The lm_sensors package includes a collection of modules for general SMBus access and hardware monitoring. NOTE: this requires special support which is not in standard 2.2-vintage kernels.
Most PC's built since late 1997 now come with a hardware health monitoring chip. This chip may be accessed via the ISA bus or the SMBus, depending on the motherboard.
Some motherboard chipsets, notably the Via 686 and the SiS 5595, contain hardware monitor functions.
This FAQ frequently refers to the "LM78". This chip has been obsoleted by National Semiconductor. Most motherboards today contain a chip with similar functions.
The LM78 is a chip made by National Semiconductor which can monitor 7 voltages (5 positive, 2 negative) from 0 to 4.08V. The inputs are usually in series with voltage dividers which lower the +/- 12V and +/- 5V supplies to measurable range. Therefore, the readings for such inputs need to be re-scaled appropriately by software.
The LM78 also has 3 fan speed monitoring inputs, an internal temperature sensor, a chassis intrusion sensor, and a couple maskable interrupt inputs. The LM78 can also relay the processor's (P6 or Pent II) VID lines which are hardwired and used to indicate to the power regulator (usually on the mainboard close to the processor socket/slot) what voltage to supply to the processor.
The LM78 can be interfaced to a system via the ISA bus and/or the SMBus.
Most other sensor chips have comparable functionality. Each supported chip is documented in the doc/chips directory.
Most semiconductor companies have comprehensive documentation, including complete datasheets, on their websites. Analog Devices, Dallas Semiconductor, Maxim, and National Semiconductor have the widest selection of sensor chips. Their websites are:
Please see the file http://www.lm-sensors.org/wiki/UsefulLinks for links to other companies' websites.
Sensor chips reside on either the ISA bus, the SMBus, or both. See the file doc/chips/SUMMARY in our package for a list.
To communicate with chips on the ISA bus, the software uses simple I/O reads and writes.
To communicate with chips on the SMBus, the software must use an SMBus interface device, explained below.
The SMBus is the "System Management Bus". More specifically, it is a 2-wire, low-speed serial communication bus used for basic health monitoring and hardware management. It is a specific implementation of the more general I2C (pronunciation: I-squared-C) bus. In fact, both I2C devices and SMBus devices may be connected to the same (I2C) bus.
The SMBus (or I2C bus) starts at the host controller, used for starting transactions on the SMBus. From the host interface, the devices communicated with are the slave devices. Each slave device has a unique 7-bit address which the host uses to refer to that device.
For each supported SMBus host, there is a separate kernel module which implements the communication protocol with the host. Some SMBus hosts really operate on the SMBus level; these hosts can not cope with pure I2C devices. Other hosts are in fact I2C hosts: in this case, we implement the SMBus protocol in terms of I2C operations. But these hosts can also talk to pure I2C devices.
We promise, you do, even if you don't have any old ISA slots. The "ISA Bus" exists in your computer even if you don't have ISA slots; it is simply a memory-mapped area, 64KB in size (0x0000 - 0xFFFF) where many "legacy" functions, such as keyboard and interrupt controllers, are found. It isn't necessarily a separate physical bus. See the file /proc/ioports for a list of devices living on the "ISA Bus" in your system. If you don't like the term "ISA Bus" think "I/O Space".
Most new processors contain a thermal diode on the die itself. The electical properties of all diodes and transistors vary slightly with temperature. The thermal diode is exceptionally accurate because it is directly on the die. Newer temperature sensor chips, like the Analog Devices ADM1021 and clones, and the Winbond chips, have circuitry for measuring the the electrical properties of an external diode and converting this data to a temperature. Any sensor chip listed in doc/chips/SUMMARY in our package which has support for more than one temperature supports external temperature sensing.
Older motherboards and processors without this feature generally use an LM75 placed close to the processor. This is much less accurate.
The Pentium 2 'boxed' processor usually has an LM75 very close to the base of the box. It can be read through the SMBus to report the approximate temperature of the processor. The processor also contains an internal temperature sensor (of low accuracy) used as a fail-safe to disable the processor in case it gets much too hot (usually around 130 degrees C). And, the Pentium 2 also has a hard-wired signal (VID lines) on it's SEC (single edge connector) which indicates what power supply is required to operate the processor.
