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

 use clippy_utils::diagnostics::span_lint_and_sugg;
 use clippy_utils::source::{reindent_multiline, snippet_indent, snippet_with_applicability, snippet_with_context};
 use clippy_utils::{
     can_move_expr_to_closure_no_visit, higher, is_expr_final_block_expr, is_expr_used_or_unified, match_def_path,
     paths, peel_hir_expr_while, SpanlessEq,
 };
 use core::fmt::{self, Write};
 use rustc_errors::Applicability;
 use rustc_hir::hir_id::HirIdSet;
 use rustc_hir::intravisit::{walk_expr, Visitor};
 use rustc_hir::{Block, Expr, ExprKind, Guard, HirId, Let, Pat, Stmt, StmtKind, UnOp};
 use rustc_lint::{LateContext, LateLintPass};
 use rustc_session::{declare_lint_pass, declare_tool_lint};
 use rustc_span::{Span, SyntaxContext, DUMMY_SP};

 declare_clippy_lint! {
     /// ### What it does
     /// Checks for usage of `contains_key` + `insert` on `HashMap`
     /// or `BTreeMap`.
     ///
     /// ### Why is this bad?
     /// Using `entry` is more efficient.
     ///
     /// ### Known problems
     /// The suggestion may have type inference errors in some cases. e.g.
     /// ```rust
     /// let mut map = std::collections::HashMap::new();
     /// let _ = if !map.contains_key(&0) {
     ///     map.insert(0, 0)
     /// } else {
     ///     None
     /// };
     /// ```
     ///
     /// ### Example
     /// ```rust
     /// # use std::collections::HashMap;
     /// # let mut map = HashMap::new();
     /// # let k = 1;
     /// # let v = 1;
     /// if !map.contains_key(&k) {
     ///     map.insert(k, v);
     /// }
     /// ```
     /// Use instead:
     /// ```rust
     /// # use std::collections::HashMap;
     /// # let mut map = HashMap::new();
     /// # let k = 1;
     /// # let v = 1;
     /// map.entry(k).or_insert(v);
     /// ```
     #[clippy::version = "pre 1.29.0"]
     pub MAP_ENTRY,
     perf,
     "use of `contains_key` followed by `insert` on a `HashMap` or `BTreeMap`"
 }

 declare_lint_pass!(HashMapPass => [MAP_ENTRY]);

 impl<'tcx> LateLintPass<'tcx> for HashMapPass {
     #[expect(clippy::too_many_lines)]
     fn check_expr(&mut self, cx: &LateContext<'tcx>, expr: &'tcx Expr<'_>) {
         if expr.span.from_expansion() {
             return;
         }

         let Some(higher::If {
             cond: cond_expr,
             then: then_expr,
             r#else: else_expr,
         }) = higher::If::hir(expr)
         else {
             return;
         };

         let Some((map_ty, contains_expr)) = try_parse_contains(cx, cond_expr) else {
             return;
         };

         let Some(then_search) = find_insert_calls(cx, &contains_expr, then_expr) else {
             return;
         };

         let mut app = Applicability::MachineApplicable;
         let map_str = snippet_with_context(cx, contains_expr.map.span, contains_expr.call_ctxt, "..", &mut app).0;
         let key_str = snippet_with_context(cx, contains_expr.key.span, contains_expr.call_ctxt, "..", &mut app).0;
         let sugg = if let Some(else_expr) = else_expr {
             let Some(else_search) = find_insert_calls(cx, &contains_expr, else_expr) else {
                 return;
             };

             if then_search.edits.is_empty() && else_search.edits.is_empty() {
                 // No insertions
                 return;
             } else if then_search.edits.is_empty() || else_search.edits.is_empty() {
                 // if .. { insert } else { .. } or if .. { .. } else { insert }
                 let ((then_str, entry_kind), else_str) = match (else_search.edits.is_empty(), contains_expr.negated) {
                     (true, true) => (
                         then_search.snippet_vacant(cx, then_expr.span, &mut app),
                         snippet_with_applicability(cx, else_expr.span, "{ .. }", &mut app),
                     ),
                     (true, false) => (
                         then_search.snippet_occupied(cx, then_expr.span, &mut app),
                         snippet_with_applicability(cx, else_expr.span, "{ .. }", &mut app),
                     ),
                     (false, true) => (
                         else_search.snippet_occupied(cx, else_expr.span, &mut app),
                         snippet_with_applicability(cx, then_expr.span, "{ .. }", &mut app),
                     ),
                     (false, false) => (
                         else_search.snippet_vacant(cx, else_expr.span, &mut app),
                         snippet_with_applicability(cx, then_expr.span, "{ .. }", &mut app),
                     ),
                 };
                 format!(
                     "if let {}::{entry_kind} = {map_str}.entry({key_str}) {then_str} else {else_str}",
                     map_ty.entry_path(),
                 )
             } else {
                 // if .. { insert } else { insert }
                 let ((then_str, then_entry), (else_str, else_entry)) = if contains_expr.negated {
                     (
                         then_search.snippet_vacant(cx, then_expr.span, &mut app),
                         else_search.snippet_occupied(cx, else_expr.span, &mut app),
                     )
                 } else {
                     (
                         then_search.snippet_occupied(cx, then_expr.span, &mut app),
                         else_search.snippet_vacant(cx, else_expr.span, &mut app),
                     )
                 };
                 let indent_str = snippet_indent(cx, expr.span);
                 let indent_str = indent_str.as_deref().unwrap_or("");
                 format!(
                     "match {map_str}.entry({key_str}) {{\n{indent_str}    {entry}::{then_entry} => {}\n\
                         {indent_str}    {entry}::{else_entry} => {}\n{indent_str}}}",
                     reindent_multiline(then_str.into(), true, Some(4 + indent_str.len())),
                     reindent_multiline(else_str.into(), true, Some(4 + indent_str.len())),
                     entry = map_ty.entry_path(),
                 )
             }
         } else {
             if then_search.edits.is_empty() {
                 // no insertions
                 return;
             }

