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import requests | |
from bs4 import BeautifulSoup | |
import pandas as pd | |
import torch | |
from transformers import pipeline | |
from sentence_transformers import SentenceTransformer, util | |
import concurrent.futures | |
import time | |
import sys | |
from sklearn.feature_extraction.text import TfidfVectorizer | |
from sklearn.metrics.pairwise import cosine_similarity | |
from transformers import AutoTokenizer, AutoModel | |
import numpy as np | |
from scipy import stats | |
from PyDictionary import PyDictionary | |
import matplotlib.pyplot as plt | |
from scipy import stats | |
import litellm | |
import re | |
import sentencepiece | |
import random | |
def score_with_llm(title, topic, llm_model): | |
prompt = f"""Evaluate the relevance of the following article to the topic '{topic}'. | |
Article title: {title} | |
Give a final relevance score between 0 and 1, where 1 is very relevant and 0 is not relevant at all. | |
Respond only with a number between 0 and 1.""" | |
try: | |
response = litellm.completion( | |
model=llm_model, | |
messages=[{"role": "user", "content": prompt}], | |
max_tokens=10 | |
) | |
score_match = re.search(r'\d+(\.\d+)?', response.choices[0].message.content.strip()) | |
if score_match: | |
score = float(score_match.group()) | |
print(f"Score LLM : {score}") | |
return max(0, min(score, 1)) | |
else: | |
print(f"Could not extract a score from LLM response: {response.choices[0].message.content}") | |
return None | |
except Exception as e: | |
print(f"Error in scoring with LLM {llm_model}: {str(e)}") | |
return None | |
def expand_keywords_llm(keyword, max_synonyms=3, llm_model="ollama/qwen2"): | |
prompt = f"""Please provide up to {max_synonyms} synonyms or closely related terms for the word or phrase: "{keyword}". | |
Return only the list of synonyms, separated by commas, without any additional explanation.""" | |
try: | |
response = litellm.completion( | |
model=llm_model, | |
messages=[{"role": "user", "content": prompt}], | |
max_tokens=50 | |
) | |
synonyms = [s.strip() for s in response.choices[0].message.content.split(',')] | |
return [keyword] + synonyms[:max_synonyms] | |
except Exception as e: | |
print(f"Error in expanding keywords with LLM {llm_model}: {str(e)}") | |
return [keyword] | |
# Fonction pour obtenir les liens de la page d'accueil | |
def get_homepage_links(url): | |
response = requests.get(url) | |
soup = BeautifulSoup(response.text, 'html.parser') | |
links = soup.find_all('a', href=True) | |
return [(link.text.strip(), link['href']) for link in links if link.text.strip()] | |
# Fonction pour obtenir le contenu d'un article | |
def get_article_content(url): | |
try: | |
print(f"Récupération du contenu de : {url}") | |
response = requests.get(url) | |
print(f"Taille de la réponse HTTP : {len(response.content)} octets") # Affiche le nombre d'octets de la réponse HTTP | |
soup = BeautifulSoup(response.text, 'html.parser') | |
print(f"Taille de l'objet soup : {sys.getsizeof(soup)} octets") # Affiche la taille en mémoire de l'objet soup | |
article = soup.find('article') | |
if article: | |
paragraphs = article.find_all('p') | |
content = ' '.join([p.text for p in paragraphs]) | |
print(f"Paragraphes récupéré : {len(content)} caractères") | |
return content | |
print("Aucun contenu d'article trouvé") | |
return "" | |
except Exception as e: | |
print(f"Erreur lors de la récupération du contenu : {str(e)}") | |
return "" | |
# Fonction pour l'analyse zero-shot | |
def zero_shot_analysis(text, topic, classifier): | |
if not text: | |
print("Texte vide pour l'analyse zero-shot") | |
return 0.0 | |