The P6 (Pentium-Pro) may have an LM75 in or just under the socket. P6's also have VID lines.
Pentiums and Pentium w/ MMX do not have VID lines, and sometimes have LM75's under the sockets (depends on the mainboard, and how 'modern' the mainboard is).
The P2 Xeon was the first Intel processor to include the SMBus interface on the P2 Xeon SEC.
The LM78, and most other sensor chips like it, reads its sensors one by one. A complete scanning sweep will take about 1.5 seconds. The LM78 stops readings sensors if you try to access it, so if you access it very often (by reading sensor values; writing new limits is safe) it will not find the time to update its sensor values at all! Fortunately, the kernel module takes care not to do this, and only reads new values each 1.5 seconds. If you read the values again, you will get the 'old' values again.
It is possible to monitor each sensor and have an alarm go off if it crosses some pre-determined limits. There are two sorts of interrupts which can be generated by sensor chips if this happens (it depends a bit on the actual chip if both are supported; the LM80, for example, has only IRQ interrupts): IRQ interrupts and SMI interrupts. IRQ stands for Interrupt Request and are the interrupt lines you can find in /proc/interrupts. SMI stands for System Management Interrupt, and is a special interrupt which puts the processor in a secure environment independent of any other things running. SMI is currently not supported by the Linux kernel. IRQs are supported, of course.
Even if no interrupt is generated, some bits in a status register will be set until the register is read the next time. If the alarm condition persists after that, the bits will be set on the next scanning sweep, etc.
Most drivers in our package do not support interrupts at this time.
We tried to make this package as modular as possible. This makes it easy to add new drivers, and unused drivers will take no precious kernel space. On the other hand, it can be a bit confusing at first.
Here are two simple guidelines:
Further information is in doc/modules.
We have an excellent program that scans all your hardware. It is called sensors-detect and is installed in /usr/local/sbin by make install. Just execute this script, and it will tell you.
Chip detection in the drivers is fairly good. That means that it is usually harmless to insert more chip drivers than you need. However, this can still lead to problems, so we do not recommend it.
If sensors-detect didn't find any sensors, either you don't have any, or the ones you have, we don't support. (Look at your motherboard for candidates, then see Help)
!!!!!!!!! YES THIS IS THE MOST FREQUENT QUESTION WE GET !!!!!!!!!
We have no idea. Here is what you should do:
If that doesn't work:
We don't support boards, we support chips. See What chips are on motherboard XYZ.
This we have good answers for.
Newest Driver Status: http://www.lm-sensors.org/wiki/Devices
sensors-detect will tell you. Take the modprobe lines it recommends and paste them into the appropriate /etc/rc.d/xxxx file to be executed at startup.
You need one module for each sensor chip and bus adapter you own; if there are sensor chips on the ISA bus, you also need i2c-isa.o. for each type of chip you own. That's all. On my computer, I could use the following lines:
Yes, for any applications that use libsensors, including the sensors application included in our package. It tells libsensors how to translate the values the chip measures to real-world values. This is especially important for voltage inputs. The default configuration file should usually do the trick. It is automatically installed as /etc/sensors.conf, but it will not overwrite any existing file with that name.
Every motherboard is different. You can customize the labels in the file /etc/sensors.conf. That's why it exists! The default labelling (in lib/chips.c and /etc/sensors.conf) is just a template.
You can customize them in the file /etc/sensors.conf. See above.
You forgot to run sensors -s. See above.
Use an ignore line in /etc/sensors.conf so it isn't displayed in sensors.
There is detailed help at the top of that file.
No. Good idea though. If you would like to set one up on your website send us mail and we will set up a link to it.
Don't worry about them. The dependency files (which tell which files should be recompiled when certain files change) are created dynamically. They are not distributed with the package. The make program notices they are not there, and warns about that - and the first thing it will do is generate them. So all is well.
