1	/*
2	* Driver for simple i2c audio chips.
3	*
4	* Copyright (c) 2000 Gerd Knorr
5	* based on code by:
6	* Eric Sandeen (eric_sandeen@bigfoot.com)
7	* Steve VanDeBogart (vandebo@uclink.berkeley.edu)
8	* Greg Alexander (galexand@acm.org)
9	*
10	* For the TDA9875 part:
11	* Copyright (c) 2000 Guillaume Delvit based on Gerd Knorr source
12	* and Eric Sandeen
13	*
14	* Copyright(c) 2005-2008 Mauro Carvalho Chehab
15	* - Some cleanups, code fixes, etc
16	* - Convert it to V4L2 API
17	*
18	* This code is placed under the terms of the GNU General Public License
19	*
20	* OPTIONS:
21	* debug - set to 1 if you'd like to see debug messages
22	*
23	*/
24
25	#include <linux/module.h>
26	#include <linux/kernel.h>
27	#include <linux/sched.h>
28	#include <linux/string.h>
29	#include <linux/timer.h>
30	#include <linux/delay.h>
31	#include <linux/errno.h>
32	#include <linux/slab.h>
33	#include <linux/videodev2.h>
34	#include <linux/i2c.h>
35	#include <linux/init.h>
36	#include <linux/kthread.h>
37	#include <linux/freezer.h>
38
39	#include <media/i2c/tvaudio.h>
40	#include <media/v4l2-device.h>
41	#include <media/v4l2-ctrls.h>
42
43	/* ---------------------------------------------------------------------- */
44	/* insmod args */
45
46	static int debug; /* insmod parameter */
47	module_param(debug, int, 0644);
48
49	MODULE_DESCRIPTION("device driver for various i2c TV sound decoder / audiomux chips");
50	MODULE_AUTHOR("Eric Sandeen, Steve VanDeBogart, Greg Alexander, Gerd Knorr");
51	MODULE_LICENSE("GPL");
52
53	#define UNSET (-1U)
54
55	/* ---------------------------------------------------------------------- */
56	/* our structs */
57
58	#define MAXREGS 256
59
60	struct CHIPSTATE;
61	typedef int (*getvalue)(int);
62	typedef int (*checkit)(struct CHIPSTATE*);
63	typedef int (*initialize)(struct CHIPSTATE*);
64	typedef int (*getrxsubchans)(struct CHIPSTATE *);
65	typedef void (*setaudmode)(struct CHIPSTATE*, int mode);
66
67	/* i2c command */
68	typedef struct AUDIOCMD {
69	int count; /* # of bytes to send */
70	unsigned char bytes[MAXREGS+1]; /* addr, data, data, ... */
71	} audiocmd;
72
73	/* chip description */
74	struct CHIPDESC {
75	char *name; /* chip name */
76	int addr_lo, addr_hi; /* i2c address range */
77	int registers; /* # of registers */
78
79	int *insmodopt;
80	checkit checkit;
81	initialize initialize;
82	int flags;
83	#define CHIP_HAS_VOLUME 1
84	#define CHIP_HAS_BASSTREBLE 2
85	#define CHIP_HAS_INPUTSEL 4
86	#define CHIP_NEED_CHECKMODE 8
87
88	/* various i2c command sequences */
89	audiocmd init;
90
91	/* which register has which value */
92	int leftreg, rightreg, treblereg, bassreg;
93
94	/* initialize with (defaults to 65535/32768/32768 */
95	int volinit, trebleinit, bassinit;
96
97	/* functions to convert the values (v4l -> chip) */
98	getvalue volfunc, treblefunc, bassfunc;
99
100	/* get/set mode */
101	getrxsubchans getrxsubchans;
102	setaudmode setaudmode;
103
104	/* input switch register + values for v4l inputs */
105	int inputreg;
106	int inputmap[4];
107	int inputmute;
108	int inputmask;
109	};
110
111	/* current state of the chip */
112	struct CHIPSTATE {
113	struct v4l2_subdev sd;
114	struct v4l2_ctrl_handler hdl;
115	struct {
116	/* volume/balance cluster */
117	struct v4l2_ctrl *volume;
118	struct v4l2_ctrl *balance;
119	};
120
121	/* chip-specific description - should point to
122	an entry at CHIPDESC table */
123	struct CHIPDESC *desc;
124
125	/* shadow register set */
126	audiocmd shadow;
127
128	/* current settings */
129	u16 muted;
130	int prevmode;
131	int radio;
132	int input;
133
134	/* thread */
135	struct task_struct *thread;
136	struct timer_list wt;
137	int audmode;
138	};
139
140	static inline struct CHIPSTATE *to_state(struct v4l2_subdev *sd)
141	{
142	return container_of(sd, struct CHIPSTATE, sd);
143	}
144
145	static inline struct v4l2_subdev *to_sd(struct v4l2_ctrl *ctrl)
146	{
147	return &container_of(ctrl->handler, struct CHIPSTATE, hdl)->sd;
148	}
149
150
151	/* ---------------------------------------------------------------------- */
152	/* i2c I/O functions */
153
154	static int chip_write(struct CHIPSTATE *chip, int subaddr, int val)
155	{
156	struct v4l2_subdev *sd = &chip->sd;
157	struct i2c_client *c = v4l2_get_subdevdata(sd);
158	unsigned char buffer[2];
159	int rc;
160
161	if (subaddr < 0) {
162	v4l2_dbg(1, debug, sd, "chip_write: 0x%x\n", val);
163	chip->shadow.bytes[1] = val;
164	buffer[0] = val;
165	rc = i2c_master_send(client: c, buf: buffer, count: 1);
166	if (rc != 1) {
167	v4l2_warn(sd, "I/O error (write 0x%x)\n", val);
168	if (rc < 0)
169	return rc;
170	return -EIO;
171	}
172	} else {
173	if (subaddr + 1 >= ARRAY_SIZE(chip->shadow.bytes)) {
174	v4l2_info(sd,
175	"Tried to access a non-existent register: %d\n",
176	subaddr);
177	return -EINVAL;
178	}
179
180	v4l2_dbg(1, debug, sd, "chip_write: reg%d=0x%x\n",
181	subaddr, val);
182	chip->shadow.bytes[subaddr+1] = val;
183	buffer[0] = subaddr;
184	buffer[1] = val;
185	rc = i2c_master_send(client: c, buf: buffer, count: 2);
186	if (rc != 2) {
187	v4l2_warn(sd, "I/O error (write reg%d=0x%x)\n",
188	subaddr, val);
189	if (rc < 0)
190	return rc;
191	return -EIO;
192	}
193	}
194	return 0;
195	}
196
197	static int chip_write_masked(struct CHIPSTATE *chip,
198	int subaddr, int val, int mask)
199	{
200	struct v4l2_subdev *sd = &chip->sd;
201
202	if (mask != 0) {
203	if (subaddr < 0) {
204	val = (chip->shadow.bytes[1] & ~mask) | (val & mask);
205	} else {
206	if (subaddr + 1 >= ARRAY_SIZE(chip->shadow.bytes)) {
207	v4l2_info(sd,
208	"Tried to access a non-existent register: %d\n",
209	subaddr);
210	return -EINVAL;
211	}
212
213	val = (chip->shadow.bytes[subaddr+1] & ~mask) | (val & mask);
214	}
215	}
216	return chip_write(chip, subaddr, val);
217	}
218
219	static int chip_read(struct CHIPSTATE *chip)
220	{
221	struct v4l2_subdev *sd = &chip->sd;
222	struct i2c_client *c = v4l2_get_subdevdata(sd);
223	unsigned char buffer;
224	int rc;
225
226	rc = i2c_master_recv(client: c, buf: &buffer, count: 1);
227	if (rc != 1) {
228	v4l2_warn(sd, "I/O error (read)\n");
229	if (rc < 0)
230	return rc;
231	return -EIO;
232	}
233	v4l2_dbg(1, debug, sd, "chip_read: 0x%x\n", buffer);
234	return buffer;
235	}
236
237	static int chip_read2(struct CHIPSTATE *chip, int subaddr)
238	{
239	struct v4l2_subdev *sd = &chip->sd;
240	struct i2c_client *c = v4l2_get_subdevdata(sd);
241	int rc;
242	unsigned char write[1];
243	unsigned char read[1];
244	struct i2c_msg msgs[2] = {
245	{
246	.addr = c->addr,
247	.len = 1,
248	.buf = write
249	},
250	{
251	.addr = c->addr,
252	.flags = I2C_M_RD,
253	.len = 1,
254	.buf = read
255	}
256	};
257
258	write[0] = subaddr;
259
260	rc = i2c_transfer(adap: c->adapter, msgs, num: 2);
261	if (rc != 2) {
262	v4l2_warn(sd, "I/O error (read2)\n");
263	if (rc < 0)
264	return rc;
265	return -EIO;
266	}
267	v4l2_dbg(1, debug, sd, "chip_read2: reg%d=0x%x\n",
268	subaddr, read[0]);
269	return read[0];
270	}
271
272	static int chip_cmd(struct CHIPSTATE *chip, char *name, audiocmd *cmd)
273	{
274	struct v4l2_subdev *sd = &chip->sd;
275	struct i2c_client *c = v4l2_get_subdevdata(sd);
276	int i, rc;
277
278	if (0 == cmd->count)
279	return 0;
280
281	if (cmd->count + cmd->bytes[0] - 1 >= ARRAY_SIZE(chip->shadow.bytes)) {
282	v4l2_info(sd,
283	"Tried to access a non-existent register range: %d to %d\n",
284	cmd->bytes[0] + 1, cmd->bytes[0] + cmd->count - 1);
285	return -EINVAL;
286	}
287
288	/* FIXME: it seems that the shadow bytes are wrong below !*/
289
290	/* update our shadow register set; print bytes if (debug > 0) */
291	v4l2_dbg(1, debug, sd, "chip_cmd(%s): reg=%d, data:",
292	name, cmd->bytes[0]);
293	for (i = 1; i < cmd->count; i++) {
294	if (debug)
295	printk(KERN_CONT " 0x%x", cmd->bytes[i]);
296	chip->shadow.bytes[i+cmd->bytes[0]] = cmd->bytes[i];
297	}
298	if (debug)
299	printk(KERN_CONT "\n");
300
301	/* send data to the chip */
302	rc = i2c_master_send(client: c, buf: cmd->bytes, count: cmd->count);
303	if (rc != cmd->count) {
304	v4l2_warn(sd, "I/O error (%s)\n", name);
305	if (rc < 0)
306	return rc;
307	return -EIO;
308	}
309	return 0;
310	}
311
312	/* ---------------------------------------------------------------------- */
313	/* kernel thread for doing i2c stuff asyncronly
314	* right now it is used only to check the audio mode (mono/stereo/whatever)
315	* some time after switching to another TV channel, then turn on stereo
316	* if available, ...
