src/librustdoc/clean/cfg.rs - third_party/rust - Git at Google

 //! The representation of a `#[doc(cfg(...))]` attribute.

 // FIXME: Once the portability lint RFC is implemented (see tracking issue #41619),
 // switch to use those structures instead.

 use std::fmt::{self, Write};
 use std::mem;
 use std::ops;

 use rustc_ast::{LitKind, MetaItem, MetaItemKind, NestedMetaItem};
 use rustc_feature::Features;
 use rustc_session::parse::ParseSess;
 use rustc_span::symbol::{sym, Symbol};

 use rustc_span::Span;

 use crate::html::escape::Escape;

 #[cfg(test)]
 mod tests;

 #[derive(Clone, Debug, PartialEq, Eq, Hash)]
 pub enum Cfg {
     /// Accepts all configurations.
     True,
     /// Denies all configurations.
     False,
     /// A generic configuration option, e.g., `test` or `target_os = "linux"`.
     Cfg(Symbol, Option<Symbol>),
     /// Negates a configuration requirement, i.e., `not(x)`.
     Not(Box<Cfg>),
     /// Union of a list of configuration requirements, i.e., `any(...)`.
     Any(Vec<Cfg>),
     /// Intersection of a list of configuration requirements, i.e., `all(...)`.
     All(Vec<Cfg>),
 }

 #[derive(PartialEq, Debug)]
 pub struct InvalidCfgError {
     pub msg: &'static str,
     pub span: Span,
 }

 impl Cfg {
     /// Parses a `NestedMetaItem` into a `Cfg`.
     fn parse_nested(nested_cfg: &NestedMetaItem) -> Result<Cfg, InvalidCfgError> {
         match nested_cfg {
             NestedMetaItem::MetaItem(ref cfg) => Cfg::parse(cfg),
             NestedMetaItem::Literal(ref lit) => {
                 Err(InvalidCfgError { msg: "unexpected literal", span: lit.span })
             }
         }
     }

     /// Parses a `MetaItem` into a `Cfg`.
     ///
     /// The `MetaItem` should be the content of the `#[cfg(...)]`, e.g., `unix` or
     /// `target_os = "redox"`.
     ///
     /// If the content is not properly formatted, it will return an error indicating what and where
     /// the error is.
     pub fn parse(cfg: &MetaItem) -> Result<Cfg, InvalidCfgError> {
         let name = match cfg.ident() {
             Some(ident) => ident.name,
             None => {
                 return Err(InvalidCfgError {
                     msg: "expected a single identifier",
                     span: cfg.span,
                 });
             }
         };
         match cfg.kind {
             MetaItemKind::Word => Ok(Cfg::Cfg(name, None)),
             MetaItemKind::NameValue(ref lit) => match lit.kind {
                 LitKind::Str(value, _) => Ok(Cfg::Cfg(name, Some(value))),
                 _ => Err(InvalidCfgError {
                     // FIXME: if the main #[cfg] syntax decided to support non-string literals,
                     // this should be changed as well.
                     msg: "value of cfg option should be a string literal",
                     span: lit.span,
                 }),
             },
             MetaItemKind::List(ref items) => {
                 let mut sub_cfgs = items.iter().map(Cfg::parse_nested);
                 match name {
                     sym::all => sub_cfgs.fold(Ok(Cfg::True), |x, y| Ok(x? & y?)),
                     sym::any => sub_cfgs.fold(Ok(Cfg::False), |x, y| Ok(x? | y?)),
                     sym::not => {
                         if sub_cfgs.len() == 1 {
                             Ok(!sub_cfgs.next().unwrap()?)
                         } else {
                             Err(InvalidCfgError { msg: "expected 1 cfg-pattern", span: cfg.span })
                         }
                     }
                     _ => Err(InvalidCfgError { msg: "invalid predicate", span: cfg.span }),
                 }
             }
         }
     }

     /// Checks whether the given configuration can be matched in the current session.
     ///
     /// Equivalent to `attr::cfg_matches`.
     // FIXME: Actually make use of `features`.
     pub fn matches(&self, parse_sess: &ParseSess, features: Option<&Features>) -> bool {
         match *self {
             Cfg::False => false,
             Cfg::True => true,
             Cfg::Not(ref child) => !child.matches(parse_sess, features),
             Cfg::All(ref sub_cfgs) => {
                 sub_cfgs.iter().all(|sub_cfg| sub_cfg.matches(parse_sess, features))
             }
             Cfg::Any(ref sub_cfgs) => {
                 sub_cfgs.iter().any(|sub_cfg| sub_cfg.matches(parse_sess, features))
             }
             Cfg::Cfg(name, value) => parse_sess.config.contains(&(name, value)),
         }
     }

     /// Whether the configuration consists of just `Cfg` or `Not`.
     fn is_simple(&self) -> bool {
         match *self {
             Cfg::False | Cfg::True | Cfg::Cfg(..) | Cfg::Not(..) => true,
             Cfg::All(..) | Cfg::Any(..) => false,
         }
     }

