alsa-utils/topology/nhlt/intel/ssp-nhlt.c

// SPDX-License-Identifier: BSD-3-Clause
//
// Copyright(c) 2021 Intel Corporation. All rights reserved.
//
// Author: Jaska Uimonen <jaska.uimonen@linux.intel.com>

#include <stdint.h>
#include <errno.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <alsa/input.h>
#include <alsa/output.h>
#include <alsa/conf.h>
#include <alsa/error.h>
#include "intel-nhlt.h"
#include "ssp-nhlt.h"
#include "ssp/ssp-process.h"

static int set_ssp_data(struct intel_nhlt_params *nhlt, snd_config_t *dai_cfg, snd_config_t *top)
{
	const char *tdm_padding_per_slot = NULL;
	const char *direction = NULL;
	const char *quirks = NULL;
	long frame_pulse_width = 0;
	long clks_control = 0;
	long sample_bits = 0;
	long bclk_delay = 0;
	long dai_index = 0;
	long mclk_id = 0;
	long io_clk = 0;
	int ret;

	struct dai_values ssp_data[] = {
		{ "io_clk",  SND_CONFIG_TYPE_INTEGER, NULL, &io_clk, NULL},
		{ "direction", SND_CONFIG_TYPE_STRING, NULL, NULL, &direction},
		{ "quirks", SND_CONFIG_TYPE_STRING, NULL, NULL, &quirks},
		{ "dai_index", SND_CONFIG_TYPE_INTEGER, NULL, &dai_index, NULL},
		{ "sample_bits", SND_CONFIG_TYPE_INTEGER, NULL, &sample_bits, NULL},
		{ "bclk_delay", SND_CONFIG_TYPE_INTEGER, NULL, &bclk_delay, NULL},
		{ "mclk_id", SND_CONFIG_TYPE_INTEGER, NULL, &mclk_id, NULL},
		{ "clks_control", SND_CONFIG_TYPE_INTEGER, NULL, &clks_control, NULL},
		{ "frame_pulse_width", SND_CONFIG_TYPE_INTEGER, NULL, &frame_pulse_width, NULL},
		{ "tdm_padding_per_slot", SND_CONFIG_TYPE_STRING, NULL, NULL,
		  &tdm_padding_per_slot},
	};

	ret = find_set_values(&ssp_data[0], ARRAY_SIZE(ssp_data), dai_cfg, top, "Class.Dai.SSP");
	if (ret < 0)
		return ret;

	return ssp_set_params(nhlt, direction, dai_index, io_clk, bclk_delay, sample_bits, mclk_id,
			      clks_control, frame_pulse_width, tdm_padding_per_slot, quirks);
}

static int set_hw_config(struct intel_nhlt_params *nhlt, snd_config_t *cfg, snd_config_t *top)
{
	const char *format = NULL;
	const char *mclk = NULL;
	const char *bclk = NULL;
	const char *bclk_invert = NULL;
	const char *fsync = NULL;
	const char *fsync_invert = NULL;
	long mclk_freq = 0;
	long bclk_freq = 0;
	long fsync_freq = 0;
	long tdm_slots = 0;
	long tdm_slot_width = 0;
	long tx_slots = 0;
	long rx_slots = 0;
	long ret;

	struct dai_values ssp_hw_data[] = {
		{"format", SND_CONFIG_TYPE_STRING, NULL, NULL, &format},
		{"mclk", SND_CONFIG_TYPE_STRING, NULL, NULL, &mclk},
		{"bclk", SND_CONFIG_TYPE_STRING, NULL, NULL, &bclk},
		{"fsync", SND_CONFIG_TYPE_STRING, NULL, NULL, &fsync},
		{"bclk_invert", SND_CONFIG_TYPE_STRING, NULL, NULL, &bclk_invert},
		{"fsync_invert", SND_CONFIG_TYPE_STRING, NULL, NULL, &fsync_invert},
		{"fsync_freq", SND_CONFIG_TYPE_INTEGER, NULL, &fsync_freq, NULL},
		{"bclk_freq", SND_CONFIG_TYPE_INTEGER, NULL, &bclk_freq, NULL},
		{"mclk_freq", SND_CONFIG_TYPE_INTEGER, NULL, &mclk_freq, NULL},
		{"tdm_slots", SND_CONFIG_TYPE_INTEGER, NULL, &tdm_slots, NULL},
		{"tdm_slot_width", SND_CONFIG_TYPE_INTEGER, NULL, &tdm_slot_width, NULL},
		{"tx_slots", SND_CONFIG_TYPE_INTEGER, NULL, &tx_slots, NULL},
		{"rx_slots", SND_CONFIG_TYPE_INTEGER, NULL, &rx_slots, NULL},
	};

