Applio15 / tabs /inference /inference.py
Aitron Emper
Upload 74 files
1a7d583 verified
import os, sys
import gradio as gr
import regex as re
import shutil
import datetime
import random
from core import (
run_infer_script,
run_batch_infer_script,
)
from assets.i18n.i18n import I18nAuto
from rvc.lib.utils import format_title
i18n = I18nAuto()
now_dir = os.getcwd()
sys.path.append(now_dir)
model_root = os.path.join(now_dir, "logs")
audio_root = os.path.join(now_dir, "assets", "audios")
model_root_relative = os.path.relpath(model_root, now_dir)
audio_root_relative = os.path.relpath(audio_root, now_dir)
sup_audioext = {
"wav",
"mp3",
"flac",
"ogg",
"opus",
"m4a",
"mp4",
"aac",
"alac",
"wma",
"aiff",
"webm",
"ac3",
}
names = [
os.path.join(root, file)
for root, _, files in os.walk(model_root_relative, topdown=False)
for file in files
if (
file.endswith((".pth", ".onnx"))
and not (file.startswith("G_") or file.startswith("D_"))
)
]
indexes_list = [
os.path.join(root, name)
for root, _, files in os.walk(model_root_relative, topdown=False)
for name in files
if name.endswith(".index") and "trained" not in name
]
audio_paths = [
os.path.join(root, name)
for root, _, files in os.walk(audio_root_relative, topdown=False)
for name in files
if name.endswith(tuple(sup_audioext))
and root == audio_root_relative
and "_output" not in name
]
def output_path_fn(input_audio_path):
original_name_without_extension = os.path.basename(input_audio_path).rsplit(".", 1)[
0
]
new_name = original_name_without_extension + "_output.wav"
output_path = os.path.join(os.path.dirname(input_audio_path), new_name)
return output_path
def change_choices():
names = [
os.path.join(root, file)
for root, _, files in os.walk(model_root_relative, topdown=False)
for file in files
if (
file.endswith((".pth", ".onnx"))
and not (file.startswith("G_") or file.startswith("D_"))
)
]
indexes_list = [
os.path.join(root, name)
for root, _, files in os.walk(model_root_relative, topdown=False)
for name in files
if name.endswith(".index") and "trained" not in name
]
audio_paths = [
os.path.join(root, name)
for root, _, files in os.walk(audio_root_relative, topdown=False)
for name in files
if name.endswith(tuple(sup_audioext))
and root == audio_root_relative
and "_output" not in name
]
return (
{"choices": sorted(names), "__type__": "update"},
{"choices": sorted(indexes_list), "__type__": "update"},
{"choices": sorted(audio_paths), "__type__": "update"},
)
def get_indexes():
indexes_list = [
os.path.join(dirpath, filename)
for dirpath, _, filenames in os.walk(model_root_relative)
for filename in filenames
if filename.endswith(".index") and "trained" not in filename
]
return indexes_list if indexes_list else ""
def save_to_wav(record_button):
if record_button is None:
pass
else:
path_to_file = record_button
new_name = datetime.datetime.now().strftime("%Y-%m-%d_%H-%M-%S") + ".wav"
target_path = os.path.join(audio_root_relative, os.path.basename(new_name))
shutil.move(path_to_file, target_path)
return target_path, output_path_fn(target_path)
def save_to_wav2(upload_audio):
file_path = upload_audio
formated_name = format_title(os.path.basename(file_path))
target_path = os.path.join(audio_root_relative, formated_name)
if os.path.exists(target_path):
os.remove(target_path)
shutil.copy(file_path, target_path)
return target_path, output_path_fn(target_path)
def delete_outputs():
gr.Info(f"Outputs cleared!")
