Various RFCs and other documentation that we (I) may need

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Ed. Note: The following note is from the author's original email
announcing this CTCP specification file. All of this came after the
original RFC 1459 for the IRC protocol. -Jolo
From: ben@gnu.ai.mit.edu
Subject: REVISED AND UPDATED CTCP SPECIFICATION
Date: Fri, 12 Aug 94 00:21:54 edt
As part of documenting the ZenIRC client, I expanded, revised, and
merged two text files that have been around on IRC archive sites for
some time: ctcp.doc, and dcc.protocol. The file "ctcp.doc" by Klaus
Zeuge described the basic CTCP protocol, and most of the CTCP commands
other than DCC. The file Troy Rollo wrote, "dcc.protocol", contained
a description of the CTCP DCC messages as well as the protocols used
by DCC CHAT and DCC file transfers. I have merged the two documents to
produce this one, edited them for clarity, and expanded on them where I
found them unclear while implementing CTCP in the ZenIRC client.
--Ben
----------------------------------------------------------------------
The Client-To-Client Protocol (CTCP)
Klaus Zeuge <sojge@Minsk.DoCS.UU.SE>
Troy Rollo <troy@plod.cbme.unsw.oz.au>
Ben Mesander <ben@gnu.ai.mit.edu>
The Client-To-Client Protocol is meant to be used as a way to
1/ in general send structured data (such as graphics,
voice and different font information) between users
clients, and in a more specific case:
2/ place a query to a users client and getting an answer.
*****************************************
BASIC PROTOCOL BETWEEN CLIENTS AND SERVER
*****************************************
Characters between an Internet Relay Chat (IRC) client and server are
8 bit bytes (also known as octets) and can have numeric values from
octal \000 to \377 inclusive (0 to 255 decimal). Some characters are
special:
CHARS ::= '\000' .. '\377'
NUL ::= '\000'
NL ::= '\n'
CR ::= '\r'
Note: `\' followed by three digits is used to denote an octal value in this
paper. `\' followed by an alphabetic character is used to denote a C
language style special character, and `..' denotes a range of characters.
A line sent to a server, or received from a server (here called "low
level messages") consist or zero or more octets (expcept NUL, NL or
CR) with either a NL or CR appended.
L-CHARS ::= '\001' .. '\011' | '\013' | '\014' |
'\016' .. '\377'
L-LINE ::= L-CHARS* CR LF
Note: The `*' is used here to denote "zero or more of the preceding class of
characters", and the `|' is used to denote alternation.
A NUL is never sent to the server.
*****************
LOW LEVEL QUOTING
*****************
Even though messages to and from IRC servers cannot contain NUL, NL,
or CR, it still might be desirable to send ANY character (in so called
"middle level messages") between clients. In order for this to be
possible, those three characters have to be quoted. Therefore a quote
character is needed. Of course, the quote character itself has to be
quoted too, since it is in-band.
M-QUOTE ::= '\020'
(Ie a CNTRL/P).
When sending a middle level message, if there is a character in the
set { NUL, NL, CR, M-QUOTE } present in the message, that character is
replaced by a two character sequence according to the following table:
NUL --> M-QUOTE '0'
NL --> M-QUOTE 'n'
CR --> M-QUOTE 'r'
M-QUOTE --> M-QUOTE M-QUOTE
When receiving a low level message, if there is a M-QUOTE, look at the
next character, and replace those two according to the following table
to get the corresponding middle level message:
M-QUOTE '0' --> NUL
M-QUOTE 'n' --> NL
M-QUOTE 'r' --> CR
M-QUOTE M-QUOTE --> M-QUOTE
If the character following M-QUOTE is not any of the listed
characters, that is an error, so drop the M-QUOTE character from the
message, optionally warning the user about it. For example, a string
'x' M-QUOTE 'y' 'z' from a server dequotes into 'x 'y' 'z'.
Before low level quoting, a message to the server (and in the opposite
direction: after low level dequoting, a message from the server) looks
like:
M-LINE ::= CHARS*
***********
TAGGED DATA
***********
To send both extended data and query/reply pairs between clients, an
extended data format is needed. The extended data are sent in the text
part of a middle level message (and after low level quoting, in the
text part of the low level message).
To send extended data inside the middle level message, we need some
way to delimit it. This is done by starting and ending extended data
with a delimiter character, defined as:
X-DELIM ::= '\001'
As both the starting and ending delimiter looks the same, the first
X-DELIM is called the odd delimiter, and the one that follows, the
even delimiter. The next one after that, an odd delimiter, then and
even, and so on.
When data are quoted (and conversely, before being dequoted) any number
of characters of any kind except X-DELIM can be used in the extended
data inside the X-DELIM pair.
X-CHR ::= '\000' | '\002' .. '\377'
An extended message is either empty (nothing between the odd and even
delimiter), has one or more non-space characters (any character but
'\040') or has one or more non-space characters followed by a space
followed by zero or more characters.
X-N-AS ::= '\000' | '\002' .. '\037' | '\041' .. '\377'
SPC ::= '\040'
X-MSG ::= | X-N-AS+ | X-N-AS+ SPC X-CHR*
Note: Here `+' is used to denote "one or more of the previous class of
characters", and `*' is used to denote "zero or more of the previous
class of characters".
The characters up until the first SPC (or if no SPC, all of the X-MSG)
is called the tag of the extended message. The tag is used to denote
what kind of extended data is used.
The tag can be *any* string of characters, and if it contains
alphabetics, it is case sensitive, so upper and lower case matters.
Extended data is only valid in PRIVMSG and NOTICE commands. If the
extended data is a reply to a query, it is sent in a NOTICE, otherwise
it is sent in a PRIVMSG. Both PRIVMSG and NOTICE to a user and to a
channel may contain extended data.
The text part of a PRIVMSG or NOTICE might contain zero or more
extended messages, intermixed with zero or more chunks of non-extended
data.
******************
CTCP LEVEL QUOTING
******************
In order to be able to send the delimiter X-DELIM inside an extended
data message, it has to be quoted. This introduces another quote
character (which differs from the low level quote character so it
won't have to be quoted yet again).
X-QUOTE ::= '\134'
(a back slash - `\').
When quoting on the CTCP level, only the actual CTCP message (extended
data, queries, replies) are quoted. This enables users to actually
send X-QUOTE characters at will. The following translations should be
used:
X-DELIM --> X-QUOTE 'a'
X-QUOTE --> X-QUOTE X-QUOTE
and when dequoting on the CTCP level, only CTCP messages are dequoted
whereby the following table is used.
X-QUOTE 'a' --> X-DELIM
X-QUOTE X-QUOTE --> X-QUOTE
If an X-QUOTE is seen with a character following it other than the
ones above, that is an error and the X-QUOTE character should be
dropped. For example the CTCP-quoted string 'x' X-QUOTE 'y' 'z'
becomes after dequoting, the three character string 'x' 'y' 'z'.
If a X-DELIM is found outside a CTCP message, the message will contain
the X-DELIM. (This should only happen with the last X-DELIM when there
are an odd number of X-DELIM's in a middle level message.)
****************
QUOTING EXAMPLES
****************
There are three levels of messages. The highest level (H) is the text
on the user-to-client level. The middle layer (M) is on the level
where CTCP quoting has been applied to the H-level message. The lowest
level (L) is on the client-to-server level, where low level quoting
has been applied to the M-level message.
The following relations are true, with lowQuote(message) being a
function doing the low level quoting, lowDequote(message) the low
level dequoting function, ctcpQuote(message) the CTCP level quoting
function, ctcpDequote(message) the CTCP level dequoting function, and
ctcpExtract(message) the function which removes all CTCP messages from
a message:
L = lowQuote(M)
M = ctcpDequote(L)
M = ctcpQuote(H)
H = ctcpDequote(ctcpExtract(M))
When sending a CTCP message embedded in normal text:
M = ctcpQuote(H1) || '\001' || ctcpQuote(X) || '\001' || ctcpQuote(H2)
Note: The operator || denotes string concatenation.
Of course, there might be zero or more normal text messages and zero
or more CTCP messages mixed.
- --- Example 1 -----------------------------------------------------------------
A user (called actor) wanting to send the string:
Hi there!\nHow are you?
to user victim, i.e. a message where the user has entered an inline
newline (how this is done, if at all, differs from client to client),
will result internaly in the client in the command:
PRIVMSG victim :Hi there!\nHow are you? \K?
which will be CTCP quoted into:
PRIVMSG victim :Hi there!\nHow are you? \\K?
which in turn will be low level quoted into:
PRIVMSG victim :Hi there!\020nHow are you? \\K?
and sent to the server after appending a newline at the end.
