alsa-utils/topology/nhlt/intel/dmic/dmic-internal.h

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

#ifndef __DMIC_MACROS_H
#define __DMIC_MACROS_H

#include "dmic-intel.h"

#define DMIC_HW_CONTROLLERS	2
#define DMIC_HW_FIFOS		2
#define DMIC_HW_FIR_LENGTH_MAX	250

/* Get max and min signed integer values for N bits word length */
#define INT_MAX(N)	((int64_t)((1ULL << ((N) - 1)) - 1))

/* Fractional multiplication with shift and round
 * Note that the parameters px and py must be cast to (int64_t) if other type.
 */
#define Q_MULTSR_32X32(px, py, qx, qy, qp) \
	((((px) * (py) >> ((qx) + (qy) - (qp) - 1)) + 1) >> 1)

/* Convert a float number to fractional Qnx.ny format. Note that there is no
 * check for nx+ny number of bits to fit the word length of int. The parameter
 * qy must be 31 or less.
 */
#define Q_CONVERT_FLOAT(f, qy) \
	((int32_t)(((const double)f) * ((int64_t)1 << (const int)qy) + 0.5))

/* Saturation */
#define SATP_INT32(x) (((x) > INT32_MAX) ? INT32_MAX : (x))

#define DMIC_MAX_MODES 50
#define DMIC_FIR_PIPELINE_OVERHEAD 5

/* Minimum OSR is always applied for 48 kHz and less sample rates */
#define DMIC_MIN_OSR  50

/* These are used as guideline for configuring > 48 kHz sample rates. The
 * minimum OSR can be relaxed down to 40 (use 3.84 MHz clock for 96 kHz).
 */
#define DMIC_HIGH_RATE_MIN_FS	64000
#define DMIC_HIGH_RATE_OSR_MIN	40

/* Used for scaling FIR coefficients for HW */
#define DMIC_HW_FIR_COEF_MAX ((1 << (DMIC_HW_BITS_FIR_COEF - 1)) - 1)
#define DMIC_HW_FIR_COEF_Q (DMIC_HW_BITS_FIR_COEF - 1)

/* Internal precision in gains computation, e.g. Q4.28 in int32_t */
#define DMIC_FIR_SCALE_Q 28

/* Parameters used in modes computation */
#define DMIC_HW_BITS_CIC		26
#define DMIC_HW_BITS_FIR_COEF		20
#define DMIC_HW_BITS_FIR_GAIN		20
#define DMIC_HW_BITS_FIR_INPUT		22
#define DMIC_HW_BITS_FIR_OUTPUT		24
#define DMIC_HW_BITS_FIR_INTERNAL	26
#define DMIC_HW_BITS_GAIN_OUTPUT	22
#define DMIC_HW_CIC_SHIFT_MIN		-8
#define DMIC_HW_CIC_SHIFT_MAX		4
#define DMIC_HW_FIR_SHIFT_MIN		0
#define DMIC_HW_FIR_SHIFT_MAX		8
#define DMIC_HW_CIC_DECIM_MIN		5
#define DMIC_HW_CIC_DECIM_MAX		31 /* Note: Limited by BITS_CIC */
#define DMIC_HW_FIR_DECIM_MIN		2
#define DMIC_HW_FIR_DECIM_MAX		20 /* Note: Practical upper limit */
#define DMIC_HW_SENS_Q28		Q_CONVERT_FLOAT(1.0, 28) /* Q1.28 */
#define DMIC_HW_PDM_CLK_MIN		100000 /* Note: Practical min value */
#define DMIC_HW_DUTY_MIN		20 /* Note: Practical min value */
#define DMIC_HW_DUTY_MAX		80 /* Note: Practical max value */

/* OUTCONTROL0 bits */
#define OUTCONTROL0_TIE_BIT	BIT(27)
#define OUTCONTROL0_SIP_BIT	BIT(26)
#define OUTCONTROL0_FINIT_BIT	BIT(25)
#define OUTCONTROL0_FCI_BIT	BIT(24)
#define OUTCONTROL0_TIE(x)	SET_BIT(27, x)
#define OUTCONTROL0_SIP(x)	SET_BIT(26, x)
#define OUTCONTROL0_FINIT(x)	SET_BIT(25, x)
#define OUTCONTROL0_FCI(x)	SET_BIT(24, x)
#define OUTCONTROL0_BFTH(x)	SET_BITS(23, 20, x)
#define OUTCONTROL0_OF(x)	SET_BITS(19, 18, x)
#define OUTCONTROL0_TH(x)	SET_BITS(5, 0, x)

