app.py

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 to_numpy_audio(audio):
    # Convert output_audio to numpy array if it's a tensor
    if isinstance(audio, torch.Tensor):
        audio = audio.cpu().numpy()
    # check dimension
    if audio.ndim == 1:
        audio = audio.reshape(-1, 1)
    elif audio.ndim > 2:
        audio = audio.squeeze()
    # Ensure the audio is in the correct shape (samples, channels)
    if audio.shape[1] > audio.shape[0]:
        audio = audio.transpose(1,0)
    return audio

def process_audio(input_audio, reference_audio):
    output_audio, predicted_params, sr, normalized_input = mastering_transfer.process_audio(
        input_audio, reference_audio
    )
    
    param_output = mastering_transfer.get_param_output_string(predicted_params)

    # Convert to numpy audio
    output_audio = to_numpy_audio(output_audio)
    normalized_input = to_numpy_audio(normalized_input)
    # 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, (sr, normalized_input)

def perform_ito(input_audio, reference_audio, ito_reference_audio, num_steps, optimizer, learning_rate, af_weights, loss_function, clap_target_type, clap_text_prompt, clap_distance_fn):
    if ito_reference_audio is None:
        ito_reference_audio = reference_audio
    af_weights = [float(w.strip()) for w in af_weights.split(',')]

    ito_config = {
        'optimizer': optimizer,
        'learning_rate': learning_rate,
        'num_steps': num_steps,
        'af_weights': af_weights,
        'sample_rate': args.sample_rate,
        'loss_function': loss_function,
        'clap_target_type': clap_target_type,
        'clap_text_prompt': clap_text_prompt,
        'clap_distance_fn': clap_distance_fn
    }

    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)

    all_results, min_loss_step = mastering_transfer.inference_time_optimization(
        input_tensor, ito_reference_tensor, ito_config, initial_reference_feature
    )

    ito_log = ""
    loss_values = []
    for result in all_results:
        ito_log += result['log']
        loss_values.append({"step": result['step'], "loss": result['loss']})
        
    # Return the results of the last step
    last_result = all_results[-1]
    current_output = last_result['audio']
    ito_param_output = mastering_transfer.get_param_output_string(last_result['params'])

    # Convert to numpy audio
    current_output = to_numpy_audio(current_output)
    # 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)

    return (args.sample_rate, current_output), ito_param_output, num_steps, ito_log, pd.DataFrame(loss_values), all_results

def update_ito_output(all_results, selected_step):
    selected_result = all_results[selected_step - 1]
    current_output = selected_result['audio']
    ito_param_output = mastering_transfer.get_param_output_string(selected_result['params'])

    # Convert to numpy audio
    current_output = to_numpy_audio(current_output)
    # 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)

    return (args.sample_rate, current_output), ito_param_output, selected_result['log']


""" APP display """
with gr.Blocks() as demo:
    gr.Markdown("# ITO-Master: Inference Time Optimization for Mastering Style Transfer")
    with gr.Row():
        gr.Markdown("Interactive demo of Inference Time Optimization (ITO) for Music Mastering Style Transfer. \
                    The mastering style transfer is performed by a differentiable audio processing model, and the predicted parameters are shown as the output. \
                    Perform mastering style transfer with an input source audio and a reference mastering style audio. On top of this result, you can perform ITO to optimize the reference embedding $z_{ref}$ to further gain control over the output mastering style.")
        gr.Image("ito_snow.png", width=100, label="ITO pipeline")

    gr.Markdown("## Step 1: Mastering Style Transfer")

    with gr.Tab("Upload Audio"):
        with gr.Row():
            input_audio = gr.Audio(label="Source Audio $x_{in}$")
            reference_audio = gr.Audio(label="Reference Style Audio $x_{ref}$")
        
        process_button = gr.Button("Process Mastering Style Transfer")
        
        with gr.Row():
            with gr.Column():
                output_audio = gr.Audio(label="Output Audio y'", type='numpy')
                normalized_input = gr.Audio(label="Normalized Source 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, normalized_input]
        )

    with gr.Tab("YouTube Audio"):
        with gr.Row():
            input_youtube_url = gr.Textbox(label="Input YouTube URL")
            reference_youtube_url = gr.Textbox(label="Reference YouTube URL")
        with gr.Row():
            input_audio_yt = gr.Audio(label="Source Audio (Do not put when using YouTube URL)")
            reference_audio_yt = gr.Audio(label="Reference Style Audio (Do not put when using YouTube URL)")
        
        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 Style Audio $x'_{ref}$ (optional)")
        with gr.Column():
            num_steps = gr.Slider(minimum=1, maximum=100, value=10, step=1, label="Number of Steps for additional optimization")
            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")
            loss_function = gr.Radio(["AudioFeatureLoss", "CLAPFeatureLoss"], label="Loss Function", value="AudioFeatureLoss")

            # Audio Feature Loss weights
            with gr.Column(visible=True) as audio_feature_weights:
                af_weights = gr.Textbox(
                    label="AudioFeatureLoss Weights (comma-separated)",
                    value="0.1,0.001,1.0,1.0,0.1",
                    info="RMS, Crest Factor, Stereo Width, Stereo Imbalance, Bark Spectrum"
                )

            # CLAP Loss options
            with gr.Column(visible=False) as clap_options:
                clap_target_type = gr.Radio(["Audio", "Text"], label="CLAP Target Type", value="Audio")
                clap_text_prompt = gr.Textbox(label="CLAP Text Prompt", visible=False)
                clap_distance_fn = gr.Dropdown([ "cosine", "mse", "l1"], label="CLAP Distance Function", value="cosine")

    def update_clap_options(loss_function):
        if loss_function == "CLAPFeatureLoss":
            return gr.update(visible=False), gr.update(visible=True)
        else:
            return gr.update(visible=True), gr.update(visible=False)

    loss_function.change(
        update_clap_options,
        inputs=[loss_function],
        outputs=[audio_feature_weights, clap_options]
    )

    def update_clap_text_prompt(clap_target_type):
        return gr.update(visible=clap_target_type == "Text")

    clap_target_type.change(
        update_clap_text_prompt,
        inputs=[clap_target_type],
        outputs=[clap_text_prompt]
    )

    ito_button = gr.Button("Perform ITO")

    with gr.Row():
        with gr.Column():
            ito_output_audio = gr.Audio(label="ITO Output Audio")
            ito_step_slider = gr.Slider(minimum=1, maximum=100, step=1, label="ITO Step", interactive=True)
            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)

    all_results = gr.State([])

    ito_button.click(
        perform_ito,
        inputs=[normalized_input, reference_audio, ito_reference_audio, num_steps, optimizer, learning_rate, af_weights, loss_function, clap_target_type, clap_text_prompt, clap_distance_fn],
        outputs=[ito_output_audio, ito_param_output, ito_step_slider, ito_log, ito_loss_plot, all_results]
    ).then(
        update_ito_output,
        inputs=[all_results, ito_step_slider],
        outputs=[ito_output_audio, ito_param_output, ito_log]
    )

    ito_step_slider.change(
        update_ito_output,
        inputs=[all_results, ito_step_slider],
        outputs=[ito_output_audio, ito_param_output, ito_log]
    )

demo.launch()