result = classifier(text, candidate_labels=[topic, f"not {topic}"], multi_label=False) | |
print(f"Score zero-shot : {result['scores'][0]}") | |
return result['scores'][0] | |
# Fonction pour l'analyse par embeddings | |
def embedding_analysis(text, topic_embedding, model): | |
if not text: | |
print("Texte vide pour l'analyse par embeddings") | |
return 0.0 | |
text_embedding = model.encode([text], convert_to_tensor=True) | |
similarity = util.pytorch_cos_sim(text_embedding, topic_embedding).item() | |
print(f"Score embedding : {similarity}") | |
return similarity | |
from sklearn.feature_extraction.text import TfidfVectorizer | |
from sklearn.metrics.pairwise import cosine_similarity | |
#import nltk | |
#from nltk.corpus import wordnet | |
#nltk.download('wordnet') | |
def preprocess_text(text): | |
# Tokenize the text | |
tokens = text.lower().split() | |
# Expand each token with its synonyms | |
expanded_tokens = [] | |
for token in tokens: | |
synonyms = set() | |
for syn in wordnet.synsets(token): | |
for lemma in syn.lemmas(): | |
synonyms.add(lemma.name()) | |
expanded_tokens.extend(list(synonyms)) | |
return ' '.join(expanded_tokens) | |
def improved_tfidf_similarity(texts, query): | |
# Preprocess texts and query | |
preprocessed_texts = [preprocess_text(text) for text in texts] | |
preprocessed_query = preprocess_text(query) | |
# Combine texts and query for vectorization | |
all_texts = preprocessed_texts + [preprocessed_query] | |
# Use TfidfVectorizer with custom parameters | |
vectorizer = TfidfVectorizer(ngram_range=(1, 2), min_df=1, smooth_idf=True) | |
tfidf_matrix = vectorizer.fit_transform(all_texts) | |
# Calculate cosine similarity | |
cosine_similarities = cosine_similarity(tfidf_matrix[-1], tfidf_matrix[:-1]).flatten() | |
# Normalize similarities to avoid zero scores | |
normalized_similarities = (cosine_similarities - cosine_similarities.min()) / (cosine_similarities.max() - cosine_similarities.min()) | |
return normalized_similarities | |
from sklearn.feature_extraction.text import TfidfVectorizer | |
from sklearn.metrics.pairwise import cosine_similarity | |
import numpy as np | |
def improved_tfidf_similarity_v2(texts, query): | |
# Combine texts and query, treating each word or phrase as a separate document | |
all_docs = [word.strip() for text in texts for word in text.split(',')] + [word.strip() for word in query.split(',')] | |
# Create TF-IDF matrix | |
vectorizer = TfidfVectorizer() | |
tfidf_matrix = vectorizer.fit_transform(all_docs) | |
# Calculate document vectors by summing the TF-IDF vectors of their words | |
doc_vectors = [] | |
query_vector = np.zeros((1, tfidf_matrix.shape[1])) | |
current_doc = 0 | |
for i, doc in enumerate(all_docs): | |
if i < len(all_docs) - len(query.split(',')): # If it's part of the texts | |
if current_doc == len(texts): | |
break | |
if doc in texts[current_doc]: | |
doc_vectors.append(tfidf_matrix[i].toarray()) | |
else: | |
current_doc += 1 | |
doc_vectors.append(tfidf_matrix[i].toarray()) | |
else: # If it's part of the query | |
query_vector += tfidf_matrix[i].toarray() | |
doc_vectors = np.array([np.sum(doc, axis=0) for doc in doc_vectors]) | |
# Calculate cosine similarity | |
similarities = cosine_similarity(query_vector, doc_vectors).flatten() | |
# Normalize similarities to avoid zero scores | |
normalized_similarities = (similarities - similarities.min()) / (similarities.max() - similarities.min() + 1e-8) | |
return normalized_similarities | |
# Example usage: | |
# texts = ["longevity, health, aging", "computer science, AI"] | |
# query = "longevity, life extension, anti-aging" | |
# results = improved_tfidf_similarity_v2(texts, query) | |
# print(results) | |
# Nouvelles fonctions | |
def tfidf_similarity(texts, query): | |
