src/libsyntax_ext/deriving/cmp/partial_ord.rs - third_party/rust - Git at Google

 pub use OrderingOp::*;

 use crate::deriving::{path_local, pathvec_std, path_std};
 use crate::deriving::generic::*;
 use crate::deriving::generic::ty::*;

 use syntax::ast::{self, BinOpKind, Expr, MetaItem};
 use syntax::ext::base::{Annotatable, ExtCtxt};
 use syntax::ptr::P;
 use syntax::symbol::{sym, Symbol};
 use syntax_pos::Span;

 pub fn expand_deriving_partial_ord(cx: &mut ExtCtxt<'_>,
                                    span: Span,
                                    mitem: &MetaItem,
                                    item: &Annotatable,
                                    push: &mut dyn FnMut(Annotatable)) {
     macro_rules! md {
         ($name:expr, $op:expr, $equal:expr) => { {
             let inline = cx.meta_word(span, sym::inline);
             let attrs = vec![cx.attribute(inline)];
             MethodDef {
                 name: $name,
                 generics: LifetimeBounds::empty(),
                 explicit_self: borrowed_explicit_self(),
                 args: vec![(borrowed_self(), "other")],
                 ret_ty: Literal(path_local!(bool)),
                 attributes: attrs,
                 is_unsafe: false,
                 unify_fieldless_variants: true,
                 combine_substructure: combine_substructure(Box::new(|cx, span, substr| {
                     cs_op($op, $equal, cx, span, substr)
                 }))
             }
         } }
     }

     let ordering_ty = Literal(path_std!(cx, cmp::Ordering));
     let ret_ty = Literal(Path::new_(pathvec_std!(cx, option::Option),
                                     None,
                                     vec![Box::new(ordering_ty)],
                                     PathKind::Std));

     let inline = cx.meta_word(span, sym::inline);
     let attrs = vec![cx.attribute(inline)];

     let partial_cmp_def = MethodDef {
         name: "partial_cmp",
         generics: LifetimeBounds::empty(),
         explicit_self: borrowed_explicit_self(),
         args: vec![(borrowed_self(), "other")],
         ret_ty,
         attributes: attrs,
         is_unsafe: false,
         unify_fieldless_variants: true,
         combine_substructure: combine_substructure(Box::new(|cx, span, substr| {
             cs_partial_cmp(cx, span, substr)
         })),
     };

     // avoid defining extra methods if we can
     // c-like enums, enums without any fields and structs without fields
     // can safely define only `partial_cmp`.
     let methods = if is_type_without_fields(item) {
         vec![partial_cmp_def]
     } else {
         vec![partial_cmp_def,
              md!("lt", true, false),
              md!("le", true, true),
              md!("gt", false, false),
              md!("ge", false, true)]
     };

     let trait_def = TraitDef {
         span,
         attributes: vec![],
         path: path_std!(cx, cmp::PartialOrd),
         additional_bounds: vec![],
         generics: LifetimeBounds::empty(),
         is_unsafe: false,
         supports_unions: false,
         methods,
         associated_types: Vec::new(),
     };
     trait_def.expand(cx, mitem, item, push)
 }

 #[derive(Copy, Clone)]
 pub enum OrderingOp {
     PartialCmpOp,
     LtOp,
     LeOp,
     GtOp,
     GeOp,
 }

 pub fn some_ordering_collapsed(cx: &mut ExtCtxt<'_>,
                                span: Span,
                                op: OrderingOp,
                                self_arg_tags: &[ast::Ident])
                                -> P<ast::Expr> {
     let lft = cx.expr_ident(span, self_arg_tags[0]);
     let rgt = cx.expr_addr_of(span, cx.expr_ident(span, self_arg_tags[1]));
     let op_str = match op {
         PartialCmpOp => "partial_cmp",
         LtOp => "lt",
         LeOp => "le",
         GtOp => "gt",
         GeOp => "ge",
     };
     cx.expr_method_call(span, lft, cx.ident_of(op_str), vec![rgt])
 }

 pub fn cs_partial_cmp(cx: &mut ExtCtxt<'_>, span: Span, substr: &Substructure<'_>) -> P<Expr> {
     let test_id = cx.ident_of("cmp").gensym();
     let ordering = cx.path_global(span, cx.std_path(&[sym::cmp, sym::Ordering, sym::Equal]));
     let ordering_expr = cx.expr_path(ordering.clone());
     let equals_expr = cx.expr_some(span, ordering_expr);

     let partial_cmp_path = cx.std_path(&[sym::cmp, sym::PartialOrd, sym::partial_cmp]);

