Key_Information_Extraction

import os
os.system('pip3 install torch torchvision torchaudio --extra-index-url https://download.pytorch.org/whl/cpu')

import gradio as gr

import numpy as np
import tensorflow as tf

import torch
import json

from datasets.features import ClassLabel
from transformers import AutoProcessor

from datasets import Features, Sequence, ClassLabel, Value, Array2D, Array3D
from datasets import load_dataset # this dataset uses the new Image feature :) 

from transformers import LayoutLMv3ForTokenClassification
from transformers.data.data_collator import default_data_collator
from transformers import AutoModelForTokenClassification

import cv2
from PIL import Image, ImageDraw, ImageFont

#setting up the Huggingface env
# pip install -q git+https://github.com/huggingface/transformers.git
# !pip install h5py
# It's useful for evaluation metrics such as F1 on sequence labeling tasks
# !pip install -q datasets seqeval

# this dataset uses the new Image feature :)
dataset = load_dataset("nielsr/funsd-layoutlmv3") 
#dataset = load_dataset("G:\\BITS - MTECH\\Sem -4\\Final Report\\code\dataset")

Image.open(dataset[2]["image_path"]).convert("RGB").save("example1.png")
Image.open(dataset[1]["image_path"]).convert("RGB").save("example2.png")
Image.open(dataset[0]["image_path"]).convert("RGB").save("example3.png")

example = dataset["test"][0]

words, boxes, ner_tags = example["tokens"], example["bboxes"], example["ner_tags"]

features = dataset["test"].features

column_names = dataset["test"].column_names
image_column_name = "image"
text_column_name = "tokens"
boxes_column_name = "bboxes"
label_column_name = "ner_tags"

def get_label_list(labels):
    unique_labels = set()
    for label in labels:
        unique_labels = unique_labels | set(label)
    label_list = list(unique_labels)
    label_list.sort()
    return label_list

if isinstance(features[label_column_name].feature, ClassLabel):
    label_list = features[label_column_name].feature.names
    # No need to convert the labels since they are already ints.
    id2label = {k: v for k,v in enumerate(label_list)}
    label2id = {v: k for k,v in enumerate(label_list)}
else:
    label_list = get_label_list(dataset["train"][label_column_name])
    id2label = {k: v for k,v in enumerate(label_list)}
    label2id = {v: k for k,v in enumerate(label_list)}
num_labels = len(label_list)

label2color = {'question':'blue', 'answer':'green', 'header':'orange', 'other':'violet'}


def prepare_examples(examples):
  images = examples[image_column_name]
  words = examples[text_column_name]
  boxes = examples[boxes_column_name]
  word_labels = examples[label_column_name]

  encoding = processor(images, words, boxes=boxes, word_labels=word_labels,
                       truncation=True, padding="max_length")

  return encoding

processor = AutoProcessor.from_pretrained("microsoft/layoutlmv3-base", apply_ocr=False)
#model = AutoModelForTokenClassification.from_pretrained("microsoft/layoutlmv3-base")

model = LayoutLMv3ForTokenClassification.from_pretrained("microsoft/layoutlmv3-base",
                                                         id2label=id2label,
                                                         label2id=label2id)

# we need to define custom features for `set_format` (used later on) to work properly
features = Features({
    'pixel_values': Array3D(dtype="float32", shape=(3, 224, 224)),
    'input_ids': Sequence(feature=Value(dtype='int64')),
    'attention_mask': Sequence(Value(dtype='int64')),
    'bbox': Array2D(dtype="int64", shape=(512, 4)),
    'labels': Sequence(feature=Value(dtype='int64')),
})

# train_dataset = dataset["train"].map(
#     prepare_examples,
#     batched=True,
#     remove_columns=column_names,
#     features=features,
# )
eval_dataset = dataset["test"].map(
    prepare_examples,
    batched=True,
    remove_columns=column_names,
    features=features,
)

def unnormalize_box(bbox, width, height):
     return [
         width * (bbox[0] / 1000),
         height * (bbox[1] / 1000),
         width * (bbox[2] / 1000),
         height * (bbox[3] / 1000),
     ]

def process_image(image):

    print(type(image))
    width, height = image.size

    # encode
    #encoding = processor(image, truncation=True, return_offsets_mapping=True, return_tensors="pt")
    #offset_mapping = encoding.pop('offset_mapping')

    image = example["image"]
    words = example["tokens"]
    boxes = example["bboxes"]
    word_labels = example["ner_tags"]

    encoding = processor(image, words, truncation=True,boxes=boxes, word_labels=word_labels,return_offsets_mapping=True, return_tensors="pt")
    offset_mapping = encoding.pop('offset_mapping')

    for k,v in encoding.items():
        print(k,v.shape)

    # forward pass
    with torch.no_grad():
        outputs = model(**encoding)

    # get predictions

    # We take the highest score for each token, using argmax. 
    # This serves as the predicted label for each token.
    logits = outputs.logits
    #logits.shape
    predictions = logits.argmax(-1).squeeze().tolist()

    labels = encoding.labels.squeeze().tolist()

    token_boxes = encoding.bbox.squeeze().tolist()
    width, height = image.size

    true_predictions = [model.config.id2label[pred] for pred, label in zip(predictions, labels) if label != - 100]
    true_labels = [model.config.id2label[label] for prediction, label in zip(predictions, labels) if label != -100]
    true_boxes = [unnormalize_box(box, width, height) for box, label in zip(token_boxes, labels) if label != -100]
    
    
    # only keep non-subword predictions
    is_subword = np.array(offset_mapping.squeeze().tolist())[:,0] != 0
    true_predictions = [id2label[pred] for idx, pred in enumerate(predictions) if not is_subword[idx]]
    true_boxes = [unnormalize_box(box, width, height) for idx, box in enumerate(token_boxes) if not is_subword[idx]]

    # draw predictions over the image
    draw = ImageDraw.Draw(image)
    font = ImageFont.load_default()
    for prediction, box in zip(true_predictions, true_boxes):
        predicted_label = id2label(prediction)
        draw.rectangle(box, outline=label2color[predicted_label])
        draw.text((box[0]+10, box[1]-10), text=predicted_label, fill=label2color[predicted_label], font=font)
    
    return image

title = "DocumentAI - Extraction using LayoutLMv3 model"
description = "Extraction of Form or Invoice Extraction - We use Microsoft's LayoutLMv3 trained on Invoice Dataset to predict the Biller Name, Biller Address, Biller post_code, Due_date, GST, Invoice_date, Invoice_number, Subtotal and Total. To use it, simply upload an image or use the example image below. Results will show up in a few seconds."

article="<b>References</b><br>[1] Y. Xu et al., “LayoutLMv3: Pre-training for Document AI with Unified Text and Image Masking.” 2022. <a href='https://arxiv.org/abs/2204.08387'>Paper Link</a><br>[2]  <a href='https://github.com/NielsRogge/Transformers-Tutorials/tree/master/LayoutLMv3'>LayoutLMv3 training and inference</a>" 

examples =[['example1.png'],['example2.png'],['example3.png']]

css = """.output_image, .input_image {height: 600px !important}"""

iface = gr.Interface(fn=process_image, 
                     inputs=gr.inputs.Image(type="pil"), 
                     outputs=gr.outputs.Image(type="pil", label="annotated image"),
                     title=title,
                     description=description,
                     article=article,
                     examples=examples,
                     css=css,
                     analytics_enabled = True, enable_queue=True)

iface.launch(inline=False, share=False, debug=False)