for root, _, files in os.walk(audio_root_relative, topdown=False):
for name in files:
if name.endswith(tuple(sup_audioext)) and name.__contains__("_output"):
os.remove(os.path.join(root, name))
def match_index(model_file_value):
if model_file_value:
model_folder = os.path.dirname(model_file_value)
index_files = get_indexes()
for index_file in index_files:
if os.path.dirname(index_file) == model_folder:
return index_file
return ""
# Inference tab
def inference_tab():
default_weight = random.choice(names) if names else None
with gr.Row():
with gr.Row():
model_file = gr.Dropdown(
label=i18n("Voice Model"),
info=i18n("Select the voice model to use for the conversion."),
choices=sorted(names, key=lambda path: os.path.getsize(path)),
interactive=True,
value=default_weight,
allow_custom_value=True,
)
index_file = gr.Dropdown(
label=i18n("Index File"),
info=i18n("Select the index file to use for the conversion."),
choices=get_indexes(),
value=match_index(default_weight) if default_weight else "",
interactive=True,
allow_custom_value=True,
)
with gr.Column():
refresh_button = gr.Button(i18n("Refresh"))
unload_button = gr.Button(i18n("Unload Voice"))
unload_button.click(
fn=lambda: (
{"value": "", "__type__": "update"},
{"value": "", "__type__": "update"},
),
inputs=[],
outputs=[model_file, index_file],
)
model_file.select(
fn=lambda model_file_value: match_index(model_file_value),
inputs=[model_file],
outputs=[index_file],
)
# Single inference tab
with gr.Tab(i18n("Single")):
with gr.Column():
upload_audio = gr.Audio(
label=i18n("Upload Audio"), type="filepath", editable=False
)
with gr.Row():
audio = gr.Dropdown(
label=i18n("Select Audio"),
info=i18n("Select the audio to convert."),
choices=sorted(audio_paths),
value=audio_paths[0] if audio_paths else "",
interactive=True,
allow_custom_value=True,
)
with gr.Accordion(i18n("Advanced Settings"), open=False):
with gr.Column():
clear_outputs_infer = gr.Button(
i18n("Clear Outputs (Deletes all audios in assets/audios)")
)
output_path = gr.Textbox(
label=i18n("Output Path"),
placeholder=i18n("Enter output path"),
info=i18n(
"The path where the output audio will be saved, by default in assets/audios/output.wav"
),
value=(
output_path_fn(audio_paths[0])
if audio_paths
else os.path.join(now_dir, "assets", "audios", "output.wav")
),
interactive=True,
)
export_format = gr.Radio(
label=i18n("Export Format"),
info=i18n("Select the format to export the audio."),
choices=["WAV", "MP3", "FLAC", "OGG", "M4A"],
value="WAV",
interactive=True,
)
split_audio = gr.Checkbox(
label=i18n("Split Audio"),
info=i18n(
"Split the audio into chunks for inference to obtain better results in some cases."
),
visible=True,
value=False,
interactive=True,
)
autotune = gr.Checkbox(
label=i18n("Autotune"),
info=i18n(
"Apply a soft autotune to your inferences, recommended for singing conversions."
),
visible=True,
value=False,
interactive=True,
)
clean_audio = gr.Checkbox(
label=i18n("Clean Audio"),
info=i18n(
"Clean your audio output using noise detection algorithms, recommended for speaking audios."
),
visible=True,
value=False,
interactive=True,
)
clean_strength = gr.Slider(
minimum=0,
maximum=1,
label=i18n("Clean Strength"),
info=i18n(
"Set the clean-up level to the audio you want, the more you increase it the more it will clean up, but it is possible that the audio will be more compressed."
),
visible=False,
value=0.5,
interactive=True,
)
pitch = gr.Slider(
minimum=-24,
maximum=24,
step=1,
label=i18n("Pitch"),
info=i18n(
"Set the pitch of the audio, the higher the value, the higher the pitch."
),
value=0,
interactive=True,
)
filter_radius = gr.Slider(
minimum=0,
maximum=7,
label=i18n("Filter Radius"),
info=i18n(
"If the number is greater than or equal to three, employing median filtering on the collected tone results has the potential to decrease respiration."
),
value=3,
step=1,
interactive=True,
)
index_rate = gr.Slider(
minimum=0,
maximum=1,
label=i18n("Search Feature Ratio"),
info=i18n(
"Influence exerted by the index file; a higher value corresponds to greater influence. However, opting for lower values can help mitigate artifacts present in the audio."
),
value=0.75,
interactive=True,
)
rms_mix_rate = gr.Slider(
minimum=0,
maximum=1,
label=i18n("Volume Envelope"),
info=i18n(
"Substitute or blend with the volume envelope of the output. The closer the ratio is to 1, the more the output envelope is employed."