317	*/
318
319	static void chip_thread_wake(struct timer_list *t)
320	{
321	struct CHIPSTATE *chip = from_timer(chip, t, wt);
322	wake_up_process(tsk: chip->thread);
323	}
324
325	static int chip_thread(void *data)
326	{
327	struct CHIPSTATE *chip = data;
328	struct CHIPDESC *desc = chip->desc;
329	struct v4l2_subdev *sd = &chip->sd;
330	int mode, selected;
331
332	v4l2_dbg(1, debug, sd, "thread started\n");
333	set_freezable();
334	for (;;) {
335	set_current_state(TASK_INTERRUPTIBLE);
336	if (!kthread_should_stop())
337	schedule();
338	set_current_state(TASK_RUNNING);
339	try_to_freeze();
340	if (kthread_should_stop())
341	break;
342	v4l2_dbg(1, debug, sd, "thread wakeup\n");
343
344	/* don't do anything for radio */
345	if (chip->radio)
346	continue;
347
348	/* have a look what's going on */
349	mode = desc->getrxsubchans(chip);
350	if (mode == chip->prevmode)
351	continue;
352
353	/* chip detected a new audio mode - set it */
354	v4l2_dbg(1, debug, sd, "thread checkmode\n");
355
356	chip->prevmode = mode;
357
358	selected = V4L2_TUNER_MODE_MONO;
359	switch (chip->audmode) {
360	case V4L2_TUNER_MODE_MONO:
361	if (mode & V4L2_TUNER_SUB_LANG1)
362	selected = V4L2_TUNER_MODE_LANG1;
363	break;
364	case V4L2_TUNER_MODE_STEREO:
365	case V4L2_TUNER_MODE_LANG1:
366	if (mode & V4L2_TUNER_SUB_LANG1)
367	selected = V4L2_TUNER_MODE_LANG1;
368	else if (mode & V4L2_TUNER_SUB_STEREO)
369	selected = V4L2_TUNER_MODE_STEREO;
370	break;
371	case V4L2_TUNER_MODE_LANG2:
372	if (mode & V4L2_TUNER_SUB_LANG2)
373	selected = V4L2_TUNER_MODE_LANG2;
374	else if (mode & V4L2_TUNER_SUB_STEREO)
375	selected = V4L2_TUNER_MODE_STEREO;
376	break;
377	case V4L2_TUNER_MODE_LANG1_LANG2:
378	if (mode & V4L2_TUNER_SUB_LANG2)
379	selected = V4L2_TUNER_MODE_LANG1_LANG2;
380	else if (mode & V4L2_TUNER_SUB_STEREO)
381	selected = V4L2_TUNER_MODE_STEREO;
382	}
383	desc->setaudmode(chip, selected);
384
385	/* schedule next check */
386	mod_timer(timer: &chip->wt, expires: jiffies+msecs_to_jiffies(m: 2000));
387	}
388
389	v4l2_dbg(1, debug, sd, "thread exiting\n");
390	return 0;
391	}
392
393	/* ---------------------------------------------------------------------- */
394	/* audio chip descriptions - defines+functions for tda9840 */
395
396	#define TDA9840_SW 0x00
397	#define TDA9840_LVADJ 0x02
398	#define TDA9840_STADJ 0x03
399	#define TDA9840_TEST 0x04
400
401	#define TDA9840_MONO 0x10
402	#define TDA9840_STEREO 0x2a
403	#define TDA9840_DUALA 0x12
404	#define TDA9840_DUALB 0x1e
405	#define TDA9840_DUALAB 0x1a
406	#define TDA9840_DUALBA 0x16
407	#define TDA9840_EXTERNAL 0x7a
408
409	#define TDA9840_DS_DUAL 0x20 /* Dual sound identified */
410	#define TDA9840_ST_STEREO 0x40 /* Stereo sound identified */
411	#define TDA9840_PONRES 0x80 /* Power-on reset detected if = 1 */
412
413	#define TDA9840_TEST_INT1SN 0x1 /* Integration time 0.5s when set */
414	#define TDA9840_TEST_INTFU 0x02 /* Disables integrator function */
415
416	static int tda9840_getrxsubchans(struct CHIPSTATE *chip)
417	{
418	struct v4l2_subdev *sd = &chip->sd;
419	int val, mode;
420
421	mode = V4L2_TUNER_SUB_MONO;
422
423	val = chip_read(chip);
424	if (val < 0)
425	return mode;
426
427	if (val & TDA9840_DS_DUAL)
428	mode |= V4L2_TUNER_SUB_LANG1 | V4L2_TUNER_SUB_LANG2;
429	if (val & TDA9840_ST_STEREO)
430	mode = V4L2_TUNER_SUB_STEREO;
431
432	v4l2_dbg(1, debug, sd,
433	"tda9840_getrxsubchans(): raw chip read: %d, return: %d\n",
434	val, mode);
435	return mode;
436	}
437
438	static void tda9840_setaudmode(struct CHIPSTATE *chip, int mode)
439	{
440	int update = 1;
441	int t = chip->shadow.bytes[TDA9840_SW + 1] & ~0x7e;
442
443	switch (mode) {
444	case V4L2_TUNER_MODE_MONO:
445	t |= TDA9840_MONO;
446	break;
447	case V4L2_TUNER_MODE_STEREO:
448	t |= TDA9840_STEREO;
449	break;
450	case V4L2_TUNER_MODE_LANG1:
451	t |= TDA9840_DUALA;
452	break;
453	case V4L2_TUNER_MODE_LANG2:
454	t |= TDA9840_DUALB;
455	break;
456	case V4L2_TUNER_MODE_LANG1_LANG2:
457	t |= TDA9840_DUALAB;
458	break;
459	default:
460	update = 0;
461	}
462
463	if (update)
464	chip_write(chip, TDA9840_SW, val: t);
465	}
466
467	static int tda9840_checkit(struct CHIPSTATE *chip)
468	{
469	int rc;
470
471	rc = chip_read(chip);
472	if (rc < 0)
473	return 0;
474
475
476	/* lower 5 bits should be 0 */
477	return ((rc & 0x1f) == 0) ? 1 : 0;
478	}
479
480	/* ---------------------------------------------------------------------- */
481	/* audio chip descriptions - defines+functions for tda985x */
482
483	/* subaddresses for TDA9855 */
484	#define TDA9855_VR 0x00 /* Volume, right */
485	#define TDA9855_VL 0x01 /* Volume, left */
486	#define TDA9855_BA 0x02 /* Bass */
487	#define TDA9855_TR 0x03 /* Treble */
488	#define TDA9855_SW 0x04 /* Subwoofer - not connected on DTV2000 */
489
490	/* subaddresses for TDA9850 */
491	#define TDA9850_C4 0x04 /* Control 1 for TDA9850 */
492
493	/* subaddesses for both chips */
494	#define TDA985x_C5 0x05 /* Control 2 for TDA9850, Control 1 for TDA9855 */
495	#define TDA985x_C6 0x06 /* Control 3 for TDA9850, Control 2 for TDA9855 */
496	#define TDA985x_C7 0x07 /* Control 4 for TDA9850, Control 3 for TDA9855 */
497	#define TDA985x_A1 0x08 /* Alignment 1 for both chips */
498	#define TDA985x_A2 0x09 /* Alignment 2 for both chips */
499	#define TDA985x_A3 0x0a /* Alignment 3 for both chips */
500
501	/* Masks for bits in TDA9855 subaddresses */
502	/* 0x00 - VR in TDA9855 */
503	/* 0x01 - VL in TDA9855 */
504	/* lower 7 bits control gain from -71dB (0x28) to 16dB (0x7f)
505	* in 1dB steps - mute is 0x27 */
506
507
508	/* 0x02 - BA in TDA9855 */
509	/* lower 5 bits control bass gain from -12dB (0x06) to 16.5dB (0x19)
510	* in .5dB steps - 0 is 0x0E */
511
512
513	/* 0x03 - TR in TDA9855 */
514	/* 4 bits << 1 control treble gain from -12dB (0x3) to 12dB (0xb)
515	* in 3dB steps - 0 is 0x7 */
516
517	/* Masks for bits in both chips' subaddresses */
518	/* 0x04 - SW in TDA9855, C4/Control 1 in TDA9850 */
519	/* Unique to TDA9855: */
520	/* 4 bits << 2 control subwoofer/surround gain from -14db (0x1) to 14db (0xf)
521	* in 3dB steps - mute is 0x0 */
522
523	/* Unique to TDA9850: */
524	/* lower 4 bits control stereo noise threshold, over which stereo turns off
525	* set to values of 0x00 through 0x0f for Ster1 through Ster16 */
526
527
528	/* 0x05 - C5 - Control 1 in TDA9855 , Control 2 in TDA9850*/
529	/* Unique to TDA9855: */
530	#define TDA9855_MUTE 1<<7 /* GMU, Mute at outputs */
531	#define TDA9855_AVL 1<<6 /* AVL, Automatic Volume Level */
532	#define TDA9855_LOUD 1<<5 /* Loudness, 1==off */
533	#define TDA9855_SUR 1<<3 /* Surround / Subwoofer 1==.5(L-R) 0==.5(L+R) */
534	/* Bits 0 to 3 select various combinations
535	* of line in and line out, only the
536	* interesting ones are defined */
537	#define TDA9855_EXT 1<<2 /* Selects inputs LIR and LIL. Pins 41 & 12 */
538	#define TDA9855_INT 0 /* Selects inputs LOR and LOL. (internal) */
539
540	/* Unique to TDA9850: */
541	/* lower 4 bits control SAP noise threshold, over which SAP turns off
542	* set to values of 0x00 through 0x0f for SAP1 through SAP16 */
543
544
545	/* 0x06 - C6 - Control 2 in TDA9855, Control 3 in TDA9850 */
546	/* Common to TDA9855 and TDA9850: */
547	#define TDA985x_SAP 3<<6 /* Selects SAP output, mute if not received */
548	#define TDA985x_MONOSAP 2<<6 /* Selects Mono on left, SAP on right */
549	#define TDA985x_STEREO 1<<6 /* Selects Stereo output, mono if not received */
550	#define TDA985x_MONO 0 /* Forces Mono output */
551	#define TDA985x_LMU 1<<3 /* Mute (LOR/LOL for 9855, OUTL/OUTR for 9850) */
552
553	/* Unique to TDA9855: */
554	#define TDA9855_TZCM 1<<5 /* If set, don't mute till zero crossing */
555	#define TDA9855_VZCM 1<<4 /* If set, don't change volume till zero crossing*/
556	#define TDA9855_LINEAR 0 /* Linear Stereo */
557	#define TDA9855_PSEUDO 1 /* Pseudo Stereo */
558	#define TDA9855_SPAT_30 2 /* Spatial Stereo, 30% anti-phase crosstalk */
559	#define TDA9855_SPAT_50 3 /* Spatial Stereo, 52% anti-phase crosstalk */
560	#define TDA9855_E_MONO 7 /* Forced mono - mono select elseware, so useless*/
561
562	/* 0x07 - C7 - Control 3 in TDA9855, Control 4 in TDA9850 */
563	/* Common to both TDA9855 and TDA9850: */
564	/* lower 4 bits control input gain from -3.5dB (0x0) to 4dB (0xF)
565	* in .5dB steps - 0dB is 0x7 */
566
567	/* 0x08, 0x09 - A1 and A2 (read/write) */
568	/* Common to both TDA9855 and TDA9850: */
569	/* lower 5 bites are wideband and spectral expander alignment
570	* from 0x00 to 0x1f - nominal at 0x0f and 0x10 (read/write) */
571	#define TDA985x_STP 1<<5 /* Stereo Pilot/detect (read-only) */
572	#define TDA985x_SAPP 1<<6 /* SAP Pilot/detect (read-only) */
573	#define TDA985x_STS 1<<7 /* Stereo trigger 1= <35mV 0= <30mV (write-only)*/
574
575	/* 0x0a - A3 */
576	/* Common to both TDA9855 and TDA9850: */
577	/* lower 3 bits control timing current for alignment: -30% (0x0), -20% (0x1),
578	* -10% (0x2), nominal (0x3), +10% (0x6), +20% (0x5), +30% (0x4) */
579	#define TDA985x_ADJ 1<<7 /* Stereo adjust on/off (wideband and spectral */
580
581	static int tda9855_volume(int val) { return val/0x2e8+0x27; }
582	static int tda9855_bass(int val) { return val/0xccc+0x06; }
583	static int tda9855_treble(int val) { return (val/0x1c71+0x3)<<1; }
584
585	static int tda985x_getrxsubchans(struct CHIPSTATE *chip)
586	{
587	int mode, val;
588
589	/* Add mono mode regardless of SAP and stereo */
590	/* Allows forced mono */
591	mode = V4L2_TUNER_SUB_MONO;
592	val = chip_read(chip);
