soc/intel/quark: Add temperature sensor support

Migrate the temperature sensor support from QuarkFspPkg into coreboot. TEST=Build and run on Galileo Gen2 Change-Id: I6dc68c735375c9d1777693264674521f67397556 Signed-off-by: Lee Leahy <leroy.p.leahy@intel.com> Reviewed-on: https://review.coreboot.org/14565 Tested-by: build bot (Jenkins) Reviewed-by: Martin Roth <martinroth@google.com>
2016-04-30 08:48:52 -07:00 · 2016-04-30 08:48:52 -07:00 · 63e3dff02f
parent 4dd34eee09
commit 63e3dff02f
3 changed files with 197 additions and 0 deletions
--- a/src/soc/intel/quark/chip.c
+++ b/src/soc/intel/quark/chip.c
@ -17,9 +17,104 @@
 #include <console/console.h>
 #include <device/device.h>
 #include <soc/ramstage.h>
 #include <soc/reg_access.h>
 /* Cat Trip Clear value must be less than Cat Trip Set value */
 #define PLATFORM_CATASTROPHIC_TRIP_CELSIUS	105
 #define PLATFORM_CATASTROPHIC_CLEAR_CELSIUS	65
 static const struct reg_script thermal_init_script[] = {
 	/* Setup RMU Thermal sensor registers for Ratiometric mode. */
 	REG_SOC_UNIT_RMW(QUARK_SCSS_SOC_UNIT_TSCGF1_CONFIG,
 		~(B_TSCGF1_CONFIG_ISNSCURRENTSEL_MASK
 			| B_TSCGF1_CONFIG_ISNSCHOPSEL_MASK
 			| B_TSCGF1_CONFIG_ISNSINTERNALVREFEN
 			| B_TSCGF1_CONFIG_IBGEN
 			| B_TSCGF1_CONFIG_IBGCHOPEN),
 		((V_TSCGF1_CONFIG_ISNSCURRENTSEL_RATIO_MODE
 			<< B_TSCGF1_CONFIG_ISNSCURRENTSEL_BP)
 		| (V_TSCGF1_CONFIG_ISNSCHOPSEL_RATIO_MODE
 			<< B_TSCGF1_CONFIG_ISNSCHOPSEL_BP)
 		| (V_TSCGF1_CONFIG_ISNSINTERNALVREFEN_RATIO_MODE
 			<< B_TSCGF1_CONFIG_ISNSINTERNALVREFEN_BP)
 		| (V_TSCGF1_CONFIG_IBGEN_RATIO_MODE
 			<< B_TSCGF1_CONFIG_IBGEN_BP)
 		| (V_TSCGF1_CONFIG_IBGCHOPEN_RATIO_MODE
 			<< B_TSCGF1_CONFIG_IBGCHOPEN_BP))),
 	REG_SOC_UNIT_RMW(QUARK_SCSS_SOC_UNIT_TSCGF2_CONFIG2,
 		~(B_TSCGF2_CONFIG2_ICALCONFIGSEL_MASK
 			| B_TSCGF2_CONFIG2_ISPARECTRL_MASK
 			| B_TSCGF2_CONFIG2_ICALCOARSETUNE_MASK),
 		((V_TSCGF2_CONFIG2_ICALCONFIGSEL_RATIO_MODE
 			<< B_TSCGF2_CONFIG2_ICALCONFIGSEL_BP)
 		| (V_TSCGF2_CONFIG2_ISPARECTRL_RATIO_MODE
 			<< B_TSCGF2_CONFIG2_ISPARECTRL_BP)
 		| (V_TSCGF2_CONFIG2_ICALCOARSETUNE_RATIO_MODE
 			<< B_TSCGF2_CONFIG2_ICALCOARSETUNE_BP))),
 	REG_SOC_UNIT_RMW(QUARK_SCSS_SOC_UNIT_TSCGF2_CONFIG,
 		~(B_TSCGF2_CONFIG_IDSCONTROL_MASK
 			| B_TSCGF2_CONFIG_IDSTIMING_MASK),
 		((V_TSCGF2_CONFIG_IDSCONTROL_RATIO_MODE
 			<< B_TSCGF2_CONFIG_IDSCONTROL_BP)
 		| (V_TSCGF2_CONFIG_IDSTIMING_RATIO_MODE
 			<< B_TSCGF2_CONFIG_IDSTIMING_BP))),
 	REG_SOC_UNIT_RMW(QUARK_SCSS_SOC_UNIT_TSCGF3_CONFIG,
 		~B_TSCGF3_CONFIG_ITSGAMMACOEFF_MASK,
 		V_TSCGF3_CONFIG_ITSGAMMACOEFF_RATIO_MODE
 			<< B_TSCGF3_CONFIG_ITSGAMMACOEFF_BP),
 	/* Enable RMU Thermal sensor with a Catastrophic Trip point. */
 	/* Set up Catastrophic Trip point.
