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471 lines
21 KiB
Python
471 lines
21 KiB
Python
# Copyright (c) 2025, NVIDIA CORPORATION. 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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import inspect
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import torch
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from omegaconf import DictConfig, open_dict
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from torch import nn
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from transformers import BertConfig
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from transformers.models.bert.modeling_bert import BertEncoder
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from nemo.collections.asr.models import ASRModel
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from nemo.collections.asr.modules.conformer_encoder import ConformerMultiLayerFeatureExtractor
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from nemo.collections.asr.parts.mixins import TranscribeConfig
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from nemo.core import Exportable, NeuralModule, typecheck
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class AudioPerceptionModule(NeuralModule, Exportable):
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"""Audio perception module that consists of audio encoder(s) and modality adapter."""
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@property
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def token_equivalent_duration(self) -> float:
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"""
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Returns the audio duration corresponding to a single frame/token in the output
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of this module.
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"""
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frame_shift = self.preprocessor.featurizer.hop_length / self.preprocessor.featurizer.sample_rate
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encoder_subsampling = self.encoder.subsampling_factor
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adapter_subsampling = getattr(self.modality_adapter, "subsampling_factor", 1.0)
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return frame_shift * encoder_subsampling * adapter_subsampling
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@property
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def encoder_frame_duration(self) -> float:
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"""
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Returns the audio duration corresponding to a single frame at the encoder output
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(but before the modality adapter).
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"""
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frame_shift = self.preprocessor.featurizer.hop_length / self.preprocessor.featurizer.sample_rate
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return frame_shift * self.encoder.subsampling_factor
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@property
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def encoder(self) -> nn.Module:
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# When the modality adapter needs per-layer activations (Qformer / MultiLayer
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# projection), the encoder is wrapped inside ``encoder_multilayer`` so
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# ConformerMultiLayerFeatureExtractor can attach hooks. Expose it at the top
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# level here so downstream code (training_step freeze checks, etc.) sees a
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# single logical ``encoder`` submodule regardless of the adapter choice.
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# For the non-multilayer path, the encoder was registered via
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# ``self.encoder = encoder`` through nn.Module.__setattr__ (which bypasses
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# this property); look it up directly in _modules.
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if 'encoder_multilayer' in self._modules:
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return self._modules['encoder_multilayer'].encoder
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return self._modules['encoder']
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def __init__(self, cfg: DictConfig):
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super().__init__()
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# Initialize components
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self.cfg = cfg
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self.preprocessor = self.from_config_dict(cfg.preprocessor)
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encoder = self.from_config_dict(cfg.encoder)
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if 'spec_augment' in cfg and cfg.spec_augment is not None:
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self.spec_augmentation = self.from_config_dict(cfg.spec_augment)
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else:
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self.spec_augmentation = None
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self.modality_adapter = self.from_config_dict(cfg.modality_adapter)
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if isinstance(self.modality_adapter, (QformerConnector, MultiLayerProjectionConnector)):
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self.encoder_multilayer = ConformerMultiLayerFeatureExtractor(
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encoder,
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layer_idx_list=cfg.modality_adapter.target_layer_ids,
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detach=False,
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convert_to_cpu=False,
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include_final_output=cfg.modality_adapter.get("include_final_output", True),
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)
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else:
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self.encoder = encoder
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if 'output_dim' not in cfg.modality_adapter and "d_model" in cfg.modality_adapter: # e.g., conformer encoder
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self.proj = nn.Linear(cfg.modality_adapter.d_model, cfg.output_dim)
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else:
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self.proj = nn.Identity()
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# Optional Rotary Time Embedding (ROTE), applied to the encoder output features
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# at the entrance of the modality adapter. ``None`` (default) is a no-op.
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self.rote = self.from_config_dict(cfg.rote) if cfg.get("rote") is not None else None
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def set_activation_checkpointing(self, enabled: bool) -> None:
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"""Enable/disable activation checkpointing on the encoder's transformer layers.
