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LeafOS / LeafOS-Devices / android_device_samsung_exynos9820-common / 087e1b74cb242358c041c355c9c0bf7b1459f2dc / . / audio / proxy / audio_proxy.c
blob: 2bfb9788177c6610ee9103adc6b82c82d86477d0 [file] [log] [blame]
/*
* Copyright (C) 2017 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#define LOG_TAG "audio_hw_proxy"
#define LOG_NDEBUG 0
//#define VERY_VERY_VERBOSE_LOGGING
#ifdef VERY_VERY_VERBOSE_LOGGING
#define ALOGVV ALOGD
#else
#define ALOGVV(a...) do { } while(0)
#endif
//#define SEAMLESS_DUMP
#include <stdio.h>
#include <stdlib.h>
#include <errno.h>
#include <pthread.h>
#include <unistd.h>
#include <dirent.h>
#include <sys/stat.h>
#include <dlfcn.h>
#include <fcntl.h>
#include <expat.h>
#include <log/log.h>
#include <cutils/str_parms.h>
#include <cutils/properties.h>
#include <audio_utils/channels.h>
#include <audio_utils/primitives.h>
#include <audio_utils/clock.h>
#include <hardware/audio.h>
#include <sound/asound.h>
#include "audio_proxy.h"
#include "audio_proxy_interface.h"
#include "audio_tables.h"
#include "audio_definition.h"
#include "audio_board_info.h"
#include "audio_usb_proxy_interface.h"
#ifdef SUPPORT_BTA2DP_OFFLOAD
#include "audio_a2dp_proxy.h"
#endif
/* Vendor Property Definitions */
#define NUM_EARPIECE_DEFAULT "1"
#define NUM_EARPIECE_PROPERTY "ro.vendor.config.num_earpiece"
#define NUM_SPEAKER_DEFAULT "1"
#define NUM_SPEAKER_PROPERTY "ro.vendor.config.num_speaker"
#define NUM_PROXIMITY_DEFAULT "1"
#define NUM_PROXIMITY_PROPERTY "ro.vendor.config.num_proximity"
#define SPEAKER_AMP_DEFAULT "1"
#define SPEAKER_AMP_PROPERTY "ro.vendor.config.speaker_amp"
#define BLUETOOTH_DEFAULT "external"
#define BLUETOOTH_PROPERTY "ro.vendor.config.bluetooth"
#define FMRADIO_DEFAULT "external"
#define FMRADIO_PROPERTY "ro.vendor.config.fmradio"
#define USBBYPRIMARY_DEFAULT "no"
#define USBBYPRIMARY_PROPERTY "ro.vendor.config.usb_by_primary"
/******************************************************************************/
/** **/
/** Audio Proxy is Singleton **/
/** **/
/******************************************************************************/
static struct audio_proxy *instance = NULL;
static struct audio_proxy* getInstance(void)
{
if (instance == NULL) {
instance = calloc(1, sizeof(struct audio_proxy));
ALOGI("proxy-%s: created Audio Proxy Instance!", __func__);
}
return instance;
}
static void destroyInstance(void)
{
if (instance) {
free(instance);
instance = NULL;
ALOGI("proxy-%s: destroyed Audio Proxy Instance!", __func__);
}
return;
}
/******************************************************************************/
/** **/
/** Utility Interfaces **/
/** **/
/******************************************************************************/
int get_supported_device_number(void *proxy, int device_type)
{
struct audio_proxy *aproxy = (struct audio_proxy *)proxy;
int ret = 0;
switch (device_type) {
case BUILTIN_EARPIECE:
ret = aproxy->num_earpiece;
break;
case BUILTIN_SPEAKER:
ret = aproxy->num_speaker;
break;
case BUILTIN_MIC:
ret = aproxy->num_mic;
break;
case PROXIMITY_SENSOR:
ret = aproxy->num_proximity;
break;
default:
break;
}
return ret;
}
int get_supported_config(void *proxy, int device_type)
{
struct audio_proxy *aproxy = (struct audio_proxy *)proxy;
int ret = DEVICE_CONFIG_NONE;
switch (device_type) {
case DEVICE_BLUETOOTH:
if (aproxy->bt_internal)
ret = DEVICE_CONFIG_INTERNAL;
else if (aproxy->bt_external)
ret = DEVICE_CONFIG_EXTERNAL;
break;
case DEVICE_FMRADIO:
if (aproxy->fm_internal)
ret = DEVICE_CONFIG_INTERNAL;
else if (aproxy->fm_external)
ret = DEVICE_CONFIG_EXTERNAL;
break;
default:
break;
}
return ret;
}
bool is_needed_config(void *proxy, int config_type)
{
struct audio_proxy *aproxy = (struct audio_proxy *)proxy;
bool ret = false;
switch (config_type) {
case NEED_VOICEPCM_REOPEN:
if (aproxy->btsco_playback)
ret = true;
break;
case SUPPORT_USB_BY_PRIMARY:
if (aproxy->usb_by_primary)
ret = true;
break;
default:
break;
}
return ret;
}
bool is_active_usage_CPCall(void *proxy)
{
struct audio_proxy *aproxy = (struct audio_proxy *)proxy;
if (aproxy->active_playback_ausage >= AUSAGE_CPCALL_MIN &&
aproxy->active_playback_ausage <= AUSAGE_CPCALL_MAX)
return true;
else
return false;
}
bool is_usage_CPCall(audio_usage ausage)
{
if (ausage >= AUSAGE_CPCALL_MIN && ausage <= AUSAGE_CPCALL_MAX)
return true;
else
return false;
}
bool is_active_usage_APCall(void *proxy)
{
struct audio_proxy *aproxy = (struct audio_proxy *)proxy;
if (aproxy->active_playback_ausage >= AUSAGE_APCALL_MIN &&
aproxy->active_playback_ausage <= AUSAGE_APCALL_MAX)
return true;
else
return false;
}
bool is_usage_APCall(audio_usage ausage)
{
if (ausage >= AUSAGE_APCALL_MIN && ausage <= AUSAGE_APCALL_MAX)
return true;
else
return false;
}
bool is_usage_Call(audio_usage ausage)
{
if (ausage >= AUSAGE_CPCALL_MIN && ausage <= AUSAGE_CPCALL_MAX)
return true;
else if (ausage >= AUSAGE_APCALL_MIN && ausage <= AUSAGE_APCALL_MAX)
return true;
else
return false;
}
bool is_usage_Loopback(audio_usage ausage)
{
// AUSAGE_LOOPBACK == min, AUSAGE_LOOPBACK_CODEC == max
if (ausage >= AUSAGE_LOOPBACK && ausage <= AUSAGE_LOOPBACK_CODEC)
return true;
else
return false;
}
bool is_usb_connected(void)
{
struct audio_proxy *aproxy = getInstance();
if (proxy_is_usb_playback_device_connected(aproxy->usb_aproxy))
return true;
else
return false;
}
#ifdef SUPPORT_BTA2DP_OFFLOAD
bool proxy_is_bt_a2dp_ready(void)
{
struct audio_proxy *aproxy = getInstance();
// bt offload enabled and not suspend state
if (aproxy && aproxy->a2dp_out_enabled) {
if (!proxy_a2dp_is_suspended())
return true;
}
return false;
}
static const audio_format_t AUDIO_FORMAT_SEC_BT_A2DP_OFFLOAD = (audio_format_t)0x200000u;
static inline bool audio_is_bt_offload_format(audio_format_t format){
if ((format & AUDIO_FORMAT_SEC_BT_A2DP_OFFLOAD) == AUDIO_FORMAT_SEC_BT_A2DP_OFFLOAD) {
return true;
}
return false;
}
#endif
void update_usb_clksource_info(bool flag)
{
struct audio_proxy *aproxy = getInstance();
struct mixer_ctl *ctrl = NULL;
int ret = 0;
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
// set usb device clock info if flag is true and usb connected
if (flag) {
/* USB Clock Source information Mixer control */
ctrl = mixer_get_ctl_by_name(aproxy->mixer, MIXER_CTL_ABOX_USB_CLOCKSOURCE);
if (ctrl) {
ret = mixer_ctl_get_value(ctrl, 0);
if (ret < 0) {
ALOGE("proxy-%s: failed to get %s %d", __func__, MIXER_CTL_ABOX_USB_CLOCKSOURCE, ret);
} else {
aproxy->is_usb_single_clksrc = ret;
ALOGI("proxy-%s: get USB Device ClockSource information %d",
__func__, aproxy->is_usb_single_clksrc);
}
} else {
ALOGE("proxy-%s: cannot find %s Mixer Control", __func__, MIXER_CTL_ABOX_USB_CLOCKSOURCE);
}
} else {
// reset usb device clock info when usb disconnected
aproxy->is_usb_single_clksrc = false;
ALOGI("proxy-%s: reset USB Device ClockSource information %d",
__func__, aproxy->is_usb_single_clksrc);
}
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return;
}
bool is_usb_single_clksource()
{
struct audio_proxy *aproxy = getInstance();
return aproxy->is_usb_single_clksrc;
}
/******************************************************************************/
/** **/
/** Local Fuctions for Audio Device Proxy **/
/** **/
/******************************************************************************/
static audio_format_t get_pcmformat_from_alsaformat(enum pcm_format pcmformat)
{
audio_format_t format = AUDIO_FORMAT_PCM_16_BIT;
switch (pcmformat) {
case PCM_FORMAT_S16_LE:
format = AUDIO_FORMAT_PCM_16_BIT;
break;
case PCM_FORMAT_S32_LE:
format = AUDIO_FORMAT_PCM_32_BIT;
break;
case PCM_FORMAT_S8:
format = AUDIO_FORMAT_PCM_8_BIT;
break;
case PCM_FORMAT_S24_LE:
case PCM_FORMAT_S24_3LE:
format = AUDIO_FORMAT_PCM_8_24_BIT;
break;
case PCM_FORMAT_INVALID:
case PCM_FORMAT_MAX:
format = AUDIO_FORMAT_PCM_16_BIT;
break;
}
return format;
}
static bool is_playback_device_bt(device_type device)
{
if (device == DEVICE_BT_HEADSET || device == DEVICE_SPEAKER_AND_BT_HEADSET
#ifdef SUPPORT_BTA2DP_OFFLOAD
|| device == DEVICE_BT_A2DP_HEADPHONE || device == DEVICE_SPEAKER_AND_BT_A2DP_HEADPHONE
#endif
)
return true;
else
return false;
}
static bool is_playback_device_speaker_dualpath(device_type device)
{
if (device == DEVICE_SPEAKER_AND_HEADSET ||
device == DEVICE_SPEAKER_AND_HEADPHONE ||
device == DEVICE_SPEAKER_AND_BT_HEADSET ||
device == DEVICE_SPEAKER_AND_USB_HEADSET
#ifdef SUPPORT_BTA2DP_OFFLOAD
|| device == DEVICE_SPEAKER_AND_BT_A2DP_HEADPHONE
#endif
)
return true;
else
return false;
}
#ifdef SUPPORT_BTA2DP_OFFLOAD
static bool is_active_playback_device_bta2dp(struct audio_proxy *aproxy)
{
if (aproxy->active_playback_device == DEVICE_BT_A2DP_HEADPHONE ||
aproxy->active_playback_device == DEVICE_SPEAKER_AND_BT_A2DP_HEADPHONE)
return true;
else
return false;
}
static bool is_playback_device_bta2dp(device_type device)
{
if (device == DEVICE_BT_A2DP_HEADPHONE || device == DEVICE_SPEAKER_AND_BT_A2DP_HEADPHONE)
return true;
else
return false;
}
#endif
static bool is_device_speaker(device_type device)
{
if (device < DEVICE_MAIN_MIC) {
if (device == DEVICE_SPEAKER
#ifdef SEC_AUDIO_SUPPORT_GAMECHAT_SPK_AEC
|| (device == DEVICE_SPEAKER_GAMING)
#endif
|| (device == DEVICE_SPEAKER_DEX)) {
return true;
}
return false;
} else {
if (device == DEVICE_SPEAKER_MIC
#ifdef SEC_AUDIO_SUPPORT_GAMECHAT_SPK_AEC
|| (device == DEVICE_SPEAKER_GAMING_MIC)
#endif
|| (device == DEVICE_SPEAKER_DEX_MIC)) {
return true;
}
return false;
}
}
static bool is_usb_mic_device(device_type device)
{
return (device == DEVICE_USB_HEADSET_MIC /*||
device == DEVICE_USB_FULL_MIC ||
device == DEVICE_USB_HCO_MIC*/);
}
#ifdef SUPPORT_QUAD_MIC
static bool is_quad_mic_device(device_type device)
{
struct audio_proxy *aproxy = getInstance();
bool flag = false;
if (is_usage_CPCall(aproxy->active_capture_ausage) ||
is_usage_APCall(aproxy->active_capture_ausage))
flag = (device == DEVICE_MAIN_MIC ||
device == DEVICE_HANDSET_MIC ||
device == DEVICE_HEADPHONE_MIC ||
device == DEVICE_SPEAKER_MIC ||
device == DEVICE_SPEAKER_DEX_MIC /*||
device == DEVICE_SPEAKER_GAMING_MIC*/);
return flag;
}
#endif
// If there are specific device number in mixer_paths.xml, it get the specific device number from mixer_paths.xml
static int get_pcm_device_number(void *proxy, void *proxy_stream)
{
struct audio_proxy *aproxy = proxy;
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
int pcm_device_number = -1;
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
if (apstream) {
switch(apstream->stream_type) {
case ASTREAM_PLAYBACK_PRIMARY:
pcm_device_number = PRIMARY_PLAYBACK_DEVICE;
break;
case ASTREAM_PLAYBACK_FAST:
pcm_device_number = FAST_PLAYBACK_DEVICE;
break;
case ASTREAM_PLAYBACK_LOW_LATENCY:
pcm_device_number = LOW_PLAYBACK_DEVICE;
break;
case ASTREAM_PLAYBACK_DEEP_BUFFER:
pcm_device_number = DEEP_PLAYBACK_DEVICE;
break;
case ASTREAM_PLAYBACK_COMPR_OFFLOAD:
pcm_device_number = OFFLOAD_PLAYBACK_DEVICE;
break;
case ASTREAM_PLAYBACK_MMAP:
pcm_device_number = MMAP_PLAYBACK_DEVICE;
break;
case ASTREAM_PLAYBACK_AUX_DIGITAL:
pcm_device_number = AUX_PLAYBACK_DEVICE;
break;
case ASTREAM_PLAYBACK_DIRECT:
pcm_device_number = DIRECT_PLAYBACK_DEVICE;
break;
case ASTREAM_CAPTURE_PRIMARY:
pcm_device_number = PRIMARY_CAPTURE_DEVICE;
break;
case ASTREAM_CAPTURE_CALL:
pcm_device_number = CALL_RECORD_DEVICE;
break;
case ASTREAM_CAPTURE_LOW_LATENCY:
pcm_device_number = LOW_CAPTURE_DEVICE;
break;
case ASTREAM_CAPTURE_MMAP:
pcm_device_number = MMAP_CAPTURE_DEVICE;
break;
case ASTREAM_CAPTURE_FM_TUNER:
case ASTREAM_CAPTURE_FM_RECORDING:
pcm_device_number = FM_RECORD_DEVICE;
break;
default:
break;
}
} else {
}
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return pcm_device_number;
}
/*
* Internal Path Control Functions for A-Box
*/
static void disable_erap_in(void *proxy)
{
struct audio_proxy *aproxy = proxy;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_out_loopback) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
ERAP_IN_CARD, ERAP_IN_DEVICE, 'c');
/* Disables ERAP In Path */
if (aproxy->erap_in) {
pcm_stop(aproxy->erap_in);
pcm_close(aproxy->erap_in);
aproxy->erap_in = NULL;
ALOGI("proxy-%s: ERAP In PCM Device(%s) is stopped & closed!", __func__, pcm_path);
}
}
return ;
}
static void enable_erap_in(void *proxy, device_type target_device)
{
struct audio_proxy *aproxy = proxy;
struct pcm_config pcmconfig = pcm_config_erap_in;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_out_loopback) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
ERAP_IN_CARD, ERAP_IN_DEVICE, 'c');
/* Enables ERAP In Path */
if (aproxy->erap_in == NULL) {
/* If target device is USB Headset, then loopback path's PCM channels should be
* matched with USB device supported channels */
if (target_device == DEVICE_SPEAKER_AND_USB_HEADSET) {
pcmconfig.channels = proxy_usb_get_playback_channels(aproxy->usb_aproxy);
/* check if connected USB headset's highest channel count is 6, then forcelly
* change it to 8 channels as A-Box HW cannot support 6 channel conversion */
if (pcmconfig.channels == ABOX_UNSUPPORTED_CHANNELS) {
ALOGI("proxy-%s: supported CH is(%d) Changed to (%d)", __func__, pcmconfig.channels,
ABOX_SUPPORTED_MAX_CHANNELS);
pcmconfig.channels = ABOX_SUPPORTED_MAX_CHANNELS;
}
ALOGI("proxy-%s: ERAP In USB Device channels updated as CC(%d)",
__func__, pcmconfig.channels);
}
#ifdef SUPPORT_QUAD_MIC
else if (target_device == DEVICE_CALL_FWD) {
pcmconfig.channels = MEDIA_4_CHANNELS;
ALOGI("proxy-%s: Call-forwarding/spectro ERAP In channels fixed to (%d)", __func__, pcmconfig.channels);
}
#endif
aproxy->erap_in = pcm_open(ERAP_IN_CARD, ERAP_IN_DEVICE,
PCM_IN | PCM_MONOTONIC, &pcmconfig);
if (aproxy->erap_in && !pcm_is_ready(aproxy->erap_in)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("proxy-%s: ERAP In PCM Device(%s) with SR(%u) PF(%d) CC(%d) is not ready as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->erap_in));
goto err_open;
}
ALOGVV("proxy-%s: ERAP In PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
if (pcm_start(aproxy->erap_in) == 0) {
ALOGI("proxy-%s: ERAP In PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened & started",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
} else {
ALOGE("proxy-%s: ERAP In PCM Device(%s) with SR(%u) PF(%d) CC(%d) cannot be started as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->erap_in));
goto err_open;
}
}
}
return ;
err_open:
disable_erap_in(proxy);
return ;
}
static void disable_voice_tx_direct_in(void *proxy)
{
struct audio_proxy *aproxy = proxy;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->call_tx_direct) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
VC_FMRADIO_CAPTURE_CARD, VC_FMRADIO_CAPTURE_DEVICE, 'c');
pcm_stop(aproxy->call_tx_direct);
pcm_close(aproxy->call_tx_direct);
aproxy->call_tx_direct= NULL;
ALOGI("proxy-%s: Voice Call TX Direct PCM Device(%s) is stopped & closed!", __func__, pcm_path);
}
return;
}
static void enable_voice_tx_direct_in(void *proxy, device_type target_device __unused)
{
struct audio_proxy *aproxy = proxy;
struct pcm_config pcmconfig;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->call_tx_direct== NULL) {
#ifdef SUPPORT_QUAD_MIC
if (is_quad_mic_device(target_device)) {
pcmconfig = pcm_config_vc_quad_mic_capture;
ALOGI("proxy-%s: Quad-Mic config for Voice Call TX Direct ", __func__);
} else
#endif
pcmconfig = pcm_config_vc_fmradio_capture;
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
VC_FMRADIO_CAPTURE_CARD, VC_FMRADIO_CAPTURE_DEVICE, 'c');
aproxy->call_tx_direct = pcm_open(VC_FMRADIO_CAPTURE_CARD,
VC_FMRADIO_CAPTURE_DEVICE,
PCM_IN | PCM_MONOTONIC, &pcmconfig);
if (aproxy->call_tx_direct && !pcm_is_ready(aproxy->call_tx_direct)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("proxy-%s: Voice Call TX Direct PCM Device(%s) with SR(%u) PF(%d) CC(%d) is not ready as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->call_tx_direct));
goto err_open;
}
ALOGVV("proxy-%s: Voice Call TX Direct PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
if (pcm_start(aproxy->call_tx_direct) == 0) {
ALOGI("proxy-%s: Voice Call TX Direct PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened & started",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
} else {
ALOGE("proxy-%s: Voice Call TX Direct PCM Device(%s) with SR(%u) PF(%d) CC(%d) cannot be started as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->call_tx_direct));
goto err_open;
}
}
return;
err_open:
disable_voice_tx_direct_in(proxy);
}
static void disable_usb_out_loopback(void *proxy)
{
struct audio_proxy *aproxy = proxy;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_usb_out_loopback) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
USBOUT_LOOPBACK_CARD, USBOUT_LOOPBACK_DEVICE, 'c');
/* Disables USB Out Loopback Path */
if (aproxy->usb_out_loopback) {
pcm_stop(aproxy->usb_out_loopback);
pcm_close(aproxy->usb_out_loopback);
aproxy->usb_out_loopback = NULL;
ALOGI("proxy-%s: USBOut Loopback PCM Device(%s) is stopped & closed!", __func__, pcm_path);
}
}
return ;
}
static void enable_usb_out_loopback(void *proxy)
{
struct audio_proxy *aproxy = proxy;
struct pcm_config pcmconfig = pcm_config_usb_out_loopback;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_usb_out_loopback) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
USBOUT_LOOPBACK_CARD, USBOUT_LOOPBACK_DEVICE, 'c');
/* Enables USB Out Loopback path */
if (aproxy->usb_out_loopback == NULL) {
// Updates PCM Configuration same as USB PCM Configuration
pcmconfig.rate = proxy_usb_get_playback_samplerate(aproxy->usb_aproxy);
pcmconfig.channels = proxy_usb_get_playback_channels(aproxy->usb_aproxy);
/* A-Box limitation all DMA buffer size should be multiple of 16
therefore Period Size(Frame Count) is rounded of to nearest 4 multiple */
pcmconfig.period_size = ((pcmconfig.rate * PREDEFINED_USB_PLAYBACK_DURATION) / 1000) & ~0x3;
pcmconfig.format = proxy_usb_get_playback_format(aproxy->usb_aproxy);
/* check if connected USB headset's channel count is 6, then forcelly
* change it to 8 channels as A-Box HW cannot support 6 channel conversion */
if (pcmconfig.channels == ABOX_UNSUPPORTED_CHANNELS) {
ALOGI("proxy-%s: supported CH is(%d) Changed to (%d)", __func__, pcmconfig.channels,
ABOX_SUPPORTED_MAX_CHANNELS);
pcmconfig.channels = ABOX_SUPPORTED_MAX_CHANNELS;
}
/* PCM_FORMAT_S24_3LE (24bit packed) format is not supported by A-Box hardware
* therefore forcefully change the format to PCM_FORMAT_S24_LE */
if (pcmconfig.format == PCM_FORMAT_S24_3LE) {
ALOGI("proxy-%s: USB Format is forcefully changed 24bit packed -> 24bit padded", __func__);
pcmconfig.format = PCM_FORMAT_S24_LE;
}
aproxy->usb_out_loopback = pcm_open(USBOUT_LOOPBACK_CARD, USBOUT_LOOPBACK_DEVICE,
PCM_IN | PCM_MONOTONIC, &pcmconfig);
if (aproxy->usb_out_loopback && !pcm_is_ready(aproxy->usb_out_loopback)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("proxy-%s: USBOut Loopback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is not ready as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->usb_out_loopback));
goto err_open;
}
ALOGI("proxy-%s: USBOut Loopback PCM Device(%s) with SR(%u) PF(%d) CC(%d) PdSz(%d) PdCnt(%d) is opened",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcmconfig.period_size, pcmconfig.period_count);
if (pcm_start(aproxy->usb_out_loopback) == 0) {
ALOGI("proxy-%s: USBOut Loopback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened & started",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
} else {
ALOGE("proxy-%s: USBOut Loopback PCM Device(%s) with SR(%u) PF(%d) CC(%d) cannot be started as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->usb_out_loopback));
goto err_open;
}
}
}
return ;
err_open:
disable_usb_out_loopback(proxy);
return ;
}
static void disable_usb_in_loopback(void *proxy)
{
struct audio_proxy *aproxy = proxy;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_usb_in_loopback) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
USBIN_LOOPBACK_CARD, USBIN_LOOPBACK_DEVICE, 'p');
/* Disables USB In Loopback Path */
if (aproxy->usb_in_loopback) {
pcm_stop(aproxy->usb_in_loopback);
pcm_close(aproxy->usb_in_loopback);
aproxy->usb_in_loopback = NULL;
ALOGI("proxy-%s: USBIn Loopback PCM Device(%s) is stopped & closed!", __func__, pcm_path);
}
}
return ;
}
static void enable_usb_in_loopback(void *proxy)
{
struct audio_proxy *aproxy = proxy;
struct pcm_config pcmconfig = pcm_config_usb_in_loopback;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_usb_in_loopback) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
USBIN_LOOPBACK_CARD, USBIN_LOOPBACK_DEVICE, 'p');
/* Enables USB In Loopback path */
if (aproxy->usb_in_loopback == NULL) {
// Updates PCM Configuration same as USB PCM Configuration
pcmconfig.rate = proxy_usb_get_capture_samplerate(aproxy->usb_aproxy);
pcmconfig.channels = proxy_usb_get_capture_channels(aproxy->usb_aproxy);
/* A-Box limitation all DMA buffer size should be multiple of 16
therefore Period Size(Frame Count) is rounded of to nearest 4 multiple */
pcmconfig.period_size = ((pcmconfig.rate * PREDEFINED_USB_PLAYBACK_DURATION) / 1000) & ~0x3;
pcmconfig.format = proxy_usb_get_capture_format(aproxy->usb_aproxy);
/* check if connected USB headset's channel count is 6, then forcelly
* change it to 8 channels as A-Box HW cannot support 6 channel conversion */
if (pcmconfig.channels == ABOX_UNSUPPORTED_CHANNELS) {
ALOGI("proxy-%s: supported CH is(%d) Changed to (%d)", __func__, pcmconfig.channels,
ABOX_SUPPORTED_MAX_CHANNELS);
pcmconfig.channels = ABOX_SUPPORTED_MAX_CHANNELS;
}
/* PCM_FORMAT_S24_3LE (24bit packed) format is not supported by A-Box hardware
* therefore forcefully change the format to PCM_FORMAT_S24_LE */
if (pcmconfig.format == PCM_FORMAT_S24_3LE) {
ALOGI("proxy-%s: USB Format is forcefully changed from 24bit packed -> 24bit padded", __func__);
pcmconfig.format = PCM_FORMAT_S24_LE;
}
aproxy->usb_in_loopback = pcm_open(USBIN_LOOPBACK_CARD, USBIN_LOOPBACK_DEVICE,
PCM_OUT | PCM_MONOTONIC, &pcmconfig);
if (aproxy->usb_in_loopback && !pcm_is_ready(aproxy->usb_in_loopback)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("proxy-%s: USBIn Loopback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is not ready as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->usb_in_loopback));
goto err_open;
}
ALOGI("proxy-%s: USBIn Loopback PCM Device(%s) with SR(%u)PF(%d) CC(%d) PdSz(%d) PdCnt(%d) is opened",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcmconfig.period_size, pcmconfig.period_count);
if (pcm_start(aproxy->usb_in_loopback) == 0) {
ALOGI("proxy-%s: USBIn Loopback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened & started",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
} else {
ALOGE("proxy-%s: USBIn Loopback PCM Device(%s) with SR(%u) PF(%d) CC(%d) cannot be started as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->usb_in_loopback));
goto err_open;
}
}
}
return ;
err_open:
disable_usb_in_loopback(proxy);
return ;
}
static void disable_spkamp_reference(void *proxy)
{
struct audio_proxy *aproxy = proxy;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_spkamp) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
SPKAMP_REFERENCE_CARD, SPKAMP_REFERENCE_DEVICE, 'c');
/* Disables Speaker AMP Reference Path */
if (aproxy->spkamp_reference) {
pcm_stop(aproxy->spkamp_reference);
pcm_close(aproxy->spkamp_reference);
aproxy->spkamp_reference = NULL;
ALOGI("proxy-%s: SPKAMP Reference PCM Device(%s) is stopped & closed!", __func__, pcm_path);
}
}
return ;
}
static void enable_spkamp_reference(void *proxy)
{
struct audio_proxy *aproxy = proxy;
struct pcm_config pcmconfig = pcm_config_spkamp_reference;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_spkamp) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
SPKAMP_REFERENCE_CARD, SPKAMP_REFERENCE_DEVICE, 'c');
/* Enables Speaker AMP Reference Path */
if (aproxy->spkamp_reference == NULL) {
aproxy->spkamp_reference = pcm_open(SPKAMP_REFERENCE_CARD, SPKAMP_REFERENCE_DEVICE,
PCM_IN | PCM_MONOTONIC, &pcmconfig);
if (aproxy->spkamp_reference && !pcm_is_ready(aproxy->spkamp_reference)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("proxy-%s: SPKAMP Reference PCM Device(%s) with SR(%u) PF(%d) CC(%d) is not ready as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->spkamp_reference));
goto err_open;
}
ALOGVV("proxy-%s: SPKAMP Reference PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
if (pcm_start(aproxy->spkamp_reference) == 0) {
ALOGI("proxy-%s: SPKAMP Reference PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened & started",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
} else {
ALOGE("proxy-%s: SPKAMP Reference PCM Device(%s) with SR(%u) PF(%d) CC(%d) cannot be started as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->spkamp_reference));
goto err_open;
}
}
}
return ;
err_open:
disable_spkamp_reference(proxy);
return ;
}
static void disable_spkamp_playback(void *proxy)
{
struct audio_proxy *aproxy = proxy;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_spkamp && ENABLE_SPKAMP_PLAYBACK) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
SPKAMP_PLAYBACK_CARD, SPKAMP_PLAYBACK_DEVICE, 'p');
/* Disables Speaker AMP Playback Path */
if (aproxy->spkamp_playback) {
pcm_stop(aproxy->spkamp_playback);
pcm_close(aproxy->spkamp_playback);
aproxy->spkamp_playback = NULL;
ALOGI("proxy-%s: SPKAMP Playback PCM Device(%s) is stopped & closed!", __func__, pcm_path);
}
}
return ;
}
static void enable_spkamp_playback(void *proxy)
{
struct audio_proxy *aproxy = proxy;
struct pcm_config pcmconfig = pcm_config_spkamp_playback;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_spkamp && ENABLE_SPKAMP_PLAYBACK) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
SPKAMP_PLAYBACK_CARD, SPKAMP_PLAYBACK_DEVICE, 'p');
/* Enables Speaker AMP Playback path */
if (aproxy->spkamp_playback == NULL) {
aproxy->spkamp_playback = pcm_open(SPKAMP_PLAYBACK_CARD, SPKAMP_PLAYBACK_DEVICE,
PCM_OUT | PCM_MONOTONIC, &pcmconfig);
if (aproxy->spkamp_playback && !pcm_is_ready(aproxy->spkamp_playback)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("proxy-%s: SPKAMP Playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is not ready as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->spkamp_playback));
