gstreamer/gst/audiofx/audiowsincband.c

/* -*- c-basic-offset: 2 -*-
 * 
 * GStreamer
 * Copyright (C) 1999-2001 Erik Walthinsen <omega@cse.ogi.edu>
 *               2006 Dreamlab Technologies Ltd. <mathis.hofer@dreamlab.net>
 *               2007 Sebastian Dröge <slomo@circular-chaos.org>
 *
 * This library is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Library General Public
 * License as published by the Free Software Foundation; either
 * version 2 of the License, or (at your option) any later version.
 *
 * This library is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * Library General Public License for more details.
 *
 * You should have received a copy of the GNU Library General Public
 * License along with this library; if not, write to the
 * Free Software Foundation, Inc., 59 Temple Place - Suite 330,
 * Boston, MA 02111-1307, USA.
 * 
 * 
 * this windowed sinc filter is taken from the freely downloadable DSP book,
 * "The Scientist and Engineer's Guide to Digital Signal Processing",
 * chapter 16
 * available at http://www.dspguide.com/
 *
 * TODO:  - Implement the convolution in place, probably only makes sense
 *          when using FFT convolution as currently the convolution itself
 *          is probably the bottleneck
 *        - Maybe allow cascading the filter to get a better stopband attenuation.
 *          Can be done by convolving a filter kernel with itself
 *        - Drop the first kernel_length/2 samples and append the same number of
 *          samples on EOS as the first few samples are essentialy zero.
 */

/**
 * SECTION:element-audiowsincband
 * @short_description: Windowed Sinc band pass and band reject filter
 *
 * <refsect2>
 * <para>
 * Attenuates all frequencies outside (bandpass) or inside (bandreject) of a frequency
 * band. The length parameter controls the rolloff, the window parameter
 * controls rolloff and stopband attenuation. The Hamming window provides a faster rolloff but a bit
 * worse stopband attenuation, the other way around for the Blackman window.
 * </para>
 * <para>
 * This element has the advantage over the Chebyshev bandpass and bandreject filter that it has
 * a much better rolloff when using a larger kernel size and almost linear phase. The only
 * disadvantage is the much slower execution time with larger kernels.
 * </para>
 * <title>Example launch line</title>
 * <para>
 * <programlisting>
 * gst-launch audiotestsrc freq=1500 ! audioconvert ! audiosincband mode=band-pass lower-frequency=3000 upper-frequency=10000 length=501 window=blackman ! audioconvert ! alsasink
 * gst-launch filesrc location="melo1.ogg" ! oggdemux ! vorbisdec ! audioconvert ! audiowsincband mode=band-reject lower-frequency=59 upper-frequency=61 length=10001 window=hamming ! audioconvert ! alsasink
 * gst-launch audiotestsrc wave=white-noise ! audioconvert ! audiowsincband mode=band-pass lower-frequency=1000 upper-frequency=2000 length=31 ! audioconvert ! alsasink
 * </programlisting>
 * </para>
 * </refsect2>
 */

#ifdef HAVE_CONFIG_H
#include "config.h"
#endif

#include <string.h>
#include <math.h>
#include <gst/gst.h>
#include <gst/audio/gstaudiofilter.h>
#include <gst/controller/gstcontroller.h>

#include "audiowsincband.h"

#define GST_CAT_DEFAULT gst_audio_wsincband_debug
GST_DEBUG_CATEGORY_STATIC (GST_CAT_DEFAULT);

static const GstElementDetails audio_wsincband_details =
GST_ELEMENT_DETAILS ("Band pass & band reject filter",
    "Filter/Effect/Audio",
    "Band pass and band reject windowed sinc filter",
    "Thomas <thomas@apestaart.org>, "
    "Steven W. Smith, "
    "Dreamlab Technologies Ltd. <mathis.hofer@dreamlab.net>, "
    "Sebastian Dröge <slomo@circular-chaos.org>");

/* Filter signals and args */
enum
{
  /* FILL ME */
  LAST_SIGNAL
};

enum
{
  PROP_0,
  PROP_LENGTH,
  PROP_LOWER_FREQUENCY,
  PROP_UPPER_FREQUENCY,
  PROP_MODE,
  PROP_WINDOW
};

enum
{
  MODE_BAND_PASS = 0,
  MODE_BAND_REJECT
};

