This section is just from messages I've seen on the net. I haven't done it so I can't write from experience. If anyone has, please write this section for me :). See also the message about the GPS1000 contained in section GPS1000 from ACCODATA, not to mention all the UPS specific data in section Info on selected UPSs.
>From [email protected] Wed Jul 21 14:26:33 1993 Newsgroups: comp.os.linux Subject: Re: UPS interface for Linux? From: [email protected] (Miquel van Smoorenburg) Date: Sat, 17 Jul 93 18:03:37 Distribution: world Organization: Cistron Electronics. In article <[email protected]> [email protected] (Joel M. Hoffman) writes: >I'm in the process of buying a UPS (Uninteruptable Power Supply), and >notice that some of them have interfaces for LAN's to signal the LAN >when the power fails. > >Is there such an interface for Linux? > >Thanks. > >-Joel >([email protected]) > When I worked on the last versioon of SysVinit (Now version 2.4), I temporarily had a UPS on my computer, so I added support for it. You might have seen that in the latest <signal.h> header files there is a #define SIGPWR 30 now :-). Anyway, I did not have such a special interface but the output of most UPS's is just a relais that makes or breaks on power interrupt. I thought up a simple way to connect this to the DCD line of the serial port. In the SysVinit package there is a daemon called 'powerd' that keeps an eye on that serial line and sends SIGPWR to init when the status changes, so that init can do something (such as bringing the system down within 5 minutes). How to connect the UPS to the serial line is described in the source "powerd.c", but I will draw it here for explanation: +------------------------o DTR | +---+ | | resistor | | 10 kilo-Ohm | | +---+ To serial port. | +-----o-------+------------------------o DCD | | o UPS | \ relais | \ | | | +-----o-------+------------------------o GND Nice drawing eh? Hope this helps. SysVinit can be found on sunsite (and tsx-11 probably) as SysVinit2.4.tar.z Mike. -- Miquel van Smoorenburg, <[email protected]> Ibmio.com: cannot open CONFIG.SYS: file handle broke off. >From [email protected] Wed Jul 21 14:27:04 1993 Newsgroups: comp.os.linux Subject: Re: UPS interface for Linux? From: [email protected] (Danny ter Haar) Date: Mon, 19 Jul 93 11:02:14 Distribution: world Organization: Cistron Electronics. In article <[email protected]> [email protected] (Miquel van Smoorenburg) writes: >How to connect the UPS to the serial line is described in the source >"powerd.c", but I will draw it here for explanation: The drawing wasn't really clear, please use this one in stead ! > > +------------------------o DTR > | > +---+ > | | resistor > | | 10 kilo-Ohm > | | > +---+ To serial port. > | > +-----o-------+------------------------o DCD > | > o UPS > \ relais > \ > | > +-----o--------------------------------o GND > The DTR is kept high, when the UPS's power input is gone it will close the relais . The computer is monitoring the DCD input port to go LOW . When this happens it will start a shutdown sequence... _____ Danny -- <=====================================================================> Danny ter Haar <[email protected]> or <[email protected]> Robins law #103: 'a couple of lightyears can't part good friends'
Try to get documentation for the cables that your UPS seller supplies. In particular find out:
You then need to either hack powerd.c
appropriately, or use one of the above configurable packages (see the packages genpower-1.0.1.tgz
, powerd-2.0.tar.gz
, or upsd-1.0.tgz
described in section Software). If you use one of the packages, follow the instructions there. If you want to hack powerd.c
, keep reading.
If you have trouble getting the above information, or just want to check it (a good idea) the following program might help. It's a hacked version of powerd.c
. It allows you to set the necessary port flags from the command line and then monitors the port, displaying the control lines every second. I used it as ``upscheck /dev/cua1 2'' (for example) to set the 2nd bit (DTR
) and to clear the other bits. The number base 2 indicates which bits to set, so for example to set bits 1, 2 and 3, (and clear the others) use 7. See the code for details.
Here's the (untested) upscheck.c program. It's untested because I edited the version I originally used to make it clearer, and can't test the new version at the moment.
