Linux IP Masquerade mini HOWTO Ambrose Au, achau@wwonline.com v1.00, 1 January 1997 This document describes how to enable IP masquerade feature on a Linux host, allowing connected computers that do not have registered Inter­ net IP addresses to connect to the Internet through your Linux box. 1. Introduction 1.1. Introduction This document describes how to enable IP masquerade feature on a Linux host, allowing connected computers that do not have registered Internet IP addresses to connect to the Internet through your Linux box. It is possible to connect your machines to the Linux host with ethernet, as well as other kinds of connection such as a dialup ppp link. This document will emphasize on ethernet connection, since it should be the most likely case. This document is intended for users using kernels 2.0.x. Development kernels 2.1.x are NOT covered. 1.2. Foreword, Feedback & Credits First of all, I would like to let you know that I am NOT a knowledgeable nor an experienced user of IP masquerade. I find it very confusing as a new user setting up IP masquerade on a newer kernel, i.e. 2.x kernel. Although there is a FAQ and a mailing list, there is no document dedicates on that; and there are some requests on the mailing list for such a HOWTO. So, I decided to write this up as a starting point for new users, and possibly a building block for knowledgeable users to build on for documentation. If you think I'm not doing a good job, feel free to tell me so that I can make it better. This document is heavily based on the original FAQ by Ken Eves , and numerous helpful messages in the ip_masq mailing list. And a special thanks to Mr. Matthew Driver whose mailing list message inspired me to set up ip_masq and eventually writing this. Please feel free to send any feedback or comments to achau@wwonline.com if I'm mistaken on any information, or if any information is missing. Your invaluable feedback will certainly be influencing the future of this HOWTO! This HOWTO is meant to be a quick guide to get your IP Masquerade working in the shortest time. The latest news and information can be found at the IP Masquerade Resource web page that I maintained. If you have any technical questions on IP Masquerade, please join the IP Masquerade Mailing List instead of sending email to me since I have limited time, and the developers of IP_Masq are more capable of answering your questions. The latest version of this document can be found at the IP Masquerade Resource, which also contains the HTML and postscript version: · http://www.wwonline.com/~achau/ipmasq/ · http://www.hwy401.com/achau/ipmasq/ · http://www.leg.uct.ac.za/mirrors/ipmasq/ · http://130.89.230.132/linux/ipmasq/ 1.3. Copyright & Disclaimer This document is copyright(c) 1996 Ambrose Au, and it's a free document. You can redistribute it under the terms of the GNU General Public License. The information and other contents in this document are to the best of my knowledge. However, ip_masq is experimental, and there is chance that I make mistakes as well; so you should determine if you want to follow the information in this document. Nobody is responsible for any damage on your computers and any other losses by using the information on this document. i.e. THE AUTHOR IS NOT RESPONSIBLE FOR ANY DAMAGES INCURRED DUE TO ACTIONS TAKEN BASED ON THE INFORMATION IN THIS DOCUMENT. 2. Background Knowledge 2.1. What is IP Masquerade? IP Masquerade is a developing networking function in Linux. If a Linux host is connected to the Internet with IP Masquerade enabled, then computers connecting to it (either on the same LAN or connected with modems) can reach the Internet as well, even though they have no official assigned IP addresses. This allows a set of machines to invisibly access the Internet hidden behind a gateway system, which appears to be the only system using the Internet. Breaking the security of a well set-up masquerading system should be considerably more difficult than breaking a good packet filter based firewall (assuming there are no bugs in either). 2.2. Current Status IP Masquerade is still at its experimental stages. However, kernels since 1.3.x had built-in support already. Many individuals and even companies are using it, with satisfactory results. Browsing web pages and telnet are reported to work well over ip_masq. FTP, IRC and listening to Real Audio are working with certain modules loaded. Other network streaming audio such as True Speech and Internet Wave work too. Some fellow users on the mailing list even tried video conferencing software. Ping is now working, with the newly available ICMP patch Please refer to section 4.3 for a more complete listing of software supported. IP Masquerade works well with 'client machines' on several different OS and platforms. There are successful cases with systems using Unix, Windows 95, Windows NT, Windows for Workgroup(with TCP/IP package), OS/2, Macintosh System's OS with Mac TCP, Mac Open Transport, DOS with NCSA Telnet package, VAX, Alpha with Linux, and even Amiga with AmiTCP or AS225-stack. 2.3. Who Can Benefit From IP Masquerade? · If you have a Linux host connected to the Internet, and · if you have some computers running TCP/IP connected to that Linux box on a local subnet, and/or · if your Linux host has more than one modem and acts as a PPP or SLIP server connecting to others, which · those OTHER machines do not have official assigned IP addresses. (these machines are represented by OTHER machines hereby) · And of course, if you want those OTHER machines to make it onto the Internet without spending extra bucks :) 2.4. Who Doesn't Need IP Masquerade? · If your machine is a stand-alone Linux host connected to the Internet, then it is pointless to have ip_masq running, or · if you already have assigned addresses for your OTHER machines, then you don't need IP Masquerade, · and of course, if you don't like the idea of a 'free ride'. 