     /// Whether the configuration consists of just `Cfg`, `Not` or `All`.
     fn is_all(&self) -> bool {
         match *self {
             Cfg::False | Cfg::True | Cfg::Cfg(..) | Cfg::Not(..) | Cfg::All(..) => true,
             Cfg::Any(..) => false,
         }
     }

     /// Renders the configuration for human display, as a short HTML description.
     pub(crate) fn render_short_html(&self) -> String {
         let mut msg = Display(self, Format::ShortHtml).to_string();
         if self.should_capitalize_first_letter() {
             if let Some(i) = msg.find(|c: char| c.is_ascii_alphanumeric()) {
                 msg[i..i + 1].make_ascii_uppercase();
             }
         }
         msg
     }

     /// Renders the configuration for long display, as a long HTML description.
     pub(crate) fn render_long_html(&self) -> String {
         let on = if self.should_use_with_in_description() { "with" } else { "on" };

         let mut msg = format!(
             "This is supported {} <strong>{}</strong>",
             on,
             Display(self, Format::LongHtml)
         );
         if self.should_append_only_to_description() {
             msg.push_str(" only");
         }
         msg.push('.');
         msg
     }

     /// Renders the configuration for long display, as a long plain text description.
     pub(crate) fn render_long_plain(&self) -> String {
         let on = if self.should_use_with_in_description() { "with" } else { "on" };

         let mut msg = format!("This is supported {} {}", on, Display(self, Format::LongPlain));
         if self.should_append_only_to_description() {
             msg.push_str(" only");
         }
         msg
     }

     fn should_capitalize_first_letter(&self) -> bool {
         match *self {
             Cfg::False | Cfg::True | Cfg::Not(..) => true,
             Cfg::Any(ref sub_cfgs) | Cfg::All(ref sub_cfgs) => {
                 sub_cfgs.first().map(Cfg::should_capitalize_first_letter).unwrap_or(false)
             }
             Cfg::Cfg(name, _) => match name {
                 sym::debug_assertions | sym::target_endian => true,
                 _ => false,
             },
         }
     }

     fn should_append_only_to_description(&self) -> bool {
         match *self {
             Cfg::False | Cfg::True => false,
             Cfg::Any(..) | Cfg::All(..) | Cfg::Cfg(..) => true,
             Cfg::Not(ref child) => match **child {
                 Cfg::Cfg(..) => true,
                 _ => false,
             },
         }
     }

     fn should_use_with_in_description(&self) -> bool {
         match *self {
             Cfg::Cfg(name, _) if name == sym::target_feature => true,
             _ => false,
         }
     }

     /// Attempt to simplify this cfg by assuming that `assume` is already known to be true, will
     /// return `None` if simplification managed to completely eliminate any requirements from this
     /// `Cfg`.
     ///
     /// See `tests::test_simplify_with` for examples.
     pub(crate) fn simplify_with(&self, assume: &Cfg) -> Option<Cfg> {
         if self == assume {
             return None;
         }

         if let Cfg::All(a) = self {
             let mut sub_cfgs: Vec<Cfg> = if let Cfg::All(b) = assume {
                 a.iter().filter(|a| !b.contains(a)).cloned().collect()
             } else {
                 a.iter().filter(|&a| a != assume).cloned().collect()
             };
             let len = sub_cfgs.len();
             return match len {
                 0 => None,
                 1 => sub_cfgs.pop(),
                 _ => Some(Cfg::All(sub_cfgs)),
             };
         } else if let Cfg::All(b) = assume {
             if b.contains(self) {
                 return None;
             }
         }

         Some(self.clone())
     }
 }

 impl ops::Not for Cfg {
     type Output = Cfg;
     fn not(self) -> Cfg {
         match self {
             Cfg::False => Cfg::True,
             Cfg::True => Cfg::False,
             Cfg::Not(cfg) => *cfg,
             s => Cfg::Not(Box::new(s)),
         }
     }
 }

 impl ops::BitAndAssign for Cfg {
     fn bitand_assign(&mut self, other: Cfg) {
         match (self, other) {
             (&mut Cfg::False, _) | (_, Cfg::True) => {}
             (s, Cfg::False) => *s = Cfg::False,
             (s @ &mut Cfg::True, b) => *s = b,
             (&mut Cfg::All(ref mut a), Cfg::All(ref mut b)) => {
                 for c in b.drain(..) {
                     if !a.contains(&c) {
                         a.push(c);
                     }
                 }
             }
             (&mut Cfg::All(ref mut a), ref mut b) => {
                 if !a.contains(b) {
                     a.push(mem::replace(b, Cfg::True));
                 }
             }
             (s, Cfg::All(mut a)) => {
                 let b = mem::replace(s, Cfg::True);
                 if !a.contains(&b) {
                     a.push(b);
                 }
                 *s = Cfg::All(a);
             }
             (s, b) => {
                 if *s != b {
                     let a = mem::replace(s, Cfg::True);
                     *s = Cfg::All(vec![a, b]);
                 }
             }
         }
     }
 }