 	*
 	* Trip Register fields are 8-bit temperature values of granularity 1
 	* degree C where 0x00 corresponds to -50 degrees C and 0xFF corresponds
 	* to 205 degrees C.
 	*
 	* Add 50 to Celsius values to get values for register fields.
 	*/
 	REG_RMU_TEMP_RMW(QUARK_NC_RMU_REG_TS_TRIP,
 		~(TS_CAT_TRIP_SET_THOLD_MASK | TS_CAT_TRIP_CLEAR_THOLD_MASK),
 		(((PLATFORM_CATASTROPHIC_TRIP_CELSIUS + 50)
 			<< TS_CAT_TRIP_SET_THOLD_BP)
 		| ((PLATFORM_CATASTROPHIC_CLEAR_CELSIUS + 50)
 			<< TS_CAT_TRIP_CLEAR_THOLD_BP))),
 	/* To enable the TS do the following:
 	 *    1)  Take the TS out of reset by setting itsrst to 0x0.
 	 *    2)  Enable the TS using RMU Thermal sensor mode register.
 	 */
 	REG_SOC_UNIT_AND(QUARK_SCSS_SOC_UNIT_TSCGF3_CONFIG,
 		~B_TSCGF3_CONFIG_ITSRST),
 	REG_RMU_TEMP_OR(QUARK_NC_RMU_REG_TS_MODE, TS_ENABLE),
 	/* Lock all RMU Thermal sensor control & trip point registers. */
 	REG_RMU_TEMP_OR(QUARK_NC_RMU_REG_CONFIG, TS_LOCK_THRM_CTRL_REGS_ENABLE
 		| TS_LOCK_AUX_TRIP_PT_REGS_ENABLE),
 	REG_SCRIPT_END
 };
 static void chip_init(void *chip_info)
 {
 	/* Validate the temperature settings */
 	ASSERT(PLATFORM_CATASTROPHIC_TRIP_CELSIUS <= 255);
 	ASSERT(PLATFORM_CATASTROPHIC_TRIP_CELSIUS
 		> PLATFORM_CATASTROPHIC_CLEAR_CELSIUS);
 	/* Set the temperature settings */
 	reg_script_run(thermal_init_script);
 	/* Verify that the thermal configuration is locked */
 	ASSERT((reg_rmu_temp_read(QUARK_NC_RMU_REG_CONFIG)
 		& (TS_LOCK_THRM_CTRL_REGS_ENABLE
 			| TS_LOCK_AUX_TRIP_PT_REGS_ENABLE))
 		== (TS_LOCK_THRM_CTRL_REGS_ENABLE
 			| TS_LOCK_AUX_TRIP_PT_REGS_ENABLE));
 	/* Perform silicon specific init. */
 	if (IS_ENABLED(CONFIG_RELOCATE_FSP_INTO_DRAM))
 		intel_silicon_init();
--- a/src/soc/intel/quark/include/soc/reg_access.h
+++ b/src/soc/intel/quark/include/soc/reg_access.h
@ -18,10 +18,13 @@
 #include <fsp/util.h>
 #include <reg_script.h>
 #include <soc/IntelQNCConfig.h>
 #include <soc/QuarkNcSocId.h>
 enum {
 	USB_PHY_REGS = 1,
 	SOC_UNIT_REGS,
 	RMU_TEMP_REGS,
 };
 enum {
@ -32,6 +35,50 @@ enum {
 #define SOC_ACCESS(cmd_, reg_, size_, mask_, value_, timeout_, reg_set_)   \
 	_REG_SCRIPT_ENCODE_RAW(REG_SCRIPT_COMMAND_##cmd_, SOC_TYPE,        \
 			       size_, reg_, mask_, value_, timeout_, reg_set_)
