src/librustc_resolve/check_unused.rs - third_party/rust - Git at Google

 //
 // Unused import checking
 //
 // Although this is mostly a lint pass, it lives in here because it depends on
 // resolve data structures and because it finalises the privacy information for
 // `use` directives.
 //
 // Unused trait imports can't be checked until the method resolution. We save
 // candidates here, and do the actual check in librustc_typeck/check_unused.rs.
 //
 // Checking for unused imports is split into three steps:
 //
 //  - `UnusedImportCheckVisitor` walks the AST to find all the unused imports
 //    inside of `UseTree`s, recording their `NodeId`s and grouping them by
 //    the parent `use` item
 //
 //  - `calc_unused_spans` then walks over all the `use` items marked in the
 //    previous step to collect the spans associated with the `NodeId`s and to
 //    calculate the spans that can be removed by rustfix; This is done in a
 //    separate step to be able to collapse the adjacent spans that rustfix
 //    will remove
 //
 //  - `check_crate` finally emits the diagnostics based on the data generated
 //    in the last step

 use crate::Resolver;
 use crate::resolve_imports::ImportDirectiveSubclass;

 use rustc::util::nodemap::NodeMap;
 use rustc::{lint, ty};
 use rustc_data_structures::fx::FxHashSet;
 use syntax::ast;
 use syntax::visit::{self, Visitor};
 use syntax_pos::{Span, MultiSpan, DUMMY_SP};

 struct UnusedImport<'a> {
     use_tree: &'a ast::UseTree,
     use_tree_id: ast::NodeId,
     item_span: Span,
     unused: FxHashSet<ast::NodeId>,
 }

 impl<'a> UnusedImport<'a> {
     fn add(&mut self, id: ast::NodeId) {
         self.unused.insert(id);
     }
 }

 struct UnusedImportCheckVisitor<'a, 'b> {
     r: &'a mut Resolver<'b>,
     /// All the (so far) unused imports, grouped path list
     unused_imports: NodeMap<UnusedImport<'a>>,
     base_use_tree: Option<&'a ast::UseTree>,
     base_id: ast::NodeId,
     item_span: Span,
 }

 impl<'a, 'b> UnusedImportCheckVisitor<'a, 'b> {
     // We have information about whether `use` (import) directives are actually
     // used now. If an import is not used at all, we signal a lint error.
     fn check_import(&mut self, id: ast::NodeId) {
         let mut used = false;
         self.r.per_ns(|this, ns| used |= this.used_imports.contains(&(id, ns)));
         if !used {
             if self.r.maybe_unused_trait_imports.contains(&id) {
                 // Check later.
                 return;
             }
             self.unused_import(self.base_id).add(id);
         } else {
             // This trait import is definitely used, in a way other than
             // method resolution.
             self.r.maybe_unused_trait_imports.remove(&id);
             if let Some(i) = self.unused_imports.get_mut(&self.base_id) {
                 i.unused.remove(&id);
             }
         }
     }

     fn unused_import(&mut self, id: ast::NodeId) -> &mut UnusedImport<'a> {
         let use_tree_id = self.base_id;
         let use_tree = self.base_use_tree.unwrap();
         let item_span = self.item_span;

         self.unused_imports
             .entry(id)
             .or_insert_with(|| UnusedImport {
                 use_tree,
                 use_tree_id,
                 item_span,
                 unused: FxHashSet::default(),
             })
     }
 }

 impl<'a, 'b> Visitor<'a> for UnusedImportCheckVisitor<'a, 'b> {
     fn visit_item(&mut self, item: &'a ast::Item) {
         self.item_span = item.span;

         // Ignore is_public import statements because there's no way to be sure
         // whether they're used or not. Also ignore imports with a dummy span
         // because this means that they were generated in some fashion by the
         // compiler and we don't need to consider them.
         if let ast::ItemKind::Use(..) = item.node {
             if item.vis.node.is_pub() || item.span.is_dummy() {
                 return;
             }
         }

         visit::walk_item(self, item);
     }

     fn visit_use_tree(&mut self, use_tree: &'a ast::UseTree, id: ast::NodeId, nested: bool) {
         // Use the base UseTree's NodeId as the item id
         // This allows the grouping of all the lints in the same item
         if !nested {
             self.base_id = id;
             self.base_use_tree = Some(use_tree);
         }

         if let ast::UseTreeKind::Nested(ref items) = use_tree.kind {
             if items.is_empty() {
                 self.unused_import(self.base_id).add(id);
             }
         } else {
             self.check_import(id);
         }

