Difference between revisions of "Code/tp-fancontrol"
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#!/bin/bash | #!/bin/bash | ||
− | # tp-fancontrol 0. | + | # tp-fancontrol 0.3.02 (http://thinkwiki.org/wiki/ACPI_fan_control_script) |
# Provided under the GNU General Public License version 2 or later or | # Provided under the GNU General Public License version 2 or later or | ||
# the GNU Free Documentation License version 1.2 or later, at your option. | # the GNU Free Documentation License version 1.2 or later, at your option. | ||
Line 30: | Line 30: | ||
# max temperature: when to step up to maximum fan level) | # max temperature: when to step up to maximum fan level) | ||
THRESHOLDS=( # Sensor ThinkPad model | THRESHOLDS=( # Sensor ThinkPad model | ||
− | # R51 T41/2 Z60t | + | # R51 T41/2 Z60t T43-26xx |
# min max # ---------- ------- ----- ----- --------------------------- | # min max # ---------- ------- ----- ----- --------------------------- | ||
50 70 # EC 0x78 CPU CPU ? CPU | 50 70 # EC 0x78 CPU CPU ? CPU | ||
Line 37: | Line 37: | ||
49 68 # EC 0x7B GPU GPU ? GPU | 49 68 # EC 0x7B GPU GPU ? GPU | ||
40 50 # EC 0x7C BAT BAT BAT Sys BAT (front left of battery) | 40 50 # EC 0x7C BAT BAT BAT Sys BAT (front left of battery) | ||
− | + | 40 50 # EC 0x7D n/a n/a n/a UltraBay BAT | |
37 47 # EC 0x7E BAT BAT BAT Sys BAT (rear right of battery) | 37 47 # EC 0x7E BAT BAT BAT Sys BAT (rear right of battery) | ||
− | + | 37 47 # EC 0x7F n/a n/a n/a UltraBay BAT | |
+ | |||
45 60 # EC 0xC0 ? n/a ? Between northbridge and DRAM | 45 60 # EC 0xC0 ? n/a ? Between northbridge and DRAM | ||
48 62 # EC 0xC1 ? n/a ? Southbridge (under miniPCI) | 48 62 # EC 0xC1 ? n/a ? Southbridge (under miniPCI) | ||
50 65 # EC 0xC2 ? n/a ? Power circuitry (under CDC) | 50 65 # EC 0xC2 ? n/a ? Power circuitry (under CDC) | ||
− | 47 | + | |
+ | 47 58 # HDD -> -> -> Hard disk internal sensor | ||
+ | 47 60 # HDAPS -> -> -> HDAPS readout (same as EC 0x79) | ||
) | ) | ||
Line 53: | Line 56: | ||
OFF_THRESH_DELTA=3 # when gets this much cooler than 'min' above, may turn off fan | OFF_THRESH_DELTA=3 # when gets this much cooler than 'min' above, may turn off fan | ||
MIN_THRESH_SHIFT=0 # increase min thresholds by this much | MIN_THRESH_SHIFT=0 # increase min thresholds by this much | ||
+ | MAX_THRESH_SHIFT=0 # increase max thresholds by this much | ||
MIN_WAIT=180 # minimum time (seconds) to spend in a given level before stepping down | MIN_WAIT=180 # minimum time (seconds) to spend in a given level before stepping down | ||
IBM_ACPI=/proc/acpi/ibm | IBM_ACPI=/proc/acpi/ibm | ||
HDAPS_TEMP=/sys/bus/platform/drivers/hdaps/hdaps/temp1 | HDAPS_TEMP=/sys/bus/platform/drivers/hdaps/hdaps/temp1 | ||
− | LOGGER=/usr/bin/logger | + | PID_FILE=/var/run/tp-fancontrol.pid |
+ | LOGGER=/usr/bin/logger | ||
INTERVAL=3 # sample+refresh interval | INTERVAL=3 # sample+refresh interval | ||
SETTLE_TIME=6 # wait this many seconds long before applying anti-pulsing | SETTLE_TIME=6 # wait this many seconds long before applying anti-pulsing | ||
RESETTLE_TIME=600 # briefly disable anti-pulsing at every N seconds | RESETTLE_TIME=600 # briefly disable anti-pulsing at every N seconds | ||
SUSPEND_TIME=5 # seconds to sleep when receiving SIGUSR1 | SUSPEND_TIME=5 # seconds to sleep when receiving SIGUSR1 | ||
