lexer! {
// First line specifies name of the lexer and the token type returned by
// semantic actions
Lexer -> Token;
// Regular expressions can be named with `let` syntax
let init = ['a'-'z'];
let subseq = $init | ['A'-'Z' '0'-'9' '-' '_'];
// Rule sets have names. Each rule set is compiled to a separate DFA.
// Switching between rule sets is done explicitly in semantic actions.
rule Init {
// Rules without a right-hand side for skipping whitespace,
// comments, etc.
[' ' '\t' '\n']+,
// Rule for matching identifiers
$init $subseq* => |lexer| {
let token = Token::Id(lexer.match_().to_owned());
lexer.return_(token)
},
}
}
// The token type
#[derive(Debug, PartialEq, Eq)]
enum Token {
// An identifier
Id(String),
}
// Generated lexers are initialized with a `&str` for the input
let mut lexer = Lexer::new(" abc123Q-t z9_9");
// Lexers implement `Iterator<Item=Result<(Loc, T, Loc), LexerError>>`,
// where `T` is the token type specified in the lexer definition (`Token` in
// this case), and `Loc`s indicate line, column, and byte indices of
// beginning and end of the lexemes.
assert_eq!(
lexer.next(),
Some(Ok((
Loc { line: 0, col: 1, byte_idx: 1 },
Token::Id("abc123Q-t".to_owned()),
Loc { line: 0, col: 10, byte_idx: 10 }
)))
);
assert_eq!(
lexer.next(),
Some(Ok((
Loc { line: 0, col: 12, byte_idx: 12 },
Token::Id("z9_9".to_owned()),
Loc { line: 0, col: 16, byte_idx: 16 }
)))
);
assert_eq!(lexer.next(), None);
See also:
- Simple lexer definitions in tests
- A full Lua 5.1 lexer
- An example that uses lexgen with LALRPOP
- A lexer for a simpler version of OCaml
Implementing lexing is often (along with parsing) the most tedious part of implementing a language. Lexer generators make this much easier, but in Rust existing lexer generators miss essential features for practical use, and/or require a pre-processing step when building.
My goal with lexgen is to have a feature-complete and easy to use lexer generator.
lexgen doesn't require a build step. Add same versions of lexgen
and
lexgen_util
as dependencies in your Cargo.toml
.
lexgen lexers start with type of the generated lexer struct, optional user state part, and the token type (type of values returned by semantic actions). Example:
lexer! {
Lexer(LexerState) -> Token;
...
}
Here the lexer struct is named Lexer
. User state type is LexerState
(this
type should be defined by the user). The token type is Token
.
Next is let bindings for regular expressions. These are optional. The syntax is
let <id> = <regex>;
where <id>
is a Rust identifier and regex is as
described below.
let init = ['a'-'z'];
let subseq = $init | ['A'-'Z' '0'-'9' '-' '_'];
Finally we define the lexer rules:
rule Init {
...
}
rule SomeOtherRule {
...
}
The first rule set will be defining the initial state of the lexer and needs to
be named Init
.
In the body of a rule
block we define the rules for that lexer state. The
syntax for a rule is <regex> => <semantic action>,
. Regex syntax is described
below. Semantic action is any Rust code with type fn(LexerHandle) -> LexerAction
where LexerHandle
and LexerAction
are generated names derived
from the lexer name (Lexer
). More on these types below.
You can omit the rule Init { ... }
part and have all of your rules at the top
level if you don't need rule sets.
In summary:
-
First line is in form
<lexer name>(<user state type>) -> <token type name>
. The(<user state type>)
part can be omitted for stateless lexers. -
Next we have let bindings for regexes. This part is optional.
-
Next is the rule sets. There should be at least one rule set with the name
Init
, which is the name of the initial state.
Regex syntax can be used in right-hand side of let bindings and left-hand side of rules. The syntax is:
-
$var
for variables defined in the let binding section. Variables need to be defined before used. -
$$var
for built-in regexes (see "Built-in regular expressions" section below). -
Rust character syntax for characters, e.g.
'a'
. -
Rust string syntax for strings, e.g.
"abc"
. -
[...]
for character sets. Inside the brackets you can have one or more of:- Characters
- Character ranges: e.g.
'a'-'z'
Here's an example character set for ASCII alphanumerics:
['a'-'z' 'A'-'Z' '0'-'9']
-
_
for matching any character -
$
for matching end-of-input -
<regex>*
for zero or more repetitions of<regex>
-
<regex>+
for one or more repetitions of<regex>
-
<regex>?
for zero or one repetitions of<regex>
-
<regex> <regex>
for concatenation -
<regex> | <regex>
for alternation: match the first one, or the second one. -
<regex> # <regex>
for difference: match characters in the first regex that are not in the second regex. Note that regexes on the left and right of#
should be "characters sets", i.e.*
,+
,?
,"..."
,$
, and concatenation are not allowed. Variables that are bound to character sets are allowed.
Binding powers (precedences), from higher to lower:
*
,+
,?
#
- Concatenation
|
You can use parenthesis for grouping, e.g. ('a' | 'b')*
.
Example: 'a' 'b' | 'c'+
is the same as (('a' 'b') | ('c'+))
.
A rule in a rule set can be followed by another regex using > <regex>
syntax,
for right context. Right context is basically a limited form of lookahead: they
can only appear after a top-level regex for a rule. They cannot be used nested
in a regex.
For example, the rule left-hand side 'a' > (_ # 'b')
matches 'a'
as long as
it's not followed by 'b'
.
