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android / toolchain / rustc / cd1aefd586783f162dd848e314bd6991a5ffe033 / . / compiler / rustc_lint / src / context.rs
blob: 1d0c43e95e0859e1d5c2a33cb7137608e5a67094 [file] [log] [blame]
//! Implementation of lint checking.
//!
//! The lint checking is mostly consolidated into one pass which runs
//! after all other analyses. Throughout compilation, lint warnings
//! can be added via the `add_lint` method on the Session structure. This
//! requires a span and an ID of the node that the lint is being added to. The
//! lint isn't actually emitted at that time because it is unknown what the
//! actual lint level at that location is.
//!
//! To actually emit lint warnings/errors, a separate pass is used.
//! A context keeps track of the current state of all lint levels.
//! Upon entering a node of the ast which can modify the lint settings, the
//! previous lint state is pushed onto a stack and the ast is then recursed
//! upon. As the ast is traversed, this keeps track of the current lint level
//! for all lint attributes.
use self::TargetLint::*;
use crate::errors::{
CheckNameDeprecated, CheckNameUnknown, CheckNameUnknownTool, CheckNameWarning, RequestedLevel,
UnsupportedGroup,
};
use crate::levels::LintLevelsBuilder;
use crate::passes::{EarlyLintPassObject, LateLintPassObject};
use rustc_ast::util::unicode::TEXT_FLOW_CONTROL_CHARS;
use rustc_data_structures::fx::FxHashMap;
use rustc_data_structures::sync;
use rustc_errors::{add_elided_lifetime_in_path_suggestion, DiagnosticBuilder, DiagnosticMessage};
use rustc_errors::{Applicability, DecorateLint, MultiSpan, SuggestionStyle};
use rustc_hir as hir;
use rustc_hir::def::Res;
use rustc_hir::def_id::{CrateNum, DefId};
use rustc_hir::definitions::{DefPathData, DisambiguatedDefPathData};
use rustc_middle::middle::privacy::EffectiveVisibilities;
use rustc_middle::middle::stability;
use rustc_middle::ty::layout::{LayoutError, LayoutOfHelpers, TyAndLayout};
use rustc_middle::ty::print::with_no_trimmed_paths;
use rustc_middle::ty::{self, print::Printer, subst::GenericArg, RegisteredTools, Ty, TyCtxt};
use rustc_session::config::ExpectedValues;
use rustc_session::lint::{BuiltinLintDiagnostics, LintExpectationId};
use rustc_session::lint::{FutureIncompatibleInfo, Level, Lint, LintBuffer, LintId};
use rustc_session::Session;
use rustc_span::edit_distance::find_best_match_for_name;
use rustc_span::symbol::{sym, Ident, Symbol};
use rustc_span::{BytePos, Span};
use rustc_target::abi;
use std::cell::Cell;
use std::iter;
use std::slice;
type EarlyLintPassFactory = dyn Fn() -> EarlyLintPassObject + sync::DynSend + sync::DynSync;
type LateLintPassFactory =
dyn for<'tcx> Fn(TyCtxt<'tcx>) -> LateLintPassObject<'tcx> + sync::DynSend + sync::DynSync;
/// Information about the registered lints.
///
/// This is basically the subset of `Context` that we can
/// build early in the compile pipeline.
pub struct LintStore {
/// Registered lints.
lints: Vec<&'static Lint>,
/// Constructor functions for each variety of lint pass.
///
/// These should only be called once, but since we want to avoid locks or
/// interior mutability, we don't enforce this (and lints should, in theory,
/// be compatible with being constructed more than once, though not
/// necessarily in a sane manner. This is safe though.)
pub pre_expansion_passes: Vec<Box<EarlyLintPassFactory>>,
pub early_passes: Vec<Box<EarlyLintPassFactory>>,
pub late_passes: Vec<Box<LateLintPassFactory>>,
/// This is unique in that we construct them per-module, so not once.
pub late_module_passes: Vec<Box<LateLintPassFactory>>,
/// Lints indexed by name.
by_name: FxHashMap<String, TargetLint>,
/// Map of registered lint groups to what lints they expand to.
lint_groups: FxHashMap<&'static str, LintGroup>,
}
/// The target of the `by_name` map, which accounts for renaming/deprecation.
#[derive(Debug)]
enum TargetLint {
/// A direct lint target
Id(LintId),
/// Temporary renaming, used for easing migration pain; see #16545
Renamed(String, LintId),
/// Lint with this name existed previously, but has been removed/deprecated.
/// The string argument is the reason for removal.
Removed(String),
/// A lint name that should give no warnings and have no effect.
///
/// This is used by rustc to avoid warning about old rustdoc lints before rustdoc registers them as tool lints.
Ignored,
}
pub enum FindLintError {
NotFound,
Removed,
}
struct LintAlias {
name: &'static str,
/// Whether deprecation warnings should be suppressed for this alias.
silent: bool,
}
struct LintGroup {
lint_ids: Vec<LintId>,
from_plugin: bool,
depr: Option<LintAlias>,
}
#[derive(Debug)]
pub enum CheckLintNameResult<'a> {
Ok(&'a [LintId]),
/// Lint doesn't exist. Potentially contains a suggestion for a correct lint name.
NoLint(Option<Symbol>),
/// The lint refers to a tool that has not been registered.
NoTool,
/// The lint is either renamed or removed. This is the warning
/// message, and an optional new name (`None` if removed).
Warning(String, Option<String>),
/// The lint is from a tool. If the Option is None, then either
/// the lint does not exist in the tool or the code was not
/// compiled with the tool and therefore the lint was never
/// added to the `LintStore`. Otherwise the `LintId` will be
/// returned as if it where a rustc lint.
Tool(Result<&'a [LintId], (Option<&'a [LintId]>, String)>),
}
impl LintStore {
pub fn new() -> LintStore {
LintStore {
lints: vec![],
pre_expansion_passes: vec![],
early_passes: vec![],
late_passes: vec![],
late_module_passes: vec![],
by_name: Default::default(),
lint_groups: Default::default(),
}
}
pub fn get_lints<'t>(&'t self) -> &'t [&'static Lint] {
&self.lints
}
pub fn get_lint_groups<'t>(
&'t self,
) -> impl Iterator<Item = (&'static str, Vec<LintId>, bool)> + 't {
// This function is not used in a way which observes the order of lints.
