#define PJ_LIB__ #include #include #include "proj.h" #include "proj_internal.h" PROJ_HEAD(igh, "Interrupted Goode Homolosine") "\n\tPCyl, Sph"; /* This projection is a compilation of 12 separate sub-projections. Sinusoidal projections are found near the equator and Mollweide projections are found at higher latitudes. The transition between the two occurs at 40 degrees latitude and is represented by the constant `phi_boundary`. Each sub-projection is assigned an integer label numbered 1 through 12. Most of this code contains logic to assign the labels based on latitude (phi) and longitude (lam) regions. Original Reference: J. Paul Goode (1925) THE HOMOLOSINE PROJECTION: A NEW DEVICE FOR PORTRAYING THE EARTH'S SURFACE ENTIRE, Annals of the Association of American Geographers, 15:3, 119-125, DOI: 10.1080/00045602509356949 */ C_NAMESPACE PJ *pj_sinu(PJ *), *pj_moll(PJ *); /* Transition from sinusoidal to Mollweide projection Latitude (phi): 40deg 44' 11.8" */ static const double phi_boundary = (40 + 44/60. + 11.8/3600.) * DEG_TO_RAD; static const double d10 = 10 * DEG_TO_RAD; static const double d20 = 20 * DEG_TO_RAD; static const double d30 = 30 * DEG_TO_RAD; static const double d40 = 40 * DEG_TO_RAD; static const double d50 = 50 * DEG_TO_RAD; static const double d60 = 60 * DEG_TO_RAD; static const double d80 = 80 * DEG_TO_RAD; static const double d90 = 90 * DEG_TO_RAD; static const double d100 = 100 * DEG_TO_RAD; static const double d140 = 140 * DEG_TO_RAD; static const double d160 = 160 * DEG_TO_RAD; static const double d180 = 180 * DEG_TO_RAD; static const double EPSLN = 1.e-10; /* allow a little 'slack' on zone edge positions */ namespace { // anonymous namespace struct pj_opaque { struct PJconsts* pj[12]; \ double dy0; }; } // anonymous namespace static PJ_XY igh_s_forward (PJ_LP lp, PJ *P) { /* Spheroidal, forward */ PJ_XY xy; struct pj_opaque *Q = static_cast(P->opaque); int z; if (lp.phi >= phi_boundary) { /* 1|2 */ z = (lp.lam <= -d40 ? 1: 2); } else if (lp.phi >= 0) { /* 3|4 */ z = (lp.lam <= -d40 ? 3: 4); } else if (lp.phi >= -phi_boundary) { /* 5|6|7|8 */ if (lp.lam <= -d100) z = 5; /* 5 */ else if (lp.lam <= -d20) z = 6; /* 6 */ else if (lp.lam <= d80) z = 7; /* 7 */ else z = 8; /* 8 */ } else { /* 9|10|11|12 */ if (lp.lam <= -d100) z = 9; /* 9 */ else if (lp.lam <= -d20) z = 10; /* 10 */ else if (lp.lam <= d80) z = 11; /* 11 */ else z = 12; /* 12 */ } lp.lam -= Q->pj[z-1]->lam0; xy = Q->pj[z-1]->fwd(lp, Q->pj[z-1]); xy.x += Q->pj[z-1]->x0; xy.y += Q->pj[z-1]->y0; return xy; } static PJ_LP igh_s_inverse (PJ_XY xy, PJ *P) { /* Spheroidal, inverse */ PJ_LP lp = {0.0,0.0}; struct pj_opaque *Q = static_cast(P->opaque); const double y90 = Q->dy0 + sqrt(2.0); /* lt=90 corresponds to y=y0+sqrt(2) */ int z = 0; if (xy.y > y90+EPSLN || xy.y < -y90+EPSLN) /* 0 */ z = 0; else if (xy.y >= phi_boundary) /* 1|2 */ z = (xy.x <= -d40? 1: 2); else if (xy.y >= 0) /* 3|4 */ z = (xy.x <= -d40? 3: 4); else if (xy.y >= -phi_boundary) { /* 5|6|7|8 */ if (xy.x <= -d100) z = 5; /* 5 */ else if (xy.x <= -d20) z = 6; /* 6 */ else if (xy.x <= d80) z = 7; /* 7 */ else z = 8; /* 8 */ } else { /* 9|10|11|12 */ if (xy.x <= -d100) z = 9; /* 9 */ else if (xy.x <= -d20) z = 10; /* 10 */ else if (xy.x <= d80) z = 11; /* 11 */ else z = 12; /* 12 */ } if (z) { bool ok = false; xy.x -= Q->pj[z-1]->x0; xy.y -= Q->pj[z-1]->y0; lp = Q->pj[z-1]->inv(xy, Q->pj[z-1]); lp.lam += Q->pj[z-1]->lam0; switch (z) { case 1: ok = (lp.lam >= -d180-EPSLN && lp.lam <= -d40+EPSLN) || ((lp.lam >= -d40-EPSLN && lp.lam <= -d10+EPSLN) && (lp.phi >= d60-EPSLN && lp.phi <= d90+EPSLN)); break; case 2: ok = (lp.lam >= -d40-EPSLN && lp.lam <= d180+EPSLN) || ((lp.lam >= -d180-EPSLN && lp.lam <= -d160+EPSLN) && (lp.phi >= d50-EPSLN && lp.phi <= d90+EPSLN)) || ((lp.lam >= -d50-EPSLN && lp.lam <= -d40+EPSLN) && (lp.phi >= d60-EPSLN && lp.phi <= d90+EPSLN)); break; case 3: ok = (lp.lam >= -d180-EPSLN && lp.lam <= -d40+EPSLN); break; case 4: ok = (lp.lam >= -d40-EPSLN && lp.lam <= d180+EPSLN); break; case 5: ok = (lp.lam >= -d180-EPSLN && lp.lam <= -d100+EPSLN); break; case 6: ok = (lp.lam >= -d100-EPSLN && lp.lam <= -d20+EPSLN); break; case 7: ok = (lp.lam >= -d20-EPSLN && lp.lam <= d80+EPSLN); break; case 8: ok = (lp.lam >= d80-EPSLN && lp.lam <= d180+EPSLN); break; case 9: ok = (lp.lam >= -d180-EPSLN && lp.lam <= -d100+EPSLN); break; case 10: ok = (lp.lam >= -d100-EPSLN && lp.lam <= -d20+EPSLN); break; case 11: ok = (lp.lam >= -d20-EPSLN && lp.lam <= d80+EPSLN); break; case 12: ok = (lp.lam >= d80-EPSLN && lp.lam <= d180+EPSLN); break; } z = (!ok? 0: z); /* projectable? */ } if (!z) lp.lam = HUGE_VAL; if (!z) lp.phi = HUGE_VAL; return lp; } static PJ *destructor (PJ *P, int errlev) { int i; if (nullptr==P) return nullptr; if (nullptr==P->opaque) return pj_default_destructor (P, errlev); struct pj_opaque *Q = static_cast(P->opaque); for (i = 0; i < 12; ++i) { if (Q->pj[i]) Q->pj[i]->destructor(Q->pj[i], errlev); } return pj_default_destructor(P, errlev); } /* Zones: -180 -40 180 +--------------+-------------------------+ Zones 1,2,9,10,11 & 12: |1 |2 | Mollweide projection | | | +--------------+-------------------------+ Zones 3,4,5,6,7 & 8: |3 |4 | Sinusoidal projection | | | 0 +-------+------+-+-----------+-----------+ |5 |6 |7 |8 | | | | | | +-------+--------+-----------+-----------+ |9 |10 |11 |12 | | | | | | +-------+--------+-----------+-----------+ -180 -100 -20 80 180 */ static bool setup_zone(PJ *P, struct pj_opaque *Q, int n, PJ*(*proj_ptr)(PJ*), double x_0, double y_0, double lon_0) { if (!(Q->pj[n-1] = proj_ptr(nullptr))) return false; if (!(Q->pj[n-1] = proj_ptr(Q->pj[n-1]))) return false; Q->pj[n-1]->ctx = P->ctx; Q->pj[n-1]->x0 = x_0; Q->pj[n-1]->y0 = y_0; Q->pj[n-1]->lam0 = lon_0; return true; } PJ *PROJECTION(igh) { PJ_XY xy1, xy3; PJ_LP lp = { 0, phi_boundary }; struct pj_opaque *Q = static_cast(calloc (1, sizeof (struct pj_opaque))); if (nullptr==Q) return pj_default_destructor (P, PROJ_ERR_OTHER /*ENOMEM*/); P->opaque = Q; /* sinusoidal zones */ if (!setup_zone(P, Q, 3, pj_sinu, -d100, 0, -d100) || !setup_zone(P, Q, 4, pj_sinu, d30, 0, d30) || !setup_zone(P, Q, 5, pj_sinu, -d160, 0, -d160) || !setup_zone(P, Q, 6, pj_sinu, -d60, 0, -d60) || !setup_zone(P, Q, 7, pj_sinu, d20, 0, d20) || !setup_zone(P, Q, 8, pj_sinu, d140, 0, d140)) { return destructor(P, PROJ_ERR_OTHER /*ENOMEM*/); } /* mollweide zones */ if( !setup_zone(P, Q, 1, pj_moll, -d100, 0, -d100)) { return destructor(P, PROJ_ERR_OTHER /*ENOMEM*/); } /* y0 ? */ xy1 = Q->pj[0]->fwd(lp, Q->pj[0]); /* zone 1 */ xy3 = Q->pj[2]->fwd(lp, Q->pj[2]); /* zone 3 */ /* y0 + xy1.y = xy3.y for lt = 40d44'11.8" */ Q->dy0 = xy3.y - xy1.y; Q->pj[0]->y0 = Q->dy0; /* mollweide zones (cont'd) */ if (!setup_zone(P, Q, 2, pj_moll, d30, Q->dy0, d30) || !setup_zone(P, Q, 9, pj_moll, -d160, -Q->dy0, -d160) || !setup_zone(P, Q,10, pj_moll, -d60, -Q->dy0, -d60) || !setup_zone(P, Q,11, pj_moll, d20, -Q->dy0, d20) || !setup_zone(P, Q,12, pj_moll, d140, -Q->dy0, d140)) { return destructor(P, PROJ_ERR_OTHER /*ENOMEM*/); } P->inv = igh_s_inverse; P->fwd = igh_s_forward; P->destructor = destructor; P->es = 0.; return P; }