use proc_macro2::{Span, TokenStream}; use syn::spanned::Spanned; use syn::{self, Ident, Index, Member}; use bound; use dummy; use fragment::{Fragment, Match, Stmts}; use internals::ast::{Container, Data, Field, Style, Variant}; use internals::{attr, replace_receiver, Ctxt, Derive}; use pretend; use this; pub fn expand_derive_serialize( input: &mut syn::DeriveInput, ) -> Result> { replace_receiver(input); let ctxt = Ctxt::new(); let cont = match Container::from_ast(&ctxt, input, Derive::Serialize) { Some(cont) => cont, None => return Err(ctxt.check().unwrap_err()), }; precondition(&ctxt, &cont); ctxt.check()?; let ident = &cont.ident; let params = Parameters::new(&cont); let (impl_generics, ty_generics, where_clause) = params.generics.split_for_impl(); let body = Stmts(serialize_body(&cont, ¶ms)); let serde = cont.attrs.serde_path(); let impl_block = if let Some(remote) = cont.attrs.remote() { let vis = &input.vis; let used = pretend::pretend_used(&cont, params.is_packed); quote! { impl #impl_generics #ident #ty_generics #where_clause { #vis fn serialize<__S>(__self: &#remote #ty_generics, __serializer: __S) -> #serde::__private::Result<__S::Ok, __S::Error> where __S: #serde::Serializer, { #used #body } } } } else { quote! { #[automatically_derived] impl #impl_generics #serde::Serialize for #ident #ty_generics #where_clause { fn serialize<__S>(&self, __serializer: __S) -> #serde::__private::Result<__S::Ok, __S::Error> where __S: #serde::Serializer, { #body } } } }; Ok(dummy::wrap_in_const( cont.attrs.custom_serde_path(), "SERIALIZE", ident, impl_block, )) } fn precondition(cx: &Ctxt, cont: &Container) { match cont.attrs.identifier() { attr::Identifier::No => {} attr::Identifier::Field => { cx.error_spanned_by(cont.original, "field identifiers cannot be serialized"); } attr::Identifier::Variant => { cx.error_spanned_by(cont.original, "variant identifiers cannot be serialized"); } } } struct Parameters { /// Variable holding the value being serialized. Either `self` for local /// types or `__self` for remote types. self_var: Ident, /// Path to the type the impl is for. Either a single `Ident` for local /// types (does not include generic parameters) or `some::remote::Path` for /// remote types. this_type: syn::Path, /// Same as `this_type` but using `::` for generic parameters for use in /// expression position. this_value: syn::Path, /// Generics including any explicit and inferred bounds for the impl. generics: syn::Generics, /// Type has a `serde(remote = "...")` attribute. is_remote: bool, /// Type has a repr(packed) attribute. is_packed: bool, } impl Parameters { fn new(cont: &Container) -> Self { let is_remote = cont.attrs.remote().is_some(); let self_var = if is_remote { Ident::new("__self", Span::call_site()) } else { Ident::new("self", Span::call_site()) }; let this_type = this::this_type(cont); let this_value = this::this_value(cont); let is_packed = cont.attrs.is_packed(); let generics = build_generics(cont); Parameters { self_var, this_type, this_value, generics, is_remote, is_packed, } } /// Type name to use in error messages and `&'static str` arguments to /// various Serializer methods. fn type_name(&self) -> String { self.this_type.segments.last().unwrap().ident.to_string() } } // All the generics in the input, plus a bound `T: Serialize` for each generic // field type that will be serialized by us. fn build_generics(cont: &Container) -> syn::Generics { let generics = bound::without_defaults(cont.generics); let generics = bound::with_where_predicates_from_fields(cont, &generics, attr::Field::ser_bound); let generics = bound::with_where_predicates_from_variants(cont, &generics, attr::Variant::ser_bound); match cont.attrs.ser_bound() { Some(predicates) => bound::with_where_predicates(&generics, predicates), None => bound::with_bound( cont, &generics, needs_serialize_bound, &parse_quote!