// sherpa-onnx/csrc/online-transducer-modified-beam-search-decoder.cc // // Copyright (c) 2023 Pingfeng Luo // Copyright (c) 2023 Xiaomi Corporation #include "sherpa-onnx/csrc/online-transducer-modified-beam-search-decoder.h" #include #include #include #include "sherpa-onnx/csrc/log.h" #include "sherpa-onnx/csrc/onnx-utils.h" namespace sherpa_onnx { static void UseCachedDecoderOut( const std::vector &hyps_row_splits, const std::vector &results, int32_t context_size, Ort::Value *decoder_out) { std::vector shape = decoder_out->GetTensorTypeAndShapeInfo().GetShape(); float *dst = decoder_out->GetTensorMutableData(); int32_t batch_size = static_cast(results.size()); for (int32_t i = 0; i != batch_size; ++i) { int32_t num_hyps = hyps_row_splits[i + 1] - hyps_row_splits[i]; if (num_hyps > 1 || !results[i].decoder_out) { dst += num_hyps * shape[1]; continue; } const float *src = results[i].decoder_out.GetTensorData(); std::copy(src, src + shape[1], dst); dst += shape[1]; } } OnlineTransducerDecoderResult OnlineTransducerModifiedBeamSearchDecoder::GetEmptyResult() const { int32_t context_size = model_->ContextSize(); int32_t blank_id = 0; // always 0 OnlineTransducerDecoderResult r; std::vector blanks(context_size, -1); blanks.back() = blank_id; Hypotheses blank_hyp({{blanks, 0}}); r.hyps = std::move(blank_hyp); r.tokens = std::move(blanks); return r; } void OnlineTransducerModifiedBeamSearchDecoder::StripLeadingBlanks( OnlineTransducerDecoderResult *r) const { int32_t context_size = model_->ContextSize(); auto hyp = r->hyps.GetMostProbable(true); std::vector tokens(hyp.ys.begin() + context_size, hyp.ys.end()); r->tokens = std::move(tokens); r->timestamps = std::move(hyp.timestamps); r->num_trailing_blanks = hyp.num_trailing_blanks; } void OnlineTransducerModifiedBeamSearchDecoder::Decode( Ort::Value encoder_out, std::vector *result) { Decode(std::move(encoder_out), nullptr, result); } void OnlineTransducerModifiedBeamSearchDecoder::Decode( Ort::Value encoder_out, OnlineStream **ss, std::vector *result) { std::vector encoder_out_shape = encoder_out.GetTensorTypeAndShapeInfo().GetShape(); if (encoder_out_shape[0] != result->size()) { fprintf(stderr, "Size mismatch! encoder_out.size(0) %d, result.size(0): %d\n", static_cast(encoder_out_shape[0]), static_cast(result->size())); exit(-1); } int32_t batch_size = static_cast(encoder_out_shape[0]); int32_t num_frames = static_cast(encoder_out_shape[1]); int32_t vocab_size = model_->VocabSize(); std::vector cur; for (auto &r : *result) { cur.push_back(std::move(r.hyps)); } std::vector prev; for (int32_t t = 0; t != num_frames; ++t) { // Due to merging paths with identical token sequences, // not all utterances have "num_active_paths" paths. auto hyps_row_splits = GetHypsRowSplits(cur); int32_t num_hyps = hyps_row_splits.back(); // total num hyps for all utterance prev.clear(); for (auto &hyps : cur) { for (auto &h : hyps) { prev.push_back(std::move(h.second)); } } cur.clear(); cur.reserve(batch_size); Ort::Value decoder_input = model_->BuildDecoderInput(prev); Ort::Value decoder_out = model_->RunDecoder(std::move(decoder_input)); if (t == 0) { UseCachedDecoderOut(hyps_row_splits, *result, model_->ContextSize(), &decoder_out); } Ort::Value cur_encoder_out = GetEncoderOutFrame(model_->Allocator(), &encoder_out, t); cur_encoder_out = Repeat(model_->Allocator(), &cur_encoder_out, hyps_row_splits); Ort::Value logit = model_->RunJoiner( std::move(cur_encoder_out), Clone(model_->Allocator(), &decoder_out)); float *p_logit = logit.GetTensorMutableData(); LogSoftmax(p_logit, vocab_size, num_hyps); // now p_logit contains log_softmax output, we rename it to p_logprob // to match what it actually contains float *p_logprob = p_logit; // add log_prob of each hypothesis to p_logprob before taking top_k for (int32_t i = 0; i != num_hyps; ++i) { float log_prob = prev[i].log_prob + prev[i].lm_log_prob; for (int32_t k = 0; k != vocab_size; ++k, ++p_logprob) { *p_logprob += log_prob; } } p_logprob = p_logit; // we changed p_logprob in the above for loop for (int32_t b = 0; b != batch_size; ++b) { int32_t frame_offset = (*result)[b].frame_offset; int32_t start = hyps_row_splits[b]; int32_t end = hyps_row_splits[b + 1]; auto topk = TopkIndex(p_logprob, vocab_size * (end - start), max_active_paths_); Hypotheses hyps; for (auto k : topk) { int32_t hyp_index = k / vocab_size + start; int32_t new_token = k % vocab_size; Hypothesis new_hyp = prev[hyp_index]; const float prev_lm_log_prob = new_hyp.lm_log_prob; float context_score = 0; auto context_state = new_hyp.context_state; // blank is hardcoded to 0 // also, it treats unk as blank if (new_token != 0 && new_token != unk_id_) { new_hyp.ys.push_back(new_token); new_hyp.timestamps.push_back(t + frame_offset); new_hyp.num_trailing_blanks = 0; if (ss != nullptr && ss[b]->GetContextGraph() != nullptr) { auto context_res = ss[b]->GetContextGraph()->ForwardOneStep( context_state, new_token); context_score = context_res.first; new_hyp.context_state = context_res.second; } if (lm_) { lm_->ComputeLMScore(lm_scale_, &new_hyp); } } else { ++new_hyp.num_trailing_blanks; } new_hyp.log_prob = p_logprob[k] + context_score - prev_lm_log_prob; // log_prob only includes the // score of the transducer hyps.Add(std::move(new_hyp)); } // for (auto k : topk) cur.push_back(std::move(hyps)); p_logprob += (end - start) * vocab_size; } // for (int32_t b = 0; b != batch_size; ++b) } for (int32_t b = 0; b != batch_size; ++b) { auto &hyps = cur[b]; auto best_hyp = hyps.GetMostProbable(true); auto &r = (*result)[b]; r.hyps = std::move(hyps); r.tokens = std::move(best_hyp.ys); r.num_trailing_blanks = best_hyp.num_trailing_blanks; r.frame_offset += num_frames; } } void OnlineTransducerModifiedBeamSearchDecoder::UpdateDecoderOut( OnlineTransducerDecoderResult *result) { if (result->tokens.size() == model_->ContextSize()) { result->decoder_out = Ort::Value{nullptr}; return; } Ort::Value decoder_input = model_->BuildDecoderInput({*result}); result->decoder_out = model_->RunDecoder(std::move(decoder_input)); } } // namespace sherpa_onnx