use std::borrow::Cow; use std::iter; use std::ops::{Deref, Range}; use clippy_utils::diagnostics::{span_lint, span_lint_and_sugg, span_lint_and_then}; use clippy_utils::source::{snippet, snippet_opt, snippet_with_applicability}; use rustc_ast::ast::{Expr, ExprKind, Impl, Item, ItemKind, MacCall, Path, StrLit, StrStyle}; use rustc_ast::ptr::P; use rustc_ast::token::{self, LitKind}; use rustc_ast::tokenstream::TokenStream; use rustc_errors::{Applicability, DiagnosticBuilder}; use rustc_lexer::unescape::{self, EscapeError}; use rustc_lint::{EarlyContext, EarlyLintPass, LintContext}; use rustc_parse::parser; use rustc_session::{declare_tool_lint, impl_lint_pass}; use rustc_span::symbol::{kw, Symbol}; use rustc_span::{sym, BytePos, InnerSpan, Span, DUMMY_SP}; declare_clippy_lint! { /// ### What it does /// This lint warns when you use `println!("")` to /// print a newline. /// /// ### Why is this bad? /// You should use `println!()`, which is simpler. /// /// ### Example /// ```rust /// println!(""); /// ``` /// /// Use instead: /// ```rust /// println!(); /// ``` #[clippy::version = "pre 1.29.0"] pub PRINTLN_EMPTY_STRING, style, "using `println!(\"\")` with an empty string" } declare_clippy_lint! { /// ### What it does /// This lint warns when you use `print!()` with a format /// string that ends in a newline. /// /// ### Why is this bad? /// You should use `println!()` instead, which appends the /// newline. /// /// ### Example /// ```rust /// # let name = "World"; /// print!("Hello {}!\n", name); /// ``` /// use println!() instead /// ```rust /// # let name = "World"; /// println!("Hello {}!", name); /// ``` #[clippy::version = "pre 1.29.0"] pub PRINT_WITH_NEWLINE, style, "using `print!()` with a format string that ends in a single newline" } declare_clippy_lint! { /// ### What it does /// Checks for printing on *stdout*. The purpose of this lint /// is to catch debugging remnants. /// /// ### Why is this bad? /// People often print on *stdout* while debugging an /// application and might forget to remove those prints afterward. /// /// ### Known problems /// * Only catches `print!` and `println!` calls. /// * The lint level is unaffected by crate attributes. The level can still /// be set for functions, modules and other items. To change the level for /// the entire crate, please use command line flags. More information and a /// configuration example can be found in [clippy#6610]. /// /// [clippy#6610]: https://github.com/rust-lang/rust-clippy/issues/6610#issuecomment-977120558 /// /// ### Example /// ```rust /// println!("Hello world!"); /// ``` #[clippy::version = "pre 1.29.0"] pub PRINT_STDOUT, restriction, "printing on stdout" } declare_clippy_lint! { /// ### What it does /// Checks for printing on *stderr*. The purpose of this lint /// is to catch debugging remnants. /// /// ### Why is this bad? /// People often print on *stderr* while debugging an /// application and might forget to remove those prints afterward. /// /// ### Known problems /// * Only catches `eprint!` and `eprintln!` calls. /// * The lint level is unaffected by crate attributes. The level can still /// be set for functions, modules and other items. To change the level for /// the entire crate, please use command line flags. More information and a /// configuration example can be found in [clippy#6610]. /// /// [clippy#6610]: https://github.com/rust-lang/rust-clippy/issues/6610#issuecomment-977120558 /// /// ### Example /// ```rust /// eprintln!