(_serde::Serialize), ), } } // Fields with a `skip_serializing` or `serialize_with` attribute, or which // belong to a variant with a 'skip_serializing` or `serialize_with` attribute, // are not serialized by us so we do not generate a bound. Fields with a `bound` // attribute specify their own bound so we do not generate one. All other fields // may need a `T: Serialize` bound where T is the type of the field. fn needs_serialize_bound(field: &attr::Field, variant: Option<&attr::Variant>) -> bool { !field.skip_serializing() && field.serialize_with().is_none() && field.ser_bound().is_none() && variant.map_or(true, |variant| { !variant.skip_serializing() && variant.serialize_with().is_none() && variant.ser_bound().is_none() }) } fn serialize_body(cont: &Container, params: &Parameters) -> Fragment { if cont.attrs.transparent() { serialize_transparent(cont, params) } else if let Some(type_into) = cont.attrs.type_into() { serialize_into(params, type_into) } else { match &cont.data { Data::Enum(variants) => serialize_enum(params, variants, &cont.attrs), Data::Struct(Style::Struct, fields) => serialize_struct(params, fields, &cont.attrs), Data::Struct(Style::Tuple, fields) => { serialize_tuple_struct(params, fields, &cont.attrs) } Data::Struct(Style::Newtype, fields) => { serialize_newtype_struct(params, &fields[0], &cont.attrs) } Data::Struct(Style::Unit, _) => serialize_unit_struct(&cont.attrs), } } } fn serialize_transparent(cont: &Container, params: &Parameters) -> Fragment { let fields = match &cont.data { Data::Struct(_, fields) => fields, Data::Enum(_) => unreachable!(), }; let self_var = ¶ms.self_var; let transparent_field = fields.iter().find(|f| f.attrs.transparent()).unwrap(); let member = &transparent_field.member; let path = match transparent_field.attrs.serialize_with() { Some(path) => quote!(#path), None => { let span = transparent_field.original.span(); quote_spanned!(span=> _serde::Serialize::serialize) } }; quote_block! { #path(&#self_var.#member, __serializer) } } fn serialize_into(params: &Parameters, type_into: &syn::Type) -> Fragment { let self_var = ¶ms.self_var; quote_block! { _serde::Serialize::serialize( &_serde::__private::Into::<#type_into>::into(_serde::__private::Clone::clone(#self_var)), __serializer) } } fn serialize_unit_struct(cattrs: &attr::Container) -> Fragment { let type_name = cattrs.name().serialize_name(); quote_expr! { _serde::Serializer::serialize_unit_struct(__serializer, #type_name) } } fn serialize_newtype_struct( params: &Parameters, field: &Field, cattrs: &attr::Container, ) -> Fragment { let type_name = cattrs.name().serialize_name(); let mut field_expr = get_member( params, field, &Member::Unnamed(Index { index: 0, span: Span::call_site(), }), ); if let Some(path) = field.attrs.serialize_with() { field_expr = wrap_serialize_field_with(params, field.ty, path, &field_expr); } let span = field.original.span(); let func = quote_spanned!(span=> _serde::Serializer::serialize_newtype_struct); quote_expr! { #func(__serializer, #type_name, #field_expr) } } fn serialize_tuple_struct( params: &Parameters, fields: &[Field], cattrs: &attr::Container, ) -> Fragment { let serialize_stmts = serialize_tuple_struct_visitor(fields, params, false, &TupleTrait::SerializeTupleStruct); let type_name = cattrs.name().serialize_name(); let mut serialized_fields = fields .iter() .enumerate() .filter(|(_, field)| !field.attrs.skip_serializing()) .peekable(); let let_mut = mut_if(serialized_fields.peek().is_some()); let len = serialized_fields .map(|(i, field)| match field.attrs.skip_serializing_if() { None => quote!(1), Some(path) => { let index = syn::Index { index: i as u32, span: Span::call_site(), }; let field_expr = get_member(params, field, &Member::Unnamed(index)); quote!(if #path(#field_expr) { 0 } else { 1 }) } }) .fold(quote!(0), |sum, expr| quote!(#sum + #expr)); quote_block! { let #let_mut __serde_state = try!(_serde::Serializer::serialize_tuple_struct(__serializer, #type_name, #len)); #(#serialize_stmts)* _serde::ser::SerializeTupleStruct::end(__serde_state) } } fn serialize_struct(params: &Parameters, fields: &[Field], cattrs: &attr::Container) -> Fragment { assert!