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feat/1.12.5_mr_v100
enginex-mr_series-sherpa-onnx/sherpa-onnx/csrc/offline-transducer-nemo-model.cc
Fangjun Kuang f00066db88 Add C++ runtime for parakeet-tdt-0.6b-v2. (#2181)
2025-05-06 16:59:01 +08:00

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// sherpa-onnx/csrc/offline-transducer-nemo-model.cc
//
// Copyright (c) 2024 Xiaomi Corporation
#include "sherpa-onnx/csrc/offline-transducer-nemo-model.h"
#include <algorithm>
#include <string>
#include <utility>
#include <vector>
#if __ANDROID_API__ >= 9
#include "android/asset_manager.h"
#include "android/asset_manager_jni.h"
#endif
#if __OHOS__
#include "rawfile/raw_file_manager.h"
#endif
#include "sherpa-onnx/csrc/file-utils.h"
#include "sherpa-onnx/csrc/macros.h"
#include "sherpa-onnx/csrc/offline-transducer-decoder.h"
#include "sherpa-onnx/csrc/onnx-utils.h"
#include "sherpa-onnx/csrc/session.h"
#include "sherpa-onnx/csrc/transpose.h"
namespace sherpa_onnx {
class OfflineTransducerNeMoModel::Impl {
public:
explicit Impl(const OfflineModelConfig &config)
: config_(config),
env_(ORT_LOGGING_LEVEL_ERROR),
sess_opts_(GetSessionOptions(config)),
allocator_{} {
{
auto buf = ReadFile(config.transducer.encoder_filename);
InitEncoder(buf.data(), buf.size());
}
{
auto buf = ReadFile(config.transducer.decoder_filename);
InitDecoder(buf.data(), buf.size());
}
{
auto buf = ReadFile(config.transducer.joiner_filename);
InitJoiner(buf.data(), buf.size());
}
}
template <typename Manager>
Impl(Manager *mgr, const OfflineModelConfig &config)
: config_(config),
env_(ORT_LOGGING_LEVEL_ERROR),
sess_opts_(GetSessionOptions(config)),
allocator_{} {
{
auto buf = ReadFile(mgr, config.transducer.encoder_filename);
InitEncoder(buf.data(), buf.size());
}
{
auto buf = ReadFile(mgr, config.transducer.decoder_filename);
InitDecoder(buf.data(), buf.size());
}
{
auto buf = ReadFile(mgr, config.transducer.joiner_filename);
InitJoiner(buf.data(), buf.size());
}
}
std::vector<Ort::Value> RunEncoder(Ort::Value features,
Ort::Value features_length) {
// (B, T, C) -> (B, C, T)
features = Transpose12(allocator_, &features);
std::array<Ort::Value, 2> encoder_inputs = {std::move(features),
std::move(features_length)};
auto encoder_out = encoder_sess_->Run(
{}, encoder_input_names_ptr_.data(), encoder_inputs.data(),
encoder_inputs.size(), encoder_output_names_ptr_.data(),
encoder_output_names_ptr_.size());
return encoder_out;
}
std::pair<Ort::Value, std::vector<Ort::Value>> RunDecoder(
Ort::Value targets, Ort::Value targets_length,
std::vector<Ort::Value> states) {
std::vector<Ort::Value> decoder_inputs;
decoder_inputs.reserve(2 + states.size());
decoder_inputs.push_back(std::move(targets));
decoder_inputs.push_back(std::move(targets_length));
for (auto &s : states) {
decoder_inputs.push_back(std::move(s));
}
auto decoder_out = decoder_sess_->Run(
{}, decoder_input_names_ptr_.data(), decoder_inputs.data(),
decoder_inputs.size(), decoder_output_names_ptr_.data(),
decoder_output_names_ptr_.size());
std::vector<Ort::Value> states_next;
states_next.reserve(states.size());
// decoder_out[0]: decoder_output
// decoder_out[1]: decoder_output_length
// decoder_out[2:] states_next
for (int32_t i = 0; i != states.size(); ++i) {
states_next.push_back(std::move(decoder_out[i + 2]));
}
// we discard decoder_out[1]
