# -*- coding: utf-8 -*- """Untitled1.ipynb Automatically generated by Colaboratory. Original file is located at https://colab.research.google.com/drive/1J4fCr7TGzdFvkCeikMAQ5af5ml2Q83W0 """ import os os.system('pip3 install torch torchvision torchaudio --extra-index-url https://download.pytorch.org/whl/cpu') import os, glob, fitz import cv2 import os import PIL import torch import pandas as pd import numpy as np import pandas as pd import gradio as gr from tqdm import tqdm from PIL import Image as im from scipy import ndimage from difflib import SequenceMatcher from itertools import groupby from datasets import load_metric from datasets import load_dataset from datasets.features import ClassLabel from transformers import AutoProcessor from PIL import Image, ImageDraw, ImageFont from transformers import AutoModelForTokenClassification from transformers.data.data_collator import default_data_collator from datasets import Features, Sequence, ClassLabel, Value, Array2D, Array3D from transformers import LayoutLMv3ForTokenClassification,LayoutLMv3FeatureExtractor # define id2label id2label = {0: 'song name', 1: 'artist', 2: 'year', 3: 'album', 4: 'genres', 5: 'song writer', 6: 'lyrics', 7: 'others'} custom_config = r'--oem 3 --psm 6' # lang='eng+deu+ita+chi_sim' lang='spa' label_ints = np.random.randint(0,len(PIL.ImageColor.colormap.items()),42) label_color_pil = [k for k,_ in PIL.ImageColor.colormap.items()] label_color = [label_color_pil[i] for i in label_ints] label2color = {} for k,v in id2label.items(): if v[:2] == '': label2color['o']=label_color[k] else: label2color[v[2:]]=label_color[k] processor = AutoProcessor.from_pretrained("microsoft/layoutlmv3-base", apply_ocr=True,lang=lang) model = AutoModelForTokenClassification.from_pretrained("alitavanaali/music_layoutlmv3_model") feature_extractor = LayoutLMv3FeatureExtractor(apply_ocr=True,lang=lang) def unnormalize_box(bbox, width, height): #print('shape is: ', np.asarray(bbox).shape, ' and box has values: ', bbox) return [ width * (bbox[0] / 1000), height * (bbox[1] / 1000), width * (bbox[2] / 1000), height * (bbox[3] / 1000), ] def iob_to_label(label): if label == 0: return 'song name' if label == 1: return 'artist' if label == 2: return 'year' if label == 3: return 'album' if label == 4: return 'genres' if label == 5: return 'song writer' if label == 6: return 'lyrics' if label == 7: return 'others' # this method will detect if there is any intersect between two boxes or not def intersect(w, z): x1 = max(w[0], z[0]) #190 | 881 | 10 y1 = max(w[1], z[1]) #90 | 49 | 273 x2 = min(w[2], z[2]) #406 | 406 | 1310 y2 = min(w[3], z[3]) #149 | 703 | 149 if (x1 > x2 or y1 > y2): return 0 else: # because sometimes in annotating, it is possible to overlap rows or columns by mistake # for very small pixels, we check a threshold to delete them area = (x2-x1) * (y2-y1) if (area > 0): return [int(x1), int(y1), int(x2), int(y2)] else: return 0 def process_image(image): custom_config = r'--oem 3 --psm 6' # lang='eng+deu+ita+chi_sim' lang='eng' width, height = image.size encoding_feature_extractor = feature_extractor(image, return_tensors="pt",truncation=True) words, boxes = encoding_feature_extractor.words, encoding_feature_extractor.boxes custom_config = r'--oem 3 --psm 6' # encode inference_image = [image.convert("RGB")] encoding = processor(inference_image , truncation=True, return_offsets_mapping=True, return_tensors="pt", padding="max_length", stride =128, max_length=512, return_overflowing_tokens=True) offset_mapping = encoding.pop('offset_mapping') overflow_to_sample_mapping = encoding.pop('overflow_to_sample_mapping') # change the shape of pixel values x = [] for i in range(0, len(encoding['pixel_values'])): x.append(encoding['pixel_values'][i]) x = torch.stack(x) encoding['pixel_values'] = x # forward pass outputs = model(**encoding) # get predictions predictions = outputs.logits.argmax(-1).squeeze().tolist() token_boxes = encoding.bbox.squeeze().tolist() # only keep non-subword predictions preds = [] l_words = [] bboxes = [] token_section_num = [] # related to more than 512 tokens if (len(token_boxes) == 512): predictions = [predictions] token_boxes = [token_boxes] for i in range(0, len(token_boxes)): for j in range(0, len(token_boxes[i])): #print(np.asarray(token_boxes[i][j]).shape) unnormal_box = unnormalize_box(token_boxes[i][j], width, height) #print('prediction: {} - box: {} - word:{}'.format(predictions[i][j], unnormal_box, processor.tokenizer.decode(encoding["input_ids"][i][j]))) if (np.asarray(token_boxes[i][j]).shape != (4,)): continue elif (token_boxes[i][j] == [0, 0, 0, 0] or token_boxes[i][j] == 0): #print('zero found!') continue # if bbox is available in the list, just we need to update text elif (unnormal_box not in bboxes): preds.append(predictions[i][j]) l_words.append(processor.tokenizer.decode(encoding["input_ids"][i][j])) bboxes.append(unnormal_box) token_section_num.append(i) else: # we have to update the word _index = bboxes.index(unnormal_box) if (token_section_num[_index] == i): # check if they're in a same section or not (documents with more than 512 tokens will divide to seperate # parts, so it's possible to have a word in both of the pages and we have to control that repetetive words # HERE: because they're in a same section, so we can merge them safely l_words[_index] = l_words[_index] + processor.tokenizer.decode(encoding["input_ids"][i][j]) else: continue return bboxes, preds, l_words, image def visualize_image(final_bbox, final_preds, l_words, image): draw = ImageDraw.Draw(image) font = ImageFont.load_default() #{0: 'document number', 1: 'elemento pn', 2: 'nombre del responsabile', 3: 'fecha', 4: 'internal reference', 5: 'others'} #id2label = {0: 'song name', 1: 'artist', 2: 'year', 3: 'album', 4: 'genres', 5: 'song writer', 6: 'lyrics', 7: 'others'} label2color = {'song name':'red', 'artist':'blue', 'year':'black', 'album':'green', 'genres':'brown', 'song writer':'blue', 'lyrics':'purple', 'others': 'white'} l2l = {'song name':'red', 'artist':'blue', 'year':'black', 'album':'green', 'genres':'brown', 'song writer':'blue','lyrics':'purple', 'others':'white'} f_labels = {'song name':'red', 'artist':'blue', 'year':'black', 'album':'green', 'genres':'brown', 'song writer':'blue','lyrics':'purple', 'others':'white'} json_df = [] # draw bboxes on image for ix, (prediction, box) in enumerate(zip(final_preds, final_bbox)): predicted_label = iob_to_label(prediction).lower() if (predicted_label != 'others'): draw.rectangle(box, outline=label2color[predicted_label]) draw.text((box[0]+10, box[1]-10), text=predicted_label, fill=label2color[predicted_label], font=font) json_dict = {} json_dict['TEXT'] = l_words[ix] json_dict['LABEL'] = f_labels[predicted_label] json_df.append(json_dict) return image, json_df def mergeCloseBoxes(pr, bb, wr, threshold): idx = 0 final_bbox =[] final_preds =[] final_words=[] for box, pred, word in zip(bb, pr, wr): if (pred=='others'): continue else: flag = False for b, p, w in zip(bb, pr, wr): if (p == 'others'): #print('others') #print('-------') continue