use crate::Lint; use crate::{EarlyContext, EarlyLintPass, LateContext, LateLintPass, LintContext}; use rustc_ast as ast; use rustc_ast::util::{classify, parser}; use rustc_ast::{ExprKind, StmtKind}; use rustc_errors::{fluent, pluralize, Applicability, MultiSpan}; use rustc_hir as hir; use rustc_hir::def::{DefKind, Res}; use rustc_hir::def_id::DefId; use rustc_middle::ty::adjustment; use rustc_middle::ty::{self, Ty}; use rustc_span::symbol::Symbol; use rustc_span::symbol::{kw, sym}; use rustc_span::{BytePos, Span}; declare_lint! { /// The `unused_must_use` lint detects unused result of a type flagged as /// `#[must_use]`. /// /// ### Example /// /// ```rust /// fn returns_result() -> Result<(), ()> { /// Ok(()) /// } /// /// fn main() { /// returns_result(); /// } /// ``` /// /// {{produces}} /// /// ### Explanation /// /// The `#[must_use]` attribute is an indicator that it is a mistake to /// ignore the value. See [the reference] for more details. /// /// [the reference]: https://doc.rust-lang.org/reference/attributes/diagnostics.html#the-must_use-attribute pub UNUSED_MUST_USE, Warn, "unused result of a type flagged as `#[must_use]`", report_in_external_macro } declare_lint! { /// The `unused_results` lint checks for the unused result of an /// expression in a statement. /// /// ### Example /// /// ```rust,compile_fail /// #![deny(unused_results)] /// fn foo() -> T { panic!() } /// /// fn main() { /// foo::(); /// } /// ``` /// /// {{produces}} /// /// ### Explanation /// /// Ignoring the return value of a function may indicate a mistake. In /// cases were it is almost certain that the result should be used, it is /// recommended to annotate the function with the [`must_use` attribute]. /// Failure to use such a return value will trigger the [`unused_must_use` /// lint] which is warn-by-default. The `unused_results` lint is /// essentially the same, but triggers for *all* return values. /// /// This lint is "allow" by default because it can be noisy, and may not be /// an actual problem. For example, calling the `remove` method of a `Vec` /// or `HashMap` returns the previous value, which you may not care about. /// Using this lint would require explicitly ignoring or discarding such /// values. /// /// [`must_use` attribute]: https://doc.rust-lang.org/reference/attributes/diagnostics.html#the-must_use-attribute /// [`unused_must_use` lint]: warn-by-default.html#unused-must-use pub UNUSED_RESULTS, Allow, "unused result of an expression in a statement" } declare_lint_pass!(UnusedResults => [UNUSED_MUST_USE, UNUSED_RESULTS]); impl<'tcx> LateLintPass<'tcx> for UnusedResults { fn check_stmt(&mut self, cx: &LateContext<'_>, s: &hir::Stmt<'_>) { let expr = match s.kind { hir::StmtKind::Semi(ref expr) => &**expr, _ => return, }; if let hir::ExprKind::Ret(..) = expr.kind { return; } let ty = cx.typeck_results().expr_ty(&expr); let type_permits_lack_of_use = check_must_use_ty(cx, ty, &expr, s.span, "", "", 1); let mut fn_warned = false; let mut op_warned = false; let maybe_def_id = match expr.kind { hir::ExprKind::Call(ref callee, _) => { match callee.kind { hir::ExprKind::Path(ref qpath) => { match cx.qpath_res(qpath, callee.hir_id) { Res::Def(DefKind::Fn | DefKind::AssocFn, def_id) => Some(def_id), // `Res::Local` if it was a closure, for which we // do not currently support must-use linting _ => None, } } _ => None, } } hir::ExprKind::MethodCall(..) => cx.typeck_results().type_dependent_def_id(expr.hir_id), _ => None, }; if let Some(def_id) = maybe_def_id { fn_warned = check_must_use_def(cx, def_id, s.span, "return value of ", ""); } else if type_permits_lack_of_use { // We don't warn about unused unit or uninhabited types. // (See https://github.com/rust-lang/rust/issues/43806 for details.) return; } let must_use_op = match expr.kind { // Hardcoding operators here