     // Builds:
     //
     // match ::std::cmp::PartialOrd::partial_cmp(&self_field1, &other_field1) {
     // ::std::option::Option::Some(::std::cmp::Ordering::Equal) =>
     // match ::std::cmp::PartialOrd::partial_cmp(&self_field2, &other_field2) {
     // ::std::option::Option::Some(::std::cmp::Ordering::Equal) => {
     // ...
     // }
     // cmp => cmp
     // },
     // cmp => cmp
     // }
     //
     cs_fold(// foldr nests the if-elses correctly, leaving the first field
             // as the outermost one, and the last as the innermost.
             false,
             |cx, span, old, self_f, other_fs| {
                 // match new {
                 //     Some(::std::cmp::Ordering::Equal) => old,
                 //     cmp => cmp
                 // }

                 let new = {
                     let other_f = match other_fs {
                         [o_f] => o_f,
                                 _ => {
                                     cx.span_bug(span,
                                         "not exactly 2 arguments in `derive(PartialOrd)`")
                                 }
                     };

                     let args = vec![
                             cx.expr_addr_of(span, self_f),
                             cx.expr_addr_of(span, other_f.clone()),
                         ];

                     cx.expr_call_global(span, partial_cmp_path.clone(), args)
                 };

                 let eq_arm = cx.arm(span,
                                     vec![cx.pat_some(span, cx.pat_path(span, ordering.clone()))],
                                     old);
                 let neq_arm = cx.arm(span,
                                     vec![cx.pat_ident(span, test_id)],
                                     cx.expr_ident(span, test_id));

                 cx.expr_match(span, new, vec![eq_arm, neq_arm])
             },
             equals_expr,
             Box::new(|cx, span, (self_args, tag_tuple), _non_self_args| {
         if self_args.len() != 2 {
             cx.span_bug(span, "not exactly 2 arguments in `derive(PartialOrd)`")
         } else {
             some_ordering_collapsed(cx, span, PartialCmpOp, tag_tuple)
         }
     }),
             cx,
             span,
             substr)
 }

 /// Strict inequality.
 fn cs_op(less: bool,
          inclusive: bool,
          cx: &mut ExtCtxt<'_>,
          span: Span,
          substr: &Substructure<'_>) -> P<Expr> {
     let ordering_path = |cx: &mut ExtCtxt<'_>, name: &str| {
         cx.expr_path(cx.path_global(
             span, cx.std_path(&[sym::cmp, sym::Ordering, Symbol::intern(name)])))
     };

     let par_cmp = |cx: &mut ExtCtxt<'_>, span, self_f: P<Expr>, other_fs: &[P<Expr>], default| {
         let other_f = match other_fs {
             [o_f] => o_f,
             _ => cx.span_bug(span, "not exactly 2 arguments in `derive(PartialOrd)`"),
         };

         // `PartialOrd::partial_cmp(self.fi, other.fi)`
         let cmp_path = cx.expr_path(cx.path_global(span, cx.std_path(&[sym::cmp,
                                                                        sym::PartialOrd,
                                                                        sym::partial_cmp])));
         let cmp = cx.expr_call(span,
                                cmp_path,
                                vec![cx.expr_addr_of(span, self_f),
                                     cx.expr_addr_of(span, other_f.clone())]);

         let default = ordering_path(cx, default);
         // `Option::unwrap_or(_, Ordering::Equal)`
         let unwrap_path = cx.expr_path(cx.path_global(span, cx.std_path(&[sym::option,
                                                                           sym::Option,
                                                                           sym::unwrap_or])));
         cx.expr_call(span, unwrap_path, vec![cmp, default])
     };

     let fold = cs_fold1(false, // need foldr
         |cx, span, subexpr, self_f, other_fs| {
             // build up a series of `partial_cmp`s from the inside
             // out (hence foldr) to get lexical ordering, i.e., for op ==
             // `ast::lt`
             //
             // ```
             // Ordering::then_with(
             //    Option::unwrap_or(
             //        PartialOrd::partial_cmp(self.f1, other.f1), Ordering::Equal)
             //    ),
             //    Option::unwrap_or(
             //        PartialOrd::partial_cmp(self.f2, other.f2), Ordering::Greater)
             //    )
             // )
             // == Ordering::Less
             // ```
             //
             // and for op ==
             // `ast::le`
             //
             // ```
             // Ordering::then_with(
             //    Option::unwrap_or(
             //        PartialOrd::partial_cmp(self.f1, other.f1), Ordering::Equal)
             //    ),
             //    Option::unwrap_or(
             //        PartialOrd::partial_cmp(self.f2, other.f2), Ordering::Greater)
             //    )
             // )
             // != Ordering::Greater
             // ```
             //
             // The optimiser should remove the redundancy. We explicitly
             // get use the binops to avoid auto-deref dereferencing too many
             // layers of pointers, if the type includes pointers.

