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from collections import defaultdict |
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from copy import deepcopy |
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from dataclasses import dataclass, field |
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from itertools import chain |
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import logging |
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import math |
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from pathlib import Path |
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import random |
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import re |
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import typing as tp |
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import warnings |
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import einops |
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from num2words import num2words |
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import spacy |
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from transformers import RobertaTokenizer, T5EncoderModel, T5Tokenizer |
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import torch |
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from torch import nn |
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import torch.nn.functional as F |
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from torch.nn.utils.rnn import pad_sequence |
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from .chroma import ChromaExtractor |
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from .streaming import StreamingModule |
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from .transformer import create_sin_embedding |
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from ..data.audio import audio_read |
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from ..data.audio_dataset import SegmentInfo |
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from ..data.audio_utils import convert_audio |
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from ..environment import AudioCraftEnvironment |
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from ..quantization import ResidualVectorQuantizer |
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from ..utils.autocast import TorchAutocast |
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from ..utils.cache import EmbeddingCache |
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from ..utils.utils import collate, hash_trick, length_to_mask, load_clap_state_dict, warn_once |
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logger = logging.getLogger(__name__) |
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TextCondition = tp.Optional[str] |
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ConditionType = tp.Tuple[torch.Tensor, torch.Tensor] |
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class WavCondition(tp.NamedTuple): |
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wav: torch.Tensor |
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length: torch.Tensor |
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sample_rate: tp.List[int] |
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path: tp.List[tp.Optional[str]] = [] |
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seek_time: tp.List[tp.Optional[float]] = [] |
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class JointEmbedCondition(tp.NamedTuple): |
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wav: torch.Tensor |
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text: tp.List[tp.Optional[str]] |
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length: torch.Tensor |
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sample_rate: tp.List[int] |
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path: tp.List[tp.Optional[str]] = [] |
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seek_time: tp.List[tp.Optional[float]] = [] |
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@dataclass |
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class ConditioningAttributes: |
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text: tp.Dict[str, tp.Optional[str]] = field(default_factory=dict) |
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wav: tp.Dict[str, WavCondition] = field(default_factory=dict) |
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joint_embed: tp.Dict[str, JointEmbedCondition] = field(default_factory=dict) |
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def __getitem__(self, item): |
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return getattr(self, item) |
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@property |
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def text_attributes(self): |
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return self.text.keys() |
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@property |
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def wav_attributes(self): |
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return self.wav.keys() |
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@property |
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def joint_embed_attributes(self): |
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return self.joint_embed.keys() |
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@property |
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def attributes(self): |
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return { |
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"text": self.text_attributes, |
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"wav": self.wav_attributes, |
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"joint_embed": self.joint_embed_attributes, |
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} |
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def to_flat_dict(self): |
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return { |
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**{f"text.{k}": v for k, v in self.text.items()}, |
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**{f"wav.{k}": v for k, v in self.wav.items()}, |
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**{f"joint_embed.{k}": v for k, v in self.joint_embed.items()} |
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} |
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@classmethod |
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def from_flat_dict(cls, x): |
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out = cls() |
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for k, v in x.items(): |
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kind, att = k.split(".") |
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out[kind][att] = v |
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return out |
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class SegmentWithAttributes(SegmentInfo): |
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"""Base class for all dataclasses that are used for conditioning. |
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All child classes should implement `to_condition_attributes` that converts |
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the existing attributes to a dataclass of type ConditioningAttributes. |
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""" |
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def to_condition_attributes(self) -> ConditioningAttributes: |
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raise NotImplementedError() |
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def nullify_condition(condition: ConditionType, dim: int = 1): |
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"""Transform an input condition to a null condition. |
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The way it is done by converting it to a single zero vector similarly |
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to how it is done inside WhiteSpaceTokenizer and NoopTokenizer. |
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Args: |
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condition (ConditionType): A tuple of condition and mask (tuple[torch.Tensor, torch.Tensor]) |
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dim (int): The dimension that will be truncated (should be the time dimension) |
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WARNING!: dim should not be the batch dimension! |
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Returns: |
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ConditionType: A tuple of null condition and mask |
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""" |
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assert dim != 0, "dim cannot be the batch dimension!" |
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assert isinstance(condition, tuple) and \ |
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isinstance(condition[0], torch.Tensor) and \ |
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isinstance(condition[1], torch.Tensor), "'nullify_condition' got an unexpected input type!" |
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cond, mask = condition |
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B = cond.shape[0] |
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last_dim = cond.dim() - 1 |
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out = cond.transpose(dim, last_dim) |
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out = 0. * out[..., :1] |
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out = out.transpose(dim, last_dim) |
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mask = torch.zeros((B, 1), device=out.device).int() |
