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

 //! The compiler code necessary to implement the `#[derive(Encodable)]`
 //! (and `Decodable`, in `decodable.rs`) extension. The idea here is that
 //! type-defining items may be tagged with `#[derive(Encodable, Decodable)]`.
 //!
 //! For example, a type like:
 //!
 //! ```
 //! #[derive(Encodable, Decodable)]
 //! struct Node { id: usize }
 //! ```
 //!
 //! would generate two implementations like:
 //!
 //! ```
 //! # struct Node { id: usize }
 //! impl<S: Encoder<E>, E> Encodable<S, E> for Node {
 //!     fn encode(&self, s: &mut S) -> Result<(), E> {
 //!         s.emit_struct("Node", 1, |this| {
 //!             this.emit_struct_field("id", 0, |this| {
 //!                 Encodable::encode(&self.id, this)
 //!                 /* this.emit_usize(self.id) can also be used */
 //!             })
 //!         })
 //!     }
 //! }
 //!
 //! impl<D: Decoder<E>, E> Decodable<D, E> for Node {
 //!     fn decode(d: &mut D) -> Result<Node, E> {
 //!         d.read_struct("Node", 1, |this| {
 //!             match this.read_struct_field("id", 0, |this| Decodable::decode(this)) {
 //!                 Ok(id) => Ok(Node { id: id }),
 //!                 Err(e) => Err(e),
 //!             }
 //!         })
 //!     }
 //! }
 //! ```
 //!
 //! Other interesting scenarios are when the item has type parameters or
 //! references other non-built-in types. A type definition like:
 //!
 //! ```
 //! # #[derive(Encodable, Decodable)] struct Span;
 //! #[derive(Encodable, Decodable)]
 //! struct Spanned<T> { node: T, span: Span }
 //! ```
 //!
 //! would yield functions like:
 //!
 //! ```
 //! # #[derive(Encodable, Decodable)] struct Span;
 //! # struct Spanned<T> { node: T, span: Span }
 //! impl<
 //!     S: Encoder<E>,
 //!     E,
 //!     T: Encodable<S, E>
 //! > Encodable<S, E> for Spanned<T> {
 //!     fn encode(&self, s: &mut S) -> Result<(), E> {
 //!         s.emit_struct("Spanned", 2, |this| {
 //!             this.emit_struct_field("node", 0, |this| self.node.encode(this))
 //!                 .unwrap();
 //!             this.emit_struct_field("span", 1, |this| self.span.encode(this))
 //!         })
 //!     }
 //! }
 //!
 //! impl<
 //!     D: Decoder<E>,
 //!     E,
 //!     T: Decodable<D, E>
 //! > Decodable<D, E> for Spanned<T> {
 //!     fn decode(d: &mut D) -> Result<Spanned<T>, E> {
 //!         d.read_struct("Spanned", 2, |this| {
 //!             Ok(Spanned {
 //!                 node: this.read_struct_field("node", 0, |this| Decodable::decode(this))
 //!                     .unwrap(),
 //!                 span: this.read_struct_field("span", 1, |this| Decodable::decode(this))
 //!                     .unwrap(),
 //!             })
 //!         })
 //!     }
 //! }
 //! ```

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

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

 pub fn expand_deriving_rustc_encodable(cx: &mut ExtCtxt<'_>,
                                        span: Span,
                                        mitem: &MetaItem,
                                        item: &Annotatable,
                                        push: &mut dyn FnMut(Annotatable)) {
     let krate = "rustc_serialize";
     let typaram = &*deriving::hygienic_type_parameter(item, "__S");