elif (box==b): # we shouldn't check each item with itself #print('itself') #print('--------') continue else: XMIN, YMIN, XMAX, YMAX = box xmin, ymin, xmax, ymax = b #print('word: {} , w:{}'.format(word, w)) intsc = intersect([XMIN, YMIN, XMAX+threshold, YMAX], [xmin-threshold, ymin, xmax, ymax]) if (intsc != 0 and pred==p): flag = True #print('there is intersect') # if(abs(XMAX - xmin) < treshold and abs(YMIN - ymin) < 10): # we have to check if there is any intersection between box and all the values in final_bbox list # because if we have updated it before, now we have to update in final_bbox #print(final_bbox) print(*final_bbox, sep=",") merged_box = [ min(XMIN, xmin), min(YMIN, ymin), max(XMAX, xmax), max(YMAX, ymax) ] merged_words = word + ' ' + w # add to final_bbox wasAvailable = False for id, fbox in enumerate(final_bbox): if (intersect(box, fbox) != 0 and pred==final_preds[id]): #print('added before!') # box is inside another processed box, so we have to update it wasAvailable = True merged_box = [ min(fbox[0], min(XMIN, xmin)), min(fbox[1], min(YMIN, ymin)), max(fbox[2], max(XMAX, xmax)), max(fbox[3], max(YMAX, ymax)) ] final_bbox[id] = merged_box final_words[id] = final_words[id] + ' ' + w break if (not wasAvailable): # there was no intersect, bbox is not added before #print('not added before, so we add merged box!') final_bbox.append(merged_box) final_preds.append(pred) final_words.append(merged_words) '''else: print() final_bbox.append(box) final_preds.append(pred) final_words.append(word)''' if (flag == False): #print('flag is false, word: {} added'.format(word)) # there is no intersect between word and the others # we will check for last time if box is inside the others, because if the word is last word (like Juan + Mulian + Alexander) (Alexander) # it is added before but it has not intersection with others, so we will check to prevent for id, fbox in enumerate(final_bbox): if (intersect(box, fbox) != 0 and pred==final_preds[id]): flag = True if (not flag): final_bbox.append(box) final_preds.append(pred) final_words.append(word) return final_bbox, final_preds, final_words def createDataframe(preds, words): df = pd.DataFrame(columns = ['song name', 'artist', 'year', 'album', 'genres', 'song writer', 'lyrics', 'others']) if (len(preds) > 0): flag_label = preds[0] #print(preds) #print(words) #print('@@@@@') #print(flag_label) row_number = -1 for i in range(len(preds)): #print('i is: {}'.format(i)) if (preds[i] == flag_label): row_number = row_number + 1 df.at[row_number, preds[i]] = words[i] #print('row number is: {}'.format(row_number)) continue else: #print('row_number {} is <= of df.shape {}'.format(row_number, df.shape[0])) #print(pd.isna(df[preds[i]].iloc[row_number])) #print(pd.isna(df[preds[i]].iloc[row_number])) if(pd.isna(df[preds[i]].iloc[row_number])): df.at[row_number, preds[i]] = words[i] else: row_number = row_number + 1 df.at[row_number, preds[i]] = words[i] return df def isInside(w, z): # return True if w is inside z, if z is inside w return false if(w[0] >= z[0] and w[1] >= z[1] and w[2] <= z[2] and w[3] <= z[3]): return True return False def removeSimilarItems(final_bbox, final_preds, final_words): _bb =[] _pp=[] _ww=[] for i in range(len(final_bbox)): _bb.append(final_bbox[i]) _pp.append(final_preds[i]) _ww.append(final_words[i]) for j in range(len(final_bbox)): if (final_bbox[i] == final_bbox[j]): continue elif (isInside(final_bbox[i], final_bbox[j]) and final_preds[i]==final_preds[j] ): # box i is inside box j, so we