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linux-next/drivers/macintosh/windfarm_pm72.c
Wei Yongjun c7c360eedb powerpc/windfarm: Use for_each_node_by_type() macro
Use for_each_node_by_type() macro instead of open coding it.

Signed-off-by: Wei Yongjun <yongjun_wei@trendmicro.com.cn>
Signed-off-by: Benjamin Herrenschmidt <benh@kernel.crashing.org>
2013-01-10 17:00:36 +11:00

848 lines
20 KiB
C

/*
* Windfarm PowerMac thermal control.
* Control loops for PowerMac7,2 and 7,3
*
* Copyright (C) 2012 Benjamin Herrenschmidt, IBM Corp.
*
* Use and redistribute under the terms of the GNU GPL v2.
*/
#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>
#include <asm/prom.h>
#include <asm/smu.h>
#include "windfarm.h"
#include "windfarm_pid.h"
#include "windfarm_mpu.h"
#define VERSION "1.0"
#undef 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 */
#define NR_CHIPS 2
#define NR_CPU_FANS 3 * NR_CHIPS
/* Controls and sensors */
static struct wf_sensor *sens_cpu_temp[NR_CHIPS];
static struct wf_sensor *sens_cpu_volts[NR_CHIPS];
static struct wf_sensor *sens_cpu_amps[NR_CHIPS];
static struct wf_sensor *backside_temp;
static struct wf_sensor *drives_temp;
static struct wf_control *cpu_front_fans[NR_CHIPS];
static struct wf_control *cpu_rear_fans[NR_CHIPS];
static struct wf_control *cpu_pumps[NR_CHIPS];
static struct wf_control *backside_fan;
static struct wf_control *drives_fan;
static struct wf_control *slots_fan;
static struct wf_control *cpufreq_clamp;
/* We keep a temperature history for average calculation of 180s */
#define CPU_TEMP_HIST_SIZE 180
/* Fixed speed for slot fan */
#define SLOTS_FAN_DEFAULT_PWM 40
/* Scale value for CPU intake fans */
#define CPU_INTAKE_SCALE 0x0000f852
/* PID loop state */
static const struct mpu_data *cpu_mpu_data[NR_CHIPS];
static struct wf_cpu_pid_state cpu_pid[NR_CHIPS];
static bool cpu_pid_combined;
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 struct wf_pid_state backside_pid;
static int backside_tick;
static struct wf_pid_state drives_pid;
static int drives_tick;
static int nr_chips;
static bool have_all_controls;
static bool have_all_sensors;
static bool started;
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)
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_chips; i++) {
if (cpu_front_fans[i])
wf_control_set_max(cpu_front_fans[i]);
if (cpu_rear_fans[i])
wf_control_set_max(cpu_rear_fans[i]);
if (cpu_pumps[i])
wf_control_set_max(cpu_pumps[i]);
}
}
static int cpu_check_overtemp(s32 temp)
{
int new_state = 0;
s32 t_avg, t_old;
static bool first = true;
/* 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");
}
/*
* The first time around, initialize the array with the first
* temperature reading
*/
if (first) {
int i;
cpu_thist_total = 0;
for (i = 0; i < CPU_TEMP_HIST_SIZE; i++) {
cpu_thist[i] = temp;
cpu_thist_total += temp;
}
first = false;
}
/*
* 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 int read_one_cpu_vals(int cpu, s32 *temp, s32 *power)
{
s32 dtemp, volts, amps;
int rc;
/* Get diode temperature */
rc = wf_sensor_get(sens_cpu_temp[cpu], &dtemp);
if (rc) {
DBG(" CPU%d: temp reading error !\n", cpu);
return -EIO;
}
DBG_LOTS(" CPU%d: temp = %d.%03d\n", cpu, FIX32TOPRINT((dtemp)));
*temp = dtemp;
/* Get voltage */
