vendor/nom-7.1.3/tests/arithmetic.rs - toolchain/rustc - Git at Google

 use nom::{
   branch::alt,
   bytes::complete::tag,
   character::complete::char,
   character::complete::{digit1 as digit, space0 as space},
   combinator::map_res,
   multi::fold_many0,
   sequence::{delimited, pair},
   IResult,
 };

 // Parser definition

 use std::str::FromStr;

 // We parse any expr surrounded by parens, ignoring all whitespaces around those
 fn parens(i: &str) -> IResult<&str, i64> {
   delimited(space, delimited(tag("("), expr, tag(")")), space)(i)
 }

 // We transform an integer string into a i64, ignoring surrounding whitespaces
 // We look for a digit suite, and try to convert it.
 // If either str::from_utf8 or FromStr::from_str fail,
 // we fallback to the parens parser defined above
 fn factor(i: &str) -> IResult<&str, i64> {
   alt((
     map_res(delimited(space, digit, space), FromStr::from_str),
     parens,
   ))(i)
 }

 // We read an initial factor and for each time we find
 // a * or / operator followed by another factor, we do
 // the math by folding everything
 fn term(i: &str) -> IResult<&str, i64> {
   let (i, init) = factor(i)?;

   fold_many0(
     pair(alt((char('*'), char('/'))), factor),
     move || init,
     |acc, (op, val): (char, i64)| {
       if op == '*' {
         acc * val
       } else {
         acc / val
       }
     },
   )(i)
 }

 fn expr(i: &str) -> IResult<&str, i64> {
   let (i, init) = term(i)?;

   fold_many0(
     pair(alt((char('+'), char('-'))), term),
     move || init,
     |acc, (op, val): (char, i64)| {
       if op == '+' {
         acc + val
       } else {
         acc - val
       }
     },
   )(i)
 }

 #[test]
 fn factor_test() {
   assert_eq!(factor("3"), Ok(("", 3)));
   assert_eq!(factor(" 12"), Ok(("", 12)));
   assert_eq!(factor("537  "), Ok(("", 537)));
   assert_eq!(factor("  24   "), Ok(("", 24)));
 }

 #[test]
 fn term_test() {
   assert_eq!(term(" 12 *2 /  3"), Ok(("", 8)));
   assert_eq!(term(" 2* 3  *2 *2 /  3"), Ok(("", 8)));
   assert_eq!(term(" 48 /  3/2"), Ok(("", 8)));
 }

 #[test]
 fn expr_test() {
   assert_eq!(expr(" 1 +  2 "), Ok(("", 3)));
   assert_eq!(expr(" 12 + 6 - 4+  3"), Ok(("", 17)));
   assert_eq!(expr(" 1 + 2*3 + 4"), Ok(("", 11)));
 }

 #[test]
 fn parens_test() {
   assert_eq!(expr(" (  2 )"), Ok(("", 2)));
   assert_eq!(expr(" 2* (  3 + 4 ) "), Ok(("", 14)));
   assert_eq!(expr("  2*2 / ( 5 - 1) + 3"), Ok(("", 4)));
 }
	use nom::{
	branch::alt,
	bytes::complete::tag,
	character::complete::char,
	character::complete::{digit1 as digit, space0 as space},
	combinator::map_res,
	multi::fold_many0,
	sequence::{delimited, pair},
	IResult,
	};

	// Parser definition

	use std::str::FromStr;

	// We parse any expr surrounded by parens, ignoring all whitespaces around those
	fn parens(i: &str) -> IResult<&str, i64> {
	delimited(space, delimited(tag("("), expr, tag(")")), space)(i)
	}

	// We transform an integer string into a i64, ignoring surrounding whitespaces
	// We look for a digit suite, and try to convert it.
	// If either str::from_utf8 or FromStr::from_str fail,
	// we fallback to the parens parser defined above
	fn factor(i: &str) -> IResult<&str, i64> {
	alt((
	map_res(delimited(space, digit, space), FromStr::from_str),
	parens,
	))(i)
	}

	// We read an initial factor and for each time we find
	// a * or / operator followed by another factor, we do
	// the math by folding everything
	fn term(i: &str) -> IResult<&str, i64> {
	let (i, init) = factor(i)?;

	fold_many0(
	pair(alt((char('*'), char('/'))), factor),
	move \|\| init,
	\|acc, (op, val): (char, i64)\| {
	if op == '*' {
	acc * val
	} else {
	acc / val
	}
	},
	)(i)
	}

	fn expr(i: &str) -> IResult<&str, i64> {
	let (i, init) = term(i)?;

	fold_many0(
	pair(alt((char('+'), char('-'))), term),
	move \|\| init,
	\|acc, (op, val): (char, i64)\| {
	if op == '+' {
	acc + val
	} else {
	acc - val
	}
	},
	)(i)
	}

	#[test]
	fn factor_test() {
	assert_eq!(factor("3"), Ok(("", 3)));
	assert_eq!(factor(" 12"), Ok(("", 12)));
	assert_eq!(factor("537 "), Ok(("", 537)));
	assert_eq!(factor(" 24 "), Ok(("", 24)));
	}

	#[test]
	fn term_test() {
	assert_eq!(term(" 12 *2 / 3"), Ok(("", 8)));
	assert_eq!(term(" 2* 3 2 2 / 3"), Ok(("", 8)));
	assert_eq!(term(" 48 / 3/2"), Ok(("", 8)));
	}

	#[test]
	fn expr_test() {
	assert_eq!(expr(" 1 + 2 "), Ok(("", 3)));
	assert_eq!(expr(" 12 + 6 - 4+ 3"), Ok(("", 17)));
	assert_eq!(expr(" 1 + 2*3 + 4"), Ok(("", 11)));
	}

	#[test]
	fn parens_test() {
	assert_eq!(expr(" ( 2 )"), Ok(("", 2)));
	assert_eq!(expr(" 2* ( 3 + 4 ) "), Ok(("", 14)));
	assert_eq!(expr(" 2*2 / ( 5 - 1) + 3"), Ok(("", 4)));
	}