1	// SPDX-License-Identifier: GPL-2.0-only
2	/*
3	* Copyright (C) 2008, Creative Technology Ltd. All Rights Reserved.
4	*
5	* @File cthw20k2.c
6	*
7	* @Brief
8	* This file contains the implementation of hardware access method for 20k2.
9	*
10	* @Author Liu Chun
11	* @Date May 14 2008
12	*/
13
14	#include <linux/types.h>
15	#include <linux/slab.h>
16	#include <linux/pci.h>
17	#include <linux/io.h>
18	#include <linux/string.h>
19	#include <linux/kernel.h>
20	#include <linux/interrupt.h>
21	#include <linux/delay.h>
22	#include "cthw20k2.h"
23	#include "ct20k2reg.h"
24
25	struct hw20k2 {
26	struct hw hw;
27	/* for i2c */
28	unsigned char dev_id;
29	unsigned char addr_size;
30	unsigned char data_size;
31
32	int mic_source;
33	};
34
35	static u32 hw_read_20kx(struct hw *hw, u32 reg);
36	static void hw_write_20kx(struct hw *hw, u32 reg, u32 data);
37
38	/*
39	* Type definition block.
40	* The layout of control structures can be directly applied on 20k2 chip.
41	*/
42
43	/*
44	* SRC control block definitions.
45	*/
46
47	/* SRC resource control block */
48	#define SRCCTL_STATE 0x00000007
49	#define SRCCTL_BM 0x00000008
50	#define SRCCTL_RSR 0x00000030
51	#define SRCCTL_SF 0x000001C0
52	#define SRCCTL_WR 0x00000200
53	#define SRCCTL_PM 0x00000400
54	#define SRCCTL_ROM 0x00001800
55	#define SRCCTL_VO 0x00002000
56	#define SRCCTL_ST 0x00004000
57	#define SRCCTL_IE 0x00008000
58	#define SRCCTL_ILSZ 0x000F0000
59	#define SRCCTL_BP 0x00100000
60
61	#define SRCCCR_CISZ 0x000007FF
62	#define SRCCCR_CWA 0x001FF800
63	#define SRCCCR_D 0x00200000
64	#define SRCCCR_RS 0x01C00000
65	#define SRCCCR_NAL 0x3E000000
66	#define SRCCCR_RA 0xC0000000
67
68	#define SRCCA_CA 0x0FFFFFFF
69	#define SRCCA_RS 0xE0000000
70
71	#define SRCSA_SA 0x0FFFFFFF
72
73	#define SRCLA_LA 0x0FFFFFFF
74
75	/* Mixer Parameter Ring ram Low and Hight register.
76	* Fixed-point value in 8.24 format for parameter channel */
77	#define MPRLH_PITCH 0xFFFFFFFF
78
79	/* SRC resource register dirty flags */
80	union src_dirty {
81	struct {
82	u16 ctl:1;
83	u16 ccr:1;
84	u16 sa:1;
85	u16 la:1;
86	u16 ca:1;
87	u16 mpr:1;
88	u16 czbfs:1; /* Clear Z-Buffers */
89	u16 rsv:9;
90	} bf;
91	u16 data;
92	};
93
94	struct src_rsc_ctrl_blk {
95	unsigned int ctl;
96	unsigned int ccr;
97	unsigned int ca;
98	unsigned int sa;
99	unsigned int la;
100	unsigned int mpr;
101	union src_dirty dirty;
102	};
103
104	/* SRC manager control block */
105	union src_mgr_dirty {
106	struct {
107	u16 enb0:1;
108	u16 enb1:1;
109	u16 enb2:1;
110	u16 enb3:1;
111	u16 enb4:1;
112	u16 enb5:1;
113	u16 enb6:1;
114	u16 enb7:1;
115	u16 enbsa:1;
116	u16 rsv:7;
117	} bf;
118	u16 data;
119	};
120
121	struct src_mgr_ctrl_blk {
122	unsigned int enbsa;
123	unsigned int enb[8];
124	union src_mgr_dirty dirty;
125	};
126
127	/* SRCIMP manager control block */
128	#define SRCAIM_ARC 0x00000FFF
129	#define SRCAIM_NXT 0x00FF0000
130	#define SRCAIM_SRC 0xFF000000
131
132	struct srcimap {
133	unsigned int srcaim;
134	unsigned int idx;
135	};
136
137	/* SRCIMP manager register dirty flags */
138	union srcimp_mgr_dirty {
139	struct {
140	u16 srcimap:1;
141	u16 rsv:15;
142	} bf;
143	u16 data;
144	};
145
146	struct srcimp_mgr_ctrl_blk {
147	struct srcimap srcimap;
148	union srcimp_mgr_dirty dirty;
149	};
150
151	/*
152	* Function implementation block.
153	*/
154
155	static int src_get_rsc_ctrl_blk(void **rblk)
156	{
157	struct src_rsc_ctrl_blk *blk;
158
159	*rblk = NULL;
160	blk = kzalloc(size: sizeof(*blk), GFP_KERNEL);
161	if (!blk)
162	return -ENOMEM;
163
164	*rblk = blk;
165
166	return 0;
167	}
168
169	static int src_put_rsc_ctrl_blk(void *blk)
170	{
171	kfree(objp: blk);
172
173	return 0;
174	}
175
176	static int src_set_state(void *blk, unsigned int state)
177	{
178	struct src_rsc_ctrl_blk *ctl = blk;
179
180	set_field(data: &ctl->ctl, SRCCTL_STATE, value: state);
181	ctl->dirty.bf.ctl = 1;
182	return 0;
183	}
184
185	static int src_set_bm(void *blk, unsigned int bm)
186	{
187	struct src_rsc_ctrl_blk *ctl = blk;
188
189	set_field(data: &ctl->ctl, SRCCTL_BM, value: bm);
190	ctl->dirty.bf.ctl = 1;
191	return 0;
192	}
193
194	static int src_set_rsr(void *blk, unsigned int rsr)
195	{
196	struct src_rsc_ctrl_blk *ctl = blk;
197
198	set_field(data: &ctl->ctl, SRCCTL_RSR, value: rsr);
199	ctl->dirty.bf.ctl = 1;
200	return 0;
201	}
202
203	static int src_set_sf(void *blk, unsigned int sf)
204	{
205	struct src_rsc_ctrl_blk *ctl = blk;
206
207	set_field(data: &ctl->ctl, SRCCTL_SF, value: sf);
208	ctl->dirty.bf.ctl = 1;
209	return 0;
210	}
211
212	static int src_set_wr(void *blk, unsigned int wr)
213	{
214	struct src_rsc_ctrl_blk *ctl = blk;
215
216	set_field(data: &ctl->ctl, SRCCTL_WR, value: wr);
217	ctl->dirty.bf.ctl = 1;
218	return 0;
219	}
220
221	static int src_set_pm(void *blk, unsigned int pm)
222	{
223	struct src_rsc_ctrl_blk *ctl = blk;
224
225	set_field(data: &ctl->ctl, SRCCTL_PM, value: pm);
226	ctl->dirty.bf.ctl = 1;
227	return 0;
228	}
229
230	static int src_set_rom(void *blk, unsigned int rom)
231	{
232	struct src_rsc_ctrl_blk *ctl = blk;
233
234	set_field(data: &ctl->ctl, SRCCTL_ROM, value: rom);
235	ctl->dirty.bf.ctl = 1;
236	return 0;
237	}
238
239	static int src_set_vo(void *blk, unsigned int vo)
240	{
241	struct src_rsc_ctrl_blk *ctl = blk;
242
243	set_field(data: &ctl->ctl, SRCCTL_VO, value: vo);
244	ctl->dirty.bf.ctl = 1;
245	return 0;
246	}
247
248	static int src_set_st(void *blk, unsigned int st)
249	{
250	struct src_rsc_ctrl_blk *ctl = blk;
251
252	set_field(data: &ctl->ctl, SRCCTL_ST, value: st);
253	ctl->dirty.bf.ctl = 1;
254	return 0;
255	}
256
257	static int src_set_ie(void *blk, unsigned int ie)
258	{
259	struct src_rsc_ctrl_blk *ctl = blk;
260
261	set_field(data: &ctl->ctl, SRCCTL_IE, value: ie);
262	ctl->dirty.bf.ctl = 1;
263	return 0;
264	}
265
266	static int src_set_ilsz(void *blk, unsigned int ilsz)
267	{
268	struct src_rsc_ctrl_blk *ctl = blk;
269
270	set_field(data: &ctl->ctl, SRCCTL_ILSZ, value: ilsz);
271	ctl->dirty.bf.ctl = 1;
272	return 0;
273	}
274
275	static int src_set_bp(void *blk, unsigned int bp)
276	{
277	struct src_rsc_ctrl_blk *ctl = blk;
278
279	set_field(data: &ctl->ctl, SRCCTL_BP, value: bp);
280	ctl->dirty.bf.ctl = 1;
281	return 0;
282	}
283
284	static int src_set_cisz(void *blk, unsigned int cisz)
285	{
286	struct src_rsc_ctrl_blk *ctl = blk;
287
288	set_field(data: &ctl->ccr, SRCCCR_CISZ, value: cisz);
289	ctl->dirty.bf.ccr = 1;
290	return 0;
291	}
292
293	static int src_set_ca(void *blk, unsigned int ca)
294	{
295	struct src_rsc_ctrl_blk *ctl = blk;
296
297	set_field(data: &ctl->ca, SRCCA_CA, value: ca);
298	ctl->dirty.bf.ca = 1;
299	return 0;
300	}
301
302	static int src_set_sa(void *blk, unsigned int sa)
303	{
304	struct src_rsc_ctrl_blk *ctl = blk;
305
306	set_field(data: &ctl->sa, SRCSA_SA, value: sa);
307	ctl->dirty.bf.sa = 1;
308	return 0;
309	}
310
311	static int src_set_la(void *blk, unsigned int la)
312	{
313	struct src_rsc_ctrl_blk *ctl = blk;
314
315	set_field(data: &ctl->la, SRCLA_LA, value: la);
316	ctl->dirty.bf.la = 1;
317	return 0;
318	}
319
320	static int src_set_pitch(void *blk, unsigned int pitch)
321	{
322	struct src_rsc_ctrl_blk *ctl = blk;
323
324	set_field(data: &ctl->mpr, MPRLH_PITCH, value: pitch);
325	ctl->dirty.bf.mpr = 1;
326	return 0;
327	}
328
329	static int src_set_clear_zbufs(void *blk, unsigned int clear)
330	{
331	((struct src_rsc_ctrl_blk *)blk)->dirty.bf.czbfs = (clear ? 1 : 0);
332	return 0;
333	}
334
335	static int src_set_dirty(void *blk, unsigned int flags)
336	{
337	((struct src_rsc_ctrl_blk *)blk)->dirty.data = (flags & 0xffff);
338	return 0;
339	}
340
341	static int src_set_dirty_all(void *blk)
342	{
343	((struct src_rsc_ctrl_blk *)blk)->dirty.data = ~(0x0);
344	return 0;
345	}
346
347	#define AR_SLOT_SIZE 4096
348	#define AR_SLOT_BLOCK_SIZE 16
349	#define AR_PTS_PITCH 6
350	#define AR_PARAM_SRC_OFFSET 0x60
351
352	static unsigned int src_param_pitch_mixer(unsigned int src_idx)
353	{
354	return ((src_idx << 4) + AR_PTS_PITCH + AR_SLOT_SIZE
355	- AR_PARAM_SRC_OFFSET) % AR_SLOT_SIZE;
356
357	}
358
359	static int src_commit_write(struct hw *hw, unsigned int idx, void *blk)
360	{
361	struct src_rsc_ctrl_blk *ctl = blk;
362	int i;
363
364	if (ctl->dirty.bf.czbfs) {
365	/* Clear Z-Buffer registers */
366	for (i = 0; i < 8; i++)
367	hw_write_20kx(hw, SRC_UPZ+idx*0x100+i*0x4, data: 0);
368
369	for (i = 0; i < 4; i++)
370	hw_write_20kx(hw, SRC_DN0Z+idx*0x100+i*0x4, data: 0);
371
372	for (i = 0; i < 8; i++)
373	hw_write_20kx(hw, SRC_DN1Z+idx*0x100+i*0x4, data: 0);
374
