import math import os import random import string import torch import torch.nn.functional as F import torchaudio from tqdm import tqdm from f5_tts.eval.ecapa_tdnn import ECAPA_TDNN_SMALL from f5_tts.model.modules import MelSpec from f5_tts.model.utils import convert_char_to_pinyin # seedtts testset metainfo: utt, prompt_text, prompt_wav, gt_text, gt_wav def get_seedtts_testset_metainfo(metalst): f = open(metalst) lines = f.readlines() f.close() metainfo = [] for line in lines: if len(line.strip().split("|")) == 5: utt, prompt_text, prompt_wav, gt_text, gt_wav = line.strip().split("|") elif len(line.strip().split("|")) == 4: utt, prompt_text, prompt_wav, gt_text = line.strip().split("|") gt_wav = os.path.join(os.path.dirname(metalst), "wavs", utt + ".wav") if not os.path.isabs(prompt_wav): prompt_wav = os.path.join(os.path.dirname(metalst), prompt_wav) metainfo.append((utt, prompt_text, prompt_wav, gt_text, gt_wav)) return metainfo # librispeech test-clean metainfo: gen_utt, ref_txt, ref_wav, gen_txt, gen_wav def get_librispeech_test_clean_metainfo(metalst, librispeech_test_clean_path): f = open(metalst) lines = f.readlines() f.close() metainfo = [] for line in lines: ref_utt, ref_dur, ref_txt, gen_utt, gen_dur, gen_txt = line.strip().split("\t") # ref_txt = ref_txt[0] + ref_txt[1:].lower() + '.' # if use librispeech test-clean (no-pc) ref_spk_id, ref_chaptr_id, _ = ref_utt.split("-") ref_wav = os.path.join(librispeech_test_clean_path, ref_spk_id, ref_chaptr_id, ref_utt + ".flac") # gen_txt = gen_txt[0] + gen_txt[1:].lower() + '.' # if use librispeech test-clean (no-pc) gen_spk_id, gen_chaptr_id, _ = gen_utt.split("-") gen_wav = os.path.join(librispeech_test_clean_path, gen_spk_id, gen_chaptr_id, gen_utt + ".flac") metainfo.append((gen_utt, ref_txt, ref_wav, " " + gen_txt, gen_wav)) return metainfo # padded to max length mel batch def padded_mel_batch(ref_mels): max_mel_length = torch.LongTensor([mel.shape[-1] for mel in ref_mels]).amax() padded_ref_mels = [] for mel in ref_mels: padded_ref_mel = F.pad(mel, (0, max_mel_length - mel.shape[-1]), value=0) padded_ref_mels.append(padded_ref_mel) padded_ref_mels = torch.stack(padded_ref_mels) padded_ref_mels = padded_ref_mels.permute(0, 2, 1) return padded_ref_mels # get prompts from metainfo containing: utt, prompt_text, prompt_wav, gt_text, gt_wav def get_inference_prompt( metainfo, speed=1.0, tokenizer="pinyin", polyphone=True, target_sample_rate=24000, n_fft=1024, win_length=1024, n_mel_channels=100, hop_length=256, mel_spec_type="vocos", target_rms=0.1, use_truth_duration=False, infer_batch_size=1, num_buckets=200, min_secs=3, max_secs=40, ): prompts_all = [] min_tokens = min_secs * target_sample_rate // hop_length max_tokens = max_secs * target_sample_rate // hop_length batch_accum = [0] * num_buckets utts, ref_rms_list, ref_mels, ref_mel_lens, total_mel_lens, final_text_list = ( [[] for _ in range(num_buckets)] for _ in range(6) ) mel_spectrogram = MelSpec( n_fft=n_fft, hop_length=hop_length, win_length=win_length, n_mel_channels=n_mel_channels, target_sample_rate=target_sample_rate, mel_spec_type=mel_spec_type, ) for utt, prompt_text, prompt_wav, gt_text, gt_wav in tqdm(metainfo, desc="Processing prompts..."): # Audio ref_audio, ref_sr = torchaudio.load(prompt_wav) ref_rms = torch.sqrt(torch.mean(torch.square(ref_audio))) if ref_rms < target_rms: ref_audio = ref_audio * target_rms / ref_rms assert ref_audio.shape[-1] > 5000, f"Empty prompt wav: {prompt_wav}, or torchaudio backend issue." if ref_sr != target_sample_rate: resampler = torchaudio.transforms.Resample(ref_sr, target_sample_rate) ref_audio = resampler(ref_audio) # Text if len(prompt_text[-1].encode("utf-8")) == 1: prompt_text = prompt_text + " " text = [prompt_text + gt_text] if