compiler/rustc_typeck/src/coherence/inherent_impls_overlap.rs - toolchain/rustc - Git at Google

 use rustc_data_structures::fx::{FxHashMap, FxHashSet};
 use rustc_errors::struct_span_err;
 use rustc_hir as hir;
 use rustc_hir::def::DefKind;
 use rustc_hir::def_id::DefId;
 use rustc_index::vec::IndexVec;
 use rustc_middle::traits::specialization_graph::OverlapMode;
 use rustc_middle::ty::{self, TyCtxt};
 use rustc_span::Symbol;
 use rustc_trait_selection::traits::{self, SkipLeakCheck};
 use smallvec::SmallVec;
 use std::collections::hash_map::Entry;

 pub fn crate_inherent_impls_overlap_check(tcx: TyCtxt<'_>, (): ()) {
     let mut inherent_overlap_checker = InherentOverlapChecker { tcx };
     for id in tcx.hir().items() {
         inherent_overlap_checker.check_item(id);
     }
 }

 struct InherentOverlapChecker<'tcx> {
     tcx: TyCtxt<'tcx>,
 }

 impl<'tcx> InherentOverlapChecker<'tcx> {
     /// Checks whether any associated items in impls 1 and 2 share the same identifier and
     /// namespace.
     fn impls_have_common_items(
         &self,
         impl_items1: &ty::AssocItems<'_>,
         impl_items2: &ty::AssocItems<'_>,
     ) -> bool {
         let mut impl_items1 = &impl_items1;
         let mut impl_items2 = &impl_items2;

         // Performance optimization: iterate over the smaller list
         if impl_items1.len() > impl_items2.len() {
             std::mem::swap(&mut impl_items1, &mut impl_items2);
         }

         for item1 in impl_items1.in_definition_order() {
             let collision = impl_items2
                 .filter_by_name_unhygienic(item1.name)
                 .any(|item2| self.compare_hygienically(item1, item2));

             if collision {
                 return true;
             }
         }

         false
     }

     fn compare_hygienically(&self, item1: &ty::AssocItem, item2: &ty::AssocItem) -> bool {
         // Symbols and namespace match, compare hygienically.
         item1.kind.namespace() == item2.kind.namespace()
             && item1.ident(self.tcx).normalize_to_macros_2_0()
                 == item2.ident(self.tcx).normalize_to_macros_2_0()
     }

     fn check_for_common_items_in_impls(
         &self,
         impl1: DefId,
         impl2: DefId,
         overlap: traits::OverlapResult<'_>,
     ) {
         let impl_items1 = self.tcx.associated_items(impl1);
         let impl_items2 = self.tcx.associated_items(impl2);

         for item1 in impl_items1.in_definition_order() {
             let collision = impl_items2
                 .filter_by_name_unhygienic(item1.name)
                 .find(|item2| self.compare_hygienically(item1, item2));

             if let Some(item2) = collision {
                 let name = item1.ident(self.tcx).normalize_to_macros_2_0();
                 let mut err = struct_span_err!(
                     self.tcx.sess,
                     self.tcx.def_span(item1.def_id),
                     E0592,
                     "duplicate definitions with name `{}`",
                     name
                 );
                 err.span_label(
                     self.tcx.def_span(item1.def_id),
                     format!("duplicate definitions for `{}`", name),
                 );
                 err.span_label(
                     self.tcx.def_span(item2.def_id),
                     format!("other definition for `{}`", name),
                 );

                 for cause in &overlap.intercrate_ambiguity_causes {
                     cause.add_intercrate_ambiguity_hint(&mut err);
                 }

                 if overlap.involves_placeholder {
                     traits::add_placeholder_note(&mut err);
                 }

                 err.emit();
             }
         }
     }

     fn check_for_overlapping_inherent_impls(
         &self,
         overlap_mode: OverlapMode,
         impl1_def_id: DefId,
         impl2_def_id: DefId,
     ) {
         traits::overlapping_impls(
             self.tcx,
             impl1_def_id,
             impl2_def_id,
             // We go ahead and just skip the leak check for
             // inherent impls without warning.
             SkipLeakCheck::Yes,
             overlap_mode,
             |overlap| {
                 self.check_for_common_items_in_impls(impl1_def_id, impl2_def_id, overlap);
                 false
             },
             || true,
         );
     }

     fn check_item(&mut self, id: hir::ItemId) {
         let def_kind = self.tcx.def_kind(id.def_id);
         if !matches!(def_kind, DefKind::Enum | DefKind::Struct | DefKind::Trait | DefKind::Union) {
             return;
         }

         let impls = self.tcx.inherent_impls(id.def_id);