("Hello world!"); /// ``` #[clippy::version = "1.50.0"] pub PRINT_STDERR, restriction, "printing on stderr" } declare_clippy_lint! { /// ### What it does /// Checks for use of `Debug` formatting. The purpose of this /// lint is to catch debugging remnants. /// /// ### Why is this bad? /// The purpose of the `Debug` trait is to facilitate /// debugging Rust code. It should not be used in user-facing output. /// /// ### Example /// ```rust /// # let foo = "bar"; /// println!("{:?}", foo); /// ``` #[clippy::version = "pre 1.29.0"] pub USE_DEBUG, restriction, "use of `Debug`-based formatting" } declare_clippy_lint! { /// ### What it does /// This lint warns about the use of literals as `print!`/`println!` args. /// /// ### Why is this bad? /// Using literals as `println!` args is inefficient /// (c.f., https://github.com/matthiaskrgr/rust-str-bench) and unnecessary /// (i.e., just put the literal in the format string) /// /// ### Known problems /// Will also warn with macro calls as arguments that expand to literals /// -- e.g., `println!("{}", env!("FOO"))`. /// /// ### Example /// ```rust /// println!("{}", "foo"); /// ``` /// use the literal without formatting: /// ```rust /// println!("foo"); /// ``` #[clippy::version = "pre 1.29.0"] pub PRINT_LITERAL, style, "printing a literal with a format string" } declare_clippy_lint! { /// ### What it does /// This lint warns when you use `writeln!(buf, "")` to /// print a newline. /// /// ### Why is this bad? /// You should use `writeln!(buf)`, which is simpler. /// /// ### Example /// ```rust /// # use std::fmt::Write; /// # let mut buf = String::new(); /// writeln!(buf, ""); /// ``` /// /// Use instead: /// ```rust /// # use std::fmt::Write; /// # let mut buf = String::new(); /// writeln!(buf); /// ``` #[clippy::version = "pre 1.29.0"] pub WRITELN_EMPTY_STRING, style, "using `writeln!(buf, \"\")` with an empty string" } declare_clippy_lint! { /// ### What it does /// This lint warns when you use `write!()` with a format /// string that /// ends in a newline. /// /// ### Why is this bad? /// You should use `writeln!()` instead, which appends the /// newline. /// /// ### Example /// ```rust /// # use std::fmt::Write; /// # let mut buf = String::new(); /// # let name = "World"; /// write!(buf, "Hello {}!\n", name); /// ``` /// /// Use instead: /// ```rust /// # use std::fmt::Write; /// # let mut buf = String::new(); /// # let name = "World"; /// writeln!(buf, "Hello {}!", name); /// ``` #[clippy::version = "pre 1.29.0"] pub WRITE_WITH_NEWLINE, style, "using `write!()` with a format string that ends in a single newline" } declare_clippy_lint! { /// ### What it does /// This lint warns about the use of literals as `write!`/`writeln!` args. /// /// ### Why is this bad? /// Using literals as `writeln!` args is inefficient /// (c.f., https://github.com/matthiaskrgr/rust-str-bench) and unnecessary /// (i.e., just put the literal in the format string) /// /// ### Known problems /// Will also warn with macro calls as arguments that expand to literals /// -- e.g., `writeln!(buf, "{}", env!("FOO"))`. /// /// ### Example /// ```rust /// # use std::fmt::Write; /// # let mut buf = String::new(); /// writeln!(buf, "{}", "foo"); /// ``` /// /// Use instead: /// ```rust /// # use std::fmt::Write; /// # let mut buf = String::new(); /// writeln!(buf, "foo"); /// ``` #[clippy::version = "pre 1.29.0"] pub WRITE_LITERAL, style, "writing a literal with a format string" } declare_clippy_lint! { /// ### What it does /// This lint warns when a named parameter in a format string is used as a positional one. /// /// ### Why is this bad? /// It may be confused for an assignment and obfuscates which parameter is being used. /// /// ### Example /// ```rust /// println!("{}", x = 10); /// ``` /// /// Use instead: /// ```rust /// println!