advancedskrald/ChessAR/Assets/OpenCVForUnity/org/opencv/video/Video.cs

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using OpenCVForUnity.CoreModule;
using OpenCVForUnity.UtilsModule;
using System;
using System.Collections.Generic;
using System.Runtime.InteropServices;
namespace OpenCVForUnity.VideoModule
{
// C++: class Video
//javadoc: Video
public class Video
{
private const int CV_LKFLOW_INITIAL_GUESSES = 4;
private const int CV_LKFLOW_GET_MIN_EIGENVALS = 8;
// C++: enum <unnamed>
public const int OPTFLOW_USE_INITIAL_FLOW = 4;
public const int OPTFLOW_LK_GET_MIN_EIGENVALS = 8;
public const int OPTFLOW_FARNEBACK_GAUSSIAN = 256;
public const int MOTION_TRANSLATION = 0;
public const int MOTION_EUCLIDEAN = 1;
public const int MOTION_AFFINE = 2;
public const int MOTION_HOMOGRAPHY = 3;
//
// C++: Mat cv::readOpticalFlow(String path)
//
//javadoc: readOpticalFlow(path)
public static Mat readOpticalFlow (string path)
{
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
Mat retVal = new Mat(video_Video_readOpticalFlow_10(path));
return retVal;
#else
return null;
#endif
}
//
// C++: Ptr_BackgroundSubtractorKNN cv::createBackgroundSubtractorKNN(int history = 500, double dist2Threshold = 400.0, bool detectShadows = true)
//
//javadoc: createBackgroundSubtractorKNN(history, dist2Threshold, detectShadows)
public static BackgroundSubtractorKNN createBackgroundSubtractorKNN (int history, double dist2Threshold, bool detectShadows)
{
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
BackgroundSubtractorKNN retVal = BackgroundSubtractorKNN.__fromPtr__(video_Video_createBackgroundSubtractorKNN_10(history, dist2Threshold, detectShadows));
return retVal;
#else
return null;
#endif
}
//javadoc: createBackgroundSubtractorKNN(history, dist2Threshold)
public static BackgroundSubtractorKNN createBackgroundSubtractorKNN (int history, double dist2Threshold)
{
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
BackgroundSubtractorKNN retVal = BackgroundSubtractorKNN.__fromPtr__(video_Video_createBackgroundSubtractorKNN_11(history, dist2Threshold));
return retVal;
#else
return null;
#endif
}
//javadoc: createBackgroundSubtractorKNN(history)
public static BackgroundSubtractorKNN createBackgroundSubtractorKNN (int history)
{
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
BackgroundSubtractorKNN retVal = BackgroundSubtractorKNN.__fromPtr__(video_Video_createBackgroundSubtractorKNN_12(history));
return retVal;
#else
return null;
#endif
}
//javadoc: createBackgroundSubtractorKNN()
public static BackgroundSubtractorKNN createBackgroundSubtractorKNN ()
{
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
BackgroundSubtractorKNN retVal = BackgroundSubtractorKNN.__fromPtr__(video_Video_createBackgroundSubtractorKNN_13());
return retVal;
#else
return null;
#endif
}
//
// C++: Ptr_BackgroundSubtractorMOG2 cv::createBackgroundSubtractorMOG2(int history = 500, double varThreshold = 16, bool detectShadows = true)
//
//javadoc: createBackgroundSubtractorMOG2(history, varThreshold, detectShadows)
public static BackgroundSubtractorMOG2 createBackgroundSubtractorMOG2 (int history, double varThreshold, bool detectShadows)
{
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
BackgroundSubtractorMOG2 retVal = BackgroundSubtractorMOG2.__fromPtr__(video_Video_createBackgroundSubtractorMOG2_10(history, varThreshold, detectShadows));
return retVal;
#else
return null;
#endif
