include/linux/msm_adc.h - kernel/msm.git - Git at Google

 #ifndef __MSM_ADC_H
 #define __MSM_ADC_H

 #include <linux/sched.h>

 #define MSM_ADC_MAX_CHAN_STR 64

 /* must be <= to the max buffer size in the modem implementation */
 #define MSM_ADC_DEV_MAX_INFLIGHT 9

 #define MSM_ADC_IOCTL_CODE		0x90

 struct msm_adc_conversion {
 	/* hwmon channel number - this is not equivalent to the DAL chan */
 	uint32_t chan;
 	/* returned result in ms */
 	int result;
 };

 struct adc_chan_result {
 	/* The channel number of the requesting/requested conversion */
 	uint32_t chan;
 	/* The pre-calibrated digital output of a given ADC relative to the
 	ADC reference */
 	int32_t adc_code;
 	/* in units specific for a given ADC; most ADC uses reference voltage
 	 *  but some ADC uses reference current.  This measurement here is
 	 *  a number relative to a reference of a given ADC */
 	int64_t measurement;
 	/* The data meaningful for each individual channel whether it is
 	 * voltage, current, temperature, etc. */
 	int64_t physical;
 };

 /*
  * Issue a blocking adc conversion request. Once the call returns, the data
  * can be found in the 'physical' field of adc_chan_result. This call will
  * return ENODATA if there is an invalid result returned by the modem driver.
  */
 #define MSM_ADC_REQUEST			_IOWR(MSM_ADC_IOCTL_CODE, 1,	\
 					     struct adc_chan_result)

 /*
  * Issue a non-blocking adc conversion request. The results from this
  * request can be obtained by calling AIO_READ once the transfer is
  * completed. To verify completion, the blocking call AIO_POLL can be used.
  * If there are no slot resources, this call will return an error with errno
  * set to EWOULDBLOCK.
  */
 #define MSM_ADC_AIO_REQUEST		_IOWR(MSM_ADC_IOCTL_CODE, 2,	\
 					     struct adc_chan_result)

 /*
  * Same non-blocking semantics as AIO_REQUEST, except this call will block
  * if there are no available slot resources. This call can fail with errno
  * set to EDEADLK if there are no resources and the file descriptor in question
  * has outstanding conversion requests already. This is done so the client
  * does not block on resources that can only be freed by reading the results --
  * effectively deadlocking the system. In this case, the client must read
  * pending results before proceeding to free up resources.
  */
 #define MSM_ADC_AIO_REQUEST_BLOCK_RES	_IOWR(MSM_ADC_IOCTL_CODE, 3,	\
 					     struct adc_chan_result)

 /*
  * Returns the number of pending results that are associated with a particular
  * file descriptor. If there are no pending results, this call will block until
  * there is at least one. If there are no requests queued at all on this file
  * descriptor, this call will fail with EDEADLK. This is to prevent deadlock in
  * a single-threaded scenario where POLL would never return.
  */
 #define MSM_ADC_AIO_POLL		_IOR(MSM_ADC_IOCTL_CODE, 4,	\
 					     uint32_t)

 #define MSM_ADC_FLUID_INIT	_IOR(MSM_ADC_IOCTL_CODE, 5,	\
 					     uint32_t)

 #define MSM_ADC_FLUID_DEINIT	_IOR(MSM_ADC_IOCTL_CODE, 6,	\
 					     uint32_t)

 struct msm_adc_aio_result {
 	uint32_t chan;
 	int result;
 };

 /*
  * Read the results from an AIO / non-blocking conversion request. AIO_POLL
  * should be used before using this command to verify how many pending requests
  * are available for the file descriptor. This call will fail with errno set to
  * ENOMSG if there are no pending messages to be read at the time of the call.
  * The call will return ENODATA if there is an invalid result returned by the
  * modem driver.
  */
 #define MSM_ADC_AIO_READ		_IOR(MSM_ADC_IOCTL_CODE, 5,	\
 					     struct adc_chan_result)

 struct msm_adc_lookup {
 	/* channel name (input) */
 	char name[MSM_ADC_MAX_CHAN_STR];
 	/* local channel index (output) */
 	uint32_t chan_idx;
 };

 /*
  * Look up a channel name and get back an index that can be used
  * as a parameter to the conversion request commands.
  */
 #define MSM_ADC_LOOKUP			_IOWR(MSM_ADC_IOCTL_CODE, 6,	\
 					     struct msm_adc_lookup)


