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longer uses these interrupt vectors for its ISA interrupt pins, so these entries will not be overwritten. If we get a spurious interrupt from the ATPIC when using the APIC, it will be treated as a stray interrupt instead of causing a panic. |
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ccbque.h | ||
clock.c | ||
cronyx.c | ||
ctx.c | ||
ctxreg.h | ||
cx.c | ||
cxreg.h | ||
cy.c | ||
cyreg.h | ||
elink.c | ||
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gpib.c | ||
gpib.h | ||
gpibreg.h | ||
gsc.c | ||
gscreg.h | ||
icu.h | ||
if_cx.c | ||
if_el.c | ||
if_elreg.h | ||
if_le.c | ||
if_rdp.c | ||
if_rdpreg.h | ||
isa_compat.c | ||
isa_device.h | ||
isa_dma.c | ||
isa_dma.h | ||
isa.c | ||
isa.h | ||
istallion.c | ||
loran.c | ||
lptreg.h | ||
mse.c | ||
nmi.c | ||
npx.c | ||
pcf.c | ||
pmtimer.c | ||
prof_machdep.c | ||
README.le | ||
README.stl | ||
spic.c | ||
spicreg.h | ||
spigot.c | ||
spkr.c | ||
stallion.c | ||
timerreg.h | ||
vesa.c | ||
wt.c | ||
wtreg.h |
$FreeBSD$ Stallion Multiport Serial Driver Readme --------------------------------------- Version: 0.0.5 alpha Date: 20MAR96 Author: Greg Ungerer (gerg@stallion.oz.au) 1. INTRODUCTION This is a FreeBSD driver for some of the Stallion Technologies range of multiport serial boards. This driver is still very new, so it should be considered to be of very alpha quality. This driver has not been developed by Stallion Technologies. I developed it in my spare time in the hope that it would be useful. As such there is no warranty or support of any form. What this means is that this driver is not officially supported by Stallion Technologies, so don't ring their support if you can't get it working. They will probably not be able to help you. Instead email me if you have problems or bug reports and I will do what I can... (Sorry to sound so heavy handed, but I need to stress that this driver is not officially supported in any way.) This package actually contains two drivers. One is for the true Stallion intelligent multiport boards, and the other is for the smart range of boards. All host driver source is included in this package, and is copyrighted under a BSD style copyright. The board "firmware" code in this package is copyright Stallion Technologies (the files cdk.sys and 2681.sys). 1.1 SMART MULTIPORT BOARD DRIVER This driver supports the EasyIO and EasyConnection 8/32 range of boards. These boards are not classic intelligent multiport boards, but are host based multiport boards that use high performance Cirrus Logic CL-CD1400 RISC UART's (they have built in FIFO's, automatic flow control and some other good stuff). The EasyIO range of cards comes in 3 forms, the EasyIO-4, EasyIO-8 and the EasyIO-8M. All of these are non-expandable, low cost, ISA, multiport boards with 4, 8 and 8 RS-232C ports respectively. Each EasyIO board requires 8 bytes of I/O address space and 1 interrupt. On an EISA system it is possible to share 1 interrupt between multiple boards. The EasyIO-4 has 10 pin RJ connectors, and the EasyIO-8 comes with a dongle cable with either 10 pin RJ connectors or DB-25 connectors. The EasyIO-8M has 6 pin RJ connectors. The EasyConnection 8/32 family of boards is a relatively low cost modular range of multiport serial boards. The EasyConnection 8/32 boards can be configured to have from 8 to 32 serial ports by plugging in external serial port modules that contain either 8 or 16 ports each. There is a wide range of external modules available that offer: DB-25 connectors, RJ-45 connectors (both with RS-232 D and E compatible drivers), and also RS-422 and RS-485 ports. The EasyConnection 8/32 boards come in ISA, PCI and MCA bus versions. The board takes the form of a host adapter card, with an external connector cable that plugs into the external modules. The external modules just clip together to add ports (BTW, they are NOT hot pluggable). Each ISA EasyConnection 8/32 board requires two separate I/O address ranges, one two bytes in size and a secondary region of 32 bytes. Each PCI EasyConnection 8/32 requires two regions of I/O address space, normally these will be automatically allocated by the system BIOS at system power on time. Each MCA EasyConnection board requires one I/O address region 64 bytes in size. All board types also require one interrupt. On EISA systems multiple boards can share one interrupt. The secondary I/O range of the ISA board (the 32 byte range) can be shared between multiple boards on any bus type. 1.2 INTELLIGENT MULTIPORT BOARD DRIVER This driver is for Stallion's range of true intelligent multiport boards. It supports the EasyConnection 8/64, ONboard, Brumby and original Stallion families of multiport boards. The EasyConnection 8/64 and