             // if .. { insert }
             if !then_search.allow_insert_closure {
                 let (body_str, entry_kind) = if contains_expr.negated {
                     then_search.snippet_vacant(cx, then_expr.span, &mut app)
                 } else {
                     then_search.snippet_occupied(cx, then_expr.span, &mut app)
                 };
                 format!(
                     "if let {}::{entry_kind} = {map_str}.entry({key_str}) {body_str}",
                     map_ty.entry_path(),
                 )
             } else if let Some(insertion) = then_search.as_single_insertion() {
                 let value_str = snippet_with_context(cx, insertion.value.span, then_expr.span.ctxt(), "..", &mut app).0;
                 if contains_expr.negated {
                     if insertion.value.can_have_side_effects() {
                         format!("{map_str}.entry({key_str}).or_insert_with(|| {value_str});")
                     } else {
                         format!("{map_str}.entry({key_str}).or_insert({value_str});")
                     }
                 } else {
                     // TODO: suggest using `if let Some(v) = map.get_mut(k) { .. }` here.
                     // This would need to be a different lint.
                     return;
                 }
             } else {
                 let block_str = then_search.snippet_closure(cx, then_expr.span, &mut app);
                 if contains_expr.negated {
                     format!("{map_str}.entry({key_str}).or_insert_with(|| {block_str});")
                 } else {
                     // TODO: suggest using `if let Some(v) = map.get_mut(k) { .. }` here.
                     // This would need to be a different lint.
                     return;
                 }
             }
         };

         span_lint_and_sugg(
             cx,
             MAP_ENTRY,
             expr.span,
             &format!("usage of `contains_key` followed by `insert` on a `{}`", map_ty.name()),
             "try",
             sugg,
             app,
         );
     }
 }

 #[derive(Clone, Copy)]
 enum MapType {
     Hash,
     BTree,
 }
 impl MapType {
     fn name(self) -> &'static str {
         match self {
             Self::Hash => "HashMap",
             Self::BTree => "BTreeMap",
         }
     }
     fn entry_path(self) -> &'static str {
         match self {
             Self::Hash => "std::collections::hash_map::Entry",
             Self::BTree => "std::collections::btree_map::Entry",
         }
     }
 }

 struct ContainsExpr<'tcx> {
     negated: bool,
     map: &'tcx Expr<'tcx>,
     key: &'tcx Expr<'tcx>,
     call_ctxt: SyntaxContext,
 }
 fn try_parse_contains<'tcx>(cx: &LateContext<'_>, expr: &'tcx Expr<'_>) -> Option<(MapType, ContainsExpr<'tcx>)> {
     let mut negated = false;
     let expr = peel_hir_expr_while(expr, |e| match e.kind {
         ExprKind::Unary(UnOp::Not, e) => {
             negated = !negated;
             Some(e)
         },
         _ => None,
     });
     match expr.kind {
         ExprKind::MethodCall(
             _,
             map,
             [
                 Expr {
                     kind: ExprKind::AddrOf(_, _, key),
                     span: key_span,
                     ..
                 },
             ],
             _,
         ) if key_span.ctxt() == expr.span.ctxt() => {
             let id = cx.typeck_results().type_dependent_def_id(expr.hir_id)?;
             let expr = ContainsExpr {
                 negated,
                 map,
                 key,
                 call_ctxt: expr.span.ctxt(),
             };
             if match_def_path(cx, id, &paths::BTREEMAP_CONTAINS_KEY) {
                 Some((MapType::BTree, expr))
             } else if match_def_path(cx, id, &paths::HASHMAP_CONTAINS_KEY) {
                 Some((MapType::Hash, expr))
             } else {
                 None
             }
         },
         _ => None,
     }
 }

 struct InsertExpr<'tcx> {
     map: &'tcx Expr<'tcx>,
     key: &'tcx Expr<'tcx>,
     value: &'tcx Expr<'tcx>,
 }
 fn try_parse_insert<'tcx>(cx: &LateContext<'tcx>, expr: &'tcx Expr<'_>) -> Option<InsertExpr<'tcx>> {
     if let ExprKind::MethodCall(_, map, [key, value], _) = expr.kind {
         let id = cx.typeck_results().type_dependent_def_id(expr.hir_id)?;
         if match_def_path(cx, id, &paths::BTREEMAP_INSERT) || match_def_path(cx, id, &paths::HASHMAP_INSERT) {
             Some(InsertExpr { map, key, value })
         } else {
             None
         }
     } else {
         None
     }
 }

 /// An edit that will need to be made to move the expression to use the entry api
 #[derive(Clone, Copy)]
 enum Edit<'tcx> {
     /// A semicolon that needs to be removed. Used to create a closure for `insert_with`.
     RemoveSemi(Span),
     /// An insertion into the map.
     Insertion(Insertion<'tcx>),
 }
 impl<'tcx> Edit<'tcx> {
     fn as_insertion(self) -> Option<Insertion<'tcx>> {
         if let Self::Insertion(i) = self { Some(i) } else { None }
     }
 }
 #[derive(Clone, Copy)]
 struct Insertion<'tcx> {
     call: &'tcx Expr<'tcx>,
     value: &'tcx Expr<'tcx>,
 }