/* OUTCONTROL1 bits */
#define OUTCONTROL1_TIE_BIT	BIT(27)
#define OUTCONTROL1_SIP_BIT	BIT(26)
#define OUTCONTROL1_FINIT_BIT	BIT(25)
#define OUTCONTROL1_FCI_BIT	BIT(24)
#define OUTCONTROL1_TIE(x)	SET_BIT(27, x)
#define OUTCONTROL1_SIP(x)	SET_BIT(26, x)
#define OUTCONTROL1_FINIT(x)	SET_BIT(25, x)
#define OUTCONTROL1_FCI(x)	SET_BIT(24, x)
#define OUTCONTROL1_BFTH(x)	SET_BITS(23, 20, x)
#define OUTCONTROL1_OF(x)	SET_BITS(19, 18, x)
#define OUTCONTROL1_TH(x)	SET_BITS(5, 0, x)

/* OUTCONTROL0 bits ver1*/
#define OUTCONTROL0_IPM_VER1(x)	SET_BITS(17, 16, x)
/* OUTCONTROL1 bits ver1 */
#define OUTCONTROL1_IPM_VER1(x)	SET_BITS(17, 16, x)

/* OUTCONTROL0 bits */
#define OUTCONTROL0_IPM_VER2(x)			SET_BITS(17, 15, x)
#define OUTCONTROL0_IPM_SOURCE_1(x)		SET_BITS(14, 13, x)
#define OUTCONTROL0_IPM_SOURCE_2(x)		SET_BITS(12, 11, x)
#define OUTCONTROL0_IPM_SOURCE_3(x)		SET_BITS(10, 9, x)
#define OUTCONTROL0_IPM_SOURCE_4(x)		SET_BITS(8, 7, x)
#define OUTCONTROL0_IPM_SOURCE_MODE(x)		SET_BIT(6, x)

/* OUTCONTROL1 bits */
#define OUTCONTROL1_IPM_VER2(x)			SET_BITS(17, 15, x)
#define OUTCONTROL1_IPM_SOURCE_1(x)		SET_BITS(14, 13, x)
#define OUTCONTROL1_IPM_SOURCE_2(x)		SET_BITS(12, 11, x)
#define OUTCONTROL1_IPM_SOURCE_3(x)		SET_BITS(10, 9, x)
#define OUTCONTROL1_IPM_SOURCE_4(x)		SET_BITS(8, 7, x)
#define OUTCONTROL1_IPM_SOURCE_MODE(x)		SET_BIT(6, x)

#define OUTCONTROLX_IPM_NUMSOURCES		4

/* CIC_CONTROL bits */
#define CIC_CONTROL_SOFT_RESET_BIT	BIT(16)
#define CIC_CONTROL_CIC_START_B_BIT	BIT(15)
#define CIC_CONTROL_CIC_START_A_BIT	BIT(14)
#define CIC_CONTROL_MIC_B_POLARITY_BIT	BIT(3)
#define CIC_CONTROL_MIC_A_POLARITY_BIT	BIT(2)
#define CIC_CONTROL_MIC_MUTE_BIT	BIT(1)
#define CIC_CONTROL_STEREO_MODE_BIT	BIT(0)

#define CIC_CONTROL_SOFT_RESET(x)	SET_BIT(16, x)
#define CIC_CONTROL_CIC_START_B(x)	SET_BIT(15, x)
#define CIC_CONTROL_CIC_START_A(x)	SET_BIT(14, x)
#define CIC_CONTROL_MIC_B_POLARITY(x)	SET_BIT(3, x)
#define CIC_CONTROL_MIC_A_POLARITY(x)	SET_BIT(2, x)
#define CIC_CONTROL_MIC_MUTE(x)		SET_BIT(1, x)
#define CIC_CONTROL_STEREO_MODE(x)	SET_BIT(0, x)

/* CIC_CONFIG bits */
#define CIC_CONFIG_CIC_SHIFT(x)		SET_BITS(27, 24, x)
#define CIC_CONFIG_COMB_COUNT(x)	SET_BITS(15, 8, x)

/* CIC_CONFIG masks */
#define CIC_CONFIG_CIC_SHIFT_MASK	MASK(27, 24)
#define CIC_CONFIG_COMB_COUNT_MASK	MASK(15, 8)

