I was drawn to Raku due to its built-in grammars and figured I'd play around with it and write a simple email address parser, only problem: I couldn't get it to work.

I tried countless iterations before landing on something that actually works, and I'm struggling to understand why.

All it boiled down to, was changing token to rule.

Here's my example code:

grammar Email {
  token TOP { <name> '@' [<subdomain> '.']* <domain> '.' <tld> }  
  token name { \w+ ['.' \w+]* }
  token domain { \w+ }
  token subdomain { \w+ }
  token tld { \w+ }
say Email.parse('foo.bar@baz.example.com');

doesn't work, it simply prints Nil, but

grammar Email {
  rule TOP { <name> '@' [<subdomain> '.']* <domain> '.' <tld> }  
  token name { \w+ ['.' \w+]* }
  token domain { \w+ }
  token subdomain { \w+ }
  token tld { \w+ }
say Email.parse('foo.bar@baz.example.com');

does work and correctly prints

 name => 「foo.bar」
 subdomain => 「baz」
 domain => 「example」
 tld => 「com」

And all I changed was token TOP to rule TOP.

From what I can gather from the documentation, the only difference between those two keywords, is that whitespace is significant in rule, but isn't in token. If that's true, the first example should work, as I want to ignore the whitespace between the individual pieces of the pattern.

Removing the spaces between the pieces

rule TOP { <name>'@'[<subdomain>'.']*<domain>'.'<tld> }

reverts the behaviour back to printing Nil.

Anyone able to clue me in on what's going on here?

EDIT: Changing the TOP rule to a regex instead, which allows for backtracking makes it work too.

The question still remains, how come rule { } (which is the same as regex {:ratchet :sigspace }) matches when token { } (which is the same as regex {:ratchet }) doesn't?

The email address doesn't have any spaces in it, so for all intents and purposes it should fail right away

  • 2
    @raiph I added [context-free-grammar] because I originally didn't know any better. A few hours later I had read more up on it all, and you're right, it is closer to unrestricted grammar – Electric Coffee May 28 at 6:34

Your SO demonstrates an extraordinary bug. See JJ's answer for the issue he's filed to follow up on it. I've moved my notes about it to the last section of this answer.

Putting the bug aside, your grammar directs Raku to not match your input:

  • The [<subdomain> '.']* atom eagerly consumes the string 'baz.example.' from your input;

  • The remaining input ('com') fails to match the remaining atoms (<domain> '.' <tld>);

  • The :ratchet that's in effect for tokens means the [<subdomain> '.']* atom does not backtrack;

  • Thus the overall match fails.

The simple solution to make your grammar work is to append ! to the [<subdomain> '.']* pattern in your token.

This directs Raku to enable backtracking for that atom, i.e. drop the last of the [<subdomain> '.'] match repetitions if any of the remainder of the token fails to match, and try again, and then drop another if need be, until either the rest of the token matches or there are no matches of [<subdomain> '.'] left.

The rest of this answer discusses other aspects.

Playing with Raku, developing grammars, and debugging

Nil is fine as a response from a grammar that is known (or thought) to work fine, and you don't want any more useful response in the event of a parse fail.

For any other scenario there are much better options, as summarized in my answer to How can error reporting in grammars be improved?.

In particular, for playing around, or developing a grammar, or debugging one, the best option by far is to install the free Comma and use its Grammar Live View feature.

What are Raku Rules / grammars?

You originally added a [context-free-grammar] tag to your question. This made sense; you were "playing around", and Raku's parsing DSL uses a variant of BNF as part of its syntax.

But, formally speaking, Raku grammars are analytic, not generative.

The most well known analytic grammar formalism is Parsing Expression Grammars (PEGs). While Raku grammars are fully general (turing complete) and a much richer formalism than PEGs, the Introduction section of Wikipedia's PEG page serves well as a framework for understanding Raku grammars as well. The following quotes that introduction in full, alternating between sentences about PEG and notes about how Raku's grammars differ:

In computer science, a parsing expression grammar (PEG) is a type of analytic formal grammar, i.e. it describes a formal language in terms of a set of rules for recognizing strings in the language.