rc = wf_sensor_get(sens_cpu_volts[cpu], &volts);
if (rc) {
DBG(" CPU%d, volts reading error !\n", cpu);
return -EIO;
}
DBG_LOTS(" CPU%d: volts = %d.%03d\n", cpu, FIX32TOPRINT((volts)));
/* Get current */
rc = wf_sensor_get(sens_cpu_amps[cpu], &amps);
if (rc) {
DBG(" CPU%d, current reading error !\n", cpu);
return -EIO;
}
DBG_LOTS(" CPU%d: amps = %d.%03d\n", cpu, FIX32TOPRINT((amps)));
/* Calculate power */
/* Scale voltage and current raw sensor values according to fixed scales
* obtained in Darwin and calculate power from I and V
*/
*power = (((u64)volts) * ((u64)amps)) >> 16;
DBG_LOTS(" CPU%d: power = %d.%03d\n", cpu, FIX32TOPRINT((*power)));
return 0;
}
static void cpu_fans_tick_split(void)
{
int err, cpu;
s32 intake, temp, power, t_max = 0;
DBG_LOTS("* cpu fans_tick_split()\n");
for (cpu = 0; cpu < nr_chips; ++cpu) {
struct wf_cpu_pid_state *sp = &cpu_pid[cpu];
/* Read current speed */
wf_control_get(cpu_rear_fans[cpu], &sp->target);
DBG_LOTS(" CPU%d: cur_target = %d RPM\n", cpu, sp->target);
err = read_one_cpu_vals(cpu, &temp, &power);
if (err) {
failure_state |= FAILURE_SENSOR;
cpu_max_all_fans();
return;
}
/* Keep track of highest temp */
t_max = max(t_max, temp);
/* Handle possible overtemps */
if (cpu_check_overtemp(t_max))
return;
/* Run PID */
wf_cpu_pid_run(sp, power, temp);
DBG_LOTS(" CPU%d: target = %d RPM\n", cpu, sp->target);
/* Apply result directly to exhaust fan */
err = wf_control_set(cpu_rear_fans[cpu], sp->target);
if (err) {
pr_warning("wf_pm72: Fan %s reports error %d\n",
cpu_rear_fans[cpu]->name, err);
failure_state |= FAILURE_FAN;
break;
}
/* Scale result for intake fan */
intake = (sp->target * CPU_INTAKE_SCALE) >> 16;
DBG_LOTS(" CPU%d: intake = %d RPM\n", cpu, intake);
err = wf_control_set(cpu_front_fans[cpu], intake);
if (err) {
pr_warning("wf_pm72: Fan %s reports error %d\n",
cpu_front_fans[cpu]->name, err);
failure_state |= FAILURE_FAN;
break;
}
}
}
static void cpu_fans_tick_combined(void)
{
s32 temp0, power0, temp1, power1, t_max = 0;
s32 temp, power, intake, pump;
struct wf_control *pump0, *pump1;
struct wf_cpu_pid_state *sp = &cpu_pid[0];
int err, cpu;
DBG_LOTS("* cpu fans_tick_combined()\n");
/* Read current speed from cpu 0 */
wf_control_get(cpu_rear_fans[0], &sp->target);
DBG_LOTS(" CPUs: cur_target = %d RPM\n", sp->target);
/* Read values for both CPUs */
err = read_one_cpu_vals(0, &temp0, &power0);
if (err) {
failure_state |= FAILURE_SENSOR;
cpu_max_all_fans();
return;
}
err = read_one_cpu_vals(1, &temp1, &power1);
if (err) {
failure_state |= FAILURE_SENSOR;
cpu_max_all_fans();
return;
}
/* Keep track of highest temp */
t_max = max(t_max, max(temp0, temp1));
/* Handle possible overtemps */
if (cpu_check_overtemp(t_max))
return;
/* Use the max temp & power of both */
temp = max(temp0, temp1);
power = max(power0, power1);
/* Run PID */
wf_cpu_pid_run(sp, power, temp);
/* Scale result for intake fan */
intake = (sp->target * CPU_INTAKE_SCALE) >> 16;
/* Same deal with pump speed */
pump0 = cpu_pumps[0];
pump1 = cpu_pumps[1];
if (!pump0) {
pump0 = pump1;
pump1 = NULL;
}
pump = (sp->target * wf_control_get_max(pump0)) /
cpu_mpu_data[0]->rmaxn_exhaust_fan;
DBG_LOTS(" CPUs: target = %d RPM\n", sp->target);
DBG_LOTS(" CPUs: intake = %d RPM\n", intake);
DBG_LOTS(" CPUs: pump = %d RPM\n", pump);
