# How do I crop to largest interior bounding box in OpenCV?

I have some images on a black background where the images don't have square edges (see bottom right of image below). I would like to crop them down the largest rectangular image (red border). I know I will potentially lose from of the original image. Is it possible to do this in OpenCV with Python. I know there are are functions to crop to a bounding box of a contour but that would still leave me with black background in places. • What more can you tell besides 'images don't have square edges'? is it always like in the example - where you need to crop from bottom and right? (in that case it is pretty simple) – Eran W Jan 29 '14 at 3:24
• The image (none black area) can have any shape, an I want to convert it to be rectangular while losing the minimum amount of the image. – nickponline Jan 29 '14 at 19:20
• @nickponline did you find any solution? – Micka Mar 14 '14 at 10:41

ok, I've played with an idea and tested it (it's c++ but you'll probably be able to convert that to python):

1. assumption: background is black and the interior has no black boundary parts
2. you can find the external contour with `findContours`
3. use min/max x/y point positions from that contour until the rectangle that is built by those points contains no points that lie outside of the contour

I can't guarantee that this method always finds the "best" interior box, but I use a heuristic to choose whether the rectangle is reduced at top/bottom/left/right side.

Code can certainly be optimized, too ;)

using this as a testimage, I got that result (non-red region is the found interior rectangle):  regard that there is one pixel at top right that shouldnt containt to the rectangle, maybe thats from extrascting/drawing the contour wrong?!?

and here's code:

``````cv::Mat input = cv::imread("LenaWithBG.png");

cv::Mat gray;
cv::cvtColor(input,gray,CV_BGR2GRAY);

cv::imshow("gray", gray);

// extract all the black background (and some interior parts maybe)

// now extract the outer contour
std::vector<std::vector<cv::Point> > contours;
std::vector<cv::Vec4i> hierarchy;

std::cout << "found contours: " << contours.size() << std::endl;

cv::Mat contourImage = cv::Mat::zeros( input.size(), CV_8UC3 );;

//find contour with max elements
// remark: in theory there should be only one single outer contour surrounded by black regions!!

unsigned int maxSize = 0;
unsigned int id = 0;
for(unsigned int i=0; i<contours.size(); ++i)
{
if(contours.at(i).size() > maxSize)
{
maxSize = contours.at(i).size();
id = i;
}
}

std::cout << "chosen id: " << id << std::endl;
std::cout << "max size: " << maxSize << std::endl;

/// Draw filled contour to obtain a mask with interior parts
cv::Mat contourMask = cv::Mat::zeros( input.size(), CV_8UC1 );
cv::drawContours( contourMask, contours, id, cv::Scalar(255), -1, 8, hierarchy, 0, cv::Point() );

// sort contour in x/y directions to easily find min/max and next
std::vector<cv::Point> cSortedX = contours.at(id);
std::sort(cSortedX.begin(), cSortedX.end(), sortX);

std::vector<cv::Point> cSortedY = contours.at(id);
std::sort(cSortedY.begin(), cSortedY.end(), sortY);

unsigned int minXId = 0;
unsigned int maxXId = cSortedX.size()-1;

unsigned int minYId = 0;
unsigned int maxYId = cSortedY.size()-1;

cv::Rect interiorBB;

while( (minXId<maxXId)&&(minYId<maxYId) )
{
cv::Point min(cSortedX[minXId].x, cSortedY[minYId].y);
cv::Point max(cSortedX[maxXId].x, cSortedY[maxYId].y);

interiorBB = cv::Rect(min.x,min.y, max.x-min.x, max.y-min.y);

// out-codes: if one of them is set, the rectangle size has to be reduced at that border
int ocTop = 0;
int ocBottom = 0;
int ocLeft = 0;
int ocRight = 0;

bool finished = checkInteriorExterior(contourMask, interiorBB, ocTop, ocBottom,ocLeft, ocRight);
if(finished)
{
break;
}

// reduce rectangle at border if necessary
if(ocLeft)++minXId;
if(ocRight) --maxXId;

if(ocTop) ++minYId;
if(ocBottom)--maxYId;

}

std::cout <<  "done! : " << interiorBB << std::endl;

cv::Mat mask2 = cv::Mat::zeros(input.rows, input.cols, CV_8UC1);

{
}