     let trait_def = TraitDef {
         span,
         attributes: Vec::new(),
         path: Path::new_(vec![krate, "Encodable"], None, vec![], PathKind::Global),
         additional_bounds: Vec::new(),
         generics: LifetimeBounds::empty(),
         is_unsafe: false,
         supports_unions: false,
         methods: vec![
             MethodDef {
                 name: "encode",
                 generics: LifetimeBounds {
                     lifetimes: Vec::new(),
                     bounds: vec![
                         (typaram,
                          vec![Path::new_(vec![krate, "Encoder"], None, vec![], PathKind::Global)])
                     ],
                 },
                 explicit_self: borrowed_explicit_self(),
                 args: vec![(Ptr(Box::new(Literal(Path::new_local(typaram))),
                            Borrowed(None, Mutability::Mutable)), "s")],
                 ret_ty: Literal(Path::new_(
                     pathvec_std!(cx, result::Result),
                     None,
                     vec![Box::new(Tuple(Vec::new())), Box::new(Literal(Path::new_(
                         vec![typaram, "Error"], None, vec![], PathKind::Local
                     )))],
                     PathKind::Std
                 )),
                 attributes: Vec::new(),
                 is_unsafe: false,
                 unify_fieldless_variants: false,
                 combine_substructure: combine_substructure(Box::new(|a, b, c| {
                     encodable_substructure(a, b, c, krate)
                 })),
             }
         ],
         associated_types: Vec::new(),
     };

     trait_def.expand(cx, mitem, item, push)
 }

 fn encodable_substructure(cx: &mut ExtCtxt<'_>,
                           trait_span: Span,
                           substr: &Substructure<'_>,
                           krate: &'static str)
                           -> P<Expr> {
     let encoder = substr.nonself_args[0].clone();
     // throw an underscore in front to suppress unused variable warnings
     let blkarg = cx.ident_of("_e");
     let blkencoder = cx.expr_ident(trait_span, blkarg);
     let fn_path = cx.expr_path(cx.path_global(trait_span,
                                               vec![cx.ident_of(krate),
                                                    cx.ident_of("Encodable"),
                                                    cx.ident_of("encode")]));

     return match *substr.fields {
         Struct(_, ref fields) => {
             let emit_struct_field = cx.ident_of("emit_struct_field");
             let mut stmts = Vec::new();
             for (i, &FieldInfo { name, ref self_, span, .. }) in fields.iter().enumerate() {
                 let name = match name {
                     Some(id) => id.name,
                     None => Symbol::intern(&format!("_field{}", i)),
                 };
                 let self_ref = cx.expr_addr_of(span, self_.clone());
                 let enc = cx.expr_call(span, fn_path.clone(), vec![self_ref, blkencoder.clone()]);
                 let lambda = cx.lambda1(span, enc, blkarg);
                 let call = cx.expr_method_call(span,
                                                blkencoder.clone(),
                                                emit_struct_field,
                                                vec![cx.expr_str(span, name),
                                                     cx.expr_usize(span, i),
                                                     lambda]);

                 // last call doesn't need a try!
                 let last = fields.len() - 1;
                 let call = if i != last {
                     cx.expr_try(span, call)
                 } else {
                     cx.expr(span, ExprKind::Ret(Some(call)))
                 };

                 let stmt = cx.stmt_expr(call);
                 stmts.push(stmt);
             }

             // unit structs have no fields and need to return Ok()
             let blk = if stmts.is_empty() {
                 let ok = cx.expr_ok(trait_span, cx.expr_tuple(trait_span, vec![]));
                 cx.lambda1(trait_span, ok, blkarg)
             } else {
                 cx.lambda_stmts_1(trait_span, stmts, blkarg)
             };

             cx.expr_method_call(trait_span,
                                 encoder,
                                 cx.ident_of("emit_struct"),
                                 vec![cx.expr_str(trait_span, substr.type_ident.name),
                                      cx.expr_usize(trait_span, fields.len()),
                                      blk])
         }

