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Music-Descriptor

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Epsilon617

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3462d76 about 1 year ago

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	import gradio as gr
	#
	from transformers import Wav2Vec2FeatureExtractor
	from transformers import AutoModel
	import torch
	from torch import nn
	import torchaudio
	import torchaudio.transforms as T
	import logging

	import json
	import os
	import re

	import pandas as pd

	import importlib
	modeling_MERT = importlib.import_module("MERT-v1-95M.modeling_MERT")

	from Prediction_Head.MTGGenre_head import MLPProberBase
	# input cr: https://huggingface.co/spaces/thealphhamerc/audio-to-text/blob/main/app.py


	logger = logging.getLogger("MERT-v1-95M-app")
	logger.setLevel(logging.INFO)
	ch = logging.StreamHandler()
	ch.setLevel(logging.INFO)
	formatter = logging.Formatter(
	"%(asctime)s;%(levelname)s;%(message)s", "%Y-%m-%d %H:%M:%S")
	ch.setFormatter(formatter)
	logger.addHandler(ch)



	inputs = [
	gr.components.Audio(type="filepath", label="Add music audio file"),
	gr.inputs.Audio(source="microphone", type="filepath"),
	]
	live_inputs = [
	gr.Audio(source="microphone",streaming=True, type="filepath"),
	]

	title = "One Model for All Music Understanding Tasks"
	description = "An example of using the [MERT-v1-95M](https://huggingface.co/m-a-p/MERT-v1-95M) model as backbone to conduct multiple music understanding tasks with the universal represenation."
	# article = "The tasks include EMO, GS, MTGInstrument, MTGGenre, MTGTop50, MTGMood, NSynthI, NSynthP, VocalSetS, VocalSetT. \n\n More models can be referred at the [map organization page](https://huggingface.co/m-a-p)."
	with open('./README.md', 'r') as f:
	# skip the header
	header_count = 0
	for line in f:
	if '---' in line:
	header_count += 1
	if header_count >= 2:
	break
	# read the rest conent
	article = f.read()

	audio_examples = [
	# ["input/example-1.wav"],
	# ["input/example-2.wav"],
	]

	df_init = pd.DataFrame(columns=['Task', 'Top 1', 'Top 2', 'Top 3', 'Top 4', 'Top 5'])
	transcription_df = gr.DataFrame(value=df_init, label="Output Dataframe", row_count=(
	0, "dynamic"), max_rows=30, wrap=True, overflow_row_behaviour='paginate')
	# outputs = [gr.components.Textbox()]
	outputs = transcription_df

	df_init_live = pd.DataFrame(columns=['Task', 'Top 1', 'Top 2', 'Top 3', 'Top 4', 'Top 5'])
	transcription_df_live = gr.DataFrame(value=df_init_live, label="Output Dataframe", row_count=(
	0, "dynamic"), max_rows=30, wrap=True, overflow_row_behaviour='paginate')
	outputs_live = transcription_df_live

	# Load the model and the corresponding preprocessor config
	# model = AutoModel.from_pretrained("m-a-p/MERT-v0-public", trust_remote_code=True)
	# processor = Wav2Vec2FeatureExtractor.from_pretrained("m-a-p/MERT-v0-public",trust_remote_code=True)
	model = modeling_MERT.MERTModel.from_pretrained("./MERT-v1-95M")
	processor = Wav2Vec2FeatureExtractor.from_pretrained("./MERT-v1-95M")

	device = 'cuda' if torch.cuda.is_available() else 'cpu'

	MERT_BEST_LAYER_IDX = {
	'EMO': 5,
	'GS': 8,
	'GTZAN': 7,
	'MTGGenre': 7,
	'MTGInstrument': 'all',
	'MTGMood': 6,
	'MTGTop50': 6,
	'MTT': 'all',
	'NSynthI': 6,
	'NSynthP': 1,
	'VocalSetS': 2,
	'VocalSetT': 9,
	}

	MERT_BEST_LAYER_IDX = {
	'EMO': 5,
	'GS': 8,
	'GTZAN': 7,
	'MTGGenre': 7,
	'MTGInstrument': 'all',
	'MTGMood': 6,
	'MTGTop50': 6,
	'MTT': 'all',
	'NSynthI': 6,
	'NSynthP': 1,
	'VocalSetS': 2,
	'VocalSetT': 9,
	}
	CLASSIFIERS = {

