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

// SPDX-License-Identifier: BSD-3-Clause
//
// Copyright(c) 2021 Intel Corporation. All rights reserved.
//
// Author: Liam Girdwood <liam.r.girdwood@linux.intel.com>
//         Keyon Jie <yang.jie@linux.intel.com>
//         Rander Wang <rander.wang@linux.intel.com>
//         Jaska Uimonen <jaska.uimonen@linux.intel.com>

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

static int popcount(uint32_t value)
{
	int bits_set = 0;

	while (value) {
		bits_set += value & 1;
		value >>= 1;
	}

	return bits_set;
}

static void ssp_calculate_intern_v15(struct intel_nhlt_params *nhlt, int hwi)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;
	int di = ssp->ssp_count;;
	struct ssp_intel_config_data_1_5 *blob15 = &ssp->ssp_blob_1_5[di][hwi];
	struct ssp_intel_config_data *blob = &ssp->ssp_blob[di][hwi];
	int i;

	blob15->gateway_attributes = ssp->ssp_blob[di][hwi].gateway_attributes;
	blob15->version = SSP_BLOB_VER_1_5;

	for (i = 0; i < 8; i++)
		blob15->ts_group[i] = blob->ts_group[i];

	blob15->ssc0 = blob->ssc0;
	blob15->ssc1 = blob->ssc1;
	blob15->sscto = blob->sscto;
	blob15->sspsp = blob->sspsp;
	blob15->sstsa = blob->sstsa;
	blob15->ssrsa = blob->ssrsa;
	blob15->ssc2 = blob->ssc2;
	blob15->sspsp2 = blob->sspsp2;
	blob15->ssc3 = blob->ssc3;
	blob15->ssioc = blob->ssioc;

	/* for now we use only 1 divider as in legacy */
	blob15->mdivctlr = blob->mdivc;
	ssp->ssp_prm[di].mdivr[hwi].count = 1;
	blob15->mdivrcnt = ssp->ssp_prm[di].mdivr[hwi].count;
	ssp->ssp_prm[di].mdivr[hwi].mdivrs[0] = blob->mdivr;

	blob15->size = sizeof(struct ssp_intel_config_data_1_5) +
		blob15->mdivrcnt * sizeof(uint32_t) +
		ssp->ssp_blob_ext[di][hwi].size;
}

static int ssp_calculate_intern(struct intel_nhlt_params *nhlt, int hwi)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;
	uint32_t active_tx_slots = 2;
	uint32_t active_rx_slots = 2;
	uint32_t inverted_frame = 0;
	uint32_t inverted_bclk = 0;
	uint32_t frame_end_padding;
	uint32_t total_sample_size;
	uint32_t slot_end_padding;
	bool start_delay = false;
	uint32_t frame_len = 0;
	uint32_t sample_width;
	uint32_t end_padding;
	uint32_t data_size;
	uint32_t bdiv_min;
	bool cfs = false;
	uint32_t clk_div;
	uint32_t bdiv;
	uint32_t tft;
	uint32_t rft;
	int di;
	int i, j;

	if (!ssp)
		return -EINVAL;

	di = ssp->ssp_count;

	/* should be eventually the lp_mode defined in pipeline */
	ssp->ssp_blob[di][hwi].gateway_attributes = 0;

	for (j = 0; j < SSP_TDM_MAX_SLOT_MAP_COUNT; j++) {
		for (i = 0; i < ssp->ssp_prm[di].hw_cfg[hwi].tdm_slots; i++)
			ssp->ssp_blob[di][hwi].ts_group[j] |= (i << (i * 4));
		for (; i < SSP_TDM_MAX_SLOT_MAP_COUNT; i++)
			ssp->ssp_blob[di][hwi].ts_group[j] |= (0xF << (i * 4));
	}

	/* reset SSP settings */
	/* sscr0 dynamic settings are DSS, EDSS, SCR, FRDC, ECS */
	ssp->ssp_blob[di][hwi].ssc0 = SSCR0_PSP | SSCR0_RIM | SSCR0_TIM;

	/* sscr1 dynamic settings are SFRMDIR, SCLKDIR, SCFR */
	ssp->ssp_blob[di][hwi].ssc1 = SSCR1_TTE | SSCR1_TTELP | SSCR1_TRAIL | SSCR1_RSRE |
		SSCR1_TSRE;

	/* sscr2 dynamic setting is LJDFD */
	ssp->ssp_blob[di][hwi].ssc2 = SSCR2_SDFD | SSCR2_TURM1;

	/* sscr3 dynamic settings are TFT, RFT */
	ssp->ssp_blob[di][hwi].ssc3 = 0;

	/* sspsp dynamic settings are SCMODE, SFRMP, DMYSTRT, SFRMWDTH */
	ssp->ssp_blob[di][hwi].sspsp = 0;

	/* sspsp2 no dynamic setting */
	ssp->ssp_blob[di][hwi].sspsp2 = 0x0;

	/* ssioc dynamic setting is SFCR */
	ssp->ssp_blob[di][hwi].ssioc = SSIOC_SCOE;

	/* ssto no dynamic setting */
	ssp->ssp_blob[di][hwi].sscto = 0x0;

	/* sstsa dynamic setting is TTSA, default 2 slots */
	ssp->ssp_blob[di][hwi].sstsa = SSTSA_SSTSA(ssp->ssp_prm[di].hw_cfg[hwi].tx_slots);

	/* ssrsa dynamic setting is RTSA, default 2 slots */
	ssp->ssp_blob[di][hwi].ssrsa = SSRSA_SSRSA(ssp->ssp_prm[di].hw_cfg[hwi].rx_slots);

	switch (ssp->ssp_prm[di].hw_cfg[hwi].format & SSP_FMT_CLOCK_PROVIDER_MASK) {
	case SSP_FMT_CBP_CFP:
		ssp->ssp_blob[di][hwi].ssc1 |= SSCR1_SCLKDIR | SSCR1_SFRMDIR;
		break;
	case SSP_FMT_CBC_CFC:
		ssp->ssp_blob[di][hwi].ssc1 |= SSCR1_SCFR;
		cfs = true;
		break;
	case SSP_FMT_CBP_CFC:
		ssp->ssp_blob[di][hwi].ssc1 |= SSCR1_SCLKDIR;
		/* FIXME: this mode has not been tested */

		cfs = true;
		break;
	case SSP_FMT_CBC_CFP:
		ssp->ssp_blob[di][hwi].ssc1 |= SSCR1_SCFR | SSCR1_SFRMDIR;
		/* FIXME: this mode has not been tested */
		break;
	default:
		fprintf(stderr, "ssp_calculate(): format & PROVIDER_MASK EINVAL\n");
		return -EINVAL;
	}

