E2-F5-TTSII / inference-cli.py
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import argparse
import codecs
import re
import tempfile
from pathlib import Path
import numpy as np
import soundfile as sf
import tomli
import torch
import torchaudio
import tqdm
from cached_path import cached_path
from einops import rearrange
from pydub import AudioSegment, silence
from transformers import pipeline
from vocos import Vocos
from model import CFM, DiT, MMDiT, UNetT
from model.utils import (convert_char_to_pinyin, get_tokenizer,
load_checkpoint, save_spectrogram)
parser = argparse.ArgumentParser(
prog="python3 inference-cli.py",
description="Commandline interface for E2/F5 TTS with Advanced Batch Processing.",
epilog="Specify options above to override one or more settings from config.",
)
parser.add_argument(
"-c",
"--config",
help="Configuration file. Default=cli-config.toml",
default="inference-cli.toml",
)
parser.add_argument(
"-m",
"--model",
help="F5-TTS | E2-TTS",
)
parser.add_argument(
"-r",
"--ref_audio",
type=str,
help="Reference audio file < 15 seconds."
)
parser.add_argument(
"-s",
"--ref_text",
type=str,
default="666",
help="Subtitle for the reference audio."
)
parser.add_argument(
"-t",
"--gen_text",
type=str,
help="Text to generate.",
)
parser.add_argument(
"-f",
"--gen_file",
type=str,
help="File with text to generate. Ignores --text",
)
parser.add_argument(
"-o",
"--output_dir",
type=str,
help="Path to output folder..",
)
parser.add_argument(
"--remove_silence",
help="Remove silence.",
)
parser.add_argument(
"--load_vocoder_from_local",
action="store_true",
help="load vocoder from local. Default: ../checkpoints/charactr/vocos-mel-24khz",
)
args = parser.parse_args()
config = tomli.load(open(args.config, "rb"))
ref_audio = args.ref_audio if args.ref_audio else config["ref_audio"]
ref_text = args.ref_text if args.ref_text != "666" else config["ref_text"]
gen_text = args.gen_text if args.gen_text else config["gen_text"]
gen_file = args.gen_file if args.gen_file else config["gen_file"]
if gen_file:
gen_text = codecs.open(gen_file, "r", "utf-8").read()
output_dir = args.output_dir if args.output_dir else config["output_dir"]
model = args.model if args.model else config["model"]
remove_silence = args.remove_silence if args.remove_silence else config["remove_silence"]
wave_path = Path(output_dir)/"out.wav"
spectrogram_path = Path(output_dir)/"out.png"
vocos_local_path = "../checkpoints/charactr/vocos-mel-24khz"
device = (
"cuda"
if torch.cuda.is_available()
else "mps" if torch.backends.mps.is_available() else "cpu"
)
if args.load_vocoder_from_local:
print(f"Load vocos from local path {vocos_local_path}")
vocos = Vocos.from_hparams(f"{vocos_local_path}/config.yaml")
state_dict = torch.load(f"{vocos_local_path}/pytorch_model.bin", map_location=device)
vocos.load_state_dict(state_dict)
vocos.eval()
else:
print("Donwload Vocos from huggingface charactr/vocos-mel-24khz")
vocos = Vocos.from_pretrained("charactr/vocos-mel-24khz")
print(f"Using {device} device")
# --------------------- Settings -------------------- #
target_sample_rate = 24000
n_mel_channels = 100
hop_length = 256
target_rms = 0.1
nfe_step = 32 # 16, 32
cfg_strength = 2.0
ode_method = "euler"
sway_sampling_coef = -1.0
speed = 1.0
# fix_duration = 27 # None or float (duration in seconds)
fix_duration = None
def load_model(repo_name, exp_name, model_cls, model_cfg, ckpt_step):
ckpt_path = f"ckpts/{exp_name}/model_{ckpt_step}.pt" # .pt | .safetensors
if not Path(ckpt_path).exists():
ckpt_path = str(cached_path(f"hf://SWivid/{repo_name}/{exp_name}/model_{ckpt_step}.safetensors"))
vocab_char_map, vocab_size = get_tokenizer("Emilia_ZH_EN", "pinyin")
model = CFM(
transformer=model_cls(
**model_cfg, text_num_embeds=vocab_size, mel_dim=n_mel_channels
),
mel_spec_kwargs=dict(
target_sample_rate=target_sample_rate,
n_mel_channels=n_mel_channels,
hop_length=hop_length,
),
odeint_kwargs=dict(
method=ode_method,
),
vocab_char_map=vocab_char_map,
).to(device)
model = load_checkpoint(model, ckpt_path, device, use_ema = True)
return model
# load models
F5TTS_model_cfg = dict(
dim=1024, depth=22, heads=16, ff_mult=2, text_dim=512, conv_layers=4
)
E2TTS_model_cfg = dict(dim=1024, depth=24, heads=16, ff_mult=4)
def chunk_text(text, max_chars=135):
"""
Splits the input text into chunks, each with a maximum number of characters.
