Okay, I'll bite. First, Mathematica allows functions to be applied via one of several forms: standard form - `f[x]`

, prefix form - `f @ x`

, postfix form - `f // x`

, and infix form - `x ~ f ~ y`

. Belisarius's code uses both standard and prefix form.

So, let's look at the outermost functions first: `Graphics @ x /. gg : Graphics[___]:> Rotate[gg,Pi/2]`

, where `x`

is everything inside of `Flatten`

. Essentially, what this does is create a `Graphics`

object from `x`

and using a named pattern (`gg : Graphics[___]`

) rotates the resulting `Graphics`

object by 90 degrees.

Now, to create a `Graphics`

object, we need to supply a bunch of primitives and this is in the form of a nested list, where each sublist describes some element. This is done via the `Table`

command which has the form: `Table[ expr, iterators ]`

. Iterators can have several forms, but here they both have the form `{var, min, max}`

, and since they lack a 4th term, they take on each value between `min`

and `max`

in integer steps. So, our iterators are `{r, 7, 64}`

and `{t, 1, 72}`

, and `expr`

is evaluated for each value that they take on. Since, we have two iterators this produces a matrix, which would confuse `Graphics`

, so we using `Flatten[ Table[ ... ], 1]`

we take every element of the matrix and put it into a simple list.

Each element that `Table`

produces is simply: color (`ColorData`

), point size (`PointSize`

), and point location (`Point`

). So, with `Flatten`

, we have created the following:

```
Graphics[{{color, point size, point}, {color, point size, point}, ... }]
```

The color generation is taken from the data, and it assumes that the data has been put into a list called `a`

. The individual elements of `a`

are accessed through the `Part`

construct: `[[]]`

. On the surface, the `ColorData`

construct is a little odd, but it can be read as `ColorData["CMYKColors"]`

returns a `ColorDataFunction`

that produces a CMYK color value when a value between 0 and 1 is supplied. That is why the data from `a`

is scaled the way it is.

The point size is generated from the radial coordinate. You'd expect with `1/Sqrt[r]`

the point size should be getting smaller as `r`

increases, but the `Log`

inverts the scale.

Similarly, the point location is produced from the radial and angular (`t`

) variables, but `Point`

only accepts them in `{x,y}`

form, so he needed to convert them. Two odd constructs occur in the transformation from `{r,t}`

to `{x,y}`

: both `rr`

and `tt`

are Set (`=`

) while calculating `x`

allowing them to be used when calculating `y`

. Also, the term `t 5 Degree`

lets Mathematica know that the angle is in degrees, not radians. Additionally, as written, there is a bug: immediately following the closing `}`

, the terms `&`

and `@`

should not be there.

Does that help?