ad5064.c source code [linux/drivers/iio/dac/ad5064.c]

1	// SPDX-License-Identifier: GPL-2.0-only
2	/*
3	* AD5024, AD5025, AD5044, AD5045, AD5064, AD5064-1, AD5065, AD5625, AD5625R,
4	* AD5627, AD5627R, AD5628, AD5629R, AD5645R, AD5647R, AD5648, AD5665, AD5665R,
5	* AD5666, AD5667, AD5667R, AD5668, AD5669R, LTC2606, LTC2607, LTC2609, LTC2616,
6	* LTC2617, LTC2619, LTC2626, LTC2627, LTC2629, LTC2631, LTC2633, LTC2635
7	* Digital to analog converters driver
8	*
9	* Copyright 2011 Analog Devices Inc.
10	*/
11
12	#include <linux/device.h>
13	#include <linux/err.h>
14	#include <linux/module.h>
15	#include <linux/kernel.h>
16	#include <linux/spi/spi.h>
17	#include <linux/i2c.h>
18	#include <linux/slab.h>
19	#include <linux/sysfs.h>
20	#include <linux/regulator/consumer.h>
21	#include <asm/unaligned.h>
22
23	#include <linux/iio/iio.h>
24	#include <linux/iio/sysfs.h>
25
26	#define AD5064_MAX_DAC_CHANNELS 8
27	#define AD5064_MAX_VREFS 4
28
29	#define AD5064_ADDR(x) ((x) << 20)
30	#define AD5064_CMD(x) ((x) << 24)
31
32	#define AD5064_ADDR_ALL_DAC 0xF
33
34	#define AD5064_CMD_WRITE_INPUT_N 0x0
35	#define AD5064_CMD_UPDATE_DAC_N 0x1
36	#define AD5064_CMD_WRITE_INPUT_N_UPDATE_ALL 0x2
37	#define AD5064_CMD_WRITE_INPUT_N_UPDATE_N 0x3
38	#define AD5064_CMD_POWERDOWN_DAC 0x4
39	#define AD5064_CMD_CLEAR 0x5
40	#define AD5064_CMD_LDAC_MASK 0x6
41	#define AD5064_CMD_RESET 0x7
42	#define AD5064_CMD_CONFIG 0x8
43
44	#define AD5064_CMD_RESET_V2 0x5
45	#define AD5064_CMD_CONFIG_V2 0x7
46
47	#define AD5064_CONFIG_DAISY_CHAIN_ENABLE BIT(1)
48	#define AD5064_CONFIG_INT_VREF_ENABLE BIT(0)
49
50	#define AD5064_LDAC_PWRDN_NONE 0x0
51	#define AD5064_LDAC_PWRDN_1K 0x1
52	#define AD5064_LDAC_PWRDN_100K 0x2
53	#define AD5064_LDAC_PWRDN_3STATE 0x3
54
55	/**
56	* enum ad5064_regmap_type - Register layout variant
57	* @AD5064_REGMAP_ADI: Old Analog Devices register map layout
58	* @AD5064_REGMAP_ADI2: New Analog Devices register map layout
59	* @AD5064_REGMAP_LTC: LTC register map layout
60	*/
61	enum ad5064_regmap_type {
62	AD5064_REGMAP_ADI,
63	AD5064_REGMAP_ADI2,
64	AD5064_REGMAP_LTC,
65	};
66
67	/**
68	* struct ad5064_chip_info - chip specific information
69	* @shared_vref: whether the vref supply is shared between channels
70	* @internal_vref: internal reference voltage. 0 if the chip has no
71	* internal vref.
72	* @channels: channel specification
73	* @num_channels: number of channels
74	* @regmap_type: register map layout variant
75	*/
76
77	struct ad5064_chip_info {
78	bool shared_vref;
79	unsigned long internal_vref;
80	const struct iio_chan_spec *channels;
81	unsigned int num_channels;
82	enum ad5064_regmap_type regmap_type;
83	};
84
85	struct ad5064_state;
86
87	typedef int (ad5064_write_func)(struct* ad5064_state st, unsigned* int cmd,
88	unsigned int addr, unsigned int val);
89
90	/**
91	* struct ad5064_state - driver instance specific data
92	* @dev: the device for this driver instance
93	* @chip_info: chip model specific constants, available modes etc
94	* @vref_reg: vref supply regulators
95	* @pwr_down: whether channel is powered down
96	* @pwr_down_mode: channel's current power down mode
97	* @dac_cache: current DAC raw value (chip does not support readback)
98	* @use_internal_vref: set to true if the internal reference voltage should be
99	* used.
100	* @write: register write callback
101	* @lock: maintain consistency between cached and dev state
102	* @data: i2c/spi transfer buffers
103	*/
104
105	struct ad5064_state {
106	struct device *dev;
107	const struct ad5064_chip_info *chip_info;
108	struct regulator_bulk_data vref_reg[AD5064_MAX_VREFS];
109	bool pwr_down[AD5064_MAX_DAC_CHANNELS];
110	u8 pwr_down_mode[AD5064_MAX_DAC_CHANNELS];
111	unsigned int dac_cache[AD5064_MAX_DAC_CHANNELS];
112	bool use_internal_vref;
113
114	ad5064_write_func write;
115	struct mutex lock;
116
117	/*
118	* DMA (thus cache coherency maintenance) may require the
119	* transfer buffers to live in their own cache lines.