(fields.len() as u64 <= u64::from(u32::max_value())); if cattrs.has_flatten() { serialize_struct_as_map(params, fields, cattrs) } else { serialize_struct_as_struct(params, fields, cattrs) } } fn serialize_struct_tag_field(cattrs: &attr::Container, struct_trait: &StructTrait) -> TokenStream { match cattrs.tag() { attr::TagType::Internal { tag } => { let type_name = cattrs.name().serialize_name(); let func = struct_trait.serialize_field(Span::call_site()); quote! { try!(#func(&mut __serde_state, #tag, #type_name)); } } _ => quote! {}, } } fn serialize_struct_as_struct( params: &Parameters, fields: &[Field], cattrs: &attr::Container, ) -> Fragment { let serialize_fields = serialize_struct_visitor(fields, params, false, &StructTrait::SerializeStruct); let type_name = cattrs.name().serialize_name(); let tag_field = serialize_struct_tag_field(cattrs, &StructTrait::SerializeStruct); let tag_field_exists = !tag_field.is_empty(); let mut serialized_fields = fields .iter() .filter(|&field| !field.attrs.skip_serializing()) .peekable(); let let_mut = mut_if(serialized_fields.peek().is_some() || tag_field_exists); let len = serialized_fields .map(|field| match field.attrs.skip_serializing_if() { None => quote!(1), Some(path) => { let field_expr = get_member(params, field, &field.member); quote!(if #path(#field_expr) { 0 } else { 1 }) } }) .fold( quote!(#tag_field_exists as usize), |sum, expr| quote!(#sum + #expr), ); quote_block! { let #let_mut __serde_state = try!(_serde::Serializer::serialize_struct(__serializer, #type_name, #len)); #tag_field #(#serialize_fields)* _serde::ser::SerializeStruct::end(__serde_state) } } fn serialize_struct_as_map( params: &Parameters, fields: &[Field], cattrs: &attr::Container, ) -> Fragment { let serialize_fields = serialize_struct_visitor(fields, params, false, &StructTrait::SerializeMap); let tag_field = serialize_struct_tag_field(cattrs, &StructTrait::SerializeMap); let tag_field_exists = !tag_field.is_empty(); let mut serialized_fields = fields .iter() .filter(|&field| !field.attrs.skip_serializing()) .peekable(); let let_mut = mut_if(serialized_fields.peek().is_some() || tag_field_exists); let len = if cattrs.has_flatten() { quote!(_serde::__private::None) } else { let len = serialized_fields .map(|field| match field.attrs.skip_serializing_if() { None => quote!(1), Some(path) => { let field_expr = get_member(params, field, &field.member); quote!(if #path(#field_expr) { 0 } else { 1 }) } }) .fold( quote!(#tag_field_exists as usize), |sum, expr| quote!(#sum + #expr), ); quote!(_serde::__private::Some(#len)) }; quote_block! { let #let_mut __serde_state = try!(_serde::Serializer::serialize_map(__serializer, #len)); #tag_field #(#serialize_fields)* _serde::ser::SerializeMap::end(__serde_state) } } fn serialize_enum(params: &Parameters, variants: &[Variant], cattrs: &attr::Container) -> Fragment { assert!(variants.len() as u64 <= u64::from(u32::max_value())); let self_var = ¶ms.self_var; let arms: Vec<_> = variants .iter() .enumerate() .map(|(variant_index, variant)| { serialize_variant(params, variant, variant_index as u32, cattrs) }) .collect(); quote_expr! { match *#self_var { #(#arms)* } } } fn serialize_variant( params: &Parameters, variant: &Variant, variant_index: u32, cattrs: &attr::Container, ) -> TokenStream { let this_value = ¶ms.this_value; let variant_ident = &variant.ident; if variant.attrs.skip_serializing() { let skipped_msg = format!( "the enum variant {}::{} cannot be serialized", params.type_name(), variant_ident ); let skipped_err = quote! { _serde::__private::Err(_serde::ser::Error::custom(#skipped_msg)) }; let fields_pat = match variant.style { Style::Unit => quote!(), Style::Newtype | Style::Tuple => quote!((..)), Style::Struct => quote!({ .. }), }; quote! { #this_value::#variant_ident #fields_pat => #skipped_err, } } else { // variant wasn't skipped let case = match variant.style { Style::Unit => { quote! { #this_value::#variant_ident } } Style::Newtype => { quote! { #this_value::#variant_ident(ref __field0) } } Style::Tuple => { let field_names = (0..variant.fields.len()) .map(|i| Ident::new(&format!