Commit b074cf80 authored by Wolfram Sang's avatar Wolfram Sang

macintosh: therm_pm72: delete deprecated driver

The new driver is around for more than 2 years now, so the old one can
go. Getting rid of it helps the removal of the legacy .attach_adapter
callback of the I2C subsystem.
Signed-off-by: default avatarWolfram Sang <wsa@the-dreams.de>
Acked-by: default avatarBenjamin Herrenschmidt <benh@kernel.crashing.org>
parent f16ea4f0
......@@ -204,16 +204,6 @@ config THERM_ADT746X
iBook G4, and the ATI based aluminium PowerBooks, allowing slightly
better fan behaviour by default, and some manual control.
config THERM_PM72
tristate "Support for thermal management on PowerMac G5 (AGP)"
depends on I2C && I2C_POWERMAC && PPC_PMAC64
default n
help
This driver provides thermostat and fan control for the desktop
G5 machines.
This is deprecated, use windfarm instead.
config WINDFARM
tristate "New PowerMac thermal control infrastructure"
depends on PPC
......
......@@ -25,7 +25,6 @@ obj-$(CONFIG_ADB_IOP) += adb-iop.o
obj-$(CONFIG_ADB_PMU68K) += via-pmu68k.o
obj-$(CONFIG_ADB_MACIO) += macio-adb.o
obj-$(CONFIG_THERM_PM72) += therm_pm72.o
obj-$(CONFIG_THERM_WINDTUNNEL) += therm_windtunnel.o
obj-$(CONFIG_THERM_ADT746X) += therm_adt746x.o
obj-$(CONFIG_WINDFARM) += windfarm_core.o
......
/*
* Device driver for the thermostats & fan controller of the
* Apple G5 "PowerMac7,2" desktop machines.
*
* (c) Copyright IBM Corp. 2003-2004
*
* Maintained by: Benjamin Herrenschmidt
* <benh@kernel.crashing.org>
*
*
* The algorithm used is the PID control algorithm, used the same
* way the published Darwin code does, using the same values that
* are present in the Darwin 7.0 snapshot property lists.
*
* As far as the CPUs control loops are concerned, I use the
* calibration & PID constants provided by the EEPROM,
* I do _not_ embed any value from the property lists, as the ones
* provided by Darwin 7.0 seem to always have an older version that
* what I've seen on the actual computers.
* It would be interesting to verify that though. Darwin has a
* version code of 1.0.0d11 for all control loops it seems, while
* so far, the machines EEPROMs contain a dataset versioned 1.0.0f
*
* Darwin doesn't provide source to all parts, some missing
* bits like the AppleFCU driver or the actual scale of some
* of the values returned by sensors had to be "guessed" some
* way... or based on what Open Firmware does.
*
* I didn't yet figure out how to get the slots power consumption
* out of the FCU, so that part has not been implemented yet and
* the slots fan is set to a fixed 50% PWM, hoping this value is
* safe enough ...
*
* Note: I have observed strange oscillations of the CPU control
* loop on a dual G5 here. When idle, the CPU exhaust fan tend to
* oscillates slowly (over several minutes) between the minimum
* of 300RPMs and approx. 1000 RPMs. I don't know what is causing
* this, it could be some incorrect constant or an error in the
* way I ported the algorithm, or it could be just normal. I
* don't have full understanding on the way Apple tweaked the PID
* algorithm for the CPU control, it is definitely not a standard
* implementation...
*
* TODO: - Check MPU structure version/signature
* - Add things like /sbin/overtemp for non-critical
* overtemp conditions so userland can take some policy
* decisions, like slowing down CPUs
* - Deal with fan and i2c failures in a better way
* - Maybe do a generic PID based on params used for
* U3 and Drives ? Definitely need to factor code a bit
* better... also make sensor detection more robust using
* the device-tree to probe for them
* - Figure out how to get the slots consumption and set the
* slots fan accordingly
*
* History:
*
* Nov. 13, 2003 : 0.5
* - First release
*
* Nov. 14, 2003 : 0.6
* - Read fan speed from FCU, low level fan routines now deal
* with errors & check fan status, though higher level don't
* do much.
* - Move a bunch of definitions to .h file
*
* Nov. 18, 2003 : 0.7
* - Fix build on ppc64 kernel
* - Move back statics definitions to .c file
* - Avoid calling schedule_timeout with a negative number
*
* Dec. 18, 2003 : 0.8
* - Fix typo when reading back fan speed on 2 CPU machines
*
* Mar. 11, 2004 : 0.9
* - Rework code accessing the ADC chips, make it more robust and
* closer to the chip spec. Also make sure it is configured properly,
* I've seen yet unexplained cases where on startup, I would have stale
* values in the configuration register
* - Switch back to use of target fan speed for PID, thus lowering
* pressure on i2c
*
* Oct. 20, 2004 : 1.1
* - Add device-tree lookup for fan IDs, should detect liquid cooling
* pumps when present
* - Enable driver for PowerMac7,3 machines
* - Split the U3/Backside cooling on U3 & U3H versions as Darwin does
* - Add new CPU cooling algorithm for machines with liquid cooling
* - Workaround for some PowerMac7,3 with empty "fan" node in the devtree
* - Fix a signed/unsigned compare issue in some PID loops
*
* Mar. 10, 2005 : 1.2
* - Add basic support for Xserve G5
* - Retrieve pumps min/max from EEPROM image in device-tree (broken)
* - Use min/max macros here or there
* - Latest darwin updated U3H min fan speed to 20% PWM
*
* July. 06, 2006 : 1.3
* - Fix setting of RPM fans on Xserve G5 (they were going too fast)
* - Add missing slots fan control loop for Xserve G5
* - Lower fixed slots fan speed from 50% to 40% on desktop G5s. We
* still can't properly implement the control loop for these, so let's
* reduce the noise a little bit, it appears that 40% still gives us
* a pretty good air flow
* - Add code to "tickle" the FCU regulary so it doesn't think that
* we are gone while in fact, the machine just didn't need any fan
* speed change lately
*
*/
#include <linux/types.h>
#include <linux/module.h>
#include <linux/errno.h>
#include <linux/kernel.h>
#include <linux/delay.h>
#include <linux/sched.h>
#include <linux/init.h>
#include <linux/spinlock.h>
#include <linux/wait.h>
#include <linux/reboot.h>
#include <linux/kmod.h>
#include <linux/i2c.h>
#include <linux/kthread.h>
#include <linux/mutex.h>
#include <linux/of_device.h>
#include <linux/of_platform.h>
#include <asm/prom.h>
#include <asm/machdep.h>
#include <asm/io.h>
#include <asm/sections.h>
#include <asm/macio.h>
#include "therm_pm72.h"
#define VERSION "1.3"
#undef DEBUG
#ifdef DEBUG
#define DBG(args...) printk(args)
#else
#define DBG(args...) do { } while(0)
#endif
/*
* Driver statics
*/
static struct platform_device * of_dev;
static struct i2c_adapter * u3_0;
static struct i2c_adapter * u3_1;
static struct i2c_adapter * k2;
static struct i2c_client * fcu;
static struct cpu_pid_state processor_state[2];
static struct basckside_pid_params backside_params;
static struct backside_pid_state backside_state;
static struct drives_pid_state drives_state;
static struct dimm_pid_state dimms_state;
static struct slots_pid_state slots_state;
static int state;
static int cpu_count;
static int cpu_pid_type;
static struct task_struct *ctrl_task;
static struct completion ctrl_complete;
static int critical_state;
static int rackmac;
static s32 dimm_output_clamp;
static int fcu_rpm_shift;
static int fcu_tickle_ticks;
static DEFINE_MUTEX(driver_lock);
/*
* We have 3 types of CPU PID control. One is "split" old style control
* for intake & exhaust fans, the other is "combined" control for both
* CPUs that also deals with the pumps when present. To be "compatible"
* with OS X at this point, we only use "COMBINED" on the machines that
* are identified as having the pumps (though that identification is at
* least dodgy). Ultimately, we could probably switch completely to this
* algorithm provided we hack it to deal with the UP case
*/
#define CPU_PID_TYPE_SPLIT 0
#define CPU_PID_TYPE_COMBINED 1
#define CPU_PID_TYPE_RACKMAC 2
/*
* This table describes all fans in the FCU. The "id" and "type" values
* are defaults valid for all earlier machines. Newer machines will
* eventually override the table content based on the device-tree
*/
struct fcu_fan_table
{
char* loc; /* location code */
int type; /* 0 = rpm, 1 = pwm, 2 = pump */
int id; /* id or -1 */
};
#define FCU_FAN_RPM 0
#define FCU_FAN_PWM 1
#define FCU_FAN_ABSENT_ID -1
#define FCU_FAN_COUNT ARRAY_SIZE(fcu_fans)
struct fcu_fan_table fcu_fans[] = {
[BACKSIDE_FAN_PWM_INDEX] = {
.loc = "BACKSIDE,SYS CTRLR FAN",
.type = FCU_FAN_PWM,
.id = BACKSIDE_FAN_PWM_DEFAULT_ID,
},
[DRIVES_FAN_RPM_INDEX] = {
.loc = "DRIVE BAY",
.type = FCU_FAN_RPM,
.id = DRIVES_FAN_RPM_DEFAULT_ID,
},
[SLOTS_FAN_PWM_INDEX] = {
.loc = "SLOT,PCI FAN",
.type = FCU_FAN_PWM,
.id = SLOTS_FAN_PWM_DEFAULT_ID,
},
[CPUA_INTAKE_FAN_RPM_INDEX] = {
.loc = "CPU A INTAKE",
.type = FCU_FAN_RPM,
.id = CPUA_INTAKE_FAN_RPM_DEFAULT_ID,
},
[CPUA_EXHAUST_FAN_RPM_INDEX] = {
.loc = "CPU A EXHAUST",
.type = FCU_FAN_RPM,
.id = CPUA_EXHAUST_FAN_RPM_DEFAULT_ID,
},
[CPUB_INTAKE_FAN_RPM_INDEX] = {
.loc = "CPU B INTAKE",
.type = FCU_FAN_RPM,
.id = CPUB_INTAKE_FAN_RPM_DEFAULT_ID,
},
[CPUB_EXHAUST_FAN_RPM_INDEX] = {
.loc = "CPU B EXHAUST",
.type = FCU_FAN_RPM,
.id = CPUB_EXHAUST_FAN_RPM_DEFAULT_ID,
},
/* pumps aren't present by default, have to be looked up in the
* device-tree
*/
[CPUA_PUMP_RPM_INDEX] = {
.loc = "CPU A PUMP",
.type = FCU_FAN_RPM,
.id = FCU_FAN_ABSENT_ID,
},
[CPUB_PUMP_RPM_INDEX] = {
.loc = "CPU B PUMP",
.type = FCU_FAN_RPM,
.id = FCU_FAN_ABSENT_ID,
},
/* Xserve fans */
[CPU_A1_FAN_RPM_INDEX] = {
.loc = "CPU A 1",
.type = FCU_FAN_RPM,
.id = FCU_FAN_ABSENT_ID,
},
[CPU_A2_FAN_RPM_INDEX] = {
.loc = "CPU A 2",
.type = FCU_FAN_RPM,
.id = FCU_FAN_ABSENT_ID,
},
[CPU_A3_FAN_RPM_INDEX] = {
.loc = "CPU A 3",
.type = FCU_FAN_RPM,
.id = FCU_FAN_ABSENT_ID,
},
[CPU_B1_FAN_RPM_INDEX] = {
.loc = "CPU B 1",
.type = FCU_FAN_RPM,
.id = FCU_FAN_ABSENT_ID,
},
[CPU_B2_FAN_RPM_INDEX] = {
.loc = "CPU B 2",
.type = FCU_FAN_RPM,
.id = FCU_FAN_ABSENT_ID,
},
[CPU_B3_FAN_RPM_INDEX] = {
.loc = "CPU B 3",
.type = FCU_FAN_RPM,
.id = FCU_FAN_ABSENT_ID,
},
};
static struct i2c_driver therm_pm72_driver;
/*
* Utility function to create an i2c_client structure and
* attach it to one of u3 adapters
*/
static struct i2c_client *attach_i2c_chip(int id, const char *name)
{
struct i2c_client *clt;
struct i2c_adapter *adap;
struct i2c_board_info info;
if (id & 0x200)
adap = k2;
else if (id & 0x100)
adap = u3_1;
else
adap = u3_0;
if (adap == NULL)
return NULL;
memset(&info, 0, sizeof(struct i2c_board_info));
info.addr = (id >> 1) & 0x7f;
strlcpy(info.type, "therm_pm72", I2C_NAME_SIZE);
clt = i2c_new_device(adap, &info);
if (!clt) {
printk(KERN_ERR "therm_pm72: Failed to attach to i2c ID 0x%x\n", id);
return NULL;
}
/*
* Let i2c-core delete that device on driver removal.
