PROC(5)
NAME
proc - process information pseudo-filesystem
DESCRIPTION
/proc is a pseudo-filesystem which is used as an interface
to kernel data structures rather than reading and inter-
preting /dev/kmem. Most of it is read-only, but some
files allow kernel variables to be changed.
The following outline gives a quick tour through the /proc
hierarchy.
[number]
There is a numerical subdirectory for each running
process; the subdirectory is named by the process
ID. Each contains the following pseudo-files and
directories.
cmdline
This holds the complete command line for the
process, unless the whole process has been
swapped out, or unless the process is a
zombie. In either of these later cases,
there is nothing in this file: i.e. a read
on this file will return as having read 0
characters. This file is null-terminated,
but not newline-terminated.
cwd This is a link current working directory of
the process. To find out the cwd of process
20, for instance, you can do this:
cd /proc/20/cwd; /bin/pwd
Note that the pwd command is often a shell builtin,
and might not work properly in this context.
environ
This file contains the environment for the
process. The entries are separated by null
characters, and there may be a null
character at the end. Thus, to print out
the environment of process 1, you would do:
(cat /proc/1/environ; echo) | tr "\000" "\n"
(For a reason why one should want to do this, see
lilo(8).)
exe a pointer to the binary which was executed,
and appears as a symbolic link. readlink(2)
on the exe special file returns a string in
the format:
[device]:inode
For example, [0301]:1502 would be inode 1502
on device major 03 (IDE, MFM, etc. drives)
minor 01 (first partition on the first
drive).
Also, the symbolic link can be dereferenced
normally - attempting to open "exe" will
open the executable. You can even type
/proc/[number]/exe to run another copy of
the same process as [number].
find(1) with the -inum option can be used to
locate the file.
fd This is a subdirectory containing one entry
for each file which the process has open,
named by its file descriptor, and which is a
symbolic link to the actual file (as the exe
entry does). Thus, 0 is standard input, 1
standard output, 2 standard error, etc.
Programs that will take a filename, but will
not take the standard input, and which write
to a file, but will not send their output to
standard output, can be effectively foiled
this way, assuming that -i is the flag
designating an input file and -o is the flag
designating an output file:
foobar -i /proc/self/fd/0 -o /proc/self/fd/1 ...
and you have a working filter. Note that
this will not work for programs that seek on
their files, as the files in the fd
directory are not seekable.
/proc/self/fd/N is approximately the same as
/dev/fd/N in some UNIX and UNIX-like
systems. Most Linux MAKEDEV scripts
symbolically link /dev/fd to /proc/self/fd,
in fact.
maps A file containing the currently mapped
memory regions and their access permissions.
The format is:
address perms offset dev inode
00000000-0002f000 r-x-- 00000400 03:03 1401
0002f000-00032000 rwx-p 0002f400 03:03 1401
00032000-0005b000 rwx-p 00000000 00:00 0
60000000-60098000 rwx-p 00000400 03:03 215
60098000-600c7000 rwx-p 00000000 00:00 0
bfffa000-c0000000 rwx-p 00000000 00:00 0
where address is the address space in the process
that it occupies, perms is a set of permissions:
r = read
w = write
x = execute
s = shared
p = private (copy on write)
offset is the offset into the file/whatever, dev is
the device (major:minor), and inode is the inode on
that device. 0 indicates that no inode is
associated with the memory region, as the case
would be with bss.
mem This is not the same as the mem (1,1)
device, despite the fact that it has the
same device numbers. The /dev/mem device is
the physical memory before any address
translation is done, but the mem file here
is the memory of the process that accesses
it. This cannot be mmap(2)'ed currently,
and will not be until a general mmap(2) is
added to the kernel. (This might have
happened by the time you read this.)
mmap Directory of maps by mmap(2) which are
symbolic links like exe, fd/*, etc. Note
that maps includes a superset of this
information, so /proc/*/mmap should be
considered obsolete.
"0" is usually libc.so.4.
/proc/*/mmap was removed in Linux kernel
version 1.1.40. (It really was obsolete!)
root Unix and linux support the idea of a per-
process root of the filesystem, set by the
chroot(2) system call. Root points to the
file system root, and behaves as exe, fd/*,
etc. do.
stat Status information about the process. This
is used by ps(1).
The fields, in order, with their proper
scanf(3) format specifiers, are:
pid %d The process id.
comm %s
The filename of the executable, in
parentheses. This is visible
whether or not the executable is
swapped out.
state %c
One character from the string
"RSDZT" where R is running, S is
sleeping in an interruptible wait, D
is sleeping in an uninterruptible
wait or swapping, Z is zombie, and T
is traced or stopped (on a signal).
ppid %d
The PID of the parent.
pgrp %d
The process group ID of the process.
session %d
The session ID of the process.
tty %d The tty the process uses.
tpgid %d
The process group ID of the process
which currently owns the tty that
the process is connected to.
flags %u
The flags of the process.