("__field{}", i), Span::call_site())); quote! { #this_value::#variant_ident(#(ref #field_names),*) } } Style::Struct => { let members = variant.fields.iter().map(|f| &f.member); quote! { #this_value::#variant_ident { #(ref #members),* } } } }; let body = Match(match cattrs.tag() { attr::TagType::External => { serialize_externally_tagged_variant(params, variant, variant_index, cattrs) } attr::TagType::Internal { tag } => { serialize_internally_tagged_variant(params, variant, cattrs, tag) } attr::TagType::Adjacent { tag, content } => { serialize_adjacently_tagged_variant(params, variant, cattrs, tag, content) } attr::TagType::None => serialize_untagged_variant(params, variant, cattrs), }); quote! { #case => #body } } } fn serialize_externally_tagged_variant( params: &Parameters, variant: &Variant, variant_index: u32, cattrs: &attr::Container, ) -> Fragment { let type_name = cattrs.name().serialize_name(); let variant_name = variant.attrs.name().serialize_name(); if let Some(path) = variant.attrs.serialize_with() { let ser = wrap_serialize_variant_with(params, path, variant); return quote_expr! { _serde::Serializer::serialize_newtype_variant( __serializer, #type_name, #variant_index, #variant_name, #ser, ) }; } match effective_style(variant) { Style::Unit => { quote_expr! { _serde::Serializer::serialize_unit_variant( __serializer, #type_name, #variant_index, #variant_name, ) } } Style::Newtype => { let field = &variant.fields[0]; let mut field_expr = quote!(__field0); if let Some(path) = field.attrs.serialize_with() { field_expr = wrap_serialize_field_with(params, field.ty, path, &field_expr); } let span = field.original.span(); let func = quote_spanned!(span=> _serde::Serializer::serialize_newtype_variant); quote_expr! { #func( __serializer, #type_name, #variant_index, #variant_name, #field_expr, ) } } Style::Tuple => serialize_tuple_variant( TupleVariant::ExternallyTagged { type_name, variant_index, variant_name, }, params, &variant.fields, ), Style::Struct => serialize_struct_variant( StructVariant::ExternallyTagged { variant_index, variant_name, }, params, &variant.fields, &type_name, ), } } fn serialize_internally_tagged_variant( params: &Parameters, variant: &Variant, cattrs: &attr::Container, tag: &str, ) -> Fragment { let type_name = cattrs.name().serialize_name(); let variant_name = variant.attrs.name().serialize_name(); let enum_ident_str = params.type_name(); let variant_ident_str = variant.ident.to_string(); if let Some(path) = variant.attrs.serialize_with() { let ser = wrap_serialize_variant_with(params, path, variant); return quote_expr! { _serde::__private::ser::serialize_tagged_newtype( __serializer, #enum_ident_str, #variant_ident_str, #tag, #variant_name, #ser, ) }; } match effective_style(variant) { Style::Unit => { quote_block! { let mut __struct = try!(_serde::Serializer::serialize_struct( __serializer, #type_name, 1)); try!(_serde::ser::SerializeStruct::serialize_field( &mut __struct, #tag, #variant_name)); _serde::ser::SerializeStruct::end(__struct) } } Style::Newtype => { let field = &variant.fields[0]; let mut field_expr = quote!(__field0); if let Some(path) = field.attrs.serialize_with() { field_expr = wrap_serialize_field_with(params, field.ty, path, &field_expr); } let span = field.original.span(); let func = quote_spanned!(span=> _serde::__private::ser::serialize_tagged_newtype); quote_expr! { #func( __serializer, #enum_ident_str, #variant_ident_str, #tag, #variant_name, #field_expr, ) } } Style::Struct => serialize_struct_variant( StructVariant::InternallyTagged { tag, variant_name }, params, &variant.fields, &type_name, ), Style::Tuple => unreachable!("checked in serde_derive_internals"), } } fn serialize_adjacently_tagged_variant( params: &Parameters, variant: &Variant, cattrs: &attr::Container, tag: &str, content: &str, ) -> Fragment { let this_type = ¶ms.this_type; let type_name = cattrs.name().serialize_name(); let variant_name = variant.attrs.name().serialize_name(); let inner = Stmts(if let Some(path) = variant.attrs.serialize_with() { let ser = wrap_serialize_variant_with(params, path, variant); quote_expr! { _serde::Serialize::serialize(#ser, __serializer) } } else { match effective_style(variant) { Style::Unit => { return quote_block! { let mut __struct = try!