 /// This visitor needs to do a multiple things:
 /// * Find all usages of the map. An insertion can only be made before any other usages of the map.
 /// * Determine if there's an insertion using the same key. There's no need for the entry api
 ///   otherwise.
 /// * Determine if the final statement executed is an insertion. This is needed to use
 ///   `or_insert_with`.
 /// * Determine if there's any sub-expression that can't be placed in a closure.
 /// * Determine if there's only a single insert statement. `or_insert` can be used in this case.
 #[expect(clippy::struct_excessive_bools)]
 struct InsertSearcher<'cx, 'tcx> {
     cx: &'cx LateContext<'tcx>,
     /// The map expression used in the contains call.
     map: &'tcx Expr<'tcx>,
     /// The key expression used in the contains call.
     key: &'tcx Expr<'tcx>,
     /// The context of the top level block. All insert calls must be in the same context.
     ctxt: SyntaxContext,
     /// Whether this expression can be safely moved into a closure.
     allow_insert_closure: bool,
     /// Whether this expression can use the entry api.
     can_use_entry: bool,
     /// Whether this expression is the final expression in this code path. This may be a statement.
     in_tail_pos: bool,
     // Is this expression a single insert. A slightly better suggestion can be made in this case.
     is_single_insert: bool,
     /// If the visitor has seen the map being used.
     is_map_used: bool,
     /// The locations where changes need to be made for the suggestion.
     edits: Vec<Edit<'tcx>>,
     /// A stack of loops the visitor is currently in.
     loops: Vec<HirId>,
     /// Local variables created in the expression. These don't need to be captured.
     locals: HirIdSet,
 }
 impl<'tcx> InsertSearcher<'_, 'tcx> {
     /// Visit the expression as a branch in control flow. Multiple insert calls can be used, but
     /// only if they are on separate code paths. This will return whether the map was used in the
     /// given expression.
     fn visit_cond_arm(&mut self, e: &'tcx Expr<'_>) -> bool {
         let is_map_used = self.is_map_used;
         let in_tail_pos = self.in_tail_pos;
         self.visit_expr(e);
         let res = self.is_map_used;
         self.is_map_used = is_map_used;
         self.in_tail_pos = in_tail_pos;
         res
     }

     /// Visits an expression which is not itself in a tail position, but other sibling expressions
     /// may be. e.g. if conditions
     fn visit_non_tail_expr(&mut self, e: &'tcx Expr<'_>) {
         let in_tail_pos = self.in_tail_pos;
         self.in_tail_pos = false;
         self.visit_expr(e);
         self.in_tail_pos = in_tail_pos;
     }
 }
 impl<'tcx> Visitor<'tcx> for InsertSearcher<'_, 'tcx> {
     fn visit_stmt(&mut self, stmt: &'tcx Stmt<'_>) {
         match stmt.kind {
             StmtKind::Semi(e) => {
                 self.visit_expr(e);

                 if self.in_tail_pos && self.allow_insert_closure {
                     // The spans are used to slice the top level expression into multiple parts. This requires that
                     // they all come from the same part of the source code.
                     if stmt.span.ctxt() == self.ctxt && e.span.ctxt() == self.ctxt {
                         self.edits
                             .push(Edit::RemoveSemi(stmt.span.trim_start(e.span).unwrap_or(DUMMY_SP)));
                     } else {
                         self.allow_insert_closure = false;
                     }
                 }
             },
             StmtKind::Expr(e) => self.visit_expr(e),
             StmtKind::Local(l) => {
                 self.visit_pat(l.pat);
                 if let Some(e) = l.init {
                     self.allow_insert_closure &= !self.in_tail_pos;
                     self.in_tail_pos = false;
                     self.is_single_insert = false;
                     self.visit_expr(e);
                 }
             },
             StmtKind::Item(_) => {
                 self.allow_insert_closure &= !self.in_tail_pos;
                 self.is_single_insert = false;
             },
         }
     }

     fn visit_block(&mut self, block: &'tcx Block<'_>) {
         // If the block is in a tail position, then the last expression (possibly a statement) is in the
         // tail position. The rest, however, are not.
         match (block.stmts, block.expr) {
             ([], None) => {
                 self.allow_insert_closure &= !self.in_tail_pos;
             },
             ([], Some(expr)) => self.visit_expr(expr),
             (stmts, Some(expr)) => {
                 let in_tail_pos = self.in_tail_pos;
                 self.in_tail_pos = false;
                 for stmt in stmts {
                     self.visit_stmt(stmt);
                 }
                 self.in_tail_pos = in_tail_pos;
                 self.visit_expr(expr);
             },
             ([stmts @ .., stmt], None) => {
                 let in_tail_pos = self.in_tail_pos;
                 self.in_tail_pos = false;
                 for stmt in stmts {
                     self.visit_stmt(stmt);
                 }
                 self.in_tail_pos = in_tail_pos;
                 self.visit_stmt(stmt);
             },
         }
     }

     fn visit_expr(&mut self, expr: &'tcx Expr<'_>) {
         if !self.can_use_entry {
             return;
         }

         match try_parse_insert(self.cx, expr) {
             Some(insert_expr) if SpanlessEq::new(self.cx).eq_expr(self.map, insert_expr.map) => {
                 // Multiple inserts, inserts with a different key, and inserts from a macro can't use the entry api.
                 if self.is_map_used
                     || !SpanlessEq::new(self.cx).eq_expr(self.key, insert_expr.key)
                     || expr.span.ctxt() != self.ctxt
                 {
                     self.can_use_entry = false;
                     return;
                 }

                 self.edits.push(Edit::Insertion(Insertion {
                     call: expr,
                     value: insert_expr.value,
                 }));
                 self.is_map_used = true;
                 self.allow_insert_closure &= self.in_tail_pos;

                 // The value doesn't affect whether there is only a single insert expression.
                 let is_single_insert = self.is_single_insert;
                 self.visit_non_tail_expr(insert_expr.value);
                 self.is_single_insert = is_single_insert;
             },
             _ if SpanlessEq::new(self.cx).eq_expr(self.map, expr) => {
                 self.is_map_used = true;
             },
             _ => match expr.kind {
                 ExprKind::If(cond_expr, then_expr, Some(else_expr)) => {
                     self.is_single_insert = false;
                     self.visit_non_tail_expr(cond_expr);
                     // Each branch may contain it's own insert expression.
                     let mut is_map_used = self.visit_cond_arm(then_expr);
                     is_map_used |= self.visit_cond_arm(else_expr);
                     self.is_map_used = is_map_used;
                 },
                 ExprKind::Match(scrutinee_expr, arms, _) => {
                     self.is_single_insert = false;
                     self.visit_non_tail_expr(scrutinee_expr);
                     // Each branch may contain it's own insert expression.
                     let mut is_map_used = self.is_map_used;
                     for arm in arms {
                         self.visit_pat(arm.pat);
                         if let Some(Guard::If(guard) | Guard::IfLet(&Let { init: guard, .. })) = arm.guard {
                             self.visit_non_tail_expr(guard);
                         }
                         is_map_used |= self.visit_cond_arm(arm.body);
                     }
                     self.is_map_used = is_map_used;
                 },
                 ExprKind::Loop(block, ..) => {
                     self.loops.push(expr.hir_id);
                     self.is_single_insert = false;
                     self.allow_insert_closure &= !self.in_tail_pos;
                     // Don't allow insertions inside of a loop.
                     let edit_len = self.edits.len();
                     self.visit_block(block);
                     if self.edits.len() != edit_len {
                         self.can_use_entry = false;
                     }
                     self.loops.pop();
                 },
                 ExprKind::Block(block, _) => self.visit_block(block),
                 ExprKind::InlineAsm(_) => {
                     self.can_use_entry = false;
                 },
                 _ => {
                     self.allow_insert_closure &= !self.in_tail_pos;
                     self.allow_insert_closure &=
                         can_move_expr_to_closure_no_visit(self.cx, expr, &self.loops, &self.locals);
                     // Sub expressions are no longer in the tail position.
                     self.is_single_insert = false;
                     self.in_tail_pos = false;
                     walk_expr(self, expr);
                 },
             },
         }
     }

