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pigweed / third_party / github / zephyrproject-rtos / zephyr / dab93222dac6e4c7344dbfc44e0abe21f34d0eba / . / drivers / dai / intel / dmic / dmic_nhlt.c
blob: c7fe48e1432da79d5f633127650065591bc507c9 [file] [log] [blame]
/*
* Copyright (c) 2022 Intel Corporation.
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <stdint.h>
#include <errno.h>
#include <zephyr/spinlock.h>
#define LOG_DOMAIN dai_intel_dmic_nhlt
#include <zephyr/logging/log.h>
LOG_MODULE_REGISTER(LOG_DOMAIN);
#include <zephyr/drivers/dai.h>
#include <adsp_clk.h>
#include "dmic.h"
#include <dmic_regs.h>
#include "dmic_nhlt.h"
extern struct dai_dmic_global_shared dai_dmic_global;
/* Base addresses (in PDM scope) of 2ch PDM controllers and coefficient RAM. */
static const uint32_t dmic_base[4] = {PDM0, PDM1, PDM2, PDM3};
static inline void dai_dmic_write(const struct dai_intel_dmic *dmic,
uint32_t reg, uint32_t val)
{
sys_write32(val, dmic->reg_base + reg);
}
static inline uint32_t dai_dmic_read(const struct dai_intel_dmic *dmic, uint32_t reg)
{
return sys_read32(dmic->reg_base + reg);
}
/*
* @brief Move pointer to next coefficient data
*
* @return Returns pointer right after coefficient data
*/
static const uint32_t *dai_dmic_skip_coeff(const uint32_t *coeff, const int length,
const bool packed)
{
if (!packed) {
coeff += length;
} else {
coeff += ROUND_UP(3 * length, sizeof(uint32_t)) / sizeof(uint32_t);
}
return coeff;
}
/*
* @brief Write the fir coefficients in the PDMs' RAM
*/
static void dai_dmic_write_coeff(const struct dai_intel_dmic *dmic, uint32_t base,
const uint32_t *coeff, int length, const bool packed)
{
const uint8_t *coeff_in_bytes;
uint32_t coeff_val;
if (!packed) {
while (length--) {
dai_dmic_write(dmic, base, *coeff++);
base += sizeof(uint32_t);
}
} else {
coeff_in_bytes = (const uint8_t *)coeff;
while (length--) {
coeff_val = coeff_in_bytes[0] +
(coeff_in_bytes[1] << 8) +
(coeff_in_bytes[2] << 16);
dai_dmic_write(dmic, base, coeff_val);
base += sizeof(uint32_t);
coeff_in_bytes += 3;
}
}
}
/*
* @brief Configures the fir coefficients in the PDMs' RAM
*
* @return Returns pointer right after coefficients data
*/
static const uint32_t *dai_dmic_configure_coeff(const struct dai_intel_dmic *dmic,
const struct nhlt_pdm_ctrl_cfg * const pdm_cfg,
const uint32_t pdm_base,
const uint32_t *coeffs)
{
int fir_length_a, fir_length_b;
bool packed = false;
const uint32_t *coeffs_b;
fir_length_a = FIELD_GET(FIR_CONFIG_FIR_LENGTH, pdm_cfg->fir_config[0].fir_config) + 1;
fir_length_b = FIELD_GET(FIR_CONFIG_FIR_LENGTH, pdm_cfg->fir_config[1].fir_config) + 1;
if (fir_length_a > 256 || fir_length_b > 256) {
LOG_ERR("invalid coeff length! %d %d", fir_length_a, fir_length_b);
return NULL;
}
if (*coeffs == FIR_COEFFS_PACKED_TO_24_BITS) {
packed = true;
/* First dword is not included into length_0 and length_1 - skip it. */
coeffs++;
}
