use proc_macro2::{Literal, Span, TokenStream}; use quote::ToTokens; use syn::punctuated::Punctuated; use syn::spanned::Spanned; use syn::{self, Ident, Index, Member}; use bound; use dummy; use fragment::{Expr, Fragment, Match, Stmts}; use internals::ast::{Container, Data, Field, Style, Variant}; use internals::{attr, replace_receiver, ungroup, Ctxt, Derive}; use pretend; use this; use std::collections::BTreeSet; use std::ptr; pub fn expand_derive_deserialize(input: &mut syn::DeriveInput) -> syn::Result { replace_receiver(input); let ctxt = Ctxt::new(); let cont = match Container::from_ast(&ctxt, input, Derive::Deserialize) { 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 (de_impl_generics, _, ty_generics, where_clause) = split_with_de_lifetime(¶ms); let body = Stmts(deserialize_body(&cont, ¶ms)); let delife = params.borrowed.de_lifetime(); 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 #de_impl_generics #ident #ty_generics #where_clause { #vis fn deserialize<__D>(__deserializer: __D) -> #serde::__private::Result<#remote #ty_generics, __D::Error> where __D: #serde::Deserializer<#delife>, { #used #body } } } } else { let fn_deserialize_in_place = deserialize_in_place_body(&cont, ¶ms); quote! { #[automatically_derived] impl #de_impl_generics #serde::Deserialize<#delife> for #ident #ty_generics #where_clause { fn deserialize<__D>(__deserializer: __D) -> #serde::__private::Result where __D: #serde::Deserializer<#delife>, { #body } #fn_deserialize_in_place } } }; Ok(dummy::wrap_in_const( cont.attrs.custom_serde_path(), impl_block, )) } fn precondition(cx: &Ctxt, cont: &Container) { precondition_sized(cx, cont); precondition_no_de_lifetime(cx, cont); } fn precondition_sized(cx: &Ctxt, cont: &Container) { if let Data::Struct(_, fields) = &cont.data { if let Some(last) = fields.last() { if let syn::Type::Slice(_) = ungroup(last.ty) { cx.error_spanned_by( cont.original, "cannot deserialize a dynamically sized struct", ); } } } } fn precondition_no_de_lifetime(cx: &Ctxt, cont: &Container) { if let BorrowedLifetimes::Borrowed(_) = borrowed_lifetimes(cont) { for param in cont.generics.lifetimes() { if param.lifetime.to_string() == "'de" { cx.error_spanned_by( ¶m.lifetime, "cannot deserialize when there is a lifetime parameter called 'de", ); return; } } } } struct Parameters { /// Name of the type the `derive` is on. local: syn::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, /// Lifetimes borrowed from the deserializer. These will become bounds on /// the `'de` lifetime of the deserializer. borrowed: BorrowedLifetimes, /// At least one field has a serde(getter) attribute, implying that the /// remote type has a private field. has_getter: bool, /// Type has a repr(packed) attribute. is_packed: bool, } impl Parameters { fn new(cont: &Container) -> Self { let local = cont.ident.clone(); let this_type = this::this_type(cont); let this_value = this::this_value(cont); let borrowed = borrowed_lifetimes(cont); let generics = build_generics(cont, &borrowed); let has_getter = cont.data.has_getter(); let is_packed = cont.attrs.is_packed(); Parameters { local, this_type, this_value, generics, borrowed, has_getter, is_packed, } } /// Type name to use in error messages and `&'static str` arguments to /// various Deserializer 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: Deserialize` for each generic // field type that will be deserialized by us, plus a bound `T: Default` for // each generic field type that will be set to a default value. fn build_generics(cont: &Container, borrowed: &BorrowedLifetimes) -> syn::Generics { let generics = bound::without_defaults(cont.generics); let generics = bound::with_where_predicates_from_fields(cont, &generics, attr::Field::de_bound); let generics = bound::with_where_predicates_from_variants(cont, &generics, attr::Variant::de_bound); match cont.attrs.de_bound() { Some(predicates) => bound::with_where_predicates(&generics, predicates), None => { let generics = match *cont.attrs.default() { attr::Default::Default => bound::with_self_bound( cont, &generics, &parse_quote!(_serde::__private::Default), ), attr::Default::None | attr::Default::Path(_) => generics, }; let delife = borrowed.de_lifetime(); let generics = bound::with_bound( cont, &generics, needs_deserialize_bound, &parse_quote!(_serde::Deserialize<#delife>), ); bound::with_bound( cont, &generics, requires_default, &parse_quote!(_serde::__private::Default), ) } } } // Fields with a `skip_deserializing` or `deserialize_with` attribute, or which // belong to a variant with a `skip_deserializing` or `deserialize_with` // attribute, are not deserialized 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: Deserialize` bound where T is the type of the // field. fn needs_deserialize_bound(field: &attr::Field, variant: Option<&attr::Variant>) -> bool { !field.skip_deserializing() && field.deserialize_with().is_none() && field.de_bound().is_none() && variant.map_or(true, |variant| { !variant.skip_deserializing() && variant.deserialize_with().is_none() && variant.de_bound().is_none() }) } // Fields with a `default` attribute (not `default=...`), and fields with a // `skip_deserializing` attribute that do not also have `default=...`. fn requires_default(field: &attr::Field, _variant: Option<&attr::Variant>) -> bool { if let attr::Default::Default = *field.default() { true } else { false } } enum BorrowedLifetimes { Borrowed(BTreeSet), Static, } impl BorrowedLifetimes { fn de_lifetime(&self) -> syn::Lifetime { match *self { BorrowedLifetimes::Borrowed(_) => syn::Lifetime::new("'de", Span::call_site()), BorrowedLifetimes::Static => syn::Lifetime::new("'static", Span::call_site()), } } fn de_lifetime_param(&self) -> Option { match self { BorrowedLifetimes::Borrowed(bounds) => Some(syn::LifetimeParam { attrs: Vec::new(), lifetime: syn::Lifetime::new("'de", Span::call_site()), colon_token: None, bounds: bounds.iter().cloned().collect(), }), BorrowedLifetimes::Static => None, } } } // The union of lifetimes borrowed by each field of the container. // // These turn into bounds on the `'de` lifetime of the Deserialize impl. If // lifetimes `'a` and `'b` are borrowed but `'c` is not, the impl is: // // impl<'de: 'a + 'b, 'a, 'b, 'c> Deserialize<'de> for S<'a, 'b, 'c> // // If any borrowed lifetime is `'static`, then `'de: 'static` would be redundant // and we use plain `'static` instead of `'de`. fn borrowed_lifetimes(cont: &Container) -> BorrowedLifetimes { let mut lifetimes = BTreeSet::new(); for field in cont.data.all_fields() { if !field.attrs.skip_deserializing() { lifetimes.extend(field.attrs.borrowed_lifetimes().iter().cloned()); } } if lifetimes.iter().any(|b| b.to_string() == "'static") { BorrowedLifetimes::Static } else { BorrowedLifetimes::Borrowed(lifetimes) } } fn deserialize_body(cont: &Container, params: &Parameters) -> Fragment { if cont.attrs.transparent() { deserialize_transparent(cont, params) } else if let Some(type_from) = cont.attrs.type_from() { deserialize_from(type_from) } else if let Some(type_try_from) = cont.attrs.type_try_from() { deserialize_try_from(type_try_from) } else if let attr::Identifier::No = cont.attrs.identifier() { match &cont.data { Data::Enum(variants) => deserialize_enum(params, variants, &cont.attrs), Data::Struct(Style::Struct, fields) => { deserialize_struct(None, params, fields, &cont.attrs, None, &Untagged::No) } Data::Struct(Style::Tuple, fields) | Data::Struct(Style::Newtype, fields) => { deserialize_tuple(None, params, fields, &cont.attrs, None) } Data::Struct(Style::Unit, _) => deserialize_unit_struct(params, &cont.attrs), } } else { match &cont.data { Data::Enum(variants) => deserialize_custom_identifier(params, variants, &cont.attrs), Data::Struct(_, _) => unreachable!("checked in serde_derive_internals"), } } } #[cfg(feature = "deserialize_in_place")] fn deserialize_in_place_body(cont: &Container, params: &Parameters) -> Option { // Only remote derives have getters, and we do not generate // deserialize_in_place for remote derives. assert!(!params.has_getter); if cont.attrs.transparent() || cont.attrs.type_from().is_some() || cont.attrs.type_try_from().is_some() || cont.attrs.identifier().is_some() || cont .data .all_fields() .all(|f| f.attrs.deserialize_with().is_some()) { return None; } let code = match &cont.data { Data::Struct(Style::Struct, fields) => { deserialize_struct_in_place(None, params, fields, &cont.attrs, None)? } Data::Struct(Style::Tuple, fields) | Data::Struct(Style::Newtype, fields) => { deserialize_tuple_in_place(None, params, fields, &cont.attrs, None) } Data::Enum(_) | Data::Struct(Style::Unit, _) => { return None; } }; let delife = params.borrowed.de_lifetime(); let stmts = Stmts(code); let fn_deserialize_in_place = quote_block! { fn deserialize_in_place<__D>(__deserializer: __D, __place: &mut Self) -> _serde::__private::Result<(), __D::Error> where __D: _serde::Deserializer<#delife>, { #stmts } }; Some(Stmts(fn_deserialize_in_place)) } #[cfg(not(feature = "deserialize_in_place"))] fn deserialize_in_place_body(_cont: &Container, _params: &Parameters) -> Option { None } fn deserialize_transparent(cont: &Container, params: &Parameters) -> Fragment { let fields = match &cont.data { Data::Struct(_, fields) => fields, Data::Enum(_) => unreachable!(), }; let this_value = ¶ms.this_value; let transparent_field = fields.iter().find(|f| f.attrs.transparent()).unwrap(); let path = match transparent_field.attrs.deserialize_with() { Some(path) => quote!(#path), None => { let span = transparent_field.original.span(); quote_spanned!(span=> _serde::Deserialize::deserialize) } }; let assign = fields.iter().map(|field| { let member = &field.member; if ptr::eq(field, transparent_field) { quote!(#member: __transparent) } else { let value = match field.attrs.default() { attr::Default::Default => quote!(_serde::__private::Default::default()), attr::Default::Path(path) => quote!(#path()), attr::Default::None => quote!(_serde::__private::PhantomData), }; quote!