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Laronix_Recording / local /fine-tuning.py

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	"""
	TODO:
	+ [x] Load Configuration
	+ [ ] Multi ASR Engine
	+ [ ] Batch / Real Time support
	"""
	from pathlib import Path
	from transformers import AutoTokenizer, AutoFeatureExtractor, AutoModelForCTC, AutoProcessor
	from datasets import load_dataset
	from datasets import Dataset, Audio
	import pdb
	import string
	# local import
	import sys

	sys.path.append("src")

	# token_model = AutoModelForCTC.from_pretrained(
	# "facebook/wav2vec2-base-960h"
	# )

	# ds = load_dataset("patrickvonplaten/librispeech_asr_dummy", "clean", split="validation")

	audio_path = "/Users/kevingeng/Laronix/Laronix_PAL_ASR_Offline_Plot/data/samples/3_Healthy1.wav"

	audio_dir= "/Users/kevingeng/Laronix/laronix_automos/data/Patient_sil_trim_16k_normed_5_snr_40/"
	# tgt_audio_dir= "/Users/kevingeng/Laronix/Dataset/Pneumatic/automos"

	# src_audio_list = sorted(Path(src_audio_dir).glob("*/.wav"))
	# src_audio_list = [str(x) for x in src_audio_list]
	# src_audio_dict = {"audio": src_audio_list}
	# src_dataset = Dataset.from_dict(src_audio_dict).cast_column("audio", Audio())

	# tgt_audio_list = sorted(Path(tgt_audio_dir).glob("*/.wav"))
	# tgt_audio_list = [str(x) for x in tgt_audio_list]
	# tgt_audio_dict = {"audio": tgt_audio_list}
	# tgt_dataset = Dataset.from_dict(tgt_audio_dict).cast_column("audio", Audio())

	# Get Transcription, WER and PPM
	"""
	TODO:
	[DONE]: Automatic generating Config
	"""

	import yaml
	import argparse
	import sys
	from pathlib import Path

	sys.path.append("./src")
	import lightning_module
	from UV import plot_UV, get_speech_interval
	from transformers import pipeline
	from rich.progress import track
	from rich import print as rprint
	import numpy as np
	import jiwer
	import pdb
	import torch.nn as nn
	import torch
	import torchaudio
	import gradio as gr
	from sys import flags
	from random import sample
	from transformers import Wav2Vec2Processor, Wav2Vec2ForCTC

	# root_path = Path(__file__).parents[1]

	class ChangeSampleRate(nn.Module):
	def __init__(self, input_rate: int, output_rate: int):
	super().__init__()
	self.output_rate = output_rate
	self.input_rate = input_rate

	def forward(self, wav: torch.tensor) -> torch.tensor:
	# Only accepts 1-channel waveform input
	wav = wav.view(wav.size(0), -1)
	new_length = wav.size(-1) * self.output_rate // self.input_rate
	indices = torch.arange(new_length) * (
	self.input_rate / self.output_rate
	)
	round_down = wav[:, indices.long()]
	round_up = wav[:, (indices.long() + 1).clamp(max=wav.size(-1) - 1)]
	output = round_down * (1.0 - indices.fmod(1.0)).unsqueeze(
	0
	) + round_up * indices.fmod(1.0).unsqueeze(0)
	return output


	model = lightning_module.BaselineLightningModule.load_from_checkpoint(
	"./src/epoch=3-step=7459.ckpt"
	).eval()


	def calc_wer(audio_path, ref):
	wav, sr = torchaudio.load(audio_path)
	osr = 16_000
	batch = wav.unsqueeze(0).repeat(10, 1, 1)
	csr = ChangeSampleRate(sr, osr)
	out_wavs = csr(wav)
	# ASR
	trans = p(audio_path)["text"]
	# WER
	wer = jiwer.wer(
	ref,
	trans,
	truth_transform=transformation,
	hypothesis_transform=transformation,
	)
	return trans, wer

