Exemplo n.º 1
0
static GstFlowReturn
gst_aubio_tempo_transform_ip (GstBaseTransform * trans, GstBuffer * buf)
{
  uint j;
  GstAubioTempo *filter = GST_AUBIOTEMPO(trans);
  GstAudioFilter *audiofilter = GST_AUDIO_FILTER(trans);

  gint nsamples = GST_BUFFER_SIZE (buf) / (4 * audiofilter->format.channels);

  /* block loop */
  for (j = 0; j < nsamples; j++) {
    /* copy input to ibuf */
    fvec_write_sample(filter->ibuf, ((smpl_t *) GST_BUFFER_DATA(buf))[j],
        filter->pos);

    if (filter->pos == filter->hop_size - 1) {
      aubio_tempo_do(filter->t, filter->ibuf, filter->out);

      if (filter->out->data[0]> 0.) {
        gdouble now = GST_BUFFER_OFFSET (buf);
        // correction of inside buffer time
        now += (smpl_t)(j - filter->hop_size + 1);
        // correction of float period
        now += (filter->out->data[0] - 1.)*(smpl_t)filter->hop_size;

        if (filter->last_beat != -1 && now > filter->last_beat) {
          filter->bpm = 60./(GST_FRAMES_TO_CLOCK_TIME(now - filter->last_beat, audiofilter->format.rate))*1.e+9;
        } else {
          filter->bpm = 0.;
        }

        if (filter->silent == FALSE) {
          g_print ("beat: %f ", GST_FRAMES_TO_CLOCK_TIME( now, audiofilter->format.rate)*1.e-9);
          g_print ("| bpm: %f\n", filter->bpm);
        }

        GST_LOG_OBJECT (filter, "beat %" GST_TIME_FORMAT ", bpm %3.2f",
            GST_TIME_ARGS(now), filter->bpm);

        if (filter->message) {
          GstMessage *m = gst_aubio_tempo_message_new (filter, now);
          gst_element_post_message (GST_ELEMENT (filter), m);
        }

        filter->last_beat = now;
      }

      filter->pos = -1; /* so it will be zero next j loop */
    }
    filter->pos++;
  }

  return GST_FLOW_OK;
}
Exemplo n.º 2
0
static GstFlowReturn
gst_ofa_transform_ip (GstBaseTransform * trans, GstBuffer * buf)
{
  GstOFA *ofa = GST_OFA (trans);
  GstAudioFilter *ofa_filter = GST_AUDIO_FILTER (ofa);
  guint64 nframes;
  GstClockTime duration;
  gint rate = ofa_filter->format.rate;
  gint channels = ofa_filter->format.channels;

  g_return_val_if_fail (rate > 0 && channels > 0, GST_FLOW_NOT_NEGOTIATED);

  if (!ofa->record)
    return GST_FLOW_OK;

  gst_adapter_push (ofa->adapter, gst_buffer_copy (buf));

  nframes = gst_adapter_available (ofa->adapter) / (channels * 2);
  duration = GST_FRAMES_TO_CLOCK_TIME (nframes, rate);

  if (duration >= 135 * GST_SECOND && ofa->fingerprint == NULL)
    create_fingerprint (ofa);

  return GST_FLOW_OK;
}
Exemplo n.º 3
0
/* this tests that the output is a perfect stream if the input is */
static void
test_perfect_stream_instance (int inrate, int outrate, int samples,
    int numbuffers)
{
  GstElement *audioresample;
  GstBuffer *inbuffer, *outbuffer;
  GstCaps *caps;
  guint64 offset = 0;
  int i, j;
  GstMapInfo map;
  gint16 *p;

  audioresample =
      setup_audioresample (2, 0x3, inrate, outrate, GST_AUDIO_NE (S16));
  caps = gst_pad_get_current_caps (mysrcpad);
  fail_unless (gst_caps_is_fixed (caps));

  fail_unless (gst_element_set_state (audioresample,
          GST_STATE_PLAYING) == GST_STATE_CHANGE_SUCCESS,
      "could not set to playing");