* This is safe because i2c-core holds the core_lock mutex for us.
*/
list_add_tail(&clt->detected, &therm_pm72_driver.clients);
return clt;
}
/*
* Here are the i2c chip access wrappers
*/
static void initialize_adc(struct cpu_pid_state *state)
{
int rc;
u8 buf[2];
/* Read ADC the configuration register and cache it. We
* also make sure Config2 contains proper values, I've seen
* cases where we got stale grabage in there, thus preventing
* proper reading of conv. values
*/
/* Clear Config2 */
buf[0] = 5;
buf[1] = 0;
i2c_master_send(state->monitor, buf, 2);
/* Read & cache Config1 */
buf[0] = 1;
rc = i2c_master_send(state->monitor, buf, 1);
if (rc > 0) {
rc = i2c_master_recv(state->monitor, buf, 1);
if (rc > 0) {
state->adc_config = buf[0];
DBG("ADC config reg: %02x\n", state->adc_config);
/* Disable shutdown mode */
state->adc_config &= 0xfe;
buf[0] = 1;
buf[1] = state->adc_config;
rc = i2c_master_send(state->monitor, buf, 2);
}
}
if (rc <= 0)
printk(KERN_ERR "therm_pm72: Error reading ADC config"
" register !\n");
}
static int read_smon_adc(struct cpu_pid_state *state, int chan)
{
int rc, data, tries = 0;
u8 buf[2];
for (;;) {
/* Set channel */
buf[0] = 1;
buf[1] = (state->adc_config & 0x1f) | (chan << 5);
rc = i2c_master_send(state->monitor, buf, 2);
if (rc <= 0)
goto error;
/* Wait for conversion */
msleep(1);
/* Switch to data register */
buf[0] = 4;
rc = i2c_master_send(state->monitor, buf, 1);
if (rc <= 0)
goto error;
/* Read result */
rc = i2c_master_recv(state->monitor, buf, 2);
if (rc < 0)
goto error;
data = ((u16)buf[0]) << 8 | (u16)buf[1];
return data >> 6;
error:
DBG("Error reading ADC, retrying...\n");
if (++tries > 10) {
printk(KERN_ERR "therm_pm72: Error reading ADC !\n");
return -1;
}
msleep(10);
}
}
static int read_lm87_reg(struct i2c_client * chip, int reg)
{
int rc, tries = 0;
u8 buf;
for (;;) {
/* Set address */
buf = (u8)reg;
rc = i2c_master_send(chip, &buf, 1);
if (rc <= 0)
goto error;
rc = i2c_master_recv(chip, &buf, 1);
if (rc <= 0)
goto error;
return (int)buf;
error:
DBG("Error reading LM87, retrying...\n");
if (++tries > 10) {
printk(KERN_ERR "therm_pm72: Error reading LM87 !\n");
return -1;
}
msleep(10);
}
}
static int fan_read_reg(int reg, unsigned char *buf, int nb)
{
int tries, nr, nw;
buf[0] = reg;
tries = 0;
for (;;) {
nw = i2c_master_send(fcu, buf, 1);
if (nw > 0 || (nw < 0 && nw != -EIO) || tries >= 100)
break;
msleep(10);
++tries;
}
if (nw <= 0) {
printk(KERN_ERR "Failure writing address to FCU: %d", nw);
return -EIO;
}
tries = 0;
for (;;) {
nr = i2c_master_recv(fcu, buf, nb);
if (nr > 0 || (nr < 0 && nr != -ENODEV) || tries >= 100)
break;
msleep(10);
++tries;
}
if (nr <= 0)
printk(KERN_ERR "Failure reading data from FCU: %d", nw);
return nr;
}
static int fan_write_reg(int reg, const unsigned char *ptr, int nb)
{
int tries, nw;
unsigned char buf[16];
buf[0] = reg;
memcpy(buf+1, ptr, nb);
++nb;
tries = 0;
for (;;) {
nw = i2c_master_send(fcu, buf, nb);
if (nw > 0 || (nw < 0 && nw != -EIO) || tries >= 100)
break;
msleep(10);
++tries;
}
if (nw < 0)
printk(KERN_ERR "Failure writing to FCU: %d", nw);
return nw;
}
static int start_fcu(void)
{
unsigned char buf = 0xff;
int rc;
rc = fan_write_reg(0xe, &buf, 1);
if (rc < 0)
return -EIO;
rc = fan_write_reg(0x2e, &buf, 1);
if (rc < 0)
return -EIO;
rc = fan_read_reg(0, &buf, 1);
if (rc < 0)
return -EIO;
fcu_rpm_shift = (buf == 1) ? 2 : 3;
printk(KERN_DEBUG "FCU Initialized, RPM fan shift is %d\n",
fcu_rpm_shift);
return 0;
}
static int set_rpm_fan(int fan_index, int rpm)
{
unsigned char buf[2];
int rc, id, min, max;
if (fcu_fans[fan_index].type != FCU_FAN_RPM)
return -EINVAL;
id = fcu_fans[fan_index].id;
if (id == FCU_FAN_ABSENT_ID)
return -EINVAL;
min = 2400 >> fcu_rpm_shift;
max = 56000 >> fcu_rpm_shift;
if (rpm < min)
rpm = min;
else if (rpm > max)
rpm = max;
buf[0] = rpm >> (8 - fcu_rpm_shift);
buf[1] = rpm << fcu_rpm_shift;
rc = fan_write_reg(0x10 + (id * 2), buf, 2);
if (rc < 0)
return -EIO;
return 0;
}
static int get_rpm_fan(int fan_index, int programmed)
{
unsigned char failure;
unsigned char active;
unsigned char buf[2];
int rc, id, reg_base;
if (fcu_fans[fan_index].type != FCU_FAN_RPM)
return -EINVAL;
id = fcu_fans[fan_index].id;
if (id == FCU_FAN_ABSENT_ID)
return -EINVAL;
rc = fan_read_reg(0xb, &failure, 1);
if (rc != 1)
return -EIO;
if ((failure & (1 << id)) != 0)
return -EFAULT;
rc = fan_read_reg(0xd, &active, 1);
if (rc != 1)
return -EIO;
if ((active & (1 << id)) == 0)
return -ENXIO;
/* Programmed value or real current speed */
reg_base = programmed ? 0x10 : 0x11;
rc = fan_read_reg(reg_base + (id * 2), buf, 2);
if (rc != 2)
return -EIO;
return (buf[0] << (8 - fcu_rpm_shift)) | buf[1] >> fcu_rpm_shift;
}
static int set_pwm_fan(int fan_index, int pwm)
{
unsigned char buf[2];
int rc, id;
if (fcu_fans[fan_index].type != FCU_FAN_PWM)
return -EINVAL;
id = fcu_fans[fan_index].id;
if (id == FCU_FAN_ABSENT_ID)
return -EINVAL;
if (pwm < 10)
pwm = 10;
else if (pwm > 100)
pwm = 100;
pwm = (pwm * 2559) / 1000;
buf[0] = pwm;
rc = fan_write_reg(0x30 + (id * 2), buf, 1);
if (rc < 0)
return rc;
return 0;
}
static int get_pwm_fan(int fan_index)
{
unsigned char failure;
unsigned char active;
unsigned char buf[2];
int rc, id;
if (fcu_fans[fan_index].type != FCU_FAN_PWM)
return -EINVAL;
id = fcu_fans[fan_index].id;
if (id == FCU_FAN_ABSENT_ID)
return -EINVAL;
rc = fan_read_reg(0x2b, &failure, 1);
if (rc != 1)
return -EIO;
if ((failure & (1 << id)) != 0)
return -EFAULT;
rc = fan_read_reg(0x2d, &active, 1);
if (rc != 1)
return -EIO;
if ((active & (1 << id)) == 0)
return -ENXIO;
/* Programmed value or real current speed */
rc = fan_read_reg(0x30 + (id * 2), buf, 1);
if (rc != 1)
return -EIO;
return (buf[0] * 1000) / 2559;
}
static void tickle_fcu(void)
{
int pwm;
pwm = get_pwm_fan(SLOTS_FAN_PWM_INDEX);
DBG("FCU Tickle, slots fan is: %d\n", pwm);
if (pwm < 0)
pwm = 100;
if (!rackmac) {
pwm = SLOTS_FAN_DEFAULT_PWM;
} else if (pwm < SLOTS_PID_OUTPUT_MIN)
pwm = SLOTS_PID_OUTPUT_MIN;
/* That is hopefully enough to make the FCU happy */
set_pwm_fan(SLOTS_FAN_PWM_INDEX, pwm);
}
/*
* Utility routine to read the CPU calibration EEPROM data
* from the device-tree
*/
static int read_eeprom(int cpu, struct mpu_data *out)
{
struct device_node *np;
char nodename[64];
const u8 *data;
int len;
/* prom.c routine for finding a node by path is a bit brain dead
* and requires exact @xxx unit numbers. This is a bit ugly but
* will work for these machines
*/
sprintf(nodename, "/u3@0,f8000000/i2c@f8001000/cpuid@a%d", cpu ? 2 : 0);
np = of_find_node_by_path(nodename);
if (np == NULL) {
printk(KERN_ERR "therm_pm72: Failed to retrieve cpuid node from device-tree\n");
return -ENODEV;
}
data = of_get_property(np, "cpuid", &len);
if (data == NULL) {
printk(KERN_ERR "therm_pm72: Failed to retrieve cpuid property from device-tree\n");
of_node_put(np);
return -ENODEV;
}
memcpy(out, data, sizeof(struct mpu_data));
of_node_put(np);
return 0;
}
static void fetch_cpu_pumps_minmax(void)
{
struct cpu_pid_state *state0 = &processor_state[0];
struct cpu_pid_state *state1 = &processor_state[1];
u16 pump_min = 0, pump_max = 0xffff;
u16 tmp[4];
/* Try to fetch pumps min/max infos from eeprom */
memcpy(&tmp, &state0->mpu.processor_part_num, 8);
if (tmp[0] != 0xffff && tmp[1] != 0xffff) {
pump_min = max(pump_min, tmp[0]);
pump_max = min(pump_max, tmp[1]);
}
if (tmp[2] != 0xffff && tmp[3] != 0xffff) {
pump_min = max(pump_min, tmp[2]);
pump_max = min(pump_max, tmp[3]);
}
/* Double check the values, this _IS_ needed as the EEPROM on
* some dual 2.5Ghz G5s seem, at least, to have both min & max
* same to the same value ... (grrrr)
*/
if (pump_min == pump_max || pump_min == 0 || pump_max == 0xffff) {
pump_min = CPU_PUMP_OUTPUT_MIN;
pump_max = CPU_PUMP_OUTPUT_MAX;
}
state0->pump_min = state1->pump_min = pump_min;
state0->pump_max = state1->pump_max = pump_max;
}
/*
* Now, unfortunately, sysfs doesn't give us a nice void * we could
* pass around to the attribute functions, so we don't really have
* choice but implement a bunch of them...