coeffs_b = dai_dmic_skip_coeff(coeffs, fir_length_a, packed);
LOG_INF("fir_length_a = %d, fir_length_b = %d, packed = %d", fir_length_a, fir_length_b,
packed);
if (dmic->dai_config_params.dai_index == 0) {
dai_dmic_write_coeff(dmic, pdm_base + PDM_COEFFICIENT_A, coeffs, fir_length_a,
packed);
} else {
dai_dmic_write_coeff(dmic, pdm_base + PDM_COEFFICIENT_B, coeffs_b, fir_length_b,
packed);
}
return dai_dmic_skip_coeff(coeffs_b, fir_length_b, packed);
}
static int dai_nhlt_get_clock_div(const struct dai_intel_dmic *dmic, const int pdm)
{
uint32_t val;
int p_mcic, p_clkdiv, p_mfir, rate_div;
val = dai_dmic_read(dmic, dmic_base[pdm] + CIC_CONFIG);
p_mcic = FIELD_GET(CIC_CONFIG_COMB_COUNT, val) + 1;
val = dai_dmic_read(dmic, dmic_base[pdm] + MIC_CONTROL);
p_clkdiv = FIELD_GET(MIC_CONTROL_PDM_CLKDIV, val) + 2;
val = dai_dmic_read(dmic, dmic_base[pdm] +
FIR_CHANNEL_REGS_SIZE * dmic->dai_config_params.dai_index + FIR_CONFIG);
LOG_INF("pdm = %d, FIR_CONFIG = 0x%08X", pdm, val);
p_mfir = FIELD_GET(FIR_CONFIG_FIR_DECIMATION, val) + 1;
rate_div = p_clkdiv * p_mcic * p_mfir;
LOG_INF("dai_index = %d, rate_div = %d, p_clkdiv = %d, p_mcic = %d, p_mfir = %d",
dmic->dai_config_params.dai_index, rate_div, p_clkdiv, p_mcic, p_mfir);
if (!rate_div) {
LOG_ERR("zero clock divide or decimation factor");
return -EINVAL;
}
return rate_div;
}
static int dai_nhlt_update_rate(struct dai_intel_dmic *dmic, const int clock_source, const int pdm)
{
int rate_div;
rate_div = dai_nhlt_get_clock_div(dmic, pdm);
if (rate_div < 0) {
return rate_div;
}
dmic->dai_config_params.rate = adsp_clock_source_frequency(clock_source) /
rate_div;
LOG_INF("rate = %d, channels = %d, format = %d",
dmic->dai_config_params.rate, dmic->dai_config_params.channels,
dmic->dai_config_params.format);
LOG_INF("io_clk %u, rate_div %d", adsp_clock_source_frequency(clock_source), rate_div);
return 0;
}
#ifdef CONFIG_SOC_SERIES_INTEL_ADSP_ACE
static int dai_ipm_source_to_enable(struct dai_intel_dmic *dmic,
int *count, int pdm_count, int stereo,
int source_pdm)
{
int mic_swap;
if (source_pdm >= CONFIG_DAI_DMIC_HW_CONTROLLERS)
return -EINVAL;
if (*count < pdm_count) {
(*count)++;
mic_swap = FIELD_GET(MIC_CONTROL_CLK_EDGE, dai_dmic_read(
dmic, dmic_base[source_pdm] + MIC_CONTROL));
if (stereo)
dmic->enable[source_pdm] = 0x3; /* PDMi MIC A and B */
else
dmic->enable[source_pdm] = mic_swap ? 0x2 : 0x1; /* PDMi MIC B or MIC A */
}
return 0;
}
static int dai_nhlt_dmic_dai_params_get(struct dai_intel_dmic *dmic, const int clock_source)
{
bool stereo_pdm;
int source_pdm;
int first_pdm;
int num_pdm;
int ret;
int n;
uint32_t outcontrol_val = dai_dmic_read(dmic, dmic->dai_config_params.dai_index *
PDM_CHANNEL_REGS_SIZE + OUTCONTROL);
switch (FIELD_GET(OUTCONTROL_OF, outcontrol_val)) {
case 0:
case 1:
dmic->dai_config_params.format = DAI_DMIC_FRAME_S16_LE;
dmic->dai_config_params.word_size = 16;
break;
case 2:
dmic->dai_config_params.format = DAI_DMIC_FRAME_S32_LE;
