use proc_macro2::{Span, TokenStream}; use std::mem; use syn::visit_mut::{self, VisitMut}; use syn::{ parse_quote_spanned, token, Expr, GenericArgument, Lifetime, Receiver, ReturnType, Token, Type, TypeBareFn, TypeImplTrait, TypeParen, TypePtr, TypeReference, }; pub struct CollectLifetimes { pub elided: Vec, pub explicit: Vec, } impl CollectLifetimes { pub fn new() -> Self { CollectLifetimes { elided: Vec::new(), explicit: Vec::new(), } } fn visit_opt_lifetime(&mut self, reference: Token![&], lifetime: &mut Option) { match lifetime { None => *lifetime = Some(self.next_lifetime(reference.span)), Some(lifetime) => self.visit_lifetime(lifetime), } } fn visit_lifetime(&mut self, lifetime: &mut Lifetime) { if lifetime.ident == "_" { *lifetime = self.next_lifetime(lifetime.span()); } else { self.explicit.push(lifetime.clone()); } } fn next_lifetime(&mut self, span: Span) -> Lifetime { let name = format!("'life{}", self.elided.len()); let life = Lifetime::new(&name, span); self.elided.push(life.clone()); life } } impl VisitMut for CollectLifetimes { fn visit_receiver_mut(&mut self, arg: &mut Receiver) { if let Some((reference, lifetime)) = &mut arg.reference { self.visit_opt_lifetime(*reference, lifetime); } else { visit_mut::visit_type_mut(self, &mut arg.ty); } } fn visit_type_reference_mut(&mut self, ty: &mut TypeReference) { self.visit_opt_lifetime(ty.and_token, &mut ty.lifetime); visit_mut::visit_type_reference_mut(self, ty); } fn visit_generic_argument_mut(&mut self, gen: &mut GenericArgument) { if let GenericArgument::Lifetime(lifetime) = gen { self.visit_lifetime(lifetime); } visit_mut::visit_generic_argument_mut(self, gen); } } pub struct AddLifetimeToImplTrait; impl VisitMut for AddLifetimeToImplTrait { fn visit_type_impl_trait_mut(&mut self, ty: &mut TypeImplTrait) { let span = ty.impl_token.span; let lifetime = parse_quote_spanned!(span=> 'async_trait); ty.bounds.insert(0, lifetime); if let Some(punct) = ty.bounds.pairs_mut().next().unwrap().punct_mut() { punct.span = span; } visit_mut::visit_type_impl_trait_mut(self, ty); } fn visit_type_reference_mut(&mut self, ty: &mut TypeReference) { parenthesize_impl_trait(&mut ty.elem, ty.and_token.span); visit_mut::visit_type_reference_mut(self, ty); } fn visit_type_ptr_mut(&mut self, ty: &mut TypePtr) { parenthesize_impl_trait(&mut ty.elem, ty.star_token.span); visit_mut::visit_type_ptr_mut(self, ty); } fn visit_type_bare_fn_mut(&mut self, ty: &mut TypeBareFn) { if let ReturnType::Type(arrow, return_type) = &mut ty.output { parenthesize_impl_trait(return_type, arrow.spans[0]); } visit_mut::visit_type_bare_fn_mut(self, ty); } fn visit_expr_mut(&mut self, _e: &mut Expr) { // Do not recurse into impl Traits inside of an array length expression. // // fn outer(arg: [u8; { fn inner(_: impl Trait) {}; 0 }]); } } fn parenthesize_impl_trait(elem: &mut Type, paren_span: Span) { if let Type::ImplTrait(_) = *elem { let placeholder = Type::Verbatim(TokenStream::new()); *elem = Type::Paren(TypeParen { paren_token: token::Paren(paren_span), elem: Box::new(mem::replace(elem, placeholder)), }); } }