src/tools/clippy/clippy_lints/src/lifetimes.rs - toolchain/rustc - Git at Google

 use clippy_utils::diagnostics::{span_lint, span_lint_and_then};
 use clippy_utils::trait_ref_of_method;
 use itertools::Itertools;
 use rustc_data_structures::fx::{FxHashMap, FxHashSet};
 use rustc_errors::Applicability;
 use rustc_hir::intravisit::nested_filter::{self as hir_nested_filter, NestedFilter};
 use rustc_hir::intravisit::{
     walk_fn_decl, walk_generic_param, walk_generics, walk_impl_item_ref, walk_item, walk_param_bound,
     walk_poly_trait_ref, walk_trait_ref, walk_ty, Visitor,
 };
 use rustc_hir::FnRetTy::Return;
 use rustc_hir::{
     lang_items, BareFnTy, BodyId, FnDecl, FnSig, GenericArg, GenericBound, GenericParam, GenericParamKind, Generics,
     Impl, ImplItem, ImplItemKind, Item, ItemKind, Lifetime, LifetimeName, LifetimeParamKind, Node, PolyTraitRef,
     PredicateOrigin, TraitFn, TraitItem, TraitItemKind, Ty, TyKind, WherePredicate,
 };
 use rustc_lint::{LateContext, LateLintPass, LintContext};
 use rustc_middle::hir::map::Map;
 use rustc_middle::hir::nested_filter as middle_nested_filter;
 use rustc_middle::lint::in_external_macro;
 use rustc_session::{declare_lint_pass, declare_tool_lint};
 use rustc_span::def_id::LocalDefId;
 use rustc_span::Span;
 use rustc_span::symbol::{kw, Ident, Symbol};

 declare_clippy_lint! {
     /// ### What it does
     /// Checks for lifetime annotations which can be removed by
     /// relying on lifetime elision.
     ///
     /// ### Why is this bad?
     /// The additional lifetimes make the code look more
     /// complicated, while there is nothing out of the ordinary going on. Removing
     /// them leads to more readable code.
     ///
     /// ### Known problems
     /// - We bail out if the function has a `where` clause where lifetimes
     /// are mentioned due to potential false positives.
     ///
     /// ### Example
     /// ```no_run
     /// // Unnecessary lifetime annotations
     /// fn in_and_out<'a>(x: &'a u8, y: u8) -> &'a u8 {
     ///     x
     /// }
     /// ```
     ///
     /// Use instead:
     /// ```no_run
     /// fn elided(x: &u8, y: u8) -> &u8 {
     ///     x
     /// }
     /// ```
     #[clippy::version = "pre 1.29.0"]
     pub NEEDLESS_LIFETIMES,
     complexity,
     "using explicit lifetimes for references in function arguments when elision rules \
      would allow omitting them"
 }

 declare_clippy_lint! {
     /// ### What it does
     /// Checks for lifetimes in generics that are never used
     /// anywhere else.
     ///
     /// ### Why is this bad?
     /// The additional lifetimes make the code look more
     /// complicated, while there is nothing out of the ordinary going on. Removing
     /// them leads to more readable code.
     ///
     /// ### Example
     /// ```no_run
     /// // unnecessary lifetimes
     /// fn unused_lifetime<'a>(x: u8) {
     ///     // ..
     /// }
     /// ```
     ///
     /// Use instead:
     /// ```no_run
     /// fn no_lifetime(x: u8) {
     ///     // ...
     /// }
     /// ```
     #[clippy::version = "pre 1.29.0"]
     pub EXTRA_UNUSED_LIFETIMES,
     complexity,
     "unused lifetimes in function definitions"
 }

 declare_lint_pass!(Lifetimes => [NEEDLESS_LIFETIMES, EXTRA_UNUSED_LIFETIMES]);

 impl<'tcx> LateLintPass<'tcx> for Lifetimes {
     fn check_item(&mut self, cx: &LateContext<'tcx>, item: &'tcx Item<'_>) {
         if let ItemKind::Fn(ref sig, generics, id) = item.kind {
             check_fn_inner(cx, sig, Some(id), None, generics, item.span, true);
         } else if let ItemKind::Impl(impl_) = item.kind {
             if !item.span.from_expansion() {
                 report_extra_impl_lifetimes(cx, impl_);
             }
         }
     }

     fn check_impl_item(&mut self, cx: &LateContext<'tcx>, item: &'tcx ImplItem<'_>) {
         if let ImplItemKind::Fn(ref sig, id) = item.kind {
             let report_extra_lifetimes = trait_ref_of_method(cx, item.owner_id.def_id).is_none();
             check_fn_inner(
                 cx,
                 sig,
                 Some(id),
                 None,
                 item.generics,
                 item.span,
                 report_extra_lifetimes,
             );
         }
     }

     fn check_trait_item(&mut self, cx: &LateContext<'tcx>, item: &'tcx TraitItem<'_>) {
         if let TraitItemKind::Fn(ref sig, ref body) = item.kind {
             let (body, trait_sig) = match *body {
                 TraitFn::Required(sig) => (None, Some(sig)),
                 TraitFn::Provided(id) => (Some(id), None),
             };
             check_fn_inner(cx, sig, body, trait_sig, item.generics, item.span, true);
         }
     }
 }

 fn check_fn_inner<'tcx>(
     cx: &LateContext<'tcx>,
     sig: &'tcx FnSig<'_>,
     body: Option<BodyId>,
     trait_sig: Option<&[Ident]>,
     generics: &'tcx Generics<'_>,
     span: Span,
     report_extra_lifetimes: bool,
 ) {
     if in_external_macro(cx.sess(), span) || has_where_lifetimes(cx, generics) {
         return;
     }

     let types = generics
         .params
         .iter()
         .filter(|param| matches!(param.kind, GenericParamKind::Type { .. }));

     for typ in types {
         if !typ.span.eq_ctxt(span) {
             return;
         }

         for pred in generics.bounds_for_param(typ.def_id) {
             if pred.origin == PredicateOrigin::WhereClause {
                 // has_where_lifetimes checked that this predicate contains no lifetime.
                 continue;
             }