	/* clock signal polarity */
	switch (ssp->ssp_prm[di].hw_cfg[hwi].format & SSP_FMT_INV_MASK) {
	case SSP_FMT_NB_NF:
		break;
	case SSP_FMT_NB_IF:
		inverted_frame = 1; /* handled later with format */
		break;
	case SSP_FMT_IB_IF:
		inverted_bclk = 1; /* handled later with bclk idle */
		inverted_frame = 1; /* handled later with format */
		break;
	case SSP_FMT_IB_NF:
		inverted_bclk = 1; /* handled later with bclk idle */
		break;
	default:
		fprintf(stderr, "ssp_calculate: format & INV_MASK EINVAL\n");
		return -EINVAL;
	}

	/* supporting bclk idle state */
	if (ssp->ssp_prm[di].clks_control &
		SSP_INTEL_CLKCTRL_BCLK_IDLE_HIGH) {
		/* bclk idle state high */
		ssp->ssp_blob[di][hwi].sspsp |= SSPSP_SCMODE((inverted_bclk ^ 0x3) & 0x3);
	} else {
		/* bclk idle state low */
		ssp->ssp_blob[di][hwi].sspsp |= SSPSP_SCMODE(inverted_bclk);
	}

	ssp->ssp_blob[di][hwi].ssc0 |= SSCR0_MOD | SSCR0_ACS;

	/* Additional hardware settings */

	/* Receiver Time-out Interrupt Disabled/Enabled */
	ssp->ssp_blob[di][hwi].ssc1 |= (ssp->ssp_prm[di].quirks & SSP_INTEL_QUIRK_TINTE) ?
		SSCR1_TINTE : 0;

	/* Peripheral Trailing Byte Interrupts Disable/Enable */
	ssp->ssp_blob[di][hwi].ssc1 |= (ssp->ssp_prm[di].quirks & SSP_INTEL_QUIRK_PINTE) ?
		SSCR1_PINTE : 0;

	/* Enable/disable internal loopback. Output of transmit serial
	 * shifter connected to input of receive serial shifter, internally.
	 */
	ssp->ssp_blob[di][hwi].ssc1 |= (ssp->ssp_prm[di].quirks & SSP_INTEL_QUIRK_LBM) ?
		SSCR1_LBM : 0;

	/* Transmit data are driven at the same/opposite clock edge specified
	 * in SSPSP.SCMODE[1:0]
	 */
	ssp->ssp_blob[di][hwi].ssc2 |= (ssp->ssp_prm[di].quirks & SSP_INTEL_QUIRK_SMTATF) ?
		SSCR2_SMTATF : 0;

	/* Receive data are sampled at the same/opposite clock edge specified
	 * in SSPSP.SCMODE[1:0]
	 */
	ssp->ssp_blob[di][hwi].ssc2 |= (ssp->ssp_prm[di].quirks & SSP_INTEL_QUIRK_MMRATF) ?
		SSCR2_MMRATF : 0;

	/* Enable/disable the fix for PSP consumer mode TXD wait for frame
	 * de-assertion before starting the second channel
	 */
	ssp->ssp_blob[di][hwi].ssc2 |= (ssp->ssp_prm[di].quirks & SSP_INTEL_QUIRK_PSPSTWFDFD) ?
		SSCR2_PSPSTWFDFD : 0;

	/* Enable/disable the fix for PSP provider mode FSRT with dummy stop &
	 * frame end padding capability
	 */
	ssp->ssp_blob[di][hwi].ssc2 |= (ssp->ssp_prm[di].quirks & SSP_INTEL_QUIRK_PSPSRWFDFD) ?
		SSCR2_PSPSRWFDFD : 0;

	if (!ssp->ssp_prm[di].hw_cfg[hwi].mclk_rate) {
		fprintf(stderr, "ssp_calculate(): invalid MCLK = %u \n",
			ssp->ssp_prm[di].hw_cfg[hwi].mclk_rate);
		return -EINVAL;
	}

	if (!ssp->ssp_prm[di].hw_cfg[hwi].bclk_rate ||
	    ssp->ssp_prm[di].hw_cfg[hwi].bclk_rate > ssp->ssp_prm[di].hw_cfg[hwi].mclk_rate) {
		fprintf(stderr, "ssp_calculate(): BCLK %u Hz = 0 or > MCLK %u Hz\n",
			ssp->ssp_prm[di].hw_cfg[hwi].bclk_rate,
			ssp->ssp_prm[di].hw_cfg[hwi].mclk_rate);
		return -EINVAL;
	}

	/* calc frame width based on BCLK and rate - must be divisible */
	if (ssp->ssp_prm[di].hw_cfg[hwi].bclk_rate % ssp->ssp_prm[di].hw_cfg[hwi].fsync_rate) {
		fprintf(stderr, "ssp_calculate(): BCLK %u is not divisible by rate %u\n",
			ssp->ssp_prm[di].hw_cfg[hwi].bclk_rate,
			ssp->ssp_prm[di].hw_cfg[hwi].fsync_rate);
		return -EINVAL;
	}

	/* must be enough BCLKs for data */
	bdiv = ssp->ssp_prm[di].hw_cfg[hwi].bclk_rate / ssp->ssp_prm[di].hw_cfg[hwi].fsync_rate;
	if (bdiv < ssp->ssp_prm[di].hw_cfg[hwi].tdm_slot_width *
	    ssp->ssp_prm[di].hw_cfg[hwi].tdm_slots) {
		fprintf(stderr, "ssp_calculate(): not enough BCLKs need %u\n",
			ssp->ssp_prm[di].hw_cfg[hwi].tdm_slot_width *
			ssp->ssp_prm[di].hw_cfg[hwi].tdm_slots);
		return -EINVAL;
	}

	/* tdm_slot_width must be <= 38 for SSP */
	if (ssp->ssp_prm[di].hw_cfg[hwi].tdm_slot_width > 38) {
		fprintf(stderr, "ssp_calculate(): tdm_slot_width %u > 38\n",
			ssp->ssp_prm[di].hw_cfg[hwi].tdm_slot_width);
		return -EINVAL;
	}

	bdiv_min = ssp->ssp_prm[di].hw_cfg[hwi].tdm_slots *
		   (ssp->ssp_prm[di].tdm_per_slot_padding_flag ?
		    ssp->ssp_prm[di].hw_cfg[hwi].tdm_slot_width :
		    ssp->ssp_prm[di].sample_valid_bits);
	if (bdiv < bdiv_min) {
		fprintf(stderr, "ssp_calculate(): bdiv(%u) < bdiv_min(%u)\n",
			bdiv, bdiv_min);
		return -EINVAL;
	}

	frame_end_padding = bdiv - bdiv_min;
	if (frame_end_padding > SSPSP2_FEP_MASK) {
		fprintf(stderr, "ssp_calculate(): frame_end_padding too big: %u\n",
			frame_end_padding);
		return -EINVAL;
	}

