| Chapter 5. Network setup | ||
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| Chapter 5. Network setup | ||
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Table of Contents
![[Tip]](images/tip.png) |
Tip |
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For general guide to the GNU/Linux networking, read the Linux Network Administrators Guide. |
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Although this document still uses old ifconfig(8) with IPv4 for its network configuration examples, Debian is moving to ip(8) with IPv4+IPv6 in the |
Let's review the basic network infrastructure on the modern Debian system.
Table 5.1. List of network configuration tools
The naming for the domain name is a tricky one for the normal PC workstation users. The PC workstation may be mobile one hopping around the network or located behind the NAT firewall inaccessible from the Internet. For such case, you may not want the domain name to be a valid domain name to avoid name collision.
If you are not sure what to chose for the domain name, choose "localdomain".
Other popular choices for such invalid and safe top-level domain (TLD) seem to be "lan", "localnet", "home", "invalid", or "local" according to my incoming mail analysis. This is consistent with the reported invalid TLD queries. You may also chose some unused second or third level domains.
".invalid" is intended for use in online construction of domain names that are sure to be invalid. (rfc2606)
".local" is the pseudo-top-level domain used by the mDNS network discovery protocol (Apple Bonjour / Apple Rendezvous, Avahi on Debian).
![[Warning]](images/warning.png) |
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If the DNS service on your LAN uses " |
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When you use an invalid domain name, you need to spoof the domain name used by some programs such as MTA for their proper operation. See Section 6.3.3, “The mail address configuration”. |
The hostname resolution is currently supported by the NSS (Name Service Switch) mechanism too. The flow of this resolution is the following.
The "/etc/nsswitch.conf" file with stanza like "hosts: files dns" dictates the hostname resolution order. (This replaces the old functionality of the "order" stanza in "/etc/host.conf".)
The files method is invoked first. If the hostname is found in the "/etc/hosts" file, it returns all valid addresses for it and exits. (The "/etc/host.conf" file contains "multi on".)
The dns method is invoked. If the hostname is found by the query to the Internet Domain Name System (DNS) identified by the "/etc/resolv.conf" file, it returns all valid addresses for it and exits.
For example, "/etc/hosts" looks like the following.
127.0.0.1 localhost 127.0.1.1 <host_name>.<domain_name> <host_name> # The following lines are desirable for IPv6 capable hosts ::1 ip6-localhost ip6-loopback fe00::0 ip6-localnet ff00::0 ip6-mcastprefix ff02::1 ip6-allnodes ff02::2 ip6-allrouters ff02::3 ip6-allhosts
Each line starts with a IP address and it is followed by the associated hostname.
The IP address 127.0.1.1 in the second line of this example may not be found on some other Unix-like systems. The Debian Installer creates this entry for a system without a permanent IP address as a workaround for some software (e.g., GNOME) as documented in the bug #316099.
The <host_name> matches the hostname defined in the "/etc/hostname".
For <domain_name> of the mobile PC, you may chose invalid and safe domain such as "localdomain". (See Section 5.1.1, “The domain name”)
For a system with a permanent IP address, that permanent IP address should be used here instead of 127.0.1.1.
For a system with a permanent IP address and a fully qualified domain name (FQDN) provided by the Domain Name System (DNS), that canonical <host_name> and <domain_name> should be used here.
The "/etc/resolv.conf" is a static file if the resolvconf package is not installed. If installed, it is a symbolic link. Either way, it contains information that initialize the resolver routines. If the DNS is found at IP="192.168.11.1", it contains the following.
nameserver 192.168.11.1
The resolvconf package makes this "/etc/resolv.conf" into a symbolic link and manages its contents by the hook scripts automatically.
The hostname resolution via Multicast DNS (using Zeroconf, aka Apple Bonjour / Apple Rendezvous) which effectively allows name resolution by common Unix/Linux programs in the ad-hoc mDNS domain "local", can be provided by installing the libnss-mdns package. The "/etc/nsswitch.conf" file should have stanza like "hosts: files mdns4_minimal [NOTFOUND=return] dns mdns4" to enable this functionality.
The hostname resolution via deprecated NETBios over TCP/IP used by the older Windows system can be provided by installing the winbind package. The "/etc/nsswitch.conf" file should have stanza like "hosts: files mdns4_minimal [NOTFOUND=return] dns mdns4 wins" to enable this functionality. (Modern Windows system usually use the dns method for the hostname resolution.)
The network interface name, e.g. eth0, is assigned to each hardware in the Linux kernel through the user space configuration mechanism, udev (see Section 3.5.11, “The udev system”), as it is found. The network interface name is referred as physical interface in ifup(8) and interfaces(5).
In order to ensure each network interface to be named persistently for each reboot using MAC address etc., there is a record file "/etc/udev/rules.d/70-persistent-net.rules". This file is automatically generated by the "/lib/udev/write_net_rules" program, probably run by the "persistent-net-generator.rules" rules file. You can modify it to change naming rule.
![[Caution]](images/caution.png) |
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When editing the " |
Let us be reminded of the IPv4 32 bit address ranges in each class reserved for use on the local area networks (LANs) by rfc1918. These addresses are guaranteed not to conflict with any addresses on the Internet proper.
