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# geo functions
# -------------------------------------------------------------------------------------------------
#
#
# geo.Coord class
# -------------------------------------------------------------------------------------------------
#
# geo.Coord.new([<coord>]) ... class that holds and maintains geographical coordinates
# can be initialized with another geo.Coord instance
#
# SETTER METHODS:
#
# .set(<coord>) ... sets coordinates from another geo.Coord instance
#
# .set_lat(<num>) ... functions for setting latitude/longitude/altitude
# .set_lon(<num>)
# .set_alt(<num>) ..this is in meters
# .set_latlon(<num>, <num> [, <num>]) (altitude (meters) is optional; default=0)
#
# .set_x(<num>) ... functions for setting cartesian x/y/z coordinates
# .set_y(<num>)
# .set_z(<num>)
# .set_xyz(<num>, <num>, <num>)
#
#
# GETTER METHODS:
#
# .lat()
# .lon() ... functions for getting lat/lon/alt
# .alt() ... returns altitude in m
# .latlon() ... returns vector [<lat>, <lon>, <alt>]
#
# .x() ... functions for reading cartesian coords (in m)
# .y()
# .z()
# .xyz() ... returns vector [<x>, <y>, <z>]
#
#
# QUERY METHODS:
#
# .is_defined() ... returns whether the coords are defined
# .dump() ... outputs coordinates
# .course_to(<coord>) ... returns course to another geo.Coord instance (degree)
# .distance_to(<coord>) ... returns distance in m along Earth curvature, ignoring altitudes
# useful for map distance
# .direct_distance_to(<coord>) ... distance in m direct, considers altitude,
# but cuts through Earth surface
# .greatcircle_distance_to(<coord>, <coord>) ... returns distance to a great circle (in m along Earth curvature)
# defined by two points
# .horizon() ... returns distance to the horizon in m along Earth curvature, ignoring altitudes
#
#
# MANIPULATION METHODS:
#
# .apply_course_distance(<course>, <distance>) ... moves the coord distance in meters in course direction (true)
#
#
#
#
# -------------------------------------------------------------------------------------------------
#
# geo.aircraft_position() ... returns current aircraft position as geo.Coord
# geo.viewer_position() ... returns viewer position as geo.Coord
# geo.click_position() ... returns last click coords as geo.Coord or nil before first click
#
# geo.tile_path(<lat>, <lon>) ... returns tile path string (e.g. "w130n30/w123n37/942056.stg")
# geo.elevation(<lat>, <lon> [, <top:10000>])
# ... returns elevation in meter for given lat/lon, or nil on error;
# <top> is the altitude at which the intersection test starts
#
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# geo.normdeg(<angle>) ... returns angle normalized to 0 <= angle < 360
# geo.normdeg180(<angle>) ... returns angle normalized to -180 < angle <= 360
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#
# geo.put_model(<path>, <lat>, <lon> [, <elev:nil> [, <hdg:0> [, <pitch:0> [, <roll:0>]]]]);
# ... put model <path> at location <lat>/<lon> with given elevation
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# (optional, default: surface). <hdg>/<pitch>/<roll> are optional
