include/llvm/ADT/SparseMultiSet.h - llvm - Git at Google

 //===- llvm/ADT/SparseMultiSet.h - Sparse multiset --------------*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // This file defines the SparseMultiSet class, which adds multiset behavior to
 // the SparseSet.
 //
 // A sparse multiset holds a small number of objects identified by integer keys
 // from a moderately sized universe. The sparse multiset uses more memory than
 // other containers in order to provide faster operations. Any key can map to
 // multiple values. A SparseMultiSetNode class is provided, which serves as a
 // convenient base class for the contents of a SparseMultiSet.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_ADT_SPARSEMULTISET_H
 #define LLVM_ADT_SPARSEMULTISET_H

 #include "llvm/ADT/STLExtras.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/ADT/SparseSet.h"
 #include <cassert>
 #include <cstdint>
 #include <cstdlib>
 #include <iterator>
 #include <limits>
 #include <utility>

 namespace llvm {

 /// Fast multiset implementation for objects that can be identified by small
 /// unsigned keys.
 ///
 /// SparseMultiSet allocates memory proportional to the size of the key
 /// universe, so it is not recommended for building composite data structures.
 /// It is useful for algorithms that require a single set with fast operations.
 ///
 /// Compared to DenseSet and DenseMap, SparseMultiSet provides constant-time
 /// fast clear() as fast as a vector.  The find(), insert(), and erase()
 /// operations are all constant time, and typically faster than a hash table.
 /// The iteration order doesn't depend on numerical key values, it only depends
 /// on the order of insert() and erase() operations.  Iteration order is the
 /// insertion order. Iteration is only provided over elements of equivalent
 /// keys, but iterators are bidirectional.
 ///
 /// Compared to BitVector, SparseMultiSet<unsigned> uses 8x-40x more memory, but
 /// offers constant-time clear() and size() operations as well as fast iteration
 /// independent on the size of the universe.
 ///
 /// SparseMultiSet contains a dense vector holding all the objects and a sparse
 /// array holding indexes into the dense vector.  Most of the memory is used by
 /// the sparse array which is the size of the key universe. The SparseT template
 /// parameter provides a space/speed tradeoff for sets holding many elements.
 ///
 /// When SparseT is uint32_t, find() only touches up to 3 cache lines, but the
 /// sparse array uses 4 x Universe bytes.
 ///
 /// When SparseT is uint8_t (the default), find() touches up to 3+[N/256] cache
 /// lines, but the sparse array is 4x smaller.  N is the number of elements in
 /// the set.
 ///
 /// For sets that may grow to thousands of elements, SparseT should be set to
 /// uint16_t or uint32_t.
 ///
 /// Multiset behavior is provided by providing doubly linked lists for values
 /// that are inlined in the dense vector. SparseMultiSet is a good choice when
 /// one desires a growable number of entries per key, as it will retain the
 /// SparseSet algorithmic properties despite being growable. Thus, it is often a
 /// better choice than a SparseSet of growable containers or a vector of
 /// vectors. SparseMultiSet also keeps iterators valid after erasure (provided
 /// the iterators don't point to the element erased), allowing for more
 /// intuitive and fast removal.
 ///
 /// @tparam ValueT      The type of objects in the set.
 /// @tparam KeyFunctorT A functor that computes an unsigned index from KeyT.
 /// @tparam SparseT     An unsigned integer type. See above.
 ///
 template<typename ValueT,
          typename KeyFunctorT = identity<unsigned>,
          typename SparseT = uint8_t>
 class SparseMultiSet {
   static_assert(std::numeric_limits<SparseT>::is_integer &&
                 !std::numeric_limits<SparseT>::is_signed,
                 "SparseT must be an unsigned integer type");

   /// The actual data that's stored, as a doubly-linked list implemented via
   /// indices into the DenseVector.  The doubly linked list is implemented
   /// circular in Prev indices, and INVALID-terminated in Next indices. This
   /// provides efficient access to list tails. These nodes can also be
   /// tombstones, in which case they are actually nodes in a single-linked
   /// freelist of recyclable slots.
   struct SMSNode {
     static const unsigned INVALID = ~0U;

     ValueT Data;
     unsigned Prev;
     unsigned Next;

     SMSNode(ValueT D, unsigned P, unsigned N) : Data(D), Prev(P), Next(N) {}

     /// List tails have invalid Nexts.
     bool isTail() const {
       return Next == INVALID;
     }

     /// Whether this node is a tombstone node, and thus is in our freelist.
     bool isTombstone() const {
       return Prev == INVALID;
     }