*
* That sucks a bit, we take the lock because FIX32TOPRINT evaluates
* the input twice... I accept patches :)
*/
#define BUILD_SHOW_FUNC_FIX(name, data) \
static ssize_t show_##name(struct device *dev, struct device_attribute *attr, char *buf) \
{ \
ssize_t r; \
mutex_lock(&driver_lock); \
r = sprintf(buf, "%d.%03d", FIX32TOPRINT(data)); \
mutex_unlock(&driver_lock); \
return r; \
}
#define BUILD_SHOW_FUNC_INT(name, data) \
static ssize_t show_##name(struct device *dev, struct device_attribute *attr, char *buf) \
{ \
return sprintf(buf, "%d", data); \
}
BUILD_SHOW_FUNC_FIX(cpu0_temperature, processor_state[0].last_temp)
BUILD_SHOW_FUNC_FIX(cpu0_voltage, processor_state[0].voltage)
BUILD_SHOW_FUNC_FIX(cpu0_current, processor_state[0].current_a)
BUILD_SHOW_FUNC_INT(cpu0_exhaust_fan_rpm, processor_state[0].rpm)
BUILD_SHOW_FUNC_INT(cpu0_intake_fan_rpm, processor_state[0].intake_rpm)
BUILD_SHOW_FUNC_FIX(cpu1_temperature, processor_state[1].last_temp)
BUILD_SHOW_FUNC_FIX(cpu1_voltage, processor_state[1].voltage)
BUILD_SHOW_FUNC_FIX(cpu1_current, processor_state[1].current_a)
BUILD_SHOW_FUNC_INT(cpu1_exhaust_fan_rpm, processor_state[1].rpm)
BUILD_SHOW_FUNC_INT(cpu1_intake_fan_rpm, processor_state[1].intake_rpm)
BUILD_SHOW_FUNC_FIX(backside_temperature, backside_state.last_temp)
BUILD_SHOW_FUNC_INT(backside_fan_pwm, backside_state.pwm)
BUILD_SHOW_FUNC_FIX(drives_temperature, drives_state.last_temp)
BUILD_SHOW_FUNC_INT(drives_fan_rpm, drives_state.rpm)
BUILD_SHOW_FUNC_FIX(slots_temperature, slots_state.last_temp)
BUILD_SHOW_FUNC_INT(slots_fan_pwm, slots_state.pwm)
BUILD_SHOW_FUNC_FIX(dimms_temperature, dimms_state.last_temp)
static DEVICE_ATTR(cpu0_temperature,S_IRUGO,show_cpu0_temperature,NULL);
static DEVICE_ATTR(cpu0_voltage,S_IRUGO,show_cpu0_voltage,NULL);
static DEVICE_ATTR(cpu0_current,S_IRUGO,show_cpu0_current,NULL);
static DEVICE_ATTR(cpu0_exhaust_fan_rpm,S_IRUGO,show_cpu0_exhaust_fan_rpm,NULL);
static DEVICE_ATTR(cpu0_intake_fan_rpm,S_IRUGO,show_cpu0_intake_fan_rpm,NULL);
static DEVICE_ATTR(cpu1_temperature,S_IRUGO,show_cpu1_temperature,NULL);
static DEVICE_ATTR(cpu1_voltage,S_IRUGO,show_cpu1_voltage,NULL);
static DEVICE_ATTR(cpu1_current,S_IRUGO,show_cpu1_current,NULL);
static DEVICE_ATTR(cpu1_exhaust_fan_rpm,S_IRUGO,show_cpu1_exhaust_fan_rpm,NULL);
static DEVICE_ATTR(cpu1_intake_fan_rpm,S_IRUGO,show_cpu1_intake_fan_rpm,NULL);
static DEVICE_ATTR(backside_temperature,S_IRUGO,show_backside_temperature,NULL);
static DEVICE_ATTR(backside_fan_pwm,S_IRUGO,show_backside_fan_pwm,NULL);
static DEVICE_ATTR(drives_temperature,S_IRUGO,show_drives_temperature,NULL);
static DEVICE_ATTR(drives_fan_rpm,S_IRUGO,show_drives_fan_rpm,NULL);
static DEVICE_ATTR(slots_temperature,S_IRUGO,show_slots_temperature,NULL);
static DEVICE_ATTR(slots_fan_pwm,S_IRUGO,show_slots_fan_pwm,NULL);
static DEVICE_ATTR(dimms_temperature,S_IRUGO,show_dimms_temperature,NULL);
/*
* CPUs fans control loop
*/
static int do_read_one_cpu_values(struct cpu_pid_state *state, s32 *temp, s32 *power)
{
s32 ltemp, volts, amps;
int index, rc = 0;
/* Default (in case of error) */
*temp = state->cur_temp;
*power = state->cur_power;
if (cpu_pid_type == CPU_PID_TYPE_RACKMAC)
index = (state->index == 0) ?
CPU_A1_FAN_RPM_INDEX : CPU_B1_FAN_RPM_INDEX;
else
index = (state->index == 0) ?
CPUA_EXHAUST_FAN_RPM_INDEX : CPUB_EXHAUST_FAN_RPM_INDEX;
/* Read current fan status */
rc = get_rpm_fan(index, !RPM_PID_USE_ACTUAL_SPEED);
if (rc < 0) {
/* XXX What do we do now ? Nothing for now, keep old value, but
* return error upstream
*/
DBG(" cpu %d, fan reading error !\n", state->index);
} else {
state->rpm = rc;
DBG(" cpu %d, exhaust RPM: %d\n", state->index, state->rpm);
}
/* Get some sensor readings and scale it */
ltemp = read_smon_adc(state, 1);
if (ltemp == -1) {
/* XXX What do we do now ? */
state->overtemp++;
if (rc == 0)
rc = -EIO;
DBG(" cpu %d, temp reading error !\n", state->index);
} else {
/* Fixup temperature according to diode calibration
*/
DBG(" cpu %d, temp raw: %04x, m_diode: %04x, b_diode: %04x\n",
state->index,
ltemp, state->mpu.mdiode, state->mpu.bdiode);
*temp = ((s32)ltemp * (s32)state->mpu.mdiode + ((s32)state->mpu.bdiode << 12)) >> 2;
state->last_temp = *temp;
DBG(" temp: %d.%03d\n", FIX32TOPRINT((*temp)));
}
/*
* Read voltage & current and calculate power
*/
volts = read_smon_adc(state, 3);
amps = read_smon_adc(state, 4);
/* Scale voltage and current raw sensor values according to fixed scales
* obtained in Darwin and calculate power from I and V
*/
volts *= ADC_CPU_VOLTAGE_SCALE;
amps *= ADC_CPU_CURRENT_SCALE;
*power = (((u64)volts) * ((u64)amps)) >> 16;
state->voltage = volts;
state->current_a = amps;
state->last_power = *power;
DBG(" cpu %d, current: %d.%03d, voltage: %d.%03d, power: %d.%03d W\n",
state->index, FIX32TOPRINT(state->current_a),
FIX32TOPRINT(state->voltage), FIX32TOPRINT(*power));
return 0;
}
static void do_cpu_pid(struct cpu_pid_state *state, s32 temp, s32 power)
{
s32 power_target, integral, derivative, proportional, adj_in_target, sval;
s64 integ_p, deriv_p, prop_p, sum;
int i;
/* Calculate power target value (could be done once for all)
* and convert to a 16.16 fp number
*/
power_target = ((u32)(state->mpu.pmaxh - state->mpu.padjmax)) << 16;
DBG(" power target: %d.%03d, error: %d.%03d\n",
FIX32TOPRINT(power_target), FIX32TOPRINT(power_target - power));
/* Store temperature and power in history array */
state->cur_temp = (state->cur_temp + 1) % CPU_TEMP_HISTORY_SIZE;
state->temp_history[state->cur_temp] = temp;
state->cur_power = (state->cur_power + 1) % state->count_power;
state->power_history[state->cur_power] = power;
state->error_history[state->cur_power] = power_target - power;
/* If first loop, fill the history table */
if (state->first) {
for (i = 0; i < (state->count_power - 1); i++) {
state->cur_power = (state->cur_power + 1) % state->count_power;
state->power_history[state->cur_power] = power;
state->error_history[state->cur_power] = power_target - power;
}
for (i = 0; i < (CPU_TEMP_HISTORY_SIZE - 1); i++) {
state->cur_temp = (state->cur_temp + 1) % CPU_TEMP_HISTORY_SIZE;
state->temp_history[state->cur_temp] = temp;
}
state->first = 0;
}
/* Calculate the integral term normally based on the "power" values */
sum = 0;
integral = 0;
for (i = 0; i < state->count_power; i++)
integral += state->error_history[i];
integral *= CPU_PID_INTERVAL;
DBG(" integral: %08x\n", integral);
/* Calculate the adjusted input (sense value).
