//! Contains utility functions to generate suggestions. #![deny(clippy::missing_docs_in_private_items)] use crate::source::{snippet, snippet_opt, snippet_with_applicability, snippet_with_context}; use crate::ty::expr_sig; use crate::{get_parent_expr_for_hir, higher}; use rustc_ast::util::parser::AssocOp; use rustc_ast::{ast, token}; use rustc_ast_pretty::pprust::token_kind_to_string; use rustc_errors::Applicability; use rustc_hir as hir; use rustc_hir::{Closure, ExprKind, HirId, MutTy, TyKind}; use rustc_hir_typeck::expr_use_visitor::{Delegate, ExprUseVisitor, PlaceBase, PlaceWithHirId}; use rustc_lint::{EarlyContext, LateContext, LintContext}; use rustc_middle::hir::place::ProjectionKind; use rustc_middle::mir::{FakeReadCause, Mutability}; use rustc_middle::ty; use rustc_span::{BytePos, CharPos, Pos, Span, SyntaxContext}; use std::borrow::Cow; use std::fmt::{self, Display, Write as _}; use std::ops::{Add, Neg, Not, Sub}; /// A helper type to build suggestion correctly handling parentheses. #[derive(Clone, Debug, PartialEq)] pub enum Sugg<'a> { /// An expression that never needs parentheses such as `1337` or `[0; 42]`. NonParen(Cow<'a, str>), /// An expression that does not fit in other variants. MaybeParen(Cow<'a, str>), /// A binary operator expression, including `as`-casts and explicit type /// coercion. BinOp(AssocOp, Cow<'a, str>, Cow<'a, str>), } /// Literal constant `0`, for convenience. pub const ZERO: Sugg<'static> = Sugg::NonParen(Cow::Borrowed("0")); /// Literal constant `1`, for convenience. pub const ONE: Sugg<'static> = Sugg::NonParen(Cow::Borrowed("1")); /// a constant represents an empty string, for convenience. pub const EMPTY: Sugg<'static> = Sugg::NonParen(Cow::Borrowed("")); impl Display for Sugg<'_> { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> Result<(), fmt::Error> { match *self { Sugg::NonParen(ref s) | Sugg::MaybeParen(ref s) => s.fmt(f), Sugg::BinOp(op, ref lhs, ref rhs) => binop_to_string(op, lhs, rhs).fmt(f), } } } #[expect(clippy::wrong_self_convention)] // ok, because of the function `as_ty` method impl<'a> Sugg<'a> { /// Prepare a suggestion from an expression. pub fn hir_opt(cx: &LateContext<'_>, expr: &hir::Expr<'_>) -> Option { let ctxt = expr.span.ctxt(); let get_snippet = |span| snippet_with_context(cx, span, ctxt, "", &mut Applicability::Unspecified).0; snippet_opt(cx, expr.span).map(|_| Self::hir_from_snippet(expr, get_snippet)) } /// Convenience function around `hir_opt` for suggestions with a default /// text. pub fn hir(cx: &LateContext<'_>, expr: &hir::Expr<'_>, default: &'a str) -> Self { Self::hir_opt(cx, expr).unwrap_or(Sugg::NonParen(Cow::Borrowed(default))) } /// Same as `hir`, but it adapts the applicability level by following rules: /// /// - Applicability level `Unspecified` will never be changed. /// - If the span is inside a macro, change the applicability level to `MaybeIncorrect`. /// - If the default value is used and the applicability level is `MachineApplicable`, change it /// to `HasPlaceholders` pub fn hir_with_applicability( cx: &LateContext<'_>, expr: &hir::Expr<'_>, default: &'a str, applicability: &mut Applicability, ) -> Self { if *applicability != Applicability::Unspecified && expr.span.from_expansion() { *applicability = Applicability::MaybeIncorrect; } Self::hir_opt(cx, expr).unwrap_or_else(|| { if *applicability == Applicability::MachineApplicable { *applicability = Applicability::HasPlaceholders; } Sugg::NonParen(Cow::Borrowed(default)) }) } /// Same as `hir`, but first walks the span up to the given context. This will result in the /// macro call, rather than the expansion, if the span is from a child context. If the span is /// not from a child context, it will be used directly instead. /// /// e.g. Given the expression `&vec![]`, getting a snippet from the span for `vec![]` as a HIR /// node would result in `box []`. If given the context of the address of expression, this /// function will correctly get a snippet of `vec![]`. pub fn hir_with_context( cx: &LateContext<'_>, expr: &hir::Expr<'_>, ctxt: SyntaxContext, default: &'a str, applicability: &mut Applicability, ) -> Self { if expr.span.ctxt() == ctxt { Self::hir_from_snippet(expr, |span| { snippet_with_context(cx, span, ctxt, default, applicability).0 }) } else { let (snip, _) = snippet_with_context(cx, expr.span, ctxt, default, applicability); Sugg::NonParen(snip) } } /// Generate a suggestion for an expression with the given snippet. This is used by the `hir_*` /// function variants of `Sugg`, since these use different snippet functions. fn hir_from_snippet(expr: &hir::Expr<'_>, mut get_snippet: impl FnMut(Span) -> Cow<'a, str>) -> Self { if let Some(range) = higher::Range::hir(expr) { let op = match range.limits { ast::RangeLimits::HalfOpen => AssocOp::DotDot, ast::RangeLimits::Closed => AssocOp::DotDotEq, }; let start = range.start.map_or("".into(), |expr| get_snippet(expr.span)); let end = range.end.map_or("".into(), |expr| get_snippet(expr.span)); return Sugg::BinOp(op, start, end); } match expr.kind { ExprKind::AddrOf(..) | ExprKind::If(..) | ExprKind::Let(..) | ExprKind::Closure { .. } | ExprKind::Unary(..) | ExprKind::Match(..) => Sugg::MaybeParen(get_snippet(expr.span)), ExprKind::Continue(..) | ExprKind::Yield(..) | ExprKind::Array(..) | ExprKind::Block(..) | ExprKind::Break(..) | ExprKind::Call(..) | ExprKind::Field(..) | ExprKind::Index(..) | ExprKind::InlineAsm(..) | ExprKind::OffsetOf(..) | ExprKind::ConstBlock(..) | ExprKind::Lit(..) | ExprKind::Loop(..) | ExprKind::MethodCall(..) | ExprKind::Path(..) | ExprKind::Repeat(..) | ExprKind::Ret(..) | ExprKind::Become(..) | ExprKind::Struct(..) | ExprKind::Tup(..) | ExprKind::Err(_) => Sugg::NonParen(get_snippet(expr.span)), ExprKind::DropTemps(inner) => Self::hir_from_snippet(inner, get_snippet), ExprKind::Assign(lhs, rhs, _) => { Sugg::BinOp(AssocOp::Assign, get_snippet(lhs.span), get_snippet(rhs.span)) }, ExprKind::AssignOp(op, lhs, rhs) => { Sugg::BinOp(hirbinop2assignop(op), get_snippet(lhs.span), get_snippet(rhs.span)) }, ExprKind::Binary(op, lhs, rhs) => Sugg::BinOp( AssocOp::from_ast_binop(op.node), get_snippet(lhs.span), get_snippet(rhs.span), ), ExprKind::Cast(lhs, ty) | //FIXME(chenyukang), remove this after type ascription is removed from AST ExprKind::Type(lhs, ty) => Sugg::BinOp(AssocOp::As, get_snippet(lhs.span), get_snippet(ty.span)), } } /// Prepare a suggestion from an expression. pub fn ast( cx: &EarlyContext<'_>, expr: &ast::Expr, default: &'a str, ctxt: SyntaxContext, app: &mut Applicability, ) -> Self { use rustc_ast::ast::RangeLimits; let mut snippet = |span: Span| snippet_with_context(cx, span, ctxt, default, app).0; match expr.kind { _ if expr.span.ctxt() != ctxt => Sugg::NonParen(snippet(expr.span)), ast::ExprKind::AddrOf(..) | ast::ExprKind::Closure { .. } | ast::ExprKind::If(..) | ast::ExprKind::Let(..) | ast::ExprKind::Unary(..) | ast::ExprKind::Match(..) => match snippet_with_context(cx, expr.span, ctxt, default, app) { (snip, false) => Sugg::MaybeParen(snip), (snip, true) => Sugg::NonParen(snip), }, ast::ExprKind::Gen(..) | ast::ExprKind::Block(..) | ast::ExprKind::Break(..) | ast::ExprKind::Call(..) | ast::ExprKind::Continue(..) | ast::ExprKind::Yield(..) | ast::ExprKind::Field(..) | ast::ExprKind::ForLoop { .. } | ast::ExprKind::Index(..) | ast::ExprKind::InlineAsm(..) | ast::ExprKind::OffsetOf(..) | ast::ExprKind::ConstBlock(..) | ast::ExprKind::Lit(..) | ast::ExprKind::IncludedBytes(..) | ast::ExprKind::Loop(..) | ast::ExprKind::MacCall(..) | ast::ExprKind::MethodCall(..) | ast::ExprKind::Paren(..) | ast::ExprKind::Underscore | ast::ExprKind::Path(..) | ast::ExprKind::Repeat(..) | ast::ExprKind::Ret(..) | ast::ExprKind::Become(..) | ast::ExprKind::Yeet(..) | ast::ExprKind::FormatArgs(..) | ast::ExprKind::Struct(..) | ast::ExprKind::Try(..) | ast::ExprKind::TryBlock(..) | ast::ExprKind::Tup(..) | ast::ExprKind::Array(..) | ast::ExprKind::While(..) | ast::ExprKind::Await(..) | ast::ExprKind::Err(_) | ast::ExprKind::Dummy => Sugg::NonParen(snippet(expr.span)), ast::ExprKind::Range(ref lhs, ref rhs, RangeLimits::HalfOpen) => Sugg::BinOp( AssocOp::DotDot, lhs.as_ref().map_or("".into(), |lhs| snippet(lhs.span)), rhs.as_ref().map_or("".into(), |rhs| snippet(rhs.span)), ), ast::ExprKind::Range(ref lhs, ref rhs, RangeLimits::Closed) => Sugg::BinOp( AssocOp::DotDotEq, lhs.as_ref().map_or("".into(), |lhs| snippet(lhs.span)), rhs.as_ref().map_or("".into(), |rhs| snippet(rhs.span)), ), ast::ExprKind::Assign(ref