mt8183-afe-pcm.c source code [linux/sound/soc/mediatek/mt8183/mt8183-afe-pcm.c]

1	// SPDX-License-Identifier: GPL-2.0
2	//
3	// Mediatek ALSA SoC AFE platform driver for 8183
4	//
5	// Copyright (c) 2018 MediaTek Inc.
6	// Author: KaiChieh Chuang <kaichieh.chuang@mediatek.com>
7
8	#include <linux/delay.h>
9	#include <linux/dma-mapping.h>
10	#include <linux/module.h>
11	#include <linux/mfd/syscon.h>
12	#include <linux/of.h>
13	#include <linux/of_address.h>
14	#include <linux/of_reserved_mem.h>
15	#include <linux/pm_runtime.h>
16	#include <linux/reset.h>
17
18	#include "mt8183-afe-common.h"
19	#include "mt8183-afe-clk.h"
20	#include "mt8183-interconnection.h"
21	#include "mt8183-reg.h"
22	#include "../common/mtk-afe-platform-driver.h"
23	#include "../common/mtk-afe-fe-dai.h"
24
25	enum {
26	MTK_AFE_RATE_8K = `0`,
27	MTK_AFE_RATE_11K = `1`,
28	MTK_AFE_RATE_12K = `2`,
29	MTK_AFE_RATE_384K = `3`,
30	MTK_AFE_RATE_16K = `4`,
31	MTK_AFE_RATE_22K = `5`,
32	MTK_AFE_RATE_24K = `6`,
33	MTK_AFE_RATE_130K = `7`,
34	MTK_AFE_RATE_32K = `8`,
35	MTK_AFE_RATE_44K = `9`,
36	MTK_AFE_RATE_48K = `10`,
37	MTK_AFE_RATE_88K = `11`,
38	MTK_AFE_RATE_96K = `12`,
39	MTK_AFE_RATE_176K = `13`,
40	MTK_AFE_RATE_192K = `14`,
41	MTK_AFE_RATE_260K = `15`,
42	};
43
44	enum {
45	MTK_AFE_DAI_MEMIF_RATE_8K = `0`,
46	MTK_AFE_DAI_MEMIF_RATE_16K = `1`,
47	MTK_AFE_DAI_MEMIF_RATE_32K = `2`,
48	MTK_AFE_DAI_MEMIF_RATE_48K = `3`,
49	};
50
51	enum {
52	MTK_AFE_PCM_RATE_8K = `0`,
53	MTK_AFE_PCM_RATE_16K = `1`,
54	MTK_AFE_PCM_RATE_32K = `2`,
55	MTK_AFE_PCM_RATE_48K = `3`,
56	};
57
58	unsigned int mt8183_general_rate_transform(struct device *dev,
59	unsigned int rate)
60	{
61	switch (rate) {
62	case `8000`:
63	return MTK_AFE_RATE_8K;
64	case `11025`:
65	return MTK_AFE_RATE_11K;
66	case `12000`:
67	return MTK_AFE_RATE_12K;
68	case `16000`:
69	return MTK_AFE_RATE_16K;
70	case `22050`:
71	return MTK_AFE_RATE_22K;
72	case `24000`:
73	return MTK_AFE_RATE_24K;
74	case `32000`:
75	return MTK_AFE_RATE_32K;
76	case `44100`:
77	return MTK_AFE_RATE_44K;
78	case `48000`:
79	return MTK_AFE_RATE_48K;
80	case `88200`:
81	return MTK_AFE_RATE_88K;
82	case `96000`:
83	return MTK_AFE_RATE_96K;
84	case `130000`:
85	return MTK_AFE_RATE_130K;
86	case `176400`:
87	return MTK_AFE_RATE_176K;
88	case `192000`:
89	return MTK_AFE_RATE_192K;
90	case `260000`:
91	return MTK_AFE_RATE_260K;
92	default:
93	dev_warn(dev, "%s(), rate %u invalid, use %d!!!\n",
94	__func__, rate, MTK_AFE_RATE_48K);
95	return MTK_AFE_RATE_48K;
96	}
97	}
98
99	static unsigned int dai_memif_rate_transform(struct device *dev,
100	unsigned int rate)
101	{
102	switch (rate) {
103	case `8000`:
104	return MTK_AFE_DAI_MEMIF_RATE_8K;
105	case `16000`:
106	return MTK_AFE_DAI_MEMIF_RATE_16K;
107	case `32000`:
108	return MTK_AFE_DAI_MEMIF_RATE_32K;
109	case `48000`:
110	return MTK_AFE_DAI_MEMIF_RATE_48K;
111	default:
112	dev_warn(dev, "%s(), rate %u invalid, use %d!!!\n",
113	__func__, rate, MTK_AFE_DAI_MEMIF_RATE_16K);
114	return MTK_AFE_DAI_MEMIF_RATE_16K;
115	}
116	}
117
118	unsigned int mt8183_rate_transform(struct device *dev,
119	unsigned int rate, int aud_blk)
120	{
121	switch (aud_blk) {
122	case MT8183_MEMIF_MOD_DAI:
123	return dai_memif_rate_transform(dev, rate);
124	default:
125	return mt8183_general_rate_transform(dev, rate);
126	}
127	}
128
129	static const struct snd_pcm_hardware mt8183_afe_hardware = {
130	.info = SNDRV_PCM_INFO_MMAP \|
131	SNDRV_PCM_INFO_INTERLEAVED \|
132	SNDRV_PCM_INFO_MMAP_VALID,
133	.formats = SNDRV_PCM_FMTBIT_S16_LE \|
134	SNDRV_PCM_FMTBIT_S24_LE \|
135	SNDRV_PCM_FMTBIT_S32_LE,
136	.period_bytes_min = `256`,
137	.period_bytes_max = `4` * `48` * `1024`,
138	.periods_min = `2`,
139	.periods_max = `256`,
140	.buffer_bytes_max = `8` * `48` * `1024`,
141	.fifo_size = `0`,