#[allow(rustc::potential_query_instability)]
self.lint_groups
.iter()
.filter(|(_, LintGroup { depr, .. })| {
// Don't display deprecated lint groups.
depr.is_none()
})
.map(|(k, LintGroup { lint_ids, from_plugin, .. })| {
(*k, lint_ids.clone(), *from_plugin)
})
}
pub fn register_early_pass(
&mut self,
pass: impl Fn() -> EarlyLintPassObject + 'static + sync::DynSend + sync::DynSync,
) {
self.early_passes.push(Box::new(pass));
}
/// This lint pass is softly deprecated. It misses expanded code and has caused a few
/// errors in the past. Currently, it is only used in Clippy. New implementations
/// should avoid using this interface, as it might be removed in the future.
///
/// * See [rust#69838](https://github.com/rust-lang/rust/pull/69838)
/// * See [rust-clippy#5518](https://github.com/rust-lang/rust-clippy/pull/5518)
pub fn register_pre_expansion_pass(
&mut self,
pass: impl Fn() -> EarlyLintPassObject + 'static + sync::DynSend + sync::DynSync,
) {
self.pre_expansion_passes.push(Box::new(pass));
}
pub fn register_late_pass(
&mut self,
pass: impl for<'tcx> Fn(TyCtxt<'tcx>) -> LateLintPassObject<'tcx>
+ 'static
+ sync::DynSend
+ sync::DynSync,
) {
self.late_passes.push(Box::new(pass));
}
pub fn register_late_mod_pass(
&mut self,
pass: impl for<'tcx> Fn(TyCtxt<'tcx>) -> LateLintPassObject<'tcx>
+ 'static
+ sync::DynSend
+ sync::DynSync,
) {
self.late_module_passes.push(Box::new(pass));
}
/// Helper method for register_early/late_pass
pub fn register_lints(&mut self, lints: &[&'static Lint]) {
for lint in lints {
self.lints.push(lint);
let id = LintId::of(lint);
if self.by_name.insert(lint.name_lower(), Id(id)).is_some() {
bug!("duplicate specification of lint {}", lint.name_lower())
}
if let Some(FutureIncompatibleInfo { reason, .. }) = lint.future_incompatible {
if let Some(edition) = reason.edition() {
self.lint_groups
.entry(edition.lint_name())
.or_insert(LintGroup {
lint_ids: vec![],
from_plugin: lint.is_plugin,
depr: None,
})
.lint_ids
.push(id);
} else {
// Lints belonging to the `future_incompatible` lint group are lints where a
// future version of rustc will cause existing code to stop compiling.
// Lints tied to an edition don't count because they are opt-in.
self.lint_groups
.entry("future_incompatible")
.or_insert(LintGroup {
lint_ids: vec![],
from_plugin: lint.is_plugin,
depr: None,
})
.lint_ids
.push(id);
}
}
}
}
pub fn register_group_alias(&mut self, lint_name: &'static str, alias: &'static str) {
self.lint_groups.insert(
alias,
LintGroup {
lint_ids: vec![],
from_plugin: false,
depr: Some(LintAlias { name: lint_name, silent: true }),
},
);
}
pub fn register_group(
&mut self,
from_plugin: bool,
name: &'static str,
deprecated_name: Option<&'static str>,
to: Vec<LintId>,
) {
let new = self
.lint_groups
.insert(name, LintGroup { lint_ids: to, from_plugin, depr: None })
.is_none();
if let Some(deprecated) = deprecated_name {
self.lint_groups.insert(
deprecated,
LintGroup {
lint_ids: vec![],
from_plugin,
depr: Some(LintAlias { name, silent: false }),
},
);
}
if !new {
bug!("duplicate specification of lint group {}", name);
}
}
/// This lint should give no warning and have no effect.
///
/// This is used by rustc to avoid warning about old rustdoc lints before rustdoc registers them as tool lints.
#[track_caller]
pub fn register_ignored(&mut self, name: &str) {
if self.by_name.insert(name.to_string(), Ignored).is_some() {
bug!("duplicate specification of lint {}", name);
}
}
/// This lint has been renamed; warn about using the new name and apply the lint.
#[track_caller]
pub fn register_renamed(&mut self, old_name: &str, new_name: &str) {
let Some(&Id(target)) = self.by_name.get(new_name) else {
bug!("invalid lint renaming of {} to {}", old_name, new_name);
};
self.by_name.insert(old_name.to_string(), Renamed(new_name.to_string(), target));
}
pub fn register_removed(&mut self, name: &str, reason: &str) {
self.by_name.insert(name.into(), Removed(reason.into()));
}
pub fn find_lints(&self, mut lint_name: &str) -> Result<Vec<LintId>, FindLintError> {
match self.by_name.get(lint_name) {
Some(&Id(lint_id)) => Ok(vec![lint_id]),
Some(&Renamed(_, lint_id)) => Ok(vec![lint_id]),
Some(&Removed(_)) => Err(FindLintError::Removed),
Some(&Ignored) => Ok(vec![]),
None => loop {
return match self.lint_groups.get(lint_name) {
Some(LintGroup { lint_ids, depr, .. }) => {
if let Some(LintAlias { name, .. }) = depr {
lint_name = name;
continue;
}
Ok(lint_ids.clone())
}
None => Err(FindLintError::Removed),
};
},
}
}
/// Checks the validity of lint names derived from the command line.
pub fn check_lint_name_cmdline(
&self,
sess: &Session,
lint_name: &str,
level: Level,
registered_tools: &RegisteredTools,
) {
let (tool_name, lint_name_only) = parse_lint_and_tool_name(lint_name);
if lint_name_only == crate::WARNINGS.name_lower() && matches!(level, Level::ForceWarn(_)) {
sess.emit_err(UnsupportedGroup { lint_group: crate::WARNINGS.name_lower() });
return;
}
let lint_name = lint_name.to_string();
match self.check_lint_name(lint_name_only, tool_name, registered_tools) {
CheckLintNameResult::Warning(msg, _) => {
sess.emit_warning(CheckNameWarning {
msg,
sub: RequestedLevel { level, lint_name },
});
}
CheckLintNameResult::NoLint(suggestion) => {
sess.emit_err(CheckNameUnknown {
lint_name: lint_name.clone(),
suggestion,
sub: RequestedLevel { level, lint_name },
});
}
CheckLintNameResult::Tool(Err((Some(_), new_name))) => {
sess.emit_warning(CheckNameDeprecated {
lint_name: lint_name.clone(),
new_name,
sub: RequestedLevel { level, lint_name },
});
}
CheckLintNameResult::NoTool => {
sess.emit_err(CheckNameUnknownTool {
tool_name: tool_name.unwrap(),
sub: RequestedLevel { level, lint_name },
});
}
_ => {}
};
}
/// True if this symbol represents a lint group name.
