drivers/audio/tlv320dac310x.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2019 Intel Corporation
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #define DT_DRV_COMPAT ti_tlv320dac

 #include <errno.h>

 #include <zephyr/sys/util.h>

 #include <zephyr/device.h>
 #include <zephyr/drivers/i2c.h>
 #include <zephyr/drivers/gpio.h>

 #include <zephyr/audio/codec.h>
 #include "tlv320dac310x.h"

 #define LOG_LEVEL CONFIG_AUDIO_CODEC_LOG_LEVEL
 #include <zephyr/logging/log.h>
 LOG_MODULE_REGISTER(tlv320dac310x);

 #define CODEC_OUTPUT_VOLUME_MAX		0
 #define CODEC_OUTPUT_VOLUME_MIN		(-78 * 2)

 struct codec_driver_config {
 	struct i2c_dt_spec bus;
 	struct gpio_dt_spec reset_gpio;
 };

 struct codec_driver_data {
 	struct reg_addr	reg_addr_cache;
 };

 static struct codec_driver_config codec_device_config = {
 	.bus		= I2C_DT_SPEC_INST_GET(0),
 	.reset_gpio	= GPIO_DT_SPEC_INST_GET(0, reset_gpios),
 };

 static struct codec_driver_data codec_device_data;

 static void codec_write_reg(const struct device *dev, struct reg_addr reg,
 			    uint8_t val);
 static void codec_read_reg(const struct device *dev, struct reg_addr reg,
 			   uint8_t *val);
 static void codec_soft_reset(const struct device *dev);
 static int codec_configure_dai(const struct device *dev, audio_dai_cfg_t *cfg);
 static int codec_configure_clocks(const struct device *dev,
 				  struct audio_codec_cfg *cfg);
 static int codec_configure_filters(const struct device *dev,
 				   audio_dai_cfg_t *cfg);
 static enum osr_multiple codec_get_osr_multiple(audio_dai_cfg_t *cfg);
 static void codec_configure_output(const struct device *dev);
 static int codec_set_output_volume(const struct device *dev, int vol);

 #if (LOG_LEVEL >= LOG_LEVEL_DEBUG)
 static void codec_read_all_regs(const struct device *dev);
 #define CODEC_DUMP_REGS(dev)	codec_read_all_regs((dev))
 #else
 #define CODEC_DUMP_REGS(dev)
 #endif

 static int codec_initialize(const struct device *dev)
 {
 	const struct codec_driver_config *const dev_cfg = dev->config;

 	if (!device_is_ready(dev_cfg->bus.bus)) {
 		LOG_ERR("I2C device not ready");
 		return -ENODEV;
 	}

 	if (!device_is_ready(dev_cfg->reset_gpio.port)) {
 		LOG_ERR("GPIO device not ready");
 		return -ENODEV;
 	}

 	return 0;
 }

 static int codec_configure(const struct device *dev,
 			   struct audio_codec_cfg *cfg)
 {
 	const struct codec_driver_config *const dev_cfg = dev->config;
 	int ret;

 	if (cfg->dai_type != AUDIO_DAI_TYPE_I2S) {
 		LOG_ERR("dai_type must be AUDIO_DAI_TYPE_I2S");
 		return -EINVAL;
 	}

 	/* Configure reset GPIO, and set the line to inactive, which will also
 	 * de-assert the reset line and thus enable the codec.
 	 */
 	gpio_pin_configure_dt(&dev_cfg->reset_gpio, GPIO_OUTPUT_INACTIVE);

 	codec_soft_reset(dev);

 	ret = codec_configure_clocks(dev, cfg);
 	if (ret == 0) {
 		ret = codec_configure_dai(dev, &cfg->dai_cfg);
 	}
 	if (ret == 0) {
 		ret = codec_configure_filters(dev, &cfg->dai_cfg);
 	}
 	codec_configure_output(dev);

 	return ret;
 }

 static void codec_start_output(const struct device *dev)
 {
 	/* powerup DAC channels */
 	codec_write_reg(dev, DATA_PATH_SETUP_ADDR, DAC_LR_POWERUP_DEFAULT);

 	/* unmute DAC channels */
 	codec_write_reg(dev, VOL_CTRL_ADDR, VOL_CTRL_UNMUTE_DEFAULT);

 	CODEC_DUMP_REGS(dev);
 }

 static void codec_stop_output(const struct device *dev)
 {
 	/* mute DAC channels */
 	codec_write_reg(dev, VOL_CTRL_ADDR, VOL_CTRL_MUTE_DEFAULT);

 	/* powerdown DAC channels */
 	codec_write_reg(dev, DATA_PATH_SETUP_ADDR, DAC_LR_POWERDN_DEFAULT);
 }

 static void codec_mute_output(const struct device *dev)
 {
 	/* mute DAC channels */
 	codec_write_reg(dev, VOL_CTRL_ADDR, VOL_CTRL_MUTE_DEFAULT);
 }

 static void codec_unmute_output(const struct device *dev)
 {
 	/* unmute DAC channels */
 	codec_write_reg(dev, VOL_CTRL_ADDR, VOL_CTRL_UNMUTE_DEFAULT);
 }

 static int codec_set_property(const struct device *dev,
 			      audio_property_t property,
 			      audio_channel_t channel,
 			      audio_property_value_t val)
 {
 	/* individual channel control not currently supported */
 	if (channel != AUDIO_CHANNEL_ALL) {
 		LOG_ERR("channel %u invalid. must be AUDIO_CHANNEL_ALL",
 			channel);
 		return -EINVAL;
 	}

 	switch (property) {
 	case AUDIO_PROPERTY_OUTPUT_VOLUME:
 		return codec_set_output_volume(dev, val.vol);

 	case AUDIO_PROPERTY_OUTPUT_MUTE:
 		if (val.mute) {
 			codec_mute_output(dev);
 		} else {
 			codec_unmute_output(dev);
 		}
 		return 0;

 	default:
 		break;
 	}

 	return -EINVAL;
 }

 static int codec_apply_properties(const struct device *dev)
 {
 	/* nothing to do because there is nothing cached */
 	return 0;
 }

 static void codec_write_reg(const struct device *dev, struct reg_addr reg,
 			    uint8_t val)
 {
 	struct codec_driver_data *const dev_data = dev->data;
 	const struct codec_driver_config *const dev_cfg = dev->config;