     /// Since the list is circular in Prev, all non-tombstone nodes have a valid
     /// Prev.
     bool isValid() const { return Prev != INVALID; }
   };

   using KeyT = typename KeyFunctorT::argument_type;
   using DenseT = SmallVector<SMSNode, 8>;
   DenseT Dense;
   SparseT *Sparse = nullptr;
   unsigned Universe = 0;
   KeyFunctorT KeyIndexOf;
   SparseSetValFunctor<KeyT, ValueT, KeyFunctorT> ValIndexOf;

   /// We have a built-in recycler for reusing tombstone slots. This recycler
   /// puts a singly-linked free list into tombstone slots, allowing us quick
   /// erasure, iterator preservation, and dense size.
   unsigned FreelistIdx = SMSNode::INVALID;
   unsigned NumFree = 0;

   unsigned sparseIndex(const ValueT &Val) const {
     assert(ValIndexOf(Val) < Universe &&
            "Invalid key in set. Did object mutate?");
     return ValIndexOf(Val);
   }
   unsigned sparseIndex(const SMSNode &N) const { return sparseIndex(N.Data); }

   /// Whether the given entry is the head of the list. List heads's previous
   /// pointers are to the tail of the list, allowing for efficient access to the
   /// list tail. D must be a valid entry node.
   bool isHead(const SMSNode &D) const {
     assert(D.isValid() && "Invalid node for head");
     return Dense[D.Prev].isTail();
   }

   /// Whether the given entry is a singleton entry, i.e. the only entry with
   /// that key.
   bool isSingleton(const SMSNode &N) const {
     assert(N.isValid() && "Invalid node for singleton");
     // Is N its own predecessor?
     return &Dense[N.Prev] == &N;
   }

   /// Add in the given SMSNode. Uses a free entry in our freelist if
   /// available. Returns the index of the added node.
   unsigned addValue(const ValueT& V, unsigned Prev, unsigned Next) {
     if (NumFree == 0) {
       Dense.push_back(SMSNode(V, Prev, Next));
       return Dense.size() - 1;
     }

     // Peel off a free slot
     unsigned Idx = FreelistIdx;
     unsigned NextFree = Dense[Idx].Next;
     assert(Dense[Idx].isTombstone() && "Non-tombstone free?");

     Dense[Idx] = SMSNode(V, Prev, Next);
     FreelistIdx = NextFree;
     --NumFree;
     return Idx;
   }

   /// Make the current index a new tombstone. Pushes it onto the freelist.
   void makeTombstone(unsigned Idx) {
     Dense[Idx].Prev = SMSNode::INVALID;
     Dense[Idx].Next = FreelistIdx;
     FreelistIdx = Idx;
     ++NumFree;
   }

 public:
   using value_type = ValueT;
   using reference = ValueT &;
   using const_reference = const ValueT &;
   using pointer = ValueT *;
   using const_pointer = const ValueT *;
   using size_type = unsigned;

   SparseMultiSet() = default;
   SparseMultiSet(const SparseMultiSet &) = delete;
   SparseMultiSet &operator=(const SparseMultiSet &) = delete;
   ~SparseMultiSet() { free(Sparse); }

   /// Set the universe size which determines the largest key the set can hold.
   /// The universe must be sized before any elements can be added.
   ///
   /// @param U Universe size. All object keys must be less than U.
   ///
   void setUniverse(unsigned U) {
     // It's not hard to resize the universe on a non-empty set, but it doesn't
     // seem like a likely use case, so we can add that code when we need it.
     assert(empty() && "Can only resize universe on an empty map");
     // Hysteresis prevents needless reallocations.
     if (U >= Universe/4 && U <= Universe)
       return;
     free(Sparse);
     // The Sparse array doesn't actually need to be initialized, so malloc
     // would be enough here, but that will cause tools like valgrind to
     // complain about branching on uninitialized data.
     Sparse = static_cast<SparseT*>(safe_calloc(U, sizeof(SparseT)));
     Universe = U;
   }

   /// Our iterators are iterators over the collection of objects that share a
   /// key.
   template<typename SMSPtrTy>
   class iterator_base : public std::iterator<std::bidirectional_iterator_tag,
                                              ValueT> {
     friend class SparseMultiSet;

     SMSPtrTy SMS;
     unsigned Idx;
     unsigned SparseIdx;

     iterator_base(SMSPtrTy P, unsigned I, unsigned SI)
       : SMS(P), Idx(I), SparseIdx(SI) {}

     /// Whether our iterator has fallen outside our dense vector.
     bool isEnd() const {
       if (Idx == SMSNode::INVALID)
         return true;

       assert(Idx < SMS->Dense.size() && "Out of range, non-INVALID Idx?");
       return false;
     }

