image-table-ocr/pdf_table_extraction_and_ocr.org

PDF Parsing

• Overview
  • To get CSV data from a table in a scanned pdf document:
  • Possible improvements
• Preparing data
  • Converting PDFs to images
  • Detecting image orientation and applying rotation.
• Detecting tables
  • Improving accuracy
• OCR tables
  • Blur
  • Threshold
  • Finding the vertical and horizontal lines of the table
  • Finding the contours
  • Sorting the bounding rectangles
  • Cropping each cell to the text
  • OCR each cell
• Files
  • setup.py
  • table_ocr
    • table_ocr/__init__.py
    • table_ocr/util.py
    • table_ocr/pdf_to_images/
      • table_ocr/pdf_to_images/__init__.py
      • table_ocr/pdf_to_images/__main__.py
    • table_ocr/extract_tables/
      • table_ocr/extract_tables/__init__.py
      • table_ocr/extract_tables/__main__.py
    • table_ocr/extract_cells/
      • table_ocr/extract_cells/__init__.py
      • table_ocr/extract_cells/__main__.py
    • table_ocr/ocr_image.py
    • table_ocr/ocr_to_csv.py
• Utils
  • Logging

Some notes about the header for those not familiar with Org Mode:

The property `header-args` with :session \*Python\* will cause all evaluated source code blocks to be evaluated in the buffer named "\*Python\*", which is the default buffer name for the buffer connected to an inferior python process. This is useful for interactive development. It gives you a REPL to work with rather than having to constantly evaluate source code blocks and view the results output to try any change.

Another note along those lines is that when source code blocks are evaluated, some unnecessary output is printed in the *Python* buffer. Adding :results output to a code block will minimize that noise.

Overview

To get CSV data from a table in a scanned pdf document:

TABLES=("/tmp/example-1/example-1.pdf" "/tmp/example-2/example-2.pdf")
python -m table_ocr.prepare_pdfs $TABLES | grep .png > /tmp/pdf-images.txt
cat /tmp/pdf-images.txt | xargs -I{} python -m table_ocr.extract_tables {}  | grep table > /tmp/extracted-tables.txt
cat /tmp/extracted-tables.txt | xargs -I{} python -m table_ocr.extract_cells_from_table {} | grep cells > /tmp/extracted-cells.txt
cat /tmp/extracted-cells.txt | xargs -I{} python -m table_ocr.ocr_image {}

# This next one needs to be run on each subdirectory one at a time.
python -m table_ocr.ocr_to_csv $(find . -iregex ".*cells.*ocr_data.*\.txt" 2>/dev/null)

Or, as a shell script.

#!/bin/sh

PDF=$1

python -m table_ocr.prepare_pdfs $PDF | grep .png > /tmp/pdf-images.txt
cat /tmp/pdf-images.txt | xargs -I{} python -m table_ocr.extract_tables {}  | grep table > /tmp/extracted-tables.txt
cat /tmp/extracted-tables.txt | xargs -I{} python -m table_ocr.extract_cells_from_table {} | grep cells > /tmp/extracted-cells.txt
cat /tmp/extracted-cells.txt | xargs -I{} python -m table_ocr.ocr_image {} --psm 7 -l data-table

for image in $(cat /tmp/extracted-tables.txt); do
    dir=$(dirname $image)
    python -m table_ocr.ocr_to_csv $(find $dir/cells -name "*.txt")
done

Possible improvements

Detect text with the stroke-width-transform alogoritm. https://zablo.net/blog/post/stroke-width-transform-swt-python/index.html

Preparing data

Converting PDFs to images

Not all pdfs need to be sent through OCR to extract the text content. If you can click and drag to highlight text in the pdf, then the tools in this library probably aren't necessary.

This code calls out to pdfimages from Poppler.

