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# Copyright (c) 2021 PaddlePaddle Authors. All Rights Reserved.
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#
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# Licensed under the Apache License, Version 2.0 (the "License");
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# you may not use this file except in compliance with the License.
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# You may obtain a copy of the License at
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#
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# http://www.apache.org/licenses/LICENSE-2.0
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#
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# Unless required by applicable law or agreed to in writing, software
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# distributed under the License is distributed on an "AS IS" BASIS,
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# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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# See the License for the specific language governing permissions and
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# limitations under the License.
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# Modified from espnet(https://github.com/espnet/espnet)
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"""Beam search module."""
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from itertools import chain
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from typing import Any
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from typing import Dict
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from typing import List
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from typing import NamedTuple
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from typing import Tuple
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from typing import Union
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import paddle
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from ..scorers.scorer_interface import PartialScorerInterface
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from ..scorers.scorer_interface import ScorerInterface
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from ..utils import end_detect
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from paddlespeech.s2t.utils.log import Log
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logger = Log(__name__).getlog()
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class Hypothesis(NamedTuple):
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"""Hypothesis data type."""
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yseq: paddle.Tensor # (T,)
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score: Union[float, paddle.Tensor] = 0
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scores: Dict[str, Union[float, paddle.Tensor]] = dict()
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states: Dict[str, Any] = dict()
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def asdict(self) -> dict:
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"""Convert data to JSON-friendly dict."""
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return self._replace(
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yseq=self.yseq.tolist(),
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score=float(self.score),
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scores={k: float(v)
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for k, v in self.scores.items()}, )._asdict()
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class BeamSearch(paddle.nn.Layer):
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"""Beam search implementation."""
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def __init__(
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self,
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scorers: Dict[str, ScorerInterface],
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weights: Dict[str, float],
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beam_size: int,
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vocab_size: int,
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sos: int,
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eos: int,
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token_list: List[str]=None,
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pre_beam_ratio: float=1.5,
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pre_beam_score_key: str=None, ):
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"""Initialize beam search.
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Args:
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scorers (dict[str, ScorerInterface]): Dict of decoder modules
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e.g., Decoder, CTCPrefixScorer, LM
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The scorer will be ignored if it is `None`
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weights (dict[str, float]): Dict of weights for each scorers
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The scorer will be ignored if its weight is 0
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beam_size (int): The number of hypotheses kept during search
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vocab_size (int): The number of vocabulary
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sos (int): Start of sequence id
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eos (int): End of sequence id
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token_list (list[str]): List of tokens for debug log
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pre_beam_score_key (str): key of scores to perform pre-beam search
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pre_beam_ratio (float): beam size in the pre-beam search
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will be `int(pre_beam_ratio * beam_size)`
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"""
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super().__init__()
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# set scorers
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self.weights = weights
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self.scorers = dict() # all = full + partial
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self.full_scorers = dict() # full tokens
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self.part_scorers = dict() # partial tokens
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# this module dict is required for recursive cast
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# `self.to(device, dtype)` in `recog.py`
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self.nn_dict = paddle.nn.LayerDict() # nn.Layer
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for k, v in scorers.items():
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w = weights.get(k, 0)
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if w == 0 or v is None:
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continue
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assert isinstance(
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v, ScorerInterface
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), f"{k} ({type(v)}) does not implement ScorerInterface"
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self.scorers[k] = v
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if isinstance(v, PartialScorerInterface):
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self.part_scorers[k] = v
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else:
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self.full_scorers[k] = v
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if isinstance(v, paddle.nn.Layer):
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self.nn_dict[k] = v
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# set configurations
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self.sos = sos
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self.eos = eos
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self.token_list = token_list
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# pre_beam_size > beam_size
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self.pre_beam_size = int(pre_beam_ratio * beam_size)
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self.beam_size = beam_size
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self.n_vocab = vocab_size
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if (pre_beam_score_key is not None and pre_beam_score_key != "full" and
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pre_beam_score_key not in self.full_scorers):
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raise KeyError(
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f"{pre_beam_score_key} is not found in {self.full_scorers}")
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# selected `key` scorer to do pre beam search
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self.pre_beam_score_key = pre_beam_score_key
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# do_pre_beam when need, valid and has part_scorers
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self.do_pre_beam = (self.pre_beam_score_key is not None and
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self.pre_beam_size < self.n_vocab and
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len(self.part_scorers) > 0)
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def init_hyp(self, x: paddle.Tensor) -> List[Hypothesis]:
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"""Get an initial hypothesis data.
