.\" -*-nroff-*- .\". .\" Manual for the server .\" .\" (c) 2008 Straylight/Edgeware .\" . .\"----- Licensing notice --------------------------------------------------- .\" .\" This file is part of Trivial IP Encryption (TrIPE). .\" .\" TrIPE is free software; you can redistribute it and/or modify .\" it under the terms of the GNU General Public License as published by .\" the Free Software Foundation; either version 2 of the License, or .\" (at your option) any later version. .\" .\" TrIPE is distributed in the hope that it will be useful, .\" but WITHOUT ANY WARRANTY; without even the implied warranty of .\" MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the .\" GNU General Public License for more details. .\" .\" You should have received a copy of the GNU General Public License .\" along with TrIPE; if not, write to the Free Software Foundation, .\" Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. . .\"-------------------------------------------------------------------------- .so ../common/defs.man \" @@@PRE@@@ . .\"-------------------------------------------------------------------------- .TH tripe 8 "10 February 2001" "Straylight/Edgeware" "TrIPE: Trivial IP Encryption" . .\"-------------------------------------------------------------------------- .SH "NAME" . tripe \- a simple VPN daemon . .\"-------------------------------------------------------------------------- .SH "SYNOPSIS" . .B tripe .RB [ \-DF ] .RB [ \-d .IR dir ] .RB [ \-b .IR addr ] .RB [ \-p .IR port ] .RB [ \-n .IR tunnel ] .br \c .RB [ \-U .IR user ] .RB [ \-G .IR group ] .RB [ \-a .IR socket ] .RB [ \-m .IR mode ] .RB [ \-T .IR trace-opts ] .br \c .RB [ \-k .IR priv-keyring ] .RB [ \-K .IR pub-keyring ] .RB [ \-t .IR key-tag ] . .\"-------------------------------------------------------------------------- .SH "DESCRIPTION" . The .B tripe program is a server which can provide strong IP-level encryption and authentication between co-operating hosts. The program and its protocol are deliberately very simple, to make analysing them easy and to help build trust rapidly in the system. .SS "Overview" The .B tripe server manages a number of secure connections to other `peer' hosts. Each daemon is given a private key of its own, and a file of public keys for the peers with which it is meant to communicate. It is responsible for negotiating sets of symmetric keys with its peers, and for encrypting, encapsulating and sending IP packets to its peers, and decrypting, checking and de-encapsulating packets it receives from them. .PP When the server starts, it creates a Unix-domain socket on which it listens for administration commands. It also logs warnings and diagnostic information to the programs connected to its admin socket. Clients connected to the socket can add new peers, and remove or find out about existing peers. The textual protocol used to give the .B tripe server admin commands is described in .BR tripe\-admin (5). A client program .BR tripectl (1) is provided to allow commands to be sent to the server either interactively or by simple scripts. .SS "Command-line arguments" If not given any command-line arguments, .B tripe will initialize by following these steps: .hP 1. It sets the directory named by the .B TRIPEDIR environment variable (or .B "\*(/c" if the variable is unset) as the current directory. .hP 2. It acquires a UDP socket with an arbitrary kernel-selected port number. It will use this socket to send and receive all communications with its peer servers. The port chosen may be discovered by means of the .B PORT admin command (see .BR tripe\-admin (5)). .hP 3. It loads the private key with the tag or type name .B tripe (or, failing that, .B tripe\-dh for backwards compatibility reasons) from the Catacomb-format file .BR keyring , and loads the file .B keyring.pub ready for extracting the public keys of peers as they're introduced. (The format of these files is described in .BR keyring (5). They are maintained using the program .BR key (1) provided with the Catacomb distribution.) .hP 4. It creates and listens to the Unix-domain socket .BR tripesock . .PP Following this, the server enters its main loop, accepting admin connections and obeying any administrative commands, and communicating with peers. It also treats its standard input and standard output streams as an admin connection, reading commands from standard input and writing responses and diagnostics messages to standard output. Finally, it will reload keys from its keyring files if it notices that they've changed (it checks inode number and modification time) \- there's no need to send a signal. .PP Much of this behaviour may be altered by giving .B tripe suitable command-line options: .TP .B "\-h, \-\-help" Writes a brief description of the command-line options available to standard output and exits with status 0. .TP .B "\-v, \-\-version" Writes .BR tripe 's version number to standard output and exits with status 0. .TP .B "\-u, \-\-usage" Writes a brief usage summary to standard output and exits with status 0. .TP .B "\-\-tunnels" Writes to standard output a list of the configured tunnel drivers, one per line, and exits with status 0. This is intended for the use of the start-up script, so that it can check that it will actually work. .TP .B "\-D, \-\-daemon" Dissociates from its terminal and starts running in the background after completing the initialization procedure described above. If running as a daemon, .B tripe will not read commands from standard input or write diagnostics to standard output. A better way to start .B tripe in the background is with .BR tripectl (1). .TP .B "\-F, \-\-foreground" Runs the server in the `foreground'; i.e., .B tripe will quit if it sees end-of-file on its standard input. This is incompatible with .BR \-D . .TP .BI "\-d, \-\-directory=" dir Makes .I dir the current directory. The default directory to change to is given by the environment variable .BR TRIPEDIR ; if that's not specified, a default default of .B "\*(/c" is used. Give a current directory of .B . if you don't want it to change directory at all. .TP .BI "\-b, \-\-bind-address="addr Bind the UDP socket to IP address .I addr rather than the default of .BR INADDR_ANY . This is useful if your main globally-routable IP address is one you want to tunnel through the VPN. .TP .BI "\-p, \-\-port=" port Use the specified UDP port for all communications with peers, rather than an arbitarary kernel-assigned port. .TP .BI "\-n, \-\-tunnel=" tunnel Use the specified tunnel driver for new peers by default. .TP .BI "\-U, \-\-setuid=" user Set uid to that of .I user (either a user name or integer uid) after initialization. Also set gid to .IR user 's primary group, unless overridden by a .B \-G option. The selected user (and group) will also be the owner of the administration socket. .TP .BI "\-G, \-\-setgid=" group If the current effective uid is zero (i.e., the daemon was invoked as .BR root ) then set gid to that of .I group (either a group name or integer gid) after initialization. In any event, arrange hat the administration socket be owned by the given .IR group . .TP .BI "\-k, \-\-priv\-keyring=" file Reads the private key from .I file rather than the default .BR keyring . .TP .BI "\-K, \-\-pub\-keyring=" file Reads public keys from .I file rather than the default .BR keyring.pub . This can be the same as the private keyring, but that's not recommended. .TP .BI "\-t, \-\-tag=" tag Uses the private key whose tag or type is .I tag rather than the default .B tripe or .BR tripe\-dh . .TP .BI "\-a, \-\-admin\-socket=" socket Accept admin connections to a Unix-domain socket named .IR socket . The default socket, if this option isn't specified, is given by the environment variable .BR TRIPESOCK ; if that's not set either, then a default default of .B "\*(/s/tripesock" is used instead. .TP .BI "\-m, \-\-admin\-perms=" mode Permissions (as an octal number) to set on the administration socket. The default is 600, which allows only the socket owner. Setting 660 allows members of the .I group configured through the .B \-G option to connect to the socket, which may be useful. Allowing world access is a terrible idea. .TP .BI "\-T, \-\-trace=" trace-opts Allows the enabling or disabling of various internal diagnostics. See below for the list of options. .SS "Key exchange group types" The .B tripe server uses Diffie\(en\&Hellman key exchange to agree the symmetric keys used for bulk data transfer. Currently .B tripe can do Diffie\(en\&Hellman in two different kinds of cyclic groups: .I "Schnorr groups" (denoted .BR dh ) and .I "elliptic curve groups" (denoted .BR ec ). .PP A Schnorr group is a prime-order subgroup of the multiplicative group of a finite field; this is the usual .I g\*(ssx\*(se mod .I p kind of Diffie\(en\&Hellman. An elliptic curve group is a prime-order subgroup of the abelian group of .BR K -rational points on an elliptic curve defined over a finite field .BR K . .PP Given current public knowledge, elliptic curves can provide similar or better security to systems based on integer discrete log problems, faster, and with less transmitted data. It's a matter of controversy whether this will continue to be the case. The author uses elliptic curves. .PP The server works out which it should be doing based on the key's .B kx-group attribute, which should be either .B dh or .BR ec . If this attribute isn't present, then the key's type