# Wrapper around the Poppler command line utility "pdfimages" and helpers for
# finding the output files of that command.
def pdf_to_images(pdf_filepath):
    """
    Turn a pdf into images
    """
    directory, filename = os.path.split(pdf_filepath)
    with working_dir(directory):
        image_filenames = pdfimages(pdf_filepath)

    # Since pdfimages creates a number of files named each for there page number
    # and doesn't return us the list that it created
    return [os.path.join(directory, f) for f in image_filenames]


def pdfimages(pdf_filepath):
    """
    Uses the `pdfimages` utility from Poppler
    (https://poppler.freedesktop.org/). Creates images out of each page. Images
    are prefixed by their name sans extension and suffixed by their page number.

    This should work up to pdfs with 999 pages since find matching files in dir
    uses 3 digits in its regex.
    """
    directory, filename = os.path.split(pdf_filepath)
    filename_sans_ext = filename.split(".pdf")[0]
    subprocess.run(["pdfimages", "-png", pdf_filepath, filename.split(".pdf")[0]])
    image_filenames = find_matching_files_in_dir(filename_sans_ext, directory)
    logger.debug(
        "Converted {} into files:\n{}".format(pdf_filepath, "\n".join(image_filenames))
    )
    return image_filenames


def find_matching_files_in_dir(file_prefix, directory):
    files = [
        filename
        for filename in os.listdir(directory)
        if re.match(r"{}-\d{{3}}.*\.png".format(re.escape(file_prefix)), filename)
    ]
    return files

Detecting image orientation and applying rotation.

Tesseract can detect orientation and we can then use ImageMagick's mogrify to rotate the image.

Here's an example of the output we get from orientation detection with Tesseract.

➜  example/ tesseract --psm 0 example-000.png -
Page number: 0
Orientation in degrees: 90
Rotate: 270
Orientation confidence: 26.86
Script: Latin
Script confidence: 2.44

The following are some helpers to detect orientation of the images that Poppler extracted and, if the images are rotated or skewed, use ImageMagick's `mogrify` to correct the rotation. This makes OCR more straightforward.

def preprocess_img(filepath):
    """
    Processing that involves running shell executables,
    like mogrify to rotate.
    """
    rotate = get_rotate(filepath)
    logger.debug("Rotating {} by {}.".format(filepath, rotate))
    mogrify(filepath, rotate)


def get_rotate(image_filepath):
    output = (
        subprocess.check_output(["tesseract", "--psm", "0", image_filepath, "-"])
        .decode("utf-8")
        .split("\n")
    )
    output = next(l for l in output if "Rotate: " in l)
    output = output.split(": ")[1]
    return output


def mogrify(image_filepath, rotate):
    subprocess.run(["mogrify", "-rotate", rotate, image_filepath])

Detecting tables

This answer from opencv.org was heavily referenced while writing the code around table detection: https://answers.opencv.org/question/63847/how-to-extract-tables-from-an-image/.

It's much easier to OCR a table when the table is the only thing in the image. This code detects tables in an image and returns a list of images of just the tables, no surrounding text or noise.

The blurring, thresholding, and line detection is used here as well as later on for cell extraction. They are good techniques for cleaning an image up in a way that makes things like shape detection more accurate.

def find_tables(image):
    <<blur>>
    <<threshold>>
    <<lines-of-table>>
    contours, heirarchy = cv2.findContours(
        mask, cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_SIMPLE,
    )

    MIN_TABLE_AREA = 1e5
    contours = [c for c in contours if cv2.contourArea(c) > MIN_TABLE_AREA]
    perimeter_lengths = [cv2.arcLength(c, True) for c in contours]
    epsilons = [0.1 * p for p in perimeter_lengths]
    approx_polys = [cv2.approxPolyDP(c, e, True) for c, e in zip(contours, epsilons)]
    bounding_rects = [cv2.boundingRect(a) for a in approx_polys]