seemed more expedient than the // refactoring that would be needed to look up the `#[must_use]` // attribute which does exist on the comparison trait methods hir::ExprKind::Binary(bin_op, ..) => match bin_op.node { hir::BinOpKind::Eq | hir::BinOpKind::Lt | hir::BinOpKind::Le | hir::BinOpKind::Ne | hir::BinOpKind::Ge | hir::BinOpKind::Gt => Some("comparison"), hir::BinOpKind::Add | hir::BinOpKind::Sub | hir::BinOpKind::Div | hir::BinOpKind::Mul | hir::BinOpKind::Rem => Some("arithmetic operation"), hir::BinOpKind::And | hir::BinOpKind::Or => Some("logical operation"), hir::BinOpKind::BitXor | hir::BinOpKind::BitAnd | hir::BinOpKind::BitOr | hir::BinOpKind::Shl | hir::BinOpKind::Shr => Some("bitwise operation"), }, hir::ExprKind::AddrOf(..) => Some("borrow"), hir::ExprKind::Unary(..) => Some("unary operation"), _ => None, }; if let Some(must_use_op) = must_use_op { cx.struct_span_lint(UNUSED_MUST_USE, expr.span, |lint| { lint.build(fluent::lint::unused_op) .set_arg("op", must_use_op) .span_label(expr.span, fluent::lint::label) .span_suggestion_verbose( expr.span.shrink_to_lo(), fluent::lint::suggestion, "let _ = ", Applicability::MachineApplicable, ) .emit(); }); op_warned = true; } if !(type_permits_lack_of_use || fn_warned || op_warned) { cx.struct_span_lint(UNUSED_RESULTS, s.span, |lint| { lint.build(fluent::lint::unused_result).set_arg("ty", ty).emit(); }); } // Returns whether an error has been emitted (and thus another does not need to be later). fn check_must_use_ty<'tcx>( cx: &LateContext<'tcx>, ty: Ty<'tcx>, expr: &hir::Expr<'_>, span: Span, descr_pre: &str, descr_post: &str, plural_len: usize, ) -> bool { if ty.is_unit() || cx.tcx.is_ty_uninhabited_from( cx.tcx.parent_module(expr.hir_id).to_def_id(), ty, cx.param_env, ) { return true; } let plural_suffix = pluralize!(plural_len); match *ty.kind() { ty::Adt(..) if ty.is_box() => { let boxed_ty = ty.boxed_ty(); let descr_pre = &format!("{}boxed ", descr_pre); check_must_use_ty(cx, boxed_ty, expr, span, descr_pre, descr_post, plural_len) } ty::Adt(def, _) => check_must_use_def(cx, def.did(), span, descr_pre, descr_post), ty::Opaque(def, _) => { let mut has_emitted = false; for &(predicate, _) in cx.tcx.explicit_item_bounds(def) { // We only look at the `DefId`, so it is safe to skip the binder here. if let ty::PredicateKind::Trait(ref poly_trait_predicate) = predicate.kind().skip_binder() { let def_id = poly_trait_predicate.trait_ref.def_id; let descr_pre = &format!("{}implementer{} of ", descr_pre, plural_suffix,); if check_must_use_def(cx, def_id, span, descr_pre, descr_post) { has_emitted = true; break; } } } has_emitted } ty::Dynamic(binder, _, _) => { let mut has_emitted = false; for predicate in binder.iter() { if let ty::ExistentialPredicate::Trait(ref trait_ref) = predicate.skip_binder() { let def_id = trait_ref.def_id; let descr_post = &format!(" trait object{}{}", plural_suffix, descr_post,); if check_must_use_def(cx, def_id, span, descr_pre, descr_post) { has_emitted = true; break; } } } has_emitted } ty::Tuple(ref tys) => { let mut has_emitted = false; let comps = if let hir::ExprKind::Tup(comps) = expr.kind { debug_assert_eq!(comps.len(), tys.len()); comps } else { &[] }; for (i, ty) in tys.iter().enumerate() { let descr_post = &format!(" in tuple element {}", i); let e = comps.get(i).unwrap_or(expr); let span = e.span; if check_must_use_ty(cx, ty, e, span, descr_pre, descr_post, plural_len) { has_emitted = true; } } has_emitted } ty::Array(ty, len) => match len.try_eval_usize(cx.tcx, cx.param_env) { // If the array is empty we don't lint, to avoid false positives Some(0) | None => false, // If the array is definitely non-empty, we can do `#[must_use]` checking. Some(n) => { let descr_pre = &format!