It's tempting to use "parsing expression grammars" as a generic term that covers Raku Rules as well as PEGs. This helps place them in the right formal category (analytic rather than generative). But it's ill-advised because Raku Rules are quite unlike Bryan Ford's formalism in theory, practice, capabilities, and features.

The formalism was introduced by Bryan Ford in 2004 and is closely related to the family of top-down parsing languages introduced in the early 1970s.

Raku Rules were first described in 2002 (but not fully implemented until recently). They also draw from top down parsing techniques but combine them with: formal regular expressions; Perl style regex features; a BNF-like gloss; turing complete recursive descent with backtracking (cf parser combinators); Longest Token Matching (discussed below); Raku's other language features; and tight bidirectional integration with third party languages by inlining code via Inlines.

Syntactically, PEGs also look similar to context-free grammars (CFGs), but they have a different interpretation: the choice operator selects the first match in PEG, while it is ambiguous in CFG. This is closer to how string recognition tends to be done in practice, e.g. by a recursive descent parser.

A subset of Rules syntax also looks similar to context-free grammars (CFGs), but, like all the DSLs that make up the Raku braid, the standard grammar DSL embeds within it all the other DSLs. So, while many grammars look like CFGs, others look very different.

Unlike PEGs, whose only choice operation is based on the lexical ordering of rules, Raku Rules support two major improvements. First is multiple dispatch; one rule can call another with arguments, and the receiving rule is selected by type or value based multiple dispatch resolution. Second is Longest Token Matching (LTM). LTM models an important aspect of how humans process language, and automatically turns it into an efficient NFA based approach to tokenizing.

Unlike CFGs, PEGs cannot be ambiguous; if a string parses, it has exactly one valid parse tree.

Raku grammars are also never ambiguous. This is important if a language's overall grammar and rules are to be composed together from sub-languages, and automatically turned into a parser. While individual CFGs can be individually manually proven unambiguous by humans, unambiguous CFGs do not compose in a CS sense -- that is to say, composition may produce ambiguous CFGs, and it's known that there is no algorithm that can detect this, let alone fix it.

It is conjectured that there exist context-free languages that cannot be recognized by a PEG, but this is not yet proven.

Raku Rules are turing complete. Thus, if a language, context-free or otherwise, cannot be recognized by a Raku grammar, then it cannot be recognized, period. See unrestricted grammars.

PEGs are well-suited to parsing computer languages (and artificial human languages such as Lojban), but not natural languages where the performance of PEG algorithms is comparable to general CFG algorithms such as the Earley algorithm.

In theory, Raku Rules performance corresponds to recursive descent parsing for the non-terminal rules, NFA processing for LTM, and whatever backtracking a grammar specifies. In practice, it's considered fast enough by core devs, which in practice means it hasn't been optimized, despite hints in recent years (1, 2), that it might be, leaving it a lot slower than existing fast parsing solutions.

Fixing your grammar

Your grammar suggests two three options1:

  • Parse forwards with some backtracking.

  • Parse backwards. Write the pattern in reverse, and reverse the input and output.

  • Post parse the parse.

Parse forwards with backtracking

Backtracking is a reasonable approach for parsing some patterns. But it is best minimized to maximize performance, and carries DoS risks if written carelessly.2

To switch on backtracking for an entire token, just switch the declarator to regex instead. A regex is just like a token but specifically enables backtracking like a traditional regex.

Another option is to stick with token and limit the part of the pattern that might backtrack. One way to do that is to append a ! after an atom to let it backtrack, explicitly overriding the token's overall ratchet for that atom:

token TOP { <name> '@' [<subdomain> '.']*! <domain> '.' <tld> }

An alternative to ! is to insert :!ratchet to switch "ratcheting" off for a part of a rule, and then :ratchet to switch ratcheting back on again, eg:

token TOP { <name> '@' :!ratchet [<subdomain> '.']* :ratchet <domain> '.' <tld> }  

You can also use r as an abbreviation for ratchet, i.e. :!r and :r.

