compiler/rustc_builtin_macros/src/format_foreign.rs - third_party/rust - Git at Google

 pub mod printf {
     use super::strcursor::StrCursor as Cur;
     use rustc_span::InnerSpan;

     /// Represents a single `printf`-style substitution.
     #[derive(Clone, PartialEq, Debug)]
     pub enum Substitution<'a> {
         /// A formatted output substitution with its internal byte offset.
         Format(Format<'a>),
         /// A literal `%%` escape.
         Escape,
     }

     impl<'a> Substitution<'a> {
         pub fn as_str(&self) -> &str {
             match *self {
                 Substitution::Format(ref fmt) => fmt.span,
                 Substitution::Escape => "%%",
             }
         }

         pub fn position(&self) -> Option<InnerSpan> {
             match *self {
                 Substitution::Format(ref fmt) => Some(fmt.position),
                 _ => None,
             }
         }

         pub fn set_position(&mut self, start: usize, end: usize) {
             if let Substitution::Format(ref mut fmt) = self {
                 fmt.position = InnerSpan::new(start, end);
             }
         }

         /// Translate this substitution into an equivalent Rust formatting directive.
         ///
         /// This ignores cases where the substitution does not have an exact equivalent, or where
         /// the substitution would be unnecessary.
         pub fn translate(&self) -> Option<String> {
             match *self {
                 Substitution::Format(ref fmt) => fmt.translate(),
                 Substitution::Escape => None,
             }
         }
     }

     #[derive(Clone, PartialEq, Debug)]
     /// A single `printf`-style formatting directive.
     pub struct Format<'a> {
         /// The entire original formatting directive.
         pub span: &'a str,
         /// The (1-based) parameter to be converted.
         pub parameter: Option<u16>,
         /// Formatting flags.
         pub flags: &'a str,
         /// Minimum width of the output.
         pub width: Option<Num>,
         /// Precision of the conversion.
         pub precision: Option<Num>,
         /// Length modifier for the conversion.
         pub length: Option<&'a str>,
         /// Type of parameter being converted.
         pub type_: &'a str,
         /// Byte offset for the start and end of this formatting directive.
         pub position: InnerSpan,
     }

     impl Format<'_> {
         /// Translate this directive into an equivalent Rust formatting directive.
         ///
         /// Returns `None` in cases where the `printf` directive does not have an exact Rust
         /// equivalent, rather than guessing.
         pub fn translate(&self) -> Option<String> {
             use std::fmt::Write;

             let (c_alt, c_zero, c_left, c_plus) = {
                 let mut c_alt = false;
                 let mut c_zero = false;
                 let mut c_left = false;
                 let mut c_plus = false;
                 for c in self.flags.chars() {
                     match c {
                         '#' => c_alt = true,
                         '0' => c_zero = true,
                         '-' => c_left = true,
                         '+' => c_plus = true,
                         _ => return None,
                     }
                 }
                 (c_alt, c_zero, c_left, c_plus)
             };

             // Has a special form in Rust for numbers.
             let fill = c_zero.then_some("0");

             let align = c_left.then_some("<");

             // Rust doesn't have an equivalent to the `' '` flag.
             let sign = c_plus.then_some("+");

             // Not *quite* the same, depending on the type...
             let alt = c_alt;

             let width = match self.width {
                 Some(Num::Next) => {
                     // NOTE: Rust doesn't support this.
                     return None;
                 }
                 w @ Some(Num::Arg(_)) => w,
                 w @ Some(Num::Num(_)) => w,
                 None => None,
             };

             let precision = self.precision;

             // NOTE: although length *can* have an effect, we can't duplicate the effect in Rust, so
             // we just ignore it.

             let (type_, use_zero_fill, is_int) = match self.type_ {
                 "d" | "i" | "u" => (None, true, true),
                 "f" | "F" => (None, false, false),
                 "s" | "c" => (None, false, false),
                 "e" | "E" => (Some(self.type_), true, false),
                 "x" | "X" | "o" => (Some(self.type_), true, true),
                 "p" => (Some(self.type_), false, true),
                 "g" => (Some("e"), true, false),
                 "G" => (Some("E"), true, false),
                 _ => return None,
             };

             let (fill, width, precision) = match (is_int, width, precision) {
                 (true, Some(_), Some(_)) => {
                     // Rust can't duplicate this insanity.
                     return None;
                 }
                 (true, None, Some(p)) => (Some("0"), Some(p), None),
                 (true, w, None) => (fill, w, None),
                 (false, w, p) => (fill, w, p),
             };

             let align = match (self.type_, width.is_some(), align.is_some()) {
                 ("s", true, false) => Some(">"),
                 _ => align,
             };

             let (fill, zero_fill) = match (fill, use_zero_fill) {
                 (Some("0"), true) => (None, true),
                 (fill, _) => (fill, false),
             };

             let alt = match type_ {
                 Some("x" | "X") => alt,
                 _ => false,
             };

             let has_options = fill.is_some()
                 || align.is_some()
                 || sign.is_some()
                 || alt
                 || zero_fill
                 || width.is_some()
                 || precision.is_some()
                 || type_.is_some();

