dillon. 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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.\"
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.\" THIS SOFTWARE IS PROVIDED BY 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 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 October 30, 2017
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.Dt TUNING 7
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.Os
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.Sh NAME
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.Nm tuning
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.Nd performance tuning under FreeBSD
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.Sh SYSTEM SETUP - DISKLABEL, NEWFS, TUNEFS, SWAP
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The swap partition should typically be approximately 2x the size of
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main memory
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for systems with less than 4GB of RAM, or approximately equal to
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the size of main memory
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if you have more.
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Keep in mind future memory
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expansion when sizing the swap partition.
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Configuring too little swap can lead
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to inefficiencies in the VM page scanning code as well as create issues
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later on if you add more memory to your machine.
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On larger systems
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with multiple disks, configure swap on each drive.
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The swap partitions on the drives should be approximately the same size.
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The kernel can handle arbitrary sizes but
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internal data structures scale to 4 times the largest swap partition.
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Keeping
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the swap partitions near the same size will allow the kernel to optimally
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stripe swap space across the N disks.
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Do not worry about overdoing it a
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little, swap space is the saving grace of
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.Ux
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and even if you do not normally use much swap, it can give you more time to
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recover from a runaway program before being forced to reboot.
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.Pp
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It is not a good idea to make one large partition.
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First,
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each partition has different operational characteristics and separating them
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allows the file system to tune itself to those characteristics.
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For example,
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the root and
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.Pa /usr
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partitions are read-mostly, with very little writing, while
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a lot of reading and writing could occur in
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.Pa /var/tmp .
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By properly
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partitioning your system fragmentation introduced in the smaller more
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heavily write-loaded partitions will not bleed over into the mostly-read
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partitions.
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.Pp
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Properly partitioning your system also allows you to tune
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.Xr newfs 8 ,
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and
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.Xr tunefs 8
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parameters.
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The only
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.Xr tunefs 8
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option worthwhile turning on is
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.Em softupdates
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with
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.Dq Li "tunefs -n enable /filesystem" .
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Softupdates drastically improves meta-data performance, mainly file
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creation and deletion.
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We recommend enabling softupdates on most file systems; however, there
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are two limitations to softupdates that you should be aware of when
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determining whether to use it on a file system.
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First, softupdates guarantees file system consistency in the
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case of a crash but could very easily be several seconds (even a minute!\&)
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behind on pending write to the physical disk.
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If you crash you may lose more work
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than otherwise.
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Secondly, softupdates delays the freeing of file system
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blocks.
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If you have a file system (such as the root file system) which is
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close to full, doing a major update of it, e.g.,\&
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.Dq Li "make installworld" ,
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can run it out of space and cause the update to fail.
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For this reason, softupdates will not be enabled on the root file system
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during a typical install.
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There is no loss of performance since the root
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file system is rarely written to.
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.Pp
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A number of run-time
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.Xr mount 8
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options exist that can help you tune the system.
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The most obvious and most dangerous one is
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.Cm async .
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Only use this option in conjunction with
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.Xr gjournal 8 ,
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as it is far too dangerous on a normal file system.
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A less dangerous and more
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useful
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.Xr mount 8
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option is called
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.Cm noatime .
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.Ux
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file systems normally update the last-accessed time of a file or
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directory whenever it is accessed.
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This operation is handled in
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.Fx
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with a delayed write and normally does not create a burden on the system.
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However, if your system is accessing a huge number of files on a continuing
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basis the buffer cache can wind up getting polluted with atime updates,
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creating a burden on the system.
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For example, if you are running a heavily
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loaded web site, or a news server with lots of readers, you might want to
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consider turning off atime updates on your larger partitions with this
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.Xr mount 8
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option.
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However, you should not gratuitously turn off atime
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updates everywhere.
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For example, the
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.Pa /var
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file system customarily
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holds mailboxes, and atime (in combination with mtime) is used to
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determine whether a mailbox has new mail.
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You might as well leave
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atime turned on for mostly read-only partitions such as
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.Pa /
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and
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.Pa /usr
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as well.
