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answer_44.cpp
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answer_44.cpp
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#include <opencv2/core.hpp>
#include <opencv2/highgui.hpp>
#include <iostream>
#include <math.h>
// RGB to Gray scale
cv::Mat BGR2GRAY(cv::Mat img){
// get height and width
int height = img.rows;
int width = img.cols;
int channel = img.channels();
// prepare output
cv::Mat out = cv::Mat::zeros(height, width, CV_8UC1);
// BGR -> Gray
for (int y = 0; y < height; y++){
for (int x = 0; x < width; x++){
out.at<uchar>(y, x) = (int)((float)img.at<cv::Vec3b>(y, x)[0] * 0.0722 + \
(float)img.at<cv::Vec3b>(y, x)[1] * 0.7152 + \
(float)img.at<cv::Vec3b>(y, x)[2] * 0.2126);
}
}
return out;
}
float clip(float value, float min, float max){
return fmin(fmax(value, 0), 255);
}
// gaussian filter
cv::Mat gaussian_filter(cv::Mat img, double sigma, int kernel_size){
int height = img.rows;
int width = img.cols;
int channel = img.channels();
// prepare output
cv::Mat out = cv::Mat::zeros(height, width, CV_8UC3);
if (channel == 1) {
out = cv::Mat::zeros(height, width, CV_8UC1);
}
// prepare kernel
int pad = floor(kernel_size / 2);
int _x = 0, _y = 0;
double kernel_sum = 0;
// get gaussian kernel
float kernel[kernel_size][kernel_size];
for (int y = 0; y < kernel_size; y++){
for (int x = 0; x < kernel_size; x++){
_y = y - pad;
_x = x - pad;
kernel[y][x] = 1 / (2 * M_PI * sigma * sigma) * exp( - (_x * _x + _y * _y) / (2 * sigma * sigma));
kernel_sum += kernel[y][x];
}
}
for (int y = 0; y < kernel_size; y++){
for (int x = 0; x < kernel_size; x++){
kernel[y][x] /= kernel_sum;
}
}
// filtering
double v = 0;
for (int y = 0; y < height; y++){
for (int x = 0; x < width; x++){
// for BGR
if (channel == 3){
for (int c = 0; c < channel; c++){
v = 0;
for (int dy = -pad; dy < pad + 1; dy++){
for (int dx = -pad; dx < pad + 1; dx++){
if (((x + dx) >= 0) && ((y + dy) >= 0) && ((x + dx) < width) && ((y + dy) < height)){
v += (double)img.at<cv::Vec3b>(y + dy, x + dx)[c] * kernel[dy + pad][dx + pad];
}
}
}
out.at<cv::Vec3b>(y, x)[c] = (uchar)clip(v, 0, 255);
}
} else {
// for Gray
v = 0;
for (int dy = -pad; dy < pad + 1; dy++){
for (int dx = -pad; dx < pad + 1; dx++){
if (((x + dx) >= 0) && ((y + dy) >= 0) && ((x + dx) < width) && ((y + dy) < height)){
v += (double)img.at<uchar>(y + dy, x + dx) * kernel[dy + pad][dx + pad];
}
}
}
out.at<uchar>(y, x) = (uchar)clip(v, 0, 255);
}
}
}
return out;
}
// Sobel filter
cv::Mat sobel_filter(cv::Mat img, int kernel_size, bool horizontal){
int height = img.rows;
int width = img.cols;
int channel = img.channels();
// prepare output
cv::Mat out = cv::Mat::zeros(height, width, CV_8UC1);
// prepare kernel
double kernel[kernel_size][kernel_size] = {{1, 2, 1}, {0, 0, 0}, {-1, -2, -1}};
if (horizontal){
kernel[0][1] = 0;
