int zoom_pan_update(void *closure, int sxn, int syn, int button)
{
G_debug(2, "button = %d x = %d y = %d", button, sxn, syn);
if (button == 3)
return 1;
if (button == 1) {
double x = D_d_to_u_col(sxn);
double y = D_d_to_u_row(syn);
double dx = (window.east - window.west) / 2;
double dy = (window.north - window.south) / 2;
window.north = y + dy;
window.south = y - dy;
window.east = x + dx;
window.west = x - dx;
G_debug(2, "w = %f e = %f n = %f s = %f", window.west, window.east,
window.north, window.south);
G_adjust_Cell_head(&window, 0, 0);
G_put_window(&window);
G_set_window(&window);
display_redraw();
}
return 0;
}
void update_default_window(struct Cell_head *cellhd)
{
/* -------------------------------------------------------------------- */
/* Extend current window based on dataset. */
/* -------------------------------------------------------------------- */
struct Cell_head cur_wind;
if (strcmp(G_mapset(), "PERMANENT") == 0)
/* fixme: expand WIND and DEFAULT_WIND independently. (currently
WIND gets forgotten and DEFAULT_WIND is expanded for both) */
G_get_default_window(&cur_wind);
else
G_get_window(&cur_wind);
cur_wind.north = MAX(cur_wind.north, cellhd->north);
cur_wind.south = MIN(cur_wind.south, cellhd->south);
cur_wind.west = MIN(cur_wind.west, cellhd->west);
cur_wind.east = MAX(cur_wind.east, cellhd->east);
cur_wind.rows = (int)ceil((cur_wind.north - cur_wind.south)
/ cur_wind.ns_res);
cur_wind.south = cur_wind.north - cur_wind.rows * cur_wind.ns_res;
cur_wind.cols = (int)ceil((cur_wind.east - cur_wind.west)
/ cur_wind.ew_res);
cur_wind.east = cur_wind.west + cur_wind.cols * cur_wind.ew_res;
if (strcmp(G_mapset(), "PERMANENT") == 0) {
G_put_element_window(&cur_wind, "", "DEFAULT_WIND");
G_message(_("Default region for this location updated"));
}
G_put_window(&cur_wind);
G_message(_("Region for the current mapset updated"));
}
void QgsGrassRegion::accept()
{
// TODO: better repaint region
QSettings settings;
bool on = settings.value( "/GRASS/region/on", true ).toBool();
if ( on )
{
mPlugin->switchRegion( false ); // delete
}
QgsGrass::setLocation( QgsGrass::getDefaultGisdbase(), QgsGrass::getDefaultLocation() );
G__setenv(( char * ) "MAPSET", QgsGrass::getDefaultMapset().toLatin1().data() );
if ( G_put_window( &mWindow ) == -1 )
{
QMessageBox::warning( 0, tr( "Warning" ), tr( "Cannot write region" ) );
return;
}
if ( on )
{
mPlugin->switchRegion( on ); // draw new
}
saveWindowLocation();
mCanvas->setMapTool( NULL );
QDialog::accept();
}
int zoom_window_update(void *closure, int sxn, int syn, int button)
{
struct zoom_window *zw = closure;
if (zw->mode == 1) {
i_prompt_buttons(_("1. corner"), _("2. corner"), _("Quit"));
zw->next_mode = 2;
}
G_debug(2, "button = %d x = %d y = %d", button, sxn, syn);
if (button == 3)
return 1;
if (zw->mode == 2 && button == 2) {
double x1 = D_d_to_u_col(zw->sxo);
double y1 = D_d_to_u_row(zw->syo);
double x2 = D_d_to_u_col(sxn);
double y2 = D_d_to_u_row(syn);
G_debug(2, "x1 = %f x2 = %f y1 = %f y2 = %f", x1, x2, y1, y2);
window.north = y1 > y2 ? y1 : y2;
window.south = y1 < y2 ? y1 : y2;
window.west = x1 < x2 ? x1 : x2;
window.east = x1 > x2 ? x1 : x2;
G_debug(2, "w = %f e = %f n = %f s = %f", window.west, window.east,
window.north, window.south);
G_adjust_Cell_head(&window, 0, 0);
G_put_window(&window);
G_set_window(&window);
display_redraw();
i_prompt_buttons(_("1. corner"), _("1. corner"), _("Quit"));
zw->next_mode = 1;
}
zw->sxo = sxn;
zw->syo = syn;
zw->mode = zw->next_mode;
set_mode(zw->mode == 2 ? MOUSE_BOX : MOUSE_POINT);
set_location(zw->sxo, zw->syo);
return 0;
}
bool GRASS_EXPORT QgsGrass::writeRegion( QString gisbase,
QString location, QString mapset,
struct Cell_head *window )
{
QgsDebugMsg( "entered." );
QgsDebugMsg( QString( "n = %1 s = %2" ).arg( window->north ).arg( window->south ) );
QgsDebugMsg( QString( "e = %1 w = %2" ).arg( window->east ).arg( window->west ) );
QgsGrass::setMapset( gisbase, location, mapset );
if ( G_put_window( window ) == -1 )
{
return false;
}
return true;
}
/* Zoom - default region */
int zoom_default(void)
{
struct Cell_head defwin;
G_debug(2, "zoom_default()");
driver_open();
G_get_default_window(&defwin);
G_put_window(&defwin);
G_set_window(&defwin);
display_redraw();
driver_close();
G_debug(3, "zoom_default(): End");
return 1;
}
/* Zoom - in / out (centre unchanged) */
int zoom_centre(double factor)
{
double xc, yc, dx, dy;
G_debug(2, "zoom_centre()");
driver_open();
G_debug(2, "1 n = %f s = %f", window.north, window.south);
dx = (window.east - window.west) / 2;
dy = (window.north - window.south) / 2;
xc = (window.east + window.west) / 2;
yc = (window.north + window.south) / 2;
G_debug(2, " yc = %f dy = %f", yc, dy);
window.north = yc + dy * factor;
window.south = yc - dy * factor;
window.east = xc + dx * factor;
window.west = xc - dx * factor;
G_debug(2, "2 n = %f s = %f", window.north, window.south);
G_adjust_Cell_head(&window, 0, 0);
G_debug(2, "3 n = %f s = %f", window.north, window.south);
G_put_window(&window);
G_set_window(&window);
display_redraw();
driver_close();
G_debug(3, "zoom_centre(): End");
return 1;
}
int main(int argc, char **argv)
{
struct GModule *module;
int i, first = 1;
char *mapset;
char **rast, **vect;
int nrasts, nvects;
struct Cell_head window, temp_window;
G_gisinit(argv[0]);
module = G_define_module();
module->keywords = _("display, setup");
module->description =
"Sets window region so that all currently displayed raster "
"and vector maps can be shown in a monitor.";
if (argc > 1 && G_parser(argc, argv))
exit(-1);
if (R_open_driver() != 0)
G_fatal_error(_("No graphics device selected"));
if (D_get_cell_list(&rast, &nrasts) < 0)
rast = NULL;
if (D_get_dig_list(&vect, &nvects) < 0)
vect = NULL;
R_close_driver();
if (rast == NULL && vect == NULL)
G_fatal_error(_("No raster or vector map displayed"));
G_get_window(&window);
if (rast) {
for (i = 0; i < nrasts; i++) {
mapset = G_find_cell2(rast[i], "");
if (mapset == NULL)
G_fatal_error(_("Raster map <%s> not found"), rast[i]);
if (G_get_cellhd(rast[i], mapset, &temp_window) >= 0) {
if (first) {
first = 0;
G_copy(&window, &temp_window, sizeof(window));
}
else {
if (window.east < temp_window.east)
window.east = temp_window.east;
if (window.west > temp_window.west)
window.west = temp_window.west;
if (window.south > temp_window.south)
window.south = temp_window.south;
if (window.north < temp_window.north)