}
//javadoc: createBackgroundSubtractorMOG2(history, varThreshold)
public static BackgroundSubtractorMOG2 createBackgroundSubtractorMOG2 (int history, double varThreshold)
{
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
BackgroundSubtractorMOG2 retVal = BackgroundSubtractorMOG2.__fromPtr__(video_Video_createBackgroundSubtractorMOG2_11(history, varThreshold));
return retVal;
#else
return null;
#endif
}
//javadoc: createBackgroundSubtractorMOG2(history)
public static BackgroundSubtractorMOG2 createBackgroundSubtractorMOG2 (int history)
{
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
BackgroundSubtractorMOG2 retVal = BackgroundSubtractorMOG2.__fromPtr__(video_Video_createBackgroundSubtractorMOG2_12(history));
return retVal;
#else
return null;
#endif
}
//javadoc: createBackgroundSubtractorMOG2()
public static BackgroundSubtractorMOG2 createBackgroundSubtractorMOG2 ()
{
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
BackgroundSubtractorMOG2 retVal = BackgroundSubtractorMOG2.__fromPtr__(video_Video_createBackgroundSubtractorMOG2_13());
return retVal;
#else
return null;
#endif
}
//
// C++: RotatedRect cv::CamShift(Mat probImage, Rect& window, TermCriteria criteria)
//
//javadoc: CamShift(probImage, window, criteria)
public static RotatedRect CamShift (Mat probImage, Rect window, TermCriteria criteria)
{
if (probImage != null) probImage.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
double[] window_out = new double[4];
double[] tmpArray = new double[5];
video_Video_CamShift_10(probImage.nativeObj, window.x, window.y, window.width, window.height, window_out, criteria.type, criteria.maxCount, criteria.epsilon, tmpArray);
RotatedRect retVal = new RotatedRect (tmpArray);
if(window!=null){ window.x = (int)window_out[0]; window.y = (int)window_out[1]; window.width = (int)window_out[2]; window.height = (int)window_out[3]; }
return retVal;
#else
return null;
#endif
}
//
// C++: bool cv::writeOpticalFlow(String path, Mat flow)
//
//javadoc: writeOpticalFlow(path, flow)
public static bool writeOpticalFlow (string path, Mat flow)
{
if (flow != null) flow.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
bool retVal = video_Video_writeOpticalFlow_10(path, flow.nativeObj);
return retVal;
#else
return false;
#endif
}
//
// C++: double cv::findTransformECC(Mat templateImage, Mat inputImage, Mat& warpMatrix, int motionType = MOTION_AFFINE, TermCriteria criteria = TermCriteria(TermCriteria::COUNT+TermCriteria::EPS, 50, 0.001), Mat inputMask = Mat())
//
//javadoc: findTransformECC(templateImage, inputImage, warpMatrix, motionType, criteria, inputMask)
public static double findTransformECC (Mat templateImage, Mat inputImage, Mat warpMatrix, int motionType, TermCriteria criteria, Mat inputMask)
{
if (templateImage != null) templateImage.ThrowIfDisposed ();
if (inputImage != null) inputImage.ThrowIfDisposed ();
if (warpMatrix != null) warpMatrix.ThrowIfDisposed ();
if (inputMask != null) inputMask.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
double retVal = video_Video_findTransformECC_10(templateImage.nativeObj, inputImage.nativeObj, warpMatrix.nativeObj, motionType, criteria.type, criteria.maxCount, criteria.epsilon, inputMask.nativeObj);
return retVal;
#else
return -1;
#endif
}
//javadoc: findTransformECC(templateImage, inputImage, warpMatrix, motionType, criteria)
public static double findTransformECC (Mat templateImage, Mat inputImage, Mat warpMatrix, int motionType, TermCriteria criteria)
