double get_lunar_transit_time( const int year, const int month,
const int day, const double latitude, const double longitude,
const int time_zone, const int dst, const int real_transit)
{
const long jd0 = dmy_to_day( day, month, year, 0);
const long day_of_year = jd0 - dmy_to_day( 1, 1, year, 0);
double jd = (double)jd0;
static char *vsop_data = NULL;
int dst_hours = (dst ? is_dst( 720, (int)day_of_year, year) : 0);
if( !vsop_data)
vsop_data = load_file_into_memory( "vsop.bin", NULL);
if( !vsop_data)
return( -2.);
jd -= (double)time_zone / 24.; /* convert local to UT */
jd -= dst_hours / 24.;
jd = look_for_transit_time( 10, jd,
latitude * pi / 180., longitude * pi / 180.,
vsop_data, real_transit);
jd += (double)time_zone / 24.; /* convert UT back to local */
jd += dst_hours / 24.;
return( jd - (double)jd0 + .5);
}
std::vector<std::pair<int, int>> solve_astar(std::vector<std::vector<int>>& G,
int ys, int xs, int yd, int xd) {
m_G = G;
m_h = G.size();
m_w = G[0].size();
m_ys = ys;
m_xs = xs;
m_yd = yd;
m_xd = xd;
// open set, close set
std::set<std::pair<double, std::pair<int, int>>> st_open;
std::set<std::pair<int, int>> st_close;
// cell
m_C.resize(m_h, std::vector<cell>(m_w));
for (int y = 0; y < m_h; ++y) {
for (int x = 0; x < m_w; ++x) {
cell& C = m_C[y][x];
if (y == ys && x == xs) {
C.m_f = 0.0;
C.m_g = 0.0;
C.m_h = 0.0;
C.m_p_y = y;
C.m_p_x = x;
st_open.insert({C.m_f, {y, x}});
} else {
C.m_f = std::numeric_limits<double>::max();
C.m_g = std::numeric_limits<double>::max();
C.m_h = std::numeric_limits<double>::max();
C.m_p_y = -1;
C.m_p_x = -1;
}
}
}
int dy[8] = {-1, 1, 0, 1, 1, 1, 0, -1};
int dx[8] = { 0, 1, 1, 1, 0, -1, -1, -1};
while (!st_open.empty()) {
// get node which has small f
auto it = st_open.begin();
int y = (*it).second.first;
int x = (*it).second.second;
st_open.erase(it);
st_close.insert({y, x});
if (is_dst(y, x)) {
// printf("st_open.count: %d, st_close.count: %d\n",
// st_open.size(), st_close.size());
return get_path();
}
for (int d = 0; d < 8; ++d) {
// get node to visit
int yn = y + dy[d];
int xn = x + dx[d];
// printf(" %d, %d\n", yn, xn);
if (!is_valid(yn, xn) ||
st_close.count({yn, xn}) > 0 ||
!is_placeable(yn, xn))
continue;
cell& C = m_C[yn][xn];
double gn = C.m_g + 1.0;
double hn = get_h(yn, xn);
double fn = gn + hn;
if (C.m_f == std::numeric_limits<double>::max() ||
C.m_f > fn) {
st_open.insert({fn, {yn, xn}});
C.m_f = fn;
C.m_g = gn;
C.m_h = hn;
C.m_p_y = y;
C.m_p_x = x;
// printf("(%d, %d) -> (%d, %d)\n", y, x, yn, xn);
}
}
}
return {};
}