goto err_open;
}
ALOGVV("proxy-%s: SPKAMP Playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
if (pcm_start(aproxy->spkamp_playback) == 0) {
ALOGI("proxy-%s: SPKAMP Playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened & started",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
} else {
ALOGE("proxy-%s: SPKAMP Playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) cannot be started as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->spkamp_playback));
goto err_open;
}
}
}
return ;
err_open:
disable_spkamp_playback(proxy);
return ;
}
static void disable_btsco_playback(void *proxy)
{
struct audio_proxy *aproxy = proxy;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_btsco) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
BTSCO_PLAYBACK_CARD, BTSCO_PLAYBACK_DEVICE, 'p');
/* Disables BT-SCO Playback Path */
if (aproxy->btsco_playback) {
pcm_stop(aproxy->btsco_playback);
pcm_close(aproxy->btsco_playback);
aproxy->btsco_playback = NULL;
ALOGI("proxy-%s: BTSCO Playback PCM Device(%s) is stopped & closed!", __func__, pcm_path);
}
}
return ;
}
static void enable_btsco_playback(void *proxy)
{
struct audio_proxy *aproxy = proxy;
struct pcm_config pcmconfig = pcm_config_btsco_playback;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_btsco) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
BTSCO_PLAYBACK_CARD, BTSCO_PLAYBACK_DEVICE, 'p');
/* Enables BT-SCO Playback Path */
if (aproxy->btsco_playback == NULL) {
aproxy->btsco_playback = pcm_open(BTSCO_PLAYBACK_CARD, BTSCO_PLAYBACK_DEVICE,
PCM_OUT | PCM_MONOTONIC, &pcmconfig);
if (aproxy->btsco_playback && !pcm_is_ready(aproxy->btsco_playback)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("proxy-%s: BTSCO Playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is not ready as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->btsco_playback));
goto err_open;
}
ALOGVV("proxy-%s: BTSCO Playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
if (pcm_start(aproxy->btsco_playback) == 0) {
ALOGI("proxy-%s: BTSCO Playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened & started",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
} else {
ALOGE("proxy-%s: BTSCO Playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) cannot be started as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->btsco_playback));
goto err_open;
}
}
}
return ;
err_open:
disable_btsco_playback(proxy);
return ;
}
#ifdef SUPPORT_BTA2DP_OFFLOAD
static void disable_bta2dp_out_loopback(void *proxy)
{
struct audio_proxy *aproxy = proxy;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_bta2dp) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
BTA2DP_OUT_LOOPBACK_CARD, BTA2DP_OUT_LOOPBACK_DEVICE, 'c');
/* Disables BT-A2DP Out Loopback Path */
if (aproxy->bta2dp_out_loopback) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
BTA2DP_OUT_LOOPBACK_CARD, BTA2DP_OUT_LOOPBACK_DEVICE, 'c');
pcm_stop(aproxy->bta2dp_out_loopback);
pcm_close(aproxy->bta2dp_out_loopback);
aproxy->bta2dp_out_loopback = NULL;
ALOGI("proxy-%s: BT A2DP Out Loopback PCM Device(%s) is stopped & closed!", __func__, pcm_path);
}
}
return;
}
static void enable_bta2dp_out_loopback(void *proxy)
{
struct audio_proxy *aproxy = proxy;
struct pcm_config pcmconfig = pcm_config_bta2dp_out_loopback;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_bta2dp) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
BTA2DP_OUT_LOOPBACK_CARD, BTA2DP_OUT_LOOPBACK_DEVICE, 'c');
/* Enables BT-A2DP Out Loopback Path */
if (aproxy->bta2dp_out_loopback == NULL) {
aproxy->bta2dp_out_loopback = pcm_open(BTA2DP_OUT_LOOPBACK_CARD, BTA2DP_OUT_LOOPBACK_DEVICE,
PCM_IN | PCM_MONOTONIC, &pcmconfig);
if (aproxy->bta2dp_out_loopback && !pcm_is_ready(aproxy->bta2dp_out_loopback)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("proxy-%s: BT A2DP Out Loopback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is not ready as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->bta2dp_out_loopback));
goto err_open;
}
ALOGI("proxy-%s: BT A2DP Out Loopback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
if (pcm_start(aproxy->bta2dp_out_loopback) == 0) {
ALOGI("proxy-%s: BT A2DP Out Loopback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is started",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
} else {
ALOGE("proxy-%s: BT A2DP Out Loopback PCM Device(%s) with SR(%u) PF(%d) CC(%d) cannot be started as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->bta2dp_out_loopback));
goto err_open;
}
}
}
return;
err_open:
disable_bta2dp_out_loopback(aproxy);
}
static void disable_bta2dp_playback(void *proxy)
{
struct audio_proxy *aproxy = proxy;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_bta2dp) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
BTA2DP_PLAYBACK_CARD, BTA2DP_PLAYBACK_DEVICE, 'p');
/* Disables BT-SCO Playback Path */
if (aproxy->bta2dp_playback) {
pcm_stop(aproxy->bta2dp_playback);
pcm_close(aproxy->bta2dp_playback);
aproxy->bta2dp_playback = NULL;
ALOGI("proxy-%s: BTA2DP Playback PCM Device(%s) is stopped & closed!", __func__, pcm_path);
}
}
return ;
}
static void enable_bta2dp_playback(void *proxy)
{
struct audio_proxy *aproxy = proxy;
struct pcm_config pcmconfig = pcm_config_bta2dp_playback;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_bta2dp) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
BTA2DP_PLAYBACK_CARD, BTA2DP_PLAYBACK_DEVICE, 'p');
/* Enables BT-SCO Playback Path */
if (aproxy->bta2dp_playback == NULL) {
aproxy->bta2dp_playback = pcm_open(BTA2DP_PLAYBACK_CARD, BTA2DP_PLAYBACK_DEVICE,
PCM_OUT | PCM_MONOTONIC, &pcmconfig);
if (aproxy->bta2dp_playback && !pcm_is_ready(aproxy->bta2dp_playback)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("proxy-%s: BTA2DP Playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is not ready as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->bta2dp_playback));
goto err_open;
}
ALOGI("proxy-%s: BTA2DP Playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
if (pcm_start(aproxy->bta2dp_playback) == 0) {
ALOGI("proxy-%s: BTA2DP Playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is started",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
} else {
ALOGE("proxy-%s: BTA2DP Playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) cannot be started as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->bta2dp_playback));
goto err_open;
}
}
}
return ;
err_open:
disable_bta2dp_playback(proxy);
}
/* modified by samsung convgergence */
void set_a2dp_suspend_mixer(int a2dp_suspend)
{
struct audio_proxy *aproxy = getInstance();
uint32_t value[MIXER_CTL_ABOX_A2DP_SUSPEND_PARAMS_CNT] = {0, };
ALOGI("proxy-%s: a2dp-suspend[%d]", __func__, a2dp_suspend);
value[0] = a2dp_suspend;
proxy_set_mixer_value_array(aproxy, MIXER_CTL_ABOX_A2DP_SUSPEND_PARAMS, value,
MIXER_CTL_ABOX_A2DP_SUSPEND_PARAMS_CNT);
/* Forcefully disonnect A2DP to RDMA6 connection to fix BTSCO switching */
if (is_active_playback_device_bta2dp(aproxy)) {
if (a2dp_suspend == MIXER_ON) {
proxy_set_mixer_value_string(aproxy, "ABOX SPUS OUT6", "RESERVED");
ALOGI("proxy-%s: set ABOX SPUS OUT6 to RESERVED", __func__);
proxy_set_mixer_value_string(aproxy, "ABOX SIFS2", "RESERVED");
ALOGI("proxy-%s: set ABOX SIFS2 to RESERVED", __func__);
} else {
proxy_set_mixer_value_string(aproxy, "ABOX SPUS OUT6", "SIFS2");
ALOGI("proxy-%s: set ABOX SPUS OUT6 to SIFS2", __func__);
proxy_set_mixer_value_string(aproxy, "ABOX SIFS2", "SPUS OUT6");
ALOGI("proxy-%s: set ABOX SIFS2 to SPUS OUT6", __func__);
}
}
}
#endif
// Specific Mixer Control Functions for Internal Loopback Handling
void proxy_set_mixercontrol(struct audio_proxy *aproxy, erap_trigger type, int value)
{
struct mixer_ctl *ctrl = NULL;
char mixer_name[MAX_MIXER_NAME_LEN];
int ret = 0, val = value;
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
if (type == MUTE_CONTROL) {
ctrl = mixer_get_ctl_by_name(aproxy->mixer, ABOX_MUTE_CONTROL_NAME);
snprintf(mixer_name, sizeof(mixer_name), ABOX_MUTE_CONTROL_NAME);
} else if (type == TICKLE_CONTROL) {
ctrl = mixer_get_ctl_by_name(aproxy->mixer, ABOX_TICKLE_CONTROL_NAME);
snprintf(mixer_name, sizeof(mixer_name), ABOX_TICKLE_CONTROL_NAME);
}
if (ctrl) {
ret = mixer_ctl_set_value(ctrl, 0,val);
if (ret != 0)
ALOGE("proxy-%s: failed to set Mixer Control(%s)", __func__, mixer_name);
else
ALOGI("proxy-%s: set Mixer Control(%s) to %d", __func__, mixer_name, val);
} else {
ALOGE("proxy-%s: cannot find Mixer Control", __func__);
}
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ;
}
/* Enable usb playback new Modifier */
static void set_usb_playback_modifier(void *proxy)
{
struct audio_proxy *aproxy = proxy;
struct mixer_ctl *ctrl = NULL;
int ret, val = 0;
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
/* Mixer out sample rate configuration */
ctrl = mixer_get_ctl_by_name(aproxy->mixer, ABOX_SAMPLE_RATE_MIXER_NAME);
if (ctrl) {
val = proxy_usb_get_playback_samplerate(aproxy->usb_aproxy);
ALOGI("proxy-%s: configured SR(%d)", __func__, val);
ret = mixer_ctl_set_value(ctrl, 0, val);
if (ret != 0)
ALOGE("proxy-%s: failed to set %s", __func__, ABOX_SAMPLE_RATE_MIXER_NAME);
} else {
ALOGE("proxy-%s: cannot find %s Mixer Control", __func__, ABOX_SAMPLE_RATE_MIXER_NAME);
}
/* Mixer out channels configuration */
ctrl = mixer_get_ctl_by_name(aproxy->mixer, ABOX_CHANNELS_MIXER_NAME);
if (ctrl) {
val = proxy_usb_get_playback_channels(aproxy->usb_aproxy);
/* check if connected USB headset's highest channel count is 6, then forcelly
* change it to 8 channels as A-Box HW cannot support 6 channel conversion */
if (val == ABOX_UNSUPPORTED_CHANNELS) {
ALOGI("proxy-%s: supported CH is(%d) Changed to (%d)", __func__, val,
ABOX_SUPPORTED_MAX_CHANNELS);
val = ABOX_SUPPORTED_MAX_CHANNELS;
}
ALOGI("proxy-%s: configured CH(%d)", __func__, val);
ret = mixer_ctl_set_value(ctrl, 0, val);
if (ret != 0)
ALOGE("proxy-%s: failed to set %s", __func__, ABOX_CHANNELS_MIXER_NAME);
} else {
ALOGE("proxy-%s: cannot find %s Mixer Control", __func__, ABOX_CHANNELS_MIXER_NAME);
}
/* Mixer out bit width configuration */
ctrl = mixer_get_ctl_by_name(aproxy->mixer, ABOX_BIT_WIDTH_MIXER_NAME);
if (ctrl) {
val = proxy_usb_get_playback_bitwidth(aproxy->usb_aproxy);
ALOGI("proxy-%s: configured BW(%d)", __func__, val);
ret = mixer_ctl_set_value(ctrl, 0, val);
if (ret != 0)
ALOGE("proxy-%s: failed to set %s", __func__, ABOX_BIT_WIDTH_MIXER_NAME);
} else {
ALOGE("proxy-%s: cannot find %s Mixer Control", __func__, ABOX_BIT_WIDTH_MIXER_NAME);
}
#ifdef SUPPORT_DIRECT_RCVSPK_PATH
/*
* SIFS0 switch control is required to reconfigure all running DMA ASRC configurations
*/
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_SIFS0_SWITCH, MIXER_OFF);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_SIFS0_SWITCH, MIXER_ON);
ALOGI("proxy-%s: control SIFS0 Off/On", __func__);
#endif
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ;
}
/* Resset Modifier to default values */
static void reset_playback_modifier(void *proxy)
{
struct audio_proxy *aproxy = proxy;
struct mixer_ctl *ctrl = NULL;
int ret, val = 0;
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
/* Mixer out sample rate configuration */
ctrl = mixer_get_ctl_by_name(aproxy->mixer, ABOX_SAMPLE_RATE_MIXER_NAME);
if (ctrl) {
val = DEFAULT_MEDIA_SAMPLING_RATE;
ALOGI("proxy-%s: configured SR(%d)", __func__, val);
ret = mixer_ctl_set_value(ctrl, 0, val);
if (ret != 0)
ALOGE("proxy-%s: failed to set %s", __func__, ABOX_SAMPLE_RATE_MIXER_NAME);
} else {
ALOGE("proxy-%s: cannot find %s Mixer Control", __func__, ABOX_SAMPLE_RATE_MIXER_NAME);
}
/* Mixer out channels configuration */
ctrl = mixer_get_ctl_by_name(aproxy->mixer, ABOX_CHANNELS_MIXER_NAME);
if (ctrl) {
val = DEFAULT_MEDIA_CHANNELS;
ALOGI("proxy-%s: configured CH(%d)", __func__, val);
ret = mixer_ctl_set_value(ctrl, 0, val);
if (ret != 0)
ALOGE("proxy-%s: failed to set %s", __func__, ABOX_CHANNELS_MIXER_NAME);
} else {
ALOGE("proxy-%s: cannot find %s Mixer Control", __func__, ABOX_CHANNELS_MIXER_NAME);
}
/* Mixer out bit width configuration */
ctrl = mixer_get_ctl_by_name(aproxy->mixer, ABOX_BIT_WIDTH_MIXER_NAME);
if (ctrl) {
val = DEFAULT_MEDIA_BITWIDTH;
ALOGI("proxy-%s: configured BW(%d)", __func__, val);
ret = mixer_ctl_set_value(ctrl, 0, val);
if (ret != 0)
ALOGE("proxy-%s: failed to set %s", __func__, ABOX_BIT_WIDTH_MIXER_NAME);
} else {
ALOGE("proxy-%s: cannot find %s Mixer Control", __func__, ABOX_BIT_WIDTH_MIXER_NAME);
}
#ifdef SUPPORT_DIRECT_RCVSPK_PATH
/*
* SIFS0 switch control is required to reconfigure all running DMA ASRC configurations
*/
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_SIFS0_SWITCH, MIXER_OFF);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_SIFS0_SWITCH, MIXER_ON);
ALOGI("proxy-%s: control SIFS0 Off/On", __func__);
#endif
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ;
}
#ifdef SUPPORT_BTA2DP_OFFLOAD
/* BT A2DP Audio Specific Functions */
static void bta2dp_playback_start(struct audio_proxy *aproxy)
{
audio_format_t codec_type = AUDIO_FORMAT_SBC; // SBC is Max Size Structure, so it is default
audio_sbc_encoder_config codec_info;
int ret = 0;
if (aproxy && aproxy->a2dp_out_enabled) {
ret = proxy_a2dp_start();
if (ret == 0) {
ALOGI("proxy-%s: started BT A2DP", __func__);
ret = proxy_a2dp_get_config((uint32_t *)&codec_type, (void *)&codec_info);
if (ret == 0) {
if (codec_type == AUDIO_FORMAT_SBC) {
struct sbc_enc_cfg_t config;
audio_sbc_encoder_config *sbc_config = (audio_sbc_encoder_config *)&codec_info;
memset(&config, 0, sizeof(struct sbc_enc_cfg_t));
config.enc_format = ENC_MEDIA_FMT_SBC;
config.num_subbands = (uint32_t)sbc_config->subband;
config.blk_len = (uint32_t)sbc_config->blk_len;
config.channel_mode = (uint32_t)sbc_config->channels;
config.alloc_method = (uint32_t)sbc_config->alloc;
config.bit_rate = (uint32_t)sbc_config->bitrate;
config.sample_rate = (uint32_t)sbc_config->sampling_rate;
proxy_set_mixer_value_array(aproxy, ABOX_A2DP_OFFLOAD_SET_PARAMS_NAME,
&config, ABOX_A2DP_OFFLOAD_SET_PARAMS_COUNT);
ALOGI("proxy-%s: set A2DP SBC Encoder Configurations", __func__);
// Default SBC Latency = 150ms
aproxy->a2dp_default_delay = 150;
} else if (codec_type == AUDIO_FORMAT_APTX) {
struct aptx_enc_cfg_t config;
audio_aptx_encoder_config *aptx_config = (audio_aptx_encoder_config *)&codec_info;
memset(&config, 0, sizeof(struct aptx_enc_cfg_t));
config.enc_format = ENC_MEDIA_FMT_APTX;
config.sample_rate = (uint32_t)aptx_config->sampling_rate;
config.num_channels = (uint32_t)aptx_config->channels;
switch (config.num_channels) {
case 1:
config.channel_mapping[0] = PCM_CHANNEL_C;
break;
case 2:
default:
config.channel_mapping[0] = PCM_CHANNEL_L;
config.channel_mapping[1] = PCM_CHANNEL_R;
}
proxy_set_mixer_value_array(aproxy, ABOX_A2DP_OFFLOAD_SET_PARAMS_NAME,
&config, ABOX_A2DP_OFFLOAD_SET_PARAMS_COUNT);
ALOGI("proxy-%s: set A2DP APTX Encoder Configurations", __func__);
// Default APTX Latency = 200ms
aproxy->a2dp_default_delay = 200;
}
} else
ALOGE("proxy-%s: failed to get BT A2DP Codec Configurations", __func__);
}
}
return ;
}
static void bta2dp_playback_stop(struct audio_proxy *aproxy)
{
int ret = 0;
if (aproxy && aproxy->a2dp_out_enabled) {
ret = proxy_a2dp_stop();
if (ret == 0)
ALOGI("proxy-%s: stopped stream for BT A2DP", __func__);
}
return ;
}
static void disable_a2dp_mute_playback(void *proxy)
{
struct audio_proxy *aproxy = proxy;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_bta2dp) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
A2DPMUTE_PLAYBACK_CARD, A2DPMUTE_PLAYBACK_DEVICE, 'p');
/* Disables a2dp mute playback Path */
if (aproxy->a2dp_mute_playback) {
pcm_stop(aproxy->a2dp_mute_playback);
pcm_close(aproxy->a2dp_mute_playback);
aproxy->a2dp_mute_playback = NULL;
ALOGI("proxy-%s: A2DP Mute playback PCM Device(%s) is stopped & closed!", __func__, pcm_path);
}
}
return ;
}
static void enable_a2dp_mute_playback(void *proxy)
{
struct audio_proxy *aproxy = proxy;
struct pcm_config pcmconfig = pcm_config_a2dp_mute_playback;
char pcm_path[MAX_PCM_PATH_LEN];
if (aproxy->support_bta2dp) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
A2DPMUTE_PLAYBACK_CARD, A2DPMUTE_PLAYBACK_DEVICE, 'p');
/* Enables A2DP Mute playback path */
if (aproxy->a2dp_mute_playback == NULL) {
aproxy->a2dp_mute_playback = pcm_open(A2DPMUTE_PLAYBACK_CARD, A2DPMUTE_PLAYBACK_DEVICE,
PCM_OUT | PCM_MONOTONIC, &pcmconfig);
if (aproxy->a2dp_mute_playback && !pcm_is_ready(aproxy->a2dp_mute_playback)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("proxy-%s: A2DP Mute playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is not ready as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->a2dp_mute_playback));
goto err_open;
}
ALOGI("proxy-%s: A2DP Mute playback PCM Device(%s) with SR(%u)PF(%d) CC(%d) PdSz(%d) PdCnt(%d) is opened",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcmconfig.period_size, pcmconfig.period_count);
if (pcm_start(aproxy->a2dp_mute_playback) == 0) {
ALOGI("proxy-%s: A2DP Mute playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened & started",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
} else {
ALOGE("proxy-%s: A2DP Mute playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) cannot be started as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->a2dp_mute_playback));
goto err_open;
}
}
}
return ;
err_open:
disable_a2dp_mute_playback(proxy);
return ;
}
#endif
static void enable_internal_path(void *proxy, int ausage, device_type target_device)
{
struct audio_proxy *aproxy = proxy;
/* skip internal pcm controls for VoiceCall bandwidth change */
if (aproxy->skip_internalpath) {
ALOGI("proxy-%s: skip enabling internal path", __func__);
return;
}
if (target_device == DEVICE_EARPIECE ||
target_device == DEVICE_SPEAKER || target_device == DEVICE_SPEAKER2 ||
target_device == DEVICE_SPEAKER_DUAL || target_device == DEVICE_SPEAKER_DEX ||
target_device == DEVICE_SPEAKER_AND_HEADSET || target_device == DEVICE_SPEAKER_AND_HEADPHONE) {
#ifdef SUPPORT_DIRECT_RCVSPK_PATH
if (is_playback_device_speaker_dualpath(target_device)
|| ausage == AUSAGE_FM_RADIO_CAPTURE
|| ausage == AUSAGE_FM_RADIO_TUNER)
#endif
{
enable_spkamp_playback(aproxy);
enable_erap_in(aproxy, target_device);
}
enable_spkamp_reference(aproxy);
#ifdef SUPPORT_BTA2DP_OFFLOAD
} else if (target_device == DEVICE_BT_A2DP_HEADPHONE ||
target_device == DEVICE_SPEAKER_AND_BT_A2DP_HEADPHONE) {
/* Transit BT A2DP Status */
pthread_mutex_lock(&aproxy->a2dp_lock);
// Case : Audio Path changed from Others to A2DP Device
// BT A2DP need to be started
bta2dp_playback_start(aproxy);
pthread_mutex_unlock(&aproxy->a2dp_lock);
if (target_device == DEVICE_SPEAKER_AND_BT_A2DP_HEADPHONE) {
enable_erap_in(aproxy, target_device);
enable_spkamp_reference(aproxy);
enable_spkamp_playback(aproxy);
}
enable_bta2dp_playback(aproxy);
enable_bta2dp_out_loopback(aproxy);
// Start A2DP Mute playback node
enable_a2dp_mute_playback(proxy);
#endif
} else if (target_device == DEVICE_BT_HEADSET || target_device == DEVICE_SPEAKER_AND_BT_HEADSET) {
enable_erap_in(aproxy, target_device);
if (target_device == DEVICE_SPEAKER_AND_BT_HEADSET) {
enable_spkamp_reference(aproxy);
enable_spkamp_playback(aproxy);
}
enable_btsco_playback(aproxy);
} else if (target_device == DEVICE_HEADSET || target_device == DEVICE_HEADPHONE ||
target_device == DEVICE_CALL_FWD) {
/* In cases of CP/AP Calland Loopback, ERAP Path is needed for SE */
// In case of Normal Media, ERAP Path is not needed
if (is_active_usage_CPCall(aproxy) || is_active_usage_APCall(aproxy) ||
is_usage_Loopback(ausage))
enable_erap_in(aproxy, target_device);
} else if (target_device == DEVICE_USB_HEADSET ||
target_device == DEVICE_SPEAKER_AND_USB_HEADSET) {
/* Prepare USB device configuration based upon usage */
if (aproxy->usb_aproxy) {
/* USB output playback constraints
* Full configuration for all modes except CP Call mode
* CP Call mode: fix configuration to 48KHz 16bit or
* supported configuration */
if (is_usage_CPCall(ausage) &&
!proxy_is_usb_playback_CPCall_prepared(aproxy->usb_aproxy)) {
/* prepare for cp call playback with fixed configuration */
proxy_usb_playback_prepare(aproxy->usb_aproxy, false);
} else if (!is_usage_CPCall(ausage) &&
proxy_is_usb_playback_CPCall_prepared(aproxy->usb_aproxy)) {
/* prepare for playback with default configuration */
proxy_usb_playback_prepare(aproxy->usb_aproxy, true);
}
proxy_usb_open_out_proxy(aproxy->usb_aproxy);
}
/* set USB playback modifier controls */
set_usb_playback_modifier(aproxy);
if (target_device == DEVICE_SPEAKER_AND_USB_HEADSET) {
enable_spkamp_playback(aproxy);
enable_spkamp_reference(aproxy);
}
// In cases of CP/AP Call, Internal Loop & ERAP Path is needed for SE
// In case of Normal Media, No Paths are needed
if (target_device == DEVICE_SPEAKER_AND_USB_HEADSET ||
is_active_usage_CPCall(aproxy) || is_active_usage_APCall(aproxy) ||
is_usage_Loopback(ausage)) {
enable_erap_in(aproxy, target_device);
}
enable_usb_out_loopback(aproxy);
} else if (is_usb_mic_device(target_device)) {
// Check whether USB device is single clocksource, and match samplerate
// with playback
if (aproxy->is_usb_single_clksrc)
proxy_usb_capture_prepare(aproxy->usb_aproxy, true);
if (aproxy->usb_aproxy)
proxy_usb_open_in_proxy(aproxy->usb_aproxy);
enable_usb_in_loopback(proxy);
}
/* enable direct MIC path pcm for voiceCall scenario */
if ((is_usage_CPCall(ausage) || is_usage_Loopback(ausage)) &&
target_device >= DEVICE_MAIN_MIC)
enable_voice_tx_direct_in(aproxy, target_device);
return;
}
static void disable_internal_path(void *proxy, int ausage, device_type target_device)
{
struct audio_proxy *aproxy = proxy;
/* skip internal pcm controls for VoiceCall bandwidth change */
if (aproxy->skip_internalpath) {
ALOGI("proxy-%s: skip disabling internal path", __func__);
return;
}
/* disable direct MIC path pcm for voiceCall scenario */
if ((is_usage_CPCall(ausage) || is_usage_Loopback(ausage)) &&
target_device >= DEVICE_MAIN_MIC)
disable_voice_tx_direct_in(aproxy);
if (target_device == DEVICE_SPEAKER ||
target_device == DEVICE_SPEAKER2 || target_device == DEVICE_SPEAKER_DUAL ||
target_device == DEVICE_EARPIECE || target_device == DEVICE_SPEAKER_DEX ||
target_device == DEVICE_SPEAKER_AND_HEADSET || target_device == DEVICE_SPEAKER_AND_HEADPHONE) {
#ifdef SUPPORT_DIRECT_RCVSPK_PATH
if (is_playback_device_speaker_dualpath(target_device)
|| ausage == AUSAGE_FM_RADIO_CAPTURE
|| ausage == AUSAGE_FM_RADIO_TUNER)
#endif
{
disable_erap_in(aproxy);
disable_spkamp_playback(aproxy);
}
disable_spkamp_reference(aproxy);
#ifdef SUPPORT_BTA2DP_OFFLOAD
} else if (target_device == DEVICE_BT_A2DP_HEADPHONE ||
target_device == DEVICE_SPEAKER_AND_BT_A2DP_HEADPHONE) {
/* Transit BT A2DP Status */
pthread_mutex_lock(&aproxy->a2dp_lock);
// Case : Audio Path reset for A2DP Device
// BT A2DP need to be stoped
bta2dp_playback_stop(aproxy);
pthread_mutex_unlock(&aproxy->a2dp_lock);
// Stop A2DP Mute playback node
disable_a2dp_mute_playback(proxy);
if (target_device == DEVICE_SPEAKER_AND_BT_A2DP_HEADPHONE) {
disable_spkamp_playback(aproxy);
disable_spkamp_reference(aproxy);
disable_erap_in(aproxy);
}
disable_bta2dp_out_loopback(aproxy);
disable_bta2dp_playback(aproxy);
#endif
} else if (target_device == DEVICE_BT_HEADSET || target_device == DEVICE_SPEAKER_AND_BT_HEADSET) {
disable_btsco_playback(aproxy);
if (target_device == DEVICE_SPEAKER_AND_BT_HEADSET) {
disable_spkamp_playback(aproxy);
disable_spkamp_reference(aproxy);
}
disable_erap_in(aproxy);
/* reset Mixp configuration to default values when path is disabled */
reset_playback_modifier(aproxy);
} else if (target_device == DEVICE_HEADSET || target_device == DEVICE_HEADPHONE ||
target_device == DEVICE_CALL_FWD) {
if (is_active_usage_CPCall(aproxy) || is_active_usage_APCall(aproxy) ||
is_usage_Loopback(ausage))
disable_erap_in(aproxy);
} else if (target_device == DEVICE_USB_HEADSET ||
target_device == DEVICE_SPEAKER_AND_USB_HEADSET) {
if (target_device == DEVICE_SPEAKER_AND_USB_HEADSET ||
is_active_usage_CPCall(aproxy) || is_active_usage_APCall(aproxy) ||
is_usage_Loopback(ausage)) {
disable_erap_in(aproxy);
}
if (target_device == DEVICE_SPEAKER_AND_USB_HEADSET) {
disable_spkamp_playback(aproxy);
disable_spkamp_reference(aproxy);
}
disable_usb_out_loopback(aproxy);
if (aproxy->usb_aproxy)
proxy_usb_close_out_proxy(aproxy->usb_aproxy);
/* reset Mixp configuration to default values when path is disabled */
reset_playback_modifier(aproxy);
} else if (is_usb_mic_device(target_device)) {
disable_usb_in_loopback(proxy);
if (aproxy->usb_aproxy)
proxy_usb_close_in_proxy(aproxy->usb_aproxy);
}
return ;
}
// Voice Call PCM Handler
static void voice_rx_stop(struct audio_proxy *aproxy)
{
char pcm_path[MAX_PCM_PATH_LEN];
/* Disables Voice Call RX Playback Stream */
if (aproxy->call_rx) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
VRX_PLAYBACK_CARD, VRX_PLAYBACK_DEVICE, 'p');
pcm_stop(aproxy->call_rx);
pcm_close(aproxy->call_rx);
aproxy->call_rx = NULL;
ALOGI("proxy-%s: Voice Call RX PCM Device(%s) is stopped & closed!", __func__, pcm_path);
}
}
static int voice_rx_start(struct audio_proxy *aproxy)
{
struct pcm_config pcmconfig = pcm_config_voicerx_playback;
char pcm_path[MAX_PCM_PATH_LEN];
/* Enables Voice Call RX Playback Stream */
if (aproxy->call_rx == NULL) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
VRX_PLAYBACK_CARD, VRX_PLAYBACK_DEVICE, 'p');
aproxy->call_rx = pcm_open(VRX_PLAYBACK_CARD, VRX_PLAYBACK_DEVICE,
PCM_OUT | PCM_MONOTONIC, &pcmconfig);
if (aproxy->call_rx && !pcm_is_ready(aproxy->call_rx)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("proxy-%s: Voice Call RX PCM Device(%s) with SR(%u) PF(%d) CC(%d) is not ready as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->call_rx));
goto err_open;
}
ALOGVV("proxy-%s: Voice Call RX PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
if (pcm_start(aproxy->call_rx) == 0) {
ALOGI("proxy-%s: Voice Call RX PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened & started",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
} else {
ALOGE("proxy-%s: Voice Call RX PCM Device(%s) with SR(%u) PF(%d) CC(%d) cannot be started as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->call_rx));