2.5. How IP Masquerade Works? From IP Masquerade FAQ by Ken Eves: Here is a drawing of the most simple setup: SLIP/PPP +------------+ +-------------+ to provider | Linux | SLIP/PPP | Anybox | <---------- modem1| |modem2 ----------- modem | | 111.222.333.444 | | 192.168.1.100 | | +------------+ +-------------+ In the above drawing a Linux box with ip_masquerading installed and running is connected to the Internet via SLIP/or/PPP using modem1. It has an assigned IP address of 111.222.333.444. It is setup that modem2 allows callers to login and start a SLIP/or/PPP connection. The second system (which doesn't have to be running Linux) calls into the Linux box and starts a SLIP/or/PPP connection. It does NOT have an assigned IP address on the Internet so it uses 192.168.1.100. (see below) With ip_masquerade and the routing configured properly the machine Anybox can interact with the Internet as if it was really connected (with a few exceptions). Quoting Pauline Middelink: Do not forget to mention the ANYBOX should have the Linux box as its gateway (whether is be the default route or just a subnet is no matter). If the ANYBOX can not do this, the Linux machine should do a proxy arp for all routed address, but the setup of proxy arp is beyond the scope of the document. The following is an excerpt from a post on comp.os.linux.networking which has been edited to match the names used in the above example: o I tell machine ANYBOX that my slipped linux box is its gateway. o When a packet comes into the linux box from ANYBOX, it will assign it new source port number, and slap its own ip address in the packet header, saving the originals. It will then send the modified packet out over the SLIP/or/PPP interface to the Internet. o When a packet comes from the Internet to the linux box, if the port number is one of those assigned above, it will get the original port and ip address, put them back in the packet header, and send the packet to ANYBOX. o The host that sent the packet will never know the difference. An IP Masquerading Example typical example is given in the diagram below:- +----------+ | | Ethernet | abox |:::::: | |2 :192.168.1.x +----------+ : : +----------+ PPP +----------+ : 1| Linux | link | | ::::| masq-gate|:::::::::// Internet | bbox |:::::: | | | |3 : +----------+ +----------+ : : +----------+ : | | : | cbox |:::::: | |4 +----------+ <-Internal Network-> In this example there are 4 computer systems that we are concerned about (there is presumably also something on the far right that your IP connection to the internet comes through, and there is something (far off the page) on the internet that you are interested in exchang­ ing information with). The Linux system masq-gate is the masquerading gateway for the internal network of machines abox, bbox and cbox to get to the internet. The internal network uses one of the assigned private network addresses, in this case the class C network 192.168.1.0, with the linux box having address 192.168.1.1 and the other systems having addresses on that network. The three machines abox, bbox and cbox (which can, by the way, be running any operating system as long as they can speak IP - such as Windows 95, Macintosh MacTCP or even another linux box) can connect to other machines on the internet, however the masquerading system masq- gate converts all of their connections so that they appear to originate from masq-gate, and arranges that data coming back in to a masqueraded connection is relayed back to the originating system - so the systems on the internal network see a direct route to the internet and are unaware that their data is being masqueraded. 2.6. Requirements for Using IP Masquerade on Linux 2.x · Kernel 2.0.x source available from ftp://ftp.funet.fi/pub/Linux/kernel/src/v2.0/ (Yes, you'll have to compile your kernel with certain supports.... The latest stable kernel is recommended) · Loadable kernel modules, preferably 2.0.0 or newer available from http://www.pi.se/blox/modules/modules-2.0.0.tar.gz (modules-1.3.57 is the minimal requirement) · A well set up TCP/IP network covered in Linux NET-2 HOWTO and the Network Administrator's Guide · Connectivity to Internet for your Linux host covered in Linux ISP Hookup HOWTO , Linux PPP HOWTO and Linux PPP-over-ISDN mini-HOWTO · Ipfwadm 2.3 or newer available from ftp://ftp.xos.nl/pub/linux/ipfwadm/ipfwadm-2.3.tar.gz more information on version requirement is on the Linux Ipfwadm page · You can optionally apply some IP Masquerade patches to enable other functionality. More information availabe on IP Masquerade Resources (these patches apply to all 2.0.x kernels) 3. Setting Up IP Masquerade If your private network contains any vital information, think twice before using IP Masquerade. This may be a GATE­ WAY for you to get to the Internet, and vice versa for some­ one on the other side of the world to get into your network. 