 /* RMU temperature register access macros */
 #define REG_RMU_TEMP_ACCESS(cmd_, reg_, mask_, value_, timeout_) \
 	SOC_ACCESS(cmd_, reg_, REG_SCRIPT_SIZE_32, mask_, value_, timeout_, \
 		RMU_TEMP_REGS)
 #define REG_RMU_TEMP_READ(reg_) \
 	REG_RMU_TEMP_ACCESS(READ, reg_, 0, 0, 0)
 #define REG_RMU_TEMP_WRITE(reg_, value_) \
 	REG_RMU_TEMP_ACCESS(WRITE, reg_, 0, value_, 0)
 #define REG_RMU_TEMP_AND(reg_, value_) \
 	REG_RMU_TEMP_RMW(reg_, value_, 0)
 #define REG_RMU_TEMP_RMW(reg_, mask_, value_) \
 	REG_RMU_TEMP_ACCESS(RMW, reg_, mask_, value_, 0)
 #define REG_RMU_TEMP_RXW(reg_, mask_, value_) \
 	REG_RMU_TEMP_ACCESS(RXW, reg_, mask_, value_, 0)
 #define REG_RMU_TEMP_OR(reg_, value_) \
 	REG_RMU_TEMP_RMW(reg_, 0xffffffff, value_)
 #define REG_RMU_TEMP_POLL(reg_, mask_, value_, timeout_) \
 	REG_RMU_TEMP_ACCESS(POLL, reg_, mask_, value_, timeout_)
 #define REG_RMU_TEMP_XOR(reg_, value_) \
 	REG_RMU_TEMP_RXW(reg_, 0xffffffff, value_)
 /* Temperature sensor access macros */
 #define REG_SOC_UNIT_ACCESS(cmd_, reg_, mask_, value_, timeout_) \
 	SOC_ACCESS(cmd_, reg_, REG_SCRIPT_SIZE_32, mask_, value_, timeout_, \
 		SOC_UNIT_REGS)
 #define REG_SOC_UNIT_READ(reg_) \
 	REG_SOC_UNIT_ACCESS(READ, reg_, 0, 0, 0)
 #define REG_SOC_UNIT_WRITE(reg_, value_) \
 	REG_SOC_UNIT_ACCESS(WRITE, reg_, 0, value_, 0)
 #define REG_SOC_UNIT_AND(reg_, value_) \
 	REG_SOC_UNIT_RMW(reg_, value_, 0)
 #define REG_SOC_UNIT_RMW(reg_, mask_, value_) \
 	REG_SOC_UNIT_ACCESS(RMW, reg_, mask_, value_, 0)
 #define REG_SOC_UNIT_RXW(reg_, mask_, value_) \
 	REG_SOC_UNIT_ACCESS(RXW, reg_, mask_, value_, 0)
 #define REG_SOC_UNIT_OR(reg_, value_) \
 	REG_SOC_UNIT_RMW(reg_, 0xffffffff, value_)
 #define REG_SOC_UNIT_POLL(reg_, mask_, value_, timeout_) \
 	REG_SOC_UNIT_ACCESS(POLL, reg_, mask_, value_, timeout_)
 #define REG_SOC_UNIT_XOR(reg_, value_) \
 	REG_SOC_UNIT_RXW(reg_, 0xffffffff, value_)
 /* USB register access macros */
 #define REG_USB_ACCESS(cmd_, reg_, mask_, value_, timeout_) \
 	SOC_ACCESS(cmd_, reg_, REG_SCRIPT_SIZE_32, mask_, value_, timeout_, \
 		USB_PHY_REGS)
@ -56,5 +103,6 @@ void mcr_write(uint8_t opcode, uint8_t port, uint32_t reg_address);
 uint32_t mdr_read(void);
 void mdr_write(uint32_t value);
 void mea_write(uint32_t reg_address);