goto err_open;
}
}
return 0;
err_open:
voice_rx_stop(aproxy);
return -1;
}
static void voice_tx_stop(struct audio_proxy *aproxy)
{
char pcm_path[MAX_PCM_PATH_LEN];
/* Disables Voice Call TX Capture Stream */
if (aproxy->call_tx) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
VTX_CAPTURE_CARD, VTX_CAPTURE_DEVICE, 'c');
pcm_stop(aproxy->call_tx);
pcm_close(aproxy->call_tx);
aproxy->call_tx = NULL;
ALOGI("proxy-%s: Voice Call TX PCM Device(%s) is stopped & closed!", __func__, pcm_path);
}
}
static int voice_tx_start(struct audio_proxy *aproxy)
{
struct pcm_config pcmconfig;
char pcm_path[MAX_PCM_PATH_LEN];
/* Enables Voice Call TX Capture Stream */
if (aproxy->call_tx == NULL) {
#ifdef SUPPORT_QUAD_MIC
if (is_quad_mic_device(aproxy->active_capture_device)) {
pcmconfig = pcm_config_quad_mic_voicetx_capture;
ALOGI("proxy-%s: Quad-Mic config for Voice Call TX", __func__);
} else
#endif
pcmconfig = pcm_config_voicetx_capture;
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
VTX_CAPTURE_CARD, VTX_CAPTURE_DEVICE, 'c');
aproxy->call_tx = pcm_open(VTX_CAPTURE_CARD, VTX_CAPTURE_DEVICE,
PCM_IN | PCM_MONOTONIC, &pcmconfig);
if (aproxy->call_tx && !pcm_is_ready(aproxy->call_tx)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("proxy-%s: Voice Call TX PCM Device(%s) with SR(%u) PF(%d) CC(%d) is not ready as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->call_tx));
goto err_open;
}
ALOGVV("proxy-%s: Voice Call TX PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
if (pcm_start(aproxy->call_tx) == 0) {
ALOGI("proxy-%s: Voice Call TX PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened & started",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
} else {
ALOGE("proxy-%s: Voice Call TX PCM Device(%s) with SR(%u) PF(%d) CC(%d) cannot be started as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->call_tx));
goto err_open;
}
}
return 0;
err_open:
voice_tx_stop(aproxy);
return -1;
}
// FM Radio PCM Handler
static void fmradio_playback_stop(struct audio_proxy *aproxy)
{
char pcm_path[MAX_PCM_PATH_LEN];
/* Disables FM Radio Playback Stream */
if (aproxy->fm_playback) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
FMRADIO_PLAYBACK_CARD, FMRADIO_PLAYBACK_DEVICE, 'p');
pcm_stop(aproxy->fm_playback);
pcm_close(aproxy->fm_playback);
aproxy->fm_playback = NULL;
ALOGI("proxy-%s: FM Radio Playback PCM Device(%s) is stopped & closed!", __func__, pcm_path);
}
}
static int fmradio_playback_start(struct audio_proxy *aproxy)
{
struct pcm_config pcmconfig = pcm_config_fmradio_playback;
char pcm_path[MAX_PCM_PATH_LEN];
/* Enables RM Radio Playback Stream */
if (aproxy->fm_playback == NULL) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
FMRADIO_PLAYBACK_CARD, FMRADIO_PLAYBACK_DEVICE, 'p');
aproxy->fm_playback = pcm_open(FMRADIO_PLAYBACK_CARD, FMRADIO_PLAYBACK_DEVICE,
PCM_OUT | PCM_MONOTONIC, &pcmconfig);
if (aproxy->fm_playback && !pcm_is_ready(aproxy->fm_playback)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("proxy-%s: FM Radio Playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is not ready as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->fm_playback));
goto err_open;
}
ALOGVV("proxy-%s: FM Radio Playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
if (pcm_start(aproxy->fm_playback) == 0) {
ALOGI("proxy-%s: FM Radio Playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened & started",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
} else {
ALOGE("proxy-%s: FM Radio Playback PCM Device(%s) with SR(%u) PF(%d) CC(%d) cannot be started as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->fm_playback));
goto err_open;
}
}
return 0;
err_open:
fmradio_playback_stop(aproxy);
return -1;
}
static void fmradio_capture_stop(struct audio_proxy *aproxy)
{
char pcm_path[MAX_PCM_PATH_LEN];
/* Disables FM Radio Capture Stream */
if (aproxy->fm_capture) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
VC_FMRADIO_CAPTURE_CARD, VC_FMRADIO_CAPTURE_DEVICE, 'c');
pcm_stop(aproxy->fm_capture);
pcm_close(aproxy->fm_capture);
aproxy->fm_capture = NULL;
ALOGI("proxy-%s: FM Radio Capture PCM Device(%s) is stopped & closed!", __func__, pcm_path);
}
}
static int fmradio_capture_start(struct audio_proxy *aproxy)
{
struct pcm_config pcmconfig = pcm_config_vc_fmradio_capture;
char pcm_path[MAX_PCM_PATH_LEN];
/* Enables RM Radio Capture Stream */
if (aproxy->fm_capture == NULL) {
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c",
VC_FMRADIO_CAPTURE_CARD, VC_FMRADIO_CAPTURE_DEVICE, 'c');
aproxy->fm_capture = pcm_open(VC_FMRADIO_CAPTURE_CARD, VC_FMRADIO_CAPTURE_DEVICE,
PCM_IN | PCM_MONOTONIC, &pcmconfig);
if (aproxy->fm_capture && !pcm_is_ready(aproxy->fm_capture)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("proxy-%s: FM Radio Capture PCM Device(%s) with SR(%u) PF(%d) CC(%d) is not ready as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->fm_capture));
goto err_open;
}
ALOGVV("proxy-%s: FM Radio Capture PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
if (pcm_start(aproxy->fm_capture) == 0) {
ALOGI("proxy-%s: FM Radio Capture PCM Device(%s) with SR(%u) PF(%d) CC(%d) is opened & started",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels);
} else {
ALOGE("proxy-%s: FM Radio Capture PCM Device(%s) with SR(%u) PF(%d) CC(%d) cannot be started as error(%s)",
__func__, pcm_path, pcmconfig.rate, pcmconfig.format, pcmconfig.channels,
pcm_get_error(aproxy->fm_capture));
goto err_open;
}
}
return 0;
err_open:
fmradio_capture_stop(aproxy);
return -1;
}
struct mixer {
int fd;
struct snd_ctl_card_info card_info;
struct snd_ctl_elem_info *elem_info;
struct mixer_ctl *ctl;
unsigned int count;
};
static struct snd_ctl_event *mixer_read_event_sec(struct mixer *mixer, unsigned int mask)
{
struct snd_ctl_event *ev;
if (!mixer)
return 0;
ev = calloc(1, sizeof(*ev));
if (!ev)
return 0;
while (read(mixer->fd, ev, sizeof(*ev)) > 0) {
if (ev->type != SNDRV_CTL_EVENT_ELEM)
continue;
if (!(ev->data.elem.mask & mask))
continue;
return ev;
}
free(ev);
return 0;
}
static int audio_route_missing_ctl(struct audio_route *ar) {
return 0;
}
/* Mask for mixer_read_event()
* It should be same with SNDRV_CTL_EVENT_MASK_* in asound.h.
*/
#define MIXER_EVENT_VALUE (1 << 0)
#define MIXER_EVENT_INFO (1 << 1)
#define MIXER_EVENT_ADD (1 << 2)
#define MIXER_EVENT_TLV (1 << 3)
#define MIXER_EVENT_REMOVE (~0U)
static void *mixer_update_loop(void *context)
{
struct audio_proxy *aproxy = (struct audio_proxy *)context;
struct snd_ctl_event *event = NULL;
struct timespec ts_start, ts_tick;
ALOGI("proxy-%s: started running Mixer Updater Thread", __func__);
clock_gettime(CLOCK_MONOTONIC, &ts_start);
do {
if (aproxy->mixer) {
ALOGD("proxy-%s: wait add event", __func__);
event = mixer_read_event_sec(aproxy->mixer, MIXER_EVENT_ADD);
if (!event) {
ALOGE("proxy-%s: returned as error or mixer close", __func__);
clock_gettime(CLOCK_MONOTONIC, &ts_tick);
if ((ts_tick.tv_sec - ts_start.tv_sec) > MIXER_UPDATE_TIMEOUT) {
ALOGI("proxy-%s: Mixer Update Timeout, it will be destroyed", __func__);
break;
}
continue;
}
ALOGD("proxy-%s: returned as add event", __func__);
} else
continue;
pthread_rwlock_wrlock(&aproxy->mixer_update_lock);
mixer_close(aproxy->mixer);
aproxy->mixer = mixer_open(MIXER_CARD0);
if (!aproxy->mixer)
ALOGE("proxy-%s: failed to re-open Mixer", __func__);
mixer_subscribe_events(aproxy->mixer, 1);
audio_route_free(aproxy->aroute);
aproxy->aroute = audio_route_init(MIXER_CARD0, aproxy->xml_path);
if (!aproxy->aroute)
ALOGE("proxy-%s: failed to re-init audio route", __func__);
ALOGI("proxy-%s: mixer and route are updated", __func__);
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
free(event);
} while (aproxy->mixer && aproxy->aroute && audio_route_missing_ctl(aproxy->aroute));
ALOGI("proxy-%s: all mixer controls are found", __func__);
if (aproxy->mixer)
mixer_subscribe_events(aproxy->mixer, 0);
ALOGI("proxy-%s: stopped running Mixer Updater Thread", __func__);
return NULL;
}
static void make_path(audio_usage ausage, device_type device, char *path_name)
{
memset(path_name, 0, MAX_PATH_NAME_LEN);
strlcpy(path_name, usage_path_table[ausage], MAX_PATH_NAME_LEN);
if (strlen(device_table[device]) > 0) {
strlcat(path_name, "-", MAX_PATH_NAME_LEN);
strlcat(path_name, device_table[device], MAX_PATH_NAME_LEN);
}
return ;
}
static void make_gain(char *path_name, char *gain_name)
{
memset(gain_name, 0, MAX_GAIN_PATH_NAME_LEN);
strlcpy(gain_name, "gain-", MAX_PATH_NAME_LEN);
strlcat(gain_name, path_name, MAX_PATH_NAME_LEN);
return ;
}
static void add_dual_path(void *proxy, char *path_name)
{
struct audio_proxy *aproxy = proxy;
if (aproxy->support_dualspk) {
char tempStr[MAX_PATH_NAME_LEN] = {0};
char* szDump;
szDump = strstr(path_name, "speaker");
// do not add dual- path for loopback
if (strstr(path_name, "loopback")) {
return ;
}
if (szDump != NULL) {
char tempRet[MAX_PATH_NAME_LEN] = {0};
strncpy(tempStr, path_name, szDump - path_name);
sprintf(tempRet, "%s%s%s", tempStr, "dual-", szDump);
strncpy(path_name, tempRet, MAX_PATH_NAME_LEN);
}
}
}
/* Enable new Audio Path */
static void set_route(void *proxy, audio_usage ausage, device_type device)
{
struct audio_proxy *aproxy = proxy;
char path_name[MAX_PATH_NAME_LEN];
char gain_name[MAX_GAIN_PATH_NAME_LEN];
if (device == DEVICE_AUX_DIGITAL)
return ;
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
make_path(ausage, device, path_name);
add_dual_path(aproxy, path_name);
audio_route_apply_and_update_path(aproxy->aroute, path_name);
ALOGI("proxy-%s: routed to %s", __func__, path_name);
make_gain(path_name, gain_name);
audio_route_apply_and_update_path(aproxy->aroute, gain_name);
ALOGI("proxy-%s: set gain as %s", __func__, gain_name);
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ;
}
/* reroute Audio Path */
static void set_reroute(void *proxy, audio_usage old_ausage, device_type old_device,
audio_usage new_ausage, device_type new_device)
{
struct audio_proxy *aproxy = proxy;
char path_name[MAX_PATH_NAME_LEN];
char gain_name[MAX_GAIN_PATH_NAME_LEN];
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
// 1. Unset Active Route
make_path(old_ausage, old_device, path_name);
add_dual_path(aproxy, path_name);
/* Updated to reset_and_update to match Q audio-route changes
* otherwise noise issue happened in alarm/ringtone scenarios
*/
audio_route_reset_and_update_path(aproxy->aroute, path_name);
ALOGI("proxy-%s: unrouted %s", __func__, path_name);
make_gain(path_name, gain_name);
audio_route_reset_and_update_path(aproxy->aroute, gain_name);
ALOGI("proxy-%s: reset gain %s", __func__, gain_name);
// 2. Set New Route
if (new_device != DEVICE_AUX_DIGITAL) {
make_path(new_ausage, new_device, path_name);
add_dual_path(aproxy, path_name);
audio_route_apply_and_update_path(aproxy->aroute, path_name);
ALOGI("proxy-%s: routed %s", __func__, path_name);
make_gain(path_name, gain_name);
audio_route_apply_and_update_path(aproxy->aroute, gain_name);
ALOGI("proxy-%s: set gain as %s", __func__, gain_name);
}
// 3. Update Mixers
audio_route_update_mixer(aproxy->aroute);
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ;
}
/* Disable Audio Path */
static void reset_route(void *proxy, audio_usage ausage, device_type device)
{
struct audio_proxy *aproxy = proxy;
char path_name[MAX_PATH_NAME_LEN];
char gain_name[MAX_GAIN_PATH_NAME_LEN];
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
make_path(ausage, device, path_name);
add_dual_path(aproxy, path_name);
audio_route_reset_and_update_path(aproxy->aroute, path_name);
ALOGI("proxy-%s: unrouted %s", __func__, path_name);
make_gain(path_name, gain_name);
audio_route_reset_and_update_path(aproxy->aroute, gain_name);
ALOGI("proxy-%s: reset gain %s", __func__, gain_name);
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ;
}
/* Enable new Modifier */
static void set_modifier(void *proxy, modifier_type modifier)
{
struct audio_proxy *aproxy = proxy;
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
audio_route_apply_and_update_path(aproxy->aroute, modifier_table[modifier]);
ALOGI("proxy-%s: enabled to %s", __func__, modifier_table[modifier]);
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ;
}
/* Update Modifier */
static void update_modifier(void *proxy, modifier_type old_modifier, modifier_type new_modifier)
{
struct audio_proxy *aproxy = proxy;
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
// 1. Unset Active Modifier
audio_route_reset_path(aproxy->aroute, modifier_table[old_modifier]);
ALOGI("proxy-%s: disabled %s", __func__, modifier_table[old_modifier]);
// 2. Set New Modifier
audio_route_apply_path(aproxy->aroute, modifier_table[new_modifier]);
ALOGI("proxy-%s: enabled %s", __func__, modifier_table[new_modifier]);
// 3. Update Mixers
audio_route_update_mixer(aproxy->aroute);
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ;
}
/* Disable Modifier */
static void reset_modifier(void *proxy, modifier_type modifier)
{
struct audio_proxy *aproxy = proxy;
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
audio_route_reset_and_update_path(aproxy->aroute, modifier_table[modifier]);
ALOGI("proxy-%s: disabled %s", __func__, modifier_table[modifier]);
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ;
}
static void do_operations_by_playback_route_set(struct audio_proxy *aproxy,
audio_usage routed_ausage, device_type routed_device)
{
/* skip internal pcm controls */
if (aproxy->skip_internalpath) {
ALOGI("proxy-%s: skip internal path pcm controls", __func__);
return;
}
/* Open/Close FM Radio PCM node based on Enable/disable */
if (routed_ausage != AUSAGE_FM_RADIO_CAPTURE && routed_ausage != AUSAGE_FM_RADIO_TUNER) {
fmradio_playback_stop(aproxy);
fmradio_capture_stop(aproxy);
}
/* Set Mute during APCall Path Change */
if ((aproxy->active_playback_device != routed_device) &&
(is_active_usage_APCall(aproxy) || is_usage_APCall(routed_ausage)))
proxy_set_mixercontrol(aproxy, MUTE_CONTROL, ABOX_MUTE_CNT_FOR_PATH_CHANGE);
return ;
}
static void do_operations_by_playback_route_reset(struct audio_proxy *aproxy __unused)
{
return ;
}
/*
* Dump functions
*/
static void calliope_cleanup_old(const char *path, const char *prefix)
{
struct dirent **namelist;
int n, match = 0;
ALOGV("proxy-%s", __func__);
n = scandir(path, &namelist, NULL, alphasort);
if (n > 0) {
/* interate in reverse order to get old file */
while (n--) {
if (strstr(namelist[n]->d_name, prefix) == namelist[n]->d_name) {
if (++match > ABOX_DUMP_LIMIT) {
char *tgt;
if (asprintf(&tgt, "%s/%s", path, namelist[n]->d_name) != -1) {
remove(tgt);
free(tgt);
}
}
}
free(namelist[n]);
}
free(namelist);
}
return ;
}
static void __calliope_dump(int fd, const char *in_prefix, const char *in_file, const char *out_prefix, const char *out_suffix)
{
static const int buf_size = 4096;
char *buf, in_path[128], out_path[128];
int fd_in = -1, fd_out = -1, n;
mode_t mask;
ALOGV("proxy-%s", __func__);
if (snprintf(in_path, sizeof(in_path) - 1, "%s%s", in_prefix, in_file) < 0) {
ALOGE("proxy-%s: in path error: %s", __func__, strerror(errno));
return;
}
if (snprintf(out_path, sizeof(out_path) - 1, "%s%s_%s.bin", out_prefix, in_file, out_suffix) < 0) {
ALOGE("proxy-%s: out path error: %s", __func__, strerror(errno));
return;
}
buf = malloc(buf_size);
if (!buf) {
ALOGE("proxy-%s: malloc failed: %s", __func__, strerror(errno));
return;
}
mask = umask(0);
ALOGV("umask = %o", mask);
fd_in = open(in_path, O_RDONLY | O_NONBLOCK);
if (fd_in < 0)
ALOGE("proxy-%s: open error: %s, fd_in=%s", __func__, strerror(errno), in_path);
fd_out = open(out_path, O_CREAT | O_WRONLY, S_IRUSR | S_IWUSR | S_IRGRP | S_IWGRP | S_IROTH);
if (fd_out < 0)
ALOGE("proxy-%s: open error: %s, fd_out=%s", __func__, strerror(errno), out_path);
if (fd_in >= 0 && fd_out >= 0) {
while((n = read(fd_in, buf, buf_size)) > 0) {
if (write(fd_out, buf, n) < 0) {
ALOGE("proxy-%s: write error: %s", __func__, strerror(errno));
}
}
n = snprintf(buf, buf_size, " %s_%s.bin <= %s\n", in_file, out_suffix, in_file);
write(fd, buf, n);
ALOGI("proxy-%s", buf);
}
calliope_cleanup_old(out_prefix, in_file);
if (fd_in >= 0)
close(fd_in);
if (fd_out >= 0)
close(fd_out);
mask = umask(mask);
free(buf);
return ;
}
static void calliope_ramdump(int fd)
{
char str_time[32];
time_t t;
struct tm *lt;
ALOGD("%s", __func__);
t = time(NULL);
lt = localtime(&t);
if (lt == NULL) {
ALOGE("%s: time conversion error: %s", __func__, strerror(errno));
return;
}
if (strftime(str_time, sizeof(str_time), "%Y%m%d_%H%M%S", lt) == 0) {
ALOGE("%s: time error: %s", __func__, strerror(errno));
}
write(fd, "\n", strlen("\n"));
write(fd, "Calliope snapshot:\n", strlen("Calliope snapshot:\n"));
ALOGI("Calliope snapshot:\n");
__calliope_dump(fd, SYSFS_PREFIX ABOX_DEV ABOX_DEBUG, ABOX_GPR, ABOX_DUMP, str_time);
__calliope_dump(fd, CALLIOPE_DBG_PATH, CALLIOPE_LOG, ABOX_DUMP, str_time);
__calliope_dump(fd, SYSFS_PREFIX ABOX_DEV ABOX_DEBUG, ABOX_SRAM, ABOX_DUMP, str_time);
__calliope_dump(fd, SYSFS_PREFIX ABOX_DEV ABOX_DEBUG, ABOX_DRAM, ABOX_DUMP, str_time);
__calliope_dump(fd, ABOX_REGMAP_PATH, ABOX_REG_FILE, ABOX_DUMP, str_time);
write(fd, "Calliope snapshot done\n", strlen("Calliope snapshot done\n"));
return ;
}
/******************************************************************************/
/** **/
/** Local Functions for Audio Stream Proxy **/
/** **/
/******************************************************************************/
/* Compress Offload Specific Functions */
static bool is_supported_compressed_format(audio_format_t format)
{
switch (format & AUDIO_FORMAT_MAIN_MASK) {
case AUDIO_FORMAT_MP3:
case AUDIO_FORMAT_AAC:
case AUDIO_FORMAT_FLAC:
return true;
default:
break;
}
return false;
}
static int get_snd_codec_id(audio_format_t format)
{
int id = 0;
switch (format & AUDIO_FORMAT_MAIN_MASK) {
case AUDIO_FORMAT_MP3:
id = SND_AUDIOCODEC_MP3;
break;
case AUDIO_FORMAT_AAC:
id = SND_AUDIOCODEC_AAC;
break;
case AUDIO_FORMAT_FLAC:
id = SND_AUDIOCODEC_FLAC;
break;
default:
ALOGE("offload_out-%s: Unsupported audio format", __func__);
}
return id;
}
static int check_direct_config_support(struct audio_proxy_stream *apstream)
{
int i;
int ret = 0;
// Check Sampling Rate
for (i = 0; i < MAX_NUM_PLAYBACK_SR; i++) {
if (apstream->requested_sample_rate == supported_playback_samplingrate[i]) {
if (apstream->requested_sample_rate != apstream->pcmconfig.rate) {
apstream->pcmconfig.rate = apstream->requested_sample_rate;
}
apstream->pcmconfig.period_size = (apstream->pcmconfig.rate * PREDEFINED_USB_PLAYBACK_DURATION) / 1000;
// DMA in A-Box is 128-bit aligned, so period_size has to be multiple of 4 frames
apstream->pcmconfig.period_size &= 0xFFFFFFFC;
ALOGD("%s-%s: updates samplig rate to %u, period_size to %u", stream_table[apstream->stream_type],
__func__, apstream->pcmconfig.rate,
apstream->pcmconfig.period_size);
break;
}
}
if (i == MAX_NUM_PLAYBACK_SR) {
ALOGD("%s-%s: unsupported samplerate to %u", stream_table[apstream->stream_type], __func__,
apstream->requested_sample_rate);
ret = -EINVAL;
goto err;
}
// Check Channel Mask
for (i = 0; i < MAX_NUM_DIRECT_PLAYBACK_CM; i++) {
if (apstream->requested_channel_mask == supported_direct_playback_channelmask[i]) {
if (audio_channel_count_from_out_mask(apstream->requested_channel_mask)
!= apstream->pcmconfig.channels) {
if (apstream->requested_channel_mask == AUDIO_CHANNEL_OUT_5POINT1) {
ALOGD("%s-%s: channel padding needed from 6 Channels to %u channels",
stream_table[apstream->stream_type], __func__,
apstream->pcmconfig.channels);
/* A-Box HW doesn't 6 channels therefore 2 channel padding is required */
apstream->need_channelpadding = true;
} else {
apstream->pcmconfig.channels =
audio_channel_count_from_out_mask(apstream->requested_channel_mask);
ALOGD("%s-%s: channel count updated to %u",
stream_table[apstream->stream_type], __func__,
apstream->pcmconfig.channels);
}
}
ALOGD("%s-%s: requested channel mask %u configured channels %d ",
stream_table[apstream->stream_type], __func__,
audio_channel_count_from_out_mask(apstream->requested_channel_mask),
apstream->pcmconfig.channels);
break;
}
}
if (i == MAX_NUM_DIRECT_PLAYBACK_CM) {
ALOGD("%s-%s: unsupported channel mask %u ", stream_table[apstream->stream_type],
__func__, audio_channel_count_from_out_mask(apstream->requested_channel_mask));
ret = -EINVAL;
}
// Check PCM Format
for (i = 0; i < MAX_NUM_PLAYBACK_PF; i++) {
if (apstream->requested_format == supported_playback_pcmformat[i]) {
if (pcm_format_from_audio_format(apstream->requested_format) !=
apstream->pcmconfig.format) {
apstream->pcmconfig.format =
pcm_format_from_audio_format(apstream->requested_format);
ALOGD("%s-%s: updates PCM format to %d", stream_table[apstream->stream_type],
__func__, apstream->pcmconfig.format);
}
break;
}
}
if (i == MAX_NUM_PLAYBACK_PF) {
ALOGD("%s-%s: unsupported format 0x%x", stream_table[apstream->stream_type],
__func__, apstream->requested_format);
ret = -EINVAL;
goto err;
}
err:
return ret;
}
static void save_written_frames(struct audio_proxy_stream *apstream, int bytes)
{
apstream->frames += bytes / (apstream->pcmconfig.channels *
audio_bytes_per_sample(audio_format_from_pcm_format(apstream->pcmconfig.format)));
ALOGVV("%s-%s: written = %u frames", stream_table[apstream->stream_type], __func__,
(unsigned int)apstream->frames);
return ;
}
static void skip_pcm_processing(struct audio_proxy_stream *apstream, int bytes)
{
unsigned int frames = 0;
frames = bytes / (apstream->pcmconfig.channels *
audio_bytes_per_sample(audio_format_from_pcm_format(apstream->pcmconfig.format)));
usleep(frames * 1000000 / proxy_get_actual_sampling_rate(apstream));
return ;
}
static void update_capture_pcmconfig(struct audio_proxy_stream *apstream)
{
#ifdef SUPPORT_QUAD_MIC
struct audio_proxy *aproxy = getInstance();
#endif
int i;
// Check Sampling Rate
for (i = 0; i < MAX_NUM_CAPTURE_SR; i++) {
if (apstream->requested_sample_rate == supported_capture_samplingrate[i]) {
if (apstream->requested_sample_rate != apstream->pcmconfig.rate) {
apstream->pcmconfig.rate = apstream->requested_sample_rate;
if (apstream->stream_type == ASTREAM_CAPTURE_PRIMARY)
apstream->pcmconfig.period_size = (apstream->pcmconfig.rate * PREDEFINED_MEDIA_CAPTURE_DURATION) / 1000;
else if (apstream->stream_type == ASTREAM_CAPTURE_LOW_LATENCY)
apstream->pcmconfig.period_size = (apstream->pcmconfig.rate * PREDEFINED_LOW_CAPTURE_DURATION) / 1000;
// WDMA in A-Box is 128-bit aligned, so period_size has to be multiple of 4 frames
apstream->pcmconfig.period_size &= 0xFFFFFFFC;
ALOGD("%s-%s: updates samplig rate to %u, period_size to %u", stream_table[apstream->stream_type],
__func__, apstream->pcmconfig.rate,
apstream->pcmconfig.period_size);
}
break;
}
}
if (i == MAX_NUM_CAPTURE_SR)
ALOGD("%s-%s: needs re-sampling to %u", stream_table[apstream->stream_type], __func__,
apstream->requested_sample_rate);
// Check Channel Mask
for (i = 0; i < MAX_NUM_CAPTURE_CM; i++) {
if (apstream->requested_channel_mask == supported_capture_channelmask[i]) {
if (audio_channel_count_from_in_mask(apstream->requested_channel_mask)
!= apstream->pcmconfig.channels) {
#ifdef SUPPORT_QUAD_MIC
if ((is_active_usage_CPCall(aproxy) || is_active_usage_APCall(aproxy)
|| apstream->stream_usage == AUSAGE_CAMCORDER)
&& is_quad_mic_device(aproxy->active_capture_device)) {
ALOGD("%s-%s: Skip channel count updating to %u", stream_table[apstream->stream_type],
__func__, apstream->pcmconfig.channels);
} else
#endif
{
apstream->pcmconfig.channels = audio_channel_count_from_in_mask(apstream->requested_channel_mask);
ALOGD("%s-%s: updates channel count to %u", stream_table[apstream->stream_type],
__func__, apstream->pcmconfig.channels);
}
}
break;
}
}
if (i == MAX_NUM_CAPTURE_CM)
ALOGD("%s-%s: needs re-channeling to %u from %u", stream_table[apstream->stream_type], __func__,
audio_channel_count_from_in_mask(apstream->requested_channel_mask), apstream->pcmconfig.channels);
// Check PCM Format
for (i = 0; i < MAX_NUM_CAPTURE_PF; i++) {
if (apstream->requested_format == supported_capture_pcmformat[i]) {
if (pcm_format_from_audio_format(apstream->requested_format) != apstream->pcmconfig.format) {
apstream->pcmconfig.format = pcm_format_from_audio_format(apstream->requested_format);
ALOGD("%s-%s: updates PCM format to %d", stream_table[apstream->stream_type], __func__,
apstream->pcmconfig.format);
}
break;
}
}
if (i == MAX_NUM_CAPTURE_PF)
ALOGD("%s-%s: needs re-formating to 0x%x", stream_table[apstream->stream_type], __func__,
apstream->requested_format);
return ;
}
// For Resampler
int proxy_get_requested_frame_size(struct audio_proxy_stream *apstream)
{
return audio_channel_count_from_in_mask(apstream->requested_channel_mask) *
audio_bytes_per_sample(apstream->requested_format);
}
static int get_next_buffer(struct resampler_buffer_provider *buffer_provider,
struct resampler_buffer* buffer)
{
struct audio_proxy_stream *apstream;
if (buffer_provider == NULL || buffer == NULL)
return -EINVAL;
apstream = (struct audio_proxy_stream *)((char *)buffer_provider -
offsetof(struct audio_proxy_stream, buf_provider));
if (apstream->pcm) {
if (apstream->read_buf_frames == 0) {
unsigned int size_in_bytes = pcm_frames_to_bytes(apstream->pcm, apstream->pcmconfig.period_size);
if (apstream->actual_read_buf_size < size_in_bytes) {
apstream->actual_read_buf_size = size_in_bytes;
apstream->actual_read_buf = (int16_t *) realloc(apstream->actual_read_buf, size_in_bytes);
if (apstream->actual_read_buf != NULL)
ALOGI("%s-%s: alloc actual read buffer with %u bytes",
stream_table[apstream->stream_type], __func__, size_in_bytes);
}
if (apstream->actual_read_buf != NULL) {
apstream->actual_read_status = pcm_read(apstream->pcm, (void*)apstream->actual_read_buf, size_in_bytes);
if (apstream->actual_read_status != 0) {
ALOGE("%s-%s: pcm_read error %d(%s)", stream_table[apstream->stream_type],
__func__, apstream->actual_read_status, pcm_get_error(apstream->pcm));
buffer->raw = NULL;
buffer->frame_count = 0;
return apstream->actual_read_status;
}
if (apstream->stream_type == ASTREAM_CAPTURE_CALL) {
/*
* [Call Recording Case]
* In case of Call Recording, A-Box sends stereo stream which uplink/downlink voice
* allocated in left/right to AudioHAL.
