Linux Ethernet-Howto by Paul Gortmaker v2.66, 6 July 1998 This is the Ethernet-Howto, which is a compilation of information about which ethernet devices can be used for Linux, and how to set them up. It hopefully answers all the frequently asked questions about using ethernet cards with Linux. Note that this Howto is focused on the hardware and low level driver aspect of the ethernet cards, and does not cover the software end of things like ifconfig and route. See the Network Howto for that stuff. ______________________________________________________________________ Table of Contents 1. Introduction 1.1 New Versions of this Document 1.2 Using the Ethernet-Howto 1.3 HELP - It doesn't work! 2. What card should I buy for Linux? 2.1 So What Drivers are Stable? 2.2 Eight bit vs 16 bit Cards 2.3 32 Bit (VLB/EISA/PCI) Ethernet Cards 2.4 Available 100Mbs Cards and Drivers 2.5 100VG versus 100BaseT 2.6 Programmed I/O vs. Shared Memory vs. DMA 2.6.1 Programmed I/O (e.g. NE2000, 3c509) 2.6.2 Shared memory (e.g. WD80x3, SMC-Ultra, 3c503) 2.6.3 Slave (normal) Direct Memory Access (e.g. none for Linux!) 2.6.4 Bus Master Direct Memory Access (e.g. LANCE, DEC 21040) 2.7 Type of cable that your card should support 3. Frequently Asked Questions 3.1 Alpha Drivers -- Getting and Using them 3.2 Using More than one Ethernet Card per Machine 3.3 Poor NE2000 Clones 3.4 Problems with NE1000 / NE2000 cards (and clones) 3.5 Problems with SMC Ultra/EtherEZ and WD80*3 cards 3.6 Problems with 3Com cards 3.7 FAQs Not Specific to Any Card. 3.7.1 Ethercard is Not Detected at Boot. 3.7.2 (TT 3.7.3 PCI machine detects card but driver fails probe. 3.7.4 Shared Memory ISA cards in PCI Machine dont work (0xffff) 3.7.5 NexGen machine gets `mismatched read page pointers' errors. 3.7.6 Asynchronous Transfer Mode (ATM) Support 3.7.7 Gigabyte Ethernet Support 3.7.8 FDDI Support 3.7.9 Full Duplex Support 3.7.10 Ethernet Cards for Linux on Alpha/AXP PCI Boards 3.7.11 Ethernet for Linux on SUN/Sparc Hardware. 3.7.12 Linking 10BaseT without a Hub 3.7.13 SIOCSIFxxx: No such device 3.7.14 SIOCSFFLAGS: Try again 3.7.15 Using `ifconfig' and Link UNSPEC with HW-addr of 00:00:00:00:00:00 3.7.16 Huge Number of RX and TX Errors 3.7.17 Entries in 3.7.18 Linux and ``trailers'' 3.7.19 Access to the raw Ethernet Device 4. Performance Tips 4.1 General Concepts 4.2 ISA Bus Speed 4.3 Setting the TCP Rx Window 4.4 Increasing NFS performance 5. Vendor/Manufacturer/Model Specific Information 5.1 3Com 5.1.1 3c501 5.1.2 EtherLink II, 3c503, 3c503/16 5.1.3 3c505 5.1.4 3c507 5.1.5 3c509 / 3c509B 5.1.6 3c515 5.1.7 3c523 5.1.8 3c527 5.1.9 3c529 5.1.10 3c562 5.1.11 3c575 5.1.12 3c579 5.1.13 3c589 / 3c589B 5.1.14 3c590 / 3c595 5.1.15 3c592 / 3c597 5.1.16 3c900 / 3c905 / 3c905B 5.2 Accton 5.2.1 Accton MPX 5.2.2 Accton EN1203, EN1207, EtherDuo-PCI 5.2.3 Accton EN2209 Parallel Port Adaptor (EtherPocket) 5.2.4 Accton EN2212 PCMCIA Card 5.3 Allied Telesyn/Telesis 5.3.1 AT1500 5.3.2 AT1700 5.3.3 AT2450 5.3.4 AT2540FX 5.4 AMD / Advanced Micro Devices 5.4.1 AMD LANCE (7990, 79C960/961/961A, PCnet-ISA) 5.4.2 AMD 79C965 (PCnet-32) 5.4.3 AMD 79C970/970A (PCnet-PCI) 5.4.4 AMD 79C971 (PCnet-FAST) 5.4.5 AMD 79C974 (PCnet-SCSI) 5.5 Ansel Communications 5.5.1 AC3200 EISA 5.6 Apricot 5.6.1 Apricot Xen-II On Board Ethernet 5.7 Arcnet 5.8 AT&T 5.8.1 AT&T T7231 (LanPACER+) 5.9 AT-Lan-Tec / RealTek 5.9.1 AT-Lan-Tec / RealTek Pocket adaptor 5.9.2 RealTek 8009 5.9.3 RealTek 8019 5.9.4 RealTek 8029 5.9.5 RealTek 8129/8139 5.10 Boca Research 5.10.1 Boca BEN (ISA, VLB, PCI) 5.11 Cabletron 5.11.1 E10**, E10**-x, E20**, E20**-x 5.11.2 E2100 5.11.3 E22** 5.12 Cogent 5.12.1 EM100-ISA/EISA 5.12.2 Cogent eMASTER+, EM100-PCI, EM400, EM960, EM964 5.13 Compaq 5.13.1 Compaq Deskpro / Compaq XL (Embedded AMD Chip) 5.14 Danpex 5.14.1 Danpex EN9400 5.15 D-Link 5.15.1 DE-100, DE-200, DE-220-T, DE-250 5.15.2 DE-520 5.15.3 DE-530 5.15.4 DE-600 5.15.5 DE-620 5.15.6 DE-650 5.16 DFI 5.16.1 DFINET-300 and DFINET-400 5.17 Digital / DEC 5.17.1 DEPCA, DE100/1, DE200/1/2, DE210, DE422 5.17.2 Digital EtherWorks 3 (DE203, DE204, DE205) 5.17.3 DE425 (EISA), DE434, DE435, DE500 5.17.4 DEC 21040, 21041, 2114x, Tulip 5.18 Farallon 5.18.1 Farallon Etherwave 5.19 Hewlett Packard 5.19.1 27245A 5.19.2 HP EtherTwist, PC Lan+ (27247, 27252A) 5.19.3 HP-J2405A 5.19.4 HP-Vectra On Board Ethernet 5.19.5 HP 10/100 VG Any Lan Cards (27248B, J2573, J2577, J2585) 5.19.6 HP NetServer 10/100TX PCI (D5013A) 5.20 IBM / International Business Machines 5.20.1 IBM Thinkpad 300 5.20.2 IBM Credit Card Adaptor for Ethernet 5.20.3 IBM Token Ring 5.21 ICL Ethernet Cards 5.21.1 ICL EtherTeam 16i/32 5.22 Intel Ethernet Cards 5.22.1 Ether Express 5.22.2 Ether Express PRO/10 5.22.3 Ether Express PRO/10 PCI (EISA) 5.22.4 Ether Express PRO 10/100B 5.23 Kingston 5.24 LinkSys 5.24.1 LinkSys Etherfast 10/100 Cards. 5.24.2 LinkSys Pocket Ethernet Adapter Plus (PEAEPP) 5.24.3 LinkSys PCMCIA Adaptor 5.25 Microdyne 5.25.1 Microdyne Exos 205T 5.26 Mylex 5.26.1 Mylex LNE390A, LNE390B 5.26.2 Mylex LNP101 5.26.3 Mylex LNP104 5.27 Novell Ethernet, NExxxx and associated clones. 5.27.1 NE1000, NE2000 5.27.2 NE2000-PCI (RealTek/Winbond/Compex) 5.27.3 NE-10/100 5.27.4 NE1500, NE2100 5.27.5 NE3200 5.27.6 NE5500 5.28 Proteon 5.28.1 Proteon P1370-EA 5.28.2 Proteon P1670-EA 5.29 Pure Data 5.29.1 PDUC8028, PDI8023 5.30 Racal-Interlan 5.30.1 ES3210 5.30.2 NI5010 5.30.3 NI5210 5.30.4 NI6510 (not EB) 5.30.5 EtherBlaster (aka NI6510EB) 5.31 Sager 5.31.1 Sager NP943 5.32 Schneider & Koch 5.32.1 SK G16 5.33 SEEQ 5.33.1 SEEQ 8005 5.34 SMC (Standard Microsystems Corp.) 5.35 Thomas Conrad 5.35.1 Thomas Conrad TC-5048 5.36 Western Digital / SMC 5.36.1 WD8003, SMC Elite 5.36.2 WD8013, SMC Elite16 5.36.3 SMC Elite Ultra 5.36.4 SMC Elite Ultra32 EISA 5.36.5 SMC EtherEZ (8416) 5.36.6 SMC EtherPower PCI (8432) 5.36.7 SMC EtherPower II PCI (9432) 5.36.8 SMC 3008 5.36.9 SMC 3016 5.36.10 SMC-9000 / SMC 91c92/4 5.36.11 SMC 91c100 5.37 Xircom 5.37.1 PE1, PE2, PE3-10B* 5.38 Zenith 5.38.1 Z-Note 5.39 Znyx 5.39.1 Znyx ZX342 (DEC 21040 based) 5.40 Identifying an Unknown Card 5.40.1 Identifying the Network Interface Controller 5.40.2 Identifying the Ethernet Address 5.40.3 Tips on Trying to Use an Unknown Card 5.41 Drivers for Non-Ethernet Devices 6. Cables, Coax, Twisted Pair 6.1 Thin Ethernet (thinnet) 6.2 Twisted Pair 6.3 Thick Ethernet 7. Software Configuration and Card Diagnostics 7.1 Configuration Programs for Ethernet Cards 7.1.1 WD80x3 Cards 7.1.2 Digital / DEC Cards 7.1.3 NE2000+ or AT/LANTIC Cards 7.1.4 3Com Cards 7.2 Diagnostic Programs for Ethernet Cards 8. Technical Information 8.1 Probed Addresses 8.2 Writing a Driver 8.3 Driver interface to the kernel 8.3.1 Probe 8.3.2 Interrupt handler 8.3.3 Transmit function 8.3.4 Receive function 8.3.5 Open function 8.3.6 Close function (optional) 8.3.7 Miscellaneous functions 8.4 Interrupts and Linux 8.5 Programming the Intel chips (i82586 and i82593) 8.6 Technical information from 3Com 8.7 Notes on AMD PCnet / LANCE Based cards 8.8 Multicast and Promiscuous Mode 8.9 The Berkeley Packet Filter (BPF) 9. Networking with a Laptop/Notebook Computer 9.1 Using SLIP 9.2 Built in NE2000 9.3 PCMCIA Support 9.4 ISA Ethercard in the Docking Station. 9.5 Pocket / parallel port adaptors. 10. Miscellaneous. 10.1 Passing Ethernet Arguments to the Kernel 10.1.1 The 10.1.2 The 10.2 Using the Ethernet Drivers as Modules 10.3 Mailing Lists and the Linux Newsgroups 10.4 Related Documentation 10.5 Contributors 10.6 Disclaimer and Copyright 10.7 Closing ______________________________________________________________________ 1. Introduction The Ethernet-Howto covers what cards you should and shouldn't buy; how to set them up, how to run more than one, and other common problems and questions. It contains detailed information on the current level of support for all of the most common ethernet cards available. It does not cover the software end of things, as that is covered in the NET-3 Howto. Also note that general non-Linux specific questions about Ethernet are not (or at least they should not be) answered here. For those types of questions, see the excellent amount of information in the comp.dcom.lans.ethernet FAQ. You can FTP it from rtfm.mit.edu just like all the other newsgroup FAQs. This present revision covers distribution kernels up to and including 2.0.34. Some information pertaining to development kernels up to version 2.1.108 is also included. The Ethernet-Howto is by: Paul Gortmaker, gpg109@rsphy1.anu.edu.au The primary source of information for the initial ASCII-only version of the Ethernet-Howto was: Donald J. Becker, becker@cesdis.gsfc.nasa.gov who we should thank for writing the vast majority of ethernet card drivers that are presently available for Linux. He also is the original author of the NFS server too. Thanks Donald! Please see the Disclaimer and Copying information at the end of this document for information about redistribution of this document and the usual `we are not responsible for what you do...' legal stuff. 1.1. New Versions of this Document New versions of this document can be retrieved via anonymous FTP from: Sunsite HOWTO Archive and various Linux ftp mirror sites. Updates will be made as new information and/or drivers becomes available. If this copy that you are reading is more than 6 months old, it is either out of date, or it means that I have been lazy and haven't updated it. If you have sent me an update and it is not included in the next release, it probably means I've lost it amongst the ton of junk e-mail I get. Please re-send it (along with an abusive message) and I will try and make sure it gets included in the next release. This document was produced by using the SGML system that was specifically set up for the Linux Howto project, and there are various output formats available, including, postscript, dvi, ascii, html, and soon TeXinfo. I would recommend viewing it in the html (via a WWW browser) or the Postscript/dvi format. Both of these contain cross-references that are lost in the ascii format. If you want to get the latest copy off sunsite, here is URL. Ethernet-HOWTO 1.2. Using the Ethernet-Howto As this guide is getting bigger and bigger, you probably don't want to spend the rest of your afternoon reading the whole thing. And the good news is that you don't have to read it all. Chances are you are reading this document beacuse you can't get things to work and you don't know what to do or check. The next section (``HELP - It doesn't work!'') is aimed at newcomers to linux and will point you in the right direction. Typically the same problems and questions are asked over and over again by different people. Chances are your specific problem or question is one of these frequently asked questions, and is answered in the FAQ portion of this document . (``The FAQ section''). Everybody should have a look through this section before posting for help. If you haven't got an ethernet card, then you will want to start with deciding on a card. (``What card should I buy...'') If you have already got an ethernet card, but are not sure if you can use it with Linux, then you will want to read the section which contains specific information on each manufacturer, and their cards. (``Vendor Specific...'') If you are interested in some of the technical aspects of the Linux device drivers, then you can have a browse of the section with this type of information. (``Technical Information'') 1.3. HELP - It doesn't work! Okay, don't panic. This will lead you through the process of getting things working, even if you have no prior background in linux or ethernet hardware. First thing you need to do is figure out what model your card is so you can determine if Linux has a driver for that particular card. Different cards typically have different ways of being controlled by the host computer, and the linux driver (if there is one) contains this control information in a format that allows linux to use the card. If you don't have any manuals or anything of the sort that tell you anything about the card model, then you can try the section on helping with mystery cards (reference section: ``Identifying an Unknown Card''). Now that you know what type of card you have, read through the details of your particular card in the card specific section (reference section: ``Vendor Specific...'') which lists in alphabetical order, card manufacturers, individual model numbers and whether it has a linux driver or not. If it lists it as `Not Supported' you can pretty much give up here. If you can't find your card in that list, then check to see if your card manual lists it as being `compatible' with another known card type. For example there are hundreds, if not thousands of different cards made to be compatible with the original Novell NE2000 design. Assuming you have found out that a linux driver exists for your card, you now have to find it and make use of it. Just because linux has a driver for your card does not mean that it is built into every kernel. (The kernel is the core operating system that is first loaded at boot, and contains drivers for various pieces of hardware, among other things.) Depending on who made the particular linux distribution you are using, there may be only a few pre-built kernels, and a whole bunch of drivers as smaller separate modules, or there may be a whole lot of kernels, covering a vast combination of built-in driver combinations. Most linux distributions now ship with a bunch of small modules that are the various drivers. The required modules are typically loaded late in the boot process, or on-demand as a driver is needed to access a particualr device. You will need to attach this module to the kernel after it has booted up. See the information that came with your distribution on installing and using modules, along with the module section in this document. (``Using the Ethernet Drivers as Modules'') If you didn't find either a pre-built kernel with your driver, or a module form of the driver, chances are you have a typically uncommon card, and you will have to build your own kernel with that driver included. Once you have linux installed, building a custom kernel is not difficult at all. You essentially answer yes or no to what you want the kernel to contain, and then tell it to build it. There is a Kernel-HowTo that will help you along. At this point you should have somehow managed to be booting a kernel with your driver built in, or be loading it as a module. About half of the problems people have are related to not having driver loaded one way or another, so you may find things work now. If it still doesn't work, then you need to verify that the kernel is indeed detecting the card. To do this, you need to type dmesg | more when logged in after the system has booted and all modules have been loaded. This will allow you to review the boot messages that the kernel scrolled up the screen during the boot process. If the card has been detected, you should see somewhere in that list a message from your card's driver that starts with eth0, mentions the driver name and the hardware parameters (interrupt setting, input/output port address, etc) that the card is set for. If you don't see a message like this, then