             // Initialise with a rough guess.
             let cap = self.span.len() + if has_options { 2 } else { 0 };
             let mut s = String::with_capacity(cap);

             s.push('{');

             if let Some(arg) = self.parameter {
                 write!(s, "{}", arg.checked_sub(1)?).ok()?;
             }

             if has_options {
                 s.push(':');

                 let align = if let Some(fill) = fill {
                     s.push_str(fill);
                     align.or(Some(">"))
                 } else {
                     align
                 };

                 if let Some(align) = align {
                     s.push_str(align);
                 }

                 if let Some(sign) = sign {
                     s.push_str(sign);
                 }

                 if alt {
                     s.push('#');
                 }

                 if zero_fill {
                     s.push('0');
                 }

                 if let Some(width) = width {
                     width.translate(&mut s).ok()?;
                 }

                 if let Some(precision) = precision {
                     s.push('.');
                     precision.translate(&mut s).ok()?;
                 }

                 if let Some(type_) = type_ {
                     s.push_str(type_);
                 }
             }

             s.push('}');
             Some(s)
         }
     }

     /// A general number used in a `printf` formatting directive.
     #[derive(Copy, Clone, PartialEq, Debug)]
     pub enum Num {
         // The range of these values is technically bounded by `NL_ARGMAX`... but, at least for GNU
         // libc, it apparently has no real fixed limit.  A `u16` is used here on the basis that it
         // is *vanishingly* unlikely that *anyone* is going to try formatting something wider, or
         // with more precision, than 32 thousand positions which is so wide it couldn't possibly fit
         // on a screen.
         /// A specific, fixed value.
         Num(u16),
         /// The value is derived from a positional argument.
         Arg(u16),
         /// The value is derived from the "next" unconverted argument.
         Next,
     }

     impl Num {
         fn from_str(s: &str, arg: Option<&str>) -> Self {
             if let Some(arg) = arg {
                 Num::Arg(arg.parse().unwrap_or_else(|_| panic!("invalid format arg `{:?}`", arg)))
             } else if s == "*" {
                 Num::Next
             } else {
                 Num::Num(s.parse().unwrap_or_else(|_| panic!("invalid format num `{:?}`", s)))
             }
         }

         fn translate(&self, s: &mut String) -> std::fmt::Result {
             use std::fmt::Write;
             match *self {
                 Num::Num(n) => write!(s, "{}", n),
                 Num::Arg(n) => {
                     let n = n.checked_sub(1).ok_or(std::fmt::Error)?;
                     write!(s, "{}$", n)
                 }
                 Num::Next => write!(s, "*"),
             }
         }
     }

     /// Returns an iterator over all substitutions in a given string.
     pub fn iter_subs(s: &str, start_pos: usize) -> Substitutions<'_> {
         Substitutions { s, pos: start_pos }
     }

     /// Iterator over substitutions in a string.
     pub struct Substitutions<'a> {
         s: &'a str,
         pos: usize,
     }

     impl<'a> Iterator for Substitutions<'a> {
         type Item = Substitution<'a>;
         fn next(&mut self) -> Option<Self::Item> {
             let (mut sub, tail) = parse_next_substitution(self.s)?;
             self.s = tail;
             match sub {
                 Substitution::Format(_) => {
                     if let Some(inner_span) = sub.position() {
                         sub.set_position(inner_span.start + self.pos, inner_span.end + self.pos);
                         self.pos += inner_span.end;
                     }
                 }
                 Substitution::Escape => self.pos += 2,
             }
             Some(sub)
         }

         fn size_hint(&self) -> (usize, Option<usize>) {
             // Substitutions are at least 2 characters long.
             (0, Some(self.s.len() / 2))
         }
     }

     enum State {
         Start,
         Flags,
         Width,
         WidthArg,
         Prec,
         PrecInner,
         Length,
         Type,
     }

     /// Parse the next substitution from the input string.
     pub fn parse_next_substitution(s: &str) -> Option<(Substitution<'_>, &str)> {
         use self::State::*;

         let at = {
             let start = s.find('%')?;
             if let '%' = s[start + 1..].chars().next()? {
                 return Some((Substitution::Escape, &s[start + 2..]));
             }

             Cur::new_at(&s[..], start)
         };

         // This is meant to be a translation of the following regex:
         //
         // ```regex
         // (?x)
         // ^ %
         // (?: (?P<parameter> \d+) \$ )?
         // (?P<flags> [-+ 0\#']* )
         // (?P<width> \d+ | \* (?: (?P<widtha> \d+) \$ )? )?
         // (?: \. (?P<precision> \d+ | \* (?: (?P<precisiona> \d+) \$ )? ) )?
         // (?P<length>
         //     # Standard
         //     hh | h | ll | l | L | z | j | t
         //
         //     # Other
         //     | I32 | I64 | I | q
         // )?
         // (?P<type> . )
         // ```

         // Used to establish the full span at the end.
         let start = at;
         // The current position within the string.
         let mut at = at.at_next_cp()?;
         // `c` is the next codepoint, `next` is a cursor after it.
         let (mut c, mut next) = at.next_cp()?;

         // Update `at`, `c`, and `next`, exiting if we're out of input.
         macro_rules! move_to {
             ($cur:expr) => {{
                 at = $cur;
                 let (c_, next_) = at.next_cp()?;
                 c = c_;
                 next = next_;
             }};
         }

         // Constructs a result when parsing fails.
         //
         // Note: `move` used to capture copies of the cursors as they are *now*.
         let fallback = move || {
             Some((
                 Substitution::Format(Format {
                     span: start.slice_between(next).unwrap(),
                     parameter: None,
                     flags: "",
                     width: None,
                     precision: None,
                     length: None,
                     type_: at.slice_between(next).unwrap(),
                     position: InnerSpan::new(start.at, next.at),
                 }),
                 next.slice_after(),
             ))
         };

         // Next parsing state.
         let mut state = Start;

