int main(int argc, char* argv[])
{
char* fname = NULL;
int ij = 0;
int compact = 0;
NODETYPE nt = NT_DD;
gridnodes* gn = NULL;
poly* pl = NULL;
parse_commandline(argc, argv, &fname, &compact, &ij, &nt);
if (nt == NT_DD) {
/*
* read DD grid nodes
*/
gridnodes* gndd = gridnodes_read(fname, NT_DD);
gridnodes_validate(gndd);
/*
* get corner grid nodes from DD grid nodes
*/
gn = gridnodes_transform(gndd, NT_COR);
gridnodes_destroy(gndd);
} else {
gn = gridnodes_read(fname, NT_COR);
gridnodes_validate(gn);
}
/*
* build boundary polygon
*/
if (!ij)
pl = poly_formbound(gridnodes_getnce1(gn), gridnodes_getnce2(gn), gridnodes_getx(gn), gridnodes_gety(gn));
else
pl = poly_formboundij(gridnodes_getnce1(gn), gridnodes_getnce2(gn), gridnodes_getx(gn));
if (compact)
poly_compact(pl, 1.0e-10);
poly_write(pl, stdout);
poly_destroy(pl);
gridnodes_destroy(gn);
return 0;
}
int main(int argc, char* argv[])
{
char* gridfname = NULL;
char* maskfname = NULL;
NODETYPE ntin = NT_DD;
NODETYPE ntout = NT_DD;
COORDTYPE ct = CT_XY;
int tweaknpolar = 0;
gridnodes* gn = NULL;
parse_commandline(argc, argv, &gridfname, &maskfname, &ntin, &ntout, &ct, &tweaknpolar);
gn = gridnodes_read(gridfname, ntin);
gridnodes_validate(gn);
if (ntin != ntout) {
gridnodes* gnnew = gridnodes_transform(gn, ntout);
gridnodes_destroy(gn);
gn = gnnew;
}
if (maskfname != NULL) {
int nx = gridnodes_getnce1(gn);
int ny = gridnodes_getnce2(gn);
int** mask = gu_readmask(maskfname, nx, ny);
gridnodes_applymask(gn, mask);
gu_free2d(mask);
}
if (tweaknpolar)
gridnodes_tweaknpolar(gn);
if (gu_verbose)
gridnodes_calcstats(gn);
gridnodes_write(gn, "stdout", ct);
gridnodes_destroy(gn);
return 0;
}
int main(int argc, char* argv[])
{
char* gfname = NULL;
char* ofname = NULL;
FILE* of = NULL;
gridnodes* gn = NULL;
gridmap* map = NULL;
char buf[BUFSIZE];
parse_commandline(argc, argv, &gfname, &ofname);
if (nt == NT_DD) {
gridnodes* gndd = gridnodes_read(gfname, NT_DD);
gridnodes_validate(gndd);
gn = gridnodes_transform(gndd, NT_COR);
gridnodes_destroy(gndd);
} else {
gn = gridnodes_read(gfname, NT_COR);
gridnodes_validate(gn);
}
/*
* build grid map
*/
map = gridmap_build(gridnodes_getnce1(gn), gridnodes_getnce2(gn), gridnodes_getx(gn), gridnodes_gety(gn));
if (strcmp(ofname, "stdin") == 0 || strcmp(ofname, "-") == 0)
of = stdin;
else
of = gu_fopen(ofname, "r");
/*
* read points to be mapped, do the mapping and write results to stdout
*/
while (fgets(buf, BUFSIZE, of) != NULL) {
char rem[BUFSIZE] = "";
double xc, yc, ic, jc;
if (sscanf(buf, "%lf %lf %[^\n]", &xc, &yc, rem) >= 2) {
if ((!reverse && gridmap_xy2fij(map, xc, yc, &ic, &jc)) || (reverse && gridmap_fij2xy(map, xc, yc, &ic, &jc))) {
if (!isnan(ic))
printf("%.15g %.15g %s\n", ic, jc, rem);
else
printf("NaN NaN %s\n", rem);
} else {
if (!force)
quit("could not convert (%.15g, %.15g) from %s to %s space\n", xc, yc, (reverse) ? "index" : "physical", (reverse) ? "physical" : "index");
else
printf("NaN NaN %s\n", rem);
}
} else
printf("%s", buf);
}
if (of != stdin)
fclose(of);
gridmap_destroy(map);
gridnodes_destroy(gn);
return 0;
}
int main(int argc, char* argv[])
{
char* fname1 = NULL;
char* fname2 = NULL;
gridnodes* grid1 = NULL;
gridnodes* grid2 = NULL;
gridnodes* grid3 = NULL;
NODETYPE type = NT_NONE;
int i0 = INT_MAX;
int j0 = INT_MAX;
int nx1 = 0;
int ny1 = 0;
int nx2 = 0;
int ny2 = 0;
int nx3 = 0;
int ny3 = 0;
double** gx1 = NULL;
double** gy1 = NULL;
