pinebuds/tests/anc_usb/usb_audio_app.c

/***************************************************************************
 *
 * Copyright 2015-2019 BES.
 * All rights reserved. All unpublished rights reserved.
 *
 * No part of this work may be used or reproduced in any form or by any
 * means, or stored in a database or retrieval system, without prior written
 * permission of BES.
 *
 * Use of this work is governed by a license granted by BES.
 * This work contains confidential and proprietary information of
 * BES. which is protected by copyright, trade secret,
 * trademark and other intellectual property rights.
 *
 ****************************************************************************/
#include "usb_audio_app.h"
#include "analog.h"
#include "audio_resample_ex.h"
#include "audioflinger.h"
#include "cmsis.h"
#include "hal_aud.h"
#include "hal_codec.h"
#include "hal_location.h"
#include "hal_sleep.h"
#include "hal_sysfreq.h"
#include "hal_timer.h"
#include "hal_trace.h"
#include "memutils.h"
#include "pmu.h"
#include "resample_coef.h"
#include "safe_queue.h"
#include "string.h"
#include "tgt_hardware.h"
#include "usb_audio.h"
#include "usb_audio_frm_defs.h"
#include "usb_audio_sync.h"

#ifdef _VENDOR_MSG_SUPPT_
#include "usb_vendor_msg.h"
#endif

#if defined(USB_AUDIO_SPEECH)
#include "app_overlay.h"
#include "speech_process.h"
#endif

#if defined(__HW_FIR_DSD_PROCESS__)
#include "dsd_process.h"
#endif

#if defined(AUDIO_ANC_FB_MC)
#include "anc_process.h"
#endif

#include "hw_codec_iir_process.h"
#include "hw_iir_process.h"

#ifdef __AUDIO_RESAMPLE__
#ifdef SW_PLAYBACK_RESAMPLE
#if defined(CHIP_BEST1000) && (defined(ANC_APP) || defined(_DUAL_AUX_MIC_))
#error "Software playback resample conflicts with ANC/AuxMic"
#endif
#else
#ifdef CHIP_BEST1000
#error "No hardware playback resample support"
#endif
#endif

#ifndef SW_CAPTURE_RESAMPLE
#if defined(CHIP_BEST1000) || defined(CHIP_BEST2000)
#error "No hardware capture resample support"
#endif
#endif
#endif // __AUDIO_RESAMPLE__

#ifdef CODEC_DSD
#if defined(__SW_IIR_EQ_PROCESS__) || defined(__HW_FIR_EQ_PROCESS__) ||        \
    defined(__HW_IIR_EQ_PROCESS__) || defined(__HW_DAC_IIR_EQ_PROCESS__)
#error "EQ conflicts with CODEC_DSD"
#endif
#ifdef FREQ_RESP_EQ
#error "FREQ_RESP_EQ conflicts with CODEC_DSD"
#endif
#ifdef __HW_FIR_DSD_PROCESS__
#error "__HW_FIR_DSD_PROCESS__ conflicts with CODEC_DSD"
#endif
#ifdef AUDIO_ANC_FB_MC
#error "AUDIO_ANC_FB_MC conflicts with CODEC_DSD"
#endif
#ifdef NOISE_GATING
#error "NOISE_GATING conflicts with CODEC_DSD"
#endif
#ifdef NOISE_REDUCTION
#error "NOISE_REDUCTION conflicts with CODEC_DSD"
#endif
#endif

#if defined(__SW_IIR_EQ_PROCESS__)
static uint8_t audio_eq_sw_iir_index = 0;
extern const IIR_CFG_T *const audio_eq_sw_iir_cfg_list[];
#endif

#if defined(__HW_FIR_EQ_PROCESS__)
static uint8_t audio_eq_hw_fir_index = 0;
extern const FIR_CFG_T *const audio_eq_hw_fir_cfg_list[];
#endif

#if defined(__HW_DAC_IIR_EQ_PROCESS__)
static uint8_t audio_eq_hw_dac_iir_index = 0;
extern const IIR_CFG_T *const audio_eq_hw_dac_iir_cfg_list[];
#endif

#if defined(__HW_IIR_EQ_PROCESS__)
static uint8_t audio_eq_hw_iir_index = 0;
extern const IIR_CFG_T *const audio_eq_hw_iir_cfg_list[];
#endif

#define KEY_TRACE
//#define UNMUTE_WHEN_SET_VOL
#define STREAM_RATE_BITS_SETUP

#if defined(USB_AUDIO_DYN_CFG) && defined(ANC_L_R_MISALIGN_WORKAROUND)
#ifndef AUDIO_PLAYBACK_24BIT
//#define AUDIO_PLAYBACK_24BIT
#endif
#endif

#if defined(__HW_FIR_DSD_PROCESS__) || defined(CODEC_DSD)
#define DSD_SUPPORT
#endif

#ifdef TARGET_TO_MAX_DIFF
#if defined(USB_AUDIO_RECV_ENABLE) && defined(USB_AUDIO_SEND_ENABLE)
#if defined(__AUDIO_RESAMPLE__) && defined(PLL_TUNE_SAMPLE_RATE)
#define UAUD_SYNC_STREAM_TARGET
#else
#error                                                                         \
    "TARGET_TO_MAX_DIFF can be enabled only with __AUDIO_RESAMPLE__ and PLL_TUNE_SAMPLE_RATE if both playback and capture streams exist"
#endif
#endif

#ifdef USB_AUDIO_MULTIFUNC
#error "TARGET_TO_MAX_DIFF can NOT be enabled with USB_AUDIO_MULTIFUNC"
#endif
#endif // TARGET_TO_MAX_DIFF

#define VERBOSE_TRACE 0 // 0xFFFF

#ifdef TIMER1_BASE
#define TRACE_TIME(num, s, ...)                                                \
  TRACE(num + 1, "[%u] " s, FAST_TICKS_TO_US(hal_fast_sys_timer_get()),        \
        ##__VA_ARGS__)
#else
#define TRACE_TIME(num, s, ...)                                                \
  TRACE(num + 1, "[%X] " s, hal_sys_timer_get(), ##__VA_ARGS__)
#endif

#define USB_AUDIO_CPU_WAKE_USER HAL_CPU_WAKE_LOCK_USER_3

#define RECV_PAUSED_SAMPLE_RATE_FLAG (1 << 31)

#define DIFF_ERR_THRESH_PLAYBACK (sample_rate_recv / 1000 / 2)
#define DIFF_ERR_THRESH_CAPTURE (sample_rate_send / 1000 / 2)

#define DIFF_SYNC_THRESH_PLAYBACK 10
#define DIFF_SYNC_THRESH_CAPTURE 10

#define DIFF_AVG_CNT 30

#define MAX_TARGET_RATIO 0.000020f

#define MIN_VOLUME_VAL (TGT_VOLUME_LEVEL_MUTE)
#define MAX_VOLUME_VAL (TGT_VOLUME_LEVEL_QTY - 1)

#define MIN_CAP_VOLUME_VAL (TGT_ADC_VOL_LEVEL_0)
#define MAX_CAP_VOLUME_VAL (TGT_ADC_VOL_LEVEL_QTY - 1)

#define NOISE_GATING_INTERVAL MS_TO_TICKS(800)
#define NOISE_GATING_THRESH_16BIT 3 // -80dB
#define NOISE_GATING_THRESH_24BIT (NOISE_GATING_THRESH_16BIT << 8)

#define NOISE_REDUCTION_INTERVAL MS_TO_TICKS(100)
#define NOISE_REDUCTION_MATCH_CNT 200
#define NOISE_REDUCTION_THRESH_16BIT 100 // -50dB
#define NOISE_REDUCTION_THRESH_24BIT (NOISE_REDUCTION_THRESH_16BIT << 8)

#define CONFLICT_CMD_TRIG_COUNT 10
#define CONFLICT_CMD_TRIG_INTERVAL MS_TO_TICKS(20000)
#define CONFLICT_STATE_RESET_INTERVAL MS_TO_TICKS(10000)

#define CAPTURE_STABLE_INTERVAL MS_TO_TICKS(200)

#define USB_MAX_XFER_INTERVAL MS_TO_TICKS(10)

#define USB_XFER_ERR_REPORT_INTERVAL MS_TO_TICKS(5000)

#define USB_AUDIO_MIN_DBVAL (-99)

#define USB_AUDIO_VOL_UPDATE_STEP 0.00002

#ifndef USB_AUDIO_KEY_MAP
#ifdef ANDROID_ACCESSORY_SPEC
#ifdef ANDROID_VOICE_CMD_KEY
#define USB_AUDIO_KEY_VOICE_CMD                                                \
  {                                                                            \
      USB_AUDIO_HID_VOICE_CMD,                                                 \
      HAL_KEY_CODE_FN4,                                                        \
      KEY_EVENT_SET2(DOWN, UP),                                                \
  },
#else
#define USB_AUDIO_KEY_VOICE_CMD
#endif
#define USB_AUDIO_KEY_MAP                                                      \
  {                                                                            \
    {                                                                          \
        USB_AUDIO_HID_PLAY_PAUSE,                                              \
        HAL_KEY_CODE_FN1,                                                      \
        KEY_EVENT_SET2(DOWN, UP),                                              \
    },                                                                         \
        {                                                                      \
            USB_AUDIO_HID_VOL_UP,                                              \
            HAL_KEY_CODE_FN2,                                                  \
            KEY_EVENT_SET2(DOWN, UP),                                          \
        },                                                                     \
        {                                                                      \
            USB_AUDIO_HID_VOL_DOWN,                                            \
            HAL_KEY_CODE_FN3,                                                  \
            KEY_EVENT_SET2(DOWN, UP),                                          \
        },                                                                     \
        USB_AUDIO_KEY_VOICE_CMD                                                \
  }
#else
#define USB_AUDIO_KEY_MAP                                                      \
  {                                                                            \
    {                                                                          \
        USB_AUDIO_HID_PLAY_PAUSE,                                              \
        HAL_KEY_CODE_FN1,                                                      \
        KEY_EVENT_SET(CLICK),                                                  \
    },                                                                         \
        {                                                                      \
            USB_AUDIO_HID_SCAN_NEXT,                                           \
            HAL_KEY_CODE_FN1,                                                  \
            KEY_EVENT_SET(DOUBLECLICK),                                        \
        },                                                                     \
        {                                                                      \
            USB_AUDIO_HID_SCAN_PREV,                                           \
            HAL_KEY_CODE_FN1,                                                  \
            KEY_EVENT_SET(TRIPLECLICK),                                        \
        },                                                                     \
        {                                                                      \
            USB_AUDIO_HID_VOL_UP,                                              \
            HAL_KEY_CODE_FN2,                                                  \
            KEY_EVENT_SET4(CLICK, DOUBLECLICK, TRIPLECLICK, REPEAT),           \
        },                                                                     \
        {                                                                      \
            USB_AUDIO_HID_VOL_DOWN,                                            \
            HAL_KEY_CODE_FN3,                                                  \
            KEY_EVENT_SET4(CLICK, DOUBLECLICK, TRIPLECLICK, REPEAT),           \
        },                                                                     \
        {                                                                      \
            USB_AUDIO_HID_HOOK_SWITCH,                                         \
            HAL_KEY_CODE_FN4,                                                  \
            KEY_EVENT_SET(CLICK),                                              \
        },                                                                     \
  }
#endif
#endif

enum AUDIO_CMD_T {
  AUDIO_CMD_START_PLAY = 0,
  AUDIO_CMD_STOP_PLAY,
  AUDIO_CMD_START_CAPTURE,
  AUDIO_CMD_STOP_CAPTURE,
  AUDIO_CMD_SET_VOLUME,
  AUDIO_CMD_SET_CAP_VOLUME,
  AUDIO_CMD_MUTE_CTRL,
  AUDIO_CMD_CAP_MUTE_CTRL,
  AUDIO_CMD_USB_RESET,
  AUDIO_CMD_USB_DISCONNECT,
  AUDIO_CMD_USB_CONFIG,
  AUDIO_CMD_USB_SLEEP,
  AUDIO_CMD_USB_WAKEUP,
  AUDIO_CMD_RECV_PAUSE,
  AUDIO_CMD_RECV_CONTINUE,
  AUDIO_CMD_SET_RECV_RATE,
  AUDIO_CMD_SET_SEND_RATE,
  AUDIO_CMD_RESET_CODEC,
  AUDIO_CMD_NOISE_GATING,
  AUDIO_CMD_NOISE_REDUCTION,
  AUDIO_CMD_TUNE_RATE,
  AUDIO_CMD_SET_DSD_CFG,

  TEST_CMD_PERF_TEST_POWER,
  TEST_CMD_PA_ON_OFF,

  AUDIO_CMD_QTY
};

enum AUDIO_ITF_STATE_T {
  AUDIO_ITF_STATE_STOPPED = 0,
  AUDIO_ITF_STATE_STARTED,
};

enum AUDIO_STREAM_REQ_USER_T {
  AUDIO_STREAM_REQ_USB = 0,
  AUDIO_STREAM_REQ_ANC,

  AUDIO_STREAM_REQ_USER_QTY,
  AUDIO_STREAM_REQ_USER_ALL = AUDIO_STREAM_REQ_USER_QTY,
};

enum AUDIO_STREAM_STATUS_T {
  AUDIO_STREAM_OPENED = 0,
  AUDIO_STREAM_STARTED,

  AUDIO_STREAM_STATUS_QTY
};

enum AUDIO_STREAM_RUNNING_T {
  AUDIO_STREAM_RUNNING_NULL,
  AUDIO_STREAM_RUNNING_ENABLED,
  AUDIO_STREAM_RUNNING_DISABLED,
};

enum CODEC_CONFIG_LOCK_USER_T {
  CODEC_CONFIG_LOCK_RESTART_PLAY,
  CODEC_CONFIG_LOCK_RESTART_CAP,

  CODEC_CONFIG_LOCK_USER_QTY
};

enum CODEC_MUTE_USER_T {
  CODEC_MUTE_USER_CMD,
  CODEC_MUTE_USER_NOISE_GATING,

  CODEC_MUTE_USER_QTY,
  CODEC_MUTE_USER_ALL = CODEC_MUTE_USER_QTY,
};

struct USB_AUDIO_KEY_MAP_T {
  enum USB_AUDIO_HID_EVENT_T hid_event;
  enum HAL_KEY_CODE_T key_code;
  uint32_t key_event_bitset;
};

STATIC_ASSERT(8 * sizeof(((struct USB_AUDIO_KEY_MAP_T *)0)->key_event_bitset) >=
                  HAL_KEY_EVENT_NUM,
              "key_event_bitset size is too small");

#ifdef USB_AUDIO_DYN_CFG

static enum AUD_SAMPRATE_T sample_rate_play;
static enum AUD_SAMPRATE_T sample_rate_cap;
static enum AUD_SAMPRATE_T sample_rate_recv;
static enum AUD_SAMPRATE_T sample_rate_send;
static enum AUD_SAMPRATE_T new_sample_rate_recv;
static enum AUD_SAMPRATE_T new_sample_rate_send;
#ifdef AUDIO_PLAYBACK_24BIT
static
#ifndef CODEC_DSD
    const
#endif
    uint8_t sample_size_play = 4;
#else
static uint8_t sample_size_play;
#endif
static const uint8_t sample_size_cap = SAMPLE_SIZE_CAPTURE;
static uint8_t sample_size_recv;
static const uint8_t sample_size_send = SAMPLE_SIZE_SEND;
static uint8_t new_sample_size_recv;

#else // !USB_AUDIO_DYN_CFG

static const enum AUD_SAMPRATE_T sample_rate_play = SAMPLE_RATE_PLAYBACK;
static const enum AUD_SAMPRATE_T sample_rate_cap = SAMPLE_RATE_CAPTURE;
static const enum AUD_SAMPRATE_T sample_rate_recv = SAMPLE_RATE_RECV;
static const enum AUD_SAMPRATE_T sample_rate_send = SAMPLE_RATE_SEND;
static
#ifndef CODEC_DSD
    const
#endif
    uint8_t sample_size_play = SAMPLE_SIZE_PLAYBACK;
static const uint8_t sample_size_cap = SAMPLE_SIZE_CAPTURE;
static const uint8_t sample_size_recv = SAMPLE_SIZE_RECV;
static const uint8_t sample_size_send = SAMPLE_SIZE_SEND;

#endif // !USB_AUDIO_DYN_CFG

#if defined(CHIP_BEST1000) && (defined(ANC_APP) || defined(_DUAL_AUX_MIC_))
#ifdef USB_AUDIO_DYN_CFG
static enum AUD_SAMPRATE_T sample_rate_ref_cap;
#else // !USB_AUDIO_DYN_CFG
#ifdef __AUDIO_RESAMPLE__
static const enum AUD_SAMPRATE_T sample_rate_ref_cap = SAMPLE_RATE_CAPTURE;
#elif defined(USB_AUDIO_16K)
static const enum AUD_SAMPRATE_T sample_rate_ref_cap = SAMPLE_RATE_CAPTURE;
#else
static const enum AUD_SAMPRATE_T sample_rate_ref_cap =
    (SAMPLE_RATE_RECV % AUD_SAMPRATE_8000) ? AUD_SAMPRATE_44100
                                           : AUD_SAMPRATE_48000;
#endif
#endif // !USB_AUDIO_DYN_CFG
#endif // (CHIP_BEST1000 && (ANC_APP || _DUAL_AUX_MIC_))

static enum AUDIO_ITF_STATE_T playback_state = AUDIO_ITF_STATE_STOPPED;
static enum AUDIO_ITF_STATE_T capture_state = AUDIO_ITF_STATE_STOPPED;
static enum AUDIO_ITF_STATE_T recv_state = AUDIO_ITF_STATE_STOPPED;
static enum AUDIO_ITF_STATE_T send_state = AUDIO_ITF_STATE_STOPPED;

static uint8_t codec_stream_map[AUD_STREAM_NUM][AUDIO_STREAM_STATUS_QTY];
static uint8_t eq_opened;
static enum AUDIO_STREAM_RUNNING_T streams_running_req;

static uint8_t playback_paused;

static uint8_t playback_conflicted;
static uint8_t capture_conflicted;

#ifdef NOISE_GATING
enum NOISE_GATING_CMD_T {
  NOISE_GATING_CMD_NULL,
  NOISE_GATING_CMD_MUTE,
  NOISE_GATING_CMD_UNMUTE,
};
static enum NOISE_GATING_CMD_T noise_gating_cmd = NOISE_GATING_CMD_NULL;
static uint32_t last_high_signal_time;

#ifdef NOISE_REDUCTION
enum NOISE_REDUCTION_CMD_T {
  NOISE_REDUCTION_CMD_NULL,
  NOISE_REDUCTION_CMD_FIRE,
  NOISE_REDUCTION_CMD_RESTORE,
};
static enum NOISE_REDUCTION_CMD_T noise_reduction_cmd =
    NOISE_REDUCTION_CMD_NULL;
static bool nr_active;
static bool prev_samp_positive[2];
static uint16_t prev_zero_diff[2][2];
static uint16_t cur_zero_diff[2][2];
static uint16_t nr_cont_cnt;
static uint32_t last_nr_restore_time;

static void restore_noise_reduction_status(void);
#endif
#endif

static uint8_t *playback_buf;
static uint32_t playback_size;
static uint32_t playback_pos;

#ifdef AUDIO_ANC_FB_MC
static int32_t playback_samplerate_ratio;
#endif

static uint8_t *capture_buf;
static uint32_t capture_size;
static uint32_t capture_pos;

static uint8_t *playback_eq_buf;
static uint32_t playback_eq_size;

#ifdef USB_AUDIO_DYN_CFG
#ifdef KEEP_SAME_LATENCY
static uint32_t playback_max_size;
static uint32_t capture_max_size;
static uint32_t usb_recv_max_size;
static uint32_t usb_send_max_size;
#endif
static uint8_t playback_itf_set;
static uint8_t capture_itf_set;
#endif

#ifdef SW_CAPTURE_RESAMPLE
static RESAMPLE_ID resample_id;
static bool resample_cap_enabled;
static uint8_t *resample_history_buf;
static uint32_t resample_history_size;
static uint8_t *resample_input_buf;
static uint32_t resample_input_size;
#endif

static uint8_t *usb_recv_buf;
static uint32_t usb_recv_size;
static uint32_t usb_recv_rpos;
static uint32_t usb_recv_wpos;

static uint8_t *usb_send_buf;
static uint32_t usb_send_size;
static uint32_t usb_send_rpos;
static uint32_t usb_send_wpos;

static uint8_t usb_configured;

static uint8_t usb_recv_valid;
static uint8_t usb_send_valid;

static uint8_t usb_recv_init_rpos;
static uint8_t usb_send_init_wpos;

static uint8_t codec_play_seq;
static uint8_t codec_cap_seq;
static volatile uint8_t usb_recv_seq;
static volatile uint8_t usb_send_seq;

static uint8_t codec_play_valid;
static uint8_t codec_cap_valid;

#ifdef USB_AUDIO_MULTIFUNC
static const uint8_t playback_vol = AUDIO_OUTPUT_VOLUME_DEFAULT;
#else
static uint8_t playback_vol;
#endif
static uint8_t new_playback_vol;
static uint8_t new_mute_state;
static uint8_t mute_user_map;
STATIC_ASSERT(sizeof(mute_user_map) * 8 >= CODEC_MUTE_USER_QTY,
              "mute_user_map size too small");

static uint8_t capture_vol;
static uint8_t new_capture_vol;
static uint8_t new_cap_mute_state;

static uint32_t last_usb_recv_err_time;
static uint32_t usb_recv_err_cnt;
static uint32_t usb_recv_ok_cnt;

static uint32_t last_usb_send_err_time;
static uint32_t usb_send_err_cnt;
static uint32_t usb_send_ok_cnt;

#ifdef USB_AUDIO_MULTIFUNC
static uint8_t playback_conflicted2;
static enum AUDIO_ITF_STATE_T recv2_state = AUDIO_ITF_STATE_STOPPED;
static uint8_t *usb_recv2_buf;
static uint32_t usb_recv2_size;
static uint32_t usb_recv2_rpos;
static uint32_t usb_recv2_wpos;
static uint8_t usb_recv2_valid;
static uint8_t usb_recv2_init_rpos;
static uint8_t new_playback2_vol;
static uint8_t new_mute2_state;
static float new_playback_coef;
static float new_playback2_coef;
static float playback_coef;
static float playback2_coef;

static uint32_t last_usb_recv2_err_time;
static uint32_t usb_recv2_err_cnt;
static uint32_t usb_recv2_ok_cnt;

static float playback_gain_to_float(uint32_t level);
#endif

static uint8_t codec_config_lock;
STATIC_ASSERT(sizeof(codec_config_lock) * 8 >= CODEC_CONFIG_LOCK_USER_QTY,
              "codec_config_lock size too small");

static struct USB_AUDIO_STREAM_INFO_T playback_info;
static struct USB_AUDIO_STREAM_INFO_T capture_info;

static uint8_t nonconflict_start;
static uint16_t conflict_cnt;
static uint32_t conflict_time;
static uint32_t nonconflict_time;

static uint32_t codec_cap_start_time;

static uint32_t last_usb_recv_time;
static uint32_t last_usb_send_time;

#define CMD_LIST_SIZE 30
static uint32_t cmd_list[CMD_LIST_SIZE];
static uint32_t cmd_watermark;
static struct SAFE_QUEUE_T cmd_queue;

#define EXTRACT_CMD(d) ((d)&0xFF)
#define EXTRACT_SEQ(d) (((d) >> 8) & 0xFF)
#define EXTRACT_ARG(d) (((d) >> 16) & 0xFF)
#define MAKE_QUEUE_DATA(c, s, a)                                               \
  (((c)&0xFF) | ((s)&0xFF) << 8 | ((a)&0xFF) << 16)
STATIC_ASSERT(AUDIO_CMD_QTY <= 0xFF, "audio cmd num exceeds size in queue");
STATIC_ASSERT(USB_AUDIO_STATE_EVENT_QTY <= 0xFF,
              "uaud evt num exceeds size in queue");
STATIC_ASSERT(sizeof(usb_recv_seq) <= 1, "usb recv seq exceeds size in queue");
STATIC_ASSERT(sizeof(usb_send_seq) <= 1, "usb send seq exceeds size in queue");

static const struct USB_AUDIO_KEY_MAP_T key_map[] = USB_AUDIO_KEY_MAP;

#ifdef PERF_TEST_POWER_KEY
static enum HAL_CODEC_PERF_TEST_POWER_T perft_power_type;
#endif
#ifdef PA_ON_OFF_KEY
static bool pa_on_off_muted;
#endif

static float rate_tune_ratio[AUD_STREAM_NUM];

#ifdef DSD_SUPPORT
static bool usb_dsd_enabled;
static bool codec_dsd_enabled;
static uint16_t usb_dsd_cont_cnt = 0;
#ifdef CODEC_DSD
static uint8_t dsd_saved_sample_size;
#endif
#endif

#ifdef BT_USB_AUDIO_DUAL_MODE
static USB_AUDIO_ENQUEUE_CMD_CALLBACK enqueue_cmd_cb;
#endif

static void enqueue_unique_cmd(enum AUDIO_CMD_T cmd);
static void usb_audio_set_codec_volume(enum AUD_STREAM_T stream, uint8_t vol);
static void usb_audio_cmd_tune_rate(enum AUD_STREAM_T stream);

#if defined(CHIP_BEST1000) && defined(_DUAL_AUX_MIC_)

extern void damic_init(void);
extern void damic_deinit(void);

// second-order IR filter
short soir_filter(int32_t PcmValue) {
  float gain = 2.0F;
  const float NUM[3] = {0.013318022713065147, 0.02375408448278904,
                        0.010780527256429195};
  const float DEN[3] = {1, -1.6983977556228638, 0.74625039100646973};

  static float y0 = 0, y1 = 0, y2 = 0, x0 = 0, x1 = 0, x2 = 0;
  int32_t PcmOut = 0;

  // Left channel
  x0 = PcmValue * gain;
  y0 = x0 * NUM[0] + x1 * NUM[1] + x2 * NUM[2] - y1 * DEN[1] - y2 * DEN[2];
  y2 = y1;
  y1 = y0;
  x2 = x1;
  x1 = x0;

  PcmOut = (int32_t)y0;

  PcmOut = __SSAT(PcmOut, 16);

  return (short)PcmOut;
}

#ifdef DUAL_AUX_MIC_MORE_FILTER
// second-order IR filter
short soir_filter1(int32_t PcmValue) {
  // float gain = 0.003031153698;
  const float NUM[3] = {0.013318022713065147, 0.02375408448278904,
                        0.010780527256429195};
  const float DEN[3] = {1, -1.6983977556228638, 0.74625039100646973};

  static float y0 = 0, y1 = 0, y2 = 0, x0 = 0, x1 = 0, x2 = 0;
  int32_t PcmOut = 0;

  // Left channel
  // x0 = PcmValue* gain;
  x0 = PcmValue;
  y0 = x0 * NUM[0] + x1 * NUM[1] + x2 * NUM[2] - y1 * DEN[1] - y2 * DEN[2];
  y2 = y1;
  y1 = y0;
  x2 = x1;
  x1 = x0;

  PcmOut = (int32_t)y0;

  PcmOut = __SSAT(PcmOut, 16);

  return (short)PcmOut;
}

// second-order IR filter
short soir_filter2(int32_t PcmValue) {
  // float gain = 0.003031153698;
  const float NUM[3] = {0.013318022713065147, 0.02375408448278904,
                        0.010780527256429195};
  const float DEN[3] = {1, -1.6983977556228638, 0.74625039100646973};

  static float y0 = 0, y1 = 0, y2 = 0, x0 = 0, x1 = 0, x2 = 0;
  int32_t PcmOut = 0;

  // Left channel
  // x0 = PcmValue* gain;
  x0 = PcmValue;
  y0 = x0 * NUM[0] + x1 * NUM[1] + x2 * NUM[2] - y1 * DEN[1] - y2 * DEN[2];
  y2 = y1;
  y1 = y0;
  x2 = x1;
  x1 = x0;

  PcmOut = (int32_t)y0;

  PcmOut = __SSAT(PcmOut, 16);

  return (short)PcmOut;
}
#endif

static float s_f_amic3_dc;
static float s_f_amic4_dc;
static short s_amic3_dc;
static short s_amic4_dc;

static void init_amic_dc(void) {
  s_amic3_dc = 0;
  s_amic4_dc = 0;
  s_f_amic3_dc = 0.0;
  s_f_amic4_dc = 0.0;
}

static void get_amic_dc(short *src, uint32_t samp_cnt, uint32_t step) {
  uint32_t i = 0;

  float u3_1 = 0.00001;
  float u3_2 = 1 - u3_1;

  float u4_1 = 0.00001;
  float u4_2 = 1 - u4_1;

  for (i = 0; i < samp_cnt; i += (2 << step)) {
    s_f_amic3_dc = u3_2 * s_f_amic3_dc + u3_1 * src[i << 1];
    s_f_amic4_dc = u4_2 * s_f_amic4_dc + u4_1 * src[(i << 1) + 1];
  }

  s_amic3_dc = __SSAT((int)s_f_amic3_dc, 16);
  s_amic4_dc = __SSAT((int)s_f_amic4_dc, 16);
}
#endif

#ifdef FREQ_RESP_EQ

#ifndef AUDIO_PLAYBACK_24BIT
#error "FREQ_RESP_EQ requires AUDIO_PLAYBACK_24BIT"
#endif