593	if (val < 0)
594	return mode;
595
596	if (val & TDA985x_STP)
597	mode = V4L2_TUNER_SUB_STEREO;
598	if (val & TDA985x_SAPP)
599	mode |= V4L2_TUNER_SUB_SAP;
600	return mode;
601	}
602
603	static void tda985x_setaudmode(struct CHIPSTATE *chip, int mode)
604	{
605	int update = 1;
606	int c6 = chip->shadow.bytes[TDA985x_C6+1] & 0x3f;
607
608	switch (mode) {
609	case V4L2_TUNER_MODE_MONO:
610	c6 |= TDA985x_MONO;
611	break;
612	case V4L2_TUNER_MODE_STEREO:
613	case V4L2_TUNER_MODE_LANG1:
614	c6 |= TDA985x_STEREO;
615	break;
616	case V4L2_TUNER_MODE_SAP:
617	c6 |= TDA985x_SAP;
618	break;
619	case V4L2_TUNER_MODE_LANG1_LANG2:
620	c6 |= TDA985x_MONOSAP;
621	break;
622	default:
623	update = 0;
624	}
625	if (update)
626	chip_write(chip,TDA985x_C6,val: c6);
627	}
628
629
630	/* ---------------------------------------------------------------------- */
631	/* audio chip descriptions - defines+functions for tda9873h */
632
633	/* Subaddresses for TDA9873H */
634
635	#define TDA9873_SW 0x00 /* Switching */
636	#define TDA9873_AD 0x01 /* Adjust */
637	#define TDA9873_PT 0x02 /* Port */
638
639	/* Subaddress 0x00: Switching Data
640	* B7..B0:
641	*
642	* B1, B0: Input source selection
643	* 0, 0 internal
644	* 1, 0 external stereo
645	* 0, 1 external mono
646	*/
647	#define TDA9873_INP_MASK 3
648	#define TDA9873_INTERNAL 0
649	#define TDA9873_EXT_STEREO 2
650	#define TDA9873_EXT_MONO 1
651
652	/* B3, B2: output signal select
653	* B4 : transmission mode
654	* 0, 0, 1 Mono
655	* 1, 0, 0 Stereo
656	* 1, 1, 1 Stereo (reversed channel)
657	* 0, 0, 0 Dual AB
658	* 0, 0, 1 Dual AA
659	* 0, 1, 0 Dual BB
660	* 0, 1, 1 Dual BA
661	*/
662
663	#define TDA9873_TR_MASK (7 << 2)
664	#define TDA9873_TR_MONO 4
665	#define TDA9873_TR_STEREO 1 << 4
666	#define TDA9873_TR_REVERSE ((1 << 3) | (1 << 2))
667	#define TDA9873_TR_DUALA 1 << 2
668	#define TDA9873_TR_DUALB 1 << 3
669	#define TDA9873_TR_DUALAB 0
670
671	/* output level controls
672	* B5: output level switch (0 = reduced gain, 1 = normal gain)
673	* B6: mute (1 = muted)
674	* B7: auto-mute (1 = auto-mute enabled)
675	*/
676
677	#define TDA9873_GAIN_NORMAL 1 << 5
678	#define TDA9873_MUTE 1 << 6
679	#define TDA9873_AUTOMUTE 1 << 7
680
681	/* Subaddress 0x01: Adjust/standard */
682
683	/* Lower 4 bits (C3..C0) control stereo adjustment on R channel (-0.6 - +0.7 dB)
684	* Recommended value is +0 dB
685	*/
686
687	#define TDA9873_STEREO_ADJ 0x06 /* 0dB gain */
688
689	/* Bits C6..C4 control FM stantard
690	* C6, C5, C4
691	* 0, 0, 0 B/G (PAL FM)
692	* 0, 0, 1 M
693	* 0, 1, 0 D/K(1)
694	* 0, 1, 1 D/K(2)
695	* 1, 0, 0 D/K(3)
696	* 1, 0, 1 I
697	*/
698	#define TDA9873_BG 0
699	#define TDA9873_M 1
700	#define TDA9873_DK1 2
701	#define TDA9873_DK2 3
702	#define TDA9873_DK3 4
703	#define TDA9873_I 5
704
705	/* C7 controls identification response time (1=fast/0=normal)
706	*/
707	#define TDA9873_IDR_NORM 0
708	#define TDA9873_IDR_FAST 1 << 7
709
710
711	/* Subaddress 0x02: Port data */
712
713	/* E1, E0 free programmable ports P1/P2
714	0, 0 both ports low
715	0, 1 P1 high
716	1, 0 P2 high
717	1, 1 both ports high
718	*/
719
720	#define TDA9873_PORTS 3
721
722	/* E2: test port */
723	#define TDA9873_TST_PORT 1 << 2
724
725	/* E5..E3 control mono output channel (together with transmission mode bit B4)
726	*
727	* E5 E4 E3 B4 OUTM
728	* 0 0 0 0 mono
729	* 0 0 1 0 DUAL B
730	* 0 1 0 1 mono (from stereo decoder)
731	*/
732	#define TDA9873_MOUT_MONO 0
733	#define TDA9873_MOUT_FMONO 0
734	#define TDA9873_MOUT_DUALA 0
735	#define TDA9873_MOUT_DUALB 1 << 3
736	#define TDA9873_MOUT_ST 1 << 4
737	#define TDA9873_MOUT_EXTM ((1 << 4) | (1 << 3))
738	#define TDA9873_MOUT_EXTL 1 << 5
739	#define TDA9873_MOUT_EXTR ((1 << 5) | (1 << 3))
740	#define TDA9873_MOUT_EXTLR ((1 << 5) | (1 << 4))
741	#define TDA9873_MOUT_MUTE ((1 << 5) | (1 << 4) | (1 << 3))
742
743	/* Status bits: (chip read) */
744	#define TDA9873_PONR 0 /* Power-on reset detected if = 1 */
745	#define TDA9873_STEREO 2 /* Stereo sound is identified */
746	#define TDA9873_DUAL 4 /* Dual sound is identified */
747
748	static int tda9873_getrxsubchans(struct CHIPSTATE *chip)
749	{
750	struct v4l2_subdev *sd = &chip->sd;
751	int val,mode;
752
753	mode = V4L2_TUNER_SUB_MONO;
754
755	val = chip_read(chip);
756	if (val < 0)
757	return mode;
758
759	if (val & TDA9873_STEREO)
760	mode = V4L2_TUNER_SUB_STEREO;
761	if (val & TDA9873_DUAL)
762	mode |= V4L2_TUNER_SUB_LANG1 | V4L2_TUNER_SUB_LANG2;
763	v4l2_dbg(1, debug, sd,
764	"tda9873_getrxsubchans(): raw chip read: %d, return: %d\n",
765	val, mode);
766	return mode;
767	}
768
769	static void tda9873_setaudmode(struct CHIPSTATE *chip, int mode)
770	{
771	struct v4l2_subdev *sd = &chip->sd;
772	int sw_data = chip->shadow.bytes[TDA9873_SW+1] & ~ TDA9873_TR_MASK;
773	/* int adj_data = chip->shadow.bytes[TDA9873_AD+1] ; */
774
775	if ((sw_data & TDA9873_INP_MASK) != TDA9873_INTERNAL) {
776	v4l2_dbg(1, debug, sd,
777	"tda9873_setaudmode(): external input\n");
778	return;
779	}
780
781	v4l2_dbg(1, debug, sd,
782	"tda9873_setaudmode(): chip->shadow.bytes[%d] = %d\n",
783	TDA9873_SW+1, chip->shadow.bytes[TDA9873_SW+1]);
784	v4l2_dbg(1, debug, sd, "tda9873_setaudmode(): sw_data = %d\n",
785	sw_data);
786
787	switch (mode) {
788	case V4L2_TUNER_MODE_MONO:
789	sw_data |= TDA9873_TR_MONO;
790	break;
791	case V4L2_TUNER_MODE_STEREO:
792	sw_data |= TDA9873_TR_STEREO;
793	break;
794	case V4L2_TUNER_MODE_LANG1:
795	sw_data |= TDA9873_TR_DUALA;
796	break;
797	case V4L2_TUNER_MODE_LANG2:
798	sw_data |= TDA9873_TR_DUALB;
799	break;
800	case V4L2_TUNER_MODE_LANG1_LANG2:
801	sw_data |= TDA9873_TR_DUALAB;
802	break;
803	default:
804	return;
805	}
806
807	chip_write(chip, TDA9873_SW, val: sw_data);
808	v4l2_dbg(1, debug, sd,
809	"tda9873_setaudmode(): req. mode %d; chip_write: %d\n",
810	mode, sw_data);
811	}
812
813	static int tda9873_checkit(struct CHIPSTATE *chip)
814	{
815	int rc;
816
817	rc = chip_read2(chip, subaddr: 254);
818	if (rc < 0)
819	return 0;
820	return (rc & ~0x1f) == 0x80;
821	}
822
823
824	/* ---------------------------------------------------------------------- */
825	/* audio chip description - defines+functions for tda9874h and tda9874a */
826	/* Dariusz Kowalewski <darekk@automex.pl> */
827
828	/* Subaddresses for TDA9874H and TDA9874A (slave rx) */
829	#define TDA9874A_AGCGR 0x00 /* AGC gain */
830	#define TDA9874A_GCONR 0x01 /* general config */
831	#define TDA9874A_MSR 0x02 /* monitor select */
832	#define TDA9874A_C1FRA 0x03 /* carrier 1 freq. */
833	#define TDA9874A_C1FRB 0x04 /* carrier 1 freq. */
834	#define TDA9874A_C1FRC 0x05 /* carrier 1 freq. */
835	#define TDA9874A_C2FRA 0x06 /* carrier 2 freq. */
836	#define TDA9874A_C2FRB 0x07 /* carrier 2 freq. */
837	#define TDA9874A_C2FRC 0x08 /* carrier 2 freq. */
838	#define TDA9874A_DCR 0x09 /* demodulator config */
839	#define TDA9874A_FMER 0x0a /* FM de-emphasis */
840	#define TDA9874A_FMMR 0x0b /* FM dematrix */
841	#define TDA9874A_C1OLAR 0x0c /* ch.1 output level adj. */
842	#define TDA9874A_C2OLAR 0x0d /* ch.2 output level adj. */
843	#define TDA9874A_NCONR 0x0e /* NICAM config */
844	#define TDA9874A_NOLAR 0x0f /* NICAM output level adj. */
845	#define TDA9874A_NLELR 0x10 /* NICAM lower error limit */
846	#define TDA9874A_NUELR 0x11 /* NICAM upper error limit */
847	#define TDA9874A_AMCONR 0x12 /* audio mute control */
848	#define TDA9874A_SDACOSR 0x13 /* stereo DAC output select */
849	#define TDA9874A_AOSR 0x14 /* analog output select */
850	#define TDA9874A_DAICONR 0x15 /* digital audio interface config */
851	#define TDA9874A_I2SOSR 0x16 /* I2S-bus output select */
852	#define TDA9874A_I2SOLAR 0x17 /* I2S-bus output level adj. */
853	#define TDA9874A_MDACOSR 0x18 /* mono DAC output select (tda9874a) */
854	#define TDA9874A_ESP 0xFF /* easy standard progr. (tda9874a) */
855
856	/* Subaddresses for TDA9874H and TDA9874A (slave tx) */
857	#define TDA9874A_DSR 0x00 /* device status */
858	#define TDA9874A_NSR 0x01 /* NICAM status */
859	#define TDA9874A_NECR 0x02 /* NICAM error count */
860	#define TDA9874A_DR1 0x03 /* add. data LSB */
861	#define TDA9874A_DR2 0x04 /* add. data MSB */
862	#define TDA9874A_LLRA 0x05 /* monitor level read-out LSB */
863	#define TDA9874A_LLRB 0x06 /* monitor level read-out MSB */
864	#define TDA9874A_SIFLR 0x07 /* SIF level */
865	#define TDA9874A_TR2 252 /* test reg. 2 */
866	#define TDA9874A_TR1 253 /* test reg. 1 */
867	#define TDA9874A_DIC 254 /* device id. code */
868	#define TDA9874A_SIC 255 /* software id. code */
869
870
871	static int tda9874a_mode = 1; /* 0: A2, 1: NICAM */
872	static int tda9874a_GCONR = 0xc0; /* default config. input pin: SIFSEL=0 */
873	static int tda9874a_NCONR = 0x01; /* default NICAM config.: AMSEL=0,AMUTE=1 */
874	static int tda9874a_ESP = 0x07; /* default standard: NICAM D/K */
875	static int tda9874a_dic = -1; /* device id. code */
876
877	/* insmod options for tda9874a */
878	static unsigned int tda9874a_SIF = UNSET;
879	static unsigned int tda9874a_AMSEL = UNSET;
880	static unsigned int tda9874a_STD = UNSET;
881	module_param(tda9874a_SIF, int, 0444);
882	module_param(tda9874a_AMSEL, int, 0444);
883	module_param(tda9874a_STD, int, 0444);
884
885	/*
886	* initialization table for tda9874 decoder:
887	* - carrier 1 freq. registers (3 bytes)
888	* - carrier 2 freq. registers (3 bytes)
889	* - demudulator config register
890	* - FM de-emphasis register (slow identification mode)
891	* Note: frequency registers must be written in single i2c transfer.