the driver didn't detect your card, and that is why things aren't working. See the FAQ (``The FAQ Section'') for what to do if your card is not detected. If you have a NE2000 compatible, there is also some NE2000 specific tips on getting a card detected in the FAQ section as well. If the card is detected, but the detection message reports some sort of error, like a resource conflict, then the driver probably won't have initialized properly and the card still wont be useable. Most common error messages of this sort are also listed in the FAQ section, along with a solution. If the detection message seems okay, then double check the card resources reported by the driver against those that the card is physically set for (either by little black jumpers on the card, or by a software utility supplied by the card manufacturer.) These must match exactly. For example, if you have the card jumpered or configured to IRQ 15 and the driver reports IRQ 10 in the boot messages, things will not work. The FAQ section discusses the most common cases of drivers incorrectly detecting the configuration information of various cards. At this point, you have managed to get you card detected with all the correct parameters, and hopefully everything is working. If not, then you either have a software configuration error, or a hardware configuration error. A software configuration error is not setting up the right network addresses for the ifconfig and route commands, and details of how to do that are fully described in the Network HowTo and the `Network Administrator's Guide' which both probably came on the CD-ROM you installed from. A hardware configuration error is when some sort of resource conflict or mis-configuration (that the driver didn't detect at boot) that stops the card from working properly. This typically can be observed in one of three different ways. (1) You get an error message when ifconfig tries to open the device for use, such as ``SIOCSFFLAGS: Try again''. (2) The driver reports eth0 error messages (viewed by dmesg | more) or strange inconsistencies for each time it tries to send or receive data. (3) Typing cat /proc/net/dev shows non-zero numbers in one of the errs, drop, fifo, frame or carrier columns for eth0. Most of the typical hardware configuration errors are also discussed in the FAQ section. Well, if you have got to this point and things still aren't working, read the FAQ section of this document, read the vendor specific section detailing your particular card, and if it still doesn't work then you may have to resort to posting to an appropriate newsgroup for help. If you do post, please detail all relevant information in that post, such as the card brand, the kernel version, the driver boot messages, the output from cat /proc/net/dev, a clear description of the problem, and of course what you have already tried to do in an effort to get things to work. You would be surprised at how many people post useless things like ``Can someone help me? My ethernet doesn't work.'' and nothing else. Readers of the newsgroups tend to ignore such silly posts, whereas a detailed and informational problem description may allow a `linux- guru' to spot your problem right away. 2. What card should I buy for Linux? The answer to this question depends heavily on exactly what you intend on doing with your net connection, and how much traffic it will see. If you only expect a single user to be doing the occasional ftp session or WWW connection, then even an old 8 bit ISA card will probably keep you happy. If you intend to set up a server, and you require the CPU overhead of Rx'ing and Tx'ing network data to be kept to a minimum, you probably want to look at one of the newer PCI cards that has bus-mastering capapbility, such as with the DEC tulip (21xxx) chip, or the AMD PCnet-PCI chip. If you fall somewhere in the middle of the above, then any one of the 16 bit ISA cards with stable drivers will do the job for you. 2.1. So What Drivers are Stable? Of the 16 bit ISA cards, the following drivers are very mature, and you shouldn't have any problems if you buy a card that uses these drivers. SMC-Ultra/EtherEZ, SMC-Elite (WD80x3), 3c509, Lance, NE2000. This is not to say that all the other drivers are unstable. It just happens that the above are the oldest and most used of all the linux drivers, making them the safest choice. Note that some el-cheapo motherboards can have trouble with the bus- mastering that the ISA Lance cards do, and some el-cheapo NE2000 clones can have trouble getting detected at boot. The most commonly used linux PCI drivers are probably the 3Com Vortex/Boomerang (3c59x/3c9xx), the DEC tulip (21xxx), and the Intel EtherExpressPro 100. The various PCI-NE2000 clone cards are also extremely common, but purchasing a PCI-NE2000 clone card is not recommended unless the lowest possible price is more important than having a modern high-performace design card. 2.2. Eight bit vs 16 bit Cards You probably can't buy a new 8 bit ISA ethercard anymore, but you will find lots of them turning up at computer swap meets and the like for the next few years, at very low prices. This will make them popular for ``home-ethernet'' systems. The above holds true for 16 bit ISA cards now as well, since PCI cards are now very common. Some 8 bit cards that will provide adequate performance for light to average use are the wd8003, the 3c503 and the ne1000. The 3c501 provides poor performance, and these poor 12 year old relics of the XT days should be avoided. The 8 bit data path doesn't hurt performance that much, as you can still expect to get about 500 to 800kB/s ftp download speed to an 8 bit wd8003 card (on a fast ISA bus) from a fast host. And if most of your net-traffic is going to remote sites, then the bottleneck in the path will be elsewhere, and the only speed difference you will notice is during net activity on your local subnet. 2.3. 32 Bit (VLB/EISA/PCI) Ethernet Cards Note that a 10Mbs network typically doesn't justify requiring a 32 bit interface. See ``Programmed I/O vs. ...'' as to why having a 10Mbps ethercard on an 8MHz ISA bus is really not a bottleneck. Even though having the ethercard on a fast bus won't necessarily mean faster transfers, it will usually mean reduced CPU overhead, which is good for multi-user systems. Of course for 100Mbps networks, which are now commonplace, the 32 bit interface is a must to make use of the full bandwidth. AMD has the 32 bit PCnet-VLB and PCnet-PCI chips. See ``AMD PCnet-32'' for info on the 32 bit versions of the LANCE / PCnet-ISA chip. The DEC 21xxx PCI `tulip' chip is another option (see ``DEC 21040'') for power-users. Many manufacturers produce cards that use this chip, and the prices of such no-name cards is usually quite cheap. 3Com's `Vortex' and `Boomerang' PCI cards are also another option, and the price is quite cheap if you can get one under their evaluation deal while it lasts. (see ``3c590/3c595'') Intel's EtherExpress Pro 10/100 PCI cards have also been reported to work well with linux. (see ``EtherExpress'') Various clone manufacturers have started making PCI NE2000 clones based on a RealTek or Winbond chip. These cards are also supported by the linux ne2000 driver for v2.0.31 and newer kernels. However you only benefit from the faster bus interface, as the card is still using the age-old ne2000 driver interface. As of v2.0.34 (and above) a separate PCI-specific driver for these cards ne2k-pci.c is also available, which will be sightly more efficient than the ISA ne.c driver. 2.4. Available 100Mbs Cards and Drivers The present list of supported 100Mbs hardware is as follows: cards with the DEC 21140 chip; the 3c595/3c90x Vortex cards; and the HP 100VG ANY-LAN. The drivers for the first two are quite stable, but feedback on the HP driver has been low so far. The EtherExpressPro10/100B now also has a driver in the current v2.0 kenrel. For updates and/or support, see the relevant section in this document. The 21140 100Base-? chip is supported with the same driver as its 10Mbs counterpart, the 21040. SMC's 100Mbs EtherPower PCI card uses this chip. As with the 21040, you have a choice of two drivers to pick from. Also have a look at the information on Donald's WWW site, at the following URL: 100Mbs Ethernet Donald had done a fair bit of work with the SMC EtherPower-10/100 cards, and reported getting about 4.6MB/s application to application with TCP on P5-100 Triton machines. (See ``3c595'' and ``DEC 21140'' for more details.) For 100VG information, see the following section, and this URL on Donald's Site: Donald's 100VG Page You may also be interested in looking at: Dan Kegel's Fast Ethernet Page 2.5. 100VG versus 100BaseT 100BaseT is much more prominent than 100VG, and the following blurb from an older one of Donald's informative comp.os.linux postings summarizes the situation quite well: ``For those not in the know, there are two competing 100Mbs ethernet standards, 100VG (aka 100baseVG and 100VG-AnyLAN) and 100baseT (with 100baseTx, 100baseT4 and 100baseFx cable types). 100VG was on the market first, and I feel that it is better engineered than 100baseTx. I was rooting for it to win, but it clearly isn't going to. HP et al. made several bad choices: 1) Delaying the standard so that they could accommodate IBM and support token ring frames. It `seemed like a good idea at the time', since it would enable token ring shops to upgrade without the managers having to admit they made a very expensive mistake committing to the wrong technology. But there was nothing to be gained, as the two frame types couldn't coexist on a network, token ring is a morass of complexity, and IBM went with 100baseT anyway. 2) Producing only ISA and EISA cards. (A PCI model was only recently announced.) The ISA bus is too slow for 100mbs, and relatively few EISA machines exist. At the time VLB was common, fast, and cheap with PCI a viable choice. But "old-timer" wisdom held that servers would stay with the more expensive EISA bus. 3) Not sending me a databook. Yes, this action was the real reason for the 100VGs downfall :-). I called all over for programming info, and all I could get was a few page color glossy brochure from AT&T describing how wonderful the Regatta chipset was.'' 2.6. Programmed I/O vs. Shared Memory vs. DMA If you can already send and receive back-to-back packets, you just can't put more bits over the wire. Every modern ethercard can receive back-to-back packets. The Linux DP8390 drivers (wd80x3, SMC-Ultra, 3c503, ne2000, etc) come pretty close to sending back-to-back packets (depending on the current interrupt latency) and the 3c509 and AT1500 hardware have no problem at all automatically sending back-to-back packets. The ISA bus can do 5.3MB/sec (42Mb/sec), which sounds like more than enough for 10Mbps ethernet. In the case of the 100Mbps cards, you clearly need a faster bus to take advantage of the network bandwidth. 2.6.1. Programmed I/O (e.g. NE2000, 3c509) Pro: Doesn't use any constrained system resources, just a few I/O registers, and has no 16M limit. Con: Usually the slowest transfer rate, the CPU is waiting the whole time, and interleaved packet access is usually difficult to impossible. 2.6.2. Shared memory (e.g. WD80x3, SMC-Ultra, 3c503) Pro: Simple, faster than programmed I/O, and allows random access to packets. The linux drivers compute the checksum of incoming IP packets as they are copied off the card, resulting in a further reduction of CPU usage vs. an equivalent PIO card. Con: Uses up memory space (a big one for DOS users, essentially a non- issue under Linux), and it still ties up the CPU. 2.6.3. Slave (normal) Direct Memory Access (e.g. none for Linux!) Pro: Frees up the CPU during the actual data transfer. Con: Checking boundary conditions, allocating contiguous buffers, and programming the DMA registers makes it the slowest of all techniques. It also uses up a scarce DMA channel, and requires aligned low memory buffers. 2.6.4. Bus Master Direct Memory Access (e.g. LANCE, DEC 21040) Pro: Frees up the CPU during the data transfer, can string together buffers, can require little or no CPU time lost on the ISA bus. Most of the bus-mastering linux drivers now use a `copybreak' scheme where large packets are put directly into a kernel networking buffer by the card, and small packets are copied by the CPU which primes the cache for subsequent processing. Con: (Only applicable to ISA bus cards) Requires low-memory buffers and a DMA channel for cards. Any bus-master will have problems with other bus-masters that are bus-hogs, such as some primitive SCSI adaptors. A few badly-designed motherboard chipsets have problems with bus-masters. And a reason for not using any type of DMA device is using a 486 processor designed for plug-in replacement of a 386: these processors must flush their cache with each DMA cycle. (This includes the Cx486DLC, Ti486DLC, Cx486SLC, Ti486SLC, etc.) 2.7. Type of cable that your card should support If you are setting up a small ``personal'' network, you will probably want to use thinnet or thin ethernet cable. This is the style with the standard BNC connectors. See ``Cables, Coax...'' for other concerns with different types of ethernet cable. Most ethercards also come in a `Combo' version for only $10-$20 more. These have both twisted pair and thinnet transceiver built-in, allowing you to change your mind later. The twisted pair cables, with the RJ-45 (giant phone jack) connectors is technically called 10BaseT. You may also hear it called UTP (Unsheilded Twisted Pair). The thinnet, or thin ethernet cabling, (RG-58 coaxial cable) with the BNC (metal push and turn-to-lock) connectors is technically called 10Base2. The older thick ethernet (10mm coaxial cable) which is only found in older installations is called 10Base5. Large corporate installations will most likely use 10BaseT instead of 10Base2. 10Base2 does not offer an easy upgrade path to the new upcoming 100Base-whatever. 3. Frequently Asked Questions Here are some of the more frequently asked questions about using Linux with an Ethernet connection. Some of the more specific questions are sorted on a `per manufacturer basis'. However, since this document is basically `old' by the time you get it, any `new' problems will not appear here instantly. For these, I suggest that you make efficient use of your newsreader. For example, nn users would type nn -xX -s'3c' to get all the news articles in your subscribed list that have `3c' in the subject. (ie. 3com, 3c509, 3c503, etc.) The moral: Read the man page for your newsreader. 