#define FREQ_RESP_EQ_COEF_NUM 7
static float freq_resp_eq_coef[FREQ_RESP_EQ_COEF_NUM] = {
    //        -0.000155,  0.000774,  -0.003854,  0.994971,  -0.003854, 0.000774,
    //        -0.000155
    -0.000138, 0.000687, -0.003426, 0.990852, -0.003426, 0.000687, -0.000138};

static int32_t freq_resp_eq_hist[2][(FREQ_RESP_EQ_COEF_NUM - 1) * 2];
static uint8_t freq_resp_eq_hist_idx;

void freq_resp_eq_init(void) {
  int i;

  freq_resp_eq_hist_idx = 0;
  for (i = 0; i < ARRAY_SIZE(freq_resp_eq_hist[0]); i++) {
    freq_resp_eq_hist[0][i] = 0;
    freq_resp_eq_hist[1][i] = 0;
  }
}

int freq_resp_eq_run(uint8_t *buf, uint32_t len) {
  ASSERT(sample_size_play == 4,
         "Freq resp eq is running on 24-bit playback only");

  if (sample_rate_play > AUD_SAMPRATE_96000) {
    // Sample rate higher than 96K will require higher system freq, which
    // consumes more power
    return 0;
  }

  int32_t *src_buf = (int32_t *)buf;
  int32_t *dst_buf = (int32_t *)buf;
  uint32_t mono_samp_num = len / 2 / sample_size_play;
  int32_t start_idx, in_idx, coef_idx;
  int32_t in_l, in_r;
  float out_l, out_r;
  uint8_t new_seq_idx = !freq_resp_eq_hist_idx;

  if (mono_samp_num >= (FREQ_RESP_EQ_COEF_NUM - 1)) {
    start_idx = (mono_samp_num - FREQ_RESP_EQ_COEF_NUM + 1) * 2;
    for (in_idx = 0; in_idx < (FREQ_RESP_EQ_COEF_NUM - 1) * 2; in_idx++) {
      freq_resp_eq_hist[new_seq_idx][in_idx] = src_buf[start_idx + in_idx];
    }
  } else {
    start_idx = (FREQ_RESP_EQ_COEF_NUM - 1 - mono_samp_num) * 2;
    for (in_idx = 0; in_idx < start_idx; in_idx++) {
      freq_resp_eq_hist[new_seq_idx][in_idx] =
          freq_resp_eq_hist[freq_resp_eq_hist_idx][mono_samp_num * 2 + in_idx];
    }
    for (in_idx = 0; in_idx < mono_samp_num * 2; in_idx++) {
      freq_resp_eq_hist[new_seq_idx][start_idx + in_idx] = src_buf[in_idx];
    }
  }

  for (in_idx = mono_samp_num - 1; in_idx >= 0; in_idx--) {
    out_l = 0;
    out_r = 0;
    for (coef_idx = 0; coef_idx < FREQ_RESP_EQ_COEF_NUM; coef_idx++) {
      if (in_idx + coef_idx - FREQ_RESP_EQ_COEF_NUM + 1 >= 0) {
        in_l = src_buf[(in_idx + coef_idx - FREQ_RESP_EQ_COEF_NUM + 1) * 2];
        in_r = src_buf[(in_idx + coef_idx - FREQ_RESP_EQ_COEF_NUM + 1) * 2 + 1];
      } else {
        in_l =
            freq_resp_eq_hist[freq_resp_eq_hist_idx][(in_idx + coef_idx) * 2];
        in_r = freq_resp_eq_hist[freq_resp_eq_hist_idx]
                                [(in_idx + coef_idx) * 2 + 1];
      }
      out_l += in_l * freq_resp_eq_coef[coef_idx];
      out_r += in_r * freq_resp_eq_coef[coef_idx];
    }

    // TODO: Is it really neccessary to round the float?
    // dst_buf[in_idx * 2]     = __SSAT(ftoi_nearest(out_l), 24);
    // dst_buf[in_idx * 2 + 1] = __SSAT(ftoi_nearest(out_r), 24);
    dst_buf[in_idx * 2] = __SSAT((int32_t)out_l, 24);
    dst_buf[in_idx * 2 + 1] = __SSAT((int32_t)out_r, 24);
  }

  freq_resp_eq_hist_idx = new_seq_idx;

  return 0;
}

#endif // FREQ_RESP_EQ

static enum AUD_BITS_T sample_size_to_enum_playback(uint32_t size) {
  if (size == 2) {
    return AUD_BITS_16;
  } else if (size == 4) {
    return AUD_BITS_24;
  } else {
    ASSERT(false, "%s: Invalid sample size: %u", __FUNCTION__, size);
  }

  return 0;
}

static enum AUD_BITS_T sample_size_to_enum_capture(uint32_t size) {
  if (size == 2) {
    return AUD_BITS_16;
  } else if (size == 4) {
#ifdef USB_AUDIO_SEND_32BIT
    return AUD_BITS_32;
#else
    return AUD_BITS_24;
#endif
  } else {
    ASSERT(false, "%s: Invalid sample size: %u", __FUNCTION__, size);
  }

  return 0;
}

static enum AUD_CHANNEL_NUM_T chan_num_to_enum(uint32_t num) {
  return AUD_CHANNEL_NUM_1 + (num - 1);
}

static uint32_t POSSIBLY_UNUSED byte_to_samp_playback(uint32_t n) {
#if defined(USB_AUDIO_DYN_CFG) || defined(CODEC_DSD)
  return n / sample_size_play / CHAN_NUM_PLAYBACK;
#else
  return BYTE_TO_SAMP_PLAYBACK(n);
#endif
}

static uint32_t POSSIBLY_UNUSED byte_to_samp_capture(uint32_t n) {
#ifdef USB_AUDIO_DYN_CFG
  return n / sample_size_cap / CHAN_NUM_CAPTURE;
#else
  return BYTE_TO_SAMP_CAPTURE(n);
#endif
}

static uint32_t POSSIBLY_UNUSED byte_to_samp_recv(uint32_t n) {
#ifdef USB_AUDIO_DYN_CFG
  return n / sample_size_recv / CHAN_NUM_RECV;
#else
  return BYTE_TO_SAMP_RECV(n);
#endif
}

static uint32_t POSSIBLY_UNUSED byte_to_samp_send(uint32_t n) {
#ifdef USB_AUDIO_DYN_CFG
  return n / sample_size_send / CHAN_NUM_SEND;
#else
  return BYTE_TO_SAMP_SEND(n);
#endif
}

static uint32_t POSSIBLY_UNUSED samp_to_byte_playback(uint32_t n) {
#if defined(USB_AUDIO_DYN_CFG) || defined(CODEC_DSD)
  return n * sample_size_play * CHAN_NUM_PLAYBACK;
#else
  return SAMP_TO_BYTE_PLAYBACK(n);
#endif
}

static uint32_t POSSIBLY_UNUSED samp_to_byte_capture(uint32_t n) {
#ifdef USB_AUDIO_DYN_CFG
  return n * sample_size_cap * CHAN_NUM_CAPTURE;
#else
  return SAMP_TO_BYTE_CAPTURE(n);
#endif
}

static uint32_t POSSIBLY_UNUSED samp_to_byte_recv(uint32_t n) {
#ifdef USB_AUDIO_DYN_CFG
  return n * sample_size_recv * CHAN_NUM_RECV;
#else
  return SAMP_TO_BYTE_RECV(n);
#endif
}

static uint32_t POSSIBLY_UNUSED samp_to_byte_send(uint32_t n) {
#ifdef USB_AUDIO_DYN_CFG
  return n * sample_size_send * CHAN_NUM_SEND;
#else
  return SAMP_TO_BYTE_SEND(n);
#endif
}

static uint32_t playback_to_recv_len(uint32_t n) {
#if defined(USB_AUDIO_DYN_CFG) || defined(CODEC_DSD)
  uint32_t len;

  // 1) When changing recv sample rate, the play stream will be stopped and then
  // restarted.
  //    So when calculating the len, play sample rate has been changed according
  //    to recv sample rate.
  // 2) Play and recv sample rates are integral multiple of each other.

  len = samp_to_byte_recv(byte_to_samp_playback(n));
  if (sample_rate_recv == sample_rate_play) {
    return len;
  } else if (sample_rate_recv < sample_rate_play) {
    return len / (sample_rate_play / sample_rate_recv);
  } else {
    return len * (sample_rate_recv / sample_rate_play);
  }
#else
  return PLAYBACK_TO_RECV_LEN(n);
#endif
}

static uint32_t capture_to_send_len(uint32_t n) {
#ifdef USB_AUDIO_DYN_CFG
  uint32_t len;
  enum AUD_SAMPRATE_T send_rate;
  enum AUD_SAMPRATE_T cap_rate;

  // 1) When changing send sample rate, the cap stream will not be changed if
  // the play stream is active.
  //    Moreover, the cap stream might be changed if changing recv sample rate
  //    (and then play sample rate). So when calculating the len, cap sample
  //    rate might be inconsistent with send sample rate.
  // 2) Resample might be applied to the cap stream. Cap and send sample rates
  // have no integral multiple relationship.

  send_rate = sample_rate_send;
  cap_rate = sample_rate_cap;

  len = samp_to_byte_send(byte_to_samp_capture(n));
  if (send_rate == cap_rate) {
    return len;
  } else {
    // Unlikely to overflow for the max send_rate is 48000
    return ALIGN((len * send_rate + cap_rate - 1) / cap_rate,
                 sample_size_send * CHAN_NUM_SEND);
  }
#else
  return CAPTURE_TO_SEND_LEN(n);
#endif
}

#ifdef USB_AUDIO_DYN_CFG
static uint32_t POSSIBLY_UNUSED capture_to_ref_len(uint32_t n) {
  uint32_t len;

  len = samp_to_byte_send(byte_to_samp_capture(n));

#if defined(CHIP_BEST1000) && (defined(ANC_APP) || defined(_DUAL_AUX_MIC_))
  // Capture reference sample rate and capture sample rate are integral multiple
  // of each other.

  if (sample_rate_ref_cap == sample_rate_cap) {
    return len;
  } else if (sample_rate_ref_cap < sample_rate_cap) {
    return len / (sample_rate_cap / sample_rate_ref_cap);
  } else {
    return len * (sample_rate_ref_cap / sample_rate_cap);
  }
#else
  return len;
#endif
}

#ifdef KEEP_SAME_LATENCY
static uint32_t calc_usb_recv_size(enum AUD_SAMPRATE_T rate,
                                   uint8_t sample_size) {
  uint32_t size;
  size = (SAMP_RATE_TO_FRAME_SIZE(rate) * sample_size * CHAN_NUM_RECV) *
         (usb_recv_max_size / MAX_FRAME_SIZE_RECV);
  return NON_EXP_ALIGN(size, RECV_BUFF_ALIGN);
}

static uint32_t calc_usb_send_size(enum AUD_SAMPRATE_T rate) {
  uint32_t size;
  size = samp_to_byte_send(SAMP_RATE_TO_FRAME_SIZE(rate)) * usb_send_max_size /
         MAX_FRAME_SIZE_SEND;
  return NON_EXP_ALIGN(size, SEND_BUFF_ALIGN);
}

static uint32_t calc_playback_size(enum AUD_SAMPRATE_T rate) {
  uint32_t size;
  size = samp_to_byte_playback(SAMP_RATE_TO_FRAME_SIZE(rate)) *
         (playback_max_size / MAX_FRAME_SIZE_PLAYBACK);
  return NON_EXP_ALIGN(size, DAC_BUFF_ALIGN);
}

static uint32_t calc_capture_size(enum AUD_SAMPRATE_T rate) {
  uint32_t size;
  size = samp_to_byte_capture(SAMP_RATE_TO_FRAME_SIZE(rate)) *
         (capture_max_size / MAX_FRAME_SIZE_CAPTURE);
  return NON_EXP_ALIGN(size, ADC_BUFF_ALIGN);
}
#endif
#endif

static void record_conflict(int conflicted) {
  uint32_t lock;
  uint32_t interval;
  bool reset = false;

  lock = int_lock();

  if (conflicted) {
    nonconflict_start = 0;
    if (conflict_cnt == 0) {
      conflict_time = hal_sys_timer_get();
    }
    conflict_cnt++;

    if (conflict_cnt >= CONFLICT_CMD_TRIG_COUNT) {
      interval = hal_sys_timer_get() - conflict_time;
      if (interval < CONFLICT_CMD_TRIG_INTERVAL) {
        // TRACE(2,"RESET CODEC: conflict cnt=%u interval=%u ms", conflict_cnt,
        // TICKS_TO_MS(interval));
        reset = true;
      }
      conflict_cnt = 0;
    }
  } else {
    if (nonconflict_start == 0) {
      nonconflict_start = 1;
      if (conflict_cnt) {
        nonconflict_time = hal_sys_timer_get();
      }
    } else {
      if (conflict_cnt) {
        interval = hal_sys_timer_get() - nonconflict_time;
        if (interval >= CONFLICT_STATE_RESET_INTERVAL) {
          // TRACE(2,"RESET CONFLICT STATE: conflict cnt=%u nonconflict
          // interval=%u ms", conflict_cnt, TICKS_TO_MS(interval));
          conflict_cnt = 0;
        }
      }
    }
  }

  int_unlock(lock);

  if (reset) {
    // Avoid invoking cmd callback when irq is locked
    enqueue_unique_cmd(AUDIO_CMD_RESET_CODEC);
  }
}

static void reset_conflict(void) {
  uint32_t lock;

  lock = int_lock();
  conflict_cnt = 0;
  nonconflict_start = 0;
  int_unlock(lock);
}

uint8_t usb_audio_get_eq_index(AUDIO_EQ_TYPE_T audio_eq_type,
                               uint8_t anc_status) {
  uint8_t index_eq = 0;

#if defined(__SW_IIR_EQ_PROCESS__) || defined(__HW_FIR_EQ_PROCESS__) ||        \
    defined(__HW_DAC_IIR_EQ_PROCESS__) || defined(__HW_IIR_EQ_PROCESS__)
  switch (audio_eq_type) {
#if defined(__SW_IIR_EQ_PROCESS__)
  case AUDIO_EQ_TYPE_SW_IIR: {
    if (anc_status) {
      index_eq = audio_eq_sw_iir_index + 1;
    } else {
      index_eq = audio_eq_sw_iir_index;
    }

  } break;
#endif

#if defined(__HW_FIR_EQ_PROCESS__)
  case AUDIO_EQ_TYPE_HW_FIR: {
#ifdef USB_AUDIO_DYN_CFG
    if (sample_rate_recv == AUD_SAMPRATE_44100) {
      index_eq = 0;
    } else if (sample_rate_recv == AUD_SAMPRATE_48000) {
      index_eq = 1;
    } else if (sample_rate_recv == AUD_SAMPRATE_96000) {
      index_eq = 2;
    } else if (sample_rate_recv == AUD_SAMPRATE_192000) {
      index_eq = 3;
    } else {
      ASSERT(0, "[%s] sample_rate_recv(%d) is not supported", __func__,
             sample_rate_recv);
    }
    audio_eq_hw_fir_index = index_eq;
#else
    index_eq = audio_eq_hw_fir_index;
#endif
    if (anc_status) {
      index_eq = index_eq + 4;
    }
  } break;
#endif

#if defined(__HW_DAC_IIR_EQ_PROCESS__)
  case AUDIO_EQ_TYPE_HW_DAC_IIR: {
    if (anc_status) {
      index_eq = audio_eq_hw_dac_iir_index + 1;
    } else {
      index_eq = audio_eq_hw_dac_iir_index;
    }
  } break;
#endif

#if defined(__HW_IIR_EQ_PROCESS__)
  case AUDIO_EQ_TYPE_HW_IIR: {
    if (anc_status) {
      index_eq = audio_eq_hw_iir_index + 1;
    } else {
      index_eq = audio_eq_hw_iir_index;
    }
  } break;
#endif
  default: {
    ASSERT(false, "[%s]Error eq type!", __func__);
  }
  }
#endif
  return index_eq;
}

uint32_t usb_audio_set_eq(AUDIO_EQ_TYPE_T audio_eq_type, uint8_t index) {
  const FIR_CFG_T *fir_cfg = NULL;
  const IIR_CFG_T *iir_cfg = NULL;

  TRACE(3, "[%s]audio_eq_type=%d,index=%d", __func__, audio_eq_type, index);

#if defined(__SW_IIR_EQ_PROCESS__) || defined(__HW_FIR_EQ_PROCESS__) ||        \
    defined(__HW_DAC_IIR_EQ_PROCESS__) || defined(__HW_IIR_EQ_PROCESS__)
  switch (audio_eq_type) {
#if defined(__SW_IIR_EQ_PROCESS__)
  case AUDIO_EQ_TYPE_SW_IIR: {
    if (index >= EQ_SW_IIR_LIST_NUM) {
      TRACE(2, "[%s] index[%d] > EQ_SW_IIR_LIST_NUM", __func__, index);
      return 1;
    }

    iir_cfg = audio_eq_sw_iir_cfg_list[index];
  } break;
#endif

#if defined(__HW_FIR_EQ_PROCESS__)
  case AUDIO_EQ_TYPE_HW_FIR: {
    if (index >= EQ_HW_FIR_LIST_NUM) {
      TRACE(2, "[%s] index[%d] > EQ_HW_FIR_LIST_NUM", __func__, index);
      return 1;
    }

    fir_cfg = audio_eq_hw_fir_cfg_list[index];
  } break;
#endif

#if defined(__HW_DAC_IIR_EQ_PROCESS__)
  case AUDIO_EQ_TYPE_HW_DAC_IIR: {
    if (index >= EQ_HW_DAC_IIR_LIST_NUM) {
      TRACE(2, "[%s] index[%d] > EQ_HW_DAC_IIR_LIST_NUM", __func__, index);
      return 1;
    }

    iir_cfg = audio_eq_hw_dac_iir_cfg_list[index];
  } break;
#endif

#if defined(__HW_IIR_EQ_PROCESS__)
  case AUDIO_EQ_TYPE_HW_IIR: {
    if (index >= EQ_HW_IIR_LIST_NUM) {
      TRACE(2, "[%s] index[%d] > EQ_HW_IIR_LIST_NUM", __func__, index);
      return 1;
    }

    iir_cfg = audio_eq_hw_iir_cfg_list[index];
  } break;
#endif
  default: {
    ASSERT(false, "[%s]Error eq type!", __func__);
  }
  }
#endif

  return audio_eq_set_cfg(fir_cfg, iir_cfg, audio_eq_type);
}

static void set_codec_config_status(enum CODEC_CONFIG_LOCK_USER_T user,
                                    bool lock) {
  if (lock) {
    codec_config_lock |= (1 << user);
  } else {
    codec_config_lock &= ~(1 << user);
  }
}

static void usb_audio_codec_mute(enum CODEC_MUTE_USER_T user) {
  TRACE(3, "%s: user=%d map=0x%02X", __FUNCTION__, user, mute_user_map);

  if (user >= CODEC_MUTE_USER_QTY || mute_user_map == 0) {
    af_stream_mute(AUD_STREAM_ID_0, AUD_STREAM_PLAYBACK, true);
  }
  if (user < CODEC_MUTE_USER_QTY) {
    mute_user_map |= (1 << user);
  }
}

static void usb_audio_codec_unmute(enum CODEC_MUTE_USER_T user) {
  uint8_t old_map;
  STATIC_ASSERT(sizeof(old_map) * 8 >= CODEC_MUTE_USER_QTY,
                "old_map size too small");

  TRACE(3, "%s: user=%d map=0x%02X", __FUNCTION__, user, mute_user_map);

  old_map = mute_user_map;

  if (user < CODEC_MUTE_USER_QTY) {
    mute_user_map &= ~(1 << user);
  }
  if (user >= CODEC_MUTE_USER_QTY || (old_map && mute_user_map == 0)) {
    af_stream_mute(AUD_STREAM_ID_0, AUD_STREAM_PLAYBACK, false);
  }
}

#ifdef AUDIO_ANC_FB_MC

#define DELAY_SAMPLE_MC (33 * 2) //  2:ch
static int32_t delay_buf[DELAY_SAMPLE_MC];
static int32_t mid_p_8_old_l = 0;
static int32_t mid_p_8_old_r = 0;
static uint32_t audio_mc_data_playback(uint8_t *buf, uint32_t mc_len_bytes) {
  // uint32_t begin_time;
  // uint32_t end_time;
  // begin_time = hal_sys_timer_get();
  // TRACE(1,"cancel: %d",begin_time);

  float left_gain;
  float right_gain;
  uint32_t playback_len_bytes;
  int i, j, k;
  int delay_sample;

  hal_codec_get_dac_gain(&left_gain, &right_gain);

  // TRACE(1,"playback_samplerate_ratio:  %d",playback_samplerate_ratio);

  // TRACE(1,"left_gain:  %d",(int)(left_gain*(1<<12)));
  // TRACE(1,"right_gain: %d",(int)(right_gain*(1<<12)));

  playback_len_bytes = mc_len_bytes / playback_samplerate_ratio;

  if (sample_size_play == 2) {
    int16_t *sour_p = (int16_t *)(playback_buf + playback_size / 2);
    int16_t *mid_p = (int16_t *)(buf);
    int16_t *mid_p_8 = (int16_t *)(buf + mc_len_bytes - mc_len_bytes / 8);
    int16_t *dest_p = (int16_t *)buf;
    int i, j, k;

    if (buf == (playback_buf + playback_size)) {
      sour_p = (int16_t *)playback_buf;
    }

    delay_sample = DELAY_SAMPLE_MC;

    for (i = 0, j = 0; i < delay_sample; i = i + 2) {
      mid_p[j++] = delay_buf[i];
      mid_p[j++] = delay_buf[i + 1];
    }

    for (i = 0; i < playback_len_bytes / 2 - delay_sample; i = i + 2) {
      mid_p[j++] = sour_p[i];
      mid_p[j++] = sour_p[i + 1];
    }

    for (j = 0; i < playback_len_bytes / 2; i = i + 2) {
      delay_buf[j++] = sour_p[i];
      delay_buf[j++] = sour_p[i + 1];
    }

    if (playback_samplerate_ratio <= 8) {
      for (i = 0, j = 0; i < playback_len_bytes / 2;
           i = i + 2 * (8 / playback_samplerate_ratio)) {
        mid_p_8[j++] = mid_p[i];
        mid_p_8[j++] = mid_p[i + 1];
      }
    } else {
      for (i = 0, j = 0; i < playback_len_bytes / 2; i = i + 2) {
        for (k = 0; k < playback_samplerate_ratio / 8; k++) {
          mid_p_8[j++] = mid_p[i];
          mid_p_8[j++] = mid_p[i + 1];
        }
      }
    }

    anc_mc_run_stereo((uint8_t *)mid_p_8, mc_len_bytes / 8, left_gain,
                      right_gain, AUD_BITS_16);

    for (i = 0, j = 0; i < (mc_len_bytes / 8) / 2; i = i + 2) {
      float delta_l = (mid_p_8[i] - mid_p_8_old_l) / 8.0f;
      float delta_r = (mid_p_8[i + 1] - mid_p_8_old_r) / 8.0f;
      for (k = 0; k < 8; k++) {
        dest_p[j++] = mid_p_8_old_l + (int32_t)(delta_l * k);
        dest_p[j++] = mid_p_8_old_r + (int32_t)(delta_r * k);
      }
      mid_p_8_old_l = mid_p_8[i];
      mid_p_8_old_r = mid_p_8[i + 1];
    }
  } else if (sample_size_play == 4) {
    int32_t *sour_p = (int32_t *)(playback_buf + playback_size / 2);
    int32_t *mid_p = (int32_t *)(buf);
    int32_t *mid_p_8 = (int32_t *)(buf + mc_len_bytes - mc_len_bytes / 8);
    int32_t *dest_p = (int32_t *)buf;

    if (buf == (playback_buf + playback_size)) {
      sour_p = (int32_t *)playback_buf;
    }

    delay_sample = DELAY_SAMPLE_MC;

    for (i = 0, j = 0; i < delay_sample; i = i + 2) {
      mid_p[j++] = delay_buf[i];
      mid_p[j++] = delay_buf[i + 1];
    }

    for (i = 0; i < playback_len_bytes / 4 - delay_sample; i = i + 2) {
      mid_p[j++] = sour_p[i];
      mid_p[j++] = sour_p[i + 1];
    }

    for (j = 0; i < playback_len_bytes / 4; i = i + 2) {
      delay_buf[j++] = sour_p[i];
      delay_buf[j++] = sour_p[i + 1];
    }

    if (playback_samplerate_ratio <= 8) {
      for (i = 0, j = 0; i < playback_len_bytes / 4;
           i = i + 2 * (8 / playback_samplerate_ratio)) {
        mid_p_8[j++] = mid_p[i];
        mid_p_8[j++] = mid_p[i + 1];
      }
    } else {
      for (i = 0, j = 0; i < playback_len_bytes / 4; i = i + 2) {
        for (k = 0; k < playback_samplerate_ratio / 8; k++) {
          mid_p_8[j++] = mid_p[i];
          mid_p_8[j++] = mid_p[i + 1];
        }
      }
    }

    anc_mc_run_stereo((uint8_t *)mid_p_8, mc_len_bytes / 8, left_gain,
                      right_gain, AUD_BITS_24);

    for (i = 0, j = 0; i < (mc_len_bytes / 8) / 4; i = i + 2) {
      float delta_l = (mid_p_8[i] - mid_p_8_old_l) / 8.0f;
      float delta_r = (mid_p_8[i + 1] - mid_p_8_old_r) / 8.0f;
      for (k = 0; k < 8; k++) {
        dest_p[j++] = mid_p_8_old_l + (int32_t)(delta_l * k);
        dest_p[j++] = mid_p_8_old_r + (int32_t)(delta_r * k);
      }
      mid_p_8_old_l = mid_p_8[i];
      mid_p_8_old_r = mid_p_8[i + 1];
    }
  }

  // end_time = hal_sys_timer_get();
  // TRACE(2,"%s:run time: %d", __FUNCTION__, end_time-begin_time);

  return 0;
}
#endif

static uint32_t usb_audio_data_playback(uint8_t *buf, uint32_t len) {
  uint32_t usb_len;
  uint32_t old_rpos, saved_old_rpos, new_rpos, wpos;
  uint8_t recv_valid, init_pos;
  uint8_t conflicted;
  uint32_t reset_len = usb_recv_size / 2;
#ifdef USB_AUDIO_MULTIFUNC
  uint32_t old_rpos2, saved_old_rpos2, new_rpos2, wpos2;
  uint8_t recv2_valid, init_pos2;
  uint8_t conflicted2;
  uint32_t reset_len2 = usb_recv2_size / 2;
#endif
  uint32_t play_next;
  uint32_t lock;
  uint8_t *conv_buf;
  uint32_t cur_time;
  uint32_t usb_time;

  usb_time = last_usb_recv_time;
  cur_time = hal_sys_timer_get();

  //----------------------------------------
  // Speech processing start
  //----------------------------------------
#ifdef USB_AUDIO_SPEECH
  speech_process_playback_run(buf, &len);
#endif
  //----------------------------------------
  // Speech processing end
  //----------------------------------------

  ASSERT(((uint32_t)buf & 0x3) == 0, "%s: Invalid buf: %p", __FUNCTION__, buf);

  // playback is valid when reaching here
  codec_play_valid = 1;

  init_pos = 0;
  // Allow to play till the end of the buffer when itf stopped
  if (usb_recv_valid && !(recv_state == AUDIO_ITF_STATE_STOPPED &&
                          usb_recv_rpos == usb_recv_wpos)) {
    recv_valid = 1;
    if (usb_recv_init_rpos == 0) {
      init_pos = 1;
    }
  } else {
    recv_valid = 0;
  }
#ifdef USB_AUDIO_MULTIFUNC
  init_pos2 = 0;
  if (usb_recv2_valid && !(recv2_state == AUDIO_ITF_STATE_STOPPED &&
                           usb_recv2_rpos == usb_recv2_wpos)) {
    recv2_valid = 1;
    if (usb_recv2_init_rpos == 0) {
      init_pos2 = 1;
    }
  } else {
    recv2_valid = 0;
  }
#endif

  if (codec_play_seq != usb_recv_seq ||
      playback_state == AUDIO_ITF_STATE_STOPPED ||
#ifdef USB_AUDIO_MULTIFUNC
      (recv_valid == 0 && recv2_valid == 0) ||
#else
      recv_valid == 0 ||
#endif
      cur_time - usb_time > USB_MAX_XFER_INTERVAL) {
  _invalid_play:
    zero_mem32(buf, len);
    conv_buf = buf;
    // If usb recv is stopped, set usb_recv_rpos to the value of usb_recv_wpos
    // -- avoid playing noise. Otherwise set usb_recv_rpos to 0 -- avoid buffer
    // conflicts at usb recv startup.
    new_rpos = (recv_state == AUDIO_ITF_STATE_STOPPED) ? usb_recv_wpos : 0;
    conflicted = 0;
#ifdef USB_AUDIO_MULTIFUNC
    new_rpos2 = (recv2_state == AUDIO_ITF_STATE_STOPPED) ? usb_recv2_wpos : 0;
    conflicted2 = 0;
#endif

    goto _conv_end;
  }

  //----------------------------------------
  // Check conflict
  //----------------------------------------

  usb_len = playback_to_recv_len(len);
  conflicted = 0;
#ifdef USB_AUDIO_MULTIFUNC
  conflicted2 = 0;
#endif

  lock = int_lock();
  wpos = usb_recv_wpos;
  if (init_pos) {
    old_rpos = wpos + reset_len;
    if (old_rpos >= usb_recv_size) {
      old_rpos -= usb_recv_size;
    }
    usb_recv_rpos = old_rpos;
    usb_recv_init_rpos = 1;
  } else {
    old_rpos = usb_recv_rpos;
  }
  saved_old_rpos = old_rpos;
  new_rpos = usb_recv_rpos + usb_len;
  if (new_rpos >= usb_recv_size) {
    new_rpos -= usb_recv_size;
  }
  if (recv_valid && init_pos == 0) {
    if (old_rpos <= wpos) {
      if (new_rpos < old_rpos || wpos < new_rpos) {
        if (recv_state == AUDIO_ITF_STATE_STOPPED) {
          if (new_rpos < old_rpos) {
            zero_mem(usb_recv_buf + wpos, usb_recv_size - wpos);
            zero_mem(usb_recv_buf, new_rpos);
          } else {
            zero_mem(usb_recv_buf + wpos, new_rpos - wpos);
          }
          wpos = new_rpos;
          usb_recv_wpos = new_rpos;
        } else {
          conflicted = 1;
        }
      }
    } else {
      if (wpos < new_rpos && new_rpos < old_rpos) {
        if (recv_state == AUDIO_ITF_STATE_STOPPED) {
          zero_mem(usb_recv_buf + wpos, new_rpos - wpos);
          wpos = new_rpos;
          usb_recv_wpos = new_rpos;
        } else {
          conflicted = 1;
        }
      }
    }
    if (conflicted) {
      // Reset read position
      old_rpos = wpos + reset_len;
      if (old_rpos >= usb_recv_size) {
        old_rpos -= usb_recv_size;
      }
      new_rpos = old_rpos + usb_len;
      if (new_rpos >= usb_recv_size) {
        new_rpos -= usb_recv_size;
      }
      // Update global read position
      usb_recv_rpos = old_rpos;
    }
  }

