mirror of
https://github.com/Ttanasart-pt/Pixel-Composer.git
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745 lines
17 KiB
Text
745 lines
17 KiB
Text
/// @macro {Struct.BBMOD_Vec3} A shorthand for `new BBMOD_Vec3(1, 0, 0)`.
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/// @see BBMOD_VEC3_RIGHT
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/// @see BBMOD_VEC3_UP
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/// @see BBMOD_Vec3
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#macro BBMOD_VEC3_FORWARD new BBMOD_Vec3(1.0, 0.0, 0.0)
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/// @macro {Struct.BBMOD_Vec3} A shorthand for `new BBMOD_Vec3(0, 1, 0)`.
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/// @see BBMOD_VEC3_FORWARD
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/// @see BBMOD_VEC3_UP
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/// @see BBMOD_Vec3
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#macro BBMOD_VEC3_RIGHT new BBMOD_Vec3(0.0, 1.0, 0.0)
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/// @macro {Struct.BBMOD_Vec3} A shorthand for `new BBMOD_Vec3(0, 0, 1)`.
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/// @see BBMOD_VEC3_RIGHT
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/// @see BBMOD_VEC3_FORWARD
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/// @see BBMOD_Vec3
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#macro BBMOD_VEC3_UP new BBMOD_Vec3(0.0, 0.0, 1.0)
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/// @func BBMOD_Vec3([_x[, _y, _z]])
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///
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/// @desc A 3D vector.
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///
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/// @param {Real} [_x] The first component of the vector. Defaults to 0.
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/// @param {Real} [_y] The second component of the vector. Defaults to `_x`.
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/// @param {Real} [_z] The third component of the vector. Defaults to `_x`.
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///
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/// @see BBMOD_Vec2
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/// @see BBMOD_Vec4
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function BBMOD_Vec3(_x=0.0, _y=_x, _z=_x) constructor {
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if(is_instanceof(_x, __vec3)) {
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X = _x.x;
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Y = _x.y;
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Z = _x.z;
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} else if(is_instanceof(_x, BBMOD_Vec3)) {
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X = _x.X;
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Y = _x.Y;
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Z = _x.Z;
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} else if(is_array(_x)) {
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X = _x[0];
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Y = _x[1];
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Z = _x[2];
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} else {
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X = _x;
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Y = _y;
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Z = _z;
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}
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/// @func Abs()
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///
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/// @desc Creates a new vector where each component is equal to the absolute
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/// value of the original component.
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///
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/// @return {Struct.BBMOD_Vec3} The created vector.
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///
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/// @example
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/// ```gml
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/// new BBMOD_Vec3(-1.0, 2.0, -3.0).Abs() // => BBMOD_Vec3(1.0, 2.0, 3.0)
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/// ```
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static Abs = function () {
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INLINE
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return new BBMOD_Vec3(
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abs(X),
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abs(Y),
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abs(Z)
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);
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};
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/// @func Add(_v)
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///
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/// @desc Adds vectors and returns the result as a new vector.
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///
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/// @param {Struct.BBMOD_Vec3} _v The other vector.
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///
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/// @return {Struct.BBMOD_Vec3} The created vector.
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static Add = function (_v) {
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INLINE
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return new BBMOD_Vec3(
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X + _v.X,
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Y + _v.Y,
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Z + _v.Z
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);
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};
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/// @func Ceil()
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///
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/// @desc Applies function `ceil` to each component of the vector and returns
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/// the result as a new vector.
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///
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/// @return {Struct.BBMOD_Vec3} The created vector.
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///
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/// @example
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/// ```gml
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/// new BBMOD_Vec3(0.2, 1.6, 2.4).Ceil() // => BBMOD_Vec3(1.0, 2.0, 3.0)
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/// ```
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static Ceil = function () {
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INLINE
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return new BBMOD_Vec3(
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ceil(X),
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ceil(Y),
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ceil(Z)
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);
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};
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/// @func Clamp(_min, _max)
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///
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/// @desc Clamps each component of the vector between corresponding
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/// components of `_min` and `_max` and returns the result as a new vector.
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///
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/// @param {Struct.BBMOD_Vec3} _min A vector with minimum components.
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/// @param {Struct.BBMOD_Vec3} _max A vector with maximum components.