 uint32_t reg_rmu_temp_read(uint32_t reg_address);
 #endif /* _QUARK_REG_ACCESS_H_ */
--- a/src/soc/intel/quark/reg_access.c
+++ b/src/soc/intel/quark/reg_access.c
@ -45,6 +45,40 @@ void mea_write(uint32_t reg_address)
 		& QNC_MEA_MASK);
 }
 uint32_t reg_rmu_temp_read(uint32_t reg_address)
 {
 	/* Read the RMU temperature register */
 	mea_write(reg_address);
 	mcr_write(QUARK_OPCODE_READ, QUARK_NC_RMU_SB_PORT_ID, reg_address);
 	return mdr_read();
 }
 static void reg_rmu_temp_write(uint32_t reg_address, uint32_t value)
 {
 	/* Write the RMU temperature register */
 	mea_write(reg_address);
 	mdr_write(value);
 	mcr_write(QUARK_OPCODE_WRITE, QUARK_NC_RMU_SB_PORT_ID, reg_address);
 }
 static uint32_t reg_soc_unit_read(uint32_t reg_address)
 {
 	/* Read the temperature sensor register */
 	mea_write(reg_address);
 	mcr_write(QUARK_ALT_OPCODE_READ, QUARK_SCSS_SOC_UNIT_SB_PORT_ID,
 		reg_address);
 	return mdr_read();
 }
 static void reg_soc_unit_write(uint32_t reg_address, uint32_t value)
 {
 	/* Write the temperature sensor register */
 	mea_write(reg_address);
 	mdr_write(value);
 	mcr_write(QUARK_ALT_OPCODE_WRITE, QUARK_SCSS_SOC_UNIT_SB_PORT_ID,
 		reg_address);
 }
 static uint32_t reg_usb_read(uint32_t reg_address)
 {
 	/* Read the USB register */
@ -76,6 +110,16 @@ static uint64_t reg_read(struct reg_script_context *ctx)
 		ctx->display_features = REG_SCRIPT_DISPLAY_NOTHING;
 		return 0;
 	case RMU_TEMP_REGS:
 		ctx->display_prefix = "RMU TEMP";
 		value = reg_rmu_temp_read(step->reg);
 		break;
 	case SOC_UNIT_REGS:
 		ctx->display_prefix = "SOC Unit";
 		value = reg_soc_unit_read(step->reg);
 		break;
 	case USB_PHY_REGS:
 		ctx->display_prefix = "USB PHY";
 		value = reg_usb_read(step->reg);
@ -96,6 +140,16 @@ static void reg_write(struct reg_script_context *ctx)
 		ctx->display_features = REG_SCRIPT_DISPLAY_NOTHING;
 		return;
 	case RMU_TEMP_REGS:
 		ctx->display_prefix = "RMU TEMP";
 		reg_rmu_temp_write(step->reg, (uint32_t)step->value);
 		break;
 	case SOC_UNIT_REGS:
 		ctx->display_prefix = "SOC Unit";
 		reg_soc_unit_write(step->reg, (uint32_t)step->value);
 		break;
 	case USB_PHY_REGS:
 		ctx->display_prefix = "USB PHY";
 		reg_usb_write(step->reg, (uint32_t)step->value);