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| import json | |
| import argparse | |
| import os | |
| import random | |
| import torch | |
| import torch.nn as nn | |
| from torch.utils.data import Dataset, DataLoader, random_split | |
| from transformers import LayoutLMv3TokenizerFast, LayoutLMv3Model | |
| from TorchCRF import CRF | |
| from torch.optim import AdamW | |
| from tqdm import tqdm | |
| from sklearn.metrics import precision_recall_fscore_support | |
| import fitz # PyMuPDF | |
| import pytesseract | |
| from PIL import Image | |
| from pdf2image import convert_from_path | |
| # --- Configuration for Augmentation --- | |
| MAX_BBOX_DIMENSION = 999 | |
| MAX_SHIFT = 30 | |
| AUGMENTATION_FACTOR = 1 | |
| # ------------------------------------- | |
| # ------------------------- | |
| # Step 1: Preprocessing (Label Studio β BIO + bboxes) | |
| # ------------------------- | |
| def preprocess_labelstudio(input_path, output_path): | |
| with open(input_path, "r", encoding="utf-8") as f: | |
| data = json.load(f) | |
| processed = [] | |
| total_items = len(data) # Added for potential verbose logging | |
| print(f"π Starting preprocessing of {total_items} documents...") | |
| for item in data: | |
| words = item["data"]["original_words"] | |
| bboxes = item["data"]["original_bboxes"] | |
| labels = ["O"] * len(words) | |
| if "annotations" in item: | |
| for ann in item["annotations"]: | |
| for res in ann["result"]: | |
| # Check if the result item is a span annotation | |
| if "value" in res and "labels" in res["value"]: | |
| text = res["value"]["text"] | |
| tag = res["value"]["labels"][0] | |
| # Some tokenizers may split words, so we must find a consecutive word match. | |
| text_tokens = text.split() | |
| for i in range(len(words) - len(text_tokens) + 1): | |
| if words[i:i + len(text_tokens)] == text_tokens: | |
| labels[i] = f"B-{tag}" | |
| for j in range(1, len(text_tokens)): | |
| labels[i + j] = f"I-{tag}" | |
| break # Move to next annotation if a match is found | |
| processed.append({"tokens": words, "labels": labels, "bboxes": bboxes}) | |
| with open(output_path, "w", encoding="utf-8") as f: | |
| json.dump(processed, f, indent=2, ensure_ascii=False) | |
| print(f"β Preprocessed data saved to {output_path}") | |
| return output_path | |
| # ------------------------- | |
| # Step 1.5: Bounding Box Augmentation | |
| # ------------------------- | |
| def translate_bbox(bbox, shift_x, shift_y): | |
| """ | |
| Translates a single bounding box [x_min, y_min, x_max, y_max] by (shift_x, shift_y) | |
| and clamps the coordinates to the valid range [0, MAX_BBOX_DIMENSION]. | |
| """ | |
| x_min, y_min, x_max, y_max = bbox | |
| new_x_min = x_min + shift_x | |
| new_y_min = y_min + shift_y | |
| new_x_max = x_max + shift_x | |
| new_y_max = y_max + shift_y | |
| # Clamp the new coordinates | |
| new_x_min = max(0, min(new_x_min, MAX_BBOX_DIMENSION)) | |
| new_y_min = max(0, min(new_y_min, MAX_BBOX_DIMENSION)) | |
| new_x_max = max(0, min(new_x_max, MAX_BBOX_DIMENSION)) | |
| new_y_max = max(0, min(new_y_max, MAX_BBOX_DIMENSION)) | |
| # Safety check | |
| if new_x_min > new_x_max: new_x_min = new_x_max | |
| if new_y_min > new_y_max: new_y_min = new_y_max | |
| return [new_x_min, new_y_min, new_x_max, new_y_max] | |
| def augment_sample(sample): | |
| """ | |
| Generates a new sample by translating all bounding boxes. | |
| """ | |
| shift_x = random.randint(-MAX_SHIFT, MAX_SHIFT) | |
| shift_y = random.randint(-MAX_SHIFT, MAX_SHIFT) | |
| new_sample = sample.copy() | |
| # Ensure tokens and labels are copied (they remain unchanged) | |
| new_sample["tokens"] = sample["tokens"] | |
| new_sample["labels"] = sample["labels"] | |