This will arrive on victim's side as:
:actor PRIVMSG victim :Hi there!\020nHow are you? \\K?
(where the \\K would look similar to OK in SIS D47 et. al.) which after
low level dequoting becomes:
:actor PRIVMSG victim :Hi there!\nHow are you? \\K?
and after CTCP dequoting:
:actom PRIVMSG victim :Hi there!\nHow are you? \K?
How this is displayed differs from client to client, but it suggested
that a line break should occour between the words "there" and "How".
- --- Example 2 -----------------------------------------------------------------
If actor's client wants to send the string "Emacs wins" this might
become the string "\n\t\big\020\001\000\\:" when being SED-encrypted
[SED is a simple encryption protocol between IRC clients implemented
with CTCP. I don't have any reference for it -- Ben] using some key,
so the client starts by CTCP-quoting this string into the string
"\n\t\big\020\\a\000\\\\:" and builds the M-level message:
PRIVMSG victim :\001SED \n\t\big\020\\a\000\\\\:\001
which after low level quoting becomes:
PRIVMSG victim :\001SED \020n\t\big\020\020\\a\0200\\\\:\001
which will be sent to the server, with a newline tacked on.
On victim's side, the string:
:actor PRIVMSG victim :\001SED \020n\t\big\020\020\\a\0200\\\\:\001
will be received from the server and low level dequoted into:
:actor PRIVMSG victim :\001SED \n\t\big\020\\a\000\\\\:\001
whereafter the string "\n\t\big\020\\a\000\\\\:" will be extracted
and first CTCP dequoted into "\n\t\big\020\001\000\\:" and then
SED decoded getting back "Emacs wins" when using the same key.
- --- Example 3 -----------------------------------------------------------------
If the user actor wants to query the USERINFO of user victim, and is
in the middle of a conversation, the client may decide to tack on
USERINFO request on the end of a normal text message. Let's say actor
wants to send the textmessage "Say hi to Ron\n\t/actor" and the CTCP
request "USERINFO" to victim:
PRIVMSG victim :Say hi to Ron\n\t/actor
plus:
USERINFO
which after CTCP quoting become:
PRIVMSG victim :Say hi to Ron\n\t/actor
plus:
USERINFO
which gets merged into:
PRIVMSG victim :Say hi to Ron\n\t/actor\001USERINFO\001
and after low level quoting:
PRIVMSG victim :Say hi to Ron\020n\t/actor\001USERINFO\001
and sent off to the server.
On victim's side, the message:
:actor PRIVMSG victim :Say hi to Ron\020n\t/actor\001USERINFO\001
arrives. This gets low level dequoted into:
:actor PRIVMSG victim :Say hi to Ron\n\t/actor\001USERINFO\001
and thereafter split up into:
:actor PRIVMSG victim :Say hi to Ron\n\t/actor
plus:
USERINFO
After CTCP dequoting both, the message:
:actor PRIVMSG victim :Say hi to Ron\n\t/actor
gets displayed, while the CTCP command:
USERINFO
gets replied to. The reply might be:
USERINFO :CS student\n\001test\001
which gets CTCP quoted into:
USERINFO :CS student\n\\atest\\a
and sent in a NOTICE as it is a reply:
NOTICE actor :\001USERINFO :CS student\n\\atest\\a\001
and low level quoted into:
NOTICE actor :\001USERINFO :CS student\020n\\atest\\a\001
after which is it sent to victim's server.
When arriving on actor's side, the message:
:victim NOTICE actor :\001USERINFO :CS student\020n\\atest\\a\001
gets low level dequoted into:
:victim NOTICE actor :\001USERINFO :CS student\n\\atest\\a\001
At this point, all CTCP replies get extracted, giving 1 CTCP reply and
no normal NOTICE:
USERINFO :CS student\n\\atest\\a
The remaining reply gets CTCP dequoted into:
USERINFO :CS student\n\001test\001
and presumly displayed to user actor.
*******************
KNOWN EXTENDED DATA
*******************
Extended data passed between clients can be used to pass structured
information between them. Currently known extended data types are:
ACTION - Used to simulate "role playing" on IRC.
DCC - Negotiates file transfers and direct tcp chat
connections between clients.
SED - Used to send encrypted messages between clients.
ACTION
======
This is used by losers on IRC to simulate "role playing" games. An
action message looks like the following:
\001ACTION barfs on the floor.\001
Clients that recieve such a message should format them to indicate the
user who did this is performing an "action". For example, if the user
"actor" sent the above message to the channel "#twilight_zone", other
users clients might display the message as:
[ACTION] actor->#twilight_zone: barfs on the floor.
Presumably other users on the channel are suitably impressed.
DCC
===
DCC stands for something like "Direct Client Connection". CTCP DCC
extended data messages are used to negotiate file transfers between
clients and to negotiate chat connections over tcp connections between
two clients, with no IRC server involved. Connections between clients
involve protocols other than the usual IRC protocol. Due to this
complexity, a full description of the DCC protocol is included
separately at the end of this document in Appendix A.
SED
===
SED probably stands for something like "Simple Encryption D???". It is
used by clients to exchange encrypted messages between clients. A
message encoded by SED probably looks something like:
\001SED encrypted-text-goes-here\001
Clients which accept such messages should display them in decrypted
form. It would be nice if someone documented this, and included the
encryption scheme in an Appendix B.
*************************
KNOWN REQUEST/REPLY PAIRS
*************************
A request/reply pair is sent between the two clients in two phases.
The first phase is to send the request. This is done with a "privmsg"
command (either to a nick or to a channel -- it doesn't matter).
The second phase is to send a reply. This is done with a "notice"
command.
The known request/reply pairs are for the following commands.
FINGER - Returns the user's full name, and idle time.
VERSION - The version and type of the client.
SOURCE - Where to obtain a copy of a client.
USERINFO - A string set by the user (never the client coder)
CLIENTINFO - Dynamic master index of what a client knows.
ERRMSG - Used when an error needs to be replied with.
PING - Used to measure the delay of the IRC network
between clients.
TIME - Gets the local date and time from other clients.
FINGER
======
This is used to get a user's real name, and perhaps also the idle time
of the user (this usage has been obsoleted by enhancements to the IRC
protocol. The request is in a "privmsg" and looks like
\001FINGER\001
while the reply is in a "notice" and looks like
\001FINGER :#\001
where the # denotes contains information about the users real name,
login name at clientmachine and idle time and is of type X-N-AS.
VERSION
=======
This is used to get information about the name of the other client and
the version of it. The request in a "privmsg" is simply
\001VERSION\001
and the reply
\001VERSION #:#:#\001
where the first # denotes the name of the client, the second # denotes
the version of the client, the third # the enviroment the client is
running in.
Using
X-N-CLN ::= '\000' .. '\071' | '\073' .. '\377'
the client name is a string of type X-N-CLN saying things like "Kiwi"
or "ircII", the version saying things like "5.2" or "2.1.5c", the
enviroment saying things like "GNU Emacs 18.57.19 under SunOS 4.1.1 on
Sun SLC" or "Compiled with gcc -ansi under Ultrix 4.0 on VAX-11/730".
SOURCE
This is used to get information about where to get a copy of the
client. The request in a "privmsg" is simply
\001SOURCE\001
and the reply is zero or more CTCP replies of the form
\001SOURCE #:#:#\001
followed by an end marker
\001SOURCE\001
where the first # is the name of an Internet host where the client can
be gotten from with anonymous FTP the second # a directory names, and
the third # a space separated list of files to be gotten from that
directory.
Using
X-N-SPC ::= '\000' .. '\037' | '\041' .. '\377'
the name of the FTP site is to be given by name like "cs.bu.edu" or
"funic.funet.fi".
The file name field is a directory specification optionally followed
by one or more file names, delimited by spaces. If only a directory
name is given, all files in that directory should be copied when
retrieving the clients source. If some files are given, only those
files in that directpry should be copied. Note that the spcification
allows for all characters but space in the names, this includes
allowing :. Examples are "pub/emacs/irc/" to get all files in
directory pub/emacs/irc/, the client should be able to first login as
user "ftp" and the give the command "CD pub/emacs/irc/", followed by
the command "mget *". (It of course has to take care of binary and
prompt mode too). Another example is "/pub/irc Kiwi.5.2.el.Z" in which
case a "CD /pub/irc" and "get Kiwi.5.2.el.Z" is what should be done.
USERINFO
========
This is used to transmit a string which is settable by the user (and
never should be set by the client). The query is simply
\001USERINFO\001
with the reply
\001USERINFO :#\001
where the # is the value of the string the client's user has set.
