lm93 13 KB

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  1. Kernel driver lm93
  2. ==================
  3. Supported chips:
  4. * National Semiconductor LM93
  5. Prefix 'lm93'
  6. Addresses scanned: I2C 0x2c-0x2e
  7. Datasheet: http://www.national.com/ds.cgi/LM/LM93.pdf
  8. * National Semiconductor LM94
  9. Prefix 'lm94'
  10. Addresses scanned: I2C 0x2c-0x2e
  11. Datasheet: http://www.national.com/ds.cgi/LM/LM94.pdf
  12. Authors:
  13. Mark M. Hoffman <mhoffman@lightlink.com>
  14. Ported to 2.6 by Eric J. Bowersox <ericb@aspsys.com>
  15. Adapted to 2.6.20 by Carsten Emde <ce@osadl.org>
  16. Modified for mainline integration by Hans J. Koch <hjk@hansjkoch.de>
  17. Module Parameters
  18. -----------------
  19. * init: integer
  20. Set to non-zero to force some initializations (default is 0).
  21. * disable_block: integer
  22. A "0" allows SMBus block data transactions if the host supports them. A "1"
  23. disables SMBus block data transactions. The default is 0.
  24. * vccp_limit_type: integer array (2)
  25. Configures in7 and in8 limit type, where 0 means absolute and non-zero
  26. means relative. "Relative" here refers to "Dynamic Vccp Monitoring using
  27. VID" from the datasheet. It greatly simplifies the interface to allow
  28. only one set of limits (absolute or relative) to be in operation at a
  29. time (even though the hardware is capable of enabling both). There's
  30. not a compelling use case for enabling both at once, anyway. The default
  31. is "0,0".
  32. * vid_agtl: integer
  33. A "0" configures the VID pins for V(ih) = 2.1V min, V(il) = 0.8V max.
  34. A "1" configures the VID pins for V(ih) = 0.8V min, V(il) = 0.4V max.
  35. (The latter setting is referred to as AGTL+ Compatible in the datasheet.)
  36. I.e. this parameter controls the VID pin input thresholds; if your VID
  37. inputs are not working, try changing this. The default value is "0".
  38. Hardware Description
  39. --------------------
  40. (from the datasheet)
  41. The LM93 hardware monitor has a two wire digital interface compatible with
  42. SMBus 2.0. Using an 8-bit ADC, the LM93 measures the temperature of two remote
  43. diode connected transistors as well as its own die and 16 power supply
  44. voltages. To set fan speed, the LM93 has two PWM outputs that are each
  45. controlled by up to four temperature zones. The fancontrol algorithm is lookup
  46. table based. The LM93 includes a digital filter that can be invoked to smooth
  47. temperature readings for better control of fan speed. The LM93 has four
  48. tachometer inputs to measure fan speed. Limit and status registers for all
  49. measured values are included. The LM93 builds upon the functionality of
  50. previous motherboard management ASICs and uses some of the LM85's features
  51. (i.e. smart tachometer mode). It also adds measurement and control support
  52. for dynamic Vccp monitoring and PROCHOT. It is designed to monitor a dual
  53. processor Xeon class motherboard with a minimum of external components.
  54. LM94 is also supported in LM93 compatible mode. Extra sensors and features of
  55. LM94 are not supported.
  56. User Interface
  57. --------------
  58. #PROCHOT:
  59. The LM93 can monitor two #PROCHOT signals. The results are found in the
  60. sysfs files prochot1, prochot2, prochot1_avg, prochot2_avg, prochot1_max,
  61. and prochot2_max. prochot1_max and prochot2_max contain the user limits
  62. for #PROCHOT1 and #PROCHOT2, respectively. prochot1 and prochot2 contain
  63. the current readings for the most recent complete time interval. The
  64. value of prochot1_avg and prochot2_avg is something like a 2 period
  65. exponential moving average (but not quite - check the datasheet). Note
  66. that this third value is calculated by the chip itself. All values range
  67. from 0-255 where 0 indicates no throttling, and 255 indicates > 99.6%.
  68. The monitoring intervals for the two #PROCHOT signals is also configurable.
  69. These intervals can be found in the sysfs files prochot1_interval and
  70. prochot2_interval. The values in these files specify the intervals for
  71. #P1_PROCHOT and #P2_PROCHOT, respectively. Selecting a value not in this
  72. list will cause the driver to use the next largest interval. The available
  73. intervals are (in seconds):
  74. #PROCHOT intervals: 0.73, 1.46, 2.9, 5.8, 11.7, 23.3, 46.6, 93.2, 186, 372
  75. It is possible to configure the LM93 to logically short the two #PROCHOT
  76. signals. I.e. when #P1_PROCHOT is asserted, the LM93 will automatically
  77. assert #P2_PROCHOT, and vice-versa. This mode is enabled by writing a
  78. non-zero integer to the sysfs file prochot_short.