{
if (templateImage != null) templateImage.ThrowIfDisposed ();
if (inputImage != null) inputImage.ThrowIfDisposed ();
if (warpMatrix != null) warpMatrix.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
double retVal = video_Video_findTransformECC_11(templateImage.nativeObj, inputImage.nativeObj, warpMatrix.nativeObj, motionType, criteria.type, criteria.maxCount, criteria.epsilon);
return retVal;
#else
return -1;
#endif
}
//javadoc: findTransformECC(templateImage, inputImage, warpMatrix, motionType)
public static double findTransformECC (Mat templateImage, Mat inputImage, Mat warpMatrix, int motionType)
{
if (templateImage != null) templateImage.ThrowIfDisposed ();
if (inputImage != null) inputImage.ThrowIfDisposed ();
if (warpMatrix != null) warpMatrix.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
double retVal = video_Video_findTransformECC_12(templateImage.nativeObj, inputImage.nativeObj, warpMatrix.nativeObj, motionType);
return retVal;
#else
return -1;
#endif
}
//javadoc: findTransformECC(templateImage, inputImage, warpMatrix)
public static double findTransformECC (Mat templateImage, Mat inputImage, Mat warpMatrix)
{
if (templateImage != null) templateImage.ThrowIfDisposed ();
if (inputImage != null) inputImage.ThrowIfDisposed ();
if (warpMatrix != null) warpMatrix.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
double retVal = video_Video_findTransformECC_13(templateImage.nativeObj, inputImage.nativeObj, warpMatrix.nativeObj);
return retVal;
#else
return -1;
#endif
}
//
// C++: int cv::buildOpticalFlowPyramid(Mat img, vector_Mat& pyramid, Size winSize, int maxLevel, bool withDerivatives = true, int pyrBorder = BORDER_REFLECT_101, int derivBorder = BORDER_CONSTANT, bool tryReuseInputImage = true)
//
//javadoc: buildOpticalFlowPyramid(img, pyramid, winSize, maxLevel, withDerivatives, pyrBorder, derivBorder, tryReuseInputImage)
public static int buildOpticalFlowPyramid (Mat img, List<Mat> pyramid, Size winSize, int maxLevel, bool withDerivatives, int pyrBorder, int derivBorder, bool tryReuseInputImage)
{
if (img != null) img.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
Mat pyramid_mat = new Mat();
int retVal = video_Video_buildOpticalFlowPyramid_10(img.nativeObj, pyramid_mat.nativeObj, winSize.width, winSize.height, maxLevel, withDerivatives, pyrBorder, derivBorder, tryReuseInputImage);
Converters.Mat_to_vector_Mat(pyramid_mat, pyramid);
pyramid_mat.release();
return retVal;
#else
return -1;
#endif
}
//javadoc: buildOpticalFlowPyramid(img, pyramid, winSize, maxLevel, withDerivatives, pyrBorder, derivBorder)
public static int buildOpticalFlowPyramid (Mat img, List<Mat> pyramid, Size winSize, int maxLevel, bool withDerivatives, int pyrBorder, int derivBorder)
{
if (img != null) img.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
Mat pyramid_mat = new Mat();
int retVal = video_Video_buildOpticalFlowPyramid_11(img.nativeObj, pyramid_mat.nativeObj, winSize.width, winSize.height, maxLevel, withDerivatives, pyrBorder, derivBorder);
Converters.Mat_to_vector_Mat(pyramid_mat, pyramid);
pyramid_mat.release();
return retVal;
#else
return -1;
#endif
}
//javadoc: buildOpticalFlowPyramid(img, pyramid, winSize, maxLevel, withDerivatives, pyrBorder)
public static int buildOpticalFlowPyramid (Mat img, List<Mat> pyramid, Size winSize, int maxLevel, bool withDerivatives, int pyrBorder)