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This is especially useful for
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.Pa /
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since some system utilities
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use the atime field for reporting.
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.Sh STRIPING DISKS
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In larger systems you can stripe partitions from several drives together
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to create a much larger overall partition.
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Striping can also improve
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the performance of a file system by splitting I/O operations across two
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or more disks.
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The
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.Xr gstripe 8 ,
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.Xr gvinum 8 ,
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and
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.Xr ccdconfig 8
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utilities may be used to create simple striped file systems.
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Generally
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speaking, striping smaller partitions such as the root and
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.Pa /var/tmp ,
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or essentially read-only partitions such as
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.Pa /usr
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is a complete waste of time.
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You should only stripe partitions that require serious I/O performance,
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typically
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.Pa /var , /home ,
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or custom partitions used to hold databases and web pages.
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Choosing the proper stripe size is also
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important.
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File systems tend to store meta-data on power-of-2 boundaries
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and you usually want to reduce seeking rather than increase seeking.
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This
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means you want to use a large off-center stripe size such as 1152 sectors
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so sequential I/O does not seek both disks and so meta-data is distributed
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across both disks rather than concentrated on a single disk.
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.Sh SYSCTL TUNING
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.Xr sysctl 8
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variables permit system behavior to be monitored and controlled at
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run-time.
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Some sysctls simply report on the behavior of the system; others allow
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the system behavior to be modified;
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some may be set at boot time using
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.Xr rc.conf 5 ,
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but most will be set via
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.Xr sysctl.conf 5 .
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There are several hundred sysctls in the system, including many that appear
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to be candidates for tuning but actually are not.
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In this document we will only cover the ones that have the greatest effect
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on the system.
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.Pp
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The
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.Va vm.overcommit
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sysctl defines the overcommit behaviour of the vm subsystem.
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The virtual memory system always does accounting of the swap space
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reservation, both total for system and per-user.
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Corresponding values
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are available through sysctl
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.Va vm.swap_total ,
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that gives the total bytes available for swapping, and
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.Va vm.swap_reserved ,
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that gives number of bytes that may be needed to back all currently
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allocated anonymous memory.
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.Pp
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Setting bit 0 of the
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.Va vm.overcommit
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sysctl causes the virtual memory system to return failure
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to the process when allocation of memory causes
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.Va vm.swap_reserved
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to exceed
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.Va vm.swap_total .
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Bit 1 of the sysctl enforces
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.Dv RLIMIT_SWAP
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limit
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(see
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.Xr getrlimit 2 ) .
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Root is exempt from this limit.
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Bit 2 allows to count most of the physical
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memory as allocatable, except wired and free reserved pages
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(accounted by
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.Va vm.stats.vm.v_free_target
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and
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.Va vm.stats.vm.v_wire_count
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sysctls, respectively).
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.Pp
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The
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.Va kern.ipc.maxpipekva
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loader tunable is used to set a hard limit on the
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amount of kernel address space allocated to mapping of pipe buffers.
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Use of the mapping allows the kernel to eliminate a copy of the
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data from writer address space into the kernel, directly copying
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the content of mapped buffer to the reader.
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Increasing this value to a higher setting, such as `25165824' might
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improve performance on systems where space for mapping pipe buffers
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is quickly exhausted.
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This exhaustion is not fatal; however, and it will only cause pipes
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to fall back to using double-copy.
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.Pp
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The
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.Va kern.ipc.shm_use_phys
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sysctl defaults to 0 (off) and may be set to 0 (off) or 1 (on).
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Setting
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this parameter to 1 will cause all System V shared memory segments to be
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mapped to unpageable physical RAM.
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This feature only has an effect if you
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are either (A) mapping small amounts of shared memory across many (hundreds)
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of processes, or (B) mapping large amounts of shared memory across any
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number of processes.
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This feature allows the kernel to remove a great deal
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of internal memory management page-tracking overhead at the cost of wiring
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the shared memory into core, making it unswappable.