return {std::move(decoder_out[0]), std::move(states_next)};
}
Ort::Value RunJoiner(Ort::Value encoder_out, Ort::Value decoder_out) {
std::array<Ort::Value, 2> joiner_input = {std::move(encoder_out),
std::move(decoder_out)};
auto logit = joiner_sess_->Run({}, joiner_input_names_ptr_.data(),
joiner_input.data(), joiner_input.size(),
joiner_output_names_ptr_.data(),
joiner_output_names_ptr_.size());
return std::move(logit[0]);
}
std::vector<Ort::Value> GetDecoderInitStates(int32_t batch_size) {
std::array<int64_t, 3> s0_shape{pred_rnn_layers_, batch_size, pred_hidden_};
Ort::Value s0 = Ort::Value::CreateTensor<float>(allocator_, s0_shape.data(),
s0_shape.size());
Fill<float>(&s0, 0);
std::array<int64_t, 3> s1_shape{pred_rnn_layers_, batch_size, pred_hidden_};
Ort::Value s1 = Ort::Value::CreateTensor<float>(allocator_, s1_shape.data(),
s1_shape.size());
Fill<float>(&s1, 0);
std::vector<Ort::Value> states;
states.reserve(2);
states.push_back(std::move(s0));
states.push_back(std::move(s1));
return states;
}
int32_t SubsamplingFactor() const { return subsampling_factor_; }
int32_t VocabSize() const { return vocab_size_; }
OrtAllocator *Allocator() { return allocator_; }
std::string FeatureNormalizationMethod() const { return normalize_type_; }
bool IsGigaAM() const { return is_giga_am_; }
int32_t FeatureDim() const { return feat_dim_; }
private:
void InitEncoder(void *model_data, size_t model_data_length) {
encoder_sess_ = std::make_unique<Ort::Session>(
env_, model_data, model_data_length, sess_opts_);
GetInputNames(encoder_sess_.get(), &encoder_input_names_,
&encoder_input_names_ptr_);
GetOutputNames(encoder_sess_.get(), &encoder_output_names_,
&encoder_output_names_ptr_);
// get meta data
Ort::ModelMetadata meta_data = encoder_sess_->GetModelMetadata();
if (config_.debug) {
std::ostringstream os;
os << "---encoder---\n";
PrintModelMetadata(os, meta_data);
#if __OHOS__
SHERPA_ONNX_LOGE("%{public}s\n", os.str().c_str());
#else
SHERPA_ONNX_LOGE("%s\n", os.str().c_str());
#endif
}
Ort::AllocatorWithDefaultOptions allocator; // used in the macro below
SHERPA_ONNX_READ_META_DATA(vocab_size_, "vocab_size");
// need to increase by 1 since the blank token is not included in computing
// vocab_size in NeMo.
vocab_size_ += 1;
SHERPA_ONNX_READ_META_DATA(subsampling_factor_, "subsampling_factor");
SHERPA_ONNX_READ_META_DATA_STR_ALLOW_EMPTY(normalize_type_,
"normalize_type");
SHERPA_ONNX_READ_META_DATA(pred_rnn_layers_, "pred_rnn_layers");
SHERPA_ONNX_READ_META_DATA(pred_hidden_, "pred_hidden");
SHERPA_ONNX_READ_META_DATA_WITH_DEFAULT(is_giga_am_, "is_giga_am", 0);
SHERPA_ONNX_READ_META_DATA_WITH_DEFAULT(feat_dim_, "feat_dim", -1);
if (normalize_type_ == "NA") {
normalize_type_ = "";
}
}
void InitDecoder(void *model_data, size_t model_data_length) {
decoder_sess_ = std::make_unique<Ort::Session>(
env_, model_data, model_data_length, sess_opts_);
GetInputNames(decoder_sess_.get(), &decoder_input_names_,
&decoder_input_names_ptr_);
GetOutputNames(decoder_sess_.get(), &decoder_output_names_,
&decoder_output_names_ptr_);
}
void InitJoiner(void *model_data, size_t model_data_length) {
joiner_sess_ = std::make_unique<Ort::Session>(
env_, model_data, model_data_length, sess_opts_);
GetInputNames(joiner_sess_.get(), &joiner_input_names_,
&joiner_input_names_ptr_);
GetOutputNames(joiner_sess_.get(), &joiner_output_names_,
