4 files changed, 136 insertions, 14 deletions
diff --git a/include/math/defs.h b/include/math/defs.h
index f67ee97..f572d8f 100644
--- a/include/math/defs.h
+++ b/include/math/defs.h
@@ -14,7 +14,7 @@ typedef double R;
 #define R_MIN DBL_MIN
 #define R_MAX DBL_MAX
 #else // floats
-typedef float       R;
+typedef float   R;
 #define R_MIN FLT_MIN
 #define R_MAX FLT_MAX
 #endif
@@ -29,13 +29,15 @@ typedef float       R;
 #define TO_DEG (180.0 / PI)
 #ifdef MATH_USE_DOUBLE
-static inline double min(R a, R b) { return fmin(a, b); }
+static inline R min(R a, R b) { return fmin(a, b); }
-static inline double max(R a, R b) { return fmax(a, b); }
+static inline R max(R a, R b) { return fmax(a, b); }
-static inline double rlog2(R a) { return log2(a); }
+static inline R rlog2(R a) { return log2(a); }
+static inline R rmod(R a, R m) { return fmodf(a, m); }
 #else // floats
-static inline float min(R a, R b) { return fminf(a, b); }
+static inline R min(R a, R b) { return fminf(a, b); }
-static inline float max(R a, R b) { return fmaxf(a, b); }
+static inline R max(R a, R b) { return fmaxf(a, b); }
-static inline float rlog2(R a) { return log2f(a); }
+static inline R rlog2(R a) { return log2f(a); }
+static inline R rmod(R a, R m) { return fmod(a, m); }
 #endif
 static inline R rabs(R x) { return x >= 0.0 ? x : -x; }
@@ -51,3 +53,4 @@ static inline R sign(R x) {
  }
 }
 static inline R lerp(R a, R b, R t) { return a + (b - a) * t; }
+static inline R R_eq(R a, R b, R eps) { return rabs(a - b) <= eps; }
diff --git a/include/math/quat.h b/include/math/quat.h
index b284567..a154044 100644
--- a/include/math/quat.h
+++ b/include/math/quat.h
@@ -4,23 +4,38 @@
 #include "mat4.h"
 #include "vec3.h"
+#include <assert.h>
 /// A quaternion.
 typedef struct quat {
-  R w, x, y, z;
+  R x, y, z, w;
 } quat;
+/// Return the unit/identity quaternion.
 static inline quat qunit() {
-  return (quat){.x = 0.0, .y = 0.0, .z = 0.0, .w = 0.0};
+  return (quat){.x = 0.0, .y = 0.0, .z = 0.0, .w = 1.0};
 }
+/// Construct a quaternion.
 static inline quat qmake(R x, R y, R z, R w) {
  return (quat){.x = x, .y = y, .z = z, .w = w};
 }
+/// Construct a quaternion from an array.
 static inline quat quat_from_array(const R xyzw[4]) {
  return (quat){.x = xyzw[0], .y = xyzw[1], .z = xyzw[2], .w = xyzw[3]};
 }
+/// Construct a quaternion from a 3D point.
+static inline quat quat_from_vec3(vec3 p) {
+  return (quat){.x = p.x, .y = p.y, .z = p.z, .w = 0.0};
+}
+/// Get a 3D point back from a quaternion.
+static inline vec3 vec3_from_quat(quat q) {
+  return (vec3){.x = q.x, .y = q.y, .z = q.z};
+}
 /// Construct a rotation quaternion.
 static inline quat qmake_rot(R angle, R x, R y, R z) {
  const R a   = angle * 0.5;
@@ -34,6 +49,11 @@ static inline quat qmake_rot(R angle, R x, R y, R z) {
  return (quat){x / mag, y / mag, z / mag, w};
 }
+/// Add two quaternions.
+static inline quat qadd(quat a, quat b) {
+  return (quat){.x = a.x + b.x, .y = a.y + b.y, .z = a.z + b.z, .w = a.w + b.w};
+}
 /// Multiply two quaternions.
 static inline quat qmul(quat q1, quat q2) {
  const R x = q1.w * q2.x + q1.x * q2.w + q1.y * q2.z - q1.z * q2.y;
@@ -61,6 +81,37 @@ static inline vec3 qrot(quat q, vec3 v) {
  return vec3_make(u.x, u.y, u.z);
 }
+/// Negate the quaternion.
+static inline quat qneg(quat q) {
+  return (quat){.x = -q.x, .y = -q.y, .z = -q.z, .w = -q.w};
+}
+/// Return the dot product of two quaternions.