 impl ops::BitAnd for Cfg {
     type Output = Cfg;
     fn bitand(mut self, other: Cfg) -> Cfg {
         self &= other;
         self
     }
 }

 impl ops::BitOrAssign for Cfg {
     fn bitor_assign(&mut self, other: Cfg) {
         match (self, other) {
             (&mut Cfg::True, _) | (_, Cfg::False) => {}
             (s, Cfg::True) => *s = Cfg::True,
             (s @ &mut Cfg::False, b) => *s = b,
             (&mut Cfg::Any(ref mut a), Cfg::Any(ref mut b)) => {
                 for c in b.drain(..) {
                     if !a.contains(&c) {
                         a.push(c);
                     }
                 }
             }
             (&mut Cfg::Any(ref mut a), ref mut b) => {
                 if !a.contains(b) {
                     a.push(mem::replace(b, Cfg::True));
                 }
             }
             (s, Cfg::Any(mut a)) => {
                 let b = mem::replace(s, Cfg::True);
                 if !a.contains(&b) {
                     a.push(b);
                 }
                 *s = Cfg::Any(a);
             }
             (s, b) => {
                 if *s != b {
                     let a = mem::replace(s, Cfg::True);
                     *s = Cfg::Any(vec![a, b]);
                 }
             }
         }
     }
 }

 impl ops::BitOr for Cfg {
     type Output = Cfg;
     fn bitor(mut self, other: Cfg) -> Cfg {
         self |= other;
         self
     }
 }

 #[derive(Clone, Copy)]
 enum Format {
     LongHtml,
     LongPlain,
     ShortHtml,
 }

 impl Format {
     fn is_long(self) -> bool {
         match self {
             Format::LongHtml | Format::LongPlain => true,
             Format::ShortHtml => false,
         }
     }

     fn is_html(self) -> bool {
         match self {
             Format::LongHtml | Format::ShortHtml => true,
             Format::LongPlain => false,
         }
     }
 }

 /// Pretty-print wrapper for a `Cfg`. Also indicates what form of rendering should be used.
 struct Display<'a>(&'a Cfg, Format);

 fn write_with_opt_paren<T: fmt::Display>(
     fmt: &mut fmt::Formatter<'_>,
     has_paren: bool,
     obj: T,
 ) -> fmt::Result {
     if has_paren {
         fmt.write_char('(')?;
     }
     obj.fmt(fmt)?;
     if has_paren {
         fmt.write_char(')')?;
     }
     Ok(())
 }

 impl<'a> fmt::Display for Display<'a> {
     fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result {
         match *self.0 {
             Cfg::Not(ref child) => match **child {
                 Cfg::Any(ref sub_cfgs) => {
                     let separator =
                         if sub_cfgs.iter().all(Cfg::is_simple) { " nor " } else { ", nor " };
                     for (i, sub_cfg) in sub_cfgs.iter().enumerate() {
                         fmt.write_str(if i == 0 { "neither " } else { separator })?;
                         write_with_opt_paren(fmt, !sub_cfg.is_all(), Display(sub_cfg, self.1))?;
                     }
                     Ok(())
                 }
                 ref simple @ Cfg::Cfg(..) => write!(fmt, "non-{}", Display(simple, self.1)),
                 ref c => write!(fmt, "not ({})", Display(c, self.1)),
             },

             Cfg::Any(ref sub_cfgs) => {
                 let separator = if sub_cfgs.iter().all(Cfg::is_simple) { " or " } else { ", or " };

                 let short_longhand = self.1.is_long() && {
                     let all_crate_features = sub_cfgs
                         .iter()
                         .all(|sub_cfg| matches!(sub_cfg, Cfg::Cfg(sym::feature, Some(_))));
                     let all_target_features = sub_cfgs
                         .iter()
                         .all(|sub_cfg| matches!(sub_cfg, Cfg::Cfg(sym::target_feature, Some(_))));

                     if all_crate_features {
                         fmt.write_str("crate features ")?;
                         true
                     } else if all_target_features {
                         fmt.write_str("target features ")?;
                         true
                     } else {
                         false
                     }
                 };

                 for (i, sub_cfg) in sub_cfgs.iter().enumerate() {
                     if i != 0 {
                         fmt.write_str(separator)?;
                     }
                     if let (true, Cfg::Cfg(_, Some(feat))) = (short_longhand, sub_cfg) {
                         if self.1.is_html() {
                             write!(fmt, "<code>{}</code>", feat)?;
                         } else {
                             write!(fmt, "`{}`", feat)?;
                         }
                     } else {
                         write_with_opt_paren(fmt, !sub_cfg.is_all(), Display(sub_cfg, self.1))?;
                     }
                 }
                 Ok(())
             }