             for bound in pred.bounds {
                 let mut visitor = RefVisitor::new(cx);
                 walk_param_bound(&mut visitor, bound);
                 if visitor.lts.iter().any(|lt| matches!(lt.res, LifetimeName::Param(_))) {
                     return;
                 }
                 if let GenericBound::Trait(ref trait_ref, _) = *bound {
                     let params = &trait_ref
                         .trait_ref
                         .path
                         .segments
                         .last()
                         .expect("a path must have at least one segment")
                         .args;
                     if let Some(params) = *params {
                         let lifetimes = params.args.iter().filter_map(|arg| match arg {
                             GenericArg::Lifetime(lt) => Some(lt),
                             _ => None,
                         });
                         for bound in lifetimes {
                             if !bound.is_static() && !bound.is_elided() {
                                 return;
                             }
                         }
                     }
                 }
             }
         }
     }

     if let Some((elidable_lts, usages)) = could_use_elision(cx, sig.decl, body, trait_sig, generics.params) {
         if usages.iter().any(|usage| !usage.ident.span.eq_ctxt(span)) {
             return;
         }

         let lts = elidable_lts
             .iter()
             // In principle, the result of the call to `Node::ident` could be `unwrap`ped, as `DefId` should refer to a
             // `Node::GenericParam`.
             .filter_map(|&def_id| cx.tcx.hir().get_by_def_id(def_id).ident())
             .map(|ident| ident.to_string())
             .collect::<Vec<_>>()
             .join(", ");

         span_lint_and_then(
             cx,
             NEEDLESS_LIFETIMES,
             elidable_lts
                 .iter()
                 .map(|&lt| cx.tcx.def_span(lt))
                 .chain(usages.iter().filter_map(|usage| {
                     if let LifetimeName::Param(def_id) = usage.res
                         && elidable_lts.contains(&def_id)
                     {
                         return Some(usage.ident.span);
                     }

                     None
                 }))
                 .collect_vec(),
             &format!("the following explicit lifetimes could be elided: {lts}"),
             |diag| {
                 if sig.header.is_async() {
                     // async functions have usages whose spans point at the lifetime declaration which messes up
                     // suggestions
                     return;
                 };

                 if let Some(suggestions) = elision_suggestions(cx, generics, &elidable_lts, &usages) {
                     diag.multipart_suggestion("elide the lifetimes", suggestions, Applicability::MachineApplicable);
                 }
             },
         );
     }

     if report_extra_lifetimes {
         self::report_extra_lifetimes(cx, sig.decl, generics);
     }
 }

 fn elision_suggestions(
     cx: &LateContext<'_>,
     generics: &Generics<'_>,
     elidable_lts: &[LocalDefId],
     usages: &[Lifetime],
 ) -> Option<Vec<(Span, String)>> {
     let explicit_params = generics
         .params
         .iter()
         .filter(|param| !param.is_elided_lifetime() && !param.is_impl_trait())
         .collect::<Vec<_>>();

     let mut suggestions = if elidable_lts.len() == explicit_params.len() {
         // if all the params are elided remove the whole generic block
         //
         // fn x<'a>() {}
         //     ^^^^
         vec![(generics.span, String::new())]
     } else {
         elidable_lts
             .iter()
             .map(|&id| {
                 let pos = explicit_params.iter().position(|param| param.def_id == id)?;
                 let param = explicit_params.get(pos)?;

                 let span = if let Some(next) = explicit_params.get(pos + 1) {
                     // fn x<'prev, 'a, 'next>() {}
                     //             ^^^^
                     param.span.until(next.span)
                 } else {
                     // `pos` should be at least 1 here, because the param in position 0 would either have a `next`
                     // param or would have taken the `elidable_lts.len() == explicit_params.len()` branch.
                     let prev = explicit_params.get(pos - 1)?;

                     // fn x<'prev, 'a>() {}
                     //           ^^^^
                     param.span.with_lo(prev.span.hi())
                 };

                 Some((span, String::new()))
             })
             .collect::<Option<Vec<_>>>()?
     };

     suggestions.extend(
         usages
             .iter()
             .filter(|usage| named_lifetime(usage).map_or(false, |id| elidable_lts.contains(&id)))
             .map(|usage| {
                 match cx.tcx.hir().get_parent(usage.hir_id) {
                     Node::Ty(Ty {
                         kind: TyKind::Ref(..), ..
                     }) => {
                         // expand `&'a T` to `&'a T`
                         //          ^^         ^^^
                         let span = cx
                             .sess()
                             .source_map()
                             .span_extend_while(usage.ident.span, |ch| ch.is_ascii_whitespace())
                             .unwrap_or(usage.ident.span);

                         (span, String::new())
                     },
                     // `T<'a>` and `impl Foo + 'a` should be replaced by `'_`
                     _ => (usage.ident.span, String::from("'_")),
                 }
             }),
     );

     Some(suggestions)
 }

 // elision doesn't work for explicit self types, see rust-lang/rust#69064
 fn explicit_self_type<'tcx>(cx: &LateContext<'tcx>, func: &FnDecl<'tcx>, ident: Option<Ident>) -> bool {
     if_chain! {
         if let Some(ident) = ident;
         if ident.name == kw::SelfLower;
         if !func.implicit_self.has_implicit_self();

         if let Some(self_ty) = func.inputs.first();
         then {
             let mut visitor = RefVisitor::new(cx);
             visitor.visit_ty(self_ty);

             !visitor.all_lts().is_empty()
         } else {
             false
         }
     }
 }

 fn named_lifetime(lt: &Lifetime) -> Option<LocalDefId> {
     match lt.res {
         LifetimeName::Param(id) if !lt.is_anonymous() => Some(id),
         _ => None,
     }
 }

 fn could_use_elision<'tcx>(
     cx: &LateContext<'tcx>,
     func: &'tcx FnDecl<'_>,
     body: Option<BodyId>,
     trait_sig: Option<&[Ident]>,
     named_generics: &'tcx [GenericParam<'_>],
 ) -> Option<(Vec<LocalDefId>, Vec<Lifetime>)> {
     // There are two scenarios where elision works:
     // * no output references, all input references have different LT
     // * output references, exactly one input reference with same LT
     // All lifetimes must be unnamed, 'static or defined without bounds on the
     // level of the current item.