120	*/
121	union {
122	u8 i2c[`3`];
123	__be32 spi;
124	} data __aligned(IIO_DMA_MINALIGN);
125	};
126
127	enum ad5064_type {
128	ID_AD5024,
129	ID_AD5025,
130	ID_AD5044,
131	ID_AD5045,
132	ID_AD5064,
133	ID_AD5064_1,
134	ID_AD5065,
135	ID_AD5625,
136	ID_AD5625R_1V25,
137	ID_AD5625R_2V5,
138	ID_AD5627,
139	ID_AD5627R_1V25,
140	ID_AD5627R_2V5,
141	ID_AD5628_1,
142	ID_AD5628_2,
143	ID_AD5629_1,
144	ID_AD5629_2,
145	ID_AD5645R_1V25,
146	ID_AD5645R_2V5,
147	ID_AD5647R_1V25,
148	ID_AD5647R_2V5,
149	ID_AD5648_1,
150	ID_AD5648_2,
151	ID_AD5665,
152	ID_AD5665R_1V25,
153	ID_AD5665R_2V5,
154	ID_AD5666_1,
155	ID_AD5666_2,
156	ID_AD5667,
157	ID_AD5667R_1V25,
158	ID_AD5667R_2V5,
159	ID_AD5668_1,
160	ID_AD5668_2,
161	ID_AD5669_1,
162	ID_AD5669_2,
163	ID_LTC2606,
164	ID_LTC2607,
165	ID_LTC2609,
166	ID_LTC2616,
167	ID_LTC2617,
168	ID_LTC2619,
169	ID_LTC2626,
170	ID_LTC2627,
171	ID_LTC2629,
172	ID_LTC2631_L12,
173	ID_LTC2631_H12,
174	ID_LTC2631_L10,
175	ID_LTC2631_H10,
176	ID_LTC2631_L8,
177	ID_LTC2631_H8,
178	ID_LTC2633_L12,
179	ID_LTC2633_H12,
180	ID_LTC2633_L10,
181	ID_LTC2633_H10,
182	ID_LTC2633_L8,
183	ID_LTC2633_H8,
184	ID_LTC2635_L12,
185	ID_LTC2635_H12,
186	ID_LTC2635_L10,
187	ID_LTC2635_H10,
188	ID_LTC2635_L8,
189	ID_LTC2635_H8,
190	};
191
192	static int ad5064_write(struct ad5064_state st, unsigned* int cmd,
193	unsigned int addr, unsigned int val, unsigned int shift)
194	{
195	val <<= shift;
196
197	return st->write(st, cmd, addr, val);
198	}
199
200	static int ad5064_sync_powerdown_mode(struct ad5064_state *st,
201	const struct iio_chan_spec *chan)
202	{
203	unsigned int val, address;
204	unsigned int shift;
205	int ret;
206
207	if (st->chip_info->regmap_type == AD5064_REGMAP_LTC) {
208	val = `0`;
209	address = chan->address;
210	} else {
211	if (st->chip_info->regmap_type == AD5064_REGMAP_ADI2)
212	shift = `4`;
213	else
214	shift = `8`;
215
216	val = (`0x1` << chan->address);
217	address = `0`;
218
219	if (st->pwr_down[chan->channel])
220	val \|= st->pwr_down_mode[chan->channel] << shift;
221	}
222
223	ret = ad5064_write(st, AD5064_CMD_POWERDOWN_DAC, addr: address, val, shift: `0`);
224
225	return ret;
226	}
227
228	static const char * const ad5064_powerdown_modes[] = {
229	"1kohm_to_gnd",
230	"100kohm_to_gnd",
231	"three_state",
232	};
233
234	static const char * const ltc2617_powerdown_modes[] = {
235	"90kohm_to_gnd",
236	};
237
238	static int ad5064_get_powerdown_mode(struct iio_dev *indio_dev,
239	const struct iio_chan_spec *chan)
240	{
241	struct ad5064_state *st = iio_priv(indio_dev);
242
243	return st->pwr_down_mode[chan->channel] - `1`;
244	}
245
246	static int ad5064_set_powerdown_mode(struct iio_dev *indio_dev,
247	const struct iio_chan_spec chan, unsigned* int mode)
248	{
249	struct ad5064_state *st = iio_priv(indio_dev);
250	int ret;
251
252	mutex_lock(&st->lock);
253	st->pwr_down_mode[chan->channel] = mode + `1`;
254
255	ret = ad5064_sync_powerdown_mode(st, chan);
256	mutex_unlock(lock: &st->lock);
257
258	return ret;
259	}
260
261	static const struct iio_enum ad5064_powerdown_mode_enum = {
262	.items = ad5064_powerdown_modes,
263	.num_items = ARRAY_SIZE(ad5064_powerdown_modes),
264	.get = ad5064_get_powerdown_mode,
265	.set = ad5064_set_powerdown_mode,
266	};
267
268	static const struct iio_enum ltc2617_powerdown_mode_enum = {
269	.items = ltc2617_powerdown_modes,
270	.num_items = ARRAY_SIZE(ltc2617_powerdown_modes),
271	.get = ad5064_get_powerdown_mode,
272	.set = ad5064_set_powerdown_mode,
273	};
274
275	static ssize_t ad5064_read_dac_powerdown(struct iio_dev *indio_dev,
276	uintptr_t private, const struct iio_chan_spec chan, char* *buf)
277	{
278	struct ad5064_state *st = iio_priv(indio_dev);
279
280	return sysfs_emit(buf, fmt: "%d\n", st->pwr_down[chan->channel]);
281	}
282
283	static ssize_t ad5064_write_dac_powerdown(struct iio_dev *indio_dev,
284	uintptr_t private, const struct iio_chan_spec chan, const* char *buf,
285	size_t len)
286	{
287	struct ad5064_state *st = iio_priv(indio_dev);