pub fn is_lint_group(&self, lint_name: Symbol) -> bool {
debug!(
"is_lint_group(lint_name={:?}, lint_groups={:?})",
lint_name,
self.lint_groups.keys().collect::<Vec<_>>()
);
let lint_name_str = lint_name.as_str();
self.lint_groups.contains_key(lint_name_str) || {
let warnings_name_str = crate::WARNINGS.name_lower();
lint_name_str == warnings_name_str
}
}
/// Checks the name of a lint for its existence, and whether it was
/// renamed or removed. Generates a DiagnosticBuilder containing a
/// warning for renamed and removed lints. This is over both lint
/// names from attributes and those passed on the command line. Since
/// it emits non-fatal warnings and there are *two* lint passes that
/// inspect attributes, this is only run from the late pass to avoid
/// printing duplicate warnings.
pub fn check_lint_name(
&self,
lint_name: &str,
tool_name: Option<Symbol>,
registered_tools: &RegisteredTools,
) -> CheckLintNameResult<'_> {
if let Some(tool_name) = tool_name {
// FIXME: rustc and rustdoc are considered tools for lints, but not for attributes.
if tool_name != sym::rustc
&& tool_name != sym::rustdoc
&& !registered_tools.contains(&Ident::with_dummy_span(tool_name))
{
return CheckLintNameResult::NoTool;
}
}
let complete_name = if let Some(tool_name) = tool_name {
format!("{}::{}", tool_name, lint_name)
} else {
lint_name.to_string()
};
// If the lint was scoped with `tool::` check if the tool lint exists
if let Some(tool_name) = tool_name {
match self.by_name.get(&complete_name) {
None => match self.lint_groups.get(&*complete_name) {
// If the lint isn't registered, there are two possibilities:
None => {
// 1. The tool is currently running, so this lint really doesn't exist.
// FIXME: should this handle tools that never register a lint, like rustfmt?
debug!("lints={:?}", self.by_name.keys().collect::<Vec<_>>());
let tool_prefix = format!("{}::", tool_name);
return if self.by_name.keys().any(|lint| lint.starts_with(&tool_prefix)) {
self.no_lint_suggestion(&complete_name)
} else {
// 2. The tool isn't currently running, so no lints will be registered.
// To avoid giving a false positive, ignore all unknown lints.
CheckLintNameResult::Tool(Err((None, String::new())))
};
}
Some(LintGroup { lint_ids, .. }) => {
return CheckLintNameResult::Tool(Ok(&lint_ids));
}
},
Some(Id(id)) => return CheckLintNameResult::Tool(Ok(slice::from_ref(id))),
// If the lint was registered as removed or renamed by the lint tool, we don't need
// to treat tool_lints and rustc lints different and can use the code below.
_ => {}
}
}
match self.by_name.get(&complete_name) {
Some(Renamed(new_name, _)) => CheckLintNameResult::Warning(
format!("lint `{}` has been renamed to `{}`", complete_name, new_name),
Some(new_name.to_owned()),
),
Some(Removed(reason)) => CheckLintNameResult::Warning(
format!("lint `{}` has been removed: {}", complete_name, reason),
None,
),
None => match self.lint_groups.get(&*complete_name) {
// If neither the lint, nor the lint group exists check if there is a `clippy::`
// variant of this lint
None => self.check_tool_name_for_backwards_compat(&complete_name, "clippy"),
Some(LintGroup { lint_ids, depr, .. }) => {
// Check if the lint group name is deprecated
if let Some(LintAlias { name, silent }) = depr {
let LintGroup { lint_ids, .. } = self.lint_groups.get(name).unwrap();
return if *silent {
CheckLintNameResult::Ok(&lint_ids)
} else {
CheckLintNameResult::Tool(Err((Some(&lint_ids), (*name).to_string())))
};
}
CheckLintNameResult::Ok(&lint_ids)
}
},
Some(Id(id)) => CheckLintNameResult::Ok(slice::from_ref(id)),
Some(&Ignored) => CheckLintNameResult::Ok(&[]),
}
}
fn no_lint_suggestion(&self, lint_name: &str) -> CheckLintNameResult<'_> {
let name_lower = lint_name.to_lowercase();
if lint_name.chars().any(char::is_uppercase) && self.find_lints(&name_lower).is_ok() {
// First check if the lint name is (partly) in upper case instead of lower case...
return CheckLintNameResult::NoLint(Some(Symbol::intern(&name_lower)));
}
// ...if not, search for lints with a similar name
// Note: find_best_match_for_name depends on the sort order of its input vector.
// To ensure deterministic output, sort elements of the lint_groups hash map.
// Also, never suggest deprecated lint groups.
let mut groups: Vec<_> = self
.lint_groups
.iter()
.filter_map(|(k, LintGroup { depr, .. })| depr.is_none().then_some(k))
.collect();
groups.sort();
let groups = groups.iter().map(|k| Symbol::intern(k));
let lints = self.lints.iter().map(|l| Symbol::intern(&l.name_lower()));
let names: Vec<Symbol> = groups.chain(lints).collect();
let suggestion = find_best_match_for_name(&names, Symbol::intern(&name_lower), None);
CheckLintNameResult::NoLint(suggestion)
}
fn check_tool_name_for_backwards_compat(
&self,
lint_name: &str,
tool_name: &str,
) -> CheckLintNameResult<'_> {
let complete_name = format!("{}::{}", tool_name, lint_name);
match self.by_name.get(&complete_name) {
None => match self.lint_groups.get(&*complete_name) {
// Now we are sure, that this lint exists nowhere
None => self.no_lint_suggestion(lint_name),
Some(LintGroup { lint_ids, depr, .. }) => {
// Reaching this would be weird, but let's cover this case anyway
if let Some(LintAlias { name, silent }) = depr {
let LintGroup { lint_ids, .. } = self.lint_groups.get(name).unwrap();
return if *silent {
CheckLintNameResult::Tool(Err((Some(&lint_ids), complete_name)))
} else {
CheckLintNameResult::Tool(Err((Some(&lint_ids), (*name).to_string())))
};
}
CheckLintNameResult::Tool(Err((Some(&lint_ids), complete_name)))
}
},
Some(Id(id)) => {
CheckLintNameResult::Tool(Err((Some(slice::from_ref(id)), complete_name)))
}
Some(other) => {
debug!("got renamed lint {:?}", other);
CheckLintNameResult::NoLint(None)
}
}
}
}
/// Context for lint checking outside of type inference.
pub struct LateContext<'tcx> {
/// Type context we're checking in.
pub tcx: TyCtxt<'tcx>,
/// Current body, or `None` if outside a body.
pub enclosing_body: Option<hir::BodyId>,
/// Type-checking results for the current body. Access using the `typeck_results`
/// and `maybe_typeck_results` methods, which handle querying the typeck results on demand.
