use super ::{length_data, length_value, many0_count, many1_count};
use crate ::{
bytes::streaming::tag,
character::streaming::digit1 as digit,
error::{ErrorKind, ParseError},
internal::{Err, IResult, Needed},
lib::std::str::{self , FromStr},
number::streaming::{be_u16, be_u8},
sequence::{pair, tuple},
};
#[ cfg(feature = "alloc" )]
use crate ::{
lib::std::vec::Vec,
multi::{
count, fold_many0, fold_many1, fold_many_m_n, length_count, many0, many1, many_m_n, many_till,
separated_list0, separated_list1,
},
};
#[ test]
#[ cfg(feature = "alloc" )]
fn separated_list0_test() {
fn multi(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
separated_list0(tag("," ), tag("abcd" ))(i)
}
fn multi_empty(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
separated_list0(tag("," ), tag("" ))(i)
}
fn empty_sep(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
separated_list0(tag("" ), tag("abc" ))(i)
}
fn multi_longsep(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
separated_list0(tag(".." ), tag("abcd" ))(i)
}
let a = &b"abcdef" [..];
let b = &b"abcd,abcdef" [..];
let c = &b"azerty" [..];
let d = &b",,abc" [..];
let e = &b"abcd,abcd,ef" [..];
let f = &b"abc" [..];
let g = &b"abcd." [..];
let h = &b"abcd,abc" [..];
let i = &b"abcabc" [..];
let res1 = vec![&b"abcd" [..]];
assert_eq!(multi(a), Ok((&b"ef" [..], res1)));
let res2 = vec![&b"abcd" [..], &b"abcd" [..]];
assert_eq!(multi(b), Ok((&b"ef" [..], res2)));
assert_eq!(multi(c), Ok((&b"azerty" [..], Vec::new())));
let res3 = vec![&b"" [..], &b"" [..], &bstyle='color:blue'>"" [..]];
assert_eq!(multi_empty(d), Ok((&b"abc" [..], res3)));
let i_err_pos = &i[3 ..];
assert_eq!(
empty_sep(i),
Err(Err::Error(error_position!(
i_err_pos,
ErrorKind::SeparatedList
)))
);
let res4 = vec![&b"abcd" [..], &b"abcd" [..]];
assert_eq!(multi(e), Ok((&b",ef" [..], res4)));
assert_eq!(multi(f), Err(Err::Incomplete(Needed::new(1 ))));
assert_eq!(multi_longsep(g), Err(Err::Incomplete(Needed::new(1 ))));
assert_eq!(multi(h), Err(Err::Incomplete(Needed::new(1 ))));
}
#[ test]
#[ cfg(feature = "alloc" )]
fn separated_list1_test() {
fn multi(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
separated_list1(tag("," ), tag("abcd" ))(i)
}
fn multi_longsep(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
separated_list1(tag(".." ), tag("abcd" ))(i)
}
let a = &b"abcdef" [..];
let b = &b"abcd,abcdef" [..];
let c = &b"azerty" [..];
let d = &b"abcd,abcd,ef" [..];
let f = &b"abc" [..];
let g = &b"abcd." [..];
let h = &b"abcd,abc" [..];
let res1 = vec![&b"abcd" [..]];
assert_eq!(multi(a), Ok((&b"ef" [..], res1)));
let res2 = vec![&b"abcd" [..], &b"abcd" [..]];
assert_eq!(multi(b), Ok((&b"ef" [..], res2)));
assert_eq!(
multi(c),
Err(Err::Error(error_position!(c, ErrorKind::Tag)))
);
let res3 = vec![&b"abcd" [..], &b"abcd" [..]];
assert_eq!(multi(d), Ok((&b",ef" [..], res3)));
assert_eq!(multi(f), Err(Err::Incomplete(Needed::new(1 ))));
assert_eq!(multi_longsep(g), Err(Err::Incomplete(Needed::new(1 ))));
assert_eq!(multi(h), Err(Err::Incomplete(Needed::new(1 ))));
}
#[ test]
#[ cfg(feature = "alloc" )]
fn many0_test() {
fn multi(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
many0(tag("abcd" ))(i)
}
fn multi_empty(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
many0(tag("" ))(i)
}
assert_eq!(multi(&b"abcdef" [..]), Ok((&b"ef" [..], vec![&b"abcd" [..]])));
assert_eq!(
multi(&b"abcdabcdefgh" [..]),
Ok((&b"efgh" [..], vec![&b"abcd" [..], &bpan style='color:blue'>"abcd"[..]]))
