| \documentstyle[12pt,twoside]{article} |
| \def\TITLE{IP Command Reference} |
| \input preamble |
| \begin{center} |
| \Large\bf IP Command Reference. |
| \end{center} |
| |
| |
| \begin{center} |
| { \large Alexey~N.~Kuznetsov } \\ |
| \em Institute for Nuclear Research, Moscow \\ |
| \verb|kuznet@ms2.inr.ac.ru| \\ |
| \rm April 14, 1999 |
| \end{center} |
| |
| \vspace{5mm} |
| |
| \tableofcontents |
| |
| \newpage |
| |
| \section{About this document} |
| |
| This document presents a comprehensive description of the \verb|ip| utility |
| from the \verb|iproute2| package. It is not a tutorial or user's guide. |
| It is a {\em dictionary\/}, not explaining terms, |
| but translating them into other terms, which may also be unknown to the reader. |
| However, the document is self-contained and the reader, provided they have a |
| basic networking background, will find enough information |
| and examples to understand and configure Linux-2.2 IP and IPv6 |
| networking. |
| |
| This document is split into sections explaining \verb|ip| commands |
| and options, decrypting \verb|ip| output and containing a few examples. |
| More voluminous examples and some topics, which require more elaborate |
| discussion, are in the appendix. |
| |
| The paragraphs beginning with NB contain side notes, warnings about |
| bugs and design drawbacks. They may be skipped at the first reading. |
| |
| \section{{\tt ip} --- command syntax} |
| |
| The generic form of an \verb|ip| command is: |
| \begin{verbatim} |
| ip [ OPTIONS ] OBJECT [ COMMAND [ ARGUMENTS ]] |
| \end{verbatim} |
| where \verb|OPTIONS| is a set of optional modifiers affecting the |
| general behaviour of the \verb|ip| utility or changing its output. All options |
| begin with the character \verb|'-'| and may be used in either long or abbreviated |
| forms. Currently, the following options are available: |
| |
| \begin{itemize} |
| \item \verb|-V|, \verb|-Version| |
| |
| --- print the version of the \verb|ip| utility and exit. |
| |
| |
| \item \verb|-s|, \verb|-stats|, \verb|-statistics| |
| |
| --- output more information. If the option |
| appears twice or more, the amount of information increases. |
| As a rule, the information is statistics or some time values. |
| |
| |
| \item \verb|-f|, \verb|-family| followed by a protocol family |
| identifier: \verb|inet|, \verb|inet6| or \verb|link|. |
| |
| --- enforce the protocol family to use. If the option is not present, |
| the protocol family is guessed from other arguments. If the rest of the command |
| line does not give enough information to guess the family, \verb|ip| falls back to the default |
| one, usually \verb|inet| or \verb|any|. \verb|link| is a special family |
| identifier meaning that no networking protocol is involved. |
| |
| \item \verb|-4| |
| |
| --- shortcut for \verb|-family inet|. |
| |
| \item \verb|-6| |
| |
| --- shortcut for \verb|-family inet6|. |
| |
| \item \verb|-0| |
| |
| --- shortcut for \verb|-family link|. |
| |
| |
| \item \verb|-o|, \verb|-oneline| |
| |
| --- output each record on a single line, replacing line feeds |
| with the \verb|'\'| character. This is convenient when you want to |
| count records with \verb|wc| or to \verb|grep| the output. The trivial |
| script \verb|rtpr| converts the output back into readable form. |
| |
| \item \verb|-r|, \verb|-resolve| |
| |
| --- use the system's name resolver to print DNS names instead of |
| host addresses. |
| |
| \begin{NB} |
| Do not use this option when reporting bugs or asking for advice. |
| \end{NB} |
| \begin{NB} |
| \verb|ip| never uses DNS to resolve names to addresses. |
| \end{NB} |
| |
| \end{itemize} |
| |
| \verb|OBJECT| is the object to manage or to get information about. |
| The object types currently understood by \verb|ip| are: |
| |
| \begin{itemize} |
| \item \verb|link| --- network device |
| \item \verb|address| --- protocol (IP or IPv6) address on a device |
| \item \verb|neighbour| --- ARP or NDISC cache entry |
| \item \verb|route| --- routing table entry |
| \item \verb|rule| --- rule in routing policy database |
| \item \verb|maddress| --- multicast address |
| \item \verb|mroute| --- multicast routing cache entry |
| \item \verb|tunnel| --- tunnel over IP |
| \end{itemize} |
| |
| Again, the names of all objects may be written in full or |
| abbreviated form, f.e.\ \verb|address| is abbreviated as \verb|addr| |
| or just \verb|a|. |
| |
| \verb|COMMAND| specifies the action to perform on the object. |
| The set of possible actions depends on the object type. |
| As a rule, it is possible to \verb|add|, \verb|delete| and |
| \verb|show| (or \verb|list|) objects, but some objects |
| do not allow all of these operations or have some additional commands. |
| The \verb|help| command is available for all objects. It prints |
| out a list of available commands and argument syntax conventions. |
| |
| If no command is given, some default command is assumed. |
| Usually it is \verb|list| or, if the objects of this class |
| cannot be listed, \verb|help|. |
| |
| \verb|ARGUMENTS| is a list of arguments to the command. |
| The arguments depend on the command and object. There are two types of arguments: |
| {\em flags\/}, consisting of a single keyword, and {\em parameters\/}, |
| consisting of a keyword followed by a value. For convenience, |
| each command has some {\em default parameter\/} |
| which may be omitted. F.e.\ parameter \verb|dev| is the default |
| for the {\tt ip link} command, so {\tt ip link ls eth0} is equivalent |
| to {\tt ip link ls dev eth0}. |
| In the command descriptions below such parameters |
| are distinguished with the marker: ``(default)''. |
| |
| Almost all keywords may be abbreviated with several first (or even single) |
| letters. The shortcuts are convenient when \verb|ip| is used interactively, |
| but they are not recommended in scripts or when reporting bugs |
| or asking for advice. ``Officially'' allowed abbreviations are listed |
| in the document body. |
| |
| |
| |
| \section{{\tt ip} --- error messages} |
| |
| \verb|ip| may fail for one of the following reasons: |
| |
| \begin{itemize} |
| \item |
| A syntax error on the command line: an unknown keyword, incorrectly formatted |
| IP address {\em et al\/}. In this case \verb|ip| prints an error message |
| and exits. As a rule, the error message will contain information |
| about the reason for the failure. Sometimes it also prints a help page. |
| |
| \item |
| The arguments did not pass verification for self-consistency. |
| |
| \item |
| \verb|ip| failed to compile a kernel request from the arguments |
| because the user didn't give enough information. |
| |
| \item |
| The kernel returned an error to some syscall. In this case \verb|ip| |
| prints the error message, as it is output with \verb|perror(3)|, |
| prefixed with a comment and a syscall identifier. |
| |
| \item |
| The kernel returned an error to some RTNETLINK request. |
| In this case \verb|ip| prints the error message, as it is output |
| with \verb|perror(3)| prefixed with ``RTNETLINK answers:''. |
| |
| \end{itemize} |
| |
| All the operations are atomic, i.e.\ |
| if the \verb|ip| utility fails, it does not change anything |
| in the system. One harmful exception is \verb|ip link| command |
| (Sec.\ref{IP-LINK}, p.\pageref{IP-LINK}), |
| which may change only some of the device parameters given |
| on command line. |
| |
| It is difficult to list all the error messages (especially |
| syntax errors). However, as a rule, their meaning is clear |
| from the context of the command. |
| |
| The most common mistakes are: |
| |
| \begin{enumerate} |
| \item Netlink is not configured in the kernel. The message is: |
| \begin{verbatim} |
| Cannot open netlink socket: Invalid value |
| \end{verbatim} |
| |
| \item RTNETLINK is not configured in the kernel. In this case |
| one of the following messages may be printed, depending on the command: |
| \begin{verbatim} |
| Cannot talk to rtnetlink: Connection refused |
| Cannot send dump request: Connection refused |
| \end{verbatim} |
| |
| \item The \verb|CONFIG_IP_MULTIPLE_TABLES| option was not selected |
| when configuring the kernel. In this case any attempt to use the |
| \verb|ip| \verb|rule| command will fail, f.e. |
| \begin{verbatim} |
| kuznet@kaiser $ ip rule list |
| RTNETLINK error: Invalid argument |
| dump terminated |
| \end{verbatim} |
| |
| \end{enumerate} |
| |
| |
| \section{{\tt ip link} --- network device configuration} |
| \label{IP-LINK} |
| |
| \paragraph{Object:} A \verb|link| is a network device and the corresponding |
| commands display and change the state of devices. |
| |
| \paragraph{Commands:} \verb|set| and \verb|show| (or \verb|list|). |
| |
| \subsection{{\tt ip link set} --- change device attributes} |
| |
| \paragraph{Abbreviations:} \verb|set|, \verb|s|. |
| |
| \paragraph{Arguments:} |
| |
| \begin{itemize} |
| \item \verb|dev NAME| (default) |
| |
| --- \verb|NAME| specifies the network device on which to operate. |
| |
| \item \verb|up| and \verb|down| |
| |
| --- change the state of the device to \verb|UP| or \verb|DOWN|. |
| |
| \item \verb|arp on| or \verb|arp off| |
| |
| --- change the \verb|NOARP| flag on the device. |
| |
| \begin{NB} |
| This operation is {\em not allowed\/} if the device is in state \verb|UP|. |
| Though neither the \verb|ip| utility nor the kernel check for this condition. |
| You can get unpredictable results changing this flag while the |
| device is running. |
| \end{NB} |
| |
| \item \verb|multicast on| or \verb|multicast off| |
| |
| --- change the \verb|MULTICAST| flag on the device. |
| |
| \item \verb|dynamic on| or \verb|dynamic off| |
| |
| --- change the \verb|DYNAMIC| flag on the device. |
| |
| \item \verb|name NAME| |
| |
| --- change the name of the device. This operation is not |
| recommended if the device is running or has some addresses |
| already configured. |
| |
| \item \verb|txqueuelen NUMBER| or \verb|txqlen NUMBER| |
| |
| --- change the transmit queue length of the device. |
| |
| \item \verb|mtu NUMBER| |
| |
| --- change the MTU of the device. |
| |
| \item \verb|address LLADDRESS| |
| |
| --- change the station address of the interface. |
| |
| \item \verb|broadcast LLADDRESS|, \verb|brd LLADDRESS| or \verb|peer LLADDRESS| |
| |
| --- change the link layer broadcast address or the peer address when |
| the interface is \verb|POINTOPOINT|. |
| |
| \vskip 1mm |
| \begin{NB} |
| For most devices (f.e.\ for Ethernet) changing the link layer |
| broadcast address will break networking. |
| Do not use it, if you do not understand what this operation really does. |
| \end{NB} |
| |
| \item \verb|netns PID| |
| |
| --- move the device to the network namespace associated with the process PID. |
| |
| \end{itemize} |
| |
| \vskip 1mm |
| \begin{NB} |
| The \verb|PROMISC| and \verb|ALLMULTI| flags are considered |
| obsolete and should not be changed administratively, though |
| the {\tt ip} utility will allow that. |
| \end{NB} |
| |
| \paragraph{Warning:} If multiple parameter changes are requested, |
| \verb|ip| aborts immediately after any of the changes have failed. |
| This is the only case when \verb|ip| can move the system to |
| an unpredictable state. The solution is to avoid changing |
| several parameters with one {\tt ip link set} call. |
| |
| \paragraph{Examples:} |
| \begin{itemize} |
| \item \verb|ip link set dummy address 00:00:00:00:00:01| |
| |
| --- change the station address of the interface \verb|dummy|. |
| |
| \item \verb|ip link set dummy up| |
| |
| --- start the interface \verb|dummy|. |
| |
| \end{itemize} |
| |
| |
| \subsection{{\tt ip link show} --- display device attributes} |
| \label{IP-LINK-SHOW} |
| |
| \paragraph{Abbreviations:} \verb|show|, \verb|list|, \verb|lst|, \verb|sh|, \verb|ls|, |
| \verb|l|. |
| |
| \paragraph{Arguments:} |
| \begin{itemize} |
| \item \verb|dev NAME| (default) |
| |
| --- \verb|NAME| specifies the network device to show. |
| If this argument is omitted all devices are listed. |
| |
| \item \verb|up| |
| |
| --- only display running interfaces. |
| |
| \end{itemize} |
| |
| |
| \paragraph{Output format:} |
| |
| \begin{verbatim} |
| kuznet@alisa:~ $ ip link ls eth0 |
| 3: eth0: <BROADCAST,MULTICAST,UP> mtu 1500 qdisc cbq qlen 100 |
| link/ether 00:a0:cc:66:18:78 brd ff:ff:ff:ff:ff:ff |
| kuznet@alisa:~ $ ip link ls sit0 |
| 5: sit0@NONE: <NOARP,UP> mtu 1480 qdisc noqueue |
| link/sit 0.0.0.0 brd 0.0.0.0 |
| kuznet@alisa:~ $ ip link ls dummy |
| 2: dummy: <BROADCAST,NOARP> mtu 1500 qdisc noop |
| link/ether 00:00:00:00:00:00 brd ff:ff:ff:ff:ff:ff |
| kuznet@alisa:~ $ |
| \end{verbatim} |
| |
| |
| The number before each colon is an {\em interface index\/} or {\em ifindex\/}. |
| This number uniquely identifies the interface. This is followed by the {\em interface name\/} |
| (\verb|eth0|, \verb|sit0| etc.). The interface name is also |
| unique at every given moment. However, the interface may disappear from the |
| list (f.e.\ when the corresponding driver module is unloaded) and another |
| one with the same name may be created later. Besides that, |
| the administrator may change the name of any device with |
| \verb|ip| \verb|link| \verb|set| \verb|name| |
| to make it more intelligible. |
| |
| The interface name may have another name or \verb|NONE| appended |
| after the \verb|@| sign. This means that this device is bound to some other |
| device, |
| i.e.\ packets send through it are encapsulated and sent via the ``master'' |
| device. If the name is \verb|NONE|, the master is unknown. |
| |
| Then we see the interface {\em mtu\/} (``maximal transfer unit''). This determines |
| the maximal size of data which can be sent as a single packet over this interface. |
| |
| {\em qdisc\/} (``queuing discipline'') shows the queuing algorithm used |
| on the interface. Particularly, \verb|noqueue| means that this interface |
| does not queue anything and \verb|noop| means that the interface is in blackhole |
| mode i.e.\ all packets sent to it are immediately discarded. |
| {\em qlen\/} is the default transmit queue length of the device measured |
| in packets. |
| |
| The interface flags are summarized in the angle brackets. |
| |
| \begin{itemize} |
| \item \verb|UP| --- the device is turned on. It is ready to accept |
| packets for transmission and it may inject into the kernel packets received |
| from other nodes on the network. |
| |
| \item \verb|LOOPBACK| --- the interface does not communicate with other |
| hosts. All packets sent through it will be returned |
| and nothing but bounced packets can be received. |
| |
| \item \verb|BROADCAST| --- the device has the facility to send packets |
| to all hosts sharing the same link. A typical example is an Ethernet link. |
| |
| \item \verb|POINTOPOINT| --- the link has only two ends with one node |
| attached to each end. All packets sent to this link will reach the peer |
| and all packets received by us came from this single peer. |
| |
| If neither \verb|LOOPBACK| nor \verb|BROADCAST| nor \verb|POINTOPOINT| |
| are set, the interface is assumed to be NMBA (Non-Broadcast Multi-Access). |
| This is the most generic type of device and the most complicated one, because |
| the host attached to a NBMA link has no means to send to anyone |
| without additionally configured information. |
| |
| \item \verb|MULTICAST| --- is an advisory flag indicating that the interface |
| is aware of multicasting i.e.\ sending packets to some subset of neighbouring |
| nodes. Broadcasting is a particular case of multicasting, where the multicast |
| group consists of all nodes on the link. It is important to emphasize |
| that software {\em must not\/} interpret the absence of this flag as the inability |
| to use multicasting on this interface. Any \verb|POINTOPOINT| and |
| \verb|BROADCAST| link is multicasting by definition, because we have |
| direct access to all the neighbours and, hence, to any part of them. |
| Certainly, the use of high bandwidth multicast transfers is not recommended |
| on broadcast-only links because of high expense, but it is not strictly |
| prohibited. |
| |
| \item \verb|PROMISC| --- the device listens to and feeds to the kernel all |