	ret = find_set_values(&ssp_hw_data[0], ARRAY_SIZE(ssp_hw_data), cfg, top,
			      "Class.Base.hw_config");
	if (ret < 0)
		return ret;

	return ssp_hw_set_params(nhlt, format, mclk, bclk, bclk_invert, fsync, fsync_invert,
				 mclk_freq, bclk_freq, fsync_freq, tdm_slots, tdm_slot_width,
				 tx_slots, rx_slots);
}

/* init ssp parameters, should be called before parsing dais */
int nhlt_ssp_init_params(struct intel_nhlt_params *nhlt)
{
	return ssp_init_params(nhlt);
}

int nhlt_ssp_get_ep_count(struct intel_nhlt_params *nhlt)
{
	return ssp_get_vendor_blob_count(nhlt);
}

int nhlt_ssp_get_dir(struct intel_nhlt_params *nhlt, int dai_index, uint8_t *dir)
{
	return ssp_get_dir(nhlt, dai_index, dir);
}

int nhlt_ssp_get_ep(struct intel_nhlt_params *nhlt, struct endpoint_descriptor **eps,
		    int dai_index, uint8_t dir)
{
	struct endpoint_descriptor ep;
	struct ssp_device_specific_config ssp_conf;
	struct formats_config f_conf;
	struct format_config f_conf1[8];
	uint32_t sample_rate;
	uint16_t channel_count;
	uint32_t bits_per_sample;
	uint32_t virtualbus_id;
	uint32_t formats_count;
	uint8_t *ep_target;
	size_t blob_size;
	int ret;
	int i;

	/*
	 * nhlt ssp structure:
	 *
	 * endpoint_descriptor, sizeof(struct endpoint_descriptor)
	 * device_specific_config (headset), sizeof(struct ssp_device_specific_config)
	 * formats_config (formats_count), sizeof(struct formats_config)
	 * format_config (waveex), sizeof(struct format_config)
	 * vendor_blob sizeof(vendor_blob)
	 */

	ret = ssp_get_params(nhlt, dai_index, &virtualbus_id, &formats_count);
	if (ret < 0) {
		fprintf(stderr, "nhlt_ssp_get_ep: ssp_get_params failed\n");
		return ret;
	}

	ep.link_type = NHLT_LINK_TYPE_SSP;
	ep.instance_id = 0;
	ep.vendor_id = NHLT_VENDOR_ID_INTEL;
	ep.device_id = NHLT_DEVICE_ID_INTEL_I2S_TDM;
	ep.revision_id = 0;
	ep.subsystem_id = 0;
	ep.device_type = 0;

	ep.direction = dir;
	/* ssp device index */
	ep.virtualbus_id = virtualbus_id;
	/* ssp config */
	ssp_conf.config.capabilities_size = 2;
	ssp_conf.device_config.virtual_slot = 0;
	ssp_conf.device_config.config_type = 0;

	/* formats_config */
	f_conf.formats_count = formats_count;

	for (i = 0; i < f_conf.formats_count; i++) {
		/* fill in wave format extensible types */
		f_conf1[i].format.wFormatTag = 0xFFFE;

		ret = ssp_get_hw_params(nhlt, i, &sample_rate, &channel_count, &bits_per_sample);

		if (ret < 0) {
			fprintf(stderr, "nhlt_ssp_get_ep: ssp_get_hw_params failed\n");
			return ret;
		}

		f_conf1[i].format.nChannels = channel_count;
		f_conf1[i].format.nSamplesPerSec = sample_rate;
		f_conf1[i].format.wBitsPerSample = bits_per_sample;
		f_conf1[i].format.nBlockAlign = channel_count * bits_per_sample / 8;
		f_conf1[i].format.nAvgBytesPerSec = sample_rate * f_conf1[i].format.nBlockAlign;

