use std::collections::HashSet; use syn; use syn::punctuated::{Pair, Punctuated}; use internals::ast::{Container, Data}; use internals::{attr, ungroup}; use proc_macro2::Span; // Remove the default from every type parameter because in the generated impls // they look like associated types: "error: associated type bindings are not // allowed here". pub fn without_defaults(generics: &syn::Generics) -> syn::Generics { syn::Generics { params: generics .params .iter() .map(|param| match param { syn::GenericParam::Type(param) => syn::GenericParam::Type(syn::TypeParam { eq_token: None, default: None, ..param.clone() }), _ => param.clone(), }) .collect(), ..generics.clone() } } pub fn with_where_predicates( generics: &syn::Generics, predicates: &[syn::WherePredicate], ) -> syn::Generics { let mut generics = generics.clone(); generics .make_where_clause() .predicates .extend(predicates.iter().cloned()); generics } pub fn with_where_predicates_from_fields( cont: &Container, generics: &syn::Generics, from_field: fn(&attr::Field) -> Option<&[syn::WherePredicate]>, ) -> syn::Generics { let predicates = cont .data .all_fields() .filter_map(|field| from_field(&field.attrs)) .flat_map(<[syn::WherePredicate]>::to_vec); let mut generics = generics.clone(); generics.make_where_clause().predicates.extend(predicates); generics } pub fn with_where_predicates_from_variants( cont: &Container, generics: &syn::Generics, from_variant: fn(&attr::Variant) -> Option<&[syn::WherePredicate]>, ) -> syn::Generics { let variants = match &cont.data { Data::Enum(variants) => variants, Data::Struct(_, _) => { return generics.clone(); } }; let predicates = variants .iter() .filter_map(|variant| from_variant(&variant.attrs)) .flat_map(<[syn::WherePredicate]>::to_vec); let mut generics = generics.clone(); generics.make_where_clause().predicates.extend(predicates); generics } // Puts the given bound on any generic type parameters that are used in fields // for which filter returns true. // // For example, the following struct needs the bound `A: Serialize, B: // Serialize`. // // struct S<'b, A, B: 'b, C> { // a: A, // b: Option<&'b B> // #[serde(skip_serializing)] // c: C, // } pub fn with_bound( cont: &Container, generics: &syn::Generics, filter: fn(&attr::Field, Option<&attr::Variant>) -> bool, bound: &syn::Path, ) -> syn::Generics { struct FindTyParams<'ast> { // Set of all generic type parameters on the current struct (A, B, C in // the example). Initialized up front. all_type_params: HashSet, // Set of generic type parameters used in fields for which filter // returns true (A and B in the example). Filled in as the visitor sees // them. relevant_type_params: HashSet, // Fields whose type is an associated type of one of the generic type // parameters. associated_type_usage: Vec<&'ast syn::TypePath>, } impl<'ast> FindTyParams<'ast> { fn visit_field(&mut self, field: &'ast syn::Field) { if let syn::Type::Path(ty) = ungroup(&field.ty) { if let Some(Pair::Punctuated(t, _)) = ty.path.segments.pairs().next() { if self.all_type_params.contains(&t.ident) { self.associated_type_usage.push(ty); } } } self.visit_type(&field.ty); } fn visit_path(&mut self, path: &'ast syn::Path) { if let Some(seg) = path.segments.last() { if seg.ident == "PhantomData" { // Hardcoded exception, because PhantomData implements // Serialize and Deserialize whether or not T implements it. return; } } if path.leading_colon.is_none() && path.segments.len() == 1 { let id = &path.segments[0].ident; if self.all_type_params.contains(id) { self.relevant_type_params.insert(id.clone()); } } for segment in &path.segments { self.visit_path_segment(segment); } } // Everything below is simply traversing the syntax tree. fn visit_type(&mut self, ty: &'ast syn::Type) { match ty { syn::Type::Array(ty) => self.visit_type(&ty.elem), syn::Type::BareFn(ty) => { for arg in &ty.inputs { self.visit_type(&arg.ty); } self.visit_return_type(&ty.output); } syn::Type::Group(ty) => self.visit_type(&ty.elem), syn::Type::ImplTrait(ty) => { for bound in &ty.bounds { self.visit_type_param_bound(bound); } } syn::Type::Macro(ty) => self.visit_macro(&ty.mac), syn::Type::Paren(ty) => self.visit_type(&ty.elem), syn::Type::Path(ty) => { if let Some(qself) = &ty.qself { self.visit_type(&qself.ty); } self.visit_path(&ty.path); } syn::Type::Ptr(ty) => self.visit_type(&ty.elem), syn::Type::Reference(ty) => self.visit_type(&ty.elem), syn::Type::Slice(ty) => self.visit_type(&ty.elem), syn::Type::TraitObject(ty) => { for bound in &ty.bounds { self.visit_type_param_bound(bound); } } syn::Type::Tuple(ty) => { for elem in &ty.elems { self.visit_type(elem); } } syn::Type::Infer(_) | syn::Type::Never(_) | syn::Type::Verbatim(_) => {} #[cfg_attr(all(test, exhaustive), deny(non_exhaustive_omitted_patterns))] _ => {} } } fn visit_path_segment(&mut self, segment: &'ast