142	};
143
144	static int mt8183_memif_fs(struct snd_pcm_substream *substream,
145	unsigned int rate)
146	{
147	struct snd_soc_pcm_runtime *rtd = snd_soc_substream_to_rtd(substream);
148	struct snd_soc_component *component =
149	snd_soc_rtdcom_lookup(rtd, AFE_PCM_NAME);
150	struct mtk_base_afe *afe = snd_soc_component_get_drvdata(c: component);
151	int id = snd_soc_rtd_to_cpu(rtd, `0`)->id;
152
153	return mt8183_rate_transform(dev: afe->dev, rate, aud_blk: id);
154	}
155
156	static int mt8183_irq_fs(struct snd_pcm_substream substream, unsigned* int rate)
157	{
158	struct snd_soc_pcm_runtime *rtd = snd_soc_substream_to_rtd(substream);
159	struct snd_soc_component *component =
160	snd_soc_rtdcom_lookup(rtd, AFE_PCM_NAME);
161	struct mtk_base_afe *afe = snd_soc_component_get_drvdata(c: component);
162
163	return mt8183_general_rate_transform(dev: afe->dev, rate);
164	}
165
166	#define MTK_PCM_RATES (SNDRV_PCM_RATE_8000_48000 \|\
167	SNDRV_PCM_RATE_88200 \|\
168	SNDRV_PCM_RATE_96000 \|\
169	SNDRV_PCM_RATE_176400 \|\
170	SNDRV_PCM_RATE_192000)
171
172	#define MTK_PCM_DAI_RATES (SNDRV_PCM_RATE_8000 \|\
173	SNDRV_PCM_RATE_16000 \|\
174	SNDRV_PCM_RATE_32000 \|\
175	SNDRV_PCM_RATE_48000)
176
177	#define MTK_PCM_FORMATS (SNDRV_PCM_FMTBIT_S16_LE \|\
178	SNDRV_PCM_FMTBIT_S24_LE \|\
179	SNDRV_PCM_FMTBIT_S32_LE)
180
181	static struct snd_soc_dai_driver mt8183_memif_dai_driver[] = {
182	/ FE DAIs: memory intefaces to CPU /
183	{
184	.name = "DL1",
185	.id = MT8183_MEMIF_DL1,
186	.playback = {
187	.stream_name = "DL1",
188	.channels_min = `1`,
189	.channels_max = `2`,
190	.rates = MTK_PCM_RATES,
191	.formats = MTK_PCM_FORMATS,
192	},
193	.ops = &mtk_afe_fe_ops,
194	},
195	{
196	.name = "DL2",
197	.id = MT8183_MEMIF_DL2,
198	.playback = {
199	.stream_name = "DL2",
200	.channels_min = `1`,
201	.channels_max = `2`,
202	.rates = MTK_PCM_RATES,
203	.formats = MTK_PCM_FORMATS,
204	},
205	.ops = &mtk_afe_fe_ops,
206	},
207	{
208	.name = "DL3",
209	.id = MT8183_MEMIF_DL3,
210	.playback = {
211	.stream_name = "DL3",
212	.channels_min = `1`,
213	.channels_max = `2`,
214	.rates = MTK_PCM_RATES,
215	.formats = MTK_PCM_FORMATS,
216	},
217	.ops = &mtk_afe_fe_ops,
218	},
219	{
220	.name = "UL1",
221	.id = MT8183_MEMIF_VUL12,
222	.capture = {
223	.stream_name = "UL1",
224	.channels_min = `1`,
225	.channels_max = `2`,
226	.rates = MTK_PCM_RATES,
227	.formats = MTK_PCM_FORMATS,
228	},
229	.ops = &mtk_afe_fe_ops,
230	},
231	{
232	.name = "UL2",
233	.id = MT8183_MEMIF_AWB,
234	.capture = {
235	.stream_name = "UL2",
236	.channels_min = `1`,
237	.channels_max = `2`,
238	.rates = MTK_PCM_RATES,
239	.formats = MTK_PCM_FORMATS,
240	},
241	.ops = &mtk_afe_fe_ops,
242	},
243	{
244	.name = "UL3",
245	.id = MT8183_MEMIF_VUL2,
246	.capture = {
247	.stream_name = "UL3",
248	.channels_min = `1`,
249	.channels_max = `2`,
250	.rates = MTK_PCM_RATES,
251	.formats = MTK_PCM_FORMATS,
252	},
253	.ops = &mtk_afe_fe_ops,
254	},
255	{
256	.name = "UL4",
257	.id = MT8183_MEMIF_AWB2,
258	.capture = {
259	.stream_name = "UL4",
260	.channels_min = `1`,
261	.channels_max = `2`,
262	.rates = MTK_PCM_RATES,
263	.formats = MTK_PCM_FORMATS,
264	},
265	.ops = &mtk_afe_fe_ops,
266	},
267	{
268	.name = "UL_MONO_1",
269	.id = MT8183_MEMIF_MOD_DAI,
270	.capture = {
271	.stream_name = "UL_MONO_1",
272	.channels_min = `1`,
273	.channels_max = `1`,
274	.rates = MTK_PCM_DAI_RATES,
275	.formats = MTK_PCM_FORMATS,
276	},
277	.ops = &mtk_afe_fe_ops,
278	},
279	{
280	.name = "HDMI",
281	.id = MT8183_MEMIF_HDMI,
282	.playback = {
283	.stream_name = "HDMI",
284	.channels_min = `2`,
285	.channels_max = `8`,
286	.rates = MTK_PCM_RATES,
287	.formats = MTK_PCM_FORMATS,
288	},
289	.ops = &mtk_afe_fe_ops,
290	},
291	};
292
293	/ dma widget & routes/