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.Pp
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The
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.Va vfs.vmiodirenable
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sysctl defaults to 1 (on).
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This parameter controls how directories are cached
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by the system.
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Most directories are small and use but a single fragment
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(typically 2K) in the file system and even less (typically 512 bytes) in
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the buffer cache.
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However, when operating in the default mode the buffer
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cache will only cache a fixed number of directories even if you have a huge
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amount of memory.
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Turning on this sysctl allows the buffer cache to use
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the VM Page Cache to cache the directories.
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The advantage is that all of
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memory is now available for caching directories.
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The disadvantage is that
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the minimum in-core memory used to cache a directory is the physical page
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size (typically 4K) rather than 512 bytes.
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We recommend turning this option off in memory-constrained environments;
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however, when on, it will substantially improve the performance of services
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that manipulate a large number of files.
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Such services can include web caches, large mail systems, and news systems.
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Turning on this option will generally not reduce performance even with the
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wasted memory but you should experiment to find out.
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.Pp
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The
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.Va vfs.write_behind
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sysctl defaults to 1 (on).
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This tells the file system to issue media
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writes as full clusters are collected, which typically occurs when writing
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large sequential files.
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The idea is to avoid saturating the buffer
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cache with dirty buffers when it would not benefit I/O performance.
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However,
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this may stall processes and under certain circumstances you may wish to turn
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it off.
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.Pp
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The
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.Va vfs.hirunningspace
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sysctl determines how much outstanding write I/O may be queued to
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disk controllers system-wide at any given time.
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It is used by the UFS file system.
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The default is self-tuned and
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usually sufficient but on machines with advanced controllers and lots
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of disks this may be tuned up to match what the controllers buffer.
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Configuring this setting to match tagged queuing capabilities of
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controllers or drives with average IO size used in production works
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best (for example: 16 MiB will use 128 tags with IO requests of 128 KiB).
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Note that setting too high a value
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(exceeding the buffer cache's write threshold) can lead to extremely
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bad clustering performance.
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Do not set this value arbitrarily high!
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Higher write queuing values may also add latency to reads occurring at
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the same time.
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.Pp
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The
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.Va vfs.read_max
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sysctl governs VFS read-ahead and is expressed as the number of blocks
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to pre-read if the heuristics algorithm decides that the reads are
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issued sequentially.
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It is used by the UFS, ext2fs and msdosfs file systems.
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With the default UFS block size of 32 KiB, a setting of 64 will allow
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speculatively reading up to 2 MiB.
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This setting may be increased to get around disk I/O latencies, especially
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where these latencies are large such as in virtual machine emulated
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environments.
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It may be tuned down in specific cases where the I/O load is such that
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read-ahead adversely affects performance or where system memory is really
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low.
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.Pp
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The
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.Va vfs.ncsizefactor
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sysctl defines how large VFS namecache may grow.
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The number of currently allocated entries in namecache is provided by
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.Va debug.numcache
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sysctl and the condition
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debug.numcache < kern.maxvnodes * vfs.ncsizefactor
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is adhered to.
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.Pp
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The
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.Va vfs.ncnegfactor
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sysctl defines how many negative entries VFS namecache is allowed to create.
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The number of currently allocated negative entries is provided by
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.Va debug.numneg
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sysctl and the condition
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vfs.ncnegfactor * debug.numneg < debug.numcache
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is adhered to.
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.Pp
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There are various other buffer-cache and VM page cache related sysctls.
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We do not recommend modifying these values.
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.Pp
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The
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.Va net.inet.tcp.sendspace
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and
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.Va net.inet.tcp.recvspace
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sysctls are of particular interest if you are running network intensive
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applications.
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They control the amount of send and receive buffer space
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allowed for any given TCP connection.
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The default sending buffer is 32K; the default receiving buffer
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is 64K.
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You can often
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improve bandwidth utilization by increasing the default at the cost of
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eating up more kernel memory for each connection.
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We do not recommend
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increasing the defaults if you are serving hundreds or thousands of
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simultaneous connections because it is possible to quickly run the system
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out of memory due to stalled connections building up.
