linux/sound/soc/codecs/nau8825.c
David Lin 6133148ca0
ASoC: nau8825: add clock management for power saving
Adjust dapm widget to manage clock from power event for power saving.

Signed-off-by: David Lin <CTLIN0@nuvoton.com>
Signed-off-by: Mac Chiang <mac.chiang@intel.com>
Link: https://lore.kernel.org/r/20211025113857.3860951-3-CTLIN0@nuvoton.com
Signed-off-by: Mark Brown <broonie@kernel.org>
2021-10-26 12:35:16 +01:00

2715 lines
88 KiB
C

// SPDX-License-Identifier: GPL-2.0-only
/*
* Nuvoton NAU8825 audio codec driver
*
* Copyright 2015 Google Chromium project.
* Author: Anatol Pomozov <anatol@chromium.org>
* Copyright 2015 Nuvoton Technology Corp.
* Co-author: Meng-Huang Kuo <mhkuo@nuvoton.com>
*/
#include <linux/module.h>
#include <linux/delay.h>
#include <linux/init.h>
#include <linux/i2c.h>
#include <linux/regmap.h>
#include <linux/slab.h>
#include <linux/clk.h>
#include <linux/acpi.h>
#include <linux/math64.h>
#include <linux/semaphore.h>
#include <sound/initval.h>
#include <sound/tlv.h>
#include <sound/core.h>
#include <sound/pcm.h>
#include <sound/pcm_params.h>
#include <sound/soc.h>
#include <sound/jack.h>
#include "nau8825.h"
#define NUVOTON_CODEC_DAI "nau8825-hifi"
#define NAU_FREF_MAX 13500000
#define NAU_FVCO_MAX 124000000
#define NAU_FVCO_MIN 90000000
/* cross talk suppression detection */
#define LOG10_MAGIC 646456993
#define GAIN_AUGMENT 22500
#define SIDETONE_BASE 207000
/* the maximum frequency of CLK_ADC and CLK_DAC */
#define CLK_DA_AD_MAX 6144000
static int nau8825_configure_sysclk(struct nau8825 *nau8825,
int clk_id, unsigned int freq);
static bool nau8825_is_jack_inserted(struct regmap *regmap);
struct nau8825_fll {
int mclk_src;
int ratio;
int fll_frac;
int fll_int;
int clk_ref_div;
};
struct nau8825_fll_attr {
unsigned int param;
unsigned int val;
};
/* scaling for mclk from sysclk_src output */
static const struct nau8825_fll_attr mclk_src_scaling[] = {
{ 1, 0x0 },
{ 2, 0x2 },
{ 4, 0x3 },
{ 8, 0x4 },
{ 16, 0x5 },
{ 32, 0x6 },
{ 3, 0x7 },
{ 6, 0xa },
{ 12, 0xb },
{ 24, 0xc },
{ 48, 0xd },
{ 96, 0xe },
{ 5, 0xf },
};
/* ratio for input clk freq */
static const struct nau8825_fll_attr fll_ratio[] = {
{ 512000, 0x01 },
{ 256000, 0x02 },
{ 128000, 0x04 },
{ 64000, 0x08 },
{ 32000, 0x10 },
{ 8000, 0x20 },
{ 4000, 0x40 },
};
static const struct nau8825_fll_attr fll_pre_scalar[] = {
{ 1, 0x0 },
{ 2, 0x1 },
{ 4, 0x2 },
{ 8, 0x3 },
};
/* over sampling rate */
struct nau8825_osr_attr {
unsigned int osr;
unsigned int clk_src;
};
static const struct nau8825_osr_attr osr_dac_sel[] = {
{ 64, 2 }, /* OSR 64, SRC 1/4 */
{ 256, 0 }, /* OSR 256, SRC 1 */
{ 128, 1 }, /* OSR 128, SRC 1/2 */
{ 0, 0 },
{ 32, 3 }, /* OSR 32, SRC 1/8 */
};
static const struct nau8825_osr_attr osr_adc_sel[] = {
{ 32, 3 }, /* OSR 32, SRC 1/8 */
{ 64, 2 }, /* OSR 64, SRC 1/4 */
{ 128, 1 }, /* OSR 128, SRC 1/2 */
{ 256, 0 }, /* OSR 256, SRC 1 */
};
static const struct reg_default nau8825_reg_defaults[] = {
{ NAU8825_REG_ENA_CTRL, 0x00ff },
{ NAU8825_REG_IIC_ADDR_SET, 0x0 },
{ NAU8825_REG_CLK_DIVIDER, 0x0050 },
{ NAU8825_REG_FLL1, 0x0 },
{ NAU8825_REG_FLL2, 0x3126 },
{ NAU8825_REG_FLL3, 0x0008 },
{ NAU8825_REG_FLL4, 0x0010 },
{ NAU8825_REG_FLL5, 0x0 },
{ NAU8825_REG_FLL6, 0x6000 },
{ NAU8825_REG_FLL_VCO_RSV, 0xf13c },
{ NAU8825_REG_HSD_CTRL, 0x000c },
{ NAU8825_REG_JACK_DET_CTRL, 0x0 },
{ NAU8825_REG_INTERRUPT_MASK, 0x0 },
{ NAU8825_REG_INTERRUPT_DIS_CTRL, 0xffff },
{ NAU8825_REG_SAR_CTRL, 0x0015 },
{ NAU8825_REG_KEYDET_CTRL, 0x0110 },
{ NAU8825_REG_VDET_THRESHOLD_1, 0x0 },
{ NAU8825_REG_VDET_THRESHOLD_2, 0x0 },
{ NAU8825_REG_VDET_THRESHOLD_3, 0x0 },
{ NAU8825_REG_VDET_THRESHOLD_4, 0x0 },
{ NAU8825_REG_GPIO34_CTRL, 0x0 },
{ NAU8825_REG_GPIO12_CTRL, 0x0 },
{ NAU8825_REG_TDM_CTRL, 0x0 },
{ NAU8825_REG_I2S_PCM_CTRL1, 0x000b },
{ NAU8825_REG_I2S_PCM_CTRL2, 0x8010 },
{ NAU8825_REG_LEFT_TIME_SLOT, 0x0 },
{ NAU8825_REG_RIGHT_TIME_SLOT, 0x0 },
{ NAU8825_REG_BIQ_CTRL, 0x0 },
{ NAU8825_REG_BIQ_COF1, 0x0 },
{ NAU8825_REG_BIQ_COF2, 0x0 },
{ NAU8825_REG_BIQ_COF3, 0x0 },
{ NAU8825_REG_BIQ_COF4, 0x0 },
{ NAU8825_REG_BIQ_COF5, 0x0 },
{ NAU8825_REG_BIQ_COF6, 0x0 },
{ NAU8825_REG_BIQ_COF7, 0x0 },
{ NAU8825_REG_BIQ_COF8, 0x0 },
{ NAU8825_REG_BIQ_COF9, 0x0 },
{ NAU8825_REG_BIQ_COF10, 0x0 },
{ NAU8825_REG_ADC_RATE, 0x0010 },
{ NAU8825_REG_DAC_CTRL1, 0x0001 },
{ NAU8825_REG_DAC_CTRL2, 0x0 },
{ NAU8825_REG_DAC_DGAIN_CTRL, 0x0 },
{ NAU8825_REG_ADC_DGAIN_CTRL, 0x00cf },
{ NAU8825_REG_MUTE_CTRL, 0x0 },
{ NAU8825_REG_HSVOL_CTRL, 0x0 },
{ NAU8825_REG_DACL_CTRL, 0x02cf },
{ NAU8825_REG_DACR_CTRL, 0x00cf },
{ NAU8825_REG_ADC_DRC_KNEE_IP12, 0x1486 },
{ NAU8825_REG_ADC_DRC_KNEE_IP34, 0x0f12 },
{ NAU8825_REG_ADC_DRC_SLOPES, 0x25ff },
{ NAU8825_REG_ADC_DRC_ATKDCY, 0x3457 },
{ NAU8825_REG_DAC_DRC_KNEE_IP12, 0x1486 },
{ NAU8825_REG_DAC_DRC_KNEE_IP34, 0x0f12 },
{ NAU8825_REG_DAC_DRC_SLOPES, 0x25f9 },
{ NAU8825_REG_DAC_DRC_ATKDCY, 0x3457 },
{ NAU8825_REG_IMM_MODE_CTRL, 0x0 },
{ NAU8825_REG_CLASSG_CTRL, 0x0 },
{ NAU8825_REG_OPT_EFUSE_CTRL, 0x0 },
{ NAU8825_REG_MISC_CTRL, 0x0 },
{ NAU8825_REG_BIAS_ADJ, 0x0 },
{ NAU8825_REG_TRIM_SETTINGS, 0x0 },
{ NAU8825_REG_ANALOG_CONTROL_1, 0x0 },
{ NAU8825_REG_ANALOG_CONTROL_2, 0x0 },
{ NAU8825_REG_ANALOG_ADC_1, 0x0011 },
{ NAU8825_REG_ANALOG_ADC_2, 0x0020 },
{ NAU8825_REG_RDAC, 0x0008 },
{ NAU8825_REG_MIC_BIAS, 0x0006 },
{ NAU8825_REG_BOOST, 0x0 },
{ NAU8825_REG_FEPGA, 0x0 },
{ NAU8825_REG_POWER_UP_CONTROL, 0x0 },
{ NAU8825_REG_CHARGE_PUMP, 0x0 },
};
/* register backup table when cross talk detection */
static struct reg_default nau8825_xtalk_baktab[] = {
{ NAU8825_REG_ADC_DGAIN_CTRL, 0x00cf },
{ NAU8825_REG_HSVOL_CTRL, 0 },
{ NAU8825_REG_DACL_CTRL, 0x00cf },
{ NAU8825_REG_DACR_CTRL, 0x02cf },
};
static const unsigned short logtable[256] = {
0x0000, 0x0171, 0x02e0, 0x044e, 0x05ba, 0x0725, 0x088e, 0x09f7,
0x0b5d, 0x0cc3, 0x0e27, 0x0f8a, 0x10eb, 0x124b, 0x13aa, 0x1508,
0x1664, 0x17bf, 0x1919, 0x1a71, 0x1bc8, 0x1d1e, 0x1e73, 0x1fc6,
0x2119, 0x226a, 0x23ba, 0x2508, 0x2656, 0x27a2, 0x28ed, 0x2a37,
0x2b80, 0x2cc8, 0x2e0f, 0x2f54, 0x3098, 0x31dc, 0x331e, 0x345f,
0x359f, 0x36de, 0x381b, 0x3958, 0x3a94, 0x3bce, 0x3d08, 0x3e41,
0x3f78, 0x40af, 0x41e4, 0x4319, 0x444c, 0x457f, 0x46b0, 0x47e1,
0x4910, 0x4a3f, 0x4b6c, 0x4c99, 0x4dc5, 0x4eef, 0x5019, 0x5142,
0x526a, 0x5391, 0x54b7, 0x55dc, 0x5700, 0x5824, 0x5946, 0x5a68,
0x5b89, 0x5ca8, 0x5dc7, 0x5ee5, 0x6003, 0x611f, 0x623a, 0x6355,
0x646f, 0x6588, 0x66a0, 0x67b7, 0x68ce, 0x69e4, 0x6af8, 0x6c0c,
0x6d20, 0x6e32, 0x6f44, 0x7055, 0x7165, 0x7274, 0x7383, 0x7490,
0x759d, 0x76aa, 0x77b5, 0x78c0, 0x79ca, 0x7ad3, 0x7bdb, 0x7ce3,
0x7dea, 0x7ef0, 0x7ff6, 0x80fb, 0x81ff, 0x8302, 0x8405, 0x8507,
0x8608, 0x8709, 0x8809, 0x8908, 0x8a06, 0x8b04, 0x8c01, 0x8cfe,
0x8dfa, 0x8ef5, 0x8fef, 0x90e9, 0x91e2, 0x92db, 0x93d2, 0x94ca,
0x95c0, 0x96b6, 0x97ab, 0x98a0, 0x9994, 0x9a87, 0x9b7a, 0x9c6c,
0x9d5e, 0x9e4f, 0x9f3f, 0xa02e, 0xa11e, 0xa20c, 0xa2fa, 0xa3e7,
0xa4d4, 0xa5c0, 0xa6ab, 0xa796, 0xa881, 0xa96a, 0xaa53, 0xab3c,
0xac24, 0xad0c, 0xadf2, 0xaed9, 0xafbe, 0xb0a4, 0xb188, 0xb26c,
0xb350, 0xb433, 0xb515, 0xb5f7, 0xb6d9, 0xb7ba, 0xb89a, 0xb97a,
0xba59, 0xbb38, 0xbc16, 0xbcf4, 0xbdd1, 0xbead, 0xbf8a, 0xc065,
0xc140, 0xc21b, 0xc2f5, 0xc3cf, 0xc4a8, 0xc580, 0xc658, 0xc730,
0xc807, 0xc8de, 0xc9b4, 0xca8a, 0xcb5f, 0xcc34, 0xcd08, 0xcddc,
0xceaf, 0xcf82, 0xd054, 0xd126, 0xd1f7, 0xd2c8, 0xd399, 0xd469,
0xd538, 0xd607, 0xd6d6, 0xd7a4, 0xd872, 0xd93f, 0xda0c, 0xdad9,
0xdba5, 0xdc70, 0xdd3b, 0xde06, 0xded0, 0xdf9a, 0xe063, 0xe12c,
0xe1f5, 0xe2bd, 0xe385, 0xe44c, 0xe513, 0xe5d9, 0xe69f, 0xe765,
0xe82a, 0xe8ef, 0xe9b3, 0xea77, 0xeb3b, 0xebfe, 0xecc1, 0xed83,
0xee45, 0xef06, 0xefc8, 0xf088, 0xf149, 0xf209, 0xf2c8, 0xf387,
0xf446, 0xf505, 0xf5c3, 0xf680, 0xf73e, 0xf7fb, 0xf8b7, 0xf973,
0xfa2f, 0xfaea, 0xfba5, 0xfc60, 0xfd1a, 0xfdd4, 0xfe8e, 0xff47
};
/**
* nau8825_sema_acquire - acquire the semaphore of nau88l25
* @nau8825: component to register the codec private data with
* @timeout: how long in jiffies to wait before failure or zero to wait
* until release
*
* Attempts to acquire the semaphore with number of jiffies. If no more
* tasks are allowed to acquire the semaphore, calling this function will
* put the task to sleep. If the semaphore is not released within the
* specified number of jiffies, this function returns.
* If the semaphore is not released within the specified number of jiffies,
* this function returns -ETIME. If the sleep is interrupted by a signal,
* this function will return -EINTR. It returns 0 if the semaphore was
* acquired successfully.
*
* Acquires the semaphore without jiffies. Try to acquire the semaphore
* atomically. Returns 0 if the semaphore has been acquired successfully
* or 1 if it cannot be acquired.
*/
static int nau8825_sema_acquire(struct nau8825 *nau8825, long timeout)
{
int ret;
if (timeout) {
ret = down_timeout(&nau8825->xtalk_sem, timeout);
if (ret < 0)
dev_warn(nau8825->dev, "Acquire semaphore timeout\n");
} else {
ret = down_trylock(&nau8825->xtalk_sem);
if (ret)
dev_warn(nau8825->dev, "Acquire semaphore fail\n");
}
return ret;
}
/**
* nau8825_sema_release - release the semaphore of nau88l25
* @nau8825: component to register the codec private data with
*
* Release the semaphore which may be called from any context and
* even by tasks which have never called down().
*/
static inline void nau8825_sema_release(struct nau8825 *nau8825)
{
up(&nau8825->xtalk_sem);
}
/**
* nau8825_sema_reset - reset the semaphore for nau88l25
* @nau8825: component to register the codec private data with
*
* Reset the counter of the semaphore. Call this function to restart
* a new round task management.
