/* * Copyright (c) 2016-2018, The Linux Foundation. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above * copyright notice, this list of conditions and the following * disclaimer in the documentation and/or other materials provided * with the distribution. * * Neither the name of The Linux Foundation nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR * BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE * OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN * IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #define LOG_TAG "audio_hw_qaf" /*#define LOG_NDEBUG 0*/ /*#define VERY_VERY_VERBOSE_LOGGING*/ #ifdef VERY_VERY_VERBOSE_LOGGING #define DEBUG_MSG_VV DEBUG_MSG #else #define DEBUG_MSG_VV(a...) do { } while(0) #endif #define DEBUG_MSG(arg,...) ALOGV("%s: %d: " arg, __func__, __LINE__, ##__VA_ARGS__) #define ERROR_MSG(arg,...) ALOGE("%s: %d: " arg, __func__, __LINE__, ##__VA_ARGS__) #define COMPRESS_OFFLOAD_NUM_FRAGMENTS 2 #define COMPRESS_PASSTHROUGH_DDP_FRAGMENT_SIZE 4608 #define QAF_DEFAULT_COMPR_AUDIO_HANDLE 1001 #define QAF_DEFAULT_COMPR_PASSTHROUGH_HANDLE 1002 #define QAF_DEFAULT_PASSTHROUGH_HANDLE 1003 #define COMPRESS_OFFLOAD_PLAYBACK_LATENCY 300 #define MIN_PCM_OFFLOAD_FRAGMENT_SIZE 512 #define MAX_PCM_OFFLOAD_FRAGMENT_SIZE (240 * 1024) #define DIV_ROUND_UP(x, y) (((x) + (y) - 1)/(y)) #define ALIGN(x, y) ((y) * DIV_ROUND_UP((x), (y))) /* Pcm input node buffer size is 6144 bytes, i.e, 32msec for 48000 samplerate */ #define QAF_MODULE_PCM_INPUT_BUFFER_LATENCY 32 #define MS12_PCM_OUT_FRAGMENT_SIZE 1536 //samples #define MS12_PCM_IN_FRAGMENT_SIZE 1536 //samples #define DD_FRAME_SIZE 1536 #define DDP_FRAME_SIZE DD_FRAME_SIZE /* * DD encoder output size for one frame. */ #define DD_ENCODER_OUTPUT_SIZE 2560 /* * DDP encoder output size for one frame. */ #define DDP_ENCODER_OUTPUT_SIZE 4608 /*********TODO Need to get correct values.*************************/ #define DTS_PCM_OUT_FRAGMENT_SIZE 1024 //samples #define DTS_FRAME_SIZE 1536 #define DTSHD_FRAME_SIZE DTS_FRAME_SIZE /* * DTS encoder output size for one frame. */ #define DTS_ENCODER_OUTPUT_SIZE 2560 /* * DTSHD encoder output size for one frame. */ #define DTSHD_ENCODER_OUTPUT_SIZE 4608 /******************************************************************/ /* * QAF Latency to process buffers since out_write from primary HAL */ #define QAF_COMPRESS_OFFLOAD_PROCESSING_LATENCY 18 #define QAF_PCM_OFFLOAD_PROCESSING_LATENCY 48 //TODO: Need to handle for DTS #define QAF_DEEP_BUFFER_OUTPUT_PERIOD_SIZE 1536 #include #include #include #include #include #include #include #include #include #include #include "audio_utils/primitives.h" #include "audio_hw.h" #include "platform_api.h" #include #include #include #include "audio_extn.h" #include #include "sound/compress_params.h" #include "ip_hdlr_intf.h" #ifdef DYNAMIC_LOG_ENABLED #include #define LOG_MASK HAL_MOD_FILE_QAF #include #endif //TODO: Need to remove this. #define QAF_OUTPUT_SAMPLING_RATE 48000 #ifdef QAF_DUMP_ENABLED FILE *fp_output_writer_hdmi = NULL; #endif void set_hdmi_configuration_to_module(); void set_bt_configuration_to_module(); struct qaf_adsp_hdlr_config_state { struct audio_adsp_event event_params; /* For holding client audio_adsp_event payload */ uint8_t event_payload[AUDIO_MAX_ADSP_STREAM_CMD_PAYLOAD_LEN]; bool adsp_hdlr_config_valid; }; //Types of MM module, currently supported by QAF. typedef enum { MS12, DTS_M8, MAX_MM_MODULE_TYPE, INVALID_MM_MODULE } mm_module_type; typedef enum { QAF_OUT_TRANSCODE_PASSTHROUGH = 0, /* Transcode passthrough via MM module*/ QAF_OUT_OFFLOAD_MCH, /* Multi-channel PCM offload*/ QAF_OUT_OFFLOAD, /* PCM offload */ MAX_QAF_MODULE_OUT } mm_module_output_type; typedef enum { QAF_IN_MAIN = 0, /* Single PID Main/Primary or Dual-PID stream */ QAF_IN_ASSOC, /* Associated/Secondary stream */ QAF_IN_PCM, /* PCM stream. */ QAF_IN_MAIN_2, /* Single PID Main2 stream */ MAX_QAF_MODULE_IN } mm_module_input_type; typedef enum { STOPPED, /*Stream is in stop state. */ STOPPING, /*Stream is stopping, waiting for EOS. */ RUN, /*Stream is in run state. */ MAX_STATES } qaf_stream_state; struct qaf_module { audio_session_handle_t session_handle; void *ip_hdlr_hdl; void *qaf_lib; int (*qaf_audio_session_open)(audio_session_handle_t* session_handle, audio_session_type_t s_type, void *p_data, void* license_data); int (*qaf_audio_session_close)(audio_session_handle_t session_handle); int (*qaf_audio_stream_open)(audio_session_handle_t session_handle, audio_stream_handle_t* stream_handle, audio_stream_config_t input_config, audio_devices_t devices, stream_type_t flags); int (*qaf_audio_stream_close)(audio_stream_handle_t stream_handle); int (*qaf_audio_stream_set_param)(audio_stream_handle_t stream_handle, const char* kv_pairs); int (*qaf_audio_session_set_param)(audio_session_handle_t handle, const char* kv_pairs); char* (*qaf_audio_stream_get_param)(audio_stream_handle_t stream_handle, const char* key); char* (*qaf_audio_session_get_param)(audio_session_handle_t handle, const char* key); int (*qaf_audio_stream_start)(audio_stream_handle_t handle); int (*qaf_audio_stream_stop)(audio_stream_handle_t stream_handle); int (*qaf_audio_stream_pause)(audio_stream_handle_t stream_handle); int (*qaf_audio_stream_flush)(audio_stream_handle_t stream_handle); int (*qaf_audio_stream_write)(audio_stream_handle_t stream_handle, const void* buf, int size); void (*qaf_register_event_callback)(audio_session_handle_t session_handle, void *priv_data, notify_event_callback_t event_callback, audio_event_id_t event_id); /*Input stream of MM module */ struct stream_out *stream_in[MAX_QAF_MODULE_IN]; /*Output Stream from MM module */ struct stream_out *stream_out[MAX_QAF_MODULE_OUT]; /*Media format associated with each output id raised by mm module. */ audio_qaf_media_format_t out_stream_fmt[MAX_QAF_MODULE_OUT]; /*Flag is set if media format is changed for an mm module output. */ bool is_media_fmt_changed[MAX_QAF_MODULE_OUT]; /*Index to be updated in out_stream_fmt array for a new mm module output. */ int new_out_format_index; struct qaf_adsp_hdlr_config_state adsp_hdlr_config[MAX_QAF_MODULE_IN]; //BT session handle. void *bt_hdl; float vol_left; float vol_right; bool is_vol_set; qaf_stream_state stream_state[MAX_QAF_MODULE_IN]; bool is_session_closing; }; struct qaf { struct audio_device *adev; pthread_mutex_t lock; bool bt_connect; bool hdmi_connect; int hdmi_sink_channels; //Flag to indicate if QAF transcode output stream is enabled from any mm module. bool passthrough_enabled; //Flag to indicate if QAF mch pcm output stream is enabled from any mm module. bool mch_pcm_hdmi_enabled; //Flag to indicate if msmd is supported. bool qaf_msmd_enabled; //Handle of QAF input stream, which is routed as QAF passthrough. struct stream_out *passthrough_in; //Handle of QAF passthrough stream. struct stream_out *passthrough_out; struct qaf_module qaf_mod[MAX_MM_MODULE_TYPE]; }; static int qaf_out_pause(struct audio_stream_out* stream); static int qaf_out_flush(struct audio_stream_out* stream); static int qaf_out_drain(struct audio_stream_out* stream, audio_drain_type_t type); static int qaf_session_close(); //Global handle of QAF. Access to this should be protected by mutex lock. static struct qaf *p_qaf = NULL; /* Gets the pointer to qaf module for the qaf input stream. */ static struct qaf_module* get_qaf_module_for_input_stream(struct stream_out *out) { struct qaf_module *qaf_mod = NULL; int i, j; if (!p_qaf) return NULL; for (i = 0; i < MAX_MM_MODULE_TYPE; i++) { for (j = 0; j < MAX_QAF_MODULE_IN; j++) { if (p_qaf->qaf_mod[i].stream_in[j] == out) { qaf_mod = &(p_qaf->qaf_mod[i]); break; } } } return qaf_mod; } /* Finds the mm module input stream index for the QAF input stream. */ static int get_input_stream_index(struct stream_out *out) { int index = -1, j; struct qaf_module* qaf_mod = NULL; qaf_mod = get_qaf_module_for_input_stream(out); if (!qaf_mod) return index; for (j = 0; j < MAX_QAF_MODULE_IN; j++) { if (qaf_mod->stream_in[j] == out) { index = j; break; } } return index; } static void set_stream_state(struct stream_out *out, int state) { struct qaf_module *qaf_mod = get_qaf_module_for_input_stream(out); int index = get_input_stream_index(out); if (qaf_mod && index >= 0) qaf_mod->stream_state[index] = state; } static bool check_stream_state(struct stream_out *out, int state) { struct qaf_module *qaf_mod = get_qaf_module_for_input_stream(out); int index = get_input_stream_index(out); if (qaf_mod && index >= 0) return (qaf_mod->stream_state[index] == state); return false; } /* Finds the right mm module for the QAF input stream format. */ static mm_module_type get_mm_module_for_format(audio_format_t format) { int j; DEBUG_MSG("Format 0x%x", format); if (format == AUDIO_FORMAT_PCM_16_BIT) { //If dts is not supported then alway support pcm with MS12 if (!property_get_bool("vendor.audio.qaf.dts_m8", false)) { //TODO: Need to add this property for DTS. return MS12; } //If QAF passthrough is active then send the PCM stream to primary HAL. if (!p_qaf->passthrough_out) { /* Iff any stream is active in MS12 module then route PCM stream to it. */ for (j = 0; j < MAX_QAF_MODULE_IN; j++) { if (p_qaf->qaf_mod[MS12].stream_in[j]) { return MS12; } } } return INVALID_MM_MODULE; } switch (format & AUDIO_FORMAT_MAIN_MASK) { case AUDIO_FORMAT_AC3: case AUDIO_FORMAT_E_AC3: case AUDIO_FORMAT_AAC: case AUDIO_FORMAT_AAC_ADTS: case AUDIO_FORMAT_AC4: return MS12; case AUDIO_FORMAT_DTS: case AUDIO_FORMAT_DTS_HD: return DTS_M8; default: return INVALID_MM_MODULE; } } static bool is_main_active(struct qaf_module* qaf_mod) { return (qaf_mod->stream_in[QAF_IN_MAIN] || qaf_mod->stream_in[QAF_IN_MAIN_2]); } static bool is_dual_main_active(struct qaf_module* qaf_mod) { return (qaf_mod->stream_in[QAF_IN_MAIN] && qaf_mod->stream_in[QAF_IN_MAIN_2]); } //Checks if any main or pcm stream is running in the session. static bool is_any_stream_running(struct qaf_module* qaf_mod) { //Not checking associated stream. struct stream_out *out = qaf_mod->stream_in[QAF_IN_MAIN]; struct stream_out *out_pcm = qaf_mod->stream_in[QAF_IN_PCM]; struct stream_out *out_main2 = qaf_mod->stream_in[QAF_IN_MAIN_2]; if ((out == NULL || (out != NULL && check_stream_state(out, STOPPED))) && (out_main2 == NULL || (out_main2 != NULL && check_stream_state(out_main2, STOPPED))) && (out_pcm == NULL || (out_pcm != NULL && check_stream_state(out_pcm, STOPPED)))) { return false; } return true; } /* Gets the pcm output buffer size(in samples) for the mm module. */ static uint32_t get_pcm_output_buffer_size_samples(struct qaf_module *qaf_mod) { uint32_t pcm_output_buffer_size = 0; if (qaf_mod == &p_qaf->qaf_mod[MS12]) { pcm_output_buffer_size = MS12_PCM_OUT_FRAGMENT_SIZE; } else if (qaf_mod == &p_qaf->qaf_mod[DTS_M8]) { pcm_output_buffer_size = DTS_PCM_OUT_FRAGMENT_SIZE; } return pcm_output_buffer_size; } static int get_media_fmt_array_index_for_output_id( struct qaf_module* qaf_mod, uint32_t output_id) { int i; for (i = 0; i < MAX_QAF_MODULE_OUT; i++) { if (qaf_mod->out_stream_fmt[i].output_id == output_id) { return i; } } return -1; } /* Acquire Mutex lock on output stream */ static void lock_output_stream(struct stream_out *out) { pthread_mutex_lock(&out->pre_lock); pthread_mutex_lock(&out->lock); pthread_mutex_unlock(&out->pre_lock); } /* Release Mutex lock on output stream */ static void unlock_output_stream(struct stream_out *out) { pthread_mutex_unlock(&out->lock); } /* Checks if stream can be routed as QAF passthrough or not. */ static bool audio_extn_qaf_passthrough_enabled(struct stream_out *out) { DEBUG_MSG("Format 0x%x", out->format); bool is_enabled = false; if (!p_qaf) return false; if ((!property_get_bool("vendor.audio.qaf.reencode", false)) && property_get_bool("vendor.audio.qaf.passthrough", false)) { if ((out->format == AUDIO_FORMAT_PCM_16_BIT) && (popcount(out->channel_mask) > 2)) { is_enabled = true; } else if (property_get_bool("vendor.audio.offload.passthrough", false)) { switch (out->format) { case AUDIO_FORMAT_AC3: case AUDIO_FORMAT_E_AC3: case AUDIO_FORMAT_DTS: case AUDIO_FORMAT_DTS_HD: case AUDIO_FORMAT_DOLBY_TRUEHD: case AUDIO_FORMAT_IEC61937: { is_enabled = true; break; } default: is_enabled = false; break; } } } return is_enabled; } /*Closes all pcm hdmi output from QAF. */ static void close_all_pcm_hdmi_output() { int i; //Closing all the PCM HDMI output stream from QAF. for (i = 0; i < MAX_MM_MODULE_TYPE; i++) { if (p_qaf->qaf_mod[i].stream_out[QAF_OUT_OFFLOAD_MCH]) { adev_close_output_stream((struct audio_hw_device *)p_qaf->adev, (struct audio_stream_out *)(p_qaf->qaf_mod[i].stream_out[QAF_OUT_OFFLOAD_MCH])); p_qaf->qaf_mod[i].stream_out[QAF_OUT_OFFLOAD_MCH] = NULL; } if ((p_qaf->qaf_mod[i].stream_out[QAF_OUT_OFFLOAD]) && (p_qaf->qaf_mod[i].stream_out[QAF_OUT_OFFLOAD]->devices & AUDIO_DEVICE_OUT_AUX_DIGITAL)) { adev_close_output_stream((struct audio_hw_device *)p_qaf->adev, (struct audio_stream_out *)(p_qaf->qaf_mod[i].stream_out[QAF_OUT_OFFLOAD])); p_qaf->qaf_mod[i].stream_out[QAF_OUT_OFFLOAD] = NULL; } } p_qaf->mch_pcm_hdmi_enabled = 0; } static void close_all_hdmi_output() { int k; for (k = 0; k < MAX_MM_MODULE_TYPE; k++) { if (p_qaf->qaf_mod[k].stream_out[QAF_OUT_TRANSCODE_PASSTHROUGH]) { adev_close_output_stream((struct audio_hw_device *)p_qaf->adev, (struct audio_stream_out *)(p_qaf->qaf_mod[k].stream_out[QAF_OUT_TRANSCODE_PASSTHROUGH])); p_qaf->qaf_mod[k].stream_out[QAF_OUT_TRANSCODE_PASSTHROUGH] = NULL; } } p_qaf->passthrough_enabled = 0; close_all_pcm_hdmi_output(); } static int qaf_out_callback(stream_callback_event_t event, void *param __unused, void *cookie) { struct stream_out *out = (struct stream_out *)cookie; out->client_callback(event, NULL, out->client_cookie); return 0; } /* Creates the QAF passthrough output stream. */ static int create_qaf_passthrough_stream() { DEBUG_MSG(); int ret = 0; struct stream_out *out = p_qaf->passthrough_in; if (!out) return -EINVAL; pthread_mutex_lock(&p_qaf->lock); lock_output_stream(out); //Creating QAF passthrough output stream. if (NULL == p_qaf->passthrough_out) { audio_output_flags_t flags; struct audio_config config; audio_devices_t devices; config.sample_rate = config.offload_info.sample_rate = out->sample_rate; config.offload_info.version = AUDIO_INFO_INITIALIZER.version; config.offload_info.size = AUDIO_INFO_INITIALIZER.size; config.offload_info.format = out->format; config.offload_info.bit_width = out->bit_width; config.format = out->format; config.offload_info.channel_mask = config.channel_mask = out->channel_mask; //Device is copied from the QAF passthrough input stream. devices = out->devices; flags = out->flags; ret = adev_open_output_stream((struct audio_hw_device *)p_qaf->adev, QAF_DEFAULT_PASSTHROUGH_HANDLE, devices, flags, &config, (struct audio_stream_out **)&(p_qaf->passthrough_out), NULL); if (ret < 0) { ERROR_MSG("adev_open_output_stream failed with ret = %d!", ret); unlock_output_stream(out); return ret; } p_qaf->passthrough_in = out; p_qaf->passthrough_out->stream.set_callback((struct audio_stream_out *)p_qaf->passthrough_out, (stream_callback_t) qaf_out_callback, out); } unlock_output_stream(out); //Since QAF-Passthrough is created, close other HDMI outputs. close_all_hdmi_output(); pthread_mutex_unlock(&p_qaf->lock); return ret; } /* Closes the QAF passthrough output stream. */ static void close_qaf_passthrough_stream() { if (p_qaf->passthrough_out != NULL) { //QAF pasthroug is enabled. Close it. pthread_mutex_lock(&p_qaf->lock); adev_close_output_stream((struct audio_hw_device *)p_qaf->adev, (struct audio_stream_out *)(p_qaf->passthrough_out)); p_qaf->passthrough_out = NULL; pthread_mutex_unlock(&p_qaf->lock); if (p_qaf->passthrough_in->qaf_stream_handle) { qaf_out_pause((struct audio_stream_out*)p_qaf->passthrough_in); qaf_out_flush((struct audio_stream_out*)p_qaf->passthrough_in); qaf_out_drain((struct audio_stream_out*)p_qaf->passthrough_in, (audio_drain_type_t)STREAM_CBK_EVENT_DRAIN_READY); } } } /* Sends a command to output stream offload thread. */ static int qaf_send_offload_cmd_l(struct stream_out* out, int command) { DEBUG_MSG_VV("command is %d", command); struct offload_cmd *cmd = (struct offload_cmd *)calloc(1, sizeof(struct offload_cmd)); if (!cmd) { ERROR_MSG("failed to allocate mem for command 0x%x", command); return -ENOMEM; } cmd->cmd = command; lock_output_stream(out); list_add_tail(&out->qaf_offload_cmd_list, &cmd->node); pthread_cond_signal(&out->qaf_offload_cond); unlock_output_stream(out); return 0; } /* Stops a QAF module stream.*/ static int audio_extn_qaf_stream_stop(struct stream_out *out) { int ret = 0; DEBUG_MSG("Output Stream 0x%p", out); if (!check_stream_state(out, RUN)) return ret; struct qaf_module *qaf_mod = get_qaf_module_for_input_stream(out); if ((!qaf_mod) || (!qaf_mod->qaf_audio_stream_stop)) { return ret; } if (out->qaf_stream_handle) { ret = qaf_mod->qaf_audio_stream_stop(out->qaf_stream_handle); } return ret; } /* Puts a QAF module stream in standby. */ static int qaf_out_standby(struct audio_stream *stream) { struct stream_out *out = (struct stream_out *)stream; int status = 0; ALOGD("%s: enter: stream (%p) usecase(%d: %s)", __func__, stream, out->usecase, use_case_table[out->usecase]); lock_output_stream(out); //If QAF passthrough is active then block standby on all the input streams of QAF mm modules. if (p_qaf->passthrough_out) { //If standby is received on QAF passthrough stream then forward it to primary HAL. if (p_qaf->passthrough_in == out) { status = p_qaf->passthrough_out->stream.common.standby( (struct audio_stream *)p_qaf->passthrough_out); } } else if (check_stream_state(out, RUN)) { //If QAF passthrough stream is not active then stop the QAF module stream. status = audio_extn_qaf_stream_stop(out); if (status == 0) { //Setting state to stopped as client not expecting drain_ready event. set_stream_state(out, STOPPED); } } if (!out->standby) { out->standby = true; } unlock_output_stream(out); return status; } /* Sets the volume to PCM output stream. */ static int qaf_out_set_volume(struct audio_stream_out *stream, float left, float right) { int ret = 0; struct stream_out *out = (struct stream_out *)stream; struct qaf_module *qaf_mod = NULL; DEBUG_MSG("Left %f, Right %f", left, right); qaf_mod = get_qaf_module_for_input_stream(out); if (!qaf_mod) { return -EINVAL; } pthread_mutex_lock(&p_qaf->lock); qaf_mod->vol_left = left; qaf_mod->vol_right = right; qaf_mod->is_vol_set = true; pthread_mutex_unlock(&p_qaf->lock); if (qaf_mod->stream_out[QAF_OUT_OFFLOAD] != NULL) { ret = qaf_mod->stream_out[QAF_OUT_OFFLOAD]->stream.set_volume( (struct audio_stream_out *)qaf_mod->stream_out[QAF_OUT_OFFLOAD], left, right); } return ret; } /* Starts a QAF module stream. */ static int qaf_stream_start(struct stream_out *out) { int ret = -EINVAL; struct qaf_module *qaf_mod = NULL; DEBUG_MSG("Output Stream = %p", out); qaf_mod = get_qaf_module_for_input_stream(out); if ((!qaf_mod) || (!qaf_mod->qaf_audio_stream_start)) { return -EINVAL; } if (out->qaf_stream_handle) { ret = qaf_mod->qaf_audio_stream_start(out->qaf_stream_handle); } return ret; } static int qaf_start_output_stream(struct stream_out *out) { int ret = 0; struct audio_device *adev = out->dev; if ((out->usecase < 0) || (out->usecase >= AUDIO_USECASE_MAX)) { ret = -EINVAL; usleep(50000); return ret; } ALOGD("%s: enter: stream(%p)usecase(%d: %s) devices(%#x)", __func__, &out->stream, out->usecase, use_case_table[out->usecase], out->devices); if (CARD_STATUS_OFFLINE == out->card_status || CARD_STATUS_OFFLINE == adev->card_status) { ALOGE("%s: sound card is not active/SSR returning error", __func__); ret = -EIO; usleep(50000); return ret; } return qaf_stream_start(out); } /* Sends input buffer to the QAF MM module. */ static int qaf_module_write_input_buffer(struct stream_out *out, const void *buffer, int bytes) { int ret = -EINVAL; struct qaf_module *qaf_mod = NULL; qaf_mod = get_qaf_module_for_input_stream(out); if ((!qaf_mod) || (!qaf_mod->qaf_audio_stream_write)) { return ret; } //If data received on associated stream when all other stream are stopped then drop the data. if (out == qaf_mod->stream_in[QAF_IN_ASSOC] && !is_any_stream_running(qaf_mod)) return bytes; if (out->qaf_stream_handle) { ret = qaf_mod->qaf_audio_stream_write(out->qaf_stream_handle, buffer, bytes); if(ret > 0) set_stream_state(out, RUN); } return ret; } /* Writes buffer to QAF input stream. */ static ssize_t qaf_out_write(struct audio_stream_out *stream, const void *buffer, size_t bytes) { struct stream_out *out = (struct stream_out *)stream; struct audio_device *adev = out->dev; ssize_t ret = 0; DEBUG_MSG_VV("bytes = %d, usecase[%d] and flags[%x] for handle[%p]", (int)bytes, out->usecase, out->flags, out); lock_output_stream(out); // If QAF passthrough is active then block writing data to QAF mm module. if (p_qaf->passthrough_out) { //If write is received for the QAF passthrough stream then send the buffer to primary HAL. if (p_qaf->passthrough_in == out) { ret = p_qaf->passthrough_out->stream.write( (struct audio_stream_out *)(p_qaf->passthrough_out), buffer, bytes); if (ret > 0) out->standby = false; } unlock_output_stream(out); return ret; } else if (out->standby) { pthread_mutex_lock(&adev->lock); ret = qaf_start_output_stream(out); pthread_mutex_unlock(&adev->lock); if (ret == 0) { out->standby = false; } else { goto exit; } } if ((adev->is_channel_status_set == false) && (out->devices & AUDIO_DEVICE_OUT_AUX_DIGITAL)) { audio_utils_set_hdmi_channel_status(out, (char *)buffer, bytes); adev->is_channel_status_set = true; } ret = qaf_module_write_input_buffer(out, buffer, bytes); DEBUG_MSG_VV("ret [%d]", (int)ret); if (ret >= 0) { out->written += ret / ((popcount(out->channel_mask) * sizeof(short))); } exit: unlock_output_stream(out); if (ret < 0) { if (ret == -EAGAIN) { DEBUG_MSG_VV("No space available in mm module, post msg to cb thread"); ret = qaf_send_offload_cmd_l(out, OFFLOAD_CMD_WAIT_FOR_BUFFER); bytes = 0; } else if (ret == -ENOMEM || ret == -EPERM) { if (out->pcm) ERROR_MSG("error %d, %s", (int)ret, pcm_get_error(out->pcm)); qaf_out_standby(&out->stream.common); usleep(bytes * 1000000 / audio_stream_out_frame_size(stream) / out->stream.common.get_sample_rate(&out->stream.common)); } } else if (ret < (ssize_t)bytes) { //partial buffer copied to the module. DEBUG_MSG_VV("Not enough space available in mm module, post msg to cb thread"); (void)qaf_send_offload_cmd_l(out, OFFLOAD_CMD_WAIT_FOR_BUFFER); bytes = ret; } return bytes; } /* Gets PCM offload buffer size for a given config. */ static uint32_t qaf_get_pcm_offload_buffer_size(audio_offload_info_t* info, uint32_t samples_per_frame) { uint32_t fragment_size = 0; fragment_size = (samples_per_frame * (info->bit_width >> 3) * popcount(info->channel_mask)); if (fragment_size < MIN_PCM_OFFLOAD_FRAGMENT_SIZE) fragment_size = MIN_PCM_OFFLOAD_FRAGMENT_SIZE; else if (fragment_size > MAX_PCM_OFFLOAD_FRAGMENT_SIZE) fragment_size = MAX_PCM_OFFLOAD_FRAGMENT_SIZE; // To have same PCM samples for all channels, the buffer size requires to // be multiple of (number of channels * bytes per sample) // For writes to succeed, the buffer must be written at address which is multiple of 32 fragment_size = ALIGN(fragment_size, ((info->bit_width >> 