CLIENTINFO
==========
This is for client developers use to make it easier to show other
client hackers what a certain client knows when it comes to CTCP. The
replies should be fairly verbose explaining what CTCP commands are
understood, what arguments are expected of what type, and what replies
might be expected from the client.
The query is the word CLIENTINFO in a "privmsg" optionally followed by
a colon and one or more specifying words delimited by spaces, where
the word CLIENTINFO by itself,
\001CLIENTINFO\001
should be replied to by giving a list of known tags (see above in
section TAGGED DATA). This is only intended to be read by humans.
With one argument, the reply should be a description of how to use
that tag. With two arguments, a description of how to use that
tag's subcommand. And so on.
ERRMSG
======
This is used as a reply whenever an unknown query is seen. Also, when
used as a query, the reply should echo back the text in the query,
together with an indication that no error has happened. Should the
query form be used, it is
\001ERRMSG #\001
where # is a string containing any character, with the reply
\001ERRMSG # :#\001
where the first # is the same string as in the query and the second #
a short text notifying the user that no error has occurred.
A normal ERRMSG reply which is sent when a corrupted query or some
corrupted extended data is received, looks like
\001ERRMSG # :#\001
where the first # is the the failed query or corrupted extended data
and the second # a text explaining what the problem is, like "unknown
query" or "failed decrypting text".
PING
====
Ping is used to measure the time delay between clients on the IRC
network. A ping query is encoded in a privmsg, and has the form:
\001PING timestamp\001
where `timestamp' is the current time encoded in any form the querying
client finds convienent. The replying client sends back an identical
message inside a notice:
\001PING timestamp\001
The querying client can then subtract the recieved timestamp from the
current time to obtain the delay between clients over the IRC network.
TIME
====
Time queries are used to determine what time it is where another
user's client is running. This can be useful to determine if someone
is probably awake or not, or what timezone they are in. A time query
has the form:
\001TIME\001
On reciept of such a query in a privmsg, clients should reply with a
notice of the form:
\001TIME :human-readable-time-string\001
For example:
\001TIME :Thu Aug 11 22:52:51 1994 CST\001
********
EXAMPLES
********
Sending
PRIVMSG victim :\001FINGER\001
might return
:victim NOTICE actor :\001FINGER :Please check my USERINFO
instead :Klaus Zeuge (sojge@mizar) 1 second has passed since
victim gave a command last.\001
(this is only one line) or why not
:victim NOTICE actor :\001FINGER :Please check my USERINFO
instead :Klaus Zeuge (sojge@mizar) 427 seconds (7 minutes and
7 seconds) have passed since victim gave a command last.\001
if Klaus Zeuge happens to be lazy? :-)
Sending
PRIVMSG victim :\001CLIENTINFO\001
might return
:victim NOTICE actor :\001CLIENTINFO :You can request help of the
commands CLIENTINFO ERRMSG FINGER USERINFO VERSION by giving
an argument to CLIENTINFO.\001
Sending
PRIVMSG victim :\001CLIENTINFO CLIENTINFO\001
might return
:victim NOTICE actor :\001CLIENTINFO :CLIENTINFO with 0
arguments gives a list of known client query keywords. With 1
argument, a description of the client query keyword is
returned.\001
while sending
PRIVMSG victim :\001clientinfo clientinfo\001
probably will return something like
:victim NOTICE actor :\001ERRMSG clientinfo clientinfo :Query is
unknown\001
as tag "clientinfo" isn't known.
Sending
PRIVMSG victim :\001CLIENTINFO ERRMSG\001
might return
:victim NOTICE actor :\001CLIENTINFO :ERRMSG is the given answer
on seeing an unknown keyword. When seeing the keyword ERRMSG,
it works like an echo.\001
Sending
PRIVMSG victim :\001USERINFO\001
might return the somewhat pathetically long
:victim NOTICE actor :\001USERINFO :I'm studying computer
science in Uppsala, I'm male (somehow, that seems to be an
important matter on IRC:-) and I speak fluent swedish, decent
german, and some english.\001
Sending
PRIVMSG victim :\001VERSION\001
might return:
:victim NOTICE actor :\001VERSION Kiwi:5.2:GNU Emacs
18.57.19 under SunOS 4.1.1 on Sun
SLC:FTP.Lysator.LiU.SE:/pub/emacs Kiwi-5.2.el.Z
Kiwi.README\001
if the client is named Kiwi of version 5.2 and is used under GNU Emacs
18.57.19 running on a Sun SLCwith SunOS 4.1.1. The client claims a
copy of it can be found with anonymous FTP on FTP.Lysator.LiU.SE after
giving the FTP command "cd /pub/emacs/". There, one should get files
Kiwi-5.2.el.Z and Kiwi.README; presumably one of the files tells how to
proceed with building the client after having gotten the files.
----------------------------------------------------------------------
**********************************************************************
Appendix A -- A description of the DCC protocol
**********************************************************************
By Troy Rollo (troy@plod.cbme.unsw.oz.au)
Revised by Ben Mesander (ben@gnu.ai.mit.edu)
Troy Rollo, the original implementor of the DCC protocol, said
that the DCC protocol was never designed to be portable to clients
other than IRCII. However, time has shown that DCC is useable in
environments other than IRCII. IRC clients in diverse languages, such
as ksh, elisp, C, and perl have all had DCC implementations.
Why DCC?
========
DCC allows the user to overcome some limitations of the IRC
server network and to have a somewhat more secure chat connection
while still in an IRC-oriented protocol.
DCC uses direct TCP connections between the clients taking
part to carry data. There is no flood control, so packets can be sent
at full speed, and there is no dependance on server links (or load
imposed on them). In addition, since only the initial handshake for
DCC conections is passed through the IRC network, it makes it harder
for operators with cracked servers to spy on personal messages.
How?
====
The initial socket for a DCC connection is created
by the side that initiates (Offers) the connection. This socket
should be a TCP socket bound to INADDR_ANY, listening for
connections.
The Initiating client, on creating the socket, should
send its details to the target client using the CTCP command
DCC. This command takes the form:
DCC type argument address port [size]
type - The connection type.
argument - The connectin type dependant argument.
address - The host address of the initiator as an integer.
port - The port or the socket on which the initiator expects
to receive the connection.
size - If the connection type is "SEND" (see below), then size
will indicate the size of the file being offered. Obsolete
IRCII clients do not send this, so be prepared if this is
not present.
The address, port, and size should be sent as ASCII representations of
the decimal integer formed by converting the values to host byte order
and treating them as an unsigned long, unsigned short, and unsigned
long respectively.
Implementations of the DCC protocol should be prepared to
accept further arguments in a CTCP DCC message. There has been some
discussion of adding another argument that would specify the type of
file being transferred - text, binary, and perhaps others if DCC is
implemented on operating systems other than UNIX. If additional
arguments are added to the protocol, they should have semantics such
that clients which ignore them will interoperate with clients that
don't in a sensible way.
The following DCC connection types are defined:
Type Purpose Argument
CHAT To carry on a semi-secure conversation the string "chat"
SEND To send a file to the recipient the file name
Although the following subcommand is included in the IRCII DCC command,
it does _not_ transmit a DCC request via IRC, and thus is not
discussed in this document:
TALK Establishes a TALK connection
Implementation
==============
The CHAT and SEND connection types should not be
accepted automatically as this would create the potential for
terrorism. Instead, they should notify the user that an
offer has been made, and allow the user to accept it.
The recipient should have the opportunity to rename a file
offered with the DCC SEND command prior to retrieving it. It is also
desirable to ensure that the offered file will not overwrite an
existing file.
Older IRCII clients send the entire pathname of the file being
transmitted. This is annoying, and newer clients should simply send
the filename portion of the file being transmitted.
The port number should be scrutinized - if the port number is
in the UNIX reserved port range, the connection should only be
accepted with caution.
If it is not possible in the client implementation language to
handle a 32-bit integer (for instance emacs 18 elisp and ksh 88), then
it is often possible to use the hostname in the originating PRIVMSG.
The following are the steps which should occur in the clients
(this description assumes use of the BSD socket interface on a UNIX
system).
Initiator:
DCC command issued.
Create a socket, bind it to INADDR_ANY, port 0, and
make it passive (a listening socket).
Send the recipient a DCC request via CTCP supplying
the address and port of the socket. (This
is ideally taken from the address of the local
side of the socket which is connected to a
server. This is presumably the interface on
the host which is closest to the rest of
the net, and results in one less routing hop
in the case of gateway nodes).
Continue normally until a connection is received.
On a connection:
Accept the connection.
Close the original passive socket.
Conduct transaction on the new socket.
Acceptor:
CTCP DCC request received.