         visit::walk_use_tree(self, use_tree, id);
     }
 }

 enum UnusedSpanResult {
     Used,
     FlatUnused(Span, Span),
     NestedFullUnused(Vec<Span>, Span),
     NestedPartialUnused(Vec<Span>, Vec<Span>),
 }

 fn calc_unused_spans(
     unused_import: &UnusedImport<'_>,
     use_tree: &ast::UseTree,
     use_tree_id: ast::NodeId,
 ) -> UnusedSpanResult {
     // The full span is the whole item's span if this current tree is not nested inside another
     // This tells rustfix to remove the whole item if all the imports are unused
     let full_span = if unused_import.use_tree.span == use_tree.span {
         unused_import.item_span
     } else {
         use_tree.span
     };
     match use_tree.kind {
         ast::UseTreeKind::Simple(..) | ast::UseTreeKind::Glob => {
             if unused_import.unused.contains(&use_tree_id) {
                 UnusedSpanResult::FlatUnused(use_tree.span, full_span)
             } else {
                 UnusedSpanResult::Used
             }
         }
         ast::UseTreeKind::Nested(ref nested) => {
             if nested.len() == 0 {
                 return UnusedSpanResult::FlatUnused(use_tree.span, full_span);
             }

             let mut unused_spans = Vec::new();
             let mut to_remove = Vec::new();
             let mut all_nested_unused = true;
             let mut previous_unused = false;
             for (pos, (use_tree, use_tree_id)) in nested.iter().enumerate() {
                 let remove = match calc_unused_spans(unused_import, use_tree, *use_tree_id) {
                     UnusedSpanResult::Used => {
                         all_nested_unused = false;
                         None
                     }
                     UnusedSpanResult::FlatUnused(span, remove) => {
                         unused_spans.push(span);
                         Some(remove)
                     }
                     UnusedSpanResult::NestedFullUnused(mut spans, remove) => {
                         unused_spans.append(&mut spans);
                         Some(remove)
                     }
                     UnusedSpanResult::NestedPartialUnused(mut spans, mut to_remove_extra) => {
                         all_nested_unused = false;
                         unused_spans.append(&mut spans);
                         to_remove.append(&mut to_remove_extra);
                         None
                     }
                 };
                 if let Some(remove) = remove {
                     let remove_span = if nested.len() == 1 {
                         remove
                     } else if pos == nested.len() - 1 || !all_nested_unused {
                         // Delete everything from the end of the last import, to delete the
                         // previous comma
                         nested[pos - 1].0.span.shrink_to_hi().to(use_tree.span)
                     } else {
                         // Delete everything until the next import, to delete the trailing commas
                         use_tree.span.to(nested[pos + 1].0.span.shrink_to_lo())
                     };

                     // Try to collapse adjacent spans into a single one. This prevents all cases of
                     // overlapping removals, which are not supported by rustfix
                     if previous_unused && !to_remove.is_empty() {
                         let previous = to_remove.pop().unwrap();
                         to_remove.push(previous.to(remove_span));
                     } else {
                         to_remove.push(remove_span);
                     }
                 }
                 previous_unused = remove.is_some();
             }
             if unused_spans.is_empty() {
                 UnusedSpanResult::Used
             } else if all_nested_unused {
                 UnusedSpanResult::NestedFullUnused(unused_spans, full_span)
             } else {
                 UnusedSpanResult::NestedPartialUnused(unused_spans, to_remove)
             }
         }
     }
 }

 impl Resolver<'_> {
     crate fn check_unused(&mut self, krate: &ast::Crate) {
         for directive in self.potentially_unused_imports.iter() {
             match directive.subclass {
                 _ if directive.used.get() ||
                     directive.vis.get() == ty::Visibility::Public ||
                     directive.span.is_dummy() => {
                     if let ImportDirectiveSubclass::MacroUse = directive.subclass {
                         if !directive.span.is_dummy() {
                             self.session.buffer_lint(
                                 lint::builtin::MACRO_USE_EXTERN_CRATE,
                                 directive.id,
                                 directive.span,
                                 "deprecated `#[macro_use]` directive used to \
                                 import macros should be replaced at use sites \
                                 with a `use` statement to import the macro \
                                 instead",
                             );
                         }
                     }
                 }
                 ImportDirectiveSubclass::ExternCrate { .. } => {
                     self.maybe_unused_extern_crates.push((directive.id, directive.span));
                 }
                 ImportDirectiveSubclass::MacroUse => {
                     let lint = lint::builtin::UNUSED_IMPORTS;
                     let msg = "unused `#[macro_use]` import";
                     self.session.buffer_lint(lint, directive.id, directive.span, msg);
                 }
                 _ => {}
             }
         }

