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#include <chrono>
#include <iostream>
#include <libsurvive/survive.h>
#include <libsurvive/survive_reproject.h>
#include <map>
#include <math.h>
#include <memory>
#include <set>
#include <vector>
#include "opencv2/imgproc.hpp"
#include <opencv2/highgui/highgui.hpp>
#include <opencv2/imgcodecs.hpp>
uint32_t timestamp;
cv::Mat_<cv::Vec3b> img;
cv::Mat_<cv::Vec3b> err[2];
cv::Vec3f flow2rgb(float x, float y, float scale = 1) {
cv::Mat_<cv::Vec3f> hsv(1, 1);
hsv(0, 0) = {atan2(y, x) * 180. / M_PI, 1.0, std::min(1.0f, sqrt(x * x + y * y) * scale)};
cv::Mat_<cv::Vec3f> bgr(1, 1);
cv::cvtColor(hsv, bgr, CV_HSV2RGB_FULL);
return bgr(0, 0) * 255;
}
static void draw_viz(cv::Mat &img, double scale = 1) {
double size = 50;
cv::Point2f origin(size, size);
for (double r = size; r > size / 100.; r -= size / 100.) {
for (double theta = 0; theta < 2 * M_PI; theta += .01) {
auto x = cos(theta) * r;
auto y = sin(theta) * r;
auto clr = flow2rgb(x, y, scale / size);
cv::line(img, cv::Point2f(x, y) + origin, origin, clr);
}
}
}
double error = 0;
int error_count = 0;
static void redraw(SurviveContext *ctx) {
int SIZE = 1000;
int shift = ctx->user_ptr ? 1 : 0;
auto show_pov = 130. / 180;
auto fov = 120. / 180. * SIZE / show_pov;
auto map = [&](const double *a) {
auto x = a[0] * SIZE / (M_PI) / show_pov + SIZE / 2;
return cv::Point(x, SIZE - (a[1] * SIZE / (M_PI) + SIZE / 2));
};
auto region = img.data ? img(cv::Rect(SIZE * shift, 0, SIZE, SIZE)) : cv::Mat_<cv::Vec3b>();
if (region.data) {
region.setTo(cv::Vec3b(0, 0, 0));
cv::rectangle(region, cv::Point(SIZE / 2 - fov / 2, SIZE / 2 - fov / 2),
cv::Point(SIZE / 2 + fov / 2, SIZE / 2 + fov / 2), cv::Vec3b(255, 255, 255));
}
// eregion.copyTo(region);
for (int i = 0; i < ctx->objs_ct; i++) {
auto so = ctx->objs[i];
auto scene = &so->activations;
for (size_t lh = 0; lh < 2; lh++) {
auto eregion = err[lh](cv::Rect(SIZE * shift, 0, SIZE, SIZE));
for (size_t sensor = 0; sensor < so->sensor_ct; sensor++) {
auto ncolor = cv::Vec3b(lh == 0 ? 255 : 0,
255, // sensor / (double)so->sensor_ct * 255,
i / (double)ctx->objs_ct * 255);
auto rcolor = cv::Vec3b(lh == 0 ? 255 : 0,
128, // sensor / (double)so->sensor_ct * 255,
i / (double)ctx->objs_ct * 255);
if (SurviveSensorActivations_isPairValid(scene, SurviveSensorActivations_default_tolerance, timestamp,
sensor, lh)) {
const double *a = scene->angles[sensor][lh];
// FLT a[2];
// survive_apply_bsd_calibration(so->ctx, lh, _a, a);
auto l = scene->lengths[sensor][lh];
double r = std::max(3., (l[0] + l[1]) / 1000.);
// std::cerr << lh << "\t" << sensor << "\t" << ((l[0] + l[1]) / 2000.) << "\t" << l[0] << "\t" <<
// l[1] << std::endl;
if (region.data)
cv::circle(region, map(a), r, ncolor);
FLT point3d[3];
FLT out[2];
ApplyPoseToPoint(point3d, &so->OutPose, so->sensor_locations + 3 * sensor);
survive_reproject(ctx, lh, point3d, out);
double ex = out[0] - a[0];
double ey = out[1] - a[1];
double err_add = sqrt(ex * ex + ey * ey);
error += err_add;
error_count++;
auto &e = eregion(map(a).y, map(a).x);
e = flow2rgb(ex, ey, 100);
cv::putText(img, std::to_string(error / error_count), cv::Point2f(10, 20), CV_FONT_HERSHEY_PLAIN, 1,
cv::Scalar(255, 255, 255));
if (region.data) {
if (err_add < .01) {
cv::line(region, map(a) + cv::Point(ex * 10000, -ey * 10000), map(a),
cv::Scalar(255, 255, 255));
}
cv::rectangle(region, map(out) - cv::Point(r, r), map(out) + cv::Point(r, r), rcolor);
}
}
}
};
}
if (img.data) {
cv::imshow("Reprojection", img);
}
}
void light_process(SurviveObject *so, int sensor_id, int acode, int timeinsweep, uint32_t timecode, uint32_t length,
uint32_t lighthouse) {
timestamp = timecode;
survive_default_light_process(so, sensor_id, acode, timeinsweep, timecode, length, lighthouse);
