src/librustc_middle/lint.rs - third_party/rust - Git at Google

 use std::cmp;

 use crate::ich::StableHashingContext;
 use rustc_data_structures::fx::FxHashMap;
 use rustc_data_structures::stable_hasher::{HashStable, StableHasher};
 use rustc_errors::{DiagnosticBuilder, DiagnosticId};
 use rustc_hir::HirId;
 use rustc_session::lint::{builtin, Level, Lint, LintId};
 use rustc_session::{DiagnosticMessageId, Session};
 use rustc_span::hygiene::MacroKind;
 use rustc_span::source_map::{DesugaringKind, ExpnKind, MultiSpan};
 use rustc_span::{Span, Symbol};

 /// How a lint level was set.
 #[derive(Clone, Copy, PartialEq, Eq, HashStable)]
 pub enum LintSource {
     /// Lint is at the default level as declared
     /// in rustc or a plugin.
     Default,

     /// Lint level was set by an attribute.
     Node(Symbol, Span, Option<Symbol> /* RFC 2383 reason */),

     /// Lint level was set by a command-line flag.
     CommandLine(Symbol),
 }

 pub type LevelSource = (Level, LintSource);

 pub struct LintLevelSets {
     pub list: Vec<LintSet>,
     pub lint_cap: Level,
 }

 pub enum LintSet {
     CommandLine {
         // -A,-W,-D flags, a `Symbol` for the flag itself and `Level` for which
         // flag.
         specs: FxHashMap<LintId, LevelSource>,
     },

     Node {
         specs: FxHashMap<LintId, LevelSource>,
         parent: u32,
     },
 }

 impl LintLevelSets {
     pub fn new() -> Self {
         LintLevelSets { list: Vec::new(), lint_cap: Level::Forbid }
     }

     pub fn get_lint_level(
         &self,
         lint: &'static Lint,
         idx: u32,
         aux: Option<&FxHashMap<LintId, LevelSource>>,
         sess: &Session,
     ) -> LevelSource {
         let (level, mut src) = self.get_lint_id_level(LintId::of(lint), idx, aux);

         // If `level` is none then we actually assume the default level for this
         // lint.
         let mut level = level.unwrap_or_else(|| lint.default_level(sess.edition()));

         // If we're about to issue a warning, check at the last minute for any
         // directives against the warnings "lint". If, for example, there's an
         // `allow(warnings)` in scope then we want to respect that instead.
         if level == Level::Warn {
             let (warnings_level, warnings_src) =
                 self.get_lint_id_level(LintId::of(builtin::WARNINGS), idx, aux);
             if let Some(configured_warning_level) = warnings_level {
                 if configured_warning_level != Level::Warn {
                     level = configured_warning_level;
                     src = warnings_src;
                 }
             }
         }

         // Ensure that we never exceed the `--cap-lints` argument.
         level = cmp::min(level, self.lint_cap);

         if let Some(driver_level) = sess.driver_lint_caps.get(&LintId::of(lint)) {
             // Ensure that we never exceed driver level.
             level = cmp::min(*driver_level, level);
         }

         (level, src)
     }

     pub fn get_lint_id_level(
         &self,
         id: LintId,
         mut idx: u32,
         aux: Option<&FxHashMap<LintId, LevelSource>>,
     ) -> (Option<Level>, LintSource) {
         if let Some(specs) = aux {
             if let Some(&(level, src)) = specs.get(&id) {
                 return (Some(level), src);
             }
         }
         loop {
             match self.list[idx as usize] {
                 LintSet::CommandLine { ref specs } => {
                     if let Some(&(level, src)) = specs.get(&id) {
                         return (Some(level), src);
                     }
                     return (None, LintSource::Default);
                 }
                 LintSet::Node { ref specs, parent } => {
                     if let Some(&(level, src)) = specs.get(&id) {
                         return (Some(level), src);
                     }
                     idx = parent;
                 }
             }
         }
     }
 }

 pub struct LintLevelMap {
     pub sets: LintLevelSets,
     pub id_to_set: FxHashMap<HirId, u32>,
 }

