Datasets:

echodict
/

NeMo

	# Copyright (c) 2025, NVIDIA CORPORATION. All rights reserved.
	#
	# 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
	#
	# Unless required by applicable law or agreed to in writing, software
	# distributed under the License is distributed on an "AS IS" BASIS,
	# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	# See the License for the specific language governing permissions and
	# limitations under the License.


	from functools import lru_cache
	from typing import Callable

	import numpy as np

	from nemo.collections.asr.inference.streaming.state.state import StreamingState
	from nemo.collections.asr.inference.utils.constants import (
	POST_WORD_PUNCTUATION,
	ROUND_PRECISION,
	SENTENCEPIECE_UNDERSCORE,
	)
	from nemo.collections.asr.inference.utils.text_segment import TextSegment, Word
	from nemo.collections.common.tokenizers.tokenizer_spec import TokenizerSpec


	class BPEDecoder:
	"""
	BPEDecoder class for decoding BPE (Byte Pair Encoding) tokens into words and segments by preserving timestamps and confidence scores
	"""

	def __init__(
	self,
	vocabulary: list[str],
	tokenizer: TokenizerSpec,
	confidence_aggregator: Callable,
	asr_supported_puncts: set,
	word_boundary_tolerance: float,
	token_duration_in_secs: float,
	):
	"""
	Initialize the BPEDecoder.
	Args:
	vocabulary (list[str]): List of vocabulary tokens.
	tokenizer (TokenizerSpec): Tokenizer object.
	confidence_aggregator (Callable): Confidence aggregator function.
	asr_supported_puncts (set): Set of supported punctuation symbols.
	word_boundary_tolerance (float): Word boundary tolerance for timestamp refinement.
	token_duration_in_secs (float): Token duration in seconds.
	"""

	self.vocabulary = vocabulary
	self.tokenizer = tokenizer
	self.confidence_aggregator = confidence_aggregator
	self.asr_supported_puncts = asr_supported_puncts
	self.punct_marks_with_underscore = asr_supported_puncts.union({SENTENCEPIECE_UNDERSCORE})
	self.word_boundary_tolerance = word_boundary_tolerance
	self.token_duration_in_secs = token_duration_in_secs
	self.start_of_word_cache = {
	token_id: token.startswith(SENTENCEPIECE_UNDERSCORE) for token_id, token in enumerate(self.vocabulary)
	}
	self.punct_cache = {
	token_id: (token in self.asr_supported_puncts, token in self.punct_marks_with_underscore)
	for token_id, token in enumerate(self.vocabulary)
	}

	@lru_cache(maxsize=10000)
	def cached_ids_to_text(self, tokens_slice: tuple[int]) -> str:
	"""
	Cached tokenizer output to avoid repeated calls to the tokenizer.
	Args:
	tokens_slice (tuple): Tuple of token indices to be detokenized.
	Returns:
	str: Detokenized text.
	"""
	word_text = self.tokenizer.ids_to_text(list(tokens_slice)).strip()
	return word_text

	def decode_bpe_tokens(self, state: StreamingState) -> None:
	"""
	Decodes BPE tokens into words or segments with timestamps and confidence scores.
	Args:
	state (StreamingState): The state object containing the BPE tokens, timestamps, and confidence scores.
	"""
	if state.options.is_word_level_output():
	# Form words and push them to the state
	decoded_words, need_merge = self.group_tokens_into_words(state.tokens, state.timesteps, state.confidences)
	state.push_back_words(decoded_words, need_merge, self.confidence_aggregator)
	elif state.options.is_segment_level_output():
	# Form text segment and push it to the state
	if state.tokens:
	decoded_segment, need_merge = self.group_tokens_into_segment(
	state.tokens, state.timesteps, state.confidences
	)
	state.push_back_segment(decoded_segment, need_merge, self.confidence_aggregator)
	else:
	raise ValueError(f"Invalid output granularity: {state.options.asr_output_granularity}")

	def group_tokens_into_segment(
	self, tokens: list, timesteps: list, confidences: list
	) -> tuple[TextSegment \| None, bool]:
	"""
	Group tokens into a text segment with timestamps and confidence scores.
	Args:
	tokens (list): List of token indices.
	timesteps (list): List of token timestamps.
	confidences (list): List of token confidence scores.
	Returns:
	(tuple[TextSegment \| None, bool]) Text segment with text, start time, end time, and confidence score.
	Also returns a boolean to indicate if the text segment should be merged with the last segment stored in the state
	"""
	n_tokens = len(tokens)

	if n_tokens != len(timesteps) or n_tokens != len(confidences):
	raise ValueError("tokens, timesteps and confidences must have the same length")

	if n_tokens == 0:
	return None, False

	need_merge = not bool(self.start_of_word_cache[tokens[0]])

	# Get the segment text
	segment_text = self.tokenizer.ids_to_text(tokens).strip()

	# Refine the start and end timestamps of the text segment
	start, end = self.refine_text_segment_timestamp(tokens, timesteps)

	# Convert token timestamps to seconds
	start = round(start * self.token_duration_in_secs, ROUND_PRECISION)
	end = round(end * self.token_duration_in_secs, ROUND_PRECISION)