+static inline R qdot(quat a, quat b) {
+  return a.x * b.x + a.y * b.y + a.z * b.z + a.w * b.w;
+}
+/// Return the quaternion's magnitude.
+static inline R qnorm(quat q) {
+  return sqrt(q.x * q.x + q.y * q.y + q.z * q.z + q.w * q.w);
+}
+/// Return the quaternion's squared magnitude.
+static inline R qnorm2(quat q) {
+  return q.x * q.x + q.y * q.y + q.z * q.z + q.w * q.w;
+}
+/// Normalize the quaternion.
+static inline quat qnormalize(quat q) {
+  const R n = qnorm(q);
+  return (quat){.x = q.x / n, .y = q.y / n, .z = q.z / n, .w = q.w / n};
+}
+/// Scale the quaternion.
+static inline quat qscale(quat q, R s) {
+  return (quat){.x = s * q.x, .y = s * q.y, .z = s * q.z, .w = s * q.w};
+}
 /// Get a 4x4 rotation matrix from a quaternion.
 static inline mat4 mat4_from_quat(quat q) {
  const R xx = q.x * q.x;
@@ -77,3 +128,35 @@ static inline mat4 mat4_from_quat(quat q) {
      1 - 2 * xx - 2 * zz, 2 * yz - 2 * wx, 0, 2 * xz - 2 * wy, 2 * yz + 2 * wx,
      1 - 2 * xx - 2 * yy, 0, 0, 0, 0, 1);
 }
+/// Interpolate two unit quaternions using spherical linear interpolation.
+///
+/// Note: You might want to normalize the result.
+static inline quat qslerp(quat a, quat b, R t) {
+  assert(0.0 <= t);
+  assert(t <= 1.0);
+  const R eps = 1e-5;
+  (void)eps;
+  assert(R_eq(qnorm2(a), 1.0, eps));
+  assert(R_eq(qnorm2(b), 1.0, eps));
+  R dot = qdot(a, b);
+  // Make the rotation path follow the "short way", i.e., ensure that:
+  // -90 <= angle <= 90
+  if (dot < 0.0) {
+    dot = -dot;
+    b   = qneg(b);
+  }
+  // For numerical stability, perform linear interpolation when the two
+  // quaternions are close to each other.
+  R ta, tb;
+  if (1.0 - dot > 1e-6) {
+    const R theta     = acos(dot);
+    const R sin_theta = sqrt(1 - dot * dot);
+    ta                = sin(theta * (1.0 - t)) / sin_theta;
+    tb                = sin(theta * t) / sin_theta;
+  } else { // Linear interpolation.
+    ta = 1.0 - t;
+    tb = t;
+  }
+  return qadd(qscale(a, ta), qscale(b, tb));
+}
diff --git a/include/math/spatial3.h b/include/math/spatial3.h
index 8de38bf..9065972 100644
--- a/include/math/spatial3.h
+++ b/include/math/spatial3.h
@@ -118,7 +118,7 @@ static inline void spatial3_set_transform(Spatial3* spatial, mat4 transform) {
 static inline void spatial3_set_forward(Spatial3* spatial, vec3 forward) {
  spatial->f = vec3_normalize(forward);
  // Use aux vector to define right vector orthogonal to forward.
-  if (vec3_eq(vec3_abs(spatial->f), up3())) {
+  if (vec3_eq(vec3_abs(spatial->f), up3(), 1e-9)) {
    spatial->r = vec3_normalize(vec3_cross(spatial->f, forward3()));
  } else {
    spatial->r = vec3_normalize(vec3_cross(spatial->f, up3()));
diff --git a/include/math/vec3.h b/include/math/vec3.h
index 641c02f..d8e1248 100644
--- a/include/math/vec3.h
+++ b/include/math/vec3.h
@@ -51,14 +51,14 @@ static inline vec3 vec3_div(vec3 a, vec3 b) {
  return (vec3){a.x / b.x, a.y / b.y, a.z / b.z};
 }
-/// Scale a vector by a scalar value.
+/// Scale the vector.
 static inline vec3 vec3_scale(vec3 v, R s) {
  return (vec3){v.x * s, v.y * s, v.z * s};
 }
 /// Compare two vectors for equality.
-static inline bool vec3_eq(vec3 a, vec3 b) {
+static inline bool vec3_eq(vec3 a, vec3 b, R eps) {
-  return a.x == b.x && a.y == b.y && a.z == b.z;
+  return R_eq(a.x, b.x, eps) && R_eq(a.y, b.y, eps) && R_eq(a.z, b.z, eps);
 }
 /// Return the absolute value of the vector.
