The power of Postscript is its ruthless pursuit of the ideal of "delayed binding". The implementation of rotations is no exception. It works by making use of a more general tool, the Affine Transformation Matrix.

You can rotate both text and graphics (because text **IS** graphics) because all user specified coordinates are first multiplied through this matrix to produce *device coordinates*.

To perform all the necessary tricks (scaling, rotation, shear, translation), we first have to extend the 2d points to 3d points on the plane z=1 (don't ask me why; read Bill Casselman's *Mathematical Illustrations* or the Adobe Blue Book for more).

```
[ x [ a b 0
y * c d 0 = [ x' y' 1 ] = [ ax+cy+e bx+dy+f 1 ]
1 ] e f 1 ]
```

Since the 3rd column of the matrix is always [ 0 0 1 ] it is omitted from the external representation, and the matrix is described in postscript as:

```
[ a b c d e f ]
```

So when you use a coordinate pair for, say, a `moveto`

operator, `moveto`

first transforms it to device coordinates, x' = ax+by+e, y' = cx+dy+f, before adding a `<</move [x' y']>>`

element to the current path.
Change the matrix: change the "meaning" of user coordinates.

The identity matrix is this:

```
[ 1 0 0 1 0 0 ] % x' = x, y' = y
```

To scale, replace the 1s with x and y scaling factors:

```
[ Sx 0 0 Sy 0 0 ] % x' = Sx*x, y' = Sy*y
```

To translate, replace e and f with the x and y translation offsets:

```
[ 1 0 0 1 Tx Ty ] % x' = x+Tx, y' = y+Ty
```

To rotate, replace a,b,c,d with sin and cos scaling and shearing factors:

```
[ cosW sinW -sinW cosW 0 0 ] % x' = x*cosW-y*sinW, y' = x*sinW+y*cosW, where W is angle(degrees) from x-axis
```

You "install" this matrix with `concat`

which takes the Current Tranformation Matrix (CTM), multiplies it by your new matrix, and uses the product as the new CTM. So `translate`

, `rotate`

, and `scale`

are just "convenience functions" which could be implemented like this:

```
/translate { [ 1 0 0 1 7 -2 roll ] concat } def
/scale { [ 3 1 roll 0 0 3 -1 roll 0 0 ] concat } def
/rotate { [ exch dup cos exch sin dup neg 2 index 0 0 ] concat } def
```

Since the CTM is part of the graphics state, you can use the graphics state stack to manipulate your transformations in a hierarchical manner:

```
/box { % x y w h %create a path in the shape of a box w*h with lower left corner at x,y
4 2 roll moveto
exch dup 3 1 roll
0 rlineto
0 exch rlineto
neg 0 rlineto
closepath
} def
/Courier 10 selectfont
100 100 100 100 box stroke % draw an oriented box
120 120 moveto (inside) show
gsave
150 150 translate % make the center of the box the new 0,0 point
45 rotate % rotate CCW 45 degrees
0 0 100 100 box stroke % a rotated, shifted box
20 20 moveto (inside) show
grestore
100 200 100 100 box stroke % another box, just north of the first, in the original coordinte system
120 220 moveto (inside) show
```

This produces the following image: