[J-u-boot.git] / include / adc.h

/* SPDX-License-Identifier: GPL-2.0+ */
/*
 * Copyright (C) 2015 Samsung Electronics
 * Przemyslaw Marczak <[email protected]>
 */

#ifndef _ADC_H_
#define _ADC_H_

#include <stdbool.h>

/* ADC_CHANNEL() - ADC channel bit mask, to select only required channels */
#define ADC_CHANNEL(x)		(1 << x)

/* The last possible selected channel with 32-bit mask */
#define ADC_MAX_CHANNEL		31

/**
 * adc_data_format: define the ADC output data format, can be useful when
 * the device's input Voltage range is bipolar.
 * - ADC_DATA_FORMAT_BIN - binary offset
 * - ADC_DATA_FORMAT_2S  - two's complement
 *
 * Note: Device's driver should fill the 'data_format' field of its uclass's
 * platform data using one of the above data format types.
 */
enum adc_data_format {
	ADC_DATA_FORMAT_BIN,
	ADC_DATA_FORMAT_2S,
};

/**
 * struct adc_channel - structure to hold channel conversion data.
 * Useful to keep the result of a multi-channel conversion output.
 *
 * @id   - channel id
 * @data - channel conversion data
 */
struct adc_channel {
	int id;
	unsigned int data;
};

/**
 * struct adc_uclass_plat - basic ADC info
 *
 * Note: The positive/negative reference Voltage is only a name and it doesn't
 * provide an information about the value polarity. It is possible, for both
 * values to be a negative or positive. For this purpose the uclass's platform
 * data provides a bool fields: 'vdd/vss_supply_is_negative'. This is useful,
 * since the regulator API returns only a positive Voltage values.
 *
 * To get the reference Voltage values with polarity, use functions:
 * - adc_vdd_value()
 * - adc_vss_value()
 * Those are useful for some cases of ADC's references, e.g.:
 * * Vdd: +3.3V; Vss: -3.3V -> 6.6 Vdiff
 * * Vdd: +3.3V; Vss: +0.3V -> 3.0 Vdiff
 * * Vdd: +3.3V; Vss:  0.0V -> 3.3 Vdiff
 * The last one is usually standard and doesn't require the fdt polarity info.
 *
 * For more informations read binding info:
 * - doc/device-tree-bindings/adc/adc.txt
 *
 * @data_mask              - conversion output data mask
 * @data_timeout_us        - single channel conversion timeout
 * @multidata_timeout_us   - multi channel conversion timeout
 * @channel_mask           - bit mask of available channels [0:31]
 * @vdd_supply             - positive reference Voltage supply (regulator)
 * @vss_supply             - negative reference Voltage supply (regulator)
 * @vdd_polarity_negative  - positive reference Voltage has negative polarity
 * @vss_polarity_negative  - negative reference Voltage has negative polarity
 * @vdd_microvolts         - positive reference Voltage value
 * @vss_microvolts         - negative reference Voltage value
 */
struct adc_uclass_plat {
	int data_format;
	unsigned int data_mask;
	unsigned int data_timeout_us;
	unsigned int multidata_timeout_us;
	unsigned int channel_mask;
	struct udevice *vdd_supply;
	struct udevice *vss_supply;
	bool vdd_polarity_negative;
	bool vss_polarity_negative;
	int vdd_microvolts;
	int vss_microvolts;
};

/**
 * struct adc_ops - ADC device operations for single/multi-channel operation.
 */
struct adc_ops {
	/**
	 * start_channel() - start conversion with its default parameters
	 *                   for the given channel number.
	 *
	 * @dev:          ADC device to init
	 * @channel:      analog channel number
	 * @return:       0 if OK, -ve on error
	 */
	int (*start_channel)(struct udevice *dev, int channel);

	/**
	 * start_channels() - start conversion with its default parameters
	 *                    for the channel numbers selected by the bit mask.
	 *
	 * This is optional, useful when the hardware supports multichannel
	 * conversion by the single software trigger.
	 *
	 * @dev:          ADC device to init
	 * @channel_mask: bit mask of selected analog channels
	 * @return:       0 if OK, -ve on error
	 */
	int (*start_channels)(struct udevice *dev, unsigned int channel_mask);

	/**
	 * channel_data() - get conversion output data for the given channel.
	 *
	 * Note: The implementation of this function should only check, that
	 * the conversion data is available at the call time. If the hardware
	 * requires some delay to get the data, then this function should
	 * return with -EBUSY value. The ADC API will call it in a loop,
	 * until the data is available or the timeout expires. The maximum
	 * timeout for this operation is defined by the field 'data_timeout_us'
	 * in ADC uclasses platform data structure.
	 *
	 * @dev:          ADC device to trigger
	 * @channel:      selected analog channel number
	 * @data:         returned pointer to selected channel's output data
	 * @return:       0 if OK, -EBUSY if busy, and other negative on error
	 */
	int (*channel_data)(struct udevice *dev, int channel,
			    unsigned int *data);

