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Corrected the word adventerous to adventurous. Signed-off-by: Stefan Huber <steffhip@gmail.com> Signed-off-by: Matthias Schid <aircrach115@gmail.com> Signed-off-by: Simon Puels <simon.puels@gmail.com> Signed-off-by: Jiri Kosina <jkosina@suse.cz>
313 lines
12 KiB
Plaintext
313 lines
12 KiB
Plaintext
uGuru datasheet
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===============
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First of all, what I know about uGuru is no fact based on any help, hints or
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datasheet from Abit. The data I have got on uGuru have I assembled through
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my weak knowledge in "backwards engineering".
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And just for the record, you may have noticed uGuru isn't a chip developed by
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Abit, as they claim it to be. It's really just an microprocessor (uC) created by
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Winbond (W83L950D). And no, reading the manual for this specific uC or
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mailing Windbond for help won't give any useful data about uGuru, as it is
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the program inside the uC that is responding to calls.
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Olle Sandberg <ollebull@gmail.com>, 2005-05-25
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Original version by Olle Sandberg who did the heavy lifting of the initial
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reverse engineering. This version has been almost fully rewritten for clarity
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and extended with write support and info on more databanks, the write support
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is once again reverse engineered by Olle the additional databanks have been
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reverse engineered by me. I would like to express my thanks to Olle, this
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document and the Linux driver could not have been written without his efforts.
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Note: because of the lack of specs only the sensors part of the uGuru is
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described here and not the CPU / RAM / etc voltage & frequency control.
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Hans de Goede <j.w.r.degoede@hhs.nl>, 28-01-2006
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Detection
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=========
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As far as known the uGuru is always placed at and using the (ISA) I/O-ports
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0xE0 and 0xE4, so we don't have to scan any port-range, just check what the two
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ports are holding for detection. We will refer to 0xE0 as CMD (command-port)
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and 0xE4 as DATA because Abit refers to them with these names.
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If DATA holds 0x00 or 0x08 and CMD holds 0x00 or 0xAC an uGuru could be
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present. We have to check for two different values at data-port, because
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after a reboot uGuru will hold 0x00 here, but if the driver is removed and
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later on attached again data-port will hold 0x08, more about this later.
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After wider testing of the Linux kernel driver some variants of the uGuru have
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turned up which will hold 0x00 instead of 0xAC at the CMD port, thus we also
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have to test CMD for two different values. On these uGuru's DATA will initially
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hold 0x09 and will only hold 0x08 after reading CMD first, so CMD must be read
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first!
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To be really sure an uGuru is present a test read of one or more register
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sets should be done.
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Reading / Writing
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=================
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Addressing
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----------
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The uGuru has a number of different addressing levels. The first addressing
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level we will call banks. A bank holds data for one or more sensors. The data
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in a bank for a sensor is one or more bytes large.
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The number of bytes is fixed for a given bank, you should always read or write
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that many bytes, reading / writing more will fail, the results when writing
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less then the number of bytes for a given bank are undetermined.
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See below for all known bank addresses, numbers of sensors in that bank,
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number of bytes data per sensor and contents/meaning of those bytes.
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Although both this document and the kernel driver have kept the sensor
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terminoligy for the addressing within a bank this is not 100% correct, in
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bank 0x24 for example the addressing within the bank selects a PWM output not
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a sensor.
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Notice that some banks have both a read and a write address this is how the
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uGuru determines if a read from or a write to the bank is taking place, thus
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when reading you should always use the read address and when writing the
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write address. The write address is always one (1) more than the read address.
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uGuru ready
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-----------
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Before you can read from or write to the uGuru you must first put the uGuru
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in "ready" mode.
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To put the uGuru in ready mode first write 0x00 to DATA and then wait for DATA
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to hold 0x09, DATA should read 0x09 within 250 read cycles.
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Next CMD _must_ be read and should hold 0xAC, usually CMD will hold 0xAC the
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first read but sometimes it takes a while before CMD holds 0xAC and thus it
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has to be read a number of times (max 50).
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After reading CMD, DATA should hold 0x08 which means that the uGuru is ready
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for input. As above DATA will usually hold 0x08 the first read but not always.
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This step can be skipped, but it is undetermined what happens if the uGuru has
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not yet reported 0x08 at DATA and you proceed with writing a bank address.