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Args:
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x (paddle.Tensor): The encoder output feature, (T, D)
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Returns:
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Hypothesis: The initial hypothesis.
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"""
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init_states = dict()
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init_scores = dict()
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for k, d in self.scorers.items():
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init_states[k] = d.init_state(x)
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init_scores[k] = 0.0
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return [
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Hypothesis(
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yseq=paddle.to_tensor([self.sos], place=x.place),
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score=0.0,
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scores=init_scores,
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states=init_states, )
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]
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@staticmethod
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def append_token(xs: paddle.Tensor,
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x: Union[int, paddle.Tensor]) -> paddle.Tensor:
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"""Append new token to prefix tokens.
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Args:
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xs (paddle.Tensor): The prefix token, (T,)
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x (int): The new token to append
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Returns:
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paddle.Tensor: (T+1,), New tensor contains: xs + [x] with xs.dtype and xs.device
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"""
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x = paddle.to_tensor([x], dtype=xs.dtype) if isinstance(x, int) else x
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return paddle.concat((xs, x))
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def score_full(self, hyp: Hypothesis, x: paddle.Tensor
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) -> Tuple[Dict[str, paddle.Tensor], Dict[str, Any]]:
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"""Score new hypothesis by `self.full_scorers`.
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Args:
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hyp (Hypothesis): Hypothesis with prefix tokens to score
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x (paddle.Tensor): Corresponding input feature, (T, D)
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Returns:
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Tuple[Dict[str, paddle.Tensor], Dict[str, Any]]: Tuple of
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score dict of `hyp` that has string keys of `self.full_scorers`
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and tensor score values of shape: `(self.n_vocab,)`,
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and state dict that has string keys
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and state values of `self.full_scorers`
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"""
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scores = dict()
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states = dict()
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for k, d in self.full_scorers.items():
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# scores[k] shape (self.n_vocab,)
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scores[k], states[k] = d.score(hyp.yseq, hyp.states[k], x)
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return scores, states
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def score_partial(self,
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hyp: Hypothesis,
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ids: paddle.Tensor,
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x: paddle.Tensor
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) -> Tuple[Dict[str, paddle.Tensor], Dict[str, Any]]:
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"""Score new hypothesis by `self.part_scorers`.
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Args:
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hyp (Hypothesis): Hypothesis with prefix tokens to score
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ids (paddle.Tensor): 1D tensor of new partial tokens to score,
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len(ids) < n_vocab
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x (paddle.Tensor): Corresponding input feature, (T, D)
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Returns:
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Tuple[Dict[str, paddle.Tensor], Dict[str, Any]]: Tuple of
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score dict of `hyp` that has string keys of `self.part_scorers`
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and tensor score values of shape: `(len(ids),)`,
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and state dict that has string keys
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and state values of `self.part_scorers`
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"""
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scores = dict()
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states = dict()
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for k, d in self.part_scorers.items():
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# scores[k] shape (len(ids),)
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scores[k], states[k] = d.score_partial(hyp.yseq, ids, hyp.states[k],
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x)
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return scores, states
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def beam(self, weighted_scores: paddle.Tensor,
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ids: paddle.Tensor) -> Tuple[paddle.Tensor, paddle.Tensor]:
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"""Compute topk full token ids and partial token ids.
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Args:
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weighted_scores (paddle.Tensor): The weighted sum scores for each tokens.