294	static const struct snd_kcontrol_new memif_ul1_ch1_mix[] = {
295	SOC_DAPM_SINGLE_AUTODISABLE("ADDA_UL_CH1", AFE_CONN21,
296	I_ADDA_UL_CH1, `1`, `0`),
297	SOC_DAPM_SINGLE_AUTODISABLE("I2S0_CH1", AFE_CONN21,
298	I_I2S0_CH1, `1`, `0`),
299	};
300
301	static const struct snd_kcontrol_new memif_ul1_ch2_mix[] = {
302	SOC_DAPM_SINGLE_AUTODISABLE("ADDA_UL_CH2", AFE_CONN22,
303	I_ADDA_UL_CH2, `1`, `0`),
304	SOC_DAPM_SINGLE_AUTODISABLE("I2S0_CH2", AFE_CONN21,
305	I_I2S0_CH2, `1`, `0`),
306	};
307
308	static const struct snd_kcontrol_new memif_ul2_ch1_mix[] = {
309	SOC_DAPM_SINGLE_AUTODISABLE("ADDA_UL_CH1", AFE_CONN5,
310	I_ADDA_UL_CH1, `1`, `0`),
311	SOC_DAPM_SINGLE_AUTODISABLE("DL1_CH1", AFE_CONN5,
312	I_DL1_CH1, `1`, `0`),
313	SOC_DAPM_SINGLE_AUTODISABLE("DL2_CH1", AFE_CONN5,
314	I_DL2_CH1, `1`, `0`),
315	SOC_DAPM_SINGLE_AUTODISABLE("DL3_CH1", AFE_CONN5,
316	I_DL3_CH1, `1`, `0`),
317	SOC_DAPM_SINGLE_AUTODISABLE("I2S2_CH1", AFE_CONN5,
318	I_I2S2_CH1, `1`, `0`),
319	};
320
321	static const struct snd_kcontrol_new memif_ul2_ch2_mix[] = {
322	SOC_DAPM_SINGLE_AUTODISABLE("ADDA_UL_CH2", AFE_CONN6,
323	I_ADDA_UL_CH2, `1`, `0`),
324	SOC_DAPM_SINGLE_AUTODISABLE("DL1_CH2", AFE_CONN6,
325	I_DL1_CH2, `1`, `0`),
326	SOC_DAPM_SINGLE_AUTODISABLE("DL2_CH2", AFE_CONN6,
327	I_DL2_CH2, `1`, `0`),
328	SOC_DAPM_SINGLE_AUTODISABLE("DL3_CH2", AFE_CONN6,
329	I_DL3_CH2, `1`, `0`),
330	SOC_DAPM_SINGLE_AUTODISABLE("I2S2_CH2", AFE_CONN6,
331	I_I2S2_CH2, `1`, `0`),
332	};
333
334	static const struct snd_kcontrol_new memif_ul3_ch1_mix[] = {
335	SOC_DAPM_SINGLE_AUTODISABLE("ADDA_UL_CH1", AFE_CONN32,
336	I_ADDA_UL_CH1, `1`, `0`),
337	SOC_DAPM_SINGLE_AUTODISABLE("I2S2_CH1", AFE_CONN32,
338	I_I2S2_CH1, `1`, `0`),
339	};
340
341	static const struct snd_kcontrol_new memif_ul3_ch2_mix[] = {
342	SOC_DAPM_SINGLE_AUTODISABLE("ADDA_UL_CH2", AFE_CONN33,
343	I_ADDA_UL_CH2, `1`, `0`),
344	SOC_DAPM_SINGLE_AUTODISABLE("I2S2_CH2", AFE_CONN33,
345	I_I2S2_CH2, `1`, `0`),
346	};
347
348	static const struct snd_kcontrol_new memif_ul4_ch1_mix[] = {
349	SOC_DAPM_SINGLE_AUTODISABLE("ADDA_UL_CH1", AFE_CONN38,
350	I_ADDA_UL_CH1, `1`, `0`),
351	};
352
353	static const struct snd_kcontrol_new memif_ul4_ch2_mix[] = {
354	SOC_DAPM_SINGLE_AUTODISABLE("ADDA_UL_CH2", AFE_CONN39,
355	I_ADDA_UL_CH2, `1`, `0`),
356	};
357
358	static const struct snd_kcontrol_new memif_ul_mono_1_mix[] = {
359	SOC_DAPM_SINGLE_AUTODISABLE("ADDA_UL_CH1", AFE_CONN12,
360	I_ADDA_UL_CH1, `1`, `0`),
361	SOC_DAPM_SINGLE_AUTODISABLE("ADDA_UL_CH2", AFE_CONN12,
362	I_ADDA_UL_CH2, `1`, `0`),
363	};
364
365	static const struct snd_soc_dapm_widget mt8183_memif_widgets[] = {
366	/ memif /
367	SND_SOC_DAPM_MIXER("UL1_CH1", SND_SOC_NOPM, `0`, `0`,
368	memif_ul1_ch1_mix, ARRAY_SIZE(memif_ul1_ch1_mix)),
369	SND_SOC_DAPM_MIXER("UL1_CH2", SND_SOC_NOPM, `0`, `0`,
370	memif_ul1_ch2_mix, ARRAY_SIZE(memif_ul1_ch2_mix)),
371
372	SND_SOC_DAPM_MIXER("UL2_CH1", SND_SOC_NOPM, `0`, `0`,
373	memif_ul2_ch1_mix, ARRAY_SIZE(memif_ul2_ch1_mix)),
374	SND_SOC_DAPM_MIXER("UL2_CH2", SND_SOC_NOPM, `0`, `0`,
375	memif_ul2_ch2_mix, ARRAY_SIZE(memif_ul2_ch2_mix)),
376
377	SND_SOC_DAPM_MIXER("UL3_CH1", SND_SOC_NOPM, `0`, `0`,
378	memif_ul3_ch1_mix, ARRAY_SIZE(memif_ul3_ch1_mix)),
379	SND_SOC_DAPM_MIXER("UL3_CH2", SND_SOC_NOPM, `0`, `0`,
380	memif_ul3_ch2_mix, ARRAY_SIZE(memif_ul3_ch2_mix)),
381
382	SND_SOC_DAPM_MIXER("UL4_CH1", SND_SOC_NOPM, `0`, `0`,
383	memif_ul4_ch1_mix, ARRAY_SIZE(memif_ul4_ch1_mix)),
384	SND_SOC_DAPM_MIXER("UL4_CH2", SND_SOC_NOPM, `0`, `0`,
385	memif_ul4_ch2_mix, ARRAY_SIZE(memif_ul4_ch2_mix)),
386
387	SND_SOC_DAPM_MIXER("UL_MONO_1_CH1", SND_SOC_NOPM, `0`, `0`,
388	memif_ul_mono_1_mix,
389	ARRAY_SIZE(memif_ul_mono_1_mix)),
390	};
391
392	static const struct snd_soc_dapm_route mt8183_memif_routes[] = {
393	/ capture /