         let mut visitor = UnusedImportCheckVisitor {
             r: self,
             unused_imports: Default::default(),
             base_use_tree: None,
             base_id: ast::DUMMY_NODE_ID,
             item_span: DUMMY_SP,
         };
         visit::walk_crate(&mut visitor, krate);

         for unused in visitor.unused_imports.values() {
             let mut fixes = Vec::new();
             let mut spans = match calc_unused_spans(unused, unused.use_tree, unused.use_tree_id) {
                 UnusedSpanResult::Used => continue,
                 UnusedSpanResult::FlatUnused(span, remove) => {
                     fixes.push((remove, String::new()));
                     vec![span]
                 }
                 UnusedSpanResult::NestedFullUnused(spans, remove) => {
                     fixes.push((remove, String::new()));
                     spans
                 }
                 UnusedSpanResult::NestedPartialUnused(spans, remove) => {
                     for fix in &remove {
                         fixes.push((*fix, String::new()));
                     }
                     spans
                 }
             };

             let len = spans.len();
             spans.sort();
             let ms = MultiSpan::from_spans(spans.clone());
             let mut span_snippets = spans.iter()
                 .filter_map(|s| {
                     match visitor.r.session.source_map().span_to_snippet(*s) {
                         Ok(s) => Some(format!("`{}`", s)),
                         _ => None,
                     }
                 }).collect::<Vec<String>>();
             span_snippets.sort();
             let msg = format!("unused import{}{}",
                             if len > 1 { "s" } else { "" },
                             if !span_snippets.is_empty() {
                                 format!(": {}", span_snippets.join(", "))
                             } else {
                                 String::new()
                             });

             let fix_msg = if fixes.len() == 1 && fixes[0].0 == unused.item_span {
                 "remove the whole `use` item"
             } else if spans.len() > 1 {
                 "remove the unused imports"
             } else {
                 "remove the unused import"
             };

             visitor.r.session.buffer_lint_with_diagnostic(
                 lint::builtin::UNUSED_IMPORTS,
                 unused.use_tree_id,
                 ms,
                 &msg,
                 lint::builtin::BuiltinLintDiagnostics::UnusedImports(fix_msg.into(), fixes),
             );
         }
     }
 }
	//
	// Unused import checking
	//
	// Although this is mostly a lint pass, it lives in here because it depends on
	// resolve data structures and because it finalises the privacy information for
	// `use` directives.
	//
	// Unused trait imports can't be checked until the method resolution. We save
	// candidates here, and do the actual check in librustc_typeck/check_unused.rs.
	//
	// Checking for unused imports is split into three steps:
	//
	// - `UnusedImportCheckVisitor` walks the AST to find all the unused imports
	// inside of `UseTree`s, recording their `NodeId`s and grouping them by
	// the parent `use` item
	//
	// - `calc_unused_spans` then walks over all the `use` items marked in the
	// previous step to collect the spans associated with the `NodeId`s and to
	// calculate the spans that can be removed by rustfix; This is done in a
	// separate step to be able to collapse the adjacent spans that rustfix
	// will remove
	//
	// - `check_crate` finally emits the diagnostics based on the data generated
	// in the last step

	use crate::Resolver;
	use crate::resolve_imports::ImportDirectiveSubclass;

	use rustc::util::nodemap::NodeMap;
	use rustc::{lint, ty};
	use rustc_data_structures::fx::FxHashSet;
	use syntax::ast;
	use syntax::visit::{self, Visitor};
	use syntax_pos::{Span, MultiSpan, DUMMY_SP};

	struct UnusedImport<'a> {
	use_tree: &'a ast::UseTree,
	use_tree_id: ast::NodeId,
	item_span: Span,
	unused: FxHashSet<ast::NodeId>,
	}

	impl<'a> UnusedImport<'a> {
	fn add(&mut self, id: ast::NodeId) {
	self.unused.insert(id);
	}
	}

	struct UnusedImportCheckVisitor<'a, 'b> {
	r: &'a mut Resolver<'b>,
	/// All the (so far) unused imports, grouped path list
	unused_imports: NodeMap<UnusedImport<'a>>,
	base_use_tree: Option<&'a ast::UseTree>,
	base_id: ast::NodeId,
	item_span: Span,
	}

