//! Parsers recognizing numbers #![allow(clippy::match_same_arms)] pub mod bits; #[cfg(test)] mod tests; use crate::combinator::repeat; use crate::error::ErrMode; use crate::error::ErrorKind; use crate::error::Needed; use crate::error::ParseError; use crate::lib::std::ops::{Add, Shl}; use crate::stream::Accumulate; use crate::stream::{AsBytes, Stream, StreamIsPartial}; use crate::stream::{ToUsize, UpdateSlice}; use crate::token::take; use crate::trace::trace; use crate::IResult; use crate::Parser; /// Configurable endianness #[derive(Debug, PartialEq, Eq, Clone, Copy)] pub enum Endianness { /// Big endian Big, /// Little endian Little, /// Will match the host's endianness Native, } /// Recognizes an unsigned 1 byte integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::be_u8; /// /// fn parser(s: &[u8]) -> IResult<&[u8], u8> { /// be_u8.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03abcefg"[..]), Ok((&b"\x03abcefg"[..], 0x00))); /// assert_eq!(parser(&b""[..]), Err(ErrMode::Backtrack(Error::new(&[][..], ErrorKind::Token)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::be_u8; /// /// fn parser(s: Partial<&[u8]>) -> IResult, u8> { /// be_u8.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01abcd"[..])), Ok((Partial::new(&b"\x01abcd"[..]), 0x00))); /// assert_eq!(parser(Partial::new(&b""[..])), Err(ErrMode::Incomplete(Needed::new(1)))); /// ``` #[inline(always)] pub fn be_u8>(input: I) -> IResult where I: StreamIsPartial, I: Stream, { u8(input) } /// Recognizes a big endian unsigned 2 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::be_u16; /// /// fn parser(s: &[u8]) -> IResult<&[u8], u16> { /// be_u16.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03abcefg"[..]), Ok((&b"abcefg"[..], 0x0003))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::be_u16; /// /// fn parser(s: Partial<&[u8]>) -> IResult, u16> { /// be_u16.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x0001))); /// assert_eq!(parser(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(1)))); /// ``` #[inline(always)] pub fn be_u16>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("be_u16", move |input: I| be_uint(input, 2)).parse_next(input) } /// Recognizes a big endian unsigned 3 byte integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::be_u24; /// /// fn parser(s: &[u8]) -> IResult<&[u8], u32> { /// be_u24.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03\x05abcefg"[..]), Ok((&b"abcefg"[..], 0x000305))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::be_u24; /// /// fn parser(s: Partial<&[u8]>) -> IResult, u32> { /// be_u24.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01\x02abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x000102))); /// assert_eq!(parser(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(2)))); /// ``` #[inline(always)] pub fn be_u24>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("be_u23", move |input: I| be_uint(input, 3)).parse_next(input) } /// Recognizes a big endian unsigned 4 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::be_u32; /// /// fn parser(s: &[u8]) -> IResult<&[u8], u32> { /// be_u32.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03\x05\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x00030507))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::be_u32; /// /// fn parser(s: Partial<&[u8]>) -> IResult, u32> { /// be_u32.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01\x02\x03abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x00010203))); /// assert_eq!(parser(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(3)))); /// ``` #[inline(always)] pub fn be_u32>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("be_u32", move |input: I| be_uint(input, 4)).parse_next(input) } /// Recognizes a big endian unsigned 8 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::be_u64; /// /// fn parser(s: &[u8]) -> IResult<&[u8], u64> { /// be_u64.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x0001020304050607))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::be_u64; /// /// fn parser(s: Partial<&[u8]>) -> IResult, u64> { /// be_u64.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01\x02\x03\x04\x05\x06\x07abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x0001020304050607))); /// assert_eq!(parser(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(7)))); /// ``` #[inline(always)] pub fn be_u64>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("be_u64", move |input: I| be_uint(input, 8)).parse_next(input) } /// Recognizes a big endian unsigned 16 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::be_u128; /// /// fn parser(s: &[u8]) -> IResult<&[u8], u128> { /// be_u128.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x01\x02\x03\x04\x05\x06\x07\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x00010203040506070001020304050607))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::be_u128; /// /// fn parser(s: Partial<&[u8]>) -> IResult, u128> { /// be_u128.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01\x02\x03\x04\x05\x06\x07\x08\x09\x10\x11\x12\x13\x14\x15abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x00010203040506070809101112131415))); /// assert_eq!(parser(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(15)))); /// ``` #[inline(always)] pub fn be_u128>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("be_u128", move |input: I| be_uint(input, 16)).parse_next(input) } #[inline] fn be_uint>(input: I, bound: usize) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, Uint: Default + Shl + Add + From, { debug_assert_ne!(bound, 1, "to_be_uint needs extra work to avoid overflow"); take(bound) .map(|n: ::Slice| to_be_uint(n.as_bytes())) .parse_next(input) } #[inline] fn to_be_uint(number: &[u8]) -> Uint where Uint: Default + Shl + Add + From, { let mut res = Uint::default(); for byte in number.iter().copied() { res = (res << 8) + byte.into(); } res } /// Recognizes a signed 1 byte integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::be_i8; /// /// fn parser(s: &[u8]) -> IResult<&[u8], i8> { /// be_i8.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03abcefg"[..]), Ok((&b"\x03abcefg"[..], 0x00))); /// assert_eq!(parser(&b""[..]), Err(ErrMode::Backtrack(Error::new(&[][..], ErrorKind::Token)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::be_i8; /// /// fn parser(s: Partial<&[u8]>) -> IResult, i8> { /// be_i8.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01abcd"[..])), Ok((Partial::new(&b"\x01abcd"[..]), 0x00))); /// assert_eq!(parser(Partial::new(&b""[..])), Err(ErrMode::Incomplete(Needed::new(1)))); /// ``` #[inline(always)] pub fn be_i8>(input: I) -> IResult where I: StreamIsPartial, I: Stream, { i8(input) } /// Recognizes a big endian signed 2 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::be_i16; /// /// fn parser(s: &[u8]) -> IResult<&[u8], i16> { /// be_i16.