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cwitkowitz
commited on
Commit
•
883013e
1
Parent(s):
94fc053
Working standalone.
Browse files- .gitignore +3 -0
- app.py +83 -0
- model-8750.pt +3 -0
- models/__init__.py +0 -0
- models/cqt_module.py +281 -0
- models/transcriber.py +626 -0
- requirements.txt +6 -0
.gitignore
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*__pycache__
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_outputs
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.idea
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app.py
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from pyharp import ModelCard, build_endpoint
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import gradio as gr
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import torchaudio
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import torch
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import os
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timbre_trap = torch.load('model-8750.pt', map_location='cpu')
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card = ModelCard(
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name='Timbre-Trap',
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description='De-timbre your audio!',
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author='Frank Cwitkowitz',
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tags=['example', 'music transcription', 'multi-pitch estimation', 'timbre filtering']
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)
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def process_fn(audio_path, de_timbre):
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# Load the audio with torchaudio
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audio, fs = torchaudio.load(audio_path)
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# Average channels to obtain mono-channel
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audio = torch.mean(audio, dim=0, keepdim=True)
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# Resample audio to the specified sampling rate
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audio = torchaudio.functional.resample(audio, fs, 22050)
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# Add a batch dimension
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audio = audio.unsqueeze(0)
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# Determine original number of samples
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n_samples = audio.size(-1)
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# Pad audio to next multiple of block length
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audio = timbre_trap.sliCQ.pad_to_block_length(audio)
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# Encode raw audio into latent vectors
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latents, embeddings, _ = timbre_trap.encode(audio)
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# Apply skip connections if they are turned on
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embeddings = timbre_trap.apply_skip_connections(embeddings)
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# Obtain transcription or reconstructed spectral coefficients
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coefficients = timbre_trap.decode(latents, embeddings, de_timbre)
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# Invert reconstructed spectral coefficients
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audio = timbre_trap.sliCQ.decode(coefficients)
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# Trim to original number of samples
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audio = audio[..., :n_samples]
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# Remove batch dimension
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audio = audio.squeeze(0)
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if de_timbre and audio.abs().max():
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# Normalize audio to [-1, 1]
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audio /= audio.abs().max()
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# Create a temporary directory for output
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os.makedirs('_outputs', exist_ok=True)
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# Create a path for saving the audio
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save_path = os.path.join('_outputs', 'output.wav')
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# Save the audio
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torchaudio.save(save_path, audio, 22050)
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return save_path
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with gr.Blocks() as demo:
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inputs = [
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gr.Audio(
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label='Audio Input',
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type='filepath'
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),
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#gr.Checkbox(
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# value=False,
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# label='De-Timbre'
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#)
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gr.Slider(
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minimum=0,
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maximum=1,
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step=1,
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value=0,
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label='De-Timbre'
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)
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]
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output = gr.Audio(label='Audio Output', type='filepath')
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ctrls_data, ctrls_button, process_button = build_endpoint(inputs, output, process_fn, card)
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demo.launch(share=True)
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model-8750.pt
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version https://git-lfs.github.com/spec/v1
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oid sha256:e1eb515001ebb871a934379bbd44a22e00a2f41b20c34cd862274aa04c0ca900
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size 11401913
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models/__init__.py
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File without changes
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models/cqt_module.py
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from torchaudio.transforms import AmplitudeToDB
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from cqt_pytorch import CQT as _CQT
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import numpy as np
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import librosa
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import torch
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import math
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class CQT(_CQT):
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"""
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Wrapper which adds some basic functionality to the sliCQ module.
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"""
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def __init__(self, n_octaves, bins_per_octave, sample_rate, secs_per_block):
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"""
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Instantiate the sliCQ module and wrapper.
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Parameters
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----------
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n_octaves : int
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Number of octaves below Nyquist to span
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bins_per_octave : int
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Number of bins allocated to each octave
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sample_rate : int or float
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Number of samples per second of audio
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secs_per_block : float
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Number of seconds to process at a time
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"""
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super().__init__(num_octaves=n_octaves,
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num_bins_per_octave=bins_per_octave,
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sample_rate=sample_rate,
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block_length=int(secs_per_block * sample_rate),
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power_of_2_length=True)
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self.sample_rate = sample_rate
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# Compute hop length corresponding to transform coefficients
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self.hop_length = (self.block_length / self.max_window_length)
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# Compute total number of bins
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self.n_bins = n_octaves * bins_per_octave
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# Determine frequency (MIDI) below Nyquist by specified octaves
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fmin = librosa.hz_to_midi((sample_rate / 2) / (2 ** n_octaves))
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# Determine center frequency (MIDI) associated with each bin of module
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self.midi_freqs = fmin + np.arange(self.n_bins) / (bins_per_octave / 12)
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def forward(self, audio):
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"""
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Encode a batch of audio into CQT spectral coefficients.