("{x}", x = 10); /// ``` #[clippy::version = "1.63.0"] pub POSITIONAL_NAMED_FORMAT_PARAMETERS, suspicious, "named parameter in a format string is used positionally" } #[derive(Default)] pub struct Write { in_debug_impl: bool, } impl_lint_pass!(Write => [ PRINT_WITH_NEWLINE, PRINTLN_EMPTY_STRING, PRINT_STDOUT, PRINT_STDERR, USE_DEBUG, PRINT_LITERAL, WRITE_WITH_NEWLINE, WRITELN_EMPTY_STRING, WRITE_LITERAL, POSITIONAL_NAMED_FORMAT_PARAMETERS, ]); impl EarlyLintPass for Write { fn check_item(&mut self, _: &EarlyContext<'_>, item: &Item) { if let ItemKind::Impl(box Impl { of_trait: Some(trait_ref), .. }) = &item.kind { let trait_name = trait_ref .path .segments .iter() .last() .expect("path has at least one segment") .ident .name; if trait_name == sym::Debug { self.in_debug_impl = true; } } } fn check_item_post(&mut self, _: &EarlyContext<'_>, _: &Item) { self.in_debug_impl = false; } fn check_mac(&mut self, cx: &EarlyContext<'_>, mac: &MacCall) { fn is_build_script(cx: &EarlyContext<'_>) -> bool { // Cargo sets the crate name for build scripts to `build_script_build` cx.sess() .opts .crate_name .as_ref() .map_or(false, |crate_name| crate_name == "build_script_build") } if mac.path == sym!(print) { if !is_build_script(cx) { span_lint(cx, PRINT_STDOUT, mac.span(), "use of `print!`"); } self.lint_print_with_newline(cx, mac); } else if mac.path == sym!(println) { if !is_build_script(cx) { span_lint(cx, PRINT_STDOUT, mac.span(), "use of `println!`"); } self.lint_println_empty_string(cx, mac); } else if mac.path == sym!(eprint) { span_lint(cx, PRINT_STDERR, mac.span(), "use of `eprint!`"); self.lint_print_with_newline(cx, mac); } else if mac.path == sym!(eprintln) { span_lint(cx, PRINT_STDERR, mac.span(), "use of `eprintln!`"); self.lint_println_empty_string(cx, mac); } else if mac.path == sym!(write) { if let (Some(fmt_str), dest) = self.check_tts(cx, mac.args.inner_tokens(), true) { if check_newlines(&fmt_str) { let (nl_span, only_nl) = newline_span(&fmt_str); let nl_span = match (dest, only_nl) { // Special case of `write!(buf, "\n")`: Mark everything from the end of // `buf` for removal so no trailing comma [`writeln!(buf, )`] remains. (Some(dest_expr), true) => nl_span.with_lo(dest_expr.span.hi()), _ => nl_span, }; span_lint_and_then( cx, WRITE_WITH_NEWLINE, mac.span(), "using `write!()` with a format string that ends in a single newline", |err| { err.multipart_suggestion( "use `writeln!()` instead", vec![(mac.path.span, String::from("writeln")), (nl_span, String::new())], Applicability::MachineApplicable, ); }, ); } } } else if mac.path == sym!(writeln) { if let (Some(fmt_str), expr) = self.check_tts(cx, mac.args.inner_tokens(), true) { if fmt_str.symbol == kw::Empty { let mut applicability = Applicability::MachineApplicable; let suggestion = if let Some(e) = expr { snippet_with_applicability(cx, e.span, "v", &mut applicability) } else { applicability = Applicability::HasPlaceholders; Cow::Borrowed("v") }; span_lint_and_sugg( cx, WRITELN_EMPTY_STRING, mac.span(), format!("using `writeln!({}, \"\")`", suggestion).as_str(), "replace it with", format!("writeln!({})", suggestion), applicability, ); } } } } } /// Given a format string that ends in a newline and its span, calculates the span of the /// newline, or the format string itself if the format string consists solely of a newline. /// Return this and a boolean indicating whether it only consisted of a newline. fn newline_span(fmtstr: &StrLit) -> (Span, bool) { let sp = fmtstr.span; let contents = fmtstr.symbol.as_str(); if contents == r"\n" { return (sp, true); } let newline_sp_hi = sp.hi() - match fmtstr.style { StrStyle::Cooked => BytePos(1), StrStyle::Raw(hashes) => BytePos((1 + hashes).into()), }; let newline_sp_len = if contents.ends_with('\n') { BytePos(1) } else if contents.ends_with(r"\n") { BytePos(2) } else { panic!