ITO-Master / app.py
jhtonyKoo's picture
modify app
6838a44
raw
history blame
10.2 kB
import gradio as gr
import torch
import soundfile as sf
import numpy as np
import yaml
from inference import MasteringStyleTransfer
from utils import download_youtube_audio
from config import args
import pyloudnorm as pyln
import tempfile
import os
import pandas as pd
mastering_transfer = MasteringStyleTransfer(args)
def denormalize_audio(audio, dtype=np.int16):
"""
Denormalize the audio from the range [-1, 1] to the full range of the specified dtype.
"""
if dtype == np.int16:
audio = np.clip(audio, -1, 1) # Ensure the input is in the range [-1, 1]
return (audio * 32767).astype(np.int16)
elif dtype == np.float32:
return audio.astype(np.float32)
else:
raise ValueError("Unsupported dtype. Use np.int16 or np.float32.")
def loudness_normalize(audio, sample_rate, target_loudness=-12.0):
# Ensure audio is float32
if audio.dtype != np.float32:
audio = audio.astype(np.float32)
# If audio is mono, reshape to (samples, 1)
if audio.ndim == 1:
audio = audio.reshape(-1, 1)
meter = pyln.Meter(sample_rate) # create BS.1770 meter
loudness = meter.integrated_loudness(audio)
loudness_normalized_audio = pyln.normalize.loudness(audio, loudness, target_loudness)
return loudness_normalized_audio
def process_youtube_url(url):
try:
audio, sr = download_youtube_audio(url)
return (sr, audio)
except Exception as e:
return None, f"Error processing YouTube URL: {str(e)}"
def process_audio_with_youtube(input_audio, input_youtube_url, reference_audio, reference_youtube_url):
if input_youtube_url:
input_audio, error = process_youtube_url(input_youtube_url)
if error:
return None, None, error
if reference_youtube_url:
reference_audio, error = process_youtube_url(reference_youtube_url)
if error:
return None, None, error
if input_audio is None or reference_audio is None:
return None, None, "Both input and reference audio are required."
return process_audio(input_audio, reference_audio)
def process_audio(input_audio, reference_audio):
output_audio, predicted_params, sr = mastering_transfer.process_audio(
input_audio, reference_audio, reference_audio
)
param_output = mastering_transfer.get_param_output_string(predicted_params)
# Convert output_audio to numpy array if it's a tensor
if isinstance(output_audio, torch.Tensor):
output_audio = output_audio.cpu().numpy()
if output_audio.ndim == 1:
output_audio = output_audio.reshape(-1, 1)
elif output_audio.ndim > 2:
output_audio = output_audio.squeeze()
# Ensure the audio is in the correct shape (samples, channels)
if output_audio.shape[1] > output_audio.shape[0]:
output_audio = output_audio.transpose(1,0)
print(output_audio.shape)
print(f"sr: {sr}")
# Normalize output audio
output_audio = loudness_normalize(output_audio, sr)
# Denormalize the audio to int16
output_audio = denormalize_audio(output_audio, dtype=np.int16)
return (sr, output_audio), param_output
def perform_ito(input_audio, reference_audio, ito_reference_audio, num_steps, optimizer, learning_rate, af_weights):
if ito_reference_audio is None:
ito_reference_audio = reference_audio
ito_config = {
'optimizer': optimizer,
'learning_rate': learning_rate,
'num_steps': num_steps,
'af_weights': af_weights,
'sample_rate': args.sample_rate
}
input_tensor = mastering_transfer.preprocess_audio(input_audio, args.sample_rate)
reference_tensor = mastering_transfer.preprocess_audio(reference_audio, args.sample_rate)
ito_reference_tensor = mastering_transfer.preprocess_audio(ito_reference_audio, args.sample_rate)
initial_reference_feature = mastering_transfer.get_reference_embedding(reference_tensor)
ito_log = ""
loss_values = []
for log_entry, current_output, current_params, step, loss in mastering_transfer.inference_time_optimization(
input_tensor, ito_reference_tensor, ito_config, initial_reference_feature
):
ito_log += log_entry
ito_param_output = mastering_transfer.get_param_output_string(current_params)
loss_values.append({"step": int(step), "loss": loss})
# Convert current_output to numpy array if it's a tensor
if isinstance(current_output, torch.Tensor):
current_output = current_output.cpu().numpy()
if current_output.ndim == 1:
current_output = current_output.reshape(-1, 1)
elif current_output.ndim > 2:
current_output = current_output.squeeze()
