OpenCV_4.2.0/opencv_contrib-4.2.0/modules/aruco/samples/detect_diamonds.cpp

253 lines
9.8 KiB
C++

/*
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License Agreement
For Open Source Computer Vision Library
(3-clause BSD License)
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Redistribution and use in source and binary forms, with or without modification,
are permitted provided that the following conditions are met:
* Redistributions of source code must retain the above copyright notice,
this list of conditions and the following disclaimer.
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this list of conditions and the following disclaimer in the documentation
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* Neither the names of the copyright holders nor the names of the contributors
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This software is provided by the copyright holders and contributors "as is" and
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any direct, indirect, incidental, special, exemplary, or consequential damages
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*/
#include <opencv2/highgui.hpp>
#include <opencv2/aruco/charuco.hpp>
#include <vector>
#include <iostream>
using namespace std;
using namespace cv;
namespace {
const char* about = "Detect ChArUco markers";
const char* keys =
"{sl | | Square side length (in meters) }"
"{ml | | Marker side length (in meters) }"
"{d | | dictionary: DICT_4X4_50=0, DICT_4X4_100=1, DICT_4X4_250=2,"
"DICT_4X4_1000=3, DICT_5X5_50=4, DICT_5X5_100=5, DICT_5X5_250=6, DICT_5X5_1000=7, "
"DICT_6X6_50=8, DICT_6X6_100=9, DICT_6X6_250=10, DICT_6X6_1000=11, DICT_7X7_50=12,"
"DICT_7X7_100=13, DICT_7X7_250=14, DICT_7X7_1000=15, DICT_ARUCO_ORIGINAL = 16}"
"{c | | Output file with calibrated camera parameters }"
"{as | | Automatic scale. The provided number is multiplied by the last"
"diamond id becoming an indicator of the square length. In this case, the -sl and "
"-ml are only used to know the relative length relation between squares and markers }"
"{v | | Input from video file, if ommited, input comes from camera }"
"{ci | 0 | Camera id if input doesnt come from video (-v) }"
"{dp | | File of marker detector parameters }"
"{rs | | Apply refind strategy }"
"{r | | show rejected candidates too }";
}
/**
*/
static bool readCameraParameters(string filename, Mat &camMatrix, Mat &distCoeffs) {
FileStorage fs(filename, FileStorage::READ);
if(!fs.isOpened())
return false;
fs["camera_matrix"] >> camMatrix;
fs["distortion_coefficients"] >> distCoeffs;
return true;
}
/**
*/
static bool readDetectorParameters(string filename, Ptr<aruco::DetectorParameters> &params) {
FileStorage fs(filename, FileStorage::READ);
if(!fs.isOpened())
return false;
fs["adaptiveThreshWinSizeMin"] >> params->adaptiveThreshWinSizeMin;
fs["adaptiveThreshWinSizeMax"] >> params->adaptiveThreshWinSizeMax;
fs["adaptiveThreshWinSizeStep"] >> params->adaptiveThreshWinSizeStep;
fs["adaptiveThreshConstant"] >> params->adaptiveThreshConstant;
fs["minMarkerPerimeterRate"] >> params->minMarkerPerimeterRate;
fs["maxMarkerPerimeterRate"] >> params->maxMarkerPerimeterRate;
fs["polygonalApproxAccuracyRate"] >> params->polygonalApproxAccuracyRate;
fs["minCornerDistanceRate"] >> params->minCornerDistanceRate;
fs["minDistanceToBorder"] >> params->minDistanceToBorder;
fs["minMarkerDistanceRate"] >> params->minMarkerDistanceRate;
fs["cornerRefinementMethod"] >> params->cornerRefinementMethod;
fs["cornerRefinementWinSize"] >> params->cornerRefinementWinSize;
fs["cornerRefinementMaxIterations"] >> params->cornerRefinementMaxIterations;
fs["cornerRefinementMinAccuracy"] >> params->cornerRefinementMinAccuracy;
fs["markerBorderBits"] >> params->markerBorderBits;
fs["perspectiveRemovePixelPerCell"] >> params->perspectiveRemovePixelPerCell;