		/* bytes after this value in this struct */
		f_conf1[i].format.cbSize = 22;
		/* actual bits in container */
		f_conf1[i].format.wValidBitsPerSample = bits_per_sample;
		/* channel map not used at this time */
		f_conf1[i].format.dwChannelMask = 0;
		/* WAVE_FORMAT_PCM guid (0x0001) ? */
		f_conf1[i].format.SubFormat[0] = 0;
		f_conf1[i].format.SubFormat[1] = 0;
		f_conf1[i].format.SubFormat[2] = 0;
		f_conf1[i].format.SubFormat[3] = 0;

		ret = ssp_get_vendor_blob_size(nhlt, &blob_size);
		if (ret < 0) {
			fprintf(stderr, "nhlt_ssp_get_ep: dmic_get_vendor_blob_size failed\n");
			return ret;
		}
		f_conf1[i].vendor_blob.capabilities_size = blob_size;
	}

	ep.length = sizeof(struct endpoint_descriptor) +
		sizeof(struct ssp_device_specific_config) +
		sizeof(struct formats_config) +
		sizeof(struct format_config) * f_conf.formats_count +
		blob_size * f_conf.formats_count;

	/* allocate the final variable length ep struct */
	ep_target = calloc(ep.length, sizeof(uint8_t));
	if (!ep_target)
		return -ENOMEM;

	*eps = (struct endpoint_descriptor *)ep_target;

	/* copy all parsed sub arrays into the top level array */
	memcpy(ep_target, &ep, sizeof(struct endpoint_descriptor));

	ep_target += sizeof(struct endpoint_descriptor);

	memcpy(ep_target, &ssp_conf, sizeof(struct ssp_device_specific_config));
	ep_target += sizeof(struct ssp_device_specific_config);

	memcpy(ep_target, &f_conf, sizeof(struct formats_config));
	ep_target += sizeof(struct formats_config);

	/* copy all hw configs */
	for (i = 0; i < f_conf.formats_count; i++) {
		memcpy(ep_target, &f_conf1[i], sizeof(struct format_config));
		ep_target += sizeof(struct format_config);
		ret = ssp_get_vendor_blob(nhlt, ep_target, dai_index, i);
		if (ret < 0) {
			fprintf(stderr, "nhlt_sso_get_ep: ssp_get_vendor_blob failed\n");
			return ret;
		}
		ep_target += blob_size;
	}

	return 0;
}

/* Set ssp parameters from topology for ssp coefficient calculation.
 *
 * You can see an example of topology v2 config of ssp below. In this example the default
 * object parameters are spelled out for clarity. General parameters like sample_bits are parsed
 * with set_ssp_data and hw_config object data with set_hw_data. Ssp can have multiple hw_configs.
 * Values are saved into intermediate structs and the vendor specific blob is calculated at the end
 * of parsing with ssp_calculate.
 *
 * 	SSP."0" {
 *		id 			0
 *		direction		"duplex"
 *		name			NoCodec-0
 *		io_clk			38400000
 *		default_hw_conf_id	0
 *		sample_bits		16
 *		quirks			"lbm_mode"
 *		bclk_delay		0
 *		mclk_id 		0
 *		clks_control 		0
 *		frame_pulse_width	0
 *		tdm_padding_per_slot	false
 *
 *		Object.Base.hw_config."SSP0" {
 *			id	0
 *			mclk_freq	24576000
 *			bclk_freq	3072000
 *			tdm_slot_width	32
 *			format		"I2S"
 *			mclk		"codec_mclk_in"
 *			bclk		"codec_consumer"
 *			fsync		"codec_consumer"
 *			fsync_freq	48000
 *			tdm_slots	2
 *			tx_slots	3
 *			rx_slots	3
 *		}
 *	}
 */
int nhlt_ssp_set_params(struct intel_nhlt_params *nhlt, snd_config_t *cfg, snd_config_t *top)
{
	snd_config_iterator_t i, next;
	snd_config_t *items;
	snd_config_t *n;
	const char *id;
	int ret;