 	/* set page if different */
 	if (dev_data->reg_addr_cache.page != reg.page) {
 		i2c_reg_write_byte_dt(&dev_cfg->bus, 0, reg.page);
 		dev_data->reg_addr_cache.page = reg.page;
 	}

 	i2c_reg_write_byte_dt(&dev_cfg->bus, reg.reg_addr, val);
 	LOG_DBG("WR PG:%u REG:%02u VAL:0x%02x",
 			reg.page, reg.reg_addr, val);
 }

 static void codec_read_reg(const struct device *dev, struct reg_addr reg,
 			   uint8_t *val)
 {
 	struct codec_driver_data *const dev_data = dev->data;
 	const struct codec_driver_config *const dev_cfg = dev->config;

 	/* set page if different */
 	if (dev_data->reg_addr_cache.page != reg.page) {
 		i2c_reg_write_byte_dt(&dev_cfg->bus, 0, reg.page);
 		dev_data->reg_addr_cache.page = reg.page;
 	}

 	i2c_reg_read_byte_dt(&dev_cfg->bus, reg.reg_addr, val);
 	LOG_DBG("RD PG:%u REG:%02u VAL:0x%02x",
 			reg.page, reg.reg_addr, *val);
 }

 static void codec_soft_reset(const struct device *dev)
 {
 	/* soft reset the DAC */
 	codec_write_reg(dev, SOFT_RESET_ADDR, SOFT_RESET_ASSERT);
 }

 static int codec_configure_dai(const struct device *dev, audio_dai_cfg_t *cfg)
 {
 	uint8_t val;

 	/* configure I2S interface */
 	val = IF_CTRL_IFTYPE(IF_CTRL_IFTYPE_I2S);
 	if (cfg->i2s.options & I2S_OPT_BIT_CLK_MASTER) {
 		val |= IF_CTRL_BCLK_OUT;
 	}

 	if (cfg->i2s.options & I2S_OPT_FRAME_CLK_MASTER) {
 		val |= IF_CTRL_WCLK_OUT;
 	}

 	switch (cfg->i2s.word_size) {
 	case AUDIO_PCM_WIDTH_16_BITS:
 		val |= IF_CTRL_WLEN(IF_CTRL_WLEN_16);
 		break;
 	case AUDIO_PCM_WIDTH_20_BITS:
 		val |= IF_CTRL_WLEN(IF_CTRL_WLEN_20);
 		break;
 	case AUDIO_PCM_WIDTH_24_BITS:
 		val |= IF_CTRL_WLEN(IF_CTRL_WLEN_24);
 		break;
 	case AUDIO_PCM_WIDTH_32_BITS:
 		val |= IF_CTRL_WLEN(IF_CTRL_WLEN_32);
 		break;
 	default:
 		LOG_ERR("Unsupported PCM sample bit width %u",
 				cfg->i2s.word_size);
 		return -EINVAL;
 	}

 	codec_write_reg(dev, IF_CTRL1_ADDR, val);
 	return 0;
 }

 static int codec_configure_clocks(const struct device *dev,
 				  struct audio_codec_cfg *cfg)
 {
 	int dac_clk, mod_clk;
 	struct i2s_config *i2s;
 	int osr, osr_min, osr_max;
 	enum osr_multiple osr_multiple;
 	int mdac, ndac, bclk_div, mclk_div;

 	i2s = &cfg->dai_cfg.i2s;
 	LOG_DBG("MCLK %u Hz PCM Rate: %u Hz", cfg->mclk_freq,
 			i2s->frame_clk_freq);

 	if (cfg->mclk_freq <= DAC_PROC_CLK_FREQ_MAX) {
 		/* use MCLK frequency as the DAC processing clock */
 		ndac = 1;
 	} else {
 		ndac = cfg->mclk_freq / DAC_PROC_CLK_FREQ_MAX;
 	}

 	dac_clk = cfg->mclk_freq / ndac;

 	/* determine OSR Multiple based on PCM rate */
 	osr_multiple = codec_get_osr_multiple(&cfg->dai_cfg);

 	/*
 	 * calculate MOD clock such that it is an integer multiple of
 	 * cfg->i2s.frame_clk_freq and
 	 * DAC_MOD_CLK_FREQ_MIN <= MOD clock <= DAC_MOD_CLK_FREQ_MAX
 	 */
 	osr_min = (DAC_MOD_CLK_FREQ_MIN + i2s->frame_clk_freq - 1) /
 		i2s->frame_clk_freq;
 	osr_max = DAC_MOD_CLK_FREQ_MAX / i2s->frame_clk_freq;

 	/* round mix and max values to the required multiple */
 	osr_max = (osr_max / osr_multiple) * osr_multiple;
 	osr_min = (osr_min + osr_multiple - 1) / osr_multiple;

 	osr = osr_max;
 	while (osr >= osr_min) {
 		mod_clk = i2s->frame_clk_freq * osr;

