new_sound_generation.py

import numpy as np
import matplotlib
from pathlib import Path
import shutil
from tqdm import tqdm
from tools import save_results, VAE_out_put_to_spc, show_spc


def test_reconstruction(encoder, decoder, data, n_sample=5, f=0, path_name="./data/test_reconstruction", save_data=False):
    """Generate and show reconstruction results. Randomly reconstruct 'n_sample' samples in 'data'.
    You can manually set the index of the first reconstructed sample by 'f'.

    Parameters
    ----------
    encoder: keras.engine.functional.Functional
        The VAE encoder.
    decoder: keras.engine.functional.Functional
        Sample rate of the audio to generate.
    data: numpy array
        The VAE decoder.
    n_sample: int
        Number of samples to reconstruct.
    f: int
        Index of the first reconstructed sample.
    path_name: String
        Path to save the results.
    save_data: bool
        Whether save the results.

    Returns
    -------
    """
    if save_data:
        if Path(path_name).exists():
            shutil.rmtree(path_name)
        Path(path_name).mkdir(parents=True, exist_ok=True)
        
    for i in range(n_sample):
        index = np.random.randint(np.shape(data)[0])
        if i == 0:
            index = f
        print("######################################################")
        print(f"index: {index}")

        input = data[index]
        print(f"Original:")
        show_spc(VAE_out_put_to_spc(input))
        if save_data:
            save_results(VAE_out_put_to_spc(input), f"{path_name}/origin_{index}.png", f"{path_name}/origin_{index}.wav")

        input = data[index:index + 1]
        timbre_encode = encoder.predict(input)[0]

        encode = timbre_encode

        reconstruction = decoder.predict(encode)[0]
        reconstruction = VAE_out_put_to_spc(reconstruction)
        reconstruction = np.minimum(5000, reconstruction)
        print(f"Reconstruction:")
        show_spc(reconstruction)
        if save_data:
            save_results(reconstruction, f"{path_name}/reconstruction_{index}.png", f"{path_name}/reconstruction_{index}.wav")
            
            
def test_interpulation(data0, data1, encoder, decoder, path_name = "./data/test_interpolation", save_data=False):
    """Generate new sounds by latent space interpolation.

    Parameters
    ----------
    data0: numpy array
        First input for interpolation.
    data1: numpy array
        Second input for interpolation.
    encoder: keras.engine.functional.Functional
        The VAE encoder.
    decoder: keras.engine.functional.Functional
        Sample rate of the audio to generate.
    path_name: String
        Path to save the results.
    save_data: bool
        Whether save the results.

    Returns
    -------
    """
    if save_data:
        if Path(path_name).exists():
            shutil.rmtree(path_name)
        Path(path_name).mkdir(parents=True, exist_ok=True)

    if save_data:
        save_results(VAE_out_put_to_spc(data0), f"{path_name}/origin_0.png", f"{path_name}/origin_0.wav")
        save_results(VAE_out_put_to_spc(data1), f"{path_name}/origin_1.png", f"{path_name}/origin_1.wav")

    print("First Original:")
    show_spc(VAE_out_put_to_spc(data0))
    print("Second Original:")
    show_spc(VAE_out_put_to_spc(data1))
    print("######################################################")
    print("Interpolations:")
    data0 = np.reshape(data0, (1, 512, 256, 1))
    data1 = np.reshape(data1, (1, 512, 256, 1))
    timbre_encode0 = encoder.predict(data0)[0]
    timbre_encode1 = encoder.predict(data1)[0]

    n_f = 8
    for i in tqdm(range(n_f+1)):
        rate = 1 - i/n_f
        new_timbre = rate * timbre_encode0 + (1-rate) * timbre_encode1
        output = decoder.predict(new_timbre)
    
        spc = np.reshape(VAE_out_put_to_spc(output), (512,256))
        if save_data:
            save_results(spc, f"{path_name}/test_interpolation_{i}.png", f"{path_name}/test_interpolation_{i}.wav")
        show_spc(spc)
            
            
def test_random_sampling(decoder, n_sample=20, mu=np.zeros(20), sigma=np.ones(20), save_data = False, path_name = "./data/test_random_sampling"):
    """Generate new sounds by random sampling in the latent space.

    Parameters
    ----------
    decoder: keras.engine.functional.Functional
        Sample rate of the audio to generate.
    path_name: String
        Path to save the results.
    save_data: bool
        Whether save the results.

    Returns
    -------
    """
    if save_data:
        if Path(path_name).exists():
            shutil.rmtree(path_name)
        Path(path_name).mkdir(parents=True, exist_ok=True)

    for i in tqdm(range(n_sample)):
        off_set = np.random.normal(mu,np.square(sigma))
        new_timbre = np.reshape(off_set, (1,20))
    
        output = decoder.predict(new_timbre)
        
        spc = np.reshape(VAE_out_put_to_spc(output), (512,256))
        if save_data:
            save_results(spc, f"{path_name}/random_sampling_{i}.png", f"{path_name}/random_sampling_{i}.wav")
        show_spc(spc)
            

def test_style_transform(original, encoder, decoder, perceptual_label_predictor, n_samples=10, save_data = False, goal=0, direction=0, path_name = "./data/test_style_transform"):
    """Generate new sounds by latent space interpolation.

    Parameters
    ----------
    original: numpy array
        Original for style transform.
    encoder: keras.engine.functional.Functional
        The VAE encoder.
    decoder: keras.engine.functional.Functional
        Sample rate of the audio to generate.
    perceptual_label_predictor: keras.engine.functional.Functional
        Model that selects the output.
    path_name: String
        Path to save the results.
    save_data: bool
        Whether save the results.

    Returns
    -------
    """
    if save_data:
        if Path(path_name).exists():
            shutil.rmtree(path_name)
        Path(path_name).mkdir(parents=True, exist_ok=True)
        save_results(VAE_out_put_to_spc(original), f"{path_name}/origin.png", f"{path_name}/origin.wav")
    labels_names = ["metallic", "warm", "breathy", "evolving", "aggressiv"]
    timbre_dim = 20

    print("Original:")
    show_spc(VAE_out_put_to_spc(original))
    print("######################################################")
    original_code = encoder.predict(np.reshape(original, (1,512,256,1)))[0]
    new_encodes = np.zeros((n_samples, timbre_dim)) + original_code
    
    new_encodes = [new_encode + np.random.normal(np.zeros(timbre_dim) * 0.2,np.ones(timbre_dim)) for new_encode in new_encodes]
    new_encodes = np.array(new_encodes, dtype=np.float32)
    perceptual_labels = perceptual_label_predictor.predict(new_encodes)[:,goal]

    if direction == 0:
        best_index = np.argmin(perceptual_labels)
        suffix = f"less_{labels_names[goal]}"
    else:
        best_index = np.argmax(perceptual_labels)
        suffix = f"more_{labels_names[goal]}"

    output = decoder.predict(new_encodes[best_index:best_index+1])
        
    spc = np.reshape(VAE_out_put_to_spc(output), (512,256))
    if save_data:
        save_results(spc, f"{path_name}/{suffix}.png", f"{path_name}/{suffix}.wav")
    print("Manipulated (suffix):")
    show_spc(spc)