	# Aggregate the confidence score of the text segment
	conf = self.confidence_aggregator(confidences)

	# Create a text segment
	return TextSegment(text=segment_text, start=start, end=end, conf=conf), need_merge

	def group_tokens_into_words(self, tokens: list, timesteps: list, confidences: list) -> tuple[list[Word], bool]:
	"""
	Decodes BPE tokens into words with timestamps and confidence scores.
	Args:
	tokens (list): List of token indices.
	timesteps (list): List of token timesteps.
	confidences (list): List of token confidence scores.
	Returns:
	(tuple[list[Word], bool]) List of decoded words with text, start time, end time, and confidence score.
	Also returns a boolean to indicate if the first word should be merged with the last word stored in the state
	"""
	n_tokens = len(tokens)

	if n_tokens != len(timesteps) or n_tokens != len(confidences):
	raise ValueError("tokens, timesteps and confidences must have the same length")

	if n_tokens == 0:
	return [], False

	# Group tokens into words
	is_start_mask = np.fromiter((self.start_of_word_cache[tok] for tok in tokens), dtype=np.int32)
	word_ids = np.cumsum(is_start_mask)

	start_indices = np.nonzero(np.diff(word_ids, prepend=word_ids[0] - 1))[0]
	end_indices = np.append(start_indices[1:], n_tokens)

	decoded_words, prev_word_end = [], None

	# If the first word is the start of a word, we need to merge it with the last word stored in the state
	need_merge = not bool(is_start_mask[0])

	for start_idx, end_idx in zip(start_indices, end_indices):

	tokens_slice = tokens[start_idx:end_idx]
	time_slice = timesteps[start_idx:end_idx]
	conf_slice = confidences[start_idx:end_idx]

	word_text = self.cached_ids_to_text(tuple(tokens_slice))

	# Ignore empty text
	if not word_text:
	continue

	# Append the post word punctuation to the previous word
	if word_text in POST_WORD_PUNCTUATION and len(decoded_words) > 0:
	prev_word = decoded_words[-1]
	prev_word.text += word_text
	continue

	# Refine timestamps
	word_start_tms, word_end_tms = self.refine_text_segment_timestamp(
	current_tokens=tokens_slice,
	current_timesteps=time_slice,
	next_segment_start_timestep=timesteps[end_idx] if end_idx < n_tokens else None,
	need_merge_with_next_segment=(
	self.start_of_word_cache[tokens[end_idx]] if end_idx < n_tokens else None
	),
	prev_segment_end=prev_word_end,
	)
	prev_word_end = word_end_tms

	# Aggregate confidence
	word_conf = self.confidence_aggregator(conf_slice)

	# Convert token timestamps to seconds
	start_sec = round(word_start_tms * self.token_duration_in_secs, ROUND_PRECISION)
	end_sec = round(word_end_tms * self.token_duration_in_secs, ROUND_PRECISION)

	decoded_words.append(Word(text=word_text, start=start_sec, end=end_sec, conf=word_conf))

	return decoded_words, need_merge

	def refine_text_segment_timestamp(
	self,
	current_tokens: list[int],
	current_timesteps: list[float],
	next_segment_start_timestep: float \| None = None,
	need_merge_with_next_segment: bool \| None = None,
	prev_segment_end: float \| None = None,
	) -> tuple[float, float]:
	"""
	Refines the text segment timestamp based on the current tokens, timestamps, and the next segment start timestamp.
	Args:
	current_tokens (list[int]): List of token indices.
	current_timesteps (list[float]): List of token timestamps.
	next_segment_start_timestep (float \| None): The start timestamp of the next segment.
	need_merge_with_next_segment (bool \| None): True if the current segment should be merged with the next segment.
	prev_segment_end (float \| None): The end timestamp of the previous segment.
	Returns:
	tuple(float, float): The refined start and end timestamps.
	"""

	start, end = current_timesteps[0], current_timesteps[-1]

	# --- Correct the start timestamp if the first token is underscore or punctuation ---
	first_token = current_tokens[0]
	if self.punct_cache[first_token][1]:
	start = next(
	(tms for tms, token in zip(current_timesteps, current_tokens) if not self.punct_cache[token][1]),
	start,
	)

	# --- Correct the end timestamp if the last token is punctuation ---
	last_token = current_tokens[-1]
	if self.punct_cache[last_token][0]:
	end = next(
	(
	current_timesteps[i]
	for i in reversed(range(len(current_tokens)))
	if not self.punct_cache[current_tokens[i]][0]
	),
	end,
	)

	# --- If the next segment is close to the end of the current segment, merge timestamps ---
	if next_segment_start_timestep is not None and need_merge_with_next_segment:
	if next_segment_start_timestep - end <= self.word_boundary_tolerance:
	end = next_segment_start_timestep

	# --- Adjust the start and end timestamps based on the previous segment end ---
	delta = 0
	if prev_segment_end is not None:
	if prev_segment_end > start:
	delta = prev_segment_end - start

	start = start + delta
	end = end + delta
	return start, end + (1 if start == end else 0)