{
if (img != null) img.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
Mat pyramid_mat = new Mat();
int retVal = video_Video_buildOpticalFlowPyramid_12(img.nativeObj, pyramid_mat.nativeObj, winSize.width, winSize.height, maxLevel, withDerivatives, pyrBorder);
Converters.Mat_to_vector_Mat(pyramid_mat, pyramid);
pyramid_mat.release();
return retVal;
#else
return -1;
#endif
}
//javadoc: buildOpticalFlowPyramid(img, pyramid, winSize, maxLevel, withDerivatives)
public static int buildOpticalFlowPyramid (Mat img, List<Mat> pyramid, Size winSize, int maxLevel, bool withDerivatives)
{
if (img != null) img.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
Mat pyramid_mat = new Mat();
int retVal = video_Video_buildOpticalFlowPyramid_13(img.nativeObj, pyramid_mat.nativeObj, winSize.width, winSize.height, maxLevel, withDerivatives);
Converters.Mat_to_vector_Mat(pyramid_mat, pyramid);
pyramid_mat.release();
return retVal;
#else
return -1;
#endif
}
//javadoc: buildOpticalFlowPyramid(img, pyramid, winSize, maxLevel)
public static int buildOpticalFlowPyramid (Mat img, List<Mat> pyramid, Size winSize, int maxLevel)
{
if (img != null) img.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
Mat pyramid_mat = new Mat();
int retVal = video_Video_buildOpticalFlowPyramid_14(img.nativeObj, pyramid_mat.nativeObj, winSize.width, winSize.height, maxLevel);
Converters.Mat_to_vector_Mat(pyramid_mat, pyramid);
pyramid_mat.release();
return retVal;
#else
return -1;
#endif
}
//
// C++: int cv::meanShift(Mat probImage, Rect& window, TermCriteria criteria)
//
//javadoc: meanShift(probImage, window, criteria)
public static int meanShift (Mat probImage, Rect window, TermCriteria criteria)
{
if (probImage != null) probImage.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
double[] window_out = new double[4];
int retVal = video_Video_meanShift_10(probImage.nativeObj, window.x, window.y, window.width, window.height, window_out, criteria.type, criteria.maxCount, criteria.epsilon);
if(window!=null){ window.x = (int)window_out[0]; window.y = (int)window_out[1]; window.width = (int)window_out[2]; window.height = (int)window_out[3]; }
return retVal;
#else
return -1;
#endif
}
//
// C++: void cv::calcOpticalFlowFarneback(Mat prev, Mat next, Mat& flow, double pyr_scale, int levels, int winsize, int iterations, int poly_n, double poly_sigma, int flags)
//
//javadoc: calcOpticalFlowFarneback(prev, next, flow, pyr_scale, levels, winsize, iterations, poly_n, poly_sigma, flags)
public static void calcOpticalFlowFarneback (Mat prev, Mat next, Mat flow, double pyr_scale, int levels, int winsize, int iterations, int poly_n, double poly_sigma, int flags)
{
if (prev != null) prev.ThrowIfDisposed ();
if (next != null) next.ThrowIfDisposed ();
if (flow != null) flow.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
video_Video_calcOpticalFlowFarneback_10(prev.nativeObj, next.nativeObj, flow.nativeObj, pyr_scale, levels, winsize, iterations, poly_n, poly_sigma, flags);
return;
#else
return;
#endif
}
//
// C++: void cv::calcOpticalFlowPyrLK(Mat prevImg, Mat nextImg, vector_Point2f prevPts, vector_Point2f& nextPts, vector_uchar& status, vector_float& err, Size winSize = Size(21,21), int maxLevel = 3, TermCriteria criteria = TermCriteria(TermCriteria::COUNT+TermCriteria::EPS, 30, 0.01), int flags = 0, double minEigThreshold = 1e-4)
//