 		/* calculate mdac */
 		mdac = dac_clk / mod_clk;

 		/* check if mdac is an integer */
 		if ((mdac * mod_clk) == dac_clk) {
 			/* found suitable dividers */
 			break;
 		}
 		osr -= osr_multiple;
 	}

 	/* check if suitable value was found */
 	if (osr < osr_min) {
 		LOG_ERR("Unable to find suitable mdac and osr values");
 		return -EINVAL;
 	}

 	LOG_DBG("Processing freq: %u Hz Modulator freq: %u Hz",
 			dac_clk, mod_clk);
 	LOG_DBG("NDAC: %u MDAC: %u OSR: %u", ndac, mdac, osr);

 	if (i2s->options & I2S_OPT_BIT_CLK_MASTER) {
 		bclk_div = osr * mdac / (i2s->word_size * 2U); /* stereo */
 		if ((bclk_div * i2s->word_size * 2) != (osr * mdac)) {
 			LOG_ERR("Unable to generate BCLK %u from MCLK %u",
 				i2s->frame_clk_freq * i2s->word_size * 2U,
 				cfg->mclk_freq);
 			return -EINVAL;
 		}
 		LOG_DBG("I2S Master BCLKDIV: %u", bclk_div);
 		codec_write_reg(dev, BCLK_DIV_ADDR,
 				BCLK_DIV_POWER_UP | BCLK_DIV(bclk_div));
 	}

 	/* set NDAC, then MDAC, followed by OSR */
 	codec_write_reg(dev, NDAC_DIV_ADDR,
 			(uint8_t)(NDAC_DIV(ndac) | NDAC_POWER_UP_MASK));
 	codec_write_reg(dev, MDAC_DIV_ADDR,
 			(uint8_t)(MDAC_DIV(mdac) | MDAC_POWER_UP_MASK));
 	codec_write_reg(dev, OSR_MSB_ADDR, (uint8_t)((osr >> 8) & OSR_MSB_MASK));
 	codec_write_reg(dev, OSR_LSB_ADDR, (uint8_t)(osr & OSR_LSB_MASK));

 	if (i2s->options & I2S_OPT_BIT_CLK_MASTER) {
 		codec_write_reg(dev, BCLK_DIV_ADDR,
 				BCLK_DIV(bclk_div) | BCLK_DIV_POWER_UP);
 	}

 	/* calculate MCLK divider to get ~1MHz */
 	mclk_div = (cfg->mclk_freq + 1000000 - 1) / 1000000U;
 	/* setup timer clock to be MCLK divided */
 	codec_write_reg(dev, TIMER_MCLK_DIV_ADDR,
 			TIMER_MCLK_DIV_EN_EXT | TIMER_MCLK_DIV_VAL(mclk_div));
 	LOG_DBG("Timer MCLK Divider: %u", mclk_div);

 	return 0;
 }

 static int codec_configure_filters(const struct device *dev,
 				   audio_dai_cfg_t *cfg)
 {
 	enum proc_block proc_blk;

 	/* determine decimation filter type */
 	if (cfg->i2s.frame_clk_freq >= AUDIO_PCM_RATE_192K) {
 		proc_blk = PRB_P18_DECIMATION_C;
 		LOG_INF("PCM Rate: %u Filter C PRB P18 selected",
 				cfg->i2s.frame_clk_freq);
 	} else if (cfg->i2s.frame_clk_freq >= AUDIO_PCM_RATE_96K) {
 		proc_blk = PRB_P10_DECIMATION_B;
 		LOG_INF("PCM Rate: %u Filter B PRB P10 selected",
 				cfg->i2s.frame_clk_freq);
 	} else {
 		proc_blk = PRB_P25_DECIMATION_A;
 		LOG_INF("PCM Rate: %u Filter A PRB P25 selected",
 				cfg->i2s.frame_clk_freq);
 	}

 	codec_write_reg(dev, PROC_BLK_SEL_ADDR, PROC_BLK_SEL(proc_blk));
 	return 0;
 }

 static enum osr_multiple codec_get_osr_multiple(audio_dai_cfg_t *cfg)
 {
 	enum osr_multiple osr;

 	if (cfg->i2s.frame_clk_freq >= AUDIO_PCM_RATE_192K) {
 		osr = OSR_MULTIPLE_2;
 	} else if (cfg->i2s.frame_clk_freq >= AUDIO_PCM_RATE_96K) {
 		osr = OSR_MULTIPLE_4;
 	} else {
 		osr = OSR_MULTIPLE_8;
 	}

 	LOG_INF("PCM Rate: %u OSR Multiple: %u", cfg->i2s.frame_clk_freq,
 			osr);
 	return osr;
 }

 static void codec_configure_output(const struct device *dev)
 {
 	uint8_t val;

 	/*
 	 * set common mode voltage to 1.65V (half of AVDD)
 	 * AVDD is typically 3.3V
 	 */
 	codec_read_reg(dev, HEADPHONE_DRV_ADDR, &val);
 	val &= ~HEADPHONE_DRV_CM_MASK;
 	val |= HEADPHONE_DRV_CM(CM_VOLTAGE_1P65) | HEADPHONE_DRV_RESERVED;
 	codec_write_reg(dev, HEADPHONE_DRV_ADDR, val);

 	/* enable pop removal on power down/up */
 	codec_read_reg(dev, HP_OUT_POP_RM_ADDR, &val);
 	codec_write_reg(dev, HP_OUT_POP_RM_ADDR, val | HP_OUT_POP_RM_ENABLE);

