audio/audio_aec.c - device/linaro/dragonboard - Git at Google

 /*
  * Copyright (C) 2019 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 // clang-format off
 /*
  * Typical AEC signal flow:
  *
  *                          Microphone Audio
  *                          Timestamps
  *                        +--------------------------------------+
  *                        |                                      |       +---------------+
  *                        |    Microphone +---------------+      |       |               |
  *             O|======   |    Audio      | Sample Rate   |      +------->               |
  *    (from         .  +--+    Samples    | +             |              |               |
  *     mic          .  +==================> Format        |==============>               |
  *     codec)       .                     | Conversion    |              |               |   Cleaned
  *             O|======                   | (if required) |              |   Acoustic    |   Audio
  *                                        +---------------+              |   Echo        |   Samples
  *                                                                       |   Canceller   |===================>
  *                                                                       |   (AEC)       |
  *                            Reference   +---------------+              |               |
  *                            Audio       | Sample Rate   |              |               |
  *                            Samples     | +             |              |               |
  *                          +=============> Format        |==============>               |
  *                          |             | Conversion    |              |               |
  *                          |             | (if required) |      +------->               |
  *                          |             +---------------+      |       |               |
  *                          |                                    |       +---------------+
  *                          |    +-------------------------------+
  *                          |    |  Reference Audio
  *                          |    |  Timestamps
  *                          |    |
  *                       +--+----+---------+                                                       AUDIO CAPTURE
  *                       | Speaker         |
  *          +------------+ Audio/Timestamp +---------------------------------------------------------------------------+
  *                       | Buffer          |
  *                       +--^----^---------+                                                       AUDIO PLAYBACK
  *                          |    |
  *                          |    |
  *                          |    |
  *                          |    |
  *                |\        |    |
  *                | +-+     |    |
  *      (to       | | +-----C----+
  *       speaker  | | |     |                                                                  Playback
  *       codec)   | | <=====+================================================================+ Audio
  *                | +-+                                                                        Samples
  *                |/
  *
  */
 // clang-format on

 #define LOG_TAG "audio_hw_aec"
 // #define LOG_NDEBUG 0

 #include <audio_utils/primitives.h>
 #include <stdio.h>
 #include <inttypes.h>
 #include <errno.h>
 #include <malloc.h>
 #include <sys/time.h>
 #include <tinyalsa/asoundlib.h>
 #include <unistd.h>
 #include <log/log.h>
 #include "audio_aec.h"

 #ifdef AEC_HAL
 #include "audio_aec_process.h"
 #else
 #define aec_spk_mic_init(...) ((int)0)
 #define aec_spk_mic_reset(...) ((void)0)
 #define aec_spk_mic_process(...) ((int32_t)0)
 #define aec_spk_mic_release(...) ((void)0)
 #endif

 #define MAX_TIMESTAMP_DIFF_USEC 200000

 #define MAX_READ_WAIT_TIME_MSEC 80

 uint64_t timespec_to_usec(struct timespec ts) {
     return (ts.tv_sec * 1e6L + ts.tv_nsec/1000);
 }

 void get_reference_audio_in_place(struct aec_t *aec, size_t frames) {
     if (aec->num_reference_channels == aec->spk_num_channels) {
         /* Reference count equals speaker channels, nothing to do here. */
         return;
     } else if (aec->num_reference_channels != 1) {
         /* We don't have  a rule for non-mono references, show error on log */
         ALOGE("Invalid reference count - must be 1 or match number of playback channels!");
         return;
     }
     int16_t *src_Nch = &aec->spk_buf_playback_format[0];
     int16_t *dst_1ch = &aec->spk_buf_playback_format[0];
     int32_t num_channels = (int32_t)aec->spk_num_channels;
     size_t frame, ch;
     for (frame = 0; frame < frames; frame++) {
         int32_t acc = 0;
         for (ch = 0; ch < aec->spk_num_channels; ch++) {
             acc += src_Nch[ch];
         }
         *dst_1ch++ = clamp16(acc/num_channels);
         src_Nch += aec->spk_num_channels;
     }
 }

 void print_queue_status_to_log(struct aec_t *aec, bool write_side) {
     ssize_t q1 = fifo_available_to_read(aec->spk_fifo);
     ssize_t q2 = fifo_available_to_read(aec->ts_fifo);

     ALOGV("Queue available %s: Spk %zd (count %zd) TS %zd (count %zd)",
         (write_side) ? "(POST-WRITE)" : "(PRE-READ)",
         q1, q1/aec->spk_frame_size_bytes/PLAYBACK_PERIOD_SIZE,
         q2, q2/sizeof(struct aec_info));
 }

 void flush_aec_fifos(struct aec_t *aec) {
     if (aec == NULL) {
         return;
     }
     if (aec->spk_fifo != NULL) {
         ALOGV("Flushing AEC Spk FIFO...");
         fifo_flush(aec->spk_fifo);
     }
     if (aec->ts_fifo != NULL) {
         ALOGV("Flushing AEC Timestamp FIFO...");
         fifo_flush(aec->ts_fifo);
     }
     /* Reset FIFO read-write offset tracker */
     aec->read_write_diff_bytes = 0;
 }

 void aec_set_spk_running_no_lock(struct aec_t* aec, bool state) {
     aec->spk_running = state;
 }

 bool aec_get_spk_running_no_lock(struct aec_t* aec) {
     return aec->spk_running;
 }

 void destroy_aec_reference_config_no_lock(struct aec_t* aec) {
     if (!aec->spk_initialized) {
         return;
     }
     aec_set_spk_running_no_lock(aec, false);
     fifo_release(aec->spk_fifo);
     fifo_release(aec->ts_fifo);
     memset(&aec->last_spk_info, 0, sizeof(struct aec_info));
     aec->spk_initialized = false;
 }

 void destroy_aec_mic_config_no_lock(struct aec_t* aec) {
     if (!aec->mic_initialized) {
         return;
     }
     release_resampler(aec->spk_resampler);
     free(aec->mic_buf);
     free(aec->spk_buf);
     free(aec->spk_buf_playback_format);
     free(aec->spk_buf_resampler_out);
     memset(&aec->last_mic_info, 0, sizeof(struct aec_info));
     aec->mic_initialized = false;
 }

 struct aec_t *init_aec_interface() {
     ALOGV("%s enter", __func__);
     struct aec_t *aec = (struct aec_t *)calloc(1, sizeof(struct aec_t));
     if (aec == NULL) {
         ALOGE("Failed to allocate memory for AEC interface!");
     } else {
         pthread_mutex_init(&aec->lock, NULL);
     }