3.1. Compiling the Kernel for IP Masquerade Support · First of all, you need the kernel source (preferably stable kernel version 2.0.0 or above) · If this is your first time compiling the kernel, don't be scared. In fact, it's rather easy and it's covered in Linux Kernel HOWTO . · Unpack the kernel source to /usr/src/ with a command: tar xvzf linux-2.0.x.tar.gz -C /usr/src, where x is the patch level beyond 2.0 (make sure there is a directory or symbolic link called linux ) · Apply appropriate patches. Since new patches are coming out, details will not be included here. Please refer to IP Masquerade Resources for up-to-date information. · Refer to the Kernel HOWTO and the README file in the kernel source directory for further instructions on compiling a kernel · Here are the options that you need to compile in: Say YES to the following, * Prompt for development and/or incomplete code/drivers CONFIG_EXPERIMENTAL - this will allow you to select experimental ip_masq code compiled into the kernel * Enable loadable module support CONFIG_MODULES - allows you to load modules * Networking support CONFIG_NET * Network firewalls CONFIG_FIREWALL * TCP/IP networking CONFIG_INET * IP: forwarding/gatewaying CONFIG_IP_FORWARD * IP: firewalling CONFIG_IP_FIREWALL * IP: masquerading (EXPERIMENTAL) CONFIG_IP_MASQUERADE - although it is experimental, it is a *MUST* * IP: always defragment CONFIG_IP_ALWAYS_DEFRAG - highly recommended * Dummy net driver support CONFIG_DUMMY - recommended NOTE: These are just the component you need for ip_masq, select whatever other options you need for your specific setup. · After compiling the kernel, you should compile and install the modules: make modules; make modules_install · Then you should add a few lines into your /etc/rc.d/rc.local file (or any file you think is appropriate) to load the required modules reside in /lib/modules/2.0.x/ipv4/ automatically during each reboot: . . . /sbin/depmod -a /sbin/modprobe ip_masq_ftp /sbin/modprobe ip_masq_raudio /sbin/modprobe ip_masq_irc (and other modules such as ip_masq_cuseeme, ip_masq_vdolive if you have applied the patches) . . . Note: You can also load it manually before using ip_masq, but DON'T use kerneld for this, it will NOT work! 3.2. Assigning Private Network IP Address Since all OTHER machines do not have official assigned addressees, there must be a right way to allocate address to those machines. From IP Masquerade FAQ: There is an RFC (#1597) on which IP addresses are to be used on a non- connected network. There are 3 blocks of numbers set aside specifically for this purpose. One which I use is 255 Class-C subnets at 192.168.1.n to 192.168.255.n . From RCF 1597: Section 3: Private Address Space The Internet Assigned Numbers Authority (IANA) has reserved the following three blocks of the IP address space for private networks: 10.0.0.0 - 10.255.255.255 172.16.0.0 - 172.31.255.255 192.168.0.0 - 192.168.255.255 We will refer to the first block as "24-bit block", the second as "20-bit block", and to the third as "16-bit" block". Note that the first block is nothing but a single class A network number, while the second block is a set of 16 contiguous class B network numbers, and third block is a set of 255 contiguous class C network numbers. So, if you're using a class C network, you should name your machines as 192.168.1.1, 1.92.168.1.2, 1.92.168.1.3, ..., 192.168.1.x 192.168.1.1 is usually the gateway machine, which is your Linux host connecting to the Internet. Notice that 192.168.1.0 and 192.168.1.255 are the Network and Broadcast address respectively, which are reserved. Avoid using these addresses on your machines. 3.3. Configuring the OTHER machines Besides setting the appropriate IP address for each machine, you should also set the appropriate gateway. In general, it is rather straight forward. You simply enter the address of your Linux host (usually 192.168.1.1) as the gateway address. For the Domain Name Service, you can add in any DNS available. The most apparent one should be the one that your Linux is using. You can optionally add any domain search suffix as well. After you have reconfigured those IP addresses, remember to restart the appropriate services or reboot your systems. The following configuration instructions assume that you are using a Class C network with 192.168.1.1 as your Linux host's address. Please note that 192.168.1.0 and 192.168.1.255 are reserved. 3.3.1. Configuring Windows 95 1. If you haven't installed your network card and adapter driver, do so now. 2. Go to 'Control Panel'/'Network'. 3. Add 'TCP/IP protocol' if you don't already have it. 4. In 'TCP/IP properties', goto 'IP Address' and set IP Address to 192.168.1.x, (1 < x < 255), and then set Subnet Mask to 255.255.255.0 5. Add 192.168.1.1 as your gateway under 'Gateway'. 6. Under 'DNS Configuration'/'DNS Server search order' add your the DNS that your Linux host uses (usually find in /etc/resolv.conf). Optionally, you can add the appropriate domain search suffix. 7. Leave all the other settings as they are unless you know what you're doing. 8. Click 'OK' on all dialog boxes and restart system. 9. Ping the linux box to test the network connection: 'Start/Run', type: ping 192.168.1.1 (This is only a LAN connection testing, you can't ping the outside world yet.) 10. You can optionally create a HOSTS file in the windows directory so that you can use hostname of the machines on your LAN. There is an example called HOSTS.SAM in the windows directory. 3.3.2. Configuring Windows for Workgroup 3.11 1. If you haven't installed your network card and adapter driver, do so now. 2. Install the TCP/IP 32b package if you don't have it already. 3. In 'Main'/'Windows Setup'/'Network Setup', click on 'Drivers'. 4. Highlight 'Microsoft TCP/IP-32 3.11b' in the 'Network Drivers' section, click 'Setup'. 5. Set IP Address to 192.168.1.x (1 < x < 255), then set Subnet Mask to 255.255.255.0 and Default Gateway to 192.168.1.1 6. Do not enable 'Automatic DHCP Configuration' and put anything in those 'WINS Server' input areas unless you're in a Windows NT domain and you know what you're doing. 