// sgmm2bin/sgmm2-rescore-lattice.cc // Copyright 2009-2012 Saarland University (Author: Arnab Ghoshal) // Johns Hopkins University (Author: Daniel Povey) // Cisco Systems (Author: Neha Agrawal) // 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 "util/stl-utils.h" #include "sgmm2/am-sgmm2.h" #include "hmm/transition-model.h" #include "fstext/fstext-lib.h" #include "lat/kaldi-lattice.h" #include "lat/lattice-functions.h" #include "sgmm2/decodable-am-sgmm2.h" int main(int argc, char *argv[]) { try { using namespace kaldi; typedef kaldi::int32 int32; typedef kaldi::int64 int64; using fst::SymbolTable; using fst::VectorFst; using fst::StdArc; const char *usage = "Replace the acoustic scores on a lattice using a new model.\n" "Usage: sgmm2-rescore-lattice [options]

" "

\n" " e.g.: sgmm2-rescore-lattice 1.mdl ark:1.lats scp:trn.scp ark:2.lats\n"; kaldi::BaseFloat old_acoustic_scale = 0.0; bool speedup = false; BaseFloat log_prune = 5.0; std::string gselect_rspecifier, spkvecs_rspecifier, utt2spk_rspecifier; kaldi::ParseOptions po(usage); po.Register("old-acoustic-scale", &old_acoustic_scale, "Add the current acoustic scores with some scale."); po.Register("log-prune", &log_prune, "Pruning beam used to reduce number of exp() evaluations."); po.Register("spk-vecs", &spkvecs_rspecifier, "Speaker vectors (rspecifier)"); po.Register("utt2spk", &utt2spk_rspecifier, "rspecifier for utterance to speaker map"); po.Register("gselect", &gselect_rspecifier, "Precomputed Gaussian indices (rspecifier)"); po.Register("speedup", &speedup, "If true, enable a faster version of the computation that " "saves times when there is only one pdf-id on a single frame " "by only sometimes (randomly) computing the probabilities, and " "then scaling them up to preserve corpus-level diagnostics."); po.Read(argc, argv); if (po.NumArgs() != 4) { po.PrintUsage(); exit(1); } if (gselect_rspecifier == "") KALDI_ERR << "--gselect-rspecifier option is required."; std::string model_filename = po.GetArg(1), lats_rspecifier = po.GetArg(2), feature_rspecifier = po.GetArg(3), lats_wspecifier = po.GetArg(4); AmSgmm2 am_sgmm; TransitionModel trans_model; { bool binary; Input ki(model_filename, &binary); trans_model.Read(ki.Stream(), binary); am_sgmm.Read(ki.Stream(), binary); } RandomAccessInt32VectorVectorReader gselect_reader(gselect_rspecifier); RandomAccessBaseFloatVectorReaderMapped spkvecs_reader(spkvecs_rspecifier, utt2spk_rspecifier); RandomAccessBaseFloatMatrixReader feature_reader(feature_rspecifier); // Read as compact lattice SequentialCompactLatticeReader compact_lattice_reader(lats_rspecifier); // Write as compact lattice. CompactLatticeWriter compact_lattice_writer(lats_wspecifier); int32 num_done = 0, num_err = 0; for (; !compact_lattice_reader.Done(); compact_lattice_reader.Next()) { std::string utt = compact_lattice_reader.Key(); if (!feature_reader.HasKey(utt)) { KALDI_WARN << "No feature found for utterance " << utt; num_err++; continue; } CompactLattice clat = compact_lattice_reader.Value(); compact_lattice_reader.FreeCurrent(); if (old_acoustic_scale != 1.0) fst::ScaleLattice(fst::AcousticLatticeScale(old_acoustic_scale), &clat); const Matrix &feats = feature_reader.Value(utt); // Get speaker vectors Sgmm2PerSpkDerivedVars spk_vars; if (spkvecs_reader.IsOpen()) { if (spkvecs_reader.HasKey(utt)) { spk_vars.SetSpeakerVector(spkvecs_reader.Value(utt)); am_sgmm.ComputePerSpkDerivedVars(&spk_vars); } else { KALDI_WARN << "Cannot find speaker vector for " << utt; num_err++; continue; } } // else spk_vars is "empty" if (!gselect_reader.HasKey(utt) || gselect_reader.Value(utt).size() != feats.NumRows()) { KALDI_WARN << "No Gaussian-selection info available for utterance " << utt << " (or wrong size)"; num_err++; continue; } const std::vector > &gselect = gselect_reader.Value(utt); DecodableAmSgmm2 sgmm2_decodable(am_sgmm, trans_model, feats, gselect, log_prune, &spk_vars); if (!speedup) { if (kaldi::RescoreCompactLattice(&sgmm2_decodable, &clat)) { compact_lattice_writer.Write(utt, clat); num_done++; } else num_err++; } else { BaseFloat speedup_factor = 100.0; if (kaldi::RescoreCompactLatticeSpeedup(trans_model, speedup_factor, &sgmm2_decodable, &clat)) { compact_lattice_writer.Write(utt, clat); num_done++; } else num_err++; } } KALDI_LOG << "Done " << num_done << " lattices, errors on " << num_err; return (num_done != 0 ? 0 : 1); } catch(const std::exception &e) { std::cerr << e.what(); return -1; } }