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assert cond.dim() == out.dim() |
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return out, mask |
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def nullify_wav(cond: WavCondition) -> WavCondition: |
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"""Transform a WavCondition to a nullified WavCondition. |
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It replaces the wav by a null tensor, forces its length to 0, and replaces metadata by dummy attributes. |
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Args: |
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cond (WavCondition): Wav condition with wav, tensor of shape [B, T]. |
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Returns: |
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WavCondition: Nullified wav condition. |
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""" |
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null_wav, _ = nullify_condition((cond.wav, torch.zeros_like(cond.wav)), dim=cond.wav.dim() - 1) |
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return WavCondition( |
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wav=null_wav, |
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length=torch.tensor([0] * cond.wav.shape[0], device=cond.wav.device), |
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sample_rate=cond.sample_rate, |
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path=[None] * cond.wav.shape[0], |
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seek_time=[None] * cond.wav.shape[0], |
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) |
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def nullify_joint_embed(embed: JointEmbedCondition) -> JointEmbedCondition: |
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"""Nullify the joint embedding condition by replacing it by a null tensor, forcing its length to 0, |
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and replacing metadata by dummy attributes. |
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Args: |
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cond (JointEmbedCondition): Joint embedding condition with wav and text, wav tensor of shape [B, C, T]. |
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""" |
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null_wav, _ = nullify_condition((embed.wav, torch.zeros_like(embed.wav)), dim=embed.wav.dim() - 1) |
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return JointEmbedCondition( |
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wav=null_wav, text=[None] * len(embed.text), |
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length=torch.LongTensor([0]).to(embed.wav.device), |
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sample_rate=embed.sample_rate, |
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path=[None] * embed.wav.shape[0], |
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seek_time=[0] * embed.wav.shape[0], |
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) |
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class Tokenizer: |
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"""Base tokenizer implementation |
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(in case we want to introduce more advances tokenizers in the future). |
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""" |
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def __call__(self, texts: tp.List[tp.Optional[str]]) -> tp.Tuple[torch.Tensor, torch.Tensor]: |
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raise NotImplementedError() |
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class WhiteSpaceTokenizer(Tokenizer): |
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"""This tokenizer should be used for natural language descriptions. |
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For example: |
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["he didn't, know he's going home.", 'shorter sentence'] => |
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[[78, 62, 31, 4, 78, 25, 19, 34], |
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[59, 77, 0, 0, 0, 0, 0, 0]] |
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""" |
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PUNCTUATION = "?:!.,;" |
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def __init__(self, n_bins: int, pad_idx: int = 0, language: str = "en_core_web_sm", |
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lemma: bool = True, stopwords: bool = True) -> None: |
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self.n_bins = n_bins |
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self.pad_idx = pad_idx |
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self.lemma = lemma |
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self.stopwords = stopwords |
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try: |
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self.nlp = spacy.load(language) |
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except IOError: |
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spacy.cli.download(language) |
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self.nlp = spacy.load(language) |
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@tp.no_type_check |
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def __call__(self, texts: tp.List[tp.Optional[str]], |
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return_text: bool = False) -> tp.Tuple[torch.Tensor, torch.Tensor]: |
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"""Take a list of strings and convert them to a tensor of indices. |
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Args: |
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texts (list[str]): List of strings. |
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return_text (bool, optional): Whether to return text as additional tuple item. Defaults to False. |
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Returns: |
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tuple[torch.Tensor, torch.Tensor]: |
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- Indices of words in the LUT. |
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- And a mask indicating where the padding tokens are |
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""" |
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output, lengths = [], [] |
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texts = deepcopy(texts) |
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for i, text in enumerate(texts): |
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if text is None: |
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output.append(torch.Tensor([self.pad_idx])) |
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lengths.append(0) |
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continue |
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text = re.sub(r"(\d+)", lambda x: num2words(int(x.group(0))), text) |
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text = self.nlp(text) |
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if self.stopwords: |
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text = [w for w in text if not w.is_stop] |
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text = [w for w in text if w.text not in self.PUNCTUATION] |
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text = [getattr(t, "lemma_" if self.lemma else "text") for t in text] |
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texts[i] = " ".join(text) |
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lengths.append(len(text)) |
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tokens = torch.Tensor([hash_trick(w, self.n_bins) for w in text]) |
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output.append(tokens) |
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mask = length_to_mask(torch.IntTensor(lengths)).int() |
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padded_output = pad_sequence(output, padding_value=self.pad_idx).int().t() |
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if return_text: |
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return padded_output, mask, texts |
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return padded_output, mask |
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class NoopTokenizer(Tokenizer): |
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"""This tokenizer should be used for global conditioners such as: artist, genre, key, etc. |
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The difference between this and WhiteSpaceTokenizer is that NoopTokenizer does not split |
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strings, so "Jeff Buckley" will get it's own index. Whereas WhiteSpaceTokenizer will |
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split it to ["Jeff", "Buckley"] and return an index per word. |
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For example: |
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["Queen", "ABBA", "Jeff Buckley"] => [43, 55, 101] |
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["Metal", "Rock", "Classical"] => [0, 223, 51] |
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""" |
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def __init__(self, n_bins: int, pad_idx: int = 0): |
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self.n_bins = n_bins |
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self.pad_idx = pad_idx |
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def __call__(self, texts: tp.List[tp.Optional[str]]) -> tp.Tuple[torch.Tensor, torch.Tensor]: |
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output, lengths = [], [] |
