mn88443x.c source code [linux/drivers/media/dvb-frontends/mn88443x.c]

1	// SPDX-License-Identifier: GPL-2.0
2	//
3	// Socionext MN88443x series demodulator driver for ISDB-S/ISDB-T.
4	//
5	// Copyright (c) 2018 Socionext Inc.
6
7	#include <linux/bitfield.h>
8	#include <linux/clk.h>
9	#include <linux/delay.h>
10	#include <linux/gpio/consumer.h>
11	#include <linux/of.h>
12	#include <linux/regmap.h>
13	#include <linux/int_log.h>
14
15	#include "mn88443x.h"
16
17	/ ISDB-S registers /
18	#define ATSIDU_S 0x2f
19	#define ATSIDL_S 0x30
20	#define TSSET_S 0x31
21	#define AGCREAD_S 0x5a
22	#define CPMON1_S 0x5e
23	#define CPMON1_S_FSYNC BIT(5)
24	#define CPMON1_S_ERRMON BIT(4)
25	#define CPMON1_S_SIGOFF BIT(3)
26	#define CPMON1_S_W2LOCK BIT(2)
27	#define CPMON1_S_W1LOCK BIT(1)
28	#define CPMON1_S_DW1LOCK BIT(0)
29	#define TRMON_S 0x60
30	#define BERCNFLG_S 0x68
31	#define BERCNFLG_S_BERVRDY BIT(5)
32	#define BERCNFLG_S_BERVCHK BIT(4)
33	#define BERCNFLG_S_BERDRDY BIT(3)
34	#define BERCNFLG_S_BERDCHK BIT(2)
35	#define CNRDXU_S 0x69
36	#define CNRDXL_S 0x6a
37	#define CNRDYU_S 0x6b
38	#define CNRDYL_S 0x6c
39	#define BERVRDU_S 0x71
40	#define BERVRDL_S 0x72
41	#define DOSET1_S 0x73
42
43	/ Primary ISDB-T /
44	#define PLLASET1 0x00
45	#define PLLASET2 0x01
46	#define PLLBSET1 0x02
47	#define PLLBSET2 0x03
48	#define PLLSET 0x04
49	#define OUTCSET 0x08
50	#define OUTCSET_CHDRV_8MA 0xff
51	#define OUTCSET_CHDRV_4MA 0x00
52	#define PLDWSET 0x09
53	#define PLDWSET_NORMAL 0x00
54	#define PLDWSET_PULLDOWN 0xff
55	#define HIZSET1 0x0a
56	#define HIZSET2 0x0b
57
58	/ Secondary ISDB-T (for MN884434 only) /
59	#define RCVSET 0x00
60	#define TSSET1_M 0x01
61	#define TSSET2_M 0x02
62	#define TSSET3_M 0x03
63	#define INTACSET 0x08
64	#define HIZSET3 0x0b
65
66	/ ISDB-T registers /
67	#define TSSET1 0x05
68	#define TSSET1_TSASEL_MASK GENMASK(4, 3)
69	#define TSSET1_TSASEL_ISDBT (0x0 << 3)
70	#define TSSET1_TSASEL_ISDBS (0x1 << 3)
71	#define TSSET1_TSASEL_NONE (0x2 << 3)
72	#define TSSET1_TSBSEL_MASK GENMASK(2, 1)
73	#define TSSET1_TSBSEL_ISDBS (0x0 << 1)
74	#define TSSET1_TSBSEL_ISDBT (0x1 << 1)
75	#define TSSET1_TSBSEL_NONE (0x2 << 1)
76	#define TSSET2 0x06
77	#define TSSET3 0x07
78	#define TSSET3_INTASEL_MASK GENMASK(7, 6)
79	#define TSSET3_INTASEL_T (0x0 << 6)
80	#define TSSET3_INTASEL_S (0x1 << 6)
81	#define TSSET3_INTASEL_NONE (0x2 << 6)
82	#define TSSET3_INTBSEL_MASK GENMASK(5, 4)
83	#define TSSET3_INTBSEL_S (0x0 << 4)
84	#define TSSET3_INTBSEL_T (0x1 << 4)
85	#define TSSET3_INTBSEL_NONE (0x2 << 4)
86	#define OUTSET2 0x0d
87	#define PWDSET 0x0f
88	#define PWDSET_OFDMPD_MASK GENMASK(3, 2)
89	#define PWDSET_OFDMPD_DOWN BIT(3)
90	#define PWDSET_PSKPD_MASK GENMASK(1, 0)
91	#define PWDSET_PSKPD_DOWN BIT(1)
92	#define CLKSET1_T 0x11
93	#define MDSET_T 0x13
94	#define MDSET_T_MDAUTO_MASK GENMASK(7, 4)
95	#define MDSET_T_MDAUTO_AUTO (0xf << 4)
96	#define MDSET_T_MDAUTO_MANUAL (0x0 << 4)
97	#define MDSET_T_FFTS_MASK GENMASK(3, 2)
98	#define MDSET_T_FFTS_MODE1 (0x0 << 2)
99	#define MDSET_T_FFTS_MODE2 (0x1 << 2)
100	#define MDSET_T_FFTS_MODE3 (0x2 << 2)
101	#define MDSET_T_GI_MASK GENMASK(1, 0)
