ade9000.c 51 KB

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  1. // SPDX-License-Identifier: GPL-2.0-only
  2. /**
  3. * ADE9000 driver
  4. *
  5. * Copyright 2025 Analog Devices Inc.
  6. */
  7. #include <linux/bitfield.h>
  8. #include <linux/clk.h>
  9. #include <linux/clk-provider.h>
  10. #include <linux/completion.h>
  11. #include <linux/delay.h>
  12. #include <linux/gpio/consumer.h>
  13. #include <linux/iio/iio.h>
  14. #include <linux/iio/buffer.h>
  15. #include <linux/iio/kfifo_buf.h>
  16. #include <linux/iio/events.h>
  17. #include <linux/interrupt.h>
  18. #include <linux/minmax.h>
  19. #include <linux/module.h>
  20. #include <linux/property.h>
  21. #include <linux/regmap.h>
  22. #include <linux/regulator/consumer.h>
  23. #include <linux/spi/spi.h>
  24. #include <linux/unaligned.h>
  25. /* Address of ADE9000 registers */
  26. #define ADE9000_REG_AIGAIN 0x000
  27. #define ADE9000_REG_AVGAIN 0x00B
  28. #define ADE9000_REG_AIRMSOS 0x00C
  29. #define ADE9000_REG_AVRMSOS 0x00D
  30. #define ADE9000_REG_APGAIN 0x00E
  31. #define ADE9000_REG_AWATTOS 0x00F
  32. #define ADE9000_REG_AVAROS 0x010
  33. #define ADE9000_REG_AFVAROS 0x012
  34. #define ADE9000_REG_CONFIG0 0x060
  35. #define ADE9000_REG_DICOEFF 0x072
  36. #define ADE9000_REG_AI_PCF 0x20A
  37. #define ADE9000_REG_AV_PCF 0x20B
  38. #define ADE9000_REG_AIRMS 0x20C
  39. #define ADE9000_REG_AVRMS 0x20D
  40. #define ADE9000_REG_AWATT 0x210
  41. #define ADE9000_REG_AVAR 0x211
  42. #define ADE9000_REG_AVA 0x212
  43. #define ADE9000_REG_AFVAR 0x214
  44. #define ADE9000_REG_APF 0x216
  45. #define ADE9000_REG_BI_PCF 0x22A
  46. #define ADE9000_REG_BV_PCF 0x22B
  47. #define ADE9000_REG_BIRMS 0x22C
  48. #define ADE9000_REG_BVRMS 0x22D
  49. #define ADE9000_REG_CI_PCF 0x24A
  50. #define ADE9000_REG_CV_PCF 0x24B
  51. #define ADE9000_REG_CIRMS 0x24C
  52. #define ADE9000_REG_CVRMS 0x24D
  53. #define ADE9000_REG_AWATT_ACC 0x2E5
  54. #define ADE9000_REG_AWATTHR_LO 0x2E6
  55. #define ADE9000_REG_AVAHR_LO 0x2FA
  56. #define ADE9000_REG_AFVARHR_LO 0x30E
  57. #define ADE9000_REG_BWATTHR_LO 0x322
  58. #define ADE9000_REG_BVAHR_LO 0x336
  59. #define ADE9000_REG_BFVARHR_LO 0x34A
  60. #define ADE9000_REG_CWATTHR_LO 0x35E
  61. #define ADE9000_REG_CVAHR_LO 0x372
  62. #define ADE9000_REG_CFVARHR_LO 0x386
  63. #define ADE9000_REG_STATUS0 0x402
  64. #define ADE9000_REG_STATUS1 0x403
  65. #define ADE9000_REG_MASK0 0x405
  66. #define ADE9000_REG_MASK1 0x406
  67. #define ADE9000_REG_EVENT_MASK 0x407
  68. #define ADE9000_REG_VLEVEL 0x40F
  69. #define ADE9000_REG_DIP_LVL 0x410
  70. #define ADE9000_REG_DIPA 0x411
  71. #define ADE9000_REG_DIPB 0x412
  72. #define ADE9000_REG_DIPC 0x413
  73. #define ADE9000_REG_SWELL_LVL 0x414
  74. #define ADE9000_REG_SWELLA 0x415
  75. #define ADE9000_REG_SWELLB 0x416
  76. #define ADE9000_REG_SWELLC 0x417
  77. #define ADE9000_REG_APERIOD 0x418
  78. #define ADE9000_REG_BPERIOD 0x419
  79. #define ADE9000_REG_CPERIOD 0x41A
  80. #define ADE9000_REG_RUN 0x480
  81. #define ADE9000_REG_CONFIG1 0x481
  82. #define ADE9000_REG_ACCMODE 0x492
  83. #define ADE9000_REG_CONFIG3 0x493
  84. #define ADE9000_REG_ZXTOUT 0x498
  85. #define ADE9000_REG_ZX_LP_SEL 0x49A
  86. #define ADE9000_REG_WFB_CFG 0x4A0
  87. #define ADE9000_REG_WFB_PG_IRQEN 0x4A1
  88. #define ADE9000_REG_WFB_TRG_CFG 0x4A2
  89. #define ADE9000_REG_WFB_TRG_STAT 0x4A3
  90. #define ADE9000_REG_CONFIG2 0x4AF
  91. #define ADE9000_REG_EP_CFG 0x4B0
  92. #define ADE9000_REG_EGY_TIME 0x4B2
  93. #define ADE9000_REG_PGA_GAIN 0x4B9
  94. #define ADE9000_REG_VERSION 0x4FE
  95. #define ADE9000_REG_WF_BUFF 0x800
  96. #define ADE9000_REG_WF_HALF_BUFF 0xC00
  97. #define ADE9000_REG_ADDR_MASK GENMASK(15, 4)
  98. #define ADE9000_REG_READ_BIT_MASK BIT(3)
  99. #define ADE9000_WF_CAP_EN_MASK BIT(4)
  100. #define ADE9000_WF_CAP_SEL_MASK BIT(5)
  101. #define ADE9000_WF_MODE_MASK GENMASK(7, 6)
  102. #define ADE9000_WF_SRC_MASK GENMASK(9, 8)
  103. #define ADE9000_WF_IN_EN_MASK BIT(12)
  104. /* External reference selection bit in CONFIG1 */
  105. #define ADE9000_EXT_REF_MASK BIT(15)
  106. /*
  107. * Configuration registers
  108. */
  109. #define ADE9000_PGA_GAIN 0x0000
  110. /* Default configuration */
  111. #define ADE9000_CONFIG0 0x00000000
  112. /* CF3/ZX pin outputs Zero crossing, CF4 = DREADY */
  113. #define ADE9000_CONFIG1 0x000E
  114. /* Default High pass corner frequency of 1.25Hz */
  115. #define ADE9000_CONFIG2 0x0A00
  116. /* Peak and overcurrent detection disabled */
  117. #define ADE9000_CONFIG3 0x0000
  118. /*
  119. * 50Hz operation, 3P4W Wye configuration, signed accumulation
  120. * 3P4W Wye = 3-Phase 4-Wire star configuration (3 phases + neutral wire)
  121. * Clear bit 8 i.e. ACCMODE=0x00xx for 50Hz operation
  122. * ACCMODE=0x0x9x for 3Wire delta when phase B is used as reference
  123. * 3Wire delta = 3-Phase 3-Wire triangle configuration (3 phases, no neutral)
  124. */
  125. #define ADE9000_ACCMODE 0x0000
  126. #define ADE9000_ACCMODE_60HZ 0x0100
  127. /*Line period and zero crossing obtained from VA */
  128. #define ADE9000_ZX_LP_SEL 0x0000
  129. /* Interrupt mask values for initialization */
  130. #define ADE9000_MASK0_ALL_INT_DIS 0
  131. #define ADE9000_MASK1_ALL_INT_DIS 0x00000000
  132. /* Events disabled */
  133. #define ADE9000_EVENT_DISABLE 0x00000000
  134. /*
  135. * Assuming Vnom=1/2 of full scale.
  136. * Refer to Technical reference manual for detailed calculations.