288	bool pwr_down;
289	int ret;
290
291	ret = kstrtobool(s: buf, res: &pwr_down);
292	if (ret)
293	return ret;
294
295	mutex_lock(&st->lock);
296	st->pwr_down[chan->channel] = pwr_down;
297
298	ret = ad5064_sync_powerdown_mode(st, chan);
299	mutex_unlock(lock: &st->lock);
300	return ret ? ret : len;
301	}
302
303	static int ad5064_get_vref(struct ad5064_state *st,
304	struct iio_chan_spec const *chan)
305	{
306	unsigned int i;
307
308	if (st->use_internal_vref)
309	return st->chip_info->internal_vref;
310
311	i = st->chip_info->shared_vref ? `0` : chan->channel;
312	return regulator_get_voltage(regulator: st->vref_reg[i].consumer);
313	}
314
315	static int ad5064_read_raw(struct iio_dev *indio_dev,
316	struct iio_chan_spec const *chan,
317	int *val,
318	int *val2,
319	long m)
320	{
321	struct ad5064_state *st = iio_priv(indio_dev);
322	int scale_uv;
323
324	switch (m) {
325	case IIO_CHAN_INFO_RAW:
326	*val = st->dac_cache[chan->channel];
327	return IIO_VAL_INT;
328	case IIO_CHAN_INFO_SCALE:
329	scale_uv = ad5064_get_vref(st, chan);
330	if (scale_uv < `0`)
331	return scale_uv;
332
333	*val = scale_uv / `1000`;
334	*val2 = chan->scan_type.realbits;
335	return IIO_VAL_FRACTIONAL_LOG2;
336	default:
337	break;
338	}
339	return -EINVAL;
340	}
341
342	static int ad5064_write_raw(struct iio_dev *indio_dev,
343	struct iio_chan_spec const chan, int* val, int val2, long mask)
344	{
345	struct ad5064_state *st = iio_priv(indio_dev);
346	int ret;
347
348	switch (mask) {
349	case IIO_CHAN_INFO_RAW:
350	if (val >= (`1` << chan->scan_type.realbits) \|\| val < `0`)
351	return -EINVAL;
352
353	mutex_lock(&st->lock);
354	ret = ad5064_write(st, AD5064_CMD_WRITE_INPUT_N_UPDATE_N,
355	addr: chan->address, val, shift: chan->scan_type.shift);
356	if (ret == `0`)
357	st->dac_cache[chan->channel] = val;
358	mutex_unlock(lock: &st->lock);
359	break;
360	default:
361	ret = -EINVAL;
362	}
363
364	return ret;
365	}
366
367	static const struct iio_info ad5064_info = {
368	.read_raw = ad5064_read_raw,
369	.write_raw = ad5064_write_raw,
370	};
371
372	static const struct iio_chan_spec_ext_info ad5064_ext_info[] = {
373	{
374	.name = "powerdown",
375	.read = ad5064_read_dac_powerdown,
376	.write = ad5064_write_dac_powerdown,
377	.shared = IIO_SEPARATE,
378	},
379	IIO_ENUM("powerdown_mode", IIO_SEPARATE, &ad5064_powerdown_mode_enum),
380	IIO_ENUM_AVAILABLE("powerdown_mode", IIO_SHARED_BY_TYPE, &ad5064_powerdown_mode_enum),
381	{ },
382	};
383
384	static const struct iio_chan_spec_ext_info ltc2617_ext_info[] = {
385	{
386	.name = "powerdown",
387	.read = ad5064_read_dac_powerdown,
388	.write = ad5064_write_dac_powerdown,
389	.shared = IIO_SEPARATE,
390	},
391	IIO_ENUM("powerdown_mode", IIO_SEPARATE, &ltc2617_powerdown_mode_enum),
392	IIO_ENUM_AVAILABLE("powerdown_mode", IIO_SHARED_BY_TYPE, &ltc2617_powerdown_mode_enum),
393	{ },
394	};
395
396	#define AD5064_CHANNEL(chan, addr, bits, _shift, _ext_info) { \
397	.type = IIO_VOLTAGE, \
398	.indexed = 1, \
399	.output = 1, \
400	.channel = (chan), \
401	.info_mask_separate = BIT(IIO_CHAN_INFO_RAW) \| \
402	BIT(IIO_CHAN_INFO_SCALE), \
403	.address = addr, \
404	.scan_type = { \
405	.sign = 'u', \
406	.realbits = (bits), \
407	.storagebits = 16, \
408	.shift = (_shift), \
409	}, \
410	.ext_info = (_ext_info), \
411	}
412
413	#define DECLARE_AD5064_CHANNELS(name, bits, shift, ext_info) \
414	const struct iio_chan_spec name[] = { \
415	AD5064_CHANNEL(0, 0, bits, shift, ext_info), \
416	AD5064_CHANNEL(1, 1, bits, shift, ext_info), \
417	AD5064_CHANNEL(2, 2, bits, shift, ext_info), \
418	AD5064_CHANNEL(3, 3, bits, shift, ext_info), \
419	AD5064_CHANNEL(4, 4, bits, shift, ext_info), \
420	AD5064_CHANNEL(5, 5, bits, shift, ext_info), \
421	AD5064_CHANNEL(6, 6, bits, shift, ext_info), \
422	AD5064_CHANNEL(7, 7, bits, shift, ext_info), \
423	}
424
425	#define DECLARE_AD5065_CHANNELS(name, bits, shift, ext_info) \
426	const struct iio_chan_spec name[] = { \
427	AD5064_CHANNEL(0, 0, bits, shift, ext_info), \
