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|
/* $OpenBSD: smu.c,v 1.23 2011/05/15 09:10:26 mpi Exp $ */
/*
* Copyright (c) 2005 Mark Kettenis
*
* Permission to use, copy, modify, and distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*/
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/device.h>
#include <sys/kernel.h>
#include <sys/rwlock.h>
#include <sys/proc.h>
#include <sys/sensors.h>
#include <machine/autoconf.h>
#include <machine/cpu.h>
#include <dev/clock_subr.h>
#include <dev/i2c/i2cvar.h>
#include <dev/ofw/openfirm.h>
#include <macppc/dev/maci2cvar.h>
#include <macppc/pci/macobio.h>
int smu_match(struct device *, void *, void *);
void smu_attach(struct device *, struct device *, void *);
#define SMU_MAXFANS 3
struct smu_fan {
u_int8_t reg;
u_int16_t min_rpm;
u_int16_t max_rpm;
u_int16_t unmanaged_rpm;
struct ksensor sensor;
};
#define SMU_MAXSENSORS 4
struct smu_sensor {
u_int8_t reg;
struct ksensor sensor;
};
struct smu_softc {
struct device sc_dev;
/* SMU command buffer. */
bus_dma_tag_t sc_dmat;
bus_dmamap_t sc_cmdmap;
bus_dma_segment_t sc_cmdseg[1];
caddr_t sc_cmd;
struct rwlock sc_lock;
/* Doorbell and mailbox. */
struct ppc_bus_space sc_mem_bus_space;
bus_space_tag_t sc_memt;
bus_space_handle_t sc_gpioh;
bus_space_handle_t sc_buffh;
struct smu_fan sc_fans[SMU_MAXFANS];
int sc_num_fans;
struct smu_sensor sc_sensors[SMU_MAXSENSORS];
int sc_num_sensors;
struct ksensordev sc_sensordev;
u_int16_t sc_cpu_diode_scale;
int16_t sc_cpu_diode_offset;
u_int16_t sc_cpu_volt_scale;
int16_t sc_cpu_volt_offset;
u_int16_t sc_cpu_curr_scale;
int16_t sc_cpu_curr_offset;
u_int16_t sc_slots_pow_scale;
int16_t sc_slots_pow_offset;
struct i2c_controller sc_i2c_tag;
};
struct cfattach smu_ca = {
sizeof(struct smu_softc), smu_match, smu_attach
};
struct cfdriver smu_cd = {
NULL, "smu", DV_DULL,
};
/* SMU command */
struct smu_cmd {
u_int8_t cmd;
u_int8_t len;
u_int8_t data[254];
};
#define SMU_CMDSZ sizeof(struct smu_cmd)
/* RTC */
#define SMU_RTC 0x8e
#define SMU_RTC_SET_DATETIME 0x80
#define SMU_RTC_GET_DATETIME 0x81
/* ADC */
#define SMU_ADC 0xd8
/* Fan control */
#define SMU_FAN 0x4a
/* Data partitions */
#define SMU_PARTITION 0x3e
#define SMU_PARTITION_LATEST 0x01
#define SMU_PARTITION_BASE 0x02
#define SMU_PARTITION_UPDATE 0x03
/* I2C */
#define SMU_I2C 0x9a
#define SMU_I2C_SIMPLE 0x00
#define SMU_I2C_NORMAL 0x01
#define SMU_I2C_COMBINED 0x02
/* Power Management */
#define SMU_POWER 0xaa
/* Miscellaneous */
#define SMU_MISC 0xee
#define SMU_MISC_GET_DATA 0x02
int smu_intr(void *);
int smu_do_cmd(struct smu_softc *, int);
int smu_time_read(time_t *);
int smu_time_write(time_t);
int smu_get_datablock(struct smu_softc *sc, u_int8_t, u_int8_t *, size_t);
int smu_fan_set_rpm(struct smu_softc *, struct smu_fan *, u_int16_t);
int smu_fan_refresh(struct smu_softc *, struct smu_fan *);
int smu_sensor_refresh(struct smu_softc *, struct smu_sensor *);
void smu_refresh_sensors(void *);
int smu_i2c_acquire_bus(void *, int);
void smu_i2c_release_bus(void *, int);
int smu_i2c_exec(void *, i2c_op_t, i2c_addr_t,
const void *, size_t, void *buf, size_t, int);
void smu_slew_voltage(u_int);
int