  137. */
  138. #define ADE9000_VLEVEL 0x0022EA28
  139. /* Set DICOEFF= 0xFFFFE000 when integrator is enabled */
  140. #define ADE9000_DICOEFF 0x00000000
  141. /* DSP ON */
  142. #define ADE9000_RUN_ON 0xFFFFFFFF
  143. /*
  144. * Energy Accumulation Settings
  145. * Enable energy accumulation, accumulate samples at 8ksps
  146. * latch energy accumulation after EGYRDY
  147. * If accumulation is changed to half line cycle mode, change EGY_TIME
  148. */
  149. #define ADE9000_EP_CFG 0x0011
  150. /* Accumulate 4000 samples */
  151. #define ADE9000_EGY_TIME 7999
  152. /*
  153. * Constant Definitions
  154. * ADE9000 FDSP: 8000sps, ADE9000 FDSP: 4000sps
  155. */
  156. #define ADE9000_FDSP 4000
  157. #define ADE9000_DEFAULT_CLK_FREQ_HZ 24576000
  158. #define ADE9000_WFB_CFG 0x03E9
  159. #define ADE9000_WFB_PAGE_SIZE 128
  160. #define ADE9000_WFB_NR_OF_PAGES 16
  161. #define ADE9000_WFB_MAX_CHANNELS 8
  162. #define ADE9000_WFB_BYTES_IN_SAMPLE 4
  163. #define ADE9000_WFB_SAMPLES_IN_PAGE \
  164. (ADE9000_WFB_PAGE_SIZE / ADE9000_WFB_MAX_CHANNELS)
  165. #define ADE9000_WFB_MAX_SAMPLES_CHAN \
  166. (ADE9000_WFB_SAMPLES_IN_PAGE * ADE9000_WFB_NR_OF_PAGES)
  167. #define ADE9000_WFB_FULL_BUFF_NR_SAMPLES \
  168. (ADE9000_WFB_PAGE_SIZE * ADE9000_WFB_NR_OF_PAGES)
  169. #define ADE9000_WFB_FULL_BUFF_SIZE \
  170. (ADE9000_WFB_FULL_BUFF_NR_SAMPLES * ADE9000_WFB_BYTES_IN_SAMPLE)
  171. #define ADE9000_SWRST_BIT BIT(0)
  172. /* Status and Mask register bits*/
  173. #define ADE9000_ST0_WFB_TRIG_BIT BIT(16)
  174. #define ADE9000_ST0_PAGE_FULL_BIT BIT(17)
  175. #define ADE9000_ST0_EGYRDY BIT(0)
  176. #define ADE9000_ST1_ZXTOVA_BIT BIT(6)
  177. #define ADE9000_ST1_ZXTOVB_BIT BIT(7)
  178. #define ADE9000_ST1_ZXTOVC_BIT BIT(8)
  179. #define ADE9000_ST1_ZXVA_BIT BIT(9)
  180. #define ADE9000_ST1_ZXVB_BIT BIT(10)
  181. #define ADE9000_ST1_ZXVC_BIT BIT(11)
  182. #define ADE9000_ST1_ZXIA_BIT BIT(13)
  183. #define ADE9000_ST1_ZXIB_BIT BIT(14)
  184. #define ADE9000_ST1_ZXIC_BIT BIT(15)
  185. #define ADE9000_ST1_RSTDONE_BIT BIT(16)
  186. #define ADE9000_ST1_SEQERR_BIT BIT(18)
  187. #define ADE9000_ST1_SWELLA_BIT BIT(20)
  188. #define ADE9000_ST1_SWELLB_BIT BIT(21)
  189. #define ADE9000_ST1_SWELLC_BIT BIT(22)
  190. #define ADE9000_ST1_DIPA_BIT BIT(23)
  191. #define ADE9000_ST1_DIPB_BIT BIT(24)
  192. #define ADE9000_ST1_DIPC_BIT BIT(25)
  193. #define ADE9000_ST1_ERROR0_BIT BIT(28)
  194. #define ADE9000_ST1_ERROR1_BIT BIT(29)
  195. #define ADE9000_ST1_ERROR2_BIT BIT(30)
  196. #define ADE9000_ST1_ERROR3_BIT BIT(31)
  197. #define ADE9000_ST_ERROR \
  198. (ADE9000_ST1_ERROR0 | ADE9000_ST1_ERROR1 | \
  199. ADE9000_ST1_ERROR2 | ADE9000_ST1_ERROR3)
  200. #define ADE9000_ST1_CROSSING_FIRST 6
  201. #define ADE9000_ST1_CROSSING_DEPTH 25
  202. #define ADE9000_WFB_TRG_DIP_BIT BIT(0)
  203. #define ADE9000_WFB_TRG_SWELL_BIT BIT(1)
  204. #define ADE9000_WFB_TRG_ZXIA_BIT BIT(3)
  205. #define ADE9000_WFB_TRG_ZXIB_BIT BIT(4)
  206. #define ADE9000_WFB_TRG_ZXIC_BIT BIT(5)
  207. #define ADE9000_WFB_TRG_ZXVA_BIT BIT(6)
  208. #define ADE9000_WFB_TRG_ZXVB_BIT BIT(7)
  209. #define ADE9000_WFB_TRG_ZXVC_BIT BIT(8)
  210. /* Stop when waveform buffer is full */
  211. #define ADE9000_WFB_FULL_MODE 0x0
  212. /* Continuous fill—stop only on enabled trigger events */
  213. #define ADE9000_WFB_EN_TRIG_MODE 0x1
  214. /* Continuous filling—center capture around enabled trigger events */
  215. #define ADE9000_WFB_C_EN_TRIG_MODE 0x2
  216. /* Continuous fill—used as streaming mode for continuous data output */
  217. #define ADE9000_WFB_STREAMING_MODE 0x3
  218. #define ADE9000_LAST_PAGE_BIT BIT(15)
  219. #define ADE9000_MIDDLE_PAGE_BIT BIT(7)
  220. /*
  221. * Full scale Codes referred from Datasheet. Respective digital codes are
  222. * produced when ADC inputs are at full scale.
  223. */
  224. #define ADE9000_RMS_FULL_SCALE_CODES 52866837
  225. #define ADE9000_WATT_FULL_SCALE_CODES 20694066
  226. #define ADE9000_PCF_FULL_SCALE_CODES 74770000
  227. /* Phase and channel definitions */
  228. #define ADE9000_PHASE_A_NR 0
  229. #define ADE9000_PHASE_B_NR 1
  230. #define ADE9000_PHASE_C_NR 2
  231. #define ADE9000_SCAN_POS_IA BIT(0)
  232. #define ADE9000_SCAN_POS_VA BIT(1)
  233. #define ADE9000_SCAN_POS_IB BIT(2)
  234. #define ADE9000_SCAN_POS_VB BIT(3)
  235. #define ADE9000_SCAN_POS_IC BIT(4)
  236. #define ADE9000_SCAN_POS_VC BIT(5)
  237. /* Waveform buffer configuration values */
  238. enum ade9000_wfb_cfg {
  239. ADE9000_WFB_CFG_ALL_CHAN = 0x0,
  240. ADE9000_WFB_CFG_IA_VA = 0x1,
  241. ADE9000_WFB_CFG_IB_VB = 0x2,
  242. ADE9000_WFB_CFG_IC_VC = 0x3,
  243. ADE9000_WFB_CFG_IA = 0x8,
  244. ADE9000_WFB_CFG_VA = 0x9,
  245. ADE9000_WFB_CFG_IB = 0xA,
  246. ADE9000_WFB_CFG_VB = 0xB,
  247. ADE9000_WFB_CFG_IC = 0xC,
  248. ADE9000_WFB_CFG_VC = 0xD,
  249. };
  250. #define ADE9000_PHASE_B_POS_BIT BIT(5)
  251. #define ADE9000_PHASE_C_POS_BIT BIT(6)
  252. #define ADE9000_MAX_PHASE_NR 3
  253. #define AD9000_CHANNELS_PER_PHASE 10
  254. /*
  255. * Calculate register address for multi-phase device.
  256. * Phase A (chan 0): base address + 0x00
  257. * Phase B (chan 1): base address + 0x20
  258. * Phase C (chan 2): base address + 0x40
  259. */
  260. #define ADE9000_ADDR_ADJUST(addr, chan) \
  261. (((chan) == 0 ? 0 : (chan) == 1 ? 2 : 4) << 4 | (addr))
  262. struct ade9000_state {
  263. struct completion reset_completion;
  264. struct mutex lock; /* Protects SPI transactions */
  265. u8 wf_src;
  266. u32 wfb_trg;
  267. u8 wfb_nr_activ_chan;
  268. u32 wfb_nr_samples;
  269. struct spi_device *spi;
  270. struct clk *clkin;
  271. struct spi_transfer xfer[2];
  272. struct spi_message spi_msg;
  273. struct regmap *regmap;
  274. union{
  275. u8 byte[ADE9000_WFB_FULL_BUFF_SIZE];
  276. __be32 word[ADE9000_WFB_FULL_BUFF_NR_SAMPLES];
  277. } rx_buff __aligned(IIO_DMA_MINALIGN);
  278. u8 tx_buff[2] __aligned(IIO_DMA_MINALIGN);
  279. unsigned int bulk_read_buf[2];
  280. };
  281. struct ade9000_irq1_event {
  282. u32 bit_mask;
  283. enum iio_chan_type chan_type;
  284. u32 channel;
  285. enum iio_event_type event_type;
  286. enum iio_event_direction event_dir;
  287. };
  288. static const struct ade9000_irq1_event ade9000_irq1_events[] = {
  289. { ADE9000_ST1_ZXVA_BIT, IIO_VOLTAGE, ADE9000_PHASE_A_NR, IIO_EV_TYPE_THRESH, IIO_EV_DIR_EITHER },
  290. { ADE9000_ST1_ZXIA_BIT, IIO_CURRENT, ADE9000_PHASE_A_NR, IIO_EV_TYPE_THRESH, IIO_EV_DIR_EITHER },
  291. { ADE9000_ST1_ZXVB_BIT, IIO_VOLTAGE, ADE9000_PHASE_B_NR, IIO_EV_TYPE_THRESH, IIO_EV_DIR_EITHER },
  292. { ADE9000_ST1_ZXIB_BIT, IIO_CURRENT, ADE9000_PHASE_B_NR, IIO_EV_TYPE_THRESH, IIO_EV_DIR_EITHER },
  293. { ADE9000_ST1_ZXVC_BIT, IIO_VOLTAGE, ADE9000_PHASE_C_NR, IIO_EV_TYPE_THRESH, IIO_EV_DIR_EITHER },
  294. { ADE9000_ST1_ZXIC_BIT, IIO_CURRENT, ADE9000_PHASE_C_NR, IIO_EV_TYPE_THRESH, IIO_EV_DIR_EITHER },
  295. { ADE9000_ST1_SWELLA_BIT, IIO_ALTVOLTAGE, ADE9000_PHASE_A_NR, IIO_EV_TYPE_THRESH, IIO_EV_DIR_RISING },
  296. { ADE9000_ST1_SWELLB_BIT, IIO_ALTVOLTAGE, ADE9000_PHASE_B_NR, IIO_EV_TYPE_THRESH, IIO_EV_DIR_RISING },
  297. { ADE9000_ST1_SWELLC_BIT, IIO_ALTVOLTAGE, ADE9000_PHASE_C_NR, IIO_EV_TYPE_THRESH, IIO_EV_DIR_RISING },
  298. { ADE9000_ST1_DIPA_BIT, IIO_ALTVOLTAGE, ADE9000_PHASE_A_NR, IIO_EV_TYPE_THRESH, IIO_EV_DIR_FALLING },
  299. { ADE9000_ST1_DIPB_BIT, IIO_ALTVOLTAGE, ADE9000_PHASE_B_NR, IIO_EV_TYPE_THRESH, IIO_EV_DIR_FALLING },
  300. { ADE9000_ST1_DIPC_BIT, IIO_ALTVOLTAGE, ADE9000_PHASE_C_NR, IIO_EV_TYPE_THRESH, IIO_EV_DIR_FALLING },
  301. };
  302. /* Voltage events (zero crossing on instantaneous voltage) */
  303. static const struct iio_event_spec ade9000_voltage_events[] = {
  304. {
  305. /* Zero crossing detection - datasheet: ZXV interrupts */
  306. .type = IIO_EV_TYPE_THRESH,
  307. .dir = IIO_EV_DIR_EITHER,
  308. .mask_separate = BIT(IIO_EV_INFO_ENABLE),
  309. },
  310. };
  311. /* Current events (zero crossing on instantaneous current) */
  312. static const struct iio_event_spec ade9000_current_events[] = {
  313. {
  314. /* Zero crossing detection - datasheet: ZXI interrupts */
  315. .type = IIO_EV_TYPE_THRESH,
