protected static MatOfPoint convertIndexToPoint(MatOfInt index, MatOfPoint contour)
{
Point[] arrPoint = contour.toArray();
int[] arrIndex = index.toArray();
Point[] arrResult = new Point[arrIndex.Length];
for (int i = 0; i < arrIndex.Length; i++)
{
arrResult[i] = arrPoint[arrIndex[i]];
}
MatOfPoint hull = new MatOfPoint();
hull.fromArray(arrResult);
return(hull);
}
private void EstimateHand(Mat mat, List <MatOfPoint> contours, RecordHandDetectResult resultSetter)
{
//画像処理としてはcontourがあったが、今調べてる側については
if (contours.Count == 0)
{
resultSetter.HasValidHandArea = false;
return;
}
var contour = SelectLargestContour(contours);
var boundRect = Imgproc.boundingRect(contour);
//画像の下側で手首の凹み部分を検出することがあるのを、指の凹みと誤認識しないためのガードです。
double defectMinY = boundRect.y + boundRect.height * 0.7;
var pointMat = new MatOfPoint2f();
Imgproc.approxPolyDP(new MatOfPoint2f(contour.toArray()), pointMat, 3, true);
contour = new MatOfPoint(pointMat.toArray());
var handArea = Imgproc.minAreaRect(pointMat);
var handAreaCenter = handArea.center;
var handAreaSize = handArea.size;
//方向固定のBoundを使うとこう。
resultSetter.HandAreaCenter = new Vector2(boundRect.x + boundRect.width / 2, boundRect.y + boundRect.height / 2);
resultSetter.HandAreaSize = new Vector2(boundRect.width, boundRect.height);
resultSetter.HandAreaRotation = (float)handArea.angle;
//OBBを使うとこうなるが、これだけだとangleが45度超えてるときの挙動が直感に反する事があるので要注意
// resultSetter.HandAreaCenter = new Vector2((float)handAreaCenter.x, (float)handAreaCenter.y);
// resultSetter.HandAreaSize = new Vector2((float)handAreaSize.width, (float)handAreaSize.height);
// resultSetter.HandAreaRotation = (float)handArea.angle;
Imgproc.convexHull(contour, _hullIndices);
var hullIndicesArray = _hullIndices.toArray();
//通常ありえないが、凸包がちゃんと作れてないケース
if (hullIndicesArray.Length < 3)
{
resultSetter.HasValidHandArea = false;
return;
}
UpdateConvexityDefection(contour, _hullIndices, defectMinY, resultSetter);
}
private void Find4PointContours(Mat image, List <MatOfPoint> contours)
{
contours.Clear();
List <MatOfPoint> tmp_contours = new List <MatOfPoint>();
Mat hierarchy = new Mat();
Imgproc.findContours(image, tmp_contours, hierarchy, Imgproc.RETR_EXTERNAL, Imgproc.CHAIN_APPROX_SIMPLE);
foreach (var cnt in tmp_contours)
{
MatOfInt hull = new MatOfInt();
Imgproc.convexHull(cnt, hull, false);
Point[] cnt_arr = cnt.toArray();
int[] hull_arr = hull.toArray();
Point[] pts = new Point[hull_arr.Length];
for (int i = 0; i < hull_arr.Length; i++)
{
pts[i] = cnt_arr[hull_arr[i]];
}
MatOfPoint2f ptsFC2 = new MatOfPoint2f(pts);
MatOfPoint2f approxFC2 = new MatOfPoint2f();
MatOfPoint approxSC2 = new MatOfPoint();
double arclen = Imgproc.arcLength(ptsFC2, true);
Imgproc.approxPolyDP(ptsFC2, approxFC2, 0.01 * arclen, true);
approxFC2.convertTo(approxSC2, CvType.CV_32S);
if (approxSC2.size().area() != 4)
{
continue;
}
contours.Add(approxSC2);
}
}
/// <summary>
/// Hands the pose estimation process.
/// </summary>
public void handPoseEstimationProcess(Mat rgbaMat)
{
//Imgproc.blur(mRgba, mRgba, new Size(5,5));
Imgproc.GaussianBlur(rgbaMat, rgbaMat, new OpenCVForUnity.Size(3, 3), 1, 1);
//Imgproc.medianBlur(mRgba, mRgba, 3);
if (!isColorSelected)
{
return;
}
List <MatOfPoint> contours = detector.getContours();
detector.process(rgbaMat);
// Debug.Log ("Contours count: " + contours.Count);
if (contours.Count <= 0)
{
return;
}
RotatedRect rect = Imgproc.minAreaRect(new MatOfPoint2f(contours [0].toArray()));
double boundWidth = rect.size.width;
double boundHeight = rect.size.height;
int boundPos = 0;
for (int i = 1; i < contours.Count; i++)
{
rect = Imgproc.minAreaRect(new MatOfPoint2f(contours [i].toArray()));
if (rect.size.width * rect.size.height > boundWidth * boundHeight)
{
boundWidth = rect.size.width;
boundHeight = rect.size.height;
boundPos = i;
}
}
OpenCVForUnity.Rect boundRect = Imgproc.boundingRect(new MatOfPoint(contours [boundPos].toArray()));
Core.rectangle(rgbaMat, boundRect.tl(), boundRect.br(), CONTOUR_COLOR_WHITE, 2, 8, 0);
// Debug.Log (
// " Row start [" +
// (int)boundRect.tl ().y + "] row end [" +
// (int)boundRect.br ().y + "] Col start [" +
// (int)boundRect.tl ().x + "] Col end [" +
// (int)boundRect.br ().x + "]");
double a = boundRect.br().y - boundRect.tl().y;
a = a * 0.7;
a = boundRect.tl().y + a;
// Debug.Log (
// " A [" + a + "] br y - tl y = [" + (boundRect.br ().y - boundRect.tl ().y) + "]");
//Core.rectangle( mRgba, boundRect.tl(), boundRect.br(), CONTOUR_COLOR, 2, 8, 0 );
Core.rectangle(rgbaMat, boundRect.tl(), new Point(boundRect.br().x, a), CONTOUR_COLOR, 2, 8, 0);
MatOfPoint2f pointMat = new MatOfPoint2f();
Imgproc.approxPolyDP(new MatOfPoint2f(contours [boundPos].toArray()), pointMat, 3, true);
contours [boundPos] = new MatOfPoint(pointMat.toArray());
MatOfInt hull = new MatOfInt();
MatOfInt4 convexDefect = new MatOfInt4();
Imgproc.convexHull(new MatOfPoint(contours [boundPos].toArray()), hull);
if (hull.toArray().Length < 3)
{
return;
}
Imgproc.convexityDefects(new MatOfPoint(contours [boundPos].toArray()), hull, convexDefect);
List <MatOfPoint> hullPoints = new List <MatOfPoint> ();
List <Point> listPo = new List <Point> ();
for (int j = 0; j < hull.toList().Count; j++)
{
listPo.Add(contours [boundPos].toList() [hull.toList() [j]]);
}
MatOfPoint e = new MatOfPoint();
e.fromList(listPo);
hullPoints.Add(e);
List <MatOfPoint> defectPoints = new List <MatOfPoint> ();
List <Point> listPoDefect = new List <Point> ();
for (int j = 0; j < convexDefect.toList().Count; j = j + 4)
{
Point farPoint = contours [boundPos].toList() [convexDefect.toList() [j + 2]];
int depth = convexDefect.toList() [j + 3];
if (depth > threasholdSlider.value && farPoint.y < a)
{
listPoDefect.Add(contours [boundPos].toList() [convexDefect.toList() [j + 2]]);
}
// Debug.Log ("defects [" + j + "] " + convexDefect.toList () [j + 3]);
}
MatOfPoint e2 = new MatOfPoint();
e2.fromList(listPo);
defectPoints.Add(e2);
// Debug.Log ("hull: " + hull.toList ());
// Debug.Log ("defects: " + convexDefect.toList ());
Imgproc.drawContours(rgbaMat, hullPoints, -1, CONTOUR_COLOR, 3);
// int defectsTotal = (int)convexDefect.total();
// Debug.Log ("Defect total " + defectsTotal);
this.numberOfFingers = listPoDefect.Count;
if (this.numberOfFingers > 5)
{
this.numberOfFingers = 5;
}
// Debug.Log ("numberOfFingers " + numberOfFingers);
// Core.putText (mRgba, "" + numberOfFingers, new Point (mRgba.cols () / 2, mRgba.rows () / 2), Core.FONT_HERSHEY_PLAIN, 4.0, new Scalar (255, 255, 255, 255), 6, Core.LINE_AA, false);
numberOfFingersText.text = numberOfFingers.ToString();
foreach (Point p in listPoDefect)
{
Core.circle(rgbaMat, p, 6, new Scalar(255, 0, 255, 255), -1);
}
}
/// <summary>
/// Recognizes the markers.