| traffic on the link even if it is not destined for us, not broadcasted |
| and not destined for a multicast group of which we are member. Usually |
| this mode exists only on broadcast links and is used by bridges and for network |
| monitoring. |
| |
| \item \verb|ALLMULTI| --- the device receives all multicast packets |
| wandering on the link. This mode is used by multicast routers. |
| |
| \item \verb|NOARP| --- this flag is different from the other ones. It has |
| no invariant value and its interpretation depends on the network protocols |
| involved. As a rule, it indicates that the device needs no address |
| resolution and that the software or hardware knows how to deliver packets |
| without any help from the protocol stacks. |
| |
| \item \verb|DYNAMIC| --- is an advisory flag indicating that the interface is |
| dynamically created and destroyed. |
| |
| \item \verb|SLAVE| --- this interface is bonded to some other interfaces |
| to share link capacities. |
| |
| \end{itemize} |
| |
| \vskip 1mm |
| \begin{NB} |
| There are other flags but they are either obsolete (\verb|NOTRAILERS|) |
| or not implemented (\verb|DEBUG|) or specific to some devices |
| (\verb|MASTER|, \verb|AUTOMEDIA| and \verb|PORTSEL|). We do not discuss |
| them here. |
| \end{NB} |
| |
| |
| The second line contains information on the link layer addresses |
| associated with the device. The first word (\verb|ether|, \verb|sit|) |
| defines the interface hardware type. This type determines the format and semantics |
| of the addresses and is logically part of the address. |
| The default format of the station address and the broadcast address |
| (or the peer address for pointopoint links) is a |
| sequence of hexadecimal bytes separated by colons, but some link |
| types may have their natural address format, f.e.\ addresses |
| of tunnels over IP are printed as dotted-quad IP addresses. |
| |
| \vskip 1mm |
| \begin{NB} |
| NBMA links have no well-defined broadcast or peer address, |
| however this field may contain useful information, f.e.\ |
| about the address of broadcast relay or about the address of the ARP server. |
| \end{NB} |
| \begin{NB} |
| Multicast addresses are not shown by this command, see |
| \verb|ip maddr ls| in~Sec.\ref{IP-MADDR} (p.\pageref{IP-MADDR} of this |
| document). |
| \end{NB} |
| |
| |
| \paragraph{Statistics:} With the \verb|-statistics| option, \verb|ip| also |
| prints interface statistics: |
| |
| \begin{verbatim} |
| kuznet@alisa:~ $ ip -s link ls eth0 |
| 3: eth0: <BROADCAST,MULTICAST,UP> mtu 1500 qdisc cbq qlen 100 |
| link/ether 00:a0:cc:66:18:78 brd ff:ff:ff:ff:ff:ff |
| RX: bytes packets errors dropped overrun mcast |
| 2449949362 2786187 0 0 0 0 |
| TX: bytes packets errors dropped carrier collsns |
| 178558497 1783945 332 0 332 35172 |
| kuznet@alisa:~ $ |
| \end{verbatim} |
| \verb|RX:| and \verb|TX:| lines summarize receiver and transmitter |
| statistics. They contain: |
| \begin{itemize} |
| \item \verb|bytes| --- the total number of bytes received or transmitted |
| on the interface. This number wraps when the maximal length of the data type |
| natural for the architecture is exceeded, so continuous monitoring requires |
| a user level daemon snapping it periodically. |
| \item \verb|packets| --- the total number of packets received or transmitted |
| on the interface. |
| \item \verb|errors| --- the total number of receiver or transmitter errors. |
| \item \verb|dropped| --- the total number of packets dropped due to lack |
| of resources. |
| \item \verb|overrun| --- the total number of receiver overruns resulting |
| in dropped packets. As a rule, if the interface is overrun, it means |
| serious problems in the kernel or that your machine is too slow |
| for this interface. |
| \item \verb|mcast| --- the total number of received multicast packets. This option |
| is only supported by a few devices. |
| \item \verb|carrier| --- total number of link media failures f.e.\ because |
| of lost carrier. |
| \item \verb|collsns| --- the total number of collision events |
| on Ethernet-like media. This number may have a different sense on other |
| link types. |
| \item \verb|compressed| --- the total number of compressed packets. This is |
| available only for links using VJ header compression. |
| \end{itemize} |
| |
| |
| If the \verb|-s| option is entered twice or more, |
| \verb|ip| prints more detailed statistics on receiver |
| and transmitter errors. |
| |
| \begin{verbatim} |
| kuznet@alisa:~ $ ip -s -s link ls eth0 |
| 3: eth0: <BROADCAST,MULTICAST,UP> mtu 1500 qdisc cbq qlen 100 |
| link/ether 00:a0:cc:66:18:78 brd ff:ff:ff:ff:ff:ff |
| RX: bytes packets errors dropped overrun mcast |
| 2449949362 2786187 0 0 0 0 |
| RX errors: length crc frame fifo missed |
| 0 0 0 0 0 |
| TX: bytes packets errors dropped carrier collsns |
| 178558497 1783945 332 0 332 35172 |
| TX errors: aborted fifo window heartbeat |
| 0 0 0 332 |
| kuznet@alisa:~ $ |
| \end{verbatim} |
| These error names are pure Ethernetisms. Other devices |
| may have non zero values in these fields but they may be |
| interpreted differently. |
| |
| |
| \section{{\tt ip address} --- protocol address management} |
| |
| \paragraph{Abbreviations:} \verb|address|, \verb|addr|, \verb|a|. |
| |
| \paragraph{Object:} The \verb|address| is a protocol (IP or IPv6) address attached |
| to a network device. Each device must have at least one address |
| to use the corresponding protocol. It is possible to have several |
| different addresses attached to one device. These addresses are not |
| discriminated, so that the term {\em alias\/} is not quite appropriate |
| for them and we do not use it in this document. |
| |
| The \verb|ip addr| command displays addresses and their properties, |
| adds new addresses and deletes old ones. |
| |
| \paragraph{Commands:} \verb|add|, \verb|delete|, \verb|flush| and \verb|show| |
| (or \verb|list|). |
| |
| |
| \subsection{{\tt ip address add} --- add a new protocol address} |
| \label{IP-ADDR-ADD} |
| |
| \paragraph{Abbreviations:} \verb|add|, \verb|a|. |
| |
| \paragraph{Arguments:} |
| |
| \begin{itemize} |
| \item \verb|dev NAME| |
| |
| \noindent--- the name of the device to add the address to. |
| |
| \item \verb|local ADDRESS| (default) |
| |
| --- the address of the interface. The format of the address depends |
| on the protocol. It is a dotted quad for IP and a sequence of hexadecimal halfwords |
| separated by colons for IPv6. The \verb|ADDRESS| may be followed by |
| a slash and a decimal number which encodes the network prefix length. |
| |
| |
| \item \verb|peer ADDRESS| |
| |
| --- the address of the remote endpoint for pointopoint interfaces. |
| Again, the \verb|ADDRESS| may be followed by a slash and a decimal number, |
| encoding the network prefix length. If a peer address is specified, |
| the local address {\em cannot\/} have a prefix length. The network prefix is associated |
| with the peer rather than with the local address. |
| |
| |
| \item \verb|broadcast ADDRESS| |
| |
| --- the broadcast address on the interface. |
| |
| It is possible to use the special symbols \verb|'+'| and \verb|'-'| |
| instead of the broadcast address. In this case, the broadcast address |
| is derived by setting/resetting the host bits of the interface prefix. |
| |
| \vskip 1mm |
| \begin{NB} |
| Unlike \verb|ifconfig|, the \verb|ip| utility {\em does not\/} set any broadcast |
| address unless explicitly requested. |
| \end{NB} |
| |
| |
| \item \verb|label NAME| |
| |
| --- Each address may be tagged with a label string. |
| In order to preserve compatibility with Linux-2.0 net aliases, |
| this string must coincide with the name of the device or must be prefixed |
| with the device name followed by colon. |
| |
| |
| \item \verb|scope SCOPE_VALUE| |
| |
| --- the scope of the area where this address is valid. |
| The available scopes are listed in file \verb|/etc/iproute2/rt_scopes|. |
| Predefined scope values are: |
| |
| \begin{itemize} |
| \item \verb|global| --- the address is globally valid. |
| \item \verb|site| --- (IPv6 only) the address is site local, |
| i.e.\ it is valid inside this site. |
| \item \verb|link| --- the address is link local, i.e.\ |
| it is valid only on this device. |
| \item \verb|host| --- the address is valid only inside this host. |
| \end{itemize} |
| |
| Appendix~\ref{ADDR-SEL} (p.\pageref{ADDR-SEL} of this document) |
| contains more details on address scopes. |
| |
| \end{itemize} |
| |
| \paragraph{Examples:} |
| \begin{itemize} |
| \item \verb|ip addr add 127.0.0.1/8 dev lo brd + scope host| |
| |
| --- add the usual loopback address to the loopback device. |
| |
| \item \verb|ip addr add 10.0.0.1/24 brd + dev eth0 label eth0:Alias| |
| |
| --- add the address 10.0.0.1 with prefix length 24 (i.e.\ netmask |
| \verb|255.255.255.0|), standard broadcast and label \verb|eth0:Alias| |
| to the interface \verb|eth0|. |
| \end{itemize} |
| |
| |
| \subsection{{\tt ip address delete} --- delete a protocol address} |
| |
| \paragraph{Abbreviations:} \verb|delete|, \verb|del|, \verb|d|. |
| |
| \paragraph{Arguments:} coincide with the arguments of \verb|ip addr add|. |
| The device name is a required argument. The rest are optional. |
| If no arguments are given, the first address is deleted. |
| |
| \paragraph{Examples:} |
| \begin{itemize} |
| \item \verb|ip addr del 127.0.0.1/8 dev lo| |
| |
| --- deletes the loopback address from the loopback device. |
| It would be best not to repeat this experiment. |
| |
| \item Disable IP on the interface \verb|eth0|: |
| \begin{verbatim} |
| while ip -f inet addr del dev eth0; do |
| : nothing |
| done |
| \end{verbatim} |
| Another method to disable IP on an interface using {\tt ip addr flush} |
| may be found in sec.\ref{IP-ADDR-FLUSH}, p.\pageref{IP-ADDR-FLUSH}. |
| |
| \end{itemize} |
| |
| |
| \subsection{{\tt ip address show} --- display protocol addresses} |
| |
| \paragraph{Abbreviations:} \verb|show|, \verb|list|, \verb|lst|, \verb|sh|, \verb|ls|, |
| \verb|l|. |
| |
| \paragraph{Arguments:} |
| |
| \begin{itemize} |
| \item \verb|dev NAME| (default) |
| |
| --- the name of the device. |
| |
| \item \verb|scope SCOPE_VAL| |
| |
| --- only list addresses with this scope. |
| |
| \item \verb|to PREFIX| |
| |
| --- only list addresses matching this prefix. |
| |
| \item \verb|label PATTERN| |
| |
| --- only list addresses with labels matching the \verb|PATTERN|. |
| \verb|PATTERN| is a usual shell style pattern. |
| |
| |
| \item \verb|dynamic| and \verb|permanent| |
| |
| --- (IPv6 only) only list addresses installed due to stateless |
| address configuration or only list permanent (not dynamic) addresses. |
| |
| \item \verb|tentative| |
| |
| --- (IPv6 only) only list addresses which did not pass duplicate |
| address detection. |
| |
| \item \verb|deprecated| |
| |
| --- (IPv6 only) only list deprecated addresses. |
| |
| |
| \item \verb|primary| and \verb|secondary| |
| |
| --- only list primary (or secondary) addresses. |
| |
| \end{itemize} |
| |
| |
| \paragraph{Output format:} |
| |
| \begin{verbatim} |
| kuznet@alisa:~ $ ip addr ls eth0 |
| 3: eth0: <BROADCAST,MULTICAST,UP> mtu 1500 qdisc cbq qlen 100 |
| link/ether 00:a0:cc:66:18:78 brd ff:ff:ff:ff:ff:ff |
| inet 193.233.7.90/24 brd 193.233.7.255 scope global eth0 |
| inet6 3ffe:2400:0:1:2a0:ccff:fe66:1878/64 scope global dynamic |
| valid_lft forever preferred_lft 604746sec |
| inet6 fe80::2a0:ccff:fe66:1878/10 scope link |
| kuznet@alisa:~ $ |
| \end{verbatim} |
| |
| The first two lines coincide with the output of \verb|ip link ls|. |
| It is natural to interpret link layer addresses |
| as addresses of the protocol family \verb|AF_PACKET|. |
| |
| Then the list of IP and IPv6 addresses follows, accompanied by |
| additional address attributes: scope value (see Sec.\ref{IP-ADDR-ADD}, |
| p.\pageref{IP-ADDR-ADD} above), flags and the address label. |
| |
| Address flags are set by the kernel and cannot be changed |
| administratively. Currently, the following flags are defined: |
| |
| \begin{enumerate} |
| \item \verb|secondary| |
| |
| --- the address is not used when selecting the default source address |
| of outgoing packets (Cf.\ Appendix~\ref{ADDR-SEL}, p.\pageref{ADDR-SEL}.). |
| An IP address becomes secondary if another address with the same |
| prefix bits already exists. The first address is primary. |
| It is the leader of the group of all secondary addresses. When the leader |
| is deleted, all secondaries are purged too. |
| There is a tweak in \verb|/proc/sys/net/ipv4/conf/<dev>/promote_secondaries| |
| which activate secondaries promotion when a primary is deleted. |
| To permanently enable this feature on all devices add |
| \verb|net.ipv4.conf.all.promote_secondaries=1| to \verb|/etc/sysctl.conf|. |
| This tweak is available in linux 2.6.15 and later. |
| |
| |
| \item \verb|dynamic| |
| |
| --- the address was created due to stateless autoconfiguration~\cite{RFC-ADDRCONF}. |
| In this case the output also contains information on times, when |
| the address is still valid. After \verb|preferred_lft| expires the address is |
| moved to the deprecated state. After \verb|valid_lft| expires the address |
| is finally invalidated. |
| |
| \item \verb|deprecated| |
| |
| --- the address is deprecated, i.e.\ it is still valid, but cannot |
| be used by newly created connections. |
| |
| \item \verb|tentative| |
| |
| --- the address is not used because duplicate address detection~\cite{RFC-ADDRCONF} |
| is still not complete or failed. |
| |
| \end{enumerate} |
| |
| |
| \subsection{{\tt ip address flush} --- flush protocol addresses} |
| \label{IP-ADDR-FLUSH} |
| |
| \paragraph{Abbreviations:} \verb|flush|, \verb|f|. |
| |
| \paragraph{Description:}This command flushes the protocol addresses |
| selected by some criteria. |
| |
| \paragraph{Arguments:} This command has the same arguments as \verb|show|. |
| The difference is that it does not run when no arguments are given. |
| |
| \paragraph{Warning:} This command (and other \verb|flush| commands |
| described below) is pretty dangerous. If you make a mistake, it will |
| not forgive it, but will cruelly purge all the addresses. |
| |
| \paragraph{Statistics:} With the \verb|-statistics| option, the command |
| becomes verbose. It prints out the number of deleted addresses and the number |
| of rounds made to flush the address list. If this option is given |
| twice, \verb|ip addr flush| also dumps all the deleted addresses |
| in the format described in the previous subsection. |
| |
| \paragraph{Example:} Delete all the addresses from the private network |
| 10.0.0.0/8: |
| \begin{verbatim} |
| netadm@amber:~ # ip -s -s a f to 10/8 |
| 2: dummy inet 10.7.7.7/16 brd 10.7.255.255 scope global dummy |
| 3: eth0 inet 10.10.7.7/16 brd 10.10.255.255 scope global eth0 |
| 4: eth1 inet 10.8.7.7/16 brd 10.8.255.255 scope global eth1 |
| |
| *** Round 1, deleting 3 addresses *** |
| *** Flush is complete after 1 round *** |
| netadm@amber:~ # |
| \end{verbatim} |
| Another instructive example is disabling IP on all the Ethernets: |
| \begin{verbatim} |
| netadm@amber:~ # ip -4 addr flush label "eth*" |
| \end{verbatim} |
| And the last example shows how to flush all the IPv6 addresses |
| acquired by the host from stateless address autoconfiguration |
| after you enabled forwarding or disabled autoconfiguration. |
| \begin{verbatim} |
| netadm@amber:~ # ip -6 addr flush dynamic |
| \end{verbatim} |
| |
| |
| |
| \section{{\tt ip neighbour} --- neighbour/arp tables management} |
| |
| \paragraph{Abbreviations:} \verb|neighbour|, \verb|neighbor|, \verb|neigh|, |
| \verb|n|. |
| |
| \paragraph{Object:} \verb|neighbour| objects establish bindings between protocol |
| addresses and link layer addresses for hosts sharing the same link. |
| Neighbour entries are organized into tables. The IPv4 neighbour table |
| is known by another name --- the ARP table. |
| |
| The corresponding commands display neighbour bindings |
| and their properties, add new neighbour entries and delete old ones. |
| |
| \paragraph{Commands:} \verb|add|, \verb|change|, \verb|replace|, |
| \verb|delete|, \verb|flush| and \verb|show| (or \verb|list|). |
| |