Parse backwards

A classic parsing trick that works for some scenarios, is to parse backwards as a way to avoid backtracking.

grammar Email {
  token TOP { <tld> '.' <domain> ['.' <subdomain> ]* '@' <name> }  
  token name { \w+ ['.' \w+]* }
  token domain { \w+ }
  token subdomain { \w+ }
  token tld { \w+ }
say Email.parse(flip 'foo.bar@baz.example.com').hash>>.flip;
#{domain => example, name => foo.bar, subdomain => [baz], tld => com}

Probably too complicated for most folks' needs but I thought I'd include it in my answer.

Post parse the parse

In the above I presented a solution that introduces some backtracking, and another that avoids it but with significant costs in terms of ugliness, cognitive load etc. (parsing backwards?!?).

There's another very important technique that I overlooked until reminded by JJ's answer.1 Just parse the results of the parse.

Here's one way. I've completely restructured the grammar, partly to make more sense of this way of doing things, and partly to demonstrate some Raku grammar features:

grammar Email {
  token TOP {
              <dotted-parts(1)> '@'
    $<host> = <dotted-parts(2)>
  token dotted-parts(\min) { <parts> ** {min..*} % '.' }
  token parts { \w+ }
say Email.parse('foo.bar@baz.buz.example.com')<host><parts>


[「baz」 「buz」 「example」 「com」]

While this grammar matches the same strings as yours, and post-parses like JJ's, it's obviously very different:

  • The grammar is reduced to three tokens.

  • The TOP token makes two calls to a generic dotted-parts token, with an argument specifying the minimum number of parts.

  • $<host> = ... captures the following atom under the name <host>. This is typically redundant if the atom is itself a named pattern, as it is in this case -- <dotted-parts>. But "dotted-parts" is rather generic; and to refer to the second match of it (the first comes before the @), we'd need to write <dotted-parts>[1]. So I've tidied up by naming it <host>.

  • The dotted-parts pattern may look a bit challenging but it's actually pretty simple. It uses a quantifier clause (** {min..max}) to express any number of parts provided it's at least the minimum, and a modifier clause (% <separator>) which says there must be a dot between each part.

  • <host><parts> extracts from the parse tree the captured data associated with the parts token of the second use in the TOP rule of dotted-parts. Which is an array: [「baz」 「buz」 「example」 「com」].

Sometimes one wants some or all of the the reparsing to happen during the parsing, so that reparsed results are ready when a call to .parse completes.

JJ has shown one way to code what are called actions. He wrote named methods in a class, and then told the parsing to use that class, and the outcome was that each action method was called if a rule with the corresponding name had successfully arrived at the end of its call (the action method is called while the rule remains on the call stack). The action method is passed the match object captured by the rule, and can do whatever it likes, including reparsing what just got matched.

I want to show another way to achieve a somewhat similar effect to JJ's code. I'll build on the grammar above:

grammar Email {
  token TOP {
              <dotted-parts(1)> '@'
    $<host> = <dotted-parts(2)>

    # The new bit:
      make (subs => .[ 0 .. *-3 ],
            dom  => .[      *-2 ],
            tld  => .[      *-1 ])

      given $<host><parts>

  token dotted-parts(\min) { <parts> ** {min..*} % '.' }
  token parts { \w+ }
.say for Email.parse('foo.bar@baz.buz.example.com') .made;


subs => (「baz」 「buz」)
dom => 「example」
tld => 「com」


  • I've directly inlined the code doing the reparsing. One can insert arbitary code blocks ({...}) anywhere one could otherwise insert an atom. (In the days before we had grammar debuggers a classic use case was { say $/ } which prints $/, the match object, as it is at the point the code block appears.)