/* MIC_CONTROL bits */
#define MIC_CONTROL_PDM_EN_B_BIT	BIT(1)
#define MIC_CONTROL_PDM_EN_A_BIT	BIT(0)
#define MIC_CONTROL_PDM_CLKDIV(x)	SET_BITS(15, 8, x)
#define MIC_CONTROL_PDM_SKEW(x)		SET_BITS(7, 4, x)
#define MIC_CONTROL_CLK_EDGE(x)		SET_BIT(3, x)
#define MIC_CONTROL_PDM_EN_B(x)		SET_BIT(1, x)
#define MIC_CONTROL_PDM_EN_A(x)		SET_BIT(0, x)

/* MIC_CONTROL masks */
#define MIC_CONTROL_PDM_CLKDIV_MASK	MASK(15, 8)

/* FIR_CONTROL_A bits */
#define FIR_CONTROL_A_START_BIT			BIT(7)
#define FIR_CONTROL_A_ARRAY_START_EN_BIT	BIT(6)
#define FIR_CONTROL_A_MUTE_BIT			BIT(1)
#define FIR_CONTROL_A_START(x)			SET_BIT(7, x)
#define FIR_CONTROL_A_ARRAY_START_EN(x)		SET_BIT(6, x)
#define FIR_CONTROL_A_DCCOMP(x)			SET_BIT(4, x)
#define FIR_CONTROL_A_MUTE(x)			SET_BIT(1, x)
#define FIR_CONTROL_A_STEREO(x)			SET_BIT(0, x)

/* FIR_CONFIG_A bits */
#define FIR_CONFIG_A_FIR_DECIMATION(x)		SET_BITS(20, 16, x)
#define FIR_CONFIG_A_FIR_SHIFT(x)		SET_BITS(11, 8, x)
#define FIR_CONFIG_A_FIR_LENGTH(x)		SET_BITS(7, 0, x)

/* DC offset compensation time constants */
#define DCCOMP_TC0	0
#define DCCOMP_TC1	1
#define DCCOMP_TC2	2
#define DCCOMP_TC3	3
#define DCCOMP_TC4	4
#define DCCOMP_TC5	5
#define DCCOMP_TC6	6
#define DCCOMP_TC7	7

/* DC_OFFSET_LEFT_A bits */
#define DC_OFFSET_LEFT_A_DC_OFFS(x)		SET_BITS(21, 0, x)

/* DC_OFFSET_RIGHT_A bits */
#define DC_OFFSET_RIGHT_A_DC_OFFS(x)		SET_BITS(21, 0, x)

/* OUT_GAIN_LEFT_A bits */
#define OUT_GAIN_LEFT_A_GAIN(x)			SET_BITS(19, 0, x)

/* OUT_GAIN_RIGHT_A bits */
#define OUT_GAIN_RIGHT_A_GAIN(x)		SET_BITS(19, 0, x)

/* FIR_CONTROL_B bits */
#define FIR_CONTROL_B_START_BIT			BIT(7)
#define FIR_CONTROL_B_ARRAY_START_EN_BIT	BIT(6)
#define FIR_CONTROL_B_MUTE_BIT			BIT(1)
#define FIR_CONTROL_B_START(x)			SET_BIT(7, x)
#define FIR_CONTROL_B_ARRAY_START_EN(x)		SET_BIT(6, x)
#define FIR_CONTROL_B_DCCOMP(x)			SET_BIT(4, x)
#define FIR_CONTROL_B_MUTE(x)			SET_BIT(1, x)
#define FIR_CONTROL_B_STEREO(x)			SET_BIT(0, x)

/* FIR_CONFIG_B bits */
#define FIR_CONFIG_B_FIR_DECIMATION(x)		SET_BITS(20, 16, x)
#define FIR_CONFIG_B_FIR_SHIFT(x)		SET_BITS(11, 8, x)
#define FIR_CONFIG_B_FIR_LENGTH(x)		SET_BITS(7, 0, x)

/* DC_OFFSET_LEFT_B bits */
#define DC_OFFSET_LEFT_B_DC_OFFS(x)		SET_BITS(21, 0, x)

/* DC_OFFSET_RIGHT_B bits */
#define DC_OFFSET_RIGHT_B_DC_OFFS(x)		SET_BITS(21, 0, x)

/* OUT_GAIN_LEFT_B bits */
#define OUT_GAIN_LEFT_B_GAIN(x)			SET_BITS(19, 0, x)

/* OUT_GAIN_RIGHT_B bits */
#define OUT_GAIN_RIGHT_B_GAIN(x)		SET_BITS(19, 0, x)

/* FIR coefficients */
#define FIR_COEF_A(x)				SET_BITS(19, 0, x)
#define FIR_COEF_B(x)				SET_BITS(19, 0, x)