vectorizer = TfidfVectorizer() | |
tfidf_matrix = vectorizer.fit_transform(texts + [query]) | |
cosine_similarities = cosine_similarity(tfidf_matrix[-1], tfidf_matrix[:-1]).flatten() | |
return cosine_similarities | |
def bert_similarity(texts, query, model_name='bert-base-uncased'): | |
tokenizer = AutoTokenizer.from_pretrained(model_name) | |
model = AutoModel.from_pretrained(model_name) | |
def get_embedding(text): | |
inputs = tokenizer(text, return_tensors='pt', truncation=True, padding=True, max_length=512) | |
with torch.no_grad(): | |
outputs = model(**inputs) | |
return outputs.last_hidden_state.mean(dim=1).squeeze().numpy() | |
query_embedding = get_embedding(query) | |
text_embeddings = [get_embedding(text) for text in texts] | |
similarities = [cosine_similarity([query_embedding], [text_embedding])[0][0] for text_embedding in text_embeddings] | |
return similarities | |
# Fonction principale d'analyse modifiée | |
def analyze_link(title, link, topic, zero_shot_classifiers, embedding_models, expanded_query, llm_models, testcontent): | |
print(f"\nAnalyse de : {title}") | |
results = { | |
"Titre": title, | |
#"TF-IDF (titre)": improved_tfidf_similarity_v2([title], expanded_query)[0], | |
#"BERT (titre)": bert_similarity([title], expanded_query)[0], | |
} | |
# Zero-shot analysis | |
for name, classifier in zero_shot_classifiers.items(): | |
results[f"Zero-shot (titre) - {name}"] = zero_shot_analysis(title, topic, classifier) | |
# Embedding analysis | |
for name, model in embedding_models.items(): | |
topic_embedding = model.encode([expanded_query], convert_to_tensor=True) | |
results[f"Embeddings (titre) - {name}"] = embedding_analysis(title, topic_embedding, model) | |
# LLM analysis | |
for model in llm_models: | |
results[f"LLM Score - {model}"] = score_with_llm(title, topic, model) | |
if testcontent: | |
content = get_article_content(link) | |
#results["TF-IDF (contenu)"] = improved_tfidf_similarity_v2([content], expanded_query)[0] | |
#results["BERT (contenu)"]= bert_similarity([content], expanded_query)[0] | |
# Zero-shot analysis | |
for name, classifier in zero_shot_classifiers.items(): | |
results[f"Zero-shot (contenu) - {name}"] = zero_shot_analysis(content, topic, classifier) | |
# Embedding analysis | |
for name, model in embedding_models.items(): | |
topic_embedding = model.encode([expanded_query], convert_to_tensor=True) | |
results[f"Embeddings (contenu) - {name}"] = embedding_analysis(content, topic_embedding, model) | |
# LLM analysis | |
for model in llm_models: | |
results[f"LLM Content Score - {model}"] = score_with_llm(content, topic, model) | |
return results | |
from scipy import stats | |
def evaluate_ranking(reference_data_valid, reference_data_rejected, method_scores, threshold, silent): | |
simple_score = 0 | |
true_positives = 0 | |
false_positives = 0 | |
true_negatives = 0 | |
false_negatives = 0 | |
# Créer une liste de tous les éléments avec leur statut (1 pour valide, 0 pour rejeté) | |
all_items = [(item, 1) for item in reference_data_valid] + [(item, 0) for item in reference_data_rejected] | |
# Trier les éléments selon leur score dans la méthode | |
all_items_temp = all_items.copy() | |
# correct false positive if method spit out same score for all | |
#random.shuffle(all_items_temp) | |
all_items_temp.reverse() | |
sorted_method = sorted([(item, method_scores.get(item, 0)) for item, _ in all_items_temp], | |
key=lambda x: x[1], reverse=True) | |
# Créer des listes pour le calcul de la corrélation de Spearman | |
reference_ranks = [] | |