lhs, ref rhs, _) => Sugg::BinOp( AssocOp::Assign, snippet(lhs.span), snippet(rhs.span), ), ast::ExprKind::AssignOp(op, ref lhs, ref rhs) => Sugg::BinOp( astbinop2assignop(op), snippet(lhs.span), snippet(rhs.span), ), ast::ExprKind::Binary(op, ref lhs, ref rhs) => Sugg::BinOp( AssocOp::from_ast_binop(op.node), snippet(lhs.span), snippet(rhs.span), ), ast::ExprKind::Cast(ref lhs, ref ty) | //FIXME(chenyukang), remove this after type ascription is removed from AST ast::ExprKind::Type(ref lhs, ref ty) => Sugg::BinOp( AssocOp::As, snippet(lhs.span), snippet(ty.span), ), } } /// Convenience method to create the ` && ` suggestion. pub fn and(self, rhs: &Self) -> Sugg<'static> { make_binop(ast::BinOpKind::And, &self, rhs) } /// Convenience method to create the ` & ` suggestion. pub fn bit_and(self, rhs: &Self) -> Sugg<'static> { make_binop(ast::BinOpKind::BitAnd, &self, rhs) } /// Convenience method to create the ` as ` suggestion. pub fn as_ty(self, rhs: R) -> Sugg<'static> { make_assoc(AssocOp::As, &self, &Sugg::NonParen(rhs.to_string().into())) } /// Convenience method to create the `&` suggestion. pub fn addr(self) -> Sugg<'static> { make_unop("&", self) } /// Convenience method to create the `&mut ` suggestion. pub fn mut_addr(self) -> Sugg<'static> { make_unop("&mut ", self) } /// Convenience method to create the `*` suggestion. pub fn deref(self) -> Sugg<'static> { make_unop("*", self) } /// Convenience method to create the `&*` suggestion. Currently this /// is needed because `sugg.deref().addr()` produces an unnecessary set of /// parentheses around the deref. pub fn addr_deref(self) -> Sugg<'static> { make_unop("&*", self) } /// Convenience method to create the `&mut *` suggestion. Currently /// this is needed because `sugg.deref().mut_addr()` produces an unnecessary /// set of parentheses around the deref. pub fn mut_addr_deref(self) -> Sugg<'static> { make_unop("&mut *", self) } /// Convenience method to transform suggestion into a return call pub fn make_return(self) -> Sugg<'static> { Sugg::NonParen(Cow::Owned(format!("return {self}"))) } /// Convenience method to transform suggestion into a block /// where the suggestion is a trailing expression pub fn blockify(self) -> Sugg<'static> { Sugg::NonParen(Cow::Owned(format!("{{ {self} }}"))) } /// Convenience method to prefix the expression with the `async` keyword. /// Can be used after `blockify` to create an async block. pub fn asyncify(self) -> Sugg<'static> { Sugg::NonParen(Cow::Owned(format!("async {self}"))) } /// Convenience method to create the `..` or `...` /// suggestion. pub fn range(self, end: &Self, limit: ast::RangeLimits) -> Sugg<'static> { match limit { ast::RangeLimits::HalfOpen => make_assoc(AssocOp::DotDot, &self, end), ast::RangeLimits::Closed => make_assoc(AssocOp::DotDotEq, &self, end), } } /// Adds parentheses to any expression that might need them. Suitable to the /// `self` argument of a method call /// (e.g., to build `bar.foo()` or `(1 + 2).foo()`). #[must_use] pub fn maybe_par(self) -> Self { match self { Sugg::NonParen(..) => self, // `(x)` and `(x).y()` both don't need additional parens. Sugg::MaybeParen(sugg) => { if has_enclosing_paren(&sugg) { Sugg::MaybeParen(sugg) } else { Sugg::NonParen(format!("({sugg})").into()) } }, Sugg::BinOp(op, lhs, rhs) => { let sugg = binop_to_string(op, &lhs, &rhs); Sugg::NonParen(format!("({sugg})").into()) }, } } pub fn into_string(self) -> String { match self { Sugg::NonParen(p) | Sugg::MaybeParen(p) => p.into_owned(), Sugg::BinOp(b, l, r) => binop_to_string(b, &l, &r), } } } /// Generates a string from the operator and both sides. fn binop_to_string(op: AssocOp, lhs: &str, rhs: &str) -> String { match op { AssocOp::Add | AssocOp::Subtract | AssocOp::Multiply | AssocOp::Divide | AssocOp::Modulus | AssocOp::LAnd | AssocOp::LOr | AssocOp::BitXor | AssocOp::BitAnd | AssocOp::BitOr | AssocOp::ShiftLeft | AssocOp::ShiftRight | AssocOp::Equal | AssocOp::Less | AssocOp::LessEqual | AssocOp::NotEqual | AssocOp::Greater | AssocOp::GreaterEqual => { format!("{lhs} {} {rhs}", op.to_ast_binop().expect("Those are AST ops").as_str()) }, AssocOp::Assign => format!("{lhs} = {rhs}"), AssocOp::AssignOp(op) => { format!