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// SPDX-License-Identifier: GPL-2.0-only
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/*
* Windfarm PowerMac thermal control .
* Control loops for machines with SMU and PPC970MP processors .
*
* Copyright ( C ) 2005 Paul Mackerras , IBM Corp . < paulus @ samba . org >
* Copyright ( C ) 2006 Benjamin Herrenschmidt , IBM Corp .
*/
# include <linux/types.h>
# include <linux/errno.h>
# include <linux/kernel.h>
# include <linux/device.h>
# include <linux/platform_device.h>
# include <linux/reboot.h>
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# include <linux/of.h>
# include <linux/slab.h>
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# include <asm/smu.h>
# include "windfarm.h"
# include "windfarm_pid.h"
# define VERSION "0.2"
# define DEBUG
# undef LOTSA_DEBUG
# ifdef DEBUG
# define DBG(args...) printk(args)
# else
# define DBG(args...) do { } while(0)
# endif
# ifdef LOTSA_DEBUG
# define DBG_LOTS(args...) printk(args)
# else
# define DBG_LOTS(args...) do { } while(0)
# endif
/* define this to force CPU overtemp to 60 degree, useful for testing
* the overtemp code
*/
# undef HACKED_OVERTEMP
/* We currently only handle 2 chips, 4 cores... */
# define NR_CHIPS 2
# define NR_CORES 4
# define NR_CPU_FANS 3 * NR_CHIPS
/* Controls and sensors */
static struct wf_sensor * sens_cpu_temp [ NR_CORES ] ;
static struct wf_sensor * sens_cpu_power [ NR_CORES ] ;
static struct wf_sensor * hd_temp ;
static struct wf_sensor * slots_power ;
static struct wf_sensor * u4_temp ;
static struct wf_control * cpu_fans [ NR_CPU_FANS ] ;
static char * cpu_fan_names [ NR_CPU_FANS ] = {
" cpu-rear-fan-0 " ,
" cpu-rear-fan-1 " ,
" cpu-front-fan-0 " ,
" cpu-front-fan-1 " ,
" cpu-pump-0 " ,
" cpu-pump-1 " ,
} ;
static struct wf_control * cpufreq_clamp ;
/* Second pump isn't required (and isn't actually present) */
# define CPU_FANS_REQD (NR_CPU_FANS - 2)
# define FIRST_PUMP 4
# define LAST_PUMP 5
/* We keep a temperature history for average calculation of 180s */
# define CPU_TEMP_HIST_SIZE 180
/* Scale factor for fan speed, *100 */
static int cpu_fan_scale [ NR_CPU_FANS ] = {
100 ,
100 ,
97 , /* inlet fans run at 97% of exhaust fan */
97 ,
100 , /* updated later */
100 , /* updated later */
} ;
static struct wf_control * backside_fan ;
static struct wf_control * slots_fan ;
static struct wf_control * drive_bay_fan ;
/* PID loop state */
static struct wf_cpu_pid_state cpu_pid [ NR_CORES ] ;
static u32 cpu_thist [ CPU_TEMP_HIST_SIZE ] ;
static int cpu_thist_pt ;
static s64 cpu_thist_total ;
static s32 cpu_all_tmax = 100 < < 16 ;
static int cpu_last_target ;
static struct wf_pid_state backside_pid ;
static int backside_tick ;
static struct wf_pid_state slots_pid ;
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static bool slots_started ;
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static struct wf_pid_state drive_bay_pid ;
static int drive_bay_tick ;
static int nr_cores ;
static int have_all_controls ;
static int have_all_sensors ;
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static bool started ;
