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Running
on
T4
""" | |
Taken from ESPNet, modified by Florian Lux | |
""" | |
import json | |
import os | |
import matplotlib.pyplot as plt | |
import numpy as np | |
import torch | |
import torch.multiprocessing | |
from matplotlib.lines import Line2D | |
import Modules.GeneralLayers.ConditionalLayerNorm | |
from Preprocessing.TextFrontend import ArticulatoryCombinedTextFrontend | |
from Preprocessing.TextFrontend import get_language_id | |
def integrate_with_utt_embed(hs, utt_embeddings, projection, embedding_training): | |
if not embedding_training: | |
# concat hidden states with spk embeds and then apply projection | |
embeddings_expanded = torch.nn.functional.normalize(utt_embeddings).unsqueeze(1).expand(-1, hs.size(1), -1) | |
hs = projection(torch.cat([hs, embeddings_expanded], dim=-1)) | |
else: | |
# in this case we don't want to normalize the embeddings to not impair the gradient flow | |
hs = projection(hs, utt_embeddings) | |
return hs | |
def float2pcm(sig, dtype='int16'): | |
""" | |
https://gist.github.com/HudsonHuang/fbdf8e9af7993fe2a91620d3fb86a182 | |
""" | |
sig = np.asarray(sig) | |
if sig.dtype.kind != 'f': | |
raise TypeError("'sig' must be a float array") | |
dtype = np.dtype(dtype) | |
if dtype.kind not in 'iu': | |
raise TypeError("'dtype' must be an integer type") | |
i = np.iinfo(dtype) | |
abs_max = 2 ** (i.bits - 1) | |
offset = i.min + abs_max | |
return (sig * abs_max + offset).clip(i.min, i.max).astype(dtype) | |
def make_estimated_durations_usable_for_inference(xs, offset=1.0): | |
return torch.clamp(torch.round(xs.exp() - offset), min=0).long() | |
def cut_to_multiple_of_n(x, n=4, return_diff=False, seq_dim=1): | |
max_frames = x.shape[seq_dim] // n * n | |
if return_diff: | |
return x[:, :max_frames], x.shape[seq_dim] - max_frames | |
return x[:, :max_frames] | |
def pad_to_multiple_of_n(x, n=4, seq_dim=1, pad_value=0): | |
max_frames = ((x.shape[seq_dim] // n) + 1) * n | |
diff = max_frames - x.shape[seq_dim] | |
return torch.nn.functional.pad(x, [0, 0, 0, diff, 0, 0], mode="constant", value=pad_value) | |
def plot_progress_spec_toucantts(net, | |
device, | |
save_dir, | |
step, | |
lang, | |
default_emb, | |
run_stochastic): | |
tf = ArticulatoryCombinedTextFrontend(language=lang) | |
sentence = tf.get_example_sentence(lang=lang) | |
if sentence is None: | |
return None | |
phoneme_vector = tf.string_to_tensor(sentence).squeeze(0).to(device) | |
mel, durations, pitch, energy = net.inference(text=phoneme_vector, | |
return_duration_pitch_energy=True, | |
utterance_embedding=default_emb, | |
lang_id=get_language_id(lang).to(device), | |
run_stochastic=run_stochastic) | |
plot_code_spec(pitch, energy, sentence, durations, mel, os.path.join(save_dir, "visualization"), tf, step) | |
return os.path.join(os.path.join(save_dir, "visualization"), f"{step}.png") | |
def plot_code_spec(pitch, energy, sentence, durations, mel, save_path, tf, step): | |
fig, ax = plt.subplots(nrows=2, ncols=1, figsize=(9, 8)) | |
expanded_pitch = list() | |
expanded_energy = list() | |
for p, e, d in zip(pitch.cpu().squeeze().numpy(), energy.cpu().squeeze().numpy(), durations.cpu().numpy()): | |
for _ in range(d): | |
expanded_energy.append(e) | |
expanded_pitch.append(p) | |
pitch = expanded_pitch | |
energy = expanded_energy | |
spec_plot_axis = ax[1] | |
pitch_and_energy_axis = ax[0] | |
spec_plot_axis.imshow(mel.cpu().numpy(), origin="lower", cmap='GnBu') | |
pitch_and_energy_axis.yaxis.set_visible(False) | |