	impl<'a, 'b> UnusedImportCheckVisitor<'a, 'b> {
	// We have information about whether `use` (import) directives are actually
	// used now. If an import is not used at all, we signal a lint error.
	fn check_import(&mut self, id: ast::NodeId) {
	let mut used = false;
	self.r.per_ns(\|this, ns\| used \|= this.used_imports.contains(&(id, ns)));
	if !used {
	if self.r.maybe_unused_trait_imports.contains(&id) {
	// Check later.
	return;
	}
	self.unused_import(self.base_id).add(id);
	} else {
	// This trait import is definitely used, in a way other than
	// method resolution.
	self.r.maybe_unused_trait_imports.remove(&id);
	if let Some(i) = self.unused_imports.get_mut(&self.base_id) {
	i.unused.remove(&id);
	}
	}
	}

	fn unused_import(&mut self, id: ast::NodeId) -> &mut UnusedImport<'a> {
	let use_tree_id = self.base_id;
	let use_tree = self.base_use_tree.unwrap();
	let item_span = self.item_span;

	self.unused_imports
	.entry(id)
	.or_insert_with(\|\| UnusedImport {
	use_tree,
	use_tree_id,
	item_span,
	unused: FxHashSet::default(),
	})
	}
	}

	impl<'a, 'b> Visitor<'a> for UnusedImportCheckVisitor<'a, 'b> {
	fn visit_item(&mut self, item: &'a ast::Item) {
	self.item_span = item.span;

	// Ignore is_public import statements because there's no way to be sure
	// whether they're used or not. Also ignore imports with a dummy span
	// because this means that they were generated in some fashion by the
	// compiler and we don't need to consider them.
	if let ast::ItemKind::Use(..) = item.node {
	if item.vis.node.is_pub() \|\| item.span.is_dummy() {
	return;
	}
	}

	visit::walk_item(self, item);
	}

	fn visit_use_tree(&mut self, use_tree: &'a ast::UseTree, id: ast::NodeId, nested: bool) {
	// Use the base UseTree's NodeId as the item id
	// This allows the grouping of all the lints in the same item
	if !nested {
	self.base_id = id;
	self.base_use_tree = Some(use_tree);
	}

	if let ast::UseTreeKind::Nested(ref items) = use_tree.kind {
	if items.is_empty() {
	self.unused_import(self.base_id).add(id);
	}
	} else {
	self.check_import(id);
	}

	visit::walk_use_tree(self, use_tree, id);
	}
	}

	enum UnusedSpanResult {
	Used,
	FlatUnused(Span, Span),
	NestedFullUnused(Vec<Span>, Span),
	NestedPartialUnused(Vec<Span>, Vec<Span>),
	}

	fn calc_unused_spans(
	unused_import: &UnusedImport<'_>,
	use_tree: &ast::UseTree,
	use_tree_id: ast::NodeId,
	) -> UnusedSpanResult {
	// The full span is the whole item's span if this current tree is not nested inside another
	// This tells rustfix to remove the whole item if all the imports are unused
	let full_span = if unused_import.use_tree.span == use_tree.span {
	unused_import.item_span
	} else {
	use_tree.span
	};
	match use_tree.kind {
	ast::UseTreeKind::Simple(..) \| ast::UseTreeKind::Glob => {
	if unused_import.unused.contains(&use_tree_id) {
	UnusedSpanResult::FlatUnused(use_tree.span, full_span)
	} else {
	UnusedSpanResult::Used
	}
	}
	ast::UseTreeKind::Nested(ref nested) => {
	if nested.len() == 0 {
	return UnusedSpanResult::FlatUnused(use_tree.span, full_span);
	}

	let mut unused_spans = Vec::new();
	let mut to_remove = Vec::new();
	let mut all_nested_unused = true;
	let mut previous_unused = false;
	for (pos, (use_tree, use_tree_id)) in nested.iter().enumerate() {
	let remove = match calc_unused_spans(unused_import, use_tree, *use_tree_id) {
	UnusedSpanResult::Used => {
	all_nested_unused = false;
	None
	}
	UnusedSpanResult::FlatUnused(span, remove) => {
	unused_spans.push(span);
	Some(remove)
	}
	UnusedSpanResult::NestedFullUnused(mut spans, remove) => {
	unused_spans.append(&mut spans);
	Some(remove)
	}
	UnusedSpanResult::NestedPartialUnused(mut spans, mut to_remove_extra) => {
	all_nested_unused = false;
	unused_spans.append(&mut spans);
	to_remove.append(&mut to_remove_extra);
	None
	}
	};
	if let Some(remove) = remove {
	let remove_span = if nested.len() == 1 {
	remove
	} else if pos == nested.len() - 1 \|\| !all_nested_unused {
	// Delete everything from the end of the last import, to delete the
	// previous comma
	nested[pos - 1].0.span.shrink_to_hi().to(use_tree.span)
	} else {
	// Delete everything until the next import, to delete the trailing commas
	use_tree.span.to(nested[pos + 1].0.span.shrink_to_lo())
	};

