mirror of
https://github.com/Anjok07/ultimatevocalremovergui.git
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649 lines
26 KiB
Python
649 lines
26 KiB
Python
# Copyright (c) Meta, Inc. and its affiliates.
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# All rights reserved.
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#
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# This source code is licensed under the license found in the
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# LICENSE file in the root directory of this source tree.
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# First author is Simon Rouard.
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"""
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This code contains the spectrogram and Hybrid version of Demucs.
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"""
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import math
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from .filtering import wiener
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import torch
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from torch import nn
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from torch.nn import functional as F
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from fractions import Fraction
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from einops import rearrange
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from .transformer import CrossTransformerEncoder
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from .demucs import rescale_module
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from .states import capture_init
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from .spec import spectro, ispectro
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from .hdemucs import pad1d, ScaledEmbedding, HEncLayer, MultiWrap, HDecLayer
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class HTDemucs(nn.Module):
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"""
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Spectrogram and hybrid Demucs model.
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The spectrogram model has the same structure as Demucs, except the first few layers are over the
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frequency axis, until there is only 1 frequency, and then it moves to time convolutions.
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Frequency layers can still access information across time steps thanks to the DConv residual.
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Hybrid model have a parallel time branch. At some layer, the time branch has the same stride
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as the frequency branch and then the two are combined. The opposite happens in the decoder.
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Models can either use naive iSTFT from masking, Wiener filtering ([Ulhih et al. 2017]),
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or complex as channels (CaC) [Choi et al. 2020]. Wiener filtering is based on
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Open Unmix implementation [Stoter et al. 2019].
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The loss is always on the temporal domain, by backpropagating through the above
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output methods and iSTFT. This allows to define hybrid models nicely. However, this breaks
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a bit Wiener filtering, as doing more iteration at test time will change the spectrogram
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contribution, without changing the one from the waveform, which will lead to worse performance.
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I tried using the residual option in OpenUnmix Wiener implementation, but it didn't improve.
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CaC on the other hand provides similar performance for hybrid, and works naturally with
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hybrid models.
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This model also uses frequency embeddings are used to improve efficiency on convolutions
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over the freq. axis, following [Isik et al. 2020] (https://arxiv.org/pdf/2008.04470.pdf).
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Unlike classic Demucs, there is no resampling here, and normalization is always applied.
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"""
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@capture_init
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def __init__(
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self,
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sources,
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# Channels
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audio_channels=2,
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channels=48,
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channels_time=None,
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growth=2,
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# STFT
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nfft=4096,
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wiener_iters=0,
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end_iters=0,
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wiener_residual=False,
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cac=True,
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# Main structure
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depth=4,
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rewrite=True,
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# Frequency branch
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multi_freqs=None,
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multi_freqs_depth=3,
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freq_emb=0.2,
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emb_scale=10,
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emb_smooth=True,
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# Convolutions
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kernel_size=8,
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time_stride=2,
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stride=4,
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context=1,
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context_enc=0,
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# Normalization
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norm_starts=4,
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norm_groups=4,
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# DConv residual branch
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dconv_mode=1,
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dconv_depth=2,
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dconv_comp=8,
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dconv_init=1e-3,
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# Before the Transformer
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bottom_channels=0,
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# Transformer
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t_layers=5,
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t_emb="sin",
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t_hidden_scale=4.0,
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t_heads=8,
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t_dropout=0.0,
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t_max_positions=10000,
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t_norm_in=True,
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t_norm_in_group=False,
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t_group_norm=False,
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t_norm_first=True,
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t_norm_out=True,
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t_max_period=10000.0,
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t_weight_decay=0.0,
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t_lr=None,
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t_layer_scale=True,
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t_gelu=True,
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t_weight_pos_embed=1.0,
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t_sin_random_shift=0,
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t_cape_mean_normalize=True,
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t_cape_augment=True,
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t_cape_glob_loc_scale=[5000.0, 1.0, 1.4],
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t_sparse_self_attn=False,
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t_sparse_cross_attn=False,
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t_mask_type="diag",
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t_mask_random_seed=42,
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t_sparse_attn_window=500,
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t_global_window=100,
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t_sparsity=0.95,
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t_auto_sparsity=False,
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# ------ Particuliar parameters
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t_cross_first=False,
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# Weight init
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rescale=0.1,
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# Metadata
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samplerate=44100,
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segment=10,
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use_train_segment=True,
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):
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"""
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Args:
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sources (list[str]): list of source names.