pitch_and_energy_axis.xaxis.set_visible(False) | |
spec_plot_axis.yaxis.set_visible(False) | |
duration_splits, label_positions = cumsum_durations(durations.cpu().numpy()) | |
spec_plot_axis.xaxis.grid(True, which='minor') | |
spec_plot_axis.set_xticks(label_positions, minor=False) | |
phones = tf.get_phone_string(sentence, for_plot_labels=True) | |
spec_plot_axis.set_xticklabels(phones) | |
word_boundaries = list() | |
for label_index, phone in enumerate(phones): | |
if phone == "|": | |
word_boundaries.append(label_positions[label_index]) | |
try: | |
prev_word_boundary = 0 | |
word_label_positions = list() | |
for word_boundary in word_boundaries: | |
word_label_positions.append((word_boundary + prev_word_boundary) / 2) | |
prev_word_boundary = word_boundary | |
word_label_positions.append((duration_splits[-1] + prev_word_boundary) / 2) | |
secondary_ax = spec_plot_axis.secondary_xaxis('bottom') | |
secondary_ax.tick_params(axis="x", direction="out", pad=24) | |
secondary_ax.set_xticks(word_label_positions, minor=False) | |
secondary_ax.set_xticklabels(sentence.split()) | |
secondary_ax.tick_params(axis='x', colors='orange') | |
secondary_ax.xaxis.label.set_color('orange') | |
except ValueError: | |
spec_plot_axis.set_title(sentence) | |
except IndexError: | |
spec_plot_axis.set_title(sentence) | |
spec_plot_axis.vlines(x=duration_splits, colors="green", linestyles="solid", ymin=0, ymax=15, linewidth=1.0) | |
spec_plot_axis.vlines(x=word_boundaries, colors="orange", linestyles="solid", ymin=0, ymax=15, linewidth=2.0) | |
pitch_and_energy_axis.plot(pitch, color="blue") | |
pitch_and_energy_axis.plot(energy, color="green") | |
spec_plot_axis.set_aspect("auto") | |
pitch_and_energy_axis.set_aspect("auto") | |
plt.subplots_adjust(left=0.05, bottom=0.1, right=0.95, top=.95, wspace=0.0, hspace=0.0) | |
os.makedirs(save_path, exist_ok=True) | |
plt.savefig(os.path.join(save_path, f"{step}.png"), dpi=100) | |
plt.clf() | |
plt.close() | |
def plot_spec_tensor(spec, save_path, name, title=None): | |
fig, spec_plot_axis = plt.subplots(nrows=1, ncols=1, figsize=(9, 4)) | |
spec_plot_axis.imshow(spec.detach().cpu().numpy(), origin="lower", cmap='GnBu') | |
spec_plot_axis.yaxis.set_visible(False) | |
spec_plot_axis.set_aspect("auto") | |
if title is not None: | |
spec_plot_axis.set_title(title) | |
plt.subplots_adjust(left=0.05, bottom=0.1, right=0.95, top=.95 if title is None else .85, wspace=0.0, hspace=0.0) | |
os.makedirs(save_path, exist_ok=True) | |
plt.savefig(os.path.join(save_path, f"{name}.png"), dpi=100) | |
plt.clf() | |
plt.close() | |
def cumsum_durations(durations): | |
out = [0] | |
for duration in durations: | |
out.append(duration + out[-1]) | |
centers = list() | |
for index, _ in enumerate(out): | |
if index + 1 < len(out): | |
centers.append((out[index] + out[index + 1]) // 2) | |
return out, centers | |
def delete_old_checkpoints(checkpoint_dir, keep=5): | |
checkpoint_list = list() | |
for el in os.listdir(checkpoint_dir): | |
if el.endswith(".pt"): | |
try: | |
checkpoint_list.append(int(el.replace("checkpoint_", "").replace(".pt", ""))) | |
except ValueError: | |
pass | |
if len(checkpoint_list) <= keep: | |
return | |
else: | |
checkpoint_list.sort(reverse=False) | |
checkpoints_to_delete = [os.path.join(checkpoint_dir, "checkpoint_{}.pt".format(step)) for step in | |
checkpoint_list[:-keep]] | |
for old_checkpoint in checkpoints_to_delete: | |
os.remove(os.path.join(old_checkpoint)) | |
def plot_grad_flow(named_parameters): | |
""" | |