&joiner_output_names_ptr_);
}
private:
OfflineModelConfig config_;
Ort::Env env_;
Ort::SessionOptions sess_opts_;
Ort::AllocatorWithDefaultOptions allocator_;
std::unique_ptr<Ort::Session> encoder_sess_;
std::unique_ptr<Ort::Session> decoder_sess_;
std::unique_ptr<Ort::Session> joiner_sess_;
std::vector<std::string> encoder_input_names_;
std::vector<const char *> encoder_input_names_ptr_;
std::vector<std::string> encoder_output_names_;
std::vector<const char *> encoder_output_names_ptr_;
std::vector<std::string> decoder_input_names_;
std::vector<const char *> decoder_input_names_ptr_;
std::vector<std::string> decoder_output_names_;
std::vector<const char *> decoder_output_names_ptr_;
std::vector<std::string> joiner_input_names_;
std::vector<const char *> joiner_input_names_ptr_;
std::vector<std::string> joiner_output_names_;
std::vector<const char *> joiner_output_names_ptr_;
int32_t vocab_size_ = 0;
int32_t subsampling_factor_ = 8;
std::string normalize_type_;
int32_t pred_rnn_layers_ = -1;
int32_t pred_hidden_ = -1;
int32_t is_giga_am_ = 0;
// giga am uses 64
// parakeet-tdt-0.6b-v2 uses 128
// others use 80
int32_t feat_dim_ = -1; // -1 means to use default values.
};
OfflineTransducerNeMoModel::OfflineTransducerNeMoModel(
const OfflineModelConfig &config)
: impl_(std::make_unique<Impl>(config)) {}
template <typename Manager>
OfflineTransducerNeMoModel::OfflineTransducerNeMoModel(
Manager *mgr, const OfflineModelConfig &config)
: impl_(std::make_unique<Impl>(mgr, config)) {}
OfflineTransducerNeMoModel::~OfflineTransducerNeMoModel() = default;
std::vector<Ort::Value> OfflineTransducerNeMoModel::RunEncoder(
Ort::Value features, Ort::Value features_length) const {
return impl_->RunEncoder(std::move(features), std::move(features_length));
}
std::pair<Ort::Value, std::vector<Ort::Value>>
OfflineTransducerNeMoModel::RunDecoder(Ort::Value targets,
Ort::Value targets_length,
std::vector<Ort::Value> states) const {
return impl_->RunDecoder(std::move(targets), std::move(targets_length),
std::move(states));
}
std::vector<Ort::Value> OfflineTransducerNeMoModel::GetDecoderInitStates(
int32_t batch_size) const {
return impl_->GetDecoderInitStates(batch_size);
}
Ort::Value OfflineTransducerNeMoModel::RunJoiner(Ort::Value encoder_out,
Ort::Value decoder_out) const {
return impl_->RunJoiner(std::move(encoder_out), std::move(decoder_out));
}
int32_t OfflineTransducerNeMoModel::SubsamplingFactor() const {
return impl_->SubsamplingFactor();
}
int32_t OfflineTransducerNeMoModel::VocabSize() const {
return impl_->VocabSize();
}
OrtAllocator *OfflineTransducerNeMoModel::Allocator() const {
return impl_->Allocator();
}
std::string OfflineTransducerNeMoModel::FeatureNormalizationMethod() const {
return impl_->FeatureNormalizationMethod();
}
bool OfflineTransducerNeMoModel::IsGigaAM() const { return impl_->IsGigaAM(); }
int32_t OfflineTransducerNeMoModel::FeatureDim() const {
return impl_->FeatureDim();
}
#if __ANDROID_API__ >= 9
template OfflineTransducerNeMoModel::OfflineTransducerNeMoModel(
AAssetManager *mgr, const OfflineModelConfig &config);
#endif
#if __OHOS__
template OfflineTransducerNeMoModel::OfflineTransducerNeMoModel(
NativeResourceManager *mgr, const OfflineModelConfig &config);
#endif
} // namespace sherpa_onnx
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