| \paragraph{See also:} Appendix~\ref{PROXY-NEIGH}, p.\pageref{PROXY-NEIGH} |
| describes how to manage proxy ARP/NDISC with the \verb|ip| utility. |
| |
| |
| \subsection{{\tt ip neighbour add} --- add a new neighbour entry\\ |
| {\tt ip neighbour change} --- change an existing entry\\ |
| {\tt ip neighbour replace} --- add a new entry or change an existing one} |
| |
| \paragraph{Abbreviations:} \verb|add|, \verb|a|; \verb|change|, \verb|chg|; |
| \verb|replace|, \verb|repl|. |
| |
| \paragraph{Description:} These commands create new neighbour records |
| or update existing ones. |
| |
| \paragraph{Arguments:} |
| |
| \begin{itemize} |
| \item \verb|to ADDRESS| (default) |
| |
| --- the protocol address of the neighbour. It is either an IPv4 or IPv6 address. |
| |
| \item \verb|dev NAME| |
| |
| --- the interface to which this neighbour is attached. |
| |
| |
| \item \verb|lladdr LLADDRESS| |
| |
| --- the link layer address of the neighbour. \verb|LLADDRESS| can also be |
| \verb|null|. |
| |
| \item \verb|nud NUD_STATE| |
| |
| --- the state of the neighbour entry. \verb|nud| is an abbreviation for ``Neighbour |
| Unreachability Detection''. The state can take one of the following values: |
| |
| \begin{enumerate} |
| \item \verb|permanent| --- the neighbour entry is valid forever and can be only be removed |
| administratively. |
| \item \verb|noarp| --- the neighbour entry is valid. No attempts to validate |
| this entry will be made but it can be removed when its lifetime expires. |
| \item \verb|reachable| --- the neighbour entry is valid until the reachability |
| timeout expires. |
| \item \verb|stale| --- the neighbour entry is valid but suspicious. |
| This option to \verb|ip neigh| does not change the neighbour state if |
| it was valid and the address is not changed by this command. |
| \end{enumerate} |
| |
| \end{itemize} |
| |
| \paragraph{Examples:} |
| \begin{itemize} |
| \item \verb|ip neigh add 10.0.0.3 lladdr 0:0:0:0:0:1 dev eth0 nud perm| |
| |
| --- add a permanent ARP entry for the neighbour 10.0.0.3 on the device \verb|eth0|. |
| |
| \item \verb|ip neigh chg 10.0.0.3 dev eth0 nud reachable| |
| |
| --- change its state to \verb|reachable|. |
| \end{itemize} |
| |
| |
| \subsection{{\tt ip neighbour delete} --- delete a neighbour entry} |
| |
| \paragraph{Abbreviations:} \verb|delete|, \verb|del|, \verb|d|. |
| |
| \paragraph{Description:} This command invalidates a neighbour entry. |
| |
| \paragraph{Arguments:} The arguments are the same as with \verb|ip neigh add|, |
| except that \verb|lladdr| and \verb|nud| are ignored. |
| |
| |
| \paragraph{Example:} |
| \begin{itemize} |
| \item \verb|ip neigh del 10.0.0.3 dev eth0| |
| |
| --- invalidate an ARP entry for the neighbour 10.0.0.3 on the device \verb|eth0|. |
| |
| \end{itemize} |
| |
| \begin{NB} |
| The deleted neighbour entry will not disappear from the tables |
| immediately. If it is in use it cannot be deleted until the last |
| client releases it. Otherwise it will be destroyed during |
| the next garbage collection. |
| \end{NB} |
| |
| |
| \paragraph{Warning:} Attempts to delete or manually change |
| a \verb|noarp| entry created by the kernel may result in unpredictable behaviour. |
| Particularly, the kernel may try to resolve this address even |
| on a \verb|NOARP| interface or if the address is multicast or broadcast. |
| |
| |
| \subsection{{\tt ip neighbour show} --- list neighbour entries} |
| |
| \paragraph{Abbreviations:} \verb|show|, \verb|list|, \verb|sh|, \verb|ls|. |
| |
| \paragraph{Description:}This commands displays neighbour tables. |
| |
| \paragraph{Arguments:} |
| |
| \begin{itemize} |
| |
| \item \verb|to ADDRESS| (default) |
| |
| --- the prefix selecting the neighbours to list. |
| |
| \item \verb|dev NAME| |
| |
| --- only list the neighbours attached to this device. |
| |
| \item \verb|unused| |
| |
| --- only list neighbours which are not currently in use. |
| |
| \item \verb|nud NUD_STATE| |
| |
| --- only list neighbour entries in this state. \verb|NUD_STATE| takes |
| values listed below or the special value \verb|all| which means all states. |
| This option may occur more than once. If this option is absent, \verb|ip| |
| lists all entries except for \verb|none| and \verb|noarp|. |
| |
| \end{itemize} |
| |
| |
| \paragraph{Output format:} |
| |
| \begin{verbatim} |
| kuznet@alisa:~ $ ip neigh ls |
| :: dev lo lladdr 00:00:00:00:00:00 nud noarp |
| fe80::200:cff:fe76:3f85 dev eth0 lladdr 00:00:0c:76:3f:85 router \ |
| nud stale |
| 0.0.0.0 dev lo lladdr 00:00:00:00:00:00 nud noarp |
| 193.233.7.254 dev eth0 lladdr 00:00:0c:76:3f:85 nud reachable |
| 193.233.7.85 dev eth0 lladdr 00:e0:1e:63:39:00 nud stale |
| kuznet@alisa:~ $ |
| \end{verbatim} |
| |
| The first word of each line is the protocol address of the neighbour. |
| Then the device name follows. The rest of the line describes the contents of |
| the neighbour entry identified by the pair (device, address). |
| |
| \verb|lladdr| is the link layer address of the neighbour. |
| |
| \verb|nud| is the state of the ``neighbour unreachability detection'' machine |
| for this entry. The detailed description of the neighbour |
| state machine can be found in~\cite{RFC-NDISC}. Here is the full list |
| of the states with short descriptions: |
| |
| \begin{enumerate} |
| \item\verb|none| --- the state of the neighbour is void. |
| \item\verb|incomplete| --- the neighbour is in the process of resolution. |
| \item\verb|reachable| --- the neighbour is valid and apparently reachable. |
| \item\verb|stale| --- the neighbour is valid, but is probably already |
| unreachable, so the kernel will try to check it at the first transmission. |
| \item\verb|delay| --- a packet has been sent to the stale neighbour and the kernel is waiting |
| for confirmation. |
| \item\verb|probe| --- the delay timer expired but no confirmation was received. |
| The kernel has started to probe the neighbour with ARP/NDISC messages. |
| \item\verb|failed| --- resolution has failed. |
| \item\verb|noarp| --- the neighbour is valid. No attempts to check the entry |
| will be made. |
| \item\verb|permanent| --- it is a \verb|noarp| entry, but only the administrator |
| may remove the entry from the neighbour table. |
| \end{enumerate} |
| |
| The link layer address is valid in all states except for \verb|none|, |
| \verb|failed| and \verb|incomplete|. |
| |
| IPv6 neighbours can be marked with the additional flag \verb|router| |
| which means that the neighbour introduced itself as an IPv6 router~\cite{RFC-NDISC}. |
| |
| \paragraph{Statistics:} The \verb|-statistics| option displays some usage |
| statistics, f.e.\ |
| |
| \begin{verbatim} |
| kuznet@alisa:~ $ ip -s n ls 193.233.7.254 |
| 193.233.7.254 dev eth0 lladdr 00:00:0c:76:3f:85 ref 5 used 12/13/20 \ |
| nud reachable |
| kuznet@alisa:~ $ |
| \end{verbatim} |
| |
| Here \verb|ref| is the number of users of this entry |
| and \verb|used| is a triplet of time intervals in seconds |
| separated by slashes. In this case they show that: |
| |
| \begin{enumerate} |
| \item the entry was used 12 seconds ago. |
| \item the entry was confirmed 13 seconds ago. |
| \item the entry was updated 20 seconds ago. |
| \end{enumerate} |
| |
| \subsection{{\tt ip neighbour flush} --- flush neighbour entries} |
| |
| \paragraph{Abbreviations:} \verb|flush|, \verb|f|. |
| |
| \paragraph{Description:}This command flushes neighbour tables, selecting |
| entries to flush by some criteria. |
| |
| \paragraph{Arguments:} This command has the same arguments as \verb|show|. |
| The differences are that it does not run when no arguments are given, |
| and that the default neighbour states to be flushed do not include |
| \verb|permanent| and \verb|noarp|. |
| |
| |
| \paragraph{Statistics:} With the \verb|-statistics| option, the command |
| becomes verbose. It prints out the number of deleted neighbours and the number |
| of rounds made to flush the neighbour table. If the option is given |
| twice, \verb|ip neigh flush| also dumps all the deleted neighbours |
| in the format described in the previous subsection. |
| |
| \paragraph{Example:} |
| \begin{verbatim} |
| netadm@alisa:~ # ip -s -s n f 193.233.7.254 |
| 193.233.7.254 dev eth0 lladdr 00:00:0c:76:3f:85 ref 5 used 12/13/20 \ |
| nud reachable |
| |
| *** Round 1, deleting 1 entries *** |
| *** Flush is complete after 1 round *** |
| netadm@alisa:~ # |
| \end{verbatim} |
| |
| |
| \section{{\tt ip route} --- routing table management} |
| \label{IP-ROUTE} |
| |
| \paragraph{Abbreviations:} \verb|route|, \verb|ro|, \verb|r|. |
| |
| \paragraph{Object:} \verb|route| entries in the kernel routing tables keep |
| information about paths to other networked nodes. |
| |
| Each route entry has a {\em key\/} consisting of a {\em prefix\/} |
| (i.e.\ a pair containing a network address and the length of its mask) and, |
| optionally, the TOS value. An IP packet matches the route if the highest |
| bits of its destination address are equal to the route prefix at least |
| up to the prefix length and if the TOS of the route is zero or equal to |
| the TOS of the packet. |
| |
| If several routes match the packet, the following pruning rules |
| are used to select the best one (see~\cite{RFC1812}): |
| \begin{enumerate} |
| \item The longest matching prefix is selected. All shorter ones |
| are dropped. |
| |
| \item If the TOS of some route with the longest prefix is equal to the TOS |
| of the packet, the routes with different TOS are dropped. |
| |
| If no exact TOS match was found and routes with TOS=0 exist, |
| the rest of routes are pruned. |
| |
| Otherwise, the route lookup fails. |
| |
| \item If several routes remain after the previous steps, then |
| the routes with the best preference values are selected. |
| |
| \item If we still have several routes, then the {\em first\/} of them |
| is selected. |
| |
| \begin{NB} |
| Note the ambiguity of the last step. Unfortunately, Linux |
| historically allows such a bizarre situation. The sense of the |
| word ``first'' depends on the order of route additions and it is practically |
| impossible to maintain a bundle of such routes in this order. |
| \end{NB} |
| |
| For simplicity we will limit ourselves to the case where such a situation |
| is impossible and routes are uniquely identified by the triplet |
| \{prefix, tos, preference\}. Actually, it is impossible to create |
| non-unique routes with \verb|ip| commands described in this section. |
| |
| One useful exception to this rule is the default route on non-forwarding |
| hosts. It is ``officially'' allowed to have several fallback routes |
| when several routers are present on directly connected networks. |
| In this case, Linux-2.2 makes ``dead gateway detection''~\cite{RFC1122} |
| controlled by neighbour unreachability detection and by advice |
| from transport protocols to select a working router, so the order |
| of the routes is not essential. However, in this case, |
| fiddling with default routes manually is not recommended. Use the Router Discovery |
| protocol (see Appendix~\ref{EXAMPLE-SETUP}, p.\pageref{EXAMPLE-SETUP}) |
| instead. Actually, Linux-2.2 IPv6 does not give user level applications |
| any access to default routes. |
| \end{enumerate} |
| |
| Certainly, the steps above are not performed exactly |
| in this sequence. Instead, the routing table in the kernel is kept |
| in some data structure to achieve the final result |
| with minimal cost. However, not depending on a particular |
| routing algorithm implemented in the kernel, we can summarize |
| the statements above as: a route is identified by the triplet |
| \{prefix, tos, preference\}. This {\em key\/} lets us locate |
| the route in the routing table. |
| |
| \paragraph{Route attributes:} Each route key refers to a routing |
| information record containing |
| the data required to deliver IP packets (f.e.\ output device and |
| next hop router) and some optional attributes (f.e. the path MTU or |
| the preferred source address when communicating with this destination). |
| These attributes are described in the following subsection. |
| |
| \paragraph{Route types:} \label{IP-ROUTE-TYPES} |
| It is important that the set |
| of required and optional attributes depend on the route {\em type\/}. |
| The most important route type |
| is \verb|unicast|. It describes real paths to other hosts. |
| As a rule, common routing tables contain only such routes. However, |
| there are other types of routes with different semantics. The |
| full list of types understood by Linux-2.2 is: |
| \begin{itemize} |
| \item \verb|unicast| --- the route entry describes real paths to the |
| destinations covered by the route prefix. |
| \item \verb|unreachable| --- these destinations are unreachable. Packets |
| are discarded and the ICMP message {\em host unreachable\/} is generated. |
| The local senders get an \verb|EHOSTUNREACH| error. |
| \item \verb|blackhole| --- these destinations are unreachable. Packets |
| are discarded silently. The local senders get an \verb|EINVAL| error. |
| \item \verb|prohibit| --- these destinations are unreachable. Packets |
| are discarded and the ICMP message {\em communication administratively |
| prohibited\/} is generated. The local senders get an \verb|EACCES| error. |
| \item \verb|local| --- the destinations are assigned to this |
| host. The packets are looped back and delivered locally. |
| \item \verb|broadcast| --- the destinations are broadcast addresses. |
| The packets are sent as link broadcasts. |
| \item \verb|throw| --- a special control route used together with policy |
| rules (see sec.\ref{IP-RULE}, p.\pageref{IP-RULE}). If such a route is selected, lookup |
| in this table is terminated pretending that no route was found. |
| Without policy routing it is equivalent to the absence of the route in the routing |
| table. The packets are dropped and the ICMP message {\em net unreachable\/} |
| is generated. The local senders get an \verb|ENETUNREACH| error. |
| \item \verb|nat| --- a special NAT route. Destinations covered by the prefix |
| are considered to be dummy (or external) addresses which require translation |
| to real (or internal) ones before forwarding. The addresses to translate to |
| are selected with the attribute \verb|via|. More about NAT is |
| in Appendix~\ref{ROUTE-NAT}, p.\pageref{ROUTE-NAT}. |
| \item \verb|anycast| --- ({\em not implemented\/}) the destinations are |
| {\em anycast\/} addresses assigned to this host. They are mainly equivalent |
| to \verb|local| with one difference: such addresses are invalid when used |
| as the source address of any packet. |
| \item \verb|multicast| --- a special type used for multicast routing. |
| It is not present in normal routing tables. |
| \end{itemize} |
| |
| \paragraph{Route tables:} Linux-2.2 can pack routes into several routing |
| tables identified by a number in the range from 1 to 255 or by |
| name from the file \verb|/etc/iproute2/rt_tables|. By default all normal |
| routes are inserted into the \verb|main| table (ID 254) and the kernel only uses |
| this table when calculating routes. |
| |
| Actually, one other table always exists, which is invisible but |
| even more important. It is the \verb|local| table (ID 255). This table |
| consists of routes for local and broadcast addresses. The kernel maintains |
| this table automatically and the administrator usually need not modify it |
| or even look at it. |
| |
| The multiple routing tables enter the game when {\em policy routing\/} |
| is used. See sec.\ref{IP-RULE}, p.\pageref{IP-RULE}. |
| In this case, the table identifier effectively becomes |
| one more parameter, which should be added to the triplet |
| \{prefix, tos, preference\} to uniquely identify the route. |
| |
| |
| \subsection{{\tt ip route add} --- add a new route\\ |
| {\tt ip route change} --- change a route\\ |
| {\tt ip route replace} --- change a route or add a new one} |
| \label{IP-ROUTE-ADD} |
| |
| \paragraph{Abbreviations:} \verb|add|, \verb|a|; \verb|change|, \verb|chg|; |
| \verb|replace|, \verb|repl|. |
| |
| |
| \paragraph{Arguments:} |
| \begin{itemize} |
| \item \verb|to PREFIX| or \verb|to TYPE PREFIX| (default) |
| |