428	AD5064_CHANNEL(1, 3, bits, shift, ext_info), \
429	}
430
431	static DECLARE_AD5064_CHANNELS(ad5024_channels, `12`, `8`, ad5064_ext_info);
432	static DECLARE_AD5064_CHANNELS(ad5044_channels, `14`, `6`, ad5064_ext_info);
433	static DECLARE_AD5064_CHANNELS(ad5064_channels, `16`, `4`, ad5064_ext_info);
434
435	static DECLARE_AD5065_CHANNELS(ad5025_channels, `12`, `8`, ad5064_ext_info);
436	static DECLARE_AD5065_CHANNELS(ad5045_channels, `14`, `6`, ad5064_ext_info);
437	static DECLARE_AD5065_CHANNELS(ad5065_channels, `16`, `4`, ad5064_ext_info);
438
439	static DECLARE_AD5064_CHANNELS(ad5629_channels, `12`, `4`, ad5064_ext_info);
440	static DECLARE_AD5064_CHANNELS(ad5645_channels, `14`, `2`, ad5064_ext_info);
441	static DECLARE_AD5064_CHANNELS(ad5669_channels, `16`, `0`, ad5064_ext_info);
442
443	static DECLARE_AD5064_CHANNELS(ltc2607_channels, `16`, `0`, ltc2617_ext_info);
444	static DECLARE_AD5064_CHANNELS(ltc2617_channels, `14`, `2`, ltc2617_ext_info);
445	static DECLARE_AD5064_CHANNELS(ltc2627_channels, `12`, `4`, ltc2617_ext_info);
446	#define ltc2631_12_channels ltc2627_channels
447	static DECLARE_AD5064_CHANNELS(ltc2631_10_channels, `10`, `6`, ltc2617_ext_info);
448	static DECLARE_AD5064_CHANNELS(ltc2631_8_channels, `8`, `8`, ltc2617_ext_info);
449
450	#define LTC2631_INFO(vref, pchannels, nchannels) \
451	{ \
452	.shared_vref = true, \
453	.internal_vref = vref, \
454	.channels = pchannels, \
455	.num_channels = nchannels, \
456	.regmap_type = AD5064_REGMAP_LTC, \
457	}
458
459
460	static const struct ad5064_chip_info ad5064_chip_info_tbl[] = {
461	[ID_AD5024] = {
462	.shared_vref = false,
463	.channels = ad5024_channels,
464	.num_channels = `4`,
465	.regmap_type = AD5064_REGMAP_ADI,
466	},
467	[ID_AD5025] = {
468	.shared_vref = false,
469	.channels = ad5025_channels,
470	.num_channels = `2`,
471	.regmap_type = AD5064_REGMAP_ADI,
472	},
473	[ID_AD5044] = {
474	.shared_vref = false,
475	.channels = ad5044_channels,
476	.num_channels = `4`,
477	.regmap_type = AD5064_REGMAP_ADI,
478	},
479	[ID_AD5045] = {
480	.shared_vref = false,
481	.channels = ad5045_channels,
482	.num_channels = `2`,
483	.regmap_type = AD5064_REGMAP_ADI,
484	},
485	[ID_AD5064] = {
486	.shared_vref = false,
487	.channels = ad5064_channels,
488	.num_channels = `4`,
489	.regmap_type = AD5064_REGMAP_ADI,
490	},
491	[ID_AD5064_1] = {
492	.shared_vref = true,
493	.channels = ad5064_channels,
494	.num_channels = `4`,
495	.regmap_type = AD5064_REGMAP_ADI,
496	},
497	[ID_AD5065] = {
498	.shared_vref = false,
499	.channels = ad5065_channels,
500	.num_channels = `2`,
501	.regmap_type = AD5064_REGMAP_ADI,
502	},
503	[ID_AD5625] = {
504	.shared_vref = true,
505	.channels = ad5629_channels,
506	.num_channels = `4`,
507	.regmap_type = AD5064_REGMAP_ADI2
508	},
509	[ID_AD5625R_1V25] = {
510	.shared_vref = true,
511	.internal_vref = `1250000`,
512	.channels = ad5629_channels,
513	.num_channels = `4`,
514	.regmap_type = AD5064_REGMAP_ADI2
515	},
516	[ID_AD5625R_2V5] = {
517	.shared_vref = true,
518	.internal_vref = `2500000`,
519	.channels = ad5629_channels,
520	.num_channels = `4`,
521	.regmap_type = AD5064_REGMAP_ADI2
522	},
523	[ID_AD5627] = {
524	.shared_vref = true,
525	.channels = ad5629_channels,
526	.num_channels = `2`,
527	.regmap_type = AD5064_REGMAP_ADI2
528	},
529	[ID_AD5627R_1V25] = {
530	.shared_vref = true,
531	.internal_vref = `1250000`,
532	.channels = ad5629_channels,
533	.num_channels = `2`,
534	.regmap_type = AD5064_REGMAP_ADI2
535	},
536	[ID_AD5627R_2V5] = {
537	.shared_vref = true,
538	.internal_vref = `2500000`,
539	.channels = ad5629_channels,
540	.num_channels = `2`,
541	.regmap_type = AD5064_REGMAP_ADI2
542	},
543	[ID_AD5628_1] = {
544	.shared_vref = true,
545	.internal_vref = `2500000`,
546	.channels = ad5024_channels,
547	.num_channels = `8`,
548	.regmap_type = AD5064_REGMAP_ADI,
549	},
550	[ID_AD5628_2] = {
551	.shared_vref = true,
552	.internal_vref = `5000000`,
553	.channels = ad5024_channels,
554	.num_channels = `8`,