*/
static inline void nau8825_sema_reset(struct nau8825 *nau8825)
{
nau8825->xtalk_sem.count = 1;
}
/**
* nau8825_hpvol_ramp - Ramp up the headphone volume change gradually to target level.
*
* @nau8825: component to register the codec private data with
* @vol_from: the volume to start up
* @vol_to: the target volume
* @step: the volume span to move on
*
* The headphone volume is from 0dB to minimum -54dB and -1dB per step.
* If the volume changes sharp, there is a pop noise heard in headphone. We
* provide the function to ramp up the volume up or down by delaying 10ms
* per step.
*/
static void nau8825_hpvol_ramp(struct nau8825 *nau8825,
unsigned int vol_from, unsigned int vol_to, unsigned int step)
{
unsigned int value, volume, ramp_up, from, to;
if (vol_from == vol_to || step == 0) {
return;
} else if (vol_from < vol_to) {
ramp_up = true;
from = vol_from;
to = vol_to;
} else {
ramp_up = false;
from = vol_to;
to = vol_from;
}
/* only handle volume from 0dB to minimum -54dB */
if (to > NAU8825_HP_VOL_MIN)
to = NAU8825_HP_VOL_MIN;
for (volume = from; volume < to; volume += step) {
if (ramp_up)
value = volume;
else
value = to - volume + from;
regmap_update_bits(nau8825->regmap, NAU8825_REG_HSVOL_CTRL,
NAU8825_HPL_VOL_MASK | NAU8825_HPR_VOL_MASK,
(value << NAU8825_HPL_VOL_SFT) | value);
usleep_range(10000, 10500);
}
if (ramp_up)
value = to;
else
value = from;
regmap_update_bits(nau8825->regmap, NAU8825_REG_HSVOL_CTRL,
NAU8825_HPL_VOL_MASK | NAU8825_HPR_VOL_MASK,
(value << NAU8825_HPL_VOL_SFT) | value);
}
/**
* nau8825_intlog10_dec3 - Computes log10 of a value
* the result is round off to 3 decimal. This function takes reference to
* dvb-math. The source code locates as the following.
* Linux/drivers/media/dvb-core/dvb_math.c
* @value: input for log10
*
* return log10(value) * 1000
*/
static u32 nau8825_intlog10_dec3(u32 value)
{
u32 msb, logentry, significand, interpolation, log10val;
u64 log2val;
/* first detect the msb (count begins at 0) */
msb = fls(value) - 1;
/**
* now we use a logtable after the following method:
*
* log2(2^x * y) * 2^24 = x * 2^24 + log2(y) * 2^24
* where x = msb and therefore 1 <= y < 2
* first y is determined by shifting the value left
* so that msb is bit 31
* 0x00231f56 -> 0x8C7D5800
* the result is y * 2^31 -> "significand"
* then the highest 9 bits are used for a table lookup
* the highest bit is discarded because it's always set
* the highest nine bits in our example are 100011000
* so we would use the entry 0x18
*/
significand = value << (31 - msb);
logentry = (significand >> 23) & 0xff;
/**
* last step we do is interpolation because of the
* limitations of the log table the error is that part of
* the significand which isn't used for lookup then we
* compute the ratio between the error and the next table entry
* and interpolate it between the log table entry used and the
* next one the biggest error possible is 0x7fffff
* (in our example it's 0x7D5800)
* needed value for next table entry is 0x800000
* so the interpolation is
* (error / 0x800000) * (logtable_next - logtable_current)
* in the implementation the division is moved to the end for
* better accuracy there is also an overflow correction if
* logtable_next is 256
*/
interpolation = ((significand & 0x7fffff) *
((logtable[(logentry + 1) & 0xff] -
logtable[logentry]) & 0xffff)) >> 15;
log2val = ((msb << 24) + (logtable[logentry] << 8) + interpolation);
/**
* log10(x) = log2(x) * log10(2)
*/
log10val = (log2val * LOG10_MAGIC) >> 31;
/**
* the result is round off to 3 decimal
*/
return log10val / ((1 << 24) / 1000);
}
/**
* nau8825_xtalk_sidetone - computes cross talk suppression sidetone gain.
*
* @sig_org: orignal signal level
* @sig_cros: cross talk signal level
*
* The orignal and cross talk signal vlues need to be characterized.
* Once these values have been characterized, this sidetone value
* can be converted to decibel with the equation below.
* sidetone = 20 * log (original signal level / crosstalk signal level)
*
* return cross talk sidetone gain
*/
static u32 nau8825_xtalk_sidetone(u32 sig_org, u32 sig_cros)
{
u32 gain, sidetone;
if (WARN_ON(sig_org == 0 || sig_cros == 0))
return 0;
sig_org = nau8825_intlog10_dec3(sig_org);
sig_cros = nau8825_intlog10_dec3(sig_cros);
if (sig_org >= sig_cros)
gain = (sig_org - sig_cros) * 20 + GAIN_AUGMENT;
else
gain = (sig_cros - sig_org) * 20 + GAIN_AUGMENT;
sidetone = SIDETONE_BASE - gain * 2;
sidetone /= 1000;
return sidetone;
}
static int nau8825_xtalk_baktab_index_by_reg(unsigned int reg)
{
int index;
for (index = 0; index < ARRAY_SIZE(nau8825_xtalk_baktab); index++)
if (nau8825_xtalk_baktab[index].reg == reg)
return index;
return -EINVAL;
}
static void nau8825_xtalk_backup(struct nau8825 *nau8825)
{
int i;
if (nau8825->xtalk_baktab_initialized)
return;
/* Backup some register values to backup table */
for (i = 0; i < ARRAY_SIZE(nau8825_xtalk_baktab); i++)
regmap_read(nau8825->regmap, nau8825_xtalk_baktab[i].reg,
&nau8825_xtalk_baktab[i].def);
nau8825->xtalk_baktab_initialized = true;
}
static void nau8825_xtalk_restore(struct nau8825 *nau8825, bool cause_cancel)
{
int i, volume;
if (!nau8825->xtalk_baktab_initialized)
return;
/* Restore register values from backup table; When the driver restores
* the headphone volume in XTALK_DONE state, it needs recover to
* original level gradually with 3dB per step for less pop noise.
* Otherwise, the restore should do ASAP.
*/
for (i = 0; i < ARRAY_SIZE(nau8825_xtalk_baktab); i++) {
if (!cause_cancel && nau8825_xtalk_baktab[i].reg ==
NAU8825_REG_HSVOL_CTRL) {
/* Ramping up the volume change to reduce pop noise */
volume = nau8825_xtalk_baktab[i].def &
NAU8825_HPR_VOL_MASK;
nau8825_hpvol_ramp(nau8825, 0, volume, 3);
continue;
}
regmap_write(nau8825->regmap, nau8825_xtalk_baktab[i].reg,
nau8825_xtalk_baktab[i].def);
}
nau8825->xtalk_baktab_initialized = false;
}
static void nau8825_xtalk_prepare_dac(struct nau8825 *nau8825)
{
/* Enable power of DAC path */
regmap_update_bits(nau8825->regmap, NAU8825_REG_ENA_CTRL,
NAU8825_ENABLE_DACR | NAU8825_ENABLE_DACL |
NAU8825_ENABLE_ADC | NAU8825_ENABLE_ADC_CLK |
NAU8825_ENABLE_DAC_CLK, NAU8825_ENABLE_DACR |
NAU8825_ENABLE_DACL | NAU8825_ENABLE_ADC |
NAU8825_ENABLE_ADC_CLK | NAU8825_ENABLE_DAC_CLK);
/* Prevent startup click by letting charge pump to ramp up and
* change bump enable
*/
regmap_update_bits(nau8825->regmap, NAU8825_REG_CHARGE_PUMP,
NAU8825_JAMNODCLOW | NAU8825_CHANRGE_PUMP_EN,
NAU8825_JAMNODCLOW | NAU8825_CHANRGE_PUMP_EN);
/* Enable clock sync of DAC and DAC clock */
regmap_update_bits(nau8825->regmap, NAU8825_REG_RDAC,
NAU8825_RDAC_EN | NAU8825_RDAC_CLK_EN |
NAU8825_RDAC_FS_BCLK_ENB,
NAU8825_RDAC_EN | NAU8825_RDAC_CLK_EN);
/* Power up output driver with 2 stage */
regmap_update_bits(nau8825->regmap, NAU8825_REG_POWER_UP_CONTROL,
NAU8825_POWERUP_INTEGR_R | NAU8825_POWERUP_INTEGR_L |
NAU8825_POWERUP_DRV_IN_R | NAU8825_POWERUP_DRV_IN_L,
NAU8825_POWERUP_INTEGR_R | NAU8825_POWERUP_INTEGR_L |
NAU8825_POWERUP_DRV_IN_R | NAU8825_POWERUP_DRV_IN_L);
regmap_update_bits(nau8825->regmap, NAU8825_REG_POWER_UP_CONTROL,
NAU8825_POWERUP_HP_DRV_R | NAU8825_POWERUP_HP_DRV_L,
NAU8825_POWERUP_HP_DRV_R | NAU8825_POWERUP_HP_DRV_L);
/* HP outputs not shouted to ground */
regmap_update_bits(nau8825->regmap, NAU8825_REG_HSD_CTRL,
NAU8825_SPKR_DWN1R | NAU8825_SPKR_DWN1L, 0);
/* Enable HP boost driver */
regmap_update_bits(nau8825->regmap, NAU8825_REG_BOOST,
NAU8825_HP_BOOST_DIS, NAU8825_HP_BOOST_DIS);
/* Enable class G compare path to supply 1.8V or 0.9V. */
regmap_update_bits(nau8825->regmap, NAU8825_REG_CLASSG_CTRL,
NAU8825_CLASSG_LDAC_EN | NAU8825_CLASSG_RDAC_EN,
NAU8825_CLASSG_LDAC_EN | NAU8825_CLASSG_RDAC_EN);
}
static void nau8825_xtalk_prepare_adc(struct nau8825 *nau8825)
{
/* Power up left ADC and raise 5dB than Vmid for Vref */
regmap_update_bits(nau8825->regmap, NAU8825_REG_ANALOG_ADC_2,
NAU8825_POWERUP_ADCL | NAU8825_ADC_VREFSEL_MASK,
NAU8825_POWERUP_ADCL | NAU8825_ADC_VREFSEL_VMID_PLUS_0_5DB);
}
static void nau8825_xtalk_clock(struct nau8825 *nau8825)
{
/* Recover FLL default value */
regmap_write(nau8825->regmap, NAU8825_REG_FLL1, 0x0);
regmap_write(nau8825->regmap, NAU8825_REG_FLL2, 0x3126);
regmap_write(nau8825->regmap, NAU8825_REG_FLL3, 0x0008);
regmap_write(nau8825->regmap, NAU8825_REG_FLL4, 0x0010);
regmap_write(nau8825->regmap, NAU8825_REG_FLL5, 0x0);
regmap_write(nau8825->regmap, NAU8825_REG_FLL6, 0x6000);
/* Enable internal VCO clock for detection signal generated */
regmap_update_bits(nau8825->regmap, NAU8825_REG_CLK_DIVIDER,
NAU8825_CLK_SRC_MASK, NAU8825_CLK_SRC_VCO);
regmap_update_bits(nau8825->regmap, NAU8825_REG_FLL6, NAU8825_DCO_EN,
NAU8825_DCO_EN);
/* Given specific clock frequency of internal clock to
* generate signal.
*/
regmap_update_bits(nau8825->regmap, NAU8825_REG_CLK_DIVIDER,
NAU8825_CLK_MCLK_SRC_MASK, 0xf);
regmap_update_bits(nau8825->regmap, NAU8825_REG_FLL1,
NAU8825_FLL_RATIO_MASK, 0x10);
}
static void nau8825_xtalk_prepare(struct nau8825 *nau8825)
{
int volume, index;
/* Backup those registers changed by cross talk detection */
nau8825_xtalk_backup(nau8825);
/* Config IIS as master to output signal by codec */
regmap_update_bits(nau8825->regmap, NAU8825_REG_I2S_PCM_CTRL2,
NAU8825_I2S_MS_MASK | NAU8825_I2S_LRC_DIV_MASK |
NAU8825_I2S_BLK_DIV_MASK, NAU8825_I2S_MS_MASTER |
(0x2 << NAU8825_I2S_LRC_DIV_SFT) | 0x1);
/* Ramp up headphone volume to 0dB to get better performance and
* avoid pop noise in headphone.
*/
index = nau8825_xtalk_baktab_index_by_reg(NAU8825_REG_HSVOL_CTRL);
if (index != -EINVAL) {
volume = nau8825_xtalk_baktab[index].def &
NAU8825_HPR_VOL_MASK;
nau8825_hpvol_ramp(nau8825, volume, 0, 3);
}
nau8825_xtalk_clock(nau8825);
nau8825_xtalk_prepare_dac(nau8825);
nau8825_xtalk_prepare_adc(nau8825);
/* Config channel path and digital gain */
regmap_update_bits(nau8825->regmap, NAU8825_REG_DACL_CTRL,
NAU8825_DACL_CH_SEL_MASK | NAU8825_DACL_CH_VOL_MASK,
NAU8825_DACL_CH_SEL_L | 0xab);
regmap_update_bits(nau8825->regmap, NAU8825_REG_DACR_CTRL,
NAU8825_DACR_CH_SEL_MASK | NAU8825_DACR_CH_VOL_MASK,
NAU8825_DACR_CH_SEL_R | 0xab);
/* Config cross talk parameters and generate the 23Hz sine wave with
* 1/16 full scale of signal level for impedance measurement.