kernel[0][2] = -1;
kernel[1][0] = 2;
kernel[1][2] = -2;
kernel[2][0] = 1;
kernel[2][1] = 0;
}
int pad = floor(kernel_size / 2);
double v = 0;
// filtering
for (int y = 0; y < height; y++){
for (int x = 0; x < width; x++){
v = 0;
for (int dy = -pad; dy < pad + 1; dy++){
for (int dx = -pad; dx < pad + 1; dx++){
if (((y + dy) >= 0) && (( x + dx) >= 0) && ((y + dy) < height) && ((x + dx) < width)){
v += (double)img.at<uchar>(y + dy, x + dx) * kernel[dy + pad][dx + pad];
}
}
}
out.at<uchar>(y, x) = (uchar)clip(v, 0, 255);
}
}
return out;
}
// get edge
cv::Mat get_edge(cv::Mat fx, cv::Mat fy){
// get height and width
int height = fx.rows;
int width = fx.cols;
// prepare output
cv::Mat out = cv::Mat::zeros(height, width, CV_8UC1);
double _fx, _fy;
for(int y = 0; y < height; y++){
for(int x = 0; x < width; x++){
_fx = (double)fx.at<uchar>(y, x);
_fy = (double)fy.at<uchar>(y, x);
out.at<uchar>(y, x) = (uchar)clip(sqrt(_fx * _fx + _fy * _fy), 0, 255);
}
}
return out;
}
// get angle
cv::Mat get_angle(cv::Mat fx, cv::Mat fy){
// get height and width
int height = fx.rows;
int width = fx.cols;
// prepare output
cv::Mat out = cv::Mat::zeros(height, width, CV_8UC1);
double _fx, _fy;
double angle;
for(int y = 0; y < height; y++){
for(int x = 0; x < width; x++){
_fx = fmax((double)fx.at<uchar>(y, x), 0.000001);
_fy = (double)fy.at<uchar>(y, x);
angle = atan2(_fy, _fx);
angle = angle / M_PI * 180;
if(angle < -22.5){
angle = 180 + angle;
} else if (angle >= 157.5) {
angle = angle - 180;
}
// quantization
if (angle <= 22.5){
out.at<uchar>(y, x) = 0;
} else if (angle <= 67.5){
out.at<uchar>(y, x) = 45;
} else if (angle <= 112.5){
out.at<uchar>(y, x) = 90;
} else {
out.at<uchar>(y, x) = 135;
}
}
}
return out;
}
// non maximum suppression
cv::Mat non_maximum_suppression(cv::Mat angle, cv::Mat edge){
int height = angle.rows;
int width = angle.cols;
int channel = angle.channels();
int dx1, dx2, dy1, dy2;
int now_angle;
// prepare output
cv::Mat _edge = cv::Mat::zeros(height, width, CV_8UC1);
for (int y = 0; y < height; y++){
for (int x = 0; x < width; x++){
now_angle = angle.at<uchar>(y, x);
// angle condition
if (now_angle == 0){
dx1 = -1;
dy1 = 0;
dx2 = 1;
dy2 = 0;
} else if(now_angle == 45) {
dx1 = -1;
dy1 = 1;
dx2 = 1;
dy2 = -1;
} else if(now_angle == 90){
dx1 = 0;
dy1 = -1;
dx2 = 0;
dy2 = 1;
} else {
dx1 = -1;
dy1 = -1;
dx2 = 1;
dy2 = 1;
}
if (x == 0){
dx1 = fmax(dx1, 0);
dx2 = fmax(dx2, 0);
}
if (x == (width - 1)){
dx1 = fmin(dx1, 0);
dx2 = fmin(dx2, 0);
}
if (y == 0){
dy1 = fmax(dy1, 0);
dy2 = fmax(dy2, 0);
}
if (y == (height - 1)){
dy1 = fmin(dy1, 0);
dy2 = fmin(dy2, 0);
}
// if pixel is max among adjuscent pixels, pixel is kept
if (fmax(fmax(edge.at<uchar>(y, x), edge.at<uchar>(y + dy1, x + dx1)), edge.at<uchar>(y + dy2, x + dx2)) == edge.at<uchar>(y, x)) {
_edge.at<uchar>(y, x) = edge.at<uchar>(y, x);
}
}
}
return _edge;
}