     fn visit_pat(&mut self, p: &'tcx Pat<'tcx>) {
         p.each_binding_or_first(&mut |_, id, _, _| {
             self.locals.insert(id);
         });
     }
 }

 struct InsertSearchResults<'tcx> {
     edits: Vec<Edit<'tcx>>,
     allow_insert_closure: bool,
     is_single_insert: bool,
 }
 impl<'tcx> InsertSearchResults<'tcx> {
     fn as_single_insertion(&self) -> Option<Insertion<'tcx>> {
         self.is_single_insert.then(|| self.edits[0].as_insertion().unwrap())
     }

     fn snippet(
         &self,
         cx: &LateContext<'_>,
         mut span: Span,
         app: &mut Applicability,
         write_wrapped: impl Fn(&mut String, Insertion<'_>, SyntaxContext, &mut Applicability),
     ) -> String {
         let ctxt = span.ctxt();
         let mut res = String::new();
         for insertion in self.edits.iter().filter_map(|e| e.as_insertion()) {
             res.push_str(&snippet_with_applicability(
                 cx,
                 span.until(insertion.call.span),
                 "..",
                 app,
             ));
             if is_expr_used_or_unified(cx.tcx, insertion.call) {
                 write_wrapped(&mut res, insertion, ctxt, app);
             } else {
                 let _: fmt::Result = write!(
                     res,
                     "e.insert({})",
                     snippet_with_context(cx, insertion.value.span, ctxt, "..", app).0
                 );
             }
             span = span.trim_start(insertion.call.span).unwrap_or(DUMMY_SP);
         }
         res.push_str(&snippet_with_applicability(cx, span, "..", app));
         res
     }

     fn snippet_occupied(&self, cx: &LateContext<'_>, span: Span, app: &mut Applicability) -> (String, &'static str) {
         (
             self.snippet(cx, span, app, |res, insertion, ctxt, app| {
                 // Insertion into a map would return `Some(&mut value)`, but the entry returns `&mut value`
                 let _: fmt::Result = write!(
                     res,
                     "Some(e.insert({}))",
                     snippet_with_context(cx, insertion.value.span, ctxt, "..", app).0
                 );
             }),
             "Occupied(mut e)",
         )
     }

     fn snippet_vacant(&self, cx: &LateContext<'_>, span: Span, app: &mut Applicability) -> (String, &'static str) {
         (
             self.snippet(cx, span, app, |res, insertion, ctxt, app| {
                 // Insertion into a map would return `None`, but the entry returns a mutable reference.
                 let _: fmt::Result = if is_expr_final_block_expr(cx.tcx, insertion.call) {
                     write!(
                         res,
                         "e.insert({});\n{}None",
                         snippet_with_context(cx, insertion.value.span, ctxt, "..", app).0,
                         snippet_indent(cx, insertion.call.span).as_deref().unwrap_or(""),
                     )
                 } else {
                     write!(
                         res,
                         "{{ e.insert({}); None }}",
                         snippet_with_context(cx, insertion.value.span, ctxt, "..", app).0,
                     )
                 };
             }),
             "Vacant(e)",
         )
     }

     fn snippet_closure(&self, cx: &LateContext<'_>, mut span: Span, app: &mut Applicability) -> String {
         let ctxt = span.ctxt();
         let mut res = String::new();
         for edit in &self.edits {
             match *edit {
                 Edit::Insertion(insertion) => {
                     // Cut out the value from `map.insert(key, value)`
                     res.push_str(&snippet_with_applicability(
                         cx,
                         span.until(insertion.call.span),
                         "..",
                         app,
                     ));
                     res.push_str(&snippet_with_context(cx, insertion.value.span, ctxt, "..", app).0);
                     span = span.trim_start(insertion.call.span).unwrap_or(DUMMY_SP);
                 },
                 Edit::RemoveSemi(semi_span) => {
                     // Cut out the semicolon. This allows the value to be returned from the closure.
                     res.push_str(&snippet_with_applicability(cx, span.until(semi_span), "..", app));
                     span = span.trim_start(semi_span).unwrap_or(DUMMY_SP);
                 },
             }
         }
         res.push_str(&snippet_with_applicability(cx, span, "..", app));
         res
     }
 }