* G_r is 12.20
* integ is 16.16
* so the result is 28.36
*
* input target is mpu.ttarget, input max is mpu.tmax
*/
integ_p = ((s64)state->mpu.pid_gr) * (s64)integral;
DBG(" integ_p: %d\n", (int)(integ_p >> 36));
sval = (state->mpu.tmax << 16) - ((integ_p >> 20) & 0xffffffff);
adj_in_target = (state->mpu.ttarget << 16);
if (adj_in_target > sval)
adj_in_target = sval;
DBG(" adj_in_target: %d.%03d, ttarget: %d\n", FIX32TOPRINT(adj_in_target),
state->mpu.ttarget);
/* Calculate the derivative term */
derivative = state->temp_history[state->cur_temp] -
state->temp_history[(state->cur_temp + CPU_TEMP_HISTORY_SIZE - 1)
% CPU_TEMP_HISTORY_SIZE];
derivative /= CPU_PID_INTERVAL;
deriv_p = ((s64)state->mpu.pid_gd) * (s64)derivative;
DBG(" deriv_p: %d\n", (int)(deriv_p >> 36));
sum += deriv_p;
/* Calculate the proportional term */
proportional = temp - adj_in_target;
prop_p = ((s64)state->mpu.pid_gp) * (s64)proportional;
DBG(" prop_p: %d\n", (int)(prop_p >> 36));
sum += prop_p;
/* Scale sum */
sum >>= 36;
DBG(" sum: %d\n", (int)sum);
state->rpm += (s32)sum;
}
static void do_monitor_cpu_combined(void)
{
struct cpu_pid_state *state0 = &processor_state[0];
struct cpu_pid_state *state1 = &processor_state[1];
s32 temp0, power0, temp1, power1;
s32 temp_combi, power_combi;
int rc, intake, pump;
rc = do_read_one_cpu_values(state0, &temp0, &power0);
if (rc < 0) {
/* XXX What do we do now ? */
}
state1->overtemp = 0;
rc = do_read_one_cpu_values(state1, &temp1, &power1);
if (rc < 0) {
/* XXX What do we do now ? */
}
if (state1->overtemp)
state0->overtemp++;
temp_combi = max(temp0, temp1);
power_combi = max(power0, power1);
/* Check tmax, increment overtemp if we are there. At tmax+8, we go
* full blown immediately and try to trigger a shutdown
*/
if (temp_combi >= ((state0->mpu.tmax + 8) << 16)) {
printk(KERN_WARNING "Warning ! Temperature way above maximum (%d) !\n",
temp_combi >> 16);
state0->overtemp += CPU_MAX_OVERTEMP / 4;
} else if (temp_combi > (state0->mpu.tmax << 16)) {
state0->overtemp++;
printk(KERN_WARNING "Temperature %d above max %d. overtemp %d\n",
temp_combi >> 16, state0->mpu.tmax, state0->overtemp);
} else {
if (state0->overtemp)
printk(KERN_WARNING "Temperature back down to %d\n",
temp_combi >> 16);
state0->overtemp = 0;
}
if (state0->overtemp >= CPU_MAX_OVERTEMP)
critical_state = 1;
if (state0->overtemp > 0) {
state0->rpm = state0->mpu.rmaxn_exhaust_fan;
state0->intake_rpm = intake = state0->mpu.rmaxn_intake_fan;
pump = state0->pump_max;
goto do_set_fans;
}
/* Do the PID */
do_cpu_pid(state0, temp_combi, power_combi);
/* Range check */
state0->rpm = max(state0->rpm, (int)state0->mpu.rminn_exhaust_fan);
state0->rpm = min(state0->rpm, (int)state0->mpu.rmaxn_exhaust_fan);
/* Calculate intake fan speed */
intake = (state0->rpm * CPU_INTAKE_SCALE) >> 16;
intake = max(intake, (int)state0->mpu.rminn_intake_fan);
intake = min(intake, (int)state0->mpu.rmaxn_intake_fan);
state0->intake_rpm = intake;
/* Calculate pump speed */
pump = (state0->rpm * state0->pump_max) /
state0->mpu.rmaxn_exhaust_fan;
pump = min(pump, state0->pump_max);
pump = max(pump, state0->pump_min);
do_set_fans:
/* We copy values from state 0 to state 1 for /sysfs */
state1->rpm = state0->rpm;
state1->intake_rpm = state0->intake_rpm;
DBG("** CPU %d RPM: %d Ex, %d, Pump: %d, In, overtemp: %d\n",
state1->index, (int)state1->rpm, intake, pump, state1->overtemp);
/* We should check for errors, shouldn't we ? But then, what
* do we do once the error occurs ? For FCU notified fan
* failures (-EFAULT) we probably want to notify userland
* some way...
*/
set_rpm_fan(CPUA_INTAKE_FAN_RPM_INDEX, intake);
set_rpm_fan(CPUA_EXHAUST_FAN_RPM_INDEX, state0->rpm);
set_rpm_fan(CPUB_INTAKE_FAN_RPM_INDEX, intake);
set_rpm_fan(CPUB_EXHAUST_FAN_RPM_INDEX, state0->rpm);
if (fcu_fans[CPUA_PUMP_RPM_INDEX].id != FCU_FAN_ABSENT_ID)
set_rpm_fan(CPUA_PUMP_RPM_INDEX, pump);
if (fcu_fans[CPUB_PUMP_RPM_INDEX].id != FCU_FAN_ABSENT_ID)
set_rpm_fan(CPUB_PUMP_RPM_INDEX, pump);
}
static void do_monitor_cpu_split(struct cpu_pid_state *state)
{
s32 temp, power;
int rc, intake;
/* Read current fan status */
rc = do_read_one_cpu_values(state, &temp, &power);
if (rc < 0) {
/* XXX What do we do now ? */
}
/* Check tmax, increment overtemp if we are there. At tmax+8, we go
* full blown immediately and try to trigger a shutdown
*/
if (temp >= ((state->mpu.tmax + 8) << 16)) {
printk(KERN_WARNING "Warning ! CPU %d temperature way above maximum"
" (%d) !\n",
state->index, temp >> 16);
state->overtemp += CPU_MAX_OVERTEMP / 4;
} else if (temp > (state->mpu.tmax << 16)) {
state->overtemp++;
printk(KERN_WARNING "CPU %d temperature %d above max %d. overtemp %d\n",
state->index, temp >> 16, state->mpu.tmax, state->overtemp);
} else {
if (state->overtemp)
printk(KERN_WARNING "CPU %d temperature back down to %d\n",
state->index, temp >> 16);
state->overtemp = 0;
}
if (state->overtemp >= CPU_MAX_OVERTEMP)
critical_state = 1;
if (state->overtemp > 0) {
state->rpm = state->mpu.rmaxn_exhaust_fan;
state->intake_rpm = intake = state->mpu.rmaxn_intake_fan;
goto do_set_fans;
}
/* Do the PID */
do_cpu_pid(state, temp, power);
/* Range check */
state->rpm = max(state->rpm, (int)state->mpu.rminn_exhaust_fan);
state->rpm = min(state->rpm, (int)state->mpu.rmaxn_exhaust_fan);
/* Calculate intake fan */
intake = (state->rpm * CPU_INTAKE_SCALE) >> 16;
intake = max(intake, (int)state->mpu.rminn_intake_fan);
intake = min(intake, (int)state->mpu.rmaxn_intake_fan);
state->intake_rpm = intake;
do_set_fans:
DBG("** CPU %d RPM: %d Ex, %d In, overtemp: %d\n",
state->index, (int)state->rpm, intake, state->overtemp);
/* We should check for errors, shouldn't we ? But then, what
* do we do once the error occurs ? For FCU notified fan
* failures (-EFAULT) we probably want to notify userland
* some way...
*/
if (state->index == 0) {
set_rpm_fan(CPUA_INTAKE_FAN_RPM_INDEX, intake);
set_rpm_fan(CPUA_EXHAUST_FAN_RPM_INDEX, state->rpm);
} else {
set_rpm_fan(CPUB_INTAKE_FAN_RPM_INDEX, intake);
set_rpm_fan(CPUB_EXHAUST_FAN_RPM_INDEX, state->rpm);
}
}
static void do_monitor_cpu_rack(struct cpu_pid_state *state)
{
s32 temp, power, fan_min;
int rc;
/* Read current fan status */
rc = do_read_one_cpu_values(state, &temp, &power);
if (rc < 0) {
/* XXX What do we do now ? */
}
/* Check tmax, increment overtemp if we are there. At tmax+8, we go
* full blown immediately and try to trigger a shutdown
*/
if (temp >= ((state->mpu.tmax + 8) << 16)) {
printk(KERN_WARNING "Warning ! CPU %d temperature way above maximum"
" (%d) !\n",
state->index, temp >> 16);
state->overtemp = CPU_MAX_OVERTEMP / 4;
} else if (temp > (state->mpu.tmax << 16)) {
state->overtemp++;
printk(KERN_WARNING "CPU %d temperature %d above max %d. overtemp %d\n",
state->index, temp >> 16, state->mpu.tmax, state->overtemp);
} else {
if (state->overtemp)
printk(KERN_WARNING "CPU %d temperature back down to %d\n",
state->index, temp >> 16);
state->overtemp = 0;
}
if (state->overtemp >= CPU_MAX_OVERTEMP)
critical_state = 1;
if (state->overtemp > 0) {
state->rpm = state->intake_rpm = state->mpu.rmaxn_intake_fan;
goto do_set_fans;
}
/* Do the PID */
do_cpu_pid(state, temp, power);
/* Check clamp from dimms */
fan_min = dimm_output_clamp;
fan_min = max(fan_min, (int)state->mpu.rminn_intake_fan);
DBG(" CPU min mpu = %d, min dimm = %d\n",
state->mpu.rminn_intake_fan, dimm_output_clamp);
state->rpm = max(state->rpm, (int)fan_min);
state->rpm = min(state->rpm, (int)state->mpu.rmaxn_intake_fan);
state->intake_rpm = state->rpm;
do_set_fans:
DBG("** CPU %d RPM: %d overtemp: %d\n",
state->index, (int)state->rpm, state->overtemp);
/* We should check for errors, shouldn't we ? But then, what
* do we do once the error occurs ? For FCU notified fan
* failures (-EFAULT) we probably want to notify userland
* some way...
*/
if (state->index == 0) {
set_rpm_fan(CPU_A1_FAN_RPM_INDEX, state->rpm);
set_rpm_fan(CPU_A2_FAN_RPM_INDEX, state->rpm);
set_rpm_fan(CPU_A3_FAN_RPM_INDEX, state->rpm);
} else {
set_rpm_fan(CPU_B1_FAN_RPM_INDEX, state->rpm);
set_rpm_fan(CPU_B2_FAN_RPM_INDEX, state->rpm);
set_rpm_fan(CPU_B3_FAN_RPM_INDEX, state->rpm);
}
}
/*
* Initialize the state structure for one CPU control loop
*/
static int init_processor_state(struct cpu_pid_state *state, int index)
{
int err;
state->index = index;
state->first = 1;
state->rpm = (cpu_pid_type == CPU_PID_TYPE_RACKMAC) ? 4000 : 1000;
state->overtemp = 0;
state->adc_config = 0x00;
if (index == 0)
state->monitor = attach_i2c_chip(SUPPLY_MONITOR_ID, "CPU0_monitor");
else if (index == 1)
state->monitor = attach_i2c_chip(SUPPLY_MONITORB_ID, "CPU1_monitor");
if (state->monitor == NULL)
goto fail;
if (read_eeprom(index, &state->mpu))
goto fail;
state->count_power = state->mpu.tguardband;
if (state->count_power > CPU_POWER_HISTORY_SIZE) {
printk(KERN_WARNING "Warning ! too many power history slots\n");
state->count_power = CPU_POWER_HISTORY_SIZE;
}
DBG("CPU %d Using %d power history entries\n", index, state->count_power);
if (index == 0) {
err = device_create_file(&of_dev->dev, &dev_attr_cpu0_temperature);
err |= device_create_file(&of_dev->dev, &dev_attr_cpu0_voltage);
err |= device_create_file(&of_dev->dev, &dev_attr_cpu0_current);
err |= device_create_file(&of_dev->dev, &dev_attr_cpu0_exhaust_fan_rpm);
err |= device_create_file(&of_dev->dev, &dev_attr_cpu0_intake_fan_rpm);
} else {
err = device_create_file(&of_dev->dev, &dev_attr_cpu1_temperature);
err |= device_create_file(&of_dev->dev, &dev_attr_cpu1_voltage);
err |= device_create_file(&of_dev->dev, &dev_attr_cpu1_current);
err |= device_create_file(&of_dev->dev, &dev_attr_cpu1_exhaust_fan_rpm);
err |= device_create_file(&of_dev->dev, &dev_attr_cpu1_intake_fan_rpm);
}
if (err)
printk(KERN_WARNING "Failed to create some of the attribute"
"files for CPU %d\n", index);
return 0;
fail:
state->monitor = NULL;
return -ENODEV;
}
/*
* Dispose of the state data for one CPU control loop
*/
static void dispose_processor_state(struct cpu_pid_state *state)