Check that the correct i2c header files are used. Depending on how you installed, they should be under either /usr/local/include or /usr/src/linux*/include. Try to edit the Makefile for the other setting.
Have you installed the matching version of the i2c package? Remember, compilation is not enough, you also need to install it for the header files to be found!
If you want to patch the kernel, you will have to apply the i2c patches first!
Mandrake uses a non-standard version.h file which confuses our Makefile.
Edit our Makefile on the MODDIR := line to hard-code the module directory.
Example:
*** Unresolved symbols in /lib/modules/2.4.5/kernel/drivers/i2c/i2c-i810.o
i2c_bit_add_bus_R8c3bc60e
i2c_bit_del_bus_R92b18f49
You can also run depmod -a -e to see all unresolved symbols.
These are module versioning problems. Generally you did not compile against the kernel you are running. Sometimes the Red Hat source you have is not for the kernel you are running. You must compile our package against the source for the kernel you are running with something like make LINUX=/usr/src/linux-2.4.14.
Try the following to be sure:
kmalloc, printk etc. and note the
number code behind them, like printk_R1b7d4074. If there is no numeric
code after them, note this too.
kmalloc,
printk etc. Note the number code behind them, or the lack thereof.
In some versions of Redhat, an RPM is included to provide i2c support. However, this RPM does not place the header files in the kernel directory structure. When you update kernels, they may persist. To get rid of these obsolete header files, at a command prompt:
make clean make
The problem with much of the sensor data is that it is impossible to properly interpret some of the readings without knowing what the hardware configuration is. Some fans report one 'tick' each rotation, some report two 'ticks' each rotation. It is easy to resolve this through the configuration file /etc/sensors.conf:
chip lm78-* # Or whatever chip this relates to
compute fan1 2*@,@/2 # This will double the fan1 reading
# -- or --
compute fan1 @/2,2*@ # This will halve the fan1 reading
See doc/fan-divisors in our package for further information.
You may not have a three-wire fan, which is required.
You may need to increase the 'fan divisor'. See doc/fan-divisors in our package for further information.
Believe it or not, doubling the 'fan divisor' will not halve the fan reading. You have to add a compute line in /etc/sensors.conf. See My fans report exactly half/double their values compared to the BIOS, and see doc/fan-divisors in our package for further information.
For starters, those aren't LM75's. Your mainboard actually has the Winbond W83781D which emulates two LM75's, but many systems which use the Winbond chip (such as the Asus P2B) don't have the thermo-resisters connected to the chip resulting in these strange -48 degree readings.
In upcoming versions, you will be able to disable non-interesting readings.
The LM78 has seven voltage sensors. The default way of connecting them is used in the configuration file. This includes a VCore2, even if you do not have one. You can easily edit the configuration file to give it another name, or make this reading disappear using an ignore line.
Note that Vcore2 is often the same as Vcore on motherboards which only support one processor. Another possibility is that Vcore2 is not connected at all and will not have a valid reading at all. A third possibility, is that Vcore2 monitors something else, so you should not be too surprised if the values are completely different.
The ALARM indications in sensors are those reported by the sensor chip itself. They are NOT calculated by sensors. sensors simply reads the ALARM bits and reports them.
An ALARM will go off when a minimum or maximum limit is crossed. The ALARM is then latched - that is, it will stay there until the chip's registers are next accessed - which will be the next time you read these values, but not within (usually) 1.5 seconds since the last update.
Reading the registers clears the ALARMS, unless the current value is still out of range.
The purpose of this scheme is to tell you if there has been a problem and report it to the user. Voltage or temperature spikes get detected without having to read the sensor chip hundreds of times a second. The implemetation details depend a bit on the kind of chip. See the specific chip documentation in doc/chips and the chip datasheet for more information.
No, probably not. If your motherboard heats up a bit, the sensed voltages will drift a bit. If your power supply is loaded (because a disk gets going, for example), the voltages may get a bit lower. Heavy processor activity, in particular, dramatically increases core voltage supply load which will often cause variation in the other supplies. As long as they stay within a sensible range (say 5% of the nominal value for CPU core voltages, and 10% for other voltages), there is no reason to worry.