(#member: #value) } }); quote_block! { _serde::__private::Result::map( #path(__deserializer), |__transparent| #this_value { #(#assign),* }) } } fn deserialize_from(type_from: &syn::Type) -> Fragment { quote_block! { _serde::__private::Result::map( <#type_from as _serde::Deserialize>::deserialize(__deserializer), _serde::__private::From::from) } } fn deserialize_try_from(type_try_from: &syn::Type) -> Fragment { quote_block! { _serde::__private::Result::and_then( <#type_try_from as _serde::Deserialize>::deserialize(__deserializer), |v| _serde::__private::TryFrom::try_from(v).map_err(_serde::de::Error::custom)) } } fn deserialize_unit_struct(params: &Parameters, cattrs: &attr::Container) -> Fragment { let this_type = ¶ms.this_type; let this_value = ¶ms.this_value; let type_name = cattrs.name().deserialize_name(); let expecting = format!("unit struct {}", params.type_name()); let expecting = cattrs.expecting().unwrap_or(&expecting); quote_block! { #[doc(hidden)] struct __Visitor; impl<'de> _serde::de::Visitor<'de> for __Visitor { type Value = #this_type; fn expecting(&self, __formatter: &mut _serde::__private::Formatter) -> _serde::__private::fmt::Result { _serde::__private::Formatter::write_str(__formatter, #expecting) } #[inline] fn visit_unit<__E>(self) -> _serde::__private::Result where __E: _serde::de::Error, { _serde::__private::Ok(#this_value) } } _serde::Deserializer::deserialize_unit_struct(__deserializer, #type_name, __Visitor) } } fn deserialize_tuple( variant_ident: Option<&syn::Ident>, params: &Parameters, fields: &[Field], cattrs: &attr::Container, deserializer: Option, ) -> Fragment { let this_type = ¶ms.this_type; let this_value = ¶ms.this_value; let (de_impl_generics, de_ty_generics, ty_generics, where_clause) = split_with_de_lifetime(params); let delife = params.borrowed.de_lifetime(); assert!(!cattrs.has_flatten()); // If there are getters (implying private fields), construct the local type // and use an `Into` conversion to get the remote type. If there are no // getters then construct the target type directly. let construct = if params.has_getter { let local = ¶ms.local; quote!(#local) } else { quote!(#this_value) }; let is_enum = variant_ident.is_some(); let type_path = match variant_ident { Some(variant_ident) => quote!(#construct::#variant_ident), None => construct, }; let expecting = match variant_ident { Some(variant_ident) => format!("tuple variant {}::{}", params.type_name(), variant_ident), None => format!("tuple struct {}", params.type_name()), }; let expecting = cattrs.expecting().unwrap_or(&expecting); let nfields = fields.len(); let visit_newtype_struct = if !is_enum && nfields == 1 { Some(deserialize_newtype_struct(&type_path, params, &fields[0])) } else { None }; let visit_seq = Stmts(deserialize_seq( &type_path, params, fields, false, cattrs, expecting, )); let visitor_expr = quote! { __Visitor { marker: _serde::__private::PhantomData::<#this_type #ty_generics>, lifetime: _serde::__private::PhantomData, } }; let dispatch = if let Some(deserializer) = deserializer { quote!(_serde::Deserializer::deserialize_tuple(#deserializer, #nfields, #visitor_expr)) } else if is_enum { quote!(_serde::de::VariantAccess::tuple_variant(__variant, #nfields, #visitor_expr)) } else if nfields == 1 { let type_name = cattrs.name().deserialize_name(); quote!(_serde::Deserializer::deserialize_newtype_struct(__deserializer, #type_name, #visitor_expr)) } else { let type_name = cattrs.name().deserialize_name(); quote!(_serde::Deserializer::deserialize_tuple_struct(__deserializer, #type_name, #nfields, #visitor_expr)) }; let all_skipped = fields.iter().all(|field| field.attrs.skip_deserializing()); let visitor_var = if all_skipped { quote!(_) } else { quote!(mut __seq) }; quote_block! { #[doc(hidden)] struct __Visitor #de_impl_generics #where_clause { marker: _serde::__private::PhantomData<#this_type #ty_generics>, lifetime: _serde::__private::PhantomData<&#delife ()>, } impl #de_impl_generics _serde::de::Visitor<#delife> for __Visitor #de_ty_generics #where_clause { type Value = #this_type #ty_generics; fn expecting(&self, __formatter: &mut _serde::__private::Formatter) -> _serde::__private::fmt::Result { _serde::__private::Formatter::write_str(__formatter, #expecting) } #visit_newtype_struct #[inline] fn visit_seq<__A>(self, #visitor_var: __A) -> _serde::__private::Result where __A: _serde::de::SeqAccess<#delife>, { #visit_seq } } #dispatch } } #[cfg(feature = "deserialize_in_place")] fn deserialize_tuple_in_place( variant_ident: Option, params: &Parameters, fields: &[Field], cattrs: &attr::Container, deserializer: Option, ) -> Fragment { let this_type = ¶ms.this_type; let (de_impl_generics, de_ty_generics, ty_generics, where_clause) = split_with_de_lifetime(params); let delife = params.borrowed.de_lifetime(); assert!(!cattrs.has_flatten()); let is_enum = variant_ident.is_some(); let expecting = match variant_ident { Some(variant_ident) => format!("tuple variant {}::{}", params.type_name(), variant_ident), None => format!("tuple struct {}", params.type_name()), }; let expecting = cattrs.expecting().unwrap_or(&expecting); let nfields = fields.len(); let visit_newtype_struct = if !is_enum && nfields == 1 { Some(deserialize_newtype_struct_in_place(params, &fields[0])) } else { None }; let visit_seq = Stmts(deserialize_seq_in_place(params, fields, cattrs, expecting)); let visitor_expr = quote! { __Visitor { place: __place, lifetime: _serde::__private::PhantomData, } }; let dispatch = if let Some(deserializer) = deserializer { quote!(_serde::Deserializer::deserialize_tuple(#deserializer, #nfields, #visitor_expr)) } else if is_enum { quote!(_serde::de::VariantAccess::tuple_variant(__variant, #nfields, #visitor_expr)) } else if nfields == 1 { let type_name = cattrs.name().deserialize_name(); quote!(_serde::Deserializer::deserialize_newtype_struct(__deserializer, #type_name, #visitor_expr)) } else { let type_name = cattrs.name().deserialize_name(); quote!(_serde::Deserializer::deserialize_tuple_struct(__deserializer, #type_name, #nfields, #visitor_expr)) }; let all_skipped = fields.iter().all(|field| field.attrs.skip_deserializing()); let visitor_var = if all_skipped { quote!(_) } else { quote!(mut __seq) }; let in_place_impl_generics = de_impl_generics.in_place(); let in_place_ty_generics = de_ty_generics.in_place(); let place_life = place_lifetime(); quote_block! { #[doc(hidden)] struct __Visitor #in_place_impl_generics #where_clause { place: &#place_life mut #this_type #ty_generics, lifetime: _serde::__private::PhantomData<&#delife ()>, } impl #in_place_impl_generics _serde::de::Visitor<#delife> for __Visitor #in_place_ty_generics #where_clause { type Value = (); fn expecting(&self, __formatter: &mut _serde::__private::Formatter) -> _serde::__private::fmt::Result { _serde::__private::Formatter::write_str(__formatter, #expecting) } #visit_newtype_struct #[inline] fn visit_seq<__A>(self, #visitor_var: __A) -> _serde::__private::Result where __A: _serde::de::SeqAccess<#delife>, { #visit_seq } } #dispatch } } fn deserialize_seq( type_path: &TokenStream, params: &Parameters, fields: &[Field], is_struct: bool, cattrs: &attr::Container, expecting: &str, ) -> Fragment { let vars = (0..fields.len()).map(field_i as fn(_) -> _); let deserialized_count = fields .iter() .filter(|field| !field.attrs.skip_deserializing()) .count(); let expecting = if deserialized_count == 1 { format!("{} with 1 element", expecting) } else { format!("{} with {} elements", expecting, deserialized_count) }; let expecting = cattrs.expecting().unwrap_or(&expecting); let mut index_in_seq = 0_usize; let let_values = vars.clone().zip(fields).map(|(var, field)| { if field.attrs.skip_deserializing() { let default = Expr(expr_is_missing(field, cattrs)); quote! { let #var = #default; } } else { let visit = match field.attrs.deserialize_with() { None => { let field_ty = field.ty; let span = field.original.span(); let func = quote_spanned!(span=> _serde::de::SeqAccess::next_element::<#field_ty>); quote!(try!(#func(&mut __seq))) } Some(path) => { let (wrapper, wrapper_ty) = wrap_deserialize_field_with(params, field.ty, path); quote!({ #wrapper _serde::__private::Option::map( try!(_serde::de::SeqAccess::next_element::<#wrapper_ty>(&mut __seq)), |__wrap| __wrap.value) }) } }; let value_if_none = match field.attrs.default() { attr::Default::Default => quote!(_serde::__private::Default::default()), attr::Default::Path(path) => quote!(#path()), attr::Default::None => quote!( return _serde::__private::Err(_serde::de::Error::invalid_length(#index_in_seq, &#expecting)); ), }; let assign = quote! { let #var = match #visit { _serde::__private::Some(__value) => __value, _serde::__private::None => { #value_if_none } }; }; index_in_seq += 1; assign } }); let mut result = if is_struct { let names = fields.iter().map(|f| &f.member); quote! { #type_path { #( #names: #vars ),* } } } else { quote! { #type_path ( #(#vars),* ) } }; if params.has_getter { let this_type = ¶ms.this_type; let (_, ty_generics, _) = params.generics.split_for_impl(); result = quote! { _serde::__private::Into::<#this_type #ty_generics>::into(#result) }; } let let_default = match cattrs.default() { attr::Default::Default => Some(quote!( let __default: Self::Value = _serde::__private::Default::default(); )), attr::Default::Path(path) => Some(quote!( let __default: Self::Value = #path(); )), attr::Default::None => { // We don't need the default value, to prevent an unused variable warning // we'll leave the line empty. None } }; quote_block! { #let_default #(#let_values)* _serde::__private::Ok(#result) } } #[cfg(feature = "deserialize_in_place")] fn deserialize_seq_in_place( params: &Parameters, fields: &[Field], cattrs: &attr::Container, expecting: &str, ) -> Fragment { let deserialized_count = fields .iter() .filter(|field| !field.attrs.skip_deserializing()) .count(); let expecting = if deserialized_count == 1 { format!("{} with 1 element", expecting) } else { format!("{} with {} elements", expecting, deserialized_count) }; let expecting = cattrs.expecting().unwrap_or(&expecting); let mut index_in_seq = 0usize; let write_values = fields.iter().map(|field| { let member = &field.member; if field.attrs.skip_deserializing() { let default = Expr(expr_is_missing(field, cattrs)); quote! { self.place.#member = #default; } } else { let value_if_none = match field.attrs.default() { attr::Default::Default => quote!