  for (j = 1; j <= numbuffers; ++j) {

    inbuffer = gst_buffer_new_and_alloc (samples * 4);
    GST_BUFFER_DURATION (inbuffer) = GST_FRAMES_TO_CLOCK_TIME (samples, inrate);
    GST_BUFFER_TIMESTAMP (inbuffer) = GST_BUFFER_DURATION (inbuffer) * (j - 1);
    GST_BUFFER_OFFSET (inbuffer) = offset;
    offset += samples;
    GST_BUFFER_OFFSET_END (inbuffer) = offset;

    gst_buffer_map (inbuffer, &map, GST_MAP_WRITE);
    p = (gint16 *) map.data;

    /* create a 16 bit signed ramp */
    for (i = 0; i < samples; ++i) {
      *p = -32767 + i * (65535 / samples);
      ++p;
      *p = -32767 + i * (65535 / samples);
      ++p;
    }
    gst_buffer_unmap (inbuffer, &map);

    /* pushing gives away my reference ... */
    fail_unless (gst_pad_push (mysrcpad, inbuffer) == GST_FLOW_OK);
    /* ... but it ends up being collected on the global buffer list */
    fail_unless_equals_int (g_list_length (buffers), j);
  }

  /* FIXME: we should make audioresample handle eos by flushing out the last
   * samples, which will give us one more, small, buffer */
  fail_if ((outbuffer = (GstBuffer *) buffers->data) == NULL);
  ASSERT_BUFFER_REFCOUNT (outbuffer, "outbuffer", 1);

  fail_unless_perfect_stream ();

  /* cleanup */
  gst_caps_unref (caps);
  cleanup_audioresample (audioresample);
}
Exemplo n.º 4
0
static void
run_fft_pipeline (int inrate, int outrate, int quality, int width,
    const gchar * format, void (*init) (GstBuffer *),
    void (*compare_ffts) (GstBuffer *, GstBuffer *))
{
  GstElement *audioresample;
  GstBuffer *inbuffer, *outbuffer;
  GstCaps *caps;
  const int nsamples = 2048;

  audioresample = setup_audioresample (1, 0, inrate, outrate, format);
  fail_unless (audioresample != NULL);
  g_object_set (audioresample, "quality", quality, NULL);
  caps = gst_pad_get_current_caps (mysrcpad);
  fail_unless (gst_caps_is_fixed (caps));

  fail_unless (gst_element_set_state (audioresample,
          GST_STATE_PLAYING) == GST_STATE_CHANGE_SUCCESS,
      "could not set to playing");

  inbuffer = gst_buffer_new_and_alloc (nsamples * width / 8);
  GST_BUFFER_DURATION (inbuffer) = GST_FRAMES_TO_CLOCK_TIME (nsamples, inrate);
  GST_BUFFER_TIMESTAMP (inbuffer) = 0;
  gst_pad_set_caps (mysrcpad, caps);

  (*init) (inbuffer);

  gst_buffer_ref (inbuffer);
  /* pushing gives away my reference ... */
  fail_unless (gst_pad_push (mysrcpad, inbuffer) == GST_FLOW_OK);
  /* ... but it ends up being collected on the global buffer list */
  fail_unless_equals_int (g_list_length (buffers), 1);
  /* retrieve out buffer */
  fail_if ((outbuffer = (GstBuffer *) buffers->data) == NULL);

  fail_unless (gst_element_set_state (audioresample,
          GST_STATE_NULL) == GST_STATE_CHANGE_SUCCESS, "could not set to null");

  if (inbuffer == outbuffer)
    gst_buffer_unref (inbuffer);

  (*compare_ffts) (inbuffer, outbuffer);