* AudioHAL has to select and mix uplink/downlink voice from left/right channel as usage.
*/
int16_t data_mono;
int16_t *vc_buf = (int16_t *)(apstream->actual_read_buf);
// Channel Selection
// output : Stereo with Left/Right contains same selected channel PCM & Device SR
for (unsigned int i = 0; i < apstream->pcmconfig.period_size; i++){
if (apstream->stream_usage == AUSAGE_INCALL_UPLINK)
data_mono = (*(vc_buf + 2*i + 1)); // Tx
else if (apstream->stream_usage == AUSAGE_INCALL_DOWNLINK){
data_mono = (*(vc_buf + 2*i)); // Rx
} else {
data_mono = clamp16(((int32_t)*(vc_buf+2*i) + (int32_t)*(vc_buf+2*i+1))*0.7); // mix Rx/Tx
}
*(vc_buf + 2*i) = data_mono;
*(vc_buf + 2*i + 1) = data_mono;
}
}
/* Convert A-Box's zero padded 24bit format to signed extension */
if (apstream->pcmconfig.format == PCM_FORMAT_S24_LE) {
int *rd_buf = (int *)(apstream->actual_read_buf);
for (unsigned int i = 0;
i < (apstream->pcmconfig.period_size * apstream->pcmconfig.channels); i++) {
if (*(rd_buf + i) & 0x800000)
*(rd_buf + i) |= 0xFF000000;
}
}
apstream->read_buf_frames = apstream->pcmconfig.period_size;
} else {
ALOGE("%s-%s: failed to reallocate actual_read_buf",
stream_table[apstream->stream_type], __func__);
buffer->raw = NULL;
buffer->frame_count = 0;
apstream->actual_read_status = -ENOMEM;
return -ENOMEM;
}
}
buffer->frame_count = (buffer->frame_count > apstream->read_buf_frames) ?
apstream->read_buf_frames : buffer->frame_count;
buffer->i16 = apstream->actual_read_buf + (apstream->pcmconfig.period_size - apstream->read_buf_frames) *
apstream->pcmconfig.channels;
return apstream->actual_read_status;
} else {
buffer->raw = NULL;
buffer->frame_count = 0;
apstream->actual_read_status = -ENODEV;
return -ENODEV;
}
}
static void release_buffer(struct resampler_buffer_provider *buffer_provider,
struct resampler_buffer* buffer)
{
struct audio_proxy_stream *apstream;
if (buffer_provider == NULL || buffer == NULL)
return;
apstream = (struct audio_proxy_stream *)((char *)buffer_provider -
offsetof(struct audio_proxy_stream, buf_provider));
apstream->read_buf_frames -= buffer->frame_count;
}
static int read_frames(struct audio_proxy_stream *apstream, void *buffer, int frames)
{
int frames_wr = 0;
while (frames_wr < frames) {
size_t frames_rd = frames - frames_wr;
ALOGVV("%s-%s: frames_rd: %zd, frames_wr: %d",
stream_table[apstream->stream_type], __func__, frames_rd, frames_wr);
if (apstream->resampler != NULL) {
apstream->resampler->resample_from_provider(apstream->resampler,
(int16_t *)((char *)buffer + pcm_frames_to_bytes(apstream->pcm, frames_wr)), &frames_rd);
} else {
struct resampler_buffer buf;
buf.raw= NULL;
buf.frame_count = frames_rd;
get_next_buffer(&apstream->buf_provider, &buf);
if (buf.raw != NULL) {
memcpy((char *)buffer + pcm_frames_to_bytes(apstream->pcm, frames_wr),
buf.raw, pcm_frames_to_bytes(apstream->pcm, buf.frame_count));
frames_rd = buf.frame_count;
}
release_buffer(&apstream->buf_provider, &buf);
}
/* apstream->actual_read_status is updated by getNextBuffer() also called by
* apstream->resampler->resample_from_provider() */
if (apstream->actual_read_status != 0)
return apstream->actual_read_status;
frames_wr += frames_rd;
}
return frames_wr;
}
static int read_and_process_frames(struct audio_proxy_stream *apstream, void* buffer, int frames_num)
{
int frames_wr = 0;
unsigned int bytes_per_sample = (pcm_format_to_bits(apstream->pcmconfig.format) >> 3);
void *proc_buf_out = buffer;
int num_device_channels = proxy_get_actual_channel_count(apstream);
int num_req_channels = audio_channel_count_from_in_mask(apstream->requested_channel_mask);
/* Prepare Channel Conversion Input Buffer */
if (apstream->need_channelconversion && (num_device_channels != num_req_channels)) {
int src_buffer_size = frames_num * num_device_channels * bytes_per_sample;
if (apstream->proc_buf_size < src_buffer_size) {
apstream->proc_buf_size = src_buffer_size;
apstream->proc_buf_out = realloc(apstream->proc_buf_out, src_buffer_size);
ALOGI("%s-%s: alloc resampled read buffer with %d bytes",
stream_table[apstream->stream_type], __func__, src_buffer_size);
}
proc_buf_out = apstream->proc_buf_out;
}
frames_wr = read_frames(apstream, proc_buf_out, frames_num);
if ((frames_wr > 0) && (frames_wr > frames_num))
ALOGE("%s-%s: read more frames than requested", stream_table[apstream->stream_type], __func__);
/*
* A-Box can support only Stereo channel, not Mono channel.
* If platform wants Mono Channel Recording, AudioHAL has to support mono conversion.
*/
if (apstream->actual_read_status == 0) {
if (apstream->need_channelconversion && (num_device_channels != num_req_channels)) {
size_t ret = adjust_channels(proc_buf_out, num_device_channels,
buffer, num_req_channels,
bytes_per_sample, (frames_wr * num_device_channels * bytes_per_sample));
if (ret != (frames_wr * num_req_channels * bytes_per_sample))
ALOGE("%s-%s: channel convert failed", stream_table[apstream->stream_type], __func__);
}
} else {
ALOGE("%s-%s: Read Fail = %d", stream_table[apstream->stream_type], __func__, frames_wr);
}
return frames_wr;
}
static void check_conversion(struct audio_proxy_stream *apstream)
{
int request_cc = audio_channel_count_from_in_mask(apstream->requested_channel_mask);
// Check Mono Conversion is needed or not
if ((request_cc == MEDIA_1_CHANNEL && apstream->pcmconfig.channels == DEFAULT_MEDIA_CHANNELS)
#ifdef SUPPORT_QUAD_MIC
|| ((request_cc == DEFAULT_MEDIA_CHANNELS || request_cc == MEDIA_1_CHANNEL)
&& apstream->pcmconfig.channels == MEDIA_4_CHANNELS)
#endif
) {
// enable channel Conversion
apstream->need_channelconversion = true;
ALOGD("%s-%s: needs re-channeling to %u from %u", stream_table[apstream->stream_type], __func__,
request_cc, apstream->pcmconfig.channels);
}
// Check Re-Sampler is needed or not
if (apstream->requested_sample_rate &&
apstream->requested_sample_rate != apstream->pcmconfig.rate) {
// Only support Stereo Resampling
if (apstream->resampler) {
release_resampler(apstream->resampler);
apstream->resampler = NULL;
}
apstream->buf_provider.get_next_buffer = get_next_buffer;
apstream->buf_provider.release_buffer = release_buffer;
int ret = create_resampler(apstream->pcmconfig.rate, apstream->requested_sample_rate,
apstream->pcmconfig.channels, RESAMPLER_QUALITY_DEFAULT,
&apstream->buf_provider, &apstream->resampler);
if (ret !=0) {
ALOGE("proxy-%s: failed to create resampler", __func__);
} else {
ALOGV("proxy-%s: resampler created in-samplerate %d out-samplereate %d",
__func__, apstream->pcmconfig.rate, apstream->requested_sample_rate);
apstream->need_resampling = true;
ALOGD("%s-%s: needs re-sampling to %u Hz from %u Hz", stream_table[apstream->stream_type], __func__,
apstream->requested_sample_rate, apstream->pcmconfig.rate);
apstream->actual_read_buf = NULL;
apstream->actual_read_buf_size = 0;
apstream->read_buf_frames = 0;
apstream->resampler->reset(apstream->resampler);
}
}
return ;
}
/*
* Modify config->period_count based on min_size_frames
*/
static void adjust_mmap_period_count(struct audio_proxy_stream *apstream, struct pcm_config *config,
int32_t min_size_frames)
{
int periodCountRequested = (min_size_frames + config->period_size - 1)
/ config->period_size;
int periodCount = MMAP_PERIOD_COUNT_MIN;
ALOGV("%s-%s: original config.period_size = %d config.period_count = %d",
stream_table[apstream->stream_type], __func__, config->period_size, config->period_count);
while (periodCount < periodCountRequested && (periodCount * 2) < MMAP_PERIOD_COUNT_MAX) {
periodCount *= 2;
}
config->period_count = periodCount;
ALOGV("%s-%s: requested config.period_count = %d", stream_table[apstream->stream_type], __func__,
config->period_count);
}
int get_mmap_data_fd(void *proxy_stream, audio_usage_type usage_type,
int *fd, unsigned int *size)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
struct snd_pcm_mmap_fd mmapfd_info;
char dev_name[128];
int hw_fd = -1;
int ret = 0;
int hwdev_node = -1;
memset(&mmapfd_info, 0, sizeof(mmapfd_info));
mmapfd_info.dir = usage_type;
// get MMAP device node number based on usage direction
hwdev_node = ((usage_type == AUSAGE_PLAYBACK) ? MMAP_PLAYBACK_DEVICE :
MMAP_CAPTURE_DEVICE);
snprintf(dev_name, sizeof(dev_name), "/dev/snd/hwC0D%d", hwdev_node);
hw_fd = open(dev_name, O_RDONLY);
if (hw_fd < 0) {
ALOGE("%s: hw %s node open failed", __func__, dev_name);
ret = -1;
goto err;
}
// get mmap fd for exclusive mode
if (ioctl(hw_fd, SNDRV_PCM_IOCTL_MMAP_DATA_FD, &mmapfd_info) < 0) {
ALOGE("%s-%s: get MMAP FD IOCTL failed",
stream_table[apstream->stream_type], __func__);
ret = -1;
goto err;
}
*fd = mmapfd_info.fd;
*size = mmapfd_info.size;
err:
if (hw_fd >= 0)
close(hw_fd);
return ret;
}
/******************************************************************************/
/** **/
/** Interfaces for Audio Stream Proxy **/
/** **/
/******************************************************************************/
uint32_t proxy_get_actual_channel_count(void *proxy_stream)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
uint32_t actual_channel_count = 0;
if (apstream) {
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD)
actual_channel_count = (uint32_t)audio_channel_count_from_out_mask(apstream->comprconfig.codec->ch_in);
else
actual_channel_count = (uint32_t)apstream->pcmconfig.channels;
}
return actual_channel_count;
}
uint32_t proxy_get_actual_sampling_rate(void *proxy_stream)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
uint32_t actual_sampling_rate = 0;
if (apstream) {
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD)
actual_sampling_rate = (uint32_t)apstream->comprconfig.codec->sample_rate;
else
actual_sampling_rate = (uint32_t)apstream->pcmconfig.rate;
}
return actual_sampling_rate;
}
uint32_t proxy_get_actual_period_size(void *proxy_stream)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
uint32_t actual_period_size = 0;
if (apstream) {
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD)
actual_period_size = (uint32_t)apstream->comprconfig.fragment_size;
else
actual_period_size = (uint32_t)apstream->pcmconfig.period_size;
}
return actual_period_size;
}
uint32_t proxy_get_actual_period_count(void *proxy_stream)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
uint32_t actual_period_count = 0;
if (apstream) {
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD)
actual_period_count = (uint32_t)apstream->comprconfig.fragments;
else
actual_period_count = (uint32_t)apstream->pcmconfig.period_count;
}
return actual_period_count;
}
int32_t proxy_get_actual_format(void *proxy_stream)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
int32_t actual_format = (int32_t)AUDIO_FORMAT_INVALID;
if (apstream) {
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD)
actual_format = (int32_t)apstream->comprconfig.codec->format;
else
actual_format = (int32_t)audio_format_from_pcm_format(apstream->pcmconfig.format);
}
return actual_format;
}
void proxy_offload_set_nonblock(void *proxy_stream)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD)
apstream->nonblock_flag = 1;
return ;
}
int proxy_offload_compress_func(void *proxy_stream, int func_type)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
int ret = 0;
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD) {
if (apstream->compress) {
switch (func_type) {
case COMPRESS_TYPE_WAIT:
ret = compress_wait(apstream->compress, -1);
ALOGVV("%s-%s: returned from waiting", stream_table[apstream->stream_type], __func__);
break;
case COMPRESS_TYPE_NEXTTRACK:
ret = compress_next_track(apstream->compress);
ALOGI("%s-%s: set next track", stream_table[apstream->stream_type], __func__);
break;
case COMPRESS_TYPE_PARTIALDRAIN:
ret = compress_partial_drain(apstream->compress);
ALOGI("%s-%s: drained this track partially", stream_table[apstream->stream_type], __func__);
/* Resend the metadata for next iteration */
apstream->ready_new_metadata = 1;
break;
case COMPRESS_TYPE_DRAIN:
ret = compress_drain(apstream->compress);
ALOGI("%s-%s: drained this track", stream_table[apstream->stream_type], __func__);
break;
default:
ALOGE("%s-%s: unsupported Offload Compress Function(%d)",
stream_table[apstream->stream_type], __func__, func_type);
}
}
}
return ret;
}
int proxy_offload_pause(void *proxy_stream)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
int ret = 0;
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD) {
if (apstream->compress) {
ret = compress_pause(apstream->compress);
ALOGV("%s-%s: paused compress offload!", stream_table[apstream->stream_type], __func__);
}
}
return ret;
}
int proxy_offload_resume(void *proxy_stream)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
int ret = 0;
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD) {
if (apstream->compress) {
ret = compress_resume(apstream->compress);
ALOGV("%s-%s: resumed compress offload!", stream_table[apstream->stream_type], __func__);
}
}
return ret;
}
void *proxy_create_playback_stream(void *proxy, int type, void *config, char *address __unused)
{
struct audio_proxy *aproxy = proxy;
audio_stream_type stream_type = (audio_stream_type)type;
struct audio_config *requested_config = (struct audio_config *)config;
struct audio_proxy_stream *apstream;
apstream = (struct audio_proxy_stream *)calloc(1, sizeof(struct audio_proxy_stream));
if (!apstream) {
ALOGE("proxy-%s: failed to allocate memory for Proxy Stream", __func__);
return NULL;;
}
/* Stores the requested configurations. */
apstream->requested_sample_rate = requested_config->sample_rate;
apstream->requested_channel_mask = requested_config->channel_mask;
apstream->requested_format = requested_config->format;
apstream->stream_type = stream_type;
apstream->need_update_pcm_config = false;
/* Sets basic configuration from Stream Type. */
switch (apstream->stream_type) {
// For VTS
case ASTREAM_PLAYBACK_NO_ATTRIBUTE:
apstream->sound_card = PRIMARY_PLAYBACK_CARD;
apstream->sound_device = PRIMARY_PLAYBACK_DEVICE;
apstream->pcmconfig = pcm_config_primary_playback;
break;
case ASTREAM_PLAYBACK_PRIMARY:
apstream->sound_card = PRIMARY_PLAYBACK_CARD;
apstream->sound_device = get_pcm_device_number(aproxy, apstream);
apstream->pcmconfig = pcm_config_primary_playback;
if (aproxy->primary_out == NULL)
aproxy->primary_out = apstream;
else
ALOGE("proxy-%s: Primary Output Proxy Stream is already created!!!", __func__);
break;
case ASTREAM_PLAYBACK_DEEP_BUFFER:
apstream->sound_card = DEEP_PLAYBACK_CARD;
apstream->sound_device = get_pcm_device_number(aproxy, apstream);
apstream->pcmconfig = pcm_config_deep_playback;
break;
case ASTREAM_PLAYBACK_FAST:
apstream->sound_card = FAST_PLAYBACK_CARD;
apstream->sound_device = get_pcm_device_number(aproxy, apstream);
apstream->pcmconfig = pcm_config_fast_playback;
break;
case ASTREAM_PLAYBACK_LOW_LATENCY:
apstream->sound_card = LOW_PLAYBACK_CARD;
apstream->sound_device = get_pcm_device_number(aproxy, apstream);
apstream->pcmconfig = pcm_config_low_playback;
break;
case ASTREAM_PLAYBACK_COMPR_OFFLOAD:
apstream->sound_card = OFFLOAD_PLAYBACK_CARD;
apstream->sound_device = get_pcm_device_number(aproxy, apstream);
apstream->comprconfig = compr_config_offload_playback;
/* dummy primary pcmconfig used for best match selection */
apstream->pcmconfig = pcm_config_primary_playback;
if (is_supported_compressed_format(requested_config->offload_info.format)) {
apstream->comprconfig.codec = (struct snd_codec *)calloc(1, sizeof(struct snd_codec));
if (apstream->comprconfig.codec == NULL) {
ALOGE("proxy-%s: fail to allocate memory for Sound Codec", __func__);
goto err_open;
}
apstream->comprconfig.codec->id = get_snd_codec_id(requested_config->offload_info.format);
apstream->comprconfig.codec->ch_in = requested_config->channel_mask;
apstream->comprconfig.codec->ch_out = requested_config->channel_mask;
apstream->comprconfig.codec->sample_rate = requested_config->sample_rate;
apstream->comprconfig.codec->bit_rate = requested_config->offload_info.bit_rate;
apstream->comprconfig.codec->format = requested_config->format;
apstream->ready_new_metadata = 1;
} else {
ALOGE("proxy-%s: unsupported Compressed Format(%x)", __func__,
requested_config->offload_info.format);
goto err_open;
}
break;
case ASTREAM_PLAYBACK_MMAP:
apstream->sound_card = MMAP_PLAYBACK_CARD;
apstream->sound_device = get_pcm_device_number(aproxy, apstream);
apstream->pcmconfig = pcm_config_mmap_playback;
break;
case ASTREAM_PLAYBACK_AUX_DIGITAL:
apstream->sound_card = AUX_PLAYBACK_CARD;
apstream->sound_device = get_pcm_device_number(aproxy, apstream);
apstream->pcmconfig = pcm_config_aux_playback;
if (apstream->requested_sample_rate != 0) {
apstream->pcmconfig.rate = apstream->requested_sample_rate;
// It needs Period Size adjustment based with predefined duration
// to avoid underrun noise by small buffer at high sampling rate
if (apstream->requested_sample_rate > DEFAULT_MEDIA_SAMPLING_RATE) {
apstream->pcmconfig.period_size = (apstream->requested_sample_rate * PREDEFINED_DP_PLAYBACK_DURATION) / 1000;
ALOGI("proxy-%s: changed Period Size(%d) as requested sampling rate(%d)",
__func__, apstream->pcmconfig.period_size, apstream->pcmconfig.rate);
}
}
if (apstream->requested_channel_mask != AUDIO_CHANNEL_NONE) {
apstream->pcmconfig.channels = audio_channel_count_from_out_mask(apstream->requested_channel_mask);
}
if (apstream->requested_format != AUDIO_FORMAT_DEFAULT) {
apstream->pcmconfig.format = pcm_format_from_audio_format(apstream->requested_format);
}
break;
case ASTREAM_PLAYBACK_DIRECT:
apstream->sound_card = DIRECT_PLAYBACK_CARD;
apstream->sound_device = get_pcm_device_number(aproxy, apstream);
apstream->pcmconfig = pcm_config_direct_playback;
apstream->need_channelpadding = false;
apstream->proc_buf_out = NULL;
apstream->proc_buf_size = 0;
/* check whether connected USB device supports requested channels or not */
if (!(proxy_is_usb_playback_device_connected(aproxy->usb_aproxy) &&
(int)audio_channel_count_from_out_mask(apstream->requested_channel_mask) <=
proxy_usb_get_playback_highest_supported_channels(aproxy->usb_aproxy))) {
if (proxy_is_usb_playback_device_connected(aproxy->usb_aproxy))
ALOGE("proxy-%s: Direct stream channel mismatch (request channels %u supported channels %u) ",
__func__, audio_channel_count_from_out_mask(apstream->requested_channel_mask),
proxy_usb_get_playback_highest_supported_channels(aproxy->usb_aproxy));
else
ALOGE("proxy-%s: Direct stream is not supported for other output devices except USB ", __func__);
goto err_open;
}
/* check whether request configurations are supported by Direct
* stream or not, and update pcmconfig */
if (check_direct_config_support(apstream)) {
ALOGE("proxy-%s: Direct stream unsupported configuration ", __func__);
goto err_open;
}
break;
default:
ALOGE("proxy-%s: failed to open Proxy Stream as unknown stream type(%d)", __func__,
apstream->stream_type);
goto err_open;
}
apstream->pcm = NULL;
apstream->compress = NULL;
ALOGI("proxy-%s: opened Proxy Stream(%s)", __func__, stream_table[apstream->stream_type]);
return (void *)apstream;
err_open:
free(apstream);
return NULL;
}
void proxy_destroy_playback_stream(void *proxy_stream)
{
struct audio_proxy *aproxy = getInstance();
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
if (apstream) {