 	/* route DAC output to Headphone */
 	val = OUTPUT_ROUTING_HPL | OUTPUT_ROUTING_HPR;
 	codec_write_reg(dev, OUTPUT_ROUTING_ADDR, val);

 	/* enable volume control on Headphone out */
 	codec_write_reg(dev, HPL_ANA_VOL_CTRL_ADDR,
 			HPX_ANA_VOL(HPX_ANA_VOL_DEFAULT));
 	codec_write_reg(dev, HPR_ANA_VOL_CTRL_ADDR,
 			HPX_ANA_VOL(HPX_ANA_VOL_DEFAULT));

 	/* set headphone outputs as line-out */
 	codec_write_reg(dev, HEADPHONE_DRV_CTRL_ADDR, HEADPHONE_DRV_LINEOUT);

 	/* unmute headphone drivers */
 	codec_write_reg(dev, HPL_DRV_GAIN_CTRL_ADDR, HPX_DRV_UNMUTE);
 	codec_write_reg(dev, HPR_DRV_GAIN_CTRL_ADDR, HPX_DRV_UNMUTE);

 	/* power up headphone drivers */
 	codec_read_reg(dev, HEADPHONE_DRV_ADDR, &val);
 	val |= HEADPHONE_DRV_POWERUP | HEADPHONE_DRV_RESERVED;
 	codec_write_reg(dev, HEADPHONE_DRV_ADDR, val);
 }

 static int codec_set_output_volume(const struct device *dev, int vol)
 {
 	uint8_t vol_val;
 	int vol_index;
 	uint8_t vol_array[] = {
 		107, 108, 110, 113, 116, 120, 125, 128, 132, 138, 144
 	};

 	if ((vol > CODEC_OUTPUT_VOLUME_MAX) ||
 			(vol < CODEC_OUTPUT_VOLUME_MIN)) {
 		LOG_ERR("Invalid volume %d.%d dB",
 				vol >> 1, ((uint32_t)vol & 1) ? 5 : 0);
 		return -EINVAL;
 	}

 	/* remove sign */
 	vol = -vol;

 	/* if volume is near floor, set minimum */
 	if (vol > HPX_ANA_VOL_FLOOR) {
 		vol_val = HPX_ANA_VOL_FLOOR;
 	} else if (vol > HPX_ANA_VOL_LOW_THRESH) {
 		/* lookup low volume values */
 		for (vol_index = 0; vol_index < ARRAY_SIZE(vol_array); vol_index++) {
 			if (vol_array[vol_index] >= vol) {
 				break;
 			}
 		}
 		vol_val = HPX_ANA_VOL_LOW_THRESH + vol_index + 1;
 	} else {
 		vol_val = (uint8_t)vol;
 	}

 	codec_write_reg(dev, HPL_ANA_VOL_CTRL_ADDR, HPX_ANA_VOL(vol_val));
 	codec_write_reg(dev, HPR_ANA_VOL_CTRL_ADDR, HPX_ANA_VOL(vol_val));
 	return 0;
 }

 #if (LOG_LEVEL >= LOG_LEVEL_DEBUG)
 static void codec_read_all_regs(const struct device *dev)
 {
 	uint8_t val;

 	codec_read_reg(dev, SOFT_RESET_ADDR, &val);
 	codec_read_reg(dev, NDAC_DIV_ADDR, &val);
 	codec_read_reg(dev, MDAC_DIV_ADDR, &val);
 	codec_read_reg(dev, OSR_MSB_ADDR, &val);
 	codec_read_reg(dev, OSR_LSB_ADDR, &val);
 	codec_read_reg(dev, IF_CTRL1_ADDR, &val);
 	codec_read_reg(dev, BCLK_DIV_ADDR, &val);
 	codec_read_reg(dev, OVF_FLAG_ADDR, &val);
 	codec_read_reg(dev, PROC_BLK_SEL_ADDR, &val);
 	codec_read_reg(dev, DATA_PATH_SETUP_ADDR, &val);
 	codec_read_reg(dev, VOL_CTRL_ADDR, &val);
 	codec_read_reg(dev, L_DIG_VOL_CTRL_ADDR, &val);
 	codec_read_reg(dev, DRC_CTRL1_ADDR, &val);
 	codec_read_reg(dev, L_BEEP_GEN_ADDR, &val);
 	codec_read_reg(dev, R_BEEP_GEN_ADDR, &val);
 	codec_read_reg(dev, BEEP_LEN_MSB_ADDR, &val);
 	codec_read_reg(dev, BEEP_LEN_MIB_ADDR, &val);
 	codec_read_reg(dev, BEEP_LEN_LSB_ADDR, &val);

 	codec_read_reg(dev, HEADPHONE_DRV_ADDR, &val);
 	codec_read_reg(dev, HP_OUT_POP_RM_ADDR, &val);
 	codec_read_reg(dev, OUTPUT_ROUTING_ADDR, &val);
 	codec_read_reg(dev, HPL_ANA_VOL_CTRL_ADDR, &val);
 	codec_read_reg(dev, HPR_ANA_VOL_CTRL_ADDR, &val);
 	codec_read_reg(dev, HPL_DRV_GAIN_CTRL_ADDR, &val);
 	codec_read_reg(dev, HPR_DRV_GAIN_CTRL_ADDR, &val);
 	codec_read_reg(dev, HEADPHONE_DRV_CTRL_ADDR, &val);

 	codec_read_reg(dev, TIMER_MCLK_DIV_ADDR, &val);
 }
 #endif

 static const struct audio_codec_api codec_driver_api = {
 	.configure		= codec_configure,
 	.start_output		= codec_start_output,
 	.stop_output		= codec_stop_output,
 	.set_property		= codec_set_property,
 	.apply_properties	= codec_apply_properties,
 };