window.north = temp_window.north;
/*
if(window.ns_res < nsres)
nsres = window.ns_res;
if(window.ew_res < ewres)
ewres = window.ew_res;
*/
}
}
}
G_adjust_Cell_head3(&window, 0, 0, 0);
}
if (vect) {
struct Map_info Map;
G_copy(&temp_window, &window, sizeof(window));
Vect_set_open_level(2);
for (i = 0; i < nvects; i++) {
mapset = G_find_vector2(vect[i], "");
if (mapset == NULL)
G_fatal_error(_("Vector map <%s> not found"), vect[i]);
if (Vect_open_old_head(&Map, vect[i], mapset) == 2) {
if (first) {
first = 0;
window.east = Map.plus.box.E;
window.west = Map.plus.box.W;
window.south = Map.plus.box.S;
window.north = Map.plus.box.N;
}
else {
if (window.east < Map.plus.box.E)
window.east = Map.plus.box.E;
if (window.west > Map.plus.box.W)
window.west = Map.plus.box.W;
if (window.south > Map.plus.box.S)
window.south = Map.plus.box.S;
if (window.north < Map.plus.box.N)
window.north = Map.plus.box.N;
}
Vect_close(&Map);
}
}
if (window.north == window.south) {
window.north += 0.5 * temp_window.ns_res;
window.south -= 0.5 * temp_window.ns_res;
}
if (window.east == window.west) {
window.east += 0.5 * temp_window.ew_res;
window.west -= 0.5 * temp_window.ew_res;
}
G_align_window(&window, &temp_window);
}
G_adjust_Cell_head3(&window, 0, 0, 0);
G_put_window(&window);
exit(0);
}
int main(int argc, char *argv[])
{
int i;
int print_flag = 0;
int flat_flag;
int set_flag;
double x;
int ival;
int row_flag = 0, col_flag = 0;
struct Cell_head window, temp_window;
const char *value;
const char *name;
const char *mapset;
char **rast_ptr, **vect_ptr;
struct GModule *module;
struct
{
struct Flag
*update, *print, *gprint, *flprint, *lprint, *eprint, *nangle,
*center, *res_set, *dist_res, *dflt, *z, *savedefault,
*bbox, *gmt_style, *wms_style;
} flag;
struct
{
struct Option
*north, *south, *east, *west, *top, *bottom,
*res, *nsres, *ewres, *res3, *tbres, *rows, *cols,
*save, *region, *raster, *raster3d, *align,
*zoom, *vect;
} parm;
G_gisinit(argv[0]);
module = G_define_module();
G_add_keyword(_("general"));
G_add_keyword(_("settings"));
module->description =
_("Manages the boundary definitions for the " "geographic region.");
/* flags */
flag.dflt = G_define_flag();
flag.dflt->key = 'd';
flag.dflt->description = _("Set from default region");
flag.dflt->guisection = _("Existing");
flag.savedefault = G_define_flag();
flag.savedefault->key = 's';
flag.savedefault->label = _("Save as default region");
flag.savedefault->description = _("Only possible from the PERMANENT mapset");
flag.savedefault->guisection = _("Existing");
flag.print = G_define_flag();
flag.print->key = 'p';
flag.print->description = _("Print the current region");
flag.print->guisection = _("Print");
flag.lprint = G_define_flag();
flag.lprint->key = 'l';
flag.lprint->description = _("Print the current region in lat/long "
"using the current ellipsoid/datum");
flag.lprint->guisection = _("Print");
flag.eprint = G_define_flag();
flag.eprint->key = 'e';
flag.eprint->description = _("Print the current region extent");
flag.eprint->guisection = _("Print");
flag.center = G_define_flag();
flag.center->key = 'c';
flag.center->description =
_("Print the current region map center coordinates");
flag.center->guisection = _("Print");
flag.gmt_style = G_define_flag();
flag.gmt_style->key = 't';
flag.gmt_style->description =
_("Print the current region in GMT style");
flag.gmt_style->guisection = _("Print");
flag.wms_style = G_define_flag();
flag.wms_style->key = 'w';
flag.wms_style->description =
_("Print the current region in WMS style");
flag.wms_style->guisection = _("Print");
flag.dist_res = G_define_flag();
flag.dist_res->key = 'm';
flag.dist_res->description =
_("Print region resolution in meters (geodesic)");
flag.dist_res->guisection = _("Print");
flag.nangle = G_define_flag();
flag.nangle->key = 'n';
flag.nangle->label = _("Print the convergence angle (degrees CCW)");
flag.nangle->description =
_("The difference between the projection's grid north and true north, "
"measured at the center coordinates of the current region.");
flag.nangle->guisection = _("Print");
flag.z = G_define_flag();
flag.z->key = '3';
flag.z->description = _("Print also 3D settings");
flag.z->guisection = _("Print");
flag.bbox = G_define_flag();
flag.bbox->key = 'b';
flag.bbox->description =
_("Print the maximum bounding box in lat/long on WGS84");
flag.bbox->guisection = _("Print");
flag.gprint = G_define_flag();
flag.gprint->key = 'g';
flag.gprint->description = _("Print in shell script style");
flag.gprint->guisection = _("Print");
flag.flprint = G_define_flag();
flag.flprint->key = 'f';
flag.flprint->description = _("Print in shell script style, but in one line (flat)");
flag.flprint->guisection = _("Print");
flag.res_set = G_define_flag();
flag.res_set->key = 'a';
flag.res_set->description =
_("Align region to resolution (default = align to bounds, "
"works only for 2D resolution)");
flag.res_set->guisection = _("Bounds");
flag.update = G_define_flag();
flag.update->key = 'u';
flag.update->description = _("Do not update the current region");
flag.update->guisection = _("Effects");
/* parameters */
parm.region = G_define_standard_option(G_OPT_M_REGION);
parm.region->description = _("Set current region from named region");
parm.region->guisection = _("Existing");
parm.raster = G_define_standard_option(G_OPT_R_MAP);
parm.raster->key = "raster";
parm.raster->required = NO;
parm.raster->multiple = YES;
parm.raster->description = _("Set region to match raster map(s)");
parm.raster->guisection = _("Existing");
parm.raster3d = G_define_standard_option(G_OPT_R3_MAP);
parm.raster3d->key = "raster_3d";
parm.raster3d->required = NO;
parm.raster3d->multiple = NO;
parm.raster3d->description =
_("Set region to match 3D raster map(s) (both 2D and 3D "
"values)");
parm.raster3d->guisection = _("Existing");
parm.vect = G_define_standard_option(G_OPT_V_MAP);
parm.vect->key = "vector";
parm.vect->required = NO;
parm.vect->multiple = YES;
parm.vect->label = _("Set region to match vector map(s)");
parm.vect->description = NULL;
parm.vect->guisection = _("Existing");
parm.north = G_define_option();
parm.north->key = "n";
parm.north->key_desc = "value";
parm.north->required = NO;
parm.north->multiple = NO;
parm.north->type = TYPE_STRING;
parm.north->description = _("Value for the northern edge");
parm.north->guisection = _("Bounds");
