I was adding zero-or-more and one-or-more modifiers to my PEG parser, which is straightforward since there is so little backtracking in PEG. Earlier iterations are never reconsidered, so a simple `while`

loop suffices.

However, in other contexts, zero-or-more and one-or-more modifiers do require backtracking. For example, take the following regular expression:

```
(aa|aaa)+
```

This expression should be able to greedily match a string of seven `a`

's: there are several ways to add up 2 and 3 to get 7. But to get there, reconsidering earlier iterations is necessary. For instance, if the expression matches three `a`

's the first time and three `a`

's the second time, only one `a`

remains, which cannot be matched. Backtrack the last three `a`

's and match two `a`

's instead, however, and five `a`

's are matched. Then the last two `a`

's can be matched too (i.e., 3 + 2 + 2 = 7).

Fortunately, the regular expression quits its search once it has matched the string. But what about an EBNF parser? If the grammar is ambiguous, the parser is to use backtracking to find **all possible syntax trees**! If we have the production

```
( "aa" | "aaa" )*
```

and a string of seven `a`

's, a fully backtracking parser would return all possible ways of expressing 7 in terms of 2 and 3. And that's just for seven `a`

's: match a slightly longer string, and the *N*-ary tree of possibilities grows another *level*. Consider *N* = 6:

```
S : ( T )*
;
T : A
| B
| C
| D
| E
| F
;
```

A terrifying combinatorial explosion!

Could this *really* be the case, though? Are there no restrictions on the zero-or-more and one-or-more modifiers in EBNF? Implementing them as described would be a lot more work than the plain `while()`

loop of the PEG parser, so I have to wonder ...