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import axengine as axe
import numpy as np
import librosa
from frontend import WavFrontend
import os
import time
from typing import List, Union, Optional
from asr_decoder import CTCDecoder
from tokenizer import SentencepiecesTokenizer
from online_fbank import OnlineFbank
import torch
def sequence_mask(lengths, maxlen=None, dtype=np.float32):
# 如果 maxlen 未指定,则取 lengths 中的最大值
if maxlen is None:
maxlen = np.max(lengths)
# 创建一个从 0 到 maxlen-1 的行向量
row_vector = np.arange(0, maxlen, 1)
# 将 lengths 转换为列向量
matrix = np.expand_dims(lengths, axis=-1)
# 比较生成掩码
mask = row_vector < matrix
if mask.shape[-1] < lengths[0]:
mask = np.concatenate(
[
mask,
np.zeros(
(mask.shape[0], lengths[0] - mask.shape[-1]), dtype=np.float32
),
],
axis=-1,
)
# 返回指定数据类型的掩码
return mask.astype(dtype)[None, ...]
def unique_consecutive_np(arr):
"""
找出数组中连续的唯一值,模拟 torch.unique_consecutive(yseq, dim=-1)
参数:
arr: 一维numpy数组
返回:
unique_values: 去除连续重复值后的数组
"""
if len(arr) == 0:
return np.array([])
if len(arr) == 1:
return arr.copy()
# 找出变化的位置
diff = np.diff(arr)
change_positions = np.where(diff != 0)[0] + 1
# 添加起始位置
start_positions = np.concatenate(([0], change_positions))
# 获取唯一值(每个连续段的第一个值)
unique_values = arr[start_positions]
return unique_values
class SenseVoiceAx:
"""SenseVoice axmodel runner"""
def __init__(
self,
model_path: str,
max_len: int = 256,
beam_size: int = 3,
language: str = "auto",
hot_words: Optional[List[str]] = None,
use_itn: bool = True,
streaming: bool = False,
providers=['AxEngineExecutionProvider']
):
"""
Initialize SenseVoiceAx
Args:
model_path: Path of axmodel
max_len: Fixed shape of input of axmodel
beam_size: Max number of hypos to hold after each decode step
language: Support auto, zh(Chinese), en(English), yue(Cantonese), ja(Japanese), ko(Korean)
hot_words: Words that may fail to recognize,
special words/phrases (aka hotwords) like rare words, personalized information etc.
use_itn: Allow Invert Text Normalization if True,
ITN converts ASR model output into its written form to improve text readability,
For example, the ITN module replaces “one hundred and twenty-three dollars” transcribed by an ASR model with “$123.”
streaming: Processes audio in small segments or "chunks" sequentially and outputs text on the fly.
Use stream_infer method if streaming is true otherwise infer.
"""
model_path_root = os.path.dirname(model_path)
emb_path = os.path.join(model_path_root, "../embeddings.npy")
cmvn_file = os.path.join(model_path_root, "../am.mvn")
bpe_model = os.path.join(
model_path_root, "../chn_jpn_yue_eng_ko_spectok.bpe.model"
)
if streaming:
self.position_encoding = np.load(
os.path.join(model_path_root, "../pe_streaming.npy")
)
else:
self.position_encoding = np.load(
os.path.join(model_path_root, "../pe_nonstream.npy")
)
self.streaming = streaming
self.tokenizer = SentencepiecesTokenizer(bpemodel=bpe_model)
self.frontend = WavFrontend(
cmvn_file=cmvn_file,
fs=16000,
window="hamming",
n_mels=80,
frame_length=25,
frame_shift=10,
lfr_m=7,
lfr_n=6,
)
self.model = axe.InferenceSession(model_path, providers=providers)
self.sample_rate = 16000
self.blank_id = 0
self.max_len = max_len
self.padding = 16
self.input_size = 560
self.lid_dict = {
"auto": 0,
"zh": 3,
"en": 4,
"yue": 7,
"ja": 11,
"ko": 12,
"nospeech": 13,
}
self.lid_int_dict = {
24884: 3,
24885: 4,
24888: 7,
24892: 11,
24896: 12,
24992: 13,
}