/* structs for dmic internal calculations */
struct dmic_calc_decim_modes {
	int16_t clkdiv[DMIC_MAX_MODES];
	int16_t mcic[DMIC_MAX_MODES];
	int16_t mfir[DMIC_MAX_MODES];
	int num_of_modes;
};

struct dmic_calc_matched_modes {
	int16_t clkdiv[DMIC_MAX_MODES];
	int16_t mcic[DMIC_MAX_MODES];
	int16_t mfir_a[DMIC_MAX_MODES];
	int16_t mfir_b[DMIC_MAX_MODES];
	int num_of_modes;
};

struct dmic_calc_configuration {
	struct pdm_decim *fir_a;
	struct pdm_decim *fir_b;
	int clkdiv;
	int mcic;
	int mfir_a;
	int mfir_b;
	int cic_shift;
	int fir_a_shift;
	int fir_b_shift;
	int fir_a_length;
	int fir_b_length;
	int32_t fir_a_scale;
	int32_t fir_b_scale;
};

/* structs for gathering the parameters from topology */
struct dmic_config_pdm {
	uint16_t id;
	uint16_t enable_mic_a;
	uint16_t enable_mic_b;
	uint16_t polarity_mic_a;
	uint16_t polarity_mic_b;
	uint16_t clk_edge;
	uint16_t skew;
};

struct dmic_config_dai {
	uint32_t driver_version;
	uint32_t io_clk;
	uint32_t pdmclk_min;
	uint32_t pdmclk_max;
	uint32_t fifo_fs;
	uint16_t fifo_bits;
	uint16_t fifo_bits_b;
	uint16_t duty_min;
	uint16_t duty_max;
	uint32_t num_pdm_active;
	uint32_t wake_up_time;
	uint32_t min_clock_on_time;
	uint32_t unmute_ramp_time;
	struct dmic_config_pdm pdm[DMIC_HW_CONTROLLERS];
};

/* every pdm controller has separate fir filter for output fifos */
struct dmic_calc_fir_coeffs_array {
	uint32_t fir_len[DMIC_HW_CONTROLLERS];
	int32_t fir_coeffs[DMIC_HW_CONTROLLERS][DMIC_HW_FIFOS][DMIC_HW_FIR_LENGTH_MAX];
};

struct dmic_config_mic_vendor {
	uint8_t type;
	uint8_t panel;
	uint32_t speaker_position_distance;
	uint32_t horizontal_offset;
	uint32_t vertical_offset;
	uint8_t frequency_low_band;
	uint8_t frequency_high_band;
	uint16_t direction_angle;
	uint16_t elevation_angle;
	uint16_t vertical_angle_begin;
	uint16_t vertical_angle_end;
	uint16_t horizontal_angle_begin;
	uint16_t horizontal_angle_end;
};

struct dmic_config_mic {
	uint8_t num_mics;
	uint8_t extension;
	int8_t array_type;
	uint32_t snr;
	uint32_t sensitivity;
	struct dmic_config_mic_vendor vendor[8];
};

struct intel_dmic_params {
	/* structs to gather dmic params before calculations */
	struct dmic_config_dai dmic_prm[DMIC_HW_FIFOS];
	uint32_t dmic_dai_index;
	int dmic_count;

	/* dmic vendor blob structs */
	struct dmic_intel_config_data dmic_blob;
	struct dmic_intel_pdm_ctrl_cfg dmic_blob_pdm[DMIC_HW_CONTROLLERS];
	struct dmic_intel_fir_config dmic_blob_fir[DMIC_HW_CONTROLLERS][DMIC_HW_FIFOS];
	struct dmic_calc_fir_coeffs_array dmic_fir_array;
	struct dmic_config_mic dmic_mic_config;
};

#endif /* __DMIC_MACROS_H */
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: Seppo Ingalsuo <seppo.ingalsuo@linux.intel.com>`
			`// Jaska Uimonen <jaska.uimonen@linux.intel.com>`

			`#ifndef __DMIC_MACROS_H`
			`#define __DMIC_MACROS_H`

			`#include "dmic-intel.h"`

			`#define DMIC_HW_CONTROLLERS 2`
			`#define DMIC_HW_FIFOS 2`
			`#define DMIC_HW_FIR_LENGTH_MAX 250`

			`/* Get max and min signed integer values for N bits word length */`
			`#define INT_MAX(N) ((int64_t)((1ULL << ((N) - 1)) - 1))`

			`/* Fractional multiplication with shift and round`
			`* Note that the parameters px and py must be cast to (int64_t) if other type.`
			`*/`
			`#define Q_MULTSR_32X32(px, py, qx, qy, qp) \`
			`((((px) * (py) >> ((qx) + (qy) - (qp) - 1)) + 1) >> 1)`