 fn find_insert_calls<'tcx>(
     cx: &LateContext<'tcx>,
     contains_expr: &ContainsExpr<'tcx>,
     expr: &'tcx Expr<'_>,
 ) -> Option<InsertSearchResults<'tcx>> {
     let mut s = InsertSearcher {
         cx,
         map: contains_expr.map,
         key: contains_expr.key,
         ctxt: expr.span.ctxt(),
         edits: Vec::new(),
         is_map_used: false,
         allow_insert_closure: true,
         can_use_entry: true,
         in_tail_pos: true,
         is_single_insert: true,
         loops: Vec::new(),
         locals: HirIdSet::default(),
     };
     s.visit_expr(expr);
     let allow_insert_closure = s.allow_insert_closure;
     let is_single_insert = s.is_single_insert;
     let edits = s.edits;
     s.can_use_entry.then_some(InsertSearchResults {
         edits,
         allow_insert_closure,
         is_single_insert,
     })
 }
	use clippy_utils::diagnostics::span_lint_and_sugg;
	use clippy_utils::source::{reindent_multiline, snippet_indent, snippet_with_applicability, snippet_with_context};
	use clippy_utils::{
	can_move_expr_to_closure_no_visit, higher, is_expr_final_block_expr, is_expr_used_or_unified, match_def_path,
	paths, peel_hir_expr_while, SpanlessEq,
	};
	use core::fmt::{self, Write};
	use rustc_errors::Applicability;
	use rustc_hir::hir_id::HirIdSet;
	use rustc_hir::intravisit::{walk_expr, Visitor};
	use rustc_hir::{Block, Expr, ExprKind, Guard, HirId, Let, Pat, Stmt, StmtKind, UnOp};
	use rustc_lint::{LateContext, LateLintPass};
	use rustc_session::{declare_lint_pass, declare_tool_lint};
	use rustc_span::{Span, SyntaxContext, DUMMY_SP};

	declare_clippy_lint! {
	/// ### What it does
	/// Checks for usage of `contains_key` + `insert` on `HashMap`
	/// or `BTreeMap`.
	///
	/// ### Why is this bad?
	/// Using `entry` is more efficient.
	///
	/// ### Known problems
	/// The suggestion may have type inference errors in some cases. e.g.
	/// ```rust
	/// let mut map = std::collections::HashMap::new();
	/// let _ = if !map.contains_key(&0) {
	/// map.insert(0, 0)
	/// } else {
	/// None
	/// };
	/// ```
	///
	/// ### Example
	/// ```rust
	/// # use std::collections::HashMap;
	/// # let mut map = HashMap::new();
	/// # let k = 1;
	/// # let v = 1;
	/// if !map.contains_key(&k) {
	/// map.insert(k, v);
	/// }
	/// ```
	/// Use instead:
	/// ```rust
	/// # use std::collections::HashMap;
	/// # let mut map = HashMap::new();
	/// # let k = 1;
	/// # let v = 1;
	/// map.entry(k).or_insert(v);
	/// ```
	#[clippy::version = "pre 1.29.0"]
	pub MAP_ENTRY,
	perf,
	"use of `contains_key` followed by `insert` on a `HashMap` or `BTreeMap`"
	}

	declare_lint_pass!(HashMapPass => [MAP_ENTRY]);

	impl<'tcx> LateLintPass<'tcx> for HashMapPass {
	#[expect(clippy::too_many_lines)]
	fn check_expr(&mut self, cx: &LateContext<'tcx>, expr: &'tcx Expr<'_>) {
	if expr.span.from_expansion() {
	return;
	}

	let Some(higher::If {
	cond: cond_expr,
	then: then_expr,
	r#else: else_expr,
	}) = higher::If::hir(expr)
	else {
	return;
	};

	let Some((map_ty, contains_expr)) = try_parse_contains(cx, cond_expr) else {
	return;
	};

	let Some(then_search) = find_insert_calls(cx, &contains_expr, then_expr) else {
	return;
	};

	let mut app = Applicability::MachineApplicable;
	let map_str = snippet_with_context(cx, contains_expr.map.span, contains_expr.call_ctxt, "..", &mut app).0;
	let key_str = snippet_with_context(cx, contains_expr.key.span, contains_expr.call_ctxt, "..", &mut app).0;
	let sugg = if let Some(else_expr) = else_expr {
	let Some(else_search) = find_insert_calls(cx, &contains_expr, else_expr) else {
	return;
	};

	if then_search.edits.is_empty() && else_search.edits.is_empty() {
	// No insertions
	return;
	} else if then_search.edits.is_empty() \|\| else_search.edits.is_empty() {
	// if .. { insert } else { .. } or if .. { .. } else { insert }
	let ((then_str, entry_kind), else_str) = match (else_search.edits.is_empty(), contains_expr.negated) {
	(true, true) => (
	then_search.snippet_vacant(cx, then_expr.span, &mut app),
	snippet_with_applicability(cx, else_expr.span, "{ .. }", &mut app),
	),
	(true, false) => (
	then_search.snippet_occupied(cx, then_expr.span, &mut app),
	snippet_with_applicability(cx, else_expr.span, "{ .. }", &mut app),
	),
	(false, true) => (
	else_search.snippet_occupied(cx, else_expr.span, &mut app),
	snippet_with_applicability(cx, then_expr.span, "{ .. }", &mut app),
	),
	(false, false) => (
	else_search.snippet_vacant(cx, else_expr.span, &mut app),
	snippet_with_applicability(cx, then_expr.span, "{ .. }", &mut app),
	),
	};
	format!(
	"if let {}::{entry_kind} = {map_str}.entry({key_str}) {then_str} else {else_str}",
	map_ty.entry_path(),
	)
	} else {
	// if .. { insert } else { insert }
	let ((then_str, then_entry), (else_str, else_entry)) = if contains_expr.negated {
	(
	then_search.snippet_vacant(cx, then_expr.span, &mut app),
	else_search.snippet_occupied(cx, else_expr.span, &mut app),
	)
	} else {
	(
	then_search.snippet_occupied(cx, then_expr.span, &mut app),
	else_search.snippet_vacant(cx, else_expr.span, &mut app),
	)
	};
	let indent_str = snippet_indent(cx, expr.span);
	let indent_str = indent_str.as_deref().unwrap_or("");
	format!(
	"match {map_str}.entry({key_str}) {{\n{indent_str} {entry}::{then_entry} => {}\n\
	{indent_str} {entry}::{else_entry} => {}\n{indent_str}}}",
	reindent_multiline(then_str.into(), true, Some(4 + indent_str.len())),
	reindent_multiline(else_str.into(), true, Some(4 + indent_str.len())),
	entry = map_ty.entry_path(),
	)
	}
	} else {
	if then_search.edits.is_empty() {
	// no insertions
	return;
	}