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03abcefg"[..]), Ok((&b"abcefg"[..], 0x0003))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::be_i16; /// /// fn parser(s: Partial<&[u8]>) -> IResult, i16> { /// be_i16.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x0001))); /// assert_eq!(parser(Partial::new(&b""[..])), Err(ErrMode::Incomplete(Needed::new(2)))); /// ``` #[inline(always)] pub fn be_i16>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("be_i16", move |input: I| { be_uint::<_, u16, _>(input, 2).map(|(i, n)| (i, n as i16)) }) .parse_next(input) } /// Recognizes a big endian signed 3 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::be_i24; /// /// fn parser(s: &[u8]) -> IResult<&[u8], i32> { /// be_i24.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03\x05abcefg"[..]), Ok((&b"abcefg"[..], 0x000305))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::be_i24; /// /// fn parser(s: Partial<&[u8]>) -> IResult, i32> { /// be_i24.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01\x02abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x000102))); /// assert_eq!(parser(Partial::new(&b""[..])), Err(ErrMode::Incomplete(Needed::new(3)))); /// ``` #[inline(always)] pub fn be_i24>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("be_i24", move |input: I| { be_uint::<_, u32, _>(input, 3).map(|(i, n)| { // Same as the unsigned version but we need to sign-extend manually here let n = if n & 0x80_00_00 != 0 { (n | 0xff_00_00_00) as i32 } else { n as i32 }; (i, n) }) }) .parse_next(input) } /// Recognizes a big endian signed 4 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::be_i32; /// /// fn parser(s: &[u8]) -> IResult<&[u8], i32> { /// be_i32.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03\x05\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x00030507))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::be_i32; /// /// fn parser(s: Partial<&[u8]>) -> IResult, i32> { /// be_i32.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01\x02\x03abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x00010203))); /// assert_eq!(parser(Partial::new(&b""[..])), Err(ErrMode::Incomplete(Needed::new(4)))); /// ``` #[inline(always)] pub fn be_i32>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("be_i32", move |input: I| { be_uint::<_, u32, _>(input, 4).map(|(i, n)| (i, n as i32)) }) .parse_next(input) } /// Recognizes a big endian signed 8 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::be_i64; /// /// fn parser(s: &[u8]) -> IResult<&[u8], i64> { /// be_i64.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x0001020304050607))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::be_i64; /// /// fn parser(s: Partial<&[u8]>) -> IResult, i64> { /// be_i64.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01\x02\x03\x04\x05\x06\x07abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x0001020304050607))); /// assert_eq!(parser(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(7)))); /// ``` #[inline(always)] pub fn be_i64>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("be_i64", move |input: I| { be_uint::<_, u64, _>(input, 8).map(|(i, n)| (i, n as i64)) }) .parse_next(input) } /// Recognizes a big endian signed 16 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::be_i128; /// /// fn parser(s: &[u8]) -> IResult<&[u8], i128> { /// be_i128.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x01\x02\x03\x04\x05\x06\x07\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x00010203040506070001020304050607))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::be_i128; /// /// fn parser(s: Partial<&[u8]>) -> IResult, i128> { /// be_i128.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01\x02\x03\x04\x05\x06\x07\x08\x09\x10\x11\x12\x13\x14\x15abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x00010203040506070809101112131415))); /// assert_eq!(parser(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(15)))); /// ``` #[inline(always)] pub fn be_i128>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("be_i128", move |input: I| { be_uint::<_, u128, _>(input, 16).map(|(i, n)| (i, n as i128)) }) .parse_next(input) } /// Recognizes an unsigned 1 byte integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::le_u8; /// /// fn parser(s: &[u8]) -> IResult<&[u8], u8> { /// le_u8.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03abcefg"[..]), Ok((&b"\x03abcefg"[..], 0x00))); /// assert_eq!(parser(&b""[..]), Err(ErrMode::Backtrack(Error::new(&[][..], ErrorKind::Token)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::le_u8; /// /// fn parser(s: Partial<&[u8]>) -> IResult, u8> { /// le_u8.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01abcd"[..])), Ok((Partial::new(&b"\x01abcd"[..]), 0x00))); /// assert_eq!(parser(Partial::new(&b""[..])), Err(ErrMode::Incomplete(Needed::new(1)))); /// ``` #[inline(always)] pub fn le_u8>(input: I) -> IResult where I: StreamIsPartial, I: Stream, { u8(input) } /// Recognizes a little endian unsigned 2 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::le_u16; /// /// fn parser(s: &[u8]) -> IResult<&[u8], u16> { /// le_u16.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03abcefg"[..]), Ok((&b"abcefg"[..], 0x0300))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::le_u16; /// /// fn parser(s: Partial<&[u8]>) -> IResult, u16> { /// le_u16::<_, Error<_>>.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x0100))); /// assert_eq!(parser(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(1)))); /// ``` #[inline(always)] pub fn le_u16>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("le_u16", move |input: I| le_uint(input, 2)).parse_next(input) } /// Recognizes a little endian unsigned 3 byte integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::le_u24; /// /// fn parser(s: &[u8]) -> IResult<&[u8], u32> { /// le_u24.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03\x05abcefg"[..]), Ok((&b"abcefg"[..], 0x050300))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::le_u24; /// /// fn parser(s: Partial<&[u8]>) -> IResult, u32> { /// le_u24::<_, Error<_>>.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01\x02abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x020100))); /// assert_eq!(parser(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(2)))); /// ``` #[inline(always)] pub fn le_u24>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("le_u24", move |input: I| le_uint(input, 3)).parse_next(input) } /// Recognizes a little endian unsigned 4 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::le_u32; /// /// fn parser(s: &[u8]) -> IResult<&[u8], u32> { /// le_u32.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03\x05\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x07050300))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::le_u32; /// /// fn parser(s: Partial<&[u8]>) -> IResult, u32> { /// le_u32::<_, Error<_>>.