3.1. Alpha Drivers -- Getting and Using them I heard that there is an updated or alpha driver available for my card. Where can I get it? The newest of the `new' drivers can be found on Donald's ftp site: cesdis.gsfc.nasa.gov in the /pub/linux/ area. Things change here quite frequently, so just look around for it. Alternatively, it may be easier to use a WWW browser on: Don's Linux Home Page to locate the driver that you are looking for. (Watch out for WWW browsers that silently munge the source by replacing TABs with spaces and so on - use ftp, or at least an FTP URL for downloading if unsure.) Now, if it really is an alpha, or pre-alpha driver, then please treat it as such. In other words, don't complain because you can't figure out what to do with it. If you can't figure out how to install it, then you probably shouldn't be testing it. Also, if it brings your machine down, don't complain. Instead, send us a well documented bug report, or even better, a patch! Note that some of the `useable' experimental/alpha drivers have been included in the standard kernel source tree. When running make config one of the first things you will be asked is whether to ``Prompt for development and/or incomplete code/drivers''. You will have to answer `Y' here to get asked about including any alpha/experiemntal drivers. 3.2. Using More than one Ethernet Card per Machine What needs to be done so that Linux can run two ethernet cards? With the Driver as a Module: Most linux distributions use modular drivers now (as opposed to having the driver built into the kernel). In the case of PCI drivers, the module will typically detect all of the installed cards of that brand model automatically. However, for ISA cards, probing for a card is not a safe operation, and hence you typically need to supply the I/O base address of the card so the module knows where to look. This information is typically stored in the file /etc/conf.modules. As an example, consider a user that has two ISA NE2000 cards, one at 0x300 and one at 0x240 and what lines they would have in their /etc/conf.modules file: alias eth0 ne alias eth1 ne options ne io=0x240,0x300 What this does: This says that if the administrator (or the kernel) does a modprobe eth0 or a modprobe eth1 then the ne.o driver should be loaded for either eth0 or eth1. Furthermore, when the ne.o module is loaded, it should be loaded with the options io=0x240,0x300 so that the driver knows where to look for the cards. Note that the 0x is important - things like 300h as commonly used in the DOS world won't work. Switching the order of the 0x240 and the 0x300 will switch which physical card ends up as eth0 and eth1. Most of the ISA module drivers can take multiple comma separated i/o values like this example to handle multiple cards. However, some (older?) drivers, such as the 3c501.o module are currently only able to handle one card per module load. In this case you can load the module twice to get both cards detected. The /etc/conf.modules file in this case would look like: alias eth0 3c501 alias eth1 3c501 options eth0 -o 3c501-0 io=0x280 irq=5 options eth1 -o 3c501-1 io=0x300 irq=7 In this example the -o option has been used to give each instance of the module a unique name, since you can't have two modules loaded with the same name. The irq= option has also been used to to specify the hardware IRQ setting of the card. (This method can also be used with modules that accept comma separated i/o values, but it is less efficient since the module ends up being loaded twice when it doesn't really need to be.) As a final example, consider a user with one 3c503 card at 0x350and one SMC Elite16 (wd8013) card at 0x280. They would have: alias eth0 wd alias eth1 3c503 options wd io=0x280 options 3c503 io=0x350 For PCI cards, you typically only need the alias lines to correlate the ethN interfaces with the appropriate driver name, since the I/O base of a PCI card can be safely detected. The available modules are typically stored in /lib/modules/`uname -r`/net where the uname -r command gives the kernel version (e.g. 2.0.34). You can look in there to see which one matches your card. Once you have the correct settings in your conf.modules file, you can test things out with: modprobe ethN dmesg | tail where `N' is the number of the ethernet interface you are testing. With the Driver Compiled into the Kernel: If you have the driver compiled into the kernel, then the hooks for multiple ethercards are all there. However, note that at the moment only one ethercard is auto-probed for by default. This helps to avoid possible boot time hangs caused by probing sensitive cards. There are two ways that you can enable auto-probing for the second (and third, and...) card. The easiest method is to pass boot-time arguments to the kernel, which is usually done by LILO. Probing for the second card can be achieved by using a boot-time argument as simple as ether=0,0,eth1. In this case eth0 and eth1 will be assigned in the order that the cards are found at boot. Say if you want the card at 0x300 to be eth0 and the card at 0x280 to be eth1 then you could use LILO: linux ether=5,0x300,eth0 ether=15,0x280,eth1 The ether= command accepts more than the IRQ + i/o + name shown above. Please have a look at ``Passing Ethernet Arguments...'' for the full syntax, card specific parameters, and LILO tips. These boot time arguments can be made permanent so that you don't have to re-enter them every time. See the LILO configuration option `append' in the LILO manual. The second way (not recommended) is to edit the file Space.c and replace the 0xffe0 entry for the i/o address with a zero. The 0xffe0 entry tells it not to probe for that device -- replacing it with a zero will enable autoprobing for that device. Note that if you are intending to use Linux as a gateway between two networks, you will have to re-compile a kernel with IP forwarding enabled. Usually using an old AT/286 with something like the `kbridge' software is a better solution. If you are viewing this while net-surfing, you may wish to look at a mini-howto Donald has on his WWW site. Check out Multiple Ethercards . 3.3. Poor NE2000 Clones Here is a list of some of the NE-2000 clones that are known to have various problems. Most of them aren't fatal. In the case of the ones listed as `bad clones' -- this usually indicates that the cards don't have the two NE2000 identifier bytes. NEx000-clones have a Station Address PROM (SAPROM) in the packet buffer memory space. NE2000 clones have 0x57,0x57 in bytes 0x0e,0x0f of the SAPROM, while other supposed NE2000 clones must be detected by their SA prefix. This is not a comprehensive list of all the NE2000 clones that don't have the 0x57,0x57 in bytes 0x0e,0x0f of the SAPROM. There are probably hundreds of them. If you get a card that causes the driver to report an `invalid signature' then you will have to add your cards signature to the driver. The process for doing this is described below. Accton NE2000 -- might not get detected at boot, see below. Artisoft LANtastic AE-2 -- OK, but has flawed error-reporting registers. AT-LAN-TEC NE2000 -- clone uses Winbond chip that traps SCSI drivers ShineNet LCS-8634 -- clone uses Winbond chip that traps SCSI drivers Cabletron E10**, E20**, E10**-x, E20**-x -- bad clones, but the driver checks for them. See ``E10**''. D-Link Ethernet II -- bad clones, but the driver checks for them. See ``DE-100 / DE-200''. DFI DFINET-300, DFINET-400 -- bad clones, but the driver checks for them. See ``DFI-300 / DFI-400'' EtherNext UTP8, EtherNext UTP16 -- bad clones, but the driver checks for them. 3.4. Problems with NE1000 / NE2000 cards (and clones) Problem: PCI NE2000 clone card is not detected at boot with v2.0.x. Reason: The ne.c driver up to v2.0.30 only knows about the PCI ID number of RealTek 8029 based clone cards. Since then, several others have also released PCI NE2000 clone cards, with different PCI ID numbers, and hence the driver doesn't detect them. Solution: The easiest solution is to upgrade to a v2.0.31 (or newer) version of the linux kernel. It knows the ID numbers of about five different NE2000-PCI chips, and will detect them automatically at boot or at module loading time. If you upgrade to 2.0.34 (or newer) there is a PCI-only specific NE2000 driver that is slightly smaller and more efficient than the original ISA/PCI driver. Problem: PCI NE2000 clone card is reported as an ne1000 (8 bit card!) at boot or when I load the ne.o module for v2.0.x, and hence doesn't work. Reason: Some PCI clones don't implement byte wide access (and hence are not truly 100% NE2000 compatible). This causes the probe to think they are NE1000 cards. Solution: You need to upgrade to v2.0.31 (or newer) as described above. The driver(s) now check for this hardware bug. Problem: PCI NE2000 card gets terrible performance, even when reducing the window size as described in the Performance Tips section. Reason: The spec sheets for the original 8390 chip, desgined and sold over ten years ago, noted that a dummy read from the chip was required before each write operation for maximum reliablity. The driver has the facility to do this but it has been disabled by default since the v1.2 kernel days. One user has reported that re-enabling this `mis- feature' helped their performance with a cheap PCI NE2000 clone card. Solution: Since it has only been reported as a solution by one person, don't get your hopes up. Re-enabling the read before write fix is done by simply editing the file linux/drivers/net/ne.c, uncommenting the line containing NE_RW_BUGFIX and then rebuilding the kernel or module as appropriate. Please send an e-mail describing the performance difference and type of card/chip you have if this helps you. (The same can be done for the ne2k-pci.c driver as well). Probem: ISA Plug and Play NE2000 (such as RealTek 8019) is not detected. Reason: The original NE2000 specification (and hence the linux NE2000 driver) does not have support for Plug and Play. Solution: Use the DOS configuration disk that came with the card to disable PnP, and to set the card to a specified I/O address and IRQ. Add a line to /etc/conf.modules like options ne io=0xNNN where 0xNNN is the hex I/O address you set the card to. (This assumes you are using a modular driver; if not then use an ether=0,0xNNN,eth0 argument at boot). Alternatively, if you need to leave PnP enabled for compatibility with some other operating system, then look into the isapnptools package. Try man isapnp to see if it is already installed on your system. If not, then have a look at the following URL: ISA PNP Tools Problem: NE*000 card hangs machine, sometimes with a `DMA conflict' message, sometimes completely silently. Reason: There were some bugs in the driver and the upper networking layers that caused this. They have been fixed long ago, in kernels v1.2.9 and above. Upgrade your kernel. Problem: NE*000 card hangs machine during NE probe, or can not read station address properly. Reason: Kernels previous to v1.3.7 did not fully reset the card after finding it at boot. Some cheap cards are not left in a reasonable state after power-up and need to be fully reset before any attempt is made to use them. Also, a previous probe may have upset the NE card prior to the NE probe taking place. In that case, look in to using the ``reserve='' boot keyword to protect the card from other probes. Problem: NE*000 driver reports `not found (no reset ack)' during boot probe. Reason: This is related to the above change. After the initial verification that an 8390 is at the probed i/o address, the reset is performed. When the card has completed the reset, it is supposed to acknowedge that the reset has completed. Your card doesn't, and so the driver assumes that no NE card is present. Solution: You can tell the driver that you have a bad card by using an otherwise unused mem_end hexidecimal value of 0xbad at boot time. You have to also supply a non-zero i/o base for the card when using the 0xbad override. For example, a card that is at 0x340 that doesn't ack the reset would use something like: LILO: linux ether=0,0x340,0,0xbad,eth0 This will allow the card detection to continue, even if your card doesn't ACK the reset. If you are using the driver as a module, then you can supply the option bad=0xbad just like you supply the I/O address. Note that v2.0.x modules won't understand the bad= option, as it was added during the v2.1 development. Problem: NE*000 card hangs machine at first network access. Reason: This problem has been reported for kernels as old as 1.1.57 to the present. It appears confined to a few software configurable clone cards. It appears that they expect to be initialized in some special way. Solution: Several people have reported that running the supplied DOS software config program and/or the supplied DOS driver prior to warm booting (i.e. loadlin or the `three-finger-salute') into linux allowed the card to work. This would indicate that these cards need to be initialized in a particular fashion, slightly different than what the present Linux driver does. Problem: NE*000 ethercard at 0x360 doesn't get detected anymore. Reason: Kernels ( > 1.1.7X) have more sanity checks with respect to overlapping i/o regions. Your NE2000 card is 0x20 wide in i/o space, which makes it hit the parallel port at 0x378. Other devices that could be there are the second floppy controller (if equipped) at 0x370 and the secondary IDE controller at 0x376--0x377. If the port(s) are already registered by another driver, the kernel will not let the probe happen. Solution: Either move your card to an address like 0x280, 0x340, 0x320 or compile without parallel printer support. Problem: Network `goes away' every time I print something (NE2000) Reason: Same problem as above, but you have an older kernel that doesn't check for overlapping i/o regions. Use the same fix as above, and get a new kernel while you are at it. Problem: NE*000 ethercard probe at 0xNNN: 00 00 C5 ... not found. (invalid signature yy zz) Reason: First off, do you have a NE1000 or NE2000 card at the addr. 0xNNN? And if so, does the hardware address reported look like a valid one? If so, then you have a poor NE*000 clone. All NE*000 clones are supposed to have the value 0x57 in bytes 14 and 15 of the SA PROM on the card. Yours doesn't -- it has `yy zz' instead. Solution: There are two ways to get around this. The easiest is to use an 0xbad mem_end value as described above for the `no reset ack' problem. This will bypass the signature check, as long as a non-zero i/o base is also given. This way no recompilation of the kernel is required. The second method involves changing the driver itself, and then recompiling your kernel. The driver (/usr/src/linux/drivers/net/ne.c) has a "Hall of Shame" list at about line 42. This list is used to detect poor clones. For example, the DFI cards use `DFI' in the first 3 bytes of the PROM, instead of using 0x57 in bytes 14 and 15, like they are supposed to. You can determine what the first 3 bytes of your card PROM are by adding a line like: printk("PROM prefix: %2.2x %2.2x %2.2x\n",SA_prom[0],SA_prom[1],SA_prom[2]); into the driver, right after the error message you got above, and just before the "return ENXIO" at line 227. Reboot with this change in place, and after the detection fails, you will get the three bytes from the PROM like the DFI example above. Then you can add your card to the bad_clone_list[] at about line 43. Say the above line printed out: PROM prefix: 0x3F 0x2D 0x1C after you rebooted. And say that the 8 bit version of your card was called the "FOO-1k" and the 16 bit version the "FOO-2k". Then you would add the following line to the bad_clone_list[]: {"FOO-1k", "FOO-2k", {0x3F, 0x2D, 0x1C,}}, Note that the 2 name strings you add can be anything -- they are just printed at boot, and not