video-libs / opencv /sources /modules /video /src /tracking /tracker_vit.cpp

ffmpeg (v6.0/v7.x), gensim, numpy, opencv

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	// This file is part of OpenCV project.
	// It is subject to the license terms in the LICENSE file found in the top-level directory
	// of this distribution and at http://opencv.org/license.html.

	// Author, PengyuLiu, 1872918507@qq.com

	#include "../precomp.hpp"
	#ifdef HAVE_OPENCV_DNN
	#include "opencv2/dnn.hpp"
	#endif

	namespace cv {

	TrackerVit::TrackerVit()
	{
	// nothing
	}

	TrackerVit::~TrackerVit()
	{
	// nothing
	}

	TrackerVit::Params::Params()
	{
	net = "vitTracker.onnx";
	meanvalue = Scalar{0.485, 0.456, 0.406};
	stdvalue = Scalar{0.229, 0.224, 0.225};
	#ifdef HAVE_OPENCV_DNN
	backend = dnn::DNN_BACKEND_DEFAULT;
	target = dnn::DNN_TARGET_CPU;
	#else
	backend = -1; // invalid value
	target = -1; // invalid value
	#endif
	}

	#ifdef HAVE_OPENCV_DNN

	class TrackerVitImpl : public TrackerVit
	{
	public:
	TrackerVitImpl(const TrackerVit::Params& parameters)
	: params(parameters)
	{
	net = dnn::readNet(params.net);
	CV_Assert(!net.empty());

	net.setPreferableBackend(params.backend);
	net.setPreferableTarget(params.target);
	}

	void init(InputArray image, const Rect& boundingBox) CV_OVERRIDE;
	bool update(InputArray image, Rect& boundingBox) CV_OVERRIDE;
	float getTrackingScore() CV_OVERRIDE;

	Rect rect_last;
	float tracking_score;

	TrackerVit::Params params;


	protected:
	void preprocess(const Mat& src, Mat& dst, Size size);

	const Size searchSize{256, 256};
	const Size templateSize{128, 128};

	Mat hanningWindow;

	dnn::Net net;
	Mat image;
	};

	static void crop_image(const Mat& src, Mat& dst, Rect box, int factor)
	{
	int x = box.x, y = box.y, w = box.width, h = box.height;
	int crop_sz = cvCeil(sqrt(w * h) * factor);

	int x1 = x + (w - crop_sz) / 2;
	int x2 = x1 + crop_sz;
	int y1 = y + (h - crop_sz) / 2;
	int y2 = y1 + crop_sz;

	int x1_pad = std::max(0, -x1);
	int y1_pad = std::max(0, -y1);
	int x2_pad = std::max(x2 - src.size[1] + 1, 0);
	int y2_pad = std::max(y2 - src.size[0] + 1, 0);

	Rect roi(x1 + x1_pad, y1 + y1_pad, x2 - x2_pad - x1 - x1_pad, y2 - y2_pad - y1 - y1_pad);
	Mat im_crop = src(roi);
	copyMakeBorder(im_crop, dst, y1_pad, y2_pad, x1_pad, x2_pad, BORDER_CONSTANT);
	}

	void TrackerVitImpl::preprocess(const Mat& src, Mat& dst, Size size)
	{
	Mat mean = Mat(size, CV_32FC3, params.meanvalue);
	Mat std = Mat(size, CV_32FC3, params.stdvalue);
	mean = dnn::blobFromImage(mean, 1.0, Size(), Scalar(), false);
	std = dnn::blobFromImage(std, 1.0, Size(), Scalar(), false);