{
if (state->monitor == NULL)
return;
if (state->index == 0) {
device_remove_file(&of_dev->dev, &dev_attr_cpu0_temperature);
device_remove_file(&of_dev->dev, &dev_attr_cpu0_voltage);
device_remove_file(&of_dev->dev, &dev_attr_cpu0_current);
device_remove_file(&of_dev->dev, &dev_attr_cpu0_exhaust_fan_rpm);
device_remove_file(&of_dev->dev, &dev_attr_cpu0_intake_fan_rpm);
} else {
device_remove_file(&of_dev->dev, &dev_attr_cpu1_temperature);
device_remove_file(&of_dev->dev, &dev_attr_cpu1_voltage);
device_remove_file(&of_dev->dev, &dev_attr_cpu1_current);
device_remove_file(&of_dev->dev, &dev_attr_cpu1_exhaust_fan_rpm);
device_remove_file(&of_dev->dev, &dev_attr_cpu1_intake_fan_rpm);
}
state->monitor = NULL;
}
/*
* Motherboard backside & U3 heatsink fan control loop
*/
static void do_monitor_backside(struct backside_pid_state *state)
{
s32 temp, integral, derivative, fan_min;
s64 integ_p, deriv_p, prop_p, sum;
int i, rc;
if (--state->ticks != 0)
return;
state->ticks = backside_params.interval;
DBG("backside:\n");
/* Check fan status */
rc = get_pwm_fan(BACKSIDE_FAN_PWM_INDEX);
if (rc < 0) {
printk(KERN_WARNING "Error %d reading backside fan !\n", rc);
/* XXX What do we do now ? */
} else
state->pwm = rc;
DBG(" current pwm: %d\n", state->pwm);
/* Get some sensor readings */
temp = i2c_smbus_read_byte_data(state->monitor, MAX6690_EXT_TEMP) << 16;
state->last_temp = temp;
DBG(" temp: %d.%03d, target: %d.%03d\n", FIX32TOPRINT(temp),
FIX32TOPRINT(backside_params.input_target));
/* Store temperature and error in history array */
state->cur_sample = (state->cur_sample + 1) % BACKSIDE_PID_HISTORY_SIZE;
state->sample_history[state->cur_sample] = temp;
state->error_history[state->cur_sample] = temp - backside_params.input_target;
/* If first loop, fill the history table */
if (state->first) {
for (i = 0; i < (BACKSIDE_PID_HISTORY_SIZE - 1); i++) {
state->cur_sample = (state->cur_sample + 1) %
BACKSIDE_PID_HISTORY_SIZE;
state->sample_history[state->cur_sample] = temp;
state->error_history[state->cur_sample] =
temp - backside_params.input_target;
}
state->first = 0;
}
/* Calculate the integral term */
sum = 0;
integral = 0;
for (i = 0; i < BACKSIDE_PID_HISTORY_SIZE; i++)
integral += state->error_history[i];
integral *= backside_params.interval;
DBG(" integral: %08x\n", integral);
integ_p = ((s64)backside_params.G_r) * (s64)integral;
DBG(" integ_p: %d\n", (int)(integ_p >> 36));
sum += integ_p;
/* Calculate the derivative term */
derivative = state->error_history[state->cur_sample] -
state->error_history[(state->cur_sample + BACKSIDE_PID_HISTORY_SIZE - 1)
% BACKSIDE_PID_HISTORY_SIZE];
derivative /= backside_params.interval;
deriv_p = ((s64)backside_params.G_d) * (s64)derivative;
DBG(" deriv_p: %d\n", (int)(deriv_p >> 36));
sum += deriv_p;
/* Calculate the proportional term */
prop_p = ((s64)backside_params.G_p) * (s64)(state->error_history[state->cur_sample]);
DBG(" prop_p: %d\n", (int)(prop_p >> 36));
sum += prop_p;
/* Scale sum */
sum >>= 36;
DBG(" sum: %d\n", (int)sum);
if (backside_params.additive)
state->pwm += (s32)sum;
else
state->pwm = sum;
/* Check for clamp */
fan_min = (dimm_output_clamp * 100) / 14000;
fan_min = max(fan_min, backside_params.output_min);
state->pwm = max(state->pwm, fan_min);
state->pwm = min(state->pwm, backside_params.output_max);
DBG("** BACKSIDE PWM: %d\n", (int)state->pwm);
set_pwm_fan(BACKSIDE_FAN_PWM_INDEX, state->pwm);
}
/*
* Initialize the state structure for the backside fan control loop
*/
static int init_backside_state(struct backside_pid_state *state)
{
struct device_node *u3;
int u3h = 1; /* conservative by default */
int err;
/*
* There are different PID params for machines with U3 and machines
* with U3H, pick the right ones now
*/
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);
}
if (rackmac) {
backside_params.G_d = BACKSIDE_PID_RACK_G_d;
backside_params.input_target = BACKSIDE_PID_RACK_INPUT_TARGET;
backside_params.output_min = BACKSIDE_PID_U3H_OUTPUT_MIN;
backside_params.interval = BACKSIDE_PID_RACK_INTERVAL;
backside_params.G_p = BACKSIDE_PID_RACK_G_p;
backside_params.G_r = BACKSIDE_PID_G_r;
backside_params.output_max = BACKSIDE_PID_OUTPUT_MAX;
backside_params.additive = 0;
} else if (u3h) {
backside_params.G_d = BACKSIDE_PID_U3H_G_d;
backside_params.input_target = BACKSIDE_PID_U3H_INPUT_TARGET;
backside_params.output_min = BACKSIDE_PID_U3H_OUTPUT_MIN;
backside_params.interval = BACKSIDE_PID_INTERVAL;
backside_params.G_p = BACKSIDE_PID_G_p;
backside_params.G_r = BACKSIDE_PID_G_r;
backside_params.output_max = BACKSIDE_PID_OUTPUT_MAX;
backside_params.additive = 1;
} else {
backside_params.G_d = BACKSIDE_PID_U3_G_d;
backside_params.input_target = BACKSIDE_PID_U3_INPUT_TARGET;
backside_params.output_min = BACKSIDE_PID_U3_OUTPUT_MIN;
backside_params.interval = BACKSIDE_PID_INTERVAL;
backside_params.G_p = BACKSIDE_PID_G_p;
backside_params.G_r = BACKSIDE_PID_G_r;
backside_params.output_max = BACKSIDE_PID_OUTPUT_MAX;
backside_params.additive = 1;
}
state->ticks = 1;
state->first = 1;
state->pwm = 50;
state->monitor = attach_i2c_chip(BACKSIDE_MAX_ID, "backside_temp");
if (state->monitor == NULL)
return -ENODEV;
err = device_create_file(&of_dev->dev, &dev_attr_backside_temperature);
err |= device_create_file(&of_dev->dev, &dev_attr_backside_fan_pwm);
if (err)
printk(KERN_WARNING "Failed to create attribute file(s)"
" for backside fan\n");
return 0;
}
/*
* Dispose of the state data for the backside control loop
*/
static void dispose_backside_state(struct backside_pid_state *state)
{
if (state->monitor == NULL)
return;
device_remove_file(&of_dev->dev, &dev_attr_backside_temperature);
device_remove_file(&of_dev->dev, &dev_attr_backside_fan_pwm);
state->monitor = NULL;
}
/*
* Drives bay fan control loop
*/
static void do_monitor_drives(struct drives_pid_state *state)
{
s32 temp, integral, derivative;
s64 integ_p, deriv_p, prop_p, sum;
int i, rc;
if (--state->ticks != 0)
return;
state->ticks = DRIVES_PID_INTERVAL;
DBG("drives:\n");
/* Check fan status */
rc = get_rpm_fan(DRIVES_FAN_RPM_INDEX, !RPM_PID_USE_ACTUAL_SPEED);
if (rc < 0) {
printk(KERN_WARNING "Error %d reading drives fan !\n", rc);
/* XXX What do we do now ? */
} else
state->rpm = rc;
DBG(" current rpm: %d\n", state->rpm);
/* Get some sensor readings */
temp = le16_to_cpu(i2c_smbus_read_word_data(state->monitor,
DS1775_TEMP)) << 8;
state->last_temp = temp;
DBG(" temp: %d.%03d, target: %d.%03d\n", FIX32TOPRINT(temp),
FIX32TOPRINT(DRIVES_PID_INPUT_TARGET));
/* Store temperature and error in history array */
state->cur_sample = (state->cur_sample + 1) % DRIVES_PID_HISTORY_SIZE;
state->sample_history[state->cur_sample] = temp;
state->error_history[state->cur_sample] = temp - DRIVES_PID_INPUT_TARGET;
/* If first loop, fill the history table */
if (state->first) {
for (i = 0; i < (DRIVES_PID_HISTORY_SIZE - 1); i++) {
state->cur_sample = (state->cur_sample + 1) %
DRIVES_PID_HISTORY_SIZE;
state->sample_history[state->cur_sample] = temp;
state->error_history[state->cur_sample] =
temp - DRIVES_PID_INPUT_TARGET;
}
state->first = 0;
}
/* Calculate the integral term */
sum = 0;
integral = 0;
for (i = 0; i < DRIVES_PID_HISTORY_SIZE; i++)
integral += state->error_history[i];
integral *= DRIVES_PID_INTERVAL;
DBG(" integral: %08x\n", integral);
integ_p = ((s64)DRIVES_PID_G_r) * (s64)integral;
DBG(" integ_p: %d\n", (int)(integ_p >> 36));
sum += integ_p;
/* Calculate the derivative term */
derivative = state->error_history[state->cur_sample] -
state->error_history[(state->cur_sample + DRIVES_PID_HISTORY_SIZE - 1)
% DRIVES_PID_HISTORY_SIZE];
derivative /= DRIVES_PID_INTERVAL;
deriv_p = ((s64)DRIVES_PID_G_d) * (s64)derivative;
DBG(" deriv_p: %d\n", (int)(deriv_p >> 36));
sum += deriv_p;
/* Calculate the proportional term */
prop_p = ((s64)DRIVES_PID_G_p) * (s64)(state->error_history[state->cur_sample]);
DBG(" prop_p: %d\n", (int)(prop_p >> 36));
sum += prop_p;
/* Scale sum */
sum >>= 36;
DBG(" sum: %d\n", (int)sum);
state->rpm += (s32)sum;
state->rpm = max(state->rpm, DRIVES_PID_OUTPUT_MIN);
state->rpm = min(state->rpm, DRIVES_PID_OUTPUT_MAX);
DBG("** DRIVES RPM: %d\n", (int)state->rpm);
set_rpm_fan(DRIVES_FAN_RPM_INDEX, state->rpm);
}
/*
* Initialize the state structure for the drives bay fan control loop
*/
static int init_drives_state(struct drives_pid_state *state)
{
int err;
state->ticks = 1;
state->first = 1;
state->rpm = 1000;
state->monitor = attach_i2c_chip(DRIVES_DALLAS_ID, "drives_temp");
if (state->monitor == NULL)
return -ENODEV;
err = device_create_file(&of_dev->dev, &dev_attr_drives_temperature);
err |= device_create_file(&of_dev->dev, &dev_attr_drives_fan_rpm);
if (err)
printk(KERN_WARNING "Failed to create attribute file(s)"
" for drives bay fan\n");
return 0;
}
/*
* Dispose of the state data for the drives control loop
*/
static void dispose_drives_state(struct drives_pid_state *state)
{
if (state->monitor == NULL)
return;
device_remove_file(&of_dev->dev, &dev_attr_drives_temperature);
device_remove_file(&of_dev->dev, &dev_attr_drives_fan_rpm);
state->monitor = NULL;
}
/*
* DIMMs temp control loop
*/
static void do_monitor_dimms(struct dimm_pid_state *state)
{
s32 temp, integral, derivative, fan_min;
s64 integ_p, deriv_p, prop_p, sum;
int i;
if (--state->ticks != 0)
return;
state->ticks = DIMM_PID_INTERVAL;
DBG("DIMM:\n");
DBG(" current value: %d\n", state->output);
temp = read_lm87_reg(state->monitor, LM87_INT_TEMP);
if (temp < 0)
return;
temp <<= 16;
state->last_temp = temp;
DBG(" temp: %d.%03d, target: %d.%03d\n", FIX32TOPRINT(temp),
FIX32TOPRINT(DIMM_PID_INPUT_TARGET));
/* Store temperature and error in history array */
state->cur_sample = (state->cur_sample + 1) % DIMM_PID_HISTORY_SIZE;
state->sample_history[state->cur_sample] = temp;
state->error_history[state->cur_sample] = temp - DIMM_PID_INPUT_TARGET;
/* If first loop, fill the history table */
if (state->first) {
