The axis angle method is the fastest method, heres the C code I came up with for efficient axis/angle to 3x3 matrix conversion.

This checks for co-linear cases too.

**Note:** If you have your own math library, you can probably get `rotation_between_vecs_to_mat3`

working without any of the associated functions included for completeness.

```
#include <math.h>
#include <float.h>
/* -------------------------------------------------------------------- */
/* Math Lib declarations */
static void unit_m3(float m[3][3]);
static float dot_v3v3(const float a[3], const float b[3]);
static float normalize_v3(float n[3]);
static void cross_v3_v3v3(float r[3], const float a[3], const float b[3]);
static void mul_v3_v3fl(float r[3], const float a[3], float f);
static void ortho_v3_v3(float p[3], const float v[3]);
static void axis_angle_normalized_to_mat3_ex(
float mat[3][3], const float axis[3],
const float angle_sin, const float angle_cos);
/* -------------------------------------------------------------------- */
/* Main function */
void rotation_between_vecs_to_mat3(float m[3][3], const float v1[3], const float v2[3]);
/**
* Calculate a rotation matrix from 2 normalized vectors.
*
* v1 and v2 must be unit length.
*/
void rotation_between_vecs_to_mat3(float m[3][3], const float v1[3], const float v2[3])
{
float axis[3];
/* avoid calculating the angle */
float angle_sin;
float angle_cos;
cross_v3_v3v3(axis, v1, v2);
angle_sin = normalize_v3(axis);
angle_cos = dot_v3v3(v1, v2);
if (angle_sin > FLT_EPSILON) {
axis_calc:
axis_angle_normalized_to_mat3_ex(m, axis, angle_sin, angle_cos);
}
else {
/* Degenerate (co-linear) vectors */
if (angle_cos > 0.0f) {
/* Same vectors, zero rotation... */
unit_m3(m);
}
else {
/* Colinear but opposed vectors, 180 rotation... */
ortho_v3_v3(axis, v1);
normalize_v3(axis);
angle_sin = 0.0f; /* sin(M_PI) */
angle_cos = -1.0f; /* cos(M_PI) */
goto axis_calc;
}
}
}
/* -------------------------------------------------------------------- */
/* Math Lib */
static void unit_m3(float m[3][3])
{
m[0][0] = m[1][1] = m[2][2] = 1.0;
m[0][1] = m[0][2] = 0.0;
m[1][0] = m[1][2] = 0.0;
m[2][0] = m[2][1] = 0.0;
}
static float dot_v3v3(const float a[3], const float b[3])
{
return a[0] * b[0] + a[1] * b[1] + a[2] * b[2];
}
static void cross_v3_v3v3(float r[3], const float a[3], const float b[3])
{
r[0] = a[1] * b[2] - a[2] * b[1];
r[1] = a[2] * b[0] - a[0] * b[2];
r[2] = a[0] * b[1] - a[1] * b[0];
}
static void mul_v3_v3fl(float r[3], const float a[3], float f)
{
r[0] = a[0] * f;
r[1] = a[1] * f;
r[2] = a[2] * f;
}
static float normalize_v3_v3(float r[3], const float a[3])
{
float d = dot_v3v3(a, a);
if (d > 1.0e-35f) {
d = sqrtf(d);
mul_v3_v3fl(r, a, 1.0f / d);
}
else {
d = r[0] = r[1] = r[2] = 0.0f;
}
return d;
}
static float normalize_v3(float n[3])
{
return normalize_v3_v3(n, n);
}
static int axis_dominant_v3_single(const float vec[3])
{
const float x = fabsf(vec[0]);
const float y = fabsf(vec[1]);
const float z = fabsf(vec[2]);
return ((x > y) ?
((x > z) ? 0 : 2) :
((y > z) ? 1 : 2));
}
static void ortho_v3_v3(float p[3], const float v[3])
{
const int axis = axis_dominant_v3_single(v);
switch (axis) {
case 0:
p[0] = -v[1] - v[2];
p[1] = v[0];
p[2] = v[0];
break;
case 1:
p[0] = v[1];
p[1] = -v[0] - v[2];
p[2] = v[1];
break;
case 2:
p[0] = v[2];
p[1] = v[2];
p[2] = -v[0] - v[1];
break;
}
}
/* axis must be unit length */
static void axis_angle_normalized_to_mat3_ex(
float mat[3][3], const float axis[3],
const float angle_sin, const float angle_cos)
{
float nsi[3], ico;
float n_00, n_01, n_11, n_02, n_12, n_22;
ico = (1.0f - angle_cos);
nsi[0] = axis[0] * angle_sin;
nsi[1] = axis[1] * angle_sin;
nsi[2] = axis[2] * angle_sin;
n_00 = (axis[0] * axis[0]) * ico;
n_01 = (axis[0] * axis[1]) * ico;
n_11 = (axis[1] * axis[1]) * ico;
n_02 = (axis[0] * axis[2]) * ico;
n_12 = (axis[1] * axis[2]) * ico;
n_22 = (axis[2] * axis[2]) * ico;
mat[0][0] = n_00 + angle_cos;
mat[0][1] = n_01 + nsi[2];
mat[0][2] = n_02 - nsi[1];
mat[1][0] = n_01 - nsi[2];
mat[1][1] = n_11 + angle_cos;
mat[1][2] = n_12 + nsi[0];
mat[2][0] = n_02 + nsi[1];
mat[2][1] = n_12 - nsi[0];
mat[2][2] = n_22 + angle_cos;
}
```

differencebetween them, then`AX = B`

⇒`X = A⁻¹B`

. Since pure rotation is represented by an orthogonal matrix, its transpose is its inverse. I think the 2nd transpose is redundant, if you transpose`m1`

and then multiply it with`m2`

. – legends2k Apr 19 '14 at 7:52`XA = B`

⇒`X = BA⁻¹`

– SpiderPig Apr 19 '14 at 9:01