#ifdef USB_AUDIO_MULTIFUNC
  wpos2 = usb_recv2_wpos;
  if (init_pos2) {
    old_rpos2 = wpos2 + reset_len2;
    if (old_rpos2 >= usb_recv2_size) {
      old_rpos2 -= usb_recv2_size;
    }
    usb_recv2_rpos = old_rpos2;
    usb_recv2_init_rpos = 1;
  } else {
    old_rpos2 = usb_recv2_rpos;
  }
  saved_old_rpos2 = old_rpos2;
  new_rpos2 = usb_recv2_rpos + usb_len;
  if (new_rpos2 >= usb_recv2_size) {
    new_rpos2 -= usb_recv2_size;
  }
  if (recv2_valid && init_pos2 == 0) {
    if (old_rpos2 <= wpos2) {
      if (new_rpos2 < old_rpos2 || wpos2 < new_rpos2) {
        if (recv2_state == AUDIO_ITF_STATE_STOPPED) {
          if (new_rpos2 < old_rpos2) {
            zero_mem(usb_recv2_buf + wpos2, usb_recv2_size - wpos2);
            zero_mem(usb_recv2_buf, new_rpos2);
          } else {
            zero_mem(usb_recv2_buf + wpos2, new_rpos2 - wpos2);
          }
          wpos2 = new_rpos2;
          usb_recv2_wpos = new_rpos2;
        } else {
          conflicted2 = 1;
        }
      }
    } else {
      if (wpos2 < new_rpos2 && new_rpos2 < old_rpos2) {
        if (recv2_state == AUDIO_ITF_STATE_STOPPED) {
          zero_mem(usb_recv2_buf + wpos2, new_rpos2 - wpos2);
          wpos2 = new_rpos2;
          usb_recv2_wpos = new_rpos2;
        } else {
          conflicted2 = 1;
        }
      }
    }
    if (conflicted2) {
      // Reset read position
      old_rpos2 = wpos2 + reset_len2;
      if (old_rpos2 >= usb_recv2_size) {
        old_rpos2 -= usb_recv2_size;
      }
      new_rpos2 = old_rpos2 + usb_len;
      if (new_rpos2 >= usb_recv2_size) {
        new_rpos2 -= usb_recv2_size;
      }
      // Update global read position
      usb_recv2_rpos = old_rpos2;
    }
  }
#endif
  int_unlock(lock);

  if (conflicted) {
    TRACE(4,
          "playback: Error: rpos=%u goes beyond wpos=%u with usb_len=%u. Reset "
          "to %u",
          saved_old_rpos, wpos, usb_len, old_rpos);
  }
#ifdef USB_AUDIO_MULTIFUNC
  if (conflicted2) {
    TRACE(4,
          "playback: Error: rpos2=%u goes beyond wpos2=%u with usb_len=%u. "
          "Reset to %u",
          saved_old_rpos2, wpos2, usb_len, old_rpos2);
  }
#endif

#if (VERBOSE_TRACE & (1 << 0))
  {
    int hw_play_pos =
        af_stream_get_cur_dma_pos(AUD_STREAM_ID_0, AUD_STREAM_PLAYBACK);
    uint32_t play_pos = buf - playback_buf;
#ifdef USB_AUDIO_MULTIFUNC
    if (recv_valid == 0) {
      old_rpos = -1;
      wpos = -1;
    }
    if (recv2_valid == 0) {
      old_rpos2 = -1;
      wpos2 = -1;
    }
    TRACE_TIME(8,
               "playback: rpos=%d/%d usb_len=%d wpos=%d/%d play_pos=%d len=%d "
               "hw_play_pos=%d",
               old_rpos, old_rpos2, usb_len, wpos, wpos2, play_pos, len,
               hw_play_pos);
#else
    TRACE_TIME(6,
               "playback: rpos=%d usb_len=%d wpos=%d play_pos=%d len=%d "
               "hw_play_pos=%d",
               old_rpos, usb_len, wpos, play_pos, len, hw_play_pos);
#endif
  }
#endif

  if (codec_play_seq != usb_recv_seq) {
    goto _invalid_play;
  }

#ifdef USB_AUDIO_MULTIFUNC
  record_conflict(conflicted || conflicted2);
#else
  record_conflict(conflicted);
#endif

  //----------------------------------------
  // USB->CODEC stream format conversion start
  //----------------------------------------

  conv_buf = buf;

#ifdef USB_AUDIO_MULTIFUNC

  {
    uint8_t POSSIBLY_UNUSED *cur_buf, *buf_end, *usb_cur_buf, *usb_buf_end,
        *usb_cur_buf2, *usb_buf_end2;
    uint32_t codec_step, usb_step;
    float cur_gain, new_gain, cur_gain2, new_gain2, gain_step;

    cur_buf = conv_buf;
    buf_end = conv_buf + len;
    usb_cur_buf = usb_recv_buf + old_rpos;
    usb_buf_end = usb_recv_buf + usb_recv_size;
    usb_cur_buf2 = usb_recv2_buf + old_rpos2;
    usb_buf_end2 = usb_recv2_buf + usb_recv2_size;

    cur_gain = playback_coef;
    new_gain = new_playback_coef;
    cur_gain2 = playback2_coef;
    new_gain2 = new_playback2_coef;
    gain_step = USB_AUDIO_VOL_UPDATE_STEP;

    ASSERT(sample_rate_play == sample_rate_recv,
           "2:1: Invalid sample_rate_play=%u sample_rate_recv=%u",
           sample_rate_play, sample_rate_recv);

    if (0) {

    } else if (sample_size_play == 4 &&
               (sample_size_recv == 4 || sample_size_recv == 3 ||
                sample_size_recv == 2)) {

      int32_t left, right;
      int32_t left2, right2;

      if (sample_size_recv == 4) {
        usb_step = 8;
      } else if (sample_size_recv == 3) {
        usb_step = 6;
      } else {
        usb_step = 4;
      }

      codec_step = 8;

      while (cur_buf + codec_step <= buf_end) {
        if (usb_cur_buf + usb_step > usb_buf_end) {
          usb_cur_buf = usb_recv_buf;
        }
        if (usb_cur_buf2 + usb_step > usb_buf_end2) {
          usb_cur_buf2 = usb_recv2_buf;
        }
        if (recv_valid) {
          if (usb_step == 8) {
            left = *(int32_t *)usb_cur_buf;
            right = *((int32_t *)usb_cur_buf + 1);
          } else if (usb_step == 6) {
            left = ((usb_cur_buf[0] << 8) | (usb_cur_buf[1] << 16) |
                    (usb_cur_buf[2] << 24));
            right = ((usb_cur_buf[3] << 8) | (usb_cur_buf[4] << 16) |
                     (usb_cur_buf[5] << 24));
          } else {
            left = *(int16_t *)usb_cur_buf << 16;
            right = *((int16_t *)usb_cur_buf + 1) << 16;
          }
          if (cur_gain > new_gain) {
            cur_gain -= gain_step;
            if (cur_gain < new_gain) {
              cur_gain = new_gain;
            }
          } else if (cur_gain < new_gain) {
            cur_gain += gain_step;
            if (cur_gain > new_gain) {
              cur_gain = new_gain;
            }
          }
          left = (int32_t)(left * cur_gain);
          right = (int32_t)(right * cur_gain);
        } else {
          left = right = 0;
        }
        if (recv2_valid) {
          if (usb_step == 8) {
            left2 = *(int32_t *)usb_cur_buf2;
            right2 = *((int32_t *)usb_cur_buf2 + 1);
          } else if (usb_step == 6) {
            left2 = ((usb_cur_buf2[0] << 8) | (usb_cur_buf2[1] << 16) |
                     (usb_cur_buf2[2] << 24));
            right2 = ((usb_cur_buf2[3] << 8) | (usb_cur_buf2[4] << 16) |
                      (usb_cur_buf2[5] << 24));
          } else {
            left2 = *(int16_t *)usb_cur_buf2 << 16;
            right2 = *((int16_t *)usb_cur_buf2 + 1) << 16;
          }
          if (cur_gain2 > new_gain2) {
            cur_gain2 -= gain_step;
            if (cur_gain2 < new_gain2) {
              cur_gain2 = new_gain2;
            }
          } else if (cur_gain2 < new_gain2) {
            cur_gain2 += gain_step;
            if (cur_gain2 > new_gain2) {
              cur_gain2 = new_gain2;
            }
          }
          left2 = (int32_t)(left2 * cur_gain2);
          right2 = (int32_t)(right2 * cur_gain2);
        } else {
          left2 = right2 = 0;
        }
        left = __QADD(left, left2);
        right = __QADD(right, right2);
        // Convert to 24-bit sample
        left >>= 8;
        right >>= 8;

        *(int32_t *)cur_buf = left;
        *((int32_t *)cur_buf + 1) = right;

        cur_buf += codec_step;
        usb_cur_buf += usb_step;
        usb_cur_buf2 += usb_step;
      }
    } else if (sample_size_play == 2 && sample_size_recv == 2) {

      int32_t left, right;
      int32_t left2, right2;

      usb_step = 4;
      codec_step = 4;

      while (cur_buf + codec_step <= buf_end) {
        if (usb_cur_buf + usb_step > usb_buf_end) {
          usb_cur_buf = usb_recv_buf;
        }
        if (usb_cur_buf2 + usb_step > usb_buf_end2) {
          usb_cur_buf2 = usb_recv2_buf;
        }
        if (recv_valid) {
          left = *(int16_t *)usb_cur_buf;
          right = *((int16_t *)usb_cur_buf + 1);
          if (cur_gain > new_gain) {
            cur_gain -= gain_step;
            if (cur_gain < new_gain) {
              cur_gain = new_gain;
            }
          } else if (cur_gain < new_gain) {
            cur_gain += gain_step;
            if (cur_gain > new_gain) {
              cur_gain = new_gain;
            }
          }
          left = (int32_t)(left * cur_gain);
          right = (int32_t)(right * cur_gain);
        } else {
          left = right = 0;
        }
        if (recv2_valid) {
          left2 = *(int16_t *)usb_cur_buf2;
          right2 = *((int16_t *)usb_cur_buf2 + 1);
          if (cur_gain2 > new_gain2) {
            cur_gain2 -= gain_step;
            if (cur_gain2 < new_gain2) {
              cur_gain2 = new_gain2;
            }
          } else if (cur_gain2 < new_gain2) {
            cur_gain2 += gain_step;
            if (cur_gain2 > new_gain2) {
              cur_gain2 = new_gain2;
            }
          }
          left2 = (int32_t)(left2 * cur_gain2);
          right2 = (int32_t)(right2 * cur_gain2);
        } else {
          left2 = right2 = 0;
        }
        left = __SSAT(left + left2, 16);
        right = __SSAT(right + right2, 16);

        *(int16_t *)cur_buf = left;
        *((int16_t *)cur_buf + 1) = right;

        cur_buf += codec_step;
        usb_cur_buf += usb_step;
      }

    } else {

      ASSERT(false, "2:3: Invalid sample_size_play=%u sample_size_recv=%u",
             sample_size_play, sample_size_recv);
    }

    playback_coef = cur_gain;
    playback2_coef = cur_gain2;
  }

#else

  {
    uint8_t POSSIBLY_UNUSED *cur_buf, *buf_end, *usb_cur_buf, *usb_buf_end;
    uint32_t codec_step, usb_step;
    bool down_sampling = false;

    cur_buf = conv_buf;
    buf_end = conv_buf + len;
    usb_cur_buf = usb_recv_buf + old_rpos;
    usb_buf_end = usb_recv_buf + usb_recv_size;

    if (0) {

#ifdef CODEC_DSD
    } else if (codec_dsd_enabled) {

      ASSERT(sample_size_play == 2, "Bad DSD playback sample size: %u",
             sample_size_play);
      ASSERT(sample_size_recv == 4 || sample_size_recv == 3,
             "Bad DSD recv sample size: %u", sample_size_recv);

      uint32_t left, right;

      if (sample_size_recv == 4) {
        usb_step = 8;
      } else {
        usb_step = 6;
      }

      codec_step = 4;

      while (cur_buf + codec_step <= buf_end) {
        if (usb_cur_buf + usb_step > usb_buf_end) {
          usb_cur_buf = usb_recv_buf;
        }
        if (usb_step == 8) {
          left = *(uint32_t *)usb_cur_buf;
          right = *((uint32_t *)usb_cur_buf + 1);
        } else {
          left = ((usb_cur_buf[0] << 8) | (usb_cur_buf[1] << 16));
          right = ((usb_cur_buf[3] << 8) | (usb_cur_buf[4] << 16));
        }

        left = __RBIT(left) >> 8;
        right = __RBIT(right) >> 8;

        *(uint16_t *)cur_buf = left;
        *((uint16_t *)cur_buf + 1) = right;

        cur_buf += codec_step;
        usb_cur_buf += usb_step;
      }
#endif

    } else if (sample_size_play == 4 &&
               (sample_size_recv == 4 || sample_size_recv == 3 ||
                sample_size_recv == 2)) {

      int32_t left, right;

      if (sample_size_recv == 4) {
        usb_step = 8;
      } else if (sample_size_recv == 3) {
        usb_step = 6;
      } else {
        usb_step = 4;
      }

      if ((sample_rate_play == 96000 && sample_rate_recv == 48000) ||
          (sample_rate_play == 88200 && sample_rate_recv == 44100)) {
        codec_step = 16;
      } else if (sample_rate_play == sample_rate_recv) {
        codec_step = 8;
      } else if (sample_rate_play == 96000 && sample_rate_recv == 192000) {
        codec_step = 8;
        down_sampling = true;
      } else {
        ASSERT(false, "1: Invalid sample_rate_play=%u sample_rate_recv=%u",
               sample_rate_play, sample_rate_recv);
      }

      while (cur_buf + codec_step <= buf_end) {
        if (usb_cur_buf + usb_step > usb_buf_end) {
          usb_cur_buf = usb_recv_buf;
        }
        if (usb_step == 8) {
          left = *(int32_t *)usb_cur_buf;
          right = *((int32_t *)usb_cur_buf + 1);
        } else if (usb_step == 6) {
          left = ((usb_cur_buf[0] << 8) | (usb_cur_buf[1] << 16) |
                  (usb_cur_buf[2] << 24));
          right = ((usb_cur_buf[3] << 8) | (usb_cur_buf[4] << 16) |
                   (usb_cur_buf[5] << 24));
        } else {
          left = *(int16_t *)usb_cur_buf << 16;
          right = *((int16_t *)usb_cur_buf + 1) << 16;
        }
        // Convert to 24-bit sample
        left >>= 8;
        right >>= 8;

        if (down_sampling) {
          int32_t left_next, right_next;

          usb_cur_buf += usb_step;
          if (usb_cur_buf + usb_step > usb_buf_end) {
            usb_cur_buf = usb_recv_buf;
          }
          if (usb_step == 8) {
            left_next = *(int32_t *)usb_cur_buf;
            right_next = *((int32_t *)usb_cur_buf + 1);
          } else if (usb_step == 6) {
            left_next = ((usb_cur_buf[0] << 8) | (usb_cur_buf[1] << 16) |
                         (usb_cur_buf[2] << 24));
            right_next = ((usb_cur_buf[3] << 8) | (usb_cur_buf[4] << 16) |
                          (usb_cur_buf[5] << 24));
          } else {
            left_next = *(int16_t *)usb_cur_buf << 16;
            right_next = *((int16_t *)usb_cur_buf + 1) << 16;
          }
          // Convert to 24-bit sample
          left_next >>= 8;
          right_next >>= 8;

          // The addition of two 24-bit integers will not saturate
          left = (left + left_next) / 2;
          right = (right + right_next) / 2;
        }

        *(int32_t *)cur_buf = left;
        *((int32_t *)cur_buf + 1) = right;
        if (codec_step == 16) {
          *((int32_t *)cur_buf + 2) = left;
          *((int32_t *)cur_buf + 3) = right;
        }

        cur_buf += codec_step;
        usb_cur_buf += usb_step;
      }

    } else if (sample_size_play == 2 && sample_size_recv == 2) {

      int16_t left, right;

      usb_step = 4;

      if ((sample_rate_play == 96000 && sample_rate_recv == 48000) ||
          (sample_rate_play == 88200 && sample_rate_recv == 44100)) {
        codec_step = 8;
      } else if (sample_rate_play == sample_rate_recv) {
        codec_step = 4;
      } else if (sample_rate_play == 96000 && sample_rate_recv == 192000) {
        codec_step = 4;
        down_sampling = true;
      } else {
        ASSERT(false, "2: Invalid sample_rate_play=%u sample_rate_recv=%u",
               sample_rate_play, sample_rate_recv);
      }

      while (cur_buf + codec_step <= buf_end) {
        if (usb_cur_buf + usb_step > usb_buf_end) {
          usb_cur_buf = usb_recv_buf;
        }
        left = *(int16_t *)usb_cur_buf;
        right = *((int16_t *)usb_cur_buf + 1);
        if (down_sampling) {
          // Use 32-bit integers to avoid saturation
          int32_t left32, right32;

          usb_cur_buf += usb_step;
          if (usb_cur_buf + usb_step > usb_buf_end) {
            usb_cur_buf = usb_recv_buf;
          }
          left32 = *(int16_t *)usb_cur_buf;
          right32 = *((int16_t *)usb_cur_buf + 1);
          left = (left + left32) / 2;
          right = (right + right32) / 2;
        }
        *(int16_t *)cur_buf = left;
        *((int16_t *)cur_buf + 1) = right;
        if (codec_step == 8) {
          *((int16_t *)cur_buf + 2) = left;
          *((int16_t *)cur_buf + 3) = right;
        }
        cur_buf += codec_step;
        usb_cur_buf += usb_step;
      }

    } else {

      ASSERT(false, "3: Invalid sample_size_play=%u sample_size_recv=%u",
             sample_size_play, sample_size_recv);
    }
  }

#endif // !USB_AUDIO_MULTIFUNC

  //----------------------------------------
  // USB->CODEC stream format conversion end
  //----------------------------------------
_conv_end:

  play_next = buf + len - playback_buf;
  if (play_next >= playback_size) {
    play_next -= playback_size;
  }

  lock = int_lock();
  if (codec_play_seq == usb_recv_seq) {
#ifdef USB_AUDIO_MULTIFUNC
    if (playback_state == AUDIO_ITF_STATE_STARTED) {
      if (recv_valid) {
        usb_recv_rpos = new_rpos;
      }
      if (recv2_valid) {
        usb_recv2_rpos = new_rpos2;
      }
    } else {
      if (recv_valid) {
        usb_recv_rpos = 0;
      }
      if (recv2_valid) {
        usb_recv2_rpos = 0;
      }
    }
    if (conflicted) {
      playback_conflicted = conflicted;
    }
    if (conflicted2) {
      playback_conflicted2 = conflicted2;
    }
#else
    if (playback_state == AUDIO_ITF_STATE_STARTED) {
      usb_recv_rpos = new_rpos;
    } else {
      usb_recv_rpos = 0;
    }
    if (conflicted) {
      playback_conflicted = conflicted;
    }
#endif
    playback_pos = play_next;
  }
  int_unlock(lock);

  //----------------------------------------
  // Audio processing start
  //----------------------------------------

#ifdef FREQ_RESP_EQ
  freq_resp_eq_run(conv_buf, len);
#endif
#if defined(__HW_FIR_DSD_PROCESS__)
  if (codec_dsd_enabled) {
    dsd_process(conv_buf, len);
  }
#endif

#if defined(__SW_IIR_EQ_PROCESS__) || defined(__HW_FIR_EQ_PROCESS__) ||        \
    defined(__HW_IIR_EQ_PROCESS__)
  if (eq_opened) {
    audio_process_run(conv_buf, len);
  }
#endif

  // If conv_buf != buf, copy the output to buf

  //----------------------------------------
  // Audio processing end
  //----------------------------------------

#ifdef NOISE_GATING
  bool noise_mute = true;
#ifdef NOISE_REDUCTION
  bool nr_fire = true;
  uint8_t chan = 0;
#endif

  if (sample_size_play == 2) {
    int16_t *samp = (int16_t *)buf;
    for (uint32_t i = 0; i < len / 2; i++) {
      if (ABS(samp[i]) >= NOISE_GATING_THRESH_16BIT) {
        noise_mute = false;
        break;
      }
      // NOISE_REDUCTION is unstable for 16-bit streams for unknown reasons.
      // Skip by now.
    }
  } else {
    int32_t *samp = (int32_t *)buf;
    for (uint32_t i = 0; i < len / 4; i++) {
      if (ABS(samp[i]) >= NOISE_GATING_THRESH_24BIT) {
        noise_mute = false;
#ifndef NOISE_REDUCTION
        break;
#endif
      }
#ifdef NOISE_REDUCTION
      if (nr_fire) {
        if (ABS(samp[i]) >= NOISE_REDUCTION_THRESH_24BIT) {
          nr_fire = false;
        } else {
          cur_zero_diff[chan][0]++;
          cur_zero_diff[chan][1]++;
          if ((prev_samp_positive[chan] && samp[i] < 0) ||
              (!prev_samp_positive[chan] && samp[i] >= 0)) {
            if (ABS(cur_zero_diff[chan][prev_samp_positive[chan]] -
                    prev_zero_diff[chan][prev_samp_positive[chan]]) < 2) {
              if (nr_cont_cnt < NOISE_REDUCTION_MATCH_CNT) {
                nr_cont_cnt++;
              }
            } else if (nr_cont_cnt > 2) {
              nr_fire = false;
            }
            prev_zero_diff[chan][prev_samp_positive[chan]] =
                cur_zero_diff[chan][prev_samp_positive[chan]];
            cur_zero_diff[chan][prev_samp_positive[chan]] = 0;
          }
          prev_samp_positive[chan] = (samp[i] >= 0);
          // Switch channel
          chan = !chan;
        }
      }
#endif
    }
  }

#ifdef NOISE_REDUCTION
  if (noise_mute) {
    nr_fire = false;
  }
  if (nr_fire) {
    if (nr_cont_cnt >= NOISE_REDUCTION_MATCH_CNT && !nr_active &&
        noise_reduction_cmd != NOISE_REDUCTION_CMD_FIRE) {
      if (cur_time - last_nr_restore_time >= NOISE_REDUCTION_INTERVAL) {
        TRACE(8,
              "\nFire noise reduction: cur0=%u/%u cur1=%u/%u prev0=%u/%u "
              "prev1=%u/%u\n",
              cur_zero_diff[0][0], cur_zero_diff[0][1], cur_zero_diff[1][0],
              cur_zero_diff[1][1], prev_zero_diff[0][0], prev_zero_diff[0][1],
              prev_zero_diff[1][0], prev_zero_diff[1][1]);
        noise_reduction_cmd = NOISE_REDUCTION_CMD_FIRE;
        enqueue_unique_cmd(AUDIO_CMD_NOISE_REDUCTION);
      }
    }
  } else {
    if (nr_active && noise_reduction_cmd != NOISE_REDUCTION_CMD_RESTORE) {
      TRACE(8,
            "\nRestore noise reduction: cur0=%u/%u cur1=%u/%u prev0=%u/%u "
            "prev1=%u/%u\n",
            cur_zero_diff[0][0], cur_zero_diff[0][1], cur_zero_diff[1][0],
            cur_zero_diff[1][1], prev_zero_diff[0][0], prev_zero_diff[0][1],
            prev_zero_diff[1][0], prev_zero_diff[1][1]);
      noise_reduction_cmd = NOISE_REDUCTION_CMD_RESTORE;
      enqueue_unique_cmd(AUDIO_CMD_NOISE_REDUCTION);
    }
    memset(prev_zero_diff, 0, sizeof(prev_zero_diff));
    memset(cur_zero_diff, 0, sizeof(cur_zero_diff));
    nr_cont_cnt = 0;
    last_nr_restore_time = cur_time;
  }
#endif

  if (noise_mute) {
    if ((mute_user_map & (1 << CODEC_MUTE_USER_NOISE_GATING)) == 0 &&
        noise_gating_cmd != NOISE_GATING_CMD_MUTE) {
      if (cur_time - last_high_signal_time >= NOISE_GATING_INTERVAL) {
        noise_gating_cmd = NOISE_GATING_CMD_MUTE;
        enqueue_unique_cmd(AUDIO_CMD_NOISE_GATING);
      }
    }
  } else {
    if ((mute_user_map & (1 << CODEC_MUTE_USER_NOISE_GATING)) &&
        noise_gating_cmd != NOISE_GATING_CMD_UNMUTE) {
      noise_gating_cmd = NOISE_GATING_CMD_UNMUTE;
      enqueue_unique_cmd(AUDIO_CMD_NOISE_GATING);
    }
    last_high_signal_time = cur_time;
  }
#endif

#if (VERBOSE_TRACE & (1 << 1))
  {
    int hw_play_pos =
        af_stream_get_cur_dma_pos(AUD_STREAM_ID_0, AUD_STREAM_PLAYBACK);
    TRACE_TIME(2, "playbackEnd: playback_pos=%u hw_play_pos=%d", playback_pos,
               hw_play_pos);
  }
#endif

  return 0;
}

static uint32_t usb_audio_data_capture(uint8_t *buf, uint32_t len) {
  uint32_t usb_len;
  uint32_t old_wpos, saved_old_wpos, new_wpos, rpos;
  uint8_t init_pos;
  uint8_t conflicted;
  uint32_t reset_len = usb_send_size / 2;
  uint32_t cap_next;
  uint32_t lock;
  uint8_t *conv_buf;
  uint32_t cur_time;
  uint32_t usb_time;
#ifdef SW_CAPTURE_RESAMPLE
  enum RESAMPLE_STATUS_T ret;
  struct RESAMPLE_IO_BUF_T io;
  uint32_t in_size;
  uint32_t out_size;
  uint32_t resample_frame_len = 0;
#endif

  usb_time = last_usb_send_time;
  cur_time = hal_sys_timer_get();

  ASSERT(((uint32_t)buf & 0x3) == 0, "%s: Invalid buf: %p", __FUNCTION__, buf);

  if (codec_cap_valid == 0 &&
      cur_time - codec_cap_start_time >= CAPTURE_STABLE_INTERVAL) {
    codec_cap_valid = 1;
  }

  if (codec_cap_seq != usb_send_seq ||
      capture_state == AUDIO_ITF_STATE_STOPPED ||
      send_state == AUDIO_ITF_STATE_STOPPED || codec_cap_valid == 0 ||
      usb_send_valid == 0 || cur_time - usb_time > USB_MAX_XFER_INTERVAL) {
  _invalid_cap:
    new_wpos = 0;
    conflicted = 0;
    goto _conv_end;
  }

  if (usb_send_init_wpos) {
    init_pos = 0;
  } else {
    init_pos = 1;
  }

  //----------------------------------------
  // Check conflict
  //----------------------------------------

  usb_len = capture_to_send_len(len);
  conflicted = 0;

  lock = int_lock();
  rpos = usb_send_rpos;
  if (init_pos) {
    old_wpos = rpos + reset_len;
    if (old_wpos >= usb_send_size) {
      old_wpos -= usb_send_size;
    }
    usb_send_wpos = old_wpos;
    usb_send_init_wpos = 1;
  } else {
    old_wpos = usb_send_wpos;
  }
  saved_old_wpos = old_wpos;
  new_wpos = usb_send_wpos + usb_len;
  if (new_wpos >= usb_send_size) {
    new_wpos -= usb_send_size;
  }
  if (init_pos == 0) {
    if (old_wpos <= rpos) {
      if (new_wpos < old_wpos || rpos < new_wpos) {
        conflicted = 1;
      }
    } else {
      if (rpos < new_wpos && new_wpos < old_wpos) {
        conflicted = 1;
      }
    }
    if (conflicted) {
      // Reset write position
      old_wpos = rpos + reset_len;
      if (old_wpos >= usb_send_size) {
        old_wpos -= usb_send_size;
      }
      new_wpos = old_wpos + usb_len;
      if (new_wpos >= usb_send_size) {
        new_wpos -= usb_send_size;
      }
      // Update global write position
      usb_send_wpos = old_wpos;
    }
  }
  int_unlock(lock);

  if (conflicted) {
    TRACE(4,
          "capture: Error: wpos=%u goes beyond rpos=%u with usb_len=%u. Reset "
          "to %u",
          saved_old_wpos, rpos, usb_len, old_wpos);
  }

#if (VERBOSE_TRACE & (1 << 2))
  TRACE_TIME(5, "capture: wpos=%u usb_len=%u rpos=%u cap_pos=%u len=%u",
             old_wpos, usb_len, rpos, buf + len - capture_buf, len);
#endif

  if (codec_cap_seq != usb_send_seq) {
    goto _invalid_cap;
  }

  record_conflict(conflicted);

  //----------------------------------------
  // Audio processing start
  //----------------------------------------

  // TODO ...

