j3d1/tinc
1
0
Fork 0
Code Issues 1 Pull requests Releases Wiki Activity

Merging of the entire pre5 branch.

Browse source
This commit is contained in:
Guus Sliepen 2002-02-10 21:57:54 +00:00
parent c2752b961c
commit f0aa9641e8
70 changed files with 2575 additions and 4056 deletions
Download patch file Download diff file Expand all files Collapse all files

470
doc/tinc.texi
View file

@ -1,5 +1,5 @@
\input texinfo @c -*-texinfo-*-
@c $Id: tinc.texi,v 1.8.4.18 2001/05/25 12:45:37 guus Exp $
@c $Id: tinc.texi,v 1.8.4.19 2002/02/10 21:57:51 guus Exp $
@c %**start of header
@setfilename tinc.info
@settitle tinc Manual
@ -7,17 +7,18 @@
@c %**end of header
@ifinfo
@dircategory Networking tools
@direntry
* tinc: (tinc). The tinc Manual.
@end direntry
This is the info manual for tinc, a Virtual Private Network daemon.
Copyright @copyright{} 1998-2001 Ivo Timmermans
Copyright @copyright{} 1998-2002 Ivo Timmermans
<itimmermans@@bigfoot.com>, Guus Sliepen <guus@@sliepen.warande.net> and
Wessel Dankers <wsl@@nl.linux.org>.
$Id: tinc.texi,v 1.8.4.18 2001/05/25 12:45:37 guus Exp $
$Id: tinc.texi,v 1.8.4.19 2002/02/10 21:57:51 guus Exp $
Permission is granted to make and distribute verbatim copies of this
manual provided the copyright notice and this permission notice are
@ -38,11 +39,11 @@ permission notice identical to this one.
@page
@vskip 0pt plus 1filll
@cindex copyright
Copyright @copyright{} 1998-2001 Ivo Timmermans
Copyright @copyright{} 1998-2002 Ivo Timmermans
<itimmermans@@bigfoot.com>, Guus Sliepen <guus@@sliepen.warande.net> and
Wessel Dankers <wsl@@nl.linux.org>.
$Id: tinc.texi,v 1.8.4.18 2001/05/25 12:45:37 guus Exp $
$Id: tinc.texi,v 1.8.4.19 2002/02/10 21:57:51 guus Exp $
Permission is granted to make and distribute verbatim copies of this
manual provided the copyright notice and this permission notice are
@ -176,16 +177,14 @@ available too.
@section Supported platforms
@cindex platforms
tinc has been verified to work under Linux, FreeBSD and Solaris, with
various hardware architectures. These are the three platforms
that are supported by the universial TUN/TAP device driver, so if
support for other operating systems is added to this driver, perhaps
tinc will run on them as well. Without this driver, tinc will most
tinc has been verified to work under Linux, FreeBSD, OpenBSD and Solaris, with
various hardware architectures. These are some of the platforms
that are supported by the universal tun/tap device driver or other virtual network device drivers.
Without such a driver, tinc will most
likely compile and run, but it will not be able to send or receive data
packets.
@cindex release
The official release only truly supports Linux.
For an up to date list of supported platforms, please check the list on
our website:
@uref{http://tinc.nl.linux.org/platforms.html}.
@ -202,24 +201,32 @@ and arbitrary word length. So in theory it should run on other
processors that Linux runs on. It has already been verified to run on
alpha and sparc processors as well.
tinc uses the ethertap device or the universal TUN/TAP driver. The former is provided in the standard kernel
from version 2.1.60 up to 2.3.x, but has been replaced in favour of the TUN/TAP driver in kernel versions 2.4.0 and later.
tinc uses the ethertap device or the universal tun/tap driver. The former is provided in the standard kernel
from version 2.1.60 up to 2.3.x, but has been replaced in favour of the tun/tap driver in kernel versions 2.4.0 and later.
@c ==================================================================
@subsection FreeBSD
@cindex FreeBSD
tinc on FreeBSD relies on the universial TUN/TAP driver for its data
tinc on FreeBSD relies on the universal tun/tap driver for its data
acquisition from the kernel. Therefore, tinc will work on the same platforms
as this driver. These are: FreeBSD 3.x, 4.x, 5.x.
@c ==================================================================
@subsection OpenBSD
@cindex OpenBSD
tinc on OpenBSD relies on the tun driver for its data
acquisition from the kernel. It has been verified to work under at least OpenBSD 2.9.
@c ==================================================================
@subsection Solaris
@cindex Solaris
tinc on Solaris relies on the universial TUN/TAP driver for its data
tinc on Solaris relies on the universal tun/tap driver for its data
acquisition from the kernel. Therefore, tinc will work on the same platforms
as this driver. These are: Solaris, 2.1.x.
