kevin@pricetrak.com
This is the Linux IPX-HOWTO. You should read the Linux NET-3-HOWTO in conjunction with this document.
Change of author: Many thanks to Terry Dawson for passing on this document and congratulations on becoming a father :-). Additions: Addition of a brief explanation of IPX. This is in response to many baffled queries on the discussion lists. Corrections/Updates: New version of ncpfs which now supports NDS logins. This is early beta test and may be prohibited in your country due to the use of patented technology. Addition of support for trustee rights in mars_nwe. This is still in beta test.
The Linux Kernel has a completely new network implementation as compared to other Unix like operating systems. The ability to take a fresh approach to developing the kernel networking software has led to the Linux kernel having support for a range of non tcp/ip protocols being built. The IPX protocol is one of those that have been included.
The Linux kernel supports the IPX protocol only. It does not yet support protocols such as IPX/RIP, SAP or NCP, these are supported by other software such as that documented elsewhere in this document.
The IPX support was originally developed by Alan Cox
<alan@lxorguk.ukuu.org.uk>
and has been significantly enhanced by
Greg Page <greg@caldera.com>
.
I do not and cannot know everything there is to know about the Linux network software. Please accept and be warned that this document probably does contain errors. Please read any README files that are included with any of the various pieces of software described in this document for more detailed and accurate information. I will attempt to keep this document as error-free and up-to-date as possible. Versions of software are current as at time of writing.
In no way do I or the authors of the software in this document offer protection against your own actions. If you configure this software, even as described in this document and it causes problems on your network then you alone must carry the responsibility. I include this warning because IPX network design and configuration is not always a simple matter and sometimes undesirable interaction with other routers and fileservers can result if you do not design or configure your network carefully. I also include this warning because I was asked to by someone unfortunate enough to have discovered this lesson the hard way.
This document presumes you understand how to build a Linux kernel with the appropriate networking options selected and that you understand how to use the basic network tools such as ifconfig and route. If you do not, then you should read the NET-3-HOWTO in conjunction with this document as it describes these.
Other Linux HOWTO documents that might be useful are:
The Ethernet-HOWTO, which describes the details of configuring an Ethernet device for Linux.
The PPP-HOWTO as IPX support is available for version 2.2.0d and later of the Linux PPP implementation.
If your copy of this document is more than two months old then I strongly recommend you obtain a newer version. The networking support for Linux is changing very rapidly with new enhancements and features, so this document also changes fairly frequently. The latest released version of this document can always be retrieved by anonymous ftp from:
ftp:
/sunsite.unc.edu/pub/Linux/docs/HOWTO/IPX-HOWTO>/
or:
ftp:
/sunsite.unc.edu/pub/Linux/docs/HOWTO/other-formats/IPX-HOWTO{-html.tar,ps,dvi}.gz>/
via the World Wide Web from the
Linux Documentation Project Web Server, at page:
IPX-HOWTO
or directly from me, <kevin@pricetrak.com>
. It may
also be posted to the newsgroups: comp.os.linux.networking
,
comp.os.linux.answers
and news.answers
from time to time.
Please send any comments, updates, or suggestions to me,
<kevin@pricetrak.com>
. The sooner I get feedback, the
sooner I can update and correct this document. If you find any problems
with it, please mail me directly as I can miss info posted to the newsgroups.
There is a mailing list established for discussion of the various Linux
IPX software packages described in this document. You can subscribe to it
by sending a mail message to `listserv@sh.cvut.cz'
with
`add linware'
in the body of the message. To post to the list your
send your mail to `linware@sh.cvut.cz'
. I regularly watch this list.
The mailing list is archived at www.kin.vslib.cz.
You will often see the terms client
and server
used in this
document. They are normally fairly specific terms but in this document I have
generalized their definitions a little so that they mean the following:
The machine or program that initiates an action or a connection for the purpose of gaining use of some service or data.
The machine or program that accepts incoming connections from multiple remote machines and provides a service or data to those.
These definitions are not very reliable either, but they provide a means of distinguishing the ends of peer to peer systems such as SLIP or PPP which truly do not actually have clients and servers.
Other terms you will see are:
The bindery is a specialised database storing network configuration information on a Novell fileserver. Netware clients may query the bindery to obtain information on available services, routing and user information.
is a term used to describe that actual protocol used to carry the IPX (and IP) datagrams across your ethernet style network segments. There are four common ones. They are:
This is a refined version of the original DIX ethernet standard. Novell has been allocated a formal protocol id and this means that both IPX and IP can coexist happily in an Ethernet_II environment quite happily. This is commonly used in Novell environments and is a good choice.
This is an I.E.E.E. protocol defining a Carrier Sense Multiple Access with Collision Detection (CSMA/CD) mechanism. It was based on the original DIX Ethernet standard, with an important modification, the type (protocol id) field was converted into a length field instead. It is for this reason that IPX really shouldn't be run here. IEEE 802.3 was designed to carry IEEE 802.2 frames only but there are implementations that use it to carry IPX frames directly and remarkably it does work. Avoid it unless you are trying to interwork with a network already configured to use it.
This is an I.E.E.E. protocol that defines a set of Logical Link Control procedures. It provides a simplistic way of allowing different protocols to coexist, but is quite limited in this respect. Novell uses an unofficial Service Address Point (like a protocol id) but since everyone else uses it as well, that hasn't yet presented too much of a problem.
SNAP is the Sub Network Access Protocol. This protocol is designed ride on top of 802.3 and 802.2. It expands the multiprotocol capability of 802.2 and provides some measure of compatability with existing Ethernet and Ethernet_II frame types.
Internet Packet eXchange is a protocol used by the Novell corporation to provide internetworking support for their NetWare(tm) product. IPX is similar in functionality to the IP protocol used by the tcp/ip community.
This is a number which uniquely identifies a
particular IPX network. The usual notation for this address is in hexadecimal.
An example might look like: 0x23a91002
.
This is a virtual IPX network. It is virtual because it does not correspond to a physical network. This is used to provide a means of uniquely identifying and addressing a particular IPX host. This is generally only useful to IPX hosts that exist on more than one physical IPX network such as fileservers. The address is coded in the same form as for a physical IPX network.
Routing Information Protocol is a protocol used to automatically propagate network routes in an IPX network. It is functionally similar to the RIP used within the tcp/ip community.
NetWare Core Protocol is a networked filesystem protocol designed by the Novell Corporation for their NetWare(tm) product. NCP is functionally similar to the NFS used in the tcp/ip community.
Service Advertisement Protocol is a protocol designed by the Novell Corporation that is used to advertise network services in a NetWare(tm) environment.
This is a number that uniquely identifies a host in a
physical network at the media access layer. Examples of this are
Ethernet Addresses. An Ethernet address is generally coded as six
hexadecimal values separated by colon characters eg. 00:60:8C:C3:3C:0F
The route is the path that your packets take through the network to reach their destination.