dmic->dai_config_params.word_size = 32;
break;
default:
LOG_ERR("nhlt_dmic_dai_params_get(): Illegal OF bit field");
return -EINVAL;
}
num_pdm = FIELD_GET(OUTCONTROL_IPM, outcontrol_val);
if (num_pdm > CONFIG_DAI_DMIC_HW_CONTROLLERS) {
LOG_ERR("nhlt_dmic_dai_params_get(): Illegal IPM PDM controllers count %d",
num_pdm);
return -EINVAL;
}
stereo_pdm = FIELD_GET(OUTCONTROL_IPM_SOURCE_MODE, outcontrol_val);
dmic->dai_config_params.channels = (stereo_pdm + 1) * num_pdm;
for (n = 0; n < CONFIG_DAI_DMIC_HW_CONTROLLERS; n++)
dmic->enable[n] = 0;
n = 0;
source_pdm = FIELD_GET(OUTCONTROL_IPM_SOURCE_1, outcontrol_val);
first_pdm = source_pdm;
ret = dai_ipm_source_to_enable(dmic, &n, num_pdm, stereo_pdm, source_pdm);
if (ret) {
LOG_ERR("nhlt_dmic_dai_params_get(): Illegal IPM_SOURCE_1");
return -EINVAL;
}
source_pdm = FIELD_GET(OUTCONTROL_IPM_SOURCE_2, outcontrol_val);
ret = dai_ipm_source_to_enable(dmic, &n, num_pdm, stereo_pdm, source_pdm);
if (ret) {
LOG_ERR("nhlt_dmic_dai_params_get(): Illegal IPM_SOURCE_2");
return -EINVAL;
}
source_pdm = FIELD_GET(OUTCONTROL_IPM_SOURCE_3, outcontrol_val);
ret = dai_ipm_source_to_enable(dmic, &n, num_pdm, stereo_pdm, source_pdm);
if (ret) {
LOG_ERR("nhlt_dmic_dai_params_get(): Illegal IPM_SOURCE_3");
return -EINVAL;
}
source_pdm = FIELD_GET(OUTCONTROL_IPM_SOURCE_4, outcontrol_val);
ret = dai_ipm_source_to_enable(dmic, &n, num_pdm, stereo_pdm, source_pdm);
if (ret) {
LOG_ERR("nhlt_dmic_dai_params_get(): Illegal IPM_SOURCE_4");
return -EINVAL;
}
return dai_nhlt_update_rate(dmic, clock_source, first_pdm);
}
/*
* @brief Set clock source used by device
*
* @param source Clock source index
*/
static inline void dai_dmic_clock_select_set(const struct dai_intel_dmic *dmic, uint32_t source)
{
uint32_t val;
#ifdef CONFIG_SOC_INTEL_ACE20_LNL /* Ace 2.0 */
val = sys_read32(dmic->vshim_base + DMICLVSCTL_OFFSET);
val &= ~DMICLVSCTL_MLCS;
val |= FIELD_PREP(DMICLVSCTL_MLCS, source);
sys_write32(val, dmic->vshim_base + DMICLVSCTL_OFFSET);
#else
val = sys_read32(dmic->shim_base + DMICLCTL_OFFSET);
val &= ~DMICLCTL_MLCS;
val |= FIELD_PREP(DMICLCTL_MLCS, source);
sys_write32(val, dmic->shim_base + DMICLCTL_OFFSET);
#endif
}
/*
* @brief Get clock source used by device
*
* @return Clock source index
*/
static inline uint32_t dai_dmic_clock_select_get(const struct dai_intel_dmic *dmic)
{
uint32_t val;
#ifdef CONFIG_SOC_INTEL_ACE20_LNL /* Ace 2.0 */
val = sys_read32(dmic->vshim_base + DMICLVSCTL_OFFSET);
return FIELD_GET(DMICLVSCTL_MLCS, val);
#else
val = sys_read32(dmic->shim_base + DMICLCTL_OFFSET);
return FIELD_GET(DMICLCTL_MLCS, val);
#endif
}
/*
* @brief Set clock source used by device
*
* @param source Clock source index
*/
static int dai_dmic_set_clock(const struct dai_intel_dmic *dmic, const uint8_t clock_source)
{
LOG_DBG("%s(): clock_source = %u", __func__, clock_source);
if (!adsp_clock_source_is_supported(clock_source)) {
return -ENOTSUP;