         // If there is only one inherent impl block,
         // there is nothing to overlap check it with
         if impls.len() <= 1 {
             return;
         }

         let overlap_mode = OverlapMode::get(self.tcx, id.def_id.to_def_id());

         let impls_items = impls
             .iter()
             .map(|impl_def_id| (impl_def_id, self.tcx.associated_items(*impl_def_id)))
             .collect::<SmallVec<[_; 8]>>();

         // Perform a O(n^2) algorithm for small n,
         // otherwise switch to an allocating algorithm with
         // faster asymptotic runtime.
         const ALLOCATING_ALGO_THRESHOLD: usize = 500;
         if impls.len() < ALLOCATING_ALGO_THRESHOLD {
             for (i, &(&impl1_def_id, impl_items1)) in impls_items.iter().enumerate() {
                 for &(&impl2_def_id, impl_items2) in &impls_items[(i + 1)..] {
                     if self.impls_have_common_items(impl_items1, impl_items2) {
                         self.check_for_overlapping_inherent_impls(
                             overlap_mode,
                             impl1_def_id,
                             impl2_def_id,
                         );
                     }
                 }
             }
         } else {
             // Build a set of connected regions of impl blocks.
             // Two impl blocks are regarded as connected if they share
             // an item with the same unhygienic identifier.
             // After we have assembled the connected regions,
             // run the O(n^2) algorithm on each connected region.
             // This is advantageous to running the algorithm over the
             // entire graph when there are many connected regions.

             rustc_index::newtype_index! {
                 pub struct RegionId {
                     ENCODABLE = custom
                 }
             }
             struct ConnectedRegion {
                 idents: SmallVec<[Symbol; 8]>,
                 impl_blocks: FxHashSet<usize>,
             }
             let mut connected_regions: IndexVec<RegionId, _> = Default::default();
             // Reverse map from the Symbol to the connected region id.
             let mut connected_region_ids = FxHashMap::default();

             for (i, &(&_impl_def_id, impl_items)) in impls_items.iter().enumerate() {
                 if impl_items.len() == 0 {
                     continue;
                 }
                 // First obtain a list of existing connected region ids
                 let mut idents_to_add = SmallVec::<[Symbol; 8]>::new();
                 let mut ids = impl_items
                     .in_definition_order()
                     .filter_map(|item| {
                         let entry = connected_region_ids.entry(item.name);
                         if let Entry::Occupied(e) = &entry {
                             Some(*e.get())
                         } else {
                             idents_to_add.push(item.name);
                             None
                         }
                     })
                     .collect::<SmallVec<[RegionId; 8]>>();
                 // Sort the id list so that the algorithm is deterministic
                 ids.sort_unstable();
                 ids.dedup();
                 let ids = ids;
                 match &ids[..] {
                     // Create a new connected region
                     [] => {
                         let id_to_set = connected_regions.next_index();
                         // Update the connected region ids
                         for ident in &idents_to_add {
                             connected_region_ids.insert(*ident, id_to_set);
                         }
                         connected_regions.insert(
                             id_to_set,
                             ConnectedRegion {
                                 idents: idents_to_add,
                                 impl_blocks: std::iter::once(i).collect(),
                             },
                         );
                     }
                     // Take the only id inside the list
                     &[id_to_set] => {
                         let region = connected_regions[id_to_set].as_mut().unwrap();
                         region.impl_blocks.insert(i);
                         region.idents.extend_from_slice(&idents_to_add);
                         // Update the connected region ids
                         for ident in &idents_to_add {
                             connected_region_ids.insert(*ident, id_to_set);
                         }
                     }
                     // We have multiple connected regions to merge.
                     // In the worst case this might add impl blocks
                     // one by one and can thus be O(n^2) in the size
                     // of the resulting final connected region, but
                     // this is no issue as the final step to check
                     // for overlaps runs in O(n^2) as well.
                     &[id_to_set, ..] => {
                         let mut region = connected_regions.remove(id_to_set).unwrap();
                         region.impl_blocks.insert(i);
                         region.idents.extend_from_slice(&idents_to_add);
                         // Update the connected region ids
                         for ident in &idents_to_add {
                             connected_region_ids.insert(*ident, id_to_set);
                         }

