use clippy_utils::consts::{constant_full_int, FullInt}; use clippy_utils::diagnostics::span_lint_and_sugg; use clippy_utils::msrvs::{self, Msrv}; use clippy_utils::source::snippet_with_applicability; use clippy_utils::{in_constant, path_to_local}; use rustc_errors::Applicability; use rustc_hir::{BinOpKind, Expr, ExprKind, Node, TyKind}; use rustc_lint::{LateContext, LateLintPass, LintContext}; use rustc_middle::lint::in_external_macro; use rustc_session::{declare_tool_lint, impl_lint_pass}; declare_clippy_lint! { /// ### What it does /// Checks for an expression like `((x % 4) + 4) % 4` which is a common manual reimplementation /// of `x.rem_euclid(4)`. /// /// ### Why is this bad? /// It's simpler and more readable. /// /// ### Example /// ```rust /// let x: i32 = 24; /// let rem = ((x % 4) + 4) % 4; /// ``` /// Use instead: /// ```rust /// let x: i32 = 24; /// let rem = x.rem_euclid(4); /// ``` #[clippy::version = "1.64.0"] pub MANUAL_REM_EUCLID, complexity, "manually reimplementing `rem_euclid`" } pub struct ManualRemEuclid { msrv: Msrv, } impl ManualRemEuclid { #[must_use] pub fn new(msrv: Msrv) -> Self { Self { msrv } } } impl_lint_pass!(ManualRemEuclid => [MANUAL_REM_EUCLID]); impl<'tcx> LateLintPass<'tcx> for ManualRemEuclid { fn check_expr(&mut self, cx: &LateContext<'tcx>, expr: &'tcx Expr<'_>) { if !self.msrv.meets(msrvs::REM_EUCLID) { return; } if in_constant(cx, expr.hir_id) && !self.msrv.meets(msrvs::REM_EUCLID_CONST) { return; } if in_external_macro(cx.sess(), expr.span) { return; } if let ExprKind::Binary(op1, expr1, right) = expr.kind && op1.node == BinOpKind::Rem && let Some(const1) = check_for_unsigned_int_constant(cx, right) && let ExprKind::Binary(op2, left, right) = expr1.kind && op2.node == BinOpKind::Add && let Some((const2, expr2)) = check_for_either_unsigned_int_constant(cx, left, right) && let ExprKind::Binary(op3, expr3, right) = expr2.kind && op3.node == BinOpKind::Rem && let Some(const3) = check_for_unsigned_int_constant(cx, right) // Also ensures the const is nonzero since zero can't be a divisor && const1 == const2 && const2 == const3 && let Some(hir_id) = path_to_local(expr3) && let Some(Node::Pat(_)) = cx.tcx.hir().find(hir_id) { // Apply only to params or locals with annotated types match cx.tcx.hir().find(cx.tcx.hir().get_parent_node(hir_id)) { Some(Node::Param(..)) => (), Some(Node::Local(local)) => { let Some(ty) = local.ty else { return }; if matches!(ty.kind, TyKind::Infer) { return; } } _ => return, }; let mut app = Applicability::MachineApplicable; let rem_of = snippet_with_applicability(cx, expr3.span, "_", &mut app); span_lint_and_sugg( cx, MANUAL_REM_EUCLID, expr.span, "manual `rem_euclid` implementation", "consider using", format!("{rem_of}.rem_euclid({const1})"), app, ); } } extract_msrv_attr!(LateContext); } // Checks if either the left or right expressions can be an unsigned int constant and returns that // constant along with the other expression unchanged if so fn check_for_either_unsigned_int_constant<'a>( cx: &'a LateContext<'_>, left: &'a Expr<'_>, right: &'a Expr<'_>, ) -> Option<(u128, &'a Expr<'a>)> { check_for_unsigned_int_constant(cx, left) .map(|int_const| (int_const, right)) .or_else(|| check_for_unsigned_int_constant(cx, right).map(|int_const| (int_const, left))) } fn check_for_unsigned_int_constant<'a>(cx: &'a LateContext<'_>, expr: &'a Expr<'_>) -> Option { let Some(int_const) = constant_full_int(cx, cx.typeck_results(), expr) else { return None }; match int_const { FullInt::S(s) => s.try_into().ok(), FullInt::U(u) => Some(u), } }