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When ``enabled`` is True, wraps each layer in ``self.encoder.layers`` with
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``torch.distributed.algorithms._checkpoint.checkpoint_wrapper``. Must be
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called before FSDP2 sharding. When ``enabled`` is False, this is a no-op.
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"""
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_set_encoder_activation_checkpointing(self.encoder, enabled)
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def maybe_preprocess_audio(
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self,
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input_signal=None,
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input_signal_length=None,
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processed_signal=None,
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processed_signal_length=None,
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):
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has_input_signal = input_signal is not None and input_signal_length is not None
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has_processed_signal = processed_signal is not None and processed_signal_length is not None
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if (has_input_signal ^ has_processed_signal) is False:
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raise ValueError(
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f"{self.__class__} Arguments ``input_signal`` and ``input_signal_length`` are mutually exclusive "
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" with ``processed_signal`` and ``processed_signal_len`` arguments."
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)
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if not has_processed_signal:
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processed_signal, processed_signal_length = self.preprocessor(
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input_signal=input_signal,
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length=input_signal_length,
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)
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return processed_signal, processed_signal_length
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def _apply_rote(self, encoder_emb, time_offset=None):
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"""Apply RoTE to encoder output features ``(B, C, T)`` (or a list thereof).
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``time_offset`` is an optional per-row start time in seconds, shape ``(B,)``; when
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``None`` every row starts at time 0. Per-frame absolute time is
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``time_offset[b] + (frame_idx + 0.5) * encoder_frame_duration``.
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"""
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if isinstance(encoder_emb, (list, tuple)):
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return type(encoder_emb)(self._apply_rote(emb, time_offset) for emb in encoder_emb)
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# encoder_emb: (B, C, T) -> rotate over the channel dim with x channel-last.
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b, _, t = encoder_emb.shape
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device = encoder_emb.device
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frame_times = (torch.arange(t, device=device, dtype=torch.float32) + 0.5) * self.encoder_frame_duration
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times = frame_times.unsqueeze(0).expand(b, -1) # (B, T)
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if time_offset is not None:
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times = times + time_offset.to(device=device, dtype=torch.float32).unsqueeze(1)
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rotated = self.rote(encoder_emb.transpose(1, 2), times) # (B, T, C)
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return rotated.transpose(1, 2)
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@staticmethod
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def _encoder_accepts_spk_targets(encoder: nn.Module) -> bool:
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if hasattr(encoder, "diarization_model") or hasattr(encoder, "diar_kernel"):
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return True
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try:
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return "spk_targets" in inspect.signature(encoder.forward).parameters
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except (TypeError, ValueError):
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return False
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# disable type checks to avoid type-check errors when using Conformer as modality adapter
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@typecheck.disable_checks()
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def forward(
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self,
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input_signal=None,
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input_signal_length=None,
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processed_signal=None,
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processed_signal_length=None,
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return_encoder_emb=False,
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time_offset=None,
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spk_targets=None,
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):
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processed_signal, processed_signal_length = self.maybe_preprocess_audio(
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input_signal, input_signal_length, processed_signal, processed_signal_length
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)
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# Spec augment is not applied during evaluation/testing
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if self.spec_augmentation is not None and self.training:
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processed_signal = self.spec_augmentation(input_spec=processed_signal, length=processed_signal_length)
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if isinstance(self.modality_adapter, (QformerConnector, MultiLayerProjectionConnector)):
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encoder_emb, encoded_len = self.encoder_multilayer(
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audio_signal=processed_signal, length=processed_signal_length
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)
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else:
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encoder_kwargs = {"audio_signal": processed_signal, "length": processed_signal_length}
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if spk_targets is not None:
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if not self._encoder_accepts_spk_targets(self.encoder):
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raise ValueError(
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"`spk_targets` were provided, but the mounted perception encoder "
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f"({type(self.encoder).__name__}) does not support speaker-target inputs. "
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"spk_targets has no effect when the encoder does not support it."