	/**
	 * channels_data() - get conversion data for the selected channels.
	 *
	 * This is optional, useful when multichannel conversion is supported
	 * by the hardware, by the single software trigger.
	 *
	 * For the proper implementation, please look at the 'Note' for the
	 * above method. The only difference is in used timeout value, which
	 * is defined by field 'multidata_timeout_us'.
	 *
	 * @dev:          ADC device to trigger
	 * @channel_mask: bit mask of selected analog channels
	 * @channels:     returned pointer to array of output data for channels
	 *                selected by the given mask
	 * @return:       0 if OK, -ve on error
	 */
	int (*channels_data)(struct udevice *dev, unsigned int channel_mask,
			     struct adc_channel *channels);

	/**
	 * stop() - stop conversion of the given ADC device
	 *
	 * @dev:          ADC device to stop
	 * @return:       0 if OK, -ve on error
	 */
	int (*stop)(struct udevice *dev);
};

/**
 * adc_start_channel() - start conversion for given device/channel and exit.
 *
 * @dev:     ADC device
 * @channel: analog channel number
 * @return:  0 if OK, -ve on error
 */
int adc_start_channel(struct udevice *dev, int channel);

/**
 * adc_start_channels() - start conversion for given device/channels and exit.
 *
 * Note:
 * To use this function, device must implement method: start_channels().
 *
 * @dev:          ADC device to start
 * @channel_mask: channel selection - a bit mask
 * @channel_mask: bit mask of analog channels
 * @return:       0 if OK, -ve on error
 */
int adc_start_channels(struct udevice *dev, unsigned int channel_mask);

/**
 * adc_channel_data() - get conversion data for the given device channel number.
 *
 * @dev:     ADC device to read
 * @channel: analog channel number
 * @data:    pointer to returned channel's data
 * @return:  0 if OK, -ve on error
 */
int adc_channel_data(struct udevice *dev, int channel, unsigned int *data);

/**
 * adc_channels_data() - get conversion data for the channels selected by mask
 *
 * Note:
 * To use this function, device must implement methods:
 * - start_channels()
 * - channels_data()
 *
 * @dev:          ADC device to read
 * @channel_mask: channel selection - a bit mask
 * @channels:     pointer to structure array of returned data for each channel
 * @return:       0 if OK, -ve on error
 */
int adc_channels_data(struct udevice *dev, unsigned int channel_mask,
		      struct adc_channel *channels);

/**
 * adc_data_mask() - get data mask (ADC resolution bitmask) for given ADC device
 *
 * This can be used if adc uclass platform data is filled.
 *
 * @dev:       ADC device to check
 * @data_mask: pointer to the returned data bitmask
 * @return: 0 if OK, -ve on error
 */
int adc_data_mask(struct udevice *dev, unsigned int *data_mask);

/**
 * adc_channel_mask() - get channel mask for given ADC device
 *
 * This can be used if adc uclass platform data is filled.
 *
 * @dev:       ADC device to check
 * @channel_mask: pointer to the returned channel bitmask
 * @return: 0 if OK, -ve on error
 */
int adc_channel_mask(struct udevice *dev, unsigned int *channel_mask);

/**
 * adc_channel_single_shot() - get output data of conversion for the ADC
 * device's channel. This function searches for the device with the given name,
 * starts the given channel conversion and returns the output data.
 *
 * Note: To use this function, device must implement metods:
 * - start_channel()
 * - channel_data()
 *
 * @name:    device's name to search
 * @channel: device's input channel to init
 * @data:    pointer to conversion output data
 * @return:  0 if OK, -ve on error
 */
int adc_channel_single_shot(const char *name, int channel, unsigned int *data);

/**
 * adc_channels_single_shot() - get ADC conversion output data for the selected
 * device's channels. This function searches for the device by the given name,
 * starts the selected channels conversion and returns the output data as array
 * of type 'struct adc_channel'.
 *
 * Note: This function can be used if device implements one of ADC's single
 * or multi-channel operation API. If multi-channel operation is not supported,
 * then each selected channel is triggered by the sequence start/data in a loop.
 *
 * @name:         device's name to search
 * @channel_mask: channel selection - a bit mask
 * @channels:     pointer to conversion output data for the selected channels
 * @return:       0 if OK, -ve on error
 */
int adc_channels_single_shot(const char *name, unsigned int channel_mask,
			     struct adc_channel *channels);