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Its shape is `(self.n_vocab,)`.
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ids (paddle.Tensor): The partial token ids(Global) to compute topk.
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Returns:
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Tuple[paddle.Tensor, paddle.Tensor]:
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The topk full token ids and partial token ids.
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Their shapes are `(self.beam_size,)`.
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i.e. (global ids, global relative local ids).
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"""
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# no pre beam performed, `ids` equal to `weighted_scores`
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if paddle.shape(weighted_scores)[0] == paddle.shape(ids)[0]:
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top_ids = weighted_scores.topk(
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self.beam_size)[1] # index in n_vocab
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return top_ids, top_ids
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# mask pruned in pre-beam not to select in topk
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tmp = weighted_scores[ids]
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weighted_scores[:] = -float("inf")
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weighted_scores[ids] = tmp
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# top_ids no equal to local_ids, since ids shape not same
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top_ids = weighted_scores.topk(self.beam_size)[1] # index in n_vocab
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local_ids = weighted_scores[ids].topk(
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self.beam_size)[1] # index in len(ids)
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return top_ids, local_ids
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@staticmethod
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def merge_scores(
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prev_scores: Dict[str, float],
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next_full_scores: Dict[str, paddle.Tensor],
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full_idx: int,
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next_part_scores: Dict[str, paddle.Tensor],
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part_idx: int, ) -> Dict[str, paddle.Tensor]:
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"""Merge scores for new hypothesis.
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Args:
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prev_scores (Dict[str, float]):
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The previous hypothesis scores by `self.scorers`
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next_full_scores (Dict[str, paddle.Tensor]): scores by `self.full_scorers`
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full_idx (int): The next token id for `next_full_scores`
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next_part_scores (Dict[str, paddle.Tensor]):
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scores of partial tokens by `self.part_scorers`
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part_idx (int): The new token id for `next_part_scores`
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Returns:
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Dict[str, paddle.Tensor]: The new score dict.
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Its keys are names of `self.full_scorers` and `self.part_scorers`.
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Its values are scalar tensors by the scorers.
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"""
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new_scores = dict()
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for k, v in next_full_scores.items():
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new_scores[k] = prev_scores[k] + v[full_idx]
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for k, v in next_part_scores.items():
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new_scores[k] = prev_scores[k] + v[part_idx]
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return new_scores
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def merge_states(self, states: Any, part_states: Any, part_idx: int) -> Any:
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"""Merge states for new hypothesis.
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Args:
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states: states of `self.full_scorers`
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part_states: states of `self.part_scorers`
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part_idx (int): The new token id for `part_scores`
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Returns:
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Dict[str, paddle.Tensor]: The new score dict.
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Its keys are names of `self.full_scorers` and `self.part_scorers`.
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Its values are states of the scorers.
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"""
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new_states = dict()
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for k, v in states.items():
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new_states[k] = v
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for k, d in self.part_scorers.items():
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new_states[k] = d.select_state(part_states[k], part_idx)
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return new_states
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def search(self, running_hyps: List[Hypothesis],
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x: paddle.Tensor) -> List[Hypothesis]:
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"""Search new tokens for running hypotheses and encoded speech x.