("{lhs} {}= {rhs}", token_kind_to_string(&token::BinOp(op))) }, AssocOp::As => format!("{lhs} as {rhs}"), AssocOp::DotDot => format!("{lhs}..{rhs}"), AssocOp::DotDotEq => format!("{lhs}..={rhs}"), } } /// Returns `true` if `sugg` is enclosed in parenthesis. pub fn has_enclosing_paren(sugg: impl AsRef) -> bool { let mut chars = sugg.as_ref().chars(); if chars.next() == Some('(') { let mut depth = 1; for c in &mut chars { if c == '(' { depth += 1; } else if c == ')' { depth -= 1; } if depth == 0 { break; } } chars.next().is_none() } else { false } } /// Copied from the rust standard library, and then edited macro_rules! forward_binop_impls_to_ref { (impl $imp:ident, $method:ident for $t:ty, type Output = $o:ty) => { impl $imp<$t> for &$t { type Output = $o; fn $method(self, other: $t) -> $o { $imp::$method(self, &other) } } impl $imp<&$t> for $t { type Output = $o; fn $method(self, other: &$t) -> $o { $imp::$method(&self, other) } } impl $imp for $t { type Output = $o; fn $method(self, other: $t) -> $o { $imp::$method(&self, &other) } } }; } impl Add for &Sugg<'_> { type Output = Sugg<'static>; fn add(self, rhs: &Sugg<'_>) -> Sugg<'static> { make_binop(ast::BinOpKind::Add, self, rhs) } } impl Sub for &Sugg<'_> { type Output = Sugg<'static>; fn sub(self, rhs: &Sugg<'_>) -> Sugg<'static> { make_binop(ast::BinOpKind::Sub, self, rhs) } } forward_binop_impls_to_ref!(impl Add, add for Sugg<'_>, type Output = Sugg<'static>); forward_binop_impls_to_ref!(impl Sub, sub for Sugg<'_>, type Output = Sugg<'static>); impl Neg for Sugg<'_> { type Output = Sugg<'static>; fn neg(self) -> Sugg<'static> { match &self { Self::BinOp(AssocOp::As, ..) => Sugg::MaybeParen(format!("-({self})").into()), _ => make_unop("-", self), } } } impl<'a> Not for Sugg<'a> { type Output = Sugg<'a>; fn not(self) -> Sugg<'a> { use AssocOp::{Equal, Greater, GreaterEqual, Less, LessEqual, NotEqual}; if let Sugg::BinOp(op, lhs, rhs) = self { let to_op = match op { Equal => NotEqual, NotEqual => Equal, Less => GreaterEqual, GreaterEqual => Less, Greater => LessEqual, LessEqual => Greater, _ => return make_unop("!", Sugg::BinOp(op, lhs, rhs)), }; Sugg::BinOp(to_op, lhs, rhs) } else { make_unop("!", self) } } } /// Helper type to display either `foo` or `(foo)`. struct ParenHelper { /// `true` if parentheses are needed. paren: bool, /// The main thing to display. wrapped: T, } impl ParenHelper { /// Builds a `ParenHelper`. fn new(paren: bool, wrapped: T) -> Self { Self { paren, wrapped } } } impl Display for ParenHelper { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> Result<(), fmt::Error> { if self.paren { write!(f, "({})", self.wrapped) } else { self.wrapped.fmt(f) } } } /// Builds the string for `` adding parenthesis when necessary. /// /// For convenience, the operator is taken as a string because all unary /// operators have the same /// precedence. pub fn make_unop(op: &str, expr: Sugg<'_>) -> Sugg<'static> { Sugg::MaybeParen(format!("{op}{}", expr.maybe_par()).into()) } /// Builds the string for ` ` adding parenthesis when necessary. /// /// Precedence of shift operator relative to other arithmetic operation is /// often confusing so /// parenthesis will always be added for a mix of these. pub fn make_assoc(op: AssocOp, lhs: &Sugg<'_>, rhs: &Sugg<'_>) -> Sugg<'static> { /// Returns `true` if the operator is a shift operator `<<` or `>>`. fn is_shift(op: AssocOp) -> bool { matches!(op, AssocOp::ShiftLeft | AssocOp::ShiftRight) } /// Returns `true` if the operator is an arithmetic operator /// (i.e., `+`, `-`, `*`, `/`, `%`). fn is_arith(op: AssocOp) -> bool { matches!