 DEVICE_DT_INST_DEFINE(0, codec_initialize, NULL, &codec_device_data,
 		&codec_device_config, POST_KERNEL,
 		CONFIG_AUDIO_CODEC_INIT_PRIORITY, &codec_driver_api);
	/*
	* Copyright (c) 2019 Intel Corporation
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#define DT_DRV_COMPAT ti_tlv320dac

	#include <errno.h>

	#include <zephyr/sys/util.h>

	#include <zephyr/device.h>
	#include <zephyr/drivers/i2c.h>
	#include <zephyr/drivers/gpio.h>

	#include <zephyr/audio/codec.h>
	#include "tlv320dac310x.h"

	#define LOG_LEVEL CONFIG_AUDIO_CODEC_LOG_LEVEL
	#include <zephyr/logging/log.h>
	LOG_MODULE_REGISTER(tlv320dac310x);

	#define CODEC_OUTPUT_VOLUME_MAX 0
	#define CODEC_OUTPUT_VOLUME_MIN (-78 * 2)

	struct codec_driver_config {
	struct i2c_dt_spec bus;
	struct gpio_dt_spec reset_gpio;
	};

	struct codec_driver_data {
	struct reg_addr reg_addr_cache;
	};

	static struct codec_driver_config codec_device_config = {
	.bus = I2C_DT_SPEC_INST_GET(0),
	.reset_gpio = GPIO_DT_SPEC_INST_GET(0, reset_gpios),
	};

	static struct codec_driver_data codec_device_data;

	static void codec_write_reg(const struct device *dev, struct reg_addr reg,
	uint8_t val);
	static void codec_read_reg(const struct device *dev, struct reg_addr reg,
	uint8_t *val);
	static void codec_soft_reset(const struct device *dev);
	static int codec_configure_dai(const struct device dev, audio_dai_cfg_t cfg);
	static int codec_configure_clocks(const struct device *dev,
	struct audio_codec_cfg *cfg);
	static int codec_configure_filters(const struct device *dev,
	audio_dai_cfg_t *cfg);
	static enum osr_multiple codec_get_osr_multiple(audio_dai_cfg_t *cfg);
	static void codec_configure_output(const struct device *dev);
	static int codec_set_output_volume(const struct device *dev, int vol);

	#if (LOG_LEVEL >= LOG_LEVEL_DEBUG)
	static void codec_read_all_regs(const struct device *dev);
	#define CODEC_DUMP_REGS(dev) codec_read_all_regs((dev))
	#else
	#define CODEC_DUMP_REGS(dev)
	#endif

	static int codec_initialize(const struct device *dev)
	{
	const struct codec_driver_config *const dev_cfg = dev->config;

	if (!device_is_ready(dev_cfg->bus.bus)) {
	LOG_ERR("I2C device not ready");
	return -ENODEV;
	}

	if (!device_is_ready(dev_cfg->reset_gpio.port)) {
	LOG_ERR("GPIO device not ready");
	return -ENODEV;
	}

	return 0;
	}

	static int codec_configure(const struct device *dev,
	struct audio_codec_cfg *cfg)
	{
	const struct codec_driver_config *const dev_cfg = dev->config;
	int ret;

	if (cfg->dai_type != AUDIO_DAI_TYPE_I2S) {
	LOG_ERR("dai_type must be AUDIO_DAI_TYPE_I2S");
	return -EINVAL;
	}

	/* Configure reset GPIO, and set the line to inactive, which will also
	* de-assert the reset line and thus enable the codec.
	*/
	gpio_pin_configure_dt(&dev_cfg->reset_gpio, GPIO_OUTPUT_INACTIVE);

	codec_soft_reset(dev);

	ret = codec_configure_clocks(dev, cfg);
	if (ret == 0) {
	ret = codec_configure_dai(dev, &cfg->dai_cfg);
	}
	if (ret == 0) {
	ret = codec_configure_filters(dev, &cfg->dai_cfg);
	}
	codec_configure_output(dev);

	return ret;
	}

	static void codec_start_output(const struct device *dev)
	{
	/* powerup DAC channels */
	codec_write_reg(dev, DATA_PATH_SETUP_ADDR, DAC_LR_POWERUP_DEFAULT);

	/* unmute DAC channels */
	codec_write_reg(dev, VOL_CTRL_ADDR, VOL_CTRL_UNMUTE_DEFAULT);

	CODEC_DUMP_REGS(dev);
	}

	static void codec_stop_output(const struct device *dev)
	{
	/* mute DAC channels */
	codec_write_reg(dev, VOL_CTRL_ADDR, VOL_CTRL_MUTE_DEFAULT);