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Args:
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running_hyps (List[Hypothesis]): Running hypotheses on beam
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x (paddle.Tensor): Encoded speech feature (T, D)
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Returns:
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List[Hypotheses]: Best sorted hypotheses
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"""
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best_hyps = []
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part_ids = paddle.arange(self.n_vocab) # no pre-beam
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for hyp in running_hyps:
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# scoring
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weighted_scores = paddle.zeros([self.n_vocab], dtype=x.dtype)
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scores, states = self.score_full(hyp, x)
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for k in self.full_scorers:
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weighted_scores += self.weights[k] * scores[k]
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# partial scoring
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if self.do_pre_beam:
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pre_beam_scores = (weighted_scores
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if self.pre_beam_score_key == "full" else
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scores[self.pre_beam_score_key])
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part_ids = paddle.topk(pre_beam_scores, self.pre_beam_size)[1]
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part_scores, part_states = self.score_partial(hyp, part_ids, x)
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for k in self.part_scorers:
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weighted_scores[part_ids] += self.weights[k] * part_scores[k]
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# add previous hyp score
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weighted_scores += hyp.score
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# update hyps
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for j, part_j in zip(*self.beam(weighted_scores, part_ids)):
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# `part_j` is `j` relative id in `part_scores`
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# will be (2 x beam at most)
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best_hyps.append(
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Hypothesis(
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score=weighted_scores[j],
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yseq=self.append_token(hyp.yseq, j),
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scores=self.merge_scores(hyp.scores, scores, j,
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part_scores, part_j),
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states=self.merge_states(states, part_states, part_j),
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))
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# sort and prune 2 x beam -> beam
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best_hyps = sorted(
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best_hyps, key=lambda x: x.score,
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reverse=True)[:min(len(best_hyps), self.beam_size)]
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return best_hyps
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def forward(self,
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x: paddle.Tensor,
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maxlenratio: float=0.0,
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minlenratio: float=0.0) -> List[Hypothesis]:
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"""Perform beam search.
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Args:
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x (paddle.Tensor): Encoded speech feature (T, D)
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maxlenratio (float): Input length ratio to obtain max output length.
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If maxlenratio=0.0 (default), it uses a end-detect function
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to automatically find maximum hypothesis lengths
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If maxlenratio<0.0, its absolute value is interpreted
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as a constant max output length.
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minlenratio (float): Input length ratio to obtain min output length.
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Returns:
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list[Hypothesis]: N-best decoding results
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"""
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# set length bounds
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if maxlenratio == 0:
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maxlen = paddle.shape(x)[0]
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elif maxlenratio < 0:
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maxlen = -1 * int(maxlenratio)
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else:
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maxlen = max(1, int(maxlenratio * paddle.shape(x)[0]))
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minlen = int(minlenratio * paddle.shape(x)[0])
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logger.info("decoder input length: " + str(paddle.shape(x)[0]))
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logger.info("max output length: " + str(maxlen))
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logger.info("min output length: " + str(minlen))
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# main loop of prefix search
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running_hyps = self.init_hyp(x)
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ended_hyps = []
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for i in range(maxlen):
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logger.debug("position " + str(i))
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best = self.search(running_hyps, x)
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# post process of one iteration
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running_hyps = self.post_process(i, maxlen, maxlenratio, best,
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ended_hyps)
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# end detection
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if maxlenratio == 0.0 and end_detect(
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[h.asdict() for h in ended_hyps], i):
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logger.info(f"end detected at {i}")
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break
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if len(running_hyps) == 0:
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logger.info("no hypothesis. Finish decoding.")
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break
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else:
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logger.debug(f"remained hypotheses: {len(running_hyps)}")
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nbest_hyps = sorted(ended_hyps, key=lambda x: x.score, reverse=True)
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# check the number of hypotheses reaching to eos
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if len(nbest_hyps) == 0:
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logger.warning("there is no N-best results, perform recognition "
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"again with smaller minlenratio.")
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return ([] if minlenratio < 0.1 else
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self.forward(x, maxlenratio, max(0.0, minlenratio - 0.1)))
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# report the best result
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best = nbest_hyps[0]
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for k, v in best.scores.items():
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logger.info(
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f"{float(v):6.2f} * {self.weights[k]:3} = {float(v) * self.weights[k]:6.2f} for {k}"
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)
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logger.info(f"total log probability: {float(best.score):.2f}")
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logger.info(
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f"normalized log probability: {float(best.score) / len(best.yseq):.2f}"
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)
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logger.info(f"total number of ended hypotheses: {len(nbest_hyps)}")
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if self.token_list is not None:
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# logger.info(
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# "best hypo: "
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# + "".join([self.token_list[x] for x in best.yseq[1:-1]])
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# + "\n"
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# )
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logger.info("best hypo: " + "".join(
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[self.token_list[x] for x in best.yseq[1:]]) + "\n")
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return nbest_hyps
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def post_process(
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self,
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i: int,
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maxlen: int,
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maxlenratio: float,
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running_hyps: List[Hypothesis],
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ended_hyps: List[Hypothesis], ) -> List[Hypothesis]:
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"""Perform post-processing of beam search iterations.