 impl LintLevelMap {
     /// If the `id` was previously registered with `register_id` when building
     /// this `LintLevelMap` this returns the corresponding lint level and source
     /// of the lint level for the lint provided.
     ///
     /// If the `id` was not previously registered, returns `None`. If `None` is
     /// returned then the parent of `id` should be acquired and this function
     /// should be called again.
     pub fn level_and_source(
         &self,
         lint: &'static Lint,
         id: HirId,
         session: &Session,
     ) -> Option<LevelSource> {
         self.id_to_set.get(&id).map(|idx| self.sets.get_lint_level(lint, *idx, None, session))
     }
 }

 impl<'a> HashStable<StableHashingContext<'a>> for LintLevelMap {
     #[inline]
     fn hash_stable(&self, hcx: &mut StableHashingContext<'a>, hasher: &mut StableHasher) {
         let LintLevelMap { ref sets, ref id_to_set } = *self;

         id_to_set.hash_stable(hcx, hasher);

         let LintLevelSets { ref list, lint_cap } = *sets;

         lint_cap.hash_stable(hcx, hasher);

         hcx.while_hashing_spans(true, |hcx| {
             list.len().hash_stable(hcx, hasher);

             // We are working under the assumption here that the list of
             // lint-sets is built in a deterministic order.
             for lint_set in list {
                 ::std::mem::discriminant(lint_set).hash_stable(hcx, hasher);

                 match *lint_set {
                     LintSet::CommandLine { ref specs } => {
                         specs.hash_stable(hcx, hasher);
                     }
                     LintSet::Node { ref specs, parent } => {
                         specs.hash_stable(hcx, hasher);
                         parent.hash_stable(hcx, hasher);
                     }
                 }
             }
         })
     }
 }

 pub struct LintDiagnosticBuilder<'a>(DiagnosticBuilder<'a>);

 impl<'a> LintDiagnosticBuilder<'a> {
     /// Return the inner DiagnosticBuilder, first setting the primary message to `msg`.
     pub fn build(mut self, msg: &str) -> DiagnosticBuilder<'a> {
         self.0.set_primary_message(msg);
         self.0
     }

     /// Create a LintDiagnosticBuilder from some existing DiagnosticBuilder.
     pub fn new(err: DiagnosticBuilder<'a>) -> LintDiagnosticBuilder<'a> {
         LintDiagnosticBuilder(err)
     }
 }

 pub fn struct_lint_level<'s, 'd>(
     sess: &'s Session,
     lint: &'static Lint,
     level: Level,
     src: LintSource,
     span: Option<MultiSpan>,
     decorate: impl for<'a> FnOnce(LintDiagnosticBuilder<'a>) + 'd,
 ) {
     // Avoid codegen bloat from monomorphization by immediately doing dyn dispatch of `decorate` to
     // the "real" work.
     fn struct_lint_level_impl(
         sess: &'s Session,
         lint: &'static Lint,
         level: Level,
         src: LintSource,
         span: Option<MultiSpan>,
         decorate: Box<dyn for<'b> FnOnce(LintDiagnosticBuilder<'b>) + 'd>,
     ) {
         let mut err = match (level, span) {
             (Level::Allow, _) => {
                 return;
             }
             (Level::Warn, Some(span)) => sess.struct_span_warn(span, ""),
             (Level::Warn, None) => sess.struct_warn(""),
             (Level::Deny | Level::Forbid, Some(span)) => sess.struct_span_err(span, ""),
             (Level::Deny | Level::Forbid, None) => sess.struct_err(""),
         };

         // Check for future incompatibility lints and issue a stronger warning.
         let lint_id = LintId::of(lint);
         let future_incompatible = lint.future_incompatible;

         // If this code originates in a foreign macro, aka something that this crate
         // did not itself author, then it's likely that there's nothing this crate
         // can do about it. We probably want to skip the lint entirely.
         if err.span.primary_spans().iter().any(|s| in_external_macro(sess, *s)) {
             // Any suggestions made here are likely to be incorrect, so anything we
             // emit shouldn't be automatically fixed by rustfix.
             err.allow_suggestions(false);

