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copyright_checker / predictors.py

minko186

refactoring

45d10c4 11 months ago

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	import requests
	import httpx
	import torch
	import re
	from bs4 import BeautifulSoup
	import numpy as np
	from transformers import AutoTokenizer, AutoModelForSequenceClassification
	import asyncio
	from evaluate import load
	from datetime import date
	import nltk
	from transformers import GPT2LMHeadModel, GPT2TokenizerFast
	import plotly.graph_objects as go
	import torch.nn.functional as F
	import nltk
	from unidecode import unidecode
	import time
	from scipy.special import softmax
	import yaml
	import os
	from utils import *
	from dotenv import load_dotenv

	with open("config.yaml", "r") as file:
	params = yaml.safe_load(file)
	nltk.download("punkt")
	nltk.download("stopwords")
	load_dotenv()
	device = "cuda" if torch.cuda.is_available() else "cpu"
	text_bc_model_path = params["TEXT_BC_MODEL_PATH"]
	text_mc_model_path = params["TEXT_MC_MODEL_PATH"]
	text_quillbot_model_path = params["TEXT_QUILLBOT_MODEL_PATH"]
	quillbot_labels = params["QUILLBOT_LABELS"]
	mc_label_map = params["MC_OUTPUT_LABELS"]
	mc_token_size = int(params["MC_TOKEN_SIZE"])
	bc_token_size = int(params["BC_TOKEN_SIZE"])
	text_bc_tokenizer = AutoTokenizer.from_pretrained(text_bc_model_path)
	text_bc_model = AutoModelForSequenceClassification.from_pretrained(
	text_bc_model_path
	).to(device)
	text_mc_tokenizer = AutoTokenizer.from_pretrained(text_mc_model_path)
	text_mc_model = AutoModelForSequenceClassification.from_pretrained(
	text_mc_model_path
	).to(device)
	quillbot_tokenizer = AutoTokenizer.from_pretrained(text_quillbot_model_path)
	quillbot_model = AutoModelForSequenceClassification.from_pretrained(
	text_quillbot_model_path
	).to(device)


	def split_text_allow_complete_sentences_nltk(
	text,
	max_length=256,
	tolerance=30,
	min_last_segment_length=100,
	type_det="bc",
	):
	sentences = nltk.sent_tokenize(text)
	segments = []
	current_segment = []
	current_length = 0
	if type_det == "bc":
	tokenizer = text_bc_tokenizer
	max_length = bc_token_size
	elif type_det == "mc":
	tokenizer = text_mc_tokenizer
	max_length = mc_token_size
	for sentence in sentences:
	tokens = tokenizer.tokenize(sentence)
	sentence_length = len(tokens)

	if current_length + sentence_length <= max_length + tolerance - 2:
	current_segment.append(sentence)
	current_length += sentence_length
	else:
	if current_segment:
	encoded_segment = tokenizer.encode(
	" ".join(current_segment),
	add_special_tokens=True,
	max_length=max_length + tolerance,
	truncation=True,
	)
	segments.append((current_segment, len(encoded_segment)))
	current_segment = [sentence]
	current_length = sentence_length

	if current_segment:
	encoded_segment = tokenizer.encode(
	" ".join(current_segment),
	add_special_tokens=True,
	max_length=max_length + tolerance,
	truncation=True,
	)
	segments.append((current_segment, len(encoded_segment)))

	final_segments = []
	for i, (seg, length) in enumerate(segments):
	if i == len(segments) - 1:
	if length < min_last_segment_length and len(final_segments) > 0:
	prev_seg, prev_length = final_segments[-1]
	combined_encoded = tokenizer.encode(
	" ".join(prev_seg + seg),
	add_special_tokens=True,
	max_length=max_length + tolerance,
	truncation=True,
	)
	if len(combined_encoded) <= max_length + tolerance:
	final_segments[-1] = (prev_seg + seg, len(combined_encoded))
	else:
	final_segments.append((seg, length))
	else:
	final_segments.append((seg, length))
	else:
	final_segments.append((seg, length))

	decoded_segments = []
	encoded_segments = []
	for seg, _ in final_segments:
	encoded_segment = tokenizer.encode(
	" ".join(seg),
	add_special_tokens=True,
	max_length=max_length + tolerance,
	truncation=True,
	)
	decoded_segment = tokenizer.decode(encoded_segment)
	decoded_segments.append(decoded_segment)
	return decoded_segments