# and default to zero.
# geo.put_model(<path>, <coord> [, <hdg:0> [, <pitch:0> [, <roll:0>]]]);
# ... same as above, but lat/lon/elev are taken from a Coord object
var EPSILON = 1e-15;
var ERAD = 6378138.12; # Earth radius (m)
# class that maintains one set of geographical coordinates
#
var Coord = {
new: func(copy = nil) {
var m = { parents: [Coord] };
m._pdirty = 1; # polar
m._cdirty = 1; # cartesian
m._lat = nil; # in radian
m._lon = nil; #
m._alt = nil; # ASL
m._x = nil; # in m
m._y = nil;
m._z = nil;
if (copy != nil)
m.set(copy);
return m;
},
_cupdate: func {
me._cdirty or return;
var xyz = geodtocart(me._lat * R2D, me._lon * R2D, me._alt);
me._x = xyz[0];
me._y = xyz[1];
me._z = xyz[2];
me._cdirty = 0;
},
_pupdate: func {
me._pdirty or return;
var lla = carttogeod(me._x, me._y, me._z);
me._lat = lla[0] * D2R;
me._lon = lla[1] * D2R;
me._alt = lla[2];
me._pdirty = 0;
},
x: func { me._cupdate(); me._x },
y: func { me._cupdate(); me._y },
z: func { me._cupdate(); me._z },
xyz: func { me._cupdate(); [me._x, me._y, me._z] },
lat: func { me._pupdate(); me._lat * R2D }, # return in degree
lon: func { me._pupdate(); me._lon * R2D },
alt: func { me._pupdate(); me._alt },
latlon: func { me._pupdate(); [me._lat * R2D, me._lon * R2D, me._alt] },
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set_x: func(x) { me._cupdate(); me._pdirty = 1; me._x = x; me },
set_y: func(y) { me._cupdate(); me._pdirty = 1; me._y = y; me },
set_z: func(z) { me._cupdate(); me._pdirty = 1; me._z = z; me },
set_lat: func(lat) { me._pupdate(); me._cdirty = 1; me._lat = lat * D2R; me },
set_lon: func(lon) { me._pupdate(); me._cdirty = 1; me._lon = lon * D2R; me },
set_alt: func(alt) { me._pupdate(); me._cdirty = 1; me._alt = alt; me },
set: func(c) {
c._pupdate();
me._lat = c._lat;
me._lon = c._lon;
me._alt = c._alt;
me._cdirty = 1;
me._pdirty = 0;
me;
},
set_latlon: func(lat, lon, alt = 0) {
me._lat = lat * D2R;
me._lon = lon * D2R;
me._alt = alt;
me._cdirty = 1;
me._pdirty = 0;
me;
},
set_xyz: func(x, y, z) {
me._x = x;
me._y = y;
me._z = z;
me._pdirty = 1;
me._cdirty = 0;
me;
},
apply_course_distance: func(course, dist) {
me._pupdate();
course *= D2R;
dist /= ERAD;
if (dist < 0.0) {
dist = abs(dist);
course = course - math.pi;
}
me._lat = math.asin(math.sin(me._lat) * math.cos(dist)
+ math.cos(me._lat) * math.sin(dist) * math.cos(course));
if (math.cos(me._lat) > EPSILON)
me._lon = math.pi - math.mod(math.pi - me._lon
- math.asin(math.sin(course) * math.sin(dist)
/ math.cos(me._lat)), 2 * math.pi);
me._cdirty = 1;
me;
},
course_to: func(dest) {
me._pupdate();
dest._pupdate();
if (me._lat == dest._lat and me._lon == dest._lon)
return 0;
var dlon = dest._lon - me._lon;
var ret = nil;
call(func ret = math.mod(math.atan2(math.sin(dlon) * math.cos(dest._lat),
math.cos(me._lat) * math.sin(dest._lat)
- math.sin(me._lat) * math.cos(dest._lat)
* math.cos(dlon)), 2 * math.pi) * R2D, nil, var err = []);
if (size(err)) {
debug.printerror(err);
debug.dump(me._lat, me._lon, dlon, dest._lat, dest._lon, "--------------------------");
}
return ret;
},
# arc distance on an earth sphere; doesn't consider altitude
distance_to: func(dest) {
me._pupdate();
dest._pupdate();
if (me._lat == dest._lat and me._lon == dest._lon)
return 0;
var a = math.sin((me._lat - dest._lat) * 0.5);
var o = math.sin((me._lon - dest._lon) * 0.5);
return 2.0 * ERAD * math.asin(math.sqrt(a * a + math.cos(me._lat)
* math.cos(dest._lat) * o * o));
},
direct_distance_to: func(dest) {
me._cupdate();
dest._cupdate();
var dx = dest._x - me._x;
var dy = dest._y - me._y;
var dz = dest._z - me._z;
return math.sqrt(dx * dx + dy * dy + dz * dz);
},
# arc distance on an earth sphere to the great circle passing by A and B; doesn't consider altitude
greatcircle_distance_to: func(destA, destB) {