375	ctl->dirty.bf.czbfs = 0;
376	}
377	if (ctl->dirty.bf.mpr) {
378	/* Take the parameter mixer resource in the same group as that
379	* the idx src is in for simplicity. Unlike src, all conjugate
380	* parameter mixer resources must be programmed for
381	* corresponding conjugate src resources. */
382	unsigned int pm_idx = src_param_pitch_mixer(src_idx: idx);
383	hw_write_20kx(hw, MIXER_PRING_LO_HI+4*pm_idx, data: ctl->mpr);
384	hw_write_20kx(hw, MIXER_PMOPLO+8*pm_idx, data: 0x3);
385	hw_write_20kx(hw, MIXER_PMOPHI+8*pm_idx, data: 0x0);
386	ctl->dirty.bf.mpr = 0;
387	}
388	if (ctl->dirty.bf.sa) {
389	hw_write_20kx(hw, SRC_SA+idx*0x100, data: ctl->sa);
390	ctl->dirty.bf.sa = 0;
391	}
392	if (ctl->dirty.bf.la) {
393	hw_write_20kx(hw, SRC_LA+idx*0x100, data: ctl->la);
394	ctl->dirty.bf.la = 0;
395	}
396	if (ctl->dirty.bf.ca) {
397	hw_write_20kx(hw, SRC_CA+idx*0x100, data: ctl->ca);
398	ctl->dirty.bf.ca = 0;
399	}
400
401	/* Write srccf register */
402	hw_write_20kx(hw, SRC_CF+idx*0x100, data: 0x0);
403
404	if (ctl->dirty.bf.ccr) {
405	hw_write_20kx(hw, SRC_CCR+idx*0x100, data: ctl->ccr);
406	ctl->dirty.bf.ccr = 0;
407	}
408	if (ctl->dirty.bf.ctl) {
409	hw_write_20kx(hw, SRC_CTL+idx*0x100, data: ctl->ctl);
410	ctl->dirty.bf.ctl = 0;
411	}
412
413	return 0;
414	}
415
416	static int src_get_ca(struct hw *hw, unsigned int idx, void *blk)
417	{
418	struct src_rsc_ctrl_blk *ctl = blk;
419
420	ctl->ca = hw_read_20kx(hw, SRC_CA+idx*0x100);
421	ctl->dirty.bf.ca = 0;
422
423	return get_field(data: ctl->ca, SRCCA_CA);
424	}
425
426	static unsigned int src_get_dirty(void *blk)
427	{
428	return ((struct src_rsc_ctrl_blk *)blk)->dirty.data;
429	}
430
431	static unsigned int src_dirty_conj_mask(void)
432	{
433	return 0x20;
434	}
435
436	static int src_mgr_enbs_src(void *blk, unsigned int idx)
437	{
438	((struct src_mgr_ctrl_blk *)blk)->enbsa |= (0x1 << ((idx%128)/4));
439	((struct src_mgr_ctrl_blk *)blk)->dirty.bf.enbsa = 1;
440	((struct src_mgr_ctrl_blk *)blk)->enb[idx/32] |= (0x1 << (idx%32));
441	return 0;
442	}
443
444	static int src_mgr_enb_src(void *blk, unsigned int idx)
445	{
446	((struct src_mgr_ctrl_blk *)blk)->enb[idx/32] |= (0x1 << (idx%32));
447	((struct src_mgr_ctrl_blk *)blk)->dirty.data |= (0x1 << (idx/32));
448	return 0;
449	}
450
451	static int src_mgr_dsb_src(void *blk, unsigned int idx)
452	{
453	((struct src_mgr_ctrl_blk *)blk)->enb[idx/32] &= ~(0x1 << (idx%32));
454	((struct src_mgr_ctrl_blk *)blk)->dirty.data |= (0x1 << (idx/32));
455	return 0;
456	}
457
458	static int src_mgr_commit_write(struct hw *hw, void *blk)
459	{
460	struct src_mgr_ctrl_blk *ctl = blk;
461	int i;
462	unsigned int ret;
463
464	if (ctl->dirty.bf.enbsa) {
465	do {
466	ret = hw_read_20kx(hw, SRC_ENBSTAT);
467	} while (ret & 0x1);
468	hw_write_20kx(hw, SRC_ENBSA, data: ctl->enbsa);
469	ctl->dirty.bf.enbsa = 0;
470	}
471	for (i = 0; i < 8; i++) {
472	if ((ctl->dirty.data & (0x1 << i))) {
473	hw_write_20kx(hw, SRC_ENB+(i*0x100), data: ctl->enb[i]);
474	ctl->dirty.data &= ~(0x1 << i);
475	}
476	}
477
478	return 0;
479	}
480
481	static int src_mgr_get_ctrl_blk(void **rblk)
482	{
483	struct src_mgr_ctrl_blk *blk;
484
485	*rblk = NULL;
486	blk = kzalloc(size: sizeof(*blk), GFP_KERNEL);
487	if (!blk)
488	return -ENOMEM;
489
490	*rblk = blk;
491
492	return 0;
493	}
494
495	static int src_mgr_put_ctrl_blk(void *blk)
496	{
497	kfree(objp: blk);
498
499	return 0;
500	}
501
502	static int srcimp_mgr_get_ctrl_blk(void **rblk)
503	{
504	struct srcimp_mgr_ctrl_blk *blk;
505
506	*rblk = NULL;
507	blk = kzalloc(size: sizeof(*blk), GFP_KERNEL);
508	if (!blk)
509	return -ENOMEM;
510
511	*rblk = blk;
512
513	return 0;
514	}
515
516	static int srcimp_mgr_put_ctrl_blk(void *blk)
517	{
518	kfree(objp: blk);
519
520	return 0;
521	}
522
523	static int srcimp_mgr_set_imaparc(void *blk, unsigned int slot)
524	{
525	struct srcimp_mgr_ctrl_blk *ctl = blk;
526
527	set_field(data: &ctl->srcimap.srcaim, SRCAIM_ARC, value: slot);
528	ctl->dirty.bf.srcimap = 1;
529	return 0;
530	}
531
532	static int srcimp_mgr_set_imapuser(void *blk, unsigned int user)
533	{
534	struct srcimp_mgr_ctrl_blk *ctl = blk;
535
536	set_field(data: &ctl->srcimap.srcaim, SRCAIM_SRC, value: user);
537	ctl->dirty.bf.srcimap = 1;
538	return 0;
539	}
540
541	static int srcimp_mgr_set_imapnxt(void *blk, unsigned int next)
542	{
543	struct srcimp_mgr_ctrl_blk *ctl = blk;
544
545	set_field(data: &ctl->srcimap.srcaim, SRCAIM_NXT, value: next);
546	ctl->dirty.bf.srcimap = 1;
547	return 0;
548	}
549
550	static int srcimp_mgr_set_imapaddr(void *blk, unsigned int addr)
551	{
552	((struct srcimp_mgr_ctrl_blk *)blk)->srcimap.idx = addr;
553	((struct srcimp_mgr_ctrl_blk *)blk)->dirty.bf.srcimap = 1;
554	return 0;
555	}
556
557	static int srcimp_mgr_commit_write(struct hw *hw, void *blk)
558	{
559	struct srcimp_mgr_ctrl_blk *ctl = blk;
560
561	if (ctl->dirty.bf.srcimap) {
562	hw_write_20kx(hw, SRC_IMAP+ctl->srcimap.idx*0x100,
563	data: ctl->srcimap.srcaim);
564	ctl->dirty.bf.srcimap = 0;
565	}
566
567	return 0;
568	}
569
570	/*
571	* AMIXER control block definitions.
572	*/
573
574	#define AMOPLO_M 0x00000003
575	#define AMOPLO_IV 0x00000004
576	#define AMOPLO_X 0x0003FFF0
577	#define AMOPLO_Y 0xFFFC0000
578
579	#define AMOPHI_SADR 0x000000FF
580	#define AMOPHI_SE 0x80000000
581
582	/* AMIXER resource register dirty flags */
583	union amixer_dirty {
584	struct {
585	u16 amoplo:1;
586	u16 amophi:1;
587	u16 rsv:14;
588	} bf;
589	u16 data;
590	};
591
592	/* AMIXER resource control block */
593	struct amixer_rsc_ctrl_blk {
594	unsigned int amoplo;
595	unsigned int amophi;
596	union amixer_dirty dirty;
597	};
598
599	static int amixer_set_mode(void *blk, unsigned int mode)
600	{
601	struct amixer_rsc_ctrl_blk *ctl = blk;
602
603	set_field(data: &ctl->amoplo, AMOPLO_M, value: mode);
604	ctl->dirty.bf.amoplo = 1;
605	return 0;
606	}
607
608	static int amixer_set_iv(void *blk, unsigned int iv)
609	{
610	struct amixer_rsc_ctrl_blk *ctl = blk;
611
612	set_field(data: &ctl->amoplo, AMOPLO_IV, value: iv);
613	ctl->dirty.bf.amoplo = 1;
614	return 0;
615	}
616
617	static int amixer_set_x(void *blk, unsigned int x)
618	{
619	struct amixer_rsc_ctrl_blk *ctl = blk;
620
621	set_field(data: &ctl->amoplo, AMOPLO_X, value: x);
622	ctl->dirty.bf.amoplo = 1;
623	return 0;
624	}
625
626	static int amixer_set_y(void *blk, unsigned int y)
627	{
628	struct amixer_rsc_ctrl_blk *ctl = blk;
629
630	set_field(data: &ctl->amoplo, AMOPLO_Y, value: y);
631	ctl->dirty.bf.amoplo = 1;
632	return 0;
633	}
634
635	static int amixer_set_sadr(void *blk, unsigned int sadr)
636	{
637	struct amixer_rsc_ctrl_blk *ctl = blk;
638
639	set_field(data: &ctl->amophi, AMOPHI_SADR, value: sadr);
640	ctl->dirty.bf.amophi = 1;
641	return 0;
642	}
643
644	static int amixer_set_se(void *blk, unsigned int se)
645	{
646	struct amixer_rsc_ctrl_blk *ctl = blk;
647
648	set_field(data: &ctl->amophi, AMOPHI_SE, value: se);
649	ctl->dirty.bf.amophi = 1;
650	return 0;
651	}
652
653	static int amixer_set_dirty(void *blk, unsigned int flags)
654	{
655	((struct amixer_rsc_ctrl_blk *)blk)->dirty.data = (flags & 0xffff);
656	return 0;
657	}
658
659	static int amixer_set_dirty_all(void *blk)
660	{
661	((struct amixer_rsc_ctrl_blk *)blk)->dirty.data = ~(0x0);
662	return 0;
663	}
664
665	static int amixer_commit_write(struct hw *hw, unsigned int idx, void *blk)
666	{
667	struct amixer_rsc_ctrl_blk *ctl = blk;
668
669	if (ctl->dirty.bf.amoplo || ctl->dirty.bf.amophi) {
670	hw_write_20kx(hw, MIXER_AMOPLO+idx*8, data: ctl->amoplo);
671	ctl->dirty.bf.amoplo = 0;
672	hw_write_20kx(hw, MIXER_AMOPHI+idx*8, data: ctl->amophi);
673	ctl->dirty.bf.amophi = 0;
674	}
675
676	return 0;
677	}
678
679	static int amixer_get_y(void *blk)
680	{
681	struct amixer_rsc_ctrl_blk *ctl = blk;
682
683	return get_field(data: ctl->amoplo, AMOPLO_Y);
684	}
685
686	static unsigned int amixer_get_dirty(void *blk)
687	{
688	return ((struct amixer_rsc_ctrl_blk *)blk)->dirty.data;
689	}
690
691	static int amixer_rsc_get_ctrl_blk(void **rblk)
692	{
693	struct amixer_rsc_ctrl_blk *blk;
694
695	*rblk = NULL;
696	blk = kzalloc(size: sizeof(*blk), GFP_KERNEL);
697	if (!blk)
698	return -ENOMEM;
699
700	*rblk = blk;
701
702	return 0;
703	}
704
705	static int amixer_rsc_put_ctrl_blk(void *blk)
706	{
707	kfree(objp: blk);
708
709	return 0;
710	}
711
712	static int amixer_mgr_get_ctrl_blk(void **rblk)
713	{
714	*rblk = NULL;
715
716	return 0;
717	}
718
719	static int amixer_mgr_put_ctrl_blk(void *blk)
720	{
721	return 0;
722	}
723
724	/*
725	* DAIO control block definitions.