             // `Option::unwrap_or(PartialOrd::partial_cmp(self.fi, other.fi), Ordering::Equal)`
             let par_cmp = par_cmp(cx, span, self_f, other_fs, "Equal");

             // `Ordering::then_with(Option::unwrap_or(..), ..)`
             let then_with_path = cx.expr_path(cx.path_global(span,
                                                              cx.std_path(&[sym::cmp,
                                                                            sym::Ordering,
                                                                            sym::then_with])));
             cx.expr_call(span, then_with_path, vec![par_cmp, cx.lambda0(span, subexpr)])
         },
         |cx, args| {
             match args {
                 Some((span, self_f, other_fs)) => {
                     let opposite = if less { "Greater" } else { "Less" };
                     par_cmp(cx, span, self_f, other_fs, opposite)
                 },
                 None => cx.expr_bool(span, inclusive)
             }
         },
         Box::new(|cx, span, (self_args, tag_tuple), _non_self_args| {
             if self_args.len() != 2 {
                 cx.span_bug(span, "not exactly 2 arguments in `derive(PartialOrd)`")
             } else {
                 let op = match (less, inclusive) {
                     (false, false) => GtOp,
                     (false, true) => GeOp,
                     (true, false) => LtOp,
                     (true, true) => LeOp,
                 };
                 some_ordering_collapsed(cx, span, op, tag_tuple)
             }
         }),
         cx,
         span,
         substr);

     match *substr.fields {
         EnumMatching(.., ref all_fields) |
         Struct(.., ref all_fields) if !all_fields.is_empty() => {
             let ordering = ordering_path(cx, if less ^ inclusive { "Less" } else { "Greater" });
             let comp_op = if inclusive { BinOpKind::Ne } else { BinOpKind::Eq };

             cx.expr_binary(span, comp_op, fold, ordering)
         }
         _ => fold
     }
 }
	pub use OrderingOp::*;

	use crate::deriving::{path_local, pathvec_std, path_std};
	use crate::deriving::generic::*;
	use crate::deriving::generic::ty::*;

	use syntax::ast::{self, BinOpKind, Expr, MetaItem};
	use syntax::ext::base::{Annotatable, ExtCtxt};
	use syntax::ptr::P;
	use syntax::symbol::{sym, Symbol};
	use syntax_pos::Span;

	pub fn expand_deriving_partial_ord(cx: &mut ExtCtxt<'_>,
	span: Span,
	mitem: &MetaItem,
	item: &Annotatable,
	push: &mut dyn FnMut(Annotatable)) {
	macro_rules! md {
	($name:expr, $op:expr, $equal:expr) => { {
	let inline = cx.meta_word(span, sym::inline);
	let attrs = vec![cx.attribute(inline)];
	MethodDef {
	name: $name,
	generics: LifetimeBounds::empty(),
	explicit_self: borrowed_explicit_self(),
	args: vec![(borrowed_self(), "other")],
	ret_ty: Literal(path_local!(bool)),
	attributes: attrs,
	is_unsafe: false,
	unify_fieldless_variants: true,
	combine_substructure: combine_substructure(Box::new(\|cx, span, substr\| {
	cs_op($op, $equal, cx, span, substr)
	}))
	}
	} }
	}

	let ordering_ty = Literal(path_std!(cx, cmp::Ordering));
	let ret_ty = Literal(Path::new_(pathvec_std!(cx, option::Option),
	None,
	vec![Box::new(ordering_ty)],
	PathKind::Std));

	let inline = cx.meta_word(span, sym::inline);
	let attrs = vec![cx.attribute(inline)];

	let partial_cmp_def = MethodDef {
	name: "partial_cmp",
	generics: LifetimeBounds::empty(),
	explicit_self: borrowed_explicit_self(),
	args: vec![(borrowed_self(), "other")],
	ret_ty,
	attributes: attrs,
	is_unsafe: false,
	unify_fieldless_variants: true,
	combine_substructure: combine_substructure(Box::new(\|cx, span, substr\| {
	cs_partial_cmp(cx, span, substr)
	})),
	};