	// if .. { insert }
	if !then_search.allow_insert_closure {
	let (body_str, entry_kind) = if contains_expr.negated {
	then_search.snippet_vacant(cx, then_expr.span, &mut app)
	} else {
	then_search.snippet_occupied(cx, then_expr.span, &mut app)
	};
	format!(
	"if let {}::{entry_kind} = {map_str}.entry({key_str}) {body_str}",
	map_ty.entry_path(),
	)
	} else if let Some(insertion) = then_search.as_single_insertion() {
	let value_str = snippet_with_context(cx, insertion.value.span, then_expr.span.ctxt(), "..", &mut app).0;
	if contains_expr.negated {
	if insertion.value.can_have_side_effects() {
	format!("{map_str}.entry({key_str}).or_insert_with(\|\| {value_str});")
	} else {
	format!("{map_str}.entry({key_str}).or_insert({value_str});")
	}
	} else {
	// TODO: suggest using `if let Some(v) = map.get_mut(k) { .. }` here.
	// This would need to be a different lint.
	return;
	}
	} else {
	let block_str = then_search.snippet_closure(cx, then_expr.span, &mut app);
	if contains_expr.negated {
	format!("{map_str}.entry({key_str}).or_insert_with(\|\| {block_str});")
	} else {
	// TODO: suggest using `if let Some(v) = map.get_mut(k) { .. }` here.
	// This would need to be a different lint.
	return;
	}
	}
	};

	span_lint_and_sugg(
	cx,
	MAP_ENTRY,
	expr.span,
	&format!("usage of `contains_key` followed by `insert` on a `{}`", map_ty.name()),
	"try",
	sugg,
	app,
	);
	}
	}

	#[derive(Clone, Copy)]
	enum MapType {
	Hash,
	BTree,
	}
	impl MapType {
	fn name(self) -> &'static str {
	match self {
	Self::Hash => "HashMap",
	Self::BTree => "BTreeMap",
	}
	}
	fn entry_path(self) -> &'static str {
	match self {
	Self::Hash => "std::collections::hash_map::Entry",
	Self::BTree => "std::collections::btree_map::Entry",
	}
	}
	}

	struct ContainsExpr<'tcx> {
	negated: bool,
	map: &'tcx Expr<'tcx>,
	key: &'tcx Expr<'tcx>,
	call_ctxt: SyntaxContext,
	}
	fn try_parse_contains<'tcx>(cx: &LateContext<'_>, expr: &'tcx Expr<'_>) -> Option<(MapType, ContainsExpr<'tcx>)> {
	let mut negated = false;
	let expr = peel_hir_expr_while(expr, \|e\| match e.kind {
	ExprKind::Unary(UnOp::Not, e) => {
	negated = !negated;
	Some(e)
	},
	_ => None,
	});
	match expr.kind {
	ExprKind::MethodCall(
	_,
	map,
	[
	Expr {
	kind: ExprKind::AddrOf(_, _, key),
	span: key_span,
	..
	},
	],
	_,
	) if key_span.ctxt() == expr.span.ctxt() => {
	let id = cx.typeck_results().type_dependent_def_id(expr.hir_id)?;
	let expr = ContainsExpr {
	negated,
	map,
	key,
	call_ctxt: expr.span.ctxt(),
	};
	if match_def_path(cx, id, &paths::BTREEMAP_CONTAINS_KEY) {
	Some((MapType::BTree, expr))
	} else if match_def_path(cx, id, &paths::HASHMAP_CONTAINS_KEY) {
	Some((MapType::Hash, expr))
	} else {
	None
	}
	},
	_ => None,
	}
	}

	struct InsertExpr<'tcx> {
	map: &'tcx Expr<'tcx>,
	key: &'tcx Expr<'tcx>,
	value: &'tcx Expr<'tcx>,
	}
	fn try_parse_insert<'tcx>(cx: &LateContext<'tcx>, expr: &'tcx Expr<'_>) -> Option<InsertExpr<'tcx>> {
	if let ExprKind::MethodCall(_, map, [key, value], _) = expr.kind {
	let id = cx.typeck_results().type_dependent_def_id(expr.hir_id)?;
	if match_def_path(cx, id, &paths::BTREEMAP_INSERT) \|\| match_def_path(cx, id, &paths::HASHMAP_INSERT) {
	Some(InsertExpr { map, key, value })
	} else {
	None
	}
	} else {
	None
	}
	}

	/// An edit that will need to be made to move the expression to use the entry api
	#[derive(Clone, Copy)]
	enum Edit<'tcx> {
	/// A semicolon that needs to be removed. Used to create a closure for `insert_with`.
	RemoveSemi(Span),
	/// An insertion into the map.
	Insertion(Insertion<'tcx>),
	}
	impl<'tcx> Edit<'tcx> {
	fn as_insertion(self) -> Option<Insertion<'tcx>> {
	if let Self::Insertion(i) = self { Some(i) } else { None }
	}
	}
	#[derive(Clone, Copy)]
	struct Insertion<'tcx> {
	call: &'tcx Expr<'tcx>,
	value: &'tcx Expr<'tcx>,
	}