  //----------------------------------------
  // Audio processing end
  //----------------------------------------

  //----------------------------------------
  // Speech processing start
  //----------------------------------------
#ifdef USB_AUDIO_SPEECH
  speech_process_capture_run(buf, &len);
#endif
  //----------------------------------------
  // Speech processing end
  //----------------------------------------

  //----------------------------------------
  // CODEC->USB stream format conversion start
  //----------------------------------------

  conv_buf = buf;

  {
    uint8_t POSSIBLY_UNUSED *cur_buf, *buf_end, *dst_buf_start, *dst_cur_buf,
        *dst_buf_end;

    cur_buf = conv_buf;
    buf_end = conv_buf + len;
#ifdef SW_CAPTURE_RESAMPLE
    if (resample_cap_enabled) {
#if (CHAN_NUM_CAPTURE == CHAN_NUM_SEND)
#if (defined(CHIP_BEST1000) && (defined(ANC_APP) || defined(_DUAL_AUX_MIC_)))
      // codec capture buffer --(ref rate conversion)--> resample input buffer
      // --(resample)--> usb send buffer

#ifdef USB_AUDIO_DYN_CFG
      // Resample frame len is the capture reference len after reference rate
      // conversion
      resample_frame_len = capture_to_ref_len(len);
#else
      // Resample frame len is the capture len
      resample_frame_len = len;
#endif
      ASSERT(resample_frame_len <= resample_input_size,
             "resample_input_size too small: %u len=%u resample_frame_len=%u",
             resample_input_size, len, resample_frame_len);

      dst_buf_start = resample_input_buf;
      dst_cur_buf = resample_input_buf;
      dst_buf_end = resample_input_buf + resample_frame_len;
#else  // !(CHIP_BEST1000 && (ANC_APP || _DUAL_AUX_MIC_))
       // codec capture buffer --(resample)--> usb send buffer

      resample_input_buf = cur_buf;
      // Resample frame len is the capture len
      resample_frame_len = len;

      dst_buf_start = cur_buf;
      dst_cur_buf = cur_buf;
      dst_buf_end = cur_buf + len;
#endif // !(CHIP_BEST1000 && (ANC_APP || _DUAL_AUX_MIC_))
#elif (CHAN_NUM_CAPTURE == 2) && (CHAN_NUM_SEND == 1)
      // codec capture buffer --(chan num conversion)--> codec capture buffer
      // --(resample)--> usb send buffer

      resample_input_buf = cur_buf;
      // Resample frame len is half of the capture len
      resample_frame_len = len / 2;

      dst_buf_start = cur_buf;
      dst_cur_buf = cur_buf;
      dst_buf_end = cur_buf + resample_frame_len;
#elif (CHAN_NUM_CAPTURE == 1) && (CHAN_NUM_SEND == 2)
      // codec capture buffer --(resample)--> usb send buffer --(chan num
      // conversion)--> usb send buffer

      // Resample frame len is the capture len
      resample_frame_len = len;

      io.in = cur_buf;
      io.in_size = resample_frame_len;
      io.out = usb_send_buf + old_wpos;
      io.out_size = usb_len / 2;
      io.out_cyclic_start = usb_send_buf;
      io.out_cyclic_end = usb_send_buf + usb_send_size;

      ret = audio_resample_ex_run(resample_id, &io, &in_size, &out_size);
      ASSERT((ret == RESAMPLE_STATUS_IN_EMPTY || ret == RESAMPLE_STATUS_DONE) &&
                 io.out_size >= out_size,
             "Failed to resample: %d io.out_size=%u in_size=%u out_size=%u",
             ret, io.out_size, in_size, out_size);

      uint32_t diff = usb_len - out_size * 2;
      if (new_wpos >= diff) {
        new_wpos -= diff;
      } else {
        new_wpos = new_wpos + usb_send_size - diff;
      }

#if (VERBOSE_TRACE & (1 << 3))
      TRACE(5, "cap_resample: new_wpos=%u, in: %u -> %u, out: %u -> %u",
            new_wpos, io.in_size, in_size, io.out_size, out_size);
#endif

      dst_buf_start = usb_send_buf;
      dst_cur_buf = usb_send_buf + old_wpos;
      dst_buf_end = usb_send_buf + usb_send_size;
      cur_buf = dst_cur_buf;
      buf_end = cur_buf + out_size;
      if (buf_end >= usb_send_buf + usb_send_size) {
        buf_end -= usb_send_size;
      }
#else
#error "Unsupported CHAN_NUM_CAPTURE and CHAN_NUM_SEND configuration"
#endif
    } else
#endif // SW_CAPTURE_RESAMPLE
    {
      dst_buf_start = usb_send_buf;
      dst_cur_buf = usb_send_buf + old_wpos;
      dst_buf_end = usb_send_buf + usb_send_size;
    }

#if defined(CHIP_BEST1000) && defined(_DUAL_AUX_MIC_)

    // Assuming codec adc records stereo data, and usb sends 48K/44.1K stereo
    // data
#if (CHAN_NUM_CAPTURE != 2) || (CHAN_NUM_SEND != 2)
#error "Unsupported CHAN_NUM_CAPTURE and CHAN_NUM_SEND configuration"
#endif

    {
#define MERGE_VER 2
#if (MERGE_VER == 2)
#define THRES_MIC3 32500
#else
#define THRES_MIC3 27168
#endif
#define SHIFT_BITS 4

      uint32_t i = 0;
      short *BufSrc = (short *)cur_buf;
      short *BufDst = (short *)dst_cur_buf;
      short *BufDstStart = (short *)dst_buf_start;
      short *BufDstEnd = (short *)dst_buf_end;

      int32_t PcmValue = 0;
      int32_t BufSrcRVal = 0;

      uint32_t step;

      // TRACE(3,"%s - %d, %d", __func__, BufSrc[0], BufSrc[1]);
      // TRACE(2,"%s - %d", __func__, TICKS_TO_MS(cur_time));

      if (sample_rate_cap == 384000 || sample_rate_cap == 352800) {
        step = 2;
      } else if (sample_rate_cap == 192000 || sample_rate_cap == 176400) {
        step = 1;
      } else {
        ASSERT(false,
               "1: Invalid sample_rate_cap=%u sample_rate_ref_cap=%u "
               "sample_rate_send=%u",
               sample_rate_cap, sample_rate_ref_cap, sample_rate_send);
      }

      get_amic_dc(BufSrc, len >> 2, step);

      for (i = 0; i < (len >> 2); i += step) {
        if (step == 2) {
          if (!(i & 0x1)) {
            PcmValue = ((int32_t)(BufSrc[i << 1]));
            BufSrcRVal = ((int32_t)(BufSrc[(i << 1) + 1]));
#if (MERGE_VER == 2)
            if ((PcmValue < THRES_MIC3) && (PcmValue > -THRES_MIC3)) {
              PcmValue = (PcmValue - s_amic3_dc) >> SHIFT_BITS;
            } else {
              PcmValue = BufSrcRVal - s_amic4_dc;
            }
#else  // (MERGE_VER == 1)
            PcmValue -= s_amic3_dc;
            if ((PcmValue < THRES_MIC3) && (PcmValue > -THRES_MIC3)) {
              PcmValue >>= SHIFT_BITS;
            } else {
              PcmValue = BufSrcRVal - s_amic4_dc;
            }
#endif // MERGE_VER
            PcmValue = soir_filter(PcmValue);
#ifdef DUAL_AUX_MIC_MORE_FILTER
            PcmValue = soir_filter1(PcmValue);
            PcmValue = soir_filter2(PcmValue);
#endif
            if (!(i & 7)) {
              if (BufDst + 2 > BufDstEnd) {
                BufDst = BufDstStart;
              }
              *BufDst++ = PcmValue;
              *BufDst++ = PcmValue;
            }
          }
        } else {
          if (!(i & 0x1)) {
            PcmValue = ((int32_t)(BufSrc[i << 1]));
            BufSrcRVal = ((int32_t)(BufSrc[(i << 1) + 1]));
#if (MERGE_VER == 2)
            if ((PcmValue < THRES_MIC3) && (PcmValue > -THRES_MIC3)) {
              PcmValue = (PcmValue - s_amic3_dc) >> SHIFT_BITS;
            } else {
              PcmValue = BufSrcRVal - s_amic4_dc;
            }
#else  // (MERGE_VER == 1)
            PcmValue -= s_amic3_dc;
            if ((PcmValue < THRES_MIC3) && (PcmValue > -THRES_MIC3)) {
              PcmValue >>= SHIFT_BITS;
            } else {
              PcmValue = BufSrcRVal - s_amic4_dc;
            }
#endif // MERGE_VER
            PcmValue = soir_filter(PcmValue);
#ifdef DUAL_AUX_MIC_MORE_FILTER
            PcmValue = soir_filter1(PcmValue);
            PcmValue = soir_filter2(PcmValue);
#endif
            if (!(i & 3)) {
              if (BufDst + 2 > BufDstEnd) {
                BufDst = BufDstStart;
              }
              *BufDst++ = PcmValue;
              *BufDst++ = PcmValue;
            }
          }
        }
      }
    }

#elif defined(CHIP_BEST1000) && defined(ANC_APP)

    // Assuming codec adc records stereo data, and usb sends 48K/44.1K stereo
    // data
#if (CHAN_NUM_CAPTURE != 2) || (CHAN_NUM_SEND != 2)
#error "Unsupported CHAN_NUM_CAPTURE and CHAN_NUM_SEND configuration"
#endif

    if ((sample_rate_ref_cap == 48000 || sample_rate_ref_cap == 44100) &&
        (sample_rate_cap == sample_rate_ref_cap * 2 ||
         sample_rate_cap == sample_rate_ref_cap * 4 ||
         sample_rate_cap == sample_rate_ref_cap * 8 ||
         sample_rate_cap == sample_rate_ref_cap * 16)) {

      uint32_t POSSIBLY_UNUSED factor = sample_rate_cap / sample_rate_ref_cap;
      int32_t POSSIBLY_UNUSED left = 0;
      int32_t POSSIBLY_UNUSED right = 0;
      uint32_t step = factor * 4;

      while (cur_buf + step <= buf_end) {
        if (dst_cur_buf + 4 > dst_buf_end) {
          dst_cur_buf = dst_buf_start;
        }

        // Downsampling the adc data
#if 1
        left = 0;
        right = 0;
        for (int i = 0; i < factor; i++) {
          left += *(int16_t *)(cur_buf + 4 * i);
          right += *(int16_t *)(cur_buf + 4 * i + 2);
        }
        *(int16_t *)dst_cur_buf = left / factor;
        *(int16_t *)(dst_cur_buf + 2) = right / factor;
#else
        *(int16_t *)dst_cur_buf = *(int16_t *)cur_buf;
        *(int16_t *)(dst_cur_buf + 2) = *(int16_t *)(cur_buf + 2);
#endif

        // Move to next data
        dst_cur_buf += 4;
        cur_buf += step;
      }

    } else {
      ASSERT(false,
             "2: Invalid sample_rate_cap=%u sample_rate_ref_cap=%u "
             "sample_rate_send=%u",
             sample_rate_cap, sample_rate_ref_cap, sample_rate_send);
    }

#else // !(CHIP_BEST1000 && (ANC_APP || _DUAL_AUX_MIC_))

#ifndef SW_CAPTURE_RESAMPLE
    ASSERT(sample_rate_cap == sample_rate_send,
           "3: Invalid sample_rate_cap=%u sample_rate_send=%u", sample_rate_cap,
           sample_rate_send);
#endif

// When USB_AUDIO_SPEECH is enable, buf after algorithm shoule be CHAN_NUM_SEND,
// do not need to convert any more.
#if (CHAN_NUM_CAPTURE == 2) && (CHAN_NUM_SEND == 1) &&                         \
    !defined(USB_AUDIO_SPEECH)

    // Assuming codec adc always records stereo data

    while (cur_buf + 4 <= buf_end) {
      // Copy left channel data
      if (dst_cur_buf + 2 > dst_buf_end) {
        dst_cur_buf = dst_buf_start;
      }
      *(int16_t *)dst_cur_buf = *(int16_t *)cur_buf;

      // Move to next data
      dst_cur_buf += 2;
      cur_buf += 4;
    }

#elif (CHAN_NUM_CAPTURE == 1) && (CHAN_NUM_SEND == 2) &&                       \
    !defined(USB_AUDIO_SPEECH)

    // Assuming codec adc always records mono data

#ifdef SW_CAPTURE_RESAMPLE
#if (CHAN_NUM_CAPTURE == 1) && (CHAN_NUM_SEND == 2)
    if (resample_cap_enabled) {
      // ASSERT(cur_buf == dst_cur_buf, "Bad assumption");
      uint32_t src_len;

      if (buf_end < cur_buf) {
        src_len = buf_end + usb_send_size - cur_buf;
      } else {
        src_len = buf_end - cur_buf;
      }
      cur_buf = buf_end - 2;
      if (cur_buf < dst_buf_start) {
        cur_buf += usb_send_size;
      }
      dst_cur_buf += src_len * 2 - 4;
      if (dst_cur_buf >= dst_buf_end) {
        dst_cur_buf -= usb_send_size;
      }
      while (src_len > 0) {
        *(int16_t *)dst_cur_buf = *(int16_t *)cur_buf;
        *(int16_t *)(dst_cur_buf + 2) = *(int16_t *)cur_buf;

        // Move to next data
        src_len -= 2;
        cur_buf -= 2;
        if (cur_buf < dst_buf_start) {
          cur_buf += usb_send_size;
        }
        dst_cur_buf -= 4;
        if (dst_cur_buf < dst_buf_start) {
          dst_cur_buf += usb_send_size;
        }
      }
    } else
#endif
#endif
    {
      while (cur_buf + 2 <= buf_end) {
        // Duplicate the mono data
        if (dst_cur_buf + 4 > dst_buf_end) {
          dst_cur_buf = dst_buf_start;
        }
        *(int16_t *)dst_cur_buf = *(int16_t *)cur_buf;
        *(int16_t *)(dst_cur_buf + 2) = *(int16_t *)cur_buf;

        // Move to next data
        dst_cur_buf += 4;
        cur_buf += 2;
      }
    }

#else // (CHAN_NUM_CAPTURE == CHAN_NUM_SEND)

    // The channel numbers of codec adc and USB data are the same

    if (sample_size_cap == sample_size_send) {
#if ((CHAN_NUM_CAPTURE & 1) == 0)
#define COPY_MEM(dst, src, size) copy_mem32(dst, src, size)
#else
#define COPY_MEM(dst, src, size) copy_mem16(dst, src, size)
#endif
      if (dst_cur_buf != cur_buf) {
        if (dst_cur_buf + len <= dst_buf_end) {
          COPY_MEM(dst_cur_buf, cur_buf, len);
        } else {
          uint32_t copy_len;

          if (dst_cur_buf >= dst_buf_end) {
            copy_len = 0;
          } else {
            copy_len = dst_buf_end - dst_cur_buf;
            COPY_MEM(dst_cur_buf, cur_buf, copy_len);
          }
          COPY_MEM(dst_buf_start, cur_buf + copy_len, len - copy_len);
        }
      }
#undef COPY_MEM
    } else if (sample_size_cap == 4 && sample_size_send == 3) {
      uint32_t codec_step, usb_step;
      uint32_t ch;

      codec_step = CHAN_NUM_CAPTURE * 4;
      usb_step = CHAN_NUM_SEND * 3;

      while (cur_buf + codec_step <= buf_end) {
        if (dst_cur_buf + usb_step > dst_buf_end) {
          dst_cur_buf = dst_buf_start;
        }
        for (ch = 0; ch < CHAN_NUM_CAPTURE; ch++) {
          *(uint16_t *)dst_cur_buf = *(uint16_t *)cur_buf;
          *(uint8_t *)(dst_cur_buf + 2) = *(uint8_t *)(cur_buf + 2);
          // Move to next channel
          dst_cur_buf += 3;
          cur_buf += 4;
        }
      }
    } else {
      ASSERT(false, "4: Invalid sample_size_cap=%u sample_size_send=%u",
             sample_size_cap, sample_size_send);
    }

#endif // (CHAN_NUM_CAPTURE == CHAN_NUM_SEND)

#endif // !(CHIP_BEST1000 && (ANC_APP || _DUAL_AUX_MIC_))

#ifdef SW_CAPTURE_RESAMPLE
#if !((CHAN_NUM_CAPTURE == 1) && (CHAN_NUM_SEND == 2))
    if (resample_cap_enabled) {
      io.in = resample_input_buf;
      io.in_size = resample_frame_len;
      io.out = usb_send_buf + old_wpos;
      io.out_size = usb_len;
      io.out_cyclic_start = usb_send_buf;
      io.out_cyclic_end = usb_send_buf + usb_send_size;

      ret = audio_resample_ex_run(resample_id, &io, &in_size, &out_size);
      ASSERT((ret == RESAMPLE_STATUS_IN_EMPTY || ret == RESAMPLE_STATUS_DONE) &&
                 io.out_size >= out_size,
             "Failed to resample: %d io.out_size=%u io.in_size=%u in_size=%u "
             "out_size=%u",
             ret, io.out_size, io.in_size, in_size, out_size);

      uint32_t diff = usb_len - out_size;
      if (new_wpos >= diff) {
        new_wpos -= diff;
      } else {
        new_wpos = new_wpos + usb_send_size - diff;
      }

#if (VERBOSE_TRACE & (1 << 3))
      TRACE(5, "cap_resample: new_wpos=%u, in: %u -> %u, out: %u -> %u",
            new_wpos, io.in_size, in_size, io.out_size, out_size);
#endif
    }
#endif
#endif
  }

  //----------------------------------------
  // CODEC->USB stream format conversion end
  //----------------------------------------
_conv_end:

  cap_next = buf + len - capture_buf;
  if (cap_next >= capture_size) {
    cap_next -= capture_size;
  }

  lock = int_lock();
  if (codec_cap_seq == usb_send_seq) {
    if (capture_state == AUDIO_ITF_STATE_STARTED) {
      usb_send_wpos = new_wpos;
    } else {
      usb_send_wpos = 0;
    }
    capture_pos = cap_next;
    if (conflicted) {
      capture_conflicted = conflicted;
    }
  }
  int_unlock(lock);

#if (VERBOSE_TRACE & (1 << 4))
  TRACE_TIME(0, "captureEnd");
#endif

  return 0;
}

static void update_playback_sync_info(void) {
  playback_info.err_thresh = DIFF_ERR_THRESH_PLAYBACK;
  playback_info.samp_rate = sample_rate_play;
  playback_info.samp_cnt = byte_to_samp_recv(usb_recv_size);
#ifdef TARGET_TO_MAX_DIFF
  playback_info.max_target_thresh = playback_info.samp_cnt / 2;
  playback_info.diff_target =
      byte_to_samp_recv(playback_to_recv_len(playback_size / 2)) +
      playback_info.samp_cnt / 2;
  playback_info.diff_target = usb_audio_sync_normalize_diff(
      -playback_info.diff_target, playback_info.samp_cnt);
#endif

  TRACE(4, "%s: rate=%u cnt=%u (%u)", __FUNCTION__, playback_info.samp_rate,
        playback_info.samp_cnt, usb_recv_size);
}

static void update_capture_sync_info(void) {
  capture_info.err_thresh = DIFF_ERR_THRESH_CAPTURE;
  capture_info.samp_rate = sample_rate_cap;
  capture_info.samp_cnt = byte_to_samp_send(usb_send_size);
#ifdef TARGET_TO_MAX_DIFF
  capture_info.max_target_thresh = capture_info.samp_cnt / 2;
  capture_info.diff_target =
      byte_to_samp_send(capture_to_send_len(capture_size / 2)) +
      capture_info.samp_cnt / 2;
  capture_info.diff_target = usb_audio_sync_normalize_diff(
      capture_info.diff_target, capture_info.samp_cnt);
#endif

  TRACE(4, "%s: rate=%u cnt=%u (%u)", __FUNCTION__, capture_info.samp_rate,
        capture_info.samp_cnt, usb_send_size);
}

static int usb_audio_open_codec_stream(enum AUD_STREAM_T stream,
                                       enum AUDIO_STREAM_REQ_USER_T user) {
  int ret = 0;
  struct AF_STREAM_CONFIG_T stream_cfg;

  TRACE(4, "%s: stream=%d user=%d map=0x%x", __FUNCTION__, stream, user,
        codec_stream_map[stream][AUDIO_STREAM_OPENED]);

  if (user >= AUDIO_STREAM_REQ_USER_QTY ||
      codec_stream_map[stream][AUDIO_STREAM_OPENED] == 0) {
    memset(&stream_cfg, 0, sizeof(stream_cfg));

    if (stream == AUD_STREAM_PLAYBACK) {
#if defined(USB_AUDIO_DYN_CFG) && defined(KEEP_SAME_LATENCY)
      playback_size = calc_playback_size(sample_rate_play);
#endif

      update_playback_sync_info();

#ifdef CODEC_DSD
      if (codec_dsd_enabled) {
        stream_cfg.bits = AUD_BITS_24;
      } else
#endif
      {
        stream_cfg.bits = sample_size_to_enum_playback(sample_size_play);
      }
      stream_cfg.sample_rate = sample_rate_play;
      stream_cfg.channel_num = chan_num_to_enum(CHAN_NUM_PLAYBACK);
#ifdef USB_I2S_APP
#if defined(USB_I2S_ID) && (USB_I2S_ID == 0)
      stream_cfg.device = AUD_STREAM_USE_I2S0_MASTER;
#else
      stream_cfg.device = AUD_STREAM_USE_I2S1_MASTER;
#endif
#else
      stream_cfg.device = AUD_STREAM_USE_INT_CODEC;
#endif
      stream_cfg.vol = playback_vol;
      stream_cfg.handler = usb_audio_data_playback;
      stream_cfg.io_path = AUD_OUTPUT_PATH_SPEAKER;
      stream_cfg.data_ptr = playback_buf;
      stream_cfg.data_size = playback_size;

      // TRACE(3,"[%s] sample_rate: %d, bits = %d", __func__,
      // stream_cfg.sample_rate, stream_cfg.bits);

      ret = af_stream_open(AUD_STREAM_ID_0, AUD_STREAM_PLAYBACK, &stream_cfg);
      ASSERT(ret == 0, "af_stream_open playback failed: %d", ret);

#ifdef AUDIO_ANC_FB_MC
      stream_cfg.bits = sample_size_to_enum_playback(sample_size_play);
      stream_cfg.sample_rate = sample_rate_play;
      stream_cfg.channel_num = chan_num_to_enum(CHAN_NUM_PLAYBACK);
      stream_cfg.device = AUD_STREAM_USE_MC;
      stream_cfg.vol = playback_vol;
      stream_cfg.handler = audio_mc_data_playback;
      stream_cfg.io_path = AUD_OUTPUT_PATH_SPEAKER;
      stream_cfg.data_ptr = playback_buf + playback_size;

      mid_p_8_old_l = 0;
      mid_p_8_old_r = 0;

      if (sample_rate_play == AUD_SAMPRATE_8000) {
        playback_samplerate_ratio = 8 * 6;
      } else if (sample_rate_play == AUD_SAMPRATE_16000) {
        playback_samplerate_ratio = 8 * 3;
      } else if ((sample_rate_play == AUD_SAMPRATE_44100) ||
                 (sample_rate_play == AUD_SAMPRATE_48000) ||
                 (sample_rate_play == AUD_SAMPRATE_50781)) {
        playback_samplerate_ratio = 8;
      } else if ((sample_rate_play == AUD_SAMPRATE_88200) ||
                 (sample_rate_play == AUD_SAMPRATE_96000)) {
        playback_samplerate_ratio = 4;
      } else if ((sample_rate_play == AUD_SAMPRATE_176400) ||
                 (sample_rate_play == AUD_SAMPRATE_192000)) {
        playback_samplerate_ratio = 2;
      } else if (sample_rate_play == AUD_SAMPRATE_384000) {
        playback_samplerate_ratio = 1;
      } else {
        playback_samplerate_ratio = 1;
        ASSERT(false, "Music cancel can't support playback sample rate:%d",
               sample_rate_play);
      }

      anc_mc_run_init((sample_rate_play * playback_samplerate_ratio) / 8);

      stream_cfg.data_size = playback_size * playback_samplerate_ratio;

      // TRACE(3,"[%s] sample_rate: %d, bits = %d", __func__,
      // stream_cfg.sample_rate, stream_cfg.bits);

      ret = af_stream_open(AUD_STREAM_ID_2, AUD_STREAM_PLAYBACK, &stream_cfg);
      ASSERT(ret == 0, "af_stream_open playback failed: %d", ret);
#endif
    } else {
#if defined(USB_AUDIO_DYN_CFG) && defined(KEEP_SAME_LATENCY)
      capture_size = calc_capture_size(sample_rate_cap);
#endif

      update_capture_sync_info();

      stream_cfg.bits = sample_size_to_enum_capture(sample_size_cap);
      stream_cfg.sample_rate = sample_rate_cap;
      stream_cfg.channel_num = chan_num_to_enum(CHAN_NUM_CAPTURE);
#ifdef ANC_PROD_TEST
      stream_cfg.channel_map = anc_fb_mic_ch_l | anc_fb_mic_ch_r;
#endif
#ifdef USB_I2S_APP
#if defined(USB_I2S_ID) && (USB_I2S_ID == 0)
      stream_cfg.device = AUD_STREAM_USE_I2S0_MASTER;
#else
      stream_cfg.device = AUD_STREAM_USE_I2S1_MASTER;
#endif
#else
      stream_cfg.device = AUD_STREAM_USE_INT_CODEC;
#endif
      stream_cfg.vol = capture_vol;
      stream_cfg.handler = usb_audio_data_capture;
#if !defined(USB_AUDIO_SPEECH) && defined(BTUSB_AUDIO_MODE)
      stream_cfg.io_path = AUD_INPUT_PATH_USBAUDIO;
#else
      stream_cfg.io_path = AUD_INPUT_PATH_MAINMIC;
#endif
      stream_cfg.data_ptr = capture_buf;
      stream_cfg.data_size = capture_size;

      // TRACE(4,"[%s] sample_rate: %d, bits = %d, ch_num = %d", __func__,
      // stream_cfg.sample_rate, stream_cfg.bits, stream_cfg.channel_num);

      ret = af_stream_open(AUD_STREAM_ID_0, AUD_STREAM_CAPTURE, &stream_cfg);
      ASSERT(ret == 0, "af_stream_open catpure failed: %d", ret);
    }
  }

  if (user < AUDIO_STREAM_REQ_USER_QTY) {
    codec_stream_map[stream][AUDIO_STREAM_OPENED] |= (1 << user);
  }

  return ret;
}

static int usb_audio_close_codec_stream(enum AUD_STREAM_T stream,
                                        enum AUDIO_STREAM_REQ_USER_T user) {
  int ret = 0;

  TRACE(4, "%s: stream=%d user=%d map=0x%x", __FUNCTION__, stream, user,
        codec_stream_map[stream][AUDIO_STREAM_OPENED]);

  if (user < AUDIO_STREAM_REQ_USER_QTY) {
    codec_stream_map[stream][AUDIO_STREAM_OPENED] &= ~(1 << user);
  }

  if (user >= AUDIO_STREAM_REQ_USER_QTY ||
      codec_stream_map[stream][AUDIO_STREAM_OPENED] == 0) {
    ret = af_stream_close(AUD_STREAM_ID_0, stream);

#ifdef AUDIO_ANC_FB_MC
    if (stream == AUD_STREAM_PLAYBACK) {
      ret = af_stream_close(AUD_STREAM_ID_2, stream);
    }
#endif
  }

  return ret;
}

static int usb_audio_open_eq(void) {
  int ret = 0;

  TRACE(4, "[%s] EQ: sample_rate_recv=%d, sample_rate_play=%d, sample_bits=%d",
        __func__, sample_rate_recv, sample_rate_play,
        sample_size_to_enum_playback(sample_size_play));

#if defined(__SW_IIR_EQ_PROCESS__) || defined(__HW_FIR_EQ_PROCESS__) ||        \
    defined(__HW_IIR_EQ_PROCESS__) || defined(__HW_DAC_IIR_EQ_PROCESS__)
  enum AUD_BITS_T sample_bits = sample_size_to_enum_playback(sample_size_play);
  enum AUD_CHANNEL_NUM_T chan_num = chan_num_to_enum(CHAN_NUM_PLAYBACK);
  ret = audio_process_open(sample_rate_play, sample_bits, chan_num,
                           playback_eq_size / 2, playback_eq_buf,
                           playback_eq_size);

  // TRACE(1,"audio_process_open: %d", ret);

#ifdef __SW_IIR_EQ_PROCESS__
  usb_audio_set_eq(AUDIO_EQ_TYPE_SW_IIR,
                   usb_audio_get_eq_index(AUDIO_EQ_TYPE_SW_IIR, 0));
#endif

#ifdef __HW_FIR_EQ_PROCESS__
  usb_audio_set_eq(AUDIO_EQ_TYPE_HW_FIR,
                   usb_audio_get_eq_index(AUDIO_EQ_TYPE_HW_FIR, 0));
#endif

#ifdef __HW_DAC_IIR_EQ_PROCESS__
  usb_audio_set_eq(AUDIO_EQ_TYPE_HW_DAC_IIR,
                   usb_audio_get_eq_index(AUDIO_EQ_TYPE_HW_DAC_IIR, 0));
#endif

#ifdef __HW_IIR_EQ_PROCESS__
  usb_audio_set_eq(AUDIO_EQ_TYPE_HW_IIR,
                   usb_audio_get_eq_index(AUDIO_EQ_TYPE_HW_IIR, 0));
#endif

#endif

  eq_opened = 1;

  return ret;
}

static int usb_audio_close_eq(void) {
  int ret = 0;

#if defined(__SW_IIR_EQ_PROCESS__) || defined(__HW_FIR_EQ_PROCESS__) ||        \
    defined(__HW_IIR_EQ_PROCESS__) || defined(__HW_DAC_IIR_EQ_PROCESS__)
  ret = audio_process_close();
#endif

  eq_opened = 0;

  return ret;
}

static int usb_audio_start_codec_stream(enum AUD_STREAM_T stream,
                                        enum AUDIO_STREAM_REQ_USER_T user) {
  int ret = 0;

  TRACE(4, "%s: stream=%d user=%d map=0x%x", __FUNCTION__, stream, user,
        codec_stream_map[stream][AUDIO_STREAM_STARTED]);

  if (user >= AUDIO_STREAM_REQ_USER_QTY ||
      codec_stream_map[stream][AUDIO_STREAM_STARTED] == 0) {
    reset_conflict();

    if (stream == AUD_STREAM_PLAYBACK) {
      zero_mem32(playback_buf, playback_size);
      codec_play_valid = 0;
      usb_recv_init_rpos = 0;
      playback_pos = 0;
      playback_conflicted = 0;
#ifdef USB_AUDIO_MULTIFUNC
      usb_recv2_init_rpos = 0;
      playback_conflicted2 = 0;
#endif
#ifdef DSD_SUPPORT
      if (codec_dsd_enabled) {
#if defined(__HW_FIR_DSD_PROCESS__)
        uint8_t *dsd_buf;
        uint32_t dsd_size;

        // DoP format requirement
        dsd_size = playback_size * 16;
        ;
        dsd_buf = (uint8_t *)(HW_FIR_DSD_BUF_MID_ADDR - dsd_size / 2);
        dsd_open(sample_rate_play, AUD_BITS_24, AUD_CHANNEL_NUM_2, dsd_buf,
                 dsd_size);
#elif defined(CODEC_DSD)
        af_dsd_enable();
#endif
      }
#endif
      usb_audio_open_eq();
    } else {
#if defined(CHIP_BEST1000) && defined(_DUAL_AUX_MIC_)
      damic_init();
      init_amic_dc();
#endif