}
#ifndef CONFIG_SOC_INTEL_ACE20_LNL /* Ace 2.0 */
if (clock_source && !(sys_read32(dmic->shim_base + DMICLCAP_OFFSET) & DMICLCAP_MLCS)) {
return -ENOTSUP;
}
#endif
dai_dmic_clock_select_set(dmic, clock_source);
return 0;
}
#else
static int dai_nhlt_dmic_dai_params_get(struct dai_intel_dmic *dmic)
{
uint32_t outcontrol;
uint32_t fir_control[2];
uint32_t mic_control[2];
int fir_stereo[2];
int mic_swap;
outcontrol = dai_dmic_read(dmic, dmic->dai_config_params.dai_index * PDM_CHANNEL_REGS_SIZE +
OUTCONTROL);
switch (FIELD_GET(OUTCONTROL_OF, outcontrol)) {
case 0:
case 1:
dmic->dai_config_params.format = DAI_DMIC_FRAME_S16_LE;
break;
case 2:
dmic->dai_config_params.format = DAI_DMIC_FRAME_S32_LE;
break;
default:
LOG_ERR("Illegal OF bit field");
return -EINVAL;
}
fir_control[0] = dai_dmic_read(dmic, dmic_base[0] +
dmic->dai_config_params.dai_index * FIR_CHANNEL_REGS_SIZE +
FIR_CONTROL);
fir_control[1] = dai_dmic_read(dmic, dmic_base[1] +
dmic->dai_config_params.dai_index * FIR_CHANNEL_REGS_SIZE +
FIR_CONTROL);
mic_control[0] = dai_dmic_read(dmic, dmic_base[0] + MIC_CONTROL);
mic_control[1] = dai_dmic_read(dmic, dmic_base[1] + MIC_CONTROL);
switch (FIELD_GET(OUTCONTROL_IPM, outcontrol)) {
case 0:
fir_stereo[0] = FIELD_GET(FIR_CONTROL_STEREO, fir_control[0]);
if (fir_stereo[0]) {
dmic->dai_config_params.channels = 2;
dmic->enable[0] = 0x3; /* PDM0 MIC A and B */
dmic->enable[1] = 0x0; /* PDM1 none */
} else {
dmic->dai_config_params.channels = 1;
mic_swap = FIELD_GET(MIC_CONTROL_CLK_EDGE, mic_control[0]);
dmic->enable[0] = mic_swap ? 0x2 : 0x1; /* PDM0 MIC B or MIC A */
dmic->enable[1] = 0x0; /* PDM1 */
}
break;
case 1:
fir_stereo[1] = FIELD_GET(FIR_CONTROL_STEREO, fir_control[1]);
if (fir_stereo[1]) {
dmic->dai_config_params.channels = 2;
dmic->enable[0] = 0x0; /* PDM0 none */
dmic->enable[1] = 0x3; /* PDM1 MIC A and B */
} else {
dmic->dai_config_params.channels = 1;
dmic->enable[0] = 0x0; /* PDM0 none */
mic_swap = FIELD_GET(MIC_CONTROL_CLK_EDGE, mic_control[1]);
dmic->enable[1] = mic_swap ? 0x2 : 0x1; /* PDM1 MIC B or MIC A */
}
break;
case 2:
fir_stereo[0] = FIELD_GET(FIR_CONTROL_STEREO, fir_control[0]);
fir_stereo[1] = FIELD_GET(FIR_CONTROL_STEREO, fir_control[1]);
if (fir_stereo[0] == fir_stereo[1]) {
dmic->dai_config_params.channels = 4;
dmic->enable[0] = 0x3; /* PDM0 MIC A and B */
dmic->enable[1] = 0x3; /* PDM1 MIC A and B */
LOG_INF("set 4ch pdm0 and pdm1");
} else {
LOG_ERR("Illegal 4ch configuration");
return -EINVAL;
}
break;
default:
LOG_ERR("Illegal OF bit field");
return -EINVAL;
}
return dai_nhlt_update_rate(dmic, 0, 0);
}
static inline int dai_dmic_set_clock(const struct dai_intel_dmic *dmic, const uint8_t clock_source)
{
return 0;
}
#endif
static int print_outcontrol(uint32_t val)
{
int bf1, bf2, bf3, bf4, bf5, bf6, bf7, bf8;
#ifdef CONFIG_SOC_SERIES_INTEL_ADSP_ACE
int bf9, bf10, bf11, bf12, bf13;
#endif
uint32_t ref;
bf1 = FIELD_GET(OUTCONTROL_TIE, val);