parm.south = G_define_option();
parm.south->key = "s";
parm.south->key_desc = "value";
parm.south->required = NO;
parm.south->multiple = NO;
parm.south->type = TYPE_STRING;
parm.south->description = _("Value for the southern edge");
parm.south->guisection = _("Bounds");
parm.east = G_define_option();
parm.east->key = "e";
parm.east->key_desc = "value";
parm.east->required = NO;
parm.east->multiple = NO;
parm.east->type = TYPE_STRING;
parm.east->description = _("Value for the eastern edge");
parm.east->guisection = _("Bounds");
parm.west = G_define_option();
parm.west->key = "w";
parm.west->key_desc = "value";
parm.west->required = NO;
parm.west->multiple = NO;
parm.west->type = TYPE_STRING;
parm.west->description = _("Value for the western edge");
parm.west->guisection = _("Bounds");
parm.top = G_define_option();
parm.top->key = "t";
parm.top->key_desc = "value";
parm.top->required = NO;
parm.top->multiple = NO;
parm.top->type = TYPE_STRING;
parm.top->description = _("Value for the top edge");
parm.top->guisection = _("Bounds");
parm.bottom = G_define_option();
parm.bottom->key = "b";
parm.bottom->key_desc = "value";
parm.bottom->required = NO;
parm.bottom->multiple = NO;
parm.bottom->type = TYPE_STRING;
parm.bottom->description = _("Value for the bottom edge");
parm.bottom->guisection = _("Bounds");
parm.rows = G_define_option();
parm.rows->key = "rows";
parm.rows->key_desc = "value";
parm.rows->required = NO;
parm.rows->multiple = NO;
parm.rows->type = TYPE_INTEGER;
parm.rows->description = _("Number of rows in the new region");
parm.rows->guisection = _("Resolution");
parm.cols = G_define_option();
parm.cols->key = "cols";
parm.cols->key_desc = "value";
parm.cols->required = NO;
parm.cols->multiple = NO;
parm.cols->type = TYPE_INTEGER;
parm.cols->description = _("Number of columns in the new region");
parm.cols->guisection = _("Resolution");
parm.res = G_define_option();
parm.res->key = "res";
parm.res->key_desc = "value";
parm.res->required = NO;
parm.res->multiple = NO;
parm.res->type = TYPE_STRING;
parm.res->description =
_("2D grid resolution (north-south and east-west)");
parm.res->guisection = _("Resolution");
parm.res3 = G_define_option();
parm.res3->key = "res3";
parm.res3->key_desc = "value";
parm.res3->required = NO;
parm.res3->multiple = NO;
parm.res3->type = TYPE_STRING;
parm.res3->description =
_("3D grid resolution (north-south, east-west and top-bottom)");
parm.res3->guisection = _("Resolution");
parm.nsres = G_define_option();
parm.nsres->key = "nsres";
parm.nsres->key_desc = "value";
parm.nsres->required = NO;
parm.nsres->multiple = NO;
parm.nsres->type = TYPE_STRING;
parm.nsres->description = _("North-south 2D grid resolution");
parm.nsres->guisection = _("Resolution");
parm.ewres = G_define_option();
parm.ewres->key = "ewres";
parm.ewres->key_desc = "value";
parm.ewres->required = NO;
parm.ewres->multiple = NO;
parm.ewres->type = TYPE_STRING;
parm.ewres->description = _("East-west 2D grid resolution");
parm.ewres->guisection = _("Resolution");
parm.tbres = G_define_option();
parm.tbres->key = "tbres";
parm.tbres->key_desc = "value";
parm.tbres->required = NO;
parm.tbres->multiple = NO;
parm.tbres->type = TYPE_STRING;
parm.tbres->description = _("Top-bottom 3D grid resolution");
parm.tbres->guisection = _("Resolution");
parm.zoom = G_define_option();
parm.zoom->key = "zoom";
parm.zoom->key_desc = "name";
parm.zoom->required = NO;
parm.zoom->multiple = NO;
parm.zoom->type = TYPE_STRING;
parm.zoom->description =
_("Shrink region until it meets non-NULL data from this raster map");
parm.zoom->gisprompt = "old,cell,raster";
parm.zoom->guisection = _("Bounds");
parm.align = G_define_option();
parm.align->key = "align";
parm.align->key_desc = "name";
parm.align->required = NO;
parm.align->multiple = NO;
parm.align->type = TYPE_STRING;
parm.align->description =
_("Adjust region cells to cleanly align with this raster map");
parm.align->gisprompt = "old,cell,raster";
parm.align->guisection = _("Bounds");
parm.save = G_define_option();
parm.save->key = "save";
parm.save->key_desc = "name";
parm.save->required = NO;
parm.save->multiple = NO;
parm.save->type = TYPE_STRING;
parm.save->description =
_("Save current region settings in named region file");
parm.save->gisprompt = "new,windows,region";
parm.save->guisection = _("Effects");
G_option_required(flag.dflt, flag.savedefault, flag.print, flag.lprint,
flag.eprint, flag.center, flag.gmt_style, flag.wms_style,
flag.dist_res, flag.nangle, flag. z, flag.bbox, flag.gprint,
flag.res_set, flag.update, parm.region, parm.raster,
parm.raster3d, parm.vect, parm.north, parm.south, parm.east,
parm.west, parm.top, parm.bottom, parm.rows, parm.cols,
parm.res, parm.res3, parm.nsres, parm.ewres, parm.tbres,
parm.zoom, parm.align, parm.save, NULL);
if (G_parser(argc, argv))
exit(EXIT_FAILURE);
G_get_default_window(&window);
set_flag = !flag.update->answer;
flat_flag = flag.flprint->answer;
if (flag.print->answer)
print_flag |= PRINT_REG;
if (flag.gprint->answer)
print_flag |= PRINT_SH;
if (flag.lprint->answer)
print_flag |= PRINT_LL;
if (flag.eprint->answer)
print_flag |= PRINT_EXTENT;
if (flag.center->answer)
print_flag |= PRINT_CENTER;
if (flag.gmt_style->answer)
print_flag |= PRINT_GMT;
if (flag.wms_style->answer)
print_flag |= PRINT_WMS;
if (flag.nangle->answer)
print_flag |= PRINT_NANGLE;
if (flag.dist_res->answer)
print_flag |= PRINT_METERS;
if (flag.z->answer)
print_flag |= PRINT_3D;
if (flag.bbox->answer)
print_flag |= PRINT_MBBOX;
if (print_flag == PRINT_METERS)
print_flag |= PRINT_SH;
if (print_flag == PRINT_SH ||
print_flag & PRINT_3D || print_flag == PRINT_METERS + PRINT_SH) {
print_flag |= PRINT_REG;
}
if (!flag.dflt->answer)
G_get_window(&window);
/* region= */
if ((name = parm.region->answer)) {
mapset = G_find_file2("windows", name, "");
if (!mapset)
G_fatal_error(_("Region <%s> not found"), name);
G_get_element_window(&window, "windows", name, mapset);
}
/* raster= */
if (parm.raster->answer) {
int first = 0;
rast_ptr = parm.raster->answers;
for (; *rast_ptr != NULL; rast_ptr++) {
char rast_name[GNAME_MAX];
strcpy(rast_name, *rast_ptr);
mapset = G_find_raster2(rast_name, "");
if (!mapset)
G_fatal_error(_("Raster map <%s> not found"), rast_name);
Rast_get_cellhd(rast_name, mapset, &temp_window);
if (!first) {
window = temp_window;
first = 1;
}
else {
window.north = (window.north > temp_window.north) ?