Table 5.2. List of network address ranges
| Class | network addresses | net mask | net mask /bits | # of subnets |
|---|---|---|---|---|
| A | 10.x.x.x | 255.0.0.0 | /8 | 1 |
| B | 172.16.x.x — 172.31.x.x | 255.255.0.0 | /16 | 16 |
| C | 192.168.0.x — 192.168.255.x | 255.255.255.0 | /24 | 256 |
![[Note]](images/note.png) |
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If one of these addresses is assigned to a host, then that host must not access the Internet directly but must access it through a gateway that acts as a proxy for individual services or else does Network Address Translation(NAT). The broadband router usually performs NAT for the consumer LAN environment. |
Although most hardware devices are supported by the Debian system, there are some network devices which require DFSG non-free external hardware drivers to support them. Please see Section 9.7.6, “Non-free hardware drivers”.
Debian squeeze systems can manage the network connection via management daemon software such as NetworkManager (NM) (network-manager and associated packages) or Wicd (wicd and associated packages).
They come with their own GUI and command-line programs as their user interfaces.
They come with their own daemon as their backend system.
They allow easy connection of your system to the Internet.
They allow easy management of wired and wireless network configuration.
They allow us to configure network independent of the legacy ifupdown package.
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Do not use these automatic network configuration tools for servers. These are aimed primarily for mobile desktop users on laptops. |
These modern network configuration tools need to be configured properly to avoid conflicting with the legacy ifupdown package and its configuration file "/etc/network/interfaces".
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Some features of these automatic network configuration tools may suffer regressions. These are not as robust as the legacy |
Official documentations for NM and Wicd on Debian are provided in "/usr/share/doc/network-manager/README.Debian" and "/usr/share/doc/wicd/README.Debian", respectively.
Essentially, the network configuration for desktop is done as follows.
Make desktop user, e.g. foo, belong to group "netdev" by the following (Alternatively, do it automatically via D-bus under modern desktop environments such as GNOME and KDE).
$ sudo adduser foo netdev
Keep configuration of "/etc/network/interfaces" as simple as the the following.
auto lo iface lo inet loopback
Restart NM or Wicd by the following.
$ sudo /etc/init.d/network-manager restart
$ sudo /etc/init.d/wicd restart
Configure your network via GUI.
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Only interfaces which are not listed in " |
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If you wish to extend network configuration capabilities of NM, please seek appropriate plug-in modules and supplemental packages such as |
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These automatic network configuration tools may not be compatible with esoteric configurations of legacy |
When the method described in Section 5.2, “The modern network configuration for desktop” does not suffice your needs, you should use the legacy network connection and configuration method which combines many simpler tools.
The legacy network connection is specific for each method (see Section 5.4, “The network connection method (legacy)”).
There are 2 types of programs for the low level network configuration on Linux (see Section 5.7.1, “Iproute2 commands”).
Old net-tools programs (ifconfig(8), …) are from the Linux NET-3 networking system. Most of these are obsolete now.
New Linux iproute2 programs (ip(8), …) are the current Linux networking system.
Although these low level networking programs are powerful, they are cumbersome to use. So high level network configuration systems have been created.
The ifupdown package is the de facto standard for such high level network configuration system on Debian. It enables you to bring up network simply by doing , e.g., "ifup eth0". Its configuration file is the "/etc/network/interfaces" file and its typical contents are the following.
auto lo iface lo inet loopback auto eth0 iface eth0 inet dhcp
The resolvconf package was created to supplement ifupdown system to support smooth reconfiguration of network address resolution by automating rewrite of resolver configuration file "/etc/resolv.conf". Now, most Debian network configuration packages are modified to use resolvconf package (see "/usr/share/doc/resolvconf/README.Debian").
Helper scripts to the ifupdown package such as ifplugd, guessnet, ifscheme, etc. are created to automate dynamic configuration of network environment such as one for mobile PC on wired LAN. These are relatively difficult to use but play well with existing ifupdown system.
These are explained in detail with examples (see Section 5.5, “The basic network configuration with ifupdown (legacy)” and Section 5.6, “The advanced network configuration with ifupdown (legacy)”).
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The connection test method described in this section are meant for testing purposes. It is not meant to be used directly for the daily network connection. You are advised to use them via NM, Wicd, or the |
The typical network connection method and connection path for a PC can be summarized as the following.
Table 5.3. List of network connection methods and connection paths
| PC | connection method | connection path |
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Serial port (ppp0)
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PPP | ⇔ modem ⇔ POTS ⇔ dial-up access point ⇔ ISP |
Ethernet port (eth0)
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PPPoE/DHCP/Static | ⇔ BB-modem ⇔ BB service ⇔ BB access point ⇔ ISP |
Ethernet port (eth0)
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DHCP/Static | ⇔ LAN ⇔ BB-router with network address translation (NAT) (⇔ BB-modem …) |
Here is the summary of configuration script for each connection method.
Table 5.4. List of network connection configurations
| connection method | configuration | backend package(s) |
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| PPP |
pppconfig to create deterministic chat
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pppconfig, ppp
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| PPP (alternative) |
wvdialconf to create heuristic chat
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ppp, wvdial
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| PPPoE |
pppoeconf to create deterministic chat
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pppoeconf, ppp
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| DHCP |
described in "/etc/dhcp/dhclient.conf"
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isc-dhcp-client
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| static IP (IPv4) |
described in "/etc/network/interfaces"
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net-tools
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| static IP (IPv6) |
described in "/etc/network/interfaces"
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iproute
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The network connection acronyms mean the following.