// histerisis
cv::Mat histerisis(cv::Mat edge, int HT, int LT){
int height = edge.rows;
int width = edge.cols;
int channle = edge.channels();
// prepare output
cv::Mat _edge = cv::Mat::zeros(height, width, CV_8UC1);
int now_pixel;
for (int y = 0; y < height; y++){
for (int x = 0; x < width; x++){
// get pixel
now_pixel = edge.at<uchar>(y, x);
// if pixel >= HT
if (now_pixel >= HT){
_edge.at<uchar>(y, x) = 255;
}
// if LT < pixel < HT
else if (now_pixel > LT) {
for (int dy = -1; dy < 2; dy++){
for (int dx = -1; dx < 2; dx++){
// if 8 nearest neighbor pixel >= HT
if (edge.at<uchar>(fmin(fmax(y + dy, 0), 255), fmin(fmax(x + dx, 0), 255)) >= HT){
_edge.at<uchar>(y, x) = 255;
}
}
}
}
}
}
return _edge;
}
// Canny
cv::Mat Canny(cv::Mat img){
// BGR -> Gray
cv::Mat gray = BGR2GRAY(img);
// gaussian filter
cv::Mat gaussian = gaussian_filter(gray, 1.4, 5);
// sobel filter (vertical)
cv::Mat fy = sobel_filter(gaussian, 3, false);
// sobel filter (horizontal)
cv::Mat fx = sobel_filter(gaussian, 3, true);
// get edge
cv::Mat edge = get_edge(fx, fy);
// get angle
cv::Mat angle = get_angle(fx, fy);
// edge non-maximum suppression
edge = non_maximum_suppression(angle, edge);
// histerisis
edge = histerisis(edge, 100, 30);
return edge;
}
//------
// hough
const int ANGLE_T = 180;
const int RHO_MAX = 320;
// hough table
struct struct_hough_table {
int table[RHO_MAX * 2][ANGLE_T];
};
// hough vote
struct_hough_table Hough_vote(struct_hough_table hough_table, cv::Mat img){
int height = img.rows;
int width = img.cols;
int rho = 0;
double angle = 0;
for (int y = 0; y < height; y++){
for (int x = 0; x < width; x++){
// if not edge, skip
if (img.at<uchar>(y, x) != 255){
continue;
}
// 0 <= angle t < 180
for (int t = 0; t < ANGLE_T; t++){
angle = M_PI / 180 * t;
rho = (int)(x * cos(angle) + y * sin(angle));
hough_table.table[rho + RHO_MAX][t] ++;
}
}
}
return hough_table;
}
// hough nms
struct_hough_table Hough_NMS(struct_hough_table hough_table){
// output hough table
struct_hough_table output_hough_table;
// initialize 0
for (int rho = 0; rho < RHO_MAX * 2; rho++){
for (int t = 0; t < ANGLE_T; t++){
output_hough_table.table[rho][t] = 0;
}
}
// top N x, y
int N = 30;
int top_N_rho[N], top_N_t[N], top_N_vote[N];
int tmp_rho, tmp_t, tmp_vote, tmp_rho2, tmp_t2, tmp_vote2;
int rho, t;
for (int n = 0; n < N; n++){
top_N_rho[n] = -1;
top_N_t[n] = -1;
top_N_vote[n] = -1;
}
for (int rho = 0; rho < RHO_MAX * 2; rho++){
for (int t = 0; t < ANGLE_T; t++){
if (hough_table.table[rho][t] == 0){
continue;
}
// compare to left top
if (((t - 1) >= 0) && ((rho - 1) >= 0)){
if (hough_table.table[rho][t] < hough_table.table[rho - 1][t - 1]){
continue;
}
}
// comparet to top
if ((rho - 1) >= 0){
if (hough_table.table[rho][t] < hough_table.table[rho - 1][t]){
continue;
}
}
// compare to left top
if (((t + 1) < ANGLE_T) && ((rho - 1) >= 0)){
