hw/dts.c - skiboot - Git at Google

 // SPDX-License-Identifier: Apache-2.0
 /* Copyright 2013-2019 IBM Corp. */

 #include <xscom.h>
 #include <chip.h>
 #include <sensor.h>
 #include <dts.h>
 #include <skiboot.h>
 #include <opal-api.h>
 #include <opal-msg.h>
 #include <timer.h>
 #include <timebase.h>

 struct dts {
 	uint8_t		valid;
 	uint8_t		trip;
 	int16_t		temp;
 };

 /*
  * Attributes for the core temperature sensor
  */
 enum {
 	SENSOR_DTS_ATTR_TEMP_MAX,
 	SENSOR_DTS_ATTR_TEMP_TRIP
 };


 /* Therm mac result masking for DTS (result(0:15)
  *  0:3   - 0x0
  *  4:11  - Temperature in degrees C
  *  12:13 - trip bits: 00 - no trip; 01 - warning; 10 - critical; 11 - fatal
  *  14    - spare
  *  15    - valid
  */
 static void dts_decode_one_dts(uint16_t raw, struct dts *dts)
 {
 	/*
 	 * The value is both signed and unsigned :-) 0xff could be
 	 * either 255C or -1C, so for now we treat this as unsigned
 	 * which is sufficient for our purpose. We could try to be
 	 * a bit smarter and treat it as signed for values between
 	 * -10 and 0 and unsigned to 239 or something like that...
 	 */
 	dts->valid = raw & 1;
 	if (dts->valid) {
 		dts->temp = (raw >> 4) & 0xff;
 		dts->trip = (raw >> 2) & 0x3;
 	} else {
 		dts->temp = 0;
 		dts->trip = 0;
 	}
 }

 static void dts_keep_max(struct dts *temps, int n, struct dts *dts)
 {
 	int i;

 	for (i = 0; i < n; i++) {
 		int16_t t = temps[i].temp;

 		if (!temps[i].valid)
 			continue;

 		if (t > dts->temp)
 			dts->temp = t;

 		dts->valid++;
 		dts->trip |= temps[i].trip;
 	}
 }

 /* Per core Digital Thermal Sensors */
 #define EX_THERM_DTS_RESULT0	0x10050000
 #define EX_THERM_DTS_RESULT1	0x10050001

 /* Different sensor locations */
 #define P8_CT_ZONE_LSU	0
 #define P8_CT_ZONE_ISU	1
 #define P8_CT_ZONE_FXU	2
 #define P8_CT_ZONE_L3C	3
 #define P8_CT_ZONES	4

 /*
  * Returns the temperature as the max of all 4 zones and a global trip
  * attribute.
  */
 static int dts_read_core_temp_p8(uint32_t pir, struct dts *dts)
 {
 	int32_t chip_id = pir_to_chip_id(pir);
 	int32_t core = pir_to_core_id(pir);
 	uint64_t dts0, dts1;
 	struct dts temps[P8_CT_ZONES];
 	int rc;

 	rc = xscom_read(chip_id, XSCOM_ADDR_P8_EX(core, EX_THERM_DTS_RESULT0),
 			&dts0);
 	if (rc)
 		return rc;

 	rc = xscom_read(chip_id, XSCOM_ADDR_P8_EX(core, EX_THERM_DTS_RESULT1),
 			&dts1);
 	if (rc)
 		return rc;

 	dts_decode_one_dts(dts0 >> 48, &temps[P8_CT_ZONE_LSU]);
 	dts_decode_one_dts(dts0 >> 32, &temps[P8_CT_ZONE_ISU]);
 	dts_decode_one_dts(dts0 >> 16, &temps[P8_CT_ZONE_FXU]);
 	dts_decode_one_dts(dts1 >> 48, &temps[P8_CT_ZONE_L3C]);

 	dts_keep_max(temps, P8_CT_ZONES, dts);

 	prlog(PR_TRACE, "DTS: Chip %x Core %x temp:%dC trip:%x\n",
 	      chip_id, core, dts->temp, dts->trip);

 	/*
 	 * FIXME: The trip bits are always set ?! Just discard
 	 * them for the moment until we understand why.
 	 */
 	dts->trip = 0;
 	return 0;
 }