Args:
text (str): The text to be split.
max_chars (int): The maximum number of characters per chunk.
Returns:
List[str]: A list of text chunks.
"""
chunks = []
current_chunk = ""
# Split the text into sentences based on punctuation followed by whitespace
sentences = re.split(r'(?<=[;:,.!?])\s+|(?<=[;:,。!?])', text)
for sentence in sentences:
if len(current_chunk.encode('utf-8')) + len(sentence.encode('utf-8')) <= max_chars:
current_chunk += sentence + " " if sentence and len(sentence[-1].encode('utf-8')) == 1 else sentence
else:
if current_chunk:
chunks.append(current_chunk.strip())
current_chunk = sentence + " " if sentence and len(sentence[-1].encode('utf-8')) == 1 else sentence
if current_chunk:
chunks.append(current_chunk.strip())
return chunks
def infer_batch(ref_audio, ref_text, gen_text_batches, model, remove_silence, cross_fade_duration=0.15):
if model == "F5-TTS":
ema_model = load_model(model, "F5TTS_Base", DiT, F5TTS_model_cfg, 1200000)
elif model == "E2-TTS":
ema_model = load_model(model, "E2TTS_Base", UNetT, E2TTS_model_cfg, 1200000)
audio, sr = ref_audio
if audio.shape[0] > 1:
audio = torch.mean(audio, dim=0, keepdim=True)
rms = torch.sqrt(torch.mean(torch.square(audio)))
if rms < target_rms:
audio = audio * target_rms / rms
if sr != target_sample_rate:
resampler = torchaudio.transforms.Resample(sr, target_sample_rate)
audio = resampler(audio)
audio = audio.to(device)
generated_waves = []
spectrograms = []
for i, gen_text in enumerate(tqdm.tqdm(gen_text_batches)):
# Prepare the text
if len(ref_text[-1].encode('utf-8')) == 1:
ref_text = ref_text + " "
text_list = [ref_text + gen_text]
final_text_list = convert_char_to_pinyin(text_list)
# Calculate duration
ref_audio_len = audio.shape[-1] // hop_length
zh_pause_punc = r"。,、;:?!"
ref_text_len = len(ref_text.encode('utf-8')) + 3 * len(re.findall(zh_pause_punc, ref_text))
gen_text_len = len(gen_text.encode('utf-8')) + 3 * len(re.findall(zh_pause_punc, gen_text))
duration = ref_audio_len + int(ref_audio_len / ref_text_len * gen_text_len / speed)
# inference
with torch.inference_mode():
generated, _ = ema_model.sample(
cond=audio,
text=final_text_list,
duration=duration,
steps=nfe_step,
cfg_strength=cfg_strength,
sway_sampling_coef=sway_sampling_coef,
)
generated = generated[:, ref_audio_len:, :]
generated_mel_spec = rearrange(generated, "1 n d -> 1 d n")
generated_wave = vocos.decode(generated_mel_spec.cpu())
if rms < target_rms:
generated_wave = generated_wave * rms / target_rms
# wav -> numpy
generated_wave = generated_wave.squeeze().cpu().numpy()
generated_waves.append(generated_wave)
spectrograms.append(generated_mel_spec[0].cpu().numpy())
# Combine all generated waves with cross-fading
if cross_fade_duration <= 0:
# Simply concatenate
final_wave = np.concatenate(generated_waves)
else:
final_wave = generated_waves[0]
for i in range(1, len(generated_waves)):
prev_wave = final_wave
next_wave = generated_waves[i]
# Calculate cross-fade samples, ensuring it does not exceed wave lengths
cross_fade_samples = int(cross_fade_duration * target_sample_rate)
cross_fade_samples = min(cross_fade_samples, len(prev_wave), len(next_wave))
if cross_fade_samples <= 0:
# No overlap possible, concatenate
final_wave = np.concatenate([prev_wave, next_wave])
continue
# Overlapping parts
prev_overlap = prev_wave[-cross_fade_samples:]
next_overlap = next_wave[:cross_fade_samples]
# Fade out and fade in
fade_out = np.linspace(1, 0, cross_fade_samples)
fade_in = np.linspace(0, 1, cross_fade_samples)
# Cross-faded overlap
cross_faded_overlap = prev_overlap * fade_out + next_overlap * fade_in
# Combine
new_wave = np.concatenate([
prev_wave[:-cross_fade_samples],
cross_faded_overlap,
next_wave[cross_fade_samples:]
])
final_wave = new_wave
# Create a combined spectrogram
combined_spectrogram = np.concatenate(spectrograms, axis=1)
return final_wave, combined_spectrogram
def process_voice(ref_audio_orig, ref_text):
print("Converting audio...")