	Mat img;
	resize(src, img, size);

	dst = dnn::blobFromImage(img, 1.0, Size(), Scalar(), false);
	dst /= 255;
	dst = (dst - mean) / std;
	}

	static Mat hann1d(int sz, bool centered = true) {
	Mat hanningWindow(sz, 1, CV_32FC1);
	float* data = hanningWindow.ptr<float>(0);

	if(centered) {
	for(int i = 0; i < sz; i++) {
	float val = 0.5f * (1.f - std::cos(static_cast<float>(2 * M_PI / (sz + 1)) * (i + 1)));
	data[i] = val;
	}
	}
	else {
	int half_sz = sz / 2;
	for(int i = 0; i <= half_sz; i++) {
	float val = 0.5f * (1.f + std::cos(static_cast<float>(2 * M_PI / (sz + 2)) * i));
	data[i] = val;
	data[sz - 1 - i] = val;
	}
	}

	return hanningWindow;
	}

	static Mat hann2d(Size size, bool centered = true) {
	int rows = size.height;
	int cols = size.width;

	Mat hanningWindowRows = hann1d(rows, centered);
	Mat hanningWindowCols = hann1d(cols, centered);

	Mat hanningWindow = hanningWindowRows * hanningWindowCols.t();

	return hanningWindow;
	}

	static Rect returnfromcrop(float x, float y, float w, float h, Rect res_Last)
	{
	int cropwindowwh = 4 * cvFloor(sqrt(res_Last.width * res_Last.height));
	int x0 = res_Last.x + (res_Last.width - cropwindowwh) / 2;
	int y0 = res_Last.y + (res_Last.height - cropwindowwh) / 2;
	Rect finalres;
	finalres.x = cvFloor(x * cropwindowwh + x0);
	finalres.y = cvFloor(y * cropwindowwh + y0);
	finalres.width = cvFloor(w * cropwindowwh);
	finalres.height = cvFloor(h * cropwindowwh);
	return finalres;
	}

	void TrackerVitImpl::init(InputArray image_, const Rect &boundingBox_)
	{
	image = image_.getMat().clone();
	Mat crop;
	crop_image(image, crop, boundingBox_, 2);
	Mat blob;
	preprocess(crop, blob, templateSize);
	net.setInput(blob, "template");
	Size size(16, 16);
	hanningWindow = hann2d(size, true);
	rect_last = boundingBox_;
	}

	bool TrackerVitImpl::update(InputArray image_, Rect &boundingBoxRes)
	{
	image = image_.getMat().clone();
	Mat crop;
	crop_image(image, crop, rect_last, 4);
	Mat blob;
	preprocess(crop, blob, searchSize);
	net.setInput(blob, "search");
	std::vector<String> outputName = {"output1", "output2", "output3"};
	std::vector<Mat> outs;
	net.forward(outs, outputName);
	CV_Assert(outs.size() == 3);

	Mat conf_map = outs[0].reshape(0, {16, 16});
	Mat size_map = outs[1].reshape(0, {2, 16, 16});
	Mat offset_map = outs[2].reshape(0, {2, 16, 16});

	multiply(conf_map, hanningWindow, conf_map);

	double maxVal;
	Point maxLoc;
	minMaxLoc(conf_map, nullptr, &maxVal, nullptr, &maxLoc);
	tracking_score = static_cast<float>(maxVal);

	float cx = (maxLoc.x + offset_map.at<float>(0, maxLoc.y, maxLoc.x)) / 16;
	float cy = (maxLoc.y + offset_map.at<float>(1, maxLoc.y, maxLoc.x)) / 16;
	float w = size_map.at<float>(0, maxLoc.y, maxLoc.x);
	float h = size_map.at<float>(1, maxLoc.y, maxLoc.x);

	Rect finalres = returnfromcrop(cx - w / 2, cy - h / 2, w, h, rect_last);
	rect_last = finalres;
	boundingBoxRes = finalres;
	return true;
	}

	float TrackerVitImpl::getTrackingScore()
	{
	return tracking_score;
	}

	Ptr<TrackerVit> TrackerVit::create(const TrackerVit::Params& parameters)
	{
	return makePtr<TrackerVitImpl>(parameters);
	}

	#else // OPENCV_HAVE_DNN
	Ptr<TrackerVit> TrackerVit::create(const TrackerVit::Params& parameters)
	{
	CV_UNUSED(parameters);
	CV_Error(Error::StsNotImplemented, "to use vittrack, the tracking module needs to be built with opencv_dnn !");
	}
	#endif // OPENCV_HAVE_DNN
	}