102	#define MDSET_T_GI_1_32 (0x0 << 0)
103	#define MDSET_T_GI_1_16 (0x1 << 0)
104	#define MDSET_T_GI_1_8 (0x2 << 0)
105	#define MDSET_T_GI_1_4 (0x3 << 0)
106	#define MDASET_T 0x14
107	#define ADCSET1_T 0x20
108	#define ADCSET1_T_REFSEL_MASK GENMASK(1, 0)
109	#define ADCSET1_T_REFSEL_2V (0x3 << 0)
110	#define ADCSET1_T_REFSEL_1_5V (0x2 << 0)
111	#define ADCSET1_T_REFSEL_1V (0x1 << 0)
112	#define NCOFREQU_T 0x24
113	#define NCOFREQM_T 0x25
114	#define NCOFREQL_T 0x26
115	#define FADU_T 0x27
116	#define FADM_T 0x28
117	#define FADL_T 0x29
118	#define AGCSET2_T 0x2c
119	#define AGCSET2_T_IFPOLINV_INC BIT(0)
120	#define AGCSET2_T_RFPOLINV_INC BIT(1)
121	#define AGCV3_T 0x3e
122	#define MDRD_T 0xa2
123	#define MDRD_T_SEGID_MASK GENMASK(5, 4)
124	#define MDRD_T_SEGID_13 (0x0 << 4)
125	#define MDRD_T_SEGID_1 (0x1 << 4)
126	#define MDRD_T_SEGID_3 (0x2 << 4)
127	#define MDRD_T_FFTS_MASK GENMASK(3, 2)
128	#define MDRD_T_FFTS_MODE1 (0x0 << 2)
129	#define MDRD_T_FFTS_MODE2 (0x1 << 2)
130	#define MDRD_T_FFTS_MODE3 (0x2 << 2)
131	#define MDRD_T_GI_MASK GENMASK(1, 0)
132	#define MDRD_T_GI_1_32 (0x0 << 0)
133	#define MDRD_T_GI_1_16 (0x1 << 0)
134	#define MDRD_T_GI_1_8 (0x2 << 0)
135	#define MDRD_T_GI_1_4 (0x3 << 0)
136	#define SSEQRD_T 0xa3
137	#define SSEQRD_T_SSEQSTRD_MASK GENMASK(3, 0)
138	#define SSEQRD_T_SSEQSTRD_RESET (0x0 << 0)
139	#define SSEQRD_T_SSEQSTRD_TUNING (0x1 << 0)
140	#define SSEQRD_T_SSEQSTRD_AGC (0x2 << 0)
141	#define SSEQRD_T_SSEQSTRD_SEARCH (0x3 << 0)
142	#define SSEQRD_T_SSEQSTRD_CLOCK_SYNC (0x4 << 0)
143	#define SSEQRD_T_SSEQSTRD_FREQ_SYNC (0x8 << 0)
144	#define SSEQRD_T_SSEQSTRD_FRAME_SYNC (0x9 << 0)
145	#define SSEQRD_T_SSEQSTRD_SYNC (0xa << 0)
146	#define SSEQRD_T_SSEQSTRD_LOCK (0xb << 0)
147	#define AGCRDU_T 0xa8
148	#define AGCRDL_T 0xa9
149	#define CNRDU_T 0xbe
150	#define CNRDL_T 0xbf
151	#define BERFLG_T 0xc0
152	#define BERFLG_T_BERDRDY BIT(7)
153	#define BERFLG_T_BERDCHK BIT(6)
154	#define BERFLG_T_BERVRDYA BIT(5)
155	#define BERFLG_T_BERVCHKA BIT(4)
156	#define BERFLG_T_BERVRDYB BIT(3)
157	#define BERFLG_T_BERVCHKB BIT(2)
158	#define BERFLG_T_BERVRDYC BIT(1)
159	#define BERFLG_T_BERVCHKC BIT(0)
160	#define BERRDU_T 0xc1
161	#define BERRDM_T 0xc2
162	#define BERRDL_T 0xc3
163	#define BERLENRDU_T 0xc4
164	#define BERLENRDL_T 0xc5
165	#define ERRFLG_T 0xc6
166	#define ERRFLG_T_BERDOVF BIT(7)
167	#define ERRFLG_T_BERVOVFA BIT(6)
168	#define ERRFLG_T_BERVOVFB BIT(5)
169	#define ERRFLG_T_BERVOVFC BIT(4)
170	#define ERRFLG_T_NERRFA BIT(3)
171	#define ERRFLG_T_NERRFB BIT(2)
172	#define ERRFLG_T_NERRFC BIT(1)
173	#define ERRFLG_T_NERRF BIT(0)
174	#define DOSET1_T 0xcf
175
176	#define CLK_LOW 4000000
177	#define CLK_DIRECT 20200000
178	#define CLK_MAX 25410000
179
180	#define S_T_FREQ 8126984 /* 512 / 63 MHz */
181
182	struct mn88443x_spec {
183	bool primary;
184	};
185
186	struct mn88443x_priv {
187	const struct mn88443x_spec *spec;
188
189	struct dvb_frontend fe;
190	struct clk *mclk;
191	struct gpio_desc *reset_gpio;
192	u32 clk_freq;
193	u32 if_freq;
194
195	/ Common /
196	bool use_clkbuf;
197
198	/ ISDB-S /
199	struct i2c_client *client_s;
200	struct regmap *regmap_s;