// FIXME(eddyb) move all the code accessing internal fields like this,
// to this module, to avoid exposing it to lint logic.
pub(super) cached_typeck_results: Cell<Option<&'tcx ty::TypeckResults<'tcx>>>,
/// Parameter environment for the item we are in.
pub param_env: ty::ParamEnv<'tcx>,
/// Items accessible from the crate being checked.
pub effective_visibilities: &'tcx EffectiveVisibilities,
/// The store of registered lints and the lint levels.
pub lint_store: &'tcx LintStore,
pub last_node_with_lint_attrs: hir::HirId,
/// Generic type parameters in scope for the item we are in.
pub generics: Option<&'tcx hir::Generics<'tcx>>,
/// We are only looking at one module
pub only_module: bool,
}
/// Context for lint checking of the AST, after expansion, before lowering to HIR.
pub struct EarlyContext<'a> {
pub builder: LintLevelsBuilder<'a, crate::levels::TopDown>,
pub buffered: LintBuffer,
}
pub trait LintPassObject: Sized {}
impl LintPassObject for EarlyLintPassObject {}
impl LintPassObject for LateLintPassObject<'_> {}
pub trait LintContext: Sized {
type PassObject: LintPassObject;
fn sess(&self) -> &Session;
fn lints(&self) -> &LintStore;
/// Emit a lint at the appropriate level, with an optional associated span and an existing diagnostic.
///
/// Return value of the `decorate` closure is ignored, see [`struct_lint_level`] for a detailed explanation.
///
/// [`struct_lint_level`]: rustc_middle::lint::struct_lint_level#decorate-signature
#[rustc_lint_diagnostics]
fn lookup_with_diagnostics(
&self,
lint: &'static Lint,
span: Option<impl Into<MultiSpan>>,
msg: impl Into<DiagnosticMessage>,
decorate: impl for<'a, 'b> FnOnce(
&'b mut DiagnosticBuilder<'a, ()>,
) -> &'b mut DiagnosticBuilder<'a, ()>,
diagnostic: BuiltinLintDiagnostics,
) {
// We first generate a blank diagnostic.
self.lookup(lint, span, msg,|db| {
// Now, set up surrounding context.
let sess = self.sess();
match diagnostic {
BuiltinLintDiagnostics::UnicodeTextFlow(span, content) => {
let spans: Vec<_> = content
.char_indices()
.filter_map(|(i, c)| {
TEXT_FLOW_CONTROL_CHARS.contains(&c).then(|| {
let lo = span.lo() + BytePos(2 + i as u32);
(c, span.with_lo(lo).with_hi(lo + BytePos(c.len_utf8() as u32)))
})
})
.collect();
let (an, s) = match spans.len() {
1 => ("an ", ""),
_ => ("", "s"),
};
db.span_label(span, format!(
"this comment contains {}invisible unicode text flow control codepoint{}",
an,
s,
));
for (c, span) in &spans {
db.span_label(*span, format!("{:?}", c));
}
db.note(
"these kind of unicode codepoints change the way text flows on \
applications that support them, but can cause confusion because they \
change the order of characters on the screen",
);
if !spans.is_empty() {
db.multipart_suggestion_with_style(
"if their presence wasn't intentional, you can remove them",
spans.into_iter().map(|(_, span)| (span, "".to_string())).collect(),
Applicability::MachineApplicable,
SuggestionStyle::HideCodeAlways,
);
}
},
BuiltinLintDiagnostics::Normal => (),
BuiltinLintDiagnostics::AbsPathWithModule(span) => {
let (sugg, app) = match sess.source_map().span_to_snippet(span) {
Ok(ref s) => {
// FIXME(Manishearth) ideally the emitting code
// can tell us whether or not this is global
let opt_colon =
if s.trim_start().starts_with("::") { "" } else { "::" };
(format!("crate{}{}", opt_colon, s), Applicability::MachineApplicable)
}
Err(_) => ("crate::<path>".to_string(), Applicability::HasPlaceholders),
};
db.span_suggestion(span, "use `crate`", sugg, app);
}
BuiltinLintDiagnostics::ProcMacroDeriveResolutionFallback(span) => {
db.span_label(
span,
"names from parent modules are not accessible without an explicit import",
);
}
BuiltinLintDiagnostics::MacroExpandedMacroExportsAccessedByAbsolutePaths(
span_def,
) => {
db.span_note(span_def, "the macro is defined here");
}
BuiltinLintDiagnostics::ElidedLifetimesInPaths(
n,
path_span,
incl_angl_brckt,
insertion_span,
) => {
add_elided_lifetime_in_path_suggestion(
sess.source_map(),
db,
n,
path_span,
incl_angl_brckt,
insertion_span,
);
}
BuiltinLintDiagnostics::UnknownCrateTypes(span, note, sugg) => {
db.span_suggestion(span, note, sugg, Applicability::MaybeIncorrect);
}
BuiltinLintDiagnostics::UnusedImports(message, replaces, in_test_module) => {
if !replaces.is_empty() {
db.tool_only_multipart_suggestion(
message,
replaces,
Applicability::MachineApplicable,
);
}
if let Some(span) = in_test_module {
db.span_help(
self.sess().source_map().guess_head_span(span),
"consider adding a `#[cfg(test)]` to the containing module",
);
}
}
BuiltinLintDiagnostics::RedundantImport(spans, ident) => {
for (span, is_imported) in spans {
let introduced = if is_imported { "imported" } else { "defined" };
db.span_label(
span,
format!("the item `{}` is already {} here", ident, introduced),
);
}
}
BuiltinLintDiagnostics::DeprecatedMacro(suggestion, span) => {
stability::deprecation_suggestion(db, "macro", suggestion, span)
}
BuiltinLintDiagnostics::UnusedDocComment(span) => {
db.span_label(span, "rustdoc does not generate documentation for macro invocations");
db.help("to document an item produced by a macro, \
the macro must produce the documentation as part of its expansion");
}
BuiltinLintDiagnostics::PatternsInFnsWithoutBody(span, ident) => {
db.span_suggestion(span, "remove `mut` from the parameter", ident, Applicability::MachineApplicable);
}
BuiltinLintDiagnostics::MissingAbi(span, default_abi) => {