("expected format string to contain a newline"); }; (sp.with_lo(newline_sp_hi - newline_sp_len).with_hi(newline_sp_hi), false) } /// Stores a list of replacement spans for each argument, but only if all the replacements used an /// empty format string. #[derive(Default)] struct SimpleFormatArgs { unnamed: Vec>, complex_unnamed: Vec>, named: Vec<(Symbol, Vec)>, } impl SimpleFormatArgs { fn get_unnamed(&self) -> impl Iterator { self.unnamed.iter().map(|x| match x.as_slice() { // Ignore the dummy span added from out of order format arguments. [DUMMY_SP] => &[], x => x, }) } fn get_complex_unnamed(&self) -> impl Iterator { self.complex_unnamed.iter().map(Vec::as_slice) } fn get_named(&self, n: &Path) -> &[Span] { self.named.iter().find(|x| *n == x.0).map_or(&[], |x| x.1.as_slice()) } fn push(&mut self, arg: rustc_parse_format::Argument<'_>, span: Span) { use rustc_parse_format::{ AlignUnknown, ArgumentImplicitlyIs, ArgumentIs, ArgumentNamed, CountImplied, FormatSpec, }; const SIMPLE: FormatSpec<'_> = FormatSpec { fill: None, align: AlignUnknown, flags: 0, precision: CountImplied, precision_span: None, width: CountImplied, width_span: None, ty: "", ty_span: None, }; match arg.position { ArgumentIs(n) | ArgumentImplicitlyIs(n) => { if self.unnamed.len() <= n { // Use a dummy span to mark all unseen arguments. self.unnamed.resize_with(n, || vec![DUMMY_SP]); if arg.format == SIMPLE { self.unnamed.push(vec![span]); } else { self.unnamed.push(Vec::new()); } } else { let args = &mut self.unnamed[n]; match (args.as_mut_slice(), arg.format == SIMPLE) { // A non-empty format string has been seen already. ([], _) => (), // Replace the dummy span, if it exists. ([dummy @ DUMMY_SP], true) => *dummy = span, ([_, ..], true) => args.push(span), ([_, ..], false) => *args = Vec::new(), } } }, ArgumentNamed(n) => { let n = Symbol::intern(n); if let Some(x) = self.named.iter_mut().find(|x| x.0 == n) { match x.1.as_slice() { // A non-empty format string has been seen already. [] => (), [_, ..] if arg.format == SIMPLE => x.1.push(span), [_, ..] => x.1 = Vec::new(), } } else if arg.format == SIMPLE { self.named.push((n, vec![span])); } else { self.named.push((n, Vec::new())); } }, }; } fn push_to_complex(&mut self, span: Span, position: usize) { if self.complex_unnamed.len() <= position { self.complex_unnamed.resize_with(position, Vec::new); self.complex_unnamed.push(vec![span]); } else { let args: &mut Vec = &mut self.complex_unnamed[position]; args.push(span); } } fn push_complex( &mut self, cx: &EarlyContext<'_>, arg: rustc_parse_format::Argument<'_>, str_lit_span: Span, fmt_span: Span, ) { use rustc_parse_format::{ArgumentImplicitlyIs, ArgumentIs, CountIsParam}; let snippet = snippet_opt(cx, fmt_span); let end = snippet .as_ref() .and_then(|s| s.find(':')) .or_else(|| fmt_span.hi().0.checked_sub(fmt_span.lo().0 + 1).map(|u| u as usize)); if let (ArgumentIs(n) | ArgumentImplicitlyIs(n), Some(end)) = (arg.position, end) { let span = fmt_span.from_inner(InnerSpan::new(1, end)); self.push_to_complex(span, n); }; if let (CountIsParam(n), Some(span)) = (arg.format.precision, arg.format.precision_span) { // We need to do this hack as precision spans should be converted from .