pinebuds/tests/anc_usb/anc_usb_app.c

1058 lines
28 KiB
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 All unpublished rights reserved.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 "anc_process.h"
#include "anc_usb_app.h"
#include "audioflinger.h"
#include "cmsis.h"
#include "hal_codec.h"
#include "hal_key.h"
#include "hal_sleep.h"
#include "hal_timer.h"
#include "hal_trace.h"
#include "hwtimer_list.h"
#include "pmu.h"
#include "usb_audio_app.h"
#include "tgt_hardware.h"
#ifdef ANC_SWITCH_GPADC_CHAN
#include "hal_gpadc.h"
#endif
#define ANC_KEY_CPU_WAKE_USER HAL_CPU_WAKE_LOCK_USER_4
#define ANC_STATE_CPU_WAKE_USER HAL_CPU_WAKE_LOCK_USER_5
#define ANC_FADE_IN_OUT
#define ANC_FADE_GAIN_STEP 1
#define ANC_MODE_SWITCH_WITHOUT_FADE
#ifndef ANC_INIT_ON_TIMEOUT_MS
#ifdef CHIP_BEST1000
#define ANC_INIT_ON_TIMEOUT_MS 1200
#else
#define ANC_INIT_ON_TIMEOUT_MS 200
#endif
#endif
#ifndef ANC_SHUTDOWN_TIMEOUT_MS
#define ANC_SHUTDOWN_TIMEOUT_MS 5000
#endif
#ifndef ANC_SWITCH_CHECK_INTERVAL
#define ANC_SWITCH_CHECK_INTERVAL MS_TO_TICKS(500)
#endif
#ifdef ANC_COEF_NUM
#if (ANC_COEF_NUM < 1)
#error "Invalid ANC_COEF_NUM configuration"
#endif
#else
#define ANC_COEF_NUM (1)
#endif
#define KEY_PROCESS_TIMER_INTERVAL (MS_TO_TICKS(1) / 2)
#define FADE_TIMER_INTERVAL (MS_TO_TICKS(1) / 2)
enum ANC_STATUS_T {
ANC_STATUS_NULL = 0,
ANC_STATUS_INIT,
ANC_STATUS_FADEIN,
ANC_STATUS_ENABLE,
ANC_STATUS_FADEOUT,
ANC_STATUS_DISABLE,
ANC_STATUS_INIT_CLOSE,
};
enum ANC_KEY_STATE_T {
ANC_KEY_STATE_NULL = 0,
ANC_KEY_STATE_CLOSE,
ANC_KEY_STATE_OPEN,
ANC_KEY_STATE_DEBOUNCE,
};
enum ANC_CTRL_SM_T {
ANC_CTRL_SM_OFF = 0,
ANC_CTRL_SM_COEF_0,
ANC_CTRL_SM_COEF_N = ANC_CTRL_SM_COEF_0 + ANC_COEF_NUM - 1,
ANC_CTRL_SM_QTY
};
static enum ANC_STATUS_T anc_status = ANC_STATUS_NULL;
static enum ANC_KEY_STATE_T prev_key_state = ANC_KEY_STATE_NULL;
static enum HAL_KEY_EVENT_T anc_key_event = HAL_KEY_EVENT_NONE;
static enum ANC_CTRL_SM_T anc_ctrl_sm = ANC_CTRL_SM_OFF;
#ifdef ANC_TALK_THROUGH
static bool talk_through = false;
#endif
static uint32_t anc_init_time;
static uint32_t anc_close_time;
static enum ANC_INDEX cur_coef_index = ANC_INDEX_0;
static enum AUD_SAMPRATE_T anc_sample_rate[AUD_STREAM_NUM];
static bool anc_running = false;
#ifdef ANC_SWITCH_GPIO_PIN
static const struct HAL_IOMUX_PIN_FUNCTION_MAP pinmux_anc = {ANC_SWITCH_GPIO_PIN, HAL_IOMUX_FUNC_AS_GPIO, HAL_IOMUX_PIN_VOLTAGE_VIO, HAL_IOMUX_PIN_PULLUP_ENABLE};
static bool gpio_pending;
static bool gpio_irq_en;
static enum HAL_GPIO_IRQ_POLARITY_T gpio_irq_polarity;
#endif
// ANC_SWITCH_GPADC_CHAN
static HWTIMER_ID gpadc_timer;
// ANC_FADE_IN_OUT
static uint8_t fadein_cnt = 0;
static uint8_t fadeout_cnt = 0;
static uint32_t prev_fade_time = 0;
#ifdef CFG_HW_ANC_LED_PIN
const struct HAL_IOMUX_PIN_FUNCTION_MAP pinmux_anc_led[] = {
{CFG_HW_ANC_LED_PIN, HAL_IOMUX_FUNC_AS_GPIO, HAL_IOMUX_PIN_VOLTAGE_VIO, HAL_IOMUX_PIN_NOPULL},
};
#endif
#ifdef CFG_HW_ANC_LED_PIN2