3) * popcount(info->channel_mask) * 32)); ALOGI("Qaf PCM offload Fragment size is %d bytes", fragment_size); return fragment_size; } static uint32_t qaf_get_pcm_offload_input_buffer_size(audio_offload_info_t* info) { return qaf_get_pcm_offload_buffer_size(info, MS12_PCM_IN_FRAGMENT_SIZE); } static uint32_t qaf_get_pcm_offload_output_buffer_size(struct qaf_module *qaf_mod, audio_offload_info_t* info) { return qaf_get_pcm_offload_buffer_size(info, get_pcm_output_buffer_size_samples(qaf_mod)); } /* Gets buffer latency in samples. */ static int get_buffer_latency(struct stream_out *out, uint32_t buffer_size, uint32_t *latency) { unsigned long int samples_in_one_encoded_frame; unsigned long int size_of_one_encoded_frame; switch (out->format) { case AUDIO_FORMAT_AC3: samples_in_one_encoded_frame = DD_FRAME_SIZE; size_of_one_encoded_frame = DD_ENCODER_OUTPUT_SIZE; break; case AUDIO_FORMAT_E_AC3: samples_in_one_encoded_frame = DDP_FRAME_SIZE; size_of_one_encoded_frame = DDP_ENCODER_OUTPUT_SIZE; break; case AUDIO_FORMAT_DTS: samples_in_one_encoded_frame = DTS_FRAME_SIZE; size_of_one_encoded_frame = DTS_ENCODER_OUTPUT_SIZE; break; case AUDIO_FORMAT_DTS_HD: samples_in_one_encoded_frame = DTSHD_FRAME_SIZE; size_of_one_encoded_frame = DTSHD_ENCODER_OUTPUT_SIZE; break; case AUDIO_FORMAT_PCM_16_BIT: samples_in_one_encoded_frame = 1; size_of_one_encoded_frame = ((out->bit_width) >> 3) * popcount(out->channel_mask); break; default: *latency = 0; return (-EINVAL); } *latency = ((buffer_size * samples_in_one_encoded_frame) / size_of_one_encoded_frame); return 0; } /* Returns the number of frames rendered to outside observer. */ static int qaf_get_rendered_frames(struct stream_out *out, uint64_t *frames) { int ret = 0, i; struct str_parms *parms; int value = 0; int module_latency = 0; uint32_t kernel_latency = 0; uint32_t dsp_latency = 0; int signed_frames = 0; char* kvpairs = NULL; struct qaf_module *qaf_mod = NULL; DEBUG_MSG("Output Format %d", out->format); qaf_mod = get_qaf_module_for_input_stream(out); if ((!qaf_mod) || (!qaf_mod->qaf_audio_stream_get_param)) { return -EINVAL; } //Get MM module latency. kvpairs = qaf_mod->qaf_audio_stream_get_param(out->qaf_stream_handle, "get_latency"); if (kvpairs) { parms = str_parms_create_str(kvpairs); ret = str_parms_get_int(parms, "get_latency", &module_latency); if (ret >= 0) { str_parms_destroy(parms); parms = NULL; } free(kvpairs); kvpairs = NULL; } //Get kernel Latency for (i = MAX_QAF_MODULE_OUT - 1; i >= 0; i--) { if (qaf_mod->stream_out[i] == NULL) { continue; } else { unsigned int num_fragments = qaf_mod->stream_out[i]->compr_config.fragments; uint32_t fragment_size = qaf_mod->stream_out[i]->compr_config.fragment_size; uint32_t kernel_buffer_size = num_fragments * fragment_size; get_buffer_latency(qaf_mod->stream_out[i], kernel_buffer_size, &kernel_latency); break; } } //Get DSP latency if ((qaf_mod->stream_out[QAF_OUT_OFFLOAD] != NULL) || (qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH] != NULL)) { unsigned int sample_rate = 0; audio_usecase_t platform_latency = 0; if (qaf_mod->stream_out[QAF_OUT_OFFLOAD]) sample_rate = qaf_mod->stream_out[QAF_OUT_OFFLOAD]->sample_rate; else if (qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]) sample_rate = qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]->sample_rate; if (qaf_mod->stream_out[QAF_OUT_OFFLOAD]) platform_latency = platform_render_latency(qaf_mod->stream_out[QAF_OUT_OFFLOAD]->usecase); else platform_latency = platform_render_latency(qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]->usecase); dsp_latency = (platform_latency * sample_rate) / 1000000LL; } else if (qaf_mod->stream_out[QAF_OUT_TRANSCODE_PASSTHROUGH] != NULL) { unsigned int sample_rate = 0; sample_rate = qaf_mod->stream_out[QAF_OUT_TRANSCODE_PASSTHROUGH]->sample_rate; //TODO: How this sample rate can be used? dsp_latency = (COMPRESS_OFFLOAD_PLAYBACK_LATENCY * sample_rate) / 1000; } // MM Module Latency + Kernel Latency + DSP Latency if ( audio_extn_bt_hal_get_output_stream(qaf_mod->bt_hdl) != NULL) { out->platform_latency = module_latency + audio_extn_bt_hal_get_latency(qaf_mod->bt_hdl); } else { out->platform_latency = (uint32_t)module_latency + kernel_latency + dsp_latency; } if (out->format & AUDIO_FORMAT_PCM_16_BIT) { *frames = 0; signed_frames = out->written - out->platform_latency; // It would be unusual for this value to be negative, but check just in case ... if (signed_frames >= 0) { *frames = signed_frames; } } else if (qaf_mod->qaf_audio_stream_get_param) { kvpairs = qaf_mod->qaf_audio_stream_get_param(out->qaf_stream_handle, "position"); if (kvpairs) { parms = str_parms_create_str(kvpairs); ret = str_parms_get_int(parms, "position", &value); if (ret >= 0) { *frames = value; signed_frames = value - out->platform_latency; // It would be unusual for this value to be negative, but check just in case ... if (signed_frames >= 0) { *frames = signed_frames; } } str_parms_destroy(parms); } } else { ret = -EINVAL; } return ret; } static int qaf_out_get_render_position(const struct audio_stream_out *stream, uint32_t *dsp_frames) { struct stream_out *out = (struct stream_out *)stream; int ret = 0; uint64_t frames=0; struct qaf_module* qaf_mod = NULL; ALOGV("%s, Output Stream %p,dsp frames %d",__func__, stream, (int)dsp_frames); qaf_mod = get_qaf_module_for_input_stream(out); if (!qaf_mod) { ret = out->stream.get_render_position(stream, dsp_frames); ALOGV("%s, non qaf_MOD DSP FRAMES %d",__func__, (int)dsp_frames); return ret; } if (p_qaf->passthrough_out) { pthread_mutex_lock(&p_qaf->lock); ret = p_qaf->passthrough_out->stream.get_render_position((struct audio_stream_out *)p_qaf->passthrough_out, dsp_frames); pthread_mutex_unlock(&p_qaf->lock); ALOGV("%s, PASS THROUGH DSP FRAMES %p",__func__, dsp_frames); return ret; } frames=*dsp_frames; ret = qaf_get_rendered_frames(out, &frames); *dsp_frames = (uint32_t)frames; ALOGV("%s, DSP FRAMES %d",__func__, (int)dsp_frames); return ret; } static int qaf_out_get_presentation_position(const struct audio_stream_out *stream, uint64_t *frames, struct timespec *timestamp) { struct stream_out *out = (struct stream_out *)stream; int ret = 0; DEBUG_MSG("Output Stream %p", stream); //If QAF passthorugh output stream is active. if (p_qaf->passthrough_out) { if (p_qaf->passthrough_in == out) { //If api is called for QAF passthorugh stream then call the primary HAL api to get the position. pthread_mutex_lock(&p_qaf->lock); ret = p_qaf->passthrough_out->stream.get_presentation_position( (struct audio_stream_out *)p_qaf->passthrough_out, frames, timestamp); pthread_mutex_unlock(&p_qaf->lock); } else { //If api is called for other stream then return zero frames. *frames = 0; clock_gettime(CLOCK_MONOTONIC, timestamp); } return ret; } ret = qaf_get_rendered_frames(out, frames); clock_gettime(CLOCK_MONOTONIC, timestamp); return ret; } /* Pause the QAF module input stream. */ static int qaf_stream_pause(struct stream_out *out) { struct qaf_module *qaf_mod = NULL; int ret = -EINVAL; qaf_mod = get_qaf_module_for_input_stream(out); if (!qaf_mod || !qaf_mod->qaf_audio_stream_pause) { return -EINVAL; } if (out->qaf_stream_handle) ret = qaf_mod->qaf_audio_stream_pause(out->qaf_stream_handle); return ret; } /* Pause a QAF input stream. */ static int qaf_out_pause(struct audio_stream_out* stream) { struct stream_out *out = (struct stream_out *)stream; int status = 0; DEBUG_MSG("Output Stream %p", out); lock_output_stream(out); //If QAF passthrough is enabled then block the pause on module stream. if (p_qaf->passthrough_out) { pthread_mutex_lock(&p_qaf->lock); //If pause is received for QAF passthorugh stream then call the primary HAL api. if (p_qaf->passthrough_in == out) { status = p_qaf->passthrough_out->stream.pause( (struct audio_stream_out *)p_qaf->passthrough_out); out->offload_state = OFFLOAD_STATE_PAUSED; } pthread_mutex_unlock(&p_qaf->lock); } else { //Pause the module input stream. status = qaf_stream_pause(out); } unlock_output_stream(out); return status; } /* Drains a qaf input stream. */ static int qaf_out_drain(struct audio_stream_out* stream, audio_drain_type_t type) { struct stream_out *out = (struct stream_out *)stream; int status = 0; struct qaf_module *qaf_mod = NULL; qaf_mod = get_qaf_module_for_input_stream(out); DEBUG_MSG("Output Stream %p", out); lock_output_stream(out); //If QAF passthrough is enabled then block the drain on module stream. if (p_qaf->passthrough_out) { pthread_mutex_lock(&p_qaf->lock); //If drain is received for QAF passthorugh stream then call the primary HAL api. if (p_qaf->passthrough_in == out) { status = p_qaf->passthrough_out->stream.drain( (struct audio_stream_out *)p_qaf->passthrough_out, type); } pthread_mutex_unlock(&p_qaf->lock); } else if (!is_any_stream_running(qaf_mod)) { //If stream is already stopped then send the drain ready. out->client_callback(STREAM_CBK_EVENT_DRAIN_READY, NULL, out->client_cookie); set_stream_state(out, STOPPED); } else { //Drain the module input stream. /* Stream stop will trigger EOS and on EOS_EVENT received from callback DRAIN_READY command is sent */ status = audio_extn_qaf_stream_stop(out); if (status == 0) { //Setting state to stopping as client is expecting drain_ready event. set_stream_state(out, STOPPING); } } unlock_output_stream(out); return status; } /* Flush the QAF module input stream. */ static int audio_extn_qaf_stream_flush(struct stream_out *out) { DEBUG_MSG("Output Stream %p", out); int ret = -EINVAL; struct qaf_module *qaf_mod = NULL; qaf_mod = get_qaf_module_for_input_stream(out); if ((!qaf_mod) || (!qaf_mod->qaf_audio_stream_flush)) { return -EINVAL; } if (out->qaf_stream_handle) ret = qaf_mod->qaf_audio_stream_flush(out->qaf_stream_handle); return ret; } /* Flush the QAF input stream. */ static int qaf_out_flush(struct audio_stream_out* stream) { struct stream_out *out = (struct stream_out *)stream; int status = 0; DEBUG_MSG("Output Stream %p", out); lock_output_stream(out); if (!out->standby) { //If QAF passthrough is active then block the flush on module input streams. if (p_qaf->passthrough_out) { pthread_mutex_lock(&p_qaf->lock); //If flush is received for the QAF passthrough stream then call the primary HAL api. if (p_qaf->passthrough_in == out) { status = p_qaf->passthrough_out->stream.flush( (struct audio_stream_out *)p_qaf->passthrough_out); out->offload_state = OFFLOAD_STATE_IDLE; } pthread_mutex_unlock(&p_qaf->lock); } else { //Flush the module input stream. status = audio_extn_qaf_stream_flush(out); } } unlock_output_stream(out); DEBUG_MSG("Exit"); return status; } static uint32_t qaf_out_get_latency(const struct audio_stream_out *stream) { struct stream_out *out = (struct stream_out *)stream; uint32_t latency = 0; struct qaf_module *qaf_mod = NULL; DEBUG_MSG_VV("Output Stream %p", out); qaf_mod = get_qaf_module_for_input_stream(out); if (!qaf_mod) { return 0; } //If QAF passthrough is active then block the get latency on module input streams. if (p_qaf->passthrough_out) { pthread_mutex_lock(&p_qaf->lock); //If get latency is called for the QAF passthrough stream then call the primary HAL api. if (p_qaf->passthrough_in == out) { latency = p_qaf->passthrough_out->stream.get_latency( (struct audio_stream_out *)p_qaf->passthrough_out); } pthread_mutex_unlock(&p_qaf->lock); } else { if (is_offload_usecase(out->usecase)) { latency = COMPRESS_OFFLOAD_PLAYBACK_LATENCY; } else { uint32_t sample_rate = 0; latency = QAF_MODULE_PCM_INPUT_BUFFER_LATENCY; //Input latency if (qaf_mod->stream_out[QAF_OUT_OFFLOAD]) sample_rate = qaf_mod->stream_out[QAF_OUT_OFFLOAD]->sample_rate; else if (qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]) sample_rate = qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]->sample_rate; if (sample_rate) { latency += (get_pcm_output_buffer_size_samples(qaf_mod) * 1000) / out->sample_rate; } } if ( audio_extn_bt_hal_get_output_stream(qaf_mod->bt_hdl) != NULL) { if (is_offload_usecase(out->usecase)) { latency = audio_extn_bt_hal_get_latency(qaf_mod->bt_hdl) + QAF_COMPRESS_OFFLOAD_PROCESSING_LATENCY; } else { latency = audio_extn_bt_hal_get_latency(qaf_mod->bt_hdl) + QAF_PCM_OFFLOAD_PROCESSING_LATENCY; } } } DEBUG_MSG_VV("Latency %d", latency); return latency; } static bool check_and_get_compressed_device_format(int device, int *format) { switch (device) { case (AUDIO_DEVICE_OUT_AUX_DIGITAL | AUDIO_COMPRESSED_OUT_DD): *format = AUDIO_FORMAT_AC3; return true; case (AUDIO_DEVICE_OUT_AUX_DIGITAL | AUDIO_COMPRESSED_OUT_DDP): *format = AUDIO_FORMAT_E_AC3; return true; case (AUDIO_DEVICE_OUT_AUX_DIGITAL | AUDIO_FORMAT_DTS): *format = AUDIO_FORMAT_DTS; return true; default: return false; } } static void set_out_stream_channel_map(struct stream_out *out, audio_qaf_media_format_t *media_fmt) { if (media_fmt == NULL || out == NULL) { return; } struct audio_out_channel_map_param chmap = {0,{0}}; int i = 0; chmap.channels = media_fmt->channels; for (i = 0; i < chmap.channels && i < AUDIO_CHANNEL_COUNT_MAX && i < AUDIO_QAF_MAX_CHANNELS; i++) { chmap.channel_map[i] = media_fmt->ch_map[i]; } audio_extn_utils_set_channel_map(out, &chmap); } /* Call back function for mm module. */ static void notify_event_callback(audio_session_handle_t session_handle __unused, void *prv_data, void *buf, audio_event_id_t event_id, int size, int device) //TODO: add media format as well. { /* For SPKR: 1. Open pcm device if device_id passed to it SPKR and write the data to pcm device For HDMI 1.Open compress device for HDMI(PCM or AC3) based on current hdmi o/p format and write data to the HDMI device. */ int ret; audio_output_flags_t flags; struct qaf_module* qaf_mod = (struct qaf_module*)prv_data; struct audio_stream_out *bt_stream = NULL; int format; int8_t *data_buffer_p = NULL; uint32_t buffer_size = 0; bool need_to_recreate_stream = false; struct audio_config config; audio_qaf_media_format_t *media_fmt = NULL; if (qaf_mod->is_session_closing) { DEBUG_MSG("Dropping event as session is closing." "Device 0x%X, Event = 0x%X, Bytes to write %d", device, event_id, size); return; } DEBUG_MSG_VV("Device 0x%X, Event = 0x%X, Bytes to write %d", device, event_id, size); /* Default config initialization. */ config.sample_rate = config.offload_info.sample_rate = QAF_OUTPUT_SAMPLING_RATE; config.offload_info.version = AUDIO_INFO_INITIALIZER.version; config.offload_info.size = AUDIO_INFO_INITIALIZER.size; config.format = config.offload_info.format = AUDIO_FORMAT_PCM_16_BIT; config.offload_info.bit_width = CODEC_BACKEND_DEFAULT_BIT_WIDTH; config.offload_info.channel_mask = config.channel_mask = AUDIO_CHANNEL_OUT_STEREO; if (event_id == AUDIO_SEC_FAIL_EVENT) { DEBUG_MSG("%s Security failed, closing session", __func__); qaf_session_close(qaf_mod); return; } pthread_mutex_lock(&p_qaf->lock); if (event_id == AUDIO_DATA_EVENT) { data_buffer_p = (int8_t*)buf; buffer_size = size; } else if (event_id == AUDIO_DATA_EVENT_V2) { audio_qaf_out_buffer_t *buf_payload = (audio_qaf_out_buffer_t*)buf; int index = -1; if ((uint32_t)size < sizeof(audio_qaf_out_buffer_t)) { ERROR_MSG("AUDIO_DATA_EVENT_V2 payload size is not sufficient."); return; } data_buffer_p = (int8_t*)buf_payload->data + buf_payload->offset; buffer_size = buf_payload->size - buf_payload->offset; index = get_media_fmt_array_index_for_output_id(qaf_mod, buf_payload->output_id); if (index < 0) { /*If media format is not received then switch to default values.*/ event_id = AUDIO_DATA_EVENT; } else { media_fmt = &qaf_mod->out_stream_fmt[index]; need_to_recreate_stream = qaf_mod->is_media_fmt_changed[index]; qaf_mod->is_media_fmt_changed[index] = false; config.sample_rate = config.offload_info.sample_rate = media_fmt->sample_rate; config.offload_info.version = AUDIO_INFO_INITIALIZER.version; config.offload_info.size = AUDIO_INFO_INITIALIZER.size; config.format = config.offload_info.format = media_fmt->format; config.offload_info.bit_width = media_fmt->bit_width; if (media_fmt->format == AUDIO_FORMAT_PCM) { if (media_fmt->bit_width == 16) config.format = config.offload_info.format = AUDIO_FORMAT_PCM_16_BIT; else if (media_fmt->bit_width == 24) config.format = config.offload_info.format = AUDIO_FORMAT_PCM_24_BIT_PACKED; else config.format = config.offload_info.format = AUDIO_FORMAT_PCM_32_BIT; } device |= (media_fmt->format & AUDIO_FORMAT_MAIN_MASK); config.channel_mask = audio_channel_out_mask_from_count(media_fmt->channels); config.offload_info.channel_mask = config.channel_mask; } } if (event_id == AUDIO_OUTPUT_MEDIA_FORMAT_EVENT) { audio_qaf_media_format_t *p_fmt = (audio_qaf_media_format_t*)buf; audio_qaf_media_format_t *p_cached_fmt = NULL; int index = -1; if ( (uint32_t)size < sizeof(audio_qaf_media_format_t)) { ERROR_MSG("Size is not proper for the event AUDIO_OUTPUT_MEDIA_FORMAT_EVENT."); return ; } index = get_media_fmt_array_index_for_output_id(qaf_mod, p_fmt->output_id); if (index >= 0) { p_cached_fmt = &qaf_mod->out_stream_fmt[index]; } else if (index < 0 && qaf_mod->new_out_format_index < MAX_QAF_MODULE_OUT) { index = qaf_mod->new_out_format_index; p_cached_fmt = &qaf_mod->out_stream_fmt[index]; qaf_mod->new_out_format_index++; } if (p_cached_fmt == NULL) { ERROR_MSG("Maximum output from a QAF module is reached. Can not process new output."); return ; } if (memcmp(p_cached_fmt, p_fmt, sizeof(audio_qaf_media_format_t)) != 0) { memcpy(p_cached_fmt, p_fmt, sizeof(audio_qaf_media_format_t)); qaf_mod->is_media_fmt_changed[index] = true; } } else if (event_id == AUDIO_DATA_EVENT || event_id == AUDIO_DATA_EVENT_V2) { if (p_qaf->passthrough_out != NULL) { //If QAF passthrough is active then all the module output will be dropped. pthread_mutex_unlock(&p_qaf->lock); DEBUG_MSG("QAF-PSTH is active, DROPPING DATA!"); return; } if (check_and_get_compressed_device_format(device, &format)) { /* * CASE 1: Transcoded output of mm module. * If HDMI is not connected then drop the data. * Only one HDMI output can be supported from all the mm modules of QAF. * Multi-Channel PCM HDMI output streams will be closed from all the mm modules. * If transcoded output of other module is already enabled then this data will be dropped. */ if (!p_qaf->hdmi_connect) { DEBUG_MSG("HDMI not connected, DROPPING DATA!"); pthread_mutex_unlock(&p_qaf->lock); return; } //Closing all the PCM HDMI output stream from QAF. close_all_pcm_hdmi_output(); /* If Media format was changed for this stream then need to re-create the stream. */ if (need_to_recreate_stream && qaf_mod->stream_out[QAF_OUT_TRANSCODE_PASSTHROUGH]) { adev_close_output_stream((struct audio_hw_device *)p_qaf->adev, (struct audio_stream_out *)(qaf_mod->stream_out[QAF_OUT_TRANSCODE_PASSTHROUGH])); qaf_mod->stream_out[QAF_OUT_TRANSCODE_PASSTHROUGH] = NULL; p_qaf->passthrough_enabled = false; } if (!p_qaf->passthrough_enabled && !(qaf_mod->stream_out[QAF_OUT_TRANSCODE_PASSTHROUGH])) { audio_devices_t devices; config.format = config.offload_info.format = format; config.offload_info.channel_mask = config.channel_mask = AUDIO_CHANNEL_OUT_5POINT1; flags = (AUDIO_OUTPUT_FLAG_NON_BLOCKING | AUDIO_OUTPUT_FLAG_COMPRESS_OFFLOAD | AUDIO_OUTPUT_FLAG_DIRECT | AUDIO_OUTPUT_FLAG_COMPRESS_PASSTHROUGH); devices = AUDIO_DEVICE_OUT_AUX_DIGITAL; ret = adev_open_output_stream((struct audio_hw_device *)p_qaf->adev, QAF_DEFAULT_COMPR_PASSTHROUGH_HANDLE, devices, flags, &config, (struct audio_stream_out **)&(qaf_mod->stream_out[QAF_OUT_TRANSCODE_PASSTHROUGH]), NULL); if (ret < 0) { ERROR_MSG("adev_open_output_stream failed with ret = %d!", ret); pthread_mutex_unlock(&p_qaf->lock); return; } if (format == AUDIO_FORMAT_E_AC3) { qaf_mod->stream_out[QAF_OUT_TRANSCODE_PASSTHROUGH]->compr_config.fragment_size = COMPRESS_PASSTHROUGH_DDP_FRAGMENT_SIZE; } qaf_mod->stream_out[QAF_OUT_TRANSCODE_PASSTHROUGH]->compr_config.fragments = COMPRESS_OFFLOAD_NUM_FRAGMENTS; p_qaf->passthrough_enabled = true; } if (qaf_mod->stream_out[QAF_OUT_TRANSCODE_PASSTHROUGH]) { ret = qaf_mod->stream_out[QAF_OUT_TRANSCODE_PASSTHROUGH]->stream.write( (struct audio_stream_out *)qaf_mod->stream_out[QAF_OUT_TRANSCODE_PASSTHROUGH], data_buffer_p, buffer_size); } } else if ((device & AUDIO_DEVICE_OUT_AUX_DIGITAL) && (p_qaf->hdmi_connect) && (p_qaf->hdmi_sink_channels > 2)) { /* CASE 2: Multi-Channel PCM output to HDMI. * If any other HDMI output is already enabled then this has to be dropped. */ if (p_qaf->passthrough_enabled) { //Closing all the multi-Channel PCM HDMI output stream from QAF. close_all_pcm_hdmi_output(); //If passthrough is active then pcm hdmi output has to be dropped. pthread_mutex_unlock(&p_qaf->lock); DEBUG_MSG("Compressed passthrough enabled, DROPPING DATA!"); return; } /* If Media format was changed for this stream then need to re-create the stream. */ if (need_to_recreate_stream && qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]) { adev_close_output_stream((struct audio_hw_device *)p_qaf->adev, (struct audio_stream_out *)(qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH])); qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH] = NULL; p_qaf->mch_pcm_hdmi_enabled = false; } if (!p_qaf->mch_pcm_hdmi_enabled && !(qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH])) { audio_devices_t devices; if (event_id == AUDIO_DATA_EVENT) { config.offload_info.format = config.format = AUDIO_FORMAT_PCM_16_BIT; if (p_qaf->hdmi_sink_channels == 8) { config.offload_info.channel_mask = config.channel_mask = AUDIO_CHANNEL_OUT_7POINT1; } else if (p_qaf->hdmi_sink_channels == 6) { config.offload_info.channel_mask = config.channel_mask = AUDIO_CHANNEL_OUT_5POINT1; } else { config.offload_info.channel_mask = config.channel_mask = AUDIO_CHANNEL_OUT_STEREO; } } devices = AUDIO_DEVICE_OUT_AUX_DIGITAL; flags = AUDIO_OUTPUT_FLAG_DIRECT; ret = adev_open_output_stream((struct audio_hw_device *)p_qaf->adev, QAF_DEFAULT_COMPR_AUDIO_HANDLE, devices, flags, &config, (struct audio_stream_out **)&(qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]), NULL); if (ret < 0) { ERROR_MSG("adev_open_output_stream failed with ret = %d!", ret); pthread_mutex_unlock(&p_qaf->lock); return; } set_out_stream_channel_map(qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH], media_fmt); qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]->compr_config.fragments = COMPRESS_OFFLOAD_NUM_FRAGMENTS; qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]->compr_config.fragment_size = qaf_get_pcm_offload_output_buffer_size(qaf_mod, &config.offload_info); p_qaf->mch_pcm_hdmi_enabled = true; if ((qaf_mod->stream_in[QAF_IN_MAIN] && qaf_mod->stream_in[QAF_IN_MAIN]->client_callback != NULL) || (qaf_mod->stream_in[QAF_IN_MAIN_2] && qaf_mod->stream_in[QAF_IN_MAIN_2]->client_callback != NULL)) { if (qaf_mod->stream_in[QAF_IN_MAIN]) { qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]->stream.set_callback( (struct audio_stream_out *)qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH], qaf_mod->stream_in[QAF_IN_MAIN]->client_callback, qaf_mod->stream_in[QAF_IN_MAIN]->client_cookie); } if (qaf_mod->stream_in[QAF_IN_MAIN_2]) { qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]->stream.set_callback( (struct audio_stream_out *)qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH], qaf_mod->stream_in[QAF_IN_MAIN_2]->client_callback, qaf_mod->stream_in[QAF_IN_MAIN_2]->client_cookie); } } else if (qaf_mod->stream_in[QAF_IN_PCM] && qaf_mod->stream_in[QAF_IN_PCM]->client_callback != NULL) { qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]->stream.set_callback( (struct audio_stream_out *)qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH], qaf_mod->stream_in[QAF_IN_PCM]->client_callback, qaf_mod->stream_in[QAF_IN_PCM]->client_cookie); } int index = -1; if (qaf_mod->adsp_hdlr_config[QAF_IN_MAIN].adsp_hdlr_config_valid) index = (int) QAF_IN_MAIN; else if (qaf_mod->adsp_hdlr_config[QAF_IN_MAIN_2].adsp_hdlr_config_valid) index = (int) QAF_IN_MAIN_2; else if (qaf_mod->adsp_hdlr_config[QAF_IN_PCM].adsp_hdlr_config_valid) index = (int) QAF_IN_PCM; if (index >= 0) { if (qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]->standby) qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]->stream.write( (struct audio_stream_out *)qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH], NULL, 0); lock_output_stream(qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]); ret = audio_extn_out_set_param_data( qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH], AUDIO_EXTN_PARAM_ADSP_STREAM_CMD, (audio_extn_param_payload *)&qaf_mod->adsp_hdlr_config[index].event_params); unlock_output_stream(qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]); } } if (qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]) { ret = qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH]->stream.write( (struct audio_stream_out *)qaf_mod->stream_out[QAF_OUT_OFFLOAD_MCH], data_buffer_p, buffer_size); } } else { /* CASE 3: PCM output. */ /* If Media format was changed for this stream then need to re-create the stream. */ if (need_to_recreate_stream && qaf_mod->stream_out[QAF_OUT_OFFLOAD]) { adev_close_output_stream((struct audio_hw_device *)p_qaf->adev, (struct audio_stream_out *)(qaf_mod->stream_out[QAF_OUT_OFFLOAD])); qaf_mod->stream_out[QAF_OUT_OFFLOAD] = NULL; } bt_stream = audio_extn_bt_hal_get_output_stream(qaf_mod->bt_hdl); if (bt_stream != NULL) { if (qaf_mod->stream_out[QAF_OUT_OFFLOAD]) { adev_close_output_stream((struct audio_hw_device *)p_qaf->adev, (struct audio_stream_out *)(qaf_mod->stream_out[QAF_OUT_OFFLOAD])); qaf_mod->stream_out[QAF_OUT_OFFLOAD] = NULL; } audio_extn_bt_hal_out_write(p_qaf->bt_hdl, data_buffer_p, buffer_size); } else if (NULL == qaf_mod->stream_out[QAF_OUT_OFFLOAD]) { audio_devices_t devices; if (qaf_mod->stream_in[QAF_IN_MAIN]) devices = qaf_mod->stream_in[QAF_IN_MAIN]->devices; else devices = qaf_mod->stream_in[QAF_IN_PCM]->devices; //If multi channel pcm or passthrough is already enabled then remove the hdmi flag from device. if (p_qaf->mch_pcm_hdmi_enabled || p_qaf->passthrough_enabled) { if (devices & AUDIO_DEVICE_OUT_AUX_DIGITAL) devices ^= AUDIO_DEVICE_OUT_AUX_DIGITAL; } if (devices == 0) { devices = device; } flags = AUDIO_OUTPUT_FLAG_DIRECT; /* TODO:: Need to Propagate errors to framework */ ret = adev_open_output_stream((struct audio_hw_device *)p_qaf->adev, QAF_DEFAULT_COMPR_AUDIO_HANDLE, devices, flags, &config, (struct audio_stream_out **)&(qaf_mod->stream_out[QAF_OUT_OFFLOAD]), NULL); if (ret < 0) { ERROR_MSG("adev_open_output_stream failed with ret = %d!", ret); pthread_mutex_unlock(&p_qaf->lock); return; } set_out_stream_channel_map(qaf_mod->stream_out[QAF_OUT_OFFLOAD], media_fmt); if ((qaf_mod->stream_in[QAF_IN_MAIN] && qaf_mod->stream_in[QAF_IN_MAIN]->client_callback != NULL) || (qaf_mod->stream_in[QAF_IN_MAIN_2] && qaf_mod->stream_in[QAF_IN_MAIN_2]->client_callback != NULL)) { if (qaf_mod->stream_in[QAF_IN_MAIN]) { qaf_mod->stream_out[QAF_OUT_OFFLOAD]->stream.set_callback( (struct audio_stream_out *)qaf_mod->stream_out[QAF_OUT_OFFLOAD], qaf_mod->stream_in[QAF_IN_MAIN]->client_callback, qaf_mod->stream_in[QAF_IN_MAIN]->client_cookie); } if (qaf_mod->stream_in[QAF_IN_MAIN_2]) { qaf_mod->stream_out[QAF_OUT_OFFLOAD]->stream.set_callback( (struct audio_stream_out *)qaf_mod->stream_out[QAF_OUT_OFFLOAD], qaf_mod->stream_in[QAF_IN_MAIN_2]->client_callback, qaf_mod->stream_in[QAF_IN_MAIN_2]->client_cookie); } } else if (qaf_mod->stream_in[QAF_IN_PCM] && qaf_mod->stream_in[QAF_IN_PCM]->client_callback != NULL) { qaf_mod->stream_out[QAF_OUT_OFFLOAD]->stream.set_callback( (struct audio_stream_out *)qaf_mod->stream_out[QAF_OUT_OFFLOAD], qaf_mod->stream_in[QAF_IN_PCM]->client_callback, qaf_mod->stream_in[QAF_IN_PCM]->client_cookie); } qaf_mod->stream_out[QAF_OUT_OFFLOAD]->compr_config.fragments = COMPRESS_OFFLOAD_NUM_FRAGMENTS; qaf_mod->stream_out[QAF_OUT_OFFLOAD]->compr_config.fragment_size = qaf_get_pcm_offload_output_buffer_size(qaf_mod, &config.offload_info); if (qaf_mod->is_vol_set) { DEBUG_MSG("Setting Volume Left[%f], Right[%f]", qaf_mod->vol_left, qaf_mod->vol_right); qaf_mod->stream_out[QAF_OUT_OFFLOAD]->stream.set_volume( (struct audio_stream_out *)qaf_mod->stream_out[QAF_OUT_OFFLOAD], qaf_mod->vol_left, qaf_mod->vol_right); } int index = -1; if (qaf_mod->adsp_hdlr_config[QAF_IN_MAIN].adsp_hdlr_config_valid) index = (int) QAF_IN_MAIN; else if (qaf_mod->adsp_hdlr_config[QAF_IN_MAIN_2].adsp_hdlr_config_valid) index = (int) QAF_IN_MAIN_2; else if (qaf_mod->adsp_hdlr_config[QAF_IN_PCM].adsp_hdlr_config_valid) index = (int) QAF_IN_PCM; if (index >= 0) { if (qaf_mod->stream_out[QAF_OUT_OFFLOAD]->standby) { qaf_mod->stream_out[QAF_OUT_OFFLOAD]->stream.write( (struct audio_stream_out *)qaf_mod->stream_out[QAF_OUT_OFFLOAD], NULL, 0); } lock_output_stream(qaf_mod->stream_out[QAF_OUT_OFFLOAD]); ret = audio_extn_out_set_param_data( qaf_mod->stream_out[QAF_OUT_OFFLOAD], AUDIO_EXTN_PARAM_ADSP_STREAM_CMD, (audio_extn_param_payload *)&qaf_mod->adsp_hdlr_config[index].event_params); unlock_output_stream(qaf_mod->stream_out[QAF_OUT_OFFLOAD]); } } /* * TODO:: Since this is mixed data, * need to identify to which stream the error should be sent */ if (qaf_mod->stream_out[QAF_OUT_OFFLOAD]) { ret = qaf_mod->stream_out[QAF_OUT_OFFLOAD]->stream.write( (struct audio_stream_out *)qaf_mod->stream_out[QAF_OUT_OFFLOAD], data_buffer_p, buffer_size); } } DEBUG_MSG_VV("Bytes written = %d", ret); } else if (event_id == AUDIO_EOS_EVENT || event_id == AUDIO_EOS_MAIN_DD_DDP_EVENT || event_id == AUDIO_EOS_MAIN_2_DD_DDP_EVENT || event_id == AUDIO_EOS_MAIN_AAC_EVENT || event_id == AUDIO_EOS_MAIN_AC4_EVENT || event_id == AUDIO_EOS_ASSOC_DD_DDP_EVENT || event_id == AUDIO_EOS_ASSOC_AAC_EVENT || event_id == AUDIO_EOS_ASSOC_AC4_EVENT) { struct stream_out *out = qaf_mod->stream_in[QAF_IN_MAIN]; struct stream_out *out_pcm = qaf_mod->stream_in[QAF_IN_PCM]; struct stream_out *out_main2 = qaf_mod->stream_in[QAF_IN_MAIN_2]; struct stream_out *out_assoc = qaf_mod->stream_in[QAF_IN_ASSOC]; /** * TODO:: Only DD/DDP Associate Eos is handled, need to add support * for other formats. */ if (event_id == AUDIO_EOS_EVENT && (out_pcm != NULL) && (check_stream_state(out_pcm, STOPPING))) { lock_output_stream(out_pcm); out_pcm->client_callback(STREAM_CBK_EVENT_DRAIN_READY, NULL, out_pcm->client_cookie); set_stream_state(out_pcm, STOPPED); unlock_output_stream(out_pcm); DEBUG_MSG("sent pcm DRAIN_READY"); } else if ( (event_id == AUDIO_EOS_ASSOC_DD_DDP_EVENT || event_id == AUDIO_EOS_ASSOC_AAC_EVENT || event_id == AUDIO_EOS_ASSOC_AC4_EVENT) && (out_assoc != NULL) && (check_stream_state(out_assoc, STOPPING))) { lock_output_stream(out_assoc); out_assoc->client_callback(STREAM_CBK_EVENT_DRAIN_READY, NULL, out_assoc->client_cookie); set_stream_state(out_assoc, STOPPED); unlock_output_stream(out_assoc); DEBUG_MSG("sent associated DRAIN_READY"); } else if (event_id == AUDIO_EOS_MAIN_2_DD_DDP_EVENT && (out_main2 != NULL) && (check_stream_state(out_main2, STOPPING))) { lock_output_stream(out_main2); out_main2->client_callback(STREAM_CBK_EVENT_DRAIN_READY, NULL, out_main2->client_cookie); set_stream_state(out_main2, STOPPED); unlock_output_stream(out_main2); DEBUG_MSG("sent main2 DRAIN_READY"); } else if ((out != NULL) && (check_stream_state(out, STOPPING))) { lock_output_stream(out); out->client_callback(STREAM_CBK_EVENT_DRAIN_READY, NULL, out->client_cookie); set_stream_state(out, STOPPED); unlock_output_stream(out); DEBUG_MSG("sent main DRAIN_READY"); } } else if (event_id == AUDIO_MAIN_EOS_EVENT || event_id == AUDIO_ASSOC_EOS_EVENT) { struct stream_out *out = NULL; if (event_id == AUDIO_MAIN_EOS_EVENT) { out = qaf_mod->stream_in[QAF_IN_MAIN]; } else { out = qaf_mod->stream_in[QAF_IN_ASSOC]; } if ((out != NULL) && (check_stream_state(out, STOPPING))) { lock_output_stream(out); out->client_callback(STREAM_CBK_EVENT_DRAIN_READY, NULL, out->client_cookie); set_stream_state(out, STOPPED); unlock_output_stream(out); DEBUG_MSG("sent DRAIN_READY"); } } pthread_mutex_unlock(&p_qaf->lock); return; } /* Close the mm module session. */ static int qaf_session_close(struct qaf_module* qaf_mod) { int j; DEBUG_MSG("Closing Session."); //Check if all streams are closed or not. for (j = 0; j < MAX_QAF_MODULE_IN; j++) { if (qaf_mod->stream_in[j] != NULL) { break; } } if (j != MAX_QAF_MODULE_IN) { return 0; //Some stream is already active, Can not close session. } qaf_mod->is_session_closing = true; pthread_mutex_lock(&p_qaf->lock); if (qaf_mod->session_handle != NULL && qaf_mod->qaf_audio_session_close) { #ifdef AUDIO_EXTN_IP_HDLR_ENABLED if (qaf_mod == &p_qaf->qaf_mod[MS12]) { audio_extn_ip_hdlr_intf_close(qaf_mod->ip_hdlr_hdl, false, qaf_mod->session_handle); } #endif qaf_mod->qaf_audio_session_close(qaf_mod->session_handle); qaf_mod->session_handle = NULL; qaf_mod->is_vol_set = false; memset(qaf_mod->stream_state, 0, sizeof(qaf_mod->stream_state)); } for (j = 0; j < MAX_QAF_MODULE_OUT; j++) { if (qaf_mod->stream_out[j]) { adev_close_output_stream((struct audio_hw_device *)p_qaf->adev, (struct audio_stream_out *)(qaf_mod->stream_out[j])); qaf_mod->stream_out[j] = NULL; } memset(&qaf_mod->out_stream_fmt[j], 0, sizeof(audio_qaf_media_format_t)); qaf_mod->is_media_fmt_changed[j] = false; } qaf_mod->new_out_format_index = 0; pthread_mutex_unlock(&p_qaf->lock); qaf_mod->is_session_closing = false; DEBUG_MSG("Session Closed."); return 0; } /* Close the stream of QAF module. */ static int qaf_stream_close(struct stream_out *out) { int ret = -EINVAL; struct qaf_module *qaf_mod = NULL; int index = -1; DEBUG_MSG("Flag [0x%x], Stream handle [%p]", out->flags, out->qaf_stream_handle); qaf_mod = get_qaf_module_for_input_stream(out); index = get_input_stream_index(out); if (!qaf_mod || !qaf_mod->qaf_audio_stream_close || index < 0) { return -EINVAL; } pthread_mutex_lock(&p_qaf->lock); set_stream_state(out,STOPPED); qaf_mod->stream_in[index] = NULL; memset(&qaf_mod->adsp_hdlr_config[index], 0, sizeof(struct qaf_adsp_hdlr_config_state)); lock_output_stream(out); if (out->qaf_stream_handle) { ret = qaf_mod->qaf_audio_stream_close(out->qaf_stream_handle); out->qaf_stream_handle = NULL; } unlock_output_stream(out); pthread_mutex_unlock(&p_qaf->lock); //If all streams are closed then close the session. qaf_session_close(qaf_mod); DEBUG_MSG(); return ret; } /* Open a MM module session with QAF. */ static int audio_extn_qaf_session_open(mm_module_type mod_type, struct stream_out *out) { ALOGV("%s %d", __func__, __LINE__); unsigned char* license_data = NULL; device_license_config_t lic_config = {NULL, 0, 0}; int ret = -ENOSYS; struct qaf_module *qaf_mod = NULL; if (mod_type >= MAX_MM_MODULE_TYPE || !