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static int failure_state ;
# define FAILURE_SENSOR 1
# define FAILURE_FAN 2
# define FAILURE_PERM 4
# define FAILURE_LOW_OVERTEMP 8
# define FAILURE_HIGH_OVERTEMP 16
/* Overtemp values */
# define LOW_OVER_AVERAGE 0
# define LOW_OVER_IMMEDIATE (10 << 16)
# define LOW_OVER_CLEAR ((-10) << 16)
# define HIGH_OVER_IMMEDIATE (14 << 16)
# define HIGH_OVER_AVERAGE (10 << 16)
# define HIGH_OVER_IMMEDIATE (14 << 16)
/* Implementation... */
static int create_cpu_loop ( int cpu )
{
int chip = cpu / 2 ;
int core = cpu & 1 ;
struct smu_sdbp_header * hdr ;
struct smu_sdbp_cpupiddata * piddata ;
struct wf_cpu_pid_param pid ;
struct wf_control * main_fan = cpu_fans [ 0 ] ;
s32 tmax ;
int fmin ;
/* Get FVT params to get Tmax; if not found, assume default */
hdr = smu_sat_get_sdb_partition ( chip , 0xC4 + core , NULL ) ;
if ( hdr ) {
struct smu_sdbp_fvt * fvt = ( struct smu_sdbp_fvt * ) & hdr [ 1 ] ;
tmax = fvt - > maxtemp < < 16 ;
} else
tmax = 95 < < 16 ; /* default to 95 degrees C */
/* We keep a global tmax for overtemp calculations */
if ( tmax < cpu_all_tmax )
cpu_all_tmax = tmax ;
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kfree ( hdr ) ;
/* Get PID params from the appropriate SAT */
hdr = smu_sat_get_sdb_partition ( chip , 0xC8 + core , NULL ) ;
if ( hdr = = NULL ) {
printk ( KERN_WARNING " windfarm: can't get CPU PID fan config \n " ) ;
return - EINVAL ;
}
piddata = ( struct smu_sdbp_cpupiddata * ) & hdr [ 1 ] ;
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/*
* Darwin has a minimum fan speed of 1000 rpm for the 4 - way and
* 515 for the 2 - way . That appears to be overkill , so for now ,
* impose a minimum of 750 or 515.
*/
fmin = ( nr_cores > 2 ) ? 750 : 515 ;
/* Initialize PID loop */
pid . interval = 1 ; /* seconds */
pid . history_len = piddata - > history_len ;
pid . gd = piddata - > gd ;
pid . gp = piddata - > gp ;
pid . gr = piddata - > gr / piddata - > history_len ;
pid . pmaxadj = ( piddata - > max_power < < 16 ) - ( piddata - > power_adj < < 8 ) ;
pid . ttarget = tmax - ( piddata - > target_temp_delta < < 16 ) ;
pid . tmax = tmax ;
pid . min = main_fan - > ops - > get_min ( main_fan ) ;
pid . max = main_fan - > ops - > get_max ( main_fan ) ;
if ( pid . min < fmin )
pid . min = fmin ;
wf_cpu_pid_init ( & cpu_pid [ cpu ] , & pid ) ;
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kfree ( hdr ) ;
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return 0 ;
}
static void cpu_max_all_fans ( void )
{
int i ;
/* We max all CPU fans in case of a sensor error. We also do the
* cpufreq clamping now , even if it ' s supposedly done later by the
* generic code anyway , we do it earlier here to react faster
*/
if ( cpufreq_clamp )
wf_control_set_max ( cpufreq_clamp ) ;
for ( i = 0 ; i < NR_CPU_FANS ; + + i )
if ( cpu_fans [ i ] )
wf_control_set_max ( cpu_fans [ i ] ) ;
}
static int cpu_check_overtemp ( s32 temp )
{
int new_state = 0 ;
s32 t_avg , t_old ;
/* First check for immediate overtemps */
if ( temp > = ( cpu_all_tmax + LOW_OVER_IMMEDIATE ) ) {