( op, AssocOp::Add | AssocOp::Subtract | AssocOp::Multiply | AssocOp::Divide | AssocOp::Modulus ) } /// Returns `true` if the operator `op` needs parenthesis with the operator /// `other` in the direction `dir`. fn needs_paren(op: AssocOp, other: AssocOp, dir: Associativity) -> bool { other.precedence() < op.precedence() || (other.precedence() == op.precedence() && ((op != other && associativity(op) != dir) || (op == other && associativity(op) != Associativity::Both))) || is_shift(op) && is_arith(other) || is_shift(other) && is_arith(op) } let lhs_paren = if let Sugg::BinOp(lop, _, _) = *lhs { needs_paren(op, lop, Associativity::Left) } else { false }; let rhs_paren = if let Sugg::BinOp(rop, _, _) = *rhs { needs_paren(op, rop, Associativity::Right) } else { false }; let lhs = ParenHelper::new(lhs_paren, lhs).to_string(); let rhs = ParenHelper::new(rhs_paren, rhs).to_string(); Sugg::BinOp(op, lhs.into(), rhs.into()) } /// Convenience wrapper around `make_assoc` and `AssocOp::from_ast_binop`. pub fn make_binop(op: ast::BinOpKind, lhs: &Sugg<'_>, rhs: &Sugg<'_>) -> Sugg<'static> { make_assoc(AssocOp::from_ast_binop(op), lhs, rhs) } #[derive(PartialEq, Eq, Clone, Copy)] /// Operator associativity. enum Associativity { /// The operator is both left-associative and right-associative. Both, /// The operator is left-associative. Left, /// The operator is not associative. None, /// The operator is right-associative. Right, } /// Returns the associativity/fixity of an operator. The difference with /// `AssocOp::fixity` is that an operator can be both left and right associative /// (such as `+`: `a + b + c == (a + b) + c == a + (b + c)`. /// /// Chained `as` and explicit `:` type coercion never need inner parenthesis so /// they are considered /// associative. #[must_use] fn associativity(op: AssocOp) -> Associativity { use rustc_ast::util::parser::AssocOp::{ Add, As, Assign, AssignOp, BitAnd, BitOr, BitXor, Divide, DotDot, DotDotEq, Equal, Greater, GreaterEqual, LAnd, LOr, Less, LessEqual, Modulus, Multiply, NotEqual, ShiftLeft, ShiftRight, Subtract, }; match op { Assign | AssignOp(_) => Associativity::Right, Add | BitAnd | BitOr | BitXor | LAnd | LOr | Multiply | As => Associativity::Both, Divide | Equal | Greater | GreaterEqual | Less | LessEqual | Modulus | NotEqual | ShiftLeft | ShiftRight | Subtract => Associativity::Left, DotDot | DotDotEq => Associativity::None, } } /// Converts a `hir::BinOp` to the corresponding assigning binary operator. fn hirbinop2assignop(op: hir::BinOp) -> AssocOp { use rustc_ast::token::BinOpToken::{And, Caret, Minus, Or, Percent, Plus, Shl, Shr, Slash, Star}; AssocOp::AssignOp(match op.node { hir::BinOpKind::Add => Plus, hir::BinOpKind::BitAnd => And, hir::BinOpKind::BitOr => Or, hir::BinOpKind::BitXor => Caret, hir::BinOpKind::Div => Slash, hir::BinOpKind::Mul => Star, hir::BinOpKind::Rem => Percent, hir::BinOpKind::Shl => Shl, hir::BinOpKind::Shr => Shr, hir::BinOpKind::Sub => Minus, hir::BinOpKind::And | hir::BinOpKind::Eq | hir::BinOpKind::Ge | hir::BinOpKind::Gt | hir::BinOpKind::Le | hir::BinOpKind::Lt | hir::BinOpKind::Ne | hir::BinOpKind::Or => panic!("This operator does not exist"), }) } /// Converts an `ast::BinOp` to the corresponding assigning binary operator. fn astbinop2assignop(op: ast::BinOp) -> AssocOp { use rustc_ast::ast::BinOpKind::{ Add, And, BitAnd, BitOr, BitXor, Div, Eq, Ge, Gt, Le, Lt, Mul, Ne, Or, Rem, Shl, Shr, Sub, }; use rustc_ast::token::BinOpToken; AssocOp::AssignOp(match op.node { Add => BinOpToken::Plus, BitAnd => BinOpToken::And, BitOr => BinOpToken::Or, BitXor => BinOpToken::Caret, Div => BinOpToken::Slash, Mul => BinOpToken::Star, Rem => BinOpToken::Percent, Shl => BinOpToken::Shl, Shr => BinOpToken::Shr, Sub => BinOpToken::Minus, And | Eq | Ge | Gt | Le | Lt | Ne | Or => panic!("This operator does not exist"), }) } /// Returns the indentation before `span` if there are nothing but `[ \t]` /// before it on its line. fn indentation(cx: &T, span: Span) -> Option { let lo = cx.sess().source_map().lookup_char_pos(span.lo()); lo.file .get_line(lo.line - 1 /* line numbers in `Loc` are 1-based */) .and_then(|line| { if let Some((pos, _)) = line.char_indices().find(|&(_, c)| c != ' ' && c != '\t') { // We can mix char and byte positions here because we only consider `[ \t]`. if lo.col == CharPos(pos) { Some(line[..pos].into()) } else { None } } else { None } }) } /// Convenience extension trait for `Diag`. pub trait DiagExt { /// Suggests to add an attribute to an item. /// /// Correctly handles indentation of the attribute and item. /// /// # Example /// /// ```rust,ignore /// diag.suggest_item_with_attr(cx, item, "#[derive(Default)]"); /// ``` fn suggest_item_with_attr( &mut self, cx: &T, item: Span, msg: &str, attr: &D, applicability: Applicability, ); /// Suggest to add an item before another. /// /// The item should