Table 5.5. List of network connection acronyms
| acronym | meaning |
|---|---|
| POTS | plain old telephone service |
| BB | broadband |
| BB-service | e.g., the digital subscriber line (DSL), the cable TV, or the fiber to the premises (FTTP) |
| BB-modem | e.g., the DSL modem, the cable modem, or the optical network terminal (ONT) |
| LAN | local area network |
| WAN | wide area network |
| DHCP | dynamic host configuration protocol |
| PPP | point-to-point protocol |
| PPPoE | point-to-point protocol over Ethernet |
| ISP | Internet service provider |
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The WAN connection services via cable TV are generally served by DHCP or PPPoE. The ones by ADSL and FTTP are generally served by PPPoE. You have to consult your ISP for exact configuration requirements of the WAN connection. |
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When BB-router is used to create home LAN environment, PCs on LAN are connected to the WAN via BB-router with network address translation (NAT). For such case, PC's network interfaces on the LAN are served by static IP or DHCP from the BB-router. BB-router must be configured to connect the WAN following the instruction by your ISP. |
The typical modern home and small business network, i.e. LAN, are connected to the WAN(Internet) using some consumer grade broadband router. The LAN behind this router is usually served by the dynamic host configuration protocol (DHCP) server running on the router.
Just install the isc-dhcp-client package for the Ethernet served by the dynamic host configuration protocol (DHCP).
See dhclient.conf(5).
No special action is needed for the Ethernet served by the static IP.
The configuration script pppconfig configures the PPP connection interactively just by selecting the following.
The telephone number
The ISP user name
The ISP password
The port speed
The modem communication port
The authentication method
Table 5.6. List of configuration files for the PPP connection with pppconfig
| file | function |
|---|---|
/etc/ppp/peers/<isp_name>
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The pppconfig generated configuration file for pppd specific to <isp_name>
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/etc/chatscripts/<isp_name>
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The pppconfig generated configuration file for chat specific to <isp_name>
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/etc/ppp/options
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The general execution parameter for pppd
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/etc/ppp/pap-secret
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Authentication data for the PAP (security risk) |
/etc/ppp/chap-secret
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Authentication data for the CHAP (more secure) |
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The "<isp_name>" value of " |
You can test configuration using low level network configuration tools as the following.
$ sudo pon <isp_name> ... $ sudo poff <isp_name>
See "/usr/share/doc/ppp/README.Debian.gz".
A different approach to using pppd(8) is to run it from wvdial(1) which comes in the wvdial package. Instead of pppd running chat(8) to dial in and negotiate the connection, wvdial does the dialing and initial negotiating and then starts pppd to do the rest.
The configuration script wvdialconf configures the PPP connection interactively just by selecting the following.
The telephone number
The ISP user name
The ISP password
wvdial succeeds in making the connection in most cases and maintains authentication data list automatically.
Table 5.7. List of configuration files for the PPP connection with wvdialconf
| file | function |
|---|---|
/etc/ppp/peers/wvdial
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The wvdialconf generated configuration file for pppd specific to wvdial
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/etc/wvdial.conf
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The wvdialconf generated configuration file
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/etc/ppp/options
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The general execution parameter for pppd
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/etc/ppp/pap-secret
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Authentication data for the PAP (security risk) |
/etc/ppp/chap-secret
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Authentication data for the CHAP (more secure) |
You can test configuration using low level network configuration tools as the following.
$ sudo wvdial ... $ sudo killall wvdial
See wvdial(1) and wvdial.conf(5).
When your ISP serves you with PPPoE connection and you decide to connect your PC directly to the WAN, the network of your PC must be configured with the PPPoE. The PPPoE stand for PPP over Ethernet. The configuration script pppoeconf configures the PPPoE connection interactively.
The configuration files are the following.
Table 5.8. List of configuration files for the PPPoE connection with pppoeconf
| file | function |
|---|---|
/etc/ppp/peers/dsl-provider
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The pppoeconf generated configuration file for pppd specific to pppoe
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/etc/ppp/options
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The general execution parameter for pppd
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/etc/ppp/pap-secret
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Authentication data for the PAP (security risk) |
/etc/ppp/chap-secret
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Authentication data for the CHAP (more secure) |
You can test configuration using low level network configuration tools as the following.
$ sudo /sbin/ifconfig eth0 up $ sudo pon dsl-provider ... $ sudo poff dsl-provider $ sudo /sbin/ifconfig eth0 down
See "/usr/share/doc/pppoeconf/README.Debian".
The traditional TCP/IP network setup on Debian system uses ifupdown package as a high level tool. There are 2 typical cases.
For dynamic IP system such as mobile PCs, you should setup TCP/IP network with the resolvconf package and enable you to switch your network configuration easily (see Section 5.5.4, “The network interface served by the DHCP”).
For static IP system such as servers, you should setup TCP/IP network without the resolvconf package and keep your system simple (see Section 5.5.5, “The network interface with the static IP”).
These traditional setup methods are quite useful if you wish to set up advanced configuration (see Section 5.5, “The basic network configuration with ifupdown (legacy)”).
The ifupdown package provides the standardized framework for the high level network configuration in the Debian system. In this section, we learn the basic network configuration with ifupdown with simplified introduction and many typical examples.
The ifupdown package contains 2 commands: ifup(8) and ifdown(8). They offer high level network configuration dictated by the configuration file "/etc/network/interfaces".