201
202	/ ISDB-T /
203	struct i2c_client *client_t;
204	struct regmap *regmap_t;
205	};
206
207	static int mn88443x_cmn_power_on(struct mn88443x_priv *chip)
208	{
209	struct device *dev = &chip->client_s->dev;
210	struct regmap *r_t = chip->regmap_t;
211	int ret;
212
213	ret = clk_prepare_enable(clk: chip->mclk);
214	if (ret) {
215	dev_err(dev, "Failed to prepare and enable mclk: %d\n",
216	ret);
217	return ret;
218	}
219
220	gpiod_set_value_cansleep(desc: chip->reset_gpio, value: `1`);
221	usleep_range(min: `100`, max: `1000`);
222	gpiod_set_value_cansleep(desc: chip->reset_gpio, value: `0`);
223
224	if (chip->spec->primary) {
225	regmap_write(map: r_t, OUTCSET, OUTCSET_CHDRV_8MA);
226	regmap_write(map: r_t, PLDWSET, PLDWSET_NORMAL);
227	regmap_write(map: r_t, HIZSET1, val: `0x80`);
228	regmap_write(map: r_t, HIZSET2, val: `0xe0`);
229	} else {
230	regmap_write(map: r_t, HIZSET3, val: `0x8f`);
231	}
232
233	return `0`;
234	}
235
236	static void mn88443x_cmn_power_off(struct mn88443x_priv *chip)
237	{
238	gpiod_set_value_cansleep(desc: chip->reset_gpio, value: `1`);
239
240	clk_disable_unprepare(clk: chip->mclk);
241	}
242
243	static void mn88443x_s_sleep(struct mn88443x_priv *chip)
244	{
245	struct regmap *r_t = chip->regmap_t;
246
247	regmap_update_bits(map: r_t, PWDSET, PWDSET_PSKPD_MASK,
248	PWDSET_PSKPD_DOWN);
249	}
250
251	static void mn88443x_s_wake(struct mn88443x_priv *chip)
252	{
253	struct regmap *r_t = chip->regmap_t;
254
255	regmap_update_bits(map: r_t, PWDSET, PWDSET_PSKPD_MASK, val: `0`);
256	}
257
258	static void mn88443x_s_tune(struct mn88443x_priv *chip,
259	struct dtv_frontend_properties *c)
260	{
261	struct regmap *r_s = chip->regmap_s;
262
263	regmap_write(map: r_s, ATSIDU_S, val: c->stream_id >> `8`);
264	regmap_write(map: r_s, ATSIDL_S, val: c->stream_id);
265	regmap_write(map: r_s, TSSET_S, val: `0`);
266	}
267
268	static int mn88443x_s_read_status(struct mn88443x_priv *chip,
269	struct dtv_frontend_properties *c,
270	enum fe_status *status)
271	{
272	struct regmap *r_s = chip->regmap_s;
273	u32 cpmon, tmpu, tmpl, flg;
274	u64 tmp;
275
276	/ Sync detection /
277	regmap_read(map: r_s, CPMON1_S, val: &cpmon);
278
279	*status = `0`;
280	if (cpmon & CPMON1_S_FSYNC)
281	*status \|= FE_HAS_VITERBI \| FE_HAS_SYNC \| FE_HAS_LOCK;
282	if (cpmon & CPMON1_S_W2LOCK)
283	*status \|= FE_HAS_SIGNAL \| FE_HAS_CARRIER;
284
285	/ Signal strength /
286	c->strength.stat[`0`].scale = FE_SCALE_NOT_AVAILABLE;
287
288	if (*status & FE_HAS_SIGNAL) {
289	u32 agc;
290
291	regmap_read(map: r_s, AGCREAD_S, val: &tmpu);
292	agc = tmpu << `8`;
293
294	c->strength.len = `1`;
295	c->strength.stat[`0`].scale = FE_SCALE_RELATIVE;
296	c->strength.stat[`0`].uvalue = agc;
297	}
298
299	/ C/N rate /
300	c->cnr.stat[`0`].scale = FE_SCALE_NOT_AVAILABLE;
301
302	if (*status & FE_HAS_VITERBI) {
303	u32 cnr = `0`, x, y, d;
304	u64 d_3 = `0`;
305
306	regmap_read(map: r_s, CNRDXU_S, val: &tmpu);
307	regmap_read(map: r_s, CNRDXL_S, val: &tmpl);
308	x = (tmpu << `8`) \| tmpl;
309	regmap_read(map: r_s, CNRDYU_S, val: &tmpu);
310	regmap_read(map: r_s, CNRDYL_S, val: &tmpl);
311	y = (tmpu << `8`) \| tmpl;