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audio_channels (int): input/output audio channels.
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channels (int): initial number of hidden channels.
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channels_time: if not None, use a different `channels` value for the time branch.
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growth: increase the number of hidden channels by this factor at each layer.
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nfft: number of fft bins. Note that changing this require careful computation of
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various shape parameters and will not work out of the box for hybrid models.
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wiener_iters: when using Wiener filtering, number of iterations at test time.
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end_iters: same but at train time. For a hybrid model, must be equal to `wiener_iters`.
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wiener_residual: add residual source before wiener filtering.
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cac: uses complex as channels, i.e. complex numbers are 2 channels each
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in input and output. no further processing is done before ISTFT.
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depth (int): number of layers in the encoder and in the decoder.
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rewrite (bool): add 1x1 convolution to each layer.
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multi_freqs: list of frequency ratios for splitting frequency bands with `MultiWrap`.
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multi_freqs_depth: how many layers to wrap with `MultiWrap`. Only the outermost
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layers will be wrapped.
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freq_emb: add frequency embedding after the first frequency layer if > 0,
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the actual value controls the weight of the embedding.
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emb_scale: equivalent to scaling the embedding learning rate
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emb_smooth: initialize the embedding with a smooth one (with respect to frequencies).
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kernel_size: kernel_size for encoder and decoder layers.
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stride: stride for encoder and decoder layers.
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time_stride: stride for the final time layer, after the merge.
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context: context for 1x1 conv in the decoder.
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context_enc: context for 1x1 conv in the encoder.
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norm_starts: layer at which group norm starts being used.
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decoder layers are numbered in reverse order.
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norm_groups: number of groups for group norm.
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dconv_mode: if 1: dconv in encoder only, 2: decoder only, 3: both.
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dconv_depth: depth of residual DConv branch.
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dconv_comp: compression of DConv branch.
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dconv_attn: adds attention layers in DConv branch starting at this layer.
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dconv_lstm: adds a LSTM layer in DConv branch starting at this layer.
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dconv_init: initial scale for the DConv branch LayerScale.
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bottom_channels: if >0 it adds a linear layer (1x1 Conv) before and after the
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transformer in order to change the number of channels
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t_layers: number of layers in each branch (waveform and spec) of the transformer
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t_emb: "sin", "cape" or "scaled"
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t_hidden_scale: the hidden scale of the Feedforward parts of the transformer
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for instance if C = 384 (the number of channels in the transformer) and
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t_hidden_scale = 4.0 then the intermediate layer of the FFN has dimension
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384 * 4 = 1536
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t_heads: number of heads for the transformer
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t_dropout: dropout in the transformer
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t_max_positions: max_positions for the "scaled" positional embedding, only
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useful if t_emb="scaled"
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t_norm_in: (bool) norm before addinf positional embedding and getting into the
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transformer layers
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t_norm_in_group: (bool) if True while t_norm_in=True, the norm is on all the
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timesteps (GroupNorm with group=1)
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t_group_norm: (bool) if True, the norms of the Encoder Layers are on all the
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timesteps (GroupNorm with group=1)
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t_norm_first: (bool) if True the norm is before the attention and before the FFN
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t_norm_out: (bool) if True, there is a GroupNorm (group=1) at the end of each layer
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t_max_period: (float) denominator in the sinusoidal embedding expression
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t_weight_decay: (float) weight decay for the transformer
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t_lr: (float) specific learning rate for the transformer
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t_layer_scale: (bool) Layer Scale for the transformer
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t_gelu: (bool) activations of the transformer are GeLU if True, ReLU else
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t_weight_pos_embed: (float) weighting of the positional embedding
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t_cape_mean_normalize: (bool) if t_emb="cape", normalisation of positional embeddings
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see: https://arxiv.org/abs/2106.03143
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t_cape_augment: (bool) if t_emb="cape", must be True during training and False
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during the inference, see: https://arxiv.org/abs/2106.03143
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t_cape_glob_loc_scale: (list of 3 floats) if t_emb="cape", CAPE parameters
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see: https://arxiv.org/abs/2106.03143
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t_sparse_self_attn: (bool) if True, the self attentions are sparse
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t_sparse_cross_attn: (bool) if True, the cross-attentions are sparse (don't use it
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unless you designed really specific masks)
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t_mask_type: (str) can be "diag", "jmask", "random", "global" or any combination
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with '_' between: i.e. "diag_jmask_random" (note that this is permutation
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invariant i.e. "diag_jmask_random" is equivalent to "jmask_random_diag")
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t_mask_random_seed: (int) if "random" is in t_mask_type, controls the seed
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that generated the random part of the mask
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t_sparse_attn_window: (int) if "diag" is in t_mask_type, for a query (i), and
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a key (j), the mask is True id |i-j|<=t_sparse_attn_window
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t_global_window: (int) if "global" is in t_mask_type, mask[:t_global_window, :]
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and mask[:, :t_global_window] will be True
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t_sparsity: (float) if "random" is in t_mask_type, t_sparsity is the sparsity
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level of the random part of the mask.
