cv-analysis-service/table_parsing/table_parsig.py

from itertools import count

import cv2
import numpy as np
import pdf2image
from matplotlib import pyplot as plt
from timeit import timeit


def parse(image: np.array):
    gray_scale = cv2.cvtColor(image, cv2.COLOR_BGR2GRAY)
    th1, img_bin = cv2.threshold(gray_scale, 200, 255, cv2.THRESH_BINARY)
    img_bin = ~img_bin

    line_min_width = 5
    kernel_h = np.ones((1, line_min_width), np.uint8)
    kernel_v = np.ones((line_min_width, 1), np.uint8)

    img_bin_h = cv2.morphologyEx(img_bin, cv2.MORPH_OPEN, kernel_h)
    img_bin_v = cv2.morphologyEx(img_bin, cv2.MORPH_OPEN, kernel_v)
    # find_and_close_internal_gaps(img_bin_v)
    img_bin_final = img_bin_h | img_bin_v
    plt.imshow(img_bin_final)
    #find_and_close_internal_gaps(img_bin_final)
    #find_and_close_edges(img_bin_final)

    _, labels, stats, _ = cv2.connectedComponentsWithStats(~img_bin_final, connectivity=8, ltype=cv2.CV_32S)
    return labels, stats

# def parse(image: np.array):
#     gray_scale = cv2.cvtColor(image, cv2.COLOR_BGR2GRAY)
#     th1, img_bin = cv2.threshold(gray_scale, 250, 255, cv2.THRESH_BINARY)
#     img_bin = ~img_bin
#
#     line_min_width = 10
#     kernel_h = np.ones((20, line_min_width), np.uint8)
#     #kernel_v = np.ones((line_min_width, 20), np.uint8)
#
#     img_bin_h = cv2.morphologyEx(img_bin, cv2.MORPH_OPEN, kernel_h)
#     #img_bin_v = cv2.morphologyEx(img_bin, cv2.MORPH_OPEN, kernel_v)
#     #img_bin_final = img_bin_h | img_bin_v
#     contours, hierarchy = cv2.findContours(img_bin_h, cv2.RETR_TREE, cv2.CHAIN_APPROX_SIMPLE)
#     cv2.drawContours(img_bin_h, contours, 1, (255,0,0) , 6)
#     plt.imshow(img_bin_h)
#     print([cnt for cnt in contours if len(cnt)==4])
#     #plt.imshow(img_bin_h)
#     #find_and_close_internal_gaps(img_bin_final)
#     #find_and_close_edges(img_bin_final)
#
#     #_, labels, stats, _ = cv2.connectedComponentsWithStats(~img_bin_final, connectivity=8, ltype=cv2.CV_32S)
#     #return labels, stats
#     return contours,hierarchy

# def filter_unconnected_cells(stats):
#     filtered_cells = []
#     for left, middle, right in zip(stats[0:], stats[1:], list(stats[2:])+[None]):
#         x, y, w, h, area = middle
#         if w > 35 and h > 13 and area > 500:
#             if y == left[1] or y == right[1]:
#                 filtered_cells.append(middle)
#     return filtered_cells

def filter_unconnected_cells(stats):
    filtered_cells = []
    # print(stats)
    for left, middle, right in zip(stats[0:], stats[1:], list(stats[2:]) + [np.array([None, None, None, None, None])]):
        x, y, w, h, area = middle
        if w > 35 and h > 13 and area > 500:
            if right[1] is None:
                if y == left[1] or x == left[0]:
                    filtered_cells.append(middle)
            else:
                if y == left[1] or y == right[1] or x == left[0] or x == right[0]:
                    filtered_cells.append(middle)
    return filtered_cells



def annotate_image(image, stats):
    stats = filter_unconnected_cells(stats)
    for stat in stats:
        x, y, w, h, area = stat
        cv2.rectangle(image, (x, y), (x + w, y + h), (255, 0, 255), 2)
        for i, (s, v) in enumerate(zip(["x", "y", "w", "h"], [x, y, w, h])):
            anno = f"{s} = {v}"
            xann = int(x + 5)
            yann = int(y + h - (20 * (i + 1)))
            cv2.putText(image, anno, (xann, yann), cv2.FONT_HERSHEY_SIMPLEX, 0.7, (255, 0, 255), 2)