     /// Whether our iterator is properly keyed, i.e. the SparseIdx is valid
     bool isKeyed() const { return SparseIdx < SMS->Universe; }

     unsigned Prev() const { return SMS->Dense[Idx].Prev; }
     unsigned Next() const { return SMS->Dense[Idx].Next; }

     void setPrev(unsigned P) { SMS->Dense[Idx].Prev = P; }
     void setNext(unsigned N) { SMS->Dense[Idx].Next = N; }

   public:
     using super = std::iterator<std::bidirectional_iterator_tag, ValueT>;
     using value_type = typename super::value_type;
     using difference_type = typename super::difference_type;
     using pointer = typename super::pointer;
     using reference = typename super::reference;

     reference operator*() const {
       assert(isKeyed() && SMS->sparseIndex(SMS->Dense[Idx].Data) == SparseIdx &&
              "Dereferencing iterator of invalid key or index");

       return SMS->Dense[Idx].Data;
     }
     pointer operator->() const { return &operator*(); }

     /// Comparison operators
     bool operator==(const iterator_base &RHS) const {
       // end compares equal
       if (SMS == RHS.SMS && Idx == RHS.Idx) {
         assert((isEnd() || SparseIdx == RHS.SparseIdx) &&
                "Same dense entry, but different keys?");
         return true;
       }

       return false;
     }

     bool operator!=(const iterator_base &RHS) const {
       return !operator==(RHS);
     }

     /// Increment and decrement operators
     iterator_base &operator--() { // predecrement - Back up
       assert(isKeyed() && "Decrementing an invalid iterator");
       assert((isEnd() || !SMS->isHead(SMS->Dense[Idx])) &&
              "Decrementing head of list");

       // If we're at the end, then issue a new find()
       if (isEnd())
         Idx = SMS->findIndex(SparseIdx).Prev();
       else
         Idx = Prev();

       return *this;
     }
     iterator_base &operator++() { // preincrement - Advance
       assert(!isEnd() && isKeyed() && "Incrementing an invalid/end iterator");
       Idx = Next();
       return *this;
     }
     iterator_base operator--(int) { // postdecrement
       iterator_base I(*this);
       --*this;
       return I;
     }
     iterator_base operator++(int) { // postincrement
       iterator_base I(*this);
       ++*this;
       return I;
     }
   };

   using iterator = iterator_base<SparseMultiSet *>;
   using const_iterator = iterator_base<const SparseMultiSet *>;

   // Convenience types
   using RangePair = std::pair<iterator, iterator>;

   /// Returns an iterator past this container. Note that such an iterator cannot
   /// be decremented, but will compare equal to other end iterators.
   iterator end() { return iterator(this, SMSNode::INVALID, SMSNode::INVALID); }
   const_iterator end() const {
     return const_iterator(this, SMSNode::INVALID, SMSNode::INVALID);
   }

   /// Returns true if the set is empty.
   ///
   /// This is not the same as BitVector::empty().
   ///
   bool empty() const { return size() == 0; }

   /// Returns the number of elements in the set.
   ///
   /// This is not the same as BitVector::size() which returns the size of the
   /// universe.
   ///
   size_type size() const {
     assert(NumFree <= Dense.size() && "Out-of-bounds free entries");
     return Dense.size() - NumFree;
   }

   /// Clears the set.  This is a very fast constant time operation.
   ///
   void clear() {
     // Sparse does not need to be cleared, see find().
     Dense.clear();
     NumFree = 0;
     FreelistIdx = SMSNode::INVALID;
   }

   /// Find an element by its index.
   ///
   /// @param   Idx A valid index to find.
   /// @returns An iterator to the element identified by key, or end().
   ///
   iterator findIndex(unsigned Idx) {
     assert(Idx < Universe && "Key out of range");
     const unsigned Stride = std::numeric_limits<SparseT>::max() + 1u;
     for (unsigned i = Sparse[Idx], e = Dense.size(); i < e; i += Stride) {
       const unsigned FoundIdx = sparseIndex(Dense[i]);
       // Check that we're pointing at the correct entry and that it is the head
       // of a valid list.
       if (Idx == FoundIdx && Dense[i].isValid() && isHead(Dense[i]))
         return iterator(this, i, Idx);
       // Stride is 0 when SparseT >= unsigned.  We don't need to loop.
       if (!Stride)
         break;
     }
     return end();
   }

   /// Find an element by its key.
   ///
   /// @param   Key A valid key to find.
   /// @returns An iterator to the element identified by key, or end().
   ///
   iterator find(const KeyT &Key) {
     return findIndex(KeyIndexOf(Key));
   }

   const_iterator find(const KeyT &Key) const {
     iterator I = const_cast<SparseMultiSet*>(this)->findIndex(KeyIndexOf(Key));
     return const_iterator(I.SMS, I.Idx, KeyIndexOf(Key));
   }