smu_match(struct device *parent, void *cf, void *aux)
{
struct confargs *ca = aux;
if (strcmp(ca->ca_name, "smu") == 0)
return (1);
return (0);
}
/* XXX */
extern struct powerpc_bus_dma_tag pci_bus_dma_tag;
void
smu_attach(struct device *parent, struct device *self, void *aux)
{
struct smu_softc *sc = (struct smu_softc *)self;
struct confargs *ca = aux;
struct i2cbus_attach_args iba;
struct smu_fan *fan;
struct smu_sensor *sensor;
int nseg, node;
char type[32], loc[32];
u_int32_t reg, intr, gpio, val;
u_int8_t data[12];
/* XXX */
sc->sc_mem_bus_space.bus_base = 0x80000000;
sc->sc_mem_bus_space.bus_size = 0;
sc->sc_mem_bus_space.bus_io = 0;
sc->sc_memt = &sc->sc_mem_bus_space;
/* Map smu-doorbell gpio. */
if (OF_getprop(ca->ca_node, "platform-doorbell-ack",
&node, sizeof node) <= 0 ||
OF_getprop(node, "reg", ®, sizeof reg) <= 0 ||
OF_getprop(node, "interrupts", &intr, sizeof intr) <= 0 ||
OF_getprop(OF_parent(node), "reg", &gpio, sizeof gpio) <= 0) {
printf(": cannot find smu-doorbell gpio\n");
return;
}
if (bus_space_map(sc->sc_memt, gpio + reg, 1, 0, &sc->sc_gpioh)) {
printf(": cannot map smu-doorbell gpio\n");
return;
}
/* XXX Should get this from OF. */
if (bus_space_map(sc->sc_memt, 0x860c, 4, 0, &sc->sc_buffh)) {
printf(": cannot map smu-doorbell buffer\n");
return;
}
/* XXX */
sc->sc_dmat = &pci_bus_dma_tag;
/* Allocate and map SMU command buffer. */
if (bus_dmamem_alloc(sc->sc_dmat, SMU_CMDSZ, 0, 0,
sc->sc_cmdseg, 1, &nseg, BUS_DMA_NOWAIT)) {
printf(": cannot allocate cmd buffer\n");
return;
}
if (bus_dmamem_map(sc->sc_dmat, sc->sc_cmdseg, nseg,
SMU_CMDSZ, &sc->sc_cmd, BUS_DMA_NOWAIT)) {
printf(": cannot map cmd buffer\n");
bus_dmamem_free(sc->sc_dmat, sc->sc_cmdseg, 1);
return;
}
if (bus_dmamap_create(sc->sc_dmat, SMU_CMDSZ, 1, SMU_CMDSZ, 0,
BUS_DMA_NOWAIT | BUS_DMA_ALLOCNOW, &sc->sc_cmdmap)) {
printf(": cannot create cmd dmamap\n");
bus_dmamem_unmap(sc->sc_dmat, sc->sc_cmd, SMU_CMDSZ);
bus_dmamem_free(sc->sc_dmat, sc->sc_cmdseg, 1);
return;
}
if (bus_dmamap_load(sc->sc_dmat, sc->sc_cmdmap, sc->sc_cmd,
SMU_CMDSZ, NULL, BUS_DMA_NOWAIT)) {
printf(": cannot load cmd dmamap\n");
bus_dmamap_destroy(sc->sc_dmat, sc->sc_cmdmap);
bus_dmamem_unmap(sc->sc_dmat, sc->sc_cmd, SMU_CMDSZ);
bus_dmamem_free(sc->sc_dmat, sc->sc_cmdseg, nseg);
return;
}
rw_init(&sc->sc_lock, sc->sc_dev.dv_xname);
/* Establish smu-doorbell interrupt. */
mac_intr_establish(parent, intr, IST_EDGE, IPL_BIO,
smu_intr, sc, sc->sc_dev.dv_xname);
/* Initialize global variables that control RTC functionality. */
time_read = smu_time_read;
time_write = smu_time_write;
/* Fans */
node = OF_getnodebyname(ca->ca_node, "rpm-fans");
if (node == 0)
node = OF_getnodebyname(ca->ca_node, "fans");
for (node = OF_child(node); node; node = OF_peer(node)) {
if (OF_getprop(node, "reg", ®, sizeof reg) <= 0 ||
OF_getprop(node, "device_type", type, sizeof type) <= 0)
continue;
if (strcmp(type, "fan-rpm-control") != 0) {
printf(": unsupported fan type: %s\n", type);
return;
}
if (sc->sc_num_fans >= SMU_MAXFANS) {
printf(": too many fans\n");
return;
}
fan = &sc->sc_fans[sc->sc_num_fans++];
fan->sensor.type = SENSOR_FANRPM;
fan->sensor.flags = SENSOR_FINVALID;
fan->reg = reg;