  316. .dir = IIO_EV_DIR_EITHER,
  317. .mask_separate = BIT(IIO_EV_INFO_ENABLE),
  318. },
  319. };
  320. /* RMS voltage events (swell/sag detection on RMS values) */
  321. static const struct iio_event_spec ade9000_rms_voltage_events[] = {
  322. {
  323. .type = IIO_EV_TYPE_THRESH,
  324. .dir = IIO_EV_DIR_RISING, /* RMS swell detection */
  325. .mask_separate = BIT(IIO_EV_INFO_ENABLE) | BIT(IIO_EV_INFO_VALUE),
  326. },
  327. {
  328. .type = IIO_EV_TYPE_THRESH,
  329. .dir = IIO_EV_DIR_FALLING, /* RMS sag/dip detection */
  330. .mask_separate = BIT(IIO_EV_INFO_ENABLE) | BIT(IIO_EV_INFO_VALUE),
  331. },
  332. };
  333. static const char * const ade9000_filter_type_items[] = {
  334. "sinc4", "sinc4+lp",
  335. };
  336. static const int ade9000_filter_type_values[] = {
  337. 0, 2,
  338. };
  339. static int ade9000_filter_type_get(struct iio_dev *indio_dev,
  340. const struct iio_chan_spec *chan)
  341. {
  342. struct ade9000_state *st = iio_priv(indio_dev);
  343. u32 val;
  344. int ret;
  345. unsigned int i;
  346. ret = regmap_read(st->regmap, ADE9000_REG_WFB_CFG, &val);
  347. if (ret)
  348. return ret;
  349. val = FIELD_GET(ADE9000_WF_SRC_MASK, val);
  350. for (i = 0; i < ARRAY_SIZE(ade9000_filter_type_values); i++) {
  351. if (ade9000_filter_type_values[i] == val)
  352. return i;
  353. }
  354. return -EINVAL;
  355. }
  356. static int ade9000_filter_type_set(struct iio_dev *indio_dev,
  357. const struct iio_chan_spec *chan,
  358. unsigned int index)
  359. {
  360. struct ade9000_state *st = iio_priv(indio_dev);
  361. int ret, val;
  362. if (index >= ARRAY_SIZE(ade9000_filter_type_values))
  363. return -EINVAL;
  364. val = ade9000_filter_type_values[index];
  365. /* Update the WFB_CFG register with the new filter type */
  366. ret = regmap_update_bits(st->regmap, ADE9000_REG_WFB_CFG,
  367. ADE9000_WF_SRC_MASK,
  368. FIELD_PREP(ADE9000_WF_SRC_MASK, val));
  369. if (ret)
  370. return ret;
  371. /* Update cached value */
  372. st->wf_src = val;
  373. return 0;
  374. }
  375. static const struct iio_enum ade9000_filter_type_enum = {
  376. .items = ade9000_filter_type_items,
  377. .num_items = ARRAY_SIZE(ade9000_filter_type_items),
  378. .get = ade9000_filter_type_get,
  379. .set = ade9000_filter_type_set,
  380. };
  381. static const struct iio_chan_spec_ext_info ade9000_ext_info[] = {
  382. IIO_ENUM("filter_type", IIO_SHARED_BY_ALL, &ade9000_filter_type_enum),
  383. IIO_ENUM_AVAILABLE("filter_type", IIO_SHARED_BY_ALL, &ade9000_filter_type_enum),
  384. { }
  385. };
  386. #define ADE9000_CURRENT_CHANNEL(num) { \
  387. .type = IIO_CURRENT, \
  388. .channel = num, \
  389. .address = ADE9000_ADDR_ADJUST(ADE9000_REG_AI_PCF, num), \
  390. .info_mask_separate = BIT(IIO_CHAN_INFO_RAW) | \
  391. BIT(IIO_CHAN_INFO_SCALE) | \
  392. BIT(IIO_CHAN_INFO_CALIBSCALE), \
  393. .event_spec = ade9000_current_events, \
  394. .num_event_specs = ARRAY_SIZE(ade9000_current_events), \
  395. .scan_index = num, \
  396. .indexed = 1, \
  397. .scan_type = { \
  398. .sign = 's', \
  399. .realbits = 32, \
  400. .storagebits = 32, \
  401. .endianness = IIO_BE, \
  402. }, \
  403. }
  404. #define ADE9000_VOLTAGE_CHANNEL(num) { \
  405. .type = IIO_VOLTAGE, \
  406. .channel = num, \
  407. .address = ADE9000_ADDR_ADJUST(ADE9000_REG_AV_PCF, num), \
  408. .info_mask_separate = BIT(IIO_CHAN_INFO_RAW) | \
  409. BIT(IIO_CHAN_INFO_SCALE) | \
  410. BIT(IIO_CHAN_INFO_CALIBSCALE) | \
  411. BIT(IIO_CHAN_INFO_FREQUENCY), \
  412. .event_spec = ade9000_voltage_events, \
  413. .num_event_specs = ARRAY_SIZE(ade9000_voltage_events), \
  414. .scan_index = num + 1, /* interleave with current channels */ \
  415. .indexed = 1, \
  416. .scan_type = { \
  417. .sign = 's', \
  418. .realbits = 32, \
  419. .storagebits = 32, \
  420. .endianness = IIO_BE, \
  421. }, \
  422. .ext_info = ade9000_ext_info, \
  423. }
  424. #define ADE9000_ALTCURRENT_RMS_CHANNEL(num) { \
  425. .type = IIO_ALTCURRENT, \
  426. .channel = num, \
  427. .address = ADE9000_ADDR_ADJUST(ADE9000_REG_AIRMS, num), \
  428. .channel2 = IIO_MOD_RMS, \
  429. .modified = 1, \
  430. .indexed = 1, \
  431. .info_mask_separate = BIT(IIO_CHAN_INFO_RAW) | \
  432. BIT(IIO_CHAN_INFO_SCALE) | \
  433. BIT(IIO_CHAN_INFO_CALIBBIAS), \
  434. .scan_index = -1 \
  435. }
  436. #define ADE9000_ALTVOLTAGE_RMS_CHANNEL(num) { \
  437. .type = IIO_ALTVOLTAGE, \
  438. .channel = num, \
  439. .address = ADE9000_ADDR_ADJUST(ADE9000_REG_AVRMS, num), \
  440. .channel2 = IIO_MOD_RMS, \
  441. .modified = 1, \
  442. .indexed = 1, \
  443. .info_mask_separate = BIT(IIO_CHAN_INFO_RAW) | \
  444. BIT(IIO_CHAN_INFO_SCALE) | \
  445. BIT(IIO_CHAN_INFO_CALIBBIAS), \
  446. .event_spec = ade9000_rms_voltage_events, \
  447. .num_event_specs = ARRAY_SIZE(ade9000_rms_voltage_events), \
  448. .scan_index = -1 \
  449. }
  450. #define ADE9000_POWER_ACTIVE_CHANNEL(num) { \
  451. .type = IIO_POWER, \
  452. .channel = num, \
  453. .address = ADE9000_ADDR_ADJUST(ADE9000_REG_AWATT, num), \
  454. .channel2 = IIO_MOD_ACTIVE, \
  455. .modified = 1, \
  456. .indexed = 1, \
  457. .info_mask_separate = BIT(IIO_CHAN_INFO_RAW) | \
  458. BIT(IIO_CHAN_INFO_SCALE) | \
  459. BIT(IIO_CHAN_INFO_CALIBBIAS) | \
  460. BIT(IIO_CHAN_INFO_CALIBSCALE), \
  461. .scan_index = -1 \
  462. }
  463. #define ADE9000_POWER_REACTIVE_CHANNEL(num) { \
  464. .type = IIO_POWER, \
  465. .channel = num, \
  466. .address = ADE9000_ADDR_ADJUST(ADE9000_REG_AVAR, num), \
  467. .channel2 = IIO_MOD_REACTIVE, \
  468. .modified = 1, \
  469. .indexed = 1, \
  470. .info_mask_separate = BIT(IIO_CHAN_INFO_RAW) | \
  471. BIT(IIO_CHAN_INFO_SCALE) | \
  472. BIT(IIO_CHAN_INFO_CALIBBIAS), \
  473. .scan_index = -1 \
  474. }
  475. #define ADE9000_POWER_APPARENT_CHANNEL(num) { \
  476. .type = IIO_POWER, \
  477. .channel = num, \
  478. .address = ADE9000_ADDR_ADJUST(ADE9000_REG_AVA, num), \
  479. .channel2 = IIO_MOD_APPARENT, \
  480. .modified = 1, \
  481. .indexed = 1, \
  482. .info_mask_separate = BIT(IIO_CHAN_INFO_RAW) | \
  483. BIT(IIO_CHAN_INFO_SCALE), \
  484. .scan_index = -1 \
  485. }
  486. #define ADE9000_ENERGY_ACTIVE_CHANNEL(num, addr) { \
  487. .type = IIO_ENERGY, \
  488. .channel = num, \
  489. .address = addr, \
  490. .channel2 = IIO_MOD_ACTIVE, \
  491. .modified = 1, \
  492. .indexed = 1, \
  493. .info_mask_separate = BIT(IIO_CHAN_INFO_RAW), \
  494. .scan_index = -1 \
  495. }
  496. #define ADE9000_ENERGY_APPARENT_CHANNEL(num, addr) { \
  497. .type = IIO_ENERGY, \
  498. .channel = num, \
  499. .address = addr, \
  500. .channel2 = IIO_MOD_APPARENT, \
  501. .modified = 1, \
  502. .indexed = 1, \
  503. .info_mask_separate = BIT(IIO_CHAN_INFO_RAW), \
  504. .scan_index = -1 \
  505. }
  506. #define ADE9000_ENERGY_REACTIVE_CHANNEL(num, addr) { \
  507. .type = IIO_ENERGY, \
  508. .channel = num, \
  509. .address = addr, \
  510. .channel2 = IIO_MOD_REACTIVE, \
  511. .modified = 1, \
  512. .indexed = 1, \
  513. .info_mask_separate = BIT(IIO_CHAN_INFO_RAW), \
  514. .scan_index = -1 \
  515. }
  516. #define ADE9000_POWER_FACTOR_CHANNEL(num) { \
  517. .type = IIO_POWER, \
  518. .channel = num, \
  519. .address = ADE9000_ADDR_ADJUST(ADE9000_REG_APF, num), \
  520. .indexed = 1, \
  521. .info_mask_separate = BIT(IIO_CHAN_INFO_POWERFACTOR), \
  522. .scan_index = -1 \
  523. }
  524. static const struct iio_chan_spec ade9000_channels[] = {
  525. /* Phase A channels */
  526. ADE9000_CURRENT_CHANNEL(ADE9000_PHASE_A_NR),
  527. ADE9000_VOLTAGE_CHANNEL(ADE9000_PHASE_A_NR),
  528. ADE9000_ALTCURRENT_RMS_CHANNEL(ADE9000_PHASE_A_NR),
  529. ADE9000_ALTVOLTAGE_RMS_CHANNEL(ADE9000_PHASE_A_NR),
  530. ADE9000_POWER_ACTIVE_CHANNEL(ADE9000_PHASE_A_NR),
  531. ADE9000_POWER_REACTIVE_CHANNEL(ADE9000_PHASE_A_NR),
  532. ADE9000_POWER_APPARENT_CHANNEL(ADE9000_PHASE_A_NR),
  533. ADE9000_ENERGY_ACTIVE_CHANNEL(ADE9000_PHASE_A_NR, ADE9000_REG_AWATTHR_LO),
  534. ADE9000_ENERGY_APPARENT_CHANNEL(ADE9000_PHASE_A_NR, ADE9000_REG_AVAHR_LO),
  535. ADE9000_ENERGY_REACTIVE_CHANNEL(ADE9000_PHASE_A_NR, ADE9000_REG_AFVARHR_LO),
  536. ADE9000_POWER_FACTOR_CHANNEL(ADE9000_PHASE_A_NR),
  537. /* Phase B channels */