 #ifdef __KERNEL__
 #define MSM_ADC_MAX_NUM_DEVS		3

 enum {
 	ADC_CONFIG_TYPE1,
 	ADC_CONFIG_TYPE2,
 	ADC_CONFIG_NONE = 0xffffffff
 };

 enum {
 	ADC_CALIB_CONFIG_TYPE1,
 	ADC_CALIB_CONFIG_TYPE2,
 	ADC_CALIB_CONFIG_TYPE3,
 	ADC_CALIB_CONFIG_TYPE4,
 	ADC_CALIB_CONFIG_TYPE5,
 	ADC_CALIB_CONFIG_TYPE6,
 	ADC_CALIB_CONFIG_TYPE7,
 	ADC_CALIB_CONFIG_NONE = 0xffffffff
 };

 enum {
 	/* CHAN_PATH_TYPEn is specific for each ADC driver
 	and can be used however way it wants*/
 	CHAN_PATH_TYPE1,
 	CHAN_PATH_TYPE2,
 	CHAN_PATH_TYPE3,
 	CHAN_PATH_TYPE4,
 	CHAN_PATH_TYPE5,
 	CHAN_PATH_TYPE6,
 	CHAN_PATH_TYPE7,
 	CHAN_PATH_TYPE8,
 	CHAN_PATH_TYPE9,
 	CHAN_PATH_TYPE10,
 	CHAN_PATH_TYPE11,
 	CHAN_PATH_TYPE12,
 	CHAN_PATH_TYPE13,
 	CHAN_PATH_TYPE14,
 	CHAN_PATH_TYPE15,
 	CHAN_PATH_TYPE16,
 	/* A given channel connects directly to the ADC */
 	CHAN_PATH_TYPE_NONE = 0xffffffff
 };

 #define CHANNEL_ADC_BATT_ID     0
 #define CHANNEL_ADC_BATT_THERM  1
 #define CHANNEL_ADC_BATT_AMON   2
 #define CHANNEL_ADC_VBATT       3
 #define CHANNEL_ADC_VCOIN       4
 #define CHANNEL_ADC_VCHG        5
 #define CHANNEL_ADC_CHG_MONITOR 6
 #define CHANNEL_ADC_VPH_PWR     7
 #define CHANNEL_ADC_USB_VBUS    8
 #define CHANNEL_ADC_DIE_TEMP    9
 #define CHANNEL_ADC_DIE_TEMP_4K 0xa
 #define CHANNEL_ADC_XOTHERM     0xb
 #define CHANNEL_ADC_XOTHERM_4K  0xc
 #define CHANNEL_ADC_HDSET       0xd
 #define CHANNEL_ADC_MSM_THERM	0xe
 #define CHANNEL_ADC_625_REF	0xf
 #define CHANNEL_ADC_1250_REF	0x10
 #define CHANNEL_ADC_325_REF	0x11
 #define CHANNEL_ADC_FSM_THERM	0x12
 #define CHANNEL_ADC_PA_THERM	0x13

 enum {
 	CALIB_STARTED,
 	CALIB_NOT_REQUIRED = 0xffffffff,
 };

 struct linear_graph {
 	int32_t offset;
 	int32_t dy; /* Slope numerator */
 	int32_t dx; /* Slope denominator */
 };

 struct adc_map_pt {
 	int32_t x;
 	int32_t y;
 };

 struct adc_properties {
 	uint32_t adc_reference; /* milli-voltage for this adc */
 	uint32_t bitresolution;
 	bool bipolar;
 	uint32_t conversiontime;
 };

 struct chan_properties {
 	uint32_t gain_numerator;
 	uint32_t gain_denominator;
 	struct linear_graph *adc_graph;
 /* this maybe the same as adc_properties.ConversionTime
    if channel does not change the adc properties */
 	uint32_t chan_conv_time;
 };

 struct msm_adc_channels {
 	char *name;
 	uint32_t channel_name;
 	uint32_t adc_dev_instance;
 	struct adc_access_fn *adc_access_fn;
 	uint32_t chan_path_type;
 	uint32_t adc_config_type;
 	uint32_t adc_calib_type;
 	int32_t (*chan_processor)(int32_t, const struct adc_properties *,
 		const struct chan_properties *, struct adc_chan_result *);