for (cpu = 0; cpu < nr_chips; cpu++) {
err = wf_control_set(cpu_rear_fans[cpu], sp->target);
if (err) {
pr_warning("wf_pm72: Fan %s reports error %d\n",
cpu_rear_fans[cpu]->name, err);
failure_state |= FAILURE_FAN;
}
err = wf_control_set(cpu_front_fans[cpu], intake);
if (err) {
pr_warning("wf_pm72: Fan %s reports error %d\n",
cpu_front_fans[cpu]->name, err);
failure_state |= FAILURE_FAN;
}
err = 0;
if (cpu_pumps[cpu])
err = wf_control_set(cpu_pumps[cpu], pump);
if (err) {
pr_warning("wf_pm72: Pump %s reports error %d\n",
cpu_pumps[cpu]->name, err);
failure_state |= FAILURE_FAN;
}
}
}
/* Implementation... */
static int cpu_setup_pid(int cpu)
{
struct wf_cpu_pid_param pid;
const struct mpu_data *mpu = cpu_mpu_data[cpu];
s32 tmax, ttarget, ptarget;
int fmin, fmax, hsize;
/* Get PID params from the appropriate MPU EEPROM */
tmax = mpu->tmax << 16;
ttarget = mpu->ttarget << 16;
ptarget = ((s32)(mpu->pmaxh - mpu->padjmax)) << 16;
DBG("wf_72: CPU%d ttarget = %d.%03d, tmax = %d.%03d\n",
cpu, FIX32TOPRINT(ttarget), FIX32TOPRINT(tmax));
/* We keep a global tmax for overtemp calculations */
if (tmax < cpu_all_tmax)
cpu_all_tmax = tmax;
/* Set PID min/max by using the rear fan min/max */
fmin = wf_control_get_min(cpu_rear_fans[cpu]);
fmax = wf_control_get_max(cpu_rear_fans[cpu]);
DBG("wf_72: CPU%d max RPM range = [%d..%d]\n", cpu, fmin, fmax);
/* History size */
hsize = min_t(int, mpu->tguardband, WF_PID_MAX_HISTORY);
DBG("wf_72: CPU%d history size = %d\n", cpu, hsize);
/* Initialize PID loop */
pid.interval = 1; /* seconds */
pid.history_len = hsize;
pid.gd = mpu->pid_gd;
pid.gp = mpu->pid_gp;
pid.gr = mpu->pid_gr;
pid.tmax = tmax;
pid.ttarget = ttarget;
pid.pmaxadj = ptarget;
pid.min = fmin;
pid.max = fmax;
wf_cpu_pid_init(&cpu_pid[cpu], &pid);
cpu_pid[cpu].target = 1000;
return 0;
}
/* Backside/U3 fan */
static struct wf_pid_param backside_u3_param = {
.interval = 5,
.history_len = 2,
.gd = 40 << 20,
.gp = 5 << 20,
.gr = 0,
.itarget = 65 << 16,
.additive = 1,
.min = 20,
.max = 100,
};
static struct wf_pid_param backside_u3h_param = {
.interval = 5,
.history_len = 2,
.gd = 20 << 20,
.gp = 5 << 20,
.gr = 0,
.itarget = 75 << 16,
.additive = 1,
.min = 20,
.max = 100,
};
static void backside_fan_tick(void)
{
s32 temp;
int speed;
int err;
if (!backside_fan || !backside_temp || !backside_tick)
return;
if (--backside_tick > 0)
return;
backside_tick = backside_pid.param.interval;
DBG_LOTS("* backside fans tick\n");
/* Update fan speed from actual fans */
err = wf_control_get(backside_fan, &speed);
if (!err)
backside_pid.target = speed;
err = wf_sensor_get(backside_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 = wf_control_set(backside_fan, speed);
if (err) {
printk(KERN_WARNING "windfarm: backside fan error %d\n", err);
failure_state |= FAILURE_FAN;
}
}
static void backside_setup_pid(void)
{
/* first time initialize things */
s32 fmin = wf_control_get_min(backside_fan);
s32 fmax = wf_control_get_max(backside_fan);
struct wf_pid_param param;
struct device_node *u3;
int u3h = 1; /* conservative by default */
u3 = of_find_node_by_path("/u3@0,f8000000");
if (u3 != NULL) {
const u32 *vers = of_get_property(u3, "device-rev", NULL);
if (vers)
if (((*vers) & 0x3f) < 0x34)
u3h = 0;
of_node_put(u3);
}