| # Translate all bounding boxes | |
| new_bboxes = [translate_bbox(bbox, shift_x, shift_y) for bbox in sample["bboxes"]] | |
| new_sample["bboxes"] = new_bboxes | |
| return new_sample | |
| def augment_and_save_dataset(input_json_path, output_json_path): | |
| """ | |
| Loads preprocessed data, performs augmentation, and saves the result. | |
| """ | |
| print(f"π Loading preprocessed data from {input_json_path} for augmentation...") | |
| with open(input_json_path, 'r', encoding="utf-8") as f: | |
| training_data = json.load(f) | |
| augmented_data = [] | |
| original_count = len(training_data) | |
| print(f"π Starting augmentation (Factor: {AUGMENTATION_FACTOR}, {original_count} documents)...") | |
| for i, original_sample in enumerate(training_data): | |
| # 1. Add the original sample | |
| augmented_data.append(original_sample) | |
| # 2. Generate augmented samples | |
| for _ in range(AUGMENTATION_FACTOR): | |
| if "tokens" in original_sample and "labels" in original_sample and "bboxes" in original_sample: | |
| augmented_data.append(augment_sample(original_sample)) | |
| else: | |
| print(f"Warning: Skipping augmentation for sample {i} due to missing keys.") | |
| augmented_count = len(augmented_data) | |
| print(f"Dataset Augmentation: Original samples: {original_count}, Total samples: {augmented_count}") | |
| # Save the augmented dataset | |
| with open(output_json_path, 'w', encoding="utf-8") as f: | |
| json.dump(augmented_data, f, indent=2, ensure_ascii=False) | |
| print(f"β Augmented data saved to {output_json_path}") | |
| return output_json_path | |
| # ------------------------- | |
| # Step 2: Dataset Class (Unchanged) | |
| # ------------------------- | |
| class LayoutDataset(Dataset): | |
| def __init__(self, json_path, tokenizer, label2id, max_len=512): | |
| with open(json_path, "r", encoding="utf-8") as f: | |
| self.data = json.load(f) | |
| self.tokenizer = tokenizer | |
| self.label2id = label2id | |
| self.max_len = max_len | |
| def __len__(self): | |
| return len(self.data) | |
| def __getitem__(self, idx): | |
| item = self.data[idx] | |
| words, bboxes, labels = item["tokens"], item["bboxes"], item["labels"] | |
| # Tokenize | |
| encodings = self.tokenizer( | |
| words, | |
| boxes=bboxes, | |
| padding="max_length", | |
| truncation=True, | |
| max_length=self.max_len, | |
| return_offsets_mapping=True, | |
| return_tensors="pt" | |
| ) | |
| # Align labels to word pieces | |
| word_ids = encodings.word_ids(batch_index=0) | |
| label_ids = [] | |
| for word_id in word_ids: | |
| if word_id is None: | |
| label_ids.append(self.label2id["O"]) # [CLS], [SEP], padding | |
| else: | |
| label_ids.append(self.label2id.get(labels[word_id], self.label2id["O"])) | |
| encodings.pop("offset_mapping") | |
| encodings["labels"] = torch.tensor(label_ids) | |
| return {key: val.squeeze(0) for key, val in encodings.items()} | |
| # ------------------------- | |
| # Step 3: Model Architecture (Unchanged) | |
| # ------------------------- | |
| class LayoutLMv3CRF(nn.Module): | |
| def __init__(self, model_name, num_labels): | |
| super().__init__() | |
| self.layoutlm = LayoutLMv3Model.from_pretrained(model_name) | |
| # self.layoutlm = LayoutLMv3Model.from_pretrained("heerjtdev/edugenius") | |
| self.dropout = nn.Dropout(0.1) | |
| self.classifier = nn.Linear(self.layoutlm.config.hidden_size, num_labels) | |
| self.crf = CRF(num_labels) | |
| def forward(self, input_ids, bbox, attention_mask, labels=None): | |
| outputs = self.layoutlm(input_ids=input_ids, bbox=bbox, attention_mask=attention_mask) | |
| sequence_output = self.dropout(outputs.last_hidden_state) | |
| emissions = self.classifier(sequence_output) | |
| if labels is not None: | |