self.textnorm_dict = {"withitn": 14, "woitn": 15}
self.textnorm_int_dict = {25016: 14, 25017: 15}
self.emo_dict = {
"unk": 25009,
"happy": 25001,
"sad": 25002,
"angry": 25003,
"neutral": 25004,
}
self.load_embeddings(emb_path, language, use_itn)
self.language = language
# decoder
if beam_size > 1 and hot_words is not None:
self.beam_size = beam_size
symbol_table = {}
for i in range(self.tokenizer.get_vocab_size()):
symbol_table[self.tokenizer.decode(i)] = i
self.decoder = CTCDecoder(hot_words, symbol_table, bpe_model)
else:
self.beam_size = 1
self.decoder = CTCDecoder()
if streaming:
self.cur_idx = -1
self.chunk_size = max_len - self.padding
self.caches_shape = (max_len, self.input_size)
self.caches = np.zeros(self.caches_shape, dtype=np.float32)
self.zeros = np.zeros((1, self.input_size), dtype=np.float32)
self.neg_mean, self.inv_stddev = (
self.frontend.cmvn[0, :],
self.frontend.cmvn[1, :],
)
self.fbank = OnlineFbank(window_type="hamming")
self.masks = sequence_mask(
np.array([self.max_len], dtype=np.int32),
maxlen=self.max_len,
dtype=np.float32,
)
@property
def language_options(self):
return list(self.lid_dict.keys())
@property
def textnorm_options(self):
return list(self.textnorm_dict.keys())
def load_embeddings(self, emb_path, language, use_itn):
self.embeddings = np.load(emb_path, allow_pickle=True).item()
self.language_query = self.embeddings[language]
self.textnorm_query = (
self.embeddings["withitn"] if use_itn else self.embeddings["woitn"]
)
self.event_emo_query = self.embeddings["event_emo"]
self.input_query = np.concatenate(
(self.textnorm_query, self.language_query, self.event_emo_query), axis=1
)
self.query_num = self.input_query.shape[1]
def choose_language(self, language):
self.language_query = self.embeddings[language]
self.input_query = np.concatenate(
(self.textnorm_query, self.language_query, self.event_emo_query), axis=1
)
self.language = language
def load_data(self, filepath: str) -> np.ndarray:
waveform, _ = librosa.load(filepath, sr=self.sample_rate)
return waveform.flatten()
@staticmethod
def pad_feats(feats: List[np.ndarray], max_feat_len: int) -> np.ndarray:
def pad_feat(feat: np.ndarray, cur_len: int) -> np.ndarray:
pad_width = ((0, max_feat_len - cur_len), (0, 0))
return np.pad(feat, pad_width, "constant", constant_values=0)
feat_res = [pad_feat(feat, feat.shape[0]) for feat in feats]
feats = np.array(feat_res).astype(np.float32)
return feats
def preprocess(self, waveform):
feats, feats_len = [], []
for wf in [waveform]:
speech, _ = self.frontend.fbank(wf)
feat, feat_len = self.frontend.lfr_cmvn(speech)
feats.append(feat)
feats_len.append(feat_len)
feats = self.pad_feats(feats, np.max(feats_len))
feats_len = np.array(feats_len).astype(np.int32)
return feats, feats_len
def postprocess(self, ctc_logits, encoder_out_lens):
# 提取数据
x = ctc_logits[0, 4 : encoder_out_lens[0], :]
# 获取最大值索引
yseq = np.argmax(x, axis=-1)
# 去除连续重复元素
yseq = unique_consecutive_np(yseq)
# 创建掩码并过滤 blank_id
mask = yseq != self.blank_id
token_int = yseq[mask].tolist()
return token_int
def infer_waveform(self, waveform: np.ndarray, language="auto"):
if language != self.language:
self.choose_language(language)
# start = time.time()
feat, feat_len = self.preprocess(waveform)
# print(f"Preprocess take {time.time() - start}s")
slice_len = self.max_len - self.query_num
slice_num = int(np.ceil(feat.shape[1] / slice_len))
asr_res = []
for i in range(slice_num):
if i == 0:
sub_feat = feat[:, i * slice_len : (i + 1) * slice_len, :]
else:
sub_feat = feat[
:,
i * slice_len - self.padding : (i + 1) * slice_len - self.padding,
:,
]
# concat query
sub_feat = np.concatenate([self.input_query, sub_feat], axis=1)
real_len = sub_feat.shape[1]
if real_len < self.max_len:
sub_feat = np.concatenate(
[
sub_feat,
np.zeros(
(1, self.max_len - real_len, sub_feat.shape[-1]),
dtype=np.float32,
),
],
axis=1,
)
masks = sequence_mask(
np.array([self.max_len], dtype=np.int32),
maxlen=real_len,
dtype=np.float32,
)
# start = time.time()
outputs = self.model.run(
None,
{
"speech": sub_feat,
"masks": masks,
"position_encoding": self.position_encoding,
},
)
ctc_logits, encoder_out_lens = outputs
token_int = self.postprocess(ctc_logits, encoder_out_lens)
if self.tokenizer is not None:
asr_res.append(self.tokenizer.tokens2text(token_int))
else:
asr_res.append(token_int)
return asr_res
def infer(
self, filepath_or_data: Union[np.ndarray, str], language="auto", print_rtf=False
):
assert not self.streaming, "This method is for non-streaming model"
if isinstance(filepath_or_data, str):
waveform = self.load_data(filepath_or_data)
else:
waveform = filepath_or_data
total_time = waveform.shape[-1] / self.sample_rate
start = time.time()
asr_res = self.infer_waveform(waveform, language)
latency = time.time() - start
if print_rtf:
rtf = latency / total_time
print(f"RTF: {rtf} Latency: {latency}s Total length: {total_time}s")
return "".join(asr_res)
def decode(self, times, tokens):
times_ms = []
for step, token in zip(times, tokens):
if len(self.tokenizer.decode(token).strip()) == 0:
continue
times_ms.append(step * 60)
return times_ms, self.tokenizer.decode(tokens)
def reset(self):
self.cur_idx = -1
self.decoder.reset()
self.fbank = OnlineFbank(window_type="hamming")
self.caches = np.zeros(self.caches_shape)
def get_size(self):
effective_size = self.cur_idx + 1 - self.padding
if effective_size <= 0:
return 0
return effective_size % self.chunk_size or self.chunk_size
def stream_infer(self, audio, is_last, language="auto"):
assert self.streaming, "This method is for streaming model"
if language != self.language:
self.choose_language(language)
self.fbank.accept_waveform(audio, is_last)
features = self.fbank.get_lfr_frames(
neg_mean=self.neg_mean, inv_stddev=self.inv_stddev
)
if is_last and len(features) == 0:
features = self.zeros
for idx, feature in enumerate(features):
is_last = is_last and idx == features.shape[0] - 1
self.caches = np.roll(self.caches, -1, axis=0)
self.caches[-1, :] = feature
self.cur_idx += 1
cur_size = self.get_size()
if cur_size != self.chunk_size and not is_last:
continue
speech = self.caches[None, ...]
outputs = self.model.run(
None,
{
"speech": speech,
"masks": self.masks,
"position_encoding": self.position_encoding,
},
)
ctc_logits, encoder_out_lens = outputs
probs = ctc_logits[0, 4 : encoder_out_lens[0]]
probs = torch.from_numpy(probs)
if cur_size != self.chunk_size:
probs = probs[self.chunk_size - cur_size :]
if not is_last:
probs = probs[: self.chunk_size]
if self.beam_size > 1:
res = self.decoder.ctc_prefix_beam_search(
probs, beam_size=self.beam_size, is_last=is_last
)
times_ms, text = self.decode(res["times"][0], res["tokens"][0])
else:
res = self.decoder.ctc_greedy_search(probs, is_last=is_last)
times_ms, text = self.decode(res["times"], res["tokens"])
yield {"timestamps": times_ms, "text": text}
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