train_model.py aktualisiert

train_model.py

@@ -1,3 +1,4 @@
+# train_model_v3.0.py (final)
 import pandas as pd
 import numpy as np
 import re
@@ -10,7 +11,7 @@ from thefuzz import fuzz
 from collections import Counter
 import logging
 import sys
-
+import os
 from google_sheet_handler import GoogleSheetHandler
 from helpers import normalize_company_name
 
@@ -25,91 +26,93 @@ CRM_PREDICTION_FILE = 'crm_for_prediction.pkl'
 BEST_MATCH_COL = 'Best Match Option'
 SUGGESTION_COLS = ['V2_Match_Suggestion', 'V3_Match_Suggestion', 'V4_Match_Suggestion']
 
-STOP_TOKENS_BASE = {
-    'gmbh','mbh','ag','kg','ug','ohg','se','co','kgaa','inc','llc','ltd','sarl', 'b.v', 'bv',
-    'holding','gruppe','group','international','solutions','solution','service','services',
-}
-CITY_TOKENS = set()
-
+# ... (Alle Hilfsfunktionen bleiben identisch zu Version 2.4/2.5) ...
 def _tokenize(s: str):
     if not s: return []
     return re.split(r"[^a-z0-9äöüß]+", str(s).lower())
-
 def clean_name_for_scoring(norm_name: str):
+    STOP_TOKENS_BASE = {'gmbh','mbh','ag','kg','ug','ohg','se','co','kgaa','inc','llc','ltd','sarl', 'b.v', 'bv','holding','gruppe','group','international','solutions','solution','service','services'}
+    CITY_TOKENS = set()
     if not norm_name: return "", set()
     tokens = [t for t in _tokenize(norm_name) if len(t) >= 3]
     stop_union = STOP_TOKENS_BASE | CITY_TOKENS
     final_tokens = [t for t in tokens if t not in stop_union]
     return " ".join(final_tokens), set(final_tokens)
-
 def choose_rarest_token(norm_name: str, term_weights: dict):
     _, toks = clean_name_for_scoring(norm_name)
     if not toks: return None
     return max(toks, key=lambda t: term_weights.get(t, 0))
-
 def create_features(mrec: dict, crec: dict, term_weights: dict):
     features = {}
     n1_raw = mrec.get('normalized_CRM Name', '')
     n2_raw = crec.get('normalized_name', '')
     clean1, toks1 = clean_name_for_scoring(n1_raw)
     clean2, toks2 = clean_name_for_scoring(n2_raw)
-
     features['fuzz_ratio'] = fuzz.ratio(n1_raw, n2_raw)
     features['fuzz_partial_ratio'] = fuzz.partial_ratio(n1_raw, n2_raw)
     features['fuzz_token_set_ratio'] = fuzz.token_set_ratio(clean1, clean2)
     features['fuzz_token_sort_ratio'] = fuzz.token_sort_ratio(clean1, clean2)
-    
     domain1_raw = str(mrec.get('CRM Website', '')).lower()
     domain2_raw = str(crec.get('CRM Website', '')).lower()
     domain1 = domain1_raw.replace('www.', '').split('/')[0].strip()
     domain2 = domain2_raw.replace('www.', '').split('/')[0].strip()
     features['domain_match'] = 1 if domain1 and domain1 == domain2 else 0
-    
     features['city_match'] = 1 if mrec.get('CRM Ort') and crec.get('CRM Ort') and mrec['CRM Ort'] == crec['CRM Ort'] else 0
     features['country_match'] = 1 if mrec.get('CRM Land') and crec.get('CRM Land') and mrec['CRM Land'] == crec['CRM Land'] else 0
     features['country_mismatch'] = 1 if (mrec.get('CRM Land') and crec.get('CRM Land') and mrec['CRM Land'] != crec['CRM Land']) else 0
-    
     overlapping_tokens = toks1 & toks2
     rarest_token_mrec = choose_rarest_token(n1_raw, term_weights)
-    
     features['rarest_token_overlap'] = 1 if rarest_token_mrec and rarest_token_mrec in toks2 else 0
     features['weighted_token_score'] = sum(term_weights.get(t, 0) for t in overlapping_tokens)
     features['jaccard_similarity'] = len(overlapping_tokens) / len(toks1 | toks2) if len(toks1 | toks2) > 0 else 0
-    
     features['name_len_diff'] = abs(len(n1_raw) - len(n2_raw))
     features['candidate_is_shorter'] = 1 if len(n2_raw) < len(n1_raw) else 0
-
     return features
 