Record information on the DCC request and notify the user.
At this point, the USER should be able to abort (close) the
request, or accept it. The request should be accepted with
a command specifying the sender, type, and argument, or
a subset of these where no ambiguity exists.
If accepted, create a TCP socket.
Connect the new socket to the address and port supplied.
Conduct the transaction over the socket.
Type specific details.
======================
CHAT Data sent across a CHAT connection should be sent line-by-line
without any prefixes or commands. A CHAT connection ends when
one party issues the DCC CLOSE command to their clients, which
causes the socket to be closed and the information on the connection
to be discarded. The terminating character of each line is a
newline character, '\n'.
FILE Data is sent in packets, rather than dumped in a stream manner.
This allows the DCC SEND connection to survive where an FTP
connection might fail. The size of the packets is up to the
client, and may be set by the user. Smaller packets result
in a higher probability of survival over bad links.
The recipient should acknowledge each packet by transmitting
the total number of bytes received as an unsigned, 4 byte
integer in network byte order. The sender should not continue
to transmit until the recipient has acknowledged all data
already transmitted. Additionally, the sender should not
close the connection until the last byte has been
acknowledged by the recipient.
Older IRCII clients do not send the file size of the file
being transmitted via DCC. For those clients, note that it is
not possible for the recipient to tell if the entire file has
been received - only the sender has that information, although
IRCII does not report it. Users generally verify the transfer
by checking file sizes. Authors of clients are urged to use
the size feature.
Note also that no provision is made for text translation.
The original block size used by IRCII was 1024. Other clients
have adopted this. Note, however, that an implementation should accept
any blocksize. IRCII currently allows a user-settable blocksize.

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RFC 2810 (RFC2810)
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RFC 2810 - Internet Relay Chat: Architecture
----------------------------------------------------------------------
Network Working Group C. Kalt
Request for Comments: 2810 April 2000
Updates: 1459
Category: Informational
Internet Relay Chat: Architecture
Status of this Memo
This memo provides information for the Internet community. It does
not specify an Internet standard of any kind. Distribution of this
memo is unlimited.
Copyright Notice
Copyright (C) The Internet Society (2000). All Rights Reserved.
Abstract
The IRC (Internet Relay Chat) protocol is for use with text based
conferencing. It has been developed since 1989 when it was originally
implemented as a mean for users on a BBS to chat amongst themselves.
First formally documented in May 1993 by RFC 1459 [IRC], the protocol
has kept evolving. This document is an update describing the
architecture of the current IRC protocol and the role of its
different components. Other documents describe in detail the
protocol used between the various components defined here.
Table of Contents
1. Introduction ............................................... 2
2. Components ................................................. 2
2.1 Servers ................................................ 2
2.2 Clients ................................................ 3
2.2.1 User Clients ...................................... 3
2.2.2 Service Clients ................................... 3
3. Architecture ............................................... 3
4. IRC Protocol Services ...................................... 4
4.1 Client Locator ......................................... 4
4.2 Message Relaying ....................................... 4
4.3 Channel Hosting And Management ......................... 4
5. IRC Concepts ............................................... 4
5.1 One-To-One Communication ............................... 5
5.2 One-To-Many ............................................ 5
5.2.1 To A Channel ...................................... 5
5.2.2 To A Host/Server Mask ............................. 6
5.2.3 To A List ......................................... 6
5.3 One-To-All ............................................. 6
5.3.1 Client-to-Client .................................. 6
5.3.2 Client-to-Server .................................. 7
5.3.3 Server-to-Server .................................. 7
6. Current Problems ........................................... 7
6.1 Scalability ............................................ 7
6.2 Reliability ............................................ 7
6.3 Network Congestion ..................................... 7
6.4 Privacy ................................................ 8
7. Security Considerations .................................... 8
8. Current Support And Availability ........................... 8
9. Acknowledgements ........................................... 8
10. References ................................................ 8
11. Author's Address .......................................... 9
12. Full Copyright Statement .................................. 10
1. Introduction
The IRC (Internet Relay Chat) protocol has been designed over a
number of years for use with text based conferencing. This document
describes its current architecture.
The IRC Protocol is based on the client-server model, and is well
suited to running on many machines in a distributed fashion. A
typical setup involves a single process (the server) forming a
central point for clients (or other servers) to connect to,
performing the required message delivery/multiplexing and other
functions.
This distributed model, which requires each server to have a copy
of the global state information, is still the most flagrant problem
of the protocol as it is a serious handicap, which limits the maximum
size a network can reach. If the existing networks have been able to
keep growing at an incredible pace, we must thank hardware
manufacturers for giving us ever more powerful systems.
2. Components
The following paragraphs define the basic components of the IRC
protocol.
2.1 Servers
The server forms the backbone of IRC as it is the only component
of the protocol which is able to link all the other components
together: it provides a point to which clients may connect to talk to
each other [IRC-CLIENT], and a point for other servers to connect to
[IRC-SERVER]. The server is also responsible for providing the basic
services defined by the IRC protocol.
2.2 Clients
A client is anything connecting to a server that is not another
server. There are two types of clients which both serve a different
purpose.
2.2.1 User Clients
User clients are generally programs providing a text based
interface that is used to communicate interactively via IRC. This
particular type of clients is often referred as "users".
2.2.2 Service Clients
Unlike users, service clients are not intended to be used manually
nor for talking. They have a more limited access to the chat
functions of the protocol, while optionally having access to more
private data from the servers.
Services are typically automatons used to provide some kind of
service (not necessarily related to IRC itself) to users. An example
is a service collecting statistics about the origin of users
connected on the IRC network.
3. Architecture
An IRC network is defined by a group of servers connected to each
other. A single server forms the simplest IRC network.
The only network configuration allowed for IRC servers is that of
a spanning tree where each server acts as a central node for the rest
of the network it sees.
1--\
A D---4
2--/ \ /
B----C
/ \
3 E
Servers: A, B, C, D, E Clients: 1, 2, 3, 4
[ Fig. 1. Sample small IRC network ]
The IRC protocol provides no mean for two clients to directly
communicate. All communication between clients is relayed by the
server(s).
4. IRC Protocol Services
This section describes the services offered by the IRC protocol. The
combination of these services allow real-time conferencing.
4.1 Client Locator
To be able to exchange messages, two clients must be able to locate
each other.
Upon connecting to a server, a client registers using a label which
is then used by other servers and clients to know where the client is
located. Servers are responsible for keeping track of all the labels
being used.
4.2 Message Relaying
The IRC protocol provides no mean for two clients to directly
communicate. All communication between clients is relayed by the
server(s).
4.3 Channel Hosting And Management
A channel is a named group of one or more users which will all
receive messages addressed to that channel. A channel is
characterized by its name and current members, it also has a set of
properties which can be manipulated by (some of) its members.
Channels provide a mean for a message to be sent to several clients.
Servers host channels, providing the necessary message multiplexing.
Servers are also responsible for managing channels by keeping track
of the channel members. The exact role of servers is defined in
"Internet Relay Chat: Channel Management" [IRC-CHAN].
5. IRC Concepts
This section is devoted to describing the actual concepts behind the
organization of the IRC protocol and how different classes of
messages are delivered.
5.1 One-To-One Communication
Communication on a one-to-one basis is usually performed by clients,
since most server-server traffic is not a result of servers talking
only to each other. To provide a means for clients to talk to each
other, it is REQUIRED that all servers be able to send a message in
exactly one direction along the spanning tree in order to reach any
client. Thus the path of a message being delivered is the shortest
path between any two points on the spanning tree.
The following examples all refer to Figure 1 above.
Example 1: A message between clients 1 and 2 is only seen by server
A, which sends it straight to client 2.
Example 2: A message between clients 1 and 3 is seen by servers A &
B, and client 3. No other clients or servers are allowed see the
message.
Example 3: A message between clients 2 and 4 is seen by servers A, B,
C & D and client 4 only.
5.2 One-To-Many
The main goal of IRC is to provide a forum which allows easy and
efficient conferencing (one to many conversations). IRC offers
several means to achieve this, each serving its own purpose.
5.2.1 To A Channel
In IRC the channel has a role equivalent to that of the multicast
group; their existence is dynamic and the actual conversation carried
out on a channel MUST only be sent to servers which are supporting
users on a given channel. Moreover, the message SHALL only be sent
once to every local link as each server is responsible to fan the
original message to ensure that it will reach all the recipients.
The following examples all refer to Figure 2.
Example 4: Any channel with 1 client in it. Messages to the channel
go to the server and then nowhere else.
Example 5: 2 clients in a channel. All messages traverse a path as if
they were private messages between the two clients outside a
channel.