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///
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/// @return {Struct.BBMOD_Vec3} The resulting vector.
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static Clamp = function (_min, _max) {
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INLINE
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return new BBMOD_Vec3(
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clamp(X, _min.X, _max.X),
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clamp(Y, _min.Y, _max.Y),
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clamp(Z, _min.Z, _max.Z)
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);
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};
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/// @func ClampLength(_min, _max)
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///
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/// @desc Clamps the length of the vector between `_min` and `_max` and
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/// returns the result as a new vector.
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///
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/// @param {Real} _min The minimum length of the vector.
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/// @param {Real} _max The maximum length of the vector.
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///
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/// @return {Struct.BBMOD_Vec3} The created vector.
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///
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/// @example
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/// ```gml
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/// // => BBMOD_Vec3(3.0, 0.0, 0.0):
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/// new BBMOD_Vec3(3.0, 0.0, 0.0).ClampLength(1.0, 5.0)
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/// // => BBMOD_Vec3(4.0, 0.0, 0.0):
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/// new BBMOD_Vec3(3.0, 0.0, 0.0).ClampLength(4.0, 5.0)
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/// // => BBMOD_Vec3(2.0, 0.0, 0.0):
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/// new BBMOD_Vec3(3.0, 0.0, 0.0).ClampLength(1.0, 2.0)
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/// ```
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static ClampLength = function (_min, _max) {
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INLINE
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var _length = sqrt(
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X * X
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+ Y * Y
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+ Z * Z
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);
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var _newLength = clamp(_length, _min, _max);
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return new BBMOD_Vec3(
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(X / _length) * _newLength,
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(Y / _length) * _newLength,
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(Z / _length) * _newLength
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);
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};
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/// @func Clone()
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///
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/// @desc Creates a clone of the vector.
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///
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/// @return {Struct.BBMOD_Vec3} The creted vector.
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static Clone = function () {
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INLINE
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return new BBMOD_Vec3(
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X,
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Y,
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Z
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);
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};
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/// @func Copy(_dest)
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///
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/// @desc Copies components of the vector to the `_dest` vector.
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///
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/// @param {Struct.BBMOD_Vec3} _dest The destination vector.
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///
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/// @return {Struct.BBMOD_Vec3} Returns `self`.
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///
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/// @example
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/// ```gml
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/// var _v1 = new BBMOD_Vec3(1.0, 2.0, 3.0);
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/// var _v2 = new BBMOD_Vec3(4.0, 5.0, 6.0);
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/// show_debug_message(_v2) // Prints { X: 4.0, Y: 5.0, Z: 6.0 }
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/// _v1.Copy(_v2);
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/// show_debug_message(_v2) // Prints { X: 1.0, Y: 2.0, Z: 3.0 }
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/// ```
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static Copy = function (_dest) {
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INLINE
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_dest.X = X;
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_dest.Y = Y;
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_dest.Z = Z;
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return self;
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};
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/// @func Cross(_v)
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///
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/// @desc Computes a cross product of this vector and vector `_v` and returns
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/// the result as a new vector.
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///
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/// @param {Struct.BBMOD_Vec3} _v The other vector.
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///
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/// @return {Struct.BBMOD_Vec3} The created vector.
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static Cross = function (_v) {
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INLINE
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return new BBMOD_Vec3(
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Y * _v.Z - Z * _v.Y,
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Z * _v.X - X * _v.Z,
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X * _v.Y - Y * _v.X
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);
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};
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/// @func Dot(_v)
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///
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/// @desc Computes the dot product of this vector and vector `_v`.
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///
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/// @param {Struct.BBMOD_Vec3} _v The other vector.
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///
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/// @return {Real} The dot product of this vector and vector `_v`.
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static Dot = function (_v) {
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INLINE
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return (
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X * _v.X
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+ Y * _v.Y
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+ Z * _v.Z
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);
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};
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/// @func Equals(_v)
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///
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/// @desc Checks whether this vectors equals to vector `_v`.
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///
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/// @param {Struct.BBMOD_Vec3} _v The vector to compare to.
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///
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/// @return {Bool} Returns `true` if the two vectors are equal.