This is a much simplified explanation for people new to IPX. Large networks will probably break lots of the rules explained here. In complex IPX networks the administrator should always be consulted.
IPX networking revolves around a scheme of numbered networks unlike IP which places more emphasis on the interface addresses. A network is a collection of equipment connected to the same LAN segment and using the same frame type. Different frame types on the same LAN segment are treated as seperate networks.
Each network must be allocated a number which is unique across the entire internetwork. This is usually performed by a NetWare(tm) server, but can easily be performed by Linux. IPX clients are given this number by the server when starting, they only require to know the correct frame type.
Routing between networks is usually performed by putting two network cards in a server. This server then runs the RIP protocol which holds a routing table for the internetwork. Periodic broadcasts of this routing table are exchanged between servers. Within a short time each server 'discovers' the topology of the internetwork.
If you only wish to use the services of an existing NetWare server, you
can use ipx_configure
(section 7.1) to automatically define the
IPX interfaces by using broadcast queries to look for a server. If this
fails, or you wish to provide IPX services, you will need to define the
interfaces manually using ipx_interface
or mars_nwe
.
/proc
filesystem.There are a number of files related to the Linux IPX support that are located
within the /proc
filesystem. They are:
This file contains information about the IPX interfaces configured on your machine. These may have been configured manually by command or automatically detected and configured.
This file contains a list of the routes that exist in the IPX routing table. These routes may have been added manually by command or automatically by an IPX routing daemon.
This file is a list of the IPX sockets that are currently open for use on the machine.
Greg Page <greg@caldera.com
of Caldera Incorporated has written
a suite of IPX configuration tools and enhanced the Linux IPX kernel support.
The kernel enhancements allow linux to be configured as a fully featured IPX bridge or router. The enhanced IPX support has already been fed back into the mainstream kernel distribution so you will probably already have it.
The network configuration tools provide you with the capability to configure your network devices to support IPX and allow you to configure IPX routing and other facilities under Linux. The Linux IPX network tools are available from: sunsite.unc.edu.
This command is used to manually add, delete or check
ipx capability to an existing network device. Normally the network device
would be an Ethernet device such at eth0
. At least one IPX interface
must be designated the primary interface and the -p flag
to this command does this. For example to enable Ethernet device eth0
for IPX capability as the primary IPX interface using the IEEE 802.2 frame type
and IPX network address 39ab0222
you would use:
# ipx_interface add -p eth0 802.2 0x39ab0222
If the frame type differs from NetWare(tm) servers on this network, they will studiously ignore you. If the frame type is correct but the network number differs, they will still ignore you but complain frequently on the NetWare server console. The latter is guaranteed to gain you flames from your NetWare administrator and may disrupt existing NetWare clients.
If you get an error while running this program and you happen to not
have already configured tcp/ip, then you will find that you need to manually
start the eth0
interface using the command:
# ifconfig eth0 up
This command enables or disables the automatic setting of the interface configuration and primary interface settings.
--auto_interface
allows you to select whether new network devices should be automatically configured as IPX devices or not.
--auto_primary
allows you to select whether the IPX software should automatically select a primary interface or not. Problems have been noted using this with Windows 95 clients on the network.
# ipx_configure --auto_interface=on --auto_primary=on
This command allows you to configure or deconfigure
an internal network address. An internal network address is optional, but when
it is configured it will always be the primary interface. To configure an
IPX network address of ab000000
on IPX node 1
you would use:
# ipx_internal_net add 0xab000000 1
The command allows you to manually modify the IPX routing
table. For example to add a route to IPX network 39ab0222
via
a router with node number 00608CC33C0F
on IPX network
39ab0108
:
# ipx_route add 0x39ab0222 0x39ab0108 0x00608CC33C0F
If you have a number of IPX segments that you wish to internetwork you need the services of a router. In the Novell environment there are two pieces of information which are necessary to be propagated around the network. They are the network routing information propagated using Novell RIP, and the service advertisement information propagated using Novell SAP. Any router must support both of these protocols to be useful in most situations.
Linux has support for both of these protocols and can be fairly easily made to function as a fully Novell compliant router.
The Linux kernel IPX support actually manages the IPX packet forwarding across interfaces, but it does this according to the rules coded into the IPX routing table. Linux needs a program to implement the Novell RIP and SAP to ensure that the IPX routing table is built correctly and updated periodically to reflect changes in the network status.
Volker Lendecke <lendecke@namu01.gwdg.de>
has developed a routing
daemon ipxripd that will do this for you. The mars_nwe package
mentioned later includes an alternative routing daemon.
You can find ipxripd at:
or at Volkers home site at:
Configuring your Linux machine to act as a router is very straightforward. The steps you must take are:
/proc
support.Consider the following simple network:
IPX Addr: 0x01000000 802.2 |--------------------------| | \_________________________ \ Linux Router IPX Addr: 0x02000000 802.2 \ |--------------------------| \ eth0/-----------\ | \--====| | \_________________________ | IPX route | \ eth1| Table | IPX Addr: 0x03000000 etherII \----====| ^ | |--------------------------| | | | | eth2| IPXd | \______________________________/====| | | SAPd | IPX Addr: 0x04000000 etherII eth3| | |--------------------------| /====| | | | \___________/ \______________________________/
The configuration for the above network would look like:
# ipx_interface add eth0 802.2 0x0100000000
# ipx_interface add eth1 802.2 0x0200000000
# ipx_interface add eth2 etherii 0x0300000000
# ipx_interface add eth3 etherii 0x0400000000
# ipxd
You should then wait a moment or two and check your
/proc/net/ipx_route
file and you should see it populated with
the IPX routes relevant to your configuration and any learned from any other
routers in the network.
Novell has a feature called an internal network, which it uses to simplify routing in situations where a host has more than one network device connected. This is useful in the case of a fileserver connected to multiple networks as it means that only one route needs to be advertised to reach the server regardless of which network you are attempting from.
In the case of a configuration where you are not running a fileserver and your machine acting only as an IPX router the question is not as simple to answer. It has been reported that configuring for IPX/PPP works `better' if you also configure an internal network.
In any case it is easy to do, but may require a rebuild of your kernel.
When you are working through the kernel make config
you must answer
y
when asked Full internal IPX network
as illustrated:
...
...
Full internal IPX network (CONFIG_IPX_INTERN) [N/y/?] y
...
...
To configure the internal network interface, use the ipx_internal_net command described earlier in the IPX tools section. The main precaution to take is to ensure that they IPX network address you assign is unique on your network and that no other machine or network is using it.
If you are a user of a mixed technology network that comprises both IP and IPX protocols it is likely that at some time or another you have wanted to have your Linux machine access data stored on a Novell fileserver on your network. Novell have long offered an NFS server package for their fileservers that would allow this, but if you are a small site or have only a small number of people interested in doing this it is difficult to justify the cost of the commercial package.