@ -278,6 +285,7 @@ you should read the @uref{http://howto.linuxberg.com/LDP/HOWTO/Kernel-HOWTO.html
* Configuration of Linux kernels 2.1.60 up to 2.4.0::
* Configuration of Linux kernels 2.4.0 and higher::
* Configuration of FreeBSD kernels::
* Configuration of OpenBSD kernels::
* Configuration of Solaris kernels::
@end menu
@ -329,18 +337,18 @@ Here are the options you have to turn on when configuring a new kernel:
Code maturity level options
[*] Prompt for development and/or incomplete code/drivers
Network device support
<M> Universal TUN/TAP device driver support
<M> Universal tun/tap device driver support
@end example
It's not necessary to compile this driver as a module, even if you are going to
run more than one instance of tinc.
If you have an early 2.4 kernel, you can choose both the TUN/TAP driver and the
If you have an early 2.4 kernel, you can choose both the tun/tap driver and the
`Ethertap network tap' device. This latter is marked obsolete, and chances are
that it won't even function correctly anymore. Make sure you select the
universal TUN/TAP driver.
universal tun/tap driver.
If you decide to build the TUN/TAP driver as a kernel module, add these lines
If you decide to build the tun/tap driver as a kernel module, add these lines
to @file{/etc/modules.conf}:
@example
@ -349,24 +357,35 @@ alias char-major-10-200 tun
@c ==================================================================
@node Configuration of FreeBSD kernels, Configuration of Solaris kernels, Configuration of Linux kernels 2.4.0 and higher, Configuring the kernel
@node Configuration of FreeBSD kernels, Configuration of OpenBSD kernels, Configuration of Linux kernels 2.4.0 and higher, Configuring the kernel
@subsection Configuration of FreeBSD kernels
This section will contain information on how to configure your FreeBSD
kernel to support the universal TUN/TAP device. For 5.0 and 4.1
systems, this is included in the kernel configuration, for earlier
systems (4.0 and 3.x), you need to install the universal TUN/TAP driver
kernel to support the universal tun/tap device. For 4.1 and higher
versions, this is included in the default kernel configuration, for earlier
systems (4.0 and earlier), you need to install the universal tun/tap driver
yourself.
Unfortunately somebody still has to write the text.
@c ==================================================================
@node Configuration of Solaris kernels, , Configuration of FreeBSD kernels, Configuring the kernel
@node Configuration of OpenBSD kernels, Configuration of Solaris kernels, Configuration of FreeBSD kernels, Configuring the kernel
@subsection Configuration of OpenBSD kernels
This section will contain information on how to configure your OpenBSD
kernel to support the tun device. For 2.9 and 3.0 systems,
this is included in the default kernel configuration.
Unfortunately somebody still has to write the text.
@c ==================================================================
@node Configuration of Solaris kernels, , Configuration of OpenBSD kernels, Configuring the kernel
@subsection Configuration of Solaris kernels
This section will contain information on how to configure your Solaris
kernel to support the universal TUN/TAP device. You need to install
kernel to support the universal tun/tap device. You need to install
this driver yourself.
Unfortunately somebody still has to write the text.
@ -451,11 +470,11 @@ all other requirements of the GPL are met.
@node Installation, Configuration, Preparations, Top
@chapter Installation
If you use Redhat or Debian, you may want to install one of the
If you use Debian, you may want to install one of the
precompiled packages for your system. These packages are equipped with
system startup scripts and sample configurations.
If you don't run either of these systems, or you want to compile tinc
If you cannot use one of the precompiled packages, or you want to compile tinc
for yourself, you can use the source. The source is distributed under
the GNU General Public License (GPL). Download the source from the
@uref{http://tinc.nl.linux.org/download.html, download page}, which has
@ -528,7 +547,7 @@ chown 0.0 /dev/tap@emph{N}
There is a maximum of 16 ethertap devices.
If you use the universal TUN/TAP driver, you have to create the
If you use the universal tun/tap driver, you have to create the
following device file (unless it already exist):
@example
@ -537,8 +556,8 @@ chown 0.0 /dev/tun
@end example
If you use Linux, and you run the new 2.4 kernel using the devfs filesystem,
then the TUN/TAP device will probably be automatically generated as
@file{/dev/net/tun}.
then the tun/tap device will probably be automatically generated as
@file{/dev/misc/net/tun}.
Unlike the ethertap device, you do not need multiple device files if
you are planning to run multiple tinc daemons.
@ -617,7 +636,7 @@ A good resource on networking is the
If you have everything clearly pictured in your mind,
proceed in the following order:
First, generate the configuration files (tinc.conf, your host configuration file, tinc-up and perhaps tinc-down).
First, generate the configuration files (@file{tinc.conf}, your host configuration file, @file{tinc-up} and perhaps @file{tinc-down}).
Then generate the keypairs.
Finally, distribute the host configuration files.
These steps are described in the subsections below.