*/
regmap_update_bits(nau8825->regmap, NAU8825_REG_IMM_MODE_CTRL,
NAU8825_IMM_THD_MASK | NAU8825_IMM_GEN_VOL_MASK |
NAU8825_IMM_CYC_MASK | NAU8825_IMM_DAC_SRC_MASK,
(0x9 << NAU8825_IMM_THD_SFT) | NAU8825_IMM_GEN_VOL_1_16th |
NAU8825_IMM_CYC_8192 | NAU8825_IMM_DAC_SRC_SIN);
/* RMS intrruption enable */
regmap_update_bits(nau8825->regmap,
NAU8825_REG_INTERRUPT_MASK, NAU8825_IRQ_RMS_EN, 0);
/* Power up left and right DAC */
regmap_update_bits(nau8825->regmap, NAU8825_REG_CHARGE_PUMP,
NAU8825_POWER_DOWN_DACR | NAU8825_POWER_DOWN_DACL, 0);
}
static void nau8825_xtalk_clean_dac(struct nau8825 *nau8825)
{
/* Disable HP boost driver */
regmap_update_bits(nau8825->regmap, NAU8825_REG_BOOST,
NAU8825_HP_BOOST_DIS, 0);
/* HP outputs shouted to ground */
regmap_update_bits(nau8825->regmap, NAU8825_REG_HSD_CTRL,
NAU8825_SPKR_DWN1R | NAU8825_SPKR_DWN1L,
NAU8825_SPKR_DWN1R | NAU8825_SPKR_DWN1L);
/* Power down left and right DAC */
regmap_update_bits(nau8825->regmap, NAU8825_REG_CHARGE_PUMP,
NAU8825_POWER_DOWN_DACR | NAU8825_POWER_DOWN_DACL,
NAU8825_POWER_DOWN_DACR | NAU8825_POWER_DOWN_DACL);
/* Enable the TESTDAC and disable L/R HP impedance */
regmap_update_bits(nau8825->regmap, NAU8825_REG_BIAS_ADJ,
NAU8825_BIAS_HPR_IMP | NAU8825_BIAS_HPL_IMP |
NAU8825_BIAS_TESTDAC_EN, NAU8825_BIAS_TESTDAC_EN);
/* Power down output driver with 2 stage */
regmap_update_bits(nau8825->regmap, NAU8825_REG_POWER_UP_CONTROL,
NAU8825_POWERUP_HP_DRV_R | NAU8825_POWERUP_HP_DRV_L, 0);
regmap_update_bits(nau8825->regmap, NAU8825_REG_POWER_UP_CONTROL,
NAU8825_POWERUP_INTEGR_R | NAU8825_POWERUP_INTEGR_L |
NAU8825_POWERUP_DRV_IN_R | NAU8825_POWERUP_DRV_IN_L, 0);
/* Disable clock sync of DAC and DAC clock */
regmap_update_bits(nau8825->regmap, NAU8825_REG_RDAC,
NAU8825_RDAC_EN | NAU8825_RDAC_CLK_EN, 0);
/* Disable charge pump ramp up function and change bump */
regmap_update_bits(nau8825->regmap, NAU8825_REG_CHARGE_PUMP,
NAU8825_JAMNODCLOW | NAU8825_CHANRGE_PUMP_EN, 0);
/* Disable power of DAC path */
regmap_update_bits(nau8825->regmap, NAU8825_REG_ENA_CTRL,
NAU8825_ENABLE_DACR | NAU8825_ENABLE_DACL |
NAU8825_ENABLE_ADC_CLK | NAU8825_ENABLE_DAC_CLK, 0);
if (!nau8825->irq)
regmap_update_bits(nau8825->regmap,
NAU8825_REG_ENA_CTRL, NAU8825_ENABLE_ADC, 0);
}
static void nau8825_xtalk_clean_adc(struct nau8825 *nau8825)
{
/* Power down left ADC and restore voltage to Vmid */
regmap_update_bits(nau8825->regmap, NAU8825_REG_ANALOG_ADC_2,
NAU8825_POWERUP_ADCL | NAU8825_ADC_VREFSEL_MASK, 0);
}
static void nau8825_xtalk_clean(struct nau8825 *nau8825, bool cause_cancel)
{
/* Enable internal VCO needed for interruptions */
nau8825_configure_sysclk(nau8825, NAU8825_CLK_INTERNAL, 0);
nau8825_xtalk_clean_dac(nau8825);
nau8825_xtalk_clean_adc(nau8825);
/* Clear cross talk parameters and disable */
regmap_write(nau8825->regmap, NAU8825_REG_IMM_MODE_CTRL, 0);
/* RMS intrruption disable */
regmap_update_bits(nau8825->regmap, NAU8825_REG_INTERRUPT_MASK,
NAU8825_IRQ_RMS_EN, NAU8825_IRQ_RMS_EN);
/* Recover default value for IIS */
regmap_update_bits(nau8825->regmap, NAU8825_REG_I2S_PCM_CTRL2,
NAU8825_I2S_MS_MASK | NAU8825_I2S_LRC_DIV_MASK |
NAU8825_I2S_BLK_DIV_MASK, NAU8825_I2S_MS_SLAVE);
/* Restore value of specific register for cross talk */
nau8825_xtalk_restore(nau8825, cause_cancel);
}
static void nau8825_xtalk_imm_start(struct nau8825 *nau8825, int vol)
{
/* Apply ADC volume for better cross talk performance */
regmap_update_bits(nau8825->regmap, NAU8825_REG_ADC_DGAIN_CTRL,
NAU8825_ADC_DIG_VOL_MASK, vol);
/* Disables JKTIP(HPL) DAC channel for right to left measurement.
* Do it before sending signal in order to erase pop noise.
*/
regmap_update_bits(nau8825->regmap, NAU8825_REG_BIAS_ADJ,
NAU8825_BIAS_TESTDACR_EN | NAU8825_BIAS_TESTDACL_EN,
NAU8825_BIAS_TESTDACL_EN);
switch (nau8825->xtalk_state) {
case NAU8825_XTALK_HPR_R2L:
/* Enable right headphone impedance */
regmap_update_bits(nau8825->regmap, NAU8825_REG_BIAS_ADJ,
NAU8825_BIAS_HPR_IMP | NAU8825_BIAS_HPL_IMP,
NAU8825_BIAS_HPR_IMP);
break;
case NAU8825_XTALK_HPL_R2L:
/* Enable left headphone impedance */
regmap_update_bits(nau8825->regmap, NAU8825_REG_BIAS_ADJ,
NAU8825_BIAS_HPR_IMP | NAU8825_BIAS_HPL_IMP,
NAU8825_BIAS_HPL_IMP);
break;
default:
break;
}
msleep(100);
/* Impedance measurement mode enable */
regmap_update_bits(nau8825->regmap, NAU8825_REG_IMM_MODE_CTRL,
NAU8825_IMM_EN, NAU8825_IMM_EN);
}
static void nau8825_xtalk_imm_stop(struct nau8825 *nau8825)
{
/* Impedance measurement mode disable */
regmap_update_bits(nau8825->regmap,
NAU8825_REG_IMM_MODE_CTRL, NAU8825_IMM_EN, 0);
}
/* The cross talk measurement function can reduce cross talk across the
* JKTIP(HPL) and JKR1(HPR) outputs which measures the cross talk signal
* level to determine what cross talk reduction gain is. This system works by
* sending a 23Hz -24dBV sine wave into the headset output DAC and through
* the PGA. The output of the PGA is then connected to an internal current
* sense which measures the attenuated 23Hz signal and passing the output to
* an ADC which converts the measurement to a binary code. With two separated
* measurement, one for JKR1(HPR) and the other JKTIP(HPL), measurement data
* can be separated read in IMM_RMS_L for HSR and HSL after each measurement.
* Thus, the measurement function has four states to complete whole sequence.
* 1. Prepare state : Prepare the resource for detection and transfer to HPR
* IMM stat to make JKR1(HPR) impedance measure.
* 2. HPR IMM state : Read out orignal signal level of JKR1(HPR) and transfer
* to HPL IMM state to make JKTIP(HPL) impedance measure.
* 3. HPL IMM state : Read out cross talk signal level of JKTIP(HPL) and
* transfer to IMM state to determine suppression sidetone gain.
* 4. IMM state : Computes cross talk suppression sidetone gain with orignal
* and cross talk signal level. Apply this gain and then restore codec
* configuration. Then transfer to Done state for ending.
*/
static void nau8825_xtalk_measure(struct nau8825 *nau8825)
{
u32 sidetone;
switch (nau8825->xtalk_state) {
case NAU8825_XTALK_PREPARE:
/* In prepare state, set up clock, intrruption, DAC path, ADC
* path and cross talk detection parameters for preparation.
*/
nau8825_xtalk_prepare(nau8825);
msleep(280);
/* Trigger right headphone impedance detection */
nau8825->xtalk_state = NAU8825_XTALK_HPR_R2L;
nau8825_xtalk_imm_start(nau8825, 0x00d2);
break;
case NAU8825_XTALK_HPR_R2L:
/* In right headphone IMM state, read out right headphone
* impedance measure result, and then start up left side.
*/
regmap_read(nau8825->regmap, NAU8825_REG_IMM_RMS_L,
&nau8825->imp_rms[NAU8825_XTALK_HPR_R2L]);
dev_dbg(nau8825->dev, "HPR_R2L imm: %x\n",
nau8825->imp_rms[NAU8825_XTALK_HPR_R2L]);
/* Disable then re-enable IMM mode to update */
nau8825_xtalk_imm_stop(nau8825);
/* Trigger left headphone impedance detection */
nau8825->xtalk_state = NAU8825_XTALK_HPL_R2L;
nau8825_xtalk_imm_start(nau8825, 0x00ff);
break;
case NAU8825_XTALK_HPL_R2L:
/* In left headphone IMM state, read out left headphone
* impedance measure result, and delay some time to wait
* detection sine wave output finish. Then, we can calculate
* the cross talk suppresstion side tone according to the L/R
* headphone imedance.
*/
regmap_read(nau8825->regmap, NAU8825_REG_IMM_RMS_L,
&nau8825->imp_rms[NAU8825_XTALK_HPL_R2L]);
dev_dbg(nau8825->dev, "HPL_R2L imm: %x\n",
nau8825->imp_rms[NAU8825_XTALK_HPL_R2L]);
nau8825_xtalk_imm_stop(nau8825);
msleep(150);
nau8825->xtalk_state = NAU8825_XTALK_IMM;
break;
case NAU8825_XTALK_IMM:
/* In impedance measure state, the orignal and cross talk
* signal level vlues are ready. The side tone gain is deter-
* mined with these signal level. After all, restore codec
* configuration.
*/
sidetone = nau8825_xtalk_sidetone(
nau8825->imp_rms[NAU8825_XTALK_HPR_R2L],
nau8825->imp_rms[NAU8825_XTALK_HPL_R2L]);
dev_dbg(nau8825->dev, "cross talk sidetone: %x\n", sidetone);
regmap_write(nau8825->regmap, NAU8825_REG_DAC_DGAIN_CTRL,
(sidetone << 8) | sidetone);
nau8825_xtalk_clean(nau8825, false);
nau8825->xtalk_state = NAU8825_XTALK_DONE;
break;
default:
break;
}
}
static void nau8825_xtalk_work(struct work_struct *work)
{
struct nau8825 *nau8825 = container_of(
work, struct nau8825, xtalk_work);
nau8825_xtalk_measure(nau8825);
/* To determine the cross talk side tone gain when reach
* the impedance measure state.
*/
if (nau8825->xtalk_state == NAU8825_XTALK_IMM)
nau8825_xtalk_measure(nau8825);
/* Delay jack report until cross talk detection process
* completed. It can avoid application to do playback
* preparation before cross talk detection is still working.
* Meanwhile, the protection of the cross talk detection
* is released.
*/
if (nau8825->xtalk_state == NAU8825_XTALK_DONE) {
snd_soc_jack_report(nau8825->jack, nau8825->xtalk_event,
nau8825->xtalk_event_mask);
nau8825_sema_release(nau8825);
nau8825->xtalk_protect = false;
}
}
static void nau8825_xtalk_cancel(struct nau8825 *nau8825)
{
/* If the crosstalk is eanbled and the process is on going,
* the driver forces to cancel the crosstalk task and
* restores the configuration to original status.
*/
if (nau8825->xtalk_enable && nau8825->xtalk_state !=
NAU8825_XTALK_DONE) {
cancel_work_sync(&nau8825->xtalk_work);
nau8825_xtalk_clean(nau8825, true);
}
/* Reset parameters for cross talk suppression function */
nau8825_sema_reset(nau8825);
nau8825->xtalk_state = NAU8825_XTALK_DONE;
nau8825->xtalk_protect = false;
}
static bool nau8825_readable_reg(struct device *dev, unsigned int reg)
{
switch (reg) {
case NAU8825_REG_ENA_CTRL ... NAU8825_REG_FLL_VCO_RSV:
case NAU8825_REG_HSD_CTRL ... NAU8825_REG_JACK_DET_CTRL:
case NAU8825_REG_INTERRUPT_MASK ... NAU8825_REG_KEYDET_CTRL:
case NAU8825_REG_VDET_THRESHOLD_1 ... NAU8825_REG_DACR_CTRL:
case NAU8825_REG_ADC_DRC_KNEE_IP12 ... NAU8825_REG_ADC_DRC_ATKDCY:
case NAU8825_REG_DAC_DRC_KNEE_IP12 ... NAU8825_REG_DAC_DRC_ATKDCY:
case NAU8825_REG_IMM_MODE_CTRL ... NAU8825_REG_IMM_RMS_R:
case NAU8825_REG_CLASSG_CTRL ... NAU8825_REG_OPT_EFUSE_CTRL:
case NAU8825_REG_MISC_CTRL:
case NAU8825_REG_I2C_DEVICE_ID ... NAU8825_REG_SARDOUT_RAM_STATUS:
case NAU8825_REG_BIAS_ADJ:
case NAU8825_REG_TRIM_SETTINGS ... NAU8825_REG_ANALOG_CONTROL_2:
case NAU8825_REG_ANALOG_ADC_1 ... NAU8825_REG_MIC_BIAS:
case NAU8825_REG_BOOST ... NAU8825_REG_FEPGA:
case NAU8825_REG_POWER_UP_CONTROL ... NAU8825_REG_GENERAL_STATUS:
return true;
default:
return false;
}
}
static bool nau8825_writeable_reg(struct device *dev, unsigned int reg)
{
switch (reg) {
case NAU8825_REG_RESET ... NAU8825_REG_FLL_VCO_RSV:
case NAU8825_REG_HSD_CTRL ... NAU8825_REG_JACK_DET_CTRL:
case NAU8825_REG_INTERRUPT_MASK:
case NAU8825_REG_INT_CLR_KEY_STATUS ... NAU8825_REG_KEYDET_CTRL:
case NAU8825_REG_VDET_THRESHOLD_1 ... NAU8825_REG_DACR_CTRL:
case NAU8825_REG_ADC_DRC_KNEE_IP12 ... NAU8825_REG_ADC_DRC_ATKDCY:
case NAU8825_REG_DAC_DRC_KNEE_IP12 ... NAU8825_REG_DAC_DRC_ATKDCY:
case NAU8825_REG_IMM_MODE_CTRL:
case NAU8825_REG_CLASSG_CTRL ... NAU8825_REG_OPT_EFUSE_CTRL:
case NAU8825_REG_MISC_CTRL:
case NAU8825_REG_BIAS_ADJ:
case NAU8825_REG_TRIM_SETTINGS ... NAU8825_REG_ANALOG_CONTROL_2:
case NAU8825_REG_ANALOG_ADC_1 ... NAU8825_REG_MIC_BIAS:
case NAU8825_REG_BOOST ... NAU8825_REG_FEPGA:
case NAU8825_REG_POWER_UP_CONTROL ... NAU8825_REG_CHARGE_PUMP:
return true;
default:
return false;
}
}
static bool nau8825_volatile_reg(struct device *dev, unsigned int reg)
{
switch (reg) {
case NAU8825_REG_RESET:
case NAU8825_REG_IRQ_STATUS:
case NAU8825_REG_INT_CLR_KEY_STATUS:
case NAU8825_REG_IMM_RMS_L:
case NAU8825_REG_IMM_RMS_R:
case NAU8825_REG_I2C_DEVICE_ID:
case NAU8825_REG_SARDOUT_RAM_STATUS:
case NAU8825_REG_CHARGE_PUMP_INPUT_READ:
case NAU8825_REG_GENERAL_STATUS:
case NAU8825_REG_BIQ_CTRL ... NAU8825_REG_BIQ_COF10:
return true;
default:
return false;
}
}
static int nau8825_adc_event(struct snd_soc_dapm_widget *w,
struct snd_kcontrol *kcontrol, int event)
{
struct snd_soc_component *component = snd_soc_dapm_to_component(w->dapm);
struct nau8825 *nau8825 = snd_soc_component_get_drvdata(component);
switch (event) {
case SND_SOC_DAPM_POST_PMU:
msleep(125);
regmap_update_bits(nau8825->regmap, NAU8825_REG_ENA_CTRL,
NAU8825_ENABLE_ADC, NAU8825_ENABLE_ADC);
break;
case SND_SOC_DAPM_POST_PMD:
if (!nau8825->irq)
regmap_update_bits(nau8825->regmap,
NAU8825_REG_ENA_CTRL, NAU8825_ENABLE_ADC, 0);
break;
default:
return -EINVAL;
}
return 0;
}
static int nau8825_pump_event(struct snd_soc_dapm_widget *w,
struct snd_kcontrol *kcontrol, int event)
{
struct snd_soc_component *component = snd_soc_dapm_to_component(w->dapm);
struct nau8825 *nau8825 = snd_soc_component_get_drvdata(component);
switch (event) {
case SND_SOC_DAPM_POST_PMU:
/* Prevent startup click by letting charge pump to ramp up */
msleep(10);
regmap_update_bits(nau8825->regmap, NAU8825_REG_CHARGE_PUMP,
NAU8825_JAMNODCLOW, NAU8825_JAMNODCLOW);
break;
case SND_SOC_DAPM_PRE_PMD:
regmap_update_bits(nau8825->regmap, NAU8825_REG_CHARGE_PUMP,
NAU8825_JAMNODCLOW, 0);
break;
default:
return -EINVAL;
}
return 0;
}
static int nau8825_output_dac_event(struct snd_soc_dapm_widget *w,
struct snd_kcontrol *kcontrol, int event)
{
struct snd_soc_component *component = snd_soc_dapm_to_component(w->dapm);
struct nau8825 *nau8825 = snd_soc_component_get_drvdata(component);
switch (event) {
case SND_SOC_DAPM_PRE_PMU:
/* Disables the TESTDAC to let DAC signal pass through. */
regmap_update_bits(nau8825->regmap, NAU8825_REG_BIAS_ADJ,
NAU8825_BIAS_TESTDAC_EN, 0);
break;
case SND_SOC_DAPM_POST_PMD:
regmap_update_bits(nau8825->regmap, NAU8825_REG_BIAS_ADJ,
NAU8825_BIAS_TESTDAC_EN, NAU8825_BIAS_TESTDAC_EN);
break;
default:
return -EINVAL;
}
return 0;
}
static int system_clock_control(struct snd_soc_dapm_widget *w,
struct snd_kcontrol *k, int event)
{
struct snd_soc_component *component = snd_soc_dapm_to_component(w->dapm);
struct nau8825 *nau8825 = snd_soc_component_get_drvdata(component);
struct regmap *regmap = nau8825->regmap;
if (SND_SOC_DAPM_EVENT_OFF(event)) {
dev_dbg(nau8825->dev, "system clock control : POWER OFF\n");
/* Set clock source to disable or internal clock before the
* playback or capture end. Codec needs clock for Jack
* detection and button press if jack inserted; otherwise,
* the clock should be closed.