	// avoid defining extra methods if we can
	// c-like enums, enums without any fields and structs without fields
	// can safely define only `partial_cmp`.
	let methods = if is_type_without_fields(item) {
	vec![partial_cmp_def]
	} else {
	vec![partial_cmp_def,
	md!("lt", true, false),
	md!("le", true, true),
	md!("gt", false, false),
	md!("ge", false, true)]
	};

	let trait_def = TraitDef {
	span,
	attributes: vec![],
	path: path_std!(cx, cmp::PartialOrd),
	additional_bounds: vec![],
	generics: LifetimeBounds::empty(),
	is_unsafe: false,
	supports_unions: false,
	methods,
	associated_types: Vec::new(),
	};
	trait_def.expand(cx, mitem, item, push)
	}

	#[derive(Copy, Clone)]
	pub enum OrderingOp {
	PartialCmpOp,
	LtOp,
	LeOp,
	GtOp,
	GeOp,
	}

	pub fn some_ordering_collapsed(cx: &mut ExtCtxt<'_>,
	span: Span,
	op: OrderingOp,
	self_arg_tags: &[ast::Ident])
	-> P<ast::Expr> {
	let lft = cx.expr_ident(span, self_arg_tags[0]);
	let rgt = cx.expr_addr_of(span, cx.expr_ident(span, self_arg_tags[1]));
	let op_str = match op {
	PartialCmpOp => "partial_cmp",
	LtOp => "lt",
	LeOp => "le",
	GtOp => "gt",
	GeOp => "ge",
	};
	cx.expr_method_call(span, lft, cx.ident_of(op_str), vec![rgt])
	}

	pub fn cs_partial_cmp(cx: &mut ExtCtxt<'_>, span: Span, substr: &Substructure<'_>) -> P<Expr> {
	let test_id = cx.ident_of("cmp").gensym();
	let ordering = cx.path_global(span, cx.std_path(&[sym::cmp, sym::Ordering, sym::Equal]));
	let ordering_expr = cx.expr_path(ordering.clone());
	let equals_expr = cx.expr_some(span, ordering_expr);

	let partial_cmp_path = cx.std_path(&[sym::cmp, sym::PartialOrd, sym::partial_cmp]);

	// Builds:
	//
	// match ::std::cmp::PartialOrd::partial_cmp(&self_field1, &other_field1) {
	// ::std::option::Option::Some(::std::cmp::Ordering::Equal) =>
	// match ::std::cmp::PartialOrd::partial_cmp(&self_field2, &other_field2) {
	// ::std::option::Option::Some(::std::cmp::Ordering::Equal) => {
	// ...
	// }
	// cmp => cmp
	// },
	// cmp => cmp
	// }
	//
	cs_fold(// foldr nests the if-elses correctly, leaving the first field
	// as the outermost one, and the last as the innermost.
	false,
	\|cx, span, old, self_f, other_fs\| {
	// match new {
	// Some(::std::cmp::Ordering::Equal) => old,
	// cmp => cmp
	// }

	let new = {
	let other_f = match other_fs {
	[o_f] => o_f,
	_ => {
	cx.span_bug(span,
	"not exactly 2 arguments in `derive(PartialOrd)`")
	}
	};

	let args = vec![
	cx.expr_addr_of(span, self_f),
	cx.expr_addr_of(span, other_f.clone()),
	];

	cx.expr_call_global(span, partial_cmp_path.clone(), args)
	};

	let eq_arm = cx.arm(span,
	vec![cx.pat_some(span, cx.pat_path(span, ordering.clone()))],
	old);
	let neq_arm = cx.arm(span,
	vec![cx.pat_ident(span, test_id)],
	cx.expr_ident(span, test_id));

	cx.expr_match(span, new, vec![eq_arm, neq_arm])
	},
	equals_expr,
	Box::new(\|cx, span, (self_args, tag_tuple), _non_self_args\| {
	if self_args.len() != 2 {
	cx.span_bug(span, "not exactly 2 arguments in `derive(PartialOrd)`")
	} else {
	some_ordering_collapsed(cx, span, PartialCmpOp, tag_tuple)
	}
	}),
	cx,
	span,
	substr)
	}