param = u3h ? backside_u3h_param : backside_u3_param;
param.min = max(param.min, fmin);
param.max = min(param.max, fmax);
wf_pid_init(&backside_pid, &param);
backside_tick = 1;
pr_info("wf_pm72: Backside control loop started.\n");
}
/* Drive bay fan */
static const struct wf_pid_param drives_param = {
.interval = 5,
.history_len = 2,
.gd = 30 << 20,
.gp = 5 << 20,
.gr = 0,
.itarget = 40 << 16,
.additive = 1,
.min = 300,
.max = 4000,
};
static void drives_fan_tick(void)
{
s32 temp;
int speed;
int err;
if (!drives_fan || !drives_temp || !drives_tick)
return;
if (--drives_tick > 0)
return;
drives_tick = drives_pid.param.interval;
DBG_LOTS("* drives fans tick\n");
/* Update fan speed from actual fans */
err = wf_control_get(drives_fan, &speed);
if (!err)
drives_pid.target = speed;
err = wf_sensor_get(drives_temp, &temp);
if (err) {
pr_warning("wf_pm72: drive bay temp sensor error %d\n", err);
failure_state |= FAILURE_SENSOR;
wf_control_set_max(drives_fan);
return;
}
speed = wf_pid_run(&drives_pid, temp);
DBG_LOTS("drives PID temp=%d.%.3d speed=%d\n",
FIX32TOPRINT(temp), speed);
err = wf_control_set(drives_fan, speed);
if (err) {
printk(KERN_WARNING "windfarm: drive bay fan error %d\n", err);
failure_state |= FAILURE_FAN;
}
}
static void drives_setup_pid(void)
{
/* first time initialize things */
s32 fmin = wf_control_get_min(drives_fan);
s32 fmax = wf_control_get_max(drives_fan);
struct wf_pid_param param = drives_param;
param.min = max(param.min, fmin);
param.max = min(param.max, fmax);
wf_pid_init(&drives_pid, &param);
drives_tick = 1;
pr_info("wf_pm72: Drive bay control loop started.\n");
}
static void set_fail_state(void)
{
cpu_max_all_fans();
if (backside_fan)
wf_control_set_max(backside_fan);
if (slots_fan)
wf_control_set_max(slots_fan);
if (drives_fan)
wf_control_set_max(drives_fan);
}
static void pm72_tick(void)
{
int i, last_failure;
if (!started) {
started = 1;
printk(KERN_INFO "windfarm: CPUs control loops started.\n");
for (i = 0; i < nr_chips; ++i) {
if (cpu_setup_pid(i) < 0) {
failure_state = FAILURE_PERM;
set_fail_state();
break;
}
}
DBG_LOTS("cpu_all_tmax=%d.%03d\n", FIX32TOPRINT(cpu_all_tmax));
backside_setup_pid();
drives_setup_pid();
/*
* We don't have the right stuff to drive the PCI fan
* so we fix it to a default value
*/
wf_control_set(slots_fan, SLOTS_FAN_DEFAULT_PWM);
#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;
if (cpu_pid_combined)
cpu_fans_tick_combined();
else
cpu_fans_tick_split();
backside_fan_tick();
drives_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 pm72_new_control(struct wf_control *ct)
{
bool all_controls;
bool had_pump = cpu_pumps[0] || cpu_pumps[1];
if (!strcmp(ct->name, "cpu-front-fan-0"))
cpu_front_fans[0] = ct;
else if (!strcmp(ct->name, "cpu-front-fan-1"))
cpu_front_fans[1] = ct;
else if (!strcmp(ct->name, "cpu-rear-fan-0"))
cpu_rear_fans[0] = ct;
else if (!strcmp(ct->name, "cpu-rear-fan-1"))
cpu_rear_fans[1] = ct;
else if (!strcmp(ct->name, "cpu-pump-0"))
cpu_pumps[0] = ct;
else if (!strcmp(ct->name, "cpu-pump-1"))
cpu_pumps[1] = ct;
else if (!strcmp(ct->name, "backside-fan"))
backside_fan = ct;
else if (!strcmp(ct->name, "slots-fan"))
slots_fan = ct;
else if (!strcmp(ct->name, "drive-bay-fan"))
drives_fan = ct;
else if (!strcmp(ct->name, "cpufreq-clamp"))
