compiler/rustc_builtin_macros/src/deriving/clone.rs - toolchain/rustc - Git at Google

 use crate::deriving::generic::ty::*;
 use crate::deriving::generic::*;
 use crate::deriving::path_std;
 use rustc_ast::{self as ast, Generics, ItemKind, MetaItem, VariantData};
 use rustc_data_structures::fx::FxHashSet;
 use rustc_expand::base::{Annotatable, ExtCtxt};
 use rustc_span::symbol::{kw, sym, Ident};
 use rustc_span::Span;
 use thin_vec::{thin_vec, ThinVec};

 pub fn expand_deriving_clone(
     cx: &mut ExtCtxt<'_>,
     span: Span,
     mitem: &MetaItem,
     item: &Annotatable,
     push: &mut dyn FnMut(Annotatable),
     is_const: bool,
 ) {
     // The simple form is `fn clone(&self) -> Self { *self }`, possibly with
     // some additional `AssertParamIsClone` assertions.
     //
     // We can use the simple form if either of the following are true.
     // - The type derives Copy and there are no generic parameters. (If we
     //   used the simple form with generics, we'd have to bound the generics
     //   with Clone + Copy, and then there'd be no Clone impl at all if the
     //   user fills in something that is Clone but not Copy. After
     //   specialization we can remove this no-generics limitation.)
     // - The item is a union. (Unions with generic parameters still can derive
     //   Clone because they require Copy for deriving, Clone alone is not
     //   enough. Whether Clone is implemented for fields is irrelevant so we
     //   don't assert it.)
     let bounds;
     let substructure;
     let is_simple;
     match item {
         Annotatable::Item(annitem) => match &annitem.kind {
             ItemKind::Struct(_, Generics { params, .. })
             | ItemKind::Enum(_, Generics { params, .. }) => {
                 let container_id = cx.current_expansion.id.expn_data().parent.expect_local();
                 let has_derive_copy = cx.resolver.has_derive_copy(container_id);
                 if has_derive_copy
                     && !params
                         .iter()
                         .any(|param| matches!(param.kind, ast::GenericParamKind::Type { .. }))
                 {
                     bounds = vec![];
                     is_simple = true;
                     substructure = combine_substructure(Box::new(|c, s, sub| {
                         cs_clone_simple("Clone", c, s, sub, false)
                     }));
                 } else {
                     bounds = vec![];
                     is_simple = false;
                     substructure =
                         combine_substructure(Box::new(|c, s, sub| cs_clone("Clone", c, s, sub)));
                 }
             }
             ItemKind::Union(..) => {
                 bounds = vec![Path(path_std!(marker::Copy))];
                 is_simple = true;
                 substructure = combine_substructure(Box::new(|c, s, sub| {
                     cs_clone_simple("Clone", c, s, sub, true)
                 }));
             }
             _ => cx.span_bug(span, "`#[derive(Clone)]` on wrong item kind"),
         },

         _ => cx.span_bug(span, "`#[derive(Clone)]` on trait item or impl item"),
     }

     let trait_def = TraitDef {
         span,
         path: path_std!(clone::Clone),
         skip_path_as_bound: false,
         needs_copy_as_bound_if_packed: true,
         additional_bounds: bounds,
         supports_unions: true,
         methods: vec![MethodDef {
             name: sym::clone,
             generics: Bounds::empty(),
             explicit_self: true,
             nonself_args: Vec::new(),
             ret_ty: Self_,
             attributes: thin_vec![cx.attr_word(sym::inline, span)],
             fieldless_variants_strategy: FieldlessVariantsStrategy::Default,
             combine_substructure: substructure,
         }],
         associated_types: Vec::new(),
         is_const,
     };