	/* format */
	switch (ssp->ssp_prm[di].hw_cfg[hwi].format & SSP_FMT_FORMAT_MASK) {
	case SSP_FMT_I2S:

		start_delay = true;

		ssp->ssp_blob[di][hwi].ssc0 |= SSCR0_FRDC(ssp->ssp_prm[di].hw_cfg[hwi].tdm_slots);

		if (bdiv % 2) {
			fprintf(stderr, "ssp_calculate(): bdiv %u is not divisible by 2\n",
				bdiv);
			return -EINVAL;
		}

		/* set asserted frame length to half frame length */
		frame_len = bdiv / 2;

		/*
		 * handle frame polarity, I2S default is falling/active low,
		 * non-inverted(inverted_frame=0) -- active low(SFRMP=0),
		 * inverted(inverted_frame=1) -- rising/active high(SFRMP=1),
		 * so, we should set SFRMP to inverted_frame.
		 */
		ssp->ssp_blob[di][hwi].sspsp |= SSPSP_SFRMP(inverted_frame);

		/*
		 *  for I2S/LEFT_J, the padding has to happen at the end
		 * of each slot
		 */
		if (frame_end_padding % 2) {
			fprintf(stderr, "ssp_calculate():frame_end_padding %u not divisible by 2\n",
				frame_end_padding);
			return -EINVAL;
		}

		slot_end_padding = frame_end_padding / 2;

		if (slot_end_padding > SSP_INTEL_SLOT_PADDING_MAX) {
			/* too big padding */
			fprintf(stderr, "ssp_calculate(): slot_end_padding > %d\n",
				SSP_INTEL_SLOT_PADDING_MAX);
			return -EINVAL;
		}

		ssp->ssp_blob[di][hwi].sspsp |= SSPSP_DMYSTOP(slot_end_padding);
		slot_end_padding >>= SSPSP_DMYSTOP_BITS;
		ssp->ssp_blob[di][hwi].sspsp |= SSPSP_EDMYSTOP(slot_end_padding);

		break;

	case SSP_FMT_LEFT_J:

		/* default start_delay value is set to false */

		ssp->ssp_blob[di][hwi].ssc0 |= SSCR0_FRDC(ssp->ssp_prm[di].hw_cfg[hwi].tdm_slots);

		/* LJDFD enable */
		ssp->ssp_blob[di][hwi].ssc2 &= ~SSCR2_LJDFD;

		if (bdiv % 2) {
			fprintf(stderr, "ssp_calculate(): bdiv %u is not divisible by 2\n",
				bdiv);
			return -EINVAL;
		}

		/* set asserted frame length to half frame length */
		frame_len = bdiv / 2;

		/*
		 * handle frame polarity, LEFT_J default is rising/active high,
		 * non-inverted(inverted_frame=0) -- active high(SFRMP=1),
		 * inverted(inverted_frame=1) -- falling/active low(SFRMP=0),
		 * so, we should set SFRMP to !inverted_frame.
		 */
		ssp->ssp_blob[di][hwi].sspsp |= SSPSP_SFRMP(!inverted_frame ? 1 : 0);

		/*
		 *  for I2S/LEFT_J, the padding has to happen at the end
		 * of each slot
		 */
		if (frame_end_padding % 2) {
			fprintf(stderr, "ssp_set_config(): frame padding %u not divisible by 2\n",
				frame_end_padding);
			return -EINVAL;
		}

		slot_end_padding = frame_end_padding / 2;

		if (slot_end_padding > 15) {
			/* can't handle padding over 15 bits */
			fprintf(stderr, "ssp_set_config(): slot_end_padding %u > 15 bits\n",
				slot_end_padding);
			return -EINVAL;
		}

		ssp->ssp_blob[di][hwi].sspsp |= SSPSP_DMYSTOP(slot_end_padding);
		slot_end_padding >>= SSPSP_DMYSTOP_BITS;
		ssp->ssp_blob[di][hwi].sspsp |= SSPSP_EDMYSTOP(slot_end_padding);

		break;
	case SSP_FMT_DSP_A:

		start_delay = true;

		/* fallthrough */

	case SSP_FMT_DSP_B:

		/* default start_delay value is set to false */

		ssp->ssp_blob[di][hwi].ssc0 |= SSCR0_MOD |
			SSCR0_FRDC(ssp->ssp_prm[di].hw_cfg[hwi].tdm_slots);

		/* set asserted frame length */
		frame_len = 1; /* default */

		if (cfs && ssp->ssp_prm[di].frame_pulse_width > 0 &&
		    ssp->ssp_prm[di].frame_pulse_width <=
		    SSP_INTEL_FRAME_PULSE_WIDTH_MAX) {
			frame_len = ssp->ssp_prm[di].frame_pulse_width;
		}

		/* frame_pulse_width must less or equal 38 */
		if (ssp->ssp_prm[di].frame_pulse_width >
			SSP_INTEL_FRAME_PULSE_WIDTH_MAX) {
			fprintf(stderr, "ssp_set_config(): frame_pulse_width > %d\n",
				SSP_INTEL_FRAME_PULSE_WIDTH_MAX);
			return -EINVAL;
		}
		/*
		 * handle frame polarity, DSP_B default is rising/active high,
		 * non-inverted(inverted_frame=0) -- active high(SFRMP=1),
		 * inverted(inverted_frame=1) -- falling/active low(SFRMP=0),
		 * so, we should set SFRMP to !inverted_frame.
		 */
		ssp->ssp_blob[di][hwi].sspsp |= SSPSP_SFRMP(!inverted_frame ? 1 : 0);

		active_tx_slots = popcount(ssp->ssp_prm[di].hw_cfg[hwi].tx_slots);
		active_rx_slots = popcount(ssp->ssp_prm[di].hw_cfg[hwi].rx_slots);