         EnumMatching(idx, _, variant, ref fields) => {
             // We're not generating an AST that the borrow checker is expecting,
             // so we need to generate a unique local variable to take the
             // mutable loan out on, otherwise we get conflicts which don't
             // actually exist.
             let me = cx.stmt_let(trait_span, false, blkarg, encoder);
             let encoder = cx.expr_ident(trait_span, blkarg);
             let emit_variant_arg = cx.ident_of("emit_enum_variant_arg");
             let mut stmts = Vec::new();
             if !fields.is_empty() {
                 let last = fields.len() - 1;
                 for (i, &FieldInfo { ref self_, span, .. }) in fields.iter().enumerate() {
                     let self_ref = cx.expr_addr_of(span, self_.clone());
                     let enc =
                         cx.expr_call(span, fn_path.clone(), vec![self_ref, blkencoder.clone()]);
                     let lambda = cx.lambda1(span, enc, blkarg);
                     let call = cx.expr_method_call(span,
                                                    blkencoder.clone(),
                                                    emit_variant_arg,
                                                    vec![cx.expr_usize(span, i), lambda]);
                     let call = if i != last {
                         cx.expr_try(span, call)
                     } else {
                         cx.expr(span, ExprKind::Ret(Some(call)))
                     };
                     stmts.push(cx.stmt_expr(call));
                 }
             } else {
                 let ok = cx.expr_ok(trait_span, cx.expr_tuple(trait_span, vec![]));
                 let ret_ok = cx.expr(trait_span, ExprKind::Ret(Some(ok)));
                 stmts.push(cx.stmt_expr(ret_ok));
             }

             let blk = cx.lambda_stmts_1(trait_span, stmts, blkarg);
             let name = cx.expr_str(trait_span, variant.ident.name);
             let call = cx.expr_method_call(trait_span,
                                            blkencoder,
                                            cx.ident_of("emit_enum_variant"),
                                            vec![name,
                                                 cx.expr_usize(trait_span, idx),
                                                 cx.expr_usize(trait_span, fields.len()),
                                                 blk]);
             let blk = cx.lambda1(trait_span, call, blkarg);
             let ret = cx.expr_method_call(trait_span,
                                           encoder,
                                           cx.ident_of("emit_enum"),
                                           vec![cx.expr_str(trait_span ,substr.type_ident.name),
                                                blk]);
             cx.expr_block(cx.block(trait_span, vec![me, cx.stmt_expr(ret)]))
         }

         _ => cx.bug("expected Struct or EnumMatching in derive(Encodable)"),
     };
 }
	//! The compiler code necessary to implement the `#[derive(Encodable)]`
	//! (and `Decodable`, in `decodable.rs`) extension. The idea here is that
	//! type-defining items may be tagged with `#[derive(Encodable, Decodable)]`.
	//!
	//! For example, a type like:
	//!
	//! ```
	//! #[derive(Encodable, Decodable)]
	//! struct Node { id: usize }
	//! ```
	//!
	//! would generate two implementations like:
	//!
	//! ```
	//! # struct Node { id: usize }
	//! impl<S: Encoder<E>, E> Encodable<S, E> for Node {
	//! fn encode(&self, s: &mut S) -> Result<(), E> {
	//! s.emit_struct("Node", 1, \|this\| {
	//! this.emit_struct_field("id", 0, \|this\| {
	//! Encodable::encode(&self.id, this)
	//! /* this.emit_usize(self.id) can also be used */
	//! })
	//! })
	//! }
	//! }
	//!
	//! impl<D: Decoder<E>, E> Decodable<D, E> for Node {
	//! fn decode(d: &mut D) -> Result<Node, E> {
	//! d.read_struct("Node", 1, \|this\| {
	//! match this.read_struct_field("id", 0, \|this\| Decodable::decode(this)) {
	//! Ok(id) => Ok(Node { id: id }),
	//! Err(e) => Err(e),
	//! }
	//! })
	//! }
	//! }
	//! ```
	//!
	//! Other interesting scenarios are when the item has type parameters or
	//! references other non-built-in types. A type definition like:
	//!
	//! ```
	//! # #[derive(Encodable, Decodable)] struct Span;
	//! #[derive(Encodable, Decodable)]
	//! struct Spanned<T> { node: T, span: Span }
	//! ```
	//!
	//! would yield functions like:
	//!
	//! ```
	//! # #[derive(Encodable, Decodable)] struct Span;
	//! # struct Spanned<T> { node: T, span: Span }
	//! impl<
	//! S: Encoder<E>,
	//! E,
	//! T: Encodable<S, E>
	//! > Encodable<S, E> for Spanned<T> {
	//! fn encode(&self, s: &mut S) -> Result<(), E> {
	//! s.emit_struct("Spanned", 2, \|this\| {
	//! this.emit_struct_field("node", 0, \|this\| self.node.encode(this))
	//! .unwrap();
	//! this.emit_struct_field("span", 1, \|this\| self.span.encode(this))
	//! })
	//! }
	//! }
	//!
	//! impl<
	//! D: Decoder<E>,
	//! E,
	//! T: Decodable<D, E>
	//! > Decodable<D, E> for Spanned<T> {
	//! fn decode(d: &mut D) -> Result<Spanned<T>, E> {
	//! d.read_struct("Spanned", 2, \|this\| {
	//! Ok(Spanned {
	//! node: this.read_struct_field("node", 0, \|this\| Decodable::decode(this))
	//! .unwrap(),
	//! span: this.read_struct_field("span", 1, \|this\| Decodable::decode(this))
	//! .unwrap(),
	//! })
	//! })
	//! }
	//! }
	//! ```