  538. ADE9000_CURRENT_CHANNEL(ADE9000_PHASE_B_NR),
  539. ADE9000_VOLTAGE_CHANNEL(ADE9000_PHASE_B_NR),
  540. ADE9000_ALTCURRENT_RMS_CHANNEL(ADE9000_PHASE_B_NR),
  541. ADE9000_ALTVOLTAGE_RMS_CHANNEL(ADE9000_PHASE_B_NR),
  542. ADE9000_POWER_ACTIVE_CHANNEL(ADE9000_PHASE_B_NR),
  543. ADE9000_POWER_REACTIVE_CHANNEL(ADE9000_PHASE_B_NR),
  544. ADE9000_POWER_APPARENT_CHANNEL(ADE9000_PHASE_B_NR),
  545. ADE9000_ENERGY_ACTIVE_CHANNEL(ADE9000_PHASE_B_NR, ADE9000_REG_BWATTHR_LO),
  546. ADE9000_ENERGY_APPARENT_CHANNEL(ADE9000_PHASE_B_NR, ADE9000_REG_BVAHR_LO),
  547. ADE9000_ENERGY_REACTIVE_CHANNEL(ADE9000_PHASE_B_NR, ADE9000_REG_BFVARHR_LO),
  548. ADE9000_POWER_FACTOR_CHANNEL(ADE9000_PHASE_B_NR),
  549. /* Phase C channels */
  550. ADE9000_CURRENT_CHANNEL(ADE9000_PHASE_C_NR),
  551. ADE9000_VOLTAGE_CHANNEL(ADE9000_PHASE_C_NR),
  552. ADE9000_ALTCURRENT_RMS_CHANNEL(ADE9000_PHASE_C_NR),
  553. ADE9000_ALTVOLTAGE_RMS_CHANNEL(ADE9000_PHASE_C_NR),
  554. ADE9000_POWER_ACTIVE_CHANNEL(ADE9000_PHASE_C_NR),
  555. ADE9000_POWER_REACTIVE_CHANNEL(ADE9000_PHASE_C_NR),
  556. ADE9000_POWER_APPARENT_CHANNEL(ADE9000_PHASE_C_NR),
  557. ADE9000_ENERGY_ACTIVE_CHANNEL(ADE9000_PHASE_C_NR, ADE9000_REG_CWATTHR_LO),
  558. ADE9000_ENERGY_APPARENT_CHANNEL(ADE9000_PHASE_C_NR, ADE9000_REG_CVAHR_LO),
  559. ADE9000_ENERGY_REACTIVE_CHANNEL(ADE9000_PHASE_C_NR, ADE9000_REG_CFVARHR_LO),
  560. ADE9000_POWER_FACTOR_CHANNEL(ADE9000_PHASE_C_NR),
  561. };
  562. static const struct reg_sequence ade9000_initialization_sequence[] = {
  563. { ADE9000_REG_PGA_GAIN, ADE9000_PGA_GAIN },
  564. { ADE9000_REG_CONFIG0, ADE9000_CONFIG0 },
  565. { ADE9000_REG_CONFIG1, ADE9000_CONFIG1 },
  566. { ADE9000_REG_CONFIG2, ADE9000_CONFIG2 },
  567. { ADE9000_REG_CONFIG3, ADE9000_CONFIG3 },
  568. { ADE9000_REG_ACCMODE, ADE9000_ACCMODE },
  569. { ADE9000_REG_ZX_LP_SEL, ADE9000_ZX_LP_SEL },
  570. { ADE9000_REG_MASK0, ADE9000_MASK0_ALL_INT_DIS },
  571. { ADE9000_REG_MASK1, ADE9000_MASK1_ALL_INT_DIS },
  572. { ADE9000_REG_EVENT_MASK, ADE9000_EVENT_DISABLE },
  573. { ADE9000_REG_WFB_CFG, ADE9000_WFB_CFG },
  574. { ADE9000_REG_VLEVEL, ADE9000_VLEVEL },
  575. { ADE9000_REG_DICOEFF, ADE9000_DICOEFF },
  576. { ADE9000_REG_EGY_TIME, ADE9000_EGY_TIME },
  577. { ADE9000_REG_EP_CFG, ADE9000_EP_CFG },
  578. /* Clear all pending status bits by writing 1s */
  579. { ADE9000_REG_STATUS0, GENMASK(31, 0) },
  580. { ADE9000_REG_STATUS1, GENMASK(31, 0) },
  581. { ADE9000_REG_RUN, ADE9000_RUN_ON }
  582. };
  583. static int ade9000_spi_write_reg(void *context, unsigned int reg,
  584. unsigned int val)
  585. {
  586. struct ade9000_state *st = context;
  587. u8 tx_buf[6];
  588. u16 addr;
  589. int ret, len;
  590. guard(mutex)(&st->lock);
  591. addr = FIELD_PREP(ADE9000_REG_ADDR_MASK, reg);
  592. put_unaligned_be16(addr, tx_buf);
  593. if (reg > ADE9000_REG_RUN && reg < ADE9000_REG_VERSION) {
  594. put_unaligned_be16(val, &tx_buf[2]);
  595. len = 4;
  596. } else {
  597. put_unaligned_be32(val, &tx_buf[2]);
  598. len = 6;
  599. }
  600. ret = spi_write_then_read(st->spi, tx_buf, len, NULL, 0);
  601. if (ret)
  602. dev_err(&st->spi->dev, "problem when writing register 0x%x\n", reg);
  603. return ret;
  604. }
  605. static int ade9000_spi_read_reg(void *context, unsigned int reg,
  606. unsigned int *val)
  607. {
  608. struct ade9000_state *st = context;
  609. u8 tx_buf[2];
  610. u8 rx_buf[4];
  611. u16 addr;
  612. int ret, rx_len;
  613. guard(mutex)(&st->lock);
  614. addr = FIELD_PREP(ADE9000_REG_ADDR_MASK, reg) |
  615. ADE9000_REG_READ_BIT_MASK;
  616. put_unaligned_be16(addr, tx_buf);
  617. /* Skip CRC bytes - only read actual data */
  618. if (reg > ADE9000_REG_RUN && reg < ADE9000_REG_VERSION)
  619. rx_len = 2;
  620. else
  621. rx_len = 4;
  622. ret = spi_write_then_read(st->spi, tx_buf, 2, rx_buf, rx_len);
  623. if (ret) {
  624. dev_err(&st->spi->dev, "error reading register 0x%x\n", reg);
  625. return ret;
  626. }
  627. if (reg > ADE9000_REG_RUN && reg < ADE9000_REG_VERSION)
  628. *val = get_unaligned_be16(rx_buf);
  629. else
  630. *val = get_unaligned_be32(rx_buf);
  631. return 0;
  632. }
  633. static bool ade9000_is_volatile_reg(struct device *dev, unsigned int reg)
  634. {
  635. switch (reg) {
  636. /* Interrupt/error status registers - volatile */
  637. case ADE9000_REG_STATUS0:
  638. case ADE9000_REG_STATUS1:
  639. return true;
  640. default:
  641. /* All other registers are non-volatile */
  642. return false;
  643. }
  644. }
  645. static void ade9000_configure_scan(struct iio_dev *indio_dev, u32 wfb_addr)
  646. {
  647. struct ade9000_state *st = iio_priv(indio_dev);
  648. u16 addr;
  649. addr = FIELD_PREP(ADE9000_REG_ADDR_MASK, wfb_addr) |
  650. ADE9000_REG_READ_BIT_MASK;
  651. put_unaligned_be16(addr, st->tx_buff);
  652. st->xfer[0].tx_buf = &st->tx_buff[0];
  653. st->xfer[0].len = 2;
  654. st->xfer[1].rx_buf = st->rx_buff.byte;
  655. /* Always use streaming mode */
  656. st->xfer[1].len = (st->wfb_nr_samples / 2) * 4;
  657. spi_message_init_with_transfers(&st->spi_msg, st->xfer, ARRAY_SIZE(st->xfer));
  658. }
  659. static int ade9000_iio_push_streaming(struct iio_dev *indio_dev)
  660. {
  661. struct ade9000_state *st = iio_priv(indio_dev);
  662. struct device *dev = &st->spi->dev;
  663. u32 current_page, i;
  664. int ret;
  665. guard(mutex)(&st->lock);
  666. ret = spi_sync(st->spi, &st->spi_msg);
  667. if (ret) {
  668. dev_err_ratelimited(dev, "SPI fail in trigger handler\n");
  669. return ret;
  670. }
  671. /* In streaming mode, only half the buffer is filled per interrupt */
  672. for (i = 0; i < st->wfb_nr_samples / 2; i += st->wfb_nr_activ_chan)
  673. iio_push_to_buffers(indio_dev, &st->rx_buff.word[i]);
  674. ret = regmap_read(st->regmap, ADE9000_REG_WFB_PG_IRQEN, &current_page);
  675. if (ret) {
  676. dev_err_ratelimited(dev, "IRQ0 WFB read fail\n");
  677. return ret;
  678. }
  679. if (current_page & ADE9000_MIDDLE_PAGE_BIT) {
  680. ret = regmap_write(st->regmap, ADE9000_REG_WFB_PG_IRQEN,
  681. ADE9000_LAST_PAGE_BIT);
  682. if (ret) {
  683. dev_err_ratelimited(dev, "IRQ0 WFB write fail\n");
  684. return ret;
  685. }
  686. ade9000_configure_scan(indio_dev,
  687. ADE9000_REG_WF_HALF_BUFF);
  688. } else {
  689. ret = regmap_write(st->regmap, ADE9000_REG_WFB_PG_IRQEN,
  690. ADE9000_MIDDLE_PAGE_BIT);
  691. if (ret) {
  692. dev_err_ratelimited(dev, "IRQ0 WFB write fail");
  693. return ret;
  694. }
  695. ade9000_configure_scan(indio_dev, ADE9000_REG_WF_BUFF);
  696. }
  697. return 0;
  698. }
  699. static int ade9000_iio_push_buffer(struct iio_dev *indio_dev)
  700. {
  701. struct ade9000_state *st = iio_priv(indio_dev);
  702. int ret;
  703. u32 i;
  704. guard(mutex)(&st->lock);
  705. ret = spi_sync(st->spi, &st->spi_msg);
  706. if (ret) {
  707. dev_err_ratelimited(&st->spi->dev,
  708. "SPI fail in trigger handler\n");
  709. return ret;
  710. }
  711. for (i = 0; i < st->wfb_nr_samples; i += st->wfb_nr_activ_chan)
  712. iio_push_to_buffers(indio_dev, &st->rx_buff.word[i]);
  713. return 0;
  714. }
  715. static irqreturn_t ade9000_irq0_thread(int irq, void *data)
  716. {
  717. struct iio_dev *indio_dev = data;
  718. struct ade9000_state *st = iio_priv(indio_dev);
  719. struct device *dev = &st->spi->dev;
  720. u32 handled_irq = 0;
  721. u32 interrupts, status;
  722. int ret;
  723. ret = regmap_read(st->regmap, ADE9000_REG_STATUS0, &status);
  724. if (ret) {
  725. dev_err_ratelimited(dev, "IRQ0 read status fail\n");
  726. return IRQ_HANDLED;
  727. }
  728. ret = regmap_read(st->regmap, ADE9000_REG_MASK0, &interrupts);
  729. if (ret) {
  730. dev_err_ratelimited(dev, "IRQ0 read mask fail\n");
  731. return IRQ_HANDLED;
  732. }
  733. if ((status & ADE9000_ST0_PAGE_FULL_BIT) &&
  734. (interrupts & ADE9000_ST0_PAGE_FULL_BIT)) {
  735. /* Always use streaming mode */
  736. ret = ade9000_iio_push_streaming(indio_dev);
  737. if (ret) {
  738. dev_err_ratelimited(dev, "IRQ0 IIO push fail\n");
  739. return IRQ_HANDLED;
  740. }
  741. handled_irq |= ADE9000_ST0_PAGE_FULL_BIT;
  742. }
  743. if ((status & ADE9000_ST0_WFB_TRIG_BIT) &&