//javadoc: calcOpticalFlowPyrLK(prevImg, nextImg, prevPts, nextPts, status, err, winSize, maxLevel, criteria, flags, minEigThreshold)
public static void calcOpticalFlowPyrLK (Mat prevImg, Mat nextImg, MatOfPoint2f prevPts, MatOfPoint2f nextPts, MatOfByte status, MatOfFloat err, Size winSize, int maxLevel, TermCriteria criteria, int flags, double minEigThreshold)
{
if (prevImg != null) prevImg.ThrowIfDisposed ();
if (nextImg != null) nextImg.ThrowIfDisposed ();
if (prevPts != null) prevPts.ThrowIfDisposed ();
if (nextPts != null) nextPts.ThrowIfDisposed ();
if (status != null) status.ThrowIfDisposed ();
if (err != null) err.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
Mat prevPts_mat = prevPts;
Mat nextPts_mat = nextPts;
Mat status_mat = status;
Mat err_mat = err;
video_Video_calcOpticalFlowPyrLK_10(prevImg.nativeObj, nextImg.nativeObj, prevPts_mat.nativeObj, nextPts_mat.nativeObj, status_mat.nativeObj, err_mat.nativeObj, winSize.width, winSize.height, maxLevel, criteria.type, criteria.maxCount, criteria.epsilon, flags, minEigThreshold);
return;
#else
return;
#endif
}
//javadoc: calcOpticalFlowPyrLK(prevImg, nextImg, prevPts, nextPts, status, err, winSize, maxLevel, criteria, flags)
public static void calcOpticalFlowPyrLK (Mat prevImg, Mat nextImg, MatOfPoint2f prevPts, MatOfPoint2f nextPts, MatOfByte status, MatOfFloat err, Size winSize, int maxLevel, TermCriteria criteria, int flags)
{
if (prevImg != null) prevImg.ThrowIfDisposed ();
if (nextImg != null) nextImg.ThrowIfDisposed ();
if (prevPts != null) prevPts.ThrowIfDisposed ();
if (nextPts != null) nextPts.ThrowIfDisposed ();
if (status != null) status.ThrowIfDisposed ();
if (err != null) err.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
Mat prevPts_mat = prevPts;
Mat nextPts_mat = nextPts;
Mat status_mat = status;
Mat err_mat = err;
video_Video_calcOpticalFlowPyrLK_11(prevImg.nativeObj, nextImg.nativeObj, prevPts_mat.nativeObj, nextPts_mat.nativeObj, status_mat.nativeObj, err_mat.nativeObj, winSize.width, winSize.height, maxLevel, criteria.type, criteria.maxCount, criteria.epsilon, flags);
return;
#else
return;
#endif
}
//javadoc: calcOpticalFlowPyrLK(prevImg, nextImg, prevPts, nextPts, status, err, winSize, maxLevel, criteria)
public static void calcOpticalFlowPyrLK (Mat prevImg, Mat nextImg, MatOfPoint2f prevPts, MatOfPoint2f nextPts, MatOfByte status, MatOfFloat err, Size winSize, int maxLevel, TermCriteria criteria)
{
if (prevImg != null) prevImg.ThrowIfDisposed ();
if (nextImg != null) nextImg.ThrowIfDisposed ();
if (prevPts != null) prevPts.ThrowIfDisposed ();
if (nextPts != null) nextPts.ThrowIfDisposed ();
if (status != null) status.ThrowIfDisposed ();
if (err != null) err.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
Mat prevPts_mat = prevPts;
Mat nextPts_mat = nextPts;
Mat status_mat = status;
Mat err_mat = err;
video_Video_calcOpticalFlowPyrLK_12(prevImg.nativeObj, nextImg.nativeObj, prevPts_mat.nativeObj, nextPts_mat.nativeObj, status_mat.nativeObj, err_mat.nativeObj, winSize.width, winSize.height, maxLevel, criteria.type, criteria.maxCount, criteria.epsilon);
return;
#else
return;
#endif
}
//javadoc: calcOpticalFlowPyrLK(prevImg, nextImg, prevPts, nextPts, status, err, winSize, maxLevel)
public static void calcOpticalFlowPyrLK (Mat prevImg, Mat nextImg, MatOfPoint2f prevPts, MatOfPoint2f nextPts, MatOfByte status, MatOfFloat err, Size winSize, int maxLevel)
{
if (prevImg != null) prevImg.ThrowIfDisposed ();