             // If this is a future incompatible lint it'll become a hard error, so
             // we have to emit *something*. Also, if this lint occurs in the
             // expansion of a macro from an external crate, allow individual lints
             // to opt-out from being reported.
             if future_incompatible.is_none() && !lint.report_in_external_macro {
                 err.cancel();
                 // Don't continue further, since we don't want to have
                 // `diag_span_note_once` called for a diagnostic that isn't emitted.
                 return;
             }
         }

         let name = lint.name_lower();
         match src {
             LintSource::Default => {
                 sess.diag_note_once(
                     &mut err,
                     DiagnosticMessageId::from(lint),
                     &format!("`#[{}({})]` on by default", level.as_str(), name),
                 );
             }
             LintSource::CommandLine(lint_flag_val) => {
                 let flag = match level {
                     Level::Warn => "-W",
                     Level::Deny => "-D",
                     Level::Forbid => "-F",
                     Level::Allow => panic!(),
                 };
                 let hyphen_case_lint_name = name.replace("_", "-");
                 if lint_flag_val.as_str() == name {
                     sess.diag_note_once(
                         &mut err,
                         DiagnosticMessageId::from(lint),
                         &format!(
                             "requested on the command line with `{} {}`",
                             flag, hyphen_case_lint_name
                         ),
                     );
                 } else {
                     let hyphen_case_flag_val = lint_flag_val.as_str().replace("_", "-");
                     sess.diag_note_once(
                         &mut err,
                         DiagnosticMessageId::from(lint),
                         &format!(
                             "`{} {}` implied by `{} {}`",
                             flag, hyphen_case_lint_name, flag, hyphen_case_flag_val
                         ),
                     );
                 }
             }
             LintSource::Node(lint_attr_name, src, reason) => {
                 if let Some(rationale) = reason {
                     err.note(&rationale.as_str());
                 }
                 sess.diag_span_note_once(
                     &mut err,
                     DiagnosticMessageId::from(lint),
                     src,
                     "the lint level is defined here",
                 );
                 if lint_attr_name.as_str() != name {
                     let level_str = level.as_str();
                     sess.diag_note_once(
                         &mut err,
                         DiagnosticMessageId::from(lint),
                         &format!(
                             "`#[{}({})]` implied by `#[{}({})]`",
                             level_str, name, level_str, lint_attr_name
                         ),
                     );
                 }
             }
         }

         err.code(DiagnosticId::Lint(name));

         if let Some(future_incompatible) = future_incompatible {
             const STANDARD_MESSAGE: &str = "this was previously accepted by the compiler but is being phased out; \
                  it will become a hard error";

             let explanation = if lint_id == LintId::of(builtin::UNSTABLE_NAME_COLLISIONS) {
                 "once this method is added to the standard library, \
                  the ambiguity may cause an error or change in behavior!"
                     .to_owned()
             } else if lint_id == LintId::of(builtin::MUTABLE_BORROW_RESERVATION_CONFLICT) {
                 "this borrowing pattern was not meant to be accepted, \
                  and may become a hard error in the future"
                     .to_owned()
             } else if let Some(edition) = future_incompatible.edition {
                 format!("{} in the {} edition!", STANDARD_MESSAGE, edition)
             } else {
                 format!("{} in a future release!", STANDARD_MESSAGE)
             };
             let citation = format!("for more information, see {}", future_incompatible.reference);
             err.warn(&explanation);
             err.note(&citation);
         }

         // Finally, run `decorate`. This function is also responsible for emitting the diagnostic.
         decorate(LintDiagnosticBuilder::new(err));
     }
     struct_lint_level_impl(sess, lint, level, src, span, Box::new(decorate))
 }

 /// Returns whether `span` originates in a foreign crate's external macro.
 ///
 /// This is used to test whether a lint should not even begin to figure out whether it should
 /// be reported on the current node.
 pub fn in_external_macro(sess: &Session, span: Span) -> bool {
     let expn_data = span.ctxt().outer_expn_data();
     match expn_data.kind {
         ExpnKind::Root | ExpnKind::Desugaring(DesugaringKind::ForLoop(_)) => false,
         ExpnKind::AstPass(_) | ExpnKind::Desugaring(_) => true, // well, it's "external"
         ExpnKind::Macro(MacroKind::Bang, _) => {
             // Dummy span for the `def_site` means it's an external macro.
             expn_data.def_site.is_dummy() || sess.source_map().is_imported(expn_data.def_site)
         }
         ExpnKind::Macro(..) => true, // definitely a plugin
     }
 }
	use std::cmp;