892	*/
893	static struct tda9874a_MODES {
894	char *name;
895	audiocmd cmd;
896	} tda9874a_modelist[9] = {
897	{ "A2, B/G", /* default */
898	{ 9, { TDA9874A_C1FRA, 0x72,0x95,0x55, 0x77,0xA0,0x00, 0x00,0x00 }} },
899	{ "A2, M (Korea)",
900	{ 9, { TDA9874A_C1FRA, 0x5D,0xC0,0x00, 0x62,0x6A,0xAA, 0x20,0x22 }} },
901	{ "A2, D/K (1)",
902	{ 9, { TDA9874A_C1FRA, 0x87,0x6A,0xAA, 0x82,0x60,0x00, 0x00,0x00 }} },
903	{ "A2, D/K (2)",
904	{ 9, { TDA9874A_C1FRA, 0x87,0x6A,0xAA, 0x8C,0x75,0x55, 0x00,0x00 }} },
905	{ "A2, D/K (3)",
906	{ 9, { TDA9874A_C1FRA, 0x87,0x6A,0xAA, 0x77,0xA0,0x00, 0x00,0x00 }} },
907	{ "NICAM, I",
908	{ 9, { TDA9874A_C1FRA, 0x7D,0x00,0x00, 0x88,0x8A,0xAA, 0x08,0x33 }} },
909	{ "NICAM, B/G",
910	{ 9, { TDA9874A_C1FRA, 0x72,0x95,0x55, 0x79,0xEA,0xAA, 0x08,0x33 }} },
911	{ "NICAM, D/K",
912	{ 9, { TDA9874A_C1FRA, 0x87,0x6A,0xAA, 0x79,0xEA,0xAA, 0x08,0x33 }} },
913	{ "NICAM, L",
914	{ 9, { TDA9874A_C1FRA, 0x87,0x6A,0xAA, 0x79,0xEA,0xAA, 0x09,0x33 }} }
915	};
916
917	static int tda9874a_setup(struct CHIPSTATE *chip)
918	{
919	struct v4l2_subdev *sd = &chip->sd;
920
921	chip_write(chip, TDA9874A_AGCGR, val: 0x00); /* 0 dB */
922	chip_write(chip, TDA9874A_GCONR, val: tda9874a_GCONR);
923	chip_write(chip, TDA9874A_MSR, val: (tda9874a_mode) ? 0x03:0x02);
924	if(tda9874a_dic == 0x11) {
925	chip_write(chip, TDA9874A_FMMR, val: 0x80);
926	} else { /* dic == 0x07 */
927	chip_cmd(chip,name: "tda9874_modelist",cmd: &tda9874a_modelist[tda9874a_STD].cmd);
928	chip_write(chip, TDA9874A_FMMR, val: 0x00);
929	}
930	chip_write(chip, TDA9874A_C1OLAR, val: 0x00); /* 0 dB */
931	chip_write(chip, TDA9874A_C2OLAR, val: 0x00); /* 0 dB */
932	chip_write(chip, TDA9874A_NCONR, val: tda9874a_NCONR);
933	chip_write(chip, TDA9874A_NOLAR, val: 0x00); /* 0 dB */
934	/* Note: If signal quality is poor you may want to change NICAM */
935	/* error limit registers (NLELR and NUELR) to some greater values. */
936	/* Then the sound would remain stereo, but won't be so clear. */
937	chip_write(chip, TDA9874A_NLELR, val: 0x14); /* default */
938	chip_write(chip, TDA9874A_NUELR, val: 0x50); /* default */
939
940	if(tda9874a_dic == 0x11) {
941	chip_write(chip, TDA9874A_AMCONR, val: 0xf9);
942	chip_write(chip, TDA9874A_SDACOSR, val: (tda9874a_mode) ? 0x81:0x80);
943	chip_write(chip, TDA9874A_AOSR, val: 0x80);
944	chip_write(chip, TDA9874A_MDACOSR, val: (tda9874a_mode) ? 0x82:0x80);
945	chip_write(chip, TDA9874A_ESP, val: tda9874a_ESP);
946	} else { /* dic == 0x07 */
947	chip_write(chip, TDA9874A_AMCONR, val: 0xfb);
948	chip_write(chip, TDA9874A_SDACOSR, val: (tda9874a_mode) ? 0x81:0x80);
949	chip_write(chip, TDA9874A_AOSR, val: 0x00); /* or 0x10 */
950	}
951	v4l2_dbg(1, debug, sd, "tda9874a_setup(): %s [0x%02X].\n",
952	tda9874a_modelist[tda9874a_STD].name,tda9874a_STD);
953	return 1;
954	}
955
956	static int tda9874a_getrxsubchans(struct CHIPSTATE *chip)
957	{
958	struct v4l2_subdev *sd = &chip->sd;
959	int dsr,nsr,mode;
960	int necr; /* just for debugging */
961
962	mode = V4L2_TUNER_SUB_MONO;
963
964	dsr = chip_read2(chip, TDA9874A_DSR);
965	if (dsr < 0)
966	return mode;
967	nsr = chip_read2(chip, TDA9874A_NSR);
968	if (nsr < 0)
969	return mode;
970	necr = chip_read2(chip, TDA9874A_NECR);
971	if (necr < 0)
972	return mode;
973
974	/* need to store dsr/nsr somewhere */
975	chip->shadow.bytes[MAXREGS-2] = dsr;
976	chip->shadow.bytes[MAXREGS-1] = nsr;
977
978	if(tda9874a_mode) {
979	/* Note: DSR.RSSF and DSR.AMSTAT bits are also checked.
980	* If NICAM auto-muting is enabled, DSR.AMSTAT=1 indicates
981	* that sound has (temporarily) switched from NICAM to
982	* mono FM (or AM) on 1st sound carrier due to high NICAM bit
983	* error count. So in fact there is no stereo in this case :-(
984	* But changing the mode to V4L2_TUNER_MODE_MONO would switch
985	* external 4052 multiplexer in audio_hook().
986	*/
987	if(nsr & 0x02) /* NSR.S/MB=1 */
988	mode = V4L2_TUNER_SUB_STEREO;
989	if(nsr & 0x01) /* NSR.D/SB=1 */
990	mode |= V4L2_TUNER_SUB_LANG1 | V4L2_TUNER_SUB_LANG2;
991	} else {
992	if(dsr & 0x02) /* DSR.IDSTE=1 */
993	mode = V4L2_TUNER_SUB_STEREO;
994	if(dsr & 0x04) /* DSR.IDDUA=1 */
995	mode |= V4L2_TUNER_SUB_LANG1 | V4L2_TUNER_SUB_LANG2;
996	}
997
998	v4l2_dbg(1, debug, sd,
999	"tda9874a_getrxsubchans(): DSR=0x%X, NSR=0x%X, NECR=0x%X, return: %d.\n",
1000	dsr, nsr, necr, mode);
1001	return mode;
1002	}
1003
1004	static void tda9874a_setaudmode(struct CHIPSTATE *chip, int mode)
1005	{
1006	struct v4l2_subdev *sd = &chip->sd;
1007
1008	/* Disable/enable NICAM auto-muting (based on DSR.RSSF status bit). */
1009	/* If auto-muting is disabled, we can hear a signal of degrading quality. */
1010	if (tda9874a_mode) {
1011	if(chip->shadow.bytes[MAXREGS-2] & 0x20) /* DSR.RSSF=1 */
1012	tda9874a_NCONR &= 0xfe; /* enable */
1013	else
1014	tda9874a_NCONR |= 0x01; /* disable */
1015	chip_write(chip, TDA9874A_NCONR, val: tda9874a_NCONR);
1016	}
1017
1018	/* Note: TDA9874A supports automatic FM dematrixing (FMMR register)
1019	* and has auto-select function for audio output (AOSR register).
1020	* Old TDA9874H doesn't support these features.
1021	* TDA9874A also has additional mono output pin (OUTM), which
1022	* on same (all?) tv-cards is not used, anyway (as well as MONOIN).
1023	*/
1024	if(tda9874a_dic == 0x11) {
1025	int aosr = 0x80;
1026	int mdacosr = (tda9874a_mode) ? 0x82:0x80;
1027
1028	switch(mode) {
1029	case V4L2_TUNER_MODE_MONO:
1030	case V4L2_TUNER_MODE_STEREO:
1031	break;
1032	case V4L2_TUNER_MODE_LANG1:
1033	aosr = 0x80; /* auto-select, dual A/A */
1034	mdacosr = (tda9874a_mode) ? 0x82:0x80;
1035	break;
1036	case V4L2_TUNER_MODE_LANG2:
1037	aosr = 0xa0; /* auto-select, dual B/B */
1038	mdacosr = (tda9874a_mode) ? 0x83:0x81;
1039	break;
1040	case V4L2_TUNER_MODE_LANG1_LANG2:
1041	aosr = 0x00; /* always route L to L and R to R */
1042	mdacosr = (tda9874a_mode) ? 0x82:0x80;
1043	break;
1044	default:
1045	return;
1046	}
1047	chip_write(chip, TDA9874A_AOSR, val: aosr);
1048	chip_write(chip, TDA9874A_MDACOSR, val: mdacosr);
1049
1050	v4l2_dbg(1, debug, sd,
1051	"tda9874a_setaudmode(): req. mode %d; AOSR=0x%X, MDACOSR=0x%X.\n",
1052	mode, aosr, mdacosr);
1053
1054	} else { /* dic == 0x07 */
1055	int fmmr,aosr;
1056
1057	switch(mode) {
1058	case V4L2_TUNER_MODE_MONO:
1059	fmmr = 0x00; /* mono */
1060	aosr = 0x10; /* A/A */
1061	break;
1062	case V4L2_TUNER_MODE_STEREO:
1063	if(tda9874a_mode) {
1064	fmmr = 0x00;
1065	aosr = 0x00; /* handled by NICAM auto-mute */
1066	} else {
1067	fmmr = (tda9874a_ESP == 1) ? 0x05 : 0x04; /* stereo */
1068	aosr = 0x00;
1069	}
1070	break;
1071	case V4L2_TUNER_MODE_LANG1:
1072	fmmr = 0x02; /* dual */
1073	aosr = 0x10; /* dual A/A */
1074	break;
1075	case V4L2_TUNER_MODE_LANG2:
1076	fmmr = 0x02; /* dual */
1077	aosr = 0x20; /* dual B/B */
1078	break;
1079	case V4L2_TUNER_MODE_LANG1_LANG2:
1080	fmmr = 0x02; /* dual */
1081	aosr = 0x00; /* dual A/B */
1082	break;
1083	default:
1084	return;
1085	}
1086	chip_write(chip, TDA9874A_FMMR, val: fmmr);
1087	chip_write(chip, TDA9874A_AOSR, val: aosr);
1088
1089	v4l2_dbg(1, debug, sd,
1090	"tda9874a_setaudmode(): req. mode %d; FMMR=0x%X, AOSR=0x%X.\n",
1091	mode, fmmr, aosr);
1092	}
1093	}
1094
1095	static int tda9874a_checkit(struct CHIPSTATE *chip)
1096	{
1097	struct v4l2_subdev *sd = &chip->sd;
1098	int dic,sic; /* device id. and software id. codes */
1099
1100	dic = chip_read2(chip, TDA9874A_DIC);
1101	if (dic < 0)
1102	return 0;
1103	sic = chip_read2(chip, TDA9874A_SIC);
1104	if (sic < 0)
1105	return 0;
1106
1107	v4l2_dbg(1, debug, sd, "tda9874a_checkit(): DIC=0x%X, SIC=0x%X.\n", dic, sic);
1108
1109	if((dic == 0x11)||(dic == 0x07)) {
1110	v4l2_info(sd, "found tda9874%s.\n", (dic == 0x11) ? "a" : "h");
1111	tda9874a_dic = dic; /* remember device id. */
1112	return 1;
1113	}
1114	return 0; /* not found */
1115	}
1116
1117	static int tda9874a_initialize(struct CHIPSTATE *chip)
1118	{
1119	if (tda9874a_SIF > 2)
1120	tda9874a_SIF = 1;
1121	if (tda9874a_STD >= ARRAY_SIZE(tda9874a_modelist))
1122	tda9874a_STD = 0;
1123	if(tda9874a_AMSEL > 1)
1124	tda9874a_AMSEL = 0;
1125
1126	if(tda9874a_SIF == 1)
1127	tda9874a_GCONR = 0xc0; /* sound IF input 1 */
1128	else
1129	tda9874a_GCONR = 0xc1; /* sound IF input 2 */
1130
1131	tda9874a_ESP = tda9874a_STD;
1132	tda9874a_mode = (tda9874a_STD < 5) ? 0 : 1;
1133
1134	if(tda9874a_AMSEL == 0)
1135	tda9874a_NCONR = 0x01; /* auto-mute: analog mono input */
1136	else
1137	tda9874a_NCONR = 0x05; /* auto-mute: 1st carrier FM or AM */
1138
1139	tda9874a_setup(chip);
1140	return 0;
1141	}
1142
1143	/* ---------------------------------------------------------------------- */