if (nextImg != null) nextImg.ThrowIfDisposed ();
if (prevPts != null) prevPts.ThrowIfDisposed ();
if (nextPts != null) nextPts.ThrowIfDisposed ();
if (status != null) status.ThrowIfDisposed ();
if (err != null) err.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
Mat prevPts_mat = prevPts;
Mat nextPts_mat = nextPts;
Mat status_mat = status;
Mat err_mat = err;
video_Video_calcOpticalFlowPyrLK_13(prevImg.nativeObj, nextImg.nativeObj, prevPts_mat.nativeObj, nextPts_mat.nativeObj, status_mat.nativeObj, err_mat.nativeObj, winSize.width, winSize.height, maxLevel);
return;
#else
return;
#endif
}
//javadoc: calcOpticalFlowPyrLK(prevImg, nextImg, prevPts, nextPts, status, err, winSize)
public static void calcOpticalFlowPyrLK (Mat prevImg, Mat nextImg, MatOfPoint2f prevPts, MatOfPoint2f nextPts, MatOfByte status, MatOfFloat err, Size winSize)
{
if (prevImg != null) prevImg.ThrowIfDisposed ();
if (nextImg != null) nextImg.ThrowIfDisposed ();
if (prevPts != null) prevPts.ThrowIfDisposed ();
if (nextPts != null) nextPts.ThrowIfDisposed ();
if (status != null) status.ThrowIfDisposed ();
if (err != null) err.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
Mat prevPts_mat = prevPts;
Mat nextPts_mat = nextPts;
Mat status_mat = status;
Mat err_mat = err;
video_Video_calcOpticalFlowPyrLK_14(prevImg.nativeObj, nextImg.nativeObj, prevPts_mat.nativeObj, nextPts_mat.nativeObj, status_mat.nativeObj, err_mat.nativeObj, winSize.width, winSize.height);
return;
#else
return;
#endif
}
//javadoc: calcOpticalFlowPyrLK(prevImg, nextImg, prevPts, nextPts, status, err)
public static void calcOpticalFlowPyrLK (Mat prevImg, Mat nextImg, MatOfPoint2f prevPts, MatOfPoint2f nextPts, MatOfByte status, MatOfFloat err)
{
if (prevImg != null) prevImg.ThrowIfDisposed ();
if (nextImg != null) nextImg.ThrowIfDisposed ();
if (prevPts != null) prevPts.ThrowIfDisposed ();
if (nextPts != null) nextPts.ThrowIfDisposed ();
if (status != null) status.ThrowIfDisposed ();
if (err != null) err.ThrowIfDisposed ();
#if ((UNITY_ANDROID || UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR) || UNITY_5 || UNITY_5_3_OR_NEWER
Mat prevPts_mat = prevPts;
Mat nextPts_mat = nextPts;
Mat status_mat = status;
Mat err_mat = err;
video_Video_calcOpticalFlowPyrLK_15(prevImg.nativeObj, nextImg.nativeObj, prevPts_mat.nativeObj, nextPts_mat.nativeObj, status_mat.nativeObj, err_mat.nativeObj);
return;
#else
return;
#endif
}
#if (UNITY_IOS || UNITY_WEBGL) && !UNITY_EDITOR
const string LIBNAME = "__Internal";
#else
const string LIBNAME = "opencvforunity";
#endif
// C++: Mat cv::readOpticalFlow(String path)
[DllImport (LIBNAME)]
private static extern IntPtr video_Video_readOpticalFlow_10 (string path);
// C++: Ptr_BackgroundSubtractorKNN cv::createBackgroundSubtractorKNN(int history = 500, double dist2Threshold = 400.0, bool detectShadows = true)
[DllImport (LIBNAME)]
private static extern IntPtr video_Video_createBackgroundSubtractorKNN_10 (int history, double dist2Threshold, bool detectShadows);
[DllImport (LIBNAME)]
private static extern IntPtr video_Video_createBackgroundSubtractorKNN_11 (int history, double dist2Threshold);
[DllImport (LIBNAME)]
private static extern IntPtr video_Video_createBackgroundSubtractorKNN_12 (int history);
[DllImport (LIBNAME)]
private static extern IntPtr video_Video_createBackgroundSubtractorKNN_13 ();
// C++: Ptr_BackgroundSubtractorMOG2 cv::createBackgroundSubtractorMOG2(int history = 500, double varThreshold = 16, bool detectShadows = true)