  /* cleanup */
  gst_caps_unref (caps);
  cleanup_audioresample (audioresample);
}
Exemplo n.º 5
0
static void
gst_level_recalc_interval_frames (GstLevel * level)
{
  GstClockTime interval = level->interval;
  guint sample_rate = GST_AUDIO_INFO_RATE (&level->info);
  guint interval_frames;

  interval_frames = GST_CLOCK_TIME_TO_FRAMES (interval, sample_rate);

  if (interval_frames == 0) {
    GST_WARNING_OBJECT (level, "interval %" GST_TIME_FORMAT " is too small, "
        "should be at least %" GST_TIME_FORMAT " for sample rate %u",
        GST_TIME_ARGS (interval),
        GST_TIME_ARGS (GST_FRAMES_TO_CLOCK_TIME (1, sample_rate)), sample_rate);
    interval_frames = 1;
  }

  level->interval_frames = interval_frames;

  GST_INFO_OBJECT (level, "interval_frames now %u for interval "
      "%" GST_TIME_FORMAT " and sample rate %u", interval_frames,
      GST_TIME_ARGS (interval), sample_rate);
}
Exemplo n.º 6
0
static GstFlowReturn
gst_aubio_pitch_transform_ip (GstBaseTransform * trans, GstBuffer * buf)
{
  uint j;
  GstAubioPitch *filter = GST_AUBIO_PITCH (trans);
  GstAudioFilter *audiofilter = GST_AUDIO_FILTER(trans);

  gint nsamples = GST_BUFFER_SIZE (buf) / (4 * audiofilter->format.channels);

  /* block loop */
  for (j = 0; j < nsamples; j++) {
    /* copy input to ibuf */
    fvec_write_sample(filter->ibuf, ((smpl_t *) GST_BUFFER_DATA(buf))[j],
        filter->pos);

    if (filter->pos == filter->hop_size - 1) {
      aubio_pitch_do(filter->t, filter->ibuf, filter->obuf);
      smpl_t pitch = filter->obuf->data[0];
      GstClockTime now = GST_BUFFER_TIMESTAMP (buf);
      // correction of inside buffer time
      now += GST_FRAMES_TO_CLOCK_TIME(j, audiofilter->format.rate);

      if (filter->silent == FALSE) {
        g_print ("%" GST_TIME_FORMAT "\tpitch: %.3f\n",
                GST_TIME_ARGS(now), pitch);
      }

      GST_LOG_OBJECT (filter, "pitch %" GST_TIME_FORMAT ", freq %3.2f",
              GST_TIME_ARGS(now), pitch);

      filter->pos = -1; /* so it will be zero next j loop */
    }
    filter->pos++;
  }

  return GST_FLOW_OK;
}
/**
 * gst_audio_info_convert:
 * @info: a #GstAudioInfo
 * @src_fmt: #GstFormat of the @src_val
 * @src_val: value to convert
 * @dest_fmt: #GstFormat of the @dest_val
 * @dest_val: pointer to destination value
 *
 * Converts among various #GstFormat types.  This function handles
 * GST_FORMAT_BYTES, GST_FORMAT_TIME, and GST_FORMAT_DEFAULT.  For
 * raw audio, GST_FORMAT_DEFAULT corresponds to audio frames.  This
 * function can be used to handle pad queries of the type GST_QUERY_CONVERT.
 *
 * Returns: TRUE if the conversion was successful.
 */
gboolean
gst_audio_info_convert (const GstAudioInfo * info,
    GstFormat src_fmt, gint64 src_val, GstFormat dest_fmt, gint64 * dest_val)
{
  gboolean res = TRUE;
  gint bpf, rate;

  GST_DEBUG ("converting value %" G_GINT64_FORMAT " from %s (%d) to %s (%d)",
      src_val, gst_format_get_name (src_fmt), src_fmt,
      gst_format_get_name (dest_fmt), dest_fmt);

  if (src_fmt == dest_fmt || src_val == -1) {
    *dest_val = src_val;
    goto done;
  }