726	*/
727
728	/* Receiver Sample Rate Tracker Control register */
729	#define SRTCTL_SRCO 0x000000FF
730	#define SRTCTL_SRCM 0x0000FF00
731	#define SRTCTL_RSR 0x00030000
732	#define SRTCTL_DRAT 0x00300000
733	#define SRTCTL_EC 0x01000000
734	#define SRTCTL_ET 0x10000000
735
736	/* DAIO Receiver register dirty flags */
737	union dai_dirty {
738	struct {
739	u16 srt:1;
740	u16 rsv:15;
741	} bf;
742	u16 data;
743	};
744
745	/* DAIO Receiver control block */
746	struct dai_ctrl_blk {
747	unsigned int srt;
748	union dai_dirty dirty;
749	};
750
751	/* Audio Input Mapper RAM */
752	#define AIM_ARC 0x00000FFF
753	#define AIM_NXT 0x007F0000
754
755	struct daoimap {
756	unsigned int aim;
757	unsigned int idx;
758	};
759
760	/* Audio Transmitter Control and Status register */
761	#define ATXCTL_EN 0x00000001
762	#define ATXCTL_MODE 0x00000010
763	#define ATXCTL_CD 0x00000020
764	#define ATXCTL_RAW 0x00000100
765	#define ATXCTL_MT 0x00000200
766	#define ATXCTL_NUC 0x00003000
767	#define ATXCTL_BEN 0x00010000
768	#define ATXCTL_BMUX 0x00700000
769	#define ATXCTL_B24 0x01000000
770	#define ATXCTL_CPF 0x02000000
771	#define ATXCTL_RIV 0x10000000
772	#define ATXCTL_LIV 0x20000000
773	#define ATXCTL_RSAT 0x40000000
774	#define ATXCTL_LSAT 0x80000000
775
776	/* XDIF Transmitter register dirty flags */
777	union dao_dirty {
778	struct {
779	u16 atxcsl:1;
780	u16 rsv:15;
781	} bf;
782	u16 data;
783	};
784
785	/* XDIF Transmitter control block */
786	struct dao_ctrl_blk {
787	/* XDIF Transmitter Channel Status Low Register */
788	unsigned int atxcsl;
789	union dao_dirty dirty;
790	};
791
792	/* Audio Receiver Control register */
793	#define ARXCTL_EN 0x00000001
794
795	/* DAIO manager register dirty flags */
796	union daio_mgr_dirty {
797	struct {
798	u32 atxctl:8;
799	u32 arxctl:8;
800	u32 daoimap:1;
801	u32 rsv:15;
802	} bf;
803	u32 data;
804	};
805
806	/* DAIO manager control block */
807	struct daio_mgr_ctrl_blk {
808	struct daoimap daoimap;
809	unsigned int txctl[8];
810	unsigned int rxctl[8];
811	union daio_mgr_dirty dirty;
812	};
813
814	static int dai_srt_set_srco(void *blk, unsigned int src)
815	{
816	struct dai_ctrl_blk *ctl = blk;
817
818	set_field(data: &ctl->srt, SRTCTL_SRCO, value: src);
819	ctl->dirty.bf.srt = 1;
820	return 0;
821	}
822
823	static int dai_srt_set_srcm(void *blk, unsigned int src)
824	{
825	struct dai_ctrl_blk *ctl = blk;
826
827	set_field(data: &ctl->srt, SRTCTL_SRCM, value: src);
828	ctl->dirty.bf.srt = 1;
829	return 0;
830	}
831
832	static int dai_srt_set_rsr(void *blk, unsigned int rsr)
833	{
834	struct dai_ctrl_blk *ctl = blk;
835
836	set_field(data: &ctl->srt, SRTCTL_RSR, value: rsr);
837	ctl->dirty.bf.srt = 1;
838	return 0;
839	}
840
841	static int dai_srt_set_drat(void *blk, unsigned int drat)
842	{
843	struct dai_ctrl_blk *ctl = blk;
844
845	set_field(data: &ctl->srt, SRTCTL_DRAT, value: drat);
846	ctl->dirty.bf.srt = 1;
847	return 0;
848	}
849
850	static int dai_srt_set_ec(void *blk, unsigned int ec)
851	{
852	struct dai_ctrl_blk *ctl = blk;
853
854	set_field(data: &ctl->srt, SRTCTL_EC, value: ec ? 1 : 0);
855	ctl->dirty.bf.srt = 1;
856	return 0;
857	}
858
859	static int dai_srt_set_et(void *blk, unsigned int et)
860	{
861	struct dai_ctrl_blk *ctl = blk;
862
863	set_field(data: &ctl->srt, SRTCTL_ET, value: et ? 1 : 0);
864	ctl->dirty.bf.srt = 1;
865	return 0;
866	}
867
868	static int dai_commit_write(struct hw *hw, unsigned int idx, void *blk)
869	{
870	struct dai_ctrl_blk *ctl = blk;
871
872	if (ctl->dirty.bf.srt) {
873	hw_write_20kx(hw, AUDIO_IO_RX_SRT_CTL+0x40*idx, data: ctl->srt);
874	ctl->dirty.bf.srt = 0;
875	}
876
877	return 0;
878	}
879
880	static int dai_get_ctrl_blk(void **rblk)
881	{
882	struct dai_ctrl_blk *blk;
883
884	*rblk = NULL;
885	blk = kzalloc(size: sizeof(*blk), GFP_KERNEL);
886	if (!blk)
887	return -ENOMEM;
888
889	*rblk = blk;
890
891	return 0;
892	}
893
894	static int dai_put_ctrl_blk(void *blk)
895	{
896	kfree(objp: blk);
897
898	return 0;
899	}
900
901	static int dao_set_spos(void *blk, unsigned int spos)
902	{
903	((struct dao_ctrl_blk *)blk)->atxcsl = spos;
904	((struct dao_ctrl_blk *)blk)->dirty.bf.atxcsl = 1;
905	return 0;
906	}
907
908	static int dao_commit_write(struct hw *hw, unsigned int idx, void *blk)
909	{
910	struct dao_ctrl_blk *ctl = blk;
911
912	if (ctl->dirty.bf.atxcsl) {
913	if (idx < 4) {
914	/* S/PDIF SPOSx */
915	hw_write_20kx(hw, AUDIO_IO_TX_CSTAT_L+0x40*idx,
916	data: ctl->atxcsl);
917	}
918	ctl->dirty.bf.atxcsl = 0;
919	}
920
921	return 0;
922	}
923
924	static int dao_get_spos(void *blk, unsigned int *spos)
925	{
926	*spos = ((struct dao_ctrl_blk *)blk)->atxcsl;
927	return 0;
928	}
929
930	static int dao_get_ctrl_blk(void **rblk)
931	{
932	struct dao_ctrl_blk *blk;
933
934	*rblk = NULL;
935	blk = kzalloc(size: sizeof(*blk), GFP_KERNEL);
936	if (!blk)
937	return -ENOMEM;
938
939	*rblk = blk;
940
941	return 0;
942	}
943
944	static int dao_put_ctrl_blk(void *blk)
945	{
946	kfree(objp: blk);
947
948	return 0;
949	}
950
951	static int daio_mgr_enb_dai(void *blk, unsigned int idx)
952	{
953	struct daio_mgr_ctrl_blk *ctl = blk;
954
955	set_field(data: &ctl->rxctl[idx], ARXCTL_EN, value: 1);
956	ctl->dirty.bf.arxctl |= (0x1 << idx);
957	return 0;
958	}
959
960	static int daio_mgr_dsb_dai(void *blk, unsigned int idx)
961	{
962	struct daio_mgr_ctrl_blk *ctl = blk;
963
964	set_field(data: &ctl->rxctl[idx], ARXCTL_EN, value: 0);
965
966	ctl->dirty.bf.arxctl |= (0x1 << idx);
967	return 0;
968	}
969
970	static int daio_mgr_enb_dao(void *blk, unsigned int idx)
971	{
972	struct daio_mgr_ctrl_blk *ctl = blk;
973
974	set_field(data: &ctl->txctl[idx], ATXCTL_EN, value: 1);
975	ctl->dirty.bf.atxctl |= (0x1 << idx);
976	return 0;
977	}
978
979	static int daio_mgr_dsb_dao(void *blk, unsigned int idx)
980	{
981	struct daio_mgr_ctrl_blk *ctl = blk;
982
983	set_field(data: &ctl->txctl[idx], ATXCTL_EN, value: 0);
984	ctl->dirty.bf.atxctl |= (0x1 << idx);
985	return 0;
986	}
987
988	static int daio_mgr_dao_init(void *blk, unsigned int idx, unsigned int conf)
989	{
990	struct daio_mgr_ctrl_blk *ctl = blk;
991
992	if (idx < 4) {
993	/* S/PDIF output */
994	switch ((conf & 0xf)) {
995	case 1:
996	set_field(data: &ctl->txctl[idx], ATXCTL_NUC, value: 0);
997	break;
998	case 2:
999	set_field(data: &ctl->txctl[idx], ATXCTL_NUC, value: 1);
1000	break;
1001	case 4:
1002	set_field(data: &ctl->txctl[idx], ATXCTL_NUC, value: 2);
1003	break;
1004	case 8:
1005	set_field(data: &ctl->txctl[idx], ATXCTL_NUC, value: 3);
1006	break;
1007	default:
1008	break;
1009	}
1010	/* CDIF */
1011	set_field(data: &ctl->txctl[idx], ATXCTL_CD, value: (!(conf & 0x7)));
1012	/* Non-audio */
1013	set_field(data: &ctl->txctl[idx], ATXCTL_LIV, value: (conf >> 4) & 0x1);
1014	/* Non-audio */
1015	set_field(data: &ctl->txctl[idx], ATXCTL_RIV, value: (conf >> 4) & 0x1);
1016	set_field(data: &ctl->txctl[idx], ATXCTL_RAW,
1017	value: ((conf >> 3) & 0x1) ? 0 : 0);
1018	ctl->dirty.bf.atxctl |= (0x1 << idx);
1019	} else {
1020	/* I2S output */
1021	/*idx %= 4; */
1022	}
1023	return 0;
1024	}
1025
1026	static int daio_mgr_set_imaparc(void *blk, unsigned int slot)
1027	{
1028	struct daio_mgr_ctrl_blk *ctl = blk;
1029
1030	set_field(data: &ctl->daoimap.aim, AIM_ARC, value: slot);
1031	ctl->dirty.bf.daoimap = 1;
1032	return 0;
1033	}
1034
1035	static int daio_mgr_set_imapnxt(void *blk, unsigned int next)
1036	{
1037	struct daio_mgr_ctrl_blk *ctl = blk;
1038
1039	set_field(data: &ctl->daoimap.aim, AIM_NXT, value: next);
1040	ctl->dirty.bf.daoimap = 1;
1041	return 0;
1042	}
1043
1044	static int daio_mgr_set_imapaddr(void *blk, unsigned int addr)
1045	{
1046	((struct daio_mgr_ctrl_blk *)blk)->daoimap.idx = addr;
1047	((struct daio_mgr_ctrl_blk *)blk)->dirty.bf.daoimap = 1;
1048	return 0;
1049	}
1050
1051	static int daio_mgr_commit_write(struct hw *hw, void *blk)
1052	{
1053	struct daio_mgr_ctrl_blk *ctl = blk;
1054	unsigned int data;
1055	int i;
1056
1057	for (i = 0; i < 8; i++) {
1058	if ((ctl->dirty.bf.atxctl & (0x1 << i))) {
1059	data = ctl->txctl[i];
1060	hw_write_20kx(hw, reg: (AUDIO_IO_TX_CTL+(0x40*i)), data);
1061	ctl->dirty.bf.atxctl &= ~(0x1 << i);
1062	mdelay(1);
1063	}
1064	if ((ctl->dirty.bf.arxctl & (0x1 << i))) {
1065	data = ctl->rxctl[i];
1066	hw_write_20kx(hw, reg: (AUDIO_IO_RX_CTL+(0x40*i)), data);
1067	ctl->dirty.bf.arxctl &= ~(0x1 << i);
1068	mdelay(1);
1069	}
1070	}
1071	if (ctl->dirty.bf.daoimap) {
1072	hw_write_20kx(hw, AUDIO_IO_AIM+ctl->daoimap.idx*4,
1073	data: ctl->daoimap.aim);
1074	ctl->dirty.bf.daoimap = 0;
1075	}
1076
1077	return 0;
1078	}
1079
1080	static int daio_mgr_get_ctrl_blk(struct hw *hw, void **rblk)
1081	{
1082	struct daio_mgr_ctrl_blk *blk;
1083	int i;
1084
1085	*rblk = NULL;
1086	blk = kzalloc(size: sizeof(*blk), GFP_KERNEL);
1087	if (!blk)
1088	return -ENOMEM;
1089
1090	for (i = 0; i < 8; i++) {
1091	blk->txctl[i] = hw_read_20kx(hw, AUDIO_IO_TX_CTL+(0x40*i));
1092	blk->rxctl[i] = hw_read_20kx(hw, AUDIO_IO_RX_CTL+(0x40*i));
1093	}
1094
1095	*rblk = blk;
1096
1097	return 0;
1098	}
1099
1100	static int daio_mgr_put_ctrl_blk(void *blk)
1101	{
1102	kfree(objp: blk);
1103
1104	return 0;
1105	}
1106
1107	/* Timer interrupt */
1108	static int set_timer_irq(struct hw *hw, int enable)
1109	{
1110	hw_write_20kx(hw, GIE, data: enable ? IT_INT : 0);
1111	return 0;
1112	}
1113
1114	static int set_timer_tick(struct hw *hw, unsigned int ticks)
1115	{
1116	if (ticks)
1117	ticks |= TIMR_IE | TIMR_IP;
1118	hw_write_20kx(hw, TIMR, data: ticks);
1119	return 0;
1120	}
1121
1122	static unsigned int get_wc(struct hw *hw)
1123	{
1124	return hw_read_20kx(hw, WC);
1125	}
1126
1127	/* Card hardware initialization block */
1128	struct dac_conf {
1129	unsigned int msr; /* master sample rate in rsrs */
1130	};
1131
1132	struct adc_conf {
1133	unsigned int msr; /* master sample rate in rsrs */
1134	unsigned char input; /* the input source of ADC */
1135	unsigned char mic20db; /* boost mic by 20db if input is microphone */
1136	};
1137
1138	struct daio_conf {
1139	unsigned int msr; /* master sample rate in rsrs */
1140	};
1141
1142	struct trn_conf {
1143	unsigned long vm_pgt_phys;
1144	};
1145
1146	static int hw_daio_init(struct hw *hw, const struct daio_conf *info)
1147	{
1148	u32 data;
1149	int i;
1150
1151	/* Program I2S with proper sample rate and enable the correct I2S
1152	* channel. ED(0/8/16/24): Enable all I2S/I2X master clock output */
1153	if (1 == info->msr) {
1154	hw_write_20kx(hw, AUDIO_IO_MCLK, data: 0x01010101);
1155	hw_write_20kx(hw, AUDIO_IO_TX_BLRCLK, data: 0x01010101);
1156	hw_write_20kx(hw, AUDIO_IO_RX_BLRCLK, data: 0);
1157	} else if (2 == info->msr) {
1158	if (hw->model != CTSB1270) {
1159	hw_write_20kx(hw, AUDIO_IO_MCLK, data: 0x11111111);
1160	} else {
1161	/* PCM4220 on Titanium HD is different. */
1162	hw_write_20kx(hw, AUDIO_IO_MCLK, data: 0x11011111);
1163	}
1164	/* Specify all playing 96khz
1165	* EA [0] - Enabled
1166	* RTA [4:5] - 96kHz
1167	* EB [8] - Enabled
1168	* RTB [12:13] - 96kHz
1169	* EC [16] - Enabled
1170	* RTC [20:21] - 96kHz
1171	* ED [24] - Enabled
1172	* RTD [28:29] - 96kHz */
1173	hw_write_20kx(hw, AUDIO_IO_TX_BLRCLK, data: 0x11111111);
1174	hw_write_20kx(hw, AUDIO_IO_RX_BLRCLK, data: 0);
1175	} else if ((4 == info->msr) && (hw->model == CTSB1270)) {
1176	hw_write_20kx(hw, AUDIO_IO_MCLK, data: 0x21011111);
1177	hw_write_20kx(hw, AUDIO_IO_TX_BLRCLK, data: 0x21212121);
1178	hw_write_20kx(hw, AUDIO_IO_RX_BLRCLK, data: 0);
1179	} else {
1180	dev_alert(hw->card->dev,
1181	"ERROR!!! Invalid sampling rate!!!\n");
1182	return -EINVAL;
1183	}
1184
1185	for (i = 0; i < 8; i++) {
1186	if (i <= 3) {
1187	/* This comment looks wrong since loop is over 4 */
1188	/* channels and emu20k2 supports 4 spdif IOs. */
1189	/* 1st 3 channels are SPDIFs (SB0960) */
1190	if (i == 3)
1191	data = 0x1001001;
1192	else
1193	data = 0x1000001;
1194
1195	hw_write_20kx(hw, reg: (AUDIO_IO_TX_CTL+(0x40*i)), data);
1196	hw_write_20kx(hw, reg: (AUDIO_IO_RX_CTL+(0x40*i)), data);
1197
1198	/* Initialize the SPDIF Out Channel status registers.
1199	* The value specified here is based on the typical
1200	* values provided in the specification, namely: Clock
1201	* Accuracy of 1000ppm, Sample Rate of 48KHz,
1202	* unspecified source number, Generation status = 1,
1203	* Category code = 0x12 (Digital Signal Mixer),
1204	* Mode = 0, Emph = 0, Copy Permitted, AN = 0
1205	* (indicating that we're transmitting digital audio,
1206	* and the Professional Use bit is 0. */
1207
1208	hw_write_20kx(hw, AUDIO_IO_TX_CSTAT_L+(0x40*i),
1209	data: 0x02109204); /* Default to 48kHz */
1210
1211	hw_write_20kx(hw, AUDIO_IO_TX_CSTAT_H+(0x40*i), data: 0x0B);
1212	} else {
1213	/* Again, loop is over 4 channels not 5. */
1214	/* Next 5 channels are I2S (SB0960) */
1215	data = 0x11;
1216	hw_write_20kx(hw, AUDIO_IO_RX_CTL+(0x40*i), data);
1217	if (2 == info->msr) {
1218	/* Four channels per sample period */
1219	data |= 0x1000;
1220	} else if (4 == info->msr) {
1221	/* FIXME: check this against the chip spec */
1222	data |= 0x2000;
1223	}
1224	hw_write_20kx(hw, AUDIO_IO_TX_CTL+(0x40*i), data);
1225	}
1226	}
1227
1228	return 0;
1229	}
1230
1231	/* TRANSPORT operations */
1232	static int hw_trn_init(struct hw *hw, const struct trn_conf *info)
1233	{
1234	u32 vmctl, data;
1235	u32 ptp_phys_low, ptp_phys_high;
1236	int i;
1237
1238	/* Set up device page table */
1239	if ((~0UL) == info->vm_pgt_phys) {
1240	dev_alert(hw->card->dev,
1241	"Wrong device page table page address!!!\n");
1242	return -1;
1243	}
1244
1245	vmctl = 0x80000C0F; /* 32-bit, 4k-size page */
1246	ptp_phys_low = (u32)info->vm_pgt_phys;
1247	ptp_phys_high = upper_32_bits(info->vm_pgt_phys);
1248	if (sizeof(void *) == 8) /* 64bit address */
1249	vmctl |= (3 << 8);
1250	/* Write page table physical address to all PTPAL registers */
1251	for (i = 0; i < 64; i++) {
1252	hw_write_20kx(hw, VMEM_PTPAL+(16*i), data: ptp_phys_low);
1253	hw_write_20kx(hw, VMEM_PTPAH+(16*i), data: ptp_phys_high);
1254	}
1255	/* Enable virtual memory transfer */
1256	hw_write_20kx(hw, VMEM_CTL, data: vmctl);
1257	/* Enable transport bus master and queueing of request */
1258	hw_write_20kx(hw, TRANSPORT_CTL, data: 0x03);
1259	hw_write_20kx(hw, TRANSPORT_INT, data: 0x200c01);
1260	/* Enable transport ring */
1261	data = hw_read_20kx(hw, TRANSPORT_ENB);
1262	hw_write_20kx(hw, TRANSPORT_ENB, data: (data | 0x03));
1263
1264	return 0;
1265	}
1266
1267	/* Card initialization */
1268	#define GCTL_AIE 0x00000001
1269	#define GCTL_UAA 0x00000002
1270	#define GCTL_DPC 0x00000004
1271	#define GCTL_DBP 0x00000008
1272	#define GCTL_ABP 0x00000010
1273	#define GCTL_TBP 0x00000020
1274	#define GCTL_SBP 0x00000040
1275	#define GCTL_FBP 0x00000080
1276	#define GCTL_ME 0x00000100
1277	#define GCTL_AID 0x00001000
1278
1279	#define PLLCTL_SRC 0x00000007
1280	#define PLLCTL_SPE 0x00000008
1281	#define PLLCTL_RD 0x000000F0
1282	#define PLLCTL_FD 0x0001FF00
1283	#define PLLCTL_OD 0x00060000
1284	#define PLLCTL_B 0x00080000
1285	#define PLLCTL_AS 0x00100000
1286	#define PLLCTL_LF 0x03E00000
1287	#define PLLCTL_SPS 0x1C000000
1288	#define PLLCTL_AD 0x60000000
1289
1290	#define PLLSTAT_CCS 0x00000007
1291	#define PLLSTAT_SPL 0x00000008
1292	#define PLLSTAT_CRD 0x000000F0
1293	#define PLLSTAT_CFD 0x0001FF00
1294	#define PLLSTAT_SL 0x00020000
1295	#define PLLSTAT_FAS 0x00040000
1296	#define PLLSTAT_B 0x00080000
1297	#define PLLSTAT_PD 0x00100000
1298	#define PLLSTAT_OCA 0x00200000
1299	#define PLLSTAT_NCA 0x00400000
1300
1301	static int hw_pll_init(struct hw *hw, unsigned int rsr)
1302	{
1303	unsigned int pllenb;
1304	unsigned int pllctl;
1305	unsigned int pllstat;
1306	int i;
1307
1308	pllenb = 0xB;
1309	hw_write_20kx(hw, PLL_ENB, data: pllenb);
1310	pllctl = 0x20C00000;
1311	set_field(data: &pllctl, PLLCTL_B, value: 0);
1312	set_field(data: &pllctl, PLLCTL_FD, value: 48000 == rsr ? 16 - 4 : 147 - 4);
1313	set_field(data: &pllctl, PLLCTL_RD, value: 48000 == rsr ? 1 - 1 : 10 - 1);
1314	hw_write_20kx(hw, PLL_CTL, data: pllctl);
1315	msleep(msecs: 40);
1316
1317	pllctl = hw_read_20kx(hw, PLL_CTL);
1318	set_field(data: &pllctl, PLLCTL_FD, value: 48000 == rsr ? 16 - 2 : 147 - 2);
1319	hw_write_20kx(hw, PLL_CTL, data: pllctl);
1320	msleep(msecs: 40);
1321
1322	for (i = 0; i < 1000; i++) {
1323	pllstat = hw_read_20kx(hw, PLL_STAT);
1324	if (get_field(data: pllstat, PLLSTAT_PD))
1325	continue;
1326
1327	if (get_field(data: pllstat, PLLSTAT_B) !=
1328	get_field(data: pllctl, PLLCTL_B))
1329	continue;
1330
1331	if (get_field(data: pllstat, PLLSTAT_CCS) !=
1332	get_field(data: pllctl, PLLCTL_SRC))
1333	continue;
1334
1335	if (get_field(data: pllstat, PLLSTAT_CRD) !=
1336	get_field(data: pllctl, PLLCTL_RD))
1337	continue;
1338
1339	if (get_field(data: pllstat, PLLSTAT_CFD) !=
1340	get_field(data: pllctl, PLLCTL_FD))
1341	continue;
1342
1343	break;
1344	}
1345	if (i >= 1000) {
1346	dev_alert(hw->card->dev,
1347	"PLL initialization failed!!!\n");
1348	return -EBUSY;
1349	}
1350
1351	return 0;
1352	}
1353
1354	static int hw_auto_init(struct hw *hw)
1355	{
1356	unsigned int gctl;
1357	int i;
1358
1359	gctl = hw_read_20kx(hw, GLOBAL_CNTL_GCTL);
1360	set_field(data: &gctl, GCTL_AIE, value: 0);
1361	hw_write_20kx(hw, GLOBAL_CNTL_GCTL, data: gctl);
1362	set_field(data: &gctl, GCTL_AIE, value: 1);
1363	hw_write_20kx(hw, GLOBAL_CNTL_GCTL, data: gctl);
1364	mdelay(10);
1365	for (i = 0; i < 400000; i++) {
1366	gctl = hw_read_20kx(hw, GLOBAL_CNTL_GCTL);
1367	if (get_field(data: gctl, GCTL_AID))
1368	break;
1369	}
1370	if (!get_field(data: gctl, GCTL_AID)) {
1371	dev_alert(hw->card->dev, "Card Auto-init failed!!!\n");
1372	return -EBUSY;
1373	}
1374
1375	return 0;
1376	}
1377
1378	/* DAC operations */
1379
1380	#define CS4382_MC1 0x1
1381	#define CS4382_MC2 0x2
1382	#define CS4382_MC3 0x3
1383	#define CS4382_FC 0x4
1384	#define CS4382_IC 0x5
1385	#define CS4382_XC1 0x6
1386	#define CS4382_VCA1 0x7
1387	#define CS4382_VCB1 0x8
1388	#define CS4382_XC2 0x9
1389	#define CS4382_VCA2 0xA
1390	#define CS4382_VCB2 0xB
1391	#define CS4382_XC3 0xC
1392	#define CS4382_VCA3 0xD
1393	#define CS4382_VCB3 0xE
1394	#define CS4382_XC4 0xF
1395	#define CS4382_VCA4 0x10
1396	#define CS4382_VCB4 0x11
1397	#define CS4382_CREV 0x12
1398
1399	/* I2C status */
1400	#define STATE_LOCKED 0x00
1401	#define STATE_UNLOCKED 0xAA
1402	#define DATA_READY 0x800000 /* Used with I2C_IF_STATUS */
1403	#define DATA_ABORT 0x10000 /* Used with I2C_IF_STATUS */
1404
1405	#define I2C_STATUS_DCM 0x00000001
1406	#define I2C_STATUS_BC 0x00000006
1407	#define I2C_STATUS_APD 0x00000008
1408	#define I2C_STATUS_AB 0x00010000
1409	#define I2C_STATUS_DR 0x00800000
1410
1411	#define I2C_ADDRESS_PTAD 0x0000FFFF
1412	#define I2C_ADDRESS_SLAD 0x007F0000
1413
1414	struct regs_cs4382 {
1415	u32 mode_control_1;
1416	u32 mode_control_2;
1417	u32 mode_control_3;
1418
1419	u32 filter_control;
1420	u32 invert_control;
1421
1422	u32 mix_control_P1;
1423	u32 vol_control_A1;
1424	u32 vol_control_B1;
1425
1426	u32 mix_control_P2;
1427	u32 vol_control_A2;
1428	u32 vol_control_B2;
1429
1430	u32 mix_control_P3;
1431	u32 vol_control_A3;
1432	u32 vol_control_B3;
1433
1434	u32 mix_control_P4;
1435	u32 vol_control_A4;
1436	u32 vol_control_B4;
1437	};
1438
1439	static int hw20k2_i2c_unlock_full_access(struct hw *hw)
1440	{
1441	u8 UnlockKeySequence_FLASH_FULLACCESS_MODE[2] = {0xB3, 0xD4};
1442
1443	/* Send keys for forced BIOS mode */
1444	hw_write_20kx(hw, I2C_IF_WLOCK,
1445	data: UnlockKeySequence_FLASH_FULLACCESS_MODE[0]);
1446	hw_write_20kx(hw, I2C_IF_WLOCK,
1447	data: UnlockKeySequence_FLASH_FULLACCESS_MODE[1]);
1448	/* Check whether the chip is unlocked */
1449	if (hw_read_20kx(hw, I2C_IF_WLOCK) == STATE_UNLOCKED)
1450	return 0;
1451
1452	return -1;
1453	}
1454
1455	static int hw20k2_i2c_lock_chip(struct hw *hw)
1456	{
1457	/* Write twice */
1458	hw_write_20kx(hw, I2C_IF_WLOCK, STATE_LOCKED);
1459	hw_write_20kx(hw, I2C_IF_WLOCK, STATE_LOCKED);
1460	if (hw_read_20kx(hw, I2C_IF_WLOCK) == STATE_LOCKED)
1461	return 0;
1462
1463	return -1;
1464	}
1465
1466	static int hw20k2_i2c_init(struct hw *hw, u8 dev_id, u8 addr_size, u8 data_size)
1467	{
1468	struct hw20k2 *hw20k2 = (struct hw20k2 *)hw;
1469	int err;
1470	unsigned int i2c_status;
1471	unsigned int i2c_addr;
1472
1473	err = hw20k2_i2c_unlock_full_access(hw);
1474	if (err < 0)
1475	return err;
1476
1477	hw20k2->addr_size = addr_size;
1478	hw20k2->data_size = data_size;
1479	hw20k2->dev_id = dev_id;
1480
1481	i2c_addr = 0;
1482	set_field(data: &i2c_addr, I2C_ADDRESS_SLAD, value: dev_id);
1483
1484	hw_write_20kx(hw, I2C_IF_ADDRESS, data: i2c_addr);
1485
1486	i2c_status = hw_read_20kx(hw, I2C_IF_STATUS);
1487
1488	set_field(data: &i2c_status, I2C_STATUS_DCM, value: 1); /* Direct control mode */
1489
1490	hw_write_20kx(hw, I2C_IF_STATUS, data: i2c_status);
1491
1492	return 0;
1493	}
1494
1495	static int hw20k2_i2c_uninit(struct hw *hw)
1496	{
1497	unsigned int i2c_status;
1498	unsigned int i2c_addr;
1499
1500	i2c_addr = 0;
1501	set_field(data: &i2c_addr, I2C_ADDRESS_SLAD, value: 0x57); /* I2C id */
1502
1503	hw_write_20kx(hw, I2C_IF_ADDRESS, data: i2c_addr);
1504
1505	i2c_status = hw_read_20kx(hw, I2C_IF_STATUS);
1506
1507	set_field(data: &i2c_status, I2C_STATUS_DCM, value: 0); /* I2C mode */
1508
1509	hw_write_20kx(hw, I2C_IF_STATUS, data: i2c_status);
1510
1511	return hw20k2_i2c_lock_chip(hw);
1512	}
1513
1514	static int hw20k2_i2c_wait_data_ready(struct hw *hw)
1515	{
1516	int i = 0x400000;
1517	unsigned int ret;
1518
1519	do {
1520	ret = hw_read_20kx(hw, I2C_IF_STATUS);
1521	} while ((!(ret & DATA_READY)) && --i);
1522
1523	return i;
1524	}
1525
1526	static int hw20k2_i2c_read(struct hw *hw, u16 addr, u32 *datap)
1527	{
1528	struct hw20k2 *hw20k2 = (struct hw20k2 *)hw;
1529	unsigned int i2c_status;
1530
1531	i2c_status = hw_read_20kx(hw, I2C_IF_STATUS);
1532	set_field(data: &i2c_status, I2C_STATUS_BC,
1533	value: (4 == hw20k2->addr_size) ? 0 : hw20k2->addr_size);
1534	hw_write_20kx(hw, I2C_IF_STATUS, data: i2c_status);
1535	if (!hw20k2_i2c_wait_data_ready(hw))
1536	return -1;
1537
1538	hw_write_20kx(hw, I2C_IF_WDATA, data: addr);
1539	if (!hw20k2_i2c_wait_data_ready(hw))
1540	return -1;
1541
1542	/* Force a read operation */
1543	hw_write_20kx(hw, I2C_IF_RDATA, data: 0);
1544	if (!hw20k2_i2c_wait_data_ready(hw))
1545	return -1;
1546
1547	*datap = hw_read_20kx(hw, I2C_IF_RDATA);
1548
1549	return 0;
1550	}
1551
1552	static int hw20k2_i2c_write(struct hw *hw, u16 addr, u32 data)
1553	{
1554	struct hw20k2 *hw20k2 = (struct hw20k2 *)hw;
1555	unsigned int i2c_data = (data << (hw20k2->addr_size * 8)) | addr;
1556	unsigned int i2c_status;
1557
1558	i2c_status = hw_read_20kx(hw, I2C_IF_STATUS);
1559
1560	set_field(data: &i2c_status, I2C_STATUS_BC,
1561	value: (4 == (hw20k2->addr_size + hw20k2->data_size)) ?