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)
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encoder_kwargs["spk_targets"] = spk_targets
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encoder_emb, encoded_len = self.encoder(**encoder_kwargs)
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if self.rote is not None:
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encoder_emb = self._apply_rote(encoder_emb, time_offset)
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encoded, encoded_len = self.modality_adapter(audio_signal=encoder_emb, length=encoded_len)
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# b, c, t -> b, t, c
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encoded = self.proj(encoded.transpose(1, 2))
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if return_encoder_emb:
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return encoded, encoded_len, encoder_emb.transpose(1, 2)
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else:
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return encoded, encoded_len
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class IdentityConnector(nn.Module):
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"""User to pass encoder's representations as-is to the LLM."""
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def __init__(
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self,
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*args,
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**kwargs,
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):
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super().__init__()
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def forward(self, audio_signal, length=None, *args, **kwargs):
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return audio_signal, length
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def _set_encoder_activation_checkpointing(encoder: nn.Module, enabled: bool) -> None:
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"""Wrap the encoder's subsampling front-end and each transformer layer with
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``checkpoint_wrapper`` when enabled.
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Covers ``encoder.pre_encode`` (the Conformer fbank→subsampled-activation
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module: ``ConvSubsampling`` / ``StackingSubsampling`` / ``nn.Linear``) and
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each entry in ``encoder.layers``. Missing attributes are skipped so
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non-Conformer architectures degrade gracefully. No-op when ``enabled`` is
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False.
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"""
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if not enabled:
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return
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from torch.distributed.algorithms._checkpoint.checkpoint_wrapper import checkpoint_wrapper
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pre_encode = getattr(encoder, "pre_encode", None)
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# ConformerEncoder.forward dispatches on ``isinstance(pre_encode, nn.Linear)``
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# to choose between positional and (x=, lengths=) kwargs. Wrapping a Linear
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# hides its type and routes it to the wrong branch, so skip that case — the
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# memory win is negligible anyway (one linear vs. a conv/stacking stack).
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if pre_encode is not None and not isinstance(pre_encode, nn.Linear):
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encoder.pre_encode = checkpoint_wrapper(pre_encode)
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layers = getattr(encoder, "layers", None)
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if layers is not None:
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for i in range(len(layers)):
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layers[i] = checkpoint_wrapper(layers[i])
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class AudioTranscriptionPerceptionModule(NeuralModule, Exportable):
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"""Audio perception module that consists of audio encoder(s) and modality adapter."""
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@property
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def token_equivalent_duration(self) -> float:
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"""
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Returns the audio duration corresponding to a single frame/token in the output
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of this module.
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"""
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frame_shift = self.preprocessor.featurizer.hop_length / self.preprocessor.featurizer.sample_rate
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encoder_subsampling = self.encoder.subsampling_factor
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adapter_subsampling = getattr(self.modality_adapter, "subsampling_factor", 1.0)
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return frame_shift * encoder_subsampling * adapter_subsampling
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@property
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def encoder(self) -> nn.Module:
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return self.asr.encoder
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@property
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def preprocessor(self) -> nn.Module:
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return self.asr.preprocessor
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def __init__(self, cfg: DictConfig, pretrained_asr: str):
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from nemo.collections.speechlm2.parts.pretrained import load_pretrained_nemo
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super().__init__()
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# Initialize components
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self.cfg = cfg
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self.asr = load_pretrained_nemo(ASRModel, pretrained_asr)
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with open_dict(self.cfg):
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self.cfg.asr = self.asr.cfg
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# self.asr = ASRModel.from_config_dict(cfg.asr)
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self.spec_augmentation = None
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if 'spec_augment' in cfg and cfg.spec_augment is not None:
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self.spec_augmentation = self.from_config_dict(cfg.spec_augment)
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self.modality_adapter = self.from_config_dict(cfg.modality_adapter)
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if isinstance(self.modality_adapter, (QformerConnector, MultiLayerProjectionConnector)):
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self.encoder_multilayer = ConformerMultiLayerFeatureExtractor(
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self.asr.encoder,
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layer_idx_list=cfg.modality_adapter.target_layer_ids,
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detach=False,
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convert_to_cpu=False,
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include_final_output=cfg.modality_adapter.get("include_final_output", True),
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)
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if 'output_dim' not in cfg.modality_adapter and "d_model" in cfg.modality_adapter: # e.g., conformer encoder
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self.proj = nn.Linear(cfg.modality_adapter.d_model, cfg.output_dim)
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else:
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self.proj = nn.Identity()
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def set_activation_checkpointing(self, enabled: bool) -> None:
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"""Enable/disable activation checkpointing on the encoder's transformer layers.