  /* get important info */
  bpf = GST_AUDIO_INFO_BPF (info);
  rate = GST_AUDIO_INFO_RATE (info);

  if (bpf == 0 || rate == 0) {
    GST_DEBUG ("no rate or bpf configured");
    res = FALSE;
    goto done;
  }

  switch (src_fmt) {
    case GST_FORMAT_BYTES:
      switch (dest_fmt) {
        case GST_FORMAT_TIME:
          *dest_val = GST_FRAMES_TO_CLOCK_TIME (src_val / bpf, rate);
          break;
        case GST_FORMAT_DEFAULT:
          *dest_val = src_val / bpf;
          break;
        default:
          res = FALSE;
          break;
      }
      break;
    case GST_FORMAT_DEFAULT:
      switch (dest_fmt) {
        case GST_FORMAT_TIME:
          *dest_val = GST_FRAMES_TO_CLOCK_TIME (src_val, rate);
          break;
        case GST_FORMAT_BYTES:
          *dest_val = src_val * bpf;
          break;
        default:
          res = FALSE;
          break;
      }
      break;
    case GST_FORMAT_TIME:
      switch (dest_fmt) {
        case GST_FORMAT_DEFAULT:
          *dest_val = GST_CLOCK_TIME_TO_FRAMES (src_val, rate);
          break;
        case GST_FORMAT_BYTES:
          *dest_val = GST_CLOCK_TIME_TO_FRAMES (src_val, rate);
          *dest_val *= bpf;
          break;
        default:
          res = FALSE;
          break;
      }
      break;
    default:
      res = FALSE;
      break;
  }
done:

  GST_DEBUG ("ret=%d result %" G_GINT64_FORMAT, res, res ? *dest_val : -1);

  return res;
}
Exemplo n.º 8
0
static void
gst_level_post_message (GstLevel * filter)
{
  guint i;
  gint channels, rate, frames = filter->num_frames;
  GstClockTime duration;

  channels = GST_AUDIO_INFO_CHANNELS (&filter->info);
  rate = GST_AUDIO_INFO_RATE (&filter->info);
  duration = GST_FRAMES_TO_CLOCK_TIME (frames, rate);

  if (filter->post_messages) {
    GstMessage *m =
        gst_level_message_new (filter, filter->message_ts, duration);

    GST_LOG_OBJECT (filter,
        "message: ts %" GST_TIME_FORMAT ", duration %" GST_TIME_FORMAT
        ", num_frames %d", GST_TIME_ARGS (filter->message_ts),
        GST_TIME_ARGS (duration), frames);

    for (i = 0; i < channels; ++i) {
      gdouble RMS;
      gdouble RMSdB, peakdB, decaydB;

      RMS = sqrt (filter->CS[i] / frames);
      GST_LOG_OBJECT (filter,
          "message: channel %d, CS %f, RMS %f", i, filter->CS[i], RMS);
      GST_LOG_OBJECT (filter,
          "message: last_peak: %f, decay_peak: %f",
          filter->last_peak[i], filter->decay_peak[i]);
      /* RMS values are calculated in amplitude, so 20 * log 10 */
      RMSdB = 20 * log10 (RMS + EPSILON);
      /* peak values are square sums, ie. power, so 10 * log 10 */
      peakdB = 10 * log10 (filter->last_peak[i] + EPSILON);
      decaydB = 10 * log10 (filter->decay_peak[i] + EPSILON);

      if (filter->decay_peak[i] < filter->last_peak[i]) {
        /* this can happen in certain cases, for example when
         * the last peak is between decay_peak and decay_peak_base */
        GST_DEBUG_OBJECT (filter,
            "message: decay peak dB %f smaller than last peak dB %f, copying",
            decaydB, peakdB);
        filter->decay_peak[i] = filter->last_peak[i];
      }
      GST_LOG_OBJECT (filter,
          "message: RMS %f dB, peak %f dB, decay %f dB",
          RMSdB, peakdB, decaydB);

      gst_level_message_append_channel (m, RMSdB, peakdB, decaydB);

      /* reset cumulative and normal peak */
      filter->CS[i] = 0.0;
      filter->last_peak[i] = 0.0;
    }

    gst_element_post_message (GST_ELEMENT (filter), m);