for (i = 0; i < (DIMM_PID_HISTORY_SIZE - 1); i++) {
state->cur_sample = (state->cur_sample + 1) %
DIMM_PID_HISTORY_SIZE;
state->sample_history[state->cur_sample] = temp;
state->error_history[state->cur_sample] =
temp - DIMM_PID_INPUT_TARGET;
}
state->first = 0;
}
/* Calculate the integral term */
sum = 0;
integral = 0;
for (i = 0; i < DIMM_PID_HISTORY_SIZE; i++)
integral += state->error_history[i];
integral *= DIMM_PID_INTERVAL;
DBG(" integral: %08x\n", integral);
integ_p = ((s64)DIMM_PID_G_r) * (s64)integral;
DBG(" integ_p: %d\n", (int)(integ_p >> 36));
sum += integ_p;
/* Calculate the derivative term */
derivative = state->error_history[state->cur_sample] -
state->error_history[(state->cur_sample + DIMM_PID_HISTORY_SIZE - 1)
% DIMM_PID_HISTORY_SIZE];
derivative /= DIMM_PID_INTERVAL;
deriv_p = ((s64)DIMM_PID_G_d) * (s64)derivative;
DBG(" deriv_p: %d\n", (int)(deriv_p >> 36));
sum += deriv_p;
/* Calculate the proportional term */
prop_p = ((s64)DIMM_PID_G_p) * (s64)(state->error_history[state->cur_sample]);
DBG(" prop_p: %d\n", (int)(prop_p >> 36));
sum += prop_p;
/* Scale sum */
sum >>= 36;
DBG(" sum: %d\n", (int)sum);
state->output = (s32)sum;
state->output = max(state->output, DIMM_PID_OUTPUT_MIN);
state->output = min(state->output, DIMM_PID_OUTPUT_MAX);
dimm_output_clamp = state->output;
DBG("** DIMM clamp value: %d\n", (int)state->output);
/* Backside PID is only every 5 seconds, force backside fan clamping now */
fan_min = (dimm_output_clamp * 100) / 14000;
fan_min = max(fan_min, backside_params.output_min);
if (backside_state.pwm < fan_min) {
backside_state.pwm = fan_min;
DBG(" -> applying clamp to backside fan now: %d !\n", fan_min);
set_pwm_fan(BACKSIDE_FAN_PWM_INDEX, fan_min);
}
}
/*
* Initialize the state structure for the DIMM temp control loop
*/
static int init_dimms_state(struct dimm_pid_state *state)
{
state->ticks = 1;
state->first = 1;
state->output = 4000;
state->monitor = attach_i2c_chip(XSERVE_DIMMS_LM87, "dimms_temp");
if (state->monitor == NULL)
return -ENODEV;
if (device_create_file(&of_dev->dev, &dev_attr_dimms_temperature))
printk(KERN_WARNING "Failed to create attribute file"
" for DIMM temperature\n");
return 0;
}
/*
* Dispose of the state data for the DIMM control loop
*/
static void dispose_dimms_state(struct dimm_pid_state *state)
{
if (state->monitor == NULL)
return;
device_remove_file(&of_dev->dev, &dev_attr_dimms_temperature);
state->monitor = NULL;
}
/*
* Slots fan control loop
*/
static void do_monitor_slots(struct slots_pid_state *state)
{
s32 temp, integral, derivative;
s64 integ_p, deriv_p, prop_p, sum;
int i, rc;
if (--state->ticks != 0)
return;
state->ticks = SLOTS_PID_INTERVAL;
DBG("slots:\n");
/* Check fan status */
rc = get_pwm_fan(SLOTS_FAN_PWM_INDEX);
if (rc < 0) {
printk(KERN_WARNING "Error %d reading slots fan !\n", rc);
/* XXX What do we do now ? */
} else
state->pwm = rc;
DBG(" current pwm: %d\n", state->pwm);
/* Get some sensor readings */
temp = le16_to_cpu(i2c_smbus_read_word_data(state->monitor,
DS1775_TEMP)) << 8;
state->last_temp = temp;
DBG(" temp: %d.%03d, target: %d.%03d\n", FIX32TOPRINT(temp),
FIX32TOPRINT(SLOTS_PID_INPUT_TARGET));
/* Store temperature and error in history array */
state->cur_sample = (state->cur_sample + 1) % SLOTS_PID_HISTORY_SIZE;
state->sample_history[state->cur_sample] = temp;
state->error_history[state->cur_sample] = temp - SLOTS_PID_INPUT_TARGET;
/* If first loop, fill the history table */
if (state->first) {
for (i = 0; i < (SLOTS_PID_HISTORY_SIZE - 1); i++) {
state->cur_sample = (state->cur_sample + 1) %
SLOTS_PID_HISTORY_SIZE;
state->sample_history[state->cur_sample] = temp;
state->error_history[state->cur_sample] =
temp - SLOTS_PID_INPUT_TARGET;
}
state->first = 0;
}
/* Calculate the integral term */
sum = 0;
integral = 0;
for (i = 0; i < SLOTS_PID_HISTORY_SIZE; i++)
integral += state->error_history[i];
integral *= SLOTS_PID_INTERVAL;
DBG(" integral: %08x\n", integral);
integ_p = ((s64)SLOTS_PID_G_r) * (s64)integral;
DBG(" integ_p: %d\n", (int)(integ_p >> 36));
sum += integ_p;
/* Calculate the derivative term */
derivative = state->error_history[state->cur_sample] -
state->error_history[(state->cur_sample + SLOTS_PID_HISTORY_SIZE - 1)
% SLOTS_PID_HISTORY_SIZE];
derivative /= SLOTS_PID_INTERVAL;
deriv_p = ((s64)SLOTS_PID_G_d) * (s64)derivative;
DBG(" deriv_p: %d\n", (int)(deriv_p >> 36));
sum += deriv_p;
/* Calculate the proportional term */
prop_p = ((s64)SLOTS_PID_G_p) * (s64)(state->error_history[state->cur_sample]);
DBG(" prop_p: %d\n", (int)(prop_p >> 36));
sum += prop_p;
/* Scale sum */
sum >>= 36;
DBG(" sum: %d\n", (int)sum);
state->pwm = (s32)sum;
state->pwm = max(state->pwm, SLOTS_PID_OUTPUT_MIN);
state->pwm = min(state->pwm, SLOTS_PID_OUTPUT_MAX);
DBG("** DRIVES PWM: %d\n", (int)state->pwm);
set_pwm_fan(SLOTS_FAN_PWM_INDEX, state->pwm);
}
/*
* Initialize the state structure for the slots bay fan control loop
*/
static int init_slots_state(struct slots_pid_state *state)
{
int err;
state->ticks = 1;
state->first = 1;
state->pwm = 50;
state->monitor = attach_i2c_chip(XSERVE_SLOTS_LM75, "slots_temp");
if (state->monitor == NULL)
return -ENODEV;
err = device_create_file(&of_dev->dev, &dev_attr_slots_temperature);
err |= device_create_file(&of_dev->dev, &dev_attr_slots_fan_pwm);
if (err)
printk(KERN_WARNING "Failed to create attribute file(s)"
" for slots bay fan\n");
return 0;
}
/*
* Dispose of the state data for the slots control loop
*/
static void dispose_slots_state(struct slots_pid_state *state)
{
if (state->monitor == NULL)
return;
device_remove_file(&of_dev->dev, &dev_attr_slots_temperature);
device_remove_file(&of_dev->dev, &dev_attr_slots_fan_pwm);
state->monitor = NULL;
}
static int call_critical_overtemp(void)
{
char *argv[] = { critical_overtemp_path, NULL };
static char *envp[] = { "HOME=/",
"TERM=linux",
"PATH=/sbin:/usr/sbin:/bin:/usr/bin",
NULL };
return call_usermodehelper(critical_overtemp_path,
argv, envp, UMH_WAIT_EXEC);
}
/*
* Here's the kernel thread that calls the various control loops
*/
static int main_control_loop(void *x)
{
DBG("main_control_loop started\n");
mutex_lock(&driver_lock);
if (start_fcu() < 0) {
printk(KERN_ERR "kfand: failed to start FCU\n");
mutex_unlock(&driver_lock);
goto out;
}
/* Set the PCI fan once for now on non-RackMac */
if (!rackmac)
set_pwm_fan(SLOTS_FAN_PWM_INDEX, SLOTS_FAN_DEFAULT_PWM);
/* Initialize ADCs */
initialize_adc(&processor_state[0]);
if (processor_state[1].monitor != NULL)
initialize_adc(&processor_state[1]);
fcu_tickle_ticks = FCU_TICKLE_TICKS;
mutex_unlock(&driver_lock);
while (state == state_attached) {
unsigned long elapsed, start;
start = jiffies;
mutex_lock(&driver_lock);
/* Tickle the FCU just in case */
if (--fcu_tickle_ticks < 0) {
fcu_tickle_ticks = FCU_TICKLE_TICKS;
tickle_fcu();
}
/* First, we always calculate the new DIMMs state on an Xserve */
if (rackmac)
do_monitor_dimms(&dimms_state);
/* Then, the CPUs */
if (cpu_pid_type == CPU_PID_TYPE_COMBINED)
do_monitor_cpu_combined();
else if (cpu_pid_type == CPU_PID_TYPE_RACKMAC) {
do_monitor_cpu_rack(&processor_state[0]);
if (processor_state[1].monitor != NULL)
do_monitor_cpu_rack(&processor_state[1]);
// better deal with UP
} else {
do_monitor_cpu_split(&processor_state[0]);
if (processor_state[1].monitor != NULL)
do_monitor_cpu_split(&processor_state[1]);
// better deal with UP
}
/* Then, the rest */
do_monitor_backside(&backside_state);
if (rackmac)
do_monitor_slots(&slots_state);
else
do_monitor_drives(&drives_state);
mutex_unlock(&driver_lock);
if (critical_state == 1) {
printk(KERN_WARNING "Temperature control detected a critical condition\n");
printk(KERN_WARNING "Attempting to shut down...\n");
if (call_critical_overtemp()) {
printk(KERN_WARNING "Can't call %s, power off now!\n",
critical_overtemp_path);
machine_power_off();
}
}
if (critical_state > 0)
critical_state++;
if (critical_state > MAX_CRITICAL_STATE) {
printk(KERN_WARNING "Shutdown timed out, power off now !\n");
machine_power_off();
}
// FIXME: Deal with signals
elapsed = jiffies - start;
if (elapsed < HZ)
schedule_timeout_interruptible(HZ - elapsed);
}
out:
DBG("main_control_loop ended\n");
ctrl_task = 0;
complete_and_exit(&ctrl_complete, 0);
}
/*
* Dispose the control loops when tearing down
*/
static void dispose_control_loops(void)
{
dispose_processor_state(&processor_state[0]);
dispose_processor_state(&processor_state[1]);
dispose_backside_state(&backside_state);
dispose_drives_state(&drives_state);
dispose_slots_state(&slots_state);
dispose_dimms_state(&dimms_state);
}
/*
* Create the control loops. U3-0 i2c bus is up, so we can now
* get to the various sensors
*/
static int create_control_loops(void)
{
struct device_node *np;
/* Count CPUs from the device-tree, we don't care how many are
* actually used by Linux
*/
cpu_count = 0;
for (np = NULL; NULL != (np = of_find_node_by_type(np, "cpu"));)
cpu_count++;
DBG("counted %d CPUs in the device-tree\n", cpu_count);
/* Decide the type of PID algorithm to use based on the presence of
* the pumps, though that may not be the best way, that is good enough
* for now
*/
if (rackmac)
cpu_pid_type = CPU_PID_TYPE_RACKMAC;
else if (of_machine_is_compatible("PowerMac7,3")
&& (cpu_count > 1)
&& fcu_fans[CPUA_PUMP_RPM_INDEX].id != FCU_FAN_ABSENT_ID
&& fcu_fans[CPUB_PUMP_RPM_INDEX].id != FCU_FAN_ABSENT_ID) {
printk(KERN_INFO "Liquid cooling pumps detected, using new algorithm !\n");
cpu_pid_type = CPU_PID_TYPE_COMBINED;
} else
cpu_pid_type = CPU_PID_TYPE_SPLIT;
/* Create control loops for everything. If any fail, everything
* fails
*/
if (init_processor_state(&processor_state[0], 0))
goto fail;
if (cpu_pid_type == CPU_PID_TYPE_COMBINED)
fetch_cpu_pumps_minmax();
if (cpu_count > 1 && init_processor_state(&processor_state[1], 1))
goto fail;
if (init_backside_state(&backside_state))
goto fail;
if (rackmac && init_dimms_state(&dimms_state))
goto fail;
if (rackmac && init_slots_state(&slots_state))
goto fail;