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static Equals = function (_v) {
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INLINE
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return (
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X == _v.X
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&& Y == _v.Y
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&& Z == _v.Z
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);
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};
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/// @func Floor()
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///
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/// @desc Applies function `floor` to each component of the vector and returns
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/// the result as a new vector.
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///
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/// @return {Struct.BBMOD_Vec3} The created vector.
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///
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/// @example
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/// ```gml
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/// new BBMOD_Vec3(0.2, 1.6, 2.4).Floor() // => BBMOD_Vec3(0.0, 1.0, 2.0)
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/// ```
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static Floor = function () {
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INLINE
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return new BBMOD_Vec3(
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floor(X),
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floor(Y),
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floor(Z)
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);
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};
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/// @func Frac()
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///
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/// @desc Applies function `frac` to each component of the vector and returns
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/// the result as a new vector.
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///
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/// @return {Struct.BBMOD_Vec3} The created vector.
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///
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/// @example
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/// ```gml
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/// new BBMOD_Vec3(0.2, 1.6, 2.4).Frac() // => BBMOD_Vec3(0.2, 0.6, 0.4)
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/// ```
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static Frac = function () {
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INLINE
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return new BBMOD_Vec3(
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frac(X),
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frac(Y),
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frac(Z)
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);
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};
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/// @func FromArray(_array[, _index])
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///
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/// @desc Loads vector components from an array.
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///
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/// @param {Array<Real>} _array The array to read the components from.
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/// @param {Real} [_index] The index to start reading the vector components
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/// from. Defaults to 0.
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///
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/// @return {Struct.BBMOD_Vec3} Returns `self`.
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static FromArray = function (_array, _index=0) {
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INLINE
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X = _array[_index];
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Y = _array[_index + 1];
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Z = _array[_index + 2];
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return self;
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};
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/// @func FromBarycentric(_v1, _v2, _v3, _f, _g)
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///
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/// @desc Computes the vector components using a formula
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/// `_v1 + _f * (_v2 - _v1) + _g * (_v3 - _v1)`.
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///
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/// @param {Struct.BBMOD_Vec3} _v1 The first point of a triangle.
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/// @param {Struct.BBMOD_Vec3} _v2 The second point of a triangle.
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/// @param {Struct.BBMOD_Vec3} _v3 The third point of a triangle.
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/// @param {Real} _f The weighting factor between `_v1` and `_v2`.
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/// @param {Real} _g The weighting factor between `_v1` and `_v3`.
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///
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/// @return {Struct.BBMOD_Vec3} Returns `self`.
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static FromBarycentric = function (_v1, _v2, _v3, _f, _g) {
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INLINE
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var _v1X = _v1.X;
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var _v1Y = _v1.Y;
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var _v1Z = _v1.Z;
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X = _v1X + _f * (_v2.X - _v1X) + _g * (_v3.X - _v1X);
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Y = _v1Y + _f * (_v2.Y - _v1Y) + _g * (_v3.Y - _v1Y);
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Z = _v1Z + _f * (_v2.Z - _v1Z) + _g * (_v3.Z - _v1Z);
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return self;
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};
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/// @func FromBuffer(_buffer, _type)
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///
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/// @desc Loads vector components from a buffer.
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///
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/// @param {Id.Buffer} _buffer The buffer to read the components from.
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/// @param {Constant.BufferDataType} _type The type of each component.
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///
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/// @return {Struct.BBMOD_Vec3} Returns `self`.
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static FromBuffer = function (_buffer, _type) {
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INLINE
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X = buffer_read(_buffer, _type);
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Y = buffer_read(_buffer, _type);
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Z = buffer_read(_buffer, _type);
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return self;
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};
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/// @func Length()
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///
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/// @desc Computes the length of the vector.
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///
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/// @return {Real} The length of the vector.
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static Length = function () {
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INLINE
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return sqrt(
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X * X
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+ Y * Y
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+ Z * Z
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);
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};
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/// @func LengthSqr()
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///
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/// @desc Computes a squared length of the vector.
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///
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/// @return {Real} The squared length of the vector.
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static LengthSqr = function () {
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INLINE
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return (
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X * X
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+ Y * Y
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+ Z * Z
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);
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};
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/// @func Lerp(_v, _amount)
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///
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/// @desc Linearly interpolates between vector `_v` by the given amount.