#ifdef USB_AUDIO_SPEECH
      app_overlay_select(APP_OVERLAY_HFP);

      speech_process_init(sample_rate_cap, CHAN_NUM_CAPTURE,
                          sample_size_to_enum_playback(sample_size_cap),
                          sample_rate_play, CHAN_NUM_PLAYBACK,
                          sample_size_to_enum_playback(sample_size_play), 16,
                          16, CHAN_NUM_SEND, CHAN_NUM_RECV);
#endif

      codec_cap_valid = 0;
      usb_send_init_wpos = 0;
      capture_pos = 0;
      capture_conflicted = 0;
    }

    // Tune rate according to the newest sync ratio info
    usb_audio_cmd_tune_rate(stream);

    ret = af_stream_start(AUD_STREAM_ID_0, stream);
    ASSERT(ret == 0, "af_stream_start %d failed: %d", stream, ret);

    if (stream == AUD_STREAM_PLAYBACK) {
#ifdef AUDIO_ANC_FB_MC
      ret = af_stream_start(AUD_STREAM_ID_2, stream);
      ASSERT(ret == 0, "af_stream_start %d failed: %d", stream, ret);
#endif
    } else {
      codec_cap_start_time = hal_sys_timer_get();
    }
  }

  if (user < AUDIO_STREAM_REQ_USER_QTY) {
    codec_stream_map[stream][AUDIO_STREAM_STARTED] |= (1 << user);
  }

  return ret;
}

static int usb_audio_stop_codec_stream(enum AUD_STREAM_T stream,
                                       enum AUDIO_STREAM_REQ_USER_T user) {
  int ret = 0;

  TRACE(4, "%s: stream=%d user=%d map=0x%x", __FUNCTION__, stream, user,
        codec_stream_map[stream][AUDIO_STREAM_STARTED]);

  if (user < AUDIO_STREAM_REQ_USER_QTY) {
    codec_stream_map[stream][AUDIO_STREAM_STARTED] &= ~(1 << user);
  }

  if (user >= AUDIO_STREAM_REQ_USER_QTY ||
      codec_stream_map[stream][AUDIO_STREAM_STARTED] == 0) {
    ret = af_stream_stop(AUD_STREAM_ID_0, stream);

    if (stream == AUD_STREAM_PLAYBACK) {
#ifdef AUDIO_ANC_FB_MC
      ret = af_stream_stop(AUD_STREAM_ID_2, stream);
#endif
#ifdef DSD_SUPPORT
      if (codec_dsd_enabled) {
#if defined(__HW_FIR_DSD_PROCESS__)
        dsd_close();
#elif defined(CODEC_DSD)
        af_dsd_disable();
#endif
      }
#endif
      usb_audio_close_eq();
    } else {
#if defined(CHIP_BEST1000) && defined(_DUAL_AUX_MIC_)
      damic_deinit();
#endif

#ifdef USB_AUDIO_SPEECH
      speech_process_deinit();
      app_overlay_unloadall();
#endif
    }
  }

  return ret;
}

static int usb_audio_start_usb_stream(enum AUD_STREAM_T stream) {
  int ret;

  reset_conflict();

  if (stream == AUD_STREAM_PLAYBACK) {
    usb_audio_sync_reset(&playback_info);

    usb_recv_valid = 0;
#ifdef USB_AUDIO_MULTIFUNC
    if (recv2_state == AUDIO_ITF_STATE_STOPPED)
#endif
    {
      usb_recv_seq++;
    }

    usb_recv_rpos = 0;
    usb_recv_wpos = usb_recv_size / 2;
    zero_mem32(usb_recv_buf, usb_recv_size);

    usb_recv_err_cnt = 0;

#ifdef DSD_SUPPORT
    usb_dsd_enabled = false;
    usb_dsd_cont_cnt = 0;
#endif

    ret = usb_audio_start_recv(usb_recv_buf, usb_recv_wpos, usb_recv_size);
    if (ret == 1) {
      TRACE(0, "usb_audio_start_recv failed: usb not configured");
    } else {
      ASSERT(ret == 0, "usb_audio_start_recv failed: %d", ret);
    }
  } else {
#ifndef UAUD_SYNC_STREAM_TARGET
    if (recv_state == AUDIO_ITF_STATE_STOPPED)
#endif
    {
      usb_audio_sync_reset(&capture_info);
    }

    usb_send_valid = 0;
    usb_send_seq++;

    usb_send_rpos = usb_send_size / 2;
    usb_send_wpos = 0;
    zero_mem32(usb_send_buf, usb_send_size);

    usb_send_err_cnt = 0;

    ret = usb_audio_start_send(usb_send_buf, usb_send_rpos, usb_send_size);
    if (ret == 1) {
      TRACE(0, "usb_audio_start_send failed: usb not configured");
    } else {
      ASSERT(ret == 0, "usb_audio_start_send failed: %d", ret);
    }
  }

  return ret;
}

static int usb_audio_stop_usb_stream(enum AUD_STREAM_T stream) {
  if (stream == AUD_STREAM_PLAYBACK) {
    usb_audio_stop_recv();

#ifdef DSD_SUPPORT
    usb_dsd_enabled = false;
#endif

    usb_audio_sync_reset(&playback_info);
  } else {
    usb_audio_stop_send();

#ifndef UAUD_SYNC_STREAM_TARGET
    if (recv_state == AUDIO_ITF_STATE_STOPPED)
#endif
    {
      usb_audio_sync_reset(&capture_info);
    }
  }

  return 0;
}

static void usb_audio_set_codec_volume(enum AUD_STREAM_T stream, uint8_t vol) {
  struct AF_STREAM_CONFIG_T *cfg;
  uint8_t POSSIBLY_UNUSED old_vol;
  uint32_t ret;

  ret = af_stream_get_cfg(AUD_STREAM_ID_0, stream, &cfg, true);
  if (ret == 0) {
    old_vol = cfg->vol;
    if (old_vol != vol) {
      cfg->vol = vol;
      af_stream_setup(AUD_STREAM_ID_0, stream, cfg);
    }
  }

#ifdef AUDIO_ANC_FB_MC
  if (stream == AUD_STREAM_PLAYBACK) {
    ret = af_stream_get_cfg(AUD_STREAM_ID_2, AUD_STREAM_PLAYBACK, &cfg, true);
    if (ret == 0) {
      if (cfg->vol != vol) {
        cfg->vol = vol;
        af_stream_setup(AUD_STREAM_ID_2, AUD_STREAM_PLAYBACK, cfg);
      }
    }
  }
#endif
}

static void usb_audio_enqueue_cmd(uint32_t data) {
  int ret;
  uint32_t mark;

  ret = safe_queue_put(&cmd_queue, data);
  ASSERT(ret == 0 || safe_queue_dump(&cmd_queue), "%s: cmd queue overflow",
         __FUNCTION__);

  hal_cpu_wake_lock(USB_AUDIO_CPU_WAKE_USER);

  mark = safe_queue_watermark(&cmd_queue);
  if (mark > cmd_watermark) {
    cmd_watermark = mark;
    TRACE(2, "%s: new watermark %u", __FUNCTION__, mark);
  }

#ifdef BT_USB_AUDIO_DUAL_MODE
  if (enqueue_cmd_cb) {
    enqueue_cmd_cb(data);
  }
#endif
}

#ifdef BT_USB_AUDIO_DUAL_MODE
void usb_audio_set_enqueue_cmd_callback(USB_AUDIO_ENQUEUE_CMD_CALLBACK cb) {
  enqueue_cmd_cb = cb;
}
#endif

static void enqueue_unique_cmd_with_opp(enum AUDIO_CMD_T cmd, uint8_t seq,
                                        uint8_t arg,
                                        enum AUDIO_CMD_T oppsite_cmd) {
  uint32_t last[3];
  uint32_t lock;
  bool dup = false;

  lock = int_lock();
  if (safe_queue_peek(&cmd_queue, -1, &last[0]) == 0 &&
      safe_queue_peek(&cmd_queue, -2, &last[1]) == 0 &&
      safe_queue_peek(&cmd_queue, -3, &last[2]) == 0) {
    if (EXTRACT_CMD(last[0]) == cmd) {
      dup = true;
      safe_queue_pop(&cmd_queue, NULL);
    } else if (EXTRACT_CMD(last[0]) == oppsite_cmd &&
               EXTRACT_CMD(last[1]) == cmd &&
               EXTRACT_CMD(last[2]) == oppsite_cmd) {
      dup = true;
      safe_queue_pop(&cmd_queue, NULL);
      safe_queue_pop(&cmd_queue, NULL);
    }
  }
  int_unlock(lock);

  usb_audio_enqueue_cmd(MAKE_QUEUE_DATA(cmd, seq, arg));

  if (dup) {
    TRACE(2, "%s: Remove old duplicate cmd %d", __FUNCTION__, cmd);
  }
}

static void enqueue_unique_cmd_arg(enum AUDIO_CMD_T cmd, uint8_t seq,
                                   uint8_t arg) {
  uint32_t last;
  uint32_t cur;
  uint32_t lock;
  bool enqueue = true;

  cur = MAKE_QUEUE_DATA(cmd, seq, arg);

  lock = int_lock();
  if (safe_queue_peek(&cmd_queue, -1, &last) == 0) {
    if (last == cur) {
      enqueue = false;
    }
  }
  int_unlock(lock);

  if (enqueue) {
    usb_audio_enqueue_cmd(cur);
  } else {
    TRACE(2, "%s: Skip duplicate cmd %d", __FUNCTION__, cmd);
  }
}

static void enqueue_unique_cmd(enum AUDIO_CMD_T cmd) {
  enqueue_unique_cmd_arg(cmd, 0, 0);
}

static void usb_audio_playback_start(enum USB_AUDIO_ITF_CMD_T cmd) {
  if (cmd == USB_AUDIO_ITF_STOP) {
    // Stop the stream right now
    if (recv_state == AUDIO_ITF_STATE_STARTED) {
      usb_audio_stop_usb_stream(AUD_STREAM_PLAYBACK);
      recv_state = AUDIO_ITF_STATE_STOPPED;
    }

#ifdef USB_AUDIO_DYN_CFG
    playback_itf_set = 0;
#ifdef USB_AUDIO_UAC2
    enqueue_unique_cmd_with_opp(AUDIO_CMD_STOP_PLAY, usb_recv_seq, 0,
                                AUDIO_CMD_START_PLAY);
#else
    enqueue_unique_cmd_with_opp(AUDIO_CMD_STOP_PLAY, usb_recv_seq, 0,
                                AUDIO_CMD_SET_RECV_RATE);
#endif
#else

#ifdef USB_AUDIO_MULTIFUNC
    if (recv2_state == AUDIO_ITF_STATE_STARTED) {
      return;
    }
#endif

    enqueue_unique_cmd_with_opp(AUDIO_CMD_STOP_PLAY, usb_recv_seq, 0,
                                AUDIO_CMD_START_PLAY);
#endif
  } else {
#ifdef USB_AUDIO_DYN_CFG
    if (cmd == USB_AUDIO_ITF_START_16BIT) {
      new_sample_size_recv = 2;
    } else if (cmd == USB_AUDIO_ITF_START_24BIT) {
      new_sample_size_recv = 3;
    } else {
      new_sample_size_recv = 4;
    }
    playback_itf_set = 1;

    // Some host applications will not stop current stream before changing
    // sample size
    if (recv_state == AUDIO_ITF_STATE_STARTED) {
      usb_audio_stop_usb_stream(AUD_STREAM_PLAYBACK);
      recv_state = AUDIO_ITF_STATE_STOPPED;
    }

#ifdef USB_AUDIO_UAC2
#ifdef KEEP_SAME_LATENCY
    usb_recv_size =
        calc_usb_recv_size(new_sample_rate_recv, new_sample_size_recv);
    TRACE(2, "%s: Set usb_recv_size=%u", __FUNCTION__, usb_recv_size);
#endif

    usb_audio_start_usb_stream(AUD_STREAM_PLAYBACK);
    recv_state = AUDIO_ITF_STATE_STARTED;

    enqueue_unique_cmd_with_opp(AUDIO_CMD_START_PLAY, usb_recv_seq, 0,
                                AUDIO_CMD_STOP_PLAY);
#else
    // Wait for sampling freq ctrl msg to start the stream
#endif
    return;
#else
    if (recv_state == AUDIO_ITF_STATE_STOPPED) {
      usb_audio_start_usb_stream(AUD_STREAM_PLAYBACK);
      recv_state = AUDIO_ITF_STATE_STARTED;
    }

#ifdef USB_AUDIO_MULTIFUNC
    if (recv2_state == AUDIO_ITF_STATE_STARTED) {
      return;
    }
#endif

    enqueue_unique_cmd_with_opp(AUDIO_CMD_START_PLAY, usb_recv_seq, 0,
                                AUDIO_CMD_STOP_PLAY);
#endif
  }
}

static void usb_audio_capture_start(enum USB_AUDIO_ITF_CMD_T cmd) {
  if (cmd == USB_AUDIO_ITF_STOP) {
    // Stop the stream right now
    if (send_state == AUDIO_ITF_STATE_STARTED) {
      usb_audio_stop_usb_stream(AUD_STREAM_CAPTURE);
      send_state = AUDIO_ITF_STATE_STOPPED;
    }

#ifdef USB_AUDIO_DYN_CFG
    capture_itf_set = 0;
#ifdef USB_AUDIO_UAC2
    enqueue_unique_cmd_with_opp(AUDIO_CMD_STOP_CAPTURE, usb_send_seq, 0,
                                AUDIO_CMD_START_CAPTURE);
#else
    enqueue_unique_cmd_with_opp(AUDIO_CMD_STOP_CAPTURE, usb_send_seq, 0,
                                AUDIO_CMD_SET_SEND_RATE);
#endif
#else
    enqueue_unique_cmd_with_opp(AUDIO_CMD_STOP_CAPTURE, usb_send_seq, 0,
                                AUDIO_CMD_START_CAPTURE);
#endif
  } else {
#ifdef USB_AUDIO_DYN_CFG
    capture_itf_set = 1;

    // Some host applications will not stop current stream before changing
    // sample size
    if (send_state == AUDIO_ITF_STATE_STARTED) {
      usb_audio_stop_usb_stream(AUD_STREAM_CAPTURE);
      send_state = AUDIO_ITF_STATE_STOPPED;
    }

#ifdef USB_AUDIO_UAC2
    usb_audio_start_usb_stream(AUD_STREAM_CAPTURE);
    send_state = AUDIO_ITF_STATE_STARTED;

    enqueue_unique_cmd_with_opp(AUDIO_CMD_START_CAPTURE, usb_send_seq, 0,
                                AUDIO_CMD_STOP_CAPTURE);
#else
    // Wait for sampling freq ctrl msg to start the stream
#endif
    return;
#else
    if (send_state == AUDIO_ITF_STATE_STOPPED) {
      usb_audio_start_usb_stream(AUD_STREAM_CAPTURE);
      send_state = AUDIO_ITF_STATE_STARTED;
    }

    enqueue_unique_cmd_with_opp(AUDIO_CMD_START_CAPTURE, usb_send_seq, 0,
                                AUDIO_CMD_STOP_CAPTURE);
#endif
  }
}

static void usb_audio_mute_control(uint32_t mute) {
  TRACE(1, "MUTE CTRL: %u", mute);

  new_mute_state = mute;
#ifdef USB_AUDIO_MULTIFUNC
  if (mute) {
    new_playback_coef = 0;
  } else {
    new_playback_coef = playback_gain_to_float(new_playback_vol);
  }
#endif
  usb_audio_enqueue_cmd(AUDIO_CMD_MUTE_CTRL);
}

static void usb_audio_cap_mute_control(uint32_t mute) {
  TRACE(1, "CAP MUTE CTRL: %u", mute);

  new_cap_mute_state = mute;
  usb_audio_enqueue_cmd(AUDIO_CMD_CAP_MUTE_CTRL);
}

static void usb_audio_vol_control(uint32_t percent) {
  if (percent >= 100) {
    new_playback_vol = MAX_VOLUME_VAL;
  } else {
    new_playback_vol = MIN_VOLUME_VAL +
                       (percent * (MAX_VOLUME_VAL - MIN_VOLUME_VAL) + 50) / 100;
  }

  TRACE(2, "VOL CTRL: percent=%u new_playback_vol=%u", percent,
        new_playback_vol);

#ifdef USB_AUDIO_MULTIFUNC
  new_playback_coef = playback_gain_to_float(new_playback_vol);
#else
  usb_audio_enqueue_cmd(AUDIO_CMD_SET_VOLUME);
#endif
}

static void usb_audio_cap_vol_control(uint32_t percent) {
  if (percent >= 100) {
    new_capture_vol = MAX_CAP_VOLUME_VAL;
  } else {
    new_capture_vol =
        MIN_CAP_VOLUME_VAL +
        (percent * (MAX_CAP_VOLUME_VAL - MIN_CAP_VOLUME_VAL) + 50) / 100;
  }

  TRACE(2, "CAP VOL CTRL: percent=%u new_capture_vol=%u", percent,
        new_capture_vol);

  usb_audio_enqueue_cmd(AUDIO_CMD_SET_CAP_VOLUME);
}

static uint32_t usb_audio_get_vol_percent(void) {
  if (new_playback_vol >= MAX_VOLUME_VAL) {
    return 100;
  } else if (new_playback_vol <= MIN_VOLUME_VAL) {
    return 0;
  } else {
    return ((new_playback_vol - MIN_VOLUME_VAL) * 100 +
            (MAX_VOLUME_VAL - MIN_VOLUME_VAL) / 2) /
           (MAX_VOLUME_VAL - MIN_VOLUME_VAL);
  }
}

static uint32_t usb_audio_get_cap_vol_percent(void) {
  if (new_capture_vol >= MAX_CAP_VOLUME_VAL) {
    return 100;
  } else if (new_capture_vol <= MIN_CAP_VOLUME_VAL) {
    return 0;
  } else {
    return ((new_capture_vol - MIN_CAP_VOLUME_VAL) * 100 +
            (MAX_CAP_VOLUME_VAL - MIN_CAP_VOLUME_VAL) / 2) /
           (MAX_CAP_VOLUME_VAL - MIN_CAP_VOLUME_VAL);
  }
}

static void usb_audio_tune_rate(enum AUD_STREAM_T stream, float ratio) {
  bool update_play, update_cap;

  update_play = true;
  update_cap = false;

#if defined(__AUDIO_RESAMPLE__) && defined(PLL_TUNE_SAMPLE_RATE)
#ifdef UAUD_SYNC_STREAM_TARGET
  if (stream == AUD_STREAM_PLAYBACK) {
    update_play = true;
    update_cap = false;
  } else {
    update_play = false;
    update_cap = true;
  }
#else
  update_play = true;
  update_cap = true;
#endif
#endif

  if (update_play) {
    rate_tune_ratio[AUD_STREAM_PLAYBACK] =
        rate_tune_ratio[AUD_STREAM_PLAYBACK] + ratio +
        rate_tune_ratio[AUD_STREAM_PLAYBACK] * ratio;
  }
  if (update_cap) {
    rate_tune_ratio[AUD_STREAM_CAPTURE] =
        rate_tune_ratio[AUD_STREAM_CAPTURE] + ratio +
        rate_tune_ratio[AUD_STREAM_CAPTURE] * ratio;
  }

  TRACE(4, "%s[%u]: ratio=%d resample_ratio=%d", __FUNCTION__, stream,
        FLOAT_TO_PPB_INT(ratio),
        update_cap ? FLOAT_TO_PPB_INT(rate_tune_ratio[stream])
                   : FLOAT_TO_PPB_INT(rate_tune_ratio[AUD_STREAM_PLAYBACK]));

  enqueue_unique_cmd_arg(AUDIO_CMD_TUNE_RATE, 0, stream);
}

static void
usb_audio_data_recv_handler(const struct USB_AUDIO_XFER_INFO_T *info) {
  const uint8_t *data;
  uint32_t size;
  uint32_t old_wpos, new_wpos, wpos_boundary, rpos;
  uint32_t old_play_pos = 0;
  uint32_t play_pos;
  uint32_t lock;
  int conflicted;
  uint32_t recv_samp, play_samp;
  uint32_t cur_time;

  cur_time = hal_sys_timer_get();
  last_usb_recv_time = cur_time;

  data = info->data;
  size = info->size;

  if (info->cur_compl_err || info->next_xfer_err) {
    if (usb_recv_err_cnt == 0) {
      usb_recv_err_cnt++;
      usb_recv_ok_cnt = 0;
      last_usb_recv_err_time = cur_time;
    } else {
      usb_recv_err_cnt++;
    }
  } else {
    if (usb_recv_err_cnt) {
      usb_recv_ok_cnt++;
    }
  }
  if (usb_recv_err_cnt &&
      cur_time - last_usb_recv_err_time >= USB_XFER_ERR_REPORT_INTERVAL) {
    if (info->cur_compl_err || info->next_xfer_err) {
      TRACE(2, "recv: ERROR: cur_err=%d next_err=%d", info->cur_compl_err,
            info->next_xfer_err);
    }
    TRACE(3, "recv: ERROR-CNT: err=%u ok=%u in %u ms", usb_recv_err_cnt,
          usb_recv_ok_cnt, TICKS_TO_MS(USB_XFER_ERR_REPORT_INTERVAL));
    usb_recv_err_cnt = 0;
  }

  if (usb_recv_buf <= data && data <= usb_recv_buf + usb_recv_size) {
    if (data != usb_recv_buf + usb_recv_wpos) {
      TRACE(
          3,
          "recv: WARNING: Invalid wpos=0x%x data=%p recv_buf=%p. IRQ missing?",
          usb_recv_wpos, data, usb_recv_buf);
      usb_recv_wpos = data - usb_recv_buf;
    }
  }

  old_wpos = usb_recv_wpos;
  new_wpos = old_wpos + size;
  if (new_wpos >= usb_recv_size) {
    new_wpos -= usb_recv_size;
  }

  if (recv_state == AUDIO_ITF_STATE_STOPPED || size == 0 || // rx paused
      0) {
    usb_recv_valid = 0;
  } else {
    if (info->cur_compl_err == 0) {
      usb_recv_valid = 1;
    }
  }

  if (usb_recv_valid == 0 || usb_recv_init_rpos == 0 || codec_config_lock ||
      codec_play_seq != usb_recv_seq || codec_play_valid == 0 ||
      playback_state == AUDIO_ITF_STATE_STOPPED || 0) {
    usb_recv_wpos = new_wpos;
    return;
  }

  conflicted = 0;

  lock = int_lock();
  if (playback_conflicted) {
    playback_conflicted = 0;
    rpos = 0; // Avoid compiler warnings
    conflicted = 1;
  } else {
    rpos = usb_recv_rpos;
    old_play_pos = playback_pos;
    play_pos = af_stream_get_cur_dma_pos(AUD_STREAM_ID_0, AUD_STREAM_PLAYBACK);
  }
  int_unlock(lock);

  if (conflicted == 0) {
    if (info->pool_enabled) {
      // USBC will write to memory pool.
      wpos_boundary = new_wpos;
    } else {
      // USBC will write to new_wpos directly, so the buffer [new_wpos, new_wpos
      // + info->next_size) must be protected too.
      wpos_boundary = new_wpos + info->next_size;
      if (wpos_boundary >= usb_recv_size) {
        wpos_boundary -= usb_recv_size;
      }
    }

    if (old_wpos <= rpos) {
      if (wpos_boundary < old_wpos || rpos < wpos_boundary) {
        conflicted = 1;
      }
    } else {
      if (rpos < wpos_boundary && wpos_boundary < old_wpos) {
        conflicted = 1;
      }
    }

    if (conflicted) {
      uint32_t reset_len = usb_recv_size / 2;
      uint32_t saved_old_wpos = old_wpos;

      // Reset write position
      old_wpos = rpos + reset_len;
      if (old_wpos >= usb_recv_size) {
        old_wpos -= usb_recv_size;
      }
      new_wpos = old_wpos + size;
      if (new_wpos >= usb_recv_size) {
        new_wpos -= usb_recv_size;
      }

#if 0
            usb_audio_stop_recv();
            usb_audio_start_recv(usb_recv_buf, new_wpos, usb_recv_size);
#else
      usb_audio_set_recv_pos(new_wpos);
#endif

      TRACE(4,
            "recv: Error: wpos=%u goes beyond rpos=%u with len=%u. Reset to %u",
            saved_old_wpos, rpos, size, old_wpos);
    }
    record_conflict(conflicted);
  }

  usb_recv_wpos = new_wpos;

#if (VERBOSE_TRACE & (1 << 5))
  {
    int hw_play_pos =
        af_stream_get_cur_dma_pos(AUD_STREAM_ID_0, AUD_STREAM_PLAYBACK);
    TRACE_TIME(5,
               "recv: wpos=%u size=%u rpos=%u playback_pos=%u hw_play_pos=%d",
               old_wpos, size, rpos, playback_pos, hw_play_pos);
  }
#endif

  if (conflicted) {
    usb_audio_sync_reset(&playback_info);
    return;
  }

  if (usb_recv_buf <= data && data <= usb_recv_buf + usb_recv_size) {
    recv_samp = byte_to_samp_recv(new_wpos);
  } else {
    recv_samp = -1;
  }

  if ((int)play_pos >= 0) {
    if (play_pos >= playback_size) {
      play_pos = 0;
    }
    // Count the bytes of data waiting to play in the codec buffer
    uint32_t bytes_to_play;
    if (old_play_pos <= play_pos) {
      bytes_to_play = playback_size + old_play_pos - play_pos;
    } else {
      bytes_to_play = old_play_pos - play_pos;
    }
    uint32_t usb_bytes_to_play;
    usb_bytes_to_play = playback_to_recv_len(bytes_to_play);
    if (rpos >= usb_bytes_to_play) {
      play_pos = rpos - usb_bytes_to_play;
    } else {
      play_pos = usb_recv_size + rpos - usb_bytes_to_play;
    }
    play_samp = byte_to_samp_recv(play_pos);
  } else {
    play_samp = -1;
  }

  if (recv_samp != -1 && play_samp != -1) {
    enum UAUD_SYNC_RET_T ret;
    float ratio;

    ret = usb_audio_sync(play_samp, recv_samp, &playback_info, &ratio);
    if (ret == UAUD_SYNC_START) {
      usb_audio_tune_rate(AUD_STREAM_PLAYBACK, ratio);
    }
  } else {
    // TRACE(2,"recv_hdlr: recv_samp=0x%08x play_samp=0x%08x", recv_samp,
    // play_samp);
  }

#ifdef DSD_SUPPORT
  if (sample_size_recv == 3 &&
      (sample_rate_recv == 176400 || sample_rate_recv == 352800)) {
    // First DoP solution marks
    static const uint8_t pattern[2] = {
        0x05,
        0xFA,
    };
    // Second DoP solution marks -- not supported yet
    // static const uint8_t pattern2[2] = { 0x06, 0xF9, };
    static const uint16_t dsd_detect_thresh = 32;
    uint8_t idx;
    const uint8_t *dsd, *dsd_end, *dsd_end2;
    bool dsd_valid = true;

    dsd = data + 2;
    dsd_end = data + size;
    dsd_end2 = usb_recv_buf + usb_recv_size;
    if (dsd_end <= dsd_end2) {
      dsd_end2 = NULL;
    } else {
      dsd_end = dsd_end2;
      dsd_end2 = data + size - usb_recv_size;
    }
    if (*dsd == pattern[0]) {
      idx = 0;
    } else {
      idx = 1;
    }