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t_cross_first: (bool) if True cross attention is the first layer of the
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transformer (False seems to be better)
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rescale: weight rescaling trick
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use_train_segment: (bool) if True, the actual size that is used during the
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training is used during inference.
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"""
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super().__init__()
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self.cac = cac
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self.wiener_residual = wiener_residual
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self.audio_channels = audio_channels
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self.sources = sources
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self.kernel_size = kernel_size
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self.context = context
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self.stride = stride
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self.depth = depth
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self.bottom_channels = bottom_channels
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self.channels = channels
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self.samplerate = samplerate
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self.segment = segment
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self.use_train_segment = use_train_segment
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self.nfft = nfft
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self.hop_length = nfft // 4
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self.wiener_iters = wiener_iters
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self.end_iters = end_iters
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self.freq_emb = None
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assert wiener_iters == end_iters
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self.encoder = nn.ModuleList()
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self.decoder = nn.ModuleList()
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self.tencoder = nn.ModuleList()
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self.tdecoder = nn.ModuleList()
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chin = audio_channels
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chin_z = chin # number of channels for the freq branch
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if self.cac:
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chin_z *= 2
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chout = channels_time or channels
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chout_z = channels
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freqs = nfft // 2
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for index in range(depth):
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norm = index >= norm_starts
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freq = freqs > 1
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stri = stride
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ker = kernel_size
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if not freq:
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assert freqs == 1
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ker = time_stride * 2
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stri = time_stride
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pad = True
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last_freq = False
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if freq and freqs <= kernel_size:
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ker = freqs
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pad = False
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last_freq = True
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kw = {
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"kernel_size": ker,
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"stride": stri,
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"freq": freq,
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"pad": pad,
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"norm": norm,
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"rewrite": rewrite,
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"norm_groups": norm_groups,
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"dconv_kw": {
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"depth": dconv_depth,
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"compress": dconv_comp,
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"init": dconv_init,
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"gelu": True,
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},
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}
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kwt = dict(kw)
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kwt["freq"] = 0
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kwt["kernel_size"] = kernel_size
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kwt["stride"] = stride
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kwt["pad"] = True
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kw_dec = dict(kw)
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multi = False
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if multi_freqs and index < multi_freqs_depth:
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multi = True
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kw_dec["context_freq"] = False
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if last_freq:
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chout_z = max(chout, chout_z)
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chout = chout_z
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enc = HEncLayer(
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chin_z, chout_z, dconv=dconv_mode & 1, context=context_enc, **kw
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)
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if freq:
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tenc = HEncLayer(
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chin,
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chout,
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dconv=dconv_mode & 1,
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context=context_enc,
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empty=last_freq,
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**kwt
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)
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self.tencoder.append(tenc)
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if multi:
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enc = MultiWrap(enc, multi_freqs)
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self.encoder.append(enc)
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if index == 0:
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chin = self.audio_channels * len(self.sources)
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chin_z = chin
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if self.cac:
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chin_z *= 2
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dec = HDecLayer(
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chout_z,
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chin_z,
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dconv=dconv_mode & 2,
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last=index == 0,
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context=context,
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**kw_dec
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)
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if multi:
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dec = MultiWrap(dec, multi_freqs)
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if freq:
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tdec = HDecLayer(
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chout,
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chin,