             Cfg::All(ref sub_cfgs) => {
                 let short_longhand = self.1.is_long() && {
                     let all_crate_features = sub_cfgs
                         .iter()
                         .all(|sub_cfg| matches!(sub_cfg, Cfg::Cfg(sym::feature, Some(_))));
                     let all_target_features = sub_cfgs
                         .iter()
                         .all(|sub_cfg| matches!(sub_cfg, Cfg::Cfg(sym::target_feature, Some(_))));

                     if all_crate_features {
                         fmt.write_str("crate features ")?;
                         true
                     } else if all_target_features {
                         fmt.write_str("target features ")?;
                         true
                     } else {
                         false
                     }
                 };

                 for (i, sub_cfg) in sub_cfgs.iter().enumerate() {
                     if i != 0 {
                         fmt.write_str(" and ")?;
                     }
                     if let (true, Cfg::Cfg(_, Some(feat))) = (short_longhand, sub_cfg) {
                         if self.1.is_html() {
                             write!(fmt, "<code>{}</code>", feat)?;
                         } else {
                             write!(fmt, "`{}`", feat)?;
                         }
                     } else {
                         write_with_opt_paren(fmt, !sub_cfg.is_simple(), Display(sub_cfg, self.1))?;
                     }
                 }
                 Ok(())
             }

             Cfg::True => fmt.write_str("everywhere"),
             Cfg::False => fmt.write_str("nowhere"),

             Cfg::Cfg(name, value) => {
                 let human_readable = match (name, value) {
                     (sym::unix, None) => "Unix",
                     (sym::windows, None) => "Windows",
                     (sym::debug_assertions, None) => "debug-assertions enabled",
                     (sym::target_os, Some(os)) => match &*os.as_str() {
                         "android" => "Android",
                         "dragonfly" => "DragonFly BSD",
                         "emscripten" => "Emscripten",
                         "freebsd" => "FreeBSD",
                         "fuchsia" => "Fuchsia",
                         "haiku" => "Haiku",
                         "hermit" => "HermitCore",
                         "illumos" => "illumos",
                         "ios" => "iOS",
                         "l4re" => "L4Re",
                         "linux" => "Linux",
                         "macos" => "macOS",
                         "netbsd" => "NetBSD",
                         "openbsd" => "OpenBSD",
                         "redox" => "Redox",
                         "solaris" => "Solaris",
                         "windows" => "Windows",
                         _ => "",
                     },
                     (sym::target_arch, Some(arch)) => match &*arch.as_str() {
                         "aarch64" => "AArch64",
                         "arm" => "ARM",
                         "asmjs" => "JavaScript",
                         "mips" => "MIPS",
                         "mips64" => "MIPS-64",
                         "msp430" => "MSP430",
                         "powerpc" => "PowerPC",
                         "powerpc64" => "PowerPC-64",
                         "s390x" => "s390x",
                         "sparc64" => "SPARC64",
                         "wasm32" => "WebAssembly",
                         "x86" => "x86",
                         "x86_64" => "x86-64",
                         _ => "",
                     },
                     (sym::target_vendor, Some(vendor)) => match &*vendor.as_str() {
                         "apple" => "Apple",
                         "pc" => "PC",
                         "rumprun" => "Rumprun",
                         "sun" => "Sun",
                         "fortanix" => "Fortanix",
                         _ => "",
                     },
                     (sym::target_env, Some(env)) => match &*env.as_str() {
                         "gnu" => "GNU",
                         "msvc" => "MSVC",
                         "musl" => "musl",
                         "newlib" => "Newlib",
                         "uclibc" => "uClibc",
                         "sgx" => "SGX",
                         _ => "",
                     },
                     (sym::target_endian, Some(endian)) => return write!(fmt, "{}-endian", endian),
                     (sym::target_pointer_width, Some(bits)) => return write!(fmt, "{}-bit", bits),
                     (sym::target_feature, Some(feat)) => match self.1 {
                         Format::LongHtml => {
                             return write!(fmt, "target feature <code>{}</code>", feat);
                         }
                         Format::LongPlain => return write!(fmt, "target feature `{}`", feat),
                         Format::ShortHtml => return write!(fmt, "<code>{}</code>", feat),
                     },
                     (sym::feature, Some(feat)) => match self.1 {
                         Format::LongHtml => {
                             return write!(fmt, "crate feature <code>{}</code>", feat);
                         }
                         Format::LongPlain => return write!(fmt, "crate feature `{}`", feat),
                         Format::ShortHtml => return write!(fmt, "<code>{}</code>", feat),
                     },
                     _ => "",
                 };
                 if !human_readable.is_empty() {
                     fmt.write_str(human_readable)
                 } else if let Some(v) = value {
                     if self.1.is_html() {
                         write!(
                             fmt,
                             r#"<code>{}="{}"</code>"#,
                             Escape(&name.as_str()),
                             Escape(&v.as_str())
                         )
                     } else {
                         write!(fmt, r#"`{}="{}"`"#, name, v)
                     }
                 } else if self.1.is_html() {
                     write!(fmt, "<code>{}</code>", Escape(&name.as_str()))
                 } else {
                     write!(fmt, "`{}`", name)
                 }
             }
         }
     }
 }
	//! The representation of a `#[doc(cfg(...))]` attribute.