  _check_dsd:
    while (dsd < dsd_end) {
      if (*dsd == pattern[idx]) {
#if (CHAN_NUM_RECV == 2)
        dsd += 3;
        if (dsd >= dsd_end || *dsd != pattern[idx]) {
          dsd_valid = false;
          break;
        }
#endif
        if (usb_dsd_cont_cnt < dsd_detect_thresh) {
          usb_dsd_cont_cnt += CHAN_NUM_RECV;
        }
        idx = !idx;
        dsd += 3;
      } else {
        dsd_valid = false;
        break;
      }
    }
    if (dsd_valid && dsd_end2) {
      dsd = usb_recv_buf + 2;
      dsd_end = dsd_end2;
      dsd_end2 = NULL;
      goto _check_dsd;
    }

    if (dsd_valid && usb_dsd_cont_cnt < dsd_detect_thresh) {
      dsd_valid = false;
    }
    if (!dsd_valid) {
      usb_dsd_cont_cnt = 0;
    }

    if (dsd_valid != usb_dsd_enabled) {
      usb_dsd_enabled = dsd_valid;
      enqueue_unique_cmd(AUDIO_CMD_SET_DSD_CFG);
    }
  }
#endif
}

static void
usb_audio_data_send_handler(const struct USB_AUDIO_XFER_INFO_T *info) {
  const uint8_t *data;
  uint32_t size;
  uint32_t old_rpos, new_rpos, rpos_boundary, wpos;
  uint32_t old_cap_pos = 0;
  uint32_t cap_pos;
  uint32_t lock;
  int conflicted;
  uint32_t send_samp, cap_samp;
  uint32_t cur_time;

  cur_time = hal_sys_timer_get();
  last_usb_send_time = cur_time;

  data = info->data;
  size = info->size;

  if (info->cur_compl_err || info->next_xfer_err) {
    if (usb_send_err_cnt == 0) {
      usb_send_err_cnt++;
      usb_send_ok_cnt = 0;
      last_usb_send_err_time = cur_time;
    } else {
      usb_send_err_cnt++;
    }
  } else {
    if (usb_send_err_cnt) {
      usb_send_ok_cnt++;
    }
  }
  if (usb_send_err_cnt &&
      cur_time - last_usb_send_err_time >= USB_XFER_ERR_REPORT_INTERVAL) {
    if (info->cur_compl_err || info->next_xfer_err) {
      TRACE(2, "send: ERROR: cur_err=%d next_err=%d", info->cur_compl_err,
            info->next_xfer_err);
    }
    TRACE(3, "send: ERROR-CNT: err=%u ok=%u in %u ms", usb_send_err_cnt,
          usb_send_ok_cnt, TICKS_TO_MS(USB_XFER_ERR_REPORT_INTERVAL));
    usb_send_err_cnt = 0;
  }

  if (info->pool_enabled) {
    // The buffer [data, size) has been sent completely, and
    // the buffer [data + size, data + size + info->next_size) has been copied
    // to memory pool. Make usb_send_rpos point to the pending send buffer
    data += size;
    if (data >= usb_send_buf + usb_send_size) {
      data -= usb_send_size;
    }
    size = info->next_size;
  }

  if (usb_send_buf <= data && data <= usb_send_buf + usb_send_size) {
    if (data != usb_send_buf + usb_send_rpos) {
      if (usb_send_valid == 0 && info->pool_enabled &&
          info->data != usb_send_buf + usb_send_rpos) {
        TRACE(3,
              "send: WARNING: Invalid rpos=0x%x data=%p send_buf=%p. IRQ "
              "missing?",
              usb_send_rpos, data, usb_send_buf);
      }
      usb_send_rpos = data - usb_send_buf;
    }
  }

  old_rpos = usb_send_rpos;
  new_rpos = old_rpos + size;
  if (new_rpos >= usb_send_size) {
    new_rpos -= usb_send_size;
  }

  if (send_state == AUDIO_ITF_STATE_STOPPED || size == 0 || // tx paused
      0) {
    usb_send_valid = 0;
  } else {
    if (info->cur_compl_err == 0) {
      usb_send_valid = 1;
    }
  }

  if (usb_send_valid == 0 || usb_send_init_wpos == 0 || codec_config_lock ||
      codec_cap_seq != usb_send_seq || codec_cap_valid == 0 ||
      capture_state == AUDIO_ITF_STATE_STOPPED || 0) {
    usb_send_rpos = new_rpos;
    if (usb_send_valid) {
      // Zero the send buffer next to the part being sent by USB h/w
      if (info->pool_enabled) {
        uint32_t clr_len;

        clr_len = samp_to_byte_send(SAMP_RATE_TO_FRAME_SIZE(sample_rate_send));
        if (usb_send_rpos + clr_len <= usb_send_size) {
          zero_mem16(usb_send_buf + usb_send_rpos, clr_len);
        } else {
          zero_mem16(usb_send_buf + usb_send_rpos,
                     usb_send_size - usb_send_rpos);
          zero_mem16(usb_send_buf, clr_len - (usb_send_size - usb_send_rpos));
        }
      } else {
        // If no pool is enabled, the send pkt size is a fixed value, and
        // the send buffer size is a integral multiple of the send pkt size
        if (usb_send_rpos + size + size <= usb_send_size) {
          zero_mem32(usb_send_buf + usb_send_rpos + size, size);
        } else {
          zero_mem32(usb_send_buf, size);
        }
      }
    }
    return;
  }

  conflicted = 0;

  lock = int_lock();
  if (capture_conflicted) {
    capture_conflicted = 0;
    wpos = 0; // Avoid compiler warnings
    conflicted = 1;
  } else {
    wpos = usb_send_wpos;
    old_cap_pos = capture_pos;
    cap_pos = af_stream_get_cur_dma_pos(AUD_STREAM_ID_0, AUD_STREAM_CAPTURE);
  }
  int_unlock(lock);

  if (conflicted == 0) {
    if (info->pool_enabled) {
      // old_rpos points to the pending send buffer, which has been copied to
      // memory pool. USBC will read from memory pool.
      rpos_boundary = new_rpos;
    } else {
      // old_rpos points to the buffer just sent completely.
      // USBC will read from new_rpos directly, so the buffer [new_rpos,
      // new_rpos + info->next_size) must be protected too.
      rpos_boundary = new_rpos + info->next_size;
      if (rpos_boundary >= usb_recv_size) {
        rpos_boundary -= usb_recv_size;
      }
    }

    if (old_rpos <= wpos) {
      if (new_rpos < old_rpos || wpos < new_rpos) {
        conflicted = 1;
      }
    } else {
      if (wpos < new_rpos && new_rpos < old_rpos) {
        conflicted = 1;
      }
    }

    if (conflicted) {
      uint32_t reset_len = usb_send_size / 2;
      uint32_t saved_old_rpos = old_rpos;

      // Reset read position
      old_rpos = wpos + reset_len;
      if (old_rpos >= usb_send_size) {
        old_rpos -= usb_send_size;
      }
      new_rpos = old_rpos + size;
      if (new_rpos >= usb_send_size) {
        new_rpos -= usb_send_size;
      }

#if 0
            usb_audio_stop_send();
            usb_audio_start_send(usb_send_buf, new_rpos, usb_send_size);
#else
      usb_audio_set_send_pos(new_rpos);
#endif

      TRACE(4,
            "send: Error: rpos=%u goes beyond wpos=%u with len=%u. Reset to %u",
            saved_old_rpos, wpos, size, old_rpos);
    }
    record_conflict(conflicted);
  }

  usb_send_rpos = new_rpos;

#if (VERBOSE_TRACE & (1 << 6))
  TRACE_TIME(3, "send: rpos=%u size=%u wpos=%u", old_rpos, size, wpos);
#endif

  if (conflicted) {
    usb_audio_sync_reset(&capture_info);
    return;
  }

#ifndef UAUD_SYNC_STREAM_TARGET
  // Recv takes precedence
  if (recv_state == AUDIO_ITF_STATE_STARTED) {
    return;
  }
#endif

  if (usb_send_buf <= data && data <= usb_send_buf + usb_send_size) {
    send_samp = byte_to_samp_send(new_rpos);
  } else {
    send_samp = -1;
  }

  if ((int)cap_pos >= 0) {
    if (cap_pos >= capture_size) {
      cap_pos = 0;
    }
    // Count the bytes of data newly captured in the codec buffer
    uint32_t bytes_cap;
    if (old_cap_pos <= cap_pos) {
      bytes_cap = cap_pos - old_cap_pos;
    } else {
      bytes_cap = capture_size + cap_pos - old_cap_pos;
    }
    uint32_t usb_bytes_cap;
    usb_bytes_cap = capture_to_send_len(bytes_cap);
    cap_pos = wpos + usb_bytes_cap;
    if (cap_pos >= usb_send_size) {
      cap_pos -= usb_send_size;
    }
    cap_samp = byte_to_samp_send(cap_pos);
  } else {
    cap_samp = -1;
  }

  if (send_samp != -1 && cap_samp != -1) {
    enum UAUD_SYNC_RET_T ret;
    float ratio;

    ret = usb_audio_sync(cap_samp, send_samp, &capture_info, &ratio);
    if (ret == UAUD_SYNC_START) {
      usb_audio_tune_rate(AUD_STREAM_CAPTURE, ratio);
    }
  } else {
    // TRACE(2,"send_hdlr: send_samp=0x%08x cap_samp=0x%08x", send_samp,
    // cap_samp);
  }
}

#ifdef USB_AUDIO_MULTIFUNC
static float playback_gain_to_float(uint32_t level) {
  int32_t db;

  if (level > MAX_VOLUME_VAL || level < MIN_VOLUME_VAL) {
    return 0;
  }

  db = codec_dac_vol[level].sdac_volume;
  if (db <= USB_AUDIO_MIN_DBVAL) {
    return 0;
  }

  return db_to_float(db);
}

static void usb_audio_playback2_start(enum USB_AUDIO_ITF_CMD_T cmd) {
  if (cmd == USB_AUDIO_ITF_STOP) {
    // Stop the stream right now
    if (recv2_state == AUDIO_ITF_STATE_STARTED) {
      usb_audio_stop_recv2();
      if (recv_state == AUDIO_ITF_STATE_STOPPED &&
          send_state == AUDIO_ITF_STATE_STOPPED) {
        usb_audio_sync_reset(&playback_info);
      }
      recv2_state = AUDIO_ITF_STATE_STOPPED;
    }

    if (recv_state == AUDIO_ITF_STATE_STARTED) {
      return;
    }

    enqueue_unique_cmd_with_opp(AUDIO_CMD_STOP_PLAY, usb_recv_seq, 0,
                                AUDIO_CMD_START_PLAY);
  } else {
    if (recv2_state == AUDIO_ITF_STATE_STOPPED) {
      int ret;

      reset_conflict();

      if (recv_state == AUDIO_ITF_STATE_STOPPED &&
          send_state == AUDIO_ITF_STATE_STOPPED) {
        usb_audio_sync_reset(&playback_info);
      }

      usb_recv2_valid = 0;
      if (recv_state == AUDIO_ITF_STATE_STOPPED) {
        usb_recv_seq++;
      }

      usb_recv2_rpos = 0;
      usb_recv2_wpos = usb_recv_size / 2;
      zero_mem32(usb_recv2_buf, usb_recv2_size);

      usb_recv2_err_cnt = 0;

      ret =
          usb_audio_start_recv2(usb_recv2_buf, usb_recv2_wpos, usb_recv2_size);
      if (ret == 1) {
        TRACE(0, "usb_audio_start_recv2 failed: usb not configured");
      } else {
        ASSERT(ret == 0, "usb_audio_start_recv2 failed: %d", ret);
      }
      recv2_state = AUDIO_ITF_STATE_STARTED;
    }

    if (recv_state == AUDIO_ITF_STATE_STARTED) {
      return;
    }

    enqueue_unique_cmd_with_opp(AUDIO_CMD_START_PLAY, usb_recv_seq, 0,
                                AUDIO_CMD_STOP_PLAY);
  }
}

static void usb_audio_mute2_control(uint32_t mute) {
  TRACE(1, "MUTE2 CTRL: %u", mute);

  new_mute2_state = mute;
  if (mute) {
    new_playback2_coef = 0;
  } else {
    new_playback2_coef = playback_gain_to_float(new_playback2_vol);
  }
  usb_audio_enqueue_cmd(AUDIO_CMD_MUTE_CTRL);
}

static void usb_audio_vol2_control(uint32_t percent) {
  if (percent >= 100) {
    new_playback2_vol = MAX_VOLUME_VAL;
  } else {
    new_playback2_vol =
        MIN_VOLUME_VAL +
        (percent * (MAX_VOLUME_VAL - MIN_VOLUME_VAL) + 50) / 100;
  }

  new_playback2_coef = playback_gain_to_float(new_playback2_vol);

  TRACE(2, "VOL2 CTRL: percent=%u new_playback_vol=%u", percent,
        new_playback2_vol);
}

static uint32_t usb_audio_get_vol2_percent(void) {
  if (new_playback2_vol >= MAX_VOLUME_VAL) {
    return 100;
  } else {
    return ((new_playback2_vol - MIN_VOLUME_VAL) * 100 +
            (MAX_VOLUME_VAL - MIN_VOLUME_VAL) / 2) /
           (MAX_VOLUME_VAL - MIN_VOLUME_VAL);
  }
}

static void
usb_audio_data_recv2_handler(const struct USB_AUDIO_XFER_INFO_T *info) {
  const uint8_t *data;
  uint32_t size;
  uint32_t old_wpos, new_wpos, wpos_boundary, rpos;
  uint32_t old_play_pos = 0;
  uint32_t play_pos;
  uint32_t lock;
  int conflicted;
  uint32_t recv_samp, play_samp;
  uint32_t cur_time;

  cur_time = hal_sys_timer_get();
  last_usb_recv_time = cur_time;

  data = info->data;
  size = info->size;

  if (info->cur_compl_err || info->next_xfer_err) {
    if (usb_recv2_err_cnt == 0) {
      usb_recv2_err_cnt++;
      usb_recv2_ok_cnt = 0;
      last_usb_recv2_err_time = cur_time;
    } else {
      usb_recv2_err_cnt++;
    }
  } else {
    if (usb_recv2_err_cnt) {
      usb_recv2_ok_cnt++;
    }
  }
  if (usb_recv2_err_cnt &&
      cur_time - last_usb_recv2_err_time >= USB_XFER_ERR_REPORT_INTERVAL) {
    if (info->cur_compl_err || info->next_xfer_err) {
      TRACE(2, "recv2: ERROR: cur_err=%d next_err=%d", info->cur_compl_err,
            info->next_xfer_err);
    }
    TRACE(3, "recv2: ERROR-CNT: err=%u ok=%u in %u ms", usb_recv2_err_cnt,
          usb_recv2_ok_cnt, TICKS_TO_MS(USB_XFER_ERR_REPORT_INTERVAL));
    usb_recv2_err_cnt = 0;
  }

  if (usb_recv2_buf <= data && data <= usb_recv2_buf + usb_recv2_size) {
    if (data != usb_recv2_buf + usb_recv2_wpos) {
      TRACE(3,
            "recv2: WARNING: Invalid wpos=0x%x data=%p recv2_buf=%p. IRQ "
            "missing?",
            usb_recv2_wpos, data, usb_recv2_buf);
      usb_recv2_wpos = data - usb_recv2_buf;
    }
  }

  old_wpos = usb_recv2_wpos;
  new_wpos = old_wpos + size;
  if (new_wpos >= usb_recv2_size) {
    new_wpos -= usb_recv2_size;
  }

  if (codec_config_lock || codec_play_seq != usb_recv_seq ||
      codec_play_valid == 0 || playback_state == AUDIO_ITF_STATE_STOPPED ||
      recv2_state == AUDIO_ITF_STATE_STOPPED || size == 0 || // rx paused
      0) {
    usb_recv2_valid = 0;
  } else {
    if (info->cur_compl_err == 0) {
      usb_recv2_valid = 1;
    }
  }

  if (usb_recv2_valid == 0 || usb_recv2_init_rpos == 0) {
    usb_recv2_wpos = new_wpos;
    return;
  }

  conflicted = 0;

  lock = int_lock();
  if (playback_conflicted2) {
    playback_conflicted2 = 0;
    rpos = 0; // Avoid compiler warnings
    conflicted = 1;
  } else {
    rpos = usb_recv2_rpos;
    old_play_pos = playback_pos;
    play_pos = af_stream_get_cur_dma_pos(AUD_STREAM_ID_0, AUD_STREAM_PLAYBACK);
  }
  int_unlock(lock);

  if (conflicted == 0) {
    if (info->pool_enabled) {
      // USBC will write to memory pool.
      wpos_boundary = new_wpos;
    } else {
      // USBC will write to new_wpos directly, so the buffer [new_wpos, new_wpos
      // + info->next_size) must be protected too.
      wpos_boundary = new_wpos + info->next_size;
      if (wpos_boundary >= usb_recv2_size) {
        wpos_boundary -= usb_recv2_size;
      }
    }

    if (old_wpos <= rpos) {
      if (wpos_boundary < old_wpos || rpos < wpos_boundary) {
        conflicted = 1;
      }
    } else {
      if (rpos < wpos_boundary && wpos_boundary < old_wpos) {
        conflicted = 1;
      }
    }

    if (conflicted) {
      uint32_t reset_len = usb_recv2_size / 2;
      uint32_t saved_old_wpos = old_wpos;

      // Reset read position
      old_wpos = rpos + reset_len;
      if (old_wpos >= usb_recv2_size) {
        old_wpos -= usb_recv2_size;
      }
      new_wpos = old_wpos + size;
      if (new_wpos >= usb_recv2_size) {
        new_wpos -= usb_recv2_size;
      }

#if 0
            usb_audio_stop_recv();
            usb_audio_start_recv(usb_recv2_buf, new_wpos, usb_recv2_size);
#else
      usb_audio_set_recv2_pos(new_wpos);
#endif

      TRACE(
          4,
          "recv2: Error: wpos=%u goes beyond rpos=%u with len=%u. Reset to %u",
          saved_old_wpos, rpos, size, old_wpos);
    }
    record_conflict(conflicted);
  }

  usb_recv2_wpos = new_wpos;

#if (VERBOSE_TRACE & (1 << 5))
  {
    int hw_play_pos =
        af_stream_get_cur_dma_pos(AUD_STREAM_ID_0, AUD_STREAM_PLAYBACK);
    TRACE_TIME(5,
               "recv2: wpos=%u size=%u rpos=%u playback_pos=%u hw_play_pos=%d",
               old_wpos, size, rpos, playback_pos, hw_play_pos);
  }
#endif

  if (conflicted) {
    usb_audio_sync_reset(&playback_info);
    return;
  }

  // Recv and send takes precedence
  if (recv_state == AUDIO_ITF_STATE_STARTED ||
      send_state == AUDIO_ITF_STATE_STARTED) {
    return;
  }

  if (usb_recv2_buf <= data && data <= usb_recv2_buf + usb_recv2_size) {
    recv_samp = byte_to_samp_recv(new_wpos);
  } else {
    recv_samp = -1;
  }

  if ((int)play_pos >= 0) {
    if (play_pos >= playback_size) {
      play_pos = 0;
    }
    // Count the bytes of data waiting to play in the codec buffer
    uint32_t bytes_to_play;
    if (old_play_pos <= play_pos) {
      bytes_to_play = playback_size + old_play_pos - play_pos;
    } else {
      bytes_to_play = old_play_pos - play_pos;
    }
    uint32_t usb_bytes_to_play;
    usb_bytes_to_play = playback_to_recv_len(bytes_to_play);
    if (rpos >= usb_bytes_to_play) {
      play_pos = rpos - usb_bytes_to_play;
    } else {
      play_pos = usb_recv2_size + rpos - usb_bytes_to_play;
    }
    play_samp = byte_to_samp_recv(play_pos);
  } else {
    play_samp = -1;
  }

  if (recv_samp != -1 && play_samp != -1) {
    enum UAUD_SYNC_RET_T ret;
    float ratio;

    ret = usb_audio_sync(play_samp, recv_samp, &playback_info, &ratio);
    if (ret == UAUD_SYNC_START) {
      usb_audio_tune_rate(AUD_STREAM_PLAYBACK, ratio);
    }
  } else {
    // TRACE(2,"recv_hdlr: recv_samp=0x%08x play_samp=0x%08x", recv_samp,
    // play_samp);
  }
}
#endif

static void usb_audio_reset_usb_stream_state(bool init) {
  if (init) {
    recv_state = AUDIO_ITF_STATE_STOPPED;
    send_state = AUDIO_ITF_STATE_STOPPED;

#ifdef USB_AUDIO_DYN_CFG
    // Reset itf setting
    playback_itf_set = 0;
    capture_itf_set = 0;
#endif

    // Reset mute and volume setting
    new_mute_state = 0;
    new_cap_mute_state = 0;

    new_playback_vol = AUDIO_OUTPUT_VOLUME_DEFAULT;
    if (new_playback_vol > MAX_VOLUME_VAL) {
      new_playback_vol = MAX_VOLUME_VAL;
    } else if (new_playback_vol < MIN_VOLUME_VAL) {
      new_playback_vol = MIN_VOLUME_VAL;
    }

    new_capture_vol = CODEC_SADC_VOL;
    if (new_capture_vol > MAX_CAP_VOLUME_VAL) {
      new_capture_vol = MAX_CAP_VOLUME_VAL;
    } else if (new_capture_vol < MIN_CAP_VOLUME_VAL) {
      new_capture_vol = MIN_CAP_VOLUME_VAL;
    }

#ifdef USB_AUDIO_MULTIFUNC
    new_playback_coef = playback_gain_to_float(new_playback_vol);
    playback_coef = new_playback_coef;

    recv2_state = AUDIO_ITF_STATE_STOPPED;
    new_mute2_state = 0;
    new_playback2_vol = AUDIO_OUTPUT_VOLUME_DEFAULT;
    if (new_playback2_vol > MAX_VOLUME_VAL) {
      new_playback2_vol = MAX_VOLUME_VAL;
    } else if (new_playback2_vol < MIN_VOLUME_VAL) {
      new_playback2_vol = MIN_VOLUME_VAL;
    }
    new_playback2_coef = playback_gain_to_float(new_playback2_vol);
    playback2_coef = new_playback2_coef;
#endif
  } else {
    if (recv_state == AUDIO_ITF_STATE_STARTED) {
      usb_audio_stop_usb_stream(AUD_STREAM_PLAYBACK);
      recv_state = AUDIO_ITF_STATE_STOPPED;
    }
    if (send_state == AUDIO_ITF_STATE_STARTED) {
      usb_audio_stop_usb_stream(AUD_STREAM_CAPTURE);
      send_state = AUDIO_ITF_STATE_STOPPED;
    }

#ifdef USB_AUDIO_MULTIFUNC
    if (recv2_state == AUDIO_ITF_STATE_STARTED) {
      usb_audio_stop_recv2();
      if (recv_state == AUDIO_ITF_STATE_STOPPED &&
          send_state == AUDIO_ITF_STATE_STOPPED) {
        usb_audio_sync_reset(&playback_info);
      }
      recv2_state = AUDIO_ITF_STATE_STOPPED;
    }
#endif

    // Keep old itf setting unless it is in init mode

    // Keep old mute and playback volume setting unless it is in init mode
  }
}

static void usb_audio_reset_codec_stream_state(bool init) {
  playback_state = AUDIO_ITF_STATE_STOPPED;
  capture_state = AUDIO_ITF_STATE_STOPPED;

#ifndef USB_AUDIO_MULTIFUNC
  playback_vol = new_playback_vol;
#endif
  capture_vol = new_capture_vol;

  playback_paused = 0;

  playback_conflicted = 0;
#ifdef USB_AUDIO_MULTIFUNC
  playback_conflicted2 = 0;
#endif
  capture_conflicted = 0;

  // Keep old mute setting unless it is in init mode
  if (init) {
#ifdef PERF_TEST_POWER_KEY
    perft_power_type = 0;
    af_codec_set_perf_test_power(perft_power_type);
#endif
#ifdef PA_ON_OFF_KEY
    if (pa_on_off_muted) {
      pa_on_off_muted = false;
      if (mute_user_map == 0) {
        usb_audio_codec_unmute(CODEC_MUTE_USER_ALL);
      }
    }
#endif
    if (mute_user_map) {
      mute_user_map = 0;
      usb_audio_codec_unmute(CODEC_MUTE_USER_ALL);
    }
#if defined(NOISE_GATING) && defined(NOISE_REDUCTION)
    restore_noise_reduction_status();
#endif
  }
}

#ifdef USB_AUDIO_DYN_CFG
static void usb_audio_set_recv_rate(enum AUD_SAMPRATE_T rate) {
#ifndef USB_AUDIO_UAC2
  if (playback_itf_set == 0) {
    TRACE(1, "\nWARNING: Set recv rate while itf not set: %d\n", rate);
    return;
  }
#endif

  // Some host applications will not stop current stream before changing sample
  // rate
  if (recv_state == AUDIO_ITF_STATE_STARTED) {
    usb_audio_stop_usb_stream(AUD_STREAM_PLAYBACK);
    recv_state = AUDIO_ITF_STATE_STOPPED;
  }

  TRACE(3, "%s: Change recv sample rate from %u to %u", __FUNCTION__,
        sample_rate_recv, rate);

  new_sample_rate_recv = rate;

#ifdef KEEP_SAME_LATENCY
  usb_recv_size =
      calc_usb_recv_size(new_sample_rate_recv, new_sample_size_recv);
  TRACE(2, "%s: Set usb_recv_size=%u", __FUNCTION__, usb_recv_size);
#endif

  if (playback_itf_set) {
    usb_audio_start_usb_stream(AUD_STREAM_PLAYBACK);
    recv_state = AUDIO_ITF_STATE_STARTED;
  }

#ifdef USB_AUDIO_UAC2
  enqueue_unique_cmd_arg(AUDIO_CMD_SET_RECV_RATE, usb_recv_seq, 0);
#else
  enqueue_unique_cmd_with_opp(AUDIO_CMD_SET_RECV_RATE, usb_recv_seq, 0,
                              AUDIO_CMD_STOP_PLAY);
#endif
}

static void usb_audio_set_send_rate(enum AUD_SAMPRATE_T rate) {
#ifndef USB_AUDIO_UAC2
  if (capture_itf_set == 0) {
    TRACE(1, "\nWARNING: Set send rate while itf not set: %d\n", rate);
    return;
  }
#endif

  // Some host applications will not stop current stream before changing sample
  // rate
  if (send_state == AUDIO_ITF_STATE_STARTED) {
    usb_audio_stop_usb_stream(AUD_STREAM_CAPTURE);
    send_state = AUDIO_ITF_STATE_STOPPED;
  }

  TRACE(3, "%s: Change send sample rate from %u to %u", __FUNCTION__,
        sample_rate_send, rate);

  new_sample_rate_send = rate;

#ifdef KEEP_SAME_LATENCY
  usb_send_size = calc_usb_send_size(new_sample_rate_send);
  TRACE(2, "%s: Set usb_send_size=%u", __FUNCTION__, usb_send_size);
#endif

  if (capture_itf_set) {
    usb_audio_start_usb_stream(AUD_STREAM_CAPTURE);
    send_state = AUDIO_ITF_STATE_STARTED;
  }

#ifdef USB_AUDIO_UAC2
  enqueue_unique_cmd_arg(AUDIO_CMD_SET_SEND_RATE, usb_send_seq, 0);
#else
  enqueue_unique_cmd_with_opp(AUDIO_CMD_SET_SEND_RATE, usb_send_seq, 0,
                              AUDIO_CMD_STOP_CAPTURE);
#endif
}
#endif

static void usb_audio_state_control(enum USB_AUDIO_STATE_EVENT_T event,
                                    uint32_t param) {
  TRACE(3, "%s: %d (%u)", __FUNCTION__, event, param);

  if (event == USB_AUDIO_STATE_RESET || event == USB_AUDIO_STATE_DISCONNECT ||
      event == USB_AUDIO_STATE_CONFIG) {
    usb_audio_reset_usb_stream_state(true);
  } else if (event == USB_AUDIO_STATE_SLEEP ||
             event == USB_AUDIO_STATE_WAKEUP) {
    usb_audio_reset_usb_stream_state(false);
  }

  if (event == USB_AUDIO_STATE_RESET) {
    usb_audio_enqueue_cmd(AUDIO_CMD_USB_RESET);
  } else if (event == USB_AUDIO_STATE_DISCONNECT) {
    usb_audio_enqueue_cmd(AUDIO_CMD_USB_DISCONNECT);
  } else if (event == USB_AUDIO_STATE_CONFIG) {
    usb_audio_enqueue_cmd(AUDIO_CMD_USB_CONFIG);
  } else if (event == USB_AUDIO_STATE_SLEEP) {
    usb_audio_enqueue_cmd(AUDIO_CMD_USB_SLEEP);
  } else if (event == USB_AUDIO_STATE_WAKEUP) {
    usb_audio_enqueue_cmd(AUDIO_CMD_USB_WAKEUP);
  } else if (event == USB_AUDIO_STATE_RECV_PAUSE ||
             event == USB_AUDIO_STATE_RECV2_PAUSE) {
#ifndef USB_AUDIO_MULTIFUNC
    enqueue_unique_cmd_with_opp(AUDIO_CMD_RECV_PAUSE, usb_recv_seq, 0,
                                AUDIO_CMD_RECV_CONTINUE);
#endif
  } else if (event == USB_AUDIO_STATE_RECV_CONTINUE ||
             event == USB_AUDIO_STATE_RECV2_CONTINUE) {
#ifndef USB_AUDIO_MULTIFUNC
    enqueue_unique_cmd_with_opp(AUDIO_CMD_RECV_CONTINUE, usb_recv_seq, 0,
                                AUDIO_CMD_RECV_PAUSE);
#endif
#ifdef USB_AUDIO_DYN_CFG
  } else if (event == USB_AUDIO_STATE_SET_RECV_RATE) {
    usb_audio_set_recv_rate(param);
  } else if (event == USB_AUDIO_STATE_SET_SEND_RATE) {
    usb_audio_set_send_rate(param);
#endif
  } else {
    ASSERT(false, "Bad state event");
  }
}

static void usb_audio_acquire_freq(void) {
  enum HAL_CMU_FREQ_T freq;

#if defined(CHIP_BEST1000) && defined(_DUAL_AUX_MIC_)
#ifdef SW_CAPTURE_RESAMPLE
  if (resample_cap_enabled) {
    freq = HAL_CMU_FREQ_104M;
  } else
#endif
      if (capture_state == AUDIO_ITF_STATE_STARTED) {
#ifdef DUAL_AUX_MIC_MORE_FILTER
    freq = HAL_CMU_FREQ_104M;
#else
    freq = HAL_CMU_FREQ_78M;
#endif
  } else
#else // !(CHIP_BEST1000 && _DUAL_AUX_MIC_)
#ifdef SW_CAPTURE_RESAMPLE
  if (resample_cap_enabled) {
#ifdef CHIP_BEST1000
    freq = HAL_CMU_FREQ_78M;
#else
    freq = HAL_CMU_FREQ_52M;
#endif
  } else
#endif
#endif // !(CHIP_BEST1000 && _DUAL_AUX_MIC_)
  {
    freq = HAL_CMU_FREQ_52M;
  }

#if defined(USB_HIGH_SPEED) && defined(USB_AUDIO_UAC2)
  if (playback_state == AUDIO_ITF_STATE_STARTED &&
      sample_rate_play >= AUD_SAMPRATE_352800) {
    if (freq < HAL_CMU_FREQ_104M) {
      freq = HAL_CMU_FREQ_104M;
    }
  }
#endif

#ifdef AUDIO_ANC_FB_MC
  if (freq < HAL_CMU_FREQ_104M) {
    freq = HAL_CMU_FREQ_104M;
  }
#endif

#ifdef __HW_FIR_DSD_PROCESS__
  if (freq < HAL_CMU_FREQ_104M) {
    freq = HAL_CMU_FREQ_104M;
  }
#endif

#ifdef USB_AUDIO_SPEECH
  enum HAL_CMU_FREQ_T speech_freq;

  speech_freq = speech_process_need_freq();
  if (freq < speech_freq) {
    freq = speech_freq;
  }
#endif

  hal_sysfreq_req(HAL_SYSFREQ_USER_APP_2, freq);
  // TRACE(2,"[%s] app_sysfreq_req %d", __FUNCTION__, freq);
  // TRACE(2,"[%s] sys freq calc : %d\n", __FUNCTION__,
  // hal_sys_timer_calc_cpu_freq(5, 0));
}

static void usb_audio_release_freq(void) {
  hal_sysfreq_req(HAL_SYSFREQ_USER_APP_2, HAL_CMU_FREQ_32K);
}

static void usb_audio_update_freq(void) { usb_audio_acquire_freq(); }

#ifdef SW_CAPTURE_RESAMPLE

static enum AUD_CHANNEL_NUM_T get_capture_resample_chan_num(void) {
#if (CHAN_NUM_CAPTURE == CHAN_NUM_SEND)
  return chan_num_to_enum(CHAN_NUM_CAPTURE);
#else
  return AUD_CHANNEL_NUM_1;
#endif
}

static void capture_stream_resample_config(void) {
  struct RESAMPLE_CFG_T cfg;
  enum RESAMPLE_STATUS_T ret;
  enum AUD_SAMPRATE_T cap_rate;

#if defined(CHIP_BEST1000) && (defined(ANC_APP) || defined(_DUAL_AUX_MIC_))
  cap_rate = sample_rate_ref_cap;
#else
  cap_rate = sample_rate_cap;
#endif