 /* Per core Digital Thermal Sensors */
 #define EC_THERM_P9_DTS_RESULT0	0x050000

 /* Different sensor locations */
 #define P9_CORE_DTS0	0
 #define P9_CORE_DTS1	1
 #define P9_CORE_ZONES	2

 /*
  * Returns the temperature as the max of all zones and a global trip
  * attribute.
  */
 static int dts_read_core_temp_p9(uint32_t pir, struct dts *dts)
 {
 	int32_t chip_id = pir_to_chip_id(pir);
 	int32_t core = pir_to_core_id(pir);
 	uint64_t dts0;
 	struct dts temps[P9_CORE_ZONES];
 	int rc;

 	rc = xscom_read(chip_id, XSCOM_ADDR_P9_EC(core, EC_THERM_P9_DTS_RESULT0),
 			&dts0);
 	if (rc)
 		return rc;

 	dts_decode_one_dts(dts0 >> 48, &temps[P9_CORE_DTS0]);
 	dts_decode_one_dts(dts0 >> 32, &temps[P9_CORE_DTS1]);

 	dts_keep_max(temps, P9_CORE_ZONES, dts);

 	prlog(PR_TRACE, "DTS: Chip %x Core %x temp:%dC trip:%x\n",
 	      chip_id, core, dts->temp, dts->trip);

 	/*
 	 * FIXME: The trip bits are always set ?! Just discard
 	 * them for the moment until we understand why.
 	 */
 	dts->trip = 0;
 	return 0;
 }

 static void dts_async_read_temp(struct timer *t __unused, void *data,
 				u64 now __unused)
 {
 	struct dts dts = {0};
 	int rc, swkup_rc;
 	struct cpu_thread *cpu = data;

 	swkup_rc = dctl_set_special_wakeup(cpu);

 	if (proc_gen == proc_gen_p9)
 		rc = dts_read_core_temp_p9(cpu->pir, &dts);
 	else /* (proc_gen == proc_gen_p10) */
 		rc = OPAL_UNSUPPORTED; /* XXX P10 */

 	if (!rc) {
 		if (cpu->sensor_attr == SENSOR_DTS_ATTR_TEMP_MAX)
 			*cpu->sensor_data = cpu_to_be64(dts.temp);
 		else if (cpu->sensor_attr == SENSOR_DTS_ATTR_TEMP_TRIP)
 			*cpu->sensor_data = cpu_to_be64(dts.trip);
 	}

 	if (!swkup_rc)
 		dctl_clear_special_wakeup(cpu);

 	check_sensor_read(cpu->token);
 	rc = opal_queue_msg(OPAL_MSG_ASYNC_COMP, NULL, NULL,
 			cpu_to_be64(cpu->token),
 			cpu_to_be64(rc));
 	if (rc)
 		prerror("Failed to queue async message\n");

 	cpu->dts_read_in_progress = false;
 }

 static int dts_read_core_temp(u32 pir, struct dts *dts, u8 attr,
 			      int token, __be64 *sensor_data)
 {
 	struct cpu_thread *cpu;
 	int rc;

 	switch (proc_gen) {
 	case proc_gen_p8:
 		rc = dts_read_core_temp_p8(pir, dts);
 		break;
 	case proc_gen_p9: /* Asynchronus read */
 		cpu = find_cpu_by_pir(pir);
 		if (!cpu)
 			return OPAL_PARAMETER;
 		lock(&cpu->dts_lock);
 		if (cpu->dts_read_in_progress) {
 			unlock(&cpu->dts_lock);
 			return OPAL_BUSY;
 		}
 		cpu->dts_read_in_progress = true;
 		cpu->sensor_attr = attr;
 		cpu->sensor_data = sensor_data;
 		cpu->token = token;
 		schedule_timer(&cpu->dts_timer, 0);
 		rc = OPAL_ASYNC_COMPLETION;
 		unlock(&cpu->dts_lock);
 		break;
 	case proc_gen_p10: /* XXX P10 */
 	default:
 		rc = OPAL_UNSUPPORTED;
 	}
 	return rc;
 }

 /* Per memory controller Digital Thermal Sensors */
 #define THERM_MEM_DTS_RESULT0	0x2050000

