Expand description
Logos
Create ridiculously fast Lexers.
Logos has two goals:
- To make it easy to create a Lexer, so you can focus on more complex problems.
- To make the generated Lexer faster than anything you’d write by hand.
To achieve those, Logos:
- Combines all token definitions into a single deterministic state machine.
- Optimizes branches into lookup tables or jump tables.
- Prevents backtracking inside token definitions.
- Unwinds loops, and batches reads to minimize bounds checking.
- Does all of that heavy lifting at compile time.
Example
use logos::Logos;
#[derive(Logos, Debug, PartialEq)]
enum Token {
// Tokens can be literal strings, of any length.
#[token("fast")]
Fast,
#[token(".")]
Period,
// Or regular expressions.
#[regex("[a-zA-Z]+")]
Text,
// Logos requires one token variant to handle errors,
// it can be named anything you wish.
#[error]
// We can also use this variant to define whitespace,
// or any other matches we wish to skip.
#[regex(r"[ \t\n\f]+", logos::skip)]
Error,
}
fn main() {
let mut lex = Token::lexer("Create ridiculously fast Lexers.");
assert_eq!(lex.next(), Some(Token::Text));
assert_eq!(lex.span(), 0..6);
assert_eq!(lex.slice(), "Create");
assert_eq!(lex.next(), Some(Token::Text));
assert_eq!(lex.span(), 7..19);
assert_eq!(lex.slice(), "ridiculously");
assert_eq!(lex.next(), Some(Token::Fast));
assert_eq!(lex.span(), 20..24);
assert_eq!(lex.slice(), "fast");
assert_eq!(lex.next(), Some(Token::Text));
assert_eq!(lex.slice(), "Lexers");
assert_eq!(lex.span(), 25..31);
assert_eq!(lex.next(), Some(Token::Period));
assert_eq!(lex.span(), 31..32);
assert_eq!(lex.slice(), ".");
assert_eq!(lex.next(), None);
}Callbacks
Logos can also call arbitrary functions whenever a pattern is matched, which can be used to put data into a variant:
use logos::{Logos, Lexer};
// Note: callbacks can return `Option` or `Result`
fn kilo(lex: &mut Lexer<Token>) -> Option<u64> {
let slice = lex.slice();
let n: u64 = slice[..slice.len() - 1].parse().ok()?; // skip 'k'
Some(n * 1_000)
}
fn mega(lex: &mut Lexer<Token>) -> Option<u64> {
let slice = lex.slice();
let n: u64 = slice[..slice.len() - 1].parse().ok()?; // skip 'm'
Some(n * 1_000_000)
}
#[derive(Logos, Debug, PartialEq)]
enum Token {
#[regex(r"[ \t\n\f]+", logos::skip)]
#[error]
Error,
// Callbacks can use closure syntax, or refer
// to a function defined elsewhere.
//
// Each pattern can have it's own callback.
#[regex("[0-9]+", |lex| lex.slice().parse())]
#[regex("[0-9]+k", kilo)]
#[regex("[0-9]+m", mega)]
Number(u64),
}
fn main() {
let mut lex = Token::lexer("5 42k 75m");
assert_eq!(lex.next(), Some(Token::Number(5)));
assert_eq!(lex.slice(), "5");
assert_eq!(lex.next(), Some(Token::Number(42_000)));
assert_eq!(lex.slice(), "42k");
assert_eq!(lex.next(), Some(Token::Number(75_000_000)));
assert_eq!(lex.slice(), "75m");
assert_eq!(lex.next(), None);
}Logos can handle callbacks with following return types:
| Return type | Produces |
|---|---|
() | Token::Unit |
bool | Token::Unit or <Token as Logos>::ERROR |
Result<(), _> | Token::Unit or <Token as Logos>::ERROR |
T | Token::Value(T) |
Option<T> | Token::Value(T) or <Token as Logos>::ERROR |
Result<T, _> | Token::Value(T) or <Token as Logos>::ERROR |
Skip | skips matched input |
Filter<T> | Token::Value(T) or skips matched input |
Callbacks can be also used to do perform more specialized lexing in place
where regular expressions are too limiting. For specifics look at
Lexer::remainder and
Lexer::bump.
Token disambiguation
Rule of thumb is:
- Longer beats shorter.
- Specific beats generic.
If any two definitions could match the same input, like fast and [a-zA-Z]+
in the example above, it’s the longer and more specific definition of Token::Fast
that will be the result.
This is done by comparing numeric priority attached to each definition. Every consecutive, non-repeating single byte adds 2 to the priority, while every range or regex class adds 1. Loops or optional blocks are ignored, while alternations count the shortest alternative:
[a-zA-Z]+has a priority of 1 (lowest possible), because at minimum it can match a single byte to a class.foobarhas a priority of 12.(foo|hello)(bar)?has a priority of 6,foobeing it’s shortest possible match.
Re-exports
pub use crate::source::Source;Modules
This module contains a bunch of traits necessary for processing byte strings.
Structs
Lexer is the main struct of the crate that allows you to read through a
Source and produce tokens for enums implementing the Logos trait.Type that can be returned from a callback, informing the
Lexer, to skip
current token match. See also logos::skip.Iterator that pairs tokens with their position in the source.
Enums
Type that can be returned from a callback, either producing a field
for a token, or skipping it.
Type that can be returned from a callback, either producing a field
for a token, skipping it, or emitting an error.
Traits
Trait implemented for an enum representing all tokens. You should never have
to implement it manually, use the
#[derive(Logos)] attribute on your enum.Functions
Predefined callback that will inform the
Lexer to skip a definition.Type Definitions
Byte range in the source.