have to remove it #print('box[i]: {} is inside box[j]:{}'.format(final_bbox[i], final_bbox[j])) _bb = _bb[:-1] _pp = _pp[:-1] _ww = _ww[:-1] continue return _bb, _pp, _ww #[45.604, 2309.811, 66.652, 2391.6839999999997] def process_form(preds, words, bboxes): final_bbox, final_preds, final_words = mergeCloseBoxes(preds, bboxes, words, 30) _bbox, _preds, _words = removeSimilarItems(final_bbox, final_preds, final_words) # convert float list to int _bbox = [[int(x) for x in item ] for item in _bbox] # creat data object for sorting data = [] for index in range(len(_bbox)): data.append((_bbox[index], _preds[index], _words[index])) # sorting by the height of the page sorted_list = sorted( data, key=lambda x: x[0][1] ) _bbox = [item[0] for item in sorted_list] _preds = [item[1] for item in sorted_list] _words = [item[2] for item in sorted_list] return _bbox, _preds, _words def mergeImageVertical(a): list_im = a imgs = [ Image.open(i) for i in list_im ] # pick the image which is the smallest, and resize the others to match it (can be arbitrary image shape here) min_shape = sorted( [(np.sum(i.size), i.size ) for i in imgs])[0][1] imgs_comb = np.hstack([i.resize(min_shape) for i in imgs]) # for a vertical stacking it is simple: use vstack imgs_comb = np.vstack([i.resize(min_shape) for i in imgs]) imgs_comb = Image.fromarray( imgs_comb) imgs_comb.save( 'Trifecta_vertical.jpg' ) return imgs_comb def completepreprocess(pdffile): myDataFrame = pd.DataFrame() a=[] doc = fitz.open(pdffile) for i in range(0,len(doc)): page = doc.load_page(i) zoom = 2 # zoom factor mat = fitz.Matrix(zoom, zoom) pix = page.get_pixmap(matrix = mat,dpi = 200) t=pix.save("page"+str(i)+".jpg") images = Image.open("page"+str(i)+".jpg") image = images.convert("RGB") bbox, preds, words, image = process_image(image) print(preds) print(words) im, df = visualize_image(bbox, preds, words, image) im1 = im.save("page"+str(i)+".jpg") a.append("page"+str(i)+".jpg") pred_list = [] for number in preds: pred_list.append(iob_to_label(number)) _bbox, _preds, _words = process_form(pred_list, words, bbox) print('page: ' + str(i) + ' ' + str(len(_preds))+ ' ' + str(len(_words))) df = createDataframe(_preds, _words) myDataFrame=myDataFrame.append(df) im2=mergeImageVertical(a) return im2,myDataFrame title = "Interactive demo: Music Information Extraction model" description = "Music Information Extraction - We used Microsoft’s LayoutLMv3 trained on Our Music Dataset through csv's to predict the labels. To use it, simply upload a PDF or use the example PDF below and click ‘Submit’. Results will show up in a few seconds. If you want to make the output bigger, right-click on it and select ‘Open image in new tab’.Train =16 ,Test =7" css = """.output_image, .input_image {height: 600px !important}""" #examples = [["461BHH69.PDF"],["AP-481-RF.PDF"],["DP-095-ML.PDF"],["DQ-231-LL.PDF"],["FK-941-ET.PDF"], ["FL-078-NH.PDF"] # ,["14ZZ69.PDF"],["74BCA69.PDF"],["254BEG69.PDF"],["761BJQ69.PDF"],["AB-486-EH.PDF"],["AZ-211-ZA.PDF"], ["CY-073-YV.PDF"]] # ["744BJQ69.PDF"], ['tarros_2.jpg'], examples = [['test1.jpg'], ['doc1.pdf'], ['doc1.2.pdf']] iface = gr.Interface(fn=completepreprocess, #inputs=gr.inputs.Image(type="pil",optional=True,label="upload file"), inputs=gr.File(label="PDF"), #inputs=gr.inputs.Image(type="pil") outputs=[gr.outputs.Image(type="pil", label="annotated image"),"dataframe"] , title=title, description=description, examples=examples, css=css, analytics_enabled = True, enable_queue=True) iface.launch(inline=False , debug=True)