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Parameters
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----------
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audio : Tensor (B x 1 X T)
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Batch of input audio
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Returns
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----------
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coefficients : Tensor (B x 2 x F X T)
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Batch of real/imaginary CQT coefficients
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"""
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with torch.no_grad():
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# Obtain complex CQT coefficients
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coefficients = self.encode(audio)
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# Convert complex coefficients to real representation
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coefficients = self.to_real(coefficients)
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return coefficients
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@staticmethod
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def to_real(coefficients):
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"""
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Convert a set of complex coefficients to equivalent real representation.
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Parameters
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----------
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coefficients : Tensor (B x 1 x F X T)
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Batch of complex CQT coefficients
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Returns
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----------
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coefficients : Tensor (B x 2 x F X T)
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Batch of real/imaginary CQT coefficients
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"""
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# Collapse channel dimension (mono assumed)
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coefficients = coefficients.squeeze(-3)
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# Convert complex coefficients to real and imaginary
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coefficients = torch.view_as_real(coefficients)
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# Place real and imaginary coefficients under channel dimension
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coefficients = coefficients.transpose(-1, -2).transpose(-2, -3)
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return coefficients
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@staticmethod
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def to_complex(coefficients):
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"""
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Convert a set of real coefficients to their equivalent complex representation.
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Parameters
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----------
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coefficients : Tensor (B x 2 x F X T)
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Batch of real/imaginary CQT coefficients
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Returns
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----------
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coefficients : Tensor (B x F X T)
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Batch of complex CQT coefficients
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"""
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# Move real and imaginary coefficients to last dimension
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coefficients = coefficients.transpose(-3, -2).transpose(-2, -1)
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# Convert real and imaginary coefficients to complex
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coefficients = torch.view_as_complex(coefficients.contiguous())
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return coefficients
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@staticmethod
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def to_magnitude(coefficients):
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"""
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Compute the magnitude for a set of real coefficients.
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Parameters
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----------
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coefficients : Tensor (B x 2 x F X T)
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Batch of real/imaginary CQT coefficients
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Returns
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----------
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magnitude : Tensor (B x F X T)
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Batch of magnitude coefficients
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"""
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# Compute L2-norm of coefficients to compute magnitude
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magnitude = coefficients.norm(p=2, dim=-3)
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return magnitude
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@staticmethod
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def to_decibels(magnitude, rescale=True):
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"""
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Convert a set of magnitude coefficients to decibels.
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TODO - move 0 dB only if maximum is higher?
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- currently it's consistent with previous dB scaling
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- currently it's only used for visualization
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Parameters
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----------
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magnitude : Tensor (B x F X T)
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Batch of magnitude coefficients (amplitude)
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rescale : bool
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Rescale decibels to the range [0, 1]
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Returns
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----------
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decibels : Tensor (B x F X T)
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Batch of magnitude coefficients (dB)
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"""
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# Initialize a differentiable conversion to decibels
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decibels = AmplitudeToDB(stype='amplitude', top_db=80)(magnitude)
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if rescale:
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# Make 0 dB ceiling
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decibels -= decibels.max()
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# Rescale decibels to range [0, 1]
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decibels = 1 + decibels / 80
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return decibels
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def decode(self, coefficients):
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"""
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Invert CQT spectral coefficients to synthesize audio.
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Parameters
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----------
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coefficients : Tensor (B x 2 OR 1 x F X T)
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Batch of real/imaginary OR complex CQT coefficients
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Returns
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----------
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output : Tensor (B x 1 x T)
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Batch of reconstructed audio
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"""
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with torch.no_grad():
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if not coefficients.is_complex():
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# Convert real coefficients to complex representation
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coefficients = self.to_complex(coefficients)
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# Add a channel dimension to coefficients
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coefficients = coefficients.unsqueeze(-3)
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# Decode the complex CQT coefficients
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audio = super().decode(coefficients)
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return audio
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def pad_to_block_length(self, audio):
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"""
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Pad audio to the next multiple of block length such that it can be processed in full.
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Parameters
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----------
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audio : Tensor (B x 1 X T)
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Batch of audio
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Returns
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----------
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audio : Tensor (B x 1 X T + p)
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Batch of padded audio
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"""
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# Pad the audio with zeros to fill up the remainder of the final block
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audio = torch.nn.functional.pad(audio, (0, -audio.size(-1) % self.block_length))
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return audio
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def get_expected_samples(self, t):
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224 |
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"""
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Determine the number of samples corresponding to a specified amount of time.
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226 |
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227 |
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Parameters
|
228 |
+
----------
|
229 |
+
t : float
|
230 |
+
Amount of time
|
231 |
+
|
232 |
+
Returns
|
233 |
+
----------
|
234 |
+
num_samples : int
|
235 |
+
Number of audio samples expected
|
236 |
+
"""
|
237 |
+
|
238 |
+
# Compute number of samples and round down
|
239 |
+
num_samples = int(max(0, t) * self.sample_rate)
|
240 |
+
|
241 |
+
return num_samples
|
242 |
+
|
243 |
+
def get_expected_frames(self, num_samples):
|
244 |
+
"""
|
245 |
+
Determine the number of frames the module will return for a given number of samples.