+ | DISK_POLL_PERIOD=15 # poll period in seconds for disk sensors (it changes slowly and is expensive to read) | ||
+ | HITACHI_MODELS="^(HTS4212..H9AT00|HTS726060M9AT00|HTS5410..G9AT00|IC25[NT]0..ATCS0[45]|HTE541040G9AT00|HTS5416..J9(AT|SA)00)" | ||
+ | SEP=',' # Separator char for display | ||
+ | |||
+ | WATCHDOG_DELAY=$(( 3 * INTERVAL )) | ||
+ | HAVE_WATCHDOG=`grep -q watchdog $IBM_ACPI/fan && echo true || echo false` | ||
+ | HAVE_LEVELCMD=`grep -q disengaged $IBM_ACPI/fan && echo true || echo false` | ||
− | |||
QUIET=false | QUIET=false | ||
DRY_RUN=false | DRY_RUN=false | ||
Line 71: | Line 82: | ||
SUSPEND_DAEMON=false | SUSPEND_DAEMON=false | ||
SYSLOG=false | SYSLOG=false | ||
+ | DISK_POLL_TIME=-$DISK_POLL_PERIOD | ||
usage() { | usage() { | ||
Line 77: | Line 89: | ||
Available options: | Available options: | ||
− | -s N | + | -s N Shift up the min temperature thresholds by N degrees |
− | (positive for quieter, negative for cooler) | + | (positive for quieter, negative for cooler). |
− | -t | + | Max temperature thresholds are not affected. |
− | -q | + | -S N Shift up the max temperature thresholds by N degrees |
− | -d | + | (positive for quieter, negative for cooler). DANGEROUS. |
− | -l | + | -t Test mode |
− | -k | + | -q Quiet mode |
− | -u | + | -d Daemon mode, go into background (implies -q) |
− | -p | + | -l Log to syslog |
+ | -k Kill already-running daemon | ||
+ | -u Tell already-running daemon that the system is being suspended | ||
+ | -p Pid file location for daemon mode, default: $PID_FILE | ||
" | " | ||
exit 1; | exit 1; | ||
} | } | ||
− | while getopts 's:qtdlp:kuh' OPT; do | + | while getopts 's:S:qtdlp:kuh' OPT; do |
case "$OPT" in | case "$OPT" in | ||
s) # shift thresholds | s) # shift thresholds | ||
MIN_THRESH_SHIFT="$OPTARG" | MIN_THRESH_SHIFT="$OPTARG" | ||
+ | ;; | ||
+ | S) # shift thresholds | ||
+ | MAX_THRESH_SHIFT="$OPTARG" | ||
;; | ;; | ||
t) # test mode | t) # test mode | ||
Line 134: | Line 152: | ||
DAEMONIZE=false | DAEMONIZE=false | ||
fi | fi | ||
+ | |||
+ | # Read the temperature sensor on new Hitachi drivers without spinning up the | ||
+ | # disk or unloading its head (this cannot be done using standard SMART). | ||
+ | # Works only with drivers/ide or new libata. Equivalent to hdparm -H in >=6.7. | ||
+ | read_hitachi_temp() { perl - "$@" <<'EOPERL' # do it in Perl | ||
+ | #!/usr/bin/perl | ||
+ | $dev="$ARGV[0]" or die "No device given.\n"; | ||
+ | $HDIO_DRIVE_CMD=0x031f; | ||
+ | $args=pack("cccc",0xf0,0,0x01,0); # Sense Condition command | ||
+ | open(DEV,"<",$dev) or die "open(\"$dev\"): $!\n"; | ||
+ | if (ioctl(DEV,$HDIO_DRIVE_CMD,$args)) { | ||
+ | $nsect=(unpack("cccc",$args))[2]; | ||
+ | if ($nsect==0 || $nsect==0xff) { | ||
+ | die "Temperature over/underflow.\n"; | ||
+ | } elsif ($nsect==0x01) { # Linux<=2.6.18 doesn't return ATA registers | ||
+ | die "Old Linux kernel, readout not supported.\n"; | ||
+ | } else { | ||
+ | printf "%d\n", $nsect/2-20; | ||
+ | } | ||
+ | } else { | ||
+ | die "ioctl(\"$dev\",HDIO_DRIVE_CMD,SENSE_CONDITION): $!\n" | ||
+ | } | ||
+ | EOPERL | ||
+ | } | ||
+ | |||
+ | update_disk_temp() { | ||
+ | if (( SECONDS >= DISK_POLL_TIME + DISK_POLL_PERIOD )); then | ||
+ | LAST_DISK_TEMP="-128" | ||
+ | for DEV in {sda,hda}; do | ||