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD) {
if (apstream->comprconfig.codec != NULL)
free(apstream->comprconfig.codec);
}
if (apstream->stream_type == ASTREAM_PLAYBACK_PRIMARY) {
if (aproxy->primary_out != NULL)
aproxy->primary_out = NULL;
}
if (apstream->proc_buf_out)
free(apstream->proc_buf_out);
free(apstream);
}
return ;
}
int proxy_close_playback_stream(void *proxy_stream)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
int ret = 0;
/* Close Noamrl PCM Device */
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD) {
if (apstream->compress) {
compress_close(apstream->compress);
apstream->compress = NULL;
}
ALOGI("%s-%s: closed Compress Device", stream_table[apstream->stream_type], __func__);
} else {
if (apstream->pcm) {
ret = pcm_close(apstream->pcm);
apstream->pcm = NULL;
}
if (apstream->dma_pcm) {
pcm_close(apstream->dma_pcm);
apstream->dma_pcm = NULL;
}
ALOGI("%s-%s: closed PCM Device", stream_table[apstream->stream_type], __func__);
}
return ret;
}
int proxy_open_playback_stream(void *proxy_stream, int32_t min_size_frames, void *mmap_info)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
struct audio_proxy *aproxy = getInstance();
struct audio_mmap_buffer_info *info = (struct audio_mmap_buffer_info *)mmap_info;
unsigned int sound_card;
unsigned int sound_device;
unsigned int flags;
int ret = 0;
char pcm_path[MAX_PCM_PATH_LEN];
/* Get PCM/Compress Device */
sound_card = apstream->sound_card;
sound_device = apstream->sound_device;
/* Open Normal PCM Device */
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD) {
if (apstream->compress == NULL) {
flags = COMPRESS_IN;
apstream->compress = compress_open(sound_card, sound_device, flags, &apstream->comprconfig);
if (apstream->compress && !is_compress_ready(apstream->compress)) {
/* compress_open does always return compress structure, not NULL */
ALOGE("%s-%s: Compress Device is not ready with Sampling_Rate(%u) error(%s)!",
stream_table[apstream->stream_type], __func__, apstream->comprconfig.codec->sample_rate,
compress_get_error(apstream->compress));
goto err_open;
}
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/comprC%uD%u", sound_card, sound_device);
ALOGI("%s-%s: The opened Compress Device is %s with Sampling_Rate(%u) PCM_Format(%d) Fragment_Size(%u)",
stream_table[apstream->stream_type], __func__, pcm_path,
apstream->comprconfig.codec->sample_rate, apstream->comprconfig.codec->format,
apstream->comprconfig.fragment_size);
apstream->pcm = NULL;
}
} else {
if (apstream->pcm == NULL) {
struct pcm_config *ppcmconfig = &apstream->pcmconfig;
if (apstream->stream_type == ASTREAM_PLAYBACK_MMAP) {
flags = PCM_OUT | PCM_MMAP | PCM_NOIRQ | PCM_MONOTONIC;
adjust_mmap_period_count(apstream, ppcmconfig, min_size_frames);
} else
flags = PCM_OUT | PCM_MONOTONIC;
apstream->dma_pcm = pcm_open(sound_card, sound_device, flags, ppcmconfig);
if (apstream->dma_pcm && !pcm_is_ready(apstream->dma_pcm)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("%s-%s: PCM Device is not ready with Sampling_Rate(%u) error(%s)!",
stream_table[apstream->stream_type], __func__, ppcmconfig->rate,
pcm_get_error(apstream->dma_pcm));
goto err_open;
}
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c", sound_card, sound_device ,'p');
ALOGI("%s-%s: The opened PCM Device is %s with Sampling_Rate(%u) PCM_Format(%d) PCM_start-threshold(%d) PCM_stop-threshold(%d)",
stream_table[apstream->stream_type], __func__, pcm_path,
ppcmconfig->rate, ppcmconfig->format,
ppcmconfig->start_threshold, ppcmconfig->stop_threshold);
/* virtual pcm handling for Primary & Deep streams */
if (apstream->stream_type == ASTREAM_PLAYBACK_PRIMARY) {
/* DMA PCM should be started */
if (pcm_start(apstream->dma_pcm) == 0) {
ALOGI("proxy-%s: PCM Device(%s) with SR(%u) PF(%d) CC(%d) is started",
__func__, pcm_path, ppcmconfig->rate, ppcmconfig->format, ppcmconfig->channels);
} else {
ALOGE("proxy-%s: PCM Device(%s) with SR(%u) PF(%d) CC(%d) cannot be started as error(%s)",
__func__, pcm_path, ppcmconfig->rate, ppcmconfig->format, ppcmconfig->channels,
pcm_get_error(apstream->dma_pcm));
goto err_open;
}
/* open virtual primary pcm node */
apstream->pcm = pcm_open(VIRTUAL_PRIMARY_PLAYBACK_CARD, VIRTUAL_PRIMARY_PLAYBACK_DEVICE,
flags, &apstream->pcmconfig);
if (apstream->pcm && !pcm_is_ready(apstream->pcm)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("%s-%s: Virtual PCM Device is not ready with Sampling_Rate(%u) error(%s)!",
stream_table[apstream->stream_type], __func__, apstream->pcmconfig.rate,
pcm_get_error(apstream->pcm));
goto err_open;
}
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c", VIRTUAL_PRIMARY_PLAYBACK_CARD, VIRTUAL_PRIMARY_PLAYBACK_DEVICE,'p');
ALOGI("%s-%s: The opened Virtual PCM Device is %s with Sampling_Rate(%u) PCM_Format(%d) PCM_start-threshold(%d) PCM_stop-threshold(%d)",
stream_table[apstream->stream_type], __func__, pcm_path,
apstream->pcmconfig.rate, apstream->pcmconfig.format,
apstream->pcmconfig.start_threshold, apstream->pcmconfig.stop_threshold);
} else {
apstream->pcm = apstream->dma_pcm;
apstream->dma_pcm = NULL;
}
apstream->compress = NULL;
if (apstream->stream_type == ASTREAM_PLAYBACK_MMAP) {
unsigned int offset1 = 0;
unsigned int frames1 = 0;
unsigned int buf_size = 0;
unsigned int mmap_size = 0;
ret = pcm_mmap_begin(apstream->pcm, &info->shared_memory_address, &offset1, &frames1);
if (ret == 0) {
ALOGI("%s-%s: PCM Device begin MMAP", stream_table[apstream->stream_type], __func__);
info->buffer_size_frames = pcm_get_buffer_size(apstream->pcm);
buf_size = pcm_frames_to_bytes(apstream->pcm, info->buffer_size_frames);
info->burst_size_frames = apstream->pcmconfig.period_size;
// get mmap buffer fd
ret = get_mmap_data_fd(proxy_stream, AUSAGE_PLAYBACK,
&info->shared_memory_fd, &mmap_size);
if (ret < 0) {
// Fall back to poll_fd mode, shared mode
info->shared_memory_fd = pcm_get_poll_fd(apstream->pcm);
ALOGI("%s-%s: PCM Device MMAP Exclusive mode not support",
stream_table[apstream->stream_type], __func__);
} else {
if (mmap_size < buf_size) {
ALOGE("%s-%s: PCM Device MMAP buffer size not matching",
stream_table[apstream->stream_type], __func__);
goto err_open;
}
// FIXME: indicate exclusive mode support by returning a negative buffer size
info->buffer_size_frames *= -1;
}
memset(info->shared_memory_address, 0,
pcm_frames_to_bytes(apstream->pcm, info->buffer_size_frames));
ret = pcm_mmap_commit(apstream->pcm, 0, MMAP_PERIOD_SIZE);
if (ret < 0) {
ALOGE("%s-%s: PCM Device cannot commit MMAP with error(%s)",
stream_table[apstream->stream_type], __func__, pcm_get_error(apstream->pcm));
goto err_open;
} else {
ALOGI("%s-%s: PCM Device commit MMAP", stream_table[apstream->stream_type], __func__);
ret = 0;
}
} else {
ALOGE("%s-%s: PCM Device cannot begin MMAP with error(%s)",
stream_table[apstream->stream_type], __func__, pcm_get_error(apstream->pcm));
goto err_open;
}
}
} else
ALOGW("%s-%s: PCM Device is already opened!", stream_table[apstream->stream_type], __func__);
}
if(aproxy->support_dualspk) {
if (aproxy->active_playback_device == DEVICE_EARPIECE)
proxy_set_mixer_value_int(aproxy, SPK_AMPL_POWER_NAME, true);
else
proxy_set_mixer_value_int(aproxy, SPK_AMPL_POWER_NAME, aproxy->spk_ampL_powerOn);
}
apstream->need_update_pcm_config = false;
return ret;
err_open:
proxy_close_playback_stream(proxy_stream);
return -ENODEV;
}
int proxy_start_playback_stream(void *proxy_stream)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
int ret = 0;
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD) {
if (apstream->compress) {
if (apstream->nonblock_flag) {
compress_nonblock(apstream->compress, apstream->nonblock_flag);
ALOGV("%s-%s: set Nonblock mode!", stream_table[apstream->stream_type], __func__);
} else {
compress_nonblock(apstream->compress, 0);
ALOGV("%s-%s: set Block mode!", stream_table[apstream->stream_type], __func__);
}
ret = compress_start(apstream->compress);
if (ret == 0)
ALOGI("%s-%s: started Compress Device", stream_table[apstream->stream_type], __func__);
else
ALOGE("%s-%s: cannot start Compress Offload(%s)", stream_table[apstream->stream_type],
__func__, compress_get_error(apstream->compress));
} else
ret = -ENOSYS;
} else if (apstream->stream_type == ASTREAM_PLAYBACK_MMAP) {
if (apstream->pcm) {
ret = pcm_start(apstream->pcm);
if (ret == 0)
ALOGI("%s-%s: started MMAP Device", stream_table[apstream->stream_type], __func__);
else
ALOGE("%s-%s: cannot start MMAP device with error(%s)", stream_table[apstream->stream_type],
__func__, pcm_get_error(apstream->pcm));
} else
ret = -ENOSYS;
}
return ret;
}
int proxy_write_playback_buffer(void *proxy_stream, void* buffer, int bytes)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
int ret = 0, wrote = 0;
/* Skip other sounds except AUX Digital Stream when AUX_DIGITAL is connected */
if (apstream->stream_type != ASTREAM_PLAYBACK_AUX_DIGITAL &&
getInstance()->active_playback_device == DEVICE_AUX_DIGITAL) {
skip_pcm_processing(apstream, wrote);
wrote = bytes;
save_written_frames(apstream, wrote);
return wrote;
}
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD) {
if (apstream->compress) {
if (apstream->ready_new_metadata) {
compress_set_gapless_metadata(apstream->compress, &apstream->offload_metadata);
ALOGI("%s-%s: sent gapless metadata(delay = %u, padding = %u) to Compress Device",
stream_table[apstream->stream_type], __func__,
apstream->offload_metadata.encoder_delay, apstream->offload_metadata.encoder_padding);
apstream->ready_new_metadata = 0;
}
wrote = compress_write(apstream->compress, buffer, bytes);
ALOGVV("%s-%s: wrote Request(%u bytes) to Compress Device, and Accepted (%u bytes)",
stream_table[apstream->stream_type], __func__, (unsigned int)bytes, wrote);
}
} else {
if (apstream->pcm) {
void *proc_buf_out = buffer;
int dst_buffer_size = bytes;
/* Direct stream volume control & channel expanding if needed */
if (apstream->stream_type == ASTREAM_PLAYBACK_DIRECT && apstream->need_channelpadding) {
unsigned int bytes_per_src_sample = audio_bytes_per_sample(apstream->requested_format);
unsigned int bytes_per_dst_sample = (pcm_format_to_bits(apstream->pcmconfig.format) >> 3);
int num_device_channels = proxy_get_actual_channel_count(apstream);
int num_req_channels = audio_channel_count_from_out_mask(apstream->requested_channel_mask);
int frames_num = bytes / (num_req_channels *
audio_bytes_per_sample(apstream->requested_format));
/* Prepare Channel Conversion output Buffer */
dst_buffer_size = frames_num * num_device_channels * bytes_per_dst_sample;
if (apstream->proc_buf_size < dst_buffer_size) {
apstream->proc_buf_size = dst_buffer_size;
apstream->proc_buf_out = realloc(apstream->proc_buf_out, dst_buffer_size);
ALOGI("%s-%s: alloc expand channel buffer with %d bytes req_channels %d device_channels %d",
stream_table[apstream->stream_type], __func__, dst_buffer_size, num_req_channels, num_device_channels);
ALOGI("%s-%s: Channel adjust src-channels %d to %d, bytes per sample src-bytes %d to %d ",
stream_table[apstream->stream_type], __func__, num_req_channels,
num_device_channels, bytes_per_src_sample, bytes_per_dst_sample);
}
/* Assigned allocated buffer as output buffer for channel expanding */
proc_buf_out = apstream->proc_buf_out;
/* Adjust channels by adding zeros to audio frame end, for Direct output stream */
ret = adjust_channels(buffer, num_req_channels,
proc_buf_out, num_device_channels,
bytes_per_src_sample, bytes);
if (ret != dst_buffer_size)
ALOGE("%s-%s: channel convert failed", stream_table[apstream->stream_type], __func__);
}
ret = pcm_write(apstream->pcm, (void *)proc_buf_out, (unsigned int)dst_buffer_size);
if (ret == 0) {
ALOGVV("%s-%s: writed %u bytes to PCM Device", stream_table[apstream->stream_type],
__func__, (unsigned int)bytes);
} else {
ALOGE("%s-%s: failed to write to PCM Device with %s",
stream_table[apstream->stream_type], __func__, pcm_get_error(apstream->pcm));
skip_pcm_processing(apstream, wrote);
}
wrote = bytes;
save_written_frames(apstream, wrote);
}
}
return wrote;
}
int proxy_stop_playback_stream(void *proxy_stream)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
int ret = 0;
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD) {
if (apstream->compress) {
ret = compress_stop(apstream->compress);
if (ret == 0)
ALOGI("%s-%s: stopped Compress Device", stream_table[apstream->stream_type], __func__);
else
ALOGE("%s-%s: cannot stop Compress Offload(%s)", stream_table[apstream->stream_type],
__func__, compress_get_error(apstream->compress));
apstream->ready_new_metadata = 1;
}
} else if (apstream->stream_type == ASTREAM_PLAYBACK_MMAP) {
if (apstream->pcm) {
ret = pcm_stop(apstream->pcm);
if (ret == 0)
ALOGI("%s-%s: stop MMAP Device", stream_table[apstream->stream_type], __func__);
else
ALOGE("%s-%s: cannot stop MMAP device with error(%s)", stream_table[apstream->stream_type],
__func__, pcm_get_error(apstream->pcm));
}
}
return ret;
}
int proxy_reconfig_playback_stream(void *proxy_stream, int type, void *config)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
audio_stream_type new_type = (audio_stream_type)type;
struct audio_config *new_config = (struct audio_config *)config;
if (apstream) {
apstream->stream_type = new_type;
apstream->requested_sample_rate = new_config->sample_rate;
apstream->requested_channel_mask = new_config->channel_mask;
apstream->requested_format = new_config->format;
return 0;
} else
return -1;
}
#ifdef SUPPORT_BTA2DP_OFFLOAD
// dummy update of playback buffer for calculating presentation position
int proxy_update_playback_buffer(void *proxy_stream, void *buffer, int bytes)
{
struct audio_proxy *aproxy = getInstance();
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
// if bt offload on & suspend state or compr case, skip to use temp add routine
if ((aproxy->a2dp_out_enabled)
|| (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD)) {
return 0;
}
skip_pcm_processing(apstream, 0);
save_written_frames(apstream, bytes);
ALOGE("%s-%s: failed to write and just update written buffer byte (%d), apstream->frames (%u)",
stream_table[apstream->stream_type], __func__, bytes, (unsigned int)apstream->frames);
return bytes;
}
// dummy calculation of presentation position
int proxy_get_presen_position_temp(void *proxy_stream, uint64_t *frames, struct timespec *timestamp)
{
struct audio_proxy *aproxy = getInstance();
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
int ret = -ENODATA;
if (aproxy->a2dp_out_enabled) {
// if bt offload on & suspend state, then get original position from hw
ret = proxy_get_presen_position(proxy_stream, frames, timestamp);
} else {
// use bt offload disbaled state only
*frames = apstream->frames;
clock_gettime(CLOCK_MONOTONIC, timestamp);
ret = 0;
}
return ret;
}
#endif
int proxy_get_render_position(void *proxy_stream, uint32_t *frames)
{
struct audio_proxy *aproxy = getInstance();
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
uint32_t presented_frames = 0;
unsigned long hw_frames;
unsigned int sample_rate = 0;
int ret = -ENODATA;
if (frames != NULL) {
*frames = 0;
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD) {
if (apstream->compress) {
ret = compress_get_tstamp(apstream->compress, &hw_frames, &sample_rate);
if (ret == 0) {
ALOGVV("%s-%s: rendered frames %u with sample_rate %u",
stream_table[apstream->stream_type], __func__, *frames, sample_rate);
presented_frames = (uint32_t)hw_frames;
#ifdef SUPPORT_BTA2DP_OFFLOAD
if (aproxy->a2dp_out_enabled && is_active_playback_device_bta2dp(aproxy)) {
uint32_t a2dp_delay = 0;
if (aproxy->a2dp_delay > aproxy->a2dp_default_delay)
a2dp_delay = aproxy->a2dp_delay;
else
a2dp_delay = aproxy->a2dp_default_delay;
uint32_t latency_frames = (a2dp_delay *
proxy_get_actual_sampling_rate(apstream)) / 1000;
if (presented_frames > latency_frames)
*frames = presented_frames - latency_frames;
else
ret = -ENODATA;
} else
#endif
*frames = presented_frames;
} else
ret = -ENODATA;
}
}
} else {
ALOGE("%s-%s: Invalid Parameter with Null pointer parameter",
stream_table[apstream->stream_type], __func__);
ret = -EINVAL;
}
return ret;
}
int proxy_get_presen_position(void *proxy_stream, uint64_t *frames, struct timespec *timestamp)
{
struct audio_proxy *aproxy = getInstance();
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
uint64_t presented_frames = 0;
unsigned long hw_frames;
unsigned int sample_rate = 0;
unsigned int avail = 0;
int ret = -ENODATA;
if (frames != NULL && timestamp != NULL) {
*frames = 0;
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD) {
if (apstream->compress) {
ret = compress_get_tstamp(apstream->compress, &hw_frames, &sample_rate);
if (ret == 0) {
ALOGVV("%s-%s: presented frames %lu with sample_rate %u",
stream_table[apstream->stream_type], __func__, hw_frames, sample_rate);
presented_frames = (uint64_t)hw_frames;
#ifdef SUPPORT_BTA2DP_OFFLOAD
if (aproxy->a2dp_out_enabled && is_active_playback_device_bta2dp(aproxy)) {
uint32_t a2dp_delay = 0;
if (aproxy->a2dp_delay > aproxy->a2dp_default_delay)
a2dp_delay = aproxy->a2dp_delay;
else
a2dp_delay = aproxy->a2dp_default_delay;
uint32_t latency_frames = (a2dp_delay *
proxy_get_actual_sampling_rate(apstream)) / 1000;
if (presented_frames > latency_frames)
*frames = presented_frames - latency_frames;
else
ret = -ENODATA;
} else
#endif
*frames = presented_frames;
clock_gettime(CLOCK_MONOTONIC, timestamp);
} else
ret = -ENODATA;
}
} else {
if (apstream->pcm) {
ret = pcm_get_htimestamp(apstream->pcm, &avail, timestamp);
if (ret == 0) {
// Total Frame Count in kernel Buffer
uint64_t kernel_buffer_size = (uint64_t)apstream->pcmconfig.period_size *
(uint64_t)apstream->pcmconfig.period_count;
// Real frames which played out to device
int64_t signed_frames = apstream->frames - kernel_buffer_size + avail;
if (signed_frames >= 0) {
presented_frames = (uint64_t)signed_frames;
#ifdef SUPPORT_BTA2DP_OFFLOAD
if (aproxy->a2dp_out_enabled && is_active_playback_device_bta2dp(aproxy)) {
uint32_t a2dp_delay = 0;
if (aproxy->a2dp_delay > aproxy->a2dp_default_delay)
a2dp_delay = aproxy->a2dp_delay;
else
a2dp_delay = aproxy->a2dp_default_delay;
uint32_t latency_frames = (a2dp_delay *
proxy_get_actual_sampling_rate(apstream)) / 1000;
if (presented_frames > latency_frames)
*frames = presented_frames - latency_frames;
else
ret = -ENODATA;
} else
#endif
*frames = presented_frames;
} else {
ret = -ENODATA;
}
} else {
ret = -ENODATA;
}
}
}
} else {
ALOGE("%s-%s: Invalid Parameter with Null pointer parameter",
stream_table[apstream->stream_type], __func__);
ret = -EINVAL;
}
return ret;
}
int proxy_getparam_playback_stream(void *proxy_stream, void *query_params, void *reply_params)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
struct audio_proxy *aproxy = getInstance();
struct str_parms *query = (struct str_parms *)query_params;
struct str_parms *reply = (struct str_parms *)reply_params;
if (apstream->stream_type == ASTREAM_PLAYBACK_NO_ATTRIBUTE &&
proxy_is_usb_playback_device_connected(aproxy->usb_aproxy)) {
// get USB playback param information
proxy_usb_getparam_playback_stream(aproxy->usb_aproxy, query, reply);
} else {
/*
* Supported Audio Configuration can be different as Target Project.
* AudioHAL engineers have to modify these codes based on Target Project.