syn::PathSegment) { self.visit_path_arguments(&segment.arguments); } fn visit_path_arguments(&mut self, arguments: &'ast syn::PathArguments) { match arguments { syn::PathArguments::None => {} syn::PathArguments::AngleBracketed(arguments) => { for arg in &arguments.args { match arg { syn::GenericArgument::Type(arg) => self.visit_type(arg), syn::GenericArgument::Binding(arg) => self.visit_type(&arg.ty), syn::GenericArgument::Lifetime(_) | syn::GenericArgument::Constraint(_) | syn::GenericArgument::Const(_) => {} } } } syn::PathArguments::Parenthesized(arguments) => { for argument in &arguments.inputs { self.visit_type(argument); } self.visit_return_type(&arguments.output); } } } fn visit_return_type(&mut self, return_type: &'ast syn::ReturnType) { match return_type { syn::ReturnType::Default => {} syn::ReturnType::Type(_, output) => self.visit_type(output), } } fn visit_type_param_bound(&mut self, bound: &'ast syn::TypeParamBound) { match bound { syn::TypeParamBound::Trait(bound) => self.visit_path(&bound.path), syn::TypeParamBound::Lifetime(_) => {} } } // Type parameter should not be considered used by a macro path. // // struct TypeMacro { // mac: T!(), // marker: PhantomData, // } fn visit_macro(&mut self, _mac: &'ast syn::Macro) {} } let all_type_params = generics .type_params() .map(|param| param.ident.clone()) .collect(); let mut visitor = FindTyParams { all_type_params, relevant_type_params: HashSet::new(), associated_type_usage: Vec::new(), }; match &cont.data { Data::Enum(variants) => { for variant in variants.iter() { let relevant_fields = variant .fields .iter() .filter(|field| filter(&field.attrs, Some(&variant.attrs))); for field in relevant_fields { visitor.visit_field(field.original); } } } Data::Struct(_, fields) => { for field in fields.iter().filter(|field| filter(&field.attrs, None)) { visitor.visit_field(field.original); } } } let relevant_type_params = visitor.relevant_type_params; let associated_type_usage = visitor.associated_type_usage; let new_predicates = generics .type_params() .map(|param| param.ident.clone()) .filter(|id| relevant_type_params.contains(id)) .map(|id| syn::TypePath { qself: None, path: id.into(), }) .chain(associated_type_usage.into_iter().cloned()) .map(|bounded_ty| { syn::WherePredicate::Type(syn::PredicateType { lifetimes: None, // the type parameter that is being bounded e.g. T bounded_ty: syn::Type::Path(bounded_ty), colon_token: ::default(), // the bound e.g. Serialize bounds: vec![syn::TypeParamBound::Trait(syn::TraitBound { paren_token: None, modifier: syn::TraitBoundModifier::None, lifetimes: None, path: bound.clone(), })] .into_iter() .collect(), }) }); let mut generics = generics.clone(); generics .make_where_clause() .predicates .extend(new_predicates); generics } pub fn with_self_bound( cont: &Container, generics: &syn::Generics, bound: &syn::Path, ) -> syn::Generics { let mut generics = generics.clone(); generics .make_where_clause() .predicates .push(syn::WherePredicate::Type(syn::PredicateType { lifetimes: None, // the type that is being bounded e.g. MyStruct<'a, T> bounded_ty: type_of_item(cont), colon_token: ::default(), // the bound e.g. Default bounds: vec![syn::TypeParamBound::Trait(syn::TraitBound { paren_token: None, modifier: syn::TraitBoundModifier::None, lifetimes: None, path: bound.clone(), })] .into_iter() .collect(), })); generics } pub fn with_lifetime_bound(generics: &syn::Generics, lifetime: &str) -> syn::Generics { let bound = syn::Lifetime::new(lifetime, Span::call_site()); let def = syn::LifetimeDef { attrs: Vec::new(), lifetime: bound.clone(), colon_token: None, bounds: Punctuated::new(), }; let params = Some(syn::GenericParam::Lifetime(def)) .into_iter() .chain(generics.params.iter().cloned().map(|mut param| { match &mut param { syn::GenericParam::Lifetime(param) => { param.bounds.push(bound.clone()); } syn::GenericParam::Type(param) => { param .bounds .push(syn::TypeParamBound::Lifetime(bound.clone())); } syn::GenericParam::Const(_) => {} } param })) .collect(); syn::Generics { params, ..generics.clone() } } fn type_of_item(cont: &Container) -> syn::Type { syn::Type::Path(syn::TypePath { qself: None, path: syn::Path { leading_colon: None, segments: vec![syn::PathSegment { ident: cont.ident.clone(), arguments: syn::PathArguments::AngleBracketed( syn::AngleBracketedGenericArguments { colon2_token: None, lt_token: ::default(), args: cont .generics .params .iter() .map(|param| match param { syn::GenericParam::Type(param) => { syn::GenericArgument::Type(syn::Type::Path(syn::TypePath { qself: None, path: param.ident.clone().into(), })) } syn::GenericParam::Lifetime(param) => { syn::GenericArgument::Lifetime(param.lifetime.clone()) } syn::GenericParam::Const(_) => { panic!("Serde does not support const generics yet"); } }) .collect(), gt_token: ]>::default(), }, ), }] .into_iter() .collect(), }, }) }