new_state | = FAILURE_LOW_OVERTEMP ;
if ( ( failure_state & FAILURE_LOW_OVERTEMP ) = = 0 )
printk ( KERN_ERR " windfarm: Overtemp due to immediate CPU "
" temperature ! \n " ) ;
}
if ( temp > = ( cpu_all_tmax + HIGH_OVER_IMMEDIATE ) ) {
new_state | = FAILURE_HIGH_OVERTEMP ;
if ( ( failure_state & FAILURE_HIGH_OVERTEMP ) = = 0 )
printk ( KERN_ERR " windfarm: Critical overtemp due to "
" immediate CPU temperature ! \n " ) ;
}
/* We calculate a history of max temperatures and use that for the
* overtemp management
*/
t_old = cpu_thist [ cpu_thist_pt ] ;
cpu_thist [ cpu_thist_pt ] = temp ;
cpu_thist_pt = ( cpu_thist_pt + 1 ) % CPU_TEMP_HIST_SIZE ;
cpu_thist_total - = t_old ;
cpu_thist_total + = temp ;
t_avg = cpu_thist_total / CPU_TEMP_HIST_SIZE ;
DBG_LOTS ( " t_avg = %d.%03d (out: %d.%03d, in: %d.%03d) \n " ,
FIX32TOPRINT ( t_avg ) , FIX32TOPRINT ( t_old ) , FIX32TOPRINT ( temp ) ) ;
/* Now check for average overtemps */
if ( t_avg > = ( cpu_all_tmax + LOW_OVER_AVERAGE ) ) {
new_state | = FAILURE_LOW_OVERTEMP ;
if ( ( failure_state & FAILURE_LOW_OVERTEMP ) = = 0 )
printk ( KERN_ERR " windfarm: Overtemp due to average CPU "
" temperature ! \n " ) ;
}
if ( t_avg > = ( cpu_all_tmax + HIGH_OVER_AVERAGE ) ) {
new_state | = FAILURE_HIGH_OVERTEMP ;
if ( ( failure_state & FAILURE_HIGH_OVERTEMP ) = = 0 )
printk ( KERN_ERR " windfarm: Critical overtemp due to "
" average CPU temperature ! \n " ) ;
}
/* Now handle overtemp conditions. We don't currently use the windfarm
* overtemp handling core as it ' s not fully suited to the needs of those
* new machine . This will be fixed later .
*/
if ( new_state ) {
/* High overtemp -> immediate shutdown */
if ( new_state & FAILURE_HIGH_OVERTEMP )
machine_power_off ( ) ;
if ( ( failure_state & new_state ) ! = new_state )
cpu_max_all_fans ( ) ;
failure_state | = new_state ;
} else if ( ( failure_state & FAILURE_LOW_OVERTEMP ) & &
( temp < ( cpu_all_tmax + LOW_OVER_CLEAR ) ) ) {
printk ( KERN_ERR " windfarm: Overtemp condition cleared ! \n " ) ;
failure_state & = ~ FAILURE_LOW_OVERTEMP ;
}
return failure_state & ( FAILURE_LOW_OVERTEMP | FAILURE_HIGH_OVERTEMP ) ;
}
static void cpu_fans_tick ( void )
{
int err , cpu ;
s32 greatest_delta = 0 ;
s32 temp , power , t_max = 0 ;
int i , t , target = 0 ;
struct wf_sensor * sr ;
struct wf_control * ct ;
struct wf_cpu_pid_state * sp ;
DBG_LOTS ( KERN_DEBUG ) ;
for ( cpu = 0 ; cpu < nr_cores ; + + cpu ) {
/* Get CPU core temperature */
sr = sens_cpu_temp [ cpu ] ;
err = sr - > ops - > get_value ( sr , & temp ) ;
if ( err ) {
DBG ( " \n " ) ;
printk ( KERN_WARNING " windfarm: CPU %d temperature "
" sensor error %d \n " , cpu , err ) ;
failure_state | = FAILURE_SENSOR ;
cpu_max_all_fans ( ) ;
return ;
}
/* Keep track of highest temp */
t_max = max ( t_max , temp ) ;
/* Get CPU power */
sr = sens_cpu_power [ cpu ] ;
err = sr - > ops - > get_value ( sr , & power ) ;
if ( err ) {
DBG ( " \n " ) ;
printk ( KERN_WARNING " windfarm: CPU %d power "
" sensor error %d \n " , cpu , err ) ;
failure_state | = FAILURE_SENSOR ;
cpu_max_all_fans ( ) ;
return ;
}
/* Run PID */
sp = & cpu_pid [ cpu ] ;