matched against anything on the card. You can also take out the "printk()" that you added above, if you want. It shouldn't hit that line anymore anyway. Then recompile once more, and your card should be detected. Problem: Errors like DMA address mismatch Is the chip a real NatSemi 8390? (DP8390, DP83901, DP83902 or DP83905)? If not, some clone chips don't correctly implement the transfer verification register. MS-DOS drivers never do error checking, so it doesn't matter to them. (Note: The DMA address check is not done by default as of v1.2.4 for performance reasons. Enable it with the `NE_SANITY' define in ne.c if you want the check done.) Are most of the messages off by a factor of 2? If so: Are you using the NE2000 in a 16 bit slot? Is it jumpered to use only 8 bit transfers? The Linux driver expects a NE2000 to be in a 16 bit slot. A NE1000 can be in either size slot. This problem can also occur with some clones, notably older D-Link 16 bit cards, that don't have the correct ID bytes in the station address PROM. Are you running the bus faster than 8Mhz? If you can change the speed (faster or slower), see if that makes a difference. Most NE2000 clones will run at 16MHz, but some may not. Changing speed can also mask a noisy bus. What other devices are on the bus? If moving the devices around changes the reliability, then you have a bus noise problem -- just what that error message was designed to detect. Congratulations, you've probably found the source of other problems as well. Problem: The machine hangs during boot right after the `8390...' or `WD....' message. Removing the NE2000 fixes the problem. Solution: Change your NE2000 base address to something like 0x340. Alternatively, you can use the ``reserve='' boot argument in conjunction with the ``ether='' argument to protect the card from other device driver probes. Reason: Your NE2000 clone isn't a good enough clone. An active NE2000 is a bottomless pit that will trap any driver autoprobing in its space. Changing the NE2000 to a less-popular address will move it out of the way of other autoprobes, allowing your machine to boot. Problem: The machine hangs during the SCSI probe at boot. Reason: It's the same problem as above, change the ethercard's address, or use the reserve/ether boot arguments. Problem: The machine hangs during the soundcard probe at boot. Reason: No, that's really during the silent SCSI probe, and it's the same problem as above. Problem: NE2000 not detected at boot - no boot messages at all Solution: There is no `magic solution' as there can be a number of reasons why it wasn't detected. The following list should help you walk through the possible problems. 1) Build a new kernel with only the device drivers that you need. Verify that you are indeed booting the fresh kernel. Forgetting to run lilo, etc. can result in booting the old one. (Look closely at the build time/date reported at boot.) Sounds obvious, but we have all done it before. Make sure the driver is in fact included in the new kernel, by checking the System.map file for names like ne_probe. 2) Look at the boot messages carefully. Does it ever even mention doing a ne2k probe such as `NE*000 probe at 0xNNN: not found (blah blah)' or does it just fail silently. There is a big difference. Use dmesg|more to review the boot messages after logging in, or hit Shift- PgUp to scroll the screen up after the boot has completed and the login prompt appears. 3) After booting, do a cat /proc/ioports and verify that the full iospace that the card will require is vacant. If you are at 0x300 then the ne2k driver will ask for 0x300-0x31f. If any other device driver has registered even one port anywhere in that range, the probe will not take place at that address and will silently continue to the next of the probed addresses. A common case is having the lp driver reserve 0x378 or the second IDE channel reserve 0x376 which stops the ne driver from probing 0x360-0x380. 4) Same as above for cat /proc/interrupts. Make sure no other device has registered the interrupt that you set the ethercard for. In this case, the probe will happen, and the ether driver will complain loudly at boot about not being able to get the desired IRQ line. 5) If you are still stumped by the silent failure of the driver, then edit it and add some printk() to the probe. For example, with the ne2k you could add/remove lines (marked with a `+' or `-') in net/ne.c like: ______________________________________________________________________ int reg0 = inb_p(ioaddr); + printk("NE2k probe - now checking %x\n",ioaddr); - if (reg0 == 0xFF) + if (reg0 == 0xFF) { + printk("NE2k probe - got 0xFF (vacant i/o port)\n"); return ENODEV; + } ______________________________________________________________________ Then it will output messages for each port address that it checks, and you will see if your card's address is being probed or not. 6) You can also get the ne2k diagnostic from Don's ftp site (mentioned in the howto as well) and see if it is able to detect your card after you have booted into linux. Use the `-p 0xNNN' option to tell it where to look for the card. (The default is 0x300 and it doesn't go looking elsewhere, unlike the boot-time probe.) The output from when it finds a card will look something like: ______________________________________________________________________ Checking the ethercard at 0x300. Register 0x0d (0x30d) is 00 Passed initial NE2000 probe, value 00. 8390 registers: 0a 00 00 00 63 00 00 00 01 00 30 01 00 00 00 00 SA PROM 0: 00 00 00 00 c0 c0 b0 b0 05 05 65 65 05 05 20 20 SA PROM 0x10: 00 00 07 07 0d 0d 01 01 14 14 02 02 57 57 57 57 NE2000 found at 0x300, using start page 0x40 and end page 0x80. ______________________________________________________________________ Your register values and PROM values will probably be different. Note that all the PROM values are doubled for a 16 bit card, and that the ethernet address (00:00:c0:b0:05:65) appears in the first row, and the double 0x57 signature appears at the end of the PROM. The output from when there is no card installed at 0x300 will look something like this: ______________________________________________________________________ Checking the ethercard at 0x300. Register 0x0d (0x30d) is ff Failed initial NE2000 probe, value ff. 8390 registers: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff SA PROM 0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff SA PROM 0x10: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff Invalid signature found, wordlength 2. ______________________________________________________________________ The 0xff values arise because that is the value that is returned when one reads a vacant i/o port. If you happen to have some other hardware in the region that is probed, you may see some non 0xff values as well. 7) Try warm booting into linux from a DOS boot floppy (via loadlin) after running the supplied DOS driver or config program. It may be doing some extra (i.e. non-standard) "magic" to initialize the card. 8) Try Russ Nelson's ne2000.com packet driver to see if even it can see your card -- if not, then things do not look good. Example: A:> ne2000 0x60 10 0x300 The arguments are software interrupt vector, hardware IRQ, and i/o base. You can get it from any msdos archive in pktdrv11.zip -- The current version may be newer than 11. 3.5. Problems with SMC Ultra/EtherEZ and WD80*3 cards Problem: You get messages such as the following: eth0: bogus packet size: 65531, status=0xff, nxpg=0xff Reason: There is a shared memory problem. Solution: The most common reason for this is PCI machines that are not configured to map in ISA memory devices. Hence you end up reading the PC's RAM (all 0xff values) instead of the RAM on the card that contains the data from the received packet. Other typical problems that are easy to fix are board conflicts, having cache or `shadow ROM' enabled for that region, or running your ISA bus faster than 8Mhz. There are also a surprising number of memory failures on ethernet cards, so run a diagnostic program if you have one for your ethercard. Problem: SMC EtherEZ doesn't work in non-shared memory (PIO) mode. Reason: Older versions of the Ultra driver only supported the card in the shared memory mode of operation. Solution: The driver in kernel version 2.0 and above also supports the programmed i/o mode of operation. Upgrade to v2.0, or get the drop-in replacement for kernel v1.2.13 from Donald's ftp/www site. Problem: Old wd8003 and/or jumper-settable wd8013 always get the IRQ wrong. Reason: The old wd8003 cards and jumper-settable wd8013 clones don't have the EEPROM that the driver can read the IRQ setting from. If the driver can't read the IRQ, then it tries to auto-IRQ to find out what it is. And if auto-IRQ returns zero, then the driver just assigns IRQ 5 for an 8 bit card or IRQ 10 for a 16 bit card. Solution: Avoid the auto-IRQ code, and tell the kernel what the IRQ that you have jumpered the card to is via a boot time argument. For example, if you are using IRQ 9, using the following should work. LILO: linux ether=9,0,eth0 Problem: SMC Ultra card is detected as wd8013, but the IRQ and shared memory base is wrong. Reason: The Ultra card looks a lot like a wd8013, and if the Ultra driver is not present in the kernel, the wd driver may mistake the ultra as a wd8013. The ultra probe comes before the wd probe, so this usually shouldn't happen. The ultra stores the IRQ and mem base in the EEPROM differently than a wd8013, hence the bogus values reported. Solution: Recompile with only the drivers you need in the kernel. If you have a mix of wd and ultra cards in one machine, and are using modules, then load the ultra module first. 3.6. Problems with 3Com cards Problem: The 3c503 picks IRQ N, but this is needed for some other device which needs IRQ N. (eg. CD ROM driver, modem, etc.) Can this be fixed without compiling this into the kernel? Solution: The 3c503 driver probes for a free IRQ line in the order {5, 9/2, 3, 4}, and it should pick a line which isn't being used. The driver chooses when the card is ifconfig'ed into operation. If you are using a modular driver, you can use module parameters to set various things, including the IRQ value. The following selects IRQ9, base location 0x300, , and if_port #1 (the external transceiver). io=0x300 irq=9 xcvr=1 Alternately, if the driver is compiled into the kernel, you can set the same values at boot by passing parameters via LILO. LILO: linux ether=9,0x300,0,1,eth0 The following selects IRQ3, probes for the base location, , and the default if_port #0 (the internal transceiver) LILO: linux ether=3,0,0,0,eth0 Problem: 3c503: configured interrupt X invalid, will use autoIRQ. Reason: The 3c503 card can only use one of IRQ{5, 2/9, 3, 4} (These are the only lines that are connected to the card.) If you pass in an IRQ value that is not in the above set, you will get the above message. Usually, specifying an interrupt value for the 3c503 is not necessary. The 3c503 will autoIRQ when it gets ifconfig'ed, and pick one of IRQ{5, 2/9, 3, 4}. Solution: Use one of the valid IRQs listed above, or enable autoIRQ by not specifying the IRQ line at all. Problem: The supplied 3c503 drivers don't use the AUI (thicknet) port. How does one choose it over the default thinnet port? Solution: The 3c503 AUI port can be selected at boot-time for in- kernel drivers, and at module insertion for modular drivers. The selection is overloaded onto the low bit of the currently-unused dev->rmem_start variable, so a boot-time parameter of: LILO: linux ether=0,0,0,1,eth0 should work for in-kernel drivers. To specify the AUI port when loading as a module, just append xcvr=1 to the module options line along with your i/o and irq values. 3.7. FAQs Not Specific to Any Card. 3.7.1. Ethercard is Not Detected at Boot. The usual reason for this is that people are using a kernel that does not have support for their particular card built in. For a modular kernel, it usually means that the required module has not been requested for loading, or that an I/O address needs to be specified as a module option. If you are using a modular based kernel, such as those installed by most of the linux distributions, then try and use the configuration utility for the distribution to select the module for your card. For ISA cards, it is a good idea to determine the I/O address of the card and add it as an option (e.g. io=0x340) if the configuration utility asks for any options. If there is no configuration utility, then you will have to add the correct module name (and options) to /etc/conf.modules -- see man modprobe for more details. If you are using a pre-compiled kernel that is part of a distribution set, then check the documentation to see which kernel you installed, and if it was built with support for your particular card. If it wasn't, then your options are to try and get one that has support for your card, or build your own. It is usually wise to build your own kernel with only the drivers you need, as this cuts down on the kernel size (saving your precious RAM for applications!) and reduces the number of device probes that can upset sensitive hardware. Building a kernel is not as complicated as it sounds. You just have to answer yes or no to a bunch of questions about what drivers you want, and it does the rest. The next main cause is having another device using part of the i/o space that your card needs. Most cards are 16 or 32 bytes wide in i/o space. If your card is set at 0x300 and 32 bytes wide, then the driver will ask for 0x300-0x31f. If any other device driver has registered even one port anywhere in that range, the probe will not take place at that address and the driver will silently continue to the next of the probed addresses. So, after booting, do a cat /proc/ioports and verify that the full iospace that the card will require is vacant. Another problem is having your card jumpered to an i/o address that isn't probed by default. There is a list ``probed addresses'' for each card in this document. Even if the i/o setting of your card is not in the list of probed addresses, you can supply it at boot (for in-kernel drivers) with the ether= command as described in ``Passing Ethernet Arguments...'' Modular drivers can make use of the io= option to specify an address that isn't probed by default. 3.7.2. ifconfig reports the wrong i/o address for the card. No it doesn't. You are just interpreting it incorrectly. This is not a bug, and the numbers reported are correct. It just happens that some 8390 based cards (wd80x3, smc-ultra, etc) have the actual 8390 chip living at an offset from the first assigned i/o port. This is the value stored in dev->base_addr, and is what ifconfig reports. If you want to see the full range of ports that your card uses, then try cat /proc/ioports which will give the numbers you expect. 