if (!rackmac && init_drives_state(&drives_state))
goto fail;
DBG("all control loops up !\n");
return 0;
fail:
DBG("failure creating control loops, disposing\n");
dispose_control_loops();
return -ENODEV;
}
/*
* Start the control loops after everything is up, that is create
* the thread that will make them run
*/
static void start_control_loops(void)
{
init_completion(&ctrl_complete);
ctrl_task = kthread_run(main_control_loop, NULL, "kfand");
}
/*
* Stop the control loops when tearing down
*/
static void stop_control_loops(void)
{
if (ctrl_task)
wait_for_completion(&ctrl_complete);
}
/*
* Attach to the i2c FCU after detecting U3-1 bus
*/
static int attach_fcu(void)
{
fcu = attach_i2c_chip(FAN_CTRLER_ID, "fcu");
if (fcu == NULL)
return -ENODEV;
DBG("FCU attached\n");
return 0;
}
/*
* Detach from the i2c FCU when tearing down
*/
static void detach_fcu(void)
{
fcu = NULL;
}
/*
* Attach to the i2c controller. We probe the various chips based
* on the device-tree nodes and build everything for the driver to
* run, we then kick the driver monitoring thread
*/
static int therm_pm72_attach(struct i2c_adapter *adapter)
{
mutex_lock(&driver_lock);
/* Check state */
if (state == state_detached)
state = state_attaching;
if (state != state_attaching) {
mutex_unlock(&driver_lock);
return 0;
}
/* Check if we are looking for one of these */
if (u3_0 == NULL && !strcmp(adapter->name, "u3 0")) {
u3_0 = adapter;
DBG("found U3-0\n");
if (k2 || !rackmac)
if (create_control_loops())
u3_0 = NULL;
} else if (u3_1 == NULL && !strcmp(adapter->name, "u3 1")) {
u3_1 = adapter;
DBG("found U3-1, attaching FCU\n");
if (attach_fcu())
u3_1 = NULL;
} else if (k2 == NULL && !strcmp(adapter->name, "mac-io 0")) {
k2 = adapter;
DBG("Found K2\n");
if (u3_0 && rackmac)
if (create_control_loops())
k2 = NULL;
}
/* We got all we need, start control loops */
if (u3_0 != NULL && u3_1 != NULL && (k2 || !rackmac)) {
DBG("everything up, starting control loops\n");
state = state_attached;
start_control_loops();
}
mutex_unlock(&driver_lock);
return 0;
}
static int therm_pm72_probe(struct i2c_client *client,
const struct i2c_device_id *id)
{
/* Always succeed, the real work was done in therm_pm72_attach() */
return 0;
}
/*
* Called when any of the devices which participates into thermal management
* is going away.
*/
static int therm_pm72_remove(struct i2c_client *client)
{
struct i2c_adapter *adapter = client->adapter;
mutex_lock(&driver_lock);
if (state != state_detached)
state = state_detaching;
/* Stop control loops if any */
DBG("stopping control loops\n");
mutex_unlock(&driver_lock);
stop_control_loops();
mutex_lock(&driver_lock);
if (u3_0 != NULL && !strcmp(adapter->name, "u3 0")) {
DBG("lost U3-0, disposing control loops\n");
dispose_control_loops();
u3_0 = NULL;
}
if (u3_1 != NULL && !strcmp(adapter->name, "u3 1")) {
DBG("lost U3-1, detaching FCU\n");
detach_fcu();
u3_1 = NULL;
}
if (u3_0 == NULL && u3_1 == NULL)
state = state_detached;
mutex_unlock(&driver_lock);
return 0;
}
/*
* i2c_driver structure to attach to the host i2c controller
*/
static const struct i2c_device_id therm_pm72_id[] = {
/*
* Fake device name, thermal management is done by several
* chips but we don't need to differentiate between them at
* this point.
*/
{ "therm_pm72", 0 },
{ }
};
static struct i2c_driver therm_pm72_driver = {
.driver = {
.name = "therm_pm72",
},
.attach_adapter = therm_pm72_attach,
.probe = therm_pm72_probe,
.remove = therm_pm72_remove,
.id_table = therm_pm72_id,
};
static int fan_check_loc_match(const char *loc, int fan)
{
char tmp[64];
char *c, *e;
strlcpy(tmp, fcu_fans[fan].loc, 64);
c = tmp;
for (;;) {
e = strchr(c, ',');
if (e)
*e = 0;
if (strcmp(loc, c) == 0)
return 1;
if (e == NULL)
break;
c = e + 1;
}
return 0;
}
static void fcu_lookup_fans(struct device_node *fcu_node)
{
struct device_node *np = NULL;
int i;
/* The table is filled by default with values that are suitable
* for the old machines without device-tree informations. We scan
* the device-tree and override those values with whatever is
* there
*/
DBG("Looking up FCU controls in device-tree...\n");
while ((np = of_get_next_child(fcu_node, np)) != NULL) {
int type = -1;
const char *loc;
const u32 *reg;
DBG(" control: %s, type: %s\n", np->name, np->type);
/* Detect control type */
if (!strcmp(np->type, "fan-rpm-control") ||
!strcmp(np->type, "fan-rpm"))
type = FCU_FAN_RPM;
if (!strcmp(np->type, "fan-pwm-control") ||
!strcmp(np->type, "fan-pwm"))
type = FCU_FAN_PWM;
/* Only care about fans for now */
if (type == -1)
continue;
/* Lookup for a matching location */
loc = of_get_property(np, "location", NULL);
reg = of_get_property(np, "reg", NULL);
if (loc == NULL || reg == NULL)
continue;
DBG(" matching location: %s, reg: 0x%08x\n", loc, *reg);
for (i = 0; i < FCU_FAN_COUNT; i++) {
int fan_id;
if (!fan_check_loc_match(loc, i))
continue;
DBG(" location match, index: %d\n", i);
fcu_fans[i].id = FCU_FAN_ABSENT_ID;
if (type != fcu_fans[i].type) {
printk(KERN_WARNING "therm_pm72: Fan type mismatch "
"in device-tree for %s\n", np->full_name);
break;
}
if (type == FCU_FAN_RPM)
fan_id = ((*reg) - 0x10) / 2;
else
fan_id = ((*reg) - 0x30) / 2;
if (fan_id > 7) {
printk(KERN_WARNING "therm_pm72: Can't parse "
"fan ID in device-tree for %s\n", np->full_name);
break;
}
DBG(" fan id -> %d, type -> %d\n", fan_id, type);
fcu_fans[i].id = fan_id;
}
}
/* Now dump the array */
printk(KERN_INFO "Detected fan controls:\n");
for (i = 0; i < FCU_FAN_COUNT; i++) {
if (fcu_fans[i].id == FCU_FAN_ABSENT_ID)
continue;
printk(KERN_INFO " %d: %s fan, id %d, location: %s\n", i,
fcu_fans[i].type == FCU_FAN_RPM ? "RPM" : "PWM",
fcu_fans[i].id, fcu_fans[i].loc);
}
}
static int fcu_of_probe(struct platform_device* dev)
{
state = state_detached;
of_dev = dev;
dev_info(&dev->dev, "PowerMac G5 Thermal control driver %s\n", VERSION);
/* Lookup the fans in the device tree */
fcu_lookup_fans(dev->dev.of_node);
/* Add the driver */
return i2c_add_driver(&therm_pm72_driver);
}
static int fcu_of_remove(struct platform_device* dev)
{
i2c_del_driver(&therm_pm72_driver);
return 0;
}
static const struct of_device_id fcu_match[] =
{
{
.type = "fcu",
},
{},
};
MODULE_DEVICE_TABLE(of, fcu_match);
static struct platform_driver fcu_of_platform_driver =
{
.driver = {
.name = "temperature",
.of_match_table = fcu_match,
},
.probe = fcu_of_probe,
.remove = fcu_of_remove
};
/*
* Check machine type, attach to i2c controller
*/
static int __init therm_pm72_init(void)
{
rackmac = of_machine_is_compatible("RackMac3,1");
if (!of_machine_is_compatible("PowerMac7,2") &&
!of_machine_is_compatible("PowerMac7,3") &&
!rackmac)
return -ENODEV;
return platform_driver_register(&fcu_of_platform_driver);
}
static void __exit therm_pm72_exit(void)
{
platform_driver_unregister(&fcu_of_platform_driver);
}
module_init(therm_pm72_init);
module_exit(therm_pm72_exit);
MODULE_AUTHOR("Benjamin Herrenschmidt <benh@kernel.crashing.org>");
MODULE_DESCRIPTION("Driver for Apple's PowerMac G5 thermal control");
MODULE_LICENSE("GPL");
#ifndef __THERM_PMAC_7_2_H__
#define __THERM_PMAC_7_2_H__
typedef unsigned short fu16;
typedef int fs32;
typedef short fs16;
struct mpu_data
{
u8 signature; /* 0x00 - EEPROM sig. */
u8 bytes_used; /* 0x01 - Bytes used in eeprom (160 ?) */
u8 size; /* 0x02 - EEPROM size (256 ?) */
u8 version; /* 0x03 - EEPROM version */
u32 data_revision; /* 0x04 - Dataset revision */
u8 processor_bin_code[3]; /* 0x08 - Processor BIN code */
u8 bin_code_expansion; /* 0x0b - ??? (padding ?) */
u8 processor_num; /* 0x0c - Number of CPUs on this MPU */
u8 input_mul_bus_div; /* 0x0d - Clock input multiplier/bus divider */
u8 reserved1[2]; /* 0x0e - */
u32 input_clk_freq_high; /* 0x10 - Input clock frequency high */
u8 cpu_nb_target_cycles; /* 0x14 - ??? */
u8 cpu_statlat; /* 0x15 - ??? */
u8 cpu_snooplat; /* 0x16 - ??? */
u8 cpu_snoopacc; /* 0x17 - ??? */
u8 nb_paamwin; /* 0x18 - ??? */
u8 nb_statlat; /* 0x19 - ??? */
u8 nb_snooplat; /* 0x1a - ??? */
u8 nb_snoopwin; /* 0x1b - ??? */
u8 api_bus_mode; /* 0x1c - ??? */
u8 reserved2[3]; /* 0x1d - */
u32 input_clk_freq_low; /* 0x20 - Input clock frequency low */
u8 processor_card_slot; /* 0x24 - Processor card slot number */
u8 reserved3[2]; /* 0x25 - */
u8 padjmax; /* 0x27 - Max power adjustment (Not in OF!) */
u8 ttarget; /* 0x28 - Target temperature */
u8 tmax; /* 0x29 - Max temperature */
u8 pmaxh; /* 0x2a - Max power */
u8 tguardband; /* 0x2b - Guardband temp ??? Hist. len in OSX */
fs32 pid_gp; /* 0x2c - PID proportional gain */
fs32 pid_gr; /* 0x30 - PID reset gain */
fs32 pid_gd; /* 0x34 - PID derivative gain */
fu16 voph; /* 0x38 - Vop High */
fu16 vopl; /* 0x3a - Vop Low */
fs16 nactual_die; /* 0x3c - nActual Die */
fs16 nactual_heatsink; /* 0x3e - nActual Heatsink */
fs16 nactual_system; /* 0x40 - nActual System */
u16 calibration_flags; /* 0x42 - Calibration flags */
fu16 mdiode; /* 0x44 - Diode M value (scaling factor) */
fs16 bdiode; /* 0x46 - Diode B value (offset) */
fs32 theta_heat_sink; /* 0x48 - Theta heat sink */
u16 rminn_intake_fan; /* 0x4c - Intake fan min RPM */
u16 rmaxn_intake_fan; /* 0x4e - Intake fan max RPM */
u16 rminn_exhaust_fan; /* 0x50 - Exhaust fan min RPM */
u16 rmaxn_exhaust_fan; /* 0x52 - Exhaust fan max RPM */
u8 processor_part_num[8]; /* 0x54 - Processor part number XX pumps min/max */
u32 processor_lot_num; /* 0x5c - Processor lot number */
u8 orig_card_sernum[0x10]; /* 0x60 - Card original serial number */
u8 curr_card_sernum[0x10]; /* 0x70 - Card current serial number */
u8 mlb_sernum[0x18]; /* 0x80 - MLB serial number */
u32 checksum1; /* 0x98 - */
u32 checksum2; /* 0x9c - */
}; /* Total size = 0xa0 */
/* Display a 16.16 fixed point value */
#define FIX32TOPRINT(f) ((f) >> 16),((((f) & 0xffff) * 1000) >> 16)
/*
* Maximum number of seconds to be in critical state (after a
* normal shutdown attempt). If the machine isn't down after
* this counter elapses, we force an immediate machine power
* off.