	ret = set_ssp_data(nhlt, cfg, top);
	if (ret < 0)
		return ret;

	ret = snd_config_search(cfg, "Object.Base.hw_config", &items);
	if (ret < 0)
		return ret;

	snd_config_for_each(i, next, items) {
		n = snd_config_iterator_entry(i);

		if (snd_config_get_id(n, &id) < 0)
			continue;

		ret = set_hw_config(nhlt, n, top);
		if (ret < 0)
			return ret;
	}

	ret = ssp_calculate(nhlt);

	return ret;
}
topology: plugins - add Intel nhlt encoder plugin Add Intel nhlt acpi table encoder plugin into topology2.0 processing. Nhlt internal structure is defined in: https://01.org/sites/default/files/595976_intel_sst_nhlt.pdf Nhlt acpi table contain vendor specific binary data blobs that are used in some Intel dsp platforms for configuring the dmic and ssp hardware. The function of this code is mainly to generate the vendor specific binary blobs, but as there is existing nhlt parser code and header in kernel there's no point of re-inventing the container: just use the existing nhlt acpi table format. Basically this code is creating similar nhlt acpi table that you would get from: cat /sys/firmware/acpi/tables/NHLT This code will have implementation for dmic and ssp endpoints. Thus the code will translate the topology dai tokens into vendor specific binary blobs and pack them into nhlt acpi table. Ssp and dmic code is lifted from Sound Open Firmware (sof) code base, thus it will have BSD-3 license. This plugin can be enabled from command line with: alsatplg -DPREPROCESS_PLUGINS="nhlt" -c foo.conf -p -o bar.tplg You can also dump the nhlt binary into a file with additional define: -DNHLT_BIN="nhlt.bin" Link: https://github.com/alsa-project/alsa-utils/pull/129 Signed-off-by: Jaska Uimonen <jaska.uimonen@linux.intel.com> Signed-off-by: Jaroslav Kysela <perex@perex.cz> 2021-12-14 16:20:50 +01:00			`// SPDX-License-Identifier: BSD-3-Clause`
			`//`
			`// Copyright(c) 2021 Intel Corporation. All rights reserved.`
			`//`
			`// Author: Jaska Uimonen <jaska.uimonen@linux.intel.com>`

			`#include <stdint.h>`
			`#include <errno.h>`
			`#include <stdio.h>`
			`#include <stdlib.h>`
			`#include <string.h>`
			`#include <alsa/input.h>`
			`#include <alsa/output.h>`
			`#include <alsa/conf.h>`
			`#include <alsa/error.h>`
			`#include "intel-nhlt.h"`
			`#include "ssp-nhlt.h"`
			`#include "ssp/ssp-process.h"`

			`static int set_ssp_data(struct intel_nhlt_params nhlt, snd_config_t dai_cfg, snd_config_t *top)`
			`{`
			`const char *tdm_padding_per_slot = NULL;`
			`const char *direction = NULL;`
			`const char *quirks = NULL;`
			`long frame_pulse_width = 0;`
			`long clks_control = 0;`
			`long sample_bits = 0;`
			`long bclk_delay = 0;`
			`long dai_index = 0;`
			`long mclk_id = 0;`
			`long io_clk = 0;`
			`int ret;`

			`struct dai_values ssp_data[] = {`
			`{ "io_clk", SND_CONFIG_TYPE_INTEGER, NULL, &io_clk, NULL},`
			`{ "direction", SND_CONFIG_TYPE_STRING, NULL, NULL, &direction},`
			`{ "quirks", SND_CONFIG_TYPE_STRING, NULL, NULL, &quirks},`
			`{ "dai_index", SND_CONFIG_TYPE_INTEGER, NULL, &dai_index, NULL},`
			`{ "sample_bits", SND_CONFIG_TYPE_INTEGER, NULL, &sample_bits, NULL},`
			`{ "bclk_delay", SND_CONFIG_TYPE_INTEGER, NULL, &bclk_delay, NULL},`
			`{ "mclk_id", SND_CONFIG_TYPE_INTEGER, NULL, &mclk_id, NULL},`
			`{ "clks_control", SND_CONFIG_TYPE_INTEGER, NULL, &clks_control, NULL},`
			`{ "frame_pulse_width", SND_CONFIG_TYPE_INTEGER, NULL, &frame_pulse_width, NULL},`
			`{ "tdm_padding_per_slot", SND_CONFIG_TYPE_STRING, NULL, NULL,`
			`&tdm_padding_per_slot},`
			`};`