1144	/* audio chip description - defines+functions for tda9875 */
1145	/* The TDA9875 is made by Philips Semiconductor
1146	* http://www.semiconductors.philips.com
1147	* TDA9875: I2C-bus controlled DSP audio processor, FM demodulator
1148	*
1149	*/
1150
1151	/* subaddresses for TDA9875 */
1152	#define TDA9875_MUT 0x12 /*General mute (value --> 0b11001100*/
1153	#define TDA9875_CFG 0x01 /* Config register (value --> 0b00000000 */
1154	#define TDA9875_DACOS 0x13 /*DAC i/o select (ADC) 0b0000100*/
1155	#define TDA9875_LOSR 0x16 /*Line output select regirter 0b0100 0001*/
1156
1157	#define TDA9875_CH1V 0x0c /*Channel 1 volume (mute)*/
1158	#define TDA9875_CH2V 0x0d /*Channel 2 volume (mute)*/
1159	#define TDA9875_SC1 0x14 /*SCART 1 in (mono)*/
1160	#define TDA9875_SC2 0x15 /*SCART 2 in (mono)*/
1161
1162	#define TDA9875_ADCIS 0x17 /*ADC input select (mono) 0b0110 000*/
1163	#define TDA9875_AER 0x19 /*Audio effect (AVL+Pseudo) 0b0000 0110*/
1164	#define TDA9875_MCS 0x18 /*Main channel select (DAC) 0b0000100*/
1165	#define TDA9875_MVL 0x1a /* Main volume gauche */
1166	#define TDA9875_MVR 0x1b /* Main volume droite */
1167	#define TDA9875_MBA 0x1d /* Main Basse */
1168	#define TDA9875_MTR 0x1e /* Main treble */
1169	#define TDA9875_ACS 0x1f /* Auxiliary channel select (FM) 0b0000000*/
1170	#define TDA9875_AVL 0x20 /* Auxiliary volume gauche */
1171	#define TDA9875_AVR 0x21 /* Auxiliary volume droite */
1172	#define TDA9875_ABA 0x22 /* Auxiliary Basse */
1173	#define TDA9875_ATR 0x23 /* Auxiliary treble */
1174
1175	#define TDA9875_MSR 0x02 /* Monitor select register */
1176	#define TDA9875_C1MSB 0x03 /* Carrier 1 (FM) frequency register MSB */
1177	#define TDA9875_C1MIB 0x04 /* Carrier 1 (FM) frequency register (16-8]b */
1178	#define TDA9875_C1LSB 0x05 /* Carrier 1 (FM) frequency register LSB */
1179	#define TDA9875_C2MSB 0x06 /* Carrier 2 (nicam) frequency register MSB */
1180	#define TDA9875_C2MIB 0x07 /* Carrier 2 (nicam) frequency register (16-8]b */
1181	#define TDA9875_C2LSB 0x08 /* Carrier 2 (nicam) frequency register LSB */
1182	#define TDA9875_DCR 0x09 /* Demodulateur configuration regirter*/
1183	#define TDA9875_DEEM 0x0a /* FM de-emphasis regirter*/
1184	#define TDA9875_FMAT 0x0b /* FM Matrix regirter*/
1185
1186	/* values */
1187	#define TDA9875_MUTE_ON 0xff /* general mute */
1188	#define TDA9875_MUTE_OFF 0xcc /* general no mute */
1189
1190	static int tda9875_initialize(struct CHIPSTATE *chip)
1191	{
1192	chip_write(chip, TDA9875_CFG, val: 0xd0); /*reg de config 0 (reset)*/
1193	chip_write(chip, TDA9875_MSR, val: 0x03); /* Monitor 0b00000XXX*/
1194	chip_write(chip, TDA9875_C1MSB, val: 0x00); /*Car1(FM) MSB XMHz*/
1195	chip_write(chip, TDA9875_C1MIB, val: 0x00); /*Car1(FM) MIB XMHz*/
1196	chip_write(chip, TDA9875_C1LSB, val: 0x00); /*Car1(FM) LSB XMHz*/
1197	chip_write(chip, TDA9875_C2MSB, val: 0x00); /*Car2(NICAM) MSB XMHz*/
1198	chip_write(chip, TDA9875_C2MIB, val: 0x00); /*Car2(NICAM) MIB XMHz*/
1199	chip_write(chip, TDA9875_C2LSB, val: 0x00); /*Car2(NICAM) LSB XMHz*/
1200	chip_write(chip, TDA9875_DCR, val: 0x00); /*Demod config 0x00*/
1201	chip_write(chip, TDA9875_DEEM, val: 0x44); /*DE-Emph 0b0100 0100*/
1202	chip_write(chip, TDA9875_FMAT, val: 0x00); /*FM Matrix reg 0x00*/
1203	chip_write(chip, TDA9875_SC1, val: 0x00); /* SCART 1 (SC1)*/
1204	chip_write(chip, TDA9875_SC2, val: 0x01); /* SCART 2 (sc2)*/
1205
1206	chip_write(chip, TDA9875_CH1V, val: 0x10); /* Channel volume 1 mute*/
1207	chip_write(chip, TDA9875_CH2V, val: 0x10); /* Channel volume 2 mute */
1208	chip_write(chip, TDA9875_DACOS, val: 0x02); /* sig DAC i/o(in:nicam)*/
1209	chip_write(chip, TDA9875_ADCIS, val: 0x6f); /* sig ADC input(in:mono)*/
1210	chip_write(chip, TDA9875_LOSR, val: 0x00); /* line out (in:mono)*/
1211	chip_write(chip, TDA9875_AER, val: 0x00); /*06 Effect (AVL+PSEUDO) */
1212	chip_write(chip, TDA9875_MCS, val: 0x44); /* Main ch select (DAC) */
1213	chip_write(chip, TDA9875_MVL, val: 0x03); /* Vol Main left 10dB */
1214	chip_write(chip, TDA9875_MVR, val: 0x03); /* Vol Main right 10dB*/
1215	chip_write(chip, TDA9875_MBA, val: 0x00); /* Main Bass Main 0dB*/
1216	chip_write(chip, TDA9875_MTR, val: 0x00); /* Main Treble Main 0dB*/
1217	chip_write(chip, TDA9875_ACS, val: 0x44); /* Aux chan select (dac)*/
1218	chip_write(chip, TDA9875_AVL, val: 0x00); /* Vol Aux left 0dB*/
1219	chip_write(chip, TDA9875_AVR, val: 0x00); /* Vol Aux right 0dB*/
1220	chip_write(chip, TDA9875_ABA, val: 0x00); /* Aux Bass Main 0dB*/
1221	chip_write(chip, TDA9875_ATR, val: 0x00); /* Aux Aigus Main 0dB*/
1222
1223	chip_write(chip, TDA9875_MUT, val: 0xcc); /* General mute */
1224	return 0;
1225	}
1226
1227	static int tda9875_volume(int val) { return (unsigned char)(val / 602 - 84); }
1228	static int tda9875_bass(int val) { return (unsigned char)(max(-12, val / 2115 - 15)); }
1229	static int tda9875_treble(int val) { return (unsigned char)(val / 2622 - 12); }
1230
1231	/* ----------------------------------------------------------------------- */
1232
1233
1234	/* *********************** *
1235	* i2c interface functions *
1236	* *********************** */
1237
1238	static int tda9875_checkit(struct CHIPSTATE *chip)
1239	{
1240	struct v4l2_subdev *sd = &chip->sd;
1241	int dic, rev;
1242
1243	dic = chip_read2(chip, subaddr: 254);
1244	if (dic < 0)
1245	return 0;
1246	rev = chip_read2(chip, subaddr: 255);
1247	if (rev < 0)
1248	return 0;
1249
1250	if (dic == 0 || dic == 2) { /* tda9875 and tda9875A */
1251	v4l2_info(sd, "found tda9875%s rev. %d.\n",
1252	dic == 0 ? "" : "A", rev);
1253	return 1;
1254	}
1255	return 0;
1256	}
1257
1258	/* ---------------------------------------------------------------------- */
1259	/* audio chip descriptions - defines+functions for tea6420 */
1260
1261	#define TEA6300_VL 0x00 /* volume left */
1262	#define TEA6300_VR 0x01 /* volume right */
1263	#define TEA6300_BA 0x02 /* bass */
1264	#define TEA6300_TR 0x03 /* treble */
1265	#define TEA6300_FA 0x04 /* fader control */
1266	#define TEA6300_S 0x05 /* switch register */
1267	/* values for those registers: */
1268	#define TEA6300_S_SA 0x01 /* stereo A input */
1269	#define TEA6300_S_SB 0x02 /* stereo B */
1270	#define TEA6300_S_SC 0x04 /* stereo C */
1271	#define TEA6300_S_GMU 0x80 /* general mute */
1272
1273	#define TEA6320_V 0x00 /* volume (0-5)/loudness off (6)/zero crossing mute(7) */
1274	#define TEA6320_FFR 0x01 /* fader front right (0-5) */
1275	#define TEA6320_FFL 0x02 /* fader front left (0-5) */
1276	#define TEA6320_FRR 0x03 /* fader rear right (0-5) */
1277	#define TEA6320_FRL 0x04 /* fader rear left (0-5) */
1278	#define TEA6320_BA 0x05 /* bass (0-4) */
1279	#define TEA6320_TR 0x06 /* treble (0-4) */
1280	#define TEA6320_S 0x07 /* switch register */
1281	/* values for those registers: */
1282	#define TEA6320_S_SA 0x07 /* stereo A input */
1283	#define TEA6320_S_SB 0x06 /* stereo B */
1284	#define TEA6320_S_SC 0x05 /* stereo C */
1285	#define TEA6320_S_SD 0x04 /* stereo D */
1286	#define TEA6320_S_GMU 0x80 /* general mute */
1287
1288	#define TEA6420_S_SA 0x00 /* stereo A input */
1289	#define TEA6420_S_SB 0x01 /* stereo B */
1290	#define TEA6420_S_SC 0x02 /* stereo C */
1291	#define TEA6420_S_SD 0x03 /* stereo D */
1292	#define TEA6420_S_SE 0x04 /* stereo E */
1293	#define TEA6420_S_GMU 0x05 /* general mute */
1294
1295	static int tea6300_shift10(int val) { return val >> 10; }
1296	static int tea6300_shift12(int val) { return val >> 12; }
1297
1298	/* Assumes 16bit input (values 0x3f to 0x0c are unique, values less than */
1299	/* 0x0c mirror those immediately higher) */
1300	static int tea6320_volume(int val) { return (val / (65535/(63-12)) + 12) & 0x3f; }
1301	static int tea6320_shift11(int val) { return val >> 11; }
1302	static int tea6320_initialize(struct CHIPSTATE * chip)
1303	{
1304	chip_write(chip, TEA6320_FFR, val: 0x3f);
1305	chip_write(chip, TEA6320_FFL, val: 0x3f);
1306	chip_write(chip, TEA6320_FRR, val: 0x3f);
1307	chip_write(chip, TEA6320_FRL, val: 0x3f);
1308
1309	return 0;
1310	}
1311
1312
1313	/* ---------------------------------------------------------------------- */
1314	/* audio chip descriptions - defines+functions for tda8425 */
1315
1316	#define TDA8425_VL 0x00 /* volume left */
1317	#define TDA8425_VR 0x01 /* volume right */
1318	#define TDA8425_BA 0x02 /* bass */
1319	#define TDA8425_TR 0x03 /* treble */
1320	#define TDA8425_S1 0x08 /* switch functions */
1321	/* values for those registers: */
1322	#define TDA8425_S1_OFF 0xEE /* audio off (mute on) */