);
assert_eq!(multi(&b"azerty" [..]), Ok((&b"azerty" [..], Vec::new())));
assert_eq!(multi(&b"abcdab" [..]), Err(Err::Incomplete(Needed::new(2 ))));
assert_eq!(multi(&b"abcd" [..]), Err(Err::Incomplete(Needed::new(4 ))));
assert_eq!(multi(&b"" [..]), Err(Err::Incomplete(Needed::new(4 ))));
assert_eq!(
multi_empty(&b"abcdef" [..]),
Err(Err::Error(error_position!(
&b"abcdef" [..],
ErrorKind::Many0
)))
);
}
#[ test]
#[ cfg(feature = "alloc" )]
fn many1_test() {
fn multi(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
many1(tag("abcd" ))(i)
}
let a = &b"abcdef" [..];
let b = &b"abcdabcdefgh" [..];
let c = &b"azerty" [..];
let d = &b"abcdab" [..];
let res1 = vec![&b"abcd" [..]];
assert_eq!(multi(a), Ok((&b"ef" [..], res1)));
let res2 = vec![&b"abcd" [..], &b"abcd" [..]];
assert_eq!(multi(b), Ok((&b"efgh" [..], res2)));
assert_eq!(
multi(c),
Err(Err::Error(error_position!(c, ErrorKind::Tag)))
);
assert_eq!(multi(d), Err(Err::Incomplete(Needed::new(2 ))));
}
#[ test]
#[ cfg(feature = "alloc" )]
fn many_till_test() {
fn multi(i: &[u8]) -> IResult<&[u8], (Vec<&[u8]>, &[u8])> {
many_till(tag("abcd" ), tag("efgh" ))(i)
}
let a = b"abcdabcdefghabcd" ;
let b = b"efghabcd" ;
let c = b"azerty" ;
let res_a = (vec![&b"abcd" [..], &b"abcd" [..]], &b"efgh" [..]);
let res_b: (Vec<&[u8]>, &[u8]) = (Vec::new(), &b"efgh" [..]);
assert_eq!(multi(&a[..]), Ok((&b"abcd" [..], res_a)));
assert_eq!(multi(&b[..]), Ok((&b"abcd" [..], res_b)));
assert_eq!(
multi(&c[..]),
Err(Err::Error(error_node_position!(
&c[..],
ErrorKind::ManyTill,
error_position!(&c[..], ErrorKind::Tag)
)))
);
}
#[ test]
#[ cfg(feature = "std" )]
fn infinite_many() {
fn tst(input: &[u8]) -> IResult<&[u8], &[u8]> {
println!("input: {:?}" , input);
Err(Err::Error(error_position!(input, ErrorKind::Tag)))
}
// should not go into an infinite loop
fn multi0(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
many0(tst)(i)
}
let a = &b"abcdef" [..];
assert_eq!(multi0(a), Ok((a, Vec::new())));
fn multi1(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
many1(tst)(i)
}
let a = &b"abcdef" [..];
assert_eq!(
multi1(a),
Err(Err::Error(error_position!(a, ErrorKind::Tag)))
);
}
#[ test]
#[ cfg(feature = "alloc" )]
fn many_m_n_test() {
fn multi(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
many_m_n(2 , 4 , tag("Abcd" ))(i)
}
let a = &b"Abcdef" [..];
let b = &b"AbcdAbcdefgh" [..];
let c = &b"AbcdAbcdAbcdAbcdefgh" [..];
let d = &b"AbcdAbcdAbcdAbcdAbcdefgh" [..];
let e = &b"AbcdAb" [..];
assert_eq!(
multi(a),
Err(Err::Error(error_position!(&b"ef" [..], ErrorKind::Tag)))
);
let res1 = vec![&b"Abcd" [..], &b"Abcd" [..]];
assert_eq!(multi(b), Ok((&b"efgh" [..], res1)));
let res2 = vec![&b"Abcd" [..], &b"Abcd" [..], &b"Abcd" [..], &b"Abcd" [..]];
assert_eq!(multi(c), Ok((&b"efgh" [..], res2)));
let res3 = vec![&b"Abcd" [..], &b"Abcd" [..], &b"Abcd" [..], &b"Abcd" [..]];
assert_eq!(multi(d), Ok((&b"Abcdefgh" [..], res3)));
assert_eq!(multi(e), Err(Err::Incomplete(Needed::new(2 ))));
}
#[ test]
#[ cfg(feature = "alloc" )]
fn count_test() {
const TIMES: usize = 2 ;
fn cnt_2(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
count(tag("abc" ), TIMES)(i)
}
assert_eq!(
cnt_2(&b"abcabcabcdef" [..]),
Ok((&b"abcdef" [..], vec![&b"abc" [..], &b<span style='color:blue'>"abc"[..]]))