7. Click 'DNS', fill in the appropriate information mentioned in STEP 6 of section 3.3.1, then click 'OK' when you're done with it. 8. Click 'Advanced', check 'Enable DNS for Windows Name Resolution' and 'Enable LMHOSTS lookup' if you're using a look up host file, similar to the one mentioned in STEP 10 of section 3.3.1 9. Click 'OK' on all dialog boxes and restart system. 10. Ping the linux box to test the network connection: 'File/Run', type: ping 192.168.1.1 (This is only a LAN connection testing, you can't ping the outside world yet.) 3.3.3. Configuring Windows NT 3.51 1. If you haven't installed your network card and adapter driver, do so now. 2. Go to 'Main'/'Control Panel'/'Network' 3. Add the TCP/IP Protocol and Related Component from the 'Add Software' menu if you don't have TCP/IP service installed already. 4. Under 'Network Software and Adapter Cards' section, highlight 'TCP/IP Protocol' in the 'Installed Network Software' selection box. 5. In 'TCP/IP Configuration', select the appropriate adapter, e.g. [1]Novell NE2000 Adapter. Then set the IP Address to 192.168.1.x (1 < x < 255), then set Subnet Mask to 255.255.255.0 and Default Gateway to 192.168.1.1 6. Do not enable 'Automatic DHCP Configuration' and put anything in those 'WINS Server' input areas unless you're in a Windows NT domain and you know what you're doing. 7. Click 'DNS', fill in the appropriate information mentioned in STEP 6 of section 3.3.1, then click 'OK' when you're done with it. 8. Click 'Advanced', check 'Enable DNS for Windows Name Resolution' and 'Enable LMHOSTS lookup' if you're using a look up host file, similar to the one mentioned in STEP 10 of section 3.3.1 9. Click 'OK' on all dialog boxes and restart system. 10. Ping the linux box to test the network connection: 'File/Run', type: ping 192.168.1.1 (This is only a LAN connection testing, you can't ping the outside world yet.) 3.3.4. Configuring UNIX Based Systems 1. If you haven't installed your network card and recompile your kernel with the appropriate adapter driver, do so now. 2. Install TCP/IP networking, such as the nettools package, if you don't have it already. 3. Set IPADDR to 192.168.1.x (1 < x < 255), then set NETMASK to 255.255.255.0, GATEWAY to 192.168.1.1, and BROADCAST to 192.168.1.255 For example, you can edit the /etc/sysconfig/network-scripts/ifcfg- eth0 file on a Red Hat Linux system, or simply do it through the Control Panel. (it's different in SunOS, BSDi, Slackware Linux, etc...) 4. Add your domain name service (DNS) and domain search suffix in /etc/resolv.conf 5. You may want to update your /etc/networks file depending on your settings. 6. Restart the appropriate services, or simply restart your system. 7. Issue a ping command: ping 192.168.1.1 to test the connection to your gateway machine. (This is only a LAN connection testing, you can't ping the outside world yet.) 3.3.5. Configuring DOS using NCSA Telnet package 1. If you haven't installed your network card, do so now. 2. Load the appropriate packet driver. For an NE2000 card, issue nwpd 0x60 10 0x300, with your network card set to IRQ 10 and hardware address at 0x300 3. Make a new directory, and then unpack the NCSA Telnet package: pkunzip tel2308b.zip 4. Use a text editor to open the config.tel file 5. Set myip=192.168.1.x (1 < x < 255), and netmask=255.255.255.0 6. In this example, you should set hardware=packet, interrupt=10, ioaddr=60 7. You should have at least one individual machine specification set as the gateway, i.e. the Linux host: name=default host=yourlinuxhostname hostip=192.168.1.1 gateway=1 8. Have another specification for a domain name service: name=dns.domain.com ; hostip=123.123.123.123; nameserver=1 Note: substitute the appropriate information about the DNS that your Linux host uses 9. Save your config.tel file 10. Telnet to the linux box to test the network connection: telnet 192.168.1.1 3.3.6. Configuring MacOS Based System Running MacTCP 1. If you haven't installed the appropriate driver software for your Ethernet adapter, now would be a very good time to do so. 2. Open the MacTCP control panel. Select the appropriate network driver (Ethernet, NOT EtherTalk) and click on the 'More...' button. 3. Under 'Obtain Address:', click 'Manually'. 4. Under 'IP Address:', select class C from the popup menu. Ignore the rest of this section of the dialog box. 5. Fill in the appropriate information under 'Domain Name Server Information:'. 6. Under 'Gateway Address:', enter 192.168.1.1 7. Click 'OK' to save the settings. In the main window of the MacTCP control panel, enter the IP address of your Mac (192.168.1.x, 1 < x < 255) in the 'IP Address:' box. 8. Close the MacTCP control panel. If a dialog box pops up notifying you to do so, restart the system. 9. You may optionally ping the Linux box to test the network connection. If you have the freeware program MacTCP Watcher, click on the 'Ping' button, and enter the address of your Linux box (192.168.1.1) in the dialog box that pops up. (This is only a LAN connection testing, you can't ping the outside world yet.) 10. You can optionally create a Hosts file in your System Folder so that you can use the hostnames of the machines on your LAN. The file should already exist in your System Folder, and should contain some (commented-out) sample entries which you can modify according to your needs. 3.3.7. Configuring MacOS Based System Running Open Transport 1. If you haven't installed the appropriate driver software for your Ethernet adapter, now would be a very good time to do so. 2. Open the TCP/IP Control Panel and choose 'User Mode ...' from the Edit menu. Make sure the user mode is set to at least 'Advanced' and click the 'OK' button. 