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Adam Chalmers

Parsing Text with Nom

"Parsing" is turning a stream of raw text or binary into some structured data types, i.e. a Rust type that your code can understand and use. This isn't the textbook definition of parsing, but damnit, this is my blog and my opinion. This tutorial is about nom, my favourite Rust parsing library. It uses a parser combinator approach: you start writing tiny parsers that match, say, a single number or a character. These become building blocks for larger parsers, that match, say, a date or a phone number. By combining many small parsers together, you can build a big parser that decodes a file or stream into nice Rust structs and enums. In this tutorial we'll use Nom to parse the input file to an Advent of Code puzzle.

What are parsers?

Most programs need to read some input before they know what to do. A video game will move a character based on keyboard input, the cat command will display different text based on its arguments, and accounting software will output a very good or a very worrying message depending on the spreadsheet it loads.

Program input can come in many different forms. Sometimes the input is already structured, for example, most video game programming environments can recognize when a mouse button is pressed, know which mouse button it was, and call the appropriate code to react to that. But sometimes input is unstructured -- it can't be easily understood by your program. For example, the input could be a text file. Your programming languages probably understands that it's been given a text file. But it doesn't understand what the text means or what it should do in response. So programmers use parsers to take this unstructured file and examine it, match it against some logical rules. Once the data has been structured, you can call the appropriate functions to handle it.

For example, in Advent of Code day 5 you're given a list of lines and must find points where two or more lines overlap. The Advent of Code website gives the puzzle input in a text file like this:

0,9 -> 5,9
8,0 -> 0,8
9,4 -> 3,4
2,2 -> 2,1
7,0 -> 7,4
6,4 -> 2,0
0,9 -> 2,9
3,4 -> 1,4
0,0 -> 8,8
5,5 -> 8,2

Rust doesn't natively know to interpret this file as a list of lines in 2D space. To the Rust compiler, this text file is just a big String. We have to write a parser which takes that string and parses it into types Rust can understand, like

/// A point in 2D space
pub struct Point {
    pub x: u32,
    pub y: u32,
}

/// A line spanning two points.
pub struct Line(pub Point, pub Point);

If you already know the basics of Nom, or you've used parser combinators in other languages, feel free to skip ahead, but for now, let's take a closer look at Nom.

Building parsers with Nom

Nom is a parser combinator library. In general, a combinator framework gives you

  1. A set of tiny primitive tools for doing small, simple tasks.
  2. Ways to combine those tools to accomplish more complex tasks. These are called combinators.

For example, you can think of the Bash shell as a combinator approach. You have

  1. A set of primitive tools like ls, cd, cat and grep that do one thing, and do it well.
  2. Ways to combine tools, for example |, &&, loops and if statements.

Another example of the combinator pattern is Rust's Result<T,E> type. Your primitive tools might be closures like Fn(T) -> Result<V, U>. The combinators are methods like map, and_then and or_else.

Nom takes a similar approach, using combinators to combine parsers1. There are primitive parsers that match one simple value from the input string, and functions (called combinators) which let you combine multiple primitive parsers into a more complex (composite) parser. Let's look at the primitives first.

Primitive parsers

A parser's job is to consume bytes from some input, and try converting them into some output Rust value. If this conversion succeeds, the parser should return two things:

  1. The remaining input which wasn't parsed, so that you can continue running other parsers on the rest of the input file
  2. The parsed output value

If the conversion failed, the parser should return some helpful error.

In Nom, parsers are just functions. Each parser function has three generic types:

  • I is for input. In this tutorial, our input will always be a string, but you can use Nom to parse binary (Vec<u8> or Bytes) or your own custom type, for example tokens output by a lexer.
  • O is for output. The parser reads some bytes from the input and tries to convert them to its output value. Some parsers will output a number, a string, or some "business logic" type like a Person or User struct. In our Advent of Code above, we'll write parsers that output Points and Lines.
  • E is for error (just like in the stdlib Result<T,E>). It's generic because Nom supports different error types with different trade-offs. We'll discuss them later.

Each function's type signature is basically the same: Fn(I) -> Result<(I, O), E>. It's just a function that takes the input string, reads some bytes, and tries to convert them into an output value O. If that conversion succeeds, it returns the rest of the input (the remainder, the part the parser didn't need to read to get a value) and the value, which is why the OK branch is (I, O). If it fails, it just returns the error E.

Here's a very simple example parser: digit1. Technically it's nom::character::complete::digit12. The nom docs are usually really good, so let's take a look at their example.

use nom::character::complete::newline;

fn parser(input: &str) -> IResult<&str, &str> {
    digit1(input)
}

assert_eq!(parser("21c"), Ok(("c", "21")));
assert_eq!(parser("c1"), Err(Err::Error(Error::new("c1", ErrorKind::Digit))));
assert_eq!(parser(""), Err(Err::Error(Error::new("", ErrorKind::Digit))));

So, we see that digit1 is just a function. It takes one argument, the input string. The parser reads characters from the start of the input string, and if the character is a digit, it adds it to the output. When it finds a non-digit character, it terminates. Once it terminates it returns an IResult... what's that?