312
313	/ CNR[dB]: 10 * log10(D) - 30.74 / D^3 - 3 /
314	/ D = x^2 / (2^15 * y - x^2) /
315	d = (y << `15`) - x * x;
316	if (d > `0`) {
317	/ (2^4 * D)^3 = 2^12 * D^3 /
318	/ 3.074 * 2^(12 + 24) = 211243671486 /
319	d_3 = div_u64(dividend: `16` * x * x, divisor: d);
320	d_3 = d_3 * d_3 * d_3;
321	if (d_3)
322	d_3 = div_u64(dividend: `211243671486ULL`, divisor: d_3);
323	}
324
325	if (d_3) {
326	/ 0.3 * 2^24 = 5033164 /
327	tmp = (s64)`2` * intlog10(value: x) - intlog10(abs(d)) - d_3
328	- `5033164`;
329	cnr = div_u64(dividend: tmp * `10000`, divisor: `1` << `24`);
330	}
331
332	if (cnr) {
333	c->cnr.len = `1`;
334	c->cnr.stat[`0`].scale = FE_SCALE_DECIBEL;
335	c->cnr.stat[`0`].uvalue = cnr;
336	}
337	}
338
339	/ BER /
340	c->post_bit_error.stat[`0`].scale = FE_SCALE_NOT_AVAILABLE;
341	c->post_bit_count.stat[`0`].scale = FE_SCALE_NOT_AVAILABLE;
342
343	regmap_read(map: r_s, BERCNFLG_S, val: &flg);
344
345	if ((*status & FE_HAS_VITERBI) && (flg & BERCNFLG_S_BERVRDY)) {
346	u32 bit_err, bit_cnt;
347
348	regmap_read(map: r_s, BERVRDU_S, val: &tmpu);
349	regmap_read(map: r_s, BERVRDL_S, val: &tmpl);
350	bit_err = (tmpu << `8`) \| tmpl;
351	bit_cnt = (`1` << `13`) * `204`;
352
353	if (bit_cnt) {
354	c->post_bit_error.len = `1`;
355	c->post_bit_error.stat[`0`].scale = FE_SCALE_COUNTER;
356	c->post_bit_error.stat[`0`].uvalue = bit_err;
357	c->post_bit_count.len = `1`;
358	c->post_bit_count.stat[`0`].scale = FE_SCALE_COUNTER;
359	c->post_bit_count.stat[`0`].uvalue = bit_cnt;
360	}
361	}
362
363	return `0`;
364	}
365
366	static void mn88443x_t_sleep(struct mn88443x_priv *chip)
367	{
368	struct regmap *r_t = chip->regmap_t;
369
370	regmap_update_bits(map: r_t, PWDSET, PWDSET_OFDMPD_MASK,
371	PWDSET_OFDMPD_DOWN);
372	}
373
374	static void mn88443x_t_wake(struct mn88443x_priv *chip)
375	{
376	struct regmap *r_t = chip->regmap_t;
377
378	regmap_update_bits(map: r_t, PWDSET, PWDSET_OFDMPD_MASK, val: `0`);
379	}
380
381	static bool mn88443x_t_is_valid_clk(u32 adckt, u32 if_freq)
382	{
383	if (if_freq == DIRECT_IF_57MHZ) {
384	if (adckt >= CLK_DIRECT && adckt <= `21000000`)
385	return true;
386	if (adckt >= `25300000` && adckt <= CLK_MAX)
387	return true;
388	} else if (if_freq == DIRECT_IF_44MHZ) {
389	if (adckt >= `25000000` && adckt <= CLK_MAX)
390	return true;
391	} else if (if_freq >= LOW_IF_4MHZ && if_freq < DIRECT_IF_44MHZ) {
392	if (adckt >= CLK_DIRECT && adckt <= CLK_MAX)
393	return true;
394	}
395
396	return false;
397	}
398
399	static int mn88443x_t_set_freq(struct mn88443x_priv *chip)
400	{
401	struct device *dev = &chip->client_s->dev;
402	struct regmap *r_t = chip->regmap_t;
403	s64 adckt, nco, ad_t;
404	u32 m, v;
405
406	/ Clock buffer (but not supported) or XTAL /
407	if (chip->clk_freq >= CLK_LOW && chip->clk_freq < CLK_DIRECT) {
408	chip->use_clkbuf = true;
409	regmap_write(map: r_t, CLKSET1_T, val: `0x07`);
410
411	adckt = `0`;
412	} else {
413	chip->use_clkbuf = false;
414	regmap_write(map: r_t, CLKSET1_T, val: `0x00`);
415
416	adckt = chip->clk_freq;
417	}
418	if (!mn88443x_t_is_valid_clk(adckt, if_freq: chip->if_freq)) {
419	dev_err(dev, "Invalid clock, CLK:%d, ADCKT:%lld, IF:%d\n",