Plots the gradients flowing through different layers in the net during training. | |
Can be used for checking for possible gradient vanishing / exploding problems. | |
Usage: Plug this function after loss.backwards() and unscaling as | |
"plot_grad_flow(self.model.named_parameters())" to visualize the gradient flow | |
""" | |
ave_grads = [] | |
max_grads = [] | |
layers = [] | |
for n, p in named_parameters: | |
if p.requires_grad and ("bias" not in n): | |
layers.append(n) | |
ave_grads.append(p.grad.abs().mean()) | |
max_grads.append(p.grad.abs().max()) | |
plt.bar(np.arange(len(max_grads)), max_grads, alpha=0.1, lw=1, color="c") | |
plt.bar(np.arange(len(max_grads)), ave_grads, alpha=0.1, lw=1, color="b") | |
plt.hlines(0, 0, len(ave_grads) + 1, lw=2, color="k") | |
plt.xticks(range(0, len(ave_grads), 1), layers, rotation="vertical") | |
plt.xlim(left=0, right=len(ave_grads)) | |
plt.ylim(bottom=-0.001, top=0.02) # zoom in on the lower gradient regions | |
plt.xlabel("Layers") | |
plt.ylabel("Gradient") | |
plt.title("Gradient Flow") | |
plt.grid(True) | |
plt.legend([Line2D([0], [0], color="c", lw=4), | |
Line2D([0], [0], color="b", lw=4), | |
Line2D([0], [0], color="k", lw=4)], ['max-gradient', 'mean-gradient', 'zero-gradient']) | |
plt.show() | |
def get_most_recent_checkpoint(checkpoint_dir, verbose=True): | |
checkpoint_list = list() | |
for el in os.listdir(checkpoint_dir): | |
if el.endswith(".pt") and el != "best.pt" and el != "embedding_function.pt": | |
try: | |
checkpoint_list.append(int(el.split(".")[0].split("_")[1])) | |
except ValueError: | |
pass | |
if len(checkpoint_list) == 0: | |
print("No previous checkpoints found, cannot reload.") | |
return None | |
checkpoint_list.sort(reverse=True) | |
if verbose: | |
print("Reloading checkpoint_{}.pt".format(checkpoint_list[0])) | |
return os.path.join(checkpoint_dir, "checkpoint_{}.pt".format(checkpoint_list[0])) | |
def make_pad_mask(lengths, xs=None, length_dim=-1, device=None): | |
""" | |
Make mask tensor containing indices of padded part. | |
Args: | |
lengths (LongTensor or List): Batch of lengths (B,). | |
xs (Tensor, optional): The reference tensor. | |
If set, masks will be the same shape as this tensor. | |
length_dim (int, optional): Dimension indicator of the above tensor. | |
See the example. | |
Returns: | |
Tensor: Mask tensor containing indices of padded part. | |
dtype=torch.uint8 in PyTorch 1.2- | |
dtype=torch.bool in PyTorch 1.2+ (including 1.2) | |
""" | |
if length_dim == 0: | |
raise ValueError("length_dim cannot be 0: {}".format(length_dim)) | |
if not isinstance(lengths, list): | |
lengths = lengths.tolist() | |
bs = int(len(lengths)) | |
if xs is None: | |
maxlen = int(max(lengths)) | |
else: | |
maxlen = xs.size(length_dim) | |
if device is not None: | |
seq_range = torch.arange(0, maxlen, dtype=torch.int64, device=device) | |
else: | |
seq_range = torch.arange(0, maxlen, dtype=torch.int64) | |
seq_range_expand = seq_range.unsqueeze(0).expand(bs, maxlen) | |
seq_length_expand = seq_range_expand.new(lengths).unsqueeze(-1) | |
mask = seq_range_expand >= seq_length_expand | |
if xs is not None: | |
assert xs.size(0) == bs, (xs.size(0), bs) | |
if length_dim < 0: | |
length_dim = xs.dim() + length_dim | |
# ind = (:, None, ..., None, :, , None, ..., None) | |
ind = tuple(slice(None) if i in (0, length_dim) else None for i in range(xs.dim())) | |
mask = mask[ind].expand_as(xs).to(xs.device) | |
return mask | |
def make_non_pad_mask(lengths, xs=None, length_dim=-1, device=None): | |