         // Sadly, Rust isn't *quite* smart enough to know these *must* be initialised by the end.
         let mut parameter: Option<u16> = None;
         let mut flags: &str = "";
         let mut width: Option<Num> = None;
         let mut precision: Option<Num> = None;
         let mut length: Option<&str> = None;
         let mut type_: &str = "";
         let end: Cur<'_>;

         if let Start = state {
             match c {
                 '1'..='9' => {
                     let end = at_next_cp_while(next, is_digit);
                     match end.next_cp() {
                         // Yes, this *is* the parameter.
                         Some(('$', end2)) => {
                             state = Flags;
                             parameter = Some(at.slice_between(end).unwrap().parse().unwrap());
                             move_to!(end2);
                         }
                         // Wait, no, actually, it's the width.
                         Some(_) => {
                             state = Prec;
                             parameter = None;
                             flags = "";
                             width = Some(Num::from_str(at.slice_between(end).unwrap(), None));
                             move_to!(end);
                         }
                         // It's invalid, is what it is.
                         None => return fallback(),
                     }
                 }
                 _ => {
                     state = Flags;
                     parameter = None;
                     move_to!(at);
                 }
             }
         }

         if let Flags = state {
             let end = at_next_cp_while(at, is_flag);
             state = Width;
             flags = at.slice_between(end).unwrap();
             move_to!(end);
         }

         if let Width = state {
             match c {
                 '*' => {
                     state = WidthArg;
                     move_to!(next);
                 }
                 '1'..='9' => {
                     let end = at_next_cp_while(next, is_digit);
                     state = Prec;
                     width = Some(Num::from_str(at.slice_between(end).unwrap(), None));
                     move_to!(end);
                 }
                 _ => {
                     state = Prec;
                     width = None;
                     move_to!(at);
                 }
             }
         }

         if let WidthArg = state {
             let end = at_next_cp_while(at, is_digit);
             match end.next_cp() {
                 Some(('$', end2)) => {
                     state = Prec;
                     width = Some(Num::from_str("", Some(at.slice_between(end).unwrap())));
                     move_to!(end2);
                 }
                 _ => {
                     state = Prec;
                     width = Some(Num::Next);
                     move_to!(end);
                 }
             }
         }

         if let Prec = state {
             match c {
                 '.' => {
                     state = PrecInner;
                     move_to!(next);
                 }
                 _ => {
                     state = Length;
                     precision = None;
                     move_to!(at);
                 }
             }
         }

         if let PrecInner = state {
             match c {
                 '*' => {
                     let end = at_next_cp_while(next, is_digit);
                     match end.next_cp() {
                         Some(('$', end2)) => {
                             state = Length;
                             precision = Some(Num::from_str("*", next.slice_between(end)));
                             move_to!(end2);
                         }
                         _ => {
                             state = Length;
                             precision = Some(Num::Next);
                             move_to!(end);
                         }
                     }
                 }
                 '0'..='9' => {
                     let end = at_next_cp_while(next, is_digit);
                     state = Length;
                     precision = Some(Num::from_str(at.slice_between(end).unwrap(), None));
                     move_to!(end);
                 }
                 _ => return fallback(),
             }
         }

         if let Length = state {
             let c1_next1 = next.next_cp();
             match (c, c1_next1) {
                 ('h', Some(('h', next1))) | ('l', Some(('l', next1))) => {
                     state = Type;
                     length = Some(at.slice_between(next1).unwrap());
                     move_to!(next1);
                 }

                 ('h' | 'l' | 'L' | 'z' | 'j' | 't' | 'q', _) => {
                     state = Type;
                     length = Some(at.slice_between(next).unwrap());
                     move_to!(next);
                 }

                 ('I', _) => {
                     let end = next
                         .at_next_cp()
                         .and_then(|end| end.at_next_cp())
                         .map(|end| (next.slice_between(end).unwrap(), end));
                     let end = match end {
                         Some(("32" | "64", end)) => end,
                         _ => next,
                     };
                     state = Type;
                     length = Some(at.slice_between(end).unwrap());
                     move_to!(end);
                 }

                 _ => {
                     state = Type;
                     length = None;
                     move_to!(at);
                 }
             }
         }

         if let Type = state {
             drop(c);
             type_ = at.slice_between(next).unwrap();

             // Don't use `move_to!` here, as we *can* be at the end of the input.
             at = next;
         }

         drop(c);
         drop(next);

         end = at;
         let position = InnerSpan::new(start.at, end.at);

         let f = Format {
             span: start.slice_between(end).unwrap(),
             parameter,
             flags,
             width,
             precision,
             length,
             type_,
             position,
         };
         Some((Substitution::Format(f), end.slice_after()))
     }

     fn at_next_cp_while<F>(mut cur: Cur<'_>, mut pred: F) -> Cur<'_>
     where
         F: FnMut(char) -> bool,
     {
         loop {
             match cur.next_cp() {
                 Some((c, next)) => {
                     if pred(c) {
                         cur = next;
                     } else {
                         return cur;
                     }
                 }
                 None => return cur,
             }
         }
     }

     fn is_digit(c: char) -> bool {
         match c {
             '0'..='9' => true,
             _ => false,
         }
     }

     fn is_flag(c: char) -> bool {
         match c {
             '0' | '-' | '+' | ' ' | '#' | '\'' => true,
             _ => false,
         }
     }

     #[cfg(test)]
     mod tests;
 }

 pub mod shell {
     use super::strcursor::StrCursor as Cur;
     use rustc_span::InnerSpan;