( self.place.#member = _serde::__private::Default::default(); ), attr::Default::Path(path) => quote!( self.place.#member = #path(); ), attr::Default::None => quote!( return _serde::__private::Err(_serde::de::Error::invalid_length(#index_in_seq, &#expecting)); ), }; let write = match field.attrs.deserialize_with() { None => { quote! { if let _serde::__private::None = try!(_serde::de::SeqAccess::next_element_seed(&mut __seq, _serde::__private::de::InPlaceSeed(&mut self.place.#member))) { #value_if_none } } } Some(path) => { let (wrapper, wrapper_ty) = wrap_deserialize_field_with(params, field.ty, path); quote!({ #wrapper match try!(_serde::de::SeqAccess::next_element::<#wrapper_ty>(&mut __seq)) { _serde::__private::Some(__wrap) => { self.place.#member = __wrap.value; } _serde::__private::None => { #value_if_none } } }) } }; index_in_seq += 1; write } }); let this_type = ¶ms.this_type; let (_, ty_generics, _) = params.generics.split_for_impl(); let let_default = match cattrs.default() { attr::Default::Default => Some(quote!( let __default: #this_type #ty_generics = _serde::__private::Default::default(); )), attr::Default::Path(path) => Some(quote!( let __default: #this_type #ty_generics = #path(); )), attr::Default::None => { // We don't need the default value, to prevent an unused variable warning // we'll leave the line empty. None } }; quote_block! { #let_default #(#write_values)* _serde::__private::Ok(()) } } fn deserialize_newtype_struct( type_path: &TokenStream, params: &Parameters, field: &Field, ) -> TokenStream { let delife = params.borrowed.de_lifetime(); let field_ty = field.ty; let value = match field.attrs.deserialize_with() { None => { let span = field.original.span(); let func = quote_spanned!(span=> <#field_ty as _serde::Deserialize>::deserialize); quote! { try!(#func(__e)) } } Some(path) => { quote! { try!(#path(__e)) } } }; let mut result = quote!(#type_path(__field0)); if params.has_getter { let this_type = ¶ms.this_type; let (_, ty_generics, _) = params.generics.split_for_impl(); result = quote! { _serde::__private::Into::<#this_type #ty_generics>::into(#result) }; } quote! { #[inline] fn visit_newtype_struct<__E>(self, __e: __E) -> _serde::__private::Result where __E: _serde::Deserializer<#delife>, { let __field0: #field_ty = #value; _serde::__private::Ok(#result) } } } #[cfg(feature = "deserialize_in_place")] fn deserialize_newtype_struct_in_place(params: &Parameters, field: &Field) -> TokenStream { // We do not generate deserialize_in_place if every field has a // deserialize_with. assert!(field.attrs.deserialize_with().is_none()); let delife = params.borrowed.de_lifetime(); quote! { #[inline] fn visit_newtype_struct<__E>(self, __e: __E) -> _serde::__private::Result where __E: _serde::Deserializer<#delife>, { _serde::Deserialize::deserialize_in_place(__e, &mut self.place.0) } } } enum Untagged { Yes, No, } fn deserialize_struct( variant_ident: Option<&syn::Ident>, params: &Parameters, fields: &[Field], cattrs: &attr::Container, deserializer: Option, untagged: &Untagged, ) -> Fragment { let is_enum = variant_ident.is_some(); let this_type = ¶ms.this_type; let this_value = ¶ms.this_value; let (de_impl_generics, de_ty_generics, ty_generics, where_clause) = split_with_de_lifetime(params); let delife = params.borrowed.de_lifetime(); // If there are getters (implying private fields), construct the local type // and use an `Into` conversion to get the remote type. If there are no // getters then construct the target type directly. let construct = if params.has_getter { let local = ¶ms.local; quote!(#local) } else { quote!(#this_value) }; let type_path = match variant_ident { Some(variant_ident) => quote!(#construct::#variant_ident), None => construct, }; let expecting = match variant_ident { Some(variant_ident) => format!("struct variant {}::{}", params.type_name(), variant_ident), None => format!("struct {}", params.type_name()), }; let expecting = cattrs.expecting().unwrap_or(&expecting); let visit_seq = Stmts(deserialize_seq( &type_path, params, fields, true, cattrs, expecting, )); let (field_visitor, fields_stmt, visit_map) = if cattrs.has_flatten() { deserialize_struct_as_map_visitor(&type_path, params, fields, cattrs) } else { deserialize_struct_as_struct_visitor(&type_path, params, fields, cattrs) }; let field_visitor = Stmts(field_visitor); let fields_stmt = fields_stmt.map(Stmts); let visit_map = Stmts(visit_map); let visitor_expr = quote! { __Visitor { marker: _serde::__private::PhantomData::<#this_type #ty_generics>, lifetime: _serde::__private::PhantomData, } }; let need_seed = deserializer.is_none(); let dispatch = if let Some(deserializer) = deserializer { quote! { _serde::Deserializer::deserialize_any(#deserializer, #visitor_expr) } } else if is_enum && cattrs.has_flatten() { quote! { _serde::de::VariantAccess::newtype_variant_seed(__variant, #visitor_expr) } } else if is_enum { quote! { _serde::de::VariantAccess::struct_variant(__variant, FIELDS, #visitor_expr) } } else if cattrs.has_flatten() { quote! { _serde::Deserializer::deserialize_map(__deserializer, #visitor_expr) } } else { let type_name = cattrs.name().deserialize_name(); quote! { _serde::Deserializer::deserialize_struct(__deserializer, #type_name, FIELDS, #visitor_expr) } }; let all_skipped = fields.iter().all(|field| field.attrs.skip_deserializing()); let visitor_var = if all_skipped { quote!(_) } else { quote!(mut __seq) }; // untagged struct variants do not get a visit_seq method. The same applies to // structs that only have a map representation. let visit_seq = match *untagged { Untagged::No if !cattrs.has_flatten() => Some(quote! { #[inline] fn visit_seq<__A>(self, #visitor_var: __A) -> _serde::__private::Result where __A: _serde::de::SeqAccess<#delife>, { #visit_seq } }), _ => None, }; let visitor_seed = if need_seed && is_enum && cattrs.has_flatten() { Some(quote! { impl #de_impl_generics _serde::de::DeserializeSeed<#delife> for __Visitor #de_ty_generics #where_clause { type Value = #this_type #ty_generics; fn deserialize<__D>(self, __deserializer: __D) -> _serde::__private::Result where __D: _serde::Deserializer<#delife>, { _serde::Deserializer::deserialize_map(__deserializer, self) } } }) } else { None }; quote_block! { #field_visitor #[doc(hidden)] struct __Visitor #de_impl_generics #where_clause { marker: _serde::__private::PhantomData<#this_type #ty_generics>, lifetime: _serde::__private::PhantomData<&#delife ()>, } impl #de_impl_generics _serde::de::Visitor<#delife> for __Visitor #de_ty_generics #where_clause { type Value = #this_type #ty_generics; fn expecting(&self, __formatter: &mut _serde::__private::Formatter) -> _serde::__private::fmt::Result { _serde::__private::Formatter::write_str(__formatter, #expecting) } #visit_seq #[inline] fn visit_map<__A>(self, mut __map: __A) -> _serde::__private::Result where __A: _serde::de::MapAccess<#delife>, { #visit_map } } #visitor_seed #fields_stmt #dispatch } } #[cfg(feature = "deserialize_in_place")] fn deserialize_struct_in_place( variant_ident: Option, params: &Parameters, fields: &[Field], cattrs: &attr::Container, deserializer: Option, ) -> Option { let is_enum = variant_ident.is_some(); // for now we do not support in_place deserialization for structs that // are represented as map. if cattrs.has_flatten() { return None; } let this_type = ¶ms.this_type; let (de_impl_generics, de_ty_generics, ty_generics, where_clause) = split_with_de_lifetime(params); let delife = params.borrowed.de_lifetime(); let expecting = match variant_ident { Some(variant_ident) => format!("struct variant {}::{}", params.type_name(), variant_ident), None => format!("struct {}", params.type_name()), }; let expecting = cattrs.expecting().unwrap_or(&expecting); let visit_seq = Stmts(deserialize_seq_in_place(params, fields, cattrs, expecting)); let (field_visitor, fields_stmt, visit_map) = deserialize_struct_as_struct_in_place_visitor(params, fields, cattrs); let field_visitor = Stmts(field_visitor); let fields_stmt = Stmts(fields_stmt); let visit_map = Stmts(visit_map); let visitor_expr = quote! { __Visitor { place: __place, lifetime: _serde::__private::PhantomData, } }; let dispatch = if let Some(deserializer) = deserializer { quote! { _serde::Deserializer::deserialize_any(#deserializer, #visitor_expr) } } else if is_enum { quote! { _serde::de::VariantAccess::struct_variant(__variant, FIELDS, #visitor_expr) } } else { let type_name = cattrs.name().deserialize_name(); quote! { _serde::Deserializer::deserialize_struct(__deserializer, #type_name, FIELDS, #visitor_expr) } }; let all_skipped = fields.iter().all(|field| field.attrs.skip_deserializing()); let visitor_var = if all_skipped { quote!(_) } else { quote!