This approach works only on points. You don't need to create masks for this.

The main idea is:

- Find defects on contour
- If I find at least two defects, find the two closest defects
- Remove from the contour the points between the two closest defects
- Restart from 1 on the new contour

I get the following results. As you can see, it has some drawbacks for *smooth* defects (e.g. 7th image), but works pretty good for clearly visible defects. I don't know if this will solve your problem, but can be a starting point. In practice should be quite fast (you can surely optimize the code below, specially the `removeFromContour`

function). Also, the only parameter of this approach is the amount of the convexity defect, so it works well with both small and big defecting blobs.

```
#include <opencv2/opencv.hpp>
using namespace cv;
using namespace std;
int ed2(const Point& lhs, const Point& rhs)
{
return (lhs.x - rhs.x)*(lhs.x - rhs.x) + (lhs.y - rhs.y)*(lhs.y - rhs.y);
}
vector<Point> removeFromContour(const vector<Point>& contour, const vector<int>& defectsIdx)
{
int minDist = INT_MAX;
int startIdx;
int endIdx;
// Find nearest defects
for (int i = 0; i < defectsIdx.size(); ++i)
{
for (int j = i + 1; j < defectsIdx.size(); ++j)
{
float dist = ed2(contour[defectsIdx[i]], contour[defectsIdx[j]]);
if (minDist > dist)
{
minDist = dist;
startIdx = defectsIdx[i];
endIdx = defectsIdx[j];
}
}
}
// Check if intervals are swapped
if (startIdx <= endIdx)
{
int len1 = endIdx - startIdx;
int len2 = contour.size() - endIdx + startIdx;
if (len2 < len1)
{
swap(startIdx, endIdx);
}
}
else
{
int len1 = startIdx - endIdx;
int len2 = contour.size() - startIdx + endIdx;
if (len1 < len2)
{
swap(startIdx, endIdx);
}
}
// Remove unwanted points
vector<Point> out;
if (startIdx <= endIdx)
{
out.insert(out.end(), contour.begin(), contour.begin() + startIdx);
out.insert(out.end(), contour.begin() + endIdx, contour.end());
}
else
{
out.insert(out.end(), contour.begin() + endIdx, contour.begin() + startIdx);
}
return out;
}
int main()
{
Mat1b img = imread("path_to_mask", IMREAD_GRAYSCALE);
Mat3b out;
cvtColor(img, out, COLOR_GRAY2BGR);
vector<vector<Point>> contours;
findContours(img.clone(), contours, RETR_EXTERNAL, CHAIN_APPROX_NONE);
vector<Point> pts = contours[0];
vector<int> hullIdx;
convexHull(pts, hullIdx, false);
vector<Vec4i> defects;
convexityDefects(pts, hullIdx, defects);
while (true)
{
// For debug
Mat3b dbg;
cvtColor(img, dbg, COLOR_GRAY2BGR);
vector<vector<Point>> tmp = {pts};
drawContours(dbg, tmp, 0, Scalar(255, 127, 0));
vector<int> defectsIdx;
for (const Vec4i& v : defects)
{
float depth = float(v[3]) / 256.f;
if (depth > 2) // filter defects by depth
{
// Defect found
defectsIdx.push_back(v[2]);
int startidx = v[0]; Point ptStart(pts[startidx]);
int endidx = v[1]; Point ptEnd(pts[endidx]);
int faridx = v[2]; Point ptFar(pts[faridx]);
line(dbg, ptStart, ptEnd, Scalar(255, 0, 0), 1);
line(dbg, ptStart, ptFar, Scalar(0, 255, 0), 1);
line(dbg, ptEnd, ptFar, Scalar(0, 0, 255), 1);
circle(dbg, ptFar, 4, Scalar(127, 127, 255), 2);
}
}
if (defectsIdx.size() < 2)
{
break;
}
// If I have more than two defects, remove the points between the two nearest defects
pts = removeFromContour(pts, defectsIdx);
convexHull(pts, hullIdx, false);
convexityDefects(pts, hullIdx, defects);
}
// Draw result contour
vector<vector<Point>> tmp = { pts };
drawContours(out, tmp, 0, Scalar(0, 0, 255), 1);
imshow("Result", out);
waitKey();
return 0;
}
```

**UPDATE**

Working on an approximated contour (e.g. using `CHAIN_APPROX_SIMPLE`

in `findContours`

) may be faster, but the length of contours must be computed using `arcLength()`

.

This is the snippet to replace in the *swapping* part of `removeFromContour`

:

```
// Check if intervals are swapped
if (startIdx <= endIdx)
{
//int len11 = endIdx - startIdx;
vector<Point> inside(contour.begin() + startIdx, contour.begin() + endIdx);
int len1 = (inside.empty()) ? 0 : arcLength(inside, false);
//int len22 = contour.size() - endIdx + startIdx;
vector<Point> outside1(contour.begin(), contour.begin() + startIdx);
vector<Point> outside2(contour.begin() + endIdx, contour.end());
int len2 = (outside1.empty() ? 0 : arcLength(outside1, false)) + (outside2.empty() ? 0 : arcLength(outside2, false));
if (len2 < len1)
{
swap(startIdx, endIdx);
}
}
else
{
//int len1 = startIdx - endIdx;
vector<Point> inside(contour.begin() + endIdx, contour.begin() + startIdx);
int len1 = (inside.empty()) ? 0 : arcLength(inside, false);
//int len2 = contour.size() - startIdx + endIdx;
vector<Point> outside1(contour.begin(), contour.begin() + endIdx);
vector<Point> outside2(contour.begin() + startIdx, contour.end());
int len2 = (outside1.empty() ? 0 : arcLength(outside1, false)) + (outside2.empty() ? 0 : arcLength(outside2, false));
if (len1 < len2)
{
swap(startIdx, endIdx);
}
}
```

`convexityDefects`

? docs.opencv.org/2.4/modules/imgproc/doc/…