/* * upscheck Check how UPS & computer communicate. * * Usage: upscheck <device> <bits to set> * For example, upscheck /dev/cua4 4 to set bit 3 & * monitor /dev/cua4. * * Author: Harvey J. Stein <[email protected]> * (but really just a minor modification of Miquel van * Smoorenburg's <[email protected]> powerd.c * * Version: 1.0 19940802 * */ #include <sys/types.h> #include <sys/ioctl.h> #include <fcntl.h> #include <errno.h> #include <stdlib.h> #include <unistd.h> #include <stdio.h> #include <signal.h> /* Main program. */ int main(int argc, char **argv) { int fd; /* These TIOCM_* parameters are defined in <linux/termios.h>, which */ /* is indirectly included here. */ int dtr_bit = TIOCM_DTR; int rts_bit = TIOCM_RTS; int set_bits; int flags; int status, oldstat = -1; int count = 0; int pc; if (argc < 2) { fprintf(stderr, "Usage: upscheck <device> <bits-to-set>\n"); exit(1); } /* Open monitor device. */ if ((fd = open(argv[1], O_RDWR | O_NDELAY)) < 0) { fprintf(stderr, "upscheck: %s: %s\n", argv[1], sys_errlist[errno]); exit(1);} /* Get the bits to set from the command line. */ sscanf(argv[2], "%d", &set_bits); while (1) { /* Set the command line specified bits (& only the command line */ /* specified bits). */ ioctl(fd, TIOCMSET, &set_bits); fprintf(stderr, "Setting %o.\n", set_bits); sleep(1); /* Get the current line bits */ ioctl(fd, TIOCMGET, &flags); fprintf(stderr, "Flags are %o.\n", flags); /* Fiddle here by changing TIOCM_CTS to some other TIOCM until */ /* this program detects that the power goes out when you yank */ /* the plug on the UPS. Then you'll know how to modify powerd.c. */ if (flags & TIOCM_CTS) { pc = 0 ; fprintf(stderr, "power is up.\n"); } else { pc = pc + 1 ; fprintf(stderr, "power is down.\n"); } } close(fd); }
The previous section presupposes knowledge of the correspondence between terminal signals and serial port pins. Here's a reference for that correspondence, taken from David Tal's ``Frequently Used Cables and Connectors'' document. I'm including a diagram illustrating the connectors, and a table listing the correspondence between pin numbers and terminal line signals.
If you need a general reference for cable wiring, connectors, etc, then David Tal's would be a good one, but I can't seem to locate this document on the net any more. But I've found a good replacement. It's The Hardware Book.
Other useful sites:
Incidentally, it seems that the Linuxdoc-sgml package still doesn't format tables very well in the html
output. If you want to be able to read the following table, you're probably going to have to look at either the DVI
version or the plain text version of this document.
DB-25 |
DB-9 | Name | EIA | CCITT | DTE-DCE | Description |
Pin # | Pin # | |||||
1 | FG | AA | 101 | --- | Frame Ground/Chassis GND | |
2 | 3 | TD | BA | 103 | ---> | Transmitted Data, TxD |
3 | 2 | RD | BB | 104 | <--- | Received Data, RxD |
4 | 7 | RTS | CA | 105 | ---> | Request To Send |
5 | 8 | CTS | CB | 106 | <--- | Clear To Send |
6 | 6 | DSR | CC | 107 | <--- | Data Set Ready |
7 | 5 | SG | AB | 102 | ---- | Signal Ground, GND |
8 | 1 | DCD | CF | 109 | <--- | Data Carrier Detect |
9 | -- | -- | - | - | Positive DC test voltage | |
10 | -- | -- | - | - | Negative DC test voltage | |
11 | QM | -- | - | <--- | Equalizer mode | |
12 | SDCD | SCF | 122 | <--- | Secondary Data Carrier Detect | |
13 | SCTS | SCB | 121 | <--- | Secondary Clear To Send | |
14 | STD | SBA | 118 | ---> | Secondary Transmitted Data | |
15 | TC | DB | 114 | <--- | Transmitter (signal) Clock | |
16 | SRD | SBB | 119 | <--- | Secondary Receiver Clock | |
17 | RC | DD | 115 | ---> | Receiver (signal) Clock | |
18 | DCR | -- | - | <--- | Divided Clock Receiver | |
19 | SRTS | SCA | 120 | ---> | Secondary Request To Send | |
20 | 4 | DTR | CD | 108.2 | ---> | Data Terminal Ready |
21 | SQ | CG | 110 | <--- | Signal Quality Detect | |
22 | 9 | RI | CE | 125 | <--- | Ring Indicator |
23 | -- | CH | 111 | ---> | Data rate selector | |
24 | -- | CI | 112 | <--- | Data rate selector | |
25 | TC | DA | 113 | <--- | Transmitted Clock | |
1 13 1 5 _______________________________ _______________ \ . . . . . . . . . . . . . / \ . . . . . / RS232-connectors \ . . . . . . . . . . . . / \ . . . . / seen from outside --------------------------- ----------- of computer. 14 25 6 9 DTE : Data Terminal Equipment (i.e. computer) DCE : Data Communications Equipment (i.e. modem) RxD : Data received; 1 is transmitted "low", 0 as "high" TxD : Data sent; 1 is transmitted "low", 0 as "high" DTR : DTE announces that it is powered up and ready to communicate DSR : DCE announces that it is ready to communicate; low=modem hangup RTS : DTE asks DCE for permission to send data CTS : DCE agrees on RTS RI : DCE signals the DTE that an establishment of a connection is attempted DCD : DCE announces that a connection is established
Since you also might need to modify powerd.c
to raise and lower the correct lines, you might also need the numeric values of different terminal signals. The can be found in /usr/include/linux/termios.h
, but are reproduced here for reference. Since they could change, you're best off confirming these values against said file.
/* modem lines */ #define TIOCM_LE 0x001 #define TIOCM_DTR 0x002 #define TIOCM_RTS 0x004 #define TIOCM_ST 0x008 #define TIOCM_SR 0x010 #define TIOCM_CTS 0x020 #define TIOCM_CAR 0x040 #define TIOCM_RNG 0x080 #define TIOCM_DSR 0x100 #define TIOCM_CD TIOCM_CAR #define TIOCM_RI TIOCM_RNG
Note that the 3rd column is in Hex.