db.span_label(span, "ABI should be specified here");
db.help(format!("the default ABI is {}", default_abi.name()));
}
BuiltinLintDiagnostics::LegacyDeriveHelpers(span) => {
db.span_label(span, "the attribute is introduced here");
}
BuiltinLintDiagnostics::ProcMacroBackCompat(note) => {
db.note(note);
}
BuiltinLintDiagnostics::OrPatternsBackCompat(span,suggestion) => {
db.span_suggestion(span, "use pat_param to preserve semantics", suggestion, Applicability::MachineApplicable);
}
BuiltinLintDiagnostics::ReservedPrefix(span) => {
db.span_label(span, "unknown prefix");
db.span_suggestion_verbose(
span.shrink_to_hi(),
"insert whitespace here to avoid this being parsed as a prefix in Rust 2021",
" ",
Applicability::MachineApplicable,
);
}
BuiltinLintDiagnostics::UnusedBuiltinAttribute {
attr_name,
macro_name,
invoc_span
} => {
db.span_note(
invoc_span,
format!("the built-in attribute `{attr_name}` will be ignored, since it's applied to the macro invocation `{macro_name}`")
);
}
BuiltinLintDiagnostics::TrailingMacro(is_trailing, name) => {
if is_trailing {
db.note("macro invocations at the end of a block are treated as expressions");
db.note(format!("to ignore the value produced by the macro, add a semicolon after the invocation of `{name}`"));
}
}
BuiltinLintDiagnostics::BreakWithLabelAndLoop(span) => {
db.multipart_suggestion(
"wrap this expression in parentheses",
vec![(span.shrink_to_lo(), "(".to_string()),
(span.shrink_to_hi(), ")".to_string())],
Applicability::MachineApplicable
);
}
BuiltinLintDiagnostics::NamedAsmLabel(help) => {
db.help(help);
db.note("see the asm section of Rust By Example <https://doc.rust-lang.org/nightly/rust-by-example/unsafe/asm.html#labels> for more information");
},
BuiltinLintDiagnostics::UnexpectedCfgName((name, name_span), value) => {
let possibilities: Vec<Symbol> = sess.parse_sess.check_config.expecteds.keys().map(|s| *s).collect();
// Suggest the most probable if we found one
if let Some(best_match) = find_best_match_for_name(&possibilities, name, None) {
if let Some(ExpectedValues::Some(best_match_values)) =
sess.parse_sess.check_config.expecteds.get(&best_match) {
let mut possibilities = best_match_values.iter()
.flatten()
.map(Symbol::as_str)
.collect::<Vec<_>>();
possibilities.sort();
if let Some((value, value_span)) = value {
if best_match_values.contains(&Some(value)) {
db.span_suggestion(name_span, "there is a config with a similar name and value", best_match, Applicability::MaybeIncorrect);
} else if best_match_values.contains(&None) {
db.span_suggestion(name_span.to(value_span), "there is a config with a similar name and no value", best_match, Applicability::MaybeIncorrect);
} else if let Some(first_value) = possibilities.first() {
db.span_suggestion(name_span.to(value_span), "there is a config with a similar name and different values", format!("{best_match} = \"{first_value}\""), Applicability::MaybeIncorrect);
} else {
db.span_suggestion(name_span.to(value_span), "there is a config with a similar name and different values", best_match, Applicability::MaybeIncorrect);
};
} else {
db.span_suggestion(name_span, "there is a config with a similar name", best_match, Applicability::MaybeIncorrect);
}
if !possibilities.is_empty() {
let possibilities = possibilities.join("`, `");
db.help(format!("expected values for `{best_match}` are: `{possibilities}`"));
}
} else {
db.span_suggestion(name_span, "there is a config with a similar name", best_match, Applicability::MaybeIncorrect);
}
}
},
BuiltinLintDiagnostics::UnexpectedCfgValue((name, name_span), value) => {
let Some(ExpectedValues::Some(values)) = &sess.parse_sess.check_config.expecteds.get(&name) else {
bug!("it shouldn't be possible to have a diagnostic on a value whose name is not in values");
};
let mut have_none_possibility = false;
let possibilities: Vec<Symbol> = values.iter()
.inspect(|a| have_none_possibility |= a.is_none())
.copied()
.flatten()
.collect();
// Show the full list if all possible values for a given name, but don't do it
// for names as the possibilities could be very long
if !possibilities.is_empty() {
{
let mut possibilities = possibilities.iter().map(Symbol::as_str).collect::<Vec<_>>();
possibilities.sort();
let possibilities = possibilities.join("`, `");
let none = if have_none_possibility { "(none), " } else { "" };
db.note(format!("expected values for `{name}` are: {none}`{possibilities}`"));
}
if let Some((value, value_span)) = value {
// Suggest the most probable if we found one
if let Some(best_match) = find_best_match_for_name(&possibilities, value, None) {
db.span_suggestion(value_span, "there is a expected value with a similar name", format!("\"{best_match}\""), Applicability::MaybeIncorrect);
}
} else if let &[first_possibility] = &possibilities[..] {
db.span_suggestion(name_span.shrink_to_hi(), "specify a config value", format!(" = \"{first_possibility}\""), Applicability::MaybeIncorrect);
}
} else if have_none_possibility {
db.note(format!("no expected value for `{name}`"));
if let Some((_value, value_span)) = value {
db.span_suggestion(name_span.shrink_to_hi().to(value_span), "remove the value", "", Applicability::MaybeIncorrect);
}
}
},
BuiltinLintDiagnostics::DeprecatedWhereclauseLocation(new_span, suggestion) => {
db.multipart_suggestion(
"move it to the end of the type declaration",
vec![(db.span.primary_span().unwrap(), "".to_string()), (new_span, suggestion)],
Applicability::MachineApplicable,
);
