fgdata/Nasal/compat_layer.nas

########################################################
# compatibility layer for local weather package
# Thorsten Renk, July 2010
########################################################

# function			purpose
#
# setVisibility			to set the visibility to a given value
# setRain			to set rain to a given value
# setSnow			to set snow to a given value
# setTurbulence			to set turbulence to a given value
# setTemperature		to set temperature to a given value
# setPressure			to set pressure to a given value
# setDewpoint			to set the dewpoint to a given value
# setWind			to set wind
# setWindSmoothly 		to set the wind gradually across a second
# smooth_wind_loop		helper function for setWindSmoothly
# create_cloud			to place a single cloud into the scenery
# create_cloud_array		to place clouds from storage arrays into the scenery
# move_cloud			to move the cloud position
# remove_clouds			to remove clouds by tile index
# waiting_loop			to ensure tile removal calls do not overlap
# remove_tile_loop		to remove a fixed number of clouds per frame
# get_elevation			to get the terrain elevation at given coordinates
# get_elevation_vector		to get terrain elevation at given coordinate vector


####################################
# set visibility to given value
####################################

var setVisibility = func (vis) {

# this is a rather dirty workaround till a better solution becomes available
# essentially we update all entries in config and reinit environment

var entries_aloft = props.globals.getNode("environment/config/aloft", 1).getChildren("entry");
foreach (var e; entries_aloft) {
		e.getNode("visibility-m",1).setValue(vis);
		}

var entries_boundary = props.globals.getNode("environment/config/boundary", 1).getChildren("entry");
foreach (var e; entries_boundary) {
		e.getNode("visibility-m",1).setValue(vis);
		}
fgcommand("reinit", props.Node.new({subsystem:"environment"}));

}

####################################
# set rain to given value
####################################

var setRain = func (rain) {

# setting the lowest cloud layer to 30.000 ft is a workaround
# as rain is only created below that layer in default

setprop("environment/clouds/layer[0]/elevation-ft", 30000.0);
setprop("environment/metar/rain-norm",rain);

}

####################################
# set snow to given value
####################################

var setSnow = func (snow) {

# setting the lowest cloud layer to 30.000 ft is a workaround
# as snow is only created below that layer in default

setprop("environment/clouds/layer[0]/elevation-ft", 30000.0);
setprop("environment/metar/snow-norm",snow);
}


####################################
# set turbulence to given value
####################################

var setTurbulence = func (turbulence) {

# this is a rather dirty workaround till a better solution becomes available
# essentially we update all entries in config and reinit environment

var entries_aloft = props.globals.getNode("environment/config/aloft", 1).getChildren("entry");
foreach (var e; entries_aloft) {
		e.getNode("turbulence/magnitude-norm",1).setValue(turbulence);
		}

# turbulence is slightly reduced in boundary layers

var entries_boundary = props.globals.getNode("environment/config/boundary", 1).getChildren("entry");
var i = 1;
foreach (var e; entries_boundary) {
		e.getNode("turbulence/magnitude-norm",1).setValue(turbulence * 0.25*i);
		i = i + 1;
		}
fgcommand("reinit", props.Node.new({subsystem:"environment"}));

}


####################################
# set temperature to given value
####################################

var setTemperature = func (T) {

# this is a rather dirty workaround till a better solution becomes available
# essentially we update the entry in config and reinit environment

setprop(ec~"boundary/entry[0]/temperature-degc",T);
fgcommand("reinit", props.Node.new({subsystem:"environment"}));
}

####################################
# set pressure to given value
####################################

var setPressure = func (p) {

# this is a rather dirty workaround till a better solution becomes available
# essentially we update the entry in config and reinit environment

setprop(ec~"boundary/entry[0]/pressure-sea-level-inhg",p);
setprop(ec~"aloft/entry[0]/pressure-sea-level-inhg",p);
fgcommand("reinit", props.Node.new({subsystem:"environment"}));
}