ONboard boards come in ISA, EISA and Microchannel bus versions. The Brumby and Stallion boards are only available in ISA versions. The EasyConnection 8/64 family of boards is a medium cost, high performance, modular range of intelligent multiport serial boards. The EasyConnection 8/64 boards can be configured to have from 8 to 64 serial ports by plugging in external serial port modules that contain either 8 or 16 ports each (these modules are the same used by the EasyConnection 8/32 board). There is a wide range of external modules available that offer: DB-25 connectors, RJ-45 connectors (both with RS-232 D and E compatible drivers), and also RS-422 and RS-485 ports. The board takes the form of a host adapter card, with an external connector cable that plugs into the external modules. The external modules just clip together to add ports (BTW, they are NOT hot pluggable). Each EasyConnection 8/64 board requires 4 bytes of I/O address space and a region of memory space. The size of the memory region required depends on the exact board type. The EISA version requires 64 Kbytes of address space (that can reside anywhere in the 4 Gigabyte physical address space). The ISA and MCA boards require 4 Kbytes of address space (which must reside in the lower 1 Mbyte of physical address space - typically in the c8000 to e0000 range). No interrupts are required. The physical memory region of multiple EasyConnection 8/64 boards can be shared, but each board must have a separate I/O address space. The ONboard family of boards are traditional intelligent multiport serial boards. They are Stallion's older range of boards with a limited expansion capability. They come in 4, 8, 12, 16 and 32 port versions. The board uses the same base card (which has 4 ports on it) and is expanded to more ports via a mezzanine board that attaches directly onto the board. External panels plug into the ONboard providing RS-232C ports with DB-25 plugs. An RS-422 DB-25 dual interface panel is also available. The ISA and microchannel ONboards require 16 bytes of I/O address space and 64K bytes of memory space. The memory space can be anywhere in the 16 Mbyte ISA bus address range. No interrupt is required. The EISA ONboard requires 64 Kbytes of memory space that can be anywhere in the 4 Gigabyte physical address space. All ONboard boards can share their memory region with other ONboards (or EasyConnection 8/64 boards). The Brumby family of boards are traditional, low cost intelligent multiport serial boards. They are non-expandable and come in 4, 8 and 16 port versions. They are only available for the ISA bus. The serial ports are all on DB-25 "dongle" cables that attach to the rear of the board. Each Brumby board requires 16 bytes of I/O address space and 16 Kbytes of memory space. No interrupts are required. The original Stallion boards are old. They went out of production some years back. They offer limited expandability and are available in 8 or 16 port configurations. An external panel houses 16 RS-232C ports with DB-9 connectors. They require 16 bytes of I/O address space, and either 64K or 128K of memory space. No interrupt is required. I will not actively support these boards, although they will work with the driver. That's the boards supported by the second driver. The ONboard, Brumby and Stallion boards are Stallion's older range of intelligent multiports - so there are lots of them around. They only support a maximum baud rate of 38400. The EasyConnection 8/64 is a true high performance intelligent multiport board, having much greater throughput than any of Stallion's older boards. It also supports speeds up to 115200 baud. 1.3 HOW TO GET BOARDS Stallion Technologies has offices all over the world, as well as many more distributors and resellers. To find out about local availability please contact the nearest Stallion office and they can give you all the information you need. Stallion Technologies Sales and Support Offices =============================================== Stallion Technologies Pty. Ltd. P.O. Box 954 Toowong, QLD 4066, Australia Tel. +61 7 3270 4242 Fax. +61 7 3270 4245 Email: support@stallion.oz.au Stallion Technologies Inc. 2880 Research Park Drive, Soquel, CA 95073, USA. Tel. +1 408 477 0440 Fax. +1 408 477 0444 Email: support@staltec.com Stallion Technologies Deutschland GmbH. Martin-Behaim-Strasse 12 63263 Neu-Isenburg Germany Tel. +49 6102 73970 Fax. +49 6102 739710 Another good source of information about the Stallion range of boards and local availability is on the Stallion Web page. Check it out at http://www.stallion.com. 2. INSTALLATION This driver, as is, will work on a FreeBSD 2.1 system. It will run on a 2.0.5 system, or -current version systems by changing a define in the driver source. You will need to