);
assert_eq!(cnt_2(&b"ab" [..]), Err(Err::Incomplete(Needed::new(1 ))));
assert_eq!(cnt_2(&b"abcab" [..]), Err(Err::Incomplete(Needed::new(1 ))));
assert_eq!(
cnt_2(&b"xxx" [..]),
Err(Err::Error(error_position!(&b"xxx" [..], ErrorKind::Tag)))
);
assert_eq!(
cnt_2(&b"xxxabcabcdef" [..]),
Err(Err::Error(error_position!(
&b"xxxabcabcdef" [..],
ErrorKind::Tag
)))
);
assert_eq!(
cnt_2(&b"abcxxxabcdef" [..]),
Err(Err::Error(error_position!(
&b"xxxabcdef" [..],
ErrorKind::Tag
)))
);
}
#[ test]
#[ cfg(feature = "alloc" )]
fn count_zero() {
const TIMES: usize = 0 ;
fn counter_2(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
count(tag("abc" ), TIMES)(i)
}
let done = &b"abcabcabcdef" [..];
let parsed_done = Vec::new();
let rest = done;
let incomplete_1 = &b"ab" [..];
let parsed_incompl_1 = Vec::new();
let incomplete_2 = &b"abcab" [..];
let parsed_incompl_2 = Vec::new();
let error = &b"xxx" [..];
let error_remain = &b"xxx" [..];
let parsed_err = Vec::new();
let error_1 = &b"xxxabcabcdef" [..];
let parsed_err_1 = Vec::new();
let error_1_remain = &b"xxxabcabcdef" [..];
let error_2 = &b"abcxxxabcdef" [..];
let parsed_err_2 = Vec::new();
let error_2_remain = &b"abcxxxabcdef" [..];
assert_eq!(counter_2(done), Ok((rest, parsed_done)));
assert_eq!(
counter_2(incomplete_1),
Ok((incomplete_1, parsed_incompl_1))
);
assert_eq!(
counter_2(incomplete_2),
Ok((incomplete_2, parsed_incompl_2))
);
assert_eq!(counter_2(error), Ok((error_remain, parsed_err)));
assert_eq!(counter_2(error_1), Ok((error_1_remain, parsed_err_1)));
assert_eq!(counter_2(error_2), Ok((error_2_remain, parsed_err_2)));
}
#[ derive(Debug, Clone, PartialEq)]
pub struct NilError;
impl <I> From<(I, ErrorKind)> for NilError {
fn from(_: (I, ErrorKind)) -> Self {
NilError
}
}
impl <I> ParseError<I> for NilError {
fn from_error_kind(_: I, _: ErrorKind) -> NilError {
NilError
}
fn append(_: I, _: ErrorKind, _: NilError) -> NilError {
NilError
}
}
fn number(i: &[u8]) -> IResult<&[u8], u32> {
use crate ::combinator::map_res;
map_res(map_res(digit, str::from_utf8), FromStr::from_str)(i)
}
#[ test]
#[ cfg(feature = "alloc" )]
fn length_count_test() {
fn cnt(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
length_count(number, tag("abc" ))(i)
}
assert_eq!(
cnt(&b"2abcabcabcdef" [..]),
Ok((&b"abcdef" [..], vec![&b"abc" [..], &b<span style='color:blue'>"abc"[..]]))