(p_qaf->qaf_mod[mod_type].qaf_audio_session_open)) return -ENOTSUP; //Not supported by QAF module. pthread_mutex_lock(&p_qaf->lock); qaf_mod = &(p_qaf->qaf_mod[mod_type]); //If session is already opened then return. if (qaf_mod->session_handle) { DEBUG_MSG("Session is already opened."); pthread_mutex_unlock(&p_qaf->lock); return 0; } #ifndef AUDIO_EXTN_IP_HDLR_ENABLED { int size=0; char value[PROPERTY_VALUE_MAX] = {0}; if (mod_type == MS12) { //Getting the license license_data = platform_get_license((struct audio_hw_device *)(p_qaf->adev->platform), &size); if (!license_data) { ERROR_MSG("License data is not present."); pthread_mutex_unlock(&p_qaf->lock); return -EINVAL; } lic_config.p_license = (unsigned char*)calloc(1, size); if (lic_config.p_license == NULL) { ERROR_MSG("Out of Memory"); ret = -ENOMEM; goto exit; } lic_config.l_size = size; memcpy(lic_config.p_license, license_data, size); if (property_get("vendor.audio.qaf.manufacturer", value, "") && atoi(value)) { lic_config.manufacturer_id = (unsigned long)atoi(value); } else { ERROR_MSG("vendor.audio.qaf.manufacturer id is not set"); ret = -EINVAL; goto exit; } } } #endif ret = qaf_mod->qaf_audio_session_open(&qaf_mod->session_handle, AUDIO_SESSION_BROADCAST, (void *)(qaf_mod), (void *)&lic_config); if (ret < 0) { ERROR_MSG("Error in session open %d", ret); goto exit; } if (qaf_mod->session_handle == NULL) { ERROR_MSG("Session handle is NULL."); ret = -ENOMEM; goto exit; } if (qaf_mod->qaf_register_event_callback) qaf_mod->qaf_register_event_callback(qaf_mod->session_handle, qaf_mod, ¬ify_event_callback, AUDIO_DATA_EVENT_V2); if(p_qaf->bt_connect) set_bt_configuration_to_module(); else set_hdmi_configuration_to_module(); #ifdef AUDIO_EXTN_IP_HDLR_ENABLED if (mod_type == MS12) { ret = audio_extn_ip_hdlr_intf_open(qaf_mod->ip_hdlr_hdl, false, qaf_mod->session_handle, out->usecase); if (ret < 0) { ERROR_MSG("%s audio_extn_ip_hdlr_intf_open failed, ret = %d", __func__, ret); goto exit; } } #endif exit: if (license_data != NULL) { free(license_data); license_data = NULL; } if (lic_config.p_license != NULL) { free(lic_config.p_license); lic_config.p_license = NULL; } pthread_mutex_unlock(&p_qaf->lock); return ret; } /* opens a stream in QAF module. */ static int qaf_stream_open(struct stream_out *out, struct audio_config *config, audio_output_flags_t flags, audio_devices_t devices) { int status = -EINVAL; mm_module_type mmtype = get_mm_module_for_format(config->format); struct qaf_module* qaf_mod = NULL; DEBUG_MSG("Flags 0x%x, Device 0x%x", flags, devices); if (mmtype >= MAX_MM_MODULE_TYPE) { ERROR_MSG("Unsupported Stream"); return -ENOTSUP; } if (p_qaf->qaf_mod[mmtype].qaf_audio_session_open == NULL || p_qaf->qaf_mod[mmtype].qaf_audio_stream_open == NULL) { ERROR_MSG("Session or Stream is NULL"); return -ENOTSUP; } //Open the module session, if not opened already. status = audio_extn_qaf_session_open(mmtype, out); qaf_mod = &(p_qaf->qaf_mod[mmtype]); if ((status != 0) || (qaf_mod->session_handle == NULL)) { ERROR_MSG("Failed to open session."); return status; } audio_stream_config_t input_config; input_config.sample_rate = config->sample_rate; input_config.channels = popcount(config->channel_mask); input_config.format = config->format; if (input_config.format != AUDIO_FORMAT_PCM_16_BIT) { input_config.format &= AUDIO_FORMAT_MAIN_MASK; } DEBUG_MSG("stream_open sample_rate(%d) channels(%d) devices(%#x) flags(%#x) format(%#x)", input_config.sample_rate, input_config.channels, devices, flags, input_config.format); if (input_config.format == AUDIO_FORMAT_PCM_16_BIT) { //If PCM stream is already opened then fail this stream open. if (qaf_mod->stream_in[QAF_IN_PCM]) { ERROR_MSG("PCM input is already active."); return -ENOTSUP; } //TODO: Flag can be system tone or external associated PCM. status = qaf_mod->qaf_audio_stream_open(qaf_mod->session_handle, &out->qaf_stream_handle, input_config, devices, AUDIO_STREAM_SYSTEM_TONE); if (status == 0) { qaf_mod->stream_in[QAF_IN_PCM] = out; } else { ERROR_MSG("System tone stream open failed with QAF module !!!"); } } else if ((flags & AUDIO_OUTPUT_FLAG_MAIN) && (flags & AUDIO_OUTPUT_FLAG_ASSOCIATED)) { if (is_main_active(qaf_mod) || is_dual_main_active(qaf_mod)) { ERROR_MSG("Dual Main or Main already active. So, Cannot open main and associated stream"); return -EINVAL; } else { status = qaf_mod->qaf_audio_stream_open(qaf_mod->session_handle, &out->qaf_stream_handle, input_config, devices, /*flags*/AUDIO_STREAM_MAIN); if (status == 0) { DEBUG_MSG("Open stream for Input with both Main and Associated stream contents with flag(%x) and stream_handle(%p)", flags, out->qaf_stream_handle); qaf_mod->stream_in[QAF_IN_MAIN] = out; } else { ERROR_MSG("Stream Open FAILED !!!"); } } } else if ((flags & AUDIO_OUTPUT_FLAG_MAIN) || ((!(flags & AUDIO_OUTPUT_FLAG_MAIN)) && (!(flags & AUDIO_OUTPUT_FLAG_ASSOCIATED)))) { /* Assume Main if no flag is set */ if (is_dual_main_active(qaf_mod)) { ERROR_MSG("Dual Main already active. So, Cannot open main stream"); return -EINVAL; } else if (is_main_active(qaf_mod) && qaf_mod->stream_in[QAF_IN_ASSOC]) { ERROR_MSG("Main and Associated already active. So, Cannot open main stream"); return -EINVAL; } else if (is_main_active(qaf_mod) && (mmtype != MS12)) { ERROR_MSG("Main already active and Not an MS12 format. So, Cannot open another main stream"); return -EINVAL; } else { status = qaf_mod->qaf_audio_stream_open(qaf_mod->session_handle, &out->qaf_stream_handle, input_config, devices, /*flags*/AUDIO_STREAM_MAIN); if (status == 0) { DEBUG_MSG("Open stream for Input with only Main flag(%x) stream_handle(%p)", flags, out->qaf_stream_handle); if(qaf_mod->stream_in[QAF_IN_MAIN]) { qaf_mod->stream_in[QAF_IN_MAIN_2] = out; } else { qaf_mod->stream_in[QAF_IN_MAIN] = out; } } else { ERROR_MSG("Stream Open FAILED !!!"); } } } else if ((flags & AUDIO_OUTPUT_FLAG_ASSOCIATED)) { if (is_dual_main_active(qaf_mod)) { ERROR_MSG("Dual Main already active. So, Cannot open associated stream"); return -EINVAL; } else if (!is_main_active(qaf_mod)) { ERROR_MSG("Main not active. So, Cannot open associated stream"); return -EINVAL; } else if (qaf_mod->stream_in[QAF_IN_ASSOC]) { ERROR_MSG("Associated already active. So, Cannot open associated stream"); return -EINVAL; } status = qaf_mod->qaf_audio_stream_open(qaf_mod->session_handle, &out->qaf_stream_handle, input_config, devices, /*flags*/AUDIO_STREAM_ASSOCIATED); if (status == 0) { DEBUG_MSG("Open stream for Input with only Associated flag(%x) stream handle(%p)", flags, out->qaf_stream_handle); qaf_mod->stream_in[QAF_IN_ASSOC] = out; } else { ERROR_MSG("Stream Open FAILED !!!"); } } if (status != 0) { //If no stream is active then close the session. qaf_session_close(qaf_mod); return 0; } //If Device is HDMI, QAF passthrough is enabled and there is no previous QAF passthrough input stream. if ((!p_qaf->passthrough_in) && (devices & AUDIO_DEVICE_OUT_AUX_DIGITAL) && audio_extn_qaf_passthrough_enabled(out)) { //Assign the QAF passthrough input stream. p_qaf->passthrough_in = out; //If HDMI is connected and format is supported by HDMI then create QAF passthrough output stream. if (p_qaf->hdmi_connect && platform_is_edid_supported_format(p_qaf->adev->platform, out->format)) { status = create_qaf_passthrough_stream(); if (status < 0) { qaf_stream_close(out); ERROR_MSG("QAF passthrough stream creation failed with error %d", status); return status; } } /*Else: since QAF passthrough input stream is already initialized, * when hdmi is connected * then qaf passthrough output stream will be created. */ } DEBUG_MSG(); return status; } /* Resume a QAF stream. */ static int qaf_out_resume(struct audio_stream_out* stream) { struct stream_out *out = (struct stream_out *)stream; int status = 0; DEBUG_MSG("Output Stream %p", out); lock_output_stream(out); //If QAF passthrough is active then block the resume on module input streams. if (p_qaf->passthrough_out) { //If resume is received for the QAF passthrough stream then call the primary HAL api. pthread_mutex_lock(&p_qaf->lock); if (p_qaf->passthrough_in == out) { status = p_qaf->passthrough_out->stream.resume( (struct audio_stream_out*)p_qaf->passthrough_out); if (!status) out->offload_state = OFFLOAD_STATE_PLAYING; } pthread_mutex_unlock(&p_qaf->lock); } else { //Flush the module input stream. status = qaf_stream_start(out); } unlock_output_stream(out); DEBUG_MSG(); return status; } /* Offload thread for QAF output streams. */ static void *qaf_offload_thread_loop(void *context) { struct stream_out *out = (struct stream_out *)context; struct listnode *item; int ret = 0; struct str_parms *parms = NULL; int value = 0; char* kvpairs = NULL; struct qaf_module *qaf_mod = NULL; qaf_mod = get_qaf_module_for_input_stream(out); if (!qaf_mod) return NULL; setpriority(PRIO_PROCESS, 0, ANDROID_PRIORITY_AUDIO); set_sched_policy(0, SP_FOREGROUND); prctl(PR_SET_NAME, (unsigned long)"Offload Callback", 0, 0, 0); lock_output_stream(out); DEBUG_MSG(); for (;;) { struct offload_cmd *cmd = NULL; stream_callback_event_t event; bool send_callback = false; DEBUG_MSG_VV("List Empty %d (1:TRUE, 0:FALSE)", list_empty(&out->qaf_offload_cmd_list)); if (list_empty(&out->qaf_offload_cmd_list)) { DEBUG_MSG_VV("SLEEPING"); pthread_cond_wait(&out->qaf_offload_cond, &out->lock); DEBUG_MSG_VV("RUNNING"); continue; } item = list_head(&out->qaf_offload_cmd_list); cmd = node_to_item(item, struct offload_cmd, node); list_remove(item); if (cmd->cmd == OFFLOAD_CMD_EXIT) { free(cmd); break; } unlock_output_stream(out); send_callback = false; switch (cmd->cmd) { case OFFLOAD_CMD_WAIT_FOR_BUFFER: { DEBUG_MSG_VV("wait for buffer availability"); while (1) { kvpairs = qaf_mod->qaf_audio_stream_get_param(out->qaf_stream_handle, "buf_available"); if (kvpairs) { parms = str_parms_create_str(kvpairs); ret = str_parms_get_int(parms, "buf_available", &value); if (ret >= 0) { if (value > 0) { DEBUG_MSG_VV("buffer available"); str_parms_destroy(parms); parms = NULL; break; } else { DEBUG_MSG_VV("sleep"); str_parms_destroy(parms); parms = NULL; usleep(10000); } } free(kvpairs); kvpairs = NULL; } } send_callback = true; event = STREAM_CBK_EVENT_WRITE_READY; break; } default: DEBUG_MSG("unknown command received: %d", cmd->cmd); break; } lock_output_stream(out); if (send_callback && out->client_callback) { out->client_callback(event, NULL, out->client_cookie); } free(cmd); } while (!list_empty(&out->qaf_offload_cmd_list)) { item = list_head(&out->qaf_offload_cmd_list); list_remove(item); free (node_to_item( item, struct offload_cmd, node)); } unlock_output_stream(out); return NULL; } /* Create the offload callback thread for QAF output stream. */ static int qaf_create_offload_callback_thread(struct stream_out *out) { DEBUG_MSG("Output Stream %p", out); lock_output_stream(out); pthread_cond_init(&out->qaf_offload_cond, (const pthread_condattr_t *)NULL); list_init(&out->qaf_offload_cmd_list); pthread_create(&out->qaf_offload_thread, (const pthread_attr_t *)NULL, qaf_offload_thread_loop, out); unlock_output_stream(out); return 0; } /* Destroy the offload callback thread of QAF output stream. */ static int qaf_destroy_offload_callback_thread(struct stream_out *out) { DEBUG_MSG("Output Stream %p", out); qaf_send_offload_cmd_l(out, OFFLOAD_CMD_EXIT); pthread_join(out->qaf_offload_thread, (void **)NULL); pthread_cond_destroy(&out->qaf_offload_cond); return 0; } /* Sets the stream set parameters (device routing information). */ static int qaf_out_set_parameters(struct audio_stream *stream, const char *kvpairs) { struct str_parms *parms; char value[32]; int val = 0; struct stream_out *out = (struct stream_out *)stream; int ret = 0; int err = 0; struct qaf_module *qaf_mod = NULL; DEBUG_MSG("usecase(%d: %s) kvpairs: %s", out->usecase, use_case_table[out->usecase], kvpairs); parms = str_parms_create_str(kvpairs); err = str_parms_get_str(parms, AUDIO_PARAMETER_STREAM_ROUTING, value, sizeof(value)); if (err < 0) return err; val = atoi(value); qaf_mod = get_qaf_module_for_input_stream(out); if (!qaf_mod) return (-EINVAL); //TODO: HDMI is connected but user doesn't want HDMI output, close both HDMI outputs. /* Setting new device information to the mm module input streams. * This is needed if QAF module output streams are not created yet. */ out->devices = val; #ifndef SPLIT_A2DP_ENABLED if (val == AUDIO_DEVICE_OUT_BLUETOOTH_A2DP) { //If device is BT then open the BT stream if not already opened. if ( audio_extn_bt_hal_get_output_stream(qaf_mod->bt_hdl) == NULL && audio_extn_bt_hal_get_device(qaf_mod->bt_hdl) != NULL) { ret = audio_extn_bt_hal_open_output_stream(qaf_mod->bt_hdl, QAF_OUTPUT_SAMPLING_RATE, AUDIO_CHANNEL_OUT_STEREO, CODEC_BACKEND_DEFAULT_BIT_WIDTH); if (ret != 0) { ERROR_MSG("BT Output stream open failure!"); } } } else if (val != 0) { //If device is not BT then close the BT stream if already opened. if ( audio_extn_bt_hal_get_output_stream(qaf_mod->bt_hdl) != NULL) { audio_extn_bt_hal_close_output_stream(qaf_mod->bt_hdl); } } #endif if (p_qaf->passthrough_in == out) { //Device routing is received for QAF passthrough stream. if (!