+ | if [[ -b "/dev/$DEV" ]]; then | ||
+ | local MODEL=`cat /sys/block/$DEV/device/model` | ||
+ | if [[ "$MODEL" =~ "$HITACHI_MODELS" ]]; then | ||
+ | if HTEMP=`read_hitachi_temp "/dev/$DEV" 2>/dev/null`; then | ||
+ | LAST_DISK_TEMP="$HTEMP" | ||
+ | break | ||
+ | fi | ||
+ | fi | ||
+ | fi | ||
+ | done | ||
+ | DISK_POLL_TIME=$SECONDS | ||
+ | fi | ||
+ | } | ||
thermometer() { # output list of temperatures | thermometer() { # output list of temperatures | ||
− | # | + | # 8 basic temperatures from ibm-acpi: |
− | [ -r $IBM_ACPI/thermal ] || { echo "$0: Cannot read $IBM_ACPI/thermal" 2>&1 ; exit 1; } | + | [[ -r $IBM_ACPI/thermal ]] || { echo "$0: Cannot read $IBM_ACPI/thermal" 2>&1 ; exit 1; } |
− | read | + | read THERMAL < $IBM_ACPI/thermal |
− | + | read X Y1 Y2 Y3 Y4 Y5 Y6 Y7 Y8 Z1 Z2 Z3 JNK < <(echo "$THERMAL") | |
− | [ "$X" == "temperatures:" ] || { echo "$0: Bad | + | [[ "$X" == "temperatures:" ]] || { echo "$0: Bad readout: \"$THERMAL\"" >&2; exit 1; } |
− | echo -n "$ | + | echo -n "$Y1 $Y2 $Y3 $Y4 $Y5 $Y6 $Y7 $Y8 "; |
− | if [[ "$ | + | # 3 extra temperatures from ibm_acpi: |
− | echo -n "$ | + | if [[ -n "$Z1" && -n "$Z2" && -n "$Z3" ]]; then |
+ | # ibm_acpi provided extra sensors from at EC offsets 0xC0 to 0xC2? | ||
+ | echo -n "$SEP $Z1 $Z2 $Z3 " | ||
else | else | ||
[ -r $IBM_ACPI/ecdump ] || { echo "$0: Cannot read $IBM_ACPI/ecdump" 2>&1; exit 1; } | [ -r $IBM_ACPI/ecdump ] || { echo "$0: Cannot read $IBM_ACPI/ecdump" 2>&1; exit 1; } | ||
perl -e 'm/^EC 0xc0: .(..) .(..) .(..) / and print hex($1)." ".hex($2)." ".hex($3)." " and exit 0 while <>; exit 1' < $IBM_ACPI/ecdump | perl -e 'm/^EC 0xc0: .(..) .(..) .(..) / and print hex($1)." ".hex($2)." ".hex($3)." " and exit 0 while <>; exit 1' < $IBM_ACPI/ecdump | ||
fi | fi | ||
− | # HDAPS temperature (optional): | + | # 1 Disk drive temperatures: |
+ | echo -n "$SEP $LAST_DISK_TEMP " | ||
+ | # 1 HDAPS temperature (optional): | ||
if [ -r $HDAPS_TEMP ]; then | if [ -r $HDAPS_TEMP ]; then | ||
Y="`cat $HDAPS_TEMP`" | Y="`cat $HDAPS_TEMP`" | ||
Line 161: | Line 225: | ||
setlevel() { # set fan speed level | setlevel() { # set fan speed level | ||
− | $DRY_RUN | + | local LEVEL=$1 |
+ | if ! $DRY_RUN; then | ||
+ | if $HAVE_LEVELCMD; then | ||
+ | echo "level $LEVEL" > $IBM_ACPI/fan | ||
+ | else | ||
+ | case "$LEVEL" in | ||
+ | (auto) LEVEL=0x80 ;; | ||
+ | (disengaged) LEVEL=0x40 ;; | ||
+ | esac | ||
+ | echo 0x2F $LEVEL > $IBM_ACPI/ecdump | ||
+ | fi | ||
+ | fi | ||
} | } | ||
Line 176: | Line 251: | ||
$AM_DAEMON && rm -f "$PID_FILE" 2> /dev/null | $AM_DAEMON && rm -f "$PID_FILE" 2> /dev/null | ||
log "Shutting down, switching to automatic fan control" | log "Shutting down, switching to automatic fan control" | ||
− | $DRY_RUN | + | if ! $DRY_RUN; then |
+ | if $HAVE_LEVELCMD; then | ||
+ | echo enable > $IBM_ACPI/fan | ||
+ | else | ||
+ | echo 0x2F 0x80 > $IBM_ACPI/ecdump | ||
+ | fi | ||
+ | if $HAVE_WATCHDOG; then | ||
+ | echo watchdog 0 > $IBM_ACPI/fan # disable watchdog | ||
+ | fi | ||
+ | fi | ||
} | } | ||
Line 204: | Line 288: | ||
trap "cleanup" EXIT | trap "cleanup" EXIT | ||
trap "log 'Got SIGUSR1'; setlevel 0; RESTART=true; sleep $SUSPEND_TIME" USR1 | trap "log 'Got SIGUSR1'; setlevel 0; RESTART=true; sleep $SUSPEND_TIME" USR1 | ||
+ | if ! $DRY_RUN && $HAVE_WATCHDOG; then | ||