|
246 |
+
|
247 |
+
Parameters
|
248 |
+
----------
|
249 |
+
num_samples : int
|
250 |
+
Number of audio samples available
|
251 |
+
|
252 |
+
Returns
|
253 |
+
----------
|
254 |
+
num_frames : int
|
255 |
+
Number of frames expected
|
256 |
+
"""
|
257 |
+
|
258 |
+
# Number frames of coefficients per chunk times amount of chunks
|
259 |
+
num_frames = math.ceil((num_samples / self.block_length) * self.max_window_length)
|
260 |
+
|
261 |
+
return num_frames
|
262 |
+
|
263 |
+
def get_times(self, n_frames):
|
264 |
+
"""
|
265 |
+
Determine the time associated with each frame of coefficients.
|
266 |
+
|
267 |
+
Parameters
|
268 |
+
----------
|
269 |
+
n_frames : int
|
270 |
+
Number of frames available
|
271 |
+
|
272 |
+
Returns
|
273 |
+
----------
|
274 |
+
times : ndarray (T)
|
275 |
+
Time (seconds) associated with each frame
|
276 |
+
"""
|
277 |
+
|
278 |
+
# Compute times as cumulative hops in seconds
|
279 |
+
times = np.arange(n_frames) * self.hop_length / self.sample_rate
|
280 |
+
|
281 |
+
return times
|
models/transcriber.py
ADDED
@@ -0,0 +1,626 @@
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|
|
|
|
1 |
+
from .cqt_module import CQT
|
2 |
+
|
3 |
+
import torch.nn as nn
|
4 |
+
import torch
|
5 |
+
|
6 |
+
|
7 |
+
class Transcriber(nn.Module):
|
8 |
+
"""
|
9 |
+
Implements a 2D convolutional U-Net architecture based loosely on SoundStream.
|
10 |
+
"""
|
11 |
+
|
12 |
+
def __init__(self, sample_rate, n_octaves, bins_per_octave, secs_per_block=3, latent_size=None, model_complexity=1, skip_connections=False):
|
13 |
+
"""
|
14 |
+
Initialize the full autoencoder.
|
15 |
+
|
16 |
+
Parameters
|
17 |
+
----------
|
18 |
+
sample_rate : int
|
19 |
+
Expected sample rate of input
|
20 |
+
n_octaves : int
|
21 |
+
Number of octaves below Nyquist frequency to represent
|
22 |
+
bins_per_octave : int
|
23 |
+
Number of frequency bins within each octave
|
24 |
+
secs_per_block : float
|
25 |
+
Number of seconds to process at once with sliCQ
|
26 |
+
latent_size : int or None (Optional)
|
27 |
+
Dimensionality of latent space
|
28 |
+
model_complexity : int
|
29 |
+
Scaling factor for number of filters and embedding sizes
|
30 |
+
skip_connections : bool
|
31 |
+
Whether to include skip connections between encoder and decoder
|
32 |
+
"""
|
33 |
+
|
34 |
+
nn.Module.__init__(self)
|
35 |
+
|
36 |
+
self.sliCQ = CQT(n_octaves=n_octaves,
|
37 |
+
bins_per_octave=bins_per_octave,
|
38 |
+
sample_rate=sample_rate,
|
39 |
+
secs_per_block=secs_per_block)
|
40 |
+
|
41 |
+
self.encoder = Encoder(feature_size=self.sliCQ.n_bins, latent_size=latent_size, model_complexity=model_complexity)
|
42 |
+
self.decoder = Decoder(feature_size=self.sliCQ.n_bins, latent_size=latent_size, model_complexity=model_complexity)
|
43 |
+
|
44 |
+
if skip_connections:
|
45 |
+
# Start by adding encoder features with identity weighting
|
46 |
+
self.skip_weights = torch.nn.Parameter(torch.ones(5))
|
47 |
+
else:
|
48 |
+
# No skip connections
|
49 |
+
self.skip_weights = None
|
50 |
+
|
51 |
+
def encode(self, audio):
|
52 |
+
"""
|
53 |
+
Encode a batch of raw audio into latent codes.
|
54 |
+
|
55 |
+
Parameters
|
56 |
+
----------
|
57 |
+
audio : Tensor (B x 1 x T)
|
58 |
+
Batch of input raw audio
|
59 |
+
|
60 |
+
Returns
|
61 |
+
----------
|
62 |
+
latents : Tensor (B x D_lat x T)
|
63 |
+
Batch of latent codes
|
64 |
+
embeddings : list of [Tensor (B x C x H x T)]
|
65 |
+
Embeddings produced by encoder at each level
|
66 |
+
losses : dict containing
|
67 |
+
...
|
68 |
+
"""
|
69 |
+
|
70 |
+
# Compute CQT spectral features
|
71 |
+
coefficients = self.sliCQ(audio)
|
72 |
+
|
73 |
+
# Encode features into latent vectors
|
74 |
+
latents, embeddings, losses = self.encoder(coefficients)
|
75 |
+
|
76 |
+
return latents, embeddings, losses
|
77 |
+
|
78 |
+
def apply_skip_connections(self, embeddings):
|
79 |
+
"""
|
80 |
+
Apply skip connections to encoder embeddings, or discard the embeddings if skip connections do not exist.