 /* Different sensor locations */
 #define P8_MEM_DTS0	0
 #define P8_MEM_DTS1	1
 #define P8_MEM_ZONES	2

 static int dts_read_mem_temp(uint32_t chip_id, struct dts *dts)
 {
 	uint64_t dts0;
 	struct dts temps[P8_MEM_ZONES];
 	int i;
 	int rc;

 	rc = xscom_read(chip_id, THERM_MEM_DTS_RESULT0, &dts0);
 	if (rc)
 		return rc;

 	dts_decode_one_dts(dts0 >> 48, &temps[P8_MEM_DTS0]);
 	dts_decode_one_dts(dts0 >> 32, &temps[P8_MEM_DTS1]);

 	for (i = 0; i < P8_MEM_ZONES; i++) {
 		int16_t t = temps[i].temp;

 		if (!temps[i].valid)
 			continue;

 		/* keep the max temperature of all 4 sensors */
 		if (t > dts->temp)
 			dts->temp = t;

 		dts->valid++;
 		dts->trip |= temps[i].trip;
 	}

 	prlog(PR_TRACE, "DTS: Chip %x temp:%dC trip:%x\n",
 	      chip_id, dts->temp, dts->trip);

 	/*
 	 * FIXME: The trip bits are always set ?! Just discard
 	 * them for the moment until we understand why.
 	 */
 	dts->trip = 0;
 	return 0;
 }

 /*
  * DTS sensor class ids. Only one for the moment: the core
  * temperature.
  */
 enum sensor_dts_class {
 	SENSOR_DTS_CORE_TEMP,
 	SENSOR_DTS_MEM_TEMP,
 	/* To be continued */
 };

 /*
  * Extract the centaur chip id which was truncated to fit in the
  * resource identifier field of the sensor handler
  */
 #define centaur_get_id(rid) (0x80000000 | ((rid) & 0x3ff))

 int64_t dts_sensor_read(u32 sensor_hndl, int token, __be64 *sensor_data)
 {
 	uint8_t	attr = sensor_get_attr(sensor_hndl);
 	uint32_t rid = sensor_get_rid(sensor_hndl);
 	struct dts dts = {0};
 	int64_t rc;

 	if (attr > SENSOR_DTS_ATTR_TEMP_TRIP)
 		return OPAL_PARAMETER;

 	memset(&dts, 0, sizeof(struct dts));

 	switch (sensor_get_frc(sensor_hndl)) {
 	case SENSOR_DTS_CORE_TEMP:
 		rc = dts_read_core_temp(rid, &dts, attr, token, sensor_data);
 		break;
 	case SENSOR_DTS_MEM_TEMP:
 		rc = dts_read_mem_temp(centaur_get_id(rid), &dts);
 		break;
 	default:
 		rc = OPAL_PARAMETER;
 		break;
 	}
 	if (rc)
 		return rc;

 	if (attr == SENSOR_DTS_ATTR_TEMP_MAX)
 		*sensor_data = cpu_to_be64(dts.temp);
 	else if (attr == SENSOR_DTS_ATTR_TEMP_TRIP)
 		*sensor_data = cpu_to_be64(dts.trip);

 	return 0;
 }

 /*
  * We only have two bytes for the resource identifier in the sensor
  * handler. Let's trunctate the centaur chip id to squeeze it in.
  *
  * Centaur chip IDs are using the XSCOM "partID" encoding described in
  * xscom.h. recap:
  *
  *     0b1000.0000.0000.0000.0000.00NN.NCCC.MMMM
  *     N=Node, C=Chip, M=Memory Channel
  */
 #define centaur_make_id(cen_id, dimm_id)	\
 	(((chip_id) & 0x3ff) | ((dimm_id) << 10))

 #define core_handler(core_id, attr_id)					\
 	sensor_make_handler(SENSOR_DTS, SENSOR_DTS_CORE_TEMP,		\
 			    core_id, attr_id)

 #define cen_handler(cen_id, attr_id)					\
 	sensor_make_handler(SENSOR_DTS, SENSOR_DTS_MEM_TEMP,		\
 			    centaur_make_id(chip_id, 0), attr_id)

 bool dts_sensor_create_nodes(struct dt_node *sensors)
 {
 	struct proc_chip *chip;
 	struct dt_node *cn;
 	char name[64];