    # The link where a lot of this code was borrowed from recommends an
    # additional step to check the number of "joints" inside this bounding rectangle.
    # A table should have a lot of intersections. We might have a rectangular image
    # here though which would only have 4 intersections, 1 at each corner.
    # Leaving that step as a future TODO if it is ever necessary.
    images = [image[y:y+h, x:x+w] for x, y, w, h in bounding_rects]
    return images

import cv2

<<detect-tables>>

image_filename = "resources/examples/example-page.png"
image = cv2.imread(image_filename, cv2.IMREAD_GRAYSCALE)
image = find_tables(image)[0]
cv2.imwrite("resources/examples/example-table.png", image)
"resources/examples/example-table.png"

Improving accuracy

It's likely that some images will contain tables that aren't accurately recognized by the code above. The code will then need to be made more robust. But how will we know that changes to the code don't break the detection of tables that were previously detected?

It might be good to add some type of test suite in the future that contains a spec that matches a pdf with the pages and pixel coordinates of the detected tables. The coordinates would need to have a range. Something like "example-1.pdf, page-2.png, [450:470, 200:210, 800:820, 1270:1290]" where the elements of the list are valid x, y, w, h ranges. So the test will pass if if the x, y, width and height are anywhere in that range.

OCR tables

Find the bounding box of each cell in the table. Run tesseract on each cell. Print a comma seperated output.

We'll start with an image shown at the end of the previous section.

Blur

Blurring helps to make noise less noisy so that the overall structure of an image is more detectable.

That gray row at the bottom is kind of noisy. If we don't somehow clean it up, OpenCV will detect all sorts of odd shapes in there and it will throw off our cell detection.

Cleanup can be accomplished with a blur followed by some thresholding.

BLUR_KERNEL_SIZE = (17, 17)
STD_DEV_X_DIRECTION = 0
STD_DEV_Y_DIRECTION = 0
blurred = cv2.GaussianBlur(image, BLUR_KERNEL_SIZE, STD_DEV_X_DIRECTION, STD_DEV_Y_DIRECTION)

image = ~cv2.imread("resources/examples/example-table.png", cv2.IMREAD_GRAYSCALE)
<<blur>>
cv2.imwrite("resources/examples/example-table-blurred.png", blurred)
"resources/examples/example-table-blurred.png"

Threshold

We've got a bunch of pixels that are gray. Thresholding will turn them all either black or white. Having all black or white pixels lets us do morphological transformations like erosion and dilation.

MAX_COLOR_VAL = 255
BLOCK_SIZE = 15
SUBTRACT_FROM_MEAN = -2

img_bin = cv2.adaptiveThreshold(
    ~blurred,
    MAX_COLOR_VAL,
    cv2.ADAPTIVE_THRESH_MEAN_C,
    cv2.THRESH_BINARY,
    BLOCK_SIZE,
    SUBTRACT_FROM_MEAN,
)

<<threshold>>
cv2.imwrite("resources/examples/example-table-thresholded.png", img_bin)
"resources/examples/example-table-thresholded.png"

Finding the vertical and horizontal lines of the table

Note: There's a wierd issue with the results of the example below when it's evaluated as part of an export or a full-buffer evaluation. If you evaluate the example by itself, it looks the way it's intended. If you evaluate it as part of an entire buffer evaluation, it's distorted.

vertical = horizontal = img_bin.copy()
SCALE = 5
image_width, image_height = horizontal.shape
horizontal_kernel = cv2.getStructuringElement(cv2.MORPH_RECT, (int(image_width / SCALE), 1))
horizontally_opened = cv2.morphologyEx(img_bin, cv2.MORPH_OPEN, horizontal_kernel)
vertical_kernel = cv2.getStructuringElement(cv2.MORPH_RECT, (1, int(image_height / SCALE)))
vertically_opened = cv2.morphologyEx(img_bin, cv2.MORPH_OPEN, vertical_kernel)

horizontally_dilated = cv2.dilate(horizontally_opened, cv2.getStructuringElement(cv2.MORPH_RECT, (40, 1)))
vertically_dilated = cv2.dilate(vertically_opened, cv2.getStructuringElement(cv2.MORPH_RECT, (1, 60)))

mask = horizontally_dilated + vertically_dilated

<<lines-of-table>>
cv2.imwrite("resources/examples/example-table-lines.png", mask)
"resources/examples/example-table-lines.png"

Finding the contours

Blurring and thresholding allow us to find the lines. Opening the lines allows us to find the contours.