|
81 |
+
|
82 |
+
Parameters
|
83 |
+
----------
|
84 |
+
embeddings : list of [Tensor (B x C x H x T)]
|
85 |
+
Embeddings produced by encoder at each level
|
86 |
+
|
87 |
+
Returns
|
88 |
+
----------
|
89 |
+
embeddings : list of [Tensor (B x C x H x T)]
|
90 |
+
Encoder embeddings scaled with learnable weight
|
91 |
+
"""
|
92 |
+
|
93 |
+
if self.skip_weights is not None:
|
94 |
+
# Apply a learnable weight to the embeddings for the skip connection
|
95 |
+
embeddings = [self.skip_weights[i] * e for i, e in enumerate(embeddings)]
|
96 |
+
else:
|
97 |
+
# Discard embeddings from encoder
|
98 |
+
embeddings = None
|
99 |
+
|
100 |
+
return embeddings
|
101 |
+
|
102 |
+
def decode(self, latents, embeddings=None, transcribe=False):
|
103 |
+
"""
|
104 |
+
Decode a batch of latent codes into logits representing real/imaginary coefficients.
|
105 |
+
|
106 |
+
Parameters
|
107 |
+
----------
|
108 |
+
latents : Tensor (B x D_lat x T)
|
109 |
+
Batch of latent codes
|
110 |
+
embeddings : list of [Tensor (B x C x H x T)] or None (no skip connections)
|
111 |
+
Embeddings produced by encoder at each level
|
112 |
+
transcribe : bool
|
113 |
+
Switch for performing transcription vs. reconstruction
|
114 |
+
|
115 |
+
Returns
|
116 |
+
----------
|
117 |
+
coefficients : Tensor (B x 2 x F X T)
|
118 |
+
Batch of output logits [-∞, ∞]
|
119 |
+
"""
|
120 |
+
|
121 |
+
# Create binary values to indicate function decoder should perform
|
122 |
+
indicator = (not transcribe) * torch.ones_like(latents[..., :1, :])
|
123 |
+
|
124 |
+
# Concatenate indicator to final dimension of latents
|
125 |
+
latents = torch.cat((latents, indicator), dim=-2)
|
126 |
+
|
127 |
+
# Decode latent vectors into real/imaginary coefficients
|
128 |
+
coefficients = self.decoder(latents, embeddings)
|
129 |
+
|
130 |
+
return coefficients
|
131 |
+
|
132 |
+
def transcribe(self, audio):
|
133 |
+
"""
|
134 |
+
Obtain transcriptions for a batch of raw audio.
|
135 |
+
|
136 |
+
Parameters
|
137 |
+
----------
|
138 |
+
audio : Tensor (B x 1 x T)
|
139 |
+
Batch of input raw audio
|
140 |
+
|
141 |
+
Returns
|
142 |
+
----------
|
143 |
+
activations : Tensor (B x F X T)
|
144 |
+
Batch of multi-pitch activations [0, 1]
|
145 |
+
"""
|
146 |
+
|
147 |
+
# Encode raw audio into latent vectors
|
148 |
+
latents, embeddings, _ = self.encode(audio)
|
149 |
+
|
150 |
+
# Apply skip connections if they are turned on
|
151 |
+
embeddings = self.apply_skip_connections(embeddings)
|
152 |
+
|
153 |
+
# Estimate pitch using transcription switch
|
154 |
+
coefficients = self.decode(latents, embeddings, True)
|
155 |
+
|
156 |
+
# Extract magnitude of decoded coefficients and convert to activations
|
157 |
+
activations = torch.nn.functional.tanh(self.sliCQ.to_magnitude(coefficients))
|
158 |
+
|
159 |
+
return activations
|
160 |
+
|
161 |
+
def reconstruct(self, audio):
|
162 |
+
"""
|
163 |
+
Obtain reconstructed coefficients for a batch of raw audio.
|
164 |
+
|
165 |
+
Parameters
|
166 |
+
----------
|
167 |
+
audio : Tensor (B x 1 x T)
|
168 |
+
Batch of input raw audio
|
169 |
+
|
170 |
+
Returns
|
171 |
+
----------
|
172 |
+
reconstruction : Tensor (B x 2 x F X T)
|
173 |
+
Batch of reconstructed spectral coefficients
|
174 |
+
"""
|
175 |
+
|
176 |
+
# Encode raw audio into latent vectors
|
177 |
+
latents, embeddings, losses = self.encode(audio)
|
178 |
+
|
179 |
+
# Apply skip connections if they are turned on
|
180 |
+
embeddings = self.apply_skip_connections(embeddings)
|
181 |
+
|
182 |
+
# Decode latent vectors into spectral coefficients
|
183 |
+
reconstruction = self.decode(latents, embeddings)
|
184 |
+
|
185 |
+
return reconstruction
|
186 |
+
|
187 |
+
def forward(self, audio, consistency=False):
|
188 |
+
"""
|
189 |
+
Perform all model functions efficiently (for training/evaluation).