(mut __seq) }; let visit_seq = quote! { #[inline] fn visit_seq<__A>(self, #visitor_var: __A) -> _serde::__private::Result where __A: _serde::de::SeqAccess<#delife>, { #visit_seq } }; let in_place_impl_generics = de_impl_generics.in_place(); let in_place_ty_generics = de_ty_generics.in_place(); let place_life = place_lifetime(); Some(quote_block! { #field_visitor #[doc(hidden)] struct __Visitor #in_place_impl_generics #where_clause { place: &#place_life mut #this_type #ty_generics, lifetime: _serde::__private::PhantomData<&#delife ()>, } impl #in_place_impl_generics _serde::de::Visitor<#delife> for __Visitor #in_place_ty_generics #where_clause { type Value = (); fn expecting(&self, __formatter: &mut _serde::__private::Formatter) -> _serde::__private::fmt::Result { _serde::__private::Formatter::write_str(__formatter, #expecting) } #visit_seq #[inline] fn visit_map<__A>(self, mut __map: __A) -> _serde::__private::Result where __A: _serde::de::MapAccess<#delife>, { #visit_map } } #fields_stmt #dispatch }) } fn deserialize_enum( params: &Parameters, variants: &[Variant], cattrs: &attr::Container, ) -> Fragment { // The variants have already been checked (in ast.rs) that all untagged variants appear at the end match variants.iter().position(|var| var.attrs.untagged()) { Some(variant_idx) => { let (tagged, untagged) = variants.split_at(variant_idx); let tagged_frag = Expr(deserialize_homogeneous_enum(params, tagged, cattrs)); deserialize_untagged_enum_after(params, untagged, cattrs, Some(tagged_frag)) } None => deserialize_homogeneous_enum(params, variants, cattrs), } } fn deserialize_homogeneous_enum( params: &Parameters, variants: &[Variant], cattrs: &attr::Container, ) -> Fragment { match cattrs.tag() { attr::TagType::External => deserialize_externally_tagged_enum(params, variants, cattrs), attr::TagType::Internal { tag } => { deserialize_internally_tagged_enum(params, variants, cattrs, tag) } attr::TagType::Adjacent { tag, content } => { deserialize_adjacently_tagged_enum(params, variants, cattrs, tag, content) } attr::TagType::None => deserialize_untagged_enum(params, variants, cattrs), } } fn prepare_enum_variant_enum( variants: &[Variant], cattrs: &attr::Container, ) -> (TokenStream, Stmts) { let mut deserialized_variants = variants .iter() .enumerate() .filter(|&(_, variant)| !variant.attrs.skip_deserializing()); let variant_names_idents: Vec<_> = deserialized_variants .clone() .map(|(i, variant)| { ( variant.attrs.name().deserialize_name(), field_i(i), variant.attrs.aliases(), ) }) .collect(); let other_idx = deserialized_variants.position(|(_, variant)| variant.attrs.other()); let variants_stmt = { let variant_names = variant_names_idents.iter().map(|(name, _, _)| name); quote! { #[doc(hidden)] const VARIANTS: &'static [&'static str] = &[ #(#variant_names),* ]; } }; let variant_visitor = Stmts(deserialize_generated_identifier( &variant_names_idents, cattrs, true, other_idx, )); (variants_stmt, variant_visitor) } fn deserialize_externally_tagged_enum( params: &Parameters, variants: &[Variant], cattrs: &attr::Container, ) -> Fragment { let this_type = ¶ms.this_type; let (de_impl_generics, de_ty_generics, ty_generics, where_clause) = split_with_de_lifetime(params); let delife = params.borrowed.de_lifetime(); let type_name = cattrs.name().deserialize_name(); let expecting = format!("enum {}", params.type_name()); let expecting = cattrs.expecting().unwrap_or(&expecting); let (variants_stmt, variant_visitor) = prepare_enum_variant_enum(variants, cattrs); // Match arms to extract a variant from a string let variant_arms = variants .iter() .enumerate() .filter(|&(_, variant)| !variant.attrs.skip_deserializing()) .map(|(i, variant)| { let variant_name = field_i(i); let block = Match(deserialize_externally_tagged_variant( params, variant, cattrs, )); quote! { (__Field::#variant_name, __variant) => #block } }); let all_skipped = variants .iter() .all(|variant| variant.attrs.skip_deserializing()); let match_variant = if all_skipped { // This is an empty enum like `enum Impossible {}` or an enum in which // all variants have `#[serde(skip_deserializing)]`. quote! { // FIXME: Once feature(exhaustive_patterns) is stable: // let _serde::__private::Err(__err) = _serde::de::EnumAccess::variant::<__Field>(__data); // _serde::__private::Err(__err) _serde::__private::Result::map( _serde::de::EnumAccess::variant::<__Field>(__data), |(__impossible, _)| match __impossible {}) } } else { quote! { match try!(_serde::de::EnumAccess::variant(__data)) { #(#variant_arms)* } } }; quote_block! { #variant_visitor #[doc(hidden)] struct __Visitor #de_impl_generics #where_clause { marker: _serde::__private::PhantomData<#this_type #ty_generics>, lifetime: _serde::__private::PhantomData<&#delife ()>, } impl #de_impl_generics _serde::de::Visitor<#delife> for __Visitor #de_ty_generics #where_clause { type Value = #this_type #ty_generics; fn expecting(&self, __formatter: &mut _serde::__private::Formatter) -> _serde::__private::fmt::Result { _serde::__private::Formatter::write_str(__formatter, #expecting) } fn visit_enum<__A>(self, __data: __A) -> _serde::__private::Result where __A: _serde::de::EnumAccess<#delife>, { #match_variant } } #variants_stmt _serde::Deserializer::deserialize_enum( __deserializer, #type_name, VARIANTS, __Visitor { marker: _serde::__private::PhantomData::<#this_type #ty_generics>, lifetime: _serde::__private::PhantomData, }, ) } } fn deserialize_internally_tagged_enum( params: &Parameters, variants: &[Variant], cattrs: &attr::Container, tag: &str, ) -> Fragment { let (variants_stmt, variant_visitor) = prepare_enum_variant_enum(variants, cattrs); // Match arms to extract a variant from a string let variant_arms = variants .iter() .enumerate() .filter(|&(_, variant)| !variant.attrs.skip_deserializing()) .map(|(i, variant)| { let variant_name = field_i(i); let block = Match(deserialize_internally_tagged_variant( params, variant, cattrs, quote! { _serde::__private::de::ContentDeserializer::<__D::Error>::new(__tagged.content) }, )); quote! { __Field::#variant_name => #block } }); let expecting = format!("internally tagged enum {}", params.type_name()); let expecting = cattrs.expecting().unwrap_or(&expecting); quote_block! { #variant_visitor #variants_stmt let __tagged = try!(_serde::Deserializer::deserialize_any( __deserializer, _serde::__private::de::TaggedContentVisitor::<__Field>::new(#tag, #expecting))); match __tagged.tag { #(#variant_arms)* } } } fn deserialize_adjacently_tagged_enum( params: &Parameters, variants: &[Variant], cattrs: &attr::Container, tag: &str, content: &str, ) -> Fragment { let this_type = ¶ms.this_type; let this_value = ¶ms.this_value; let (de_impl_generics, de_ty_generics, ty_generics, where_clause) = split_with_de_lifetime(params); let delife = params.borrowed.de_lifetime(); let (variants_stmt, variant_visitor) = prepare_enum_variant_enum(variants, cattrs); let variant_arms: &Vec<_> = &variants .iter() .enumerate() .filter(|&(_, variant)| !variant.attrs.skip_deserializing()) .map(|(i, variant)| { let variant_index = field_i(i); let block = Match(deserialize_untagged_variant( params, variant, cattrs, quote!(__deserializer), )); quote! { __Field::#variant_index => #block } }) .collect(); let expecting = format!("adjacently tagged enum {}", params.type_name()); let expecting = cattrs.expecting().unwrap_or(&expecting); let type_name = cattrs.name().deserialize_name(); let deny_unknown_fields = cattrs.deny_unknown_fields(); // If unknown fields are allowed, we pick the visitor that can step over // those. Otherwise we pick the visitor that fails on unknown keys. let field_visitor_ty = if deny_unknown_fields { quote! { _serde::__private::de::TagOrContentFieldVisitor } } else { quote! { _serde::__private::de::TagContentOtherFieldVisitor } }; let tag_or_content = quote! { #field_visitor_ty { tag: #tag, content: #content, } }; let mut missing_content = quote! { _serde::__private::Err(<__A::Error as _serde::de::Error>::missing_field(#content)) }; let mut missing_content_fallthrough = quote!(); let missing_content_arms = variants .iter() .enumerate() .filter(|&(_, variant)| !variant.attrs.skip_deserializing()) .filter_map(|(i, variant)| { let variant_index = field_i(i); let variant_ident = &variant.ident; let arm = match variant.style { Style::Unit => quote! { _serde::__private::Ok(#this_value::#variant_ident) }, Style::Newtype if variant.attrs.deserialize_with().is_none() => { let span = variant.original.span(); let func = quote_spanned!(span=> _serde::__private::de::missing_field); quote! { #func(#content).map(#this_value::#variant_ident) } } _ => { missing_content_fallthrough = quote!(_ => #missing_content); return None; } }; Some(quote! { __Field::#variant_index => #arm, }) }) .collect::>(); if !missing_content_arms.is_empty() { missing_content = quote! { match __field { #(#missing_content_arms)* #missing_content_fallthrough } }; } // Advance the map by one key, returning early in case of error. let next_key = quote! { try!(_serde::de::MapAccess::next_key_seed(&mut __map, #tag_or_content)) }; // When allowing unknown fields, we want to transparently step through keys // we don't care about until we find `tag`, `content`, or run out of keys. let next_relevant_key = if deny_unknown_fields { next_key } else { quote!({ let mut __rk : _serde::__private::Option<_serde::__private::de::TagOrContentField> = _serde::__private::None; while let _serde::__private::Some(__k) = #next_key { match __k { _serde::__private::de::TagContentOtherField::Other => { let _ = try!(_serde::de::MapAccess::next_value::<_serde::de::IgnoredAny>(&mut __map)); continue; }, _serde::__private::de::TagContentOtherField::Tag => { __rk = _serde::__private::Some(_serde::__private::de::TagOrContentField::Tag); break; } _serde::__private::de::TagContentOtherField::Content => { __rk = _serde::__private::Some(_serde::__private::de::TagOrContentField::Content); break; } } } __rk }) }; // Step through remaining keys, looking for duplicates of previously-seen // keys. When unknown fields are denied, any key that isn't a duplicate will // at this point immediately produce an error. let visit_remaining_keys = quote! { match #next_relevant_key { _serde::__private::Some(_serde::__private::de::TagOrContentField::Tag) => { _serde::__private::Err(<__A::Error as _serde::de::Error>::duplicate_field(#tag)) } _serde::__private::Some(_serde::__private::de::TagOrContentField::Content) => { _serde::__private::Err(<__A::Error as _serde::de::Error>::duplicate_field(#content)) } _serde::__private::None => _serde::__private::Ok(__ret), } }; let finish_content_then_tag = if variant_arms.is_empty() { quote! { match try!(_serde::de::MapAccess::next_value::<__Field>(&mut __map)) {} } } else { quote! { let __ret = try!(match try!(_serde::de::MapAccess::next_value(&mut __map)) { // Deserialize the buffered content now that we know the variant. #(#variant_arms)* }); // Visit remaining keys, looking for duplicates. #visit_remaining_keys } }; quote_block! { #variant_visitor #variants_stmt #[doc(hidden)] struct __Seed #de_impl_generics #where_clause { field: __Field, marker: _serde::__private::PhantomData<#this_type #ty_generics>, lifetime: _serde::__private::PhantomData<&#delife ()>, } impl #de_impl_generics _serde::de::DeserializeSeed<#delife> for __Seed #de_ty_generics #where_clause { type Value = #this_type #ty_generics; fn deserialize<__D>(self, __deserializer: __D) -> _serde::__private::Result where __D: _serde::Deserializer<#delife>, { match self.field { #(#variant_arms)* } } } #[doc(hidden)] struct __Visitor #de_impl_generics #where_clause { marker: _serde::__private::PhantomData<#this_type #ty_generics>, lifetime: _serde::__private::PhantomData<&#delife ()>, } impl #de_impl_generics _serde::de::Visitor<#delife> for __Visitor #de_ty_generics #where_clause { type Value = #this_type #ty_generics; fn expecting(&self, __formatter: &mut _serde::__private::Formatter) -> _serde::__private::fmt::Result { _serde::__private::Formatter::write_str(__formatter, #expecting) } fn visit_map<__A>(self, mut __map: __A) -> _serde::__private::Result where __A: _serde::de::MapAccess<#delife>, { // Visit the first relevant key. match #next_relevant_key { // First key is the tag. _serde::__private::Some(_serde::__private::de::TagOrContentField::Tag) => { // Parse the tag. let __field = try!