+ | log "Activating watchdog with delay $WATCHDOG_DELAY sec" | ||
+ | echo "watchdog $WATCHDOG_DELAY" > $IBM_ACPI/fan | ||
+ | fi | ||
init_state | init_state | ||
Line 210: | Line 298: | ||
# Control loop: | # Control loop: | ||
while true; do | while true; do | ||
+ | # Get readouts | ||
+ | update_disk_temp # don't do this in a subshell, it's stateful | ||
TEMPS=`thermometer` | TEMPS=`thermometer` | ||
$QUIET || SPEED=`speedometer` | $QUIET || SPEED=`speedometer` | ||
$QUIET || ECLEVEL=`getlevel` | $QUIET || ECLEVEL=`getlevel` | ||
NOW=`date +%s` | NOW=`date +%s` | ||
+ | if echo "$TEMPS" | grep -q "[^ 0-9$SEP\n-]"; then | ||
+ | echo "Invalid character in temperatures: $TEMPS" >&2; exit 1; | ||
+ | fi | ||
− | # Calculate new level index by placing temperatures into Z | + | # Calculate new level index by placing temperatures into regions of "Z" values: |
# Z >= 2*I means "must be at index I or higher" | # Z >= 2*I means "must be at index I or higher" | ||
# Z = 2*I+1 is hysteresis: "don't step down if currently at I+1" | # Z = 2*I+1 is hysteresis: "don't step down if currently at I+1" | ||
− | # | + | # The set of temperatures for each Z value are as follows, denoting d=(MAX-MIN)/(2*(MAX_IDX-1)) : |
− | # Z=0:{-infty..MIN- | + | # Z=0: {-infty..MIN-OFF_THRESH_DELTA) Z=1: {MIN-OFF_THRESH_DELTA..MIN} |
+ | # Z=2: {MIN..MIN+d} Z=3: {MIN+d..MIN+2d} | ||
+ | # Z=4: {MIN+2d..MIN+3d} Z=5: {MIN+3d..MIN+4d} ... | ||
+ | # Z=2*MAX_IDX: {MAX..infty} | ||
+ | # Enforce minimum time in this level before stepping down: | ||
MAX_Z=$(( IDX>0 ? ( NOW>START_TIME+MIN_WAIT ? 2*(IDX-1) : 2*IDX ) : 0 )) | MAX_Z=$(( IDX>0 ? ( NOW>START_TIME+MIN_WAIT ? 2*(IDX-1) : 2*IDX ) : 0 )) | ||
+ | |||
+ | # Go over all sensors and compute the Z value; compute the maximum Z and a pretty-printed string: | ||
SENSOR=0 | SENSOR=0 | ||
Z_STR="$MAX_Z+" | Z_STR="$MAX_Z+" | ||
TEMP_STR=""; | TEMP_STR=""; | ||
for TEMP in $TEMPS; do | for TEMP in $TEMPS; do | ||
+ | if [[ "$TEMP" == "$SEP" ]]; then # ignore this (a separator for visual aid) | ||
+ | Z_STR="${Z_STR}$SEP" | ||
+ | TEMP_STR="${TEMP_STR}$SEP " | ||
+ | continue | ||
+ | fi | ||
[ $((2*SENSOR+2)) -le ${#THRESHOLDS[@]} ] || | [ $((2*SENSOR+2)) -le ${#THRESHOLDS[@]} ] || | ||
{ echo "Too many sensors, not enough values in THRESHOLDS" 2>&1; exit 1; } | { echo "Too many sensors, not enough values in THRESHOLDS" 2>&1; exit 1; } | ||
Line 231: | Line 335: | ||
Z='_'; TEMP='_' # inactive sensor | Z='_'; TEMP='_' # inactive sensor | ||
else | else | ||
− | MIN=$((THRESHOLDS[SENSOR*2] + MIN_THRESH_SHIFT)) | + | MIN=$((THRESHOLDS[SENSOR*2] + MIN_THRESH_SHIFT)) |
− | MAX=$((THRESHOLDS[SENSOR*2+1])) | + | MAX=$((THRESHOLDS[SENSOR*2+1] + MAX_THRESH_SHIFT )) |
+ | [[ $MAX -le $MIN ]] && \ | ||
+ | { echo 'Reversed temperature thresholds (shifted too much?)' 2>&1; exit 1; } | ||
if (( TEMP < MIN - OFF_THRESH_DELTA )); then | if (( TEMP < MIN - OFF_THRESH_DELTA )); then | ||
Z=0 | Z=0 | ||
− | else | + | else # compute Z value for this sensor (see above): |
− | Z=$(( `floor_div $(( (TEMP-MIN)*( | + | Z=$(( `floor_div $(( 2*(TEMP-MIN)*(MAX_IDX-1) )) $((MAX-MIN))` + 2 )) |
+ | [ $Z -ge 1 ] || Z=1 | ||
+ | [ $Z -le $((2*MAX_IDX)) ] || Z=$((2*MAX_IDX)) | ||
fi | fi | ||
[ $MAX_Z -gt $Z ] || MAX_Z=$Z | [ $MAX_Z -gt $Z ] || MAX_Z=$Z | ||