#define GST_TYPE_AUDIO_WSINC_BAND_MODE (gst_audio_wsincband_mode_get_type ())
static GType
gst_audio_wsincband_mode_get_type (void)
{
  static GType gtype = 0;

  if (gtype == 0) {
    static const GEnumValue values[] = {
      {MODE_BAND_PASS, "Band pass (default)",
          "band-pass"},
      {MODE_BAND_REJECT, "Band reject",
          "band-reject"},
      {0, NULL, NULL}
    };

    gtype = g_enum_register_static ("GstAudioWSincBandMode", values);
  }
  return gtype;
}

enum
{
  WINDOW_HAMMING = 0,
  WINDOW_BLACKMAN
};

#define GST_TYPE_AUDIO_WSINC_BAND_WINDOW (gst_audio_wsincband_window_get_type ())
static GType
gst_audio_wsincband_window_get_type (void)
{
  static GType gtype = 0;

  if (gtype == 0) {
    static const GEnumValue values[] = {
      {WINDOW_HAMMING, "Hamming window (default)",
          "hamming"},
      {WINDOW_BLACKMAN, "Blackman window",
          "blackman"},
      {0, NULL, NULL}
    };

    gtype = g_enum_register_static ("GstAudioWSincBandWindow", values);
  }
  return gtype;
}

#define ALLOWED_CAPS \
    "audio/x-raw-float, "                                             \
    " width = (int) { 32, 64 }, "                                     \
    " endianness = (int) BYTE_ORDER, "                                \
    " rate = (int) [ 1, MAX ], "                                      \
    " channels = (int) [ 1, MAX ] "

#define DEBUG_INIT(bla) \
  GST_DEBUG_CATEGORY_INIT (gst_audio_wsincband_debug, "audiowsincband", 0, \
      "Band-pass and Band-reject Windowed sinc filter plugin");

GST_BOILERPLATE_FULL (GstAudioWSincBand, audio_wsincband, GstAudioFilter,
    GST_TYPE_AUDIO_FILTER, DEBUG_INIT);

static void audio_wsincband_set_property (GObject * object, guint prop_id,
    const GValue * value, GParamSpec * pspec);
static void audio_wsincband_get_property (GObject * object, guint prop_id,
    GValue * value, GParamSpec * pspec);

static GstFlowReturn audio_wsincband_transform (GstBaseTransform * base,
    GstBuffer * inbuf, GstBuffer * outbuf);
static gboolean audio_wsincband_start (GstBaseTransform * base);
static gboolean audio_wsincband_event (GstBaseTransform * base,
    GstEvent * event);

static gboolean audio_wsincband_setup (GstAudioFilter * base,
    GstRingBufferSpec * format);

static gboolean audio_wsincband_query (GstPad * pad, GstQuery * query);
static const GstQueryType *audio_wsincband_query_type (GstPad * pad);

/* Element class */

static void
audio_wsincband_dispose (GObject * object)
{
  GstAudioWSincBand *self = GST_AUDIO_WSINC_BAND (object);

  if (self->residue) {
    g_free (self->residue);
    self->residue = NULL;
  }

  if (self->kernel) {
    g_free (self->kernel);
    self->kernel = NULL;
  }

  G_OBJECT_CLASS (parent_class)->dispose (object);
}

static void
audio_wsincband_base_init (gpointer g_class)
{
  GstElementClass *element_class = GST_ELEMENT_CLASS (g_class);
  GstCaps *caps;

  gst_element_class_set_details (element_class, &audio_wsincband_details);

  caps = gst_caps_from_string (ALLOWED_CAPS);
  gst_audio_filter_class_add_pad_templates (GST_AUDIO_FILTER_CLASS (g_class),
      caps);
  gst_caps_unref (caps);
}

static void
audio_wsincband_class_init (GstAudioWSincBandClass * klass)
{
  GObjectClass *gobject_class;
  GstBaseTransformClass *trans_class;
  GstAudioFilterClass *filter_class;

  gobject_class = (GObjectClass *) klass;
  trans_class = (GstBaseTransformClass *) klass;
  filter_class = (GstAudioFilterClass *) klass;

  gobject_class->set_property = audio_wsincband_set_property;
  gobject_class->get_property = audio_wsincband_get_property;
  gobject_class->dispose = audio_wsincband_dispose;