fs["perspectiveRemoveIgnoredMarginPerCell"] >> params->perspectiveRemoveIgnoredMarginPerCell;
fs["maxErroneousBitsInBorderRate"] >> params->maxErroneousBitsInBorderRate;
fs["minOtsuStdDev"] >> params->minOtsuStdDev;
fs["errorCorrectionRate"] >> params->errorCorrectionRate;
return true;
}
/**
*/
int main(int argc, char *argv[]) {
CommandLineParser parser(argc, argv, keys);
parser.about(about);
if(argc < 4) {
parser.printMessage();
return 0;
}
float squareLength = parser.get<float>("sl");
float markerLength = parser.get<float>("ml");
int dictionaryId = parser.get<int>("d");
bool showRejected = parser.has("r");
bool estimatePose = parser.has("c");
bool autoScale = parser.has("as");
float autoScaleFactor = autoScale ? parser.get<float>("as") : 1.f;
Ptr<aruco::DetectorParameters> detectorParams = aruco::DetectorParameters::create();
if(parser.has("dp")) {
bool readOk = readDetectorParameters(parser.get<string>("dp"), detectorParams);
if(!readOk) {
cerr << "Invalid detector parameters file" << endl;
return 0;
}
}
int camId = parser.get<int>("ci");
String video;
if(parser.has("v")) {
video = parser.get<String>("v");
}
if(!parser.check()) {
parser.printErrors();
return 0;
}
Ptr<aruco::Dictionary> dictionary =
aruco::getPredefinedDictionary(aruco::PREDEFINED_DICTIONARY_NAME(dictionaryId));
Mat camMatrix, distCoeffs;
if(estimatePose) {
bool readOk = readCameraParameters(parser.get<string>("c"), camMatrix, distCoeffs);
if(!readOk) {
cerr << "Invalid camera file" << endl;
return 0;
}
}
VideoCapture inputVideo;
int waitTime;
if(!video.empty()) {
inputVideo.open(video);
waitTime = 0;
} else {
inputVideo.open(camId);
waitTime = 10;
}
double totalTime = 0;
int totalIterations = 0;
while(inputVideo.grab()) {
Mat image, imageCopy;
inputVideo.retrieve(image);
double tick = (double)getTickCount();
vector< int > markerIds;
vector< Vec4i > diamondIds;
vector< vector< Point2f > > markerCorners, rejectedMarkers, diamondCorners;
vector< Vec3d > rvecs, tvecs;
// detect markers
aruco::detectMarkers(image, dictionary, markerCorners, markerIds, detectorParams,
rejectedMarkers);
// detect diamonds
if(markerIds.size() > 0)
aruco::detectCharucoDiamond(image, markerCorners, markerIds,
squareLength / markerLength, diamondCorners, diamondIds,
camMatrix, distCoeffs);
// estimate diamond pose
if(estimatePose && diamondIds.size() > 0) {
if(!autoScale) {
aruco::estimatePoseSingleMarkers(diamondCorners, squareLength, camMatrix,
distCoeffs, rvecs, tvecs);
} else {
// if autoscale, extract square size from last diamond id
for(unsigned int i = 0; i < diamondCorners.size(); i++) {
float autoSquareLength = autoScaleFactor * float(diamondIds[i].val[3]);
vector< vector< Point2f > > currentCorners;
vector< Vec3d > currentRvec, currentTvec;
currentCorners.push_back(diamondCorners[i]);
aruco::estimatePoseSingleMarkers(currentCorners, autoSquareLength, camMatrix,
distCoeffs, currentRvec, currentTvec);
rvecs.push_back(currentRvec[0]);
tvecs.push_back(currentTvec[0]);
}
}
}
double currentTime = ((double)getTickCount() - tick) / getTickFrequency();
totalTime += currentTime;
totalIterations++;
if(totalIterations % 30 == 0) {
cout << "Detection Time = " << currentTime * 1000 << " ms "
<< "(Mean = " << 1000 * totalTime / double(totalIterations) << " ms)" << endl;
}
// draw results
image.copyTo(imageCopy);
if(markerIds.size() > 0)
aruco::drawDetectedMarkers(imageCopy, markerCorners);
if(showRejected && rejectedMarkers.size() > 0)
aruco::drawDetectedMarkers(imageCopy, rejectedMarkers, noArray(), Scalar(100, 0, 255));
if(diamondIds.size() > 0) {
aruco::drawDetectedDiamonds(imageCopy, diamondCorners, diamondIds);
if(estimatePose) {
for(unsigned int i = 0; i < diamondIds.size(); i++)
aruco::drawAxis(imageCopy, camMatrix, distCoeffs, rvecs[i], tvecs[i],
squareLength * 0.5f);
}
}
imshow("out", imageCopy);
char key = (char)waitKey(waitTime);
if(key == 27) break;
}
return 0;
}