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01\x02\x03abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x03020100))); /// assert_eq!(parser(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(3)))); /// ``` #[inline(always)] pub fn le_u32>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("le_u32", move |input: I| le_uint(input, 4)).parse_next(input) } /// Recognizes a little endian unsigned 8 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::le_u64; /// /// fn parser(s: &[u8]) -> IResult<&[u8], u64> { /// le_u64.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x0706050403020100))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::le_u64; /// /// fn parser(s: Partial<&[u8]>) -> IResult, u64> { /// le_u64::<_, Error<_>>.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01\x02\x03\x04\x05\x06\x07abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x0706050403020100))); /// assert_eq!(parser(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(7)))); /// ``` #[inline(always)] pub fn le_u64>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("le_u64", move |input: I| le_uint(input, 8)).parse_next(input) } /// Recognizes a little endian unsigned 16 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::le_u128; /// /// fn parser(s: &[u8]) -> IResult<&[u8], u128> { /// le_u128.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x01\x02\x03\x04\x05\x06\x07\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x07060504030201000706050403020100))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::le_u128; /// /// fn parser(s: Partial<&[u8]>) -> IResult, u128> { /// le_u128::<_, Error<_>>.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01\x02\x03\x04\x05\x06\x07\x08\x09\x10\x11\x12\x13\x14\x15abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x15141312111009080706050403020100))); /// assert_eq!(parser(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(15)))); /// ``` #[inline(always)] pub fn le_u128>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("le_u128", move |input: I| le_uint(input, 16)).parse_next(input) } #[inline] fn le_uint>(input: I, bound: usize) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, Uint: Default + Shl + Add + From, { take(bound) .map(|n: ::Slice| to_le_uint(n.as_bytes())) .parse_next(input) } #[inline] fn to_le_uint(number: &[u8]) -> Uint where Uint: Default + Shl + Add + From, { let mut res = Uint::default(); for (index, byte) in number.iter_offsets() { res = res + (Uint::from(byte) << (8 * index as u8)); } res } /// Recognizes a signed 1 byte integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::le_i8; /// /// fn parser(s: &[u8]) -> IResult<&[u8], i8> { /// le_i8.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03abcefg"[..]), Ok((&b"\x03abcefg"[..], 0x00))); /// assert_eq!(parser(&b""[..]), Err(ErrMode::Backtrack(Error::new(&[][..], ErrorKind::Token)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::le_i8; /// /// fn parser(s: Partial<&[u8]>) -> IResult, i8> { /// le_i8.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01abcd"[..])), Ok((Partial::new(&b"\x01abcd"[..]), 0x00))); /// assert_eq!(parser(Partial::new(&b""[..])), Err(ErrMode::Incomplete(Needed::new(1)))); /// ``` #[inline(always)] pub fn le_i8>(input: I) -> IResult where I: StreamIsPartial, I: Stream, { i8(input) } /// Recognizes a little endian signed 2 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::le_i16; /// /// fn parser(s: &[u8]) -> IResult<&[u8], i16> { /// le_i16.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03abcefg"[..]), Ok((&b"abcefg"[..], 0x0300))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::le_i16; /// /// fn parser(s: Partial<&[u8]>) -> IResult, i16> { /// le_i16::<_, Error<_>>.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x0100))); /// assert_eq!(parser(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(1)))); /// ``` #[inline(always)] pub fn le_i16>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("le_i16", move |input: I| { le_uint::<_, u16, _>(input, 2).map(|(i, n)| (i, n as i16)) }) .parse_next(input) } /// Recognizes a little endian signed 3 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::le_i24; /// /// fn parser(s: &[u8]) -> IResult<&[u8], i32> { /// le_i24.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03\x05abcefg"[..]), Ok((&b"abcefg"[..], 0x050300))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::le_i24; /// /// fn parser(s: Partial<&[u8]>) -> IResult, i32> { /// le_i24::<_, Error<_>>.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01\x02abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x020100))); /// assert_eq!(parser(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(2)))); /// ``` #[inline(always)] pub fn le_i24>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("le_i24", move |input: I| { le_uint::<_, u32, _>(input, 3).map(|(i, n)| { // Same as the unsigned version but we need to sign-extend manually here let n = if n & 0x80_00_00 != 0 { (n | 0xff_00_00_00) as i32 } else { n as i32 }; (i, n) }) }) .parse_next(input) } /// Recognizes a little endian signed 4 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::le_i32; /// /// fn parser(s: &[u8]) -> IResult<&[u8], i32> { /// le_i32.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03\x05\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x07050300))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::le_i32; /// /// fn parser(s: Partial<&[u8]>) -> IResult, i32> { /// le_i32::<_, Error<_>>.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01\x02\x03abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x03020100))); /// assert_eq!(parser(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(3)))); /// ``` #[inline(always)] pub fn le_i32>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("le_i32", move |input: I| { le_uint::<_, u32, _>(input, 4).map(|(i, n)| (i, n as i32)) }) .parse_next(input) } /// Recognizes a little endian signed 8 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::le_i64; /// /// fn parser(s: &[u8]) -> IResult<&[u8], i64> { /// le_i64.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x0706050403020100))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::le_i64; /// /// fn parser(s: Partial<&[u8]>) -> IResult, i64> { /// le_i64::<_, Error<_>>.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01\x02\x03\x04\x05\x06\x07abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x0706050403020100))); /// assert_eq!(parser(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(7)))); /// ``` #[inline(always)] pub fn le_i64>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("le_i64", move |input: I| { le_uint::<_, u64, _>(input, 8).map(|(i, n)| (i, n as i64)) }) .parse_next(input) } /// Recognizes a little endian signed 16 bytes integer. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::le_i128; /// /// fn parser(s: &[u8]) -> IResult<&[u8], i128> { /// le_i128.