|
190 |
+
|
191 |
+
Parameters
|
192 |
+
----------
|
193 |
+
audio : Tensor (B x 1 x T)
|
194 |
+
Batch of input raw audio
|
195 |
+
consistency : bool
|
196 |
+
Whether to perform computations for consistency loss
|
197 |
+
|
198 |
+
Returns
|
199 |
+
----------
|
200 |
+
reconstruction : Tensor (B x 2 x F X T)
|
201 |
+
Batch of reconstructed spectral coefficients
|
202 |
+
latents : Tensor (B x D_lat x T)
|
203 |
+
Batch of latent codes
|
204 |
+
transcription : Tensor (B x 2 x F X T)
|
205 |
+
Batch of transcription spectral coefficients
|
206 |
+
transcription_rec : Tensor (B x 2 x F X T)
|
207 |
+
Batch of reconstructed spectral coefficients for transcription coefficients input
|
208 |
+
transcription_scr : Tensor (B x 2 x F X T)
|
209 |
+
Batch of transcription spectral coefficients for transcription coefficients input
|
210 |
+
losses : dict containing
|
211 |
+
...
|
212 |
+
"""
|
213 |
+
|
214 |
+
# Encode raw audio into latent vectors
|
215 |
+
latents, embeddings, losses = self.encode(audio)
|
216 |
+
|
217 |
+
# Apply skip connections if they are turned on
|
218 |
+
embeddings = self.apply_skip_connections(embeddings)
|
219 |
+
|
220 |
+
# Decode latent vectors into spectral coefficients
|
221 |
+
reconstruction = self.decode(latents, embeddings)
|
222 |
+
|
223 |
+
# Estimate pitch using transcription switch
|
224 |
+
transcription = self.decode(latents, embeddings, True)
|
225 |
+
|
226 |
+
if consistency:
|
227 |
+
# Encode transcription coefficients for samples with ground-truth
|
228 |
+
latents_trn, embeddings_trn, _ = self.encoder(transcription)
|
229 |
+
|
230 |
+
# Apply skip connections if they are turned on
|
231 |
+
embeddings_trn = self.apply_skip_connections(embeddings_trn)
|
232 |
+
|
233 |
+
# Attempt to reconstruct transcription spectral coefficients
|
234 |
+
transcription_rec = self.decode(latents_trn, embeddings_trn)
|
235 |
+
|
236 |
+
# Attempt to transcribe audio pertaining to transcription coefficients
|
237 |
+
transcription_scr = self.decode(latents_trn, embeddings_trn, True)
|
238 |
+
else:
|
239 |
+
# Return null for both sets of coefficients
|
240 |
+
transcription_rec, transcription_scr = None, None
|
241 |
+
|
242 |
+
return reconstruction, latents, transcription, transcription_rec, transcription_scr, losses
|
243 |
+
|
244 |
+
|
245 |
+
class Encoder(nn.Module):
|
246 |
+
"""
|
247 |
+
Implements a 2D convolutional encoder.
|
248 |
+
"""
|
249 |
+
|
250 |
+
def __init__(self, feature_size, latent_size=None, model_complexity=1):
|
251 |
+
"""
|
252 |
+
Initialize the encoder.
|
253 |
+
|
254 |
+
Parameters
|
255 |
+
----------
|
256 |
+
feature_size : int
|
257 |
+
Dimensionality of input features
|
258 |
+
latent_size : int or None (Optional)
|
259 |
+
Dimensionality of latent space
|
260 |
+
model_complexity : int
|
261 |
+
Scaling factor for number of filters
|
262 |
+
"""
|
263 |
+
|
264 |
+
nn.Module.__init__(self)
|
265 |
+
|
266 |
+
channels = (2 * 2 ** (model_complexity - 1),
|
267 |
+
4 * 2 ** (model_complexity - 1),
|
268 |
+
8 * 2 ** (model_complexity - 1),
|
269 |
+
16 * 2 ** (model_complexity - 1),
|
270 |
+
32 * 2 ** (model_complexity - 1))
|
271 |
+
|
272 |
+
# Make sure all channel sizes are integers
|
273 |
+
channels = tuple([round(c) for c in channels])
|
274 |
+
|
275 |
+
if latent_size is None:
|
276 |
+
# Set default dimensionality
|
277 |
+
latent_size = 32 * 2 ** (model_complexity - 1)
|
278 |
+
|
279 |
+
self.convin = nn.Sequential(
|
280 |
+
nn.Conv2d(2, channels[0], kernel_size=3, padding='same'),
|
281 |
+
nn.ELU(inplace=True)
|
282 |
+
)
|
283 |
+
|
284 |
+
self.block1 = EncoderBlock(channels[0], channels[1], stride=2)
|
285 |
+
self.block2 = EncoderBlock(channels[1], channels[2], stride=2)
|
286 |
+
self.block3 = EncoderBlock(channels[2], channels[3], stride=2)
|
287 |
+
self.block4 = EncoderBlock(channels[3], channels[4], stride=2)
|
288 |
+
|
289 |
+
embedding_size = feature_size
|
290 |
+
|
291 |
+
for i in range(4):
|
292 |
+
# Dimensionality after strided convolutions
|
293 |
+
embedding_size = embedding_size // 2 - 1
|
294 |
+
|
295 |
+
self.convlat = nn.Conv2d(channels[4], latent_size, kernel_size=(embedding_size, 1))
|
296 |
+
|
297 |
+
def forward(self, coefficients):
|
298 |
+
"""
|
299 |
+
Encode a batch of input spectral features.
