| [char](https://docs.rs/nom/latest/nom/macro.char.html) | `char!('a')` | `"abc"` | `Ok(("bc", 'a'))` |Matches one character (works with non ASCII chars too) |
| [is_a](https://docs.rs/nom/latest/nom/macro.is_a.html) | ` is_a!("ab")` | `"ababc"` | `Ok(("c", "abab"))` |Matches a sequence of any of the characters passed as arguments|
| [is_not](https://docs.rs/nom/latest/nom/macro.is_not.html) | `is_not!("cd")` | `"ababc"` | `Ok(("c", "abab"))` |Matches a sequence of none of the characters passed as arguments|
| [one_of](https://docs.rs/nom/latest/nom/macro.one_of.html) | `one_of!("abc")` | `"abc"` | `Ok(("bc", 'a'))` |Matches one of the provided characters (works with non ASCII characters too)|
| [none_of](https://docs.rs/nom/latest/nom/macro.none_of.html) | `none_of!("abc")` | `"xyab"` | `Ok(("yab", 'x'))` |Matches anything but the provided characters|
| [tag](https://docs.rs/nom/latest/nom/macro.tag.html) | `tag!("hello")` | `"hello world"` | `Ok((" world", "hello"))` |Recognizes a specific suite of characters or bytes|
| [tag_no_case](https://docs.rs/nom/latest/nom/macro.tag_no_case.html) | `tag_no_case!("hello")` | `"HeLLo World"` | `Ok((" World", "HeLLo"))` |Case insensitive comparison. Note that case insensitive comparison is not well defined for unicode, and that you might have bad surprises|
| [take](https://docs.rs/nom/latest/nom/macro.take.html) | `take!(4)` | `"hello"` | `Ok(("o", "hell"))` |Takes a specific number of bytes or characters|
| [take_while](https://docs.rs/nom/latest/nom/macro.take_while.html) | `take_while!(is_alphabetic)` | `"abc123"` | `Ok(("123", "abc"))` |Returns the longest list of bytes for which the provided function returns true. `take_while1` does the same, but must return at least one character|
| [take_till](https://docs.rs/nom/latest/nom/macro.take_till.html) | `take_till!(is_alphabetic)` | `"123abc"` | `Ok(("abc", "123"))` |Returns the longest list of bytes or characters until the provided function returns true. `take_till1` does the same, but must return at least one character. This is the reverse behaviour from `take_while`: `take_till!(f)` is equivalent to `take_while!(\|c\| !f(c))`|
| [take_until](https://docs.rs/nom/latest/nom/macro.take_until.html) | `take_until!("world")` | `"Hello world"` | `Ok(("world", "Hello "))` |Returns the longest list of bytes or characters until the provided tag is found. `take_until1` does the same, but must return at least one character|
| [alt](https://docs.rs/nom/latest/nom/macro.alt.html) | `alt!(tag!("ab") \| tag!("cd"))` | `"cdef"` | `Ok(("ef", "cd"))` |Try a list of parsers and return the result of the first successful one|
| [switch](https://docs.rs/nom/latest/nom/macro.switch.html) | `switch!(take!(2), "ab" => tag!("XYZ") \| "cd" => tag!("123"))` | `"cd1234"` | `Ok(("4", "123"))` |Choose the next parser depending on the result of the first one, if successful, and returns the result of the second parser|
| [permutation](https://docs.rs/nom/latest/nom/macro.permutation.html) | `permutation!(tag!("ab"), tag!("cd"), tag!("12"))` | `"cd12abc"` | `Ok(("c", ("ab", "cd", "12"))` |Succeeds when all its child parser have succeeded, whatever the order|
| [tuple](https://docs.rs/nom/latest/nom/macro.tuple.html) | `tuple!(tag!("ab"), tag!("XY"), take!(1))` | `"abXYZ!"` | `Ok(("!", ("ab", "XY", "Z")))` |Chains parsers and assemble the sub results in a tuple. You can use as many child parsers as you can put elements in a tuple|
| [do_parse](https://docs.rs/nom/latest/nom/macro.do_parse.html) | `do_parse!(tag: take!(2) >> length: be_u8 >> data: take!(length) >> (Buffer { tag: tag, data: data}) )` | `&[0, 0, 3, 1, 2, 3][..]` | `Buffer { tag: &[0, 0][..], data: &[1, 2, 3][..] }` |`do_parse` applies sub parsers in a sequence. It can store intermediary results and make them available for later parsers|
| [count](https://docs.rs/nom/latest/nom/macro.count.html) | `count!(take!(2), 3)` | `"abcdefgh"` | `Ok(("gh", vec!("ab", "cd", "ef")))` |Applies the child parser a specified number of times|
| [many0](https://docs.rs/nom/latest/nom/macro.many0.html) | `many0!(tag!("ab"))` | `"abababc"` | `Ok(("c", vec!("ab", "ab", "ab")))` |Applies the parser 0 or more times and returns the list of results in a Vec. `many1` does the same operation but must return at least one element|