1562	0 : (hw20k2->addr_size + hw20k2->data_size));
1563
1564	hw_write_20kx(hw, I2C_IF_STATUS, data: i2c_status);
1565	hw20k2_i2c_wait_data_ready(hw);
1566	/* Dummy write to trigger the write operation */
1567	hw_write_20kx(hw, I2C_IF_WDATA, data: 0);
1568	hw20k2_i2c_wait_data_ready(hw);
1569
1570	/* This is the real data */
1571	hw_write_20kx(hw, I2C_IF_WDATA, data: i2c_data);
1572	hw20k2_i2c_wait_data_ready(hw);
1573
1574	return 0;
1575	}
1576
1577	static void hw_dac_stop(struct hw *hw)
1578	{
1579	u32 data;
1580	data = hw_read_20kx(hw, GPIO_DATA);
1581	data &= 0xFFFFFFFD;
1582	hw_write_20kx(hw, GPIO_DATA, data);
1583	usleep_range(min: 10000, max: 11000);
1584	}
1585
1586	static void hw_dac_start(struct hw *hw)
1587	{
1588	u32 data;
1589	data = hw_read_20kx(hw, GPIO_DATA);
1590	data |= 0x2;
1591	hw_write_20kx(hw, GPIO_DATA, data);
1592	msleep(msecs: 50);
1593	}
1594
1595	static void hw_dac_reset(struct hw *hw)
1596	{
1597	hw_dac_stop(hw);
1598	hw_dac_start(hw);
1599	}
1600
1601	static int hw_dac_init(struct hw *hw, const struct dac_conf *info)
1602	{
1603	int err;
1604	u32 data;
1605	int i;
1606	struct regs_cs4382 cs_read = {0};
1607	struct regs_cs4382 cs_def = {
1608	.mode_control_1 = 0x00000001, /* Mode Control 1 */
1609	.mode_control_2 = 0x00000000, /* Mode Control 2 */
1610	.mode_control_3 = 0x00000084, /* Mode Control 3 */
1611	.filter_control = 0x00000000, /* Filter Control */
1612	.invert_control = 0x00000000, /* Invert Control */
1613	.mix_control_P1 = 0x00000024, /* Mixing Control Pair 1 */
1614	.vol_control_A1 = 0x00000000, /* Vol Control A1 */
1615	.vol_control_B1 = 0x00000000, /* Vol Control B1 */
1616	.mix_control_P2 = 0x00000024, /* Mixing Control Pair 2 */
1617	.vol_control_A2 = 0x00000000, /* Vol Control A2 */
1618	.vol_control_B2 = 0x00000000, /* Vol Control B2 */
1619	.mix_control_P3 = 0x00000024, /* Mixing Control Pair 3 */
1620	.vol_control_A3 = 0x00000000, /* Vol Control A3 */
1621	.vol_control_B3 = 0x00000000, /* Vol Control B3 */
1622	.mix_control_P4 = 0x00000024, /* Mixing Control Pair 4 */
1623	.vol_control_A4 = 0x00000000, /* Vol Control A4 */
1624	.vol_control_B4 = 0x00000000 /* Vol Control B4 */
1625	};
1626
1627	if (hw->model == CTSB1270) {
1628	hw_dac_stop(hw);
1629	data = hw_read_20kx(hw, GPIO_DATA);
1630	data &= ~0x0600;
1631	if (1 == info->msr)
1632	data |= 0x0000; /* Single Speed Mode 0-50kHz */
1633	else if (2 == info->msr)
1634	data |= 0x0200; /* Double Speed Mode 50-100kHz */
1635	else
1636	data |= 0x0600; /* Quad Speed Mode 100-200kHz */
1637	hw_write_20kx(hw, GPIO_DATA, data);
1638	hw_dac_start(hw);
1639	return 0;
1640	}
1641
1642	/* Set DAC reset bit as output */
1643	data = hw_read_20kx(hw, GPIO_CTRL);
1644	data |= 0x02;
1645	hw_write_20kx(hw, GPIO_CTRL, data);
1646
1647	err = hw20k2_i2c_init(hw, dev_id: 0x18, addr_size: 1, data_size: 1);
1648	if (err < 0)
1649	goto End;
1650
1651	for (i = 0; i < 2; i++) {
1652	/* Reset DAC twice just in-case the chip
1653	* didn't initialized properly */
1654	hw_dac_reset(hw);
1655	hw_dac_reset(hw);
1656
1657	if (hw20k2_i2c_read(hw, CS4382_MC1, datap: &cs_read.mode_control_1))
1658	continue;
1659
1660	if (hw20k2_i2c_read(hw, CS4382_MC2, datap: &cs_read.mode_control_2))
1661	continue;
1662
1663	if (hw20k2_i2c_read(hw, CS4382_MC3, datap: &cs_read.mode_control_3))
1664	continue;
1665
1666	if (hw20k2_i2c_read(hw, CS4382_FC, datap: &cs_read.filter_control))
1667	continue;
1668
1669	if (hw20k2_i2c_read(hw, CS4382_IC, datap: &cs_read.invert_control))
1670	continue;
1671
1672	if (hw20k2_i2c_read(hw, CS4382_XC1, datap: &cs_read.mix_control_P1))
1673	continue;
1674
1675	if (hw20k2_i2c_read(hw, CS4382_VCA1, datap: &cs_read.vol_control_A1))
1676	continue;
1677
1678	if (hw20k2_i2c_read(hw, CS4382_VCB1, datap: &cs_read.vol_control_B1))
1679	continue;
1680
1681	if (hw20k2_i2c_read(hw, CS4382_XC2, datap: &cs_read.mix_control_P2))
1682	continue;
1683
1684	if (hw20k2_i2c_read(hw, CS4382_VCA2, datap: &cs_read.vol_control_A2))
1685	continue;
1686
1687	if (hw20k2_i2c_read(hw, CS4382_VCB2, datap: &cs_read.vol_control_B2))
1688	continue;
1689
1690	if (hw20k2_i2c_read(hw, CS4382_XC3, datap: &cs_read.mix_control_P3))
1691	continue;
1692
1693	if (hw20k2_i2c_read(hw, CS4382_VCA3, datap: &cs_read.vol_control_A3))
1694	continue;
1695
1696	if (hw20k2_i2c_read(hw, CS4382_VCB3, datap: &cs_read.vol_control_B3))
1697	continue;
1698
1699	if (hw20k2_i2c_read(hw, CS4382_XC4, datap: &cs_read.mix_control_P4))
1700	continue;
1701
1702	if (hw20k2_i2c_read(hw, CS4382_VCA4, datap: &cs_read.vol_control_A4))
1703	continue;
1704
1705	if (hw20k2_i2c_read(hw, CS4382_VCB4, datap: &cs_read.vol_control_B4))
1706	continue;
1707
1708	if (memcmp(p: &cs_read, q: &cs_def, size: sizeof(cs_read)))
1709	continue;
1710	else
1711	break;
1712	}
1713
1714	if (i >= 2)
1715	goto End;
1716
1717	/* Note: Every I2C write must have some delay.
1718	* This is not a requirement but the delay works here... */
1719	hw20k2_i2c_write(hw, CS4382_MC1, data: 0x80);
1720	hw20k2_i2c_write(hw, CS4382_MC2, data: 0x10);
1721	if (1 == info->msr) {
1722	hw20k2_i2c_write(hw, CS4382_XC1, data: 0x24);
1723	hw20k2_i2c_write(hw, CS4382_XC2, data: 0x24);
1724	hw20k2_i2c_write(hw, CS4382_XC3, data: 0x24);
1725	hw20k2_i2c_write(hw, CS4382_XC4, data: 0x24);
1726	} else if (2 == info->msr) {
1727	hw20k2_i2c_write(hw, CS4382_XC1, data: 0x25);
1728	hw20k2_i2c_write(hw, CS4382_XC2, data: 0x25);
1729	hw20k2_i2c_write(hw, CS4382_XC3, data: 0x25);
1730	hw20k2_i2c_write(hw, CS4382_XC4, data: 0x25);
1731	} else {
1732	hw20k2_i2c_write(hw, CS4382_XC1, data: 0x26);
1733	hw20k2_i2c_write(hw, CS4382_XC2, data: 0x26);
1734	hw20k2_i2c_write(hw, CS4382_XC3, data: 0x26);
1735	hw20k2_i2c_write(hw, CS4382_XC4, data: 0x26);
1736	}
1737
1738	return 0;
1739	End:
1740
1741	hw20k2_i2c_uninit(hw);
1742	return -1;
1743	}
1744
1745	/* ADC operations */
1746	#define MAKE_WM8775_ADDR(addr, data) (u32)(((addr<<1)&0xFE)|((data>>8)&0x1))
1747	#define MAKE_WM8775_DATA(data) (u32)(data&0xFF)
1748
1749	#define WM8775_IC 0x0B
1750	#define WM8775_MMC 0x0C
1751	#define WM8775_AADCL 0x0E
1752	#define WM8775_AADCR 0x0F
1753	#define WM8775_ADCMC 0x15
1754	#define WM8775_RESET 0x17
1755
1756	static int hw_is_adc_input_selected(struct hw *hw, enum ADCSRC type)
1757	{
1758	u32 data;
1759	if (hw->model == CTSB1270) {
1760	/* Titanium HD has two ADC chips, one for line in and one */
1761	/* for MIC. We don't need to switch the ADC input. */
1762	return 1;
1763	}
1764	data = hw_read_20kx(hw, GPIO_DATA);
1765	switch (type) {
1766	case ADC_MICIN:
1767	data = (data & (0x1 << 14)) ? 1 : 0;
1768	break;
1769	case ADC_LINEIN:
1770	data = (data & (0x1 << 14)) ? 0 : 1;
1771	break;
1772	default:
1773	data = 0;
1774	}
1775	return data;
1776	}
1777
1778	#define MIC_BOOST_0DB 0xCF
1779	#define MIC_BOOST_STEPS_PER_DB 2
1780
1781	static void hw_wm8775_input_select(struct hw *hw, u8 input, s8 gain_in_db)
1782	{
1783	u32 adcmc, gain;
1784
1785	if (input > 3)
1786	input = 3;
1787
1788	adcmc = ((u32)1 << input) | 0x100; /* Link L+R gain... */
1789
1790	hw20k2_i2c_write(hw, MAKE_WM8775_ADDR(WM8775_ADCMC, adcmc),
1791	MAKE_WM8775_DATA(adcmc));
1792
1793	if (gain_in_db < -103)
1794	gain_in_db = -103;
1795	if (gain_in_db > 24)
1796	gain_in_db = 24;
1797
1798	gain = gain_in_db * MIC_BOOST_STEPS_PER_DB + MIC_BOOST_0DB;
1799
1800	hw20k2_i2c_write(hw, MAKE_WM8775_ADDR(WM8775_AADCL, gain),
1801	MAKE_WM8775_DATA(gain));
1802	/* ...so there should be no need for the following. */
1803	hw20k2_i2c_write(hw, MAKE_WM8775_ADDR(WM8775_AADCR, gain),
1804	MAKE_WM8775_DATA(gain));
1805	}
1806
1807	static int hw_adc_input_select(struct hw *hw, enum ADCSRC type)
1808	{
1809	u32 data;