 };

 struct msm_adc_platform_data {
 	struct msm_adc_channels *channel;
 	uint32_t num_chan_supported;
 	uint32_t num_adc;
 	uint32_t chan_per_adc;
 	char **dev_names;
 	uint32_t target_hw;
 	uint32_t gpio_config;
 	u32 (*adc_gpio_enable) (int);
 	u32 (*adc_gpio_disable) (int);
 	u32 (*adc_fluid_enable) (void);
 	u32 (*adc_fluid_disable) (void);
 };

 enum hw_type {
 	MSM_7x30,
 	MSM_8x60,
 	FSM_9xxx,
 	MSM_8x25,
 };

 enum epm_gpio_config {
 	MPROC_CONFIG,
 	APROC_CONFIG
 };

 enum adc_request {
 	START_OF_CONV,
 	END_OF_CONV,
 	START_OF_CALIBRATION,
 	END_OF_CALIBRATION,
 };

 struct adc_dev_spec {
 	uint32_t			hwmon_dev_idx;
 	struct dal_dev_spec {
 		uint32_t		dev_idx;
 		uint32_t		chan_idx;
 	} dal;
 };

 struct dal_conv_request {
 	struct dal_dev_spec		target;
 	void				*cb_h;
 };

 struct dal_adc_result {
 	uint32_t			status;
 	uint32_t			token;
 	uint32_t			dev_idx;
 	uint32_t			chan_idx;
 	int				physical;
 	uint32_t			percent;
 	uint32_t			microvolts;
 	uint32_t			reserved;
 };

 struct dal_conv_slot {
 	void				*cb_h;
 	struct dal_adc_result		result;
 	struct completion		comp;
 	struct list_head		list;
 	uint32_t			idx;
 	uint32_t			chan_idx;
 	bool				blocking;
 	struct msm_client_data		*client;
 };

 struct dal_translation {
 	uint32_t			dal_dev_idx;
 	uint32_t			hwmon_dev_idx;
 	uint32_t			hwmon_start;
 	uint32_t			hwmon_end;
 };

 struct msm_client_data {
 	struct list_head		complete_list;
 	bool				online;
 	int32_t				adc_chan;
 	uint32_t			num_complete;
 	uint32_t			num_outstanding;
 	wait_queue_head_t		data_wait;
 	wait_queue_head_t		outst_wait;
 	struct mutex lock;
 };

 struct adc_conv_slot {
 	void				*cb_h;
 	union {
 		struct adc_chan_result		result;
 		struct dal_adc_result		dal_result;
 	} conv;
 	struct completion		comp;
 	struct completion		*compk;
 	struct list_head		list;
 	uint32_t			idx;
 	enum adc_request		adc_request;
 	bool				blocking;
 	struct msm_client_data		*client;
 	struct work_struct		work;
 	struct chan_properties		chan_properties;
 	uint32_t			chan_path;
 	uint32_t			chan_adc_config;
 	uint32_t			chan_adc_calib;
 };

 struct adc_access_fn {
 	int32_t (*adc_select_chan_and_start_conv)(uint32_t,
 				struct adc_conv_slot*);
 	int32_t (*adc_read_adc_code)(uint32_t dev_instance, int32_t *data);
 	struct adc_properties *(*adc_get_properties)(uint32_t dev_instance);
 	void (*adc_slot_request)(uint32_t dev_instance,
 				struct adc_conv_slot **);
 	void (*adc_restore_slot)(uint32_t dev_instance,
 				struct adc_conv_slot *slot);
 	int32_t (*adc_calibrate)(uint32_t dev_instance, struct adc_conv_slot*,
 		int *);
 };

 void msm_adc_wq_work(struct work_struct *work);
 void msm_adc_conv_cb(void *context, u32 param, void *evt_buf, u32 len);
 #ifdef CONFIG_SENSORS_MSM_ADC
 int32_t adc_channel_open(uint32_t channel, void **h);
 int32_t adc_channel_close(void *h);
 int32_t adc_channel_request_conv(void *h, struct completion *conv_complete_evt);
 int32_t adc_channel_read_result(void *h, struct adc_chan_result *chan_result);
 #else
 static inline int32_t adc_channel_open(uint32_t channel, void **h)
 {
 	pr_err("%s.not supported.\n", __func__);
 	return -ENODEV;
 }
 static inline int32_t adc_channel_close(void *h)
 {
 	pr_err("%s.not supported.\n", __func__);
 	return -ENODEV;
 }
 static inline int32_t
 adc_channel_request_conv(void *h, struct completion *conv_complete_evt)
 {
 	pr_err("%s.not supported.\n", __func__);
 	return -ENODEV;
 }
 static inline int32_t
 adc_channel_read_result(void *h, struct adc_chan_result *chan_result)
 {
 	pr_err("%s.not supported.\n", __func__);
 	return -ENODEV;
 }
 #endif /* CONFIG_SENSORS_MSM_ADC */
 #endif
 #endif /* __MSM_ADC_H */
	#ifndef __MSM_ADC_H
	#define __MSM_ADC_H