Currently, every flag has the math
bit set, because crt0.s checks for
math emulation, so this is not
included in the output. This is
probably a bug, as not every process
is a compiled C program. The math
bit should be a decimal 4, and the
traced bit is decimal 10.
minflt %u
The number of minor faults the
process has made, those which have
not required loading a memory page
from disk.
cminflt %u
The number of minor faults that the
process and its children have made.
majflt %u
The number of major faults the
process has made, those which have
required loading a memory page from
disk.
cmajflt %u
The number of major faults that the
process and its children have made.
utime %d
The number of jiffies that this
process has been scheduled in user
mode.
stime %d
The number of jiffies that this
process has been scheduled in kernel
mode.
cutime %d
The number of jiffies that this
process and its children have been
scheduled in user mode.
cstime %d
The number of jiffies that this
process and its children have been
scheduled in kernel mode.
counter %d
The current maximum size in jiffies
of the process's next timeslice, of
what is currently left of its
current timeslice, if it is the
currently running process.
priority %d
The standard nice value, plus
fifteen. The value is never
negative in the kernel.
timeout %u
The time in jiffies of the process's
next timeout.
itrealvalue %u
The time (in jiffies) before the
next SIGALRM is sent to the process
due to an interval timer.
starttime %d Time the process started in
jiffies after system
boot.
vsize %u
Virtual memory size
rss %u Resident Set Size: number of pages
the process has in real memory,
minus 3 for administrative purposes.
This is just the pages which count
towards text, data, or stack space.
This does not include pages which
have not been demand-loaded in, or
which are swapped out.
rlim %u
Current limit in bytes on the rss of
the process (usually 2,147,483,647).
startcode %u
The address above which program text
can run.
endcode %u
The address below which program text
can run.
startstack %u
The address of the start of the
stack.
kstkesp %u
The current value of esp (32-bit
stack pointer), as found in the
kernel stack page for the process.
kstkeip %u
The current EIP (32-bit instruction
pointer).
signal %d
The bitmap of pending signals
(usually 0).
blocked %d
The bitmap of blocked signals
(usually 0, 2 for shells).
sigignore %d
The bitmap of ignored signals.
sigcatch %d
The bitmap of catched signals.
wchan %u
This is the "channel" in which the
process is waiting. This is the
address of a system call, and can be
looked up in a namelist if you need
a textual name. (If you have an up-
to-date /etc/psdatabase, then try ps
-l to see the WCHAN field in action)
cpuinfo
This is a collection of CPU and system architecture
dependent items, for each supported architecture a
different list. The only two common entries are
cpu which is (guess what) the CPU currently in use
and BogoMIPS a system constant which is calculated
during kernel initialization.
devices
Text listing of major numbers and device groups.
This can be used by MAKEDEV scripts for consistency
with the kernel.
dma This is a list of the registered ISA DMA (direct
memory access) channels in use.
filesystems
A text listing of the filesystems which were
compiled into the kernel. Incidentally, this is
used by mount(1) to cycle through different
filesystems when none is specified.
interrupts
This is used to record the number of interrupts per
each IRQ on (at least) the i386 architechure. Very
easy to read formatting, done in ASCII.
ioports
This is a list of currently registered Input-Output
port regions that are in use.
kcore This file represents the physical memory of the
system and is stored in the core file format. With
this pseudo-file, and an unstripped kernel
(/usr/src/linux/tools/zSystem) binary, GDB can be
used to examine the current state of any kernel
data structures.
The total length of the file is the size of
physical memory (RAM) plus 4KB.
kmsg This file can be used instead of the syslog(2)
system call to log kernel messages. A process must
have superuser privileges to read this file, and
only one process should read this file. This file
should not be read if a syslog process is running
which uses the syslog(2) system call facility to
log kernel messages.
Information in this file is retrieved with the
dmesg(8) program).
ksyms This holds the kernel exported symbol definitions
used by the modules(X) tools to dynamically link
and bind loadable modules.
loadavg
The load average numbers give the number of jobs in
the run queue averaged over 1, 5 and 15 minutes.
They are the same as the load average numbers given
by uptime(1) and other programs.
malloc This file is only present if CONFIGDEBUGMALLOC was
defined during compilation.
meminfo
This is used by free(1) to report the amount of
free and used memory (both physical and swap) on
the system as well as the shared memory and buffers
used by the kernel.