	use crate::ich::StableHashingContext;
	use rustc_data_structures::fx::FxHashMap;
	use rustc_data_structures::stable_hasher::{HashStable, StableHasher};
	use rustc_errors::{DiagnosticBuilder, DiagnosticId};
	use rustc_hir::HirId;
	use rustc_session::lint::{builtin, Level, Lint, LintId};
	use rustc_session::{DiagnosticMessageId, Session};
	use rustc_span::hygiene::MacroKind;
	use rustc_span::source_map::{DesugaringKind, ExpnKind, MultiSpan};
	use rustc_span::{Span, Symbol};

	/// How a lint level was set.
	#[derive(Clone, Copy, PartialEq, Eq, HashStable)]
	pub enum LintSource {
	/// Lint is at the default level as declared
	/// in rustc or a plugin.
	Default,

	/// Lint level was set by an attribute.
	Node(Symbol, Span, Option<Symbol> /* RFC 2383 reason */),

	/// Lint level was set by a command-line flag.
	CommandLine(Symbol),
	}

	pub type LevelSource = (Level, LintSource);

	pub struct LintLevelSets {
	pub list: Vec<LintSet>,
	pub lint_cap: Level,
	}

	pub enum LintSet {
	CommandLine {
	// -A,-W,-D flags, a `Symbol` for the flag itself and `Level` for which
	// flag.
	specs: FxHashMap<LintId, LevelSource>,
	},

	Node {
	specs: FxHashMap<LintId, LevelSource>,
	parent: u32,
	},
	}

	impl LintLevelSets {
	pub fn new() -> Self {
	LintLevelSets { list: Vec::new(), lint_cap: Level::Forbid }
	}

	pub fn get_lint_level(
	&self,
	lint: &'static Lint,
	idx: u32,
	aux: Option<&FxHashMap<LintId, LevelSource>>,
	sess: &Session,
	) -> LevelSource {
	let (level, mut src) = self.get_lint_id_level(LintId::of(lint), idx, aux);

	// If `level` is none then we actually assume the default level for this
	// lint.
	let mut level = level.unwrap_or_else(\|\| lint.default_level(sess.edition()));

	// If we're about to issue a warning, check at the last minute for any
	// directives against the warnings "lint". If, for example, there's an
	// `allow(warnings)` in scope then we want to respect that instead.
	if level == Level::Warn {
	let (warnings_level, warnings_src) =
	self.get_lint_id_level(LintId::of(builtin::WARNINGS), idx, aux);
	if let Some(configured_warning_level) = warnings_level {
	if configured_warning_level != Level::Warn {
	level = configured_warning_level;
	src = warnings_src;
	}
	}
	}

	// Ensure that we never exceed the `--cap-lints` argument.
	level = cmp::min(level, self.lint_cap);

	if let Some(driver_level) = sess.driver_lint_caps.get(&LintId::of(lint)) {
	// Ensure that we never exceed driver level.
	level = cmp::min(*driver_level, level);
	}

	(level, src)
	}

	pub fn get_lint_id_level(
	&self,
	id: LintId,
	mut idx: u32,
	aux: Option<&FxHashMap<LintId, LevelSource>>,
	) -> (Option<Level>, LintSource) {
	if let Some(specs) = aux {
	if let Some(&(level, src)) = specs.get(&id) {
	return (Some(level), src);
	}
	}
	loop {
	match self.list[idx as usize] {
	LintSet::CommandLine { ref specs } => {
	if let Some(&(level, src)) = specs.get(&id) {
	return (Some(level), src);
	}
	return (None, LintSource::Default);
	}
	LintSet::Node { ref specs, parent } => {
	if let Some(&(level, src)) = specs.get(&id) {
	return (Some(level), src);
	}
	idx = parent;
	}
	}
	}
	}
	}

	pub struct LintLevelMap {
	pub sets: LintLevelSets,
	pub id_to_set: FxHashMap<HirId, u32>,
	}