build a new kernel to use this driver. So the first thing you need is to have the full kernel source. Most people will have this (I hope!). The following assumes that the kernel source is in /usr/src/sys. The drivers can support up to 8 boards. For the smart board driver any combination of EasyIO and EasyConnection 8/32 boards can be installed. For the intelligent any combination of EasyConnection 8/64, ONboard, Brumby or original Stallion. So there is a theoretical maximum of 512 ports. (Off-course I have not tested a system with this many!) [[[ The install instructions are obsolete, it is now standard ]]] [[[ Skip forward to item 4, editing your kernel config file ]]] 2.1 Instructions to install: 1. Copy the driver source files into the kernel source tree. cp stallion.c istallion.c cdk.h comstats.h /usr/src/sys/i386/isa cp scd1400.h /usr/src/sys/i386/isa/ic Note: if you are NOT using FreeBSD 2.1.0 then you will need to edit the stallion.c and istallion.c files and change the VFREEBSD define to match your version. 2. Skip to next step if on a FreeBSD kernel later than 2.1.0. Add a character device switch table entry for the driver that you which to use into the cdevsw table structure. This involves adding some code into the kernel conf.c file. If you are using an EasyIO or EasyConnection 8/32 then you need to use the stallion.c driver. All other board types (EasyConnection 8/64, ONboard, Brumby, Stallion) use the istallion.c driver. You can also have a mix of boards using both drivers. You will need to use a different major device number for the second driver though (not the default 72 - see below for more details on this). 2.1. If using the stallion.c driver then do: cd /usr/src/sys/i386/i386 vi conf.c - add the following lines (in 2.1 I put them at line 729): /* Stallion Multiport Serial Driver */ #include "stl.h" #if NSTL > 0 d_open_t stlopen; d_close_t stlclose; d_read_t stlread; d_write_t stlwrite; d_ioctl_t stlioctl; d_stop_t stlstop; d_ttycv_t stldevtotty; #define stlreset nxreset #define stlmmap nxmmap #define stlstrategy nxstrategy #else #define stlopen nxopen #define stlclose nxclose #define stlread nxread #define stlwrite nxwrite #define stlioctl nxioctl #define stlstop nxstop #define stlreset nxreset #define stlmmap nxmmap #define stlstrategy nxstrategy #define stldevtotty nxdevtotty #endif - and then inside the actual cdevsw structure definition, at the last entry add (this is now line 1384 in the 2.1 conf.c): { stlopen, stlclose, stlread, stlwrite, /*72*/ stlioctl, stlstop, stlreset, stldevtotty,/*stallion*/ ttselect, stlmmap, stlstrategy }, - the line above used major number 72, but this may be different on your system. Take note of what major number you are using. - save the file and exit vi. 2.2. If using the istallion.c driver then do: cd /usr/src/sys/i386/i386 vi conf.c - add the following lines (in 2.1 I put them at line 729): /* Stallion Intelligent Multiport Serial Driver */ #include "stl.h" #if NSTL > 0 d_open_t stliopen; d_close_t stliclose; d_read_t stliread; d_write_t stliwrite; d_ioctl_t stliioctl; d_stop_t stlistop; d_ttycv_t stlidevtotty; #define stlireset nxreset #define stlimmap nxmmap #define stlistrategy nxstrategy #else #define stliopen nxopen #define stliclose nxclose #define stliread nxread #define stliwrite nxwrite #define stliioctl nxioctl #define stlistop nxstop #define stlireset nxreset #define stlimmap nxmmap #define stlistrategy nxstrategy #define stlidevtotty nxdevtotty #endif - and then inside the actual cdevsw structure definition, at the last entry add (this is now line 1384 in the 2.1 conf.c): { stliopen, stliclose, stliread, stliwrite, /*72*/ stliioctl, stlistop, stlireset, stlidevtotty,/*istallion*/ ttselect, stlimmap, stlistrategy }, - the line above used major number 72, but this may be different on your system. Take note of what major number you are using. - save the file and exit vi. 3. Add the driver source files to the kernel files list: cd /usr/src/sys/i386/conf vi files.i386 - add the following definition lines into the list (it is stored alphabetically, so insert them appropriately): i386/isa/istallion.c optional stli device-driver i386/isa/stallion.c optional stl device-driver - save the file and exit vi. 4. Add board probe entries into the kernel configuration file: cd /usr/src/sys/i386/conf cp GENERIC MYKERNEL - if you already have a kernel config that you use then you could just use that (instead of MYKERNEL) vi MYKERNEL - if only using ECH-PCI boards then you don't need to enter a configuration line, the kernel will automatically detect the board at boot up, so skip to step 5. - enter a line for each board that you want to use. For stallion.c boards entries should look like: device stl0 at isa? port 0x2a0 tty irq 10 For istallion.c