Line 246: | Line 354: | ||
[ $SENSOR -gt 0 ] || { echo "No temperatures read" >&2; exit 1; } | [ $SENSOR -gt 0 ] || { echo "No temperatures read" >&2; exit 1; } | ||
− | (( (MAX_Z == 2*IDX-1) && ++MAX_Z )) # hysteresis | + | HYS=$(( (MAX_Z == 2*IDX-1) && ++MAX_Z )) # hysteresis |
NEW_IDX=$(( MAX_Z/2 )) | NEW_IDX=$(( MAX_Z/2 )) | ||
− | |||
− | + | # Interrupted by a signal? | |
− | + | if $RESTART; then | |
− | + | init_state | |
− | + | log "Resetting state" | |
− | + | continue | |
− | + | fi | |
# Transition | # Transition | ||
Line 279: | Line 386: | ||
SETTLE_LEFT=$((SETTLE_LEFT-INTERVAL)) | SETTLE_LEFT=$((SETTLE_LEFT-INTERVAL)) | ||
else | else | ||
− | setlevel | + | setlevel disengaged # disengage briefly to fool embedded controller |
sleep 0.5 | sleep 0.5 | ||
RESETTLE_LEFT=$((RESETTLE_LEFT-INTERVAL)) | RESETTLE_LEFT=$((RESETTLE_LEFT-INTERVAL)) |
Latest revision as of 15:50, 7 June 2011
- !/bin/bash
- tp-fancontrol 0.3.02 (http://thinkwiki.org/wiki/ACPI_fan_control_script)
- Provided under the GNU General Public License version 2 or later or
- the GNU Free Documentation License version 1.2 or later, at your option.
- See http://www.gnu.org/copyleft/gpl.html for the Warranty Disclaimer.
- This script dynamically controls fan speed on some ThinkPad models
- according to user-defined temperature thresholds. It implements its
- own decision algorithm, overriding the ThinkPad embedded
- controller. It also implements a workaround for the fan noise pulse
- experienced every few seconds on some ThinkPads.
- Run 'tp-fancontrol --help' for options.
- For optimal fan behavior during suspend and resume, invoke
- "tp-fancontrol -u" during the suspend process.
- WARNING: This script relies on undocumented hardware features and
- overrides nominal hardware behavior. It may thus cause arbitrary
- damage to your laptop or data. Watch your temperatures!
- WARNING: The list of temperature ranges used below is much more liberal
- than the rules used by the embedded controller firmware, and is
- derived mostly from anecdotal evidence, hunches and wishful thinking.
- It is also model-specific (see http://thinkwiki.org/wiki/Thermal_sensors).
- Temperature ranges, per sensor:
- (min temperature: when to step up from 0-th fan level,
- max temperature: when to step up to maximum fan level)
THRESHOLDS=( # Sensor ThinkPad model
# R51 T41/2 Z60t T43-26xx
- min max # ---------- ------- ----- ----- ---------------------------
50 70 # EC 0x78 CPU CPU ? CPU 47 60 # EC 0x79 miniPCI ? ? Between CPU and PCMCIA slot 43 55 # EC 0x7A HDD ? ? PCMCIA slot 49 68 # EC 0x7B GPU GPU ? GPU 40 50 # EC 0x7C BAT BAT BAT Sys BAT (front left of battery) 40 50 # EC 0x7D n/a n/a n/a UltraBay BAT 37 47 # EC 0x7E BAT BAT BAT Sys BAT (rear right of battery) 37 47 # EC 0x7F n/a n/a n/a UltraBay BAT
45 60 # EC 0xC0 ? n/a ? Between northbridge and DRAM 48 62 # EC 0xC1 ? n/a ? Southbridge (under miniPCI) 50 65 # EC 0xC2 ? n/a ? Power circuitry (under CDC)
47 58 # HDD -> -> -> Hard disk internal sensor 47 60 # HDAPS -> -> -> HDAPS readout (same as EC 0x79)
)
LEVELS=( 0 2 4 7) # Fan speed levels
ANTIPULSE=( 0 1 1 0) # Prevent fan pulsing noise at this level