  }
  filter->num_frames -= frames;
  filter->message_ts += duration;
}
Exemplo n.º 9
0
static GstFlowReturn
gst_level_transform_ip (GstBaseTransform * trans, GstBuffer * in)
{
  GstLevel *filter;
  GstMapInfo map;
  guint8 *in_data;
  gsize in_size;
  gdouble CS;
  guint i;
  guint num_frames;
  guint num_int_samples = 0;    /* number of interleaved samples
                                 * ie. total count for all channels combined */
  guint block_size, block_int_size;     /* we subdivide buffers to not skip message
                                         * intervals */
  GstClockTimeDiff falloff_time;
  gint channels, rate, bps;

  filter = GST_LEVEL (trans);

  channels = GST_AUDIO_INFO_CHANNELS (&filter->info);
  bps = GST_AUDIO_INFO_BPS (&filter->info);
  rate = GST_AUDIO_INFO_RATE (&filter->info);

  gst_buffer_map (in, &map, GST_MAP_READ);
  in_data = map.data;
  in_size = map.size;

  num_int_samples = in_size / bps;

  GST_LOG_OBJECT (filter, "analyzing %u sample frames at ts %" GST_TIME_FORMAT,
      num_int_samples, GST_TIME_ARGS (GST_BUFFER_TIMESTAMP (in)));

  g_return_val_if_fail (num_int_samples % channels == 0, GST_FLOW_ERROR);

  if (GST_BUFFER_FLAG_IS_SET (in, GST_BUFFER_FLAG_DISCONT)) {
    filter->message_ts = GST_BUFFER_TIMESTAMP (in);
    filter->num_frames = 0;
  }
  if (G_UNLIKELY (!GST_CLOCK_TIME_IS_VALID (filter->message_ts))) {
    filter->message_ts = GST_BUFFER_TIMESTAMP (in);
  }

  num_frames = num_int_samples / channels;
  while (num_frames > 0) {
    block_size = filter->interval_frames - filter->num_frames;
    block_size = MIN (block_size, num_frames);
    block_int_size = block_size * channels;

    for (i = 0; i < channels; ++i) {
      if (!GST_BUFFER_FLAG_IS_SET (in, GST_BUFFER_FLAG_GAP)) {
        filter->process (in_data + (bps * i), block_int_size, channels, &CS,
            &filter->peak[i]);
        GST_LOG_OBJECT (filter,
            "[%d]: cumulative squares %lf, over %d samples/%d channels",
            i, CS, block_int_size, channels);
        filter->CS[i] += CS;
      } else {
        filter->peak[i] = 0.0;
      }

      filter->decay_peak_age[i] += GST_FRAMES_TO_CLOCK_TIME (num_frames, rate);
      GST_LOG_OBJECT (filter,
          "[%d]: peak %f, last peak %f, decay peak %f, age %" GST_TIME_FORMAT,
          i, filter->peak[i], filter->last_peak[i], filter->decay_peak[i],
          GST_TIME_ARGS (filter->decay_peak_age[i]));

      /* update running peak */
      if (filter->peak[i] > filter->last_peak[i])
        filter->last_peak[i] = filter->peak[i];

      /* make decay peak fall off if too old */
      falloff_time =
          GST_CLOCK_DIFF (gst_gdouble_to_guint64 (filter->decay_peak_ttl),
          filter->decay_peak_age[i]);
      if (falloff_time > 0) {
        gdouble falloff_dB;
        gdouble falloff;
        gdouble length;         /* length of falloff time in seconds */

        length = (gdouble) falloff_time / (gdouble) GST_SECOND;
        falloff_dB = filter->decay_peak_falloff * length;
        falloff = pow (10, falloff_dB / -20.0);

        GST_LOG_OBJECT (filter,
            "falloff: current %f, base %f, interval %" GST_TIME_FORMAT
            ", dB falloff %f, factor %e",
            filter->decay_peak[i], filter->decay_peak_base[i],
            GST_TIME_ARGS (falloff_time), falloff_dB, falloff);
        filter->decay_peak[i] = filter->decay_peak_base[i] * falloff;
        GST_LOG_OBJECT (filter,
            "peak is %" GST_TIME_FORMAT " old, decayed with factor %e to %f",
            GST_TIME_ARGS (filter->decay_peak_age[i]), falloff,
            filter->decay_peak[i]);
      } else {
        GST_LOG_OBJECT (filter, "peak not old enough, not decaying");
      }

