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DeepFilterNet2 / app.py

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Small UI improvements, Examples

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	import math
	import tempfile
	from typing import Optional, Tuple, Union
	import gradio as gr
	import markdown
	import matplotlib.pyplot as plt
	import numpy as np
	import torch
	from loguru import logger
	from PIL import Image
	from torch import Tensor
	from torchaudio.backend.common import AudioMetaData

	from df import config
	from df.enhance import enhance, init_df, load_audio, save_audio
	from df.io import resample

	device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
	model, df, _ = init_df("./DeepFilterNet2", config_allow_defaults=True)
	model = model.to(device=device).eval()

	fig_noisy: plt.Figure
	fig_enh: plt.Figure
	ax_noisy: plt.Axes
	ax_enh: plt.Axes
	fig_noisy, ax_noisy = plt.subplots(figsize=(15.2, 4))
	fig_noisy.set_tight_layout(True)
	fig_enh, ax_enh = plt.subplots(figsize=(15.2, 4))
	fig_enh.set_tight_layout(True)

	NOISES = {
	"None": None,
	"Kitchen": "samples/dkitchen.wav",
	"Living Room": "samples/dliving.wav",
	"River": "samples/nriver.wav",
	"Cafe": "samples/scafe.wav",
	}


	def mix_at_snr(clean, noise, snr, eps=1e-10):
	"""Mix clean and noise signal at a given SNR.

	Args:
	clean: 1D Tensor with the clean signal to mix.
	noise: 1D Tensor of shape.
	snr: Signal to noise ratio.

	Returns:
	clean: 1D Tensor with gain changed according to the snr.
	noise: 1D Tensor with the combined noise channels.
	mix: 1D Tensor with added clean and noise signals.

	"""
	clean = torch.as_tensor(clean).mean(0, keepdim=True)
	noise = torch.as_tensor(noise).mean(0, keepdim=True)
	if noise.shape[1] < clean.shape[1]:
	noise = noise.repeat((1, int(math.ceil(clean.shape[1] / noise.shape[1]))))
	max_start = int(noise.shape[1] - clean.shape[1])
	start = torch.randint(0, max_start, ()).item() if max_start > 0 else 0
	logger.debug(f"start: {start}, {clean.shape}")
	noise = noise[:, start : start + clean.shape[1]]
	E_speech = torch.mean(clean.pow(2)) + eps
	E_noise = torch.mean(noise.pow(2))
	K = torch.sqrt((E_noise / E_speech) * 10 ** (snr / 10) + eps)
	noise = noise / K
	mixture = clean + noise
	logger.debug("mixture: {mixture.shape}")
	assert torch.isfinite(mixture).all()
	max_m = mixture.abs().max()
	if max_m > 1:
	logger.warning(f"Clipping detected during mixing. Reducing gain by {1/max_m}")
	clean, noise, mixture = clean / max_m, noise / max_m, mixture / max_m
	return clean, noise, mixture


	def load_audio_gradio(
	audio_or_file: Union[None, str, Tuple[int, np.ndarray]], sr: int
	) -> Optional[Tuple[Tensor, AudioMetaData]]:
	if audio_or_file is None:
	return None
	if isinstance(audio_or_file, str):
	if audio_or_file.lower() == "none":
	return None
	# First try default format
	audio, meta = load_audio(audio_or_file, sr)
	else:
	meta = AudioMetaData(-1, -1, -1, -1, "")
	assert isinstance(audio_or_file, (tuple, list))
	meta.sample_rate, audio_np = audio_or_file
	# Gradio documentation says, the shape is [samples, 2], but apparently sometimes its not.
	audio_np = audio_np.reshape(audio_np.shape[0], -1).T
	if audio_np.dtype == np.int16:
	audio_np = (audio_np / (1 << 15)).astype(np.float32)
	elif audio_np.dtype == np.int32:
	audio_np = (audio_np / (1 << 31)).astype(np.float32)
	audio = resample(torch.from_numpy(audio_np), meta.sample_rate, sr)
	return audio, meta