(_serde::Serializer::serialize_struct( __serializer, #type_name, 1)); try!(_serde::ser::SerializeStruct::serialize_field( &mut __struct, #tag, #variant_name)); _serde::ser::SerializeStruct::end(__struct) }; } Style::Newtype => { let field = &variant.fields[0]; let mut field_expr = quote!(__field0); if let Some(path) = field.attrs.serialize_with() { field_expr = wrap_serialize_field_with(params, field.ty, path, &field_expr); } let span = field.original.span(); let func = quote_spanned!(span=> _serde::ser::SerializeStruct::serialize_field); return quote_block! { let mut __struct = try!(_serde::Serializer::serialize_struct( __serializer, #type_name, 2)); try!(_serde::ser::SerializeStruct::serialize_field( &mut __struct, #tag, #variant_name)); try!(#func( &mut __struct, #content, #field_expr)); _serde::ser::SerializeStruct::end(__struct) }; } Style::Tuple => { serialize_tuple_variant(TupleVariant::Untagged, params, &variant.fields) } Style::Struct => serialize_struct_variant( StructVariant::Untagged, params, &variant.fields, &variant_name, ), } }); let fields_ty = variant.fields.iter().map(|f| &f.ty); let fields_ident: &Vec<_> = &match variant.style { Style::Unit => { if variant.attrs.serialize_with().is_some() { vec![] } else { unreachable!() } } Style::Newtype => vec![Member::Named(Ident::new("__field0", Span::call_site()))], Style::Tuple => (0..variant.fields.len()) .map(|i| Member::Named(Ident::new(&format!("__field{}", i), Span::call_site()))) .collect(), Style::Struct => variant.fields.iter().map(|f| f.member.clone()).collect(), }; let (_, ty_generics, where_clause) = params.generics.split_for_impl(); let wrapper_generics = if fields_ident.is_empty() { params.generics.clone() } else { bound::with_lifetime_bound(¶ms.generics, "'__a") }; let (wrapper_impl_generics, wrapper_ty_generics, _) = wrapper_generics.split_for_impl(); quote_block! { struct __AdjacentlyTagged #wrapper_generics #where_clause { data: (#(&'__a #fields_ty,)*), phantom: _serde::__private::PhantomData<#this_type #ty_generics>, } impl #wrapper_impl_generics _serde::Serialize for __AdjacentlyTagged #wrapper_ty_generics #where_clause { fn serialize<__S>(&self, __serializer: __S) -> _serde::__private::Result<__S::Ok, __S::Error> where __S: _serde::Serializer, { // Elements that have skip_serializing will be unused. #[allow(unused_variables)] let (#(#fields_ident,)*) = self.data; #inner } } let mut __struct = try!(_serde::Serializer::serialize_struct( __serializer, #type_name, 2)); try!(_serde::ser::SerializeStruct::serialize_field( &mut __struct, #tag, #variant_name)); try!(_serde::ser::SerializeStruct::serialize_field( &mut __struct, #content, &__AdjacentlyTagged { data: (#(#fields_ident,)*), phantom: _serde::__private::PhantomData::<#this_type #ty_generics>, })); _serde::ser::SerializeStruct::end(__struct) } } fn serialize_untagged_variant( params: &Parameters, variant: &Variant, cattrs: &attr::Container, ) -> Fragment { if let Some(path) = variant.attrs.serialize_with() { let ser = wrap_serialize_variant_with(params, path, variant); return quote_expr! { _serde::Serialize::serialize(#ser, __serializer) }; } match effective_style(variant) { Style::Unit => { quote_expr! { _serde::Serializer::serialize_unit(__serializer) } } Style::Newtype => { let field = &variant.fields[0]; let mut field_expr = quote!(__field0); if let Some(path) = field.attrs.serialize_with() { field_expr = wrap_serialize_field_with(params, field.ty, path, &field_expr); } let span = field.original.span(); let func = quote_spanned!