                         // Remove other regions from ids.
                         for &id in ids.iter() {
                             if id == id_to_set {
                                 continue;
                             }
                             let r = connected_regions.remove(id).unwrap();
                             for ident in r.idents.iter() {
                                 connected_region_ids.insert(*ident, id_to_set);
                             }
                             region.idents.extend_from_slice(&r.idents);
                             region.impl_blocks.extend(r.impl_blocks);
                         }

                         connected_regions.insert(id_to_set, region);
                     }
                 }
             }

             debug!(
                 "churning through {} components (sum={}, avg={}, var={}, max={})",
                 connected_regions.len(),
                 impls.len(),
                 impls.len() / connected_regions.len(),
                 {
                     let avg = impls.len() / connected_regions.len();
                     let s = connected_regions
                         .iter()
                         .flatten()
                         .map(|r| r.impl_blocks.len() as isize - avg as isize)
                         .map(|v| v.abs() as usize)
                         .sum::<usize>();
                     s / connected_regions.len()
                 },
                 connected_regions.iter().flatten().map(|r| r.impl_blocks.len()).max().unwrap()
             );
             // List of connected regions is built. Now, run the overlap check
             // for each pair of impl blocks in the same connected region.
             for region in connected_regions.into_iter().flatten() {
                 let mut impl_blocks =
                     region.impl_blocks.into_iter().collect::<SmallVec<[usize; 8]>>();
                 impl_blocks.sort_unstable();
                 for (i, &impl1_items_idx) in impl_blocks.iter().enumerate() {
                     let &(&impl1_def_id, impl_items1) = &impls_items[impl1_items_idx];
                     for &impl2_items_idx in impl_blocks[(i + 1)..].iter() {
                         let &(&impl2_def_id, impl_items2) = &impls_items[impl2_items_idx];
                         if self.impls_have_common_items(impl_items1, impl_items2) {
                             self.check_for_overlapping_inherent_impls(
                                 overlap_mode,
                                 impl1_def_id,
                                 impl2_def_id,
                             );
                         }
                     }
                 }
             }
         }
     }
 }
	use rustc_data_structures::fx::{FxHashMap, FxHashSet};
	use rustc_errors::struct_span_err;
	use rustc_hir as hir;
	use rustc_hir::def::DefKind;
	use rustc_hir::def_id::DefId;
	use rustc_index::vec::IndexVec;
	use rustc_middle::traits::specialization_graph::OverlapMode;
	use rustc_middle::ty::{self, TyCtxt};
	use rustc_span::Symbol;
	use rustc_trait_selection::traits::{self, SkipLeakCheck};
	use smallvec::SmallVec;
	use std::collections::hash_map::Entry;

	pub fn crate_inherent_impls_overlap_check(tcx: TyCtxt<'_>, (): ()) {
	let mut inherent_overlap_checker = InherentOverlapChecker { tcx };
	for id in tcx.hir().items() {
	inherent_overlap_checker.check_item(id);
	}
	}

	struct InherentOverlapChecker<'tcx> {
	tcx: TyCtxt<'tcx>,
	}

	impl<'tcx> InherentOverlapChecker<'tcx> {
	/// Checks whether any associated items in impls 1 and 2 share the same identifier and
	/// namespace.
	fn impls_have_common_items(
	&self,
	impl_items1: &ty::AssocItems<'_>,
	impl_items2: &ty::AssocItems<'_>,
	) -> bool {
	let mut impl_items1 = &impl_items1;
	let mut impl_items2 = &impl_items2;