@ -717,8 +736,28 @@ required directives are given in @strong{bold}.
@subsection Main configuration variables
@table @asis
@item @strong{ConnectTo = <name>}
@cindex BindToInterface
@item BindToInterface = <interface>
If you have more than one network interface in your computer, tinc will
by default listen on all of them for incoming connections. It is
possible to bind tinc to a single interface like eth0 or ppp0 with this
variable.
This option may not work on all platforms.
@cindex BindToIP
@item BindToIP = <address>
If your computer has more than one IP address on a single interface (for
example if you are running virtual hosts), tinc will by default listen
on all of them for incoming connections. It is possible to bind tinc to
a single IP address with this variable. It is still possible to listen
on several interfaces at the same time though, if they share the same IP
address.
This option may not work on all platforms.
@cindex ConnectTo
@item @strong{ConnectTo = <name>}
Specifies which host to connect to on startup. Multiple ConnectTo
variables may be specified, if connecting to the first one fails then
tinc will try the next one, and so on. It is possible to specify
@ -729,8 +768,13 @@ If you don't specify a host with ConnectTo, regardless of whether a
value for ConnectPort is given, tinc won't connect at all, and will
instead just listen for incoming connections.
@item Hostnames = <yes|no> (no)
@cindex Device
@item @strong{Device = <device>} (/dev/tap0 or /dev/misc/net/tun)
The virtual network device to use. Note that you can only use one device per
daemon. See also @ref{Device files}.
@cindex Hostnames
@item Hostnames = <yes|no> (no)
This option selects whether IP addresses (both real and on the VPN)
should be resolved. Since DNS lookups are blocking, it might affect
tinc's efficiency, even stopping the daemon for a few seconds everytime
@ -739,57 +783,68 @@ it does a lookup if your DNS server is not responding.
This does not affect resolving hostnames to IP addresses from the
configuration file.
@item Interface = <device>
@cindex Interface
If you have more than one network interface in your computer, tinc will
by default listen on all of them for incoming connections. It is
possible to bind tinc to a single interface like eth0 or ppp0 with this
variable.
@item Interface = <interface>
Defines the name of the interface corresponding to the virtual network device.
Depending on the operating system and the type of device this may or may not actually set the name.
Currently this option only affects the Linux tun/tap device.
@item InterfaceIP = <local address>
@cindex InterfaceIP
If your computer has more than one IP address on a single interface (for
example if you are running virtual hosts), tinc will by default listen
on all of them for incoming connections. It is possible to bind tinc to
a single IP address with this variable. It is still possible to listen
on several interfaces at the same time though, if they share the same IP
address.
@cindex Mode
@item Mode = <router|switch|hub> (router)
This option selects the way packets are routed to other daemons.
@table @asis
@cindex router
@item router
In this mode Subnet
variables in the host configuration files will be used to form a routing table.
Only unicast packets of routable protocols (IPv4 and IPv6) are supported in this mode.
@cindex switch
@item switch
In this mode the MAC addresses of the packets on the VPN will be used to
dynamically create a routing table just like a network switch does.
Unicast, multicast and broadcast packets of every ethernet protocol are supported in this mode
at the cost of frequent broadcast ARP requests and routing table updates.
@cindex hub
@item hub
In this mode every packet will be broadcast to the other daemons.
@end table
@item KeyExpire = <seconds> (3600)
@cindex KeyExpire
@item KeyExpire = <seconds> (3600)
This option controls the time the encryption keys used to encrypt the data
are valid. It is common practice to change keys at regular intervals to
make it even harder for crackers, even though it is thought to be nearly
impossible to crack a single key.
@item @strong{Name = <name>}
@cindex Name
@item @strong{Name = <name>}
This is a symbolic name for this connection. It can be anything
@item PingTimeout = <seconds> (60)
@cindex PingTimeout
@item PingTimeout = <seconds> (60)
The number of seconds of inactivity that tinc will wait before sending a
probe to the other end. If that other end doesn't answer within that
same amount of seconds, the connection is terminated, and the others
will be notified of this.
@item PrivateKey = <key> [obsolete]
@cindex PrivateKey
@item PrivateKey = <key> [obsolete]
This is the RSA private key for tinc. However, for safety reasons it is
advised to store private keys of any kind in separate files. This prevents
accidental eavesdropping if you are editting the configuration file.
@item @strong{PrivateKeyFile = <path>} [recommended]
@cindex PrivateKeyFile
@item @strong{PrivateKeyFile = <path>} [recommended]
This is the full path name of the RSA private key file that was
generated by ``tincd --generate-keys''. It must be a full path, not a
relative directory.
@item @strong{TapDevice = <device>} (/dev/tap0 or /dev/net/tun)
@cindex TapDevice
The ethertap device to use. Note that you can only use one device per
daemon. The info pages of the tinc package contain more information
about configuring an ethertap device for Linux.