An "Opening" is an erosion followed by a dilation. Great examples and descriptions of each morphological operation can be found at https://docs.opencv.org/trunk/d9/d61/tutorial_py_morphological_ops.html">https://docs.opencv.org/trunk/d9/d61/tutorial_py_morphological_ops.html.

Contours can be explained simply as a curve joining all the continuous points (along the boundary), having same color or intensity. The contours are a useful tool for shape analysis and object detection and recognition.

We can search those contours to find rectangles of certain size.

To do that, we can use OpenCV's approxPolyEP function. It takes as arguments the contour (list of contiguous points), and a number representing how different the polygon perimeter length can be from the true perimeter length of the contour. 0.1 (10%) seems to be a good value. The difference in perimeter length between a 4-sided polygon and a 3-sided polygon is greater than 10% and the difference between a 5+ sided polygon and a 4-sided polygon is less than 10%. So a 4-sided polygon is the polygon with the fewest sides that leaves the difference in perimeter length within our 10% threshold.

Then we just get the bounding rectangle of that polygon and we have our cells!

We might need to do a little more filtering of those rectangles though. We might have accidentally found some noise such as another image on the page or a title header bar or something. If we know our cells are all within a certain size (by area of pixels) then we can filter out the junk cells by removing cells above/below certain sizes.

contours, heirarchy = cv2.findContours(
    mask, cv2.RETR_TREE, cv2.CHAIN_APPROX_SIMPLE,
)

perimeter_lengths = [cv2.arcLength(c, True) for c in contours]
epsilons = [0.05 * p for p in perimeter_lengths]
approx_polys = [cv2.approxPolyDP(c, e, True) for c, e in zip(contours, epsilons)]

# Filter out contours that aren't rectangular. Those that aren't rectangular
# are probably noise.
approx_rects = [p for p in approx_polys if len(p) == 4]
bounding_rects = [cv2.boundingRect(a) for a in approx_polys]

# Filter out rectangles that are too narrow or too short.
MIN_RECT_WIDTH = 40
MIN_RECT_HEIGHT = 10
bounding_rects = [
    r for r in bounding_rects if MIN_RECT_WIDTH < r[2] and MIN_RECT_HEIGHT < r[3]
]

# The largest bounding rectangle is assumed to be the entire table.
# Remove it from the list. We don't want to accidentally try to OCR
# the entire table.
largest_rect = max(bounding_rects, key=lambda r: r[2] * r[3])
bounding_rects = [b for b in bounding_rects if b is not largest_rect]

cells = [c for c in bounding_rects]

Sorting the bounding rectangles

We want to process these from left-to-right, top-to-bottom.

I've thought of a straightforward algorithm for it, but it could probably be made more efficient.

We'll find the most rectangle with the most top-left corner. Then we'll find all of the rectangles that have a center that is within the top-y and bottom-y values of that top-left rectangle. Then we'll sort those rectangles by the x value of their center. We'll remove those rectangles from the list and repeat.

def cell_in_same_row(c1, c2):
    c1_center = c1[1] + c1[3] - c1[3] / 2
    c2_bottom = c2[1] + c2[3]
    c2_top = c2[1]
    return c2_top < c1_center < c2_bottom

orig_cells = [c for c in cells]
rows = []
while cells:
    first = cells[0]
    rest = cells[1:]
    cells_in_same_row = sorted(
        [
            c for c in rest
            if cell_in_same_row(c, first)
        ],
        key=lambda c: c[0]
    )

    row_cells = sorted([first] + cells_in_same_row, key=lambda c: c[0])
    rows.append(row_cells)
    cells = [
        c for c in rest
        if not cell_in_same_row(c, first)
    ]