  • If a code block is put at the end of a rule, as I have done, it is almost equivalent to an action method. It will be called when the rule has otherwise completed, and $/ is already fully populated. In some scenarios inlining an anonymous action block is the way to go. In others, breaking it out into a named method in an action class like JJ did is better.

  • make is a major use case for action code. All make does is store its argument in the .made attribute of $/, which in this context is the current parse tree node. (Results stored by make are automatically thrown away if backtracking subsequently throws away the enclosing parse node. Often that's precisely what one wants.)

  • foo => bar forms a Pair.

  • The postcircumfix [...] operator indexes its invocant. In this case there's just a prefix . without an explicit LHS so the invocant is "it", as setup by the given, i.e. $<host><parts>. The * in *-n is the invocant's length; so [ 0 .. *-3 ] is all but the last two elements of $<host><parts>.

  • The .say for ... line ends in .made3, to pick up the maked value. The value my make code stores is a list of three pairs breaking out $<host><parts>.

The bug

See JJ's answer for an issue filed in response to your SO.

Golfing the problem, this seems wrong:

say 'a' ~~ rule  { .* a } # 「a」

More generally, I thought the only difference between a token and a rule was that the latter injects a <.ws> at each significant space. But that would mean this should work:

token TOP { <name> <.ws> '@' <.ws> [<subdomain> <.ws> '.']* <.ws>
            <domain> <.ws> '.' <.ws> <tld> <.ws>

But it doesn't...


1 I had truly thought my first two options were the two main ones available. It's been around 30 years since I encountered Tim Toady online. You'd think by now I'd have learned by heart his eponymous aphorism -- There Is More Than One Way To Do It!

2 Beware "pathological backtracking". In a production context, if you have suitable control of your input, or the system your program runs on, you may not have to worry about deliberate or accidental DoS attacks because they either can't happen, or will uselessly take down a system that's rebootable in the event of being rendered unavailable. But if you do need to worry, i.e. the parsing is running on a box that needs to be protected from a DoS attack, then an assessment of the threat is prudent. (Read Details of the Cloudflare outage on July 2, 2019 to get a real sense of what can go wrong.) If you are running Raku parsing code in such a demanding production environment then you would need to audit by searching for any use of regex, :!r, or *!.

3 There's an alias for .made; it's .ast. I think it stands for A Sparse Tree or Annotated Subset Tree and there's a cs.stackexchange.com question that agrees with me.

| improve this answer | |

Edit: this is probably a bug, so the straight answer to the question is whitespace interpretation (in some restricted ways), although the answer in this case seems to be "ratcheting". It shouldn't be, however, and it only happens sometimes, which is why the bug report has been created. Thanks a lot for the question. Anyway, find below a different (and not possibly buggy) way to solve the grammar problem.

It's probably good to use Grammar::Tracer to check what's going on, just download it and put use Grammar::Tracer at the top. In the first case: Grammar with token

Tokens don't backtrack, so the <domain> token is gobbling up everything until it fails. Let's see what's going on with a rule

Grammar with rule

It does backtrack in this case. Which is surprising, since, well, it should not, according to the definition (and whitespace should be significant)

What can you do? It's probably better if you take into account backtracking when dividing the host.

use Grammar::Tracer;

grammar Email {
  token TOP { <name> '@' <host> }  
  token name { \w+ ['.' \w+]* }
    token host { [\w+] ** 2..* % '.' }
say Email.parse('foo.bar@baz.example.com');

Here we make sure that we have at least two fragments, divided by a period.