@@ -67,7 +67,9 @@ static inline vec3 vec3_abs(vec3 v) {
 }
 /// Compare two vectors for inequality.
-static inline bool vec3_ne(vec3 a, vec3 b) { return !(vec3_eq(a, b)); }
+static inline bool vec3_ne(vec3 a, vec3 b, R eps) {
+  return !(vec3_eq(a, b, eps));
+}
 /// Return the vector's squared magnitude.
 static inline R vec3_norm2(vec3 v) { return v.x * v.x + v.y * v.y + v.z * v.z; }
@@ -123,6 +125,40 @@ static inline vec3 vec3_pow(vec3 v, R p) {
  return (vec3){pow(v.x, p), pow(v.y, p), pow(v.z, p)};
 }
+/// Linearly interpolate two vectors.
+static inline vec3 vec3_lerp(vec3 a, vec3 b, R t) {
+  return (vec3){
+      .x = a.x + t * (b.x - a.x),
+      .y = a.y + t * (b.y - a.y),
+      .z = a.z + t * (b.z - a.z)};
+}
+/// Interpolate two unit vectors using spherical linear interpolation.
+///
+/// Note: You might want to normalize the result.
+static inline vec3 vec3_slerp(vec3 a, vec3 b, R t) {
+  assert(0.0 <= t);
+  assert(t <= 1.0);
+  const R eps = 1e-5;
+  (void)eps;
+  assert(R_eq(vec3_norm2(a), 1.0, eps));
+  assert(R_eq(vec3_norm2(b), 1.0, eps));
+  R dot = vec3_dot(a, b);
+  // For numerical stability, perform linear interpolation when the two vectors
+  // are close to each other.
+  R ta, tb;
+  if (1.0 - dot > 1e-6) {
+    const R theta     = acos(dot);
+    const R sin_theta = sqrt(1.0 - dot * dot);
+    ta                = sin((1.0 - t) * theta) / sin_theta;
+    tb                = sin(t * theta) / sin_theta;
+  } else { // Linear interpolation.
+    ta = 1.0 - t;
+    tb = t;
+  }
+  return vec3_add(vec3_scale(a, ta), vec3_scale(b, tb));
+}
 /// The (1, 0, 0) vector.
 static inline vec3 right3() { return (vec3){1.0, 0.0, 0.0}; }

diff --git a/include/math/defs.h b/include/math/defs.h index f67ee97..f572d8f 100644 --- a/include/math/defs.h +++ b/include/math/defs.h
@@ -14,7 +14,7 @@ typedef double R;
14	#define R_MIN DBL_MIN	14	#define R_MIN DBL_MIN
15	#define R_MAX DBL_MAX	15	#define R_MAX DBL_MAX
16	#else // floats	16	#else // floats
17	typedef float R;	17	typedef float R;
18	#define R_MIN FLT_MIN	18	#define R_MIN FLT_MIN
19	#define R_MAX FLT_MAX	19	#define R_MAX FLT_MAX
20	#endif	20	#endif
@@ -29,13 +29,15 @@ typedef float R;
29	#define TO_DEG (180.0 / PI)	29	#define TO_DEG (180.0 / PI)
30		30
31	#ifdef MATH_USE_DOUBLE	31	#ifdef MATH_USE_DOUBLE
32	static inline double min(R a, R b) { return fmin(a, b); }	32	static inline R min(R a, R b) { return fmin(a, b); }
33	static inline double max(R a, R b) { return fmax(a, b); }	33	static inline R max(R a, R b) { return fmax(a, b); }
34	static inline double rlog2(R a) { return log2(a); }	34	static inline R rlog2(R a) { return log2(a); }
		35	static inline R rmod(R a, R m) { return fmodf(a, m); }
35	#else // floats	36	#else // floats
36	static inline float min(R a, R b) { return fminf(a, b); }	37	static inline R min(R a, R b) { return fminf(a, b); }
37	static inline float max(R a, R b) { return fmaxf(a, b); }	38	static inline R max(R a, R b) { return fmaxf(a, b); }
38	static inline float rlog2(R a) { return log2f(a); }	39	static inline R rlog2(R a) { return log2f(a); }
		40	static inline R rmod(R a, R m) { return fmod(a, m); }
39	#endif	41	#endif
40		42
41	static inline R rabs(R x) { return x >= 0.0 ? x : -x; }	43	static inline R rabs(R x) { return x >= 0.0 ? x : -x; }
@@ -51,3 +53,4 @@ static inline R sign(R x) {
51	}	53	}
52	}	54	}
53	static inline R lerp(R a, R b, R t) { return a + (b - a) * t; }	55	static inline R lerp(R a, R b, R t) { return a + (b - a) * t; }
		56	static inline R R_eq(R a, R b, R eps) { return rabs(a - b) <= eps; }


diff --git a/include/math/quat.h b/include/math/quat.h index b284567..a154044 100644 --- a/include/math/quat.h +++ b/include/math/quat.h
@@ -4,23 +4,38 @@
4	#include "mat4.h"	4	#include "mat4.h"
5	#include "vec3.h"	5	#include "vec3.h"
6		6
		7	#include <assert.h>
		8
7	/// A quaternion.	9	/// A quaternion.