Volker Lendecke <lendecke@namu01.gwdg.de>
has written a Linux
filesystem kernel module that supports a subset of the Novell NCP
that will allow you to mount Novell volumes into your Linux filesystem
without requiring any additional products for your fileserver.
Volker has called the package ncpfs and derived the necessary
information mainly from the book "Netzwerkprogrammierung in C" by
Manfred Hill and Ralf Zessin (further details of the book are contained within
the README file in the ncpfs package).
The software causes Linux to emulate a normal Novell workstation for file services. It also includes a small print utility that allows you to print to Novell print queues (This is documented in the Print Client section later). The ncpfs package will work with Novell fileservers of version 3.x and later, it will not work the Novell 2.x. The ncpfs client will also work with close Novell compatible products, but unfortunately some products that claim to be compatible aren't compatible enough. To use ncpfs with Novell 4.x fileservers, it is preferred to use the Novell server in bindery emulation mode. The NDS support is a very recent early beta addition to ncpfs and additionally its use may be prohibited in your country due to the inclusion of patented technology.
The latest ncpfs package was designed to be built against the version
1.2.13
kernel or kernels later than 1.3.71
(this includes 2.x.x).
If you not using a kernel in either of these categories then you will have
to upgrade your kernel. The
Kernel-HOWTO describes how to do this in
detail.
You can obtain the ncpfs package by anonymous ftp from Volker's home site at: ftp.gwdg.de or sunsite.unc.edu or mirror sites. The current version at the time of writing was:
ncpfs-2.0.11.tgz
or ncpfs-2.2.0.tgz
which adds the NDS support.
The first thing you
need to do is ensure that your kernel has been built with IPX support enabled.
In the 1.2.13
version kernel you need only ensure that you have
answered Y
to the question: 'The IPX protocol
' as
illustrated:
... ... Assume subnets are local (CONFIG_INET_SNARL) [y] Disable NAGLE algorithm (normally enabled) (CONFIG_TCP_NAGLE_OFF) [n] The IPX protocol (CONFIG_IPX) [n] y * * SCSI support ... ...You will also need to ensure that you include an appropriate driver for your Ethernet card. If you do not know how to do this then you should read the Ethernet-HOWTO.
You can then proceed to build your kernel. Make sure you remember to run lilo to install it when you have finished.
# cd /usr/src # tar xvfz ncpfs-2.0.11.tgz # cd ncpfs
If you intend to use kerneld to
autoload the ncpfs kernel module then you must uncomment the
line in the Makefile
that refers to: KERNELD
. If you
are unsure what this means then you should read the
Kernel-HOWTO to familiarise
yourself with kernel module configuration.
The software should compile cleanly with no other configuration necessary:
# make
After the make has completed you should find all of the tools
you need in the ncpfs/bin
directory. You can use:
# make install
to install the tools in Volkers choice of directories. If you are running
on an ELF based system then you will need to rerun `ldconfig -v'
to
ensure that the shared library is able to be found.
If you are compiling for a 1.2.*
kernel then you will find a file
called ncpfs.o
in the ncpfs/bin
directory after the
make has completed. This is the ncpfs kernel module.
You should copy this somewhere useful. On my debian system I have
copied it to the /lib/modules/1.2.13/fs
directory and added
ncpfs
to the /etc/modules
file so that it will be
automatically started at boot time. If you are using some other distribution
you should find where it keeps its modules and copy it there, or just copy it
to your /etc
directory. To load the modules manually you need to use
the command:
# insmod ncpfs.o
For the latest version of ncpfs you must use kernel 1.3.71
or newer, this includes the 2.0.*
kernels.
If you intend using a kernel that is version 1.3.71
or newer then the
ncpfs kernel code has been included in the standard kernel
distribution. You need only answer Y
to:
Networking options --->
...
...
<*> The IPX protocol
...
Filesystems --->
...
...
<*> NCP filesystem support (to mount NetWare volumes)
...
You will still need to follow the instructions for building for kernels
1.2.*
so that you can build the tools but there will not be a module
file for you to install.
There are two ways of configuring the IPX network software. You can manually configure all of your IPX network information or you can choose to let the software determine for itself some reasonable settings using the command:
# ipx_configure --auto_interface=on --auto_primary=on
This should be reasonable in most circumstances, but if it doesn't work for you then read the 'IPX tools' section above to configure your software manually. Problems have been noted using this on networks containing Windows '95 clients.
After your IPX network is configured you should be able to use the slist command to see a list of all of the Novell fileserver on your network:
# slistIf the slist command displays a message like:
ncp_connect: Invalid argument
then your kernel probably does not
support IPX. Check that you have actually booted off the appropriate kernel.
When you boot you should see messages about 'IPX
' and 'ncpfs
' in
the system startup messages. If the slist command does not list all
of your fileservers then you may need to use the manual network configuration
method.
If your IPX network software is working ok you should now be able to mount a Novell fileserver or volume into your Linux filesystem. The ncpmount command is used for this purpose and requires that you specify at least the following information:
There is an equivalent ncpumount command to unmount a mounted NCP filesystem. The NCP filesystems will be unmounted cleanly if you shutdown your machine normally, so you needn't worry about ncpumounting your filesystems manually before a halt or shutdown.
An example command to mount fileserver ACCT_FS01
, with a login id of
guest
with no password, under the /mnt/Accounts
directory
might look like the following:
# ncpmount -S ACCT_FS01 /mnt/Accounts -U guest -nNote the use of the
-n
option to indicate that no password is
required for the login. The same login specifying a password of secret
would look like:
# ncpmount -S ACCT_FS01 /mnt/Accounts -U guest -P secretIf you don't specify either the
-n
or the -P
options you
will be prompted for a password.
If the mount is successful you will find all the
volumes accessible to the userid used for login listed as directories under
the mount point. You should then also be able to traverse the directory
structure to find other files. You may alternatively use the -V
option
to mount a single volume.
NCP does not provide uid or gid ownership of files. All the files will have the permission and ownership assigned to the mount point directory restricted by trustee permissions on the Novell server. Bear this in mind when sharing mounts between Linux users.
If you have some
need to permanently have an ncp mount then you will want to configure the
commands above into your rc files so that they occur automatically
at boot time. If your distribution doesn't already provide some way of
configuring IPX like debian then I recommend you place them in your
/etc/rc.local
file if you have one. You might use something like:
#
# Start the ncp filesystem
/sbin/insmod /lib/modules/1.2.13/fs/ncpfs.o
# configure the IPX network
ipx_configure --auto_interface=on --auto_primary=on
# guest login to the Accounting fileserver
ncpmount -S ACCT_FS01 /mnt/Accounts -U guest -n
#
There is another means of configuring NCP mounts and that is by building
a $HOME/.nwclient
file. This file contains details of temporary
or user specific NCP mounts that would be performed regularly. It allows
you to store the details of mounts so that you can recreate them without
having to specify all of the detail each time.
Its format is quite straightforward:
# The first entry is the 'preferred server' entry and is
# used whenever you do not specify a server explicitly.
#
# User TERRY login to DOCS_FS01 fileserver with password 'password'
DOCS_FS01/TERRY password
#
# Guest login to the ACCT_FS01 fileserver with no password.
ACCT_FS01/GUEST -
To activate these mounts you could use:
$ ncpmount /home/terry/docs
to mount: DOCS_FS01 with a login of TERRY under the /home/terry/docs
directory. Note that this entry was chosen because no fileserver was
specified in the mount command. If the following command were used:
$ ncpmount -S ACCT_FS01 /home/terry/docs
then a GUEST login to ACCT_FS01 would be mounted there instead.
Note: for this mechanism to work the permissions of the
$HOME/.nwclient
file must be 0600
so you would
need to use the command:
$ chmod 0600 $HOME/.nwclient
If non-root users are to be allowed to use this mechanism then
the ncpmount command must be Set Userid Root, so you
would need to give it permissions:
# chmod 4755 ncpmount
a utility to send messages to Novell users is also included in the package, it is called nsend and is used as follows:
# nsend rod hello therewould send the message "hello there" to a logged in user "rod" on your "primary" fileserver (the first one appearing in your
.nwclient
file. You can specify another fileserver with the same syntax as for the
ncpmount command.
There are two packages available that allow Linux to provide the functions of a Novell Fileserver. They both allow you to share files on your linux machine with users using Novell NetWare client software. Users can attach and map filesystems to appear as local drives on their machines just as they would to a real Novell fileserver. You may want to try both to see which best serves your intended purpose.
Martin Stover <mstover@freeway.de>
developed mars_nwe
to enable linux to provide both file and print services for NetWare clients.
In case you are wondering about the name: mars_nwe is Martin Stovers Netware Emulator.
mars_nwe implements a subset of the full Novell NCP for file services, disk based bindery and also print services. It is likely to contain bugs but there are many people using it now and the number of bugs is steadily decreasing as new versions are released.
You can obtain mars_nwe from ftp.gwdg.de or from ftp://sunsite.unc.edu/pub/Linux/system/filesystems/ncpfs/.
The version current at the time of writing was: mars_nwe-0.99.pl10.tgz
.
In the 1.2.13
version kernel you need only ensure that you have answered Y
to the
question: 'The IPX protocol
' and N
to the question:
`Full internal IPX network
' as illustrated:
... ... The IPX protocol (CONFIG_IPX) [n] y ... ... Full internal IPX network (CONFIG_IPX_INTERN) [N/y/?] n ... ...In newer kernels a similar process is adopted but the actual text of the prompt may have changed slightly.
You will also need to ensure that you include an appropriate driver for your Ethernet card. If you do not know how to do this then you should read the Ethernet-HOWTO.
You can then proceed to build your kernel. Make sure you remember to run lilo to install it when you have finished.
# cd /usr/src
# tar xvfz mars_nwe-0.99.pl10.tgz
To make the package is very simple.
The first step is to simply run make
, this will create a
config.h
file for you. Next you should look at and edit the
config.h
file if necessary. It allows you to configure items
such as the installation directories that will be used and the maximum
number of sessions and volumes that the server will support. The really
important entries to look at are:
FILENAME_NW_INI the location of the initialisation file PATHNAME_PROGS where the executable support programs will be found. PATHNAME_BINDERY where the 'bindery' files will go. PATHNAME_PIDFILES the directory for the 'pid' files to be written. MAX_CONNECTIONS the maximum number of simultaneous connections allowed. MAX_NW_VOLS the maximum number of volumes mars_nwe will support. MAX_FILE_HANDLES_CONN the maximum number of open files per connection. WITH_NAME_SPACE_CALLS if you want to support ncpfs clients. INTERNAL_RIP_SAP whether you want mars_nwe to provide rip/sap routing. SHADOW_PWD whether you use shadow passwords or not.
The defaults will probably be ok but you should check anyway.
When this is done:
# make
# make install
will build the servers and install them in the appropriate directory. The
installation script also installs the configuration file
/etc/nwserv.conf
.
Configuration is fairly simple. You need to
edit the /etc/nwserv.conf
file. The format of this file may at first
look a little cryptic, but it is fairly straightforward. The file contains a
number of single line configuration items. Each line is whitespace delimited
and begins with a number that indicates the contents of the line. All
characters following a '#
' character are considered a comment and
ignored. Martin supplies an example configuration file in the package,
but I'll present what I consider to be a simplified example to offer an
alternative for you.