(val & AUDIO_DEVICE_OUT_AUX_DIGITAL)) { //HDMI route is disabled. //If QAF pasthrough output is enabled. Close it. close_qaf_passthrough_stream(); //Send the routing information to mm module pcm output. if (qaf_mod->stream_out[QAF_OUT_OFFLOAD]) { ret = qaf_mod->stream_out[QAF_OUT_OFFLOAD]->stream.common.set_parameters( (struct audio_stream *)qaf_mod->stream_out[QAF_OUT_OFFLOAD], kvpairs); } //else: device info is updated in the input streams. } else { //HDMI route is enabled. //create the QAf passthrough stream, if not created already. ret = create_qaf_passthrough_stream(); if (p_qaf->passthrough_out != NULL) { //If QAF passthrough out is enabled then send routing information. ret = p_qaf->passthrough_out->stream.common.set_parameters( (struct audio_stream *)p_qaf->passthrough_out, kvpairs); } } } else { //Send the routing information to mm module pcm output. if (qaf_mod->stream_out[QAF_OUT_OFFLOAD]) { ret = qaf_mod->stream_out[QAF_OUT_OFFLOAD]->stream.common.set_parameters( (struct audio_stream *)qaf_mod->stream_out[QAF_OUT_OFFLOAD], kvpairs); } //else: device info is updated in the input streams. } str_parms_destroy(parms); return ret; } /* Checks if a stream is QAF stream or not. */ bool audio_extn_is_qaf_stream(struct stream_out *out) { struct qaf_module *qaf_mod = get_qaf_module_for_input_stream(out); if (qaf_mod) { return true; } return false; } /* API to send playback stream specific config parameters */ int audio_extn_qaf_out_set_param_data(struct stream_out *out, audio_extn_param_id param_id, audio_extn_param_payload *payload) { int ret = -EINVAL; int index; struct stream_out *new_out = NULL; struct audio_adsp_event *adsp_event; struct qaf_module *qaf_mod = get_qaf_module_for_input_stream(out); if (!out || !qaf_mod || !payload) { ERROR_MSG("Invalid Param"); return ret; } /* In qaf output render session may not be opened at this time. to handle it store adsp_hdlr param info so that it can be applied later after opening render session from ms12 callback */ if (param_id == AUDIO_EXTN_PARAM_ADSP_STREAM_CMD) { index = get_input_stream_index(out); if (index < 0) { ERROR_MSG("Invalid stream"); return ret; } adsp_event = (struct audio_adsp_event *)payload; if (payload->adsp_event_params.payload_length <= AUDIO_MAX_ADSP_STREAM_CMD_PAYLOAD_LEN) { pthread_mutex_lock(&p_qaf->lock); memcpy(qaf_mod->adsp_hdlr_config[index].event_payload, adsp_event->payload, adsp_event->payload_length); qaf_mod->adsp_hdlr_config[index].event_params.payload = qaf_mod->adsp_hdlr_config[index].event_payload; qaf_mod->adsp_hdlr_config[index].event_params.payload_length = adsp_event->payload_length; qaf_mod->adsp_hdlr_config[index].adsp_hdlr_config_valid = true; pthread_mutex_unlock(&p_qaf->lock); } else { ERROR_MSG("Invalid adsp event length %d", adsp_event->payload_length); return ret; } ret = 0; } /* apply param for all active out sessions */ for (index = 0; index < MAX_QAF_MODULE_OUT; index++) { new_out = qaf_mod->stream_out[index]; if (!new_out) continue; /*ADSP event is not supported for passthrough*/ if ((param_id == AUDIO_EXTN_PARAM_ADSP_STREAM_CMD) && !(new_out->flags == AUDIO_OUTPUT_FLAG_DIRECT)) continue; if (new_out->standby) new_out->stream.write((struct audio_stream_out *)new_out, NULL, 0); lock_output_stream(new_out); ret = audio_extn_out_set_param_data(new_out, param_id, payload); if (ret) ERROR_MSG("audio_extn_out_set_param_data error %d", ret); unlock_output_stream(new_out); } return ret; } int audio_extn_qaf_out_get_param_data(struct stream_out *out, audio_extn_param_id param_id, audio_extn_param_payload *payload) { int ret = -EINVAL, i; struct stream_out *new_out = NULL; struct qaf_module *qaf_mod = get_qaf_module_for_input_stream(out); if (!out || !qaf_mod || !payload) { ERROR_MSG("Invalid Param"); return ret; } if (!p_qaf->hdmi_connect) { ERROR_MSG("hdmi not connected"); return ret; } /* get session which is routed to hdmi*/ if (p_qaf->passthrough_out) new_out = p_qaf->passthrough_out; else { for (i = 0; i < MAX_QAF_MODULE_OUT; i++) { if (qaf_mod->stream_out[i]) { new_out = qaf_mod->stream_out[i]; break; } } } if (!new_out) { ERROR_MSG("No stream active."); return ret; } if (new_out->standby) new_out->stream.write((struct audio_stream_out *)new_out, NULL, 0); lock_output_stream(new_out); ret = audio_extn_out_get_param_data(new_out, param_id, payload); if (ret) ERROR_MSG("audio_extn_out_get_param_data error %d", ret); unlock_output_stream(new_out); return ret; } /* To open a stream with QAF. */ int audio_extn_qaf_open_output_stream(struct audio_hw_device *dev, audio_io_handle_t handle, audio_devices_t devices, audio_output_flags_t flags, struct audio_config *config, struct audio_stream_out **stream_out, const char *address) { int ret = 0; struct stream_out *out; ret = adev_open_output_stream(dev, handle, devices, flags, config, stream_out, address); if (*stream_out == NULL) { ERROR_MSG("Stream open failed %d", ret); return ret; } #ifndef LINUX_ENABLED //Bypass QAF for dummy PCM session opened by APM during boot time if(flags == 0) { ALOGD("bypassing QAF for flags is equal to none"); return ret; } #endif out = (struct stream_out *)*stream_out; ret = qaf_stream_open(out, config, flags, devices); if (ret < 0) { ERROR_MSG("Error opening QAF stream err[%d]! QAF bypassed.", ret); //Stream not supported by QAF, Bypass QAF. return 0; } /* Override function pointers based on qaf definitions */ out->stream.set_volume = qaf_out_set_volume; out->stream.pause = qaf_out_pause; out->stream.resume = qaf_out_resume; out->stream.drain = qaf_out_drain; out->stream.flush = qaf_out_flush; out->stream.common.standby = qaf_out_standby; out->stream.common.set_parameters = qaf_out_set_parameters; out->stream.get_latency = qaf_out_get_latency; out->stream.get_render_position = qaf_out_get_render_position; out->stream.write = qaf_out_write; out->stream.get_presentation_position = qaf_out_get_presentation_position; out->platform_latency = 0; /*TODO: Need to handle this for DTS*/ if (out->usecase == USECASE_AUDIO_PLAYBACK_LOW_LATENCY) { out->usecase = USECASE_AUDIO_PLAYBACK_DEEP_BUFFER; out->config.period_size = QAF_DEEP_BUFFER_OUTPUT_PERIOD_SIZE; out->config.period_count = DEEP_BUFFER_OUTPUT_PERIOD_COUNT; out->config.start_threshold = QAF_DEEP_BUFFER_OUTPUT_PERIOD_SIZE / 4; out->config.avail_min = QAF_DEEP_BUFFER_OUTPUT_PERIOD_SIZE / 4; } else if(out->flags == AUDIO_OUTPUT_FLAG_DIRECT) { out->compr_config.fragment_size = qaf_get_pcm_offload_input_buffer_size(&(config->offload_info)); } *stream_out = &out->stream; if (out->flags & AUDIO_OUTPUT_FLAG_COMPRESS_OFFLOAD) { qaf_create_offload_callback_thread(out); } DEBUG_MSG("Exit"); return 0; } /* Close a QAF stream. */ void audio_extn_qaf_close_output_stream(struct audio_hw_device *dev, struct audio_stream_out *stream) { struct stream_out *out = (struct stream_out *)stream; struct qaf_module* qaf_mod = get_qaf_module_for_input_stream(out); if (!qaf_mod) { DEBUG_MSG("qaf module is NULL, bypassing qaf on close output stream"); /*closing non-MS12/default output stream opened with qaf */ adev_close_output_stream(dev, stream); return; } DEBUG_MSG("stream_handle(%p) format = %x", out, out->format); //If close is received for QAF passthrough stream then close the QAF passthrough output. if (p_qaf->passthrough_in == out) { if (p_qaf->passthrough_out) { ALOGD("%s %d closing stream handle %p", __func__, __LINE__, p_qaf->passthrough_out); pthread_mutex_lock(&p_qaf->lock); adev_close_output_stream((struct audio_hw_device *)p_qaf->adev, (struct audio_stream_out *)(p_qaf->passthrough_out)); pthread_mutex_unlock(&p_qaf->lock); p_qaf->passthrough_out = NULL; } p_qaf->passthrough_in = NULL; } if (out->flags & AUDIO_OUTPUT_FLAG_COMPRESS_OFFLOAD) { qaf_destroy_offload_callback_thread(out); } qaf_stream_close(out); adev_close_output_stream(dev, stream); DEBUG_MSG("Exit"); } /* Check if QAF is supported or not. */ bool audio_extn_qaf_is_enabled() { bool prop_enabled = false; char value[PROPERTY_VALUE_MAX] = {0}; property_get("vendor.audio.qaf.enabled", value, NULL); prop_enabled = atoi(value) || !strncmp("true", value, 4); return (prop_enabled); } void set_bt_configuration_to_module() { if (!p_qaf) { return; } if (!p_qaf->bt_connect) { DEBUG_MSG("BT is not connected."); return; } struct str_parms *qaf_params; char *format_params = NULL; qaf_params = str_parms_create(); if (qaf_params) { //ms12 wrapper don't support bt, treat this as speaker and routign to bt //will take care as a part of data callback notifier str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_DEVICE, AUDIO_QAF_PARAMETER_VALUE_DEVICE_SPEAKER); str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_RENDER_FORMAT, AUDIO_QAF_PARAMETER_VALUE_PCM); format_params = str_parms_to_str(qaf_params); if (p_qaf->qaf_mod[MS12].session_handle && p_qaf->qaf_mod[MS12].qaf_audio_session_set_param) { ALOGE(" Configuring BT/speaker for MS12 wrapper"); p_qaf->qaf_mod[MS12].qaf_audio_session_set_param(p_qaf->qaf_mod[MS12].session_handle, format_params); } if (p_qaf->qaf_mod[DTS_M8].session_handle && p_qaf->qaf_mod[DTS_M8].qaf_audio_session_set_param) { ALOGE(" Configuring BT/speaker for MS12 wrapper"); p_qaf->qaf_mod[DTS_M8].qaf_audio_session_set_param(p_qaf->qaf_mod[DTS_M8].session_handle, format_params); } } str_parms_destroy(qaf_params); } /* Query HDMI EDID and sets module output accordingly.