* to .foo$ let hack = if snippet.as_ref().and_then(|s| s.find('*')).is_some() { 0 } else { 1 }; let span = str_lit_span.from_inner(InnerSpan { start: span.start + 1, end: span.end - hack, }); self.push_to_complex(span, n); }; if let (CountIsParam(n), Some(span)) = (arg.format.width, arg.format.width_span) { let span = str_lit_span.from_inner(InnerSpan { start: span.start, end: span.end - 1, }); self.push_to_complex(span, n); }; } } impl Write { /// Parses a format string into a collection of spans for each argument. This only keeps track /// of empty format arguments. Will also lint usages of debug format strings outside of debug /// impls. fn parse_fmt_string(&self, cx: &EarlyContext<'_>, str_lit: &StrLit) -> Option { use rustc_parse_format::{ParseMode, Parser, Piece}; let str_sym = str_lit.symbol_unescaped.as_str(); let style = match str_lit.style { StrStyle::Cooked => None, StrStyle::Raw(n) => Some(n as usize), }; let mut parser = Parser::new(str_sym, style, snippet_opt(cx, str_lit.span), false, ParseMode::Format); let mut args = SimpleFormatArgs::default(); while let Some(arg) = parser.next() { let arg = match arg { Piece::String(_) => continue, Piece::NextArgument(arg) => arg, }; let span = parser .arg_places .last() .map_or(DUMMY_SP, |&x| str_lit.span.from_inner(InnerSpan::new(x.start, x.end))); if !self.in_debug_impl && arg.format.ty == "?" { // FIXME: modify rustc's fmt string parser to give us the current span span_lint(cx, USE_DEBUG, span, "use of `Debug`-based formatting"); } args.push(arg, span); args.push_complex(cx, arg, str_lit.span, span); } parser.errors.is_empty().then_some(args) } /// Checks the arguments of `print[ln]!` and `write[ln]!` calls. It will return a tuple of two /// `Option`s. The first `Option` of the tuple is the macro's format string. It includes /// the contents of the string, whether it's a raw string, and the span of the literal in the /// source. The second `Option` in the tuple is, in the `write[ln]!` case, the expression the /// `format_str` should be written to. /// /// Example: /// /// Calling this function on /// ```rust /// # use std::fmt::Write; /// # let mut buf = String::new(); /// # let something = "something"; /// writeln!(buf, "string to write: {}", something); /// ``` /// will return /// ```rust,ignore /// (Some("string to write: {}"), Some(buf)) /// ``` fn check_tts<'a>(&self, cx: &EarlyContext<'a>, tts: TokenStream, is_write: bool) -> (Option, Option) { let mut parser = parser::Parser::new(&cx.sess().parse_sess, tts, false, None); let expr = if is_write { match parser .parse_expr() .map(rustc_ast::ptr::P::into_inner) .map_err(DiagnosticBuilder::cancel) { // write!(e, ...) Ok(p) if parser.eat(&token::Comma) => Some(p), // write!(e) or error e => return (None, e.ok()), } } else { None }; let fmtstr = match parser.parse_str_lit() { Ok(fmtstr) => fmtstr, Err(_) => return (None, expr), }; let args = match self.parse_fmt_string(cx, &fmtstr) { Some(args) => args, None => return (Some(fmtstr), expr), }; let lint = if is_write { WRITE_LITERAL } else { PRINT_LITERAL }; let mut unnamed_args = args.get_unnamed(); let mut complex_unnamed_args = args.get_complex_unnamed(); loop { if !parser.eat(&token::Comma) { return (Some(fmtstr), expr); } let comma_span = parser.prev_token.span; let token_expr = if let Ok(expr) = parser.parse_expr().map_err(DiagnosticBuilder::cancel) { expr } else { return (Some(fmtstr), None); }; let complex_unnamed_arg = complex_unnamed_args.next(); let (fmt_spans, lit) = match &token_expr.kind { ExprKind::Lit(lit) => (unnamed_args.next().unwrap_or(&[]), lit), ExprKind::Assign(lhs, rhs, _) => { if let Some(span) = complex_unnamed_arg { for x in span { Self::report_positional_named_param(cx, *x, lhs, rhs); } } match (&lhs.kind, &rhs.kind) { (ExprKind::Path(_, p), ExprKind::Lit(lit)) => (args.get_named(p), lit), _ => continue, } }, _ => { unnamed_args.next(); continue; }, }; let replacement: String = match lit.token_lit.kind { LitKind::StrRaw(_) | LitKind::ByteStrRaw(_) if matches!