| --- the destination prefix of the route. If \verb|TYPE| is omitted, |
| \verb|ip| assumes type \verb|unicast|. Other values of \verb|TYPE| |
| are listed above. \verb|PREFIX| is an IP or IPv6 address optionally followed |
| by a slash and the prefix length. If the length of the prefix is missing, |
| \verb|ip| assumes a full-length host route. There is also a special |
| \verb|PREFIX| --- \verb|default| --- which is equivalent to IP \verb|0/0| or |
| to IPv6 \verb|::/0|. |
| |
| \item \verb|tos TOS| or \verb|dsfield TOS| |
| |
| --- the Type Of Service (TOS) key. This key has no associated mask and |
| the longest match is understood as: First, compare the TOS |
| of the route and of the packet. If they are not equal, then the packet |
| may still match a route with a zero TOS. \verb|TOS| is either an 8 bit hexadecimal |
| number or an identifier from {\tt /etc/iproute2/rt\_dsfield}. |
| |
| |
| \item \verb|metric NUMBER| or \verb|preference NUMBER| |
| |
| --- the preference value of the route. \verb|NUMBER| is an arbitrary 32bit number. |
| |
| \item \verb|table TABLEID| |
| |
| --- the table to add this route to. |
| \verb|TABLEID| may be a number or a string from the file |
| \verb|/etc/iproute2/rt_tables|. If this parameter is omitted, |
| \verb|ip| assumes the \verb|main| table, with the exception of |
| \verb|local|, \verb|broadcast| and \verb|nat| routes, which are |
| put into the \verb|local| table by default. |
| |
| \item \verb|dev NAME| |
| |
| --- the output device name. |
| |
| \item \verb|via ADDRESS| |
| |
| --- the address of the nexthop router. Actually, the sense of this field depends |
| on the route type. For normal \verb|unicast| routes it is either the true nexthop |
| router or, if it is a direct route installed in BSD compatibility mode, |
| it can be a local address of the interface. |
| For NAT routes it is the first address of the block of translated IP destinations. |
| |
| \item \verb|src ADDRESS| |
| |
| --- the source address to prefer when sending to the destinations |
| covered by the route prefix. |
| |
| \item \verb|realm REALMID| |
| |
| --- the realm to which this route is assigned. |
| \verb|REALMID| may be a number or a string from the file |
| \verb|/etc/iproute2/rt_realms|. Sec.\ref{RT-REALMS} (p.\pageref{RT-REALMS}) |
| contains more information on realms. |
| |
| \item \verb|mtu MTU| or \verb|mtu lock MTU| |
| |
| --- the MTU along the path to the destination. If the modifier \verb|lock| is |
| not used, the MTU may be updated by the kernel due to Path MTU Discovery. |
| If the modifier \verb|lock| is used, no path MTU discovery will be tried, |
| all packets will be sent without the DF bit in IPv4 case |
| or fragmented to MTU for IPv6. |
| |
| \item \verb|window NUMBER| |
| |
| --- the maximal window for TCP to advertise to these destinations, |
| measured in bytes. It limits maximal data bursts that our TCP |
| peers are allowed to send to us. |
| |
| \item \verb|rtt NUMBER| |
| |
| --- the initial RTT (``Round Trip Time'') estimate. |
| |
| |
| \item \verb|rttvar NUMBER| |
| |
| --- \threeonly the initial RTT variance estimate. |
| |
| |
| \item \verb|ssthresh NUMBER| |
| |
| --- \threeonly an estimate for the initial slow start threshold. |
| |
| |
| \item \verb|cwnd NUMBER| |
| |
| --- \threeonly the clamp for congestion window. It is ignored if the \verb|lock| |
| flag is not used. |
| |
| |
| \item \verb|advmss NUMBER| |
| |
| --- \threeonly the MSS (``Maximal Segment Size'') to advertise to these |
| destinations when establishing TCP connections. If it is not given, |
| Linux uses a default value calculated from the first hop device MTU. |
| |
| \begin{NB} |
| If the path to these destination is asymmetric, this guess may be wrong. |
| \end{NB} |
| |
| \item \verb|reordering NUMBER| |
| |
| --- \threeonly Maximal reordering on the path to this destination. |
| If it is not given, Linux uses the value selected with \verb|sysctl| |
| variable \verb|net/ipv4/tcp_reordering|. |
| |
| \item \verb|hoplimit NUMBER| |
| |
| --- [2.5.74+ only] Maximum number of hops on the path to this destination. |
| The default is the value selected with the \verb|sysctl| variable |
| \verb|net/ipv4/ip_default_ttl|. |
| |
| \item \verb|initcwnd NUMBER| |
| --- [2.5.70+ only] Initial congestion window size for connections to |
| this destination. Actual window size is this value multiplied by the |
| MSS (``Maximal Segment Size'') for same connection. The default is |
| zero, meaning to use the values specified in~\cite{RFC2414}. |
| |
| +\item \verb|initrwnd NUMBER| |
| |
| +--- [2.6.33+ only] Initial receive window size for connections to |
| + this destination. The actual window size is this value multiplied |
| + by the MSS (''Maximal Segment Size'') of the connection. The default |
| + value is zero, meaning to use Slow Start value. |
| |
| \item \verb|nexthop NEXTHOP| |
| |
| --- the nexthop of a multipath route. \verb|NEXTHOP| is a complex value |
| with its own syntax similar to the top level argument lists: |
| \begin{itemize} |
| \item \verb|via ADDRESS| is the nexthop router. |
| \item \verb|dev NAME| is the output device. |
| \item \verb|weight NUMBER| is a weight for this element of a multipath |
| route reflecting its relative bandwidth or quality. |
| \end{itemize} |
| |
| \item \verb|scope SCOPE_VAL| |
| |
| --- the scope of the destinations covered by the route prefix. |
| \verb|SCOPE_VAL| may be a number or a string from the file |
| \verb|/etc/iproute2/rt_scopes|. |
| If this parameter is omitted, |
| \verb|ip| assumes scope \verb|global| for all gatewayed \verb|unicast| |
| routes, scope \verb|link| for direct \verb|unicast| and \verb|broadcast| routes |
| and scope \verb|host| for \verb|local| routes. |
| |
| \item \verb|protocol RTPROTO| |
| |
| --- the routing protocol identifier of this route. |
| \verb|RTPROTO| may be a number or a string from the file |
| \verb|/etc/iproute2/rt_protos|. If the routing protocol ID is |
| not given, \verb|ip| assumes protocol \verb|boot| (i.e.\ |
| it assumes the route was added by someone who doesn't |
| understand what they are doing). Several protocol values have a fixed interpretation. |
| Namely: |
| \begin{itemize} |
| \item \verb|redirect| --- the route was installed due to an ICMP redirect. |
| \item \verb|kernel| --- the route was installed by the kernel during |
| autoconfiguration. |
| \item \verb|boot| --- the route was installed during the bootup sequence. |
| If a routing daemon starts, it will purge all of them. |
| \item \verb|static| --- the route was installed by the administrator |
| to override dynamic routing. Routing daemon will respect them |
| and, probably, even advertise them to its peers. |
| \item \verb|ra| --- the route was installed by Router Discovery protocol. |
| \end{itemize} |
| The rest of the values are not reserved and the administrator is free |
| to assign (or not to assign) protocol tags. At least, routing |
| daemons should take care of setting some unique protocol values, |
| f.e.\ as they are assigned in \verb|rtnetlink.h| or in \verb|rt_protos| |
| database. |
| |
| |
| \item \verb|onlink| |
| |
| --- pretend that the nexthop is directly attached to this link, |
| even if it does not match any interface prefix. One application of this |
| option may be found in~\cite{IP-TUNNELS}. |
| |
| \end{itemize} |
| |
| |
| \begin{NB} |
| Actually there are more commands: \verb|prepend| does the same |
| thing as classic \verb|route add|, i.e.\ adds a route, even if another |
| route to the same destination exists. Its opposite case is \verb|append|, |
| which adds the route to the end of the list. Avoid these |
| features. |
| \end{NB} |
| \begin{NB} |
| More sad news, IPv6 only understands the \verb|append| command correctly. |
| All the others are translated into \verb|append| commands. Certainly, |
| this will change in the future. |
| \end{NB} |
| |
| \paragraph{Examples:} |
| \begin{itemize} |
| \item add a plain route to network 10.0.0/24 via gateway 193.233.7.65 |
| \begin{verbatim} |
| ip route add 10.0.0/24 via 193.233.7.65 |
| \end{verbatim} |
| \item change it to a direct route via the \verb|dummy| device |
| \begin{verbatim} |
| ip ro chg 10.0.0/24 dev dummy |
| \end{verbatim} |
| \item add a default multipath route splitting the load between \verb|ppp0| |
| and \verb|ppp1| |
| \begin{verbatim} |
| ip route add default scope global nexthop dev ppp0 \ |
| nexthop dev ppp1 |
| \end{verbatim} |
| Note the scope value. It is not necessary but it informs the kernel |
| that this route is gatewayed rather than direct. Actually, if you |
| know the addresses of remote endpoints it would be better to use the |
| \verb|via| parameter. |
| \item announce that the address 192.203.80.144 is not a real one, but |
| should be translated to 193.233.7.83 before forwarding |
| \begin{verbatim} |
| ip route add nat 192.203.80.144 via 193.233.7.83 |
| \end{verbatim} |
| Backward translation is setup with policy rules described |
| in the following section (sec.\ref{IP-RULE}, p.\pageref{IP-RULE}). |
| \end{itemize} |
| |
| \subsection{{\tt ip route delete} --- delete a route} |
| |
| \paragraph{Abbreviations:} \verb|delete|, \verb|del|, \verb|d|. |
| |
| \paragraph{Arguments:} \verb|ip route del| has the same arguments as |
| \verb|ip route add|, but their semantics are a bit different. |
| |
| Key values (\verb|to|, \verb|tos|, \verb|preference| and \verb|table|) |
| select the route to delete. If optional attributes are present, \verb|ip| |
| verifies that they coincide with the attributes of the route to delete. |
| If no route with the given key and attributes was found, \verb|ip route del| |
| fails. |
| \begin{NB} |
| Linux-2.0 had the option to delete a route selected only by prefix address, |
| ignoring its length (i.e.\ netmask). This option no longer exists |
| because it was ambiguous. However, look at {\tt ip route flush} |
| (sec.\ref{IP-ROUTE-FLUSH}, p.\pageref{IP-ROUTE-FLUSH}) which |
| provides similar and even richer functionality. |
| \end{NB} |
| |
| \paragraph{Example:} |
| \begin{itemize} |
| \item delete the multipath route created by the command in previous subsection |
| \begin{verbatim} |
| ip route del default scope global nexthop dev ppp0 \ |
| nexthop dev ppp1 |
| \end{verbatim} |
| \end{itemize} |
| |
| |
| |
| \subsection{{\tt ip route show} --- list routes} |
| |
| \paragraph{Abbreviations:} \verb|show|, \verb|list|, \verb|sh|, \verb|ls|, \verb|l|. |
| |
| \paragraph{Description:} the command displays the contents of the routing tables |
| or the route(s) selected by some criteria. |
| |
| |
| \paragraph{Arguments:} |
| \begin{itemize} |
| \item \verb|to SELECTOR| (default) |
| |
| --- only select routes from the given range of destinations. \verb|SELECTOR| |
| consists of an optional modifier (\verb|root|, \verb|match| or \verb|exact|) |
| and a prefix. \verb|root PREFIX| selects routes with prefixes not shorter |
| than \verb|PREFIX|. F.e.\ \verb|root 0/0| selects the entire routing table. |
| \verb|match PREFIX| selects routes with prefixes not longer than |
| \verb|PREFIX|. F.e.\ \verb|match 10.0/16| selects \verb|10.0/16|, |
| \verb|10/8| and \verb|0/0|, but it does not select \verb|10.1/16| and |
| \verb|10.0.0/24|. And \verb|exact PREFIX| (or just \verb|PREFIX|) |
| selects routes with this exact prefix. If neither of these options |
| are present, \verb|ip| assumes \verb|root 0/0| i.e.\ it lists the entire table. |
| |
| |
| \item \verb|tos TOS| or \verb|dsfield TOS| |
| |
| --- only select routes with the given TOS. |
| |
| |
| \item \verb|table TABLEID| |
| |
| --- show the routes from this table(s). The default setting is to show |
| \verb|table| \verb|main|. \verb|TABLEID| may either be the ID of a real table |
| or one of the special values: |
| \begin{itemize} |
| \item \verb|all| --- list all of the tables. |
| \item \verb|cache| --- dump the routing cache. |
| \end{itemize} |
| \begin{NB} |
| IPv6 has a single table. However, splitting it into \verb|main|, \verb|local| |
| and \verb|cache| is emulated by the \verb|ip| utility. |
| \end{NB} |
| |
| \item \verb|cloned| or \verb|cached| |
| |
| --- list cloned routes i.e.\ routes which were dynamically forked from |
| other routes because some route attribute (f.e.\ MTU) was updated. |
| Actually, it is equivalent to \verb|table cache|. |
| |
| \item \verb|from SELECTOR| |
| |
| --- the same syntax as for \verb|to|, but it binds the source address range |
| rather than destinations. Note that the \verb|from| option only works with |
| cloned routes. |
| |
| \item \verb|protocol RTPROTO| |
| |
| --- only list routes of this protocol. |
| |
| |
| \item \verb|scope SCOPE_VAL| |
| |
| --- only list routes with this scope. |
| |
| \item \verb|type TYPE| |
| |
| --- only list routes of this type. |
| |
| \item \verb|dev NAME| |
| |
| --- only list routes going via this device. |
| |
| \item \verb|via PREFIX| |
| |
| --- only list routes going via the nexthop routers selected by \verb|PREFIX|. |
| |
| \item \verb|src PREFIX| |
| |
| --- only list routes with preferred source addresses selected |
| by \verb|PREFIX|. |
| |
| \item \verb|realm REALMID| or \verb|realms FROMREALM/TOREALM| |
| |
| --- only list routes with these realms. |
| |
| \end{itemize} |
| |
| \paragraph{Examples:} Let us count routes of protocol \verb|gated/bgp| |
| on a router: |
| \begin{verbatim} |
| kuznet@amber:~ $ ip ro ls proto gated/bgp | wc |
| 1413 9891 79010 |
| kuznet@amber:~ $ |
| \end{verbatim} |
| To count the size of the routing cache, we have to use the \verb|-o| option |
| because cached attributes can take more than one line of output: |
| \begin{verbatim} |
| kuznet@amber:~ $ ip -o ro ls cloned | wc |
| 159 2543 18707 |
| kuznet@amber:~ $ |
| \end{verbatim} |
| |
| |
| \paragraph{Output format:} The output of this command consists |
| of per route records separated by line feeds. |
| However, some records may consist |
| of more than one line: particularly, this is the case when the route |
| is cloned or you requested additional statistics. If the |
| \verb|-o| option was given, then line feeds separating lines inside |
| records are replaced with the backslash sign. |
| |
| The output has the same syntax as arguments given to {\tt ip route add}, |
| so that it can be understood easily. F.e.\ |
| \begin{verbatim} |
| kuznet@amber:~ $ ip ro ls 193.233.7/24 |
| 193.233.7.0/24 dev eth0 proto gated/conn scope link \ |
| src 193.233.7.65 realms inr.ac |
| kuznet@amber:~ $ |
| \end{verbatim} |
| |
| If you list cloned entries, the output contains other attributes which |
| are evaluated during route calculation and updated during route |
| lifetime. An example of the output is: |
| \begin{verbatim} |
| kuznet@amber:~ $ ip ro ls 193.233.7.82 tab cache |
| 193.233.7.82 from 193.233.7.82 dev eth0 src 193.233.7.65 \ |
| realms inr.ac/inr.ac |
| cache <src-direct,redirect> mtu 1500 rtt 300 iif eth0 |
| 193.233.7.82 dev eth0 src 193.233.7.65 realms inr.ac |
| cache mtu 1500 rtt 300 |
| kuznet@amber:~ $ |
| \end{verbatim} |
| \begin{NB} |
| \label{NB-strange-route} |
| The route looks a bit strange, doesn't it? Did you notice that |
| it is a path from 193.233.7.82 back to 193.233.82? Well, you will |
| see in the section on \verb|ip route get| (p.\pageref{NB-nature-of-strangeness}) |
| how it appeared. |
| \end{NB} |
| The second line, starting with the word \verb|cache|, shows |
| additional attributes which normal routes do not possess. |
| Cached flags are summarized in angle brackets: |
| \begin{itemize} |
| \item \verb|local| --- packets are delivered locally. |
| It stands for loopback unicast routes, for broadcast routes |
| and for multicast routes, if this host is a member of the corresponding |
| group. |
| |
| \item \verb|reject| --- the path is bad. Any attempt to use it results |
| in an error. See attribute \verb|error| below (p.\pageref{IP-ROUTE-GET-error}). |
| |
| \item \verb|mc| --- the destination is multicast. |
| |
| \item \verb|brd| --- the destination is broadcast. |
| |
| \item \verb|src-direct| --- the source is on a directly connected |
| interface. |
| |
| \item \verb|redirected| --- the route was created by an ICMP Redirect. |
| |
| \item \verb|redirect| --- packets going via this route will |