Table 5.9. List of basic network configuration commands with ifupdown
| command | action |
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ifup eth0
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bring up a network interface eth0 with the configuration eth0 if "iface eth0" stanza exists
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ifdown eth0
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bring down a network interface eth0 with the configuration eth0 if "iface eth0" stanza exists
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Do not use low level configuration tools such as ifconfig(8) and ip(8) commands to configure an interface in up state. |
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There is no command |
The key syntax of "/etc/network/interfaces" as explained in interfaces(5) can be summarized as the following.
Table 5.10. List of stanzas in "/etc/network/interfaces"
| stanza | meaning |
|---|---|
"auto <interface_name>"
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start interface <interface_name> upon start of the system |
"allow-auto <interface_name>"
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, , |
"allow-hotplug <interface_name>"
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start interface <interface_name> when the kernel detects a hotplug event from the interface |
Lines started with "iface <config_name> …"
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define the network configuration <config_name> |
Lines started with "mapping <interface_name_glob> "
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define mapping value of <config_name> for the matching <interface_name> |
A line starting with a hash "#"
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ignore as comments (end-of-line comments are not supported) |
A line ending with a backslash "\"
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extend the configuration to the next line |
Lines started with iface stanza has the following syntax.
iface <config_name> <address_family> <method_name> <option1> <value1> <option2> <value2> ...
For the basic configuration, the mapping stanza is not used and you use the network interface name as the network configuration name (See Section 5.6.5, “The mapping stanza”).
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Do not define duplicates of the " |
The following configuration entry in the "/etc/network/interfaces" file brings up the loopback network interface lo upon booting the system (via auto stanza).
auto lo iface lo inet loopback
This one always exists in the "/etc/network/interfaces" file.
After preparing the system by Section 5.4.1, “The DHCP connection with the Ethernet”, the network interface served by the DHCP is configured by creating the configuration entry in the "/etc/network/interfaces" file as the following.
allow-hotplug eth0 iface eth0 inet dhcp
When the Linux kernel detects the physical interface eth0, the allow-hotplug stanza causes ifup to bring up the interface and the iface stanza causes ifup to use DHCP to configure the interface.
The network interface served by the static IP is configured by creating the configuration entry in the "/etc/network/interfaces" file as the following.
allow-hotplug eth0 iface eth0 inet static address 192.168.11.100 netmask 255.255.255.0 gateway 192.168.11.1 dns-domain example.com dns-nameservers 192.168.11.1
When the Linux kernel detects the physical interface eth0, the allow-hotplug stanza causes ifup to bring up the interface and the iface stanza causes ifup to use the static IP to configure the interface.
Here, I assumed the following.
IP address range of the LAN network: 192.168.11.0 - 192.168.11.255
IP address of the gateway: 192.168.11.1
IP address of the PC: 192.168.11.100
The resolvconf package: installed
The domain name: "example.com"
IP address of the DNS server: 192.168.11.1
When the resolvconf package is not installed, DNS related configuration needs to be done manually by editing the "/etc/resolv.conf" as the following.
nameserver 192.168.11.1 domain example.com
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The IP addresses used in the above example are not meant to be copied literally. You have to adjust IP numbers to your actual network configuration. |
The wireless LAN (WLAN for short) provides the fast wireless connectivity through the spread-spectrum communication of unlicensed radio bands based on the set of standards called IEEE 802.11.
The WLAN interfaces are almost like normal Ethernet interfaces but require some network ID and encryption key data to be provided when they are initialized. Their high level network tools are exactly the same as that of Ethernet interfaces except interface names are a bit different like eth1, wlan0, ath0, wifi0, … depending on the kernel drivers used.
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The |
Here are some keywords to remember for the WLAN.
Table 5.11. List of acronyms for WLAN
| acronym | full word | meaning |
|---|---|---|
| NWID | Network ID | 16 bit network ID used by pre-802.11 WaveLAN network (very deprecated) |
| (E)SSID | (Extended) Service Set Identifier | network name of the Wireless Access Points (APs) interconnected to form an integrated 802.11 wireless LAN, Domain ID |
| WEP, (WEP2) | Wired Equivalent Privacy | 1st generation 64-bit (128-bit) wireless encryption standard with 40-bit key (deprecated) |
| WPA | Wi-Fi Protected Access | 2nd generation wireless encryption standard (most of 802.11i), compatible with WEP |
| WPA2 | Wi-Fi Protected Access 2 | 3rd generation wireless encryption standard (full 802.11i), non-compatible with WEP |
The actual choice of protocol is usually limited by the wireless router you deploy.
You need to install the wpasupplicant package to support the WLAN with the new WPA/WPA2.
In case of the DHCP served IP on WLAN connection, the "/etc/network/interfaces" file entry should be as the following.
allow-hotplug ath0 iface ath0 inet dhcp wpa-ssid homezone # hexadecimal psk is encoded from a plaintext passphrase wpa-psk 000102030405060708090a0b0c0d0e0f101112131415161718191a1b1c1d1e1f
See "/usr/share/doc/wpasupplicant/README.modes.gz".
You need to install the wireless-tools package to support the WLAN with the old WEP. (Your consumer grade router may still be using this insecure infrastructure but this is better than nothing.)
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Please note that your network traffic on WLAN with WEP may be sniffed by others. |
In case of the DHCP served IP on WLAN connection, the "/etc/network/interfaces" file entry should be as the following.
allow-hotplug eth0 iface eth0 inet dhcp wireless-essid Home wireless-key1 0123-4567-89ab-cdef wireless-key2 12345678 wireless-key3 s:password wireless-defaultkey 2 wireless-keymode open
See "/usr/share/doc/wireless-tools/README.Debian".
