# Efficient way to calculate a 3x3 rotation matrix from the rotation defined by two 3D Vectors

While I've found 2 solutions to this, I was curious if there is well known method to perform this operation since it seems a fairly common task.

Here are the 2 obvious methods psudo-code...

# Axis Angle

This is quite logical, but calls `sin` twice and `cos` once (in the angle calculation and axis angle to matrix conversion).

``````Matrix3x3 rotation_between_vectors_to_matrix(const Vector v1, const Vector v2)
{
angle = v1.angle(v2);
axis  = v1.cross(v2);

/* maths for this is well known */
Matrix3x3 matrix = axis_angle_to_matrix(axis, angle);

return matrix;
}
``````

Edit: The most straightforward function is a quite slow, however as has been pointed out in the replies here: calculating the angle can be avoided by getting `angle_sin` and `angle_cos`, from the axis length and `v1,v2` dot product respectively.

# Difference between two matrices

Here's another method I found which constructs two 3x3 matrices from the vectors and returns the difference.

However this is slower then axis/angle calculation which can be optimized (mentioned above).

Note. this assumes both vectors are normalized, matrix is column-major (OpenGL).

``````Matrix3x3 rotation_between_vectors_to_matrix(const Vector v1, const Vector v2)
{
Matrix3x3 m1, m2;

axis = v1.cross(v2);
axis.normalize();

/* construct 2 matrices */
m1[0] = v1;
m2[0] = v2;

m1[1] = axis;
m2[1] = axis;

m1[2] = m1[1].cross(m1[0]);
m2[2] = m2[1].cross(m2[0]);

/* calculate the difference between m1 and m2 */
m1.transpose();

Matrix3x3 matrix = m2 * m1;

return matrix;
}
``````

Are there better ways to perform this calculation?

Edit: The purpose of this question is NOT to micro-optimize and benchmark each method. Instead - I was curious if there is some totally different and superior method which I didn't know about.

Note: I purposefully left out checks for the degenerate case for co-linear vectors (where the axis is zero length), to keep the examples simple.

• @legends2k, not as far as I know, I just found this myself while looking into better alternatives to the axis/angle method. (its well tested and got it working in degenerate cases too) – ideasman42 Apr 19 '14 at 7:34
• Shoudn't you get the same result if you write m1.transpose(); matrix = m2 * m1; return matrix; ? Would save one transpose operation. – SpiderPig Apr 19 '14 at 7:35
• @ideasman42: Yeah, got it. Let A and B be the matrices, with some matrix X as the difference between 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
• @legends2k: In a rotation the rotation matrix comes first and the matrix/vector that is being rotated second. So it's `XA = B``X = BA⁻¹` – SpiderPig Apr 19 '14 at 9:01
• @SpiderPig, your right, removed redundant transpose. – ideasman42 Apr 19 '14 at 9:51

Both the methods you've posted can be optimised.

# Method 1

Instead of using `acos` to find the angle between the two vectors, a better thing to do is to avoid finding the angle at all. How? The axis-angle formula by Rodrigues requires only `sin θ`, `cos θ` and `1 - cos θ`, so finding the actual angle is redundant.

We know that `v1` and `v2` are unit vectors; `v1 · v2 = |v1| |v2| cos θ` since `|v1| = |v2| = 1`, `v1 · v2` directly gives us `cos θ`, finding `1 - cos θ` isn't costly. `v1 × v2 = |v1| |v2| sin θ n = sin θ n`, where `n` is a unit vector perpendicular to `v1` and `v2`, finding `|v1 × v2|` the magnitude of the cross product would directly give `sin θ`.

Now that we've `sin θ` and `cos θ`, we can directly form the rotation matrix by using Rodrigues forumla; here's a simple implementation.

# Method 2

After you've constructed two orthonormal frames as matrices, you can avoid the second transpose you do. Here's the proof.

Say `A` and `B` be the two matrices, since you want to rotate from `A` to `B` we need some matrix `X` which when multiplied with `A` will give `B`:

XA = B

X = BA⁻¹

This is all you need; when you pre-multiply `X` to `A` you'd get `B`. However, what you find is `Y`

Y = AB⁻¹

YB = A

Then you transpose `Y` to get `Y⁻¹` i.e.

Y⁻¹YB = Y⁻¹A

B = Y⁻¹A

Instead of doing two inverses (transpose here), you can just do the above method which involves only one transpose.

I'd still say that without benchmarking the methods in their optimized forms, we cannot say method 2 is faster than method 1. So I'd really urge you to benchmark between the two methods (with some non-trivial load) and then draw a conclusion.

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;
}
``````