     // check named LTs
     let allowed_lts = allowed_lts_from(named_generics);

     // these will collect all the lifetimes for references in arg/return types
     let mut input_visitor = RefVisitor::new(cx);
     let mut output_visitor = RefVisitor::new(cx);

     // extract lifetimes in input argument types
     for arg in func.inputs {
         input_visitor.visit_ty(arg);
     }
     // extract lifetimes in output type
     if let Return(ty) = func.output {
         output_visitor.visit_ty(ty);
     }
     for lt in named_generics {
         input_visitor.visit_generic_param(lt);
     }

     if input_visitor.abort() || output_visitor.abort() {
         return None;
     }

     let input_lts = input_visitor.lts;
     let output_lts = output_visitor.lts;

     if let Some(trait_sig) = trait_sig {
         if explicit_self_type(cx, func, trait_sig.first().copied()) {
             return None;
         }
     }

     if let Some(body_id) = body {
         let body = cx.tcx.hir().body(body_id);

         let first_ident = body.params.first().and_then(|param| param.pat.simple_ident());
         if explicit_self_type(cx, func, first_ident) {
             return None;
         }

         let mut checker = BodyLifetimeChecker {
             lifetimes_used_in_body: false,
         };
         checker.visit_expr(body.value);
         if checker.lifetimes_used_in_body {
             return None;
         }
     }

     // check for lifetimes from higher scopes
     for lt in input_lts.iter().chain(output_lts.iter()) {
         if let Some(id) = named_lifetime(lt)
             && !allowed_lts.contains(&id)
         {
             return None;
         }
     }

     // check for higher-ranked trait bounds
     if !input_visitor.nested_elision_site_lts.is_empty() || !output_visitor.nested_elision_site_lts.is_empty() {
         let allowed_lts: FxHashSet<_> = allowed_lts.iter().map(|id| cx.tcx.item_name(id.to_def_id())).collect();
         for lt in input_visitor.nested_elision_site_lts {
             if allowed_lts.contains(&lt.ident.name) {
                 return None;
             }
         }
         for lt in output_visitor.nested_elision_site_lts {
             if allowed_lts.contains(&lt.ident.name) {
                 return None;
             }
         }
     }

     // A lifetime can be newly elided if:
     // - It occurs only once among the inputs.
     // - If there are multiple input lifetimes, then the newly elided lifetime does not occur among the
     //   outputs (because eliding such an lifetime would create an ambiguity).
     let elidable_lts = named_lifetime_occurrences(&input_lts)
         .into_iter()
         .filter_map(|(def_id, occurrences)| {
             if occurrences == 1
                 && (input_lts.len() == 1 || !output_lts.iter().any(|lt| named_lifetime(lt) == Some(def_id)))
             {
                 Some(def_id)
             } else {
                 None
             }
         })
         .collect::<Vec<_>>();

     if elidable_lts.is_empty() {
         return None;
     }

     let usages = itertools::chain(input_lts, output_lts).collect();

     Some((elidable_lts, usages))
 }

 fn allowed_lts_from(named_generics: &[GenericParam<'_>]) -> FxHashSet<LocalDefId> {
     named_generics
         .iter()
         .filter_map(|par| {
             if let GenericParamKind::Lifetime { .. } = par.kind {
                 Some(par.def_id)
             } else {
                 None
             }
         })
         .collect()
 }

 /// Number of times each named lifetime occurs in the given slice. Returns a vector to preserve
 /// relative order.
 #[must_use]
 fn named_lifetime_occurrences(lts: &[Lifetime]) -> Vec<(LocalDefId, usize)> {
     let mut occurrences = Vec::new();
     for lt in lts {
         if let Some(curr_def_id) = named_lifetime(lt) {
             if let Some(pair) = occurrences
                 .iter_mut()
                 .find(|(prev_def_id, _)| *prev_def_id == curr_def_id)
             {
                 pair.1 += 1;
             } else {
                 occurrences.push((curr_def_id, 1));
             }
         }
     }
     occurrences
 }

 struct RefVisitor<'a, 'tcx> {
     cx: &'a LateContext<'tcx>,
     lts: Vec<Lifetime>,
     nested_elision_site_lts: Vec<Lifetime>,
     unelided_trait_object_lifetime: bool,
 }

 impl<'a, 'tcx> RefVisitor<'a, 'tcx> {
     fn new(cx: &'a LateContext<'tcx>) -> Self {
         Self {
             cx,
             lts: Vec::new(),
             nested_elision_site_lts: Vec::new(),
             unelided_trait_object_lifetime: false,
         }
     }

     fn all_lts(&self) -> Vec<Lifetime> {
         self.lts
             .iter()
             .chain(self.nested_elision_site_lts.iter())
             .copied()
             .collect::<Vec<_>>()
     }

     fn abort(&self) -> bool {
         self.unelided_trait_object_lifetime
     }
 }

 impl<'a, 'tcx> Visitor<'tcx> for RefVisitor<'a, 'tcx> {
     // for lifetimes as parameters of generics
     fn visit_lifetime(&mut self, lifetime: &'tcx Lifetime) {
         self.lts.push(*lifetime);
     }

     fn visit_poly_trait_ref(&mut self, poly_tref: &'tcx PolyTraitRef<'tcx>) {
         let trait_ref = &poly_tref.trait_ref;
         if let Some(id) = trait_ref.trait_def_id()
             && lang_items::FN_TRAITS
                 .iter()
                 .any(|&item| self.cx.tcx.lang_items().get(item) == Some(id))
         {
             let mut sub_visitor = RefVisitor::new(self.cx);
             sub_visitor.visit_trait_ref(trait_ref);
             self.nested_elision_site_lts.append(&mut sub_visitor.all_lts());
         } else {
             walk_poly_trait_ref(self, poly_tref);
         }
     }

     fn visit_ty(&mut self, ty: &'tcx Ty<'_>) {
         match ty.kind {
             TyKind::OpaqueDef(item, bounds, _) => {
                 let map = self.cx.tcx.hir();
                 let item = map.item(item);
                 let len = self.lts.len();
                 walk_item(self, item);
                 self.lts.truncate(len);
                 self.lts.extend(bounds.iter().filter_map(|bound| match bound {
                     GenericArg::Lifetime(&l) => Some(l),
                     _ => None,
                 }));
             },
             TyKind::BareFn(&BareFnTy { decl, .. }) => {
                 let mut sub_visitor = RefVisitor::new(self.cx);
                 sub_visitor.visit_fn_decl(decl);
                 self.nested_elision_site_lts.append(&mut sub_visitor.all_lts());
             },
             TyKind::TraitObject(bounds, lt, _) => {
                 if !lt.is_elided() {
                     self.unelided_trait_object_lifetime = true;
                 }
                 for bound in bounds {
                     self.visit_poly_trait_ref(bound);
                 }
             },
             _ => walk_ty(self, ty),
         }
     }
 }