420	chip->clk_freq, adckt, chip->if_freq);
421	return -EINVAL;
422	}
423
424	/ Direct IF or Low IF /
425	if (chip->if_freq == DIRECT_IF_57MHZ \|\|
426	chip->if_freq == DIRECT_IF_44MHZ)
427	nco = adckt * `2` - chip->if_freq;
428	else
429	nco = -((s64)chip->if_freq);
430	nco = div_s64(dividend: nco << `24`, divisor: adckt);
431	ad_t = div_s64(dividend: adckt << `22`, S_T_FREQ);
432
433	regmap_write(map: r_t, NCOFREQU_T, val: nco >> `16`);
434	regmap_write(map: r_t, NCOFREQM_T, val: nco >> `8`);
435	regmap_write(map: r_t, NCOFREQL_T, val: nco);
436	regmap_write(map: r_t, FADU_T, val: ad_t >> `16`);
437	regmap_write(map: r_t, FADM_T, val: ad_t >> `8`);
438	regmap_write(map: r_t, FADL_T, val: ad_t);
439
440	/ Level of IF /
441	m = ADCSET1_T_REFSEL_MASK;
442	v = ADCSET1_T_REFSEL_1_5V;
443	regmap_update_bits(map: r_t, ADCSET1_T, mask: m, val: v);
444
445	/ Polarity of AGC /
446	v = AGCSET2_T_IFPOLINV_INC \| AGCSET2_T_RFPOLINV_INC;
447	regmap_update_bits(map: r_t, AGCSET2_T, mask: v, val: v);
448
449	/ Lower output level of AGC /
450	regmap_write(map: r_t, AGCV3_T, val: `0x00`);
451
452	regmap_write(map: r_t, MDSET_T, val: `0xfa`);
453
454	return `0`;
455	}
456
457	static void mn88443x_t_tune(struct mn88443x_priv *chip,
458	struct dtv_frontend_properties *c)
459	{
460	struct regmap *r_t = chip->regmap_t;
461	u32 m, v;
462
463	m = MDSET_T_MDAUTO_MASK \| MDSET_T_FFTS_MASK \| MDSET_T_GI_MASK;
464	v = MDSET_T_MDAUTO_AUTO \| MDSET_T_FFTS_MODE3 \| MDSET_T_GI_1_8;
465	regmap_update_bits(map: r_t, MDSET_T, mask: m, val: v);
466
467	regmap_write(map: r_t, MDASET_T, val: `0`);
468	}
469
470	static int mn88443x_t_read_status(struct mn88443x_priv *chip,
471	struct dtv_frontend_properties *c,
472	enum fe_status *status)
473	{
474	struct regmap *r_t = chip->regmap_t;
475	u32 seqrd, st, flg, tmpu, tmpm, tmpl;
476	u64 tmp;
477
478	/ Sync detection /
479	regmap_read(map: r_t, SSEQRD_T, val: &seqrd);
480	st = seqrd & SSEQRD_T_SSEQSTRD_MASK;
481
482	*status = `0`;
483	if (st >= SSEQRD_T_SSEQSTRD_SYNC)
484	*status \|= FE_HAS_VITERBI \| FE_HAS_SYNC \| FE_HAS_LOCK;
485	if (st >= SSEQRD_T_SSEQSTRD_FRAME_SYNC)
486	*status \|= FE_HAS_SIGNAL \| FE_HAS_CARRIER;
487
488	/ Signal strength /
489	c->strength.stat[`0`].scale = FE_SCALE_NOT_AVAILABLE;
490
491	if (*status & FE_HAS_SIGNAL) {
492	u32 agc;
493
494	regmap_read(map: r_t, AGCRDU_T, val: &tmpu);
495	regmap_read(map: r_t, AGCRDL_T, val: &tmpl);
496	agc = (tmpu << `8`) \| tmpl;
497
498	c->strength.len = `1`;
499	c->strength.stat[`0`].scale = FE_SCALE_RELATIVE;
500	c->strength.stat[`0`].uvalue = agc;
501	}
502
503	/ C/N rate /
504	c->cnr.stat[`0`].scale = FE_SCALE_NOT_AVAILABLE;
505
506	if (*status & FE_HAS_VITERBI) {
507	u32 cnr;
508
509	regmap_read(map: r_t, CNRDU_T, val: &tmpu);
510	regmap_read(map: r_t, CNRDL_T, val: &tmpl);
511
512	if (tmpu \|\| tmpl) {
513	/ CNR[dB]: 10 * (log10(65536 / value) + 0.2) /
514	/ intlog10(65536) = 80807124, 0.2 * 2^24 = 3355443 /
515	tmp = (u64)`80807124` - intlog10(value: (tmpu << `8`) \| tmpl)
516	+ `3355443`;
517	cnr = div_u64(dividend: tmp * `10000`, divisor: `1` << `24`);
518	} else {
519	cnr = `0`;
