Crate combine [−] [src]

This crate contains parser combinators, roughly based on the Haskell libraries parsec and attoparsec.

A parser in this library can be described as a function which takes some input and if it is successful, returns a value together with the remaining input. A parser combinator is a function which takes one or more parsers and returns a new parser. For instance the many parser can be used to convert a parser for single digits into one that parses multiple digits. By modeling parsers in this way it becomes easy to compose complex parsers in an almost declarative way.

Overview

combine limits itself to creating LL(1) parsers (it is possible to opt-in to LL(k) parsing using the try combinator) which makes the parsers easy to reason about in both function and performance while sacrificing some generality. In addition to you being able to reason better about the parsers you construct combine the library also takes the knowledge of being an LL parser and uses it to automatically construct good error messages.

extern crate combine;
use combine::Parser;
use combine::stream::state::State;
use combine::parser::char::{digit, letter};
const MSG: &'static str = r#"Parse error at line: 1, column: 1
Unexpected `|`
Expected `digit` or `letter`
"#;

fn main() {
    // Wrapping a `&str` with `State` provides automatic line and column tracking. If `State`
    // was not used the positions would instead only be pointers into the `&str`
    if let Err(err) = digit().or(letter()).easy_parse(State::new("|")) {
        assert_eq!(MSG, format!("{}", err));
    }
}

This library is currently split into a few core modules:

parser is where you will find all the parsers that combine provides. It contains the core Parser trait as well as several submodules such as sequence or choice which each contain several parsers aimed at a specific niche.
stream contains the second most important trait next to Parser. Streams represent the data source which is being parsed such as &[u8], &str or iterators.
easy contains combine's default "easy" error and stream handling. If you use the easy_parse method to start your parsing these are the types that are used.
error contains the types and traits that make up combine's error handling. Unless you need to customize the errors your parsers return you should not need to use this module much.

Examples

extern crate combine;
use combine::parser::char::{spaces, digit, char};
use combine::{many1, sep_by, Parser};
use combine::stream::easy;

fn main() {
    //Parse spaces first and use the with method to only keep the result of the next parser
    let integer = spaces()
        //parse a string of digits into an i32
        .with(many1(digit()).map(|string: String| string.parse::<i32>().unwrap()));

    //Parse integers separated by commas, skipping whitespace
    let mut integer_list = sep_by(integer, spaces().skip(char(',')));

    //Call parse with the input to execute the parser
    let input = "1234, 45,78";
    let result: Result<(Vec<i32>, &str), easy::ParseError<&str>> =
        integer_list.easy_parse(input);
    match result {
        Ok((value, _remaining_input)) => println!("{:?}", value),
        Err(err) => println!("{}", err)
    }
}

If we need a parser that is mutually recursive or if we want to export a reusable parser the parser! macro can be used. In effect it makes it possible to return a parser without naming the type of the parser (which can be very large due to combine's trait based approach). While it is possible to do avoid naming the type without the macro those solutions require either allocation (Box<Parser<Input = I, Output = O, PartialState = P>>) or nightly rust via impl Trait. The macro thus threads the needle and makes it possible to have non-allocating, anonymous parsers on stable rust.

#[macro_use]
extern crate combine;
use combine::parser::char::{char, letter, spaces};
use combine::{between, many1, parser, sep_by, Parser};
use combine::error::ParseResult;
use combine::stream::{Stream, Positioned};
use combine::stream::state::State;

#[derive(Debug, PartialEq)]
pub enum Expr {
    Id(String),
    Array(Vec<Expr>),
    Pair(Box<Expr>, Box<Expr>)
}

// The `parser!` macro can be used to define parser producing functions in most cases
// (for more advanced uses standalone functions or explicit implementation of `Parser`
// can be done to handle parsing)
parser!{
   fn expr[I]()(I) -> Expr
    where [I: Stream<Item=char>]
{
    let word = many1(letter());

    //Creates a parser which parses a char and skips any trailing whitespace
    let lex_char = |c| char(c).skip(spaces());

    let comma_list = sep_by(expr(), lex_char(','));
    let array = between(lex_char('['), lex_char(']'), comma_list);

    //We can use tuples to run several parsers in sequence
    //The resulting type is a tuple containing each parsers output
    let pair = (lex_char('('),
                expr(),
                lex_char(','),
                expr(),
                lex_char(')'))
                   .map(|t| Expr::Pair(Box::new(t.1), Box::new(t.3)));

    word.map(Expr::Id)
        .or(array.map(Expr::Array))
        .or(pair)
        .skip(spaces())
}
}

fn main() {
    let result = expr()
        .parse("[[], (hello, world), [rust]]");
    let expr = Expr::Array(vec![
          Expr::Array(Vec::new())
        , Expr::Pair(Box::new(Expr::Id("hello".to_string())),
                     Box::new(Expr::Id("world".to_string())))
        , Expr::Array(vec![Expr::Id("rust".to_string())])
    ]);
    assert_eq!(result, Ok((expr, "")));
}

Re-exports

pub extern crate byteorder;

pub extern crate either;

Modules

easy	Stream wrapper which provides an informative and easy to use error type.
error	Error types and traits which define what kind of errors combine parsers may emit
parser	A collection of both concrete parsers as well as parser combinators.
stream	Traits and implementations of arbitrary data streams.