	/* powerdown DAC channels */
	codec_write_reg(dev, DATA_PATH_SETUP_ADDR, DAC_LR_POWERDN_DEFAULT);
	}

	static void codec_mute_output(const struct device *dev)
	{
	/* mute DAC channels */
	codec_write_reg(dev, VOL_CTRL_ADDR, VOL_CTRL_MUTE_DEFAULT);
	}

	static void codec_unmute_output(const struct device *dev)
	{
	/* unmute DAC channels */
	codec_write_reg(dev, VOL_CTRL_ADDR, VOL_CTRL_UNMUTE_DEFAULT);
	}

	static int codec_set_property(const struct device *dev,
	audio_property_t property,
	audio_channel_t channel,
	audio_property_value_t val)
	{
	/* individual channel control not currently supported */
	if (channel != AUDIO_CHANNEL_ALL) {
	LOG_ERR("channel %u invalid. must be AUDIO_CHANNEL_ALL",
	channel);
	return -EINVAL;
	}

	switch (property) {
	case AUDIO_PROPERTY_OUTPUT_VOLUME:
	return codec_set_output_volume(dev, val.vol);

	case AUDIO_PROPERTY_OUTPUT_MUTE:
	if (val.mute) {
	codec_mute_output(dev);
	} else {
	codec_unmute_output(dev);
	}
	return 0;

	default:
	break;
	}

	return -EINVAL;
	}

	static int codec_apply_properties(const struct device *dev)
	{
	/* nothing to do because there is nothing cached */
	return 0;
	}

	static void codec_write_reg(const struct device *dev, struct reg_addr reg,
	uint8_t val)
	{
	struct codec_driver_data *const dev_data = dev->data;
	const struct codec_driver_config *const dev_cfg = dev->config;

	/* set page if different */
	if (dev_data->reg_addr_cache.page != reg.page) {
	i2c_reg_write_byte_dt(&dev_cfg->bus, 0, reg.page);
	dev_data->reg_addr_cache.page = reg.page;
	}

	i2c_reg_write_byte_dt(&dev_cfg->bus, reg.reg_addr, val);
	LOG_DBG("WR PG:%u REG:%02u VAL:0x%02x",
	reg.page, reg.reg_addr, val);
	}

	static void codec_read_reg(const struct device *dev, struct reg_addr reg,
	uint8_t *val)
	{
	struct codec_driver_data *const dev_data = dev->data;
	const struct codec_driver_config *const dev_cfg = dev->config;

	/* set page if different */
	if (dev_data->reg_addr_cache.page != reg.page) {
	i2c_reg_write_byte_dt(&dev_cfg->bus, 0, reg.page);
	dev_data->reg_addr_cache.page = reg.page;
	}

	i2c_reg_read_byte_dt(&dev_cfg->bus, reg.reg_addr, val);
	LOG_DBG("RD PG:%u REG:%02u VAL:0x%02x",
	reg.page, reg.reg_addr, *val);
	}

	static void codec_soft_reset(const struct device *dev)
	{
	/* soft reset the DAC */
	codec_write_reg(dev, SOFT_RESET_ADDR, SOFT_RESET_ASSERT);
	}

	static int codec_configure_dai(const struct device dev, audio_dai_cfg_t cfg)
	{
	uint8_t val;

	/* configure I2S interface */
	val = IF_CTRL_IFTYPE(IF_CTRL_IFTYPE_I2S);
	if (cfg->i2s.options & I2S_OPT_BIT_CLK_MASTER) {
	val \|= IF_CTRL_BCLK_OUT;
	}

	if (cfg->i2s.options & I2S_OPT_FRAME_CLK_MASTER) {
	val \|= IF_CTRL_WCLK_OUT;
	}

	switch (cfg->i2s.word_size) {
	case AUDIO_PCM_WIDTH_16_BITS:
	val \|= IF_CTRL_WLEN(IF_CTRL_WLEN_16);
	break;
	case AUDIO_PCM_WIDTH_20_BITS:
	val \|= IF_CTRL_WLEN(IF_CTRL_WLEN_20);
	break;
	case AUDIO_PCM_WIDTH_24_BITS:
	val \|= IF_CTRL_WLEN(IF_CTRL_WLEN_24);
	break;
	case AUDIO_PCM_WIDTH_32_BITS:
	val \|= IF_CTRL_WLEN(IF_CTRL_WLEN_32);
	break;
	default:
	LOG_ERR("Unsupported PCM sample bit width %u",
	cfg->i2s.word_size);
	return -EINVAL;
	}

	codec_write_reg(dev, IF_CTRL1_ADDR, val);
	return 0;
	}

	static int codec_configure_clocks(const struct device *dev,
	struct audio_codec_cfg *cfg)
	{
	int dac_clk, mod_clk;
	struct i2s_config *i2s;
	int osr, osr_min, osr_max;
	enum osr_multiple osr_multiple;
	int mdac, ndac, bclk_div, mclk_div;

	i2s = &cfg->dai_cfg.i2s;
	LOG_DBG("MCLK %u Hz PCM Rate: %u Hz", cfg->mclk_freq,
	i2s->frame_clk_freq);

	if (cfg->mclk_freq <= DAC_PROC_CLK_FREQ_MAX) {
	/* use MCLK frequency as the DAC processing clock */
	ndac = 1;
	} else {
	ndac = cfg->mclk_freq / DAC_PROC_CLK_FREQ_MAX;
	}

	dac_clk = cfg->mclk_freq / ndac;

	/* determine OSR Multiple based on PCM rate */
	osr_multiple = codec_get_osr_multiple(&cfg->dai_cfg);

	/*
	* calculate MOD clock such that it is an integer multiple of
	* cfg->i2s.frame_clk_freq and
	* DAC_MOD_CLK_FREQ_MIN <= MOD clock <= DAC_MOD_CLK_FREQ_MAX
	*/
	osr_min = (DAC_MOD_CLK_FREQ_MIN + i2s->frame_clk_freq - 1) /
	i2s->frame_clk_freq;
	osr_max = DAC_MOD_CLK_FREQ_MAX / i2s->frame_clk_freq;

	/* round mix and max values to the required multiple */
	osr_max = (osr_max / osr_multiple) * osr_multiple;
	osr_min = (osr_min + osr_multiple - 1) / osr_multiple;

	osr = osr_max;
	while (osr >= osr_min) {
	mod_clk = i2s->frame_clk_freq * osr;