   /// Returns the number of elements identified by Key. This will be linear in
   /// the number of elements of that key.
   size_type count(const KeyT &Key) const {
     unsigned Ret = 0;
     for (const_iterator It = find(Key); It != end(); ++It)
       ++Ret;

     return Ret;
   }

   /// Returns true if this set contains an element identified by Key.
   bool contains(const KeyT &Key) const {
     return find(Key) != end();
   }

   /// Return the head and tail of the subset's list, otherwise returns end().
   iterator getHead(const KeyT &Key) { return find(Key); }
   iterator getTail(const KeyT &Key) {
     iterator I = find(Key);
     if (I != end())
       I = iterator(this, I.Prev(), KeyIndexOf(Key));
     return I;
   }

   /// The bounds of the range of items sharing Key K. First member is the head
   /// of the list, and the second member is a decrementable end iterator for
   /// that key.
   RangePair equal_range(const KeyT &K) {
     iterator B = find(K);
     iterator E = iterator(this, SMSNode::INVALID, B.SparseIdx);
     return make_pair(B, E);
   }

   /// Insert a new element at the tail of the subset list. Returns an iterator
   /// to the newly added entry.
   iterator insert(const ValueT &Val) {
     unsigned Idx = sparseIndex(Val);
     iterator I = findIndex(Idx);

     unsigned NodeIdx = addValue(Val, SMSNode::INVALID, SMSNode::INVALID);

     if (I == end()) {
       // Make a singleton list
       Sparse[Idx] = NodeIdx;
       Dense[NodeIdx].Prev = NodeIdx;
       return iterator(this, NodeIdx, Idx);
     }

     // Stick it at the end.
     unsigned HeadIdx = I.Idx;
     unsigned TailIdx = I.Prev();
     Dense[TailIdx].Next = NodeIdx;
     Dense[HeadIdx].Prev = NodeIdx;
     Dense[NodeIdx].Prev = TailIdx;

     return iterator(this, NodeIdx, Idx);
   }

   /// Erases an existing element identified by a valid iterator.
   ///
   /// This invalidates iterators pointing at the same entry, but erase() returns
   /// an iterator pointing to the next element in the subset's list. This makes
   /// it possible to erase selected elements while iterating over the subset:
   ///
   ///   tie(I, E) = Set.equal_range(Key);
   ///   while (I != E)
   ///     if (test(*I))
   ///       I = Set.erase(I);
   ///     else
   ///       ++I;
   ///
   /// Note that if the last element in the subset list is erased, this will
   /// return an end iterator which can be decremented to get the new tail (if it
   /// exists):
   ///
   ///  tie(B, I) = Set.equal_range(Key);
   ///  for (bool isBegin = B == I; !isBegin; /* empty */) {
   ///    isBegin = (--I) == B;
   ///    if (test(I))
   ///      break;
   ///    I = erase(I);
   ///  }
   iterator erase(iterator I) {
     assert(I.isKeyed() && !I.isEnd() && !Dense[I.Idx].isTombstone() &&
            "erasing invalid/end/tombstone iterator");

     // First, unlink the node from its list. Then swap the node out with the
     // dense vector's last entry
     iterator NextI = unlink(Dense[I.Idx]);

     // Put in a tombstone.
     makeTombstone(I.Idx);

     return NextI;
   }

   /// Erase all elements with the given key. This invalidates all
   /// iterators of that key.
   void eraseAll(const KeyT &K) {
     for (iterator I = find(K); I != end(); /* empty */)
       I = erase(I);
   }

 private:
   /// Unlink the node from its list. Returns the next node in the list.
   iterator unlink(const SMSNode &N) {
     if (isSingleton(N)) {
       // Singleton is already unlinked
       assert(N.Next == SMSNode::INVALID && "Singleton has next?");
       return iterator(this, SMSNode::INVALID, ValIndexOf(N.Data));
     }

     if (isHead(N)) {
       // If we're the head, then update the sparse array and our next.
       Sparse[sparseIndex(N)] = N.Next;
       Dense[N.Next].Prev = N.Prev;
       return iterator(this, N.Next, ValIndexOf(N.Data));
     }

     if (N.isTail()) {
       // If we're the tail, then update our head and our previous.
       findIndex(sparseIndex(N)).setPrev(N.Prev);
       Dense[N.Prev].Next = N.Next;

       // Give back an end iterator that can be decremented
       iterator I(this, N.Prev, ValIndexOf(N.Data));
       return ++I;
     }

     // Otherwise, just drop us
     Dense[N.Next].Prev = N.Prev;
     Dense[N.Prev].Next = N.Next;
     return iterator(this, N.Next, ValIndexOf(N.Data));
   }
 };