# VOLUMES (max. 5)
# Only the SYS volume is compulsory. The directory containing the SYS
# volume must contain the directories: LOGIN, PUBLIC, SYSTEM, MAIL.
# The 'i' option ignores case.
# The 'k' option converts all filenames in NCP requests to lowercase.
# The 'm' option marks the volume as removable (useful for cdroms etc.)
# The 'r' option set the volume to read-only.
# The 'o' option indicates the volume is a single mounted filesystem.
# The 'P' option allows commands to be used as files.
# The 'O' option allows use of the OS/2 namespace
# The 'N' option allows use of the NFS namespace
# The default is upper case.
# Syntax:
# 1 <Volumename> <Volumepath> <Options>
1 SYS /home/netware/SYS/ # SYS
1 DATA /home/netware/DATA/ k # DATA
1 CDROM /cdrom kmr # CDROM
# SERVER NAME
# If not set then the linux hostname will be converted to upper case
# and used. This is optional, the hostname will be used if this is not
# configured.
# Syntax:
# 2 <Servername>
2 LINUX_FS01
# INTERNAL NETWORK ADDRESS
# The Internal IPX Network Address is a feature that simplifies IPX routing
# for multihomed hosts (hosts that have ports on more than one IPX network).
# Syntax:
# 3 <Internal Network Address> [<Node Number>]
# or:
# 3 auto
#
# If you use 'auto' then your host IP address will be used. NOTE: this may
# be dangerous, please be sure you pick a number unique to your network.
# Addresses are 4byte hexadecimal (the leading 0x is required).
3 0x49a01010 1
# NETWORK DEVICE(S)
# This entry configures your IPX network. If you already have your
# IPX network configured then you do not need this. This is the same as
# using ipx_configure/ipx_interface before you start the server.
# Syntax:
# 4 <IPX Network Number> <device_name> <frametype> [<ticks>]
# Frame types: ethernet_ii, 802.2, 802.3, SNAP
4 0x39a01010 eth0 802.3 1
# SAVE IPX ROUTES AFTER SERVER IS DOWNED
# Syntax:
# 5 <flag>
# 0 = don't save routes, 1 = do save routes
5 0
# NETWARE VERSION
# Syntax:
# 6 <version>
# 0 = 2.15, 1 = 3.11
6 1
# PASSWORD HANDLING
# Real Novell DOS clients support a feature which encypts your
# password when changing it. You can select whether you want your
# mars server to support this feature or not.
# Syntax
# 7 <flag>
# <flag> is:
# 0 to force password encryption. (Clients can't change password)
# 1 force password encryption, allow unencrypted password change.
# 7 allow non-encrypted password but no empty passwords.
# 8 allow non-encrypted password including empty passwords.
# 9 completely unencrypted passwords (doesn't work with OS/2)
7 1
# MINIMAL GID UID rights
# permissions used for attachments with no login. These permissions
# will be used for the files in your primary server attachment.
# Syntax:
# 10 <gid>
# 11 <uid>
# <gid> <uid> are from /etc/passwd, /etc/groups
10 200
11 201
# SUPERVISOR password
# May be removed after the server is started once. The server will
# encrypt this information into the bindery file after it is run.
# You should avoid using the 'root' user and instead use another
# account to administer the mars fileserver.
#
# This entry is read and encrypted into the server bindery files, so
# it only needs to exist the first time you start the server to ensure
# that the password isn't stolen.
#
# Syntax:
# 12 <Supervisor-Login> <Unix username> [<password>]
12 SUPERVISOR terry secret
# USER ACCOUNTS
# This associates NetWare logins with unix accounts. Password are
# optional.
# Syntax:
13 <User Login> <Unix Username> [<password>]
13 MARTIN martin
13 TERRY terry
# LAZY SYSTEM ADMIN CONFIGURATION
# If you have a large numbers of users and could not be bothered using
# type 13 individual user mappings, you can automatically map mars_nwe
# logins to linux user names. BUT, there is currently no means of making
# use of the linux login password so all users configured this way are
# will use the single password supplied here. My recommendation is not
# to do this unless security is absolutely no concern to you.
# Syntax:
# 15 <flag> <common-password>
# <flag> is: 0 - don't automatically map users.
# 1 - do automatically map users not configured above.
# 99 - automatically map every user in this way.
15 0 duzzenmatta
# SANITY CHECKING
# mars_nwe will automatically ensure that certain directories exist if
# you set this flag.
# Syntax:
# 16 <flag>
# <flag> is 0 for no, don't, or 1 for yes, do.
16 0
# PRINT QUEUES
# This associates NetWare printers with unix printers. The queue
# directories must be created manually before printing is attempted.
# The queue directories are NOT lpd queues.
# Syntax:
# 21 <queue_name> <queue_directory> <unix_print_cmd>
21 EPSON SYS:/PRINT/EPSON lpr -h
21 LASER SYS:/PRINT/LASER lpr -Plaser
# DEBUG FLAGS
# These are not normally needed, but may be useful if are you debugging
# a problem.
# Syntax:
# <debug_item> <debug_flag>
#
# 100 = IPX KERNEL
# 101 = NWSERV
# 102 = NCPSERV
# 103 = NWCONN
# 104 = start NWCLIENT
# 105 = NWBIND
# 106 = NWROUTED
# 0 = disable debug, 1 = enable debug
100 0
101 0
102 0
103 0
104 0
105 0
106 0
# RUN NWSERV IN BACKGROUND AND USE LOGFILE
# Syntax:
# 200 <flag>
# 0 = run NWSERV in foreground and don't use logfile
# 1 = run NWSERV in background and use logfile
200 1
# LOGFILE NAME
# Syntax:
# 201 <logfile>
201 /tmp/nw.log
# APPEND LOG OR OVERWRITE
# Syntax:
# 202 <flag>
# 0 = append to existing logfile
# 1 = overwrite existing logfile
202 1
# SERVER DOWN TIME
# This item sets the time after a SERVER DOWN is issued that the
# server really goes down.
# Syntax:
# 210 <time>
# in seconds. (defaults 10)
210 10
# ROUTING BROADCAST INTERVAL
# The time is seconds between server broadcasts
# Syntax:
# 211 <time>
# in seconds. (defaults 60)
211 60
# ROUTING LOGGING INTERVAL
# Set how many broadcasts take place before logging of routing
# information occurs.
# Syntax:
# 300 <number>
300 5
# ROUTING LOGFILE
# Set the name of the routing logfile
# Syntax:
# 301 <filename>
301 /tmp/nw.routes
# ROUTING APPEND/OVERWRITE
# Set whether you want to append to an existing log file or
# overwrite it.
# Syntax:
# 302 <flag>
# <flag> is 0 for append, 1 for create/overwrite
302 1
# WATCHDOG TIMING
# Set the timing for watchdog messages that ensure the network is
# still alive.
# Syntax:
# 310 <value>
# <value> = 0 - always send watchdogs
# < 0 - (-ve) for disable watchdogs
# > 0 - send watchdogs when network traffic
# drops below 'n' ticks
310 7
# STATION FILE
# Set the filename for the stations file which determine which
# machines this fileserver will act as the primary fileserver for.
# The syntax of this file is described in the 'examples' directory
# of the source code.
# Syntax:
# 400 <filename>
400 /etc/nwserv.stations
# GET NEAREST FILESERVER HANDLING
# Set how SAP Get Nearest Fileserver Requests are handled.
# Syntax:
# 401 <flag>
# <flag> is: 0 - disable 'Get Nearest Fileserver' requests.
# 1 - The 'stations' file lists stations to be excluded.
# 2 - The 'stations' file lists stations to be included.
401 2
If you've configured the server to expect external programs to configure your network and/or provide the routing function then you should start those before starting the server. Presuming you have configured the server so that it will configure your interfaces for you and provide the routing services you need only issue the command:
# nwserv
To test the server you should first try to attach
and login from a NetWare client on your network. You then set a
CAPTURE
from the client and attempt a print. If both of these are
successful then the server is working.
Ales Dryak <A.Dryak@sh.cvut.cz>
developed lwared to allow
Linux to function as an NCP based fileserver.
Ales has called the package lwared, an abbreviation for LinWare Daemon.
The lwared server is capable of providing a subset of the full function of the Novell NCP. It incorporates messaging but it does not provide any printing facilities at all. It does not currently work very well with either Windows95 or Windows NT clients. The lwared server relies on external programs to build and update the IPX routing and SAP tables. Misbehaving clients can cause the server to crash. Importantly, filename translation facilities have not been included.
The server does work for NETX and VLM NetWare shells.
The lwared package can be built for any kernel newer than
1.2.0
, I recommend you use version 1.2.13
as no kernel
patches are required if you do. Some of the IPX functionality has changed
with the version 1.3.*
kernels and this means that patches are
now required to make it work properly. Appropriate patches are included for
the new kernels, so if you must use an alpha kernel you should still be able
to get lwared to work properly for you.