3. Choose 'Configurations...' from the File menu. Select your 'Default' configuration and click the 'Duplicate...' button. Enter 'IP Masq' (or something to let you know that this is a special configuration) in the 'Duplicate Configuration' dialog, it will probably say something like 'Deafault copy'. Then click the 'OK' button, and the 'Make Active' button 4. Select 'Ethernet' from the 'Connect via:' pop-up. 5. Select the appropriate item from the 'Configure:' pop-up. If you don't know which option to choose, you probably should re-select your 'Default' configuration and quit. I use 'Manually'. 6. Enter the IP address of your Mac (192.168.1.x, 1 < x < 255) in the 'IP Address:' box. 7. Enter 255.255.255.0 in the 'Subnet mask:' box. 8. Enter 192.168.1.1 in the 'Router address:' box. 9. Enter the IP addresses of your domain name servers in the 'Name server addr.:' box. 10. Enter the name of your Internet domain (e.g. 'microsoft.com') in the 'Starting domain name' box under 'Implicit Search Path:'. 11. The following procedures are optional. Incorrect values may cause erratic behavior. If your not sure, it's probably better to leave them blank, unchecked and/or un- selected. Remove any information from those fields, if necessary. As far as I know there is no way through the TCP/IP dialogs, to tell the system not to use a previously select alternate "Hosts" file. If you know, I would be interested. Check the '802.3' if your network requires 802.3 frame types. 12. Click the 'Options...' button to make sure that the TCP/IP is active. I use the 'Load only when needed' option. If you run and quit TCP/IP applications many times without rebooting your machine, you may find that unchecking the 'Load only when needed' option will prevent/reduce the effects on your machines memory management. With the item unchecked the TCP/IP protocol stacks are always loaded and available for use. If checked, the TCP/IP stacks are automatically loaded when needed and un- loaded when not. It's the loading and unloading process that can cause your machines memory to become fragmented. 13. You may ping the Linux box to test the network connection. If you have the freeware program MacTCP Watcher, click on the 'Ping' button, and enter the address of your Linux box (192.168.1.1) in the dialog box that pops up. (This is only a LAN connection testing, you can't ping the outside world yet.) 14. You can create a Hosts file in your System Folder so that you can use the hostnames of the machines on your LAN. The file may or may not already exist in your System Folder. If so, it should contain some (commented-out) sample entries which you can modify according to your needs. If not, you can get a copy of the file from a system running MacTCP, or just create your own (it follows a subset of the Unix /etc/hosts file format, described on page 33 of RFC 1035). Once you've created the file, open the TCP/IP control panel, click on the 'Select Hosts File...' button, and open the Hosts file. 15. Click the close box or choose 'Close' or 'Quit' from the File menu, and then click the 'Save' button to save the changes you have made. 16. The changes take effect immediately, but rebooting the system won't hurt. 3.3.8. Configuring Novell network using DNS 1. If you haven't installed the appropriate driver software for your Ethernet adapter, now would be a very good time to do so. 2. Downloaded tcpip16.exe from 3. edit c:\nwclient\startnet.bat SET NWLANGUAGE=ENGLISH LH LSL.COM LH KTC2000.COM LH IPXODI.COM LH tcpip LH VLM.EXE F: 4. edit c:\nwclient\net.cfg Link Driver KTC2000 Protocol IPX 0 ETHERNET_802.3 Frame ETHERNET_802.3 Frame Ethernet_II FRAME Ethernet_802.2 NetWare DOS Requester FIRST NETWORK DRIVE = F USE DEFAULTS = OFF VLM = CONN.VLM VLM = IPXNCP.VLM VLM = TRAN.VLM VLM = SECURITY.VLM VLM = NDS.VLM VLM = BIND.VLM VLM = NWP.VLM VLM = FIO.VLM VLM = GENERAL.VLM VLM = REDIR.VLM VLM = PRINT.VLM VLM = NETX.VLM Link Support Buffers 8 1500 MemPool 4096 Protocol TCPIP PATH SCRIPT C:\NET\SCRIPT PATH PROFILE C:\NET\PROFILE PATH LWP_CFG C:\NET\HSTACC PATH TCP_CFG C:\NET\TCP ip_address xxx.xxx.xxx.xxx ip_router xxx.xxx.xxx.xxx 5. and finally created c:\bin\resolv.cfg SEARCH DNS HOSTS SEQUENTIAL NAMESERVER 207.103.0.2 NAMESERVER 207.103.11.9 6. I hope this helps some people get their Novell Nets online, BTW this can be done using Netware 3.1x or 4.x 3.3.9. Configuring Other Systems such as OS/2 They should be following the same theory for setup. Check the sections above. If you're interested in writing about any of these systems such as OS/2, or any variations of UNIX based system, please send a detail setup instruction to achau@wwonline.com. 3.4. Configuring IP Forwarding Policies At this point, you should have your kernel and other required packages installed, as well as your modules loaded. Also, the IP addresses, gateway, and DNS should be all set on the OTHER machines. Now, the only thing left to do is to use ipfwadm to forward appropriate packets to the appropriate machine: ipfwadm -F -p deny ipfwadm -F -a m -S yyy.yyy.yyy.yyy/x -D 0.0.0.0/0 where x is one of the following numbers according to the class of your subnet, and yyy.yyy.yyy.yyy is your network address. netmask | x | Subnet ~~~~~~~~~~~~~~~~|~~~~|~~~~~~~~~~~~~~~ 255.0.0.0 | 8 | Class A 255.255.0.0 | 16 | Class B 255.255.255.0 | 24 | Class C 255.255.255.255 | 32 | Point-to-point For example, if I'm on a class C subnet, I would have entered: ipfwadm -F -p deny ipfwadm -F -a m -S 192.168.1.0/24 -D 0.0.0.0/0 The second command could have either -V 192.168.1.1 or -W eth0 added to it to ensure that the masqueraded packets came in through the appropriate interface of the system - if you are at all security concious (otherwise known as justifiably paranoid) then you will want to do this. Since bootp request packets comes without valid IP's once the client