Scale matrix `S`

looks like this:

```
sx 0 0 0
0 sy 0 0
0 0 sz 0
0 0 0 1
```

Translation matrix `T`

looks like this:

```
1 0 0 0
0 1 0 0
0 0 1 0
tx ty tz 1
```

Z-axis rotation matrix `R`

looks like this:

```
cos(a) sin(a) 0 0
-sin(a) cos(a) 0 0
0 0 1 0
0 0 0 1
```

If you have a transformation matrix `M`

, it is a result of a number of multiplications of `R`

, `T`

and `S`

matrices. Looking at `M`

, the order and number of those multiplications is unknown. However, if we assume that `M=S*R*T`

we can decompose it into separate matrices. Firstly let's calculate `S*R*T`

:

```
( sx*cos(a) sx*sin(a) 0 0) (m11 m12 m13 m14)
S*R*T = (-sy*sin(a) sy*cos(a) 0 0) = M = (m21 m22 m23 m24)
( 0 0 sz 0) (m31 m32 m33 m34)
( tx ty tz 1) (m41 m42 m43 m44)
```

Since we know it's a 2D transformation, getting translation is straightforward:

```
translation = vector2D(tx, ty) = vector2D(m41, m42)
```

To calculate rotation and scale, we can use `sin(a)^2+cos(a)^2=1`

:

```
(m11 / sx)^2 + (m12 / sx)^2 = 1
(m21 / sy)^2 + (m22 / sy)^2 = 1
m11^2 + m12^2 = sx^2
m21^2 + m22^2 = sy^2
sx = sqrt(m11^2 + m12^2)
sy = sqrt(m21^2 + m22^2)
scale = vector2D(sx, sy)
rotation_angle = atan2(sx*m22, sy*m12)
```