// online2bin/extend-wav-with-silence.cc
  
  // 2014  IMSL, PKU-HKUST (author: Wei Shi)
  // 2015  Tom Ko
  
  // See ../../COPYING for clarification regarding multiple authors
  //
  // 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
  //
  // THIS CODE IS PROVIDED *AS IS* BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
  // KIND, EITHER EXPRESS OR IMPLIED, INCLUDING WITHOUT LIMITATION ANY IMPLIED
  // WARRANTIES OR CONDITIONS OF TITLE, FITNESS FOR A PARTICULAR PURPOSE,
  // MERCHANTABLITY OR NON-INFRINGEMENT.
  // See the Apache 2 License for the specific language governing permissions and
  // limitations under the License.
  
  #include "base/kaldi-common.h"
  #include "util/common-utils.h"
  #include "feat/wave-reader.h"
  
  namespace kaldi{
  void FindQuietestSegment(const Vector<BaseFloat> &wav_in,
                           BaseFloat samp_rate,
                           Vector<BaseFloat> *wav_sil,
                           BaseFloat search_dur = 0.5,
                           BaseFloat seg_dur = 0.1,
                           BaseFloat seg_shift_dur = 0.05);
  
  void ExtendWaveWithSilence(const Vector<BaseFloat> &wav_in,
                             BaseFloat samp_rate,
                             Vector<BaseFloat> *wav_out,
                             BaseFloat sil_search_len,
                             BaseFloat sil_extract_len,
                             BaseFloat sil_extract_shift);
  
  }
  
  
  int main(int argc, char *argv[]) {
    try {
      typedef kaldi::int32 int32;
      using namespace kaldi;
      const char *usage =
          "Extend wave data with a fairly long silence at the end (e.g. 5 seconds).
  "
          "The input waveforms are assumed having silences at the begin/end and those
  "
          "segments are extracted and appended to the end of the utterance.
  "
          "Note this is for use in testing endpointing in decoding.
  "
          "
  "
          "Usage: extend-wav-with-silence [options] <wav-rspecifier> <wav-wspecifier>
  "
          "       extend-wav-with-silence [options] <wav-rxfilename> <wav-wxfilename>
  ";
  
      ParseOptions po(usage);
      BaseFloat sil_len = 5.0,
        sil_search_len = 0.5,
        sil_extract_len = 0.05,
        sil_extract_shift = 0.025;
      po.Register("extra-silence-length", &sil_len, "the length of silence that will be "
                  "appended to the end of each waveform, in seconds.");
      po.Register("silence-search-length", &sil_search_len, "the length at the beginning "
                  "or end of each waveform in which to search for the quietest segment of "
                  "silence, in seconds.");
      po.Register("silence-extract-length", &sil_extract_len, "the length of silence segments "
                  "to be extracted from the waveform, which must be smaller than silence-"
                  "search-length, in seconds.");
      po.Register("silence-extract-shift", &sil_extract_shift, "the shift length when searching "
                  "for segments of silences, typically samller than silence-extract-length, "
                  "in seconds.");
  
      po.Read(argc, argv);
  
      if (po.NumArgs() != 2) {
        po.PrintUsage();
        exit(1);
      }
  
      if (ClassifyRspecifier(po.GetArg(1), NULL, NULL) != kNoRspecifier) {
        SequentialTableReader<WaveHolder> reader(po.GetArg(1));
        TableWriter<WaveHolder> writer(po.GetArg(2));
        int32 num_success = 0;
  
        for(; !reader.Done(); reader.Next()){
          std::string wav_key = reader.Key();
          const WaveData &wave = reader.Value();
          BaseFloat samp_freq = wave.SampFreq();  // read sampling fequency
          const Matrix<BaseFloat> &wave_data = wave.Data();
          int32 num_chan = wave_data.NumRows(),       // number of channels in recording
            num_ext_samp  = (int32)(samp_freq * sil_len); // number of samples that will be extended
          KALDI_ASSERT(num_ext_samp > 0);
          Matrix<BaseFloat> new_wave(wave_data.NumRows(), wave_data.NumCols() + num_ext_samp);
          for(int32 i = 0; i < num_chan; i++){
            Vector<BaseFloat> wav_this_chan(wave_data.Row(i));
            Vector<BaseFloat> wav_extend(wav_this_chan.Dim() + num_ext_samp);
            ExtendWaveWithSilence(wav_this_chan, samp_freq, &wav_extend,
                                  sil_search_len, sil_extract_len, sil_extract_shift);
            KALDI_ASSERT(wav_extend.Dim() == wav_this_chan.Dim() + num_ext_samp);
            new_wave.CopyRowFromVec(wav_extend, i);
          }
          WaveData wave_out(samp_freq, new_wave);
          writer.Write(wav_key, wave_out);
          num_success++;
        }
        KALDI_LOG << "Successfully extended " << num_success << " files.";
        return 0;
      } else {
        std::string wav_rxfilename = po.GetArg(1);
        std::string wav_wxfilename = po.GetArg(2);
        bool binary = true;
        Input ki(wav_rxfilename, &binary);
        WaveHolder wh;
        if (!wh.Read(ki.Stream())) {
          KALDI_ERR << "Read failure from "
                    << PrintableRxfilename(wav_rxfilename);
        }
  
        const WaveData& wave = wh.Value();
  
        BaseFloat samp_freq = wave.SampFreq();  // read sampling fequency
        const Matrix<BaseFloat> &wave_data = wave.Data();
        int32 num_chan = wave_data.NumRows(),       // number of channels in recording
          num_ext_samp  = (int32)(samp_freq * sil_len); // number of samples that will be extended
        KALDI_ASSERT(num_ext_samp > 0);
        Matrix<BaseFloat> new_wave(wave_data.NumRows(), wave_data.NumCols() + num_ext_samp);
        for(int32 i = 0; i < num_chan; i++){
          Vector<BaseFloat> wav_this_chan(wave_data.Row(i));
          Vector<BaseFloat> wav_extend(wav_this_chan.Dim() + num_ext_samp);
          ExtendWaveWithSilence(wav_this_chan, samp_freq, &wav_extend,
                                sil_search_len, sil_extract_len, sil_extract_shift);
          KALDI_ASSERT(wav_extend.Dim() == wav_this_chan.Dim() + num_ext_samp);
          new_wave.CopyRowFromVec(wav_extend, i);
        }
        WaveData wave_out(samp_freq, new_wave);
  
        Output ko(wav_wxfilename, binary, false);
        if (!WaveHolder::Write(ko.Stream(), true, wave_out)) {
          KALDI_ERR << "Write failure to "
                    << PrintableWxfilename(wav_wxfilename);
        }
        // we do not print any log messages here
      }
    } catch(const std::exception &e) {
      std::cerr << e.what();
      return -1;
    }
  }
  
  namespace kaldi{
  
  void ExtendWaveWithSilence(const Vector<BaseFloat> &wav_in,
                             BaseFloat samp_rate,
                             Vector<BaseFloat> *wav_out,
                             BaseFloat sil_search_len,
                             BaseFloat sil_extract_len,
                             BaseFloat sil_extract_shift){
    Vector<BaseFloat> quietest_seg;
    FindQuietestSegment(wav_in, samp_rate, &quietest_seg,
                        sil_search_len, sil_extract_len, sil_extract_shift);
  
    int32 window_size = quietest_seg.Dim(),
      window_size_half = window_size / 2;
    KALDI_ASSERT(window_size > 0);
    Vector<BaseFloat> window(window_size);
    Vector<BaseFloat> windowed_silence(window_size);
    Vector<BaseFloat> half_window(window_size_half);
    for(int32 i = 0; i < window.Dim(); i++){
      BaseFloat i_fl = static_cast<BaseFloat>(i);
      window(i) = 0.54 - 0.46*cos(M_2PI * i_fl / (window_size-1));
    }
    half_window = window.Range(window_size_half, window_size_half);
    windowed_silence.AddVecVec(1.0, window, quietest_seg, 0.0);
  
    wav_out->Range(0, wav_in.Dim()).CopyFromVec(wav_in);
    SubVector<BaseFloat> wav_ext(*wav_out, wav_in.Dim() - window_size_half,
                                  wav_out->Dim() - wav_in.Dim() + window_size_half);
    for(int32 i = 0; i < window_size_half; i++)    // windowing the first half window
      wav_ext(i) *= half_window(i);
  
    int32 tmp_offset = 0;
    for(; tmp_offset + window_size < wav_ext.Dim();) {
      wav_ext.Range(tmp_offset, window_size).AddVec(1.0, windowed_silence);
      tmp_offset += window_size_half;
    }
  
    for(int32 i = tmp_offset; i < wav_ext.Dim(); i++)
      wav_ext(i) += windowed_silence(i-tmp_offset);
  
  }
  
  // Try to find the quietest seq_dur(default 0.1) second segment in the
  // search_dur(default 0.5) seconds at the beginning and the end
  // of input waveform by simply find a segment with the least energy.
  void FindQuietestSegment(const Vector<BaseFloat> &wav_in,
                           BaseFloat samp_rate,
                           Vector<BaseFloat> *wav_sil,
                           BaseFloat search_dur,
                           BaseFloat seg_dur,
                           BaseFloat seg_shift_dur){
    KALDI_ASSERT(seg_dur < search_dur);
  
    int32 search_len = (int32) (search_dur * samp_rate),
      seg_len = (int32) (seg_dur * samp_rate),
      seg_shift = (int32) (seg_shift_dur *samp_rate),
      start = 0;
    double min_energy;
    Vector<BaseFloat> wav_min_energy;
    Vector<BaseFloat> seg_tmp(wav_in.Range(0, seg_len));
    wav_min_energy = seg_tmp;
    min_energy = VecVec(seg_tmp, seg_tmp);
    for(start = 0; start + seg_len < search_len; ){
      SubVector<BaseFloat> seg_this(wav_in, start, seg_len);
      seg_tmp = seg_this;
      double energy_this = VecVec(seg_this, seg_this);
      if(energy_this < min_energy && energy_this > 0.0){
        min_energy = energy_this;
        wav_min_energy = seg_tmp;
      }
      start += seg_shift;
    }
  
    for(start = wav_in.Dim() - search_len; start + seg_len < wav_in.Dim(); ){
      SubVector<BaseFloat> seg_this(wav_in, start, seg_len);
      seg_tmp = seg_this;
      double energy_this = VecVec(seg_this, seg_this);
      if(energy_this < min_energy && energy_this > 0.0){
        min_energy = energy_this;
        wav_min_energy = seg_tmp;
      }
      start += seg_shift;
    }
  
    if (min_energy == 0.0) {
      KALDI_WARN << "Zero energy silence being used.";
    }
    *wav_sil = wav_min_energy;
  }
  
  }