	# if __name__ == "__main__":
	# # Argparse
	# parser = argparse.ArgumentParser(
	# prog="get_ref_PPM",
	# description="Generate Phoneme per Minute (and Voice/Unvoice plot)",
	# epilog="",
	# )
	# parser.add_argument(
	# "--tag",
	# type=str,
	# default=None,
	# required=False,
	# help="ID tag for output *.csv",
	# )

	# parser.add_argument("--ref_txt", type=str, required=True, help="Reference TXT")
	# parser.add_argument(
	# "--ref_wavs", type=str, required=True, help="Reference WAVs"
	# )

	# parser.add_argument(
	# "--output_dir",
	# type=str,
	# required=True,
	# help="Output Directory for *.csv",
	# )
	# parser.add_argument(
	# "--to_config",
	# choices=["True", "False"],
	# default="False",
	# help="Generating Config from .txt and wavs/*wav",
	# )


	# args = parser.parse_args()

	# refs = np.loadtxt(args.ref_txt, delimiter="\n", dtype="str")
	# refs_ids = [x.split()[0] for x in refs]
	# refs_txt = [" ".join(x.split()[1:]) for x in refs]
	# ref_wavs = [str(x) for x in sorted(Path(args.ref_wavs).glob("*/.wav"))]
	# # pdb.set_trace()
	# try:
	# len(refs) == len(ref_wavs)
	# except ValueError:
	# print("Error: Text and Wavs don't match")
	# exit()

	# # ASR part
	# p = pipeline("automatic-speech-recognition")

	# # WER part
	# transformation = jiwer.Compose(
	# [
	# jiwer.ToLowerCase(),
	# jiwer.RemoveWhiteSpace(replace_by_space=True),
	# jiwer.RemoveMultipleSpaces(),
	# jiwer.ReduceToListOfListOfWords(word_delimiter=" "),
	# ]
	# )

	# # WPM part
	# processor = Wav2Vec2Processor.from_pretrained(
	# "facebook/wav2vec2-xlsr-53-espeak-cv-ft"
	# )
	# phoneme_model = Wav2Vec2ForCTC.from_pretrained(
	# "facebook/wav2vec2-xlsr-53-espeak-cv-ft"
	# )
	# # phoneme_model = pipeline(model="facebook/wav2vec2-xlsr-53-espeak-cv-ft")

	# description = """
	# MOS prediction demo using UTMOS-strong w/o phoneme encoder model, \
	# which is trained on the main track dataset.
	# This demo only accepts .wav format. Best at 16 kHz sampling rate.

	# Paper is available [here](https://arxiv.org/abs/2204.02152)

	# Add ASR based on wav2vec-960, currently only English available.
	# Add WER interface.
	# """

	# referance_id = gr.Textbox(
	# value="ID", placeholder="Utter ID", label="Reference_ID"
	# )
	# referance_textbox = gr.Textbox(
	# value="", placeholder="Input reference here", label="Reference"
	# )
	# # Set up interface
	# result = []
	# result.append("id, trans, wer")


	# for id, x, y in track(
	# zip(refs_ids, ref_wavs, refs_txt),
	# total=len(refs_ids),
	# description="Loading references information",
	# ):
	# trans, wer = calc_wer(x, y)
	# record = ",".join(
	# [
	# id,
	# str(trans),
	# str(wer)
	# ]
	# )
	# result.append(record)

	# # Output
	# if args.tag == None:
	# args.tag = Path(args.ref_wavs).stem
	# # Make output_dir
	# # pdb.set_trace()
	# Path.mkdir(Path(args.output_dir), exist_ok=True)
	# # pdb.set_trace()
	# with open("%s/%s.csv" % (args.output_dir, args.tag), "w") as f:
	# print("\n".join(result), file=f)