bf2 = FIELD_GET(OUTCONTROL_SIP, val);
bf3 = FIELD_GET(OUTCONTROL_FINIT, val);
bf4 = FIELD_GET(OUTCONTROL_FCI, val);
bf5 = FIELD_GET(OUTCONTROL_BFTH, val);
bf6 = FIELD_GET(OUTCONTROL_OF, val);
bf7 = FIELD_GET(OUTCONTROL_IPM, val);
bf8 = FIELD_GET(OUTCONTROL_TH, val);
LOG_INF("OUTCONTROL = %08x", val);
LOG_INF(" tie=%d, sip=%d, finit=%d, fci=%d", bf1, bf2, bf3, bf4);
LOG_INF(" bfth=%d, of=%d, ipm=%d, th=%d", bf5, bf6, bf7, bf8);
if (bf5 > OUTCONTROL_BFTH_MAX) {
LOG_WRN("illegal BFTH value %d", bf5);
return -EINVAL;
}
#ifdef CONFIG_SOC_SERIES_INTEL_ADSP_ACE
bf9 = FIELD_GET(OUTCONTROL_IPM_SOURCE_1, val);
bf10 = FIELD_GET(OUTCONTROL_IPM_SOURCE_2, val);
bf11 = FIELD_GET(OUTCONTROL_IPM_SOURCE_3, val);
bf12 = FIELD_GET(OUTCONTROL_IPM_SOURCE_4, val);
bf13 = FIELD_GET(OUTCONTROL_IPM_SOURCE_MODE, val);
LOG_INF(" ipms1=%d, ipms2=%d, ipms3=%d, ipms4=%d", bf9, bf10, bf11, bf12);
LOG_INF(" ipms_mode=%d", bf13);
ref = FIELD_PREP(OUTCONTROL_TIE, bf1) | FIELD_PREP(OUTCONTROL_SIP, bf2) |
FIELD_PREP(OUTCONTROL_FINIT, bf3) | FIELD_PREP(OUTCONTROL_FCI, bf4) |
FIELD_PREP(OUTCONTROL_BFTH, bf5) | FIELD_PREP(OUTCONTROL_OF, bf6) |
FIELD_PREP(OUTCONTROL_IPM, bf7) | FIELD_PREP(OUTCONTROL_IPM_SOURCE_1, bf9) |
FIELD_PREP(OUTCONTROL_IPM_SOURCE_2, bf10) |
FIELD_PREP(OUTCONTROL_IPM_SOURCE_3, bf11) |
FIELD_PREP(OUTCONTROL_IPM_SOURCE_4, bf12) | FIELD_PREP(OUTCONTROL_TH, bf8) |
FIELD_PREP(OUTCONTROL_IPM_SOURCE_MODE, bf13);
#else
ref = FIELD_PREP(OUTCONTROL_TIE, bf1) | FIELD_PREP(OUTCONTROL_SIP, bf2) |
FIELD_PREP(OUTCONTROL_FINIT, bf3) | FIELD_PREP(OUTCONTROL_FCI, bf4) |
FIELD_PREP(OUTCONTROL_BFTH, bf5) | FIELD_PREP(OUTCONTROL_OF, bf6) |
FIELD_PREP(OUTCONTROL_IPM, bf7) | FIELD_PREP(OUTCONTROL_TH, bf8);
#endif
if (ref != val) {
LOG_WRN("Some reserved bits are set in OUTCONTROL = 0x%08x", val);
}
return 0;
}
static void print_cic_control(uint32_t val)
{
int bf1, bf2, bf3, bf4, bf5, bf6, bf7;
uint32_t ref;
bf1 = FIELD_GET(CIC_CONTROL_SOFT_RESET, val);
bf2 = FIELD_GET(CIC_CONTROL_CIC_START_B, val);
bf3 = FIELD_GET(CIC_CONTROL_CIC_START_A, val);
bf4 = FIELD_GET(CIC_CONTROL_MIC_B_POLARITY, val);
bf5 = FIELD_GET(CIC_CONTROL_MIC_A_POLARITY, val);
bf6 = FIELD_GET(CIC_CONTROL_MIC_MUTE, val);
#ifndef CONFIG_SOC_SERIES_INTEL_ADSP_ACE
bf7 = FIELD_GET(CIC_CONTROL_STEREO_MODE, val);
#else
bf7 = -1;
#endif
LOG_DBG("CIC_CONTROL = %08x", val);
LOG_DBG(" soft_reset=%d, cic_start_b=%d, cic_start_a=%d",
bf1, bf2, bf3);
LOG_DBG(" mic_b_polarity=%d, mic_a_polarity=%d, mic_mute=%d",
bf4, bf5, bf6);
ref = FIELD_PREP(CIC_CONTROL_SOFT_RESET, bf1) |
FIELD_PREP(CIC_CONTROL_CIC_START_B, bf2) |
FIELD_PREP(CIC_CONTROL_CIC_START_A, bf3) |
FIELD_PREP(CIC_CONTROL_MIC_B_POLARITY, bf4) |
FIELD_PREP(CIC_CONTROL_MIC_A_POLARITY, bf5) |
FIELD_PREP(CIC_CONTROL_MIC_MUTE, bf6)
#ifndef CONFIG_SOC_SERIES_INTEL_ADSP_ACE
| FIELD_PREP(CIC_CONTROL_STEREO_MODE, bf7)
#endif
;
LOG_DBG(" stereo_mode=%d", bf7);
if (ref != val) {