			`ret = find_set_values(&ssp_data[0], ARRAY_SIZE(ssp_data), dai_cfg, top, "Class.Dai.SSP");`
			`if (ret < 0)`
			`return ret;`

			`return ssp_set_params(nhlt, direction, dai_index, io_clk, bclk_delay, sample_bits, mclk_id,`
			`clks_control, frame_pulse_width, tdm_padding_per_slot, quirks);`
			`}`

			`static int set_hw_config(struct intel_nhlt_params nhlt, snd_config_t cfg, snd_config_t *top)`
			`{`
			`const char *format = NULL;`
			`const char *mclk = NULL;`
			`const char *bclk = NULL;`
			`const char *bclk_invert = NULL;`
			`const char *fsync = NULL;`
			`const char *fsync_invert = NULL;`
			`long mclk_freq = 0;`
			`long bclk_freq = 0;`
			`long fsync_freq = 0;`
			`long tdm_slots = 0;`
			`long tdm_slot_width = 0;`
			`long tx_slots = 0;`
			`long rx_slots = 0;`
			`long ret;`

			`struct dai_values ssp_hw_data[] = {`
			`{"format", SND_CONFIG_TYPE_STRING, NULL, NULL, &format},`
			`{"mclk", SND_CONFIG_TYPE_STRING, NULL, NULL, &mclk},`
			`{"bclk", SND_CONFIG_TYPE_STRING, NULL, NULL, &bclk},`
			`{"fsync", SND_CONFIG_TYPE_STRING, NULL, NULL, &fsync},`
			`{"bclk_invert", SND_CONFIG_TYPE_STRING, NULL, NULL, &bclk_invert},`
			`{"fsync_invert", SND_CONFIG_TYPE_STRING, NULL, NULL, &fsync_invert},`
			`{"fsync_freq", SND_CONFIG_TYPE_INTEGER, NULL, &fsync_freq, NULL},`
			`{"bclk_freq", SND_CONFIG_TYPE_INTEGER, NULL, &bclk_freq, NULL},`
			`{"mclk_freq", SND_CONFIG_TYPE_INTEGER, NULL, &mclk_freq, NULL},`
			`{"tdm_slots", SND_CONFIG_TYPE_INTEGER, NULL, &tdm_slots, NULL},`
			`{"tdm_slot_width", SND_CONFIG_TYPE_INTEGER, NULL, &tdm_slot_width, NULL},`
			`{"tx_slots", SND_CONFIG_TYPE_INTEGER, NULL, &tx_slots, NULL},`
			`{"rx_slots", SND_CONFIG_TYPE_INTEGER, NULL, &rx_slots, NULL},`
			`};`

			`ret = find_set_values(&ssp_hw_data[0], ARRAY_SIZE(ssp_hw_data), cfg, top,`
			`"Class.Base.hw_config");`
			`if (ret < 0)`
			`return ret;`

			`return ssp_hw_set_params(nhlt, format, mclk, bclk, bclk_invert, fsync, fsync_invert,`
			`mclk_freq, bclk_freq, fsync_freq, tdm_slots, tdm_slot_width,`
			`tx_slots, rx_slots);`
			`}`

			`/* init ssp parameters, should be called before parsing dais */`
			`int nhlt_ssp_init_params(struct intel_nhlt_params *nhlt)`
			`{`
			`return ssp_init_params(nhlt);`
			`}`

			`int nhlt_ssp_get_ep_count(struct intel_nhlt_params *nhlt)`
			`{`
			`return ssp_get_vendor_blob_count(nhlt);`
			`}`