const struct HAL_IOMUX_PIN_FUNCTION_MAP pinmux_anc_led2[] = {
{CFG_HW_ANC_LED_PIN2, HAL_IOMUX_FUNC_AS_GPIO, HAL_IOMUX_PIN_VOLTAGE_VIO, HAL_IOMUX_PIN_NOPULL},
};
#endif
static void anc_full_open(void);
static void anc_full_close(void);
// ANC_FADE_IN_OUT
int anc_usb_app_fadein(enum ANC_TYPE_T anc_type)
{
int32_t gain0_curr, gain1_curr;
int32_t gain0_tg, gain1_tg;
anc_get_gain(&gain0_curr, &gain1_curr,anc_type);
anc_get_cfg_gain(&gain0_tg, &gain1_tg,anc_type);
/*
anc_set_gain(gain0_tg, gain1_tg,anc_type);
return 0;
*/
if (gain0_tg > 0) {
if (gain0_curr < gain0_tg) {
if (gain0_curr + ANC_FADE_GAIN_STEP < gain0_tg) {
gain0_curr += ANC_FADE_GAIN_STEP;
} else {
gain0_curr = gain0_tg;
}
}
} else {
if (gain0_curr > gain0_tg) {
if (gain0_curr - ANC_FADE_GAIN_STEP > gain0_tg) {
gain0_curr -= ANC_FADE_GAIN_STEP;
} else {
gain0_curr = gain0_tg;
}
}
}
if (gain1_tg > 0) {
if (gain1_curr < gain1_tg) {
if (gain1_curr + ANC_FADE_GAIN_STEP < gain1_tg) {
gain1_curr += ANC_FADE_GAIN_STEP;
} else {
gain1_curr = gain1_tg;
}
}
} else {
if (gain1_curr > gain1_tg) {
if (gain1_curr - ANC_FADE_GAIN_STEP > gain1_tg) {
gain1_curr -= ANC_FADE_GAIN_STEP;
} else {
gain1_curr = gain1_tg;
}
}
}
//TRACE(3,"[%s] cur gain: %d %d", __func__, gain0_curr, gain1_curr);
anc_set_gain(gain0_curr, gain1_curr,anc_type);
if ((gain0_curr == gain0_tg) && (gain1_curr == gain1_tg)) {
return 0;
}
return 1;
}
int anc_usb_app_fadeout(enum ANC_TYPE_T anc_type)
{
/*
anc_set_gain(0, 0,anc_type);
return 0;
*/
int32_t gain0_curr, gain1_curr;
anc_get_gain(&gain0_curr, &gain1_curr,anc_type);
if (gain0_curr > 0) {
if (gain0_curr > ANC_FADE_GAIN_STEP) {
gain0_curr -= ANC_FADE_GAIN_STEP;
} else {
gain0_curr = 0;
}
} else if (gain0_curr < 0) {
if (gain0_curr < -ANC_FADE_GAIN_STEP) {
gain0_curr += ANC_FADE_GAIN_STEP;
} else {
gain0_curr = 0;
}
}
if (gain1_curr > 0) {
if (gain1_curr > ANC_FADE_GAIN_STEP) {
gain1_curr -= ANC_FADE_GAIN_STEP;
} else {
gain1_curr = 0;
}
} else if (gain1_curr < 0) {
if (gain1_curr < -ANC_FADE_GAIN_STEP) {
gain1_curr += ANC_FADE_GAIN_STEP;
} else {
gain1_curr = 0;
}
}
// TRACE(3,"[%s] gain: %d, %d", __func__, gain0_curr, gain1_curr);
anc_set_gain(gain0_curr, gain1_curr,anc_type);
if ((gain0_curr == 0) && (gain1_curr == 0)) {
return 0;
}
return 1;
}
void anc_usb_app(bool on)
{
TRACE(2,"%s: on=%d", __func__, on);
if (anc_running==on)
return;
else
anc_running=on;
if (on) {
anc_enable();
} else {
anc_disable();
}
#ifdef CFG_HW_ANC_LED_PIN
if (on) {
hal_gpio_pin_set(CFG_HW_ANC_LED_PIN);
} else {
hal_gpio_pin_clr(CFG_HW_ANC_LED_PIN);
}
#endif
#ifdef CFG_HW_ANC_LED_PIN2
if (on) {
hal_gpio_pin_set(CFG_HW_ANC_LED_PIN2);
} else {
hal_gpio_pin_clr(CFG_HW_ANC_LED_PIN2);
}
#endif
}
bool anc_usb_app_get_status()
{
return anc_running;
}
#ifdef ANC_SWITCH_GPIO_PIN
static void anc_key_gpio_handler(enum HAL_GPIO_PIN_T pin)
{
struct HAL_GPIO_IRQ_CFG_T gpiocfg;
gpiocfg.irq_enable = false;
hal_gpio_setup_irq((enum HAL_GPIO_PIN_T)pinmux_anc.pin, &gpiocfg);
gpio_irq_en = false;
gpio_pending = true;