	#include <linux/sched.h>

	#define MSM_ADC_MAX_CHAN_STR 64

	/* must be <= to the max buffer size in the modem implementation */
	#define MSM_ADC_DEV_MAX_INFLIGHT 9

	#define MSM_ADC_IOCTL_CODE 0x90

	struct msm_adc_conversion {
	/* hwmon channel number - this is not equivalent to the DAL chan */
	uint32_t chan;
	/* returned result in ms */
	int result;
	};

	struct adc_chan_result {
	/* The channel number of the requesting/requested conversion */
	uint32_t chan;
	/* The pre-calibrated digital output of a given ADC relative to the
	ADC reference */
	int32_t adc_code;
	/* in units specific for a given ADC; most ADC uses reference voltage
	* but some ADC uses reference current. This measurement here is
	* a number relative to a reference of a given ADC */
	int64_t measurement;
	/* The data meaningful for each individual channel whether it is
	* voltage, current, temperature, etc. */
	int64_t physical;
	};

	/*
	* Issue a blocking adc conversion request. Once the call returns, the data
	* can be found in the 'physical' field of adc_chan_result. This call will
	* return ENODATA if there is an invalid result returned by the modem driver.
	*/
	#define MSM_ADC_REQUEST _IOWR(MSM_ADC_IOCTL_CODE, 1, \
	struct adc_chan_result)

	/*
	* Issue a non-blocking adc conversion request. The results from this
	* request can be obtained by calling AIO_READ once the transfer is
	* completed. To verify completion, the blocking call AIO_POLL can be used.
	* If there are no slot resources, this call will return an error with errno
	* set to EWOULDBLOCK.
	*/
	#define MSM_ADC_AIO_REQUEST _IOWR(MSM_ADC_IOCTL_CODE, 2, \
	struct adc_chan_result)

	/*
	* Same non-blocking semantics as AIO_REQUEST, except this call will block
	* if there are no available slot resources. This call can fail with errno
	* set to EDEADLK if there are no resources and the file descriptor in question
	* has outstanding conversion requests already. This is done so the client
	* does not block on resources that can only be freed by reading the results --
	* effectively deadlocking the system. In this case, the client must read
	* pending results before proceeding to free up resources.
	*/
	#define MSM_ADC_AIO_REQUEST_BLOCK_RES _IOWR(MSM_ADC_IOCTL_CODE, 3, \
	struct adc_chan_result)

	/*
	* Returns the number of pending results that are associated with a particular
	* file descriptor. If there are no pending results, this call will block until
	* there is at least one. If there are no requests queued at all on this file
	* descriptor, this call will fail with EDEADLK. This is to prevent deadlock in
	* a single-threaded scenario where POLL would never return.
	*/
	#define MSM_ADC_AIO_POLL _IOR(MSM_ADC_IOCTL_CODE, 4, \
	uint32_t)

	#define MSM_ADC_FLUID_INIT _IOR(MSM_ADC_IOCTL_CODE, 5, \
	uint32_t)

	#define MSM_ADC_FLUID_DEINIT _IOR(MSM_ADC_IOCTL_CODE, 6, \
	uint32_t)

	struct msm_adc_aio_result {
	uint32_t chan;
	int result;
	};

	/*
	* Read the results from an AIO / non-blocking conversion request. AIO_POLL
	* should be used before using this command to verify how many pending requests
	* are available for the file descriptor. This call will fail with errno set to
	* ENOMSG if there are no pending messages to be read at the time of the call.
	* The call will return ENODATA if there is an invalid result returned by the
	* modem driver.
	*/
	#define MSM_ADC_AIO_READ _IOR(MSM_ADC_IOCTL_CODE, 5, \
	struct adc_chan_result)

	struct msm_adc_lookup {
	/* channel name (input) */
	char name[MSM_ADC_MAX_CHAN_STR];
	/* local channel index (output) */
	uint32_t chan_idx;
	};