*/
// supported audio formats
if (str_parms_has_key(query, AUDIO_PARAMETER_STREAM_SUP_FORMATS)) {
char formats_list[256];
memset(formats_list, 0, 256);
strncpy(formats_list, stream_format_table[apstream->stream_type],
strlen(stream_format_table[apstream->stream_type]));
str_parms_add_str(reply, AUDIO_PARAMETER_STREAM_SUP_FORMATS, formats_list);
}
// supported audio channel masks
if (str_parms_has_key(query, AUDIO_PARAMETER_STREAM_SUP_CHANNELS)) {
char channels_list[256];
memset(channels_list, 0, 256);
strncpy(channels_list, stream_channel_table[apstream->stream_type],
strlen(stream_channel_table[apstream->stream_type]));
str_parms_add_str(reply, AUDIO_PARAMETER_STREAM_SUP_CHANNELS, channels_list);
}
// supported audio samspling rates
if (str_parms_has_key(query, AUDIO_PARAMETER_STREAM_SUP_SAMPLING_RATES)) {
char rates_list[256];
memset(rates_list, 0, 256);
strncpy(rates_list, stream_rate_table[apstream->stream_type],
strlen(stream_rate_table[apstream->stream_type]));
str_parms_add_str(reply, AUDIO_PARAMETER_STREAM_SUP_SAMPLING_RATES, rates_list);
}
}
return 0;
}
int proxy_setparam_playback_stream(void *proxy_stream, void *parameters)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
struct str_parms *parms = (struct str_parms *)parameters;
char value[32];
int ret = 0;
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD) {
struct compr_gapless_mdata tmp_mdata;
bool need_to_set_metadata = false;
tmp_mdata.encoder_delay = 0;
tmp_mdata.encoder_padding = 0;
ret = str_parms_get_str(parms, AUDIO_OFFLOAD_CODEC_DELAY_SAMPLES, value, sizeof(value));
if (ret >= 0) {
tmp_mdata.encoder_delay = atoi(value);
ALOGI("%s-%s: Codec Delay Samples(%u)", stream_table[apstream->stream_type], __func__,
tmp_mdata.encoder_delay);
need_to_set_metadata = true;
}
ret = str_parms_get_str(parms, AUDIO_OFFLOAD_CODEC_PADDING_SAMPLES, value, sizeof(value));
if (ret >= 0) {
tmp_mdata.encoder_padding = atoi(value);
ALOGI("%s-%s: Codec Padding Samples(%u)", stream_table[apstream->stream_type], __func__,
tmp_mdata.encoder_padding);
need_to_set_metadata = true;
}
if (need_to_set_metadata) {
apstream->offload_metadata = tmp_mdata;
apstream->ready_new_metadata = 1;
}
}
return ret;
}
uint32_t proxy_get_playback_latency(void *proxy_stream)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
uint32_t latency;
// Total Latency = ALSA Buffer latency + HW Latency
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD) {
/*
* Offload HW latency
* - A-Box firmware triggers offload play once two buffers of 20msec each are decoded - 20msec
* - Post processing of decoded data - 10 msec
* - 20msec extra is provided considering scheduling delays
* therefore total offload HW latency will 50msec
*/
latency = 50;
} else {
latency = (apstream->pcmconfig.period_count * apstream->pcmconfig.period_size * 1000) / (apstream->pcmconfig.rate);
latency += 0; // Need to check HW Latency
}
return latency;
}
// select best pcmconfig among requested two configs
bool proxy_select_best_playback_pcmconfig(
void *proxy,
void *cur_proxy_stream,
int compr_upscaler)
{
struct audio_proxy *aproxy = proxy;
struct audio_proxy_stream *cur_apstream = (struct audio_proxy_stream *)cur_proxy_stream;
/* need to update compress stream's dummy pcmconfig based upon upscaler value
* before selecting best pcmconfig
* compress offload-upscaler values are defined as shown
* 0: 48KHz, 16bit
* 1: 192KHz, 24bit
* 2: 48KHz, 24bit
*/
if (cur_apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD) {
if (compr_upscaler == 2)
cur_apstream->pcmconfig = pcm_config_deep_playback;
else if (compr_upscaler == 1)
cur_apstream->pcmconfig = pcm_config_deep_playback_uhqa;
else
cur_apstream->pcmconfig = pcm_config_primary_playback;
ALOGI("%s-%s: upscaler: %d pcmconfig rate[%d] format[%d]",
stream_table[cur_apstream->stream_type], __func__, compr_upscaler,
cur_apstream->pcmconfig.rate, cur_apstream->pcmconfig.format);
}
return proxy_usb_out_pick_best_pcmconfig(aproxy->usb_aproxy, cur_apstream->pcmconfig);
}
/* selecting best playback pcm config to configure USB device */
void proxy_set_best_playback_pcmconfig(void *proxy, void *proxy_stream)
{
struct audio_proxy *aproxy = proxy;
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
bool reprepare_needed = false;
if (!aproxy->usb_aproxy) {
ALOGI("%s-%s: USB audio offload is not initialized",
stream_table[apstream->stream_type], __func__);
return;
}
/* update & check whether USB device re-configuraiton is required for best config */
reprepare_needed = proxy_usb_out_reconfig_needed(aproxy->usb_aproxy);
if ((aproxy->active_playback_device == DEVICE_USB_HEADSET
|| aproxy->active_playback_device == DEVICE_SPEAKER_AND_USB_HEADSET)
&& !aproxy->is_usb_single_clksrc && !is_usage_CPCall(aproxy->active_playback_ausage)
&& reprepare_needed) {
/* steps for re-configuring USB device configuration
* - Close WDMA6 & usb out pcm,
* - prepare usb for new config,
* - modify sifs0 setting to new selected PCM config
* - open wdma6 & usb out pcm
*/
/* close loopback and USB pcm nodes */
disable_usb_out_loopback(aproxy);
proxy_usb_close_out_proxy(aproxy->usb_aproxy);
/* Prepare USB device for new configuraiton */
proxy_usb_playback_prepare(aproxy->usb_aproxy, true);
set_usb_playback_modifier(aproxy);
/* re-open loopback and USB pcm nodes */
proxy_usb_open_out_proxy(aproxy->usb_aproxy);
enable_usb_out_loopback(aproxy);
ALOGI("%s-%s: USB Device re-configured",
stream_table[apstream->stream_type], __func__);
}
return;
}
/* reset playback pcm config for USB device default */
void proxy_reset_playback_pcmconfig(void *proxy)
{
struct audio_proxy *aproxy = proxy;
/* reset USB playback config to default values */
proxy_usb_out_reset_config(aproxy->usb_aproxy);
return;
}
void proxy_dump_playback_stream(void *proxy_stream, int fd)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
const size_t len = 256;
char buffer[len];
if (apstream->pcm != NULL) {
snprintf(buffer, len, "\toutput pcm config sample rate: %d\n",apstream->pcmconfig.rate);
write(fd,buffer,strlen(buffer));
snprintf(buffer, len, "\toutput pcm config period size : %d\n",apstream->pcmconfig.period_size);
write(fd,buffer,strlen(buffer));
snprintf(buffer, len, "\toutput pcm config format: %d\n",apstream->pcmconfig.format);
write(fd,buffer,strlen(buffer));
}
if (apstream->compress != NULL) {
if (apstream->comprconfig.codec != NULL) {
snprintf(buffer, len, "\toutput offload codec id: %d\n",apstream->comprconfig.codec->id);
write(fd,buffer,strlen(buffer));
snprintf(buffer, len, "\toutput offload codec input channel: %d\n",apstream->comprconfig.codec->ch_in);
write(fd,buffer,strlen(buffer));
snprintf(buffer, len, "\toutput offload codec output channel: %d\n",apstream->comprconfig.codec->ch_out);
write(fd,buffer,strlen(buffer));
snprintf(buffer, len, "\toutput offload sample rate: %d\n",apstream->comprconfig.codec->sample_rate);
write(fd,buffer,strlen(buffer));
snprintf(buffer, len, "\toutput offload bit rate : %d\n",apstream->comprconfig.codec->bit_rate);
write(fd,buffer,strlen(buffer));
snprintf(buffer, len, "\toutput offload config format: %d\n",apstream->comprconfig.codec->format);
write(fd,buffer,strlen(buffer));
}
snprintf(buffer, len, "\tOffload Fragment Size: %d\n",apstream->comprconfig.fragment_size);
write(fd,buffer,strlen(buffer));
snprintf(buffer, len, "\tOffload Fragments: %d\n",apstream->comprconfig.fragments);
write(fd,buffer,strlen(buffer));
}
return ;
}
void *proxy_create_capture_stream(void *proxy, int type, int usage, void *config, char *address __unused)
{
struct audio_proxy *aproxy = proxy;
audio_stream_type stream_type = (audio_stream_type)type;
audio_usage stream_usage = (audio_usage)usage;
struct audio_config *requested_config = (struct audio_config *)config;
struct audio_proxy_stream *apstream;
apstream = (struct audio_proxy_stream *)calloc(1, sizeof(struct audio_proxy_stream));
if (!apstream) {
ALOGE("proxy-%s: failed to allocate memory for Proxy Stream", __func__);
return NULL;;
}
/* Stores the requested configurationss */
apstream->requested_sample_rate = requested_config->sample_rate;
apstream->requested_channel_mask = requested_config->channel_mask;
apstream->requested_format = requested_config->format;
apstream->stream_type = stream_type;
apstream->stream_usage = stream_usage;
// Initialize Post-Processing
apstream->need_channelconversion = false;
apstream->need_resampling = false;
apstream->actual_read_buf = NULL;
apstream->actual_read_buf_size = 0;
apstream->proc_buf_out = NULL;
apstream->proc_buf_size = 0;
apstream->resampler = NULL;
apstream->need_update_pcm_config = false;
apstream->skip_ch_convert = false;
/* Sets basic configuration from Stream Type. */
switch (apstream->stream_type) {
// For VTS
case ASTREAM_CAPTURE_NO_ATTRIBUTE:
apstream->sound_card = PRIMARY_CAPTURE_CARD;
apstream->sound_device = PRIMARY_CAPTURE_DEVICE;
apstream->pcmconfig = pcm_config_primary_capture;
break;
case ASTREAM_CAPTURE_PRIMARY:
apstream->sound_card = PRIMARY_CAPTURE_CARD;
apstream->sound_device = get_pcm_device_number(aproxy, apstream);
#ifdef SUPPORT_QUAD_MIC
if ((is_active_usage_CPCall(aproxy)
|| is_active_usage_APCall(aproxy)
|| apstream->stream_usage == AUSAGE_CAMCORDER)
&& is_quad_mic_device(aproxy->active_capture_device)) {
apstream->pcmconfig = pcm_config_primary_quad_mic_capture;
ALOGE("proxy-%s: Primary reconfig as Quad-Mic", __func__);
} else
#endif
apstream->pcmconfig = pcm_config_primary_capture;
update_capture_pcmconfig(apstream);
check_conversion(apstream);
break;
case ASTREAM_CAPTURE_CALL:
apstream->sound_card = CALL_RECORD_CARD;
apstream->sound_device = get_pcm_device_number(aproxy, apstream);
apstream->pcmconfig = pcm_config_call_record;
check_conversion(apstream);
break;
case ASTREAM_CAPTURE_LOW_LATENCY:
apstream->sound_card = LOW_CAPTURE_CARD;
apstream->sound_device = get_pcm_device_number(aproxy, apstream);
apstream->pcmconfig = pcm_config_low_capture;
update_capture_pcmconfig(apstream);
check_conversion(apstream);
break;
case ASTREAM_CAPTURE_MMAP:
apstream->sound_card = MMAP_CAPTURE_CARD;
apstream->sound_device = get_pcm_device_number(aproxy, apstream);
apstream->pcmconfig = pcm_config_mmap_capture;
/* update HW PCM configuration with requested config, as MMAP usage cann't
use software conversions for sample rate and channels, format is fixed to
16bit */
if (apstream->requested_sample_rate != apstream->pcmconfig.rate) {
apstream->pcmconfig.rate = apstream->requested_sample_rate;
// Adjust period_size according to sample rate
apstream->pcmconfig.period_size = (apstream->pcmconfig.rate * PREDEFINED_MMAP_CAPTURE_DURATION) / 1000;
// WDMA in A-Box is 128-bit aligned, so period_size has to be multiple of 4 frames
apstream->pcmconfig.period_size &= 0xFFFFFFFC;
ALOGD("%s-%s: updates samplig rate to %u, period_size to %u",
stream_table[apstream->stream_type], __func__,
apstream->pcmconfig.rate, apstream->pcmconfig.period_size);
}
if (audio_channel_count_from_in_mask(apstream->requested_channel_mask)
!= apstream->pcmconfig.channels) {
apstream->pcmconfig.channels = audio_channel_count_from_in_mask(apstream->requested_channel_mask);
ALOGD("%s-%s: updates channel count to %u", stream_table[apstream->stream_type],
__func__, apstream->pcmconfig.channels);
}
break;
case ASTREAM_CAPTURE_FM_TUNER:
case ASTREAM_CAPTURE_FM_RECORDING:
apstream->sound_card = FM_RECORD_CARD;
apstream->sound_device = get_pcm_device_number(aproxy, apstream);
apstream->pcmconfig = pcm_config_fm_record;
check_conversion(apstream);
break;
#ifdef SUPPORT_STHAL_INTERFACE
case ASTREAM_CAPTURE_HOTWORD:
apstream->pcmconfig = pcm_config_hotword_capture;
break;
#endif
default:
ALOGE("proxy-%s: failed to open Proxy Stream as unknown stream type(%d)", __func__,
apstream->stream_type);
goto err_open;
}
apstream->pcm = NULL;
apstream->compress = NULL;
ALOGI("proxy-%s: opened Proxy Stream(%s)", __func__, stream_table[apstream->stream_type]);
return (void *)apstream;
err_open:
free(apstream);
return NULL;
}
void proxy_destroy_capture_stream(void *proxy_stream)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
if (apstream) {
if (apstream->resampler) {
ALOGV("%s-%s: released resampler", stream_table[apstream->stream_type], __func__);
release_resampler(apstream->resampler);
}
if (apstream->actual_read_buf)
free(apstream->actual_read_buf);
if (apstream->proc_buf_out)
free(apstream->proc_buf_out);
free(apstream);
}
return ;
}
int proxy_close_capture_stream(void *proxy_stream)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
struct audio_proxy *aproxy = getInstance();
int ret = 0;
#ifdef SUPPORT_STHAL_INTERFACE
/* Handle HOTWORD soure separately */
if (apstream->stream_type == ASTREAM_CAPTURE_HOTWORD) {
if (aproxy->sound_trigger_close_for_streaming) {
if (apstream->soundtrigger_handle > 0) {
if (apstream->stream_usage == AUSAGE_HOTWORD_SEAMLESS) {
aproxy->sound_trigger_close_for_streaming(apstream->soundtrigger_handle);
} else {
aproxy->sound_trigger_close_recording(apstream->soundtrigger_handle);
}
}
apstream->soundtrigger_handle = 0;
#ifdef SEAMLESS_DUMP
if (apstream->fp)
fclose(apstream->fp);
#endif
ALOGI("VTS PCM Node closed");
} else {
ALOGE("%s-%s: SoundTrigger HAL Close function Not available!",
stream_table[apstream->stream_type], __func__);
ret = -EIO;
}
return ret;
}
#endif
/* Close Normal PCM Device */
if (apstream->pcm) {
ret = pcm_close(apstream->pcm);
apstream->pcm = NULL;
}
if (apstream->dma_pcm) {
pcm_close(apstream->dma_pcm);
apstream->dma_pcm = NULL;
}
ALOGI("%s-%s: closed PCM Device", stream_table[apstream->stream_type], __func__);
return ret;
}
int proxy_open_capture_stream(void *proxy_stream, int32_t min_size_frames, void *mmap_info)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
struct audio_proxy *aproxy = getInstance();
struct audio_mmap_buffer_info *info = (struct audio_mmap_buffer_info *)mmap_info;
unsigned int sound_card;
unsigned int sound_device;
unsigned int flags;
int ret = 0;
char pcm_path[MAX_PCM_PATH_LEN];
#ifdef SUPPORT_STHAL_INTERFACE
/* Handle HOTWORD soure separately */
if (apstream->stream_type == ASTREAM_CAPTURE_HOTWORD) {
if (aproxy->sound_trigger_open_for_streaming) {
if (apstream->stream_usage == AUSAGE_HOTWORD_SEAMLESS) {
apstream->soundtrigger_handle = aproxy->sound_trigger_open_for_streaming();
} else {
apstream->soundtrigger_handle = aproxy->sound_trigger_open_recording();
}
if (apstream->soundtrigger_handle <= 0) {
ALOGE("%s: Failed to open VTS PCM Node for streaming", __func__);
ret = -EIO;
goto err_open;
}
#ifdef SEAMLESS_DUMP
apstream->fp = fopen("/data/seamdump.raw", "wr+");
if (!apstream->fp)
ALOGI("failed to open /data/seamdump.raw");
#endif
ALOGI("Opened VTS PCM Node successfully");
} else {
ALOGE("%s-%s: SoundTrigger HAL Open function Not available!",
stream_table[apstream->stream_type], __func__);
ret = -EIO;
}
apstream->need_update_pcm_config = false;
return ret;
}
#endif
if (is_active_usage_APCall(aproxy) && apstream->pcmconfig.rate != 48000) {
apstream->sound_card = PRIMARY_CAPTURE_CARD;
apstream->sound_device = get_pcm_device_number(aproxy, apstream);
apstream->pcmconfig = pcm_config_primary_capture;
check_conversion(apstream);
}
/* Get PCM Device */
sound_card = apstream->sound_card;
sound_device = apstream->sound_device;
/* Open Normal PCM Device */
if (apstream->pcm == NULL) {
if (apstream->stream_type == ASTREAM_CAPTURE_MMAP) {
flags = PCM_IN | PCM_MMAP | PCM_NOIRQ | PCM_MONOTONIC;
adjust_mmap_period_count(apstream, &apstream->pcmconfig, min_size_frames);
} else
flags = PCM_IN | PCM_MONOTONIC;
/* open WDMA pcm first to trigger DMA */
apstream->dma_pcm = pcm_open(sound_card, sound_device, flags, &apstream->pcmconfig);
if (apstream->dma_pcm && !pcm_is_ready(apstream->dma_pcm)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("%s-%s: PCM Device is not ready with Sampling_Rate(%u) error(%s)!",
stream_table[apstream->stream_type], __func__, apstream->pcmconfig.rate,
pcm_get_error(apstream->dma_pcm));
goto err_open;
}
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c", sound_card, sound_device, 'c');
ALOGI("%s-%s: The opened PCM Device is %s with Sampling_Rate(%u) PCM_Format(%d) Channel(%d)",
stream_table[apstream->stream_type], __func__, pcm_path,
apstream->pcmconfig.rate, apstream->pcmconfig.format, apstream->pcmconfig.channels);
/* Virtual dai PCM is required only for normal capture */
if (apstream->stream_type != ASTREAM_CAPTURE_LOW_LATENCY &&
apstream->stream_type != ASTREAM_CAPTURE_CALL &&
apstream->stream_type != ASTREAM_CAPTURE_FM_TUNER &&
apstream->stream_type != ASTREAM_CAPTURE_FM_RECORDING &&
apstream->stream_type != ASTREAM_CAPTURE_MMAP) {
/* WDMA pcm should be started before opening virtual pcm */
if (pcm_start(apstream->dma_pcm) == 0) {
ALOGI("proxy-%s: PCM Device(%s) with SR(%u) PF(%d) CC(%d) is started",
__func__, pcm_path, apstream->pcmconfig.rate, apstream->pcmconfig.format, apstream->pcmconfig.channels);
} else {
ALOGE("proxy-%s: PCM Device(%s) with SR(%u) PF(%d) CC(%d) cannot be started as error(%s)",
__func__, pcm_path, apstream->pcmconfig.rate, apstream->pcmconfig.format, apstream->pcmconfig.channels,
pcm_get_error(apstream->dma_pcm));
goto err_open;
}
apstream->pcm = pcm_open(VIRTUAL_PRIMARY_CAPTURE_CARD, VIRTUAL_PRIMARY_CAPTURE_DEVICE, flags, &apstream->pcmconfig);
if (apstream->pcm && !pcm_is_ready(apstream->pcm)) {
/* pcm_open does always return pcm structure, not NULL */
ALOGE("%s-%s: Virtual PCM Device is not ready with Sampling_Rate(%u) error(%s)!",
stream_table[apstream->stream_type], __func__, apstream->pcmconfig.rate,
pcm_get_error(apstream->pcm));
goto err_open;
}
snprintf(pcm_path, sizeof(pcm_path), "/dev/snd/pcmC%uD%u%c", VIRTUAL_PRIMARY_CAPTURE_CARD, VIRTUAL_PRIMARY_CAPTURE_DEVICE, 'c');
ALOGI("%s-%s: The opened Virtual PCM Device is %s with Sampling_Rate(%u) PCM_Format(%d) Channel(%d)",
stream_table[apstream->stream_type], __func__, pcm_path,
apstream->pcmconfig.rate, apstream->pcmconfig.format, apstream->pcmconfig.channels);
} else {
apstream->pcm = apstream->dma_pcm;
apstream->dma_pcm = NULL;
}
apstream->compress = NULL;
if (apstream->stream_type == ASTREAM_CAPTURE_MMAP) {
unsigned int offset1 = 0;
unsigned int frames1 = 0;
unsigned int buf_size = 0;
unsigned int mmap_size = 0;
ret = pcm_mmap_begin(apstream->pcm, &info->shared_memory_address, &offset1, &frames1);
if (ret == 0) {
ALOGI("%s-%s: PCM Device begin MMAP", stream_table[apstream->stream_type], __func__);
info->buffer_size_frames = pcm_get_buffer_size(apstream->pcm);
buf_size = pcm_frames_to_bytes(apstream->pcm, info->buffer_size_frames);
info->burst_size_frames = apstream->pcmconfig.period_size;
// get mmap buffer fd
ret = get_mmap_data_fd(proxy_stream, AUSAGE_CAPTURE,
&info->shared_memory_fd, &mmap_size);
if (ret < 0) {
// Fall back to poll_fd mode, shared mode
info->shared_memory_fd = pcm_get_poll_fd(apstream->pcm);
ALOGI("%s-%s: PCM Device MMAP Exclusive mode not support",
stream_table[apstream->stream_type], __func__);
} else {
if (mmap_size < buf_size) {
ALOGE("%s-%s: PCM Device MMAP buffer size not matching",
stream_table[apstream->stream_type], __func__);
goto err_open;
}
// FIXME: indicate exclusive mode support by returning a negative buffer size
info->buffer_size_frames *= -1;
}
memset(info->shared_memory_address, 0,
pcm_frames_to_bytes(apstream->pcm, info->buffer_size_frames));
ret = pcm_mmap_commit(apstream->pcm, 0, MMAP_PERIOD_SIZE);
if (ret < 0) {
ALOGE("%s-%s: PCM Device cannot commit MMAP with error(%s)",
stream_table[apstream->stream_type], __func__, pcm_get_error(apstream->pcm));
goto err_open;
} else {
ALOGI("%s-%s: PCM Device commit MMAP", stream_table[apstream->stream_type], __func__);
ret = 0;
}
} else {
ALOGE("%s-%s: PCM Device cannot begin MMAP with error(%s)",
stream_table[apstream->stream_type], __func__, pcm_get_error(apstream->pcm));
goto err_open;
}
}
/* HACK for MMAP/Low-latency capture path routing, normal recording uses virtualPCM DAI
* firmware component but MMAP/Low-latency case for reducing latency we have to capture
* data directly from WDMA, therefore VirtualPCM DAI is disabled after routing */
if (apstream->stream_type == ASTREAM_CAPTURE_MMAP ||
apstream->stream_type == ASTREAM_CAPTURE_LOW_LATENCY) {
proxy_set_mixer_value_string(aproxy, MIXER_CTL_ABOX_CATPURE_VPCMDAI_INSRC, "None");
ALOGI("%s-%s: MMAP VPCMIN_DAI0 component disconnect forcefully",
stream_table[apstream->stream_type], __func__);
}
} else
ALOGW("%s-%s: PCM Device is already opened!", stream_table[apstream->stream_type], __func__);
apstream->need_update_pcm_config = false;
return ret;
err_open:
proxy_close_capture_stream(proxy_stream);
return -ENODEV;
}
int proxy_start_capture_stream(void *proxy_stream)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
int ret = 0;
#ifdef SUPPORT_STHAL_INTERFACE
/* Handle HOTWORD soure separately */
if (apstream->stream_type == ASTREAM_CAPTURE_HOTWORD)
return ret;
#endif
// In case of PCM Playback, pcm_start call is not needed as auto-start
if (apstream->pcm) {
ret = pcm_start(apstream->pcm);
if (ret == 0)
ALOGI("%s-%s: started PCM Device", stream_table[apstream->stream_type], __func__);
else
ALOGE("%s-%s: cannot start PCM(%s)", stream_table[apstream->stream_type], __func__,
pcm_get_error(apstream->pcm));
}
return ret;
}
int proxy_read_capture_buffer(void *proxy_stream, void *buffer, int bytes)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
int frames_request = bytes / proxy_get_requested_frame_size(apstream);
int frames_actual = -1;
if (apstream->skip_ch_convert) {
frames_request = bytes / (proxy_get_actual_channel_count(apstream) *
audio_bytes_per_sample(apstream->requested_format));
}
#ifdef SUPPORT_STHAL_INTERFACE
int ret = 0, read = 0;
struct audio_proxy *aproxy = getInstance();
if (apstream->stream_type == ASTREAM_CAPTURE_HOTWORD) {
if (aproxy->sound_trigger_read_samples) {
if (apstream->soundtrigger_handle > 0) {
if (apstream->stream_usage == AUSAGE_HOTWORD_SEAMLESS) {
ret = aproxy->sound_trigger_read_samples(apstream->soundtrigger_handle,
buffer, bytes);
} else {
ret = aproxy->sound_trigger_read_recording_samples(buffer, bytes);
}
if (!ret) {
read = bytes;
#ifdef SEAMLESS_DUMP
if (apstream->fp ) {
fwrite((void*)buffer, bytes, 1, apstream->fp);
ALOGE("Model binary /data/seamdump.raw write completed");
} else
ALOGE("Error opening /sdcard/seamdump.raw");
#endif
}
}
} else {
ALOGE("%s-%s: SoundTrigger HAL Read function Not available!",
stream_table[apstream->stream_type], __func__);
}
return read;
} else
#endif
{
frames_actual = read_and_process_frames(apstream, buffer, frames_request);
ALOGVV("%s-%s: requested read frames = %d vs. actual processed read frames = %d",
stream_table[apstream->stream_type], __func__, frames_request, frames_actual);
}
if (frames_actual < 0) {
return frames_actual;
} else {
/* Saves read frames to calcurate timestamp */
apstream->frames += frames_actual;
ALOGVV("%s-%s: cumulative read = %u frames", stream_table[apstream->stream_type], __func__,
(unsigned int)apstream->frames);
return bytes;
}
}
int proxy_stop_capture_stream(void *proxy_stream)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
int ret = 0;
#ifdef SUPPORT_STHAL_INTERFACE
/* Handle HOTWORD soure separately */
if (apstream->stream_type == ASTREAM_CAPTURE_HOTWORD)
return ret;
#endif
if (apstream->pcm) {
ret = pcm_stop(apstream->pcm);
if (ret == 0)
ALOGI("%s-%s: stopped PCM Device", stream_table[apstream->stream_type], __func__);
else
ALOGE("%s-%s: cannot stop PCM(%s)", stream_table[apstream->stream_type], __func__,
pcm_get_error(apstream->pcm));
}
return ret;
}
int proxy_reconfig_capture_stream(void *proxy_stream, int type, void *config)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
audio_stream_type new_type = (audio_stream_type)type;
struct audio_config *new_config = (struct audio_config *)config;
if (apstream) {
apstream->stream_type = new_type;
apstream->requested_sample_rate = new_config->sample_rate;
apstream->requested_channel_mask = new_config->channel_mask;
apstream->requested_format = new_config->format;
// If some stream types need to be reset, it has to reconfigure conversions
return 0;
} else
return -1;
}
int proxy_reconfig_capture_usage(void *proxy_stream, int type, int usage)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
if (apstream == NULL)
return -1;
struct audio_proxy *aproxy = getInstance();
audio_stream_type stream_type = (audio_stream_type)type;
audio_usage stream_usage = (audio_usage)usage;
if (stream_usage != AUSAGE_NONE)
apstream->stream_usage = stream_usage;
switch (stream_type) {
case ASTREAM_CAPTURE_PRIMARY:
apstream->stream_type = stream_type;
apstream->sound_card = PRIMARY_CAPTURE_CARD;
apstream->sound_device = get_pcm_device_number(aproxy, apstream);
#ifdef SUPPORT_QUAD_MIC
if ((is_active_usage_CPCall(aproxy)
|| is_active_usage_APCall(aproxy)
|| apstream->stream_usage == AUSAGE_CAMCORDER)
&& is_quad_mic_device(aproxy->active_capture_device)) {
apstream->pcmconfig = pcm_config_primary_quad_mic_capture;
ALOGE("proxy-%s: Primary reconfig as Quad-Mic", __func__);
} else
#endif
apstream->pcmconfig = pcm_config_primary_capture;
update_capture_pcmconfig(apstream);
/*
** Reset previous configurations and release resampler if running
** for reconfiguration purpose
*/
apstream->need_channelconversion = false;
if (apstream->resampler) {
ALOGI("%s-%s: released resampler", stream_table[apstream->stream_type], __func__);
release_resampler(apstream->resampler);
apstream->resampler = NULL;
}
check_conversion(apstream);
break;
case ASTREAM_CAPTURE_CALL:
apstream->stream_type = stream_type;
apstream->sound_card = CALL_RECORD_CARD;
apstream->sound_device = get_pcm_device_number(aproxy, apstream);
apstream->pcmconfig = pcm_config_call_record;
check_conversion(apstream);
break;
default:
ALOGE("proxy-%s: failed to reconfig Proxy Stream as unknown stream type(%d)", __func__, stream_type);
return -1;
}
ALOGI("proxy-%s: reconfig Proxy Stream(%s)", __func__, stream_table[apstream->stream_type]);
return 0;
}
int proxy_get_capture_pos(void *proxy_stream, int64_t *frames, int64_t *time)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
unsigned int avail = 0;
struct timespec timestamp;
int ret = -ENOSYS;;
if (frames != NULL && time != NULL) {
*frames = 0;
*time = 0;
if (apstream->pcm) {
ret = pcm_get_htimestamp(apstream->pcm, &avail, &timestamp);
if (ret == 0) {
// Real frames which captured in from device
*frames = apstream->frames + avail;
// Nano Seconds Unit Time
*time = timestamp.tv_sec * 1000000000LL + timestamp.tv_nsec;
ret = 0;
}
}
} else {
ALOGE("%s-%s: Invalid Parameter with Null pointer parameter",
stream_table[apstream->stream_type], __func__);
ret = -EINVAL;
}
return ret;
}
int proxy_get_active_microphones(void *proxy_stream, void *array, int *count)
{
struct audio_proxy *aproxy = getInstance();
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
struct audio_microphone_characteristic_t *mic_array = array;
size_t *mic_count = (size_t *)count;
size_t actual_mic_count = 0;
int ret = 0;
if (apstream) {
if (apstream->stream_type == ASTREAM_CAPTURE_NO_ATTRIBUTE ||
apstream->stream_type == ASTREAM_CAPTURE_PRIMARY ||
apstream->stream_type == ASTREAM_CAPTURE_LOW_LATENCY ||
apstream->stream_type == ASTREAM_CAPTURE_MMAP) {
device_type active_device = aproxy->active_capture_device;
if (active_device == DEVICE_NONE) {
ALOGE("%s-%s: There are no active MIC", stream_table[apstream->stream_type], __func__);
ret = -ENOSYS;
}
if (*mic_count == 0) {
if (active_device == DEVICE_STEREO_MIC)
actual_mic_count = 2;
else
actual_mic_count = 1;
ALOGI("proxy-%s: requested number of microphone, return %zu", __func__, *mic_count);
} else {
if (active_device == DEVICE_STEREO_MIC) {
for (int i = 0; i < 2; i++) {
mic_array[i] = aproxy->mic_info[i];
ALOGD("%s-%s: %dth MIC = %s", stream_table[apstream->stream_type], __func__,
i+1, mic_array[i].device_id);
actual_mic_count++;
}
} else if (active_device == DEVICE_MAIN_MIC) {
mic_array[0] = aproxy->mic_info[0];
ALOGD("%s-%s: Active MIC = %s", stream_table[apstream->stream_type], __func__,
mic_array[0].device_id);
actual_mic_count = 1;
} else if (active_device == DEVICE_SUB_MIC) {
mic_array[0] = aproxy->mic_info[1];
ALOGD("%s-%s: Active MIC = %s", stream_table[apstream->stream_type], __func__,
mic_array[0].device_id);
actual_mic_count = 1;
} else {
ALOGE("%s-%s: Abnormal active device(%s)", stream_table[apstream->stream_type],
__func__, device_table[active_device]);
ret = -ENOSYS;
}
}
} else {
ALOGE("%s-%s: This stream doesn't have active MIC", stream_table[apstream->stream_type],
__func__);
ret = -ENOSYS;
}
} else {
ALOGE("proxy-%s: apstream is NULL", __func__);
ret = -ENOSYS;
}
*mic_count = actual_mic_count;
return ret;
}
int proxy_getparam_capture_stream(void *proxy_stream, void *query_params, void *reply_params)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
struct audio_proxy *aproxy = getInstance();
struct str_parms *query = (struct str_parms *)query_params;
struct str_parms *reply = (struct str_parms *)reply_params;
if (proxy_is_usb_capture_device_connected(aproxy->usb_aproxy)) {
// get USB capture param information
proxy_usb_getparam_capture_stream(getInstance()->usb_aproxy, query, reply);
} else {
/*
* Supported Audio Configuration can be different as Target Project.
* AudioHAL engineers have to modify these codes based on Target Project.