Each module tries to set limits to sensible values on initialization, but a module does not know how a chip is actually connected. This is described in the configuration file, which is not read by kernel modules. So limits can be strange, if the chip is connected in a non-standard way.
Readings can also be strange; there are several reasons for this. Temperature sensors, for example, can simply not be present, even though the chip supports them. Also, it can be that the input is used in a non-standard way. You can use the configuration file to describe how this measurement should be interpreted; see the comments the example file for more information.
It's very frequent that negative voltage lines are not wired because motherboard manufacturers don't think they're worth monitoring (they are mostly unused these days). You can just add ignore inN lines to /etc/sensors.conf to hide them.
Another possibility is that these lines are used to monitor different voltages. Only the motherboard manufacturer can tell for sure. Taking a look at what voltage values the BIOS displays may provide valuable hints though.
These describe the core voltage for your processor. They are supported for most processors, however they are not always correctly connected to the sensor chip, so the readings may be invalid. A reading of 0V, +3.5V or +2.05V is especially suspect. If this is the case, add a line ignore vid to /etc/sensors.conf, and change the min and max settings for the Processor Core voltage (often in0_min and in0_max) in that file so that they don't depend on vid.
The CPU nominal voltage is computed from VID lines according to a formula that depends on the CPU type. Most chips that report a VID value can be configured to use either VRM 8.2 (for Pentium III) or VRM 9.0 (for Pentium 4 and Athlon). You chose which one you want through /etc/sensors.conf. See doc/vid for more information.
If we would read the registers more often, it would not find the time to update them. So we only update our readings once each 1.5 seconds (the actual delay is chip-specific; for some chips, it may not be needed at all).
ISA bus access is fast, but SMBus access is really slow. If you have a lot of sensors, it just takes a lot of time to access them. Fortunately, this has almost no impact on the system as a whole, as another job can run while we are waiting for the transaction to finish.
No, you can't; and it may well be never supported.
Almost no mainboard we have encountered have actually connected the IRQ-out pin of sensor chips. That means that we could enable IRQ reporting, but nothing would happen. Also, even if a motherboard has it connected, it is unclear what interrupt number would be triggered. And IRQ lines are a scarce facility, which means that almost nobody would be able to use it anyway.
The SMI interrupt is only available on a few types of chips. It is really a very obscure way to handle interrupts, and supporting it under Linux might be quite hard to do.
Your best bet would be to poll the alarm file with a user-land daemon which alerts you if an alarm is raised. I am not aware of any program which does the job, though you might want to examine one of the graphical monitor programs under X, see http://www.lm-sensors.org/wiki/UsefulLinks for addresses.
Some chips which mainboard makers connect to the SMBus are not SMBus devices. An example is the 91xx clock generator chips. When read, these devices can lock up the SMBus until the next hard reboot. This is because they have a similar serial interface (like the I2C), but don't conform to Intel's SMBus standard.
Why did they connect these devices to the SMBus if they aren't compatible? Good question! :') Actually, these devices may support being written to, but lock things up when they are read.
We display the actual temperature of the sensor. This may not be the temperature you are interested in, though. If a sensor should measure the CPU temperature, it must be in thermal contact with it. In practice, it may be just somewhere nearby. Your BIOS may correct for this (by adding, for example, thirty degrees to the measured temperature). The correction factor is regrettably different for each mainboard, so we can not do this in the module itself. You can do it through the configuration file, though:
chip lm75-*-49 # Or whatever chip this relates to
label temp "Processor"
compute temp @*1.2+13,(@-13)/1.2 # Or whatever formula
However, the offset you are introducing might not be necessary. If you tried to have Linux idle temperature and BIOS "idle" temperature match, you may be misguided. We have a Supermicro (370DLE) motherboard and we know that its BIOS has a closed, almost undelayed while(1) loop that keeps the CPU busy all the time. Linux reads 26 degrees idle, BIOS reads 38 degrees. Linux at full load is in the 35-40 degrees range so this makes sense.
Remember, these values do not take the configuration file compute lines in account. This is especially obvious for voltage readings (usually called in? or vin?). Use a program linked to libsensors (like the provided sensors program) instead.