 	/* build the device tree nodes :
 	 *
 	 *     sensors/core-temp@pir
 	 *
 	 * The core is identified by its PIR, is stored in the resource
 	 * number of the sensor handler.
 	 */
 	for_each_chip(chip) {
 		struct cpu_thread *c;

 		for_each_available_core_in_chip(c, chip->id) {
 			struct dt_node *node;
 			uint32_t handler;

 			snprintf(name, sizeof(name), "core-temp@%x", c->pir);

 			handler = core_handler(c->pir, SENSOR_DTS_ATTR_TEMP_MAX);
 			node = dt_new(sensors, name);
 			dt_add_property_string(node, "compatible",
 					       "ibm,opal-sensor");
 			dt_add_property_cells(node, "sensor-data", handler);
 			handler = core_handler(c->pir, SENSOR_DTS_ATTR_TEMP_TRIP);
 			dt_add_property_cells(node, "sensor-status", handler);
 			dt_add_property_string(node, "sensor-type", "temp");
 			dt_add_property_cells(node, "ibm,pir", c->pir);
 			dt_add_property_cells(node, "reg", handler);
 			dt_add_property_string(node, "label", "Core");
 			init_timer(&c->dts_timer, dts_async_read_temp, c);
 			c->dts_read_in_progress = false;
 		}
 	}

 	/*
 	 * sensors/mem-temp@chip for Centaurs
 	 */
 	dt_for_each_compatible(dt_root, cn, "ibm,centaur") {
 		uint32_t chip_id;
 		struct dt_node *node;
 		uint32_t handler;

 		chip_id = dt_prop_get_u32(cn, "ibm,chip-id");

 		snprintf(name, sizeof(name), "mem-temp@%x", chip_id);

 		handler = cen_handler(chip_id, SENSOR_DTS_ATTR_TEMP_MAX);
 		node = dt_new(sensors, name);
 		dt_add_property_string(node, "compatible",
 				       "ibm,opal-sensor");
 		dt_add_property_cells(node, "sensor-data", handler);

 		handler = cen_handler(chip_id, SENSOR_DTS_ATTR_TEMP_TRIP);
 		dt_add_property_cells(node, "sensor-status", handler);
 		dt_add_property_string(node, "sensor-type", "temp");
 		dt_add_property_cells(node, "ibm,chip-id", chip_id);
 		dt_add_property_cells(node, "reg", handler);
 		dt_add_property_string(node, "label", "Centaur");
 	}

 	return true;
 }
	// SPDX-License-Identifier: Apache-2.0
	/* Copyright 2013-2019 IBM Corp. */

	#include <xscom.h>
	#include <chip.h>
	#include <sensor.h>
	#include <dts.h>
	#include <skiboot.h>
	#include <opal-api.h>
	#include <opal-msg.h>
	#include <timer.h>
	#include <timebase.h>

	struct dts {
	uint8_t valid;
	uint8_t trip;
	int16_t temp;
	};

	/*
	* Attributes for the core temperature sensor
	*/
	enum {
	SENSOR_DTS_ATTR_TEMP_MAX,
	SENSOR_DTS_ATTR_TEMP_TRIP
	};


	/* Therm mac result masking for DTS (result(0:15)
	* 0:3 - 0x0
	* 4:11 - Temperature in degrees C
	* 12:13 - trip bits: 00 - no trip; 01 - warning; 10 - critical; 11 - fatal
	* 14 - spare
	* 15 - valid
	*/
	static void dts_decode_one_dts(uint16_t raw, struct dts *dts)
	{
	/*
	* The value is both signed and unsigned :-) 0xff could be
	* either 255C or -1C, so for now we treat this as unsigned
	* which is sufficient for our purpose. We could try to be
	* a bit smarter and treat it as signed for values between
	* -10 and 0 and unsigned to 239 or something like that...
	*/
	dts->valid = raw & 1;
	if (dts->valid) {
	dts->temp = (raw >> 4) & 0xff;
	dts->trip = (raw >> 2) & 0x3;
	} else {
	dts->temp = 0;
	dts->trip = 0;
	}
	}

	static void dts_keep_max(struct dts temps, int n, struct dts dts)
	{
	int i;

	for (i = 0; i < n; i++) {
	int16_t t = temps[i].temp;

	if (!temps[i].valid)
	continue;

	if (t > dts->temp)
	dts->temp = t;

	dts->valid++;
	dts->trip \|= temps[i].trip;
	}
	}

	/* Per core Digital Thermal Sensors */
	#define EX_THERM_DTS_RESULT0 0x10050000
	#define EX_THERM_DTS_RESULT1 0x10050001