*/
// supported audio formats
if (str_parms_has_key(query, AUDIO_PARAMETER_STREAM_SUP_FORMATS)) {
char formats_list[256];
memset(formats_list, 0, 256);
strncpy(formats_list, stream_format_table[apstream->stream_type],
strlen(stream_format_table[apstream->stream_type]));
str_parms_add_str(reply, AUDIO_PARAMETER_STREAM_SUP_FORMATS, formats_list);
}
// supported audio channel masks
if (str_parms_has_key(query, AUDIO_PARAMETER_STREAM_SUP_CHANNELS)) {
char channels_list[256];
memset(channels_list, 0, 256);
strncpy(channels_list, stream_channel_table[apstream->stream_type],
strlen(stream_channel_table[apstream->stream_type]));
str_parms_add_str(reply, AUDIO_PARAMETER_STREAM_SUP_CHANNELS, channels_list);
}
// supported audio samspling rates
if (str_parms_has_key(query, AUDIO_PARAMETER_STREAM_SUP_SAMPLING_RATES)) {
char rates_list[256];
memset(rates_list, 0, 256);
strncpy(rates_list, stream_rate_table[apstream->stream_type],
strlen(stream_rate_table[apstream->stream_type]));
str_parms_add_str(reply, AUDIO_PARAMETER_STREAM_SUP_SAMPLING_RATES, rates_list);
}
}
return 0;
}
int proxy_setparam_capture_stream(void *proxy_stream, void *parameters)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
struct audio_proxy *aproxy = getInstance();
int ret = 0;
if (proxy_is_usb_capture_device_connected(aproxy->usb_aproxy)) {
/* Set USB parameters */
ret = proxy_usb_setparam_capture_stream(aproxy->usb_aproxy, parameters);
}
return ret;
}
void proxy_dump_capture_stream(void *proxy_stream, int fd)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
const size_t len = 256;
char buffer[len];
if (apstream->pcm != NULL) {
snprintf(buffer, len, "\tinput pcm config sample rate: %d\n",apstream->pcmconfig.rate);
write(fd,buffer,strlen(buffer));
snprintf(buffer, len, "\tinput pcm config period size : %d\n",apstream->pcmconfig.period_size);
write(fd,buffer,strlen(buffer));
snprintf(buffer, len, "\tinput pcm config format: %d\n",apstream->pcmconfig.format);
write(fd,buffer,strlen(buffer));
}
return ;
}
void proxy_update_capture_usage(void *proxy_stream, int usage)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
audio_usage stream_usage = (audio_usage)usage;
if(apstream) {
apstream->stream_usage = stream_usage;
ALOGD("proxy-%s: apstream->stream_usage = %d", __func__, apstream->stream_usage);
} else {
ALOGD("proxy-%s: apstream is NULL", __func__);
}
return ;
}
int proxy_get_mmap_position(void *proxy_stream, void *pos)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
struct audio_mmap_position *position = (struct audio_mmap_position *)pos;
int ret = -ENOSYS;
if ((apstream->stream_type == ASTREAM_PLAYBACK_MMAP || apstream->stream_type == ASTREAM_CAPTURE_MMAP)&&
apstream->pcm) {
struct timespec ts = { 0, 0 };
ret = pcm_mmap_get_hw_ptr(apstream->pcm, (unsigned int *)&position->position_frames, &ts);
if (ret < 0) {
ALOGE("proxy-%s: get_hw_ptr error %s ", __func__, pcm_get_error(apstream->pcm));
} else if (ret == 0) {
position->time_nanoseconds = audio_utils_ns_from_timespec(&ts);
}
}
return ret;
}
/******************************************************************************/
/** **/
/** Interfaces for Audio Device Proxy **/
/** **/
/******************************************************************************/
/*
* Route Control Functions
*/
bool proxy_init_route(void *proxy, char *path)
{
struct audio_proxy *aproxy = proxy;
struct audio_route *ar = NULL;
bool ret = false;
if (aproxy) {
aproxy->mixer = mixer_open(MIXER_CARD0);
proxy_set_mixercontrol(aproxy, TICKLE_CONTROL, ABOX_TICKLE_ON);
if (aproxy->mixer) {
// In order to get add event, subscription has to be here!
mixer_subscribe_events(aproxy->mixer, 1);
ar = audio_route_init(MIXER_CARD0, path);
if (!ar) {
ALOGE("proxy-%s: failed to init audio route", __func__);
mixer_subscribe_events(aproxy->mixer, 0);
mixer_close(aproxy->mixer);
aproxy->mixer = NULL;
} else {
aproxy->aroute = ar;
aproxy->xml_path = strdup(path); // Save Mixer Paths XML File path
aproxy->active_playback_ausage = AUSAGE_NONE;
aproxy->active_playback_device = DEVICE_NONE;
aproxy->active_playback_modifier = MODIFIER_NONE;
aproxy->active_capture_ausage = AUSAGE_NONE;
aproxy->active_capture_device = DEVICE_NONE;
aproxy->active_capture_modifier = MODIFIER_NONE;
ALOGI("proxy-%s: opened Mixer & initialized audio route", __func__);
ret = true;
/* Create Mixer Control Update Thread */
pthread_rwlock_init(&aproxy->mixer_update_lock, NULL);
if (audio_route_missing_ctl(ar)) {
pthread_create(&aproxy->mixer_update_thread, NULL, mixer_update_loop, aproxy);
ALOGI("proxy-%s: missing control found, update thread is created", __func__);
} else
mixer_subscribe_events(aproxy->mixer, 0);
}
} else
ALOGE("proxy-%s: failed to open Mixer", __func__);
}
return ret;
}
void proxy_deinit_route(void *proxy)
{
struct audio_proxy *aproxy = proxy;
if (aproxy) {
pthread_rwlock_wrlock(&aproxy->mixer_update_lock);
if (aproxy->aroute) {
audio_route_free(aproxy->aroute);
aproxy->aroute = NULL;
}
if (aproxy->mixer) {
mixer_close(aproxy->mixer);
aproxy->mixer = NULL;
}
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
pthread_rwlock_destroy(&aproxy->mixer_update_lock);
free(aproxy->xml_path);
}
ALOGI("proxy-%s: closed Mixer & deinitialized audio route", __func__);
return ;
}
bool proxy_update_route(void *proxy, int ausage, int device)
{
struct audio_proxy *aproxy = proxy;
audio_usage __unused routed_ausage = (audio_usage)ausage;
device_type __unused routed_device = (device_type)device;
// Temp
if (aproxy != NULL) {
routed_ausage = AUSAGE_NONE;
routed_device = DEVICE_NONE;
}
return true;
}
bool proxy_set_route(void *proxy, int ausage, int device, int modifier, bool set)
{
struct audio_proxy *aproxy = proxy;
char path_name[MAX_PATH_NAME_LEN];
audio_usage routed_ausage = (audio_usage)ausage;
device_type routed_device = (device_type)device;
audio_usage active_ausage = AUSAGE_NONE;
device_type active_device = DEVICE_NONE;
modifier_type routed_modifier = (modifier_type)modifier;
#ifdef SUPPORT_DUAL_SPEAKER
// HACK: Force dual speaker
if (routed_device == DEVICE_SPEAKER)
routed_device = DEVICE_SPEAKER_DUAL;
#endif
if (set) {
/* check whether path routing is for AP/CP call bandwidth or speaker/DEX Device Change */
if (routed_device < DEVICE_MAIN_MIC) {
active_ausage = aproxy->active_playback_ausage;
active_device = aproxy->active_playback_device;
} else {
active_ausage = aproxy->active_capture_ausage;
active_device = aproxy->active_capture_device;
}
if (is_usage_Call(active_ausage) &&
is_usage_Call(routed_ausage)) {
/* check whether internal path nodes close/re-open should be skipped,
* for following scenarios
* - cp call bandwidth change
* - Dex speaker device state change during ap/cp call
*/
if (((active_ausage != routed_ausage) && (active_device == routed_device) &&
(is_usage_CPCall(active_ausage) && is_usage_CPCall(routed_ausage))) ||
((active_ausage == routed_ausage) && (active_device != routed_device) &&
is_device_speaker(routed_device) && is_device_speaker(active_device))) {
ALOGI("proxy-%s: skip output path loopback PCMs re-open",
__func__);
ALOGI("proxy-%s: active-device(%s) requested-device(%s)", __func__,
device_table[active_device],
device_table[routed_device]);
aproxy->skip_internalpath = true;
}
}
if (routed_device < DEVICE_MAIN_MIC) {
/* Do Specific Operation based on Audio Path */
do_operations_by_playback_route_set(aproxy, routed_ausage, routed_device);
if (aproxy->active_playback_ausage != AUSAGE_NONE &&
aproxy->active_playback_device != DEVICE_NONE) {
disable_internal_path(aproxy, aproxy->active_playback_ausage,
aproxy->active_playback_device);
set_reroute(aproxy, aproxy->active_playback_ausage, aproxy->active_playback_device,
routed_ausage, routed_device);
} else
set_route(aproxy, routed_ausage, routed_device);
aproxy->active_playback_ausage = routed_ausage;
aproxy->active_playback_device = routed_device;
// Audio Path Modifier for Playback Path
if (routed_modifier < MODIFIER_BT_SCO_TX_NB) {
if (aproxy->active_playback_modifier == MODIFIER_NONE)
set_modifier(aproxy, routed_modifier);
else
update_modifier(aproxy, aproxy->active_playback_modifier, routed_modifier);
} else if (routed_modifier == MODIFIER_NONE && aproxy->active_playback_modifier != MODIFIER_NONE)
reset_modifier(aproxy, aproxy->active_playback_modifier);
if (routed_device == DEVICE_USB_HEADSET ||
routed_device == DEVICE_SPEAKER_AND_USB_HEADSET) {
/* set USB gain controls if required */
make_path(routed_ausage, routed_device, path_name);
proxy_usb_set_gain(aproxy->usb_aproxy, path_name);
}
aproxy->active_playback_modifier = routed_modifier;
// Set Loopback for Playback Path
enable_internal_path(aproxy, routed_ausage, routed_device);
if (ausage == AUSAGE_FM_RADIO_CAPTURE || ausage == AUSAGE_FM_RADIO_TUNER) {
/* Open/Close FM Radio PCM node based on Enable/disable */
proxy_start_fm_radio(aproxy);
}
} else {
// Audio Path Routing for Capture Path
if (aproxy->active_capture_ausage != AUSAGE_NONE &&
aproxy->active_capture_device != DEVICE_NONE) {
disable_internal_path(aproxy, aproxy->active_capture_ausage,
aproxy->active_capture_device);
set_reroute(aproxy, aproxy->active_capture_ausage, aproxy->active_capture_device,
routed_ausage, routed_device);
} else {
// In case of capture routing setup, it needs A-Box early-wakeup
proxy_set_mixercontrol(aproxy, TICKLE_CONTROL, ABOX_TICKLE_ON);
set_route(aproxy, routed_ausage, routed_device);
}
aproxy->active_capture_ausage = routed_ausage;
aproxy->active_capture_device = routed_device;
// Audio Path Modifier for Capture Path
if (routed_modifier >= MODIFIER_BT_SCO_TX_NB && routed_modifier < MODIFIER_NONE) {
if (aproxy->active_capture_modifier == MODIFIER_NONE)
set_modifier(aproxy, routed_modifier);
else
update_modifier(aproxy, aproxy->active_capture_modifier, routed_modifier);
} else if (routed_modifier == MODIFIER_NONE && aproxy->active_capture_modifier != MODIFIER_NONE)
reset_modifier(aproxy, aproxy->active_capture_modifier);
if (is_usb_mic_device(routed_device)) {
/* set USB gain controls if required */
make_path(routed_ausage, routed_device, path_name);
proxy_usb_set_gain(aproxy->usb_aproxy, path_name);
}
aproxy->active_capture_modifier = routed_modifier;
// Set Loopback for Capture Path
enable_internal_path(aproxy, routed_ausage, routed_device);
}
} else {
/* Do Specific Operation based on Audio Path */
if (routed_device < DEVICE_MAIN_MIC)
do_operations_by_playback_route_reset(aproxy);
// Reset Loopback
disable_internal_path(aproxy, routed_ausage, routed_device);
// Audio Path Modifier
if (routed_modifier != MODIFIER_NONE) {
reset_modifier(aproxy, routed_modifier);
if (routed_modifier < MODIFIER_BT_SCO_TX_NB)
aproxy->active_playback_modifier = MODIFIER_NONE;
else
aproxy->active_capture_modifier = MODIFIER_NONE;
} else {
aproxy->active_playback_modifier = MODIFIER_NONE;
aproxy->active_capture_modifier = MODIFIER_NONE;
}
if (routed_device == DEVICE_USB_HEADSET ||
routed_device == DEVICE_SPEAKER_AND_USB_HEADSET ||
is_usb_mic_device(routed_device)) {
/* reset USB gain controls */
make_path(routed_ausage, routed_device, path_name);
proxy_usb_reset_gain(aproxy->usb_aproxy, path_name);
}
// Audio Path Routing
reset_route(aproxy, routed_ausage, routed_device);
if (routed_device < DEVICE_MAIN_MIC) {
aproxy->active_playback_ausage = AUSAGE_NONE;
aproxy->active_playback_device = DEVICE_NONE;
} else {
aproxy->active_capture_ausage = AUSAGE_NONE;
aproxy->active_capture_device = DEVICE_NONE;
}
}
/* reset voicecall bandwidth change flag */
aproxy->skip_internalpath = false;
return true;
}
/*
* Proxy Voice Call Control
*/
void proxy_stop_voice_call(void *proxy)
{
struct audio_proxy *aproxy = (struct audio_proxy *)proxy;
voice_rx_stop(aproxy);
voice_tx_stop(aproxy);
return ;
}
void proxy_start_voice_call(void *proxy)
{
struct audio_proxy *aproxy = (struct audio_proxy *)proxy;
voice_rx_start(aproxy);
/*
** Voice TX and FM Radio are sharing same WDMA.
** So, it needs to check and close WDMA when FM Radio is working at Voice Call Start.
*/
if (aproxy->fm_playback != NULL && aproxy->fm_capture != NULL) {
fmradio_playback_stop(aproxy);
fmradio_capture_stop(aproxy);
}
voice_tx_start(aproxy);
return ;
}
/*
* Proxy FM Radio Control
*/
void proxy_stop_fm_radio(void *proxy)
{
struct audio_proxy *aproxy = (struct audio_proxy *)proxy;
fmradio_playback_stop(aproxy);
fmradio_capture_stop(aproxy);
return ;
}
void proxy_start_fm_radio(void *proxy)
{
struct audio_proxy *aproxy = (struct audio_proxy *)proxy;
fmradio_playback_start(aproxy);
fmradio_capture_start(aproxy);
return ;
}
// General Mixer Control Functions
int proxy_get_mixer_value_int(void *proxy, const char *name)
{
struct audio_proxy *aproxy = proxy;
struct mixer_ctl *ctrl = NULL;
int ret = -1;
if (name == NULL)
return ret;
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
ctrl = mixer_get_ctl_by_name(aproxy->mixer, name);
if (ctrl) {
ret = mixer_ctl_get_value(ctrl, 0);
} else {
ALOGE("proxy-%s: cannot find %s Mixer Control", __func__, name);
}
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ret;
}
int proxy_get_mixer_value_array(void *proxy, const char *name, void *value, int count)
{
struct audio_proxy *aproxy = proxy;
struct mixer_ctl *ctrl = NULL;
int ret = -1;
if (name == NULL)
return ret;
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
ctrl = mixer_get_ctl_by_name(aproxy->mixer, name);
if (ctrl) {
ret = mixer_ctl_get_array(ctrl, value, count);
} else {
ALOGE("proxy-%s: cannot find %s Mixer Control", __func__, name);
}
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ret;
}
void proxy_set_mixer_value_int(void *proxy, const char *name, int value)
{
struct audio_proxy *aproxy = proxy;
struct mixer_ctl *ctrl = NULL;
int ret = 0, val = value;
if (name == NULL)
return ;
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
ctrl = mixer_get_ctl_by_name(aproxy->mixer, name);
if (ctrl) {
ret = mixer_ctl_set_value(ctrl, 0, val);
if (ret != 0)
ALOGE("proxy-%s: failed to set %s", __func__, name);
} else {
ALOGE("proxy-%s: cannot find %s Mixer Control", __func__, name);
}
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ;
}
void proxy_set_mixer_value_string(void *proxy, const char *name, const char *value)
{
struct audio_proxy *aproxy = proxy;
struct mixer_ctl *ctrl = NULL;
int ret = 0;
if (name == NULL)
return ;
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
ctrl = mixer_get_ctl_by_name(aproxy->mixer, name);
if (ctrl) {
ret = mixer_ctl_set_enum_by_string(ctrl, value);
if (ret != 0)
ALOGE("proxy-%s: failed to set %s", __func__, name);
} else {
ALOGE("proxy-%s: cannot find %s Mixer Control", __func__, name);
}
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ;
}
void proxy_set_mixer_value_array(void *proxy, const char *name, const void *value, int count)
{
struct audio_proxy *aproxy = proxy;
struct mixer_ctl *ctrl = NULL;
int ret = 0;
if (aproxy == NULL)
aproxy = getInstance();
if (name == NULL)
return ;
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
ctrl = mixer_get_ctl_by_name(aproxy->mixer, name);
if (ctrl) {
ret = mixer_ctl_set_array(ctrl, value, count);
if (ret != 0)
ALOGE("proxy-%s: failed to set %s", __func__, name);
} else {
ALOGE("proxy-%s: cannot find %s Mixer Control", __func__, name);
}
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ;
}
void proxy_set_audio_interface(void *proxy, unsigned int interface, unsigned int sample_rate,
unsigned int bit_width, unsigned int channel)
{
struct audio_proxy *aproxy = proxy;
if (aproxy == NULL)
return ;
if (interface == UAIF0) {
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF0_SWITCH, MIXER_OFF);
/* SIFS0 Switch Off/On control is required only when SISF0 connected to UAIF0 */
if (aproxy->active_playback_device == DEVICE_HEADPHONE ||
aproxy->active_playback_device == DEVICE_HEADSET ||
aproxy->active_playback_device == DEVICE_SPEAKER_AND_HEADPHONE ||
aproxy->active_playback_device == DEVICE_SPEAKER_AND_HEADSET)
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_SIFS0_SWITCH, MIXER_OFF);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF0_SAMPLERATE, sample_rate);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF0_WIDTH, bit_width);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF0_CHANNEL, channel);
/* skip SIFS0 configuration for USB device */
if (!(aproxy->active_playback_device == DEVICE_USB_HEADSET ||
aproxy->active_playback_device == DEVICE_SPEAKER_AND_USB_HEADSET)) {
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_SIFS0_SAMPLERATE, sample_rate);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_SIFS0_WIDTH, bit_width);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_SIFS0_CHANNEL, channel);
} else {
ALOGI("proxy-%s: skip SIFS0 config for %d", __func__, aproxy->active_playback_device);
}
if (aproxy->active_playback_device == DEVICE_HEADPHONE ||
aproxy->active_playback_device == DEVICE_HEADSET ||
aproxy->active_playback_device == DEVICE_SPEAKER_AND_HEADPHONE ||
aproxy->active_playback_device == DEVICE_SPEAKER_AND_HEADSET)
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_SIFS0_SWITCH, MIXER_ON);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF0_SWITCH, MIXER_ON);
} else if (interface == UAIF1) {
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF1_SWITCH, MIXER_OFF);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF1_SAMPLERATE, sample_rate);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF1_WIDTH, bit_width);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF1_CHANNEL, channel);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF1_SWITCH, MIXER_ON);
} else if (interface == UAIF2) {
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF2_SWITCH, MIXER_OFF);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF2_SAMPLERATE, sample_rate);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF2_WIDTH, bit_width);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF2_CHANNEL, channel);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF2_SWITCH, MIXER_ON);
} else if (interface == UAIF3) {
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF3_SWITCH, MIXER_OFF);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF3_SAMPLERATE, sample_rate);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF3_WIDTH, bit_width);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF3_CHANNEL, channel);
proxy_set_mixer_value_int(proxy, MIXER_CTL_ABOX_UAIF3_SWITCH, MIXER_ON);
}
return ;
}
// Specific Mixer Control Functions
void proxy_set_audiomode(void *proxy, int audiomode)
{
struct audio_proxy *aproxy = proxy;
struct mixer_ctl *ctrl = NULL;
int ret = 0, val = audiomode;
aproxy->audio_mode = val; // set audio mode
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
/* Set Audio Mode to Kernel */
ctrl = mixer_get_ctl_by_name(aproxy->mixer, ABOX_AUDIOMODE_CONTROL_NAME);
if (ctrl) {
ret = mixer_ctl_set_value(ctrl, 0,val);
if (ret != 0)
ALOGE("proxy-%s: failed to set Android AudioMode to Kernel", __func__);
} else {
ALOGE("proxy-%s: cannot find AudioMode Mixer Control", __func__);
}
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ;
}
void proxy_set_volume(void *proxy, int volume_type, float left, float right)
{
struct audio_proxy *aproxy = proxy;
struct mixer_ctl *ctrl = NULL;
int ret = -ENAVAIL;
int val[2];
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
if (volume_type == VOLUME_TYPE_OFFLOAD) {
val[0] = (int)(left * COMPRESS_PLAYBACK_VOLUME_MAX);
val[1] = (int)(right * COMPRESS_PLAYBACK_VOLUME_MAX);
ctrl = mixer_get_ctl_by_name(aproxy->mixer, OFFLOAD_VOLUME_CONTROL_NAME);
}
if (ctrl) {
if (volume_type == VOLUME_TYPE_OFFLOAD)
ret = mixer_ctl_set_array(ctrl, val, sizeof(val)/sizeof(val[0]));
if (ret != 0)
ALOGE("proxy-%s: failed to set Volume", __func__);
else
ALOGV("proxy-%s: set Volume(%f:%f) => (%d:%d)", __func__, left, right, val[0], val[1]);
} else {
ALOGE("proxy-%s: cannot find Volume Control", __func__);
}
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return;
}
void proxy_clear_apcall_txse(void)
{
struct audio_proxy *aproxy = getInstance();
char basic_path_name[MAX_PATH_NAME_LEN];
char path_name[MAX_PATH_NAME_LEN];
audio_usage ausage = aproxy->active_capture_ausage;
memset(path_name, 0, MAX_PATH_NAME_LEN);
if (snprintf(path_name, MAX_PATH_NAME_LEN - 1, "set-%s-txse", usage_path_table[ausage]) < 0) {
ALOGE("proxy-%s: path name has error: %s", __func__, strerror(errno));
return;
}
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
audio_route_reset_and_update_path(aproxy->aroute, path_name);
ALOGI("proxy-%s: %s is disabled", __func__, path_name);
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ;
}
void proxy_set_apcall_txse(void)
{
struct audio_proxy *aproxy = getInstance();
char basic_path_name[MAX_PATH_NAME_LEN];
char path_name[MAX_PATH_NAME_LEN];
audio_usage ausage = aproxy->active_capture_ausage;
memset(path_name, 0, MAX_PATH_NAME_LEN);
if (snprintf(path_name, MAX_PATH_NAME_LEN - 1, "set-%s-txse", usage_path_table[ausage]) < 0) {
ALOGE("proxy-%s: path name has error: %s", __func__, strerror(errno));
return;
}
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
audio_route_apply_and_update_path(aproxy->aroute, path_name);
ALOGI("proxy-%s: %s is enabled", __func__, path_name);
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ;
}
void proxy_set_upscale(void *proxy, int sampling_rate, int pcm_format)
{
struct audio_proxy *aproxy = proxy;
struct mixer_ctl *ctrl = NULL;
int ret = 0, val = (int)UPSCALE_NONE;
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
/* Set Compress Offload Upscaling Info to Kernel */
ctrl = mixer_get_ctl_by_name(aproxy->mixer, OFFLOAD_UPSCALE_CONTROL_NAME);
if (ctrl) {
if (sampling_rate == 48000 && (audio_format_t)pcm_format == AUDIO_FORMAT_PCM_SUB_16_BIT)
val = (int)UPSCALE_48K_16B;
else if ((audio_format_t)pcm_format == AUDIO_FORMAT_PCM_SUB_16_BIT) {
if (sampling_rate == 48000)
val = (int)UPSCALE_48K_24B;
else if (sampling_rate == 192000)
val = (int)UPSCALE_192K_24B;
else if (sampling_rate == 384000)
val = (int)UPSCALE_384K_24B;
}
if (val != (int)UPSCALE_NONE) {
ret = mixer_ctl_set_value(ctrl, 0, val);
if (ret != 0)
ALOGE("proxy-%s: failed to set Offload Upscale Info to Kernel", __func__);
else
ALOGV("proxy-%s: set Offload Upscale Info as %d", __func__, val);
} else
ALOGE("proxy-%s: invalid Offload Upscale Info", __func__);
} else {
ALOGE("proxy-%s: cannot find Offload Upscale Info Mixer Control", __func__);
}
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return;
}
#ifdef SUPPORT_STHAL_INTERFACE
__attribute__ ((visibility ("default")))
int notify_sthal_status(int hwdmodel_state)
{
struct audio_proxy *aproxy = getInstance();
/* update sthal 'ok Google' model recognization status
true : means recognization started
false : means recognization stopped
*/
aproxy->sthal_state = hwdmodel_state;
ALOGD("proxy-%s: Ok-Google Model Recognition [%s]", __func__,
(hwdmodel_state ? "STARTED" : "STOPPED"));
return 0;
}
int proxy_check_sthalstate(void *proxy)
{
struct audio_proxy *aproxy = (struct audio_proxy *)proxy;
return aproxy->sthal_state;
}
#endif
void proxy_call_status(void *proxy, int status)
{
struct audio_proxy *aproxy = (struct audio_proxy *)proxy;
/* status : TRUE means call starting
FALSE means call stopped
*/
if (status)
aproxy->call_state = true;
else
aproxy->call_state = false;
#ifdef SUPPORT_STHAL_INTERFACE
/* Send call status notification to STHAL */
if (aproxy->sound_trigger_voicecall_status) {
aproxy->sound_trigger_voicecall_status(status);
}
ALOGD("proxy-%s: Call notification to STHAL [%s]", __func__,
(status ? "STARTING" : "STOPPED"));
#endif
return;
}
int proxy_set_parameters(void *proxy, void *parameters)