     #[derive(Clone, PartialEq, Debug)]
     pub enum Substitution<'a> {
         Ordinal(u8, (usize, usize)),
         Name(&'a str, (usize, usize)),
         Escape((usize, usize)),
     }

     impl Substitution<'_> {
         pub fn as_str(&self) -> String {
             match self {
                 Substitution::Ordinal(n, _) => format!("${}", n),
                 Substitution::Name(n, _) => format!("${}", n),
                 Substitution::Escape(_) => "$$".into(),
             }
         }

         pub fn position(&self) -> Option<InnerSpan> {
             match self {
                 Substitution::Ordinal(_, pos)
                 | Substitution::Name(_, pos)
                 | Substitution::Escape(pos) => Some(InnerSpan::new(pos.0, pos.1)),
             }
         }

         pub fn set_position(&mut self, start: usize, end: usize) {
             match self {
                 Substitution::Ordinal(_, ref mut pos)
                 | Substitution::Name(_, ref mut pos)
                 | Substitution::Escape(ref mut pos) => *pos = (start, end),
             }
         }

         pub fn translate(&self) -> Option<String> {
             match *self {
                 Substitution::Ordinal(n, _) => Some(format!("{{{}}}", n)),
                 Substitution::Name(n, _) => Some(format!("{{{}}}", n)),
                 Substitution::Escape(_) => None,
             }
         }
     }

     /// Returns an iterator over all substitutions in a given string.
     pub fn iter_subs(s: &str, start_pos: usize) -> Substitutions<'_> {
         Substitutions { s, pos: start_pos }
     }

     /// Iterator over substitutions in a string.
     pub struct Substitutions<'a> {
         s: &'a str,
         pos: usize,
     }

     impl<'a> Iterator for Substitutions<'a> {
         type Item = Substitution<'a>;
         fn next(&mut self) -> Option<Self::Item> {
             match parse_next_substitution(self.s) {
                 Some((mut sub, tail)) => {
                     self.s = tail;
                     if let Some(InnerSpan { start, end }) = sub.position() {
                         sub.set_position(start + self.pos, end + self.pos);
                         self.pos += end;
                     }
                     Some(sub)
                 }
                 None => None,
             }
         }

         fn size_hint(&self) -> (usize, Option<usize>) {
             (0, Some(self.s.len()))
         }
     }

     /// Parse the next substitution from the input string.
     pub fn parse_next_substitution(s: &str) -> Option<(Substitution<'_>, &str)> {
         let at = {
             let start = s.find('$')?;
             match s[start + 1..].chars().next()? {
                 '$' => return Some((Substitution::Escape((start, start + 2)), &s[start + 2..])),
                 c @ '0'..='9' => {
                     let n = (c as u8) - b'0';
                     return Some((Substitution::Ordinal(n, (start, start + 2)), &s[start + 2..]));
                 }
                 _ => { /* fall-through */ }
             }

             Cur::new_at(&s[..], start)
         };

         let at = at.at_next_cp()?;
         let (c, inner) = at.next_cp()?;

         if !is_ident_head(c) {
             None
         } else {
             let end = at_next_cp_while(inner, is_ident_tail);
             let slice = at.slice_between(end).unwrap();
             let start = at.at - 1;
             let end_pos = at.at + slice.len();
             Some((Substitution::Name(slice, (start, end_pos)), end.slice_after()))
         }
     }

     fn at_next_cp_while<F>(mut cur: Cur<'_>, mut pred: F) -> Cur<'_>
     where
         F: FnMut(char) -> bool,
     {
         loop {
             match cur.next_cp() {
                 Some((c, next)) => {
                     if pred(c) {
                         cur = next;
                     } else {
                         return cur;
                     }
                 }
                 None => return cur,
             }
         }
     }

     fn is_ident_head(c: char) -> bool {
         match c {
             'a'..='z' | 'A'..='Z' | '_' => true,
             _ => false,
         }
     }

     fn is_ident_tail(c: char) -> bool {
         match c {
             '0'..='9' => true,
             c => is_ident_head(c),
         }
     }

     #[cfg(test)]
     mod tests;
 }

 mod strcursor {
     pub struct StrCursor<'a> {
         s: &'a str,
         pub at: usize,
     }

     impl<'a> StrCursor<'a> {
         pub fn new_at(s: &'a str, at: usize) -> StrCursor<'a> {
             StrCursor { s, at }
         }

         pub fn at_next_cp(mut self) -> Option<StrCursor<'a>> {
             match self.try_seek_right_cp() {
                 true => Some(self),
                 false => None,
             }
         }

         pub fn next_cp(mut self) -> Option<(char, StrCursor<'a>)> {
             let cp = self.cp_after()?;
             self.seek_right(cp.len_utf8());
             Some((cp, self))
         }

         fn slice_before(&self) -> &'a str {
             &self.s[0..self.at]
         }

         pub fn slice_after(&self) -> &'a str {
             &self.s[self.at..]
         }

         pub fn slice_between(&self, until: StrCursor<'a>) -> Option<&'a str> {
             if !str_eq_literal(self.s, until.s) {
                 None
             } else {
                 use std::cmp::{max, min};
                 let beg = min(self.at, until.at);
                 let end = max(self.at, until.at);
                 Some(&self.s[beg..end])
             }
         }

         fn cp_after(&self) -> Option<char> {
             self.slice_after().chars().next()
         }

         fn try_seek_right_cp(&mut self) -> bool {
             match self.slice_after().chars().next() {
                 Some(c) => {
                     self.at += c.len_utf8();
                     true
                 }
                 None => false,
             }
         }

         fn seek_right(&mut self, bytes: usize) {
             self.at += bytes;
         }
     }

     impl Copy for StrCursor<'_> {}

     impl<'a> Clone for StrCursor<'a> {
         fn clone(&self) -> StrCursor<'a> {
             *self
         }
     }

     impl std::fmt::Debug for StrCursor<'_> {
         fn fmt(&self, fmt: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
             write!(fmt, "StrCursor({:?} | {:?})", self.slice_before(), self.slice_after())
         }
     }

     fn str_eq_literal(a: &str, b: &str) -> bool {
         a.as_bytes().as_ptr() == b.as_bytes().as_ptr() && a.len() == b.len()
     }
 }
	pub mod printf {
	use super::strcursor::StrCursor as Cur;
	use rustc_span::InnerSpan;