*/
if (nau8825_is_jack_inserted(regmap)) {
nau8825_configure_sysclk(nau8825,
NAU8825_CLK_INTERNAL, 0);
} else {
nau8825_configure_sysclk(nau8825, NAU8825_CLK_DIS, 0);
}
}
return 0;
}
static int nau8825_biq_coeff_get(struct snd_kcontrol *kcontrol,
struct snd_ctl_elem_value *ucontrol)
{
struct snd_soc_component *component = snd_kcontrol_chip(kcontrol);
struct soc_bytes_ext *params = (void *)kcontrol->private_value;
if (!component->regmap)
return -EINVAL;
regmap_raw_read(component->regmap, NAU8825_REG_BIQ_COF1,
ucontrol->value.bytes.data, params->max);
return 0;
}
static int nau8825_biq_coeff_put(struct snd_kcontrol *kcontrol,
struct snd_ctl_elem_value *ucontrol)
{
struct snd_soc_component *component = snd_kcontrol_chip(kcontrol);
struct soc_bytes_ext *params = (void *)kcontrol->private_value;
void *data;
if (!component->regmap)
return -EINVAL;
data = kmemdup(ucontrol->value.bytes.data,
params->max, GFP_KERNEL | GFP_DMA);
if (!data)
return -ENOMEM;
regmap_update_bits(component->regmap, NAU8825_REG_BIQ_CTRL,
NAU8825_BIQ_WRT_EN, 0);
regmap_raw_write(component->regmap, NAU8825_REG_BIQ_COF1,
data, params->max);
regmap_update_bits(component->regmap, NAU8825_REG_BIQ_CTRL,
NAU8825_BIQ_WRT_EN, NAU8825_BIQ_WRT_EN);
kfree(data);
return 0;
}
static const char * const nau8825_biq_path[] = {
"ADC", "DAC"
};
static const struct soc_enum nau8825_biq_path_enum =
SOC_ENUM_SINGLE(NAU8825_REG_BIQ_CTRL, NAU8825_BIQ_PATH_SFT,
ARRAY_SIZE(nau8825_biq_path), nau8825_biq_path);
static const char * const nau8825_adc_decimation[] = {
"32", "64", "128", "256"
};
static const struct soc_enum nau8825_adc_decimation_enum =
SOC_ENUM_SINGLE(NAU8825_REG_ADC_RATE, NAU8825_ADC_SYNC_DOWN_SFT,
ARRAY_SIZE(nau8825_adc_decimation), nau8825_adc_decimation);
static const char * const nau8825_dac_oversampl[] = {
"64", "256", "128", "", "32"
};
static const struct soc_enum nau8825_dac_oversampl_enum =
SOC_ENUM_SINGLE(NAU8825_REG_DAC_CTRL1, NAU8825_DAC_OVERSAMPLE_SFT,
ARRAY_SIZE(nau8825_dac_oversampl), nau8825_dac_oversampl);
static const DECLARE_TLV_DB_MINMAX_MUTE(adc_vol_tlv, -10300, 2400);
static const DECLARE_TLV_DB_MINMAX_MUTE(sidetone_vol_tlv, -4200, 0);
static const DECLARE_TLV_DB_MINMAX(dac_vol_tlv, -5400, 0);
static const DECLARE_TLV_DB_MINMAX(fepga_gain_tlv, -100, 3600);
static const DECLARE_TLV_DB_MINMAX_MUTE(crosstalk_vol_tlv, -9600, 2400);
static const struct snd_kcontrol_new nau8825_controls[] = {
SOC_SINGLE_TLV("Mic Volume", NAU8825_REG_ADC_DGAIN_CTRL,
0, 0xff, 0, adc_vol_tlv),
SOC_DOUBLE_TLV("Headphone Bypass Volume", NAU8825_REG_ADC_DGAIN_CTRL,
12, 8, 0x0f, 0, sidetone_vol_tlv),
SOC_DOUBLE_TLV("Headphone Volume", NAU8825_REG_HSVOL_CTRL,
6, 0, 0x3f, 1, dac_vol_tlv),
SOC_SINGLE_TLV("Frontend PGA Volume", NAU8825_REG_POWER_UP_CONTROL,
8, 37, 0, fepga_gain_tlv),
SOC_DOUBLE_TLV("Headphone Crosstalk Volume", NAU8825_REG_DAC_DGAIN_CTRL,
0, 8, 0xff, 0, crosstalk_vol_tlv),
SOC_ENUM("ADC Decimation Rate", nau8825_adc_decimation_enum),
SOC_ENUM("DAC Oversampling Rate", nau8825_dac_oversampl_enum),
/* programmable biquad filter */
SOC_ENUM("BIQ Path Select", nau8825_biq_path_enum),
SND_SOC_BYTES_EXT("BIQ Coefficients", 20,
nau8825_biq_coeff_get, nau8825_biq_coeff_put),
};
/* DAC Mux 0x33[9] and 0x34[9] */
static const char * const nau8825_dac_src[] = {
"DACL", "DACR",
};
static SOC_ENUM_SINGLE_DECL(
nau8825_dacl_enum, NAU8825_REG_DACL_CTRL,
NAU8825_DACL_CH_SEL_SFT, nau8825_dac_src);
static SOC_ENUM_SINGLE_DECL(
nau8825_dacr_enum, NAU8825_REG_DACR_CTRL,
NAU8825_DACR_CH_SEL_SFT, nau8825_dac_src);
static const struct snd_kcontrol_new nau8825_dacl_mux =
SOC_DAPM_ENUM("DACL Source", nau8825_dacl_enum);
static const struct snd_kcontrol_new nau8825_dacr_mux =
SOC_DAPM_ENUM("DACR Source", nau8825_dacr_enum);
static const struct snd_soc_dapm_widget nau8825_dapm_widgets[] = {
SND_SOC_DAPM_AIF_OUT("AIFTX", "Capture", 0, NAU8825_REG_I2S_PCM_CTRL2,
15, 1),
SND_SOC_DAPM_AIF_IN("AIFRX", "Playback", 0, SND_SOC_NOPM, 0, 0),
SND_SOC_DAPM_SUPPLY("System Clock", SND_SOC_NOPM, 0, 0,
system_clock_control, SND_SOC_DAPM_POST_PMD),
SND_SOC_DAPM_INPUT("MIC"),
SND_SOC_DAPM_MICBIAS("MICBIAS", NAU8825_REG_MIC_BIAS, 8, 0),
SND_SOC_DAPM_PGA("Frontend PGA", NAU8825_REG_POWER_UP_CONTROL, 14, 0,
NULL, 0),
SND_SOC_DAPM_ADC_E("ADC", NULL, SND_SOC_NOPM, 0, 0,
nau8825_adc_event, SND_SOC_DAPM_POST_PMU |
SND_SOC_DAPM_POST_PMD),
SND_SOC_DAPM_SUPPLY("ADC Clock", NAU8825_REG_ENA_CTRL, 7, 0, NULL, 0),
SND_SOC_DAPM_SUPPLY("ADC Power", NAU8825_REG_ANALOG_ADC_2, 6, 0, NULL,
0),
/* ADC for button press detection. A dapm supply widget is used to
* prevent dapm_power_widgets keeping the codec at SND_SOC_BIAS_ON
* during suspend.
*/
SND_SOC_DAPM_SUPPLY("SAR", NAU8825_REG_SAR_CTRL,
NAU8825_SAR_ADC_EN_SFT, 0, NULL, 0),
SND_SOC_DAPM_PGA_S("ADACL", 2, NAU8825_REG_RDAC, 12, 0, NULL, 0),
SND_SOC_DAPM_PGA_S("ADACR", 2, NAU8825_REG_RDAC, 13, 0, NULL, 0),
SND_SOC_DAPM_PGA_S("ADACL Clock", 3, NAU8825_REG_RDAC, 8, 0, NULL, 0),
SND_SOC_DAPM_PGA_S("ADACR Clock", 3, NAU8825_REG_RDAC, 9, 0, NULL, 0),
SND_SOC_DAPM_DAC("DDACR", NULL, NAU8825_REG_ENA_CTRL,
NAU8825_ENABLE_DACR_SFT, 0),
SND_SOC_DAPM_DAC("DDACL", NULL, NAU8825_REG_ENA_CTRL,
NAU8825_ENABLE_DACL_SFT, 0),
SND_SOC_DAPM_SUPPLY("DDAC Clock", NAU8825_REG_ENA_CTRL, 6, 0, NULL, 0),
SND_SOC_DAPM_MUX("DACL Mux", SND_SOC_NOPM, 0, 0, &nau8825_dacl_mux),
SND_SOC_DAPM_MUX("DACR Mux", SND_SOC_NOPM, 0, 0, &nau8825_dacr_mux),
SND_SOC_DAPM_PGA_S("HP amp L", 0,
NAU8825_REG_CLASSG_CTRL, 1, 0, NULL, 0),
SND_SOC_DAPM_PGA_S("HP amp R", 0,
NAU8825_REG_CLASSG_CTRL, 2, 0, NULL, 0),
SND_SOC_DAPM_PGA_S("Charge Pump", 1, NAU8825_REG_CHARGE_PUMP, 5, 0,
nau8825_pump_event, SND_SOC_DAPM_POST_PMU |
SND_SOC_DAPM_PRE_PMD),
SND_SOC_DAPM_PGA_S("Output Driver R Stage 1", 4,
NAU8825_REG_POWER_UP_CONTROL, 5, 0, NULL, 0),
SND_SOC_DAPM_PGA_S("Output Driver L Stage 1", 4,
NAU8825_REG_POWER_UP_CONTROL, 4, 0, NULL, 0),
SND_SOC_DAPM_PGA_S("Output Driver R Stage 2", 5,
NAU8825_REG_POWER_UP_CONTROL, 3, 0, NULL, 0),
SND_SOC_DAPM_PGA_S("Output Driver L Stage 2", 5,
NAU8825_REG_POWER_UP_CONTROL, 2, 0, NULL, 0),
SND_SOC_DAPM_PGA_S("Output Driver R Stage 3", 6,
NAU8825_REG_POWER_UP_CONTROL, 1, 0, NULL, 0),
SND_SOC_DAPM_PGA_S("Output Driver L Stage 3", 6,
NAU8825_REG_POWER_UP_CONTROL, 0, 0, NULL, 0),
SND_SOC_DAPM_PGA_S("Output DACL", 7,
NAU8825_REG_CHARGE_PUMP, 8, 1, nau8825_output_dac_event,
SND_SOC_DAPM_PRE_PMU | SND_SOC_DAPM_POST_PMD),
SND_SOC_DAPM_PGA_S("Output DACR", 7,
NAU8825_REG_CHARGE_PUMP, 9, 1, nau8825_output_dac_event,
SND_SOC_DAPM_PRE_PMU | SND_SOC_DAPM_POST_PMD),
/* HPOL/R are ungrounded by disabling 16 Ohm pull-downs on playback */
SND_SOC_DAPM_PGA_S("HPOL Pulldown", 8,
NAU8825_REG_HSD_CTRL, 0, 1, NULL, 0),
SND_SOC_DAPM_PGA_S("HPOR Pulldown", 8,
NAU8825_REG_HSD_CTRL, 1, 1, NULL, 0),
/* High current HPOL/R boost driver */
SND_SOC_DAPM_PGA_S("HP Boost Driver", 9,
NAU8825_REG_BOOST, 9, 1, NULL, 0),
/* Class G operation control*/
SND_SOC_DAPM_PGA_S("Class G", 10,
NAU8825_REG_CLASSG_CTRL, 0, 0, NULL, 0),
SND_SOC_DAPM_OUTPUT("HPOL"),
SND_SOC_DAPM_OUTPUT("HPOR"),
};
static const struct snd_soc_dapm_route nau8825_dapm_routes[] = {
{"Frontend PGA", NULL, "MIC"},
{"ADC", NULL, "Frontend PGA"},
{"ADC", NULL, "ADC Clock"},
{"ADC", NULL, "ADC Power"},
{"AIFTX", NULL, "ADC"},
{"AIFTX", NULL, "System Clock"},
{"AIFRX", NULL, "System Clock"},
{"DDACL", NULL, "AIFRX"},
{"DDACR", NULL, "AIFRX"},
{"DDACL", NULL, "DDAC Clock"},
{"DDACR", NULL, "DDAC Clock"},
{"DACL Mux", "DACL", "DDACL"},
{"DACL Mux", "DACR", "DDACR"},
{"DACR Mux", "DACL", "DDACL"},
{"DACR Mux", "DACR", "DDACR"},
{"HP amp L", NULL, "DACL Mux"},
{"HP amp R", NULL, "DACR Mux"},
{"Charge Pump", NULL, "HP amp L"},
{"Charge Pump", NULL, "HP amp R"},
{"ADACL", NULL, "Charge Pump"},
{"ADACR", NULL, "Charge Pump"},
{"ADACL Clock", NULL, "ADACL"},
{"ADACR Clock", NULL, "ADACR"},
{"Output Driver L Stage 1", NULL, "ADACL Clock"},
{"Output Driver R Stage 1", NULL, "ADACR Clock"},
{"Output Driver L Stage 2", NULL, "Output Driver L Stage 1"},
{"Output Driver R Stage 2", NULL, "Output Driver R Stage 1"},
{"Output Driver L Stage 3", NULL, "Output Driver L Stage 2"},
{"Output Driver R Stage 3", NULL, "Output Driver R Stage 2"},
{"Output DACL", NULL, "Output Driver L Stage 3"},
{"Output DACR", NULL, "Output Driver R Stage 3"},
{"HPOL Pulldown", NULL, "Output DACL"},
{"HPOR Pulldown", NULL, "Output DACR"},
{"HP Boost Driver", NULL, "HPOL Pulldown"},
{"HP Boost Driver", NULL, "HPOR Pulldown"},
{"Class G", NULL, "HP Boost Driver"},
{"HPOL", NULL, "Class G"},
{"HPOR", NULL, "Class G"},
};
static int nau8825_clock_check(struct nau8825 *nau8825,
int stream, int rate, int osr)
{
int osrate;
if (stream == SNDRV_PCM_STREAM_PLAYBACK) {
if (osr >= ARRAY_SIZE(osr_dac_sel))
return -EINVAL;
osrate = osr_dac_sel[osr].osr;
} else {
if (osr >= ARRAY_SIZE(osr_adc_sel))
return -EINVAL;
osrate = osr_adc_sel[osr].osr;
}
if (!osrate || rate * osr > CLK_DA_AD_MAX) {
dev_err(nau8825->dev, "exceed the maximum frequency of CLK_ADC or CLK_DAC\n");
return -EINVAL;
}
return 0;
}
static int nau8825_hw_params(struct snd_pcm_substream *substream,
struct snd_pcm_hw_params *params,
struct snd_soc_dai *dai)
{
struct snd_soc_component *component = dai->component;
struct nau8825 *nau8825 = snd_soc_component_get_drvdata(component);
unsigned int val_len = 0, osr, ctrl_val, bclk_fs, bclk_div;
nau8825_sema_acquire(nau8825, 3 * HZ);
/* CLK_DAC or CLK_ADC = OSR * FS
* DAC or ADC clock frequency is defined as Over Sampling Rate (OSR)
* multiplied by the audio sample rate (Fs). Note that the OSR and Fs
* values must be selected such that the maximum frequency is less
* than 6.144 MHz.