| [many_m_n](https://docs.rs/nom/latest/nom/macro.many_m_n.html) | `many_m_n!(1, 3, tag!("ab"))` | `"ababc"` | `Ok(("c", vec!("ab", "ab")))` |Applies the parser between m and n times (n included) and returns the list of results in a Vec|
| [many_till](https://docs.rs/nom/latest/nom/macro.many_till.html) | `many_till!(tag!( "ab" ), tag!( "ef" ))` | `"ababefg"` | `Ok(("g", (vec!("ab", "ab"), "ef")))` |Applies the first parser until the second applies. Returns a tuple containing the list of results from the first in a Vec and the result of the second|
| [separated_list](https://docs.rs/nom/latest/nom/macro.separated_list.html) | `separated_list!(tag!(","), tag!("ab"))` | `"ab,ab,ab."` | `Ok((".", vec!("ab", "ab", "ab")))` |`separated_nonempty_list` works like `separated_list` but must returns at least one element|
| [fold_many0](https://docs.rs/nom/latest/nom/macro.fold_many0.html) | `fold_many0!(be_u8, 0, \|acc, item\| acc + item)` | `[1, 2, 3]` | `Ok(([], 6))` |Applies the parser 0 or more times and folds the list of return values. The `fold_many1` version must apply the child parser at least one time|
| [fold_many_m_n](https://docs.rs/nom/latest/nom/macro.fold_many_m_n.html) | `fold_many_m_n!(1, 2, be_u8, 0, \|acc, item\| acc + item)` | `[1, 2, 3]` | `Ok(([3], 3))` |Applies the parser between m and n times (n included) and folds the list of return value|
| [length_count](https://docs.rs/nom/latest/nom/macro.length_count.html) | `length_count!(number, tag!("ab"))` | `"2ababab"` | `Ok(("ab", vec!("ab", "ab")))` |Gets a number from the first parser, then applies the second parser that many times|
- **configurable endianness:** `i16!`, `i32!`, `i64!`, `u16!`, `u32!`, `u64!` are combinators that take as argument a `nom::Endianness`, like this: `i16!(endianness)`. If the parameter is `nom::Endianness::Big`, parse a big endian `i16` integer, otherwise a little endian `i16` integer.
- **fixed endianness**: The functions are prefixed by `be_` for big endian numbers, and by `le_` for little endian numbers, and the suffix is the type they parse to. As an example, `be_u32` parses a big endian unsigned integer stored in 32 bits.
-`be_f32`, `be_f64`, `le_f32`, `le_f64`: Recognize floating point numbers
-`be_i8`, `be_i16`, `be_i24`, `be_i32`, `be_i64`: Big endian signed integers
-`be_u8`, `be_u16`, `be_u24`, `be_u32`, `be_u64`: Big endian unsigned integers
-`le_i8`, `le_i16`, `le_i24`, `le_i32`, `le_i64`: Little endian signed integers
-`le_u8`, `le_u16`, `le_u24`, `le_u32`, `le_u64`: Little endian unsigned integers
-`error_node_position!`: Creates a parse error from a `nom::ErrorKind`, the position in the input and the next error in the parsing tree. If the `verbose-errors` feature is not activated, it defaults to only the error code
-`error_position!`: Creates a parse error from a `nom::ErrorKind` and the position in the input. If the `verbose-errors` feature is not activated, it defaults to only the error code
-`fix_error!`: Translate parser result from `IResult` to `IResult` with a custom type
-`length_data!`: Gets a number from the first parser, then takes a subslice of the input of that size, and returns that subslice
-`length_bytes!`: Alias for length_data
-`length_value!`: 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
-`bits!`: Transforms the current input type (byte slice `&[u8]`) to a bit stream on which bit specific parsers and more general combinators can be applied
-`bytes!`: Transforms its bits stream input back into a byte slice for the underlying parser
-`tag_bits!`: Matches an integer pattern to a bitstream. The number of bits of the input to compare must be specified
-`take_bits!`: Generates a parser consuming the specified number of bits
-`named_args!`: Makes a function from a parser combination with arguments
-`named_attr!`: Makes a function from a parser combination with attributes
-`try_parse!`: A bit like `std::try!`, this macro will return the remaining input and parsed value if the child parser returned `Ok` and will do an early return for `Error` and `Incomplete`. This can provide more flexibility than `do_parse!` if needed