|
300 |
+
|
301 |
+
Parameters
|
302 |
+
----------
|
303 |
+
coefficients : Tensor (B x 2 x F X T)
|
304 |
+
Batch of input spectral features
|
305 |
+
|
306 |
+
Returns
|
307 |
+
----------
|
308 |
+
latents : Tensor (B x D_lat x T)
|
309 |
+
Batch of latent codes
|
310 |
+
embeddings : list of [Tensor (B x C x H x T)]
|
311 |
+
Embeddings produced by encoder at each level
|
312 |
+
losses : dict containing
|
313 |
+
...
|
314 |
+
"""
|
315 |
+
|
316 |
+
# Initialize a list to hold features for skip connections
|
317 |
+
embeddings = list()
|
318 |
+
|
319 |
+
# Encode features into embeddings
|
320 |
+
embeddings.append(self.convin(coefficients))
|
321 |
+
embeddings.append(self.block1(embeddings[-1]))
|
322 |
+
embeddings.append(self.block2(embeddings[-1]))
|
323 |
+
embeddings.append(self.block3(embeddings[-1]))
|
324 |
+
embeddings.append(self.block4(embeddings[-1]))
|
325 |
+
|
326 |
+
# Compute latent vectors from embeddings
|
327 |
+
latents = self.convlat(embeddings[-1]).squeeze(-2)
|
328 |
+
|
329 |
+
# No encoder losses
|
330 |
+
loss = dict()
|
331 |
+
|
332 |
+
return latents, embeddings, loss
|
333 |
+
|
334 |
+
|
335 |
+
class Decoder(nn.Module):
|
336 |
+
"""
|
337 |
+
Implements a 2D convolutional decoder.
|
338 |
+
"""
|
339 |
+
|
340 |
+
def __init__(self, feature_size, latent_size=None, model_complexity=1):
|
341 |
+
"""
|
342 |
+
Initialize the decoder.
|
343 |
+
|
344 |
+
Parameters
|
345 |
+
----------
|
346 |
+
feature_size : int
|
347 |
+
Dimensionality of input features
|
348 |
+
latent_size : int or None (Optional)
|
349 |
+
Dimensionality of latent space
|
350 |
+
model_complexity : int
|
351 |
+
Scaling factor for number of filters
|
352 |
+
"""
|
353 |
+
|
354 |
+
nn.Module.__init__(self)
|
355 |
+
|
356 |
+
channels = (32 * 2 ** (model_complexity - 1),
|
357 |
+
16 * 2 ** (model_complexity - 1),
|
358 |
+
8 * 2 ** (model_complexity - 1),
|
359 |
+
4 * 2 ** (model_complexity - 1),
|
360 |
+
2 * 2 ** (model_complexity - 1))
|
361 |
+
|
362 |
+
# Make sure all channel sizes are integers
|
363 |
+
channels = tuple([round(c) for c in channels])
|
364 |
+
|
365 |
+
if latent_size is None:
|
366 |
+
# Set default dimensionality
|
367 |
+
latent_size = 32 * 2 ** (model_complexity - 1)
|
368 |
+
|
369 |
+
padding = list()
|
370 |
+
|
371 |
+
embedding_size = feature_size
|
372 |
+
|
373 |
+
for i in range(4):
|
374 |
+
# Padding required for expected output size
|
375 |
+
padding.append(embedding_size % 2)
|
376 |
+
# Dimensionality after strided convolutions
|
377 |
+
embedding_size = embedding_size // 2 - 1
|
378 |
+
|
379 |
+
# Reverse order
|
380 |
+
padding.reverse()
|
381 |
+
|
382 |
+
self.convin = nn.Sequential(
|
383 |
+
nn.ConvTranspose2d(latent_size + 1, channels[0], kernel_size=(embedding_size, 1)),
|
384 |
+
nn.ELU(inplace=True)
|
385 |
+
)
|
386 |
+
|
387 |
+
self.block1 = DecoderBlock(channels[0], channels[1], stride=2, padding=padding[0])
|
388 |
+
self.block2 = DecoderBlock(channels[1], channels[2], stride=2, padding=padding[1])
|
389 |
+
self.block3 = DecoderBlock(channels[2], channels[3], stride=2, padding=padding[2])
|
390 |
+
self.block4 = DecoderBlock(channels[3], channels[4], stride=2, padding=padding[3])
|
391 |
+
|
392 |
+
self.convout = nn.Conv2d(channels[4], 2, kernel_size=3, padding='same')
|
393 |
+
|
394 |
+
def forward(self, latents, encoder_embeddings=None):
|
395 |
+
"""
|
396 |
+
Decode a batch of input latent codes.