),
value=1,
interactive=True,
)
protect = gr.Slider(
minimum=0,
maximum=0.5,
label=i18n("Protect Voiceless Consonants"),
info=i18n(
"Safeguard distinct consonants and breathing sounds to prevent electro-acoustic tearing and other artifacts. Pulling the parameter to its maximum value of 0.5 offers comprehensive protection. However, reducing this value might decrease the extent of protection while potentially mitigating the indexing effect."
),
value=0.5,
interactive=True,
)
hop_length = gr.Slider(
minimum=1,
maximum=512,
step=1,
label=i18n("Hop Length"),
info=i18n(
"Denotes the duration it takes for the system to transition to a significant pitch change. Smaller hop lengths require more time for inference but tend to yield higher pitch accuracy."
),
visible=False,
value=128,
interactive=True,
)
with gr.Column():
f0method = gr.Radio(
label=i18n("Pitch extraction algorithm"),
info=i18n(
"Pitch extraction algorithm to use for the audio conversion. The default algorithm is rmvpe, which is recommended for most cases."
),
choices=[
"pm",
"harvest",
"dio",
"crepe",
"crepe-tiny",
"rmvpe",
"fcpe",
"hybrid[rmvpe+fcpe]",
],
value="rmvpe",
interactive=True,
)
convert_button1 = gr.Button(i18n("Convert"))
with gr.Row(): # Defines output info + output audio download after conversion
vc_output1 = gr.Textbox(
label=i18n("Output Information"),
info=i18n("The output information will be displayed here."),
)
vc_output2 = gr.Audio(label=i18n("Export Audio"))
# Batch inference tab
with gr.Tab(i18n("Batch")):
with gr.Row():
with gr.Column():
input_folder_batch = gr.Textbox(
label=i18n("Input Folder"),
info=i18n("Select the folder containing the audios to convert."),
placeholder=i18n("Enter input path"),
value=os.path.join(now_dir, "assets", "audios"),
interactive=True,
)
output_folder_batch = gr.Textbox(
label=i18n("Output Folder"),
info=i18n(
"Select the folder where the output audios will be saved."
),
placeholder=i18n("Enter output path"),
value=os.path.join(now_dir, "assets", "audios"),
interactive=True,
)
with gr.Accordion(i18n("Advanced Settings"), open=False):
with gr.Column():
clear_outputs_batch = gr.Button(
i18n("Clear Outputs (Deletes all audios in assets/audios)")
)
export_format_batch = gr.Radio(
label=i18n("Export Format"),
info=i18n("Select the format to export the audio."),
choices=["WAV", "MP3", "FLAC", "OGG", "M4A"],
value="WAV",
interactive=True,
)
split_audio_batch = gr.Checkbox(
label=i18n("Split Audio"),
info=i18n(
"Split the audio into chunks for inference to obtain better results in some cases."
),
visible=True,
value=False,
interactive=True,
)
autotune_batch = gr.Checkbox(
label=i18n("Autotune"),
info=i18n(
"Apply a soft autotune to your inferences, recommended for singing conversions."
),
visible=True,
value=False,
interactive=True,
)
clean_audio_batch = gr.Checkbox(
label=i18n("Clean Audio"),
info=i18n(
"Clean your audio output using noise detection algorithms, recommended for speaking audios."
),
visible=True,
value=False,
interactive=True,
)
clean_strength_batch = gr.Slider(
minimum=0,
maximum=1,
label=i18n("Clean Strength"),
info=i18n(
"Set the clean-up level to the audio you want, the more you increase it the more it will clean up, but it is possible that the audio will be more compressed."
),
visible=False,
value=0.5,
interactive=True,
)
pitch_batch = gr.Slider(
minimum=-24,
maximum=24,
step=1,
label=i18n("Pitch"),
info=i18n(
"Set the pitch of the audio, the higher the value, the higher the pitch."
),
value=0,
interactive=True,
)
filter_radius_batch = gr.Slider(
minimum=0,
maximum=7,
label=i18n("Filter Radius"),
info=i18n(
"If the number is greater than or equal to three, employing median filtering on the collected tone results has the potential to decrease respiration."
),
value=3,
step=1,
interactive=True,
)
index_rate_batch = gr.Slider(
minimum=0,
maximum=1,
label=i18n("Search Feature Ratio"),
info=i18n(
"Influence exerted by the index file; a higher value corresponds to greater influence. However, opting for lower values can help mitigate artifacts present in the audio."