if (OF_getprop(node, "min-value", &val, sizeof val) <= 0)
val = 0;
fan->min_rpm = val;
if (OF_getprop(node, "max-value", &val, sizeof val) <= 0)
val = 0xffff;
fan->max_rpm = val;
if (OF_getprop(node, "unmanage-value", &val, sizeof val) <= 0)
val = fan->max_rpm;
fan->unmanaged_rpm = val;
if (OF_getprop(node, "location", loc, sizeof loc) <= 0)
strlcpy(loc, "Unknown", sizeof loc);
strlcpy(fan->sensor.desc, loc, sizeof sensor->sensor.desc);
/* Start running fans at their "unmanaged" speed. */
smu_fan_set_rpm(sc, fan, fan->unmanaged_rpm);
sensor_attach(&sc->sc_sensordev, &fan->sensor);
}
/*
* Bail out if we didn't find any fans. If we don't set the
* fans to a safe speed, but tickle the SMU periodically by
* reading sensors, the fans will never spin up and the
* machine might overheat.
*/
if (sc->sc_num_fans == 0) {
printf(": no fans\n");
return;
}
/* Sensors */
node = OF_getnodebyname(ca->ca_node, "sensors");
for (node = OF_child(node); node; node = OF_peer(node)) {
if (OF_getprop(node, "reg", &val, sizeof val) <= 0 ||
OF_getprop(node, "device_type", type, sizeof type) <= 0)
continue;
if (sc->sc_num_sensors >= SMU_MAXSENSORS) {
printf(": too many sensors\n");
return;
}
sensor = &sc->sc_sensors[sc->sc_num_sensors++];
sensor->sensor.flags = SENSOR_FINVALID;
sensor->reg = val;
if (strcmp(type, "current-sensor") == 0) {
sensor->sensor.type = SENSOR_AMPS;
} else if (strcmp(type, "temp-sensor") == 0) {
sensor->sensor.type = SENSOR_TEMP;
} else if (strcmp(type, "voltage-sensor") == 0) {
sensor->sensor.type = SENSOR_VOLTS_DC;
} else if (strcmp(type, "power-sensor") == 0) {
sensor->sensor.type = SENSOR_WATTS;
} else {
sensor->sensor.type = SENSOR_INTEGER;
}
if (OF_getprop(node, "location", loc, sizeof loc) <= 0)
strlcpy(loc, "Unknown", sizeof loc);
strlcpy(sensor->sensor.desc, loc, sizeof sensor->sensor.desc);
sensor_attach(&sc->sc_sensordev, &sensor->sensor);
}
/* Register sensor device with sysctl */
strlcpy(sc->sc_sensordev.xname, sc->sc_dev.dv_xname,
sizeof(sc->sc_sensordev.xname));
sensordev_install(&sc->sc_sensordev);
/* CPU temperature diode calibration */
smu_get_datablock(sc, 0x18, data, sizeof data);
sc->sc_cpu_diode_scale = (data[4] << 8) + data[5];
sc->sc_cpu_diode_offset = (data[6] << 8) + data[7];
/* CPU power (voltage and current) calibration */
smu_get_datablock(sc, 0x21, data, sizeof data);
sc->sc_cpu_volt_scale = (data[4] << 8) + data[5];
sc->sc_cpu_volt_offset = (data[6] << 8) + data[7];
sc->sc_cpu_curr_scale = (data[8] << 8) + data[9];
sc->sc_cpu_curr_offset = (data[10] << 8) + data[11];
/* Slots power calibration */
smu_get_datablock(sc, 0x78, data, sizeof data);
sc->sc_slots_pow_scale = (data[4] << 8) + data[5];
sc->sc_slots_pow_offset = (data[6] << 8) + data[7];
sensor_task_register(sc, smu_refresh_sensors, 5);
printf("\n");
ppc64_slew_voltage = smu_slew_voltage;
sc->sc_i2c_tag.ic_cookie = sc;
sc->sc_i2c_tag.ic_acquire_bus = smu_i2c_acquire_bus;
sc->sc_i2c_tag.ic_release_bus = smu_i2c_release_bus;
sc->sc_i2c_tag.ic_exec = smu_i2c_exec;
/*
* Early versions of the SMU have the i2c bus node directly
* below the "smu" node, while later models have an
* intermediate "smu-i2c-control" node.