hal_cpu_wake_lock(ANC_KEY_CPU_WAKE_USER);
}
static void anc_key_gpio_irq_setup(enum HAL_GPIO_IRQ_POLARITY_T polarity)
{
struct HAL_GPIO_IRQ_CFG_T gpiocfg;
if (gpio_irq_en && gpio_irq_polarity == polarity) {
return;
}
gpio_irq_polarity = polarity;
gpio_irq_en = true;
gpiocfg.irq_enable = true;
gpiocfg.irq_debounce = true;
gpiocfg.irq_polarity = polarity;
gpiocfg.irq_handler = anc_key_gpio_handler;
gpiocfg.irq_type = HAL_GPIO_IRQ_TYPE_LEVEL_SENSITIVE;
hal_gpio_setup_irq((enum HAL_GPIO_PIN_T)pinmux_anc.pin, &gpiocfg);
}
#endif
static enum ANC_KEY_STATE_T anc_key_level_to_state(bool level)
{
enum ANC_KEY_STATE_T key_state;
#ifdef ANC_SWITCH_GPIO_PIN
anc_key_gpio_irq_setup(level ? HAL_GPIO_IRQ_POLARITY_LOW_FALLING : HAL_GPIO_IRQ_POLARITY_HIGH_RISING);
#endif
key_state = level ? ANC_KEY_STATE_OPEN : ANC_KEY_STATE_CLOSE;
return key_state;
}
enum ANC_KEY_STATE_T anc_key_get_state(bool init_state)
{
enum ANC_KEY_STATE_T key_state = ANC_KEY_STATE_NULL;
uint8_t level;
#if defined(ANC_SWITCH_GPIO_PIN)
level = hal_gpio_pin_get_val((enum HAL_GPIO_PIN_T)pinmux_anc.pin);
level = level ? true : false;
#elif defined(ANC_SWITCH_GPADC_CHAN)
HAL_GPADC_MV_T volt = 0;
if (hal_gpadc_get_volt(ANC_SWITCH_GPADC_CHAN, &volt)) {
level = volt > ANC_SWITCH_VOLTAGE_THRESHOLD ? ANC_SWITCH_LEVEL_HIGH : ANC_SWITCH_LEVEL_LOW;
// TRACE(3,"[%s] level = %d, volt = %d", __func__, level, volt);
} else {
// TRACE(1,"[%s] else...", __func__);
return ANC_KEY_STATE_NULL;
}
#else
return key_state;
#endif
static uint32_t s_time;
static bool key_trigger = false;
static bool key_level = false;
if (init_state) {
key_level = level;
return anc_key_level_to_state(level);
}
if (key_trigger) {
if (key_level == level) {
key_trigger = false;
} else {
uint32_t diff_time_ms;
diff_time_ms = TICKS_TO_MS(hal_sys_timer_get() - s_time);
if(diff_time_ms >= 200) {
key_level = level;
key_trigger = false;
}
}
} else {
if (key_level != level) {
s_time = hal_sys_timer_get();
key_trigger = true;
}
}
if (key_trigger) {
key_state = ANC_KEY_STATE_DEBOUNCE;
} else {
key_state = anc_key_level_to_state(level);
}
return key_state;
}
static void anc_key_proc_open(bool from_key)
{
int POSSIBLY_UNUSED ret;
uint32_t POSSIBLY_UNUSED time;
time = hal_sys_timer_get();
if (anc_status == ANC_STATUS_INIT_CLOSE) {
TRACE(1,"[ANC KEY PROC] ANC INIT_CLOSE => INIT T:%u", time);
anc_status = ANC_STATUS_INIT;
} else if (anc_status == ANC_STATUS_NULL) {
TRACE(1,"[ANC KEY PROC] ANC NULL => INIT T:%u", time);
anc_full_open();
#ifdef ANC_MODE_SWITCH_WITHOUT_FADE
} else if (anc_status == ANC_STATUS_ENABLE) {
#ifdef ANC_FF_ENABLED
ret = anc_select_coef(anc_sample_rate[AUD_STREAM_PLAYBACK],cur_coef_index,ANC_FEEDFORWARD,ANC_GAIN_NO_DELAY);
TRACE(2,"[ANC KEY PROC] updata coefs ff %d: ret=%d", cur_coef_index, ret);
#endif
#ifdef ANC_FB_ENABLED
ret = anc_select_coef(anc_sample_rate[AUD_STREAM_PLAYBACK],cur_coef_index,ANC_FEEDBACK,ANC_GAIN_NO_DELAY);
TRACE(2,"[ANC KEY PROC] updata coefs fb %d: ret=%d", cur_coef_index, ret);