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But if you need
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high bandwidth over a fewer number of connections, especially if you have
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gigabit Ethernet, increasing these defaults can make a huge difference.
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You can adjust the buffer size for incoming and outgoing data separately.
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For example, if your machine is primarily doing web serving you may want
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to decrease the recvspace in order to be able to increase the
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sendspace without eating too much kernel memory.
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Note that the routing table (see
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.Xr route 8 )
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can be used to introduce route-specific send and receive buffer size
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defaults.
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.Pp
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As an additional management tool you can use pipes in your
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firewall rules (see
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.Xr ipfw 8 )
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to limit the bandwidth going to or from particular IP blocks or ports.
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For example, if you have a T1 you might want to limit your web traffic
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to 70% of the T1's bandwidth in order to leave the remainder available
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for mail and interactive use.
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Normally a heavily loaded web server
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will not introduce significant latencies into other services even if
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the network link is maxed out, but enforcing a limit can smooth things
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out and lead to longer term stability.
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Many people also enforce artificial
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bandwidth limitations in order to ensure that they are not charged for
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using too much bandwidth.
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.Pp
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Setting the send or receive TCP buffer to values larger than 65535 will result
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in a marginal performance improvement unless both hosts support the window
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scaling extension of the TCP protocol, which is controlled by the
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.Va net.inet.tcp.rfc1323
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sysctl.
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These extensions should be enabled and the TCP buffer size should be set
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to a value larger than 65536 in order to obtain good performance from
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certain types of network links; specifically, gigabit WAN links and
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high-latency satellite links.
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RFC1323 support is enabled by default.
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.Pp
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The
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.Va net.inet.tcp.always_keepalive
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sysctl determines whether or not the TCP implementation should attempt
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to detect dead TCP connections by intermittently delivering
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.Dq keepalives
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|
on the connection.
|
|
By default, this is enabled for all applications; by setting this
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sysctl to 0, only applications that specifically request keepalives
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will use them.
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|
In most environments, TCP keepalives will improve the management of
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system state by expiring dead TCP connections, particularly for
|
|
systems serving dialup users who may not always terminate individual
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TCP connections before disconnecting from the network.
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|
However, in some environments, temporary network outages may be
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incorrectly identified as dead sessions, resulting in unexpectedly
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terminated TCP connections.
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In such environments, setting the sysctl to 0 may reduce the occurrence of
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TCP session disconnections.
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.Pp
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The
|
|
.Va net.inet.tcp.delayed_ack
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|
TCP feature is largely misunderstood.
|
|
Historically speaking, this feature
|
|
was designed to allow the acknowledgement to transmitted data to be returned
|
|
along with the response.
|
|
For example, when you type over a remote shell,
|
|
the acknowledgement to the character you send can be returned along with the
|
|
data representing the echo of the character.
|
|
With delayed acks turned off,
|
|
the acknowledgement may be sent in its own packet, before the remote service
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|
has a chance to echo the data it just received.
|
|
This same concept also
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|
applies to any interactive protocol (e.g.,\& SMTP, WWW, POP3), and can cut the
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|
number of tiny packets flowing across the network in half.
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|
The
|
|
.Fx
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|
delayed ACK implementation also follows the TCP protocol rule that
|
|
at least every other packet be acknowledged even if the standard 100ms
|
|
timeout has not yet passed.
|
|
Normally the worst a delayed ACK can do is
|
|
slightly delay the teardown of a connection, or slightly delay the ramp-up
|
|
of a slow-start TCP connection.
|
|
While we are not sure we believe that
|
|
the several FAQs related to packages such as SAMBA and SQUID which advise
|
|
turning off delayed acks may be referring to the slow-start issue.
|
|
.Pp
|
|
The
|
|
.Va net.inet.ip.portrange.*
|
|
sysctls control the port number ranges automatically bound to TCP and UDP
|
|
sockets.
|
|
There are three ranges: a low range, a default range, and a
|
|
high range, selectable via the
|
|
.Dv IP_PORTRANGE
|
|
.Xr setsockopt 2
|
|
call.
|
|
Most
|
|
network programs use the default range which is controlled by
|
|
.Va net.inet.ip.portrange.first
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|
and
|
|
.Va net.inet.ip.portrange.last ,
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|
which default to 49152 and 65535, respectively.
