```
S -> LR
L -> L0Y
L -> LX
X1 -> 1X
X0 -> 0X
X0 -> 1Y
Y1 -> 0Y
YR -> R
L -> epsilon
R -> epsilon
```

terminals: 0,1
start: S

Let's split the grammar:

```
S -> LR
L -> L0Y
L -> LX
```

This will generate a string in the form `L`

, string of `X`

and `0Y`

, `R`

.

```
X1 -> 1X
X0 -> 0X
X0 -> 1Y
Y1 -> 0Y
YR -> R
```

Treat `X`

and `Y`

as acting on the binary string: `X`

will propagate to the right, then change a `0`

to `1`

and all subsequent `1`

s to `0`

s. In effect, a single `X`

increments the binary number without changing its string length (or gets stuck).

A leading `Y`

will rewrite the string of all `1`

s to all `0`

s (or gets stuck).

Treat the rules for `L`

as the possible actions on the right part of the string. `L => L0Y`

will reset the string from all ones to all zeroes and increase its length by one. `L => LX`

will increment any other number, but fails if the value is at the maximum.

These two actions together are sufficient to generate (inefficiently) all strings of zeroes and ones (including the empty string).

```
L -> epsilon
R -> epsilon
```

will only clean up the sentinels.

one possible description of the language within four words:

set of all strings

`x`

. How did you get to the binary numbers? – Jan Dvorak Dec 7 '12 at 20:03