1810	data = hw_read_20kx(hw, GPIO_DATA);
1811	switch (type) {
1812	case ADC_MICIN:
1813	data |= (0x1 << 14);
1814	hw_write_20kx(hw, GPIO_DATA, data);
1815	hw_wm8775_input_select(hw, input: 0, gain_in_db: 20); /* Mic, 20dB */
1816	break;
1817	case ADC_LINEIN:
1818	data &= ~(0x1 << 14);
1819	hw_write_20kx(hw, GPIO_DATA, data);
1820	hw_wm8775_input_select(hw, input: 1, gain_in_db: 0); /* Line-in, 0dB */
1821	break;
1822	default:
1823	break;
1824	}
1825
1826	return 0;
1827	}
1828
1829	static int hw_adc_init(struct hw *hw, const struct adc_conf *info)
1830	{
1831	int err;
1832	u32 data, ctl;
1833
1834	/* Set ADC reset bit as output */
1835	data = hw_read_20kx(hw, GPIO_CTRL);
1836	data |= (0x1 << 15);
1837	hw_write_20kx(hw, GPIO_CTRL, data);
1838
1839	/* Initialize I2C */
1840	err = hw20k2_i2c_init(hw, dev_id: 0x1A, addr_size: 1, data_size: 1);
1841	if (err < 0) {
1842	dev_alert(hw->card->dev, "Failure to acquire I2C!!!\n");
1843	goto error;
1844	}
1845
1846	/* Reset the ADC (reset is active low). */
1847	data = hw_read_20kx(hw, GPIO_DATA);
1848	data &= ~(0x1 << 15);
1849	hw_write_20kx(hw, GPIO_DATA, data);
1850
1851	if (hw->model == CTSB1270) {
1852	/* Set up the PCM4220 ADC on Titanium HD */
1853	data &= ~0x0C;
1854	if (1 == info->msr)
1855	data |= 0x00; /* Single Speed Mode 32-50kHz */
1856	else if (2 == info->msr)
1857	data |= 0x08; /* Double Speed Mode 50-108kHz */
1858	else
1859	data |= 0x04; /* Quad Speed Mode 108kHz-216kHz */
1860	hw_write_20kx(hw, GPIO_DATA, data);
1861	}
1862
1863	usleep_range(min: 10000, max: 11000);
1864	/* Return the ADC to normal operation. */
1865	data |= (0x1 << 15);
1866	hw_write_20kx(hw, GPIO_DATA, data);
1867	msleep(msecs: 50);
1868
1869	/* I2C write to register offset 0x0B to set ADC LRCLK polarity */
1870	/* invert bit, interface format to I2S, word length to 24-bit, */
1871	/* enable ADC high pass filter. Fixes bug 5323? */
1872	hw20k2_i2c_write(hw, MAKE_WM8775_ADDR(WM8775_IC, 0x26),
1873	MAKE_WM8775_DATA(0x26));
1874
1875	/* Set the master mode (256fs) */
1876	if (1 == info->msr) {
1877	/* slave mode, 128x oversampling 256fs */
1878	hw20k2_i2c_write(hw, MAKE_WM8775_ADDR(WM8775_MMC, 0x02),
1879	MAKE_WM8775_DATA(0x02));
1880	} else if ((2 == info->msr) || (4 == info->msr)) {
1881	/* slave mode, 64x oversampling, 256fs */
1882	hw20k2_i2c_write(hw, MAKE_WM8775_ADDR(WM8775_MMC, 0x0A),
1883	MAKE_WM8775_DATA(0x0A));
1884	} else {
1885	dev_alert(hw->card->dev,
1886	"Invalid master sampling rate (msr %d)!!!\n",
1887	info->msr);
1888	err = -EINVAL;
1889	goto error;
1890	}
1891
1892	if (hw->model != CTSB1270) {
1893	/* Configure GPIO bit 14 change to line-in/mic-in */
1894	ctl = hw_read_20kx(hw, GPIO_CTRL);
1895	ctl |= 0x1 << 14;
1896	hw_write_20kx(hw, GPIO_CTRL, data: ctl);
1897	hw_adc_input_select(hw, type: ADC_LINEIN);
1898	} else {
1899	hw_wm8775_input_select(hw, input: 0, gain_in_db: 0);
1900	}
1901
1902	return 0;
1903	error:
1904	hw20k2_i2c_uninit(hw);
1905	return err;
1906	}
1907
1908	static struct capabilities hw_capabilities(struct hw *hw)
1909	{
1910	struct capabilities cap;
1911
1912	cap.digit_io_switch = 0;
1913	cap.dedicated_mic = hw->model == CTSB1270;
1914	cap.output_switch = hw->model == CTSB1270;
1915	cap.mic_source_switch = hw->model == CTSB1270;
1916
1917	return cap;
1918	}
1919
1920	static int hw_output_switch_get(struct hw *hw)
1921	{
1922	u32 data = hw_read_20kx(hw, GPIO_EXT_DATA);
1923
1924	switch (data & 0x30) {
1925	case 0x00:
1926	return 0;
1927	case 0x10:
1928	return 1;
1929	case 0x20:
1930	return 2;
1931	default:
1932	return 3;
1933	}
1934	}
1935
1936	static int hw_output_switch_put(struct hw *hw, int position)
1937	{
1938	u32 data;
1939
1940	if (position == hw_output_switch_get(hw))
1941	return 0;
1942
1943	/* Mute line and headphones (intended for anti-pop). */
1944	data = hw_read_20kx(hw, GPIO_DATA);
1945	data |= (0x03 << 11);
1946	hw_write_20kx(hw, GPIO_DATA, data);
1947
1948	data = hw_read_20kx(hw, GPIO_EXT_DATA) & ~0x30;
1949	switch (position) {
1950	case 0:
1951	break;
1952	case 1:
1953	data |= 0x10;
1954	break;
1955	default:
1956	data |= 0x20;
1957	}
1958	hw_write_20kx(hw, GPIO_EXT_DATA, data);
1959
1960	/* Unmute line and headphones. */
1961	data = hw_read_20kx(hw, GPIO_DATA);
1962	data &= ~(0x03 << 11);
1963	hw_write_20kx(hw, GPIO_DATA, data);
1964
1965	return 1;
1966	}
1967
1968	static int hw_mic_source_switch_get(struct hw *hw)
1969	{
1970	struct hw20k2 *hw20k2 = (struct hw20k2 *)hw;
1971
1972	return hw20k2->mic_source;
1973	}
1974
1975	static int hw_mic_source_switch_put(struct hw *hw, int position)
1976	{
1977	struct hw20k2 *hw20k2 = (struct hw20k2 *)hw;
1978
1979	if (position == hw20k2->mic_source)
1980	return 0;
1981
1982	switch (position) {
1983	case 0:
1984	hw_wm8775_input_select(hw, input: 0, gain_in_db: 0); /* Mic, 0dB */
1985	break;
1986	case 1:
1987	hw_wm8775_input_select(hw, input: 1, gain_in_db: 0); /* FP Mic, 0dB */
1988	break;
1989	case 2:
1990	hw_wm8775_input_select(hw, input: 3, gain_in_db: 0); /* Aux Ext, 0dB */
1991	break;
1992	default:
1993	return 0;
1994	}
1995
1996	hw20k2->mic_source = position;
1997
1998	return 1;
1999	}
2000
2001	static irqreturn_t ct_20k2_interrupt(int irq, void *dev_id)
2002	{
2003	struct hw *hw = dev_id;
2004	unsigned int status;
2005
2006	status = hw_read_20kx(hw, GIP);
2007	if (!status)
2008	return IRQ_NONE;
2009
2010	if (hw->irq_callback)
2011	hw->irq_callback(hw->irq_callback_data, status);
2012
2013	hw_write_20kx(hw, GIP, data: status);
2014	return IRQ_HANDLED;
2015	}
2016
2017	static int hw_card_start(struct hw *hw)
2018	{
2019	int err = 0;
2020	struct pci_dev *pci = hw->pci;
2021	unsigned int gctl;
2022	const unsigned int dma_bits = BITS_PER_LONG;
2023
2024	err = pci_enable_device(dev: pci);
2025	if (err < 0)
2026	return err;
2027
2028	/* Set DMA transfer mask */
2029	if (dma_set_mask_and_coherent(dev: &pci->dev, DMA_BIT_MASK(dma_bits)))
2030	dma_set_mask_and_coherent(dev: &pci->dev, DMA_BIT_MASK(32));
2031
2032	if (!hw->io_base) {
2033	err = pci_request_regions(pci, "XFi");
2034	if (err < 0)
2035	goto error1;
2036
2037	hw->io_base = pci_resource_start(hw->pci, 2);
2038	hw->mem_base = ioremap(offset: hw->io_base,
2039	pci_resource_len(hw->pci, 2));
2040	if (!hw->mem_base) {
2041	err = -ENOENT;
2042	goto error2;
2043	}
2044	}
2045
2046	/* Switch to 20k2 mode from UAA mode. */
2047	gctl = hw_read_20kx(hw, GLOBAL_CNTL_GCTL);
2048	set_field(data: &gctl, GCTL_UAA, value: 0);
2049	hw_write_20kx(hw, GLOBAL_CNTL_GCTL, data: gctl);
2050
2051	if (hw->irq < 0) {
2052	err = request_irq(irq: pci->irq, handler: ct_20k2_interrupt, IRQF_SHARED,
2053	KBUILD_MODNAME, dev: hw);
2054	if (err < 0) {
2055	dev_err(hw->card->dev,
2056	"XFi: Cannot get irq %d\n", pci->irq);
2057	goto error2;
2058	}
2059	hw->irq = pci->irq;
2060	hw->card->sync_irq = hw->irq;
2061	}
2062
2063	pci_set_master(dev: pci);
2064
2065	return 0;
2066
2067	/*error3:
2068	iounmap((void *)hw->mem_base);
2069	hw->mem_base = (unsigned long)NULL;*/
2070	error2:
2071	pci_release_regions(pci);
2072	hw->io_base = 0;
2073	error1:
2074	pci_disable_device(dev: pci);
2075	return err;
2076	}
2077
2078	static int hw_card_stop(struct hw *hw)
2079	{
2080	unsigned int data;
2081
2082	/* disable transport bus master and queueing of request */
2083	hw_write_20kx(hw, TRANSPORT_CTL, data: 0x00);
2084
2085	/* disable pll */
2086	data = hw_read_20kx(hw, PLL_ENB);
2087	hw_write_20kx(hw, PLL_ENB, data: (data & (~0x07)));
2088
2089	/* TODO: Disable interrupt and so on... */
2090	return 0;
2091	}
2092
2093	static int hw_card_shutdown(struct hw *hw)
2094	{
2095	if (hw->irq >= 0)
2096	free_irq(hw->irq, hw);
2097
2098	hw->irq = -1;
2099	iounmap(addr: hw->mem_base);
2100	hw->mem_base = NULL;