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Sending bank and sensor addresses to the uGuru
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----------------------------------------------
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First the uGuru must be in "ready" mode as described above, DATA should hold
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0x08 indicating that the uGuru wants input, in this case the bank address.
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Next write the bank address to DATA. After the bank address has been written
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wait for to DATA to hold 0x08 again indicating that it wants / is ready for
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more input (max 250 reads).
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Once DATA holds 0x08 again write the sensor address to CMD.
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Reading
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-------
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First send the bank and sensor addresses as described above.
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Then for each byte of data you want to read wait for DATA to hold 0x01
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which indicates that the uGuru is ready to be read (max 250 reads) and once
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DATA holds 0x01 read the byte from CMD.
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Once all bytes have been read data will hold 0x09, but there is no reason to
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test for this. Notice that the number of bytes is bank address dependent see
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above and below.
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After completing a successful read it is advised to put the uGuru back in
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ready mode, so that it is ready for the next read / write cycle. This way
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if your program / driver is unloaded and later loaded again the detection
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algorithm described above will still work.
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Writing
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-------
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First send the bank and sensor addresses as described above.
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Then for each byte of data you want to write wait for DATA to hold 0x00
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which indicates that the uGuru is ready to be written (max 250 reads) and
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once DATA holds 0x00 write the byte to CMD.
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Once all bytes have been written wait for DATA to hold 0x01 (max 250 reads)
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don't ask why this is the way it is.
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Once DATA holds 0x01 read CMD it should hold 0xAC now.
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After completing a successful write it is advised to put the uGuru back in
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ready mode, so that it is ready for the next read / write cycle. This way
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if your program / driver is unloaded and later loaded again the detection
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algorithm described above will still work.
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Gotchas
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-------
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After wider testing of the Linux kernel driver some variants of the uGuru have
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turned up which do not hold 0x08 at DATA within 250 reads after writing the
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bank address. With these versions this happens quite frequent, using larger
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timeouts doesn't help, they just go offline for a second or 2, doing some
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internal callibration or whatever. Your code should be prepared to handle
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this and in case of no response in this specific case just goto sleep for a
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while and then retry.
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Address Map
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===========
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Bank 0x20 Alarms (R)
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--------------------
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This bank contains 0 sensors, iow the sensor address is ignored (but must be
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written) just use 0. Bank 0x20 contains 3 bytes:
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Byte 0:
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This byte holds the alarm flags for sensor 0-7 of Sensor Bank1, with bit 0
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corresponding to sensor 0, 1 to 1, etc.
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Byte 1:
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This byte holds the alarm flags for sensor 8-15 of Sensor Bank1, with bit 0
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corresponding to sensor 8, 1 to 9, etc.
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Byte 2:
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This byte holds the alarm flags for sensor 0-5 of Sensor Bank2, with bit 0
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corresponding to sensor 0, 1 to 1, etc.
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Bank 0x21 Sensor Bank1 Values / Readings (R)
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--------------------------------------------
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This bank contains 16 sensors, for each sensor it contains 1 byte.
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So far the following sensors are known to be available on all motherboards:
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Sensor 0 CPU temp
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Sensor 1 SYS temp
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Sensor 3 CPU core volt
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Sensor 4 DDR volt
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Sensor 10 DDR Vtt volt
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Sensor 15 PWM temp
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Byte 0:
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This byte holds the reading from the sensor. Sensors in Bank1 can be both
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volt and temp sensors, this is motherboard specific. The uGuru however does
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seem to know (be programmed with) what kindoff sensor is attached see Sensor
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Bank1 Settings description.
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Volt sensors use a linear scale, a reading 0 corresponds with 0 volt and a
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reading of 255 with 3494 mV. The sensors for higher voltages however are
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connected through a division circuit. The currently known division circuits
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in use result in ranges of: 0-4361mV, 0-6248mV or 0-14510mV. 3.3 volt sources
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use the 0-4361mV range, 5 volt the 0-6248mV and 12 volt the 0-14510mV .
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Temp sensors also use a linear scale, a reading of 0 corresponds with 0 degree
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Celsius and a reading of 255 with a reading of 255 degrees Celsius.