      /* if the peak of this run is higher, the decay peak gets reset */
      if (filter->peak[i] >= filter->decay_peak[i]) {
        GST_LOG_OBJECT (filter, "new peak, %f", filter->peak[i]);
        filter->decay_peak[i] = filter->peak[i];
        filter->decay_peak_base[i] = filter->peak[i];
        filter->decay_peak_age[i] = G_GINT64_CONSTANT (0);
      }
    }
    in_data += block_size * bps * channels;

    filter->num_frames += block_size;
    num_frames -= block_size;

    /* do we need to message ? */
    if (filter->num_frames >= filter->interval_frames) {
      gst_level_post_message (filter);
    }
  }

  gst_buffer_unmap (in, &map);

  return GST_FLOW_OK;
}
static GstMessage *
update_rms_from_buffer (GstVideoFrameAudioLevel * self, GstBuffer * inbuf)
{
  GstMapInfo map;
  guint8 *in_data;
  gsize in_size;
  gdouble CS;
  guint i;
  guint num_frames, frames;
  guint num_int_samples = 0;    /* number of interleaved samples
                                 * ie. total count for all channels combined */
  gint channels, rate, bps;
  GValue v = G_VALUE_INIT;
  GValue va = G_VALUE_INIT;
  GValueArray *a;
  GstStructure *s;
  GstMessage *msg;
  GstClockTime duration, running_time;

  channels = GST_AUDIO_INFO_CHANNELS (&self->ainfo);
  bps = GST_AUDIO_INFO_BPS (&self->ainfo);
  rate = GST_AUDIO_INFO_RATE (&self->ainfo);

  gst_buffer_map (inbuf, &map, GST_MAP_READ);
  in_data = map.data;
  in_size = map.size;

  num_int_samples = in_size / bps;

  GST_LOG_OBJECT (self, "analyzing %u sample frames at ts %" GST_TIME_FORMAT,
      num_int_samples, GST_TIME_ARGS (GST_BUFFER_TIMESTAMP (inbuf)));

  g_return_val_if_fail (num_int_samples % channels == 0, NULL);

  num_frames = num_int_samples / channels;
  frames = num_frames;
  duration = GST_FRAMES_TO_CLOCK_TIME (frames, rate);
  if (num_frames > 0) {
    for (i = 0; i < channels; ++i) {
      self->process (in_data + (bps * i), num_int_samples, channels, &CS);
      GST_LOG_OBJECT (self,
          "[%d]: cumulative squares %lf, over %d samples/%d channels",
          i, CS, num_int_samples, channels);
      self->CS[i] += CS;
    }
    in_data += num_frames * bps;

    self->total_frames += num_frames;
  }
  running_time =
      self->first_time + gst_util_uint64_scale (self->total_frames, GST_SECOND,
      rate);

  a = g_value_array_new (channels);
  s = gst_structure_new ("videoframe-audiolevel", "running-time", G_TYPE_UINT64,
      running_time, "duration", G_TYPE_UINT64, duration, NULL);

  g_value_init (&v, G_TYPE_DOUBLE);
  g_value_init (&va, G_TYPE_VALUE_ARRAY);
  for (i = 0; i < channels; i++) {
    gdouble rms;
    if (frames == 0 || self->CS[i] == 0) {
      rms = 0;                  /* empty buffer */
    } else {
      rms = sqrt (self->CS[i] / frames);
    }
    self->CS[i] = 0.0;
    g_value_set_double (&v, rms);
    g_value_array_append (a, &v);
  }
  g_value_take_boxed (&va, a);
  gst_structure_take_value (s, "rms", &va);
  msg = gst_message_new_element (GST_OBJECT (self), s);

  gst_buffer_unmap (inbuf, &map);