| # Training mode: calculate loss | |
| log_likelihood = self.crf(emissions, labels, mask=attention_mask.bool()) | |
| return -log_likelihood.mean() | |
| else: | |
| # Inference mode: decode best path | |
| best_paths = self.crf.viterbi_decode(emissions, mask=attention_mask.bool()) | |
| return best_paths | |
| # ------------------------- | |
| # Step 4: Training + Evaluation (Unchanged) | |
| # ------------------------- | |
| def train_one_epoch(model, dataloader, optimizer, device): | |
| model.train() | |
| total_loss = 0 | |
| for batch in tqdm(dataloader, desc="Training"): | |
| batch = {k: v.to(device) for k, v in batch.items()} | |
| labels = batch.pop("labels") | |
| optimizer.zero_grad() | |
| loss = model(**batch, labels=labels) | |
| loss.backward() | |
| optimizer.step() | |
| total_loss += loss.item() | |
| return total_loss / len(dataloader) | |
| def evaluate(model, dataloader, device, id2label): | |
| model.eval() | |
| all_preds, all_labels = [], [] | |
| with torch.no_grad(): | |
| for batch in tqdm(dataloader, desc="Evaluating"): | |
| batch = {k: v.to(device) for k, v in batch.items()} | |
| labels = batch.pop("labels").cpu().numpy() | |
| preds = model(**batch) | |
| for p, l, mask in zip(preds, labels, batch["attention_mask"].cpu().numpy()): | |
| valid = mask == 1 | |
| l = l[valid].tolist() | |
| all_labels.extend(l) | |
| all_preds.extend(p[:len(l)]) | |
| # Exclude the "O" label and other special tokens if necessary, but using 'micro' average | |
| # on all valid tokens is typically fine for the initial evaluation. | |
| precision, recall, f1, _ = precision_recall_fscore_support(all_labels, all_preds, average="micro", zero_division=0) | |
| return precision, recall, f1 | |
| # ------------------------- | |
| # Step 5: Main Pipeline (Training) - MODIFIED LABELS + FILE PATH FIX | |
| # ------------------------- | |
| def main(args): | |
| # LABELS UPDATED: Added SECTION_HEADING and PASSAGE | |
| labels = [ | |
| "O", | |
| "B-QUESTION", "I-QUESTION", | |
| "B-OPTION", "I-OPTION", | |
| "B-ANSWER", "I-ANSWER", | |
| "B-SECTION_HEADING", "I-SECTION_HEADING", | |
| "B-PASSAGE", "I-PASSAGE" | |
| ] | |
| label2id = {l: i for i, l in enumerate(labels)} | |
| id2label = {i: l for l, i in label2id.items()} | |
| # --- FIX for FileNotFoundError: Use a temporary directory for intermediate files --- | |
| TEMP_DIR = "temp_intermediate_files" | |
| os.makedirs(TEMP_DIR, exist_ok=True) | |
| print(f"\n--- SETUP PHASE: Created temp directory: {TEMP_DIR} ---") | |
| # 1. Preprocess and save the initial training data | |
| print("\n--- START PHASE: PREPROCESSING ---") | |
| # FIX: Prepend the directory path to the file name | |
| initial_bio_json = os.path.join(TEMP_DIR, "training_data_bio_bboxes.json") | |
| preprocess_labelstudio(args.input, initial_bio_json) | |
| # 2. Augment the dataset with translated bboxes | |
| print("\n--- START PHASE: AUGMENTATION ---") | |
| # FIX: Prepend the directory path to the file name | |
| augmented_bio_json = os.path.join(TEMP_DIR, "augmented_training_data_bio_bboxes.json") | |
| final_data_path = augment_and_save_dataset(initial_bio_json, augmented_bio_json) | |
| # Clean up the intermediary file (optional) | |
| # import shutil | |
| # shutil.rmtree(TEMP_DIR) | |
| # 3. Load and split augmented dataset | |
| print("\n--- START PHASE: MODEL/DATASET SETUP ---") | |
| #MODEL_ID = "heerjtdev/edugenius" | |
| tokenizer = LayoutLMv3TokenizerFast.from_pretrained("microsoft/layoutlmv3-base") | |
| #tokenizer = LayoutLMv3TokenizerFast.from_pretrained(MODEL_ID) | |
| dataset = LayoutDataset(final_data_path, tokenizer, label2id, max_len=args.max_len) | |
| val_size = int(0.2 * len(dataset)) | |