method_ranks = [] | |
for i, (item, status) in enumerate(all_items): | |
method_score = method_scores.get(item, 0) | |
method_rank = next(j for j, (it, score) in enumerate(sorted_method) if it == item) | |
reference_ranks.append(i) | |
method_ranks.append(method_rank) | |
if status == 1: # Item valide | |
if method_score >= threshold: | |
simple_score += 1 | |
true_positives += 1 | |
else: | |
simple_score -= 1 | |
false_negatives += 1 | |
else: # Item rejeté | |
if method_score < threshold: | |
simple_score += 1 | |
true_negatives += 1 | |
else: | |
simple_score -= 1 | |
false_positives += 1 | |
# Calculer le coefficient de corrélation de Spearman | |
if not silent: | |
print("+++") | |
print(reference_ranks) | |
print("---") | |
print(method_ranks) | |
spearman_corr, _ = stats.spearmanr(reference_ranks, method_ranks) | |
# Calculer la précision, le rappel et le F1-score | |
precision = true_positives / (true_positives + false_positives) if (true_positives + false_positives) > 0 else 0 | |
recall = true_positives / (true_positives + false_negatives) if (true_positives + false_negatives) > 0 else 0 | |
f1_score = 2 * (precision * recall) / (precision + recall) if (precision + recall) > 0 else 0 | |
return { | |
"simple_score": simple_score, | |
"spearman_correlation": spearman_corr, | |
"precision": precision, | |
"recall": recall, | |
"f1_score": f1_score, | |
} | |
def find_optimal_threshold(reference_data_valid, reference_data_rejected, method_scores): | |
best_score = float('-inf') | |
best_threshold = 0 | |
for threshold in np.arange(0, 1.05, 0.05): | |
result = evaluate_ranking( | |
reference_data_valid, | |
reference_data_rejected, | |
method_scores, | |
threshold, True | |
) | |
if result['simple_score'] > best_score: | |
best_score = result['simple_score'] | |
best_threshold = threshold | |
return best_threshold | |
def reset_cuda_context(): | |
torch.cuda.empty_cache() | |
torch.cuda.ipc_collect() | |
if torch.cuda.is_available(): | |
torch.cuda.set_device(torch.cuda.current_device()) | |
torch.cuda.synchronize() | |
import gc | |
def clear_models(): | |
global zero_shot_classifiers, embedding_models_dict, bert_models, tfidf_objects | |
for classifier in zero_shot_classifiers.values(): | |
del classifier | |
zero_shot_classifiers.clear() | |
for model in embedding_models_dict.values(): | |
del model | |
embedding_models_dict.clear() | |
for model in bert_models: | |
del model | |
bert_models.clear() | |
for vectorizer in tfidf_objects: | |
del vectorizer | |
tfidf_objects.clear() | |
torch.cuda.empty_cache() | |
gc.collect() | |
def clear_globals(): | |
for name in list(globals()): | |
if isinstance(globals()[name], (torch.nn.Module, torch.Tensor)): | |
del globals()[name] | |
def release_vram(zero_shot_classifiers, embedding_models, bert_models, tfidf_objects): | |
# Supprimer les objets zero-shot classifiers | |
for model in zero_shot_classifiers.values(): | |
del model | |
# Supprimer les objets embedding models | |
for model in embedding_models.values(): | |
del model | |
# Supprimer les objets bert models | |
for model in bert_models: | |
del model | |
# Supprimer les objets tfidf objects | |
for obj in tfidf_objects: | |
del obj | |
# Vider le cache de la mémoire GPU | |
torch.cuda.empty_cache() | |
torch.cuda.synchronize() | |
gc.collect() | |
clear_globals() | |
reset_cuda_context() | |
def load_finetuned_model(model_path): | |
checkpoint = torch.load(model_path) | |
base_model = AutoModel.from_pretrained(checkpoint['base_model_name']) | |
model = EmbeddingModel(base_model) | |
model.load_state_dict(checkpoint['model_state_dict']) | |
return model | |