520	}
521
522	c->cnr.len = `1`;
523	c->cnr.stat[`0`].scale = FE_SCALE_DECIBEL;
524	c->cnr.stat[`0`].uvalue = cnr;
525	}
526
527	/ BER /
528	c->post_bit_error.stat[`0`].scale = FE_SCALE_NOT_AVAILABLE;
529	c->post_bit_count.stat[`0`].scale = FE_SCALE_NOT_AVAILABLE;
530
531	regmap_read(map: r_t, BERFLG_T, val: &flg);
532
533	if ((*status & FE_HAS_VITERBI) && (flg & BERFLG_T_BERVRDYA)) {
534	u32 bit_err, bit_cnt;
535
536	regmap_read(map: r_t, BERRDU_T, val: &tmpu);
537	regmap_read(map: r_t, BERRDM_T, val: &tmpm);
538	regmap_read(map: r_t, BERRDL_T, val: &tmpl);
539	bit_err = (tmpu << `16`) \| (tmpm << `8`) \| tmpl;
540
541	regmap_read(map: r_t, BERLENRDU_T, val: &tmpu);
542	regmap_read(map: r_t, BERLENRDL_T, val: &tmpl);
543	bit_cnt = ((tmpu << `8`) \| tmpl) * `203` * `8`;
544
545	if (bit_cnt) {
546	c->post_bit_error.len = `1`;
547	c->post_bit_error.stat[`0`].scale = FE_SCALE_COUNTER;
548	c->post_bit_error.stat[`0`].uvalue = bit_err;
549	c->post_bit_count.len = `1`;
550	c->post_bit_count.stat[`0`].scale = FE_SCALE_COUNTER;
551	c->post_bit_count.stat[`0`].uvalue = bit_cnt;
552	}
553	}
554
555	return `0`;
556	}
557
558	static int mn88443x_sleep(struct dvb_frontend *fe)
559	{
560	struct mn88443x_priv *chip = fe->demodulator_priv;
561
562	mn88443x_s_sleep(chip);
563	mn88443x_t_sleep(chip);
564
565	return `0`;
566	}
567
568	static int mn88443x_set_frontend(struct dvb_frontend *fe)
569	{
570	struct mn88443x_priv *chip = fe->demodulator_priv;
571	struct dtv_frontend_properties *c = &fe->dtv_property_cache;
572	struct regmap *r_s = chip->regmap_s;
573	struct regmap *r_t = chip->regmap_t;
574	u8 tssel = `0`, intsel = `0`;
575
576	if (c->delivery_system == SYS_ISDBS) {
577	mn88443x_s_wake(chip);
578	mn88443x_t_sleep(chip);
579
580	tssel = TSSET1_TSASEL_ISDBS;
581	intsel = TSSET3_INTASEL_S;
582	} else if (c->delivery_system == SYS_ISDBT) {
583	mn88443x_s_sleep(chip);
584	mn88443x_t_wake(chip);
585
586	mn88443x_t_set_freq(chip);
587
588	tssel = TSSET1_TSASEL_ISDBT;
589	intsel = TSSET3_INTASEL_T;
590	}
591
592	regmap_update_bits(map: r_t, TSSET1,
593	TSSET1_TSASEL_MASK \| TSSET1_TSBSEL_MASK,
594	val: tssel \| TSSET1_TSBSEL_NONE);
595	regmap_write(map: r_t, TSSET2, val: `0`);
596	regmap_update_bits(map: r_t, TSSET3,
597	TSSET3_INTASEL_MASK \| TSSET3_INTBSEL_MASK,
598	val: intsel \| TSSET3_INTBSEL_NONE);
599
600	regmap_write(map: r_t, DOSET1_T, val: `0x95`);
601	regmap_write(map: r_s, DOSET1_S, val: `0x80`);
602
603	if (c->delivery_system == SYS_ISDBS)
604	mn88443x_s_tune(chip, c);
605	else if (c->delivery_system == SYS_ISDBT)
606	mn88443x_t_tune(chip, c);
607
608	if (fe->ops.tuner_ops.set_params) {
609	if (fe->ops.i2c_gate_ctrl)
610	fe->ops.i2c_gate_ctrl(fe, `1`);
611	fe->ops.tuner_ops.set_params(fe);
612	if (fe->ops.i2c_gate_ctrl)
613	fe->ops.i2c_gate_ctrl(fe, `0`);
614	}
615
616	return `0`;
617	}
618
619	static int mn88443x_get_tune_settings(struct dvb_frontend *fe,
620	struct dvb_frontend_tune_settings *s)
621	{
622	struct dtv_frontend_properties *c = &fe->dtv_property_cache;
623
624	s->min_delay_ms = `850`;
625
626	if (c->delivery_system == SYS_ISDBS) {
627	s->max_drift = `30000` * `2` + `1`;