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x01\x02\x03\x04\x05\x06\x07\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x07060504030201000706050403020100))); /// assert_eq!(parser(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::le_i128; /// /// fn parser(s: Partial<&[u8]>) -> IResult, i128> { /// le_i128::<_, Error<_>>.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x01\x02\x03\x04\x05\x06\x07\x08\x09\x10\x11\x12\x13\x14\x15abcd"[..])), Ok((Partial::new(&b"abcd"[..]), 0x15141312111009080706050403020100))); /// assert_eq!(parser(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(15)))); /// ``` #[inline(always)] pub fn le_i128>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("le_i128", move |input: I| { le_uint::<_, u128, _>(input, 16).map(|(i, n)| (i, n as i128)) }) .parse_next(input) } /// Recognizes an unsigned 1 byte integer /// /// **Note:** that endianness does not apply to 1 byte numbers. /// /// *Complete version*: returns an error if there is not enough input data /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::u8; /// /// fn parser(s: &[u8]) -> IResult<&[u8], u8> { /// u8.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03abcefg"[..]), Ok((&b"\x03abcefg"[..], 0x00))); /// assert_eq!(parser(&b""[..]), Err(ErrMode::Backtrack(Error::new(&[][..], ErrorKind::Token)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// # use winnow::Partial; /// use winnow::binary::u8; /// /// fn parser(s: Partial<&[u8]>) -> IResult, u8> { /// u8::<_, Error<_>>.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x03abcefg"[..])), Ok((Partial::new(&b"\x03abcefg"[..]), 0x00))); /// assert_eq!(parser(Partial::new(&b""[..])), Err(ErrMode::Incomplete(Needed::new(1)))); /// ``` #[inline(always)] pub fn u8>(input: I) -> IResult where I: StreamIsPartial, I: Stream, { trace("u8", move |input: I| { if ::is_partial_supported() { u8_::<_, _, true>(input) } else { u8_::<_, _, false>(input) } }) .parse_next(input) } fn u8_, const PARTIAL: bool>(input: I) -> IResult where I: StreamIsPartial, I: Stream, { input.next_token().ok_or_else(|| { if PARTIAL && input.is_partial() { ErrMode::Incomplete(Needed::new(1)) } else { ErrMode::Backtrack(E::from_error_kind(input, ErrorKind::Token)) } }) } /// Recognizes an unsigned 2 bytes integer /// /// If the parameter is `winnow::binary::Endianness::Big`, parse a big endian u16 integer, /// otherwise if `winnow::binary::Endianness::Little` parse a little endian u16 integer. /// /// *Complete version*: returns an error if there is not enough input data /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::u16; /// /// let be_u16 = |s| { /// u16(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_u16(&b"\x00\x03abcefg"[..]), Ok((&b"abcefg"[..], 0x0003))); /// assert_eq!(be_u16(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// /// let le_u16 = |s| { /// u16(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_u16(&b"\x00\x03abcefg"[..]), Ok((&b"abcefg"[..], 0x0300))); /// assert_eq!(le_u16(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// # use winnow::Partial; /// use winnow::binary::u16; /// /// let be_u16 = |s| { /// u16::<_, Error<_>>(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_u16(Partial::new(&b"\x00\x03abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x0003))); /// assert_eq!(be_u16(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(1)))); /// /// let le_u16 = |s| { /// u16::<_, Error<_>>(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_u16(Partial::new(&b"\x00\x03abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x0300))); /// assert_eq!(le_u16(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(1)))); /// ``` #[inline(always)] pub fn u16>(endian: Endianness) -> impl Parser where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { move |input: I| { match endian { Endianness::Big => be_u16, Endianness::Little => le_u16, #[cfg(target_endian = "big")] Endianness::Native => be_u16, #[cfg(target_endian = "little")] Endianness::Native => le_u16, } }(input) } /// Recognizes an unsigned 3 byte integer /// /// If the parameter is `winnow::binary::Endianness::Big`, parse a big endian u24 integer, /// otherwise if `winnow::binary::Endianness::Little` parse a little endian u24 integer. /// /// *Complete version*: returns an error if there is not enough input data /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::u24; /// /// let be_u24 = |s| { /// u24(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_u24(&b"\x00\x03\x05abcefg"[..]), Ok((&b"abcefg"[..], 0x000305))); /// assert_eq!(be_u24(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// /// let le_u24 = |s| { /// u24(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_u24(&b"\x00\x03\x05abcefg"[..]), Ok((&b"abcefg"[..], 0x050300))); /// assert_eq!(le_u24(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// # use winnow::Partial; /// use winnow::binary::u24; /// /// let be_u24 = |s| { /// u24::<_,Error<_>>(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_u24(Partial::new(&b"\x00\x03\x05abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x000305))); /// assert_eq!(be_u24(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(2)))); /// /// let le_u24 = |s| { /// u24::<_, Error<_>>(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_u24(Partial::new(&b"\x00\x03\x05abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x050300))); /// assert_eq!(le_u24(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(2)))); /// ``` #[inline(always)] pub fn u24>(endian: Endianness) -> impl Parser where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { move |input: I| { match endian { Endianness::Big => be_u24, Endianness::Little => le_u24, #[cfg(target_endian = "big")] Endianness::Native => be_u24, #[cfg(target_endian = "little")] Endianness::Native => le_u24, } }(input) } /// Recognizes an unsigned 4 byte integer /// /// If the parameter is `winnow::binary::Endianness::Big`, parse a big endian u32 integer, /// otherwise if `winnow::binary::Endianness::Little` parse a little endian u32 integer. /// /// *Complete version*: returns an error if there is not enough input data /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::u32; /// /// let be_u32 = |s| { /// u32(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_u32(&b"\x00\x03\x05\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x00030507))); /// assert_eq!(be_u32(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// /// let le_u32 = |s| { /// u32(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_u32(&b"\x00\x03\x05\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x07050300))); /// assert_eq!(le_u32(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// # use winnow::Partial; /// use winnow::binary::u32; /// /// let be_u32 = |s| { /// u32::<_, Error<_>>(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_u32(Partial::new(&b"\x00\x03\x05\x07abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x00030507))); /// assert_eq!(be_u32(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(3)))); /// /// let le_u32 = |s| { /// u32::<_, Error<_>>(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_u32(Partial::new(&b"\x00\x03\x05\x07abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x07050300))); /// assert_eq!(le_u32(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(3)))); /// ``` #[inline(always)] pub fn u32>(endian: Endianness) -> impl Parser where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { move |input: I| { match endian { Endianness::Big => be_u32, Endianness::Little => le_u32, #[cfg(target_endian = "big")] Endianness::Native => be_u32, #[cfg(target_endian = "little")] Endianness::Native => le_u32, } }(input) } /// Recognizes an unsigned 8 byte integer /// /// If the parameter is `winnow::binary::Endianness::Big`, parse a big endian u64 integer, /// otherwise if `winnow::binary::Endianness::Little` parse a little endian u64 integer. /// /// *Complete version*: returns an error if there is not enough input data /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::u64; /// /// let be_u64 = |s| { /// u64(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_u64(&b"\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x0001020304050607))); /// assert_eq!(be_u64(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// /// let le_u64 = |s| { /// u64(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_u64(&b"\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x0706050403020100))); /// assert_eq!(le_u64(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// # use winnow::Partial; /// use winnow::binary::u64; /// /// let be_u64 = |s| { /// u64::<_, Error<_>>(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_u64(Partial::new(&b"\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x0001020304050607))); /// assert_eq!(be_u64(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(7)))); /// /// let le_u64 = |s| { /// u64::<_, Error<_>>(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_u64(Partial::new(&b"\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x0706050403020100))); /// assert_eq!(le_u64(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(7)))); /// ``` #[inline(always)] pub fn u64>(endian: Endianness) -> impl Parser where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { move |input: I| { match endian { Endianness::Big => be_u64, Endianness::Little => le_u64, #[cfg(target_endian = "big")] Endianness::Native => be_u64, #[cfg(target_endian = "little")] Endianness::Native => le_u64, } }(input) } /// Recognizes an unsigned 16 byte integer /// /// If the parameter is `winnow::binary::Endianness::Big`, parse a big endian u128 integer, /// otherwise if `winnow::binary::Endianness::Little` parse a little endian u128 integer. /// /// *Complete version*: returns an error if there is not enough input data /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::u128; /// /// let be_u128 = |s| { /// u128(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_u128(&b"\x00\x01\x02\x03\x04\x05\x06\x07\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x00010203040506070001020304050607))); /// assert_eq!(be_u128(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// /// let le_u128 = |s| { /// u128(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_u128(&b"\x00\x01\x02\x03\x04\x05\x06\x07\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x07060504030201000706050403020100))); /// assert_eq!(le_u128(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// # use winnow::Partial; /// use winnow::binary::u128; /// /// let be_u128 = |s| { /// u128::<_, Error<_>>(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_u128(Partial::new(&b"\x00\x01\x02\x03\x04\x05\x06\x07\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x00010203040506070001020304050607))); /// assert_eq!(be_u128(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(15)))); /// /// let le_u128 = |s| { /// u128::<_, Error<_>>(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_u128(Partial::new(&b"\x00\x01\x02\x03\x04\x05\x06\x07\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x07060504030201000706050403020100))); /// assert_eq!(le_u128(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(15)))); /// ``` #[inline(always)] pub fn u128>(endian: Endianness) -> impl Parser where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { move |input: I| { match endian { Endianness::Big => be_u128, Endianness::Little => le_u128, #[cfg(target_endian = "big")] Endianness::Native => be_u128, #[cfg(target_endian = "little")] Endianness::Native => le_u128, } }(input) } /// Recognizes a signed 1 byte integer /// /// **Note:** that endianness does not apply to 1 byte numbers. /// /// *Complete version*: returns an error if there is not enough input data /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::i8; /// /// fn parser(s: &[u8]) -> IResult<&[u8], i8> { /// i8.parse_next(s) /// } /// /// assert_eq!(parser(&b"\x00\x03abcefg"[..]), Ok((&b"\x03abcefg"[..], 0x00))); /// assert_eq!(parser(&b""[..]), Err(ErrMode::Backtrack(Error::new(&[][..], ErrorKind::Token)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// # use winnow::Partial; /// use winnow::binary::i8; /// /// fn parser(s: Partial<&[u8]>) -> IResult, i8> { /// i8.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&b"\x00\x03abcefg"[..])), Ok((Partial::new(&b"\x03abcefg"[..]), 0x00))); /// assert_eq!(parser(Partial::new(&b""[..])), Err(ErrMode::Incomplete(Needed::new(1)))); /// ``` #[inline(always)] pub fn i8>(input: I) -> IResult where I: StreamIsPartial, I: Stream, { trace("i8", move |input: I| { if ::is_partial_supported() { u8_::<_, _, true>(input) } else { u8_::<_, _, false>(input) } .map(|(i, n)| (i, n as i8)) }) .parse_next(input) } /// Recognizes a signed 2 byte integer /// /// If the parameter is `winnow::binary::Endianness::Big`, parse a big endian i16 integer, /// otherwise if `winnow::binary::Endianness::Little` parse a little endian i16 integer. /// /// *Complete version*: returns an error if there is not enough input data /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::i16; /// /// let be_i16 = |s| { /// i16(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_i16(&b"\x00\x03abcefg"[..]), Ok((&b"abcefg"[..], 0x0003))); /// assert_eq!(be_i16(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// /// let le_i16 = |s| { /// i16(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_i16(&b"\x00\x03abcefg"[..]), Ok((&b"abcefg"[..], 0x0300))); /// assert_eq!(le_i16(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// # use winnow::Partial; /// use winnow::binary::i16; /// /// let be_i16 = |s| { /// i16::<_, Error<_>>(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_i16(Partial::new(&b"\x00\x03abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x0003))); /// assert_eq!