	/*
	* Look up a channel name and get back an index that can be used
	* as a parameter to the conversion request commands.
	*/
	#define MSM_ADC_LOOKUP _IOWR(MSM_ADC_IOCTL_CODE, 6, \
	struct msm_adc_lookup)


	#ifdef __KERNEL__
	#define MSM_ADC_MAX_NUM_DEVS 3

	enum {
	ADC_CONFIG_TYPE1,
	ADC_CONFIG_TYPE2,
	ADC_CONFIG_NONE = 0xffffffff
	};

	enum {
	ADC_CALIB_CONFIG_TYPE1,
	ADC_CALIB_CONFIG_TYPE2,
	ADC_CALIB_CONFIG_TYPE3,
	ADC_CALIB_CONFIG_TYPE4,
	ADC_CALIB_CONFIG_TYPE5,
	ADC_CALIB_CONFIG_TYPE6,
	ADC_CALIB_CONFIG_TYPE7,
	ADC_CALIB_CONFIG_NONE = 0xffffffff
	};

	enum {
	/* CHAN_PATH_TYPEn is specific for each ADC driver
	and can be used however way it wants*/
	CHAN_PATH_TYPE1,
	CHAN_PATH_TYPE2,
	CHAN_PATH_TYPE3,
	CHAN_PATH_TYPE4,
	CHAN_PATH_TYPE5,
	CHAN_PATH_TYPE6,
	CHAN_PATH_TYPE7,
	CHAN_PATH_TYPE8,
	CHAN_PATH_TYPE9,
	CHAN_PATH_TYPE10,
	CHAN_PATH_TYPE11,
	CHAN_PATH_TYPE12,
	CHAN_PATH_TYPE13,
	CHAN_PATH_TYPE14,
	CHAN_PATH_TYPE15,
	CHAN_PATH_TYPE16,
	/* A given channel connects directly to the ADC */
	CHAN_PATH_TYPE_NONE = 0xffffffff
	};

	#define CHANNEL_ADC_BATT_ID 0
	#define CHANNEL_ADC_BATT_THERM 1
	#define CHANNEL_ADC_BATT_AMON 2
	#define CHANNEL_ADC_VBATT 3
	#define CHANNEL_ADC_VCOIN 4
	#define CHANNEL_ADC_VCHG 5
	#define CHANNEL_ADC_CHG_MONITOR 6
	#define CHANNEL_ADC_VPH_PWR 7
	#define CHANNEL_ADC_USB_VBUS 8
	#define CHANNEL_ADC_DIE_TEMP 9
	#define CHANNEL_ADC_DIE_TEMP_4K 0xa
	#define CHANNEL_ADC_XOTHERM 0xb
	#define CHANNEL_ADC_XOTHERM_4K 0xc
	#define CHANNEL_ADC_HDSET 0xd
	#define CHANNEL_ADC_MSM_THERM 0xe
	#define CHANNEL_ADC_625_REF 0xf
	#define CHANNEL_ADC_1250_REF 0x10
	#define CHANNEL_ADC_325_REF 0x11
	#define CHANNEL_ADC_FSM_THERM 0x12
	#define CHANNEL_ADC_PA_THERM 0x13

	enum {
	CALIB_STARTED,
	CALIB_NOT_REQUIRED = 0xffffffff,
	};

	struct linear_graph {
	int32_t offset;
	int32_t dy; /* Slope numerator */
	int32_t dx; /* Slope denominator */
	};

	struct adc_map_pt {
	int32_t x;
	int32_t y;
	};

	struct adc_properties {
	uint32_t adc_reference; /* milli-voltage for this adc */
	uint32_t bitresolution;
	bool bipolar;
	uint32_t conversiontime;
	};

	struct chan_properties {
	uint32_t gain_numerator;
	uint32_t gain_denominator;
	struct linear_graph *adc_graph;
	/* this maybe the same as adc_properties.ConversionTime
	if channel does not change the adc properties */
	uint32_t chan_conv_time;
	};

	struct msm_adc_channels {
	char *name;
	uint32_t channel_name;
	uint32_t adc_dev_instance;
	struct adc_access_fn *adc_access_fn;
	uint32_t chan_path_type;
	uint32_t adc_config_type;
	uint32_t adc_calib_type;
	int32_t (chan_processor)(int32_t, const struct adc_properties ,
	const struct chan_properties , struct adc_chan_result );