	impl LintLevelMap {
	/// If the `id` was previously registered with `register_id` when building
	/// this `LintLevelMap` this returns the corresponding lint level and source
	/// of the lint level for the lint provided.
	///
	/// If the `id` was not previously registered, returns `None`. If `None` is
	/// returned then the parent of `id` should be acquired and this function
	/// should be called again.
	pub fn level_and_source(
	&self,
	lint: &'static Lint,
	id: HirId,
	session: &Session,
	) -> Option<LevelSource> {
	self.id_to_set.get(&id).map(\|idx\| self.sets.get_lint_level(lint, *idx, None, session))
	}
	}

	impl<'a> HashStable<StableHashingContext<'a>> for LintLevelMap {
	#[inline]
	fn hash_stable(&self, hcx: &mut StableHashingContext<'a>, hasher: &mut StableHasher) {
	let LintLevelMap { ref sets, ref id_to_set } = *self;

	id_to_set.hash_stable(hcx, hasher);

	let LintLevelSets { ref list, lint_cap } = *sets;

	lint_cap.hash_stable(hcx, hasher);

	hcx.while_hashing_spans(true, \|hcx\| {
	list.len().hash_stable(hcx, hasher);

	// We are working under the assumption here that the list of
	// lint-sets is built in a deterministic order.
	for lint_set in list {
	::std::mem::discriminant(lint_set).hash_stable(hcx, hasher);

	match *lint_set {
	LintSet::CommandLine { ref specs } => {
	specs.hash_stable(hcx, hasher);
	}
	LintSet::Node { ref specs, parent } => {
	specs.hash_stable(hcx, hasher);
	parent.hash_stable(hcx, hasher);
	}
	}
	}
	})
	}
	}

	pub struct LintDiagnosticBuilder<'a>(DiagnosticBuilder<'a>);

	impl<'a> LintDiagnosticBuilder<'a> {
	/// Return the inner DiagnosticBuilder, first setting the primary message to `msg`.
	pub fn build(mut self, msg: &str) -> DiagnosticBuilder<'a> {
	self.0.set_primary_message(msg);
	self.0
	}

	/// Create a LintDiagnosticBuilder from some existing DiagnosticBuilder.
	pub fn new(err: DiagnosticBuilder<'a>) -> LintDiagnosticBuilder<'a> {
	LintDiagnosticBuilder(err)
	}
	}

	pub fn struct_lint_level<'s, 'd>(
	sess: &'s Session,
	lint: &'static Lint,
	level: Level,
	src: LintSource,
	span: Option<MultiSpan>,
	decorate: impl for<'a> FnOnce(LintDiagnosticBuilder<'a>) + 'd,
	) {
	// Avoid codegen bloat from monomorphization by immediately doing dyn dispatch of `decorate` to
	// the "real" work.
	fn struct_lint_level_impl(
	sess: &'s Session,
	lint: &'static Lint,
	level: Level,
	src: LintSource,
	span: Option<MultiSpan>,
	decorate: Box<dyn for<'b> FnOnce(LintDiagnosticBuilder<'b>) + 'd>,
	) {
	let mut err = match (level, span) {
	(Level::Allow, _) => {
	return;
	}
	(Level::Warn, Some(span)) => sess.struct_span_warn(span, ""),
	(Level::Warn, None) => sess.struct_warn(""),
	(Level::Deny \| Level::Forbid, Some(span)) => sess.struct_span_err(span, ""),
	(Level::Deny \| Level::Forbid, None) => sess.struct_err(""),
	};

	// Check for future incompatibility lints and issue a stronger warning.
	let lint_id = LintId::of(lint);
	let future_incompatible = lint.future_incompatible;

	// If this code originates in a foreign macro, aka something that this crate
	// did not itself author, then it's likely that there's nothing this crate
	// can do about it. We probably want to skip the lint entirely.
	if err.span.primary_spans().iter().any(\|s\| in_external_macro(sess, *s)) {
	// Any suggestions made here are likely to be incorrect, so anything we
	// emit shouldn't be automatically fixed by rustfix.
	err.allow_suggestions(false);