# (reduces frequency of fan RPM updates)
OFF_THRESH_DELTA=3 # when gets this much cooler than 'min' above, may turn off fan MIN_THRESH_SHIFT=0 # increase min thresholds by this much MAX_THRESH_SHIFT=0 # increase max thresholds by this much MIN_WAIT=180 # minimum time (seconds) to spend in a given level before stepping down
IBM_ACPI=/proc/acpi/ibm HDAPS_TEMP=/sys/bus/platform/drivers/hdaps/hdaps/temp1 PID_FILE=/var/run/tp-fancontrol.pid LOGGER=/usr/bin/logger INTERVAL=3 # sample+refresh interval SETTLE_TIME=6 # wait this many seconds long before applying anti-pulsing RESETTLE_TIME=600 # briefly disable anti-pulsing at every N seconds SUSPEND_TIME=5 # seconds to sleep when receiving SIGUSR1 DISK_POLL_PERIOD=15 # poll period in seconds for disk sensors (it changes slowly and is expensive to read) HITACHI_MODELS="^(HTS4212..H9AT00|HTS726060M9AT00|HTS5410..G9AT00|IC25[NT]0..ATCS0[45]|HTE541040G9AT00|HTS5416..J9(AT|SA)00)" SEP=',' # Separator char for display
WATCHDOG_DELAY=$(( 3 * INTERVAL )) HAVE_WATCHDOG=`grep -q watchdog $IBM_ACPI/fan && echo true || echo false` HAVE_LEVELCMD=`grep -q disengaged $IBM_ACPI/fan && echo true || echo false`
QUIET=false DRY_RUN=false DAEMONIZE=false AM_DAEMON=false KILL_DAEMON=false SUSPEND_DAEMON=false SYSLOG=false DISK_POLL_TIME=-$DISK_POLL_PERIOD
usage() {
echo "
Usage: $0 [OPTION]...
Available options:
-s N Shift up the min temperature thresholds by N degrees (positive for quieter, negative for cooler). Max temperature thresholds are not affected. -S N Shift up the max temperature thresholds by N degrees (positive for quieter, negative for cooler). DANGEROUS. -t Test mode -q Quiet mode -d Daemon mode, go into background (implies -q) -l Log to syslog -k Kill already-running daemon -u Tell already-running daemon that the system is being suspended -p Pid file location for daemon mode, default: $PID_FILE
"
exit 1;
}
while getopts 's:S:qtdlp:kuh' OPT; do
case "$OPT" in s) # shift thresholds MIN_THRESH_SHIFT="$OPTARG" ;; S) # shift thresholds MAX_THRESH_SHIFT="$OPTARG" ;; t) # test mode DRY_RUN=true ;; q) # quiet mode QUIET=true ;; d) # go into background and daemonize DAEMONIZE=true ;; l) # log to syslog SYSLOG=true ;; p) # different pidfile PID_FILE="$OPTARG" ;; k) # kill daemon KILL_DAEMON=true ;; u) # suspend daemon SUSPEND_DAEMON=true ;; h) # short help usage ;; \?) # error usage ;; esac
done [ $OPTIND -gt $# ] || usage # no non-option args
- no logger found, no syslog capabilities
$SYSLOG && [ ! -x $LOGGER ] && SYSLOG=false || :
if $DRY_RUN; then
echo "$0: Dry run, will not change fan state." QUIET=false DAEMONIZE=false
fi
- Read the temperature sensor on new Hitachi drivers without spinning up the
- disk or unloading its head (this cannot be done using standard SMART).
- Works only with drivers/ide or new libata. Equivalent to hdparm -H in >=6.7.
read_hitachi_temp() { perl - "$@" <<'EOPERL' # do it in Perl
#!/usr/bin/perl $dev="$ARGV[0]" or die "No device given.\n"; $HDIO_DRIVE_CMD=0x031f; $args=pack("cccc",0xf0,0,0x01,0); # Sense Condition command open(DEV,"<",$dev) or die "open(\"$dev\"): $!\n"; if (ioctl(DEV,$HDIO_DRIVE_CMD,$args)) { $nsect=(unpack("cccc",$args))[2]; if ($nsect==0 || $nsect==0xff) { die "Temperature over/underflow.\n"; } elsif ($nsect==0x01) { # Linux<=2.6.18 doesn't return ATA registers die "Old Linux kernel, readout not supported.\n"; } else { printf "%d\n", $nsect/2-20; } } else { die "ioctl(\"$dev\",HDIO_DRIVE_CMD,SENSE_CONDITION): $!\n" }
EOPERL }