1323	#define TDA8425_S1_CH1 0xCE /* audio channel 1 (mute off) - "linear stereo" mode */
1324	#define TDA8425_S1_CH2 0xCF /* audio channel 2 (mute off) - "linear stereo" mode */
1325	#define TDA8425_S1_MU 0x20 /* mute bit */
1326	#define TDA8425_S1_STEREO 0x18 /* stereo bits */
1327	#define TDA8425_S1_STEREO_SPATIAL 0x18 /* spatial stereo */
1328	#define TDA8425_S1_STEREO_LINEAR 0x08 /* linear stereo */
1329	#define TDA8425_S1_STEREO_PSEUDO 0x10 /* pseudo stereo */
1330	#define TDA8425_S1_STEREO_MONO 0x00 /* forced mono */
1331	#define TDA8425_S1_ML 0x06 /* language selector */
1332	#define TDA8425_S1_ML_SOUND_A 0x02 /* sound a */
1333	#define TDA8425_S1_ML_SOUND_B 0x04 /* sound b */
1334	#define TDA8425_S1_ML_STEREO 0x06 /* stereo */
1335	#define TDA8425_S1_IS 0x01 /* channel selector */
1336
1337
1338	static int tda8425_shift10(int val) { return (val >> 10) | 0xc0; }
1339	static int tda8425_shift12(int val) { return (val >> 12) | 0xf0; }
1340
1341	static void tda8425_setaudmode(struct CHIPSTATE *chip, int mode)
1342	{
1343	int s1 = chip->shadow.bytes[TDA8425_S1+1] & 0xe1;
1344
1345	switch (mode) {
1346	case V4L2_TUNER_MODE_LANG1:
1347	s1 |= TDA8425_S1_ML_SOUND_A;
1348	s1 |= TDA8425_S1_STEREO_PSEUDO;
1349	break;
1350	case V4L2_TUNER_MODE_LANG2:
1351	s1 |= TDA8425_S1_ML_SOUND_B;
1352	s1 |= TDA8425_S1_STEREO_PSEUDO;
1353	break;
1354	case V4L2_TUNER_MODE_LANG1_LANG2:
1355	s1 |= TDA8425_S1_ML_STEREO;
1356	s1 |= TDA8425_S1_STEREO_LINEAR;
1357	break;
1358	case V4L2_TUNER_MODE_MONO:
1359	s1 |= TDA8425_S1_ML_STEREO;
1360	s1 |= TDA8425_S1_STEREO_MONO;
1361	break;
1362	case V4L2_TUNER_MODE_STEREO:
1363	s1 |= TDA8425_S1_ML_STEREO;
1364	s1 |= TDA8425_S1_STEREO_SPATIAL;
1365	break;
1366	default:
1367	return;
1368	}
1369	chip_write(chip,TDA8425_S1,val: s1);
1370	}
1371
1372
1373	/* ---------------------------------------------------------------------- */
1374	/* audio chip descriptions - defines+functions for pic16c54 (PV951) */
1375
1376	/* the registers of 16C54, I2C sub address. */
1377	#define PIC16C54_REG_KEY_CODE 0x01 /* Not use. */
1378	#define PIC16C54_REG_MISC 0x02
1379
1380	/* bit definition of the RESET register, I2C data. */
1381	#define PIC16C54_MISC_RESET_REMOTE_CTL 0x01 /* bit 0, Reset to receive the key */
1382	/* code of remote controller */
1383	#define PIC16C54_MISC_MTS_MAIN 0x02 /* bit 1 */
1384	#define PIC16C54_MISC_MTS_SAP 0x04 /* bit 2 */
1385	#define PIC16C54_MISC_MTS_BOTH 0x08 /* bit 3 */
1386	#define PIC16C54_MISC_SND_MUTE 0x10 /* bit 4, Mute Audio(Line-in and Tuner) */
1387	#define PIC16C54_MISC_SND_NOTMUTE 0x20 /* bit 5 */
1388	#define PIC16C54_MISC_SWITCH_TUNER 0x40 /* bit 6 , Switch to Line-in */
1389	#define PIC16C54_MISC_SWITCH_LINE 0x80 /* bit 7 , Switch to Tuner */
1390
1391	/* ---------------------------------------------------------------------- */
1392	/* audio chip descriptions - defines+functions for TA8874Z */
1393
1394	/* write 1st byte */
1395	#define TA8874Z_LED_STE 0x80
1396	#define TA8874Z_LED_BIL 0x40
1397	#define TA8874Z_LED_EXT 0x20
1398	#define TA8874Z_MONO_SET 0x10
1399	#define TA8874Z_MUTE 0x08
1400	#define TA8874Z_F_MONO 0x04
1401	#define TA8874Z_MODE_SUB 0x02
1402	#define TA8874Z_MODE_MAIN 0x01
1403
1404	/* write 2nd byte */
1405	/*#define TA8874Z_TI 0x80 */ /* test mode */
1406	#define TA8874Z_SEPARATION 0x3f
1407	#define TA8874Z_SEPARATION_DEFAULT 0x10
1408
1409	/* read */
1410	#define TA8874Z_B1 0x80
1411	#define TA8874Z_B0 0x40
1412	#define TA8874Z_CHAG_FLAG 0x20
1413
1414	/*
1415	* B1 B0
1416	* mono L H
1417	* stereo L L
1418	* BIL H L
1419	*/
1420	static int ta8874z_getrxsubchans(struct CHIPSTATE *chip)
1421	{
1422	int val, mode;
1423
1424	mode = V4L2_TUNER_SUB_MONO;
1425
1426	val = chip_read(chip);
1427	if (val < 0)
1428	return mode;
1429
1430	if (val & TA8874Z_B1){
1431	mode |= V4L2_TUNER_SUB_LANG1 | V4L2_TUNER_SUB_LANG2;
1432	}else if (!(val & TA8874Z_B0)){
1433	mode = V4L2_TUNER_SUB_STEREO;
1434	}
1435	/* v4l2_dbg(1, debug, &chip->sd,
1436	"ta8874z_getrxsubchans(): raw chip read: 0x%02x, return: 0x%02x\n",
1437	val, mode); */
1438	return mode;
1439	}
1440
1441	static audiocmd ta8874z_stereo = { 2, {0, TA8874Z_SEPARATION_DEFAULT}};
1442	static audiocmd ta8874z_mono = {2, { TA8874Z_MONO_SET, TA8874Z_SEPARATION_DEFAULT}};
1443	static audiocmd ta8874z_main = {2, { 0, TA8874Z_SEPARATION_DEFAULT}};
1444	static audiocmd ta8874z_sub = {2, { TA8874Z_MODE_SUB, TA8874Z_SEPARATION_DEFAULT}};
1445	static audiocmd ta8874z_both = {2, { TA8874Z_MODE_MAIN | TA8874Z_MODE_SUB, TA8874Z_SEPARATION_DEFAULT}};
1446
1447	static void ta8874z_setaudmode(struct CHIPSTATE *chip, int mode)
1448	{
1449	struct v4l2_subdev *sd = &chip->sd;
1450	int update = 1;
1451	audiocmd *t = NULL;
1452
1453	v4l2_dbg(1, debug, sd, "ta8874z_setaudmode(): mode: 0x%02x\n", mode);
1454
1455	switch(mode){
1456	case V4L2_TUNER_MODE_MONO:
1457	t = &ta8874z_mono;
1458	break;
1459	case V4L2_TUNER_MODE_STEREO:
1460	t = &ta8874z_stereo;
1461	break;
1462	case V4L2_TUNER_MODE_LANG1:
1463	t = &ta8874z_main;
1464	break;
1465	case V4L2_TUNER_MODE_LANG2:
1466	t = &ta8874z_sub;
1467	break;
1468	case V4L2_TUNER_MODE_LANG1_LANG2:
1469	t = &ta8874z_both;
1470	break;
1471	default:
1472	update = 0;
1473	}
1474
1475	if(update)
1476	chip_cmd(chip, name: "TA8874Z", cmd: t);
1477	}
1478
1479	static int ta8874z_checkit(struct CHIPSTATE *chip)
1480	{
1481	int rc;
1482
1483	rc = chip_read(chip);
1484	if (rc < 0)
1485	return rc;
1486
1487	return ((rc & 0x1f) == 0x1f) ? 1 : 0;
1488	}
1489
1490	/* ---------------------------------------------------------------------- */
1491	/* audio chip descriptions - struct CHIPDESC */
1492
1493	/* insmod options to enable/disable individual audio chips */
1494	static int tda8425 = 1;
1495	static int tda9840 = 1;
1496	static int tda9850 = 1;
1497	static int tda9855 = 1;
1498	static int tda9873 = 1;
1499	static int tda9874a = 1;
1500	static int tda9875 = 1;
1501	static int tea6300; /* default 0 - address clash with msp34xx */
1502	static int tea6320; /* default 0 - address clash with msp34xx */
1503	static int tea6420 = 1;
1504	static int pic16c54 = 1;
1505	static int ta8874z; /* default 0 - address clash with tda9840 */
1506
1507	module_param(tda8425, int, 0444);
1508	module_param(tda9840, int, 0444);
1509	module_param(tda9850, int, 0444);
1510	module_param(tda9855, int, 0444);
1511	module_param(tda9873, int, 0444);
1512	module_param(tda9874a, int, 0444);
1513	module_param(tda9875, int, 0444);
1514	module_param(tea6300, int, 0444);
1515	module_param(tea6320, int, 0444);
1516	module_param(tea6420, int, 0444);
1517	module_param(pic16c54, int, 0444);
1518	module_param(ta8874z, int, 0444);
1519
1520	static struct CHIPDESC chiplist[] = {
1521	{
1522	.name = "tda9840",
1523	.insmodopt = &tda9840,
1524	.addr_lo = I2C_ADDR_TDA9840 >> 1,
1525	.addr_hi = I2C_ADDR_TDA9840 >> 1,
1526	.registers = 5,
1527	.flags = CHIP_NEED_CHECKMODE,
1528
1529	/* callbacks */
1530	.checkit = tda9840_checkit,
1531	.getrxsubchans = tda9840_getrxsubchans,
1532	.setaudmode = tda9840_setaudmode,
1533
1534	.init = { .count: 2, .bytes: { TDA9840_TEST, TDA9840_TEST_INT1SN
1535	/* ,TDA9840_SW, TDA9840_MONO */} }
1536	},
1537	{
1538	.name = "tda9873h",
1539	.insmodopt = &tda9873,
1540	.addr_lo = I2C_ADDR_TDA985x_L >> 1,
1541	.addr_hi = I2C_ADDR_TDA985x_H >> 1,
1542	.registers = 3,
1543	.flags = CHIP_HAS_INPUTSEL | CHIP_NEED_CHECKMODE,
1544
1545	/* callbacks */
1546	.checkit = tda9873_checkit,
1547	.getrxsubchans = tda9873_getrxsubchans,
1548	.setaudmode = tda9873_setaudmode,
1549
1550	.init = { .count: 4, .bytes: { TDA9873_SW, 0xa4, 0x06, 0x03 } },
1551	.inputreg = TDA9873_SW,
1552	.inputmute = TDA9873_MUTE | TDA9873_AUTOMUTE,
1553	.inputmap = {0xa0, 0xa2, 0xa0, 0xa0},
1554	.inputmask = TDA9873_INP_MASK|TDA9873_MUTE|TDA9873_AUTOMUTE,
1555
1556	},
1557	{
1558	.name = "tda9874h/a",
1559	.insmodopt = &tda9874a,
1560	.addr_lo = I2C_ADDR_TDA9874 >> 1,
1561	.addr_hi = I2C_ADDR_TDA9874 >> 1,
1562	.flags = CHIP_NEED_CHECKMODE,
1563
1564	/* callbacks */
1565	.initialize = tda9874a_initialize,
1566	.checkit = tda9874a_checkit,
1567	.getrxsubchans = tda9874a_getrxsubchans,
1568	.setaudmode = tda9874a_setaudmode,
1569	},
1570	{
1571	.name = "tda9875",
1572	.insmodopt = &tda9875,
1573	.addr_lo = I2C_ADDR_TDA9875 >> 1,
1574	.addr_hi = I2C_ADDR_TDA9875 >> 1,
1575	.flags = CHIP_HAS_VOLUME | CHIP_HAS_BASSTREBLE,
1576
1577	/* callbacks */
1578	.initialize = tda9875_initialize,
1579	.checkit = tda9875_checkit,
1580	.volfunc = tda9875_volume,
1581	.bassfunc = tda9875_bass,
1582	.treblefunc = tda9875_treble,
1583	.leftreg = TDA9875_MVL,
1584	.rightreg = TDA9875_MVR,
1585	.bassreg = TDA9875_MBA,