not be indented (except for inner indentation). /// /// # Example /// /// ```rust,ignore /// diag.suggest_prepend_item(cx, item, /// "fn foo() { /// bar(); /// }"); /// ``` fn suggest_prepend_item(&mut self, cx: &T, item: Span, msg: &str, new_item: &str, applicability: Applicability); /// Suggest to completely remove an item. /// /// This will remove an item and all following whitespace until the next non-whitespace /// character. This should work correctly if item is on the same indentation level as the /// following item. /// /// # Example /// /// ```rust,ignore /// diag.suggest_remove_item(cx, item, "remove this") /// ``` fn suggest_remove_item(&mut self, cx: &T, item: Span, msg: &str, applicability: Applicability); } impl DiagExt for rustc_errors::Diag<'_, ()> { fn suggest_item_with_attr( &mut self, cx: &T, item: Span, msg: &str, attr: &D, applicability: Applicability, ) { if let Some(indent) = indentation(cx, item) { let span = item.with_hi(item.lo()); self.span_suggestion(span, msg.to_string(), format!("{attr}\n{indent}"), applicability); } } fn suggest_prepend_item(&mut self, cx: &T, item: Span, msg: &str, new_item: &str, applicability: Applicability) { if let Some(indent) = indentation(cx, item) { let span = item.with_hi(item.lo()); let mut first = true; let new_item = new_item .lines() .map(|l| { if first { first = false; format!("{l}\n") } else { format!("{indent}{l}\n") } }) .collect::(); self.span_suggestion(span, msg.to_string(), format!("{new_item}\n{indent}"), applicability); } } fn suggest_remove_item(&mut self, cx: &T, item: Span, msg: &str, applicability: Applicability) { let mut remove_span = item; let fmpos = cx.sess().source_map().lookup_byte_offset(remove_span.hi()); if let Some(ref src) = fmpos.sf.src { let non_whitespace_offset = src[fmpos.pos.to_usize()..].find(|c| c != ' ' && c != '\t' && c != '\n'); if let Some(non_whitespace_offset) = non_whitespace_offset { remove_span = remove_span .with_hi(remove_span.hi() + BytePos(non_whitespace_offset.try_into().expect("offset too large"))); } } self.span_suggestion(remove_span, msg.to_string(), "", applicability); } } /// Suggestion results for handling closure /// args dereferencing and borrowing pub struct DerefClosure { /// confidence on the built suggestion pub applicability: Applicability, /// gradually built suggestion pub suggestion: String, } /// Build suggestion gradually by handling closure arg specific usages, /// such as explicit deref and borrowing cases. /// Returns `None` if no such use cases have been triggered in closure body /// /// note: this only works on single line immutable closures with exactly one input parameter. pub fn deref_closure_args(cx: &LateContext<'_>, closure: &hir::Expr<'_>) -> Option { if let ExprKind::Closure(&Closure { fn_decl, def_id, body, .. }) = closure.kind { let closure_body = cx.tcx.hir().body(body); // is closure arg a type annotated double reference (i.e.: `|x: &&i32| ...`) // a type annotation is present if param `kind` is different from `TyKind::Infer` let closure_arg_is_type_annotated_double_ref = if let TyKind::Ref(_, MutTy { ty, .. }) = fn_decl.inputs[0].kind { matches!(ty.kind, TyKind::Ref(_, MutTy { .. })) } else { false }; let mut visitor = DerefDelegate { cx, closure_span: closure.span, closure_arg_is_type_annotated_double_ref, next_pos: closure.span.lo(), suggestion_start: String::new(), applicability: Applicability::MachineApplicable, }; ExprUseVisitor::for_clippy(cx, def_id, &mut visitor) .consume_body(closure_body) .into_ok(); if !visitor.suggestion_start.is_empty() { return Some(DerefClosure { applicability: visitor.applicability, suggestion: visitor.finish(), }); } } None } /// Visitor struct used for tracking down /// dereferencing and borrowing of closure's args struct DerefDelegate<'a, 'tcx> { /// The late context of the lint cx: &'a LateContext<'tcx>, /// The span of the input closure to adapt closure_span: Span, /// Indicates if the arg of the closure is a type annotated double reference closure_arg_is_type_annotated_double_ref: bool, /// last position of the span to gradually build the suggestion next_pos: BytePos, /// starting part of the gradually built suggestion suggestion_start: String, /// confidence on the built suggestion applicability: Applicability, } impl<'tcx> DerefDelegate<'_, 'tcx> { /// build final suggestion: /// - create the ending part of suggestion /// - concatenate starting and ending parts /// - potentially remove needless borrowing pub fn finish(&mut self) -> String { let end_span = Span::new(self.next_pos, self.closure_span.hi(), self.closure_span.ctxt(), None); let end_snip = snippet_with_applicability(self.cx, end_span, "..", &mut self.applicability); let sugg = format!