  79. The LM93 can also override the #PROCHOT pins by driving a PWM signal onto
  80. one or both of them. When overridden, the signal has a period of 3.56 ms,
  81. a minimum pulse width of 5 clocks (at 22.5kHz => 6.25% duty cycle), and
  82. a maximum pulse width of 80 clocks (at 22.5kHz => 99.88% duty cycle).
  83. The sysfs files prochot1_override and prochot2_override contain boolean
  84. integers which enable or disable the override function for #P1_PROCHOT and
  85. #P2_PROCHOT, respectively. The sysfs file prochot_override_duty_cycle
  86. contains a value controlling the duty cycle for the PWM signal used when
  87. the override function is enabled. This value ranges from 0 to 15, with 0
  88. indicating minimum duty cycle and 15 indicating maximum.
  89. #VRD_HOT:
  90. The LM93 can monitor two #VRD_HOT signals. The results are found in the
  91. sysfs files vrdhot1 and vrdhot2. There is one value per file: a boolean for
  92. which 1 indicates #VRD_HOT is asserted and 0 indicates it is negated. These
  93. files are read-only.
  94. Smart Tach Mode:
  95. (from the datasheet)
  96. If a fan is driven using a low-side drive PWM, the tachometer
  97. output of the fan is corrupted. The LM93 includes smart tachometer
  98. circuitry that allows an accurate tachometer reading to be
  99. achieved despite the signal corruption. In smart tach mode all
  100. four signals are measured within 4 seconds.
  101. Smart tach mode is enabled by the driver by writing 1 or 2 (associating the
  102. the fan tachometer with a pwm) to the sysfs file fan<n>_smart_tach. A zero
  103. will disable the function for that fan. Note that Smart tach mode cannot be
  104. enabled if the PWM output frequency is 22500 Hz (see below).
  105. Manual PWM:
  106. The LM93 has a fixed or override mode for the two PWM outputs (although, there
  107. are still some conditions that will override even this mode - see section
  108. 15.10.6 of the datasheet for details.) The sysfs files pwm1_override
  109. and pwm2_override are used to enable this mode; each is a boolean integer
  110. where 0 disables and 1 enables the manual control mode. The sysfs files pwm1
  111. and pwm2 are used to set the manual duty cycle; each is an integer (0-255)
  112. where 0 is 0% duty cycle, and 255 is 100%. Note that the duty cycle values
  113. are constrained by the hardware. Selecting a value which is not available
  114. will cause the driver to use the next largest value. Also note: when manual
  115. PWM mode is disabled, the value of pwm1 and pwm2 indicates the current duty
  116. cycle chosen by the h/w.
  117. PWM Output Frequency:
  118. The LM93 supports several different frequencies for the PWM output channels.
  119. The sysfs files pwm1_freq and pwm2_freq are used to select the frequency. The
  120. frequency values are constrained by the hardware. Selecting a value which is
  121. not available will cause the driver to use the next largest value. Also note
  122. that this parameter has implications for the Smart Tach Mode (see above).
  123. PWM Output Frequencies (in Hz): 12, 36, 48, 60, 72, 84, 96, 22500 (default)
  124. Automatic PWM:
  125. The LM93 is capable of complex automatic fan control, with many different
  126. points of configuration. To start, each PWM output can be bound to any
  127. combination of eight control sources. The final PWM is the largest of all
  128. individual control sources to which the PWM output is bound.
  129. The eight control sources are: temp1-temp4 (aka "zones" in the datasheet),
  130. #PROCHOT 1 & 2, and #VRDHOT 1 & 2. The bindings are expressed as a bitmask
  131. in the sysfs files pwm<n>_auto_channels, where a "1" enables the binding, and
  132. a "0" disables it. The h/w default is 0x0f (all temperatures bound).
  133. 0x01 - Temp 1
  134. 0x02 - Temp 2
  135. 0x04 - Temp 3
  136. 0x08 - Temp 4
  137. 0x10 - #PROCHOT 1
  138. 0x20 - #PROCHOT 2
  139. 0x40 - #VRDHOT 1
  140. 0x80 - #VRDHOT 2
  141. The function y = f(x) takes a source temperature x to a PWM output y. This
  142. function of the LM93 is derived from a base temperature and a table of 12
  143. temperature offsets. The base temperature is expressed in degrees C in the
  144. sysfs files temp<n>_auto_base. The offsets are expressed in cumulative
  145. degrees C, with the value of offset <i> for temperature value <n> being
  146. contained in the file temp<n>_auto_offset<i>. E.g. if the base temperature
  147. is 40C:
  148. offset # temp<n>_auto_offset<i> range pwm
  149. 1 0 - 25.00%
  150. 2 0 - 28.57%
  151. 3 1 40C - 41C 32.14%
  152. 4 1 41C - 42C 35.71%
  153. 5 2 42C - 44C 39.29%
  154. 6 2 44C - 46C 42.86%
  155. 7 2 48C - 50C 46.43%
  156. 8 2 50C - 52C 50.00%
  157. 9 2 52C - 54C 53.57%
  158. 10 2 54C - 56C 57.14%
  159. 11 2 56C - 58C 71.43%
  160. 12 2 58C - 60C 85.71%
  161. > 60C 100.00%
  162. Valid offsets are in the range 0C <= x <= 7.5C in 0.5C increments.
  163. There is an independent base temperature for each temperature channel. Note,
  164. however, there are only two tables of offsets: one each for temp[12] and
  165. temp[34]. Therefore, any change to e.g. temp1_auto_offset<i> will also
  166. affect temp2_auto_offset<i>.
