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#  Tuning the kernel 

##  Process and file descriptor limits 

**Before reading:**

_These are mostly only demonstative values on how to tune your system for different needs. They are not some kind of an ultimate optional values. This article mostly aims to provide a quick overview on the ways to fine tune your system settings and being aware of the limitations._

###  maxusers 

The name is a bit misleading, because it doesn't set the number of users on the system, but used in the formula to calculate maximal number of allowed processes. 

You can find it in your kernel configuration file, something like this: 
    maxusers        32

This is the default value, so if we look at the formulae we get process limit values: 
       #define  NPROC    (20 + 16 * MAXUSERS)
       #define  MAXFILES (3 * (NPROC + MAXUSERS) + 80)

So we got 532 for NPROC (maximal number of processes) and 1772 for MAXFILES (maximal number of open file descriptors). 

Some say that the maxusers should be set to the amount of RAM in megabytes.  
For reference, FreeBSD sets is automaticaly by this formula, but limits it's maximum to 384. 

Setting it to 64 is always a safe bet if you don't want too much experimenting. Just change it in your kernel configuration file: 
    maxusers        64

Compile the new kernel with or manualy, install the new kernel and reboot. 

You can check your limits with sysctl: 

With maxusers 32 
    $ sysctl proc.curproc.rlimit.maxproc
    proc.curproc.rlimit.maxproc.soft = 160
    proc.curproc.rlimit.maxproc.hard = 532
    $ sysctl proc.curproc.rlimit.descriptors
    proc.curproc.rlimit.descriptors.soft = 64
    proc.curproc.rlimit.descriptors.hard = 1772

With maxusers 64 

You can check your limits with sysctl: 
    $ sysctl proc.curproc.rlimit.maxproc
    proc.curproc.rlimit.maxproc.soft = 160
    proc.curproc.rlimit.maxproc.hard = 1044
    $ sysctl proc.curproc.rlimit.descriptors
    proc.curproc.rlimit.descriptors.soft = 64
    proc.curproc.rlimit.descriptors.hard = 3404

###  login.conf 

So you can change the hard limits now. Let's see the soft limits. 

or with ulimit: 
    $ ulimit -a
    core file size          (blocks, -c) unlimited
    data seg size           (kbytes, -d) 131072
    file size               (blocks, -f) unlimited
    max locked memory       (kbytes, -l) 80920
    max memory size         (kbytes, -m) 242760
    open files                      (-n) 64
    pipe size            (512 bytes, -p) 1
    stack size              (kbytes, -s) 2048
    cpu time               (seconds, -t) unlimited
    max user processes              (-u) 160
    virtual memory          (kbytes, -v) 133120

You can set it with the file /etc/login.conf: 
        :path=/usr/bin /bin /usr/sbin /sbin /usr/X11R6/bin /usr/pkg/bin /usr/pkg/sbin /usr/local/bin:\

Next time you start the sytem, all users belonging to the _default_ login group will have the following limits: 
    $ ulimit -a
    coredump(blocks)     unlimited
    data(KiB)            1048576
    file(blocks)         unlimited
    lockedmem(KiB)       124528
    memory(KiB)          373584
    nofiles(descriptors) 256
    processes            512
    stack(KiB)           8192
    time(cpu-seconds)    unlimited

You may set different limits for different user, thus different services: 

You should run this command after editing your login.conf: 
    $ cap_mkdb /etc/login.conf

You can assign the newly created login class to the desired user by doing something like this: 
    $ usermod -L database pgsql

Let's check our limits again with sysctl: 
    $ sysctl proc.curproc.rlimit.maxproc
    proc.curproc.rlimit.maxproc.soft = 512
    proc.curproc.rlimit.maxproc.hard = 1044
    $ sysctl proc.curproc.rlimit.descriptors
    proc.curproc.rlimit.descriptors.soft = 256
    proc.curproc.rlimit.descriptors.hard = 3404

Much reasonable for a modern system. 

##  System V interprocess communication 

Shared memory and semaphores are part of the System V IPC. Using and fine tuning shared memory and semaphores can give you increased performance on your NetBSD server. 

You can check it's settings with sysctl: 
    $ sysctl kern.ipc
    kern.ipc.sysvmsg = 1
    kern.ipc.sysvsem = 1
    kern.ipc.sysvshm = 1
    kern.ipc.shmmax = 8388608
    kern.ipc.shmmni = 128
    kern.ipc.shmseg = 128
    kern.ipc.shmmaxpgs = 2048
    kern.ipc.shm_use_phys = 0
    kern.ipc.msgmni = 40
    kern.ipc.msgseg = 2048
    kern.ipc.semmni = 10
    kern.ipc.semmns = 60
    kern.ipc.semmnu = 30

As you can see, the default maximum size of shared memory segment (shmmax) is 8 megabytes by default, but for a postgresql server you will most likely need about 128 megabytes. 

Note, that you cannot set shmmax directly with syctl, but you need to set the value in pages size with _kern.ipc.shmmaxpgs_. 