(fmtstr.style, StrStyle::Raw(_)) => { lit.token_lit.symbol.as_str().replace('{', "{{").replace('}', "}}") }, LitKind::Str | LitKind::ByteStr if matches!(fmtstr.style, StrStyle::Cooked) => { lit.token_lit.symbol.as_str().replace('{', "{{").replace('}', "}}") }, LitKind::StrRaw(_) | LitKind::Str | LitKind::ByteStrRaw(_) | LitKind::ByteStr | LitKind::Integer | LitKind::Float | LitKind::Err => continue, LitKind::Byte | LitKind::Char => match lit.token_lit.symbol.as_str() { "\"" if matches!(fmtstr.style, StrStyle::Cooked) => "\\\"", "\"" if matches!(fmtstr.style, StrStyle::Raw(0)) => continue, "\\\\" if matches!(fmtstr.style, StrStyle::Raw(_)) => "\\", "\\'" => "'", "{" => "{{", "}" => "}}", x if matches!(fmtstr.style, StrStyle::Raw(_)) && x.starts_with('\\') => continue, x => x, } .into(), LitKind::Bool => lit.token_lit.symbol.as_str().deref().into(), }; if !fmt_spans.is_empty() { span_lint_and_then( cx, lint, token_expr.span, "literal with an empty format string", |diag| { diag.multipart_suggestion( "try this", iter::once((comma_span.to(token_expr.span), String::new())) .chain(fmt_spans.iter().copied().zip(iter::repeat(replacement))) .collect(), Applicability::MachineApplicable, ); }, ); } } } fn report_positional_named_param(cx: &EarlyContext<'_>, span: Span, lhs: &P, _rhs: &P) { if let ExprKind::Path(_, _p) = &lhs.kind { let mut applicability = Applicability::MachineApplicable; let name = snippet_with_applicability(cx, lhs.span, "name", &mut applicability); // We need to do this hack as precision spans should be converted from .* to .foo$ let hack = snippet(cx, span, "").contains('*'); span_lint_and_sugg( cx, POSITIONAL_NAMED_FORMAT_PARAMETERS, span, &format!("named parameter {} is used as a positional parameter", name), "replace it with", if hack { format!("{}$", name) } else { format!("{}", name) }, applicability, ); }; } fn lint_println_empty_string(&self, cx: &EarlyContext<'_>, mac: &MacCall) { if let (Some(fmt_str), _) = self.check_tts(cx, mac.args.inner_tokens(), false) { if fmt_str.symbol == kw::Empty { let name = mac.path.segments[0].ident.name; span_lint_and_sugg( cx, PRINTLN_EMPTY_STRING, mac.span(), &format!("using `{}!(\"\")`", name), "replace it with", format!("{}!()", name), Applicability::MachineApplicable, ); } } } fn lint_print_with_newline(&self, cx: &EarlyContext<'_>, mac: &MacCall) { if let (Some(fmt_str), _) = self.check_tts(cx, mac.args.inner_tokens(), false) { if check_newlines(&fmt_str) { let name = mac.path.segments[0].ident.name; let suggested = format!("{}ln", name); span_lint_and_then( cx, PRINT_WITH_NEWLINE, mac.span(), &format!("using `{}!()` with a format string that ends in a single newline", name), |err| { err.multipart_suggestion( &format!("use `{}!` instead", suggested), vec![(mac.path.span, suggested), (newline_span(&fmt_str).0, String::new())], Applicability::MachineApplicable, ); }, ); } } } } /// Checks if the format string contains a single newline that terminates it. /// /// Literal and escaped newlines are both checked (only literal for raw strings). fn check_newlines(fmtstr: &StrLit) -> bool { let mut has_internal_newline = false; let mut last_was_cr = false; let mut should_lint = false; let contents = fmtstr.symbol.as_str(); let mut cb = |r: Range, c: Result| { let c = c.unwrap(); if r.end == contents.len() && c == '\n' && !last_was_cr && !has_internal_newline { should_lint = true; } else { last_was_cr = c == '\r'; if c == '\n' { has_internal_newline = true; } } }; match fmtstr.style { StrStyle::Cooked => unescape::unescape_literal(contents, unescape::Mode::Str, &mut cb), StrStyle::Raw(_) => unescape::unescape_literal(contents, unescape::Mode::RawStr, &mut cb), } should_lint }