Example 6: Clients 1, 2 and 3 in a channel. All messages to the
channel are sent to all clients and only those servers which must
be traversed by the message if it were a private message to a
single client. If client 1 sends a message, it goes back to
client 2 and then via server B to client 3.
5.2.2 To A Host/Server Mask
To provide with some mechanism to send messages to a large body of
related users, host and server mask messages are available. These
messages are sent to users whose host or server information match
that of the mask. The messages are only sent to locations where
users are, in a fashion similar to that of channels.
5.2.3 To A List
The least efficient style of one-to-many conversation is through
clients talking to a 'list' of targets (client, channel, mask). How
this is done is almost self explanatory: the client gives a list of
destinations to which the message is to be delivered and the server
breaks it up and dispatches a separate copy of the message to each
given destination.
This is not as efficient as using a channel since the destination
list MAY be broken up and the dispatch sent without checking to make
sure duplicates aren't sent down each path.
5.3 One-To-All
The one-to-all type of message is better described as a broadcast
message, sent to all clients or servers or both. On a large network
of users and servers, a single message can result in a lot of traffic
being sent over the network in an effort to reach all of the desired
destinations.
For some class of messages, there is no option but to broadcast it to
all servers so that the state information held by each server is
consistent between servers.
5.3.1 Client-to-Client
There is no class of message which, from a single message, results in
a message being sent to every other client.
5.3.2 Client-to-Server
Most of the commands which result in a change of state information
(such as channel membership, channel mode, user status, etc.) MUST be
sent to all servers by default, and this distribution SHALL NOT be
changed by the client.
5.3.3 Server-to-Server
While most messages between servers are distributed to all 'other'
servers, this is only required for any message that affects a user,
channel or server. Since these are the basic items found in IRC,
nearly all messages originating from a server are broadcast to all
other connected servers.
6. Current Problems
There are a number of recognized problems with this protocol, this
section only addresses the problems related to the architecture of
the protocol.
6.1 Scalability
It is widely recognized that this protocol does not scale
sufficiently well when used in a large arena. The main problem comes
from the requirement that all servers know about all other servers,
clients and channels and that information regarding them be updated
as soon as it changes.
6.2 Reliability
As the only network configuration allowed for IRC servers is that of
a spanning tree, each link between two servers is an obvious and
quite serious point of failure. This particular issue is addressed
more in detail in "Internet Relay Chat: Server Protocol" [IRC-
SERVER].
6.3 Network Congestion
Another problem related to the scalability and reliability issues, as
well as the spanning tree architecture, is that the protocol and
architecture for IRC are extremely vulnerable to network congestions.
This problem is endemic, and should be solved for the next
generation: if congestion and high traffic volume cause a link
between two servers to fail, not only this failure generates more
network traffic, but the reconnection (eventually elsewhere) of two
servers also generates more traffic.
In an attempt to minimize the impact of these problems, it is
strongly RECOMMENDED that servers do not automatically try to
reconnect too fast, in order to avoid aggravating the situation.
6.4 Privacy
Besides not scaling well, the fact that servers need to know all
information about other entities, the issue of privacy is also a
concern. This is in particular true for channels, as the related
information is quite a lot more revealing than whether a user is
online or not.
7. Security Considerations
Asides from the privacy concerns mentioned in section 6.4 (Privacy),
security is believed to be irrelevant to this document.
8. Current Support And Availability
Mailing lists for IRC related discussion:
General discussion: ircd-users@irc.org
Protocol development: ircd-dev@irc.org
Software implementations:
ftp://ftp.irc.org/irc/server
ftp://ftp.funet.fi/pub/unix/irc
ftp://coombs.anu.edu.au/pub/irc
Newsgroup: alt.irc
9. Acknowledgements
Parts of this document were copied from the RFC 1459 [IRC] which
first formally documented the IRC Protocol. It has also benefited
from many rounds of review and comments. In particular, the
following people have made significant contributions to this
document:
Matthew Green, Michael Neumayer, Volker Paulsen, Kurt Roeckx, Vesa
Ruokonen, Magnus Tjernstrom, Stefan Zehl.
10. References
[KEYWORDS] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[IRC] Oikarinen, J. and D. Reed, "Internet Relay Chat
Protocol", RFC 1459, May 1993.
[IRC-CLIENT] Kalt, C., "Internet Relay Chat: Client Protocol", RFC
2812, April 2000.
[IRC-SERVER] Kalt, C., "Internet Relay Chat: Server Protocol", RFC
2813, April 2000.
[IRC-CHAN] Kalt, C., "Internet Relay Chat: Channel Management", RFC
2811, April 2000.
11. Author's Address
Christophe Kalt
99 Teaneck Rd, Apt #117
Ridgefield Park, NJ 07660
USA
EMail: kalt@stealth.net
12. Full Copyright Statement
Copyright (C) The Internet Society (2000). All Rights Reserved.
This document and translations of it may be copied and furnished to
others, and derivative works that comment on or otherwise explain it
or assist in its implementation may be prepared, copied, published
and distributed, in whole or in part, without restriction of any
kind, provided that the above copyright notice and this paragraph are
included on all such copies and derivative works. However, this
document itself may not be modified in any way, such as by removing
the copyright notice or references to the Internet Society or other
Internet organizations, except as needed for the purpose of
developing Internet standards in which case the procedures for
copyrights defined in the Internet Standards process must be
followed, or as required to translate it into languages other than
English.
The limited permissions granted above are perpetual and will not be
revoked by the Internet Society or its successors or assigns.
This document and the information contained herein is provided on an
"AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING
TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING
BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION
HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF
MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
Acknowledgement
Funding for the RFC Editor function is currently provided by the
Internet Society.
Comments about this RFC:
* RFC 2810: Hi, Here goes the text in section 5.2.1 : "The following
examples all... by AkA (6/2/2007)
Previous: RFC 2809 - Implementation of Next: RFC 2811 - Internet Relay Chat:
L2TP Compulsory Tunneling via RADIUS Channel Management
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RFC 2811 - Internet Relay Chat: Channel Management
----------------------------------------------------------------------
Network Working Group C. Kalt
Request for Comments: 2811 April 2000
Updates: 1459
Category: Informational
Internet Relay Chat: Channel Management
Status of this Memo
This memo provides information for the Internet community. It does
not specify an Internet standard of any kind. Distribution of this
memo is unlimited.
Copyright Notice
Copyright (C) The Internet Society (2000). All Rights Reserved.
Abstract
One of the most notable characteristics of the IRC (Internet Relay
Chat) protocol is to allow for users to be grouped in forums, called
channels, providing a mean for multiple users to communicate
together.
There was originally a unique type of channels, but with the years,
new types appeared either as a response to a need, or for
experimental purposes.
This document specifies how channels, their characteristics and
properties are managed by IRC servers.
Table of Contents
1. Introduction ............................................... 2
2. Channel Characteristics .................................... 3
2.1 Namespace .............................................. 3
2.2 Channel Scope .......................................... 3
2.3 Channel Properties ..................................... 4
2.4 Privileged Channel Members ............................. 4
2.4.1 Channel Operators ................................. 5
2.4.2 Channel Creator ................................... 5
3. Channel lifetime ........................................... 5
3.1 Standard channels ...................................... 5
3.2 Safe Channels .......................................... 6
4. Channel Modes .............................................. 7
4.1 Member Status .......................................... 7
4.1.1 "Channel Creator" Status .......................... 7
4.1.2 Channel Operator Status ........................... 8
4.1.3 Voice Privilege ................................... 8
4.2 Channel Flags .......................................... 8
4.2.1 Anonymous Flag .................................... 8
4.2.2 Invite Only Flag .................................. 8
4.2.3 Moderated Channel Flag ............................ 9
4.2.4 No Messages To Channel From Clients On The Outside 9
4.2.5 Quiet Channel ..................................... 9
4.2.6 Private and Secret Channels ....................... 9
4.2.7 Server Reop Flag .................................. 10
4.2.8 Topic ............................................. 10
4.2.9 User Limit ........................................ 10
4.2.10 Channel Key ...................................... 10
4.3 Channel Access Control ................................. 10
4.3.1 Channel Ban and Exception ......................... 11
4.3.2 Channel Invitation ................................ 11
5. Current Implementations .................................... 11
5.1 Tracking Recently Used Channels ........................ 11
5.2 Safe Channels .......................................... 12
5.2.1 Channel Identifier ................................ 12
5.2.2 Channel Delay ..................................... 12
5.2.3 Abuse Window ...................................... 13
5.2.4 Preserving Sanity In The Name Space ............... 13
5.2.5 Server Reop Mechanism ............................. 13
6. Current problems ........................................... 14
6.1 Labels ................................................. 14
6.1.1 Channel Delay ..................................... 14
6.1.2 Safe Channels ..................................... 15
6.2 Mode Propagation Delays ................................ 15
6.3 Collisions And Channel Modes ........................... 15
6.4 Resource Exhaustion .................................... 16
7. Security Considerations .................................... 16
7.1 Access Control ......................................... 16
7.2 Channel Privacy ........................................ 16
7.3 Anonymity ............................................... 17
8. Current support and availability ........................... 17
9. Acknowledgements ........................................... 17
10. References ................................................ 18
11. Author's Address .......................................... 18
12. Full Copyright Statement ................................... 19
1. Introduction
This document defines in detail on how channels are managed by the
IRC servers and will be mostly useful to people working on
implementing an IRC server.