(span=> _serde::Serialize::serialize); quote_expr! { #func(#field_expr, __serializer) } } Style::Tuple => serialize_tuple_variant(TupleVariant::Untagged, params, &variant.fields), Style::Struct => { let type_name = cattrs.name().serialize_name(); serialize_struct_variant(StructVariant::Untagged, params, &variant.fields, &type_name) } } } enum TupleVariant { ExternallyTagged { type_name: String, variant_index: u32, variant_name: String, }, Untagged, } fn serialize_tuple_variant( context: TupleVariant, params: &Parameters, fields: &[Field], ) -> Fragment { let tuple_trait = match context { TupleVariant::ExternallyTagged { .. } => TupleTrait::SerializeTupleVariant, TupleVariant::Untagged => TupleTrait::SerializeTuple, }; let serialize_stmts = serialize_tuple_struct_visitor(fields, params, true, &tuple_trait); let mut serialized_fields = fields .iter() .enumerate() .filter(|(_, field)| !field.attrs.skip_serializing()) .peekable(); let let_mut = mut_if(serialized_fields.peek().is_some()); let len = serialized_fields .map(|(i, field)| match field.attrs.skip_serializing_if() { None => quote!(1), Some(path) => { let field_expr = Ident::new(&format!("__field{}", i), Span::call_site()); quote!(if #path(#field_expr) { 0 } else { 1 }) } }) .fold(quote!(0), |sum, expr| quote!(#sum + #expr)); match context { TupleVariant::ExternallyTagged { type_name, variant_index, variant_name, } => { quote_block! { let #let_mut __serde_state = try!(_serde::Serializer::serialize_tuple_variant( __serializer, #type_name, #variant_index, #variant_name, #len)); #(#serialize_stmts)* _serde::ser::SerializeTupleVariant::end(__serde_state) } } TupleVariant::Untagged => { quote_block! { let #let_mut __serde_state = try!(_serde::Serializer::serialize_tuple( __serializer, #len)); #(#serialize_stmts)* _serde::ser::SerializeTuple::end(__serde_state) } } } } enum StructVariant<'a> { ExternallyTagged { variant_index: u32, variant_name: String, }, InternallyTagged { tag: &'a str, variant_name: String, }, Untagged, } fn serialize_struct_variant( context: StructVariant, params: &Parameters, fields: &[Field], name: &str, ) -> Fragment { if fields.iter().any(|field| field.attrs.flatten()) { return serialize_struct_variant_with_flatten(context, params, fields, name); } let struct_trait = match context { StructVariant::ExternallyTagged { .. } => StructTrait::SerializeStructVariant, StructVariant::InternallyTagged { .. } | StructVariant::Untagged => { StructTrait::SerializeStruct } }; let serialize_fields = serialize_struct_visitor(fields, params, true, &struct_trait); let mut serialized_fields = fields .iter() .filter(|&field| !field.attrs.skip_serializing()) .peekable(); let let_mut = mut_if(serialized_fields.peek().is_some()); let len = serialized_fields .map(|field| { let member = &field.member; match field.attrs.skip_serializing_if() { Some(path) => quote!(if #path(#member) { 0 } else { 1 }), None => quote!(1), } }) .fold(quote!(0), |sum, expr| quote!(#sum + #expr)); match context { StructVariant::ExternallyTagged { variant_index, variant_name, } => { quote_block! { let #let_mut __serde_state = try!(_serde::Serializer::serialize_struct_variant( __serializer, #name, #variant_index, #variant_name, #len, )); #(#serialize_fields)* _serde::ser::SerializeStructVariant::end(__serde_state) } } StructVariant::InternallyTagged { tag, variant_name } => { quote_block! { let mut __serde_state = try!(_serde::Serializer::serialize_struct( __serializer, #name, #len + 1, )); try!(_serde::ser::SerializeStruct::serialize_field( &mut __serde_state, #tag, #variant_name, )); #(#serialize_fields)* _serde::ser::SerializeStruct::end(__serde_state) } } StructVariant::Untagged => { quote_block! { let #let_mut __serde_state = try!(_serde::Serializer::serialize_struct( __serializer, #name, #len, )); #(#serialize_fields)* _serde::ser::SerializeStruct::end(__serde_state) } } } } fn serialize_struct_variant_with_flatten( context: StructVariant, params: &Parameters, fields: &[Field], name: &str, ) -> Fragment { let struct_trait = StructTrait::SerializeMap; let serialize_fields = serialize_struct_visitor(fields, params, true, &struct_trait); let mut serialized_fields = fields .iter() .filter(|&field| !field.attrs.skip_serializing()) .peekable(); let let_mut = mut_if(serialized_fields.peek().is_some()); match context { StructVariant::ExternallyTagged { variant_index, variant_name, } => { let this_type = ¶ms.this_type; let fields_ty = fields.iter().map(|f| &f.ty); let members = &fields.iter().map(|f| &f.member).collect::>(); let (_, ty_generics, where_clause) = params.generics.split_for_impl(); let wrapper_generics = bound::with_lifetime_bound(¶ms.generics, "'__a"); let (wrapper_impl_generics, wrapper_ty_generics, _) = wrapper_generics.split_for_impl(); quote_block! { struct __EnumFlatten #wrapper_generics #where_clause { data: (#(&'__a #fields_ty,)*), phantom: _serde::__private::PhantomData<#this_type #ty_generics>, } impl #wrapper_impl_generics _serde::Serialize for __EnumFlatten #wrapper_ty_generics #where_clause { fn serialize<__S>(&self, __serializer: __S) -> _serde::__private::Result<__S::Ok, __S::Error> where __S: _serde::Serializer, { let (#(#members,)*) = self.data; let #let_mut __serde_state = try!(_serde::Serializer::serialize_map( __serializer, _serde::__private::None)); #(#serialize_fields)* _serde::ser::SerializeMap::end(__serde_state) } } _serde::Serializer::serialize_newtype_variant( __serializer, #name, #variant_index, #variant_name, &__EnumFlatten { data: (#(#members,)*), phantom: _serde::__private::PhantomData::<#this_type #ty_generics>, }) } } StructVariant::InternallyTagged { tag, variant_name } => { quote_block! { let #let_mut __serde_state = try!(_serde::Serializer::serialize_map( __serializer, _serde::__private::None)); try!(_serde::ser::SerializeMap::serialize_entry( &mut __serde_state, #tag, #variant_name, )); #(#serialize_fields)* _serde::ser::SerializeMap::end(__serde_state) } } StructVariant::Untagged => { quote_block! { let #let_mut __serde_state = try!(_serde::Serializer::serialize_map( __serializer, _serde::__private::None)); #(#serialize_fields)* _serde::ser::SerializeMap::end(__serde_state) } } } } fn serialize_tuple_struct_visitor( fields: &[Field], params: &Parameters, is_enum: bool, tuple_trait: &TupleTrait, ) -> Vec { fields .iter() .enumerate() .filter(|(_, field)| !field.attrs.skip_serializing()) .map(|(i, field)| { let mut field_expr = if is_enum { let id = Ident::new(&format!("__field{}", i), Span::call_site()); quote!(#id) } else { get_member( params, field, &Member::Unnamed(Index { index: i as u32, span: Span::call_site(), }), ) }; let skip = field .attrs .skip_serializing_if() .map(|path| quote!(#path(#field_expr))); if let Some(path) = field.attrs.serialize_with() { field_expr = wrap_serialize_field_with(params, field.ty, path, &field_expr); } let span = field.original.span(); let func = tuple_trait.serialize_element(span); let ser = quote! { try!(#func(&mut __serde_state, #field_expr)); }; match skip { None => ser, Some(skip) => quote!(if !#skip { #ser }), } }) .collect() } fn serialize_struct_visitor( fields: &[Field], params: &Parameters, is_enum: bool, struct_trait: &StructTrait, ) -> Vec { fields .iter() .filter(|&field| !field.attrs.skip_serializing()) .map(|field| { let member = &field.member; let mut field_expr = if is_enum { quote!(#member) } else { get_member(params, field, member) }; let key_expr = field.attrs.name().serialize_name(); let skip = field .attrs .skip_serializing_if() .map(|path| quote!(#path(#field_expr))); if let Some(path) = field.attrs.serialize_with() { field_expr = wrap_serialize_field_with(params, field.ty, path, &field_expr); } let span = field.original.span(); let ser = if field.attrs.flatten() { let func = quote_spanned!(span=> _serde::Serialize::serialize); quote! { try!(#func(&#field_expr, _serde::__private::ser::FlatMapSerializer(&mut __serde_state))); } } else { let func = struct_trait.serialize_field(span); quote! { try!(#func(&mut __serde_state, #key_expr, #field_expr)); } }; match skip { None => ser, Some(skip) => { if let Some(skip_func) = struct_trait.skip_field(span) { quote! { if !#skip { #ser } else { try!(#skip_func(&mut __serde_state, #key_expr)); } } } else { quote! { if !#skip { #ser } } } } } }) .collect() } fn wrap_serialize_field_with( params: &Parameters, field_ty: &syn::Type, serialize_with: &syn::ExprPath, field_expr: &TokenStream, ) -> TokenStream { wrap_serialize_with(params, serialize_with, &[field_ty], &[quote!