 if __name__ == "__main__":
-    # ... (der gesamte Trainingsprozess bis zum Speichern) ...
+    log.info("Starte Trainingsprozess (v3.0 final)")
+    try:
+        gold_df = pd.read_csv(GOLD_STANDARD_FILE, sep=';', encoding='utf-8')
+        sheet_handler = GoogleSheetHandler()
+        crm_df = sheet_handler.get_sheet_as_dataframe(CRM_SHEET_NAME)
+    except Exception as e:
+        log.critical(f"Fehler beim Laden der Daten: {e}")
+        sys.exit(1)
+
+    crm_df.drop_duplicates(subset=['CRM Name'], keep='first', inplace=True)
+    crm_df['normalized_name'] = crm_df['CRM Name'].astype(str).apply(normalize_company_name)
+    gold_df['normalized_CRM Name'] = gold_df['CRM Name'].astype(str).apply(normalize_company_name)
+    term_weights = {token: math.log(len(crm_df) / (count + 1)) for token, count in Counter(t for n in crm_df['normalized_name'] for t in set(clean_name_for_scoring(n)[1])).items()}
+    
+    features_list, labels = [], []
+    crm_lookup = crm_df.set_index('CRM Name').to_dict('index')
+    suggestion_cols_found = [col for col in gold_df.columns if col in SUGGESTION_COLS]
+
+    for _, row in gold_df.iterrows():
+        mrec = row.to_dict()
+        best_match_name = row.get(BEST_MATCH_COL)
+        if pd.notna(best_match_name) and str(best_match_name).strip() != '' and best_match_name in crm_lookup:
+            features_list.append(create_features(mrec, crm_lookup[best_match_name], term_weights))
+            labels.append(1)
+        for col_name in suggestion_cols_found:
+            suggestion_name = row.get(col_name)
+            if pd.notna(suggestion_name) and suggestion_name != best_match_name and suggestion_name in crm_lookup:
+                features_list.append(create_features(mrec, crm_lookup[suggestion_name], term_weights))
+                labels.append(0)
+
+    X, y = pd.DataFrame(features_list), np.array(labels)
+    log.info(f"Trainingsdatensatz erstellt mit {X.shape[0]} Beispielen. Klassenverteilung: {Counter(y)}")
+    
+    X_train, X_test, y_train, y_test = train_test_split(X, y, test_size=0.2, random_state=42, stratify=y)
+    scale_pos_weight = sum(y_train == 0) / sum(y_train) if sum(y_train) > 0 else 1
+    model = xgb.XGBClassifier(use_label_encoder=False, eval_metric='logloss', scale_pos_weight=scale_pos_weight)
+    model.fit(X_train, y_train)
     log.info("Modell erfolgreich trainiert.")
     
     y_pred = model.predict(X_test)
     log.info(f"\n--- Validierungsergebnis ---\nGenauigkeit: {accuracy_score(y_test, y_pred):.2%}\n" + classification_report(y_test, y_pred, zero_division=0))
     
-    try:
     model.save_model(MODEL_OUTPUT_FILE)
-        log.info(f"Modell in '{MODEL_OUTPUT_FILE}' gespeichert.")
-        
-        # <<< KORREKTUR: Wir exportieren jetzt in das korrekte Format (.so für Linux) >>>
-        TREELITE_MODEL_SO_FILE = 'xgb_model.so'
-        treelite_model = treelite.Model.from_xgboost(model.get_booster())
-        
-        # Dieser Befehl kompiliert das Modell in eine native Bibliothek
-        treelite_model.export_lib(
-            toolchain='gcc', 
-            libpath=TREELITE_MODEL_SO_FILE, 
-            params={'parallel_comp': 4}, # Anzahl der CPU-Kerne nutzen
-            verbose=True
-        )
-        log.info(f"Kompiliertes Modell in '{TREELITE_MODEL_SO_FILE}' gespeichert.")
-        
     joblib.dump(term_weights, TERM_WEIGHTS_OUTPUT_FILE)
-        log.info(f"Wortgewichte in '{TERM_WEIGHTS_OUTPUT_FILE}' gespeichert.")
     crm_df.to_pickle(CRM_PREDICTION_FILE)
-        log.info(f"CRM-Daten in '{CRM_PREDICTION_FILE}' gespeichert.")
-        log.info("Alle Dateien wurden erfolgreich erstellt.")
-        
-    except Exception as e:
-        log.critical(f"FEHLER BEIM SPEICHERN DER DATEIEN: {e}")
+    log.info("Alle 3 Modelldateien erfolgreich erstellt.")