			`/* Convert a float number to fractional Qnx.ny format. Note that there is no`
			`* check for nx+ny number of bits to fit the word length of int. The parameter`
			`* qy must be 31 or less.`
			`*/`
			`#define Q_CONVERT_FLOAT(f, qy) \`
			`((int32_t)(((const double)f) * ((int64_t)1 << (const int)qy) + 0.5))`

			`/* Saturation */`
			`#define SATP_INT32(x) (((x) > INT32_MAX) ? INT32_MAX : (x))`

			`#define DMIC_MAX_MODES 50`
			`#define DMIC_FIR_PIPELINE_OVERHEAD 5`

			`/* Minimum OSR is always applied for 48 kHz and less sample rates */`
			`#define DMIC_MIN_OSR 50`

			`/* These are used as guideline for configuring > 48 kHz sample rates. The`
			`* minimum OSR can be relaxed down to 40 (use 3.84 MHz clock for 96 kHz).`
			`*/`
			`#define DMIC_HIGH_RATE_MIN_FS 64000`
			`#define DMIC_HIGH_RATE_OSR_MIN 40`

			`/* Used for scaling FIR coefficients for HW */`
			`#define DMIC_HW_FIR_COEF_MAX ((1 << (DMIC_HW_BITS_FIR_COEF - 1)) - 1)`
			`#define DMIC_HW_FIR_COEF_Q (DMIC_HW_BITS_FIR_COEF - 1)`

			`/* Internal precision in gains computation, e.g. Q4.28 in int32_t */`
			`#define DMIC_FIR_SCALE_Q 28`

			`/* Parameters used in modes computation */`
			`#define DMIC_HW_BITS_CIC 26`
			`#define DMIC_HW_BITS_FIR_COEF 20`
			`#define DMIC_HW_BITS_FIR_GAIN 20`
			`#define DMIC_HW_BITS_FIR_INPUT 22`
			`#define DMIC_HW_BITS_FIR_OUTPUT 24`
			`#define DMIC_HW_BITS_FIR_INTERNAL 26`
			`#define DMIC_HW_BITS_GAIN_OUTPUT 22`
			`#define DMIC_HW_CIC_SHIFT_MIN -8`
			`#define DMIC_HW_CIC_SHIFT_MAX 4`
			`#define DMIC_HW_FIR_SHIFT_MIN 0`
			`#define DMIC_HW_FIR_SHIFT_MAX 8`
			`#define DMIC_HW_CIC_DECIM_MIN 5`
			`#define DMIC_HW_CIC_DECIM_MAX 31 /* Note: Limited by BITS_CIC */`
			`#define DMIC_HW_FIR_DECIM_MIN 2`
			`#define DMIC_HW_FIR_DECIM_MAX 20 /* Note: Practical upper limit */`
			`#define DMIC_HW_SENS_Q28 Q_CONVERT_FLOAT(1.0, 28) /* Q1.28 */`
			`#define DMIC_HW_PDM_CLK_MIN 100000 /* Note: Practical min value */`
			`#define DMIC_HW_DUTY_MIN 20 /* Note: Practical min value */`
			`#define DMIC_HW_DUTY_MAX 80 /* Note: Practical max value */`

			`/* OUTCONTROL0 bits */`
			`#define OUTCONTROL0_TIE_BIT BIT(27)`
			`#define OUTCONTROL0_SIP_BIT BIT(26)`
			`#define OUTCONTROL0_FINIT_BIT BIT(25)`
			`#define OUTCONTROL0_FCI_BIT BIT(24)`
			`#define OUTCONTROL0_TIE(x) SET_BIT(27, x)`
			`#define OUTCONTROL0_SIP(x) SET_BIT(26, x)`
			`#define OUTCONTROL0_FINIT(x) SET_BIT(25, x)`
			`#define OUTCONTROL0_FCI(x) SET_BIT(24, x)`
			`#define OUTCONTROL0_BFTH(x) SET_BITS(23, 20, x)`
			`#define OUTCONTROL0_OF(x) SET_BITS(19, 18, x)`
			`#define OUTCONTROL0_TH(x) SET_BITS(5, 0, x)`