  return msg;
}
Exemplo n.º 11
0
/******************************************************************************
 * gst_tiaudenc1_encode_thread
 *     Call the audio codec to process a full input buffer
 ******************************************************************************/
static void* gst_tiaudenc1_encode_thread(void *arg)
{
    GstTIAudenc1   *audenc1    = GST_TIAUDENC1(gst_object_ref(arg));
    void          *threadRet = GstTIThreadSuccess;
    Buffer_Handle  hDstBuf;
    Int32          encDataConsumed;
    GstBuffer     *encDataWindow = NULL;
    GstClockTime   encDataTime;
    Buffer_Handle  hEncDataWindow;
    GstBuffer     *outBuf;
    GstClockTime   sampleDuration;
    guint          sampleRate;
    guint          numSamples;
    Int            bufIdx;
    Int            ret;

    GST_LOG("starting audenc encode thread\n");

    /* Initialize codec engine */
    ret = gst_tiaudenc1_codec_start(audenc1);

    /* Notify main thread that it is ok to continue initialization */
    Rendezvous_meet(audenc1->waitOnEncodeThread);
    Rendezvous_reset(audenc1->waitOnEncodeThread);

    if (ret == FALSE) {
        GST_ELEMENT_ERROR(audenc1, RESOURCE, FAILED,
        ("Failed to start codec\n"), (NULL));
        goto thread_exit;
    }

    while (TRUE) {

        /* Obtain an raw data frame */
        encDataWindow  = gst_ticircbuffer_get_data(audenc1->circBuf);
        encDataTime    = GST_BUFFER_TIMESTAMP(encDataWindow);
        hEncDataWindow = GST_TIDMAIBUFFERTRANSPORT_DMAIBUF(encDataWindow);

        /* Check if there is enough encoded data to be sent to the codec.
         * The last frame of data may not be sufficient to meet the codec
         * requirements for the amount of input data.  If so just throw
         * away the last bit of data rather than filling with bogus
         * data.
         */
        if (GST_BUFFER_SIZE(encDataWindow) <
            Aenc1_getInBufSize(audenc1->hAe)) {
            GST_LOG("Not enough audio data remains\n");
            if (!audenc1->drainingEOS) {
                goto thread_failure;
            }
            goto thread_exit;
        }

        /* Obtain a free output buffer for the encoded data */
        if (!(hDstBuf = gst_tidmaibuftab_get_buf(audenc1->hOutBufTab))) {
            GST_ELEMENT_ERROR(audenc1, RESOURCE, READ,
                ("Failed to get a free contiguous buffer from BufTab\n"),
                (NULL));
            goto thread_exit;
        }

        /* Invoke the audio encoder */
        GST_LOG("Invoking the audio encoder at 0x%08lx with %u bytes\n",
            (unsigned long)Buffer_getUserPtr(hEncDataWindow),
            GST_BUFFER_SIZE(encDataWindow));
        ret             = Aenc1_process(audenc1->hAe, hEncDataWindow, hDstBuf);
        encDataConsumed = Buffer_getNumBytesUsed(hEncDataWindow);

        if (ret < 0) {
            GST_ELEMENT_ERROR(audenc1, STREAM, ENCODE,
            ("Failed to encode audio buffer\n"), (NULL));
            goto thread_failure;
        }

        /* If no encoded data was used we cannot find the next frame */
        if (ret == Dmai_EBITERROR && encDataConsumed == 0) {
            GST_ELEMENT_ERROR(audenc1, STREAM, ENCODE,
            ("Fatal bit error\n"), (NULL));
            goto thread_failure;
        }

        if (ret > 0) {
            GST_LOG("Aenc1_process returned success code %d\n", ret); 
        }

        sampleRate     = audenc1->samplefreq;
        numSamples     = encDataConsumed / (2 * audenc1->channels) ;
        sampleDuration = GST_FRAMES_TO_CLOCK_TIME(numSamples, sampleRate);

        /* Release the reference buffer, and tell the circular buffer how much
         * data was consumed.
         */
        ret = gst_ticircbuffer_data_consumed(audenc1->circBuf, encDataWindow,
                  encDataConsumed);
        encDataWindow = NULL;

        if (!ret) {
            goto thread_failure;
        }

        /* Set the source pad capabilities based on the encoded frame
         * properties.
         */
        gst_tiaudenc1_set_source_caps(audenc1);