	// FIXME: Once the portability lint RFC is implemented (see tracking issue #41619),
	// switch to use those structures instead.

	use std::fmt::{self, Write};
	use std::mem;
	use std::ops;

	use rustc_ast::{LitKind, MetaItem, MetaItemKind, NestedMetaItem};
	use rustc_feature::Features;
	use rustc_session::parse::ParseSess;
	use rustc_span::symbol::{sym, Symbol};

	use rustc_span::Span;

	use crate::html::escape::Escape;

	#[cfg(test)]
	mod tests;

	#[derive(Clone, Debug, PartialEq, Eq, Hash)]
	pub enum Cfg {
	/// Accepts all configurations.
	True,
	/// Denies all configurations.
	False,
	/// A generic configuration option, e.g., `test` or `target_os = "linux"`.
	Cfg(Symbol, Option<Symbol>),
	/// Negates a configuration requirement, i.e., `not(x)`.
	Not(Box<Cfg>),
	/// Union of a list of configuration requirements, i.e., `any(...)`.
	Any(Vec<Cfg>),
	/// Intersection of a list of configuration requirements, i.e., `all(...)`.
	All(Vec<Cfg>),
	}

	#[derive(PartialEq, Debug)]
	pub struct InvalidCfgError {
	pub msg: &'static str,
	pub span: Span,
	}

	impl Cfg {
	/// Parses a `NestedMetaItem` into a `Cfg`.
	fn parse_nested(nested_cfg: &NestedMetaItem) -> Result<Cfg, InvalidCfgError> {
	match nested_cfg {
	NestedMetaItem::MetaItem(ref cfg) => Cfg::parse(cfg),
	NestedMetaItem::Literal(ref lit) => {
	Err(InvalidCfgError { msg: "unexpected literal", span: lit.span })
	}
	}
	}

	/// Parses a `MetaItem` into a `Cfg`.
	///
	/// The `MetaItem` should be the content of the `#[cfg(...)]`, e.g., `unix` or
	/// `target_os = "redox"`.
	///
	/// If the content is not properly formatted, it will return an error indicating what and where
	/// the error is.
	pub fn parse(cfg: &MetaItem) -> Result<Cfg, InvalidCfgError> {
	let name = match cfg.ident() {
	Some(ident) => ident.name,
	None => {
	return Err(InvalidCfgError {
	msg: "expected a single identifier",
	span: cfg.span,
	});
	}
	};
	match cfg.kind {
	MetaItemKind::Word => Ok(Cfg::Cfg(name, None)),
	MetaItemKind::NameValue(ref lit) => match lit.kind {
	LitKind::Str(value, _) => Ok(Cfg::Cfg(name, Some(value))),
	_ => Err(InvalidCfgError {
	// FIXME: if the main #[cfg] syntax decided to support non-string literals,
	// this should be changed as well.
	msg: "value of cfg option should be a string literal",
	span: lit.span,
	}),
	},
	MetaItemKind::List(ref items) => {
	let mut sub_cfgs = items.iter().map(Cfg::parse_nested);
	match name {
	sym::all => sub_cfgs.fold(Ok(Cfg::True), \|x, y\| Ok(x? & y?)),
	sym::any => sub_cfgs.fold(Ok(Cfg::False), \|x, y\| Ok(x? \| y?)),
	sym::not => {
	if sub_cfgs.len() == 1 {
	Ok(!sub_cfgs.next().unwrap()?)
	} else {
	Err(InvalidCfgError { msg: "expected 1 cfg-pattern", span: cfg.span })
	}
	}
	_ => Err(InvalidCfgError { msg: "invalid predicate", span: cfg.span }),
	}
	}
	}
	}

	/// Checks whether the given configuration can be matched in the current session.
	///
	/// Equivalent to `attr::cfg_matches`.
	// FIXME: Actually make use of `features`.
	pub fn matches(&self, parse_sess: &ParseSess, features: Option<&Features>) -> bool {
	match *self {
	Cfg::False => false,
	Cfg::True => true,
	Cfg::Not(ref child) => !child.matches(parse_sess, features),
	Cfg::All(ref sub_cfgs) => {
	sub_cfgs.iter().all(\|sub_cfg\| sub_cfg.matches(parse_sess, features))
	}
	Cfg::Any(ref sub_cfgs) => {
	sub_cfgs.iter().any(\|sub_cfg\| sub_cfg.matches(parse_sess, features))
	}
	Cfg::Cfg(name, value) => parse_sess.config.contains(&(name, value)),
	}
	}