394	{"UL1", NULL, "UL1_CH1"},
395	{"UL1", NULL, "UL1_CH2"},
396	{"UL1_CH1", "ADDA_UL_CH1", "ADDA Capture"},
397	{"UL1_CH2", "ADDA_UL_CH2", "ADDA Capture"},
398	{"UL1_CH1", "I2S0_CH1", "I2S0"},
399	{"UL1_CH2", "I2S0_CH2", "I2S0"},
400
401	{"UL2", NULL, "UL2_CH1"},
402	{"UL2", NULL, "UL2_CH2"},
403	{"UL2_CH1", "ADDA_UL_CH1", "ADDA Capture"},
404	{"UL2_CH2", "ADDA_UL_CH2", "ADDA Capture"},
405	{"UL2_CH1", "I2S2_CH1", "I2S2"},
406	{"UL2_CH2", "I2S2_CH2", "I2S2"},
407
408	{"UL3", NULL, "UL3_CH1"},
409	{"UL3", NULL, "UL3_CH2"},
410	{"UL3_CH1", "ADDA_UL_CH1", "ADDA Capture"},
411	{"UL3_CH2", "ADDA_UL_CH2", "ADDA Capture"},
412	{"UL3_CH1", "I2S2_CH1", "I2S2"},
413	{"UL3_CH2", "I2S2_CH2", "I2S2"},
414
415	{"UL4", NULL, "UL4_CH1"},
416	{"UL4", NULL, "UL4_CH2"},
417	{"UL4_CH1", "ADDA_UL_CH1", "ADDA Capture"},
418	{"UL4_CH2", "ADDA_UL_CH2", "ADDA Capture"},
419
420	{"UL_MONO_1", NULL, "UL_MONO_1_CH1"},
421	{"UL_MONO_1_CH1", "ADDA_UL_CH1", "ADDA Capture"},
422	{"UL_MONO_1_CH1", "ADDA_UL_CH2", "ADDA Capture"},
423	};
424
425	static const struct snd_soc_component_driver mt8183_afe_pcm_dai_component = {
426	.name = "mt8183-afe-pcm-dai",
427	};
428
429	#define MT8183_MEMIF_BASE(_id, _en_reg, _fs_reg, _mono_reg) \
430	[MT8183_MEMIF_##_id] = { \
431	.name = #_id, \
432	.id = MT8183_MEMIF_##_id, \
433	.reg_ofs_base = AFE_##_id##_BASE, \
434	.reg_ofs_cur = AFE_##_id##_CUR, \
435	.reg_ofs_end = AFE_##_id##_END, \
436	.reg_ofs_base_msb = AFE_##_id##_BASE_MSB, \
437	.reg_ofs_cur_msb = AFE_##_id##_CUR_MSB, \
438	.reg_ofs_end_msb = AFE_##_id##_END_MSB, \
439	.fs_reg = (_fs_reg), \
440	.fs_shift = _id##_MODE_SFT, \
441	.fs_maskbit = _id##_MODE_MASK, \
442	.mono_reg = (_mono_reg), \
443	.mono_shift = _id##_DATA_SFT, \
444	.enable_reg = (_en_reg), \
445	.enable_shift = _id##_ON_SFT, \
446	.hd_reg = AFE_MEMIF_HD_MODE, \
447	.hd_align_reg = AFE_MEMIF_HDALIGN, \
448	.hd_shift = _id##_HD_SFT, \
449	.hd_align_mshift = _id##_HD_ALIGN_SFT, \
450	.agent_disable_reg = -1, \
451	.agent_disable_shift = -1, \
452	.msb_reg = -1, \
453	.msb_shift = -1, \
454	}
455
456	#define MT8183_MEMIF(_id, _fs_reg, _mono_reg) \
457	MT8183_MEMIF_BASE(_id, AFE_DAC_CON0, _fs_reg, _mono_reg)
458
459	/ For convenience with macros: missing register fields /
460	#define MOD_DAI_DATA_SFT -1
461	#define HDMI_MODE_SFT -1
462	#define HDMI_MODE_MASK -1
463	#define HDMI_DATA_SFT -1
464	#define HDMI_ON_SFT -1
465
466	/ For convenience with macros: register name differences /
467	#define AFE_VUL12_BASE AFE_VUL_D2_BASE
468	#define AFE_VUL12_CUR AFE_VUL_D2_CUR
469	#define AFE_VUL12_END AFE_VUL_D2_END
470	#define AFE_VUL12_BASE_MSB AFE_VUL_D2_BASE_MSB
471	#define AFE_VUL12_CUR_MSB AFE_VUL_D2_CUR_MSB
472	#define AFE_VUL12_END_MSB AFE_VUL_D2_END_MSB
473	#define AWB2_HD_ALIGN_SFT AWB2_ALIGN_SFT
474	#define VUL12_DATA_SFT VUL12_MONO_SFT
475	#define AFE_HDMI_BASE AFE_HDMI_OUT_BASE
476	#define AFE_HDMI_CUR AFE_HDMI_OUT_CUR
477	#define AFE_HDMI_END AFE_HDMI_OUT_END
478	#define AFE_HDMI_BASE_MSB AFE_HDMI_OUT_BASE_MSB
479	#define AFE_HDMI_CUR_MSB AFE_HDMI_OUT_CUR_MSB
480	#define AFE_HDMI_END_MSB AFE_HDMI_OUT_END_MSB
481
482	static const struct mtk_base_memif_data memif_data[MT8183_MEMIF_NUM] = {
483	MT8183_MEMIF(DL1, AFE_DAC_CON1, AFE_DAC_CON1),
484	MT8183_MEMIF(DL2, AFE_DAC_CON1, AFE_DAC_CON1),
485	MT8183_MEMIF(DL3, AFE_DAC_CON2, AFE_DAC_CON1),
486	MT8183_MEMIF(VUL2, AFE_DAC_CON2, AFE_DAC_CON2),
487	MT8183_MEMIF(AWB, AFE_DAC_CON1, AFE_DAC_CON1),
488	MT8183_MEMIF(AWB2, AFE_DAC_CON2, AFE_DAC_CON2),
489	MT8183_MEMIF(VUL12, AFE_DAC_CON0, AFE_DAC_CON0),
490	MT8183_MEMIF(MOD_DAI, AFE_DAC_CON1, -`1`),
491	/ enable control in tdm for sync start /
492	MT8183_MEMIF_BASE(HDMI, -`1`, -`1`, -`1`),
493	};
494
495	#define MT8183_AFE_IRQ_BASE(_id, _fs_reg, _fs_shift, _fs_maskbit) \