[DllImport (LIBNAME)]
private static extern IntPtr video_Video_createBackgroundSubtractorMOG2_10 (int history, double varThreshold, bool detectShadows);
[DllImport (LIBNAME)]
private static extern IntPtr video_Video_createBackgroundSubtractorMOG2_11 (int history, double varThreshold);
[DllImport (LIBNAME)]
private static extern IntPtr video_Video_createBackgroundSubtractorMOG2_12 (int history);
[DllImport (LIBNAME)]
private static extern IntPtr video_Video_createBackgroundSubtractorMOG2_13 ();
// C++: RotatedRect cv::CamShift(Mat probImage, Rect& window, TermCriteria criteria)
[DllImport (LIBNAME)]
private static extern void video_Video_CamShift_10 (IntPtr probImage_nativeObj, int window_x, int window_y, int window_width, int window_height, double[] window_out, int criteria_type, int criteria_maxCount, double criteria_epsilon, double[] retVal);
// C++: bool cv::writeOpticalFlow(String path, Mat flow)
[DllImport (LIBNAME)]
private static extern bool video_Video_writeOpticalFlow_10 (string path, IntPtr flow_nativeObj);
// C++: double cv::findTransformECC(Mat templateImage, Mat inputImage, Mat& warpMatrix, int motionType = MOTION_AFFINE, TermCriteria criteria = TermCriteria(TermCriteria::COUNT+TermCriteria::EPS, 50, 0.001), Mat inputMask = Mat())
[DllImport (LIBNAME)]
private static extern double video_Video_findTransformECC_10 (IntPtr templateImage_nativeObj, IntPtr inputImage_nativeObj, IntPtr warpMatrix_nativeObj, int motionType, int criteria_type, int criteria_maxCount, double criteria_epsilon, IntPtr inputMask_nativeObj);
[DllImport (LIBNAME)]
private static extern double video_Video_findTransformECC_11 (IntPtr templateImage_nativeObj, IntPtr inputImage_nativeObj, IntPtr warpMatrix_nativeObj, int motionType, int criteria_type, int criteria_maxCount, double criteria_epsilon);
[DllImport (LIBNAME)]
private static extern double video_Video_findTransformECC_12 (IntPtr templateImage_nativeObj, IntPtr inputImage_nativeObj, IntPtr warpMatrix_nativeObj, int motionType);
[DllImport (LIBNAME)]
private static extern double video_Video_findTransformECC_13 (IntPtr templateImage_nativeObj, IntPtr inputImage_nativeObj, IntPtr warpMatrix_nativeObj);
// C++: int cv::buildOpticalFlowPyramid(Mat img, vector_Mat& pyramid, Size winSize, int maxLevel, bool withDerivatives = true, int pyrBorder = BORDER_REFLECT_101, int derivBorder = BORDER_CONSTANT, bool tryReuseInputImage = true)
[DllImport (LIBNAME)]
private static extern int video_Video_buildOpticalFlowPyramid_10 (IntPtr img_nativeObj, IntPtr pyramid_mat_nativeObj, double winSize_width, double winSize_height, int maxLevel, bool withDerivatives, int pyrBorder, int derivBorder, bool tryReuseInputImage);
[DllImport (LIBNAME)]
private static extern int video_Video_buildOpticalFlowPyramid_11 (IntPtr img_nativeObj, IntPtr pyramid_mat_nativeObj, double winSize_width, double winSize_height, int maxLevel, bool withDerivatives, int pyrBorder, int derivBorder);
[DllImport (LIBNAME)]
private static extern int video_Video_buildOpticalFlowPyramid_12 (IntPtr img_nativeObj, IntPtr pyramid_mat_nativeObj, double winSize_width, double winSize_height, int maxLevel, bool withDerivatives, int pyrBorder);
[DllImport (LIBNAME)]
private static extern int video_Video_buildOpticalFlowPyramid_13 (IntPtr img_nativeObj, IntPtr pyramid_mat_nativeObj, double winSize_width, double winSize_height, int maxLevel, bool withDerivatives);
