The `color.RGBA`

type implements the `RGBA`

method to satisfy the `color.Color`

interface:

```
type Color interface {
// RGBA returns the alpha-premultiplied red, green, blue and alpha values
// for the color. Each value ranges within [0, 0xffff], but is represented
// by a uint32 so that multiplying by a blend factor up to 0xffff will not
// overflow.
//
// An alpha-premultiplied color component c has been scaled by alpha (a),
// so has valid values 0 <= c <= a.
RGBA() (r, g, b, a uint32)
}
```

Now the RGBA type represents the colour channels with the `uint8`

type, giving a range of [0, 0xff]. Simply converting these values to `uint32`

would not extend the range up to [0, 0xffff].

An appropriate conversion would be something like:

```
r = uint32((float64(c.R) / 0xff) * 0xffff)
```

However, they want to avoid the floating point arithmetic. Luckily `0xffff / 0xff`

is `0x0101`

, so we can simplify the expression (ignoring the type conversions for now):

```
r = c.R * 0x0101
= c.R * 0x0100 + c.R
= (c.R << 8) + c.R # multiply by power of 2 is equivalent to shift
= (c.R << 8) | c.R # equivalent, since bottom 8 bits of first operand are 0
```

And that's essentially what the code in the standard library is doing.