	/* calculate mdac */
	mdac = dac_clk / mod_clk;

	/* check if mdac is an integer */
	if ((mdac * mod_clk) == dac_clk) {
	/* found suitable dividers */
	break;
	}
	osr -= osr_multiple;
	}

	/* check if suitable value was found */
	if (osr < osr_min) {
	LOG_ERR("Unable to find suitable mdac and osr values");
	return -EINVAL;
	}

	LOG_DBG("Processing freq: %u Hz Modulator freq: %u Hz",
	dac_clk, mod_clk);
	LOG_DBG("NDAC: %u MDAC: %u OSR: %u", ndac, mdac, osr);

	if (i2s->options & I2S_OPT_BIT_CLK_MASTER) {
	bclk_div = osr * mdac / (i2s->word_size * 2U); /* stereo */
	if ((bclk_div * i2s->word_size * 2) != (osr * mdac)) {
	LOG_ERR("Unable to generate BCLK %u from MCLK %u",
	i2s->frame_clk_freq * i2s->word_size * 2U,
	cfg->mclk_freq);
	return -EINVAL;
	}
	LOG_DBG("I2S Master BCLKDIV: %u", bclk_div);
	codec_write_reg(dev, BCLK_DIV_ADDR,
	BCLK_DIV_POWER_UP \| BCLK_DIV(bclk_div));
	}

	/* set NDAC, then MDAC, followed by OSR */
	codec_write_reg(dev, NDAC_DIV_ADDR,
	(uint8_t)(NDAC_DIV(ndac) \| NDAC_POWER_UP_MASK));
	codec_write_reg(dev, MDAC_DIV_ADDR,
	(uint8_t)(MDAC_DIV(mdac) \| MDAC_POWER_UP_MASK));
	codec_write_reg(dev, OSR_MSB_ADDR, (uint8_t)((osr >> 8) & OSR_MSB_MASK));
	codec_write_reg(dev, OSR_LSB_ADDR, (uint8_t)(osr & OSR_LSB_MASK));

	if (i2s->options & I2S_OPT_BIT_CLK_MASTER) {
	codec_write_reg(dev, BCLK_DIV_ADDR,
	BCLK_DIV(bclk_div) \| BCLK_DIV_POWER_UP);
	}

	/* calculate MCLK divider to get ~1MHz */
	mclk_div = (cfg->mclk_freq + 1000000 - 1) / 1000000U;
	/* setup timer clock to be MCLK divided */
	codec_write_reg(dev, TIMER_MCLK_DIV_ADDR,
	TIMER_MCLK_DIV_EN_EXT \| TIMER_MCLK_DIV_VAL(mclk_div));
	LOG_DBG("Timer MCLK Divider: %u", mclk_div);

	return 0;
	}

	static int codec_configure_filters(const struct device *dev,
	audio_dai_cfg_t *cfg)
	{
	enum proc_block proc_blk;

	/* determine decimation filter type */
	if (cfg->i2s.frame_clk_freq >= AUDIO_PCM_RATE_192K) {
	proc_blk = PRB_P18_DECIMATION_C;
	LOG_INF("PCM Rate: %u Filter C PRB P18 selected",
	cfg->i2s.frame_clk_freq);
	} else if (cfg->i2s.frame_clk_freq >= AUDIO_PCM_RATE_96K) {
	proc_blk = PRB_P10_DECIMATION_B;
	LOG_INF("PCM Rate: %u Filter B PRB P10 selected",
	cfg->i2s.frame_clk_freq);
	} else {
	proc_blk = PRB_P25_DECIMATION_A;
	LOG_INF("PCM Rate: %u Filter A PRB P25 selected",
	cfg->i2s.frame_clk_freq);
	}

	codec_write_reg(dev, PROC_BLK_SEL_ADDR, PROC_BLK_SEL(proc_blk));
	return 0;
	}

	static enum osr_multiple codec_get_osr_multiple(audio_dai_cfg_t *cfg)
	{
	enum osr_multiple osr;

	if (cfg->i2s.frame_clk_freq >= AUDIO_PCM_RATE_192K) {
	osr = OSR_MULTIPLE_2;
	} else if (cfg->i2s.frame_clk_freq >= AUDIO_PCM_RATE_96K) {
	osr = OSR_MULTIPLE_4;
	} else {
	osr = OSR_MULTIPLE_8;
	}

	LOG_INF("PCM Rate: %u OSR Multiple: %u", cfg->i2s.frame_clk_freq,
	osr);
	return osr;
	}

	static void codec_configure_output(const struct device *dev)
	{
	uint8_t val;

	/*
	* set common mode voltage to 1.65V (half of AVDD)
	* AVDD is typically 3.3V
	*/
	codec_read_reg(dev, HEADPHONE_DRV_ADDR, &val);
	val &= ~HEADPHONE_DRV_CM_MASK;
	val \|= HEADPHONE_DRV_CM(CM_VOLTAGE_1P65) \| HEADPHONE_DRV_RESERVED;
	codec_write_reg(dev, HEADPHONE_DRV_ADDR, val);

	/* enable pop removal on power down/up */
	codec_read_reg(dev, HP_OUT_POP_RM_ADDR, &val);
	codec_write_reg(dev, HP_OUT_POP_RM_ADDR, val \| HP_OUT_POP_RM_ENABLE);

	/* route DAC output to Headphone */
	val = OUTPUT_ROUTING_HPL \| OUTPUT_ROUTING_HPR;
	codec_write_reg(dev, OUTPUT_ROUTING_ADDR, val);