boards, the entries should look like: device stli0 at isa? port 0x2a0 tty iomem 0xcc000 iosiz 0x1000 flags 23 (I suggest you put them after the sio? entries) (Don't enter lines for ECH-PCI boards) - change the entry resources as required. For the Stallion.c entries this may involve changing the port address or irq. For the istallion.c entries this may involve changing the port address, iomem address, iosiz value and the flags. Select from the following table for appropriate flags and iosiz values for your board type: EasyConnection 8/64 ISA: flags 23 iosiz 0x1000 EasyConnection 8/64 EISA: flags 24 iosiz 0x10000 EasyConnection 8/64 MCA: flags 25 iosiz 0x1000 ONboard ISA: flags 4 iosiz 0x10000 ONboard EISA: flags 7 iosiz 0x10000 ONboard MCA: flags 3 iosiz 0x10000 Brumby: flags 2 iosiz 0x4000 Stallion: flags 1 iosiz 0x10000 - save the file and exit 5. Build a new kernel using this configuration. cd /usr/src/sys/i386/conf config MYKERNEL cd ../../compile/MYKERNEL make depend make all make install And there you have it! It is a little bit of effort to get it in there... Once you have a new kernel built reboot to start it up. On startup the Stallion board probes will report on whether the boards were found or not. For each board found the driver will print out the type of board found, and how many panels and ports it has. If a board is not found by the driver but is actually in the system then the most likely problem is that the IO address is incorrect. The easiest thing to do is change the DIP switches on the board to the desired address and reboot. On EasyIO and EasyConnection 8/32 boards the IRQ is software programmable, so if there is a conflict you may need to change the IRQ used for a board in the MYKERNEL configuration file and rebuild the kernel. Note that the secondary IO address of the EasyConnection 8/32 boards is hard coded into the stallion.c driver code. It is currently set to IO address 0x280. If you need to use a different address then you will need to edit this file and change the variable named stl_ioshared. On intelligent boards it is possible that the board shared memory region is clashing with that of some other device. Check for this and change the device or kernel configuration as required. 2.2 INTELLIGENT DRIVER OPERATION The intelligent boards also need to have their "firmware" code downloaded to them. This is done via a user level application supplied in the driver package called "stlload". Compile this program where ever you dropped the package files, by typing "make". In its simplest form you can then type ./stlload -i cdk.sys in this directory and that will download board 0 (assuming board 0 is an EasyConnection 8/64 board). To download to an ONboard, Brumby or Stallion do: ./stlload -i 2681.sys Normally you would want all boards to be downloaded as part of the standard system startup. To achieve this, add one of the lines above into the /etc/rc.serial file. To download each board just add the "-b <brd-number>" option to the line. You will need to download code for every board. You should probably move the stlload program into a system directory, such as /usr/sbin. Also, the default location of the cdk.sys image file in the stlload down-loader is /usr/lib/stallion. Create that directory and put the cdk.sys and 2681.sys files in it. (It's a convenient place to put them anyway). As an example your /etc/rc.serial file might have the following lines added to it (if you had 3 boards): /usr/sbin/stlload -b 0 -i /usr/lib/stallion/cdk.sys /usr/sbin/stlload -b 1 -i /usr/lib/stallion/2681.sys /usr/sbin/stlload -b 2 -i /usr/lib/stallion/2681.sys The image files cdk.sys and 2681.sys are specific to the board types. The cdk.sys will only function correctly on an EasyConnection 8/64 board. Similarly the 2681.sys image will only operate on ONboard, Brumby and Stallion boards. If you load the wrong image file into a board it will fail to start up, and of course the ports will not be operational! 3. USING THE DRIVER Once the driver is installed you will need to setup some device nodes to access the serial ports. Use the supplied "mkdevnods" script to automatically create all required device entries for your boards. To make device nodes for more than 1 board then just supply the number of boards you are using as a command line parameter to mkdevnods and it will create nodes for that number of boards. By default it will create device nodes for 1 board only. Note that if the driver is not installed at character major number 72 then you will need to edit the mkdevnods script and modify the STL_SERIALMAJOR variable to the major number you are using. Device nodes created for the normal serial port devices are named /dev/ttyEX where X is the port number. (The second boards ports will start from