db.note(
"see issue #89122 <https://github.com/rust-lang/rust/issues/89122> for more information",
);
},
BuiltinLintDiagnostics::SingleUseLifetime {
param_span,
use_span: Some((use_span, elide)),
deletion_span,
} => {
debug!(?param_span, ?use_span, ?deletion_span);
db.span_label(param_span, "this lifetime...");
db.span_label(use_span, "...is used only here");
if let Some(deletion_span) = deletion_span {
let msg = "elide the single-use lifetime";
let (use_span, replace_lt) = if elide {
let use_span = sess.source_map().span_extend_while(
use_span,
char::is_whitespace,
).unwrap_or(use_span);
(use_span, String::new())
} else {
(use_span, "'_".to_owned())
};
debug!(?deletion_span, ?use_span);
// issue 107998 for the case such as a wrong function pointer type
// `deletion_span` is empty and there is no need to report lifetime uses here
let suggestions = if deletion_span.is_empty() {
vec![(use_span, replace_lt)]
} else {
vec![(deletion_span, String::new()), (use_span, replace_lt)]
};
db.multipart_suggestion(
msg,
suggestions,
Applicability::MachineApplicable,
);
}
},
BuiltinLintDiagnostics::SingleUseLifetime {
param_span: _,
use_span: None,
deletion_span,
} => {
debug!(?deletion_span);
if let Some(deletion_span) = deletion_span {
db.span_suggestion(
deletion_span,
"elide the unused lifetime",
"",
Applicability::MachineApplicable,
);
}
},
BuiltinLintDiagnostics::NamedArgumentUsedPositionally{ position_sp_to_replace, position_sp_for_msg, named_arg_sp, named_arg_name, is_formatting_arg} => {
db.span_label(named_arg_sp, "this named argument is referred to by position in formatting string");
if let Some(positional_arg_for_msg) = position_sp_for_msg {
let msg = format!("this formatting argument uses named argument `{}` by position", named_arg_name);
db.span_label(positional_arg_for_msg, msg);
}
if let Some(positional_arg_to_replace) = position_sp_to_replace {
let name = if is_formatting_arg { named_arg_name + "$" } else { named_arg_name };
let span_to_replace = if let Ok(positional_arg_content) =
self.sess().source_map().span_to_snippet(positional_arg_to_replace) && positional_arg_content.starts_with(':') {
positional_arg_to_replace.shrink_to_lo()
} else {
positional_arg_to_replace
};
db.span_suggestion_verbose(
span_to_replace,
"use the named argument by name to avoid ambiguity",
name,
Applicability::MaybeIncorrect,
);
}
}
BuiltinLintDiagnostics::ByteSliceInPackedStructWithDerive => {
db.help("consider implementing the trait by hand, or remove the `packed` attribute");
}
BuiltinLintDiagnostics::UnusedExternCrate { removal_span }=> {
db.span_suggestion(
removal_span,
"remove it",
"",
Applicability::MachineApplicable,
);
}
BuiltinLintDiagnostics::ExternCrateNotIdiomatic { vis_span, ident_span }=> {
let suggestion_span = vis_span.between(ident_span);
db.span_suggestion_verbose(
suggestion_span,
"convert it to a `use`",
if vis_span.is_empty() { "use " } else { " use " },
Applicability::MachineApplicable,
);
}
BuiltinLintDiagnostics::AmbiguousGlobReexports { name, namespace, first_reexport_span, duplicate_reexport_span } => {
db.span_label(first_reexport_span, format!("the name `{}` in the {} namespace is first re-exported here", name, namespace));
db.span_label(duplicate_reexport_span, format!("but the name `{}` in the {} namespace is also re-exported here", name, namespace));
}
}
// Rewrap `db`, and pass control to the user.
decorate(db)
});
}
// FIXME: These methods should not take an Into<MultiSpan> -- instead, callers should need to
// set the span in their `decorate` function (preferably using set_span).
/// Emit a lint at the appropriate level, with an optional associated span.
///
/// Return value of the `decorate` closure is ignored, see [`struct_lint_level`] for a detailed explanation.
///
/// [`struct_lint_level`]: rustc_middle::lint::struct_lint_level#decorate-signature
#[rustc_lint_diagnostics]
fn lookup<S: Into<MultiSpan>>(
&self,
lint: &'static Lint,
span: Option<S>,
msg: impl Into<DiagnosticMessage>,
decorate: impl for<'a, 'b> FnOnce(
&'b mut DiagnosticBuilder<'a, ()>,
) -> &'b mut DiagnosticBuilder<'a, ()>,
);
/// Emit a lint at `span` from a lint struct (some type that implements `DecorateLint`,
/// typically generated by `#[derive(LintDiagnostic)]`).
fn emit_spanned_lint<S: Into<MultiSpan>>(
&self,
lint: &'static Lint,
span: S,
decorator: impl for<'a> DecorateLint<'a, ()>,
) {
self.lookup(lint, Some(span), decorator.msg(), |diag| decorator.decorate_lint(diag));
}
/// Emit a lint at the appropriate level, with an associated span.
///
/// Return value of the `decorate` closure is ignored, see [`struct_lint_level`] for a detailed explanation.
///
/// [`struct_lint_level`]: rustc_middle::lint::struct_lint_level#decorate-signature
#[rustc_lint_diagnostics]
fn struct_span_lint<S: Into<MultiSpan>>(
&self,
lint: &'static Lint,
span: S,
msg: impl Into<DiagnosticMessage>,
decorate: impl for<'a, 'b> FnOnce(
&'b mut DiagnosticBuilder<'a, ()>,
) -> &'b mut DiagnosticBuilder<'a, ()>,
) {
self.lookup(lint, Some(span), msg, decorate);
}
/// Emit a lint from a lint struct (some type that implements `DecorateLint`, typically
/// generated by `#[derive(LintDiagnostic)]`).
fn emit_lint(&self, lint: &'static Lint, decorator: impl for<'a> DecorateLint<'a, ()>) {
self.lookup(lint, None as Option<Span>, decorator.msg(), |diag| {
decorator.decorate_lint(diag)
});
}
/// Emit a lint at the appropriate level, with no associated span.