You can obtain the lwared package by anonymous ftp from: klokan.sh.cvut.cz
or from:
sunsite.unc.edu
or mirror sites. The current version at the time of writing was:
lwared-0.95.tar.gz
Something like:
# cd /usr/src # tar xvpfz lwared-0.95.tar.gz
If you are using an alpha 1.3.*
kernel then you should try and use
kernel version 1.3.17
or newer because the supplied patches were built
against it. 1.3.*
kernels older than 1.3.17
will require
hand patching to install. (some information on how to do this is included
in the INSTALL
file in the package.). To install the patches
against a 1.3.17
kernel or newer you should try:
# make patch
After applying the patches if necessary, the next thing you need to do is
ensure that your kernel has been built with IPX support enabled. In the
1.2.13
version kernel you need only ensure that you have answered
Y
to the question: 'The IPX protocol
' as
illustrated:
... ... Assume subnets are local (CONFIG_INET_SNARL) [y] Disable NAGLE algorithm (normally enabled) (CONFIG_TCP_NAGLE_OFF) [n] The IPX protocol (CONFIG_IPX) [n] y * * SCSI support ... ...In newer kernels a similar process is adopted by the actual text of the prompt may have changed slightly.
You will also need to ensure that you include an appropriate driver for your Ethernet card. If you do not know how to do this then you should read the Ethernet-HOWTO.
You can then proceed to build your kernel. Make sure you remember to run lilo to install it when you have finished.
To compile lwared you
should first check, edit if necessary, the server/config.h
file. This
file contains various settings that will govern the way your server will
behave when it is running. The defaults are reasonable, though you might want
to check that the directories specified for the log files and configuration
files suit your system.
# make depend # make # make installI found that the '
make depend
' complained about not finding the
float.h
file on my system but appeared to work anyway.
I also found that when I tried compiling with gcc 2.6.3
I found
I had to change the line:
#include <net/route.h>to
#include <net/if_route.h>in
lib/ipxkern.c
as this file changed name sometime.
The 'make install
' will attempt to install the server and routing
daemon programs into your /usr/sbin
directory, the lwpasswd
program into your /usr/bin
directory, the IPX utility programs will
be installed into your /sbin
directory and last but not least the
manual pages will go into the /usr/man
directory structure. If any
of these locations are not suitable for your system then you should edit
the relevant Makefile
and change the target directories to suit.
Now the fun bit!
The first thing you must do is configure
your Ethernet interfaces to support the IPX networks your server will support.
To do this you will need to know the IPX network addresses for each of your
LAN segments, which Ethernet device (eth0
, eth1
etc.) is
on which segment, what frame type (802.3
, EtherII
etc.) each
LAN segment uses and what Internal Network address your server should use
(this is really needed if your server will service more than one LAN segment).
A configuration for a server that is on two dis-similar segments with IPX
network addresses 23a91300
and 23a91301
and internal network
address bdefaced
might look like:
# ipx_internal_net add BDEFACED 1 # ipx_interface add eth0 802.3 23a91300 # ipx_interface add eth1 etherii 23a91301
The kernel software itself actually does the IPX packet forwarding as it does for IP, but the kernel requires additional programs to manage the routing table updates. In the case of IPX two daemons are needed and both are supplied with lwared: ipxripd manages the IPX routing information and ipxsapd manages the SAP information. To start the daemons you need only specify the location of where they should write their log messages:
# ipxripd /var/adm/ipxrip # ipxsapd /var/adm/ipxsap
There are two files that you must manually configure to allow user login to your lwared server. They are:
/etc/lwpasswd
This is where LinWare user account
information is kept. The lwpasswd program is to keep it up to date.
In its simplest form the /etc/lwpasswd
file looks like:
ales: terryd: guest:Its format is a simple list of login id followed by a ':' character and then the encrypted version of the login passwd. A couple of important caveats here: No encrypted password means no password, LinWare users must have Linux accounts, that is any user you place in
/etc/lwpasswd
must also
appear in /etc/passwd
and root
is the only account that can
change the password of another LinWare user. If you are logged in as
root
you can change the password of a LinWare user as this transcript
demonstrates:
# lwpasswd rodg Changing password for RODG Enter new password: Re-type new password: Password changed.
/etc/lwvtab
This is the LinWare volume tables and it stores
information about what directories should be made available to LinWare users
(this file is similar in nature to the NFS /etc/exports
file). A
simple example of its format is as follows:
SYS /lwfs/sys DATA /lwfs/data HOME /homeThe format is simple: Volume name followed by whitespace followed by Linux directory to export. You must have at least an entry for the
SYS
volume for the server to start. If you intend your DOS based
users to be able use your LinWare server as their primary server then you must
install a standard SYS
volume directory structure underneath the
directory you export as your SYS
volume. Since these files are
proprietary and copyright to the Novell corporation you should have a license
for these. If you users will be using a Novell fileserver as their primary
server then this will not be necessary.
tada!
# lwaredIt is almost an anticlimax isn't it ? Ok so you've got a question, right? What is the fileserver name that is being advertised ? If you started the server as shown then the LinWare server name being advertised will be based on what is returned by the Linux hostname. If you'd like it to be something else then you can give the server the name when you start it, for example:
# lwared -nlinux00would start the server with the name
linux00
.
The very first thing to test is
that your LinWare server appears in an slist from a DOS client
on your network. The slist program is stored on the SYS
volume of a Novell fileserver so you must do this from a machine that is
already logged in somewhere. If this is not successful then check that
ipxsapd and lwared are both running. If the slist
is successful then you should try attaching to the server and mapping
a volume:
C:> attach linux00/ales ... ... C:> map l:=linux00/data: C:> l:You should then be able to treat the new map just like any other map. The file permissions you will have will be based on those allowed to the linux account that parallels your LinWare login.
The ncpfs package includes two small programs that allow you to handle printing from you Linux machine to a printer attached to a Novell print server. The nprint command allows you to print to a file to a NetWare print queue. The pqlist command allows you the list the available print queues on a NetWare server.
To obtain and install these commands just follow the instructions relating to the NCP client described earlier.
Both commands require that you supply username and password so you might normally consider building some shell scripts to make the task of printing easier.
An example might look like:
# pqlist -S ACCT_FS01 -U guest -n
# nprint -S ACCT_FS01 -q LASER -U guest -n filename.txt
The login syntax is similar to the ncpmount command. The examples
above assume that fileserver ACCT_FS01
has a guest
account
with no password, that a print queue called LASER
exists and that
guest
is allowed to print to it.
On my Linux boxen I have a short shell script for each Novell printer. This can then be used as a print filter to allow printing using the standard Linux spooler.
A program to allow your Linux machine to act as a print server on a Netware network is included in the ncpfs package. For instructions on how to obtain and build, it follow the directions in the `Netware client' section above. Alternatively, support is included in the mars_nwe package.
Configuration is quite straightforward but relies on you already having your printer configuration completed and working under Linux. This is covered in the Printing-HOWTO in some depth.
When you have a working printer configuration, and you have built and
installed the pserver utility then you need to add commands to start it
into your rc
files.
