third_party_rust_nom/examples/string.rs
2021-10-23 22:34:38 +02:00

187 lines
7.3 KiB
Rust
Raw Permalink Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

//! This example shows an example of how to parse an escaped string. The
//! rules for the string are similar to JSON and rust. A string is:
//!
//! - Enclosed by double quotes
//! - Can contain any raw unescaped code point besides \ and "
//! - Matches the following escape sequences: \b, \f, \n, \r, \t, \", \\, \/
//! - Matches code points like Rust: \u{XXXX}, where XXXX can be up to 6
//! hex characters
//! - an escape followed by whitespace consumes all whitespace between the
//! escape and the next non-whitespace character
#![cfg(feature = "alloc")]
use nom::branch::alt;
use nom::bytes::streaming::{is_not, take_while_m_n};
use nom::character::streaming::{char, multispace1};
use nom::combinator::{map, map_opt, map_res, value, verify};
use nom::error::{FromExternalError, ParseError};
use nom::multi::fold_many0;
use nom::sequence::{delimited, preceded};
use nom::IResult;
// parser combinators are constructed from the bottom up:
// first we write parsers for the smallest elements (escaped characters),
// then combine them into larger parsers.
/// Parse a unicode sequence, of the form u{XXXX}, where XXXX is 1 to 6
/// hexadecimal numerals. We will combine this later with parse_escaped_char
/// to parse sequences like \u{00AC}.
fn parse_unicode<'a, E>(input: &'a str) -> IResult<&'a str, char, E>
where
E: ParseError<&'a str> + FromExternalError<&'a str, std::num::ParseIntError>,
{
// `take_while_m_n` parses between `m` and `n` bytes (inclusive) that match
// a predicate. `parse_hex` here parses between 1 and 6 hexadecimal numerals.
let parse_hex = take_while_m_n(1, 6, |c: char| c.is_ascii_hexdigit());
// `preceded` takes a prefix parser, and if it succeeds, returns the result
// of the body parser. In this case, it parses u{XXXX}.
let parse_delimited_hex = preceded(
char('u'),
// `delimited` is like `preceded`, but it parses both a prefix and a suffix.
// It returns the result of the middle parser. In this case, it parses
// {XXXX}, where XXXX is 1 to 6 hex numerals, and returns XXXX
delimited(char('{'), parse_hex, char('}')),
);
// `map_res` takes the result of a parser and applies a function that returns
// a Result. In this case we take the hex bytes from parse_hex and attempt to
// convert them to a u32.
let parse_u32 = map_res(parse_delimited_hex, move |hex| u32::from_str_radix(hex, 16));
// map_opt is like map_res, but it takes an Option instead of a Result. If
// the function returns None, map_opt returns an error. In this case, because
// not all u32 values are valid unicode code points, we have to fallibly
// convert to char with from_u32.
map_opt(parse_u32, |value| std::char::from_u32(value))(input)
}
/// Parse an escaped character: \n, \t, \r, \u{00AC}, etc.
fn parse_escaped_char<'a, E>(input: &'a str) -> IResult<&'a str, char, E>
where
E: ParseError<&'a str> + FromExternalError<&'a str, std::num::ParseIntError>,
{
preceded(
char('\\'),
// `alt` tries each parser in sequence, returning the result of
// the first successful match
alt((
parse_unicode,
// The `value` parser returns a fixed value (the first argument) if its
// parser (the second argument) succeeds. In these cases, it looks for
// the marker characters (n, r, t, etc) and returns the matching
// character (\n, \r, \t, etc).
value('\n', char('n')),
value('\r', char('r')),
value('\t', char('t')),
value('\u{08}', char('b')),
value('\u{0C}', char('f')),
value('\\', char('\\')),
value('/', char('/')),
value('"', char('"')),
)),
)(input)
}
/// Parse a backslash, followed by any amount of whitespace. This is used later
/// to discard any escaped whitespace.
fn parse_escaped_whitespace<'a, E: ParseError<&'a str>>(
input: &'a str,
) -> IResult<&'a str, &'a str, E> {
preceded(char('\\'), multispace1)(input)
}
/// Parse a non-empty block of text that doesn't include \ or "
fn parse_literal<'a, E: ParseError<&'a str>>(input: &'a str) -> IResult<&'a str, &'a str, E> {
// `is_not` parses a string of 0 or more characters that aren't one of the
// given characters.
let not_quote_slash = is_not("\"\\");
// `verify` runs a parser, then runs a verification function on the output of
// the parser. The verification function accepts out output only if it
// returns true. In this case, we want to ensure that the output of is_not
// is non-empty.
verify(not_quote_slash, |s: &str| !s.is_empty())(input)
}
/// A string fragment contains a fragment of a string being parsed: either
/// a non-empty Literal (a series of non-escaped characters), a single
/// parsed escaped character, or a block of escaped whitespace.
#[derive(Debug, Clone, Copy, PartialEq, Eq)]
enum StringFragment<'a> {
Literal(&'a str),
EscapedChar(char),
EscapedWS,
}
/// Combine parse_literal, parse_escaped_whitespace, and parse_escaped_char
/// into a StringFragment.
fn parse_fragment<'a, E>(input: &'a str) -> IResult<&'a str, StringFragment<'a>, E>
where
E: ParseError<&'a str> + FromExternalError<&'a str, std::num::ParseIntError>,
{
alt((
// The `map` combinator runs a parser, then applies a function to the output
// of that parser.
map(parse_literal, StringFragment::Literal),
map(parse_escaped_char, StringFragment::EscapedChar),
value(StringFragment::EscapedWS, parse_escaped_whitespace),
))(input)
}
/// Parse a string. Use a loop of parse_fragment and push all of the fragments
/// into an output string.
fn parse_string<'a, E>(input: &'a str) -> IResult<&'a str, String, E>
where
E: ParseError<&'a str> + FromExternalError<&'a str, std::num::ParseIntError>,
{
// fold_many0 is the equivalent of iterator::fold. It runs a parser in a loop,
// and for each output value, calls a folding function on each output value.
let build_string = fold_many0(
// Our parser function parses a single string fragment
parse_fragment,
// Our init value, an empty string
String::new,
// Our folding function. For each fragment, append the fragment to the
// string.
|mut string, fragment| {
match fragment {
StringFragment::Literal(s) => string.push_str(s),
StringFragment::EscapedChar(c) => string.push(c),
StringFragment::EscapedWS => {}
}
string
},
);
// Finally, parse the string. Note that, if `build_string` could accept a raw
// " character, the closing delimiter " would never match. When using
// `delimited` with a looping parser (like fold_many0), be sure that the
// loop won't accidentally match your closing delimiter!
delimited(char('"'), build_string, char('"'))(input)
}
fn main() {
let data = "\"abc\"";
println!("EXAMPLE 1:\nParsing a simple input string: {}", data);
let result = parse_string::<()>(data);
assert_eq!(result, Ok(("", String::from("abc"))));
println!("Result: {}\n\n", result.unwrap().1);
let data = "\"tab:\\tafter tab, newline:\\nnew line, quote: \\\", emoji: \\u{1F602}, newline:\\nescaped whitespace: \\ abc\"";
println!(
"EXAMPLE 2:\nParsing a string with escape sequences, newline literal, and escaped whitespace:\n\n{}\n",
data
);
let result = parse_string::<()>(data);
assert_eq!(
result,
Ok((
"",
String::from("tab:\tafter tab, newline:\nnew line, quote: \", emoji: 😂, newline:\nescaped whitespace: abc")
))
);
println!("Result:\n\n{}", result.unwrap().1);
}