is examined: if it's of the form .BR tripe\- group then the .I group is used. If no group is specified, .B dh is used as a fallback. .PP To create usual Schnorr-group keys, say something like .VS key add \-adh-param \-LS \-b3072 \-B256 \e \-eforever \-tparam tripe\-param kx-group=dh .VE to construct a parameters key; and create the private keys by .VS key add \-adh \-pparam \-talice \e \-e"now + 1 year" tripe .VE To create elliptic curve keys, say something like .VS key add \-aec\-param \-Cnist-p256 \-eforever \e \-tparam tripe\-param kx-group=ec .VE to construct a parameters key, using your preferred elliptic curve in the .B \-C option (see .BR key (1) for details); and create the private keys by .VS key add \-aec \-pparam \-talice \e \-e"now + 1 year" tripe .VE Note that the .BR tripe-keys (8) program provides a rather more convenient means for generating and managing keys for .BR tripe . .SS "Using other symmetric algorithms" The default symmetric algorithms .B tripe uses are Blowfish (by Schneier) for symmetric encryption, and RIPEMD-160 (by Dobbertin, Bosselaers and Preneel) for hashing and as a MAC (in HMAC mode, designed by Bellare, Canetti and Krawczyk). These can all be overridden by setting attributes on your private key, as follows. .TP .B cipher Names the symmetric encryption scheme to use. The default is .BR blowfish\-cbc . .TP .B hash Names the hash function to use. The default is .BR rmd160 . .TP .B mac Names the message authentication code to use. The name of the MAC may be followed by a .RB ` / ' and the desired tag length in bits. The default is .IB hash \-hmac at half the underlying hash function's output length. .TP .B mgf A `mask-generation function', used in the key-exchange. The default is .IB hash \-mgf and there's no good reason to change it. .SS "Using SLIP interfaces" Though not for the faint of heart, it is possible to get .B tripe to read and write network packets to a pair of file descriptors using SLIP encapsulation. No fancy header compression of any kind is supported. .PP Two usage modes are supported: a preallocation system, whereby SLIP interfaces are created and passed to the .B tripe server at startup; and a dynamic system, where the server runs a script to allocate a new SLIP interface when it needs one. It is possible to use a mixture of these two modes, starting .B tripe with a few preallocated interfaces and having it allocate more dynamically as it needs them. .PP The behaviour of .BR tripe 's SLIP driver is controlled by the .B TRIPE_SLIPIF environment variable. The server will not create SLIP tunnels if this variable is not defined. The variable's value is a colon-delimited list of preallocated interfaces, followed optionally by the filename of a script to run to dynamically allocate more interfaces. .PP A static allocation entry has the form .IR infd [ \c .BI , outfd \c .RB ] \c .BI = \c .IR ifname , If the .I outfd is omitted, the same file descriptor is used for input and output. .PP The dynamic allocation script must be named by an absolute or relative pathname, beginning with .RB ` / ' or .RB ` . '. The server will pass the script an argument, which is the name of the peer for which the interface is being created. The script should allocate a new SLIP interface (presumably by creating a pty pair), configure it appropriately, and write the interface's name to its standard output, followed by a newline. It should then read and write SLIP packets on its stdin and stdout. The script's stdin will be closed when the interface is no longer needed, and the server will attempt to send it a .B SIGTERM signal (though this may fail if the script runs with higher privileges than the server). .PP The output file descriptor should not block unless it really needs to: the .B tripe daemon assumes that it won't, and will get wedged waiting for it to accept output. .SS "About the name" The program's name is .BR tripe , all in lower-case. The name of the protocol it uses is `TrIPE', with four capital letters and one lower-case. The name stands for `Trivial IP Encryption'. . .\"-------------------------------------------------------------------------- .SH "BUGS" . The code hasn't been audited. It may contain security bugs. If you find one, please inform the author .IR immediately . . .\"-------------------------------------------------------------------------- .SH "SEE ALSO" . .BR key (1), .BR tripectl (1), .BR tripe\-admin (5), .BR tripe\-keys (8). .PP .IR "The Trivial IP Encryption Protocol" , .IR "The Wrestlers Protocol" . . .\"-------------------------------------------------------------------------- .SH "AUTHOR" . Mark Wooding, . .\"----- That's all, folks --------------------------------------------------