# Sort rows by average height of their center.
def avg_height_of_center(row):
    centers = [y + h - h / 2 for x, y, w, h in row]
    return sum(centers) / len(centers)

rows.sort(key=avg_height_of_center)

To test if this code works, let's try sorting the bounding rectangles and numbering them from right to left, top to bottom.

import cv2
image = cv2.imread("resources/examples/example-table.png", cv2.IMREAD_GRAYSCALE)
<<blur>>
<<threshold>>
<<lines-of-table>>
<<bounding-rects>>
<<sort-contours>>

FONT_SCALE = 0.7
FONT_COLOR = (127, 127, 127)
for i, row in enumerate(rows):
    for j, cell in enumerate(row):
        x, y, w, h = cell
        cv2.putText(
            image,
            "{},{}".format(i, j),
            (int(x + w - w / 2), int(y + h - h / 2)),
            cv2.FONT_HERSHEY_SIMPLEX,
            FONT_SCALE,
            FONT_COLOR,
            2,
        )
cv2.imwrite("resources/examples/example-table-cells-numbered.png", image)
"resources/examples/example-table-cells-numbered.png"

def extract_cell_images_from_table(image):
    <<blur>>
    <<threshold>>
    <<lines-of-table>>
    <<bounding-rects>>
    <<sort-contours>>
    cell_images_rows = []
    for row in rows:
        cell_images_row = []
        for x, y, w, h in row:
            cell_images_row.append(image[y:y+h, x:x+w])
        cell_images_rows.append(cell_images_row)
    return cell_images_rows

<<extract-cells-from-table>>
image = cv2.imread("resources/examples/example-table.png", cv2.IMREAD_GRAYSCALE)
cell_images_rows = extract_cell_images_from_table(image)
cv2.imwrite("resources/examples/example-table-cell-1-1.png", cell_images_rows[1][1])
"resources/examples/example-table-cell-1-1.png"

Cropping each cell to the text

OCR with Tesseract works best when there is about 10 pixels of white border around the text.

Our bounding rectangles may have picked up some stray pixels from the horizontal and vertical lines of the cells in the table. It's probobly just a few pixels, much fewer than the width of the text. If that's the case, then we can remove that noise with a simple open morph.

Once the stray border pixels have been removed, we can expand our border using copyMakeBorder.

def crop_to_text(image):
    MAX_COLOR_VAL = 255
    BLOCK_SIZE = 15
    SUBTRACT_FROM_MEAN = -2

    img_bin = cv2.adaptiveThreshold(
        ~image,
        MAX_COLOR_VAL,
        cv2.ADAPTIVE_THRESH_MEAN_C,
        cv2.THRESH_BINARY,
        BLOCK_SIZE,
        SUBTRACT_FROM_MEAN,
    )

    img_h, img_w = image.shape
    horizontal_kernel = cv2.getStructuringElement(cv2.MORPH_RECT, (int(img_w * 0.5), 1))
    vertical_kernel = cv2.getStructuringElement(cv2.MORPH_RECT, (1, int(img_h * 0.7)))
    horizontal_lines = cv2.morphologyEx(img_bin, cv2.MORPH_OPEN, horizontal_kernel)
    vertical_lines = cv2.morphologyEx(img_bin, cv2.MORPH_OPEN, vertical_kernel)
    both = horizontal_lines + vertical_lines
    cleaned = img_bin - both