("{}array{} of ", descr_pre, plural_suffix,); check_must_use_ty(cx, ty, expr, span, descr_pre, descr_post, n as usize + 1) } }, ty::Closure(..) => { cx.struct_span_lint(UNUSED_MUST_USE, span, |lint| { // FIXME(davidtwco): this isn't properly translatable because of the // pre/post strings lint.build(fluent::lint::unused_closure) .set_arg("count", plural_len) .set_arg("pre", descr_pre) .set_arg("post", descr_post) .note(fluent::lint::note) .emit(); }); true } ty::Generator(..) => { cx.struct_span_lint(UNUSED_MUST_USE, span, |lint| { // FIXME(davidtwco): this isn't properly translatable because of the // pre/post strings lint.build(fluent::lint::unused_generator) .set_arg("count", plural_len) .set_arg("pre", descr_pre) .set_arg("post", descr_post) .note(fluent::lint::note) .emit(); }); true } _ => false, } } // Returns whether an error has been emitted (and thus another does not need to be later). // FIXME: Args desc_{pre,post}_path could be made lazy by taking Fn() -> &str, but this // would make calling it a big awkward. Could also take String (so args are moved), but // this would still require a copy into the format string, which would only be executed // when needed. fn check_must_use_def( cx: &LateContext<'_>, def_id: DefId, span: Span, descr_pre_path: &str, descr_post_path: &str, ) -> bool { if let Some(attr) = cx.tcx.get_attr(def_id, sym::must_use) { cx.struct_span_lint(UNUSED_MUST_USE, span, |lint| { // FIXME(davidtwco): this isn't properly translatable because of the pre/post // strings let mut err = lint.build(fluent::lint::unused_def); err.set_arg("pre", descr_pre_path); err.set_arg("post", descr_post_path); err.set_arg("def", cx.tcx.def_path_str(def_id)); // check for #[must_use = "..."] if let Some(note) = attr.value_str() { err.note(note.as_str()); } err.emit(); }); true } else { false } } } } declare_lint! { /// The `path_statements` lint detects path statements with no effect. /// /// ### Example /// /// ```rust /// let x = 42; /// /// x; /// ``` /// /// {{produces}} /// /// ### Explanation /// /// It is usually a mistake to have a statement that has no effect. pub PATH_STATEMENTS, Warn, "path statements with no effect" } declare_lint_pass!(PathStatements => [PATH_STATEMENTS]); impl<'tcx> LateLintPass<'tcx> for PathStatements { fn check_stmt(&mut self, cx: &LateContext<'_>, s: &hir::Stmt<'_>) { if let hir::StmtKind::Semi(expr) = s.kind { if let hir::ExprKind::Path(_) = expr.kind { cx.struct_span_lint(PATH_STATEMENTS, s.span, |lint| { let ty = cx.typeck_results().expr_ty(expr); if ty.needs_drop(cx.tcx, cx.param_env) { let mut lint = lint.build(fluent::lint::path_statement_drop); if let Ok(snippet) = cx.sess().source_map().span_to_snippet(expr.span) { lint.span_suggestion( s.span, fluent::lint::suggestion, format!("drop({});", snippet), Applicability::MachineApplicable, ); } else { lint.span_help(s.span, fluent::lint::suggestion); } lint.emit(); } else { lint.build(fluent::lint::path_statement_no_effect).emit(); } }); } } } } #[derive(Copy, Clone, Debug, PartialEq, Eq)] enum UnusedDelimsCtx { FunctionArg, MethodArg, AssignedValue, AssignedValueLetElse, IfCond, WhileCond, ForIterExpr, MatchScrutineeExpr, ReturnValue, BlockRetValue, LetScrutineeExpr, ArrayLenExpr, AnonConst, MatchArmExpr, } impl From for &'static str { fn from(ctx: UnusedDelimsCtx) -> &'static str { match ctx { UnusedDelimsCtx::FunctionArg => "function argument", UnusedDelimsCtx::MethodArg => "method argument", UnusedDelimsCtx::AssignedValue | UnusedDelimsCtx::AssignedValueLetElse => { "assigned value" } UnusedDelimsCtx::IfCond => "`if` condition", UnusedDelimsCtx::WhileCond => "`while` condition", UnusedDelimsCtx::ForIterExpr => "`for` iterator expression", UnusedDelimsCtx::MatchScrutineeExpr => "`match` scrutinee expression", UnusedDelimsCtx::ReturnValue => "`return` value", UnusedDelimsCtx::BlockRetValue => "block return value", UnusedDelimsCtx::LetScrutineeExpr => "`let` scrutinee