);
assert_eq!(cnt(&b"2ab" [..]), Err(Err::Incomplete(Needed::new(1 ))));
assert_eq!(cnt(&b"3abcab" [..]), Err(Err::Incomplete(Needed::new(1 ))));
assert_eq!(
cnt(&b"xxx" [..]),
Err(Err::Error(error_position!(&b"xxx" [..], ErrorKind::Digit)))
);
assert_eq!(
cnt(&b"2abcxxx" [..]),
Err(Err::Error(error_position!(&b"xxx" [..], ErrorKind::Tag)))
);
}
#[ test]
fn length_data_test() {
fn take(i: &[u8]) -> IResult<&[u8], &[u8]> {
length_data(number)(i)
}
assert_eq!(
take(&b"6abcabcabcdef" [..]),
Ok((&b"abcdef" [..], &b"abcabc" [..]))
);
assert_eq!(take(&b"3ab" [..]), Err(Err::Incomplete(Needed::new(1 ))));
assert_eq!(
take(&b"xxx" [..]),
Err(Err::Error(error_position!(&b"xxx" [..], ErrorKind::Digit)))
);
assert_eq!(take(&b"2abcxxx" [..]), Ok((&b"cxxx" [..], &b"ab" [..])));
}
#[ test]
fn length_value_test() {
fn length_value_1(i: &[u8]) -> IResult<&[u8], u16> {
length_value(be_u8, be_u16)(i)
}
fn length_value_2(i: &[u8]) -> IResult<&[u8], (u8, u8)> {
length_value(be_u8, tuple((be_u8, be_u8)))(i)
}
let i1 = [0 , 5 , 6 ];
assert_eq!(
length_value_1(&i1),
Err(Err::Error(error_position!(&b"" [..], ErrorKind::Complete)))
);
assert_eq!(
length_value_2(&i1),
Err(Err::Error(error_position!(&b"" [..], ErrorKind::Complete)))
);
let i2 = [1 , 5 , 6 , 3 ];
assert_eq!(
length_value_1(&i2),
Err(Err::Error(error_position!(&i2[1 ..2 ], ErrorKind::Complete)))
);
assert_eq!(
length_value_2(&i2),
Err(Err::Error(error_position!(&i2[1 ..2 ], ErrorKind::Complete)))
);
let i3 = [2 , 5 , 6 , 3 , 4 , 5 , 7 ];
assert_eq!(length_value_1(&i3), Ok((&i3[3 ..], 1286 )));
assert_eq!(length_value_2(&i3), Ok((&i3[3 ..], (5 , 6 ))));
let i4 = [3 , 5 , 6 , 3 , 4 , 5 ];
assert_eq!(length_value_1(&i4), Ok((&i4[4 ..], 1286 )));
assert_eq!(length_value_2(&i4), Ok((&i4[4 ..], (5 , 6 ))));
}
#[ test]
#[ cfg(feature = "alloc" )]
fn fold_many0_test() {
fn fold_into_vec<T>(mut acc: Vec<T>, item: T) -> Vec<T> {
acc.push(item);
acc
}
fn multi(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
fold_many0(tag("abcd" ), Vec::new, fold_into_vec)(i)
}
fn multi_empty(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
fold_many0(tag("" ), Vec::new, fold_into_vec)(i)
}
assert_eq!(multi(&b"abcdef" [..]), Ok((&b"ef" [..], vec![&b"abcd" [..]])));
assert_eq!(
multi(&b"abcdabcdefgh" [..]),
Ok((&b"efgh" [..], vec![&b"abcd" [..], &bpan style='color:blue'>"abcd"[..]]))