	/// Represents a single `printf`-style substitution.
	#[derive(Clone, PartialEq, Debug)]
	pub enum Substitution<'a> {
	/// A formatted output substitution with its internal byte offset.
	Format(Format<'a>),
	/// A literal `%%` escape.
	Escape,
	}

	impl<'a> Substitution<'a> {
	pub fn as_str(&self) -> &str {
	match *self {
	Substitution::Format(ref fmt) => fmt.span,
	Substitution::Escape => "%%",
	}
	}

	pub fn position(&self) -> Option<InnerSpan> {
	match *self {
	Substitution::Format(ref fmt) => Some(fmt.position),
	_ => None,
	}
	}

	pub fn set_position(&mut self, start: usize, end: usize) {
	if let Substitution::Format(ref mut fmt) = self {
	fmt.position = InnerSpan::new(start, end);
	}
	}

	/// Translate this substitution into an equivalent Rust formatting directive.
	///
	/// This ignores cases where the substitution does not have an exact equivalent, or where
	/// the substitution would be unnecessary.
	pub fn translate(&self) -> Option<String> {
	match *self {
	Substitution::Format(ref fmt) => fmt.translate(),
	Substitution::Escape => None,
	}
	}
	}

	#[derive(Clone, PartialEq, Debug)]
	/// A single `printf`-style formatting directive.
	pub struct Format<'a> {
	/// The entire original formatting directive.
	pub span: &'a str,
	/// The (1-based) parameter to be converted.
	pub parameter: Option<u16>,
	/// Formatting flags.
	pub flags: &'a str,
	/// Minimum width of the output.
	pub width: Option<Num>,
	/// Precision of the conversion.
	pub precision: Option<Num>,
	/// Length modifier for the conversion.
	pub length: Option<&'a str>,
	/// Type of parameter being converted.
	pub type_: &'a str,
	/// Byte offset for the start and end of this formatting directive.
	pub position: InnerSpan,
	}

	impl Format<'_> {
	/// Translate this directive into an equivalent Rust formatting directive.
	///
	/// Returns `None` in cases where the `printf` directive does not have an exact Rust
	/// equivalent, rather than guessing.
	pub fn translate(&self) -> Option<String> {
	use std::fmt::Write;

	let (c_alt, c_zero, c_left, c_plus) = {
	let mut c_alt = false;
	let mut c_zero = false;
	let mut c_left = false;
	let mut c_plus = false;
	for c in self.flags.chars() {
	match c {
	'#' => c_alt = true,
	'0' => c_zero = true,
	'-' => c_left = true,
	'+' => c_plus = true,
	_ => return None,
	}
	}
	(c_alt, c_zero, c_left, c_plus)
	};

	// Has a special form in Rust for numbers.
	let fill = c_zero.then_some("0");

	let align = c_left.then_some("<");

	// Rust doesn't have an equivalent to the `' '` flag.
	let sign = c_plus.then_some("+");

	// Not quite the same, depending on the type...
	let alt = c_alt;

	let width = match self.width {
	Some(Num::Next) => {
	// NOTE: Rust doesn't support this.
	return None;
	}
	w @ Some(Num::Arg(_)) => w,
	w @ Some(Num::Num(_)) => w,
	None => None,
	};

	let precision = self.precision;

	// NOTE: although length can have an effect, we can't duplicate the effect in Rust, so
	// we just ignore it.

	let (type_, use_zero_fill, is_int) = match self.type_ {
	"d" \| "i" \| "u" => (None, true, true),
	"f" \| "F" => (None, false, false),
	"s" \| "c" => (None, false, false),
	"e" \| "E" => (Some(self.type_), true, false),
	"x" \| "X" \| "o" => (Some(self.type_), true, true),
	"p" => (Some(self.type_), false, true),
	"g" => (Some("e"), true, false),
	"G" => (Some("E"), true, false),
	_ => return None,
	};

	let (fill, width, precision) = match (is_int, width, precision) {
	(true, Some(_), Some(_)) => {
	// Rust can't duplicate this insanity.
	return None;
	}
	(true, None, Some(p)) => (Some("0"), Some(p), None),
	(true, w, None) => (fill, w, None),
	(false, w, p) => (fill, w, p),
	};

	let align = match (self.type_, width.is_some(), align.is_some()) {
	("s", true, false) => Some(">"),
	_ => align,
	};

	let (fill, zero_fill) = match (fill, use_zero_fill) {
	(Some("0"), true) => (None, true),
	(fill, _) => (fill, false),
	};

	let alt = match type_ {
	Some("x" \| "X") => alt,
	_ => false,
	};

	let has_options = fill.is_some()
	\|\| align.is_some()
	\|\| sign.is_some()
	\|\| alt
	\|\| zero_fill
	\|\| width.is_some()
	\|\| precision.is_some()
	\|\| type_.is_some();