Macros

choice	Takes a number of parsers and tries to apply them each in order. Fails if all the parsers fails or if an applied parser consumes input before failing.
parser	Declares a named parser which can easily be reused.
struct_parser	Sequences multiple parsers and builds a struct out of them.

Traits

ParseError	Trait which defines a combine parse error.
Parser	By implementing the `Parser` trait a type says that it can be used to parse an input stream into the type `Output`.
Positioned	A type which has a position.
RangeStream	A `RangeStream` is an extension of `Stream` which allows for zero copy parsing.
RangeStreamOnce	A `RangeStream` is an extension of `StreamOnce` which allows for zero copy parsing.
Stream	A stream of tokens which can be duplicated
StreamOnce	`StreamOnce` represents a sequence of items that can be extracted one by one.

Functions

any	Parses any token.
between	Parses `open` followed by `parser` followed by `close`. Returns the value of `parser`.
chainl1	Parses `p` 1 or more times separated by `op`. The value returned is the one produced by the left associative application of the function returned by the parser `op`.
chainr1	Parses `p` one or more times separated by `op`. The value returned is the one produced by the right associative application of the function returned by `op`.
choice	Takes a tuple, a slice or an array of parsers and tries to apply them each in order. Fails if all the parsers fails or if an applied parser consumes input before failing.
count	Parses `parser` from zero up to `count` times.
count_min_max	Parses `parser` from `min` to `max` times (including `min` and `max`).
env_parser	Constructs a parser out of an environment and a function which needs the given environment to do the parsing. This is commonly useful to allow multiple parsers to share some environment while still allowing the parsers to be written in separate functions.
eof	Succeeds only if the stream is at end of input, fails otherwise.
look_ahead	`look_ahead(p)` acts as `p` but doesn't consume input on success.
many	Parses `p` zero or more times returning a collection with the values from `p`.
many1	Parses `p` one or more times returning a collection with the values from `p`.
none_of	Extract one token and succeeds if it is not part of `tokens`.
not_followed_by	Succeeds only if `parser` fails. Never consumes any input.
one_of	Extract one token and succeeds if it is part of `tokens`.
optional	Parses `parser` and outputs `Some(value)` if it succeeds, `None` if it fails without consuming any input. Fails if `parser` fails after having consumed some input.
parser	Wraps a function, turning it into a parser.
position	Parser which just returns the current position in the stream.
satisfy	Parses a token and succeeds depending on the result of `predicate`.
satisfy_map	Parses a token and passes it to `predicate`. If `predicate` returns `Some` the parser succeeds and returns the value inside the `Option`. If `predicate` returns `None` the parser fails without consuming any input.
sep_by	Parses `parser` zero or more time separated by `separator`, returning a collection with the values from `p`.
sep_by1	Parses `parser` one or more time separated by `separator`, returning a collection with the values from `p`.
sep_end_by	Parses `parser` zero or more times separated and ended by `separator`, returning a collection with the values from `p`.
sep_end_by1	Parses `parser` one or more times separated and ended by `separator`, returning a collection with the values from `p`.
skip_count	Parses `parser` from zero up to `count` times skipping the output of `parser`.
skip_count_min_max	Parses `parser` from `min` to `max` times (including `min` and `max`) skipping the output of `parser`.
skip_many	Parses `p` zero or more times ignoring the result.
skip_many1	Parses `p` one or more times ignoring the result.
token	Parses a character and succeeds if the character is equal to `c`.
tokens	Parses multiple tokens.
try	`try(p)` behaves as `p` except it acts as if the parser hadn't consumed any input if `p` fails after consuming input.
unexpected	Always fails with `message` as an unexpected error. Never consumes any input.
value	Always returns the value `v` without consuming any input.

Type Definitions

ConsumedResult	A `Result` type which has the consumed status flattened into the result. Conversions to and from `std::result::Result` can be done using `result.into()` or `From::from(result)`
ParseResult	A type alias over the specific `Result` type used by parsers to indicate whether they were successful or not. `O` is the type that is output on success. `I` is the specific stream type used in the parser.