#-------------------------------------------------------------------------------------------------- var oclock = func(bearing) int(0.5 + geo.normdeg(bearing) / 30) or 12; var tanker_msg = func setprop("sim/messages/ai-plane", call(sprintf, arg)); var pilot_msg = func setprop("/sim/messages/pilot", call(sprintf, arg)); var atc_msg = func setprop("sim/messages/atc", call(sprintf, arg)); var skip_cloud_layer = func(alt) { var c = []; foreach (var layer; props.globals.getNode("/environment/clouds").getChildren("layer")) { var elev = (layer.getNode("elevation-ft", 1).getValue() or -9999) * FT2M; var thck = (layer.getNode("thickness-ft", 1).getValue() or 0) * FT2M; if (elev > -1000) append(c, { bottom: elev - thck * 0.5 - 100, top: elev + thck * 0.5 + 100 }); } while (check; 1) { foreach (var layer; c) { if (alt > layer.bottom and alt < layer.top) { alt += 1000; continue check; } } return alt; } } var identity = { get: func { # return free AI id number and least used, free callsign/channel pair var data = {}; # copy of me.pool var revdata = {}; # channel->callsign foreach (var k; keys(me.pool)) { data[k] = me.pool[k]; revdata[me.pool[k][0]] = k; } var id_used = {}; foreach (var t; props.globals.getNode("ai/models", 1).getChildren()) { if ((var c = t.getNode("callsign")) != nil) delete(data, c.getValue() or ""); if ((var c = t.getNode("navaids/tacan/channel-ID")) != nil) delete(data, revdata[c.getValue() or ""]); if ((var c = t.getNode("id")) != nil and c.getValue() != ""){ var v = c.getValue(); if (v != nil and v != "") id_used[v] = 1; } } for (var aiid = -2; aiid; aiid -= 1) if (!id_used[aiid]) break; if (!size(data)) return [aiid, "MOBIL3", "062X"]; var d = sort(keys(data), func(a, b) data[a][1] - data[b][1])[0]; me.pool[d][1] += 1; return [aiid, d, data[d][0]]; }, pool: { ESSO1: ["040X", rand()], ESSO2: ["041X", rand()], ESSO3: ["042X", rand()], TEXACO1: ["050X", rand()], TEXACO2: ["051X", rand()], TEXACO3: ["052X", rand()], MOBIL1: ["060X", rand()], MOBIL2: ["061X", rand()], MOBIL3: ["062X", rand()], }, }; var replayTime = props.globals.getNode("sim/replay/time",1); var simTimeElapsedSec = props.globals.getNode("sim/time/elapsed-sec",1); var simTimeDeltaSec = props.globals.getNode("sim/time/delta-sec",1); var acHeading = props.globals.getNode("/orientation/heading-deg"); var acPitch = props.globals.getNode("/orientation/pitch-deg"); var acContactDist = props.globals.getNode("/systems/refuel/contact-radius-m"); var refuelOffsetX = props.globals.getNode("/systems/refuel/offset-x-m",1); var refuelOffsetY = props.globals.getNode("/systems/refuel/offset-y-m",1); var refuelOffsetZ = props.globals.getNode("/systems/refuel/offset-z-m",1); var acRoll = props.globals.getNode("/orientation/roll-deg"); var Tanker = { new: func(aiid, callsign, tacan, type, model, kias, maxfuel, pattern, contacts, heading, coord) { var m = { parents: [Tanker] }; m.callsign = callsign; m.tacan = tacan; m.kias = kias; m.heading = m.course = m.track_course = heading; m.out_of_range_time = 0; m.interval = 10; m.length = pattern; m.contacts = contacts; m.roll = 0; m.coord = geo.Coord.new(coord); m.anchor = geo.Coord.new(coord).apply_course_distance(m.track_course, m.length); # ARCP m.goal = [nil, m.anchor]; m.lastmode = "none"; m.mode = "leg"; m.rollrate = 2; # deg/s m.maxbank = 25; var n = props.globals.getNode("models", 1); for (var i = 0; 1; i += 1) if (n.getChild("model", i, 0) == nil) break; m.model = n.getChild("model", i, 1); var n = props.globals.getNode("ai/models", 