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Args:
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i (int): The length of hypothesis tokens.
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maxlen (int): The maximum length of tokens in beam search.
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maxlenratio (int): The maximum length ratio in beam search.
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running_hyps (List[Hypothesis]): The running hypotheses in beam search.
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ended_hyps (List[Hypothesis]): The ended hypotheses in beam search.
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Returns:
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List[Hypothesis]: The new running hypotheses.
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"""
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logger.debug(f"the number of running hypotheses: {len(running_hyps)}")
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if self.token_list is not None:
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logger.debug("best hypo: " + "".join(
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[self.token_list[x] for x in running_hyps[0].yseq[1:]]))
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# add eos in the final loop to avoid that there are no ended hyps
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if i == maxlen - 1:
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logger.info("adding <eos> in the last position in the loop")
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running_hyps = [
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h._replace(yseq=self.append_token(h.yseq, self.eos))
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for h in running_hyps
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]
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# add ended hypotheses to a final list, and removed them from current hypotheses
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# (this will be a problem, number of hyps < beam)
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remained_hyps = []
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for hyp in running_hyps:
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if hyp.yseq[-1] == self.eos:
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# e.g., Word LM needs to add final <eos> score
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for k, d in chain(self.full_scorers.items(),
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self.part_scorers.items()):
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s = d.final_score(hyp.states[k])
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hyp.scores[k] += s
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hyp = hyp._replace(score=hyp.score + self.weights[k] * s)
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ended_hyps.append(hyp)
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else:
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remained_hyps.append(hyp)
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return remained_hyps
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def beam_search(
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x: paddle.Tensor,
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sos: int,
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eos: int,
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beam_size: int,
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vocab_size: int,
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scorers: Dict[str, ScorerInterface],
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weights: Dict[str, float],
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token_list: List[str]=None,
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maxlenratio: float=0.0,
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minlenratio: float=0.0,
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pre_beam_ratio: float=1.5,
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pre_beam_score_key: str="full", ) -> list:
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"""Perform beam search with scorers.
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Args:
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x (paddle.Tensor): Encoded speech feature (T, D)
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sos (int): Start of sequence id
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eos (int): End of sequence id
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beam_size (int): The number of hypotheses kept during search
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vocab_size (int): The number of vocabulary
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scorers (dict[str, ScorerInterface]): Dict of decoder modules
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e.g., Decoder, CTCPrefixScorer, LM
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The scorer will be ignored if it is `None`
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weights (dict[str, float]): Dict of weights for each scorers
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The scorer will be ignored if its weight is 0
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token_list (list[str]): List of tokens for debug log
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maxlenratio (float): Input length ratio to obtain max output length.
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If maxlenratio=0.0 (default), it uses a end-detect function
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to automatically find maximum hypothesis lengths
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minlenratio (float): Input length ratio to obtain min output length.
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pre_beam_score_key (str): key of scores to perform pre-beam search
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pre_beam_ratio (float): beam size in the pre-beam search
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will be `int(pre_beam_ratio * beam_size)`
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Returns:
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List[Dict]: N-best decoding results
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"""
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ret = BeamSearch(
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scorers,
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weights,
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beam_size=beam_size,
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vocab_size=vocab_size,
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pre_beam_ratio=pre_beam_ratio,
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pre_beam_score_key=pre_beam_score_key,
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sos=sos,
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eos=eos,
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token_list=token_list, ).forward(
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x=x, maxlenratio=maxlenratio, minlenratio=minlenratio)
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return [h.asdict() for h in ret]
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