/// </summary>
/// <param name="grayscale">Grayscale.</param>
/// <param name="detectedMarkers">Detected markers.</param>
void recognizeMarkers(Mat grayscale, List <Marker> detectedMarkers)
{
List <Marker> goodMarkers = new List <Marker> ();
// Identify the markers
for (int i = 0; i < detectedMarkers.Count; i++)
{
Marker marker = detectedMarkers [i];
// Find the perspective transformation that brings current marker to rectangular form
Mat markerTransform = Imgproc.getPerspectiveTransform(new MatOfPoint2f(marker.points.toArray()), m_markerCorners2d);
// Transform image to get a canonical marker image
Imgproc.warpPerspective(grayscale, canonicalMarkerImage, markerTransform, markerSize);
for (int p = 0; p < m_markerDesigns.Count; p++)
{
MatOfInt nRotations = new MatOfInt(0);
int id = Marker.getMarkerId(canonicalMarkerImage, nRotations, m_markerDesigns [p]);
if (id != -1)
{
marker.id = id;
// Debug.Log ("id " + id);
//sort the points so that they are always in the same order no matter the camera orientation
List <Point> MarkerPointsList = marker.points.toList();
// std::rotate(marker.points.begin(), marker.points.begin() + 4 - nRotations, marker.points.end());
MarkerPointsList = MarkerPointsList.Skip(4 - nRotations.toArray() [0]).Concat(MarkerPointsList.Take(4 - nRotations.toArray() [0])).ToList();
marker.points.fromList(MarkerPointsList);
goodMarkers.Add(marker);
}
nRotations.Dispose();
}
}
// Debug.Log ("goodMarkers " + goodMarkers.Count);
// Refine marker corners using sub pixel accuracy
if (goodMarkers.Count > 0)
{
List <Point> preciseCornersPoint = new List <Point> (4 * goodMarkers.Count);
for (int i = 0; i < preciseCornersPoint.Capacity; i++)
{
preciseCornersPoint.Add(new Point(0, 0));
}
for (int i = 0; i < goodMarkers.Count; i++)
{
Marker marker = goodMarkers [i];
List <Point> markerPointsList = marker.points.toList();
for (int c = 0; c < 4; c++)
{
preciseCornersPoint [i * 4 + c] = markerPointsList [c];
}
}
MatOfPoint2f preciseCorners = new MatOfPoint2f(preciseCornersPoint.ToArray());
TermCriteria termCriteria = new TermCriteria(TermCriteria.MAX_ITER | TermCriteria.EPS, 30, 0.01);
Imgproc.cornerSubPix(grayscale, preciseCorners, new Size(5, 5), new Size(-1, -1), termCriteria);
preciseCornersPoint = preciseCorners.toList();
// Copy refined corners position back to markers
for (int i = 0; i < goodMarkers.Count; i++)
{
Marker marker = goodMarkers [i];
List <Point> markerPointsList = marker.points.toList();
for (int c = 0; c < 4; c++)
{
markerPointsList [c] = preciseCornersPoint [i * 4 + c];
}
}
preciseCorners.Dispose();
}
detectedMarkers.Clear();
detectedMarkers.AddRange(goodMarkers);
}
/// <summary>
/// Hands the pose estimation process.
/// </summary>
public void handPoseEstimationProcess(Mat rgbaMat)
{
//Imgproc.blur(mRgba, mRgba, new Size(5,5));
Imgproc.GaussianBlur (rgbaMat, rgbaMat, new OpenCVForUnity.Size (3, 3), 1, 1);
//Imgproc.medianBlur(mRgba, mRgba, 3);
if (!isColorSelected)
return;
List<MatOfPoint> contours = detector.getContours ();
detector.process (rgbaMat);
// Debug.Log ("Contours count: " + contours.Count);
if (contours.Count <= 0) {
return;
}
RotatedRect rect = Imgproc.minAreaRect (new MatOfPoint2f (contours [0].toArray ()));
double boundWidth = rect.size.width;
double boundHeight = rect.size.height;
int boundPos = 0;
for (int i = 1; i < contours.Count; i++) {
rect = Imgproc.minAreaRect (new MatOfPoint2f (contours [i].toArray ()));
if (rect.size.width * rect.size.height > boundWidth * boundHeight) {
boundWidth = rect.size.width;
boundHeight = rect.size.height;
boundPos = i;
}
}
OpenCVForUnity.Rect boundRect = Imgproc.boundingRect (new MatOfPoint (contours [boundPos].toArray ()));
Imgproc.rectangle (rgbaMat, boundRect.tl (), boundRect.br (), CONTOUR_COLOR_WHITE, 2, 8, 0);
// Debug.Log (
// " Row start [" +
// (int)boundRect.tl ().y + "] row end [" +
// (int)boundRect.br ().y + "] Col start [" +
// (int)boundRect.tl ().x + "] Col end [" +
// (int)boundRect.br ().x + "]");
double a = boundRect.br ().y - boundRect.tl ().y;
a = a * 0.7;
a = boundRect.tl ().y + a;
// Debug.Log (
// " A [" + a + "] br y - tl y = [" + (boundRect.br ().y - boundRect.tl ().y) + "]");
//Core.rectangle( mRgba, boundRect.tl(), boundRect.br(), CONTOUR_COLOR, 2, 8, 0 );
Imgproc.rectangle (rgbaMat, boundRect.tl (), new Point (boundRect.br ().x, a), CONTOUR_COLOR, 2, 8, 0);
MatOfPoint2f pointMat = new MatOfPoint2f ();
Imgproc.approxPolyDP (new MatOfPoint2f (contours [boundPos].toArray ()), pointMat, 3, true);
contours [boundPos] = new MatOfPoint (pointMat.toArray ());
MatOfInt hull = new MatOfInt ();
MatOfInt4 convexDefect = new MatOfInt4 ();
Imgproc.convexHull (new MatOfPoint (contours [boundPos].toArray ()), hull);
if (hull.toArray ().Length < 3)
return;
Imgproc.convexityDefects (new MatOfPoint (contours [boundPos] .toArray ()), hull, convexDefect);
List<MatOfPoint> hullPoints = new List<MatOfPoint> ();
List<Point> listPo = new List<Point> ();
for (int j = 0; j < hull.toList().Count; j++) {
listPo.Add (contours [boundPos].toList () [hull.toList () [j]]);
}
MatOfPoint e = new MatOfPoint ();
e.fromList (listPo);
hullPoints.Add (e);
List<MatOfPoint> defectPoints = new List<MatOfPoint> ();
List<Point> listPoDefect = new List<Point> ();
for (int j = 0; j < convexDefect.toList().Count; j = j+4) {
Point farPoint = contours [boundPos].toList () [convexDefect.toList () [j + 2]];
int depth = convexDefect.toList () [j + 3];
if (depth > threasholdSlider.value && farPoint.y < a) {
listPoDefect.Add (contours [boundPos].toList () [convexDefect.toList () [j + 2]]);
}
// Debug.Log ("defects [" + j + "] " + convexDefect.toList () [j + 3]);
}
MatOfPoint e2 = new MatOfPoint ();
e2.fromList (listPo);
defectPoints.Add (e2);
// Debug.Log ("hull: " + hull.toList ());
// Debug.Log ("defects: " + convexDefect.toList ());
Imgproc.drawContours (rgbaMat, hullPoints, -1, CONTOUR_COLOR, 3);
// int defectsTotal = (int)convexDefect.total();
// Debug.Log ("Defect total " + defectsTotal);
this.numberOfFingers = listPoDefect.Count;
if (this.numberOfFingers > 5)
this.numberOfFingers = 5;
// Debug.Log ("numberOfFingers " + numberOfFingers);
// Core.putText (mRgba, "" + numberOfFingers, new Point (mRgba.cols () / 2, mRgba.rows () / 2), Core.FONT_HERSHEY_PLAIN, 4.0, new Scalar (255, 255, 255, 255), 6, Core.LINE_AA, false);
numberOfFingersText.text = numberOfFingers.ToString ();
foreach (Point p in listPoDefect) {
Imgproc.circle (rgbaMat, p, 6, new Scalar (255, 0, 255, 255), -1);
}
}
/// <summary>
/// Recognizes the markers.
/// </summary>
/// <param name="grayscale">Grayscale.</param>
/// <param name="detectedMarkers">Detected markers.</param>
void recognizeMarkers (Mat grayscale, List<Marker> detectedMarkers)
{
List<Marker> goodMarkers = new List<Marker> ();
// Identify the markers
for (int i=0; i<detectedMarkers.Count; i++) {
Marker marker = detectedMarkers [i];
// Find the perspective transformation that brings current marker to rectangular form
Mat markerTransform = Imgproc.getPerspectiveTransform (new MatOfPoint2f (marker.points.toArray ()), m_markerCorners2d);
// Transform image to get a canonical marker image
Imgproc.warpPerspective (grayscale, canonicalMarkerImage, markerTransform, markerSize);
MatOfInt nRotations = new MatOfInt (0);
int id = Marker.getMarkerId (canonicalMarkerImage, nRotations, m_markerDesign);
if (id != - 1) {
marker.id = id;
// Debug.Log ("id " + id);
//sort the points so that they are always in the same order no matter the camera orientation
List<Point> MarkerPointsList = marker.points.toList ();