 /// Are any lifetimes mentioned in the `where` clause? If so, we don't try to
 /// reason about elision.
 fn has_where_lifetimes<'tcx>(cx: &LateContext<'tcx>, generics: &'tcx Generics<'_>) -> bool {
     for predicate in generics.predicates {
         match *predicate {
             WherePredicate::RegionPredicate(..) => return true,
             WherePredicate::BoundPredicate(ref pred) => {
                 // a predicate like F: Trait or F: for<'a> Trait<'a>
                 let mut visitor = RefVisitor::new(cx);
                 // walk the type F, it may not contain LT refs
                 walk_ty(&mut visitor, pred.bounded_ty);
                 if !visitor.all_lts().is_empty() {
                     return true;
                 }
                 // if the bounds define new lifetimes, they are fine to occur
                 let allowed_lts = allowed_lts_from(pred.bound_generic_params);
                 // now walk the bounds
                 for bound in pred.bounds {
                     walk_param_bound(&mut visitor, bound);
                 }
                 // and check that all lifetimes are allowed
                 for lt in visitor.all_lts() {
                     if let Some(id) = named_lifetime(&lt)
                         && !allowed_lts.contains(&id)
                     {
                         return true;
                     }
                 }
             },
             WherePredicate::EqPredicate(ref pred) => {
                 let mut visitor = RefVisitor::new(cx);
                 walk_ty(&mut visitor, pred.lhs_ty);
                 walk_ty(&mut visitor, pred.rhs_ty);
                 if !visitor.lts.is_empty() {
                     return true;
                 }
             },
         }
     }
     false
 }

 struct LifetimeChecker<'cx, 'tcx, F> {
     cx: &'cx LateContext<'tcx>,
     map: FxHashMap<Symbol, Span>,
     phantom: std::marker::PhantomData<F>,
 }

 impl<'cx, 'tcx, F> LifetimeChecker<'cx, 'tcx, F> {
     fn new(cx: &'cx LateContext<'tcx>, map: FxHashMap<Symbol, Span>) -> LifetimeChecker<'cx, 'tcx, F> {
         Self {
             cx,
             map,
             phantom: std::marker::PhantomData,
         }
     }
 }

 impl<'cx, 'tcx, F> Visitor<'tcx> for LifetimeChecker<'cx, 'tcx, F>
 where
     F: NestedFilter<'tcx>,
 {
     type Map = Map<'tcx>;
     type NestedFilter = F;

     // for lifetimes as parameters of generics
     fn visit_lifetime(&mut self, lifetime: &'tcx Lifetime) {
         self.map.remove(&lifetime.ident.name);
     }

     fn visit_generic_param(&mut self, param: &'tcx GenericParam<'_>) {
         // don't actually visit `<'a>` or `<'a: 'b>`
         // we've already visited the `'a` declarations and
         // don't want to spuriously remove them
         // `'b` in `'a: 'b` is useless unless used elsewhere in
         // a non-lifetime bound
         if let GenericParamKind::Type { .. } = param.kind {
             walk_generic_param(self, param);
         }
     }

     fn nested_visit_map(&mut self) -> Self::Map {
         self.cx.tcx.hir()
     }
 }

 fn report_extra_lifetimes<'tcx>(cx: &LateContext<'tcx>, func: &'tcx FnDecl<'_>, generics: &'tcx Generics<'_>) {
     let hs = generics
         .params
         .iter()
         .filter_map(|par| match par.kind {
             GenericParamKind::Lifetime {
                 kind: LifetimeParamKind::Explicit,
             } => Some((par.name.ident().name, par.span)),
             _ => None,
         })
         .collect();
     let mut checker = LifetimeChecker::<hir_nested_filter::None>::new(cx, hs);

     walk_generics(&mut checker, generics);
     walk_fn_decl(&mut checker, func);

     for &v in checker.map.values() {
         span_lint(
             cx,
             EXTRA_UNUSED_LIFETIMES,
             v,
             "this lifetime isn't used in the function definition",
         );
     }
 }

 fn report_extra_impl_lifetimes<'tcx>(cx: &LateContext<'tcx>, impl_: &'tcx Impl<'_>) {
     let hs = impl_
         .generics
         .params
         .iter()
         .filter_map(|par| match par.kind {
             GenericParamKind::Lifetime {
                 kind: LifetimeParamKind::Explicit,
             } => Some((par.name.ident().name, par.span)),
             _ => None,
         })
         .collect();
     let mut checker = LifetimeChecker::<middle_nested_filter::All>::new(cx, hs);

     walk_generics(&mut checker, impl_.generics);
     if let Some(ref trait_ref) = impl_.of_trait {
         walk_trait_ref(&mut checker, trait_ref);
     }
     walk_ty(&mut checker, impl_.self_ty);
     for item in impl_.items {
         walk_impl_item_ref(&mut checker, item);
     }

     for &v in checker.map.values() {
         span_lint(cx, EXTRA_UNUSED_LIFETIMES, v, "this lifetime isn't used in the impl");
     }
 }