	/* enable volume control on Headphone out */
	codec_write_reg(dev, HPL_ANA_VOL_CTRL_ADDR,
	HPX_ANA_VOL(HPX_ANA_VOL_DEFAULT));
	codec_write_reg(dev, HPR_ANA_VOL_CTRL_ADDR,
	HPX_ANA_VOL(HPX_ANA_VOL_DEFAULT));

	/* set headphone outputs as line-out */
	codec_write_reg(dev, HEADPHONE_DRV_CTRL_ADDR, HEADPHONE_DRV_LINEOUT);

	/* unmute headphone drivers */
	codec_write_reg(dev, HPL_DRV_GAIN_CTRL_ADDR, HPX_DRV_UNMUTE);
	codec_write_reg(dev, HPR_DRV_GAIN_CTRL_ADDR, HPX_DRV_UNMUTE);

	/* power up headphone drivers */
	codec_read_reg(dev, HEADPHONE_DRV_ADDR, &val);
	val \|= HEADPHONE_DRV_POWERUP \| HEADPHONE_DRV_RESERVED;
	codec_write_reg(dev, HEADPHONE_DRV_ADDR, val);
	}

	static int codec_set_output_volume(const struct device *dev, int vol)
	{
	uint8_t vol_val;
	int vol_index;
	uint8_t vol_array[] = {
	107, 108, 110, 113, 116, 120, 125, 128, 132, 138, 144
	};

	if ((vol > CODEC_OUTPUT_VOLUME_MAX) \|\|
	(vol < CODEC_OUTPUT_VOLUME_MIN)) {
	LOG_ERR("Invalid volume %d.%d dB",
	vol >> 1, ((uint32_t)vol & 1) ? 5 : 0);
	return -EINVAL;
	}

	/* remove sign */
	vol = -vol;

	/* if volume is near floor, set minimum */
	if (vol > HPX_ANA_VOL_FLOOR) {
	vol_val = HPX_ANA_VOL_FLOOR;
	} else if (vol > HPX_ANA_VOL_LOW_THRESH) {
	/* lookup low volume values */
	for (vol_index = 0; vol_index < ARRAY_SIZE(vol_array); vol_index++) {
	if (vol_array[vol_index] >= vol) {
	break;
	}
	}
	vol_val = HPX_ANA_VOL_LOW_THRESH + vol_index + 1;
	} else {
	vol_val = (uint8_t)vol;
	}

	codec_write_reg(dev, HPL_ANA_VOL_CTRL_ADDR, HPX_ANA_VOL(vol_val));
	codec_write_reg(dev, HPR_ANA_VOL_CTRL_ADDR, HPX_ANA_VOL(vol_val));
	return 0;
	}

	#if (LOG_LEVEL >= LOG_LEVEL_DEBUG)
	static void codec_read_all_regs(const struct device *dev)
	{
	uint8_t val;

	codec_read_reg(dev, SOFT_RESET_ADDR, &val);
	codec_read_reg(dev, NDAC_DIV_ADDR, &val);
	codec_read_reg(dev, MDAC_DIV_ADDR, &val);
	codec_read_reg(dev, OSR_MSB_ADDR, &val);
	codec_read_reg(dev, OSR_LSB_ADDR, &val);
	codec_read_reg(dev, IF_CTRL1_ADDR, &val);
	codec_read_reg(dev, BCLK_DIV_ADDR, &val);
	codec_read_reg(dev, OVF_FLAG_ADDR, &val);
	codec_read_reg(dev, PROC_BLK_SEL_ADDR, &val);
	codec_read_reg(dev, DATA_PATH_SETUP_ADDR, &val);
	codec_read_reg(dev, VOL_CTRL_ADDR, &val);
	codec_read_reg(dev, L_DIG_VOL_CTRL_ADDR, &val);
	codec_read_reg(dev, DRC_CTRL1_ADDR, &val);
	codec_read_reg(dev, L_BEEP_GEN_ADDR, &val);
	codec_read_reg(dev, R_BEEP_GEN_ADDR, &val);
	codec_read_reg(dev, BEEP_LEN_MSB_ADDR, &val);
	codec_read_reg(dev, BEEP_LEN_MIB_ADDR, &val);
	codec_read_reg(dev, BEEP_LEN_LSB_ADDR, &val);

	codec_read_reg(dev, HEADPHONE_DRV_ADDR, &val);
	codec_read_reg(dev, HP_OUT_POP_RM_ADDR, &val);
	codec_read_reg(dev, OUTPUT_ROUTING_ADDR, &val);
	codec_read_reg(dev, HPL_ANA_VOL_CTRL_ADDR, &val);
	codec_read_reg(dev, HPR_ANA_VOL_CTRL_ADDR, &val);
	codec_read_reg(dev, HPL_DRV_GAIN_CTRL_ADDR, &val);
	codec_read_reg(dev, HPR_DRV_GAIN_CTRL_ADDR, &val);
	codec_read_reg(dev, HEADPHONE_DRV_CTRL_ADDR, &val);

	codec_read_reg(dev, TIMER_MCLK_DIV_ADDR, &val);
	}
	#endif

	static const struct audio_codec_api codec_driver_api = {
	.configure = codec_configure,
	.start_output = codec_start_output,
	.stop_output = codec_stop_output,
	.set_property = codec_set_property,
	.apply_properties = codec_apply_properties,
	};

	DEVICE_DT_INST_DEFINE(0, codec_initialize, NULL, &codec_device_data,
	&codec_device_config, POST_KERNEL,
	CONFIG_AUDIO_CODEC_INIT_PRIORITY, &codec_driver_api);