*/ void set_hdmi_configuration_to_module() { int channels = 0; char *format_params; struct str_parms *qaf_params; char prop_value[PROPERTY_VALUE_MAX]; bool passth_support = false; DEBUG_MSG("Entry"); if (!p_qaf) { return; } if (!p_qaf->hdmi_connect) { DEBUG_MSG("HDMI is not connected."); return; } p_qaf->hdmi_sink_channels = 0; //QAF re-encoding and DSP offload passthrough is supported. if (property_get_bool("vendor.audio.offload.passthrough", false) && property_get_bool("vendor.audio.qaf.reencode", false)) { //If MS12 session is active. if (p_qaf->qaf_mod[MS12].session_handle && p_qaf->qaf_mod[MS12].qaf_audio_session_set_param) { bool do_setparam = false; qaf_params = str_parms_create(); property_get("vendor.audio.qaf.hdmi.out", prop_value, NULL); if (platform_is_edid_supported_format(p_qaf->adev->platform, AUDIO_FORMAT_E_AC3) && (strncmp(prop_value, "ddp", 3) == 0)) { do_setparam = true; if (qaf_params) { str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_RENDER_FORMAT, AUDIO_QAF_PARAMETER_VALUE_REENCODE_EAC3); } } else if (platform_is_edid_supported_format(p_qaf->adev->platform, AUDIO_FORMAT_AC3)) { do_setparam = true; if (qaf_params) { str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_RENDER_FORMAT, AUDIO_QAF_PARAMETER_VALUE_REENCODE_AC3); } } if (do_setparam) { if (p_qaf->qaf_msmd_enabled) { str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_DEVICE, AUDIO_QAF_PARAMETER_VALUE_DEVICE_HDMI_AND_SPK); //TODO: Need enhancement. } else { str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_DEVICE, AUDIO_QAF_PARAMETER_VALUE_DEVICE_HDMI); } format_params = str_parms_to_str(qaf_params); p_qaf->qaf_mod[MS12].qaf_audio_session_set_param(p_qaf->qaf_mod[MS12].session_handle, format_params); passth_support = true; } str_parms_destroy(qaf_params); } //DTS_M8 session is active. if (p_qaf->qaf_mod[DTS_M8].session_handle && p_qaf->qaf_mod[DTS_M8].qaf_audio_session_set_param) { bool do_setparam = false; qaf_params = str_parms_create(); if (platform_is_edid_supported_format(p_qaf->adev->platform, AUDIO_FORMAT_DTS)) { do_setparam = true; if (qaf_params) { str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_RENDER_FORMAT, AUDIO_QAF_PARAMETER_VALUE_REENCODE_DTS); } } if (do_setparam) { if (p_qaf->qaf_msmd_enabled) { str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_DEVICE, AUDIO_QAF_PARAMETER_VALUE_DEVICE_HDMI_AND_SPK); //TODO: Need enhancement. } else { str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_DEVICE, AUDIO_QAF_PARAMETER_VALUE_DEVICE_HDMI); } format_params = str_parms_to_str(qaf_params); p_qaf->qaf_mod[DTS_M8].qaf_audio_session_set_param(p_qaf->qaf_mod[DTS_M8].session_handle, format_params); passth_support = true; } str_parms_destroy(qaf_params); } } //Compressed passthrough is not enabled. if (!passth_support) { channels = platform_edid_get_max_channels(p_qaf->adev->platform); qaf_params = str_parms_create(); str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_RENDER_FORMAT, AUDIO_QAF_PARAMETER_VALUE_PCM); switch (channels) { case 8: DEBUG_MSG("Switching Qaf output to 7.1 channels"); str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_CHANNELS, AUDIO_QAF_PARAMETER_VALUE_8_CHANNELS); if (p_qaf->qaf_msmd_enabled) { str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_DEVICE, AUDIO_QAF_PARAMETER_VALUE_DEVICE_HDMI_AND_SPK); } else { str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_DEVICE, AUDIO_QAF_PARAMETER_VALUE_DEVICE_HDMI); } p_qaf->hdmi_sink_channels = channels; break; case 6: DEBUG_MSG("Switching Qaf output to 5.1 channels"); str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_CHANNELS, AUDIO_QAF_PARAMETER_VALUE_6_CHANNELS); if (p_qaf->qaf_msmd_enabled) { str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_DEVICE, AUDIO_QAF_PARAMETER_VALUE_DEVICE_HDMI_AND_SPK); } else { str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_DEVICE, AUDIO_QAF_PARAMETER_VALUE_DEVICE_HDMI); } p_qaf->hdmi_sink_channels = channels; break; default: DEBUG_MSG("Switching Qaf output to default channels"); str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_CHANNELS, AUDIO_QAF_PARAMETER_VALUE_DEFAULT_CHANNELS); if (p_qaf->qaf_msmd_enabled) { str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_DEVICE, AUDIO_QAF_PARAMETER_VALUE_DEVICE_HDMI_AND_SPK); } else { str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_DEVICE, AUDIO_QAF_PARAMETER_VALUE_DEVICE_SPEAKER); } p_qaf->hdmi_sink_channels = 2; break; } format_params = str_parms_to_str(qaf_params); if (p_qaf->qaf_mod[MS12].session_handle && p_qaf->qaf_mod[MS12].qaf_audio_session_set_param) { p_qaf->qaf_mod[MS12].qaf_audio_session_set_param(p_qaf->qaf_mod[MS12].session_handle, format_params); } if (p_qaf->qaf_mod[DTS_M8].session_handle && p_qaf->qaf_mod[DTS_M8].qaf_audio_session_set_param) { p_qaf->qaf_mod[DTS_M8].qaf_audio_session_set_param(p_qaf->qaf_mod[DTS_M8].session_handle, format_params); } str_parms_destroy(qaf_params); } DEBUG_MSG("Exit"); } /* QAF set parameter function. For Device connect and disconnect. */ int audio_extn_qaf_set_parameters(struct audio_device *adev, struct str_parms *parms) { int status = 0, val = 0, k; char *format_params, *kv_parirs; struct str_parms *qaf_params; DEBUG_MSG("Entry"); if (!p_qaf) { return -EINVAL; } status = str_parms_get_int(parms, AUDIO_PARAMETER_DEVICE_CONNECT, &val); if ((status >= 0) && audio_is_output_device(val)) { if (val & AUDIO_DEVICE_OUT_AUX_DIGITAL) { //HDMI is connected. p_qaf->hdmi_connect = 1; p_qaf->hdmi_sink_channels = 0; if (p_qaf->passthrough_in) { //If QAF passthrough is already initialized. lock_output_stream(p_qaf->passthrough_in); if (platform_is_edid_supported_format(adev->platform, p_qaf->passthrough_in->format)) { //If passthrough format is supported by HDMI then create the QAF passthrough output if not created already. create_qaf_passthrough_stream(); //Ignoring the returned error, If error then QAF passthrough is disabled. } else { //If passthrough format is not supported by HDMI then close the QAF passthrough output if already created. close_qaf_passthrough_stream(); } unlock_output_stream(p_qaf->passthrough_in); } set_hdmi_configuration_to_module(); } else if (val & AUDIO_DEVICE_OUT_BLUETOOTH_A2DP) { p_qaf->bt_connect = 1; set_bt_configuration_to_module(); #ifndef SPLIT_A2DP_ENABLED for (k = 0; k < MAX_MM_MODULE_TYPE; k++) { if (!p_qaf->qaf_mod[k].bt_hdl) { DEBUG_MSG("Opening a2dp output..."); status = audio_extn_bt_hal_load(&p_qaf->qaf_mod[k].bt_hdl); if (status != 0) { ERROR_MSG("Error opening BT module"); return status; } } } #endif } //TODO else if: Need to consider other devices. } status = str_parms_get_int(parms, AUDIO_PARAMETER_DEVICE_DISCONNECT, &val); if ((status >= 0) && audio_is_output_device(val)) { if (val & AUDIO_DEVICE_OUT_AUX_DIGITAL) { //HDMI is disconnected. qaf_params = str_parms_create(); str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_DEVICE, AUDIO_QAF_PARAMETER_VALUE_DEVICE_SPEAKER); str_parms_add_str(qaf_params, AUDIO_QAF_PARAMETER_KEY_RENDER_FORMAT, AUDIO_QAF_PARAMETER_VALUE_PCM); p_qaf->hdmi_sink_channels = 0; p_qaf->passthrough_enabled = 0; p_qaf->mch_pcm_hdmi_enabled = 0; p_qaf->hdmi_connect = 0; format_params = str_parms_to_str(qaf_params); for (k = 0; k < MAX_MM_MODULE_TYPE; k++) { if (p_qaf->qaf_mod[k].session_handle && p_qaf->qaf_mod[k].qaf_audio_session_set_param) { p_qaf->qaf_mod[k].qaf_audio_session_set_param( p_qaf->qaf_mod[k].session_handle, format_params); } } close_all_hdmi_output(); str_parms_destroy(qaf_params); close_qaf_passthrough_stream(); } else if (val & AUDIO_DEVICE_OUT_BLUETOOTH_A2DP) { p_qaf->bt_connect = 0; //reconfig HDMI as end device (if connected) if(p_qaf->hdmi_connect) set_hdmi_configuration_to_module(); #ifndef SPLIT_A2DP_ENABLED DEBUG_MSG("Closing a2dp output..."); for (k = 0; k < MAX_MM_MODULE_TYPE; k++) { if (p_qaf->qaf_mod[k].bt_hdl) { audio_extn_bt_hal_unload(p_qaf->qaf_mod[k].bt_hdl); p_qaf->qaf_mod[k].bt_hdl = NULL; } } #endif } //TODO else if: Need to consider other devices. } for (k = 0; k < MAX_MM_MODULE_TYPE; k++) { kv_parirs = str_parms_to_str(parms); if (p_qaf->qaf_mod[k].session_handle && p_qaf->qaf_mod[k].qaf_audio_session_set_param) { p_qaf->qaf_mod[k].qaf_audio_session_set_param( p_qaf->qaf_mod[k].session_handle, kv_parirs); } } DEBUG_MSG("Exit"); return status; } /* Create the QAF. */ int audio_extn_qaf_init(struct audio_device *adev) { DEBUG_MSG("Entry"); p_qaf = calloc(1, sizeof(struct qaf)); if (p_qaf == NULL) { ERROR_MSG("Out of memory"); return -ENOMEM; } p_qaf->adev = adev; if (property_get_bool("vendor.audio.qaf.msmd", false)) { p_qaf->qaf_msmd_enabled = 1; } pthread_mutex_init(&p_qaf->lock, (const pthread_mutexattr_t *) NULL); int i = 0; for (i = 0; i < MAX_MM_MODULE_TYPE; i++) { char value[PROPERTY_VALUE_MAX] = {0}; char lib_name[PROPERTY_VALUE_MAX] = {0}; struct qaf_module *qaf_mod = &(p_qaf->qaf_mod[i]); if (i == MS12) { property_get("vendor.audio.qaf.library", value, NULL); snprintf(lib_name, PROPERTY_VALUE_MAX, "%s", value); #ifdef AUDIO_EXTN_IP_HDLR_ENABLED { int ret = 0; ret = audio_extn_ip_hdlr_intf_init(&qaf_mod->ip_hdlr_hdl, lib_name, &qaf_mod->qaf_lib, adev, USECASE_AUDIO_PLAYBACK_OFFLOAD); if (ret < 0) { ERROR_MSG("audio_extn_ip_hdlr_intf_init failed, ret = %d", ret); continue; } if (qaf_mod->qaf_lib == NULL) { ERROR_MSG("failed to get library handle"); continue; } } #else qaf_mod->qaf_lib = dlopen(lib_name, RTLD_NOW); if (qaf_mod->qaf_lib == NULL) { ERROR_MSG("DLOPEN failed for %s", lib_name); continue; } DEBUG_MSG("DLOPEN successful for %s", lib_name); #endif } else if (i == DTS_M8) { property_get("vendor.audio.qaf.m8.library", value, NULL); snprintf(lib_name, PROPERTY_VALUE_MAX, "%s", value); qaf_mod->qaf_lib = dlopen(lib_name, RTLD_NOW); if (qaf_mod->qaf_lib == NULL) { ERROR_MSG("DLOPEN failed for %s", lib_name); continue; } DEBUG_MSG("DLOPEN successful for %s", lib_name); } else { continue; } qaf_mod->qaf_audio_session_open = (int (*)(audio_session_handle_t* session_handle, audio_session_type_t s_type, void *p_data, void* license_data))dlsym(qaf_mod->qaf_lib, "audio_session_open"); qaf_mod->qaf_audio_session_close = (int (*)(audio_session_handle_t session_handle))dlsym(qaf_mod->qaf_lib, "audio_session_close"); qaf_mod->qaf_audio_stream_open = (int (*)(audio_session_handle_t session_handle, audio_stream_handle_t* stream_handle, audio_stream_config_t input_config, audio_devices_t devices, stream_type_t flags))dlsym(qaf_mod->qaf_lib, "audio_stream_open"); qaf_mod->qaf_audio_stream_close = (int (*)(audio_stream_handle_t stream_handle))dlsym(qaf_mod->qaf_lib, "audio_stream_close"); qaf_mod->qaf_audio_stream_set_param = (int (*)(audio_stream_handle_t stream_handle, const char* kv_pairs))dlsym(qaf_mod->qaf_lib, "audio_stream_set_param"); qaf_mod->qaf_audio_session_set_param = (int (*)(audio_session_handle_t handle, const char* kv_pairs))dlsym(qaf_mod->qaf_lib, "audio_session_set_param"); qaf_mod->qaf_audio_stream_get_param = (char* (*)(audio_stream_handle_t stream_handle, const char* key))dlsym(qaf_mod->qaf_lib, "audio_stream_get_param"); qaf_mod->qaf_audio_session_get_param = (char* (*)(audio_session_handle_t handle, const char* key))dlsym(qaf_mod->qaf_lib, "audio_session_get_param"); qaf_mod->qaf_audio_stream_start = (int (*)(audio_stream_handle_t stream_handle))dlsym(qaf_mod->qaf_lib, "audio_stream_start"); qaf_mod->qaf_audio_stream_stop = (int (*)(audio_stream_handle_t stream_handle))dlsym(qaf_mod->qaf_lib, "audio_stream_stop"); qaf_mod->qaf_audio_stream_pause = (int (*)(audio_stream_handle_t stream_handle))dlsym(qaf_mod->qaf_lib, "audio_stream_pause"); qaf_mod->qaf_audio_stream_flush = (int (*)(audio_stream_handle_t stream_handle))dlsym(qaf_mod->qaf_lib, "audio_stream_flush"); qaf_mod->qaf_audio_stream_write = (int (*)(audio_stream_handle_t stream_handle, const void* buf, int size))dlsym(qaf_mod->qaf_lib, "audio_stream_write"); qaf_mod->qaf_register_event_callback = (void (*)(audio_session_handle_t session_handle, void *priv_data, notify_event_callback_t event_callback, audio_event_id_t event_id))dlsym(qaf_mod->qaf_lib, "register_event_callback"); } DEBUG_MSG("Exit"); return 0; } /* Tear down the qaf extension. */ void audio_extn_qaf_deinit() { int i; DEBUG_MSG("Entry"); if (p_qaf != NULL) { for (i = 0; i < MAX_MM_MODULE_TYPE; i++) { qaf_session_close(&p_qaf->qaf_mod[i]); if (p_qaf->qaf_mod[i].qaf_lib != NULL) { if (i == MS12) { #ifdef AUDIO_EXTN_IP_HDLR_ENABLED audio_extn_ip_hdlr_intf_deinit(p_qaf->qaf_mod[i].ip_hdlr_hdl); #else dlclose(p_qaf->qaf_mod[i].qaf_lib); #endif p_qaf->qaf_mod[i].qaf_lib = NULL; } else { dlclose(p_qaf->qaf_mod[i].qaf_lib); p_qaf->qaf_mod[i].qaf_lib = NULL; } } } if (p_qaf->passthrough_out) { adev_close_output_stream((struct audio_hw_device *)p_qaf->adev, (struct audio_stream_out *)(p_qaf->passthrough_out)); p_qaf->passthrough_out = NULL; } pthread_mutex_destroy(&p_qaf->lock); free(p_qaf); p_qaf = NULL; } DEBUG_MSG("Exit"); }