	/// This visitor needs to do a multiple things:
	/// * Find all usages of the map. An insertion can only be made before any other usages of the map.
	/// * Determine if there's an insertion using the same key. There's no need for the entry api
	/// otherwise.
	/// * Determine if the final statement executed is an insertion. This is needed to use
	/// `or_insert_with`.
	/// * Determine if there's any sub-expression that can't be placed in a closure.
	/// * Determine if there's only a single insert statement. `or_insert` can be used in this case.
	#[expect(clippy::struct_excessive_bools)]
	struct InsertSearcher<'cx, 'tcx> {
	cx: &'cx LateContext<'tcx>,
	/// The map expression used in the contains call.
	map: &'tcx Expr<'tcx>,
	/// The key expression used in the contains call.
	key: &'tcx Expr<'tcx>,
	/// The context of the top level block. All insert calls must be in the same context.
	ctxt: SyntaxContext,
	/// Whether this expression can be safely moved into a closure.
	allow_insert_closure: bool,
	/// Whether this expression can use the entry api.
	can_use_entry: bool,
	/// Whether this expression is the final expression in this code path. This may be a statement.
	in_tail_pos: bool,
	// Is this expression a single insert. A slightly better suggestion can be made in this case.
	is_single_insert: bool,
	/// If the visitor has seen the map being used.
	is_map_used: bool,
	/// The locations where changes need to be made for the suggestion.
	edits: Vec<Edit<'tcx>>,
	/// A stack of loops the visitor is currently in.
	loops: Vec<HirId>,
	/// Local variables created in the expression. These don't need to be captured.
	locals: HirIdSet,
	}
	impl<'tcx> InsertSearcher<'_, 'tcx> {
	/// Visit the expression as a branch in control flow. Multiple insert calls can be used, but
	/// only if they are on separate code paths. This will return whether the map was used in the
	/// given expression.
	fn visit_cond_arm(&mut self, e: &'tcx Expr<'_>) -> bool {
	let is_map_used = self.is_map_used;
	let in_tail_pos = self.in_tail_pos;
	self.visit_expr(e);
	let res = self.is_map_used;
	self.is_map_used = is_map_used;
	self.in_tail_pos = in_tail_pos;
	res
	}

	/// Visits an expression which is not itself in a tail position, but other sibling expressions
	/// may be. e.g. if conditions
	fn visit_non_tail_expr(&mut self, e: &'tcx Expr<'_>) {
	let in_tail_pos = self.in_tail_pos;
	self.in_tail_pos = false;
	self.visit_expr(e);
	self.in_tail_pos = in_tail_pos;
	}
	}
	impl<'tcx> Visitor<'tcx> for InsertSearcher<'_, 'tcx> {
	fn visit_stmt(&mut self, stmt: &'tcx Stmt<'_>) {
	match stmt.kind {
	StmtKind::Semi(e) => {
	self.visit_expr(e);

	if self.in_tail_pos && self.allow_insert_closure {
	// The spans are used to slice the top level expression into multiple parts. This requires that
	// they all come from the same part of the source code.
	if stmt.span.ctxt() == self.ctxt && e.span.ctxt() == self.ctxt {
	self.edits
	.push(Edit::RemoveSemi(stmt.span.trim_start(e.span).unwrap_or(DUMMY_SP)));
	} else {
	self.allow_insert_closure = false;
	}
	}
	},
	StmtKind::Expr(e) => self.visit_expr(e),
	StmtKind::Local(l) => {
	self.visit_pat(l.pat);
	if let Some(e) = l.init {
	self.allow_insert_closure &= !self.in_tail_pos;
	self.in_tail_pos = false;
	self.is_single_insert = false;
	self.visit_expr(e);
	}
	},
	StmtKind::Item(_) => {
	self.allow_insert_closure &= !self.in_tail_pos;
	self.is_single_insert = false;
	},
	}
	}

	fn visit_block(&mut self, block: &'tcx Block<'_>) {
	// If the block is in a tail position, then the last expression (possibly a statement) is in the
	// tail position. The rest, however, are not.
	match (block.stmts, block.expr) {
	([], None) => {
	self.allow_insert_closure &= !self.in_tail_pos;
	},
	([], Some(expr)) => self.visit_expr(expr),
	(stmts, Some(expr)) => {
	let in_tail_pos = self.in_tail_pos;
	self.in_tail_pos = false;
	for stmt in stmts {
	self.visit_stmt(stmt);
	}
	self.in_tail_pos = in_tail_pos;
	self.visit_expr(expr);
	},
	([stmts @ .., stmt], None) => {
	let in_tail_pos = self.in_tail_pos;
	self.in_tail_pos = false;
	for stmt in stmts {
	self.visit_stmt(stmt);
	}
	self.in_tail_pos = in_tail_pos;
	self.visit_stmt(stmt);
	},
	}
	}

	fn visit_expr(&mut self, expr: &'tcx Expr<'_>) {
	if !self.can_use_entry {
	return;
	}

	match try_parse_insert(self.cx, expr) {
	Some(insert_expr) if SpanlessEq::new(self.cx).eq_expr(self.map, insert_expr.map) => {
	// Multiple inserts, inserts with a different key, and inserts from a macro can't use the entry api.
	if self.is_map_used
	\|\| !SpanlessEq::new(self.cx).eq_expr(self.key, insert_expr.key)
	\|\| expr.span.ctxt() != self.ctxt
	{
	self.can_use_entry = false;
	return;
	}

	self.edits.push(Edit::Insertion(Insertion {
	call: expr,
	value: insert_expr.value,
	}));
	self.is_map_used = true;
	self.allow_insert_closure &= self.in_tail_pos;

	// The value doesn't affect whether there is only a single insert expression.
	let is_single_insert = self.is_single_insert;
	self.visit_non_tail_expr(insert_expr.value);
	self.is_single_insert = is_single_insert;
	},
	_ if SpanlessEq::new(self.cx).eq_expr(self.map, expr) => {
	self.is_map_used = true;
	},
	_ => match expr.kind {
	ExprKind::If(cond_expr, then_expr, Some(else_expr)) => {
	self.is_single_insert = false;
	self.visit_non_tail_expr(cond_expr);
	// Each branch may contain it's own insert expression.
	let mut is_map_used = self.visit_cond_arm(then_expr);
	is_map_used \|= self.visit_cond_arm(else_expr);
	self.is_map_used = is_map_used;
	},
	ExprKind::Match(scrutinee_expr, arms, _) => {
	self.is_single_insert = false;
	self.visit_non_tail_expr(scrutinee_expr);
	// Each branch may contain it's own insert expression.
	let mut is_map_used = self.is_map_used;
	for arm in arms {
	self.visit_pat(arm.pat);
	if let Some(Guard::If(guard) \| Guard::IfLet(&Let { init: guard, .. })) = arm.guard {
	self.visit_non_tail_expr(guard);
	}
	is_map_used \|= self.visit_cond_arm(arm.body);
	}
	self.is_map_used = is_map_used;
	},
	ExprKind::Loop(block, ..) => {
	self.loops.push(expr.hir_id);
	self.is_single_insert = false;
	self.allow_insert_closure &= !self.in_tail_pos;
	// Don't allow insertions inside of a loop.
	let edit_len = self.edits.len();
	self.visit_block(block);
	if self.edits.len() != edit_len {
	self.can_use_entry = false;
	}
	self.loops.pop();
	},
	ExprKind::Block(block, _) => self.visit_block(block),
	ExprKind::InlineAsm(_) => {
	self.can_use_entry = false;
	},
	_ => {
	self.allow_insert_closure &= !self.in_tail_pos;
	self.allow_insert_closure &=
	can_move_expr_to_closure_no_visit(self.cx, expr, &self.loops, &self.locals);
	// Sub expressions are no longer in the tail position.
	self.is_single_insert = false;
	self.in_tail_pos = false;
	walk_expr(self, expr);
	},
	},
	}
	}