[DllImport (LIBNAME)]
private static extern int video_Video_buildOpticalFlowPyramid_14 (IntPtr img_nativeObj, IntPtr pyramid_mat_nativeObj, double winSize_width, double winSize_height, int maxLevel);
// C++: int cv::meanShift(Mat probImage, Rect& window, TermCriteria criteria)
[DllImport (LIBNAME)]
private static extern int video_Video_meanShift_10 (IntPtr probImage_nativeObj, int window_x, int window_y, int window_width, int window_height, double[] window_out, int criteria_type, int criteria_maxCount, double criteria_epsilon);
// C++: void cv::calcOpticalFlowFarneback(Mat prev, Mat next, Mat& flow, double pyr_scale, int levels, int winsize, int iterations, int poly_n, double poly_sigma, int flags)
[DllImport (LIBNAME)]
private static extern void video_Video_calcOpticalFlowFarneback_10 (IntPtr prev_nativeObj, IntPtr next_nativeObj, IntPtr flow_nativeObj, double pyr_scale, int levels, int winsize, int iterations, int poly_n, double poly_sigma, int flags);
// C++: void cv::calcOpticalFlowPyrLK(Mat prevImg, Mat nextImg, vector_Point2f prevPts, vector_Point2f& nextPts, vector_uchar& status, vector_float& err, Size winSize = Size(21,21), int maxLevel = 3, TermCriteria criteria = TermCriteria(TermCriteria::COUNT+TermCriteria::EPS, 30, 0.01), int flags = 0, double minEigThreshold = 1e-4)
[DllImport (LIBNAME)]
private static extern void video_Video_calcOpticalFlowPyrLK_10 (IntPtr prevImg_nativeObj, IntPtr nextImg_nativeObj, IntPtr prevPts_mat_nativeObj, IntPtr nextPts_mat_nativeObj, IntPtr status_mat_nativeObj, IntPtr err_mat_nativeObj, double winSize_width, double winSize_height, int maxLevel, int criteria_type, int criteria_maxCount, double criteria_epsilon, int flags, double minEigThreshold);
[DllImport (LIBNAME)]
private static extern void video_Video_calcOpticalFlowPyrLK_11 (IntPtr prevImg_nativeObj, IntPtr nextImg_nativeObj, IntPtr prevPts_mat_nativeObj, IntPtr nextPts_mat_nativeObj, IntPtr status_mat_nativeObj, IntPtr err_mat_nativeObj, double winSize_width, double winSize_height, int maxLevel, int criteria_type, int criteria_maxCount, double criteria_epsilon, int flags);
[DllImport (LIBNAME)]
private static extern void video_Video_calcOpticalFlowPyrLK_12 (IntPtr prevImg_nativeObj, IntPtr nextImg_nativeObj, IntPtr prevPts_mat_nativeObj, IntPtr nextPts_mat_nativeObj, IntPtr status_mat_nativeObj, IntPtr err_mat_nativeObj, double winSize_width, double winSize_height, int maxLevel, int criteria_type, int criteria_maxCount, double criteria_epsilon);
[DllImport (LIBNAME)]
private static extern void video_Video_calcOpticalFlowPyrLK_13 (IntPtr prevImg_nativeObj, IntPtr nextImg_nativeObj, IntPtr prevPts_mat_nativeObj, IntPtr nextPts_mat_nativeObj, IntPtr status_mat_nativeObj, IntPtr err_mat_nativeObj, double winSize_width, double winSize_height, int maxLevel);
[DllImport (LIBNAME)]
private static extern void video_Video_calcOpticalFlowPyrLK_14 (IntPtr prevImg_nativeObj, IntPtr nextImg_nativeObj, IntPtr prevPts_mat_nativeObj, IntPtr nextPts_mat_nativeObj, IntPtr status_mat_nativeObj, IntPtr err_mat_nativeObj, double winSize_width, double winSize_height);
[DllImport (LIBNAME)]
private static extern void video_Video_calcOpticalFlowPyrLK_15 (IntPtr prevImg_nativeObj, IntPtr nextImg_nativeObj, IntPtr prevPts_mat_nativeObj, IntPtr nextPts_mat_nativeObj, IntPtr status_mat_nativeObj, IntPtr err_mat_nativeObj);
}
}