/* SPDX-License-Identifier: ((GPL-2.0 WITH Linux-syscall-note) OR BSD-3-Clause) */ /* * This file is provided under a dual BSD/GPLv2 license. When using or * redistributing this file, you may do so under either license. * * Copyright(c) 2018 Intel Corporation. All rights reserved. */ #ifndef __INCLUDE_UAPI_SOUND_SOF_USER_EQ_H__ #define __INCLUDE_UAPI_SOUND_SOF_USER_EQ_H__ /* FIR EQ type */ #define SOF_EQ_FIR_IDX_SWITCH 0 #define SOF_EQ_FIR_MAX_SIZE 4096 /* Max size allowed for coef data in bytes */ #define SOF_EQ_FIR_MAX_LENGTH 192 /* Max length for individual filter */ #define SOF_EQ_FIR_MAX_RESPONSES 8 /* A blob can define max 8 FIR EQs */ /* * eq_fir_configuration data structure contains this information * uint32_t size * This is the number of bytes need to store the received EQ * configuration. * uint16_t channels_in_config * This describes the number of channels in this EQ config data. It * can be different from PLATFORM_MAX_CHANNELS. * uint16_t number_of_responses * 0=no responses, 1=one response defined, 2=two responses defined, etc. * int16_t data[] * assign_response[channels_in_config] * 0 = use first response, 1 = use 2nd response, etc. * E.g. {0, 0, 0, 0, 1, 1, 1, 1} would apply to channels 0-3 the * same first defined response and for to channels 4-7 the second. * coef_data[] * Repeated data * { filter_length, output_shift, h[] } * for every EQ response defined where vector h has filter_length * number of coefficients. Coefficients in h[] are in Q1.15 format. * E.g. 16384 (Q1.15) = 0.5. The shifts are number of right shifts. * * NOTE: The channels_in_config must be even to have coef_data aligned to * 32 bit word in RAM. Therefore a mono EQ assign must be duplicated to 2ch * even if it would never used. Similarly a 5ch EQ assign must be increased * to 6ch. EQ init will return an error if this is not met. * * NOTE: The filter_length must be multiple of four. Therefore the filter must * be padded from the end with zeros have this condition met. */ struct sof_eq_fir_config { uint32_t size; uint16_t channels_in_config; uint16_t number_of_responses; /* reserved */ uint32_t reserved[4]; int16_t data[]; } __packed; struct sof_eq_fir_coef_data { int16_t length; /* Number of FIR taps */ int16_t out_shift; /* Amount of right shifts at output */ /* reserved */ uint32_t reserved[4]; int16_t coef[]; /* FIR coefficients */ } __packed; /* In the struct above there's two 16 bit words (length, shift) and four * reserved 32 bit words before the actual FIR coefficients. This information * is used in parsing of the configuration blob. */ #define SOF_EQ_FIR_COEF_NHEADER \ (sizeof(struct sof_eq_fir_coef_data) / sizeof(int16_t)) /* IIR EQ type */ #define SOF_EQ_IIR_IDX_SWITCH 0 #define SOF_EQ_IIR_MAX_SIZE 1024 /* Max size allowed for coef data in bytes */ #define SOF_EQ_IIR_MAX_RESPONSES 8 /* A blob can define max 8 IIR EQs */ /* eq_iir_configuration * uint32_t channels_in_config * This describes the number of channels in this EQ config data. It * can be different from PLATFORM_MAX_CHANNELS. * uint32_t number_of_responses_defined * 0=no responses, 1=one response defined, 2=two responses defined, etc. * int32_t data[] * Data consist of two parts. First is the response assign vector that * has length of channels_in_config. The latter part is coefficient * data. * uint32_t assign_response[channels_in_config] * -1 = not defined, 0 = use first response, 1 = use 2nd, etc. * E.g. {0, 0, 0, 0, -1, -1, -1, -1} would apply to channels 0-3 the * same first defined response and leave channels 4-7 unequalized. * coefficient_data[] * <1st EQ> * uint32_t num_biquads * uint32_t num_biquads_in_series * <1st biquad> * int32_t coef_a2 Q2.30 format * int32_t coef_a1 Q2.30 format * int32_t coef_b2 Q2.30 format * int32_t coef_b1 Q2.30 format * int32_t coef_b0 Q2.30 format * int32_t output_shift number of shifts right, shift left is negative * int32_t output_gain Q2.14 format * <2nd biquad> * ... * <2nd EQ> * * Note: A flat response biquad can be made with a section set to * b0 = 1.0, gain = 1.0, and other parameters set to 0 * {0, 0, 0, 0, 1073741824, 0, 16484} */ struct sof_eq_iir_config { uint32_t size; uint32_t channels_in_config; uint32_t number_of_responses; /* reserved */ uint32_t reserved[4]; int32_t data[]; /* eq_assign[channels], eq 0, eq 1, ... */ } __packed; struct sof_eq_iir_header_df2t { uint32_t num_sections; uint32_t num_sections_in_series; /* reserved */ uint32_t reserved[4]; int32_t biquads[]; /* Repeated biquad coefficients */ } __packed; struct sof_eq_iir_biquad_df2t { int32_t a2; /* Q2.30 */ int32_t a1; /* Q2.30 */ int32_t b2; /* Q2.30 */ int32_t b1; /* Q2.30 */ int32_t b0; /* Q2.30 */ int32_t output_shift; /* Number of right shifts */ int32_t output_gain; /* Q2.14 */ } __packed; /* A full 22th order equalizer with 11 biquads cover octave bands 1-11 in * in the 0 - 20 kHz bandwidth. */ #define SOF_EQ_IIR_DF2T_BIQUADS_MAX 11 /* The number of int32_t words in sof_eq_iir_header_df2t: * num_sections, num_sections_in_series, reserved[4] */ #define SOF_EQ_IIR_NHEADER_DF2T \ (sizeof(struct sof_eq_iir_header_df2t) / sizeof(int32_t)) /* The number of int32_t words in sof_eq_iir_biquad_df2t: * a2, a1, b2, b1, b0, output_shift, output_gain */ #define SOF_EQ_IIR_NBIQUAD_DF2T \ (sizeof(struct sof_eq_iir_biquad_df2t) / sizeof(int32_t)) #endif