  744. (interrupts & ADE9000_ST0_WFB_TRIG_BIT)) {
  745. ret = regmap_update_bits(st->regmap, ADE9000_REG_WFB_CFG,
  746. ADE9000_WF_CAP_EN_MASK, 0);
  747. if (ret) {
  748. dev_err_ratelimited(dev, "IRQ0 WFB fail\n");
  749. return IRQ_HANDLED;
  750. }
  751. if (iio_buffer_enabled(indio_dev)) {
  752. ret = ade9000_iio_push_buffer(indio_dev);
  753. if (ret) {
  754. dev_err_ratelimited(dev,
  755. "IRQ0 IIO push fail @ WFB TRIG\n");
  756. return IRQ_HANDLED;
  757. }
  758. }
  759. handled_irq |= ADE9000_ST0_WFB_TRIG_BIT;
  760. }
  761. ret = regmap_write(st->regmap, ADE9000_REG_STATUS0, handled_irq);
  762. if (ret)
  763. dev_err_ratelimited(dev, "IRQ0 write status fail\n");
  764. return IRQ_HANDLED;
  765. }
  766. static irqreturn_t ade9000_irq1_thread(int irq, void *data)
  767. {
  768. struct iio_dev *indio_dev = data;
  769. struct ade9000_state *st = iio_priv(indio_dev);
  770. unsigned int bit = ADE9000_ST1_CROSSING_FIRST;
  771. s64 timestamp = iio_get_time_ns(indio_dev);
  772. u32 handled_irq = 0;
  773. u32 interrupts, result, status, tmp;
  774. DECLARE_BITMAP(interrupt_bits, ADE9000_ST1_CROSSING_DEPTH);
  775. const struct ade9000_irq1_event *event;
  776. int ret, i;
  777. if (!completion_done(&st->reset_completion)) {
  778. ret = regmap_read(st->regmap, ADE9000_REG_STATUS1, &result);
  779. if (ret) {
  780. dev_err_ratelimited(&st->spi->dev, "IRQ1 read status fail\n");
  781. return IRQ_HANDLED;
  782. }
  783. if (result & ADE9000_ST1_RSTDONE_BIT) {
  784. complete(&st->reset_completion);
  785. /* Clear the reset done status bit */
  786. ret = regmap_write(st->regmap, ADE9000_REG_STATUS1, ADE9000_ST1_RSTDONE_BIT);
  787. if (ret)
  788. dev_err_ratelimited(&st->spi->dev,
  789. "IRQ1 clear reset status fail\n");
  790. } else {
  791. dev_err_ratelimited(&st->spi->dev,
  792. "Error testing reset done\n");
  793. }
  794. return IRQ_HANDLED;
  795. }
  796. ret = regmap_read(st->regmap, ADE9000_REG_STATUS1, &status);
  797. if (ret) {
  798. dev_err_ratelimited(&st->spi->dev, "IRQ1 read status fail\n");
  799. return IRQ_HANDLED;
  800. }
  801. ret = regmap_read(st->regmap, ADE9000_REG_MASK1, &interrupts);
  802. if (ret) {
  803. dev_err_ratelimited(&st->spi->dev, "IRQ1 read mask fail\n");
  804. return IRQ_HANDLED;
  805. }
  806. bitmap_from_arr32(interrupt_bits, &interrupts, ADE9000_ST1_CROSSING_DEPTH);
  807. for_each_set_bit_from(bit, interrupt_bits,
  808. ADE9000_ST1_CROSSING_DEPTH) {
  809. tmp = status & BIT(bit);
  810. if (!tmp)
  811. continue;
  812. event = NULL;
  813. /* Find corresponding event in lookup table */
  814. for (i = 0; i < ARRAY_SIZE(ade9000_irq1_events); i++) {
  815. if (ade9000_irq1_events[i].bit_mask == tmp) {
  816. event = &ade9000_irq1_events[i];
  817. break;
  818. }
  819. }
  820. if (event) {
  821. iio_push_event(indio_dev,
  822. IIO_UNMOD_EVENT_CODE(event->chan_type,
  823. event->channel,
  824. event->event_type,
  825. event->event_dir),
  826. timestamp);
  827. }
  828. handled_irq |= tmp;
  829. }
  830. ret = regmap_write(st->regmap, ADE9000_REG_STATUS1, handled_irq);
  831. if (ret)
  832. dev_err_ratelimited(&st->spi->dev, "IRQ1 write status fail\n");
  833. return IRQ_HANDLED;
  834. }
  835. static irqreturn_t ade9000_dready_thread(int irq, void *data)
  836. {
  837. struct iio_dev *indio_dev = data;
  838. /* Handle data ready interrupt from C4/EVENT/DREADY pin */
  839. if (iio_device_try_claim_buffer_mode(indio_dev)) {
  840. ade9000_iio_push_buffer(indio_dev);
  841. iio_device_release_buffer_mode(indio_dev);
  842. }
  843. return IRQ_HANDLED;
  844. }
  845. static int ade9000_read_raw(struct iio_dev *indio_dev,
  846. struct iio_chan_spec const *chan,
  847. int *val,
  848. int *val2,
  849. long mask)
  850. {
  851. struct ade9000_state *st = iio_priv(indio_dev);
  852. unsigned int measured;
  853. int ret;
  854. switch (mask) {
  855. case IIO_CHAN_INFO_FREQUENCY:
  856. if (chan->type == IIO_VOLTAGE) {
  857. int period_reg;
  858. int period;
  859. switch (chan->channel) {
  860. case ADE9000_PHASE_A_NR:
  861. period_reg = ADE9000_REG_APERIOD;
  862. break;
  863. case ADE9000_PHASE_B_NR:
  864. period_reg = ADE9000_REG_BPERIOD;
  865. break;
  866. case ADE9000_PHASE_C_NR:
  867. period_reg = ADE9000_REG_CPERIOD;
  868. break;
  869. default:
  870. return -EINVAL;
  871. }
  872. ret = regmap_read(st->regmap, period_reg, &period);
  873. if (ret)
  874. return ret;
  875. /*
  876. * Frequency = (4MHz * 65536) / (PERIOD + 1)
  877. * 4MHz = ADC sample rate, 65536 = 2^16 period register scaling
  878. * See ADE9000 datasheet section on period measurement
  879. */
  880. *val = 4000 * 65536;
  881. *val2 = period + 1;
  882. return IIO_VAL_FRACTIONAL;
  883. }
  884. return -EINVAL;
  885. case IIO_CHAN_INFO_RAW:
  886. if (chan->type == IIO_ENERGY) {
  887. u16 lo_reg = chan->address;
  888. ret = regmap_bulk_read(st->regmap, lo_reg,
  889. st->bulk_read_buf, 2);
  890. if (ret)
  891. return ret;
  892. *val = st->bulk_read_buf[0]; /* Lower 32 bits */
  893. *val2 = st->bulk_read_buf[1]; /* Upper 32 bits */
  894. return IIO_VAL_INT_64;
  895. }
  896. if (!iio_device_claim_direct(indio_dev))
  897. return -EBUSY;
  898. ret = regmap_read(st->regmap, chan->address, &measured);
  899. iio_device_release_direct(indio_dev);
  900. if (ret)
  901. return ret;
  902. *val = measured;
  903. return IIO_VAL_INT;
  904. case IIO_CHAN_INFO_POWERFACTOR:
  905. if (!iio_device_claim_direct(indio_dev))
  906. return -EBUSY;
  907. ret = regmap_read(st->regmap, chan->address, &measured);
  908. iio_device_release_direct(indio_dev);
  909. if (ret)
  910. return ret;
  911. *val = measured;
  912. return IIO_VAL_INT;
  913. case IIO_CHAN_INFO_SCALE:
  914. switch (chan->type) {
  915. case IIO_CURRENT:
  916. case IIO_VOLTAGE:
  917. case IIO_ALTVOLTAGE:
  918. case IIO_ALTCURRENT:
  919. switch (chan->address) {
  920. case ADE9000_REG_AI_PCF:
  921. case ADE9000_REG_AV_PCF:
  922. case ADE9000_REG_BI_PCF:
  923. case ADE9000_REG_BV_PCF:
  924. case ADE9000_REG_CI_PCF:
  925. case ADE9000_REG_CV_PCF:
  926. *val = 1;
  927. *val2 = ADE9000_PCF_FULL_SCALE_CODES;
  928. return IIO_VAL_FRACTIONAL;
  929. case ADE9000_REG_AIRMS:
  930. case ADE9000_REG_AVRMS:
  931. case ADE9000_REG_BIRMS:
  932. case ADE9000_REG_BVRMS:
  933. case ADE9000_REG_CIRMS:
  934. case ADE9000_REG_CVRMS:
  935. *val = 1;
  936. *val2 = ADE9000_RMS_FULL_SCALE_CODES;
  937. return IIO_VAL_FRACTIONAL;
  938. default:
  939. return -EINVAL;
  940. }
  941. case IIO_POWER:
  942. *val = 1;
  943. *val2 = ADE9000_WATT_FULL_SCALE_CODES;
  944. return IIO_VAL_FRACTIONAL;
  945. default:
  946. break;
  947. }
  948. return -EINVAL;
  949. default:
  950. return -EINVAL;
  951. }
  952. }
  953. static int ade9000_write_raw(struct iio_dev *indio_dev,
  954. struct iio_chan_spec const *chan,
  955. int val,
  956. int val2,
  957. long mask)
  958. {
  959. struct ade9000_state *st = iio_priv(indio_dev);
  960. u32 tmp;
  961. switch (mask) {
  962. case IIO_CHAN_INFO_CALIBBIAS:
  963. switch (chan->type) {
  964. case IIO_CURRENT:
  965. return regmap_write(st->regmap,
  966. ADE9000_ADDR_ADJUST(ADE9000_REG_AIRMSOS,
  967. chan->channel), val);
  968. case IIO_VOLTAGE:
  969. case IIO_ALTVOLTAGE:
  970. return regmap_write(st->regmap,
  971. ADE9000_ADDR_ADJUST(ADE9000_REG_AVRMSOS,
  972. chan->channel), val);
  973. case IIO_POWER:
  974. tmp = chan->address;
  975. tmp &= ~ADE9000_PHASE_B_POS_BIT;
  976. tmp &= ~ADE9000_PHASE_C_POS_BIT;
  977. switch (tmp) {
  978. case ADE9000_REG_AWATT:
  979. return regmap_write(st->regmap,
  980. ADE9000_ADDR_ADJUST(ADE9000_REG_AWATTOS,
  981. chan->channel), val);
  982. case ADE9000_REG_AVAR:
  983. return regmap_write(st->regmap,
  984. ADE9000_ADDR_ADJUST(ADE9000_REG_AVAROS,
  985. chan->channel), val);
  986. case ADE9000_REG_AFVAR:
  987. return regmap_write(st->regmap,
  988. ADE9000_ADDR_ADJUST(ADE9000_REG_AFVAROS,
  989. chan->channel), val);
  990. default:
  991. return -EINVAL;
  992. }
  993. default:
  994. return -EINVAL;
  995. }
  996. case IIO_CHAN_INFO_CALIBSCALE:
  997. /*
  998. * Calibration gain registers for fine-tuning measurements.