	};

	struct msm_adc_platform_data {
	struct msm_adc_channels *channel;
	uint32_t num_chan_supported;
	uint32_t num_adc;
	uint32_t chan_per_adc;
	char **dev_names;
	uint32_t target_hw;
	uint32_t gpio_config;
	u32 (*adc_gpio_enable) (int);
	u32 (*adc_gpio_disable) (int);
	u32 (*adc_fluid_enable) (void);
	u32 (*adc_fluid_disable) (void);
	};

	enum hw_type {
	MSM_7x30,
	MSM_8x60,
	FSM_9xxx,
	MSM_8x25,
	};

	enum epm_gpio_config {
	MPROC_CONFIG,
	APROC_CONFIG
	};

	enum adc_request {
	START_OF_CONV,
	END_OF_CONV,
	START_OF_CALIBRATION,
	END_OF_CALIBRATION,
	};

	struct adc_dev_spec {
	uint32_t hwmon_dev_idx;
	struct dal_dev_spec {
	uint32_t dev_idx;
	uint32_t chan_idx;
	} dal;
	};

	struct dal_conv_request {
	struct dal_dev_spec target;
	void *cb_h;
	};

	struct dal_adc_result {
	uint32_t status;
	uint32_t token;
	uint32_t dev_idx;
	uint32_t chan_idx;
	int physical;
	uint32_t percent;
	uint32_t microvolts;
	uint32_t reserved;
	};

	struct dal_conv_slot {
	void *cb_h;
	struct dal_adc_result result;
	struct completion comp;
	struct list_head list;
	uint32_t idx;
	uint32_t chan_idx;
	bool blocking;
	struct msm_client_data *client;
	};

	struct dal_translation {
	uint32_t dal_dev_idx;
	uint32_t hwmon_dev_idx;
	uint32_t hwmon_start;
	uint32_t hwmon_end;
	};

	struct msm_client_data {
	struct list_head complete_list;
	bool online;
	int32_t adc_chan;
	uint32_t num_complete;
	uint32_t num_outstanding;
	wait_queue_head_t data_wait;
	wait_queue_head_t outst_wait;
	struct mutex lock;
	};

	struct adc_conv_slot {
	void *cb_h;
	union {
	struct adc_chan_result result;
	struct dal_adc_result dal_result;
	} conv;
	struct completion comp;
	struct completion *compk;
	struct list_head list;
	uint32_t idx;
	enum adc_request adc_request;
	bool blocking;
	struct msm_client_data *client;
	struct work_struct work;
	struct chan_properties chan_properties;
	uint32_t chan_path;
	uint32_t chan_adc_config;
	uint32_t chan_adc_calib;
	};

	struct adc_access_fn {
	int32_t (*adc_select_chan_and_start_conv)(uint32_t,
	struct adc_conv_slot*);
	int32_t (adc_read_adc_code)(uint32_t dev_instance, int32_t data);
	struct adc_properties (adc_get_properties)(uint32_t dev_instance);
	void (*adc_slot_request)(uint32_t dev_instance,
	struct adc_conv_slot **);
	void (*adc_restore_slot)(uint32_t dev_instance,
	struct adc_conv_slot *slot);
	int32_t (adc_calibrate)(uint32_t dev_instance, struct adc_conv_slot,
	int *);
	};

	void msm_adc_wq_work(struct work_struct *work);
	void msm_adc_conv_cb(void context, u32 param, void evt_buf, u32 len);
	#ifdef CONFIG_SENSORS_MSM_ADC
	int32_t adc_channel_open(uint32_t channel, void **h);
	int32_t adc_channel_close(void *h);
	int32_t adc_channel_request_conv(void h, struct completion conv_complete_evt);
	int32_t adc_channel_read_result(void h, struct adc_chan_result chan_result);
	#else
	static inline int32_t adc_channel_open(uint32_t channel, void **h)
	{
	pr_err("%s.not supported.\n", __func__);
	return -ENODEV;
	}
	static inline int32_t adc_channel_close(void *h)
	{
	pr_err("%s.not supported.\n", __func__);
	return -ENODEV;
	}
	static inline int32_t
	adc_channel_request_conv(void h, struct completion conv_complete_evt)
	{
	pr_err("%s.not supported.\n", __func__);
	return -ENODEV;
	}
	static inline int32_t
	adc_channel_read_result(void h, struct adc_chan_result chan_result)
	{
	pr_err("%s.not supported.\n", __func__);
	return -ENODEV;
	}
	#endif /* CONFIG_SENSORS_MSM_ADC */
	#endif
	#endif /* __MSM_ADC_H */