555	.regmap_type = AD5064_REGMAP_ADI,
556	},
557	[ID_AD5629_1] = {
558	.shared_vref = true,
559	.internal_vref = `2500000`,
560	.channels = ad5629_channels,
561	.num_channels = `8`,
562	.regmap_type = AD5064_REGMAP_ADI,
563	},
564	[ID_AD5629_2] = {
565	.shared_vref = true,
566	.internal_vref = `5000000`,
567	.channels = ad5629_channels,
568	.num_channels = `8`,
569	.regmap_type = AD5064_REGMAP_ADI,
570	},
571	[ID_AD5645R_1V25] = {
572	.shared_vref = true,
573	.internal_vref = `1250000`,
574	.channels = ad5645_channels,
575	.num_channels = `4`,
576	.regmap_type = AD5064_REGMAP_ADI2
577	},
578	[ID_AD5645R_2V5] = {
579	.shared_vref = true,
580	.internal_vref = `2500000`,
581	.channels = ad5645_channels,
582	.num_channels = `4`,
583	.regmap_type = AD5064_REGMAP_ADI2
584	},
585	[ID_AD5647R_1V25] = {
586	.shared_vref = true,
587	.internal_vref = `1250000`,
588	.channels = ad5645_channels,
589	.num_channels = `2`,
590	.regmap_type = AD5064_REGMAP_ADI2
591	},
592	[ID_AD5647R_2V5] = {
593	.shared_vref = true,
594	.internal_vref = `2500000`,
595	.channels = ad5645_channels,
596	.num_channels = `2`,
597	.regmap_type = AD5064_REGMAP_ADI2
598	},
599	[ID_AD5648_1] = {
600	.shared_vref = true,
601	.internal_vref = `2500000`,
602	.channels = ad5044_channels,
603	.num_channels = `8`,
604	.regmap_type = AD5064_REGMAP_ADI,
605	},
606	[ID_AD5648_2] = {
607	.shared_vref = true,
608	.internal_vref = `5000000`,
609	.channels = ad5044_channels,
610	.num_channels = `8`,
611	.regmap_type = AD5064_REGMAP_ADI,
612	},
613	[ID_AD5665] = {
614	.shared_vref = true,
615	.channels = ad5669_channels,
616	.num_channels = `4`,
617	.regmap_type = AD5064_REGMAP_ADI2
618	},
619	[ID_AD5665R_1V25] = {
620	.shared_vref = true,
621	.internal_vref = `1250000`,
622	.channels = ad5669_channels,
623	.num_channels = `4`,
624	.regmap_type = AD5064_REGMAP_ADI2
625	},
626	[ID_AD5665R_2V5] = {
627	.shared_vref = true,
628	.internal_vref = `2500000`,
629	.channels = ad5669_channels,
630	.num_channels = `4`,
631	.regmap_type = AD5064_REGMAP_ADI2
632	},
633	[ID_AD5666_1] = {
634	.shared_vref = true,
635	.internal_vref = `2500000`,
636	.channels = ad5064_channels,
637	.num_channels = `4`,
638	.regmap_type = AD5064_REGMAP_ADI,
639	},
640	[ID_AD5666_2] = {
641	.shared_vref = true,
642	.internal_vref = `5000000`,
643	.channels = ad5064_channels,
644	.num_channels = `4`,
645	.regmap_type = AD5064_REGMAP_ADI,
646	},
647	[ID_AD5667] = {
648	.shared_vref = true,
649	.channels = ad5669_channels,
650	.num_channels = `2`,
651	.regmap_type = AD5064_REGMAP_ADI2
652	},
653	[ID_AD5667R_1V25] = {
654	.shared_vref = true,
655	.internal_vref = `1250000`,
656	.channels = ad5669_channels,
657	.num_channels = `2`,
658	.regmap_type = AD5064_REGMAP_ADI2
659	},
660	[ID_AD5667R_2V5] = {
661	.shared_vref = true,
662	.internal_vref = `2500000`,
663	.channels = ad5669_channels,
664	.num_channels = `2`,
665	.regmap_type = AD5064_REGMAP_ADI2
666	},
667	[ID_AD5668_1] = {
668	.shared_vref = true,
669	.internal_vref = `2500000`,
670	.channels = ad5064_channels,
671	.num_channels = `8`,
672	.regmap_type = AD5064_REGMAP_ADI,
673	},
674	[ID_AD5668_2] = {
675	.shared_vref = true,
676	.internal_vref = `5000000`,
677	.channels = ad5064_channels,
678	.num_channels = `8`,
679	.regmap_type = AD5064_REGMAP_ADI,
680	},
681	[ID_AD5669_1] = {
682	.shared_vref = true,
683	.internal_vref = `2500000`,
684	.channels = ad5669_channels,
685	.num_channels = `8`,
686	.regmap_type = AD5064_REGMAP_ADI,
687	},
688	[ID_AD5669_2] = {
689	.shared_vref = true,
690	.internal_vref = `5000000`,
691	.channels = ad5669_channels,
692	.num_channels = `8`,
693	.regmap_type = AD5064_REGMAP_ADI,
694	},
695	[ID_LTC2606] = {
696	.shared_vref = true,
697	.internal_vref = `0`,
698	.channels = ltc2607_channels,
699	.num_channels = `1`,
700	.regmap_type = AD5064_REGMAP_LTC,
701	},
702	[ID_LTC2607] = {
703	.shared_vref = true,
704	.internal_vref = `0`,
705	.channels = ltc2607_channels,
706	.num_channels = `2`,