// std::rotate(marker.points.begin(), marker.points.begin() + 4 - nRotations, marker.points.end());
MarkerPointsList = MarkerPointsList.Skip (4 - nRotations.toArray () [0]).Concat (MarkerPointsList.Take (4 - nRotations.toArray () [0])).ToList ();
marker.points.fromList (MarkerPointsList);
goodMarkers.Add (marker);
}
nRotations.Dispose ();
}
// Debug.Log ("goodMarkers " + goodMarkers.Count);
// Refine marker corners using sub pixel accuracy
if (goodMarkers.Count > 0) {
List<Point> preciseCornersPoint = new List<Point> (4 * goodMarkers.Count);
for (int i = 0; i < preciseCornersPoint.Capacity; i++) {
preciseCornersPoint.Add (new Point (0, 0));
}
for (int i=0; i<goodMarkers.Count; i++) {
Marker marker = goodMarkers [i];
List<Point> markerPointsList = marker.points.toList ();
for (int c = 0; c <4; c++) {
preciseCornersPoint [i * 4 + c] = markerPointsList [c];
}
}
MatOfPoint2f preciseCorners = new MatOfPoint2f (preciseCornersPoint.ToArray ());
TermCriteria termCriteria = new TermCriteria (TermCriteria.MAX_ITER | TermCriteria.EPS, 30, 0.01);
Imgproc.cornerSubPix (grayscale, preciseCorners, new Size (5, 5), new Size (-1, -1), termCriteria);
preciseCornersPoint = preciseCorners.toList ();
// Copy refined corners position back to markers
for (int i=0; i<goodMarkers.Count; i++) {
Marker marker = goodMarkers [i];
List<Point> markerPointsList = marker.points.toList ();
for (int c=0; c<4; c++) {
markerPointsList [c] = preciseCornersPoint [i * 4 + c];
}
}
preciseCorners.Dispose ();
}
detectedMarkers.Clear ();
detectedMarkers.AddRange (goodMarkers);
}
public int getAnswerNumber(Mat align, Rect r)
{
Mat roi = new Mat(align, r);
Mat roi_gray = new Mat(), roi_edges = new Mat();
Imgproc.cvtColor(roi, roi_gray, Imgproc.COLOR_RGB2GRAY);
Imgproc.Canny(roi_gray, roi_edges, 200, 200);
// Mat element = Imgproc.getStructuringElement(Imgproc.MORPH_ELLIPSE, new Size(2 + 1, 2 + 1), new Point(1, 1));
// Imgproc.dilate(roi_edges, roi_edges, element);
//Shape detection
List <MatOfPoint> contours = new List <MatOfPoint>();
Mat hierarchy = new Mat();
Imgproc.findContours(roi_edges, contours, hierarchy, Imgproc.RETR_TREE, Imgproc.CHAIN_APPROX_SIMPLE, new Point(0, 0));
List <MatOfPoint> hulls = new List <MatOfPoint>();
for (int i = 0; i < contours.Count; i++)
{
MatOfInt hull_temp = new MatOfInt();
Imgproc.convexHull(contours[i], hull_temp);
int[] arrIndex = hull_temp.toArray();
Point[] arrContour = contours[i].toArray();
Point[] arrPoints = new Point[arrIndex.Length];
for (int k = 0; k < arrIndex.Length; k++)
{
arrPoints[k] = arrContour[arrIndex[k]];
}
MatOfPoint temp = new MatOfPoint();
temp.fromArray(arrPoints);
//Filter outliers
if (Imgproc.contourArea(temp) > 40 && Imgproc.contourArea(temp) < 200)
{
hulls.Add(temp);
}
}
List <MatOfPoint2f> hull2f = new List <MatOfPoint2f>();
for (int i = 0; i < hulls.Count; i++)
{
MatOfPoint2f newPoint = new MatOfPoint2f(hulls[i].toArray());
hull2f.Add(newPoint);
}
for (int i = 0; i < hulls.Count; i++)
{
//Approximate polygon
MatOfPoint2f approx = new MatOfPoint2f();
Imgproc.approxPolyDP(hull2f[i], approx, 0.01 * Imgproc.arcLength(hull2f[i], true), true);
List <Point> approx_polygon = approx.toList();
approx_polygon = Scannerproc.filterPolygon(approx_polygon);
double area = Imgproc.contourArea(approx);
//Center of mass
int cx = 0,
cy = 0;
for (int k = 0; k < approx_polygon.Count; k++)
{
cx += (int)approx_polygon[k].x;
cy += (int)approx_polygon[k].y;
}
cx /= approx_polygon.Count;
cy /= approx_polygon.Count;
// Imgproc.circle(roi, new Point(cx, cy), 5, new Scalar(255), -1);
// Texture2D tex = new Texture2D(roi.width(), roi.height(), TextureFormat.RGB24, false);
// Utils.matToTexture2D(roi, tex);
// byte[] bytes1 = tex.EncodeToJPG();
// File.WriteAllBytes("D:/2019/OMR/" + "test.png", bytes1);
Point pos1 = new Point((roi.width() * 1) / 10, cy);
Point pos2 = new Point((roi.width() * 3) / 10, cy);
Point pos3 = new Point((roi.width() * 5) / 10, cy);
Point pos4 = new Point((roi.width() * 7) / 10, cy);
Point pos5 = new Point((roi.width() * 9) / 10, cy);
Point nowPos = new Point(cx, cy);
double[] dist = new double[5];
dist[0] = Scannerproc.distanceTwoPoints(pos1, nowPos);
dist[1] = Scannerproc.distanceTwoPoints(pos2, nowPos);
dist[2] = Scannerproc.distanceTwoPoints(pos3, nowPos);
dist[3] = Scannerproc.distanceTwoPoints(pos4, nowPos);
dist[4] = Scannerproc.distanceTwoPoints(pos5, nowPos);
int id = -1;
double min_dist = 999999;
for (int t = 0; t < 5; t++)
{
if (dist[t] < min_dist)
{
min_dist = dist[t];
id = t;
}
}
return(id + 1);
//return plusPoints(tl, new Point(cx, cy));
}
return(0);
}
public void getAnswerNumber(Mat align)
{
Mat align_gray = new Mat(), align_edges = new Mat();
Imgproc.cvtColor(align, align_gray, Imgproc.COLOR_RGB2GRAY);
Imgproc.Canny(align_gray, align_edges, 50, 50);
Mat element = Imgproc.getStructuringElement(Imgproc.MORPH_ELLIPSE, new Size(2 + 1, 2 + 1), new Point(1, 1));
Imgproc.dilate(align_edges, align_edges, element);
//Shape detection
List <MatOfPoint> contours = new List <MatOfPoint>();
Mat hierarchy = new Mat();
Imgproc.findContours(align_edges, contours, hierarchy, Imgproc.RETR_TREE, Imgproc.CHAIN_APPROX_SIMPLE, new Point(0, 0));
List <MatOfPoint> hulls = new List <MatOfPoint>();
//Texture2D tex = new Texture2D(align_edges.width(), align_edges.height(), TextureFormat.RGB24, false);
//Utils.matToTexture2D(align_edges, tex);
//byte[] bytes1 = tex.EncodeToJPG();
//File.WriteAllBytes("D:/2019/OMR/" + "test.png", bytes1);
for (int i = 0; i < contours.Count; i++)
{
MatOfInt hull_temp = new MatOfInt();
Imgproc.convexHull(contours[i], hull_temp);
int[] arrIndex = hull_temp.toArray();
Point[] arrContour = contours[i].toArray();
Point[] arrPoints = new Point[arrIndex.Length];
for (int k = 0; k < arrIndex.Length; k++)
{
arrPoints[k] = arrContour[arrIndex[k]];
}
MatOfPoint temp = new MatOfPoint();
temp.fromArray(arrPoints);
//Filter outliers
if (Imgproc.contourArea(temp) > 90000 && Imgproc.contourArea(temp) < 110000)
{
hulls.Add(temp);
}
}
List <MatOfPoint2f> hull2f = new List <MatOfPoint2f>();
for (int i = 0; i < hulls.Count; i++)
{
MatOfPoint2f newPoint = new MatOfPoint2f(hulls[i].toArray());
hull2f.Add(newPoint);
}
List <Rect> rects = new List <Rect>();
for (int i = 0; i < hulls.Count; i++)
{
//Approximate polygon
MatOfPoint2f approx = new MatOfPoint2f();
Imgproc.approxPolyDP(hull2f[i], approx, 0.01 * Imgproc.arcLength(hull2f[i], true), true);
List <Point> approx_polygon = approx.toList();
approx_polygon = Scannerproc.filterPolygon(approx_polygon);
double area = Imgproc.contourArea(approx);
if (Scannerproc.isSquare(approx_polygon))
{
Rect r = Imgproc.boundingRect(new MatOfPoint(approx_polygon.ToArray()));
bool isContain = false;
for (int k = 0; k < rects.Count; k++)
{
if (Scannerproc.distanceTwoPoints(rects[k].tl(), r.tl()) < 100)
{
//if (rects[k].contains(r) || r.contains(rects[k]))
isContain = true;
}
}
if (!isContain)
{
rects.Add(r);
// Imgproc.rectangle(align, r.tl(), r.br(), new Scalar(255, 0, 0, 255), 3);
for (int j = 1; j < 21; j++)
{
Rect roi = new Rect((int)r.tl().x + (int)((r.width * 1.3) / 6), (int)r.tl().y + (r.height / 21) * j, (int)((r.width * 4.7) / 6), r.height / 21);
int num = getAnswerNumber(align, roi);
if (num != 0)
{
Imgproc.putText(align, " " + num, new Point(roi.x - 40, roi.y + 25), 1, 2, new Scalar(255, 0, 0, 255), 3, Core.LINE_AA, false);
Imgproc.rectangle(align, roi.tl(), roi.br(), new Scalar(0, 255, 0, 255), 2);
}
}
}
}
//Center of mass
int cx = 0,
cy = 0;
for (int k = 0; k < approx_polygon.Count; k++)
{
cx += (int)approx_polygon[k].x;