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for text in texts: |
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if text is None: |
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output.append(self.pad_idx) |
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lengths.append(0) |
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else: |
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output.append(hash_trick(text, self.n_bins)) |
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lengths.append(1) |
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tokens = torch.LongTensor(output).unsqueeze(1) |
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mask = length_to_mask(torch.IntTensor(lengths)).int() |
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return tokens, mask |
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class BaseConditioner(nn.Module): |
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"""Base model for all conditioner modules. |
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We allow the output dim to be different than the hidden dim for two reasons: |
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1) keep our LUTs small when the vocab is large; |
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2) make all condition dims consistent. |
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Args: |
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dim (int): Hidden dim of the model. |
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output_dim (int): Output dim of the conditioner. |
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""" |
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def __init__(self, dim: int, output_dim: int): |
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super().__init__() |
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self.dim = dim |
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self.output_dim = output_dim |
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self.output_proj = nn.Linear(dim, output_dim) |
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def tokenize(self, *args, **kwargs) -> tp.Any: |
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"""Should be any part of the processing that will lead to a synchronization |
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point, e.g. BPE tokenization with transfer to the GPU. |
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The returned value will be saved and return later when calling forward(). |
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""" |
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raise NotImplementedError() |
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def forward(self, inputs: tp.Any) -> ConditionType: |
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"""Gets input that should be used as conditioning (e.g, genre, description or a waveform). |
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Outputs a ConditionType, after the input data was embedded as a dense vector. |
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Returns: |
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ConditionType: |
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- A tensor of size [B, T, D] where B is the batch size, T is the length of the |
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output embedding and D is the dimension of the embedding. |
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- And a mask indicating where the padding tokens. |
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""" |
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raise NotImplementedError() |
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class TextConditioner(BaseConditioner): |
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... |
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class LUTConditioner(TextConditioner): |
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"""Lookup table TextConditioner. |
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Args: |
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n_bins (int): Number of bins. |
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dim (int): Hidden dim of the model (text-encoder/LUT). |
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output_dim (int): Output dim of the conditioner. |
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tokenizer (str): Name of the tokenizer. |
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pad_idx (int, optional): Index for padding token. Defaults to 0. |
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""" |
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def __init__(self, n_bins: int, dim: int, output_dim: int, tokenizer: str, pad_idx: int = 0): |
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super().__init__(dim, output_dim) |
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self.embed = nn.Embedding(n_bins, dim) |
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self.tokenizer: Tokenizer |
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if tokenizer == 'whitespace': |
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self.tokenizer = WhiteSpaceTokenizer(n_bins, pad_idx=pad_idx) |
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elif tokenizer == 'noop': |
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self.tokenizer = NoopTokenizer(n_bins, pad_idx=pad_idx) |
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else: |
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raise ValueError(f"unrecognized tokenizer `{tokenizer}`.") |
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def tokenize(self, x: tp.List[tp.Optional[str]]) -> tp.Tuple[torch.Tensor, torch.Tensor]: |
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device = self.embed.weight.device |
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tokens, mask = self.tokenizer(x) |
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tokens, mask = tokens.to(device), mask.to(device) |
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return tokens, mask |
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def forward(self, inputs: tp.Tuple[torch.Tensor, torch.Tensor]) -> ConditionType: |
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tokens, mask = inputs |
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embeds = self.embed(tokens) |
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embeds = self.output_proj(embeds) |
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embeds = (embeds * mask.unsqueeze(-1)) |
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return embeds, mask |
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class T5Conditioner(TextConditioner): |
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"""T5-based TextConditioner. |
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Args: |
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name (str): Name of the T5 model. |
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output_dim (int): Output dim of the conditioner. |
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finetune (bool): Whether to fine-tune T5 at train time. |
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device (str): Device for T5 Conditioner. |
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autocast_dtype (tp.Optional[str], optional): Autocast dtype. |
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word_dropout (float, optional): Word dropout probability. |
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normalize_text (bool, optional): Whether to apply text normalization. |
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""" |
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MODELS = ["t5-small", "t5-base", "t5-large", "t5-3b", "t5-11b", |
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"google/flan-t5-small", "google/flan-t5-base", "google/flan-t5-large", |
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"google/flan-t5-xl", "google/flan-t5-xxl"] |
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MODELS_DIMS = { |
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"t5-small": 512, |
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"t5-base": 768, |
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"t5-large": 1024, |
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"t5-3b": 1024, |
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"t5-11b": 1024, |
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"google/flan-t5-small": 512, |
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"google/flan-t5-base": 768, |
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"google/flan-t5-large": 1024, |
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"google/flan-t5-3b": 1024, |
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"google/flan-t5-11b": 1024, |
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} |
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def __init__(self, name: str, output_dim: int, finetune: bool, device: str, |
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autocast_dtype: tp.Optional[str] = 'float32', word_dropout: float = 0., |
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normalize_text: bool = False): |
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assert name in self.MODELS, f"Unrecognized t5 model name (should in {self.MODELS})" |
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super().__init__(self.MODELS_DIMS[name], output_dim) |
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self.device = device |
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self.name = name |
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self.finetune = finetune |
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self.word_dropout = word_dropout |
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if autocast_dtype is None or self.device == 'cpu': |
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self.autocast = TorchAutocast(enabled=False) |
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if self.device != 'cpu': |
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logger.warning("T5 has no autocast, this might lead to NaN") |
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else: |
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dtype = getattr(torch, autocast_dtype) |
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assert isinstance(dtype, torch.dtype) |
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logger.info(f"T5 will be evaluated with autocast as {autocast_dtype}") |
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self.autocast = TorchAutocast(enabled=True, device_type=self.device, dtype=dtype) |
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previous_level = logging.root.manager.disable |
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logging.disable(logging.ERROR) |
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with warnings.catch_warnings(): |
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warnings.simplefilter("ignore") |
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try: |
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self.t5_tokenizer = T5Tokenizer.from_pretrained(name) |
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t5 = T5EncoderModel.from_pretrained(name).train(mode=finetune) |
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finally: |
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logging.disable(previous_level) |
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if finetune: |
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self.t5 = t5 |
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else: |
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self.__dict__['t5'] = t5.to(device) |
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self.normalize_text = normalize_text |
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if normalize_text: |
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self.text_normalizer = WhiteSpaceTokenizer(1, lemma=True, stopwords=True) |
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|
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def tokenize(self, x: tp.List[tp.Optional[str]]) -> tp.Dict[str, torch.Tensor]: |
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entries: tp.List[str] = [xi if xi is not None else "" for xi in x] |
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if self.normalize_text: |
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_, _, entries = self.text_normalizer(entries, return_text=True) |
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if self.word_dropout > 0. and self.training: |
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new_entries = [] |
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for entry in entries: |
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words = [word for word in entry.split(" ") if random.random() >= self.word_dropout] |
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new_entries.append(" ".join(words)) |
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entries = new_entries |
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empty_idx = torch.LongTensor([i for i, xi in enumerate(entries) if xi == ""]) |
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|
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inputs = self.t5_tokenizer(entries, return_tensors='pt', padding=True).to(self.device) |
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mask = inputs['attention_mask'] |
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mask[empty_idx, :] = 0 |
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return inputs |
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def forward(self, inputs: tp.Dict[str, torch.Tensor]) -> ConditionType: |
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mask = inputs['attention_mask'] |
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with torch.set_grad_enabled(self.finetune), self.autocast: |
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embeds = self.t5(**inputs).last_hidden_state |
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embeds = self.output_proj(embeds.to(self.output_proj.weight)) |
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embeds = (embeds * mask.unsqueeze(-1)) |
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return embeds, mask |
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|
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class WaveformConditioner(BaseConditioner): |
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"""Base class for all conditioners that take a waveform as input. |
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Classes that inherit must implement `_get_wav_embedding` that outputs |
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a continuous tensor, and `_downsampling_factor` that returns the down-sampling |
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factor of the embedding model. |
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|
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Args: |
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dim (int): The internal representation dimension. |
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output_dim (int): Output dimension. |
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device (tp.Union[torch.device, str]): Device. |
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""" |
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def __init__(self, dim: int, output_dim: int, device: tp.Union[torch.device, str]): |
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super().__init__(dim, output_dim) |
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self.device = device |
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self._use_masking = True |
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def tokenize(self, x: WavCondition) -> WavCondition: |
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wav, length, sample_rate, path, seek_time = x |
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assert length is not None |
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return WavCondition(wav.to(self.device), length.to(self.device), sample_rate, path, seek_time) |
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|
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def _get_wav_embedding(self, x: WavCondition) -> torch.Tensor: |
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"""Gets as input a WavCondition and returns a dense embedding.""" |
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raise NotImplementedError() |
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|
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def _downsampling_factor(self): |
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"""Returns the downsampling factor of the embedding model.""" |
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raise NotImplementedError() |
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|
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def forward(self, x: WavCondition) -> ConditionType: |
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"""Extract condition embedding and mask from a waveform and its metadata. |
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Args: |
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x (WavCondition): Waveform condition containing raw waveform and metadata. |
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Returns: |
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ConditionType: a dense vector representing the conditioning along with its mask |
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""" |
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wav, lengths, *_ = x |
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with torch.no_grad(): |
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embeds = self._get_wav_embedding(x) |
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embeds = embeds.to(self.output_proj.weight) |
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embeds = self.output_proj(embeds) |
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|
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if lengths is not None and self._use_masking: |
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lengths = lengths / self._downsampling_factor() |
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mask = length_to_mask(lengths, max_len=embeds.shape[1]).int() |
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else: |
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mask = torch.ones_like(embeds[..., 0]) |
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embeds = (embeds * mask.unsqueeze(-1)) |
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return embeds, mask |
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|
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class ChromaStemConditioner(WaveformConditioner): |
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"""Chroma conditioner based on stems. |
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The ChromaStemConditioner uses DEMUCS to first filter out drums and bass, as |
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the drums and bass often dominate the chroma leading to the chroma features |
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not containing information about the melody. |
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|
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Args: |
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output_dim (int): Output dimension for the conditioner. |
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sample_rate (int): Sample rate for the chroma extractor. |
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n_chroma (int): Number of chroma bins for the chroma extractor. |
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radix2_exp (int): Size of stft window for the chroma extractor (power of 2, e.g. 12 -> 2^12). |
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duration (int): duration used during training. This is later used for correct padding |
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in case we are using chroma as prefix. |
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match_len_on_eval (bool, optional): if True then all chromas are padded to the training |
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duration. Defaults to False. |
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eval_wavs (str, optional): path to a dataset manifest with waveform, this waveforms are used as |
|
conditions during eval (for cases where we don't want to leak test conditions like MusicCaps). |
|
Defaults to None. |
|
n_eval_wavs (int, optional): limits the number of waveforms used for conditioning. Defaults to 0. |
|
device (tp.Union[torch.device, str], optional): Device for the conditioner. |
|
**kwargs: Additional parameters for the chroma extractor. |
|
""" |
|
def __init__(self, output_dim: int, sample_rate: int, n_chroma: int, radix2_exp: int, |
|
duration: float, match_len_on_eval: bool = True, eval_wavs: tp.Optional[str] = None, |
|
n_eval_wavs: int = 0, cache_path: tp.Optional[tp.Union[str, Path]] = None, |
|
device: tp.Union[torch.device, str] = 'cpu', **kwargs): |
|
from demucs import pretrained |
|
super().__init__(dim=n_chroma, output_dim=output_dim, device=device) |
|
self.autocast = TorchAutocast(enabled=device != 'cpu', device_type=self.device, dtype=torch.float32) |
|
self.sample_rate = sample_rate |
|
self.match_len_on_eval = match_len_on_eval |
|
if match_len_on_eval: |
|
self._use_masking = False |
|
self.duration = duration |
|
self.__dict__['demucs'] = pretrained.get_model('htdemucs').to(device) |
|
stem_sources: list = self.demucs.sources |
|
self.stem_indices = torch.LongTensor([stem_sources.index('vocals'), stem_sources.index('other')]).to(device) |
|
self.chroma = ChromaExtractor(sample_rate=sample_rate, n_chroma=n_chroma, |
|
radix2_exp=radix2_exp, **kwargs).to(device) |
|
self.chroma_len = self._get_chroma_len() |
|
self.eval_wavs: tp.Optional[torch.Tensor] = self._load_eval_wavs(eval_wavs, n_eval_wavs) |
|
self.cache = None |
|
if cache_path is not None: |
|
self.cache = EmbeddingCache(Path(cache_path) / 'wav', self.device, |
|
compute_embed_fn=self._get_full_chroma_for_cache, |
|
extract_embed_fn=self._extract_chroma_chunk) |
|
|
|
def _downsampling_factor(self) -> int: |
|
return self.chroma.winhop |
|
|
|
def _load_eval_wavs(self, path: tp.Optional[str], num_samples: int) -> tp.Optional[torch.Tensor]: |
|
"""Load pre-defined waveforms from a json. |
|
These waveforms will be used for chroma extraction during evaluation. |
|
This is done to make the evaluation on MusicCaps fair (we shouldn't see the chromas of MusicCaps). |
|
""" |
|
if path is None: |
|
return None |
|
|
|
logger.info(f"Loading evaluation wavs from {path}") |
|
from audiocraft.data.audio_dataset import AudioDataset |
|
dataset: AudioDataset = AudioDataset.from_meta( |
|
path, segment_duration=self.duration, min_audio_duration=self.duration, |
|
sample_rate=self.sample_rate, channels=1) |
|
|
|
if len(dataset) > 0: |
|
eval_wavs = dataset.collater([dataset[i] for i in range(num_samples)]).to(self.device) |
|
logger.info(f"Using {len(eval_wavs)} evaluation wavs for chroma-stem conditioner") |
|
return eval_wavs |
|
else: |
|
raise ValueError("Could not find evaluation wavs, check lengths of wavs") |
|
|
|
def reset_eval_wavs(self, eval_wavs: tp.Optional[torch.Tensor]) -> None: |
|
self.eval_wavs = eval_wavs |
|
|
|
def has_eval_wavs(self) -> bool: |
|
return self.eval_wavs is not None |
|
|
|
def _sample_eval_wavs(self, num_samples: int) -> torch.Tensor: |
|
"""Sample wavs from a predefined list.""" |
|
assert self.eval_wavs is not None, "Cannot sample eval wavs as no eval wavs provided." |
|
total_eval_wavs = len(self.eval_wavs) |
|
out = self.eval_wavs |
|
if num_samples > total_eval_wavs: |
|
out = self.eval_wavs.repeat(num_samples // total_eval_wavs + 1, 1, 1) |
|
return out[torch.randperm(len(out))][:num_samples] |
|
|
|
def _get_chroma_len(self) -> int: |
|
"""Get length of chroma during training.""" |
|
dummy_wav = torch.zeros((1, int(self.sample_rate * self.duration)), device=self.device) |
|
dummy_chr = self.chroma(dummy_wav) |
|
return dummy_chr.shape[1] |
|
|
|
@torch.no_grad() |
|
def _get_stemmed_wav(self, wav: torch.Tensor, sample_rate: int) -> torch.Tensor: |
|
"""Get parts of the wav that holds the melody, extracting the main stems from the wav.""" |
|
from demucs.apply import apply_model |
|
from demucs.audio import convert_audio |
|
with self.autocast: |
|
wav = convert_audio( |
|
wav, sample_rate, self.demucs.samplerate, self.demucs.audio_channels) |
|
stems = apply_model(self.demucs, wav, device=self.device) |
|
stems = stems[:, self.stem_indices] |
|
mix_wav = stems.sum(1) |
|
mix_wav = convert_audio(mix_wav, self.demucs.samplerate, self.sample_rate, 1) |
|
return mix_wav |
|
|
|
@torch.no_grad() |
|
def _extract_chroma(self, wav: torch.Tensor) -> torch.Tensor: |
|
"""Extract chroma features from the waveform.""" |
|
with self.autocast: |
|
return self.chroma(wav) |
|
|
|
@torch.no_grad() |
|
def _compute_wav_embedding(self, wav: torch.Tensor, sample_rate: int) -> torch.Tensor: |
|
"""Compute wav embedding, applying stem and chroma extraction.""" |
|
|
|
if wav.shape[-1] == 1: |
|
return self._extract_chroma(wav) |
|
stems = self._get_stemmed_wav(wav, sample_rate) |
|
chroma = self._extract_chroma(stems) |
|
return chroma |
|
|
|
@torch.no_grad() |
|
def _get_full_chroma_for_cache(self, path: tp.Union[str, Path], x: WavCondition, idx: int) -> torch.Tensor: |
|
"""Extract chroma from the whole audio waveform at the given path.""" |
|
wav, sr = audio_read(path) |
|
wav = wav[None].to(self.device) |
|
wav = convert_audio(wav, sr, self.sample_rate, to_channels=1) |
|
chroma = self._compute_wav_embedding(wav, self.sample_rate)[0] |
|
return chroma |
|
|
|
def _extract_chroma_chunk(self, full_chroma: torch.Tensor, x: WavCondition, idx: int) -> torch.Tensor: |
|
"""Extract a chunk of chroma from the full chroma derived from the full waveform.""" |
|
wav_length = x.wav.shape[-1] |
|
seek_time = x.seek_time[idx] |
|
assert seek_time is not None, ( |
|
"WavCondition seek_time is required " |
|
"when extracting chroma chunks from pre-computed chroma.") |
|
full_chroma = full_chroma.float() |
|
frame_rate = self.sample_rate / self._downsampling_factor() |
|
target_length = int(frame_rate * wav_length / self.sample_rate) |
|
index = int(frame_rate * seek_time) |
|
out = full_chroma[index: index + target_length] |
|
out = F.pad(out[None], (0, 0, 0, target_length - out.shape[0]))[0] |
|
return out.to(self.device) |
|
|
|
@torch.no_grad() |
|
def _get_wav_embedding(self, x: WavCondition) -> torch.Tensor: |
|
"""Get the wav embedding from the WavCondition. |
|
The conditioner will either extract the embedding on-the-fly computing it from the condition wav directly |
|
or will rely on the embedding cache to load the pre-computed embedding if relevant. |
|
""" |
|
sampled_wav: tp.Optional[torch.Tensor] = None |
|
if not self.training and self.eval_wavs is not None: |
|
warn_once(logger, "Using precomputed evaluation wavs!") |
|
sampled_wav = self._sample_eval_wavs(len(x.wav)) |
|
|
|
no_undefined_paths = all(p is not None for p in x.path) |
|
no_nullified_cond = x.wav.shape[-1] > 1 |
|
if sampled_wav is not None: |
|
chroma = self._compute_wav_embedding(sampled_wav, self.sample_rate) |
|
elif self.cache is not None and no_undefined_paths and no_nullified_cond: |
|
paths = [Path(p) for p in x.path if p is not None] |
|
chroma = self.cache.get_embed_from_cache(paths, x) |
|
else: |
|
assert all(sr == x.sample_rate[0] for sr in x.sample_rate), "All sample rates in batch should be equal." |
|
chroma = self._compute_wav_embedding(x.wav, x.sample_rate[0]) |
|
|
|
if self.match_len_on_eval: |
|
B, T, C = chroma.shape |
|
if T > self.chroma_len: |
|
chroma = chroma[:, :self.chroma_len] |
|
logger.debug(f"Chroma was truncated to match length! ({T} -> {chroma.shape[1]})") |
|
elif T < self.chroma_len: |
|
n_repeat = int(math.ceil(self.chroma_len / T)) |
|
chroma = chroma.repeat(1, n_repeat, 1) |
|
chroma = chroma[:, :self.chroma_len] |
|
logger.debug(f"Chroma was repeated to match length! ({T} -> {chroma.shape[1]})") |
|
|
|
return chroma |
|
|
|
def tokenize(self, x: WavCondition) -> WavCondition: |
|
"""Apply WavConditioner tokenization and populate cache if needed.""" |
|
x = super().tokenize(x) |
|
no_undefined_paths = all(p is not None for p in x.path) |
|
if self.cache is not None and no_undefined_paths: |
|
paths = [Path(p) for p in x.path if p is not None] |
|
self.cache.populate_embed_cache(paths, x) |
|
return x |
|
|
|
|
|
class JointEmbeddingConditioner(BaseConditioner): |
|
"""Joint embedding conditioning supporting both audio or text conditioning. |
|
|
|
Args: |
|
dim (int): Dimension. |
|
output_dim (int): Output dimension. |
|
device (str): Device. |
|
attribute (str): Attribute used by the conditioner. |
|
autocast_dtype (str): Autocast for the conditioner. |
|
quantize (bool): Whether to quantize the CLAP embedding. |
|
n_q (int): Number of residual quantizers (used if quantize is true). |
|
bins (int): Quantizers' codebooks size (used if quantize is true). |
|
kwargs: Additional parameters for residual vector quantizer. |
|
""" |
|