And then you use actions to divide between the different parts of the host

grammar Email {
  token TOP { <name> '@' <host> }  
  token name { \w+ ['.' \w+]* }
  token host { [\w+] ** 2..* % '.' }

class Email-Action {
    method TOP ($/) {
    my %email;
    %email<name> = $/<name>.made;
    my @fragments = $/<host>.made.split("\.");
    %email<tld> = @fragments.pop;
    %email<domain> = @fragments.pop;
    %email<subdomain> = @fragments.join(".") if @fragments;
    make %email;

    method name ($/) { make $/ }
    method host ($/) { make $/ }
say Email.parse('foo.bar@baz.example.com', actions => Email-Action.new).made;

We pop twice since we know that, at least, we have a TLD and a domain; if there's anything left, it goes to subdomains. This will print, for this

say Email.parse('foo.bar@baz.example.com', actions => Email-Action.new).made;
say Email.parse('foo@example.com', actions => Email-Action.new).made;
say Email.parse('foo.bar.baz@quux.zuuz.example.com', actions => Email-Action.new).made;

The correct answer:

{domain => example, name => 「foo.bar」, subdomain => baz, tld => com}
{domain => example, name => 「foo」, tld => com}
{domain => example, name => 「foo.bar.baz」, subdomain => quux.zuuz, tld => com}

Grammars are incredibly powerful, but also, with its depth-first search, somewhat difficult to debug and wrap your head around. But if there's a part that can be deferred to actions, which, besides, give you a ready-made data structure, why not use it?

I'm aware that does not really answer your question, why a token is behaving differently than a rule, and a rule is behaving as if it were a regex, not using whitespace and also doing ratcheting. I just don't know. The problem is that, in the way you have formulated your grammar, once it's gobbled up the period, it's not going to give it back. So either you somehow include the subdomain and domain in a single token so that it matches, or you will need a non-ratcheting environment like regexes (and, well, apparently rules too) to make it work. Take into account that token and regexes are very different things. They use the same notation and everything, but its behavior is totally different. I encourage you to use Grammar::Tracer or the grammar testing environment in CommaIDE to check the differences.

| improve this answer | |

As per the Raku docs:

  • Token methods are faster than regex methods and ignore whitespace. Token methods don't backtrack; they give up after the first possible match.
  • Rule methods are the same as token methods except whitespace is not ignored.

Not ignored means they are treated as syntax, rather than matched literally. They actually insert a <.ws>. See sigspace for more information about that.

| improve this answer | |
  • Yeah i know that, my original question also reflects the fact that I understand it doesn't ignore whitespace. But emails don't have whitespace, this shouldn't work! – Electric Coffee May 28 at 6:25
  • "emails don't have whitespace, this shouldn't work!" You're right it shouldn't work, but it's not because emails don't have whitespace. Raku is carefully designed with the intent of making things that are complicated in other languages become simple. One way to do that is pedagogical facilitation. ws is an examplar. The phrase "significant whitespace" is technically only about whitespace in the pattern, not input. Yes, the default ws can match whitespace. But it turns out that <ws> can also match where there is no whitespace! – raiph May 28 at 15:04
  • @raiph but if it matches where there's no whitespace, how can you then rely on it? If I want a rule constraint { NOT NULL | PRIMARY KEY } I don't want NOTNULL to be a valid match – Electric Coffee May 29 at 8:29
  • @ElectricCoffee ws's definition fits well with an average person's natural language intuition. So it's easy to rely on it if your intuition is an average person's intuition, and you're willing to go with your intuitive sense. Or if you're willing to look at the doc definition -- token { <!ww> \s* } -- and rely on that. rule constraint { NOT NULL | PRIMARY KEY } shouldn't match NOTNULL per intuition, and won't per the default ws rule. But rule { foo '@' bar } will match both foo @ bar and foo@bar. Should ws have been named otherwise? Pedagogical facilitators thought not. :) – raiph May 29 at 11:05
  • @raiph "rule constraint { NOT NULL | PRIMARY KEY } shouldn't match NOTNULL per intuition, and won't per the default ws rule. But rule { foo '@' bar } will matchboth foo @ bar and foo@bar" It's not at all obvious how the language would even distinguish between those two scenarios... – Electric Coffee May 30 at 7:46

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