	// If this is a future incompatible lint it'll become a hard error, so
	// we have to emit something. Also, if this lint occurs in the
	// expansion of a macro from an external crate, allow individual lints
	// to opt-out from being reported.
	if future_incompatible.is_none() && !lint.report_in_external_macro {
	err.cancel();
	// Don't continue further, since we don't want to have
	// `diag_span_note_once` called for a diagnostic that isn't emitted.
	return;
	}
	}

	let name = lint.name_lower();
	match src {
	LintSource::Default => {
	sess.diag_note_once(
	&mut err,
	DiagnosticMessageId::from(lint),
	&format!("`#[{}({})]` on by default", level.as_str(), name),
	);
	}
	LintSource::CommandLine(lint_flag_val) => {
	let flag = match level {
	Level::Warn => "-W",
	Level::Deny => "-D",
	Level::Forbid => "-F",
	Level::Allow => panic!(),
	};
	let hyphen_case_lint_name = name.replace("_", "-");
	if lint_flag_val.as_str() == name {
	sess.diag_note_once(
	&mut err,
	DiagnosticMessageId::from(lint),
	&format!(
	"requested on the command line with `{} {}`",
	flag, hyphen_case_lint_name
	),
	);
	} else {
	let hyphen_case_flag_val = lint_flag_val.as_str().replace("_", "-");
	sess.diag_note_once(
	&mut err,
	DiagnosticMessageId::from(lint),
	&format!(
	"`{} {}` implied by `{} {}`",
	flag, hyphen_case_lint_name, flag, hyphen_case_flag_val
	),
	);
	}
	}
	LintSource::Node(lint_attr_name, src, reason) => {
	if let Some(rationale) = reason {
	err.note(&rationale.as_str());
	}
	sess.diag_span_note_once(
	&mut err,
	DiagnosticMessageId::from(lint),
	src,
	"the lint level is defined here",
	);
	if lint_attr_name.as_str() != name {
	let level_str = level.as_str();
	sess.diag_note_once(
	&mut err,
	DiagnosticMessageId::from(lint),
	&format!(
	"`#[{}({})]` implied by `#[{}({})]`",
	level_str, name, level_str, lint_attr_name
	),
	);
	}
	}
	}

	err.code(DiagnosticId::Lint(name));

	if let Some(future_incompatible) = future_incompatible {
	const STANDARD_MESSAGE: &str = "this was previously accepted by the compiler but is being phased out; \
	it will become a hard error";

	let explanation = if lint_id == LintId::of(builtin::UNSTABLE_NAME_COLLISIONS) {
	"once this method is added to the standard library, \
	the ambiguity may cause an error or change in behavior!"
	.to_owned()
	} else if lint_id == LintId::of(builtin::MUTABLE_BORROW_RESERVATION_CONFLICT) {
	"this borrowing pattern was not meant to be accepted, \
	and may become a hard error in the future"
	.to_owned()
	} else if let Some(edition) = future_incompatible.edition {
	format!("{} in the {} edition!", STANDARD_MESSAGE, edition)
	} else {
	format!("{} in a future release!", STANDARD_MESSAGE)
	};
	let citation = format!("for more information, see {}", future_incompatible.reference);
	err.warn(&explanation);
	err.note(&citation);
	}

	// Finally, run `decorate`. This function is also responsible for emitting the diagnostic.
	decorate(LintDiagnosticBuilder::new(err));
	}
	struct_lint_level_impl(sess, lint, level, src, span, Box::new(decorate))
	}

	/// Returns whether `span` originates in a foreign crate's external macro.
	///
	/// This is used to test whether a lint should not even begin to figure out whether it should
	/// be reported on the current node.
	pub fn in_external_macro(sess: &Session, span: Span) -> bool {
	let expn_data = span.ctxt().outer_expn_data();
	match expn_data.kind {
	ExpnKind::Root \| ExpnKind::Desugaring(DesugaringKind::ForLoop(_)) => false,
	ExpnKind::AstPass(_) \| ExpnKind::Desugaring(_) => true, // well, it's "external"
	ExpnKind::Macro(MacroKind::Bang, _) => {
	// Dummy span for the `def_site` means it's an external macro.
	expn_data.def_site.is_dummy() \|\| sess.source_map().is_imported(expn_data.def_site)
	}
	ExpnKind::Macro(..) => true, // definitely a plugin
	}
	}