*/
#define MAX_CRITICAL_STATE 30
static char * critical_overtemp_path = "/sbin/critical_overtemp";
/*
* This option is "weird" :) Basically, if you define this to 1
* the control loop for the RPMs fans (not PWMs) will apply the
* correction factor obtained from the PID to the _actual_ RPM
* speed read from the FCU.
* If you define the below constant to 0, then it will be
* applied to the setpoint RPM speed, that is basically the
* speed we proviously "asked" for.
*
* I'm not sure which of these Apple's algorithm is supposed
* to use
*/
#define RPM_PID_USE_ACTUAL_SPEED 0
/*
* i2c IDs. Currently, we hard code those and assume that
* the FCU is on U3 bus 1 while all sensors are on U3 bus
* 0. This appear to be safe enough for this first version
* of the driver, though I would accept any clean patch
* doing a better use of the device-tree without turning the
* while i2c registration mechanism into a racy mess
*
* Note: Xserve changed this. We have some bits on the K2 bus,
* which I arbitrarily set to 0x200. Ultimately, we really want
* too lookup these in the device-tree though
*/
#define FAN_CTRLER_ID 0x15e
#define SUPPLY_MONITOR_ID 0x58
#define SUPPLY_MONITORB_ID 0x5a
#define DRIVES_DALLAS_ID 0x94
#define BACKSIDE_MAX_ID 0x98
#define XSERVE_DIMMS_LM87 0x25a
#define XSERVE_SLOTS_LM75 0x290
/*
* Some MAX6690, DS1775, LM87 register definitions
*/
#define MAX6690_INT_TEMP 0
#define MAX6690_EXT_TEMP 1
#define DS1775_TEMP 0
#define LM87_INT_TEMP 0x27
/*
* Scaling factors for the AD7417 ADC converters (except
* for the CPU diode which is obtained from the EEPROM).
* Those values are obtained from the property list of
* the darwin driver
*/
#define ADC_12V_CURRENT_SCALE 0x0320 /* _AD2 */
#define ADC_CPU_VOLTAGE_SCALE 0x00a0 /* _AD3 */
#define ADC_CPU_CURRENT_SCALE 0x1f40 /* _AD4 */
/*
* PID factors for the U3/Backside fan control loop. We have 2 sets
* of values here, one set for U3 and one set for U3H
*/
#define BACKSIDE_FAN_PWM_DEFAULT_ID 1
#define BACKSIDE_FAN_PWM_INDEX 0
#define BACKSIDE_PID_U3_G_d 0x02800000
#define BACKSIDE_PID_U3H_G_d 0x01400000
#define BACKSIDE_PID_RACK_G_d 0x00500000
#define BACKSIDE_PID_G_p 0x00500000
#define BACKSIDE_PID_RACK_G_p 0x0004cccc
#define BACKSIDE_PID_G_r 0x00000000
#define BACKSIDE_PID_U3_INPUT_TARGET 0x00410000
#define BACKSIDE_PID_U3H_INPUT_TARGET 0x004b0000
#define BACKSIDE_PID_RACK_INPUT_TARGET 0x00460000
#define BACKSIDE_PID_INTERVAL 5
#define BACKSIDE_PID_RACK_INTERVAL 1
#define BACKSIDE_PID_OUTPUT_MAX 100
#define BACKSIDE_PID_U3_OUTPUT_MIN 20
#define BACKSIDE_PID_U3H_OUTPUT_MIN 20
#define BACKSIDE_PID_HISTORY_SIZE 2
struct basckside_pid_params
{
s32 G_d;
s32 G_p;
s32 G_r;
s32 input_target;
s32 output_min;
s32 output_max;
s32 interval;
int additive;
};
struct backside_pid_state
{
int ticks;
struct i2c_client * monitor;
s32 sample_history[BACKSIDE_PID_HISTORY_SIZE];
s32 error_history[BACKSIDE_PID_HISTORY_SIZE];
int cur_sample;
s32 last_temp;
int pwm;
int first;
};
/*
* PID factors for the Drive Bay fan control loop
*/
#define DRIVES_FAN_RPM_DEFAULT_ID 2
#define DRIVES_FAN_RPM_INDEX 1
#define DRIVES_PID_G_d 0x01e00000
#define DRIVES_PID_G_p 0x00500000
#define DRIVES_PID_G_r 0x00000000
#define DRIVES_PID_INPUT_TARGET 0x00280000
#define DRIVES_PID_INTERVAL 5
#define DRIVES_PID_OUTPUT_MAX 4000
#define DRIVES_PID_OUTPUT_MIN 300
#define DRIVES_PID_HISTORY_SIZE 2
struct drives_pid_state
{
int ticks;
struct i2c_client * monitor;
s32 sample_history[BACKSIDE_PID_HISTORY_SIZE];
s32 error_history[BACKSIDE_PID_HISTORY_SIZE];
int cur_sample;
s32 last_temp;
int rpm;
int first;
};
#define SLOTS_FAN_PWM_DEFAULT_ID 2
#define SLOTS_FAN_PWM_INDEX 2
#define SLOTS_FAN_DEFAULT_PWM 40 /* Do better here ! */
/*
* PID factors for the Xserve DIMM control loop
*/
#define DIMM_PID_G_d 0
#define DIMM_PID_G_p 0
#define DIMM_PID_G_r 0x06553600
#define DIMM_PID_INPUT_TARGET 3276800
#define DIMM_PID_INTERVAL 1
#define DIMM_PID_OUTPUT_MAX 14000
#define DIMM_PID_OUTPUT_MIN 4000
#define DIMM_PID_HISTORY_SIZE 20
struct dimm_pid_state
{
int ticks;
struct i2c_client * monitor;
s32 sample_history[DIMM_PID_HISTORY_SIZE];
s32 error_history[DIMM_PID_HISTORY_SIZE];
int cur_sample;
s32 last_temp;
int first;
int output;
};
/*
* PID factors for the Xserve Slots control loop
*/
#define SLOTS_PID_G_d 0
#define SLOTS_PID_G_p 0
#define SLOTS_PID_G_r 0x00100000
#define SLOTS_PID_INPUT_TARGET 3200000
#define SLOTS_PID_INTERVAL 1
#define SLOTS_PID_OUTPUT_MAX 100
#define SLOTS_PID_OUTPUT_MIN 20
#define SLOTS_PID_HISTORY_SIZE 20
struct slots_pid_state
{
int ticks;
struct i2c_client * monitor;
s32 sample_history[SLOTS_PID_HISTORY_SIZE];
s32 error_history[SLOTS_PID_HISTORY_SIZE];
int cur_sample;
s32 last_temp;
int first;
int pwm;
};
/* Desktops */
#define CPUA_INTAKE_FAN_RPM_DEFAULT_ID 3
#define CPUA_EXHAUST_FAN_RPM_DEFAULT_ID 4
#define CPUB_INTAKE_FAN_RPM_DEFAULT_ID 5
#define CPUB_EXHAUST_FAN_RPM_DEFAULT_ID 6
#define CPUA_INTAKE_FAN_RPM_INDEX 3
#define CPUA_EXHAUST_FAN_RPM_INDEX 4
#define CPUB_INTAKE_FAN_RPM_INDEX 5
#define CPUB_EXHAUST_FAN_RPM_INDEX 6
#define CPU_INTAKE_SCALE 0x0000f852
#define CPU_TEMP_HISTORY_SIZE 2
#define CPU_POWER_HISTORY_SIZE 10
#define CPU_PID_INTERVAL 1
#define CPU_MAX_OVERTEMP 90
#define CPUA_PUMP_RPM_INDEX 7
#define CPUB_PUMP_RPM_INDEX 8
#define CPU_PUMP_OUTPUT_MAX 3200
#define CPU_PUMP_OUTPUT_MIN 1250
/* Xserve */
#define CPU_A1_FAN_RPM_INDEX 9
#define CPU_A2_FAN_RPM_INDEX 10
#define CPU_A3_FAN_RPM_INDEX 11
#define CPU_B1_FAN_RPM_INDEX 12
#define CPU_B2_FAN_RPM_INDEX 13
#define CPU_B3_FAN_RPM_INDEX 14
struct cpu_pid_state
{
int index;
struct i2c_client * monitor;
struct mpu_data mpu;
int overtemp;
s32 temp_history[CPU_TEMP_HISTORY_SIZE];
int cur_temp;
s32 power_history[CPU_POWER_HISTORY_SIZE];
s32 error_history[CPU_POWER_HISTORY_SIZE];
int cur_power;
int count_power;
int rpm;
int intake_rpm;
s32 voltage;
s32 current_a;
s32 last_temp;
s32 last_power;
int first;
u8 adc_config;
s32 pump_min;
s32 pump_max;
};
/* Tickle FCU every 10 seconds */
#define FCU_TICKLE_TICKS 10
/*
* Driver state
*/
enum {
state_detached,
state_attaching,
state_attached,
state_detaching,
};
#endif /* __THERM_PMAC_7_2_H__ */
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