me._pupdate();
destA._pupdate();
destB._pupdate();
# AB is not a circle but a point
if (destA._lat == destB._lat and destA._lon == destB._lon) {
return me.distance_to(destA);
}
var ca1 = math.cos(destA._lon);
var cd1 = math.cos(destA._lat);
var sa1 = math.sin(destA._lon);
var sd1 = math.sin(destA._lat);
var ca2 = math.cos(destB._lon);
var cd2 = math.cos(destB._lat);
var sa2 = math.sin(destB._lon);
var sd2 = math.sin(destB._lat);
var sa12 = math.sin(destA._lon - destB._lon);
var ca3 = math.cos(me._lon);
var cd3 = math.cos(me._lat);
var sa3 = math.sin(me._lon);
var sd3 = math.sin(me._lat);
# this is sin(greatcircle_dist) * sin(arcAB)
var sDsAB = cd3 * sa3 * (ca2 * cd2 * sd1 - ca1 * cd1 * sd2 )
+ ca3 * cd3 * ( cd1 * sa1 * sd2 - cd2 * sa2 * sd1 )
- cd1 * cd2 * sd3 * sa12;
# direct calculation of sin(arcAB) to not call sin(arcsin(distance_to))
var a = math.sin((destA._lat - destB._lat) * 0.5);
var o = math.sin((destA._lon - destB._lon) * 0.5);
var hs12 = a * a + cd1 * cd2 * o * o;
var hc12 = 1.0 - hs12;
# AB is undertermined; a great circle should be defined with non-colinear vectors
if (hs12*hc12 == 0.0) {
die("Great circles are defined with non-colinear vectors");
}
return ERAD * math.abs( math.asin( 0.5 * sDsAB / math.sqrt( hs12 * hc12 ) ) );
},
# arc distance on an earth sphere to the horizon
horizon: func() {
me._pupdate();
if (me._alt < 0.0) {
return 0.0;
}
else {
return ERAD*math.acos(ERAD/(ERAD+me._alt));
}
},
is_defined: func {
return !(me._cdirty and me._pdirty);
},
dump: func {
if (me._cdirty and me._pdirty)
print("Coord.dump(): coordinates undefined");
me._cupdate();
me._pupdate();
printf("x=%f y=%f z=%f lat=%f lon=%f alt=%f",
me.x(), me.y(), me.z(), me.lat(), me.lon(), me.alt());
},
};
# normalize degree to 0 <= angle < 360
#
var normdeg = func(angle) {
while (angle < 0)
angle += 360;
while (angle >= 360)
angle -= 360;
return angle;
}
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# normalize degree to -180 < angle <= 180
#
var normdeg180 = func(angle) {
while (angle <= -180)
angle += 360;
while (angle > 180)
angle -= 360;
return angle;
}
var tile_index = func(lat, lon) {
return tileIndex(lat, lon);
}
var format = func(lat, lon) {
sprintf("%s%03d%s%02d", lon < 0 ? "w" : "e", abs(lon), lat < 0 ? "s" : "n", abs(lat));
}
var tile_path = func(lat, lon) {
var p = tilePath(lat, lon) ~ "/" ~ tileIndex(lat, lon) ~ ".stg";
}
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var put_model = func(path, c, arg...) {
call(_put_model, [path, nil] ~ (isa(c, Coord) ? c.latlon() : [c]) ~ arg);
}
var put_marker = func(label, c, arg...) {
if (isa(c, Coord)) {
call(_put_marker, [label] ~ c.latlon() ~ arg);
}
else {
call(_put_marker, [label, c] ~ arg);
}
}
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var _put_model = func(path, label, lat, lon, elev_m = nil, hdg = 0, pitch = 0, roll = 0) {
if (elev_m == nil)
elev_m = elevation(lat, lon);
if (elev_m == nil)
die("geo.put_model(): cannot get elevation for " ~ lat ~ "/" ~ lon);
fgcommand("add-model", var n = props.Node.new({ "path": path,
"latitude-deg": lat, "longitude-deg": lon, "elevation-m": elev_m,
"heading-deg": hdg, "pitch-deg": pitch, "roll-deg": roll,
}));
return props.globals.getNode(n.getNode("property").getValue());
}
var _put_marker = func(label, lat, lon, elev = nil, color = nil, text_height_m = 1, pin_height_m = 1000, pin_tip_height_m = 0) {
params = {
"internal-model": "marker",
"heading-deg": 0, "pitch-deg": 0, "roll-deg": 0,
"marker": {
"text": label,
"color": color,
"size": text_height_m,
"height": pin_height_m,
"tip-height": pin_tip_height_m,
},
};
if (isnum(lat)) {
params['latitude-deg'] = lat;
}
elsif (isscalar(lat)) {
params['latitude-deg-prop'] = lat;
}
if (isnum(lon)) {
params['longitude-deg'] = lon;
}
elsif (isscalar(lon)) {