	/// Whether the configuration consists of just `Cfg` or `Not`.
	fn is_simple(&self) -> bool {
	match *self {
	Cfg::False \| Cfg::True \| Cfg::Cfg(..) \| Cfg::Not(..) => true,
	Cfg::All(..) \| Cfg::Any(..) => false,
	}
	}

	/// Whether the configuration consists of just `Cfg`, `Not` or `All`.
	fn is_all(&self) -> bool {
	match *self {
	Cfg::False \| Cfg::True \| Cfg::Cfg(..) \| Cfg::Not(..) \| Cfg::All(..) => true,
	Cfg::Any(..) => false,
	}
	}

	/// Renders the configuration for human display, as a short HTML description.
	pub(crate) fn render_short_html(&self) -> String {
	let mut msg = Display(self, Format::ShortHtml).to_string();
	if self.should_capitalize_first_letter() {
	if let Some(i) = msg.find(\|c: char\| c.is_ascii_alphanumeric()) {
	msg[i..i + 1].make_ascii_uppercase();
	}
	}
	msg
	}

	/// Renders the configuration for long display, as a long HTML description.
	pub(crate) fn render_long_html(&self) -> String {
	let on = if self.should_use_with_in_description() { "with" } else { "on" };

	let mut msg = format!(
	"This is supported {} <strong>{}</strong>",
	on,
	Display(self, Format::LongHtml)
	);
	if self.should_append_only_to_description() {
	msg.push_str(" only");
	}
	msg.push('.');
	msg
	}

	/// Renders the configuration for long display, as a long plain text description.
	pub(crate) fn render_long_plain(&self) -> String {
	let on = if self.should_use_with_in_description() { "with" } else { "on" };

	let mut msg = format!("This is supported {} {}", on, Display(self, Format::LongPlain));
	if self.should_append_only_to_description() {
	msg.push_str(" only");
	}
	msg
	}

	fn should_capitalize_first_letter(&self) -> bool {
	match *self {
	Cfg::False \| Cfg::True \| Cfg::Not(..) => true,
	Cfg::Any(ref sub_cfgs) \| Cfg::All(ref sub_cfgs) => {
	sub_cfgs.first().map(Cfg::should_capitalize_first_letter).unwrap_or(false)
	}
	Cfg::Cfg(name, _) => match name {
	sym::debug_assertions \| sym::target_endian => true,
	_ => false,
	},
	}
	}

	fn should_append_only_to_description(&self) -> bool {
	match *self {
	Cfg::False \| Cfg::True => false,
	Cfg::Any(..) \| Cfg::All(..) \| Cfg::Cfg(..) => true,
	Cfg::Not(ref child) => match **child {
	Cfg::Cfg(..) => true,
	_ => false,
	},
	}
	}

	fn should_use_with_in_description(&self) -> bool {
	match *self {
	Cfg::Cfg(name, _) if name == sym::target_feature => true,
	_ => false,
	}
	}

	/// Attempt to simplify this cfg by assuming that `assume` is already known to be true, will
	/// return `None` if simplification managed to completely eliminate any requirements from this
	/// `Cfg`.
	///
	/// See `tests::test_simplify_with` for examples.
	pub(crate) fn simplify_with(&self, assume: &Cfg) -> Option<Cfg> {
	if self == assume {
	return None;
	}

	if let Cfg::All(a) = self {
	let mut sub_cfgs: Vec<Cfg> = if let Cfg::All(b) = assume {
	a.iter().filter(\|a\| !b.contains(a)).cloned().collect()
	} else {
	a.iter().filter(\|&a\| a != assume).cloned().collect()
	};
	let len = sub_cfgs.len();
	return match len {
	0 => None,
	1 => sub_cfgs.pop(),
	_ => Some(Cfg::All(sub_cfgs)),
	};
	} else if let Cfg::All(b) = assume {
	if b.contains(self) {
	return None;
	}
	}

	Some(self.clone())
	}
	}

	impl ops::Not for Cfg {
	type Output = Cfg;
	fn not(self) -> Cfg {
	match self {
	Cfg::False => Cfg::True,
	Cfg::True => Cfg::False,
	Cfg::Not(cfg) => *cfg,
	s => Cfg::Not(Box::new(s)),
	}
	}
	}

	impl ops::BitAndAssign for Cfg {
	fn bitand_assign(&mut self, other: Cfg) {
	match (self, other) {
	(&mut Cfg::False, _) \| (_, Cfg::True) => {}
	(s, Cfg::False) => *s = Cfg::False,
	(s @ &mut Cfg::True, b) => *s = b,
	(&mut Cfg::All(ref mut a), Cfg::All(ref mut b)) => {
	for c in b.drain(..) {
	if !a.contains(&c) {
	a.push(c);
	}
	}
	}
	(&mut Cfg::All(ref mut a), ref mut b) => {
	if !a.contains(b) {
	a.push(mem::replace(b, Cfg::True));
	}
	}
	(s, Cfg::All(mut a)) => {
	let b = mem::replace(s, Cfg::True);
	if !a.contains(&b) {
	a.push(b);
	}
	*s = Cfg::All(a);
	}
	(s, b) => {
	if *s != b {
	let a = mem::replace(s, Cfg::True);
	*s = Cfg::All(vec![a, b]);
	}
	}
	}
	}
	}