def __init__(self, dim: int, output_dim: int, device: str, attribute: str, |
|
autocast_dtype: tp.Optional[str] = 'float32', quantize: bool = True, |
|
n_q: int = 12, bins: int = 1024, **kwargs): |
|
super().__init__(dim=dim, output_dim=output_dim) |
|
self.device = device |
|
self.attribute = attribute |
|
if autocast_dtype is None or device == 'cpu': |
|
self.autocast = TorchAutocast(enabled=False) |
|
logger.warning("JointEmbeddingConditioner has no autocast, this might lead to NaN.") |
|
else: |
|
dtype = getattr(torch, autocast_dtype) |
|
assert isinstance(dtype, torch.dtype) |
|
logger.info(f"JointEmbeddingConditioner will be evaluated with autocast as {autocast_dtype}.") |
|
self.autocast = TorchAutocast(enabled=True, device_type=self.device, dtype=dtype) |
|
|
|
self.quantizer: tp.Optional[ResidualVectorQuantizer] = None |
|
if quantize: |
|
self.quantizer = ResidualVectorQuantizer(dim, n_q=n_q, bins=bins, **kwargs) |
|
|
|
def _get_embed(self, x: JointEmbedCondition) -> tp.Tuple[torch.Tensor, torch.Tensor]: |
|
"""Get joint embedding in latent space from the inputs. |
|
|
|
Returns: |
|
tuple[torch.Tensor, torch.Tensor]: Tensor for the latent embedding |
|
and corresponding empty indexes. |
|
""" |
|
raise NotImplementedError() |
|
|
|
def forward(self, x: JointEmbedCondition) -> ConditionType: |
|
with self.autocast: |
|
embed, empty_idx = self._get_embed(x) |
|
if self.quantizer is not None: |
|
embed = embed.view(-1, self.dim, 1) |
|
q_res = self.quantizer(embed, frame_rate=1) |
|
out_embed = q_res.x.view(-1, self.dim) |
|
else: |
|
out_embed = embed |
|
out_embed = self.output_proj(out_embed).view(-1, 1, self.output_dim) |
|
mask = torch.ones(*out_embed.shape[:2], device=out_embed.device) |
|
mask[empty_idx, :] = 0 |
|
out_embed = (out_embed * mask.unsqueeze(-1)) |
|
return out_embed, mask |
|
|
|
def tokenize(self, x: JointEmbedCondition) -> JointEmbedCondition: |
|
return x |
|
|
|
|
|
class CLAPEmbeddingConditioner(JointEmbeddingConditioner): |
|
"""Joint Embedding conditioner based on pre-trained CLAP model. |
|
|
|
This CLAP-based conditioner supports a caching mechanism |
|
over the computed embeddings for faster training. |
|
|
|
Args: |
|
dim (int): Dimension. |
|
output_dim (int): Output dimension. |
|
device (str): Device. |
|
attribute (str): Attribute used by the conditioner. |
|
quantize (bool): Whether to quantize the CLAP embedding. |
|
n_q (int): Number of residual quantizers (used if quantize is true). |
|
bins (int): Quantizers' codebooks size (used if quantize is true). |
|
checkpoint (str): Path to CLAP checkpoint. |
|
model_arch (str): CLAP model architecture. |
|
enable_fusion (bool): Enable fusion for CLAP model. |
|
sample_rate (int): Sample rate used by CLAP model. |
|
max_audio_length (float): Maximum audio length for CLAP model. |
|
audio_stride (float): Stride to use for getting a CLAP embedding on the full sequence. |
|
normalize (bool): Whether to normalize the CLAP embedding. |
|
text_p (float): Probability of using text representation instead of audio at train time. |
|
batch_size (Optional[int]): Batch size for CLAP embedding computation. |
|
autocast_dtype (str): Autocast for the conditioner. |
|
cache_path (Optional[str]): Path for pre-computed embeddings caching. |
|
kwargs: Additional parameters for residual vector quantizer. |
|
""" |
|
def __init__(self, dim: int, output_dim: int, device: str, attribute: str, |
|
quantize: bool, n_q: int, bins: int, checkpoint: tp.Union[str, Path], model_arch: str, |
|
enable_fusion: bool, sample_rate: int, max_audio_length: int, audio_stride: int, |
|
normalize: bool, text_p: bool, batch_size: tp.Optional[int] = None, |
|
autocast_dtype: tp.Optional[str] = 'float32', cache_path: tp.Optional[str] = None, **kwargs): |
|
try: |
|
import laion_clap |
|
except ImportError: |
|
raise ImportError("Please install CLAP to use the CLAPEmbeddingConditioner: 'pip install laion_clap'") |
|
warnings.warn("Sample rate for CLAP conditioner was fixed in version v1.1.0, (from 44.1 to 48 kHz). " |
|
"Please retrain all models.") |
|
checkpoint = AudioCraftEnvironment.resolve_reference_path(checkpoint) |
|
clap_tokenize = RobertaTokenizer.from_pretrained('roberta-base') |
|
clap_model = laion_clap.CLAP_Module(enable_fusion=enable_fusion, amodel=model_arch) |
|
load_clap_state_dict(clap_model, checkpoint) |
|
clap_model.eval() |
|
clap_model.to(device) |
|
super().__init__(dim=dim, output_dim=output_dim, device=device, attribute=attribute, |
|
autocast_dtype=autocast_dtype, quantize=quantize, n_q=n_q, bins=bins, |
|
**kwargs) |
|
self.checkpoint = checkpoint |
|
self.enable_fusion = enable_fusion |
|
self.model_arch = model_arch |
|
self.clap: laion_clap.CLAP_Module |
|
self.clap_tokenize: RobertaTokenizer |
|
self.clap_sample_rate = sample_rate |
|
self.clap_max_frames = int(self.clap_sample_rate * max_audio_length) |
|
self.clap_stride = int(self.clap_sample_rate * audio_stride) |
|
self.batch_size = batch_size or 1 |
|
self.normalize = normalize |
|
self.text_p = text_p |
|
self.__dict__['clap_tokenize'] = clap_tokenize |
|
self.__dict__['clap'] = clap_model |
|
self.wav_cache, self.text_cache = None, None |
|
if cache_path is not None: |
|
self.wav_cache = EmbeddingCache(Path(cache_path) / 'wav', self.device, |
|
compute_embed_fn=self._get_wav_embedding_for_cache, |
|
extract_embed_fn=self._extract_wav_embedding_chunk) |
|
self.text_cache = EmbeddingCache(Path(cache_path) / 'text', self.device, |
|
compute_embed_fn=self._get_text_embedding_for_cache) |
|
|
|
def _tokenizer(self, texts: tp.Union[str, tp.List[str]]) -> dict: |
|
|
|
return self.clap_tokenize(texts, padding="max_length", truncation=True, max_length=77, return_tensors="pt") |
|
|
|
def _compute_text_embedding(self, text: tp.List[str]) -> torch.Tensor: |
|
"""Compute text embedding from CLAP model on a given a batch of text. |
|
|
|
Args: |
|
text (list[str]): List of text for the batch, with B items. |
|
Returns: |
|
torch.Tensor: CLAP embedding derived from text, of shape [B, 1, D], with D the CLAP embedding dimension. |
|
""" |
|
with torch.no_grad(): |
|
embed = self.clap.get_text_embedding(text, tokenizer=self._tokenizer, use_tensor=True) |
|
return embed.view(embed.size(0), 1, embed.size(-1)) |
|
|
|
def _get_text_embedding_for_cache(self, path: tp.Union[Path, str], |
|
x: JointEmbedCondition, idx: int) -> torch.Tensor: |
|
"""Get text embedding function for the cache.""" |
|
text = x.text[idx] |
|
text = text if text is not None else "" |
|
return self._compute_text_embedding([text])[0] |
|
|
|
def _preprocess_wav(self, wav: torch.Tensor, length: torch.Tensor, sample_rates: tp.List[int]) -> torch.Tensor: |
|
"""Preprocess wav to expected format by CLAP model. |
|
|
|
Args: |
|
wav (torch.Tensor): Audio wav, of shape [B, C, T]. |
|
length (torch.Tensor): Actual length of the audio for each item in the batch, of shape [B]. |
|
sample_rates (list[int]): Sample rates for each sample in the batch |
|
Returns: |
|
torch.Tensor: Audio wav of shape [B, T]. |
|
""" |
|
assert wav.dim() == 3, "Expecting wav to be [B, C, T]" |
|
if sample_rates is not None: |
|
_wav = [] |
|
for i, audio in enumerate(wav): |
|
sr = sample_rates[i] |
|
audio = convert_audio(audio, from_rate=sr, to_rate=self.clap_sample_rate, to_channels=1) |
|
_wav.append(audio) |
|
wav = torch.stack(_wav, dim=0) |
|
wav = wav.mean(dim=1) |
|
return wav |
|
|
|
def _compute_wav_embedding(self, wav: torch.Tensor, length: torch.Tensor, |
|
sample_rates: tp.List[int], reduce_mean: bool = False) -> torch.Tensor: |
|
"""Compute audio wave embedding from CLAP model. |
|
|
|
Since CLAP operates on a fixed sequence length audio inputs and we need to process longer audio sequences, |
|
we calculate the wav embeddings on `clap_max_frames` windows with `clap_stride`-second stride and |
|
average the resulting embeddings. |
|
|
|
Args: |
|
wav (torch.Tensor): Audio wav, of shape [B, C, T]. |
|
length (torch.Tensor): Actual length of the audio for each item in the batch, of shape [B]. |
|
sample_rates (list[int]): Sample rates for each sample in the batch. |
|
reduce_mean (bool): Whether to get the average tensor. |
|
Returns: |
|
torch.Tensor: Audio embedding of shape [B, F, D], F being the number of chunks, D the dimension. |
|
""" |
|
with torch.no_grad(): |
|
wav = self._preprocess_wav(wav, length, sample_rates) |
|
B, T = wav.shape |
|
if T >= self.clap_max_frames: |
|
wav = wav.unfold(-1, self.clap_max_frames, self.clap_stride) |
|
else: |
|
wav = wav.view(-1, 1, T) |
|
wav = einops.rearrange(wav, 'b f t -> (b f) t') |
|
embed_list = [] |
|
for i in range(0, wav.size(0), self.batch_size): |
|
_wav = wav[i:i+self.batch_size, ...] |
|
_embed = self.clap.get_audio_embedding_from_data(_wav, use_tensor=True) |
|
embed_list.append(_embed) |
|
embed = torch.cat(embed_list, dim=0) |
|
embed = einops.rearrange(embed, '(b f) d -> b f d', b=B) |
|
if reduce_mean: |
|
embed = embed.mean(dim=1, keepdim=True) |
|
return embed |
|
|
|
def _get_wav_embedding_for_cache(self, path: tp.Union[str, Path], |
|
x: JointEmbedCondition, idx: int) -> torch.Tensor: |
|
"""Compute audio wave embedding for the cache. |
|
The embedding is computed on a given audio read from file. |
|
|
|
Args: |
|
path (str or Path): Path to the full audio file. |
|
Returns: |
|
torch.Tensor: Single-item tensor of shape [F, D], F being the number of chunks, D the dimension. |
|
""" |
|
wav, sr = audio_read(path) |
|
wav = wav.unsqueeze(0).to(self.device) |
|
wav_len = torch.LongTensor([wav.shape[-1]]).to(self.device) |
|
embed = self._compute_wav_embedding(wav, wav_len, [sr], reduce_mean=False) |
|
return embed.squeeze(0) |
|
|
|
def _extract_wav_embedding_chunk(self, full_embed: torch.Tensor, x: JointEmbedCondition, idx: int) -> torch.Tensor: |
|
"""Extract the chunk of embedding matching the seek_time and length from the full CLAP audio embedding. |
|
|
|
Args: |
|
full_embed (torch.Tensor): CLAP embedding computed on the full wave, of shape [F, D]. |