Change the limit values in /etc/sensors.conf and then run sensors -s.
You forgot to run sensors -s. Put it in a /etc/rc.d/... file after the modprobe lines to run at startup.
Yes, this is still a problem. It is partially solved by alias detection and confidence values in sensors-detect, but it is really tough.
Double detections can be caused by two things: sensors can be detected to both the ISA and the SMBus (and if you have loaded the approprate adapter drivers, it will be detected on both), and some chips simulate other chips (the Winbond W83781D simulates LM75 chips on the SMBus, for example). Remove the offending adapter or chip driver, or run sensors-detect and add the ignore= modprobe parameters it suggests.
Your SMBus (PIIX4?) is probably crashed or hung. There are some mainboards which connect a clock chip to the SMBus. Unfortunately, this clock chip hangs the PIIX4 if it is read (it is an I2C device, but not SMBus compatible). We have found no way of solving this, except for rebooting your computer. Next time when you run sensors-detect, you may want to exclude addresses 0x69 and/or 0x6a, by entering s when you are asked whether you want to scan the PIIX4.
See below for some particularly troublesome chips. Also be sure and check doc/chips/xxxxx for the particular driver.
The Asus AS99127F is a modified version of the Winbond W83781D. Asus will not release a datasheet. The driver was developed by tedious experimentation. We've done the best we can. If you want to make adjustments to the readings please edit /etc/sensors.conf. Please don't ask us to fix the driver. Ask Asus to release a datasheet.
The Via 686A datasheet is incomplete. Via will not release details. The driver was developed by tedious experimentation. We've done the best we can. If you want to make adjustments to the readings please edit /etc/sensors.conf. Please don't ask us to fix the driver. Ask Via to release a better datasheet. Also, don't forget to modprobe i2c-isa.
The MTP008 has programmable temperature sensor types. If your sensor type does not match the default, you will have to change it. See doc/chips/mtp008 for details. Also, MTP008 chips seem to randomly refuse to respond, for unknown reasons. You can see this as 'XX' entries in i2cdump.
This chip can use multiple thermistor types and there are also two different versions of the chip. We are trying to get the driver working better and develop formulas for different thermistors but we aren't there yet. Sorry. Also, many times the chip isn't really a sis5595 but it was misidentified. We are working on improving that too.
Do you own an ASUS motherboard? Perhaps your chip is being
misidentified. Look on the motherboard (or at
http://mbm.livewiredev.com) for a 'Winbond' or Asus chip.
Often the real device is an Asus as99127f. If so, the driver can be
forced to recognize the as99127f with
force_as99127f=BUS,0x2d where BUS is your i2c bus number.
Cat /proc/bus/i2c to see a list of bus numbers.
Read the w83781d module documentation (doc/chips/w83781d)
for more details.
The SMBus tends to hang on this board and it seems to get worse at higher temperatures. Use ISA accesses to reliably use the w83781d monitor chip on this board and use the ignore=1,0x2d or similar option to the w83781d module to prevent i2c accesses.
The LM75 detection is poor and other hardware is often misdetected as an LM75. Figure out what you really have See What chips are on motherboard XYZ.
The LM78 is no longer manufactured by National Semiconductor. You probably don't have a real LM78 but something similar that we do not recogize or support. Figure out what you really have See What chips are on motherboard XYZ.
The LM80 detection is poor and other hardware is often misdetected as an LM80. Figure out what you really have See What chips are on motherboard XYZ.
There is a SuperMicro board with two LM87's on it that are not hooked up in the same way, so they need different defaults. For example, both CPU temperatures go to one LM87.
Make two different sections in /etc/sensors.conf as follows:
chip "lm87-i2c-*-2c"
put configuration for the chip at 0x2c here
chip "lm87-i2c-*-2d"
put configuration for the chip at 0x2d here
There is a commented example in sensors.conf.eg which should be helpful.
If the problem is a PCI device is not present in lspci, the solution is complex. For the ALI M7101 device, there is a solution which uses the 2.4 kernel's hotplug facility. See prog/hotplug in our package. For other PCI devices, you can try to modify the m7101 solution in prog/hotplug.