*/
if (substream->stream == SNDRV_PCM_STREAM_PLAYBACK) {
regmap_read(nau8825->regmap, NAU8825_REG_DAC_CTRL1, &osr);
osr &= NAU8825_DAC_OVERSAMPLE_MASK;
if (nau8825_clock_check(nau8825, substream->stream,
params_rate(params), osr)) {
nau8825_sema_release(nau8825);
return -EINVAL;
}
regmap_update_bits(nau8825->regmap, NAU8825_REG_CLK_DIVIDER,
NAU8825_CLK_DAC_SRC_MASK,
osr_dac_sel[osr].clk_src << NAU8825_CLK_DAC_SRC_SFT);
} else {
regmap_read(nau8825->regmap, NAU8825_REG_ADC_RATE, &osr);
osr &= NAU8825_ADC_SYNC_DOWN_MASK;
if (nau8825_clock_check(nau8825, substream->stream,
params_rate(params), osr)) {
nau8825_sema_release(nau8825);
return -EINVAL;
}
regmap_update_bits(nau8825->regmap, NAU8825_REG_CLK_DIVIDER,
NAU8825_CLK_ADC_SRC_MASK,
osr_adc_sel[osr].clk_src << NAU8825_CLK_ADC_SRC_SFT);
}
/* make BCLK and LRC divde configuration if the codec as master. */
regmap_read(nau8825->regmap, NAU8825_REG_I2S_PCM_CTRL2, &ctrl_val);
if (ctrl_val & NAU8825_I2S_MS_MASTER) {
/* get the bclk and fs ratio */
bclk_fs = snd_soc_params_to_bclk(params) / params_rate(params);
if (bclk_fs <= 32)
bclk_div = 2;
else if (bclk_fs <= 64)
bclk_div = 1;
else if (bclk_fs <= 128)
bclk_div = 0;
else {
nau8825_sema_release(nau8825);
return -EINVAL;
}
regmap_update_bits(nau8825->regmap, NAU8825_REG_I2S_PCM_CTRL2,
NAU8825_I2S_LRC_DIV_MASK | NAU8825_I2S_BLK_DIV_MASK,
((bclk_div + 1) << NAU8825_I2S_LRC_DIV_SFT) | bclk_div);
}
switch (params_width(params)) {
case 16:
val_len |= NAU8825_I2S_DL_16;
break;
case 20:
val_len |= NAU8825_I2S_DL_20;
break;
case 24:
val_len |= NAU8825_I2S_DL_24;
break;
case 32:
val_len |= NAU8825_I2S_DL_32;
break;
default:
nau8825_sema_release(nau8825);
return -EINVAL;
}
regmap_update_bits(nau8825->regmap, NAU8825_REG_I2S_PCM_CTRL1,
NAU8825_I2S_DL_MASK, val_len);
/* Release the semaphore. */
nau8825_sema_release(nau8825);
return 0;
}
static int nau8825_set_dai_fmt(struct snd_soc_dai *codec_dai, unsigned int fmt)
{
struct snd_soc_component *component = codec_dai->component;
struct nau8825 *nau8825 = snd_soc_component_get_drvdata(component);
unsigned int ctrl1_val = 0, ctrl2_val = 0;
switch (fmt & SND_SOC_DAIFMT_MASTER_MASK) {
case SND_SOC_DAIFMT_CBM_CFM:
ctrl2_val |= NAU8825_I2S_MS_MASTER;
break;
case SND_SOC_DAIFMT_CBS_CFS:
break;
default:
return -EINVAL;
}
switch (fmt & SND_SOC_DAIFMT_INV_MASK) {
case SND_SOC_DAIFMT_NB_NF:
break;
case SND_SOC_DAIFMT_IB_NF:
ctrl1_val |= NAU8825_I2S_BP_INV;
break;
default:
return -EINVAL;
}
switch (fmt & SND_SOC_DAIFMT_FORMAT_MASK) {
case SND_SOC_DAIFMT_I2S:
ctrl1_val |= NAU8825_I2S_DF_I2S;
break;
case SND_SOC_DAIFMT_LEFT_J:
ctrl1_val |= NAU8825_I2S_DF_LEFT;
break;
case SND_SOC_DAIFMT_RIGHT_J:
ctrl1_val |= NAU8825_I2S_DF_RIGTH;
break;
case SND_SOC_DAIFMT_DSP_A:
ctrl1_val |= NAU8825_I2S_DF_PCM_AB;
break;
case SND_SOC_DAIFMT_DSP_B:
ctrl1_val |= NAU8825_I2S_DF_PCM_AB;
ctrl1_val |= NAU8825_I2S_PCMB_EN;
break;
default:
return -EINVAL;
}
nau8825_sema_acquire(nau8825, 3 * HZ);
regmap_update_bits(nau8825->regmap, NAU8825_REG_I2S_PCM_CTRL1,
NAU8825_I2S_DL_MASK | NAU8825_I2S_DF_MASK |
NAU8825_I2S_BP_MASK | NAU8825_I2S_PCMB_MASK,
ctrl1_val);
regmap_update_bits(nau8825->regmap, NAU8825_REG_I2S_PCM_CTRL2,
NAU8825_I2S_MS_MASK, ctrl2_val);
/* Release the semaphore. */
nau8825_sema_release(nau8825);
return 0;
}
static const struct snd_soc_dai_ops nau8825_dai_ops = {
.hw_params = nau8825_hw_params,
.set_fmt = nau8825_set_dai_fmt,
};
#define NAU8825_RATES SNDRV_PCM_RATE_8000_192000
#define NAU8825_FORMATS (SNDRV_PCM_FMTBIT_S16_LE | SNDRV_PCM_FMTBIT_S20_3LE \
| SNDRV_PCM_FMTBIT_S24_3LE | SNDRV_PCM_FMTBIT_S32_LE)
static struct snd_soc_dai_driver nau8825_dai = {
.name = "nau8825-hifi",
.playback = {
.stream_name = "Playback",
.channels_min = 1,
.channels_max = 2,
.rates = NAU8825_RATES,
.formats = NAU8825_FORMATS,
},
.capture = {
.stream_name = "Capture",
.channels_min = 1,
.channels_max = 1,
.rates = NAU8825_RATES,
.formats = NAU8825_FORMATS,
},
.ops = &nau8825_dai_ops,
};
/**
* nau8825_enable_jack_detect - Specify a jack for event reporting
*
* @component: component to register the jack with
* @jack: jack to use to report headset and button events on
*
* After this function has been called the headset insert/remove and button
* events will be routed to the given jack. Jack can be null to stop
* reporting.
*/
int nau8825_enable_jack_detect(struct snd_soc_component *component,
struct snd_soc_jack *jack)
{
struct nau8825 *nau8825 = snd_soc_component_get_drvdata(component);
struct regmap *regmap = nau8825->regmap;
nau8825->jack = jack;
if (!nau8825->jack) {
regmap_update_bits(regmap, NAU8825_REG_HSD_CTRL,
NAU8825_HSD_AUTO_MODE | NAU8825_SPKR_DWN1R |
NAU8825_SPKR_DWN1L, 0);
return 0;
}
/* Ground HP Outputs[1:0], needed for headset auto detection
* Enable Automatic Mic/Gnd switching reading on insert interrupt[6]
*/
regmap_update_bits(regmap, NAU8825_REG_HSD_CTRL,
NAU8825_HSD_AUTO_MODE | NAU8825_SPKR_DWN1R | NAU8825_SPKR_DWN1L,
NAU8825_HSD_AUTO_MODE | NAU8825_SPKR_DWN1R | NAU8825_SPKR_DWN1L);
return 0;
}
EXPORT_SYMBOL_GPL(nau8825_enable_jack_detect);
static bool nau8825_is_jack_inserted(struct regmap *regmap)
{
bool active_high, is_high;
int status, jkdet;
regmap_read(regmap, NAU8825_REG_JACK_DET_CTRL, &jkdet);
active_high = jkdet & NAU8825_JACK_POLARITY;
regmap_read(regmap, NAU8825_REG_I2C_DEVICE_ID, &status);
is_high = status & NAU8825_GPIO2JD1;
/* return jack connection status according to jack insertion logic
* active high or active low.
*/
return active_high == is_high;
}
static void nau8825_restart_jack_detection(struct regmap *regmap)
{
/* this will restart the entire jack detection process including MIC/GND
* switching and create interrupts. We have to go from 0 to 1 and back
* to 0 to restart.
*/
regmap_update_bits(regmap, NAU8825_REG_JACK_DET_CTRL,
NAU8825_JACK_DET_RESTART, NAU8825_JACK_DET_RESTART);
regmap_update_bits(regmap, NAU8825_REG_JACK_DET_CTRL,
NAU8825_JACK_DET_RESTART, 0);
}
static void nau8825_int_status_clear_all(struct regmap *regmap)
{
int active_irq, clear_irq, i;
/* Reset the intrruption status from rightmost bit if the corres-
* ponding irq event occurs.
*/
regmap_read(regmap, NAU8825_REG_IRQ_STATUS, &active_irq);
for (i = 0; i < NAU8825_REG_DATA_LEN; i++) {
clear_irq = (0x1 << i);
if (active_irq & clear_irq)
regmap_write(regmap,
NAU8825_REG_INT_CLR_KEY_STATUS, clear_irq);
}
}
static void nau8825_eject_jack(struct nau8825 *nau8825)
{
struct snd_soc_dapm_context *dapm = nau8825->dapm;
struct regmap *regmap = nau8825->regmap;
/* Force to cancel the cross talk detection process */
nau8825_xtalk_cancel(nau8825);
snd_soc_dapm_disable_pin(dapm, "SAR");
snd_soc_dapm_disable_pin(dapm, "MICBIAS");
/* Detach 2kOhm Resistors from MICBIAS to MICGND1/2 */
regmap_update_bits(regmap, NAU8825_REG_MIC_BIAS,
NAU8825_MICBIAS_JKSLV | NAU8825_MICBIAS_JKR2, 0);
/* ground HPL/HPR, MICGRND1/2 */
regmap_update_bits(regmap, NAU8825_REG_HSD_CTRL, 0xf, 0xf);
snd_soc_dapm_sync(dapm);
/* Clear all interruption status */
nau8825_int_status_clear_all(regmap);
/* Enable the insertion interruption, disable the ejection inter-
* ruption, and then bypass de-bounce circuit.
*/
regmap_update_bits(regmap, NAU8825_REG_INTERRUPT_DIS_CTRL,
NAU8825_IRQ_EJECT_DIS | NAU8825_IRQ_INSERT_DIS,
NAU8825_IRQ_EJECT_DIS);
regmap_update_bits(regmap, NAU8825_REG_INTERRUPT_MASK,
NAU8825_IRQ_OUTPUT_EN | NAU8825_IRQ_EJECT_EN |
NAU8825_IRQ_HEADSET_COMPLETE_EN | NAU8825_IRQ_INSERT_EN,
NAU8825_IRQ_OUTPUT_EN | NAU8825_IRQ_EJECT_EN |
NAU8825_IRQ_HEADSET_COMPLETE_EN);
regmap_update_bits(regmap, NAU8825_REG_JACK_DET_CTRL,
NAU8825_JACK_DET_DB_BYPASS, NAU8825_JACK_DET_DB_BYPASS);
/* Disable ADC needed for interruptions at audo mode */
regmap_update_bits(regmap, NAU8825_REG_ENA_CTRL,
NAU8825_ENABLE_ADC, 0);
/* Close clock for jack type detection at manual mode */
nau8825_configure_sysclk(nau8825, NAU8825_CLK_DIS, 0);
}
/* Enable audo mode interruptions with internal clock. */
static void nau8825_setup_auto_irq(struct nau8825 *nau8825)
{
struct regmap *regmap = nau8825->regmap;
/* Enable headset jack type detection complete interruption and
* jack ejection interruption.
*/
regmap_update_bits(regmap, NAU8825_REG_INTERRUPT_MASK,
NAU8825_IRQ_HEADSET_COMPLETE_EN | NAU8825_IRQ_EJECT_EN, 0);
/* Enable internal VCO needed for interruptions */
nau8825_configure_sysclk(nau8825, NAU8825_CLK_INTERNAL, 0);
/* Enable ADC needed for interruptions */
regmap_update_bits(regmap, NAU8825_REG_ENA_CTRL,
NAU8825_ENABLE_ADC, NAU8825_ENABLE_ADC);
/* Chip needs one FSCLK cycle in order to generate interruptions,
* as we cannot guarantee one will be provided by the system. Turning
* master mode on then off enables us to generate that FSCLK cycle
* with a minimum of contention on the clock bus.