""" | |
Make mask tensor containing indices of non-padded part. | |
Args: | |
lengths (LongTensor or List): Batch of lengths (B,). | |
xs (Tensor, optional): The reference tensor. | |
If set, masks will be the same shape as this tensor. | |
length_dim (int, optional): Dimension indicator of the above tensor. | |
See the example. | |
Returns: | |
ByteTensor: mask tensor containing indices of padded part. | |
dtype=torch.uint8 in PyTorch 1.2- | |
dtype=torch.bool in PyTorch 1.2+ (including 1.2) | |
""" | |
return ~make_pad_mask(lengths, xs, length_dim, device=device) | |
def initialize(model, init): | |
""" | |
Initialize weights of a neural network module. | |
Parameters are initialized using the given method or distribution. | |
Args: | |
model: Target. | |
init: Method of initialization. | |
""" | |
# weight init | |
for p in model.parameters(): | |
if p.dim() > 1: | |
if init == "xavier_uniform": | |
torch.nn.init.xavier_uniform_(p.data) | |
elif init == "xavier_normal": | |
torch.nn.init.xavier_normal_(p.data) | |
elif init == "kaiming_uniform": | |
torch.nn.init.kaiming_uniform_(p.data, nonlinearity="relu") | |
elif init == "kaiming_normal": | |
torch.nn.init.kaiming_normal_(p.data, nonlinearity="relu") | |
else: | |
raise ValueError("Unknown initialization: " + init) | |
# bias init | |
for p in model.parameters(): | |
if p.dim() == 1: | |
p.data.zero_() | |
# reset some modules with default init | |
for m in model.modules(): | |
if isinstance(m, (torch.nn.Embedding, | |
torch.nn.LayerNorm, | |
Modules.GeneralLayers.ConditionalLayerNorm.ConditionalLayerNorm, | |
Modules.GeneralLayers.ConditionalLayerNorm.SequentialWrappableConditionalLayerNorm | |
)): | |
m.reset_parameters() | |
def pad_list(xs, pad_value): | |
""" | |
Perform padding for the list of tensors. | |
Args: | |
xs (List): List of Tensors [(T_1, `*`), (T_2, `*`), ..., (T_B, `*`)]. | |
pad_value (float): Value for padding. | |
Returns: | |
Tensor: Padded tensor (B, Tmax, `*`). | |
""" | |
n_batch = len(xs) | |
max_len = max(x.size(0) for x in xs) | |
pad = xs[0].new(n_batch, max_len, *xs[0].size()[1:]).fill_(pad_value) | |
for i in range(n_batch): | |
pad[i, : xs[i].size(0)] = xs[i] | |
return pad | |
def curve_smoother(curve): | |
if len(curve) < 3: | |
return curve | |
new_curve = list() | |
for index in range(len(curve)): | |
if curve[index] != 0: | |
current_value = curve[index] | |
if index != len(curve) - 1: | |
if curve[index + 1] != 0: | |
next_value = curve[index + 1] | |
else: | |
next_value = curve[index] | |
if index != 0: | |
if curve[index - 1] != 0: | |
prev_value = curve[index - 1] | |
else: | |
prev_value = curve[index] | |
else: | |
prev_value = curve[index] | |
smooth_value = (current_value * 3 + prev_value + next_value) / 5 | |
new_curve.append(smooth_value) | |
else: | |
new_curve.append(0) | |
return new_curve | |
def remove_elements(tensor, indexes): | |
# Create a boolean mask where True represents the elements to keep | |
print("\n\n\n") | |
print(tensor.shape) | |
print(indexes) | |
mask = torch.ones(tensor.size(0), dtype=torch.bool) | |
mask[indexes] = False | |
# Use the mask to select the elements to keep | |
result = tensor[mask, :] | |
print(result.shape) | |
return result | |
def load_json_from_path(path): | |
with open(path, "r", encoding="utf8") as f: | |
obj = json.loads(f.read()) | |
return obj | |
if __name__ == '__main__': | |
data = np.random.randn(50) | |
plt.plot(data, color="b") | |
smooth = curve_smoother(data) | |
plt.plot(smooth, color="g") | |
plt.show() | |