		/*
		 * handle TDM mode, TDM mode has padding at the end of
		 * each slot. The amount of padding is equal to result of
		 * subtracting slot width and valid bits per slot.
		 */
		if (ssp->ssp_prm[di].tdm_per_slot_padding_flag) {
			frame_end_padding = bdiv - ssp->ssp_prm[di].hw_cfg[hwi].tdm_slots *
				ssp->ssp_prm[di].hw_cfg[hwi].tdm_slot_width;

			slot_end_padding = ssp->ssp_prm[di].hw_cfg[hwi].tdm_slot_width -
				ssp->ssp_prm[di].sample_valid_bits;

			if (slot_end_padding >
				SSP_INTEL_SLOT_PADDING_MAX) {
				fprintf(stderr, "ssp_set_config(): slot_end_padding > %d\n",
					SSP_INTEL_SLOT_PADDING_MAX);
				return -EINVAL;
			}

			ssp->ssp_blob[di][hwi].sspsp |= SSPSP_DMYSTOP(slot_end_padding);
			slot_end_padding >>= SSPSP_DMYSTOP_BITS;
			ssp->ssp_blob[di][hwi].sspsp |= SSPSP_EDMYSTOP(slot_end_padding);
		}

		ssp->ssp_blob[di][hwi].sspsp2 |= (frame_end_padding & SSPSP2_FEP_MASK);

		break;
	default:
		fprintf(stderr, "ssp_set_config(): invalid format 0x%04x\n",
			ssp->ssp_prm[di].hw_cfg[hwi].format);
		return -EINVAL;
	}

	if (start_delay)
		ssp->ssp_blob[di][hwi].sspsp |= SSPSP_FSRT;

	ssp->ssp_blob[di][hwi].sspsp |= SSPSP_SFRMWDTH(frame_len);

	data_size = ssp->ssp_prm[di].sample_valid_bits;

	if (data_size > 16)
		ssp->ssp_blob[di][hwi].ssc0 |= (SSCR0_EDSS | SSCR0_DSIZE(data_size - 16));
	else
		ssp->ssp_blob[di][hwi].ssc0 |= SSCR0_DSIZE(data_size);

	end_padding = 0;
	total_sample_size = ssp->ssp_prm[di].hw_cfg[hwi].tdm_slot_width *
		ssp->ssp_prm[di].hw_cfg[hwi].tdm_slots;
	while (ssp->ssp_prm[di].io_clk % ((total_sample_size + end_padding) *
				      ssp->ssp_prm[di].hw_cfg[hwi].fsync_rate)) {
		if (++end_padding >= 256)
			break;
	}

	if (end_padding >= 256)
		return -EINVAL;

	/* calc scr divisor */
	clk_div = ssp->ssp_prm[di].io_clk / ((total_sample_size + end_padding) *
					 ssp->ssp_prm[di].hw_cfg[hwi].fsync_rate);
	if (clk_div >= 4095)
		return -EINVAL;

	ssp->ssp_blob[di][hwi].ssc0 |= SSCR0_SCR(clk_div - 1);

	/* setting TFT and RFT */
	switch (ssp->ssp_prm[di].sample_valid_bits) {
	case 16:
		/* use 2 bytes for each slot */
		sample_width = 2;
		break;
	case 24:
	case 32:
		/* use 4 bytes for each slot */
		sample_width = 4;
		break;
	default:
		fprintf(stderr, "ssp_set_config(): sample_valid_bits %u\n",
			ssp->ssp_prm[di].sample_valid_bits);
		return -EINVAL;
	}

	tft = MIN(SSP_FIFO_DEPTH - SSP_FIFO_WATERMARK,
		  sample_width * active_tx_slots);
	rft = MIN(SSP_FIFO_DEPTH - SSP_FIFO_WATERMARK,
		  sample_width * active_rx_slots);

	ssp->ssp_blob[di][hwi].ssc3 |= SSCR3_TX(tft) | SSCR3_RX(rft);

	/* calc mn divisor */
	if (ssp->ssp_prm[di].io_clk % ssp->ssp_prm[di].hw_cfg[hwi].mclk_rate) {
		fprintf(stderr, "ssp_set_config(): io_clk not divisible with mclk\n");
		return -EINVAL;
	}

	clk_div = ssp->ssp_prm[di].io_clk / ssp->ssp_prm[di].hw_cfg[hwi].mclk_rate;
	if (clk_div > 1)
		clk_div -= 2;
	else
		clk_div = 0xFFF; /* bypass clk divider */

	ssp->ssp_blob[di][hwi].mdivr = clk_div;
	/* clock will always go through the divider */
	ssp->ssp_blob[di][hwi].ssc0 |= SSCR0_ECS;
	/* enable divider for this clock id */
	ssp->ssp_blob[di][hwi].mdivc |= BIT(ssp->ssp_prm[di].mclk_id);
	/* set mclk source always for audio cardinal clock */
	ssp->ssp_blob[di][hwi].mdivc |= MCDSS(SSP_CLOCK_AUDIO_CARDINAL);
	/* set bclk source for audio cardinal clock */
	ssp->ssp_blob[di][hwi].mdivc |= MNDSS(SSP_CLOCK_AUDIO_CARDINAL);

	return 0;
}

static int ssp_calculate_intern_ext(struct intel_nhlt_params *nhlt, int hwi)
{
	size_t aux_size, mn_size, clk_size, tr_size, run_size, sync_size, node_size, ext_size,
		link_size, size, total_size;
	struct intel_ssp_params *ssp;
	struct ssp_config_aux *aux;
	struct ssp_intel_aux_tlv *tlv;
	struct ssp_intel_mn_ctl *mn;
	struct ssp_intel_clk_ctl *clk;
	struct ssp_intel_tr_ctl *tr;
	struct ssp_intel_run_ctl *run;
	struct ssp_intel_sync_ctl *sync;
	struct ssp_intel_node_ctl *node;
	struct ssp_intel_ext_ctl *ext;
	struct ssp_intel_link_ctl *link;
	uint8_t *aux_blob;
	uint32_t enabled;
	int di, i;

	aux_size = sizeof(struct ssp_intel_aux_tlv);
	mn_size = sizeof(struct ssp_intel_mn_ctl);
	clk_size = sizeof(struct ssp_intel_clk_ctl);
	tr_size = sizeof(struct ssp_intel_tr_ctl);
	run_size = sizeof(struct ssp_intel_run_ctl);
	sync_size = sizeof(struct ssp_intel_sync_ctl);
	node_size = sizeof(struct ssp_intel_node_ctl);
	ext_size = sizeof(struct ssp_intel_ext_ctl);
	link_size = sizeof(struct ssp_intel_link_ctl);

	ssp = (struct intel_ssp_params *)nhlt->ssp_params;
	di = ssp->ssp_count;
	enabled = ssp->ssp_prm[di].aux_cfg[hwi].enabled;
	aux = &(ssp->ssp_prm[di].aux_cfg[hwi]);
	aux_blob = ssp->ssp_blob_ext[di][hwi].aux_blob;
	total_size = 0;
	size = 0;

	if (enabled & BIT(SSP_MN_DIVIDER_CONTROLS)) {
		tlv = (struct ssp_intel_aux_tlv *)aux_blob;
		mn = (struct ssp_intel_mn_ctl *)(aux_blob + aux_size);
		size = mn_size + aux_size;
		tlv->type = SSP_MN_DIVIDER_CONTROLS;
		tlv->size = mn_size;
		mn->div_m = aux->mn.m_div;
		mn->div_n = aux->mn.n_div;
		aux_blob += size;
		total_size += size;
	}