			`/* OUTCONTROL1 bits */`
			`#define OUTCONTROL1_TIE_BIT BIT(27)`
			`#define OUTCONTROL1_SIP_BIT BIT(26)`
			`#define OUTCONTROL1_FINIT_BIT BIT(25)`
			`#define OUTCONTROL1_FCI_BIT BIT(24)`
			`#define OUTCONTROL1_TIE(x) SET_BIT(27, x)`
			`#define OUTCONTROL1_SIP(x) SET_BIT(26, x)`
			`#define OUTCONTROL1_FINIT(x) SET_BIT(25, x)`
			`#define OUTCONTROL1_FCI(x) SET_BIT(24, x)`
			`#define OUTCONTROL1_BFTH(x) SET_BITS(23, 20, x)`
			`#define OUTCONTROL1_OF(x) SET_BITS(19, 18, x)`
			`#define OUTCONTROL1_TH(x) SET_BITS(5, 0, x)`

			`/* OUTCONTROL0 bits ver1*/`
			`#define OUTCONTROL0_IPM_VER1(x) SET_BITS(17, 16, x)`
			`/* OUTCONTROL1 bits ver1 */`
			`#define OUTCONTROL1_IPM_VER1(x) SET_BITS(17, 16, x)`

			`/* OUTCONTROL0 bits */`
			`#define OUTCONTROL0_IPM_VER2(x) SET_BITS(17, 15, x)`
			`#define OUTCONTROL0_IPM_SOURCE_1(x) SET_BITS(14, 13, x)`
			`#define OUTCONTROL0_IPM_SOURCE_2(x) SET_BITS(12, 11, x)`
			`#define OUTCONTROL0_IPM_SOURCE_3(x) SET_BITS(10, 9, x)`
			`#define OUTCONTROL0_IPM_SOURCE_4(x) SET_BITS(8, 7, x)`
			`#define OUTCONTROL0_IPM_SOURCE_MODE(x) SET_BIT(6, x)`

			`/* OUTCONTROL1 bits */`
			`#define OUTCONTROL1_IPM_VER2(x) SET_BITS(17, 15, x)`
			`#define OUTCONTROL1_IPM_SOURCE_1(x) SET_BITS(14, 13, x)`
			`#define OUTCONTROL1_IPM_SOURCE_2(x) SET_BITS(12, 11, x)`
			`#define OUTCONTROL1_IPM_SOURCE_3(x) SET_BITS(10, 9, x)`
			`#define OUTCONTROL1_IPM_SOURCE_4(x) SET_BITS(8, 7, x)`
			`#define OUTCONTROL1_IPM_SOURCE_MODE(x) SET_BIT(6, x)`

			`#define OUTCONTROLX_IPM_NUMSOURCES 4`

			`/* CIC_CONTROL bits */`
			`#define CIC_CONTROL_SOFT_RESET_BIT BIT(16)`
			`#define CIC_CONTROL_CIC_START_B_BIT BIT(15)`
			`#define CIC_CONTROL_CIC_START_A_BIT BIT(14)`
			`#define CIC_CONTROL_MIC_B_POLARITY_BIT BIT(3)`
			`#define CIC_CONTROL_MIC_A_POLARITY_BIT BIT(2)`
			`#define CIC_CONTROL_MIC_MUTE_BIT BIT(1)`
			`#define CIC_CONTROL_STEREO_MODE_BIT BIT(0)`

			`#define CIC_CONTROL_SOFT_RESET(x) SET_BIT(16, x)`
			`#define CIC_CONTROL_CIC_START_B(x) SET_BIT(15, x)`
			`#define CIC_CONTROL_CIC_START_A(x) SET_BIT(14, x)`
			`#define CIC_CONTROL_MIC_B_POLARITY(x) SET_BIT(3, x)`
			`#define CIC_CONTROL_MIC_A_POLARITY(x) SET_BIT(2, x)`
			`#define CIC_CONTROL_MIC_MUTE(x) SET_BIT(1, x)`
			`#define CIC_CONTROL_STEREO_MODE(x) SET_BIT(0, x)`

			`/* CIC_CONFIG bits */`
			`#define CIC_CONFIG_CIC_SHIFT(x) SET_BITS(27, 24, x)`
			`#define CIC_CONFIG_COMB_COUNT(x) SET_BITS(15, 8, x)`

			`/* CIC_CONFIG masks */`
			`#define CIC_CONFIG_CIC_SHIFT_MASK MASK(27, 24)`
			`#define CIC_CONFIG_COMB_COUNT_MASK MASK(15, 8)`