(_serde::de::MapAccess::next_value(&mut __map)); // Visit the second key. match #next_relevant_key { // Second key is a duplicate of the tag. _serde::__private::Some(_serde::__private::de::TagOrContentField::Tag) => { _serde::__private::Err(<__A::Error as _serde::de::Error>::duplicate_field(#tag)) } // Second key is the content. _serde::__private::Some(_serde::__private::de::TagOrContentField::Content) => { let __ret = try!(_serde::de::MapAccess::next_value_seed(&mut __map, __Seed { field: __field, marker: _serde::__private::PhantomData, lifetime: _serde::__private::PhantomData, })); // Visit remaining keys, looking for duplicates. #visit_remaining_keys } // There is no second key; might be okay if the we have a unit variant. _serde::__private::None => #missing_content } } // First key is the content. _serde::__private::Some(_serde::__private::de::TagOrContentField::Content) => { // Buffer up the content. let __content = try!(_serde::de::MapAccess::next_value::<_serde::__private::de::Content>(&mut __map)); // Visit the second key. match #next_relevant_key { // Second key is the tag. _serde::__private::Some(_serde::__private::de::TagOrContentField::Tag) => { let __deserializer = _serde::__private::de::ContentDeserializer::<__A::Error>::new(__content); #finish_content_then_tag } // Second key is a duplicate of the content. _serde::__private::Some(_serde::__private::de::TagOrContentField::Content) => { _serde::__private::Err(<__A::Error as _serde::de::Error>::duplicate_field(#content)) } // There is no second key. _serde::__private::None => { _serde::__private::Err(<__A::Error as _serde::de::Error>::missing_field(#tag)) } } } // There is no first key. _serde::__private::None => { _serde::__private::Err(<__A::Error as _serde::de::Error>::missing_field(#tag)) } } } fn visit_seq<__A>(self, mut __seq: __A) -> _serde::__private::Result where __A: _serde::de::SeqAccess<#delife>, { // Visit the first element - the tag. match try!(_serde::de::SeqAccess::next_element(&mut __seq)) { _serde::__private::Some(__field) => { // Visit the second element - the content. match try!(_serde::de::SeqAccess::next_element_seed( &mut __seq, __Seed { field: __field, marker: _serde::__private::PhantomData, lifetime: _serde::__private::PhantomData, }, )) { _serde::__private::Some(__ret) => _serde::__private::Ok(__ret), // There is no second element. _serde::__private::None => { _serde::__private::Err(_serde::de::Error::invalid_length(1, &self)) } } } // There is no first element. _serde::__private::None => { _serde::__private::Err(_serde::de::Error::invalid_length(0, &self)) } } } } #[doc(hidden)] const FIELDS: &'static [&'static str] = &[#tag, #content]; _serde::Deserializer::deserialize_struct( __deserializer, #type_name, FIELDS, __Visitor { marker: _serde::__private::PhantomData::<#this_type #ty_generics>, lifetime: _serde::__private::PhantomData, }, ) } } fn deserialize_untagged_enum( params: &Parameters, variants: &[Variant], cattrs: &attr::Container, ) -> Fragment { let first_attempt = None; deserialize_untagged_enum_after(params, variants, cattrs, first_attempt) } fn deserialize_untagged_enum_after( params: &Parameters, variants: &[Variant], cattrs: &attr::Container, first_attempt: Option, ) -> Fragment { let attempts = variants .iter() .filter(|variant| !variant.attrs.skip_deserializing()) .map(|variant| { Expr(deserialize_untagged_variant( params, variant, cattrs, quote!(__deserializer), )) }); let attempts = first_attempt.into_iter().chain(attempts); // TODO this message could be better by saving the errors from the failed // attempts. The heuristic used by TOML was to count the number of fields // processed before an error, and use the error that happened after the // largest number of fields. I'm not sure I like that. Maybe it would be // better to save all the errors and combine them into one message that // explains why none of the variants matched. let fallthrough_msg = format!( "data did not match any variant of untagged enum {}", params.type_name() ); let fallthrough_msg = cattrs.expecting().unwrap_or(&fallthrough_msg); quote_block! { let __content = try!(<_serde::__private::de::Content as _serde::Deserialize>::deserialize(__deserializer)); let __deserializer = _serde::__private::de::ContentRefDeserializer::<__D::Error>::new(&__content); #( if let _serde::__private::Ok(__ok) = #attempts { return _serde::__private::Ok(__ok); } )* _serde::__private::Err(_serde::de::Error::custom(#fallthrough_msg)) } } fn deserialize_externally_tagged_variant( params: &Parameters, variant: &Variant, cattrs: &attr::Container, ) -> Fragment { if let Some(path) = variant.attrs.deserialize_with() { let (wrapper, wrapper_ty, unwrap_fn) = wrap_deserialize_variant_with(params, variant, path); return quote_block! { #wrapper _serde::__private::Result::map( _serde::de::VariantAccess::newtype_variant::<#wrapper_ty>(__variant), #unwrap_fn) }; } let variant_ident = &variant.ident; match variant.style { Style::Unit => { let this_value = ¶ms.this_value; quote_block! { try!(_serde::de::VariantAccess::unit_variant(__variant)); _serde::__private::Ok(#this_value::#variant_ident) } } Style::Newtype => deserialize_externally_tagged_newtype_variant( variant_ident, params, &variant.fields[0], cattrs, ), Style::Tuple => { deserialize_tuple(Some(variant_ident), params, &variant.fields, cattrs, None) } Style::Struct => deserialize_struct( Some(variant_ident), params, &variant.fields, cattrs, None, &Untagged::No, ), } } // Generates significant part of the visit_seq and visit_map bodies of visitors // for the variants of internally tagged enum. fn deserialize_internally_tagged_variant( params: &Parameters, variant: &Variant, cattrs: &attr::Container, deserializer: TokenStream, ) -> Fragment { if variant.attrs.deserialize_with().is_some() { return deserialize_untagged_variant(params, variant, cattrs, deserializer); } let variant_ident = &variant.ident; match effective_style(variant) { Style::Unit => { let this_value = ¶ms.this_value; let type_name = params.type_name(); let variant_name = variant.ident.to_string(); let default = variant.fields.get(0).map(|field| { let default = Expr(expr_is_missing(field, cattrs)); quote!((#default)) }); quote_block! { try!(_serde::Deserializer::deserialize_any(#deserializer, _serde::__private::de::InternallyTaggedUnitVisitor::new(#type_name, #variant_name))); _serde::__private::Ok(#this_value::#variant_ident #default) } } Style::Newtype => deserialize_untagged_newtype_variant( variant_ident, params, &variant.fields[0], &deserializer, ), Style::Struct => deserialize_struct( Some(variant_ident), params, &variant.fields, cattrs, Some(deserializer), &Untagged::No, ), Style::Tuple => unreachable!("checked in serde_derive_internals"), } } fn deserialize_untagged_variant( params: &Parameters, variant: &Variant, cattrs: &attr::Container, deserializer: TokenStream, ) -> Fragment { if let Some(path) = variant.attrs.deserialize_with() { let unwrap_fn = unwrap_to_variant_closure(params, variant, false); return quote_block! { _serde::__private::Result::map(#path(#deserializer), #unwrap_fn) }; } let variant_ident = &variant.ident; match effective_style(variant) { Style::Unit => { let this_value = ¶ms.this_value; let type_name = params.type_name(); let variant_name = variant.ident.to_string(); let default = variant.fields.get(0).map(|field| { let default = Expr(expr_is_missing(field, cattrs)); quote!((#default)) }); quote_expr! { match _serde::Deserializer::deserialize_any( #deserializer, _serde::__private::de::UntaggedUnitVisitor::new(#type_name, #variant_name) ) { _serde::__private::Ok(()) => _serde::__private::Ok(#this_value::#variant_ident #default), _serde::__private::Err(__err) => _serde::__private::Err(__err), } } } Style::Newtype => deserialize_untagged_newtype_variant( variant_ident, params, &variant.fields[0], &deserializer, ), Style::Tuple => deserialize_tuple( Some(variant_ident), params, &variant.fields, cattrs, Some(deserializer), ), Style::Struct => deserialize_struct( Some(variant_ident), params, &variant.fields, cattrs, Some(deserializer), &Untagged::Yes, ), } } fn deserialize_externally_tagged_newtype_variant( variant_ident: &syn::Ident, params: &Parameters, field: &Field, cattrs: &attr::Container, ) -> Fragment { let this_value = ¶ms.this_value; if field.attrs.skip_deserializing() { let default = Expr(expr_is_missing(field, cattrs)); return quote_block! { try!(_serde::de::VariantAccess::unit_variant(__variant)); _serde::__private::Ok(#this_value::#variant_ident(#default)) }; } match field.attrs.deserialize_with() { None => { let field_ty = field.ty; let span = field.original.span(); let func = quote_spanned!(span=> _serde::de::VariantAccess::newtype_variant::<#field_ty>); quote_expr! { _serde::__private::Result::map(#func(__variant), #this_value::#variant_ident) } } Some(path) => { let (wrapper, wrapper_ty) = wrap_deserialize_field_with(params, field.ty, path); quote_block! { #wrapper _serde::__private::Result::map( _serde::de::VariantAccess::newtype_variant::<#wrapper_ty>(__variant), |__wrapper| #this_value::#variant_ident(__wrapper.value)) } } } } fn deserialize_untagged_newtype_variant( variant_ident: &syn::Ident, params: &Parameters, field: &Field, deserializer: &TokenStream, ) -> Fragment { let this_value = ¶ms.this_value; let field_ty = field.ty; match field.attrs.deserialize_with() { None => { let span = field.original.span(); let func = quote_spanned!