			`int nhlt_ssp_get_dir(struct intel_nhlt_params nhlt, int dai_index, uint8_t dir)`
			`{`
			`return ssp_get_dir(nhlt, dai_index, dir);`
			`}`

			`int nhlt_ssp_get_ep(struct intel_nhlt_params nhlt, struct endpoint_descriptor *eps,`
			`int dai_index, uint8_t dir)`
			`{`
			`struct endpoint_descriptor ep;`
			`struct ssp_device_specific_config ssp_conf;`
			`struct formats_config f_conf;`
			`struct format_config f_conf1[8];`
			`uint32_t sample_rate;`
			`uint16_t channel_count;`
			`uint32_t bits_per_sample;`
			`uint32_t virtualbus_id;`
			`uint32_t formats_count;`
			`uint8_t *ep_target;`
			`size_t blob_size;`
			`int ret;`
			`int i;`

			`/*`
			`* nhlt ssp structure:`
			`*`
			`* endpoint_descriptor, sizeof(struct endpoint_descriptor)`
			`* device_specific_config (headset), sizeof(struct ssp_device_specific_config)`
			`* formats_config (formats_count), sizeof(struct formats_config)`
			`* format_config (waveex), sizeof(struct format_config)`
			`* vendor_blob sizeof(vendor_blob)`
			`*/`

			`ret = ssp_get_params(nhlt, dai_index, &virtualbus_id, &formats_count);`
			`if (ret < 0) {`
			`fprintf(stderr, "nhlt_ssp_get_ep: ssp_get_params failed\n");`
			`return ret;`
			`}`

			`ep.link_type = NHLT_LINK_TYPE_SSP;`
			`ep.instance_id = 0;`
			`ep.vendor_id = NHLT_VENDOR_ID_INTEL;`
			`ep.device_id = NHLT_DEVICE_ID_INTEL_I2S_TDM;`
			`ep.revision_id = 0;`
			`ep.subsystem_id = 0;`
			`ep.device_type = 0;`

			`ep.direction = dir;`
			`/* ssp device index */`
			`ep.virtualbus_id = virtualbus_id;`
			`/* ssp config */`
			`ssp_conf.config.capabilities_size = 2;`
			`ssp_conf.device_config.virtual_slot = 0;`
			`ssp_conf.device_config.config_type = 0;`

			`/* formats_config */`
			`f_conf.formats_count = formats_count;`

			`for (i = 0; i < f_conf.formats_count; i++) {`
			`/* fill in wave format extensible types */`
			`f_conf1[i].format.wFormatTag = 0xFFFE;`

			`ret = ssp_get_hw_params(nhlt, i, &sample_rate, &channel_count, &bits_per_sample);`

			`if (ret < 0) {`
			`fprintf(stderr, "nhlt_ssp_get_ep: ssp_get_hw_params failed\n");`
			`return ret;`
			`}`

			`f_conf1[i].format.nChannels = channel_count;`
			`f_conf1[i].format.nSamplesPerSec = sample_rate;`
			`f_conf1[i].format.wBitsPerSample = bits_per_sample;`
			`f_conf1[i].format.nBlockAlign = channel_count * bits_per_sample / 8;`
			`f_conf1[i].format.nAvgBytesPerSec = sample_rate * f_conf1[i].format.nBlockAlign;`

			`/* bytes after this value in this struct */`
			`f_conf1[i].format.cbSize = 22;`
			`/* actual bits in container */`
			`f_conf1[i].format.wValidBitsPerSample = bits_per_sample;`
			`/* channel map not used at this time */`
			`f_conf1[i].format.dwChannelMask = 0;`
			`/* WAVE_FORMAT_PCM guid (0x0001) ? */`
			`f_conf1[i].format.SubFormat[0] = 0;`
			`f_conf1[i].format.SubFormat[1] = 0;`
			`f_conf1[i].format.SubFormat[2] = 0;`
			`f_conf1[i].format.SubFormat[3] = 0;`

			`ret = ssp_get_vendor_blob_size(nhlt, &blob_size);`
			`if (ret < 0) {`
			`fprintf(stderr, "nhlt_ssp_get_ep: dmic_get_vendor_blob_size failed\n");`
			`return ret;`
			`}`
			`f_conf1[i].vendor_blob.capabilities_size = blob_size;`
			`}`

