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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 * | |
import joblib | |
with open("config.yaml", "r") as file: | |
params = yaml.safe_load(file) | |
nltk.download("punkt") | |
nltk.download("stopwords") | |
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"] | |
text_1on1_models = params["TEXT_1ON1_MODEL"] | |
quillbot_labels = params["QUILLBOT_LABELS"] | |
mc_label_map = params["MC_OUTPUT_LABELS"] | |
text_1on1_label_map = params["1ON1_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) | |
tokenizers_1on1 = {} | |
models_1on1 = {} | |
for model_name, model in zip(mc_label_map, text_1on1_models): | |
tokenizers_1on1[model_name] = AutoTokenizer.from_pretrained(model) | |
models_1on1[model_name] = AutoModelForSequenceClassification.from_pretrained( | |
model | |
).to(device) | |
# proxy models for explainability | |
mini_bc_model_name = "polygraf-ai/bc-model-bert-mini" | |
bc_tokenizer_mini = AutoTokenizer.from_pretrained(mini_bc_model_name) | |
bc_model_mini = AutoModelForSequenceClassification.from_pretrained( | |
mini_bc_model_name | |
).to(device) | |
mini_humanizer_model_name = "polygraf-ai/quillbot-detector-bert-mini-9K" | |
humanizer_tokenizer_mini = AutoTokenizer.from_pretrained(mini_humanizer_model_name) | |
humanizer_model_mini = AutoModelForSequenceClassification.from_pretrained( | |
mini_humanizer_model_name | |
).to(device) | |
# model score calibration | |
iso_reg = joblib.load("isotonic_regression_model.joblib") | |
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_for_explainanility(text, model_type=None): | |
if model_type == "quillbot": | |
cleaning = False | |
max_length = 256 | |
model = humanizer_model_mini | |
tokenizer = humanizer_tokenizer_mini | |
elif model_type == "bc": | |
cleaning = True | |
max_length = 512 | |
model = bc_model_mini | |
tokenizer = bc_tokenizer_mini | |
else: | |
raise ValueError("Invalid model type") | |
with torch.no_grad(): | |
if cleaning: | |
text = [remove_special_characters(t) for t in text] | |
tokenized_text = tokenizer( | |
text, | |
return_tensors="pt", | |
padding="max_length", | |
truncation=True, | |
max_length=max_length, | |
).to(device) | |
outputs = model(**tokenized_text) | |
tensor_logits = outputs[0] | |
probas = F.softmax(tensor_logits).detach().cpu().numpy() | |
return probas | |
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 = [] | |
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() | |
print(f"Original BC scores: AI: {bc_score_list[1]}, HUMAN: {bc_score_list[0]}") | |
# isotonic regression calibration | |
ai_score = iso_reg.predict([bc_score_list[1]])[0] | |
human_score = 1 - ai_score | |
bc_score = {"AI": ai_score, "HUMAN": human_score} | |
print(f"Calibration BC scores: AI: {ai_score}, HUMAN: {human_score}") | |
return bc_score | |
def predict_1on1(model, tokenizer, text): | |
with torch.no_grad(): | |
model.eval() | |
tokens = 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_1on1_combined(input): | |
predictions = [] | |
for i, model in enumerate(text_1on1_models): | |
predictions.append( | |
predict_1on1(models_1on1[model], tokenizers_1on1[model], input)[1] | |
) | |
return predictions | |
def predict_1on1_single(input, model): | |
predictions = predict_1on1(models_1on1[model], tokenizers_1on1[model], input)[1] | |
return predictions | |
def predict_1on1_scores(input, models): | |
if len(models) == 0: | |
return {} | |
print(f"Models to Test: {models}") | |
# BC SCORE | |
bc_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]} | |
# MC SCORE | |
if len(models) > 1: | |
print("Starting MC") | |
mc_scores = [] | |
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 | |
mc_score = { | |
key: mc_score[key.upper()] for key in models if key.upper() in mc_score | |
} | |
total = sum(mc_score.values()) | |
# Normalize each value by dividing it by the total | |
mc_score = {key: value / total for key, value in mc_score.items()} | |
sum_prob = 1 - bc_score["HUMAN"] | |
for key, value in mc_score.items(): | |
mc_score[key] = value * sum_prob | |
print('MC Score:',mc_score) | |
if sum_prob < 0.01: | |
mc_score = {} | |
elif len(models) == 1: | |
print("Starting 1on1") | |
mc_scores = [] | |
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_1on1_single(cleaned_text_mc, models[0]) | |
mc_scores.append(mc_score) | |
mc_scores_array = np.array(mc_scores) | |
average_mc_scores = np.mean(mc_scores_array, axis=0) | |
print(average_mc_scores) | |
mc_score_list = average_mc_scores.tolist() | |
mc_score = {} | |
mc_score[models[0].upper()] = mc_score_list | |
mc_score["OTHER"] = 1 - mc_score_list | |
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 | |