expression", UnusedDelimsCtx::ArrayLenExpr | UnusedDelimsCtx::AnonConst => "const expression", UnusedDelimsCtx::MatchArmExpr => "match arm expression", } } } /// Used by both `UnusedParens` and `UnusedBraces` to prevent code duplication. trait UnusedDelimLint { const DELIM_STR: &'static str; /// Due to `ref` pattern, there can be a difference between using /// `{ expr }` and `expr` in pattern-matching contexts. This means /// that we should only lint `unused_parens` and not `unused_braces` /// in this case. /// /// ```rust /// let mut a = 7; /// let ref b = { a }; // We actually borrow a copy of `a` here. /// a += 1; // By mutating `a` we invalidate any borrows of `a`. /// assert_eq!(b + 1, a); // `b` does not borrow `a`, so we can still use it here. /// ``` const LINT_EXPR_IN_PATTERN_MATCHING_CTX: bool; // this cannot be a constant is it refers to a static. fn lint(&self) -> &'static Lint; fn check_unused_delims_expr( &self, cx: &EarlyContext<'_>, value: &ast::Expr, ctx: UnusedDelimsCtx, followed_by_block: bool, left_pos: Option, right_pos: Option, ); fn is_expr_delims_necessary( inner: &ast::Expr, followed_by_block: bool, followed_by_else: bool, ) -> bool { if followed_by_else { match inner.kind { ast::ExprKind::Binary(op, ..) if op.node.lazy() => return true, _ if classify::expr_trailing_brace(inner).is_some() => return true, _ => {} } } // Prevent false-positives in cases like `fn x() -> u8 { ({ 0 } + 1) }` let lhs_needs_parens = { let mut innermost = inner; loop { innermost = match &innermost.kind { ExprKind::Binary(_, lhs, _rhs) => lhs, ExprKind::Call(fn_, _params) => fn_, ExprKind::Cast(expr, _ty) => expr, ExprKind::Type(expr, _ty) => expr, ExprKind::Index(base, _subscript) => base, _ => break false, }; if !classify::expr_requires_semi_to_be_stmt(innermost) { break true; } } }; lhs_needs_parens || (followed_by_block && match &inner.kind { ExprKind::Ret(_) | ExprKind::Break(..) | ExprKind::Yield(..) => true, ExprKind::Range(_lhs, Some(rhs), _limits) => { matches!(rhs.kind, ExprKind::Block(..)) } _ => parser::contains_exterior_struct_lit(&inner), }) } fn emit_unused_delims_expr( &self, cx: &EarlyContext<'_>, value: &ast::Expr, ctx: UnusedDelimsCtx, left_pos: Option, right_pos: Option, ) { let spans = match value.kind { ast::ExprKind::Block(ref block, None) if block.stmts.len() > 0 => { let start = block.stmts[0].span; let end = block.stmts[block.stmts.len() - 1].span; if let Some(start) = start.find_ancestor_inside(value.span) && let Some(end) = end.find_ancestor_inside(value.span) { Some(( value.span.with_hi(start.lo()), value.span.with_lo(end.hi()), )) } else { None } } ast::ExprKind::Paren(ref expr) => { let expr_span = expr.span.find_ancestor_inside(value.span); if let Some(expr_span) = expr_span { Some((value.span.with_hi(expr_span.lo()), value.span.with_lo(expr_span.hi()))) } else { None } } _ => return, }; let keep_space = ( left_pos.map_or(false, |s| s >= value.span.lo()), right_pos.map_or(false, |s| s <= value.span.hi()), ); self.emit_unused_delims(cx, value.span, spans, ctx.into(), keep_space); } fn emit_unused_delims( &self, cx: &EarlyContext<'_>, value_span: Span, spans: Option<(Span, Span)>, msg: &str, keep_space: (bool, bool), ) { let primary_span = if let Some((lo, hi)) = spans { MultiSpan::from(vec![lo, hi]) } else { MultiSpan::from(value_span) }; cx.struct_span_lint(self.lint(), primary_span, |lint| { let mut db = lint.build(fluent::lint::unused_delim); db.set_arg("delim", Self::DELIM_STR); db.set_arg("item", msg); if let Some((lo, hi)) = spans { let replacement = vec![ (lo, if keep_space.0 { " ".into() } else { "".into() }), (hi, if keep_space.1 { " ".into() } else { "".into() }), ]; db.multipart_suggestion( fluent::lint::suggestion, replacement, Applicability::MachineApplicable, ); } db.emit(); }); } fn check_expr(&mut self, cx: &EarlyContext<'_>, e: &ast::Expr) { use rustc_ast::ExprKind::*; let (value, ctx, followed_by_block, left_pos, right_pos) = match e.kind { // Do not lint `unused_braces` in `if let` expressions. If(ref cond, ref block, _) if !matches!