	def demo_fn(speech_upl: str, noise_type: str, snr: int, mic_input: str):
	if (mic_input):
	speech_upl = mic_input
	sr = config("sr", 48000, int, section="df")
	logger.info(f"Got parameters speech_upl: {speech_upl}, noise: {noise_type}, snr: {snr}")
	snr = int(snr)
	noise_fn = NOISES[noise_type]
	meta = AudioMetaData(-1, -1, -1, -1, "")
	max_s = 10 # limit to 10 seconds
	if speech_upl is not None:
	sample, meta = load_audio(speech_upl, sr)
	max_len = max_s * sr
	if sample.shape[-1] > max_len:
	start = torch.randint(0, sample.shape[-1] - max_len, ()).item()
	sample = sample[..., start : start + max_len]
	else:
	sample, meta = load_audio("samples/p232_013_clean.wav", sr)
	sample = sample[..., : max_s * sr]
	if sample.dim() > 1 and sample.shape[0] > 1:
	assert (
	sample.shape[1] > sample.shape[0]
	), f"Expecting channels first, but got {sample.shape}"
	sample = sample.mean(dim=0, keepdim=True)
	logger.info(f"Loaded sample with shape {sample.shape}")
	if noise_fn is not None:
	noise, _ = load_audio(noise_fn, sr) # type: ignore
	logger.info(f"Loaded noise with shape {noise.shape}")
	_, _, sample = mix_at_snr(sample, noise, snr)
	logger.info("Start denoising audio")
	enhanced = enhance(model, df, sample)
	logger.info("Denoising finished")
	lim = torch.linspace(0.0, 1.0, int(sr * 0.15)).unsqueeze(0)
	lim = torch.cat((lim, torch.ones(1, enhanced.shape[1] - lim.shape[1])), dim=1)
	enhanced = enhanced * lim
	if meta.sample_rate != sr:
	enhanced = resample(enhanced, sr, meta.sample_rate)
	sample = resample(sample, sr, meta.sample_rate)
	sr = meta.sample_rate
	noisy_wav = tempfile.NamedTemporaryFile(suffix="noisy.wav", delete=False).name
	save_audio(noisy_wav, sample, sr)
	enhanced_wav = tempfile.NamedTemporaryFile(suffix="enhanced.wav", delete=False).name
	save_audio(enhanced_wav, enhanced, sr)
	logger.info(f"saved audios: {noisy_wav}, {enhanced_wav}")
	ax_noisy.clear()
	ax_enh.clear()
	noisy_im = spec_im(sample, sr=sr, figure=fig_noisy, ax=ax_noisy)
	enh_im = spec_im(enhanced, sr=sr, figure=fig_enh, ax=ax_enh)
	# noisy_wav = gr.make_waveform(noisy_fn, bar_count=200)
	# enh_wav = gr.make_waveform(enhanced_fn, bar_count=200)
	return noisy_wav, noisy_im, enhanced_wav, enh_im


	def specshow(
	spec,
	ax=None,
	title=None,
	xlabel=None,
	ylabel=None,
	sr=48000,
	n_fft=None,
	hop=None,
	t=None,
	f=None,
	vmin=-100,
	vmax=0,
	xlim=None,
	ylim=None,
	cmap="inferno",
	):
	"""Plots a spectrogram of shape [F, T]"""
	spec_np = spec.cpu().numpy() if isinstance(spec, torch.Tensor) else spec
	if ax is not None:
	set_title = ax.set_title
	set_xlabel = ax.set_xlabel
	set_ylabel = ax.set_ylabel
	set_xlim = ax.set_xlim
	set_ylim = ax.set_ylim
	else:
	ax = plt
	set_title = plt.title
	set_xlabel = plt.xlabel
	set_ylabel = plt.ylabel
	set_xlim = plt.xlim
	set_ylim = plt.ylim
	if n_fft is None:
	if spec.shape[0] % 2 == 0:
	n_fft = spec.shape[0] * 2
	else:
	n_fft = (spec.shape[0] - 1) * 2
	hop = hop or n_fft // 4
	if t is None:
	t = np.arange(0, spec_np.shape[-1]) * hop / sr
	if f is None:
	f = np.arange(0, spec_np.shape[0]) * sr // 2 / (n_fft // 2) / 1000
	im = ax.pcolormesh(
	t, f, spec_np, rasterized=True, shading="auto", vmin=vmin, vmax=vmax, cmap=cmap
	)
	if title is not None:
	set_title(title)
	if xlabel is not None:
	set_xlabel(xlabel)
	if ylabel is not None:
	set_ylabel(ylabel)
	if xlim is not None:
	set_xlim(xlim)
	if ylim is not None:
	set_ylim(ylim)
	return im