	if (enabled & BIT(SSP_DMA_CLK_CONTROLS)) {
		tlv = (struct ssp_intel_aux_tlv *)aux_blob;
		clk = (struct ssp_intel_clk_ctl *)(aux_blob + aux_size);
		size = clk_size + aux_size;
		tlv->type = SSP_DMA_CLK_CONTROLS;
		tlv->size = clk_size;
		clk->start |= SET_BITS(15, 0, aux->clk.clock_warm_up);
		clk->start |= SET_BIT(16, aux->clk.mclk);
		clk->start |= SET_BIT(17, aux->clk.warm_up_ovr);
		clk->stop |= SET_BITS(15, 0, aux->clk.clock_stop_delay);
		clk->stop |= SET_BIT(16, aux->clk.keep_running);
		clk->stop |= SET_BIT(17, aux->clk.clock_stop_ovr);
		aux_blob += size;
		total_size += size;
	}

	if (enabled & BIT(SSP_DMA_TRANSMISSION_START)) {
		tlv = (struct ssp_intel_aux_tlv *)aux_blob;
		tr = (struct ssp_intel_tr_ctl *)(aux_blob + aux_size);
		size = tr_size + aux_size;
		tlv->type = SSP_DMA_TRANSMISSION_START;
		tlv->size = tr_size;
		tr->sampling_frequency = aux->tr_start.sampling_frequency;
		tr->bit_depth = aux->tr_start.bit_depth;
		tr->channel_map = aux->tr_start.channel_map;
		tr->channel_config = aux->tr_start.channel_config;
		tr->interleaving_style = aux->tr_start.interleaving_style;
		tr->format |= SET_BITS(7, 0, aux->tr_start.number_of_channels);
		tr->format |= SET_BITS(15, 8, aux->tr_start.valid_bit_depth);
		tr->format |= SET_BITS(23, 16, aux->tr_start.sample_type);
		aux_blob += size;
		total_size += size;
	}

	if (enabled & BIT(SSP_DMA_TRANSMISSION_STOP)) {
		tlv = (struct ssp_intel_aux_tlv *)aux_blob;
		tr = (struct ssp_intel_tr_ctl *)(aux_blob + aux_size);
		size = tr_size + aux_size;
		tlv->type = SSP_DMA_TRANSMISSION_STOP;
		tlv->size = tr_size;
		tr->sampling_frequency = aux->tr_stop.sampling_frequency;
		tr->bit_depth = aux->tr_stop.bit_depth;
		tr->channel_map = aux->tr_stop.channel_map;
		tr->channel_config = aux->tr_stop.channel_config;
		tr->interleaving_style = aux->tr_stop.interleaving_style;
		tr->format |= SET_BITS(7, 0, aux->tr_stop.number_of_channels);
		tr->format |= SET_BITS(15, 8, aux->tr_stop.valid_bit_depth);
		tr->format |= SET_BITS(23, 16, aux->tr_stop.sample_type);
		aux_blob += size;
		total_size += size;
	}

	if (enabled & BIT(SSP_DMA_ALWAYS_RUNNING_MODE)) {
		tlv = (struct ssp_intel_aux_tlv *)aux_blob;
		run = (struct ssp_intel_run_ctl *)(aux_blob + aux_size);
		size = run_size + aux_size;
		tlv->type = SSP_DMA_ALWAYS_RUNNING_MODE;
		tlv->size = run_size;
		run->enabled = aux->run.always_run;
		aux_blob += size;
		total_size += size;
	}

	if (enabled & BIT(SSP_DMA_SYNC_DATA)) {
		tlv = (struct ssp_intel_aux_tlv *)aux_blob;
		sync = (struct ssp_intel_sync_ctl *)(aux_blob + aux_size);
		size = sync_size + aux_size;
		tlv->type = SSP_DMA_SYNC_DATA;
		tlv->size = sync_size;
		sync->sync_denominator = aux->sync.sync_denominator;
		sync->count = aux->sync.count;
		aux_blob += size;
		total_size += size;
		for (i = 0; i < sync->count; i++) {
			node = (struct ssp_intel_node_ctl *)(aux_blob);
			size = node_size;
			node->node_id = aux->sync.nodes[i].node_id;
			node->sampling_rate = aux->sync.nodes[i].sampling_rate;
			tlv->size += node_size;
			aux_blob += size;
			total_size += size;
		}
	}

	if (enabled & BIT(SSP_DMA_CLK_CONTROLS_EXT)) {
		tlv = (struct ssp_intel_aux_tlv *)aux_blob;
		ext = (struct ssp_intel_ext_ctl *)(aux_blob + aux_size);
		size = ext_size + aux_size;
		tlv->type = SSP_DMA_CLK_CONTROLS_EXT;
		tlv->size = ext_size;
		ext->ext_data |= SET_BIT(0, aux->ext.mclk_policy_override);
		ext->ext_data |= SET_BIT(1, aux->ext.mclk_always_running);
		ext->ext_data |= SET_BIT(2, aux->ext.mclk_starts_on_gtw_init);
		ext->ext_data |= SET_BIT(3, aux->ext.mclk_starts_on_run);
		ext->ext_data |= SET_BIT(4, aux->ext.mclk_starts_on_pause);
		ext->ext_data |= SET_BIT(5, aux->ext.mclk_stops_on_pause);
		ext->ext_data |= SET_BIT(6, aux->ext.mclk_stops_on_reset);
		ext->ext_data |= SET_BIT(8, aux->ext.bclk_policy_override);
		ext->ext_data |= SET_BIT(9, aux->ext.bclk_always_running);
		ext->ext_data |= SET_BIT(10, aux->ext.bclk_starts_on_gtw_init);
		ext->ext_data |= SET_BIT(11, aux->ext.bclk_starts_on_run);
		ext->ext_data |= SET_BIT(12, aux->ext.bclk_starts_on_pause);
		ext->ext_data |= SET_BIT(13, aux->ext.bclk_stops_on_pause);
		ext->ext_data |= SET_BIT(14, aux->ext.bclk_stops_on_reset);
		ext->ext_data |= SET_BIT(16, aux->ext.sync_policy_override);
		ext->ext_data |= SET_BIT(17, aux->ext.sync_always_running);
		ext->ext_data |= SET_BIT(18, aux->ext.sync_starts_on_gtw_init);
		ext->ext_data |= SET_BIT(19, aux->ext.sync_starts_on_run);
		ext->ext_data |= SET_BIT(20, aux->ext.sync_starts_on_pause);
		ext->ext_data |= SET_BIT(21, aux->ext.sync_stops_on_pause);
		ext->ext_data |= SET_BIT(22, aux->ext.sync_stops_on_reset);
		aux_blob += size;
		total_size += size;
	}

	if (enabled & BIT(SSP_LINK_CLK_SOURCE)) {
		tlv = (struct ssp_intel_aux_tlv *)aux_blob;
		link = (struct ssp_intel_link_ctl *)(aux_blob + aux_size);
		size = link_size + aux_size;
		tlv->type = SSP_LINK_CLK_SOURCE;
		tlv->size = link_size;
		link->clock_source = aux->link.clock_source;
		aux_blob += size;
		total_size += size;
	}

	ssp->ssp_blob_ext[di][hwi].size = total_size;

	return 0;
}



int ssp_calculate(struct intel_nhlt_params *nhlt)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;
	int i;

	if (!ssp)
		return -EINVAL;