window.north : temp_window.north;
window.south = (window.south < temp_window.south) ?
window.south : temp_window.south;
window.east = (window.east > temp_window.east) ?
window.east : temp_window.east;
window.west = (window.west < temp_window.west) ?
window.west : temp_window.west;
}
}
G_adjust_Cell_head3(&window, 0, 0, 0);
}
/* raster3d= */
if ((name = parm.raster3d->answer)) {
RASTER3D_Region win;
if ((mapset = G_find_raster3d(name, "")) == NULL)
G_fatal_error(_("3D raster map <%s> not found"), name);
if (Rast3d_read_region_map(name, mapset, &win) < 0)
G_fatal_error(_("Unable to read header of 3D raster map <%s@%s>"),
name, mapset);
Rast3d_region_to_cell_head(&win, &window);
}
/* vector= */
if (parm.vect->answer) {
int first = 0;
vect_ptr = parm.vect->answers;
for (; *vect_ptr != NULL; vect_ptr++) {
struct Map_info Map;
struct bound_box box;
char vect_name[GNAME_MAX];
struct Cell_head map_window;
strcpy(vect_name, *vect_ptr);
mapset = G_find_vector2(vect_name, "");
if (!mapset)
G_fatal_error(_("Vector map <%s> not found"), vect_name);
temp_window = window;
Vect_set_open_level(2);
if (2 > Vect_open_old_head(&Map, vect_name, mapset))
G_fatal_error(_("Unable to open vector map <%s> on topological level"),
vect_name);
Vect_get_map_box(&Map, &box);
map_window = window;
map_window.north = box.N;
map_window.south = box.S;
map_window.west = box.W;
map_window.east = box.E;
map_window.top = box.T;
map_window.bottom = box.B;
if (!first) {
window = map_window;
first = 1;
}
else {
window.north = (window.north > map_window.north) ?
window.north : map_window.north;
window.south = (window.south < map_window.south) ?
window.south : map_window.south;
window.east = (window.east > map_window.east) ?
window.east : map_window.east;
window.west = (window.west < map_window.west) ?
window.west : map_window.west;
if (map_window.top > window.top)
window.top = map_window.top;
if (map_window.bottom < window.bottom)
window.bottom = map_window.bottom;
}
if (window.north == window.south) {
window.north = window.north + 0.5 * temp_window.ns_res;
window.south = window.south - 0.5 * temp_window.ns_res;
}
if (window.east == window.west) {
window.west = window.west - 0.5 * temp_window.ew_res;
window.east = window.east + 0.5 * temp_window.ew_res;
}
if (window.top == window.bottom) {
window.bottom = (window.bottom - 0.5 * temp_window.tb_res);
window.top = (window.top + 0.5 * temp_window.tb_res);
}
if (flag.res_set->answer)
Rast_align_window(&window, &temp_window);
Vect_close(&Map);
}
}
/* n= */
if ((value = parm.north->answer)) {
if ((i = nsew(value, "n+", "n-", "s+"))) {
if (!G_scan_resolution(value + 2, &x, window.proj))
die(parm.north);
switch (i) {
case 1:
window.north += x;
break;
case 2:
window.north -= x;
break;
case 3:
window.north = window.south + x;
break;
}
}
else if (G_scan_northing(value, &x, window.proj))
window.north = x;
else
die(parm.north);
}
/* s= */
if ((value = parm.south->answer)) {
if ((i = nsew(value, "s+", "s-", "n-"))) {
if (!G_scan_resolution(value + 2, &x, window.proj))
die(parm.south);
switch (i) {
case 1:
window.south += x;
break;
case 2:
window.south -= x;
break;
case 3:
window.south = window.north - x;
break;
}
}
else if (G_scan_northing(value, &x, window.proj))
window.south = x;
else
die(parm.south);
}
/* e= */
if ((value = parm.east->answer)) {
if ((i = nsew(value, "e+", "e-", "w+"))) {
if (!G_scan_resolution(value + 2, &x, window.proj))
die(parm.east);
switch (i) {
case 1:
window.east += x;
break;
case 2:
window.east -= x;
break;
case 3:
window.east = window.west + x;
break;
}
}
else if (G_scan_easting(value, &x, window.proj))
window.east = x;
else
die(parm.east);
}
/* w= */
if ((value = parm.west->answer)) {
if ((i = nsew(value, "w+", "w-", "e-"))) {
if (!G_scan_resolution(value + 2, &x, window.proj))
die(parm.west);
switch (i) {
case 1:
window.west += x;
break;
case 2:
window.west -= x;
break;
case 3:
window.west = window.east - x;
break;
}
}
else if (G_scan_easting(value, &x, window.proj))
window.west = x;
else
die(parm.west);
}
/* t= */
if ((value = parm.top->answer)) {
if ((i = nsew(value, "t+", "t-", "b+"))) {
if (sscanf(value + 2, "%lf", &x) != 1)
die(parm.top);
switch (i) {
case 1:
window.top += x;
break;
case 2:
window.top -= x;
break;
case 3:
window.top = window.bottom + x;
break;
}
}
else if (sscanf(value, "%lf", &x) == 1)
window.top = x;
else
die(parm.top);
}
/* b= */
if ((value = parm.bottom->answer)) {
if ((i = nsew(value, "b+", "b-", "t-"))) {
if (sscanf(value + 2, "%lf", &x) != 1)
die(parm.bottom);
switch (i) {
case 1:
window.bottom += x;
break;
case 2:
window.bottom -= x;
break;
case 3:
window.bottom = window.top - x;
break;
}
}
else if (sscanf(value, "%lf", &x) == 1)
window.bottom = x;
else
die(parm.bottom);
}
/* res= */
if ((value = parm.res->answer)) {
if (!G_scan_resolution(value, &x, window.proj))
die(parm.res);
window.ns_res = x;
window.ew_res = x;
if (flag.res_set->answer) {
window.north = ceil(window.north / x) * x;
window.south = floor(window.south / x) * x;
window.east = ceil(window.east / x) * x;
window.west = floor(window.west / x) * x;
}
}
/* res3= */
if ((value = parm.res3->answer)) {
if (!G_scan_resolution(value, &x, window.proj))
die(parm.res);
window.ns_res3 = x;
window.ew_res3 = x;
window.tb_res = x;
}
/* nsres= */
if ((value = parm.nsres->answer)) {
if (!G_scan_resolution(value, &x, window.proj))
die(parm.nsres);
window.ns_res = x;
if (flag.res_set->answer) {
window.north = ceil(window.north / x) * x;
window.south = floor(window.south / x) * x;
}
}
/* ewres= */
if ((value = parm.ewres->answer)) {
if (!G_scan_resolution(value, &x, window.proj))
die(parm.ewres);
window.ew_res = x;
if (flag.res_set->answer) {
window.east = ceil(window.east / x) * x;
window.west = floor(window.west / x) * x;
}
}
/* tbres= */
if ((value = parm.tbres->answer)) {
if (sscanf(value, "%lf", &x) != 1)
die(parm.tbres);
window.tb_res = x;
if (flag.res_set->answer) {
window.top = ceil(window.top / x) * x;
window.bottom = floor(window.bottom / x) * x;
}
}
/* rows= */
if ((value = parm.rows->answer)) {
if (sscanf(value, "%i", &ival) != 1)
die(parm.rows);