LOG_WRN("Some reserved bits are set in CIC_CONTROL = 0x%08x", val);
}
}
static void print_fir_control(uint32_t val)
{
int bf1, bf2, bf3, bf4, bf5, bf6;
uint32_t ref;
bf1 = FIELD_GET(FIR_CONTROL_START, val);
bf2 = FIELD_GET(FIR_CONTROL_ARRAY_START_EN, val);
#ifdef CONFIG_SOC_SERIES_INTEL_ADSP_ACE
bf3 = FIELD_GET(FIR_CONTROL_PERIODIC_START_EN, val);
#else
bf3 = -1;
#endif
bf4 = FIELD_GET(FIR_CONTROL_DCCOMP, val);
bf5 = FIELD_GET(FIR_CONTROL_MUTE, val);
bf6 = FIELD_GET(FIR_CONTROL_STEREO, val);
LOG_DBG("FIR_CONTROL = %08x", val);
LOG_DBG(" start=%d, array_start_en=%d, periodic_start_en=%d",
bf1, bf2, bf3);
LOG_DBG(" dccomp=%d, mute=%d, stereo=%d", bf4, bf5, bf6);
ref = FIELD_PREP(FIR_CONTROL_START, bf1) |
FIELD_PREP(FIR_CONTROL_ARRAY_START_EN, bf2) |
#ifdef CONFIG_SOC_SERIES_INTEL_ADSP_ACE
FIELD_PREP(FIR_CONTROL_PERIODIC_START_EN, bf3) |
#endif
FIELD_PREP(FIR_CONTROL_DCCOMP, bf4) |
FIELD_PREP(FIR_CONTROL_MUTE, bf5) |
FIELD_PREP(FIR_CONTROL_STEREO, bf6);
if (ref != val) {
LOG_WRN("Some reserved bits are set in FIR_CONTROL = 0x%08x", val);
}
}
static void print_pdm_ctrl(const struct nhlt_pdm_ctrl_cfg *pdm_cfg)
{
int bf1, bf2, bf3, bf4, bf5;
uint32_t val;
LOG_DBG("CIC_CONTROL = %08x", pdm_cfg->cic_control);
val = pdm_cfg->cic_config;
bf1 = FIELD_GET(CIC_CONFIG_CIC_SHIFT, val);
bf2 = FIELD_GET(CIC_CONFIG_COMB_COUNT, val);
LOG_DBG("CIC_CONFIG = %08x", val);
LOG_DBG(" cic_shift=%d, comb_count=%d", bf1, bf2);
val = pdm_cfg->mic_control;
#ifndef CONFIG_SOC_SERIES_INTEL_ADSP_ACE
bf1 = FIELD_GET(MIC_CONTROL_PDM_SKEW, val);
#else
bf1 = -1;
#endif
bf2 = FIELD_GET(MIC_CONTROL_CLK_EDGE, val);
bf3 = FIELD_GET(MIC_CONTROL_PDM_EN_B, val);
bf4 = FIELD_GET(MIC_CONTROL_PDM_EN_A, val);
bf5 = FIELD_GET(MIC_CONTROL_PDM_CLKDIV, val);
LOG_DBG("MIC_CONTROL = %08x", val);
LOG_DBG(" clkdiv=%d, skew=%d, clk_edge=%d", bf5, bf1, bf2);
LOG_DBG(" en_b=%d, en_a=%d", bf3, bf4);
}
static void print_fir_config(const struct nhlt_pdm_ctrl_fir_cfg *fir_cfg)
{
uint32_t val;
int fir_decimation, fir_shift, fir_length;
val = fir_cfg->fir_config;
fir_length = FIELD_GET(FIR_CONFIG_FIR_LENGTH, val);
fir_decimation = FIELD_GET(FIR_CONFIG_FIR_DECIMATION, val);
fir_shift = FIELD_GET(FIR_CONFIG_FIR_SHIFT, val);
LOG_DBG("FIR_CONFIG = %08x", val);
LOG_DBG(" fir_decimation=%d, fir_shift=%d, fir_length=%d",
fir_decimation, fir_shift, fir_length);
print_fir_control(fir_cfg->fir_control);
/* Use DC_OFFSET and GAIN as such */
LOG_DBG("DC_OFFSET_LEFT = %08x", fir_cfg->dc_offset_left);
LOG_DBG("DC_OFFSET_RIGHT = %08x", fir_cfg->dc_offset_right);
LOG_DBG("OUT_GAIN_LEFT = %08x", fir_cfg->out_gain_left);
LOG_DBG("OUT_GAIN_RIGHT = %08x", fir_cfg->out_gain_right);
}
static void configure_fir(struct dai_intel_dmic *dmic, const uint32_t base,
const struct nhlt_pdm_ctrl_fir_cfg *fir_cfg)
{
uint32_t val;
print_fir_config(fir_cfg);
/* Use FIR_CONFIG as such */
val = fir_cfg->fir_config;
dai_dmic_write(dmic, base + FIR_CONFIG, val);