cy += (int)approx_polygon[k].y;
}
cx /= approx_polygon.Count;
cy /= approx_polygon.Count;
// Imgproc.circle(roi, new Point(cx, cy), 5, new Scalar(255), -1);
}
if (rects.Count == 4)
{
nowDetected = false;
}
}
/// <summary>
/// Get result form all output
/// </summary>
/// <param name="output"></param>
/// <param name="image"></param>
/// <param name="threshold"></param>
/// <param name="nmsThreshold">threshold for nms</param>
/// <param name="nms">Enable Non-maximum suppression or not</param>
private static void GetResult(IEnumerable <Mat> output, Mat image, float threshold, float nmsThreshold, bool nms = true)
{
//for nms
List <int> classIds = new List <int>();
List <float> confidences = new List <float>();
List <float> probabilities = new List <float>();
List <Rect2d> boxes = new List <Rect2d>();
var w = image.width();
var h = image.height();
/*
* YOLO3 COCO trainval output
* 0 1 : center 2 3 : w/h
* 4 : confidence 5 ~ 84 : class probability
*/
const int prefix = 5; //skip 0~4
foreach (Mat prob in output)
{
for (int i = 0; i < prob.rows(); i++)
{
var confidence = (float)prob.get(i, 4)[0];
if (confidence > threshold)
{
//get classes probability
Core.MinMaxLocResult minAndMax = Core.minMaxLoc(prob.row(i).colRange(prefix, prob.cols()));
int classes = (int)minAndMax.maxLoc.x;
var probability = (float)prob.get(i, classes + prefix)[0];
if (probability > threshold) //more accuracy, you can cancel it
{
//get center and width/height
float centerX = (float)prob.get(i, 0)[0] * w;
float centerY = (float)prob.get(i, 1)[0] * h;
float width = (float)prob.get(i, 2)[0] * w;
float height = (float)prob.get(i, 3)[0] * h;
if (!nms)
{
// draw result (if don't use NMSBoxes)
Draw(image, classes, confidence, probability, centerX, centerY, width, height);
continue;
}
//put data to list for NMSBoxes
classIds.Add(classes);
confidences.Add(confidence);
probabilities.Add(probability);
boxes.Add(new Rect2d(centerX, centerY, width, height));
}
}
}
}
if (!nms)
{
return;
}
//using non-maximum suppression to reduce overlapping low confidence box
MatOfRect2d bboxes = new MatOfRect2d();
MatOfFloat scores = new MatOfFloat();
MatOfInt indices = new MatOfInt();
bboxes.fromList(boxes);
scores.fromList(probabilities);
Dnn.NMSBoxes(bboxes, scores, threshold, nmsThreshold, indices);
int[] indicesA = indices.toArray();
foreach (var i in indicesA)
{
var box = boxes[i];
Draw(image, classIds[i], confidences[i], probabilities[i], box.x, box.y, box.width, box.height);
}
}
private void HandPoseEstimationProcess(Mat rgbaMat)
{
//Imgproc.blur(mRgba, mRgba, new Size(5,5));
Imgproc.GaussianBlur(rgbaMat, rgbaMat, new Size(3, 3), 1, 1);
//Imgproc.medianBlur(mRgba, mRgba, 3);
if (!isColorSelected)
{
return;
}
List <MatOfPoint> contours = detector.GetContours();
detector.Process(rgbaMat);
//Debug.Log ("Contours count: " + contours.Count);
if (contours.Count <= 0)
{
return;
}
RotatedRect rect = Imgproc.minAreaRect(new MatOfPoint2f(contours[0].toArray()));
double boundWidth = rect.size.width;
double boundHeight = rect.size.height;
int boundPos = 0;
for (int i = 1; i < contours.Count; i++)
{
rect = Imgproc.minAreaRect(new MatOfPoint2f(contours[i].toArray()));
if (rect.size.width * rect.size.height > boundWidth * boundHeight)
{
boundWidth = rect.size.width;
boundHeight = rect.size.height;
boundPos = i;
}
}
MatOfPoint contour = contours[boundPos];
OpenCVForUnity.CoreModule.Rect boundRect = Imgproc.boundingRect(new MatOfPoint(contour.toArray()));
Imgproc.rectangle(rgbaMat, boundRect.tl(), boundRect.br(), CONTOUR_COLOR_WHITE, 2, 8, 0);
// Debug.Log (
// " Row start [" +
//(int)boundRect.tl ().y + "] row end [" +
// (int)boundRect.br ().y + "] Col start [" +
// (int)boundRect.tl ().x + "] Col end [" +
// (int)boundRect.br ().x + "]");
Point bottomLeft = new Point(boundRect.x, boundRect.y + boundRect.height);
Point topLeft = new Point(boundRect.x, boundRect.y);
Point bottomRight = new Point(boundRect.x + boundRect.width, boundRect.y + boundRect.height);
Point topRight = new Point(boundRect.x + boundRect.width, boundRect.y);
rectPoints = new MatOfPoint2f(new Point(boundRect.x, boundRect.y), //topleft
new Point(boundRect.x + boundRect.width, boundRect.y), //Top Right
new Point(boundRect.x + boundRect.width, boundRect.y + boundRect.height), //Bottom Right
new Point(boundRect.x, boundRect.y + boundRect.height) //Bottom Left
);
//double a = boundRect.br ().y - boundRect.tl ().y;
//a = a * 0.7;
//a = boundRect.tl ().y + a;
//Debug.Log (" A [" + a + "] br y - tl y = [" + (boundRect.br ().y - boundRect.tl ().y) + "]");
//Imgproc.rectangle (rgbaMat, boundRect.tl (), new Point (boundRect.br ().x, a), CONTOUR_COLOR, 2, 8, 0);
List <Point3> m_markerCorners3dList = new List <Point3>();
m_markerCorners3dList.Add(new Point3(-0.5f, -0.5f, 0)); //Top, Left (A)
m_markerCorners3dList.Add(new Point3(+0.5f, -0.5f, 0)); //Top, Right (B)
m_markerCorners3dList.Add(new Point3(+0.5f, +0.5f, 0)); //Bottom, Right (C)
m_markerCorners3dList.Add(new Point3(-0.5f, +0.5f, 0)); //Bottom, Left (D)
m_markerCorners3d.fromList(m_markerCorners3dList);
//estimate pose
Mat Rvec = new Mat();
Mat Tvec = new Mat();
Mat raux = new Mat();
Mat taux = new Mat();
Calib3d.solvePnP(m_markerCorners3d, rectPoints, camMatrix, distCoeff, raux, taux);
raux.convertTo(Rvec, CvType.CV_32F);
taux.convertTo(Tvec, CvType.CV_32F);
rotMat = new Mat(3, 3, CvType.CV_64FC1);
Calib3d.Rodrigues(Rvec, rotMat);
transformationM.SetRow(0, new Vector4((float)rotMat.get(0, 0)[0], (float)rotMat.get(0, 1)[0], (float)rotMat.get(0, 2)[0], (float)Tvec.get(0, 0)[0]));
transformationM.SetRow(1, new Vector4((float)rotMat.get(1, 0)[0], (float)rotMat.get(1, 1)[0], (float)rotMat.get(1, 2)[0], (float)Tvec.get(1, 0)[0]));
transformationM.SetRow(2, new Vector4((float)rotMat.get(2, 0)[0], (float)rotMat.get(2, 1)[0], (float)rotMat.get(2, 2)[0], (float)Tvec.get(2, 0)[0]));
transformationM.SetRow(3, new Vector4(0, 0, 0, 1));
//Debug.Log ("transformationM " + transformationM.ToString ());
Rvec.Dispose();
Tvec.Dispose();
raux.Dispose();
taux.Dispose();
rotMat.Dispose();
ARM = ARCamera.transform.localToWorldMatrix * invertYM * transformationM * invertZM;
//Debug.Log("arM " + ARM.ToString());
if (ARGameObject != null)
{
ARUtils.SetTransformFromMatrix(ARGameObject.transform, ref ARM);
if (deactivateCoroutine == null)
{
deactivateCoroutine = StartCoroutine(Wait(10.0f));
}
ARGameObject.SetActive(true);
}
//end pose estimation
MatOfPoint2f pointMat = new MatOfPoint2f();
Imgproc.approxPolyDP(new MatOfPoint2f(contour.toArray()), pointMat, 3, true);
contour = new MatOfPoint(pointMat.toArray());
MatOfInt hull = new MatOfInt();
MatOfInt4 convexDefect = new MatOfInt4();
Imgproc.convexHull(new MatOfPoint(contour.toArray()), hull);
if (hull.toArray().Length < 3)
{
return;
}
Imgproc.convexityDefects(new MatOfPoint(contour.toArray()), hull, convexDefect);
List <MatOfPoint> hullPoints = new List <MatOfPoint>();
List <Point> listPo = new List <Point>();
for (int j = 0; j < hull.toList().Count; j++)
{
listPo.Add(contour.toList()[hull.toList()[j]]);
}
MatOfPoint e = new MatOfPoint();
e.fromList(listPo);
hullPoints.Add(e);
List <Point> listPoDefect = new List <Point>();
if (convexDefect.rows() > 0)
{
List <int> convexDefectList = convexDefect.toList();
List <Point> contourList = contour.toList();
for (int j = 0; j < convexDefectList.Count; j = j + 4)
{
Point farPoint = contourList[convexDefectList[j + 2]];
int depth = convexDefectList[j + 3];
//if (depth > threasholdSlider.value && farPoint.y < a)
//{
// listPoDefect.Add(contourList[convexDefectList[j + 2]]);
//}