window.rows = ival;
row_flag = 1;
}
/* cols= */
if ((value = parm.cols->answer)) {
if (sscanf(value, "%i", &ival) != 1)
die(parm.cols);
window.cols = ival;
col_flag = 1;
}
/* zoom= */
if ((name = parm.zoom->answer)) {
mapset = G_find_raster2(name, "");
if (!mapset)
G_fatal_error(_("Raster map <%s> not found"), name);
zoom(&window, name, mapset);
}
/* align= */
if ((name = parm.align->answer)) {
mapset = G_find_raster2(name, "");
if (!mapset)
G_fatal_error(_("Raster map <%s> not found"), name);
Rast_get_cellhd(name, mapset, &temp_window);
Rast_align_window(&window, &temp_window);
}
/* save= */
if ((name = parm.save->answer)) {
temp_window = window;
G_adjust_Cell_head3(&temp_window, 0, 0, 0);
if (G_put_element_window(&temp_window, "windows", name) < 0)
G_fatal_error(_("Unable to set region <%s>"), name);
}
G_adjust_Cell_head3(&window, row_flag, col_flag, 0);
if (set_flag) {
if (G_put_window(&window) < 0)
G_fatal_error(_("Unable to update current region"));
}
if (flag.savedefault->answer) {
if (strcmp(G_mapset(), "PERMANENT") == 0) {
G_put_element_window(&window, "", "DEFAULT_WIND");
}
else {
G_fatal_error(_("Unable to change default region. "
"The current mapset is not <PERMANENT>."));
}
} /* / flag.savedefault->answer */
if (print_flag)
print_window(&window, print_flag, flat_flag);
exit(EXIT_SUCCESS);
}
int main(int argc, char *argv[])
{
int out_fd, base_raster;
char *infile, *outmap;
int percent;
double zrange_min, zrange_max, d_tmp;
double irange_min, irange_max;
unsigned long estimated_lines;
RASTER_MAP_TYPE rtype, base_raster_data_type;
struct History history;
char title[64];
SEGMENT base_segment;
struct PointBinning point_binning;
void *base_array;
void *raster_row;
struct Cell_head region;
struct Cell_head input_region;
int rows, last_rows, row0, cols; /* scan box size */
int row; /* counters */
int pass, npasses;
unsigned long line, line_total;
unsigned int counter;
unsigned long n_invalid;
char buff[BUFFSIZE];
double x, y, z;
double intensity;
int arr_row, arr_col;
unsigned long count, count_total;
int point_class;
double zscale = 1.0;
double iscale = 1.0;
double res = 0.0;
struct BinIndex bin_index_nodes;
bin_index_nodes.num_nodes = 0;
bin_index_nodes.max_nodes = 0;
bin_index_nodes.nodes = 0;
struct GModule *module;
struct Option *input_opt, *output_opt, *percent_opt, *type_opt, *filter_opt, *class_opt;
struct Option *method_opt, *base_raster_opt;
struct Option *zrange_opt, *zscale_opt;
struct Option *irange_opt, *iscale_opt;
struct Option *trim_opt, *pth_opt, *res_opt;
struct Option *file_list_opt;
struct Flag *print_flag, *scan_flag, *shell_style, *over_flag, *extents_flag;
struct Flag *intens_flag, *intens_import_flag;
struct Flag *set_region_flag;
struct Flag *base_rast_res_flag;
struct Flag *only_valid_flag;
/* LAS */
LASReaderH LAS_reader;
LASHeaderH LAS_header;
LASSRSH LAS_srs;
LASPointH LAS_point;
int return_filter;
const char *projstr;
struct Cell_head cellhd, loc_wind;
unsigned int n_filtered;
G_gisinit(argv[0]);
module = G_define_module();
G_add_keyword(_("raster"));
G_add_keyword(_("import"));
G_add_keyword(_("LIDAR"));
G_add_keyword(_("statistics"));
G_add_keyword(_("conversion"));
G_add_keyword(_("aggregation"));
G_add_keyword(_("binning"));
module->description =
_("Creates a raster map from LAS LiDAR points using univariate statistics.");
input_opt = G_define_standard_option(G_OPT_F_BIN_INPUT);
input_opt->required = NO;
input_opt->label = _("LAS input file");
input_opt->description = _("LiDAR input files in LAS format (*.las or *.laz)");
input_opt->guisection = _("Input");
output_opt = G_define_standard_option(G_OPT_R_OUTPUT);
output_opt->required = NO;
output_opt->guisection = _("Output");
file_list_opt = G_define_standard_option(G_OPT_F_INPUT);
file_list_opt->key = "file";
file_list_opt->label = _("File containing names of LAS input files");
file_list_opt->description = _("LiDAR input files in LAS format (*.las or *.laz)");
file_list_opt->required = NO;
file_list_opt->guisection = _("Input");
method_opt = G_define_option();
method_opt->key = "method";
method_opt->type = TYPE_STRING;
method_opt->required = NO;
method_opt->description = _("Statistic to use for raster values");
method_opt->options =
"n,min,max,range,sum,mean,stddev,variance,coeff_var,median,percentile,skewness,trimmean";
method_opt->answer = "mean";
method_opt->guisection = _("Statistic");
G_asprintf((char **)&(method_opt->descriptions),
"n;%s;"
"min;%s;"
"max;%s;"
"range;%s;"
"sum;%s;"
"mean;%s;"
"stddev;%s;"
"variance;%s;"
"coeff_var;%s;"
"median;%s;"
"percentile;%s;"
"skewness;%s;"
"trimmean;%s",
_("Number of points in cell"),
_("Minimum value of point values in cell"),
_("Maximum value of point values in cell"),
_("Range of point values in cell"),
_("Sum of point values in cell"),
_("Mean (average) value of point values in cell"),
_("Standard deviation of point values in cell"),
_("Variance of point values in cell"),
_("Coefficient of variance of point values in cell"),
_("Median value of point values in cell"),
_("pth (nth) percentile of point values in cell"),
_("Skewness of point values in cell"),
_("Trimmed mean of point values in cell"));
type_opt = G_define_standard_option(G_OPT_R_TYPE);
type_opt->required = NO;
type_opt->answer = "FCELL";
base_raster_opt = G_define_standard_option(G_OPT_R_INPUT);
base_raster_opt->key = "base_raster";
base_raster_opt->required = NO;
base_raster_opt->label =
_("Subtract raster values from the Z coordinates");
base_raster_opt->description =
_("The scale for Z is applied beforehand, the range filter for"
" Z afterwards");
base_raster_opt->guisection = _("Transform");
zrange_opt = G_define_option();
zrange_opt->key = "zrange";
zrange_opt->type = TYPE_DOUBLE;
zrange_opt->required = NO;
zrange_opt->key_desc = "min,max";
zrange_opt->description = _("Filter range for Z data (min,max)");
zrange_opt->guisection = _("Selection");
zscale_opt = G_define_option();
zscale_opt->key = "zscale";
zscale_opt->type = TYPE_DOUBLE;
zscale_opt->required = NO;
zscale_opt->answer = "1.0";
zscale_opt->description = _("Scale to apply to Z data");