}
SurvivePose lastPose = {};
void raw_pose_process(SurviveObject *so, uint8_t lighthouse, SurvivePose *pose) {
survive_default_raw_pose_process(so, lighthouse, pose);
auto d = dist3d(lastPose.Pos, pose->Pos);
// std::cerr << d << std::endl;
if (d < .01) {
redraw(so->ctx);
}
lastPose = *pose;
}
void lighthouse_process(SurviveContext *ctx, uint8_t lighthouse, SurvivePose *pose, SurvivePose *obj_pose) {
survive_default_lighthouse_pose_process(ctx, lighthouse, pose, obj_pose);
}
SurviveContext *create(int argc, char **argv) {
auto ctx = survive_init(argc, argv);
survive_install_raw_pose_fn(ctx, raw_pose_process);
survive_install_lighthouse_pose_fn(ctx, lighthouse_process);
survive_install_light_fn(ctx, light_process);
return ctx;
}
void drawbsds(SurviveContext *ctx) {
int SIZE = 1000;
std::vector<SurviveCalFlag> show_flags = {
SVCal_All, SVCal_Phase, SVCal_Gib, SVCal_Curve, SVCal_Tilt,
};
for (auto f : show_flags) {
for (int lh = 0; lh < 2; lh++) {
cv::Mat_<cv::Vec3b> img = cv::Mat_<cv::Vec3b>(SIZE, SIZE);
img.setTo(cv::Vec3b(0, 0, 0));
for (int x = 0; x < SIZE; x++) {
for (int y = 0; y < SIZE; y++) {
FLT in[2] = {x * M_PI / SIZE - M_PI / 2., y * M_PI / SIZE - M_PI / 2.};
if (fabs(in[0]) > 60. / 180 * M_PI || fabs(in[1]) > 60. / 180 * M_PI)
continue;
FLT out[2];
auto config = survive_calibration_config_ctor();
config.use_flag = f;
survive_apply_bsd_calibration_by_config(ctx, lh, &config, in, out);
double ex = out[0] - in[0];
double ey = out[1] - in[1];
if (f == SVCal_All) {
ex -= ctx->bsd[lh].fcal.phase[0];
ey -= ctx->bsd[lh].fcal.phase[1];
}
// Make it opposite of angles
ex *= -1;
ey *= -1;
img(y, x) = flow2rgb(ex, ey, 100);
}
}
draw_viz(img);
cv::imwrite("BSD" + std::to_string(lh) + "_" + std::to_string(f) + ".png", img);
if (f == SVCal_All)
cv::imshow("BSD" + std::to_string(lh), img);
}
}
}
int main(int argc, char **argv) {
// for (int i = 0; i < 1 << 5; i++) {
// size_t cidx = 15 | (i << 5);
// auto conf = survive_calibration_config_create_from_idx(cidx);
// if (survive_calibration_config_index(&conf) != cidx)
// continue;
auto ctx1 = create(argc, argv);
size_t cidx = survive_configi(ctx1, "default-cal-conf", SC_GET, 0);
size_t idx = survive_configi(ctx1, "default-cal-conf2", SC_GET, 0);
SurviveContext *ctx2 = 0;
int numCtx = 1;
int ctx2_flag = 1;
if (idx != 0) {
numCtx++;
ctx2 = create(argc, argv);
ctx2->user_ptr = (void *)&ctx2_flag;
}
size_t showui = survive_configi(ctx1, "show-ui", SC_GET, 0);
drawbsds(ctx1);
int waitUpdate = 100;
int SIZE = 1000;
if (showui) {
img = cv::Mat_<cv::Vec3b>(SIZE, numCtx * SIZE);
img.setTo(cv::Vec3b(0, 0, 0));
}
for (int lh = 0; lh < 2; lh++) {
err[lh] = cv::Mat_<cv::Vec3b>(SIZE, numCtx * SIZE);
err[lh].setTo(cv::Vec3b(0, 0, 0));
}
if (img.data) {
cv::imshow("Reprojection", img);
cv::waitKey(0);
}
auto start = std::chrono::high_resolution_clock::now();
while (survive_poll(ctx1) == 0 && (ctx2 == 0 || survive_poll(ctx2) == 0)) {
auto now = std::chrono::high_resolution_clock::now();
if ((now - start) > std::chrono::milliseconds(33)) {
cv::waitKey(1);
start = now;
}
}
for (int i = 0; i < 2; i++) {
draw_viz(err[i]);
cv::putText(err[i], std::to_string(error / error_count), cv::Point2f(100, 20), CV_FONT_HERSHEY_PLAIN, 1,
cv::Scalar(255, 255, 255));
cv::putText(err[i], std::to_string(cidx), cv::Point2f(100, 40), CV_FONT_HERSHEY_PLAIN, 1,
cv::Scalar(255, 255, 255));
auto name = "LH" + std::to_string(i);
cv::imwrite(name + "_" + std::to_string(cidx) + ".png", err[i]);
cv::imshow(name, err[i]);
}
std::cerr << "Error: " << error / error_count << std::endl;
int c = '\0';
while (((c = cv::waitKey(0)) & 0xff) != 'q') {
std::cerr << (uint8_t)c << std::endl;
}
return 0;
}
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