	/* Different sensor locations */
	#define P8_CT_ZONE_LSU 0
	#define P8_CT_ZONE_ISU 1
	#define P8_CT_ZONE_FXU 2
	#define P8_CT_ZONE_L3C 3
	#define P8_CT_ZONES 4

	/*
	* Returns the temperature as the max of all 4 zones and a global trip
	* attribute.
	*/
	static int dts_read_core_temp_p8(uint32_t pir, struct dts *dts)
	{
	int32_t chip_id = pir_to_chip_id(pir);
	int32_t core = pir_to_core_id(pir);
	uint64_t dts0, dts1;
	struct dts temps[P8_CT_ZONES];
	int rc;

	rc = xscom_read(chip_id, XSCOM_ADDR_P8_EX(core, EX_THERM_DTS_RESULT0),
	&dts0);
	if (rc)
	return rc;

	rc = xscom_read(chip_id, XSCOM_ADDR_P8_EX(core, EX_THERM_DTS_RESULT1),
	&dts1);
	if (rc)
	return rc;

	dts_decode_one_dts(dts0 >> 48, &temps[P8_CT_ZONE_LSU]);
	dts_decode_one_dts(dts0 >> 32, &temps[P8_CT_ZONE_ISU]);
	dts_decode_one_dts(dts0 >> 16, &temps[P8_CT_ZONE_FXU]);
	dts_decode_one_dts(dts1 >> 48, &temps[P8_CT_ZONE_L3C]);

	dts_keep_max(temps, P8_CT_ZONES, dts);

	prlog(PR_TRACE, "DTS: Chip %x Core %x temp:%dC trip:%x\n",
	chip_id, core, dts->temp, dts->trip);

	/*
	* FIXME: The trip bits are always set ?! Just discard
	* them for the moment until we understand why.
	*/
	dts->trip = 0;
	return 0;
	}

	/* Per core Digital Thermal Sensors */
	#define EC_THERM_P9_DTS_RESULT0 0x050000

	/* Different sensor locations */
	#define P9_CORE_DTS0 0
	#define P9_CORE_DTS1 1
	#define P9_CORE_ZONES 2

	/*
	* Returns the temperature as the max of all zones and a global trip
	* attribute.
	*/
	static int dts_read_core_temp_p9(uint32_t pir, struct dts *dts)
	{
	int32_t chip_id = pir_to_chip_id(pir);
	int32_t core = pir_to_core_id(pir);
	uint64_t dts0;
	struct dts temps[P9_CORE_ZONES];
	int rc;

	rc = xscom_read(chip_id, XSCOM_ADDR_P9_EC(core, EC_THERM_P9_DTS_RESULT0),
	&dts0);
	if (rc)
	return rc;

	dts_decode_one_dts(dts0 >> 48, &temps[P9_CORE_DTS0]);
	dts_decode_one_dts(dts0 >> 32, &temps[P9_CORE_DTS1]);

	dts_keep_max(temps, P9_CORE_ZONES, dts);

	prlog(PR_TRACE, "DTS: Chip %x Core %x temp:%dC trip:%x\n",
	chip_id, core, dts->temp, dts->trip);

	/*
	* FIXME: The trip bits are always set ?! Just discard
	* them for the moment until we understand why.
	*/
	dts->trip = 0;
	return 0;
	}

	static void dts_async_read_temp(struct timer t __unused, void data,
	u64 now __unused)
	{
	struct dts dts = {0};
	int rc, swkup_rc;
	struct cpu_thread *cpu = data;

	swkup_rc = dctl_set_special_wakeup(cpu);

	if (proc_gen == proc_gen_p9)
	rc = dts_read_core_temp_p9(cpu->pir, &dts);
	else /* (proc_gen == proc_gen_p10) */
	rc = OPAL_UNSUPPORTED; /* XXX P10 */