Note that there must be exactly one of PrivateKey
or PrivateKeyFile
specified in the configuration file.
@end table
@ -799,33 +854,50 @@ about configuring an ethertap device for Linux.
@subsection Host configuration variables
@table @asis
@item @strong{Address = <IP address|hostname>} [recommended]
@cindex Address
@item @strong{Address = <IP address|hostname>} [recommended]
This variable is only required if you want to connect to this host. It
must resolve to the external IP address where the host can be reached,
not the one that is internal to the VPN.
@item IndirectData = <yes|no> (no) [experimental]
@cindex Cipher
@item Cipher = <cipher> (blowfish)
The symmetric cipher algorithm used to encrypt UDP packets.
Any cipher supported by OpenSSL is recognized.
@cindex Digest
@item Digest = <digest> (sha1)
The digest algorithm used to authenticate UDP packets.
Any digest supported by OpenSSL is recognized.
Furthermore, specifying "none" will turn off packet authentication.
@cindex IndirectData
@item IndirectData = <yes|no> (no) [experimental]
This option specifies whether other tinc daemons besides the one you
specified with ConnectTo can make a direct connection to you. This is
especially useful if you are behind a firewall and it is impossible to
make a connection from the outside to your tinc daemon. Otherwise, it
is best to leave this option out or set it to no.
@item Port = <port> (655)
@cindex MACLength
@item MACLength = <length> (4)
The length of the message authentication code used to authenticate UDP packets.
Can be anything from 0
up to the length of the digest produced by the digest algorithm.
@cindex Port
@item Port = <port> (655)
Connect to the upstream host (given with the ConnectTo directive) on
port port. port may be given in decimal (default), octal (when preceded
by a single zero) o hexadecimal (prefixed with 0x). port is the port
number for both the UDP and the TCP (meta) connections.
@item PublicKey = <key> [obsolete]
@cindex PublicKey
@item PublicKey = <key> [obsolete]
This is the RSA public key for this host.
@item PublicKeyFile = <path> [obsolete]
@cindex PublicKeyFile
@item PublicKeyFile = <path> [obsolete]
This is the full path name of the RSA public key file that was generated
by ``tincd --generate-keys''. It must be a full path, not a relative
directory.
@ -838,22 +910,29 @@ necessary. Either the PEM format is used, or exactly
in each host configuration file, if you want to be able to establish a
connection with that host.
@item Subnet = <IP address/maskbits>
@cindex Subnet
This is the subnet range of all IP addresses that will be accepted by
the host that defines it.
@item Subnet = <address[/masklength]>
The subnet which this tinc daemon will serve.
tinc tries to look up which other daemon it should send a packet to by searching the appropiate subnet.
If the packet matches a subnet,
it will be sent to the daemon who has this subnet in his host configuration file.
Multiple subnet lines can be specified for each daemon.
The range must be contained in the IP address range of the tap device,
not the real IP address of the host running tincd.
Subnets can either be single MAC, IPv4 or IPv6 addresses,
in which case a subnet consisting of only that single address is assumed,
or they can be a IPv4 or IPv6 network address with a masklength.
For example, IPv4 subnets must be in a form like 192.168.1.0/24,
where 192.168.1.0 is the network address and 24 is the number of bits set in the netmask.
Note that subnets like 192.168.1.1/24 are invalid!
@cindex CIDR notation
maskbits is the number of bits set to 1 in the netmask part; for
masklength is the number of bits set to 1 in the netmask part; for
example: netmask 255.255.255.0 would become /24, 255.255.252.0 becomes
/22. This conforms to standard CIDR notation as described in
@uref{ftp://ftp.isi.edu/in-notes/rfc1519.txt, RFC1519}
@item TCPonly = <yes|no> (no) [experimental]
@cindex TCPonly
@item TCPonly = <yes|no> (no) [experimental]
If this variable is set to yes, then the packets are tunnelled over a
TCP connection instead of a UDP connection. This is especially useful
for those who want to run a tinc daemon from behind a masquerading
@ -874,7 +953,7 @@ Adapt the following example to create a basic configuration file:
@example
Name = @emph{yourname}
TapDevice = @emph{/dev/tap0}
Device = @emph{/dev/tap0}
PrivateKeyFile = /etc/tinc/@emph{netname}/rsa_key.priv
@end example
@ -919,37 +998,39 @@ Just press enter to accept the defaults.
@section Network interfaces
Before tinc can start transmitting data over the tunnel, it must
set up the ethertap network devices.
set up the virtual network interface.
First, decide which IP addresses you want to have associated with these
devices, and what network mask they must have.
tinc will open an ethertap device or TUN/TAP device, which will also
create a network interface called `tap0', or `tap1', and so on if you are using
the ethertap driver, or a network interface with the same name as netname
if you are using the universal TUN/TAP driver.
tinc will open a virtual network device (@file{/dev/tun}, @file{/dev/tap0} or similar),
which will also create a network interface called something like `tun0', `tap0', or,
if you are using the Linux tun/tap driver, the network interface will by default have the same name as the netname.