 } // end namespace llvm

 #endif // LLVM_ADT_SPARSEMULTISET_H
	//===- llvm/ADT/SparseMultiSet.h - Sparse multiset --------------- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines the SparseMultiSet class, which adds multiset behavior to
	// the SparseSet.
	//
	// A sparse multiset holds a small number of objects identified by integer keys
	// from a moderately sized universe. The sparse multiset uses more memory than
	// other containers in order to provide faster operations. Any key can map to
	// multiple values. A SparseMultiSetNode class is provided, which serves as a
	// convenient base class for the contents of a SparseMultiSet.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_ADT_SPARSEMULTISET_H
	#define LLVM_ADT_SPARSEMULTISET_H

	#include "llvm/ADT/STLExtras.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/ADT/SparseSet.h"
	#include <cassert>
	#include <cstdint>
	#include <cstdlib>
	#include <iterator>
	#include <limits>
	#include <utility>

	namespace llvm {

	/// Fast multiset implementation for objects that can be identified by small
	/// unsigned keys.
	///
	/// SparseMultiSet allocates memory proportional to the size of the key
	/// universe, so it is not recommended for building composite data structures.
	/// It is useful for algorithms that require a single set with fast operations.
	///
	/// Compared to DenseSet and DenseMap, SparseMultiSet provides constant-time
	/// fast clear() as fast as a vector. The find(), insert(), and erase()
	/// operations are all constant time, and typically faster than a hash table.
	/// The iteration order doesn't depend on numerical key values, it only depends
	/// on the order of insert() and erase() operations. Iteration order is the
	/// insertion order. Iteration is only provided over elements of equivalent
	/// keys, but iterators are bidirectional.
	///
	/// Compared to BitVector, SparseMultiSet<unsigned> uses 8x-40x more memory, but
	/// offers constant-time clear() and size() operations as well as fast iteration
	/// independent on the size of the universe.
	///
	/// SparseMultiSet contains a dense vector holding all the objects and a sparse
	/// array holding indexes into the dense vector. Most of the memory is used by
	/// the sparse array which is the size of the key universe. The SparseT template
	/// parameter provides a space/speed tradeoff for sets holding many elements.
	///
	/// When SparseT is uint32_t, find() only touches up to 3 cache lines, but the
	/// sparse array uses 4 x Universe bytes.
	///
	/// When SparseT is uint8_t (the default), find() touches up to 3+[N/256] cache
	/// lines, but the sparse array is 4x smaller. N is the number of elements in
	/// the set.
	///
	/// For sets that may grow to thousands of elements, SparseT should be set to
	/// uint16_t or uint32_t.
	///
	/// Multiset behavior is provided by providing doubly linked lists for values
	/// that are inlined in the dense vector. SparseMultiSet is a good choice when
	/// one desires a growable number of entries per key, as it will retain the
	/// SparseSet algorithmic properties despite being growable. Thus, it is often a
	/// better choice than a SparseSet of growable containers or a vector of
	/// vectors. SparseMultiSet also keeps iterators valid after erasure (provided
	/// the iterators don't point to the element erased), allowing for more
	/// intuitive and fast removal.
	///
	/// @tparam ValueT The type of objects in the set.
	/// @tparam KeyFunctorT A functor that computes an unsigned index from KeyT.
	/// @tparam SparseT An unsigned integer type. See above.
	///
	template<typename ValueT,
	typename KeyFunctorT = identity<unsigned>,
	typename SparseT = uint8_t>
	class SparseMultiSet {
	static_assert(std::numeric_limits<SparseT>::is_integer &&
	!std::numeric_limits<SparseT>::is_signed,
	"SparseT must be an unsigned integer type");

	/// The actual data that's stored, as a doubly-linked list implemented via
	/// indices into the DenseVector. The doubly linked list is implemented
	/// circular in Prev indices, and INVALID-terminated in Next indices. This
	/// provides efficient access to list tails. These nodes can also be
	/// tombstones, in which case they are actually nodes in a single-linked
	/// freelist of recyclable slots.
	struct SMSNode {
	static const unsigned INVALID = ~0U;

	ValueT Data;
	unsigned Prev;
	unsigned Next;

	SMSNode(ValueT D, unsigned P, unsigned N) : Data(D), Prev(P), Next(N) {}

	/// List tails have invalid Nexts.
	bool isTail() const {
	return Next == INVALID;
	}

	/// Whether this node is a tombstone node, and thus is in our freelist.
	bool isTombstone() const {
	return Prev == INVALID;
	}