#ifndef __AUDIO_RESAMPLE__
  if (cap_rate == sample_rate_send) {
    if (resample_cap_enabled) {
      TRACE(1, "!!! %s: Disable capture resample", __FUNCTION__);

      audio_resample_ex_close(resample_id);
      resample_cap_enabled = false;
    }
  } else
#endif
  {
    if (!resample_cap_enabled) {
      // Resample chan num is usb send chan num
      memset(&cfg, 0, sizeof(cfg));
      cfg.chans = get_capture_resample_chan_num();
      cfg.bits = sample_size_to_enum_capture(sample_size_cap);
#ifdef __AUDIO_RESAMPLE__
      if (sample_rate_send % AUD_SAMPRATE_8000) {
        ASSERT(hal_cmu_get_crystal_freq() /
                       (CODEC_FREQ_44_1K_SERIES / sample_rate_send) ==
                   cap_rate,
               "%s: Bad cap_rate=%u with sample_rate_send=%u", __FUNCTION__,
               cap_rate, sample_rate_send);
#if (CODEC_FREQ_26M / CODEC_FREQ_CRYSTAL * CODEC_FREQ_CRYSTAL == CODEC_FREQ_26M)
        cfg.coef = &resample_coef_50p7k_to_44p1k;
#else
        cfg.coef = &resample_coef_46p8k_to_44p1k;
#endif
      } else {
        ASSERT(hal_cmu_get_crystal_freq() /
                       (CODEC_FREQ_48K_SERIES / sample_rate_send) ==
                   cap_rate,
               "%s: Bad cap_rate=%u with sample_rate_send=%u", __FUNCTION__,
               cap_rate, sample_rate_send);
#if (CODEC_FREQ_26M / CODEC_FREQ_CRYSTAL * CODEC_FREQ_CRYSTAL == CODEC_FREQ_26M)
        cfg.coef = &resample_coef_50p7k_to_48k;
#else
        cfg.coef = &resample_coef_46p8k_to_48k;
#endif
      }
#else
      if (sample_rate_send % AUD_SAMPRATE_8000) {
        ASSERT(CODEC_FREQ_48K_SERIES /
                       (CODEC_FREQ_44_1K_SERIES / sample_rate_send) ==
                   cap_rate,
               "%s: Bad cap_rate=%u with sample_rate_send=%u", __FUNCTION__,
               cap_rate, sample_rate_send);
        cfg.coef = &resample_coef_48k_to_44p1k;
      } else {
        ASSERT(CODEC_FREQ_44_1K_SERIES /
                       (CODEC_FREQ_48K_SERIES / sample_rate_send) ==
                   cap_rate,
               "%s: Bad cap_rate=%u with sample_rate_send=%u", __FUNCTION__,
               cap_rate, sample_rate_send);
        cfg.coef = &resample_coef_44p1k_to_48k;
      }
#endif
      cfg.buf = resample_history_buf;
      cfg.size = resample_history_size;

      TRACE(3, "!!! %s: Enable capture resample %u => %u", __FUNCTION__,
            cap_rate, sample_rate_send);

      ret = audio_resample_ex_open(&cfg, &resample_id);
      ASSERT(ret == RESAMPLE_STATUS_OK, "%s: Failed to init resample: %d",
             __FUNCTION__, ret);

      resample_cap_enabled = true;
    }
  }
}

#endif

static void usb_audio_init_streams(enum AUDIO_STREAM_REQ_USER_T user) {
  bool action;

  action = false;
#ifndef DELAY_STREAM_OPEN
  if (user == AUDIO_STREAM_REQ_USB) {
    action = true;
  }
#endif
#ifdef ANC_L_R_MISALIGN_WORKAROUND
  if (user == AUDIO_STREAM_REQ_ANC) {
    action = true;
  }
#endif
  if (action) {
    usb_audio_open_codec_stream(AUD_STREAM_PLAYBACK, user);
    usb_audio_open_codec_stream(AUD_STREAM_CAPTURE, user);
  }

#ifdef ANC_L_R_MISALIGN_WORKAROUND
  if (user == AUDIO_STREAM_REQ_ANC) {
    usb_audio_start_codec_stream(AUD_STREAM_PLAYBACK, user);
    usb_audio_start_codec_stream(AUD_STREAM_CAPTURE, user);
  }
#endif
}

static void usb_audio_term_streams(enum AUDIO_STREAM_REQ_USER_T user) {
  // Ensure all the streams for this user are stopped and closed
  usb_audio_stop_codec_stream(AUD_STREAM_CAPTURE, user);
  usb_audio_stop_codec_stream(AUD_STREAM_PLAYBACK, user);

  usb_audio_close_codec_stream(AUD_STREAM_CAPTURE, user);
  usb_audio_close_codec_stream(AUD_STREAM_PLAYBACK, user);
}

#if defined(ANDROID_ACCESSORY_SPEC) || defined(CFG_MIC_KEY)
static void hid_data_send_handler(enum USB_AUDIO_HID_EVENT_T event, int error) {
  TRACE(2, "HID SENT: event=0x%04x error=%d", event, error);
}
#endif

static void usb_audio_itf_callback(enum USB_AUDIO_ITF_ID_T id,
                                   enum USB_AUDIO_ITF_CMD_T cmd) {
  if (0) {
#ifdef USB_AUDIO_MULTIFUNC
  } else if (id == USB_AUDIO_ITF_ID_RECV2) {
    usb_audio_playback2_start(cmd);
#endif
  } else if (id == USB_AUDIO_ITF_ID_RECV) {
    usb_audio_playback_start(cmd);
  } else {
    usb_audio_capture_start(cmd);
  }
}

static void usb_audio_mute_callback(enum USB_AUDIO_ITF_ID_T id, uint32_t mute) {
  if (0) {
#ifdef USB_AUDIO_MULTIFUNC
  } else if (id == USB_AUDIO_ITF_ID_RECV2) {
    usb_audio_mute2_control(mute);
#endif
  } else if (id == USB_AUDIO_ITF_ID_RECV) {
    usb_audio_mute_control(mute);
  } else {
    usb_audio_cap_mute_control(mute);
  }
}

static void usb_audio_set_volume(enum USB_AUDIO_ITF_ID_T id, uint32_t percent) {
  if (0) {
#ifdef USB_AUDIO_MULTIFUNC
  } else if (id == USB_AUDIO_ITF_ID_RECV2) {
    usb_audio_vol2_control(percent);
#endif
  } else if (id == USB_AUDIO_ITF_ID_RECV) {
    usb_audio_vol_control(percent);
  } else {
    usb_audio_cap_vol_control(percent);
  }
}

static uint32_t usb_audio_get_volume(enum USB_AUDIO_ITF_ID_T id) {
  uint32_t percent = 0;

  if (0) {
#ifdef USB_AUDIO_MULTIFUNC
  } else if (id == USB_AUDIO_ITF_ID_RECV2) {
    percent = usb_audio_get_vol2_percent();
#endif
  } else if (id == USB_AUDIO_ITF_ID_RECV) {
    percent = usb_audio_get_vol_percent();
  } else {
    percent = usb_audio_get_cap_vol_percent();
  }

  return percent;
}

static void usb_audio_xfer_callback(enum USB_AUDIO_ITF_ID_T id,
                                    const struct USB_AUDIO_XFER_INFO_T *info) {
  if (0) {
#ifdef USB_AUDIO_MULTIFUNC
  } else if (id == USB_AUDIO_ITF_ID_RECV2) {
    usb_audio_data_recv2_handler(info);
#endif
  } else if (id == USB_AUDIO_ITF_ID_RECV) {
    usb_audio_data_recv_handler(info);
  } else {
    usb_audio_data_send_handler(info);
  }
}

static void usb_audio_stream_running_handler(void) {
  enum AUDIO_STREAM_RUNNING_T req;
  uint32_t lock;

  req = streams_running_req;

  if (req == AUDIO_STREAM_RUNNING_NULL) {
    return;
  } else if (req == AUDIO_STREAM_RUNNING_ENABLED) {
    usb_audio_init_streams(AUDIO_STREAM_REQ_ANC);
  } else if (req == AUDIO_STREAM_RUNNING_DISABLED) {
    usb_audio_term_streams(AUDIO_STREAM_REQ_ANC);
  }

  lock = int_lock();
  if (req == streams_running_req) {
    streams_running_req = AUDIO_STREAM_RUNNING_NULL;
  }
  int_unlock(lock);
}

void usb_audio_keep_streams_running(bool enable) {
  if (enable) {
    streams_running_req = AUDIO_STREAM_RUNNING_ENABLED;
  } else {
    streams_running_req = AUDIO_STREAM_RUNNING_DISABLED;
  }

  // TODO: Move usb_audio_stream_running_handler() into usb_audio_app_loop() ?
  //       How to ensure that streams are opened before ANC is enabled?
  usb_audio_stream_running_handler();
}

#ifdef USB_AUDIO_DYN_CFG

static enum AUD_SAMPRATE_T calc_play_sample_rate(enum AUD_SAMPRATE_T usb_rate) {
  enum AUD_SAMPRATE_T codec_rate;

#if defined(CHIP_BEST1000) && defined(ANC_APP)

  codec_rate =
      (usb_rate % AUD_SAMPRATE_8000) ? AUD_SAMPRATE_88200 : AUD_SAMPRATE_96000;

#else

  codec_rate = usb_rate;

#if defined(__AUDIO_RESAMPLE__) && defined(SW_PLAYBACK_RESAMPLE)
  if (codec_rate % AUD_SAMPRATE_8000) {
    codec_rate =
        hal_cmu_get_crystal_freq() / (CODEC_FREQ_44_1K_SERIES / codec_rate);
  } else {
    codec_rate =
        hal_cmu_get_crystal_freq() / (CODEC_FREQ_48K_SERIES / codec_rate);
  }
#endif

#endif

  return codec_rate;
}

#if defined(CHIP_BEST1000) && (defined(ANC_APP) || defined(_DUAL_AUX_MIC_))
static enum AUD_SAMPRATE_T
calc_anc_cap_sample_rate_best1000(enum AUD_SAMPRATE_T usb_rate,
                                  enum AUD_SAMPRATE_T play_rate) {
  enum AUD_SAMPRATE_T rate_cap;

#ifdef ANC_APP

#ifdef AUD_PLL_DOUBLE
#if defined(_DUAL_AUX_MIC_) || defined(CAPTURE_ANC_DATA)
  rate_cap = play_rate * 8;
#else
  rate_cap = play_rate * 2;
#endif
#else // !AUD_PLL_DOUBLE
#if defined(_DUAL_AUX_MIC_) || defined(CAPTURE_ANC_DATA)
  rate_cap = play_rate * 4;
#else
  rate_cap = play_rate;
#endif
#endif // !AUD_PLL_DOUBLE

#else // _DUAL_AUX_MIC_

  // Capture reference
  enum AUD_SAMPRATE_T rate_cap_ref;

  rate_cap_ref =
      (usb_rate % AUD_SAMPRATE_8000) ? AUD_SAMPRATE_44100 : AUD_SAMPRATE_48000;

  rate_cap = rate_cap_ref * 4;

#endif

  return rate_cap;
}
#endif

static enum AUD_SAMPRATE_T calc_cap_sample_rate(enum AUD_SAMPRATE_T usb_rate,
                                                enum AUD_SAMPRATE_T play_rate) {
#if defined(CHIP_BEST1000) && (defined(ANC_APP) || defined(_DUAL_AUX_MIC_))

  return calc_anc_cap_sample_rate_best1000(usb_rate, play_rate);

#else // !(CHIP_BEST1000 && (ANC_APP || _DUAL_AUX_MIC_))

  enum AUD_SAMPRATE_T codec_rate;

#ifdef __AUDIO_RESAMPLE__

  codec_rate = usb_rate;

#ifdef SW_CAPTURE_RESAMPLE
  if (codec_rate % AUD_SAMPRATE_8000) {
    codec_rate =
        hal_cmu_get_crystal_freq() / (CODEC_FREQ_44_1K_SERIES / codec_rate);
  } else {
    codec_rate =
        hal_cmu_get_crystal_freq() / (CODEC_FREQ_48K_SERIES / codec_rate);
  }
#endif

#else // ! __AUDIO_RESAMPLE__

  bool usb_rate_44p1k;
  bool play_rate_44p1k;

  usb_rate_44p1k = !!(usb_rate % AUD_SAMPRATE_8000);
  play_rate_44p1k = !!(play_rate % AUD_SAMPRATE_8000);

  if (usb_rate_44p1k ^ play_rate_44p1k) {
    // Playback pll is NOT compatible with capture sample rate
    if (usb_rate_44p1k) {
      codec_rate = CODEC_FREQ_48K_SERIES / (CODEC_FREQ_44_1K_SERIES / usb_rate);
    } else {
      codec_rate = CODEC_FREQ_44_1K_SERIES / (CODEC_FREQ_48K_SERIES / usb_rate);
    }
  } else {
    // Playback pll is compatible with capture sample rate
    codec_rate = usb_rate;
  }

#endif // !__AUDIO_RESAMPLE__

  return codec_rate;

#endif // !(CHIP_BEST1000 && (ANC_APP || _DUAL_AUX_MIC_))
}

#endif // USB_AUDIO_DYN_CFG

static void POSSIBLY_UNUSED
usb_audio_update_codec_stream(enum AUD_STREAM_T stream) {
  bool update_play;
  bool update_cap;
#ifdef STREAM_RATE_BITS_SETUP
  struct AF_STREAM_CONFIG_T *cfg, stream_cfg;
  uint32_t ret;
#endif

  update_play = false;
  update_cap = false;

#ifdef USB_AUDIO_DYN_CFG
  enum AUD_SAMPRATE_T new_recv_rate;
  enum AUD_SAMPRATE_T new_send_rate;
  enum AUD_SAMPRATE_T play_rate;
  enum AUD_SAMPRATE_T cap_rate;
  uint8_t new_recv_size;
  uint32_t lock;

  lock = int_lock();
  new_recv_rate = new_sample_rate_recv;
  new_recv_size = new_sample_size_recv;
  new_send_rate = new_sample_rate_send;
  int_unlock(lock);

  play_rate = sample_rate_play;
  cap_rate = sample_rate_cap;

  if (stream == AUD_STREAM_PLAYBACK) {
    if (sample_rate_recv == new_recv_rate &&
        sample_size_recv == new_recv_size) {
      // No change
      goto _done_rate_size_check;
    }
#ifdef AUDIO_PLAYBACK_24BIT
    if (sample_rate_recv == new_recv_rate &&
        sample_size_recv != new_recv_size) {
      // No codec change. Only a change in usb sample size
      TRACE(3, "%s:1: Update recv sample size from %u to %u", __FUNCTION__,
            sample_size_recv, new_recv_size);
      sample_size_recv = new_recv_size;
      update_playback_sync_info();
      goto _done_rate_size_check;
    }
#endif
  } else {
    if (sample_rate_send == new_send_rate) {
      // No change
      goto _done_rate_size_check;
    }
  }

  if (stream == AUD_STREAM_PLAYBACK) {
    play_rate = calc_play_sample_rate(new_recv_rate);
    if (sample_rate_play == play_rate) {
      if (sample_size_recv == new_recv_size) {
        // No codec change. Only a change in usb sample rate
        TRACE(3, "%s:1: Update recv sample rate from %u to %u", __FUNCTION__,
              sample_rate_recv, new_recv_rate);
        sample_rate_recv = new_recv_rate;
        update_playback_sync_info();
        goto _done_rate_size_check;
      }
    } else {
#ifndef __AUDIO_RESAMPLE__
      bool new_rate_44p1k;
      bool old_rate_44p1k;

      new_rate_44p1k = !!(play_rate % AUD_SAMPRATE_8000);
      old_rate_44p1k = !!(sample_rate_play % AUD_SAMPRATE_8000);

      if (new_rate_44p1k ^ old_rate_44p1k) {
        cap_rate = calc_cap_sample_rate(new_send_rate, play_rate);
        update_cap = true;
      }
#endif
    }
    update_play = true;
  } else {
#ifndef __AUDIO_RESAMPLE__
    if (playback_state == AUDIO_ITF_STATE_STOPPED) {
      bool usb_rate_44p1k;
      bool play_rate_44p1k;

      usb_rate_44p1k = !!(new_send_rate % AUD_SAMPRATE_8000);
      play_rate_44p1k = !!(play_rate % AUD_SAMPRATE_8000);

      if (usb_rate_44p1k ^ play_rate_44p1k) {
        play_rate = calc_play_sample_rate(usb_rate_44p1k ? AUD_SAMPRATE_44100
                                                         : AUD_SAMPRATE_48000);
        update_play = true;
      }
    }
#endif
    cap_rate = calc_cap_sample_rate(new_send_rate, play_rate);
    if (sample_rate_cap == cap_rate) {
      // No codec change. Only a change in usb sample rate
      TRACE(3, "%s:1: Update send sample rate from %u to %u", __FUNCTION__,
            sample_rate_send, new_send_rate);
      sample_rate_send = new_send_rate;
      update_capture_sync_info();
      goto _done_rate_size_check;
    }
    update_cap = true;
  }

_done_rate_size_check:;
#endif

#ifdef DSD_SUPPORT
  bool new_dsd_state;

  new_dsd_state = usb_dsd_enabled;
  if (stream == AUD_STREAM_PLAYBACK) {
    if (codec_dsd_enabled != new_dsd_state) {
      update_play = true;
    }
  }
#endif

  if (!update_play && !update_cap) {
    return;
  }

  // 1) To avoid L/R sample misalignment, streams must be stopped before
  // changing sample rate 2) To avoid FIFO corruption, streams must be stopped
  // before changing sample size
  if (update_cap &&
      codec_stream_map[AUD_STREAM_CAPTURE][AUDIO_STREAM_STARTED]) {
    set_codec_config_status(CODEC_CONFIG_LOCK_RESTART_CAP, true);
    usb_audio_stop_codec_stream(AUD_STREAM_CAPTURE, AUDIO_STREAM_REQ_USER_ALL);
  }
  if (update_play &&
      codec_stream_map[AUD_STREAM_PLAYBACK][AUDIO_STREAM_STARTED]) {
    set_codec_config_status(CODEC_CONFIG_LOCK_RESTART_PLAY, true);
    usb_audio_stop_codec_stream(AUD_STREAM_PLAYBACK, AUDIO_STREAM_REQ_USER_ALL);
  }

  if (update_play) {
#ifdef USB_AUDIO_DYN_CFG
    if (sample_rate_recv != new_recv_rate) {
      TRACE(3, "%s:2: Update recv sample rate from %u to %u", __FUNCTION__,
            sample_rate_recv, new_recv_rate);
      sample_rate_recv = new_recv_rate;
    }
    if (sample_rate_play != play_rate) {
      TRACE(3, "%s:2: Update play sample rate from %u to %u", __FUNCTION__,
            sample_rate_play, play_rate);
      sample_rate_play = play_rate;
    }
    if (sample_size_recv != new_recv_size) {
      TRACE(3, "%s:2: Update recv sample size from %u to %u", __FUNCTION__,
            sample_size_recv, new_recv_size);
      sample_size_recv = new_recv_size;
#ifndef AUDIO_PLAYBACK_24BIT
      uint8_t old_play_size;

      old_play_size = sample_size_play;
      sample_size_play = (new_recv_size == 2) ? 2 : 4;
      TRACE(3, "%s:2: Update play sample size from %u to %u", __FUNCTION__,
            old_play_size, sample_size_play);
#endif
    }
#endif
#ifdef DSD_SUPPORT
    if (codec_dsd_enabled != new_dsd_state) {
      codec_dsd_enabled = new_dsd_state;
#ifdef CODEC_DSD
      uint8_t old_play_size;

      old_play_size = sample_size_play;
      if (codec_dsd_enabled) {
        playback_size /= ((sample_size_play + 1) / 2);
        dsd_saved_sample_size = sample_size_play;
        sample_size_play = 2;
      } else {
        playback_size *= ((dsd_saved_sample_size + 1) / 2);
        sample_size_play = dsd_saved_sample_size;
      }
      TRACE(4, "%s:2: CODEC_DSD=%u update play sample size from %u to %u",
            __FUNCTION__, codec_dsd_enabled, old_play_size, sample_size_play);
#endif
    }
#endif
  }
  if (update_cap) {
#ifdef USB_AUDIO_DYN_CFG
    if (sample_rate_send != new_send_rate) {
      TRACE(3, "%s:2: Update send sample rate from %u to %u", __FUNCTION__,
            sample_rate_send, new_send_rate);
      sample_rate_send = new_send_rate;
    }
    if (sample_rate_cap != cap_rate) {
      TRACE(3, "%s:2: Update cap sample rate from %u to %u", __FUNCTION__,
            sample_rate_cap, cap_rate);
      sample_rate_cap = cap_rate;
    }
#endif
  }

#if defined(USB_AUDIO_DYN_CFG) && defined(KEEP_SAME_LATENCY)
  playback_size = calc_playback_size(sample_rate_play);
  capture_size = calc_capture_size(sample_rate_cap);
#endif

#ifdef SW_CAPTURE_RESAMPLE
  // Check whether to start capture resample
  if (update_cap && capture_state == AUDIO_ITF_STATE_STARTED) {
    capture_stream_resample_config();
  }
#endif

#ifdef STREAM_RATE_BITS_SETUP
  if (update_play) {
    update_playback_sync_info();

    ret = af_stream_get_cfg(AUD_STREAM_ID_0, AUD_STREAM_PLAYBACK, &cfg, true);
    if (ret == 0) {
      // Changes in AF_STREAM_CONFIG_T::bits must be in another cfg variable
      stream_cfg = *cfg;
#ifdef CODEC_DSD
      if (codec_dsd_enabled) {
        stream_cfg.bits = AUD_BITS_24;
      } else
#endif
      {
        stream_cfg.bits = sample_size_to_enum_playback(sample_size_play);
      }
      stream_cfg.sample_rate = sample_rate_play;
#if (defined(USB_AUDIO_DYN_CFG) && defined(KEEP_SAME_LATENCY)) ||              \
    defined(CODEC_DSD)
      stream_cfg.data_size = playback_size;
#endif
      af_stream_setup(AUD_STREAM_ID_0, AUD_STREAM_PLAYBACK, &stream_cfg);
    }

#ifdef AUDIO_ANC_FB_MC
    ret = af_stream_get_cfg(AUD_STREAM_ID_2, AUD_STREAM_PLAYBACK, &cfg, true);
    if (ret == 0) {
      // Changes in AF_STREAM_CONFIG_T::bits must be in another cfg variable
      stream_cfg = *cfg;
      stream_cfg.bits = sample_size_to_enum_playback(sample_size_play);

      if (sample_rate_play == AUD_SAMPRATE_8000) {
        playback_samplerate_ratio = 8 * 6;
      } else if (sample_rate_play == AUD_SAMPRATE_16000) {
        playback_samplerate_ratio = 8 * 3;
      } else if ((sample_rate_play == AUD_SAMPRATE_44100) ||
                 (sample_rate_play == AUD_SAMPRATE_48000) ||
                 (sample_rate_play == AUD_SAMPRATE_50781)) {
        playback_samplerate_ratio = 8;
      } else if ((sample_rate_play == AUD_SAMPRATE_88200) ||
                 (sample_rate_play == AUD_SAMPRATE_96000)) {
        playback_samplerate_ratio = 4;
      } else if ((sample_rate_play == AUD_SAMPRATE_176400) ||
                 (sample_rate_play == AUD_SAMPRATE_192000)) {
        playback_samplerate_ratio = 2;
      } else if (sample_rate_play == AUD_SAMPRATE_384000) {
        playback_samplerate_ratio = 1;
      } else {
        playback_samplerate_ratio = 1;
        ASSERT(false, "Music cancel can't support playback sample rate:%d",
               sample_rate_play);
      }

      stream_cfg.data_ptr = playback_buf + playback_size;
      stream_cfg.data_size = playback_size * playback_samplerate_ratio;

      stream_cfg.sample_rate = sample_rate_play;
      af_stream_setup(AUD_STREAM_ID_2, AUD_STREAM_PLAYBACK, &stream_cfg);
      anc_mc_run_setup((sample_rate_play * playback_samplerate_ratio) / 8);
    }
#endif
  }
  if (update_cap) {
    update_capture_sync_info();

    ret = af_stream_get_cfg(AUD_STREAM_ID_0, AUD_STREAM_CAPTURE, &cfg, true);
    if (ret == 0) {
      stream_cfg = *cfg;
      stream_cfg.bits = sample_size_to_enum_capture(sample_size_cap);
#if defined(USB_AUDIO_DYN_CFG) && defined(KEEP_SAME_LATENCY)
      stream_cfg.data_size = capture_size;
#endif
      stream_cfg.sample_rate = sample_rate_cap;
      af_stream_setup(AUD_STREAM_ID_0, AUD_STREAM_CAPTURE, &stream_cfg);
    }
  }
#else  // !STREAM_RATE_BITS_SETUP
  // Close streams
  if (update_cap && codec_stream_map[AUD_STREAM_CAPTURE][AUDIO_STREAM_OPENED]) {
    usb_audio_close_codec_stream(AUD_STREAM_CAPTURE, AUDIO_STREAM_REQ_USER_ALL);
  }
  if (update_play &&
      codec_stream_map[AUD_STREAM_PLAYBACK][AUDIO_STREAM_OPENED]) {
    usb_audio_close_codec_stream(AUD_STREAM_PLAYBACK,
                                 AUDIO_STREAM_REQ_USER_ALL);
  }
  // Open streams
  if (update_play &&
      codec_stream_map[AUD_STREAM_PLAYBACK][AUDIO_STREAM_OPENED]) {
    usb_audio_open_codec_stream(AUD_STREAM_PLAYBACK, AUDIO_STREAM_REQ_USER_ALL);
  }
  if (update_cap && codec_stream_map[AUD_STREAM_CAPTURE][AUDIO_STREAM_OPENED]) {
    usb_audio_open_codec_stream(AUD_STREAM_CAPTURE, AUDIO_STREAM_REQ_USER_ALL);
  }
#endif // !STREAM_RATE_BITS_SETUP

  if (update_play &&
      codec_stream_map[AUD_STREAM_PLAYBACK][AUDIO_STREAM_STARTED]) {
    usb_audio_start_codec_stream(AUD_STREAM_PLAYBACK,
                                 AUDIO_STREAM_REQ_USER_ALL);
    set_codec_config_status(CODEC_CONFIG_LOCK_RESTART_PLAY, false);
  }
  if (update_cap &&
      codec_stream_map[AUD_STREAM_CAPTURE][AUDIO_STREAM_STARTED]) {
    usb_audio_start_codec_stream(AUD_STREAM_CAPTURE, AUDIO_STREAM_REQ_USER_ALL);
    set_codec_config_status(CODEC_CONFIG_LOCK_RESTART_CAP, false);
  }
}

static void start_play(uint8_t seq) {
  if (playback_state == AUDIO_ITF_STATE_STOPPED) {
#ifdef FREQ_RESP_EQ
    freq_resp_eq_init();
#endif

#ifdef DELAY_STREAM_OPEN
    usb_audio_open_codec_stream(AUD_STREAM_PLAYBACK, AUDIO_STREAM_REQ_USB);
#endif

#ifdef NOISE_GATING
    last_high_signal_time = hal_sys_timer_get();
#ifdef NOISE_REDUCTION
    last_nr_restore_time = hal_sys_timer_get();
#endif
#endif

    usb_audio_start_codec_stream(AUD_STREAM_PLAYBACK, AUDIO_STREAM_REQ_USB);

    playback_state = AUDIO_ITF_STATE_STARTED;
  }

  codec_play_seq = seq;
  playback_paused = 0;

  usb_audio_update_freq();
}

static void usb_audio_cmd_start_play(uint8_t seq) {
#if defined(USB_AUDIO_DYN_CFG) && defined(USB_AUDIO_UAC2)
  usb_audio_update_codec_stream(AUD_STREAM_PLAYBACK);
#endif

  start_play(seq);
}

static void usb_audio_cmd_stop_play(void) {
  if (playback_state == AUDIO_ITF_STATE_STARTED) {
    usb_audio_stop_codec_stream(AUD_STREAM_PLAYBACK, AUDIO_STREAM_REQ_USB);

#ifdef PA_ON_OFF_KEY
    if (pa_on_off_muted) {
      pa_on_off_muted = false;
      if (mute_user_map == 0) {
        usb_audio_codec_unmute(CODEC_MUTE_USER_ALL);
      }
    }
#endif
#ifdef NOISE_GATING
    // Restore the noise gating status
    if (mute_user_map & (1 << CODEC_MUTE_USER_NOISE_GATING)) {
      usb_audio_codec_unmute(CODEC_MUTE_USER_NOISE_GATING);
    }
#ifdef NOISE_REDUCTION
    restore_noise_reduction_status();
#endif
#endif

#ifdef DELAY_STREAM_OPEN
    usb_audio_close_codec_stream(AUD_STREAM_PLAYBACK, AUDIO_STREAM_REQ_USB);
#endif

    playback_paused = 0;
    playback_state = AUDIO_ITF_STATE_STOPPED;
#ifdef DSD_SUPPORT
    if (codec_dsd_enabled) {
      usb_audio_update_codec_stream(AUD_STREAM_PLAYBACK);
    }
#endif
  }

  usb_audio_update_freq();
}

static void start_capture(uint8_t seq) {
  if (capture_state == AUDIO_ITF_STATE_STOPPED) {
#ifdef SW_CAPTURE_RESAMPLE
    // Check whether to start capture resample
    capture_stream_resample_config();
#endif

#ifdef DELAY_STREAM_OPEN
    usb_audio_open_codec_stream(AUD_STREAM_CAPTURE, AUDIO_STREAM_REQ_USB);
#endif
    usb_audio_start_codec_stream(AUD_STREAM_CAPTURE, AUDIO_STREAM_REQ_USB);

    capture_state = AUDIO_ITF_STATE_STARTED;
  }

  codec_cap_seq = seq;

  usb_audio_update_freq();
}

static void usb_audio_cmd_start_capture(uint8_t seq) { start_capture(seq); }

static void usb_audio_cmd_stop_capture(void) {
  if (capture_state == AUDIO_ITF_STATE_STARTED) {
    usb_audio_stop_codec_stream(AUD_STREAM_CAPTURE, AUDIO_STREAM_REQ_USB);