While the concepts defined here are an important part of IRC, they
remain non essential for implementing clients. While the trend seems
to be towards more and more complex and "intelligent" clients which
are able to take advantage of knowing the internal workings of
channels to provide the users with a more friendly interface, simple
clients can be implemented without reading this document.
Many of the concepts defined here were designed with the IRC
architecture [IRC-ARCH] in mind and mostly make sense in this
context. However, many others could be applied to other
architectures in order to provide forums for a conferencing system.
Finally, it is to be noted that IRC users may find some of the
following sections of interest, in particular sections 2 (Channel
Characteristics) and 4 (Channel Modes).
2. Channel Characteristics
A channel is a named group of one or more users which will all
receive messages addressed to that channel. A channel is
characterized by its name, properties and current members.
2.1 Namespace
Channels names are strings (beginning with a '&', '#', '+' or '!'
character) of length up to fifty (50) characters. Channel names are
case insensitive.
Apart from the the requirement that the first character being either
'&', '#', '+' or '!' (hereafter called "channel prefix"). The only
restriction on a channel name is that it SHALL NOT contain any spaces
(' '), a control G (^G or ASCII 7), a comma (',' which is used as a
list item separator by the protocol). Also, a colon (':') is used as
a delimiter for the channel mask. The exact syntax of a channel name
is defined in "IRC Server Protocol" [IRC-SERVER].
The use of different prefixes effectively creates four (4) distinct
namespaces for channel names. This is important because of the
protocol limitations regarding namespaces (in general). See section
6.1 (Labels) for more details on these limitations.
2.2 Channel Scope
A channel entity is known by one or more servers on the IRC network.
A user can only become member of a channel known by the server to
which the user is directly connected. The list of servers which know
of the existence of a particular channel MUST be a contiguous part of
the IRC network, in order for the messages addressed to the channel
to be sent to all the channel members.
Channels with '&' as prefix are local to the server where they are
created.
Other channels are known to one (1) or more servers that are
connected to the network, depending on the channel mask:
If there is no channel mask, then the channel is known to all
the servers.
If there is a channel mask, then the channel MUST only be known
to servers which has a local user on the channel, and to its
neighbours if the mask matches both the local and neighbouring
server names. Since other servers have absolutely no knowledge of
the existence of such a channel, the area formed by the servers
having a name matching the mask has to be contiguous for the
channel to be known by all these servers. Channel masks are best
used in conjunction with server hostmasking [IRC-SERVER].
2.3 Channel Properties
Each channel has its own properties, which are defined by channel
modes. Channel modes can be manipulated by the channel members. The
modes affect the way servers manage the channels.
Channels with '+' as prefix do not support channel modes. This means
that all the modes are unset, with the exception of the 't' channel
flag which is set.
2.4 Privileged Channel Members
In order for the channel members to keep some control over a channel,
and some kind of sanity, some channel members are privileged. Only
these members are allowed to perform the following actions on the
channel:
INVITE - Invite a client to an invite-only channel (mode +i)
KICK - Eject a client from the channel
MODE - Change the channel's mode, as well as
members' privileges
PRIVMSG - Sending messages to the channel (mode +n, +m, +v)
TOPIC - Change the channel topic in a mode +t channel
2.4.1 Channel Operators
The channel operators (also referred to as a "chop" or "chanop") on a
given channel are considered to 'own' that channel. Ownership of a
channel is shared among channel operators.
Channel operators are identified by the '@' symbol next to their
nickname whenever it is associated with a channel (i.e., replies to
the NAMES, WHO and WHOIS commands).
Since channels starting with the character '+' as prefix do not
support channel modes, no member can therefore have the status of
channel operator.
2.4.2 Channel Creator
A user who creates a channel with the character '!' as prefix is
identified as the "channel creator". Upon creation of the channel,
this user is also given channel operator status.
In recognition of this status, the channel creators are endowed with
the ability to toggle certain modes of the channel which channel
operators may not manipulate.
A "channel creator" can be distinguished from a channel operator by
issuing the proper MODE command. See the "IRC Client Protocol"
[IRC-CLIENT] for more information on this topic.
3. Channel lifetime
In regard to the lifetime of a channel, there are typically two
groups of channels: standard channels which prefix is either '&', '#'
or '+', and "safe channels" which prefix is '!'.
3.1 Standard channels
These channels are created implicitly when the first user joins it,
and cease to exist when the last user leaves it. While the channel
exists, any client can reference the channel using the name of the
channel.
The user creating a channel automatically becomes channel operator
with the notable exception of channels which name is prefixed by the
character '+', see section 4 (Channel modes). See section 2.4.1
(Channel Operators) for more details on this title.
In order to avoid the creation of duplicate channels (typically when
the IRC network becomes disjoint because of a split between two
servers), channel names SHOULD NOT be allowed to be reused by a user
if a channel operator (See Section 2.4.1 (Channel Operators)) has
recently left the channel because of a network split. If this
happens, the channel name is temporarily unavailable. The duration
while a channel remains unavailable should be tuned on a per IRC
network basis. It is important to note that this prevents local
users from creating a channel using the same name, but does not
prevent the channel to be recreated by a remote user. The latter
typically happens when the IRC network rejoins. Obviously, this
mechanism only makes sense for channels which name begins with the
character '#', but MAY be used for channels which name begins with
the character '+'. This mechanism is commonly known as "Channel
Delay".
3.2 Safe Channels
Unlike other channels, "safe channels" are not implicitly created. A
user wishing to create such a channel MUST request the creation by
sending a special JOIN command to the server in which the channel
identifier (then unknown) is replaced by the character '!'. The
creation process for this type of channel is strictly controlled.
The user only chooses part of the channel name (known as the channel
"short name"), the server automatically prepends the user provided
name with a channel identifier consisting of five (5) characters.
The channel name resulting from the combination of these two elements
is unique, making the channel safe from abuses based on network
splits.
The user who creates such a channel automatically becomes "channel
creator". See section 2.4.2 (Channel Creator) for more details on
this title.
A server MUST NOT allow the creation of a new channel if another
channel with the same short name exists; or if another channel with
the same short name existed recently AND any of its member(s) left
because of a network split. Such channel ceases to exist after last
user leaves AND no other member recently left the channel because of
a network split.
Unlike the mechanism described in section 5.2.2 (Channel Delay), in
this case, channel names do not become unavailable: these channels
may continue to exist after the last user left. Only the user
creating the channel becomes "channel creator", users joining an
existing empty channel do not automatically become "channel creator"
nor "channel operator".
To ensure the uniqueness of the channel names, the channel identifier
created by the server MUST follow specific rules. For more details
on this, see section 5.2.1 (Channel Identifier).
4. Channel Modes
The various modes available for channels are as follows:
O - give "channel creator" status;
o - give/take channel operator privilege;
v - give/take the voice privilege;
a - toggle the anonymous channel flag;
i - toggle the invite-only channel flag;
m - toggle the moderated channel;
n - toggle the no messages to channel from clients on the
outside;
q - toggle the quiet channel flag;
p - toggle the private channel flag;
s - toggle the secret channel flag;
r - toggle the server reop channel flag;
t - toggle the topic settable by channel operator only flag;
k - set/remove the channel key (password);
l - set/remove the user limit to channel;
b - set/remove ban mask to keep users out;
e - set/remove an exception mask to override a ban mask;
I - set/remove an invitation mask to automatically override
the invite-only flag;
Unless mentioned otherwise below, all these modes can be manipulated
by "channel operators" by using the MODE command defined in "IRC
Client Protocol" [IRC-CLIENT].
4.1 Member Status
The modes in this category take a channel member nickname as argument
and affect the privileges given to this user.
4.1.1 "Channel Creator" Status
The mode 'O' is only used in conjunction with "safe channels" and
SHALL NOT be manipulated by users. Servers use it to give the user
creating the channel the status of "channel creator".