{
struct audio_proxy *aproxy = (struct audio_proxy *)proxy;
struct str_parms *parms = (struct str_parms *)parameters;
char value[256];
int val;
int ret = 0; // for parameter handling
int status = 0; // for return value
ret = str_parms_get_int(parms, AUDIO_PARAMETER_DEVICE_CONNECT, &val);
if (ret >= 0) {
if ((audio_devices_t)val == AUDIO_DEVICE_IN_WIRED_HEADSET) {
ALOGD("proxy-%s: Headset Device connected 0x%x", __func__, val);
#ifdef SUPPORT_STHAL_INTERFACE
if (aproxy->sound_trigger_headset_status) {
aproxy->sound_trigger_headset_status(true);
}
#endif
} else if ((audio_devices_t)val == AUDIO_DEVICE_OUT_BLUETOOTH_A2DP ||
(audio_devices_t)val == AUDIO_DEVICE_OUT_BLUETOOTH_A2DP_HEADPHONES ||
(audio_devices_t)val == AUDIO_DEVICE_OUT_BLUETOOTH_A2DP_SPEAKER) {
ALOGI("proxy-%s: connected BT A2DP Out Device", __func__);
#ifdef SUPPORT_BTA2DP_OFFLOAD
if (aproxy->support_bta2dp) {
ret = str_parms_get_int(parms, AUDIO_PARAMETER_STREAM_FORMAT, &val);
if (ret >= 0) {
if (audio_is_bt_offload_format((audio_format_t)val)) {
pthread_mutex_lock(&aproxy->a2dp_lock);
if (!aproxy->a2dp_out_enabled) {
status = proxy_a2dp_open();
if (status == 0) {
aproxy->a2dp_out_enabled = true;
ALOGI("proxy-%s: set BT A2DP Offload Enabled & Open A2DP", __func__);
if (aproxy->a2dp_suspend) {
// a2dp suspend off -> bt offlaod on case
ALOGI("proxy-%s: set A2DP Suspend Flag", __func__);
proxy_a2dp_suspend(true); // set suspend a2dp open
/* modified by samsung convgergence */
set_a2dp_suspend_mixer(MIXER_ON);
} else if (is_active_playback_device_bta2dp(aproxy)) {
bta2dp_playback_start(aproxy); // bt path already enabled, then bta2dp_playback_start hear
}
}
}
pthread_mutex_unlock(&aproxy->a2dp_lock);
}
}
}
#endif
}
}
ret = str_parms_get_int(parms, AUDIO_PARAMETER_DEVICE_DISCONNECT, &val);
if (ret >= 0) {
if ((audio_devices_t)val == AUDIO_DEVICE_IN_WIRED_HEADSET) {
ALOGD("proxy-%s: Headset Device disconnected 0x%x", __func__, val);
#ifdef SUPPORT_STHAL_INTERFACE
if (aproxy->sound_trigger_headset_status) {
aproxy->sound_trigger_headset_status(false);
}
#endif
} else if ((audio_devices_t)val == AUDIO_DEVICE_OUT_BLUETOOTH_A2DP ||
(audio_devices_t)val == AUDIO_DEVICE_OUT_BLUETOOTH_A2DP_HEADPHONES ||
(audio_devices_t)val == AUDIO_DEVICE_OUT_BLUETOOTH_A2DP_SPEAKER) {
ALOGI("proxy-%s: disconnected BT A2DP Out Device", __func__);
#ifdef SUPPORT_BTA2DP_OFFLOAD
if (aproxy->support_bta2dp) {
pthread_mutex_lock(&aproxy->a2dp_lock);
if (aproxy->a2dp_out_enabled) {
status = proxy_a2dp_close();
if (status == 0) {
aproxy->a2dp_out_enabled = false;
aproxy->a2dp_delay = 0;
ALOGI("proxy-%s: set BT A2DP Offload Disabled & Close A2DP", __func__);
}
}
pthread_mutex_unlock(&aproxy->a2dp_lock);
}
#endif
}
}
#ifdef SUPPORT_BTA2DP_OFFLOAD
/* BT A2DP Specific */
ret = str_parms_get_str(parms, "A2dpSuspended", value, sizeof(value));
if (ret >= 0 && aproxy->support_bta2dp) {
pthread_mutex_lock(&aproxy->a2dp_lock);
bool cur_state = proxy_a2dp_is_suspended();
if(strncmp(value, "true", 4) == 0) {
if (aproxy->a2dp_out_enabled) { // send suspend call to hidl, only a2dp_offload ON
proxy_a2dp_suspend(true);
ALOGI("proxy-%s: set A2DP Suspend Flag", __func__);
}
/* modified by samsung convgergence */
set_a2dp_suspend_mixer(MIXER_ON);
aproxy->a2dp_suspend = true;
} else {
proxy_a2dp_suspend(false);
if (is_active_playback_device_bta2dp(aproxy) && cur_state) {
bta2dp_playback_start(aproxy); // start bt a2dp on suspend t -> f state
}
ALOGI("proxy-%s: cleared A2DP Suspend Flag", __func__);
/* modified by samsung convgergence */
set_a2dp_suspend_mixer(MIXER_OFF);
aproxy->a2dp_suspend = false;
}
pthread_mutex_unlock(&aproxy->a2dp_lock);
}
ret = str_parms_get_str(parms, "bt_offload_enable", value, sizeof(value));
if (ret >= 0 && aproxy->support_bta2dp) {
pthread_mutex_lock(&aproxy->a2dp_lock);
val = atoi(value);
if (val == 1 && aproxy->a2dp_out_enabled == false) {
status = proxy_a2dp_open();
if (status == 0) {
aproxy->a2dp_out_enabled = true;
ALOGI("proxy-%s: set BT A2DP Offload Enabled & Open A2DP", __func__);
if (aproxy->a2dp_suspend) {
// a2dp suspend off -> bt offlaod on case
ALOGI("proxy-%s: set A2DP Suspend Flag", __func__);
proxy_a2dp_suspend(true); // set suspend a2dp open
/* modified by samsung convgergence */
set_a2dp_suspend_mixer(MIXER_ON);
} else if (is_active_playback_device_bta2dp(aproxy)) {
bta2dp_playback_start(aproxy); // bt path already enabled, then bta2dp_playback_start hear
}
}
} else if (val == 0 && aproxy->a2dp_out_enabled == true) {
status = proxy_a2dp_close();
if (status == 0) {
aproxy->a2dp_out_enabled = false;
aproxy->a2dp_delay = 0;
ALOGI("proxy-%s: set BT A2DP Offload Disabled & Close A2DP", __func__);
}
}
pthread_mutex_unlock(&aproxy->a2dp_lock);
}
ret = str_parms_get_str(parms, "A2dpDelayReport", value, sizeof(value));
if (ret >= 0 && aproxy->support_bta2dp) {
pthread_mutex_lock(&aproxy->a2dp_lock);
val = atoi(value);
/* adjustment value to make presentation position as fast as adjust_latency(ms) */
if (val > A2DP_CAL_LATENCY_VAL)
val = val - A2DP_CAL_LATENCY_VAL;
else
val = 0;
ALOGI("proxy-%s: set BT A2DP Delay as %d ms", __func__, val);
aproxy->a2dp_delay = (uint32_t)val;
pthread_mutex_unlock(&aproxy->a2dp_lock);
}
ret = str_parms_get_str(parms, AUDIO_PARAMETER_RECONFIG_A2DP, value, sizeof(value));
if (ret >= 0 && aproxy->support_bta2dp) {
pthread_mutex_lock(&aproxy->a2dp_lock);
if (aproxy->a2dp_out_enabled) {
if(strncmp(value, "true", 4) == 0 && is_active_playback_device_bta2dp(aproxy)) {
bta2dp_playback_stop(aproxy);
bta2dp_playback_start(aproxy);
}
}
pthread_mutex_unlock(&aproxy->a2dp_lock);
}
#endif
/* Check USB parameters */
status = proxy_usb_set_parameters((void *)aproxy->usb_aproxy, parameters);
return status;
}
int proxy_get_microphones(void *proxy, void *array, int *count)
{
struct audio_proxy *aproxy = (struct audio_proxy *)proxy;
struct audio_microphone_characteristic_t *mic_array = array;
size_t *mic_count = (size_t *)count;
size_t actual_mic_count = 0;
int ret = 0;
if (aproxy) {
if (*mic_count == 0) {
*mic_count = (size_t)aproxy->num_mic;
ALOGI("proxy-%s: requested number of microphone, return %zu", __func__, *mic_count);
} else {
for (int i = 0; i < aproxy->num_mic; i++) {
mic_array[i] = aproxy->mic_info[i];
ALOGD("proxy-%s: %dth MIC = %s", __func__, i+1, mic_array[i].device_id);
actual_mic_count++;
}
*mic_count = actual_mic_count;
}
} else {
ALOGE("proxy-%s: aproxy is NULL", __func__);
ret = -ENOSYS;
}
return ret;
}
void proxy_update_uhqa_playback_stream(void *proxy_stream, int hq_mode)
{
#if 0
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
audio_quality_mode_t high_quality_mode = (audio_quality_mode_t)hq_mode;
ALOGD("proxy-%s: mode(%d)", __func__, high_quality_mode);
if (apstream) {
if (apstream->stream_type == ASTREAM_PLAYBACK_COMPR_OFFLOAD) {
// offload case
} else if (apstream->stream_type == ASTREAM_PLAYBACK_AUX_DIGITAL) {
// DP/HDMI case
if (high_quality_mode == AUDIO_QUALITY_UHQ) {
apstream->pcmconfig.format = UHQA_MEDIA_FORMAT;
} else {
apstream->pcmconfig.format = DEFAULT_MEDIA_FORMAT;
}
apstream->requested_format = get_pcmformat_from_alsaformat(apstream->pcmconfig.format);
} else if (apstream->stream_type == ASTREAM_PLAYBACK_DEEP_BUFFER) {
struct pcm_config pcm_config_map[AUDIO_QUALITY_CNT] = {
pcm_config_deep_playback,
pcm_config_deep_playback_uhqa,
pcm_config_deep_playback_wide_res,
pcm_config_deep_playback_suhqa,
};
apstream->pcmconfig = pcm_config_map[high_quality_mode];
apstream->requested_format = get_pcmformat_from_alsaformat(apstream->pcmconfig.format);
apstream->requested_sample_rate = apstream->pcmconfig.rate;
} else {
ALOGVV("proxy-%s: not supported stream", __func__);
}
}
#endif
}
void proxy_set_uhqa_stream_config(void *proxy_stream, bool config)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
if (apstream)
apstream->need_update_pcm_config = config;
}
bool proxy_get_uhqa_stream_config(void *proxy_stream)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
bool uhqa_stream_config = false;
if (apstream)
uhqa_stream_config = apstream->need_update_pcm_config;
return uhqa_stream_config;
}
void proxy_init_offload_effect_lib(void *proxy)
{
struct audio_proxy *aproxy = proxy;
if(access(OFFLOAD_EFFECT_LIBRARY_PATH, R_OK) == 0){
aproxy->offload_effect_lib = dlopen(OFFLOAD_EFFECT_LIBRARY_PATH, RTLD_NOW);
if(aproxy->offload_effect_lib == NULL){
ALOGI("proxy-%s: dlopen %s failed", __func__, OFFLOAD_EFFECT_LIBRARY_PATH);
} else {
aproxy->offload_effect_lib_update =
(void (*)(struct mixer *, int))dlsym(aproxy->offload_effect_lib,
"effect_update_by_hal");
aproxy->offload_effect_lib_update(aproxy->mixer, 0);
}
} else {
ALOGI("proxy-%s: access %s failed", __func__, OFFLOAD_EFFECT_LIBRARY_PATH);
}
return;
}
void proxy_update_offload_effect(void *proxy, int type){
struct audio_proxy *aproxy = proxy;
if (type && (aproxy->offload_effect_lib_update != NULL)) {
aproxy->offload_effect_lib_update(aproxy->mixer, type);
}
}
void proxy_set_dual_speaker_mode(void *proxy, bool state)
{
struct audio_proxy *aproxy = proxy;
aproxy->support_dualspk = state;
}
void proxy_set_stream_channel(void *proxy_stream, int new_channel, bool skip)
{
struct audio_proxy_stream *apstream = (struct audio_proxy_stream *)proxy_stream;
if (new_channel > 0) {
apstream->pcmconfig.channels = new_channel;
}
apstream->skip_ch_convert = skip;
apstream->need_channelconversion = !skip;
ALOGI("%s: new_channel %d, skip_ch_convert %d", __func__, new_channel, apstream->skip_ch_convert);
}
void proxy_set_spk_ampL_power(void* proxy, bool state)
{
struct audio_proxy *aproxy = proxy;
aproxy->spk_ampL_powerOn = state;
if(aproxy->support_dualspk)
proxy_set_mixer_value_int(aproxy, SPK_AMPL_POWER_NAME, aproxy->spk_ampL_powerOn);
}
bool proxy_get_spk_ampL_power(void* proxy)
{
struct audio_proxy *aproxy = proxy;
return aproxy->spk_ampL_powerOn;
}
void proxy_set_primary_mute(void* proxy, int count)
{
struct audio_proxy *aproxy = proxy;
struct mixer_ctl *ctrl = NULL;
char mixer_name[MAX_MIXER_NAME_LEN];
int ret = 0, val = count;
pthread_rwlock_rdlock(&aproxy->mixer_update_lock);
ctrl = mixer_get_ctl_by_name(aproxy->mixer, ABOX_MUTE_CONTROL_NAME);
snprintf(mixer_name, sizeof(mixer_name), ABOX_MUTE_CONTROL_NAME);
if (ctrl) {
ret = mixer_ctl_set_value(ctrl, 0,val);
if (ret != 0)
ALOGE("proxy-%s: failed to set primary mute(%s)", __func__, mixer_name);
else
ALOGI("proxy-%s: set set primary mute(%s) to %d", __func__, mixer_name, val);
} else {
ALOGE("proxy-%s: cannot find primary mute", __func__);
}
pthread_rwlock_unlock(&aproxy->mixer_update_lock);
return ;
}
/*
* Proxy Dump
*/
int proxy_fw_dump(int fd)
{
ALOGV("proxy-%s: enter with file descriptor(%d)", __func__, fd);
calliope_ramdump(fd);
ALOGV("proxy-%s: exit with file descriptor(%d)", __func__, fd);
return 0;
}
/*
* Proxy Device Creation/Destruction
*/
static void check_configurations(struct audio_proxy *aproxy)
{
char property[PROPERTY_VALUE_MAX];
/* Audio Device Configurations */
// BuiltIn Earpiece
memset(property, 0, PROPERTY_VALUE_MAX);
property_get(NUM_EARPIECE_PROPERTY, property, NUM_EARPIECE_DEFAULT);
aproxy->num_earpiece = atoi(property);
ALOGI("proxy-%s: The supported number of BuiltIn Earpiece = %d", __func__, aproxy->num_earpiece);
// BuiltIn Speaker
memset(property, 0, PROPERTY_VALUE_MAX);
property_get(NUM_SPEAKER_PROPERTY, property, NUM_SPEAKER_DEFAULT);
aproxy->num_speaker = atoi(property);
ALOGI("proxy-%s: The supported number of BuiltIn Speaker = %d", __func__, aproxy->num_speaker);
if (aproxy->num_speaker == 2)
ALOGI("proxy-%s: This set supports Dual Speaker", __func__);
// BuiltIn Mic
ALOGI("proxy-%s: The number of supported BuiltIn Mic = %d", __func__, aproxy->num_mic);
// Proximity Sensor
memset(property, 0, PROPERTY_VALUE_MAX);
property_get(NUM_PROXIMITY_PROPERTY, property, NUM_PROXIMITY_DEFAULT);
aproxy->num_proximity = atoi(property);
ALOGI("proxy-%s: The supported number of Proximity Sensor = %d", __func__, aproxy->num_proximity);
// Speaker AMP
memset(property, 0, PROPERTY_VALUE_MAX);
property_get(SPEAKER_AMP_PROPERTY, property, SPEAKER_AMP_DEFAULT);
aproxy->support_spkamp = (bool)atoi(property);
if (aproxy->support_spkamp)
ALOGI("proxy-%s: The Speaker AMP is supported", __func__);
// Bluetooth
memset(property, 0, PROPERTY_VALUE_MAX);
property_get(BLUETOOTH_PROPERTY, property, BLUETOOTH_DEFAULT);
if (strcmp(property, "external") == 0) {
aproxy->bt_external = true;
ALOGI("proxy-%s: The supported BT is External", __func__);
} else if (strcmp(property, "internal") == 0) {
aproxy->bt_internal = true;
ALOGI("proxy-%s: The supported BT is Internal", __func__);
} else
ALOGI("proxy-%s: The supported BT is None", __func__);
// FM Radio
memset(property, 0, PROPERTY_VALUE_MAX);
property_get(FMRADIO_PROPERTY, property, FMRADIO_DEFAULT);
if (strcmp(property, "external") == 0) {
aproxy->fm_external = true;
ALOGI("proxy-%s: The supported FM Radio is External", __func__);
} else if (strcmp(property, "internal") == 0) {
aproxy->fm_internal = true;
ALOGI("proxy-%s: The supported FM Radio is Internal", __func__);
} else
ALOGI("proxy-%s: The supported FM Radio is None", __func__);
/* A-Box Configurations */
// USB Device
memset(property, 0, PROPERTY_VALUE_MAX);
property_get(USBBYPRIMARY_PROPERTY, property, USBBYPRIMARY_DEFAULT);
if (strcmp(property, "yes") == 0) {
aproxy->usb_by_primary = true;
ALOGI("proxy-%s: The USB Device is supported by Primary AudioHAL", __func__);
} else {
aproxy->usb_by_primary = false;
ALOGI("proxy-%s: The USB Device is supported by USB AudioHAL", __func__);
}
return ;
}
static bool find_enum_from_string(struct audio_string_to_enum *table, const char *name,
int32_t table_cnt, int *value)
{
int i;
for (i = 0; i < table_cnt; i++) {
if (strcmp(table[i].name, name) == 0) {
*value = table[i].value;
return true;
}
}
return false;
}
static void set_microphone_info(struct audio_microphone_characteristic_t *microphone, const XML_Char **attr)
{
uint32_t curIdx = 0;
uint32_t array_cnt = 0;
float f_value[3] = {0, };
char *ptr = NULL;
if (strcmp(attr[curIdx++], "device_id") == 0)
strcpy(microphone->device_id, attr[curIdx++]);
if (strcmp(attr[curIdx++], "id") == 0)
microphone->id = atoi(attr[curIdx++]);
if (strcmp(attr[curIdx++], "device") == 0)
find_enum_from_string(device_in_type, attr[curIdx++], ARRAY_SIZE(device_in_type), (int *)&microphone->device);
if (strcmp(attr[curIdx++], "address") == 0)
strcpy(microphone->address, attr[curIdx++]);
if (strcmp(attr[curIdx++], "location") == 0)
find_enum_from_string(microphone_location, attr[curIdx++], AUDIO_MICROPHONE_LOCATION_CNT, (int *)&microphone->location);
if (strcmp(attr[curIdx++], "group") == 0)
microphone->group = atoi(attr[curIdx++]);
if (strcmp(attr[curIdx++], "index_in_the_group") == 0)
microphone->index_in_the_group = atoi(attr[curIdx++]);
if (strcmp(attr[curIdx++], "sensitivity") == 0)
microphone->sensitivity = atof(attr[curIdx++]);
if (strcmp(attr[curIdx++], "max_spl") == 0)
microphone->max_spl = atof(attr[curIdx++]);
if (strcmp(attr[curIdx++], "min_spl") == 0)
microphone->min_spl = atof(attr[curIdx++]);
if (strcmp(attr[curIdx++], "directionality") == 0)
find_enum_from_string(microphone_directionality, attr[curIdx++],
AUDIO_MICROPHONE_LOCATION_CNT, (int *)&microphone->directionality);
if (strcmp(attr[curIdx++], "num_frequency_responses") == 0) {
microphone->num_frequency_responses = atoi(attr[curIdx++]);
if (microphone->num_frequency_responses > 0) {
if (strcmp(attr[curIdx++], "frequencies") == 0) {
ptr = strtok((char *)attr[curIdx++], " ");
while(ptr != NULL) {
microphone->frequency_responses[0][array_cnt++] = atof(ptr);
ptr = strtok(NULL, " ");
}
}
array_cnt = 0;
if (strcmp(attr[curIdx++], "responses") == 0) {
ptr = strtok((char *)attr[curIdx++], " ");
while(ptr != NULL) {
microphone->frequency_responses[1][array_cnt++] = atof(ptr);
ptr = strtok(NULL, " ");
}
}
}
}
if (strcmp(attr[curIdx++], "geometric_location") == 0) {
ptr = strtok((char *)attr[curIdx++], " ");
array_cnt = 0;
while (ptr != NULL) {
f_value[array_cnt++] = atof(ptr);
ptr = strtok(NULL, " ");
}
microphone->geometric_location.x = f_value[0];
microphone->geometric_location.y = f_value[1];
microphone->geometric_location.z = f_value[2];
}
if (strcmp(attr[curIdx++], "orientation") == 0) {
ptr = strtok((char *)attr[curIdx++], " ");
array_cnt = 0;
while (ptr != NULL) {
f_value[array_cnt++] = atof(ptr);
ptr = strtok(NULL, " ");
}
microphone->orientation.x = f_value[0];
microphone->orientation.y = f_value[1];
microphone->orientation.z = f_value[2];
}
/* Channel mapping doesn't used for now. */
for (array_cnt = 0; array_cnt < AUDIO_CHANNEL_COUNT_MAX; array_cnt++)
microphone->channel_mapping[array_cnt] = AUDIO_MICROPHONE_CHANNEL_MAPPING_UNUSED;
}
static void end_tag(void *data, const XML_Char *tag_name)
{
if (strcmp(tag_name, "microphone_characteristis") == 0)
set_info = INFO_NONE;
}
static void start_tag(void *data, const XML_Char *tag_name, const XML_Char **attr)
{
struct audio_proxy *aproxy = getInstance();
const XML_Char *attr_name = NULL;
const XML_Char *attr_value = NULL;
if (strcmp(tag_name, "microphone_characteristics") == 0) {
set_info = MICROPHONE_CHARACTERISTIC;
} else if (strcmp(tag_name, "microphone") == 0) {
if (set_info != MICROPHONE_CHARACTERISTIC) {
ALOGE("proxy-%s: microphone tag should be supported with microphone_characteristics tag", __func__);
return ;
}
set_microphone_info(&aproxy->mic_info[aproxy->num_mic++], attr);
}
}
void proxy_set_board_info(void *proxy)
{
struct audio_proxy *aproxy = (struct audio_proxy *)proxy;
XML_Parser parser = 0;
FILE *file = NULL;
char info_file_name[MAX_MIXER_NAME_LEN] = {0};
void *buf = NULL;
uint32_t buf_size = 1024;
int32_t bytes_read = 0;
strlcpy(info_file_name, BOARD_INFO_XML_PATH, MAX_MIXER_NAME_LEN);
file = fopen(info_file_name, "r");
if (file == NULL)
ALOGE("proxy-%s: open error: %s, file=%s", __func__, strerror(errno), info_file_name);
else
ALOGI("proxy-%s: Board info file name is %s", __func__, info_file_name);
parser = XML_ParserCreate(NULL);
XML_SetElementHandler(parser, start_tag, end_tag);
while (1) {
buf = XML_GetBuffer(parser, buf_size);
if (buf == NULL) {
ALOGE("proxy-%s fail to get buffer", __func__);
break;
}
bytes_read = fread(buf, 1, buf_size, file);
if (bytes_read < 0) {
ALOGE("proxy-%s fail to read from file", __func__);
break;
}
XML_ParseBuffer(parser, bytes_read, bytes_read == 0);
if (bytes_read == 0)
break;
}
XML_ParserFree(parser);
fclose(file);
check_configurations(aproxy);
}
bool proxy_is_initialized(void)
{
if (instance)
return true;
else
return false;
}
void * proxy_init(void)
{
struct audio_proxy *aproxy;
char sound_trigger_hal_path[100] = {0, };
/* Creates the structure for audio_proxy. */
aproxy = getInstance();
if (!aproxy) {
ALOGE("proxy-%s: failed to create for audio_proxy", __func__);
return NULL;
}
aproxy->primary_out = NULL;
// In case of Output Loopback Support, initializes Out Loopback Stream
aproxy->support_out_loopback = true;
aproxy->out_loopback = NULL;
aproxy->erap_in = NULL;
// In case of External Speaker AMP Support, initializes Reference & Playback Stream
aproxy->support_spkamp = true;
aproxy->spkamp_reference = NULL;
aproxy->spkamp_playback = NULL;
#ifdef SUPPORT_BTA2DP_OFFLOAD
// BT A2DP Devices Support by Primary AudioHAL
pthread_mutex_init(&aproxy->a2dp_lock, (const pthread_mutexattr_t *) NULL);
pthread_mutex_lock(&aproxy->a2dp_lock);
proxy_a2dp_init();
aproxy->support_bta2dp = true;
aproxy->a2dp_out_enabled = false;
aproxy->a2dp_suspend = false;
aproxy->a2dp_delay = 0;
aproxy->a2dp_default_delay = 0;
aproxy->bta2dp_playback = NULL;
aproxy->bta2dp_out_loopback = NULL;
pthread_mutex_unlock(&aproxy->a2dp_lock);
aproxy->a2dp_mute_playback = NULL;
#endif
// In case of External BT-SCO Support, initializes Playback Stream
aproxy->support_btsco = true;
aproxy->btsco_playback = NULL;
// Voice Call PCM Devices
aproxy->call_rx = NULL;
aproxy->call_tx = NULL;
aproxy->call_tx_direct = NULL;
// FM Radio PCM Devices
aproxy->fm_playback = NULL;
aproxy->fm_capture = NULL;
aproxy->usb_aproxy = proxy_usb_init();
if (!aproxy->usb_aproxy) {
ALOGE("proxy-%s: failed to create audio_proxy_usb", __func__);
destroyInstance();
return NULL;
}
// In case of USB Input Loopback Support, initializes Out/In Loopback Streams
aproxy->support_usb_out_loopback = true;
aproxy->usb_out_loopback = NULL;
aproxy->support_usb_in_loopback = true;
aproxy->usb_in_loopback = NULL;
// Call State
aproxy->call_state = false;
aproxy->skip_internalpath = false;
/* Audio Mode */
aproxy->audio_mode = AUDIO_MODE_NORMAL;
// STHAL interface initialization
#ifdef SUPPORT_STHAL_INTERFACE
aproxy->sthal_state = 0;
snprintf(sound_trigger_hal_path, sizeof(sound_trigger_hal_path),
SOUND_TRIGGER_HAL_LIBRARY_PATH, XSTR(TARGET_SOC_NAME));
aproxy->sound_trigger_lib = dlopen(sound_trigger_hal_path, RTLD_NOW);
if (aproxy->sound_trigger_lib == NULL) {
ALOGE("%s: DLOPEN failed for %s", __func__, sound_trigger_hal_path);
} else {
ALOGV("%s: DLOPEN successful for %s", __func__, sound_trigger_hal_path);
aproxy->sound_trigger_open_for_streaming =
(int (*)(void))dlsym(aproxy->sound_trigger_lib,
"sound_trigger_open_for_streaming");
aproxy->sound_trigger_read_samples =
(size_t (*)(int, void*, size_t))dlsym(aproxy->sound_trigger_lib,
"sound_trigger_read_samples");
aproxy->sound_trigger_close_for_streaming =
(int (*)(int))dlsym(aproxy->sound_trigger_lib,
"sound_trigger_close_for_streaming");
aproxy->sound_trigger_open_recording =
(int (*)(void))dlsym(aproxy->sound_trigger_lib,
"sound_trigger_open_recording");
aproxy->sound_trigger_read_recording_samples =
(size_t (*)(void*, size_t))dlsym(aproxy->sound_trigger_lib,
"sound_trigger_read_recording_samples");
aproxy->sound_trigger_close_recording =
(int (*)(int))dlsym(aproxy->sound_trigger_lib,
"sound_trigger_close_recording");
aproxy->sound_trigger_headset_status =
(int (*)(int))dlsym(aproxy->sound_trigger_lib,
"sound_trigger_headset_status");
aproxy->sound_trigger_voicecall_status =
(int (*)(int))dlsym(aproxy->sound_trigger_lib,
"sound_trigger_voicecall_status");
if (!aproxy->sound_trigger_open_for_streaming ||
!aproxy->sound_trigger_read_samples ||
!aproxy->sound_trigger_close_for_streaming ||
!aproxy->sound_trigger_open_recording ||
!aproxy->sound_trigger_read_recording_samples ||
!aproxy->sound_trigger_close_recording ||
!aproxy->sound_trigger_headset_status ||
!aproxy->sound_trigger_voicecall_status) {
ALOGE("%s: Error grabbing functions in %s", __func__, sound_trigger_hal_path);
aproxy->sound_trigger_open_for_streaming = 0;
aproxy->sound_trigger_read_samples = 0;
aproxy->sound_trigger_close_for_streaming = 0;
aproxy->sound_trigger_open_recording = 0;
aproxy->sound_trigger_read_recording_samples = 0;
aproxy->sound_trigger_close_recording = 0;
aproxy->sound_trigger_headset_status = 0;
aproxy->sound_trigger_voicecall_status = 0;
}
}
#endif
/* offload effect */
aproxy->offload_effect_lib = NULL;
aproxy->offload_effect_lib_update = NULL;
aproxy->spk_ampL_powerOn = false;
proxy_set_board_info(aproxy);
ALOGI("proxy-%s: opened & initialized Audio Proxy", __func__);
return (void *)aproxy;
}
void proxy_deinit(void *proxy)
{
struct audio_proxy *aproxy = (struct audio_proxy *)proxy;
if (aproxy) {
#ifdef SUPPORT_BTA2DP_OFFLOAD
// BT A2DP Devices Support by Primary AudioHAL
if (aproxy->support_bta2dp) {
pthread_mutex_lock(&aproxy->a2dp_lock);
proxy_a2dp_deinit();
pthread_mutex_unlock(&aproxy->a2dp_lock);
pthread_mutex_destroy(&aproxy->a2dp_lock);
}
#endif
// USB Devices Support by Primary AudioHAL
proxy_usb_deinit(aproxy->usb_aproxy);
destroyInstance();
ALOGI("proxy-%s: destroyed for audio_proxy", __func__);
}
return ;
}