	/// Since the list is circular in Prev, all non-tombstone nodes have a valid
	/// Prev.
	bool isValid() const { return Prev != INVALID; }
	};

	using KeyT = typename KeyFunctorT::argument_type;
	using DenseT = SmallVector<SMSNode, 8>;
	DenseT Dense;
	SparseT *Sparse = nullptr;
	unsigned Universe = 0;
	KeyFunctorT KeyIndexOf;
	SparseSetValFunctor<KeyT, ValueT, KeyFunctorT> ValIndexOf;

	/// We have a built-in recycler for reusing tombstone slots. This recycler
	/// puts a singly-linked free list into tombstone slots, allowing us quick
	/// erasure, iterator preservation, and dense size.
	unsigned FreelistIdx = SMSNode::INVALID;
	unsigned NumFree = 0;

	unsigned sparseIndex(const ValueT &Val) const {
	assert(ValIndexOf(Val) < Universe &&
	"Invalid key in set. Did object mutate?");
	return ValIndexOf(Val);
	}
	unsigned sparseIndex(const SMSNode &N) const { return sparseIndex(N.Data); }

	/// Whether the given entry is the head of the list. List heads's previous
	/// pointers are to the tail of the list, allowing for efficient access to the
	/// list tail. D must be a valid entry node.
	bool isHead(const SMSNode &D) const {
	assert(D.isValid() && "Invalid node for head");
	return Dense[D.Prev].isTail();
	}

	/// Whether the given entry is a singleton entry, i.e. the only entry with
	/// that key.
	bool isSingleton(const SMSNode &N) const {
	assert(N.isValid() && "Invalid node for singleton");
	// Is N its own predecessor?
	return &Dense[N.Prev] == &N;
	}

	/// Add in the given SMSNode. Uses a free entry in our freelist if
	/// available. Returns the index of the added node.
	unsigned addValue(const ValueT& V, unsigned Prev, unsigned Next) {
	if (NumFree == 0) {
	Dense.push_back(SMSNode(V, Prev, Next));
	return Dense.size() - 1;
	}

	// Peel off a free slot
	unsigned Idx = FreelistIdx;
	unsigned NextFree = Dense[Idx].Next;
	assert(Dense[Idx].isTombstone() && "Non-tombstone free?");

	Dense[Idx] = SMSNode(V, Prev, Next);
	FreelistIdx = NextFree;
	--NumFree;
	return Idx;
	}

	/// Make the current index a new tombstone. Pushes it onto the freelist.
	void makeTombstone(unsigned Idx) {
	Dense[Idx].Prev = SMSNode::INVALID;
	Dense[Idx].Next = FreelistIdx;
	FreelistIdx = Idx;
	++NumFree;
	}

	public:
	using value_type = ValueT;
	using reference = ValueT &;
	using const_reference = const ValueT &;
	using pointer = ValueT *;
	using const_pointer = const ValueT *;
	using size_type = unsigned;

	SparseMultiSet() = default;
	SparseMultiSet(const SparseMultiSet &) = delete;
	SparseMultiSet &operator=(const SparseMultiSet &) = delete;
	~SparseMultiSet() { free(Sparse); }

	/// Set the universe size which determines the largest key the set can hold.
	/// The universe must be sized before any elements can be added.
	///
	/// @param U Universe size. All object keys must be less than U.
	///
	void setUniverse(unsigned U) {
	// It's not hard to resize the universe on a non-empty set, but it doesn't
	// seem like a likely use case, so we can add that code when we need it.
	assert(empty() && "Can only resize universe on an empty map");
	// Hysteresis prevents needless reallocations.
	if (U >= Universe/4 && U <= Universe)
	return;
	free(Sparse);
	// The Sparse array doesn't actually need to be initialized, so malloc
	// would be enough here, but that will cause tools like valgrind to
	// complain about branching on uninitialized data.
	Sparse = static_cast<SparseT*>(safe_calloc(U, sizeof(SparseT)));
	Universe = U;
	}

	/// Our iterators are iterators over the collection of objects that share a
	/// key.
	template<typename SMSPtrTy>
	class iterator_base : public std::iterator<std::bidirectional_iterator_tag,
	ValueT> {
	friend class SparseMultiSet;

	SMSPtrTy SMS;
	unsigned Idx;
	unsigned SparseIdx;

	iterator_base(SMSPtrTy P, unsigned I, unsigned SI)
	: SMS(P), Idx(I), SparseIdx(SI) {}

	/// Whether our iterator has fallen outside our dense vector.
	bool isEnd() const {
	if (Idx == SMSNode::INVALID)
	return true;

	assert(Idx < SMS->Dense.size() && "Out of range, non-INVALID Idx?");
	return false;
	}