  /* FIXME: Don't use the complete possible range but restrict the upper boundary
   * so automatically generated UIs can use a slider */
  g_object_class_install_property (gobject_class, PROP_LOWER_FREQUENCY,
      g_param_spec_float ("lower-frequency", "Lower Frequency",
          "Cut-off lower frequency (Hz)", 0.0, 100000.0, 0, G_PARAM_READWRITE));
  g_object_class_install_property (gobject_class, PROP_UPPER_FREQUENCY,
      g_param_spec_float ("upper-frequency", "Upper Frequency",
          "Cut-off upper frequency (Hz)", 0.0, 100000.0, 0, G_PARAM_READWRITE));
  g_object_class_install_property (gobject_class, PROP_LENGTH,
      g_param_spec_int ("length", "Length",
          "Filter kernel length, will be rounded to the next odd number",
          3, 50000, 101, G_PARAM_READWRITE));

  g_object_class_install_property (gobject_class, PROP_MODE,
      g_param_spec_enum ("mode", "Mode",
          "Band pass or band reject mode", GST_TYPE_AUDIO_WSINC_BAND_MODE,
          MODE_BAND_PASS, G_PARAM_READWRITE | GST_PARAM_CONTROLLABLE));

  g_object_class_install_property (gobject_class, PROP_WINDOW,
      g_param_spec_enum ("window", "Window",
          "Window function to use", GST_TYPE_AUDIO_WSINC_BAND_WINDOW,
          WINDOW_HAMMING, G_PARAM_READWRITE | GST_PARAM_CONTROLLABLE));

  trans_class->transform = GST_DEBUG_FUNCPTR (audio_wsincband_transform);
  trans_class->start = GST_DEBUG_FUNCPTR (audio_wsincband_start);
  trans_class->event = GST_DEBUG_FUNCPTR (audio_wsincband_event);
  filter_class->setup = GST_DEBUG_FUNCPTR (audio_wsincband_setup);
}

static void
audio_wsincband_init (GstAudioWSincBand * self,
    GstAudioWSincBandClass * g_class)
{
  self->kernel_length = 101;
  self->latency = 50;
  self->lower_frequency = 0.0;
  self->upper_frequency = 0.0;
  self->mode = MODE_BAND_PASS;
  self->window = WINDOW_HAMMING;
  self->kernel = NULL;
  self->have_kernel = FALSE;
  self->residue = NULL;

  self->residue_length = 0;
  self->next_ts = GST_CLOCK_TIME_NONE;
  self->next_off = GST_BUFFER_OFFSET_NONE;

  gst_pad_set_query_function (GST_BASE_TRANSFORM (self)->srcpad,
      audio_wsincband_query);
  gst_pad_set_query_type_function (GST_BASE_TRANSFORM (self)->srcpad,
      audio_wsincband_query_type);
}

#define DEFINE_PROCESS_FUNC(width,ctype) \
static void \
process_##width (GstAudioWSincBand * self, g##ctype * src, g##ctype * dst, guint input_samples) \
{ \
  gint kernel_length = self->kernel_length; \
  gint i, j, k, l; \
  gint channels = GST_AUDIO_FILTER (self)->format.channels; \
  gint res_start; \
  \
  /* convolution */ \
  for (i = 0; i < input_samples; i++) { \
    dst[i] = 0.0; \
    k = i % channels; \
    l = i / channels; \
    for (j = 0; j < kernel_length; j++) \
      if (l < j) \
        dst[i] += \
            self->residue[(kernel_length + l - j) * channels + \
            k] * self->kernel[j]; \
      else \
        dst[i] += src[(l - j) * channels + k] * self->kernel[j]; \
  } \
  \
  /* copy the tail of the current input buffer to the residue, while \
   * keeping parts of the residue if the input buffer is smaller than \
   * the kernel length */ \
  if (input_samples < kernel_length * channels) \
    res_start = kernel_length * channels - input_samples; \
  else \
    res_start = 0; \
  \
  for (i = 0; i < res_start; i++) \
    self->residue[i] = self->residue[i + input_samples]; \
  for (i = res_start; i < kernel_length * channels; i++) \
    self->residue[i] = src[input_samples - kernel_length * channels + i]; \
  \
  self->residue_length += kernel_length * channels - res_start; \
  if (self->residue_length > kernel_length * channels) \
    self->residue_length = kernel_length * channels; \
}