*/
regmap_update_bits(regmap, NAU8825_REG_I2S_PCM_CTRL2,
NAU8825_I2S_MS_MASK, NAU8825_I2S_MS_MASTER);
regmap_update_bits(regmap, NAU8825_REG_I2S_PCM_CTRL2,
NAU8825_I2S_MS_MASK, NAU8825_I2S_MS_SLAVE);
/* Not bypass de-bounce circuit */
regmap_update_bits(regmap, NAU8825_REG_JACK_DET_CTRL,
NAU8825_JACK_DET_DB_BYPASS, 0);
/* Unmask all interruptions */
regmap_write(regmap, NAU8825_REG_INTERRUPT_DIS_CTRL, 0);
/* Restart the jack detection process at auto mode */
nau8825_restart_jack_detection(regmap);
}
static int nau8825_button_decode(int value)
{
int buttons = 0;
/* The chip supports up to 8 buttons, but ALSA defines only 6 buttons */
if (value & BIT(0))
buttons |= SND_JACK_BTN_0;
if (value & BIT(1))
buttons |= SND_JACK_BTN_1;
if (value & BIT(2))
buttons |= SND_JACK_BTN_2;
if (value & BIT(3))
buttons |= SND_JACK_BTN_3;
if (value & BIT(4))
buttons |= SND_JACK_BTN_4;
if (value & BIT(5))
buttons |= SND_JACK_BTN_5;
return buttons;
}
static int nau8825_jack_insert(struct nau8825 *nau8825)
{
struct regmap *regmap = nau8825->regmap;
struct snd_soc_dapm_context *dapm = nau8825->dapm;
int jack_status_reg, mic_detected;
int type = 0;
regmap_read(regmap, NAU8825_REG_GENERAL_STATUS, &jack_status_reg);
mic_detected = (jack_status_reg >> 10) & 3;
/* The JKSLV and JKR2 all detected in high impedance headset */
if (mic_detected == 0x3)
nau8825->high_imped = true;
else
nau8825->high_imped = false;
switch (mic_detected) {
case 0:
/* no mic */
type = SND_JACK_HEADPHONE;
break;
case 1:
dev_dbg(nau8825->dev, "OMTP (micgnd1) mic connected\n");
type = SND_JACK_HEADSET;
/* Unground MICGND1 */
regmap_update_bits(regmap, NAU8825_REG_HSD_CTRL, 3 << 2,
1 << 2);
/* Attach 2kOhm Resistor from MICBIAS to MICGND1 */
regmap_update_bits(regmap, NAU8825_REG_MIC_BIAS,
NAU8825_MICBIAS_JKSLV | NAU8825_MICBIAS_JKR2,
NAU8825_MICBIAS_JKR2);
/* Attach SARADC to MICGND1 */
regmap_update_bits(regmap, NAU8825_REG_SAR_CTRL,
NAU8825_SAR_INPUT_MASK,
NAU8825_SAR_INPUT_JKR2);
snd_soc_dapm_force_enable_pin(dapm, "MICBIAS");
snd_soc_dapm_force_enable_pin(dapm, "SAR");
snd_soc_dapm_sync(dapm);
break;
case 2:
dev_dbg(nau8825->dev, "CTIA (micgnd2) mic connected\n");
type = SND_JACK_HEADSET;
/* Unground MICGND2 */
regmap_update_bits(regmap, NAU8825_REG_HSD_CTRL, 3 << 2,
2 << 2);
/* Attach 2kOhm Resistor from MICBIAS to MICGND2 */
regmap_update_bits(regmap, NAU8825_REG_MIC_BIAS,
NAU8825_MICBIAS_JKSLV | NAU8825_MICBIAS_JKR2,
NAU8825_MICBIAS_JKSLV);
/* Attach SARADC to MICGND2 */
regmap_update_bits(regmap, NAU8825_REG_SAR_CTRL,
NAU8825_SAR_INPUT_MASK,
NAU8825_SAR_INPUT_JKSLV);
snd_soc_dapm_force_enable_pin(dapm, "MICBIAS");
snd_soc_dapm_force_enable_pin(dapm, "SAR");
snd_soc_dapm_sync(dapm);
break;
case 3:
/* detect error case */
dev_err(nau8825->dev, "detection error; disable mic function\n");
type = SND_JACK_HEADPHONE;
break;
}
/* Leaving HPOL/R grounded after jack insert by default. They will be
* ungrounded as part of the widget power up sequence at the beginning
* of playback to reduce pop.
*/
return type;
}
#define NAU8825_BUTTONS (SND_JACK_BTN_0 | SND_JACK_BTN_1 | \
SND_JACK_BTN_2 | SND_JACK_BTN_3)
static irqreturn_t nau8825_interrupt(int irq, void *data)
{
struct nau8825 *nau8825 = (struct nau8825 *)data;
struct regmap *regmap = nau8825->regmap;
int active_irq, clear_irq = 0, event = 0, event_mask = 0;
if (regmap_read(regmap, NAU8825_REG_IRQ_STATUS, &active_irq)) {
dev_err(nau8825->dev, "failed to read irq status\n");
return IRQ_NONE;
}
if ((active_irq & NAU8825_JACK_EJECTION_IRQ_MASK) ==
NAU8825_JACK_EJECTION_DETECTED) {
nau8825_eject_jack(nau8825);
event_mask |= SND_JACK_HEADSET;
clear_irq = NAU8825_JACK_EJECTION_IRQ_MASK;
} else if (active_irq & NAU8825_KEY_SHORT_PRESS_IRQ) {
int key_status;
regmap_read(regmap, NAU8825_REG_INT_CLR_KEY_STATUS,
&key_status);
/* upper 8 bits of the register are for short pressed keys,
* lower 8 bits - for long pressed buttons
*/
nau8825->button_pressed = nau8825_button_decode(
key_status >> 8);
event |= nau8825->button_pressed;
event_mask |= NAU8825_BUTTONS;
clear_irq = NAU8825_KEY_SHORT_PRESS_IRQ;
} else if (active_irq & NAU8825_KEY_RELEASE_IRQ) {
event_mask = NAU8825_BUTTONS;
clear_irq = NAU8825_KEY_RELEASE_IRQ;
} else if (active_irq & NAU8825_HEADSET_COMPLETION_IRQ) {
if (nau8825_is_jack_inserted(regmap)) {
event |= nau8825_jack_insert(nau8825);
if (nau8825->xtalk_enable && !nau8825->high_imped) {
/* Apply the cross talk suppression in the
* headset without high impedance.
*/
if (!nau8825->xtalk_protect) {
/* Raise protection for cross talk de-
* tection if no protection before.
* The driver has to cancel the pro-
* cess and restore changes if process
* is ongoing when ejection.
*/
int ret;
nau8825->xtalk_protect = true;
ret = nau8825_sema_acquire(nau8825, 0);
if (ret)
nau8825->xtalk_protect = false;
}
/* Startup cross talk detection process */
if (nau8825->xtalk_protect) {
nau8825->xtalk_state =
NAU8825_XTALK_PREPARE;
schedule_work(&nau8825->xtalk_work);
}
} else {
/* The cross talk suppression shouldn't apply
* in the headset with high impedance. Thus,
* relieve the protection raised before.
*/
if (nau8825->xtalk_protect) {
nau8825_sema_release(nau8825);
nau8825->xtalk_protect = false;
}
}
} else {
dev_warn(nau8825->dev, "Headset completion IRQ fired but no headset connected\n");
nau8825_eject_jack(nau8825);
}
event_mask |= SND_JACK_HEADSET;
clear_irq = NAU8825_HEADSET_COMPLETION_IRQ;
/* Record the interruption report event for driver to report
* the event later. The jack report will delay until cross
* talk detection process is done.
*/
if (nau8825->xtalk_state == NAU8825_XTALK_PREPARE) {
nau8825->xtalk_event = event;
nau8825->xtalk_event_mask = event_mask;
}
} else if (active_irq & NAU8825_IMPEDANCE_MEAS_IRQ) {
/* crosstalk detection enable and process on going */
if (nau8825->xtalk_enable && nau8825->xtalk_protect)
schedule_work(&nau8825->xtalk_work);
clear_irq = NAU8825_IMPEDANCE_MEAS_IRQ;
} else if ((active_irq & NAU8825_JACK_INSERTION_IRQ_MASK) ==
NAU8825_JACK_INSERTION_DETECTED) {
/* One more step to check GPIO status directly. Thus, the
* driver can confirm the real insertion interruption because
* the intrruption at manual mode has bypassed debounce
* circuit which can get rid of unstable status.
*/
if (nau8825_is_jack_inserted(regmap)) {
/* Turn off insertion interruption at manual mode */
regmap_update_bits(regmap,
NAU8825_REG_INTERRUPT_DIS_CTRL,
NAU8825_IRQ_INSERT_DIS,
NAU8825_IRQ_INSERT_DIS);
regmap_update_bits(regmap, NAU8825_REG_INTERRUPT_MASK,
NAU8825_IRQ_INSERT_EN, NAU8825_IRQ_INSERT_EN);
/* Enable interruption for jack type detection at audo
* mode which can detect microphone and jack type.
*/
nau8825_setup_auto_irq(nau8825);
}
}
if (!clear_irq)
clear_irq = active_irq;
/* clears the rightmost interruption */
regmap_write(regmap, NAU8825_REG_INT_CLR_KEY_STATUS, clear_irq);
/* Delay jack report until cross talk detection is done. It can avoid
* application to do playback preparation when cross talk detection
* process is still working. Otherwise, the resource like clock and
* power will be issued by them at the same time and conflict happens.
*/
if (event_mask && nau8825->xtalk_state == NAU8825_XTALK_DONE)
snd_soc_jack_report(nau8825->jack, event, event_mask);
return IRQ_HANDLED;
}
static void nau8825_setup_buttons(struct nau8825 *nau8825)
{
struct regmap *regmap = nau8825->regmap;
regmap_update_bits(regmap, NAU8825_REG_SAR_CTRL,
NAU8825_SAR_TRACKING_GAIN_MASK,
nau8825->sar_voltage << NAU8825_SAR_TRACKING_GAIN_SFT);
regmap_update_bits(regmap, NAU8825_REG_SAR_CTRL,
NAU8825_SAR_COMPARE_TIME_MASK,
nau8825->sar_compare_time << NAU8825_SAR_COMPARE_TIME_SFT);
regmap_update_bits(regmap, NAU8825_REG_SAR_CTRL,
NAU8825_SAR_SAMPLING_TIME_MASK,
nau8825->sar_sampling_time << NAU8825_SAR_SAMPLING_TIME_SFT);
regmap_update_bits(regmap, NAU8825_REG_KEYDET_CTRL,
NAU8825_KEYDET_LEVELS_NR_MASK,
(nau8825->sar_threshold_num - 1) << NAU8825_KEYDET_LEVELS_NR_SFT);
regmap_update_bits(regmap, NAU8825_REG_KEYDET_CTRL,
NAU8825_KEYDET_HYSTERESIS_MASK,
nau8825->sar_hysteresis << NAU8825_KEYDET_HYSTERESIS_SFT);
regmap_update_bits(regmap, NAU8825_REG_KEYDET_CTRL,
NAU8825_KEYDET_SHORTKEY_DEBOUNCE_MASK,
nau8825->key_debounce << NAU8825_KEYDET_SHORTKEY_DEBOUNCE_SFT);
regmap_write(regmap, NAU8825_REG_VDET_THRESHOLD_1,
(nau8825->sar_threshold[0] << 8) | nau8825->sar_threshold[1]);
regmap_write(regmap, NAU8825_REG_VDET_THRESHOLD_2,
(nau8825->sar_threshold[2] << 8) | nau8825->sar_threshold[3]);
regmap_write(regmap, NAU8825_REG_VDET_THRESHOLD_3,
(nau8825->sar_threshold[4] << 8) | nau8825->sar_threshold[5]);
regmap_write(regmap, NAU8825_REG_VDET_THRESHOLD_4,
(nau8825->sar_threshold[6] << 8) | nau8825->sar_threshold[7]);
/* Enable short press and release interruptions */
regmap_update_bits(regmap, NAU8825_REG_INTERRUPT_MASK,
NAU8825_IRQ_KEY_SHORT_PRESS_EN | NAU8825_IRQ_KEY_RELEASE_EN,
0);
}
static void nau8825_init_regs(struct nau8825 *nau8825)
{
struct regmap *regmap = nau8825->regmap;
/* Latch IIC LSB value */
regmap_write(regmap, NAU8825_REG_IIC_ADDR_SET, 0x0001);
/* Enable Bias/Vmid */
regmap_update_bits(nau8825->regmap, NAU8825_REG_BIAS_ADJ,
NAU8825_BIAS_VMID, NAU8825_BIAS_VMID);
regmap_update_bits(nau8825->regmap, NAU8825_REG_BOOST,
NAU8825_GLOBAL_BIAS_EN, NAU8825_GLOBAL_BIAS_EN);
/* VMID Tieoff */
regmap_update_bits(regmap, NAU8825_REG_BIAS_ADJ,
NAU8825_BIAS_VMID_SEL_MASK,
nau8825->vref_impedance << NAU8825_BIAS_VMID_SEL_SFT);
/* Disable Boost Driver, Automatic Short circuit protection enable */
regmap_update_bits(regmap, NAU8825_REG_BOOST,
NAU8825_PRECHARGE_DIS | NAU8825_HP_BOOST_DIS |
NAU8825_HP_BOOST_G_DIS | NAU8825_SHORT_SHUTDOWN_EN,
NAU8825_PRECHARGE_DIS | NAU8825_HP_BOOST_DIS |
NAU8825_HP_BOOST_G_DIS | NAU8825_SHORT_SHUTDOWN_EN);
regmap_update_bits(regmap, NAU8825_REG_GPIO12_CTRL,
NAU8825_JKDET_OUTPUT_EN,
nau8825->jkdet_enable ? 0 : NAU8825_JKDET_OUTPUT_EN);
regmap_update_bits(regmap, NAU8825_REG_GPIO12_CTRL,
NAU8825_JKDET_PULL_EN,
nau8825->jkdet_pull_enable ? 0 : NAU8825_JKDET_PULL_EN);
regmap_update_bits(regmap, NAU8825_REG_GPIO12_CTRL,
NAU8825_JKDET_PULL_UP,
nau8825->jkdet_pull_up ? NAU8825_JKDET_PULL_UP : 0);
regmap_update_bits(regmap, NAU8825_REG_JACK_DET_CTRL,
NAU8825_JACK_POLARITY,
/* jkdet_polarity - 1 is for active-low */
nau8825->jkdet_polarity ? 0 : NAU8825_JACK_POLARITY);
regmap_update_bits(regmap, NAU8825_REG_JACK_DET_CTRL,
NAU8825_JACK_INSERT_DEBOUNCE_MASK,
nau8825->jack_insert_debounce << NAU8825_JACK_INSERT_DEBOUNCE_SFT);
regmap_update_bits(regmap, NAU8825_REG_JACK_DET_CTRL,
NAU8825_JACK_EJECT_DEBOUNCE_MASK,
nau8825->jack_eject_debounce << NAU8825_JACK_EJECT_DEBOUNCE_SFT);
/* Pull up IRQ pin */
regmap_update_bits(regmap, NAU8825_REG_INTERRUPT_MASK,
NAU8825_IRQ_PIN_PULLUP | NAU8825_IRQ_PIN_PULL_EN,
NAU8825_IRQ_PIN_PULLUP | NAU8825_IRQ_PIN_PULL_EN);
/* Mask unneeded IRQs: 1 - disable, 0 - enable */
regmap_update_bits(regmap, NAU8825_REG_INTERRUPT_MASK, 0x7ff, 0x7ff);
regmap_update_bits(regmap, NAU8825_REG_MIC_BIAS,
NAU8825_MICBIAS_VOLTAGE_MASK, nau8825->micbias_voltage);
if (nau8825->sar_threshold_num)
nau8825_setup_buttons(nau8825);
/* Default oversampling/decimations settings are unusable
* (audible hiss). Set it to something better.
*/
regmap_update_bits(regmap, NAU8825_REG_ADC_RATE,
NAU8825_ADC_SYNC_DOWN_MASK | NAU8825_ADC_SINC4_EN,
NAU8825_ADC_SYNC_DOWN_64);
regmap_update_bits(regmap, NAU8825_REG_DAC_CTRL1,
NAU8825_DAC_OVERSAMPLE_MASK, NAU8825_DAC_OVERSAMPLE_64);
/* Disable DACR/L power */
regmap_update_bits(regmap, NAU8825_REG_CHARGE_PUMP,
NAU8825_POWER_DOWN_DACR | NAU8825_POWER_DOWN_DACL,
NAU8825_POWER_DOWN_DACR | NAU8825_POWER_DOWN_DACL);
/* Enable TESTDAC. This sets the analog DAC inputs to a '0' input
* signal to avoid any glitches due to power up transients in both
* the analog and digital DAC circuit.