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|
Bound port ranges are
|
|
used for outgoing connections, and it is possible to run the system out
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|
of ports under certain circumstances.
|
|
This most commonly occurs when you are
|
|
running a heavily loaded web proxy.
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|
The port range is not an issue
|
|
when running a server which handles mainly incoming connections, such as a
|
|
normal web server, or has a limited number of outgoing connections, such
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|
as a mail relay.
|
|
For situations where you may run out of ports,
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|
we recommend decreasing
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|
.Va net.inet.ip.portrange.first
|
|
modestly.
|
|
A range of 10000 to 30000 ports may be reasonable.
|
|
You should also consider firewall effects when changing the port range.
|
|
Some firewalls
|
|
may block large ranges of ports (usually low-numbered ports) and expect systems
|
|
to use higher ranges of ports for outgoing connections.
|
|
By default
|
|
.Va net.inet.ip.portrange.last
|
|
is set at the maximum allowable port number.
|
|
.Pp
|
|
The
|
|
.Va kern.ipc.somaxconn
|
|
sysctl limits the size of the listen queue for accepting new TCP connections.
|
|
The default value of 128 is typically too low for robust handling of new
|
|
connections in a heavily loaded web server environment.
|
|
For such environments,
|
|
we recommend increasing this value to 1024 or higher.
|
|
The service daemon
|
|
may itself limit the listen queue size (e.g.,\&
|
|
.Xr sendmail 8 ,
|
|
apache) but will
|
|
often have a directive in its configuration file to adjust the queue size up.
|
|
Larger listen queues also do a better job of fending off denial of service
|
|
attacks.
|
|
.Pp
|
|
The
|
|
.Va kern.maxfiles
|
|
sysctl determines how many open files the system supports.
|
|
The default is
|
|
typically a few thousand but you may need to bump this up to ten or twenty
|
|
thousand if you are running databases or large descriptor-heavy daemons.
|
|
The read-only
|
|
.Va kern.openfiles
|
|
sysctl may be interrogated to determine the current number of open files
|
|
on the system.
|
|
.Pp
|
|
The
|
|
.Va vm.swap_idle_enabled
|
|
sysctl is useful in large multi-user systems where you have lots of users
|
|
entering and leaving the system and lots of idle processes.
|
|
Such systems
|
|
tend to generate a great deal of continuous pressure on free memory reserves.
|
|
Turning this feature on and adjusting the swapout hysteresis (in idle
|
|
seconds) via
|
|
.Va vm.swap_idle_threshold1
|
|
and
|
|
.Va vm.swap_idle_threshold2
|
|
allows you to depress the priority of pages associated with idle processes
|
|
more quickly then the normal pageout algorithm.
|
|
This gives a helping hand
|
|
to the pageout daemon.
|
|
Do not turn this option on unless you need it,
|
|
because the tradeoff you are making is to essentially pre-page memory sooner
|
|
rather than later, eating more swap and disk bandwidth.
|
|
In a small system
|
|
this option will have a detrimental effect but in a large system that is
|
|
already doing moderate paging this option allows the VM system to stage
|
|
whole processes into and out of memory more easily.
|
|
.Sh LOADER TUNABLES
|
|
Some aspects of the system behavior may not be tunable at runtime because
|
|
memory allocations they perform must occur early in the boot process.
|
|
To change loader tunables, you must set their values in
|
|
.Xr loader.conf 5
|
|
and reboot the system.
|
|
.Pp
|
|
.Va kern.maxusers
|
|
controls the scaling of a number of static system tables, including defaults
|
|
for the maximum number of open files, sizing of network memory resources, etc.