Exactly what command will use will depend on depend on exactly how you want it to operate, but in its simplest form something like the following will work:
# pserver -S ACCT_01 -U LASER -P secret -q LASERJET
This example asks the pserver utility to login in to the ACCT_01
fileserver with username LASER
and password secret
and to take
jobs from the LASERJET
print queue. When an incoming print job is received
it will use the default print command of lpr to feed the print job to the
Linux print daemon. The print queue must already be defined on the fileserver
and the username must have server priveliges for the queue.
You could if you wished use any Linux command to accept and print the
print job. The -c
argument allows you to specify the exact print command.
For example:
# pserver -S ACCT_01 -U LASER -P secret -q LASERJET -c "lpr -Plaserjet"
would do exactly the same as the previous example except it would send the
job to the laserjet
printcap configuration instead of the default
one.
Recent versions of Volker's ncpfs package include a range of user and administration commands that you might want to use. The tools are built and installed as part of the ncpfs installation process, so if you haven't already, follow the instructions supplied in the Novell Client section above to build and install them.
Detailed information is available in the supplied man pages but a brief summary of the commands is as follows;
Network Copy - allows efficient file copies to be performed by using a Netware function rather than a copy across the network.
Network Print - allows you to print a file to a Netware print queue on a Netware server.
Network Send - allows you to send messages to other users on a Netware server.
List Bindery Objects - allows you to list the bindery contents of a Netware server.
List Properties of a Bindery Object - allows you to the properties of a Netware bindery object.
Set Bindery Property - allows you to set the properties of a Netware bindery object.
Print Netware Bindery Objects Property Contents - allows you to print the contents of a Netware bindery property.
Fileserver Information - prints some summary information about a Netware server.
Netware Password - allows you to change a Netware users password.
Netware Rights - displays the rights associated with a particular file or directory.
Userlist - lists the users currently logged into a Netware fileserver.
Print Queue List - displays the contents of a Netware print queue.
Server List - displays a list of know Netware fileserver.
Create a Bindery Object - allows you to create a Netware bindery object.
Remove Bindery Object - allows you to delete a Netware bindery object.
Add Bindery Property - allows you to set the value of an existing property of a Netware bindery object.
Create Bindery Property - allows you to create a new property for an existing Netware bindery object.
Remove Bindery Property - allows you to remove a property from a Netware bindery object.
Grant Trustee Rights - allows you to assign trustee rights to a directory on a Netware fileserver.
Revoke Trustee Rights - allows you to remove trustee rights from a directory on a Netware fileserver.
New versions of the pppd PPP daemon for Linux have support that
allows you to carry IPX packets across a PPP serial link. You need at least
version ppp-2.2.0d
of the daemon. See the
PPP-HOWTO
for details on where to find it. When you compile pppd you must
ensure you enable the IPX support by adding the following two lines:
IPX_CHANGE = 1
USE_MS_DNS = 1
to: /usr/src/linux/pppd-2.2.0f/pppd/Makefile.linux
.
The IPX_CHANGE
is what configures the IPX support into PPP.
The USE_MS_DNS
define allows Microsoft Windows95 machines to do
Name Lookups.
The real trick to getting it to work in knowing how to configure it.
There are many ways of doing this, but I'm only going to describe the two that I've received any information on. I've tried neither yet, so consider this section experimental, and if you get something to work, please let me know.
The first thing you need to do is configure your Linux machine as an IP/PPP server. Don't panic! This isn't difficult. Again, follow the instructions in the PPP-HOWTO and you should be pretty much ok. When you have this done there are a couple of simple modifications you need to make to get IPX working over the same configuration.
One of the first steps you must take is to configure your linux machine as an
IPX router as described in the appropriate section earlier in this document.
You won't need to use the ipx_route command for the ppp
interface
because pppd will configure these for you as it does for IP. When you
have the ipxd daemon running it will automatically detect any new IPX
interfaces and propogates routes for them. In this way your dialup hosts will
be seen by other machines automatically when they connect.
When you are running as a server it will normally be your responsibility to assign network address to each of the PPP links when they are established. This is an important point, each PPP link will be an IPX network and will have a unique IPX network address. This means that you must decide how you will allocate addresses and what they will be. A simple convention is to allocate one IPX network address to each serial device that will support IPX/PPP. You could allocate IPX network addresses based on the login id of the connecting user, but I don't see any particularly good reason to do so.
I will assume that this is what you have done, and that there are two serial devices (modems) that we will use. The addresses I've assigned in this contrived example are:
device IPX Network Address
------ -------------------
ttyS0 0xABCDEF00
ttyS1 0xABCDEF01
Configure your /etc/ppp/options.ttyS0
file as follows:
ipx-network 0xABCDEF00
ipx-node 2:0
ipxcp-accept-remote
and your /etc/ppp/options.ttyS1
file as:
ipx-network 0xABCDEF01
ipx-node 3:0
ipxcp-accept-remote
These will ask pppd to allocate the appropriate IPX network addresses
to the link when the link is established, set the local node number to
2
or 3
and will let the remote node overwrite what the
remote node number with what it thinks it is. Note that each of the addresses
are hexadecimal numbers and that 0x
is required at the start of the
network address, but not required at the start of the node address.
There are other places this information could be configured. If you have only
one dialin modem then an entry could go into the /etc/ppp/options
file. Alternatively this information can be passed on the command line to
pppd.
To test the configuration you will need to have a client configuration that is known to work. When the caller dials in, logs in and pppd starts it will assign the network address, advise the client of the servers node number and negotiate the clients node number. When this has completed, and after ipxd has detected the new interface the client should be able to establish IPX connections to remote hosts.
In a client configuration, whether or not you configure your Linux machine as an IPX router depends on whether you have a local LAN that you wish to act as an IPX router for. If you are a standalone machine connecting to an IPX/PPP dialin server then you won't need to run ipxd, but if you have a LAN and wish all of the machines on the LAN to make use of the IPX/PPP route then you must configure and run ipxd as described. This configuration is much simpler because you do not have multiple serial devices to configure.
The simplest configuration is one that allows the server to supply all of the IPX network configuration information. This configuration would be compatible with the server configuration described above.
Again you need to add some options to your /etc/ppp/options
file,
they are:
ipxcp-accept-network
ipxcp-accept-remote
ipxcp-accept-local
These options tell pppd to act completely passively and accept
all of the configuration details from the server. You could supply default
values here for servers that don't supply details by adding
ipx-network
and ipx-node
entries similar to the server
configuration.
To test the client you will need a known working server to dial into. After
you have dialled in and pppd has run you should see the IPX details configured
on your ppp0
device when you run the ifconfig command and
you should be able to use ncpmount.
I'm not sure whether you will have to manually add IPX routes so that you can reach distant fileserver or not. This seems likely. If anyone running this configuration could tell me I'd be grateful.