///
/// Return value of the `decorate` closure is ignored, see [`struct_lint_level`] for a detailed explanation.
///
/// [`struct_lint_level`]: rustc_middle::lint::struct_lint_level#decorate-signature
#[rustc_lint_diagnostics]
fn lint(
&self,
lint: &'static Lint,
msg: impl Into<DiagnosticMessage>,
decorate: impl for<'a, 'b> FnOnce(
&'b mut DiagnosticBuilder<'a, ()>,
) -> &'b mut DiagnosticBuilder<'a, ()>,
) {
self.lookup(lint, None as Option<Span>, msg, decorate);
}
/// This returns the lint level for the given lint at the current location.
fn get_lint_level(&self, lint: &'static Lint) -> Level;
/// This function can be used to manually fulfill an expectation. This can
/// be used for lints which contain several spans, and should be suppressed,
/// if either location was marked with an expectation.
///
/// Note that this function should only be called for [`LintExpectationId`]s
/// retrieved from the current lint pass. Buffered or manually created ids can
/// cause ICEs.
#[rustc_lint_diagnostics]
fn fulfill_expectation(&self, expectation: LintExpectationId) {
// We need to make sure that submitted expectation ids are correctly fulfilled suppressed
// and stored between compilation sessions. To not manually do these steps, we simply create
// a dummy diagnostic and emit is as usual, which will be suppressed and stored like a normal
// expected lint diagnostic.
self.sess()
.struct_expect(
"this is a dummy diagnostic, to submit and store an expectation",
expectation,
)
.emit();
}
}
impl<'a> EarlyContext<'a> {
pub(crate) fn new(
sess: &'a Session,
warn_about_weird_lints: bool,
lint_store: &'a LintStore,
registered_tools: &'a RegisteredTools,
buffered: LintBuffer,
) -> EarlyContext<'a> {
EarlyContext {
builder: LintLevelsBuilder::new(
sess,
warn_about_weird_lints,
lint_store,
registered_tools,
),
buffered,
}
}
}
impl<'tcx> LintContext for LateContext<'tcx> {
type PassObject = LateLintPassObject<'tcx>;
/// Gets the overall compiler `Session` object.
fn sess(&self) -> &Session {
&self.tcx.sess
}
fn lints(&self) -> &LintStore {
&*self.lint_store
}
#[rustc_lint_diagnostics]
fn lookup<S: Into<MultiSpan>>(
&self,
lint: &'static Lint,
span: Option<S>,
msg: impl Into<DiagnosticMessage>,
decorate: impl for<'a, 'b> FnOnce(
&'b mut DiagnosticBuilder<'a, ()>,
) -> &'b mut DiagnosticBuilder<'a, ()>,
) {
let hir_id = self.last_node_with_lint_attrs;
match span {
Some(s) => self.tcx.struct_span_lint_hir(lint, hir_id, s, msg, decorate),
None => self.tcx.struct_lint_node(lint, hir_id, msg, decorate),
}
}
fn get_lint_level(&self, lint: &'static Lint) -> Level {
self.tcx.lint_level_at_node(lint, self.last_node_with_lint_attrs).0
}
}
impl LintContext for EarlyContext<'_> {
type PassObject = EarlyLintPassObject;
/// Gets the overall compiler `Session` object.
fn sess(&self) -> &Session {
&self.builder.sess()
}
fn lints(&self) -> &LintStore {
self.builder.lint_store()
}
#[rustc_lint_diagnostics]
fn lookup<S: Into<MultiSpan>>(
&self,
lint: &'static Lint,
span: Option<S>,
msg: impl Into<DiagnosticMessage>,
decorate: impl for<'a, 'b> FnOnce(
&'b mut DiagnosticBuilder<'a, ()>,
) -> &'b mut DiagnosticBuilder<'a, ()>,
) {
self.builder.struct_lint(lint, span.map(|s| s.into()), msg, decorate)
}
fn get_lint_level(&self, lint: &'static Lint) -> Level {
self.builder.lint_level(lint).0
}
}
impl<'tcx> LateContext<'tcx> {
/// Gets the type-checking results for the current body,
/// or `None` if outside a body.
pub fn maybe_typeck_results(&self) -> Option<&'tcx ty::TypeckResults<'tcx>> {
self.cached_typeck_results.get().or_else(|| {
self.enclosing_body.map(|body| {
let typeck_results = self.tcx.typeck_body(body);
self.cached_typeck_results.set(Some(typeck_results));
typeck_results
})
})
}
/// Gets the type-checking results for the current body.
/// As this will ICE if called outside bodies, only call when working with
/// `Expr` or `Pat` nodes (they are guaranteed to be found only in bodies).
#[track_caller]
pub fn typeck_results(&self) -> &'tcx ty::TypeckResults<'tcx> {
self.maybe_typeck_results().expect("`LateContext::typeck_results` called outside of body")
}
/// Returns the final resolution of a `QPath`, or `Res::Err` if unavailable.
/// Unlike `.typeck_results().qpath_res(qpath, id)`, this can be used even outside
/// bodies (e.g. for paths in `hir::Ty`), without any risk of ICE-ing.
pub fn qpath_res(&self, qpath: &hir::QPath<'_>, id: hir::HirId) -> Res {
match *qpath {
hir::QPath::Resolved(_, ref path) => path.res,
hir::QPath::TypeRelative(..) | hir::QPath::LangItem(..) => self
.maybe_typeck_results()
.filter(|typeck_results| typeck_results.hir_owner == id.owner)
.or_else(|| {
self.tcx
.has_typeck_results(id.owner.to_def_id())
.then(|| self.tcx.typeck(id.owner.def_id))
})
.and_then(|typeck_results| typeck_results.type_dependent_def(id))
.map_or(Res::Err, |(kind, def_id)| Res::Def(kind, def_id)),
}
}
/// Check if a `DefId`'s path matches the given absolute type path usage.
///
/// Anonymous scopes such as `extern` imports are matched with `kw::Empty`;
/// inherent `impl` blocks are matched with the name of the type.
///
/// Instead of using this method, it is often preferable to instead use
/// `rustc_diagnostic_item` or a `lang_item`. This is less prone to errors
/// as paths get invalidated if the target definition moves.