ttyE64, the third boards from ttyE128, etc). It will also create a set of modem call out devices named cueX where again X is the port number. For the most part the Stallion driver tries to emulate the standard PC system com ports and the standard sio serial driver. The idea is that you should be able to use Stallion board ports and com ports inter-changeably without modifying anything but the device name. Anything that doesn't work like that should be considered a bug in this driver! Since this driver tries to emulate the standard serial ports as much as possible then most system utilities should work as they do for the standard com ports. Most importantly "stty" works as expected and "comcontrol" can be used just like for the serial ports. This driver should work with anything that works on standard com serial ports. Having said that, I have used it on at least the following types of "things" under FreeBSD: a) standard dumb terminals (using getty) b) modems (using cu, etc) c) ppp (through pppd, kernel ppp) 4. NOTES Be aware that these drivers are still very new, so there is sure to be some bugs in them. Please email me any feedback on bugs, problems, or even good experiences with these drivers! You can use both drivers at once if you have a mix of board types installed in a system. However to do this you will need to change the major number used by one of the drivers. Currently both drivers use default major number 72 for their devices. Change one driver to use some other major number (how this is achieved will depend on the kernel version you are using), and then modify the mkdevnods script to make device nodes based on those new major numbers. For example, you could change the stallion.c driver to use major number 73. You will also need to create device nodes with different names for the ports, for eg ttyFXXX. Currently the intelligent board driver (istallion.c) does not have the ability to share a boards memory region with other boards (you can only do this on EasyConnection 8/64 and ONboards normally anyway). It also does not currently support any memory address ranges above the low 1Mb region. These will be fixed in a future release of the driver. Finding a free physical memory address range can be a problem. The older boards like the Stallion and ONboard need large areas (64K or even 128K), so they can be very difficult to get into a system. If you have 16 Mb of RAM then you have no choice but to put them somewhere in the 640K -> 1Mb range. ONboards require 64K, so typically 0xd0000 is good, or 0xe0000 on some systems. If you have an original Stallion board, "V4.0" or Rev.O, then you need a 64K memory address space, so again 0xd0000 and 0xe0000 are good. Older Stallion boards are a much bigger problem. They need 128K of address space and must be on a 128K boundary. If you don't have a VGA card then 0xc0000 might be usable - there is really no other place you can put them below 1Mb. Both the ONboard and old Stallion boards can use higher memory addresses as well, but you must have less than 16Mb of RAM to be able to use them. Usual high memory addresses used include 0xec0000 and 0xf00000. The Brumby boards only require 16Kb of address space, so you can usually squeeze them in somewhere. Common addresses are 0xc8000, 0xcc000, or in the 0xd0000 range. EasyConnection 8/64 boards are even better, they only require 4Kb of address space, again usually 0xc8000, 0xcc000 or 0xd0000 are good. If you are using an EasyConnection 8/64-EI or ONboard/E then usually the 0xd0000 or 0xe0000 ranges are the best options below 1Mb. If neither of them can be used then the high memory support to use the really high address ranges is the best option. Typically the 2Gb range is convenient for them, and gets them well out of the way. The ports of the EasyIO-8M board do not have DCD or DTR signals. So these ports cannot be used as real modem devices. Generally when using these ports you should only use the cueX devices. There is a new utility in this package that reports statistics on the serial ports. You will need to have the ncurses library installed on your system to build it. To build the statistics display program type: make stlstats Once compiled simply run it (you will need to be root) and it will display a port summary for the first board and panel installed. Use the digits to select different board numbers, or 'n' to cycle through the panels on a board. To look at detailed port information then hit 'p', that will display detailed port 0 information. Use the digits and letters 'a' through 'f' to select the different ports (on this board and panel). 5. ACKNOWLEDGEMENTS This driver is loosely based on the code of the FreeBSD sio serial driver. A big thanks to Stallion Technologies for the use of their equipment.