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dconv=dconv_mode & 2,
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empty=last_freq,
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last=index == 0,
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context=context,
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**kwt
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)
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self.tdecoder.insert(0, tdec)
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self.decoder.insert(0, dec)
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chin = chout
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chin_z = chout_z
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chout = int(growth * chout)
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chout_z = int(growth * chout_z)
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if freq:
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if freqs <= kernel_size:
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freqs = 1
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else:
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freqs //= stride
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if index == 0 and freq_emb:
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self.freq_emb = ScaledEmbedding(
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freqs, chin_z, smooth=emb_smooth, scale=emb_scale
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)
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self.freq_emb_scale = freq_emb
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if rescale:
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rescale_module(self, reference=rescale)
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transformer_channels = channels * growth ** (depth - 1)
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if bottom_channels:
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self.channel_upsampler = nn.Conv1d(transformer_channels, bottom_channels, 1)
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self.channel_downsampler = nn.Conv1d(
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bottom_channels, transformer_channels, 1
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)
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self.channel_upsampler_t = nn.Conv1d(
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transformer_channels, bottom_channels, 1
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)
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self.channel_downsampler_t = nn.Conv1d(
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bottom_channels, transformer_channels, 1
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)
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transformer_channels = bottom_channels
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if t_layers > 0:
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self.crosstransformer = CrossTransformerEncoder(
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dim=transformer_channels,
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emb=t_emb,
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hidden_scale=t_hidden_scale,
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num_heads=t_heads,
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num_layers=t_layers,
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cross_first=t_cross_first,
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dropout=t_dropout,
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max_positions=t_max_positions,
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norm_in=t_norm_in,
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norm_in_group=t_norm_in_group,
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group_norm=t_group_norm,
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norm_first=t_norm_first,
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norm_out=t_norm_out,
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max_period=t_max_period,
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weight_decay=t_weight_decay,
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lr=t_lr,
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layer_scale=t_layer_scale,
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gelu=t_gelu,
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sin_random_shift=t_sin_random_shift,
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weight_pos_embed=t_weight_pos_embed,
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cape_mean_normalize=t_cape_mean_normalize,
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cape_augment=t_cape_augment,
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cape_glob_loc_scale=t_cape_glob_loc_scale,
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sparse_self_attn=t_sparse_self_attn,
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sparse_cross_attn=t_sparse_cross_attn,
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mask_type=t_mask_type,
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mask_random_seed=t_mask_random_seed,
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sparse_attn_window=t_sparse_attn_window,
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global_window=t_global_window,
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sparsity=t_sparsity,
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auto_sparsity=t_auto_sparsity,
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)
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else:
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self.crosstransformer = None
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def _spec(self, x):
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hl = self.hop_length
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nfft = self.nfft
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x0 = x # noqa
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# We re-pad the signal in order to keep the property
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# that the size of the output is exactly the size of the input
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# divided by the stride (here hop_length), when divisible.
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# This is achieved by padding by 1/4th of the kernel size (here nfft).
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# which is not supported by torch.stft.
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# Having all convolution operations follow this convention allow to easily
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# align the time and frequency branches later on.
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assert hl == nfft // 4
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le = int(math.ceil(x.shape[-1] / hl))
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pad = hl // 2 * 3
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x = pad1d(x, (pad, pad + le * hl - x.shape[-1]), mode="reflect")
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z = spectro(x, nfft, hl)[..., :-1, :]
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assert z.shape[-1] == le + 4, (z.shape, x.shape, le)
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z = z[..., 2: 2 + le]
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return z
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def _ispec(self, z, length=None, scale=0):
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hl = self.hop_length // (4**scale)
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z = F.pad(z, (0, 0, 0, 1))
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z = F.pad(z, (2, 2))
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pad = hl // 2 * 3
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le = hl * int(math.ceil(length / hl)) + 2 * pad
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x = ispectro(z, hl, length=le)
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x = x[..., pad: pad + length]
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return x
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def _magnitude(self, z):
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# return the magnitude of the spectrogram, except when cac is True,
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# in which case we just move the complex dimension to the channel one.