####################################
# set dewpoint to given value
####################################

var setDewpoint = func (D) {

# this is a rather dirty workaround till a better solution becomes available
# essentially we update the entry in config and reinit environment

setprop(ec~"boundary/entry[0]/dewpoint-degc",D);
fgcommand("reinit", props.Node.new({subsystem:"environment"}));
}

###########################################################
# set wind to given direction and speed
###########################################################


var setWind = func (dir, speed) {

# this is a rather dirty workaround till a better solution becomes available
# essentially we update all entries in config and reinit environment

var entries_aloft = props.globals.getNode("environment/config/aloft", 1).getChildren("entry");
foreach (var e; entries_aloft) {
		e.getNode("wind-from-heading-deg",1).setValue(dir);
		e.getNode("wind-speed-kt",1).setValue(speed);
		}

var entries_boundary = props.globals.getNode("environment/config/boundary", 1).getChildren("entry");
foreach (var e; entries_boundary) {
		e.getNode("wind-from-heading-deg",1).setValue(dir);
		e.getNode("wind-speed-kt",1).setValue(speed);
		}

fgcommand("reinit", props.Node.new({subsystem:"environment"}));

}

###########################################################
# set wind smoothly to given direction and speed
# interpolating across several frames
###########################################################


var setWindSmoothly = func (dir, speed) {

var entries_aloft = props.globals.getNode("environment/config/aloft", 1).getChildren("entry");

var dir_old = entries_aloft[0].getNode("wind-from-heading-deg",1).getValue();
var speed_old = entries_aloft[0].getNode("wind-speed-kt",1).getValue();

var dir = dir * math.pi/180.0;
var dir_old = dir_old * math.pi/180.0;

var vx = speed * math.sin(dir);
var vx_old = speed_old * math.sin(dir_old);

var vy = speed * math.cos(dir);
var vy_old = speed_old * math.cos(dir_old);

smooth_wind_loop(vx,vy,vx_old, vy_old, 4, 4);

}


var smooth_wind_loop = func (vx, vy, vx_old, vy_old, counter, count_max) {

var time_delay = 0.9/count_max;

if (counter == 0) {return;}

var f = (counter -1)/count_max;

var vx_set = f * vx_old + (1-f) * vx;
var vy_set = f * vy_old + (1-f) * vy;

var speed_set = math.sqrt(vx_set * vx_set + vy_set * vy_set);
var dir_set = math.atan2(vx_set,vy_set) * 180.0/math.pi;

setWind(dir_set,speed_set);

settimer( func {smooth_wind_loop(vx,vy,vx_old,vy_old,counter-1, count_max); },time_delay);

}

###########################################################
# place a single cloud 
###########################################################

var create_cloud = func(path, lat, long, alt, heading) {

var tile_counter = getprop(lw~"tiles/tile-counter");

var n = props.globals.getNode("local-weather/clouds", 1);
var c = n.getChild("tile",tile_counter,1);

var cloud_number = n.getNode("placement-index").getValue();
		for (var i = cloud_number; 1; i += 1)
			if (c.getChild("cloud", i, 0) == nil)
				break;
	cl = c.getChild("cloud", i, 1);
	n.getNode("placement-index").setValue(i);


var model_number = n.getNode("model-placement-index").getValue();
var m = props.globals.getNode("models", 1);
		for (var i = model_number; 1; i += 1)
			if (m.getChild("model", i, 0) == nil)
				break;
	model = m.getChild("model", i, 1);
	n.getNode("model-placement-index").setValue(i);	



var latN = cl.getNode("position/latitude-deg", 1); latN.setValue(lat);
var lonN = cl.getNode("position/longitude-deg", 1); lonN.setValue(long);
var altN = cl.getNode("position/altitude-ft", 1); altN.setValue(alt);
var hdgN = cl.getNode("orientation/true-heading-deg", 1); hdgN.setValue(heading);
#var pitchN = cl.getNode("orientation/pitch-deg", 1); pitchN.setValue(0.0);
#var rollN = cl.getNode("orientation/roll-deg", 1);rollN.setValue(0.0);