1); for (var i = 0; 1; i += 1){ var cn = n.getChild("tanker", i, 0); if (cn == nil) break; if (cn.getNode("id") == nil or cn.getNode("id").getValue() == nil) break; } m.ai = n.getChild("tanker", i, 1); m.ai.getNode("id", 1).setIntValue(aiid); m.ai.getNode("callsign", 1).setValue(m.callsign ~ ""); m.ai.getNode("tanker", 1).setBoolValue(1); m.ai.getNode("valid", 1).setBoolValue(1); m.ai.getNode("navaids/tacan/channel-ID", 1).setValue(m.tacan); m.ai.getNode("refuel/type", 1).setValue(type); m.ai.getNode("refuel/max-fuel-transfer-lbs-min", 1).setValue(maxfuel); m.ai.getNode("refuel/contact", 1).setBoolValue(0); m.ai.getNode("radar/in-range", 1).setBoolValue(1); m.latN = m.ai.getNode("position/latitude-deg", 1); m.lonN = m.ai.getNode("position/longitude-deg", 1); m.altN = m.ai.getNode("position/altitude-ft", 1); m.hdgN = m.ai.getNode("orientation/true-heading-deg", 1); m.pitchN = m.ai.getNode("orientation/pitch-deg", 1); m.rollN = m.ai.getNode("orientation/roll-deg", 1); m.ktasN = m.ai.getNode("velocities/true-airspeed-kt", 1); m.vertN = m.ai.getNode("velocities/vertical-speed-fps", 1); m.rangeN = m.ai.getNode("radar/range-nm", 1); m.brgN = m.ai.getNode("radar/bearing-deg", 1); m.elevN = m.ai.getNode("radar/elevation-deg", 1); m.contactN = m.ai.getNode("refuel/contact", 1); m.hOffsetN = m.ai.getNode("radar/h-offset", 1); m.vOffsetN = m.ai.getNode("radar/v-offset", 1); m.update(); m.model.getNode("path", 1).setValue(model); m.model.getNode("latitude-deg-prop", 1).setValue(m.latN.getPath()); m.model.getNode("longitude-deg-prop", 1).setValue(m.lonN.getPath()); m.model.getNode("elevation-ft-prop", 1).setValue(m.altN.getPath()); m.model.getNode("heading-deg-prop", 1).setValue(m.hdgN.getPath()); m.model.getNode("pitch-deg-prop", 1).setValue(m.pitchN.getPath()); m.model.getNode("roll-deg-prop", 1).setValue(m.rollN.getPath()); m.model.getNode("load", 1).remove(); m.identify(); # notify any listeners that a new model has been added. setprop("/ai/models/model-added", m.ai.getPath()); return Tanker.active[m.callsign] = m; }, del: func { tanker_msg(me.callsign ~ " returns to base"); me.model.remove(); if (me.ai != nil){ me.ai.getChild("id").remove(); } else print(me.callsign," has no AI node"); me.ai = nil; # ensure that this tanker stops updating. delete(Tanker.active, me.callsign); }, update: func { if ( replayTime.getValue() > 0 ) return; var dt = simTimeDeltaSec.getValue(); var alt = me.coord.alt(); if (me.ai == nil){ print("Tamker ", me.callsign," stops updating"); return; } if ((me.interval += dt) >= 5) { me.interval -= 5; me.headwind = aircraft.wind_speed_from(me.course); me.ktas = aircraft.kias_to_ktas(me.kias, alt); } var distance = dt * (me.ktas - me.headwind) * NM2M / 3600; var deviation = me.roll ? dt * 1085.941 * math.tan(me.roll * D2R) / me.ktas : 0; if (me.mode == "leg") { if (me.lastmode != "leg") { me.lastmode = "leg"; # swap ARCP anchor and tanker exit point as leg end points var g = me.goal[0]; me.goal[0] = me.goal[1]; me.goal[1] = g; me.course = me.coord.course_to(me.goal[0]); me.leg_remaining = me.coord.distance_to(me.goal[0]); me.roll_target = 0; me.leg_warning = 0; } if ((me.leg_remaining -= distance) < 0) me.mode = "turn"; } else { # me.mode == "turn" if (me.lastmode != "turn") { me.lastmode = "turn"; me.full_bank_turn_angle = 0; me.turn_remaining = 180; me.roll_target = 25; } if (!me.full_bank_turn_angle and me.roll >= me.roll_target) me.full_bank_turn_angle = geo.normdeg(180 - me.turn_remaining); if (me.turn_remaining < me.full_bank_turn_angle) me.roll_target = 0; if ((me.turn_remaining -= deviation) < 0) { if (me.goal[1] == nil) # define tanker exit point (opposite of anchor point/ARCP) me.goal[1] = geo.Coord.new(me.coord).apply_course_distance(me.track_course - 180, me.length); me.mode = "leg"; } } me.coord.apply_course_distance(me.course -= deviation, distance); me.ac = geo.aircraft_position(); me.distance = me.ac.distance_to(me.coord); me.bearing = me.ac.course_to(me.coord); var dalt = alt - me.ac.alt(); var ac_hdg = acHeading.getValue(); var ac_pitch = acPitch.getValue(); var ac_contact_dist = acContactDist.getValue(); var elev = math.atan2(dalt, me.distance) * R2D; me.latN.setDoubleValue(me.coord.lat()); me.lonN.setDoubleValue(me.coord.lon()); me.altN.setDoubleValue(alt * M2FT); me.hdgN.setDoubleValue(me.heading = me.course); me.pitchN.setDoubleValue(0); me.rollN.setDoubleValue(-me.roll); me.ktasN.setDoubleValue(me.ktas); me.vertN.setDoubleValue(0); me.rangeN.setDoubleValue(me.distance * M2NM); me.brgN.setDoubleValue(me.bearing); me.elevN.setDoubleValue(elev); # Determine if any of the contact points are in contact var offset_x = 0; var offset_y = 0; var offset_z = 0; if (refuelOffsetX != nil) offset_x = refuelOffsetX.getValue() or 0; if (refuelOffsetY != nil) offset_y = refuelOffsetY.getValue() or 0; if (refuelOffsetZ != nil) offset_z = refuelOffsetZ.getValue() or 0; var roll = acRoll.getValue() * globals.D2R; # Determine contact position var probe_pos = geo.Coord.new(me.ac); probe_pos.apply_course_distance(ac_hdg, offset_x); probe_pos.apply_course_distance(ac_hdg + 90, offset_y * math.cos(roll) + offset_z * math.sin(roll)); probe_pos.set_alt(me.ac.alt() + offset_z * math.cos(roll) - offset_y * math.sin(roll)); me.contactN.setBoolValue(0); foreach (var c; me.contacts) { var drogue_pos = geo.Coord.new(me.coord); # Offset longitudonally drogue_pos.apply_course_distance(me.course, c.x); var r = me.roll * globals.D2R; # Offset laterally, taking into account any roll drogue_pos.apply_course_distance(me.course +90, c.y * math.cos(r) + c.z * math.sin(r)); # Offset vertically, again, taking into account any roll drogue_pos.set_alt(drogue_pos.alt() + c.z * math.cos(r) - c.y * math.sin(r)); #print("Distance: " ~ probe_pos.distance_to(drogue_pos) ~ " vs. " ~ me.distance); if (probe_pos.distance_to(drogue_pos) < ac_contact_dist and abs(view.normdeg(me.course - ac_hdg)) < 20) { # Contact! me.contactN.setBoolValue(1); } } me.hOffsetN.setDoubleValue(view.normdeg(me.bearing - ac_hdg)); me.vOffsetN.setDoubleValue(view.normdeg(elev - ac_pitch)); var droll = me.roll_target - me.roll; if (droll > 0) { me.roll += me.rollrate * dt; if (me.roll > me.roll_target) me.roll = me.roll_target; } elsif (droll < 0) { me.roll -= me.rollrate * dt; if (me.roll < me.roll_target) me.roll = me.roll_target; } if (!me.leg_warning and me.leg_remaining < NM2M) { tanker_msg(me.callsign ~ ", turn in one mile"); me.leg_warning = 1; } me.now = simTimeElapsedSec.getValue(); if (me.distance < 90000) me.out_of_range_time = me.now; elsif (me.now - me.out_of_range_time > 600) return me.del(); settimer(func me.update(), 0); }, identify: func { me.out_of_range_time = me.now; var alt = int((me.coord.alt() * M2FT + 50) / 100) * 100; tanker_msg("%s at %.0f, heading %.0f with %.0f knots, TACAN %s", me.callsign, alt, me.course, me.kias, me.tacan); }, report: func { me.out_of_range_time = me.now; var dist = int(me.distance * M2NM); var hdg = getprop("orientation/heading-deg"); var diff = (me.coord.alt() - me.ac.alt()) * M2FT; var