 struct BodyLifetimeChecker {
     lifetimes_used_in_body: bool,
 }

 impl<'tcx> Visitor<'tcx> for BodyLifetimeChecker {
     // for lifetimes as parameters of generics
     fn visit_lifetime(&mut self, lifetime: &'tcx Lifetime) {
         if !lifetime.is_anonymous() && lifetime.ident.name != kw::StaticLifetime {
             self.lifetimes_used_in_body = true;
         }
     }
 }
	use clippy_utils::diagnostics::{span_lint, span_lint_and_then};
	use clippy_utils::trait_ref_of_method;
	use itertools::Itertools;
	use rustc_data_structures::fx::{FxHashMap, FxHashSet};
	use rustc_errors::Applicability;
	use rustc_hir::intravisit::nested_filter::{self as hir_nested_filter, NestedFilter};
	use rustc_hir::intravisit::{
	walk_fn_decl, walk_generic_param, walk_generics, walk_impl_item_ref, walk_item, walk_param_bound,
	walk_poly_trait_ref, walk_trait_ref, walk_ty, Visitor,
	};
	use rustc_hir::FnRetTy::Return;
	use rustc_hir::{
	lang_items, BareFnTy, BodyId, FnDecl, FnSig, GenericArg, GenericBound, GenericParam, GenericParamKind, Generics,
	Impl, ImplItem, ImplItemKind, Item, ItemKind, Lifetime, LifetimeName, LifetimeParamKind, Node, PolyTraitRef,
	PredicateOrigin, TraitFn, TraitItem, TraitItemKind, Ty, TyKind, WherePredicate,
	};
	use rustc_lint::{LateContext, LateLintPass, LintContext};
	use rustc_middle::hir::map::Map;
	use rustc_middle::hir::nested_filter as middle_nested_filter;
	use rustc_middle::lint::in_external_macro;
	use rustc_session::{declare_lint_pass, declare_tool_lint};
	use rustc_span::def_id::LocalDefId;
	use rustc_span::Span;
	use rustc_span::symbol::{kw, Ident, Symbol};

	declare_clippy_lint! {
	/// ### What it does
	/// Checks for lifetime annotations which can be removed by
	/// relying on lifetime elision.
	///
	/// ### Why is this bad?
	/// The additional lifetimes make the code look more
	/// complicated, while there is nothing out of the ordinary going on. Removing
	/// them leads to more readable code.
	///
	/// ### Known problems
	/// - We bail out if the function has a `where` clause where lifetimes
	/// are mentioned due to potential false positives.
	///
	/// ### Example
	/// ```no_run
	/// // Unnecessary lifetime annotations
	/// fn in_and_out<'a>(x: &'a u8, y: u8) -> &'a u8 {
	/// x
	/// }
	/// ```
	///
	/// Use instead:
	/// ```no_run
	/// fn elided(x: &u8, y: u8) -> &u8 {
	/// x
	/// }
	/// ```
	#[clippy::version = "pre 1.29.0"]
	pub NEEDLESS_LIFETIMES,
	complexity,
	"using explicit lifetimes for references in function arguments when elision rules \
	would allow omitting them"
	}

	declare_clippy_lint! {
	/// ### What it does
	/// Checks for lifetimes in generics that are never used
	/// anywhere else.
	///
	/// ### Why is this bad?
	/// The additional lifetimes make the code look more
	/// complicated, while there is nothing out of the ordinary going on. Removing
	/// them leads to more readable code.
	///
	/// ### Example
	/// ```no_run
	/// // unnecessary lifetimes
	/// fn unused_lifetime<'a>(x: u8) {
	/// // ..
	/// }
	/// ```
	///
	/// Use instead:
	/// ```no_run
	/// fn no_lifetime(x: u8) {
	/// // ...
	/// }
	/// ```
	#[clippy::version = "pre 1.29.0"]
	pub EXTRA_UNUSED_LIFETIMES,
	complexity,
	"unused lifetimes in function definitions"
	}

	declare_lint_pass!(Lifetimes => [NEEDLESS_LIFETIMES, EXTRA_UNUSED_LIFETIMES]);

	impl<'tcx> LateLintPass<'tcx> for Lifetimes {
	fn check_item(&mut self, cx: &LateContext<'tcx>, item: &'tcx Item<'_>) {
	if let ItemKind::Fn(ref sig, generics, id) = item.kind {
	check_fn_inner(cx, sig, Some(id), None, generics, item.span, true);
	} else if let ItemKind::Impl(impl_) = item.kind {
	if !item.span.from_expansion() {
	report_extra_impl_lifetimes(cx, impl_);
	}
	}
	}

	fn check_impl_item(&mut self, cx: &LateContext<'tcx>, item: &'tcx ImplItem<'_>) {
	if let ImplItemKind::Fn(ref sig, id) = item.kind {
	let report_extra_lifetimes = trait_ref_of_method(cx, item.owner_id.def_id).is_none();
	check_fn_inner(
	cx,
	sig,
	Some(id),
	None,
	item.generics,
	item.span,
	report_extra_lifetimes,
	);
	}
	}

	fn check_trait_item(&mut self, cx: &LateContext<'tcx>, item: &'tcx TraitItem<'_>) {
	if let TraitItemKind::Fn(ref sig, ref body) = item.kind {
	let (body, trait_sig) = match *body {
	TraitFn::Required(sig) => (None, Some(sig)),
	TraitFn::Provided(id) => (Some(id), None),
	};
	check_fn_inner(cx, sig, body, trait_sig, item.generics, item.span, true);
	}
	}
	}

	fn check_fn_inner<'tcx>(
	cx: &LateContext<'tcx>,
	sig: &'tcx FnSig<'_>,
	body: Option<BodyId>,
	trait_sig: Option<&[Ident]>,
	generics: &'tcx Generics<'_>,
	span: Span,
	report_extra_lifetimes: bool,
	) {
	if in_external_macro(cx.sess(), span) \|\| has_where_lifetimes(cx, generics) {
	return;
	}

	let types = generics
	.params
	.iter()
	.filter(\|param\| matches!(param.kind, GenericParamKind::Type { .. }));

	for typ in types {
	if !typ.span.eq_ctxt(span) {
	return;
	}

	for pred in generics.bounds_for_param(typ.def_id) {
	if pred.origin == PredicateOrigin::WhereClause {
	// has_where_lifetimes checked that this predicate contains no lifetime.
	continue;
	}