	// Performance optimization: iterate over the smaller list
	if impl_items1.len() > impl_items2.len() {
	std::mem::swap(&mut impl_items1, &mut impl_items2);
	}

	for item1 in impl_items1.in_definition_order() {
	let collision = impl_items2
	.filter_by_name_unhygienic(item1.name)
	.any(\|item2\| self.compare_hygienically(item1, item2));

	if collision {
	return true;
	}
	}

	false
	}

	fn compare_hygienically(&self, item1: &ty::AssocItem, item2: &ty::AssocItem) -> bool {
	// Symbols and namespace match, compare hygienically.
	item1.kind.namespace() == item2.kind.namespace()
	&& item1.ident(self.tcx).normalize_to_macros_2_0()
	== item2.ident(self.tcx).normalize_to_macros_2_0()
	}

	fn check_for_common_items_in_impls(
	&self,
	impl1: DefId,
	impl2: DefId,
	overlap: traits::OverlapResult<'_>,
	) {
	let impl_items1 = self.tcx.associated_items(impl1);
	let impl_items2 = self.tcx.associated_items(impl2);

	for item1 in impl_items1.in_definition_order() {
	let collision = impl_items2
	.filter_by_name_unhygienic(item1.name)
	.find(\|item2\| self.compare_hygienically(item1, item2));

	if let Some(item2) = collision {
	let name = item1.ident(self.tcx).normalize_to_macros_2_0();
	let mut err = struct_span_err!(
	self.tcx.sess,
	self.tcx.def_span(item1.def_id),
	E0592,
	"duplicate definitions with name `{}`",
	name
	);
	err.span_label(
	self.tcx.def_span(item1.def_id),
	format!("duplicate definitions for `{}`", name),
	);
	err.span_label(
	self.tcx.def_span(item2.def_id),
	format!("other definition for `{}`", name),
	);

	for cause in &overlap.intercrate_ambiguity_causes {
	cause.add_intercrate_ambiguity_hint(&mut err);
	}

	if overlap.involves_placeholder {
	traits::add_placeholder_note(&mut err);
	}

	err.emit();
	}
	}
	}

	fn check_for_overlapping_inherent_impls(
	&self,
	overlap_mode: OverlapMode,
	impl1_def_id: DefId,
	impl2_def_id: DefId,
	) {
	traits::overlapping_impls(
	self.tcx,
	impl1_def_id,
	impl2_def_id,
	// We go ahead and just skip the leak check for
	// inherent impls without warning.
	SkipLeakCheck::Yes,
	overlap_mode,
	\|overlap\| {
	self.check_for_common_items_in_impls(impl1_def_id, impl2_def_id, overlap);
	false
	},
	\|\| true,
	);
	}

	fn check_item(&mut self, id: hir::ItemId) {
	let def_kind = self.tcx.def_kind(id.def_id);
	if !matches!(def_kind, DefKind::Enum \| DefKind::Struct \| DefKind::Trait \| DefKind::Union) {
	return;
	}

	let impls = self.tcx.inherent_impls(id.def_id);

	// If there is only one inherent impl block,
	// there is nothing to overlap check it with
	if impls.len() <= 1 {
	return;
	}

	let overlap_mode = OverlapMode::get(self.tcx, id.def_id.to_def_id());

	let impls_items = impls
	.iter()
	.map(\|impl_def_id\| (impl_def_id, self.tcx.associated_items(*impl_def_id)))
	.collect::<SmallVec<[_; 8]>>();

	// Perform a O(n^2) algorithm for small n,
	// otherwise switch to an allocating algorithm with
	// faster asymptotic runtime.
	const ALLOCATING_ALGO_THRESHOLD: usize = 500;
	if impls.len() < ALLOCATING_ALGO_THRESHOLD {
	for (i, &(&impl1_def_id, impl_items1)) in impls_items.iter().enumerate() {
	for &(&impl2_def_id, impl_items2) in &impls_items[(i + 1)..] {
	if self.impls_have_common_items(impl_items1, impl_items2) {
	self.check_for_overlapping_inherent_impls(
	overlap_mode,
	impl1_def_id,
	impl2_def_id,
	);
	}
	}
	}
	} else {
	// Build a set of connected regions of impl blocks.
	// Two impl blocks are regarded as connected if they share
	// an item with the same unhygienic identifier.
	// After we have assembled the connected regions,
	// run the O(n^2) algorithm on each connected region.
	// This is advantageous to running the algorithm over the
	// entire graph when there are many connected regions.