/**
 * adc_vdd_value() - get the ADC device's positive reference Voltage value
 *
 * Note: Depending on bool value 'vdd_supply_is_negative' of platform data,
 * the returned uV value can be negative, and it's not an error.
 *
 * @dev:     ADC device to check
 * @uV:      Voltage value with polarization sign (uV)
 * @return:  0 on success or -ve on error
*/
int adc_vdd_value(struct udevice *dev, int *uV);

/**
 * adc_vss_value() - get the ADC device's negative reference Voltage value
 *
 * Note: Depending on bool value 'vdd_supply_is_negative' of platform data,
 * the returned uV value can be negative, and it's not an error.
 *
 * @dev:     ADC device to check
 * @uV:      Voltage value with polarization sign (uV)
 * @return:  0 on success or -ve on error
*/
int adc_vss_value(struct udevice *dev, int *uV);

/**
 * adc_stop() - stop operation for given ADC device.
 *
 * @dev:     ADC device to stop
 * @return:  0 if OK, -ve on error
 */
int adc_stop(struct udevice *dev);

/**
 * adc_raw_to_uV() - converts raw value to microvolts for given ADC device.
 *
 * @dev:     ADC device used from conversion
 * @raw:     raw value to convert
 * @uV:	     converted value in microvolts
 * @return:  0 on success or -ve on error
 */
int adc_raw_to_uV(struct udevice *dev, unsigned int raw, int *uV);