707	.regmap_type = AD5064_REGMAP_LTC,
708	},
709	[ID_LTC2609] = {
710	.shared_vref = false,
711	.internal_vref = `0`,
712	.channels = ltc2607_channels,
713	.num_channels = `4`,
714	.regmap_type = AD5064_REGMAP_LTC,
715	},
716	[ID_LTC2616] = {
717	.shared_vref = true,
718	.internal_vref = `0`,
719	.channels = ltc2617_channels,
720	.num_channels = `1`,
721	.regmap_type = AD5064_REGMAP_LTC,
722	},
723	[ID_LTC2617] = {
724	.shared_vref = true,
725	.internal_vref = `0`,
726	.channels = ltc2617_channels,
727	.num_channels = `2`,
728	.regmap_type = AD5064_REGMAP_LTC,
729	},
730	[ID_LTC2619] = {
731	.shared_vref = false,
732	.internal_vref = `0`,
733	.channels = ltc2617_channels,
734	.num_channels = `4`,
735	.regmap_type = AD5064_REGMAP_LTC,
736	},
737	[ID_LTC2626] = {
738	.shared_vref = true,
739	.internal_vref = `0`,
740	.channels = ltc2627_channels,
741	.num_channels = `1`,
742	.regmap_type = AD5064_REGMAP_LTC,
743	},
744	[ID_LTC2627] = {
745	.shared_vref = true,
746	.internal_vref = `0`,
747	.channels = ltc2627_channels,
748	.num_channels = `2`,
749	.regmap_type = AD5064_REGMAP_LTC,
750	},
751	[ID_LTC2629] = {
752	.shared_vref = false,
753	.internal_vref = `0`,
754	.channels = ltc2627_channels,
755	.num_channels = `4`,
756	.regmap_type = AD5064_REGMAP_LTC,
757	},
758	[ID_LTC2631_L12] = LTC2631_INFO(`2500000`, ltc2631_12_channels, `1`),
759	[ID_LTC2631_H12] = LTC2631_INFO(`4096000`, ltc2631_12_channels, `1`),
760	[ID_LTC2631_L10] = LTC2631_INFO(`2500000`, ltc2631_10_channels, `1`),
761	[ID_LTC2631_H10] = LTC2631_INFO(`4096000`, ltc2631_10_channels, `1`),
762	[ID_LTC2631_L8] = LTC2631_INFO(`2500000`, ltc2631_8_channels, `1`),
763	[ID_LTC2631_H8] = LTC2631_INFO(`4096000`, ltc2631_8_channels, `1`),
764	[ID_LTC2633_L12] = LTC2631_INFO(`2500000`, ltc2631_12_channels, `2`),
765	[ID_LTC2633_H12] = LTC2631_INFO(`4096000`, ltc2631_12_channels, `2`),
766	[ID_LTC2633_L10] = LTC2631_INFO(`2500000`, ltc2631_10_channels, `2`),
767	[ID_LTC2633_H10] = LTC2631_INFO(`4096000`, ltc2631_10_channels, `2`),
768	[ID_LTC2633_L8] = LTC2631_INFO(`2500000`, ltc2631_8_channels, `2`),
769	[ID_LTC2633_H8] = LTC2631_INFO(`4096000`, ltc2631_8_channels, `2`),
770	[ID_LTC2635_L12] = LTC2631_INFO(`2500000`, ltc2631_12_channels, `4`),
771	[ID_LTC2635_H12] = LTC2631_INFO(`4096000`, ltc2631_12_channels, `4`),
772	[ID_LTC2635_L10] = LTC2631_INFO(`2500000`, ltc2631_10_channels, `4`),
773	[ID_LTC2635_H10] = LTC2631_INFO(`4096000`, ltc2631_10_channels, `4`),
774	[ID_LTC2635_L8] = LTC2631_INFO(`2500000`, ltc2631_8_channels, `4`),
775	[ID_LTC2635_H8] = LTC2631_INFO(`4096000`, ltc2631_8_channels, `4`),
776	};
777
778	static inline unsigned int ad5064_num_vref(struct ad5064_state *st)
779	{
780	return st->chip_info->shared_vref ? `1` : st->chip_info->num_channels;
781	}
782
783	static const char * const ad5064_vref_names[] = {
784	"vrefA",
785	"vrefB",
786	"vrefC",
787	"vrefD",
788	};
789
790	static const char ad5064_vref_name(struct* ad5064_state *st,
791	unsigned int vref)
792	{
793	return st->chip_info->shared_vref ? "vref" : ad5064_vref_names[vref];
794	}
795
796	static int ad5064_set_config(struct ad5064_state st, unsigned* int val)
797	{
798	unsigned int cmd;
799
800	switch (st->chip_info->regmap_type) {
801	case AD5064_REGMAP_ADI2:
802	cmd = AD5064_CMD_CONFIG_V2;
803	break;
804	default:
805	cmd = AD5064_CMD_CONFIG;
806	break;
807	}
808
809	return ad5064_write(st, cmd, addr: `0`, val, shift: `0`);
810	}
811
812	static int ad5064_request_vref(struct ad5064_state st, struct* device *dev)
813	{
814	unsigned int i;
815	int ret;
816
817	for (i = `0`; i < ad5064_num_vref(st); ++i)
818	st->vref_reg[i].supply = ad5064_vref_name(st, vref: i);
819
820	if (!st->chip_info->internal_vref)
821	return devm_regulator_bulk_get(dev, num_consumers: ad5064_num_vref(st),
822	consumers: st->vref_reg);
823
824	/*
825	* This assumes that when the regulator has an internal VREF
826	* there is only one external VREF connection, which is
827	* currently the case for all supported devices.