     trait_def.expand_ext(cx, mitem, item, push, is_simple)
 }

 fn cs_clone_simple(
     name: &str,
     cx: &mut ExtCtxt<'_>,
     trait_span: Span,
     substr: &Substructure<'_>,
     is_union: bool,
 ) -> BlockOrExpr {
     let mut stmts = ThinVec::new();
     let mut seen_type_names = FxHashSet::default();
     let mut process_variant = |variant: &VariantData| {
         for field in variant.fields() {
             // This basic redundancy checking only prevents duplication of
             // assertions like `AssertParamIsClone<Foo>` where the type is a
             // simple name. That's enough to get a lot of cases, though.
             if let Some(name) = field.ty.kind.is_simple_path()
                 && !seen_type_names.insert(name)
             {
                 // Already produced an assertion for this type.
             } else {
                 // let _: AssertParamIsClone<FieldTy>;
                 super::assert_ty_bounds(
                     cx,
                     &mut stmts,
                     field.ty.clone(),
                     field.span,
                     &[sym::clone, sym::AssertParamIsClone],
                 );
             }
         }
     };

     if is_union {
         // Just a single assertion for unions, that the union impls `Copy`.
         // let _: AssertParamIsCopy<Self>;
         let self_ty = cx.ty_path(cx.path_ident(trait_span, Ident::with_dummy_span(kw::SelfUpper)));
         super::assert_ty_bounds(
             cx,
             &mut stmts,
             self_ty,
             trait_span,
             &[sym::clone, sym::AssertParamIsCopy],
         );
     } else {
         match *substr.fields {
             StaticStruct(vdata, ..) => {
                 process_variant(vdata);
             }
             StaticEnum(enum_def, ..) => {
                 for variant in &enum_def.variants {
                     process_variant(&variant.data);
                 }
             }
             _ => cx.span_bug(
                 trait_span,
                 format!("unexpected substructure in simple `derive({name})`"),
             ),
         }
     }
     BlockOrExpr::new_mixed(stmts, Some(cx.expr_deref(trait_span, cx.expr_self(trait_span))))
 }

 fn cs_clone(
     name: &str,
     cx: &mut ExtCtxt<'_>,
     trait_span: Span,
     substr: &Substructure<'_>,
 ) -> BlockOrExpr {
     let ctor_path;
     let all_fields;
     let fn_path = cx.std_path(&[sym::clone, sym::Clone, sym::clone]);
     let subcall = |cx: &mut ExtCtxt<'_>, field: &FieldInfo| {
         let args = thin_vec![field.self_expr.clone()];
         cx.expr_call_global(field.span, fn_path.clone(), args)
     };

     let vdata;
     match substr.fields {
         Struct(vdata_, af) => {
             ctor_path = cx.path(trait_span, vec![substr.type_ident]);
             all_fields = af;
             vdata = *vdata_;
         }
         EnumMatching(.., variant, af) => {
             ctor_path = cx.path(trait_span, vec![substr.type_ident, variant.ident]);
             all_fields = af;
             vdata = &variant.data;
         }
         EnumTag(..) | AllFieldlessEnum(..) => {
             cx.span_bug(trait_span, format!("enum tags in `derive({name})`",))
         }
         StaticEnum(..) | StaticStruct(..) => {
             cx.span_bug(trait_span, format!("associated function in `derive({name})`"))
         }
     }

     let expr = match *vdata {
         VariantData::Struct(..) => {
             let fields = all_fields
                 .iter()
                 .map(|field| {
                     let Some(ident) = field.name else {
                         cx.span_bug(
                             trait_span,
                             format!("unnamed field in normal struct in `derive({name})`",),
                         );
                     };
                     let call = subcall(cx, field);
                     cx.field_imm(field.span, ident, call)
                 })
                 .collect::<ThinVec<_>>();