	/// Whether our iterator is properly keyed, i.e. the SparseIdx is valid
	bool isKeyed() const { return SparseIdx < SMS->Universe; }

	unsigned Prev() const { return SMS->Dense[Idx].Prev; }
	unsigned Next() const { return SMS->Dense[Idx].Next; }

	void setPrev(unsigned P) { SMS->Dense[Idx].Prev = P; }
	void setNext(unsigned N) { SMS->Dense[Idx].Next = N; }

	public:
	using super = std::iterator<std::bidirectional_iterator_tag, ValueT>;
	using value_type = typename super::value_type;
	using difference_type = typename super::difference_type;
	using pointer = typename super::pointer;
	using reference = typename super::reference;

	reference operator*() const {
	assert(isKeyed() && SMS->sparseIndex(SMS->Dense[Idx].Data) == SparseIdx &&
	"Dereferencing iterator of invalid key or index");

	return SMS->Dense[Idx].Data;
	}
	pointer operator->() const { return &operator*(); }

	/// Comparison operators
	bool operator==(const iterator_base &RHS) const {
	// end compares equal
	if (SMS == RHS.SMS && Idx == RHS.Idx) {
	assert((isEnd() \|\| SparseIdx == RHS.SparseIdx) &&
	"Same dense entry, but different keys?");
	return true;
	}

	return false;
	}

	bool operator!=(const iterator_base &RHS) const {
	return !operator==(RHS);
	}

	/// Increment and decrement operators
	iterator_base &operator--() { // predecrement - Back up
	assert(isKeyed() && "Decrementing an invalid iterator");
	assert((isEnd() \|\| !SMS->isHead(SMS->Dense[Idx])) &&
	"Decrementing head of list");

	// If we're at the end, then issue a new find()
	if (isEnd())
	Idx = SMS->findIndex(SparseIdx).Prev();
	else
	Idx = Prev();

	return *this;
	}
	iterator_base &operator++() { // preincrement - Advance
	assert(!isEnd() && isKeyed() && "Incrementing an invalid/end iterator");
	Idx = Next();
	return *this;
	}
	iterator_base operator--(int) { // postdecrement
	iterator_base I(*this);
	--*this;
	return I;
	}
	iterator_base operator++(int) { // postincrement
	iterator_base I(*this);
	++*this;
	return I;
	}
	};

	using iterator = iterator_base<SparseMultiSet *>;
	using const_iterator = iterator_base<const SparseMultiSet *>;

	// Convenience types
	using RangePair = std::pair<iterator, iterator>;

	/// Returns an iterator past this container. Note that such an iterator cannot
	/// be decremented, but will compare equal to other end iterators.
	iterator end() { return iterator(this, SMSNode::INVALID, SMSNode::INVALID); }
	const_iterator end() const {
	return const_iterator(this, SMSNode::INVALID, SMSNode::INVALID);
	}

	/// Returns true if the set is empty.
	///
	/// This is not the same as BitVector::empty().
	///
	bool empty() const { return size() == 0; }

	/// Returns the number of elements in the set.
	///
	/// This is not the same as BitVector::size() which returns the size of the
	/// universe.
	///
	size_type size() const {
	assert(NumFree <= Dense.size() && "Out-of-bounds free entries");
	return Dense.size() - NumFree;
	}

	/// Clears the set. This is a very fast constant time operation.
	///
	void clear() {
	// Sparse does not need to be cleared, see find().
	Dense.clear();
	NumFree = 0;
	FreelistIdx = SMSNode::INVALID;
	}

	/// Find an element by its index.
	///
	/// @param Idx A valid index to find.
	/// @returns An iterator to the element identified by key, or end().
	///
	iterator findIndex(unsigned Idx) {
	assert(Idx < Universe && "Key out of range");
	const unsigned Stride = std::numeric_limits<SparseT>::max() + 1u;
	for (unsigned i = Sparse[Idx], e = Dense.size(); i < e; i += Stride) {
	const unsigned FoundIdx = sparseIndex(Dense[i]);
	// Check that we're pointing at the correct entry and that it is the head
	// of a valid list.
	if (Idx == FoundIdx && Dense[i].isValid() && isHead(Dense[i]))
	return iterator(this, i, Idx);
	// Stride is 0 when SparseT >= unsigned. We don't need to loop.
	if (!Stride)
	break;
	}
	return end();
	}

	/// Find an element by its key.
	///
	/// @param Key A valid key to find.
	/// @returns An iterator to the element identified by key, or end().
	///
	iterator find(const KeyT &Key) {
	return findIndex(KeyIndexOf(Key));
	}

	const_iterator find(const KeyT &Key) const {
	iterator I = const_cast<SparseMultiSet*>(this)->findIndex(KeyIndexOf(Key));
	return const_iterator(I.SMS, I.Idx, KeyIndexOf(Key));
	}