You need to configure the PPP connection first as described before (see Section 5.4.3, “The PPP connection with pppconfig”). Then, add the "/etc/network/interfaces" file entry for the primary PPP device ppp0 as the following.
iface ppp0 inet ppp provider <isp_name>
You need to configure the alternative PPP connection with wvdial first as described before (see Section 5.4.4, “The alternative PPP connection with wvdialconf”). Then, add the "/etc/network/interfaces" file entry for the primary PPP device ppp0 as the following.
iface ppp0 inet wvdial
For PC connected directly to the WAN served by the PPPoE, you need to configure system with the PPPoE connection as described before (see Section 5.4.5, “The PPPoE connection with pppoeconf”). Then, add the "/etc/network/interfaces" file entry for the primary PPPoE device eth0 as the following.
allow-hotplug eth0 iface eth0 inet manual pre-up /sbin/ifconfig eth0 up up ifup ppp0=dsl down ifdown ppp0=dsl post-down /sbin/ifconfig eth0 down # The following is used internally only iface dsl inet ppp provider dsl-provider
The "/etc/network/run/ifstate" file stores the intended network configuration states for all the currently active network interfaces managed by the ifupdown package are listed. Unfortunately, even if the ifupdown system fails to bring up the interface as intended, the "/etc/network/run/ifstate" file lists it active.
Unless the output of the ifconfig(8) command for an interface does not have a line like following example, it can not be used as a part of IPV4 network.
inet addr:192.168.11.2 Bcast:192.168.11.255 Mask:255.255.255.0
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For the Ethernet device connected to the PPPoE, the output of the ifconfig(8) command lacks a line which looks like above example. |
When you try to reconfigure the interface, e.g. eth0, you must disable it first with the "sudo ifdown eth0" command. This removes the entry of eth0 from the "/etc/network/run/ifstate" file. (This may result in some error message if eth0 is not active or it is configured improperly previously. So far, it seems to be safe to do this for the simple single user work station at any time.)
You are now free to rewrite the "/etc/network/interfaces" contents as needed to reconfigure the network interface, eth0.
Then, you can reactivate eth0 with the "sudo ifup eth0" command.
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You can (re)initialize the network interface simply by " |
The ifupdown-extra package provides easy network connection tests for use with the ifupdown package.
The network-test(1) command can be used from the shell.
The automatic scripts are run for each ifup command execution.
The network-test command frees you from the execution of cumbersome low level commands to analyze the network problem.
The automatic scripts are installed in "/etc/network/*/" and performs the following.
Check the network cable connection
Check duplicate use of IP address
Setup system's static routes based on the "/etc/network/routes" definition
Check if network gateway is reachable
Record results in the "/var/log/syslog" file
This syslog record is quite useful for administration of the network problem on the remote system.
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The automatic behavior of the |
The functionality of the ifupdown package can be improved beyond what was described in Section 5.5, “The basic network configuration with ifupdown (legacy)” with the advanced knowledge.
The functionalities described here are completely optional. I, being lazy and minimalist, rarely bother to use these.
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Caution |
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If you could not set up network connection by information in Section 5.5, “The basic network configuration with ifupdown (legacy)”, you make situation worse by using information below. |
The ifplugd package is older automatic network configuration tool which can manage only Ethernet connections. This solves unplugged/replugged Ethernet cable issues for mobile PC etc. If you have NetworkManager or Wicd (see Section 5.2, “The modern network configuration for desktop”) installed, you do not need this package.
This package runs daemon and replaces auto or allow-hotplug functionalities (see Table 5.10, “List of stanzas in "/etc/network/interfaces"”) and starts interfaces upon their connection to the network.
Here is how to use the ifplugd package for the internal Ethernet port, e.g. eth0.
Remove stanza in "/etc/network/interfaces": "auto eth0" or "allow-hotplug eth0".
Keep stanza in "/etc/network/interfaces": "iface eth0 inet …" and "mapping …".
Install the ifplugd package.
Run "sudo dpkg-reconfigure ifplugd".
Put eth0 as the "static interfaces to be watched by ifplugd".
Now, the network reconfiguration works as you desire.
Upon power-on or upon hardware discovery, the interface is not brought up by itself.
Quick boot process without the long DHCP timeout.
No funny activated interface without proper IPv4 address (see Section 5.5.12, “The network configuration state of ifupdown”).
Upon finding the Ethernet cable, the interface is brought up.
Upon some time after unplugging the Ethernet cable, the interface is brought down automatically.
Upon plugging in another Ethernet cable, the interface is brought up under the new network environment.
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Tip |
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The arguments for the ifplugd(8) command can set its behaviors such as the delay for reconfiguring interfaces. |
The ifmeric package enables us to manipulate metrics of routes a posteriori even for DHCP.
The following sets the eth0 interface to be preferred over the wlan0 interface.
Install the ifmetric package.
Add an option line with "metric 0" just below the "iface eth0 inet dhcp" line.
Add an option line with "metric 1" just below the "iface wlan0 inet dhcp" line.
The metric 0 means the highest priority route and is the default one. The larger metric value means lower priority routes. The IP address of the active interface with the lowest metric value becomes the originating one. See ifmetric(8).
A single physical Ethernet interface can be configured as multiple virtual interfaces with different IP addresses. Usually the purpose is to connect an interface to several IP subnetworks. For example, IP address based virtual web hosting by a single network interface is one such application.
For example, let's suppose the following.
A single Ethernet interface on your host is connected to a Ethernet hub (not to the broadband router).
