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|
use std::collections::HashMap;
use std::str;
use winnow::prelude::*;
use winnow::Result;
use winnow::{
ascii::float,
combinator::empty,
combinator::fail,
combinator::peek,
combinator::{alt, dispatch},
combinator::{delimited, preceded, separated_pair, terminated},
combinator::{repeat, separated},
error::{AddContext, ParserError, StrContext},
token::{any, none_of, take, take_while},
};
use crate::json::JsonValue;
pub(crate) type Stream<'i> = &'i str;
/// The root element of a JSON parser is any value
///
/// A parser has the following signature:
/// `&mut Stream -> Result<Output ContextError>`
///
/// most of the times you can ignore the error type and use the default (but this
/// examples shows custom error types later on!)
///
/// Here we use `&str` as input type, but parsers can be generic over
/// the input type, work directly with `&[u8]`, or any other type that
/// implements the required traits.
pub(crate) fn json<'i, E: ParserError<Stream<'i>> + AddContext<Stream<'i>, StrContext>>(
input: &mut Stream<'i>,
) -> Result<JsonValue, E> {
delimited(ws, json_value, ws).parse_next(input)
}
/// `alt` is a combinator that tries multiple parsers one by one, until
/// one of them succeeds
fn json_value<'i, E: ParserError<Stream<'i>> + AddContext<Stream<'i>, StrContext>>(
input: &mut Stream<'i>,
) -> Result<JsonValue, E> {
// `dispatch` gives you `match`-like behavior compared to `alt` successively trying different
// implementations.
dispatch!(peek(any);
'n' => null.value(JsonValue::Null),
't' => true_.map(JsonValue::Boolean),
'f' => false_.map(JsonValue::Boolean),
'"' => string.map(JsonValue::Str),
'+' => float.map(JsonValue::Num),
'-' => float.map(JsonValue::Num),
'0'..='9' => float.map(JsonValue::Num),
'[' => array.map(JsonValue::Array),
'{' => object.map(JsonValue::Object),
_ => fail,
)
.parse_next(input)
}
/// `literal(string)` generates a parser that takes the argument string.
///
/// This also shows returning a sub-slice of the original input
fn null<'i, E: ParserError<Stream<'i>>>(input: &mut Stream<'i>) -> Result<&'i str, E> {
// This is a parser that returns `"null"` if it sees the string "null", and
// an error otherwise
"null".parse_next(input)
}
/// We can combine `tag` with other functions, like `value` which returns a given constant value on
/// success.
fn true_<'i, E: ParserError<Stream<'i>>>(input: &mut Stream<'i>) -> Result<bool, E> {
// This is a parser that returns `true` if it sees the string "true", and
// an error otherwise
"true".value(true).parse_next(input)
}
/// We can combine `tag` with other functions, like `value` which returns a given constant value on
/// success.
fn false_<'i, E: ParserError<Stream<'i>>>(input: &mut Stream<'i>) -> Result<bool, E> {
// This is a parser that returns `false` if it sees the string "false", and
// an error otherwise
"false".value(false).parse_next(input)
}
/// This parser gathers all `char`s up into a `String`with a parse to take the double quote
/// character, before the string (using `preceded`) and after the string (using `terminated`).
fn string<'i, E: ParserError<Stream<'i>> + AddContext<Stream<'i>, StrContext>>(
input: &mut Stream<'i>,
) -> Result<String, E> {
preceded(
'\"',
terminated(
repeat(0.., character).fold(String::new, |mut string, c| {
string.push(c);
string
}),
'\"',
),
)
// `context` lets you add a static string to errors to provide more information in the
// error chain (to indicate which parser had an error)
.context(StrContext::Expected("string".into()))
.parse_next(input)
}
/// You can mix the above declarative parsing with an imperative style to handle more unique cases,
/// like escaping
fn character<'i, E: ParserError<Stream<'i>>>(input: &mut Stream<'i>) -> Result<char, E> {
let c = none_of('\"').parse_next(input)?;
if c == '\\' {
dispatch!(any;
'"' => empty.value('"'),
'\\' => empty.value('\\'),
'/' => empty.value('/'),
'b' => empty.value('\x08'),
'f' => empty.value('\x0C'),
'n' => empty.value('\n'),
'r' => empty.value('\r'),
't' => empty.value('\t'),
'u' => unicode_escape,
_ => fail,
)
.parse_next(input)
} else {
Ok(c)
}
}
fn unicode_escape<'i, E: ParserError<Stream<'i>>>(input: &mut Stream<'i>) -> Result<char, E> {
alt((
// Not a surrogate
u16_hex
.verify(|cp| !(0xD800..0xE000).contains(cp))
.map(|cp| cp as u32),
// See https://en.wikipedia.org/wiki/UTF-16#Code_points_from_U+010000_to_U+10FFFF for details
separated_pair(u16_hex, "\\u", u16_hex)
.verify(|(high, low)| (0xD800..0xDC00).contains(high) && (0xDC00..0xE000).contains(low))
.map(|(high, low)| {
let high_ten = (high as u32) - 0xD800;
let low_ten = (low as u32) - 0xDC00;
(high_ten << 10) + low_ten + 0x10000
}),
))
.verify_map(
// Could be probably replaced with .unwrap() or _unchecked due to the verify checks
std::char::from_u32,
)
.parse_next(input)
}
fn u16_hex<'i, E: ParserError<Stream<'i>>>(input: &mut Stream<'i>) -> Result<u16, E> {
take(4usize)
.verify_map(|s| u16::from_str_radix(s, 16).ok())
.parse_next(input)
}
/// Some combinators, like `separated` or `repeat`, will call a parser repeatedly,
/// accumulating results in a `Vec`, until it encounters an error.