cl.getNode("tile-index",1).setValue(tile_counter);

model.getNode("path", 1).setValue(path);
model.getNode("latitude-deg-prop", 1).setValue(latN.getPath());
model.getNode("longitude-deg-prop", 1).setValue(lonN.getPath());
model.getNode("elevation-ft-prop", 1).setValue(altN.getPath());
model.getNode("heading-deg-prop", 1).setValue(hdgN.getPath());
#model.getNode("pitch-deg-prop", 1).setValue(pitchN.getPath());
#model.getNode("roll-deg-prop", 1).setValue(rollN.getPath());
model.getNode("tile-index",1).setValue(tile_counter);
model.getNode("load", 1).remove();

n.getNode("cloud-number").setValue(n.getNode("cloud-number").getValue()+1);

# sort the model nodes into a vector

append(weather_tile_management.modelArrays[tile_counter-1],model);


# if weather dynamics is on, also create a timestamp property and sort into quadtree

if (getprop(lw~"config/dynamics-flag") == 1)
	{
	cl.getNode("timestamp-sec",1).setValue(weather_dynamics.time_lw);
	var blat = getprop(lw~"tiles/tmp/latitude-deg");
	var blon = getprop(lw~"tiles/tmp/longitude-deg");
	var alpha = getprop(lw~"tmp/tile-orientation-deg");
	#weather_dynamics.sort_into_quadtree(blat, blon, alpha, lat, long, weather_dynamics.cloudQuadtree, cl); 
	weather_dynamics.sort_into_quadtree(blat, blon, alpha, lat, long, weather_dynamics.cloudQuadtrees[tile_counter-1], cl); 
	}

}


###########################################################
# place a cloud layer from arrays, split across frames 
###########################################################

var create_cloud_array = func (i, clouds_path, clouds_lat, clouds_lon, clouds_alt, clouds_orientation) {

if (getprop(lw~"tmp/thread-status") != "placing") {return;}
if (getprop(lw~"tmp/convective-status") != "idle") {return;}
if ((i < 0) or (i==0)) 
	{
	print("Cloud placement from array finished!"); 
	setprop(lw~"tmp/thread-status", "idle");
	return;
	}


var k_max = 30;
var s = size(clouds_path);  

if (s < k_max) {k_max = s;}

for (var k = 0; k < k_max; k = k+1)
	{
	#print(s, " ", k, " ", s-k-1, " ", clouds_path[s-k-1]);
	#create_cloud(clouds_type[s-k-1], clouds_path[s-k-1], clouds_lat[s-k-1], clouds_lon[s-k-1], clouds_alt[s-k-1], 0.0, 0);
	create_cloud(clouds_path[s-k-1], clouds_lat[s-k-1], clouds_lon[s-k-1], clouds_alt[s-k-1], clouds_orientation[s-k-1]);
	}

setsize(clouds_path,s-k_max);
setsize(clouds_lat,s-k_max);
setsize(clouds_lon,s-k_max);
setsize(clouds_alt,s-k_max);
setsize(clouds_orientation,s-k_max);

settimer( func {create_cloud_array(i - k, clouds_path, clouds_lat, clouds_lon, clouds_alt, clouds_orientation ) }, 0 );
};


####################################################
# move a cloud
####################################################

var move_cloud = func (c, tile_index) {

# get the old spacetime position of the cloud

var lat_old = c.getNode("position/latitude-deg").getValue();
var lon_old = c.getNode("position/longitude-deg").getValue();
var alt = c.getNode("position/altitude-ft").getValue();
var timestamp = c.getNode("timestamp-sec").getValue();