	}

	ID2CLASS = {

	}

	TASKS = ['GS', 'MTGInstrument', 'MTGGenre', 'MTGTop50', 'MTGMood', 'NSynthI', 'NSynthP', 'VocalSetS', 'VocalSetT','EMO',]
	Regression_TASKS = ['EMO']
	head_dir = './Prediction_Head/best-layer-MERT-v1-95M'
	for task in TASKS:
	print('loading', task)
	with open(os.path.join(head_dir,f'{task}.id2class.json'), 'r') as f:
	ID2CLASS[task]=json.load(f)
	num_class = len(ID2CLASS[task].keys())
	CLASSIFIERS[task] = MLPProberBase(d=768, layer=MERT_BEST_LAYER_IDX[task], num_outputs=num_class)
	CLASSIFIERS[task].load_state_dict(torch.load(f'{head_dir}/{task}.ckpt')['state_dict'])
	CLASSIFIERS[task].to(device)

	model.to(device)


	def model_infernce(inputs):
	waveform, sample_rate = torchaudio.load(inputs)

	resample_rate = processor.sampling_rate

	# make sure the sample_rate aligned
	if resample_rate != sample_rate:
	# print(f'setting rate from {sample_rate} to {resample_rate}')
	resampler = T.Resample(sample_rate, resample_rate)
	waveform = resampler(waveform)

	waveform = waveform.view(-1,) # make it (n_sample, )
	model_inputs = processor(waveform, sampling_rate=resample_rate, return_tensors="pt")
	model_inputs.to(device)
	with torch.no_grad():
	model_outputs = model(**model_inputs, output_hidden_states=True)

	# take a look at the output shape, there are 13 layers of representation
	# each layer performs differently in different downstream tasks, you should choose empirically
	all_layer_hidden_states = torch.stack(model_outputs.hidden_states).squeeze()[1:,:,:].unsqueeze(0)
	print(all_layer_hidden_states.shape) # [13 layer, Time steps, 768 feature_dim]
	all_layer_hidden_states = all_layer_hidden_states.mean(dim=2)

	task_output_texts = ""
	df = pd.DataFrame(columns=['Task', 'Top 1', 'Top 2', 'Top 3', 'Top 4', 'Top 5'])
	df_objects = []

	for task in TASKS:
	num_class = len(ID2CLASS[task].keys())
	if MERT_BEST_LAYER_IDX[task] == 'all':
	logits = CLASSIFIERS[task](all_layer_hidden_states) # [1, 87]
	else:
	logits = CLASSIFIERS[task](all_layer_hidden_states[:, MERT_BEST_LAYER_IDX[task]])
	# print(f'task {task} logits:', logits.shape, 'num class:', num_class)

	sorted_idx = torch.argsort(logits, dim = -1, descending=True)[0] # batch =1
	sorted_prob,_ = torch.sort(nn.functional.softmax(logits[0], dim=-1), dim=-1, descending=True)
	# print(sorted_prob)
	# print(sorted_prob.shape)

	top_n_show = 5 if num_class >= 5 else num_class
	# task_output_texts = task_output_texts + f"TASK {task} output:\n" + "\n".join([str(ID2CLASS[task][str(sorted_idx[idx].item())])+f', probability: {sorted_prob[idx].item():.2%}' for idx in range(top_n_show)]) + '\n'
	# task_output_texts = task_output_texts + '----------------------\n'

	row_elements = [task]
	for idx in range(top_n_show):
	print(ID2CLASS[task])
	# print('id', str(sorted_idx[idx].item()))
	output_class_name = str(ID2CLASS[task][str(sorted_idx[idx].item())])
	output_class_name = re.sub(r'^\w+---', '', output_class_name)
	output_class_name = re.sub(r'^\w+\/\w+---', '', output_class_name)
	# print('output name', output_class_name)
	output_prob = f' {sorted_prob[idx].item():.2%}'
	row_elements.append(output_class_name+output_prob)
	# fill empty elment
	for _ in range(5+1 - len(row_elements)):
	row_elements.append(' ')
	df_objects.append(row_elements)
	df = pd.DataFrame(df_objects, columns=['Task', 'Top 1', 'Top 2', 'Top 3', 'Top 4', 'Top 5'])
	return df

	def convert_audio(inputs, microphone):
	if (microphone is not None):
	inputs = microphone
	df = model_infernce(inputs)
	return df

	def live_convert_audio(microphone):
	if (microphone is not None):
	inputs = microphone
	df = model_infernce(inputs)
	return df

	audio_chunked = gr.Interface(
	fn=convert_audio,
	inputs=inputs,
	outputs=outputs,
	allow_flagging="never",
	title=title,
	description=description,
	article=article,
	examples=audio_examples,
	)

	live_audio_chunked = gr.Interface(
	fn=live_convert_audio,
	inputs=live_inputs,
	outputs=outputs_live,
	allow_flagging="never",
	title=title,
	description=description,
	article=article,
	# examples=audio_examples,
	live=True,
	)


	demo = gr.Blocks()
	with demo:
	gr.TabbedInterface(
	[
	audio_chunked,
	live_audio_chunked,
	],
	[
	"Audio File or Recording",
	"Live Streaming Music"
	]
	)
	# demo.queue(concurrency_count=1, max_size=5)
	demo.launch(show_api=False)