use rustc_ast::ast::{Lit, LitFloatType, LitIntType, LitKind}; #[derive(Debug, PartialEq)] pub enum Radix { Binary, Octal, Decimal, Hexadecimal, } impl Radix { /// Returns a reasonable digit group size for this radix. #[must_use] fn suggest_grouping(&self) -> usize { match *self { Self::Binary | Self::Hexadecimal => 4, Self::Octal | Self::Decimal => 3, } } } /// A helper method to format numeric literals with digit grouping. /// `lit` must be a valid numeric literal without suffix. pub fn format(lit: &str, type_suffix: Option<&str>, float: bool) -> String { NumericLiteral::new(lit, type_suffix, float).format() } #[derive(Debug)] pub struct NumericLiteral<'a> { /// Which radix the literal was represented in. pub radix: Radix, /// The radix prefix, if present. pub prefix: Option<&'a str>, /// The integer part of the number. pub integer: &'a str, /// The fraction part of the number. pub fraction: Option<&'a str>, /// The character used as exponent seperator (b'e' or b'E') and the exponent part. pub exponent: Option<(char, &'a str)>, /// The type suffix, including preceding underscore if present. pub suffix: Option<&'a str>, } impl<'a> NumericLiteral<'a> { pub fn from_lit(src: &'a str, lit: &Lit) -> Option> { NumericLiteral::from_lit_kind(src, &lit.kind) } pub fn from_lit_kind(src: &'a str, lit_kind: &LitKind) -> Option> { if lit_kind.is_numeric() && src.chars().next().map_or(false, |c| c.is_digit(10)) { let (unsuffixed, suffix) = split_suffix(&src, lit_kind); let float = if let LitKind::Float(..) = lit_kind { true } else { false }; Some(NumericLiteral::new(unsuffixed, suffix, float)) } else { None } } #[must_use] pub fn new(lit: &'a str, suffix: Option<&'a str>, float: bool) -> Self { // Determine delimiter for radix prefix, if present, and radix. let radix = if lit.starts_with("0x") { Radix::Hexadecimal } else if lit.starts_with("0b") { Radix::Binary } else if lit.starts_with("0o") { Radix::Octal } else { Radix::Decimal }; // Grab part of the literal after prefix, if present. let (prefix, mut sans_prefix) = if let Radix::Decimal = radix { (None, lit) } else { let (p, s) = lit.split_at(2); (Some(p), s) }; if suffix.is_some() && sans_prefix.ends_with('_') { // The '_' before the suffix isn't part of the digits sans_prefix = &sans_prefix[..sans_prefix.len() - 1]; } let (integer, fraction, exponent) = Self::split_digit_parts(sans_prefix, float); Self { radix, prefix, integer, fraction, exponent, suffix, } } pub fn is_decimal(&self) -> bool { self.radix == Radix::Decimal } pub fn split_digit_parts(digits: &str, float: bool) -> (&str, Option<&str>, Option<(char, &str)>) { let mut integer = digits; let mut fraction = None; let mut exponent = None; if float { for (i, c) in digits.char_indices() { match c { '.' => { integer = &digits[..i]; fraction = Some(&digits[i + 1..]); }, 'e' | 'E' => { if integer.len() > i { integer = &digits[..i]; } else { fraction = Some(&digits[integer.len() + 1..i]); }; exponent = Some((c, &digits[i + 1..])); break; }, _ => {}, } } } (integer, fraction, exponent) } /// Returns literal formatted in a sensible way. pub fn format(&self) -> String { let mut output = String::new(); if let Some(prefix) = self.prefix { output.push_str(prefix); } let group_size = self.radix.suggest_grouping(); Self::group_digits( &mut output, self.integer, group_size, true, self.radix == Radix::Hexadecimal, ); if let Some(fraction) = self.fraction { output.push('.'); Self::group_digits(&mut output, fraction, group_size, false, false); } if let Some((separator, exponent)) = self.exponent { output.push(separator); Self::group_digits(&mut output, exponent, group_size, true, false); } if let Some(suffix) = self.suffix { output.push('_'); output.push_str(suffix); } output } pub fn group_digits(output: &mut String, input: &str, group_size: usize, partial_group_first: bool, pad: bool) { debug_assert!(group_size > 0); let mut digits = input.chars().filter(|&c| c != '_'); let first_group_size; if partial_group_first { first_group_size = (digits.clone().count() - 1) % group_size + 1; if pad { for _ in 0..group_size - first_group_size { output.push('0'); } } } else { first_group_size = group_size; } for _ in 0..first_group_size { if let Some(digit) = digits.next() { output.push(digit); } } for (c, i) in digits.zip((0..group_size).cycle()) { if i == 0 { output.push('_'); } output.push(c); } } } fn split_suffix<'a>(src: &'a str, lit_kind: &LitKind) -> (&'a str, Option<&'a str>) { debug_assert!(lit_kind.is_numeric()); if let Some(suffix_length) = lit_suffix_length(lit_kind) { let (unsuffixed, suffix) = src.split_at(src.len() - suffix_length); (unsuffixed, Some(suffix)) } else { (src, None) } } fn lit_suffix_length(lit_kind: &LitKind) -> Option { debug_assert!(lit_kind.is_numeric()); let suffix = match lit_kind { LitKind::Int(_, int_lit_kind) => match int_lit_kind { LitIntType::Signed(int_ty) => Some(int_ty.name_str()), LitIntType::Unsigned(uint_ty) => Some(uint_ty.name_str()), LitIntType::Unsuffixed => None, }, LitKind::Float(_, float_lit_kind) => match float_lit_kind { LitFloatType::Suffixed(float_ty) => Some(float_ty.name_str()), LitFloatType::Unsuffixed => None, }, _ => None, }; suffix.map(str::len) }