	for bound in pred.bounds {
	let mut visitor = RefVisitor::new(cx);
	walk_param_bound(&mut visitor, bound);
	if visitor.lts.iter().any(\|lt\| matches!(lt.res, LifetimeName::Param(_))) {
	return;
	}
	if let GenericBound::Trait(ref trait_ref, _) = *bound {
	let params = &trait_ref
	.trait_ref
	.path
	.segments
	.last()
	.expect("a path must have at least one segment")
	.args;
	if let Some(params) = *params {
	let lifetimes = params.args.iter().filter_map(\|arg\| match arg {
	GenericArg::Lifetime(lt) => Some(lt),
	_ => None,
	});
	for bound in lifetimes {
	if !bound.is_static() && !bound.is_elided() {
	return;
	}
	}
	}
	}
	}
	}
	}

	if let Some((elidable_lts, usages)) = could_use_elision(cx, sig.decl, body, trait_sig, generics.params) {
	if usages.iter().any(\|usage\| !usage.ident.span.eq_ctxt(span)) {
	return;
	}

	let lts = elidable_lts
	.iter()
	// In principle, the result of the call to `Node::ident` could be `unwrap`ped, as `DefId` should refer to a
	// `Node::GenericParam`.
	.filter_map(\|&def_id\| cx.tcx.hir().get_by_def_id(def_id).ident())
	.map(\|ident\| ident.to_string())
	.collect::<Vec<_>>()
	.join(", ");

	span_lint_and_then(
	cx,
	NEEDLESS_LIFETIMES,
	elidable_lts
	.iter()
	.map(\|&lt\| cx.tcx.def_span(lt))
	.chain(usages.iter().filter_map(\|usage\| {
	if let LifetimeName::Param(def_id) = usage.res
	&& elidable_lts.contains(&def_id)
	{
	return Some(usage.ident.span);
	}

	None
	}))
	.collect_vec(),
	&format!("the following explicit lifetimes could be elided: {lts}"),
	\|diag\| {
	if sig.header.is_async() {
	// async functions have usages whose spans point at the lifetime declaration which messes up
	// suggestions
	return;
	};

	if let Some(suggestions) = elision_suggestions(cx, generics, &elidable_lts, &usages) {
	diag.multipart_suggestion("elide the lifetimes", suggestions, Applicability::MachineApplicable);
	}
	},
	);
	}

	if report_extra_lifetimes {
	self::report_extra_lifetimes(cx, sig.decl, generics);
	}
	}

	fn elision_suggestions(
	cx: &LateContext<'_>,
	generics: &Generics<'_>,
	elidable_lts: &[LocalDefId],
	usages: &[Lifetime],
	) -> Option<Vec<(Span, String)>> {
	let explicit_params = generics
	.params
	.iter()
	.filter(\|param\| !param.is_elided_lifetime() && !param.is_impl_trait())
	.collect::<Vec<_>>();

	let mut suggestions = if elidable_lts.len() == explicit_params.len() {
	// if all the params are elided remove the whole generic block
	//
	// fn x<'a>() {}
	// ^^^^
	vec![(generics.span, String::new())]
	} else {
	elidable_lts
	.iter()
	.map(\|&id\| {
	let pos = explicit_params.iter().position(\|param\| param.def_id == id)?;
	let param = explicit_params.get(pos)?;

	let span = if let Some(next) = explicit_params.get(pos + 1) {
	// fn x<'prev, 'a, 'next>() {}
	// ^^^^
	param.span.until(next.span)
	} else {
	// `pos` should be at least 1 here, because the param in position 0 would either have a `next`
	// param or would have taken the `elidable_lts.len() == explicit_params.len()` branch.
	let prev = explicit_params.get(pos - 1)?;

	// fn x<'prev, 'a>() {}
	// ^^^^
	param.span.with_lo(prev.span.hi())
	};

	Some((span, String::new()))
	})
	.collect::<Option<Vec<_>>>()?
	};

	suggestions.extend(
	usages
	.iter()
	.filter(\|usage\| named_lifetime(usage).map_or(false, \|id\| elidable_lts.contains(&id)))
	.map(\|usage\| {
	match cx.tcx.hir().get_parent(usage.hir_id) {
	Node::Ty(Ty {
	kind: TyKind::Ref(..), ..
	}) => {
	// expand `&'a T` to `&'a T`
	// ^^ ^^^
	let span = cx
	.sess()
	.source_map()
	.span_extend_while(usage.ident.span, \|ch\| ch.is_ascii_whitespace())
	.unwrap_or(usage.ident.span);

	(span, String::new())
	},
	// `T<'a>` and `impl Foo + 'a` should be replaced by `'_`
	_ => (usage.ident.span, String::from("'_")),
	}
	}),
	);

	Some(suggestions)
	}

	// elision doesn't work for explicit self types, see rust-lang/rust#69064
	fn explicit_self_type<'tcx>(cx: &LateContext<'tcx>, func: &FnDecl<'tcx>, ident: Option<Ident>) -> bool {
	if_chain! {
	if let Some(ident) = ident;
	if ident.name == kw::SelfLower;
	if !func.implicit_self.has_implicit_self();

	if let Some(self_ty) = func.inputs.first();
	then {
	let mut visitor = RefVisitor::new(cx);
	visitor.visit_ty(self_ty);

	!visitor.all_lts().is_empty()
	} else {
	false
	}
	}
	}

	fn named_lifetime(lt: &Lifetime) -> Option<LocalDefId> {
	match lt.res {
	LifetimeName::Param(id) if !lt.is_anonymous() => Some(id),
	_ => None,
	}
	}

	fn could_use_elision<'tcx>(
	cx: &LateContext<'tcx>,
	func: &'tcx FnDecl<'_>,
	body: Option<BodyId>,
	trait_sig: Option<&[Ident]>,
	named_generics: &'tcx [GenericParam<'_>],
	) -> Option<(Vec<LocalDefId>, Vec<Lifetime>)> {
	// There are two scenarios where elision works:
	// * no output references, all input references have different LT
	// * output references, exactly one input reference with same LT
	// All lifetimes must be unnamed, 'static or defined without bounds on the
	// level of the current item.