cpufreq_clamp = ct;
all_controls =
cpu_front_fans[0] &&
cpu_rear_fans[0] &&
backside_fan &&
slots_fan &&
drives_fan;
if (nr_chips > 1)
all_controls &=
cpu_front_fans[1] &&
cpu_rear_fans[1];
have_all_controls = all_controls;
if ((cpu_pumps[0] || cpu_pumps[1]) && !had_pump) {
pr_info("wf_pm72: Liquid cooling pump(s) detected,"
" using new algorithm !\n");
cpu_pid_combined = true;
}
}
static void pm72_new_sensor(struct wf_sensor *sr)
{
bool all_sensors;
if (!strcmp(sr->name, "cpu-diode-temp-0"))
sens_cpu_temp[0] = sr;
else if (!strcmp(sr->name, "cpu-diode-temp-1"))
sens_cpu_temp[1] = sr;
else if (!strcmp(sr->name, "cpu-voltage-0"))
sens_cpu_volts[0] = sr;
else if (!strcmp(sr->name, "cpu-voltage-1"))
sens_cpu_volts[1] = sr;
else if (!strcmp(sr->name, "cpu-current-0"))
sens_cpu_amps[0] = sr;
else if (!strcmp(sr->name, "cpu-current-1"))
sens_cpu_amps[1] = sr;
else if (!strcmp(sr->name, "backside-temp"))
backside_temp = sr;
else if (!strcmp(sr->name, "hd-temp"))
drives_temp = sr;
all_sensors =
sens_cpu_temp[0] &&
sens_cpu_volts[0] &&
sens_cpu_amps[0] &&
backside_temp &&
drives_temp;
if (nr_chips > 1)
all_sensors &=
sens_cpu_temp[1] &&
sens_cpu_volts[1] &&
sens_cpu_amps[1];
have_all_sensors = all_sensors;
}
static int pm72_wf_notify(struct notifier_block *self,
unsigned long event, void *data)
{
switch (event) {
case WF_EVENT_NEW_SENSOR:
pm72_new_sensor(data);
break;
case WF_EVENT_NEW_CONTROL:
pm72_new_control(data);
break;
case WF_EVENT_TICK:
if (have_all_controls && have_all_sensors)
pm72_tick();
}
return 0;
}
static struct notifier_block pm72_events = {
.notifier_call = pm72_wf_notify,
};
static int wf_pm72_probe(struct platform_device *dev)
{
wf_register_client(&pm72_events);
return 0;
}
static int wf_pm72_remove(struct platform_device *dev)
{
wf_unregister_client(&pm72_events);
/* should release all sensors and controls */
return 0;
}
static struct platform_driver wf_pm72_driver = {
.probe = wf_pm72_probe,
.remove = wf_pm72_remove,
.driver = {
.name = "windfarm",
.owner = THIS_MODULE,
},
};
static int __init wf_pm72_init(void)
{
struct device_node *cpu;
int i;
if (!of_machine_is_compatible("PowerMac7,2") &&
!of_machine_is_compatible("PowerMac7,3"))
return -ENODEV;
/* Count the number of CPU cores */
nr_chips = 0;
for_each_node_by_type(cpu, "cpu")
++nr_chips;
if (nr_chips > NR_CHIPS)
nr_chips = NR_CHIPS;
pr_info("windfarm: Initializing for desktop G5 with %d chips\n",
nr_chips);
/* Get MPU data for each CPU */
for (i = 0; i < nr_chips; i++) {
cpu_mpu_data[i] = wf_get_mpu(i);
if (!cpu_mpu_data[i]) {
pr_err("wf_pm72: Failed to find MPU data for CPU %d\n", i);
return -ENXIO;
}
}
#ifdef MODULE
request_module("windfarm_fcu_controls");
request_module("windfarm_lm75_sensor");
request_module("windfarm_ad7417_sensor");
request_module("windfarm_max6690_sensor");
request_module("windfarm_cpufreq_clamp");
#endif /* MODULE */
platform_driver_register(&wf_pm72_driver);
return 0;
}
static void __exit wf_pm72_exit(void)
{
platform_driver_unregister(&wf_pm72_driver);
}
module_init(wf_pm72_init);
module_exit(wf_pm72_exit);
MODULE_AUTHOR("Benjamin Herrenschmidt <benh@kernel.crashing.org>");
MODULE_DESCRIPTION("Thermal control for AGP PowerMac G5s");
MODULE_LICENSE("GPL");
MODULE_ALIAS("platform:windfarm");