#endif
#if defined(AUDIO_ANC_FB_MC_HW)
ret = anc_select_coef(anc_sample_rate[AUD_STREAM_PLAYBACK],cur_coef_index, ANC_MUSICCANCLE, ANC_GAIN_NO_DELAY);
TRACE(2,"[ANC KEY PROC] anc_select_coef mc %d: ret=%d", cur_coef_index, ret);
#endif
#if defined(AUDIO_ANC_TT_HW)
ret = anc_select_coef(anc_sample_rate[AUD_STREAM_PLAYBACK],cur_coef_index, ANC_TALKTHRU, ANC_GAIN_NO_DELAY);
TRACE(2,"[ANC KEY PROC] anc_select_coef tt %d: ret=%d", cur_coef_index, ret);
#endif
#endif
}else{
if (from_key && anc_status == ANC_STATUS_INIT) {
TRACE(1,"[ANC KEY PROC] ANC ON2 T:%u", time);
// Let state machine enable ANC
return;
}
TRACE(1,"[ANC KEY PROC] ANC ON T:%u", time);
#ifdef ANC_FF_ENABLED
ret = anc_select_coef(anc_sample_rate[AUD_STREAM_PLAYBACK],cur_coef_index,ANC_FEEDFORWARD,ANC_GAIN_DELAY);
TRACE(2,"[ANC KEY PROC] anc_select_coef ff %d: ret=%d", cur_coef_index, ret);
#endif
#ifdef ANC_FB_ENABLED
ret = anc_select_coef(anc_sample_rate[AUD_STREAM_PLAYBACK],cur_coef_index,ANC_FEEDBACK,ANC_GAIN_DELAY);
TRACE(2,"[ANC KEY PROC] anc_select_coef fb %d: ret=%d", cur_coef_index, ret);
#endif
#if defined(AUDIO_ANC_FB_MC_HW)
ret = anc_select_coef(anc_sample_rate[AUD_STREAM_PLAYBACK],cur_coef_index, ANC_MUSICCANCLE, ANC_GAIN_DELAY);
TRACE(2,"[ANC KEY PROC] anc_select_coef mc %d: ret=%d", cur_coef_index, ret);
#endif
#if defined(AUDIO_ANC_TT_HW)
ret = anc_select_coef(anc_sample_rate[AUD_STREAM_PLAYBACK],cur_coef_index, ANC_TALKTHRU, ANC_GAIN_DELAY);
TRACE(2,"[ANC KEY PROC] anc_select_coef tt %d: ret=%d", cur_coef_index, ret);
#endif
anc_usb_app(true);
#ifdef ANC_FADE_IN_OUT
fadein_cnt = 0;
anc_status = ANC_STATUS_FADEIN;
#else
{
int32_t gain_ch_l, gain_ch_r;
#if defined(AUDIO_ANC_TT_HW)
anc_get_cfg_gain(&gain_ch_l, &gain_ch_r,ANC_TALKTHRU);
anc_set_gain(gain_ch_l,gain_ch_r,ANC_TALKTHRU);
#endif
#ifdef ANC_FF_ENABLED
anc_get_cfg_gain(&gain_ch_l, &gain_ch_r,ANC_FEEDFORWARD);
anc_set_gain(gain_ch_l,gain_ch_r,ANC_FEEDFORWARD);
#endif
#ifdef ANC_FB_ENABLED
anc_get_cfg_gain(&gain_ch_l, &gain_ch_r,ANC_FEEDBACK);
anc_set_gain(gain_ch_l,gain_ch_r,ANC_FEEDBACK);
#endif
#ifdef AUDIO_ANC_FB_MC_HW
anc_get_cfg_gain(&gain_ch_l, &gain_ch_r,ANC_MUSICCANCLE);
anc_set_gain(gain_ch_l,gain_ch_r,ANC_MUSICCANCLE);
#endif
}
anc_status = ANC_STATUS_ENABLE;
#endif
}
}
static void anc_key_proc_close(bool from_key)
{
uint32_t time;
time = hal_sys_timer_get();
anc_close_time = time;
if (anc_status == ANC_STATUS_INIT) {
TRACE(1,"[ANC KEY PROC] ANC INIT => INIT_CLOSE T:%u", time);
anc_status = ANC_STATUS_INIT_CLOSE;
} else if (anc_status == ANC_STATUS_INIT_CLOSE || anc_status == ANC_STATUS_DISABLE) {
if (from_key) {
TRACE(1,"[ANC KEY PROC] ANC OFF2 T:%u", time);
// Let state machine to shutdown ANC
return;
}
TRACE(1,"[ANC KEY PROC] ANC CLOSE => NULL T:%u", time);
anc_full_close();
} else {
TRACE(1,"[ANC KEY PROC] ANC OFF T:%u", time);
#ifdef ANC_FADE_IN_OUT
fadeout_cnt = 0;
anc_status = ANC_STATUS_FADEOUT;
#else
anc_usb_app(false);
anc_status = ANC_STATUS_DISABLE;
