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#define PJ_LIB__
#include <errno.h>
#include <math.h>
#include "proj.h"
#include "proj_internal.h"
#include <math.h>
namespace { // anonymous namespace
struct pj_opaque {
double phi1;
double phi2;
double n;
double rho;
double rho0;
double c;
double *en;
int ellips;
};
} // anonymous namespace
PROJ_HEAD(eqdc, "Equidistant Conic")
"\n\tConic, Sph&Ell\n\tlat_1= lat_2=";
# define EPS10 1.e-10
static PJ_XY eqdc_e_forward (PJ_LP lp, PJ *P) { /* Ellipsoidal, forward */
PJ_XY xy = {0.0,0.0};
struct pj_opaque *Q = static_cast<struct pj_opaque*>(P->opaque);
Q->rho = Q->c - (Q->ellips ? pj_mlfn(lp.phi, sin(lp.phi),
cos(lp.phi), Q->en) : lp.phi);
const double lam_mul_n = lp.lam * Q->n;
xy.x = Q->rho * sin(lam_mul_n);
xy.y = Q->rho0 - Q->rho * cos(lam_mul_n);
return xy;
}
static PJ_LP eqdc_e_inverse (PJ_XY xy, PJ *P) { /* Ellipsoidal, inverse */
PJ_LP lp = {0.0,0.0};
struct pj_opaque *Q = static_cast<struct pj_opaque*>(P->opaque);
if ((Q->rho = hypot(xy.x, xy.y = Q->rho0 - xy.y)) != 0.0 ) {
if (Q->n < 0.) {
Q->rho = -Q->rho;
xy.x = -xy.x;
xy.y = -xy.y;
}
lp.phi = Q->c - Q->rho;
if (Q->ellips)
lp.phi = pj_inv_mlfn(P->ctx, lp.phi, P->es, Q->en);
lp.lam = atan2(xy.x, xy.y) / Q->n;
} else {
lp.lam = 0.;
lp.phi = Q->n > 0. ? M_HALFPI : -M_HALFPI;
}
return lp;
}
static PJ *destructor (PJ *P, int errlev) { /* Destructor */
if (nullptr==P)
return nullptr;
if (nullptr==P->opaque)
return pj_default_destructor (P, errlev);
free (static_cast<struct pj_opaque*>(P->opaque)->en);
return pj_default_destructor (P, errlev);
}
PJ *PROJECTION(eqdc) {
double cosphi, sinphi;
int secant;
struct pj_opaque *Q = static_cast<struct pj_opaque*>(calloc (1, sizeof (struct pj_opaque)));
if (nullptr==Q)
return pj_default_destructor (P, PROJ_ERR_OTHER /*ENOMEM*/);
P->opaque = Q;
P->destructor = destructor;
Q->phi1 = pj_param(P->ctx, P->params, "rlat_1").f;
Q->phi2 = pj_param(P->ctx, P->params, "rlat_2").f;
if (fabs(Q->phi1) > M_HALFPI)
{
proj_log_error(P, _("Invalid value for lat_1: |lat_1| should be <= 90°"));
return destructor(P, PROJ_ERR_INVALID_OP_ILLEGAL_ARG_VALUE);
}
if (fabs(Q->phi2) > M_HALFPI)
{
proj_log_error(P, _("Invalid value for lat_2: |lat_2| should be <= 90°"));
return destructor(P, PROJ_ERR_INVALID_OP_ILLEGAL_ARG_VALUE);
}
if (fabs(Q->phi1 + Q->phi2) < EPS10)
{
proj_log_error(P, _("Invalid value for lat_1 and lat_2: |lat_1 + lat_2| should be > 0"));
return destructor(P, PROJ_ERR_INVALID_OP_ILLEGAL_ARG_VALUE);
}
if (!(Q->en = pj_enfn(P->es)))
return destructor(P, PROJ_ERR_OTHER /*ENOMEM*/);
sinphi = sin(Q->phi1);
Q->n = sinphi;
cosphi = cos(Q->phi1);
secant = fabs(Q->phi1 - Q->phi2) >= EPS10;
Q->ellips = (P->es > 0.);
if( Q->ellips ) {
double ml1, m1;
m1 = pj_msfn(sinphi, cosphi, P->es);
ml1 = pj_mlfn(Q->phi1, sinphi, cosphi, Q->en);
if (secant) { /* secant cone */
sinphi = sin(Q->phi2);
cosphi = cos(Q->phi2);
Q->n = (m1 - pj_msfn(sinphi, cosphi, P->es)) /
(pj_mlfn(Q->phi2, sinphi, cosphi, Q->en) - ml1);
if (Q->n == 0) {
// Not quite, but es is very close to 1...
proj_log_error(P, _("Invalid value for eccentricity"));
return destructor(P, PROJ_ERR_INVALID_OP_ILLEGAL_ARG_VALUE);
}
}
Q->c = ml1 + m1 / Q->n;
Q->rho0 = Q->c - pj_mlfn(P->phi0, sin(P->phi0),
cos(P->phi0), Q->en);
} else {
if (secant)
Q->n = (cosphi - cos(Q->phi2)) / (Q->phi2 - Q->phi1);
if (Q->n == 0)
{
proj_log_error(P, _("Invalid value for lat_1 and lat_2: lat_1 + lat_2 should be > 0"));
return destructor(P, PROJ_ERR_INVALID_OP_ILLEGAL_ARG_VALUE);
}
Q->c = Q->phi1 + cos(Q->phi1) / Q->n;
Q->rho0 = Q->c - P->phi0;
}
P->inv = eqdc_e_inverse;
P->fwd = eqdc_e_forward;
return P;
}
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