//Debug.Log ("convexDefectList [" + j + "] " + convexDefectList [j + 3]);
}
}
Debug.Log("hull: " + hull.toList());
if (convexDefect.rows() > 0)
{
Debug.Log("defects: " + convexDefect.toList());
}
//use these contours to do heart detection
Imgproc.drawContours(rgbaMat, hullPoints, -1, CONTOUR_COLOR, 3);
int defectsTotal = (int)convexDefect.total();
Debug.Log("Defect total " + defectsTotal);
this.numberOfFingers = listPoDefect.Count;
if (this.numberOfFingers > 5)
{
this.numberOfFingers = 5;
}
Debug.Log("numberOfFingers " + numberOfFingers);
Imgproc.putText(rgbaMat, "" + numberOfFingers, new Point(rgbaMat.cols() / 2, rgbaMat.rows() / 2), Imgproc.FONT_HERSHEY_PLAIN, 4.0, new Scalar(255, 255, 255, 255), 6, Imgproc.LINE_AA, false);
numberOfFingersText.text = numberOfFingers.ToString();
foreach (Point p in listPoDefect)
{
Imgproc.circle(rgbaMat, p, 6, new Scalar(255, 0, 255, 255), -1);
}
}
//public delegate void Process(int[] tgrdeteced);
void tagramDetect(Mat t_rgbaMat, Action <TangramResultModel, List <MyShape> > prc)
{
List <MyShape> lms = new List <MyShape>();
System.Diagnostics.Stopwatch watch = null;
long elapsedMs;
TangramResultModel trm = null;
Observable.Start(() =>
{
mut.WaitOne();
Imgproc.resize(t_rgbaMat, rgbaMat, new Size(nW_goc, nH_goc));
watch = System.Diagnostics.Stopwatch.StartNew();
if (warp != null)
{
warp.Init(rgbaMat);
Mat wMat = warp.warpPerspective(rgbaMat);
rgbaMat = wMat.submat(0, nH, 0, nW);
}
else
{
rgbaMat = rgbaMat.submat(0, nH, 0, nW);
}
all_thresh = Mat.zeros(nH, nW, CvType.CV_8UC3);
all_thresh_afct = Mat.zeros(nH, nW, CvType.CV_8UC3);
dbMat = Mat.zeros(nH, nW, CvType.CV_8UC3);
all_thresh_af = Mat.zeros(nH, nW, CvType.CV_8UC3);
rgbaMat.copyTo(rgbMat);
rgbMat.convertTo(rgbMat2, CvType.CV_8UC3, 0.8, 60);
rgbMat2.copyTo(rgbMat2copy);
rgbMat.convertTo(rgbMat3, CvType.CV_8UC3, 1, 60);
rgbMat.convertTo(rgbMat4, CvType.CV_8UC3, 1.25, 35);
rgbMat.convertTo(rgbMat, CvType.CV_8UC3, 1.25, 35);
Imgproc.cvtColor(rgbMat, hsvMat, Imgproc.COLOR_RGB2HSV);
Imgproc.cvtColor(rgbMat2, hsvMat2, Imgproc.COLOR_RGB2HSV);
Imgproc.cvtColor(rgbMat3, hsvMat3, Imgproc.COLOR_RGB2HSV);
Imgproc.cvtColor(rgbMat3, hsvMat4, Imgproc.COLOR_RGB2HSV);
watch.Stop();
elapsedMs = watch.ElapsedMilliseconds;
Mat markers = Mat.zeros(rgbaMat.size(), CvType.CV_32SC1);
watch = System.Diagnostics.Stopwatch.StartNew();
for (int obj_i = 0; obj_i < ls_obj.Length; obj_i++)
{
var obj = ls_obj[obj_i];
if (obj_i == (int)tgr.ORANGE | obj_i == (int)tgr.YELLOW | obj_i == (int)tgr.GREEN)
{
Core.inRange(hsvMat2, obj.getHSVmin(), obj.getHSVmax(), thresholdMat);
}
else if (obj_i == (int)tgr.LIGHTBLUE)
{
Core.inRange(hsvMat, obj.getHSVmin(), obj.getHSVmax(), thresholdMat);
}
else
{
Core.inRange(hsvMat, obj.getHSVmin(), obj.getHSVmax(), thresholdMat);
}
if (obj_i == (int)tgr.RED)
{
Core.inRange(hsvMat, new Scalar(0, 20, 45), new Scalar(5, 255, 255), thresholdMat2);
thresholdMat2.copyTo(thresholdMat, thresholdMat2);
}
thresholdMatArr[obj_i] = thresholdMat.clone();
}
//thresholdMatArr[(int)tgr.LIGHTBLUE].setTo(new Scalar(0), thresholdMatArr[(int)tgr.BLUE]);
//thresholdMatArr[(int)tgr.LIGHTBLUE].setTo(new Scalar(0), thresholdMatArr[(int)tgr.GREEN]);
for (int obj_i = 0; obj_i < ls_obj.Length; obj_i++)
{
var obj = ls_obj[obj_i];
all_cts.Clear();
thresholdMat = thresholdMatArr[obj_i];
if (toggle_db[obj_i] == true)
{
all_thresh.setTo(obj.ColorRGB, thresholdMat);
}
if (true | obj_i == (int)tgr.PURPLE | obj_i == (int)tgr.YELLOW | obj_i == (int)tgr.RED | obj_i == (int)tgr.GREEN | obj_i == (int)tgr.ORANGE)
{
Imgproc.erode(thresholdMat, thresholdMat2, Imgproc.getStructuringElement(Imgproc.MORPH_ELLIPSE, new Size(5, 5)), new Point(-1, -1), 1);
}
if (obj_i == (int)tgr.LIGHTBLUE | obj_i == (int)tgr.PURPLE)
{
Imgproc.erode(thresholdMat, thresholdMat2, Imgproc.getStructuringElement(Imgproc.MORPH_ELLIPSE, new Size(5, 5)), new Point(-1, -1), 1);
}
if (toggle_db[obj_i] == true)
{
all_thresh_af.setTo(obj.ColorRGB, thresholdMat2);
}
all_thresh_afct.setTo(new Scalar(obj_i + 1), thresholdMat2);
color_filter.Add(thresholdMat2.clone());
Imgproc.findContours(thresholdMat2, all_cts, hierarchy, Imgproc.RETR_EXTERNAL, Imgproc.CHAIN_APPROX_SIMPLE);
Scalar c = obj.getColor();
for (int ct_i = 0; ct_i < all_cts.Count; ct_i++)
{
double area = Imgproc.contourArea(all_cts[ct_i]);
// if (area < MIN_OBJECT_AREA)
if (area < MIN_OBJECT_AREAS[obj_i] * 0.55)
{
all_cts.RemoveAt(ct_i);
ct_i--;
}
if (area > MAX_OBJECT_AREAS[obj_i] * 1.3)
{
all_cts.RemoveAt(ct_i);
ct_i--;
}
}
MyShape chon = null;
MyShape ms = new MyShape();
float dt = 1000000;
for (int ct_i = 0; ct_i < all_cts.Count; ct_i++)
{
var ct = all_cts[ct_i];
var peri = Imgproc.arcLength(new MatOfPoint2f(ct.toArray()), true);
var epsilon = 0.1 * peri;
if (obj_i == (int)tgr.ORANGE || obj_i == (int)tgr.YELLOW)
{
epsilon = 0.065 * peri;
}
Imgproc.approxPolyDP(new MatOfPoint2f(ct.toArray()), approx_ct, epsilon, true);
MatOfInt pts_cvh = new MatOfInt();
Imgproc.convexHull(ct, pts_cvh, true);
var cvh_numPts = pts_cvh.toArray().Length;
Point[] cvh_pts = new Point[cvh_numPts];
var ct_pts = ct.toArray();
for (int i = 0; i < cvh_numPts; i++)
{
var i1 = pts_cvh.toArray()[i];
var p1 = ct_pts[i1];
cvh_pts[i] = p1;
try
{
if (debug == true)
{
var i2 = pts_cvh.toArray()[(i + 1) % cvh_numPts];
var p2 = ct_pts[i2];
Imgproc.circle(rgbMat2, p1, 1, c, 2);
}
}
catch (Exception e)
{
Utilities.LogFormat("Here3:{0},{1},{2}", rgbMat2 == null, p1 == null, c == null);
Utilities.Log("Exception is {0}", e.ToString());
Utilities.Log("Trace is {0}", e.StackTrace.ToString());
}
}
MatOfPoint2f approx_cvh = new MatOfPoint2f();
var epsilon2 = peri * 0.1;
if (obj_i == (int)tgr.ORANGE)
{
epsilon2 = peri * 0.065;
}
Imgproc.approxPolyDP(new MatOfPoint2f(cvh_pts), approx_cvh, epsilon2, true);
var ct_ori = new MatOfPoint(ct.toArray());
MatOfPoint approx_ct2 = new MatOfPoint(approx_ct.toArray());
List <MatOfPoint> approx_cvh2 = new List <MatOfPoint>();
approx_cvh2.Add(new MatOfPoint(approx_cvh.toArray()));
var mu = Imgproc.moments(approx_cvh2[0], true);
cterTgr.x = mu.m10 / mu.m00;
cterTgr.y = mu.m01 / mu.m00;
if (approx_ct2.size().height == 3 | approx_ct2.size().height == 4)
{
var points = approx_cvh2[0].toArray();
var numpoints = points.Length;
ms._id = obj_i;
ms.ps = new Point[numpoints];
double rat = 1.16;
if (obj_i == (int)tgr.PURPLE)
{
rat = 1.20;
}
else if (obj_i == (int)tgr.LIGHTBLUE)
{
rat = 1.20;
}
else if (obj_i == (int)tgr.RED | obj_i == (int)tgr.BLUE)
{
rat = 1.09;
}
else if (obj_i == (int)tgr.YELLOW)
{
rat = 1.10;
}
else if (obj_i == (int)tgr.ORANGE)
{
rat = 1.10;
}
else if (obj_i == (int)tgr.GREEN)
{
rat = 1.10;
}
var ind_huyen = 0;
var max = -1d;
if (numpoints == 3 || numpoints == 4)
{
for (int p_i = 0; p_i < numpoints; p_i++)
{
var p = points[p_i];
var p2 = points[(p_i + 1) % numpoints];
var vect = p - cterTgr;
vect = vect * rat;
var p_new = cterTgr + vect;
points[p_i].x = (int)(p_new.x * 100) / 100f;
points[p_i].y = (int)(p_new.y * 100) / 100f;
if (numpoints == 4)
{
ms.ps[p_i] = p_new;
}
if (numpoints == 3)
{
var vt = p2 - p;
var length = vt.x * vt.x + vt.y * vt.y;
if (length > max)
{
ind_huyen = p_i;
max = length;
}
}
}
}
if (numpoints == 3)
{
var i_nhon1 = ind_huyen;
var i_nhon2 = (ind_huyen + 1) % numpoints;
var i_vuong = (ind_huyen + 2) % numpoints;
ms.ps[0] = points[i_vuong];
ms.ps[1] = points[i_nhon1];
ms.ps[2] = points[i_nhon2];
}
else if (numpoints == 4)
{
if (obj_i == (int)tgr.ORANGE)
{
var vt_cheo1 = ms.ps[0] - ms.ps[2];
var vt_cheo2 = ms.ps[1] - ms.ps[3];
var leng_cheo1 = vt_cheo1.x * vt_cheo1.x + vt_cheo1.y * vt_cheo1.y;