	impl ops::BitAnd for Cfg {
	type Output = Cfg;
	fn bitand(mut self, other: Cfg) -> Cfg {
	self &= other;
	self
	}
	}

	impl ops::BitOrAssign for Cfg {
	fn bitor_assign(&mut self, other: Cfg) {
	match (self, other) {
	(&mut Cfg::True, _) \| (_, Cfg::False) => {}
	(s, Cfg::True) => *s = Cfg::True,
	(s @ &mut Cfg::False, b) => *s = b,
	(&mut Cfg::Any(ref mut a), Cfg::Any(ref mut b)) => {
	for c in b.drain(..) {
	if !a.contains(&c) {
	a.push(c);
	}
	}
	}
	(&mut Cfg::Any(ref mut a), ref mut b) => {
	if !a.contains(b) {
	a.push(mem::replace(b, Cfg::True));
	}
	}
	(s, Cfg::Any(mut a)) => {
	let b = mem::replace(s, Cfg::True);
	if !a.contains(&b) {
	a.push(b);
	}
	*s = Cfg::Any(a);
	}
	(s, b) => {
	if *s != b {
	let a = mem::replace(s, Cfg::True);
	*s = Cfg::Any(vec![a, b]);
	}
	}
	}
	}
	}

	impl ops::BitOr for Cfg {
	type Output = Cfg;
	fn bitor(mut self, other: Cfg) -> Cfg {
	self \|= other;
	self
	}
	}

	#[derive(Clone, Copy)]
	enum Format {
	LongHtml,
	LongPlain,
	ShortHtml,
	}

	impl Format {
	fn is_long(self) -> bool {
	match self {
	Format::LongHtml \| Format::LongPlain => true,
	Format::ShortHtml => false,
	}
	}

	fn is_html(self) -> bool {
	match self {
	Format::LongHtml \| Format::ShortHtml => true,
	Format::LongPlain => false,
	}
	}
	}

	/// Pretty-print wrapper for a `Cfg`. Also indicates what form of rendering should be used.
	struct Display<'a>(&'a Cfg, Format);

	fn write_with_opt_paren<T: fmt::Display>(
	fmt: &mut fmt::Formatter<'_>,
	has_paren: bool,
	obj: T,
	) -> fmt::Result {
	if has_paren {
	fmt.write_char('(')?;
	}
	obj.fmt(fmt)?;
	if has_paren {
	fmt.write_char(')')?;
	}
	Ok(())
	}

	impl<'a> fmt::Display for Display<'a> {
	fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result {
	match *self.0 {
	Cfg::Not(ref child) => match **child {
	Cfg::Any(ref sub_cfgs) => {
	let separator =
	if sub_cfgs.iter().all(Cfg::is_simple) { " nor " } else { ", nor " };
	for (i, sub_cfg) in sub_cfgs.iter().enumerate() {
	fmt.write_str(if i == 0 { "neither " } else { separator })?;
	write_with_opt_paren(fmt, !sub_cfg.is_all(), Display(sub_cfg, self.1))?;
	}
	Ok(())
	}
	ref simple @ Cfg::Cfg(..) => write!(fmt, "non-{}", Display(simple, self.1)),
	ref c => write!(fmt, "not ({})", Display(c, self.1)),
	},

	Cfg::Any(ref sub_cfgs) => {
	let separator = if sub_cfgs.iter().all(Cfg::is_simple) { " or " } else { ", or " };

	let short_longhand = self.1.is_long() && {
	let all_crate_features = sub_cfgs
	.iter()
	.all(\|sub_cfg\| matches!(sub_cfg, Cfg::Cfg(sym::feature, Some(_))));
	let all_target_features = sub_cfgs
	.iter()
	.all(\|sub_cfg\| matches!(sub_cfg, Cfg::Cfg(sym::target_feature, Some(_))));

	if all_crate_features {
	fmt.write_str("crate features ")?;
	true
	} else if all_target_features {
	fmt.write_str("target features ")?;
	true
	} else {
	false
	}
	};

	for (i, sub_cfg) in sub_cfgs.iter().enumerate() {
	if i != 0 {
	fmt.write_str(separator)?;
	}
	if let (true, Cfg::Cfg(_, Some(feat))) = (short_longhand, sub_cfg) {
	if self.1.is_html() {
	write!(fmt, "<code>{}</code>", feat)?;
	} else {
	write!(fmt, "`{}`", feat)?;
	}
	} else {
	write_with_opt_paren(fmt, !sub_cfg.is_all(), Display(sub_cfg, self.1))?;
	}
	}
	Ok(())
	}

