//! The compiler code necessary for `#[derive(RustcDecodable)]`. See encodable.rs for more. use crate::deriving::generic::ty::*; use crate::deriving::generic::*; use crate::deriving::pathvec_std; use rustc_ast::ptr::P; use rustc_ast::{self as ast, Expr, MetaItem, Mutability}; use rustc_expand::base::{Annotatable, ExtCtxt}; use rustc_span::symbol::{sym, Ident, Symbol}; use rustc_span::Span; pub fn expand_deriving_rustc_decodable( cx: &mut ExtCtxt<'_>, span: Span, mitem: &MetaItem, item: &Annotatable, push: &mut dyn FnMut(Annotatable), ) { let krate = sym::rustc_serialize; let typaram = sym::__D; let trait_def = TraitDef { span, path: Path::new_(vec![krate, sym::Decodable], vec![], PathKind::Global), additional_bounds: Vec::new(), generics: Bounds::empty(), supports_unions: false, methods: vec![MethodDef { name: sym::decode, generics: Bounds { bounds: vec![( typaram, vec![Path::new_(vec![krate, sym::Decoder], vec![], PathKind::Global)], )], }, explicit_self: false, nonself_args: vec![( Ref(Box::new(Path(Path::new_local(typaram))), Mutability::Mut), sym::d, )], ret_ty: Path(Path::new_( pathvec_std!(result::Result), vec![ Box::new(Self_), Box::new(Path(Path::new_(vec![typaram, sym::Error], vec![], PathKind::Local))), ], PathKind::Std, )), attributes: ast::AttrVec::new(), unify_fieldless_variants: false, combine_substructure: combine_substructure(Box::new(|a, b, c| { decodable_substructure(a, b, c, krate) })), }], associated_types: Vec::new(), }; trait_def.expand(cx, mitem, item, push) } fn decodable_substructure( cx: &mut ExtCtxt<'_>, trait_span: Span, substr: &Substructure<'_>, krate: Symbol, ) -> BlockOrExpr { let decoder = substr.nonselflike_args[0].clone(); let recurse = vec![ Ident::new(krate, trait_span), Ident::new(sym::Decodable, trait_span), Ident::new(sym::decode, trait_span), ]; let exprdecode = cx.expr_path(cx.path_global(trait_span, recurse)); // throw an underscore in front to suppress unused variable warnings let blkarg = Ident::new(sym::_d, trait_span); let blkdecoder = cx.expr_ident(trait_span, blkarg); let expr = match *substr.fields { StaticStruct(_, ref summary) => { let nfields = match *summary { Unnamed(ref fields, _) => fields.len(), Named(ref fields) => fields.len(), }; let fn_read_struct_field_path: Vec<_> = cx.def_site_path(&[sym::rustc_serialize, sym::Decoder, sym::read_struct_field]); let path = cx.path_ident(trait_span, substr.type_ident); let result = decode_static_fields(cx, trait_span, path, summary, |cx, span, name, field| { cx.expr_try( span, cx.expr_call_global( span, fn_read_struct_field_path.clone(), vec![ blkdecoder.clone(), cx.expr_str(span, name), cx.expr_usize(span, field), exprdecode.clone(), ], ), ) }); let result = cx.expr_ok(trait_span, result); let fn_read_struct_path: Vec<_> = cx.def_site_path(&[sym::rustc_serialize, sym::Decoder, sym::read_struct]); cx.expr_call_global( trait_span, fn_read_struct_path, vec![ decoder, cx.expr_str(trait_span, substr.type_ident.name), cx.expr_usize(trait_span, nfields), cx.lambda1(trait_span, result, blkarg), ], ) } StaticEnum(_, ref fields) => { let variant = Ident::new(sym::i, trait_span); let mut arms = Vec::with_capacity(fields.len() + 1); let mut variants = Vec::with_capacity(fields.len()); let fn_read_enum_variant_arg_path: Vec<_> = cx.def_site_path(&[sym::rustc_serialize, sym::Decoder, sym::read_enum_variant_arg]); for (i, &(ident, v_span, ref parts)) in fields.iter().enumerate() { variants.push(cx.expr_str(v_span, ident.name)); let path = cx.path(trait_span, vec![substr.type_ident, ident]); let decoded = decode_static_fields(cx, v_span, path, parts, |cx, span, _, field| { let idx = cx.expr_usize(span, field); cx.expr_try( span, cx.expr_call_global( span, fn_read_enum_variant_arg_path.clone(), vec![blkdecoder.clone(), idx, exprdecode.clone()], ), ) }); arms.push(cx.arm(v_span, cx.pat_lit(v_span, cx.expr_usize(v_span, i)), decoded)); } arms.push(cx.arm_unreachable(trait_span)); let result = cx.expr_ok( trait_span, cx.expr_match(trait_span, cx.expr_ident(trait_span, variant), arms), ); let lambda = cx.lambda(trait_span, vec![blkarg, variant], result); let variant_array_ref = cx.expr_array_ref(trait_span, variants); let fn_read_enum_variant_path: Vec<_> = cx.def_site_path(&[sym::rustc_serialize, sym::Decoder, sym::read_enum_variant]); let result = cx.expr_call_global( trait_span, fn_read_enum_variant_path, vec![blkdecoder, variant_array_ref, lambda], ); let fn_read_enum_path: Vec<_> = cx.def_site_path(&[sym::rustc_serialize, sym::Decoder, sym::read_enum]); cx.expr_call_global( trait_span, fn_read_enum_path, vec![ decoder, cx.expr_str(trait_span, substr.type_ident.name), cx.lambda1(trait_span, result, blkarg), ], ) } _ => cx.bug("expected StaticEnum or StaticStruct in derive(Decodable)"), }; BlockOrExpr::new_expr(expr) } /// Creates a decoder for a single enum variant/struct: /// - `outer_pat_path` is the path to this enum variant/struct /// - `getarg` should retrieve the `usize`-th field with name `@str`. fn decode_static_fields( cx: &mut ExtCtxt<'_>, trait_span: Span, outer_pat_path: ast::Path, fields: &StaticFields, mut getarg: F, ) -> P where F: FnMut(&mut ExtCtxt<'_>, Span, Symbol, usize) -> P, { match *fields { Unnamed(ref fields, is_tuple) => { let path_expr = cx.expr_path(outer_pat_path); if !is_tuple { path_expr } else { let fields = fields .iter() .enumerate() .map(|(i, &span)| getarg(cx, span, Symbol::intern(&format!("_field{}", i)), i)) .collect(); cx.expr_call(trait_span, path_expr, fields) } } Named(ref fields) => { // use the field's span to get nicer error messages. let fields = fields .iter() .enumerate() .map(|(i, &(ident, span))| { let arg = getarg(cx, span, ident.name, i); cx.field_imm(span, ident, arg) }) .collect(); cx.expr_struct(trait_span, outer_pat_path, fields) } } }