#ifdef DELAY_STREAM_OPEN
    usb_audio_close_codec_stream(AUD_STREAM_CAPTURE, AUDIO_STREAM_REQ_USB);
#endif

#ifdef SW_CAPTURE_RESAMPLE
    if (resample_cap_enabled) {
      audio_resample_ex_close(resample_id);
      resample_cap_enabled = false;
    }
#endif

    capture_state = AUDIO_ITF_STATE_STOPPED;
  }

  usb_audio_update_freq();
}

static void usb_audio_cmd_set_volume(void) {
#ifndef USB_AUDIO_MULTIFUNC
  playback_vol = new_playback_vol;
#endif

  usb_audio_set_codec_volume(AUD_STREAM_PLAYBACK, playback_vol);

#ifdef UNMUTE_WHEN_SET_VOL
  // Unmute if muted before
  if (mute_user_map & (1 << CODEC_MUTE_USER_CMD)) {
    usb_audio_codec_unmute(CODEC_MUTE_USER_CMD);
  }
#endif
}

static void usb_audio_cmd_set_cap_volume(void) {
  capture_vol = new_capture_vol;

  usb_audio_set_codec_volume(AUD_STREAM_CAPTURE, capture_vol);
}

static void usb_audio_cmd_mute_ctrl(void) {
  uint8_t mute;

#ifdef USB_AUDIO_MULTIFUNC
  mute = new_mute_state && new_mute2_state;
#else
  mute = new_mute_state;
#endif

  if (mute) {
    usb_audio_codec_mute(CODEC_MUTE_USER_CMD);
  } else {
    usb_audio_codec_unmute(CODEC_MUTE_USER_CMD);
  }
}

static void usb_audio_cmd_cap_mute_ctrl(void) {
  uint8_t mute;

  mute = new_cap_mute_state;

  af_stream_mute(AUD_STREAM_ID_0, AUD_STREAM_CAPTURE, mute);
}

static void usb_audio_cmd_usb_state(enum AUDIO_CMD_T cmd) {
  usb_audio_cmd_stop_capture();
  usb_audio_cmd_stop_play();

  if (cmd == AUDIO_CMD_USB_RESET || cmd == AUDIO_CMD_USB_WAKEUP) {
    usb_audio_acquire_freq();
    if (cmd == AUDIO_CMD_USB_RESET) {
      usb_audio_term_streams(AUDIO_STREAM_REQ_USB);
    }
    usb_audio_reset_codec_stream_state(cmd == AUDIO_CMD_USB_RESET);
    usb_audio_init_streams(AUDIO_STREAM_REQ_USB);
  } else if (cmd == AUDIO_CMD_USB_DISCONNECT || cmd == AUDIO_CMD_USB_SLEEP) {
    usb_audio_term_streams(AUDIO_STREAM_REQ_USB);
    usb_audio_reset_codec_stream_state(cmd == AUDIO_CMD_USB_DISCONNECT);
    if (cmd == AUDIO_CMD_USB_DISCONNECT || usb_configured) {
      usb_audio_release_freq();
    }
  } else if (cmd == AUDIO_CMD_USB_CONFIG) {
    usb_configured = 1;
    usb_audio_reset_codec_stream_state(true);
  }
}

static void usb_audio_cmd_recv_pause(uint8_t seq) {
  TRACE(3, "%s: Recv pause: seq=%u usb_recv_seq=%u", __FUNCTION__, seq,
        usb_recv_seq);

  if (seq == usb_recv_seq) {
    usb_audio_cmd_stop_play();
    playback_paused = 1;
  }
}

static void usb_audio_cmd_recv_continue(uint8_t seq) {
  TRACE(3, "%s: Recv continue: seq=%u usb_recv_seq=%u", __FUNCTION__, seq,
        usb_recv_seq);

  if (seq == usb_recv_seq && playback_paused) {
    start_play(seq);
    // playback_paused = 0;
  }
}

#ifdef USB_AUDIO_DYN_CFG
static void usb_audio_cmd_set_playback_rate(uint8_t seq, uint8_t index) {
#ifndef USB_AUDIO_UAC2
  if (seq != usb_recv_seq) {
    TRACE(3, "%s: Bad seq: seq=%u usb_recv_seq=%u", __FUNCTION__, seq,
          usb_recv_seq);
    return;
  }
#endif

  usb_audio_update_codec_stream(AUD_STREAM_PLAYBACK);

#ifndef USB_AUDIO_UAC2
  start_play(seq);
#endif
}

static void usb_audio_cmd_set_capture_rate(uint8_t seq, uint8_t index) {
#ifndef USB_AUDIO_UAC2
  if (seq != usb_send_seq) {
    TRACE(3, "%s: Bad seq: seq=%u usb_send_seq=%u", __FUNCTION__, seq,
          usb_send_seq);
    return;
  }
#endif

  usb_audio_update_codec_stream(AUD_STREAM_CAPTURE);

#ifndef USB_AUDIO_UAC2
  start_capture(seq);
#endif
}
#endif

static void usb_audio_cmd_reset_codec(void) {
  TRACE(1, "%s: RESET CODEC", __FUNCTION__);

  // Regarding PLL reconfiguration, stream stop and start are enough.
  // Complete DAC/ADC reset (including analog parts) can be achieved by
  // stream close and open, which need to invoke explicitly here if
  // DELAY_STREAM_OPEN is not defined.

  if (codec_stream_map[AUD_STREAM_CAPTURE][AUDIO_STREAM_STARTED]) {
    set_codec_config_status(CODEC_CONFIG_LOCK_RESTART_CAP, true);
    usb_audio_stop_codec_stream(AUD_STREAM_CAPTURE, AUDIO_STREAM_REQ_USER_ALL);
  }

  if (codec_stream_map[AUD_STREAM_PLAYBACK][AUDIO_STREAM_STARTED]) {
    set_codec_config_status(CODEC_CONFIG_LOCK_RESTART_PLAY, true);
    usb_audio_stop_codec_stream(AUD_STREAM_PLAYBACK, AUDIO_STREAM_REQ_USER_ALL);
  }

  rate_tune_ratio[AUD_STREAM_PLAYBACK] = 0;
  rate_tune_ratio[AUD_STREAM_CAPTURE] = 0;
#ifdef __AUDIO_RESAMPLE__
#ifdef PLL_TUNE_SAMPLE_RATE
  af_codec_tune_resample_rate(AUD_STREAM_PLAYBACK,
                              rate_tune_ratio[AUD_STREAM_PLAYBACK]);
  af_codec_tune_resample_rate(AUD_STREAM_CAPTURE,
                              rate_tune_ratio[AUD_STREAM_CAPTURE]);
#elif defined(PLL_TUNE_XTAL)
  af_codec_tune_xtal(rate_tune_ratio[AUD_STREAM_PLAYBACK]);
#endif
#else
  af_codec_tune_pll(rate_tune_ratio[AUD_STREAM_PLAYBACK]);
#endif

  if (codec_stream_map[AUD_STREAM_PLAYBACK][AUDIO_STREAM_STARTED]) {
    usb_audio_start_codec_stream(AUD_STREAM_PLAYBACK,
                                 AUDIO_STREAM_REQ_USER_ALL);
    set_codec_config_status(CODEC_CONFIG_LOCK_RESTART_PLAY, false);
  }

  if (codec_stream_map[AUD_STREAM_CAPTURE][AUDIO_STREAM_STARTED]) {
    usb_audio_start_codec_stream(AUD_STREAM_CAPTURE, AUDIO_STREAM_REQ_USER_ALL);
    set_codec_config_status(CODEC_CONFIG_LOCK_RESTART_CAP, false);
  }
}

#ifdef NOISE_GATING
static void usb_audio_cmd_noise_gating(void) {
  uint32_t lock;
  enum NOISE_GATING_CMD_T cmd;

  lock = int_lock();
  cmd = noise_gating_cmd;
  noise_gating_cmd = NOISE_GATING_CMD_NULL;
  int_unlock(lock);

  TRACE(3, "%s: cmd=%d map=0x%02X", __FUNCTION__, cmd, mute_user_map);

  if (cmd == NOISE_GATING_CMD_MUTE) {
    if ((mute_user_map & (1 << CODEC_MUTE_USER_NOISE_GATING)) == 0) {
      usb_audio_codec_mute(CODEC_MUTE_USER_NOISE_GATING);
    }
  } else if (cmd == NOISE_GATING_CMD_UNMUTE) {
    if (mute_user_map & (1 << CODEC_MUTE_USER_NOISE_GATING)) {
      usb_audio_codec_unmute(CODEC_MUTE_USER_NOISE_GATING);
    }
  }
}

#ifdef NOISE_REDUCTION
static void restore_noise_reduction_status(void) {
  if (nr_active) {
    nr_active = false;
    af_codec_set_noise_reduction(false);
  }
  prev_samp_positive[0] = prev_samp_positive[1] = false;
  memset(prev_zero_diff, 0, sizeof(prev_zero_diff));
  memset(cur_zero_diff, 0, sizeof(cur_zero_diff));
  nr_cont_cnt = 0;
}

static void usb_audio_cmd_noise_reduction(void) {
  uint32_t lock;
  enum NOISE_REDUCTION_CMD_T cmd;

  lock = int_lock();
  cmd = noise_reduction_cmd;
  noise_reduction_cmd = NOISE_REDUCTION_CMD_NULL;
  int_unlock(lock);

  TRACE(2, "%s: cmd=%d", __FUNCTION__, cmd);

  if (cmd == NOISE_REDUCTION_CMD_FIRE) {
    nr_active = true;
    af_codec_set_noise_reduction(true);
  } else if (cmd == NOISE_REDUCTION_CMD_RESTORE) {
    nr_active = false;
    af_codec_set_noise_reduction(false);
  }
}
#endif
#endif

static void usb_audio_cmd_tune_rate(enum AUD_STREAM_T stream) {
#ifdef __AUDIO_RESAMPLE__
#ifdef PLL_TUNE_SAMPLE_RATE
  bool update_play, update_cap;

  update_play = true;
  update_cap = false;

#ifdef UAUD_SYNC_STREAM_TARGET
  if (stream == AUD_STREAM_PLAYBACK) {
    update_play = true;
    update_cap = false;
  } else {
    update_play = false;
    update_cap = true;
  }
#else
  update_play = true;
  update_cap = true;
#endif

#ifdef SW_RESAMPLE
  if (update_play) {
    audio_resample_ex_set_ratio_step(play_resample_id,
                                     nominal_ratio_step *
                                         rate_tune_ratio[AUD_STREAM_PLAYBACK]);
  }
  if (update_cap) {
    audio_resample_ex_set_ratio_step(cap_resample_id,
                                     nominal_ratio_step *
                                         rate_tune_ratio[AUD_STREAM_CAPTURE]);
  }
#else
  if (update_play) {
    af_codec_tune_resample_rate(AUD_STREAM_PLAYBACK,
                                rate_tune_ratio[AUD_STREAM_PLAYBACK]);
  }
  if (update_cap) {
    af_codec_tune_resample_rate(AUD_STREAM_CAPTURE,
                                rate_tune_ratio[AUD_STREAM_CAPTURE]);
  }
#endif
#elif defined(PLL_TUNE_XTAL)
  af_codec_tune_xtal(rate_tune_ratio[AUD_STREAM_PLAYBACK]);
#endif
#else  // !__AUDIO_RESAMPLE__
  af_codec_tune_pll(rate_tune_ratio[AUD_STREAM_PLAYBACK]);
#endif // !__AUDIO_RESAMPLE__
}

#ifdef DSD_SUPPORT
static void usb_audio_cmd_set_dsd_cfg(void) {
  if (codec_dsd_enabled != usb_dsd_enabled) {
    TRACE(3, "%s: %d => %d", __FUNCTION__, codec_dsd_enabled, usb_dsd_enabled);
    usb_audio_update_codec_stream(AUD_STREAM_PLAYBACK);
  }
}
#endif

#ifdef PERF_TEST_POWER_KEY
static void test_cmd_perf_test_power(void) {
  perft_power_type++;
  if (perft_power_type >= HAL_CODEC_PERF_TEST_QTY) {
    perft_power_type = 0;
  }

  TRACE(2, "%s: %d", __FUNCTION__, perft_power_type);

  af_codec_set_perf_test_power(perft_power_type);
}
#endif

#ifdef PA_ON_OFF_KEY
static void test_cmd_pa_on_off(void) {
  pa_on_off_muted = !pa_on_off_muted;

  TRACE(2, "%s: %d", __FUNCTION__, pa_on_off_muted);

  if (pa_on_off_muted) {
    usb_audio_codec_mute(CODEC_MUTE_USER_ALL);
  } else {
    usb_audio_codec_unmute(CODEC_MUTE_USER_ALL);
#ifdef PERF_TEST_POWER_KEY
    af_codec_set_perf_test_power(perft_power_type);
#endif
  }
}
#endif

static void usb_audio_cmd_handler(void *param) {
  uint32_t data;
  enum AUDIO_CMD_T cmd;
  uint8_t seq;
  uint8_t POSSIBLY_UNUSED arg;

  hal_cpu_wake_unlock(USB_AUDIO_CPU_WAKE_USER);

  while (safe_queue_get(&cmd_queue, &data) == 0) {
    cmd = EXTRACT_CMD(data);
    seq = EXTRACT_SEQ(data);
    arg = EXTRACT_ARG(data);
    TRACE(4, "%s: cmd=%d seq=%d arg=%d", __FUNCTION__, cmd, seq, arg);

    switch (cmd) {
    case AUDIO_CMD_START_PLAY:
      usb_audio_cmd_start_play(seq);
      break;

    case AUDIO_CMD_STOP_PLAY:
      usb_audio_cmd_stop_play();
      break;

    case AUDIO_CMD_START_CAPTURE:
      usb_audio_cmd_start_capture(seq);
      break;

    case AUDIO_CMD_STOP_CAPTURE:
      usb_audio_cmd_stop_capture();
      break;

    case AUDIO_CMD_SET_VOLUME:
      usb_audio_cmd_set_volume();
      break;

    case AUDIO_CMD_SET_CAP_VOLUME:
      usb_audio_cmd_set_cap_volume();
      break;

    case AUDIO_CMD_MUTE_CTRL:
      usb_audio_cmd_mute_ctrl();
      break;

    case AUDIO_CMD_CAP_MUTE_CTRL:
      usb_audio_cmd_cap_mute_ctrl();
      break;

    case AUDIO_CMD_USB_RESET:
    case AUDIO_CMD_USB_DISCONNECT:
    case AUDIO_CMD_USB_CONFIG:
    case AUDIO_CMD_USB_SLEEP:
    case AUDIO_CMD_USB_WAKEUP:
      usb_audio_cmd_usb_state(cmd);
      break;

    case AUDIO_CMD_RECV_PAUSE:
      usb_audio_cmd_recv_pause(seq);
      break;
    case AUDIO_CMD_RECV_CONTINUE:
      usb_audio_cmd_recv_continue(seq);
      break;

#ifdef USB_AUDIO_DYN_CFG
    case AUDIO_CMD_SET_RECV_RATE:
      usb_audio_cmd_set_playback_rate(seq, arg);
      break;
    case AUDIO_CMD_SET_SEND_RATE:
      usb_audio_cmd_set_capture_rate(seq, arg);
      break;
#endif

    case AUDIO_CMD_RESET_CODEC:
      usb_audio_cmd_reset_codec();
      break;

#ifdef NOISE_GATING
    case AUDIO_CMD_NOISE_GATING:
      usb_audio_cmd_noise_gating();
      break;

#ifdef NOISE_REDUCTION
    case AUDIO_CMD_NOISE_REDUCTION:
      usb_audio_cmd_noise_reduction();
      break;
#endif
#endif

    case AUDIO_CMD_TUNE_RATE:
      usb_audio_cmd_tune_rate((enum AUD_STREAM_T)arg);
      break;

#ifdef DSD_SUPPORT
    case AUDIO_CMD_SET_DSD_CFG:
      usb_audio_cmd_set_dsd_cfg();
      break;
#endif

#ifdef PERF_TEST_POWER_KEY
    case TEST_CMD_PERF_TEST_POWER:
      test_cmd_perf_test_power();
      break;
#endif

#ifdef PA_ON_OFF_KEY
    case TEST_CMD_PA_ON_OFF:
      test_cmd_pa_on_off();
      break;
#endif

    default:
      ASSERT(false, "%s: Invalid cmd %d", __FUNCTION__, cmd);
      break;
    }
  }
}

void usb_audio_app_init(const struct USB_AUDIO_BUF_CFG *cfg) {
#ifdef USB_AUDIO_DYN_CFG
  ASSERT(cfg->play_size / MAX_FRAME_SIZE_PLAYBACK <
             cfg->recv_size / MAX_FRAME_SIZE_RECV,
         "%s: play frames %u should < recv frames %u", __FUNCTION__,
         cfg->play_size / MAX_FRAME_SIZE_PLAYBACK,
         cfg->recv_size / MAX_FRAME_SIZE_RECV);
  ASSERT(cfg->cap_size / MAX_FRAME_SIZE_CAPTURE <
             cfg->send_size / MAX_FRAME_SIZE_SEND,
         "%s: cap frames %u should < send frames %u", __FUNCTION__,
         cfg->cap_size / MAX_FRAME_SIZE_CAPTURE,
         cfg->send_size / MAX_FRAME_SIZE_SEND);
#else
  ASSERT(
      cfg->play_size / FRAME_SIZE_PLAYBACK < cfg->recv_size / FRAME_SIZE_RECV,
      "%s: play frames %u should < recv frames %u", __FUNCTION__,
      cfg->play_size / FRAME_SIZE_PLAYBACK, cfg->recv_size / FRAME_SIZE_RECV);
  ASSERT(cfg->cap_size / FRAME_SIZE_CAPTURE < cfg->send_size / FRAME_SIZE_SEND,
         "%s: cap frames %u should < send frames %u", __FUNCTION__,
         cfg->cap_size / FRAME_SIZE_CAPTURE, cfg->send_size / FRAME_SIZE_SEND);
#endif

#ifdef SW_CAPTURE_RESAMPLE
  enum AUD_CHANNEL_NUM_T chans;
  enum AUD_BITS_T bits;
  uint8_t phase_coef_num;
  uint32_t resamp_calc_size;

  chans = get_capture_resample_chan_num();
  bits = sample_size_to_enum_capture(sample_size_cap);
  // Max phase coef num
  phase_coef_num = 100;

  resamp_calc_size =
      audio_resample_ex_get_buffer_size(chans, bits, phase_coef_num);
  ASSERT(cfg->resample_size > resamp_calc_size,
         "%s: Resample size too small %u (should > %u)", __FUNCTION__,
         cfg->resample_size, resamp_calc_size);

  resample_history_buf = (uint8_t *)ALIGN((uint32_t)cfg->resample_buf, 4);
  resample_history_size = resamp_calc_size;
  resample_input_buf = (uint8_t *)resample_history_buf + resample_history_size;
  ASSERT(cfg->resample_buf + cfg->resample_size > resample_input_buf,
         "%s: Resample size too small: %u", __FUNCTION__, cfg->resample_size);
  resample_input_size =
      cfg->resample_buf + cfg->resample_size - resample_input_buf;
#endif

  playback_buf = cfg->play_buf;
  capture_buf = cfg->cap_buf;
  usb_recv_buf = cfg->recv_buf;
  usb_send_buf = cfg->send_buf;
  playback_eq_buf = cfg->eq_buf;
  playback_eq_size = cfg->eq_size;

#if defined(USB_AUDIO_DYN_CFG) && defined(KEEP_SAME_LATENCY)
  playback_max_size = cfg->play_size;
  capture_max_size = cfg->cap_size;
  usb_recv_max_size = cfg->recv_size;
  usb_send_max_size = cfg->send_size;
#else
  playback_size = cfg->play_size;
  capture_size = cfg->cap_size;
  usb_recv_size = cfg->recv_size;
  usb_send_size = cfg->send_size;
#endif

  playback_pos = 0;
  usb_recv_rpos = 0;
  usb_recv_wpos = cfg->recv_size / 2;
  capture_pos = 0;
  usb_send_rpos = cfg->send_size / 2;
  usb_send_wpos = 0;

#ifdef USB_AUDIO_MULTIFUNC
  usb_recv2_buf = cfg->recv2_buf;
  usb_recv2_size = cfg->recv2_size;
  usb_recv2_rpos = 0;
  usb_recv2_wpos = cfg->recv2_size / 2;
#endif

  playback_info.id = 0;
  playback_info.sync_thresh = DIFF_SYNC_THRESH_PLAYBACK;
  playback_info.diff_avg_cnt = DIFF_AVG_CNT;
#ifdef TARGET_TO_MAX_DIFF
  playback_info.diff_target_enabled = true;
  playback_info.max_target_ratio = MAX_TARGET_RATIO;
  playback_info.time_to_ms = NULL;
#endif
  capture_info.id = 1;
  capture_info.sync_thresh = DIFF_SYNC_THRESH_CAPTURE;
  capture_info.diff_avg_cnt = DIFF_AVG_CNT;
#ifdef TARGET_TO_MAX_DIFF
  capture_info.diff_target_enabled = true;
  capture_info.max_target_ratio = MAX_TARGET_RATIO;
  capture_info.time_to_ms = NULL;
#endif

  safe_queue_init(&cmd_queue, cmd_list, CMD_LIST_SIZE);

#ifdef USB_AUDIO_PWRKEY_TEST
  hal_cmu_simu_set_val(0);
#endif
}

void usb_audio_app_term(void) {
  playback_buf = NULL;
  playback_size = 0;
  capture_buf = NULL;
  capture_size = 0;
  usb_recv_buf = NULL;
  usb_recv_size = 0;
  usb_send_buf = NULL;
  usb_send_size = 0;

  playback_pos = 0;
  usb_recv_rpos = 0;
  usb_recv_wpos = 0;

  capture_pos = 0;
  usb_send_rpos = 0;
  usb_send_wpos = 0;

#ifdef USB_AUDIO_MULTIFUNC
  usb_recv2_buf = NULL;
  usb_recv2_size = 0;
  usb_recv2_rpos = 0;
  usb_recv2_wpos = 0;
#endif
}

void usb_audio_app(bool on) {
  static const struct USB_AUDIO_CFG_T usb_audio_cfg = {
    .recv_sample_rate = SAMPLE_RATE_RECV,
    .send_sample_rate = SAMPLE_RATE_SEND,
    .itf_callback = usb_audio_itf_callback,
    .mute_callback = usb_audio_mute_callback,
    .set_volume = usb_audio_set_volume,
    .get_volume = usb_audio_get_volume,
    .state_callback = usb_audio_state_control,
    .xfer_callback = usb_audio_xfer_callback,
#if defined(ANDROID_ACCESSORY_SPEC) || defined(CFG_MIC_KEY)
    // Applications are responsible for clearing HID events
    .hid_send_callback = hid_data_send_handler,
#else
    // HID events will be cleared automatically once they are sent
    .hid_send_callback = NULL,
#endif
#ifdef _VENDOR_MSG_SUPPT_
    .vendor_msg_callback = usb_vendor_callback,
    .vendor_rx_buf = vendor_msg_rx_buf,
    .vendor_rx_size = VENDOR_RX_BUF_SZ,
#endif
  };
  static bool isRun = false;
  int ret;

  if (isRun == on)
    return;
  else
    isRun = on;

  TRACE(2, "%s: on=%d", __FUNCTION__, on);

  if (on) {
    usb_audio_acquire_freq();

    usb_audio_reset_usb_stream_state(true);
    usb_audio_reset_codec_stream_state(true);

#ifdef USB_AUDIO_DYN_CFG
    sample_rate_recv = new_sample_rate_recv = usb_audio_cfg.recv_sample_rate;
    sample_rate_send = new_sample_rate_send = usb_audio_cfg.send_sample_rate;
    // Init codec sample rates after initializing usb sample rates
    sample_rate_play = calc_play_sample_rate(sample_rate_recv);
    sample_rate_cap = calc_cap_sample_rate(sample_rate_send, sample_rate_play);
    // TODO: Check whether 16-bit sample is enabled
    sample_size_recv = new_sample_size_recv = 2;
#ifndef AUDIO_PLAYBACK_24BIT
    sample_size_play = 2;
#endif

#ifdef KEEP_SAME_LATENCY
    usb_recv_size = calc_usb_recv_size(sample_rate_recv, sample_size_recv);
    usb_send_size = calc_usb_send_size(sample_rate_send);
    playback_size = calc_playback_size(sample_rate_play);
    capture_size = calc_capture_size(sample_rate_cap);
#endif
#endif

    TRACE(3, "CODEC playback sample: rate=%u size=%u chan=%u", sample_rate_play,
          sample_size_play, CHAN_NUM_PLAYBACK);
    TRACE(3, "CODEC capture sample: rate=%u size=%u chan=%u", sample_rate_cap,
          sample_size_cap, CHAN_NUM_CAPTURE);
    TRACE(2, "USB recv sample: rate=%u size=%u", sample_rate_recv,
          sample_size_recv);
    TRACE(2, "USB send sample: rate=%u size=%u", sample_rate_send,
          sample_size_send);

    usb_audio_init_streams(AUDIO_STREAM_REQ_USB);

    pmu_usb_config(PMU_USB_CONFIG_TYPE_DEVICE);
    ret = usb_audio_open(&usb_audio_cfg);
    ASSERT(ret == 0, "usb_audio_open failed: %d", ret);
  } else {
    usb_audio_close();
    pmu_usb_config(PMU_USB_CONFIG_TYPE_NONE);

    usb_audio_term_streams(AUDIO_STREAM_REQ_USB);

    usb_audio_reset_usb_stream_state(true);
    usb_audio_reset_codec_stream_state(true);

    usb_audio_release_freq();
  }
}

static void app_key_trace(uint32_t line, enum HAL_KEY_CODE_T code,
                          enum HAL_KEY_EVENT_T event,
                          enum USB_AUDIO_HID_EVENT_T uevt, int state) {
#ifdef KEY_TRACE
  TRACE(5, "APPKEY/%u: code=%d event=%d uevt=%s state=%d", line, code, event,
        usb_audio_get_hid_event_name(uevt), state);
#endif
}

int usb_audio_app_key(enum HAL_KEY_CODE_T code, enum HAL_KEY_EVENT_T event) {
  int i;
  enum USB_AUDIO_HID_EVENT_T uevt;
  int state;

  if (event == HAL_KEY_EVENT_CLICK &&
      playback_state == AUDIO_ITF_STATE_STARTED) {
#ifdef PERF_TEST_POWER_KEY
    if (code == PERF_TEST_POWER_KEY) {
      enqueue_unique_cmd(TEST_CMD_PERF_TEST_POWER);
    }
#endif
#ifdef PA_ON_OFF_KEY
    if (code == PA_ON_OFF_KEY) {
      enqueue_unique_cmd(TEST_CMD_PA_ON_OFF);
    }
#endif
  }

#ifdef USB_AUDIO_PWRKEY_TEST
  if (code == HAL_KEY_CODE_PWR) {
    uevt = hal_cmu_simu_get_val();
    if (uevt == 0) {
      uevt = USB_AUDIO_HID_VOL_UP;
    }
#if defined(ANDROID_ACCESSORY_SPEC) || defined(CFG_MIC_KEY)
    if (event == HAL_KEY_EVENT_DOWN || event == HAL_KEY_EVENT_UP) {
      state = (event != HAL_KEY_EVENT_UP);
      app_key_trace(__LINE__, code, event, uevt, state);
      usb_audio_hid_set_event(uevt, state);
    }
    // The key event has been processed
    return 0;
#else
    if (event == HAL_KEY_EVENT_CLICK) {
      state = 1;
      app_key_trace(__LINE__, code, event, uevt, state);
      usb_audio_hid_set_event(uevt, state);
      return 0;
    }
    // Let other applications check the key event
    return 1;
#endif
  }
#endif

  if (code != HAL_KEY_CODE_NONE) {
    for (i = 0; i < ARRAY_SIZE(key_map); i++) {
      if (key_map[i].key_code == code &&
          (key_map[i].key_event_bitset & (1 << event))) {
        break;
      }
    }
    if (i < ARRAY_SIZE(key_map)) {
      uevt = key_map[i].hid_event;
      if (uevt != 0) {
#if defined(ANDROID_ACCESSORY_SPEC) || defined(CFG_MIC_KEY)
        state = (event != HAL_KEY_EVENT_UP);
#else
        state = 1;
#endif
        app_key_trace(__LINE__, code, event, uevt, state);
        usb_audio_hid_set_event(uevt, state);
        // The key event has been processed
        return 0;
      }
    }
  }

  // Let other applications check the key event
  return 1;
}

#ifdef ANC_APP
extern bool anc_usb_app_get_status();
static uint8_t anc_status = 0;
static uint8_t anc_status_record = 0xff;
#endif

void usb_audio_eq_loop(void) {
#ifdef ANC_APP
  anc_status = anc_usb_app_get_status();
  if (anc_status_record != anc_status && eq_opened == 1) {
    anc_status_record = anc_status;
    TRACE(2, "[%s]anc_status = %d", __func__, anc_status);
#ifdef __SW_IIR_EQ_PROCESS__
    usb_audio_set_eq(AUDIO_EQ_TYPE_SW_IIR,
                     usb_audio_get_eq_index(AUDIO_EQ_TYPE_SW_IIR, anc_status));
#endif

#ifdef __HW_FIR_EQ_PROCESS__
    usb_audio_set_eq(AUDIO_EQ_TYPE_HW_FIR,
                     usb_audio_get_eq_index(AUDIO_EQ_TYPE_HW_FIR, anc_status));
#endif

#ifdef __HW_DAC_IIR_EQ_PROCESS__
    usb_audio_set_eq(
        AUDIO_EQ_TYPE_HW_DAC_IIR,
        usb_audio_get_eq_index(AUDIO_EQ_TYPE_HW_DAC_IIR, anc_status));
#endif

#ifdef __HW_IIR_EQ_PROCESS__
    usb_audio_set_eq(AUDIO_EQ_TYPE_HW_IIR,
                     usb_audio_get_eq_index(AUDIO_EQ_TYPE_HW_IIR, anc_status));
#endif
  }
#endif
}

void usb_audio_app_loop(void) {
  usb_audio_cmd_handler(NULL);

  usb_audio_eq_loop();

#ifndef RTOS
  extern void af_thread(void const *argument);
  af_thread(NULL);
#endif
}

uint32_t usb_audio_get_capture_sample_rate(void) { return sample_rate_cap; }