The Ethernet hub is connected to both the Internet and LAN network.
The LAN network uses subnet 192.168.0.x/24.
Your host uses DHCP served IP address with the physical interface eth0 for the Internet.
Your host uses 192.168.0.1 with the virtual interface eth0:0 for the LAN.
The following stanzas in "/etc/network/interfaces" configure your network.
iface eth0 inet dhcp metric 0 iface eth0:0 inet static address 192.168.0.1 netmask 255.255.255.0 network 192.168.0.0 metric 1
|
Caution |
|---|---|
Although this configuration example with network address translation (NAT) using netfilter/iptables (see Section 5.9, “Netfilter infrastructure”) can provide cheap router for the LAN with only single interface, there is no real firewall capability with such set up. You should use 2 physical interfaces with NAT to secure the local network from the Internet. |
The ifupdown package offers advanced network configuration using the network configuration name and the network interface name. I use slightly different terminology from one used in ifup(8) and interfaces(5).
Table 5.12. List of terminology for network devices
| manpage terminology | my terminology | examples in the following text | description |
|---|---|---|---|
| physical interface name | network interface name |
lo, eth0, <interface_name>
|
name given by the Linux kernel (using udev mechanism)
|
| logical interface name | network configuration name |
config1, config2, <config_name>
|
name token following iface in the "/etc/network/interfaces"
|
Basic network configuration commands in Section 5.5.1, “The command syntax simplified” require the network configuration name token of the iface stanza to match the network interface name in the "/etc/network/interfaces".
Advanced network configuration commands enables separation of the network configuration name and the network interface name in the "/etc/network/interfaces" as the following.
Table 5.13. List of advanced network configuration commands with ifupdown
| command | action |
|---|---|
ifup eth0=config1
|
bring up a network interface eth0 with the configuration config1
|
ifdown eth0=config1
|
bring down a network interface eth0 with the configuration config1
|
ifup eth0
|
bring up a network interface eth0 with the configuration selected by mapping stanza
|
ifdown eth0
|
bring down a network interface eth0 with the configuration selected by mapping stanza
|
We skipped explaining the mapping stanza in the "/etc/network/interfaces" in Section 5.5.2, “The basic syntax of "/etc/network/interfaces"” to avoid complication. This stanza has the following syntax.
mapping <interface_name_glob> script <script_name> map <script_input1> map <script_input2> map ...
This provides advanced feature to the "/etc/network/interfaces" file by automating the choice of the configuration with the mapping script specified by <script_name>.
Let's follow the execution of the following.
$ sudo ifup eth0
When the "<interface_name_glob>" matches "eth0", this execution produces the execution of the following command to configure eth0 automatically.
$ sudo ifup eth0=$(echo -e '<script_input1> \n <script_input2> \n ...' | <script_name> eth0)
Here, script input lines with "map" are optional and can be repeated.
|
Note |
|---|---|
The glob for |
Here is how to switch manually among several network configurations without rewriting the "/etc/network/interfaces" file as in Section 5.5.13, “The basic network reconfiguration” .
For all the network configuration you need to access, you create a single "/etc/network/interfaces" file as the following.
auto lo iface lo inet loopback iface config1 inet dhcp iface config2 inet static address 192.168.11.100 netmask 255.255.255.0 gateway 192.168.11.1 dns-domain example.com dns-nameservers 192.168.11.1 iface pppoe inet manual pre-up /sbin/ifconfig eth0 up up ifup ppp0=dsl down ifdown ppp0=dsl post-down /sbin/ifconfig eth0 down # The following is used internally only iface dsl inet ppp provider dsl-provider iface pots inet ppp provider provider
Please note the network configuration name which is the token after iface does not use the token for the network interface name. Also, there are no auto stanza nor allow-hotplug stanza to start the network interface eth0 automatically upon events.
Now you are ready to switch the network configuration.
Let's move your PC to a LAN served by the DHCP. You bring up the network interface (the physical interface) eth0 by assigning the network configuration name (the logical interface name) config1 to it by the following.
$ sudo ifup eth0=config1 Password: ...
The interface eth0 is up, configured by DHCP and connected to LAN.
$ sudo ifdown eth0=config1 ...
The interface eth0 is down and disconnected from LAN.
Let's move your PC to a LAN served by the static IP. You bring up the network interface eth0 by assigning the network configuration name config2 to it by the following.
$ sudo ifup eth0=config2 ...
The interface eth0 is up, configured with static IP and connected to LAN. The additional parameters given as dns-* configures "/etc/resolv.conf" contents. This "/etc/resolv.conf" is better manged if the resolvconf package is installed.
$ sudo ifdown eth0=config2 ...
The interface eth0 is down and disconnected from LAN, again.
Let's move your PC to a port on BB-modem connected to the PPPoE served service. You bring up the network interface eth0 by assigning the network configuration name pppoe to it by the following.
$ sudo ifup eth0=pppoe ...
The interface eth0 is up, configured with PPPoE connection directly to the ISP.
$ sudo ifdown eth0=pppoe ...
The interface eth0 is down and disconnected, again.
Let's move your PC to a location without LAN or BB-modem but with POTS and modem. You bring up the network interface ppp0 by assigning the network configuration name pots to it by the following.
$ sudo ifup ppp0=pots ...
The interface ppp0 is up and connected to the Internet with PPP.
$ sudo ifdown ppp0=pots ...
The interface ppp0 is down and disconnected from the Internet.