3.7.3. PCI machine detects card but driver fails probe. Newer PCI BIOSes may not enable all PCI cards at power-up, especially if the BIOS option `PNP OS' is enabled. This mis-feature is to support the next release of Windows which still uses some real-mode drivers. Either disable this option, or try and upgrade to a newer driver which has the code to enable a disabled card. 3.7.4. Shared Memory ISA cards in PCI Machine dont work (0xffff) This will usually show up as reads of lots of 0xffff values. No shared memory cards of any type will work in a PCI machine unless you have the PCI ROM BIOS/CMOS SETUP configuration set properly. You have to set it to allow shared memory access from the ISA bus for the memory region that your card is trying to use. If you can't figure out which settings are applicable then ask your supplier or local computer guru. For AMI BIOS, there is usually a "Plug and Play" section where there will be an ``ISA Shared Memory Size'' and ``ISA Shared Memory Base'' settings. For cards like the wd8013 and SMC Ultra, change the size from the default of `Disabled' to 16kB, and change the base to the shared memory address of your card. 3.7.5. NexGen machine gets `mismatched read page pointers' errors. A quirk of the NexGen CPU caused all users with 8390 based cards (wd80x3, 3c503, SMC Ultra/EtherEZ, ne2000, etc.) to get these error messages. Kernel versions 2.0 and above do not have these problems. Upgrade your kernel. 3.7.6. Asynchronous Transfer Mode (ATM) Support Werner Almesberger has been working on ATM support for linux. He has been working with the Efficient Networks ENI155p board (Efficient Networks ) and the Zeitnet ZN1221 board (Zeitnet ). Werner says that the driver for the ENI155p is rather stable, while the driver for the ZN1221 is presently unfinished. Check the latest/updated status at the following URL: Linux ATM Support 3.7.7. Gigabyte Ethernet Support Is there any gigabyte ethernet support for Linux? A driver for the Packet Engines G-NIC PCI Gigabit Ethernet adapter is due to be added into the upcoming release of kernel v2.0.34. For more details, support, and driver updates, see: http://cesdis.gsfc.nasa.gov/linux/drivers/yellowfin.html 3.7.8. FDDI Support Is there FDDI support for Linux? Yes. Larry Stefani has written a driver for v2.0 with Digital's DEFEA (FDDI EISA) and DEFPA (FDDI PCI) cards. This was included into the v2.0.24 kernel. Currently no other cards are supported though. 3.7.9. Full Duplex Support Will Full Duplex give me 20MBps? Does Linux support it? Cameron Spitzer writes the following about full duplex 10Base-T cards: ``If you connect it to a full duplex switched hub, and your system is fast enough and not doing much else, it can keep the link busy in both directions. There is no such thing as full duplex 10BASE-2 or 10BASE-5 (thin and thick coax). Full Duplex works by disabling collision detection in the adapter. That's why you can't do it with coax; the LAN won't run that way. 10BASE-T (RJ45 interface) uses separate wires for send and receive, so it's possible to run both ways at the same time. The switching hub takes care of the collision problem. The signalling rate is 10 Mbps.'' So as you can see, you still will only be able to receive or transmit at 10Mbps, and hence don't expect a 2x performance increase. As to whether it is supported or not, that depends on the card and possibly the driver. Some cards may do auto-negotiation, some may need driver support, and some may need the user to select an option in a card's EEPROM configuration. Only the serious/heavy user would notice the difference between the two modes anyway. 3.7.10. Ethernet Cards for Linux on Alpha/AXP PCI Boards As of v2.0, only the 3c509, depca, de4x5 lance32, and all the 8390 drivers (wd, smc-ultra, ne, 3c503, etc.) have been made `architecture independent' so as to work on the DEC Alpha CPU based systems. Other updated PCI drivers from Donald's WWW page may also work as these have been written with architecture independence in mind. Note that the changes that are required to make a driver architecture independent aren't that complicated. You only need to do the following: -multiply all jiffies related values by HZ/100 to account for the different HZ value that the Alpha uses. (i.e timeout=2; becomes timeout=2*HZ/100;) -replace any i/o memory (640k to 1MB) pointer dereferences with the appropriate readb() writeb() readl() writel() calls, as shown in this example. ______________________________________________________________________ - int *mem_base = (int *)dev->mem_start; - mem_base[0] = 0xba5eba5e; + unsigned long mem_base = dev->mem_start; + writel(0xba5eba5e, mem_base); ______________________________________________________________________ -replace all memcpy() calls that have i/o memory as source or target destinations with the appropriate one of memcpy_fromio() or memcpy_toio(). Details on handling memory accesses in an architecture independent fashion are documented in the file linux/Documentation/IO-mapping.txt that comes with recent kernels. 3.7.11. Ethernet for Linux on SUN/Sparc Hardware. For the most up to date information on Sparc stuff, try the following URL: Linux Sparc Note that some Sparc ethernet hardware gets its MAC address from the host computer, and hence you can end up with multiple interfaces all with the same MAC address. If you need to put more than one interface on the same net then use the hw option to ifconfig to assign unique MAC address. Issues regarding porting PCI drivers to the Sparc platform are similar to those mentioned above for the AXP platform. In addition there may be some endian issues, as the Sparc is big endian, and the AXP and ix86 are little endian. 3.7.12. Linking 10BaseT without a Hub Can I link 10BaseT (RJ45) based systems together without a hub? You can link 2 machines easily, but no more than that, without extra devices/gizmos. See ``Twisted Pair'' -- it explains how to do it. And no, you can't hack together a hub just by crossing a few wires and stuff. It's pretty much impossible to do the collision signal right without duplicating a hub. 3.7.13. SIOCSIFxxx: No such device I get a bunch of `SIOCSIFxxx: No such device' messages at boot, followed by a `SIOCADDRT: Network is unreachable' What is wrong? Your ethernet device was not detected at boot/module insertion time, and when ifconfig and route are run, they have no device to work with. Use dmesg | more to review the boot messages and see if there are any messages about detecting an ethernet card. 3.7.14. SIOCSFFLAGS: Try again I get `SIOCSFFLAGS: Try again' when I run `ifconfig' -- Huh? Some other device has taken the IRQ that your ethercard is trying to use, and so the ethercard can't use the IRQ. You don't necessairly need to reboot to resolve this, as some devices only grab the IRQs when they need them and then release them when they are done. Examples are some sound cards, serial ports, floppy disk driver, etc. You can type cat /proc/interrupts to see which interrupts are presently in use. Most of the Linux ethercard drivers only grab the IRQ when they are opened for use via `ifconfig'. If you can get the other device to `let go' of the required IRQ line, then you should be able to `Try again' with ifconfig. 3.7.15. Using `ifconfig' and Link UNSPEC with HW-addr of 00:00:00:00:00:00 When I run ifconfig with no arguments, it reports that LINK is UNSPEC (instead of 10Mbs Ethernet) and it also says that my hardware address is all zeros. This is because people are running a newer version of the `ifconfig' program than their kernel version. This new version of ifconfig is not able to report these properties when used in conjunction with an older kernel. You can either upgrade your kernel, `downgrade' ifconfig, or simply ignore it. The kernel knows your hardware address, so it really doesn't matter if ifconfig can't read it. You may also get strange information if the ifconfig program you are using is a lot older than the kernel you are using. 3.7.16. Huge Number of RX and TX Errors When I run ifconfig with no arguments, it reports that I have a huge error count in both rec'd and transmitted packets. It all seems to work ok -- What is wrong? Look again. It says RX packets big number PAUSE errors 0 PAUSE dropped 0 PAUSE overrun 0. And the same for the TX column. Hence the big numbers you are seeing are the total number of packets that your machine has rec'd and transmitted. If you still find it confusing, try typing cat /proc/net/dev instead. 3.7.17. Entries in /dev/ for Ethercards I have /dev/eth0 as a link to /dev/xxx. Is this right? Contrary to what you have heard, the files in /dev/* are not used. You can delete any /dev/wd0, /dev/ne0 and similar entries. 3.7.18. Linux and ``trailers'' Should I disable trailers when I `ifconfig' my ethercard? You can't disable trailers, and you shouldn't want to. `Trailers' are a hack to avoid data copying in the networking layers. The idea was to use a trivial fixed-size header of size `H', put the variable-size header info at the end of the packet, and allocate all packets `H' bytes before the start of a page. While it was a good idea, it turned out to not work well in practice. If someone suggests the use of `-trailers', note that it is the equivalent of sacrificial goats blood. It won't do anything to solve the problem, but if problem fixes itself then someone can claim deep magical knowledge. 3.7.19. Access to the raw Ethernet Device How do I get access to the raw ethernet device in linux, without going through TCP/IP and friends? ______________________________________________________________________ int s=socket(AF_INET,SOCK_PACKET,htons(ETH_P_ALL)); ______________________________________________________________________ This gives you a socket receiving every protocol type. Do recvfrom() calls to it and it will fill the sockaddr with device type in sa_family and the device name in the sa_data array. I don't know who originally invented SOCK_PACKET for Linux (its been in for ages) but its superb stuff. You can use it to send stuff raw too via sendto() calls. You have to have root access to do either of course. 4. Performance Tips Here are some tips that you can use if you are suffering from low ethernet throughput, or to gain a bit more speed on those ftp transfers. The ttcp.c program is a good test for measuring raw throughput speed. Another common trick is to do a ftp> get large_file /dev/null where large_file is > 1MB and residing in the buffer cache on the Tx'ing machine. (Do the `get' at least twice, as the first time will be priming the buffer cache on the Tx'ing machine.) You want the file in the buffer cache because you are not interested in combining the file access speed from the disk into your measurement. Which is also why you send the incoming data to /dev/null instead of onto the disk. 4.1. General Concepts Even an 8 bit card is able to receive back-to-back packets without any problems. The difficulty arises when the computer doesn't get the Rx'd packets off the card quick enough to make room for more incoming packets. If the computer does not quickly clear the card's memory of the packets already received, the card will have no place to put the new packet. In this case the card either drops the new packet, or writes over top of a previously received packet. Either one seriously interrupts the smooth flow of traffic by causing/requesting re-transmissions and can seriously degrade performance by up to a factor of 5! Cards with more onboard memory are able to ``buffer'' more packets, and thus can handle larger bursts of back-to-back packets without dropping packets. This in turn means that the card does not require as low a latency from the the host computer with respect to pulling the packets out of the buffer to avoid dropping packets. Most 8 bit cards have an 8kB buffer, and most 16 bit cards have a 16kB buffer. Most Linux drivers will reserve 3kB of that buffer (for two Tx buffers), leaving only 5kB of receive space for an 8 bit card. This is room enough for only three full sized (1500 bytes) ethernet packets. 4.2. ISA Bus Speed As mentioned above, if the packets are removed from the card fast enough, then a drop/overrun condition won't occur even when the amount of Rx packet buffer memory is small. The factor that sets the rate at which packets are removed from the card to the computer's memory is the speed of the data path that joins the two -- that being the ISA bus speed. (If the CPU is a dog-slow 386sx-16, then this will also play a role.) The recommended ISA bus clock is about 8MHz, but many motherboards and peripheral devices can be run at higher frequencies. The clock frequency for the ISA bus can usually be set in the CMOS setup, by selecting a divisor of the mainboard/CPU clock frequency. For example, here are some receive speeds as measured by the TTCP program on a 40MHz 486, with an 8 bit WD8003EP card, for different ISA bus speeds. ______________________________________________________________________ ISA Bus Speed (MHz) Rx TTCP (kB/s) ------------------- -------------- 6.7 740 13.4 970 20.0 1030 26.7 1075 ______________________________________________________________________ You would be hard pressed to do better than 1075kB/s with any 10Mb/s ethernet card, using TCP/IP. However, don't expect every system to work at fast ISA bus speeds. Most systems will not function properly at speeds above 13MHz. (Also, some PCI systems have the ISA bus speed fixed at 8MHz, so that the end user does not have the option of increasing it.) In addition to faster transfer speeds, one will usually also benefit from a reduction in CPU usage due to the shorter duration memory and i/o cycles. (Note that hard disks and video cards located on the ISA bus will also usually experience a performance increase from an increased ISA bus speed.) Be sure to back up your data prior to experimenting with ISA bus speeds in excess of 8MHz, and thouroughly test that all ISA peripherals are operating properly after making any speed increases. 4.3. Setting the TCP Rx Window Once again, cards with small amounts of onboard RAM and relatively slow data paths between the card and the computer's memory run into trouble. The default TCP Rx window setting is 32kB, which means that a fast computer on the same subnet as you can dump 32k of data on you without stopping to see if you received any of it okay. Recent versions of the route command have the ability to set the size of this window on the fly. Usually it is only for the local net that this window must be reduced, as computers that are behind a couple of routers or gateways are `buffered' enough to not pose a problem. An example usage would be: ______________________________________________________________________ route add ... window ______________________________________________________________________ where win_size is the size of the window you wish to use (in bytes). An 8 bit 3c503 card on an ISA bus operating at a speed of 8MHz or less would work well with a window size of about 4kB. Too large a window will cause overruns and dropped packets, and a drastic reduction in ethernet throughput. You can check the operating status by doing a cat /proc/net/dev which will display any dropped or overrun conditions that occurred. 