        /* Create a DMAI transport buffer object to carry a DMAI buffer to
         * the source pad.  The transport buffer knows how to release the
         * buffer for re-use in this element when the source pad calls
         * gst_buffer_unref().
         */
        outBuf = gst_tidmaibuffertransport_new(hDstBuf, audenc1->hOutBufTab, NULL, NULL);
        gst_buffer_set_data(outBuf, GST_BUFFER_DATA(outBuf),
            Buffer_getNumBytesUsed(hDstBuf));
        gst_buffer_set_caps(outBuf, GST_PAD_CAPS(audenc1->srcpad));

        /* Set timestamp on output buffer */
        if (audenc1->genTimeStamps) {
            GST_BUFFER_DURATION(outBuf)     = sampleDuration;
            GST_BUFFER_TIMESTAMP(outBuf)    = encDataTime;
        }
        else {
            GST_BUFFER_TIMESTAMP(outBuf)    = GST_CLOCK_TIME_NONE;
        }

        /* Tell circular buffer how much time we consumed */
        gst_ticircbuffer_time_consumed(audenc1->circBuf, sampleDuration);

        /* Push the transport buffer to the source pad */
        GST_LOG("pushing buffer to source pad with timestamp : %"
                GST_TIME_FORMAT ", duration: %" GST_TIME_FORMAT,
                GST_TIME_ARGS (GST_BUFFER_TIMESTAMP(outBuf)),
                GST_TIME_ARGS (GST_BUFFER_DURATION(outBuf)));

        if (gst_pad_push(audenc1->srcpad, outBuf) != GST_FLOW_OK) {
            GST_DEBUG("push to source pad failed\n");
            goto thread_failure;
        }

        /* Release buffers no longer in use by the codec */
        Buffer_freeUseMask(hDstBuf, gst_tidmaibuffer_CODEC_FREE);
    }

thread_failure:

    gst_tithread_set_status(audenc1, TIThread_CODEC_ABORTED);
    gst_ticircbuffer_consumer_aborted(audenc1->circBuf);
    threadRet = GstTIThreadFailure;

thread_exit:

    /* Re-claim any buffers owned by the codec */
    bufIdx = BufTab_getNumBufs(GST_TIDMAIBUFTAB_BUFTAB(audenc1->hOutBufTab));

    while (bufIdx-- > 0) {
        Buffer_Handle hBuf = BufTab_getBuf(
            GST_TIDMAIBUFTAB_BUFTAB(audenc1->hOutBufTab), bufIdx);
        Buffer_freeUseMask(hBuf, gst_tidmaibuffer_CODEC_FREE);
    }

    /* Release the last buffer we retrieved from the circular buffer */
    if (encDataWindow) {
        gst_ticircbuffer_data_consumed(audenc1->circBuf, encDataWindow, 0);
    }

    /* We have to wait to shut down this thread until we can guarantee that
     * no more input buffers will be queued into the circular buffer
     * (we're about to delete it).  
     */
    Rendezvous_meet(audenc1->waitOnEncodeThread);
    Rendezvous_reset(audenc1->waitOnEncodeThread);

    /* Notify main thread that we are done draining before we shutdown the
     * codec, or we will hang.  We proceed in this order so the EOS event gets
     * propagated downstream before we attempt to shut down the codec.  The
     * codec-shutdown process will block until all BufTab buffers have been
     * released, and downstream-elements may hang on to buffers until
     * they get the EOS.
     */
    Rendezvous_force(audenc1->waitOnEncodeDrain);

    /* Initialize codec engine */
    if (gst_tiaudenc1_codec_stop(audenc1) < 0) {
        GST_ERROR("failed to stop codec\n");
        GST_ELEMENT_ERROR(audenc1, RESOURCE, FAILED,
        ("Failed to stop codec\n"), (NULL));
    }

    gst_object_unref(audenc1);

    GST_LOG("exit audio encode_thread (%d)\n", (int)threadRet);
    return threadRet;
}