#endif
}
}
void anc_switch_on_off_ctrl(void)
{
uint32_t lock;
enum ANC_KEY_STATE_T key_state = ANC_KEY_STATE_NULL;
lock = int_lock();
// Check if there is a state change
if (anc_key_event != HAL_KEY_EVENT_NONE) {
key_state = prev_key_state;
anc_key_event = HAL_KEY_EVENT_NONE;
}
int_unlock(lock);
if(key_state == ANC_KEY_STATE_OPEN) {
anc_key_proc_open(true);
} else if(key_state == ANC_KEY_STATE_CLOSE) {
anc_key_proc_close(true);
}
}
void anc_double_click_on_off(void)
{
uint32_t lock;
enum HAL_KEY_EVENT_T event;
lock = int_lock();
event = anc_key_event;
anc_key_event = HAL_KEY_EVENT_NONE;
hal_cpu_wake_unlock(ANC_KEY_CPU_WAKE_USER);
int_unlock(lock);
if (event == HAL_KEY_EVENT_NONE) {
return;
} else if (event == HAL_KEY_EVENT_DOUBLECLICK) {
prev_key_state = (prev_key_state == ANC_KEY_STATE_OPEN) ? ANC_KEY_STATE_CLOSE : ANC_KEY_STATE_OPEN;
if (prev_key_state == ANC_KEY_STATE_OPEN) {
anc_key_proc_open(true);
} else {
anc_key_proc_close(true);
}
}
}
void anc_click_on_off(void)
{
enum ANC_STATE_UPDATE_T {
ANC_STATE_UPDATE_NULL = 0,
ANC_STATE_UPDATE_TALK_THROUGH,
ANC_STATE_UPDATE_COEF,
};
enum HAL_KEY_EVENT_T event;
enum ANC_STATE_UPDATE_T state_update = ANC_STATE_UPDATE_NULL;
uint8_t click_cnt = 0;
uint32_t lock;
lock = int_lock();
event = anc_key_event;
anc_key_event = HAL_KEY_EVENT_NONE;
hal_cpu_wake_unlock(ANC_KEY_CPU_WAKE_USER);
int_unlock(lock);
if (event == HAL_KEY_EVENT_NONE) {
return;
#ifdef ANC_TALK_THROUGH
} else if (event == HAL_KEY_EVENT_LONGPRESS) {
talk_through = !talk_through;
if (talk_through) {
state_update = ANC_STATE_UPDATE_TALK_THROUGH;
cur_coef_index = ANC_COEF_NUM;
TRACE(0,"[ANC KEY PROC] anc_talk_through on");
} else {
state_update = ANC_STATE_UPDATE_COEF;
TRACE(0,"[ANC KEY PROC] anc_talk_through off");
}
#endif
} else if (event == HAL_KEY_EVENT_CLICK) {
click_cnt = 1;
} if (event == HAL_KEY_EVENT_DOUBLECLICK) {
click_cnt = 2;
} if (event == HAL_KEY_EVENT_TRIPLECLICK) {
click_cnt = 3;
}
if (click_cnt > 0) {
anc_ctrl_sm = (anc_ctrl_sm + click_cnt) % ANC_CTRL_SM_QTY;
state_update = ANC_STATE_UPDATE_COEF;
#ifdef ANC_TALK_THROUGH
talk_through = false;
#endif
}
if (state_update == ANC_STATE_UPDATE_COEF) {
if (anc_ctrl_sm >= ANC_CTRL_SM_COEF_0 && anc_ctrl_sm <= ANC_CTRL_SM_COEF_N) {
cur_coef_index = anc_ctrl_sm - ANC_CTRL_SM_COEF_0;
}
}
if (state_update != ANC_STATE_UPDATE_NULL) {
if (anc_ctrl_sm == ANC_CTRL_SM_OFF && state_update != ANC_STATE_UPDATE_TALK_THROUGH) {
anc_key_proc_close(true);
} else {
anc_key_proc_open(true);
}
}
}
static void anc_key_process(void)
{
#if defined(ANC_SWITCH_GPIO_PIN) || defined(ANC_SWITCH_GPADC_CHAN)
anc_switch_on_off_ctrl();
#elif defined(ANC_KEY_DOUBLE_CLICK_ON_OFF)
anc_double_click_on_off();
#else
anc_click_on_off();
#endif
}
void anc_state_transition(void)
{
uint32_t t_time;
#ifdef ANC_FADE_IN_OUT
int res_ff = 0, res_fb = 0;
#ifdef AUDIO_ANC_TT_HW
int res_tt = 0;
#endif
#ifdef AUDIO_ANC_FB_MC_HW
int res_mc = 0;
#endif
#endif
t_time = hal_sys_timer_get();