knows nothing about it, for people with a bootp server in the masquerade/firewall machine it is necessary to use the following before the deny command: ipfwadm -I -a accept -S 0/0 68 -D 0/0 67 -W bootp_clients_net_if_name -P udp You can also do it on a per machine basis. For example, if I want 192.168.1.2 and 192.168.1.8 to have access to the Internet, but not the other machines, I would have entered: ipfwadm -F -p deny ipfwadm -F -a m -S 192.168.1.2/32 -D 0.0.0.0/0 ipfwadm -F -a m -S 192.168.1.8/32 -D 0.0.0.0/0 Alternately, you can type the netmask instead of the value, e.g. 192.168.1.0/255.255.255.0 What appears to be a common mistake is to make the first command be this ipfwadm -F -p masquerade Do not make your default policy be masquerading - otherwise someone who can manipulate their routing will be able to tunnel straight back through your gateway, using it to masquerade their identity! Again, you can add these lines to the /etc/rc.local files, one of the rc files you prefer, or do it manually every time you need ip_masq. Please read section 4.4 for a detail guide on Ipfwadm 3.5. Testing IP Masquerade It's time to give it a try, after all these hard work. Make sure the connection of your Linux hosts to the Internet is okay. You can try browsing some 'INTERNET!!!' web sites on your OTHER machines, and see if you get it. I recommend using an IP address rather than a hostname on your first try, because your DNS setup may not be correct. For example, you can access Netscape's site http://home.netscape.com with an entry of http://198.95.249.78 If you see that nice sailboat, then congratulations! It's working! You may then try one with hostname entry, and then telnet, ftp, Real Audio, True Speech, whatever supported by IP Masquerade..... So far, I have no trouble with the above settings, and it's full credit to the people who spend their time making this wonderful feature working. 4. Other IP Masquerade Issues and Software Support 4.1. Problems with IP Masquerade Firstly masquerading can only work with ported protocols - such as TCP or UDP. It specifically will not work with ICMP, so ping and traceroute will not work (unless your ping and/or traceroute have been modified to use a different method of working). Some protocols will not currently work with masquerading because they either assume things about port numbers, or encode data in their data stream about addresses and ports - these latter protocols need specific proxies built into the masquerading code to make them work. 4.2. Incoming services Masquerading cannot handle incoming services at all. There are a few ways of allowing them, but they are completely separate from masquerading, and are really part of standard firewall practice. If you do not require high levels of security then you can simply redirect ports. There are various ways of doing this - I use a modified redir program (which I hope will be available from sunsite and mirrors soon). If you wish to have some level of authorisation on incoming connections then you can either use TCP wrappers or Xinetd on top of redir (0.7 or above) to allow only specific IP addresses through, or use some other tools. The TIS Firewall Toolkit is a good place to look for tools and information. 4.3. Supported Client Software and Other Setup Note Generally, application that uses TCP and UDP should work. If you have any suggestion about applications that are not compatible with IP Masquerade, please email to me with the name of client and a brief description. 4.3.1. Clients that Work General Clients HTTP all supported platforms, surfing the web POP & SMTP all supported platforms, email client Telnet all supported platforms, remote session FTP all supported platforms, with ip_masq_ftp.o module (not all sites work with certain clients; e.g. some sites cannot be reached using ws_ftp32 but works with netscape) Archie all supported platforms, file searching client (not all archie clients are supported) NNTP (USENET) all supported platforms, USENET news client VRML Windows(possibly all supported platforms), virtual reality surfing traceroute mainly UNIX based platforms, some variations may not work ping all platforms, with ICMP patch anything based on IRC all supported platforms, with ip_masq_irc.o modules Gopher client all supported platforms WAIS client all supported platforms Multimedia Clients Real Audio Player Windows, network streaming audio, with ip_masq_raudio module loaded True Speech Player 1.1b Windows, network streaming audio Internet Wave Player Windows, network streaming audio Worlds Chat 0.9a Windows, Client-Server 3D chat program Alpha Worlds Windows, Client-Server 3D chat program Internet Phone 3.2 Windows, Peer-to-peer audio communications, people can reach you only if you initiate the call, but people cannot call you Powwow Windows, Peer-to-peer Text audio whiteboard communications, people can reach you only if you initiate the call, but people cannot call you CU-SeeMe all supported platforms, with cuseeme modules loaded, please see IP Masquerade Resource for detail VDOLive Windows, with vdolive patch Note: Some clients such as IPhone and Powwow may work even if you're not the one who initiate the call by using ipautofw package (refer to section 4.6) Other Clients NCSA Telnet 2.3.08 DOS, a suite containing telnet, ftp, ping, etc. PC-anywhere for windows 2.0 MS-Windows, Remotely controls a PC over TCP/IP, only work if it is a client but not a host Socket Watch uses ntp - network time protocol Linux net-acct package Linux, network administration-account package 4.3.2. Clients that do not Work Intel Internet Phone Beta 2 Connects but voice travels one way (out) Traffic only Intel Streaming Media