qual = diff > 3000 ? " well" : abs(diff) > 1000 ? " slightly" : ""; var rel = diff > 1000 ? " above" : diff < -1000 ? " below" : ""; atc_msg("Tanker %s is at %s o'clock%s", me.callsign, oclock(me.ac.course_to(me.coord) - hdg), qual ~ rel); }, active: {}, }; # Factory methods # Create a tanker based on a given /sim/ai/tankers/tanker property node var create_tanker = func(tanker_node, course) { var (aiid, callsign, tacanid) =_= identity.get(); var model = tanker_node.getNode("model", 1).getValue(); var type = tanker_node.getNode("type", 1).getValue(); var spd = tanker_node.getNode("speed-kts", 1).getValue() or 250; var pattern = (tanker_node.getNode("pattern-length-nm", 1).getValue() or 50) * NM2M; var maxfuel = tanker_node.getNode("max-fuel-transfer-lbs-min", 1).getValue() or 6000; var contacts = []; foreach (var contact; tanker_node.getChildren("contact")) { var x = (contact.getNode("x-m") != nil) ? contact.getNode("x-m").getValue() : 0; var y = (contact.getNode("y-m") != nil) ? contact.getNode("y-m").getValue() : 0; var z = (contact.getNode("z-m") != nil) ? contact.getNode("z-m").getValue() : 0; append(contacts, { "x" : x, "y" : y, "z" : z }); } if (size(contacts) == 0) { append(contacts, {x: 0, y:0, z:0}); } var alt = int(10 + rand() * 15) * 1000; # FL100--FL250 alt = skip_cloud_layer(alt * FT2M); var dist = 6000 + rand() * 4000; var coord = geo.aircraft_position().apply_course_distance(course, dist).set_alt(alt); Tanker.new(aiid, callsign, tacanid, type, model, spd, maxfuel, pattern, contacts, course, coord); } # Request a new tanker var request_new = func(tanker_node=nil) { var tanker = values(Tanker.active); if (size(tanker)) tanker[0].del(); request(tanker_node); } var request = func(tanker_node=nil) { var tanker = values(Tanker.active); if (size(tanker)) return tanker[0].identify(); if (tanker_node == nil) { var type = props.globals.getNode("systems/refuel", 1).getChildren("type"); if (!size(type)) return; type = type[rand() * size(type)].getValue(); var tankers = props.globals.getNode("/sim/ai/tankers", 1).getChildren("tanker"); foreach (var tanker; tankers) { if (tanker.getNode("type", 1).getValue() == type) { tanker_node = tanker; break; } } } var hdg = getprop("orientation/heading-deg"); var course = hdg + (rand() - 0.5) * 60; create_tanker(tanker_node, course); } var request_random = func(tanker_node=nil) { var tanker = values(Tanker.active); if (size(tanker)) return tanker[0].identify(); if (tanker_node == nil) { var type = props.globals.getNode("systems/refuel", 1).getChildren("type"); if (!size(type)) return; type = type[rand() * size(type)].getValue(); var tankers = props.globals.getNode("/sim/ai/tankers", 1).getChildren("tanker"); foreach (var tanker; tankers) { if (tanker.getNode("type", 1).getValue() == type) { tanker_node = tanker; break; } } } var course = rand() * 360; create_tanker(tanker_node, course); } var report = func { var tanker = values(Tanker.active); if (size(tanker)) tanker[0].report(); } var reinit = func { foreach (var t; values(Tanker.active)) t.del(); } var aar_capable = size(props.globals.getNode("systems/refuel", 1).getChildren("type")); gui.menuEnable("tanker", aar_capable); if (!aar_capable) request = func { atc_msg("no tanker in range") }; # braces mandatory setlistener("/sim/signals/reinit", reinit, 1); if (globals["tanker"] != nil) { # reload with io.load_nasal(getprop("/sim/fg-root") ~ "/Nasal/tanker.nas"); print("reloading " ~ caller(0)[2]); var _setlistener = reinit; reinit(); }