if (anc_status == ANC_STATUS_INIT) {
if (t_time - anc_init_time >= MS_TO_TICKS(ANC_INIT_ON_TIMEOUT_MS)) {
//TRACE(2,"[%s] anc init on T:%u", __func__, t_time);
anc_key_proc_open(false);
// fadein or open
}
}
#ifdef ANC_FADE_IN_OUT
if(anc_status == ANC_STATUS_FADEIN)
{
// process
if(fadein_cnt == 0)
{
TRACE(2,"[%s] anc fadein started T:%u", __func__, t_time);
prev_fade_time = t_time;
fadein_cnt++;
}
else if(fadein_cnt == 1)
{
// delay 60 ticks
if(t_time - prev_fade_time >= 60)
{
fadein_cnt++;
prev_fade_time = t_time;
}
}
else
{
// delay 1 ticks
if(t_time > prev_fade_time)
{
//TRACE(2,"[%s] anc_usb_app_fadein T:%u", __func__, t_time);
#ifdef AUDIO_ANC_TT_HW
res_tt = anc_usb_app_fadein(ANC_TALKTHRU);
#endif
#ifdef ANC_FF_ENABLED
res_ff = anc_usb_app_fadein(ANC_FEEDFORWARD);
#endif
#ifdef ANC_FB_ENABLED
res_fb = anc_usb_app_fadein(ANC_FEEDBACK);
#endif
#ifdef AUDIO_ANC_FB_MC_HW
res_mc = anc_usb_app_fadein(ANC_MUSICCANCLE);
#endif
if(res_ff==0&&res_fb==0
#ifdef AUDIO_ANC_TT_HW
&&res_tt==0
#endif
#ifdef AUDIO_ANC_FB_MC_HW
&&res_mc==0
#endif
)
{
anc_status = ANC_STATUS_ENABLE;
TRACE(2,"[%s] anc fadein done T:%u", __func__, t_time);
}
else
{
prev_fade_time = t_time;
}
}
}
}
else if(anc_status == ANC_STATUS_FADEOUT)
{
// process
if(fadeout_cnt == 0)
{
TRACE(2,"[%s] anc fadeout started T:%u", __func__, t_time);
prev_fade_time = t_time;
fadeout_cnt++;
}
else if(fadeout_cnt == 1)
{
// delay 1 ticks
if(t_time > prev_fade_time)
{
//TRACE(2,"[%s] anc_usb_app_fadeout T:%u", __func__, t_time);
#ifdef AUDIO_ANC_TT_HW
res_tt = anc_usb_app_fadeout(ANC_TALKTHRU);
#endif
#ifdef ANC_FF_ENABLED
res_ff = anc_usb_app_fadeout(ANC_FEEDFORWARD);
#endif
#ifdef ANC_FB_ENABLED
res_fb = anc_usb_app_fadeout(ANC_FEEDBACK);
#endif
#ifdef AUDIO_ANC_FB_MC_HW
res_mc = anc_usb_app_fadein(ANC_MUSICCANCLE);
#endif
if(res_ff==0&&res_fb==0
#ifdef AUDIO_ANC_TT_HW
&&res_tt==0
#endif
#ifdef AUDIO_ANC_FB_MC_HW
&&res_mc==0
#endif
)
{
fadeout_cnt++;
}
prev_fade_time = t_time;
}
}
else
{
anc_usb_app(false);
anc_status = ANC_STATUS_DISABLE;
TRACE(2,"[%s] anc fadeout done T:%u", __func__, t_time);
}
}
#endif
if (anc_status == ANC_STATUS_INIT_CLOSE || anc_status == ANC_STATUS_DISABLE) {
if(t_time - anc_close_time >= MS_TO_TICKS(ANC_SHUTDOWN_TIMEOUT_MS)) {
//TRACE(2,"[%s] anc shutdown T:%u", __func__, t_time);
anc_key_proc_close(false);
}
}
if (anc_status == ANC_STATUS_NULL || anc_status == ANC_STATUS_ENABLE) {
hal_cpu_wake_unlock(ANC_STATE_CPU_WAKE_USER);
} else {
hal_cpu_wake_lock(ANC_STATE_CPU_WAKE_USER);
}
}
int anc_usb_app_key(enum HAL_KEY_CODE_T code, enum HAL_KEY_EVENT_T event)
{
#if !defined(ANC_SWITCH_GPIO_PIN) && !defined(ANC_SWITCH_GPADC_CHAN)
#ifdef ANC_KEY_DOUBLE_CLICK_ON_OFF
if (code == ANC_FUNCTION_KEY) {
if (event == HAL_KEY_EVENT_DOUBLECLICK) {
anc_key_event = event;
hal_cpu_wake_lock(ANC_KEY_CPU_WAKE_USER);
// The key event has been processed
return 0;
}
}
#else
if (code == ANC_FUNCTION_KEY) {
if (event == HAL_KEY_EVENT_CLICK || event == HAL_KEY_EVENT_DOUBLECLICK ||