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

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

	pub fn expand_deriving_rustc_encodable(cx: &mut ExtCtxt<'_>,
	span: Span,
	mitem: &MetaItem,
	item: &Annotatable,
	push: &mut dyn FnMut(Annotatable)) {
	let krate = "rustc_serialize";
	let typaram = &*deriving::hygienic_type_parameter(item, "__S");

	let trait_def = TraitDef {
	span,
	attributes: Vec::new(),
	path: Path::new_(vec![krate, "Encodable"], None, vec![], PathKind::Global),
	additional_bounds: Vec::new(),
	generics: LifetimeBounds::empty(),
	is_unsafe: false,
	supports_unions: false,
	methods: vec![
	MethodDef {
	name: "encode",
	generics: LifetimeBounds {
	lifetimes: Vec::new(),
	bounds: vec![
	(typaram,
	vec![Path::new_(vec![krate, "Encoder"], None, vec![], PathKind::Global)])
	],
	},
	explicit_self: borrowed_explicit_self(),
	args: vec![(Ptr(Box::new(Literal(Path::new_local(typaram))),
	Borrowed(None, Mutability::Mutable)), "s")],
	ret_ty: Literal(Path::new_(
	pathvec_std!(cx, result::Result),
	None,
	vec![Box::new(Tuple(Vec::new())), Box::new(Literal(Path::new_(
	vec![typaram, "Error"], None, vec![], PathKind::Local
	)))],
	PathKind::Std
	)),
	attributes: Vec::new(),
	is_unsafe: false,
	unify_fieldless_variants: false,
	combine_substructure: combine_substructure(Box::new(\|a, b, c\| {
	encodable_substructure(a, b, c, krate)
	})),
	}
	],
	associated_types: Vec::new(),
	};

	trait_def.expand(cx, mitem, item, push)
	}

	fn encodable_substructure(cx: &mut ExtCtxt<'_>,
	trait_span: Span,
	substr: &Substructure<'_>,
	krate: &'static str)
	-> P<Expr> {
	let encoder = substr.nonself_args[0].clone();
	// throw an underscore in front to suppress unused variable warnings
	let blkarg = cx.ident_of("_e");
	let blkencoder = cx.expr_ident(trait_span, blkarg);
	let fn_path = cx.expr_path(cx.path_global(trait_span,
	vec![cx.ident_of(krate),
	cx.ident_of("Encodable"),
	cx.ident_of("encode")]));