| trigger an ICMP redirect. |
| |
| \item \verb|fastroute| --- the route is eligible to be used for fastroute. |
| |
| \item \verb|equalize| --- make packet by packet randomization |
| along this path. |
| |
| \item \verb|dst-nat| --- the destination address requires translation. |
| |
| \item \verb|src-nat| --- the source address requires translation. |
| |
| \item \verb|masq| --- the source address requires masquerading. |
| This feature disappeared in linux-2.4. |
| |
| \item \verb|notify| --- ({\em not implemented}) change/deletion |
| of this route will trigger RTNETLINK notification. |
| \end{itemize} |
| |
| Then some optional attributes follow: |
| \begin{itemize} |
| \item \verb|error| --- on \verb|reject| routes it is error code |
| returned to local senders when they try to use this route. |
| These error codes are translated into ICMP error codes, sent to remote |
| senders, according to the rules described above in the subsection |
| devoted to route types (p.\pageref{IP-ROUTE-TYPES}). |
| \label{IP-ROUTE-GET-error} |
| |
| \item \verb|expires| --- this entry will expire after this timeout. |
| |
| \item \verb|iif| --- the packets for this path are expected to arrive |
| on this interface. |
| \end{itemize} |
| |
| \paragraph{Statistics:} With the \verb|-statistics| option, more |
| information about this route is shown: |
| \begin{itemize} |
| \item \verb|users| --- the number of users of this entry. |
| \item \verb|age| --- shows when this route was last used. |
| \item \verb|used| --- the number of lookups of this route since its creation. |
| \end{itemize} |
| |
| |
| \subsection{{\tt ip route flush} --- flush routing tables} |
| \label{IP-ROUTE-FLUSH} |
| |
| \paragraph{Abbreviations:} \verb|flush|, \verb|f|. |
| |
| \paragraph{Description:} this command flushes routes selected |
| by some criteria. |
| |
| \paragraph{Arguments:} the arguments have the same syntax and semantics |
| as the arguments of \verb|ip route show|, but routing tables are not |
| listed but purged. The only difference is the default action: \verb|show| |
| dumps all the IP main routing table but \verb|flush| prints the helper page. |
| The reason for this difference does not require any explanation, does it? |
| |
| |
| \paragraph{Statistics:} With the \verb|-statistics| option, the command |
| becomes verbose. It prints out the number of deleted routes and the number |
| of rounds made to flush the routing table. If the option is given |
| twice, \verb|ip route flush| also dumps all the deleted routes |
| in the format described in the previous subsection. |
| |
| \paragraph{Examples:} The first example flushes all the |
| gatewayed routes from the main table (f.e.\ after a routing daemon crash). |
| \begin{verbatim} |
| netadm@amber:~ # ip -4 ro flush scope global type unicast |
| \end{verbatim} |
| This option deserves to be put into a scriptlet \verb|routef|. |
| \begin{NB} |
| This option was described in the \verb|route(8)| man page borrowed |
| from BSD, but was never implemented in Linux. |
| \end{NB} |
| |
| The second example flushes all IPv6 cloned routes: |
| \begin{verbatim} |
| netadm@amber:~ # ip -6 -s -s ro flush cache |
| 3ffe:2400::220:afff:fef4:c5d1 via 3ffe:2400::220:afff:fef4:c5d1 \ |
| dev eth0 metric 0 |
| cache used 2 age 12sec mtu 1500 rtt 300 |
| 3ffe:2400::280:adff:feb7:8034 via 3ffe:2400::280:adff:feb7:8034 \ |
| dev eth0 metric 0 |
| cache used 2 age 15sec mtu 1500 rtt 300 |
| 3ffe:2400::280:c8ff:fe59:5bcc via 3ffe:2400::280:c8ff:fe59:5bcc \ |
| dev eth0 metric 0 |
| cache users 1 used 1 age 23sec mtu 1500 rtt 300 |
| 3ffe:2400:0:1:2a0:ccff:fe66:1878 via 3ffe:2400:0:1:2a0:ccff:fe66:1878 \ |
| dev eth1 metric 0 |
| cache used 2 age 20sec mtu 1500 rtt 300 |
| 3ffe:2400:0:1:a00:20ff:fe71:fb30 via 3ffe:2400:0:1:a00:20ff:fe71:fb30 \ |
| dev eth1 metric 0 |
| cache used 2 age 33sec mtu 1500 rtt 300 |
| ff02::1 via ff02::1 dev eth1 metric 0 |
| cache users 1 used 1 age 45sec mtu 1500 rtt 300 |
| |
| *** Round 1, deleting 6 entries *** |
| *** Flush is complete after 1 round *** |
| netadm@amber:~ # ip -6 -s -s ro flush cache |
| Nothing to flush. |
| netadm@amber:~ # |
| \end{verbatim} |
| |
| The third example flushes BGP routing tables after a \verb|gated| |
| death. |
| \begin{verbatim} |
| netadm@amber:~ # ip ro ls proto gated/bgp | wc |
| 1408 9856 78730 |
| netadm@amber:~ # ip -s ro f proto gated/bgp |
| |
| *** Round 1, deleting 1408 entries *** |
| *** Flush is complete after 1 round *** |
| netadm@amber:~ # ip ro f proto gated/bgp |
| Nothing to flush. |
| netadm@amber:~ # ip ro ls proto gated/bgp |
| netadm@amber:~ # |
| \end{verbatim} |
| |
| |
| \subsection{{\tt ip route get} --- get a single route} |
| \label{IP-ROUTE-GET} |
| |
| \paragraph{Abbreviations:} \verb|get|, \verb|g|. |
| |
| \paragraph{Description:} this command gets a single route to a destination |
| and prints its contents exactly as the kernel sees it. |
| |
| \paragraph{Arguments:} |
| \begin{itemize} |
| \item \verb|to ADDRESS| (default) |
| |
| --- the destination address. |
| |
| \item \verb|from ADDRESS| |
| |
| --- the source address. |
| |
| \item \verb|tos TOS| or \verb|dsfield TOS| |
| |
| --- the Type Of Service. |
| |
| \item \verb|iif NAME| |
| |
| --- the device from which this packet is expected to arrive. |
| |
| \item \verb|oif NAME| |
| |
| --- force the output device on which this packet will be routed. |
| |
| \item \verb|connected| |
| |
| --- if no source address (option \verb|from|) was given, relookup |
| the route with the source set to the preferred address received from the first lookup. |
| If policy routing is used, it may be a different route. |
| |
| \end{itemize} |
| |
| Note that this operation is not equivalent to \verb|ip route show|. |
| \verb|show| shows existing routes. \verb|get| resolves them and |
| creates new clones if necessary. Essentially, \verb|get| |
| is equivalent to sending a packet along this path. |
| If the \verb|iif| argument is not given, the kernel creates a route |
| to output packets towards the requested destination. |
| This is equivalent to pinging the destination |
| with a subsequent {\tt ip route ls cache}, however, no packets are |
| actually sent. With the \verb|iif| argument, the kernel pretends |
| that a packet arrived from this interface and searches for |
| a path to forward the packet. |
| |
| \paragraph{Output format:} This command outputs routes in the same |
| format as \verb|ip route ls|. |
| |
| \paragraph{Examples:} |
| \begin{itemize} |
| \item Find a route to output packets to 193.233.7.82: |
| \begin{verbatim} |
| kuznet@amber:~ $ ip route get 193.233.7.82 |
| 193.233.7.82 dev eth0 src 193.233.7.65 realms inr.ac |
| cache mtu 1500 rtt 300 |
| kuznet@amber:~ $ |
| \end{verbatim} |
| |
| \item Find a route to forward packets arriving on \verb|eth0| |
| from 193.233.7.82 and destined for 193.233.7.82: |
| \begin{verbatim} |
| kuznet@amber:~ $ ip r g 193.233.7.82 from 193.233.7.82 iif eth0 |
| 193.233.7.82 from 193.233.7.82 dev eth0 src 193.233.7.65 \ |
| realms inr.ac/inr.ac |
| cache <src-direct,redirect> mtu 1500 rtt 300 iif eth0 |
| kuznet@amber:~ $ |
| \end{verbatim} |
| \begin{NB} |
| \label{NB-nature-of-strangeness} |
| This is the command that created the funny route from 193.233.7.82 |
| looped back to 193.233.7.82 (cf.\ NB on~p.\pageref{NB-strange-route}). |
| Note the \verb|redirect| flag on it. |
| \end{NB} |
| |
| \item Find a multicast route for packets arriving on \verb|eth0| |
| from host 193.233.7.82 and destined for multicast group 224.2.127.254 |
| (it is assumed that a multicast routing daemon is running. |
| In this case, it is \verb|pimd|) |
| \begin{verbatim} |
| kuznet@amber:~ $ ip r g 224.2.127.254 from 193.233.7.82 iif eth0 |
| multicast 224.2.127.254 from 193.233.7.82 dev lo \ |
| src 193.233.7.65 realms inr.ac/cosmos |
| cache <mc> iif eth0 Oifs: eth1 pimreg |
| kuznet@amber:~ $ |
| \end{verbatim} |
| This route differs from the ones seen before. It contains a ``normal'' part |
| and a ``multicast'' part. The normal part is used to deliver (or not to |
| deliver) the packet to local IP listeners. In this case the router |
| is not a member |
| of this group, so that route has no \verb|local| flag and only |
| forwards packets. The output device for such entries is always loopback. |
| The multicast part consists of an additional \verb|Oifs:| list showing |
| the output interfaces. |
| \end{itemize} |
| |
| |
| It is time for a more complicated example. Let us add an invalid |
| gatewayed route for a destination which is really directly connected: |
| \begin{verbatim} |
| netadm@alisa:~ # ip route add 193.233.7.98 via 193.233.7.254 |
| netadm@alisa:~ # ip route get 193.233.7.98 |
| 193.233.7.98 via 193.233.7.254 dev eth0 src 193.233.7.90 |
| cache mtu 1500 rtt 3072 |
| netadm@alisa:~ # |
| \end{verbatim} |
| and probe it with ping: |
| \begin{verbatim} |
| netadm@alisa:~ # ping -n 193.233.7.98 |
| PING 193.233.7.98 (193.233.7.98) from 193.233.7.90 : 56 data bytes |
| From 193.233.7.254: Redirect Host(New nexthop: 193.233.7.98) |
| 64 bytes from 193.233.7.98: icmp_seq=0 ttl=255 time=3.5 ms |
| From 193.233.7.254: Redirect Host(New nexthop: 193.233.7.98) |
| 64 bytes from 193.233.7.98: icmp_seq=1 ttl=255 time=2.2 ms |
| 64 bytes from 193.233.7.98: icmp_seq=2 ttl=255 time=0.4 ms |
| 64 bytes from 193.233.7.98: icmp_seq=3 ttl=255 time=0.4 ms |
| 64 bytes from 193.233.7.98: icmp_seq=4 ttl=255 time=0.4 ms |
| ^C |
| --- 193.233.7.98 ping statistics --- |
| 5 packets transmitted, 5 packets received, 0% packet loss |
| round-trip min/avg/max = 0.4/1.3/3.5 ms |
| netadm@alisa:~ # |
| \end{verbatim} |
| What happened? Router 193.233.7.254 understood that we have a much |
| better path to the destination and sent us an ICMP redirect message. |
| We may retry \verb|ip route get| to see what we have in the routing |
| tables now: |
| \begin{verbatim} |
| netadm@alisa:~ # ip route get 193.233.7.98 |
| 193.233.7.98 dev eth0 src 193.233.7.90 |
| cache <redirected> mtu 1500 rtt 3072 |
| netadm@alisa:~ # |
| \end{verbatim} |
| |
| |
| |
| \section{{\tt ip rule} --- routing policy database management} |
| \label{IP-RULE} |
| |
| \paragraph{Abbreviations:} \verb|rule|, \verb|ru|. |
| |
| \paragraph{Object:} \verb|rule|s in the routing policy database control |
| the route selection algorithm. |
| |
| Classic routing algorithms used in the Internet make routing decisions |
| based only on the destination address of packets (and in theory, |
| but not in practice, on the TOS field). The seminal review of classic |
| routing algorithms and their modifications can be found in~\cite{RFC1812}. |
| |
| In some circumstances we want to route packets differently depending not only |
| on destination addresses, but also on other packet fields: source address, |
| IP protocol, transport protocol ports or even packet payload. |
| This task is called ``policy routing''. |
| |
| \begin{NB} |
| ``policy routing'' $\neq$ ``routing policy''. |
| |
| \noindent ``policy routing'' $=$ ``cunning routing''. |
| |
| \noindent ``routing policy'' $=$ ``routing tactics'' or ``routing plan''. |
| \end{NB} |
| |
| To solve this task, the conventional destination based routing table, ordered |
| according to the longest match rule, is replaced with a ``routing policy |
| database'' (or RPDB), which selects routes |
| by executing some set of rules. The rules may have lots of keys of different |
| natures and therefore they have no natural ordering, but one imposed |
| by the administrator. Linux-2.2 RPDB is a linear list of rules |
| ordered by numeric priority value. |
| RPDB explicitly allows matching a few packet fields: |
| |
| \begin{itemize} |
| \item packet source address. |
| \item packet destination address. |
| \item TOS. |
| \item incoming interface (which is packet metadata, rather than a packet field). |
| \end{itemize} |
| |
| Matching IP protocols and transport ports is also possible, |
| indirectly, via \verb|ipchains|, by exploiting their ability |
| to mark some classes of packets with \verb|fwmark|. Therefore, |
| \verb|fwmark| is also included in the set of keys checked by rules. |
| |
| Each policy routing rule consists of a {\em selector\/} and an {\em action\/} |
| predicate. The RPDB is scanned in the order of increasing priority. The selector |
| of each rule is applied to \{source address, destination address, incoming |
| interface, tos, fwmark\} and, if the selector matches the packet, |
| the action is performed. The action predicate may return with success. |
| In this case, it will either give a route or failure indication |
| and the RPDB lookup is terminated. Otherwise, the RPDB program |
| continues on the next rule. |
| |
| What is the action, semantically? The natural action is to select the |
| nexthop and the output device. This is what |
| Cisco IOS~\cite{IOS} does. Let us call it ``match \& set''. |
| The Linux-2.2 approach is more flexible. The action includes |
| lookups in destination-based routing tables and selecting |
| a route from these tables according to the classic longest match algorithm. |
| The ``match \& set'' approach is the simplest case of the Linux one. It is realized |
| when a second level routing table contains a single default route. |
| Recall that Linux-2.2 supports multiple tables |
| managed with the \verb|ip route| command, described in the previous section. |
| |
| At startup time the kernel configures the default RPDB consisting of three |
| rules: |
| |
| \begin{enumerate} |
| \item Priority: 0, Selector: match anything, Action: lookup routing |
| table \verb|local| (ID 255). |
| The \verb|local| table is a special routing table containing |
| high priority control routes for local and broadcast addresses. |
| |
| Rule 0 is special. It cannot be deleted or overridden. |
| |
| |
| \item Priority: 32766, Selector: match anything, Action: lookup routing |
| table \verb|main| (ID 254). |
| The \verb|main| table is the normal routing table containing all non-policy |
| routes. This rule may be deleted and/or overridden with other |
| ones by the administrator. |
| |
| \item Priority: 32767, Selector: match anything, Action: lookup routing |
| table \verb|default| (ID 253). |
| The \verb|default| table is empty. It is reserved for some |
| post-processing if no previous default rules selected the packet. |
| This rule may also be deleted. |
| |
| \end{enumerate} |
| |
| Do not confuse routing tables with rules: rules point to routing tables, |
| several rules may refer to one routing table and some routing tables |
| may have no rules pointing to them. If the administrator deletes all the rules |
| referring to a table, the table is not used, but it still exists |
| and will disappear only after all the routes contained in it are deleted. |
| |
| |
| \paragraph{Rule attributes:} Each RPDB entry has additional |
| attributes. F.e.\ each rule has a pointer to some routing |
| table. NAT and masquerading rules have an attribute to select new IP |
| address to translate/masquerade. Besides that, rules have some |
| optional attributes, which routes have, namely \verb|realms|. |
| These values do not override those contained in the routing tables. They |
| are only used if the route did not select any attributes. |
| |
| |
| \paragraph{Rule types:} The RPDB may contain rules of the following |
| types: |
| \begin{itemize} |
| \item \verb|unicast| --- the rule prescribes to return the route found |
| in the routing table referenced by the rule. |
| \item \verb|blackhole| --- the rule prescribes to silently drop the packet. |
| \item \verb|unreachable| --- the rule prescribes to generate a ``Network |
| is unreachable'' error. |
| \item \verb|prohibit| --- the rule prescribes to generate |
| ``Communication is administratively prohibited'' error. |
| \item \verb|nat| --- the rule prescribes to translate the source address |
| of the IP packet into some other value. More about NAT is |
| in Appendix~\ref{ROUTE-NAT}, p.\pageref{ROUTE-NAT}. |
| \end{itemize} |
| |
| |
| \paragraph{Commands:} \verb|add|, \verb|delete| and \verb|show| |
| (or \verb|list|). |
| |
| \subsection{{\tt ip rule add} --- insert a new rule\\ |