event == HAL_KEY_EVENT_TRIPLECLICK || event == HAL_KEY_EVENT_LONGPRESS) {
anc_key_event = event;
hal_cpu_wake_lock(ANC_KEY_CPU_WAKE_USER);
}
// The key event has been processed
return 0;
}
#endif
#endif
// Let other applications check the key event
return 1;
}
void anc_key_check(void)
{
enum ANC_KEY_STATE_T key_state;
#ifdef ANC_SWITCH_GPIO_PIN
uint32_t lock;
gpio_pending = false;
#endif
key_state = anc_key_get_state(false);
if (key_state == ANC_KEY_STATE_NULL) {
return;
} else if (key_state == ANC_KEY_STATE_DEBOUNCE) {
hal_cpu_wake_lock(ANC_KEY_CPU_WAKE_USER);
} else if (key_state != prev_key_state) {
prev_key_state = key_state;
// Reuse click event to tag a state change
anc_key_event = HAL_KEY_EVENT_CLICK;
hal_cpu_wake_lock(ANC_KEY_CPU_WAKE_USER);
} else if (anc_key_event == HAL_KEY_EVENT_NONE) {
#ifdef ANC_SWITCH_GPIO_PIN
lock = int_lock();
if (!gpio_pending) {
hal_cpu_wake_unlock(ANC_KEY_CPU_WAKE_USER);
}
int_unlock(lock);
#else
hal_cpu_wake_unlock(ANC_KEY_CPU_WAKE_USER);
#endif
}
}
void anc_key_gpadc_timer_handler(void *param)
{
hwtimer_start(gpadc_timer, ANC_SWITCH_CHECK_INTERVAL);
}
static void anc_key_init(void)
{
#if defined(ANC_SWITCH_GPIO_PIN)
hal_iomux_init((struct HAL_IOMUX_PIN_FUNCTION_MAP *)&pinmux_anc, 1);
hal_gpio_pin_set_dir((enum HAL_GPIO_PIN_T)pinmux_anc.pin, HAL_GPIO_DIR_IN, 0);
// Make sure gpio value is ready
hal_sys_timer_delay(3);
#elif defined(ANC_SWITCH_GPADC_CHAN)
hal_gpadc_open(ANC_SWITCH_GPADC_CHAN, HAL_GPADC_ATP_20MS, NULL);
// Make sure gpadc channel data is ready
hal_sys_timer_delay(6);
gpadc_timer = hwtimer_alloc(anc_key_gpadc_timer_handler, NULL);
ASSERT(gpadc_timer, "Failed to alloc gpadc timer");
hwtimer_start(gpadc_timer, ANC_SWITCH_CHECK_INTERVAL);
#endif
// Add other key initialize
}
#if defined(USB_AUDIO_DYN_CFG) && !defined(__AUDIO_RESAMPLE__)
static void anc_sample_rate_change(enum AUD_STREAM_T stream, enum AUD_SAMPRATE_T rate, enum AUD_SAMPRATE_T *new_play, enum AUD_SAMPRATE_T *new_cap)
{
enum AUD_SAMPRATE_T play_rate, cap_rate;
if (anc_sample_rate[stream] != rate) {
#ifdef CHIP_BEST1000
if (stream == AUD_STREAM_PLAYBACK) {
play_rate = rate;
cap_rate = rate * (anc_sample_rate[AUD_STREAM_CAPTURE] / anc_sample_rate[AUD_STREAM_PLAYBACK]);
} else {
play_rate = rate / (anc_sample_rate[AUD_STREAM_CAPTURE] / anc_sample_rate[AUD_STREAM_PLAYBACK]);
cap_rate = rate;
}
#else
play_rate = rate;
cap_rate = rate;
#ifdef ANC_FF_ENABLED
anc_select_coef(play_rate,cur_coef_index, ANC_FEEDFORWARD, ANC_GAIN_NO_DELAY);
#endif
#ifdef ANC_FB_ENABLED
anc_select_coef(play_rate,cur_coef_index, ANC_FEEDBACK, ANC_GAIN_NO_DELAY);
#endif
#if defined(AUDIO_ANC_FB_MC_HW)
anc_select_coef(play_rate,cur_coef_index, ANC_MUSICCANCLE, ANC_GAIN_NO_DELAY);
#endif
#if defined(AUDIO_ANC_TT_HW)
anc_select_coef(play_rate,cur_coef_index, ANC_TALKTHRU, ANC_GAIN_NO_DELAY);
#endif
#endif
TRACE(5,"%s: Update anc sample rate from %u/%u to %u/%u", __func__,