DEFINE_PROCESS_FUNC (32, float);
DEFINE_PROCESS_FUNC (64, double);

#undef DEFINE_PROCESS_FUNC

static void
audio_wsincband_build_kernel (GstAudioWSincBand * self)
{
  gint i = 0;
  gdouble sum = 0.0;
  gint len = 0;
  gdouble *kernel_lp, *kernel_hp;
  gdouble w;

  len = self->kernel_length;

  if (GST_AUDIO_FILTER (self)->format.rate == 0) {
    GST_DEBUG ("rate not set yet");
    return;
  }

  if (GST_AUDIO_FILTER (self)->format.channels == 0) {
    GST_DEBUG ("channels not set yet");
    return;
  }

  /* Clamp frequencies */
  self->lower_frequency =
      CLAMP (self->lower_frequency, 0.0,
      GST_AUDIO_FILTER (self)->format.rate / 2);
  self->upper_frequency =
      CLAMP (self->upper_frequency, 0.0,
      GST_AUDIO_FILTER (self)->format.rate / 2);
  if (self->lower_frequency > self->upper_frequency) {
    gint tmp = self->lower_frequency;

    self->lower_frequency = self->upper_frequency;
    self->upper_frequency = tmp;
  }

  GST_DEBUG ("audio_wsincband: initializing filter kernel of length %d "
      "with lower frequency %.2lf Hz "
      ", upper frequency %.2lf Hz for mode %s",
      len, self->lower_frequency, self->upper_frequency,
      (self->mode == MODE_BAND_PASS) ? "band-pass" : "band-reject");

  /* fill the lp kernel */
  w = 2 * M_PI * (self->lower_frequency / GST_AUDIO_FILTER (self)->format.rate);
  kernel_lp = g_new (gdouble, len);
  for (i = 0; i < len; ++i) {
    if (i == len / 2)
      kernel_lp[i] = w;
    else
      kernel_lp[i] = sin (w * (i - len / 2))
          / (i - len / 2);
    /* Windowing */
    if (self->window == WINDOW_HAMMING)
      kernel_lp[i] *= (0.54 - 0.46 * cos (2 * M_PI * i / len));
    else
      kernel_lp[i] *=
          (0.42 - 0.5 * cos (2 * M_PI * i / len) +
          0.08 * cos (4 * M_PI * i / len));
  }

  /* normalize for unity gain at DC */
  sum = 0.0;
  for (i = 0; i < len; ++i)
    sum += kernel_lp[i];
  for (i = 0; i < len; ++i)
    kernel_lp[i] /= sum;

  /* fill the hp kernel */
  w = 2 * M_PI * (self->upper_frequency / GST_AUDIO_FILTER (self)->format.rate);
  kernel_hp = g_new (gdouble, len);
  for (i = 0; i < len; ++i) {
    if (i == len / 2)
      kernel_hp[i] = w;
    else
      kernel_hp[i] = sin (w * (i - len / 2))
          / (i - len / 2);
    /* Windowing */
    if (self->window == WINDOW_HAMMING)
      kernel_hp[i] *= (0.54 - 0.46 * cos (2 * M_PI * i / len));
    else
      kernel_hp[i] *=
          (0.42 - 0.5 * cos (2 * M_PI * i / len) +
          0.08 * cos (4 * M_PI * i / len));
  }

  /* normalize for unity gain at DC */
  sum = 0.0;
  for (i = 0; i < len; ++i)
    sum += kernel_hp[i];
  for (i = 0; i < len; ++i)
    kernel_hp[i] /= sum;

  /* do spectral inversion to go from lowpass to highpass */
  for (i = 0; i < len; ++i)
    kernel_hp[i] = -kernel_hp[i];
  kernel_hp[len / 2] += 1;

  /* combine the two kernels */
  if (self->kernel)
    g_free (self->kernel);
  self->kernel = g_new (gdouble, len);

  for (i = 0; i < len; ++i)
    self->kernel[i] = kernel_lp[i] + kernel_hp[i];

  /* free the helper kernels */
  g_free (kernel_lp);
  g_free (kernel_hp);