    # Get rid of little noise.
    kernel = cv2.getStructuringElement(cv2.MORPH_ELLIPSE, (3, 3))
    opened = cv2.morphologyEx(cleaned, cv2.MORPH_OPEN, kernel)

    contours, hierarchy = cv2.findContours(opened, cv2.RETR_LIST, cv2.CHAIN_APPROX_SIMPLE)
    bounding_rects = [cv2.boundingRect(c) for c in contours]
    NUM_PX_COMMA = 6
    MIN_CHAR_AREA = 5 * 9
    if bounding_rects:
        minx, miny, maxx, maxy = math.inf, math.inf, 0, 0
        for x, y, w, h in [(x, y, w, h) for x, y, w, h in bounding_rects if w * h > MIN_CHAR_AREA]:
            minx = min(minx, x)
            miny = min(miny, y)
            maxx = max(maxx, x + w)
            maxy = max(maxy, y + h)
        x, y, w, h = minx, miny, maxx - minx, maxy - miny
        cropped = image[y:min(img_h, y+h+NUM_PX_COMMA), x:min(img_w, x+w)]
    else:
        # If we morphed out all of the text, fallback to using the unmorphed image.
        cropped = image
    bordered = cv2.copyMakeBorder(cropped, 5, 5, 5, 5, cv2.BORDER_CONSTANT, None, 255)
    return bordered

import cv2
<<crop-to-text>>
image = cv2.imread("resources/examples/example-table-cell-1-1.png", cv2.IMREAD_GRAYSCALE)
image = crop_to_text(image)
cv2.imwrite("resources/examples/example-table-cell-1-1-cropped.png", image)
"resources/examples/example-table-cell-1-1-cropped.png"

OCR each cell

If we cleaned up the images well enough, we might get some accurate OCR!

There is plenty that could have gone wrong along the way.

The first step to troubleshooting is to view the intermediate images and see if there's something about your image that is obviously abnormal, like some really thick noise or a wrongly detected table.

If everything looks reasonable but the OCR is doing something like turning a period into a comma, then you might need to do some custom Tesseract training.

def ocr_image(image, config):
    return pytesseract.image_to_string(
        image,
        config=config
    )

import pytesseract
import cv2
image = cv2.imread("resources/examples/example-table-cell-1-1.png", cv2.IMREAD_GRAYSCALE)
<<crop-to-text>>
<<ocr-image>>
image = crop_to_text(image)
ocr_image(image, "--psm 7")

9.09

Files

setup.py

import setuptools

long_description = """
Utilities for turning images of tables into CSV data. Uses Tesseract and OpenCV.

Requires binaries for tesseract and pdfimages (from Poppler).
"""
setuptools.setup(
    name="table_ocr",
    version="0.0.1",
    author="Eric Ihli",
    author_email="eihli@owoga.com",
    description="Turn images of tables into CSV data.",
    long_description=long_description,
    long_description_content_type="text/plain",
    url="https://github.com/eihli/image-table-ocr",
    packages=setuptools.find_packages(),
    classifiers=[
        "Programming Language :: Python :: 3",
        "License :: OSI Approved :: MIT License",
        "Operating System :: OS Independent",
    ],
    install_requires=[
        "pytesseract~=0.3",
        "opencv-python~=4.2",
    ],
    python_requires='>=3.6',
)

table_ocr

table_ocr/__init__.py

table_ocr/util.py

from contextlib import contextmanager
import functools
import logging
import os
import tempfile

<<get-logger>>

@contextmanager
def working_dir(directory):
    original_working_dir = os.getcwd()
    try:
        os.chdir(directory)
        yield directory
    finally:
        os.chdir(original_working_dir)


def make_tempdir(identifier):
    return tempfile.mkdtemp(prefix="{}_".format(identifier))

table_ocr/pdf_to_images/

table_ocr/pdf_to_images/__init__.py

import os
import re
import subprocess

from table_ocr.util import get_logger, working_dir

logger = get_logger(__name__)

<<pdf-to-images>>

<<fix-orientation>>

table_ocr/pdf_to_images/__main__.py

Takes a variable number of pdf files and creates images out of each page of the file using pdfimages from Poppler. Images are created in the same directory that contains the pdf.