  167. The LM93 can also apply hysteresis to the offset table, to prevent unwanted
  168. oscillation between two steps in the offsets table. These values are found in
  169. the sysfs files temp<n>_auto_offset_hyst. The value in this file has the
  170. same representation as in temp<n>_auto_offset<i>.
  171. If a temperature reading falls below the base value for that channel, the LM93
  172. will use the minimum PWM value. These values are found in the sysfs files
  173. temp<n>_auto_pwm_min. Note, there are only two minimums: one each for temp[12]
  174. and temp[34]. Therefore, any change to e.g. temp1_auto_pwm_min will also
  175. affect temp2_auto_pwm_min.
  176. PWM Spin-Up Cycle:
  177. A spin-up cycle occurs when a PWM output is commanded from 0% duty cycle to
  178. some value > 0%. The LM93 supports a minimum duty cycle during spin-up. These
  179. values are found in the sysfs files pwm<n>_auto_spinup_min. The value in this
  180. file has the same representation as other PWM duty cycle values. The
  181. duration of the spin-up cycle is also configurable. These values are found in
  182. the sysfs files pwm<n>_auto_spinup_time. The value in this file is
  183. the spin-up time in seconds. The available spin-up times are constrained by
  184. the hardware. Selecting a value which is not available will cause the driver
  185. to use the next largest value.
  186. Spin-up Durations: 0 (disabled, h/w default), 0.1, 0.25, 0.4, 0.7, 1.0,
  187. 2.0, 4.0
  188. #PROCHOT and #VRDHOT PWM Ramping:
  189. If the #PROCHOT or #VRDHOT signals are asserted while bound to a PWM output
  190. channel, the LM93 will ramp the PWM output up to 100% duty cycle in discrete
  191. steps. The duration of each step is configurable. There are two files, with
  192. one value each in seconds: pwm_auto_prochot_ramp and pwm_auto_vrdhot_ramp.
  193. The available ramp times are constrained by the hardware. Selecting a value
  194. which is not available will cause the driver to use the next largest value.
  195. Ramp Times: 0 (disabled, h/w default) to 0.75 in 0.05 second intervals
  196. Fan Boost:
  197. For each temperature channel, there is a boost temperature: if the channel
  198. exceeds this limit, the LM93 will immediately drive both PWM outputs to 100%.
  199. This limit is expressed in degrees C in the sysfs files temp<n>_auto_boost.
  200. There is also a hysteresis temperature for this function: after the boost
  201. limit is reached, the temperature channel must drop below this value before
  202. the boost function is disabled. This temperature is also expressed in degrees
  203. C in the sysfs files temp<n>_auto_boost_hyst.
  204. GPIO Pins:
  205. The LM93 can monitor the logic level of four dedicated GPIO pins as well as the
  206. four tach input pins. GPIO0-GPIO3 correspond to (fan) tach 1-4, respectively.
  207. All eight GPIOs are read by reading the bitmask in the sysfs file gpio. The
  208. LSB is GPIO0, and the MSB is GPIO7.
  209. LM93 Unique sysfs Files
  210. -----------------------
  211. file description
  212. -------------------------------------------------------------
  213. prochot<n> current #PROCHOT %
  214. prochot<n>_avg moving average #PROCHOT %
  215. prochot<n>_max limit #PROCHOT %
  216. prochot_short enable or disable logical #PROCHOT pin short
  217. prochot<n>_override force #PROCHOT assertion as PWM
  218. prochot_override_duty_cycle
  219. duty cycle for the PWM signal used when
  220. #PROCHOT is overridden
  221. prochot<n>_interval #PROCHOT PWM sampling interval
  222. vrdhot<n> 0 means negated, 1 means asserted
  223. fan<n>_smart_tach enable or disable smart tach mode
  224. pwm<n>_auto_channels select control sources for PWM outputs
  225. pwm<n>_auto_spinup_min minimum duty cycle during spin-up
  226. pwm<n>_auto_spinup_time duration of spin-up
  227. pwm_auto_prochot_ramp ramp time per step when #PROCHOT asserted
  228. pwm_auto_vrdhot_ramp ramp time per step when #VRDHOT asserted
  229. temp<n>_auto_base temperature channel base
  230. temp<n>_auto_offset[1-12]
  231. temperature channel offsets
  232. temp<n>_auto_offset_hyst
  233. temperature channel offset hysteresis
  234. temp<n>_auto_boost temperature channel boost (PWMs to 100%) limit
  235. temp<n>_auto_boost_hyst temperature channel boost hysteresis
  236. gpio input state of 8 GPIO pins; read-only