(span=> <#field_ty as _serde::Deserialize>::deserialize); quote_expr! { _serde::__private::Result::map(#func(#deserializer), #this_value::#variant_ident) } } Some(path) => { quote_block! { let __value: _serde::__private::Result<#field_ty, _> = #path(#deserializer); _serde::__private::Result::map(__value, #this_value::#variant_ident) } } } } fn deserialize_generated_identifier( fields: &[(String, Ident, Vec)], cattrs: &attr::Container, is_variant: bool, other_idx: Option, ) -> Fragment { let this_value = quote!(__Field); let field_idents: &Vec<_> = &fields.iter().map(|(_, ident, _)| ident).collect(); let (ignore_variant, fallthrough) = if !is_variant && cattrs.has_flatten() { let ignore_variant = quote!(__other(_serde::__private::de::Content<'de>),); let fallthrough = quote!(_serde::__private::Ok(__Field::__other(__value))); (Some(ignore_variant), Some(fallthrough)) } else if let Some(other_idx) = other_idx { let ignore_variant = fields[other_idx].1.clone(); let fallthrough = quote!(_serde::__private::Ok(__Field::#ignore_variant)); (None, Some(fallthrough)) } else if is_variant || cattrs.deny_unknown_fields() { (None, None) } else { let ignore_variant = quote!(__ignore,); let fallthrough = quote!(_serde::__private::Ok(__Field::__ignore)); (Some(ignore_variant), Some(fallthrough)) }; let visitor_impl = Stmts(deserialize_identifier( &this_value, fields, is_variant, fallthrough, None, !is_variant && cattrs.has_flatten(), None, )); let lifetime = if !is_variant && cattrs.has_flatten() { Some(quote!(<'de>)) } else { None }; quote_block! { #[allow(non_camel_case_types)] #[doc(hidden)] enum __Field #lifetime { #(#field_idents,)* #ignore_variant } #[doc(hidden)] struct __FieldVisitor; impl<'de> _serde::de::Visitor<'de> for __FieldVisitor { type Value = __Field #lifetime; #visitor_impl } impl<'de> _serde::Deserialize<'de> for __Field #lifetime { #[inline] fn deserialize<__D>(__deserializer: __D) -> _serde::__private::Result where __D: _serde::Deserializer<'de>, { _serde::Deserializer::deserialize_identifier(__deserializer, __FieldVisitor) } } } } // Generates `Deserialize::deserialize` body for an enum with // `serde(field_identifier)` or `serde(variant_identifier)` attribute. fn deserialize_custom_identifier( params: &Parameters, variants: &[Variant], cattrs: &attr::Container, ) -> Fragment { let is_variant = match cattrs.identifier() { attr::Identifier::Variant => true, attr::Identifier::Field => false, attr::Identifier::No => unreachable!(), }; let this_type = params.this_type.to_token_stream(); let this_value = params.this_value.to_token_stream(); let (ordinary, fallthrough, fallthrough_borrowed) = if let Some(last) = variants.last() { let last_ident = &last.ident; if last.attrs.other() { // Process `serde(other)` attribute. It would always be found on the // last variant (checked in `check_identifier`), so all preceding // are ordinary variants. let ordinary = &variants[..variants.len() - 1]; let fallthrough = quote!(_serde::__private::Ok(#this_value::#last_ident)); (ordinary, Some(fallthrough), None) } else if let Style::Newtype = last.style { let ordinary = &variants[..variants.len() - 1]; let fallthrough = |value| { quote! { _serde::__private::Result::map( _serde::Deserialize::deserialize( _serde::__private::de::IdentifierDeserializer::from(#value) ), #this_value::#last_ident) } }; ( ordinary, Some(fallthrough(quote!(__value))), Some(fallthrough(quote!(_serde::__private::de::Borrowed( __value )))), ) } else { (variants, None, None) } } else { (variants, None, None) }; let names_idents: Vec<_> = ordinary .iter() .map(|variant| { ( variant.attrs.name().deserialize_name(), variant.ident.clone(), variant.attrs.aliases(), ) }) .collect(); let names = names_idents.iter().map(|(name, _, _)| name); let names_const = if fallthrough.is_some() { None } else if is_variant { let variants = quote! { #[doc(hidden)] const VARIANTS: &'static [&'static str] = &[ #(#names),* ]; }; Some(variants) } else { let fields = quote! { #[doc(hidden)] const FIELDS: &'static [&'static str] = &[ #(#names),* ]; }; Some(fields) }; let (de_impl_generics, de_ty_generics, ty_generics, where_clause) = split_with_de_lifetime(params); let delife = params.borrowed.de_lifetime(); let visitor_impl = Stmts(deserialize_identifier( &this_value, &names_idents, is_variant, fallthrough, fallthrough_borrowed, false, cattrs.expecting(), )); quote_block! { #names_const #[doc(hidden)] struct __FieldVisitor #de_impl_generics #where_clause { marker: _serde::__private::PhantomData<#this_type #ty_generics>, lifetime: _serde::__private::PhantomData<&#delife ()>, } impl #de_impl_generics _serde::de::Visitor<#delife> for __FieldVisitor #de_ty_generics #where_clause { type Value = #this_type #ty_generics; #visitor_impl } let __visitor = __FieldVisitor { marker: _serde::__private::PhantomData::<#this_type #ty_generics>, lifetime: _serde::__private::PhantomData, }; _serde::Deserializer::deserialize_identifier(__deserializer, __visitor) } } fn deserialize_identifier( this_value: &TokenStream, fields: &[(String, Ident, Vec)], is_variant: bool, fallthrough: Option, fallthrough_borrowed: Option, collect_other_fields: bool, expecting: Option<&str>, ) -> Fragment { let mut flat_fields = Vec::new(); for (_, ident, aliases) in fields { flat_fields.extend(aliases.iter().map(|alias| (alias, ident))); } let field_strs: &Vec<_> = &flat_fields.iter().map(|(name, _)| name).collect(); let field_bytes: &Vec<_> = &flat_fields .iter() .map(|(name, _)| Literal::byte_string(name.as_bytes())) .collect(); let constructors: &Vec<_> = &flat_fields .iter() .map(|(_, ident)| quote!(#this_value::#ident)) .collect(); let main_constructors: &Vec<_> = &fields .iter() .map(|(_, ident, _)| quote!(#this_value::#ident)) .collect(); let expecting = expecting.unwrap_or(if is_variant { "variant identifier" } else { "field identifier" }); let index_expecting = if is_variant { "variant" } else { "field" }; let bytes_to_str = if fallthrough.is_some() || collect_other_fields { None } else { Some(quote! { let __value = &_serde::__private::from_utf8_lossy(__value); }) }; let ( value_as_str_content, value_as_borrowed_str_content, value_as_bytes_content, value_as_borrowed_bytes_content, ) = if collect_other_fields { ( Some(quote! { let __value = _serde::__private::de::Content::String(_serde::__private::ToString::to_string(__value)); }), Some(quote! { let __value = _serde::__private::de::Content::Str(__value); }), Some(quote! { let __value = _serde::__private::de::Content::ByteBuf(__value.to_vec()); }), Some(quote! { let __value = _serde::__private::de::Content::Bytes(__value); }), ) } else { (None, None, None, None) }; let fallthrough_arm_tokens; let fallthrough_arm = if let Some(fallthrough) = &fallthrough { fallthrough } else if is_variant { fallthrough_arm_tokens = quote! { _serde::__private::Err(_serde::de::Error::unknown_variant(__value, VARIANTS)) }; &fallthrough_arm_tokens } else { fallthrough_arm_tokens = quote! { _serde::__private::Err(_serde::de::Error::unknown_field(__value, FIELDS)) }; &fallthrough_arm_tokens }; let u64_fallthrough_arm_tokens; let u64_fallthrough_arm = if let Some(fallthrough) = &fallthrough { fallthrough } else { let fallthrough_msg = format!("{} index 0 <= i < {}", index_expecting, fields.len()); u64_fallthrough_arm_tokens = quote! { _serde::__private::Err(_serde::de::Error::invalid_value( _serde::de::Unexpected::Unsigned(__value), &#fallthrough_msg, )) }; &u64_fallthrough_arm_tokens }; let variant_indices = 0_u64..; let visit_other = if collect_other_fields { quote! { fn visit_bool<__E>(self, __value: bool) -> _serde::__private::Result where __E: _serde::de::Error, { _serde::__private::Ok(__Field::__other(_serde::__private::de::Content::Bool(__value))) } fn visit_i8<__E>(self, __value: i8) -> _serde::__private::Result where __E: _serde::de::Error, { _serde::__private::Ok(__Field::__other(_serde::__private::de::Content::I8(__value))) } fn visit_i16<__E>(self, __value: i16) -> _serde::__private::Result where __E: _serde::de::Error, { _serde::__private::Ok(__Field::__other(_serde::__private::de::Content::I16(__value))) } fn visit_i32<__E>(self, __value: i32) -> _serde::__private::Result where __E: _serde::de::Error, { _serde::__private::Ok(__Field::__other(_serde::__private::de::Content::I32(__value))) } fn visit_i64<__E>(self, __value: i64) -> _serde::__private::Result where __E: _serde::de::Error, { _serde::__private::Ok(__Field::__other(_serde::__private::de::Content::I64(__value))) } fn visit_u8<__E>(self, __value: u8) -> _serde::__private::Result where __E: _serde::de::Error, { _serde::__private::Ok(__Field::__other(_serde::__private::de::Content::U8(__value))) } fn visit_u16<__E>(self, __value: u16) -> _serde::__private::Result where __E: _serde::de::Error, { _serde::__private::Ok(__Field::__other(_serde::__private::de::Content::U16(__value))) } fn visit_u32<__E>(self, __value: u32) -> _serde::__private::Result where __E: _serde::de::Error, { _serde::__private::Ok(__Field::__other(_serde::__private::de::Content::U32(__value))) } fn visit_u64<__E>(self, __value: u64) -> _serde::__private::Result where __E: _serde::de::Error, { _serde::__private::Ok(__Field::__other(_serde::__private::de::Content::U64(__value))) } fn visit_f32<__E>(self, __value: f32) -> _serde::__private::Result where __E: _serde::de::Error, { _serde::__private::Ok(__Field::__other(_serde::__private::de::Content::F32(__value))) } fn visit_f64<__E>(self, __value: f64) -> _serde::__private::Result where __E: _serde::de::Error, { _serde::__private::Ok(__Field::__other(_serde::__private::de::Content::F64(__value))) } fn visit_char<__E>(self, __value: char) -> _serde::__private::Result where __E: _serde::de::Error, { _serde::__private::Ok(__Field::__other(_serde::__private::de::Content::Char(__value))) } fn visit_unit<__E>(self) -> _serde::__private::Result where __E: _serde::de::Error, { _serde::__private::Ok(__Field::__other(_serde::__private::de::Content::Unit)) } } } else { quote! { fn visit_u64<__E>(self, __value: u64) -> _serde::__private::Result where __E: _serde::de::Error, { match __value { #( #variant_indices => _serde::__private::Ok(#main_constructors), )* _ => #u64_fallthrough_arm, } } } }; let visit_borrowed = if fallthrough_borrowed.is_some() || collect_other_fields { let fallthrough_borrowed_arm = fallthrough_borrowed.as_ref().unwrap_or(fallthrough_arm); Some(quote! { fn visit_borrowed_str<__E>(self, __value: &'de str) -> _serde::__private::Result where __E: _serde::de::Error, { match __value { #( #field_strs => _serde::__private::Ok(#constructors), )* _ => { #value_as_borrowed_str_content #fallthrough_borrowed_arm } } } fn visit_borrowed_bytes<__E>(self, __value: &'de [u8]) -> _serde::__private::Result where __E: _serde::de::Error, { match __value { #( #field_bytes => _serde::__private::Ok(#constructors), )* _ => { #bytes_to_str #value_as_borrowed_bytes_content #fallthrough_borrowed_arm } } } }) } else { None }; quote_block! { fn expecting(&self, __formatter: &mut _serde::__private::Formatter) -> _serde::__private::fmt::Result { _serde::__private::Formatter::write_str(__formatter, #expecting) } #visit_other fn visit_str<__E>(self, __value: &str) -> _serde::__private::Result where __E: _serde::de::Error, { match __value { #( #field_strs => _serde::__private::Ok(#constructors), )* _ => { #value_as_str_content #fallthrough_arm } } } fn visit_bytes<__E>(self, __value: &[u8]) -> _serde::__private::Result where __E: _serde::de::Error, { match __value { #( #field_bytes => _serde::__private::Ok(#constructors), )* _ => { #bytes_to_str #value_as_bytes_content #fallthrough_arm } } } #visit_borrowed } } fn deserialize_struct_as_struct_visitor( struct_path: &TokenStream, params: &Parameters, fields: &[Field], cattrs: &attr::Container, ) -> (Fragment, Option, Fragment) { assert!