             cx.expr_struct(trait_span, ctor_path, fields)
         }
         VariantData::Tuple(..) => {
             let subcalls = all_fields.iter().map(|f| subcall(cx, f)).collect();
             let path = cx.expr_path(ctor_path);
             cx.expr_call(trait_span, path, subcalls)
         }
         VariantData::Unit(..) => cx.expr_path(ctor_path),
     };
     BlockOrExpr::new_expr(expr)
 }
	use crate::deriving::generic::ty::*;
	use crate::deriving::generic::*;
	use crate::deriving::path_std;
	use rustc_ast::{self as ast, Generics, ItemKind, MetaItem, VariantData};
	use rustc_data_structures::fx::FxHashSet;
	use rustc_expand::base::{Annotatable, ExtCtxt};
	use rustc_span::symbol::{kw, sym, Ident};
	use rustc_span::Span;
	use thin_vec::{thin_vec, ThinVec};

	pub fn expand_deriving_clone(
	cx: &mut ExtCtxt<'_>,
	span: Span,
	mitem: &MetaItem,
	item: &Annotatable,
	push: &mut dyn FnMut(Annotatable),
	is_const: bool,
	) {
	// The simple form is `fn clone(&self) -> Self { *self }`, possibly with
	// some additional `AssertParamIsClone` assertions.
	//
	// We can use the simple form if either of the following are true.
	// - The type derives Copy and there are no generic parameters. (If we
	// used the simple form with generics, we'd have to bound the generics
	// with Clone + Copy, and then there'd be no Clone impl at all if the
	// user fills in something that is Clone but not Copy. After
	// specialization we can remove this no-generics limitation.)
	// - The item is a union. (Unions with generic parameters still can derive
	// Clone because they require Copy for deriving, Clone alone is not
	// enough. Whether Clone is implemented for fields is irrelevant so we
	// don't assert it.)
	let bounds;
	let substructure;
	let is_simple;
	match item {
	Annotatable::Item(annitem) => match &annitem.kind {
	ItemKind::Struct(_, Generics { params, .. })
	\| ItemKind::Enum(_, Generics { params, .. }) => {
	let container_id = cx.current_expansion.id.expn_data().parent.expect_local();
	let has_derive_copy = cx.resolver.has_derive_copy(container_id);
	if has_derive_copy
	&& !params
	.iter()
	.any(\|param\| matches!(param.kind, ast::GenericParamKind::Type { .. }))
	{
	bounds = vec![];
	is_simple = true;
	substructure = combine_substructure(Box::new(\|c, s, sub\| {
	cs_clone_simple("Clone", c, s, sub, false)
	}));
	} else {
	bounds = vec![];
	is_simple = false;
	substructure =
	combine_substructure(Box::new(\|c, s, sub\| cs_clone("Clone", c, s, sub)));
	}
	}
	ItemKind::Union(..) => {
	bounds = vec![Path(path_std!(marker::Copy))];
	is_simple = true;
	substructure = combine_substructure(Box::new(\|c, s, sub\| {
	cs_clone_simple("Clone", c, s, sub, true)
	}));
	}
	_ => cx.span_bug(span, "`#[derive(Clone)]` on wrong item kind"),
	},

	_ => cx.span_bug(span, "`#[derive(Clone)]` on trait item or impl item"),
	}

	let trait_def = TraitDef {
	span,
	path: path_std!(clone::Clone),
	skip_path_as_bound: false,
	needs_copy_as_bound_if_packed: true,
	additional_bounds: bounds,
	supports_unions: true,
	methods: vec![MethodDef {
	name: sym::clone,
	generics: Bounds::empty(),
	explicit_self: true,
	nonself_args: Vec::new(),
	ret_ty: Self_,
	attributes: thin_vec![cx.attr_word(sym::inline, span)],
	fieldless_variants_strategy: FieldlessVariantsStrategy::Default,
	combine_substructure: substructure,
	}],
	associated_types: Vec::new(),
	is_const,
	};