("{}{end_snip}", self.suggestion_start); if self.closure_arg_is_type_annotated_double_ref { sugg.replacen('&', "", 1) } else { sugg } } /// indicates whether the function from `parent_expr` takes its args by double reference fn func_takes_arg_by_double_ref(&self, parent_expr: &'tcx hir::Expr<'_>, cmt_hir_id: HirId) -> bool { let ty = match parent_expr.kind { ExprKind::MethodCall(_, receiver, call_args, _) => { if let Some(sig) = self .cx .typeck_results() .type_dependent_def_id(parent_expr.hir_id) .map(|did| self.cx.tcx.fn_sig(did).instantiate_identity().skip_binder()) { std::iter::once(receiver) .chain(call_args.iter()) .position(|arg| arg.hir_id == cmt_hir_id) .map(|i| sig.inputs()[i]) } else { return false; } }, ExprKind::Call(func, call_args) => { if let Some(sig) = expr_sig(self.cx, func) { call_args .iter() .position(|arg| arg.hir_id == cmt_hir_id) .and_then(|i| sig.input(i)) .map(ty::Binder::skip_binder) } else { return false; } }, _ => return false, }; ty.map_or(false, |ty| matches!(ty.kind(), ty::Ref(_, inner, _) if inner.is_ref())) } } impl<'tcx> Delegate<'tcx> for DerefDelegate<'_, 'tcx> { fn consume(&mut self, _: &PlaceWithHirId<'tcx>, _: HirId) {} fn borrow(&mut self, cmt: &PlaceWithHirId<'tcx>, _: HirId, _: ty::BorrowKind) { if let PlaceBase::Local(id) = cmt.place.base { let map = self.cx.tcx.hir(); let span = map.span(cmt.hir_id); let start_span = Span::new(self.next_pos, span.lo(), span.ctxt(), None); let mut start_snip = snippet_with_applicability(self.cx, start_span, "..", &mut self.applicability); // identifier referring to the variable currently triggered (i.e.: `fp`) let ident_str = map.name(id).to_string(); // full identifier that includes projection (i.e.: `fp.field`) let ident_str_with_proj = snippet(self.cx, span, "..").to_string(); if cmt.place.projections.is_empty() { // handle item without any projection, that needs an explicit borrowing // i.e.: suggest `&x` instead of `x` let _: fmt::Result = write!(self.suggestion_start, "{start_snip}&{ident_str}"); } else { // cases where a parent `Call` or `MethodCall` is using the item // i.e.: suggest `.contains(&x)` for `.find(|x| [1, 2, 3].contains(x)).is_none()` // // Note about method calls: // - compiler automatically dereference references if the target type is a reference (works also for // function call) // - `self` arguments in the case of `x.is_something()` are also automatically (de)referenced, and // no projection should be suggested if let Some(parent_expr) = get_parent_expr_for_hir(self.cx, cmt.hir_id) { match &parent_expr.kind { // given expression is the self argument and will be handled completely by the compiler // i.e.: `|x| x.is_something()` ExprKind::MethodCall(_, self_expr, ..) if self_expr.hir_id == cmt.hir_id => { let _: fmt::Result = write!(self.suggestion_start, "{start_snip}{ident_str_with_proj}"); self.next_pos = span.hi(); return; }, // item is used in a call // i.e.: `Call`: `|x| please(x)` or `MethodCall`: `|x| [1, 2, 3].contains(x)` ExprKind::Call(_, call_args) | ExprKind::MethodCall(_, _, call_args, _) => { let expr = self.cx.tcx.hir().expect_expr(cmt.hir_id); let arg_ty_kind = self.cx.typeck_results().expr_ty(expr).kind(); if matches!(arg_ty_kind, ty::Ref(_, _, Mutability::Not)) { // suggest ampersand if call function is taking args by double reference let takes_arg_by_double_ref = self.func_takes_arg_by_double_ref(parent_expr, cmt.hir_id); // compiler will automatically dereference field or index projection, so no need // to suggest ampersand, but full identifier that includes projection is required let has_field_or_index_projection = cmt.place.projections.iter().any(|proj| { matches!