zscale_opt->guisection = _("Transform");
irange_opt = G_define_option();
irange_opt->key = "intensity_range";
irange_opt->type = TYPE_DOUBLE;
irange_opt->required = NO;
irange_opt->key_desc = "min,max";
irange_opt->description = _("Filter range for intensity values (min,max)");
irange_opt->guisection = _("Selection");
iscale_opt = G_define_option();
iscale_opt->key = "intensity_scale";
iscale_opt->type = TYPE_DOUBLE;
iscale_opt->required = NO;
iscale_opt->answer = "1.0";
iscale_opt->description = _("Scale to apply to intensity values");
iscale_opt->guisection = _("Transform");
percent_opt = G_define_option();
percent_opt->key = "percent";
percent_opt->type = TYPE_INTEGER;
percent_opt->required = NO;
percent_opt->answer = "100";
percent_opt->options = "1-100";
percent_opt->description = _("Percent of map to keep in memory");
/* I would prefer to call the following "percentile", but that has too
* much namespace overlap with the "percent" option above */
pth_opt = G_define_option();
pth_opt->key = "pth";
pth_opt->type = TYPE_INTEGER;
pth_opt->required = NO;
pth_opt->options = "1-100";
pth_opt->description = _("pth percentile of the values");
pth_opt->guisection = _("Statistic");
trim_opt = G_define_option();
trim_opt->key = "trim";
trim_opt->type = TYPE_DOUBLE;
trim_opt->required = NO;
trim_opt->options = "0-50";
trim_opt->label = _("Discard given percentage of the smallest and largest values");
trim_opt->description =
_("Discard <trim> percent of the smallest and <trim> percent of the largest observations");
trim_opt->guisection = _("Statistic");
res_opt = G_define_option();
res_opt->key = "resolution";
res_opt->type = TYPE_DOUBLE;
res_opt->required = NO;
res_opt->description =
_("Output raster resolution");
res_opt->guisection = _("Output");
filter_opt = G_define_option();
filter_opt->key = "return_filter";
filter_opt->type = TYPE_STRING;
filter_opt->required = NO;
filter_opt->label = _("Only import points of selected return type");
filter_opt->description = _("If not specified, all points are imported");
filter_opt->options = "first,last,mid";
filter_opt->guisection = _("Selection");
class_opt = G_define_option();
class_opt->key = "class_filter";
class_opt->type = TYPE_INTEGER;
class_opt->multiple = YES;
class_opt->required = NO;
class_opt->label = _("Only import points of selected class(es)");
class_opt->description = _("Input is comma separated integers. "
"If not specified, all points are imported.");
class_opt->guisection = _("Selection");
print_flag = G_define_flag();
print_flag->key = 'p';
print_flag->description =
_("Print LAS file info and exit");
extents_flag = G_define_flag();
extents_flag->key = 'e';
extents_flag->label =
_("Use the extent of the input for the raster extent");
extents_flag->description =
_("Set internally computational region extents based on the"
" point cloud");
extents_flag->guisection = _("Output");
set_region_flag = G_define_flag();
set_region_flag->key = 'n';
set_region_flag->label =
_("Set computation region to match the new raster map");
set_region_flag->description =
_("Set computation region to match the 2D extent and resolution"
" of the newly created new raster map");
set_region_flag->guisection = _("Output");
over_flag = G_define_flag();
over_flag->key = 'o';
over_flag->label =
_("Override projection check (use current location's projection)");
over_flag->description =
_("Assume that the dataset has same projection as the current location");
scan_flag = G_define_flag();
scan_flag->key = 's';
scan_flag->description = _("Scan data file for extent then exit");
shell_style = G_define_flag();
shell_style->key = 'g';
shell_style->description =
_("In scan mode, print using shell script style");
intens_flag = G_define_flag();
intens_flag->key = 'i';
intens_flag->label =
_("Use intensity values rather than Z values");
intens_flag->description =
_("Uses intensity values everywhere as if they would be Z"
" coordinates");
intens_import_flag = G_define_flag();
intens_import_flag->key = 'j';
intens_import_flag->description =
_("Use Z values for filtering, but intensity values for statistics");
base_rast_res_flag = G_define_flag();
base_rast_res_flag->key = 'd';
base_rast_res_flag->label =
_("Use base raster resolution instead of computational region");
base_rast_res_flag->description =
_("For getting values from base raster, use its actual"
" resolution instead of computational region resolution");
only_valid_flag = G_define_flag();
only_valid_flag->key = 'v';
only_valid_flag->label = _("Use only valid points");
only_valid_flag->description =
_("Points invalid according to APSRS LAS specification will be"
" filtered out");
only_valid_flag->guisection = _("Selection");
G_option_required(input_opt, file_list_opt, NULL);
G_option_exclusive(input_opt, file_list_opt, NULL);
G_option_required(output_opt, print_flag, scan_flag, shell_style, NULL);
G_option_exclusive(intens_flag, intens_import_flag, NULL);
G_option_requires(base_rast_res_flag, base_raster_opt, NULL);
if (G_parser(argc, argv))
exit(EXIT_FAILURE);
int only_valid = FALSE;
n_invalid = 0;
if (only_valid_flag->answer)
only_valid = TRUE;
/* we could use rules but this gives more info and allows continuing */
if (set_region_flag->answer && !(extents_flag->answer || res_opt->answer)) {
G_warning(_("Flag %c makes sense only with %s option or -%c flag"),
set_region_flag->key, res_opt->key, extents_flag->key);
/* avoid the call later on */
set_region_flag->answer = '\0';
}
struct StringList infiles;
if (file_list_opt->answer) {
if (access(file_list_opt->answer, F_OK) != 0)
G_fatal_error(_("File <%s> does not exist"), file_list_opt->answer);
string_list_from_file(&infiles, file_list_opt->answer);
}
else {
string_list_from_one_item(&infiles, input_opt->answer);
}
/* parse input values */
outmap = output_opt->answer;
if (shell_style->answer && !scan_flag->answer) {
scan_flag->answer = 1; /* pointer not int, so set = shell_style->answer ? */
}
/* check zrange and extent relation */
if (scan_flag->answer || extents_flag->answer) {
if (zrange_opt->answer)
G_warning(_("zrange will not be taken into account during scan"));