	// check named LTs
	let allowed_lts = allowed_lts_from(named_generics);

	// these will collect all the lifetimes for references in arg/return types
	let mut input_visitor = RefVisitor::new(cx);
	let mut output_visitor = RefVisitor::new(cx);

	// extract lifetimes in input argument types
	for arg in func.inputs {
	input_visitor.visit_ty(arg);
	}
	// extract lifetimes in output type
	if let Return(ty) = func.output {
	output_visitor.visit_ty(ty);
	}
	for lt in named_generics {
	input_visitor.visit_generic_param(lt);
	}

	if input_visitor.abort() \|\| output_visitor.abort() {
	return None;
	}

	let input_lts = input_visitor.lts;
	let output_lts = output_visitor.lts;

	if let Some(trait_sig) = trait_sig {
	if explicit_self_type(cx, func, trait_sig.first().copied()) {
	return None;
	}
	}

	if let Some(body_id) = body {
	let body = cx.tcx.hir().body(body_id);

	let first_ident = body.params.first().and_then(\|param\| param.pat.simple_ident());
	if explicit_self_type(cx, func, first_ident) {
	return None;
	}

	let mut checker = BodyLifetimeChecker {
	lifetimes_used_in_body: false,
	};
	checker.visit_expr(body.value);
	if checker.lifetimes_used_in_body {
	return None;
	}
	}

	// check for lifetimes from higher scopes
	for lt in input_lts.iter().chain(output_lts.iter()) {
	if let Some(id) = named_lifetime(lt)
	&& !allowed_lts.contains(&id)
	{
	return None;
	}
	}

	// check for higher-ranked trait bounds
	if !input_visitor.nested_elision_site_lts.is_empty() \|\| !output_visitor.nested_elision_site_lts.is_empty() {
	let allowed_lts: FxHashSet<_> = allowed_lts.iter().map(\|id\| cx.tcx.item_name(id.to_def_id())).collect();
	for lt in input_visitor.nested_elision_site_lts {
	if allowed_lts.contains(&lt.ident.name) {
	return None;
	}
	}
	for lt in output_visitor.nested_elision_site_lts {
	if allowed_lts.contains(&lt.ident.name) {
	return None;
	}
	}
	}

	// A lifetime can be newly elided if:
	// - It occurs only once among the inputs.
	// - If there are multiple input lifetimes, then the newly elided lifetime does not occur among the
	// outputs (because eliding such an lifetime would create an ambiguity).
	let elidable_lts = named_lifetime_occurrences(&input_lts)
	.into_iter()
	.filter_map(\|(def_id, occurrences)\| {
	if occurrences == 1
	&& (input_lts.len() == 1 \|\| !output_lts.iter().any(\|lt\| named_lifetime(lt) == Some(def_id)))
	{
	Some(def_id)
	} else {
	None
	}
	})
	.collect::<Vec<_>>();

	if elidable_lts.is_empty() {
	return None;
	}

	let usages = itertools::chain(input_lts, output_lts).collect();

	Some((elidable_lts, usages))
	}

	fn allowed_lts_from(named_generics: &[GenericParam<'_>]) -> FxHashSet<LocalDefId> {
	named_generics
	.iter()
	.filter_map(\|par\| {
	if let GenericParamKind::Lifetime { .. } = par.kind {
	Some(par.def_id)
	} else {
	None
	}
	})
	.collect()
	}

	/// Number of times each named lifetime occurs in the given slice. Returns a vector to preserve
	/// relative order.
	#[must_use]
	fn named_lifetime_occurrences(lts: &[Lifetime]) -> Vec<(LocalDefId, usize)> {
	let mut occurrences = Vec::new();
	for lt in lts {
	if let Some(curr_def_id) = named_lifetime(lt) {
	if let Some(pair) = occurrences
	.iter_mut()
	.find(\|(prev_def_id, _)\| *prev_def_id == curr_def_id)
	{
	pair.1 += 1;
	} else {
	occurrences.push((curr_def_id, 1));
	}
	}
	}
	occurrences
	}

	struct RefVisitor<'a, 'tcx> {
	cx: &'a LateContext<'tcx>,
	lts: Vec<Lifetime>,
	nested_elision_site_lts: Vec<Lifetime>,
	unelided_trait_object_lifetime: bool,
	}

	impl<'a, 'tcx> RefVisitor<'a, 'tcx> {
	fn new(cx: &'a LateContext<'tcx>) -> Self {
	Self {
	cx,
	lts: Vec::new(),
	nested_elision_site_lts: Vec::new(),
	unelided_trait_object_lifetime: false,
	}
	}

	fn all_lts(&self) -> Vec<Lifetime> {
	self.lts
	.iter()
	.chain(self.nested_elision_site_lts.iter())
	.copied()
	.collect::<Vec<_>>()
	}

	fn abort(&self) -> bool {
	self.unelided_trait_object_lifetime
	}
	}

	impl<'a, 'tcx> Visitor<'tcx> for RefVisitor<'a, 'tcx> {
	// for lifetimes as parameters of generics
	fn visit_lifetime(&mut self, lifetime: &'tcx Lifetime) {
	self.lts.push(*lifetime);
	}

	fn visit_poly_trait_ref(&mut self, poly_tref: &'tcx PolyTraitRef<'tcx>) {
	let trait_ref = &poly_tref.trait_ref;
	if let Some(id) = trait_ref.trait_def_id()
	&& lang_items::FN_TRAITS
	.iter()
	.any(\|&item\| self.cx.tcx.lang_items().get(item) == Some(id))
	{
	let mut sub_visitor = RefVisitor::new(self.cx);
	sub_visitor.visit_trait_ref(trait_ref);
	self.nested_elision_site_lts.append(&mut sub_visitor.all_lts());
	} else {
	walk_poly_trait_ref(self, poly_tref);
	}
	}

	fn visit_ty(&mut self, ty: &'tcx Ty<'_>) {
	match ty.kind {
	TyKind::OpaqueDef(item, bounds, _) => {
	let map = self.cx.tcx.hir();
	let item = map.item(item);
	let len = self.lts.len();
	walk_item(self, item);
	self.lts.truncate(len);
	self.lts.extend(bounds.iter().filter_map(\|bound\| match bound {
	GenericArg::Lifetime(&l) => Some(l),
	_ => None,
	}));
	},
	TyKind::BareFn(&BareFnTy { decl, .. }) => {
	let mut sub_visitor = RefVisitor::new(self.cx);
	sub_visitor.visit_fn_decl(decl);
	self.nested_elision_site_lts.append(&mut sub_visitor.all_lts());
	},
	TyKind::TraitObject(bounds, lt, _) => {
	if !lt.is_elided() {
	self.unelided_trait_object_lifetime = true;
	}
	for bound in bounds {
	self.visit_poly_trait_ref(bound);
	}
	},
	_ => walk_ty(self, ty),
	}
	}
	}