	/// Strict inequality.
	fn cs_op(less: bool,
	inclusive: bool,
	cx: &mut ExtCtxt<'_>,
	span: Span,
	substr: &Substructure<'_>) -> P<Expr> {
	let ordering_path = \|cx: &mut ExtCtxt<'_>, name: &str\| {
	cx.expr_path(cx.path_global(
	span, cx.std_path(&[sym::cmp, sym::Ordering, Symbol::intern(name)])))
	};

	let par_cmp = \|cx: &mut ExtCtxt<'_>, span, self_f: P<Expr>, other_fs: &[P<Expr>], default\| {
	let other_f = match other_fs {
	[o_f] => o_f,
	_ => cx.span_bug(span, "not exactly 2 arguments in `derive(PartialOrd)`"),
	};

	// `PartialOrd::partial_cmp(self.fi, other.fi)`
	let cmp_path = cx.expr_path(cx.path_global(span, cx.std_path(&[sym::cmp,
	sym::PartialOrd,
	sym::partial_cmp])));
	let cmp = cx.expr_call(span,
	cmp_path,
	vec![cx.expr_addr_of(span, self_f),
	cx.expr_addr_of(span, other_f.clone())]);

	let default = ordering_path(cx, default);
	// `Option::unwrap_or(_, Ordering::Equal)`
	let unwrap_path = cx.expr_path(cx.path_global(span, cx.std_path(&[sym::option,
	sym::Option,
	sym::unwrap_or])));
	cx.expr_call(span, unwrap_path, vec![cmp, default])
	};

	let fold = cs_fold1(false, // need foldr
	\|cx, span, subexpr, self_f, other_fs\| {
	// build up a series of `partial_cmp`s from the inside
	// out (hence foldr) to get lexical ordering, i.e., for op ==
	// `ast::lt`
	//
	// ```
	// Ordering::then_with(
	// Option::unwrap_or(
	// PartialOrd::partial_cmp(self.f1, other.f1), Ordering::Equal)
	// ),
	// Option::unwrap_or(
	// PartialOrd::partial_cmp(self.f2, other.f2), Ordering::Greater)
	// )
	// )
	// == Ordering::Less
	// ```
	//
	// and for op ==
	// `ast::le`
	//
	// ```
	// Ordering::then_with(
	// Option::unwrap_or(
	// PartialOrd::partial_cmp(self.f1, other.f1), Ordering::Equal)
	// ),
	// Option::unwrap_or(
	// PartialOrd::partial_cmp(self.f2, other.f2), Ordering::Greater)
	// )
	// )
	// != Ordering::Greater
	// ```
	//
	// The optimiser should remove the redundancy. We explicitly
	// get use the binops to avoid auto-deref dereferencing too many
	// layers of pointers, if the type includes pointers.

	// `Option::unwrap_or(PartialOrd::partial_cmp(self.fi, other.fi), Ordering::Equal)`
	let par_cmp = par_cmp(cx, span, self_f, other_fs, "Equal");

	// `Ordering::then_with(Option::unwrap_or(..), ..)`
	let then_with_path = cx.expr_path(cx.path_global(span,
	cx.std_path(&[sym::cmp,
	sym::Ordering,
	sym::then_with])));
	cx.expr_call(span, then_with_path, vec![par_cmp, cx.lambda0(span, subexpr)])
	},
	\|cx, args\| {
	match args {
	Some((span, self_f, other_fs)) => {
	let opposite = if less { "Greater" } else { "Less" };
	par_cmp(cx, span, self_f, other_fs, opposite)
	},
	None => cx.expr_bool(span, inclusive)
	}
	},
	Box::new(\|cx, span, (self_args, tag_tuple), _non_self_args\| {
	if self_args.len() != 2 {
	cx.span_bug(span, "not exactly 2 arguments in `derive(PartialOrd)`")
	} else {
	let op = match (less, inclusive) {
	(false, false) => GtOp,
	(false, true) => GeOp,
	(true, false) => LtOp,
	(true, true) => LeOp,
	};
	some_ordering_collapsed(cx, span, op, tag_tuple)
	}
	}),
	cx,
	span,
	substr);

	match *substr.fields {
	EnumMatching(.., ref all_fields) \|
	Struct(.., ref all_fields) if !all_fields.is_empty() => {
	let ordering = ordering_path(cx, if less ^ inclusive { "Less" } else { "Greater" });
	let comp_op = if inclusive { BinOpKind::Ne } else { BinOpKind::Eq };

	cx.expr_binary(span, comp_op, fold, ordering)
	}
	_ => fold
	}
	}