(be_i16(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(1)))); /// /// let le_i16 = |s| { /// i16::<_, Error<_>>(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_i16(Partial::new(&b"\x00\x03abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x0300))); /// assert_eq!(le_i16(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(1)))); /// ``` #[inline(always)] pub fn i16>(endian: Endianness) -> impl Parser where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { move |input: I| { match endian { Endianness::Big => be_i16, Endianness::Little => le_i16, #[cfg(target_endian = "big")] Endianness::Native => be_i16, #[cfg(target_endian = "little")] Endianness::Native => le_i16, } }(input) } /// Recognizes a signed 3 byte integer /// /// If the parameter is `winnow::binary::Endianness::Big`, parse a big endian i24 integer, /// otherwise if `winnow::binary::Endianness::Little` parse a little endian i24 integer. /// /// *Complete version*: returns an error if there is not enough input data /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::i24; /// /// let be_i24 = |s| { /// i24(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_i24(&b"\x00\x03\x05abcefg"[..]), Ok((&b"abcefg"[..], 0x000305))); /// assert_eq!(be_i24(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// /// let le_i24 = |s| { /// i24(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_i24(&b"\x00\x03\x05abcefg"[..]), Ok((&b"abcefg"[..], 0x050300))); /// assert_eq!(le_i24(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// # use winnow::Partial; /// use winnow::binary::i24; /// /// let be_i24 = |s| { /// i24::<_, Error<_>>(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_i24(Partial::new(&b"\x00\x03\x05abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x000305))); /// assert_eq!(be_i24(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(2)))); /// /// let le_i24 = |s| { /// i24::<_, Error<_>>(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_i24(Partial::new(&b"\x00\x03\x05abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x050300))); /// assert_eq!(le_i24(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(2)))); /// ``` #[inline(always)] pub fn i24>(endian: Endianness) -> impl Parser where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { move |input: I| { match endian { Endianness::Big => be_i24, Endianness::Little => le_i24, #[cfg(target_endian = "big")] Endianness::Native => be_i24, #[cfg(target_endian = "little")] Endianness::Native => le_i24, } }(input) } /// Recognizes a signed 4 byte integer /// /// If the parameter is `winnow::binary::Endianness::Big`, parse a big endian i32 integer, /// otherwise if `winnow::binary::Endianness::Little` parse a little endian i32 integer. /// /// *Complete version*: returns an error if there is not enough input data /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::i32; /// /// let be_i32 = |s| { /// i32(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_i32(&b"\x00\x03\x05\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x00030507))); /// assert_eq!(be_i32(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// /// let le_i32 = |s| { /// i32(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_i32(&b"\x00\x03\x05\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x07050300))); /// assert_eq!(le_i32(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// # use winnow::Partial; /// use winnow::binary::i32; /// /// let be_i32 = |s| { /// i32::<_, Error<_>>(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_i32(Partial::new(&b"\x00\x03\x05\x07abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x00030507))); /// assert_eq!(be_i32(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(3)))); /// /// let le_i32 = |s| { /// i32::<_, Error<_>>(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_i32(Partial::new(&b"\x00\x03\x05\x07abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x07050300))); /// assert_eq!(le_i32(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(3)))); /// ``` #[inline(always)] pub fn i32>(endian: Endianness) -> impl Parser where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { move |input: I| { match endian { Endianness::Big => be_i32, Endianness::Little => le_i32, #[cfg(target_endian = "big")] Endianness::Native => be_i32, #[cfg(target_endian = "little")] Endianness::Native => le_i32, } }(input) } /// Recognizes a signed 8 byte integer /// /// If the parameter is `winnow::binary::Endianness::Big`, parse a big endian i64 integer, /// otherwise if `winnow::binary::Endianness::Little` parse a little endian i64 integer. /// /// *Complete version*: returns an error if there is not enough input data /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::i64; /// /// let be_i64 = |s| { /// i64(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_i64(&b"\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x0001020304050607))); /// assert_eq!(be_i64(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// /// let le_i64 = |s| { /// i64(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_i64(&b"\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x0706050403020100))); /// assert_eq!(le_i64(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// # use winnow::Partial; /// use winnow::binary::i64; /// /// let be_i64 = |s| { /// i64::<_, Error<_>>(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_i64(Partial::new(&b"\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x0001020304050607))); /// assert_eq!(be_i64(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(7)))); /// /// let le_i64 = |s| { /// i64::<_, Error<_>>(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_i64(Partial::new(&b"\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x0706050403020100))); /// assert_eq!(le_i64(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(7)))); /// ``` #[inline(always)] pub fn i64>(endian: Endianness) -> impl Parser where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { move |input: I| { match endian { Endianness::Big => be_i64, Endianness::Little => le_i64, #[cfg(target_endian = "big")] Endianness::Native => be_i64, #[cfg(target_endian = "little")] Endianness::Native => le_i64, } }(input) } /// Recognizes a signed 16 byte integer /// /// If the parameter is `winnow::binary::Endianness::Big`, parse a big endian i128 integer, /// otherwise if `winnow::binary::Endianness::Little` parse a little endian i128 integer. /// /// *Complete version*: returns an error if there is not enough input data /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::i128; /// /// let be_i128 = |s| { /// i128(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_i128(&b"\x00\x01\x02\x03\x04\x05\x06\x07\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x00010203040506070001020304050607))); /// assert_eq!(be_i128(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// /// let le_i128 = |s| { /// i128(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_i128(&b"\x00\x01\x02\x03\x04\x05\x06\x07\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..]), Ok((&b"abcefg"[..], 0x07060504030201000706050403020100))); /// assert_eq!