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When ``enabled`` is True, wraps each layer in ``self.encoder.layers`` with
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``torch.distributed.algorithms._checkpoint.checkpoint_wrapper``. Must be
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called before FSDP2 sharding. When ``enabled`` is False, this is a no-op.
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"""
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_set_encoder_activation_checkpointing(self.encoder, enabled)
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def maybe_preprocess_audio(
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self,
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input_signal=None,
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input_signal_length=None,
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processed_signal=None,
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processed_signal_length=None,
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):
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has_input_signal = input_signal is not None and input_signal_length is not None
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has_processed_signal = processed_signal is not None and processed_signal_length is not None
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if (has_input_signal ^ has_processed_signal) is False:
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raise ValueError(
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f"{self.__class__} Arguments ``input_signal`` and ``input_signal_length`` are mutually exclusive "
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" with ``processed_signal`` and ``processed_signal_len`` arguments."
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)
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if not has_processed_signal:
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processed_signal, processed_signal_length = self.preprocessor(
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input_signal=input_signal,
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length=input_signal_length,
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)
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return processed_signal, processed_signal_length
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def forward_encoder(
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self,
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input_signal=None,
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input_signal_length=None,
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processed_signal=None,
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processed_signal_length=None,
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):
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processed_signal, processed_signal_length = self.maybe_preprocess_audio(
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input_signal, input_signal_length, processed_signal, processed_signal_length
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)
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if self.spec_augmentation is not None and self.training:
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processed_signal = self.spec_augmentation(input_spec=processed_signal, length=processed_signal_length)
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if isinstance(self.modality_adapter, (QformerConnector, MultiLayerProjectionConnector)):
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encoded, encoded_len = self.encoder_multilayer(
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audio_signal=processed_signal, length=processed_signal_length
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)
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else:
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encoded, encoded_len = self.encoder(audio_signal=processed_signal, length=processed_signal_length)
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return encoded, encoded_len
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def transcribe_encoded(self, encoded, encoded_len):
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if isinstance(encoded, list):
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encoded = encoded[-1]
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encoded_len = encoded_len[-1]
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return self.asr._transcribe_output_processing(
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outputs={"encoded": encoded, "encoded_len": encoded_len}, trcfg=TranscribeConfig()
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)
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# disable type checks to avoid type-check errors when using Conformer as modality adapter
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@typecheck.disable_checks()
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def forward(
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self,
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input_signal=None,
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input_signal_length=None,
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processed_signal=None,
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processed_signal_length=None,
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encoded=None,
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encoded_len=None,
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):
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if encoded is None and encoded_len is None:
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encoded, encoded_len = self.forward_encoder(
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input_signal=input_signal,
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input_signal_length=input_signal_length,
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processed_signal=processed_signal,
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processed_signal_length=processed_signal_length,
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)
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encoded, encoded_len = self.modality_adapter(audio_signal=encoded, length=encoded_len)
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# b, c, t -> b, t, c
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encoded = self.proj(encoded.transpose(1, 2))
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return encoded, encoded_len
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class QformerConnector(nn.Module):
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def __init__(
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self,
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prompt_size: int,
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target_layer_ids: list[int],
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qformer_num_hidden_layers: int,
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encoder_config: DictConfig,
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llm_config: DictConfig,
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include_final_output: bool = True,
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):
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super().__init__()
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self.prompt_size = prompt_size
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self.target_layer_ids = target_layer_ids
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self.include_final_output = include_final_output
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self.qformer_num_hidden_layers = qformer_num_hidden_layers
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self.encoder_config = encoder_config
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self.llm_config = llm_config
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num_inputs = len(self.target_layer_ids) + int(self.include_final_output)
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self.layer_prompts = nn.ParameterList(
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[nn.Parameter(torch.randn(1, self.prompt_size, self.encoder_config.d_model)) for _ in range(num_inputs)]
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)
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self.layer_weights = nn.Parameter(torch.zeros(self.prompt_size, num_inputs, dtype=torch.float))
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qformer_config = BertConfig()
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qformer_config.num_hidden_layers = self.qformer_num_hidden_layers
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qformer_config.num_attention_heads = self.encoder_config.encoder_attention_heads
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qformer_config.hidden_size = self.encoder_config.d_model
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qformer_config.add_cross_attention = True
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qformer_config.is_decoder = True
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if hasattr(qformer_config, "_attn_implementation"): # fix for newer transformers versions
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qformer_config._attn_implementation = "eager"
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self.qformer = BertEncoder(qformer_config)
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self.proj = nn.Sequential(
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nn.LayerNorm(self.encoder_config.d_model),
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nn.Linear(self.encoder_config.d_model, self.llm_config.hidden_size), # project to llm hidden size
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)
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def forward(self, audio_signal: list[torch.Tensor], length):
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"""
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input:
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audio_signal: layerwise hidden states from the encoder
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"""
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layer_prompt_outputs = []
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expected_num = len(self.target_layer_ids) + int(self.include_final_output)
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assert (
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len(audio_signal) == expected_num
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), f"Expected {expected_num} activations from encoder layers but got {len(audio_signal)}."
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for idx, encoder_hidden_state in enumerate(audio_signal):
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layer_prompt = self.layer_prompts[idx].expand(encoder_hidden_state.size(0), -1, -1)
|
|
qformer_output = self.qformer(
|
|
hidden_states=layer_prompt,
|
|
encoder_hidden_states=encoder_hidden_state.transpose(1, 2),
|
|
)
|
|
layer_prompt_output = qformer_output.last_hidden_state
|
|
layer_prompt_outputs.append(layer_prompt_output)
|
|
|
|
layer_prompt_outputs = torch.stack(layer_prompt_outputs, dim=0)
|
|
layer_prompt_outputs = layer_prompt_outputs.permute(1, 2, 0, 3)
|
|
norm_weights = torch.nn.functional.softmax(self.layer_weights, dim=-1).unsqueeze(-1)
|
|
output = (layer_prompt_outputs * norm_weights).sum(dim=2) # (b, prompt_size, d_llm)
|
|
output = self.proj(output)
|
|
output = output.transpose(1, 2)
|
|
|
|
return output, torch.tensor([output.shape[1]] * output.shape[0], device=output.device, dtype=torch.long)
|
|
|
|
|
|
class MultiLayerProjectionConnector(nn.Module):
|
|
"""User to pass encoder's representations as-is to the LLM."""
|
|
|
|
def __init__(
|
|
self,
|
|
target_layer_ids: list[int],
|
|
input_dim: int,
|
|
output_dim: int,
|
|
include_final_output: bool = True,
|
|
):
|
|
super().__init__()
|
|
self.target_layer_ids = target_layer_ids
|
|
self.include_final_output = include_final_output
|
|
self.input_dim = input_dim
|
|
self.output_dim = output_dim
|
|
num_inputs = len(self.target_layer_ids) + int(self.include_final_output)
|
|
self.proj = torch.nn.Linear(self.input_dim * num_inputs, self.output_dim)
|
|
|
|
def forward(self, audio_signal: list[torch.Tensor], length):
|
|
expected_num = len(self.target_layer_ids) + int(self.include_final_output)
|
|
assert (
|
|
len(audio_signal) == expected_num
|
|
), f"Expected {expected_num} activations from encoder layers but got {len(audio_signal)}."
|
|
audio_signal = torch.cat(audio_signal, dim=1).transpose(1, 2)
|
|
projected = self.proj(audio_signal).transpose(1, 2)
|
|
return projected, length[0]
|