*/
node = OF_getnodebyname(ca->ca_node, "smu-i2c-control");
if (node)
node = OF_child(node);
else
node = OF_getnodebyname(ca->ca_node, "i2c");
bzero(&iba, sizeof iba);
iba.iba_name = "iic";
iba.iba_tag = &sc->sc_i2c_tag;
iba.iba_bus_scan = maciic_scan;
iba.iba_bus_scan_arg = &node;
config_found(&sc->sc_dev, &iba, NULL);
}
int
smu_intr(void *arg)
{
wakeup(arg);
return 1;
}
int
smu_do_cmd(struct smu_softc *sc, int timo)
{
struct smu_cmd *cmd = (struct smu_cmd *)sc->sc_cmd;
u_int8_t gpio, ack = ~cmd->cmd;
int error;
/* Write to mailbox. */
bus_space_write_4(sc->sc_memt, sc->sc_buffh, 0,
sc->sc_cmdmap->dm_segs->ds_addr);
/* Flush to RAM. */
asm __volatile__ ("dcbst 0,%0; sync" :: "r"(sc->sc_cmd): "memory");
/* Ring doorbell. */
bus_space_write_1(sc->sc_memt, sc->sc_gpioh, 0, GPIO_DDR_OUTPUT);
do {
error = tsleep(sc, PWAIT, "smu", (timo * hz) / 1000);
if (error)
return (error);
gpio = bus_space_read_1(sc->sc_memt, sc->sc_gpioh, 0);
} while (!(gpio & (GPIO_DATA)));
/* CPU might have brought back the cache line. */
asm __volatile__ ("dcbf 0,%0; sync" :: "r"(sc->sc_cmd) : "memory");
if (cmd->cmd != ack)
return (EIO);
return (0);
}
int
smu_time_read(time_t *secs)
{
struct smu_softc *sc = smu_cd.cd_devs[0];
struct smu_cmd *cmd = (struct smu_cmd *)sc->sc_cmd;
struct clock_ymdhms dt;
int error;
rw_enter_write(&sc->sc_lock);
cmd->cmd = SMU_RTC;
cmd->len = 1;
cmd->data[0] = SMU_RTC_GET_DATETIME;
error = smu_do_cmd(sc, 800);
if (error) {
rw_exit_write(&sc->sc_lock);
*secs = 0;
return (error);
}
dt.dt_year = 2000 + FROMBCD(cmd->data[6]);
dt.dt_mon = FROMBCD(cmd->data[5]);
dt.dt_day = FROMBCD(cmd->data[4]);
dt.dt_hour = FROMBCD(cmd->data[2]);
dt.dt_min = FROMBCD(cmd->data[1]);
dt.dt_sec = FROMBCD(cmd->data[0]);
rw_exit_write(&sc->sc_lock);
*secs = clock_ymdhms_to_secs(&dt);
return (0);
}
int
smu_time_write(time_t secs)
{
struct smu_softc *sc = smu_cd.cd_devs[0];
struct smu_cmd *cmd = (struct smu_cmd *)sc->sc_cmd;
struct clock_ymdhms dt;
int error;
clock_secs_to_ymdhms(secs, &dt);
rw_enter_write(&sc->sc_lock);
cmd->cmd = SMU_RTC;
cmd->len = 8;
cmd->data[0] = SMU_RTC_SET_DATETIME;
cmd->data[1] = TOBCD(dt.dt_sec);
cmd->data[2] = TOBCD(dt.dt_min);
cmd->data[3] = TOBCD(dt.dt_hour);
cmd->data[4] = TOBCD(dt.dt_wday);
cmd->data[5] = TOBCD(dt.dt_day);
cmd->data[6] = TOBCD(dt.dt_mon);
cmd->data[7] = TOBCD(dt.dt_year - 2000);
error = smu_do_cmd(sc, 800);
rw_exit_write(&sc->sc_lock);
return (error);
}
int
smu_get_datablock(struct smu_softc *sc, u_int8_t id, u_int8_t *buf, size_t len)