#endif
Commit	Line	Data
83d290c5	1	/* SPDX-License-Identifier: GPL-2.0+ */
5decbf53 PM	2	/*
	3	* Copyright (C) 2015 Samsung Electronics
	4	* Przemyslaw Marczak <[email protected]>
5decbf53 PM	5	*/
	6
	7	#ifndef _ADC_H_
	8	#define _ADC_H_
	9
03de305e TR	10	#include <stdbool.h>
03de305e TR	11
5decbf53 PM	12	/* ADC_CHANNEL() - ADC channel bit mask, to select only required channels */
	13	#define ADC_CHANNEL(x) (1 << x)
	14
	15	/* The last possible selected channel with 32-bit mask */
	16	#define ADC_MAX_CHANNEL 31
	17
	18	/**
	19	* adc_data_format: define the ADC output data format, can be useful when
	20	* the device's input Voltage range is bipolar.
	21	* - ADC_DATA_FORMAT_BIN - binary offset
	22	* - ADC_DATA_FORMAT_2S - two's complement
	23	*
	24	* Note: Device's driver should fill the 'data_format' field of its uclass's
	25	* platform data using one of the above data format types.
	26	*/
	27	enum adc_data_format {
	28	ADC_DATA_FORMAT_BIN,
	29	ADC_DATA_FORMAT_2S,
	30	};
	31
	32	/**
	33	* struct adc_channel - structure to hold channel conversion data.
	34	* Useful to keep the result of a multi-channel conversion output.
	35	*
	36	* @id - channel id
	37	* @data - channel conversion data
	38	*/
	39	struct adc_channel {
	40	int id;
	41	unsigned int data;
	42	};
	43
	44	/**
caa4daa2	45	* struct adc_uclass_plat - basic ADC info
5decbf53 PM	46	*
	47	* Note: The positive/negative reference Voltage is only a name and it doesn't
	48	* provide an information about the value polarity. It is possible, for both
	49	* values to be a negative or positive. For this purpose the uclass's platform
	50	* data provides a bool fields: 'vdd/vss_supply_is_negative'. This is useful,
	51	* since the regulator API returns only a positive Voltage values.
	52	*
	53	* To get the reference Voltage values with polarity, use functions:
	54	* - adc_vdd_value()
	55	* - adc_vss_value()
	56	* Those are useful for some cases of ADC's references, e.g.:
	57	* * Vdd: +3.3V; Vss: -3.3V -> 6.6 Vdiff
	58	* * Vdd: +3.3V; Vss: +0.3V -> 3.0 Vdiff
	59	* * Vdd: +3.3V; Vss: 0.0V -> 3.3 Vdiff
	60	* The last one is usually standard and doesn't require the fdt polarity info.
	61	*
	62	* For more informations read binding info:
	63	* - doc/device-tree-bindings/adc/adc.txt
	64	*
	65	* @data_mask - conversion output data mask
	66	* @data_timeout_us - single channel conversion timeout
	67	* @multidata_timeout_us - multi channel conversion timeout
	68	* @channel_mask - bit mask of available channels [0:31]
	69	* @vdd_supply - positive reference Voltage supply (regulator)
	70	* @vss_supply - negative reference Voltage supply (regulator)
	71	* @vdd_polarity_negative - positive reference Voltage has negative polarity
	72	* @vss_polarity_negative - negative reference Voltage has negative polarity
	73	* @vdd_microvolts - positive reference Voltage value
	74	* @vss_microvolts - negative reference Voltage value
	75	*/
caa4daa2	76	struct adc_uclass_plat {
5decbf53 PM	77	int data_format;
	78	unsigned int data_mask;
	79	unsigned int data_timeout_us;
	80	unsigned int multidata_timeout_us;
	81	unsigned int channel_mask;
	82	struct udevice *vdd_supply;
	83	struct udevice *vss_supply;
	84	bool vdd_polarity_negative;
	85	bool vss_polarity_negative;
	86	int vdd_microvolts;
	87	int vss_microvolts;
	88	};
	89
	90	/**
	91	* struct adc_ops - ADC device operations for single/multi-channel operation.
	92	*/
	93	struct adc_ops {
	94	/**
	95	* start_channel() - start conversion with its default parameters
	96	* for the given channel number.
	97	*
	98	* @dev: ADC device to init
	99	* @channel: analog channel number
	100	* @return: 0 if OK, -ve on error
	101	*/
	102	int (start_channel)(struct udevice dev, int channel);
	103
	104	/**
	105	* start_channels() - start conversion with its default parameters
	106	* for the channel numbers selected by the bit mask.
	107	*
	108	* This is optional, useful when the hardware supports multichannel
	109	* conversion by the single software trigger.
	110	*
	111	* @dev: ADC device to init
	112	* @channel_mask: bit mask of selected analog channels
	113	* @return: 0 if OK, -ve on error
	114	*/
	115	int (start_channels)(struct udevice dev, unsigned int channel_mask);
	116
	117	/**
	118	* channel_data() - get conversion output data for the given channel.
	119	*
	120	* Note: The implementation of this function should only check, that
	121	* the conversion data is available at the call time. If the hardware
	122	* requires some delay to get the data, then this function should
	123	* return with -EBUSY value. The ADC API will call it in a loop,
	124	* until the data is available or the timeout expires. The maximum
	125	* timeout for this operation is defined by the field 'data_timeout_us'
	126	* in ADC uclasses platform data structure.
	127	*
	128	* @dev: ADC device to trigger
	129	* @channel: selected analog channel number
	130	* @data: returned pointer to selected channel's output data
	131	* @return: 0 if OK, -EBUSY if busy, and other negative on error
	132	*/
	133	int (channel_data)(struct udevice dev, int channel,
	134	unsigned int *data);
	135
	136	/**
	137	* channels_data() - get conversion data for the selected channels.
	138	*
	139	* This is optional, useful when multichannel conversion is supported
	140	* by the hardware, by the single software trigger.
141	*
142	* For the proper implementation, please look at the 'Note' for the
143	* above method. The only difference is in used timeout value, which
144	* is defined by field 'multidata_timeout_us'.
145	*
146	* @dev: ADC device to trigger
147	* @channel_mask: bit mask of selected analog channels
148	* @channels: returned pointer to array of output data for channels
149	* selected by the given mask