  /* do spectral inversion to go from bandreject to bandpass
   * if specified */
  if (self->mode == MODE_BAND_PASS) {
    for (i = 0; i < len; ++i)
      self->kernel[i] = -self->kernel[i];
    self->kernel[len / 2] += 1;
  }

  /* set up the residue memory space */
  if (!self->residue) {
    self->residue =
        g_new0 (gdouble, len * GST_AUDIO_FILTER (self)->format.channels);
    self->residue_length = 0;
  }

  self->have_kernel = TRUE;
}

static void
audio_wsincband_push_residue (GstAudioWSincBand * self)
{
  GstBuffer *outbuf;
  GstFlowReturn res;
  gint rate = GST_AUDIO_FILTER (self)->format.rate;
  gint channels = GST_AUDIO_FILTER (self)->format.channels;
  gint outsize, outsamples;
  gint diffsize, diffsamples;
  guint8 *in, *out;

  /* Calculate the number of samples and their memory size that
   * should be pushed from the residue */
  outsamples = MIN (self->latency, self->residue_length / channels);
  outsize = outsamples * channels * (GST_AUDIO_FILTER (self)->format.width / 8);
  if (outsize == 0)
    return;

  /* Process the difference between latency and residue_length samples
   * to start at the actual data instead of starting at the zeros before
   * when we only got one buffer smaller than latency */
  diffsamples = self->latency - self->residue_length / channels;
  diffsize =
      diffsamples * channels * (GST_AUDIO_FILTER (self)->format.width / 8);
  if (diffsize > 0) {
    in = g_new0 (guint8, diffsize);
    out = g_new0 (guint8, diffsize);
    self->process (self, in, out, diffsamples * channels);
    g_free (in);
    g_free (out);
  }

  res = gst_pad_alloc_buffer (GST_BASE_TRANSFORM (self)->srcpad,
      GST_BUFFER_OFFSET_NONE, outsize,
      GST_PAD_CAPS (GST_BASE_TRANSFORM (self)->srcpad), &outbuf);

  if (G_UNLIKELY (res != GST_FLOW_OK)) {
    GST_WARNING_OBJECT (self, "failed allocating buffer of %d bytes", outsize);
    return;
  }

  /* Convolve the residue with zeros to get the actual remaining data */
  in = g_new0 (guint8, outsize);
  self->process (self, in, GST_BUFFER_DATA (outbuf), outsamples * channels);
  g_free (in);

  /* Set timestamp, offset, etc from the values we
   * saved when processing the regular buffers */
  if (GST_CLOCK_TIME_IS_VALID (self->next_ts))
    GST_BUFFER_TIMESTAMP (outbuf) = self->next_ts;
  else
    GST_BUFFER_TIMESTAMP (outbuf) = 0;
  GST_BUFFER_DURATION (outbuf) =
      gst_util_uint64_scale (outsamples, GST_SECOND, rate);
  self->next_ts += gst_util_uint64_scale (outsamples, GST_SECOND, rate);

  if (self->next_off != GST_BUFFER_OFFSET_NONE) {
    GST_BUFFER_OFFSET (outbuf) = self->next_off;
    GST_BUFFER_OFFSET_END (outbuf) = self->next_off + outsamples;
  }

  GST_DEBUG_OBJECT (self, "Pushing residue buffer of size %d with timestamp: %"
      GST_TIME_FORMAT ", duration: %" GST_TIME_FORMAT ", offset: %lld,"
      " offset_end: %lld, nsamples: %d", GST_BUFFER_SIZE (outbuf),
      GST_TIME_ARGS (GST_BUFFER_TIMESTAMP (outbuf)),
      GST_TIME_ARGS (GST_BUFFER_DURATION (outbuf)), GST_BUFFER_OFFSET (outbuf),
      GST_BUFFER_OFFSET_END (outbuf), outsamples);

  res = gst_pad_push (GST_BASE_TRANSFORM (self)->srcpad, outbuf);

  if (G_UNLIKELY (res != GST_FLOW_OK)) {
    GST_WARNING_OBJECT (self, "failed to push residue");
  }