	// Try to collapse adjacent spans into a single one. This prevents all cases of
	// overlapping removals, which are not supported by rustfix
	if previous_unused && !to_remove.is_empty() {
	let previous = to_remove.pop().unwrap();
	to_remove.push(previous.to(remove_span));
	} else {
	to_remove.push(remove_span);
	}
	}
	previous_unused = remove.is_some();
	}
	if unused_spans.is_empty() {
	UnusedSpanResult::Used
	} else if all_nested_unused {
	UnusedSpanResult::NestedFullUnused(unused_spans, full_span)
	} else {
	UnusedSpanResult::NestedPartialUnused(unused_spans, to_remove)
	}
	}
	}
	}

	impl Resolver<'_> {
	crate fn check_unused(&mut self, krate: &ast::Crate) {
	for directive in self.potentially_unused_imports.iter() {
	match directive.subclass {
	_ if directive.used.get() \|\|
	directive.vis.get() == ty::Visibility::Public \|\|
	directive.span.is_dummy() => {
	if let ImportDirectiveSubclass::MacroUse = directive.subclass {
	if !directive.span.is_dummy() {
	self.session.buffer_lint(
	lint::builtin::MACRO_USE_EXTERN_CRATE,
	directive.id,
	directive.span,
	"deprecated `#[macro_use]` directive used to \
	import macros should be replaced at use sites \
	with a `use` statement to import the macro \
	instead",
	);
	}
	}
	}
	ImportDirectiveSubclass::ExternCrate { .. } => {
	self.maybe_unused_extern_crates.push((directive.id, directive.span));
	}
	ImportDirectiveSubclass::MacroUse => {
	let lint = lint::builtin::UNUSED_IMPORTS;
	let msg = "unused `#[macro_use]` import";
	self.session.buffer_lint(lint, directive.id, directive.span, msg);
	}
	_ => {}
	}
	}

	let mut visitor = UnusedImportCheckVisitor {
	r: self,
	unused_imports: Default::default(),
	base_use_tree: None,
	base_id: ast::DUMMY_NODE_ID,
	item_span: DUMMY_SP,
	};
	visit::walk_crate(&mut visitor, krate);

	for unused in visitor.unused_imports.values() {
	let mut fixes = Vec::new();
	let mut spans = match calc_unused_spans(unused, unused.use_tree, unused.use_tree_id) {
	UnusedSpanResult::Used => continue,
	UnusedSpanResult::FlatUnused(span, remove) => {
	fixes.push((remove, String::new()));
	vec![span]
	}
	UnusedSpanResult::NestedFullUnused(spans, remove) => {
	fixes.push((remove, String::new()));
	spans
	}
	UnusedSpanResult::NestedPartialUnused(spans, remove) => {
	for fix in &remove {
	fixes.push((*fix, String::new()));
	}
	spans
	}
	};

	let len = spans.len();
	spans.sort();
	let ms = MultiSpan::from_spans(spans.clone());
	let mut span_snippets = spans.iter()
	.filter_map(\|s\| {
	match visitor.r.session.source_map().span_to_snippet(*s) {
	Ok(s) => Some(format!("`{}`", s)),
	_ => None,
	}
	}).collect::<Vec<String>>();
	span_snippets.sort();
	let msg = format!("unused import{}{}",
	if len > 1 { "s" } else { "" },
	if !span_snippets.is_empty() {
	format!(": {}", span_snippets.join(", "))
	} else {
	String::new()
	});

	let fix_msg = if fixes.len() == 1 && fixes[0].0 == unused.item_span {
	"remove the whole `use` item"
	} else if spans.len() > 1 {
	"remove the unused imports"
	} else {
	"remove the unused import"
	};

	visitor.r.session.buffer_lint_with_diagnostic(
	lint::builtin::UNUSED_IMPORTS,
	unused.use_tree_id,
	ms,
	&msg,
	lint::builtin::BuiltinLintDiagnostics::UnusedImports(fix_msg.into(), fixes),
	);
	}
	}
	}