If dmesg says `try force_addr', see below. Other drivers generally do not support the force_addr parameter. Sorry. Check the documentation for your driver in doc/[chips,busses] and if we don't support it you can send us your request.
If the problem is a PCI device whose base address is not set, you may be able to set the address with a force parameter. The via686a and sis5595 chip drivers, and some bus drivers, support the command line modprobe via686a force_addr=0xADDRESS where ADDRESS is the I/O address. You must select an address that is not in use. cat /proc/ioports to check (carefully) for conflicts. A high number like 0xf000 is generally safe.
sys /sys sysfs default 0 0
and mount /sys.
proc /proc proc defaults 0 0
and mount /proc.
What specifically is the trouble?
In general, we don't know. Start by running sensors-detect. If it doesn't recognize it, try running i2cdump. A partial list of manufacturers' IDs are at the bottom of doc/chips/SUMMARY.
A clock chip. Often, accessing these clock chips in the wrong way will instantly crash your computer. Sensors-detect carefully avoids these chips. If you really really want to play with your clock chip you can look at kernel/chips/icspll.c in our package. But we do not recommend it. You have been warned.
EEPROMs on your SDRAM DIMMs. Load the eeprom module to look at some basic data in sensors or use the program prog/eeprom/decode-dimms.pl to get more information than you ever wanted.
These are often 'shadows' of your EEPROMs on your SDRAM DIMMs at addresses 0x50 - 0x57. They are the 'software write-protect' registers of the SDRAM Serial Presence Detect EEPROMs. If you try and do a i2cdump on them to read the location, you won't get anything, because they contain a single write-only register. This register can be used to permanently write-protect the contents of the eeprom.
It could be many things. What was the problem? See Problems on particular motherboards.
You don't have i2c support in your kernel, or the i2c-core module was not loaded and you did not run sensors-detect as root.
Your /dev/i2c-0, /dev/i2c0, or /dev/i2c/0 files do not exist or you did not run sensors-detect as root. Run the script prog/mkdev/mkdev.sh to create the /dev/i2c-x files. Run devfs in the kernel to get the /dev/i2c/x files.
Either
But in any case you should figure out what is on the board:
When you know what chips you have, check the Driver Status web page to see if support has been added for your chip in a later release or in SVN.
These are errors from the libsensors library in reading the /etc/sensors.conf configuration file. Go to that line number and fix it. If you have a parse error, perhaps you have to put the feature name in double quotes.
If sensors only says this, for example, and doesn't provide any actual data at all:
it87-isa-0290
Adapter: ISA adapter
Algorithm: ISA algorithm
Your chip is not currently supported by sensors and so all it does is print out that information. Get the latest release and be sure you are running the sensors program it installed and not some older sensors.
See Sensors-detect doesnt work at all, if sensors-detect failed to find any sensors.
If sensors-detect did find sensors, did you insert your modules? For chips on the ISA bus, did you insert i2c-isa?
See What to do if a module wont insert, if the modules didn't insert, also Sensors says No sensors found.
There are several possible causes:
Generally this is caused by an overtemperature alarm output from the sensor chip. This triggers hardware on the board which automatically slows down the CPU clock. Be sure that your temperature limits are above the temperature reading. Put the new limits in /etc/sensors.conf and run sensors -s.
The following boards have unique problems and solutions.
See prog/hotplug/README.p4b if your SMBus master is not found.
See support tickets 805, 765, 781, 812, 813, and 867 for information.
See support tickets 941, 840, and 841 for information.
For board hangs, see support ticket 721 for information. Also Inserting modules hangs my board.
For IBM systems, see README.thinkpad.
Not all drivers have been ported to 2.6. If your favorite driver is not in 2.6, the reason is that nobody has ported it, or the ported code did not get a proper review yet. If you would like to port the driver, see the file Documentation/i2c/porting-clients in the 2.6 kernel tree for help, then send us the ported driver when you are done.