}

/* GstAudioFilter vmethod implementations */

/* get notified of caps and plug in the correct process function */
static gboolean
audio_wsincband_setup (GstAudioFilter * base, GstRingBufferSpec * format)
{
  GstAudioWSincBand *self = GST_AUDIO_WSINC_BAND (base);

  gboolean ret = TRUE;

  if (format->width == 32)
    self->process = (GstAudioWSincBandProcessFunc) process_32;
  else if (format->width == 64)
    self->process = (GstAudioWSincBandProcessFunc) process_64;
  else
    ret = FALSE;

  self->have_kernel = FALSE;

  return TRUE;
}

/* GstBaseTransform vmethod implementations */

static GstFlowReturn
audio_wsincband_transform (GstBaseTransform * base, GstBuffer * inbuf,
    GstBuffer * outbuf)
{
  GstAudioWSincBand *self = GST_AUDIO_WSINC_BAND (base);
  GstClockTime timestamp;
  gint channels = GST_AUDIO_FILTER (self)->format.channels;
  gint rate = GST_AUDIO_FILTER (self)->format.rate;
  gint input_samples =
      GST_BUFFER_SIZE (outbuf) / (GST_AUDIO_FILTER (self)->format.width / 8);
  gint output_samples = input_samples;
  gint diff;

  /* FIXME: subdivide GST_BUFFER_SIZE into small chunks for smooth fades */
  timestamp = GST_BUFFER_TIMESTAMP (outbuf);
  if (GST_CLOCK_TIME_IS_VALID (timestamp))
    gst_object_sync_values (G_OBJECT (self), timestamp);

  if (!self->have_kernel)
    audio_wsincband_build_kernel (self);

  /* Reset the residue if already existing on discont buffers */
  if (GST_BUFFER_IS_DISCONT (inbuf)) {
    if (channels && self->residue)
      memset (self->residue, 0, channels *
          self->kernel_length * sizeof (gdouble));
    self->residue_length = 0;
    self->next_ts = GST_CLOCK_TIME_NONE;
    self->next_off = GST_BUFFER_OFFSET_NONE;
  }

  /* Calculate the number of samples we can push out now without outputting
   * kernel_length/2 zeros in the beginning */
  diff = (self->kernel_length / 2) * channels - self->residue_length;
  if (diff > 0)
    output_samples -= diff;

  self->process (self, GST_BUFFER_DATA (inbuf), GST_BUFFER_DATA (outbuf),
      input_samples);

  if (output_samples <= 0) {
    /* Drop buffer and save original timestamp/offset for later use */
    if (!GST_CLOCK_TIME_IS_VALID (self->next_ts)
        && GST_BUFFER_TIMESTAMP_IS_VALID (outbuf))
      self->next_ts = GST_BUFFER_TIMESTAMP (outbuf);
    if (self->next_off == GST_BUFFER_OFFSET_NONE
        && GST_BUFFER_OFFSET_IS_VALID (outbuf))
      self->next_off = GST_BUFFER_OFFSET (outbuf);
    return GST_BASE_TRANSFORM_FLOW_DROPPED;
  } else if (output_samples < input_samples) {
    /* First (probably partial) buffer after starting from
     * a clean residue. Use stored timestamp/offset here */
    if (GST_CLOCK_TIME_IS_VALID (self->next_ts))
      GST_BUFFER_TIMESTAMP (outbuf) = self->next_ts;

    if (self->next_off != GST_BUFFER_OFFSET_NONE) {
      GST_BUFFER_OFFSET (outbuf) = self->next_off;
      if (GST_BUFFER_OFFSET_END_IS_VALID (outbuf))
        GST_BUFFER_OFFSET_END (outbuf) =
            self->next_off + output_samples / channels;
    } else {
      /* We dropped no buffer, offset is valid, offset_end must be adjusted by diff */
      if (GST_BUFFER_OFFSET_END_IS_VALID (outbuf))
        GST_BUFFER_OFFSET_END (outbuf) -= diff / channels;
    }

    if (GST_BUFFER_DURATION_IS_VALID (outbuf))
      GST_BUFFER_DURATION (outbuf) -=
          gst_util_uint64_scale (diff, GST_SECOND, channels * rate);

    GST_BUFFER_DATA (outbuf) +=
        diff * (GST_AUDIO_FILTER (self)->format.width / 8);
    GST_BUFFER_SIZE (outbuf) -=
        diff * (GST_AUDIO_FILTER (self)->format.width / 8);
  } else {
    GstClockTime ts_latency =
        gst_util_uint64_scale (self->latency, GST_SECOND, rate);