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Bank 0x22 Sensor Bank1 Settings (R)
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Bank 0x23 Sensor Bank1 Settings (W)
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-----------------------------------
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This bank contains 16 sensors, for each sensor it contains 3 bytes. Each
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set of 3 bytes contains the settings for the sensor with the same sensor
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address in Bank 0x21 .
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Byte 0:
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Alarm behaviour for the selected sensor. A 1 enables the described behaviour.
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Bit 0: Give an alarm if measured temp is over the warning threshold (RW) *
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Bit 1: Give an alarm if measured volt is over the max threshold (RW) **
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Bit 2: Give an alarm if measured volt is under the min threshold (RW) **
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Bit 3: Beep if alarm (RW)
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Bit 4: 1 if alarm cause measured temp is over the warning threshold (R)
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Bit 5: 1 if alarm cause measured volt is over the max threshold (R)
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Bit 6: 1 if alarm cause measured volt is under the min threshold (R)
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Bit 7: Volt sensor: Shutdown if alarm persist for more than 4 seconds (RW)
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Temp sensor: Shutdown if temp is over the shutdown threshold (RW)
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* This bit is only honored/used by the uGuru if a temp sensor is connected
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** This bit is only honored/used by the uGuru if a volt sensor is connected
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Note with some trickery this can be used to find out what kinda sensor is
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detected see the Linux kernel driver for an example with many comments on
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how todo this.
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Byte 1:
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Temp sensor: warning threshold (scale as bank 0x21)
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Volt sensor: min threshold (scale as bank 0x21)
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Byte 2:
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Temp sensor: shutdown threshold (scale as bank 0x21)
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Volt sensor: max threshold (scale as bank 0x21)
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Bank 0x24 PWM outputs for FAN's (R)
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Bank 0x25 PWM outputs for FAN's (W)
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-----------------------------------
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This bank contains 3 "sensors", for each sensor it contains 5 bytes.
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Sensor 0 usually controls the CPU fan
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Sensor 1 usually controls the NB (or chipset for single chip) fan
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Sensor 2 usually controls the System fan
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Byte 0:
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Flag 0x80 to enable control, Fan runs at 100% when disabled.
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low nibble (temp)sensor address at bank 0x21 used for control.
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Byte 1:
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0-255 = 0-12v (linear), specify voltage at which fan will rotate when under
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low threshold temp (specified in byte 3)
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Byte 2:
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0-255 = 0-12v (linear), specify voltage at which fan will rotate when above
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high threshold temp (specified in byte 4)
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Byte 3:
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Low threshold temp (scale as bank 0x21)
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byte 4:
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High threshold temp (scale as bank 0x21)
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Bank 0x26 Sensors Bank2 Values / Readings (R)
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---------------------------------------------
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This bank contains 6 sensors (AFAIK), for each sensor it contains 1 byte.
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So far the following sensors are known to be available on all motherboards:
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Sensor 0: CPU fan speed
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Sensor 1: NB (or chipset for single chip) fan speed
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Sensor 2: SYS fan speed
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Byte 0:
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This byte holds the reading from the sensor. 0-255 = 0-15300 (linear)
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Bank 0x27 Sensors Bank2 Settings (R)
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Bank 0x28 Sensors Bank2 Settings (W)
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------------------------------------
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This bank contains 6 sensors (AFAIK), for each sensor it contains 2 bytes.
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Byte 0:
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Alarm behaviour for the selected sensor. A 1 enables the described behaviour.
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Bit 0: Give an alarm if measured rpm is under the min threshold (RW)
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Bit 3: Beep if alarm (RW)
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Bit 7: Shutdown if alarm persist for more than 4 seconds (RW)
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Byte 1:
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min threshold (scale as bank 0x26)
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Warning for the adventurous
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===========================
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A word of caution to those who want to experiment and see if they can figure
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the voltage / clock programming out, I tried reading and only reading banks
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0-0x30 with the reading code used for the sensor banks (0x20-0x28) and this
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resulted in a _permanent_ reprogramming of the voltages, luckily I had the
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sensors part configured so that it would shutdown my system on any out of spec
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voltages which proprably safed my computer (after a reboot I managed to
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immediately enter the bios and reload the defaults). This probably means that
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the read/write cycle for the non sensor part is different from the sensor part.
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