double** gx2 = NULL;
double** gy2 = NULL;
double** gx3 = NULL;
double** gy3 = NULL;
int i1start, i2start, j1start, j2start;
int i1, i2, j1, j2, i3, j3;
parse_commandline(argc, argv, &fname1, &fname2, &i0, &j0, &type);
grid1 = gridnodes_read(fname1, NT_NONE);
grid2 = gridnodes_read(fname2, NT_NONE);
nx1 = gridnodes_getnx(grid1);
ny1 = gridnodes_getny(grid1);
nx2 = gridnodes_getnx(grid2);
ny2 = gridnodes_getny(grid2);
gx1 = gridnodes_getx(grid1);
gy1 = gridnodes_gety(grid1);
gx2 = gridnodes_getx(grid2);
gy2 = gridnodes_gety(grid2);
nx3 = (i0 + nx2 > nx1) ? i0 + nx2 : nx1;
ny3 = (j0 + ny2 > ny1) ? j0 + ny2 : ny1;
grid3 = gridnodes_create(nx3, ny3, type);
gx3 = gridnodes_getx(grid3);
gy3 = gridnodes_gety(grid3);
if (i0 < 0) {
i1start = i0;
i2start = 0;
} else {
i1start = 0;
i2start = -i0;
}
if (j0 < 0) {
j1start = j0;
j2start = 0;
} else {
j1start = 0;
j2start = -j0;
}
if (!merge) {
for (j3 = 0, j1 = j1start, j2 = j2start; j3 < ny3; ++j3, ++j1, ++j2) {
for (i3 = 0, i1 = i1start, i2 = i2start; i3 < nx3; ++i3, ++i1, ++i2) {
int ok2 = (j2 >= 0 && j2 < ny2 && i2 >= 0 && i2 <= nx2);
if (ok2) {
gx3[j3][i3] = gx2[j2][i2];
gy3[j3][i3] = gy2[j2][i2];
} else {
int ok1 = (j1 >= 0 && j1 < ny1 && i1 >= 0 && i1 <= nx1);
if (ok1) {
gx3[j3][i3] = gx1[j1][i1];
gy3[j3][i3] = gy1[j1][i1];
} else {
gx3[j3][i3] = NaN;
gy3[j3][i3] = NaN;
}
}
}
}
} else {
for (j3 = 0, j1 = j1start, j2 = j2start; j3 < ny3; ++j3, ++j1, ++j2) {
for (i3 = 0, i1 = i1start, i2 = i2start; i3 < nx3; ++i3, ++i1, ++i2) {
int ok2 = (j2 >= 0 && j2 < ny2 && i2 >= 0 && i2 <= nx2);
int ok1 = (j1 >= 0 && j1 < ny1 && i1 >= 0 && i1 <= nx1);
if (!ok2 && !ok1) {
gx3[j3][i3] = NaN;
gy3[j3][i3] = NaN;
} else if (ok2 && !ok1) {
gx3[j3][i3] = gx2[j2][i2];
gy3[j3][i3] = gy2[j2][i2];
} else if (!ok2 && ok1) {
gx3[j3][i3] = gx1[j1][i1];
gy3[j3][i3] = gy1[j1][i1];
} else {
if (!isnan(gx2[j2][i2])) {
gx3[j3][i3] = gx2[j2][i2];
gy3[j3][i3] = gy2[j2][i2];
} else {
gx3[j3][i3] = gx1[j1][i1];
gy3[j3][i3] = gy1[j1][i1];
}
}
}
}
}
gridnodes_validate(grid3);
gridnodes_write(grid3, "stdout", CT_XY);
gridnodes_destroy(grid1);
gridnodes_destroy(grid2);
gridnodes_destroy(grid3);
return 0;
}
int main(int argc, char* argv[])
{
char* bathyfname = NULL;
int nbathy = -1;
point* pbathy = NULL;
char* gridfname = NULL;
NODETYPE nt = NT_DD;
gridnodes* gn = NULL;
gridmap* gm = NULL;
char* maskfname = NULL;
int** mask = NULL;
int ppe = PPE_DEF;
double zmin = ZMIN_DEF;
double zmax = ZMAX_DEF;
delaunay* d = NULL;
void (*interpolate_point) (void*, point *) = NULL;
void* interpolator = NULL;
int i = -1, j = -1;
parse_commandline(argc, argv, &bathyfname, &gridfname, &maskfname, &nt, &ppe, &zmin, &zmax, &i, &j);
/*
* sanity check
*/
if (bathyfname == NULL)
quit("no input bathymetry data specified");
if (gridfname == NULL)
quit("no input grid data specified");
if (ppe <= 0 || ppe > PPE_MAX)
quit("number of points per edge specified = %d greater than %d", ppe, PPE_MAX);
if (zmin >= zmax)
quit("min depth = %.3g > max depth = %.3g", zmin, zmax);
if (nt != NT_DD && nt != NT_COR)
quit("unsupported node type");
/*
* read bathymetry
*/
points_read(bathyfname, 3, &nbathy, &pbathy);
if (gu_verbose)
fprintf(stderr, "## %d input bathymetry values", nbathy);
if (nbathy < 3)
quit("less than 3 input bathymetry values");
/*
* read and validate grid
*/
gn = gridnodes_read(gridfname, nt);
gridnodes_validate(gn);
/*
* read mask
*/
if (maskfname != NULL) {
int nx = gridnodes_getnce1(gn);