	// Initialise with a rough guess.
	let cap = self.span.len() + if has_options { 2 } else { 0 };
	let mut s = String::with_capacity(cap);

	s.push('{');

	if let Some(arg) = self.parameter {
	write!(s, "{}", arg.checked_sub(1)?).ok()?;
	}

	if has_options {
	s.push(':');

	let align = if let Some(fill) = fill {
	s.push_str(fill);
	align.or(Some(">"))
	} else {
	align
	};

	if let Some(align) = align {
	s.push_str(align);
	}

	if let Some(sign) = sign {
	s.push_str(sign);
	}

	if alt {
	s.push('#');
	}

	if zero_fill {
	s.push('0');
	}

	if let Some(width) = width {
	width.translate(&mut s).ok()?;
	}

	if let Some(precision) = precision {
	s.push('.');
	precision.translate(&mut s).ok()?;
	}

	if let Some(type_) = type_ {
	s.push_str(type_);
	}
	}

	s.push('}');
	Some(s)
	}
	}

	/// A general number used in a `printf` formatting directive.
	#[derive(Copy, Clone, PartialEq, Debug)]
	pub enum Num {
	// The range of these values is technically bounded by `NL_ARGMAX`... but, at least for GNU
	// libc, it apparently has no real fixed limit. A `u16` is used here on the basis that it
	// is vanishingly unlikely that anyone is going to try formatting something wider, or
	// with more precision, than 32 thousand positions which is so wide it couldn't possibly fit
	// on a screen.
	/// A specific, fixed value.
	Num(u16),
	/// The value is derived from a positional argument.
	Arg(u16),
	/// The value is derived from the "next" unconverted argument.
	Next,
	}

	impl Num {
	fn from_str(s: &str, arg: Option<&str>) -> Self {
	if let Some(arg) = arg {
	Num::Arg(arg.parse().unwrap_or_else(\|_\| panic!("invalid format arg `{:?}`", arg)))
	} else if s == "*" {
	Num::Next
	} else {
	Num::Num(s.parse().unwrap_or_else(\|_\| panic!("invalid format num `{:?}`", s)))
	}
	}

	fn translate(&self, s: &mut String) -> std::fmt::Result {
	use std::fmt::Write;
	match *self {
	Num::Num(n) => write!(s, "{}", n),
	Num::Arg(n) => {
	let n = n.checked_sub(1).ok_or(std::fmt::Error)?;
	write!(s, "{}$", n)
	}
	Num::Next => write!(s, "*"),
	}
	}
	}

	/// Returns an iterator over all substitutions in a given string.
	pub fn iter_subs(s: &str, start_pos: usize) -> Substitutions<'_> {
	Substitutions { s, pos: start_pos }
	}

	/// Iterator over substitutions in a string.
	pub struct Substitutions<'a> {
	s: &'a str,
	pos: usize,
	}

	impl<'a> Iterator for Substitutions<'a> {
	type Item = Substitution<'a>;
	fn next(&mut self) -> Option<Self::Item> {
	let (mut sub, tail) = parse_next_substitution(self.s)?;
	self.s = tail;
	match sub {
	Substitution::Format(_) => {
	if let Some(inner_span) = sub.position() {
	sub.set_position(inner_span.start + self.pos, inner_span.end + self.pos);
	self.pos += inner_span.end;
	}
	}
	Substitution::Escape => self.pos += 2,
	}
	Some(sub)
	}

	fn size_hint(&self) -> (usize, Option<usize>) {
	// Substitutions are at least 2 characters long.
	(0, Some(self.s.len() / 2))
	}
	}

	enum State {
	Start,
	Flags,
	Width,
	WidthArg,
	Prec,
	PrecInner,
	Length,
	Type,
	}

	/// Parse the next substitution from the input string.
	pub fn parse_next_substitution(s: &str) -> Option<(Substitution<'_>, &str)> {
	use self::State::*;

	let at = {
	let start = s.find('%')?;
	if let '%' = s[start + 1..].chars().next()? {
	return Some((Substitution::Escape, &s[start + 2..]));
	}

	Cur::new_at(&s[..], start)
	};

	// This is meant to be a translation of the following regex:
	//
	// ```regex
	// (?x)
	// ^ %
	// (?: (?P<parameter> \d+) \$ )?
	// (?P<flags> [-+ 0\#']* )
	// (?P<width> \d+ \| \* (?: (?P<widtha> \d+) \$ )? )?
	// (?: \. (?P<precision> \d+ \| \* (?: (?P<precisiona> \d+) \$ )? ) )?
	// (?P<length>
	// # Standard
	// hh \| h \| ll \| l \| L \| z \| j \| t
	//
	// # Other
	// \| I32 \| I64 \| I \| q
	// )?
	// (?P<type> . )
	// ```

	// Used to establish the full span at the end.
	let start = at;
	// The current position within the string.
	let mut at = at.at_next_cp()?;
	// `c` is the next codepoint, `next` is a cursor after it.
	let (mut c, mut next) = at.next_cp()?;

	// Update `at`, `c`, and `next`, exiting if we're out of input.
	macro_rules! move_to {
	($cur:expr) => {{
	at = $cur;
	let (c_, next_) = at.next_cp()?;
	c = c_;
	next = next_;
	}};
	}

	// Constructs a result when parsing fails.
	//
	// Note: `move` used to capture copies of the cursors as they are now.
	let fallback = move \|\| {
	Some((
	Substitution::Format(Format {
	span: start.slice_between(next).unwrap(),
	parameter: None,
	flags: "",
	width: None,
	precision: None,
	length: None,
	type_: at.slice_between(next).unwrap(),
	position: InnerSpan::new(start.at, next.at),
	}),
	next.slice_after(),
	))
	};

	// Next parsing state.
	let mut state = Start;