496	[MT8183_IRQ_##_id] = { \
497	.id = MT8183_IRQ_##_id, \
498	.irq_cnt_reg = AFE_IRQ_MCU_CNT##_id, \
499	.irq_cnt_shift = 0, \
500	.irq_cnt_maskbit = 0x3ffff, \
501	.irq_fs_reg = _fs_reg, \
502	.irq_fs_shift = _fs_shift, \
503	.irq_fs_maskbit = _fs_maskbit, \
504	.irq_en_reg = AFE_IRQ_MCU_CON0, \
505	.irq_en_shift = IRQ##_id##_MCU_ON_SFT, \
506	.irq_clr_reg = AFE_IRQ_MCU_CLR, \
507	.irq_clr_shift = IRQ##_id##_MCU_CLR_SFT, \
508	}
509
510	#define MT8183_AFE_IRQ(_id) \
511	MT8183_AFE_IRQ_BASE(_id, AFE_IRQ_MCU_CON1 + _id / 8 * 4, \
512	IRQ##_id##_MCU_MODE_SFT, \
513	IRQ##_id##_MCU_MODE_MASK)
514
515	#define MT8183_AFE_IRQ_NOFS(_id) MT8183_AFE_IRQ_BASE(_id, -1, -1, -1)
516
517	static const struct mtk_base_irq_data irq_data[MT8183_IRQ_NUM] = {
518	MT8183_AFE_IRQ(`0`),
519	MT8183_AFE_IRQ(`1`),
520	MT8183_AFE_IRQ(`2`),
521	MT8183_AFE_IRQ(`3`),
522	MT8183_AFE_IRQ(`4`),
523	MT8183_AFE_IRQ(`5`),
524	MT8183_AFE_IRQ(`6`),
525	MT8183_AFE_IRQ(`7`),
526	MT8183_AFE_IRQ_NOFS(`8`),
527	MT8183_AFE_IRQ(`11`),
528	MT8183_AFE_IRQ(`12`),
529	};
530
531	static bool mt8183_is_volatile_reg(struct device dev, unsigned* int reg)
532	{
533	/ these auto-gen reg has read-only bit, so put it as volatile /
534	/ volatile reg cannot be cached, so cannot be set when power off /
535	switch (reg) {
536	case AUDIO_TOP_CON0 ... AUDIO_TOP_CON1: / reg bit controlled by CCF /
537	case AUDIO_TOP_CON3:
538	case AFE_DL1_CUR ... AFE_DL1_END:
539	case AFE_DL2_CUR ... AFE_DL2_END:
540	case AFE_AWB_END ... AFE_AWB_CUR:
541	case AFE_VUL_END ... AFE_VUL_CUR:
542	case AFE_MEMIF_MON0 ... AFE_MEMIF_MON9:
543	case AFE_ADDA_SRC_DEBUG_MON0 ... AFE_ADDA_SRC_DEBUG_MON1:
544	case AFE_ADDA_UL_SRC_MON0 ... AFE_ADDA_UL_SRC_MON1:
545	case AFE_SIDETONE_MON:
546	case AFE_SIDETONE_CON0 ... AFE_SIDETONE_COEFF:
547	case AFE_BUS_MON0:
548	case AFE_MRGIF_MON0 ... AFE_I2S_MON:
549	case AFE_DAC_MON:
550	case AFE_VUL2_END ... AFE_VUL2_CUR:
551	case AFE_IRQ0_MCU_CNT_MON ... AFE_IRQ6_MCU_CNT_MON:
552	case AFE_MOD_DAI_END ... AFE_MOD_DAI_CUR:
553	case AFE_VUL_D2_END ... AFE_VUL_D2_CUR:
554	case AFE_DL3_CUR ... AFE_DL3_END:
555	case AFE_HDMI_OUT_CON0:
556	case AFE_HDMI_OUT_CUR ... AFE_HDMI_OUT_END:
557	case AFE_IRQ3_MCU_CNT_MON... AFE_IRQ4_MCU_CNT_MON:
558	case AFE_IRQ_MCU_STATUS ... AFE_IRQ_MCU_CLR:
559	case AFE_IRQ_MCU_MON2:
560	case AFE_IRQ1_MCU_CNT_MON ... AFE_IRQ5_MCU_CNT_MON:
561	case AFE_IRQ7_MCU_CNT_MON:
562	case AFE_GAIN1_CUR:
563	case AFE_GAIN2_CUR:
564	case AFE_SRAM_DELSEL_CON0:
565	case AFE_SRAM_DELSEL_CON2 ... AFE_SRAM_DELSEL_CON3:
566	case AFE_ASRC_2CH_CON12 ... AFE_ASRC_2CH_CON13:
567	case PCM_INTF_CON2:
568	case FPGA_CFG0 ... FPGA_CFG1:
569	case FPGA_CFG2 ... FPGA_CFG3:
570	case AUDIO_TOP_DBG_MON0 ... AUDIO_TOP_DBG_MON1:
571	case AFE_IRQ8_MCU_CNT_MON ... AFE_IRQ12_MCU_CNT_MON:
572	case AFE_CBIP_MON0:
573	case AFE_CBIP_SLV_MUX_MON0 ... AFE_CBIP_SLV_DECODER_MON0:
574	case AFE_ADDA6_SRC_DEBUG_MON0:
575	case AFE_ADD6A_UL_SRC_MON0... AFE_ADDA6_UL_SRC_MON1:
576	case AFE_DL1_CUR_MSB:
577	case AFE_DL2_CUR_MSB:
578	case AFE_AWB_CUR_MSB:
579	case AFE_VUL_CUR_MSB:
580	case AFE_VUL2_CUR_MSB:
581	case AFE_MOD_DAI_CUR_MSB:
582	case AFE_VUL_D2_CUR_MSB:
583	case AFE_DL3_CUR_MSB:
584	case AFE_HDMI_OUT_CUR_MSB:
585	case AFE_AWB2_END ... AFE_AWB2_CUR:
586	case AFE_AWB2_CUR_MSB:
587	case AFE_ADDA_DL_SDM_FIFO_MON ... AFE_ADDA_DL_SDM_OUT_MON:
588	case AFE_CONNSYS_I2S_MON ... AFE_ASRC_2CH_CON0:
589	case AFE_ASRC_2CH_CON2 ... AFE_ASRC_2CH_CON5:
590	case AFE_ASRC_2CH_CON7 ... AFE_ASRC_2CH_CON8:
591	case AFE_MEMIF_MON12 ... AFE_MEMIF_MON24:
592	case AFE_ADDA_MTKAIF_MON0 ... AFE_ADDA_MTKAIF_MON1:
593	case AFE_AUD_PAD_TOP:
594	case AFE_GENERAL1_ASRC_2CH_CON0:
595	case AFE_GENERAL1_ASRC_2CH_CON2 ... AFE_GENERAL1_ASRC_2CH_CON5:
596	case AFE_GENERAL1_ASRC_2CH_CON7 ... AFE_GENERAL1_ASRC_2CH_CON8:
597	case AFE_GENERAL1_ASRC_2CH_CON12 ... AFE_GENERAL1_ASRC_2CH_CON13:
598	case AFE_GENERAL2_ASRC_2CH_CON0:
599	case AFE_GENERAL2_ASRC_2CH_CON2 ... AFE_GENERAL2_ASRC_2CH_CON5:
600	case AFE_GENERAL2_ASRC_2CH_CON7 ... AFE_GENERAL2_ASRC_2CH_CON8:
601	case AFE_GENERAL2_ASRC_2CH_CON12 ... AFE_GENERAL2_ASRC_2CH_CON13:
602	return true;
603	default:
604	return false;
605	};
606	}
607
608	static const struct regmap_config mt8183_afe_regmap_config = {
609	.reg_bits = `32`,
610	.reg_stride = `4`,
611	.val_bits = `32`,
612
613	.volatile_reg = mt8183_is_volatile_reg,
614
615	.max_register = AFE_MAX_REGISTER,
616	.num_reg_defaults_raw = AFE_MAX_REGISTER,
617
618	.cache_type = REGCACHE_FLAT,
619	};
620
621	static irqreturn_t mt8183_afe_irq_handler(int irq_id, void *dev)
622	{
623	struct mtk_base_afe *afe = dev;
624	struct mtk_base_afe_irq *irq;
625	unsigned int status;
626	unsigned int status_mcu;
627	unsigned int mcu_en;
628	int ret;
629	int i;
630	irqreturn_t irq_ret = IRQ_HANDLED;
631
632	/ get irq that is sent to MCU /
633	regmap_read(map: afe->regmap, AFE_IRQ_MCU_EN, val: &mcu_en);
634
635	ret = regmap_read(map: afe->regmap, AFE_IRQ_MCU_STATUS, val: &status);
636	/ only care IRQ which is sent to MCU /
637	status_mcu = status & mcu_en & AFE_IRQ_STATUS_BITS;
638
639	if (ret \|\| status_mcu == `0`) {
640	dev_err(afe->dev, "%s(), irq status err, ret %d, status 0x%x, mcu_en 0x%x\n",
641	__func__, ret, status, mcu_en);
642
643	irq_ret = IRQ_NONE;
644	goto err_irq;
645	}
646
647	for (i = `0`; i < MT8183_MEMIF_NUM; i++) {
648	struct mtk_base_afe_memif *memif = &afe->memif[i];
649
650	if (!memif->substream)
651	continue;
652
653	if (memif->irq_usage < `0`)
654	continue;
655
656	irq = &afe->irqs[memif->irq_usage];
657
658	if (status_mcu & (`1` << irq->irq_data->irq_en_shift))
659	snd_pcm_period_elapsed(substream: memif->substream);
660	}
661
662	err_irq:
663	/ clear irq /
664	regmap_write(map: afe->regmap,
665	AFE_IRQ_MCU_CLR,
666	val: status_mcu);
667
668	return irq_ret;
669	}
670
671	static int mt8183_afe_runtime_suspend(struct device *dev)
672	{
673	struct mtk_base_afe *afe = dev_get_drvdata(dev);
674	struct mt8183_afe_private *afe_priv = afe->platform_priv;
675	unsigned int value;
676	int ret;
677
678	if (!afe->regmap \|\| afe_priv->pm_runtime_bypass_reg_ctl)
679	goto skip_regmap;
680
681	/ disable AFE /
682	regmap_update_bits(map: afe->regmap, AFE_DAC_CON0, AFE_ON_MASK_SFT, val: `0x0`);
683
684	ret = regmap_read_poll_timeout(afe->regmap,
685	AFE_DAC_MON,
686	value,
687	(value & AFE_ON_RETM_MASK_SFT) == `0`,
688	`20`,
689	`1` * `1000` * `1000`);
690	if (ret)
691	dev_warn(afe->dev, "%s(), ret %d\n", __func__, ret);
692
693	/ make sure all irq status are cleared, twice intended /
694	regmap_update_bits(map: afe->regmap, AFE_IRQ_MCU_CLR, mask: `0xffff`, val: `0xffff`);
695	regmap_update_bits(map: afe->regmap, AFE_IRQ_MCU_CLR, mask: `0xffff`, val: `0xffff`);
696
697	/ cache only /
698	regcache_cache_only(map: afe->regmap, enable: true);
699	regcache_mark_dirty(map: afe->regmap);
700
701	skip_regmap:
702	return mt8183_afe_disable_clock(afe);
703	}
704
705	static int mt8183_afe_runtime_resume(struct device *dev)
706	{
707	struct mtk_base_afe *afe = dev_get_drvdata(dev);
708	struct mt8183_afe_private *afe_priv = afe->platform_priv;
709	int ret;
710
711	ret = mt8183_afe_enable_clock(afe);
712	if (ret)
713	return ret;
714
715	if (!afe->regmap \|\| afe_priv->pm_runtime_bypass_reg_ctl)
716	goto skip_regmap;
717
718	regcache_cache_only(map: afe->regmap, enable: false);
719	regcache_sync(map: afe->regmap);
720
721	/ enable audio sys DCM for power saving /
722	regmap_update_bits(map: afe->regmap, AUDIO_TOP_CON0, mask: `0x1` << `29`, val: `0x1` << `29`);
723