	/* calculate blob for every hw config */
	for (i = 0; i < ssp->ssp_hw_config_count[ssp->ssp_count]; i++) {
		if (ssp_calculate_intern(nhlt, i) < 0)
			return -EINVAL;
		if (ssp_calculate_intern_ext(nhlt, i) < 0)
			return -EINVAL;
		/* v15 blob is made from legacy blob, so it can't fail */
		ssp_calculate_intern_v15(nhlt, i);
	}

	ssp_print_internal(ssp);
	ssp_print_calculated(ssp);

	ssp->ssp_count++;

	return 0;
}

int ssp_get_dir(struct intel_nhlt_params *nhlt, int dai_index, uint8_t *dir)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;

	if (!ssp)
		return -EINVAL;

	*dir = ssp->ssp_prm[dai_index].direction;

	return 0;
}

int ssp_get_params(struct intel_nhlt_params *nhlt, int dai_index, uint32_t *virtualbus_id,
		   uint32_t *formats_count)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;

	if (!ssp)
		return -EINVAL;

	*virtualbus_id = ssp->ssp_dai_index[dai_index];
	*formats_count = ssp->ssp_hw_config_count[dai_index];

	return 0;
}

int ssp_get_hw_params(struct intel_nhlt_params *nhlt, int dai_index, int hw_index,
		      uint32_t *sample_rate, uint16_t *channel_count, uint32_t *bits_per_sample)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;

	if (!ssp)
		return -EINVAL;

	*channel_count = ssp->ssp_prm[dai_index].hw_cfg[hw_index].tdm_slots;
	*sample_rate = ssp->ssp_prm[dai_index].hw_cfg[hw_index].fsync_rate;
	*bits_per_sample = ssp->ssp_prm[dai_index].hw_cfg[hw_index].tdm_slot_width;

	return 0;
}

/*
 * Build ssp vendor blob from calculated parameters.
 *
 * Supposed to be called after all ssp DAIs are parsed from topology and the final nhlt blob is
 * generated.
 */
int ssp_get_vendor_blob_size(struct intel_nhlt_params *nhlt, int dai_index,
			     int hw_config_index, size_t *size)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;

	if (!ssp)
		return -EINVAL;

	/* set size for the blob */
	if (ssp->ssp_prm[dai_index].version == SSP_BLOB_VER_1_5)
		*size = ssp->ssp_blob_1_5[dai_index][hw_config_index].size;
	else
		/* legacy */
		*size = sizeof(struct ssp_intel_config_data) +
			ssp->ssp_blob_ext[dai_index][hw_config_index].size;

	return 0;
}

int ssp_get_vendor_blob_count(struct intel_nhlt_params *nhlt)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;

	if (!ssp || !ssp->ssp_count)
		return -EINVAL;

	return ssp->ssp_count;
}

/* Get the size of dynamic vendor blob to reserve proper amount of memory */
int ssp_get_vendor_blob(struct intel_nhlt_params *nhlt, uint8_t *vendor_blob,
			int dai_index, int hw_config_index)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;
	uint32_t basic_len, clock_len;

	if (!ssp)
		return -EINVAL;

	/* top level struct */
	if (ssp->ssp_prm[dai_index].version == SSP_BLOB_VER_1_5) {
		basic_len = sizeof(struct ssp_intel_config_data_1_5);
		clock_len = sizeof(uint32_t) * ssp->ssp_prm[dai_index].mdivr[hw_config_index].count;
		/* basic data */
		memcpy(vendor_blob, &ssp->ssp_blob_1_5[dai_index][hw_config_index], basic_len);
		/* clock data */
		memcpy(vendor_blob + basic_len,
		       &ssp->ssp_prm[dai_index].mdivr[hw_config_index].mdivrs[0], clock_len);
		/* ext data */
		memcpy(vendor_blob + basic_len + clock_len,
		       ssp->ssp_blob_ext[dai_index][hw_config_index].aux_blob,
		       ssp->ssp_blob_ext[dai_index][hw_config_index].size);
	}
	else {
		basic_len = sizeof(struct ssp_intel_config_data);
		/*basic data */
		memcpy(vendor_blob, &ssp->ssp_blob[dai_index][hw_config_index], basic_len);
		/* ext data */
		memcpy(vendor_blob + basic_len,
		       ssp->ssp_blob_ext[dai_index][hw_config_index].aux_blob,
		       ssp->ssp_blob_ext[dai_index][hw_config_index].size);
	}

	return 0;
}

int ssp_set_params(struct intel_nhlt_params *nhlt, const char *dir, int dai_index, int io_clk,
		   int bclk_delay, int sample_bits, int mclk_id, int clks_control,
		   int frame_pulse_width, const char *tdm_padding_per_slot, const char *quirks,
		   int version)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;

	if (!ssp)
		return -EINVAL;

	if (dir) {
		if (!strcmp(dir, "playback"))
			ssp->ssp_prm[ssp->ssp_count].direction = NHLT_ENDPOINT_DIRECTION_RENDER;
		else if (!strcmp(dir, "capture"))
			ssp->ssp_prm[ssp->ssp_count].direction = NHLT_ENDPOINT_DIRECTION_CAPTURE;
		else if (!strcmp(dir, "duplex"))
			ssp->ssp_prm[ssp->ssp_count].direction =
			  NHLT_ENDPOINT_DIRECTION_FEEDBACK_FOR_RENDER + 1;
		else
			return -EINVAL;
	}
	ssp->ssp_dai_index[ssp->ssp_count] = dai_index;
	ssp->ssp_prm[ssp->ssp_count].io_clk = io_clk;
	ssp->ssp_prm[ssp->ssp_count].bclk_delay = bclk_delay;
	ssp->ssp_prm[ssp->ssp_count].sample_valid_bits = sample_bits;
	ssp->ssp_prm[ssp->ssp_count].mclk_id = mclk_id;
	ssp->ssp_prm[ssp->ssp_count].clks_control = clks_control;
	ssp->ssp_prm[ssp->ssp_count].frame_pulse_width = frame_pulse_width;
	/* let's compare the lower 16 bits as we don't send the signature from topology */
	if (version == (SSP_BLOB_VER_1_5 & ((1 << 16) - 1)))
		ssp->ssp_prm[ssp->ssp_count].version = SSP_BLOB_VER_1_5;
	if (tdm_padding_per_slot && !strcmp(tdm_padding_per_slot, "true"))
		ssp->ssp_prm[ssp->ssp_count].tdm_per_slot_padding_flag = 1;
	else
		ssp->ssp_prm[ssp->ssp_count].tdm_per_slot_padding_flag = 0;
	if (quirks && !strcmp(quirks, "lbm_mode"))
		ssp->ssp_prm[ssp->ssp_count].quirks = 64; /* 1 << 6 */
	else
		ssp->ssp_prm[ssp->ssp_count].quirks = 0;