    return image


# def find_and_close_edges(img_bin_final):
#     contours, hierarchy = cv2.findContours(img_bin_final, cv2.RETR_TREE, cv2.CHAIN_APPROX_SIMPLE)
#
#     for cnt in contours:
#         missing_external_edges = True
#         left = tuple(cnt[cnt[:, :, 0].argmin()][0])
#         right = tuple(cnt[cnt[:, :, 0].argmax()][0])
#         top = tuple(cnt[cnt[:, :, 1].argmin()][0])
#         bottom = tuple(cnt[cnt[:, :, 1].argmax()][0])
#         topleft = [left[0] + 1, top[1]]
#         # print(cnt, left, top, topleft)
#         bottomright = [right[0] - 1, bottom[1]]
#         for arr in cnt:
#             if np.array_equal(arr, np.array([bottomright])) or np.array_equal(arr, np.array([topleft])):
#                 missing_external_edges = False
#                 break
#
#         if missing_external_edges and (bottomright[0]-topleft[0])*(bottomright[1]-topleft[1]) >= 50000:
#             topleft[0] -= 1
#             bottomright[0] += 1
#             cv2.rectangle(img_bin_final, tuple(topleft), tuple(bottomright), (255,255,255) , 2)
#             #print("missing cell detectet rectangle drawn")
#
#     return img_bin_final

def find_and_close_edges(img_bin_final):
    contours, hierarchy = cv2.findContours(img_bin_final, cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_SIMPLE)

    for cnt in contours:
        missing_external_edges = True
        left = tuple(cnt[cnt[:, :, 0].argmin()][0])
        right = tuple(cnt[cnt[:, :, 0].argmax()][0])
        top = tuple(cnt[cnt[:, :, 1].argmin()][0])
        bottom = tuple(cnt[cnt[:, :, 1].argmax()][0])
        topleft = [left[0], top[1]]
        bottomright = [right[0], bottom[1]]
        for arr in cnt:
            if np.array_equal(arr, np.array([bottomright])) or np.array_equal(arr, np.array([topleft])):
                missing_external_edges = False
                break

        if missing_external_edges and (bottomright[0] - topleft[0]) * (bottomright[1] - topleft[1]) >= 50000:
            cv2.rectangle(img_bin_final, tuple(topleft), tuple(bottomright), (255, 255, 255), 2)
            # print("missing cell detectet rectangle drawn")

    return img_bin_final


def find_and_close_internal_gaps(img_bin):
    contours, hierarchy = cv2.findContours(img_bin, cv2.RETR_TREE, cv2.CHAIN_APPROX_SIMPLE)
    cv2.drawContours(img_bin, contours, -1,(255,255,255),2)
    plt.imshow(img_bin)
    #print([cnt for cnt in contours if len(cnt) == 2])
    #
    # print(contours)
    # contours_list = sorted([cnt.tolist() for cnt in contours if len(cnt)>2])
    # lines_with_gaps = []
    # for left, right in zip(contours_list[0:], contours_list[1:] + [[[[None]]]]):
    #     print(left, left[0], left[0][0])
    #     if left[1][0][1]-left[0][0][1] > 13:
    #         if left[0][0][0] == right[0][0][0]:
    #             lines_with_gaps.append(left + right)
    # for lines in lines_with_gaps:
    #     cv2.line(img_bin, tuple(min(lines)[0]), tuple(max(lines)[0]), (255,255,255), 2)
    # #plt.imshow(img_bin)


def parse_tables_in_pdf(pages):
    return zip(map(parse, pages), count())


def annotate_tables_in_pdf(pdf_path, page_index=1):
    # timeit()
    page = pdf2image.convert_from_path(pdf_path, first_page=page_index + 1, last_page=page_index + 1)[0]
    page = np.array(page)

    _, stats = parse(page)
    page = annotate_image(page, stats)
    # print(timeit())
    fig, ax = plt.subplots(1, 1)
    fig.set_size_inches(20, 20)
    ax.imshow(page)
    plt.show()