| {\tt ip rule delete} --- delete a rule} |
| \label{IP-RULE-ADD} |
| |
| \paragraph{Abbreviations:} \verb|add|, \verb|a|; \verb|delete|, \verb|del|, |
| \verb|d|. |
| |
| \paragraph{Arguments:} |
| |
| \begin{itemize} |
| \item \verb|type TYPE| (default) |
| |
| --- the type of this rule. The list of valid types was given in the previous |
| subsection. |
| |
| \item \verb|from PREFIX| |
| |
| --- select the source prefix to match. |
| |
| \item \verb|to PREFIX| |
| |
| --- select the destination prefix to match. |
| |
| \item \verb|iif NAME| |
| |
| --- select the incoming device to match. If the interface is loopback, |
| the rule only matches packets originating from this host. This means that you |
| may create separate routing tables for forwarded and local packets and, |
| hence, completely segregate them. |
| |
| \item \verb|tos TOS| or \verb|dsfield TOS| |
| |
| --- select the TOS value to match. |
| |
| \item \verb|fwmark MARK| |
| |
| --- select the \verb|fwmark| value to match. |
| |
| \item \verb|priority PREFERENCE| |
| |
| --- the priority of this rule. Each rule should have an explicitly |
| set {\em unique\/} priority value. |
| \begin{NB} |
| Really, for historical reasons \verb|ip rule add| does not require a |
| priority value and allows them to be non-unique. |
| If the user does not supplied a priority, it is selected by the kernel. |
| If the user creates a rule with a priority value that |
| already exists, the kernel does not reject the request. It adds |
| the new rule before all old rules of the same priority. |
| |
| It is mistake in design, no more. And it will be fixed one day, |
| so do not rely on this feature. Use explicit priorities. |
| \end{NB} |
| |
| |
| \item \verb|table TABLEID| |
| |
| --- the routing table identifier to lookup if the rule selector matches. |
| |
| \item \verb|realms FROM/TO| |
| |
| --- Realms to select if the rule matched and the routing table lookup |
| succeeded. Realm \verb|TO| is only used if the route did not select |
| any realm. |
| |
| \item \verb|nat ADDRESS| |
| |
| --- The base of the IP address block to translate (for source addresses). |
| The \verb|ADDRESS| may be either the start of the block of NAT addresses |
| (selected by NAT routes) or in linux-2.2 a local host address (or even zero). |
| In the last case the router does not translate the packets, |
| but masquerades them to this address; this feature disappered in 2.4. |
| More about NAT is in Appendix~\ref{ROUTE-NAT}, |
| p.\pageref{ROUTE-NAT}. |
| |
| \end{itemize} |
| |
| \paragraph{Warning:} Changes to the RPDB made with these commands |
| do not become active immediately. It is assumed that after |
| a script finishes a batch of updates, it flushes the routing cache |
| with \verb|ip route flush cache|. |
| |
| \paragraph{Examples:} |
| \begin{itemize} |
| \item Route packets with source addresses from 192.203.80/24 |
| according to routing table \verb|inr.ruhep|: |
| \begin{verbatim} |
| ip ru add from 192.203.80.0/24 table inr.ruhep prio 220 |
| \end{verbatim} |
| |
| \item Translate packet source address 193.233.7.83 into 192.203.80.144 |
| and route it according to table \#1 (actually, it is \verb|inr.ruhep|): |
| \begin{verbatim} |
| ip ru add from 193.233.7.83 nat 192.203.80.144 table 1 prio 320 |
| \end{verbatim} |
| |
| \item Delete the unused default rule: |
| \begin{verbatim} |
| ip ru del prio 32767 |
| \end{verbatim} |
| |
| \end{itemize} |
| |
| |
| |
| \subsection{{\tt ip rule show} --- list rules} |
| \label{IP-RULE-SHOW} |
| |
| \paragraph{Abbreviations:} \verb|show|, \verb|list|, \verb|sh|, \verb|ls|, \verb|l|. |
| |
| |
| \paragraph{Arguments:} Good news, this is one command that has no arguments. |
| |
| \paragraph{Output format:} |
| |
| \begin{verbatim} |
| kuznet@amber:~ $ ip ru ls |
| 0: from all lookup local |
| 200: from 192.203.80.0/24 to 193.233.7.0/24 lookup main |
| 210: from 192.203.80.0/24 to 192.203.80.0/24 lookup main |
| 220: from 192.203.80.0/24 lookup inr.ruhep realms inr.ruhep/radio-msu |
| 300: from 193.233.7.83 to 193.233.7.0/24 lookup main |
| 310: from 193.233.7.83 to 192.203.80.0/24 lookup main |
| 320: from 193.233.7.83 lookup inr.ruhep map-to 192.203.80.144 |
| 32766: from all lookup main |
| kuznet@amber:~ $ |
| \end{verbatim} |
| |
| In the first column is the rule priority value followed |
| by a colon. Then the selectors follow. Each key is prefixed |
| with the same keyword that was used to create the rule. |
| |
| The keyword \verb|lookup| is followed by a routing table identifier, |
| as it is recorded in the file \verb|/etc/iproute2/rt_tables|. |
| |
| If the rule does NAT (f.e.\ rule \#320), it is shown by the keyword |
| \verb|map-to| followed by the start of the block of addresses to map. |
| |
| The sense of this example is pretty simple. The prefixes |
| 192.203.80.0/24 and 193.233.7.0/24 form the internal network, but |
| they are routed differently when the packets leave it. |
| Besides that, the host 193.233.7.83 is translated into |
| another prefix to look like 192.203.80.144 when talking |
| to the outer world. |
| |
| |
| |
| \section{{\tt ip maddress} --- multicast addresses management} |
| \label{IP-MADDR} |
| |
| \paragraph{Object:} \verb|maddress| objects are multicast addresses. |
| |
| \paragraph{Commands:} \verb|add|, \verb|delete|, \verb|show| (or \verb|list|). |
| |
| \subsection{{\tt ip maddress show} --- list multicast addresses} |
| |
| \paragraph{Abbreviations:} \verb|show|, \verb|list|, \verb|sh|, \verb|ls|, \verb|l|. |
| |
| \paragraph{Arguments:} |
| |
| \begin{itemize} |
| |
| \item \verb|dev NAME| (default) |
| |
| --- the device name. |
| |
| \end{itemize} |
| |
| \paragraph{Output format:} |
| |
| \begin{verbatim} |
| kuznet@alisa:~ $ ip maddr ls dummy |
| 2: dummy |
| link 33:33:00:00:00:01 |
| link 01:00:5e:00:00:01 |
| inet 224.0.0.1 users 2 |
| inet6 ff02::1 |
| kuznet@alisa:~ $ |
| \end{verbatim} |
| |
| The first line of the output shows the interface index and its name. |
| Then the multicast address list follows. Each line starts with the |
| protocol identifier. The word \verb|link| denotes a link layer |
| multicast addresses. |
| |
| If a multicast address has more than one user, the number |
| of users is shown after the \verb|users| keyword. |
| |
| One additional feature not present in the example above |
| is the \verb|static| flag, which indicates that the address was joined |
| with \verb|ip maddr add|. See the following subsection. |
| |
| |
| |
| \subsection{{\tt ip maddress add} --- add a multicast address\\ |
| {\tt ip maddress delete} --- delete a multicast address} |
| |
| \paragraph{Abbreviations:} \verb|add|, \verb|a|; \verb|delete|, \verb|del|, \verb|d|. |
| |
| \paragraph{Description:} these commands attach/detach |
| a static link layer multicast address to listen on the interface. |
| Note that it is impossible to join protocol multicast groups |
| statically. This command only manages link layer addresses. |
| |
| |
| \paragraph{Arguments:} |
| |
| \begin{itemize} |
| \item \verb|address LLADDRESS| (default) |
| |
| --- the link layer multicast address. |
| |
| \item \verb|dev NAME| |
| |
| --- the device to join/leave this multicast address. |
| |
| \end{itemize} |
| |
| |
| \paragraph{Example:} Let us continue with the example from the previous subsection. |
| |
| \begin{verbatim} |
| netadm@alisa:~ # ip maddr add 33:33:00:00:00:01 dev dummy |
| netadm@alisa:~ # ip -0 maddr ls dummy |
| 2: dummy |
| link 33:33:00:00:00:01 users 2 static |
| link 01:00:5e:00:00:01 |
| netadm@alisa:~ # ip maddr del 33:33:00:00:00:01 dev dummy |
| \end{verbatim} |
| |
| \begin{NB} |
| Neither \verb|ip| nor the kernel check for multicast address validity. |
| Particularly, this means that you can try to load a unicast address |
| instead of a multicast address. Most drivers will ignore such addresses, |
| but several (f.e.\ Tulip) will intern it to their on-board filter. |
| The effects may be strange. Namely, the addresses become additional |
| local link addresses and, if you loaded the address of another host |
| to the router, wait for duplicated packets on the wire. |
| It is not a bug, but rather a hole in the API and intra-kernel interfaces. |
| This feature is really more useful for traffic monitoring, but using it |
| with Linux-2.2 you {\em have to\/} be sure that the host is not |
| a router and, especially, that it is not a transparent proxy or masquerading |
| agent. |
| \end{NB} |
| |
| |
| |
| \section{{\tt ip mroute} --- multicast routing cache management} |
| \label{IP-MROUTE} |
| |
| \paragraph{Abbreviations:} \verb|mroute|, \verb|mr|. |
| |
| \paragraph{Object:} \verb|mroute| objects are multicast routing cache |
| entries created by a user level mrouting daemon |
| (f.e.\ \verb|pimd| or \verb|mrouted|). |
| |
| Due to the limitations of the current interface to the multicast routing |
| engine, it is impossible to change \verb|mroute| objects administratively, |
| so we may only display them. This limitation will be removed |
| in the future. |
| |
| \paragraph{Commands:} \verb|show| (or \verb|list|). |
| |
| |
| \subsection{{\tt ip mroute show} --- list mroute cache entries} |
| |
| \paragraph{Abbreviations:} \verb|show|, \verb|list|, \verb|sh|, \verb|ls|, \verb|l|. |
| |
| \paragraph{Arguments:} |
| |
| \begin{itemize} |
| \item \verb|to PREFIX| (default) |
| |
| --- the prefix selecting the destination multicast addresses to list. |
| |
| |
| \item \verb|iif NAME| |
| |
| --- the interface on which multicast packets are received. |
| |
| |
| \item \verb|from PREFIX| |
| |
| --- the prefix selecting the IP source addresses of the multicast route. |
| |
| |
| \end{itemize} |
| |
| \paragraph{Output format:} |
| |
| \begin{verbatim} |
| kuznet@amber:~ $ ip mroute ls |
| (193.232.127.6, 224.0.1.39) Iif: unresolved |
| (193.232.244.34, 224.0.1.40) Iif: unresolved |
| (193.233.7.65, 224.66.66.66) Iif: eth0 Oifs: pimreg |
| kuznet@amber:~ $ |
| \end{verbatim} |
| |
| Each line shows one (S,G) entry in the multicast routing cache, |
| where S is the source address and G is the multicast group. \verb|Iif| is |
| the interface on which multicast packets are expected to arrive. |
| If the word \verb|unresolved| is there instead of the interface name, |
| it means that the routing daemon still hasn't resolved this entry. |
| The keyword \verb|oifs| is followed by a list of output interfaces, separated |
| by spaces. If a multicast routing entry is created with non-trivial |
| TTL scope, administrative distances are appended to the device names |
| in the \verb|oifs| list. |
| |
| \paragraph{Statistics:} The \verb|-statistics| option also prints the |
| number of packets and bytes forwarded along this route and |
| the number of packets that arrived on the wrong interface, if this number is not zero. |
| |
| \begin{verbatim} |
| kuznet@amber:~ $ ip -s mr ls 224.66/16 |
| (193.233.7.65, 224.66.66.66) Iif: eth0 Oifs: pimreg |
| 9383 packets, 300256 bytes |
| kuznet@amber:~ $ |
| \end{verbatim} |
| |
| |
| \section{{\tt ip tunnel} --- tunnel configuration} |
| \label{IP-TUNNEL} |
| |
| \paragraph{Abbreviations:} \verb|tunnel|, \verb|tunl|. |
| |
| \paragraph{Object:} \verb|tunnel| objects are tunnels, encapsulating |
| packets in IPv4 packets and then sending them over the IP infrastructure. |
| |
| \paragraph{Commands:} \verb|add|, \verb|delete|, \verb|change|, \verb|show| |
| (or \verb|list|). |
| |
| \paragraph{See also:} A more informal discussion of tunneling |
| over IP and the \verb|ip tunnel| command can be found in~\cite{IP-TUNNELS}. |
| |
| \subsection{{\tt ip tunnel add} --- add a new tunnel\\ |
| {\tt ip tunnel change} --- change an existing tunnel\\ |
| {\tt ip tunnel delete} --- destroy a tunnel} |
| |
| \paragraph{Abbreviations:} \verb|add|, \verb|a|; \verb|change|, \verb|chg|; |
| \verb|delete|, \verb|del|, \verb|d|. |
| |
| |
| \paragraph{Arguments:} |
| |
| \begin{itemize} |
| |
| \item \verb|name NAME| (default) |
| |
| --- select the tunnel device name. |
| |
| \item \verb|mode MODE| |
| |
| --- set the tunnel mode. Three modes are currently available: |
| \verb|ipip|, \verb|sit| and \verb|gre|. |
| |
| \item \verb|remote ADDRESS| |
| |
| --- set the remote endpoint of the tunnel. |
| |
| \item \verb|local ADDRESS| |
| |
| --- set the fixed local address for tunneled packets. |
| It must be an address on another interface of this host. |
| |
| \item \verb|ttl N| |
| |
| --- set a fixed TTL \verb|N| on tunneled packets. |
| \verb|N| is a number in the range 1--255. 0 is a special value |
| meaning that packets inherit the TTL value. |
| The default value is: \verb|inherit|. |
| |
| \item \verb|tos T| or \verb|dsfield T| |
| |
| --- set a fixed TOS \verb|T| on tunneled packets. |
| The default value is: \verb|inherit|. |
| |
| |
| |
| \item \verb|dev NAME| |
| |
| --- bind the tunnel to the device \verb|NAME| so that |
| tunneled packets will only be routed via this device and will |
| not be able to escape to another device when the route to endpoint changes. |
| |
| \item \verb|nopmtudisc| |
| |
| --- disable Path MTU Discovery on this tunnel. |
| It is enabled by default. Note that a fixed ttl is incompatible |
| with this option: tunnelling with a fixed ttl always makes pmtu discovery. |
| |
| \item \verb|key K|, \verb|ikey K|, \verb|okey K| |
| |
| --- (only GRE tunnels) use keyed GRE with key \verb|K|. \verb|K| is |
| either a number or an IP address-like dotted quad. |
| The \verb|key| parameter sets the key to use in both directions. |
| The \verb|ikey| and \verb|okey| parameters set different keys for input and output. |
| |
| |
| \item \verb|csum|, \verb|icsum|, \verb|ocsum| |
| |
| --- (only GRE tunnels) generate/require checksums for tunneled packets. |
| The \verb|ocsum| flag calculates checksums for outgoing packets. |
| The \verb|icsum| flag requires that all input packets have the correct |
| checksum. The \verb|csum| flag is equivalent to the combination |
| ``\verb|icsum| \verb|ocsum|''. |
| |
| \item \verb|seq|, \verb|iseq|, \verb|oseq| |
| |
| --- (only GRE tunnels) serialize packets. |
| The \verb|oseq| flag enables sequencing of outgoing packets. |
| The \verb|iseq| flag requires that all input packets are serialized. |
| The \verb|seq| flag is equivalent to the combination ``\verb|iseq| \verb|oseq|''. |
| |
| \begin{NB} |
| I think this option does not |
| work. At least, I did not test it, did not debug it and |
| do not even understand how it is supposed to work or for what |
| purpose Cisco planned to use it. Do not use it. |
| \end{NB} |
| |
| |
| \end{itemize} |
| |
| \paragraph{Example:} Create a pointopoint IPv6 tunnel with maximal TTL of 32. |
| \begin{verbatim} |
| netadm@amber:~ # ip tunl add Cisco mode sit remote 192.31.7.104 \ |
| local 192.203.80.142 ttl 32 |
| \end{verbatim} |
| |
| \subsection{{\tt ip tunnel show} --- list tunnels} |
| |
| \paragraph{Abbreviations:} \verb|show|, \verb|list|, \verb|sh|, \verb|ls|, \verb|l|. |
| |
| |
| \paragraph{Arguments:} None. |
| |
| \paragraph{Output format:} |
| \begin{verbatim} |
| kuznet@amber:~ $ ip tunl ls Cisco |
| Cisco: ipv6/ip remote 192.31.7.104 local 192.203.80.142 ttl 32 |
| kuznet@amber:~ $ |
| \end{verbatim} |
| The line starts with the tunnel device name followed by a colon. |
| Then the tunnel mode follows. The parameters of the tunnel are listed |
| with the same keywords that were used when creating the tunnel. |
| |
| \paragraph{Statistics:} |
| |
| \begin{verbatim} |
| kuznet@amber:~ $ ip -s tunl ls Cisco |
| Cisco: ipv6/ip remote 192.31.7.104 local 192.203.80.142 ttl 32 |
| RX: Packets Bytes Errors CsumErrs OutOfSeq Mcasts |
| 12566 1707516 0 0 0 0 |
| TX: Packets Bytes Errors DeadLoop NoRoute NoBufs |
| 13445 1879677 0 0 0 0 |
| kuznet@amber:~ $ |
| \end{verbatim} |
| Essentially, these numbers are the same as the numbers |
| printed with {\tt ip -s link show} |
| (sec.\ref{IP-LINK-SHOW}, p.\pageref{IP-LINK-SHOW}) but the tags are different |
| to reflect that they are tunnel specific. |
| \begin{itemize} |
| \item \verb|CsumErrs| --- the total number of packets dropped |
| because of checksum failures for a GRE tunnel with checksumming enabled. |
| \item \verb|OutOfSeq| --- the total number of packets dropped |