			`ep.length = sizeof(struct endpoint_descriptor) +`
			`sizeof(struct ssp_device_specific_config) +`
			`sizeof(struct formats_config) +`
			`sizeof(struct format_config) * f_conf.formats_count +`
			`blob_size * f_conf.formats_count;`

			`/* allocate the final variable length ep struct */`
			`ep_target = calloc(ep.length, sizeof(uint8_t));`
			`if (!ep_target)`
			`return -ENOMEM;`

			`eps = (struct endpoint_descriptor )ep_target;`

			`/* copy all parsed sub arrays into the top level array */`
			`memcpy(ep_target, &ep, sizeof(struct endpoint_descriptor));`

			`ep_target += sizeof(struct endpoint_descriptor);`

			`memcpy(ep_target, &ssp_conf, sizeof(struct ssp_device_specific_config));`
			`ep_target += sizeof(struct ssp_device_specific_config);`

			`memcpy(ep_target, &f_conf, sizeof(struct formats_config));`
			`ep_target += sizeof(struct formats_config);`

			`/* copy all hw configs */`
			`for (i = 0; i < f_conf.formats_count; i++) {`
			`memcpy(ep_target, &f_conf1[i], sizeof(struct format_config));`
			`ep_target += sizeof(struct format_config);`
			`ret = ssp_get_vendor_blob(nhlt, ep_target, dai_index, i);`
			`if (ret < 0) {`
			`fprintf(stderr, "nhlt_sso_get_ep: ssp_get_vendor_blob failed\n");`
			`return ret;`
			`}`
			`ep_target += blob_size;`
			`}`

			`return 0;`
			`}`

			`/* Set ssp parameters from topology for ssp coefficient calculation.`
			`*`
			`* You can see an example of topology v2 config of ssp below. In this example the default`
			`* object parameters are spelled out for clarity. General parameters like sample_bits are parsed`
			`* with set_ssp_data and hw_config object data with set_hw_data. Ssp can have multiple hw_configs.`
			`* Values are saved into intermediate structs and the vendor specific blob is calculated at the end`
			`* of parsing with ssp_calculate.`
			`*`
			`* SSP."0" {`
			`* id 0`
			`* direction "duplex"`
			`* name NoCodec-0`
			`* io_clk 38400000`
			`* default_hw_conf_id 0`
			`* sample_bits 16`
			`* quirks "lbm_mode"`
			`* bclk_delay 0`
			`* mclk_id 0`
			`* clks_control 0`
			`* frame_pulse_width 0`
			`* tdm_padding_per_slot false`
			`*`
			`* Object.Base.hw_config."SSP0" {`
			`* id 0`
			`* mclk_freq 24576000`
			`* bclk_freq 3072000`
			`* tdm_slot_width 32`
			`* format "I2S"`
			`* mclk "codec_mclk_in"`
			`* bclk "codec_consumer"`
			`* fsync "codec_consumer"`
			`* fsync_freq 48000`
			`* tdm_slots 2`
			`* tx_slots 3`
			`* rx_slots 3`
			`* }`
			`* }`
			`*/`
			`int nhlt_ssp_set_params(struct intel_nhlt_params nhlt, snd_config_t cfg, snd_config_t *top)`
			`{`
			`snd_config_iterator_t i, next;`
			`snd_config_t *items;`
			`snd_config_t *n;`
			`const char *id;`
			`int ret;`

			`ret = set_ssp_data(nhlt, cfg, top);`
			`if (ret < 0)`
			`return ret;`

			`ret = snd_config_search(cfg, "Object.Base.hw_config", &items);`
			`if (ret < 0)`
			`return ret;`

			`snd_config_for_each(i, next, items) {`
			`n = snd_config_iterator_entry(i);`

			`if (snd_config_get_id(n, &id) < 0)`
			`continue;`

			`ret = set_hw_config(nhlt, n, top);`
			`if (ret < 0)`
			`return ret;`
			`}`

			`ret = ssp_calculate(nhlt);`

			`return ret;`
			`}`