	// Sadly, Rust isn't quite smart enough to know these must be initialised by the end.
	let mut parameter: Option<u16> = None;
	let mut flags: &str = "";
	let mut width: Option<Num> = None;
	let mut precision: Option<Num> = None;
	let mut length: Option<&str> = None;
	let mut type_: &str = "";
	let end: Cur<'_>;

	if let Start = state {
	match c {
	'1'..='9' => {
	let end = at_next_cp_while(next, is_digit);
	match end.next_cp() {
	// Yes, this is the parameter.
	Some(('$', end2)) => {
	state = Flags;
	parameter = Some(at.slice_between(end).unwrap().parse().unwrap());
	move_to!(end2);
	}
	// Wait, no, actually, it's the width.
	Some(_) => {
	state = Prec;
	parameter = None;
	flags = "";
	width = Some(Num::from_str(at.slice_between(end).unwrap(), None));
	move_to!(end);
	}
	// It's invalid, is what it is.
	None => return fallback(),
	}
	}
	_ => {
	state = Flags;
	parameter = None;
	move_to!(at);
	}
	}
	}

	if let Flags = state {
	let end = at_next_cp_while(at, is_flag);
	state = Width;
	flags = at.slice_between(end).unwrap();
	move_to!(end);
	}

	if let Width = state {
	match c {
	'*' => {
	state = WidthArg;
	move_to!(next);
	}
	'1'..='9' => {
	let end = at_next_cp_while(next, is_digit);
	state = Prec;
	width = Some(Num::from_str(at.slice_between(end).unwrap(), None));
	move_to!(end);
	}
	_ => {
	state = Prec;
	width = None;
	move_to!(at);
	}
	}
	}

	if let WidthArg = state {
	let end = at_next_cp_while(at, is_digit);
	match end.next_cp() {
	Some(('$', end2)) => {
	state = Prec;
	width = Some(Num::from_str("", Some(at.slice_between(end).unwrap())));
	move_to!(end2);
	}
	_ => {
	state = Prec;
	width = Some(Num::Next);
	move_to!(end);
	}
	}
	}

	if let Prec = state {
	match c {
	'.' => {
	state = PrecInner;
	move_to!(next);
	}
	_ => {
	state = Length;
	precision = None;
	move_to!(at);
	}
	}
	}

	if let PrecInner = state {
	match c {
	'*' => {
	let end = at_next_cp_while(next, is_digit);
	match end.next_cp() {
	Some(('$', end2)) => {
	state = Length;
	precision = Some(Num::from_str("*", next.slice_between(end)));
	move_to!(end2);
	}
	_ => {
	state = Length;
	precision = Some(Num::Next);
	move_to!(end);
	}
	}
	}
	'0'..='9' => {
	let end = at_next_cp_while(next, is_digit);
	state = Length;
	precision = Some(Num::from_str(at.slice_between(end).unwrap(), None));
	move_to!(end);
	}
	_ => return fallback(),
	}
	}

	if let Length = state {
	let c1_next1 = next.next_cp();
	match (c, c1_next1) {
	('h', Some(('h', next1))) \| ('l', Some(('l', next1))) => {
	state = Type;
	length = Some(at.slice_between(next1).unwrap());
	move_to!(next1);
	}

	('h' \| 'l' \| 'L' \| 'z' \| 'j' \| 't' \| 'q', _) => {
	state = Type;
	length = Some(at.slice_between(next).unwrap());
	move_to!(next);
	}

	('I', _) => {
	let end = next
	.at_next_cp()
	.and_then(\|end\| end.at_next_cp())
	.map(\|end\| (next.slice_between(end).unwrap(), end));
	let end = match end {
	Some(("32" \| "64", end)) => end,
	_ => next,
	};
	state = Type;
	length = Some(at.slice_between(end).unwrap());
	move_to!(end);
	}

	_ => {
	state = Type;
	length = None;
	move_to!(at);
	}
	}
	}

	if let Type = state {
	drop(c);
	type_ = at.slice_between(next).unwrap();

	// Don't use `move_to!` here, as we can be at the end of the input.
	at = next;
	}

	drop(c);
	drop(next);

	end = at;
	let position = InnerSpan::new(start.at, end.at);

	let f = Format {
	span: start.slice_between(end).unwrap(),
	parameter,
	flags,
	width,
	precision,
	length,
	type_,
	position,
	};
	Some((Substitution::Format(f), end.slice_after()))
	}

	fn at_next_cp_while<F>(mut cur: Cur<'_>, mut pred: F) -> Cur<'_>
	where
	F: FnMut(char) -> bool,
	{
	loop {
	match cur.next_cp() {
	Some((c, next)) => {
	if pred(c) {
	cur = next;
	} else {
	return cur;
	}
	}
	None => return cur,
	}
	}
	}

	fn is_digit(c: char) -> bool {
	match c {
	'0'..='9' => true,
	_ => false,
	}
	}

	fn is_flag(c: char) -> bool {
	match c {
	'0' \| '-' \| '+' \| ' ' \| '#' \| '\'' => true,
	_ => false,
	}
	}

	#[cfg(test)]
	mod tests;
	}

	pub mod shell {
	use super::strcursor::StrCursor as Cur;
	use rustc_span::InnerSpan;

