The goal of this library is to provide parser combinators that:
- are optimized for LL(1) grammars,
- support streaming input,
- do as little buffering or copying as possible, and
- do as little dynamic method dispatch as possible.
It is based on:
- Monadic Parsing in Haskell by G. Hutton and E. Meijer, JFP 8(4) pp. 437-444,
- Nom, eating data byte by byte by G. Couprie.
Rustdoc | Video | Slides | Crate | CI
extern crate parsell;
use parsell::{character,Parser,UncommittedStr,StatefulStr};
use parsell::ParseResult::{Done,Continue};
#[allow(non_snake_case)]
fn main() {
// A sequence of alphanumerics, saved in a string buffer
let ALPHANUMERIC = character(char::is_alphanumeric);
let ALPHANUMERICS = ALPHANUMERIC.plus(String::new);
// If you provide unmatching input to the parser, you'll get back a None response:
match ALPHANUMERICS.init_str("!$?") {
None => (),
_ => panic!("Can't happen."),
}
// If you provide complete input to the parser, you'll get back a Done response:
match ALPHANUMERICS.init_str("abc123!") {
Some(Done(result)) => assert_eq!(result, "abc123"),
_ => panic!("Can't happen."),
}
// If you provide incomplete input to the parser, you'll get back a Continue response:
match ALPHANUMERICS.init_str("abc") {
Some(Continue(parsing)) => match parsing.more_str("123!") {
Done(result) => assert_eq!(result, "abc123"),
_ => panic!("Can't happen."),
},
_ => panic!("Can't happen."),
}
}
Example tested with Skeptic.