}
Rast_get_window(®ion);
/* G_get_window seems to be unreliable if the location has been changed */
G_get_set_window(&loc_wind); /* TODO: v.in.lidar uses G_get_default_window() */
estimated_lines = 0;
int i;
for (i = 0; i < infiles.num_items; i++) {
infile = infiles.items[i];
/* don't if file not found */
if (access(infile, F_OK) != 0)
G_fatal_error(_("Input file <%s> does not exist"), infile);
/* Open LAS file*/
LAS_reader = LASReader_Create(infile);
if (LAS_reader == NULL)
G_fatal_error(_("Unable to open file <%s> as a LiDAR point cloud"),
infile);
LAS_header = LASReader_GetHeader(LAS_reader);
if (LAS_header == NULL) {
G_fatal_error(_("Unable to read LAS header of <%s>"), infile);
}
LAS_srs = LASHeader_GetSRS(LAS_header);
/* print info or check projection if we are actually importing */
if (print_flag->answer) {
/* print filename when there is more than one file */
if (infiles.num_items > 1)
fprintf(stdout, "File: %s\n", infile);
/* Print LAS header */
print_lasinfo(LAS_header, LAS_srs);
}
else {
/* report that we are checking more files */
if (i == 1)
G_message(_("First file's projection checked,"
" checking projection of the other files..."));
/* Fetch input map projection in GRASS form. */
projstr = LASSRS_GetWKT_CompoundOK(LAS_srs);
/* we are printing the non-warning messages only for first file */
projection_check_wkt(cellhd, loc_wind, projstr, over_flag->answer,
shell_style->answer || i);
/* if there is a problem in some other file, first OK message
* is printed but than a warning, this is not ideal but hopefully
* not so confusing when importing multiple files */
}
if (scan_flag->answer || extents_flag->answer) {
/* we assign to the first one (i==0) but update for the rest */
scan_bounds(LAS_reader, shell_style->answer, extents_flag->answer, i,
zscale, ®ion);
}
/* number of estimated point across all files */
/* TODO: this should be ull which won't work with percent report */
estimated_lines += LASHeader_GetPointRecordsCount(LAS_header);
/* We are closing all again and we will be opening them later,
* so we don't have to worry about limit for open files. */
LASSRS_Destroy(LAS_srs);
LASHeader_Destroy(LAS_header);
LASReader_Destroy(LAS_reader);
}
/* if we are not importing, end */
if (print_flag->answer || scan_flag->answer)
exit(EXIT_SUCCESS);
return_filter = LAS_ALL;
if (filter_opt->answer) {
if (strcmp(filter_opt->answer, "first") == 0)
return_filter = LAS_FIRST;
else if (strcmp(filter_opt->answer, "last") == 0)
return_filter = LAS_LAST;
else if (strcmp(filter_opt->answer, "mid") == 0)
return_filter = LAS_MID;
else
G_fatal_error(_("Unknown filter option <%s>"), filter_opt->answer);
}
struct ReturnFilter return_filter_struct;
return_filter_struct.filter = return_filter;
struct ClassFilter class_filter;
class_filter_create_from_strings(&class_filter, class_opt->answers);
percent = atoi(percent_opt->answer);
/* TODO: we already used zscale */
/* TODO: we don't report intensity range */
if (zscale_opt->answer)
zscale = atof(zscale_opt->answer);
if (iscale_opt->answer)
iscale = atof(iscale_opt->answer);
/* parse zrange */
if (zrange_opt->answer != NULL) {
if (zrange_opt->answers[0] == NULL)
G_fatal_error(_("Invalid zrange"));
sscanf(zrange_opt->answers[0], "%lf", &zrange_min);
sscanf(zrange_opt->answers[1], "%lf", &zrange_max);
if (zrange_min > zrange_max) {
d_tmp = zrange_max;
zrange_max = zrange_min;
zrange_min = d_tmp;
}
}
/* parse irange */
if (irange_opt->answer != NULL) {
if (irange_opt->answers[0] == NULL)
G_fatal_error(_("Invalid %s"), irange_opt->key);
sscanf(irange_opt->answers[0], "%lf", &irange_min);
sscanf(irange_opt->answers[1], "%lf", &irange_max);
if (irange_min > irange_max) {
d_tmp = irange_max;
irange_max = irange_min;
irange_min = d_tmp;
}
}
point_binning_set(&point_binning, method_opt->answer, pth_opt->answer,
trim_opt->answer, FALSE);
base_array = NULL;
if (strcmp("CELL", type_opt->answer) == 0)
rtype = CELL_TYPE;
else if (strcmp("DCELL", type_opt->answer) == 0)
rtype = DCELL_TYPE;
else
rtype = FCELL_TYPE;
if (point_binning.method == METHOD_N)
rtype = CELL_TYPE;
if (res_opt->answer) {
/* align to resolution */
res = atof(res_opt->answer);
if (!G_scan_resolution(res_opt->answer, &res, region.proj))
G_fatal_error(_("Invalid input <%s=%s>"), res_opt->key, res_opt->answer);
if (res <= 0)
G_fatal_error(_("Option '%s' must be > 0.0"), res_opt->key);
region.ns_res = region.ew_res = res;
region.north = ceil(region.north / res) * res;
region.south = floor(region.south / res) * res;
region.east = ceil(region.east / res) * res;
region.west = floor(region.west / res) * res;
G_adjust_Cell_head(®ion, 0, 0);
}
else if (extents_flag->answer) {
/* align to current region */
Rast_align_window(®ion, &loc_wind);
}
Rast_set_output_window(®ion);
rows = last_rows = region.rows;
npasses = 1;
if (percent < 100) {
rows = (int)(region.rows * (percent / 100.0));
npasses = region.rows / rows;
last_rows = region.rows - npasses * rows;
if (last_rows)
npasses++;
else
last_rows = rows;
}
cols = region.cols;
G_debug(2, "region.n=%f region.s=%f region.ns_res=%f", region.north,
region.south, region.ns_res);
G_debug(2, "region.rows=%d [box_rows=%d] region.cols=%d", region.rows,
rows, region.cols);
/* using row-based chunks (used for output) when input and output
* region matches and using segment library when they don't */
int use_segment = 0;
int use_base_raster_res = 0;
/* TODO: see if the input region extent is smaller than the raster
* if yes, the we need to load the whole base raster if the -e
* flag was defined (alternatively clip the regions) */
if (base_rast_res_flag->answer)
use_base_raster_res = 1;
if (base_raster_opt->answer && (res_opt->answer || use_base_raster_res
|| extents_flag->answer))
use_segment = 1;
if (base_raster_opt->answer && !use_segment) {
/* TODO: do we need to test existence first? mapset? */
base_raster = Rast_open_old(base_raster_opt->answer, "");
base_raster_data_type = Rast_get_map_type(base_raster);
base_array = G_calloc((size_t)rows * (cols + 1), Rast_cell_size(base_raster_data_type));
}