     ALOGV("%s exit", __func__);
     return aec;
 }

 void release_aec_interface(struct aec_t *aec) {
     ALOGV("%s enter", __func__);
     pthread_mutex_lock(&aec->lock);
     destroy_aec_mic_config_no_lock(aec);
     destroy_aec_reference_config_no_lock(aec);
     pthread_mutex_unlock(&aec->lock);
     free(aec);
     ALOGV("%s exit", __func__);
 }

 int init_aec(int sampling_rate, int num_reference_channels,
                 int num_microphone_channels, struct aec_t **aec_ptr) {
     ALOGV("%s enter", __func__);
     int ret = 0;
     int aec_ret = aec_spk_mic_init(
                     sampling_rate,
                     num_reference_channels,
                     num_microphone_channels);
     if (aec_ret) {
         ALOGE("AEC object failed to initialize!");
         ret = -EINVAL;
     }
     struct aec_t *aec = init_aec_interface();
     if (!ret) {
         aec->num_reference_channels = num_reference_channels;
         /* Set defaults, will be overridden by settings in init_aec_(mic|referece_config) */
         /* Capture uses 2-ch, 32-bit frames */
         aec->mic_sampling_rate = CAPTURE_CODEC_SAMPLING_RATE;
         aec->mic_frame_size_bytes = CHANNEL_STEREO * sizeof(int32_t);
         aec->mic_num_channels = CHANNEL_STEREO;

         /* Playback uses 2-ch, 16-bit frames */
         aec->spk_sampling_rate = PLAYBACK_CODEC_SAMPLING_RATE;
         aec->spk_frame_size_bytes = CHANNEL_STEREO * sizeof(int16_t);
         aec->spk_num_channels = CHANNEL_STEREO;
     }

     (*aec_ptr) = aec;
     ALOGV("%s exit", __func__);
     return ret;
 }

 void release_aec(struct aec_t *aec) {
     ALOGV("%s enter", __func__);
     if (aec == NULL) {
         return;
     }
     release_aec_interface(aec);
     aec_spk_mic_release();
     ALOGV("%s exit", __func__);
 }

 int init_aec_reference_config(struct aec_t *aec, struct alsa_stream_out *out) {
     ALOGV("%s enter", __func__);
     if (!aec) {
         ALOGE("AEC: No valid interface found!");
         return -EINVAL;
     }

     int ret = 0;
     pthread_mutex_lock(&aec->lock);
     if (aec->spk_initialized) {
         destroy_aec_reference_config_no_lock(aec);
     }

     aec->spk_fifo = fifo_init(
             out->config.period_count * out->config.period_size *
                 audio_stream_out_frame_size(&out->stream),
             false /* reader_throttles_writer */);
     if (aec->spk_fifo == NULL) {
         ALOGE("AEC: Speaker loopback FIFO Init failed!");
         ret = -EINVAL;
         goto exit;
     }
     aec->ts_fifo = fifo_init(
             out->config.period_count * sizeof(struct aec_info),
             false /* reader_throttles_writer */);
     if (aec->ts_fifo == NULL) {
         ALOGE("AEC: Speaker timestamp FIFO Init failed!");
         ret = -EINVAL;
         fifo_release(aec->spk_fifo);
         goto exit;
     }

     aec->spk_sampling_rate = out->config.rate;
     aec->spk_frame_size_bytes = audio_stream_out_frame_size(&out->stream);
     aec->spk_num_channels = out->config.channels;
     aec->spk_initialized = true;
 exit:
     pthread_mutex_unlock(&aec->lock);
     ALOGV("%s exit", __func__);
     return ret;
 }

 void destroy_aec_reference_config(struct aec_t* aec) {
     ALOGV("%s enter", __func__);
     if (aec == NULL) {
         ALOGV("%s exit", __func__);
         return;
     }
     pthread_mutex_lock(&aec->lock);
     destroy_aec_reference_config_no_lock(aec);
     pthread_mutex_unlock(&aec->lock);
     ALOGV("%s exit", __func__);
 }

 int write_to_reference_fifo(struct aec_t* aec, void* buffer, struct aec_info* info) {
     ALOGV("%s enter", __func__);
     int ret = 0;
     size_t bytes = info->bytes;

     /* Write audio samples to FIFO */
     ssize_t written_bytes = fifo_write(aec->spk_fifo, buffer, bytes);
     if (written_bytes != bytes) {
         ALOGE("Could only write %zu of %zu bytes", written_bytes, bytes);
         ret = -ENOMEM;
     }

     /* Write timestamp to FIFO */
     info->bytes = written_bytes;
     ALOGV("Speaker timestamp: %ld s, %ld nsec", info->timestamp.tv_sec, info->timestamp.tv_nsec);
     ssize_t ts_bytes = fifo_write(aec->ts_fifo, info, sizeof(struct aec_info));
     ALOGV("Wrote TS bytes: %zu", ts_bytes);
     print_queue_status_to_log(aec, true);
     ALOGV("%s exit", __func__);
     return ret;
 }

 void get_spk_timestamp(struct aec_t* aec, ssize_t read_bytes, uint64_t* spk_time) {
     *spk_time = 0;
     uint64_t spk_time_offset = 0;
     float usec_per_byte = 1E6 / ((float)(aec->spk_frame_size_bytes * aec->spk_sampling_rate));
     if (aec->read_write_diff_bytes < 0) {
         /* We're still reading a previous write packet. (We only need the first sample's timestamp,
          * so even if we straddle packets we only care about the first one)
          * So we just use the previous timestamp, with an appropriate offset
          * based on the number of bytes remaining to be read from that write packet. */
         spk_time_offset = (aec->last_spk_info.bytes + aec->read_write_diff_bytes) * usec_per_byte;
         ALOGV("Reusing previous timestamp, calculated offset (usec) %" PRIu64, spk_time_offset);
     } else {
         /* If read_write_diff_bytes > 0, there are no new writes, so there won't be timestamps in
          * the FIFO, and the check below will fail. */
         if (!fifo_available_to_read(aec->ts_fifo)) {
             ALOGE("Timestamp error: no new timestamps!");
             return;
         }
         /* We just read valid data, so if we're here, we should have a valid timestamp to use. */
         ssize_t ts_bytes = fifo_read(aec->ts_fifo, &aec->last_spk_info, sizeof(struct aec_info));
         ALOGV("Read TS bytes: %zd, expected %zu", ts_bytes, sizeof(struct aec_info));
         aec->read_write_diff_bytes -= aec->last_spk_info.bytes;
     }