|
x (JointEmbedCondition): Joint embedding condition for the full batch. |
|
idx (int): Index considered for the given embedding to extract. |
|
Returns: |
|
torch.Tensor: Wav embedding averaged on sliding window, of shape [1, D]. |
|
""" |
|
sample_rate = x.sample_rate[idx] |
|
seek_time = x.seek_time[idx] |
|
seek_time = 0. if seek_time is None else seek_time |
|
clap_stride = int(self.clap_stride / self.clap_sample_rate) * sample_rate |
|
end_seek_time = seek_time + self.clap_max_frames / self.clap_sample_rate |
|
start_offset = int(seek_time * sample_rate // clap_stride) |
|
end_offset = int(end_seek_time * sample_rate // clap_stride) |
|
wav_embed = full_embed[start_offset:end_offset, ...] |
|
wav_embed = wav_embed.mean(dim=0, keepdim=True) |
|
return wav_embed.to(self.device) |
|
|
|
def _get_text_embedding(self, x: JointEmbedCondition) -> torch.Tensor: |
|
"""Get CLAP embedding from a batch of text descriptions.""" |
|
no_nullified_cond = x.wav.shape[-1] > 1 |
|
if self.text_cache is not None and no_nullified_cond: |
|
assert all(p is not None for p in x.path), "Cache requires all JointEmbedCondition paths to be provided" |
|
paths = [Path(p) for p in x.path if p is not None] |
|
embed = self.text_cache.get_embed_from_cache(paths, x) |
|
else: |
|
text = [xi if xi is not None else "" for xi in x.text] |
|
embed = self._compute_text_embedding(text) |
|
if self.normalize: |
|
embed = torch.nn.functional.normalize(embed, p=2.0, dim=-1) |
|
return embed |
|
|
|
def _get_wav_embedding(self, x: JointEmbedCondition) -> torch.Tensor: |
|
"""Get CLAP embedding from a batch of audio tensors (and corresponding sample rates).""" |
|
no_undefined_paths = all(p is not None for p in x.path) |
|
no_nullified_cond = x.wav.shape[-1] > 1 |
|
if self.wav_cache is not None and no_undefined_paths and no_nullified_cond: |
|
paths = [Path(p) for p in x.path if p is not None] |
|
embed = self.wav_cache.get_embed_from_cache(paths, x) |
|
else: |
|
embed = self._compute_wav_embedding(x.wav, x.length, x.sample_rate, reduce_mean=True) |
|
if self.normalize: |
|
embed = torch.nn.functional.normalize(embed, p=2.0, dim=-1) |
|
return embed |
|
|
|
def tokenize(self, x: JointEmbedCondition) -> JointEmbedCondition: |
|
|
|
no_undefined_paths = all(p is not None for p in x.path) |
|
if self.wav_cache is not None and no_undefined_paths: |
|
assert all([p is not None for p in x.path]), "Cache requires all JointEmbedCondition paths to be provided" |
|
paths = [Path(p) for p in x.path if p is not None] |
|
self.wav_cache.populate_embed_cache(paths, x) |
|
if self.text_cache is not None and no_undefined_paths: |
|
assert all([p is not None for p in x.path]), "Cache requires all JointEmbedCondition paths to be provided" |
|
paths = [Path(p) for p in x.path if p is not None] |
|
self.text_cache.populate_embed_cache(paths, x) |
|
return x |
|
|
|
def _get_embed(self, x: JointEmbedCondition) -> tp.Tuple[torch.Tensor, torch.Tensor]: |
|
"""Extract shared latent representation from either the wav or the text using CLAP.""" |
|
|
|
use_text_embed = random.random() < self.text_p |
|
if self.training and not use_text_embed: |
|
embed = self._get_wav_embedding(x) |
|
empty_idx = torch.LongTensor([]) |
|
else: |
|
embed = self._get_text_embedding(x) |
|
empty_idx = torch.LongTensor([i for i, xi in enumerate(x.text) if xi is None or xi == ""]) |
|
return embed, empty_idx |
|
|
|
|
|
def dropout_condition(sample: ConditioningAttributes, condition_type: str, condition: str) -> ConditioningAttributes: |
|
"""Utility function for nullifying an attribute inside an ConditioningAttributes object. |
|
If the condition is of type "wav", then nullify it using `nullify_condition` function. |
|
If the condition is of any other type, set its value to None. |
|
Works in-place. |
|
""" |
|
if condition_type not in ['text', 'wav', 'joint_embed']: |
|
raise ValueError( |
|
"dropout_condition got an unexpected condition type!" |
|
f" expected 'text', 'wav' or 'joint_embed' but got '{condition_type}'" |
|
) |
|
|
|
if condition not in getattr(sample, condition_type): |
|
raise ValueError( |
|
"dropout_condition received an unexpected condition!" |
|
f" expected wav={sample.wav.keys()} and text={sample.text.keys()}" |
|
f" but got '{condition}' of type '{condition_type}'!" |
|
) |
|
|
|
if condition_type == 'wav': |
|
wav_cond = sample.wav[condition] |
|
sample.wav[condition] = nullify_wav(wav_cond) |
|
elif condition_type == 'joint_embed': |
|
embed = sample.joint_embed[condition] |
|
sample.joint_embed[condition] = nullify_joint_embed(embed) |
|
else: |
|
sample.text[condition] = None |
|
|
|
return sample |
|
|
|
|
|
class DropoutModule(nn.Module): |
|
"""Base module for all dropout modules.""" |
|
def __init__(self, seed: int = 1234): |
|
super().__init__() |
|
self.rng = torch.Generator() |
|
self.rng.manual_seed(seed) |
|
|
|
|
|
class AttributeDropout(DropoutModule): |
|
"""Dropout with a given probability per attribute. |
|
This is different from the behavior of ClassifierFreeGuidanceDropout as this allows for attributes |
|
to be dropped out separately. For example, "artist" can be dropped while "genre" remains. |
|
This is in contrast to ClassifierFreeGuidanceDropout where if "artist" is dropped "genre" |
|
must also be dropped. |
|
|
|
Args: |
|
p (tp.Dict[str, float]): A dict mapping between attributes and dropout probability. For example: |
|
... |
|
"genre": 0.1, |
|
"artist": 0.5, |
|
"wav": 0.25, |
|
... |
|
active_on_eval (bool, optional): Whether the dropout is active at eval. Default to False. |
|
seed (int, optional): Random seed. |
|
""" |
|
def __init__(self, p: tp.Dict[str, tp.Dict[str, float]], active_on_eval: bool = False, seed: int = 1234): |
|
super().__init__(seed=seed) |
|
self.active_on_eval = active_on_eval |
|
|
|
self.p = {} |
|
for condition_type, probs in p.items(): |
|
self.p[condition_type] = defaultdict(lambda: 0, probs) |
|
|
|
def forward(self, samples: tp.List[ConditioningAttributes]) -> tp.List[ConditioningAttributes]: |
|
""" |
|
Args: |
|
samples (list[ConditioningAttributes]): List of conditions. |
|
Returns: |
|
list[ConditioningAttributes]: List of conditions after certain attributes were set to None. |
|
""" |
|
if not self.training and not self.active_on_eval: |
|
return samples |
|
|
|
samples = deepcopy(samples) |
|
for condition_type, ps in self.p.items(): |
|
for condition, p in ps.items(): |
|
if torch.rand(1, generator=self.rng).item() < p: |
|
for sample in samples: |
|
dropout_condition(sample, condition_type, condition) |
|
return samples |
|
|
|
def __repr__(self): |
|
return f"AttributeDropout({dict(self.p)})" |
|
|
|
|
|
class ClassifierFreeGuidanceDropout(DropoutModule): |
|
"""Classifier Free Guidance dropout. |
|
All attributes are dropped with the same probability. |
|
|
|
Args: |
|
p (float): Probability to apply condition dropout during training. |
|
seed (int): Random seed. |
|
""" |
|
def __init__(self, p: float, seed: int = 1234): |
|
super().__init__(seed=seed) |
|
self.p = p |
|
|
|
def forward(self, samples: tp.List[ConditioningAttributes]) -> tp.List[ConditioningAttributes]: |
|
""" |
|
Args: |
|
samples (list[ConditioningAttributes]): List of conditions. |
|
Returns: |
|
list[ConditioningAttributes]: List of conditions after all attributes were set to None. |
|
""" |
|
if not self.training: |
|
return samples |
|
|
|
|
|
drop = torch.rand(1, generator=self.rng).item() < self.p |
|
if not drop: |
|
return samples |
|
|
|
|
|
samples = deepcopy(samples) |
|
for condition_type in ["wav", "text"]: |
|
for sample in samples: |
|
for condition in sample.attributes[condition_type]: |
|
dropout_condition(sample, condition_type, condition) |
|
return samples |
|
|
|
def __repr__(self): |
|
return f"ClassifierFreeGuidanceDropout(p={self.p})" |
|
|
|
|
|
class ConditioningProvider(nn.Module): |
|
"""Prepare and provide conditions given all the supported conditioners. |
|
|
|
Args: |
|
conditioners (dict): Dictionary of conditioners. |
|
device (torch.device or str, optional): Device for conditioners and output condition types. |
|
""" |
|
def __init__(self, conditioners: tp.Dict[str, BaseConditioner], device: tp.Union[torch.device, str] = "cpu"): |
|
super().__init__() |
|
self.device = device |
|
self.conditioners = nn.ModuleDict(conditioners) |
|
|
|
@property |
|
def joint_embed_conditions(self): |
|
return [m.attribute for m in self.conditioners.values() if isinstance(m, JointEmbeddingConditioner)] |
|
|
|
@property |
|
def has_joint_embed_conditions(self): |
|
return len(self.joint_embed_conditions) > 0 |
|
|
|
@property |
|
def text_conditions(self): |
|
return [k for k, v in self.conditioners.items() if isinstance(v, TextConditioner)] |
|
|
|
@property |
|
def wav_conditions(self): |
|
return [k for k, v in self.conditioners.items() if isinstance(v, WaveformConditioner)] |
|
|
|
@property |
|
def has_wav_condition(self): |
|
return len(self.wav_conditions) > 0 |
|
|
|
def tokenize(self, inputs: tp.List[ConditioningAttributes]) -> tp.Dict[str, tp.Any]: |
|
"""Match attributes/wavs with existing conditioners in self, and compute tokenize them accordingly. |
|
This should be called before starting any real GPU work to avoid synchronization points. |
|
This will return a dict matching conditioner names to their arbitrary tokenized representations. |
|
|
|
Args: |
|
inputs (list[ConditioningAttributes]): List of ConditioningAttributes objects containing |
|
text and wav conditions. |
|
""" |
|
assert all([isinstance(x, ConditioningAttributes) for x in inputs]), ( |
|
"Got unexpected types input for conditioner! should be tp.List[ConditioningAttributes]", |
|
f" but types were {set([type(x) for x in inputs])}" |
|
) |
|
|
|
output = {} |
|
text = self._collate_text(inputs) |
|
wavs = self._collate_wavs(inputs) |
|
joint_embeds = self._collate_joint_embeds(inputs) |
|
|
|