	fn visit_pat(&mut self, p: &'tcx Pat<'tcx>) {
	p.each_binding_or_first(&mut \|_, id, _, _\| {
	self.locals.insert(id);
	});
	}
	}

	struct InsertSearchResults<'tcx> {
	edits: Vec<Edit<'tcx>>,
	allow_insert_closure: bool,
	is_single_insert: bool,
	}
	impl<'tcx> InsertSearchResults<'tcx> {
	fn as_single_insertion(&self) -> Option<Insertion<'tcx>> {
	self.is_single_insert.then(\|\| self.edits[0].as_insertion().unwrap())
	}

	fn snippet(
	&self,
	cx: &LateContext<'_>,
	mut span: Span,
	app: &mut Applicability,
	write_wrapped: impl Fn(&mut String, Insertion<'_>, SyntaxContext, &mut Applicability),
	) -> String {
	let ctxt = span.ctxt();
	let mut res = String::new();
	for insertion in self.edits.iter().filter_map(\|e\| e.as_insertion()) {
	res.push_str(&snippet_with_applicability(
	cx,
	span.until(insertion.call.span),
	"..",
	app,
	));
	if is_expr_used_or_unified(cx.tcx, insertion.call) {
	write_wrapped(&mut res, insertion, ctxt, app);
	} else {
	let _: fmt::Result = write!(
	res,
	"e.insert({})",
	snippet_with_context(cx, insertion.value.span, ctxt, "..", app).0
	);
	}
	span = span.trim_start(insertion.call.span).unwrap_or(DUMMY_SP);
	}
	res.push_str(&snippet_with_applicability(cx, span, "..", app));
	res
	}

	fn snippet_occupied(&self, cx: &LateContext<'_>, span: Span, app: &mut Applicability) -> (String, &'static str) {
	(
	self.snippet(cx, span, app, \|res, insertion, ctxt, app\| {
	// Insertion into a map would return `Some(&mut value)`, but the entry returns `&mut value`
	let _: fmt::Result = write!(
	res,
	"Some(e.insert({}))",
	snippet_with_context(cx, insertion.value.span, ctxt, "..", app).0
	);
	}),
	"Occupied(mut e)",
	)
	}

	fn snippet_vacant(&self, cx: &LateContext<'_>, span: Span, app: &mut Applicability) -> (String, &'static str) {
	(
	self.snippet(cx, span, app, \|res, insertion, ctxt, app\| {
	// Insertion into a map would return `None`, but the entry returns a mutable reference.
	let _: fmt::Result = if is_expr_final_block_expr(cx.tcx, insertion.call) {
	write!(
	res,
	"e.insert({});\n{}None",
	snippet_with_context(cx, insertion.value.span, ctxt, "..", app).0,
	snippet_indent(cx, insertion.call.span).as_deref().unwrap_or(""),
	)
	} else {
	write!(
	res,
	"{{ e.insert({}); None }}",
	snippet_with_context(cx, insertion.value.span, ctxt, "..", app).0,
	)
	};
	}),
	"Vacant(e)",
	)
	}

	fn snippet_closure(&self, cx: &LateContext<'_>, mut span: Span, app: &mut Applicability) -> String {
	let ctxt = span.ctxt();
	let mut res = String::new();
	for edit in &self.edits {
	match *edit {
	Edit::Insertion(insertion) => {
	// Cut out the value from `map.insert(key, value)`
	res.push_str(&snippet_with_applicability(
	cx,
	span.until(insertion.call.span),
	"..",
	app,
	));
	res.push_str(&snippet_with_context(cx, insertion.value.span, ctxt, "..", app).0);
	span = span.trim_start(insertion.call.span).unwrap_or(DUMMY_SP);
	},
	Edit::RemoveSemi(semi_span) => {
	// Cut out the semicolon. This allows the value to be returned from the closure.
	res.push_str(&snippet_with_applicability(cx, span.until(semi_span), "..", app));
	span = span.trim_start(semi_span).unwrap_or(DUMMY_SP);
	},
	}
	}
	res.push_str(&snippet_with_applicability(cx, span, "..", app));
	res
	}
	}

	fn find_insert_calls<'tcx>(
	cx: &LateContext<'tcx>,
	contains_expr: &ContainsExpr<'tcx>,
	expr: &'tcx Expr<'_>,
	) -> Option<InsertSearchResults<'tcx>> {
	let mut s = InsertSearcher {
	cx,
	map: contains_expr.map,
	key: contains_expr.key,
	ctxt: expr.span.ctxt(),
	edits: Vec::new(),
	is_map_used: false,
	allow_insert_closure: true,
	can_use_entry: true,
	in_tail_pos: true,
	is_single_insert: true,
	loops: Vec::new(),
	locals: HirIdSet::default(),
	};
	s.visit_expr(expr);
	let allow_insert_closure = s.allow_insert_closure;
	let is_single_insert = s.is_single_insert;
	let edits = s.edits;
	s.can_use_entry.then_some(InsertSearchResults {
	edits,
	allow_insert_closure,
	is_single_insert,
	})
	}