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if self.cac:
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B, C, Fr, T = z.shape
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m = torch.view_as_real(z).permute(0, 1, 4, 2, 3)
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m = m.reshape(B, C * 2, Fr, T)
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else:
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m = z.abs()
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return m
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def _mask(self, z, m):
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# Apply masking given the mixture spectrogram `z` and the estimated mask `m`.
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# If `cac` is True, `m` is actually a full spectrogram and `z` is ignored.
|
|
niters = self.wiener_iters
|
|
if self.cac:
|
|
B, S, C, Fr, T = m.shape
|
|
out = m.view(B, S, -1, 2, Fr, T).permute(0, 1, 2, 4, 5, 3)
|
|
out = torch.view_as_complex(out.contiguous())
|
|
return out
|
|
if self.training:
|
|
niters = self.end_iters
|
|
if niters < 0:
|
|
z = z[:, None]
|
|
return z / (1e-8 + z.abs()) * m
|
|
else:
|
|
return self._wiener(m, z, niters)
|
|
|
|
def _wiener(self, mag_out, mix_stft, niters):
|
|
# apply wiener filtering from OpenUnmix.
|
|
init = mix_stft.dtype
|
|
wiener_win_len = 300
|
|
residual = self.wiener_residual
|
|
|
|
B, S, C, Fq, T = mag_out.shape
|
|
mag_out = mag_out.permute(0, 4, 3, 2, 1)
|
|
mix_stft = torch.view_as_real(mix_stft.permute(0, 3, 2, 1))
|
|
|
|
outs = []
|
|
for sample in range(B):
|
|
pos = 0
|
|
out = []
|
|
for pos in range(0, T, wiener_win_len):
|
|
frame = slice(pos, pos + wiener_win_len)
|
|
z_out = wiener(
|
|
mag_out[sample, frame],
|
|
mix_stft[sample, frame],
|
|
niters,
|
|
residual=residual,
|
|
)
|
|
out.append(z_out.transpose(-1, -2))
|
|
outs.append(torch.cat(out, dim=0))
|
|
out = torch.view_as_complex(torch.stack(outs, 0))
|
|
out = out.permute(0, 4, 3, 2, 1).contiguous()
|
|
if residual:
|
|
out = out[:, :-1]
|
|
assert list(out.shape) == [B, S, C, Fq, T]
|
|
return out.to(init)
|
|
|
|
def valid_length(self, length: int):
|
|
"""
|
|
Return a length that is appropriate for evaluation.
|
|
In our case, always return the training length, unless
|
|
it is smaller than the given length, in which case this
|
|
raises an error.
|
|
"""
|
|
if not self.use_train_segment:
|
|
return length
|
|
training_length = int(self.segment * self.samplerate)
|
|
if training_length < length:
|
|
raise ValueError(
|
|
f"Given length {length} is longer than "
|
|
f"training length {training_length}")
|
|
return training_length
|
|
|
|
def forward(self, mix):
|
|
length = mix.shape[-1]
|
|
length_pre_pad = None
|
|
if self.use_train_segment:
|
|
if self.training:
|
|
self.segment = Fraction(mix.shape[-1], self.samplerate)
|
|
else:
|
|
training_length = int(self.segment * self.samplerate)
|
|
if mix.shape[-1] < training_length:
|
|
length_pre_pad = mix.shape[-1]
|
|
mix = F.pad(mix, (0, training_length - length_pre_pad))
|
|
z = self._spec(mix)
|
|
mag = self._magnitude(z)
|
|
x = mag
|
|
|
|
B, C, Fq, T = x.shape
|
|
|
|
# unlike previous Demucs, we always normalize because it is easier.
|
|
mean = x.mean(dim=(1, 2, 3), keepdim=True)
|
|
std = x.std(dim=(1, 2, 3), keepdim=True)
|
|
x = (x - mean) / (1e-5 + std)
|
|
# x will be the freq. branch input.
|
|
|
|
# Prepare the time branch input.
|
|
xt = mix
|
|
meant = xt.mean(dim=(1, 2), keepdim=True)
|
|
stdt = xt.std(dim=(1, 2), keepdim=True)
|
|
xt = (xt - meant) / (1e-5 + stdt)
|
|
|
|
# okay, this is a giant mess I know...
|
|
saved = [] # skip connections, freq.