It is in the same format as free(1), except in
bytes rather than KB.
modules
A text list of the modules that have been loaded by
the system.
net various net pseudo-files, all of which give the
status of some part of the networking layer. These
files contain ASCII structures, and are therefore
readable with cat. However, the standard
netstat(8) suite provides much cleaner access to
these files.
arp This holds an ASCII readable dump of the
kernel ARP table used for address
resolutions. It will show both dynamically
learned and pre-programmed ARP entries. The
format is:
IP address HW type Flags HW address
10.11.100.129 0x1 0x6 00:20:8A:00:0C:5A
10.11.100.5 0x1 0x2 00:C0:EA:00:00:4E
44.131.10.6 0x3 0x2 GW4PTS
Where 'IP address' is the IPv4 address of the
machine, the 'HW type' is the hardware type of the
address from RFC 826. The flags are the internal
flags of the ARP structure (as defined in
/usr/include/linux/if_arp.h) and the 'HW address'
is the physical layer mapping for that IP address
if it is known.
dev The dev pseudo-file contains network device
status information. This gives the number of
received and sent packets, the number of
errors and collisions and other basic
statistics. These are used by the
ifconfig(8) program to report device status.
The format is:
Inter-| Receive | Transmit
face |packets errs drop fifo frame|packets errs drop fifo colls carrier
lo: 0 0 0 0 0 2353 0 0 0 0 0
eth0: 644324 1 0 0 1 563770 0 0 0 581 0
ipx No information.
ipx_route
No information.
rarp This file uses the same format as the arp
file and contains the current reverse
mapping database used to provide rarp(8)
reverse address lookup services. If RARP is
not configured into the kernel this file
will not be present.
raw Holds a dump of the RAW socket table. Much
of the information is not of use apart from
debugging. The 'sl' value is the kernel hash
slot for the socket, the 'local address' is
the local address and protocol number
pair."St" is the internal status of the
socket. The "tx_queue" and "rx_queue" are
the outgoing and incoming data queue in
terms of kernel memory usage. The "tr",
"tm->when" and "rexmits" fields are not used
by RAW. The uid field holds the creator euid
of the socket.
route No information, but looks similar to
route(8)
snmp This file holds the ASCII data needed for
the IP, ICMP, TCP and UDP management
information bases for an snmp agent. As of
writing the TCP mib is incomplete. It is
hoped to have it completed by 1.2.0.
tcp Holds a dump of the TCP socket table. Much
of the information is not of use apart from
debugging. The "sl" value is the kernel hash
slot for the socket, the "local address" is
the local address and port number pair. The
"remote address" is the remote address and
port number pair (if connected). 'St' is the
internal status of the socket. The
'tx_queue' and 'rx_queue' are the outgoing
and incoming data queue in terms of kernel
memory usage. The "tr", "tm->when" and
"rexmits" fields hold internal information
of the kernel socket state and are only
useful for debugging. The uid field holds
the creator euid of the socket.
udp Holds a dump of the UDP socket table. Much
of the information is not of use apart from
debugging. The "sl" value is the kernel hash
slot for the socket, the "local address" is
the local address and port number pair. The
"remote address" is the remote address and
port number pair (if connected). "St" is the
internal status of the socket. The
"tx_queue" and "rx_queue" are the outgoing
and incoming data queue in terms of kernel
memory usage. The "tr", "tm->when" and
"rexmits" fields are not used by UDP. The
uid field holds the creator euid of the
socket. The format is:
sl local_address rem_address st tx_queue rx_queue tr rexmits tm->when uid
1: 01642C89:0201 0C642C89:03FF 01 00000000:00000001 01:000071BA 00000000 0
1: 00000000:0801 00000000:0000 0A 00000000:00000000 00:00000000 6F000100 0
1: 00000000:0201 00000000:0000 0A 00000000:00000000 00:00000000 00000000 0
unix Lists the UNIX domain sockets present within
the system and their status. The format is:
Num RefCount Protocol Flags Type St Path
0: 00000002 00000000 00000000 0001 03
1: 00000001 00000000 00010000 0001 01 /dev/printer
Where 'Num' is the kernel table slot number,
'RefCount' is the number of users of the socket,
'Protocol' is currently always 0, 'Flags' represent
the internal kernel flags holding the status of the
socket. Type is always '1' currently (Unix domain
datagram sockets are not yet supported in the
kernel). 'St' is the internal state of the socket
and Path is the bound path (if any) of the socket.
pci This is a listing of all PCI devices found during
kernel initialization and their configuration.
scsi A directory with the scsi midlevel pseudo-file and
various SCSI lowlevel driver directories, which
contain a file for each SCSI host in this system,
all of which give the status of some part of the
SCSI IO subsystem. These files contain ASCII
structures, and are therefore readable with cat.