Until kernel 2.6.11, there was a PCI resource conflict between i2c-viapro (the SMBus driver for VIA bridges) and via686a (the integrated sensors driver for VIA bridges). This caused the second loaded driver to silently fail working. So do not load both i2c-viapro and via686a together unless you have a recent kernel.
The 2.6.14-rc1 kernel introduced the hwmon class, which groups all hardware monitoring drivers in a logical way. The goal was to help libsensors grab the relevant sensors information in /sys. In particular:
Note that you can still obtain information about your EEPROMs by using the dedicated perl scripts in prog/eeprom: ddcmon, decode-dimms.pl, decode-edid.pl and decode-vaio.pl.
We are always willing to answer questions if things don't work out. Post your question to our discussion list, and not the individual authors, unless you have something private to say.
Instead of using email, you can also use the web-based support area, at http://www.lm-sensors.org/wiki/FeedbackAndSupport. You will be helped just as fast, and others may profit from the answer too. You will be emailed automatically when your question has been answered.
Here's what you should send us:
Did you use modprobe instead of insmod??? Don't use insmod.
Were there unresolved symbols? Did you run depmod -a? Run depmod -a -e to see where the symbol problem is.
ALWAYS inspect the output of dmesg. That's where the error messages come out!!! Don't rely on the generic message from modprobe. If you still can't figure it out, send us the information listed above.
For an ISA sensor chip, did you also modprobe i2c-isa? It must be inserted.
For an I2C sensor chip, did you also modprobe i2c-xxx where xxx is your I2C bus adapter? It must be inserted.
Always inspect the output of dmesg. That's where the error messages come out. If you still can't figure it out, send us the information listed above.
It may be that this was a mis-detection: the chip may not be present. If you are convinced there is something wrong, verify that you indeed have the devices on your motherboard that you think you do. Look at the motherboard and make sure. If you are still stuck, please send us the usual information (see Help)
Again, send the output listed above.
Drop us a mail if you feel like it, mentioning the mainboard and detected chip type. That way, we have some positive feedback, too!
You can't. Only developers can. Follow up by emailing us and reference your ticket number in the subject. Please don't enter a new ticket with follow-up information, email us instead. Thanks.
Follow up by emailing us and reference your ticket number in the subject.
There are several reasons why we are generally not interested in writing drivers for undocumented chips:
There are also several reasons why we do not want to support such drivers, even if they were written by other people:
Lastly, there are other considerations, some of which are deliberately political:
That being said, authors of such drivers can still submit their code to the Linux kernel folks for inclusion into Linux 2.6. Their driver may be accepted there, under conditions.
If such a driver is ever accepted into the Linux 2.6 tree, and someone provides a patch to libsensors and/or sensors to add support for this driver, we will apply it. This generic code is unlikely to cause trouble.
See doc/developers/new_drivers in our package for instructions.
For anonymous SVN read access, see the instructions on our download page.
For write access, please contact us.
There are two lists you can subscribe to:
The primary mailing list archive is at: http://lists.lm-sensors.org/pipermail/lm-sensors/. It contains messages since October 28, 2001.
There is another mailing list archive at: http://news.gmane.org/gmane.linux.drivers.sensors. It contains messages since December 31, 2004. This archive may also be accessed via a news reader: nntp://news.gmane.org/gmane.linux.drivers.sensors and RSS: http://rss.gmane.org/gmane.linux.drivers.sensors.
And last there is a legacy archive at: http://archives.andrew.net.au/lm-sensors. It contains messages from October 28, 2001 through May 16, 2005.
Check out the latest from CVS, then copy the directory to another directory, and make your changes. Generate the diff with diff -u2 -r DIR1 DIR2. Or you can generate the diff in CVS with cvs diff -u2. Send us the patch in an email and tell us what it does.
Believe it or not, what we really need help with are:
If you are willing to help, simply join our discussion list, and we'll help you help us.
We don't have a separate release announcement mailing list; however, we put all our releases on freshmeat: http://freshmeat.net and you can register on our freshmeat project page http://freshmeat.net/projects/lm_sensors to 'subscribe to new releases' and then freshmeat will email you announcement.