(cond.kind, Let(_, _, _)) || Self::LINT_EXPR_IN_PATTERN_MATCHING_CTX => { let left = e.span.lo() + rustc_span::BytePos(2); let right = block.span.lo(); (cond, UnusedDelimsCtx::IfCond, true, Some(left), Some(right)) } // Do not lint `unused_braces` in `while let` expressions. While(ref cond, ref block, ..) if !matches!(cond.kind, Let(_, _, _)) || Self::LINT_EXPR_IN_PATTERN_MATCHING_CTX => { let left = e.span.lo() + rustc_span::BytePos(5); let right = block.span.lo(); (cond, UnusedDelimsCtx::WhileCond, true, Some(left), Some(right)) } ForLoop(_, ref cond, ref block, ..) => { (cond, UnusedDelimsCtx::ForIterExpr, true, None, Some(block.span.lo())) } Match(ref head, _) if Self::LINT_EXPR_IN_PATTERN_MATCHING_CTX => { let left = e.span.lo() + rustc_span::BytePos(5); (head, UnusedDelimsCtx::MatchScrutineeExpr, true, Some(left), None) } Ret(Some(ref value)) => { let left = e.span.lo() + rustc_span::BytePos(3); (value, UnusedDelimsCtx::ReturnValue, false, Some(left), None) } Assign(_, ref value, _) | AssignOp(.., ref value) => { (value, UnusedDelimsCtx::AssignedValue, false, None, None) } // either function/method call, or something this lint doesn't care about ref call_or_other => { let (args_to_check, ctx) = match *call_or_other { Call(_, ref args) => (&args[..], UnusedDelimsCtx::FunctionArg), // first "argument" is self (which sometimes needs delims) MethodCall(_, ref args, _) => (&args[1..], UnusedDelimsCtx::MethodArg), // actual catch-all arm _ => { return; } }; // Don't lint if this is a nested macro expansion: otherwise, the lint could // trigger in situations that macro authors shouldn't have to care about, e.g., // when a parenthesized token tree matched in one macro expansion is matched as // an expression in another and used as a fn/method argument (Issue #47775) if e.span.ctxt().outer_expn_data().call_site.from_expansion() { return; } for arg in args_to_check { self.check_unused_delims_expr(cx, arg, ctx, false, None, None); } return; } }; self.check_unused_delims_expr(cx, &value, ctx, followed_by_block, left_pos, right_pos); } fn check_stmt(&mut self, cx: &EarlyContext<'_>, s: &ast::Stmt) { match s.kind { StmtKind::Local(ref local) if Self::LINT_EXPR_IN_PATTERN_MATCHING_CTX => { if let Some((init, els)) = local.kind.init_else_opt() { let ctx = match els { None => UnusedDelimsCtx::AssignedValue, Some(_) => UnusedDelimsCtx::AssignedValueLetElse, }; self.check_unused_delims_expr(cx, init, ctx, false, None, None); } } StmtKind::Expr(ref expr) => { self.check_unused_delims_expr( cx, &expr, UnusedDelimsCtx::BlockRetValue, false, None, None, ); } _ => {} } } fn check_item(&mut self, cx: &EarlyContext<'_>, item: &ast::Item) { use ast::ItemKind::*; if let Const(.., Some(expr)) | Static(.., Some(expr)) = &item.kind { self.check_unused_delims_expr( cx, expr, UnusedDelimsCtx::AssignedValue, false, None, None, ); } } } declare_lint! { /// The `unused_parens` lint detects `if`, `match`, `while` and `return` /// with parentheses; they do not need them. /// /// ### Examples /// /// ```rust /// if(true) {} /// ``` /// /// {{produces}} /// /// ### Explanation /// /// The parentheses are not needed, and should be removed. This is the /// preferred style for writing these expressions. pub(super) UNUSED_PARENS, Warn, "`if`, `match`, `while` and `return` do not need parentheses" } declare_lint_pass!