4.1.2 Channel Operator Status
The mode 'o' is used to toggle the operator status of a channel
member.
4.1.3 Voice Privilege
The mode 'v' is used to give and take voice privilege to/from a
channel member. Users with this privilege can talk on moderated
channels. (See section 4.2.3 (Moderated Channel Flag).
4.2 Channel Flags
The modes in this category are used to define properties which
affects how channels operate.
4.2.1 Anonymous Flag
The channel flag 'a' defines an anonymous channel. This means that
when a message sent to the channel is sent by the server to users,
and the origin is a user, then it MUST be masked. To mask the
message, the origin is changed to "anonymous!anonymous@anonymous."
(e.g., a user with the nickname "anonymous", the username "anonymous"
and from a host called "anonymous."). Because of this, servers MUST
forbid users from using the nickname "anonymous". Servers MUST also
NOT send QUIT messages for users leaving such channels to the other
channel members but generate a PART message instead.
On channels with the character '&' as prefix, this flag MAY be
toggled by channel operators, but on channels with the character '!'
as prefix, this flag can be set (but SHALL NOT be unset) by the
"channel creator" only. This flag MUST NOT be made available on
other types of channels.
Replies to the WHOIS, WHO and NAMES commands MUST NOT reveal the
presence of other users on channels for which the anonymous flag is
set.
4.2.2 Invite Only Flag
When the channel flag 'i' is set, new members are only accepted if
their mask matches Invite-list (See section 4.3.2) or they have been
invited by a channel operator. This flag also restricts the usage of
the INVITE command (See "IRC Client Protocol" [IRC-CLIENT]) to
channel operators.
4.2.3 Moderated Channel Flag
The channel flag 'm' is used to control who may speak on a channel.
When it is set, only channel operators, and members who have been
given the voice privilege may send messages to the channel.
This flag only affects users.
4.2.4 No Messages To Channel From Clients On The Outside
When the channel flag 'n' is set, only channel members MAY send
messages to the channel.
This flag only affects users.
4.2.5 Quiet Channel
The channel flag 'q' is for use by servers only. When set, it
restricts the type of data sent to users about the channel
operations: other user joins, parts and nick changes are not sent.
From a user's point of view, the channel contains only one user.
This is typically used to create special local channels on which the
server sends notices related to its operations. This was used as a
more efficient and flexible way to replace the user mode 's' defined
in RFC 1459 [IRC].
4.2.6 Private and Secret Channels
The channel flag 'p' is used to mark a channel "private" and the
channel flag 's' to mark a channel "secret". Both properties are
similar and conceal the existence of the channel from other users.
This means that there is no way of getting this channel's name from
the server without being a member. In other words, these channels
MUST be omitted from replies to queries like the WHOIS command.
When a channel is "secret", in addition to the restriction above, the
server will act as if the channel does not exist for queries like the
TOPIC, LIST, NAMES commands. Note that there is one exception to
this rule: servers will correctly reply to the MODE command.
Finally, secret channels are not accounted for in the reply to the
LUSERS command (See "Internet Relay Chat: Client Protocol" [IRC-
CLIENT]) when the <mask> parameter is specified.
The channel flags 'p' and 's' MUST NOT both be set at the same time.
If a MODE message originating from a server sets the flag 'p' and the
flag 's' is already set for the channel, the change is silently
ignored. This should only happen during a split healing phase
(mentioned in the "IRC Server Protocol" document [IRC-SERVER]).
4.2.7 Server Reop Flag
The channel flag 'r' is only available on channels which name begins
with the character '!' and MAY only be toggled by the "channel
creator".
This flag is used to prevent a channel from having no channel
operator for an extended period of time. When this flag is set, any
channel that has lost all its channel operators for longer than the
"reop delay" period triggers a mechanism in servers to reop some or
all of the channel inhabitants. This mechanism is described more in
detail in section 5.2.4 (Channel Reop Mechanism).
4.2.8 Topic
The channel flag 't' is used to restrict the usage of the TOPIC
command to channel operators.
4.2.9 User Limit
A user limit may be set on channels by using the channel flag 'l'.
When the limit is reached, servers MUST forbid their local users to
join the channel.
The value of the limit MUST only be made available to the channel
members in the reply sent by the server to a MODE query.
4.2.10 Channel Key
When a channel key is set (by using the mode 'k'), servers MUST
reject their local users request to join the channel unless this key
is given.
The channel key MUST only be made visible to the channel members in
the reply sent by the server to a MODE query.
4.3 Channel Access Control
The last category of modes is used to control access to the channel,
they take a mask as argument.
In order to reduce the size of the global database for control access
modes set for channels, servers MAY put a maximum limit on the number
of such modes set for a particular channel. If such restriction is
imposed, it MUST only affect user requests. The limit SHOULD be
homogeneous on a per IRC network basis.
4.3.1 Channel Ban and Exception
When a user requests to join a channel, his local server checks if
the user's address matches any of the ban masks set for the channel.
If a match is found, the user request is denied unless the address
also matches an exception mask set for the channel.
Servers MUST NOT allow a channel member who is banned from the
channel to speak on the channel, unless this member is a channel
operator or has voice privilege. (See Section 4.1.3 (Voice
Privilege)).
A user who is banned from a channel and who carries an invitation
sent by a channel operator is allowed to join the channel.
4.3.2 Channel Invitation
For channels which have the invite-only flag set (See Section 4.2.2
(Invite Only Flag)), users whose address matches an invitation mask
set for the channel are allowed to join the channel without any
invitation.
5. Current Implementations
The only current implementation of these rules as part of the IRC
protocol is the IRC server, version 2.10.
The rest of this section deals with issues that are mostly of
importance to those who wish to implement a server but some parts may
also be of interest for client writers.
5.1 Tracking Recently Used Channels
This mechanism is commonly known as "Channel Delay" and generally
only applies to channels which names is prefixed with the character
'#' (See Section 3.1 "Standard channels").
When a network split occurs, servers SHOULD keep track of which
channels lost a "channel operator" as the result of the break. These
channels are then in a special state which lasts for a certain period
of time. In this particular state, the channels cannot cease to
exist. If all the channel members leave the channel, the channel
becomes unavailable: the server local clients cannot join the channel
as long as it is empty.
Once a channel is unavailable, it will become available again either
because a remote user has joined the channel (most likely because the
network is healing), or because the delay period has expired (in
which case the channel ceases to exist and may be re-created).
The duration for which a channel death is delayed SHOULD be set
considering many factors among which are the size (user wise) of the
IRC network, and the usual duration of network splits. It SHOULD be
uniform on all servers for a given IRC network.
5.2 Safe Channels
This document introduces the notion of "safe channels". These
channels have a name prefixed with the character '!' and great effort
is made to avoid collisions in this name space. Collisions are not
impossible, however they are very unlikely.
5.2.1 Channel Identifier
The channel identifier is a function of the time. The current time
(as defined under UNIX by the number of seconds elapsed since
00:00:00 GMT, January 1, 1970) is converted in a string of five (5)
characters using the following base:
"ABCDEFGHIJKLMNOPQRSTUVWXYZ1234567890" (each character has a decimal
value starting from 0 for 'A' to 35 for '0').
The channel identifier therefore has a periodicity of 36^5 seconds
(about 700 days).
5.2.2 Channel Delay
These channels MUST be subject to the "channel delay" mechanism
described in section 5.1 (Channel Delay). However, the mechanism is
slightly adapted to fit better.
Servers MUST keep track of all such channels which lose members as
the result of a network split, no matter whether the user is a
"channel operator" or not.
However, these channels do NOT ever become unavailable, it is always
possible to join them even when they are empty.
5.2.3 Abuse Window
Because the periodicity is so long, attacks on a particular channel
(name) may only occur once in a very long while. However, with luck
and patience, it is still possible for a user to cause a channel
collision. In order to avoid this, servers MUST "look in the future"
and keep a list of channel names which identifier is about to be used
(in the coming few days for example). Such list should remain small,
not be a burden for servers to maintain and be used to avoid channel
collisions by preventing the re-creation of such channel for a longer
period of time than channel delay does.
Eventually a server MAY choose to extend this procedure to forbid
creation of channels with the same shortname only (then ignoring the
channel identifier).
5.2.4 Preserving Sanity In The Name Space
The combination of the mechanisms described in sections 5.2.2 and
5.2.3 makes it quite difficult for a user to create a channel
collision. However, another type of abuse consists of creating many
channels having the same shortname, but different identifiers. To
prevent this from happening, servers MUST forbid the creation of a
new channel which has the same shortname of a channel currently
existing.