The default PAGE_SIZE is 4096, so if you want to set it to 128M, you have to do: 
    grimnismal# sysctl -w kern.ipc.shmmaxpgs=32768
    kern.ipc.shmmaxpgs: 4096 -> 32768

So the formula is: 128 * 1024 * 1024 / 4096 = 32768 

**You can make any sysctl change permanent by setting it in /etc/sysctl.conf**

You can also get detailed information on System V interprocess communication (IPC) facilities on the system with the following command: 
    $ ipcs
    IPC status from <running system> as of Mon Dec  3 18:52:00 2007
    Message Queues:
    T        ID     KEY        MODE       OWNER    GROUP
    Shared Memory:
    T        ID     KEY        MODE       OWNER    GROUP
    m     65536    5432001 --rw-------    pgsql    pgsql
    T        ID     KEY        MODE       OWNER    GROUP
    s     65536    5432001 --rw-------    pgsql    pgsql
    s     65537    5432002 --rw-------    pgsql    pgsql
    s     65538    5432003 --rw-------    pgsql    pgsql

You can also force shared memory to stay in physical memory. This means that they will be never paged out to swap.  
You may set this behaviour with the _kern.ipc.shm_use_phys_ sysctl. 

##  TCP Performance 

### Socket buffers

TCP uses what is called the “congestion window” to determine how many packets can be sent at one time. The larger the congestion window size, the higher the throughput. The maximum congestion window is related to the amount of buffer space that the kernel allocates for each socket. 

So on high bandwidth line the bottleneck could be the buffer sizes. 

Here's the formula for a network link's throughput: 
    Throughput = buffer size / latency

So if we reorganise it a bit, we get the formula of the ideal buffer size: 
    buffer size = 2 * delay * bandwidth

The delay is the network latency, which is most commonly known as "ping". 

I think I don't have to introduce this tool: 
    $ ping
    PING ( 56 data bytes
    64 bytes from icmp_seq=0 ttl=50 time=195.596 ms
    64 bytes from icmp_seq=1 ttl=50 time=188.883 ms
    64 bytes from icmp_seq=2 ttl=51 time=192.023 ms
    ^C PING Statistics----
    3 packets transmitted, 3 packets received, 0.0% packet loss
    round-trip min/avg/max/stddev = 188.883/192.167/195.596/3.359 ms

However ping(1) will give you the round-trip of the network link -- which is the twice of delay -- so the final formula is the following: 
    buffer size = RTT * bandwidth

Fortunately, there is an automatic control for those buffers in NetBSD. It can be checked and and enabled with sysctl: 
    net.inet.tcp.recvbuf_auto = 0
    net.inet.tcp.recvbuf_inc = 16384
    net.inet.tcp.recvbuf_max = 262144
    net.inet.tcp.sendbuf_auto = 0
    net.inet.tcp.sendbuf_inc = 8192
    net.inet.tcp.sendbuf_max = 262144

The default values for the maximal send and receive buffers are set to 256 KBytes, which is very tiny. 

A reasonable value for newer systems would be 16 MBytes, so you may set it to that value after you turned it on with sysctl: 

Just remember that your application has to avoid using SO_RCVBUF or SO_SNDBUF if it wants to take advantage of using automatically sized buffers.

### Increase the initial window size

RFC 6928 permits the extension of the initial window size to 10 segments. By default NetBSD uses 4 segments as specified in the RFC 3390.
You can increase it by using the following sysctl's:


### IP queue

If you are seeing drops due to the limited IP queue (check the net.inet.ip.ifq.drops sysctl), you can increase that by using:

    net.inet.ip.ifq.maxlen = 4096

### Other settings

If you still are seeing low throughput, maybe it's time for desperate measures ! Try to change the congestion algorithm to cubic using:


Or try to decrease the limit (expressed in hz ticks) at which the system fires a delayed ACK (for an odd numbered packet). Usually one hz is 10ms but you may want to double check using the kern.clockrate sysctl, and dividing one second to the value there. So, to decrease delack_ticks to 50ms use:


##  Disk I/O 

You may enable additional buffer queue strategies for better responsiveness under high disk I/O load.  

Enable them with the following lines in your kernel configuration file: 
      options         BUFQ_READPRIO
      options         BUFQ_PRIOCSCAN

##  Using optimized FLAGS with GCC 

NOTE: Trying to utilise heavy optimalisations can make your system hard to debug, cause unpredictable behaviour or kill your pet. Especially use of -mtune is highly discouraged, because it does not improve performance considerably or at all compared to -march=i686, and gcc4 can't handle it correctly at least on athlon CPUs. 

You can put something like this into your mk.conf, when you compile your packages and your system. 

FIXME: This is only for building world 
    CFLAGS+="-O2 -march=i686"

FIXME: For packages 

For more detailed information about the possible CFLAG values, please read the GNU C Compiler documentation [[!template id=man name="gcc" section="1"]]. 

#  References 

  * ["17.4. Managing Kernel Resources". PostgreSQL 8.3 Documentation. PostgreSQL Global Development Group.](

  * ["Performance Tuning a NetBSD Server". Eric Radman](

  * ["TCP Tuning Guide". Lawrence Berkeley National Laboratory](

#  See also 

  * [Configuration examples](../../examples/configuration_examples)

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