if (base_raster_opt->answer && use_segment) {
if (use_base_raster_res) {
/* read raster actual extent and resolution */
Rast_get_cellhd(base_raster_opt->answer, "", &input_region);
/* TODO: make it only as small as the output is or points are */
Rast_set_input_window(&input_region); /* we have split window */
} else {
Rast_get_input_window(&input_region);
}
rast_segment_open(&base_segment, base_raster_opt->answer, &base_raster_data_type);
}
if (!scan_flag->answer) {
if (!check_rows_cols_fit_to_size_t(rows, cols))
G_fatal_error(_("Unable to process the hole map at once. "
"Please set the '%s' option to some value lower than 100."),
percent_opt->key);
point_binning_memory_test(&point_binning, rows, cols, rtype);
}
/* open output map */
out_fd = Rast_open_new(outmap, rtype);
/* allocate memory for a single row of output data */
raster_row = Rast_allocate_output_buf(rtype);
G_message(_("Reading data ..."));
count_total = line_total = 0;
/* main binning loop(s) */
for (pass = 1; pass <= npasses; pass++) {
if (npasses > 1)
G_message(_("Pass #%d (of %d) ..."), pass, npasses);
/* figure out segmentation */
row0 = (pass - 1) * rows;
if (pass == npasses) {
rows = last_rows;
}
if (base_array) {
G_debug(2, "filling base raster array");
for (row = 0; row < rows; row++) {
Rast_get_row(base_raster, base_array + ((size_t) row * cols * Rast_cell_size(base_raster_data_type)), row, base_raster_data_type);
}
}
G_debug(2, "pass=%d/%d rows=%d", pass, npasses, rows);
point_binning_allocate(&point_binning, rows, cols, rtype);
line = 0;
count = 0;
counter = 0;
G_percent_reset();
/* loop of input files */
for (i = 0; i < infiles.num_items; i++) {
infile = infiles.items[i];
/* we already know file is there, so just do basic checks */
LAS_reader = LASReader_Create(infile);
if (LAS_reader == NULL)
G_fatal_error(_("Unable to open file <%s>"), infile);
while ((LAS_point = LASReader_GetNextPoint(LAS_reader)) != NULL) {
line++;
counter++;
if (counter == 100000) { /* speed */
if (line < estimated_lines)
G_percent(line, estimated_lines, 3);
counter = 0;
}
/* We always count them and report because behavior
* changed in between 7.0 and 7.2 from undefined (but skipping
* invalid points) to filtering them out only when requested. */
if (!LASPoint_IsValid(LAS_point)) {
n_invalid++;
if (only_valid)
continue;
}
x = LASPoint_GetX(LAS_point);
y = LASPoint_GetY(LAS_point);
if (intens_flag->answer)
/* use intensity as z here to allow all filters (and
* modifications) below to be applied for intensity */
z = LASPoint_GetIntensity(LAS_point);
else
z = LASPoint_GetZ(LAS_point);
int return_n = LASPoint_GetReturnNumber(LAS_point);
int n_returns = LASPoint_GetNumberOfReturns(LAS_point);
if (return_filter_is_out(&return_filter_struct, return_n, n_returns)) {
n_filtered++;
continue;
}
point_class = (int) LASPoint_GetClassification(LAS_point);
if (class_filter_is_out(&class_filter, point_class))
continue;
if (y <= region.south || y > region.north) {
continue;
}
if (x < region.west || x >= region.east) {
continue;
}
/* find the bin in the current array box */
arr_row = (int)((region.north - y) / region.ns_res) - row0;
if (arr_row < 0 || arr_row >= rows)
continue;
arr_col = (int)((x - region.west) / region.ew_res);
z = z * zscale;
if (base_array) {
double base_z;
if (row_array_get_value_row_col(base_array, arr_row, arr_col,
cols, base_raster_data_type,
&base_z))
z -= base_z;
else
continue;
}
else if (use_segment) {
double base_z;
if (rast_segment_get_value_xy(&base_segment, &input_region,
base_raster_data_type, x, y,
&base_z))
z -= base_z;
else
continue;
}
if (zrange_opt->answer) {
if (z < zrange_min || z > zrange_max) {
continue;
}
}
if (intens_import_flag->answer || irange_opt->answer) {
intensity = LASPoint_GetIntensity(LAS_point);
intensity *= iscale;
if (irange_opt->answer) {
if (intensity < irange_min || intensity > irange_max) {
continue;
}
}
/* use intensity for statistics */
if (intens_import_flag->answer)
z = intensity;
}
count++;
/* G_debug(5, "x: %f, y: %f, z: %f", x, y, z); */
update_value(&point_binning, &bin_index_nodes, cols,
arr_row, arr_col, rtype, x, y, z);
} /* while !EOF of one input file */
/* close input LAS file */
LASReader_Destroy(LAS_reader);
} /* end of loop for all input files files */
G_percent(1, 1, 1); /* flush */
G_debug(2, "pass %d finished, %lu coordinates in box", pass, count);
count_total += count;
line_total += line;
/* calc stats and output */
G_message(_("Writing to map ..."));
for (row = 0; row < rows; row++) {
/* potentially vector writing can be independent on the binning */
write_values(&point_binning, &bin_index_nodes, raster_row, row,
cols, rtype, NULL);
/* write out line of raster data */
Rast_put_row(out_fd, raster_row, rtype);
}
/* free memory */
point_binning_free(&point_binning, &bin_index_nodes);
} /* passes loop */
if (base_array)
Rast_close(base_raster);
if (use_segment)
Segment_close(&base_segment);
G_percent(1, 1, 1); /* flush */
G_free(raster_row);
/* close raster file & write history */
Rast_close(out_fd);
sprintf(title, "Raw X,Y,Z data binned into a raster grid by cell %s",
method_opt->answer);
Rast_put_cell_title(outmap, title);
Rast_short_history(outmap, "raster", &history);
Rast_command_history(&history);
Rast_set_history(&history, HIST_DATSRC_1, infile);
Rast_write_history(outmap, &history);
/* set computation region to the new raster map */
/* TODO: should be in the done message */
if (set_region_flag->answer)
G_put_window(®ion);
if (n_invalid && only_valid)
G_message(_("%lu input points were invalid and filtered out"),
n_invalid);
if (n_invalid && !only_valid)
G_message(_("%lu input points were invalid, use -%c flag to filter"
" them out"), n_invalid, only_valid_flag->key);
if (infiles.num_items > 1) {
sprintf(buff, _("Raster map <%s> created."
" %lu points from %d files found in region."),
outmap, count_total, infiles.num_items);
}
else {
sprintf(buff, _("Raster map <%s> created."
" %lu points found in region."),
outmap, count_total);
}
G_done_msg("%s", buff);
G_debug(1, "Processed %lu points.", line_total);
string_list_free(&infiles);
exit(EXIT_SUCCESS);
}