2101
2102	if (hw->io_base)
2103	pci_release_regions(hw->pci);
2104
2105	hw->io_base = 0;
2106
2107	pci_disable_device(dev: hw->pci);
2108
2109	return 0;
2110	}
2111
2112	static int hw_card_init(struct hw *hw, struct card_conf *info)
2113	{
2114	int err;
2115	unsigned int gctl;
2116	u32 data = 0;
2117	struct dac_conf dac_info = {0};
2118	struct adc_conf adc_info = {0};
2119	struct daio_conf daio_info = {0};
2120	struct trn_conf trn_info = {0};
2121
2122	/* Get PCI io port/memory base address and
2123	* do 20kx core switch if needed. */
2124	err = hw_card_start(hw);
2125	if (err)
2126	return err;
2127
2128	/* PLL init */
2129	err = hw_pll_init(hw, rsr: info->rsr);
2130	if (err < 0)
2131	return err;
2132
2133	/* kick off auto-init */
2134	err = hw_auto_init(hw);
2135	if (err < 0)
2136	return err;
2137
2138	gctl = hw_read_20kx(hw, GLOBAL_CNTL_GCTL);
2139	set_field(data: &gctl, GCTL_DBP, value: 1);
2140	set_field(data: &gctl, GCTL_TBP, value: 1);
2141	set_field(data: &gctl, GCTL_FBP, value: 1);
2142	set_field(data: &gctl, GCTL_DPC, value: 0);
2143	hw_write_20kx(hw, GLOBAL_CNTL_GCTL, data: gctl);
2144
2145	/* Reset all global pending interrupts */
2146	hw_write_20kx(hw, GIE, data: 0);
2147	/* Reset all SRC pending interrupts */
2148	hw_write_20kx(hw, SRC_IP, data: 0);
2149
2150	if (hw->model != CTSB1270) {
2151	/* TODO: detect the card ID and configure GPIO accordingly. */
2152	/* Configures GPIO (0xD802 0x98028) */
2153	/*hw_write_20kx(hw, GPIO_CTRL, 0x7F07);*/
2154	/* Configures GPIO (SB0880) */
2155	/*hw_write_20kx(hw, GPIO_CTRL, 0xFF07);*/
2156	hw_write_20kx(hw, GPIO_CTRL, data: 0xD802);
2157	} else {
2158	hw_write_20kx(hw, GPIO_CTRL, data: 0x9E5F);
2159	}
2160	/* Enable audio ring */
2161	hw_write_20kx(hw, MIXER_AR_ENABLE, data: 0x01);
2162
2163	trn_info.vm_pgt_phys = info->vm_pgt_phys;
2164	err = hw_trn_init(hw, info: &trn_info);
2165	if (err < 0)
2166	return err;
2167
2168	daio_info.msr = info->msr;
2169	err = hw_daio_init(hw, info: &daio_info);
2170	if (err < 0)
2171	return err;
2172
2173	dac_info.msr = info->msr;
2174	err = hw_dac_init(hw, info: &dac_info);
2175	if (err < 0)
2176	return err;
2177
2178	adc_info.msr = info->msr;
2179	adc_info.input = ADC_LINEIN;
2180	adc_info.mic20db = 0;
2181	err = hw_adc_init(hw, info: &adc_info);
2182	if (err < 0)
2183	return err;
2184
2185	data = hw_read_20kx(hw, SRC_MCTL);
2186	data |= 0x1; /* Enables input from the audio ring */
2187	hw_write_20kx(hw, SRC_MCTL, data);
2188
2189	return 0;
2190	}
2191
2192	#ifdef CONFIG_PM_SLEEP
2193	static int hw_suspend(struct hw *hw)
2194	{
2195	hw_card_stop(hw);
2196	return 0;
2197	}
2198
2199	static int hw_resume(struct hw *hw, struct card_conf *info)
2200	{
2201	/* Re-initialize card hardware. */
2202	return hw_card_init(hw, info);
2203	}
2204	#endif
2205
2206	static u32 hw_read_20kx(struct hw *hw, u32 reg)
2207	{
2208	return readl(addr: hw->mem_base + reg);
2209	}
2210
2211	static void hw_write_20kx(struct hw *hw, u32 reg, u32 data)
2212	{
2213	writel(val: data, addr: hw->mem_base + reg);
2214	}
2215
2216	static const struct hw ct20k2_preset = {
2217	.irq = -1,
2218
2219	.card_init = hw_card_init,
2220	.card_stop = hw_card_stop,
2221	.pll_init = hw_pll_init,
2222	.is_adc_source_selected = hw_is_adc_input_selected,
2223	.select_adc_source = hw_adc_input_select,
2224	.capabilities = hw_capabilities,
2225	.output_switch_get = hw_output_switch_get,
2226	.output_switch_put = hw_output_switch_put,
2227	.mic_source_switch_get = hw_mic_source_switch_get,
2228	.mic_source_switch_put = hw_mic_source_switch_put,
2229	#ifdef CONFIG_PM_SLEEP
2230	.suspend = hw_suspend,
2231	.resume = hw_resume,
2232	#endif
2233
2234	.src_rsc_get_ctrl_blk = src_get_rsc_ctrl_blk,
2235	.src_rsc_put_ctrl_blk = src_put_rsc_ctrl_blk,
2236	.src_mgr_get_ctrl_blk = src_mgr_get_ctrl_blk,
2237	.src_mgr_put_ctrl_blk = src_mgr_put_ctrl_blk,
2238	.src_set_state = src_set_state,
2239	.src_set_bm = src_set_bm,
2240	.src_set_rsr = src_set_rsr,
2241	.src_set_sf = src_set_sf,
2242	.src_set_wr = src_set_wr,
2243	.src_set_pm = src_set_pm,
2244	.src_set_rom = src_set_rom,
2245	.src_set_vo = src_set_vo,
2246	.src_set_st = src_set_st,
2247	.src_set_ie = src_set_ie,
2248	.src_set_ilsz = src_set_ilsz,
2249	.src_set_bp = src_set_bp,
2250	.src_set_cisz = src_set_cisz,
2251	.src_set_ca = src_set_ca,
2252	.src_set_sa = src_set_sa,
2253	.src_set_la = src_set_la,
2254	.src_set_pitch = src_set_pitch,
2255	.src_set_dirty = src_set_dirty,
2256	.src_set_clear_zbufs = src_set_clear_zbufs,
2257	.src_set_dirty_all = src_set_dirty_all,
2258	.src_commit_write = src_commit_write,
2259	.src_get_ca = src_get_ca,
2260	.src_get_dirty = src_get_dirty,
2261	.src_dirty_conj_mask = src_dirty_conj_mask,
2262	.src_mgr_enbs_src = src_mgr_enbs_src,
2263	.src_mgr_enb_src = src_mgr_enb_src,
2264	.src_mgr_dsb_src = src_mgr_dsb_src,
2265	.src_mgr_commit_write = src_mgr_commit_write,
2266
2267	.srcimp_mgr_get_ctrl_blk = srcimp_mgr_get_ctrl_blk,
2268	.srcimp_mgr_put_ctrl_blk = srcimp_mgr_put_ctrl_blk,
2269	.srcimp_mgr_set_imaparc = srcimp_mgr_set_imaparc,
2270	.srcimp_mgr_set_imapuser = srcimp_mgr_set_imapuser,
2271	.srcimp_mgr_set_imapnxt = srcimp_mgr_set_imapnxt,
2272	.srcimp_mgr_set_imapaddr = srcimp_mgr_set_imapaddr,
2273	.srcimp_mgr_commit_write = srcimp_mgr_commit_write,
2274
2275	.amixer_rsc_get_ctrl_blk = amixer_rsc_get_ctrl_blk,
2276	.amixer_rsc_put_ctrl_blk = amixer_rsc_put_ctrl_blk,
2277	.amixer_mgr_get_ctrl_blk = amixer_mgr_get_ctrl_blk,
2278	.amixer_mgr_put_ctrl_blk = amixer_mgr_put_ctrl_blk,
2279	.amixer_set_mode = amixer_set_mode,
2280	.amixer_set_iv = amixer_set_iv,
2281	.amixer_set_x = amixer_set_x,
2282	.amixer_set_y = amixer_set_y,
2283	.amixer_set_sadr = amixer_set_sadr,
2284	.amixer_set_se = amixer_set_se,
2285	.amixer_set_dirty = amixer_set_dirty,
2286	.amixer_set_dirty_all = amixer_set_dirty_all,
2287	.amixer_commit_write = amixer_commit_write,
2288	.amixer_get_y = amixer_get_y,
2289	.amixer_get_dirty = amixer_get_dirty,
2290
2291	.dai_get_ctrl_blk = dai_get_ctrl_blk,
2292	.dai_put_ctrl_blk = dai_put_ctrl_blk,
2293	.dai_srt_set_srco = dai_srt_set_srco,
2294	.dai_srt_set_srcm = dai_srt_set_srcm,
2295	.dai_srt_set_rsr = dai_srt_set_rsr,
2296	.dai_srt_set_drat = dai_srt_set_drat,
2297	.dai_srt_set_ec = dai_srt_set_ec,
2298	.dai_srt_set_et = dai_srt_set_et,
2299	.dai_commit_write = dai_commit_write,
2300
2301	.dao_get_ctrl_blk = dao_get_ctrl_blk,
2302	.dao_put_ctrl_blk = dao_put_ctrl_blk,
2303	.dao_set_spos = dao_set_spos,
2304	.dao_commit_write = dao_commit_write,
2305	.dao_get_spos = dao_get_spos,
2306
2307	.daio_mgr_get_ctrl_blk = daio_mgr_get_ctrl_blk,
2308	.daio_mgr_put_ctrl_blk = daio_mgr_put_ctrl_blk,
2309	.daio_mgr_enb_dai = daio_mgr_enb_dai,
2310	.daio_mgr_dsb_dai = daio_mgr_dsb_dai,
2311	.daio_mgr_enb_dao = daio_mgr_enb_dao,
2312	.daio_mgr_dsb_dao = daio_mgr_dsb_dao,
2313	.daio_mgr_dao_init = daio_mgr_dao_init,
2314	.daio_mgr_set_imaparc = daio_mgr_set_imaparc,
2315	.daio_mgr_set_imapnxt = daio_mgr_set_imapnxt,
2316	.daio_mgr_set_imapaddr = daio_mgr_set_imapaddr,
2317	.daio_mgr_commit_write = daio_mgr_commit_write,
2318
2319	.set_timer_irq = set_timer_irq,
2320	.set_timer_tick = set_timer_tick,
2321	.get_wc = get_wc,
2322	};
2323
2324	int create_20k2_hw_obj(struct hw **rhw)
2325	{
2326	struct hw20k2 *hw20k2;
2327
2328	*rhw = NULL;
2329	hw20k2 = kzalloc(size: sizeof(*hw20k2), GFP_KERNEL);
2330	if (!hw20k2)
2331	return -ENOMEM;
2332
2333	hw20k2->hw = ct20k2_preset;
2334	*rhw = &hw20k2->hw;
2335
2336	return 0;
2337	}
2338
2339	int destroy_20k2_hw_obj(struct hw *hw)
2340	{
2341	if (hw->io_base)
2342	hw_card_shutdown(hw);
2343
2344	kfree(objp: hw);
2345	return 0;
2346	}
2347