Viewer Beta 1 Cannot connect to server Netscape CoolTalk Cannot connect to opposite side talk,ntalk will not work - requires a kernel proxy to be written. WebPhone Cannot work at present (it makes invalid assumptions about addresses). X Untested, but I think it cannot work unless someone builds an X proxy, which is probably an external program to the masquerading code. One way of making this work is to use ssh as the link and use the internal X proxy of that to make things work! 4.3.3. Platforms/OS Tested as on OTHER machines · Linux · Solaris · Windows 95 · Windows NT (both workstation and server) · Windows For Workgroup 3.11 (with TCP/IP package) · Windows 3.1 (with Chameleon package) · Novel 4.01 Server · OS/2 (including Warp v3) · Macintosh OS (with MacTCP or Open Transport) · DOS (with NCSA Telnet package, DOS Trumpet works partially) · Amiga (with AmiTCP or AS225-stack) · VAX Stations 3520 and 3100 with UCX (TCP/IP stack for VMS) · Alpha/AXP with Linux/Redhat · SCO Openserver (v3.2.4.2 and 5) · IBM RS/6000 running AIX · (Anyone tried other platforms?) 4.4. IP Firewall Administration (ipfwadm) This section provides a more in-depth guide on using ipfwadm. This is a setup for a firewall/masquerade system behind a PPP link with a static PPP address follows. Trusted interface is 192.168.255.1, PPP interface has been changed to protect the guilty :). I listed each incoming and outgoing interface individually to catch IP spoofing as well as stuffed routing and/or masquerading. Also anything not explicitly allowed is forbidden! #!/bin/sh # # /etc/rc.d/rc.firewall, define the firewall configuration, invoked from # rc.local. # PATH=/sbin:/bin:/usr/sbin:/usr/bin # testing, wait a bit then clear all firewall rules. # uncomment following lines if you want the firewall to automatically # disable after 10 minutes. # (sleep 600; \ # ipfwadm -I -f; \ # ipfwadm -I -p accept; \ # ipfwadm -O -f; \ # ipfwadm -O -p accept; \ # ipfwadm -F -f; \ # ipfwadm -F -p accept; \ # ) & # Incoming, flush and set default policy of deny. Actually the default policy # is irrelevant because there is a catch all rule with deny and log. ipfwadm -I -f ipfwadm -I -p deny # local interface, local machines, going anywhere is valid ipfwadm -I -a accept -V 192.168.255.1 -S 192.168.0.0/16 -D 0.0.0.0/0 # remote interface, claiming to be local machines, IP spoofing, get lost ipfwadm -I -a deny -V your.static.PPP.address -S 192.168.0.0/16 -D 0.0.0.0/0 -o # remote interface, any source, going to permanent PPP address is valid ipfwadm -I -a accept -V your.static.PPP.address -S 0.0.0.0/0 -D your.static.PPP.address/32 # loopback interface is valid. ipfwadm -I -a accept -V 127.0.0.1 -S 0.0.0.0/0 -D 0.0.0.0/0 # catch all rule, all other incoming is denied and logged. pity there is no # log option on the policy but this does the job instead. ipfwadm -I -a deny -S 0.0.0.0/0 -D 0.0.0.0/0 -o # Outgoing, flush and set default policy of deny. Actually the default policy # is irrelevant because there is a catch all rule with deny and log. ipfwadm -O -f ipfwadm -O -p deny # local interface, any source going to local net is valid ipfwadm -O -a accept -V 192.168.255.1 -S 0.0.0.0/0 -D 192.168.0.0/16 # outgoing to local net on remote interface, stuffed routing, deny ipfwadm -O -a deny -V your.static.PPP.address -S 0.0.0.0/0 -D 192.168.0.0/16 -o # outgoing from local net on remote interface, stuffed masquerading, deny ipfwadm -O -a deny -V your.static.PPP.address -S 192.168.0.0/16 -D 0.0.0.0/0 -o # outgoing from local net on remote interface, stuffed masquerading, deny ipfwadm -O -a deny -V your.static.PPP.address -S 0.0.0.0/0 -D 192.168.0.0/16 -o # anything else outgoing on remote interface is valid ipfwadm -O -a accept -V your.static.PPP.address -S your.static.PPP.address/32 -D 0.0.0.0/0 # loopback interface is valid. ipfwadm -O -a accept -V 127.0.0.1 -S 0.0.0.0/0 -D 0.0.0.0/0 # catch all rule, all other outgoing is denied and logged. pity there is no # log option on the policy but this does the job instead. ipfwadm -O -a deny -S 0.0.0.0/0 -D 0.0.0.0/0 -o # Forwarding, flush and set default policy of deny. Actually the default policy # is irrelevant because there is a catch all rule with deny and log. ipfwadm -F -f ipfwadm -F -p deny # Masquerade from local net on local interface to anywhere. ipfwadm -F -a masquerade -W ppp0 -S 192.168.0.0/16 -D 0.0.0.0/0 # catch all rule, all other forwarding is denied and logged. pity there is no # log option on the policy but this does the job instead. ipfwadm -F -a deny -S 0.0.0.0/0 -D 0.0.0.0/0 -o You can block traffic to a particular site using the -I, -O or -F. Remember that the set of rules are scanned top to bottom and -a means "append" to the existing set of rules so any restrictions need to come before global rules. For example (and untested) :- Using -I rules. Probably the fastest but it only stops the local machines, the firewall itself can still access the "forbidden" site. Of course you might want to allow that combination. # reject and log local interface, local machines going to 204.50.10.13 ipfwadm -I -a reject -V 192.168.255.1 -S 192.168.0.0/16 -D 204.50.10.13/32 -o # local interface, local machines, going anywhere is valid ipfwadm -I -a accept -V 192.168.255.1 -S 192.168.0.0/16 -D 0.0.0.0/0 Using -O rules. Slowest because the packets go through masquerading first but this rule even stops the firewall accessing the forbidden site. # reject and log outgoing to 204.50.10.13 ipfwadm -O -a reject -V your.static.PPP.address -S your.static.PPP.address/32 -D 204.50.10.13/32 -o # anything else outgoing on remote interface is valid ipfwadm -O -a accept -V your.static.PPP.address -S your.static.PPP.address/32 -D 0.0.0.0/0 Using -F rules. Probably slower than -I and this still only stops masqueraded machines (i.e. internal), firewall can still get to forbidden site. # Reject and log from local net on PPP interface to 204.50.10.13. ipfwadm -F -a reject -W ppp0 -S 192.168.0.0/16 -D 204.50.10.13/32 -o # Masquerade from local net on local interface to anywhere. ipfwadm -F -a masquerade -W ppp0 -S 192.168.0.0/16 -D 0.0.0.0/0 No need for a special rule to allow 192.168.0.0/16 to go to 204.50.11.0, it is covered by the global rules. There is more than one way of coding the interfaces in the above rules. For example instead of -V 192.168.255.1 you can code -W eth0, instead of -V your.static.PPP.address you can use -W ppp0. Personal choice and documentation more than anything. 