	/* reset hw config count for this ssp instance */
	ssp->ssp_hw_config_count[ssp->ssp_count] = 0;

	return 0;
}

int ssp_hw_set_params(struct intel_nhlt_params *nhlt, const char *format, const char *mclk,
		      const char *bclk, const char *bclk_invert, const char *fsync,
		      const char *fsync_invert, int mclk_freq, int bclk_freq, int fsync_freq,
		      int tdm_slots, int tdm_slot_width, int tx_slots, int rx_slots)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;
	uint32_t hwi;

	if (!ssp)
		return -EINVAL;

	/* check that the strings are defined ?*/

	/* compose format out of clock related string variables */
	hwi = ssp->ssp_hw_config_count[ssp->ssp_count];

	if (!strcmp(format, "I2S")) {
		ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].format = SSP_FMT_I2S;
	} else if (!strcmp(format, "RIGHT_J")) {
		ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].format = SSP_FMT_RIGHT_J;
	} else if (!strcmp(format, "LEFT_J")) {
		ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].format = SSP_FMT_LEFT_J;
	} else if (!strcmp(format, "DSP_A")) {
		ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].format = SSP_FMT_DSP_A;
	} else if (!strcmp(format, "DSP_B")) {
		ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].format = SSP_FMT_DSP_B;
	} else {
		fprintf(stderr, "no valid format specified for ssp: %s\n", format);
		return -EINVAL;
	}

	/* clock directions wrt codec */
	if (bclk && !strcmp(bclk, "codec_provider")) {
		/* codec is bclk provider */
		if (fsync && !strcmp(fsync, "codec_provider"))
			ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].format |= SSP_FMT_CBP_CFP;
		else
			ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].format |= SSP_FMT_CBP_CFC;
	} else {
		/* codec is bclk consumer */
		if (fsync && !strcmp(fsync, "codec_provider"))
			ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].format |= SSP_FMT_CBC_CFP;
		else
			ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].format |= SSP_FMT_CBC_CFC;
	}

	/* inverted clocks ? */
	if (bclk_invert && !strcmp(bclk_invert, "true")) {
		if (fsync_invert && !strcmp(fsync_invert, "true"))
			ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].format |= SSP_FMT_IB_IF;
		else
			ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].format |= SSP_FMT_IB_NF;
	} else {
		if (fsync_invert && !strcmp(fsync_invert, "true"))
			ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].format |= SSP_FMT_NB_IF;
		else
			ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].format |= SSP_FMT_NB_NF;
	}

	ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].mclk_rate = mclk_freq;
	ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].bclk_rate = bclk_freq;
	ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].fsync_rate = fsync_freq;
	ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].tdm_slots = tdm_slots;
	ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].tdm_slot_width = tdm_slot_width;
	ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].tx_slots = tx_slots;
	ssp->ssp_prm[ssp->ssp_count].hw_cfg[hwi].rx_slots = rx_slots;

	ssp->ssp_hw_config_count[ssp->ssp_count]++;

	return 0;
}

int ssp_mn_set_params(struct intel_nhlt_params *nhlt, int m_div, int n_div)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;
	int di = ssp->ssp_count;
	int hwi = ssp->ssp_hw_config_count[di];

	if (di < 0 || hwi < 0)
		return -EINVAL;

	ssp->ssp_prm[di].aux_cfg[hwi].enabled |= BIT(SSP_MN_DIVIDER_CONTROLS);

	ssp->ssp_prm[di].aux_cfg[hwi].mn.m_div = m_div;
	ssp->ssp_prm[di].aux_cfg[hwi].mn.n_div = n_div;

	return 0;
}

int ssp_clk_set_params(struct intel_nhlt_params *nhlt, int clock_warm_up, int mclk, int warm_up_ovr,
		       int clock_stop_delay, int keep_running, int clock_stop_ovr)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;
	int di = ssp->ssp_count;
	int hwi = ssp->ssp_hw_config_count[di];

	if (di < 0 || hwi < 0)
		return -EINVAL;

	ssp->ssp_prm[di].aux_cfg[hwi].enabled |= BIT(SSP_DMA_CLK_CONTROLS);

	ssp->ssp_prm[di].aux_cfg[hwi].clk.clock_warm_up = clock_warm_up;
	ssp->ssp_prm[di].aux_cfg[hwi].clk.mclk = mclk;
	ssp->ssp_prm[di].aux_cfg[hwi].clk.warm_up_ovr = warm_up_ovr;
	ssp->ssp_prm[di].aux_cfg[hwi].clk.clock_stop_delay = clock_stop_delay;
	ssp->ssp_prm[di].aux_cfg[hwi].clk.keep_running = keep_running;
	ssp->ssp_prm[di].aux_cfg[hwi].clk.clock_stop_ovr = clock_stop_ovr;

	return 0;
}

int ssp_tr_start_set_params(struct intel_nhlt_params *nhlt, int sampling_frequency,
			    int bit_depth, int channel_map, int channel_config,
			    int interleaving_style, int number_of_channels,
			    int valid_bit_depth, int sample_type)
{
	struct intel_ssp_params *ssp;
	struct ssp_aux_config_tr *tr;
	int di, hwi;

	ssp = (struct intel_ssp_params *)nhlt->ssp_params;
	di = ssp->ssp_count;
	hwi = ssp->ssp_hw_config_count[di];
	if (di < 0 || hwi < 0)
		return -EINVAL;
	tr = (struct ssp_aux_config_tr *)&(ssp->ssp_prm[di].aux_cfg[hwi].tr_start);

	ssp->ssp_prm[di].aux_cfg[hwi].enabled |= BIT(SSP_DMA_TRANSMISSION_START);

	tr->sampling_frequency = sampling_frequency;
	tr->bit_depth = bit_depth;
	tr->channel_map = channel_map;
	tr->channel_config = channel_config;
	tr->interleaving_style = interleaving_style;
	tr->number_of_channels = number_of_channels;
	tr->valid_bit_depth = valid_bit_depth;
	tr->sample_type = sample_type;