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///
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/// @param {Struct.BBMOD_Vec3} _v The vector to interpolate with.
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/// @param {Real} _amount The interpolation factor.
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static Lerp = function (_v, _amount) {
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INLINE
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return new BBMOD_Vec3(
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lerp(X, _v.X, _amount),
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lerp(Y, _v.Y, _amount),
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lerp(Z, _v.Z, _amount)
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);
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};
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/// @func MaxComponent()
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///
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/// @desc Computes the greatest component of the vector.
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///
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/// @return {Real} The greates component of the vector.
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static MaxComponent = function () {
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INLINE
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return max(
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X,
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Y,
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Z,
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);
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};
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/// @func Maximize(_v)
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///
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/// @desc Creates a new vector where each component is the maximum component
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/// from this vector and vector `_v`.
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///
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/// @param {Struct.BBMOD_Vec3} _v The other vector.
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///
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/// @return {Struct.BBMOD_Vec3} The created vector.
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///
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/// @example
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/// ```gml
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/// var _v1 = new BBMOD_Vec3(1.0, 4.0, 5.0);
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/// var _v2 = new BBMOD_Vec3(2.0, 3.0, 6.0);
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/// var _vMax = _v1.Maximize(_v2); // Equals to BBMOD_Vec3(2.0, 4.0, 6.0)
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/// ```
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static Maximize = function (_v) {
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INLINE
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return new BBMOD_Vec3(
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max(X, _v.X),
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max(Y, _v.Y),
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max(Z, _v.Z)
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);
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};
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/// @func MinComponent()
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///
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/// @desc Computes the smallest component of the vector.
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///
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/// @return {Real} The smallest component of the vector.
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static MinComponent = function () {
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INLINE
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return min(
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X,
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Y,
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Z,
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);
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};
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/// @func Minimize(_v)
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///
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/// @desc Creates a new vector where each component is the minimum component
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/// from this vector and vector `_v`.
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///
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/// @param {Struct.BBMOD_Vec3} _v The other vector.
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///
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/// @return {Struct.BBMOD_Vec3} The created vector.
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///
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/// @example
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/// ```gml
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/// var _v1 = new BBMOD_Vec3(1.0, 4.0, 5.0);
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/// var _v2 = new BBMOD_Vec3(2.0, 3.0, 6.0);
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/// var _vMin = _v1.Minimize(_v2); // Equals to BBMOD_Vec3(1.0, 3.0, 5.0)
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/// ```
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static Minimize = function (_v) {
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INLINE
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return new BBMOD_Vec3(
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min(X, _v.X),
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min(Y, _v.Y),
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min(Z, _v.Z)
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);
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};
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/// @func Mul(_v)
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///
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/// @desc Multiplies the vector with vector `_v` and returns the result
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/// as a new vector.
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///
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/// @param {Struct.BBMOD_Vec3} _v The other vector.
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///
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/// @return {Struct.BBMOD_Vec3} The created vector.
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static Mul = function (_v) {
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INLINE
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return new BBMOD_Vec3(
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X * _v.X,
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Y * _v.Y,
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Z * _v.Z
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);
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};
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/// @func Normalize()
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///
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/// @desc Normalizes the vector and returns the result as a new vector.
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///
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/// @return {Struct.BBMOD_Vec3} The created vector.
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static Normalize = function () {
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INLINE
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var _lengthSqr = (
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X * X
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+ Y * Y
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+ Z * Z
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);
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if (_lengthSqr >= math_get_epsilon())
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{
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var _n = 1.0 / sqrt(_lengthSqr);
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return new BBMOD_Vec3(
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X * _n,
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Y * _n,
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Z * _n
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);
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}
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return new BBMOD_Vec3(
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X,
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Y,
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Z
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);
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};
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/// @func Orthonormalize(_v)
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///
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/// @desc Orthonormalizes the vectors in-place using the Gram–Schmidt process.
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///
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/// @param {Struct.BBMOD_Vec3} _v The other vector.