8	typedef struct quat {	10	typedef struct quat {
9	R w, x, y, z;	11	R x, y, z, w;
10	} quat;	12	} quat;
11		13
		14	/// Return the unit/identity quaternion.
12	static inline quat qunit() {	15	static inline quat qunit() {
13	return (quat){.x = 0.0, .y = 0.0, .z = 0.0, .w = 0.0};	16	return (quat){.x = 0.0, .y = 0.0, .z = 0.0, .w = 1.0};
14	}	17	}
15		18
		19	/// Construct a quaternion.
16	static inline quat qmake(R x, R y, R z, R w) {	20	static inline quat qmake(R x, R y, R z, R w) {
17	return (quat){.x = x, .y = y, .z = z, .w = w};	21	return (quat){.x = x, .y = y, .z = z, .w = w};
18	}	22	}
19		23
		24	/// Construct a quaternion from an array.
20	static inline quat quat_from_array(const R xyzw[4]) {	25	static inline quat quat_from_array(const R xyzw[4]) {
21	return (quat){.x = xyzw[0], .y = xyzw[1], .z = xyzw[2], .w = xyzw[3]};	26	return (quat){.x = xyzw[0], .y = xyzw[1], .z = xyzw[2], .w = xyzw[3]};
22	}	27	}
23		28
		29	/// Construct a quaternion from a 3D point.
		30	static inline quat quat_from_vec3(vec3 p) {
		31	return (quat){.x = p.x, .y = p.y, .z = p.z, .w = 0.0};
		32	}
		33
		34	/// Get a 3D point back from a quaternion.
		35	static inline vec3 vec3_from_quat(quat q) {
		36	return (vec3){.x = q.x, .y = q.y, .z = q.z};
		37	}
		38
24	/// Construct a rotation quaternion.	39	/// Construct a rotation quaternion.
25	static inline quat qmake_rot(R angle, R x, R y, R z) {	40	static inline quat qmake_rot(R angle, R x, R y, R z) {
26	const R a = angle * 0.5;	41	const R a = angle * 0.5;
@@ -34,6 +49,11 @@ static inline quat qmake_rot(R angle, R x, R y, R z) {
34	return (quat){x / mag, y / mag, z / mag, w};	49	return (quat){x / mag, y / mag, z / mag, w};
35	}	50	}
36		51
		52	/// Add two quaternions.
		53	static inline quat qadd(quat a, quat b) {
		54	return (quat){.x = a.x + b.x, .y = a.y + b.y, .z = a.z + b.z, .w = a.w + b.w};
		55	}
		56
37	/// Multiply two quaternions.	57	/// Multiply two quaternions.
38	static inline quat qmul(quat q1, quat q2) {	58	static inline quat qmul(quat q1, quat q2) {
39	const R x = q1.w * q2.x + q1.x * q2.w + q1.y * q2.z - q1.z * q2.y;	59	const R x = q1.w * q2.x + q1.x * q2.w + q1.y * q2.z - q1.z * q2.y;
@@ -61,6 +81,37 @@ static inline vec3 qrot(quat q, vec3 v) {
61	return vec3_make(u.x, u.y, u.z);	81	return vec3_make(u.x, u.y, u.z);
62	}	82	}
63		83
		84	/// Negate the quaternion.
		85	static inline quat qneg(quat q) {
		86	return (quat){.x = -q.x, .y = -q.y, .z = -q.z, .w = -q.w};
		87	}
		88
		89	/// Return the dot product of two quaternions.