tokenizer == "pinyin": text_list = convert_char_to_pinyin(text, polyphone=polyphone) else: text_list = text # Duration, mel frame length ref_mel_len = ref_audio.shape[-1] // hop_length if use_truth_duration: gt_audio, gt_sr = torchaudio.load(gt_wav) if gt_sr != target_sample_rate: resampler = torchaudio.transforms.Resample(gt_sr, target_sample_rate) gt_audio = resampler(gt_audio) total_mel_len = ref_mel_len + int(gt_audio.shape[-1] / hop_length / speed) # # test vocoder resynthesis # ref_audio = gt_audio else: ref_text_len = len(prompt_text.encode("utf-8")) gen_text_len = len(gt_text.encode("utf-8")) total_mel_len = ref_mel_len + int(ref_mel_len / ref_text_len * gen_text_len / speed) # to mel spectrogram ref_mel = mel_spectrogram(ref_audio) ref_mel = ref_mel.squeeze(0) # deal with batch assert infer_batch_size > 0, "infer_batch_size should be greater than 0." assert ( min_tokens <= total_mel_len <= max_tokens ), f"Audio {utt} has duration {total_mel_len*hop_length//target_sample_rate}s out of range [{min_secs}, {max_secs}]." bucket_i = math.floor((total_mel_len - min_tokens) / (max_tokens - min_tokens + 1) * num_buckets) utts[bucket_i].append(utt) ref_rms_list[bucket_i].append(ref_rms) ref_mels[bucket_i].append(ref_mel) ref_mel_lens[bucket_i].append(ref_mel_len) total_mel_lens[bucket_i].append(total_mel_len) final_text_list[bucket_i].extend(text_list) batch_accum[bucket_i] += total_mel_len if batch_accum[bucket_i] >= infer_batch_size: # print(f"\n{len(ref_mels[bucket_i][0][0])}\n{ref_mel_lens[bucket_i]}\n{total_mel_lens[bucket_i]}") prompts_all.append( ( utts[bucket_i], ref_rms_list[bucket_i], padded_mel_batch(ref_mels[bucket_i]), ref_mel_lens[bucket_i], total_mel_lens[bucket_i], final_text_list[bucket_i], ) ) batch_accum[bucket_i] = 0 ( utts[bucket_i], ref_rms_list[bucket_i], ref_mels[bucket_i], ref_mel_lens[bucket_i], total_mel_lens[bucket_i], final_text_list[bucket_i], ) = [], [], [], [], [], [] # add residual for bucket_i, bucket_frames in enumerate(batch_accum): if bucket_frames > 0: prompts_all.append( ( utts[bucket_i], ref_rms_list[bucket_i], padded_mel_batch(ref_mels[bucket_i]), ref_mel_lens[bucket_i], total_mel_lens[bucket_i], final_text_list[bucket_i], ) ) # not only leave easy work for last workers random.seed(666) random.shuffle(prompts_all) return prompts_all # get wav_res_ref_text of seed-tts test metalst # https://github.com/BytedanceSpeech/seed-tts-eval def get_seed_tts_test(metalst, gen_wav_dir, gpus): f = open(metalst) lines = f.readlines() f.close() test_set_ = [] for line in tqdm(lines): if len(line.strip().split("|")) == 5: utt, prompt_text, prompt_wav, gt_text, gt_wav = line.strip().split("|") elif len(line.strip().split("|")) == 4: utt, prompt_text, prompt_wav, gt_text = line.strip().split("|") if not os.path.exists(os.path.join(gen_wav_dir, utt + ".wav")): continue gen_wav = os.path.join(gen_wav_dir, utt + ".wav") if not os.path.isabs(prompt_wav): prompt_wav = os.path.join(os.path.dirname(metalst), prompt_wav) test_set_.append((gen_wav, prompt_wav, gt_text)) num_jobs = len(gpus) if num_jobs == 1: return [(gpus[0], test_set_)] wav_per_job = len(test_set_) // num_jobs + 1 test_set = [] for i in range(num_jobs): test_set.append((gpus[i], test_set_[i * wav_per_job : (i + 1) * wav_per_job])) return test_set # get librispeech test-clean cross sentence test def get_librispeech_test(metalst, gen_wav_dir, gpus, librispeech_test_clean_path, eval_ground_truth=False): f = open(metalst) lines = f.readlines() f.close() test_set_ = [] for line in tqdm(lines): ref_utt, ref_dur, ref_txt, gen_utt, gen_dur, gen_txt = line.strip().split("\t") if eval_ground_truth: gen_spk_id, gen_chaptr_id, _ = gen_utt.split("-") gen_wav = os.path.join(librispeech_test_clean_path, gen_spk_id, gen_chaptr_id, gen_utt + ".flac") else: if not os.path.exists(os.path.join(gen_wav_dir, gen_utt + ".wav")): raise FileNotFoundError(f"Generated wav not found: {gen_utt}") gen_wav = os.path.join(gen_wav_dir, gen_utt + ".wav") ref_spk_id, ref_chaptr_id, _ = ref_utt.split("-") ref_wav = os.path.join(librispeech_test_clean_path, ref_spk_id, ref_chaptr_id, ref_utt + ".flac") test_set_.append((gen_wav, ref_wav, gen_txt)) num_jobs = len(gpus) if num_jobs == 1: return [(gpus[0], test_set_)] wav_per_job = len(test_set_) // num_jobs + 1 test_set = [] for i in range(num_jobs): test_set.append((gpus[i], test_set_[i * wav_per_job : (i + 1) * wav_per_job])) return test_set # load asr model def load_asr_model(lang, ckpt_dir=""): if lang == "zh": from funasr import AutoModel model = AutoModel( model=os.path.join(ckpt_dir, "paraformer-zh"), # vad_model = os.path.join(ckpt_dir, "fsmn-vad"), # punc_model = os.path.join(ckpt_dir, "ct-punc"), # spk_model = os.path.join(ckpt_dir, "cam++"), disable_update=True, ) # following seed-tts setting elif lang == "en": from faster_whisper import WhisperModel model_size = "large-v3" if ckpt_dir == "" else ckpt_dir model = WhisperModel(model_size, device="cuda", compute_type="float16") return model # WER Evaluation, the way Seed-TTS does def run_asr_wer(args): rank, lang, test_set, ckpt_dir = args if lang == "zh": import zhconv torch.cuda.set_device(rank) elif lang == "en": os.environ["CUDA_VISIBLE_DEVICES"] = str(rank) else: raise NotImplementedError( "lang support only 'zh' (funasr paraformer-zh), 'en' (faster-whisper-large-v3), for now." ) asr_model = load_asr_model(lang, ckpt_dir=ckpt_dir) from zhon.hanzi import punctuation punctuation_all = punctuation + string.punctuation wers = [] from jiwer import compute_measures for gen_wav, prompt_wav, truth in tqdm(test_set): if lang == "zh": res = asr_model.generate(input=gen_wav, batch_size_s=300, disable_pbar=True) hypo = res[0]["text"] hypo = zhconv.convert(hypo, "zh-cn") elif lang == "en": segments, _ = asr_model.transcribe(gen_wav, beam_size=5, language="en") hypo = "" for segment in segments: hypo = hypo + " " + segment.text # raw_truth = truth # raw_hypo = hypo for x in punctuation_all: truth = truth.replace(x, "") hypo = hypo.replace(x, "") truth = truth.replace(" ", " ") hypo = hypo.replace(" ", " ") if lang == "zh": truth = " ".join([x for x in truth]) hypo = " ".join([x for x in hypo]) elif lang == "en": truth = truth.lower() hypo = hypo.lower() measures = compute_measures(truth, hypo) wer = measures["wer"] # ref_list = truth.split(" ") # subs = measures["substitutions"] / len(ref_list) # dele = measures["deletions"] / len(ref_list) # inse = measures["insertions"] / len(ref_list) wers.append(wer) return wers # SIM Evaluation def run_sim(args): rank, test_set, ckpt_dir = args device = f"cuda:{rank}" model = ECAPA_TDNN_SMALL(feat_dim=1024, feat_type="wavlm_large", config_path=None) state_dict = torch.load(ckpt_dir, weights_only=True, map_location=lambda storage, loc: storage) model.load_state_dict(state_dict["model"], strict=False) use_gpu = True if torch.cuda.is_available() else False if use_gpu: model = model.cuda(device) model.eval() sim_list = [] for wav1, wav2, truth in tqdm(test_set): wav1, sr1 = torchaudio.load(wav1) wav2, sr2 = torchaudio.load(wav2) resample1 = torchaudio.transforms.Resample(orig_freq=sr1, new_freq=16000) resample2 = torchaudio.transforms.Resample(orig_freq=sr2, new_freq=16000) wav1 = resample1(wav1) wav2 = resample2(wav2) if use_gpu: wav1 = wav1.cuda(device) wav2 = wav2.cuda(device) with torch.no_grad(): emb1 = model(wav1) emb2 = model(wav2) sim = F.cosine_similarity(emb1, emb2)[0].item() # print(f"VSim score between two audios: {sim:.4f} (-1.0, 1.0).") sim_list.append(sim) return sim_list