     *spk_time = timespec_to_usec(aec->last_spk_info.timestamp) + spk_time_offset;

     aec->read_write_diff_bytes += read_bytes;
     struct aec_info spk_info = aec->last_spk_info;
     while (aec->read_write_diff_bytes > 0) {
         /* If read_write_diff_bytes > 0, it means that there are more write packet timestamps
          * in FIFO (since there we read more valid data the size of the current timestamp's
          * packet). Keep reading timestamps from FIFO to get to the most recent one. */
         if (!fifo_available_to_read(aec->ts_fifo)) {
             /* There are no more timestamps, we have the most recent one. */
             ALOGV("At the end of timestamp FIFO, breaking...");
             break;
         }
         fifo_read(aec->ts_fifo, &spk_info, sizeof(struct aec_info));
         ALOGV("Fast-forwarded timestamp by %zd bytes, remaining bytes: %zd,"
               " new timestamp (usec) %" PRIu64,
               spk_info.bytes, aec->read_write_diff_bytes, timespec_to_usec(spk_info.timestamp));
         aec->read_write_diff_bytes -= spk_info.bytes;
     }
     aec->last_spk_info = spk_info;
 }

 int get_reference_samples(struct aec_t* aec, void* buffer, struct aec_info* info) {
     ALOGV("%s enter", __func__);

     if (!aec->spk_initialized) {
         ALOGE("%s called with no reference initialized", __func__);
         return -EINVAL;
     }

     size_t bytes = info->bytes;
     const size_t frames = bytes / aec->mic_frame_size_bytes;
     const size_t sample_rate_ratio = aec->spk_sampling_rate / aec->mic_sampling_rate;

     /* Read audio samples from FIFO */
     const size_t req_bytes = frames * sample_rate_ratio * aec->spk_frame_size_bytes;
     ssize_t available_bytes = 0;
     unsigned int wait_count = MAX_READ_WAIT_TIME_MSEC;
     while (true) {
         available_bytes = fifo_available_to_read(aec->spk_fifo);
         if (available_bytes >= req_bytes) {
             break;
         } else if (available_bytes < 0) {
             ALOGE("fifo_read returned code %zu ", available_bytes);
             return -ENOMEM;
         }

         ALOGV("Sleeping, required bytes: %zu, available bytes: %zd", req_bytes, available_bytes);
         usleep(1000);
         if ((wait_count--) == 0) {
             ALOGE("Timed out waiting for read from reference FIFO");
             return -ETIMEDOUT;
         }
     }

     const size_t read_bytes = fifo_read(aec->spk_fifo, aec->spk_buf_playback_format, req_bytes);

     /* Get timestamp*/
     get_spk_timestamp(aec, read_bytes, &info->timestamp_usec);

     /* Get reference - could be mono, downmixed from multichannel.
      * Reference stored at spk_buf_playback_format */
     const size_t resampler_in_frames = frames * sample_rate_ratio;
     get_reference_audio_in_place(aec, resampler_in_frames);

     int16_t* resampler_out_buf;
     /* Resample to mic sampling rate (16-bit resampler) */
     if (aec->spk_resampler != NULL) {
         size_t in_frame_count = resampler_in_frames;
         size_t out_frame_count = frames;
         aec->spk_resampler->resample_from_input(aec->spk_resampler, aec->spk_buf_playback_format,
                                                 &in_frame_count, aec->spk_buf_resampler_out,
                                                 &out_frame_count);
         resampler_out_buf = aec->spk_buf_resampler_out;
     } else {
         if (sample_rate_ratio != 1) {
             ALOGE("Speaker sample rate %d, mic sample rate %d but no resampler defined!",
                   aec->spk_sampling_rate, aec->mic_sampling_rate);
         }
         resampler_out_buf = aec->spk_buf_playback_format;
     }

     /* Convert to 32 bit */
     int16_t* src16 = resampler_out_buf;
     int32_t* dst32 = buffer;
     size_t frame, ch;
     for (frame = 0; frame < frames; frame++) {
         for (ch = 0; ch < aec->num_reference_channels; ch++) {
             *dst32++ = ((int32_t)*src16++) << 16;
         }
     }

     info->bytes = bytes;

     ALOGV("%s exit", __func__);
     return 0;
 }

 int init_aec_mic_config(struct aec_t *aec, struct alsa_stream_in *in) {
     ALOGV("%s enter", __func__);
 #if DEBUG_AEC
     remove("/data/local/traces/aec_in.pcm");
     remove("/data/local/traces/aec_out.pcm");
     remove("/data/local/traces/aec_ref.pcm");
     remove("/data/local/traces/aec_timestamps.txt");
 #endif /* #if DEBUG_AEC */

     if (!aec) {
         ALOGE("AEC: No valid interface found!");
         return -EINVAL;
     }

     int ret = 0;
     pthread_mutex_lock(&aec->lock);
     if (aec->mic_initialized) {
         destroy_aec_mic_config_no_lock(aec);
     }
     aec->mic_sampling_rate = in->config.rate;
     aec->mic_frame_size_bytes = audio_stream_in_frame_size(&in->stream);
     aec->mic_num_channels = in->config.channels;

     aec->mic_buf_size_bytes = in->config.period_size * audio_stream_in_frame_size(&in->stream);
     aec->mic_buf = (int32_t *)malloc(aec->mic_buf_size_bytes);
     if (aec->mic_buf == NULL) {
         ret = -ENOMEM;
         goto exit;
     }
     memset(aec->mic_buf, 0, aec->mic_buf_size_bytes);
     /* Reference buffer is the same number of frames as mic,
      * only with a different number of channels in the frame. */
     aec->spk_buf_size_bytes = in->config.period_size * aec->spk_frame_size_bytes;
     aec->spk_buf = (int32_t *)malloc(aec->spk_buf_size_bytes);
     if (aec->spk_buf == NULL) {
         ret = -ENOMEM;
         goto exit_1;
     }
     memset(aec->spk_buf, 0, aec->spk_buf_size_bytes);

     /* Pre-resampler buffer */
     size_t spk_frame_out_format_bytes = aec->spk_sampling_rate / aec->mic_sampling_rate *
                                             aec->spk_buf_size_bytes;
     aec->spk_buf_playback_format = (int16_t *)malloc(spk_frame_out_format_bytes);
     if (aec->spk_buf_playback_format == NULL) {
         ret = -ENOMEM;
         goto exit_2;
     }
     /* Resampler is 16-bit */
     aec->spk_buf_resampler_out = (int16_t *)malloc(aec->spk_buf_size_bytes);
     if (aec->spk_buf_resampler_out == NULL) {
         ret = -ENOMEM;
         goto exit_3;
     }