),
value=0.75,
interactive=True,
)
rms_mix_rate_batch = gr.Slider(
minimum=0,
maximum=1,
label=i18n("Volume Envelope"),
info=i18n(
"Substitute or blend with the volume envelope of the output. The closer the ratio is to 1, the more the output envelope is employed."
),
value=1,
interactive=True,
)
protect_batch = gr.Slider(
minimum=0,
maximum=0.5,
label=i18n("Protect Voiceless Consonants"),
info=i18n(
"Safeguard distinct consonants and breathing sounds to prevent electro-acoustic tearing and other artifacts. Pulling the parameter to its maximum value of 0.5 offers comprehensive protection. However, reducing this value might decrease the extent of protection while potentially mitigating the indexing effect."
),
value=0.5,
interactive=True,
)
hop_length_batch = gr.Slider(
minimum=1,
maximum=512,
step=1,
label=i18n("Hop Length"),
info=i18n(
"Denotes the duration it takes for the system to transition to a significant pitch change. Smaller hop lengths require more time for inference but tend to yield higher pitch accuracy."
),
visible=False,
value=128,
interactive=True,
)
with gr.Column():
f0method_batch = gr.Radio(
label=i18n("Pitch extraction algorithm"),
info=i18n(
"Pitch extraction algorithm to use for the audio conversion. The default algorithm is rmvpe, which is recommended for most cases."
),
choices=[
"pm",
"harvest",
"dio",
"crepe",
"crepe-tiny",
"rmvpe",
"fcpe",
"hybrid[rmvpe+fcpe]",
],
value="rmvpe",
interactive=True,
)
convert_button2 = gr.Button(i18n("Convert"))
with gr.Row(): # Defines output info + output audio download after conversion
vc_output3 = gr.Textbox(
label=i18n("Output Information"),
info=i18n("The output information will be displayed here."),
)
def toggle_visible(checkbox):
return {"visible": checkbox, "__type__": "update"}
def toggle_visible_hop_length(f0method):
if f0method == "crepe" or f0method == "crepe-tiny":
return {"visible": True, "__type__": "update"}
return {"visible": False, "__type__": "update"}
clean_audio.change(
fn=toggle_visible,
inputs=[clean_audio],
outputs=[clean_strength],
)
clean_audio_batch.change(
fn=toggle_visible,
inputs=[clean_audio_batch],
outputs=[clean_strength_batch],
)
f0method.change(
fn=toggle_visible_hop_length,
inputs=[f0method],
outputs=[hop_length],
)
f0method_batch.change(
fn=toggle_visible_hop_length,
inputs=[f0method_batch],
outputs=[hop_length_batch],
)
refresh_button.click(
fn=change_choices,
inputs=[],
outputs=[model_file, index_file, audio],
)
audio.change(
fn=output_path_fn,
inputs=[audio],
outputs=[output_path],
)
upload_audio.upload(
fn=save_to_wav2,
inputs=[upload_audio],
outputs=[audio, output_path],
)
upload_audio.stop_recording(
fn=save_to_wav,
inputs=[upload_audio],
outputs=[audio, output_path],
)
clear_outputs_infer.click(
fn=delete_outputs,
inputs=[],
outputs=[],
)
clear_outputs_batch.click(
fn=delete_outputs,
inputs=[],
outputs=[],
)
convert_button1.click(
fn=run_infer_script,
inputs=[
pitch,
filter_radius,
index_rate,
rms_mix_rate,
protect,
hop_length,
f0method,
audio,
output_path,
model_file,
index_file,
split_audio,
autotune,
clean_audio,
clean_strength,
export_format,
],
outputs=[vc_output1, vc_output2],
)
convert_button2.click(
fn=run_batch_infer_script,
inputs=[
pitch_batch,
filter_radius_batch,
index_rate_batch,
rms_mix_rate_batch,
protect_batch,
hop_length_batch,
f0method_batch,
input_folder_batch,
output_folder_batch,
model_file,
index_file,
split_audio_batch,
autotune_batch,
clean_audio_batch,
clean_strength_batch,
export_format_batch,
],
outputs=[vc_output3],
)