t = wf_cpu_pid_run ( sp , power , temp ) ;
if ( cpu = = 0 | | sp - > last_delta > greatest_delta ) {
greatest_delta = sp - > last_delta ;
target = t ;
}
DBG_LOTS ( " [%d] P=%d.%.3d T=%d.%.3d " ,
cpu , FIX32TOPRINT ( power ) , FIX32TOPRINT ( temp ) ) ;
}
DBG_LOTS ( " fans = %d, t_max = %d.%03d \n " , target , FIX32TOPRINT ( t_max ) ) ;
/* Darwin limits decrease to 20 per iteration */
if ( target < ( cpu_last_target - 20 ) )
target = cpu_last_target - 20 ;
cpu_last_target = target ;
for ( cpu = 0 ; cpu < nr_cores ; + + cpu )
cpu_pid [ cpu ] . target = target ;
/* Handle possible overtemps */
if ( cpu_check_overtemp ( t_max ) )
return ;
/* Set fans */
for ( i = 0 ; i < NR_CPU_FANS ; + + i ) {
ct = cpu_fans [ i ] ;
if ( ct = = NULL )
continue ;
err = ct - > ops - > set_value ( ct , target * cpu_fan_scale [ i ] / 100 ) ;
if ( err ) {
printk ( KERN_WARNING " windfarm: fan %s reports "
" error %d \n " , ct - > name , err ) ;
failure_state | = FAILURE_FAN ;
break ;
}
}
}
/* Backside/U4 fan */
static struct wf_pid_param backside_param = {
. interval = 5 ,
. history_len = 2 ,
. gd = 48 < < 20 ,
. gp = 5 < < 20 ,
. gr = 0 ,
. itarget = 64 < < 16 ,
. additive = 1 ,
} ;
static void backside_fan_tick ( void )
{
s32 temp ;
int speed ;
int err ;
if ( ! backside_fan | | ! u4_temp )
return ;
if ( ! backside_tick ) {
/* first time; initialize things */
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printk ( KERN_INFO " windfarm: Backside control loop started. \n " ) ;
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backside_param . min = backside_fan - > ops - > get_min ( backside_fan ) ;
backside_param . max = backside_fan - > ops - > get_max ( backside_fan ) ;
wf_pid_init ( & backside_pid , & backside_param ) ;
backside_tick = 1 ;
}
if ( - - backside_tick > 0 )
return ;
backside_tick = backside_pid . param . interval ;
err = u4_temp - > ops - > get_value ( u4_temp , & temp ) ;
if ( err ) {
printk ( KERN_WARNING " windfarm: U4 temp sensor error %d \n " ,
err ) ;
failure_state | = FAILURE_SENSOR ;
wf_control_set_max ( backside_fan ) ;
return ;
}
speed = wf_pid_run ( & backside_pid , temp ) ;
DBG_LOTS ( " backside PID temp=%d.%.3d speed=%d \n " ,
FIX32TOPRINT ( temp ) , speed ) ;
err = backside_fan - > ops - > set_value ( backside_fan , speed ) ;
if ( err ) {
printk ( KERN_WARNING " windfarm: backside fan error %d \n " , err ) ;
failure_state | = FAILURE_FAN ;
}
}
/* Drive bay fan */
static struct wf_pid_param drive_bay_prm = {
. interval = 5 ,
. history_len = 2 ,
. gd = 30 < < 20 ,
. gp = 5 < < 20 ,
. gr = 0 ,
. itarget = 40 < < 16 ,
. additive = 1 ,
} ;
static void drive_bay_fan_tick ( void )
{
s32 temp ;
int speed ;
int err ;
if ( ! drive_bay_fan | | ! hd_temp )
return ;
if ( ! drive_bay_tick ) {
/* first time; initialize things */
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printk ( KERN_INFO " windfarm: Drive bay control loop started. \n " ) ;
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drive_bay_prm . min = drive_bay_fan - > ops - > get_min ( drive_bay_fan ) ;
drive_bay_prm . max = drive_bay_fan - > ops - > get_max ( drive_bay_fan ) ;