	def predict_quillbot(text):
	with torch.no_grad():
	quillbot_model.eval()
	tokenized_text = quillbot_tokenizer(
	text,
	padding="max_length",
	truncation=True,
	max_length=256,
	return_tensors="pt",
	).to(device)
	output = quillbot_model(**tokenized_text)
	output_norm = softmax(output.logits.detach().cpu().numpy(), 1)[0]
	q_score = {
	"Humanized": output_norm[1].item(),
	"Original": output_norm[0].item(),
	}
	return q_score


	def predict_bc(model, tokenizer, text):
	with torch.no_grad():
	model.eval()
	tokens = text_bc_tokenizer(
	text,
	padding="max_length",
	truncation=True,
	max_length=bc_token_size,
	return_tensors="pt",
	).to(device)
	output = model(**tokens)
	output_norm = softmax(output.logits.detach().cpu().numpy(), 1)[0]
	return output_norm


	def predict_mc(model, tokenizer, text):
	with torch.no_grad():
	model.eval()
	tokens = text_mc_tokenizer(
	text,
	padding="max_length",
	truncation=True,
	return_tensors="pt",
	max_length=mc_token_size,
	).to(device)
	output = model(**tokens)
	output_norm = softmax(output.logits.detach().cpu().numpy(), 1)[0]
	return output_norm


	def predict_mc_scores(input):
	bc_scores = []
	mc_scores = []

	samples_len_bc = len(
	split_text_allow_complete_sentences_nltk(input, type_det="bc")
	)
	segments_bc = split_text_allow_complete_sentences_nltk(input, type_det="bc")
	for i in range(samples_len_bc):
	cleaned_text_bc = remove_special_characters(segments_bc[i])
	bc_score = predict_bc(text_bc_model, text_bc_tokenizer, cleaned_text_bc)
	bc_scores.append(bc_score)
	bc_scores_array = np.array(bc_scores)
	average_bc_scores = np.mean(bc_scores_array, axis=0)
	bc_score_list = average_bc_scores.tolist()
	bc_score = {"AI": bc_score_list[1], "HUMAN": bc_score_list[0]}
	segments_mc = split_text_allow_complete_sentences_nltk(input, type_det="mc")
	samples_len_mc = len(
	split_text_allow_complete_sentences_nltk(input, type_det="mc")
	)
	for i in range(samples_len_mc):
	cleaned_text_mc = remove_special_characters(segments_mc[i])
	mc_score = predict_mc(text_mc_model, text_mc_tokenizer, cleaned_text_mc)
	mc_scores.append(mc_score)
	mc_scores_array = np.array(mc_scores)
	average_mc_scores = np.mean(mc_scores_array, axis=0)
	mc_score_list = average_mc_scores.tolist()
	mc_score = {}
	for score, label in zip(mc_score_list, mc_label_map):
	mc_score[label.upper()] = score

	sum_prob = 1 - bc_score["HUMAN"]
	for key, value in mc_score.items():
	mc_score[key] = value * sum_prob
	if sum_prob < 0.01:
	mc_score = {}

	return mc_score


	def predict_bc_scores(input):
	bc_scores = []
	mc_scores = []
	samples_len_bc = len(
	split_text_allow_complete_sentences_nltk(input, type_det="bc")
	)
	segments_bc = split_text_allow_complete_sentences_nltk(input, type_det="bc")
	for i in range(samples_len_bc):
	cleaned_text_bc = remove_special_characters(segments_bc[i])
	bc_score = predict_bc(text_bc_model, text_bc_tokenizer, cleaned_text_bc)
	bc_scores.append(bc_score)
	bc_scores_array = np.array(bc_scores)
	average_bc_scores = np.mean(bc_scores_array, axis=0)
	bc_score_list = average_bc_scores.tolist()
	bc_score = {"AI": bc_score_list[1], "HUMAN": bc_score_list[0]}
	return bc_score


	# def predict_1on1(input):
	# models = ['bard', 'claude', 'gpt4', 'mistral_ai', 'llama2']
	# text = str(row["text"])
	# predictions = {}
	# prediction = predict(text, bard_model, bard_tokenizer) predictions['bard'] = prediction[1]
	# prediction = predict(text, claude_model, claude_tokenizer) predictions['claude'] = prediction[1]
	# prediction = predict(text, gpt4_model, gpt4_tokenizer) predictions['gpt4'] = prediction[1]
	# prediction = predict(text, mistral_ai_model, mistral_ai_tokenizer) predictions['mistral_ai'] = prediction[1]
	# prediction = predict(text, llama2_model, llama2_tokenizer) predictions['llama2'] = prediction[1]
	# max_key = max(predictions, key=predictions.get)