		90	static inline R qdot(quat a, quat b) {
		91	return a.x * b.x + a.y * b.y + a.z * b.z + a.w * b.w;
		92	}
		93
		94	/// Return the quaternion's magnitude.
		95	static inline R qnorm(quat q) {
		96	return sqrt(q.x * q.x + q.y * q.y + q.z * q.z + q.w * q.w);
		97	}
		98
		99	/// Return the quaternion's squared magnitude.
		100	static inline R qnorm2(quat q) {
		101	return q.x * q.x + q.y * q.y + q.z * q.z + q.w * q.w;
		102	}
		103
		104	/// Normalize the quaternion.
		105	static inline quat qnormalize(quat q) {
		106	const R n = qnorm(q);
		107	return (quat){.x = q.x / n, .y = q.y / n, .z = q.z / n, .w = q.w / n};
		108	}
		109
		110	/// Scale the quaternion.
		111	static inline quat qscale(quat q, R s) {
		112	return (quat){.x = s * q.x, .y = s * q.y, .z = s * q.z, .w = s * q.w};
		113	}
		114
64	/// Get a 4x4 rotation matrix from a quaternion.	115	/// Get a 4x4 rotation matrix from a quaternion.
65	static inline mat4 mat4_from_quat(quat q) {	116	static inline mat4 mat4_from_quat(quat q) {
66	const R xx = q.x * q.x;	117	const R xx = q.x * q.x;
@@ -77,3 +128,35 @@ static inline mat4 mat4_from_quat(quat q) {
77	1 - 2 * xx - 2 * zz, 2 * yz - 2 * wx, 0, 2 * xz - 2 * wy, 2 * yz + 2 * wx,	128	1 - 2 * xx - 2 * zz, 2 * yz - 2 * wx, 0, 2 * xz - 2 * wy, 2 * yz + 2 * wx,
78	1 - 2 * xx - 2 * yy, 0, 0, 0, 0, 1);	129	1 - 2 * xx - 2 * yy, 0, 0, 0, 0, 1);
79	}	130	}
		131
		132	/// Interpolate two unit quaternions using spherical linear interpolation.
		133	///
		134	/// Note: You might want to normalize the result.
		135	static inline quat qslerp(quat a, quat b, R t) {
		136	assert(0.0 <= t);
		137	assert(t <= 1.0);
		138	const R eps = 1e-5;
		139	(void)eps;
		140	assert(R_eq(qnorm2(a), 1.0, eps));
		141	assert(R_eq(qnorm2(b), 1.0, eps));
		142	R dot = qdot(a, b);
		143	// Make the rotation path follow the "short way", i.e., ensure that:
		144	// -90 <= angle <= 90
		145	if (dot < 0.0) {
		146	dot = -dot;
		147	b = qneg(b);
		148	}
		149	// For numerical stability, perform linear interpolation when the two
		150	// quaternions are close to each other.
		151	R ta, tb;
		152	if (1.0 - dot > 1e-6) {
		153	const R theta = acos(dot);
		154	const R sin_theta = sqrt(1 - dot * dot);
		155	ta = sin(theta * (1.0 - t)) / sin_theta;
		156	tb = sin(theta * t) / sin_theta;
		157	} else { // Linear interpolation.
		158	ta = 1.0 - t;
		159	tb = t;
		160	}
		161	return qadd(qscale(a, ta), qscale(b, tb));
		162	}


diff --git a/include/math/spatial3.h b/include/math/spatial3.h index 8de38bf..9065972 100644 --- a/include/math/spatial3.h +++ b/include/math/spatial3.h
@@ -118,7 +118,7 @@ static inline void spatial3_set_transform(Spatial3* spatial, mat4 transform) {
118	static inline void spatial3_set_forward(Spatial3* spatial, vec3 forward) {	118	static inline void spatial3_set_forward(Spatial3* spatial, vec3 forward) {
119	spatial->f = vec3_normalize(forward);	119	spatial->f = vec3_normalize(forward);
120	// Use aux vector to define right vector orthogonal to forward.	120	// Use aux vector to define right vector orthogonal to forward.