	if (!rc) {
	if (cpu->sensor_attr == SENSOR_DTS_ATTR_TEMP_MAX)
	*cpu->sensor_data = cpu_to_be64(dts.temp);
	else if (cpu->sensor_attr == SENSOR_DTS_ATTR_TEMP_TRIP)
	*cpu->sensor_data = cpu_to_be64(dts.trip);
	}

	if (!swkup_rc)
	dctl_clear_special_wakeup(cpu);

	check_sensor_read(cpu->token);
	rc = opal_queue_msg(OPAL_MSG_ASYNC_COMP, NULL, NULL,
	cpu_to_be64(cpu->token),
	cpu_to_be64(rc));
	if (rc)
	prerror("Failed to queue async message\n");

	cpu->dts_read_in_progress = false;
	}

	static int dts_read_core_temp(u32 pir, struct dts *dts, u8 attr,
	int token, __be64 *sensor_data)
	{
	struct cpu_thread *cpu;
	int rc;

	switch (proc_gen) {
	case proc_gen_p8:
	rc = dts_read_core_temp_p8(pir, dts);
	break;
	case proc_gen_p9: /* Asynchronus read */
	cpu = find_cpu_by_pir(pir);
	if (!cpu)
	return OPAL_PARAMETER;
	lock(&cpu->dts_lock);
	if (cpu->dts_read_in_progress) {
	unlock(&cpu->dts_lock);
	return OPAL_BUSY;
	}
	cpu->dts_read_in_progress = true;
	cpu->sensor_attr = attr;
	cpu->sensor_data = sensor_data;
	cpu->token = token;
	schedule_timer(&cpu->dts_timer, 0);
	rc = OPAL_ASYNC_COMPLETION;
	unlock(&cpu->dts_lock);
	break;
	case proc_gen_p10: /* XXX P10 */
	default:
	rc = OPAL_UNSUPPORTED;
	}
	return rc;
	}

	/* Per memory controller Digital Thermal Sensors */
	#define THERM_MEM_DTS_RESULT0 0x2050000

	/* Different sensor locations */
	#define P8_MEM_DTS0 0
	#define P8_MEM_DTS1 1
	#define P8_MEM_ZONES 2

	static int dts_read_mem_temp(uint32_t chip_id, struct dts *dts)
	{
	uint64_t dts0;
	struct dts temps[P8_MEM_ZONES];
	int i;
	int rc;

	rc = xscom_read(chip_id, THERM_MEM_DTS_RESULT0, &dts0);
	if (rc)
	return rc;

	dts_decode_one_dts(dts0 >> 48, &temps[P8_MEM_DTS0]);
	dts_decode_one_dts(dts0 >> 32, &temps[P8_MEM_DTS1]);

	for (i = 0; i < P8_MEM_ZONES; i++) {
	int16_t t = temps[i].temp;

	if (!temps[i].valid)
	continue;

	/* keep the max temperature of all 4 sensors */
	if (t > dts->temp)
	dts->temp = t;

	dts->valid++;
	dts->trip \|= temps[i].trip;
	}

	prlog(PR_TRACE, "DTS: Chip %x temp:%dC trip:%x\n",
	chip_id, dts->temp, dts->trip);

	/*
	* FIXME: The trip bits are always set ?! Just discard
	* them for the moment until we understand why.
	*/
	dts->trip = 0;
	return 0;
	}

	/*
	* DTS sensor class ids. Only one for the moment: the core
	* temperature.
	*/
	enum sensor_dts_class {
	SENSOR_DTS_CORE_TEMP,
	SENSOR_DTS_MEM_TEMP,
	/* To be continued */
	};