828	*/
829	st->vref_reg[`0`].consumer = devm_regulator_get_optional(dev, id: "vref");
830	if (!IS_ERR(ptr: st->vref_reg[`0`].consumer))
831	return `0`;
832
833	ret = PTR_ERR(ptr: st->vref_reg[`0`].consumer);
834	if (ret != -ENODEV)
835	return ret;
836
837	/ If no external regulator was supplied use the internal VREF /
838	st->use_internal_vref = true;
839	ret = ad5064_set_config(st, AD5064_CONFIG_INT_VREF_ENABLE);
840	if (ret)
841	dev_err(dev, "Failed to enable internal vref: %d\n", ret);
842
843	return ret;
844	}
845
846	static void ad5064_bulk_reg_disable(void *data)
847	{
848	struct ad5064_state *st = data;
849
850	regulator_bulk_disable(num_consumers: ad5064_num_vref(st), consumers: st->vref_reg);
851	}
852
853	static int ad5064_probe(struct device dev, enum* ad5064_type type,
854	const char *name, ad5064_write_func write)
855	{
856	struct iio_dev *indio_dev;
857	struct ad5064_state *st;
858	unsigned int midscale;
859	unsigned int i;
860	int ret;
861
862	indio_dev = devm_iio_device_alloc(parent: dev, sizeof_priv: sizeof(*st));
863	if (indio_dev == NULL)
864	return -ENOMEM;
865
866	st = iio_priv(indio_dev);
867	mutex_init(&st->lock);
868
869	st->chip_info = &ad5064_chip_info_tbl[type];
870	st->dev = dev;
871	st->write = write;
872
873	ret = ad5064_request_vref(st, dev);
874	if (ret)
875	return ret;
876
877	if (!st->use_internal_vref) {
878	ret = regulator_bulk_enable(num_consumers: ad5064_num_vref(st), consumers: st->vref_reg);
879	if (ret)
880	return ret;
881
882	ret = devm_add_action_or_reset(dev, ad5064_bulk_reg_disable, st);
883	if (ret)
884	return ret;
885	}
886
887	indio_dev->name = name;
888	indio_dev->info = &ad5064_info;
889	indio_dev->modes = INDIO_DIRECT_MODE;
890	indio_dev->channels = st->chip_info->channels;
891	indio_dev->num_channels = st->chip_info->num_channels;
892
893	midscale = (`1` << indio_dev->channels[`0`].scan_type.realbits) / `2`;
894
895	for (i = `0`; i < st->chip_info->num_channels; ++i) {
896	st->pwr_down_mode[i] = AD5064_LDAC_PWRDN_1K;
897	st->dac_cache[i] = midscale;
898	}
899
900	return devm_iio_device_register(dev, indio_dev);
901	}
902
903	#if IS_ENABLED(CONFIG_SPI_MASTER)
904
905	static int ad5064_spi_write(struct ad5064_state st, unsigned* int cmd,
906	unsigned int addr, unsigned int val)
907	{
908	struct spi_device *spi = to_spi_device(dev: st->dev);
909
910	st->data.spi = cpu_to_be32(AD5064_CMD(cmd) \| AD5064_ADDR(addr) \| val);
911	return spi_write(spi, buf: &st->data.spi, len: sizeof(st->data.spi));
912	}
913
914	static int ad5064_spi_probe(struct spi_device *spi)
915	{
916	const struct spi_device_id *id = spi_get_device_id(sdev: spi);
917
918	return ad5064_probe(dev: &spi->dev, type: id->driver_data, name: id->name,
919	write: ad5064_spi_write);
920	}
921
922	static const struct spi_device_id ad5064_spi_ids[] = {
923	{"ad5024", ID_AD5024},
924	{"ad5025", ID_AD5025},
925	{"ad5044", ID_AD5044},
926	{"ad5045", ID_AD5045},
927	{"ad5064", ID_AD5064},
928	{"ad5064-1", ID_AD5064_1},
929	{"ad5065", ID_AD5065},
930	{"ad5628-1", ID_AD5628_1},
931	{"ad5628-2", ID_AD5628_2},
932	{"ad5648-1", ID_AD5648_1},
933	{"ad5648-2", ID_AD5648_2},
934	{"ad5666-1", ID_AD5666_1},
935	{"ad5666-2", ID_AD5666_2},
936	{"ad5668-1", ID_AD5668_1},
937	{"ad5668-2", ID_AD5668_2},
938	{"ad5668-3", ID_AD5668_2}, / similar enough to ad5668-2 /
939	{}
940	};
941	MODULE_DEVICE_TABLE(spi, ad5064_spi_ids);
942
943	static struct spi_driver ad5064_spi_driver = {
944	.driver = {
945	.name = "ad5064",
946	},
947	.probe = ad5064_spi_probe,
948	.id_table = ad5064_spi_ids,
949	};
950
951	static int __init ad5064_spi_register_driver(void)
952	{
953	return spi_register_driver(&ad5064_spi_driver);
954	}
955
956	static void ad5064_spi_unregister_driver(void)
957	{
958	spi_unregister_driver(sdrv: &ad5064_spi_driver);
959	}
960
961	#else
962
963	static inline int ad5064_spi_register_driver(void) { return `0`; }
964	static inline void ad5064_spi_unregister_driver(void) { }
965
966	#endif
967
968	#if IS_ENABLED(CONFIG_I2C)
969