if (hough_table.table[rho][t] < hough_table.table[rho - 1][t + 1]){
continue;
}
}
// compare to left
if ((t - 1) >= 0){
if (hough_table.table[rho][t] < hough_table.table[rho][t - 1]){
continue;
}
}
// compare to right
if ((t + 1) < ANGLE_T){
if (hough_table.table[rho][t] < hough_table.table[rho][t + 1]){
continue;
}
}
// compare to left bottom
if (((t - 1) >= 0) && ((rho + 1) < RHO_MAX * 2)){
if (hough_table.table[rho][t] < hough_table.table[rho + 1][t - 1]){
continue;
}
}
// compare to bottom
if ((rho + 1) < RHO_MAX * 2){
if (hough_table.table[rho][t] < hough_table.table[rho + 1][t]){
continue;
}
}
// compare to right bottom
if (((t + 1) < ANGLE_T) && ((rho + 1) < RHO_MAX * 2)){
if (hough_table.table[rho][t] < hough_table.table[rho + 1][t + 1]){
continue;
}
}
// Select top N votes
for (int n = 0; n < N; n++){
if (top_N_vote[n] <= hough_table.table[rho][t]){
tmp_vote = top_N_vote[n];
tmp_rho = top_N_rho[n];
tmp_t = top_N_t[n];
top_N_vote[n] = hough_table.table[rho][t];
top_N_rho[n] = rho;
top_N_t[n] = t;
for (int m = n + 1; m < N - 1; m++){
tmp_vote2 = top_N_vote[m];
tmp_rho2 = top_N_rho[m];
tmp_t2 = top_N_t[m];
top_N_vote[m] = tmp_vote;
top_N_rho[m] = tmp_rho;
top_N_t[m] = tmp_t;
tmp_vote = tmp_vote2;
tmp_rho = tmp_rho2;
tmp_t = tmp_t2;
}
top_N_vote[N - 1] = tmp_vote;
top_N_rho[N - 1] = tmp_rho;
top_N_t[N - 1] = tmp_t;
break;
}
}
}
}
// get pixel for top N votes
for (int n = 0; n < N; n++){
if (top_N_rho[n] == -1){
break;
}
rho = top_N_rho[n];
t = top_N_t[n];
output_hough_table.table[rho][t] = hough_table.table[rho][t];
}
return output_hough_table;
}
// Inverse hough transformation
cv::Mat Hough_inverse(struct_hough_table hough_table, cv::Mat img){
int height = img.rows;
int width = img.cols;
double _cos, _sin;
int y, x;
for (int rho = 0; rho < RHO_MAX * 2; rho++){
for (int t = 0; t < ANGLE_T; t++){
// if not vote, skip
if (hough_table.table[rho][t] < 1){
continue;
}
_cos = cos(t * M_PI / 180);
_sin = sin(t * M_PI / 180);
if ((_sin == 0) || (_cos == 0)){
continue;
}
for (int x = 0; x < width; x++){
y = (int)(- _cos / _sin * x + (rho - RHO_MAX) / _sin);
if ((y >= 0) && (y < height)){
img.at<cv::Vec3b>(y, x) = cv::Vec3b(0, 0, 255);
}
}
for (int y = 0; y < height; y++){
x = (int)(- _sin / _cos * y + (rho - RHO_MAX) / _cos);
if ((x >= 0) && (x < width)){
img.at<cv::Vec3b>(y, x) = cv::Vec3b(0, 0, 255);
}
}
}
}
return img;
}
// hough step 2
int Hough_line(cv::Mat img){
// get edge by canny
cv::Mat edge = Canny(img);
// hough
struct_hough_table hough_table;
// initialize 0
for (int rho = 0; rho < RHO_MAX * 2; rho++){
for (int t = 0; t < ANGLE_T; t++){
hough_table.table[rho][t] = 0;
}
}
// hough vote
hough_table = Hough_vote(hough_table, edge);
return 0;
}
int main(int argc, const char* argv[]){
// read image
cv::Mat img = cv::imread("thorino.jpg", cv::IMREAD_COLOR);
// Hough line detection
Hough_line(img);
return 0;
}