Many of you will be in a situation where you have two Novell Local Area Netorks
with only an IP connection between them. How do you play multiplayer deathmatch
DOOM for DOS via this arrangement you might ask ? Andreas Godzina
<ag@agsc.han.de>
has an answer for you in the form of
ipxtunnel.
ipxtunnel provides a bridge-like facility for IPX by allowing IPX packets to be encapsulated with tcp/ip datagrams so that they can be carried by a tcp/ip connection. It listens for IPX packets and when it hears one it wraps it within a tcp/ip datagram and routes it to a remote IP address that you specify. For this to work of course the machine that you route the encapsulated IPX must also be running a copy of the same version of ipxtunnel as you.
You can obtain ipxtunnel from sunsite.unc.edu or mirror sites.
ipxtunnel built cleanly for me using the following commands:
# cd /usr/src
# tar xvfz .../ipxtunnel.tgz
# cd ipxtunnel
# make
Configuration for ipxtunnel is easy. Lets say that your friends
machine is gau.somewhere.com
and your machine is called
gim.sw.edu
. ipxtunnel uses a configuration file called
/etc/ipxtunnel.conf
. This file allows you to specify the default UDP
port to use for the tcp/ip connection, where to send the encapsulated data
and which of your local interfaces ipxtunnel should listen on
and deliver IPX packets to.
A simple configuration file would look like the following:
#
# /etc/ipxtunnel.conf for gim.sw.edu
#
# The UDP port to use: (default 7666)
port 7777
#
# The remote machine to send IPX packets to: (no default)
remote gau.somewhere.com
#
# The local interfaces to listen for IPX on: (default eth0)
interface eth0
interface eth1
Obviously the other machine would have a similar configuration file specifying
this machine as a remote
host.
ipxtunnel acts like an IPX bridge, so the IPX networks at either end of the link should probably be the same. Andreas has never tested the ipxtunnel in an environment that actually supports Novell file servers so if you do try this in a real environment let Andreas know if it works or not.
If the ipxtunnel is working you should be able to start your DOOM machines up at each end of the link running IPX mode and they should see each other.
Andreas has only used this code over good high speed lines and he makes no claim as to its performance when your link is low speed. Again, let him know what works for you and what doesn't.
Caldera Inc., produce a Linux distribution that features a range of commercially supported enhancements including fully functional Novell NetWare client support. The base distribution is the well respected Red Hat Linux Distribution and Caldera have added their "Network Desktop" products to this. The NetWare support provides a fully featured Novell NetWare client built on technology licensed from Novell Corporation. The client provides full client access to Novell 3.x and 4.x fileservers and includes features such as NetWare Directory Service (NDS) and RSA encryption.
You can obtain much more information and ordering details from the: Caldera Inc Web Server.
If you work within a Netware 4.x and/or NDS environment then the Caldera Netware Client is the only solution available.
If you have a business critical application for Novell support for Linux then the Caldera product should be something you take a close look at.
The Caldera Corporation offers a fully licensed and fully supported Netware 3.x and 4.x client. You can obtain information about it from the Caldera Inc Web Server.
The Linux IPX software does work with ArcNet and Token Ring interfaces. I haven't heard of anyone trying it with AX.25 yet. Configuration is the same as for configuring for ethernet except you will have to substitute appropriate device names in place of 'eth0' and appopriate hardware addresses where necessary.
If you have more than one interface in your machine you should use the ipx_interface command to manually configure each one, you should not use the `plug n play' configuration.
IPX networking is similar, but not identical to, IP networking. A major difference is the way that addresses are used. IPX does not use the concept of subnetworking and so the sort of associations that you have between network addresses and networks is different. The rules are fairly simple:
There are a variety of frame types in use over which you can run IPX.
The most common of these are described in the 'common terms' section of this
document (under the `Frame Type
entry').
If you are installing your machine on an existing network then you must use
whatever is already in use to allow you to interwork with the other hosts on
the network, but if the installation is a brand new network you can use any
of a range of protocols to carry your IPX traffic. My recommendation if you
are configuring a brand new network and you need to carry both IPX and IP
traffic is to use the Ethernet_II
frame type.
Apparently they can, yeah. I could make nasty comments, but instead I'll just suggest that you use the manual frame type configuration instead of the automatic one. It is probably the better way anyway.
You are probably not running a kernel that supports IPX, either recompile your kernel so it does, or double check that you have actually used lilo to install and run the new kernel.
You are probably not running a kernel that supports IPX, either recompile your kernel so it does, or double check that you have actually used lilo to install and run the new kernel.
You've probably compiled IPX as a module and not ensured that it was loaded before started pppd.
To use NFS to export an NCP filesystem you must mount it using the
ncpmount -V
option. This option allows you to mount only
one volume of a fileserver instead of the usual mounting of all of them.
When you do this your NFS daemon will allow you to export that filesystem in
the usual way.
You must have the get nearest server enabled. That is, entry 401 in /etc/nwserv.conf should be 0 unless you have a reason for not responding to get nearest servers. If you just want slist to work and not respond to every get nearest server request, include your internal network and node number in /etc/nwserv.stations and set entry 401 in /etc/nwserv.conf to 2.
Martin and Volker's code is slowly beginning to converge. Recent versions
of mars_nwe have an option to enable it to work with ncpfs.
You must enable the WITH_NAME_SPACE_CALLS
in the mars_nwe
config.h
file.
A contrived question deserves a contrived answer. I'm glad you asked,
Martin has a package that he distributes alongside his mars_nwe
package that offers free DOS client support for the mars_nwe server.
You can find it at the same sites as the server, and it will be called
mars_dosutils-0.01.tgz
. It includes C source code for programs such
as slist.exe, login.exe, map.exe etc. The source
is compilable with Borland(tm) C.
The IPX-HOWTO, a guide to software supporting the IPX protocol for Linux. Copyright (c) 1995 Terry Dawson.
This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details.
You should have received a copy of the GNU General Public License along with this program; if not, write to the:
Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
Terry Dawson <terry@perf.no.itg.telstra.com.au>
for the original
document
David E. Storey <dave@tamos.gmu.edu>
and
Volker Lendecke <lendecke@namu01.gwdg.de>
both assisted greatly by supplying me with information for this document.
Gilbert Callaghan <gilbert@pokey.inviso.com>
,
David Higgins <dave@infra.com>
and
Chad Robinson <chadr@brtgate.brttech.com>
each contributed
information on configuring IPX/PPP.
Bennie Venter <bjv@Gil-galad.paradigm-sa.com>
contributed some useful
information relating to frame types.
Christopher Wall <vergil@idir.net
contributed some useful suggestions
to improve the readability and layout of the document.
Axel Boldt <boldt@math.ucsb.edu>
contributed some useful suggestions
and feedback.
Erik D. Olson <eriko@wrq.com>
provided some useful feedback and
information on configuring PPP for IPX.
Brian King <root@brian.library.dal.ca>
contributed a question for the
FAQ section.
"NetWare" is a registered trademark of the Novell Corporation. "Caldera" is a registered trademark of the Caldera Corporation.
regards
Kevin Thorpe.
<kevin@pricetrak.com>