*/
regmap_update_bits(nau8825->regmap, NAU8825_REG_BIAS_ADJ,
NAU8825_BIAS_TESTDAC_EN, NAU8825_BIAS_TESTDAC_EN);
/* CICCLP off */
regmap_update_bits(regmap, NAU8825_REG_DAC_CTRL1,
NAU8825_DAC_CLIP_OFF, NAU8825_DAC_CLIP_OFF);
/* Class AB bias current to 2x, DAC Capacitor enable MSB/LSB */
regmap_update_bits(regmap, NAU8825_REG_ANALOG_CONTROL_2,
NAU8825_HP_NON_CLASSG_CURRENT_2xADJ |
NAU8825_DAC_CAPACITOR_MSB | NAU8825_DAC_CAPACITOR_LSB,
NAU8825_HP_NON_CLASSG_CURRENT_2xADJ |
NAU8825_DAC_CAPACITOR_MSB | NAU8825_DAC_CAPACITOR_LSB);
/* Class G timer 64ms */
regmap_update_bits(regmap, NAU8825_REG_CLASSG_CTRL,
NAU8825_CLASSG_TIMER_MASK,
0x20 << NAU8825_CLASSG_TIMER_SFT);
/* DAC clock delay 2ns, VREF */
regmap_update_bits(regmap, NAU8825_REG_RDAC,
NAU8825_RDAC_CLK_DELAY_MASK | NAU8825_RDAC_VREF_MASK,
(0x2 << NAU8825_RDAC_CLK_DELAY_SFT) |
(0x3 << NAU8825_RDAC_VREF_SFT));
/* Config L/R channel */
regmap_update_bits(nau8825->regmap, NAU8825_REG_DACL_CTRL,
NAU8825_DACL_CH_SEL_MASK, NAU8825_DACL_CH_SEL_L);
regmap_update_bits(nau8825->regmap, NAU8825_REG_DACR_CTRL,
NAU8825_DACL_CH_SEL_MASK, NAU8825_DACL_CH_SEL_R);
/* Disable short Frame Sync detection logic */
regmap_update_bits(regmap, NAU8825_REG_LEFT_TIME_SLOT,
NAU8825_DIS_FS_SHORT_DET, NAU8825_DIS_FS_SHORT_DET);
}
static const struct regmap_config nau8825_regmap_config = {
.val_bits = NAU8825_REG_DATA_LEN,
.reg_bits = NAU8825_REG_ADDR_LEN,
.max_register = NAU8825_REG_MAX,
.readable_reg = nau8825_readable_reg,
.writeable_reg = nau8825_writeable_reg,
.volatile_reg = nau8825_volatile_reg,
.cache_type = REGCACHE_RBTREE,
.reg_defaults = nau8825_reg_defaults,
.num_reg_defaults = ARRAY_SIZE(nau8825_reg_defaults),
};
static int nau8825_component_probe(struct snd_soc_component *component)
{
struct nau8825 *nau8825 = snd_soc_component_get_drvdata(component);
struct snd_soc_dapm_context *dapm = snd_soc_component_get_dapm(component);
nau8825->dapm = dapm;
return 0;
}
static void nau8825_component_remove(struct snd_soc_component *component)
{
struct nau8825 *nau8825 = snd_soc_component_get_drvdata(component);
/* Cancel and reset cross tak suppresstion detection funciton */
nau8825_xtalk_cancel(nau8825);
}
/**
* nau8825_calc_fll_param - Calculate FLL parameters.
* @fll_in: external clock provided to codec.
* @fs: sampling rate.
* @fll_param: Pointer to structure of FLL parameters.
*
* Calculate FLL parameters to configure codec.
*
* Returns 0 for success or negative error code.
*/
static int nau8825_calc_fll_param(unsigned int fll_in, unsigned int fs,
struct nau8825_fll *fll_param)
{
u64 fvco, fvco_max;
unsigned int fref, i, fvco_sel;
/* Ensure the reference clock frequency (FREF) is <= 13.5MHz by dividing
* freq_in by 1, 2, 4, or 8 using FLL pre-scalar.
* FREF = freq_in / NAU8825_FLL_REF_DIV_MASK
*/
for (i = 0; i < ARRAY_SIZE(fll_pre_scalar); i++) {
fref = fll_in / fll_pre_scalar[i].param;
if (fref <= NAU_FREF_MAX)
break;
}
if (i == ARRAY_SIZE(fll_pre_scalar))
return -EINVAL;
fll_param->clk_ref_div = fll_pre_scalar[i].val;
/* Choose the FLL ratio based on FREF */
for (i = 0; i < ARRAY_SIZE(fll_ratio); i++) {
if (fref >= fll_ratio[i].param)
break;
}
if (i == ARRAY_SIZE(fll_ratio))
return -EINVAL;
fll_param->ratio = fll_ratio[i].val;
/* Calculate the frequency of DCO (FDCO) given freq_out = 256 * Fs.
* FDCO must be within the 90MHz - 124MHz or the FFL cannot be
* guaranteed across the full range of operation.
* FDCO = freq_out * 2 * mclk_src_scaling
*/
fvco_max = 0;
fvco_sel = ARRAY_SIZE(mclk_src_scaling);
for (i = 0; i < ARRAY_SIZE(mclk_src_scaling); i++) {
fvco = 256ULL * fs * 2 * mclk_src_scaling[i].param;
if (fvco > NAU_FVCO_MIN && fvco < NAU_FVCO_MAX &&
fvco_max < fvco) {
fvco_max = fvco;
fvco_sel = i;
}
}
if (ARRAY_SIZE(mclk_src_scaling) == fvco_sel)
return -EINVAL;
fll_param->mclk_src = mclk_src_scaling[fvco_sel].val;
/* Calculate the FLL 10-bit integer input and the FLL 16-bit fractional
* input based on FDCO, FREF and FLL ratio.
*/
fvco = div_u64(fvco_max << 16, fref * fll_param->ratio);
fll_param->fll_int = (fvco >> 16) & 0x3FF;
fll_param->fll_frac = fvco & 0xFFFF;
return 0;
}
static void nau8825_fll_apply(struct nau8825 *nau8825,
struct nau8825_fll *fll_param)
{
regmap_update_bits(nau8825->regmap, NAU8825_REG_CLK_DIVIDER,
NAU8825_CLK_SRC_MASK | NAU8825_CLK_MCLK_SRC_MASK,
NAU8825_CLK_SRC_MCLK | fll_param->mclk_src);
/* Make DSP operate at high speed for better performance. */
regmap_update_bits(nau8825->regmap, NAU8825_REG_FLL1,
NAU8825_FLL_RATIO_MASK | NAU8825_ICTRL_LATCH_MASK,
fll_param->ratio | (0x6 << NAU8825_ICTRL_LATCH_SFT));
/* FLL 16-bit fractional input */
regmap_write(nau8825->regmap, NAU8825_REG_FLL2, fll_param->fll_frac);
/* FLL 10-bit integer input */
regmap_update_bits(nau8825->regmap, NAU8825_REG_FLL3,
NAU8825_FLL_INTEGER_MASK, fll_param->fll_int);
/* FLL pre-scaler */
regmap_update_bits(nau8825->regmap, NAU8825_REG_FLL4,
NAU8825_FLL_REF_DIV_MASK,
fll_param->clk_ref_div << NAU8825_FLL_REF_DIV_SFT);
/* select divided VCO input */
regmap_update_bits(nau8825->regmap, NAU8825_REG_FLL5,
NAU8825_FLL_CLK_SW_MASK, NAU8825_FLL_CLK_SW_REF);
/* Disable free-running mode */
regmap_update_bits(nau8825->regmap,
NAU8825_REG_FLL6, NAU8825_DCO_EN, 0);
if (fll_param->fll_frac) {
/* set FLL loop filter enable and cutoff frequency at 500Khz */
regmap_update_bits(nau8825->regmap, NAU8825_REG_FLL5,
NAU8825_FLL_PDB_DAC_EN | NAU8825_FLL_LOOP_FTR_EN |
NAU8825_FLL_FTR_SW_MASK,
NAU8825_FLL_PDB_DAC_EN | NAU8825_FLL_LOOP_FTR_EN |
NAU8825_FLL_FTR_SW_FILTER);
regmap_update_bits(nau8825->regmap, NAU8825_REG_FLL6,
NAU8825_SDM_EN | NAU8825_CUTOFF500,
NAU8825_SDM_EN | NAU8825_CUTOFF500);
} else {
/* disable FLL loop filter and cutoff frequency */
regmap_update_bits(nau8825->regmap, NAU8825_REG_FLL5,
NAU8825_FLL_PDB_DAC_EN | NAU8825_FLL_LOOP_FTR_EN |
NAU8825_FLL_FTR_SW_MASK, NAU8825_FLL_FTR_SW_ACCU);
regmap_update_bits(nau8825->regmap, NAU8825_REG_FLL6,
NAU8825_SDM_EN | NAU8825_CUTOFF500, 0);
}
}
/* freq_out must be 256*Fs in order to achieve the best performance */
static int nau8825_set_pll(struct snd_soc_component *component, int pll_id, int source,
unsigned int freq_in, unsigned int freq_out)
{
struct nau8825 *nau8825 = snd_soc_component_get_drvdata(component);
struct nau8825_fll fll_param;
int ret, fs;
fs = freq_out / 256;
ret = nau8825_calc_fll_param(freq_in, fs, &fll_param);
if (ret < 0) {
dev_err(component->dev, "Unsupported input clock %d\n", freq_in);
return ret;
}
dev_dbg(component->dev, "mclk_src=%x ratio=%x fll_frac=%x fll_int=%x clk_ref_div=%x\n",
fll_param.mclk_src, fll_param.ratio, fll_param.fll_frac,
fll_param.fll_int, fll_param.clk_ref_div);
nau8825_fll_apply(nau8825, &fll_param);
mdelay(2);
regmap_update_bits(nau8825->regmap, NAU8825_REG_CLK_DIVIDER,
NAU8825_CLK_SRC_MASK, NAU8825_CLK_SRC_VCO);
return 0;
}
static int nau8825_mclk_prepare(struct nau8825 *nau8825, unsigned int freq)
{
int ret;
nau8825->mclk = devm_clk_get(nau8825->dev, "mclk");
if (IS_ERR(nau8825->mclk)) {
dev_info(nau8825->dev, "No 'mclk' clock found, assume MCLK is managed externally");
return 0;
}
if (!nau8825->mclk_freq) {
ret = clk_prepare_enable(nau8825->mclk);
if (ret) {
dev_err(nau8825->dev, "Unable to prepare codec mclk\n");
return ret;
}
}
if (nau8825->mclk_freq != freq) {
freq = clk_round_rate(nau8825->mclk, freq);
ret = clk_set_rate(nau8825->mclk, freq);
if (ret) {
dev_err(nau8825->dev, "Unable to set mclk rate\n");
return ret;
}
nau8825->mclk_freq = freq;
}
return 0;
}
static void nau8825_configure_mclk_as_sysclk(struct regmap *regmap)
{
regmap_update_bits(regmap, NAU8825_REG_CLK_DIVIDER,
NAU8825_CLK_SRC_MASK, NAU8825_CLK_SRC_MCLK);
regmap_update_bits(regmap, NAU8825_REG_FLL6,
NAU8825_DCO_EN, 0);
/* Make DSP operate as default setting for power saving. */
regmap_update_bits(regmap, NAU8825_REG_FLL1,
NAU8825_ICTRL_LATCH_MASK, 0);
}
static int nau8825_configure_sysclk(struct nau8825 *nau8825, int clk_id,
unsigned int freq)
{
struct regmap *regmap = nau8825->regmap;
int ret;
switch (clk_id) {
case NAU8825_CLK_DIS:
/* Clock provided externally and disable internal VCO clock */
nau8825_configure_mclk_as_sysclk(regmap);
if (nau8825->mclk_freq) {
clk_disable_unprepare(nau8825->mclk);
nau8825->mclk_freq = 0;
}
break;
case NAU8825_CLK_MCLK:
/* Acquire the semaphore to synchronize the playback and
* interrupt handler. In order to avoid the playback inter-
* fered by cross talk process, the driver make the playback
* preparation halted until cross talk process finish.
*/
nau8825_sema_acquire(nau8825, 3 * HZ);
nau8825_configure_mclk_as_sysclk(regmap);
/* MCLK not changed by clock tree */
regmap_update_bits(regmap, NAU8825_REG_CLK_DIVIDER,
NAU8825_CLK_MCLK_SRC_MASK, 0);
/* Release the semaphore. */
nau8825_sema_release(nau8825);
ret = nau8825_mclk_prepare(nau8825, freq);
if (ret)
return ret;
break;
case NAU8825_CLK_INTERNAL:
if (nau8825_is_jack_inserted(nau8825->regmap)) {
regmap_update_bits(regmap, NAU8825_REG_FLL6,
NAU8825_DCO_EN, NAU8825_DCO_EN);
regmap_update_bits(regmap, NAU8825_REG_CLK_DIVIDER,
NAU8825_CLK_SRC_MASK, NAU8825_CLK_SRC_VCO);
/* Decrease the VCO frequency and make DSP operate
* as default setting for power saving.
*/
regmap_update_bits(regmap, NAU8825_REG_CLK_DIVIDER,
NAU8825_CLK_MCLK_SRC_MASK, 0xf);
regmap_update_bits(regmap, NAU8825_REG_FLL1,
NAU8825_ICTRL_LATCH_MASK |
NAU8825_FLL_RATIO_MASK, 0x10);
regmap_update_bits(regmap, NAU8825_REG_FLL6,
NAU8825_SDM_EN, NAU8825_SDM_EN);
} else {
/* The clock turns off intentionally for power saving
* when no headset connected.
*/
nau8825_configure_mclk_as_sysclk(regmap);
dev_warn(nau8825->dev, "Disable clock for power saving when no headset connected\n");
}
if (nau8825->mclk_freq) {
clk_disable_unprepare(nau8825->mclk);
nau8825->mclk_freq = 0;
}
break;
case NAU8825_CLK_FLL_MCLK:
/* Acquire the semaphore to synchronize the playback and
* interrupt handler. In order to avoid the playback inter-
* fered by cross talk process, the driver make the playback
* preparation halted until cross talk process finish.
*/
nau8825_sema_acquire(nau8825, 3 * HZ);
/* Higher FLL reference input frequency can only set lower
* gain error, such as 0000 for input reference from MCLK
* 12.288Mhz.
*/
regmap_update_bits(regmap, NAU8825_REG_FLL3,
NAU8825_FLL_CLK_SRC_MASK | NAU8825_GAIN_ERR_MASK,
NAU8825_FLL_CLK_SRC_MCLK | 0);
/* Release the semaphore. */
nau8825_sema_release(nau8825);
ret = nau8825_mclk_prepare(nau8825, freq);
if (ret)
return ret;
break;
case NAU8825_CLK_FLL_BLK:
/* Acquire the semaphore to synchronize the playback and
* interrupt handler. In order to avoid the playback inter-
* fered by cross talk process, the driver make the playback
* preparation halted until cross talk process finish.
*/
nau8825_sema_acquire(nau8825, 3 * HZ);
/* If FLL reference input is from low frequency source,
* higher error gain can apply such as 0xf which has
* the most sensitive gain error correction threshold,
* Therefore, FLL has the most accurate DCO to
* target frequency.
*/
regmap_update_bits(regmap, NAU8825_REG_FLL3,
NAU8825_FLL_CLK_SRC_MASK | NAU8825_GAIN_ERR_MASK,
NAU8825_FLL_CLK_SRC_BLK |
(0xf << NAU8825_GAIN_ERR_SFT));
/* Release the semaphore. */
nau8825_sema_release(nau8825);
if (nau8825->mclk_freq) {
clk_disable_unprepare(nau8825->mclk);
nau8825->mclk_freq = 0;
}
break;
case NAU8825_CLK_FLL_FS:
/* Acquire the semaphore to synchronize the playback and
* interrupt handler. In order to avoid the playback inter-
* fered by cross talk process, the driver make the playback
* preparation halted until cross talk process finish.