121	if (vec3_eq(vec3_abs(spatial->f), up3())) {	121	if (vec3_eq(vec3_abs(spatial->f), up3(), 1e-9)) {
122	spatial->r = vec3_normalize(vec3_cross(spatial->f, forward3()));	122	spatial->r = vec3_normalize(vec3_cross(spatial->f, forward3()));
123	} else {	123	} else {
124	spatial->r = vec3_normalize(vec3_cross(spatial->f, up3()));	124	spatial->r = vec3_normalize(vec3_cross(spatial->f, up3()));


diff --git a/include/math/vec3.h b/include/math/vec3.h index 641c02f..d8e1248 100644 --- a/include/math/vec3.h +++ b/include/math/vec3.h
@@ -51,14 +51,14 @@ static inline vec3 vec3_div(vec3 a, vec3 b) {
51	return (vec3){a.x / b.x, a.y / b.y, a.z / b.z};	51	return (vec3){a.x / b.x, a.y / b.y, a.z / b.z};
52	}	52	}
53		53
54	/// Scale a vector by a scalar value.	54	/// Scale the vector.
55	static inline vec3 vec3_scale(vec3 v, R s) {	55	static inline vec3 vec3_scale(vec3 v, R s) {
56	return (vec3){v.x * s, v.y * s, v.z * s};	56	return (vec3){v.x * s, v.y * s, v.z * s};
57	}	57	}
58		58
59	/// Compare two vectors for equality.	59	/// Compare two vectors for equality.
60	static inline bool vec3_eq(vec3 a, vec3 b) {	60	static inline bool vec3_eq(vec3 a, vec3 b, R eps) {
61	return a.x == b.x && a.y == b.y && a.z == b.z;	61	return R_eq(a.x, b.x, eps) && R_eq(a.y, b.y, eps) && R_eq(a.z, b.z, eps);
62	}	62	}
63		63
64	/// Return the absolute value of the vector.	64	/// Return the absolute value of the vector.
@@ -67,7 +67,9 @@ static inline vec3 vec3_abs(vec3 v) {
67	}	67	}
68		68
69	/// Compare two vectors for inequality.	69	/// Compare two vectors for inequality.
70	static inline bool vec3_ne(vec3 a, vec3 b) { return !(vec3_eq(a, b)); }	70	static inline bool vec3_ne(vec3 a, vec3 b, R eps) {
		71	return !(vec3_eq(a, b, eps));
		72	}
71		73
72	/// Return the vector's squared magnitude.	74	/// Return the vector's squared magnitude.
73	static inline R vec3_norm2(vec3 v) { return v.x * v.x + v.y * v.y + v.z * v.z; }	75	static inline R vec3_norm2(vec3 v) { return v.x * v.x + v.y * v.y + v.z * v.z; }
@@ -123,6 +125,40 @@ static inline vec3 vec3_pow(vec3 v, R p) {
123	return (vec3){pow(v.x, p), pow(v.y, p), pow(v.z, p)};	125	return (vec3){pow(v.x, p), pow(v.y, p), pow(v.z, p)};
124	}	126	}
125		127
		128	/// Linearly interpolate two vectors.
		129	static inline vec3 vec3_lerp(vec3 a, vec3 b, R t) {
		130	return (vec3){
		131	.x = a.x + t * (b.x - a.x),
		132	.y = a.y + t * (b.y - a.y),
		133	.z = a.z + t * (b.z - a.z)};
		134	}
		135
		136	/// Interpolate two unit vectors using spherical linear interpolation.
		137	///
		138	/// Note: You might want to normalize the result.
		139	static inline vec3 vec3_slerp(vec3 a, vec3 b, R t) {
		140	assert(0.0 <= t);
		141	assert(t <= 1.0);
		142	const R eps = 1e-5;
		143	(void)eps;
		144	assert(R_eq(vec3_norm2(a), 1.0, eps));
		145	assert(R_eq(vec3_norm2(b), 1.0, eps));
		146	R dot = vec3_dot(a, b);
		147	// For numerical stability, perform linear interpolation when the two vectors
		148	// are close to each other.
		149	R ta, tb;
		150	if (1.0 - dot > 1e-6) {
		151	const R theta = acos(dot);
		152	const R sin_theta = sqrt(1.0 - dot * dot);
		153	ta = sin((1.0 - t) * theta) / sin_theta;
		154	tb = sin(t * theta) / sin_theta;
		155	} else { // Linear interpolation.
		156	ta = 1.0 - t;
		157	tb = t;
		158	}
		159	return vec3_add(vec3_scale(a, ta), vec3_scale(b, tb));
		160	}
		161
126	/// The (1, 0, 0) vector.	162	/// The (1, 0, 0) vector.
127	static inline vec3 right3() { return (vec3){1.0, 0.0, 0.0}; }	163	static inline vec3 right3() { return (vec3){1.0, 0.0, 0.0}; }
128		164