	def spec_im(
	audio: torch.Tensor,
	figsize=(15, 5),
	colorbar=False,
	colorbar_format=None,
	figure=None,
	labels=True,
	**kwargs,
	) -> Image:
	audio = torch.as_tensor(audio)
	if labels:
	kwargs.setdefault("xlabel", "Time [s]")
	kwargs.setdefault("ylabel", "Frequency [Hz]")
	n_fft = kwargs.setdefault("n_fft", 1024)
	hop = kwargs.setdefault("hop", 512)
	w = torch.hann_window(n_fft, device=audio.device)
	spec = torch.stft(audio, n_fft, hop, window=w, return_complex=False)
	spec = spec.div_(w.pow(2).sum())
	spec = torch.view_as_complex(spec).abs().clamp_min(1e-12).log10().mul(10)
	kwargs.setdefault("vmax", max(0.0, spec.max().item()))

	if figure is None:
	figure = plt.figure(figsize=figsize)
	figure.set_tight_layout(True)
	if spec.dim() > 2:
	spec = spec.squeeze(0)
	im = specshow(spec, **kwargs)
	if colorbar:
	ckwargs = {}
	if "ax" in kwargs:
	if colorbar_format is None:
	if kwargs.get("vmin", None) is not None or kwargs.get("vmax", None) is not None:
	colorbar_format = "%+2.0f dB"
	ckwargs = {"ax": kwargs["ax"]}
	plt.colorbar(im, format=colorbar_format, **ckwargs)
	figure.canvas.draw()
	return Image.frombytes("RGB", figure.canvas.get_width_height(), figure.canvas.tostring_rgb())


	def toggle(choice):
	if choice == "mic":
	return gr.update(visible=True, value=None), gr.update(visible=False, value=None)
	else:
	return gr.update(visible=False, value=None), gr.update(visible=True, value=None)


	with gr.Blocks() as demo:
	with gr.Row():
	gr.Markdown("## DeepFilterNet2 Demo")
	gr.Markdown("This demo denoises audio files using DeepFilterNet. Try it with your own voice!")
	with gr.Row():
	with gr.Column():
	radio = gr.Radio(["mic", "file"], value="file",
	label="How would you like to upload your audio?")
	mic_input = gr.Mic(label="Input", type="filepath", visible=False)
	audio_file = gr.Audio(
	type="filepath", label="Input", visible=True)
	inputs = [
	audio_file,
	gr.Dropdown(
	label="Add background noise",
	choices=list(NOISES.keys()),
	value="None",
	),
	gr.Dropdown(
	label="Noise Level (SNR)",
	choices=["-5", "0", "10", "20"],
	value="10",
	),
	mic_input
	]
	btn = gr.Button("Generate")
	with gr.Column():
	outputs = [
	# gr.Video(type="filepath", label="Noisy audio"),
	gr.Audio(type="filepath", label="Noisy audio"),
	gr.Image(label="Noisy spectrogram"),
	# gr.Video(type="filepath", label="Enhanced audio"),
	gr.Audio(type="filepath", label="Enhanced audio"),
	gr.Image(label="Enhanced spectrogram"),
	]
	btn.click(fn=demo_fn, inputs=inputs, outputs=outputs)
	radio.change(toggle, radio, [mic_input, audio_file])
	gr.Examples([
	["./samples/p232_013_clean.wav", "Kitchen", "10"],
	["./samples/p232_013_clean.wav", "Cafe", "10"],
	["./samples/p232_019_clean.wav", "Cafe", "10"],
	["./samples/p232_019_clean.wav", "River", "10"]],
	fn=demo_fn, inputs=inputs, outputs=outputs, cache_examples=True),
	gr.Markdown(open("usage.md").read())


	demo.launch(enable_queue=True)