4.4. Increasing NFS performance Some people have found that using 8 bit cards in NFS clients causes poorer than expected performance, when using 8kB (native Sun) NFS packet size. The possible reason for this could be due to the difference in on board buffer size between the 8 bit and the 16 bit cards. The maximum ethernet packet size is about 1500 bytes. Now that 8kB NFS packet will arrive as about 6 back to back maximum size ethernet packets. Both the 8 and 16 bit cards have no problem Rx'ing back to back packets. The problem arises when the machine doesn't remove the packets from the cards buffer in time, and the buffer overflows. The fact that 8 bit cards take an extra ISA bus cycle per transfer doesn't help either. What you can do if you have an 8 bit card is either set the NFS transfer size to 2kB (or even 1kB), or try increasing the ISA bus speed in order to get the card's buffer cleared out faster. I have found that an old WD8003E card at 8MHz (with no other system load) can keep up with a large receive at 2kB NFS size, but not at 4kB, where performance was degraded by a factor of three. 5. Vendor/Manufacturer/Model Specific Information The following lists many cards in alphabetical order by vendor name and then product identifier. Beside each product ID, you will see either `Supported', `Semi-Supported' or `Not Supported'. Supported means that a driver for that card exists, and many people are happily using it and it seems quite reliable. Semi-Supported means that a driver exists, but at least one of the following descriptions is true: (1) The driver and/or hardware are buggy, which may cause poor performance, failing connections or even crashes. (2) The driver is new or the card is fairly uncommon, and hence the driver has seen very little use/testing and the driver author has had very little feedback. Obviously (2) is preferable to (1), and the individual description of the card/driver should make it clear which one holds true. In either case, you will probably have to answer `Y' when asked ``Prompt for development and/or incomplete code/drivers?'' when running make config. Not Supported means there is not a driver currently available for that card. This could be due to a lack of interest in hardware that is rare/uncommon, or because the vendors won't release the hardware documentation required to write a driver. Note that the difference between `Supported' and `Semi-Supported' is rather subjective, and is based on user feedback observed in newsgroup postings and mailing list messages. (After all, it is impossible for one person to test all drivers with all cards for each kernel version!!!) So be warned that you may find a card listed as semi- supported works perfectly for you (which is great), or that a card listed as supported gives you no end of troubles and problems (which is not so great). 5.1. 3Com If you are not sure what your card is, but you think it is a 3Com card, you can probably figure it out from the assembly number. 3Com has a document `Identifying 3Com Adapters By Assembly Number' (ref 24500002) that would most likely clear things up. See ``Technical Information from 3Com'' for info on how to get documents from 3Com. Also note that 3Com has a FTP site with various goodies: ftp.3Com.com that you may want to check out. For those of you browsing this document by a WWW browser, you can try 3Com's WWW site as well. 5.1.1. 3c501 Status -- Semi-Supported Too brain-damaged to use. Available surplus from many places. Avoid it like the plague. Again, do not purchase this card, even as a joke. It's performance is horrible, and it breaks in many ways. For those not yet convinced, the 3c501 can only do one thing at a time -- while you are removing one packet from the single-packet buffer it cannot receive another packet, nor can it receive a packet while loading a transmit packet. This was fine for a network between two 8088-based computers where processing each packet and replying took 10's of msecs, but modern networks send back-to-back packets for almost every transaction. AutoIRQ works, DMA isn't used, the autoprobe only looks at 0x280 and 0x300, and the debug level is set with the third boot-time argument. Once again, the use of a 3c501 is strongly discouraged! Even more so with a IP multicast kernel, as you will grind to a halt while listening to all multicast packets. See the comments at the top of the source code for more details. 5.1.2. EtherLink II, 3c503, 3c503/16 Status -- Supported The 3c503 does not have ``EEPROM setup'', so a diagnostic/setup program isn't needed before running the card with Linux. The shared memory address of the 3c503 is set using jumpers that are shared with the boot PROM address. This is confusing to people familiar with other ISA cards, where you always leave the jumper set to ``disable'' unless you have a boot PROM. These cards should be about the same speed as the same bus width WD80x3, but turn out to be actually a bit slower. These shared-memory ethercards also have a programmed I/O mode that doesn't use the 8390 facilities (their engineers found too many bugs!) The Linux 3c503 driver can also work with the 3c503 in programmed-I/O mode, but this is slower and less reliable than shared memory mode. Also, programmed- I/O mode is not as well tested when updating the drivers. You shouldn't use the programmed-I/O mode unless you need it for MS-DOS compatibility. The 3c503's IRQ line is set in software, with no hints from an EEPROM. Unlike the MS-DOS drivers, the Linux driver has capability to autoIRQ: it uses the first available IRQ line in {5,2/9,3,4}, selected each time the card is ifconfig'ed. (Older driver versions selected the IRQ at boot time.) The ioctl() call in `ifconfig' will return EAGAIN if no IRQ line is available at that time. Some common problems that people have with the 503 are discussed in ``Problems with...''. If you intend on using this driver as a loadable module you should probably see ``Using the Ethernet Drivers as Modules'' for module specific information. Note that some old diskless 386 workstations have an on board 3c503 (made by 3Com and sold under different names, like `Bull') but the vendor ID is not a 3Com ID and so it won't be detected. More details can be found in the Etherboot package, which you will need anyways to boot these diskless boxes. 5.1.3. 3c505 Status -- Semi-Supported This is a driver that was written by Craig Southeren geoffw@extro.ucc.su.oz.au. These cards also use the i82586 chip. There are not that many of these cards about. It is included in the standard kernel, but it is classed as an alpha driver. See ``Alpha Drivers'' for important information on using alpha-test ethernet drivers with Linux. There is also the file /usr/src/linux/drivers/net/README.3c505 that you should read if you are going to use one of these cards. It contains various options that you can enable/disable. Technical information is available in ``Programming the Intel chips''. 5.1.4. 3c507 Status -- Semi-Supported This card uses one of the Intel chips, and the development of the driver is closely related to the development of the Intel Ether Express driver. The driver is included in the standard kernel release, but as an alpha driver. See ``Alpha Drivers'' for important information on using alpha-test ethernet drivers with Linux. Technical information is available in ``Programming the Intel chips''. 5.1.5. 3c509 / 3c509B Status -- Supported This card is fairly inexpensive and has good performance for a non- bus-master design. The drawbacks are that the original 3c509 requires very low interrupt latency. The 3c509B shouldn't suffer from the same problem, due to having a larger buffer. (See below.) These cards use PIO transfers, similar to a ne2000 card, and so a shared memory card such as a wd8013 will be more efficient in comparison. The original 3c509 has a small packet buffer (4kB total, 2kB Rx, 2kB Tx), causing the driver to occasionally drop a packet if interrupts are masked for too long. To minimize this problem, you can try unmasking interrupts during IDE disk transfers (see man hdparm) and/or increasing your ISA bus speed so IDE transfers finish sooner. The newer model 3c509B has 8kB on board, and the buffer can be split 4/4, 5/3 or 6/2 for Rx/Tx. This setting is changed with the DOS configuration utility, and is stored on the EEPROM. This should alleviate the above problem with the original 3c509. 3c509B users should use the supplied DOS utility to disable the plug and play support, and to set the output media to what they require. The linux driver currently does not support the Autodetect media setting, so you have to select 10Base-T or 10Base-2 or AUI. With regards to the media detection features, Cameron said: ``Autoselect is a feature of the commercial drivers for 3C509(B). AFAIK nobody ever claimed the Linux driver attempts it. When drivers/net/3c509.c recognizes my 3C509B at boot time, it says: eth0: 3c509 at 0x300 tag 1, 10baseT port, ... revealing that the card is configured for 10BASE-T. It finds that out by reading the little EEPROM, which IMHO is the Right Way To Do It.'' As for the plug-and-pray stuff, Cameron adds: ``It was a marketing decision to turn PnP on as a factory default setting. If it caused you a hassle, or not, please take the time to say so when you mail in your warranty card. The more info they have, the better decisions they can make. Also, check with your motherboard supplier to see if you need a BIOS upgrade.'' Note that to turn off PnP entirely, you should do a 3C5X9CFG /PNP:DISABLE and then follow that with a hard reset to ensure that it takes effect. Some people ask about the ``Server or Workstation'' and ``Highest Modem Speed'' settings presented in the DOS configuration utility. Donald writes ``These are only hints to the drivers, and the Linux driver does not use these parameters: it always optimizes for high throughput rather than low latency (`Server'). Low latency was critically important for old, non-windowed, IPX throughput. To reduce the latency the MS-DOS driver for the 3c509 disables interrupts for some operations, blocking serial port interrupts. Thus the need for the `modem speed' setting. The Linux driver avoids the need to disable interrupts for long periods by operating only on whole packets e.g. by not starting to transmit a packet until it is completely transferred to the card.'' Note that the ISA card detection uses a different method than most cards. Basically, you ask the cards to respond by sending data to an ID_PORT (port 0x100 to 0x1ff on intervals of 0x10). This detection method means that a particular card will always get detected first in a multiple ISA 3c509 configuration. The card with the lowest hardware ethernet address will always end up being eth0. This shouldn't matter to anyone, except for those people who want to assign a 6 byte hardware address to a particular interface. If you have multiple 3c509 cards, it is best to append ether=0,0,ethN commands without the i/o port specified (i.e. use i/o=zero) and allow the probe to sort out which card is first. Using a non-zero i/o value will ensure that it does not detect all your cards, so don't do it. If this really bothers you, have a look at Donald's latest driver, as you may be able to use a 0x3c509 value in the unused mem address fields to order the detection to suit. 5.1.6. 3c515 Status -- Not Supported This is 3Com's farily recent ISA 100Mbps offering, codenamed ``CorkScrew''. Donald is working on support for these cards, and it will probably appear in the near future on his WWW driver page. The driver will be incorporated into the 3c59x/3c90x driver, so you should probably expect to look for it on the Vortex page: Vortex 5.1.7. 3c523 Status -- Semi-Supported This MCA bus card uses the i82586, and Chris Beauregard has modified the ni52 driver to work with these cards. The driver for it can be found in the v2.1 kernel source tree. More details can be found on the MCA-Linux page at http://glycerine.cetmm.uni.edu/mca/ 5.1.8. 3c527 Status -- Not Supported Yes, another MCA card. No, not too much interest in it. Better chances with the 3c529 if you are stuck with MCA. 5.1.9. 3c529 Status -- Semi-Supported This card actually uses the same chipset as the 3c509. Donald actually put hooks into the 3c509 driver to check for MCA cards after probing for EISA cards, and before probing for ISA cards. But it hasn't evolved much further than that. Donald writes: ``I don't have access to a MCA machine (nor do I fully understand the probing code) so I never wrote the mca_adaptor_select_mode() or mca_adaptor_id() routines. If you can find a way to get the adaptor I/O address that assigned at boot time, you can just hard-wire that in place of the commented-out probe. Be sure to keep the code that reads the IRQ, if_port, and ethernet address.'' Darrell Frappier (aa822@detroit.freenet.org) reports that you can get the i/o address from running the PS/2 reference diskette, and once you put that directly into the driver, it does actually work. The required MCA probe code will probably appear in the driver in a development kernel sometime soon, now that MCA support is in the kernel. More details can be found on the MCA-Linux page at http://glycerine.cetmm.uni.edu/mca/ 5.1.10. 3c562 Status -- Supported This PCMCIA card is the combination of a 3c589B ethernet card with a modem. The modem appears as a standard modem to the end user. The only difficulty is getting the two separate linux drivers to share one interrupt. There are a couple of new registers and some hardware interrupt sharing support. You need to use a v2.0 or newer kernel that has the support for interrupt sharing. As a side note, the modem part of the card has been reported to be not well documented for the end user (the manual just says `supports the AT command set') and it may not connect as well as other name brand modems. The recommendation is to buy a 3c589B instead, and then get a PCMCIA modem card from a company that specializes in modems. Thanks again to Cameron for getting a sample unit and documentation sent off to David Hinds. Look for support in David's PCMCIA package release. See ``PCMCIA Support'' for more info on PCMCIA chipsets, socket enablers, etc. 5.1.11. 3c575 Status -- Not Supported A driver for this PCMCIA card is under development and hopefully will be included in David's PCMCIA package within a few months. 5.1.12. 3c579 Status -- Supported The EISA version of the 509. The current EISA version uses the same 16 bit wide chip rather than a 32 bit interface, so the performance increase isn't stunning. Make sure the card is configured for EISA addressing mode. Read the above 3c509 section for info on the driver. 5.1.13. 3c589 / 3c589B Status -- Semi-Supported Many people have been using this PCMCIA card for quite some time now. Note that support for it is not (at present) included in the default kernel source tree. You will also need a supported PCMCIA controller chipset. There are drivers available on Donald's ftp site: cesdis.gsfc.nasa.gov:/pub/linux/pcmcia/README.3c589 cesdis.gsfc.nasa.gov:/pub/linux/pcmcia/3c589.c cesdis.gsfc.nasa.gov:/pub/linux/pcmcia/dbether.c Or for those that are net-surfing you can try: Don's PCMCIA Stuff You will still need a PCMCIA socket enabler as well. See ``PCMCIA Support'' for more info on PCMCIA chipsets, socket enablers, etc. The "B" in the name means the same here as it does for the 3c509 case. 5.1.14. 