val = fir_cfg->fir_control;
print_fir_control(val);
/* Clear START, set MUTE */
val = (val & ~FIR_CONTROL_START) | FIR_CONTROL_MUTE;
dai_dmic_write(dmic, base + FIR_CONTROL, val);
LOG_DBG("FIR_CONTROL = %08x", val);
/* Use DC_OFFSET and GAIN as such */
dai_dmic_write(dmic, base + DC_OFFSET_LEFT, fir_cfg->dc_offset_left);
dai_dmic_write(dmic, base + DC_OFFSET_RIGHT, fir_cfg->dc_offset_right);
dai_dmic_write(dmic, base + OUT_GAIN_LEFT, fir_cfg->out_gain_left);
dai_dmic_write(dmic, base + OUT_GAIN_RIGHT, fir_cfg->out_gain_right);
dmic->gain_left = fir_cfg->out_gain_left;
dmic->gain_right = fir_cfg->out_gain_right;
}
int dai_dmic_set_config_nhlt(struct dai_intel_dmic *dmic, const void *bespoke_cfg)
{
const struct nhlt_pdm_ctrl_cfg *pdm_cfg;
struct nhlt_dmic_channel_ctrl_mask *dmic_cfg;
uint32_t channel_ctrl_mask;
uint32_t pdm_ctrl_mask;
uint32_t pdm_base;
int pdm_idx;
uint32_t val;
uint32_t outcontrol;
const uint8_t *p = bespoke_cfg;
int num_fifos;
int num_pdm;
int n;
int ret;
const uint32_t *fir_coeffs;
/* Array of pointers to pdm coefficient data. Used to reuse coefficient from another pdm. */
const uint32_t *pdm_coeff_ptr[DMIC_HW_CONTROLLERS_MAX] = { 0 };
if (dmic->dai_config_params.dai_index >= DMIC_HW_FIFOS_MAX) {
LOG_ERR("dmic_set_config_nhlt(): illegal DAI index %d",
dmic->dai_config_params.dai_index);
return -EINVAL;
}
/* Skip not used headers */
p += sizeof(struct nhlt_dmic_gateway_attributes);
p += sizeof(struct nhlt_dmic_ts_group);
p += sizeof(struct nhlt_dmic_global_config);
/* Channel_ctlr_mask bits indicate the FIFOs enabled*/
dmic_cfg = (struct nhlt_dmic_channel_ctrl_mask *)p;
channel_ctrl_mask = dmic_cfg->channel_ctrl_mask;
num_fifos = POPCOUNT(channel_ctrl_mask); /* Count set bits */
p += sizeof(struct nhlt_dmic_channel_ctrl_mask);
LOG_DBG("dmic_set_config_nhlt(): channel_ctrl_mask = %d", channel_ctrl_mask);
/* Configure clock source */
ret = dai_dmic_set_clock(dmic, dmic_cfg->clock_source);
if (ret)
return ret;
/* Get OUTCONTROLx configuration */
if (num_fifos < 1 || num_fifos > DMIC_HW_FIFOS_MAX) {
LOG_ERR("dmic_set_config_nhlt(): illegal number of FIFOs %d", num_fifos);
return -EINVAL;
}
for (n = 0; n < DMIC_HW_FIFOS_MAX; n++) {
if (!(channel_ctrl_mask & (1 << n)))
continue;
val = *(uint32_t *)p;
ret = print_outcontrol(val);
if (ret) {
return ret;
}
if (dmic->dai_config_params.dai_index == n) {
/* Write the FIFO control registers. The clear/set of bits is the same for
* all DMIC_HW_VERSION
*/
/* Clear TIE, SIP, FCI, set FINIT, the rest of bits as such */
outcontrol = (val & ~(OUTCONTROL_TIE | OUTCONTROL_SIP | OUTCONTROL_FCI)) |
OUTCONTROL_FINIT;
dai_dmic_write(dmic, dmic->dai_config_params.dai_index *
PDM_CHANNEL_REGS_SIZE + OUTCONTROL, outcontrol);
LOG_INF("OUTCONTROL%d = %08x", dmic->dai_config_params.dai_index,
outcontrol);
/* Pass 2^BFTH to plat_data fifo depth. It will be used later in DMA
* configuration
*/
val = FIELD_GET(OUTCONTROL_BFTH, outcontrol);