|
397 |
+
|
398 |
+
Parameters
|
399 |
+
----------
|
400 |
+
latents : Tensor (B x D_lat x T)
|
401 |
+
Batch of latent codes
|
402 |
+
encoder_embeddings : list of [Tensor (B x C x H x T)] or None (no skip connections)
|
403 |
+
Embeddings produced by encoder at each level
|
404 |
+
|
405 |
+
Returns
|
406 |
+
----------
|
407 |
+
output : Tensor (B x 2 x F X T)
|
408 |
+
Batch of output logits [-∞, ∞]
|
409 |
+
"""
|
410 |
+
|
411 |
+
# Restore feature dimension
|
412 |
+
latents = latents.unsqueeze(-2)
|
413 |
+
|
414 |
+
# Process latents with decoder blocks
|
415 |
+
embeddings = self.convin(latents)
|
416 |
+
|
417 |
+
if encoder_embeddings is not None:
|
418 |
+
embeddings = embeddings + encoder_embeddings[-1]
|
419 |
+
|
420 |
+
embeddings = self.block1(embeddings)
|
421 |
+
|
422 |
+
if encoder_embeddings is not None:
|
423 |
+
embeddings = embeddings + encoder_embeddings[-2]
|
424 |
+
|
425 |
+
embeddings = self.block2(embeddings)
|
426 |
+
|
427 |
+
if encoder_embeddings is not None:
|
428 |
+
embeddings = embeddings + encoder_embeddings[-3]
|
429 |
+
|
430 |
+
embeddings = self.block3(embeddings)
|
431 |
+
|
432 |
+
if encoder_embeddings is not None:
|
433 |
+
embeddings = embeddings + encoder_embeddings[-4]
|
434 |
+
|
435 |
+
embeddings = self.block4(embeddings)
|
436 |
+
|
437 |
+
if encoder_embeddings is not None:
|
438 |
+
embeddings = embeddings + encoder_embeddings[-5]
|
439 |
+
|
440 |
+
# Decode embeddings into spectral logits
|
441 |
+
output = self.convout(embeddings)
|
442 |
+
|
443 |
+
return output
|
444 |
+
|
445 |
+
|
446 |
+
class EncoderBlock(nn.Module):
|
447 |
+
"""
|
448 |
+
Implements a chain of residual convolutional blocks with progressively
|
449 |
+
increased dilation, followed by down-sampling via strided convolution.
|
450 |
+
"""
|
451 |
+
|
452 |
+
def __init__(self, in_channels, out_channels, stride=2):
|
453 |
+
"""
|
454 |
+
Initialize the encoder block.
|
455 |
+
|
456 |
+
Parameters
|
457 |
+
----------
|
458 |
+
in_channels : int
|
459 |
+
Number of input feature channels
|
460 |
+
out_channels : int
|
461 |
+
Number of output feature channels
|
462 |
+
stride : int
|
463 |
+
Stride for the final convolutional layer
|
464 |
+
"""
|
465 |
+
|
466 |
+
nn.Module.__init__(self)
|
467 |
+
|
468 |
+
self.block1 = ResidualConv2dBlock(in_channels, in_channels, kernel_size=3, dilation=1)
|
469 |
+
self.block2 = ResidualConv2dBlock(in_channels, in_channels, kernel_size=3, dilation=2)
|
470 |
+
self.block3 = ResidualConv2dBlock(in_channels, in_channels, kernel_size=3, dilation=3)
|
471 |
+
|
472 |
+
self.hop = stride
|
473 |
+
self.win = 2 * stride
|
474 |
+
|
475 |
+
self.sconv = nn.Sequential(
|
476 |
+
# Down-sample along frequency (height) dimension via strided convolution
|
477 |
+
nn.Conv2d(in_channels, out_channels, kernel_size=(self.win, 1), stride=(self.hop, 1)),
|
478 |
+
nn.ELU(inplace=True)
|
479 |
+
)
|
480 |
+
|
481 |
+
def forward(self, x):
|
482 |
+
"""
|
483 |
+
Feed features through the encoder block.
|
484 |
+
|
485 |
+
Parameters
|
486 |
+
----------
|
487 |
+
x : Tensor (B x C_in x H x W)
|
488 |
+
Batch of input features
|
489 |
+
|
490 |
+
Returns
|
491 |
+
----------
|
492 |
+
y : Tensor (B x C_out x H x W)
|
493 |
+
Batch of corresponding output features
|
494 |
+
"""
|
495 |
+
|
496 |
+
# Process features
|
497 |
+
y = self.block1(x)
|
498 |
+
y = self.block2(y)
|
499 |
+
y = self.block3(y)
|
500 |
+
|
501 |
+
# Down-sample
|
502 |
+
y = self.sconv(y)
|
503 |
+
|
504 |
+
return y
|
505 |
+
|
506 |
+
|
507 |
+
class DecoderBlock(nn.Module):
|
508 |
+
"""
|
509 |
+
Implements up-sampling via transposed convolution, followed by a chain
|
510 |
+
of residual convolutional blocks with progressively increased dilation.
|
511 |
+
"""
|
512 |
+
|
513 |
+
def __init__(self, in_channels, out_channels, stride=2, padding=0):
|
514 |
+
"""
|
515 |
+
Initialize the encoder block.