update_disk_temp() {
if (( SECONDS >= DISK_POLL_TIME + DISK_POLL_PERIOD )); then LAST_DISK_TEMP="-128" for DEV in {sda,hda}; do if -b "/dev/$DEV" ; then local MODEL=`cat /sys/block/$DEV/device/model` if "$MODEL" =~ "$HITACHI_MODELS" ; then if HTEMP=`read_hitachi_temp "/dev/$DEV" 2>/dev/null`; then LAST_DISK_TEMP="$HTEMP" break fi fi fi done DISK_POLL_TIME=$SECONDS fi
}
thermometer() { # output list of temperatures
# 8 basic temperatures from ibm-acpi: -r $IBM_ACPI/thermal || { echo "$0: Cannot read $IBM_ACPI/thermal" 2>&1 ; exit 1; } read THERMAL < $IBM_ACPI/thermal read X Y1 Y2 Y3 Y4 Y5 Y6 Y7 Y8 Z1 Z2 Z3 JNK < <(echo "$THERMAL") "$X" == "temperatures:" || { echo "$0: Bad readout: \"$THERMAL\"" >&2; exit 1; } echo -n "$Y1 $Y2 $Y3 $Y4 $Y5 $Y6 $Y7 $Y8 "; # 3 extra temperatures from ibm_acpi: if -n "$Z1" && -n "$Z2" && -n "$Z3" ; then # ibm_acpi provided extra sensors from at EC offsets 0xC0 to 0xC2? echo -n "$SEP $Z1 $Z2 $Z3 " else [ -r $IBM_ACPI/ecdump ] || { echo "$0: Cannot read $IBM_ACPI/ecdump" 2>&1; exit 1; } perl -e 'm/^EC 0xc0: .(..) .(..) .(..) / and print hex($1)." ".hex($2)." ".hex($3)." " and exit 0 while <>; exit 1' < $IBM_ACPI/ecdump fi # 1 Disk drive temperatures: echo -n "$SEP $LAST_DISK_TEMP " # 1 HDAPS temperature (optional): if [ -r $HDAPS_TEMP ]; then Y="`cat $HDAPS_TEMP`" (( "$Y" > 100 )) || echo -n "$Y " # the HDAPS readouts are nonsensical right after resume fi return 0
}
speedometer() { # output fan speed RPM
sed -n 's/^speed:[ \t]*//p' $IBM_ACPI/fan
}
setlevel() { # set fan speed level
local LEVEL=$1 if ! $DRY_RUN; then if $HAVE_LEVELCMD; then echo "level $LEVEL" > $IBM_ACPI/fan
else case "$LEVEL" in (auto) LEVEL=0x80 ;; (disengaged) LEVEL=0x40 ;; esac
echo 0x2F $LEVEL > $IBM_ACPI/ecdump
fi
fi
}
getlevel() { # get fan speed level
perl -e 'm/^EC 0x20: .* .(..)$/ and print $1 and exit 0 while <>; exit 1' < $IBM_ACPI/ecdump
}
log() { $QUIET || echo "> $*" ! $SYSLOG || $LOGGER -t "`basename $0`[$$]" "$*" }
cleanup() { # clean up after work
$AM_DAEMON && rm -f "$PID_FILE" 2> /dev/null log "Shutting down, switching to automatic fan control" if ! $DRY_RUN; then if $HAVE_LEVELCMD; then echo enable > $IBM_ACPI/fan else echo 0x2F 0x80 > $IBM_ACPI/ecdump fi if $HAVE_WATCHDOG; then echo watchdog 0 > $IBM_ACPI/fan # disable watchdog fi fi
}
floor_div() {
echo $(( (($1)+1000*($2))/($2) - 1000 ))
}
set_priority() {
! $DRY_RUN && renice -10 -p $$
}
init_state() {
IDX=0 NEW_IDX=0 START_TIME=0 MAX_IDX=$(( ${#LEVELS[@]} - 1 )) SETTLE_LEFT=0 RESETTLE_LEFT=0 FIRST=true RESTART=false
}
control_fan() {
# Enable the fan in default mode if anything goes wrong: set -e -E -u trap "cleanup; exit 2" HUP INT ABRT QUIT SEGV TERM trap "cleanup" EXIT trap "log 'Got SIGUSR1'; setlevel 0; RESTART=true; sleep $SUSPEND_TIME" USR1 if ! $DRY_RUN && $HAVE_WATCHDOG; then log "Activating watchdog with delay $WATCHDOG_DELAY sec" echo "watchdog $WATCHDOG_DELAY" > $IBM_ACPI/fan fi
init_state log "Starting dynamic fan control"