/// If you want more control on the parser application, check out the `iterator`
/// combinator (cf `examples/iterator.rs`)
fn array<'i, E: ParserError<Stream<'i>> + AddContext<Stream<'i>, StrContext>>(
input: &mut Stream<'i>,
) -> Result<Vec<JsonValue>, E> {
preceded(
('[', ws),
terminated(separated(0.., json_value, (ws, ',', ws)), (ws, ']')),
)
.context(StrContext::Expected("array".into()))
.parse_next(input)
}
fn object<'i, E: ParserError<Stream<'i>> + AddContext<Stream<'i>, StrContext>>(
input: &mut Stream<'i>,
) -> Result<HashMap<String, JsonValue>, E> {
preceded(
('{', ws),
terminated(separated(0.., key_value, (ws, ',', ws)), (ws, '}')),
)
.context(StrContext::Expected("object".into()))
.parse_next(input)
}
fn key_value<'i, E: ParserError<Stream<'i>> + AddContext<Stream<'i>, StrContext>>(
input: &mut Stream<'i>,
) -> Result<(String, JsonValue), E> {
separated_pair(string, (ws, ':', ws), json_value).parse_next(input)
}
/// Parser combinators are constructed from the bottom up:
/// first we write parsers for the smallest elements (here a space character),
/// then we'll combine them in larger parsers
fn ws<'i, E: ParserError<Stream<'i>>>(input: &mut Stream<'i>) -> Result<&'i str, E> {
// Combinators like `take_while` return a function. That function is the
// parser,to which we can pass the input
take_while(0.., WS).parse_next(input)
}
const WS: &[char] = &[' ', '\t', '\r', '\n'];
#[cfg(test)]
mod test {
#[allow(clippy::useless_attribute)]
#[allow(unused_imports)] // its dead for benches
use super::*;
#[allow(clippy::useless_attribute)]
#[allow(dead_code)] // its dead for benches
type Error = winnow::error::ContextError;
#[test]
fn json_string() {
assert_eq!(string::<Error>.parse_peek("\"\""), Ok(("", "".to_owned())));
assert_eq!(
string::<Error>.parse_peek("\"abc\""),
Ok(("", "abc".to_owned()))
);
assert_eq!(
string::<Error>
.parse_peek("\"abc\\\"\\\\\\/\\b\\f\\n\\r\\t\\u0001\\u2014\u{2014}def\""),
Ok(("", "abc\"\\/\x08\x0C\n\r\t\x01ββdef".to_owned())),
);
assert_eq!(
string::<Error>.parse_peek("\"\\uD83D\\uDE10\""),
Ok(("", "π".to_owned()))
);
assert!(string::<Error>.parse_peek("\"").is_err());
assert!(string::<Error>.parse_peek("\"abc").is_err());
assert!(string::<Error>.parse_peek("\"\\\"").is_err());
assert!(string::<Error>.parse_peek("\"\\u123\"").is_err());
assert!(string::<Error>.parse_peek("\"\\uD800\"").is_err());
assert!(string::<Error>.parse_peek("\"\\uD800\\uD800\"").is_err());
assert!(string::<Error>.parse_peek("\"\\uDC00\"").is_err());
}
#[test]
fn json_object() {
use JsonValue::{Num, Object, Str};
let input = r#"{"a":42,"b":"x"}"#;
let expected = Object(
vec![
("a".to_owned(), Num(42.0)),
("b".to_owned(), Str("x".to_owned())),
]
.into_iter()
.collect(),
);
assert_eq!(json::<Error>.parse_peek(input), Ok(("", expected)));
}
#[test]
fn json_array() {
use JsonValue::{Array, Num, Str};
let input = r#"[42,"x"]"#;
let expected = Array(vec![Num(42.0), Str("x".to_owned())]);
assert_eq!(json::<Error>.parse_peek(input), Ok(("", expected)));
}
#[test]
fn json_whitespace() {
use JsonValue::{Array, Boolean, Null, Num, Object, Str};
let input = r#"
{
"null" : null,
"true" :true ,
"false": false ,
"number" : 123e4 ,
"string" : " abc 123 " ,
"array" : [ false , 1 , "two" ] ,
"object" : { "a" : 1.0 , "b" : "c" } ,
"empty_array" : [ ] ,
"empty_object" : { }
}
"#;
assert_eq!(
json::<Error>.parse_peek(input),
Ok((
"",
Object(
vec![
("null".to_owned(), Null),
("true".to_owned(), Boolean(true)),
("false".to_owned(), Boolean(false)),
("number".to_owned(), Num(123e4)),
("string".to_owned(), Str(" abc 123 ".to_owned())),
(
"array".to_owned(),
Array(vec![Boolean(false), Num(1.0), Str("two".to_owned())])
),
(
"object".to_owned(),
Object(
vec![
("a".to_owned(), Num(1.0)),
("b".to_owned(), Str("c".to_owned())),
]
.into_iter()
.collect()
)
),
("empty_array".to_owned(), Array(vec![]),),
("empty_object".to_owned(), Object(HashMap::new()),),
]
.into_iter()
.collect()
)
))
);
}
}
|