    /* Normal buffer, adjust timestamp/offset/etc by latency */
    if (GST_BUFFER_TIMESTAMP (outbuf) < ts_latency) {
      GST_WARNING_OBJECT (self, "GST_BUFFER_TIMESTAMP (outbuf) < latency");
      GST_BUFFER_TIMESTAMP (outbuf) = 0;
    } else {
      GST_BUFFER_TIMESTAMP (outbuf) -= ts_latency;
    }

    if (GST_BUFFER_OFFSET_IS_VALID (outbuf)) {
      if (GST_BUFFER_OFFSET (outbuf) > self->latency) {
        GST_BUFFER_OFFSET (outbuf) -= self->latency;
      } else {
        GST_WARNING_OBJECT (self, "GST_BUFFER_OFFSET (outbuf) < latency");
        GST_BUFFER_OFFSET (outbuf) = 0;
      }
    }

    if (GST_BUFFER_OFFSET_END_IS_VALID (outbuf)) {
      if (GST_BUFFER_OFFSET_END (outbuf) > self->latency) {
        GST_BUFFER_OFFSET_END (outbuf) -= self->latency;
      } else {
        GST_WARNING_OBJECT (self, "GST_BUFFER_OFFSET_END (outbuf) < latency");
        GST_BUFFER_OFFSET_END (outbuf) = 0;
      }
    }
  }

  GST_DEBUG_OBJECT (self, "Pushing buffer of size %d with timestamp: %"
      GST_TIME_FORMAT ", duration: %" GST_TIME_FORMAT ", offset: %lld,"
      " offset_end: %lld, nsamples: %d", GST_BUFFER_SIZE (outbuf),
      GST_TIME_ARGS (GST_BUFFER_TIMESTAMP (outbuf)),
      GST_TIME_ARGS (GST_BUFFER_DURATION (outbuf)), GST_BUFFER_OFFSET (outbuf),
      GST_BUFFER_OFFSET_END (outbuf), output_samples / channels);

  self->next_ts = GST_BUFFER_TIMESTAMP (outbuf) + GST_BUFFER_DURATION (outbuf);
  self->next_off = GST_BUFFER_OFFSET_END (outbuf);

  return GST_FLOW_OK;
}

static gboolean
audio_wsincband_start (GstBaseTransform * base)
{
  GstAudioWSincBand *self = GST_AUDIO_WSINC_BAND (base);
  gint channels = GST_AUDIO_FILTER (self)->format.channels;

  /* Reset the residue if already existing */
  if (channels && self->residue)
    memset (self->residue, 0, channels *
        self->kernel_length * sizeof (gdouble));

  self->residue_length = 0;
  self->next_ts = GST_CLOCK_TIME_NONE;
  self->next_off = GST_BUFFER_OFFSET_NONE;

  return TRUE;
}

static gboolean
audio_wsincband_query (GstPad * pad, GstQuery * query)
{
  GstAudioWSincBand *self = GST_AUDIO_WSINC_BAND (gst_pad_get_parent (pad));
  gboolean res = TRUE;

  switch (GST_QUERY_TYPE (query)) {
    case GST_QUERY_LATENCY:
    {
      GstClockTime min, max;
      gboolean live;
      guint64 latency;
      GstPad *peer;
      gint rate = GST_AUDIO_FILTER (self)->format.rate;

      if ((peer = gst_pad_get_peer (GST_BASE_TRANSFORM (self)->sinkpad))) {
        if ((res = gst_pad_query (peer, query))) {
          gst_query_parse_latency (query, &live, &min, &max);

          GST_DEBUG_OBJECT (self, "Peer latency: min %"
              GST_TIME_FORMAT " max %" GST_TIME_FORMAT,
              GST_TIME_ARGS (min), GST_TIME_ARGS (max));

          /* add our own latency */
          latency =
              (rate != 0) ? gst_util_uint64_scale (self->latency, GST_SECOND,
              rate) : 0;

          GST_DEBUG_OBJECT (self, "Our latency: %"
              GST_TIME_FORMAT, GST_TIME_ARGS (latency));

          min += latency;
          if (max != GST_CLOCK_TIME_NONE)
            max += latency;

