import numpy as np import pandas as pd import streamlit as st from PIL import Image import torch import torch.nn.functional as F import pytesseract import plotly.express as px from torch.utils.data import Dataset, DataLoader, Subset import os import io import pytesseract import fitz from typing import List import json import sys from pathlib import Path from transformers import LayoutLMv3FeatureExtractor, LayoutLMv3TokenizerFast, LayoutLMv3Processor, LayoutLMv3ForSequenceClassification DEVICE = "cuda" if torch.cuda.is_available() else "cpu" TOKENIZER = "microsoft/layoutlmv3-base" MODEL_NAME = "fsommers/layoutlmv3-autofinance-classification-us-v01" TESS_OPTIONS = "--psm 3" # Automatic page segmentation for Tesseract @st.cache_resource def create_ocr_reader(): def scale_bounding_box(box: List[int], w_scale: float = 1.0, h_scale: float = 1.0): return [ int(box[0] * w_scale), int(box[1] * h_scale), int(box[2] * w_scale), int(box[3] * h_scale) ] def ocr_page(image) -> dict: """ OCR a given image. Return a dictionary of words and the bounding boxes for each word. For each word, there is a corresponding bounding box. """ ocr_df = pytesseract.image_to_data(image, output_type='data.frame', config=TESS_OPTIONS) ocr_df = ocr_df.dropna().reset_index(drop=True) float_cols = ocr_df.select_dtypes('float').columns ocr_df[float_cols] = ocr_df[float_cols].round(0).astype(int) ocr_df = ocr_df.replace(r'^\s*$', np.nan, regex=True) ocr_df = ocr_df.dropna().reset_index(drop=True) words = list(ocr_df.text) words = [str(w) for w in words] coordinates = ocr_df[['left', 'top', 'width', 'height']] boxes = [] for i, row in coordinates.iterrows(): x, y, w, h = tuple(row) actual_box = [x, y, x + w, y + h] boxes.append(actual_box) assert len(words) == len(boxes) return {"bbox": boxes, "words": words} def prepare_image(image): ocr_data = ocr_page(image) width, height = image.size width_scale = 1000 / width height_scale = 1000 / height words = [] boxes = [] for w, b in zip(ocr_data["words"], ocr_data["bbox"]): words.append(w) boxes.append(scale_bounding_box(b, width_scale, height_scale)) assert len(words) == len(boxes) for bo in boxes: for z in bo: if (z > 1000): raise return words, boxes return prepare_image @st.cache_resource def create_model(): model = LayoutLMv3ForSequenceClassification.from_pretrained(MODEL_NAME) return model.eval().to(DEVICE) @st.cache_resource def create_processor(): feature_extractor = LayoutLMv3FeatureExtractor(apply_ocr=False) tokenizer = LayoutLMv3TokenizerFast.from_pretrained(TOKENIZER) return LayoutLMv3Processor(feature_extractor=feature_extractor, tokenizer=tokenizer) def predict(image, reader, processor: LayoutLMv3Processor, model: LayoutLMv3ForSequenceClassification): words, boxes = reader(image) encoding = processor( image, words, boxes=boxes, max_length=512, padding="max_length", truncation=True, return_tensors="pt" ) with torch.inference_mode(): output = model( input_ids=encoding["input_ids"].to(DEVICE), attention_mask=encoding["attention_mask"].to(DEVICE), bbox=encoding["bbox"].to(DEVICE), pixel_values=encoding["pixel_values"].to(DEVICE) ) logits = output.logits predicted_class = logits.argmax() probabilities = F.softmax(logits, dim=-1).flatten().tolist() return predicted_class.detach().item(), probabilities st.markdown(f"Test") # reader = create_ocr_reader() # processor = create_processor() # model = create_model() # uploaded_file = st.file_uploader("Choose a JPG file", ["jpg", "png"]) # if uploaded_file is not None: # bytes_data = io.BytesIO(uploaded_file.read()) # image = Image.open(bytes_data) # st.image(image, caption="Uploaded Image", use_column_width=True) # predicted, probabilities = predict(image, reader, processor, model) # predicted_label = model.config.id2label[predicted] # st.markdown(f"Predicted Label: {predicted_label}") # df = pd.DataFrame({ # "Label": list(model.config.id2label.values()), # "Probability": probabilities # }) # fig = px.bar(df, x="Label", y="Probability") # st.plotly_chart(fig, use_container_width=True)