You can also write to some of the files to
reconfigure the subsystem or switch certain
features on or off.
scsi This is a listing of all SCSI devices known
to the kernel. The listing is similar to the
one seen during bootup. scsi currently
supports only the singledevice command which
allows root to add a hotplugged device to
the list of known devices.
An echo 'scsi singledevice 1 0 5 0' >�>
/proc/scsi/scsi will cause host scsi1 to
scan on SCSI channel 0 for a device on ID 5
LUN 0. If there is already a device known on
this address or the address is invalid an
error will be returned.
drivername
drivername can currently be: NCR53c7xx,
aha152x, aha1542, aha1740, aic7xxx,
buslogic, eata_dma, eata_pio, fdomain,
in2000, pas16, qlogic, scsi_debug, seagate,
t128, u15-24f, ultrastore or wd7000. These
directories show up for all drivers which
registered at least one SCSI HBA. Every
directory contains one file per registered
host. Every host-file is named after the
number the host got assigned during
initilization.
Reading these files will usually show driver
and host configuration, statistics etc.
Writing to these files allows different
things on different hosts. For example with
the latency and nolatency commands root can
switch on and off command latency
measurement code in the eata_dma driver.
With the lockup and unlock commands root can
control bus lockups simulated by the
scsi_debug driver.
self This directory refers to the process accessing the
/proc filesystem, and is identical to the /proc
directory named by the process ID of the same
process.
stat kernel/system statistics
cpu 3357 0 4313 1362393
The number of jiffies (1/100ths of a second)
that the system spent in user mode, user
mode with low priority (nice), system mode,
and the idle task, respectively. The last
value should be 100 times the second entry
in the uptime pseudo-file.
disk 0 0 0 0
The four disk entries are not implemented at
this time. I'm not even sure what this
should be, since kernel statistics on other
machines usually track both transfer rate
and I/Os per second and this only allows for
one field per drive.
page 5741 1808
The number of pages the system paged in and
the number that were paged out (from disk).
swap 1 0
The number of swap pages that have been
brought in and out.
intr 1462898
The number of interrupts received from the
system boot.
ctxt 115315
The number of context switches that the
system underwent.
btime 769041601
boot time, in seconds since the epoch
(January 1, 1970).
sys This directory (present since 1.3.57) contains a
number of files and subdirectories corresponding to
kernel variables. These variables can be read and
sometimes modified using the proc file system, and
using the sysctl(2) system call. Presently, there
are subdirectories kernel, net, vm that each
contain more files and subdirectories.
kernel This contains files domainname, file-max,
file-nr, hostname, inode-max, inode-nr,
osrelease, ostype, panic, real-root-dev,
securelevel, version, with function fairly
clear from the name.
The (read-only) file file-nr gives the number of
files presently opened.
The file file-max gives the maximum number of open
files the kernel is willing to handle. If 1024 is
not enough for you, try
echo 4096 > /proc/sys/kernel/file-max
Similarly, the files inode-nr and inode-max
indicate the present and the maximum number of
inodes.
The files ostype, osrelease, version give
substrings of /proc/version.
The file panic gives r/w access to the kernel
variable panic_timeout. If this is zero, the
kernel will loop on a panic; if nonzero it
indicates that the kernel should autoreboot after
this number of seconds.
The file securelevel seems rather meaningless at
present - root is just too powerful.
uptime This file contains two numbers: the uptime of the
system (seconds), and the amount of time spent in
idle process (seconds).
version
This strings identifies the kernel version that is
currently running. For instance:
Linux version 1.0.9 (quinlan@phaze) #1 Sat May 14 01:51:54 EDT 1994
SEE ALSO
cat(1) find(1) free(1) mount(1) ps(1) tr(1)
uptime(1) readlink(2) mmap(2) chroot(2) syslog(2)
hier(7) arp(8) dmesg(8) netstat(8) route(8)
ifconfig(8) procinfo(8) and much more
CONFORMS TO
This roughly conforms to a Linux 1.3.11 kernel. Please
update this as necessary!
Last updated for Linux 1.3.11.
CAVEATS
Note that many strings (i.e., the environment and command
line) are in the internal format, with sub-fields
terminated by NUL bytes, so you may find that things are
more readable if you use od -c or tr "\000" "\n" to read
them.
This manual page is incomplete, possibly inaccurate, and
is the kind of thing that needs to be updated very often.
BUGS
The /proc file system may introduce security holes into
processes running with chroot(2). For example, if /proc
is mounted in the chroot hierarchy, a chdir(2) to
/proc/1/root will return to the original root of the file
system. This may be considered a feature instead of a
bug, since Linux does not yet support the fchroot(2) call.