int ny = gridnodes_getnce2(gn);
mask = gu_readmask(maskfname, nx, ny);
}
/*
* transform grid nodes to corner type
*/
if (nt != NT_COR) {
gridnodes* newgn = gridnodes_transform(gn, NT_COR);
gridnodes_destroy(gn);
gn = newgn;
}
/*
* build the grid map for physical <-> index space conversions
*/
gm = gridmap_build(gridnodes_getnce1(gn), gridnodes_getnce2(gn), gridnodes_getx(gn), gridnodes_gety(gn));
/*
* convert bathymetry to index space if necessary
*/
if (indexspace) {
point* newpbathy = malloc(nbathy * sizeof(point));
int newnbathy = 0;
int ii;
for (ii = 0; ii < nbathy; ++ii) {
point* p = &pbathy[ii];
point* newp = &newpbathy[newnbathy];
double ic, jc;
if (gridmap_xy2fij(gm, p->x, p->y, &ic, &jc)) {
newp->x = ic;
newp->y = jc;
newp->z = p->z;
newnbathy++;
}
}
free(pbathy);
pbathy = newpbathy;
nbathy = newnbathy;
}
/*
* create interpolator
*/
if (rule == CSA) { /* using libcsa */
interpolator = csa_create();
csa_addpoints(interpolator, nbathy, pbathy);
csa_calculatespline(interpolator);
interpolate_point = (void (*)(void*, point *)) csa_approximatepoint;
} else if (rule == AVERAGE) {
interpolator = ga_create(gm);
ga_addpoints(interpolator, nbathy, pbathy);
interpolate_point = (void (*)(void*, point *)) ga_getvalue;
ppe = 1;
} else { /* using libnn */
/*
* triangulate
*/
if (gu_verbose) {
fprintf(stderr, "## triangulating...");
fflush(stdout);
}
d = delaunay_build(nbathy, pbathy, 0, NULL, 0, NULL);
if (gu_verbose) {
fprintf(stderr, "done\n");
fflush(stderr);
}
if (rule == NN_SIBSON || rule == NN_NONSIBSONIAN) {
interpolator = nnpi_create(d);
if (rule == NN_SIBSON)
nn_rule = SIBSON;
else
nn_rule = NON_SIBSONIAN;
interpolate_point = (void (*)(void*, point *)) nnpi_interpolate_point;
} else if (rule == LINEAR) {
interpolator = lpi_build(d);
interpolate_point = (void (*)(void*, point *)) lpi_interpolate_point;
}
}
/*
* main cycle -- over grid cells
*/
{
double** gx = gridnodes_getx(gn);
int jmin, jmax, imin, imax;
if (i < 0) {
imin = 0;
imax = gridnodes_getnce1(gn) - 1;
jmin = 0;
jmax = gridnodes_getnce2(gn) - 1;
} else {
if (gu_verbose)
fprintf(stderr, "## calculating depth for cell (%d,%d)\n", i, j);
imin = i;
imax = i;
jmin = j;
jmax = j;
}
for (j = jmin; j <= jmax; ++j) {
for (i = imin; i <= imax; ++i) {
double sum = 0.0;
int count = 0;
int ii, jj;
if ((mask != NULL && mask[j][i] == 0) || isnan(gx[j][i]) || isnan(gx[j + 1][i + 1]) || isnan(gx[j][i + 1]) || isnan(gx[j + 1][i])) {
printf("NaN\n");
continue;
}
for (ii = 0; ii < ppe; ++ii) {
for (jj = 0; jj < ppe; ++jj) {
double fi = (double) i + 0.5 / (double) ppe * (1.0 + 2.0 * (double) ii);
double fj = (double) j + 0.5 / (double) ppe * (1.0 + 2.0 * (double) jj);
point p;
if (!indexspace)
gridmap_fij2xy(gm, fi, fj, &p.x, &p.y);
else {
p.x = fi;
p.y = fj;
}
interpolate_point(interpolator, &p);
if (isnan(p.z))
continue;
else if (p.z < zmin)
p.z = zmin;
else if (p.z > zmax)
p.z = zmax;
sum += p.z;
count++;
}
}
if (count == 0)
printf("NaN\n");
else
printf("%.2f\n", sum / (double) count);
fflush(stdout);
}
}
}
/*
* clean up, just because
*/
if (rule == CSA)
csa_destroy(interpolator);
else if (rule == AVERAGE)
ga_destroy(interpolator);
else {
if (rule == NN_SIBSON || rule == NN_NONSIBSONIAN)
nnpi_destroy(interpolator);
else if (rule == LINEAR)
lpi_destroy(interpolator);
delaunay_destroy(d);
}
if (mask != NULL)
gu_free2d(mask);
gridmap_destroy(gm);
gridnodes_destroy(gn);
free(pbathy);
return 0;
}