You should check the "/etc/network/run/ifstate" file for the current network configuration state of the ifupdown system.
|
Warning |
|---|---|
You may need to adjust numbers at the end of |
The ifupdown system automatically runs scripts installed in "/etc/network/*/" while exporting environment variables to scripts.
Table 5.14. List of environment variables passed by the ifupdown system
| environment variable | value passed |
|---|---|
"$IFACE"
|
physical name (interface name) of the interface being processed |
"$LOGICAL"
|
logical name (configuration name) of the interface being processed |
"$ADDRFAM"
|
<address_family> of the interface |
"$METHOD"
|
<method_name> of the interface. (e.g., "static") |
"$MODE"
|
"start" if run from ifup, "stop" if run from ifdown
|
"$PHASE"
|
as per "$MODE", but with finer granularity, distinguishing the pre-up, post-up, pre-down and post-down phases
|
"$VERBOSITY"
|
indicates whether "--verbose" was used; set to 1 if so, 0 if not
|
"$PATH"
|
command search path: "/usr/local/sbin:/usr/local/bin:/usr/sbin:/usr/bin:/sbin:/bin"
|
"$IF_<OPTION>"
|
value for the corresponding option under the iface stanza
|
Here, each environment variable, "$IF_<OPTION>", is created from the name for the corresponding option such as <option1> and <option2> by prepending "$IF_", converting the case to the upper case, replacing hyphens to underscores, and discarding non-alphanumeric characters.
|
Tip |
|---|---|
See Section 5.5.2, “The basic syntax of "/etc/network/interfaces"” for <address_family>, <method_name>, <option1> and <option2>. |
The ifupdown-extra package (see Section 5.5.14, “The ifupdown-extra package”) uses these environment variables to extend the functionality of the ifupdown package. The ifmetric package (see Section 5.6.2, “The ifmetric package”) installs the "/etc/network/if-up.d/ifmetric" script which sets the metric via the "$IF_METRIC" variable. The guessnet package (see Section 5.6.8, “Mapping with guessnet”), which provides simple and powerful framework for the auto-selection of the network configuration via the mapping mechanism, also uses these.
|
Note |
|---|---|
For more specific examples of custom network configuration scripts using these environment variables, you should check example scripts in " |
Instead of manually choosing configuration as described in Section 5.6.6, “The manually switchable network configuration”, you can use the mapping mechanism described in Section 5.6.5, “The mapping stanza” to select network configuration automatically with custom scripts.
The guessnet-ifupdown(8) command provided by the guessnet package is designed to be used as a mapping script and provides powerful framework to enhance the ifupdown system.
You list test condition as the value for guessnet options for each network configuration under iface stanza.
Mapping choses the iface with first non-ERROR result as the network configuration.
This dual usage of the "/etc/network/interfaces" file by the mapping script, guessnet-ifupdown, and the original network configuration infrastructure, ifupdown, does not cause negative impacts since guessnet options only export extra environment variables to scripts run by the ifupdown system. See details in guessnet-ifupdown(8).
|
Note |
|---|---|
When multiple |
Iproute2 commands offer complete low-level network configuration capabilities. Here is a translation table from obsolete net-tools commands to new iproute2 etc. commands.
Table 5.15. Translation table from obsolete net-tools commands to new iproute2 commands
| obsolete net-tools | new iproute2 etc. | manipulation |
|---|---|---|
| ifconfig(8) |
ip addr
|
protocol (IP or IPv6) address on a device |
| route(8) |
ip route
|
routing table entry |
| arp(8) |
ip neigh
|
ARP or NDISC cache entry |
ipmaddr
|
ip maddr
|
multicast address |
iptunnel
|
ip tunnel
|
tunnel over IP |
| nameif(8) | ifrename(8) | name network interfaces based on MAC addresses |
| mii-tool(8) | ethtool(8) | Ethernet device settings |
See ip(8) and IPROUTE2 Utility Suite Howto.
You may use low level network commands as follows safely since they do not change network configuration.
Table 5.16. List of low level network commands
| command | description |
|---|---|
ifconfig
|
display the link and address status of active interfaces |
ip addr show
|
display the link and address status of active interfaces |
route -n
|
display all the routing table in numerical addresses |
ip route show
|
display all the routing table in numerical addresses |
arp
|
display the current content of the ARP cache tables |
ip neigh
|
display the current content of the ARP cache tables |
plog
|
display ppp daemon log |
ping yahoo.com
|
check the Internet connection to "yahoo.com"
|
whois yahoo.com
|
check who registered "yahoo.com" in the domains database
|
traceroute yahoo.com
|
trace the Internet connection to "yahoo.com"
|
tracepath yahoo.com
|
trace the Internet connection to "yahoo.com"
|
mtr yahoo.com
|
trace the Internet connection to "yahoo.com" (repeatedly)
|
dig [@dns-server.com] example.com [{a|mx|any}]
|
check DNS records of "example.com" by "dns-server.com" for a "a", "mx", or "any" record
|
iptables -L -n
|
check packet filter |
netstat -a
|
find all open ports |
netstat -l --inet
|
find listening ports |
netstat -ln --tcp
|
find listening TCP ports (numeric) |
dlint example.com
|
check DNS zone information of "example.com"
|
|
Tip |
|---|---|
Some of these low level network configuration tools reside in " |
Generic network optimization is beyond the scope of this documentation. I touch only subjects pertinent to the consumer grade connection.