| train_size = len(dataset) - val_size | |
| # Use a fixed seed for reproducibility in split | |
| torch.manual_seed(42) | |
| train_dataset, val_dataset = random_split(dataset, [train_size, val_size]) | |
| train_loader = DataLoader(train_dataset, batch_size=args.batch_size, shuffle=True) | |
| val_loader = DataLoader(val_dataset, batch_size=args.batch_size) | |
| # 4. Initialize and load model | |
| device = torch.device("cuda" if torch.cuda.is_available() else "cpu") | |
| print(f"Using device: {device}") | |
| # Num_labels is based on the updated 'labels' list | |
| model = LayoutLMv3CRF("microsoft/layoutlmv3-base", num_labels=len(labels)).to(device) | |
| # model = LayoutLMv3CRF(MODEL_ID, num_labels=len(labels)).to(device) | |
| ckpt_path = "checkpoints/layoutlmv3_crf_passage.pth" | |
| os.makedirs("checkpoints", exist_ok=True) | |
| if os.path.exists(ckpt_path): | |
| # NOTE: Loading an old checkpoint will likely fail now because num_labels has changed, | |
| # unless the old checkpoint had the *exact* same number of labels. | |
| # It is recommended to start training from scratch. | |
| # print(f"π Loading checkpoint from {ckpt_path}") | |
| # model.load_state_dict(torch.load(ckpt_path, map_location=device)) | |
| print(f"β οΈ Starting fresh training. Old checkpoint {ckpt_path} may be incompatible with new label count.") | |
| optimizer = AdamW(model.parameters(), lr=args.lr) | |
| # 5. Training loop | |
| for epoch in range(args.epochs): | |
| print(f"\n--- START PHASE: EPOCH {epoch + 1}/{args.epochs} TRAINING ---") | |
| avg_loss = train_one_epoch(model, train_loader, optimizer, device) | |
| print(f"\n--- START PHASE: EPOCH {epoch + 1}/{args.epochs} EVALUATION ---") | |
| precision, recall, f1 = evaluate(model, val_loader, device, id2label) | |
| print( | |
| f"Epoch {epoch + 1}/{args.epochs} | Loss: {avg_loss:.4f} | P: {precision:.3f} R: {recall:.3f} F1: {f1:.3f}") | |
| torch.save(model.state_dict(), ckpt_path) | |
| print(f"πΎ Model saved at {ckpt_path}") | |
| def run_inference(pdf_path, model_path, output_path): | |
| # LABELS UPDATED: Added SECTION_HEADING and PASSAGE (Must match main) | |
| labels = [ | |
| "O", | |
| "B-QUESTION", "I-QUESTION", | |
| "B-OPTION", "I-OPTION", | |
| "B-ANSWER", "I-ANSWER", | |
| "B-SECTION_HEADING", "I-SECTION_HEADING", | |
| "B-PASSAGE", "I-PASSAGE" | |
| ] | |
| label2id = {l: i for i, l in enumerate(labels)} | |
| id2label = {i: l for l, i in label2id.items()} | |
| tokenizer = LayoutLMv3TokenizerFast.from_pretrained("microsoft/layoutlmv3-base") | |
| # Load the trained model | |
| device = torch.device("cuda" if torch.cuda.is_available() else "cpu") | |
| model = LayoutLMv3CRF("microsoft/layoutlmv3-base", num_labels=len(labels)).to(device) | |
| try: | |
| model.load_state_dict(torch.load(model_path, map_location=device)) | |
| except Exception as e: | |
| print( | |
| f"β Error loading model state: {e}. Ensure the model at {model_path} has been successfully trained with the new labels.") | |
| return | |
| model.eval() | |
| # Process PDF with OCR | |
| try: | |
| doc = fitz.open(pdf_path) | |
| except Exception as e: | |
| print(f"β Error opening PDF: {e}") | |
| return | |
| all_predictions = [] | |
| tesseract_config = '--psm 6' | |
| for page_num in range(len(doc)): | |
| page = doc.load_page(page_num) | |
| # Get a high-resolution image of the page for Tesseract | |
| pix = page.get_pixmap(dpi=300) | |
| img = Image.frombytes("RGB", [pix.width, pix.height], pix.samples) | |
| # Get page dimensions from PyMuPDF | |
| page_width, page_height = page.bound().width, page.bound().height | |
| # Get OCR data (words and bboxes) | |
| ocr_data = pytesseract.image_to_data(img, output_type=pytesseract.Output.DICT, config=tesseract_config) | |