|
516 |
+
|
517 |
+
Parameters
|
518 |
+
----------
|
519 |
+
in_channels : int
|
520 |
+
Number of input feature channels
|
521 |
+
out_channels : int
|
522 |
+
Number of output feature channels
|
523 |
+
stride : int
|
524 |
+
Stride for the transposed convolution
|
525 |
+
padding : int
|
526 |
+
Number of features to pad after up-sampling
|
527 |
+
"""
|
528 |
+
|
529 |
+
nn.Module.__init__(self)
|
530 |
+
|
531 |
+
self.hop = stride
|
532 |
+
self.win = 2 * stride
|
533 |
+
|
534 |
+
self.tconv = nn.Sequential(
|
535 |
+
# Up-sample along frequency (height) dimension via transposed convolution
|
536 |
+
nn.ConvTranspose2d(in_channels, out_channels, kernel_size=(self.win, 1), stride=(self.hop, 1), output_padding=(padding, 0)),
|
537 |
+
nn.ELU(inplace=True)
|
538 |
+
)
|
539 |
+
|
540 |
+
self.block1 = ResidualConv2dBlock(out_channels, out_channels, kernel_size=3, dilation=1)
|
541 |
+
self.block2 = ResidualConv2dBlock(out_channels, out_channels, kernel_size=3, dilation=2)
|
542 |
+
self.block3 = ResidualConv2dBlock(out_channels, out_channels, kernel_size=3, dilation=3)
|
543 |
+
|
544 |
+
def forward(self, x):
|
545 |
+
"""
|
546 |
+
Feed features through the decoder block.
|
547 |
+
|
548 |
+
Parameters
|
549 |
+
----------
|
550 |
+
x : Tensor (B x C_in x H x W)
|
551 |
+
Batch of input features
|
552 |
+
|
553 |
+
Returns
|
554 |
+
----------
|
555 |
+
y : Tensor (B x C_out x H x W)
|
556 |
+
Batch of corresponding output features
|
557 |
+
"""
|
558 |
+
|
559 |
+
# Up-sample
|
560 |
+
y = self.tconv(x)
|
561 |
+
|
562 |
+
# Process features
|
563 |
+
y = self.block1(y)
|
564 |
+
y = self.block2(y)
|
565 |
+
y = self.block3(y)
|
566 |
+
|
567 |
+
return y
|
568 |
+
|
569 |
+
|
570 |
+
class ResidualConv2dBlock(nn.Module):
|
571 |
+
"""
|
572 |
+
Implements a 2D convolutional block with dilation, no down-sampling, and a residual connection.
|
573 |
+
"""
|
574 |
+
|
575 |
+
def __init__(self, in_channels, out_channels, kernel_size=3, dilation=1):
|
576 |
+
"""
|
577 |
+
Initialize the convolutional block.
|
578 |
+
|
579 |
+
Parameters
|
580 |
+
----------
|
581 |
+
in_channels : int
|
582 |
+
Number of input feature channels
|
583 |
+
out_channels : int
|
584 |
+
Number of output feature channels
|
585 |
+
kernel_size : int
|
586 |
+
Kernel size for convolutions
|
587 |
+
dilation : int
|
588 |
+
Amount of dilation for first convolution
|
589 |
+
"""
|
590 |
+
|
591 |
+
nn.Module.__init__(self)
|
592 |
+
|
593 |
+
self.conv1 = nn.Sequential(
|
594 |
+
# TODO - only dilate across frequency?
|
595 |
+
nn.Conv2d(in_channels, out_channels, kernel_size=kernel_size, padding='same', dilation=dilation),
|
596 |
+
nn.ELU(inplace=True)
|
597 |
+
)
|
598 |
+
|
599 |
+
self.conv2 = nn.Sequential(
|
600 |
+
nn.Conv2d(out_channels, out_channels, kernel_size=1),
|
601 |
+
nn.ELU(inplace=True)
|
602 |
+
)
|
603 |
+
|
604 |
+
def forward(self, x):
|
605 |
+
"""
|
606 |
+
Feed features through the convolutional block.
|
607 |
+
|
608 |
+
Parameters
|
609 |
+
----------
|
610 |
+
x : Tensor (B x C_in x H x W)
|
611 |
+
Batch of input features
|
612 |
+
|
613 |
+
Returns
|
614 |
+
----------
|
615 |
+
y : Tensor (B x C_out x H x W)
|
616 |
+
Batch of corresponding output features
|
617 |
+
"""
|
618 |
+
|
619 |
+
# Process features
|
620 |
+
y = self.conv1(x)
|
621 |
+
y = self.conv2(y)
|
622 |
+
|
623 |
+
# Residual connection
|
624 |
+
y = y + x
|
625 |
+
|
626 |
+
return y
|
requirements.txt
ADDED
@@ -0,0 +1,6 @@
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
1 |
+
git+https://github.com/audacitorch/pyharp.git#egg=pyharp
|
2 |
+
#git+https://github.com/sony/timbre-trap@main
|
3 |
+
torchaudio
|
4 |
+
torch
|
5 |
+
cqt_pytorch
|
6 |
+
librosa
|