| because they arrived out of sequence for a GRE tunnel with |
| serialization enabled. |
| \item \verb|Mcasts| --- the total number of multicast packets |
| received on a broadcast GRE tunnel. |
| \item \verb|DeadLoop| --- the total number of packets which were not |
| transmitted because the tunnel is looped back to itself. |
| \item \verb|NoRoute| --- the total number of packets which were not |
| transmitted because there is no IP route to the remote endpoint. |
| \item \verb|NoBufs| --- the total number of packets which were not |
| transmitted because the kernel failed to allocate a buffer. |
| \end{itemize} |
| |
| |
| \section{{\tt ip monitor} and {\tt rtmon} --- state monitoring} |
| \label{IP-MONITOR} |
| |
| The \verb|ip| utility can monitor the state of devices, addresses |
| and routes continuously. This option has a slightly different format. |
| Namely, |
| the \verb|monitor| command is the first in the command line and then |
| the object list follows: |
| \begin{verbatim} |
| ip monitor [ file FILE ] [ all | OBJECT-LIST ] |
| \end{verbatim} |
| \verb|OBJECT-LIST| is the list of object types that we want to monitor. |
| It may contain \verb|link|, \verb|address| and \verb|route|. |
| If no \verb|file| argument is given, \verb|ip| opens RTNETLINK, |
| listens on it and dumps state changes in the format described |
| in previous sections. |
| |
| If a file name is given, it does not listen on RTNETLINK, |
| but opens the file containing RTNETLINK messages saved in binary format |
| and dumps them. Such a history file can be generated with the |
| \verb|rtmon| utility. This utility has a command line syntax similar to |
| \verb|ip monitor|. |
| Ideally, \verb|rtmon| should be started before |
| the first network configuration command is issued. F.e.\ if |
| you insert: |
| \begin{verbatim} |
| rtmon file /var/log/rtmon.log |
| \end{verbatim} |
| in a startup script, you will be able to view the full history |
| later. |
| |
| Certainly, it is possible to start \verb|rtmon| at any time. |
| It prepends the history with the state snapshot dumped at the moment |
| of starting. |
| |
| |
| \section{Route realms and policy propagation, {\tt rtacct}} |
| \label{RT-REALMS} |
| |
| On routers using OSPF ASE or, especially, the BGP protocol, routing |
| tables may be huge. If we want to classify or to account for the packets |
| per route, we will have to keep lots of information. Even worse, if we |
| want to distinguish the packets not only by their destination, but |
| also by their source, the task gets quadratic complexity and its solution |
| is physically impossible. |
| |
| One approach to propagating the policy from routing protocols |
| to the forwarding engine has been proposed in~\cite{IOS-BGP-PP}. |
| Essentially, Cisco Policy Propagation via BGP is based on the fact |
| that dedicated routers all have the RIB (Routing Information Base) |
| close to the forwarding engine, so policy routing rules can |
| check all the route attributes, including ASPATH information |
| and community strings. |
| |
| The Linux architecture, splitting the RIB (maintained by a user level |
| daemon) and the kernel based FIB (Forwarding Information Base), |
| does not allow such a simple approach. |
| |
| It is to our fortune because there is another solution |
| which allows even more flexible policy and richer semantics. |
| |
| Namely, routes can be clustered together in user space, based on their |
| attributes. F.e.\ a BGP router knows route ASPATH, its community; |
| an OSPF router knows the route tag or its area. The administrator, when adding |
| routes manually, also knows their nature. Providing that the number of such |
| aggregates (we call them {\em realms\/}) is low, the task of full |
| classification both by source and destination becomes quite manageable. |
| |
| So each route may be assigned to a realm. It is assumed that |
| this identification is made by a routing daemon, but static routes |
| can also be handled manually with \verb|ip route| (see sec.\ref{IP-ROUTE}, |
| p.\pageref{IP-ROUTE}). |
| \begin{NB} |
| There is a patch to \verb|gated|, allowing classification of routes |
| to realms with all the set of policy rules implemented in \verb|gated|: |
| by prefix, by ASPATH, by origin, by tag etc. |
| \end{NB} |
| |
| To facilitate the construction (f.e.\ in case the routing |
| daemon is not aware of realms), missing realms may be completed |
| with routing policy rules, see sec.~\ref{IP-RULE}, p.\pageref{IP-RULE}. |
| |
| For each packet the kernel calculates a tuple of realms: source realm |
| and destination realm, using the following algorithm: |
| |
| \begin{enumerate} |
| \item If the route has a realm, the destination realm of the packet is set to it. |
| \item If the rule has a source realm, the source realm of the packet is set to it. |
| If the destination realm was not inherited from the route and the rule has a destination realm, |
| it is also set. |
| \item If at least one of the realms is still unknown, the kernel finds |
| the reversed route to the source of the packet. |
| \item If the source realm is still unknown, get it from the reversed route. |
| \item If one of the realms is still unknown, swap the realms of reversed |
| routes and apply step 2 again. |
| \end{enumerate} |
| |
| After this procedure is completed we know what realm the packet |
| arrived from and the realm where it is going to propagate to. |
| If some of the realms are unknown, they are initialized to zero |
| (or realm \verb|unknown|). |
| |
| The main application of realms is the TC \verb|route| classifier~\cite{TC-CREF}, |
| where they are used to help assign packets to traffic classes, |
| to account, police and schedule them according to this |
| classification. |
| |
| A much simpler but still very useful application is incoming packet |
| accounting by realms. The kernel gathers a packet statistics summary |
| which can be viewed with the \verb|rtacct| utility. |
| \begin{verbatim} |
| kuznet@amber:~ $ rtacct russia |
| Realm BytesTo PktsTo BytesFrom PktsFrom |
| russia 20576778 169176 47080168 153805 |
| kuznet@amber:~ $ |
| \end{verbatim} |
| This shows that this router received 153805 packets from |
| the realm \verb|russia| and forwarded 169176 packets to \verb|russia|. |
| The realm \verb|russia| consists of routes with ASPATHs not leaving |
| Russia. |
| |
| Note that locally originating packets are not accounted here, |
| \verb|rtacct| shows incoming packets only. Using the \verb|route| |
| classifier (see~\cite{TC-CREF}) you can get even more detailed |
| accounting information about outgoing packets, optionally |
| summarizing traffic not only by source or destination, but |
| by any pair of source and destination realms. |
| |
| |
| \begin{thebibliography}{99} |
| \addcontentsline{toc}{section}{References} |
| \bibitem{RFC-NDISC} T.~Narten, E.~Nordmark, W.~Simpson. |
| ``Neighbor Discovery for IP Version 6 (IPv6)'', RFC-2461. |
| |
| \bibitem{RFC-ADDRCONF} S.~Thomson, T.~Narten. |
| ``IPv6 Stateless Address Autoconfiguration'', RFC-2462. |
| |
| \bibitem{RFC1812} F.~Baker. |
| ``Requirements for IP Version 4 Routers'', RFC-1812. |
| |
| \bibitem{RFC1122} R.~T.~Braden. |
| ``Requirements for Internet hosts --- communication layers'', RFC-1122. |
| |
| \bibitem{IOS} ``Cisco IOS Release 12.0 Network Protocols |
| Command Reference, Part 1'' and |
| ``Cisco IOS Release 12.0 Quality of Service Solutions |
| Configuration Guide: Configuring Policy-Based Routing'',\\ |
| http://www.cisco.com/univercd/cc/td/doc/product/software/ios120. |
| |
| \bibitem{IP-TUNNELS} A.~N.~Kuznetsov. |
| ``Tunnels over IP in Linux-2.2'', \\ |
| In: {\tt ftp://ftp.inr.ac.ru/ip-routing/iproute2-current.tar.gz}. |
| |
| \bibitem{TC-CREF} A.~N.~Kuznetsov. ``TC Command Reference'',\\ |
| In: {\tt ftp://ftp.inr.ac.ru/ip-routing/iproute2-current.tar.gz}. |
| |
| \bibitem{IOS-BGP-PP} ``Cisco IOS Release 12.0 Quality of Service Solutions |
| Configuration Guide: Configuring QoS Policy Propagation via |
| Border Gateway Protocol'',\\ |
| http://www.cisco.com/univercd/cc/td/doc/product/software/ios120. |
| |
| \bibitem{RFC-DHCP} R.~Droms. |
| ``Dynamic Host Configuration Protocol.'', RFC-2131 |
| |
| \bibitem{RFC2414} M.~Allman, S.~Floyd, C.~Partridge. |
| ``Increasing TCP's Initial Window'', RFC-2414. |
| |
| \end{thebibliography} |
| |
| |
| |
| |
| \appendix |
| \addcontentsline{toc}{section}{Appendix} |
| |
| \section{Source address selection} |
| \label{ADDR-SEL} |
| |
| When a host creates an IP packet, it must select some source |
| address. Correct source address selection is a critical procedure, |
| because it gives the receiver the information needed to deliver a |
| reply. If the source is selected incorrectly, in the best case, |
| the backward path may appear different to the forward one which |
| is harmful for performance. In the worst case, when the addresses |
| are administratively scoped, the reply may be lost entirely. |
| |
| Linux-2.2 selects source addresses using the following algorithm: |
| |
| \begin{itemize} |
| \item |
| The application may select a source address explicitly with \verb|bind(2)| |
| syscall or supplying it to \verb|sendmsg(2)| via the ancillary data object |
| \verb|IP_PKTINFO|. In this case the kernel only checks the validity |
| of the address and never tries to ``improve'' an incorrect user choice, |
| generating an error instead. |
| \begin{NB} |
| Never say ``Never''. The sysctl option \verb|ip_dynaddr| breaks |
| this axiom. It has been made deliberately with the purpose |
| of automatically reselecting the address on hosts with dynamic dial-out interfaces. |
| However, this hack {\em must not\/} be used on multihomed hosts |
| and especially on routers: it would break them. |
| \end{NB} |
| |
| |
| \item Otherwise, IP routing tables can contain an explicit source |
| address hint for this destination. The hint is set with the \verb|src| parameter |
| to the \verb|ip route| command, sec.\ref{IP-ROUTE}, p.\pageref{IP-ROUTE}. |
| |
| |
| \item Otherwise, the kernel searches through the list of addresses |
| attached to the interface through which the packets will be routed. |
| The search strategies are different for IP and IPv6. Namely: |
| |
| \begin{itemize} |
| \item IPv6 searches for the first valid, not deprecated address |
| with the same scope as the destination. |
| |
| \item IP searches for the first valid address with a scope wider |
| than the scope of the destination but it prefers addresses |
| which fall to the same subnet as the nexthop of the route |
| to the destination. Unlike IPv6, the scopes of IPv4 destinations |
| are not encoded in their addresses but are supplied |
| in routing tables instead (the \verb|scope| parameter to the \verb|ip route| command, |
| sec.\ref{IP-ROUTE}, p.\pageref{IP-ROUTE}). |
| |
| \end{itemize} |
| |
| |
| \item Otherwise, if the scope of the destination is \verb|link| or \verb|host|, |
| the algorithm fails and returns a zero source address. |
| |
| \item Otherwise, all interfaces are scanned to search for an address |
| with an appropriate scope. The loopback device \verb|lo| is always the first |
| in the search list, so that if an address with global scope (not 127.0.0.1!) |
| is configured on loopback, it is always preferred. |
| |
| \end{itemize} |
| |
| |
| \section{Proxy ARP/NDISC} |
| \label{PROXY-NEIGH} |
| |
| Routers may answer ARP/NDISC solicitations on behalf of other hosts. |
| In Linux-2.2 proxy ARP on an interface may be enabled |
| by setting the kernel \verb|sysctl| variable |
| \verb|/proc/sys/net/ipv4/conf/<dev>/proxy_arp| to 1. After this, the router |
| starts to answer ARP requests on the interface \verb|<dev>|, provided |
| the route to the requested destination does {\em not\/} go back via the same |
| device. |
| |
| The variable \verb|/proc/sys/net/ipv4/conf/all/proxy_arp| enables proxy |
| ARP on all the IP devices. |
| |
| However, this approach fails in the case of IPv6 because the router |
| must join the solicited node multicast address to listen for the corresponding |
| NDISC queries. It means that proxy NDISC is possible only on a per destination |
| basis. |
| |
| Logically, proxy ARP/NDISC is not a kernel task. It can easily be implemented |
| in user space. However, similar functionality was present in BSD kernels |
| and in Linux-2.0, so we have to preserve it at least to the extent that |
| is standardized in BSD. |
| \begin{NB} |
| Linux-2.0 ARP had a feature called {\em subnet\/} proxy ARP. |
| It is replaced with the sysctl flag in Linux-2.2. |
| \end{NB} |
| |
| |
| The \verb|ip| utility provides a way to manage proxy ARP/NDISC |
| with the \verb|ip neigh| command, namely: |
| \begin{verbatim} |
| ip neigh add proxy ADDRESS [ dev NAME ] |
| \end{verbatim} |
| adds a new proxy ARP/NDISC record and |
| \begin{verbatim} |
| ip neigh del proxy ADDRESS [ dev NAME ] |
| \end{verbatim} |
| deletes it. |
| |
| If the name of the device is not given, the router will answer solicitations |
| for address \verb|ADDRESS| on all devices, otherwise it will only serve |
| the device \verb|NAME|. Even if the proxy entry is created with |
| \verb|ip neigh|, the router {\em will not\/} answer a query if the route |
| to the destination goes back via the interface from which the solicitation |
| was received. |
| |
| It is important to emphasize that proxy entries have {\em no\/} |
| parameters other than these (IP/IPv6 address and optional device). |
| Particularly, the entry does not store any link layer address. |
| It always advertises the station address of the interface |
| on which it sends advertisements (i.e. it's own station address). |
| |
| \section{Route NAT status} |
| \label{ROUTE-NAT} |
| |
| NAT (or ``Network Address Translation'') remaps some parts |
| of the IP address space into other ones. Linux-2.2 route NAT is supposed |
| to be used to facilitate policy routing by rewriting addresses |
| to other routing domains or to help while renumbering sites |
| to another prefix. |
| |
| \paragraph{What it is not:} |
| It is necessary to emphasize that {\em it is not supposed\/} |
| to be used to compress address space or to split load. |
| This is not missing functionality but a design principle. |
| Route NAT is {\em stateless\/}. It does not hold any state |
| about translated sessions. This means that it handles any number |
| of sessions flawlessly. But it also means that it is {\em static\/}. |
| It cannot detect the moment when the last TCP client stops |
| using an address. For the same reason, it will not help to split |
| load between several servers. |
| \begin{NB} |
| It is a pretty commonly held belief that it is useful to split load between |
| several servers with NAT. This is a mistake. All you get from this |
| is the requirement that the router keep the state of all the TCP connections |
| going via it. Well, if the router is so powerful, run apache on it. 8) |
| \end{NB} |
| |
| The second feature: it does not touch packet payload, |
| does not try to ``improve'' broken protocols by looking |
| through its data and mangling it. It mangles IP addresses, |
| only IP addresses and nothing but IP addresses. |
| This also, is not missing any functionality. |
| |
| To resume: if you need to compress address space or keep |
| active FTP clients happy, your choice is not route NAT but masquerading, |
| port forwarding, NAPT etc. |
| \begin{NB} |
| By the way, you may also want to look at |
| http://www.suse.com/\~mha/HyperNews/get/linux-ip-nat.html |
| \end{NB} |
| |
| |
| \paragraph{How it works.} |
| Some part of the address space is reserved for dummy addresses |
| which will look for all the world like some host addresses |
| inside your network. No other hosts may use these addresses, |
| however other routers may also be configured to translate them. |
| \begin{NB} |
| A great advantage of route NAT is that it may be used not |
| only in stub networks but in environments with arbitrarily complicated |
| structure. It does not firewall, it {\em forwards.} |
| \end{NB} |
| These addresses are selected by the \verb|ip route| command |
| (sec.\ref{IP-ROUTE-ADD}, p.\pageref{IP-ROUTE-ADD}). F.e.\ |
| \begin{verbatim} |
| ip route add nat 192.203.80.144 via 193.233.7.83 |