var leng_cheo2 = vt_cheo2.x * vt_cheo2.x + vt_cheo2.y * vt_cheo2.y;
var i_nhon = 0;
if (leng_cheo2 > leng_cheo1)
{
i_nhon = 1;
}
ms.ps[0] = points[i_nhon];
ms.ps[1] = points[(i_nhon + 1)];
ms.ps[2] = points[(i_nhon + 2)];
ms.ps[3] = points[(i_nhon + 3) % numpoints];
var i_prvNhon = (i_nhon + 4 - 1) % numpoints;
var i_aftNhon = i_nhon + 1;
var vt_prvNhon = points[i_prvNhon] - points[i_nhon];
var vt_aftNhon = points[i_aftNhon] - points[i_nhon];
var len_prvNhon = vt_prvNhon.x * vt_prvNhon.x + vt_prvNhon.y * vt_prvNhon.y;
var len_aftNhon = vt_aftNhon.x * vt_aftNhon.x + vt_aftNhon.y * vt_aftNhon.y;
Imgproc.line(dbMat, points[i_prvNhon], points[i_nhon], c, 1);
if (len_prvNhon > len_aftNhon)
{
ms.isFlip = true;
Imgproc.putText(dbMat, " IsFLIP", ms.ps[3], 1, 1, c, 1);
}
else
{
ms.isFlip = false;
Imgproc.putText(dbMat, " IsNOTFLIP", ms.ps[3], 1, 1, c, 1);
}
}
}
var centerMat = new Point(rgbMat.width() / 2f, rgbMat.height() / 2f);
var vtLech = centerMat - cterTgr;
var dt2 = vtLech.x * vtLech.x + vtLech.y * vtLech.y;
if (dt2 < dt)
{
chon = ms;
}
}
try
{
Imgproc.circle(rgbMat, cterTgr, 1, c, 1);
Imgproc.putText(rgbMat, mu.m00.ToString(), cterTgr, 1, 1, c, 1);
}
catch (Exception e)
{
Utilities.LogFormat("Here2:{0},{1},{2}", rgbMat == null, cterTgr == null, c == null);
Utilities.Log("Exception is {0}", e.ToString());
Utilities.Log("Trace is {0}", e.StackTrace.ToString());
}
//if (approx_ct2.size().height == 3 | approx_ct2.size().height == 4) break;
}
if (chon != null)
{
lms.Add(chon);
var ps = chon.ps;
for (int i = 0; i < ps.Length; i++)
{
var p1 = ps[i];
var p2 = ps[(i + 1) % ps.Length];
try
{
Imgproc.line(rgbMat2, p1, p2, c, 1);
Imgproc.line(all_thresh_afct, p1, p2, new Scalar(255, 255, 255), 1);
Imgproc.line(dbMat, p1, p2, c, 1);
Imgproc.circle(dbMat, p1, 1, c);
}
catch (Exception e)
{
Utilities.LogFormat("Here1:{0},{1},{2}", rgbMat2 == null, p1 == null, p2 == null);
Utilities.Log("Exception is {0}", e.ToString());
Utilities.Log("Trace is {0}", e.StackTrace.ToString());
}
}
}
watch.Stop();
elapsedMs = watch.ElapsedMilliseconds;
}
TangramShape msl = new TangramShape();
msl.datas = lms;
var json = JsonUtility.ToJson(msl);
watch = System.Diagnostics.Stopwatch.StartNew();
trm = tangramFeatureModelList.Detect(msl.datas.ToArray());
watch.Stop();
elapsedMs = watch.ElapsedMilliseconds;
mut.ReleaseMutex();
}).ObserveOnMainThread().Subscribe((rx) =>
{
prc(trm, lms);
if (debug == true)
{
mut.WaitOne();
if (texture != null && debug == true)
{
Utils.matToTexture2D(dbMat, texture);
}
if (dbText1 != null && debug == true)
{
Utils.matToTexture2D(rgbMat2copy, dbText1);
}
if (dbText2 != null && debug == true)
{
Utils.matToTexture2D(rgbMat3, dbText2);
}
if (dbText3 != null && debug == true)
{
Utils.matToTexture2D(rgbMat4, dbText3);
}
if (dbText4 != null && debug == true)
{
Utils.matToTexture2D(rgbMat, dbText4);
}
all_thresh_afct = all_thresh_afct * 25;
Imgproc.cvtColor(rgbMat2, rgbMat2, Imgproc.COLOR_RGBA2RGB);
Imgproc.cvtColor(all_thresh, all_thresh, Imgproc.COLOR_RGBA2RGB);
Mat a = new Mat(all_thresh.size(), CvType.CV_8UC3);
Core.addWeighted(all_thresh, 0.2, rgbMat2, 0.8, 0, a);
if (dbText5 != null && debug == true)
{
Utils.matToTexture2D(a, dbText5);
}
if (dbText6 != null && debug == true)
{
Utils.matToTexture2D(all_thresh, dbText6);
}
if (dbText7 != null && debug == true)
{
Utils.matToTexture2D(all_thresh_afct, dbText7);
}
if (dbText8 != null && debug == true)
{
Utils.matToTexture2D(all_thresh_af, dbText8);
}
mut.ReleaseMutex();
}
});
}
/// <summary>
/// Hands the pose estimation process.
/// </summary>
public void handPoseEstimationProcess(Mat rgbaMat)
{
//Imgproc.blur(mRgba, mRgba, new Size(5,5));
Imgproc.GaussianBlur(rgbaMat, rgbaMat, new OpenCVForUnity.Size(3, 3), 1, 1);
//Imgproc.medianBlur(mRgba, mRgba, 3);
if (!isColorSelected)
{
return;
}
List <MatOfPoint> contours = detector.getContours();
detector.process(rgbaMat);
//Debug.Log(contours + " | " + contours.Count);
//string[] output = contours.ToArray();
for (int i = 0; i < contours.Count; i++)
{
//Debug.Log("MatOfPoint2f " + new MatOfPoint2f(contours[i].toArray()) + " | " + i);
//Debug.Log("MatOfPoint " + contours [i] + " | " + i);
//Imgproc.circle(rgbaMat, contours[i], 6, new Scalar(0, 255, 0, 255), -1);
//Debug.Log ("kotka" + MatOfPoint.ReferenceEquals(x, y));
}
if (contours.Count <= 0)
{
return;
}
RotatedRect rect = Imgproc.minAreaRect(new MatOfPoint2f(contours[0].toArray()));
double boundWidth = rect.size.width;
double boundHeight = rect.size.height;
int boundPos = 0;
for (int i = 1; i < contours.Count; i++)
{
rect = Imgproc.minAreaRect(new MatOfPoint2f(contours[i].toArray()));
if (rect.size.width * rect.size.height > boundWidth * boundHeight)
{
boundWidth = rect.size.width;
boundHeight = rect.size.height;
boundPos = i;
}
}
OpenCVForUnity.Rect boundRect = Imgproc.boundingRect(new MatOfPoint(contours[boundPos].toArray()));
Imgproc.rectangle(rgbaMat, boundRect.tl(), boundRect.br(), CONTOUR_COLOR_WHITE, 2, 8, 0);
//tochkaX = boundRect.tl ().x;
//tochkaY = boundRect.tl ().y;
Imgproc.circle(rgbaMat, boundRect.tl(), 6, new Scalar(0, 255, 0, 255), -1);
Imgproc.circle(rgbaMat, boundRect.br(), 6, new Scalar(0, 255, 0, 255), -1);
pointbX = boundRect.br().x;
pointbY = boundRect.br().y;
pointaX = boundRect.x;
pointbY = boundRect.y;
double a = boundRect.br().y - boundRect.tl().y;
a = a * 0.7;
a = boundRect.tl().y + a;
Imgproc.rectangle(rgbaMat, boundRect.tl(), new Point(boundRect.br().x, a), CONTOUR_COLOR, 2, 8, 0);
MatOfPoint2f pointMat = new MatOfPoint2f();
Imgproc.approxPolyDP(new MatOfPoint2f(contours[boundPos].toArray()), pointMat, 3, true);
contours[boundPos] = new MatOfPoint(pointMat.toArray());
MatOfInt hull = new MatOfInt();
MatOfInt4 convexDefect = new MatOfInt4();
Imgproc.convexHull(new MatOfPoint(contours[boundPos].toArray()), hull);
if (hull.toArray().Length < 3)
{
return;
}
Imgproc.convexityDefects(new MatOfPoint(contours[boundPos].toArray()), hull, convexDefect);
List <MatOfPoint> hullPoints = new List <MatOfPoint>();
List <Point> listPo = new List <Point>();
for (int j = 0; j < hull.toList().Count; j++)
{
listPo.Add(contours[boundPos].toList()[hull.toList()[j]]);
}
MatOfPoint e = new MatOfPoint();
e.fromList(listPo);
hullPoints.Add(e);
List <MatOfPoint> defectPoints = new List <MatOfPoint>();
List <Point> listPoDefect = new List <Point>();
for (int j = 0; j < convexDefect.toList().Count; j = j + 4)
{
Point farPoint = contours[boundPos].toList()[convexDefect.toList()[j + 2]];
int depth = convexDefect.toList()[j + 3];
if (depth > 8700 && farPoint.y < a)
{
listPoDefect.Add(contours[boundPos].toList()[convexDefect.toList()[j + 2]]);
}
}
MatOfPoint e2 = new MatOfPoint();
e2.fromList(listPo);
defectPoints.Add(e2);
Imgproc.drawContours(rgbaMat, hullPoints, -1, CONTOUR_COLOR, 3);
this.numberOfFingers = listPoDefect.Count;
if (this.numberOfFingers > 5)
{
this.numberOfFingers = 5;
}
foreach (Point p in listPoDefect)
{
Imgproc.circle(rgbaMat, p, 6, new Scalar(255, 0, 255, 255), -1);
}
}
private void HandPoseEstimationProcess(Mat rgbaMat)
{
// rgbaMat.copyTo(mRgba);
float DOWNSCALE_RATIO = 1.0f;
if (enableDownScale)
{
mRgba = imageOptimizationHelper.GetDownScaleMat(rgbaMat);
DOWNSCALE_RATIO = imageOptimizationHelper.downscaleRatio;
}
else
{
// mRgba = rgbaMat;
rgbaMat.copyTo(mRgba);
DOWNSCALE_RATIO = 1.0f;
}
// Imgproc.blur(mRgba, mRgba, new Size(5,5));
Imgproc.GaussianBlur(mRgba, mRgba, new Size(3, 3), 1, 1);
// Imgproc.medianBlur(mRgba, mRgba, 3);
if (!isColorSelected)
{
return;
}
List <MatOfPoint> contours = detector.GetContours();