dmic->fifo.depth = 1 << val;
}
p += sizeof(uint32_t);
}
/* Get PDMx registers */
pdm_ctrl_mask = ((const struct nhlt_pdm_ctrl_mask *)p)->pdm_ctrl_mask;
num_pdm = POPCOUNT(pdm_ctrl_mask); /* Count set bits */
p += sizeof(struct nhlt_pdm_ctrl_mask);
LOG_DBG("dmic_set_config_nhlt(): pdm_ctrl_mask = %d", pdm_ctrl_mask);
if (num_pdm < 1 || num_pdm > CONFIG_DAI_DMIC_HW_CONTROLLERS) {
LOG_ERR("dmic_set_config_nhlt(): illegal number of PDMs %d", num_pdm);
return -EINVAL;
}
pdm_cfg = (const struct nhlt_pdm_ctrl_cfg *)p;
for (pdm_idx = 0; pdm_idx < CONFIG_DAI_DMIC_HW_CONTROLLERS; pdm_idx++) {
pdm_base = dmic_base[pdm_idx];
if (!(pdm_ctrl_mask & (1 << pdm_idx))) {
/* Set MIC_MUTE bit to unused PDM */
dai_dmic_write(dmic, pdm_base + CIC_CONTROL, CIC_CONTROL_MIC_MUTE);
continue;
}
LOG_DBG("PDM%d", pdm_idx);
/* Get CIC configuration */
if (dai_dmic_global.active_fifos_mask == 0) {
print_pdm_ctrl(pdm_cfg);
val = pdm_cfg->cic_control;
print_cic_control(val);
/* Clear CIC_START_A and CIC_START_B */
val = (val & ~(CIC_CONTROL_CIC_START_A | CIC_CONTROL_CIC_START_B));
dai_dmic_write(dmic, pdm_base + CIC_CONTROL, val);
LOG_DBG("dmic_set_config_nhlt(): CIC_CONTROL = %08x", val);
/* Use CIC_CONFIG as such */
val = pdm_cfg->cic_config;
dai_dmic_write(dmic, pdm_base + CIC_CONFIG, val);
/* Clear PDM_EN_A and PDM_EN_B */
val = pdm_cfg->mic_control;
val &= ~(MIC_CONTROL_PDM_EN_A | MIC_CONTROL_PDM_EN_B);
dai_dmic_write(dmic, pdm_base + MIC_CONTROL, val);
LOG_DBG("dmic_set_config_nhlt(): MIC_CONTROL = %08x", val);
}
configure_fir(dmic, pdm_base +
FIR_CHANNEL_REGS_SIZE * dmic->dai_config_params.dai_index,
&pdm_cfg->fir_config[dmic->dai_config_params.dai_index]);
/* Configure fir coefficients */
/* Check if FIR coeffs should be reused */
if (pdm_cfg->reuse_fir_from_pdm == 0) {
/* get ptr, where FIR coeffs starts */
fir_coeffs = pdm_cfg->fir_coeffs;
/* and save it for future pdms reference */
pdm_coeff_ptr[pdm_idx] = fir_coeffs;
} else {
if (pdm_cfg->reuse_fir_from_pdm > pdm_idx) {
LOG_ERR("invalid reuse fir index %u", pdm_cfg->reuse_fir_from_pdm);
return -EINVAL;
}
/* get FIR coeffs from another pdm */
fir_coeffs = pdm_coeff_ptr[pdm_cfg->reuse_fir_from_pdm - 1];
if (!fir_coeffs) {
LOG_ERR("unable to reuse fir from %u", pdm_cfg->reuse_fir_from_pdm);
return -EINVAL;
}
}
fir_coeffs = dai_dmic_configure_coeff(dmic, pdm_cfg, pdm_base, fir_coeffs);
/* Update pdm_cfg ptr for next PDM Ctrl. */
if (pdm_cfg->reuse_fir_from_pdm) {
/* fir_coeffs array is empty if reusing previous coeffs */
pdm_cfg = (const struct nhlt_pdm_ctrl_cfg *)&pdm_cfg->fir_coeffs;
} else {
pdm_cfg = (const struct nhlt_pdm_ctrl_cfg *)fir_coeffs;
}
}
#ifdef CONFIG_SOC_SERIES_INTEL_ADSP_ACE
ret = dai_nhlt_dmic_dai_params_get(dmic, dmic_cfg->clock_source);
#else
ret = dai_nhlt_dmic_dai_params_get(dmic);
#endif
if (ret)
return ret;
LOG_INF("dmic_set_config_nhlt(): enable0 %u, enable1 %u",
dmic->enable[0], dmic->enable[1]);
return 0;
}