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Linux Networking

Linux Networking. TCP/IP stack kernel controls the TCP/IP protocol Ethernet adapter is hooked to the kernel in with the ipconfig command ifconfig sets the ip address as well as netmask and broadcast addresses. Network Hardware.

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Linux Networking

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  1. Linux Networking • TCP/IP stack • kernel controls the TCP/IP protocol • Ethernet adapter is hooked to the kernel in with the ipconfig command • ifconfig sets the ip address as well as netmask and broadcast addresses

  2. Network Hardware • Typically linux finds the NIC (PCI) at bootup but the administrator needs to tell linux that the card is to be enabled. • If linux doesn’t discover the NIC (network interface card) you must assign the card type, interrupt and base address for the card in the linux kernel.

  3. Ipconfig • ifconfig eth0 addr 129.123.109.154 broadcast 129.123.7.255 netmask 255.255.255.0 • Netmask forces TCP/IP to go only to the router interface for any address except those in 129.123.7. • Broadcast limits broadcasts to the 129.123.7 subnet

  4. DHCP • Dynamic Host Configuration Protocol • Allows the client to grab TCP/IP setup information from a centralized service • The client broadcasts the request over the ethernet interface. • The router recognizes the DHCP request and forwards that request to a server or system that is configured into the router as a DHCP device.

  5. Name Service • DHCP typically assigns the nameservers for the linux box. DHCP does not assign the search domain for the box. • Name resolution configuration is done in the /etc/resolv.conf file. • If the domain search field is set to usu.edu then you can access: cc.usu.edu as just cc. If you want to contact www.cs.usu.edu you would have to use www.cs • If the domain search field is usu.edu and cs.usu.edu then you can access www.cs.usu.edu as www. • The ambiguity is: What if you want www.usu.edu and not www.cs.usu.edu. • You would then need to use the fully qualified host name to contact the site you desire.

  6. Routers • Routers are added via DHCP or the route command. • The default route for a system is the address that all of the packets flow if they are resolved elsewhere. • Other routers may be defined using appropriate netmasks and ip addresses. • Since route configuration may follow indistinct paths the configuration may have to tell route how may hops (intermediate routers) there are between the local box and the actual ‘default’ router.

  7. Linux Network Features • NFS • Network File System • Centralized File sharing • NIS (Yellow Pages) • Centralized password/authentication system

  8. NFS Server Setup • NFS Server enabled • RPC server enabled • /etc/exportfs file created • /usr/local –o ro sys1,sys2,sys3 • /home/users –o rw sys1,sys2,sys3

  9. NFS Client Setup • Run mountd, lockd, statd • Mount the remote disk as: • mount –o ro server.cs.usu.edu:/usr/local /usr/local

  10. NIS Server Setup • Domainname • This is the YP domainname not necessarily the DNS domain name • ypserve, set up the yp server as a master • ypbind, bind to the server • yppasswdd, the password changing daemon • Create the maps with ypmake

  11. NIS Client Setup • Set the yp domainname • Bind to the server • ypbind • Add wildcard info to the /etc/passwd and /etc/group files (+::::::::) • Add wildcard to other files as needed

  12. PPP (dialup) • PPP will automatically configure the linux box to act as a router for the dialin users. • When a user dials in, the PPP protocol typically starts immediately so the user doesn’t see a login prompt. • The PPP (CHAP/PAP) authorization is built into the protocol. • NAT (Network Address Translation) will allow the linux box to take packets from systems on an internal (non-routable) address and translate those requests to the address of the router interface.

  13. Linux as a router • The linux box can handle up to 4 NIC (network interface cards) to act as a router for a wide area network and 3 internal networks. • With this configuration the linux box can act as a firewall. • The program routed handles the packet exchange between boards. • Care must be exercised in configuring routed so that packets are misrouted, i.e. packets are sent to the wrong interface. • One of the interfaces is the WAN and should be listed as the default router.

  14. IP access control • Ipchains and iptables can limit packets (by address and port) in either direction (coming in to the box or going out of the box) • If a particular address needs to be filtered then ipchains or iptables can block that address and never even look a which port it’s want to attach to. • IP access can be controlled (filtered) by using ipchains or iptabels on the linux box. • Ipchains or iptables can also limit which service (port) is available to outside addresses.

  15. Xinetd • Xinetd controls which services are accessible from the internet • The port numbers xinetd translate into service names are located in /etc/services. • Xinetd controls what process owns the service and what flags are passed to the service program. • Xinetd times outs the service program when the internet user completes to that memory and CPU time are freed.

  16. Xinetd server programming • Xinetd redirects input that would be from stdin and takes that from the IP packets • Xinetd redirects output that would go to stdout and puts them into the IP packets. • If a program is dispatched through xinetd then all I/O can be done via stdin and stdout

  17. Background Programs • The xinetd system has a time latency since packets need to be dispatched and the a program must start before the service can begin. • To enhance network speed a program can be started at boot time and run in the background. • These programs must communicate with the TCP/IP stack using system calls. Stdin and stdout calls will be lost or redirected to system logs and not the network.

  18. Network Programs • High network intensive programs need to run at all times on the system. Examples are: • Web servers (http) • May run several processes to gain throughput • Network file services • Remote Procedure Call programs • Mail • Low impact programs • telnet • ftp • Time • news

  19. Network monitoring • ping echo test • traceroute check the router path • netstat • -r show the routing table • -i shows the interfaces • -p what program is doing network stuff • No option • What is presently going on

  20. External Tools • Sniffer, snoop, tcpdump • Look at packets on the wire • Scanner (nmap) • What ports are open? • Security checks • Mail relays, writeable anonymous ftp

  21. Class Evaluations • Remember to do the evaluations!

  22. December 5, 2002 The End

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