	Cfg::All(ref sub_cfgs) => {
	let short_longhand = self.1.is_long() && {
	let all_crate_features = sub_cfgs
	.iter()
	.all(\|sub_cfg\| matches!(sub_cfg, Cfg::Cfg(sym::feature, Some(_))));
	let all_target_features = sub_cfgs
	.iter()
	.all(\|sub_cfg\| matches!(sub_cfg, Cfg::Cfg(sym::target_feature, Some(_))));

	if all_crate_features {
	fmt.write_str("crate features ")?;
	true
	} else if all_target_features {
	fmt.write_str("target features ")?;
	true
	} else {
	false
	}
	};

	for (i, sub_cfg) in sub_cfgs.iter().enumerate() {
	if i != 0 {
	fmt.write_str(" and ")?;
	}
	if let (true, Cfg::Cfg(_, Some(feat))) = (short_longhand, sub_cfg) {
	if self.1.is_html() {
	write!(fmt, "<code>{}</code>", feat)?;
	} else {
	write!(fmt, "`{}`", feat)?;
	}
	} else {
	write_with_opt_paren(fmt, !sub_cfg.is_simple(), Display(sub_cfg, self.1))?;
	}
	}
	Ok(())
	}

	Cfg::True => fmt.write_str("everywhere"),
	Cfg::False => fmt.write_str("nowhere"),

	Cfg::Cfg(name, value) => {
	let human_readable = match (name, value) {
	(sym::unix, None) => "Unix",
	(sym::windows, None) => "Windows",
	(sym::debug_assertions, None) => "debug-assertions enabled",
	(sym::target_os, Some(os)) => match &*os.as_str() {
	"android" => "Android",
	"dragonfly" => "DragonFly BSD",
	"emscripten" => "Emscripten",
	"freebsd" => "FreeBSD",
	"fuchsia" => "Fuchsia",
	"haiku" => "Haiku",
	"hermit" => "HermitCore",
	"illumos" => "illumos",
	"ios" => "iOS",
	"l4re" => "L4Re",
	"linux" => "Linux",
	"macos" => "macOS",
	"netbsd" => "NetBSD",
	"openbsd" => "OpenBSD",
	"redox" => "Redox",
	"solaris" => "Solaris",
	"windows" => "Windows",
	_ => "",
	},
	(sym::target_arch, Some(arch)) => match &*arch.as_str() {
	"aarch64" => "AArch64",
	"arm" => "ARM",
	"asmjs" => "JavaScript",
	"mips" => "MIPS",
	"mips64" => "MIPS-64",
	"msp430" => "MSP430",
	"powerpc" => "PowerPC",
	"powerpc64" => "PowerPC-64",
	"s390x" => "s390x",
	"sparc64" => "SPARC64",
	"wasm32" => "WebAssembly",
	"x86" => "x86",
	"x86_64" => "x86-64",
	_ => "",
	},
	(sym::target_vendor, Some(vendor)) => match &*vendor.as_str() {
	"apple" => "Apple",
	"pc" => "PC",
	"rumprun" => "Rumprun",
	"sun" => "Sun",
	"fortanix" => "Fortanix",
	_ => "",
	},
	(sym::target_env, Some(env)) => match &*env.as_str() {
	"gnu" => "GNU",
	"msvc" => "MSVC",
	"musl" => "musl",
	"newlib" => "Newlib",
	"uclibc" => "uClibc",
	"sgx" => "SGX",
	_ => "",
	},
	(sym::target_endian, Some(endian)) => return write!(fmt, "{}-endian", endian),
	(sym::target_pointer_width, Some(bits)) => return write!(fmt, "{}-bit", bits),
	(sym::target_feature, Some(feat)) => match self.1 {
	Format::LongHtml => {
	return write!(fmt, "target feature <code>{}</code>", feat);
	}
	Format::LongPlain => return write!(fmt, "target feature `{}`", feat),
	Format::ShortHtml => return write!(fmt, "<code>{}</code>", feat),
	},
	(sym::feature, Some(feat)) => match self.1 {
	Format::LongHtml => {
	return write!(fmt, "crate feature <code>{}</code>", feat);
	}
	Format::LongPlain => return write!(fmt, "crate feature `{}`", feat),
	Format::ShortHtml => return write!(fmt, "<code>{}</code>", feat),
	},
	_ => "",
	};
	if !human_readable.is_empty() {
	fmt.write_str(human_readable)
	} else if let Some(v) = value {
	if self.1.is_html() {
	write!(
	fmt,
	r#"<code>{}="{}"</code>"#,
	Escape(&name.as_str()),
	Escape(&v.as_str())
	)
	} else {
	write!(fmt, r#"`{}="{}"`"#, name, v)
	}
	} else if self.1.is_html() {
	write!(fmt, "<code>{}</code>", Escape(&name.as_str()))
	} else {
	write!(fmt, "`{}`", name)
	}
	}
	}
	}
	}