Simple Expression

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Simple expressions are not as flexible as normal scripts, but they are compiled for a very efficient execution.

Available Operators

randomGen a	random value from 0 to a (randomGen 5)
randomGen expr	random value from 0 to expression value (randomGen daylight)
a factor [x,y]	`factor` is the same as `interpolate` only output range is fixed and capped to 0...1 (or 1...0 if input range is reversed) if x<y then a<x: 0, a>y: 1 if x>y then a>x: 0, a<y: 1
a interpolate [xFrom,xTo,resFrom,resTo]	Introduced in Arma 2 1.05. interpolate result based on input value. Equivalent to x factor [xFrom,xTo] * (resTo-resFrom) + resFrom
a min b	see min
a max b	see max
a - b	see a-b
a + b	see a+b
a * b	see a*b
a / b	see a/b (for A3, not sure if others)
abs a	see abs (introduced in Arma 3 patch 1.68)
x envelope [a,b,c,d]	trapezoid envelope with output <0;1> (substitution for "(v factor(a,b))*(v factor(d,c))" (Since Arma 3 1.67) envelope graph
a > b	see a > b. Returns 1 and 0 rather than true and false.
a < b	see a < b. Returns 1 and 0 rather than true and false.
a >= b	see a >= b. Returns 1 and 0 rather than true and false.
a <= b	see a <= b. Returns 1 and 0 rather than true and false.

Description: a,b can be any simple expression. x,y can be a constant expression only (i.e. expression with a type Number).

Since Arma 3 1.67 the following operators are also available (v ... controller value):

abs(v) - absolute value
sqr(v) - square value
sqrt(v) - square root value
pow(v, a) - power

SQF Equivalent of `factor`

SQF_fnc_factor = { private _fnc_interpolateCommon = { params ["_c", "_cMin", "_cMax", "_vMin", "_vMax"]; if (_c < _cMin) exitWith { _vMin }; if (_c > _cMax) exitWith { _vMax }; (_c - _cMin) * (1 / (_cMax - _cMin)) * (_vMax - _vMin) + _vMin }; params ["_c", "_cMin", "_cMax"]; if (_cMin < _cMax) then { [_c, _cMin, _cMax, 0, 1] call _fnc_interpolateCommon } else { [_c, _cMax, _cMin, 1, 0] call _fnc_interpolateCommon }; };

Example:

[0.2, 0.1, 0.7] call SQF_fnc_factor; // 0.166667

SQF Equivalent of `interpolate`

SQF_fnc_interpolate = { private _fnc_interpolateCommon = { params ["_c", "_cMin", "_cMax", "_vMin", "_vMax"]; if (_c < _cMin) exitWith { _vMin }; if (_c > _cMax) exitWith { _vMax }; (_c - _cMin) * (1 / (_cMax - _cMin)) * (_vMax - _vMin) + _vMin }; params ["_c", "_cMin", "_cMax", "_vMin", "_vMax"]; if (_cMin < _cMax) then { [_c, _cMin, _cMax, _vMin, _vMax] call _fnc_interpolateCommon } else { [_c, _cMax, _cMin, _vMax, _vMin] call _fnc_interpolateCommon }; };

Example:

[0.2, 0.1, 0.7, 0, 100] call SQF_fnc_interpolate; // 16.6667

SQF Equivalent of `envelope`

SQF_fnc_envelope = { private _fnc_interpolateCommon = { params ["_c", "_cMin", "_cMax", "_vMin", "_vMax"]; if (_c < _cMin) exitWith { _vMin }; if (_c > _cMax) exitWith { _vMax }; (_c - _cMin) * (1 / (_cMax - _cMin)) * (_vMax - _vMin) + _vMin }; params ["_x", "_a", "_b", "_c", "_d"]; private _ret = 0; if (_x > _a && _x < _d) then { private _v = [_x, _a, _b, 0, 1] call _fnc_interpolateCommon; if (_v > 0) then { _ret = _v * ([_x, _c, _d, 1, 0] call _fnc_interpolateCommon) }; }; _ret };

Example:

[0.5, 0.1, 0.3, 0.7, 0.9] call SQF_fnc_envelope; // 1