@cindex tinc-up
You can configure that device by putting ordinary ifconfig, route, and other commands
You can configure the network interface by putting ordinary ifconfig, route, and other commands
to a script named @file{/etc/tinc/netname/tinc-up}. When tinc starts, this script
will be executed. When tinc exits, it will execute the script named
@file{/etc/tinc/netname/tinc-down}, but normally you don't need to create that script.
An example @file{tinc-up} script when using the TUN/TAP driver:
An example @file{tinc-up} script:
@example
#!/bin/sh
ifconfig $NETNAME hw ether fe:fd:00:00:00:00
ifconfig $NETNAME @emph{xx}.@emph{xx}.@emph{xx}.@emph{xx} netmask @emph{mask}
ifconfig $NETNAME -arp
ifconfig $INTERFACE hw ether fe:fd:0:0:0:0
ifconfig $INTERFACE 192.168.1.1 netmask 255.255.0.0
ifconfig $INTERFACE -arp
@end example
@cindex MAC address
@cindex hardware address
The first line sets up the MAC address of the network interface.
Due to the nature of how Ethernet and tinc work, it has to be set to fe:fd:00:00:00:00.
(tinc versions prior to 1.0pre3 required that the MAC address matched the IP address.)
You can use the environment variable $NETNAME to get the name of the interface.
Due to the nature of how Ethernet and tinc work, it has to be set to fe:fd:0:0:0:0
for tinc to work in it's normal mode.
If you configured tinc to work in `switch' or `hub' mode, the hardware address should instead
be set to a unique address instead of fe:fd:0:0:0:0.
You can use the environment variable $INTERFACE to get the name of the interface.
If you are using the ethertap driver however, you need to replace it with tap@emph{N},
corresponding to the device file name.
@ -964,7 +1045,8 @@ own subnet.
@cindex arp
The last line tells the kernel not to use ARP on that interface.
Again this has to do with how Ethernet and tinc work. Don't forget to add this line.
Again this has to do with how Ethernet and tinc work.
Use this option only if you are running tinc under Linux and are using tinc's normal routing mode.
@c ==================================================================
@ -1010,7 +1092,7 @@ In @file{/etc/tinc/company/tinc-up}:
# Real interface of internal network:
# ifconfig eth0 10.1.54.1 netmask 255.255.0.0 broadcast 10.1.255.255
ifconfig tap0 hw ether fe:fd:00:00:00:00
ifconfig tap0 hw ether fe:fd:0:0:0:0
ifconfig tap0 10.1.54.1 netmask 255.0.0.0
ifconfig tap0 -arp
@end example
@ -1020,7 +1102,7 @@ and in @file{/etc/tinc/company/tinc.conf}:
@example
Name = BranchA
PrivateKey = /etc/tinc/company/rsa_key.priv
TapDevice = /dev/tap0
Device = /dev/tap0
@end example
On all hosts, /etc/tinc/company/hosts/BranchA contains:
@ -1048,7 +1130,7 @@ In @file{/etc/tinc/company/tinc-up}:
# Real interface of internal network:
# ifconfig eth0 10.2.43.8 netmask 255.255.0.0 broadcast 10.2.255.255
ifconfig tap0 hw ether fe:fd:00:00:00:00
ifconfig tap0 hw ether fe:fd:0:0:0:0
ifconfig tap0 10.2.1.12 netmask 255.0.0.0
ifconfig tap0 -arp
@end example
@ -1085,7 +1167,7 @@ In @file{/etc/tinc/company/tinc-up}:
# Real interface of internal network:
# ifconfig eth0 10.3.69.254 netmask 255.255.0.0 broadcast 10.3.255.255
ifconfig tap1 hw ether fe:fd:00:00:00:00
ifconfig tap1 hw ether fe:fd:0:0:0:0
ifconfig tap1 10.3.69.254 netmask 255.0.0.0
ifconfig tap1 -arp
@end example
@ -1095,7 +1177,7 @@ and in @file{/etc/tinc/company/tinc.conf}:
@example
Name = BranchC
ConnectTo = BranchA
TapDevice = /dev/tap1
Device = /dev/tap1
@end example
C already has another daemon that runs on port 655, so they have to
@ -1133,13 +1215,13 @@ and in @file{/etc/tinc/company/tinc.conf}:
@example
Name = BranchD
ConnectTo = BranchC
TapDevice = /dev/net/tun
Device = /dev/misc/net/tun
PrivateKeyFile = /etc/tinc/company/rsa_key.priv
@end example
D will be connecting to C, which has a tincd running for this network on
port 2000. It knows the port number from the host configuration file.