| \end{verbatim} |
| states that the single address 192.203.80.144 is a dummy NAT address. |
| For all the world it looks like a host address inside our network. |
| For neighbouring hosts and routers it looks like the local address |
| of the translating router. The router answers ARP for it, advertises |
| this address as routed via it, {\em et al\/}. When the router |
| receives a packet destined for 192.203.80.144, it replaces |
| this address with 193.233.7.83 which is the address of some real |
| host and forwards the packet. If you need to remap |
| blocks of addresses, you may use a command like: |
| \begin{verbatim} |
| ip route add nat 192.203.80.192/26 via 193.233.7.64 |
| \end{verbatim} |
| This command will map a block of 63 addresses 192.203.80.192-255 to |
| 193.233.7.64-127. |
| |
| When an internal host (193.233.7.83 in the example above) |
| sends something to the outer world and these packets are forwarded |
| by our router, it should translate the source address 193.233.7.83 |
| into 192.203.80.144. This task is solved by setting a special |
| policy rule (sec.\ref{IP-RULE-ADD}, p.\pageref{IP-RULE-ADD}): |
| \begin{verbatim} |
| ip rule add prio 320 from 193.233.7.83 nat 192.203.80.144 |
| \end{verbatim} |
| This rule says that the source address 193.233.7.83 |
| should be translated into 192.203.80.144 before forwarding. |
| It is important that the address after the \verb|nat| keyword |
| is some NAT address, declared by {\tt ip route add nat}. |
| If it is just a random address the router will not map to it. |
| \begin{NB} |
| The exception is when the address is a local address of this |
| router (or 0.0.0.0) and masquerading is configured in the linux-2.2 |
| kernel. In this case the router will masquerade the packets as this address. |
| If 0.0.0.0 is selected, the result is equivalent to one |
| obtained with firewalling rules. Otherwise, you have the way |
| to order Linux to masquerade to this fixed address. |
| NAT mechanism used in linux-2.4 is more flexible than |
| masquerading, so that this feature has lost meaning and disabled. |
| \end{NB} |
| |
| If the network has non-trivial internal structure, it is |
| useful and even necessary to add rules disabling translation |
| when a packet does not leave this network. Let us return to the |
| example from sec.\ref{IP-RULE-SHOW} (p.\pageref{IP-RULE-SHOW}). |
| \begin{verbatim} |
| 300: from 193.233.7.83 to 193.233.7.0/24 lookup main |
| 310: from 193.233.7.83 to 192.203.80.0/24 lookup main |
| 320: from 193.233.7.83 lookup inr.ruhep map-to 192.203.80.144 |
| \end{verbatim} |
| This block of rules causes normal forwarding when |
| packets from 193.233.7.83 do not leave networks 193.233.7/24 |
| and 192.203.80/24. Also, if the \verb|inr.ruhep| table does not |
| contain a route to the destination (which means that the routing |
| domain owning addresses from 192.203.80/24 is dead), no translation |
| will occur. Otherwise, the packets are translated. |
| |
| \paragraph{How to only translate selected ports:} |
| If you only want to translate selected ports (f.e.\ http) |
| and leave the rest intact, you may use \verb|ipchains| |
| to \verb|fwmark| a class of packets. |
| Suppose you did and all the packets from 193.233.7.83 |
| destined for port 80 are marked with marker 0x1234 in input fwchain. |
| In this case you may replace rule \#320 with: |
| \begin{verbatim} |
| 320: from 193.233.7.83 fwmark 1234 lookup main map-to 192.203.80.144 |
| \end{verbatim} |
| and translation will only be enabled for outgoing http requests. |
| |
| \section{Example: minimal host setup} |
| \label{EXAMPLE-SETUP} |
| |
| The following script gives an example of a fault safe |
| setup of IP (and IPv6, if it is compiled into the kernel) |
| in the common case of a node attached to a single broadcast |
| network. A more advanced script, which may be used both on multihomed |
| hosts and on routers, is described in the following |
| section. |
| |
| The utilities used in the script may be found in the |
| directory ftp://ftp.inr.ac.ru/ip-routing/: |
| \begin{enumerate} |
| \item \verb|ip| --- package \verb|iproute2|. |
| \item \verb|arping| --- package \verb|iputils|. |
| \item \verb|rdisc| --- package \verb|iputils|. |
| \end{enumerate} |
| \begin{NB} |
| It also refers to a DHCP client, \verb|dhcpcd|. I should refrain from |
| recommending a good DHCP client to use. All that I can |
| say is that ISC \verb|dhcp-2.0b1pl6| patched with the patch that |
| can be found in the \verb|dhcp.bootp.rarp| subdirectory of |
| the same ftp site {\em does\/} work, |
| at least on Ethernet and Token Ring. |
| \end{NB} |
| |
| \begin{verbatim} |
| #! /bin/bash |
| \end{verbatim} |
| \begin{flushleft} |
| \# {\bf Usage: \verb|ifone ADDRESS[/PREFIX-LENGTH] [DEVICE]|}\\ |
| \# {\bf Parameters:}\\ |
| \# \$1 --- Static IP address, optionally followed by prefix length.\\ |
| \# \$2 --- Device name. If it is missing, \verb|eth0| is asssumed.\\ |
| \# F.e. \verb|ifone 193.233.7.90| |
| \end{flushleft} |
| \begin{verbatim} |
| dev=$2 |
| : ${dev:=eth0} |
| ipaddr= |
| \end{verbatim} |
| \# Parse IP address, splitting prefix length. |
| \begin{verbatim} |
| if [ "$1" != "" ]; then |
| ipaddr=${1%/*} |
| if [ "$1" != "$ipaddr" ]; then |
| pfxlen=${1#*/} |
| fi |
| : ${pfxlen:=24} |
| fi |
| pfx="${ipaddr}/${pfxlen}" |
| \end{verbatim} |
| |
| \begin{flushleft} |
| \# {\bf Step 0} --- enable loopback.\\ |
| \#\\ |
| \# This step is necessary on any networked box before attempt\\ |
| \# to configure any other device.\\ |
| \end{flushleft} |
| \begin{verbatim} |
| ip link set up dev lo |
| ip addr add 127.0.0.1/8 dev lo brd + scope host |
| \end{verbatim} |
| \begin{flushleft} |
| \# IPv6 autoconfigure themself on loopback.\\ |
| \#\\ |
| \# If user gave loopback as device, we add the address as alias and exit. |
| \end{flushleft} |
| \begin{verbatim} |
| if [ "$dev" = "lo" ]; then |
| if [ "$ipaddr" != "" -a "$ipaddr" != "127.0.0.1" ]; then |
| ip address add $ipaddr dev $dev |
| exit $? |
| fi |
| exit 0 |
| fi |
| \end{verbatim} |
| |
| \noindent\# {\bf Step 1} --- enable device \verb|$dev| |
| |
| \begin{verbatim} |
| if ! ip link set up dev $dev ; then |
| echo "Cannot enable interface $dev. Aborting." 1>&2 |
| exit 1 |
| fi |
| \end{verbatim} |
| \begin{flushleft} |
| \# The interface is \verb|UP|. IPv6 started stateless autoconfiguration itself,\\ |
| \# and its configuration finishes here. However,\\ |
| \# IP still needs some static preconfigured address. |
| \end{flushleft} |
| \begin{verbatim} |
| if [ "$ipaddr" = "" ]; then |
| echo "No address for $dev is configured, trying DHCP..." 1>&2 |
| dhcpcd |
| exit $? |
| fi |
| \end{verbatim} |
| |
| \begin{flushleft} |
| \# {\bf Step 2} --- IP Duplicate Address Detection~\cite{RFC-DHCP}.\\ |
| \# Send two probes and wait for result for 3 seconds.\\ |
| \# If the interface opens slower f.e.\ due to long media detection,\\ |
| \# you want to increase the timeout.\\ |
| \end{flushleft} |
| \begin{verbatim} |
| if ! arping -q -c 2 -w 3 -D -I $dev $ipaddr ; then |
| echo "Address $ipaddr is busy, trying DHCP..." 1>&2 |
| dhcpcd |
| exit $? |
| fi |
| \end{verbatim} |
| \begin{flushleft} |
| \# OK, the address is unique, we may add it on the interface.\\ |
| \#\\ |
| \# {\bf Step 3} --- Configure the address on the interface. |
| \end{flushleft} |
| |
| \begin{verbatim} |
| if ! ip address add $pfx brd + dev $dev; then |
| echo "Failed to add $pfx on $dev, trying DHCP..." 1>&2 |
| dhcpcd |
| exit $? |
| fi |
| \end{verbatim} |
| |
| \noindent\# {\bf Step 4} --- Announce our presence on the link. |
| \begin{verbatim} |
| arping -A -c 1 -I $dev $ipaddr |
| noarp=$? |
| ( sleep 2; |
| arping -U -c 1 -I $dev $ipaddr ) >& /dev/null </dev/null & |
| \end{verbatim} |
| |
| \begin{flushleft} |
| \# {\bf Step 5} (optional) --- Add some control routes.\\ |
| \#\\ |
| \# 1. Prohibit link local multicast addresses.\\ |
| \# 2. Prohibit link local (alias, limited) broadcast.\\ |
| \# 3. Add default multicast route. |
| \end{flushleft} |
| \begin{verbatim} |
| ip route add unreachable 224.0.0.0/24 |
| ip route add unreachable 255.255.255.255 |
| if [ `ip link ls $dev | grep -c MULTICAST` -ge 1 ]; then |
| ip route add 224.0.0.0/4 dev $dev scope global |
| fi |
| \end{verbatim} |
| |
| \begin{flushleft} |
| \# {\bf Step 6} --- Add fallback default route with huge metric.\\ |
| \# If a proxy ARP server is present on the interface, we will be\\ |
| \# able to talk to all the Internet without further configuration.\\ |
| \# It is not so cheap though and we still hope that this route\\ |
| \# will be overridden by more correct one by rdisc.\\ |
| \# Do not make this step if the device is not ARPable,\\ |
| \# because dead nexthop detection does not work on them. |
| \end{flushleft} |
| \begin{verbatim} |
| if [ "$noarp" = "0" ]; then |
| ip ro add default dev $dev metric 30000 scope global |
| fi |
| \end{verbatim} |
| |
| \begin{flushleft} |
| \# {\bf Step 7} --- Restart router discovery and exit. |
| \end{flushleft} |
| \begin{verbatim} |
| killall -HUP rdisc || rdisc -fs |
| exit 0 |
| \end{verbatim} |
| |
| |
| \section{Example: {\protect\tt ifcfg} --- interface address management} |
| \label{EXAMPLE-IFCFG} |
| |
| This is a simplistic script replacing one option of \verb|ifconfig|, |
| namely, IP address management. It not only adds |
| addresses, but also carries out Duplicate Address Detection~\cite{RFC-DHCP}, |
| sends unsolicited ARP to update the caches of other hosts sharing |
| the interface, adds some control routes and restarts Router Discovery |
| when it is necessary. |
| |
| I strongly recommend using it {\em instead\/} of \verb|ifconfig| both |
| on hosts and on routers. |
| |
| \begin{verbatim} |
| #! /bin/bash |
| \end{verbatim} |
| \begin{flushleft} |
| \# {\bf Usage: \verb?ifcfg DEVICE[:ALIAS] [add|del] ADDRESS[/LENGTH] [PEER]?}\\ |
| \# {\bf Parameters:}\\ |
| \# ---Device name. It may have alias suffix, separated by colon.\\ |
| \# ---Command: add, delete or stop.\\ |
| \# ---IP address, optionally followed by prefix length.\\ |
| \# ---Optional peer address for pointopoint interfaces.\\ |
| \# F.e. \verb|ifcfg eth0 193.233.7.90/24| |
| |
| \noindent\# This function determines, whether it is router or host.\\ |
| \# It returns 0, if the host is apparently not router. |
| \end{flushleft} |
| \begin{verbatim} |
| CheckForwarding () { |
| local sbase fwd |
| sbase=/proc/sys/net/ipv4/conf |
| fwd=0 |
| if [ -d $sbase ]; then |
| for dir in $sbase/*/forwarding; do |
| fwd=$[$fwd + `cat $dir`] |
| done |
| else |
| fwd=2 |
| fi |
| return $fwd |
| } |
| \end{verbatim} |
| \begin{flushleft} |
| \# This function restarts Router Discovery.\\ |
| \end{flushleft} |
| \begin{verbatim} |
| RestartRDISC () { |
| killall -HUP rdisc || rdisc -fs |
| } |
| \end{verbatim} |
| \begin{flushleft} |
| \# Calculate ABC "natural" mask length\\ |
| \# Arg: \$1 = dotquad address |
| \end{flushleft} |
| \begin{verbatim} |
| ABCMaskLen () { |
| local class; |
| class=${1%%.*} |
| if [ $class -eq 0 -o $class -ge 224 ]; then return 0 |
| elif [ $class -ge 192 ]; then return 24 |
| elif [ $class -ge 128 ]; then return 16 |
| else return 8 ; fi |
| } |
| \end{verbatim} |
| |
| |
| \begin{flushleft} |
| \# {\bf MAIN()}\\ |
| \#\\ |
| \# Strip alias suffix separated by colon. |
| \end{flushleft} |
| \begin{verbatim} |
| label="label $1" |
| ldev=$1 |
| dev=${1%:*} |
| if [ "$dev" = "" -o "$1" = "help" ]; then |
| echo "Usage: ifcfg DEV [[add|del [ADDR[/LEN]] [PEER] | stop]" 1>&2 |
| echo " add - add new address" 1>&2 |
| echo " del - delete address" 1>&2 |
| echo " stop - completely disable IP" 1>&2 |
| exit 1 |
| fi |
| shift |
| |
| CheckForwarding |
| fwd=$? |
| \end{verbatim} |
| \begin{flushleft} |
| \# Parse command. If it is ``stop'', flush and exit. |
| \end{flushleft} |
| \begin{verbatim} |
| deleting=0 |
| case "$1" in |
| add) shift ;; |
| stop) |
| if [ "$ldev" != "$dev" ]; then |
| echo "Cannot stop alias $ldev" 1>&2 |
| exit 1; |
| fi |
| ip -4 addr flush dev $dev $label || exit 1 |
| if [ $fwd -eq 0 ]; then RestartRDISC; fi |
| exit 0 ;; |
| del*) |
| deleting=1; shift ;; |
| *) |
| esac |
| \end{verbatim} |
| \begin{flushleft} |
| \# Parse prefix, split prefix length, separated by slash. |
| \end{flushleft} |
| \begin{verbatim} |
| ipaddr= |
| pfxlen= |
| if [ "$1" != "" ]; then |
| ipaddr=${1%/*} |
| if [ "$1" != "$ipaddr" ]; then |
| pfxlen=${1#*/} |
| fi |
| if [ "$ipaddr" = "" ]; then |
| echo "$1 is bad IP address." 1>&2 |
| exit 1 |
| fi |
| fi |
| shift |
| \end{verbatim} |
| \begin{flushleft} |
| \# If peer address is present, prefix length is 32.\\ |
| \# Otherwise, if prefix length was not given, guess it. |
| \end{flushleft} |
| \begin{verbatim} |
| peer=$1 |
| if [ "$peer" != "" ]; then |
| if [ "$pfxlen" != "" -a "$pfxlen" != "32" ]; then |
| echo "Peer address with non-trivial netmask." 1>&2 |
| exit 1 |
| fi |
| pfx="$ipaddr peer $peer" |
| else |
| if [ "$pfxlen" = "" ]; then |
| ABCMaskLen $ipaddr |
| pfxlen=$? |
| fi |
| pfx="$ipaddr/$pfxlen" |
| fi |
| if [ "$ldev" = "$dev" -a "$ipaddr" != "" ]; then |
| label= |
| fi |
| \end{verbatim} |
| \begin{flushleft} |
| \# If deletion was requested, delete the address and restart RDISC |
| \end{flushleft} |
| \begin{verbatim} |
| if [ $deleting -ne 0 ]; then |
| ip addr del $pfx dev $dev $label || exit 1 |
| if [ $fwd -eq 0 ]; then RestartRDISC; fi |
| exit 0 |
| fi |
| \end{verbatim} |
| \begin{flushleft} |
| \# Start interface initialization.\\ |
| \#\\ |
| \# {\bf Step 0} --- enable device \verb|$dev| |
| \end{flushleft} |
| \begin{verbatim} |
| if ! ip link set up dev $dev ; then |
| echo "Error: cannot enable interface $dev." 1>&2 |
| exit 1 |
| fi |
| if [ "$ipaddr" = "" ]; then exit 0; fi |
| \end{verbatim} |
| \begin{flushleft} |
| \# {\bf Step 1} --- IP Duplicate Address Detection~\cite{RFC-DHCP}.\\ |
| \# Send two probes and wait for result for 3 seconds.\\ |
| \# If the interface opens slower f.e.\ due to long media detection,\\ |
| \# you want to increase the timeout.\\ |
| \end{flushleft} |
| \begin{verbatim} |
| if ! arping -q -c 2 -w 3 -D -I $dev $ipaddr ; then |
| echo "Error: some host already uses address $ipaddr on $dev." 1>&2 |
| exit 1 |
| fi |
| \end{verbatim} |
| \begin{flushleft} |
| \# OK, the address is unique. We may add it to the interface.\\ |
| \#\\ |
| \# {\bf Step 2} --- Configure the address on the interface. |
| \end{flushleft} |
| \begin{verbatim} |
| if ! ip address add $pfx brd + dev $dev $label; then |
| echo "Error: failed to add $pfx on $dev." 1>&2 |
| exit 1 |
| fi |
| \end{verbatim} |
| \noindent\# {\bf Step 3} --- Announce our presence on the link |
| \begin{verbatim} |
| arping -q -A -c 1 -I $dev $ipaddr |
| noarp=$? |
| ( sleep 2 ; |
| arping -q -U -c 1 -I $dev $ipaddr ) >& /dev/null </dev/null & |
| \end{verbatim} |
| \begin{flushleft} |
| \# {\bf Step 4} (optional) --- Add some control routes.\\ |
| \#\\ |
| \# 1. Prohibit link local multicast addresses.\\ |
| \# 2. Prohibit link local (alias, limited) broadcast.\\ |
| \# 3. Add default multicast route. |
| \end{flushleft} |
| \begin{verbatim} |
| ip route add unreachable 224.0.0.0/24 >& /dev/null |
| ip route add unreachable 255.255.255.255 >& /dev/null |
| if [ `ip link ls $dev | grep -c MULTICAST` -ge 1 ]; then |
| ip route add 224.0.0.0/4 dev $dev scope global >& /dev/null |
| fi |
| \end{verbatim} |
| \begin{flushleft} |
| \# {\bf Step 5} --- Add fallback default route with huge metric.\\ |
| \# If a proxy ARP server is present on the interface, we will be\\ |
| \# able to talk to all the Internet without further configuration.\\ |
| \# Do not make this step on router or if the device is not ARPable.\\ |
| \# because dead nexthop detection does not work on them. |
| \end{flushleft} |
| \begin{verbatim} |
| if [ $fwd -eq 0 ]; then |
| if [ $noarp -eq 0 ]; then |
| ip ro append default dev $dev metric 30000 scope global |
| elif [ "$peer" != "" ]; then |
| if ping -q -c 2 -w 4 $peer ; then |
| ip ro append default via $peer dev $dev metric 30001 |
| fi |
| fi |
| RestartRDISC |
| fi |
| |
| exit 0 |
| \end{verbatim} |
| \begin{flushleft} |
| \# End of {\bf MAIN()} |
| \end{flushleft} |
| |
| |
| \end{document} |