724	/ force cpu use 8_24 format when writing 32bit data /
725	regmap_update_bits(map: afe->regmap, AFE_MEMIF_MSB,
726	CPU_HD_ALIGN_MASK_SFT, val: `0` << CPU_HD_ALIGN_SFT);
727
728	/ set all output port to 24bit /
729	regmap_write(map: afe->regmap, AFE_CONN_24BIT, val: `0xffffffff`);
730	regmap_write(map: afe->regmap, AFE_CONN_24BIT_1, val: `0xffffffff`);
731
732	/ enable AFE /
733	regmap_update_bits(map: afe->regmap, AFE_DAC_CON0, mask: `0x1`, val: `0x1`);
734
735	skip_regmap:
736	return `0`;
737	}
738
739	static int mt8183_dai_memif_register(struct mtk_base_afe *afe)
740	{
741	struct mtk_base_afe_dai *dai;
742
743	dai = devm_kzalloc(dev: afe->dev, size: sizeof(*dai), GFP_KERNEL);
744	if (!dai)
745	return -ENOMEM;
746
747	list_add(new: &dai->list, head: &afe->sub_dais);
748
749	dai->dai_drivers = mt8183_memif_dai_driver;
750	dai->num_dai_drivers = ARRAY_SIZE(mt8183_memif_dai_driver);
751
752	dai->dapm_widgets = mt8183_memif_widgets;
753	dai->num_dapm_widgets = ARRAY_SIZE(mt8183_memif_widgets);
754	dai->dapm_routes = mt8183_memif_routes;
755	dai->num_dapm_routes = ARRAY_SIZE(mt8183_memif_routes);
756	return `0`;
757	}
758
759	typedef int (dai_register_cb)(struct* mtk_base_afe *);
760	static const dai_register_cb dai_register_cbs[] = {
761	mt8183_dai_adda_register,
762	mt8183_dai_i2s_register,
763	mt8183_dai_pcm_register,
764	mt8183_dai_tdm_register,
765	mt8183_dai_hostless_register,
766	mt8183_dai_memif_register,
767	};
768
769	static int mt8183_afe_pcm_dev_probe(struct platform_device *pdev)
770	{
771	struct mtk_base_afe *afe;
772	struct mt8183_afe_private *afe_priv;
773	struct device *dev = &pdev->dev;
774	struct reset_control *rstc;
775	int i, irq_id, ret;
776
777	ret = dma_set_mask_and_coherent(dev, DMA_BIT_MASK(`34`));
778	if (ret)
779	return ret;
780
781	afe = devm_kzalloc(dev, size: sizeof(*afe), GFP_KERNEL);
782	if (!afe)
783	return -ENOMEM;
784	platform_set_drvdata(pdev, data: afe);
785
786	afe->platform_priv = devm_kzalloc(dev, size: sizeof(*afe_priv), GFP_KERNEL);
787	if (!afe->platform_priv)
788	return -ENOMEM;
789
790	afe_priv = afe->platform_priv;
791	afe->dev = dev;
792
793	ret = of_reserved_mem_device_init(dev);
794	if (ret) {
795	dev_info(dev, "no reserved memory found, pre-allocating buffers instead\n");
796	afe->preallocate_buffers = true;
797	}
798
799	/ initial audio related clock /
800	ret = mt8183_init_clock(afe);
801	if (ret) {
802	dev_err(dev, "init clock error\n");
803	return ret;
804	}
805
806	pm_runtime_enable(dev);
807
808	/ regmap init /
809	afe->regmap = syscon_node_to_regmap(np: dev->parent->of_node);
810	if (IS_ERR(ptr: afe->regmap)) {
811	dev_err(dev, "could not get regmap from parent\n");
812	ret = PTR_ERR(ptr: afe->regmap);
813	goto err_pm_disable;
814	}
815	ret = regmap_attach_dev(dev, map: afe->regmap, config: &mt8183_afe_regmap_config);
816	if (ret) {
817	dev_warn(dev, "regmap_attach_dev fail, ret %d\n", ret);
818	goto err_pm_disable;
819	}
820
821	rstc = devm_reset_control_get(dev, id: "audiosys");
822	if (IS_ERR(ptr: rstc)) {
823	ret = PTR_ERR(ptr: rstc);
824	dev_err(dev, "could not get audiosys reset:%d\n", ret);
825	goto err_pm_disable;
826	}
827
828	ret = reset_control_reset(rstc);
829	if (ret) {
830	dev_err(dev, "failed to trigger audio reset:%d\n", ret);
831	goto err_pm_disable;
832	}
833
834	/ enable clock for regcache get default value from hw /
835	afe_priv->pm_runtime_bypass_reg_ctl = true;
836	pm_runtime_get_sync(dev);
837
838	ret = regmap_reinit_cache(map: afe->regmap, config: &mt8183_afe_regmap_config);
839	if (ret) {
840	dev_err(dev, "regmap_reinit_cache fail, ret %d\n", ret);
841	goto err_pm_disable;
842	}
843
844	pm_runtime_put_sync(dev);
845	afe_priv->pm_runtime_bypass_reg_ctl = false;
846
847	regcache_cache_only(map: afe->regmap, enable: true);