1586	.treblereg = TDA9875_MTR,
1587	.volinit = 58880,
1588	},
1589	{
1590	.name = "tda9850",
1591	.insmodopt = &tda9850,
1592	.addr_lo = I2C_ADDR_TDA985x_L >> 1,
1593	.addr_hi = I2C_ADDR_TDA985x_H >> 1,
1594	.registers = 11,
1595
1596	.getrxsubchans = tda985x_getrxsubchans,
1597	.setaudmode = tda985x_setaudmode,
1598
1599	.init = { .count: 8, .bytes: { TDA9850_C4, 0x08, 0x08, TDA985x_STEREO, 0x07, 0x10, 0x10, 0x03 } }
1600	},
1601	{
1602	.name = "tda9855",
1603	.insmodopt = &tda9855,
1604	.addr_lo = I2C_ADDR_TDA985x_L >> 1,
1605	.addr_hi = I2C_ADDR_TDA985x_H >> 1,
1606	.registers = 11,
1607	.flags = CHIP_HAS_VOLUME | CHIP_HAS_BASSTREBLE,
1608
1609	.leftreg = TDA9855_VL,
1610	.rightreg = TDA9855_VR,
1611	.bassreg = TDA9855_BA,
1612	.treblereg = TDA9855_TR,
1613
1614	/* callbacks */
1615	.volfunc = tda9855_volume,
1616	.bassfunc = tda9855_bass,
1617	.treblefunc = tda9855_treble,
1618	.getrxsubchans = tda985x_getrxsubchans,
1619	.setaudmode = tda985x_setaudmode,
1620
1621	.init = { .count: 12, .bytes: { 0, 0x6f, 0x6f, 0x0e, 0x07<<1, 0x8<<2,
1622	TDA9855_MUTE | TDA9855_AVL | TDA9855_LOUD | TDA9855_INT,
1623	TDA985x_STEREO | TDA9855_LINEAR | TDA9855_TZCM | TDA9855_VZCM,
1624	0x07, 0x10, 0x10, 0x03 }}
1625	},
1626	{
1627	.name = "tea6300",
1628	.insmodopt = &tea6300,
1629	.addr_lo = I2C_ADDR_TEA6300 >> 1,
1630	.addr_hi = I2C_ADDR_TEA6300 >> 1,
1631	.registers = 6,
1632	.flags = CHIP_HAS_VOLUME | CHIP_HAS_BASSTREBLE | CHIP_HAS_INPUTSEL,
1633
1634	.leftreg = TEA6300_VR,
1635	.rightreg = TEA6300_VL,
1636	.bassreg = TEA6300_BA,
1637	.treblereg = TEA6300_TR,
1638
1639	/* callbacks */
1640	.volfunc = tea6300_shift10,
1641	.bassfunc = tea6300_shift12,
1642	.treblefunc = tea6300_shift12,
1643
1644	.inputreg = TEA6300_S,
1645	.inputmap = { TEA6300_S_SA, TEA6300_S_SB, TEA6300_S_SC },
1646	.inputmute = TEA6300_S_GMU,
1647	},
1648	{
1649	.name = "tea6320",
1650	.insmodopt = &tea6320,
1651	.addr_lo = I2C_ADDR_TEA6300 >> 1,
1652	.addr_hi = I2C_ADDR_TEA6300 >> 1,
1653	.registers = 8,
1654	.flags = CHIP_HAS_VOLUME | CHIP_HAS_BASSTREBLE | CHIP_HAS_INPUTSEL,
1655
1656	.leftreg = TEA6320_V,
1657	.rightreg = TEA6320_V,
1658	.bassreg = TEA6320_BA,
1659	.treblereg = TEA6320_TR,
1660
1661	/* callbacks */
1662	.initialize = tea6320_initialize,
1663	.volfunc = tea6320_volume,
1664	.bassfunc = tea6320_shift11,
1665	.treblefunc = tea6320_shift11,
1666
1667	.inputreg = TEA6320_S,
1668	.inputmap = { TEA6320_S_SA, TEA6420_S_SB, TEA6300_S_SC, TEA6320_S_SD },
1669	.inputmute = TEA6300_S_GMU,
1670	},
1671	{
1672	.name = "tea6420",
1673	.insmodopt = &tea6420,
1674	.addr_lo = I2C_ADDR_TEA6420 >> 1,
1675	.addr_hi = I2C_ADDR_TEA6420 >> 1,
1676	.registers = 1,
1677	.flags = CHIP_HAS_INPUTSEL,
1678
1679	.inputreg = -1,
1680	.inputmap = { TEA6420_S_SA, TEA6420_S_SB, TEA6420_S_SC },
1681	.inputmute = TEA6420_S_GMU,
1682	.inputmask = 0x07,
1683	},
1684	{
1685	.name = "tda8425",
1686	.insmodopt = &tda8425,
1687	.addr_lo = I2C_ADDR_TDA8425 >> 1,
1688	.addr_hi = I2C_ADDR_TDA8425 >> 1,
1689	.registers = 9,
1690	.flags = CHIP_HAS_VOLUME | CHIP_HAS_BASSTREBLE | CHIP_HAS_INPUTSEL,
1691
1692	.leftreg = TDA8425_VL,
1693	.rightreg = TDA8425_VR,
1694	.bassreg = TDA8425_BA,
1695	.treblereg = TDA8425_TR,
1696
1697	/* callbacks */
1698	.volfunc = tda8425_shift10,
1699	.bassfunc = tda8425_shift12,
1700	.treblefunc = tda8425_shift12,
1701	.setaudmode = tda8425_setaudmode,
1702
1703	.inputreg = TDA8425_S1,
1704	.inputmap = { TDA8425_S1_CH1, TDA8425_S1_CH1, TDA8425_S1_CH1 },
1705	.inputmute = TDA8425_S1_OFF,
1706
1707	},
1708	{
1709	.name = "pic16c54 (PV951)",
1710	.insmodopt = &pic16c54,
1711	.addr_lo = I2C_ADDR_PIC16C54 >> 1,
1712	.addr_hi = I2C_ADDR_PIC16C54>> 1,
1713	.registers = 2,
1714	.flags = CHIP_HAS_INPUTSEL,
1715
1716	.inputreg = PIC16C54_REG_MISC,
1717	.inputmap = {PIC16C54_MISC_SND_NOTMUTE|PIC16C54_MISC_SWITCH_TUNER,
1718	PIC16C54_MISC_SND_NOTMUTE|PIC16C54_MISC_SWITCH_LINE,
1719	PIC16C54_MISC_SND_NOTMUTE|PIC16C54_MISC_SWITCH_LINE,
1720	PIC16C54_MISC_SND_MUTE},
1721	.inputmute = PIC16C54_MISC_SND_MUTE,
1722	},
1723	{
1724	.name = "ta8874z",
1725	.checkit = ta8874z_checkit,
1726	.insmodopt = &ta8874z,
1727	.addr_lo = I2C_ADDR_TDA9840 >> 1,
1728	.addr_hi = I2C_ADDR_TDA9840 >> 1,
1729	.registers = 2,
1730
1731	/* callbacks */
1732	.getrxsubchans = ta8874z_getrxsubchans,
1733	.setaudmode = ta8874z_setaudmode,
1734
1735	.init = {.count: 2, .bytes: { TA8874Z_MONO_SET, TA8874Z_SEPARATION_DEFAULT}},
1736	},
1737	{ .name = NULL } /* EOF */
1738	};
1739
1740
1741	/* ---------------------------------------------------------------------- */
1742
1743	static int tvaudio_s_ctrl(struct v4l2_ctrl *ctrl)
1744	{
1745	struct v4l2_subdev *sd = to_sd(ctrl);
1746	struct CHIPSTATE *chip = to_state(sd);
1747	struct CHIPDESC *desc = chip->desc;
1748
1749	switch (ctrl->id) {
1750	case V4L2_CID_AUDIO_MUTE:
1751	chip->muted = ctrl->val;
1752	if (chip->muted)
1753	chip_write_masked(chip,subaddr: desc->inputreg,val: desc->inputmute,mask: desc->inputmask);
1754	else
1755	chip_write_masked(chip,subaddr: desc->inputreg,
1756	val: desc->inputmap[chip->input],mask: desc->inputmask);
1757	return 0;
1758	case V4L2_CID_AUDIO_VOLUME: {
1759	u32 volume, balance;
1760	u32 left, right;
1761
1762	volume = chip->volume->val;
1763	balance = chip->balance->val;
1764	left = (min(65536U - balance, 32768U) * volume) / 32768U;
1765	right = (min(balance, 32768U) * volume) / 32768U;
1766
1767	chip_write(chip, subaddr: desc->leftreg, val: desc->volfunc(left));
1768	chip_write(chip, subaddr: desc->rightreg, val: desc->volfunc(right));
1769	return 0;
1770	}
1771	case V4L2_CID_AUDIO_BASS:
1772	chip_write(chip, subaddr: desc->bassreg, val: desc->bassfunc(ctrl->val));
1773	return 0;
1774	case V4L2_CID_AUDIO_TREBLE:
1775	chip_write(chip, subaddr: desc->treblereg, val: desc->treblefunc(ctrl->val));
1776	return 0;
1777	}
1778	return -EINVAL;
1779	}
1780
1781
1782	/* ---------------------------------------------------------------------- */
1783	/* video4linux interface */
1784
1785	static int tvaudio_s_radio(struct v4l2_subdev *sd)
1786	{
1787	struct CHIPSTATE *chip = to_state(sd);
1788
1789	chip->radio = 1;
1790	/* del_timer(&chip->wt); */
1791	return 0;
1792	}
1793
1794	static int tvaudio_s_routing(struct v4l2_subdev *sd,
1795	u32 input, u32 output, u32 config)
1796	{
1797	struct CHIPSTATE *chip = to_state(sd);
1798	struct CHIPDESC *desc = chip->desc;
1799
1800	if (!(desc->flags & CHIP_HAS_INPUTSEL))
1801	return 0;
1802	if (input >= 4)
1803	return -EINVAL;
1804	/* There are four inputs: tuner, radio, extern and intern. */
1805	chip->input = input;
1806	if (chip->muted)
1807	return 0;
1808	chip_write_masked(chip, subaddr: desc->inputreg,
1809	val: desc->inputmap[chip->input], mask: desc->inputmask);
1810	return 0;
1811	}
1812
1813	static int tvaudio_s_tuner(struct v4l2_subdev *sd, const struct v4l2_tuner *vt)
1814	{
1815	struct CHIPSTATE *chip = to_state(sd);
1816	struct CHIPDESC *desc = chip->desc;
1817
1818	if (!desc->setaudmode)
1819	return 0;
1820	if (chip->radio)
1821	return 0;
1822
1823	switch (vt->audmode) {
1824	case V4L2_TUNER_MODE_MONO:
1825	case V4L2_TUNER_MODE_STEREO:
1826	case V4L2_TUNER_MODE_LANG1:
1827	case V4L2_TUNER_MODE_LANG2:
1828	case V4L2_TUNER_MODE_LANG1_LANG2:
1829	break;
1830	default:
1831	return -EINVAL;
1832	}
1833	chip->audmode = vt->audmode;
1834
1835	if (chip->thread)
1836	wake_up_process(tsk: chip->thread);
1837	else
1838	desc->setaudmode(chip, vt->audmode);
1839
1840	return 0;
1841	}
1842
1843	static int tvaudio_g_tuner(struct v4l2_subdev *sd, struct v4l2_tuner *vt)
1844	{
1845	struct CHIPSTATE *chip = to_state(sd);
1846	struct CHIPDESC *desc = chip->desc;
1847
1848	if (!desc->getrxsubchans)
1849	return 0;
1850	if (chip->radio)
1851	return 0;
1852
1853	vt->audmode = chip->audmode;
1854	vt->rxsubchans = desc->getrxsubchans(chip);
1855	vt->capability |= V4L2_TUNER_CAP_STEREO |
1856	V4L2_TUNER_CAP_LANG1 | V4L2_TUNER_CAP_LANG2;
1857
1858	return 0;
1859	}
1860
1861	static int tvaudio_s_std(struct v4l2_subdev *sd, v4l2_std_id std)
1862	{
1863	struct CHIPSTATE *chip = to_state(sd);
1864
1865	chip->radio = 0;
1866	return 0;
1867	}
1868
1869	static int tvaudio_s_frequency(struct v4l2_subdev *sd, const struct v4l2_frequency *freq)
1870	{
1871	struct CHIPSTATE *chip = to_state(sd);
1872	struct CHIPDESC *desc = chip->desc;
1873
1874	/* For chips that provide getrxsubchans and setaudmode, and doesn't
1875	automatically follows the stereo carrier, a kthread is
1876	created to set the audio standard. In this case, when then
1877	the video channel is changed, tvaudio starts on MONO mode.