(!cattrs.has_flatten()); let field_names_idents: Vec<_> = fields .iter() .enumerate() .filter(|&(_, field)| !field.attrs.skip_deserializing()) .map(|(i, field)| { ( field.attrs.name().deserialize_name(), field_i(i), field.attrs.aliases(), ) }) .collect(); let fields_stmt = { let field_names = field_names_idents .iter() .flat_map(|(_, _, aliases)| aliases); quote_block! { #[doc(hidden)] const FIELDS: &'static [&'static str] = &[ #(#field_names),* ]; } }; let field_visitor = deserialize_generated_identifier(&field_names_idents, cattrs, false, None); let visit_map = deserialize_map(struct_path, params, fields, cattrs); (field_visitor, Some(fields_stmt), visit_map) } fn deserialize_struct_as_map_visitor( struct_path: &TokenStream, params: &Parameters, fields: &[Field], cattrs: &attr::Container, ) -> (Fragment, Option, Fragment) { let field_names_idents: Vec<_> = fields .iter() .enumerate() .filter(|&(_, field)| !field.attrs.skip_deserializing() && !field.attrs.flatten()) .map(|(i, field)| { ( field.attrs.name().deserialize_name(), field_i(i), field.attrs.aliases(), ) }) .collect(); let field_visitor = deserialize_generated_identifier(&field_names_idents, cattrs, false, None); let visit_map = deserialize_map(struct_path, params, fields, cattrs); (field_visitor, None, visit_map) } fn deserialize_map( struct_path: &TokenStream, params: &Parameters, fields: &[Field], cattrs: &attr::Container, ) -> Fragment { // Create the field names for the fields. let fields_names: Vec<_> = fields .iter() .enumerate() .map(|(i, field)| (field, field_i(i))) .collect(); // Declare each field that will be deserialized. let let_values = fields_names .iter() .filter(|&&(field, _)| !field.attrs.skip_deserializing() && !field.attrs.flatten()) .map(|(field, name)| { let field_ty = field.ty; quote! { let mut #name: _serde::__private::Option<#field_ty> = _serde::__private::None; } }); // Collect contents for flatten fields into a buffer let let_collect = if cattrs.has_flatten() { Some(quote! { let mut __collect = _serde::__private::Vec::<_serde::__private::Option<( _serde::__private::de::Content, _serde::__private::de::Content )>>::new(); }) } else { None }; // Match arms to extract a value for a field. let value_arms = fields_names .iter() .filter(|&&(field, _)| !field.attrs.skip_deserializing() && !field.attrs.flatten()) .map(|(field, name)| { let deser_name = field.attrs.name().deserialize_name(); let visit = match field.attrs.deserialize_with() { None => { let field_ty = field.ty; let span = field.original.span(); let func = quote_spanned!(span=> _serde::de::MapAccess::next_value::<#field_ty>); quote! { try!(#func(&mut __map)) } } Some(path) => { let (wrapper, wrapper_ty) = wrap_deserialize_field_with(params, field.ty, path); quote!({ #wrapper match _serde::de::MapAccess::next_value::<#wrapper_ty>(&mut __map) { _serde::__private::Ok(__wrapper) => __wrapper.value, _serde::__private::Err(__err) => { return _serde::__private::Err(__err); } } }) } }; quote! { __Field::#name => { if _serde::__private::Option::is_some(&#name) { return _serde::__private::Err(<__A::Error as _serde::de::Error>::duplicate_field(#deser_name)); } #name = _serde::__private::Some(#visit); } } }); // Visit ignored values to consume them let ignored_arm = if cattrs.has_flatten() { Some(quote! { __Field::__other(__name) => { __collect.push(_serde::__private::Some(( __name, try!(_serde::de::MapAccess::next_value(&mut __map))))); } }) } else if cattrs.deny_unknown_fields() { None } else { Some(quote! { _ => { let _ = try!(_serde::de::MapAccess::next_value::<_serde::de::IgnoredAny>(&mut __map)); } }) }; let all_skipped = fields.iter().all(|field| field.attrs.skip_deserializing()); let match_keys = if cattrs.deny_unknown_fields() && all_skipped { quote! { // FIXME: Once feature(exhaustive_patterns) is stable: // let _serde::__private::None::<__Field> = try!(_serde::de::MapAccess::next_key(&mut __map)); _serde::__private::Option::map( try!(_serde::de::MapAccess::next_key::<__Field>(&mut __map)), |__impossible| match __impossible {}); } } else { quote! { while let _serde::__private::Some(__key) = try!(_serde::de::MapAccess::next_key::<__Field>(&mut __map)) { match __key { #(#value_arms)* #ignored_arm } } } }; let extract_values = fields_names .iter() .filter(|&&(field, _)| !field.attrs.skip_deserializing() && !field.attrs.flatten()) .map(|(field, name)| { let missing_expr = Match(expr_is_missing(field, cattrs)); quote! { let #name = match #name { _serde::__private::Some(#name) => #name, _serde::__private::None => #missing_expr }; } }); let extract_collected = fields_names .iter() .filter(|&&(field, _)| field.attrs.flatten() && !field.attrs.skip_deserializing()) .map(|(field, name)| { let field_ty = field.ty; let func = match field.attrs.deserialize_with() { None => { let span = field.original.span(); quote_spanned!(span=> _serde::de::Deserialize::deserialize) } Some(path) => quote!(#path), }; quote! { let #name: #field_ty = try!(#func( _serde::__private::de::FlatMapDeserializer( &mut __collect, _serde::__private::PhantomData))); } }); let collected_deny_unknown_fields = if cattrs.has_flatten() && cattrs.deny_unknown_fields() { Some(quote! { if let _serde::__private::Some(_serde::__private::Some((__key, _))) = __collect.into_iter().filter(_serde::__private::Option::is_some).next() { if let _serde::__private::Some(__key) = __key.as_str() { return _serde::__private::Err( _serde::de::Error::custom(format_args!("unknown field `{}`", &__key))); } else { return _serde::__private::Err( _serde::de::Error::custom(format_args!("unexpected map key"))); } } }) } else { None }; let result = fields_names.iter().map(|(field, name)| { let member = &field.member; if field.attrs.skip_deserializing() { let value = Expr(expr_is_missing(field, cattrs)); quote!(#member: #value) } else { quote!(#member: #name) } }); let let_default = match cattrs.default() { attr::Default::Default => Some(quote!( let __default: Self::Value = _serde::__private::Default::default(); )), attr::Default::Path(path) => Some(quote!( let __default: Self::Value = #path(); )), attr::Default::None => { // We don't need the default value, to prevent an unused variable warning // we'll leave the line empty. None } }; let mut result = quote!(#struct_path { #(#result),* }); if params.has_getter { let this_type = ¶ms.this_type; let (_, ty_generics, _) = params.generics.split_for_impl(); result = quote! { _serde::__private::Into::<#this_type #ty_generics>::into(#result) }; } quote_block! { #(#let_values)* #let_collect #match_keys #let_default #(#extract_values)* #(#extract_collected)* #collected_deny_unknown_fields _serde::__private::Ok(#result) } } #[cfg(feature = "deserialize_in_place")] fn deserialize_struct_as_struct_in_place_visitor( params: &Parameters, fields: &[Field], cattrs: &attr::Container, ) -> (Fragment, Fragment, Fragment) { assert!(!cattrs.has_flatten()); let field_names_idents: Vec<_> = fields .iter() .enumerate() .filter(|&(_, field)| !field.attrs.skip_deserializing()) .map(|(i, field)| { ( field.attrs.name().deserialize_name(), field_i(i), field.attrs.aliases(), ) }) .collect(); let fields_stmt = { let field_names = field_names_idents.iter().map(|(name, _, _)| name); quote_block! { #[doc(hidden)] const FIELDS: &'static [&'static str] = &[ #(#field_names),* ]; } }; let field_visitor = deserialize_generated_identifier(&field_names_idents, cattrs, false, None); let visit_map = deserialize_map_in_place(params, fields, cattrs); (field_visitor, fields_stmt, visit_map) } #[cfg(feature = "deserialize_in_place")] fn deserialize_map_in_place( params: &Parameters, fields: &[Field], cattrs: &attr::Container, ) -> Fragment { assert!(!cattrs.has_flatten()); // Create the field names for the fields. let fields_names: Vec<_> = fields .iter() .enumerate() .map(|(i, field)| (field, field_i(i))) .collect(); // For deserialize_in_place, declare booleans for each field that will be // deserialized. let let_flags = fields_names .iter() .filter(|&&(field, _)| !field.attrs.skip_deserializing()) .map(|(_, name)| { quote! { let mut #name: bool = false; } }); // Match arms to extract a value for a field. let value_arms_from = fields_names .iter() .filter(|&&(field, _)| !field.attrs.skip_deserializing()) .map(|(field, name)| { let deser_name = field.attrs.name().deserialize_name(); let member = &field.member; let visit = match field.attrs.deserialize_with() { None => { quote! { try!(_serde::de::MapAccess::next_value_seed(&mut __map, _serde::__private::de::InPlaceSeed(&mut self.place.#member))) } } Some(path) => { let (wrapper, wrapper_ty) = wrap_deserialize_field_with(params, field.ty, path); quote!({ #wrapper self.place.