     /* Don't use resampler if it's not required */
     if (in->config.rate == aec->spk_sampling_rate) {
         aec->spk_resampler = NULL;
     } else {
         int resampler_ret = create_resampler(
                 aec->spk_sampling_rate, in->config.rate, aec->num_reference_channels,
                 RESAMPLER_QUALITY_MAX - 1, /* MAX - 1 is the real max */
                 NULL,                      /* resampler_buffer_provider */
                 &aec->spk_resampler);
         if (resampler_ret) {
             ALOGE("AEC: Resampler initialization failed! Error code %d", resampler_ret);
             ret = resampler_ret;
             goto exit_4;
         }
     }

     flush_aec_fifos(aec);
     aec_spk_mic_reset();
     aec->mic_initialized = true;

 exit:
     pthread_mutex_unlock(&aec->lock);
     ALOGV("%s exit", __func__);
     return ret;

 exit_4:
     free(aec->spk_buf_resampler_out);
 exit_3:
     free(aec->spk_buf_playback_format);
 exit_2:
     free(aec->spk_buf);
 exit_1:
     free(aec->mic_buf);
     pthread_mutex_unlock(&aec->lock);
     ALOGV("%s exit", __func__);
     return ret;
 }

 void aec_set_spk_running(struct aec_t *aec, bool state) {
     ALOGV("%s enter", __func__);
     pthread_mutex_lock(&aec->lock);
     aec_set_spk_running_no_lock(aec, state);
     pthread_mutex_unlock(&aec->lock);
     ALOGV("%s exit", __func__);
 }

 bool aec_get_spk_running(struct aec_t *aec) {
     ALOGV("%s enter", __func__);
     pthread_mutex_lock(&aec->lock);
     bool state = aec_get_spk_running_no_lock(aec);
     pthread_mutex_unlock(&aec->lock);
     ALOGV("%s exit", __func__);
     return state;
 }

 void destroy_aec_mic_config(struct aec_t* aec) {
     ALOGV("%s enter", __func__);
     if (aec == NULL) {
         ALOGV("%s exit", __func__);
         return;
     }

     pthread_mutex_lock(&aec->lock);
     destroy_aec_mic_config_no_lock(aec);
     pthread_mutex_unlock(&aec->lock);
     ALOGV("%s exit", __func__);
 }

 #ifdef AEC_HAL
 int process_aec(struct aec_t *aec, void* buffer, struct aec_info *info) {
     ALOGV("%s enter", __func__);
     int ret = 0;

     if (aec == NULL) {
         ALOGE("AEC: Interface uninitialized! Cannot process.");
         return -EINVAL;
     }

     if ((!aec->mic_initialized) || (!aec->spk_initialized)) {
         ALOGE("%s called with initialization: mic: %d, spk: %d", __func__, aec->mic_initialized,
               aec->spk_initialized);
         return -EINVAL;
     }

     size_t bytes = info->bytes;

     size_t frame_size = aec->mic_frame_size_bytes;
     size_t in_frames = bytes / frame_size;

     /* Copy raw mic samples to AEC input buffer */
     memcpy(aec->mic_buf, buffer, bytes);

     uint64_t mic_time = timespec_to_usec(info->timestamp);
     uint64_t spk_time = 0;

     /*
      * Only run AEC if there is speaker playback.
      * The first time speaker state changes to running, flush FIFOs, so we're not stuck
      * processing stale reference input.
      */
     bool spk_running = aec_get_spk_running(aec);

     if (!spk_running) {
         /* No new playback samples, so don't run AEC.
          * 'buffer' already contains input samples. */
         ALOGV("Speaker not running, skipping AEC..");
         goto exit;
     }

     if (!aec->prev_spk_running) {
         flush_aec_fifos(aec);
     }

     /* If there's no data in FIFO, exit */
     if (fifo_available_to_read(aec->spk_fifo) <= 0) {
         ALOGV("Echo reference buffer empty, zeroing reference....");
         goto exit;
     }

     print_queue_status_to_log(aec, false);

     /* Get reference, with format and sample rate required by AEC */
     struct aec_info spk_info;
     spk_info.bytes = bytes;
     int ref_ret = get_reference_samples(aec, aec->spk_buf, &spk_info);
     spk_time = spk_info.timestamp_usec;

     if (ref_ret) {
         ALOGE("get_reference_samples returned code %d", ref_ret);
         ret = -ENOMEM;
         goto exit;
     }

     int64_t time_diff = (mic_time > spk_time) ? (mic_time - spk_time) : (spk_time - mic_time);
     if ((spk_time == 0) || (mic_time == 0) || (time_diff > MAX_TIMESTAMP_DIFF_USEC)) {
         ALOGV("Speaker-mic timestamps diverged, skipping AEC");
         flush_aec_fifos(aec);
         aec_spk_mic_reset();
         goto exit;
     }

     ALOGV("Mic time: %"PRIu64", spk time: %"PRIu64, mic_time, spk_time);

     /*
      * AEC processing call - output stored at 'buffer'
      */
     int32_t aec_status = aec_spk_mic_process(
         aec->spk_buf, spk_time,
         aec->mic_buf, mic_time,
         in_frames,
         buffer);

     if (!aec_status) {
         ALOGE("AEC processing failed!");
         ret = -EINVAL;
     }

 exit:
     aec->prev_spk_running = spk_running;
     ALOGV("Mic time: %"PRIu64", spk time: %"PRIu64, mic_time, spk_time);
     if (ret) {
         /* Best we can do is copy over the raw mic signal */
         memcpy(buffer, aec->mic_buf, bytes);
         flush_aec_fifos(aec);
         aec_spk_mic_reset();
     }

 #if DEBUG_AEC
     /* ref data is 32-bit at this point */
     size_t ref_bytes = in_frames*aec->num_reference_channels*sizeof(int32_t);

     FILE *fp_in = fopen("/data/local/traces/aec_in.pcm", "a+");
     if (fp_in) {
         fwrite((char *)aec->mic_buf, 1, bytes, fp_in);
         fclose(fp_in);
     } else {
         ALOGE("AEC debug: Could not open file aec_in.pcm!");
     }
     FILE *fp_out = fopen("/data/local/traces/aec_out.pcm", "a+");
     if (fp_out) {
         fwrite((char *)buffer, 1, bytes, fp_out);
         fclose(fp_out);
     } else {
         ALOGE("AEC debug: Could not open file aec_out.pcm!");
     }
     FILE *fp_ref = fopen("/data/local/traces/aec_ref.pcm", "a+");
     if (fp_ref) {
         fwrite((char *)aec->spk_buf, 1, ref_bytes, fp_ref);
         fclose(fp_ref);
     } else {
         ALOGE("AEC debug: Could not open file aec_ref.pcm!");
     }
     FILE *fp_ts = fopen("/data/local/traces/aec_timestamps.txt", "a+");
     if (fp_ts) {
         fprintf(fp_ts, "%"PRIu64",%"PRIu64"\n", mic_time, spk_time);
         fclose(fp_ts);
     } else {
         ALOGE("AEC debug: Could not open file aec_timestamps.txt!");
     }
 #endif /* #if DEBUG_AEC */
     ALOGV("%s exit", __func__);
     return ret;
 }