# get windfield and time since last update

var windfield = weather_dynamics.get_windfield(tile_index);
var dt = weather_dynamics.time_lw - timestamp;

#print(dt * windfield[1]);

# update the spacetime position of the cloud

c.getNode("position/latitude-deg",1).setValue(lat_old + windfield[1] * dt * local_weather.m_to_lat);
c.getNode("position/longitude-deg",1).setValue(lon_old + windfield[0] * dt * local_weather.m_to_lon);
c.getNode("timestamp-sec",1).setValue(weather_dynamics.time_lw);

}


####################################################
# remove clouds by tile index
####################################################

var remove_clouds = func (index) {

var n = size(props.globals.getNode("local-weather/clouds").getChild("tile",index,1).getChildren("cloud"));
props.globals.getNode("local-weather/clouds", 1).removeChild("tile",index);
setprop(lw~"clouds/cloud-number",getprop(lw~"clouds/cloud-number")-n);

if (getprop(lw~"tmp/thread-flag") ==  1)
	{settimer( func {waiting_loop(index); },0);} 
else 
	{
	var modelNode = props.globals.getNode("models", 1).getChildren("model");
	foreach (var m; modelNode)
		{
		if (m.getNode("tile-index",1).getValue() == index) {m.remove();} 		
		}
	}


}



# this is to avoid two tile removal loops starting at the same time

var waiting_loop = func (index) {

var status = getprop(lw~"tmp/thread-status");

if (status == "idle") {remove_tile_loop(index);}

else 	{
	print("Removal of ",index, " waiting for idle thread...");
	settimer( func {waiting_loop(index); },1.0);
	}
}


var remove_tile_loop = func (index) {

var n = 100;

var flag_mod = 0;


var status = getprop(lw~"tmp/thread-status");

if ((status == "computing") or (status == "placing")) # the array is blocked
	{
	settimer( func {remove_tile_loop(index); },0); # try again next frame
	return;
	}
else if (status == "idle") # we initialize the loop
	{
	mvec = weather_tile_management.modelArrays[index-1];
	msize = size(mvec);
	setprop(lw~"tmp/last-reading-pos-mod", msize);
	setprop(lw~"tmp/thread-status", "removing"); 
	}

var lastpos = getprop(lw~"tmp/last-reading-pos-mod"); 


if (lastpos < (msize-1)) {var istart = lastpos;} else {var istart = (msize-1);}

if (istart<0) {istart=0;}

var i_min = istart - n;
if (i_min < -1) {i_min =-1;}

for (var i = istart; i > i_min; i = i- 1)
		{
		m = mvec[i];
		m.remove();
		}

if (i<0) {flag_mod = 1;}


if (flag_mod == 0) {setprop(lw~"tmp/last-reading-pos-mod",i); }

if (flag_mod == 0) # we still have work to do
	{settimer( func {remove_tile_loop(index); },0);}
else 
	{
	print("Tile deletion loop finished!");
	setprop(lw~"tmp/thread-status", "idle"); 
	setprop(lw~"clouds/placement-index",0);
	setprop(lw~"clouds/model-placement-index",0);
	setsize(weather_tile_management.modelArrays[index-1],0);
	}

}




###########################################################
# get terrain elevation
###########################################################

var get_elevation = func (lat, lon) {

var info = geodinfo(lat, lon);
	if (info != nil) {var elevation = info[0] * local_weather.m_to_ft;}
	else {var elevation = -1.0;}

return elevation;
}

###########################################################
# get terrain elevation vector
###########################################################

var get_elevation_array = func (lat, lon) {

var elevation = [];
var n = size(lat);

for(var i = 0; i < n; i=i+1)
	{
	append(elevation, get_elevation(lat[i], lon[i]));
	}

return elevation;
}



############################################################
# global variables
############################################################

# some common abbreviations

var lw = "/local-weather/";
var ec = "/environment/config/";

# storage arrays for model vector

var mvec = [];
var msize = 0;