4.5. IP Masquerade and Demand-Dial-Up 1. If you would like to setup your network to automatically dial up the Internet, the diald demand dial-up package will be of great utility. 2. To setup the diald, please check out the Setting Up Diald for Linux Page 3. Once diald and IP masq have been setup, you can go to any of the client machines and initiate a web, telnet or ftp session. 4. Diald will detect the incoming request, then dial up your ISP and establish the connection. 5. There is a timeout that will occur with the first connection. This is inevitable if you are using analog modems. The time taken to establish the modem link and the PPP connections will cause your client program to timeout. This can be avoided if you are using an ISDN connection. All you need to do is to terminate the current process on the client and restart it. 4.6. IPautofw Packet Fowarder IPautofw is a generic forwarder of TCP and UDP for Linux masquerading. Generally to utilize a package which requires UDP, a specific ip_masq module needs to be loaded; ip_masq_raudio, ip_masq_cuseeme, ... Ipautofw acts in a more generic manner, it will forward any type of traffic including those which the application specific modules will not forward. This may create a security hole if not administered correctly. 5. Miscellaneous 5.1. Getting Help · IP Masquerade Resource page should have enough information for setting up IP Masquerade An alternative site for this page · Joining IP masquerade mailing list (recommended) To subscribe, send a mail with subject "subscribe" (no quote) to masq-request@indyramp.com To unsubscribe, send a mail with subject "unsubscribe" (no quote) to masq-request@indyramp.com To get help on using the mailing list, send a mail with subject "archive help" or "archive dir" (no quote) to masq- request@indyramp.com · IP masquerade mailing list archive contains all the past messages sent to the mailing list. · This Linux IP Masquerade mini HOWTO for kernel 2.x (if you're using a 1.3.x or 2.x kernel) · IP Masquerade HOWTO for kernel 1.2.x if you're using an older kernel · IP masquerade FAQ has some general information · X/OS Ipfwadm page contains sources, binaries, documentation, and other information about the ipfwadm package · LDP Network Administrator's Guide is a must for beginners trying to set up a network · Linux NET-2 HOWTO also has lots of useful information about Linux networking · Linux ISP Hookup HOWTO and Linux PPP HOWTO gives you information on how to connect your Linux host to the Internet · Linux Ethernet-Howto is a good source of information about setting up a LAN running ethernet · You may also be interested in Linux Firewalling and Proxy Server HOWTO · Linux Kernel HOWTO will guide you through the kernel compilation process · Other Linux HOWTOs such as Kernel HOWTO · Posting to the USENET newsgroup: comp.os.linux.networking 5.2. Thanks to · Gabriel Beitler, gbeitler@aciscorp.com on providing section 3.3.8 (setting up Novel) · Ed Doolittle, dolittle@math.toronto.edu on suggestion to -V option in ipfwadm command for improved security · Matthew Driver, mdriver@cfmeu.asn.au on helping extensively on this HOWTO, and providing section 3.3.1 (setting up Windows 95) · Ken Eves, ken@eves.com on the FAQ that provides invaluable information for this HOWTO · Ed. Lott, edlott@neosoft.com for a long list of tested system and software · Nigel Metheringham, Nigel.Metheringham@theplanet.net on contributing his version of IP Packet Filtering and IP Masquerading HOWTO, which make this HOWTO a better and technical in-depth document section 4.1, 4.2, and others · Keith Owens, kaos@ocs.com.au on providing an excellent guide on ipfwadm section 4.2 on correction to ipfwadm -deny option which avoids a security hole, and clarified the status of ping over ip_masq · Rob Pelkey, rpelkey@abacus.bates.edu on providing section 3.3.6 and 3.3.7 (setting up MacTCP and Open Transport) · Harish Pillay, h.pillay@ieee.org on providing section 4.5 (dial-on-demand using diald) · Mark Purcell, purcell@rmcs.cranfield.ac.uk on providing section 4.6 (IPautofw) · John B. (Brent) Williams, forerunner@mercury.net on providing section 3.3.7 (setting up Open Transport) · Enrique Pessoa Xavier, enrique@labma.ufrj.br on the bootp setup suggestion · developers of IP Masquerade for this great feature · Delian Delchev, delian@wfpa.acad.bg · Nigel Metheringham, Nigel.Metheringham@theplanet.net · Keith Owens, kaos@ocs.com.au · Jeanette Pauline Middelink, middelin@polyware.iaf.nl · David A. Ranch, trinity@value.net · Miquel van Smoorenburg, miquels@q.cistron.nl · Jos Vos, jos@xos.nl · all users sending feedback and suggestion to the mailing list, especially the ones who reported errors in the document and the clients that are supported and not supported 5.3. Reference · IP masquerade FAQ by Ken Eves · IP masquerade mailing list archive by Indyramp Consulting · Ipfwadm page by X/OS · Various networking related Linux HOWTOs