 #endif /*#ifdef AEC_HAL*/
	/*
	* Copyright (C) 2019 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	// clang-format off
	/*
	* Typical AEC signal flow:
	*
	* Microphone Audio
	* Timestamps
	* +--------------------------------------+
	* \| \| +---------------+
	* \| Microphone +---------------+ \| \| \|
	* O\|====== \| Audio \| Sample Rate \| +-------> \|
	* (from . +--+ Samples \| + \| \| \|
	* mic . +==================> Format \|==============> \|
	* codec) . \| Conversion \| \| \| Cleaned
	* O\|====== \| (if required) \| \| Acoustic \| Audio
	* +---------------+ \| Echo \| Samples
	* \| Canceller \|===================>
	* \| (AEC) \|
	* Reference +---------------+ \| \|
	* Audio \| Sample Rate \| \| \|
	* Samples \| + \| \| \|
	* +=============> Format \|==============> \|
	* \| \| Conversion \| \| \|
	* \| \| (if required) \| +-------> \|
	* \| +---------------+ \| \| \|
	* \| \| +---------------+
	* \| +-------------------------------+
	* \| \| Reference Audio
	* \| \| Timestamps
	* \| \|
	* +--+----+---------+ AUDIO CAPTURE
	* \| Speaker \|
	* +------------+ Audio/Timestamp +---------------------------------------------------------------------------+
	* \| Buffer \|
	* +--^----^---------+ AUDIO PLAYBACK
	* \| \|
	* \| \|
	* \| \|
	* \| \|
	* \|\ \| \|
	* \| +-+ \| \|
	* (to \| \| +-----C----+
	* speaker \| \| \| \| Playback
	* codec) \| \| <=====+================================================================+ Audio
	* \| +-+ Samples
	* \|/
	*
	*/
	// clang-format on

	#define LOG_TAG "audio_hw_aec"
	// #define LOG_NDEBUG 0

	#include <audio_utils/primitives.h>
	#include <stdio.h>
	#include <inttypes.h>
	#include <errno.h>
	#include <malloc.h>
	#include <sys/time.h>
	#include <tinyalsa/asoundlib.h>
	#include <unistd.h>
	#include <log/log.h>
	#include "audio_aec.h"

	#ifdef AEC_HAL
	#include "audio_aec_process.h"
	#else
	#define aec_spk_mic_init(...) ((int)0)
	#define aec_spk_mic_reset(...) ((void)0)
	#define aec_spk_mic_process(...) ((int32_t)0)
	#define aec_spk_mic_release(...) ((void)0)
	#endif

	#define MAX_TIMESTAMP_DIFF_USEC 200000

	#define MAX_READ_WAIT_TIME_MSEC 80

	uint64_t timespec_to_usec(struct timespec ts) {
	return (ts.tv_sec * 1e6L + ts.tv_nsec/1000);
	}

	void get_reference_audio_in_place(struct aec_t *aec, size_t frames) {
	if (aec->num_reference_channels == aec->spk_num_channels) {
	/* Reference count equals speaker channels, nothing to do here. */
	return;
	} else if (aec->num_reference_channels != 1) {
	/* We don't have a rule for non-mono references, show error on log */
	ALOGE("Invalid reference count - must be 1 or match number of playback channels!");
	return;
	}
	int16_t *src_Nch = &aec->spk_buf_playback_format[0];
	int16_t *dst_1ch = &aec->spk_buf_playback_format[0];
	int32_t num_channels = (int32_t)aec->spk_num_channels;
	size_t frame, ch;
	for (frame = 0; frame < frames; frame++) {
	int32_t acc = 0;
	for (ch = 0; ch < aec->spk_num_channels; ch++) {
	acc += src_Nch[ch];
	}
	*dst_1ch++ = clamp16(acc/num_channels);
	src_Nch += aec->spk_num_channels;
	}
	}

	void print_queue_status_to_log(struct aec_t *aec, bool write_side) {
	ssize_t q1 = fifo_available_to_read(aec->spk_fifo);
	ssize_t q2 = fifo_available_to_read(aec->ts_fifo);

	ALOGV("Queue available %s: Spk %zd (count %zd) TS %zd (count %zd)",
	(write_side) ? "(POST-WRITE)" : "(PRE-READ)",
	q1, q1/aec->spk_frame_size_bytes/PLAYBACK_PERIOD_SIZE,
	q2, q2/sizeof(struct aec_info));
	}

	void flush_aec_fifos(struct aec_t *aec) {
	if (aec == NULL) {
	return;
	}
	if (aec->spk_fifo != NULL) {
	ALOGV("Flushing AEC Spk FIFO...");
	fifo_flush(aec->spk_fifo);
	}
	if (aec->ts_fifo != NULL) {
	ALOGV("Flushing AEC Timestamp FIFO...");
	fifo_flush(aec->ts_fifo);
	}
	/* Reset FIFO read-write offset tracker */
	aec->read_write_diff_bytes = 0;
	}

	void aec_set_spk_running_no_lock(struct aec_t* aec, bool state) {
	aec->spk_running = state;
	}

	bool aec_get_spk_running_no_lock(struct aec_t* aec) {
	return aec->spk_running;
	}

	void destroy_aec_reference_config_no_lock(struct aec_t* aec) {
	if (!aec->spk_initialized) {
	return;
	}
	aec_set_spk_running_no_lock(aec, false);
	fifo_release(aec->spk_fifo);
	fifo_release(aec->ts_fifo);
	memset(&aec->last_spk_info, 0, sizeof(struct aec_info));
	aec->spk_initialized = false;
	}

	void destroy_aec_mic_config_no_lock(struct aec_t* aec) {
	if (!aec->mic_initialized) {
	return;
	}
	release_resampler(aec->spk_resampler);
	free(aec->mic_buf);
	free(aec->spk_buf);
	free(aec->spk_buf_playback_format);
	free(aec->spk_buf_resampler_out);
	memset(&aec->last_mic_info, 0, sizeof(struct aec_info));
	aec->mic_initialized = false;
	}

	struct aec_t *init_aec_interface() {
	ALOGV("%s enter", __func__);
	struct aec_t aec = (struct aec_t )calloc(1, sizeof(struct aec_t));
	if (aec == NULL) {
	ALOGE("Failed to allocate memory for AEC interface!");
	} else {
	pthread_mutex_init(&aec->lock, NULL);
	}