628	s->step_size = `30000`;
629	} else if (c->delivery_system == SYS_ISDBT) {
630	s->max_drift = `142857` * `2` + `1`;
631	s->step_size = `142857` * `2`;
632	}
633
634	return `0`;
635	}
636
637	static int mn88443x_read_status(struct dvb_frontend fe, enum* fe_status *status)
638	{
639	struct mn88443x_priv *chip = fe->demodulator_priv;
640	struct dtv_frontend_properties *c = &fe->dtv_property_cache;
641
642	if (c->delivery_system == SYS_ISDBS)
643	return mn88443x_s_read_status(chip, c, status);
644
645	if (c->delivery_system == SYS_ISDBT)
646	return mn88443x_t_read_status(chip, c, status);
647
648	return -EINVAL;
649	}
650
651	static const struct dvb_frontend_ops mn88443x_ops = {
652	.delsys = { SYS_ISDBS, SYS_ISDBT },
653	.info = {
654	.name = "Socionext MN88443x",
655	.frequency_min_hz = `470` * MHz,
656	.frequency_max_hz = `2071` * MHz,
657	.symbol_rate_min = `28860000`,
658	.symbol_rate_max = `28860000`,
659	.caps = FE_CAN_INVERSION_AUTO \| FE_CAN_FEC_AUTO \|
660	FE_CAN_QAM_AUTO \| FE_CAN_TRANSMISSION_MODE_AUTO \|
661	FE_CAN_GUARD_INTERVAL_AUTO \| FE_CAN_HIERARCHY_AUTO,
662	},
663
664	.sleep = mn88443x_sleep,
665	.set_frontend = mn88443x_set_frontend,
666	.get_tune_settings = mn88443x_get_tune_settings,
667	.read_status = mn88443x_read_status,
668	};
669
670	static const struct regmap_config regmap_config = {
671	.reg_bits = `8`,
672	.val_bits = `8`,
673	.cache_type = REGCACHE_NONE,
674	};
675
676	static int mn88443x_probe(struct i2c_client *client)
677	{
678	const struct i2c_device_id *id = i2c_client_get_device_id(client);
679	struct mn88443x_config *conf = client->dev.platform_data;
680	struct mn88443x_priv *chip;
681	struct device *dev = &client->dev;
682	int ret;
683
684	chip = devm_kzalloc(dev, size: sizeof(*chip), GFP_KERNEL);
685	if (!chip)
686	return -ENOMEM;
687
688	if (dev->of_node)
689	chip->spec = of_device_get_match_data(dev);
690	else
691	chip->spec = (struct mn88443x_spec *)id->driver_data;
692	if (!chip->spec)
693	return -EINVAL;
694
695	chip->mclk = devm_clk_get(dev, id: "mclk");
696	if (IS_ERR(ptr: chip->mclk) && !conf) {
697	dev_err(dev, "Failed to request mclk: %ld\n",
698	PTR_ERR(chip->mclk));
699	return PTR_ERR(ptr: chip->mclk);
700	}
701
702	ret = of_property_read_u32(np: dev->of_node, propname: "if-frequency",
703	out_value: &chip->if_freq);
704	if (ret && !conf) {
705	dev_err(dev, "Failed to load IF frequency: %d.\n", ret);
706	return ret;
707	}
708
709	chip->reset_gpio = devm_gpiod_get_optional(dev, con_id: "reset",
710	flags: GPIOD_OUT_HIGH);
711	if (IS_ERR(ptr: chip->reset_gpio)) {
712	dev_err(dev, "Failed to request reset_gpio: %ld\n",
713	PTR_ERR(chip->reset_gpio));
714	return PTR_ERR(ptr: chip->reset_gpio);
715	}
716
717	if (conf) {
718	chip->mclk = conf->mclk;
719	chip->if_freq = conf->if_freq;
720	chip->reset_gpio = conf->reset_gpio;
721
722	*conf->fe = &chip->fe;
723	}
724
725	chip->client_s = client;
726	chip->regmap_s = devm_regmap_init_i2c(chip->client_s, &regmap_config);
727	if (IS_ERR(ptr: chip->regmap_s))
728	return PTR_ERR(ptr: chip->regmap_s);
729
730	/*
731	* Chip has two I2C addresses for each satellite/terrestrial system.