Also note that since D uses the TUN/TAP driver, the network interface
Also note that since D uses the tun/tap driver, the network interface
will not be called `tun' or `tap0' or something like that, but will
have the same name as netname.
@ -1211,33 +1293,19 @@ generated automatically, so may be more up-to-date.
@cindex options
@c from the manpage
@table @samp
@item --bypass-security
Disables encryption and authentication.
Only useful for debugging.
@item -c, --config=PATH
Read configuration options from the directory PATH. The default is
@file{/etc/tinc/netname/}.
@cindex debug level
@item -d
Increase debug level. The higher it gets, the more gets
@item -d, --debug=LEVEL
Set debug level to LEVEL. The higher the debug level, the more gets
logged. Everything goes via syslog.
0 is the default, only some basic information connection attempts get
logged. Setting it to 1 will log a bit more, still not very
disturbing. With two -d's tincd will log protocol information, which can
get pretty noisy. Three or more -d's will output every single packet
that goes out or comes in, which probably generates more data than the
packets themselves.
@item -k, --kill
Attempt to kill a running tincd and exit. A TERM signal (15) gets sent
to the daemon that his its PID in /var/run/tinc.pid.
Because it kills only one tinc daemon, you should use -n here if you
started it that way. It will then read the PID from
@file{/var/run/tinc.NETNAME.pid}.
@item -n, --net=NETNAME
Connect to net NETNAME. @xref{Multiple networks}.
@item -K, --generate-keys[=BITS]
Generate public/private keypair of BITS length. If BITS is not specified,
1024 is the default. tinc will ask where you want to store the files,
@ -1247,6 +1315,18 @@ in combination with -K). After that, tinc will quit.
@item --help
Display a short reminder of these runtime options and terminate.
@item -k, --kill
Attempt to kill a running tincd and exit. A TERM signal (15) gets sent
to the daemon that his its PID in @file{/var/run/tinc.NETNAME.pid}.
Use it in conjunction with the -n option to make sure you kill the right tinc daemon.
@item -n, --net=NETNAME
Connect to net NETNAME. @xref{Multiple networks}.
@item -D, --no-detach
Don't fork and detach.
This will also disable the automatic restart mechanism for fatal errors.
@item --version
Output version information and exit.
@ -1269,7 +1349,7 @@ only, so keep an eye on it!
@item You forgot to compile `Netlink device emulation' in the kernel.
@end itemize
@item Can't write to /dev/net/tun: No such device
@item Can't write to /dev/misc/net/tun: No such device
@itemize
@item You forgot to `modprobe tun'.
@ -1280,10 +1360,10 @@ only, so keep an eye on it!
@itemize
@item Something is not configured right. Packets are being sent out to the
tap device, but according to the Subnet directives in your host configuration
virtual network device, but according to the Subnet directives in your host configuration
file, those packets should go to your own host. Most common mistake is that
you have a Subnet line in your host configuration file with a netmask which is
just as large as the netmask of the tap device. The latter should in almost all
just as large as the netmask of the virtual network interface. The latter should in almost all
cases be larger. Rethink your configuration.
Note that you will only see this message if you specified a debug
level of 5 or higher!
@ -1300,7 +1380,7 @@ Jan 1 12:00:00 host tinc.net[1234]: Read packet of length 46 from tap device
Jan 1 12:00:00 host tinc.net[1234]: Trying to look up 0.0.192.168 in connection list failed!
@end example
@itemize
@item Add the `ifconfig $NETNAME -arp' to tinc-up.
@item Add the `ifconfig $INTERFACE -arp' to tinc-up.
@end itemize
@item Network address and subnet mask do not match!
@ -1360,10 +1440,10 @@ computer over the existing Internet infrastructure.
@node The UDP tunnel, The meta-connection, The connection, The connection
@subsection The UDP tunnel
@cindex ethertap
@cindex virtual network device
@cindex frame type
The data itself is read from a character device file, the so-called
@emph{ethertap} device. This device is associated with a network
@emph{virtual network device}. This device is associated with a network
interface. Any data sent to this interface can be read from the device,
and any data written to the device gets sent from the interface. Data to
and from the device is formatted as if it were a normal Ethernet card,
@ -1371,32 +1451,35 @@ so a frame is preceded by two MAC addresses and a @emph{frame type}
field.
So when tinc reads an Ethernet frame from the device, it determines its
type. Right now, tinc can only handle Internet Protocol version 4 (IPv4)
frames, because it needs IP headers for routing.
Plans to support other protocols and switching instead of routing are being made.
(Some code for IPv6 routing and switching is already present but nonfunctional.)
When tinc knows
which type of frame it has read, it can also read the source and
destination address from it.
type. When tinc is in it's default routing mode, it can handle IPv4 and IPv6
packets. Depending on the Subnet lines, it will send the packets off to their destination.