See also right context tests for more examples.
lexgen comes with a set of built-in regular expressions. Regular
expressions listed below match the same set of characters as their Rust
counterparts. For example, $$alphabetic
matches the same set of characters as
Rust's char::is_alphabetic
:
$$alphabetic
$$alphanumeric
$$ascii
$$ascii_alphabetic
$$ascii_alphanumeric
$$ascii_control
$$ascii_digit
$$ascii_graphic
$$ascii_hexdigit
$$ascii_lowercase
$$ascii_punctuation
$$ascii_uppercase
$$ascii_whitespace
$$control
$$lowercase
$$numeric
$$uppercase
$$whitespace
(Note that in the generated code we don't use Rust char
methods. For simple
cases like $$ascii
we generate simple range checks. For more complicated
cases like $$lowercase
we generate a binary search table and run binary
search when checking a character)
In addition, these two built-in regular expressions match Unicode XID_Start and XID_Continue:
$$XID_Start
$$XID_Continue
-
<regex> => <semantic action>,
:<regex>
syntax is as described above.<semantic action>
is any Rust code with typefn(&mut Lexer) -> SemanticActionResult<Token>
. More onSemanticActionResult
type in the next section. -
<regex> =? <semantic action>,
: fallible actions. This syntax is similar to the syntax above, except<semantic action>
has typefn(&mut Lexer) -> LexerAction<Result<Token, UserError>>
. When using rules of this kind, the error type needs to be declared at the beginning of the lexer with thetype Error = UserError;
syntax.When a rule of this kind returns an error, the error is returned to the caller of the lexer's
next
method. -
<regex>,
: Syntactic sugar for<regex> => |lexer| lexer.continue_(),
. Useful for skipping characters (e.g. whitespace). -
<regex> = <token>,
: Syntactic sugar for<regex> => |lexer| lexer.return_(<token>),
. Useful for matching keywords, punctuation (operators) and delimiters (parens, brackets).
The lexer
macro generates a struct with the name specified by the user in the
first line of the lexer definition. In the example at the beginning (Lexer -> Token;
), name of the struct is Lexer
.
A mut reference to this type is passed to semantic action functions. In the implementation of a semantic action, you should use one of the methods below drive the lexer and return tokens:
fn match_(&self) -> &str
: returns the current match. Note that when the lexer is constructed withnew_from_iter
ornew_from_iter_with_state
, this method panics. It should only be called when the lexer is initialized withnew
ornew_with_state
.fn match_loc(&self) -> (lexgen_util::Loc, lexgen_util::Loc)
: returns the bounds of the current matchfn peek(&mut self) -> Option<char>
: looks ahead one characterfn state(&mut self) -> &mut <user state type>
: returns a mutable reference to the user statefn return_(&self, token: <user token type>) -> SemanticActionResult
: returns the passed token as a match.fn continue_(&self) -> SemanticActionResult
: ignores the current match and continues lexing in the same lexer state. Useful for skipping characters.fn switch(&mut self, rule: LexerRule) -> SemanticActionResult
: used for switching between lexer states. TheLexerRule
(whereLexer
part is the name of the lexer as specified by the user) is an enum with a variant for each rule set name, for example,LexerRule::Init
. See the stateful lexer example below.fn switch_and_return(&mut self, rule: LexerRule, token: <user token type>) -> SemanticActionResult
: switches to the given lexer state and returns the given token.fn reset_match(&mut self)
: resets the current match. E.g. if you callmatch_()
right afterreset_match()
it will return an empty string.
Semantic action functions should return a SemanticActionResult
value obtained
from one of the methods listed above.
lexgen generates 4 constructors:
-
fn new(input: &str) -> Self
: Used when the lexer does not have user state, or user state implementsDefault
. -
fn new_with_state(input: &str, user_state: S) -> Self
: Used when the lexer has user state that does not implementDefault
, or you want to initialize the state with something other than the default.S
is the user state type specified in lexer definition. See stateful lexer example below. -
fn new_from_iter<I: Iterator<Item = char> + Clone>(iter: I) -> Self
: Used when the input isn't a flat string, but something like a rope or zipper. Note that thematch_
method panics when this constructor is used. Instead usematch_loc
to get the location of the current match. -
fn new_from_iter_with_state<I: Iterator<Item = char> + Clone, S>(iter: I, user_state: S) -> Self
: Same as above, but doesn't require user state to implementDefault
.
Here's an example lexer that counts number of =
s appear between two [
s:
lexer! {
// `usize` in parenthesis is the user state type, `usize` after the arrow
// is the token type
Lexer(usize) -> usize;
rule Init {
$$ascii_whitespace, // line 7
'[' => |lexer| {
*lexer.state() = 0; // line 10
lexer.switch(LexerRule::Count) // line 11
},
}
rule Count {
'=' => |lexer| {
*lexer.state() += 1; // line 17
lexer.continue_() // line 18
},
'[' => |lexer| {
let n = *lexer.state();
lexer.switch_and_return(LexerRule::Init, n) // line 23
},
}
}
let mut lexer = Lexer::new("[[ [=[ [==[");
assert_eq!(
lexer.next(),
Some(Ok((
Loc { line: 0, col: 0, byte_idx: 0 },
0,
Loc { line: 0, col: 2, byte_idx: 2 },
)))
);
assert_eq!(
lexer.next(),
Some(Ok((
Loc { line: 0, col: 3, byte_idx: 3 },
1,
Loc { line: 0, col: 6, byte_idx: 6 },
)))
);
assert_eq!(
lexer.next(),
Some(Ok((
Loc { line: 0, col: 7, byte_idx: 7 },
2,
Loc { line: 0, col: 11, byte_idx: 11 },
)))
);
assert_eq!(lexer.next(), None);
Initially (the Init
rule set) we skip spaces (line 7). When we see a [
we
initialize the user state (line 10) and switch to the Count
state (line 11).
In Count
, each =
increments the user state by one (line 17) and skips the
match (line 18). A [
in Count
state returns the current number and switches
to the Init
state (line 23).