	ALOGV("%s exit", __func__);
	return aec;
	}

	void release_aec_interface(struct aec_t *aec) {
	ALOGV("%s enter", __func__);
	pthread_mutex_lock(&aec->lock);
	destroy_aec_mic_config_no_lock(aec);
	destroy_aec_reference_config_no_lock(aec);
	pthread_mutex_unlock(&aec->lock);
	free(aec);
	ALOGV("%s exit", __func__);
	}

	int init_aec(int sampling_rate, int num_reference_channels,
	int num_microphone_channels, struct aec_t **aec_ptr) {
	ALOGV("%s enter", __func__);
	int ret = 0;
	int aec_ret = aec_spk_mic_init(
	sampling_rate,
	num_reference_channels,
	num_microphone_channels);
	if (aec_ret) {
	ALOGE("AEC object failed to initialize!");
	ret = -EINVAL;
	}
	struct aec_t *aec = init_aec_interface();
	if (!ret) {
	aec->num_reference_channels = num_reference_channels;
	/* Set defaults, will be overridden by settings in init_aec_(mic\|referece_config) */
	/* Capture uses 2-ch, 32-bit frames */
	aec->mic_sampling_rate = CAPTURE_CODEC_SAMPLING_RATE;
	aec->mic_frame_size_bytes = CHANNEL_STEREO * sizeof(int32_t);
	aec->mic_num_channels = CHANNEL_STEREO;

	/* Playback uses 2-ch, 16-bit frames */
	aec->spk_sampling_rate = PLAYBACK_CODEC_SAMPLING_RATE;
	aec->spk_frame_size_bytes = CHANNEL_STEREO * sizeof(int16_t);
	aec->spk_num_channels = CHANNEL_STEREO;
	}

	(*aec_ptr) = aec;
	ALOGV("%s exit", __func__);
	return ret;
	}

	void release_aec(struct aec_t *aec) {
	ALOGV("%s enter", __func__);
	if (aec == NULL) {
	return;
	}
	release_aec_interface(aec);
	aec_spk_mic_release();
	ALOGV("%s exit", __func__);
	}

	int init_aec_reference_config(struct aec_t aec, struct alsa_stream_out out) {
	ALOGV("%s enter", __func__);
	if (!aec) {
	ALOGE("AEC: No valid interface found!");
	return -EINVAL;
	}

	int ret = 0;
	pthread_mutex_lock(&aec->lock);
	if (aec->spk_initialized) {
	destroy_aec_reference_config_no_lock(aec);
	}

	aec->spk_fifo = fifo_init(
	out->config.period_count * out->config.period_size *
	audio_stream_out_frame_size(&out->stream),
	false /* reader_throttles_writer */);
	if (aec->spk_fifo == NULL) {
	ALOGE("AEC: Speaker loopback FIFO Init failed!");
	ret = -EINVAL;
	goto exit;
	}
	aec->ts_fifo = fifo_init(
	out->config.period_count * sizeof(struct aec_info),
	false /* reader_throttles_writer */);
	if (aec->ts_fifo == NULL) {
	ALOGE("AEC: Speaker timestamp FIFO Init failed!");
	ret = -EINVAL;
	fifo_release(aec->spk_fifo);
	goto exit;
	}

	aec->spk_sampling_rate = out->config.rate;
	aec->spk_frame_size_bytes = audio_stream_out_frame_size(&out->stream);
	aec->spk_num_channels = out->config.channels;
	aec->spk_initialized = true;
	exit:
	pthread_mutex_unlock(&aec->lock);
	ALOGV("%s exit", __func__);
	return ret;
	}

	void destroy_aec_reference_config(struct aec_t* aec) {
	ALOGV("%s enter", __func__);
	if (aec == NULL) {
	ALOGV("%s exit", __func__);
	return;
	}
	pthread_mutex_lock(&aec->lock);
	destroy_aec_reference_config_no_lock(aec);
	pthread_mutex_unlock(&aec->lock);
	ALOGV("%s exit", __func__);
	}

	int write_to_reference_fifo(struct aec_t* aec, void* buffer, struct aec_info* info) {
	ALOGV("%s enter", __func__);
	int ret = 0;
	size_t bytes = info->bytes;

	/* Write audio samples to FIFO */
	ssize_t written_bytes = fifo_write(aec->spk_fifo, buffer, bytes);
	if (written_bytes != bytes) {
	ALOGE("Could only write %zu of %zu bytes", written_bytes, bytes);
	ret = -ENOMEM;
	}

	/* Write timestamp to FIFO */
	info->bytes = written_bytes;
	ALOGV("Speaker timestamp: %ld s, %ld nsec", info->timestamp.tv_sec, info->timestamp.tv_nsec);
	ssize_t ts_bytes = fifo_write(aec->ts_fifo, info, sizeof(struct aec_info));
	ALOGV("Wrote TS bytes: %zu", ts_bytes);
	print_queue_status_to_log(aec, true);
	ALOGV("%s exit", __func__);
	return ret;
	}

	void get_spk_timestamp(struct aec_t* aec, ssize_t read_bytes, uint64_t* spk_time) {
	*spk_time = 0;
	uint64_t spk_time_offset = 0;
	float usec_per_byte = 1E6 / ((float)(aec->spk_frame_size_bytes * aec->spk_sampling_rate));
	if (aec->read_write_diff_bytes < 0) {
	/* We're still reading a previous write packet. (We only need the first sample's timestamp,
	* so even if we straddle packets we only care about the first one)
	* So we just use the previous timestamp, with an appropriate offset
	* based on the number of bytes remaining to be read from that write packet. */
	spk_time_offset = (aec->last_spk_info.bytes + aec->read_write_diff_bytes) * usec_per_byte;
	ALOGV("Reusing previous timestamp, calculated offset (usec) %" PRIu64, spk_time_offset);
	} else {
	/* If read_write_diff_bytes > 0, there are no new writes, so there won't be timestamps in
	* the FIFO, and the check below will fail. */
	if (!fifo_available_to_read(aec->ts_fifo)) {
	ALOGE("Timestamp error: no new timestamps!");
	return;
	}
	/* We just read valid data, so if we're here, we should have a valid timestamp to use. */
	ssize_t ts_bytes = fifo_read(aec->ts_fifo, &aec->last_spk_info, sizeof(struct aec_info));
	ALOGV("Read TS bytes: %zd, expected %zu", ts_bytes, sizeof(struct aec_info));
	aec->read_write_diff_bytes -= aec->last_spk_info.bytes;
	}