anc_sample_rate[AUD_STREAM_PLAYBACK], anc_sample_rate[AUD_STREAM_CAPTURE], play_rate, cap_rate);
if (new_play) {
*new_play= play_rate;
}
if (new_cap) {
*new_cap = cap_rate;
}
anc_sample_rate[AUD_STREAM_PLAYBACK] = play_rate;
anc_sample_rate[AUD_STREAM_CAPTURE] = cap_rate;
}
}
#endif
static void anc_full_open(void)
{
AF_ANC_HANDLER POSSIBLY_UNUSED handler;
#if defined(USB_AUDIO_DYN_CFG) && !defined(__AUDIO_RESAMPLE__)
handler = anc_sample_rate_change;
#else
handler = NULL;
#endif
#ifdef USB_AUDIO_APP
usb_audio_keep_streams_running(true);
#endif
pmu_anc_config(1);
#ifdef ANC_FF_ENABLED
af_anc_open(ANC_FEEDFORWARD, anc_sample_rate[AUD_STREAM_PLAYBACK], anc_sample_rate[AUD_STREAM_CAPTURE], handler);
anc_open(ANC_FEEDFORWARD);
#endif
#ifdef ANC_FB_ENABLED
af_anc_open(ANC_FEEDBACK, anc_sample_rate[AUD_STREAM_PLAYBACK], anc_sample_rate[AUD_STREAM_CAPTURE], handler);
anc_open(ANC_FEEDBACK);
#if defined(AUDIO_ANC_FB_MC_HW)
anc_open(ANC_MUSICCANCLE);
#endif
#endif
#if defined(AUDIO_ANC_TT_HW)
anc_open(ANC_TALKTHRU);
#endif
anc_init_time = hal_sys_timer_get();
anc_status = ANC_STATUS_INIT;
}
static void anc_full_close(void)
{
#if defined(AUDIO_ANC_TT_HW)
anc_close(ANC_TALKTHRU);
#endif
#ifdef ANC_FF_ENABLED
anc_close(ANC_FEEDFORWARD);
af_anc_close(ANC_FEEDFORWARD);
#endif
#ifdef ANC_FB_ENABLED
#if defined(AUDIO_ANC_FB_MC_HW)
anc_close(ANC_MUSICCANCLE);
#endif
anc_close(ANC_FEEDBACK);
af_anc_close(ANC_FEEDBACK);
#endif
pmu_anc_config(0);
anc_status = ANC_STATUS_NULL;
#ifdef USB_AUDIO_APP
usb_audio_keep_streams_running(false);
#endif
}
void anc_usb_app_loop(void)
{
#if defined(ANC_SWITCH_GPIO_PIN) || defined(ANC_SWITCH_GPADC_CHAN)
anc_key_check();
#endif
anc_key_process();
anc_state_transition();
}
void anc_usb_app_init(enum AUD_IO_PATH_T input_path, enum AUD_SAMPRATE_T playback_rate, enum AUD_SAMPRATE_T capture_rate)
{
enum ANC_KEY_STATE_T key_state;
#ifdef CFG_HW_ANC_LED_PIN
hal_iomux_init(pinmux_anc_led, ARRAY_SIZE(pinmux_anc_led));
hal_gpio_pin_set_dir(CFG_HW_ANC_LED_PIN, HAL_GPIO_DIR_OUT, 0);
#endif
#ifdef CFG_HW_ANC_LED_PIN2
hal_iomux_init(pinmux_anc_led2, ARRAY_SIZE(pinmux_anc_led2));
hal_gpio_pin_set_dir(CFG_HW_ANC_LED_PIN2, HAL_GPIO_DIR_OUT, 0);
#endif
anc_key_init();
#ifdef __AUDIO_SECTION_SUPPT__
anc_load_cfg();
#endif
anc_sample_rate[AUD_STREAM_PLAYBACK] = hal_codec_anc_convert_rate(playback_rate);
anc_sample_rate[AUD_STREAM_CAPTURE] = hal_codec_anc_convert_rate(capture_rate);
#if defined(ANC_SWITCH_GPIO_PIN) || defined(ANC_SWITCH_GPADC_CHAN)
key_state = anc_key_get_state(true);
prev_key_state = key_state;
#elif defined(ANC_KEY_DOUBLE_CLICK_ON_OFF)
key_state = ANC_KEY_STATE_OPEN;
prev_key_state = key_state;
#else
key_state = ANC_KEY_STATE_OPEN;
anc_ctrl_sm = ANC_CTRL_SM_COEF_0 + cur_coef_index;
#endif
#ifdef ANC_INIT_OFF
key_state = ANC_KEY_STATE_CLOSE;
prev_key_state = key_state;
anc_ctrl_sm = ANC_CTRL_SM_OFF;
#endif
if (key_state == ANC_KEY_STATE_OPEN) {
anc_full_open();
}
}
void anc_usb_app_term(void)
{
anc_full_close();
}