  999. * These are separate from PGA gain and applied in the digital domain.
  1000. */
  1001. switch (chan->type) {
  1002. case IIO_CURRENT:
  1003. return regmap_write(st->regmap,
  1004. ADE9000_ADDR_ADJUST(ADE9000_REG_AIGAIN,
  1005. chan->channel), val);
  1006. case IIO_VOLTAGE:
  1007. return regmap_write(st->regmap,
  1008. ADE9000_ADDR_ADJUST(ADE9000_REG_AVGAIN,
  1009. chan->channel), val);
  1010. case IIO_POWER:
  1011. return regmap_write(st->regmap,
  1012. ADE9000_ADDR_ADJUST(ADE9000_REG_APGAIN,
  1013. chan->channel), val);
  1014. default:
  1015. return -EINVAL;
  1016. }
  1017. case IIO_CHAN_INFO_SCALE:
  1018. /* Per-channel scales are read-only */
  1019. return -EINVAL;
  1020. default:
  1021. return -EINVAL;
  1022. }
  1023. }
  1024. static int ade9000_reg_access(struct iio_dev *indio_dev,
  1025. unsigned int reg,
  1026. unsigned int tx_val,
  1027. unsigned int *rx_val)
  1028. {
  1029. struct ade9000_state *st = iio_priv(indio_dev);
  1030. if (rx_val)
  1031. return regmap_read(st->regmap, reg, rx_val);
  1032. return regmap_write(st->regmap, reg, tx_val);
  1033. }
  1034. static int ade9000_read_event_config(struct iio_dev *indio_dev,
  1035. const struct iio_chan_spec *chan,
  1036. enum iio_event_type type,
  1037. enum iio_event_direction dir)
  1038. {
  1039. struct ade9000_state *st = iio_priv(indio_dev);
  1040. u32 interrupts1;
  1041. int ret;
  1042. /* All events use MASK1 register */
  1043. ret = regmap_read(st->regmap, ADE9000_REG_MASK1, &interrupts1);
  1044. if (ret)
  1045. return ret;
  1046. switch (chan->channel) {
  1047. case ADE9000_PHASE_A_NR:
  1048. if (chan->type == IIO_VOLTAGE && dir == IIO_EV_DIR_EITHER)
  1049. return !!(interrupts1 & ADE9000_ST1_ZXVA_BIT);
  1050. else if (chan->type == IIO_CURRENT && dir == IIO_EV_DIR_EITHER)
  1051. return !!(interrupts1 & ADE9000_ST1_ZXIA_BIT);
  1052. else if (chan->type == IIO_ALTVOLTAGE && dir == IIO_EV_DIR_RISING)
  1053. return !!(interrupts1 & ADE9000_ST1_SWELLA_BIT);
  1054. else if (chan->type == IIO_ALTVOLTAGE && dir == IIO_EV_DIR_FALLING)
  1055. return !!(interrupts1 & ADE9000_ST1_DIPA_BIT);
  1056. dev_err_ratelimited(&indio_dev->dev,
  1057. "Invalid channel type %d or direction %d for phase A\n", chan->type, dir);
  1058. return -EINVAL;
  1059. case ADE9000_PHASE_B_NR:
  1060. if (chan->type == IIO_VOLTAGE && dir == IIO_EV_DIR_EITHER)
  1061. return !!(interrupts1 & ADE9000_ST1_ZXVB_BIT);
  1062. else if (chan->type == IIO_CURRENT && dir == IIO_EV_DIR_EITHER)
  1063. return !!(interrupts1 & ADE9000_ST1_ZXIB_BIT);
  1064. else if (chan->type == IIO_ALTVOLTAGE && dir == IIO_EV_DIR_RISING)
  1065. return !!(interrupts1 & ADE9000_ST1_SWELLB_BIT);
  1066. else if (chan->type == IIO_ALTVOLTAGE && dir == IIO_EV_DIR_FALLING)
  1067. return !!(interrupts1 & ADE9000_ST1_DIPB_BIT);
  1068. dev_err_ratelimited(&indio_dev->dev,
  1069. "Invalid channel type %d or direction %d for phase B\n", chan->type, dir);
  1070. return -EINVAL;
  1071. case ADE9000_PHASE_C_NR:
  1072. if (chan->type == IIO_VOLTAGE && dir == IIO_EV_DIR_EITHER)
  1073. return !!(interrupts1 & ADE9000_ST1_ZXVC_BIT);
  1074. else if (chan->type == IIO_CURRENT && dir == IIO_EV_DIR_EITHER)
  1075. return !!(interrupts1 & ADE9000_ST1_ZXIC_BIT);
  1076. else if (chan->type == IIO_ALTVOLTAGE && dir == IIO_EV_DIR_RISING)
  1077. return !!(interrupts1 & ADE9000_ST1_SWELLC_BIT);
  1078. else if (chan->type == IIO_ALTVOLTAGE && dir == IIO_EV_DIR_FALLING)
  1079. return !!(interrupts1 & ADE9000_ST1_DIPC_BIT);
  1080. dev_err_ratelimited(&indio_dev->dev,
  1081. "Invalid channel type %d or direction %d for phase C\n", chan->type, dir);
  1082. return -EINVAL;
  1083. default:
  1084. return -EINVAL;
  1085. }
  1086. }
  1087. static int ade9000_write_event_config(struct iio_dev *indio_dev,
  1088. const struct iio_chan_spec *chan,
  1089. enum iio_event_type type,
  1090. enum iio_event_direction dir,
  1091. bool state)
  1092. {
  1093. struct ade9000_state *st = iio_priv(indio_dev);
  1094. u32 bit_mask;
  1095. int ret;
  1096. /* Clear all pending events in STATUS1 register (write 1 to clear) */
  1097. ret = regmap_write(st->regmap, ADE9000_REG_STATUS1, GENMASK(31, 0));
  1098. if (ret)
  1099. return ret;
  1100. /* Determine which interrupt bit to enable/disable */
  1101. switch (chan->channel) {
  1102. case ADE9000_PHASE_A_NR:
  1103. if (chan->type == IIO_VOLTAGE && dir == IIO_EV_DIR_EITHER) {
  1104. bit_mask = ADE9000_ST1_ZXVA_BIT;
  1105. if (state)
  1106. st->wfb_trg |= ADE9000_WFB_TRG_ZXVA_BIT;
  1107. else
  1108. st->wfb_trg &= ~ADE9000_WFB_TRG_ZXVA_BIT;
  1109. } else if (chan->type == IIO_CURRENT && dir == IIO_EV_DIR_EITHER) {
  1110. bit_mask = ADE9000_ST1_ZXIA_BIT;
  1111. if (state)
  1112. st->wfb_trg |= ADE9000_WFB_TRG_ZXIA_BIT;
  1113. else
  1114. st->wfb_trg &= ~ADE9000_WFB_TRG_ZXIA_BIT;
  1115. } else if (chan->type == IIO_ALTVOLTAGE && dir == IIO_EV_DIR_RISING) {
  1116. bit_mask = ADE9000_ST1_SWELLA_BIT;
  1117. if (state)
  1118. st->wfb_trg |= ADE9000_WFB_TRG_SWELL_BIT;
  1119. else
  1120. st->wfb_trg &= ~ADE9000_WFB_TRG_SWELL_BIT;
  1121. } else if (chan->type == IIO_ALTVOLTAGE && dir == IIO_EV_DIR_FALLING) {
  1122. bit_mask = ADE9000_ST1_DIPA_BIT;
  1123. if (state)
  1124. st->wfb_trg |= ADE9000_WFB_TRG_DIP_BIT;
  1125. else
  1126. st->wfb_trg &= ~ADE9000_WFB_TRG_DIP_BIT;
  1127. } else {
  1128. dev_err_ratelimited(&indio_dev->dev, "Invalid channel type %d or direction %d for phase A\n",
  1129. chan->type, dir);
  1130. return -EINVAL;
  1131. }
  1132. break;
  1133. case ADE9000_PHASE_B_NR:
  1134. if (chan->type == IIO_VOLTAGE && dir == IIO_EV_DIR_EITHER) {
  1135. bit_mask = ADE9000_ST1_ZXVB_BIT;
  1136. if (state)
  1137. st->wfb_trg |= ADE9000_WFB_TRG_ZXVB_BIT;
  1138. else
  1139. st->wfb_trg &= ~ADE9000_WFB_TRG_ZXVB_BIT;
  1140. } else if (chan->type == IIO_CURRENT && dir == IIO_EV_DIR_EITHER) {
  1141. bit_mask = ADE9000_ST1_ZXIB_BIT;
  1142. if (state)
  1143. st->wfb_trg |= ADE9000_WFB_TRG_ZXIB_BIT;
  1144. else
  1145. st->wfb_trg &= ~ADE9000_WFB_TRG_ZXIB_BIT;
  1146. } else if (chan->type == IIO_ALTVOLTAGE && dir == IIO_EV_DIR_RISING) {
  1147. bit_mask = ADE9000_ST1_SWELLB_BIT;
  1148. if (state)
  1149. st->wfb_trg |= ADE9000_WFB_TRG_SWELL_BIT;
  1150. else
  1151. st->wfb_trg &= ~ADE9000_WFB_TRG_SWELL_BIT;
  1152. } else if (chan->type == IIO_ALTVOLTAGE && dir == IIO_EV_DIR_FALLING) {
  1153. bit_mask = ADE9000_ST1_DIPB_BIT;
  1154. if (state)
  1155. st->wfb_trg |= ADE9000_WFB_TRG_DIP_BIT;
  1156. else
  1157. st->wfb_trg &= ~ADE9000_WFB_TRG_DIP_BIT;
  1158. } else {
  1159. dev_err_ratelimited(&indio_dev->dev,
  1160. "Invalid channel type %d or direction %d for phase B\n",
  1161. chan->type, dir);
  1162. return -EINVAL;
  1163. }
  1164. break;
  1165. case ADE9000_PHASE_C_NR:
  1166. if (chan->type == IIO_VOLTAGE && dir == IIO_EV_DIR_EITHER) {
  1167. bit_mask = ADE9000_ST1_ZXVC_BIT;
  1168. if (state)
  1169. st->wfb_trg |= ADE9000_WFB_TRG_ZXVC_BIT;
  1170. else
  1171. st->wfb_trg &= ~ADE9000_WFB_TRG_ZXVC_BIT;
  1172. } else if (chan->type == IIO_CURRENT && dir == IIO_EV_DIR_EITHER) {
  1173. bit_mask = ADE9000_ST1_ZXIC_BIT;
  1174. if (state)
  1175. st->wfb_trg |= ADE9000_WFB_TRG_ZXIC_BIT;
  1176. else
  1177. st->wfb_trg &= ~ADE9000_WFB_TRG_ZXIC_BIT;