(le_i128(&b"\x01"[..]), Err(ErrMode::Backtrack(Error::new(&[0x01][..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// # use winnow::Partial; /// use winnow::binary::i128; /// /// let be_i128 = |s| { /// i128::<_, Error<_>>(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_i128(Partial::new(&b"\x00\x01\x02\x03\x04\x05\x06\x07\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x00010203040506070001020304050607))); /// assert_eq!(be_i128(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(15)))); /// /// let le_i128 = |s| { /// i128::<_, Error<_>>(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_i128(Partial::new(&b"\x00\x01\x02\x03\x04\x05\x06\x07\x00\x01\x02\x03\x04\x05\x06\x07abcefg"[..])), Ok((Partial::new(&b"abcefg"[..]), 0x07060504030201000706050403020100))); /// assert_eq!(le_i128(Partial::new(&b"\x01"[..])), Err(ErrMode::Incomplete(Needed::new(15)))); /// ``` #[inline(always)] pub fn i128>(endian: Endianness) -> impl Parser where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { move |input: I| { match endian { Endianness::Big => be_i128, Endianness::Little => le_i128, #[cfg(target_endian = "big")] Endianness::Native => be_i128, #[cfg(target_endian = "little")] Endianness::Native => le_i128, } }(input) } /// Recognizes a big endian 4 bytes floating point number. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::be_f32; /// /// fn parser(s: &[u8]) -> IResult<&[u8], f32> { /// be_f32.parse_next(s) /// } /// /// assert_eq!(parser(&[0x41, 0x48, 0x00, 0x00][..]), Ok((&b""[..], 12.5))); /// assert_eq!(parser(&b"abc"[..]), Err(ErrMode::Backtrack(Error::new(&b"abc"[..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::be_f32; /// /// fn parser(s: Partial<&[u8]>) -> IResult, f32> { /// be_f32.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&[0x40, 0x29, 0x00, 0x00][..])), Ok((Partial::new(&b""[..]), 2.640625))); /// assert_eq!(parser(Partial::new(&[0x01][..])), Err(ErrMode::Incomplete(Needed::new(3)))); /// ``` #[inline(always)] pub fn be_f32>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("be_f32", move |input: I| { be_uint::<_, u32, _>(input, 4).map(|(i, n)| (i, f32::from_bits(n))) }) .parse_next(input) } /// Recognizes a big endian 8 bytes floating point number. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::be_f64; /// /// fn parser(s: &[u8]) -> IResult<&[u8], f64> { /// be_f64.parse_next(s) /// } /// /// assert_eq!(parser(&[0x40, 0x29, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00][..]), Ok((&b""[..], 12.5))); /// assert_eq!(parser(&b"abc"[..]), Err(ErrMode::Backtrack(Error::new(&b"abc"[..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::be_f64; /// /// fn parser(s: Partial<&[u8]>) -> IResult, f64> { /// be_f64::<_, Error<_>>.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&[0x40, 0x29, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00][..])), Ok((Partial::new(&b""[..]), 12.5))); /// assert_eq!(parser(Partial::new(&[0x01][..])), Err(ErrMode::Incomplete(Needed::new(7)))); /// ``` #[inline(always)] pub fn be_f64>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("be_f64", move |input: I| { be_uint::<_, u64, _>(input, 8).map(|(i, n)| (i, f64::from_bits(n))) }) .parse_next(input) } /// Recognizes a little endian 4 bytes floating point number. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::le_f32; /// /// fn parser(s: &[u8]) -> IResult<&[u8], f32> { /// le_f32.parse_next(s) /// } /// /// assert_eq!(parser(&[0x00, 0x00, 0x48, 0x41][..]), Ok((&b""[..], 12.5))); /// assert_eq!(parser(&b"abc"[..]), Err(ErrMode::Backtrack(Error::new(&b"abc"[..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::le_f32; /// /// fn parser(s: Partial<&[u8]>) -> IResult, f32> { /// le_f32::<_, Error<_>>.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&[0x00, 0x00, 0x48, 0x41][..])), Ok((Partial::new(&b""[..]), 12.5))); /// assert_eq!(parser(Partial::new(&[0x01][..])), Err(ErrMode::Incomplete(Needed::new(3)))); /// ``` #[inline(always)] pub fn le_f32>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("le_f32", move |input: I| { le_uint::<_, u32, _>(input, 4).map(|(i, n)| (i, f32::from_bits(n))) }) .parse_next(input) } /// Recognizes a little endian 8 bytes floating point number. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::le_f64; /// /// fn parser(s: &[u8]) -> IResult<&[u8], f64> { /// le_f64.parse_next(s) /// } /// /// assert_eq!(parser(&[0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x29, 0x40][..]), Ok((&b""[..], 12.5))); /// assert_eq!(parser(&b"abc"[..]), Err(ErrMode::Backtrack(Error::new(&b"abc"[..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::Partial; /// use winnow::binary::le_f64; /// /// fn parser(s: Partial<&[u8]>) -> IResult, f64> { /// le_f64::<_, Error<_>>.parse_next(s) /// } /// /// assert_eq!(parser(Partial::new(&[0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x48, 0x41][..])), Ok((Partial::new(&b""[..]), 3145728.0))); /// assert_eq!(parser(Partial::new(&[0x01][..])), Err(ErrMode::Incomplete(Needed::new(7)))); /// ``` #[inline(always)] pub fn le_f64>(input: I) -> IResult where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { trace("be_f64", move |input: I| { le_uint::<_, u64, _>(input, 8).map(|(i, n)| (i, f64::from_bits(n))) }) .parse_next(input) } /// Recognizes a 4 byte floating point number /// /// If the parameter is `winnow::binary::Endianness::Big`, parse a big endian f32 float, /// otherwise if `winnow::binary::Endianness::Little` parse a little endian f32 float. /// /// *Complete version*: returns an error if there is not enough input data /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::f32; /// /// let be_f32 = |s| { /// f32(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_f32(&[0x41, 0x48, 0x00, 0x00][..]), Ok((&b""[..], 12.5))); /// assert_eq!(be_f32(&b"abc"[..]), Err(ErrMode::Backtrack(Error::new(&b"abc"[..], ErrorKind::Slice)))); /// /// let le_f32 = |s| { /// f32(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_f32(&[0x00, 0x00, 0x48, 0x41][..]), Ok((&b""[..], 12.5))); /// assert_eq!(le_f32(&b"abc"[..]), Err(ErrMode::Backtrack(Error::new(&b"abc"[..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// # use winnow::Partial; /// use winnow::binary::f32; /// /// let be_f32 = |s| { /// f32::<_, Error<_>>(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_f32(Partial::new(&[0x41, 0x48, 0x00, 0x00][..])), Ok((Partial::new(&b""[..]), 12.5))); /// assert_eq!(be_f32(Partial::new(&b"abc"[..])), Err(ErrMode::Incomplete(Needed::new(1)))); /// /// let le_f32 = |s| { /// f32::<_, Error<_>>(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_f32(Partial::new(&[0x00, 0x00, 0x48, 0x41][..])), Ok((Partial::new(&b""[..]), 12.5))); /// assert_eq!