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///
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/// @return {Bool} Returns `true` if the vectors were orthonormalized.
|
||
static Orthonormalize = function (_v) {
|
||
INLINE
|
||
|
||
var _v1 = Normalize();
|
||
var _proj = _v1.Scale(_v.Dot(_v1));
|
||
var _v2 = _v.Sub(_proj);
|
||
|
||
if (_v2.Length() <= 0.0)
|
||
{
|
||
return false;
|
||
}
|
||
|
||
_v1.Copy(self);
|
||
_v2.Normalize().Copy(_v);
|
||
|
||
return true;
|
||
};
|
||
|
||
/// @func Reflect(_v)
|
||
///
|
||
/// @desc Reflects the vector from vector `_v` and returns the result
|
||
/// as a new vector.
|
||
///
|
||
/// @param {Struct.BBMOD_Vec3} _v The vector to reflect from.
|
||
///
|
||
/// @return {Struct.BBMOD_Vec3} The created vector.
|
||
static Reflect = function (_v) {
|
||
INLINE
|
||
var _dot2 = (
|
||
X * _v.X
|
||
+ Y * _v.Y
|
||
+ Z * _v.Z
|
||
) * 2.0;
|
||
return new BBMOD_Vec3(
|
||
X - (_dot2 * _v.X),
|
||
Y - (_dot2 * _v.Y),
|
||
Z - (_dot2 * _v.Z)
|
||
);
|
||
};
|
||
|
||
/// @func Round()
|
||
///
|
||
/// @desc Applies function `round` to each component of the vector and returns
|
||
/// the result as a new vector.
|
||
///
|
||
/// @return {Struct.BBMOD_Vec3} The created vector.
|
||
///
|
||
/// @example
|
||
/// ```gml
|
||
/// new BBMOD_Vec3(0.2, 1.6, 2.4).Round() // => BBMOD_Vec3(0.0, 2.0, 2.0)
|
||
/// ```
|
||
static Round = function () {
|
||
INLINE
|
||
return new BBMOD_Vec3(
|
||
round(X),
|
||
round(Y),
|
||
round(Z)
|
||
);
|
||
};
|
||
|
||
/// @func Scale(_s)
|
||
///
|
||
/// @desc Scales each component of the vector by `_s` and returns the result
|
||
/// as a new vector.
|
||
///
|
||
/// @param {Real} _s The value to scale the components by.
|
||
///
|
||
/// @return {Struct.BBMOD_Vec3} The created vector.
|
||
///
|
||
/// @example
|
||
/// ```gml
|
||
/// new BBMOD_Vec3(1.0, 2.0, 3.0).Scale(2.0) // => BBMOD_Vec3(2.0, 4.0, 6.0)
|
||
/// ```
|
||
static Scale = function (_s) {
|
||
gml_pragma("forceinline")
|
||
return new BBMOD_Vec3(
|
||
X * _s,
|
||
Y * _s,
|
||
Z * _s
|
||
);
|
||
};
|
||
|
||
/// @func Get(_index)
|
||
///
|
||
/// @desc Retrieves vector component at given index (0 is X, 1 is Y, etc.).
|
||
///
|
||
/// @param {Real} _index The index of the component.
|
||
///
|
||
/// @return {Real} The value of the vector component at given index.
|
||
///
|
||
/// @throws {BBMOD_OutOfRangeException} If an invalid index is passed.
|
||
static Get = function (_index) {
|
||
INLINE
|
||
switch (_index)
|
||
{
|
||
case 0:
|
||
return X;
|
||
|
||
case 1:
|
||
return Y;
|
||
|
||
case 2:
|
||
return Z;
|
||
}
|
||
throw new BBMOD_OutOfRangeException();
|
||
};
|
||
|
||
/// @func Set([_x[, _y, _z]])
|
||
///
|
||
/// @desc Sets vector components in-place.
|
||
///
|
||
/// @param {Real} [_x] The new value of the first component. Defaults to 0.
|
||
/// @param {Real} [_y] The new value of the second component. Defaults to `_x`.
|
||
/// @param {Real} [_z] The new value of the third component. Defaults to `_x`.
|
||
///
|
||
/// @return {Struct.BBMOD_Vec3} Returns `self`.
|
||
static Set = function (_x=0.0, _y=_x, _z=_x) {
|
||
INLINE
|
||
X = _x;
|
||
Y = _y;
|
||
Z = _z;
|
||
return self;
|
||
};
|
||
|
||
/// @func SetIndex(_index, _value)
|
||
///
|
||
/// @desc Sets vector component in-place.