|
|
.Va kern.maxusers
|
|
is automatically sized at boot based on the amount of memory available in
|
|
the system, and may be determined at run-time by inspecting the value of the
|
|
read-only
|
|
.Va kern.maxusers
|
|
sysctl.
|
|
.Pp
|
|
The
|
|
.Va kern.dfldsiz
|
|
and
|
|
.Va kern.dflssiz
|
|
tunables set the default soft limits for process data and stack size
|
|
respectively.
|
|
Processes may increase these up to the hard limits by calling
|
|
.Xr setrlimit 2 .
|
|
The
|
|
.Va kern.maxdsiz ,
|
|
.Va kern.maxssiz ,
|
|
and
|
|
.Va kern.maxtsiz
|
|
tunables set the hard limits for process data, stack, and text size
|
|
respectively; processes may not exceed these limits.
|
|
The
|
|
.Va kern.sgrowsiz
|
|
tunable controls how much the stack segment will grow when a process
|
|
needs to allocate more stack.
|
|
.Pp
|
|
.Va kern.ipc.nmbclusters
|
|
may be adjusted to increase the number of network mbufs the system is
|
|
willing to allocate.
|
|
Each cluster represents approximately 2K of memory,
|
|
so a value of 1024 represents 2M of kernel memory reserved for network
|
|
buffers.
|
|
You can do a simple calculation to figure out how many you need.
|
|
If you have a web server which maxes out at 1000 simultaneous connections,
|
|
and each connection eats a 16K receive and 16K send buffer, you need
|
|
approximately 32MB worth of network buffers to deal with it.
|
|
A good rule of
|
|
thumb is to multiply by 2, so 32MBx2 = 64MB/2K = 32768.
|
|
So for this case
|
|
you would want to set
|
|
.Va kern.ipc.nmbclusters
|
|
to 32768.
|
|
We recommend values between
|
|
1024 and 4096 for machines with moderates amount of memory, and between 4096
|
|
and 32768 for machines with greater amounts of memory.
|
|
Under no circumstances
|
|
should you specify an arbitrarily high value for this parameter, it could
|
|
lead to a boot-time crash.
|
|
The
|
|
.Fl m
|
|
option to
|
|
.Xr netstat 1
|
|
may be used to observe network cluster use.
|
|
.Pp
|
|
More and more programs are using the
|
|
.Xr sendfile 2
|
|
system call to transmit files over the network.
|
|
The
|
|
.Va kern.ipc.nsfbufs
|
|
sysctl controls the number of file system buffers
|
|
.Xr sendfile 2
|
|
is allowed to use to perform its work.
|
|
This parameter nominally scales
|
|
with
|
|
.Va kern.maxusers
|
|
so you should not need to modify this parameter except under extreme
|
|
circumstances.
|
|
See the
|
|
.Sx TUNING
|
|
section in the
|
|
.Xr sendfile 2
|
|
manual page for details.
|
|
.Sh KERNEL CONFIG TUNING
|
|
There are a number of kernel options that you may have to fiddle with in
|
|
a large-scale system.
|
|
In order to change these options you need to be
|
|
able to compile a new kernel from source.
|
|
The
|
|
.Xr config 8
|
|
manual page and the handbook are good starting points for learning how to
|
|
do this.
|
|
Generally the first thing you do when creating your own custom
|
|
kernel is to strip out all the drivers and services you do not use.
|
|
Removing things like
|
|
.Dv INET6
|
|
and drivers you do not have will reduce the size of your kernel, sometimes
|
|
by a megabyte or more, leaving more memory available for applications.
|
|
.Pp
|
|
.Dv SCSI_DELAY
|
|
may be used to reduce system boot times.
|
|
The defaults are fairly high and
|
|
can be responsible for 5+ seconds of delay in the boot process.
|
|
Reducing
|
|
.Dv SCSI_DELAY
|
|
to something below 5 seconds could work (especially with modern drives).
|
|
.Pp
|
|
There are a number of
|
|
.Dv *_CPU
|
|
options that can be commented out.