  1178. } else if (chan->type == IIO_ALTVOLTAGE && dir == IIO_EV_DIR_RISING) {
  1179. bit_mask = ADE9000_ST1_SWELLC_BIT;
  1180. if (state)
  1181. st->wfb_trg |= ADE9000_WFB_TRG_SWELL_BIT;
  1182. else
  1183. st->wfb_trg &= ~ADE9000_WFB_TRG_SWELL_BIT;
  1184. } else if (chan->type == IIO_ALTVOLTAGE && dir == IIO_EV_DIR_FALLING) {
  1185. bit_mask = ADE9000_ST1_DIPC_BIT;
  1186. if (state)
  1187. st->wfb_trg |= ADE9000_WFB_TRG_DIP_BIT;
  1188. else
  1189. st->wfb_trg &= ~ADE9000_WFB_TRG_DIP_BIT;
  1190. } else {
  1191. dev_err_ratelimited(&indio_dev->dev,
  1192. "Invalid channel type %d or direction %d for phase C\n",
  1193. chan->type, dir);
  1194. return -EINVAL;
  1195. }
  1196. break;
  1197. default:
  1198. return -EINVAL;
  1199. }
  1200. /* Set bits if enabling event, clear bits if disabling */
  1201. return regmap_assign_bits(st->regmap, ADE9000_REG_MASK1, bit_mask, state ? bit_mask : 0);
  1202. }
  1203. static int ade9000_write_event_value(struct iio_dev *indio_dev,
  1204. const struct iio_chan_spec *chan,
  1205. enum iio_event_type type,
  1206. enum iio_event_direction dir,
  1207. enum iio_event_info info,
  1208. int val, int val2)
  1209. {
  1210. struct ade9000_state *st = iio_priv(indio_dev);
  1211. switch (info) {
  1212. case IIO_EV_INFO_VALUE:
  1213. switch (dir) {
  1214. case IIO_EV_DIR_FALLING:
  1215. return regmap_write(st->regmap, ADE9000_REG_DIP_LVL, val);
  1216. case IIO_EV_DIR_RISING:
  1217. return regmap_write(st->regmap, ADE9000_REG_SWELL_LVL, val);
  1218. default:
  1219. return -EINVAL;
  1220. }
  1221. default:
  1222. return -EINVAL;
  1223. }
  1224. }
  1225. static int ade9000_read_event_value(struct iio_dev *indio_dev,
  1226. const struct iio_chan_spec *chan,
  1227. enum iio_event_type type,
  1228. enum iio_event_direction dir,
  1229. enum iio_event_info info,
  1230. int *val, int *val2)
  1231. {
  1232. struct ade9000_state *st = iio_priv(indio_dev);
  1233. unsigned int data;
  1234. int ret;
  1235. switch (info) {
  1236. case IIO_EV_INFO_VALUE:
  1237. switch (dir) {
  1238. case IIO_EV_DIR_FALLING:
  1239. ret = regmap_read(st->regmap, ADE9000_REG_DIP_LVL, &data);
  1240. if (ret)
  1241. return ret;
  1242. *val = data;
  1243. return IIO_VAL_INT;
  1244. case IIO_EV_DIR_RISING:
  1245. ret = regmap_read(st->regmap, ADE9000_REG_SWELL_LVL, &data);
  1246. if (ret)
  1247. return ret;
  1248. *val = data;
  1249. return IIO_VAL_INT;
  1250. default:
  1251. return -EINVAL;
  1252. }
  1253. default:
  1254. return -EINVAL;
  1255. }
  1256. }
  1257. static int ade9000_waveform_buffer_config(struct iio_dev *indio_dev)
  1258. {
  1259. struct ade9000_state *st = iio_priv(indio_dev);
  1260. u32 wfb_cfg_val;
  1261. u32 active_scans;
  1262. bitmap_to_arr32(&active_scans, indio_dev->active_scan_mask,
  1263. iio_get_masklength(indio_dev));
  1264. switch (active_scans) {
  1265. case ADE9000_SCAN_POS_IA | ADE9000_SCAN_POS_VA:
  1266. wfb_cfg_val = ADE9000_WFB_CFG_IA_VA;
  1267. st->wfb_nr_activ_chan = 2;
  1268. break;
  1269. case ADE9000_SCAN_POS_IB | ADE9000_SCAN_POS_VB:
  1270. wfb_cfg_val = ADE9000_WFB_CFG_IB_VB;
  1271. st->wfb_nr_activ_chan = 2;
  1272. break;
  1273. case ADE9000_SCAN_POS_IC | ADE9000_SCAN_POS_VC:
  1274. wfb_cfg_val = ADE9000_WFB_CFG_IC_VC;
  1275. st->wfb_nr_activ_chan = 2;
  1276. break;
  1277. case ADE9000_SCAN_POS_IA:
  1278. wfb_cfg_val = ADE9000_WFB_CFG_IA;
  1279. st->wfb_nr_activ_chan = 1;
  1280. break;
  1281. case ADE9000_SCAN_POS_VA:
  1282. wfb_cfg_val = ADE9000_WFB_CFG_VA;
  1283. st->wfb_nr_activ_chan = 1;
  1284. break;
  1285. case ADE9000_SCAN_POS_IB:
  1286. wfb_cfg_val = ADE9000_WFB_CFG_IB;
  1287. st->wfb_nr_activ_chan = 1;
  1288. break;
  1289. case ADE9000_SCAN_POS_VB:
  1290. wfb_cfg_val = ADE9000_WFB_CFG_VB;
  1291. st->wfb_nr_activ_chan = 1;
  1292. break;
  1293. case ADE9000_SCAN_POS_IC:
  1294. wfb_cfg_val = ADE9000_WFB_CFG_IC;
  1295. st->wfb_nr_activ_chan = 1;
  1296. break;
  1297. case ADE9000_SCAN_POS_VC:
  1298. wfb_cfg_val = ADE9000_WFB_CFG_VC;
  1299. st->wfb_nr_activ_chan = 1;
  1300. break;
  1301. case (ADE9000_SCAN_POS_IA | ADE9000_SCAN_POS_VA | ADE9000_SCAN_POS_IB |
  1302. ADE9000_SCAN_POS_VB | ADE9000_SCAN_POS_IC | ADE9000_SCAN_POS_VC):
  1303. wfb_cfg_val = ADE9000_WFB_CFG_ALL_CHAN;
  1304. st->wfb_nr_activ_chan = 6;
  1305. break;
  1306. default:
  1307. dev_err(&st->spi->dev, "Unsupported combination of scans\n");
  1308. return -EINVAL;
  1309. }
  1310. wfb_cfg_val |= FIELD_PREP(ADE9000_WF_SRC_MASK, st->wf_src);
  1311. return regmap_write(st->regmap, ADE9000_REG_WFB_CFG, wfb_cfg_val);
  1312. }
  1313. static int ade9000_waveform_buffer_interrupt_setup(struct ade9000_state *st)
  1314. {
  1315. int ret;
  1316. ret = regmap_write(st->regmap, ADE9000_REG_WFB_TRG_CFG, 0x0);
  1317. if (ret)
  1318. return ret;
  1319. /* Always use streaming mode setup */
  1320. ret = regmap_write(st->regmap, ADE9000_REG_WFB_PG_IRQEN,
  1321. ADE9000_MIDDLE_PAGE_BIT);
  1322. if (ret)
  1323. return ret;
  1324. ret = regmap_write(st->regmap, ADE9000_REG_STATUS0, GENMASK(31, 0));
  1325. if (ret)
  1326. return ret;
  1327. return regmap_set_bits(st->regmap, ADE9000_REG_MASK0,
  1328. ADE9000_ST0_PAGE_FULL_BIT);
  1329. }
  1330. static int ade9000_buffer_preenable(struct iio_dev *indio_dev)
  1331. {
  1332. struct ade9000_state *st = iio_priv(indio_dev);
  1333. int ret;
  1334. ret = ade9000_waveform_buffer_config(indio_dev);
  1335. if (ret)
  1336. return ret;
  1337. st->wfb_nr_samples = ADE9000_WFB_MAX_SAMPLES_CHAN * st->wfb_nr_activ_chan;
  1338. ade9000_configure_scan(indio_dev, ADE9000_REG_WF_BUFF);
  1339. ret = ade9000_waveform_buffer_interrupt_setup(st);
  1340. if (ret)
  1341. return ret;
  1342. ret = regmap_set_bits(st->regmap, ADE9000_REG_WFB_CFG,
  1343. ADE9000_WF_CAP_EN_MASK);
  1344. if (ret) {
  1345. dev_err(&st->spi->dev, "Post-enable waveform buffer enable fail\n");
  1346. return ret;
  1347. }
  1348. return 0;
  1349. }
  1350. static int ade9000_buffer_postdisable(struct iio_dev *indio_dev)
  1351. {
  1352. struct ade9000_state *st = iio_priv(indio_dev);
  1353. struct device *dev = &st->spi->dev;
  1354. u32 interrupts;
  1355. int ret;
  1356. ret = regmap_clear_bits(st->regmap, ADE9000_REG_WFB_CFG,
  1357. ADE9000_WF_CAP_EN_MASK);
  1358. if (ret) {
  1359. dev_err(dev, "Post-disable waveform buffer disable fail\n");
  1360. return ret;
  1361. }
  1362. ret = regmap_write(st->regmap, ADE9000_REG_WFB_TRG_CFG, 0x0);
  1363. if (ret)
  1364. return ret;
  1365. interrupts = ADE9000_ST0_WFB_TRIG_BIT | ADE9000_ST0_PAGE_FULL_BIT;
  1366. ret = regmap_clear_bits(st->regmap, ADE9000_REG_MASK0, interrupts);
  1367. if (ret) {
  1368. dev_err(dev, "Post-disable update maks0 fail\n");
  1369. return ret;
  1370. }
  1371. return regmap_write(st->regmap, ADE9000_REG_STATUS0, GENMASK(31, 0));
  1372. }
  1373. static const struct iio_buffer_setup_ops ade9000_buffer_ops = {
  1374. .preenable = &ade9000_buffer_preenable,
  1375. .postdisable = &ade9000_buffer_postdisable,
  1376. };
  1377. static int ade9000_reset(struct ade9000_state *st)
  1378. {
  1379. struct device *dev = &st->spi->dev;
  1380. struct gpio_desc *gpio_reset;
  1381. int ret;
  1382. gpio_reset = devm_gpiod_get_optional(dev, "reset", GPIOD_OUT_HIGH);