(le_f32(Partial::new(&b"abc"[..])), Err(ErrMode::Incomplete(Needed::new(1)))); /// ``` #[inline(always)] pub fn f32>(endian: Endianness) -> impl Parser where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { move |input: I| { match endian { Endianness::Big => be_f32, Endianness::Little => le_f32, #[cfg(target_endian = "big")] Endianness::Native => be_f32, #[cfg(target_endian = "little")] Endianness::Native => le_f32, } }(input) } /// Recognizes an 8 byte floating point number /// /// If the parameter is `winnow::binary::Endianness::Big`, parse a big endian f64 float, /// otherwise if `winnow::binary::Endianness::Little` parse a little endian f64 float. /// /// *Complete version*: returns an error if there is not enough input data /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// use winnow::binary::f64; /// /// let be_f64 = |s| { /// f64(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_f64(&[0x40, 0x29, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00][..]), Ok((&b""[..], 12.5))); /// assert_eq!(be_f64(&b"abc"[..]), Err(ErrMode::Backtrack(Error::new(&b"abc"[..], ErrorKind::Slice)))); /// /// let le_f64 = |s| { /// f64(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_f64(&[0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x29, 0x40][..]), Ok((&b""[..], 12.5))); /// assert_eq!(le_f64(&b"abc"[..]), Err(ErrMode::Backtrack(Error::new(&b"abc"[..], ErrorKind::Slice)))); /// ``` /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Error, error::Needed}; /// # use winnow::prelude::*; /// # use winnow::error::Needed::Size; /// # use winnow::Partial; /// use winnow::binary::f64; /// /// let be_f64 = |s| { /// f64::<_, Error<_>>(winnow::binary::Endianness::Big).parse_next(s) /// }; /// /// assert_eq!(be_f64(Partial::new(&[0x40, 0x29, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00][..])), Ok((Partial::new(&b""[..]), 12.5))); /// assert_eq!(be_f64(Partial::new(&b"abc"[..])), Err(ErrMode::Incomplete(Needed::new(5)))); /// /// let le_f64 = |s| { /// f64::<_, Error<_>>(winnow::binary::Endianness::Little).parse_next(s) /// }; /// /// assert_eq!(le_f64(Partial::new(&[0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x29, 0x40][..])), Ok((Partial::new(&b""[..]), 12.5))); /// assert_eq!(le_f64(Partial::new(&b"abc"[..])), Err(ErrMode::Incomplete(Needed::new(5)))); /// ``` #[inline(always)] pub fn f64>(endian: Endianness) -> impl Parser where I: StreamIsPartial, I: Stream, ::Slice: AsBytes, { move |input: I| { match endian { Endianness::Big => be_f64, Endianness::Little => le_f64, #[cfg(target_endian = "big")] Endianness::Native => be_f64, #[cfg(target_endian = "little")] Endianness::Native => le_f64, } }(input) } /// Gets a number from the parser and returns a /// subslice of the input of that size. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Arguments /// * `f` The parser to apply. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::ErrorKind, error::Needed, stream::Partial}; /// # use winnow::prelude::*; /// use winnow::Bytes; /// use winnow::binary::be_u16; /// use winnow::binary::length_data; /// use winnow::token::tag; /// /// type Stream<'i> = Partial<&'i Bytes>; /// /// fn stream(b: &[u8]) -> Stream<'_> { /// Partial::new(Bytes::new(b)) /// } /// /// fn parser(s: Stream<'_>) -> IResult, &[u8]> { /// length_data(be_u16).parse_next(s) /// } /// /// assert_eq!(parser(stream(b"\x00\x03abcefg")), Ok((stream(&b"efg"[..]), &b"abc"[..]))); /// assert_eq!(parser(stream(b"\x00\x03a")), Err(ErrMode::Incomplete(Needed::new(2)))); /// ``` pub fn length_data(mut f: F) -> impl Parser::Slice, E> where I: StreamIsPartial, I: Stream, N: ToUsize, F: Parser, E: ParseError, { trace("length_data", move |i: I| { let (i, length) = f.parse_next(i)?; crate::token::take(length).parse_next(i) }) } /// Gets a number from the first parser, /// takes a subslice of the input of that size, /// then applies the second parser on that subslice. /// If the second parser returns `Incomplete`, /// `length_value` will return an error. /// /// *Complete version*: Returns an error if there is not enough input data. /// /// *Partial version*: Will return `Err(winnow::error::ErrMode::Incomplete(_))` if there is not enough data. /// /// # Arguments /// * `f` The parser to apply. /// * `g` The parser to apply on the subslice. /// /// # Example /// /// ```rust /// # use winnow::{error::ErrMode, error::{Error, ErrorKind}, error::Needed, stream::{Partial, StreamIsPartial}}; /// # use winnow::prelude::*; /// use winnow::Bytes; /// use winnow::binary::be_u16; /// use winnow::binary::length_value; /// use winnow::token::tag; /// /// type Stream<'i> = Partial<&'i Bytes>; /// /// fn stream(b: &[u8]) -> Stream<'_> { /// Partial::new(Bytes::new(b)) /// } /// /// fn complete_stream(b: &[u8]) -> Stream<'_> { /// let mut p = Partial::new(Bytes::new(b)); /// let _ = p.complete(); /// p /// } /// /// fn parser(s: Stream<'_>) -> IResult, &[u8]> { /// length_value(be_u16, "abc").parse_next(s) /// } /// /// assert_eq!(parser(stream(b"\x00\x03abcefg")), Ok((stream(&b"efg"[..]), &b"abc"[..]))); /// assert_eq!(parser(stream(b"\x00\x03123123")), Err(ErrMode::Backtrack(Error::new(complete_stream(&b"123"[..]), ErrorKind::Tag)))); /// assert_eq!(parser(stream(b"\x00\x03a")), Err(ErrMode::Incomplete(Needed::new(2)))); /// ``` pub fn length_value(mut f: F, mut g: G) -> impl Parser where I: StreamIsPartial, I: Stream + UpdateSlice, N: ToUsize, F: Parser, G: Parser, E: ParseError, { trace("length_value", move |i: I| { let (i, data) = length_data(f.by_ref()).parse_next(i)?; let mut data = I::update_slice(i.clone(), data); let _ = data.complete(); let (_, o) = g.by_ref().complete_err().parse_next(data)?; Ok((i, o)) }) } /// Gets a number from the first parser, /// then applies the second parser that many times. /// /// # Arguments /// * `f` The parser to apply to obtain the count. /// * `g` The parser to apply repeatedly. /// /// # Example /// /// ```rust /// # #[cfg(feature = "std")] { /// # use winnow::prelude::*; /// # use winnow::{error::ErrMode, error::{Error, ErrorKind}, error::Needed}; /// # use winnow::prelude::*; /// use winnow::Bytes; /// use winnow::binary::u8; /// use winnow::binary::length_count; /// use winnow::token::tag; /// /// type Stream<'i> = &'i Bytes; /// /// fn stream(b: &[u8]) -> Stream<'_> { /// Bytes::new(b) /// } /// /// fn parser(s: Stream<'_>) -> IResult, Vec<&[u8]>> { /// length_count(u8.map(|i| { /// println!("got number: {}", i); /// i /// }), "abc").parse_next(s) /// } /// /// assert_eq!(parser(stream(b"\x02abcabcabc")), Ok((stream(b"abc"), vec![&b"abc"[..], &b"abc"[..]]))); /// assert_eq!(parser(stream(b"\x03123123123")), Err(ErrMode::Backtrack(Error::new(stream(b"123123123"), ErrorKind::Tag)))); /// # } /// ``` pub fn length_count(mut f: F, mut g: G) -> impl Parser where I: Stream, N: ToUsize, C: Accumulate, F: Parser, G: Parser, E: ParseError, { trace("length_count", move |i: I| { let (i, n) = f.parse_next(i)?; let n = n.to_usize(); repeat(n, g.by_ref()).parse_next(i) }) }