| words = [word for word in ocr_data['text'] if word.strip()] | |
| # Skip empty pages | |
| if not words: | |
| continue | |
| # Get the scaling factors from the image resolution to the PDF's native resolution | |
| x_scale = page_width / pix.width | |
| y_scale = page_height / pix.height | |
| # Create original pixel bboxes | |
| bboxes_raw = [[ | |
| ocr_data['left'][i], | |
| ocr_data['top'][i], | |
| ocr_data['left'][i] + ocr_data['width'][i], | |
| ocr_data['top'][i] + ocr_data['height'][i] | |
| ] for i in range(len(ocr_data['text'])) if ocr_data['text'][i].strip()] | |
| # Normalize bboxes to 0-1000 scale using the correct scaling factors | |
| normalized_bboxes = [[ | |
| int(1000 * (b[0] * x_scale) / page_width), | |
| int(1000 * (b[1] * y_scale) / page_height), | |
| int(1000 * (b[2] * x_scale) / page_width), | |
| int(1000 * (b[3] * y_scale) / page_height) | |
| ] for b in bboxes_raw] | |
| # Tokenize and run inference | |
| inputs = tokenizer(words, boxes=normalized_bboxes, return_tensors="pt", truncation=True).to(device) | |
| with torch.no_grad(): | |
| # The model is run on the normalized bboxes | |
| preds = model(**inputs) | |
| # Align predictions back to words | |
| word_ids = inputs.word_ids(batch_index=0) | |
| final_preds = [] | |
| previous_word_idx = None | |
| for idx, word_id in enumerate(word_ids): | |
| if word_id is not None and word_id != previous_word_idx: | |
| # The model returns a list of predicted classes for each token | |
| final_preds.append(id2label[preds[0][idx]]) | |
| previous_word_idx = word_id | |
| # Prepare structured output | |
| page_results = [] | |
| # Tesseract returns word list that is shorter than ocr_data if it contains empty strings. | |
| # We need to use the cleaned 'words' list and its corresponding filtered bboxes. | |
| # Note: We must ensure that the word and bbox lists passed to tokenizer and the filtered | |
| # final_preds list are all correctly aligned with the original ocr_data indices. | |
| # Since 'words' and 'bboxes_raw' are filtered exactly the same way (by word.strip()), | |
| # and 'final_preds' is aligned back to 'words', we can zip them. | |
| for word, bbox, label in zip(words, bboxes_raw, final_preds): | |
| page_results.append({ | |
| "word": word, | |
| "bbox": bbox, | |
| "predicted_label": label | |
| }) | |
| all_predictions.extend(page_results) | |
| doc.close() | |
| with open(output_path, "w") as f: | |
| json.dump(all_predictions, f, indent=2, ensure_ascii=False) | |
| print(f"β Inference complete. Predictions saved to {output_path}") | |
| # ------------------------- | |
| # Step 7: Main Execution (Unchanged) | |
| # ------------------------- | |
| if __name__ == "__main__": | |
| parser = argparse.ArgumentParser(description="LayoutLMv3 Fine-tuning and Inference Script.") | |
| parser.add_argument("--mode", type=str, required=True, choices=["train", "infer"], | |
| help="Select mode: 'train' or 'infer'") | |
| parser.add_argument("--input", type=str, help="Path to input file (Label Studio JSON for train, PDF for infer).") | |
| parser.add_argument("--batch_size", type=int, default=4) | |
| parser.add_argument("--epochs", type=int, default=5) | |
| parser.add_argument("--lr", type=float, default=5e-5) | |
| parser.add_argument("--max_len", type=int, default=512) | |
| args = parser.parse_args() | |
| if args.mode == "train": | |
| if not args.input: | |
| parser.error("--input is required for 'train' mode.") | |
| main(args) | |
| elif args.mode == "infer": | |
| if not args.input: | |
| parser.error("--input is required for 'infer' mode.") | |
| run_inference(args.input, "checkpoints/layoutlmv3_crf_new_passage.pth", "inference_predictions.json") |