	rustc_index::newtype_index! {
	pub struct RegionId {
	ENCODABLE = custom
	}
	}
	struct ConnectedRegion {
	idents: SmallVec<[Symbol; 8]>,
	impl_blocks: FxHashSet<usize>,
	}
	let mut connected_regions: IndexVec<RegionId, _> = Default::default();
	// Reverse map from the Symbol to the connected region id.
	let mut connected_region_ids = FxHashMap::default();

	for (i, &(&_impl_def_id, impl_items)) in impls_items.iter().enumerate() {
	if impl_items.len() == 0 {
	continue;
	}
	// First obtain a list of existing connected region ids
	let mut idents_to_add = SmallVec::<[Symbol; 8]>::new();
	let mut ids = impl_items
	.in_definition_order()
	.filter_map(\|item\| {
	let entry = connected_region_ids.entry(item.name);
	if let Entry::Occupied(e) = &entry {
	Some(*e.get())
	} else {
	idents_to_add.push(item.name);
	None
	}
	})
	.collect::<SmallVec<[RegionId; 8]>>();
	// Sort the id list so that the algorithm is deterministic
	ids.sort_unstable();
	ids.dedup();
	let ids = ids;
	match &ids[..] {
	// Create a new connected region
	[] => {
	let id_to_set = connected_regions.next_index();
	// Update the connected region ids
	for ident in &idents_to_add {
	connected_region_ids.insert(*ident, id_to_set);
	}
	connected_regions.insert(
	id_to_set,
	ConnectedRegion {
	idents: idents_to_add,
	impl_blocks: std::iter::once(i).collect(),
	},
	);
	}
	// Take the only id inside the list
	&[id_to_set] => {
	let region = connected_regions[id_to_set].as_mut().unwrap();
	region.impl_blocks.insert(i);
	region.idents.extend_from_slice(&idents_to_add);
	// Update the connected region ids
	for ident in &idents_to_add {
	connected_region_ids.insert(*ident, id_to_set);
	}
	}
	// We have multiple connected regions to merge.
	// In the worst case this might add impl blocks
	// one by one and can thus be O(n^2) in the size
	// of the resulting final connected region, but
	// this is no issue as the final step to check
	// for overlaps runs in O(n^2) as well.
	&[id_to_set, ..] => {
	let mut region = connected_regions.remove(id_to_set).unwrap();
	region.impl_blocks.insert(i);
	region.idents.extend_from_slice(&idents_to_add);
	// Update the connected region ids
	for ident in &idents_to_add {
	connected_region_ids.insert(*ident, id_to_set);
	}

	// Remove other regions from ids.
	for &id in ids.iter() {
	if id == id_to_set {
	continue;
	}
	let r = connected_regions.remove(id).unwrap();
	for ident in r.idents.iter() {
	connected_region_ids.insert(*ident, id_to_set);
	}
	region.idents.extend_from_slice(&r.idents);
	region.impl_blocks.extend(r.impl_blocks);
	}

	connected_regions.insert(id_to_set, region);
	}
	}
	}

	debug!(
	"churning through {} components (sum={}, avg={}, var={}, max={})",
	connected_regions.len(),
	impls.len(),
	impls.len() / connected_regions.len(),
	{
	let avg = impls.len() / connected_regions.len();
	let s = connected_regions
	.iter()
	.flatten()
	.map(\|r\| r.impl_blocks.len() as isize - avg as isize)
	.map(\|v\| v.abs() as usize)
	.sum::<usize>();
	s / connected_regions.len()
	},
	connected_regions.iter().flatten().map(\|r\| r.impl_blocks.len()).max().unwrap()
	);
	// List of connected regions is built. Now, run the overlap check
	// for each pair of impl blocks in the same connected region.
	for region in connected_regions.into_iter().flatten() {
	let mut impl_blocks =
	region.impl_blocks.into_iter().collect::<SmallVec<[usize; 8]>>();
	impl_blocks.sort_unstable();
	for (i, &impl1_items_idx) in impl_blocks.iter().enumerate() {
	let &(&impl1_def_id, impl_items1) = &impls_items[impl1_items_idx];
	for &impl2_items_idx in impl_blocks[(i + 1)..].iter() {
	let &(&impl2_def_id, impl_items2) = &impls_items[impl2_items_idx];
	if self.impls_have_common_items(impl_items1, impl_items2) {
	self.check_for_overlapping_inherent_impls(
	overlap_mode,
	impl1_def_id,
	impl2_def_id,
	);
	}
	}
	}
	}
	}
	}
	}