wf_pid_init ( & drive_bay_pid , & drive_bay_prm ) ;
drive_bay_tick = 1 ;
}
if ( - - drive_bay_tick > 0 )
return ;
drive_bay_tick = drive_bay_pid . param . interval ;
err = hd_temp - > ops - > get_value ( hd_temp , & temp ) ;
if ( err ) {
printk ( KERN_WARNING " windfarm: drive bay temp sensor "
" error %d \n " , err ) ;
failure_state | = FAILURE_SENSOR ;
wf_control_set_max ( drive_bay_fan ) ;
return ;
}
speed = wf_pid_run ( & drive_bay_pid , temp ) ;
DBG_LOTS ( " drive_bay PID temp=%d.%.3d speed=%d \n " ,
FIX32TOPRINT ( temp ) , speed ) ;
err = drive_bay_fan - > ops - > set_value ( drive_bay_fan , speed ) ;
if ( err ) {
printk ( KERN_WARNING " windfarm: drive bay fan error %d \n " , err ) ;
failure_state | = FAILURE_FAN ;
}
}
/* PCI slots area fan */
/* This makes the fan speed proportional to the power consumed */
static struct wf_pid_param slots_param = {
. interval = 1 ,
. history_len = 2 ,
. gd = 0 ,
. gp = 0 ,
. gr = 0x1277952 ,
. itarget = 0 ,
. min = 1560 ,
. max = 3510 ,
} ;
static void slots_fan_tick ( void )
{
s32 power ;
int speed ;
int err ;
if ( ! slots_fan | | ! slots_power )
return ;
if ( ! slots_started ) {
/* first time; initialize things */
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printk ( KERN_INFO " windfarm: Slots control loop started. \n " ) ;
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wf_pid_init ( & slots_pid , & slots_param ) ;
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slots_started = true ;
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}
err = slots_power - > ops - > get_value ( slots_power , & power ) ;
if ( err ) {
printk ( KERN_WARNING " windfarm: slots power sensor error %d \n " ,
err ) ;
failure_state | = FAILURE_SENSOR ;
wf_control_set_max ( slots_fan ) ;
return ;
}
speed = wf_pid_run ( & slots_pid , power ) ;
DBG_LOTS ( " slots PID power=%d.%.3d speed=%d \n " ,
FIX32TOPRINT ( power ) , speed ) ;
err = slots_fan - > ops - > set_value ( slots_fan , speed ) ;
if ( err ) {
printk ( KERN_WARNING " windfarm: slots fan error %d \n " , err ) ;
failure_state | = FAILURE_FAN ;
}
}
static void set_fail_state ( void )
{
int i ;
if ( cpufreq_clamp )
wf_control_set_max ( cpufreq_clamp ) ;
for ( i = 0 ; i < NR_CPU_FANS ; + + i )
if ( cpu_fans [ i ] )
wf_control_set_max ( cpu_fans [ i ] ) ;
if ( backside_fan )
wf_control_set_max ( backside_fan ) ;
if ( slots_fan )
wf_control_set_max ( slots_fan ) ;
if ( drive_bay_fan )
wf_control_set_max ( drive_bay_fan ) ;
}
static void pm112_tick ( void )
{
int i , last_failure ;
if ( ! started ) {
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started = true ;
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printk ( KERN_INFO " windfarm: CPUs control loops started. \n " ) ;
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for ( i = 0 ; i < nr_cores ; + + i ) {
if ( create_cpu_loop ( i ) < 0 ) {
failure_state = FAILURE_PERM ;
set_fail_state ( ) ;
break ;
}
}
DBG_LOTS ( " cpu_all_tmax=%d.%03d \n " , FIX32TOPRINT ( cpu_all_tmax ) ) ;
# ifdef HACKED_OVERTEMP
cpu_all_tmax = 60 < < 16 ;
# endif
}
/* Permanent failure, bail out */