(UnusedParens => [UNUSED_PARENS]); impl UnusedDelimLint for UnusedParens { const DELIM_STR: &'static str = "parentheses"; const LINT_EXPR_IN_PATTERN_MATCHING_CTX: bool = true; fn lint(&self) -> &'static Lint { UNUSED_PARENS } fn check_unused_delims_expr( &self, cx: &EarlyContext<'_>, value: &ast::Expr, ctx: UnusedDelimsCtx, followed_by_block: bool, left_pos: Option, right_pos: Option, ) { match value.kind { ast::ExprKind::Paren(ref inner) => { let followed_by_else = ctx == UnusedDelimsCtx::AssignedValueLetElse; if !Self::is_expr_delims_necessary(inner, followed_by_block, followed_by_else) && value.attrs.is_empty() && !value.span.from_expansion() && (ctx != UnusedDelimsCtx::LetScrutineeExpr || !matches!(inner.kind, ast::ExprKind::Binary( rustc_span::source_map::Spanned { node, .. }, _, _, ) if node.lazy())) { self.emit_unused_delims_expr(cx, value, ctx, left_pos, right_pos) } } ast::ExprKind::Let(_, ref expr, _) => { self.check_unused_delims_expr( cx, expr, UnusedDelimsCtx::LetScrutineeExpr, followed_by_block, None, None, ); } _ => {} } } } impl UnusedParens { fn check_unused_parens_pat( &self, cx: &EarlyContext<'_>, value: &ast::Pat, avoid_or: bool, avoid_mut: bool, ) { use ast::{BindingAnnotation, PatKind}; if let PatKind::Paren(inner) = &value.kind { match inner.kind { // The lint visitor will visit each subpattern of `p`. We do not want to lint // any range pattern no matter where it occurs in the pattern. For something like // `&(a..=b)`, there is a recursive `check_pat` on `a` and `b`, but we will assume // that if there are unnecessary parens they serve a purpose of readability. PatKind::Range(..) => return, // Avoid `p0 | .. | pn` if we should. PatKind::Or(..) if avoid_or => return, // Avoid `mut x` and `mut x @ p` if we should: PatKind::Ident(BindingAnnotation::MUT, ..) if avoid_mut => { return; } // Otherwise proceed with linting. _ => {} } let spans = if let Some(inner) = inner.span.find_ancestor_inside(value.span) { Some((value.span.with_hi(inner.lo()), value.span.with_lo(inner.hi()))) } else { None }; self.emit_unused_delims(cx, value.span, spans, "pattern", (false, false)); } } } impl EarlyLintPass for UnusedParens { fn check_expr(&mut self, cx: &EarlyContext<'_>, e: &ast::Expr) { match e.kind { ExprKind::Let(ref pat, _, _) | ExprKind::ForLoop(ref pat, ..) => { self.check_unused_parens_pat(cx, pat, false, false); } // We ignore parens in cases like `if (((let Some(0) = Some(1))))` because we already // handle a hard error for them during AST lowering in `lower_expr_mut`, but we still // want to complain about things like `if let 42 = (42)`. ExprKind::If(ref cond, ref block, ref else_) if matches!(cond.peel_parens().kind, ExprKind::Let(..)) => { self.check_unused_delims_expr( cx, cond.peel_parens(), UnusedDelimsCtx::LetScrutineeExpr, true, None, None, ); for stmt in &block.stmts { ::check_stmt(self, cx, stmt); } if let Some(e) = else_ { ::check_expr(self, cx, e); } return; } ExprKind::Match(ref _expr, ref arm) => { for a in arm { self.check_unused_delims_expr( cx, &a.body, UnusedDelimsCtx::MatchArmExpr, false, None, None, ); } } _ => {} } ::check_expr(self, cx, e) } fn check_pat(&mut self, cx: &EarlyContext<'_>, p: &ast::Pat) { use ast::{Mutability, PatKind::*}; match &p.kind { // Do not lint on `(..)` as that will result in the other arms being useless. Paren(_) // The other cases do not contain sub-patterns. | Wild | Rest | Lit(..) | MacCall(..) | Range(..) | Ident(.., None) | Path(..) => {}, // These are list-like patterns; parens can always be removed. TupleStruct(_, _, ps) | Tuple(ps) | Slice(ps) | Or(ps) => for p in ps { self.check_unused_parens_pat(cx, p, false, false); }, Struct(_, _, fps, _) => for f in fps { self.check_unused_parens_pat(cx, &f.pat, false, false); }, // Avoid linting on `i @ (p0 | .. | pn)` and `box (p0 | .. | pn)`, #64106. Ident(.., Some(p)) | Box(p) => self.check_unused_parens_pat(cx, p, true, false), // Avoid linting on `&(mut x)` as `&mut x` has a different meaning, #55342. // Also avoid linting on `& mut? (p0 | .. | pn)`, #64106. Ref(p, m) => self.check_unused_parens_pat(cx, p, true, *m == Mutability::Not), } } fn check_stmt(&mut self, cx: &EarlyContext<'_>, s: &ast::Stmt) { if let StmtKind::Local(ref local) = s.kind { self.check_unused_parens_pat(cx, &local.pat, true, false); } ::check_stmt(self, cx, s) } fn check_param(&mut self, cx: &EarlyContext<'_>, param: &ast::Param) { self.check_unused_parens_pat(cx, ¶m.pat, true, false); } fn check_arm(&mut self, cx: &EarlyContext<'_>, arm: &ast::Arm) { self.check_unused_parens_pat(cx, &arm.pat, false, false); } fn check_ty(&mut self, cx: &EarlyContext<'_>, ty: &ast::Ty) { if let ast::TyKind::Paren(r) = &ty.kind { match &r.kind { ast::TyKind::TraitObject(..) => {} ast::TyKind::ImplTrait(_, bounds) if bounds.len() > 1 => {} ast::TyKind::Array(_, len) => { self.check_unused_delims_expr( cx, &len.value, UnusedDelimsCtx::ArrayLenExpr, false, None, None, ); } _ => { let spans = if let Some(r) = r.span.find_ancestor_inside(ty.span) { Some((ty.span.with_hi(r.lo()), ty.span.with_lo(r.hi()))) } else { None }; self.emit_unused_delims(cx, ty.span, spans, "type", (false, false)); } } } } fn check_item(&mut self, cx: &EarlyContext<'_>, item: &ast::Item) { ::check_item(self, cx, item) } } declare_lint! { /// The `unused_braces` lint detects unnecessary braces around an /// expression. /// /// ### Example /// /// ```rust /// if { true } { /// // ... /// } /// ``` /// /// {{produces}} /// /// ### Explanation /// /// The braces are not needed, and should be removed. This is the /// preferred style for writing these expressions. pub(super) UNUSED_BRACES, Warn, "unnecessary braces around an expression" } declare_lint_pass!(UnusedBraces => [UNUSED_BRACES]); impl UnusedDelimLint for UnusedBraces { const DELIM_STR: &'static str = "braces"; const LINT_EXPR_IN_PATTERN_MATCHING_CTX: bool = false; fn lint(&self) -> &'static Lint { UNUSED_BRACES } fn check_unused_delims_expr( &self, cx: &EarlyContext<'_>, value: &ast::Expr, ctx: UnusedDelimsCtx, followed_by_block: bool, left_pos: Option, right_pos: Option, ) { match value.kind { ast::ExprKind::Block(ref inner, None) if inner.rules == ast::BlockCheckMode::Default => { // emit a warning under the following conditions: // // - the block does not have a label // - the block is not `unsafe` // - the block contains exactly one expression (do not lint `{ expr; }`) // - `followed_by_block` is true and the internal expr may contain a `{` // - the block is not multiline (do not lint multiline match arms) // ``` // match expr { // Pattern => { // somewhat_long_expression // } // // ... // } // ``` // - the block has no attribute and was not created inside a macro // - if the block is an `anon_const`, the inner expr must be a literal // (do not lint `struct A; let _: A<{ 2 + 3 }>;`) // // FIXME(const_generics): handle paths when #67075 is fixed. if let [stmt] = inner.stmts.as_slice() { if let ast::StmtKind::Expr(ref expr) = stmt.kind { if !Self::is_expr_delims_necessary(expr, followed_by_block, false) && (ctx != UnusedDelimsCtx::AnonConst || matches!(expr.kind, ast::ExprKind::Lit(_))) && !cx.sess().source_map().is_multiline(value.span) && value.attrs.is_empty() && !value.span.from_expansion() { self.emit_unused_delims_expr(cx, value, ctx, left_pos, right_pos) } } } } ast::ExprKind::Let(_, ref expr, _) => { self.check_unused_delims_expr( cx, expr, UnusedDelimsCtx::LetScrutineeExpr, followed_by_block, None, None, ); } _ => {} } } } impl EarlyLintPass for UnusedBraces { fn check_stmt(&mut self, cx: &EarlyContext<'_>, s: &ast::Stmt) { ::check_stmt(self, cx, s) } fn check_expr(&mut self, cx: &EarlyContext<'_>, e: &ast::Expr) { ::check_expr(self, cx, e); if let ExprKind::Repeat(_, ref anon_const) = e.kind { self.check_unused_delims_expr( cx, &anon_const.value, UnusedDelimsCtx::AnonConst, false, None, None, ); } } fn check_generic_arg(&mut self, cx: &EarlyContext<'_>, arg: &ast::GenericArg) { if let