In the `switch' and `hub' mode, tinc will use broadcasts and MAC address discovery
to deduce the destination of the packets.
Since the latter modes only depend on the link layer information,
any protocol that runs over Ethernet is supported (for instance IPX and Appletalk).
Now it is time that the frame gets encrypted. Currently the only
encryption algorithm available is blowfish.
After the destination has been determined, a sequence number will be added to the packet.
The packet will then be encrypted and a message authentication
code will be appended.
@cindex encapsulating
@cindex UDP
When the encryption is ready, time has come to actually transport the
When that is done, time has come to actually transport the
packet to the destination computer. We do this by sending the packet
over an UDP connection to the destination host. This is called
@emph{encapsulating}, the VPN packet (though now encrypted) is
encapsulated in another IP datagram.
When the destination receives this packet, the same thing happens, only
in reverse. So it does a decrypt on the contents of the UDP datagram,
and it writes the decrypted information to its own ethertap device.
in reverse. So it checks the message authentication code, decrypts the contents of the UDP datagram,
checks the sequence number
and writes the decrypted information to its own virtual network device.
To let the kernel on the receiving end accept the packet, the destination MAC
address must match that of the tap interface. Because of the routing nature
of tinc, ARP is not possible. tinc solves this by always overwriting the
address must match that of the virtual network interface.
If tinc is in it's default routing mode, ARP does not work, so the correct destination MAC cannot be set
by the sending daemons.
tinc solves this by always overwriting the
destination MAC address with fe:fd:0:0:0:0. That is also the reason why you must
set the MAC address of your tap interface to that address.
@ -1451,32 +1534,35 @@ daemon and to read and write requests by hand, provided that one
understands the numeric codes sent.
The authentication scheme is described in @ref{Authentication protocol}. After a
succesful authentication, the server and the client will exchange all the
successful authentication, the server and the client will exchange all the
information about other tinc daemons and subnets they know of, so that both
sides (and all the other tinc daemons behind them) have their information
synchronised.
@cindex ADD_HOST
@cindex ADD_EDGE
@cindex ADD_SUBNET
@example
daemon message
--------------------------------------------------------------------------
origin ADD_HOST daemon a329e18c:655 0
| | +--> options
| +---------> real address:port
+-------------------> name of new tinc daemon
origin ADD_SUBNET daemon 1,0a010100/ffffff00
| | | +--> netmask
| | +----------> vpn IPv4 network address
| +----------------> subnet type (1=IPv4)
+--------------------> owner of this subnet
origin ADD_EDGE node1 12.23.34.45 655 node2 21.32.43.54 655 222 0
| | | \___________________/ | +-> options
| | | | +----> weight
| | | +----------------> see below
| | +--> UDP port
| +----------> real address
+------------------> name of node on one side of the edge
origin ADD_SUBNET node 192.168.1.0/24
| | +--> masklength
| +--------> IPv4 network address
+------------------> owner of this subnet
--------------------------------------------------------------------------
@end example
@cindex DEL_HOST
@cindex DEL_SUBNET
In case daemons leave the VPN, DEL_HOST and DEL_SUBNET messages with exactly
the same syntax are sent to inform the other daemons of the departure.
@cindex DEL_EDGE
In case a connection between two daemons is closed or broken, DEL_EDGE messages
are sent to inform the other daemons of that fact. Each daemon will calculate a
new route to the the daemons, or mark them unreachable if there isn't any.
The keys used to encrypt VPN packets are not sent out directly. This is
because it would generate a lot of traffic on VPNs with many daemons, and
@ -1484,7 +1570,7 @@ chances are that not every tinc daemon will ever send a packet to every
other daemon. Instead, if a daemon needs a key it sends a request for it
via the meta connection of the nearest hop in the direction of the
destination. If any hop on the way has already learned the key, it will
act as a proxy and forward it's copy back to the requestor.
act as a proxy and forward its copy back to the requester.
@cindex REQ_KEY
@cindex ANS_KEY
@ -1495,11 +1581,15 @@ daemon message
daemon REQ_KEY origin destination
| +--> name of the tinc daemon it wants the key from
+----------> name of the daemon that wants the key
daemon ANS_KEY origin destination e4ae0b0a82d6e0078179b5290c62c7d0
| | \______________________________/
| | +--> 128 bits key
daemon ANS_KEY origin destination 4ae0b0a82d6e0078 91 64 4
| | \______________/ | | +--> MAC length
| | | | +-----> digest algorithm
| | | +--------> cipher algorithm
| | +--> 128 bits key
| +--> name of the daemon that wants the key
+----------> name of the daemon that uses this key
daemon KEY_CHANGED origin
+--> daemon that has changed it's packet key
--------------------------------------------------------------------------
@ -1518,12 +1608,8 @@ messages without any other traffic won't result in known plaintext.