	# # Generating config
	# if args.to_config == "True":
	# config_dict = {
	# "exp_id": args.tag,
	# "ref_txt": args.ref_txt,
	# "ref_feature": "%s/%s.csv" % (args.output_dir, args.tag),
	# "ref_wavs": args.ref_wavs,
	# "thre": {
	# "minppm": 100,
	# "maxppm": 100,
	# "WER": 0.1,
	# "AUTOMOS": 4.0,
	# },
	# "auth": {"username": None, "password": None},
	# }
	# with open("./config/%s.yaml" % args.tag, "w") as config_f:
	# rprint("Dumping as config ./config/%s.yaml" % args.tag)
	# rprint(config_dict)
	# yaml.dump(config_dict, stream=config_f)
	# rprint("Change parameter ./config/%s.yaml if necessary" % args.tag)
	# print("Reference Dumping Finished")
	def dataclean(example):
	return {"transcription": example["transcription"].upper().translate(str.maketrans('', '', string.punctuation))}

	# processor = AutoFeatureExtractor.from_pretrained(
	# "facebook/wav2vec2-base-960h"
	# )
	processor = AutoProcessor.from_pretrained("facebook/wav2vec2-base")

	def prepare_dataset(batch):
	audio = batch["audio"]
	batch = processor(audio["array"], sampling_rate = audio["sampling_rate"], text=batch['transcription'])
	batch["input_length"] = len(batch["input_values"][0])
	return batch

	src_dataset = load_dataset("audiofolder", data_dir=audio_dir, split="train")
	src_dataset = src_dataset.map(dataclean)
	# train_dev / test
	ds = src_dataset.train_test_split(test_size=0.1)

	train_dev = ds['train']
	# train / dev
	train_dev = train_dev.train_test_split(test_size=int(len(src_dataset)*0.1))
	# train/dev/test
	train = train_dev['train']
	test = ds['test']
	dev = train_dev['test']

	# pdb.set_trace()
	import numpy as np


	def compute_metrics(pred):
	pred_logits = pred.predictions
	pred_ids = np.argmax(pred_logits, axis=-1)

	pred.label_ids[pred.label_ids == -100] = processor.tokenizer.pad_token_id

	pred_str = processor.batch_decode(pred_ids)
	label_str = processor.batch_decode(pred.label_ids, group_tokens=False)

	wer = wer.compute(predictions=pred_str, references=label_str)

	return {"wer": wer}


	pdb.set_trace()
	# TOKENLIZER("data/samples/5_Laronix1.wav")
	# pdb.set_trace()
	# tokenizer
	tokenizer = AutoTokenizer.from_pretrained("facebook/wav2vec2-base-960h")

	encoded_train = train.map(prepare_dataset, num_proc=4)

	from transformers import AutoModelForCTC, TrainingArguments, Trainer

	model = AutoModelForCTC.from_pretrained(
	"facebook/wav2vec2-base",
	ctc_loss_reduction="mean",
	pad_token_id=processor.tokenizer.pad_token_id,
	)
	pdb.set_trace()

	training_args = TrainingArguments(
	output_dir="my_awesome_asr_mind_model",
	per_device_train_batch_size=8,
	gradient_accumulation_steps=2,
	learning_rate=1e-5,
	warmup_steps=500,
	max_steps=2000,
	gradient_checkpointing=True,
	fp16=True,
	group_by_length=True,
	evaluation_strategy="steps",
	per_device_eval_batch_size=8,
	save_steps=1000,
	eval_steps=1000,
	logging_steps=25,
	load_best_model_at_end=True,
	metric_for_best_model="wer",
	greater_is_better=False,
	push_to_hub=True,
	)

	pdb.set_trace()
	trainer = Trainer(
	model=model,
	args=training_args,
	train_dataset=encoded_train["train"],
	eval_dataset=encoded_train["test"],
	tokenizer=processor.feature_extractor,
	compute_metrics=compute_metrics,
	)
	pdb.set_trace()
	# data_collator=data_collator,

	trainer.train()
	# x = tokenizer(test['transcription'][0])