848	regcache_mark_dirty(map: afe->regmap);
849
850	/ init memif /
851	afe->memif_size = MT8183_MEMIF_NUM;
852	afe->memif = devm_kcalloc(dev, n: afe->memif_size, size: sizeof(*afe->memif),
853	GFP_KERNEL);
854	if (!afe->memif) {
855	ret = -ENOMEM;
856	goto err_pm_disable;
857	}
858
859	for (i = `0`; i < afe->memif_size; i++) {
860	afe->memif[i].data = &memif_data[i];
861	afe->memif[i].irq_usage = -`1`;
862	}
863
864	afe->memif[MT8183_MEMIF_HDMI].irq_usage = MT8183_IRQ_8;
865	afe->memif[MT8183_MEMIF_HDMI].const_irq = `1`;
866
867	mutex_init(&afe->irq_alloc_lock);
868
869	/ init memif /
870	/ irq initialize /
871	afe->irqs_size = MT8183_IRQ_NUM;
872	afe->irqs = devm_kcalloc(dev, n: afe->irqs_size, size: sizeof(*afe->irqs),
873	GFP_KERNEL);
874	if (!afe->irqs) {
875	ret = -ENOMEM;
876	goto err_pm_disable;
877	}
878
879	for (i = `0`; i < afe->irqs_size; i++)
880	afe->irqs[i].irq_data = &irq_data[i];
881
882	/ request irq /
883	irq_id = platform_get_irq(pdev, `0`);
884	if (irq_id < `0`) {
885	ret = irq_id;
886	goto err_pm_disable;
887	}
888
889	ret = devm_request_irq(dev, irq: irq_id, handler: mt8183_afe_irq_handler,
890	IRQF_TRIGGER_NONE, devname: "asys-isr", dev_id: (void *)afe);
891	if (ret) {
892	dev_err(dev, "could not request_irq for asys-isr\n");
893	goto err_pm_disable;
894	}
895
896	/ init sub_dais /
897	INIT_LIST_HEAD(list: &afe->sub_dais);
898
899	for (i = `0`; i < ARRAY_SIZE(dai_register_cbs); i++) {
900	ret = dai_register_cbs[i](afe);
901	if (ret) {
902	dev_warn(dev, "dai register i %d fail, ret %d\n",
903	i, ret);
904	goto err_pm_disable;
905	}
906	}
907
908	/ init dai_driver and component_driver /
909	ret = mtk_afe_combine_sub_dai(afe);
910	if (ret) {
911	dev_warn(dev, "mtk_afe_combine_sub_dai fail, ret %d\n", ret);
912	goto err_pm_disable;
913	}
914
915	afe->mtk_afe_hardware = &mt8183_afe_hardware;
916	afe->memif_fs = mt8183_memif_fs;
917	afe->irq_fs = mt8183_irq_fs;
918
919	afe->runtime_resume = mt8183_afe_runtime_resume;
920	afe->runtime_suspend = mt8183_afe_runtime_suspend;
921
922	/ register component /
923	ret = devm_snd_soc_register_component(dev, component_driver: &mtk_afe_pcm_platform,
924	NULL, num_dai: `0`);
925	if (ret) {
926	dev_warn(dev, "err_platform\n");
927	goto err_pm_disable;
928	}
929
930	ret = devm_snd_soc_register_component(dev, component_driver: &mt8183_afe_pcm_dai_component,
931	dai_drv: afe->dai_drivers,
932	num_dai: afe->num_dai_drivers);
933	if (ret) {
934	dev_warn(dev, "err_dai_component\n");
935	goto err_pm_disable;
936	}
937
938	return ret;
939
940	err_pm_disable:
941	pm_runtime_disable(dev);
942	return ret;
943	}
944
945	static void mt8183_afe_pcm_dev_remove(struct platform_device *pdev)
946	{
947	struct device *dev = &pdev->dev;
948
949	pm_runtime_disable(dev);
950	if (!pm_runtime_status_suspended(dev))
951	mt8183_afe_runtime_suspend(dev);
952	}
953
954	static const struct of_device_id mt8183_afe_pcm_dt_match[] = {
955	{ .compatible = "mediatek,mt8183-audio", },
956	{},
957	};
958	MODULE_DEVICE_TABLE(of, mt8183_afe_pcm_dt_match);
959
960	static const struct dev_pm_ops mt8183_afe_pm_ops = {
961	RUNTIME_PM_OPS(mt8183_afe_runtime_suspend,
962	mt8183_afe_runtime_resume, NULL)
963	};
964
965	static struct platform_driver mt8183_afe_pcm_driver = {
966	.driver = {
967	.name = "mt8183-audio",
968	.of_match_table = mt8183_afe_pcm_dt_match,
969	.pm = pm_ptr(&mt8183_afe_pm_ops),
970	},
971	.probe = mt8183_afe_pcm_dev_probe,
972	.remove = mt8183_afe_pcm_dev_remove,
973	};
974
975	module_platform_driver(mt8183_afe_pcm_driver);
976
977	MODULE_DESCRIPTION("Mediatek ALSA SoC AFE platform driver for 8183");
978	MODULE_AUTHOR("KaiChieh Chuang <kaichieh.chuang@mediatek.com>");
979	MODULE_LICENSE("GPL v2");
980

source code of linux/sound/soc/mediatek/mt8183/mt8183-afe-pcm.c