Remember above, we said that parsers should return (I, O) if they succeed (the remaining input string that wasn't consumed to get an output value, and the output value itself), and E if they fail. Well, IResult is just shorthand for this. It's a convenience type alias: type IResult<I, O, E = nom::error::Error<I>> = Result<(I, O), E>. Note that E, the error type, defaults to a certain Nom error type -- we'll talk about that in a second. The docs explain IResult well:

Holds the result of parsing functions. The Ok side is a pair containing the remainder of the input (the part of the data that was not parsed) and the produced value. The Err side contains an instance of nom::Err.

As expected, if the input string doesn't start with any digits, Nom returns an error. The example uses Nom's default Error type, which tells you two things:

  1. Where in the input string Nom failed.
  2. What Nom was trying to parse when it failed.

If you want more detail, you can use E = VerboseError instead of the default error type. This has a bit more overhead at runtime, but makes debugging easier.

Let's look at another parser, named tag. It matches some specific substring chosen by the programmer. The Nom docs have an example, using tag to match the substring "Hello":

use nom::bytes::complete::tag;

fn parser(s: &str) -> IResult<&str, &str> {
  tag("Hello")(s)
}

assert_eq!(parser("Hello, World!"), Ok((", World!", "Hello")));
assert_eq!(parser("Something"), Err(Err::Error(Error::new("Something", ErrorKind::Tag))));
assert_eq!(parser(""), Err(Err::Error(Error::new("", ErrorKind::Tag))));

Notice the tag function has a different type signature to the digit1 function! That's because digit1 is a parser -- it takes an input string and outputs an IResult, defined as "the result of parsing functions". But tag isn't exactly a parser -- it's a function which outputs a parser. It takes one argument, the substring to match on, and returns a parser which matches that string.

  • digit is a parser which takes one argument (an input string) and returns IResult.
  • tag takes one argument, a string to match, and returns a parser. That parser takes one argument (an input string) and returns IResult.

Nom's other primitive parsers fall into these categories: they're either actually parsers, or functions that return a parser. For example:

OK, so we can now build small parsers that recognize particular characters. But that's not going to be enough to parse the Advent of Code input file. We need a parser that can parse the text "(3,4)" into Point{x: 3, y: 4}. To do that, we need to combine these small parsers into a composite parser that can convert text into a Point.

Combining parsers with... combinators

So far we've seen two types of Nom functions:

  1. Parsers, e.g. digit1
  2. Functions that return a parser, e.g. tag

We're about to examine a third kind:

  1. Functions that take a parser as an argument, and return a new parser, e.g. pair.

The pair function takes two parsers as arguments (call them p1 and p2). It returns a new parser that chains them together. Each parser takes its input type I (usually string) and outputs (I, O) for the remaining input and the output value it parsed:

the input remaining after p1 becomes the input to p2, and their outputs get paired together

So basically it:

  1. Runs p1
  2. If p1 failed, return the error.
  3. Otherwise, the remaining input from p1 becomes the input for p2
  4. Run p2

As usual, the official docs have a good example:

use nom::sequence::pair;
use nom::bytes::complete::tag;

// `pair` gets an object from the first parser, then gets another object from the second parser.
let mut parser = pair(tag("abc"), tag("efg"));

assert_eq!(parser("abcefg"), Ok(("", ("abc", "efg"))));
assert_eq!(parser("abcefghij"), Ok(("hij", ("abc", "efg"))));
assert_eq!(parser(""), Err(Err::Error(("", ErrorKind::Tag))));
assert_eq!(parser("123"), Err(Err::Error(("123", ErrorKind::Tag))));

So, that's a very simple parser combinator which takes two parsers and outputs a new parser. Nom is full of these helpful little functions. For example, there's separated_pair which takes three parsers: it runs all three in sequence and discards the middle parser's output. It's useful for removing separators, e.g. parsing "1,2" into "1" and "2".

fn main() {
    use nom::{character::complete::{char, digit1}, sequence::separated_pair};

    let mut parser = separated_pair(digit1, char(','), digit1);
    assert_eq!(parser("1,2"), Ok(("", ("1", "2"))));
}

So far we've looked at combinators that take multiple parsers as arguments. But here's one that only takes a single parser: it's called map. It wraps a parser, then passes the output into a closure.

use nom::{
    character::complete::{alpha1, char},
    combinator::map,
    sequence::separated_pair,
    IResult,
};