detector.Process(mRgba);
// Debug.Log ("Contours count: " + contours.Count);
if (contours.Count <= 0)
{
return;
}
RotatedRect rect = Imgproc.minAreaRect(new MatOfPoint2f(contours[0].toArray()));
double boundWidth = rect.size.width;
double boundHeight = rect.size.height;
int boundPos = 0;
for (int i = 1; i < contours.Count; i++)
{
rect = Imgproc.minAreaRect(new MatOfPoint2f(contours[i].toArray()));
if (rect.size.width * rect.size.height > boundWidth * boundHeight)
{
boundWidth = rect.size.width;
boundHeight = rect.size.height;
boundPos = i;
}
}
MatOfPoint contour = contours[boundPos];
OpenCVForUnity.CoreModule.Rect boundRect = Imgproc.boundingRect(new MatOfPoint(contour.toArray()));
Imgproc.rectangle(mRgba, boundRect.tl(), boundRect.br(), CONTOUR_COLOR_WHITE, 2, 8, 0);
// Debug.Log (
// " Row start [" +
// (int)boundRect.tl ().y + "] row end [" +
// (int)boundRect.br ().y + "] Col start [" +
// (int)boundRect.tl ().x + "] Col end [" +
// (int)boundRect.br ().x + "]");
double a = boundRect.br().y - boundRect.tl().y;
a = a * 0.7;
a = boundRect.tl().y + a;
// Debug.Log (" A [" + a + "] br y - tl y = [" + (boundRect.br ().y - boundRect.tl ().y) + "]");
// Imgproc.rectangle(mRgba, boundRect.tl(), new Point(boundRect.br().x, a), CONTOUR_COLOR, 2, 8, 0);
MatOfPoint2f pointMat = new MatOfPoint2f();
Imgproc.approxPolyDP(new MatOfPoint2f(contour.toArray()), pointMat, 3, true);
contour = new MatOfPoint(pointMat.toArray());
MatOfInt hull = new MatOfInt();
MatOfInt4 convexDefect = new MatOfInt4();
Imgproc.convexHull(new MatOfPoint(contour.toArray()), hull);
if (hull.toArray().Length < 3)
{
return;
}
Imgproc.convexityDefects(new MatOfPoint(contour.toArray()), hull, convexDefect);
List <MatOfPoint> hullPoints = new List <MatOfPoint>();
List <Point> listPo = new List <Point>();
for (int j = 0; j < hull.toList().Count; j++)
{
listPo.Add(contour.toList()[hull.toList()[j]] * DOWNSCALE_RATIO);
}
/*
* MatOfPoint e = new MatOfPoint();
* e.fromList(listPo);
* hullPoints.Add(e);
*
* List<Point> listPoDefect = new List<Point>();
*
* if (convexDefect.rows() > 0)
* {
* List<int> convexDefectList = convexDefect.toList();
* List<Point> contourList = contour.toList();
* for (int j = 0; j < convexDefectList.Count; j = j + 4)
* {
* Point farPoint = contourList[convexDefectList[j + 2]];
* int depth = convexDefectList[j + 3];
* if (depth > threshholdDetect && farPoint.y < a)
* {
* listPoDefect.Add(contourList[convexDefectList[j + 2]]);
* Imgproc.line(rgbaMat, farPoint, listPo[convexDefectList[j + 2]], new Scalar(255, 0, 0, 255),1,1);
* }
* // Debug.Log ("convexDefectList [" + j + "] " + convexDefectList [j + 3]);
* }
* }*/
// Debug.Log ("hull: " + hull.toList ());
// if (convexDefect.rows () > 0) {
// Debug.Log ("defects: " + convexDefect.toList ());
// }
//Imgproc.drawContours (rgbaMat, hullPoints, -1, CONTOUR_COLOR, 3);
for (int p = 0; p < listPo.Count; p++)
{
if (p % 2 == 0)
{
Imgproc.circle(rgbaMat, listPo[p], 6, new Scalar(255, 0, 0, 255), -1);
// Imgproc.putText(rgbaMat,p.ToString(),listPo[p],1,1,new Scalar(255,0,0,255));
// check if close
List <Point> fLMscaled = OpenCVForUnityUtils.ConvertVector2ListToPointList(facePoints);
for (int q = 0; q < fLMscaled.Count; q++)
{
if (ifLessThanDPoint(listPo[p], fLMscaled[q], 8))
{
//Point1 = listPo[p];
//Point2 = fLMscaled[q];
handPoint = p;
facePoint = q;
print(Point1 + " " + Point2);
}
}
if (p == handPoint && facePoint != 0)
{
Point1 = listPo[p];
Point2 = fLMscaled[facePoint];
Imgproc.line(rgbaMat, Point1, Point2, new Scalar(255, 255, 255, 255));
}
}
}
// int defectsTotal = (int)convexDefect.total();
// Debug.Log ("Defect total " + defectsTotal);
/* numberOfFingers = listPoDefect.Count;
* if (numberOfFingers > 5)
* numberOfFingers = 5;/
*
* // Debug.Log ("numberOfFingers " + numberOfFingers);
*
* // Imgproc.putText (rgbaMat, "" + numberOfFingers, new Point (rgbaMat.cols () / 2, rgbaMat.rows () / 2), Imgproc.FONT_HERSHEY_PLAIN, 4.0, new Scalar (255, 255, 255, 255), 6, Imgproc.LINE_AA, false);
*
*
* /* foreach (Point p in listPoDefect) {
*
* Point tempp = GetNearestL(p, listPo);
* tempp = ConvertDownscale(tempp, DOWNSCALE_RATIO);
* Point p2 = ConvertDownscale(p, DOWNSCALE_RATIO);
*
* Imgproc.circle (rgbaMat, tempp, 6, new Scalar (0, 0, 255, 255), -1);
* Imgproc.circle(rgbaMat, p2, 6, new Scalar(255, 0, 255, 255), -1);
* }*/
}
//手を検出して画像に描画する
private static void _handPoseEstimationProcess(Mat rgbaMat, Color handColor)
{
Imgproc.GaussianBlur(rgbaMat, rgbaMat, new OpenCVForUnity.Size(3, 3), 1, 1);
//検出器に色を設定
detector.setHsvColor(HGColorSpuiter.ColorToScalar(handColor));
List <MatOfPoint> contours = detector.getContours();
detector.process(rgbaMat);
if (contours.Count <= 0)
{
return;
}
//手の角度に傾いた外接矩形を作成
RotatedRect rect = Imgproc.minAreaRect(new MatOfPoint2f(contours[0].toArray()));
double boundWidth = rect.size.width;
double boundHeight = rect.size.height;
int boundPos = 0;
for (int i = 1; i < contours.Count; i++)
{
rect = Imgproc.minAreaRect(new MatOfPoint2f(contours[i].toArray()));
if (rect.size.width * rect.size.height > boundWidth * boundHeight)
{
boundWidth = rect.size.width;
boundHeight = rect.size.height;
boundPos = i;
}
}
OpenCVForUnity.Rect boundRect = Imgproc.boundingRect(new MatOfPoint(contours[boundPos].toArray()));
//手首までの範囲を描画
Imgproc.rectangle(rgbaMat, boundRect.tl(), boundRect.br(), HGColorSpuiter.ColorToScalar(WristRangeColor), 2, 8, 0);
double a = boundRect.br().y - boundRect.tl().y;
a = a * 0.7;
a = boundRect.tl().y + a;
//手のひらの範囲を描画
Imgproc.rectangle(rgbaMat, boundRect.tl(), new Point(boundRect.br().x, a), HGColorSpuiter.ColorToScalar(PalmsRangeColor), 2, 8, 0);
//折れ線カーブまたはポリゴンを,互いの距離が指定された精度以下になるように,より少ない頂点数のカーブやポリゴンで近似します
MatOfPoint2f pointMat = new MatOfPoint2f();
Imgproc.approxPolyDP(new MatOfPoint2f(contours[boundPos].toArray()), pointMat, 3, true);
contours[boundPos] = new MatOfPoint(pointMat.toArray());
//点とポリゴンの最短距離を計算
MatOfInt hull = new MatOfInt();
MatOfInt4 convexDefect = new MatOfInt4();
Imgproc.convexHull(new MatOfPoint(contours[boundPos].toArray()), hull);
if (hull.toArray().Length < 3)
{
return;
}
Imgproc.convexityDefects(new MatOfPoint(contours[boundPos].toArray()), hull, convexDefect);
//手の範囲を取得
List <MatOfPoint> hullPoints = new List <MatOfPoint>();
List <Point> listPo = new List <Point>();
for (int j = 0; j < hull.toList().Count; j++)
{
listPo.Add(contours[boundPos].toList()[hull.toList()[j]]);
}
MatOfPoint e = new MatOfPoint();
e.fromList(listPo);
hullPoints.Add(e);
//手の範囲を描画
Imgproc.drawContours(rgbaMat, hullPoints, -1, HGColorSpuiter.ColorToScalar(HandRangeColor), 3);
//指と認識した場所を取得
List <MatOfPoint> defectPoints = new List <MatOfPoint>();
List <Point> listPoDefect = new List <Point>();
for (int j = 0; j < convexDefect.toList().Count; j = j + 4)
{
Point farPoint = contours[boundPos].toList()[convexDefect.toList()[j + 2]];
int depth = convexDefect.toList()[j + 3];
if (depth > depthThreashold && farPoint.y < a)
{
listPoDefect.Add(contours[boundPos].toList()[convexDefect.toList()[j + 2]]);
}
}
MatOfPoint e2 = new MatOfPoint();
e2.fromList(listPo);
defectPoints.Add(e2);
//検出した指の本数を更新
numberOfFingers = listPoDefect.Count;
if (numberOfFingers > 5)
{
numberOfFingers = 5;
}
//指の間に点を描画
foreach (Point p in listPoDefect)
{
Imgproc.circle(rgbaMat, p, 6, HGColorSpuiter.ColorToScalar(BetweenFingersColor), -1);
}
}
// Update is called once per frame
void Update()
{
if (webCamTextureToMatHelper.IsPlaying() && webCamTextureToMatHelper.DidUpdateThisFrame())
{
frame = webCamTextureToMatHelper.GetMat();
frame.copyTo(img_orig);
drawing = img_orig.clone();