@example
daemon message
--------------------------------------------------------------------------
origin PING 9e76
\__/
+--> 2 bytes of salt (random data)
dest. PONG 3b8d
\__/
+--> 2 bytes of salt (random data)
origin PING
dest. PONG
--------------------------------------------------------------------------
@end example
@ -1546,9 +1632,8 @@ the tinc project after TINC.
But in order to be ``immune'' to eavesdropping, you'll have to encrypt
your data. Because tinc is a @emph{Secure} VPN (SVPN) daemon, it does
exactly that: encrypt.
tinc uses blowfish encryption in CBC mode and a small amount of salt
at the beginning of each packet to make sure eavesdroppers cannot get
any information at all from the packets they can intercept.
tinc uses blowfish encryption in CBC mode, sequence numbers and message authentication codes
to make sure eavesdroppers cannot get and cannot change any information at all from the packets they can intercept.
@menu
* Authentication protocol::
@ -1565,6 +1650,11 @@ A new scheme for authentication in tinc has been devised, which offers some
improvements over the protocol used in 1.0pre2 and 1.0pre3. Explanation is
below.
@cindex ID
@cindex META_KEY
@cindex CHALLENGE
@cindex CHAL_REPLY
@cindex ACK
@example
daemon message
--------------------------------------------------------------------------
@ -1572,15 +1662,13 @@ client <attempts connection>
server <accepts connection>
client ID client 10 0
| | +-> options
| +---> version
+--------> name of tinc daemon
client ID client 12
| +---> version
+-------> name of tinc daemon
server ID server 10 0
| | +-> options
| +---> version
+--------> name of tinc daemon
server ID server 12
| +---> version
+-------> name of tinc daemon
client META_KEY 5f0823a93e35b69e...7086ec7866ce582b
\_________________________________/
@ -1593,8 +1681,8 @@ server META_KEY 6ab9c1640388f8f0...45d1a07f8a672630
encrypted with client's public RSA key
From now on:
- the client will encrypt outgoing traffic using S1
- the server will encrypt outgoing traffic using S2
- the client will symmetrically encrypt outgoing traffic using S1
- the server will symmetrically encrypt outgoing traffic using S2
client CHALLENGE da02add1817c1920989ba6ae2a49cecbda0
\_________________________________/
@ -1609,6 +1697,21 @@ client CHAL_REPLY 816a86
server CHAL_REPLY 928ffe
+-> 160 bits SHA1 of H1
After the correct challenge replies are received, both ends have proved
their identity. Further information is exchanged.
client ACK 655 12.23.34.45 123 0
| | | +-> options
| | +----> estimated weight
| +------------> IP address of server as seen by client
+--------------------> UDP port of client
server ACK 655 21.32.43.54 321 0
| | | +-> options
| | +----> estimated weight
| +------------> IP address of client as seen by server
+--------------------> UDP port of server
--------------------------------------------------------------------------
@end example
@ -1662,35 +1765,26 @@ an attacker) in the beginning of the encrypted stream.
A data packet can only be sent if the encryption key is known to both
parties, and the connection is activated. If the encryption key is not
known, a request is sent to the destination using the meta connection
to retreive it. The packet is stored in a queue while waiting for the
to retrieve it. The packet is stored in a queue while waiting for the
key to arrive.
@cindex UDP
The UDP packet containing the network packet from the VPN has the following layout:
@example
... | IP header | UDP header | salt | VPN packet | UDP trailer
\___________________/
|
V
... | IP header | UDP header | seqno | VPN packet | MAC | UDP trailer
\___________________/\_____/
| |
V +---> digest algorithm
Encrypted with symmetric cipher
@end example
So, the entire UDP payload is encrypted using a symmetric cipher (blowfish in CBC mode).
2 bytes of salt (random data) are added in front of the actual VPN packet,
so that two VPN packets with (almost) the same content do not seem to be
the same for eavesdroppers.
2 bytes of salt may not seem much, but you can encrypt 65536 identical packets
now without an attacker being able to see that they were identical.
Given a MTU of 1500 this means 96 Megabyte of data.
There is no @emph{extra} provision against replay attacks or alteration of packets.
However, the VPN packets, normally UDP or TCP packets themselves, contain
checksums and sequence numbers.
Since those checksums and sequence numbers are encrypted,
they automatically become @emph{cryptographically secure}.
The kernel will handle any checksum errors and duplicate packets.
So, the entire VPN packet is encrypted using a symmetric cipher. A 32 bits
sequence number is added in front of the actual VPN packet, to act as a unique
IV for each packet and to prevent replay attacks. A message authentication code
is added to the UDP packet to prevent alteration of packets. By default the
first 4 bytes of the digest are used for this, but this can be changed using
the MACLength configuration variable.
@c ==================================================================
@node About us, Concept Index, Technical information, Top