	/// Returns the number of elements identified by Key. This will be linear in
	/// the number of elements of that key.
	size_type count(const KeyT &Key) const {
	unsigned Ret = 0;
	for (const_iterator It = find(Key); It != end(); ++It)
	++Ret;

	return Ret;
	}

	/// Returns true if this set contains an element identified by Key.
	bool contains(const KeyT &Key) const {
	return find(Key) != end();
	}

	/// Return the head and tail of the subset's list, otherwise returns end().
	iterator getHead(const KeyT &Key) { return find(Key); }
	iterator getTail(const KeyT &Key) {
	iterator I = find(Key);
	if (I != end())
	I = iterator(this, I.Prev(), KeyIndexOf(Key));
	return I;
	}

	/// The bounds of the range of items sharing Key K. First member is the head
	/// of the list, and the second member is a decrementable end iterator for
	/// that key.
	RangePair equal_range(const KeyT &K) {
	iterator B = find(K);
	iterator E = iterator(this, SMSNode::INVALID, B.SparseIdx);
	return make_pair(B, E);
	}

	/// Insert a new element at the tail of the subset list. Returns an iterator
	/// to the newly added entry.
	iterator insert(const ValueT &Val) {
	unsigned Idx = sparseIndex(Val);
	iterator I = findIndex(Idx);

	unsigned NodeIdx = addValue(Val, SMSNode::INVALID, SMSNode::INVALID);

	if (I == end()) {
	// Make a singleton list
	Sparse[Idx] = NodeIdx;
	Dense[NodeIdx].Prev = NodeIdx;
	return iterator(this, NodeIdx, Idx);
	}

	// Stick it at the end.
	unsigned HeadIdx = I.Idx;
	unsigned TailIdx = I.Prev();
	Dense[TailIdx].Next = NodeIdx;
	Dense[HeadIdx].Prev = NodeIdx;
	Dense[NodeIdx].Prev = TailIdx;

	return iterator(this, NodeIdx, Idx);
	}

	/// Erases an existing element identified by a valid iterator.
	///
	/// This invalidates iterators pointing at the same entry, but erase() returns
	/// an iterator pointing to the next element in the subset's list. This makes
	/// it possible to erase selected elements while iterating over the subset:
	///
	/// tie(I, E) = Set.equal_range(Key);
	/// while (I != E)
	/// if (test(*I))
	/// I = Set.erase(I);
	/// else
	/// ++I;
	///
	/// Note that if the last element in the subset list is erased, this will
	/// return an end iterator which can be decremented to get the new tail (if it
	/// exists):
	///
	/// tie(B, I) = Set.equal_range(Key);
	/// for (bool isBegin = B == I; !isBegin; /* empty */) {
	/// isBegin = (--I) == B;
	/// if (test(I))
	/// break;
	/// I = erase(I);
	/// }
	iterator erase(iterator I) {
	assert(I.isKeyed() && !I.isEnd() && !Dense[I.Idx].isTombstone() &&
	"erasing invalid/end/tombstone iterator");

	// First, unlink the node from its list. Then swap the node out with the
	// dense vector's last entry
	iterator NextI = unlink(Dense[I.Idx]);

	// Put in a tombstone.
	makeTombstone(I.Idx);

	return NextI;
	}

	/// Erase all elements with the given key. This invalidates all
	/// iterators of that key.
	void eraseAll(const KeyT &K) {
	for (iterator I = find(K); I != end(); /* empty */)
	I = erase(I);
	}

	private:
	/// Unlink the node from its list. Returns the next node in the list.
	iterator unlink(const SMSNode &N) {
	if (isSingleton(N)) {
	// Singleton is already unlinked
	assert(N.Next == SMSNode::INVALID && "Singleton has next?");
	return iterator(this, SMSNode::INVALID, ValIndexOf(N.Data));
	}

	if (isHead(N)) {
	// If we're the head, then update the sparse array and our next.
	Sparse[sparseIndex(N)] = N.Next;
	Dense[N.Next].Prev = N.Prev;
	return iterator(this, N.Next, ValIndexOf(N.Data));
	}

	if (N.isTail()) {
	// If we're the tail, then update our head and our previous.
	findIndex(sparseIndex(N)).setPrev(N.Prev);
	Dense[N.Prev].Next = N.Next;

	// Give back an end iterator that can be decremented
	iterator I(this, N.Prev, ValIndexOf(N.Data));
	return ++I;
	}

	// Otherwise, just drop us
	Dense[N.Next].Prev = N.Prev;
	Dense[N.Prev].Next = N.Next;
	return iterator(this, N.Next, ValIndexOf(N.Data));
	}
	};

	} // end namespace llvm

	#endif // LLVM_ADT_SPARSEMULTISET_H