	/// Are any lifetimes mentioned in the `where` clause? If so, we don't try to
	/// reason about elision.
	fn has_where_lifetimes<'tcx>(cx: &LateContext<'tcx>, generics: &'tcx Generics<'_>) -> bool {
	for predicate in generics.predicates {
	match *predicate {
	WherePredicate::RegionPredicate(..) => return true,
	WherePredicate::BoundPredicate(ref pred) => {
	// a predicate like F: Trait or F: for<'a> Trait<'a>
	let mut visitor = RefVisitor::new(cx);
	// walk the type F, it may not contain LT refs
	walk_ty(&mut visitor, pred.bounded_ty);
	if !visitor.all_lts().is_empty() {
	return true;
	}
	// if the bounds define new lifetimes, they are fine to occur
	let allowed_lts = allowed_lts_from(pred.bound_generic_params);
	// now walk the bounds
	for bound in pred.bounds {
	walk_param_bound(&mut visitor, bound);
	}
	// and check that all lifetimes are allowed
	for lt in visitor.all_lts() {
	if let Some(id) = named_lifetime(&lt)
	&& !allowed_lts.contains(&id)
	{
	return true;
	}
	}
	},
	WherePredicate::EqPredicate(ref pred) => {
	let mut visitor = RefVisitor::new(cx);
	walk_ty(&mut visitor, pred.lhs_ty);
	walk_ty(&mut visitor, pred.rhs_ty);
	if !visitor.lts.is_empty() {
	return true;
	}
	},
	}
	}
	false
	}

	struct LifetimeChecker<'cx, 'tcx, F> {
	cx: &'cx LateContext<'tcx>,
	map: FxHashMap<Symbol, Span>,
	phantom: std::marker::PhantomData<F>,
	}

	impl<'cx, 'tcx, F> LifetimeChecker<'cx, 'tcx, F> {
	fn new(cx: &'cx LateContext<'tcx>, map: FxHashMap<Symbol, Span>) -> LifetimeChecker<'cx, 'tcx, F> {
	Self {
	cx,
	map,
	phantom: std::marker::PhantomData,
	}
	}
	}

	impl<'cx, 'tcx, F> Visitor<'tcx> for LifetimeChecker<'cx, 'tcx, F>
	where
	F: NestedFilter<'tcx>,
	{
	type Map = Map<'tcx>;
	type NestedFilter = F;

	// for lifetimes as parameters of generics
	fn visit_lifetime(&mut self, lifetime: &'tcx Lifetime) {
	self.map.remove(&lifetime.ident.name);
	}

	fn visit_generic_param(&mut self, param: &'tcx GenericParam<'_>) {
	// don't actually visit `<'a>` or `<'a: 'b>`
	// we've already visited the `'a` declarations and
	// don't want to spuriously remove them
	// `'b` in `'a: 'b` is useless unless used elsewhere in
	// a non-lifetime bound
	if let GenericParamKind::Type { .. } = param.kind {
	walk_generic_param(self, param);
	}
	}

	fn nested_visit_map(&mut self) -> Self::Map {
	self.cx.tcx.hir()
	}
	}

	fn report_extra_lifetimes<'tcx>(cx: &LateContext<'tcx>, func: &'tcx FnDecl<'_>, generics: &'tcx Generics<'_>) {
	let hs = generics
	.params
	.iter()
	.filter_map(\|par\| match par.kind {
	GenericParamKind::Lifetime {
	kind: LifetimeParamKind::Explicit,
	} => Some((par.name.ident().name, par.span)),
	_ => None,
	})
	.collect();
	let mut checker = LifetimeChecker::<hir_nested_filter::None>::new(cx, hs);

	walk_generics(&mut checker, generics);
	walk_fn_decl(&mut checker, func);

	for &v in checker.map.values() {
	span_lint(
	cx,
	EXTRA_UNUSED_LIFETIMES,
	v,
	"this lifetime isn't used in the function definition",
	);
	}
	}

	fn report_extra_impl_lifetimes<'tcx>(cx: &LateContext<'tcx>, impl_: &'tcx Impl<'_>) {
	let hs = impl_
	.generics
	.params
	.iter()
	.filter_map(\|par\| match par.kind {
	GenericParamKind::Lifetime {
	kind: LifetimeParamKind::Explicit,
	} => Some((par.name.ident().name, par.span)),
	_ => None,
	})
	.collect();
	let mut checker = LifetimeChecker::<middle_nested_filter::All>::new(cx, hs);

	walk_generics(&mut checker, impl_.generics);
	if let Some(ref trait_ref) = impl_.of_trait {
	walk_trait_ref(&mut checker, trait_ref);
	}
	walk_ty(&mut checker, impl_.self_ty);
	for item in impl_.items {
	walk_impl_item_ref(&mut checker, item);
	}

	for &v in checker.map.values() {
	span_lint(cx, EXTRA_UNUSED_LIFETIMES, v, "this lifetime isn't used in the impl");
	}
	}

	struct BodyLifetimeChecker {
	lifetimes_used_in_body: bool,
	}

	impl<'tcx> Visitor<'tcx> for BodyLifetimeChecker {
	// for lifetimes as parameters of generics
	fn visit_lifetime(&mut self, lifetime: &'tcx Lifetime) {
	if !lifetime.is_anonymous() && lifetime.ident.name != kw::StaticLifetime {
	self.lifetimes_used_in_body = true;
	}
	}
	}