|
|
saved_t = [] # skip connections, time.
|
|
lengths = [] # saved lengths to properly remove padding, freq branch.
|
|
lengths_t = [] # saved lengths for time branch.
|
|
for idx, encode in enumerate(self.encoder):
|
|
lengths.append(x.shape[-1])
|
|
inject = None
|
|
if idx < len(self.tencoder):
|
|
# we have not yet merged branches.
|
|
lengths_t.append(xt.shape[-1])
|
|
tenc = self.tencoder[idx]
|
|
xt = tenc(xt)
|
|
if not tenc.empty:
|
|
# save for skip connection
|
|
saved_t.append(xt)
|
|
else:
|
|
# tenc contains just the first conv., so that now time and freq.
|
|
# branches have the same shape and can be merged.
|
|
inject = xt
|
|
x = encode(x, inject)
|
|
if idx == 0 and self.freq_emb is not None:
|
|
# add frequency embedding to allow for non equivariant convolutions
|
|
# over the frequency axis.
|
|
frs = torch.arange(x.shape[-2], device=x.device)
|
|
emb = self.freq_emb(frs).t()[None, :, :, None].expand_as(x)
|
|
x = x + self.freq_emb_scale * emb
|
|
|
|
saved.append(x)
|
|
if self.crosstransformer:
|
|
if self.bottom_channels:
|
|
b, c, f, t = x.shape
|
|
x = rearrange(x, "b c f t-> b c (f t)")
|
|
x = self.channel_upsampler(x)
|
|
x = rearrange(x, "b c (f t)-> b c f t", f=f)
|
|
xt = self.channel_upsampler_t(xt)
|
|
|
|
x, xt = self.crosstransformer(x, xt)
|
|
|
|
if self.bottom_channels:
|
|
x = rearrange(x, "b c f t-> b c (f t)")
|
|
x = self.channel_downsampler(x)
|
|
x = rearrange(x, "b c (f t)-> b c f t", f=f)
|
|
xt = self.channel_downsampler_t(xt)
|
|
|
|
for idx, decode in enumerate(self.decoder):
|
|
skip = saved.pop(-1)
|
|
x, pre = decode(x, skip, lengths.pop(-1))
|
|
# `pre` contains the output just before final transposed convolution,
|
|
# which is used when the freq. and time branch separate.
|
|
|
|
offset = self.depth - len(self.tdecoder)
|
|
if idx >= offset:
|
|
tdec = self.tdecoder[idx - offset]
|
|
length_t = lengths_t.pop(-1)
|
|
if tdec.empty:
|
|
assert pre.shape[2] == 1, pre.shape
|
|
pre = pre[:, :, 0]
|
|
xt, _ = tdec(pre, None, length_t)
|
|
else:
|
|
skip = saved_t.pop(-1)
|
|
xt, _ = tdec(xt, skip, length_t)
|
|
|
|
# Let's make sure we used all stored skip connections.
|
|
assert len(saved) == 0
|
|
assert len(lengths_t) == 0
|
|
assert len(saved_t) == 0
|
|
|
|
S = len(self.sources)
|
|
x = x.view(B, S, -1, Fq, T)
|
|
x = x * std[:, None] + mean[:, None]
|
|
|
|
zout = self._mask(z, x)
|
|
if self.use_train_segment:
|
|
if self.training:
|
|
x = self._ispec(zout, length)
|
|
else:
|
|
x = self._ispec(zout, training_length)
|
|
else:
|
|
x = self._ispec(zout, length)
|
|
|
|
if self.use_train_segment:
|
|
if self.training:
|
|
xt = xt.view(B, S, -1, length)
|
|
else:
|
|
xt = xt.view(B, S, -1, training_length)
|
|
else:
|
|
xt = xt.view(B, S, -1, length)
|
|
xt = xt * stdt[:, None] + meant[:, None]
|
|
x = xt + x
|
|
if length_pre_pad:
|
|
x = x[..., :length_pre_pad]
|
|
return x
|