/// Some example business logic type that our program uses
#[derive(PartialEq, Eq, Debug)]
struct Person {
    first_name: String,
    last_name: String,
}

impl Person {
    fn parse(input: &str) -> IResult<&str, Self> {
        // Parses two words, separated by a space.
        // Note: alpha1 recognizes one or more letters from A to Z.
        let two_words_parser = separated_pair(alpha1, char(' '), alpha1);

        // Defines a new parser which wraps the `two_words_parser`, then
        // passes the resulting pair into a closure.
        let mut person_parser = map(
            two_words_parser,
            |(first_name, last_name)| Self {
                first_name: String::from(first_name),
                last_name: String::from(last_name),
            },
        );

        // Use the parser
        person_parser(input)
    }
}

fn main() {
    let (remaining_input, actual) = Person::parse("Adam Chalmers_").unwrap();
    let expected = Person {
        first_name: "Adam".to_owned(),
        last_name: "Chalmers".to_owned(),
    };
    assert_eq!(remaining_input, "_");
    assert_eq!(expected, actual);
}

The map combinator expects a closure that always succeeds. But sometimes you want a closure that might fail. For example, you might have a parser that outputs a string, and then try to convert that string into a number. If the closure returns a Result, we can use map_res.

use nom::{character::complete::digit1, combinator::map_res, IResult};
use std::str::FromStr;

/// Parse a number from the string, but return it as an actual Rust number, not a string.
pub fn parse_numbers(input: &str) -> IResult<&str, u32> {
    let mut parser = map_res(digit1, u32::from_str);
    parser(input)
}

fn main() {
    let (actual_input_remaining, actual_output) = parse_numbers("123").unwrap();
    let expected_output = 123;
    let expected_input_remaining = "";
    assert_eq!(actual_output, expected_output);
    assert_eq!(actual_input_remaining, expected_input_remaining);
}

There are many other combinators in Nom's modules:

  • nom::sequence contains the pair and separated_pair combinators we've already seen. Others include tuple which takes any number of different parsers and runs them. pair is a special case of tuple where the tuple has length 2.
  • nom::multi has combinators that take a parser and run it many times, e.g. many0 wraps another parser and runs it 0 or more times, or separated_list1 which can parse "1,2,3" into vec![1,2,3].
  • nom::branch has combinators like alt for trying one of several different parsers (e.g. parsing either "3" or 0003 into the numeric value 3)
  • nom::combinator has general-purpose combinators e.g. map_opt (like map_res but the closure returns Option, not Result)

OK! That's the basics of Nom: parsers consume bytes from an input (often a string) and output a Rust value. There are primitive parsers that match simple patterns, like some alphanumeric characters or whitespace. Then there are combinators, which take one or more parsers and produce more complex ones. Those parsers can then become the input for yet more combinators to make even more complex parsers. If you keep applying this process, you can parse some pretty complicated formats, like HTTP or EXIF. Let's take a look at a real-world example I used Nom for: parsing Advent of Code, day 5.

Solving problems with Nom

Above we described the problem: read a text file and parse it into Line objects. The key to parsing with Nom is to start small. Find a small part of the input that you do know how to parse, and unit test it to make sure it works. Then build up more complex parsers from there.

Obviously, we'll need to know how to parse a single 2D point.

use nom::{
    character::complete::{char, digit1},
    combinator::{map, map_res},
    sequence::separated_pair,
    IResult,
};
use std::str::FromStr;

/// Parse a `u32` from the start of the input string.
/// (this is copied/pasted from earlier in the blog post!)
pub fn parse_numbers(input: &str) -> IResult<&str, u32> {
    map_res(digit1, u32::from_str)(input)
}

/// A point in 2D space
#[derive(Debug, Eq, PartialEq)]
pub struct Point {
    pub x: u32,
    pub y: u32,
}

impl Point {
    /// Parse a point.
    /// Like all Nom parsers, this has an Input type, Output type and Error type.
    /// Its Input type is &str (because we're parsing a text file that gets read into a string)
    /// Its Output type is Point (which we can refer to as Self inside an `impl Point` block)
    /// Its Error type will be the default Nom error type, so we don't have to 
    /// specify it here.
    fn parse(input: &str) -> IResult<&str, Self> {

        // This parser outputs a (u32, u32).
        // It uses the `parse_numbers` parser 
        // and the `separated_pair` combinator discussed earlier. 
        let parse_two_numbers = separated_pair(parse_numbers, char(','), parse_numbers);

        // Map the (u32, u32) into a Point.
        // Uses the `parse_two_numbers` parser defined on the previous line, 
        // and the `map` combinator discussed earlier.
        map(parse_two_numbers, |(x, y)| Point { x, y })(input)
    }
}

// Because each parser is just a pure, deterministic function, 
// it's very easy to unit test them!
#[cfg(test)]
mod tests {
    use super::*;