1878	After waiting for 2 seconds, the kernel thread is called,
1879	to follow whatever audio standard is pointed by the
1880	audio carrier.
1881	*/
1882	if (chip->thread) {
1883	desc->setaudmode(chip, V4L2_TUNER_MODE_MONO);
1884	chip->prevmode = -1; /* reset previous mode */
1885	mod_timer(timer: &chip->wt, expires: jiffies+msecs_to_jiffies(m: 2000));
1886	}
1887	return 0;
1888	}
1889
1890	static int tvaudio_log_status(struct v4l2_subdev *sd)
1891	{
1892	struct CHIPSTATE *chip = to_state(sd);
1893	struct CHIPDESC *desc = chip->desc;
1894
1895	v4l2_info(sd, "Chip: %s\n", desc->name);
1896	v4l2_ctrl_handler_log_status(hdl: &chip->hdl, prefix: sd->name);
1897	return 0;
1898	}
1899
1900	/* ----------------------------------------------------------------------- */
1901
1902	static const struct v4l2_ctrl_ops tvaudio_ctrl_ops = {
1903	.s_ctrl = tvaudio_s_ctrl,
1904	};
1905
1906	static const struct v4l2_subdev_core_ops tvaudio_core_ops = {
1907	.log_status = tvaudio_log_status,
1908	};
1909
1910	static const struct v4l2_subdev_tuner_ops tvaudio_tuner_ops = {
1911	.s_radio = tvaudio_s_radio,
1912	.s_frequency = tvaudio_s_frequency,
1913	.s_tuner = tvaudio_s_tuner,
1914	.g_tuner = tvaudio_g_tuner,
1915	};
1916
1917	static const struct v4l2_subdev_audio_ops tvaudio_audio_ops = {
1918	.s_routing = tvaudio_s_routing,
1919	};
1920
1921	static const struct v4l2_subdev_video_ops tvaudio_video_ops = {
1922	.s_std = tvaudio_s_std,
1923	};
1924
1925	static const struct v4l2_subdev_ops tvaudio_ops = {
1926	.core = &tvaudio_core_ops,
1927	.tuner = &tvaudio_tuner_ops,
1928	.audio = &tvaudio_audio_ops,
1929	.video = &tvaudio_video_ops,
1930	};
1931
1932	/* ----------------------------------------------------------------------- */
1933
1934
1935	/* i2c registration */
1936
1937	static int tvaudio_probe(struct i2c_client *client)
1938	{
1939	const struct i2c_device_id *id = i2c_client_get_device_id(client);
1940	struct CHIPSTATE *chip;
1941	struct CHIPDESC *desc;
1942	struct v4l2_subdev *sd;
1943
1944	if (debug) {
1945	printk(KERN_INFO "tvaudio: TV audio decoder + audio/video mux driver\n");
1946	printk(KERN_INFO "tvaudio: known chips: ");
1947	for (desc = chiplist; desc->name != NULL; desc++)
1948	printk(KERN_CONT "%s%s",
1949	(desc == chiplist) ? "" : ", ", desc->name);
1950	printk(KERN_CONT "\n");
1951	}
1952
1953	chip = devm_kzalloc(dev: &client->dev, size: sizeof(*chip), GFP_KERNEL);
1954	if (!chip)
1955	return -ENOMEM;
1956	sd = &chip->sd;
1957	v4l2_i2c_subdev_init(sd, client, ops: &tvaudio_ops);
1958
1959	/* find description for the chip */
1960	v4l2_dbg(1, debug, sd, "chip found @ 0x%x\n", client->addr<<1);
1961	for (desc = chiplist; desc->name != NULL; desc++) {
1962	if (0 == *(desc->insmodopt))
1963	continue;
1964	if (client->addr < desc->addr_lo ||
1965	client->addr > desc->addr_hi)
1966	continue;
1967	if (desc->checkit && !desc->checkit(chip))
1968	continue;
1969	break;
1970	}
1971	if (desc->name == NULL) {
1972	v4l2_dbg(1, debug, sd, "no matching chip description found\n");
1973	return -EIO;
1974	}
1975	v4l2_info(sd, "%s found @ 0x%x (%s)\n", desc->name, client->addr<<1, client->adapter->name);
1976	if (desc->flags) {
1977	v4l2_dbg(1, debug, sd, "matches:%s%s%s.\n",
1978	(desc->flags & CHIP_HAS_VOLUME) ? " volume" : "",
1979	(desc->flags & CHIP_HAS_BASSTREBLE) ? " bass/treble" : "",
1980	(desc->flags & CHIP_HAS_INPUTSEL) ? " audiomux" : "");
1981	}
1982
1983	/* fill required data structures */
1984	if (!id)
1985	strscpy(client->name, desc->name, I2C_NAME_SIZE);
1986	chip->desc = desc;
1987	chip->shadow.count = desc->registers+1;
1988	chip->prevmode = -1;
1989	chip->audmode = V4L2_TUNER_MODE_LANG1;
1990
1991	/* initialization */
1992	if (desc->initialize != NULL)
1993	desc->initialize(chip);
1994	else
1995	chip_cmd(chip, name: "init", cmd: &desc->init);
1996
1997	v4l2_ctrl_handler_init(&chip->hdl, 5);
1998	if (desc->flags & CHIP_HAS_INPUTSEL)
1999	v4l2_ctrl_new_std(hdl: &chip->hdl, ops: &tvaudio_ctrl_ops,
2000	V4L2_CID_AUDIO_MUTE, min: 0, max: 1, step: 1, def: 0);
2001	if (desc->flags & CHIP_HAS_VOLUME) {
2002	if (!desc->volfunc) {
2003	/* This shouldn't be happen. Warn user, but keep working
2004	without volume controls
2005	*/
2006	v4l2_info(sd, "volume callback undefined!\n");
2007	desc->flags &= ~CHIP_HAS_VOLUME;
2008	} else {
2009	chip->volume = v4l2_ctrl_new_std(hdl: &chip->hdl,
2010	ops: &tvaudio_ctrl_ops, V4L2_CID_AUDIO_VOLUME,
2011	min: 0, max: 65535, step: 65535 / 100,
2012	def: desc->volinit ? desc->volinit : 65535);
2013	chip->balance = v4l2_ctrl_new_std(hdl: &chip->hdl,
2014	ops: &tvaudio_ctrl_ops, V4L2_CID_AUDIO_BALANCE,
2015	min: 0, max: 65535, step: 65535 / 100, def: 32768);
2016	v4l2_ctrl_cluster(ncontrols: 2, controls: &chip->volume);
2017	}
2018	}
2019	if (desc->flags & CHIP_HAS_BASSTREBLE) {
2020	if (!desc->bassfunc || !desc->treblefunc) {
2021	/* This shouldn't be happen. Warn user, but keep working
2022	without bass/treble controls
2023	*/
2024	v4l2_info(sd, "bass/treble callbacks undefined!\n");
2025	desc->flags &= ~CHIP_HAS_BASSTREBLE;
2026	} else {
2027	v4l2_ctrl_new_std(hdl: &chip->hdl,
2028	ops: &tvaudio_ctrl_ops, V4L2_CID_AUDIO_BASS,
2029	min: 0, max: 65535, step: 65535 / 100,
2030	def: desc->bassinit ? desc->bassinit : 32768);
2031	v4l2_ctrl_new_std(hdl: &chip->hdl,
2032	ops: &tvaudio_ctrl_ops, V4L2_CID_AUDIO_TREBLE,
2033	min: 0, max: 65535, step: 65535 / 100,
2034	def: desc->trebleinit ? desc->trebleinit : 32768);
2035	}
2036	}
2037
2038	sd->ctrl_handler = &chip->hdl;
2039	if (chip->hdl.error) {
2040	int err = chip->hdl.error;
2041
2042	v4l2_ctrl_handler_free(hdl: &chip->hdl);
2043	return err;
2044	}
2045	/* set controls to the default values */
2046	v4l2_ctrl_handler_setup(hdl: &chip->hdl);
2047
2048	chip->thread = NULL;
2049	timer_setup(&chip->wt, chip_thread_wake, 0);
2050	if (desc->flags & CHIP_NEED_CHECKMODE) {
2051	if (!desc->getrxsubchans || !desc->setaudmode) {
2052	/* This shouldn't be happen. Warn user, but keep working
2053	without kthread
2054	*/
2055	v4l2_info(sd, "set/get mode callbacks undefined!\n");
2056	return 0;
2057	}
2058	/* start async thread */
2059	chip->thread = kthread_run(chip_thread, chip, "%s",
2060	client->name);
2061	if (IS_ERR(ptr: chip->thread)) {
2062	v4l2_warn(sd, "failed to create kthread\n");
2063	chip->thread = NULL;
2064	}
2065	}
2066	return 0;
2067	}
2068
2069	static void tvaudio_remove(struct i2c_client *client)
2070	{
2071	struct v4l2_subdev *sd = i2c_get_clientdata(client);
2072	struct CHIPSTATE *chip = to_state(sd);
2073
2074	del_timer_sync(timer: &chip->wt);
2075	if (chip->thread) {
2076	/* shutdown async thread */
2077	kthread_stop(k: chip->thread);
2078	chip->thread = NULL;
2079	}
2080
2081	v4l2_device_unregister_subdev(sd);
2082	v4l2_ctrl_handler_free(hdl: &chip->hdl);
2083	}
2084
2085	/* This driver supports many devices and the idea is to let the driver
2086	detect which device is present. So rather than listing all supported
2087	devices here, we pretend to support a single, fake device type. */
2088	static const struct i2c_device_id tvaudio_id[] = {
2089	{ "tvaudio", 0 },
2090	{ }
2091	};
2092	MODULE_DEVICE_TABLE(i2c, tvaudio_id);
2093
2094	static struct i2c_driver tvaudio_driver = {
2095	.driver = {
2096	.name = "tvaudio",
2097	},
2098	.probe = tvaudio_probe,
2099	.remove = tvaudio_remove,
2100	.id_table = tvaudio_id,
2101	};
2102
2103	module_i2c_driver(tvaudio_driver);
2104