150	* @return: 0 if OK, -ve on error
151	*/
152	int (channels_data)(struct udevice dev, unsigned int channel_mask,
153	struct adc_channel *channels);
154
155	/**
156	* stop() - stop conversion of the given ADC device
157	*
158	* @dev: ADC device to stop
159	* @return: 0 if OK, -ve on error
160	*/
161	int (stop)(struct udevice dev);
162	};
163
164	/**
165	* adc_start_channel() - start conversion for given device/channel and exit.
166	*
167	* @dev: ADC device
168	* @channel: analog channel number
169	* @return: 0 if OK, -ve on error
170	*/
171	int adc_start_channel(struct udevice *dev, int channel);
172
173	/**
174	* adc_start_channels() - start conversion for given device/channels and exit.
175	*
176	* Note:
177	* To use this function, device must implement method: start_channels().
178	*
179	* @dev: ADC device to start
180	* @channel_mask: channel selection - a bit mask
181	* @channel_mask: bit mask of analog channels
182	* @return: 0 if OK, -ve on error
183	*/
184	int adc_start_channels(struct udevice *dev, unsigned int channel_mask);
185
186	/**
187	* adc_channel_data() - get conversion data for the given device channel number.
188	*
189	* @dev: ADC device to read
190	* @channel: analog channel number
191	* @data: pointer to returned channel's data
192	* @return: 0 if OK, -ve on error
193	*/
194	int adc_channel_data(struct udevice dev, int channel, unsigned int data);
195
196	/**
197	* adc_channels_data() - get conversion data for the channels selected by mask
198	*
199	* Note:
200	* To use this function, device must implement methods:
201	* - start_channels()
202	* - channels_data()
203	*
204	* @dev: ADC device to read
205	* @channel_mask: channel selection - a bit mask
206	* @channels: pointer to structure array of returned data for each channel
207	* @return: 0 if OK, -ve on error
208	*/
209	int adc_channels_data(struct udevice *dev, unsigned int channel_mask,
210	struct adc_channel *channels);
211
212	/**
213	* adc_data_mask() - get data mask (ADC resolution bitmask) for given ADC device
214	*
215	* This can be used if adc uclass platform data is filled.
216	*
217	* @dev: ADC device to check
218	* @data_mask: pointer to the returned data bitmask
219	* @return: 0 if OK, -ve on error
220	*/
221	int adc_data_mask(struct udevice dev, unsigned int data_mask);
222
63f004e7 FG	223	/**
	224	* adc_channel_mask() - get channel mask for given ADC device
	225	*
	226	* This can be used if adc uclass platform data is filled.
	227	*
	228	* @dev: ADC device to check
	229	* @channel_mask: pointer to the returned channel bitmask
	230	* @return: 0 if OK, -ve on error
	231	*/
	232	int adc_channel_mask(struct udevice dev, unsigned int channel_mask);
	233
5decbf53 PM	234	/**
	235	* adc_channel_single_shot() - get output data of conversion for the ADC
	236	* device's channel. This function searches for the device with the given name,
	237	* starts the given channel conversion and returns the output data.
	238	*
	239	* Note: To use this function, device must implement metods:
	240	* - start_channel()
	241	* - channel_data()
	242	*
	243	* @name: device's name to search
	244	* @channel: device's input channel to init
	245	* @data: pointer to conversion output data
	246	* @return: 0 if OK, -ve on error
	247	*/
	248	int adc_channel_single_shot(const char name, int channel, unsigned int data);
	249
	250	/**
	251	* adc_channels_single_shot() - get ADC conversion output data for the selected
	252	* device's channels. This function searches for the device by the given name,
	253	* starts the selected channels conversion and returns the output data as array
	254	* of type 'struct adc_channel'.
	255	*
	256	* Note: This function can be used if device implements one of ADC's single
	257	* or multi-channel operation API. If multi-channel operation is not supported,
	258	* then each selected channel is triggered by the sequence start/data in a loop.
	259	*
	260	* @name: device's name to search
	261	* @channel_mask: channel selection - a bit mask
	262	* @channels: pointer to conversion output data for the selected channels
	263	* @return: 0 if OK, -ve on error
	264	*/
	265	int adc_channels_single_shot(const char *name, unsigned int channel_mask,
	266	struct adc_channel *channels);
	267
	268	/**
	269	* adc_vdd_value() - get the ADC device's positive reference Voltage value
	270	*
	271	* Note: Depending on bool value 'vdd_supply_is_negative' of platform data,
	272	* the returned uV value can be negative, and it's not an error.
	273	*
	274	* @dev: ADC device to check
	275	* @uV: Voltage value with polarization sign (uV)
	276	* @return: 0 on success or -ve on error
	277	*/
	278	int adc_vdd_value(struct udevice dev, int uV);
	279
	280	/**
	281	* adc_vss_value() - get the ADC device's negative reference Voltage value
	282	*
	283	* Note: Depending on bool value 'vdd_supply_is_negative' of platform data,
	284	* the returned uV value can be negative, and it's not an error.
	285	*
	286	* @dev: ADC device to check
	287	* @uV: Voltage value with polarization sign (uV)
	288	* @return: 0 on success or -ve on error
	289	*/
	290	int adc_vss_value(struct udevice dev, int uV);
	291
	292	/**
	293	* adc_stop() - stop operation for given ADC device.
	294	*
	295	* @dev: ADC device to stop
	296	* @return: 0 if OK, -ve on error
	297	*/
298	int adc_stop(struct udevice *dev);
299
63f004e7 FG	300	/**
	301	* adc_raw_to_uV() - converts raw value to microvolts for given ADC device.
	302	*
	303	* @dev: ADC device used from conversion
	304	* @raw: raw value to convert
	305	* @uV: converted value in microvolts
	306	* @return: 0 on success or -ve on error
	307	*/
	308	int adc_raw_to_uV(struct udevice dev, unsigned int raw, int uV);
	309
5decbf53	310	#endif