			`/* MIC_CONTROL bits */`
			`#define MIC_CONTROL_PDM_EN_B_BIT BIT(1)`
			`#define MIC_CONTROL_PDM_EN_A_BIT BIT(0)`
			`#define MIC_CONTROL_PDM_CLKDIV(x) SET_BITS(15, 8, x)`
			`#define MIC_CONTROL_PDM_SKEW(x) SET_BITS(7, 4, x)`
			`#define MIC_CONTROL_CLK_EDGE(x) SET_BIT(3, x)`
			`#define MIC_CONTROL_PDM_EN_B(x) SET_BIT(1, x)`
			`#define MIC_CONTROL_PDM_EN_A(x) SET_BIT(0, x)`

			`/* MIC_CONTROL masks */`
			`#define MIC_CONTROL_PDM_CLKDIV_MASK MASK(15, 8)`

			`/* FIR_CONTROL_A bits */`
			`#define FIR_CONTROL_A_START_BIT BIT(7)`
			`#define FIR_CONTROL_A_ARRAY_START_EN_BIT BIT(6)`
			`#define FIR_CONTROL_A_MUTE_BIT BIT(1)`
			`#define FIR_CONTROL_A_START(x) SET_BIT(7, x)`
			`#define FIR_CONTROL_A_ARRAY_START_EN(x) SET_BIT(6, x)`
			`#define FIR_CONTROL_A_DCCOMP(x) SET_BIT(4, x)`
			`#define FIR_CONTROL_A_MUTE(x) SET_BIT(1, x)`
			`#define FIR_CONTROL_A_STEREO(x) SET_BIT(0, x)`

			`/* FIR_CONFIG_A bits */`
			`#define FIR_CONFIG_A_FIR_DECIMATION(x) SET_BITS(20, 16, x)`
			`#define FIR_CONFIG_A_FIR_SHIFT(x) SET_BITS(11, 8, x)`
			`#define FIR_CONFIG_A_FIR_LENGTH(x) SET_BITS(7, 0, x)`

			`/* DC offset compensation time constants */`
			`#define DCCOMP_TC0 0`
			`#define DCCOMP_TC1 1`
			`#define DCCOMP_TC2 2`
			`#define DCCOMP_TC3 3`
			`#define DCCOMP_TC4 4`
			`#define DCCOMP_TC5 5`
			`#define DCCOMP_TC6 6`
			`#define DCCOMP_TC7 7`

			`/* DC_OFFSET_LEFT_A bits */`
			`#define DC_OFFSET_LEFT_A_DC_OFFS(x) SET_BITS(21, 0, x)`

			`/* DC_OFFSET_RIGHT_A bits */`
			`#define DC_OFFSET_RIGHT_A_DC_OFFS(x) SET_BITS(21, 0, x)`

			`/* OUT_GAIN_LEFT_A bits */`
			`#define OUT_GAIN_LEFT_A_GAIN(x) SET_BITS(19, 0, x)`

			`/* OUT_GAIN_RIGHT_A bits */`
			`#define OUT_GAIN_RIGHT_A_GAIN(x) SET_BITS(19, 0, x)`

			`/* FIR_CONTROL_B bits */`
			`#define FIR_CONTROL_B_START_BIT BIT(7)`
			`#define FIR_CONTROL_B_ARRAY_START_EN_BIT BIT(6)`
			`#define FIR_CONTROL_B_MUTE_BIT BIT(1)`
			`#define FIR_CONTROL_B_START(x) SET_BIT(7, x)`
			`#define FIR_CONTROL_B_ARRAY_START_EN(x) SET_BIT(6, x)`
			`#define FIR_CONTROL_B_DCCOMP(x) SET_BIT(4, x)`
			`#define FIR_CONTROL_B_MUTE(x) SET_BIT(1, x)`
			`#define FIR_CONTROL_B_STEREO(x) SET_BIT(0, x)`

			`/* FIR_CONFIG_B bits */`
			`#define FIR_CONFIG_B_FIR_DECIMATION(x) SET_BITS(20, 16, x)`
			`#define FIR_CONFIG_B_FIR_SHIFT(x) SET_BITS(11, 8, x)`
			`#define FIR_CONFIG_B_FIR_LENGTH(x) SET_BITS(7, 0, x)`

			`/* DC_OFFSET_LEFT_B bits */`
			`#define DC_OFFSET_LEFT_B_DC_OFFS(x) SET_BITS(21, 0, x)`

			`/* DC_OFFSET_RIGHT_B bits */`
			`#define DC_OFFSET_RIGHT_B_DC_OFFS(x) SET_BITS(21, 0, x)`

			`/* OUT_GAIN_LEFT_B bits */`
			`#define OUT_GAIN_LEFT_B_GAIN(x) SET_BITS(19, 0, x)`

			`/* OUT_GAIN_RIGHT_B bits */`
			`#define OUT_GAIN_RIGHT_B_GAIN(x) SET_BITS(19, 0, x)`