	return match *substr.fields {
	Struct(_, ref fields) => {
	let emit_struct_field = cx.ident_of("emit_struct_field");
	let mut stmts = Vec::new();
	for (i, &FieldInfo { name, ref self_, span, .. }) in fields.iter().enumerate() {
	let name = match name {
	Some(id) => id.name,
	None => Symbol::intern(&format!("_field{}", i)),
	};
	let self_ref = cx.expr_addr_of(span, self_.clone());
	let enc = cx.expr_call(span, fn_path.clone(), vec![self_ref, blkencoder.clone()]);
	let lambda = cx.lambda1(span, enc, blkarg);
	let call = cx.expr_method_call(span,
	blkencoder.clone(),
	emit_struct_field,
	vec![cx.expr_str(span, name),
	cx.expr_usize(span, i),
	lambda]);

	// last call doesn't need a try!
	let last = fields.len() - 1;
	let call = if i != last {
	cx.expr_try(span, call)
	} else {
	cx.expr(span, ExprKind::Ret(Some(call)))
	};

	let stmt = cx.stmt_expr(call);
	stmts.push(stmt);
	}

	// unit structs have no fields and need to return Ok()
	let blk = if stmts.is_empty() {
	let ok = cx.expr_ok(trait_span, cx.expr_tuple(trait_span, vec![]));
	cx.lambda1(trait_span, ok, blkarg)
	} else {
	cx.lambda_stmts_1(trait_span, stmts, blkarg)
	};

	cx.expr_method_call(trait_span,
	encoder,
	cx.ident_of("emit_struct"),
	vec![cx.expr_str(trait_span, substr.type_ident.name),
	cx.expr_usize(trait_span, fields.len()),
	blk])
	}

	EnumMatching(idx, _, variant, ref fields) => {
	// We're not generating an AST that the borrow checker is expecting,
	// so we need to generate a unique local variable to take the
	// mutable loan out on, otherwise we get conflicts which don't
	// actually exist.
	let me = cx.stmt_let(trait_span, false, blkarg, encoder);
	let encoder = cx.expr_ident(trait_span, blkarg);
	let emit_variant_arg = cx.ident_of("emit_enum_variant_arg");
	let mut stmts = Vec::new();
	if !fields.is_empty() {
	let last = fields.len() - 1;
	for (i, &FieldInfo { ref self_, span, .. }) in fields.iter().enumerate() {
	let self_ref = cx.expr_addr_of(span, self_.clone());
	let enc =
	cx.expr_call(span, fn_path.clone(), vec![self_ref, blkencoder.clone()]);
	let lambda = cx.lambda1(span, enc, blkarg);
	let call = cx.expr_method_call(span,
	blkencoder.clone(),
	emit_variant_arg,
	vec![cx.expr_usize(span, i), lambda]);
	let call = if i != last {
	cx.expr_try(span, call)
	} else {
	cx.expr(span, ExprKind::Ret(Some(call)))
	};
	stmts.push(cx.stmt_expr(call));
	}
	} else {
	let ok = cx.expr_ok(trait_span, cx.expr_tuple(trait_span, vec![]));
	let ret_ok = cx.expr(trait_span, ExprKind::Ret(Some(ok)));
	stmts.push(cx.stmt_expr(ret_ok));
	}

	let blk = cx.lambda_stmts_1(trait_span, stmts, blkarg);
	let name = cx.expr_str(trait_span, variant.ident.name);
	let call = cx.expr_method_call(trait_span,
	blkencoder,
	cx.ident_of("emit_enum_variant"),
	vec![name,
	cx.expr_usize(trait_span, idx),
	cx.expr_usize(trait_span, fields.len()),
	blk]);
	let blk = cx.lambda1(trait_span, call, blkarg);
	let ret = cx.expr_method_call(trait_span,
	encoder,
	cx.ident_of("emit_enum"),
	vec![cx.expr_str(trait_span ,substr.type_ident.name),
	blk]);
	cx.expr_block(cx.block(trait_span, vec![me, cx.stmt_expr(ret)]))
	}

	_ => cx.bug("expected Struct or EnumMatching in derive(Encodable)"),
	};
	}