	trait_def.expand_ext(cx, mitem, item, push, is_simple)
	}

	fn cs_clone_simple(
	name: &str,
	cx: &mut ExtCtxt<'_>,
	trait_span: Span,
	substr: &Substructure<'_>,
	is_union: bool,
	) -> BlockOrExpr {
	let mut stmts = ThinVec::new();
	let mut seen_type_names = FxHashSet::default();
	let mut process_variant = \|variant: &VariantData\| {
	for field in variant.fields() {
	// This basic redundancy checking only prevents duplication of
	// assertions like `AssertParamIsClone<Foo>` where the type is a
	// simple name. That's enough to get a lot of cases, though.
	if let Some(name) = field.ty.kind.is_simple_path()
	&& !seen_type_names.insert(name)
	{
	// Already produced an assertion for this type.
	} else {
	// let _: AssertParamIsClone<FieldTy>;
	super::assert_ty_bounds(
	cx,
	&mut stmts,
	field.ty.clone(),
	field.span,
	&[sym::clone, sym::AssertParamIsClone],
	);
	}
	}
	};

	if is_union {
	// Just a single assertion for unions, that the union impls `Copy`.
	// let _: AssertParamIsCopy<Self>;
	let self_ty = cx.ty_path(cx.path_ident(trait_span, Ident::with_dummy_span(kw::SelfUpper)));
	super::assert_ty_bounds(
	cx,
	&mut stmts,
	self_ty,
	trait_span,
	&[sym::clone, sym::AssertParamIsCopy],
	);
	} else {
	match *substr.fields {
	StaticStruct(vdata, ..) => {
	process_variant(vdata);
	}
	StaticEnum(enum_def, ..) => {
	for variant in &enum_def.variants {
	process_variant(&variant.data);
	}
	}
	_ => cx.span_bug(
	trait_span,
	format!("unexpected substructure in simple `derive({name})`"),
	),
	}
	}
	BlockOrExpr::new_mixed(stmts, Some(cx.expr_deref(trait_span, cx.expr_self(trait_span))))
	}

	fn cs_clone(
	name: &str,
	cx: &mut ExtCtxt<'_>,
	trait_span: Span,
	substr: &Substructure<'_>,
	) -> BlockOrExpr {
	let ctor_path;
	let all_fields;
	let fn_path = cx.std_path(&[sym::clone, sym::Clone, sym::clone]);
	let subcall = \|cx: &mut ExtCtxt<'_>, field: &FieldInfo\| {
	let args = thin_vec![field.self_expr.clone()];
	cx.expr_call_global(field.span, fn_path.clone(), args)
	};

	let vdata;
	match substr.fields {
	Struct(vdata_, af) => {
	ctor_path = cx.path(trait_span, vec![substr.type_ident]);
	all_fields = af;
	vdata = *vdata_;
	}
	EnumMatching(.., variant, af) => {
	ctor_path = cx.path(trait_span, vec![substr.type_ident, variant.ident]);
	all_fields = af;
	vdata = &variant.data;
	}
	EnumTag(..) \| AllFieldlessEnum(..) => {
	cx.span_bug(trait_span, format!("enum tags in `derive({name})`",))
	}
	StaticEnum(..) \| StaticStruct(..) => {
	cx.span_bug(trait_span, format!("associated function in `derive({name})`"))
	}
	}

	let expr = match *vdata {
	VariantData::Struct(..) => {
	let fields = all_fields
	.iter()
	.map(\|field\| {
	let Some(ident) = field.name else {
	cx.span_bug(
	trait_span,
	format!("unnamed field in normal struct in `derive({name})`",),
	);
	};
	let call = subcall(cx, field);
	cx.field_imm(field.span, ident, call)
	})
	.collect::<ThinVec<_>>();

	cx.expr_struct(trait_span, ctor_path, fields)
	}
	VariantData::Tuple(..) => {
	let subcalls = all_fields.iter().map(\|f\| subcall(cx, f)).collect();
	let path = cx.expr_path(ctor_path);
	cx.expr_call(trait_span, path, subcalls)
	}
	VariantData::Unit(..) => cx.expr_path(ctor_path),
	};
	BlockOrExpr::new_expr(expr)
	}