{
struct smu_cmd *cmd = (struct smu_cmd *)sc->sc_cmd;
u_int8_t addr[4];
int error;
cmd->cmd = SMU_PARTITION;
cmd->len = 2;
cmd->data[0] = SMU_PARTITION_LATEST;
cmd->data[1] = id;
error = smu_do_cmd(sc, 800);
if (error)
return (error);
addr[0] = 0x00;
addr[1] = 0x00;
addr[2] = cmd->data[0];
addr[3] = cmd->data[1];
cmd->cmd = SMU_MISC;
cmd->len = 7;
cmd->data[0] = SMU_MISC_GET_DATA;
cmd->data[1] = sizeof(u_int32_t);
cmd->data[2] = addr[0];
cmd->data[3] = addr[1];
cmd->data[4] = addr[2];
cmd->data[5] = addr[3];
cmd->data[6] = len;
error = smu_do_cmd(sc, 800);
if (error)
return (error);
memcpy(buf, cmd->data, len);
return (0);
}
int
smu_fan_set_rpm(struct smu_softc *sc, struct smu_fan *fan, u_int16_t rpm)
{
struct smu_cmd *cmd = (struct smu_cmd *)sc->sc_cmd;
/*
* On the PowerMac8,2 this command expects the requested fan
* speed at a different location in the command block than on
* the PowerMac8,1. We simply store the value at both
* locations.
*/
cmd->cmd = SMU_FAN;
cmd->len = 14;
cmd->data[0] = 0x00; /* fan-rpm-control */
cmd->data[1] = 0x01 << fan->reg;
cmd->data[2] = cmd->data[2 + fan->reg * 2] = (rpm >> 8) & 0xff;
cmd->data[3] = cmd->data[3 + fan->reg * 2] = (rpm & 0xff);
return smu_do_cmd(sc, 800);
}
int
smu_fan_refresh(struct smu_softc *sc, struct smu_fan *fan)
{
struct smu_cmd *cmd = (struct smu_cmd *)sc->sc_cmd;
int error;
cmd->cmd = SMU_FAN;
cmd->len = 2;
cmd->data[0] = 0x01; /* fan-rpm-control */
cmd->data[1] = 0x01 << fan->reg;
error = smu_do_cmd(sc, 800);
if (error) {
fan->sensor.flags = SENSOR_FINVALID;
return (error);
}
fan->sensor.value = (cmd->data[1] << 8) + cmd->data[2];
fan->sensor.flags = 0;
return (0);
}
int
smu_sensor_refresh(struct smu_softc *sc, struct smu_sensor *sensor)
{
struct smu_cmd *cmd = (struct smu_cmd *)sc->sc_cmd;
int64_t value;
int error;
cmd->cmd = SMU_ADC;
cmd->len = 1;
cmd->data[0] = sensor->reg;
error = smu_do_cmd(sc, 800);
if (error) {
sensor->sensor.flags = SENSOR_FINVALID;
return (error);
}
value = (cmd->data[0] << 8) + cmd->data[1];
switch (sensor->sensor.type) {
case SENSOR_TEMP:
value *= sc->sc_cpu_diode_scale;
value >>= 3;
value += ((int64_t)sc->sc_cpu_diode_offset) << 9;
value <<= 1;
/* Convert from 16.16 fixed point degC into muK. */
value *= 15625;
value /= 1024;
value += 273150000;
break;
case SENSOR_VOLTS_DC:
value *= sc->sc_cpu_volt_scale;
value += sc->sc_cpu_volt_offset;
value <<= 4;
/* Convert from 16.16 fixed point V into muV. */
value *= 15625;
value /= 1024;
break;
case SENSOR_AMPS:
value *= sc->sc_cpu_curr_scale;
value += sc->sc_cpu_curr_offset;
value <<= 4;
/* Convert from 16.16 fixed point A into muA. */
value *= 15625;
value /= 1024;
break;
case SENSOR_WATTS:
value *= sc->sc_slots_pow_scale;
value += sc->sc_slots_pow_offset;
value <<= 4;
/* Convert from 16.16 fixed point W into muW. */
value *= 15625;
value /= 1024;
break;
default:
break;
}
sensor->sensor.value = value;
sensor->sensor.flags = 0;
return (0);
}
void
smu_refresh_sensors(void *arg)
{
struct smu_softc *sc = arg;
int i;
rw_enter_write(&sc->sc_lock);
for (i = 0; i < sc->sc_num_sensors; i++)
smu_sensor_refresh(sc, &sc->sc_sensors[i]);
for (i = 0; i < sc->sc_num_fans; i++)
smu_fan_refresh(sc, &sc->sc_fans[i]);
rw_exit_write(&sc->sc_lock);
}
int
smu_i2c_acquire_bus(void *cookie, int flags)
{
struct smu_softc *sc = cookie;
if (flags & I2C_F_POLL)
return (0);
return (rw_enter(&sc->sc_lock, RW_WRITE));
}
void
smu_i2c_release_bus(void *cookie, int flags)
{
struct smu_softc *sc = cookie;
if (flags & I2C_F_POLL)
return;
rw_exit(&sc->sc_lock);
}
int
smu_i2c_exec(void *cookie, i2c_op_t op, i2c_addr_t addr,
const void *cmdbuf, size_t cmdlen, void *buf, size_t len, int flags)
{
struct smu_softc *sc = cookie;
struct smu_cmd *cmd = (struct smu_cmd *)sc->sc_cmd;
u_int8_t smu_op = SMU_I2C_NORMAL;
int error, retries = 10;
if (!I2C_OP_STOP_P(op) || cmdlen > 3 || len > 5)
return (EINVAL);
if(cmdlen == 0)
smu_op = SMU_I2C_SIMPLE;
else if (I2C_OP_READ_P(op))
smu_op = SMU_I2C_COMBINED;
cmd->cmd = SMU_I2C;
cmd->len = 9 + len;
cmd->data[0] = 0xb;
cmd->data[1] = smu_op;
cmd->data[2] = addr << 1;
cmd->data[3] = cmdlen;
memcpy (&cmd->data[4], cmdbuf, cmdlen);
cmd->data[7] = addr << 1 | I2C_OP_READ_P(op);
cmd->data[8] = len;
memcpy(&cmd->data[9], buf, len);
error = smu_do_cmd(sc, 250);
if (error)
return error;
while (retries--) {
cmd->cmd = SMU_I2C;
cmd->len = 1;
cmd->data[0] = 0;
memset(&cmd->data[1], 0xff, len);
error = smu_do_cmd(sc, 250);
if (error)
return error;
if ((cmd->data[0] & 0x80) == 0)
break;
if (cmd->data[0] == 0xfd)
break;
DELAY(15 * 1000);
}
if (cmd->data[0] & 0x80)
return (EIO);
if (I2C_OP_READ_P(op))
memcpy(buf, &cmd->data[1], len);
return (0);
}
void
smu_slew_voltage(u_int freq_scale)
{
struct smu_softc *sc = smu_cd.cd_devs[0];
struct smu_cmd *cmd = (struct smu_cmd *)sc->sc_cmd;
cmd->cmd = SMU_POWER;
cmd->len = 8;
memcpy(cmd->data, "VSLEW", 5);
cmd->data[5] = 0xff;
cmd->data[6] = 1;
cmd->data[7] = freq_scale;
smu_do_cmd(sc, 250);
}
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