3c590 / 3c595 Status -- Supported These ``Vortex'' cards are for PCI bus machines, with the '590 being 10Mbps and the '595 being 3Com's 100Mbs offering. Also note that you can run the '595 as a '590 (i.e. in a 10Mbps mode). The driver is included in the v2.0 kernel source, but is also continually being updated. If you have problems with the driver in the v2.0 kernel, you can get an updated driver from the following URL: Vortex Note that there are two different 3c590 cards out there, early models that had 32kB of on-board memory, and later models that only have 8kB of memory. Chances are you won't be able to buy a new 3c59x for much longer, as it is being replaced with the 3c90x card. If you are buying a used one off somebody, try and get the 32kB version. The 3c595 cards have 64kB, as you can't get away with only 8kB RAM at 100Mbps! A thanks to Cameron Spitzer and Terry Murphy of 3Com for sending cards and documentation to Donald so he could write the driver. Donald has set up a mailing list for Vortex driver support. To join the list, just do: echo subscribe | /bin/mail linux-vortex-request@cesdis.gsfc.nasa.gov 5.1.15. 3c592 / 3c597 Status -- Supported These are the EISA versions of the 3c59x series of cards. The 3c592/3c597 (aka Demon) should work with the vortex driver discussed above. 5.1.16. 3c900 / 3c905 / 3c905B Status -- Supported These cards (aka `Boomerang', aka EtherLink III XL) have been released to take over the place of the 3c590/3c595 cards. The support for the Cyclone `B' revision was only recently added. To use this card with older v2.0 kernels, you must obtain the updated 3c59x.c driver from Donald's site at: Vortex-Page If in doubt about anything then check out the above WWW page. Donald has set up a mailing list for Vortex driver support announcements and etc. To join the list, just do: echo subscribe | /bin/mail linux-vortex-request@cesdis.gsfc.nasa.gov 5.2. Accton 5.2.1. Accton MPX Status -- Supported Don't let the name fool you. This is still supposed to be a NE2000 compatible card, and should work with the ne2000 driver. 5.2.2. Accton EN1203, EN1207, EtherDuo-PCI Status -- Supported This is another implementation of the DEC 21040 PCI chip. The EN1207 card has the 21140, and also has a 10Base-2 connector, which has proved troublesome for some people in terms of selecting that media. Using the card with 10Base-T and 100Base-T media have worked for others though. So as with all purchases, you should try and make sure you can return it if it doesn't work for you. See ``DEC 21040'' for more information on these cards, and the present driver situation. 5.2.3. Accton EN2209 Parallel Port Adaptor (EtherPocket) Status -- Semi-Supported A driver for these parallel port adapters is available but not yet part of the 2.0 or 2.1 kernel source. You have to get the driver from: http://www.unix-ag.uni-siegen.de/~nils/accton_linux.html 5.2.4. Accton EN2212 PCMCIA Card Status -- Semi-Supported David Hinds has been working on a driver for this card, and you are best to check the latest release of his PCMCIA package to see what the present status is. 5.3. Allied Telesyn/Telesis 5.3.1. AT1500 Status --Supported These are a series of low-cost ethercards using the 79C960 version of the AMD LANCE. These are bus-master cards, and hence one of the faster ISA bus ethercards available. DMA selection and chip numbering information can be found in ``AMD LANCE''. More technical information on AMD LANCE based Ethernet cards can be found in ``Notes on AMD...''. 5.3.2. AT1700 Status -- Supported Note that to access this driver during make config you still have to answer `Y' when asked ``Prompt for development and/or incomplete code/drivers?'' at the first. This is simply due to lack of feedback on the driver stability due to it being a relatively rare card. This will probably be changed for v2.1 kernels. The Allied Telesis AT1700 series ethercards are based on the Fujitsu MB86965. This chip uses a programmed I/O interface, and a pair of fixed-size transmit buffers. This allows small groups of packets to be sent back-to-back, with a short pause while switching buffers. A unique feature is the ability to drive 150ohm STP (Shielded Twisted Pair) cable commonly installed for Token Ring, in addition to 10baseT 100ohm UTP (unshielded twisted pair). A fibre optic version of the card (AT1700FT) exists as well. The Fujitsu chip used on the AT1700 has a design flaw: it can only be fully reset by doing a power cycle of the machine. Pressing the reset button doesn't reset the bus interface. This wouldn't be so bad, except that it can only be reliably detected when it has been freshly reset. The solution/work-around is to power-cycle the machine if the kernel has a problem detecting the AT1700. Some production runs of the AT1700 had another problem: they are permanently wired to DMA channel 5. This is undocumented, there are no jumpers to disable the "feature", and no driver dares use the DMA capability because of compatibility problems. No device driver will be written using DMA if installing a second card into the machine breaks both, and the only way to disable the DMA is with a knife. 5.3.3. AT2450 Status -- Supported This is the PCI version of the AT1500, and it doesn't suffer from the problems that the Boca 79c970 PCI card does. DMA selection and chip numbering information can be found in ``AMD LANCE''. More technical information on AMD LANCE based Ethernet cards can be found in ``Notes on AMD...''. 5.3.4. AT2540FX Status -- Semi-Supported This card uses the i82557 chip, and hence may/should work with the eepro100 driver. If you try this please send in a report so this information can be updated. 5.4. AMD / Advanced Micro Devices Carl Ching of AMD was kind enough to provide a very detailed description of all the relevant AMD ethernet products which helped clear up this section. 5.4.1. AMD LANCE (7990, 79C960/961/961A, PCnet-ISA) Status -- Supported There really is no AMD ethernet card. You are probably reading this because the only markings you could find on your card said AMD and the above number. The 7990 is the original `LANCE' chip, but most stuff (including this document) refer to all these similar chips as `LANCE' chips. (...incorrectly, I might add.) These above numbers refer to chips from AMD that are the heart of many ethernet cards. For example, the Allied Telesis AT1500 (see ``AT1500'') and the NE1500/2100 (see ``NE1500'') use these chips. The 7990/79c90 have long been replaced by newer versions. The 79C960 (a.k.a. PCnet-ISA) essentially contains the 79c90 core, along with all the other hardware support required, which allows a single-chip ethernet solution. The 79c961 (PCnet-ISA+) is a jumperless Plug and Play version of the '960. The final chip in the ISA series is the 79c961A (PCnet-ISA II), which adds full duplex capabilities. All cards with one of these chips should work with the lance.c driver, with the exception of very old cards that used the original 7990 in a shared memory configuration. These old cards can be spotted by the lack of jumpers for a DMA channel. One common problem people have is the `busmaster arbitration failure' message. This is printed out when the LANCE driver can't get access to the bus after a reasonable amount of time has elapsed (50us). This usually indicates that the motherboard implementation of bus-mastering DMA is broken, or some other device is hogging the bus, or there is a DMA channel conflict. If your BIOS setup has the `GAT option' (for Guaranteed Access Time) then try toggling/altering that setting to see if it helps. Also note that the driver only looks at the addresses: 0x300, 0x320, 0x340, 0x360 for a valid card, and any address supplied by an ether= boot argument is silently ignored (this will be fixed) so make sure your card is configured for one of the above I/O addresses for now. The driver will still work fine, even if more than 16MB of memory is installed, since low-memory `bounce-buffers' are used when needed (i.e. any data from above 16MB is copied into a buffer below 16MB before being given to the card to transmit.) The DMA channel can be set with the low bits of the otherwise-unused dev->mem_start value (a.k.a. PARAM_1). (see ``PARAM_1'') If unset it is probed for by enabling each free DMA channel in turn and checking if initialization succeeds. The HP-J2405A board is an exception: with this board it's easy to read the EEPROM-set values for the IRQ, and DMA. See ``Notes on AMD...'' for more info on these chips. 5.4.2. AMD 79C965 (PCnet-32) Status -- Supported This is the PCnet-32 -- a 32 bit bus-master version of the original LANCE chip for VL-bus and local bus systems. chip. While these chips can be operated with the standard lance.c driver, a 32 bit version (lance32.c) is also available that does not have to concern itself with any 16MB limitations associated with the ISA bus. 5.4.3. AMD 79C970/970A (PCnet-PCI) Status -- Supported This is the PCnet-PCI -- similar to the PCnet-32, but designed for PCI bus based systems. Please see the above PCnet-32 information. This means that you need to build a kernel with PCI BIOS support enabled. The '970A adds full duplex support along with some other features to the original '970 design. Note that the Boca implementation of the 79C970 fails on fast Pentium machines. This is a hardware problem, as it affects DOS users as well. See the Boca section for more details. 5.4.4. AMD 79C971 (PCnet-FAST) Status -- Supported This is AMD's 100Mbit chip for PCI systems, which also supports full duplex operation. It was introduced in June 1996. 5.4.5. AMD 79C974 (PCnet-SCSI) Status -- Supported This is the PCnet-SCSI -- which is basically treated like a '970 from an Ethernet point of view. Also see the above information. Don't ask if the SCSI half of the chip is supported -- this is the Ethernet- HowTo, not the SCSI-HowTo. 5.5. Ansel Communications 5.5.1. AC3200 EISA Status -- Semi-Supported Note that to access this driver during make config you still have to answer `Y' when asked ``Prompt for development and/or incomplete code/drivers?'' at the first. This is simply due to lack of feedback on the driver stability due to it being a relatively rare card. This driver is included in the present kernel as an alpha test driver. It is based on the common NS8390 chip used in the ne2000 and wd80x3 cards. Please see ``Alpha Drivers'' in this document for important information regarding alpha drivers. If you use it, let one of us know how things work out, as feedback has been low, even though the driver has been in the kernel since v1.1.25. If you intend on using this driver as a loadable module you should probably see ``Using the Ethernet Drivers as Modules'' for module specific information. 5.6. Apricot 5.6.1. Apricot Xen-II On Board Ethernet Status -- Supported This on board ethernet uses an i82596 bus-master chip. It can only be at i/o address 0x300. The author of this driver is Mark Evans. By looking at the driver source, it appears that the IRQ is hardwired to 10. Earlier versions of the driver had a tendency to think that anything living at 0x300 was an apricot NIC. Since then the hardware address is checked to avoid these false detections. 5.7. Arcnet Status -- Supported With the very low cost and better performance of ethernet, chances are that most places will be giving away their Arcnet hardware for free, resulting in a lot of home systems with Arcnet. An advantage of Arcnet is that all of the cards have identical interfaces, so one driver will work for everyone. It also has built in error handling so that it supposedly never loses a packet. (Great for UDP traffic!) Avery Pennarun's arcnet driver has been in the default kernel sources since 1.1.80. The arcnet driver uses `arc0' as its name instead of the usual `eth0' for ethernet devices. Bug reports and success stories can be mailed to: apenwarr@foxnet.net There are information files contained in the standard kernel for setting jumpers and general hints. Supposedly the driver also works with the 100Mbs ARCnet cards as well! 5.8. AT&T Note that AT&T's StarLAN is an orphaned technology, like SynOptics LattisNet, and can't be used in a standard 10Base-T environment, without a hub that `speaks' both. 5.8.1. AT&T T7231 (LanPACER+) Status -- Not Supported These StarLAN cards use an interface similar to the i82586 chip. At one point, Matthijs Melchior (matthijs.n.melchior@att.com) was playing with the 3c507 driver, and almost had something useable working. Haven't heard much since that. 5.9. AT-Lan-Tec / RealTek 5.9.1. AT-Lan-Tec / RealTek Pocket adaptor Status -- Supported This is a generic, low-cost OEM pocket adaptor being sold by AT-Lan- Tec, and (likely) a number of other suppliers. A driver for it is included in the standard kernel. Note that there is substantial information contained in the driver source file `atp.c'. Note that the device name that you pass to ifconfig is not eth0 but atp0 for this device. 5.9.2. RealTek 8009 Status -- Supported This is an ISA NE2000 clone, and is reported to work fine with the linux NE2000 driver. The rset8009.exe program can be obtained from RealTek's WWW site at http://www.realtek.com.tw - or via ftp from the same site. 5.9.3. RealTek 8019 Status -- Supported This is a Plug and Pray version of the above. Use the DOS software to disable PnP and enable jumperless configuration; set the card to a sensible i/o address and IRQ and you should be ready to go. (If using the driver as a module, don't forget to add an io=0xNNN option to /etc/conf.modules). The rset8019.exe program can be obtained from RealTek's WWW site at http://www.realtek.com.tw - or via ftp from the same site. 5.9.4. RealTek 8029 Status -- Supported This is a PCI single chip implementation of a NE2000 clone. Various vendors are now selling cards with this chip. See ``NE2000-PCI'' for information on using any of these cards. 5.9.5. RealTek 8129/8139 Status -- Semi-Supported Another PCI single chip ethernet solution from RealTek. A driver for cards based upon this chip is due to be included in the v2.0.34 release of linux. For more information, see: http://cesdis.gsfc.nasa.gov/linux/drivers/rtl8139.html 5.10. Boca Research Yes, they make more than just multi-port serial cards. :-) 5.10.1. Boca BEN (ISA, VLB, PCI) Status -- Supported These cards are based on AMD's PCnet chips. Perspective buyers should be warned that many users have had endless problems with these VLB/PCI cards. Owners of fast Pentium systems have been especially hit. Note that this is not a driver problem, as it hits DOS/Win/NT users as well. Boca's technical support number is (407) 241-8088, and you can also reach them at 75300.2672@compuserve.com. The older ISA cards don't appear to suffer the same problems. Donald did a comparitive test with a Boca PCI card and a similar Allied Telsyn PCnet/PCI implementation, which showed that the problem lies in Boca's implementation of the PCnet/PCI chip. These test results can be accessed on Don's www server. Linux at CESDIS Boca is offering a `warranty repair' for affected owners, which involves adding one of the missing capacitors, but it appears that this fix doesn't work 100 percent for most people, although it helps some. If you are still thinking of buying one of these cards, then at least try and get a 7 day unconditional return policy, so that if it doesn't work properly in your system, you can return it. More general information on the AMD chips can be found in ``AMD LANCE''. More technical information on AMD LANCE based Ethernet cards can be found in ``Notes on AMD...''