///
/// # Examples
///
/// ```rust,ignore (no context or def id available)
/// if cx.match_def_path(def_id, &[sym::core, sym::option, sym::Option]) {
/// // The given `def_id` is that of an `Option` type
/// }
/// ```
///
/// Used by clippy, but should be replaced by diagnostic items eventually.
pub fn match_def_path(&self, def_id: DefId, path: &[Symbol]) -> bool {
let names = self.get_def_path(def_id);
names.len() == path.len() && iter::zip(names, path).all(|(a, &b)| a == b)
}
/// Gets the absolute path of `def_id` as a vector of `Symbol`.
///
/// # Examples
///
/// ```rust,ignore (no context or def id available)
/// let def_path = cx.get_def_path(def_id);
/// if let &[sym::core, sym::option, sym::Option] = &def_path[..] {
/// // The given `def_id` is that of an `Option` type
/// }
/// ```
pub fn get_def_path(&self, def_id: DefId) -> Vec<Symbol> {
pub struct AbsolutePathPrinter<'tcx> {
pub tcx: TyCtxt<'tcx>,
}
impl<'tcx> Printer<'tcx> for AbsolutePathPrinter<'tcx> {
type Error = !;
type Path = Vec<Symbol>;
type Region = ();
type Type = ();
type DynExistential = ();
type Const = ();
fn tcx(&self) -> TyCtxt<'tcx> {
self.tcx
}
fn print_region(self, _region: ty::Region<'_>) -> Result<Self::Region, Self::Error> {
Ok(())
}
fn print_type(self, _ty: Ty<'tcx>) -> Result<Self::Type, Self::Error> {
Ok(())
}
fn print_dyn_existential(
self,
_predicates: &'tcx ty::List<ty::PolyExistentialPredicate<'tcx>>,
) -> Result<Self::DynExistential, Self::Error> {
Ok(())
}
fn print_const(self, _ct: ty::Const<'tcx>) -> Result<Self::Const, Self::Error> {
Ok(())
}
fn path_crate(self, cnum: CrateNum) -> Result<Self::Path, Self::Error> {
Ok(vec![self.tcx.crate_name(cnum)])
}
fn path_qualified(
self,
self_ty: Ty<'tcx>,
trait_ref: Option<ty::TraitRef<'tcx>>,
) -> Result<Self::Path, Self::Error> {
if trait_ref.is_none() {
if let ty::Adt(def, substs) = self_ty.kind() {
return self.print_def_path(def.did(), substs);
}
}
// This shouldn't ever be needed, but just in case:
with_no_trimmed_paths!({
Ok(vec![match trait_ref {
Some(trait_ref) => Symbol::intern(&format!("{:?}", trait_ref)),
None => Symbol::intern(&format!("<{}>", self_ty)),
}])
})
}
fn path_append_impl(
self,
print_prefix: impl FnOnce(Self) -> Result<Self::Path, Self::Error>,
_disambiguated_data: &DisambiguatedDefPathData,
self_ty: Ty<'tcx>,
trait_ref: Option<ty::TraitRef<'tcx>>,
) -> Result<Self::Path, Self::Error> {
let mut path = print_prefix(self)?;
// This shouldn't ever be needed, but just in case:
path.push(match trait_ref {
Some(trait_ref) => {
with_no_trimmed_paths!(Symbol::intern(&format!(
"<impl {} for {}>",
trait_ref.print_only_trait_path(),
self_ty
)))
}
None => {
with_no_trimmed_paths!(Symbol::intern(&format!("<impl {}>", self_ty)))
}
});
Ok(path)
}
fn path_append(
self,
print_prefix: impl FnOnce(Self) -> Result<Self::Path, Self::Error>,
disambiguated_data: &DisambiguatedDefPathData,
) -> Result<Self::Path, Self::Error> {
let mut path = print_prefix(self)?;
// Skip `::{{extern}}` blocks and `::{{constructor}}` on tuple/unit structs.
if let DefPathData::ForeignMod | DefPathData::Ctor = disambiguated_data.data {
return Ok(path);
}
path.push(Symbol::intern(&disambiguated_data.data.to_string()));
Ok(path)
}
fn path_generic_args(
self,
print_prefix: impl FnOnce(Self) -> Result<Self::Path, Self::Error>,
_args: &[GenericArg<'tcx>],
) -> Result<Self::Path, Self::Error> {
print_prefix(self)
}
}
AbsolutePathPrinter { tcx: self.tcx }.print_def_path(def_id, &[]).unwrap()
}
/// Returns the associated type `name` for `self_ty` as an implementation of `trait_id`.
/// Do not invoke without first verifying that the type implements the trait.
pub fn get_associated_type(
&self,
self_ty: Ty<'tcx>,
trait_id: DefId,
name: &str,
) -> Option<Ty<'tcx>> {
let tcx = self.tcx;
tcx.associated_items(trait_id)
.find_by_name_and_kind(tcx, Ident::from_str(name), ty::AssocKind::Type, trait_id)
.and_then(|assoc| {
let proj = tcx.mk_projection(assoc.def_id, [self_ty]);
tcx.try_normalize_erasing_regions(self.param_env, proj).ok()
})
}
}
impl<'tcx> abi::HasDataLayout for LateContext<'tcx> {
#[inline]
fn data_layout(&self) -> &abi::TargetDataLayout {
&self.tcx.data_layout
}
}
impl<'tcx> ty::layout::HasTyCtxt<'tcx> for LateContext<'tcx> {
#[inline]
fn tcx(&self) -> TyCtxt<'tcx> {
self.tcx
}
}
impl<'tcx> ty::layout::HasParamEnv<'tcx> for LateContext<'tcx> {
#[inline]
fn param_env(&self) -> ty::ParamEnv<'tcx> {
self.param_env
}
}
impl<'tcx> LayoutOfHelpers<'tcx> for LateContext<'tcx> {
type LayoutOfResult = Result<TyAndLayout<'tcx>, LayoutError<'tcx>>;
#[inline]
fn handle_layout_err(&self, err: LayoutError<'tcx>, _: Span, _: Ty<'tcx>) -> LayoutError<'tcx> {
err
}
}
pub fn parse_lint_and_tool_name(lint_name: &str) -> (Option<Symbol>, &str) {
match lint_name.split_once("::") {
Some((tool_name, lint_name)) => {
let tool_name = Symbol::intern(tool_name);
(Some(tool_name), lint_name)
}
None => (None, lint_name),
}
}