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- import raylib;
- import std.math;
- pragma(inline, true):
- version (unittest)
- {
- import fluent.asserts;
- }
- mixin template Linear()
- {
- import std.algorithm : canFind, map;
- import std.range : join;
- import std.traits : FieldNameTuple;
- private static alias T = typeof(this);
- static T zero()
- {
- enum fragment = [FieldNameTuple!T].map!(field => "0.").join(",");
- return mixin("T(" ~ fragment ~ ")");
- }
- static T one()
- {
- enum fragment = [FieldNameTuple!T].map!(field => "1.").join(",");
- return mixin("T(" ~ fragment ~ ")");
- }
- inout T opUnary(string op)() if (["+", "-"].canFind(op))
- {
- enum fragment = [FieldNameTuple!T].map!(field => op ~ field).join(",");
- return mixin("T(" ~ fragment ~ ")");
- }
- static if (is(T == Rotor3))
- {
- /// Returns a rotor equivalent to first apply p, then apply q
- inout Rotor3 opBinary(string op)(inout Rotor3 q) if (op == "*")
- {
- alias p = this;
- Rotor3 r;
- r.a = p.a * q.a - p.i * q.i - p.j * q.j - p.k * q.k;
- r.i = p.i * q.a + p.a * q.i + p.j * q.k - p.k * q.j;
- r.j = p.j * q.a + p.a * q.j + p.k * q.i - p.i * q.k;
- r.k = p.k * q.a + p.a * q.k + p.i * q.j - p.j * q.i;
- return r;
- }
- inout Vector3 opBinary(string op)(inout Vector3 v) if (op == "*")
- {
- Vector3 rv;
- rv.x = a * v.x + xy * v.y - zx * v.z;
- rv.y = a * v.y + yz * v.z - xy * v.x;
- rv.z = a * v.z + zx * v.x - yz * v.y;
- return rv;
- }
- inout Vector3 opBinaryRight(string op)(inout Vector3 v) if (op == "*")
- {
- Vector3 vr;
- vr.x = v.x * a - v.y * xy + v.z * zx;
- vr.y = v.y * a - v.z * yz + v.x * xy;
- vr.z = v.z * a - v.x * zx + v.y * yz;
- return vr;
- }
- }
- else
- {
- inout T opBinary(string op)(inout T rhs) if (["+", "-"].canFind(op))
- {
- enum fragment = [FieldNameTuple!T].map!(field => field ~ op ~ "rhs." ~ field).join(",");
- return mixin("T(" ~ fragment ~ ")");
- }
- }
- inout T opBinary(string op)(inout float rhs) if (["+", "-", "*", "/"].canFind(op))
- {
- enum fragment = [FieldNameTuple!T].map!(field => field ~ op ~ "rhs").join(",");
- return mixin("T(" ~ fragment ~ ")");
- }
- inout T opBinaryRight(string op)(inout float lhs) if (["+", "-", "*", "/"].canFind(op))
- {
- enum fragment = [FieldNameTuple!T].map!(field => "lhs" ~ op ~ field).join(",");
- return mixin("T(" ~ fragment ~ ")");
- }
- }
- unittest
- {
- Assert.equal(Vector2.init, Vector2.zero);
- Assert.equal(Vector2(), Vector2.zero);
- Assert.equal(-Vector2(1, 2), Vector2(-1, -2));
- auto a = Vector3(1, 2, 9);
- immutable b = Vector3(3, 4, 9);
- Vector3 c = a + b;
- Assert.equal(c, Vector3(4, 6, 18));
- Assert.equal(4.0f - Vector2.zero, Vector2(4, 4));
- Assert.equal(Vector2.one - 3.0f, Vector2(-2, -2));
- }
- import std.traits : FieldNameTuple;
- import std.algorithm : map;
- import std.range : join;