Prints each pdf followed by the images extracted from that pdf followed by a blank line.

python -m table_ocr.prepare_pdfs /tmp/file1/file1.pdf /tmp/file2/file2.pdf ...

import argparse

from table_ocr.util import working_dir, make_tempdir, get_logger
from table_ocr.pdf_to_images import pdf_to_images, preprocess_img

logger = get_logger(__name__)

parser = argparse.ArgumentParser()
parser.add_argument("files", nargs="+")


def main(files):
    pdf_images = []
    for f in files:
        pdf_images.append((f, pdf_to_images(f)))

    for pdf, images in pdf_images:
        for image in images:
            preprocess_img(image)

    for pdf, images in pdf_images:
        print("{}\n{}\n".format(pdf, "\n".join(images)))


if __name__ == "__main__":
    args = parser.parse_args()
    main(args.files)

table_ocr/extract_tables/

table_ocr/extract_tables/__init__.py

import cv2

<<detect-tables>>

table_ocr/extract_tables/__main__.py

Takes 1 or more image paths as arguments.

Images are opened and read with OpenCV.

Tables are detected and extracted to a new subdirectory of the given image. The subdirectory will be the filename sans the extension. The tables inside that directory will be named table-000.png.

If you want to do something with the output, like pipe the paths of the extracted tables into some other utility, here is a description of the output.

For each image path given as an agument, outputs:

1. The given image path
2. Paths of extracted tables; seperated by newlines
3. Empty newline

import argparse
import os

import cv2

from table_ocr.extract_tables import find_tables

parser = argparse.ArgumentParser()
parser.add_argument("files", nargs="+")


def main(files):
    results = []
    for f in files:
        directory, filename = os.path.split(f)
        image = cv2.imread(f, cv2.IMREAD_GRAYSCALE)
        tables = find_tables(image)
        files = []
        filename_sans_extension = os.path.splitext(filename)[0]
        if tables:
            os.makedirs(os.path.join(directory, filename_sans_extension), exist_ok=True)
        for i, table in enumerate(tables):
            table_filename = "table-{:03d}.png".format(i)
            table_filepath = os.path.join(
                directory, filename_sans_extension, table_filename
            )
            files.append(table_filepath)
            cv2.imwrite(table_filepath, table)
        if tables:
            results.append((f, files))

    for image_filename, table_filenames in results:
        print("\n".join(table_filenames))


if __name__ == "__main__":
    args = parser.parse_args()
    files = args.files
    main(files)

table_ocr/extract_cells/

table_ocr/extract_cells/__init__.py

import cv2

<<extract-cells-from-table>>

table_ocr/extract_cells/__main__.py

import os
import sys

import cv2

from table_ocr.extract_cells import extract_cell_images_from_table

def main(f):
    results = []
    directory, filename = os.path.split(f)
    table = cv2.imread(f, cv2.IMREAD_GRAYSCALE)
    rows = extract_cell_images_from_table(table)
    cell_img_dir = os.path.join(directory, "cells")
    os.makedirs(cell_img_dir, exist_ok=True)
    for i, row in enumerate(rows):
        for j, cell in enumerate(row):
            cell_filename = "{:03d}-{:03d}.png".format(i, j)
            path = os.path.join(cell_img_dir, cell_filename)
            cv2.imwrite(path, cell)
            print(path)


<<extract-cells-from-table>>

if __name__ == "__main__":
    main(sys.argv[1])

table_ocr/ocr_image.py

This does a little bit of cleanup before sending it through tesseract.

Creates images and text files that can be used for training tesseract. See https://github.com/tesseract-ocr/tesstrain.

. ~/.virtualenvs/lotto_odds/bin/activate
python -m table_ocr.ocr_cell resources/examples/cells/000-000.png

PRIZE

import argparse
import math
import os
import sys

import cv2
import pytesseract

description="""Takes a single argument that is the image to OCR.
Remaining arguments are passed directly to Tesseract.