# Control loop: while true; do # Get readouts update_disk_temp # don't do this in a subshell, it's stateful TEMPS=`thermometer` $QUIET || SPEED=`speedometer` $QUIET || ECLEVEL=`getlevel` NOW=`date +%s` if echo "$TEMPS" | grep -q "[^ 0-9$SEP\n-]"; then echo "Invalid character in temperatures: $TEMPS" >&2; exit 1; fi
# Calculate new level index by placing temperatures into regions of "Z" values: # Z >= 2*I means "must be at index I or higher" # Z = 2*I+1 is hysteresis: "don't step down if currently at I+1" # The set of temperatures for each Z value are as follows, denoting d=(MAX-MIN)/(2*(MAX_IDX-1)) : # Z=0: {-infty..MIN-OFF_THRESH_DELTA) Z=1: {MIN-OFF_THRESH_DELTA..MIN} # Z=2: {MIN..MIN+d} Z=3: {MIN+d..MIN+2d} # Z=4: {MIN+2d..MIN+3d} Z=5: {MIN+3d..MIN+4d} ... # Z=2*MAX_IDX: {MAX..infty}
# Enforce minimum time in this level before stepping down: MAX_Z=$(( IDX>0 ? ( NOW>START_TIME+MIN_WAIT ? 2*(IDX-1) : 2*IDX ) : 0 ))
# Go over all sensors and compute the Z value; compute the maximum Z and a pretty-printed string: SENSOR=0 Z_STR="$MAX_Z+" TEMP_STR=""; for TEMP in $TEMPS; do if "$TEMP" == "$SEP" ; then # ignore this (a separator for visual aid) Z_STR="${Z_STR}$SEP" TEMP_STR="${TEMP_STR}$SEP " continue fi [ $((2*SENSOR+2)) -le ${#THRESHOLDS[@]} ] || { echo "Too many sensors, not enough values in THRESHOLDS" 2>&1; exit 1; } if | $TEMP == 128 ; then Z='_'; TEMP='_' # inactive sensor else MIN=$((THRESHOLDS[SENSOR*2] + MIN_THRESH_SHIFT)) MAX=$((THRESHOLDS[SENSOR*2+1] + MAX_THRESH_SHIFT )) $MAX -le $MIN && \ { echo 'Reversed temperature thresholds (shifted too much?)' 2>&1; exit 1; } if (( TEMP < MIN - OFF_THRESH_DELTA )); then Z=0 else # compute Z value for this sensor (see above): Z=$(( `floor_div $(( 2*(TEMP-MIN)*(MAX_IDX-1) )) $((MAX-MIN))` + 2 )) [ $Z -ge 1 ] || Z=1 [ $Z -le $((2*MAX_IDX)) ] || Z=$((2*MAX_IDX)) fi [ $MAX_Z -gt $Z ] || MAX_Z=$Z fi Z_STR="${Z_STR}${Z}" TEMP_STR="${TEMP_STR}${TEMP} " (( ++SENSOR )) done [ $SENSOR -gt 0 ] || { echo "No temperatures read" >&2; exit 1; }
HYS=$(( (MAX_Z == 2*IDX-1) && ++MAX_Z )) # hysteresis NEW_IDX=$(( MAX_Z/2 ))
# Interrupted by a signal? if $RESTART; then init_state log "Resetting state" continue fi
# Transition $FIRST && OLDLEVEL='?' || OLDLEVEL=${LEVELS[$IDX]} NEWLEVEL=${LEVELS[$NEW_IDX]} $QUIET || echo "L=$OLDLEVEL->$NEWLEVEL EC=$ECLEVEL RPM=`printf %4s $SPEED` T=($TEMP_STR) Z=$Z_STR" if [ "$OLDLEVEL" != "$NEWLEVEL" ]; then START_TIME=$NOW log "Changing fan level: $OLDLEVEL->$NEWLEVEL (temps: $TEMP_STR)" fi
setlevel $NEWLEVEL
sleep $INTERVAL
# If needed, apply anti-pulsing hack after a settle-down period (and occasionally re-settle): if [ ${ANTIPULSE[${NEW_IDX}]} == 1 ]; then if [ $NEWLEVEL != $OLDLEVEL -o $RESETTLE_LEFT -le 0 ]; then # start settling? SETTLE_LEFT=$SETTLE_TIME RESETTLE_LEFT=$RESETTLE_TIME fi if [ $SETTLE_LEFT -ge 0 ]; then SETTLE_LEFT=$((SETTLE_LEFT-INTERVAL)) else setlevel disengaged # disengage briefly to fool embedded controller sleep 0.5 RESETTLE_LEFT=$((RESETTLE_LEFT-INTERVAL)) fi fi
IDX=$NEW_IDX FIRST=false done
}
if $KILL_DAEMON || $SUSPEND_DAEMON; then
if [ -f "$PID_FILE" ]; then
set -e DPID="`cat \"$PID_FILE\"`" if $KILL_DAEMON; then
kill "$DPID"
rm "$PID_FILE" $QUIET || echo "Killed process $DPID" else # SUSPEND_DAEMON kill -USR1 "$DPID" $QUIET || echo "Sent SIGUSR1 to $DPID" fi
else $QUIET || echo "Daemon not running." exit 1 fi
elif $DAEMONIZE ; then
if [ -e "$PID_FILE" ]; then echo "$0: File $PID_FILE already exists, refusing to run." exit 1 else set_priority AM_DAEMON=true QUIET=true control_fan 0<&- 1>&- 2>&- & echo $! > "$PID_FILE" exit 0 fi
else
[ -e "$PID_FILE" ] && echo "WARNING: daemon already running" set_priority control_fan
fi