``````

with reduction function:

``````bool checkInteriorExterior(const cv::Mat&mask, const cv::Rect&interiorBB, int&top, int&bottom, int&left, int&right)
{
// return true if the rectangle is fine as it is!
bool returnVal = true;

unsigned int x=0;
unsigned int y=0;

// count how many exterior pixels are at the
unsigned int cTop=0; // top row
unsigned int cBottom=0; // bottom row
unsigned int cLeft=0; // left column
unsigned int cRight=0; // right column
// and choose that side for reduction where mose exterior pixels occured (that's the heuristic)

for(y=0, x=0 ; x<sub.cols; ++x)
{
// if there is an exterior part in the interior we have to move the top side of the rect a bit to the bottom
if(sub.at<unsigned char>(y,x) == 0)
{
returnVal = false;
++cTop;
}
}

for(y=sub.rows-1, x=0; x<sub.cols; ++x)
{
// if there is an exterior part in the interior we have to move the bottom side of the rect a bit to the top
if(sub.at<unsigned char>(y,x) == 0)
{
returnVal = false;
++cBottom;
}
}

for(y=0, x=0 ; y<sub.rows; ++y)
{
// if there is an exterior part in the interior
if(sub.at<unsigned char>(y,x) == 0)
{
returnVal = false;
++cLeft;
}
}

for(x=sub.cols-1, y=0; y<sub.rows; ++y)
{
// if there is an exterior part in the interior
if(sub.at<unsigned char>(y,x) == 0)
{
returnVal = false;
++cRight;
}
}

// that part is ugly and maybe not correct, didn't check whether all possible combinations are handled. Check that one please. The idea is to set `top = 1` iff it's better to reduce the rect at the top than anywhere else.
if(cTop > cBottom)
{
if(cTop > cLeft)
if(cTop > cRight)
top = 1;
}
else
if(cBottom > cLeft)
if(cBottom > cRight)
bottom = 1;

if(cLeft >= cRight)
{
if(cLeft >= cBottom)
if(cLeft >= cTop)
left = 1;
}
else
if(cRight >= cTop)
if(cRight >= cBottom)
right = 1;

return returnVal;
}

bool sortX(cv::Point a, cv::Point b)
{
bool ret = false;
if(a.x == a.x)
if(b.x==b.x)
ret = a.x < b.x;

return ret;
}

bool sortY(cv::Point a, cv::Point b)
{
bool ret = false;
if(a.y == a.y)
if(b.y == b.y)
ret = a.y < b.y;

return ret;
}
``````
• The algorithm is not correct. Is fails for instance with the following polygon and returns a zero height bounding box: {x=186 y=205 } {x=464 y=43 } {x=378 y=427 } {x=3 y=325 } – MiB_Coder Sep 21 '18 at 15:31
• @MiB_Coder yes, for such a contour, the heuristic will not work at all. – Micka Sep 21 '18 at 15:41
• maybe have a look at this, too: stackoverflow.com/questions/2478447/… – Micka Jun 14 '19 at 21:37

A solution inspired by @micka answer, in python.

This is not a clever solution, and could be optimized, but it worked (slowly) in my case.

I modified you image to add a square, like in your example: see there

At the end, this code crop the white rectangle in this picture

Hope you will find it helpful!

``````import cv2

# Color it in gray
gray = cv2.cvtColor(input_picture, cv2.COLOR_BGR2GRAY)

# Create our mask by selecting the non-zero values of the picture

# Select the contour
# if your mask is incurved or if you want better results,
# you may want to use cv2.CHAIN_APPROX_NONE instead of cv2.CHAIN_APPROX_SIMPLE,
# but the rectangle search will be longer

cv2.drawContours(gray, cont, -1, (255,0,0), 1)
cv2.waitKey(0)

# Get all the points of the contour
contour = cont.reshape(len(cont),2)

# we assume a rectangle with at least two points on the contour gives a 'good enough' result
# get all possible rectangles based on this hypothesis
rect = []

for i in range(len(contour)):
x1, y1 = contour[i]
for j in range(len(contour)):
x2, y2 = contour[j]
area = abs(y2-y1)*abs(x2-x1)
rect.append(((x1,y1), (x2,y2), area))

# the first rect of all_rect has the biggest area, so it's the best solution if he fits in the picture
all_rect = sorted(rect, key = lambda x : x, reverse = True)

# we take the largest rectangle we've got, based on the value of the rectangle area
# only if the border of the rectangle is not in the black part

# if the list is not empty
if all_rect:

best_rect_found = False
index_rect = 0
nb_rect = len(all_rect)

# we check if the rectangle is  a good solution
while not best_rect_found and index_rect < nb_rect:

rect = all_rect[index_rect]
(x1, y1) = rect
(x2, y2) = rect

valid_rect = True

# we search a black area in the perimeter of the rectangle (vertical borders)
x = min(x1, x2)
while x <max(x1,x2)+1 and valid_rect:
# if we find a black pixel, that means a part of the rectangle is black
# so we don't keep this rectangle
valid_rect = False
x+=1

y = min(y1, y2)
while y <max(y1,y2)+1 and valid_rect:
valid_rect = False
y+=1

if valid_rect:
best_rect_found = True

index_rect+=1

if best_rect_found:

cv2.rectangle(gray, (x1,y1), (x2,y2), (255,0,0), 1)
cv2.imshow("Is that rectangle ok?",gray)
cv2.waitKey(0)

# Finally, we crop the picture and store it
result = input_picture[min(y1, y2):max(y1, y2), min(x1,x2):max(x1,x2)]

cv2.imwrite("Lena_cropped.png",result)
else:
print("No rectangle fitting into the area")

else:
print("No rectangle found")
``````

If your mask is incurved or simply if you want better results, you may want to use cv2.CHAIN_APPROX_NONE instead of cv2.CHAIN_APPROX_SIMPLE, but the rectangle search will take more time (because it's a quadratic solution in the best case).

In ImageMagick 6.9.10-30 (or 7.0.8.30) or higher, you can use the -trim function with a new define.

``````convert image.png -fuzz 5% -define trim:percent-background=0% -trim +repage result.png
``````

Or for the image presented below:

Input: ``````convert image2.png -bordercolor black -border 1 -define trim:percent-background=0% -trim +repage result2.png
``````