#member = match _serde::de::MapAccess::next_value::<#wrapper_ty>(&mut __map) { _serde::__private::Ok(__wrapper) => __wrapper.value, _serde::__private::Err(__err) => { return _serde::__private::Err(__err); } }; }) } }; quote! { __Field::#name => { if #name { return _serde::__private::Err(<__A::Error as _serde::de::Error>::duplicate_field(#deser_name)); } #visit; #name = true; } } }); // Visit ignored values to consume them let ignored_arm = if cattrs.deny_unknown_fields() { None } else { Some(quote! { _ => { let _ = try!(_serde::de::MapAccess::next_value::<_serde::de::IgnoredAny>(&mut __map)); } }) }; let all_skipped = fields.iter().all(|field| field.attrs.skip_deserializing()); let match_keys = if cattrs.deny_unknown_fields() && all_skipped { quote! { // FIXME: Once feature(exhaustive_patterns) is stable: // let _serde::__private::None::<__Field> = try!(_serde::de::MapAccess::next_key(&mut __map)); _serde::__private::Option::map( try!(_serde::de::MapAccess::next_key::<__Field>(&mut __map)), |__impossible| match __impossible {}); } } else { quote! { while let _serde::__private::Some(__key) = try!(_serde::de::MapAccess::next_key::<__Field>(&mut __map)) { match __key { #(#value_arms_from)* #ignored_arm } } } }; let check_flags = fields_names .iter() .filter(|&&(field, _)| !field.attrs.skip_deserializing()) .map(|(field, name)| { let missing_expr = expr_is_missing(field, cattrs); // If missing_expr unconditionally returns an error, don't try // to assign its value to self.place. if field.attrs.default().is_none() && cattrs.default().is_none() && field.attrs.deserialize_with().is_some() { let missing_expr = Stmts(missing_expr); quote! { if !#name { #missing_expr; } } } else { let member = &field.member; let missing_expr = Expr(missing_expr); quote! { if !#name { self.place.#member = #missing_expr; }; } } }); let this_type = ¶ms.this_type; let (_, _, ty_generics, _) = split_with_de_lifetime(params); let let_default = match cattrs.default() { attr::Default::Default => Some(quote!( let __default: #this_type #ty_generics = _serde::__private::Default::default(); )), attr::Default::Path(path) => Some(quote!( let __default: #this_type #ty_generics = #path(); )), attr::Default::None => { // We don't need the default value, to prevent an unused variable warning // we'll leave the line empty. None } }; quote_block! { #(#let_flags)* #match_keys #let_default #(#check_flags)* _serde::__private::Ok(()) } } fn field_i(i: usize) -> Ident { Ident::new(&format!("__field{}", i), Span::call_site()) } /// This function wraps the expression in `#[serde(deserialize_with = "...")]` /// in a trait to prevent it from accessing the internal `Deserialize` state. fn wrap_deserialize_with( params: &Parameters, value_ty: &TokenStream, deserialize_with: &syn::ExprPath, ) -> (TokenStream, TokenStream) { let this_type = ¶ms.this_type; let (de_impl_generics, de_ty_generics, ty_generics, where_clause) = split_with_de_lifetime(params); let delife = params.borrowed.de_lifetime(); let wrapper = quote! { #[doc(hidden)] struct __DeserializeWith #de_impl_generics #where_clause { value: #value_ty, phantom: _serde::__private::PhantomData<#this_type #ty_generics>, lifetime: _serde::__private::PhantomData<&#delife ()>, } impl #de_impl_generics _serde::Deserialize<#delife> for __DeserializeWith #de_ty_generics #where_clause { fn deserialize<__D>(__deserializer: __D) -> _serde::__private::Result where __D: _serde::Deserializer<#delife>, { _serde::__private::Ok(__DeserializeWith { value: try!(#deserialize_with(__deserializer)), phantom: _serde::__private::PhantomData, lifetime: _serde::__private::PhantomData, }) } } }; let wrapper_ty = quote!(__DeserializeWith #de_ty_generics); (wrapper, wrapper_ty) } fn wrap_deserialize_field_with( params: &Parameters, field_ty: &syn::Type, deserialize_with: &syn::ExprPath, ) -> (TokenStream, TokenStream) { wrap_deserialize_with(params, "e!(#field_ty), deserialize_with) } fn wrap_deserialize_variant_with( params: &Parameters, variant: &Variant, deserialize_with: &syn::ExprPath, ) -> (TokenStream, TokenStream, TokenStream) { let field_tys = variant.fields.iter().map(|field| field.ty); let (wrapper, wrapper_ty) = wrap_deserialize_with(params, "e!((#(#field_tys),*)), deserialize_with); let unwrap_fn = unwrap_to_variant_closure(params, variant, true); (wrapper, wrapper_ty, unwrap_fn) } // Generates closure that converts single input parameter to the final value. fn unwrap_to_variant_closure( params: &Parameters, variant: &Variant, with_wrapper: bool, ) -> TokenStream { let this_value = ¶ms.this_value; let variant_ident = &variant.ident; let (arg, wrapper) = if with_wrapper { (quote! { __wrap }, quote! { __wrap.value }) } else { let field_tys = variant.fields.iter().map(|field| field.ty); (quote! { __wrap: (#(#field_tys),*) }, quote! { __wrap }) }; let field_access = (0..variant.fields.len()).map(|n| { Member::Unnamed(Index { index: n as u32, span: Span::call_site(), }) }); match variant.style { Style::Struct if variant.fields.len() == 1 => { let member = &variant.fields[0].member; quote! { |#arg| #this_value::#variant_ident { #member: #wrapper } } } Style::Struct => { let members = variant.fields.iter().map(|field| &field.member); quote! { |#arg| #this_value::#variant_ident { #(#members: #wrapper.#field_access),* } } } Style::Tuple => quote! { |#arg| #this_value::#variant_ident(#(#wrapper.#field_access),*) }, Style::Newtype => quote! { |#arg| #this_value::#variant_ident(#wrapper) }, Style::Unit => quote! { |#arg| #this_value::#variant_ident }, } } fn expr_is_missing(field: &Field, cattrs: &attr::Container) -> Fragment { match field.attrs.default() { attr::Default::Default => { let span = field.original.span(); let func = quote_spanned!(span=> _serde::__private::Default::default); return quote_expr!(#func()); } attr::Default::Path(path) => { return quote_expr!(#path()); } attr::Default::None => { /* below */ } } match *cattrs.default() { attr::Default::Default | attr::Default::Path(_) => { let member = &field.member; return quote_expr!(__default.#member); } attr::Default::None => { /* below */ } } let name = field.attrs.name().deserialize_name(); match field.attrs.deserialize_with() { None => { let span = field.original.span(); let func = quote_spanned!(span=> _serde::__private::de::missing_field); quote_expr! { try!(#func(#name)) } } Some(_) => { quote_expr! { return _serde::__private::Err(<__A::Error as _serde::de::Error>::missing_field(#name)) } } } } fn effective_style(variant: &Variant) -> Style { match variant.style { Style::Newtype if variant.fields[0].attrs.skip_deserializing() => Style::Unit, other => other, } } struct DeImplGenerics<'a>(&'a Parameters); #[cfg(feature = "deserialize_in_place")] struct InPlaceImplGenerics<'a>(&'a Parameters); impl<'a> ToTokens for DeImplGenerics<'a> { fn to_tokens(&self, tokens: &mut TokenStream) { let mut generics = self.0.generics.clone(); if let Some(de_lifetime) = self.0.borrowed.de_lifetime_param() { generics.params = Some(syn::GenericParam::Lifetime(de_lifetime)) .into_iter() .chain(generics.params) .collect(); } let (impl_generics, _, _) = generics.split_for_impl(); impl_generics.to_tokens(tokens); } } #[cfg(feature = "deserialize_in_place")] impl<'a> ToTokens for InPlaceImplGenerics<'a> { fn to_tokens(&self, tokens: &mut TokenStream) { let place_lifetime = place_lifetime(); let mut generics = self.0.generics.clone(); // Add lifetime for `&'place mut Self, and `'a: 'place` for param in &mut generics.params { match param { syn::GenericParam::Lifetime(param) => { param.bounds.push(place_lifetime.lifetime.clone()); } syn::GenericParam::Type(param) => { param.bounds.push(syn::TypeParamBound::Lifetime( place_lifetime.lifetime.clone(), )); } syn::GenericParam::Const(_) => {} } } generics.params = Some(syn::GenericParam::Lifetime(place_lifetime)) .into_iter() .chain(generics.params) .collect(); if let Some(de_lifetime) = self.0.borrowed.de_lifetime_param() { generics.params = Some(syn::GenericParam::Lifetime(de_lifetime)) .into_iter() .chain(generics.params) .collect(); } let (impl_generics, _, _) = generics.split_for_impl(); impl_generics.to_tokens(tokens); } } #[cfg(feature = "deserialize_in_place")] impl<'a> DeImplGenerics<'a> { fn in_place(self) -> InPlaceImplGenerics<'a> { InPlaceImplGenerics(self.0) } } struct DeTypeGenerics<'a>(&'a Parameters); #[cfg(feature = "deserialize_in_place")] struct InPlaceTypeGenerics<'a>(&'a Parameters); fn de_type_generics_to_tokens( mut generics: syn::Generics, borrowed: &BorrowedLifetimes, tokens: &mut TokenStream, ) { if borrowed.de_lifetime_param().is_some() { let def = syn::LifetimeParam { attrs: Vec::new(), lifetime: syn::Lifetime::new("'de", Span::call_site()), colon_token: None, bounds: Punctuated::new(), }; // Prepend 'de lifetime to list of generics generics.params = Some(syn::GenericParam::Lifetime(def)) .into_iter() .chain(generics.params) .collect(); } let (_, ty_generics, _) = generics.split_for_impl(); ty_generics.to_tokens(tokens); } impl<'a> ToTokens for DeTypeGenerics<'a> { fn to_tokens(&self, tokens: &mut TokenStream) { de_type_generics_to_tokens(self.0.generics.clone(), &self.0.borrowed, tokens); } } #[cfg(feature = "deserialize_in_place")] impl<'a> ToTokens for InPlaceTypeGenerics<'a> { fn to_tokens(&self, tokens: &mut TokenStream) { let mut generics = self.0.generics.clone(); generics.params = Some(syn::GenericParam::Lifetime(place_lifetime())) .into_iter() .chain(generics.params) .collect(); de_type_generics_to_tokens(generics, &self.0.borrowed, tokens); } } #[cfg(feature = "deserialize_in_place")] impl<'a> DeTypeGenerics<'a> { fn in_place(self) -> InPlaceTypeGenerics<'a> { InPlaceTypeGenerics(self.0) } } #[cfg(feature = "deserialize_in_place")] fn place_lifetime() -> syn::LifetimeParam { syn::LifetimeParam { attrs: Vec::new(), lifetime: syn::Lifetime::new("'place", Span::call_site()), colon_token: None, bounds: Punctuated::new(), } } fn split_with_de_lifetime( params: &Parameters, ) -> ( DeImplGenerics, DeTypeGenerics, syn::TypeGenerics, Option<&syn::WhereClause>, ) { let de_impl_generics = DeImplGenerics(params); let de_ty_generics = DeTypeGenerics(params); let (_, ty_generics, where_clause) = params.generics.split_for_impl(); (de_impl_generics, de_ty_generics, ty_generics, where_clause) }