	#[derive(Clone, PartialEq, Debug)]
	pub enum Substitution<'a> {
	Ordinal(u8, (usize, usize)),
	Name(&'a str, (usize, usize)),
	Escape((usize, usize)),
	}

	impl Substitution<'_> {
	pub fn as_str(&self) -> String {
	match self {
	Substitution::Ordinal(n, _) => format!("${}", n),
	Substitution::Name(n, _) => format!("${}", n),
	Substitution::Escape(_) => "$$".into(),
	}
	}

	pub fn position(&self) -> Option<InnerSpan> {
	match self {
	Substitution::Ordinal(_, pos)
	\| Substitution::Name(_, pos)
	\| Substitution::Escape(pos) => Some(InnerSpan::new(pos.0, pos.1)),
	}
	}

	pub fn set_position(&mut self, start: usize, end: usize) {
	match self {
	Substitution::Ordinal(_, ref mut pos)
	\| Substitution::Name(_, ref mut pos)
	\| Substitution::Escape(ref mut pos) => *pos = (start, end),
	}
	}

	pub fn translate(&self) -> Option<String> {
	match *self {
	Substitution::Ordinal(n, _) => Some(format!("{{{}}}", n)),
	Substitution::Name(n, _) => Some(format!("{{{}}}", n)),
	Substitution::Escape(_) => None,
	}
	}
	}

	/// Returns an iterator over all substitutions in a given string.
	pub fn iter_subs(s: &str, start_pos: usize) -> Substitutions<'_> {
	Substitutions { s, pos: start_pos }
	}

	/// Iterator over substitutions in a string.
	pub struct Substitutions<'a> {
	s: &'a str,
	pos: usize,
	}

	impl<'a> Iterator for Substitutions<'a> {
	type Item = Substitution<'a>;
	fn next(&mut self) -> Option<Self::Item> {
	match parse_next_substitution(self.s) {
	Some((mut sub, tail)) => {
	self.s = tail;
	if let Some(InnerSpan { start, end }) = sub.position() {
	sub.set_position(start + self.pos, end + self.pos);
	self.pos += end;
	}
	Some(sub)
	}
	None => None,
	}
	}

	fn size_hint(&self) -> (usize, Option<usize>) {
	(0, Some(self.s.len()))
	}
	}

	/// Parse the next substitution from the input string.
	pub fn parse_next_substitution(s: &str) -> Option<(Substitution<'_>, &str)> {
	let at = {
	let start = s.find('$')?;
	match s[start + 1..].chars().next()? {
	'$' => return Some((Substitution::Escape((start, start + 2)), &s[start + 2..])),
	c @ '0'..='9' => {
	let n = (c as u8) - b'0';
	return Some((Substitution::Ordinal(n, (start, start + 2)), &s[start + 2..]));
	}
	_ => { /* fall-through */ }
	}

	Cur::new_at(&s[..], start)
	};

	let at = at.at_next_cp()?;
	let (c, inner) = at.next_cp()?;

	if !is_ident_head(c) {
	None
	} else {
	let end = at_next_cp_while(inner, is_ident_tail);
	let slice = at.slice_between(end).unwrap();
	let start = at.at - 1;
	let end_pos = at.at + slice.len();
	Some((Substitution::Name(slice, (start, end_pos)), end.slice_after()))
	}
	}

	fn at_next_cp_while<F>(mut cur: Cur<'_>, mut pred: F) -> Cur<'_>
	where
	F: FnMut(char) -> bool,
	{
	loop {
	match cur.next_cp() {
	Some((c, next)) => {
	if pred(c) {
	cur = next;
	} else {
	return cur;
	}
	}
	None => return cur,
	}
	}
	}

	fn is_ident_head(c: char) -> bool {
	match c {
	'a'..='z' \| 'A'..='Z' \| '_' => true,
	_ => false,
	}
	}

	fn is_ident_tail(c: char) -> bool {
	match c {
	'0'..='9' => true,
	c => is_ident_head(c),
	}
	}

	#[cfg(test)]
	mod tests;
	}

	mod strcursor {
	pub struct StrCursor<'a> {
	s: &'a str,
	pub at: usize,
	}

	impl<'a> StrCursor<'a> {
	pub fn new_at(s: &'a str, at: usize) -> StrCursor<'a> {
	StrCursor { s, at }
	}

	pub fn at_next_cp(mut self) -> Option<StrCursor<'a>> {
	match self.try_seek_right_cp() {
	true => Some(self),
	false => None,
	}
	}

	pub fn next_cp(mut self) -> Option<(char, StrCursor<'a>)> {
	let cp = self.cp_after()?;
	self.seek_right(cp.len_utf8());
	Some((cp, self))
	}

	fn slice_before(&self) -> &'a str {
	&self.s[0..self.at]
	}

	pub fn slice_after(&self) -> &'a str {
	&self.s[self.at..]
	}

	pub fn slice_between(&self, until: StrCursor<'a>) -> Option<&'a str> {
	if !str_eq_literal(self.s, until.s) {
	None
	} else {
	use std::cmp::{max, min};
	let beg = min(self.at, until.at);
	let end = max(self.at, until.at);
	Some(&self.s[beg..end])
	}
	}

	fn cp_after(&self) -> Option<char> {
	self.slice_after().chars().next()
	}

	fn try_seek_right_cp(&mut self) -> bool {
	match self.slice_after().chars().next() {
	Some(c) => {
	self.at += c.len_utf8();
	true
	}
	None => false,
	}
	}

	fn seek_right(&mut self, bytes: usize) {
	self.at += bytes;
	}
	}

	impl Copy for StrCursor<'_> {}

	impl<'a> Clone for StrCursor<'a> {
	fn clone(&self) -> StrCursor<'a> {
	*self
	}
	}

	impl std::fmt::Debug for StrCursor<'_> {
	fn fmt(&self, fmt: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
	write!(fmt, "StrCursor({:?} \| {:?})", self.slice_before(), self.slice_after())
	}
	}

	fn str_eq_literal(a: &str, b: &str) -> bool {
	a.as_bytes().as_ptr() == b.as_bytes().as_ptr() && a.len() == b.len()
	}
	}