	return 0;
}

int ssp_tr_stop_set_params(struct intel_nhlt_params *nhlt, int sampling_frequency,
			    int bit_depth, int channel_map, int channel_config,
			    int interleaving_style, int number_of_channels,
			    int valid_bit_depth, int sample_type)
{
	struct intel_ssp_params *ssp;
	struct ssp_aux_config_tr *tr;
	int di, hwi;

	ssp = (struct intel_ssp_params *)nhlt->ssp_params;
	di = ssp->ssp_count;
	hwi = ssp->ssp_hw_config_count[di];
	if (di < 0 || hwi < 0)
		return -EINVAL;
	tr = (struct ssp_aux_config_tr *)&(ssp->ssp_prm[di].aux_cfg[hwi].tr_stop);

	ssp->ssp_prm[di].aux_cfg[hwi].enabled |= BIT(SSP_DMA_TRANSMISSION_STOP);

	tr->sampling_frequency = sampling_frequency;
	tr->bit_depth = bit_depth;
	tr->channel_map = channel_map;
	tr->channel_config = channel_config;
	tr->interleaving_style = interleaving_style;
	tr->number_of_channels = number_of_channels;
	tr->valid_bit_depth = valid_bit_depth;
	tr->sample_type = sample_type;

	return 0;
}

int ssp_run_set_params(struct intel_nhlt_params *nhlt, int always_run)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;
	int di = ssp->ssp_count;
	int hwi = ssp->ssp_hw_config_count[di];

	if (di < 0 || hwi < 0)
		return -EINVAL;

	ssp->ssp_prm[di].aux_cfg[hwi].enabled |= BIT(SSP_DMA_ALWAYS_RUNNING_MODE);

	ssp->ssp_prm[di].aux_cfg[hwi].run.always_run = always_run;

	return 0;
}

int ssp_sync_set_params(struct intel_nhlt_params *nhlt, int sync_denominator)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;
	int di = ssp->ssp_count;
	int hwi = ssp->ssp_hw_config_count[di];

	if (di < 0 || hwi < 0)
		return -EINVAL;

	ssp->ssp_prm[di].aux_cfg[hwi].enabled |= BIT(SSP_DMA_SYNC_DATA);

	ssp->ssp_prm[di].aux_cfg[hwi].sync.sync_denominator = sync_denominator;

	return 0;
}

int ssp_node_set_params(struct intel_nhlt_params *nhlt, int node_id, int sampling_rate)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;
	int di = ssp->ssp_count;
	int hwi = ssp->ssp_hw_config_count[di];
	int count;

	if (di < 0 || hwi < 0)
		return -EINVAL;

	count = ssp->ssp_prm[di].aux_cfg[hwi].sync.count;
	if (count > SSP_MAX_DAIS)
		return -EINVAL;

	ssp->ssp_prm[di].aux_cfg[hwi].sync.nodes[count].node_id = node_id;
	ssp->ssp_prm[di].aux_cfg[hwi].sync.nodes[count].sampling_rate = sampling_rate;

	ssp->ssp_prm[di].aux_cfg[hwi].sync.count++;

	return 0;
}

int ssp_ext_set_params(struct intel_nhlt_params *nhlt, int mclk_policy_override,
		       int mclk_always_running, int mclk_starts_on_gtw_init, int mclk_starts_on_run,
		       int mclk_starts_on_pause, int mclk_stops_on_pause, int mclk_stops_on_reset,
		       int bclk_policy_override, int bclk_always_running,
		       int bclk_starts_on_gtw_init, int bclk_starts_on_run,
		       int bclk_starts_on_pause, int bclk_stops_on_pause, int bclk_stops_on_reset,
		       int sync_policy_override, int sync_always_running,
		       int sync_starts_on_gtw_init, int sync_starts_on_run,
		       int sync_starts_on_pause, int sync_stops_on_pause, int sync_stops_on_reset)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;
	int di = ssp->ssp_count;
	int hwi = ssp->ssp_hw_config_count[di];

	if (di < 0 || hwi < 0)
		return -EINVAL;

	ssp->ssp_prm[di].aux_cfg[hwi].enabled |= BIT(SSP_DMA_CLK_CONTROLS_EXT);

	ssp->ssp_prm[di].aux_cfg[hwi].ext.mclk_policy_override = mclk_policy_override;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.mclk_always_running = mclk_always_running;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.mclk_starts_on_gtw_init  = mclk_starts_on_gtw_init;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.mclk_starts_on_run = mclk_starts_on_run;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.mclk_starts_on_pause = mclk_starts_on_pause;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.mclk_stops_on_pause = mclk_stops_on_pause;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.mclk_stops_on_reset = mclk_stops_on_reset;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.bclk_policy_override = bclk_policy_override;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.bclk_always_running = bclk_always_running;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.bclk_starts_on_gtw_init = bclk_starts_on_gtw_init;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.bclk_starts_on_run = bclk_starts_on_run;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.bclk_starts_on_pause = bclk_starts_on_pause;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.bclk_stops_on_pause = bclk_stops_on_pause;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.bclk_stops_on_reset = bclk_stops_on_reset;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.sync_policy_override = sync_policy_override;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.sync_always_running = sync_always_running;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.sync_starts_on_gtw_init = sync_starts_on_gtw_init;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.sync_starts_on_run = sync_starts_on_run;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.sync_starts_on_pause = sync_starts_on_pause;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.sync_stops_on_pause = sync_stops_on_pause;
	ssp->ssp_prm[di].aux_cfg[hwi].ext.sync_stops_on_reset = sync_stops_on_reset;

	return 0;
}

int ssp_link_set_params(struct intel_nhlt_params *nhlt, int clock_source)
{
	struct intel_ssp_params *ssp = (struct intel_ssp_params *)nhlt->ssp_params;
	int di = ssp->ssp_count;
	int hwi = ssp->ssp_hw_config_count[di];

	if (di < 0 || hwi < 0)
		return -EINVAL;

	ssp->ssp_prm[di].aux_cfg[hwi].enabled |= BIT(SSP_LINK_CLK_SOURCE);

	ssp->ssp_prm[di].aux_cfg[hwi].link.clock_source = clock_source;

	return 0;
}

/* init ssp parameters, should be called before parsing dais */
int ssp_init_params(struct intel_nhlt_params *nhlt)
{
	struct intel_ssp_params *ssp;
	int i, j;

	ssp = calloc(1, sizeof(struct intel_ssp_params));
	if (!ssp)
		return -EINVAL;

	nhlt->ssp_params = ssp;
	ssp->ssp_count = 0;

	for (i = 0; i < SSP_MAX_DAIS; i++) {
		ssp->ssp_hw_config_count[i] = 0;
		for (j = 0; j < SSP_MAX_HW_CONFIG; j++)
			ssp->ssp_prm[i].aux_cfg[j].sync.count = 0;
	}

	return 0;
}