if ( failure_state & FAILURE_PERM )
return ;
/* Clear all failure bits except low overtemp which will be eventually
* cleared by the control loop itself
*/
last_failure = failure_state ;
failure_state & = FAILURE_LOW_OVERTEMP ;
cpu_fans_tick ( ) ;
backside_fan_tick ( ) ;
slots_fan_tick ( ) ;
drive_bay_fan_tick ( ) ;
DBG_LOTS ( " last_failure: 0x%x, failure_state: %x \n " ,
last_failure , failure_state ) ;
/* Check for failures. Any failure causes cpufreq clamping */
if ( failure_state & & last_failure = = 0 & & cpufreq_clamp )
wf_control_set_max ( cpufreq_clamp ) ;
if ( failure_state = = 0 & & last_failure & & cpufreq_clamp )
wf_control_set_min ( cpufreq_clamp ) ;
/* That's it for now, we might want to deal with other failures
* differently in the future though
*/
}
static void pm112_new_control ( struct wf_control * ct )
{
int i , max_exhaust ;
if ( cpufreq_clamp = = NULL & & ! strcmp ( ct - > name , " cpufreq-clamp " ) ) {
if ( wf_get_control ( ct ) = = 0 )
cpufreq_clamp = ct ;
}
for ( i = 0 ; i < NR_CPU_FANS ; + + i ) {
if ( ! strcmp ( ct - > name , cpu_fan_names [ i ] ) ) {
if ( cpu_fans [ i ] = = NULL & & wf_get_control ( ct ) = = 0 )
cpu_fans [ i ] = ct ;
break ;
}
}
if ( i > = NR_CPU_FANS ) {
/* not a CPU fan, try the others */
if ( ! strcmp ( ct - > name , " backside-fan " ) ) {
if ( backside_fan = = NULL & & wf_get_control ( ct ) = = 0 )
backside_fan = ct ;
} else if ( ! strcmp ( ct - > name , " slots-fan " ) ) {
if ( slots_fan = = NULL & & wf_get_control ( ct ) = = 0 )
slots_fan = ct ;
} else if ( ! strcmp ( ct - > name , " drive-bay-fan " ) ) {
if ( drive_bay_fan = = NULL & & wf_get_control ( ct ) = = 0 )
drive_bay_fan = ct ;
}
return ;
}
for ( i = 0 ; i < CPU_FANS_REQD ; + + i )
if ( cpu_fans [ i ] = = NULL )
return ;
/* work out pump scaling factors */
max_exhaust = cpu_fans [ 0 ] - > ops - > get_max ( cpu_fans [ 0 ] ) ;
for ( i = FIRST_PUMP ; i < = LAST_PUMP ; + + i )
if ( ( ct = cpu_fans [ i ] ) ! = NULL )
cpu_fan_scale [ i ] =
ct - > ops - > get_max ( ct ) * 100 / max_exhaust ;
have_all_controls = 1 ;
}
static void pm112_new_sensor ( struct wf_sensor * sr )
{
unsigned int i ;
if ( ! strncmp ( sr - > name , " cpu-temp- " , 9 ) ) {
i = sr - > name [ 9 ] - ' 0 ' ;
if ( sr - > name [ 10 ] = = 0 & & i < NR_CORES & &
sens_cpu_temp [ i ] = = NULL & & wf_get_sensor ( sr ) = = 0 )
sens_cpu_temp [ i ] = sr ;
} else if ( ! strncmp ( sr - > name , " cpu-power- " , 10 ) ) {
i = sr - > name [ 10 ] - ' 0 ' ;
if ( sr - > name [ 11 ] = = 0 & & i < NR_CORES & &
sens_cpu_power [ i ] = = NULL & & wf_get_sensor ( sr ) = = 0 )
sens_cpu_power [ i ] = sr ;
} else if ( ! strcmp ( sr - > name , " hd-temp " ) ) {
if ( hd_temp = = NULL & & wf_get_sensor ( sr ) = = 0 )
hd_temp = sr ;
} else if ( ! strcmp ( sr - > name , " slots-power " ) ) {
if ( slots_power = = NULL & & wf_get_sensor ( sr ) = = 0 )
slots_power = sr ;
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} else if ( ! strcmp ( sr - > name , " backside-temp " ) ) {
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if ( u4_temp = = NULL & & wf_get_sensor ( sr ) = = 0 )
u4_temp = sr ;
} else
return ;