	*spk_time = timespec_to_usec(aec->last_spk_info.timestamp) + spk_time_offset;

	aec->read_write_diff_bytes += read_bytes;
	struct aec_info spk_info = aec->last_spk_info;
	while (aec->read_write_diff_bytes > 0) {
	/* If read_write_diff_bytes > 0, it means that there are more write packet timestamps
	* in FIFO (since there we read more valid data the size of the current timestamp's
	* packet). Keep reading timestamps from FIFO to get to the most recent one. */
	if (!fifo_available_to_read(aec->ts_fifo)) {
	/* There are no more timestamps, we have the most recent one. */
	ALOGV("At the end of timestamp FIFO, breaking...");
	break;
	}
	fifo_read(aec->ts_fifo, &spk_info, sizeof(struct aec_info));
	ALOGV("Fast-forwarded timestamp by %zd bytes, remaining bytes: %zd,"
	" new timestamp (usec) %" PRIu64,
	spk_info.bytes, aec->read_write_diff_bytes, timespec_to_usec(spk_info.timestamp));
	aec->read_write_diff_bytes -= spk_info.bytes;
	}
	aec->last_spk_info = spk_info;
	}

	int get_reference_samples(struct aec_t* aec, void* buffer, struct aec_info* info) {
	ALOGV("%s enter", __func__);

	if (!aec->spk_initialized) {
	ALOGE("%s called with no reference initialized", __func__);
	return -EINVAL;
	}

	size_t bytes = info->bytes;
	const size_t frames = bytes / aec->mic_frame_size_bytes;
	const size_t sample_rate_ratio = aec->spk_sampling_rate / aec->mic_sampling_rate;

	/* Read audio samples from FIFO */
	const size_t req_bytes = frames * sample_rate_ratio * aec->spk_frame_size_bytes;
	ssize_t available_bytes = 0;
	unsigned int wait_count = MAX_READ_WAIT_TIME_MSEC;
	while (true) {
	available_bytes = fifo_available_to_read(aec->spk_fifo);
	if (available_bytes >= req_bytes) {
	break;
	} else if (available_bytes < 0) {
	ALOGE("fifo_read returned code %zu ", available_bytes);
	return -ENOMEM;
	}

	ALOGV("Sleeping, required bytes: %zu, available bytes: %zd", req_bytes, available_bytes);
	usleep(1000);
	if ((wait_count--) == 0) {
	ALOGE("Timed out waiting for read from reference FIFO");
	return -ETIMEDOUT;
	}
	}

	const size_t read_bytes = fifo_read(aec->spk_fifo, aec->spk_buf_playback_format, req_bytes);

	/* Get timestamp*/
	get_spk_timestamp(aec, read_bytes, &info->timestamp_usec);

	/* Get reference - could be mono, downmixed from multichannel.
	* Reference stored at spk_buf_playback_format */
	const size_t resampler_in_frames = frames * sample_rate_ratio;
	get_reference_audio_in_place(aec, resampler_in_frames);

	int16_t* resampler_out_buf;
	/* Resample to mic sampling rate (16-bit resampler) */
	if (aec->spk_resampler != NULL) {
	size_t in_frame_count = resampler_in_frames;
	size_t out_frame_count = frames;
	aec->spk_resampler->resample_from_input(aec->spk_resampler, aec->spk_buf_playback_format,
	&in_frame_count, aec->spk_buf_resampler_out,
	&out_frame_count);
	resampler_out_buf = aec->spk_buf_resampler_out;
	} else {
	if (sample_rate_ratio != 1) {
	ALOGE("Speaker sample rate %d, mic sample rate %d but no resampler defined!",
	aec->spk_sampling_rate, aec->mic_sampling_rate);
	}
	resampler_out_buf = aec->spk_buf_playback_format;
	}

	/* Convert to 32 bit */
	int16_t* src16 = resampler_out_buf;
	int32_t* dst32 = buffer;
	size_t frame, ch;
	for (frame = 0; frame < frames; frame++) {
	for (ch = 0; ch < aec->num_reference_channels; ch++) {
	dst32++ = ((int32_t)src16++) << 16;
	}
	}

	info->bytes = bytes;

	ALOGV("%s exit", __func__);
	return 0;
	}

	int init_aec_mic_config(struct aec_t aec, struct alsa_stream_in in) {
	ALOGV("%s enter", __func__);
	#if DEBUG_AEC
	remove("/data/local/traces/aec_in.pcm");
	remove("/data/local/traces/aec_out.pcm");
	remove("/data/local/traces/aec_ref.pcm");
	remove("/data/local/traces/aec_timestamps.txt");
	#endif /* #if DEBUG_AEC */

	if (!aec) {
	ALOGE("AEC: No valid interface found!");
	return -EINVAL;
	}

	int ret = 0;
	pthread_mutex_lock(&aec->lock);
	if (aec->mic_initialized) {
	destroy_aec_mic_config_no_lock(aec);
	}
	aec->mic_sampling_rate = in->config.rate;
	aec->mic_frame_size_bytes = audio_stream_in_frame_size(&in->stream);
	aec->mic_num_channels = in->config.channels;

	aec->mic_buf_size_bytes = in->config.period_size * audio_stream_in_frame_size(&in->stream);
	aec->mic_buf = (int32_t *)malloc(aec->mic_buf_size_bytes);
	if (aec->mic_buf == NULL) {
	ret = -ENOMEM;
	goto exit;
	}
	memset(aec->mic_buf, 0, aec->mic_buf_size_bytes);
	/* Reference buffer is the same number of frames as mic,
	* only with a different number of channels in the frame. */
	aec->spk_buf_size_bytes = in->config.period_size * aec->spk_frame_size_bytes;
	aec->spk_buf = (int32_t *)malloc(aec->spk_buf_size_bytes);
	if (aec->spk_buf == NULL) {
	ret = -ENOMEM;
	goto exit_1;
	}
	memset(aec->spk_buf, 0, aec->spk_buf_size_bytes);

	/* Pre-resampler buffer */
	size_t spk_frame_out_format_bytes = aec->spk_sampling_rate / aec->mic_sampling_rate *
	aec->spk_buf_size_bytes;
	aec->spk_buf_playback_format = (int16_t *)malloc(spk_frame_out_format_bytes);
	if (aec->spk_buf_playback_format == NULL) {
	ret = -ENOMEM;
	goto exit_2;
	}
	/* Resampler is 16-bit */
	aec->spk_buf_resampler_out = (int16_t *)malloc(aec->spk_buf_size_bytes);
	if (aec->spk_buf_resampler_out == NULL) {
	ret = -ENOMEM;
	goto exit_3;
	}