	/*
	* Extract the centaur chip id which was truncated to fit in the
	* resource identifier field of the sensor handler
	*/
	#define centaur_get_id(rid) (0x80000000 \| ((rid) & 0x3ff))

	int64_t dts_sensor_read(u32 sensor_hndl, int token, __be64 *sensor_data)
	{
	uint8_t attr = sensor_get_attr(sensor_hndl);
	uint32_t rid = sensor_get_rid(sensor_hndl);
	struct dts dts = {0};
	int64_t rc;

	if (attr > SENSOR_DTS_ATTR_TEMP_TRIP)
	return OPAL_PARAMETER;

	memset(&dts, 0, sizeof(struct dts));

	switch (sensor_get_frc(sensor_hndl)) {
	case SENSOR_DTS_CORE_TEMP:
	rc = dts_read_core_temp(rid, &dts, attr, token, sensor_data);
	break;
	case SENSOR_DTS_MEM_TEMP:
	rc = dts_read_mem_temp(centaur_get_id(rid), &dts);
	break;
	default:
	rc = OPAL_PARAMETER;
	break;
	}
	if (rc)
	return rc;

	if (attr == SENSOR_DTS_ATTR_TEMP_MAX)
	*sensor_data = cpu_to_be64(dts.temp);
	else if (attr == SENSOR_DTS_ATTR_TEMP_TRIP)
	*sensor_data = cpu_to_be64(dts.trip);

	return 0;
	}

	/*
	* We only have two bytes for the resource identifier in the sensor
	* handler. Let's trunctate the centaur chip id to squeeze it in.
	*
	* Centaur chip IDs are using the XSCOM "partID" encoding described in
	* xscom.h. recap:
	*
	* 0b1000.0000.0000.0000.0000.00NN.NCCC.MMMM
	* N=Node, C=Chip, M=Memory Channel
	*/
	#define centaur_make_id(cen_id, dimm_id) \
	(((chip_id) & 0x3ff) \| ((dimm_id) << 10))

	#define core_handler(core_id, attr_id) \
	sensor_make_handler(SENSOR_DTS, SENSOR_DTS_CORE_TEMP, \
	core_id, attr_id)

	#define cen_handler(cen_id, attr_id) \
	sensor_make_handler(SENSOR_DTS, SENSOR_DTS_MEM_TEMP, \
	centaur_make_id(chip_id, 0), attr_id)

	bool dts_sensor_create_nodes(struct dt_node *sensors)
	{
	struct proc_chip *chip;
	struct dt_node *cn;
	char name[64];

	/* build the device tree nodes :
	*
	* sensors/core-temp@pir
	*
	* The core is identified by its PIR, is stored in the resource
	* number of the sensor handler.
	*/
	for_each_chip(chip) {
	struct cpu_thread *c;

	for_each_available_core_in_chip(c, chip->id) {
	struct dt_node *node;
	uint32_t handler;

	snprintf(name, sizeof(name), "core-temp@%x", c->pir);

	handler = core_handler(c->pir, SENSOR_DTS_ATTR_TEMP_MAX);
	node = dt_new(sensors, name);
	dt_add_property_string(node, "compatible",
	"ibm,opal-sensor");
	dt_add_property_cells(node, "sensor-data", handler);
	handler = core_handler(c->pir, SENSOR_DTS_ATTR_TEMP_TRIP);
	dt_add_property_cells(node, "sensor-status", handler);
	dt_add_property_string(node, "sensor-type", "temp");
	dt_add_property_cells(node, "ibm,pir", c->pir);
	dt_add_property_cells(node, "reg", handler);
	dt_add_property_string(node, "label", "Core");
	init_timer(&c->dts_timer, dts_async_read_temp, c);
	c->dts_read_in_progress = false;
	}
	}

	/*
	* sensors/mem-temp@chip for Centaurs
	*/
	dt_for_each_compatible(dt_root, cn, "ibm,centaur") {
	uint32_t chip_id;
	struct dt_node *node;
	uint32_t handler;

	chip_id = dt_prop_get_u32(cn, "ibm,chip-id");

	snprintf(name, sizeof(name), "mem-temp@%x", chip_id);

	handler = cen_handler(chip_id, SENSOR_DTS_ATTR_TEMP_MAX);
	node = dt_new(sensors, name);
	dt_add_property_string(node, "compatible",
	"ibm,opal-sensor");
	dt_add_property_cells(node, "sensor-data", handler);

	handler = cen_handler(chip_id, SENSOR_DTS_ATTR_TEMP_TRIP);
	dt_add_property_cells(node, "sensor-status", handler);
	dt_add_property_string(node, "sensor-type", "temp");
	dt_add_property_cells(node, "ibm,chip-id", chip_id);
	dt_add_property_cells(node, "reg", handler);
	dt_add_property_string(node, "label", "Centaur");
	}

	return true;
	}