params['longitude-deg-prop'] = lon;
}
if (isnum(elev)) {
params['elevation-ft'] = elev;
}
elsif (isscalar(elev)) {
params['elevation-ft-prop'] = elev;
}
if (color == nil)
color = [1, 1, 1];
fgcommand("add-model", var n = props.Node.new(params));
return props.globals.getNode(n.getNode("property").getValue());
}
var elevation = func(lat, lon, maxalt = 10000) {
var d = geodinfo(lat, lon, maxalt);
return d == nil ? nil : d[0];
}
var click_coord = Coord.new();
_setlistener("/sim/signals/click", func {
var lat = getprop("/sim/input/click/latitude-deg");
var lon = getprop("/sim/input/click/longitude-deg");
var elev = getprop("/sim/input/click/elevation-m");
click_coord.set_latlon(lat, lon, elev);
});
var click_position = func {
return click_coord.is_defined() ? Coord.new(click_coord) : nil;
}
var aircraft_position = func {
var lat = getprop("/position/latitude-deg");
var lon = getprop("/position/longitude-deg");
var alt = getprop("/position/altitude-ft") * FT2M;
return Coord.new().set_latlon(lat, lon, alt);
}
var viewer_position = func {
var x = getprop("/sim/current-view/viewer-x-m");
var y = getprop("/sim/current-view/viewer-y-m");
var z = getprop("/sim/current-view/viewer-z-m");
return Coord.new().set_xyz(x, y, z);
}
# A object to handle differential positioned searches:
# searchCmd executes and returns the actual search,
# onAdded and onRemoved are callbacks,
# and obj is a "me" reference (defaults to "me" in the
# caller's namespace). If searchCmd returns nil, nothing
# happens, i.e. the diff is cancelled.
var PositionedSearch = {
new: func(searchCmd, onAdded, onRemoved, obj=nil) {
return {
parents:[PositionedSearch],
obj: obj == nil ? caller(1)[0]["me"] : obj,
searchCmd: searchCmd,
onAdded: onAdded,
onRemoved: onRemoved,
result: [],
};
},
_equals: func(a,b) {
return a == b; # positioned objects are created once
#return (a == b or a.id == b.id);
},
condense: func(vec) {
var ret = [];
foreach (var e; vec)
if (e != nil) append(ret, e);
return ret;
},
diff: func(old, new) {
if (new == nil)
return [old, [], []];
var removed = old~[]; #copyvec
var added = new~[];
# Mark common elements from removed and added:
forindex (OUTER; var i; removed)
forindex (var j; new)
if (removed[i] != nil and added[j] != nil and me._equals(removed[i], added[j])) {
removed[i] = added[j] = nil;
continue OUTER;
}
# And remove those common elements, returning the result:
return [new, me.condense(removed), me.condense(added)];
},
update: func(searchCmd=nil) {
if (searchCmd == nil) searchCmd = me.searchCmd;
if (me._equals == PositionedSearch._equals) {
# Optimized search using C code
var old = me.result~[]; #copyvec
me.result = call(searchCmd, nil, me.obj);
if (me.result == nil)
{ me.result = old; return }
if (typeof(me.result) != 'vector') die("geo.PositionedSearch(): A searchCmd must return a vector of elements or nil !!"); # TODO: Maybe make this a hash instead to wrap a vector, so that we can implement basic type-checking - e.g. doing isa(PositionedSearchResult, me.result) would be kinda neat and could help troubleshooting
else
positioned.diff( old,
me.result,
func call(me.onAdded, arg, me.obj),
func call(me.onRemoved, arg, me.obj) );
} else {
(me.result, var removed, var added) = me.diff(me.result, call(searchCmd, nil, me.obj));
foreach (var e; removed)
call(me.onRemoved, [e], me.obj);
foreach (var e; added)
call(me.onAdded, [e], me.obj);
}
},
# this is the worst case scenario: switching from 640 to 320 (or vice versa)
test: func(from=640, to=320) {
var s= geo.PositionedSearch.new(
func positioned.findWithinRange(from, 'fix'),
func print('added:', arg[0].id),
func print('removed:', arg[0].id)
);
debug.benchmark('Toggle '~from~'nm/'~to~'nm', func {
s.update();
s.update( func positioned.findWithinRange(to, 'fix') );
}); # ~ takes
}, # of test
};