	/* Don't use resampler if it's not required */
	if (in->config.rate == aec->spk_sampling_rate) {
	aec->spk_resampler = NULL;
	} else {
	int resampler_ret = create_resampler(
	aec->spk_sampling_rate, in->config.rate, aec->num_reference_channels,
	RESAMPLER_QUALITY_MAX - 1, /* MAX - 1 is the real max */
	NULL, /* resampler_buffer_provider */
	&aec->spk_resampler);
	if (resampler_ret) {
	ALOGE("AEC: Resampler initialization failed! Error code %d", resampler_ret);
	ret = resampler_ret;
	goto exit_4;
	}
	}

	flush_aec_fifos(aec);
	aec_spk_mic_reset();
	aec->mic_initialized = true;

	exit:
	pthread_mutex_unlock(&aec->lock);
	ALOGV("%s exit", __func__);
	return ret;

	exit_4:
	free(aec->spk_buf_resampler_out);
	exit_3:
	free(aec->spk_buf_playback_format);
	exit_2:
	free(aec->spk_buf);
	exit_1:
	free(aec->mic_buf);
	pthread_mutex_unlock(&aec->lock);
	ALOGV("%s exit", __func__);
	return ret;
	}

	void aec_set_spk_running(struct aec_t *aec, bool state) {
	ALOGV("%s enter", __func__);
	pthread_mutex_lock(&aec->lock);
	aec_set_spk_running_no_lock(aec, state);
	pthread_mutex_unlock(&aec->lock);
	ALOGV("%s exit", __func__);
	}

	bool aec_get_spk_running(struct aec_t *aec) {
	ALOGV("%s enter", __func__);
	pthread_mutex_lock(&aec->lock);
	bool state = aec_get_spk_running_no_lock(aec);
	pthread_mutex_unlock(&aec->lock);
	ALOGV("%s exit", __func__);
	return state;
	}

	void destroy_aec_mic_config(struct aec_t* aec) {
	ALOGV("%s enter", __func__);
	if (aec == NULL) {
	ALOGV("%s exit", __func__);
	return;
	}

	pthread_mutex_lock(&aec->lock);
	destroy_aec_mic_config_no_lock(aec);
	pthread_mutex_unlock(&aec->lock);
	ALOGV("%s exit", __func__);
	}

	#ifdef AEC_HAL
	int process_aec(struct aec_t aec, void buffer, struct aec_info *info) {
	ALOGV("%s enter", __func__);
	int ret = 0;

	if (aec == NULL) {
	ALOGE("AEC: Interface uninitialized! Cannot process.");
	return -EINVAL;
	}

	if ((!aec->mic_initialized) \|\| (!aec->spk_initialized)) {
	ALOGE("%s called with initialization: mic: %d, spk: %d", __func__, aec->mic_initialized,
	aec->spk_initialized);
	return -EINVAL;
	}

	size_t bytes = info->bytes;

	size_t frame_size = aec->mic_frame_size_bytes;
	size_t in_frames = bytes / frame_size;

	/* Copy raw mic samples to AEC input buffer */
	memcpy(aec->mic_buf, buffer, bytes);

	uint64_t mic_time = timespec_to_usec(info->timestamp);
	uint64_t spk_time = 0;

	/*
	* Only run AEC if there is speaker playback.
	* The first time speaker state changes to running, flush FIFOs, so we're not stuck
	* processing stale reference input.
	*/
	bool spk_running = aec_get_spk_running(aec);

	if (!spk_running) {
	/* No new playback samples, so don't run AEC.
	* 'buffer' already contains input samples. */
	ALOGV("Speaker not running, skipping AEC..");
	goto exit;
	}

	if (!aec->prev_spk_running) {
	flush_aec_fifos(aec);
	}

	/* If there's no data in FIFO, exit */
	if (fifo_available_to_read(aec->spk_fifo) <= 0) {
	ALOGV("Echo reference buffer empty, zeroing reference....");
	goto exit;
	}

	print_queue_status_to_log(aec, false);

	/* Get reference, with format and sample rate required by AEC */
	struct aec_info spk_info;
	spk_info.bytes = bytes;
	int ref_ret = get_reference_samples(aec, aec->spk_buf, &spk_info);
	spk_time = spk_info.timestamp_usec;

	if (ref_ret) {
	ALOGE("get_reference_samples returned code %d", ref_ret);
	ret = -ENOMEM;
	goto exit;
	}

	int64_t time_diff = (mic_time > spk_time) ? (mic_time - spk_time) : (spk_time - mic_time);
	if ((spk_time == 0) \|\| (mic_time == 0) \|\| (time_diff > MAX_TIMESTAMP_DIFF_USEC)) {
	ALOGV("Speaker-mic timestamps diverged, skipping AEC");
	flush_aec_fifos(aec);
	aec_spk_mic_reset();
	goto exit;
	}

	ALOGV("Mic time: %"PRIu64", spk time: %"PRIu64, mic_time, spk_time);

	/*
	* AEC processing call - output stored at 'buffer'
	*/
	int32_t aec_status = aec_spk_mic_process(
	aec->spk_buf, spk_time,
	aec->mic_buf, mic_time,
	in_frames,
	buffer);

	if (!aec_status) {
	ALOGE("AEC processing failed!");
	ret = -EINVAL;
	}

	exit:
	aec->prev_spk_running = spk_running;
	ALOGV("Mic time: %"PRIu64", spk time: %"PRIu64, mic_time, spk_time);
	if (ret) {
	/* Best we can do is copy over the raw mic signal */
	memcpy(buffer, aec->mic_buf, bytes);
	flush_aec_fifos(aec);
	aec_spk_mic_reset();
	}

	#if DEBUG_AEC
	/* ref data is 32-bit at this point */
	size_t ref_bytes = in_framesaec->num_reference_channelssizeof(int32_t);

	FILE *fp_in = fopen("/data/local/traces/aec_in.pcm", "a+");
	if (fp_in) {
	fwrite((char *)aec->mic_buf, 1, bytes, fp_in);
	fclose(fp_in);
	} else {
	ALOGE("AEC debug: Could not open file aec_in.pcm!");
	}
	FILE *fp_out = fopen("/data/local/traces/aec_out.pcm", "a+");
	if (fp_out) {
	fwrite((char *)buffer, 1, bytes, fp_out);
	fclose(fp_out);
	} else {
	ALOGE("AEC debug: Could not open file aec_out.pcm!");
	}
	FILE *fp_ref = fopen("/data/local/traces/aec_ref.pcm", "a+");
	if (fp_ref) {
	fwrite((char *)aec->spk_buf, 1, ref_bytes, fp_ref);
	fclose(fp_ref);
	} else {
	ALOGE("AEC debug: Could not open file aec_ref.pcm!");
	}
	FILE *fp_ts = fopen("/data/local/traces/aec_timestamps.txt", "a+");
	if (fp_ts) {
	fprintf(fp_ts, "%"PRIu64",%"PRIu64"\n", mic_time, spk_time);
	fclose(fp_ts);
	} else {
	ALOGE("AEC debug: Could not open file aec_timestamps.txt!");
	}
	#endif /* #if DEBUG_AEC */
	ALOGV("%s exit", __func__);
	return ret;
	}

	#endif /#ifdef AEC_HAL/