- float length(T)(T v)
- {
- enum fragment = [FieldNameTuple!T].map!(field => "v." ~ field ~ "*" ~ "v." ~ field).join("+");
- return mixin("sqrt(" ~ fragment ~ ")");
- }
- T normal(T)(T v)
- {
- return v / v.length;
- }
- float distance(T)(T lhs, T rhs)
- {
- return (lhs - rhs).length;
- }
- float dot(T)(T lhs, T rhs)
- {
- enum fragment = [FieldNameTuple!T].map!(field => "lhs." ~ field ~ "*" ~ "rhs." ~ field).join(
- "+");
- return mixin(fragment);
- }
- unittest
- {
- Assert.equal(Vector2(3, 4).length, 5);
- const a = Vector2(-3, 4);
- Assert.equal(a.normal, Vector2(-3. / 5., 4. / 5.));
- immutable b = Vector2(9, 8);
- Assert.equal(b.distance(Vector2(-3, 3)), 13);
- Assert.equal(Vector3(2, 3, 4).dot(Vector3(4, 5, 6)), 47);
- Assert.equal(Vector2.one.length, sqrt(2.0f));
- }
- unittest
- {
- Assert.equal(Rotor3(1, 2, 3, 4), Rotor3(1, Bivector3(2, 3, 4)));
- }
- /// Mix `amount` of `lhs` with `1-amount` of `rhs`
- /// `amount` should be between 0 and 1, but can be anything
- /// lerp(lhs, rhs, 0) == lhs
- /// lerp(lhs, rhs, 1) == rhs
- T lerp(T)(T lhs, T rhs, float amount)
- {
- return lhs + amount * (rhs - lhs);
- }
- /// angle betwenn vector and x-axis (+y +x -> positive)
- float angle(Vector2 v)
- {
- return atan2(v.y, v.x);
- }
- Vector2 rotate(Vector2 v, float angle)
- {
- return Vector2(v.x * cos(angle) - v.y * sin(angle), v.x * sin(angle) + v.y * cos(angle));
- }
- Vector2 slide(Vector2 v, Vector2 along)
- {
- return along.normal * dot(v, along);
- }
- Bivector2 wedge(Vector2 lhs, Vector2 rhs)
- {
- Bivector2 result = {xy: lhs.x * rhs.y - lhs.y * rhs.x};
- return result;
- }
- // dfmt off
- Bivector3 wedge(Vector3 lhs, Vector3 rhs)
- {
- Bivector3 result = {
- xy: lhs.x * rhs.y - lhs.y * rhs.x,
- yz: lhs.y * rhs.z - lhs.z * rhs.y,
- zx: lhs.z * rhs.x - lhs.x * rhs.z,
- };
- return result;
- }
- Vector3 transform(Vector3 v, Matrix4 mat)
- {
- with (v) with (mat)
- return Vector3(
- m0 * x + m4 * y + m8 * z + m12,
- m1 * x + m5 * y + m9 * z + m13,
- m2 * x + m6 * y + m10 * z + m14
- );
- }
- // dfmt on
- Vector3 cross(Vector3 lhs, Vector3 rhs)
- {
- auto v = wedge(lhs, rhs);
- return Vector3(v.yz, v.zx, v.xy);
- }
- unittest {
- // TODO
- }
- /// Returns a unit rotor that rotates `from` to `to`
- Rotor3 rotation(Vector3 from, Vector3 to)
- {
- return Rotor3(1 + dot(to, from), wedge(to, from)).normal;
- }
- Rotor3 rotation(float angle, Bivector3 plane)
- {
- return Rotor3(cos(angle / 2.0f), -sin(angle / 2.0f) * plane);
- }
- /// Rotate q by p
- Rotor3 rotate(Rotor3 p, Rotor3 q)
- {
- return p * q * p.reverse;
- }
- /// Rotate v by r
- Vector3 rotate(Rotor3 r, Vector3 v)
- {
- return r * v * r.reverse;
- }
- Rotor3 reverse(Rotor3 r)
- {
- return Rotor3(r.a, -r.b);
- }
- unittest
- {
- // TODO
- }
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