    #[test]
    fn test_parse_point() {
        let tests = [
            ("1,2", Point { x: 1, y: 2 }, ""),
            ("1,2asdf", Point { x: 1, y: 2 }, "asdf"),
        ];
        for (input, expected_output, expected_remaining_input) in tests {
            let (remaining_input, output) = Point::parse(input).unwrap();
            assert_eq!(output, expected_output);
            assert_eq!(remaining_input, expected_remaining_input);
        }
    }
}

OK, great. Now we can reuse that Point parser for a Line parser. The Advent of Code text file stores lines like this:

0,9 -> 5,9

/// A line spanning two points.
#[derive(Debug, Eq, PartialEq)]
pub struct Line(pub Point, pub Point);

impl Line {
    /// Parse a Line from the input string.
    fn parse(input: &str) -> IResult<&str, Self> {
        let parse_arrow = tag(" -> ");
        
        // Parse two points, separated by an arrow
        let parse_points = separated_pair(Point::parse, parse_arrow, Point::parse);

        // If the parse succeeded, put those two points into a Line
        map(parse_points, |(p0, p1)| Line(p0, p1))(input)
    }
}

#[cfg(test)]
mod tests {
    use super::*;

    #[test]
    fn test_parse_line() {
        let tests = [
            (
                "0,9 -> 5,9",
                Line(Point { x: 0, y: 9 }, Point { x: 5, y: 9 }),
                "",
            ),
            (
                "0,9 -> 5,9xyz",
                Line(Point { x: 0, y: 9 }, Point { x: 5, y: 9 }),
                "xyz",
            ),
        ];
        for (input, expected_output, expected_remaining_input) in tests {
            let (remaining_input, output) = Line::parse(input).unwrap();
            assert_eq!(remaining_input, expected_remaining_input);
            assert_eq!(output, expected_output);
        }
    }
}

Now it should be easy to parse the rest. We know each line in the text file should encode one Line object. We can use separated_list1 to match a line, then match and discard a newline, then match a line, then match and discard a newline, etc etc until the end of the file.

use nom::character::complete::line_ending;

/// Parse the whole Advent of Code day 5 text file.
pub fn parse_input(s: &str) -> Vec<Line> {
    let (remaining_input, lines) = separated_list1(line_ending, Line::parse)(s).unwrap();
    assert!(remaining_input.is_empty());
    lines
}


#[cfg(test)]
mod tests {
    use super::*;

    #[test]
    fn test_parse_file() {
        // Assuming you're logged in, you can download your Day 5 puzzle input from
        // https://adventofcode.com/2021/day/5/input
        // Then save it under src/data/input.txt
        // The `include_str!` macro reads a file into a String at compile-time.
        // I use it for all my AoC problems!
        let input = include_str!("data/input.txt");
        let lines = parse_input(input);
        assert_eq!(lines.len(), 500);
    }

Now we can parse the entire text file! You can see the full code on GitHub, feel free to open PRs if you've got any suggestions.

I find the "start small" approach really productive. Using many small parsers instead of one big parser makes it very easy to understand and test each little step. I can choose any parser here and tell exactly what it does just by looking at the type signature. If I want to know the exact kind of text it parses, I can check the unit tests. This makes it easy to understand the code even years after I last touched it. I should know, because a few years ago I wrote the fountain crate which parses the Fountain markdown language in Nom, and I still find the code pretty readable3.

Next steps

I hope this helped you understand Nom and parser combinators! If you want to learn more, I suggest taking a look at Nom's README.md -- it has a list of links to different docs, including the API docs, some design documents and even a "which combinator should I use" guide. Nom's creator Geoffroy Couprie has really gone above and beyond to make some good docs!

We'll dive further into Nom in future posts. For now, if you have any questions, leave a comment below or talk to me on twitter @adam_chal. And if you liked this article, and want to get paid to talk about Rust full time with me: email your resume to [email protected] after rot13. The last person who reached out like this got hired, so don't be shy! We're currently hiring remote workers based in the EU and USA (we have offices in a lot of cities).

Thank you to Joshua Nelson, Michael Sproul and Stephen Merity for reading the draft!


Footnotes

1

Nom is inspired by Parsec, the original parser combinator library from Haskell. I first learned about Parsec from its chapter in Real World Haskell and was impressed by how easily the concept could be ported into Rust.

2

There are two kinds of parsers, complete for when you can read the whole input into memory, and streaming for when you're getting the input bit by bit. For Advent of Code, the input files are always big enough to fit into memory. But if you were streaming, say, really huge datasets that couldn't fit into memory, you'd use streaming. Or if you were reading from a streaming protocol like an HTTP or gRPC body, you'd probably use streaming there too.

3

Note the type a lot of complicated boilerplate -- that's because I wanted the parsers to support either the default Nom error, or Nom's VerboseError. If you have a suggestion for improving it without breaking backwards compatibility, please let me know!