# Ensure the audio is in the correct shape (samples, channels)
if current_output.shape[1] > current_output.shape[0]:
current_output = current_output.transpose(1,0)
# Loudness normalize output audio
current_output = loudness_normalize(current_output, args.sample_rate)
# Denormalize the audio to int16
current_output = denormalize_audio(current_output, dtype=np.int16)
yield (args.sample_rate, current_output), ito_param_output, step, ito_log, pd.DataFrame(loss_values)
""" APP display """
gr.Markdown("# ITO-Master: Inference Time Optimization for Mastering Style Transfer")
with gr.Blocks() as demo:
gr.Markdown("# Step 1: Mastering Style Transfer")
with gr.Tab("Upload Audio"):
with gr.Row():
input_audio = gr.Audio(label="Input Audio")
reference_audio = gr.Audio(label="Reference Audio")
process_button = gr.Button("Process Mastering Style Transfer")
with gr.Row():
output_audio = gr.Audio(label="Output Audio", type='numpy')
param_output = gr.Textbox(label="Predicted Parameters", lines=5)
process_button.click(
process_audio,
inputs=[input_audio, reference_audio],
outputs=[output_audio, param_output]
)
with gr.Tab("YouTube Audio"):
with gr.Row():
input_audio_yt = gr.Audio(label="Input Audio (Optional)")
input_youtube_url = gr.Textbox(label="Input YouTube URL (Optional)")
with gr.Row():
reference_audio_yt = gr.Audio(label="Reference Audio (Optional)")
reference_youtube_url = gr.Textbox(label="Reference YouTube URL (Optional)")
process_button_yt = gr.Button("Process Mastering Style Transfer")
with gr.Row():
output_audio_yt = gr.Audio(label="Output Audio", type='numpy')
param_output_yt = gr.Textbox(label="Predicted Parameters", lines=5)
error_message_yt = gr.Textbox(label="Error Message", visible=False)
def process_and_handle_errors(input_audio, input_youtube_url, reference_audio, reference_youtube_url):
result = process_audio_with_youtube(input_audio, input_youtube_url, reference_audio, reference_youtube_url)
if len(result) == 3 and isinstance(result[2], str): # Error occurred
return None, None, gr.update(visible=True, value=result[2])
return result[0], result[1], gr.update(visible=False, value="")
process_button_yt.click(
process_and_handle_errors,
inputs=[input_audio_yt, input_youtube_url, reference_audio_yt, reference_youtube_url],
outputs=[output_audio_yt, param_output_yt, error_message_yt]
)
gr.Markdown("## Step 2: Inference Time Optimization (ITO)")
with gr.Row():
ito_reference_audio = gr.Audio(label="ITO Reference Audio (optional)")
with gr.Column():
num_steps = gr.Slider(minimum=1, maximum=100, value=10, step=1, label="Number of Steps")
optimizer = gr.Dropdown(["Adam", "RAdam", "SGD"], value="RAdam", label="Optimizer")
learning_rate = gr.Slider(minimum=0.0001, maximum=0.1, value=0.001, step=0.0001, label="Learning Rate")
af_weights = gr.Textbox(label="AudioFeatureLoss Weights (comma-separated)", value="0.1,0.001,1.0,1.0,0.1")
ito_button = gr.Button("Perform ITO")
with gr.Row():
with gr.Column():
ito_output_audio = gr.Audio(label="ITO Output Audio")
ito_param_output = gr.Textbox(label="ITO Predicted Parameters", lines=15)
with gr.Column():
ito_loss_plot = gr.LinePlot(
x="step",
y="loss",
title="ITO Loss Curve",
x_title="Step",
y_title="Loss",
height=300,
width=600,
)
ito_log = gr.Textbox(label="ITO Log", lines=10)
def run_ito(input_audio, reference_audio, ito_reference_audio, num_steps, optimizer, learning_rate, af_weights):
af_weights = [float(w.strip()) for w in af_weights.split(',')]
ito_generator = perform_ito(
input_audio, reference_audio, ito_reference_audio, num_steps, optimizer, learning_rate, af_weights
)
# Initialize variables to store the final results
final_audio = None
final_params = None
final_steps = 0
final_log = ""
loss_df = None
# Iterate through the generator to get the final results
for audio, params, steps, log, loss_data in ito_generator:
final_audio = audio
final_params = params
final_steps = steps
final_log = log
loss_df = loss_data
# Calculate y_min and y_max
y_min = loss_df['loss'].min()
y_max = loss_df['loss'].max()
# Return the plot configuration along with the data
return final_audio, final_params, final_log, loss_df
ito_button.click(
run_ito,
inputs=[input_audio, reference_audio, ito_reference_audio, num_steps, optimizer, learning_rate, af_weights],
outputs=[ito_output_audio, ito_param_output, ito_log, ito_loss_plot]
)
demo.launch()