(proj.kind, ProjectionKind::Field(..) | ProjectionKind::Index) }); // no need to bind again if the function doesn't take arg by double ref // and if the item is already a double ref let ident_sugg = if !call_args.is_empty() && !takes_arg_by_double_ref && (self.closure_arg_is_type_annotated_double_ref || has_field_or_index_projection) { let ident = if has_field_or_index_projection { ident_str_with_proj } else { ident_str }; format!("{start_snip}{ident}") } else { format!("{start_snip}&{ident_str}") }; self.suggestion_start.push_str(&ident_sugg); self.next_pos = span.hi(); return; } self.applicability = Applicability::Unspecified; }, _ => (), } } let mut replacement_str = ident_str; let mut projections_handled = false; cmt.place.projections.iter().enumerate().for_each(|(i, proj)| { match proj.kind { // Field projection like `|v| v.foo` // no adjustment needed here, as field projections are handled by the compiler ProjectionKind::Field(..) => match cmt.place.ty_before_projection(i).kind() { ty::Adt(..) | ty::Tuple(_) => { replacement_str.clone_from(&ident_str_with_proj); projections_handled = true; }, _ => (), }, // Index projection like `|x| foo[x]` // the index is dropped so we can't get it to build the suggestion, // so the span is set-up again to get more code, using `span.hi()` (i.e.: `foo[x]`) // instead of `span.lo()` (i.e.: `foo`) ProjectionKind::Index => { let start_span = Span::new(self.next_pos, span.hi(), span.ctxt(), None); start_snip = snippet_with_applicability(self.cx, start_span, "..", &mut self.applicability); replacement_str.clear(); projections_handled = true; }, // note: unable to trigger `Subslice` kind in tests ProjectionKind::Subslice | // Doesn't have surface syntax. Only occurs in patterns. ProjectionKind::OpaqueCast => (), ProjectionKind::Deref => { // Explicit derefs are typically handled later on, but // some items do not need explicit deref, such as array accesses, // so we mark them as already processed // i.e.: don't suggest `*sub[1..4].len()` for `|sub| sub[1..4].len() == 3` if let ty::Ref(_, inner, _) = cmt.place.ty_before_projection(i).kind() { if matches!(inner.kind(), ty::Ref(_, innermost, _) if innermost.is_array()) { projections_handled = true; } } }, } }); // handle `ProjectionKind::Deref` by removing one explicit deref // if no special case was detected (i.e.: suggest `*x` instead of `**x`) if !projections_handled { let last_deref = cmt .place .projections .iter() .rposition(|proj| proj.kind == ProjectionKind::Deref); if let Some(pos) = last_deref { let mut projections = cmt.place.projections.clone(); projections.truncate(pos); for item in projections { if item.kind == ProjectionKind::Deref { replacement_str = format!("*{replacement_str}"); } } } } let _: fmt::Result = write!(self.suggestion_start, "{start_snip}{replacement_str}"); } self.next_pos = span.hi(); } } fn mutate(&mut self, _: &PlaceWithHirId<'tcx>, _: HirId) {} fn fake_read(&mut self, _: &PlaceWithHirId<'tcx>, _: FakeReadCause, _: HirId) {} } #[cfg(test)] mod test { use super::Sugg; use rustc_ast::util::parser::AssocOp; use std::borrow::Cow; const SUGGESTION: Sugg<'static> = Sugg::NonParen(Cow::Borrowed("function_call()")); #[test] fn make_return_transform_sugg_into_a_return_call() { assert_eq!("return function_call()", SUGGESTION.make_return().to_string()); } #[test] fn blockify_transforms_sugg_into_a_block() { assert_eq!("{ function_call() }", SUGGESTION.blockify().to_string()); } #[test] fn binop_maybe_par() { let sugg = Sugg::BinOp(AssocOp::Add, "1".into(), "1".into()); assert_eq!("(1 + 1)", sugg.maybe_par().to_string()); let sugg = Sugg::BinOp(AssocOp::Add, "(1 + 1)".into(), "(1 + 1)".into()); assert_eq!("((1 + 1) + (1 + 1))", sugg.maybe_par().to_string()); } #[test] fn not_op() { use AssocOp::{Add, Equal, Greater, GreaterEqual, LAnd, LOr, Less, LessEqual, NotEqual}; fn test_not(op: AssocOp, correct: &str) { let sugg = Sugg::BinOp(op, "x".into(), "y".into()); assert_eq!((!sugg).to_string(), correct); } // Invert the comparison operator. test_not(Equal, "x != y"); test_not(NotEqual, "x == y"); test_not(Less, "x >= y"); test_not(LessEqual, "x > y"); test_not(Greater, "x <= y"); test_not(GreaterEqual, "x < y"); // Other operators are inverted like !(..). test_not(Add, "!(x + y)"); test_not(LAnd, "!(x && y)"); test_not(LOr, "!(x || y)"); } }