with tempfile.NamedTemporaryFile(delete=False, suffix=".wav") as f:
aseg = AudioSegment.from_file(ref_audio_orig)
non_silent_segs = silence.split_on_silence(aseg, min_silence_len=1000, silence_thresh=-50, keep_silence=1000)
non_silent_wave = AudioSegment.silent(duration=0)
for non_silent_seg in non_silent_segs:
non_silent_wave += non_silent_seg
aseg = non_silent_wave
audio_duration = len(aseg)
if audio_duration > 15000:
print("Audio is over 15s, clipping to only first 15s.")
aseg = aseg[:15000]
aseg.export(f.name, format="wav")
ref_audio = f.name
if not ref_text.strip():
print("No reference text provided, transcribing reference audio...")
pipe = pipeline(
"automatic-speech-recognition",
model="openai/whisper-large-v3-turbo",
torch_dtype=torch.float16,
device=device,
)
ref_text = pipe(
ref_audio,
chunk_length_s=30,
batch_size=128,
generate_kwargs={"task": "transcribe"},
return_timestamps=False,
)["text"].strip()
print("Finished transcription")
else:
print("Using custom reference text...")
return ref_audio, ref_text
def infer(ref_audio, ref_text, gen_text, model, remove_silence, cross_fade_duration=0.15):
print(gen_text)
# Add the functionality to ensure it ends with ". "
if not ref_text.endswith(". ") and not ref_text.endswith("。"):
if ref_text.endswith("."):
ref_text += " "
else:
ref_text += ". "
# Split the input text into batches
audio, sr = torchaudio.load(ref_audio)
max_chars = int(len(ref_text.encode('utf-8')) / (audio.shape[-1] / sr) * (25 - audio.shape[-1] / sr))
gen_text_batches = chunk_text(gen_text, max_chars=max_chars)
print('ref_text', ref_text)
for i, gen_text in enumerate(gen_text_batches):
print(f'gen_text {i}', gen_text)
print(f"Generating audio using {model} in {len(gen_text_batches)} batches, loading models...")
return infer_batch((audio, sr), ref_text, gen_text_batches, model, remove_silence, cross_fade_duration)
def process(ref_audio, ref_text, text_gen, model, remove_silence):
main_voice = {"ref_audio":ref_audio, "ref_text":ref_text}
if "voices" not in config:
voices = {"main": main_voice}
else:
voices = config["voices"]
voices["main"] = main_voice
for voice in voices:
voices[voice]['ref_audio'], voices[voice]['ref_text'] = process_voice(voices[voice]['ref_audio'], voices[voice]['ref_text'])
generated_audio_segments = []
reg1 = r'(?=\[\w+\])'
chunks = re.split(reg1, text_gen)
reg2 = r'\[(\w+)\]'
for text in chunks:
match = re.match(reg2, text)
if not match or voice not in voices:
voice = "main"
else:
voice = match[1]
text = re.sub(reg2, "", text)
gen_text = text.strip()
ref_audio = voices[voice]['ref_audio']
ref_text = voices[voice]['ref_text']
print(f"Voice: {voice}")
audio, spectragram = infer(ref_audio, ref_text, gen_text, model, remove_silence)
generated_audio_segments.append(audio)
if generated_audio_segments:
final_wave = np.concatenate(generated_audio_segments)
with open(wave_path, "wb") as f:
sf.write(f.name, final_wave, target_sample_rate)
# Remove silence
if remove_silence:
aseg = AudioSegment.from_file(f.name)
non_silent_segs = silence.split_on_silence(aseg, min_silence_len=1000, silence_thresh=-50, keep_silence=500)
non_silent_wave = AudioSegment.silent(duration=0)
for non_silent_seg in non_silent_segs:
non_silent_wave += non_silent_seg
aseg = non_silent_wave
aseg.export(f.name, format="wav")
print(f.name)
process(ref_audio, ref_text, gen_text, model, remove_silence)