Attempts to make OCR more accurate by performing some modifications on the image.
Saves the modified image and the OCR text in an `ocr_data` directory.
Filenames are of the format for training with tesstrain."""
parser = argparse.ArgumentParser(description=description)
parser.add_argument("image", help="filepath of image to perform OCR")

<<crop-to-text>>
<<ocr-image>>

def main(image_file, tess_args):
    directory, filename = os.path.split(image_file)
    filename_sans_ext, ext = os.path.splitext(filename)
    image = cv2.imread(image_file, cv2.IMREAD_GRAYSCALE)
    cropped = crop_to_text(image)
    ocr_data_dir = os.path.join(directory, "ocr_data")
    os.makedirs(ocr_data_dir, exist_ok=True)
    out_imagepath = os.path.join(ocr_data_dir, filename)
    out_txtpath = os.path.join(ocr_data_dir, "{}.gt.txt".format(filename_sans_ext))
    cv2.imwrite(out_imagepath, cropped)
    txt = ocr_image(cropped, " ".join(tess_args))
    print(txt)
    with open(out_txtpath, "w") as txt_file:
        txt_file.write(txt)

if __name__ == "__main__":
    args, tess_args = parser.parse_known_args()
    main(args.image, tess_args)

table_ocr/ocr_to_csv.py

import argparse
import csv
import io
import os
import sys
import tempfile

parser = argparse.ArgumentParser()
parser.add_argument("files", nargs="+")

def main(files):
    """Files must be sorted lexicographically
    Filenames must be <row>-<colum>.txt.
    000-000.txt
    000-001.txt
    001-000.txt
    etc...
    """
    rows = []
    for f in files:
        directory, filename = os.path.split(f)
        with open(f) as of:
            txt = of.read()
        row, column = map(int, filename.split(".")[0].split("-"))
        if row == len(rows):
            rows.append([])
        rows[row].append(txt)

    csv_file = io.StringIO()
    writer = csv.writer(csv_file)
    writer.writerows(rows)
    print(csv_file.getvalue())

if __name__ == "__main__":
    args = parser.parse_args()
    files = args.files
    files.sort()
    main(files)

Utils

The following code lets us specify a size for images when they are exported to html.

Org supports specifying an export size for an image by putting the #+ATTR_HTML: :width 100px before the image. But since our images are in a results drawer, we need a way for our results drawer to do that for us automatically.

Adding #+ATTR_HTML after the beginning of the result block introduces a new problem. Org-babel no longer recognizes the result as a result block and doesn't remove it when a src block is re-evaluated, so we end up just appending new results on each evaluation.

There is nothing configurable that will tell org-babel to remove our line. But we can define a function to do some cleanup and then add it as a before hook with advice-add.

(concat "#+ATTR_HTML: :width " width " :height " height "\n[[file:" text "]]")

(defun remove-attributes-from-src-block-result (&rest args)
  (let ((location (org-babel-where-is-src-block-result))
        (attr-regexp "[ 	]*#\\+ATTR.*$"))
    (when location
      (save-excursion
        (goto-char location)
        (when (looking-at (concat org-babel-result-regexp ".*$"))
          (next-line)
          (while (looking-at attr-regexp)
            (kill-whole-line)))))))

(advice-add 'org-babel-remove-result :before #'remove-attributes-from-src-block-result)
(advice-add 'org-babel-execute-src-block :before #'remove-attributes-from-src-block-result)

Logging

def get_logger(name):
    logger = logging.getLogger(name)
    lvl = os.environ.get("PY_LOG_LVL", "info").upper()
    handler = logging.StreamHandler()
    formatter = logging.Formatter(logging.BASIC_FORMAT)
    handler.setFormatter(formatter)
    logger.addHandler(handler)
    handler.setLevel(lvl)
    logger.setLevel(lvl)
    return logger