int lowThreshold = 50;// (int)200;// slider.value;
const int ratio = 1;
const int kernel_size = 3;
Imgproc.cvtColor(img_orig, img_lab, Imgproc.COLOR_BGR2Lab);
double omrSize = img_orig.cols() * img_orig.rows();
Imgproc.cvtColor(img_orig, img_gray, Imgproc.COLOR_RGBA2GRAY);
Imgproc.GaussianBlur(img_gray, img_gray, new Size(15, 15), 1.5, 1.5); //Gaussian blur
Imgproc.erode(img_gray, img_gray, new Mat(), new Point(-1, -1), 1); //Erosion
// Imgproc.dilate(img_gray, img_gray, new Mat(), new Point(-1, -1), 10, 1, new Scalar(10)); //Dilation
Imgproc.Canny(img_gray, img_edges, lowThreshold, lowThreshold * ratio, kernel_size, false);
//Shape detection
List <MatOfPoint> contours = new List <MatOfPoint>();
Mat hierarchy = new Mat();
Imgproc.findContours(img_edges, contours, hierarchy, Imgproc.RETR_EXTERNAL, Imgproc.CHAIN_APPROX_SIMPLE, new Point(0, 0));
//Texture2D tex = new Texture2D(img_edges.width(), img_edges.height(), TextureFormat.RGB24, false);
//Utils.matToTexture2D(img_edges, tex);
//byte[] bytes1 = tex.EncodeToJPG();
//File.WriteAllBytes("D:/2019/OMR/" + "test213123.png", bytes1);
List <MatOfPoint> hulls = new List <MatOfPoint>();
for (int i = 0; i < contours.Count; i++)
{
MatOfInt hull_temp = new MatOfInt();
Imgproc.convexHull(contours[i], hull_temp);
int[] arrIndex = hull_temp.toArray();
Point[] arrContour = contours[i].toArray();
Point[] arrPoints = new Point[arrIndex.Length];
for (int k = 0; k < arrIndex.Length; k++)
{
arrPoints[k] = arrContour[arrIndex[k]];
}
MatOfPoint temp = new MatOfPoint();
temp.fromArray(arrPoints);
//Filter outliers
if (Imgproc.contourArea(temp) > omrSize / 3 && Imgproc.contourArea(temp) < (omrSize * 4) / 5)
{
hulls.Add(temp);
}
}
List <MatOfPoint2f> hull2f = new List <MatOfPoint2f>();
for (int i = 0; i < hulls.Count; i++)
{
MatOfPoint2f newPoint = new MatOfPoint2f(hulls[i].toArray());
hull2f.Add(newPoint);
}
for (int i = 0; i < hulls.Count; i++)
{
//Approximate polygon
MatOfPoint2f approx = new MatOfPoint2f();
Imgproc.approxPolyDP(hull2f[i], approx, 0.01 * Imgproc.arcLength(hull2f[i], true), true);
List <Point> approx_polygon = approx.toList();
// approx_polygon = Scannerproc.filterPolygon(approx_polygon);
// Debug.Log(approx_polygon.Count);
if (!Scannerproc.isSquare(approx_polygon))
{
continue;
}
else
{
nowRectPoints.Clear();
nowRectPoints.AddRange(approx_polygon);
perspectiveAlign();
}
//Center of mass
int cx = 0,
cy = 0;
for (int k = 0; k < approx_polygon.Count; k++)
{
cx += (int)approx_polygon[k].x;
cy += (int)approx_polygon[k].y;
}
cx /= approx_polygon.Count;
cy /= approx_polygon.Count;
Scannerproc.drawShape(drawing, approx_polygon, new Scalar(0, 255, 0));
}
if (showTextureOnScreen)
{
showCurrentTextureOnScreen();
}
}
}
/*=============================================*
* 輪郭ごとの頂点から手を判別するまで
*=============================================*/
/// <summary>
/// Contours to hand gesture.
/// </summary>
/// <param name="rgbaMat">Rgba mat.</param>
/// <param name="contour">Contour.</param>
private static void _contourToHandGesture(Mat rgbaMat, MatOfPoint contour)
{
try
{
//頂点を調査する準備をする
_pointOfVertices(rgbaMat, contour);
//基準輪郭のサイズの取得と描画(長方形)
OpenCVForUnity.Rect boundRect = Imgproc.boundingRect(new MatOfPoint(contour.toArray()));
Imgproc.rectangle(rgbaMat, boundRect.tl(), boundRect.br(), HGColorSpuiter.ColorToScalar(ContourRangeColor), 2, 8, 0);
/*=============================================*
* 腕まで含んだ手の大きさを取得する
**=============================================*/
//腕まで含んだ手の大きさを識別する
MatOfInt hull = new MatOfInt();
Imgproc.convexHull(new MatOfPoint(contour.toArray()), hull);
//腕まで含んだ手の範囲を取得
List <Point> armPointList = new List <Point>();
for (int j = 0; j < hull.toList().Count; j++)
{
Point armPoint = contour.toList()[hull.toList()[j]];
bool addFlag = true;
foreach (Point point in armPointList.ToArray())
{
//輪郭の1/10より近い頂点は誤差としてまとめる
double distance = Mathf.Sqrt((float)((armPoint.x - point.x) * (armPoint.x - point.x) + (armPoint.y - point.y) * (armPoint.y - point.y)));
if (distance <= Mathf.Min((float)boundRect.width, (float)boundRect.height) / 10)
{
addFlag = false;
break;
}
}
if (addFlag)
{
armPointList.Add(armPoint);
}
}
MatOfPoint armMatOfPoint = new MatOfPoint();
armMatOfPoint.fromList(armPointList);
List <MatOfPoint> armPoints = new List <MatOfPoint>();
armPoints.Add(armMatOfPoint);
//腕まで含んだ手の範囲を描画
Imgproc.drawContours(rgbaMat, armPoints, -1, HGColorSpuiter.ColorToScalar(ArmRangeColor), 3);
//腕まで含んだ手が三角形の場合はそれ以上の識別が難しい
if (hull.toArray().Length < 3)
{
return;
}
/*=============================================*
* 掌の大きさを取得する
**=============================================*/
//凸面の頂点から凹面の点のみを取得し、掌の範囲を取得する
MatOfInt4 convexDefect = new MatOfInt4();
Imgproc.convexityDefects(new MatOfPoint(contour.toArray()), hull, convexDefect);
//凹面の点をフィルタリングして取得
List <Point> palmPointList = new List <Point>();
for (int j = 0; j < convexDefect.toList().Count; j = j + 4)
{
Point farPoint = contour.toList()[convexDefect.toList()[j + 2]];
int depth = convexDefect.toList()[j + 3];
if (depth > depthThreashold && farPoint.y < boundRect.br().y - boundRect.tl().y)
{
palmPointList.Add(contour.toList()[convexDefect.toList()[j + 2]]);
}
}
MatOfPoint palmMatOfPoint = new MatOfPoint();
palmMatOfPoint.fromList(palmPointList);
List <MatOfPoint> palmPoints = new List <MatOfPoint>();
palmPoints.Add(palmMatOfPoint);
//掌の範囲を描画
Imgproc.drawContours(rgbaMat, palmPoints, -1, HGColorSpuiter.ColorToScalar(PalmRangeColor), 3);
/*=============================================*
* 掌+指先の大きさを取得する
**=============================================*/
//掌の位置を元に手首を除いた範囲を取得する
List <Point> handPointList = new List <Point>();
handPointList.AddRange(armPointList.ToArray());
handPointList.Reverse();
handPointList.RemoveAt(0);
handPointList.Insert(0, palmPointList.ToArray()[0]);
handPointList.RemoveAt(handPointList.Count - 1);
handPointList.Insert(handPointList.Count, palmPointList.ToArray()[palmPointList.Count - 1]);
MatOfPoint handMatOfPoint = new MatOfPoint();
handMatOfPoint.fromList(handPointList);
List <MatOfPoint> handPoints = new List <MatOfPoint>();
handPoints.Add(handMatOfPoint);
Imgproc.drawContours(rgbaMat, handPoints, -1, HGColorSpuiter.ColorToScalar(HandRangeColor), 3);
/*=============================================*
* 指先の位置を取得する
**=============================================*/
//掌の各頂点の中心を求める
List <Point> palmCenterPoints = new List <Point>();
for (int i = 0; i < palmPointList.Count; i++)
{
Point palmPoint = palmPointList.ToArray()[i];
Point palmPointNext = new Point();
if (i + 1 < palmPointList.Count)
{
palmPointNext = palmPointList.ToArray()[i + 1];
}
else
{
palmPointNext = palmPointList.ToArray()[0];
}
Point palmCenterPoint = new Point((palmPoint.x + palmPointNext.x) / 2, (palmPoint.y + palmPointNext.y) / 2);
palmCenterPoints.Add(palmCenterPoint);
}
//掌の頂点から最も近い手の頂点を求める
for (int i = 0; i < palmCenterPoints.Count && i + 1 < handPointList.Count && i < 5; i++)
{
Point palmPoint = palmCenterPoints.ToArray()[i];
List <Point> fingerList = new List <Point>();
fingerList.Add(palmPoint);
fingerList.Add(handPointList.ToArray()[i + 1]);
MatOfPoint fingerPoint = new MatOfPoint();
fingerPoint.fromList(fingerList);
List <MatOfPoint> fingerPoints = new List <MatOfPoint>();
fingerPoints.Add(fingerPoint);
Imgproc.drawContours(rgbaMat, fingerPoints, -1, HGColorSpuiter.ColorToScalar(FingerRangeColor), 3);
}
// Imgproc.putText(rgbaMat, "", new Point(2, rgbaMat.rows()-30), Core.FONT_HERSHEY_SIMPLEX, 1.0, HGColorSpuiter.ColorToScalar(Color.black), 2, Imgproc.LINE_AA, false);
}
catch (System.Exception e)
{
Debug.Log(e.Message);
}
}