732	* ISDB-T uses address ISDB-S + 4, so we register a dummy client.
733	*/
734	chip->client_t = i2c_new_dummy_device(adapter: client->adapter, address: client->addr + `4`);
735	if (IS_ERR(ptr: chip->client_t))
736	return PTR_ERR(ptr: chip->client_t);
737
738	chip->regmap_t = devm_regmap_init_i2c(chip->client_t, &regmap_config);
739	if (IS_ERR(ptr: chip->regmap_t)) {
740	ret = PTR_ERR(ptr: chip->regmap_t);
741	goto err_i2c_t;
742	}
743
744	chip->clk_freq = clk_get_rate(clk: chip->mclk);
745
746	memcpy(&chip->fe.ops, &mn88443x_ops, sizeof(mn88443x_ops));
747	chip->fe.demodulator_priv = chip;
748	i2c_set_clientdata(client, data: chip);
749
750	ret = mn88443x_cmn_power_on(chip);
751	if (ret)
752	goto err_i2c_t;
753
754	mn88443x_s_sleep(chip);
755	mn88443x_t_sleep(chip);
756
757	return `0`;
758
759	err_i2c_t:
760	i2c_unregister_device(client: chip->client_t);
761
762	return ret;
763	}
764
765	static void mn88443x_remove(struct i2c_client *client)
766	{
767	struct mn88443x_priv *chip = i2c_get_clientdata(client);
768
769	mn88443x_cmn_power_off(chip);
770
771	i2c_unregister_device(client: chip->client_t);
772	}
773
774	static const struct mn88443x_spec mn88443x_spec_pri = {
775	.primary = true,
776	};
777
778	static const struct mn88443x_spec mn88443x_spec_sec = {
779	.primary = false,
780	};
781
782	static const struct of_device_id mn88443x_of_match[] = {
783	{ .compatible = "socionext,mn884433", .data = &mn88443x_spec_pri, },
784	{ .compatible = "socionext,mn884434-0", .data = &mn88443x_spec_pri, },
785	{ .compatible = "socionext,mn884434-1", .data = &mn88443x_spec_sec, },
786	{}
787	};
788	MODULE_DEVICE_TABLE(of, mn88443x_of_match);
789
790	static const struct i2c_device_id mn88443x_i2c_id[] = {
791	{ "mn884433", (kernel_ulong_t)&mn88443x_spec_pri },
792	{ "mn884434-0", (kernel_ulong_t)&mn88443x_spec_pri },
793	{ "mn884434-1", (kernel_ulong_t)&mn88443x_spec_sec },
794	{}
795	};
796	MODULE_DEVICE_TABLE(i2c, mn88443x_i2c_id);
797
798	static struct i2c_driver mn88443x_driver = {
799	.driver = {
800	.name = "mn88443x",
801	.of_match_table = mn88443x_of_match,
802	},
803	.probe = mn88443x_probe,
804	.remove = mn88443x_remove,
805	.id_table = mn88443x_i2c_id,
806	};
807
808	module_i2c_driver(mn88443x_driver);
809
810	MODULE_AUTHOR("Katsuhiro Suzuki <suzuki.katsuhiro@socionext.com>");
811	MODULE_DESCRIPTION("Socionext MN88443x series demodulator driver.");
812	MODULE_LICENSE("GPL v2");
813

source code of linux/drivers/media/dvb-frontends/mn88443x.c