#include "script_component.hpp" /* * Author: Ruthberg * Calculates the truing drop and updates the output fields * * Arguments: * parse input * * Return Value: * None * * Example: * call ace_atragmx_fnc_calculate_truing_drop * * Public: No */ private _parseInput = _this; private _transonicRange = GVAR(truingDropRangeData) select 0; private _subsonicRange = GVAR(truingDropRangeData) select 1; private _transonicDrop = GVAR(truingDropDropData) select 1; private _subsonicDrop = GVAR(truingDropDropData) select 2; if (_parseInput) then { _transonicRange = 0 max abs(parseNumber(ctrlText 18011)) min 4000; _subsonicRange = 0 max abs(parseNumber(ctrlText 18012)) min 4000; if (GVAR(currentUnit) != 2) then { _transonicRange = _transonicRange * 0.9144; _subsonicRange = _subsonicRange * 0.9144; }; _transonicRange = Round(_transonicRange); _subsonicRange = Round(_subsonicRange); _subsonicRange = _transonicRange max _subsonicRange; _transonicDrop = -100 max parseNumber(ctrlText 18013) min 100; _subsonicDrop = -100 max parseNumber(ctrlText 18014) min 100; private _dropUnit = GVAR(currentScopeUnit); if (_dropUnit == 3) then { switch (GVAR(currentScopeClickUnit)) do { case 0: { _dropUnit = 1; }; case 1: { _dropUnit = 2; }; case 2: { _dropUnit = 0; }; }; }; switch (_dropUnit) do { case 0: { _transonicDrop = MRAD_TO_MOA(_transonicDrop); _subsonicDrop = MRAD_TO_MOA(_subsonicDrop); }; case 2: { _transonicDrop = _transonicDrop / 1.047; _subsonicDrop = _subsonicDrop / 1.047; }; }; _transonicDrop = Round(_transonicDrop * 100) / 100; _subsonicDrop = Round(_subsonicDrop * 100) / 100; _subsonicDrop = _transonicDrop max _subsonicDrop; }; if ((GVAR(truingDropDropData) select 0) == 0 || {!([_transonicRange, _subsonicRange] isEqualTo GVAR(truingDropRangeData))}) then { if (isNil QGVAR(targetSolutionInput)) then { call FUNC(calculate_target_solution); }; private _solutionInput = +GVAR(targetSolutionInput); if (_transonicRange == 0) then { _transonicRange = Round(403 call FUNC(calculate_distance_at_velocity)); }; _solutionInput set [13, _transonicRange]; private _result1 = _solutionInput call FUNC(calculate_solution); _transonicDrop = Round((_result1 select 0) * 100) / 100; GVAR(truingDropRangeData) set [0, _transonicRange]; GVAR(truingDropDropData) set [1, _transonicDrop]; GVAR(truingDropReferenceDropData) set [0, _transonicDrop]; private _speedOfSound = (_solutionInput select 5) call EFUNC(weather,calculateSpeedOfSound); if (_subsonicRange == 0) then { _subsonicRange = _speedOfSound call FUNC(calculate_distance_at_velocity); if (GVAR(currentUnit) == 2) then { _subsonicRange = _subsonicRange + 200; } else { _subsonicRange = _subsonicRange + 200 * 1.0936133; }; _subsonicRange = Round(_subsonicRange); }; _solutionInput set [13, _subsonicRange]; private _result2 = _solutionInput call FUNC(calculate_solution); _subsonicDrop = Round((_result2 select 0) * 100) / 100; GVAR(truingDropRangeData) set [1, _subsonicRange]; GVAR(truingDropDropData) set [2, _subsonicDrop]; GVAR(truingDropReferenceDropData) set [1, _subsonicDrop]; } else { if (_transonicDrop != GVAR(truingDropDropData) select 1 || _subsonicDrop != GVAR(truingDropDropData) select 2) then { GVAR(truingDropDropData) set [1, _transonicDrop]; GVAR(truingDropDropData) set [2, _subsonicDrop]; if (GVAR(truingDropMode) == 0) then { call FUNC(true_muzzle_velocity); } else { call FUNC(true_c1_ballistic_coefficient); }; }; }; call FUNC(update_truing_drop_data);