assert set(text.keys() | wavs.keys() | joint_embeds.keys()).issubset(set(self.conditioners.keys())), ( |
|
f"Got an unexpected attribute! Expected {self.conditioners.keys()}, ", |
|
f"got {text.keys(), wavs.keys(), joint_embeds.keys()}" |
|
) |
|
|
|
for attribute, batch in chain(text.items(), wavs.items(), joint_embeds.items()): |
|
output[attribute] = self.conditioners[attribute].tokenize(batch) |
|
return output |
|
|
|
def forward(self, tokenized: tp.Dict[str, tp.Any]) -> tp.Dict[str, ConditionType]: |
|
"""Compute pairs of `(embedding, mask)` using the configured conditioners and the tokenized representations. |
|
The output is for example: |
|
{ |
|
"genre": (torch.Tensor([B, 1, D_genre]), torch.Tensor([B, 1])), |
|
"description": (torch.Tensor([B, T_desc, D_desc]), torch.Tensor([B, T_desc])), |
|
... |
|
} |
|
|
|
Args: |
|
tokenized (dict): Dict of tokenized representations as returned by `tokenize()`. |
|
""" |
|
output = {} |
|
for attribute, inputs in tokenized.items(): |
|
condition, mask = self.conditioners[attribute](inputs) |
|
output[attribute] = (condition, mask) |
|
return output |
|
|
|
def _collate_text(self, samples: tp.List[ConditioningAttributes]) -> tp.Dict[str, tp.List[tp.Optional[str]]]: |
|
"""Given a list of ConditioningAttributes objects, compile a dictionary where the keys |
|
are the attributes and the values are the aggregated input per attribute. |
|
For example: |
|
Input: |
|
[ |
|
ConditioningAttributes(text={"genre": "Rock", "description": "A rock song with a guitar solo"}, wav=...), |
|
ConditioningAttributes(text={"genre": "Hip-hop", "description": "A hip-hop verse"}, wav=...), |
|
] |
|
Output: |
|
{ |
|
"genre": ["Rock", "Hip-hop"], |
|
"description": ["A rock song with a guitar solo", "A hip-hop verse"] |
|
} |
|
|
|
Args: |
|
samples (list of ConditioningAttributes): List of ConditioningAttributes samples. |
|
Returns: |
|
dict[str, list[str, optional]]: A dictionary mapping an attribute name to text batch. |
|
""" |
|
out: tp.Dict[str, tp.List[tp.Optional[str]]] = defaultdict(list) |
|
texts = [x.text for x in samples] |
|
for text in texts: |
|
for condition in self.text_conditions: |
|
out[condition].append(text[condition]) |
|
return out |
|
|
|
def _collate_wavs(self, samples: tp.List[ConditioningAttributes]) -> tp.Dict[str, WavCondition]: |
|
"""Generate a dict where the keys are attributes by which we fetch similar wavs, |
|
and the values are Tensors of wavs according to said attributes. |
|
|
|
*Note*: by the time the samples reach this function, each sample should have some waveform |
|
inside the "wav" attribute. It should be either: |
|
1. A real waveform |
|
2. A null waveform due to the sample having no similar waveforms (nullified by the dataset) |
|
3. A null waveform due to it being dropped in a dropout module (nullified by dropout) |
|
|
|
Args: |
|
samples (list of ConditioningAttributes): List of ConditioningAttributes samples. |
|
Returns: |
|
dict[str, WavCondition]: A dictionary mapping an attribute name to wavs. |
|
""" |
|
wavs = defaultdict(list) |
|
lengths = defaultdict(list) |
|
sample_rates = defaultdict(list) |
|
paths = defaultdict(list) |
|
seek_times = defaultdict(list) |
|
out: tp.Dict[str, WavCondition] = {} |
|
|
|
for sample in samples: |
|
for attribute in self.wav_conditions: |
|
wav, length, sample_rate, path, seek_time = sample.wav[attribute] |
|
assert wav.dim() == 3, f"Got wav with dim={wav.dim()}, but expected 3 [1, C, T]" |
|
assert wav.size(0) == 1, f"Got wav [B, C, T] with shape={wav.shape}, but expected B == 1" |
|
|
|
wav = wav.mean(1, keepdim=True) |
|
wavs[attribute].append(wav.flatten()) |
|
lengths[attribute].append(length) |
|
sample_rates[attribute].extend(sample_rate) |
|
paths[attribute].extend(path) |
|
seek_times[attribute].extend(seek_time) |
|
|
|
|
|
for attribute in self.wav_conditions: |
|
stacked_wav, _ = collate(wavs[attribute], dim=0) |
|
out[attribute] = WavCondition( |
|
stacked_wav.unsqueeze(1), torch.cat(lengths[attribute]), sample_rates[attribute], |
|
paths[attribute], seek_times[attribute]) |
|
|
|
return out |
|
|
|
def _collate_joint_embeds(self, samples: tp.List[ConditioningAttributes]) -> tp.Dict[str, JointEmbedCondition]: |
|
"""Generate a dict where the keys are attributes by which we compute joint embeddings, |
|
and the values are Tensors of pre-computed embeddings and the corresponding text attributes. |
|
|
|
Args: |
|
samples (list[ConditioningAttributes]): List of ConditioningAttributes samples. |
|
Returns: |
|
A dictionary mapping an attribute name to joint embeddings. |
|
""" |
|
texts = defaultdict(list) |
|
wavs = defaultdict(list) |
|
lengths = defaultdict(list) |
|
sample_rates = defaultdict(list) |
|
paths = defaultdict(list) |
|
seek_times = defaultdict(list) |
|
channels: int = 0 |
|
|
|
out = {} |
|
for sample in samples: |
|
for attribute in self.joint_embed_conditions: |
|
wav, text, length, sample_rate, path, seek_time = sample.joint_embed[attribute] |
|
assert wav.dim() == 3 |
|
if channels == 0: |
|
channels = wav.size(1) |
|
else: |
|
assert channels == wav.size(1), "not all audio has same number of channels in batch" |
|
assert wav.size(0) == 1, "Expecting single-wav batch in the collate method" |
|
wav = einops.rearrange(wav, "b c t -> (b c t)") |
|
wavs[attribute].append(wav) |
|
texts[attribute].extend(text) |
|
lengths[attribute].append(length) |
|
sample_rates[attribute].extend(sample_rate) |
|
paths[attribute].extend(path) |
|
seek_times[attribute].extend(seek_time) |
|
|
|
for attribute in self.joint_embed_conditions: |
|
stacked_texts = texts[attribute] |
|
stacked_paths = paths[attribute] |
|
stacked_seek_times = seek_times[attribute] |
|
stacked_wavs = pad_sequence(wavs[attribute]).to(self.device) |
|
stacked_wavs = einops.rearrange(stacked_wavs, "(c t) b -> b c t", c=channels) |
|
stacked_sample_rates = sample_rates[attribute] |
|
stacked_lengths = torch.cat(lengths[attribute]).to(self.device) |
|
assert stacked_lengths.size(0) == stacked_wavs.size(0) |
|
assert len(stacked_sample_rates) == stacked_wavs.size(0) |
|
assert len(stacked_texts) == stacked_wavs.size(0) |
|
out[attribute] = JointEmbedCondition( |
|
text=stacked_texts, wav=stacked_wavs, |
|
length=stacked_lengths, sample_rate=stacked_sample_rates, |
|
path=stacked_paths, seek_time=stacked_seek_times) |
|
|
|
return out |
|
|
|
|
|
class ConditionFuser(StreamingModule): |
|
"""Condition fuser handles the logic to combine the different conditions |
|
to the actual model input. |
|
|
|
Args: |
|
fuse2cond (tp.Dict[str, str]): A dictionary that says how to fuse |
|
each condition. For example: |
|
{ |
|
"prepend": ["description"], |
|
"sum": ["genre", "bpm"], |
|
"cross": ["description"], |
|
} |
|
cross_attention_pos_emb (bool, optional): Use positional embeddings in cross attention. |
|
cross_attention_pos_emb_scale (int): Scale for positional embeddings in cross attention if used. |
|
""" |
|
FUSING_METHODS = ["sum", "prepend", "cross", "input_interpolate"] |
|
|
|
def __init__(self, fuse2cond: tp.Dict[str, tp.List[str]], cross_attention_pos_emb: bool = False, |
|
cross_attention_pos_emb_scale: float = 1.0): |
|
super().__init__() |
|
assert all( |
|
[k in self.FUSING_METHODS for k in fuse2cond.keys()] |
|
), f"Got invalid fuse method, allowed methods: {self.FUSING_METHODS}" |
|
self.cross_attention_pos_emb = cross_attention_pos_emb |
|
self.cross_attention_pos_emb_scale = cross_attention_pos_emb_scale |
|
self.fuse2cond: tp.Dict[str, tp.List[str]] = fuse2cond |
|
self.cond2fuse: tp.Dict[str, str] = {} |
|
for fuse_method, conditions in fuse2cond.items(): |
|
for condition in conditions: |
|
self.cond2fuse[condition] = fuse_method |
|
|
|
def forward( |
|
self, |
|
input: torch.Tensor, |
|
conditions: tp.Dict[str, ConditionType] |
|
) -> tp.Tuple[torch.Tensor, tp.Optional[torch.Tensor]]: |
|
"""Fuse the conditions to the provided model input. |
|
|
|
Args: |
|
input (torch.Tensor): Transformer input. |
|
conditions (dict[str, ConditionType]): Dict of conditions. |
|
Returns: |
|
tuple[torch.Tensor, torch.Tensor]: The first tensor is the transformer input |
|
after the conditions have been fused. The second output tensor is the tensor |
|
used for cross-attention or None if no cross attention inputs exist. |
|
""" |
|
B, T, _ = input.shape |
|
|
|
if 'offsets' in self._streaming_state: |
|
first_step = False |
|
offsets = self._streaming_state['offsets'] |
|
else: |
|
first_step = True |
|
offsets = torch.zeros(input.shape[0], dtype=torch.long, device=input.device) |
|
|
|
assert set(conditions.keys()).issubset(set(self.cond2fuse.keys())), \ |
|
f"given conditions contain unknown attributes for fuser, " \ |
|
f"expected {self.cond2fuse.keys()}, got {conditions.keys()}" |
|
cross_attention_output = None |
|
for cond_type, (cond, cond_mask) in conditions.items(): |
|
op = self.cond2fuse[cond_type] |
|
if op == 'sum': |
|
input += cond |
|
elif op == 'input_interpolate': |
|
cond = einops.rearrange(cond, "b t d -> b d t") |
|
cond = F.interpolate(cond, size=input.shape[1]) |
|
input += einops.rearrange(cond, "b d t -> b t d") |
|
elif op == 'prepend': |
|
if first_step: |
|
input = torch.cat([cond, input], dim=1) |
|
elif op == 'cross': |
|
if cross_attention_output is not None: |
|
cross_attention_output = torch.cat([cross_attention_output, cond], dim=1) |
|
else: |
|
cross_attention_output = cond |
|
else: |
|
raise ValueError(f"unknown op ({op})") |
|
|
|
if self.cross_attention_pos_emb and cross_attention_output is not None: |
|
positions = torch.arange( |
|
cross_attention_output.shape[1], |
|
device=cross_attention_output.device |
|
).view(1, -1, 1) |
|
pos_emb = create_sin_embedding(positions, cross_attention_output.shape[-1]) |
|
cross_attention_output = cross_attention_output + self.cross_attention_pos_emb_scale * pos_emb |
|
|
|
if self._is_streaming: |
|
self._streaming_state['offsets'] = offsets + T |
|
|
|
return input, cross_attention_output |
|
|