Table 5.17. List of network optimization tools
The Maximum Transmission Unit (MTU) value can be determined experimentally with ping(8) with "-M do" option which sends ICMP packets with data size starting from 1500 (with offset of 28 bytes for the IP+ICMP header) and finding the largest size without IP fragmentation.
For example, try the following
$ ping -c 1 -s $((1500-28)) -M do www.debian.org PING www.debian.org (194.109.137.218) 1472(1500) bytes of data. From 192.168.11.2 icmp_seq=1 Frag needed and DF set (mtu = 1454) --- www.debian.org ping statistics --- 0 packets transmitted, 0 received, +1 errors
Try 1454 instead of 1500
You see ping(8) succeed with 1454.
This process is Path MTU (PMTU) discovery (RFC1191) and the tracepath(8) command can automate this.
|
Tip |
|---|---|
The above example with PMTU value of 1454 is for my previous FTTP provider which used Asynchronous Transfer Mode (ATM) as its backbone network and served its clients with the PPPoE. The actual PMTU value depends on your environment, e.g., 1500 for the my new FTTP provider. |
Table 5.18. Basic guide lines of the optimal MTU value
| network environment | MTU | rationale |
|---|---|---|
| Dial-up link (IP: PPP) | 576 | standard |
| Ethernet link (IP: DHCP or fixed) | 1500 | standard and default |
| Ethernet link (IP: PPPoE) | 1492 (=1500-8) | 2 bytes for PPP header and 6 bytes for PPPoE header |
| Ethernet link (ISP's backbone: ATM, IP: DHCP or fixed) | 1462 (=48*31-18-8) | author's speculation: 18 for Ethernet header, 8 for SAR trailer |
| Ethernet link (ISP's backbone: ATM, IP: PPPoE) | 1454 (=48*31-8-18-8) | see "Optimal MTU configuration for PPPoE ADSL Connections" for rationale |
In addtion to these basic guide lines, you should know the following.
Any use of tunneling methods (VPN etc.) may reduce optimal MTU further by their overheads.
The MTU value should not exceed the experimentally determined PMTU value.
The bigger MTU value is generally better when other limitations are met.
Here are examples for setting the MTU value from its default 1500 to 1454.
For the DHCP (see Section 5.5.4, “The network interface served by the DHCP”), you can replace pertinent iface stanza lines in the "/etc/network/interfaces" with the following.
iface eth0 inet dhcp pre-up /sbin/ifconfig $IFACE mtu 1454
For the static IP (see Section 5.5.5, “The network interface with the static IP”), you can replace pertinent iface stanza lines in the "/etc/network/interfaces" with the following.
iface eth0 inet static address 192.168.11.100 netmask 255.255.255.0 gateway 192.168.11.1 mtu 1454 dns-domain example.com dns-nameservers 192.168.11.1
For the direct PPPoE (see Section 5.4.5, “The PPPoE connection with pppoeconf”), you can replace pertinent "mtu" line in the "/etc/ppp/peers/dsl-provider" with the following.
mtu 1454
The maximum segment size (MSS) is used as an alternative measure of packet size. The relationship between MSS and MTU are the following.
MSS = MTU - 40 for IPv4
MSS = MTU - 60 for IPv6
|
Note |
|---|---|
The iptables(8) (see Section 5.9, “Netfilter infrastructure”) based optimization can clamp packet size by the MSS and is useful for the router. See "TCPMSS" in iptables(8). |
The TCP throughput can be maximized by adjusting TCP buffer size parameters as described in "TCP Tuning Guide" and "TCP tuning" for the modern high-bandwidth and high-latency WAN. So far, the current Debian default settings serve well even for my LAN connected by the fast 1G bps FTTP service.
Netfilter provides infrastructure for stateful firewall and network address translation (NAT) with Linux kernel modules (see Section 3.5.12, “The kernel module initialization”).
Table 5.19. List of firewall tools
| packages | popcon | size | description |
|---|---|---|---|
iptables
|
http://qa.debian.org/popcon.php?package=iptables | 1366 | administration tools for netfilter |
iptstate
|
http://qa.debian.org/popcon.php?package=iptstate | 164 | continuously monitor netfilter state (similar to top(1)) |
shorewall-init
|
http://qa.debian.org/popcon.php?package=shorewall-init | 95 | Shoreline Firewall initialization |
shorewall
|
http://qa.debian.org/popcon.php?package=shorewall | 1676 | Shoreline Firewall, netfilter configuration file generator |
shorewall-lite
|
http://qa.debian.org/popcon.php?package=shorewall-lite | 119 | Shoreline Firewall, netfilter configuration file generator (light version) |
shorewall6
|
http://qa.debian.org/popcon.php?package=shorewall6 | 701 | Shoreline Firewall, netfilter configuration file generator (IPv6 version) |
shorewall6-lite
|
http://qa.debian.org/popcon.php?package=shorewall6-lite | 117 | Shoreline Firewall, netfilter configuration file generator (IPv6, light version) |
Main user space program of netfilter is iptables(8). You can manually configure netfilter interactively from shell, save its state with iptables-save(8), and restore it via init script with iptables-restore(8) upon system reboot.
Configuration helper scripts such as shorewall ease this process.
See documentations at http://www.netfilter.org/documentation/ (or in "/usr/share/doc/iptables/html/").
|
Tip |
|---|---|
Although these were written for Linux 2.4, both iptables(8) command and netfilter kernel function apply for current Linux 2.6. |
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| Chapter 4. Authentication |  |
Chapter 6. Network applications |