5.2.5 Server Reop Mechanism
When a channel has been opless for longer than the "reop delay"
period and has the channel flag 'r' set (See Section 4.2.7 (Server
Reop Flag)), IRC servers are responsible for giving the channel
operator status randomly to some of the members.
The exact logic used for this mechanism by the current implementation
is described below. Servers MAY use a different logic, but that it
is strongly RECOMMENDED that all servers use the same logic on a
particular IRC network to maintain coherence as well as fairness.
For the same reason, the "reop delay" SHOULD be uniform on all
servers for a given IRC network. As for the "channel delay", the
value of the "reop delay" SHOULD be set considering many factors
among which are the size (user wise) of the IRC network, and the
usual duration of network splits.
a) the reop mechanism is triggered after a random time following the
expiration of the "reop delay". This should limit the eventuality
of the mechanism being triggered at the same time (for the same
channel) on two separate servers.
b) If the channel is small (five (5) users or less), and the "channel
delay" for this channel has expired,
Then reop all channel members if at least one member is local to
the server.
c) If the channel is small (five (5) users or less), and the "channel
delay" for this channel has expired, and the "reop delay" has
expired for longer than its value,
Then reop all channel members.
d) For other cases, reop at most one member on the channel, based on
some method build into the server. If you don't reop a member, the
method should be such that another server will probably op
someone. The method SHOULD be the same over the whole network. A
good heuristic could be just random reop.
(The current implementation actually tries to choose a member
local to the server who has not been idle for too long, eventually
postponing action, therefore letting other servers have a chance
to find a "not too idle" member. This is over complicated due to
the fact that servers only know the "idle" time of their local
users)
6. Current problems
There are a number of recognized problems with the way IRC channels
are managed. Some of these can be directly attributed to the rules
defined in this document, while others are the result of the
underlying "IRC Server Protocol" [IRC-SERVER]. Although derived from
RFC 1459 [IRC], this document introduces several novelties in an
attempt to solve some of the known problems.
6.1 Labels
This document defines one of the many labels used by the IRC
protocol. Although there are several distinct namespaces (based on
the channel name prefix), duplicates inside each of these are not
allowed. Currently, it is possible for users on different servers to
pick the label which may result in collisions (with the exception of
channels known to only one server where they can be averted).
6.1.1 Channel Delay
The channel delay mechanism described in section 5.1 (Tracking
Recently Used Channels) and used for channels prefixed with the
character '#' is a simple attempt at preventing collisions from
happening. Experience has shown that, under normal circumstances, it
is very efficient; however, it obviously has severe limitations
keeping it from being an adequate solution to the problem discussed
here.
6.1.2 Safe Channels
"Safe channels" described in section 3.2 (Safe Channels) are a better
way to prevent collisions from happening as it prevents users from
having total control over the label they choose. The obvious
drawback for such labels is that they are not user friendly.
However, it is fairly trivial for a client program to improve on
this.
6.2 Mode Propagation Delays
Because of network delays induced by the network, and because each
server on the path is REQUIRED to check the validity of mode changes
(e.g., user exists and has the right privileges), it is not unusual
for a MODE message to only affect part of the network, often creating
a discrepancy between servers on the current state of a channel.
While this may seem easy to fix (by having only the original server
check the validity of mode changes), it was decided not to do so for
various reasons. One concern is that servers cannot trust each
other, and that a misbehaving servers can easily be detected. This
way of doing so also stops wave effects on channels which are out of
synch when mode changes are issued from different directions.
6.3 Collisions And Channel Modes
The "Internet Relay Chat: Server Protocol" document [IRC-SERVER]
describes how channel data is exchanged when two servers connect to
each other. Channel collisions (either legitimate or not) are
treated as inclusive events, meaning that the resulting channel has
for members all the users who are members of the channel on either
server prior to the connection.
Similarly, each server sends the channel modes to the other one.
Therefore, each server also receives these channel modes. There are
three types of modes for a given channel: flags, masks, and data.
The first two types are easy to deal with as they are either set or
unset. If such a mode is set on one server, it MUST be set on the
other server as a result of the connection.
As topics are not sent as part of this exchange, they are not a
problem. However, channel modes 'l' and 'k' are exchanged, and if
they are set on both servers prior to the connection, there is no
mechanism to decide which of the two values takes precedence. It is
left up to the users to fix the resulting discrepancy.
6.4 Resource Exhaustion
The mode based on masks defined in section 4.3 make the IRC servers
(and network) vulnerable to a simple abuse of the system: a single
channel operator can set as many different masks as possible on a
particular channel. This can easily cause the server to waste
memory, as well as network bandwidth (since the info is propagated to
other servers). For this reason it is RECOMMENDED that a limit be
put on the number of such masks per channels as mentioned in section
4.3.
Moreover, more complex mechanisms MAY be used to avoid having
redundant masks set for the same channel.
7. Security Considerations
7.1 Access Control
One of the main ways to control access to a channel is to use masks
which are based on the username and hostname of the user connections.
This mechanism can only be efficient and safe if the IRC servers have
an accurate way of authenticating user connections, and if users
cannot easily get around it. While it is in theory possible to
implement such a strict authentication mechanism, most IRC networks
(especially public networks) do not have anything like this in place
and provide little guaranty about the accuracy of the username and
hostname for a particular client connection.
Another way to control access is to use a channel key, but since this
key is sent in plaintext, it is vulnerable to traditional man in the
middle attacks.
7.2 Channel Privacy
Because channel collisions are treated as inclusive events (See
Section 6.3), it is possible for users to join a channel overriding
its access control settings. This method has long been used by
individuals to "take over" channels by "illegitimately" gaining
channel operator status on the channel. The same method can be used
to find out the exact list of members of a channel, as well as to
eventually receive some of the messages sent to the channel.
7.3 Anonymity
The anonymous channel flag (See Section 4.2.1) can be used to render
all users on such channel "anonymous" by presenting all messages to
the channel as originating from a pseudo user which nickname is
"anonymous". This is done at the client-server level, and no
anonymity is provided at the server-server level.
It should be obvious to readers, that the level of anonymity offered
is quite poor and insecure, and that clients SHOULD display strong
warnings for users joining such channels.
8. Current support and availability
Mailing lists for IRC related discussion:
General discussion: ircd-users@irc.org
Protocol development: ircd-dev@irc.org
Software implementations:
ftp://ftp.irc.org/irc/server
ftp://ftp.funet.fi/pub/unix/irc
ftp://coombs.anu.edu.au/pub/irc
Newsgroup: alt.irc
9. Acknowledgements
Parts of this document were copied from the RFC 1459 [IRC] which
first formally documented the IRC Protocol. It has also benefited
from many rounds of review and comments. In particular, the
following people have made significant contributions to this
document:
Matthew Green, Michael Neumayer, Volker Paulsen, Kurt Roeckx, Vesa
Ruokonen, Magnus Tjernstrom, Stefan Zehl.
10. References
[KEYWORDS] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[IRC] Oikarinen, J. and D. Reed, "Internet Relay Chat
Protocol", RFC 1459, May 1993.
[IRC-ARCH] Kalt, C., "Internet Relay Chat: Architecture", RFC 2810,
April 2000.
[IRC-CLIENT] Kalt, C., "Internet Relay Chat: Client Protocol", RFC
2812, April 2000.
[IRC-SERVER] Kalt, C., "Internet Relay Chat: Server Protocol", RFC
2813, April 2000.
11. Author's Address
Christophe Kalt
99 Teaneck Rd, Apt #117
Ridgefield Park, NJ 07660
USA
EMail: kalt@stealth.net
12. Full Copyright Statement
Copyright (C) The Internet Society (2000). All Rights Reserved.
This document and translations of it may be copied and furnished to
others, and derivative works that comment on or otherwise explain it
or assist in its implementation may be prepared, copied, published
and distributed, in whole or in part, without restriction of any
kind, provided that the above copyright notice and this paragraph are
included on all such copies and derivative works. However, this
document itself may not be modified in any way, such as by removing
the copyright notice or references to the Internet Society or other
Internet organizations, except as needed for the purpose of
developing Internet standards in which case the procedures for
copyrights defined in the Internet Standards process must be
followed, or as required to translate it into languages other than
English.
The limited permissions granted above are perpetual and will not be
revoked by the Internet Society or its successors or assigns.
This document and the information contained herein is provided on an
"AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING
TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING
BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION
HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF
MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
Acknowledgement
Funding for the RFC Editor function is currently provided by the
Internet Society.
Previous: RFC 2810 - Internet Relay Next: RFC 2812 - Internet Relay Chat:
Chat: Architecture Client Protocol
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