(#field_expr)]) } fn wrap_serialize_variant_with( params: &Parameters, serialize_with: &syn::ExprPath, variant: &Variant, ) -> TokenStream { let field_tys: Vec<_> = variant.fields.iter().map(|field| field.ty).collect(); let field_exprs: Vec<_> = variant .fields .iter() .map(|field| { let id = match &field.member { Member::Named(ident) => ident.clone(), Member::Unnamed(member) => { Ident::new(&format!("__field{}", member.index), Span::call_site()) } }; quote!(#id) }) .collect(); wrap_serialize_with( params, serialize_with, field_tys.as_slice(), field_exprs.as_slice(), ) } fn wrap_serialize_with( params: &Parameters, serialize_with: &syn::ExprPath, field_tys: &[&syn::Type], field_exprs: &[TokenStream], ) -> TokenStream { let this_type = ¶ms.this_type; let (_, ty_generics, where_clause) = params.generics.split_for_impl(); let wrapper_generics = if field_exprs.is_empty() { params.generics.clone() } else { bound::with_lifetime_bound(¶ms.generics, "'__a") }; let (wrapper_impl_generics, wrapper_ty_generics, _) = wrapper_generics.split_for_impl(); let field_access = (0..field_exprs.len()).map(|n| { Member::Unnamed(Index { index: n as u32, span: Span::call_site(), }) }); quote!({ struct __SerializeWith #wrapper_impl_generics #where_clause { values: (#(&'__a #field_tys, )*), phantom: _serde::__private::PhantomData<#this_type #ty_generics>, } impl #wrapper_impl_generics _serde::Serialize for __SerializeWith #wrapper_ty_generics #where_clause { fn serialize<__S>(&self, __s: __S) -> _serde::__private::Result<__S::Ok, __S::Error> where __S: _serde::Serializer, { #serialize_with(#(self.values.#field_access, )* __s) } } &__SerializeWith { values: (#(#field_exprs, )*), phantom: _serde::__private::PhantomData::<#this_type #ty_generics>, } }) } // Serialization of an empty struct results in code like: // // let mut __serde_state = try!(serializer.serialize_struct("S", 0)); // _serde::ser::SerializeStruct::end(__serde_state) // // where we want to omit the `mut` to avoid a warning. fn mut_if(is_mut: bool) -> Option { if is_mut { Some(quote!(mut)) } else { None } } fn get_member(params: &Parameters, field: &Field, member: &Member) -> TokenStream { let self_var = ¶ms.self_var; match (params.is_remote, field.attrs.getter()) { (false, None) => { if params.is_packed { quote!(&{#self_var.#member}) } else { quote!(&#self_var.#member) } } (true, None) => { let inner = if params.is_packed { quote!(&{#self_var.#member}) } else { quote!(&#self_var.#member) }; let ty = field.ty; quote!(_serde::__private::ser::constrain::<#ty>(#inner)) } (true, Some(getter)) => { let ty = field.ty; quote!(_serde::__private::ser::constrain::<#ty>(&#getter(#self_var))) } (false, Some(_)) => { unreachable!("getter is only allowed for remote impls"); } } } fn effective_style(variant: &Variant) -> Style { match variant.style { Style::Newtype if variant.fields[0].attrs.skip_serializing() => Style::Unit, other => other, } } enum StructTrait { SerializeMap, SerializeStruct, SerializeStructVariant, } impl StructTrait { fn serialize_field(&self, span: Span) -> TokenStream { match *self { StructTrait::SerializeMap => { quote_spanned!(span=> _serde::ser::SerializeMap::serialize_entry) } StructTrait::SerializeStruct => { quote_spanned!(span=> _serde::ser::SerializeStruct::serialize_field) } StructTrait::SerializeStructVariant => { quote_spanned!(span=> _serde::ser::SerializeStructVariant::serialize_field) } } } fn skip_field(&self, span: Span) -> Option { match *self { StructTrait::SerializeMap => None, StructTrait::SerializeStruct => { Some(quote_spanned!(span=> _serde::ser::SerializeStruct::skip_field)) } StructTrait::SerializeStructVariant => { Some(quote_spanned!(span=> _serde::ser::SerializeStructVariant::skip_field)) } } } } enum TupleTrait { SerializeTuple, SerializeTupleStruct, SerializeTupleVariant, } impl TupleTrait { fn serialize_element(&self, span: Span) -> TokenStream { match *self { TupleTrait::SerializeTuple => { quote_spanned!(span=> _serde::ser::SerializeTuple::serialize_element) } TupleTrait::SerializeTupleStruct => { quote_spanned!(span=> _serde::ser::SerializeTupleStruct::serialize_field) } TupleTrait::SerializeTupleVariant => { quote_spanned!(span=> _serde::ser::SerializeTupleVariant::serialize_field) } } } }