          GST_DEBUG_OBJECT (self, "Calculated total latency : min %"
              GST_TIME_FORMAT " max %" GST_TIME_FORMAT,
              GST_TIME_ARGS (min), GST_TIME_ARGS (max));

          gst_query_set_latency (query, live, min, max);
        }
        gst_object_unref (peer);
      }
      break;
    }
    default:
      res = gst_pad_query_default (pad, query);
      break;
  }
  gst_object_unref (self);
  return res;
}

static const GstQueryType *
audio_wsincband_query_type (GstPad * pad)
{
  static const GstQueryType types[] = {
    GST_QUERY_LATENCY,
    0
  };

  return types;
}

static gboolean
audio_wsincband_event (GstBaseTransform * base, GstEvent * event)
{
  GstAudioWSincBand *self = GST_AUDIO_WSINC_BAND (base);

  switch (GST_EVENT_TYPE (event)) {
    case GST_EVENT_EOS:
      audio_wsincband_push_residue (self);
      break;
    default:
      break;
  }

  return GST_BASE_TRANSFORM_CLASS (parent_class)->event (base, event);
}

static void
audio_wsincband_set_property (GObject * object, guint prop_id,
    const GValue * value, GParamSpec * pspec)
{
  GstAudioWSincBand *self = GST_AUDIO_WSINC_BAND (object);

  g_return_if_fail (GST_IS_AUDIO_WSINC_BAND (self));

  switch (prop_id) {
    case PROP_LENGTH:{
      gint val;

      GST_BASE_TRANSFORM_LOCK (self);
      val = g_value_get_int (value);
      if (val % 2 == 0)
        val++;

      if (val != self->kernel_length) {
        if (self->residue) {
          audio_wsincband_push_residue (self);
          g_free (self->residue);
          self->residue = NULL;
        }
        self->kernel_length = val;
        self->latency = val / 2;
        audio_wsincband_build_kernel (self);
        gst_element_post_message (GST_ELEMENT (self),
            gst_message_new_latency (GST_OBJECT (self)));
      }
      GST_BASE_TRANSFORM_UNLOCK (self);
      break;
    }
    case PROP_LOWER_FREQUENCY:
      GST_BASE_TRANSFORM_LOCK (self);
      self->lower_frequency = g_value_get_float (value);
      audio_wsincband_build_kernel (self);
      GST_BASE_TRANSFORM_UNLOCK (self);
      break;
    case PROP_UPPER_FREQUENCY:
      GST_BASE_TRANSFORM_LOCK (self);
      self->upper_frequency = g_value_get_float (value);
      audio_wsincband_build_kernel (self);
      GST_BASE_TRANSFORM_UNLOCK (self);
      break;
    case PROP_MODE:
      GST_BASE_TRANSFORM_LOCK (self);
      self->mode = g_value_get_enum (value);
      audio_wsincband_build_kernel (self);
      GST_BASE_TRANSFORM_UNLOCK (self);
      break;
    case PROP_WINDOW:
      GST_BASE_TRANSFORM_LOCK (self);
      self->window = g_value_get_enum (value);
      audio_wsincband_build_kernel (self);
      GST_BASE_TRANSFORM_UNLOCK (self);
      break;
    default:
      G_OBJECT_WARN_INVALID_PROPERTY_ID (object, prop_id, pspec);
      break;
  }
}

static void
audio_wsincband_get_property (GObject * object, guint prop_id, GValue * value,
    GParamSpec * pspec)
{
  GstAudioWSincBand *self = GST_AUDIO_WSINC_BAND (object);

  switch (prop_id) {
    case PROP_LENGTH:
      g_value_set_int (value, self->kernel_length);
      break;
    case PROP_LOWER_FREQUENCY:
      g_value_set_float (value, self->lower_frequency);
      break;
    case PROP_UPPER_FREQUENCY:
      g_value_set_float (value, self->upper_frequency);
      break;
    case PROP_MODE:
      g_value_set_enum (value, self->mode);
      break;
    case PROP_WINDOW:
      g_value_set_enum (value, self->window);
      break;
    default:
      G_OBJECT_WARN_INVALID_PROPERTY_ID (object, prop_id, pspec);
      break;
  }
}