|
|
If you only want the kernel to run
|
|
on a Pentium class CPU, you can easily remove
|
|
.Dv I486_CPU ,
|
|
but only remove
|
|
.Dv I586_CPU
|
|
if you are sure your CPU is being recognized as a Pentium II or better.
|
|
Some clones may be recognized as a Pentium or even a 486 and not be able
|
|
to boot without those options.
|
|
If it works, great!
|
|
The operating system
|
|
will be able to better use higher-end CPU features for MMU, task switching,
|
|
timebase, and even device operations.
|
|
Additionally, higher-end CPUs support
|
|
4MB MMU pages, which the kernel uses to map the kernel itself into memory,
|
|
increasing its efficiency under heavy syscall loads.
|
|
.Sh CPU, MEMORY, DISK, NETWORK
|
|
The type of tuning you do depends heavily on where your system begins to
|
|
bottleneck as load increases.
|
|
If your system runs out of CPU (idle times
|
|
are perpetually 0%) then you need to consider upgrading the CPU
|
|
or perhaps you need to revisit the
|
|
programs that are causing the load and try to optimize them.
|
|
If your system
|
|
is paging to swap a lot you need to consider adding more memory.
|
|
If your
|
|
system is saturating the disk you typically see high CPU idle times and
|
|
total disk saturation.
|
|
.Xr systat 1
|
|
can be used to monitor this.
|
|
There are many solutions to saturated disks:
|
|
increasing memory for caching, mirroring disks, distributing operations across
|
|
several machines, and so forth.
|
|
.Pp
|
|
Finally, you might run out of network suds.
|
|
Optimize the network path
|
|
as much as possible.
|
|
For example, in
|
|
.Xr firewall 7
|
|
we describe a firewall protecting internal hosts with a topology where
|
|
the externally visible hosts are not routed through it.
|
|
Most bottlenecks occur at the WAN link.
|
|
If expanding the link is not an option it may be possible to use the
|
|
.Xr dummynet 4
|
|
feature to implement peak shaving or other forms of traffic shaping to
|
|
prevent the overloaded service (such as web services) from affecting other
|
|
services (such as email), or vice versa.
|
|
In home installations this could
|
|
be used to give interactive traffic (your browser,
|
|
.Xr ssh 1
|
|
logins) priority
|
|
over services you export from your box (web services, email).
|
|
.Sh SEE ALSO
|
|
.Xr netstat 1 ,
|
|
.Xr systat 1 ,
|
|
.Xr sendfile 2 ,
|
|
.Xr ata 4 ,
|
|
.Xr dummynet 4 ,
|
|
.Xr eventtimers 4 ,
|
|
.Xr login.conf 5 ,
|
|
.Xr rc.conf 5 ,
|
|
.Xr sysctl.conf 5 ,
|
|
.Xr firewall 7 ,
|
|
.Xr hier 7 ,
|
|
.Xr ports 7 ,
|
|
.Xr boot 8 ,
|
|
.Xr bsdinstall 8 ,
|
|
.Xr ccdconfig 8 ,
|
|
.Xr config 8 ,
|
|
.Xr fsck 8 ,
|
|
.Xr gjournal 8 ,
|
|
.Xr gpart 8 ,
|
|
.Xr gstripe 8 ,
|
|
.Xr gvinum 8 ,
|
|
.Xr ifconfig 8 ,
|
|
.Xr ipfw 8 ,
|
|
.Xr loader 8 ,
|
|
.Xr mount 8 ,
|
|
.Xr newfs 8 ,
|
|
.Xr route 8 ,
|
|
.Xr sysctl 8 ,
|
|
.Xr tunefs 8
|
|
.Sh HISTORY
|
|
The
|
|
.Nm
|
|
manual page was originally written by
|
|
.An Matthew Dillon
|
|
and first appeared
|
|
in
|
|
.Fx 4.3 ,
|
|
May 2001.
|
|
The manual page was greatly modified by
|
|
.An Eitan Adler Aq Mt eadler@FreeBSD.org .
|