970	static int ad5064_i2c_write(struct ad5064_state st, unsigned* int cmd,
971	unsigned int addr, unsigned int val)
972	{
973	struct i2c_client *i2c = to_i2c_client(st->dev);
974	unsigned int cmd_shift;
975	int ret;
976
977	switch (st->chip_info->regmap_type) {
978	case AD5064_REGMAP_ADI2:
979	cmd_shift = `3`;
980	break;
981	default:
982	cmd_shift = `4`;
983	break;
984	}
985
986	st->data.i2c[`0`] = (cmd << cmd_shift) \| addr;
987	put_unaligned_be16(val, p: &st->data.i2c[`1`]);
988
989	ret = i2c_master_send(client: i2c, buf: st->data.i2c, count: `3`);
990	if (ret < `0`)
991	return ret;
992
993	return `0`;
994	}
995
996	static int ad5064_i2c_probe(struct i2c_client *i2c)
997	{
998	const struct i2c_device_id *id = i2c_client_get_device_id(client: i2c);
999	return ad5064_probe(dev: &i2c->dev, type: id->driver_data, name: id->name,
1000	write: ad5064_i2c_write);
1001	}
1002
1003	static const struct i2c_device_id ad5064_i2c_ids[] = {
1004	{"ad5625", ID_AD5625 },
1005	{"ad5625r-1v25", ID_AD5625R_1V25 },
1006	{"ad5625r-2v5", ID_AD5625R_2V5 },
1007	{"ad5627", ID_AD5627 },
1008	{"ad5627r-1v25", ID_AD5627R_1V25 },
1009	{"ad5627r-2v5", ID_AD5627R_2V5 },
1010	{"ad5629-1", ID_AD5629_1},
1011	{"ad5629-2", ID_AD5629_2},
1012	{"ad5629-3", ID_AD5629_2}, / similar enough to ad5629-2 /
1013	{"ad5645r-1v25", ID_AD5645R_1V25 },
1014	{"ad5645r-2v5", ID_AD5645R_2V5 },
1015	{"ad5665", ID_AD5665 },
1016	{"ad5665r-1v25", ID_AD5665R_1V25 },
1017	{"ad5665r-2v5", ID_AD5665R_2V5 },
1018	{"ad5667", ID_AD5667 },
1019	{"ad5667r-1v25", ID_AD5667R_1V25 },
1020	{"ad5667r-2v5", ID_AD5667R_2V5 },
1021	{"ad5669-1", ID_AD5669_1},
1022	{"ad5669-2", ID_AD5669_2},
1023	{"ad5669-3", ID_AD5669_2}, / similar enough to ad5669-2 /
1024	{"ltc2606", ID_LTC2606},
1025	{"ltc2607", ID_LTC2607},
1026	{"ltc2609", ID_LTC2609},
1027	{"ltc2616", ID_LTC2616},
1028	{"ltc2617", ID_LTC2617},
1029	{"ltc2619", ID_LTC2619},
1030	{"ltc2626", ID_LTC2626},
1031	{"ltc2627", ID_LTC2627},
1032	{"ltc2629", ID_LTC2629},
1033	{"ltc2631-l12", ID_LTC2631_L12},
1034	{"ltc2631-h12", ID_LTC2631_H12},
1035	{"ltc2631-l10", ID_LTC2631_L10},
1036	{"ltc2631-h10", ID_LTC2631_H10},
1037	{"ltc2631-l8", ID_LTC2631_L8},
1038	{"ltc2631-h8", ID_LTC2631_H8},
1039	{"ltc2633-l12", ID_LTC2633_L12},
1040	{"ltc2633-h12", ID_LTC2633_H12},
1041	{"ltc2633-l10", ID_LTC2633_L10},
1042	{"ltc2633-h10", ID_LTC2633_H10},
1043	{"ltc2633-l8", ID_LTC2633_L8},
1044	{"ltc2633-h8", ID_LTC2633_H8},
1045	{"ltc2635-l12", ID_LTC2635_L12},
1046	{"ltc2635-h12", ID_LTC2635_H12},
1047	{"ltc2635-l10", ID_LTC2635_L10},
1048	{"ltc2635-h10", ID_LTC2635_H10},
1049	{"ltc2635-l8", ID_LTC2635_L8},
1050	{"ltc2635-h8", ID_LTC2635_H8},
1051	{}
1052	};
1053	MODULE_DEVICE_TABLE(i2c, ad5064_i2c_ids);
1054
1055	static struct i2c_driver ad5064_i2c_driver = {
1056	.driver = {
1057	.name = "ad5064",
1058	},
1059	.probe = ad5064_i2c_probe,
1060	.id_table = ad5064_i2c_ids,
1061	};
1062
1063	static int __init ad5064_i2c_register_driver(void)
1064	{
1065	return i2c_add_driver(&ad5064_i2c_driver);
1066	}
1067
1068	static void __exit ad5064_i2c_unregister_driver(void)
1069	{
1070	i2c_del_driver(driver: &ad5064_i2c_driver);
1071	}
1072
1073	#else
1074
1075	static inline int ad5064_i2c_register_driver(void) { return `0`; }
1076	static inline void ad5064_i2c_unregister_driver(void) { }
1077
1078	#endif
1079
1080	static int __init ad5064_init(void)
1081	{
1082	int ret;
1083
1084	ret = ad5064_spi_register_driver();
1085	if (ret)
1086	return ret;
1087
1088	ret = ad5064_i2c_register_driver();
1089	if (ret) {
1090	ad5064_spi_unregister_driver();
1091	return ret;
1092	}
1093
1094	return `0`;
1095	}
1096	module_init(ad5064_init);
1097
1098	static void __exit ad5064_exit(void)
1099	{
1100	ad5064_i2c_unregister_driver();
1101	ad5064_spi_unregister_driver();
1102	}
1103	module_exit(ad5064_exit);
1104
1105	MODULE_AUTHOR("Lars-Peter Clausen <lars@metafoo.de>");
1106	MODULE_DESCRIPTION("Analog Devices AD5024 and similar multi-channel DACs");
1107	MODULE_LICENSE("GPL v2");
1108

source code of linux/drivers/iio/dac/ad5064.c