/* check if we have all the sensors we need */
for ( i = 0 ; i < nr_cores ; + + i )
if ( sens_cpu_temp [ i ] = = NULL | | sens_cpu_power [ i ] = = NULL )
return ;
have_all_sensors = 1 ;
}
static int pm112_wf_notify ( struct notifier_block * self ,
unsigned long event , void * data )
{
switch ( event ) {
case WF_EVENT_NEW_SENSOR :
pm112_new_sensor ( data ) ;
break ;
case WF_EVENT_NEW_CONTROL :
pm112_new_control ( data ) ;
break ;
case WF_EVENT_TICK :
if ( have_all_controls & & have_all_sensors )
pm112_tick ( ) ;
}
return 0 ;
}
static struct notifier_block pm112_events = {
. notifier_call = pm112_wf_notify ,
} ;
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static int wf_pm112_probe ( struct platform_device * dev )
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{
wf_register_client ( & pm112_events ) ;
return 0 ;
}
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static int wf_pm112_remove ( struct platform_device * dev )
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{
wf_unregister_client ( & pm112_events ) ;
/* should release all sensors and controls */
return 0 ;
}
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static struct platform_driver wf_pm112_driver = {
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. probe = wf_pm112_probe ,
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. remove = wf_pm112_remove ,
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. driver = {
. name = " windfarm " ,
} ,
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} ;
static int __init wf_pm112_init ( void )
{
struct device_node * cpu ;
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if ( ! of_machine_is_compatible ( " PowerMac11,2 " ) )
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return - ENODEV ;
/* Count the number of CPU cores */
nr_cores = 0 ;
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for_each_node_by_type ( cpu , " cpu " )
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+ + nr_cores ;
printk ( KERN_INFO " windfarm: initializing for dual-core desktop G5 \n " ) ;
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# ifdef MODULE
request_module ( " windfarm_smu_controls " ) ;
request_module ( " windfarm_smu_sensors " ) ;
request_module ( " windfarm_smu_sat " ) ;
request_module ( " windfarm_lm75_sensor " ) ;
request_module ( " windfarm_max6690_sensor " ) ;
request_module ( " windfarm_cpufreq_clamp " ) ;
# endif /* MODULE */
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platform_driver_register ( & wf_pm112_driver ) ;
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return 0 ;
}
static void __exit wf_pm112_exit ( void )
{
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platform_driver_unregister ( & wf_pm112_driver ) ;
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}
module_init ( wf_pm112_init ) ;
module_exit ( wf_pm112_exit ) ;
MODULE_AUTHOR ( " Paul Mackerras <paulus@samba.org> " ) ;
MODULE_DESCRIPTION ( " Thermal control for PowerMac11,2 " ) ;
MODULE_LICENSE ( " GPL " ) ;
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MODULE_ALIAS ( " platform:windfarm " ) ;