			`/* FIR coefficients */`
			`#define FIR_COEF_A(x) SET_BITS(19, 0, x)`
			`#define FIR_COEF_B(x) SET_BITS(19, 0, x)`

			`/* structs for dmic internal calculations */`
			`struct dmic_calc_decim_modes {`
			`int16_t clkdiv[DMIC_MAX_MODES];`
			`int16_t mcic[DMIC_MAX_MODES];`
			`int16_t mfir[DMIC_MAX_MODES];`
			`int num_of_modes;`
			`};`

			`struct dmic_calc_matched_modes {`
			`int16_t clkdiv[DMIC_MAX_MODES];`
			`int16_t mcic[DMIC_MAX_MODES];`
			`int16_t mfir_a[DMIC_MAX_MODES];`
			`int16_t mfir_b[DMIC_MAX_MODES];`
			`int num_of_modes;`
			`};`

			`struct dmic_calc_configuration {`
			`struct pdm_decim *fir_a;`
			`struct pdm_decim *fir_b;`
			`int clkdiv;`
			`int mcic;`
			`int mfir_a;`
			`int mfir_b;`
			`int cic_shift;`
			`int fir_a_shift;`
			`int fir_b_shift;`
			`int fir_a_length;`
			`int fir_b_length;`
			`int32_t fir_a_scale;`
			`int32_t fir_b_scale;`
			`};`

			`/* structs for gathering the parameters from topology */`
			`struct dmic_config_pdm {`
			`uint16_t id;`
			`uint16_t enable_mic_a;`
			`uint16_t enable_mic_b;`
			`uint16_t polarity_mic_a;`
			`uint16_t polarity_mic_b;`
			`uint16_t clk_edge;`
			`uint16_t skew;`
			`};`

			`struct dmic_config_dai {`
			`uint32_t driver_version;`
			`uint32_t io_clk;`
			`uint32_t pdmclk_min;`
			`uint32_t pdmclk_max;`
			`uint32_t fifo_fs;`
			`uint16_t fifo_bits;`
			`uint16_t fifo_bits_b;`
			`uint16_t duty_min;`
			`uint16_t duty_max;`
			`uint32_t num_pdm_active;`
			`uint32_t wake_up_time;`
			`uint32_t min_clock_on_time;`
			`uint32_t unmute_ramp_time;`
			`struct dmic_config_pdm pdm[DMIC_HW_CONTROLLERS];`
			`};`

			`/* every pdm controller has separate fir filter for output fifos */`
			`struct dmic_calc_fir_coeffs_array {`
			`uint32_t fir_len[DMIC_HW_CONTROLLERS];`
			`int32_t fir_coeffs[DMIC_HW_CONTROLLERS][DMIC_HW_FIFOS][DMIC_HW_FIR_LENGTH_MAX];`
			`};`

			`struct dmic_config_mic_vendor {`
			`uint8_t type;`
			`uint8_t panel;`
			`uint32_t speaker_position_distance;`
			`uint32_t horizontal_offset;`
			`uint32_t vertical_offset;`
			`uint8_t frequency_low_band;`
			`uint8_t frequency_high_band;`
			`uint16_t direction_angle;`
			`uint16_t elevation_angle;`
			`uint16_t vertical_angle_begin;`
			`uint16_t vertical_angle_end;`
			`uint16_t horizontal_angle_begin;`
			`uint16_t horizontal_angle_end;`
			`};`

			`struct dmic_config_mic {`
			`uint8_t num_mics;`
			`uint8_t extension;`
			`int8_t array_type;`
			`uint32_t snr;`
			`uint32_t sensitivity;`
			`struct dmic_config_mic_vendor vendor[8];`
			`};`

			`struct intel_dmic_params {`
			`/* structs to gather dmic params before calculations */`
			`struct dmic_config_dai dmic_prm[DMIC_HW_FIFOS];`
			`uint32_t dmic_dai_index;`
			`int dmic_count;`

			`/* dmic vendor blob structs */`
			`struct dmic_intel_config_data dmic_blob;`
			`struct dmic_intel_pdm_ctrl_cfg dmic_blob_pdm[DMIC_HW_CONTROLLERS];`
			`struct dmic_intel_fir_config dmic_blob_fir[DMIC_HW_CONTROLLERS][DMIC_HW_FIFOS];`
			`struct dmic_calc_fir_coeffs_array dmic_fir_array;`
			`struct dmic_config_mic dmic_mic_config;`
			`};`

			`#endif /* __DMIC_MACROS_H */`