*/
nau8825_sema_acquire(nau8825, 3 * HZ);
/* If FLL reference input is from low frequency source,
* higher error gain can apply such as 0xf which has
* the most sensitive gain error correction threshold,
* Therefore, FLL has the most accurate DCO to
* target frequency.
*/
regmap_update_bits(regmap, NAU8825_REG_FLL3,
NAU8825_FLL_CLK_SRC_MASK | NAU8825_GAIN_ERR_MASK,
NAU8825_FLL_CLK_SRC_FS |
(0xf << NAU8825_GAIN_ERR_SFT));
/* Release the semaphore. */
nau8825_sema_release(nau8825);
if (nau8825->mclk_freq) {
clk_disable_unprepare(nau8825->mclk);
nau8825->mclk_freq = 0;
}
break;
default:
dev_err(nau8825->dev, "Invalid clock id (%d)\n", clk_id);
return -EINVAL;
}
dev_dbg(nau8825->dev, "Sysclk is %dHz and clock id is %d\n", freq,
clk_id);
return 0;
}
static int nau8825_set_sysclk(struct snd_soc_component *component, int clk_id,
int source, unsigned int freq, int dir)
{
struct nau8825 *nau8825 = snd_soc_component_get_drvdata(component);
return nau8825_configure_sysclk(nau8825, clk_id, freq);
}
static int nau8825_resume_setup(struct nau8825 *nau8825)
{
struct regmap *regmap = nau8825->regmap;
/* Close clock when jack type detection at manual mode */
nau8825_configure_sysclk(nau8825, NAU8825_CLK_DIS, 0);
/* Clear all interruption status */
nau8825_int_status_clear_all(regmap);
/* Enable both insertion and ejection interruptions, and then
* bypass de-bounce circuit.
*/
regmap_update_bits(regmap, NAU8825_REG_INTERRUPT_MASK,
NAU8825_IRQ_OUTPUT_EN | NAU8825_IRQ_HEADSET_COMPLETE_EN |
NAU8825_IRQ_EJECT_EN | NAU8825_IRQ_INSERT_EN,
NAU8825_IRQ_OUTPUT_EN | NAU8825_IRQ_HEADSET_COMPLETE_EN);
regmap_update_bits(regmap, NAU8825_REG_JACK_DET_CTRL,
NAU8825_JACK_DET_DB_BYPASS, NAU8825_JACK_DET_DB_BYPASS);
regmap_update_bits(regmap, NAU8825_REG_INTERRUPT_DIS_CTRL,
NAU8825_IRQ_INSERT_DIS | NAU8825_IRQ_EJECT_DIS, 0);
return 0;
}
static int nau8825_set_bias_level(struct snd_soc_component *component,
enum snd_soc_bias_level level)
{
struct nau8825 *nau8825 = snd_soc_component_get_drvdata(component);
int ret;
switch (level) {
case SND_SOC_BIAS_ON:
break;
case SND_SOC_BIAS_PREPARE:
break;
case SND_SOC_BIAS_STANDBY:
if (snd_soc_component_get_bias_level(component) == SND_SOC_BIAS_OFF) {
if (nau8825->mclk_freq) {
ret = clk_prepare_enable(nau8825->mclk);
if (ret) {
dev_err(nau8825->dev, "Unable to prepare component mclk\n");
return ret;
}
}
/* Setup codec configuration after resume */
nau8825_resume_setup(nau8825);
}
break;
case SND_SOC_BIAS_OFF:
/* Reset the configuration of jack type for detection */
/* Detach 2kOhm Resistors from MICBIAS to MICGND1/2 */
regmap_update_bits(nau8825->regmap, NAU8825_REG_MIC_BIAS,
NAU8825_MICBIAS_JKSLV | NAU8825_MICBIAS_JKR2, 0);
/* ground HPL/HPR, MICGRND1/2 */
regmap_update_bits(nau8825->regmap,
NAU8825_REG_HSD_CTRL, 0xf, 0xf);
/* Cancel and reset cross talk detection funciton */
nau8825_xtalk_cancel(nau8825);
/* Turn off all interruptions before system shutdown. Keep the
* interruption quiet before resume setup completes.
*/
regmap_write(nau8825->regmap,
NAU8825_REG_INTERRUPT_DIS_CTRL, 0xffff);
/* Disable ADC needed for interruptions at audo mode */
regmap_update_bits(nau8825->regmap, NAU8825_REG_ENA_CTRL,
NAU8825_ENABLE_ADC, 0);
if (nau8825->mclk_freq)
clk_disable_unprepare(nau8825->mclk);
break;
}
return 0;
}
static int __maybe_unused nau8825_suspend(struct snd_soc_component *component)
{
struct nau8825 *nau8825 = snd_soc_component_get_drvdata(component);
disable_irq(nau8825->irq);
snd_soc_component_force_bias_level(component, SND_SOC_BIAS_OFF);
/* Power down codec power; don't suppoet button wakeup */
snd_soc_dapm_disable_pin(nau8825->dapm, "SAR");
snd_soc_dapm_disable_pin(nau8825->dapm, "MICBIAS");
snd_soc_dapm_sync(nau8825->dapm);
regcache_cache_only(nau8825->regmap, true);
regcache_mark_dirty(nau8825->regmap);
return 0;
}
static int __maybe_unused nau8825_resume(struct snd_soc_component *component)
{
struct nau8825 *nau8825 = snd_soc_component_get_drvdata(component);
int ret;
regcache_cache_only(nau8825->regmap, false);
regcache_sync(nau8825->regmap);
nau8825->xtalk_protect = true;
ret = nau8825_sema_acquire(nau8825, 0);
if (ret)
nau8825->xtalk_protect = false;
enable_irq(nau8825->irq);
return 0;
}
static int nau8825_set_jack(struct snd_soc_component *component,
struct snd_soc_jack *jack, void *data)
{
return nau8825_enable_jack_detect(component, jack);
}
static const struct snd_soc_component_driver nau8825_component_driver = {
.probe = nau8825_component_probe,
.remove = nau8825_component_remove,
.set_sysclk = nau8825_set_sysclk,
.set_pll = nau8825_set_pll,
.set_bias_level = nau8825_set_bias_level,
.suspend = nau8825_suspend,
.resume = nau8825_resume,
.controls = nau8825_controls,
.num_controls = ARRAY_SIZE(nau8825_controls),
.dapm_widgets = nau8825_dapm_widgets,
.num_dapm_widgets = ARRAY_SIZE(nau8825_dapm_widgets),
.dapm_routes = nau8825_dapm_routes,
.num_dapm_routes = ARRAY_SIZE(nau8825_dapm_routes),
.set_jack = nau8825_set_jack,
.suspend_bias_off = 1,
.idle_bias_on = 1,
.use_pmdown_time = 1,
.endianness = 1,
.non_legacy_dai_naming = 1,
};
static void nau8825_reset_chip(struct regmap *regmap)
{
regmap_write(regmap, NAU8825_REG_RESET, 0x00);
regmap_write(regmap, NAU8825_REG_RESET, 0x00);
}
static void nau8825_print_device_properties(struct nau8825 *nau8825)
{
int i;
struct device *dev = nau8825->dev;
dev_dbg(dev, "jkdet-enable: %d\n", nau8825->jkdet_enable);
dev_dbg(dev, "jkdet-pull-enable: %d\n", nau8825->jkdet_pull_enable);
dev_dbg(dev, "jkdet-pull-up: %d\n", nau8825->jkdet_pull_up);
dev_dbg(dev, "jkdet-polarity: %d\n", nau8825->jkdet_polarity);
dev_dbg(dev, "micbias-voltage: %d\n", nau8825->micbias_voltage);
dev_dbg(dev, "vref-impedance: %d\n", nau8825->vref_impedance);
dev_dbg(dev, "sar-threshold-num: %d\n", nau8825->sar_threshold_num);
for (i = 0; i < nau8825->sar_threshold_num; i++)
dev_dbg(dev, "sar-threshold[%d]=%d\n", i,
nau8825->sar_threshold[i]);
dev_dbg(dev, "sar-hysteresis: %d\n", nau8825->sar_hysteresis);
dev_dbg(dev, "sar-voltage: %d\n", nau8825->sar_voltage);
dev_dbg(dev, "sar-compare-time: %d\n", nau8825->sar_compare_time);
dev_dbg(dev, "sar-sampling-time: %d\n", nau8825->sar_sampling_time);
dev_dbg(dev, "short-key-debounce: %d\n", nau8825->key_debounce);
dev_dbg(dev, "jack-insert-debounce: %d\n",
nau8825->jack_insert_debounce);
dev_dbg(dev, "jack-eject-debounce: %d\n",
nau8825->jack_eject_debounce);
dev_dbg(dev, "crosstalk-enable: %d\n",
nau8825->xtalk_enable);
}
static int nau8825_read_device_properties(struct device *dev,
struct nau8825 *nau8825) {
int ret;
nau8825->jkdet_enable = device_property_read_bool(dev,
"nuvoton,jkdet-enable");
nau8825->jkdet_pull_enable = device_property_read_bool(dev,
"nuvoton,jkdet-pull-enable");
nau8825->jkdet_pull_up = device_property_read_bool(dev,
"nuvoton,jkdet-pull-up");
ret = device_property_read_u32(dev, "nuvoton,jkdet-polarity",
&nau8825->jkdet_polarity);
if (ret)
nau8825->jkdet_polarity = 1;
ret = device_property_read_u32(dev, "nuvoton,micbias-voltage",
&nau8825->micbias_voltage);
if (ret)
nau8825->micbias_voltage = 6;
ret = device_property_read_u32(dev, "nuvoton,vref-impedance",
&nau8825->vref_impedance);
if (ret)
nau8825->vref_impedance = 2;
ret = device_property_read_u32(dev, "nuvoton,sar-threshold-num",
&nau8825->sar_threshold_num);
if (ret)
nau8825->sar_threshold_num = 4;
ret = device_property_read_u32_array(dev, "nuvoton,sar-threshold",
nau8825->sar_threshold, nau8825->sar_threshold_num);
if (ret) {
nau8825->sar_threshold[0] = 0x08;
nau8825->sar_threshold[1] = 0x12;
nau8825->sar_threshold[2] = 0x26;
nau8825->sar_threshold[3] = 0x73;
}
ret = device_property_read_u32(dev, "nuvoton,sar-hysteresis",
&nau8825->sar_hysteresis);
if (ret)
nau8825->sar_hysteresis = 0;
ret = device_property_read_u32(dev, "nuvoton,sar-voltage",
&nau8825->sar_voltage);
if (ret)
nau8825->sar_voltage = 6;
ret = device_property_read_u32(dev, "nuvoton,sar-compare-time",
&nau8825->sar_compare_time);
if (ret)
nau8825->sar_compare_time = 1;
ret = device_property_read_u32(dev, "nuvoton,sar-sampling-time",
&nau8825->sar_sampling_time);
if (ret)
nau8825->sar_sampling_time = 1;
ret = device_property_read_u32(dev, "nuvoton,short-key-debounce",
&nau8825->key_debounce);
if (ret)
nau8825->key_debounce = 3;
ret = device_property_read_u32(dev, "nuvoton,jack-insert-debounce",
&nau8825->jack_insert_debounce);
if (ret)
nau8825->jack_insert_debounce = 7;
ret = device_property_read_u32(dev, "nuvoton,jack-eject-debounce",
&nau8825->jack_eject_debounce);
if (ret)
nau8825->jack_eject_debounce = 0;
nau8825->xtalk_enable = device_property_read_bool(dev,
"nuvoton,crosstalk-enable");
nau8825->mclk = devm_clk_get(dev, "mclk");
if (PTR_ERR(nau8825->mclk) == -EPROBE_DEFER) {
return -EPROBE_DEFER;
} else if (PTR_ERR(nau8825->mclk) == -ENOENT) {
/* The MCLK is managed externally or not used at all */
nau8825->mclk = NULL;
dev_info(dev, "No 'mclk' clock found, assume MCLK is managed externally");
} else if (IS_ERR(nau8825->mclk)) {
return -EINVAL;
}
return 0;
}
static int nau8825_setup_irq(struct nau8825 *nau8825)
{
int ret;
ret = devm_request_threaded_irq(nau8825->dev, nau8825->irq, NULL,
nau8825_interrupt, IRQF_TRIGGER_LOW | IRQF_ONESHOT,
"nau8825", nau8825);
if (ret) {
dev_err(nau8825->dev, "Cannot request irq %d (%d)\n",
nau8825->irq, ret);
return ret;
}
return 0;
}
static int nau8825_i2c_probe(struct i2c_client *i2c,
const struct i2c_device_id *id)
{
struct device *dev = &i2c->dev;
struct nau8825 *nau8825 = dev_get_platdata(&i2c->dev);
int ret, value;
if (!nau8825) {
nau8825 = devm_kzalloc(dev, sizeof(*nau8825), GFP_KERNEL);
if (!nau8825)
return -ENOMEM;
ret = nau8825_read_device_properties(dev, nau8825);
if (ret)
return ret;
}
i2c_set_clientdata(i2c, nau8825);
nau8825->regmap = devm_regmap_init_i2c(i2c, &nau8825_regmap_config);
if (IS_ERR(nau8825->regmap))
return PTR_ERR(nau8825->regmap);
nau8825->dev = dev;
nau8825->irq = i2c->irq;
/* Initiate parameters, semaphore and work queue which are needed in
* cross talk suppression measurment function.
*/
nau8825->xtalk_state = NAU8825_XTALK_DONE;
nau8825->xtalk_protect = false;
nau8825->xtalk_baktab_initialized = false;
sema_init(&nau8825->xtalk_sem, 1);
INIT_WORK(&nau8825->xtalk_work, nau8825_xtalk_work);
nau8825_print_device_properties(nau8825);
nau8825_reset_chip(nau8825->regmap);
ret = regmap_read(nau8825->regmap, NAU8825_REG_I2C_DEVICE_ID, &value);
if (ret < 0) {
dev_err(dev, "Failed to read device id from the NAU8825: %d\n",
ret);
return ret;
}
if ((value & NAU8825_SOFTWARE_ID_MASK) !=
NAU8825_SOFTWARE_ID_NAU8825) {
dev_err(dev, "Not a NAU8825 chip\n");
return -ENODEV;
}
nau8825_init_regs(nau8825);
if (i2c->irq)
nau8825_setup_irq(nau8825);
return devm_snd_soc_register_component(&i2c->dev,
&nau8825_component_driver,
&nau8825_dai, 1);
}
static int nau8825_i2c_remove(struct i2c_client *client)
{
return 0;
}
static const struct i2c_device_id nau8825_i2c_ids[] = {
{ "nau8825", 0 },
{ }
};
MODULE_DEVICE_TABLE(i2c, nau8825_i2c_ids);
#ifdef CONFIG_OF
static const struct of_device_id nau8825_of_ids[] = {
{ .compatible = "nuvoton,nau8825", },
{}
};
MODULE_DEVICE_TABLE(of, nau8825_of_ids);
#endif
#ifdef CONFIG_ACPI
static const struct acpi_device_id nau8825_acpi_match[] = {
{ "10508825", 0 },
{},
};
MODULE_DEVICE_TABLE(acpi, nau8825_acpi_match);
#endif
static struct i2c_driver nau8825_driver = {
.driver = {
.name = "nau8825",
.of_match_table = of_match_ptr(nau8825_of_ids),
.acpi_match_table = ACPI_PTR(nau8825_acpi_match),
},
.probe = nau8825_i2c_probe,
.remove = nau8825_i2c_remove,
.id_table = nau8825_i2c_ids,
};
module_i2c_driver(nau8825_driver);
MODULE_DESCRIPTION("ASoC nau8825 driver");
MODULE_AUTHOR("Anatol Pomozov <anatol@chromium.org>");
MODULE_LICENSE("GPL");