. 5.11. Cabletron Donald writes: `Yes, another one of these companies that won't release its programming information. They waited for months before actually confirming that all their information was proprietary, deliberately wasting my time. Avoid their cards like the plague if you can. Also note that some people have phoned Cabletron, and have been told things like `a D. Becker is working on a driver for linux' -- making it sound like I work for them. This is NOT the case.' Apparently Cabletron has changed their policy with respect to programming information (like Xircom) since Donald made the above comment several years ago -- send e-mail to support@ctron.com if you want to verify this or ask for programming information. However, at this point in time, there is little demand for modified/updated drivers for the older E20xx and E21xx cards. 5.11.1. E10**, E10**-x, E20**, E20**-x Status -- Semi-Supported These are NEx000 almost-clones that are reported to work with the standard NEx000 drivers, thanks to a ctron-specific check during the probe. If there are any problems, they are unlikely to be fixed, as the programming information is unavailable. 5.11.2. E2100 Status -- Semi-Supported Again, there is not much one can do when the programming information is proprietary. The E2100 is a poor design. Whenever it maps its shared memory in during a packet transfer, it maps it into the whole 128K region! That means you can't safely use another interrupt-driven shared memory device in that region, including another E2100. It will work most of the time, but every once in a while it will bite you. (Yes, this problem can be avoided by turning off interrupts while transferring packets, but that will almost certainly lose clock ticks.) Also, if you mis-program the board, or halt the machine at just the wrong moment, even the reset button won't bring it back. You will have to turn it off and leave it off for about 30 seconds. Media selection is automatic, but you can override this with the low bits of the dev->mem_end parameter. See ``PARAM_2''. Module users can specify an xcvr=N value as an option in the /etc/conf.modules file. Also, don't confuse the E2100 for a NE2100 clone. The E2100 is a shared memory NatSemi DP8390 design, roughly similar to a brain- damaged WD8013, whereas the NE2100 (and NE1500) use a bus-mastering AMD LANCE design. There is an E2100 driver included in the standard kernel. However, seeing as programming info isn't available, don't expect bug-fixes. Don't use one unless you are already stuck with the card. If you intend on using this driver as a loadable module you should probably see ``Using the Ethernet Drivers as Modules'' for module specific information. 5.11.3. E22** Status -- Semi-Supported According to information in a Cabletron Tech Bulletin, these cards use the standard AMD PC-Net chipset (see ``AMD PC-Net'') and should work with the generic lance driver. 5.12. Cogent Here is where and how to reach them: Cogent Data Technologies, Inc. 175 West Street, P.O. Box 926 Friday Harbour, WA 98250, USA. Cogent Sales 15375 S.E. 30th Place, Suite 310 Bellevue, WA 98007, USA. Technical Support: Phone (360) 378-2929 between 8am and 5pm PST Fax (360) 378-2882 Compuserve GO COGENT Bulletin Board Service (360) 378-5405 Internet: support@cogentdata.com 5.12.1. EM100-ISA/EISA Status -- Semi-Supported These cards use the SMC 91c100 chip and may work with the SMC 91c92 driver, but this has yet to be verified. 5.12.2. Cogent eMASTER+, EM100-PCI, EM400, EM960, EM964 Status -- Supported These are yet another DEC 21040 implementation that should hopefully work fine with the standard 21040 driver. The EM400 and the EM964 are four port cards using a DEC 21050 bridge and 4 21040 chips. See ``DEC 21040'' for more information on these cards, and the present driver situation. 5.13. Compaq Compaq aren't really in the business of making ethernet cards, but a lot of their systems have embedded ethernet controllers on the motherboard. 5.13.1. Compaq Deskpro / Compaq XL (Embedded AMD Chip) Status -- Supported Machines such as the XL series have an AMD 79c97x PCI chip on the mainboard that can be used with the standard LANCE driver. But before you can use it, you have to do some trickery to get the PCI BIOS to a place where Linux can see it. Frank Maas was kind enough to provide the details: `` The problem with this Compaq machine however is that the PCI directory is loaded in high memory, at a spot where the Linux kernel can't (won't) reach. Result: the card is never detected nor is it usable (sideline: the mouse won't work either) The workaround (as described thoroughly in http://www-c724.uibk.ac.at/XL/) is to load MS- DOS, launch a little driver Compaq wrote and then load the Linux kernel using LOADLIN. Ok, I'll give you time to say `yuck, yuck', but for now this is the only working solution I know of. The little driver simply moves the PCI directory to a place where it is normally stored (and where Linux can find it).'' More general information on the AMD chips can be found in ``AMD LANCE''. 5.14. Danpex 5.14.1. Danpex EN9400 Status -- Supported Yet another card based on the DEC 21040 chip, reported to work fine, and at a relatively cheap price. See ``DEC 21040'' for more information on these cards, and the present driver situation. 5.15. D-Link 5.15.1. DE-100, DE-200, DE-220-T, DE-250 Status -- Supported Some of the early D-Link cards didn't have the 0x57 PROM signature, but the ne2000 driver knows about them. For the software configurable cards, you can get the config program from www.dlink.com. The DE2** cards were the most widely reported as having the spurious transfer address mismatch errors with early versions of linux. Note that there are also cards from Digital (DEC) that are also named DE100 and DE200, but the similarity stops there. 5.15.2. DE-520 Status -- Supported This is a PCI card using the PCI version of AMD's LANCE chip. DMA selection and chip numbering information can be found in ``AMD LANCE''. More technical information on AMD LANCE based Ethernet cards can be found in ``Notes on AMD...''. 5.15.3. DE-530 Status -- Supported This is a generic DEC 21040 PCI chip implementation, and is reported to work with the generic 21040 tulip driver. See ``DEC 21040'' for more information on these cards, and the present driver situation. 5.15.4. DE-600 Status -- Supported Laptop users and other folk who might want a quick way to put their computer onto the ethernet may want to use this. The driver is included with the default kernel source tree. Bjorn Ekwall bj0rn@blox.se wrote the driver. Expect about 180kb/s transfer speed from this via the parallel port. You should read the README.DLINK file in the kernel source tree. Note that the device name that you pass to ifconfig is now eth0 and not the previously used dl0. If your parallel port is not at the standard 0x378 then you will have to recompile. Bjorn writes: ``Since the DE-620 driver tries to sqeeze the last microsecond from the loops, I made the irq and port address constants instead of variables. This makes for a usable speed, but it also means that you can't change these assignements from e.g. lilo; you _have_ to recompile...'' Also note that some laptops implement the on-board parallel port at 0x3bc which is where the parallel ports on monochrome cards were/are. 5.15.5. DE-620 Status -- Supported Same as the DE-600, only with two output formats. Bjorn has written a driver for this model, for kernel versions 1.1 and above. See the above information on the DE-600. 5.15.6. DE-650 Status -- Semi-Supported Some people have been using this PCMCIA card for some time now with their notebooks. It is a basic 8390 design, much like a NE2000. The LinkSys PCMCIA card and the IC-Card Ethernet (available from Midwest Micro) are supposedly DE-650 clones as well. Note that at present, this driver is not part of the standard kernel, and so you will have to do some patching. See ``PCMCIA Support'' in this document, and if you can, have a look at: Don's PCMCIA Stuff 5.16. DFI 5.16.1. DFINET-300 and DFINET-400 Status -- Supported These cards are now detected (as of 0.99pl15) thanks to Eberhard Moenkeberg emoenke@gwdg.de who noted that they use `DFI' in the first 3 bytes of the prom, instead of using 0x57 in bytes 14 and 15, which is what all the NE1000 and NE2000 cards use. (The 300 is an 8 bit pseudo NE1000 clone, and the 400 is a pseudo NE2000 clone.) 5.17. Digital / DEC 5.17.1. DEPCA, DE100/1, DE200/1/2, DE210, DE422 Status -- Supported As of linux v1.0, there is a driver included as standard for these cards. It was written by David C. Davies. There is documentation included in the source file `depca.c', which includes info on how to use more than one of these cards in a machine. Note that the DE422 is an EISA card. These cards are all based on the AMD LANCE chip. See ``AMD LANCE'' for more info. A maximum of two of the ISA cards can be used, because they can only be set for 0x300 and 0x200 base I/O address. If you are intending to do this, please read the notes in the driver source file depca.c in the standard kernel source tree. This driver will also work on Alpha CPU based machines, and there are various ioctl()s that the user can play with. 5.17.2. Digital EtherWorks 3 (DE203, DE204, DE205) Status -- Supported Included into kernels v1.1.62 and above is this driver, also by David C. Davies of DEC. These cards use a proprietary chip from DEC, as opposed to the LANCE chip used in the earlier cards like the DE200. These cards support both shared memory or programmed I/O, although you take about a 50%performance hit if you use PIO mode. The shared memory size can be set to 2kB, 32kB or 64kB, but only 2 and 32 have been tested with this driver. David says that the performance is virtually identical between the 2kB and 32kB mode. There is more information (including using the driver as a loadable module) at the top of the driver file ewrk3.c and also in README.ewrk3. Both of these files come with the standard kernel distribution. This driver has Alpha CPU support like depca.c does. The standard driver has a number of interesting ioctl() calls that can be used to get or clear packet statistics, read/write the EEPROM, change the hardware address, and the like. Hackers can see the source code for more info on that one. David has also written a configuration utility for this card (along the lines of the DOS program NICSETUP.EXE) along with other tools. These can be found on sunsite.unc.edu in the directory /pub/Linux/system/Network/management -- look for the file ewrk3tools- X.XX.tar.gz. 5.17.3. DE425 (EISA), DE434, DE435, DE500 Status -- Supported These cards are based on the 21040 chip mentioned below. Included into kernels v1.1.86 and above is this driver, also by David C. Davies of DEC. It sure is nice to have support from someone on the inside ;-) The DE500 uses the newer 21140 chip to provide 10/100Mbs ethernet connections. Have a read of the 21040 section below for extra info. Note that as of 1.1.91, David has added a compile time option that will allow non-DEC cards to work with this driver. Have a look at README.de4x5 for details. All the Digital cards will autoprobe for their media (except, temporarily, the DE500 due to a patent issue). This driver is also ALPHA CPU ready and supports being loaded as a module. Users can access the driver internals through ioctl() calls - see the 'ewrk3' tools and the de4x5.c sources for information about how to do this. 5.17.4. DEC 21040, 21041, 2114x, Tulip Status -- Supported The DEC 21040 is a bus-mastering single chip ethernet solution from Digital, similar to AMD's PCnet chip. The 21040 is specifically designed for the PCI bus architecture. SMC's new EtherPower PCI card uses this chip. You have a choice of two drivers for cards based on this chip. There is the DE425 driver discussed above, and the generic 21040 driver that Donald has written. Warning: Even though your card may be based upon this chip, the drivers may not work for you. David C. Davies writes: ``There are no guarantees that either `tulip.c' OR `de4x5.c' will run any DC2114x based card other than those they've been written to support. WHY?? You ask. Because there is a register, the General Purpose Register (CSR12) that (1) in the DC21140A is programmable by each vendor and they all do it differently (2) in the DC21142/3 this is now an SIA control register (a la DC21041). The only small ray of hope is that we can decode the SROM to help set up the driver. However, this is not a guaranteed solution since some vendors (e.g. SMC 9332 card) don't follow the Digital Semiconductor recommended SROM programming format." In non-technical terms, this means that if you aren't sure that an unknown card with a DC2114x chip will work with the linux driver(s), then make sure you can return the card to the place of purchase before you pay for it. The updated 21041 chip is also found in place of the 21040 on most of the later SMC EtherPower cards. The 21140 is for supporting 100Base-? and works with the Linux drivers for the 21040 chip. To use David's de4x5 driver with non-DEC cards, have a look at README.de4x5 for details. Donald has used SMC EtherPower-10/100 cards to develop the `tulip' driver. Note that the driver that is in the standard kernel tree at the moment is not the most up to date version. If you are having trouble with this driver, you should get the newest version from Donald's ftp/WWW site. Tulip Driver The above URL also contains a (non-exhaustive) list of various cards/vendors that use the 21040 chip. Also note that the tulip driver is still considered an alpha driver (see ``Alpha Drivers'') at the moment, and should be treated as such. To use it, you will have to edit arch/i386/config.in and uncomment the line for CONFIG_DEC_ELCP support. Donald has even set up a mailing list for tulip driver support announcements, etc. To join it just type: echo subscribe | /bin/mail linux-tulip-request@cesdis.gsfc.nasa.gov 5.18. Farallon Farallon sells EtherWave adaptors and transceivers. This device allows multiple 10baseT devices to be daisy-chained. 5.18.1. Farallon Etherwave Status -- Supported This is reported to be a 3c509 clone that includes the EtherWave transceiver. People have used these successfully with Linux and the present 3c509 driver. They are too expensive for general use, but are a great option for special cases. Hublet prices start at $125, and Etherwave adds $75-$100 to the price of the board -- worth it if you have pulled one wire too few, but not if you are two network drops short. 5.19. Hewlett Packard The 272** cards use programmed I/O, similar to the NE*000 boards, but the data transfer port can be `turned off' when you aren't accessing it, avoiding problems with autoprobing drivers. Thanks to Glenn Talbott for helping clean up the confusion in this section regarding the version numbers of the HP hardware. 5.19.1. 27245A Status -- Supported 8 Bit 8390 based 10BaseT, not recommend