ast::GenericArg::Const(ct) = arg { self.check_unused_delims_expr( cx, &ct.value, UnusedDelimsCtx::AnonConst, false, None, None, ); } } fn check_variant(&mut self, cx: &EarlyContext<'_>, v: &ast::Variant) { if let Some(anon_const) = &v.disr_expr { self.check_unused_delims_expr( cx, &anon_const.value, UnusedDelimsCtx::AnonConst, false, None, None, ); } } fn check_ty(&mut self, cx: &EarlyContext<'_>, ty: &ast::Ty) { match ty.kind { ast::TyKind::Array(_, ref len) => { self.check_unused_delims_expr( cx, &len.value, UnusedDelimsCtx::ArrayLenExpr, false, None, None, ); } ast::TyKind::Typeof(ref anon_const) => { self.check_unused_delims_expr( cx, &anon_const.value, UnusedDelimsCtx::AnonConst, false, None, None, ); } _ => {} } } fn check_item(&mut self, cx: &EarlyContext<'_>, item: &ast::Item) { ::check_item(self, cx, item) } } declare_lint! { /// The `unused_import_braces` lint catches unnecessary braces around an /// imported item. /// /// ### Example /// /// ```rust,compile_fail /// #![deny(unused_import_braces)] /// use test::{A}; /// /// pub mod test { /// pub struct A; /// } /// # fn main() {} /// ``` /// /// {{produces}} /// /// ### Explanation /// /// If there is only a single item, then remove the braces (`use test::A;` /// for example). /// /// This lint is "allow" by default because it is only enforcing a /// stylistic choice. UNUSED_IMPORT_BRACES, Allow, "unnecessary braces around an imported item" } declare_lint_pass!(UnusedImportBraces => [UNUSED_IMPORT_BRACES]); impl UnusedImportBraces { fn check_use_tree(&self, cx: &EarlyContext<'_>, use_tree: &ast::UseTree, item: &ast::Item) { if let ast::UseTreeKind::Nested(ref items) = use_tree.kind { // Recursively check nested UseTrees for &(ref tree, _) in items { self.check_use_tree(cx, tree, item); } // Trigger the lint only if there is one nested item if items.len() != 1 { return; } // Trigger the lint if the nested item is a non-self single item let node_name = match items[0].0.kind { ast::UseTreeKind::Simple(rename, ..) => { let orig_ident = items[0].0.prefix.segments.last().unwrap().ident; if orig_ident.name == kw::SelfLower { return; } rename.unwrap_or(orig_ident).name } ast::UseTreeKind::Glob => Symbol::intern("*"), ast::UseTreeKind::Nested(_) => return, }; cx.struct_span_lint(UNUSED_IMPORT_BRACES, item.span, |lint| { lint.build(fluent::lint::unused_import_braces).set_arg("node", node_name).emit(); }); } } } impl EarlyLintPass for UnusedImportBraces { fn check_item(&mut self, cx: &EarlyContext<'_>, item: &ast::Item) { if let ast::ItemKind::Use(ref use_tree) = item.kind { self.check_use_tree(cx, use_tree, item); } } } declare_lint! { /// The `unused_allocation` lint detects unnecessary allocations that can /// be eliminated. /// /// ### Example /// /// ```rust /// #![feature(box_syntax)] /// fn main() { /// let a = (box [1, 2, 3]).len(); /// } /// ``` /// /// {{produces}} /// /// ### Explanation /// /// When a `box` expression is immediately coerced to a reference, then /// the allocation is unnecessary, and a reference (using `&` or `&mut`) /// should be used instead to avoid the allocation. pub(super) UNUSED_ALLOCATION, Warn, "detects unnecessary allocations that can be eliminated" } declare_lint_pass!(UnusedAllocation => [UNUSED_ALLOCATION]); impl<'tcx> LateLintPass<'tcx> for UnusedAllocation { fn check_expr(&mut self, cx: &LateContext<'_>, e: &hir::Expr<'_>) { match e.kind { hir::ExprKind::Box(_) => {} _ => return, } for adj in cx.typeck_results().expr_adjustments(e) { if let adjustment::Adjust::Borrow(adjustment::AutoBorrow::Ref(_, m)) = adj.kind { cx.struct_span_lint(UNUSED_ALLOCATION, e.span, |lint| { lint.build(match m { adjustment::AutoBorrowMutability::Not => fluent::lint::unused_allocation, adjustment::AutoBorrowMutability::Mut { .. } => { fluent::lint::unused_allocation_mut } }) .emit(); }); } } } }