);
assert_eq!(multi(&b"azerty" [..]), Ok((&b"azerty" [..], Vec::new())));
assert_eq!(multi(&b"abcdab" [..]), Err(Err::Incomplete(Needed::new(2 ))));
assert_eq!(multi(&b"abcd" [..]), Err(Err::Incomplete(Needed::new(4 ))));
assert_eq!(multi(&b"" [..]), Err(Err::Incomplete(Needed::new(4 ))));
assert_eq!(
multi_empty(&b"abcdef" [..]),
Err(Err::Error(error_position!(
&b"abcdef" [..],
ErrorKind::Many0
)))
);
}
#[ test]
#[ cfg(feature = "alloc" )]
fn fold_many1_test() {
fn fold_into_vec<T>(mut acc: Vec<T>, item: T) -> Vec<T> {
acc.push(item);
acc
}
fn multi(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
fold_many1(tag("abcd" ), Vec::new, fold_into_vec)(i)
}
let a = &b"abcdef" [..];
let b = &b"abcdabcdefgh" [..];
let c = &b"azerty" [..];
let d = &b"abcdab" [..];
let res1 = vec![&b"abcd" [..]];
assert_eq!(multi(a), Ok((&b"ef" [..], res1)));
let res2 = vec![&b"abcd" [..], &b"abcd" [..]];
assert_eq!(multi(b), Ok((&b"efgh" [..], res2)));
assert_eq!(
multi(c),
Err(Err::Error(error_position!(c, ErrorKind::Many1)))
);
assert_eq!(multi(d), Err(Err::Incomplete(Needed::new(2 ))));
}
#[ test]
#[ cfg(feature = "alloc" )]
fn fold_many_m_n_test() {
fn fold_into_vec<T>(mut acc: Vec<T>, item: T) -> Vec<T> {
acc.push(item);
acc
}
fn multi(i: &[u8]) -> IResult<&[u8], Vec<&[u8]>> {
fold_many_m_n(2 , 4 , tag("Abcd" ), Vec::new, fold_into_vec)(i)
}
let a = &b"Abcdef" [..];
let b = &b"AbcdAbcdefgh" [..];
let c = &b"AbcdAbcdAbcdAbcdefgh" [..];
let d = &b"AbcdAbcdAbcdAbcdAbcdefgh" [..];
let e = &b"AbcdAb" [..];
assert_eq!(
multi(a),
Err(Err::Error(error_position!(&b"ef" [..], ErrorKind::Tag)))
);
let res1 = vec![&b"Abcd" [..], &b"Abcd" [..]];
assert_eq!(multi(b), Ok((&b"efgh" [..], res1)));
let res2 = vec![&b"Abcd" [..], &b"Abcd" [..], &b"Abcd" [..], &b"Abcd" [..]];
assert_eq!(multi(c), Ok((&b"efgh" [..], res2)));
let res3 = vec![&b"Abcd" [..], &b"Abcd" [..], &b"Abcd" [..], &b"Abcd" [..]];
assert_eq!(multi(d), Ok((&b"Abcdefgh" [..], res3)));
assert_eq!(multi(e), Err(Err::Incomplete(Needed::new(2 ))));
}
#[ test]
fn many0_count_test() {
fn count0_nums(i: &[u8]) -> IResult<&[u8], usize> {
many0_count(pair(digit, tag("," )))(i)
}
assert_eq!(count0_nums(&b"123,junk" [..]), Ok((&b"junk" [..], 1 )));
assert_eq!(count0_nums(&b"123,45,junk" [..]), Ok((&b='color:blue'>"junk" [..], 2 )));
assert_eq!(
count0_nums(&b"1,2,3,4,5,6,7,8,9,0,junk" [..]),
Ok((&b"junk" [..], 10 ))
);
assert_eq!(count0_nums(&b"hello" [..]), Ok((&b"hello" [..], 0 )));
}
#[ test]
fn many1_count_test() {
fn count1_nums(i: &[u8]) -> IResult<&[u8], usize> {
many1_count(pair(digit, tag("," )))(i)
}
assert_eq!(count1_nums(&b"123,45,junk" [..]), Ok((&b='color:blue'>"junk" [..], 2 )));
assert_eq!(
count1_nums(&b"1,2,3,4,5,6,7,8,9,0,junk" [..]),
Ok((&b"junk" [..], 10 ))
);
assert_eq!(
count1_nums(&b"hello" [..]),
Err(Err::Error(error_position!(
&b"hello" [..],
ErrorKind::Many1Count
)))
);
}
Messung V0.5 in Prozent C=96 H=99 G=97
¤ Dauer der Verarbeitung: 0.13 Sekunden
(vorverarbeitet am 2026-06-18)
¤
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