|
||
///
|
||
/// @param {Real} _index The index of the component, starting at 0.
|
||
/// @param {Real} _value The new value of the component.
|
||
///
|
||
/// @return {Struct.BBMOD_Vec3} Returns `self`.
|
||
///
|
||
/// @throws {BBMOD_OutOfRangeException} If the given index is out of range
|
||
/// of possible values.
|
||
static SetIndex = function (_index, _value) {
|
||
INLINE
|
||
switch (_index)
|
||
{
|
||
case 0:
|
||
X = _value;
|
||
break;
|
||
|
||
case 1:
|
||
Y = _value;
|
||
break;
|
||
|
||
case 2:
|
||
Z = _value;
|
||
break;
|
||
|
||
default:
|
||
throw new BBMOD_OutOfRangeException();
|
||
break;
|
||
}
|
||
return self;
|
||
};
|
||
|
||
/// @func Sub(_v)
|
||
///
|
||
/// @desc Subtracts vector `_v` from this vector and returns the result
|
||
/// as a new vector.
|
||
///
|
||
/// @param {Struct.BBMOD_Vec3} _v The vector to subtract from this one.
|
||
///
|
||
/// @return {Struct.BBMOD_Vec3} The created vector.
|
||
///
|
||
/// @example
|
||
/// ```gml
|
||
/// var _v1 = new BBMOD_Vec3(1.0, 2.0, 3.0);
|
||
/// var _v2 = new BBMOD_Vec3(4.0, 5.0, 6.0);
|
||
/// var _v3 = _v1.Sub(_v2); // Equals to BBMOD_Vec3(-3.0, -3.0, -3.0)
|
||
/// ```
|
||
static Sub = function (_v) {
|
||
gml_pragma("forceinline")
|
||
return new BBMOD_Vec3(
|
||
X - _v.X,
|
||
Y - _v.Y,
|
||
Z - _v.Z
|
||
);
|
||
};
|
||
|
||
/// @func ToArray([_array[, _index]])
|
||
///
|
||
/// @desc Writes the components of the vector into the target array.
|
||
///
|
||
/// @param {Array<Real>} [_array] The array to write to. If `undefined` a
|
||
/// new one of required size is created.
|
||
///
|
||
/// @param {Real} [_index] The starting index within the target array.
|
||
/// Defaults to 0.
|
||
///
|
||
/// @return {Array<Real>} The target array.
|
||
static ToArray = function (_array=undefined, _index=0) {
|
||
INLINE
|
||
_array ??= array_create(3, 0.0);
|
||
_array[@ _index] = X;
|
||
_array[@ _index + 1] = Y;
|
||
_array[@ _index + 2] = Z;
|
||
return _array;
|
||
};
|
||
|
||
/// @func ToBuffer(_buffer, _type)
|
||
///
|
||
/// @desc Writes the components of the vector into the buffer.
|
||
///
|
||
/// @param {Id.Buffer} _buffer The buffer to write to.
|
||
/// @param {Constant.BufferDataType} _type The type of the components.
|
||
///
|
||
/// @return {Struct.BBMOD_Vec3} Returns `self`.
|
||
static ToBuffer = function (_buffer, _type) {
|
||
INLINE
|
||
buffer_write(_buffer, _type, X);
|
||
buffer_write(_buffer, _type, Y);
|
||
buffer_write(_buffer, _type, Z);
|
||
return self;
|
||
};
|
||
|
||
/// @func Transform(_matrix)
|
||
///
|
||
/// @desc Transforms vector `(X, Y, Z, 1.0)` by a matrix and returns the result
|
||
/// as a new vector.
|
||
///
|
||
/// @param {Array<Real>} _matrix The matrix to transform the vector by.
|
||
///
|
||
/// @return {Struct.BBMOD_Vec3} The created vector.
|
||
static Transform = function (_matrix) {
|
||
gml_pragma("forceinline")
|
||
var _res = matrix_transform_vertex(_matrix, X, Y, Z);
|
||
return new BBMOD_Vec3(
|
||
_res[0],
|
||
_res[1],
|
||
_res[2]
|
||
);
|
||
};
|
||
}
|