  1383. if (IS_ERR(gpio_reset))
  1384. return PTR_ERR(gpio_reset);
  1385. /* Software reset via register if no GPIO available */
  1386. if (!gpio_reset) {
  1387. ret = regmap_set_bits(st->regmap, ADE9000_REG_CONFIG1,
  1388. ADE9000_SWRST_BIT);
  1389. if (ret)
  1390. return ret;
  1391. fsleep(90);
  1392. return 0;
  1393. }
  1394. /* Hardware reset via GPIO */
  1395. fsleep(10);
  1396. gpiod_set_value_cansleep(gpio_reset, 0);
  1397. fsleep(50000);
  1398. /* Only wait for completion if IRQ1 is available to signal reset done */
  1399. if (fwnode_irq_get_byname(dev_fwnode(dev), "irq1") >= 0) {
  1400. if (!wait_for_completion_timeout(&st->reset_completion,
  1401. msecs_to_jiffies(1000))) {
  1402. dev_err(dev, "Reset timeout after 1s\n");
  1403. return -ETIMEDOUT;
  1404. }
  1405. }
  1406. /* If no IRQ available, reset is already complete after the 50ms delay above */
  1407. return 0;
  1408. }
  1409. static int ade9000_setup(struct ade9000_state *st)
  1410. {
  1411. struct device *dev = &st->spi->dev;
  1412. int ret;
  1413. ret = regmap_multi_reg_write(st->regmap, ade9000_initialization_sequence,
  1414. ARRAY_SIZE(ade9000_initialization_sequence));
  1415. if (ret)
  1416. return dev_err_probe(dev, ret, "Failed to write register sequence");
  1417. fsleep(2000);
  1418. return 0;
  1419. }
  1420. static const struct iio_info ade9000_info = {
  1421. .read_raw = ade9000_read_raw,
  1422. .write_raw = ade9000_write_raw,
  1423. .debugfs_reg_access = ade9000_reg_access,
  1424. .write_event_config = ade9000_write_event_config,
  1425. .read_event_config = ade9000_read_event_config,
  1426. .write_event_value = ade9000_write_event_value,
  1427. .read_event_value = ade9000_read_event_value,
  1428. };
  1429. static const struct regmap_config ade9000_regmap_config = {
  1430. .reg_bits = 16,
  1431. .val_bits = 32,
  1432. .max_register = 0x6bc,
  1433. .zero_flag_mask = true,
  1434. .cache_type = REGCACHE_MAPLE,
  1435. .reg_read = ade9000_spi_read_reg,
  1436. .reg_write = ade9000_spi_write_reg,
  1437. .volatile_reg = ade9000_is_volatile_reg,
  1438. };
  1439. static int ade9000_setup_clkout(struct device *dev, struct ade9000_state *st)
  1440. {
  1441. struct clk_hw *clkout_hw;
  1442. int ret;
  1443. if (!IS_ENABLED(CONFIG_COMMON_CLK))
  1444. return 0;
  1445. /*
  1446. * Only provide clock output when using external CMOS clock.
  1447. * When using crystal, CLKOUT is connected to crystal and shouldn't
  1448. * be used as clock provider for other devices.
  1449. */
  1450. if (!device_property_present(dev, "#clock-cells") || !st->clkin)
  1451. return 0;
  1452. /* CLKOUT passes through CLKIN with divider of 1 */
  1453. clkout_hw = devm_clk_hw_register_divider(dev, "clkout", __clk_get_name(st->clkin),
  1454. CLK_SET_RATE_PARENT, NULL, 0, 1, 0, NULL);
  1455. if (IS_ERR(clkout_hw))
  1456. return dev_err_probe(dev, PTR_ERR(clkout_hw), "Failed to register clkout");
  1457. ret = devm_of_clk_add_hw_provider(dev, of_clk_hw_simple_get, clkout_hw);
  1458. if (ret)
  1459. return dev_err_probe(dev, ret, "Failed to add clock provider");
  1460. return 0;
  1461. }
  1462. static int ade9000_request_irq(struct device *dev, const char *name,
  1463. irq_handler_t handler, void *dev_id)
  1464. {
  1465. int irq, ret;
  1466. irq = fwnode_irq_get_byname(dev_fwnode(dev), name);
  1467. if (irq == -EINVAL)
  1468. return 0; /* interrupts are optional */
  1469. if (irq < 0)
  1470. return dev_err_probe(dev, irq, "Failed to get %s irq", name);
  1471. ret = devm_request_threaded_irq(dev, irq, NULL, handler,
  1472. IRQF_ONESHOT, KBUILD_MODNAME, dev_id);
  1473. if (ret)
  1474. return dev_err_probe(dev, ret, "Failed to request %s irq", name);
  1475. return 0;
  1476. }
  1477. static int ade9000_probe(struct spi_device *spi)
  1478. {
  1479. struct device *dev = &spi->dev;
  1480. struct iio_dev *indio_dev;
  1481. struct ade9000_state *st;
  1482. struct regmap *regmap;
  1483. int ret;
  1484. indio_dev = devm_iio_device_alloc(dev, sizeof(*st));
  1485. if (!indio_dev)
  1486. return -ENOMEM;
  1487. st = iio_priv(indio_dev);
  1488. regmap = devm_regmap_init(dev, NULL, st, &ade9000_regmap_config);
  1489. if (IS_ERR(regmap))
  1490. return dev_err_probe(dev, PTR_ERR(regmap), "Unable to allocate ADE9000 regmap");
  1491. st->regmap = regmap;
  1492. st->spi = spi;
  1493. init_completion(&st->reset_completion);
  1494. ret = devm_mutex_init(dev, &st->lock);
  1495. if (ret)
  1496. return ret;
  1497. ret = ade9000_request_irq(dev, "irq0", ade9000_irq0_thread, indio_dev);
  1498. if (ret)
  1499. return ret;
  1500. ret = ade9000_request_irq(dev, "irq1", ade9000_irq1_thread, indio_dev);
  1501. if (ret)
  1502. return ret;
  1503. ret = ade9000_request_irq(dev, "dready", ade9000_dready_thread, indio_dev);
  1504. if (ret)
  1505. return ret;
  1506. /* External CMOS clock input (optional - crystal can be used instead) */
  1507. st->clkin = devm_clk_get_optional_enabled(dev, NULL);
  1508. if (IS_ERR(st->clkin))
  1509. return dev_err_probe(dev, PTR_ERR(st->clkin), "Failed to get and enable clkin");
  1510. ret = ade9000_setup_clkout(dev, st);
  1511. if (ret)
  1512. return ret;
  1513. indio_dev->name = "ade9000";
  1514. indio_dev->info = &ade9000_info;
  1515. indio_dev->modes = INDIO_DIRECT_MODE;
  1516. indio_dev->setup_ops = &ade9000_buffer_ops;
  1517. ret = devm_regulator_get_enable(&spi->dev, "vdd");
  1518. if (ret)
  1519. return dev_err_probe(&spi->dev, ret,
  1520. "Failed to get and enable vdd regulator\n");
  1521. indio_dev->channels = ade9000_channels;
  1522. indio_dev->num_channels = ARRAY_SIZE(ade9000_channels);
  1523. ret = devm_iio_kfifo_buffer_setup(dev, indio_dev,
  1524. &ade9000_buffer_ops);
  1525. if (ret)
  1526. return dev_err_probe(dev, ret, "Failed to setup IIO buffer");
  1527. ret = ade9000_reset(st);
  1528. if (ret)
  1529. return ret;
  1530. /* Configure reference selection if vref regulator is available */
  1531. ret = devm_regulator_get_enable_optional(dev, "vref");
  1532. if (ret != -ENODEV && ret >= 0) {
  1533. ret = regmap_set_bits(st->regmap, ADE9000_REG_CONFIG1,
  1534. ADE9000_EXT_REF_MASK);
  1535. if (ret)
  1536. return ret;
  1537. } else if (ret < 0 && ret != -ENODEV) {
  1538. return dev_err_probe(dev, ret,
  1539. "Failed to get and enable vref regulator\n");
  1540. }
  1541. ret = ade9000_setup(st);
  1542. if (ret)
  1543. return ret;
  1544. return devm_iio_device_register(dev, indio_dev);
  1545. };
  1546. static const struct spi_device_id ade9000_id[] = {
  1547. { "ade9000", 0 },
  1548. { }
  1549. };
  1550. MODULE_DEVICE_TABLE(spi, ade9000_id);
  1551. static const struct of_device_id ade9000_of_match[] = {
  1552. { .compatible = "adi,ade9000" },
  1553. { }
  1554. };
  1555. MODULE_DEVICE_TABLE(of, ade9000_of_match);
  1556. static struct spi_driver ade9000_driver = {
  1557. .driver = {
  1558. .name = "ade9000",
  1559. .of_match_table = ade9000_of_match,
  1560. },
  1561. .probe = ade9000_probe,
  1562. .id_table = ade9000_id,
  1563. };
  1564. module_spi_driver(ade9000_driver);
  1565. MODULE_AUTHOR("Antoniu Miclaus <antoniu.miclaus@analog.com>");
  1566. MODULE_DESCRIPTION("Analog Devices ADE9000");
  1567. MODULE_LICENSE("GPL");