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

 //===- llvm/ADT/BitVector.h - Bit vectors -----------------------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file implements the BitVector class.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_ADT_BITVECTOR_H
 #define LLVM_ADT_BITVECTOR_H

 #include "llvm/Support/Compiler.h"
 #include "llvm/Support/ErrorHandling.h"
 #include "llvm/Support/MathExtras.h"
 #include <algorithm>
 #include <cassert>
 #include <climits>
 #include <cstdlib>

 namespace llvm {

 class BitVector {
   typedef unsigned long BitWord;

   enum { BITWORD_SIZE = (unsigned)sizeof(BitWord) * CHAR_BIT };

   static_assert(BITWORD_SIZE == 64 || BITWORD_SIZE == 32,
                 "Unsupported word size");

   BitWord  *Bits;        // Actual bits.
   unsigned Size;         // Size of bitvector in bits.
   unsigned Capacity;     // Size of allocated memory in BitWord.

 public:
   typedef unsigned size_type;
   // Encapsulation of a single bit.
   class reference {
     friend class BitVector;

     BitWord *WordRef;
     unsigned BitPos;

     reference();  // Undefined

   public:
     reference(BitVector &b, unsigned Idx) {
       WordRef = &b.Bits[Idx / BITWORD_SIZE];
       BitPos = Idx % BITWORD_SIZE;
     }

     reference(const reference&) = default;

     reference &operator=(reference t) {
       *this = bool(t);
       return *this;
     }

     reference& operator=(bool t) {
       if (t)
         *WordRef |= BitWord(1) << BitPos;
       else
         *WordRef &= ~(BitWord(1) << BitPos);
       return *this;
     }

     operator bool() const {
       return ((*WordRef) & (BitWord(1) << BitPos)) ? true : false;
     }
   };


   /// BitVector default ctor - Creates an empty bitvector.
   BitVector() : Size(0), Capacity(0) {
     Bits = nullptr;
   }

   /// BitVector ctor - Creates a bitvector of specified number of bits. All
   /// bits are initialized to the specified value.
   explicit BitVector(unsigned s, bool t = false) : Size(s) {
     Capacity = NumBitWords(s);
     Bits = (BitWord *)std::malloc(Capacity * sizeof(BitWord));
     init_words(Bits, Capacity, t);
     if (t)
       clear_unused_bits();
   }

   /// BitVector copy ctor.
   BitVector(const BitVector &RHS) : Size(RHS.size()) {
     if (Size == 0) {
       Bits = nullptr;
       Capacity = 0;
       return;
     }

     Capacity = NumBitWords(RHS.size());
     Bits = (BitWord *)std::malloc(Capacity * sizeof(BitWord));
     std::memcpy(Bits, RHS.Bits, Capacity * sizeof(BitWord));
   }

   BitVector(BitVector &&RHS)
     : Bits(RHS.Bits), Size(RHS.Size), Capacity(RHS.Capacity) {
     RHS.Bits = nullptr;
   }

   ~BitVector() {
     std::free(Bits);
   }

   /// empty - Tests whether there are no bits in this bitvector.
   bool empty() const { return Size == 0; }

   /// size - Returns the number of bits in this bitvector.
   size_type size() const { return Size; }

   /// count - Returns the number of bits which are set.
   size_type count() const {
     unsigned NumBits = 0;
     for (unsigned i = 0; i < NumBitWords(size()); ++i)
       NumBits += countPopulation(Bits[i]);
     return NumBits;
   }

   /// any - Returns true if any bit is set.
   bool any() const {
     for (unsigned i = 0; i < NumBitWords(size()); ++i)
       if (Bits[i] != 0)
         return true;
     return false;
   }

   /// all - Returns true if all bits are set.
   bool all() const {
     for (unsigned i = 0; i < Size / BITWORD_SIZE; ++i)
       if (Bits[i] != ~0UL)
         return false;

     // If bits remain check that they are ones. The unused bits are always zero.
     if (unsigned Remainder = Size % BITWORD_SIZE)
       return Bits[Size / BITWORD_SIZE] == (1UL << Remainder) - 1;

     return true;
   }

   /// none - Returns true if none of the bits are set.
   bool none() const {
     return !any();
   }

   /// find_first - Returns the index of the first set bit, -1 if none
   /// of the bits are set.
   int find_first() const {
     for (unsigned i = 0; i < NumBitWords(size()); ++i)
       if (Bits[i] != 0)
         return i * BITWORD_SIZE + countTrailingZeros(Bits[i]);
     return -1;
   }

   /// find_next - Returns the index of the next set bit following the
   /// "Prev" bit. Returns -1 if the next set bit is not found.
   int find_next(unsigned Prev) const {
     ++Prev;
     if (Prev >= Size)
       return -1;

     unsigned WordPos = Prev / BITWORD_SIZE;
     unsigned BitPos = Prev % BITWORD_SIZE;
     BitWord Copy = Bits[WordPos];
     // Mask off previous bits.
     Copy &= ~0UL << BitPos;

     if (Copy != 0)
       return WordPos * BITWORD_SIZE + countTrailingZeros(Copy);

     // Check subsequent words.
     for (unsigned i = WordPos+1; i < NumBitWords(size()); ++i)
       if (Bits[i] != 0)
         return i * BITWORD_SIZE + countTrailingZeros(Bits[i]);
     return -1;
   }

   /// clear - Clear all bits.
   void clear() {
     Size = 0;
   }

   /// resize - Grow or shrink the bitvector.
   void resize(unsigned N, bool t = false) {
     if (N > Capacity * BITWORD_SIZE) {
       unsigned OldCapacity = Capacity;
       grow(N);
       init_words(&Bits[OldCapacity], (Capacity-OldCapacity), t);
     }

     // Set any old unused bits that are now included in the BitVector. This
     // may set bits that are not included in the new vector, but we will clear
     // them back out below.
     if (N > Size)
       set_unused_bits(t);

     // Update the size, and clear out any bits that are now unused
     unsigned OldSize = Size;
     Size = N;
     if (t || N < OldSize)
       clear_unused_bits();
   }

   void reserve(unsigned N) {
     if (N > Capacity * BITWORD_SIZE)
       grow(N);
   }

   // Set, reset, flip
   BitVector &set() {
     init_words(Bits, Capacity, true);
     clear_unused_bits();
     return *this;
   }

   BitVector &set(unsigned Idx) {
     assert(Bits && "Bits never allocated");
     Bits[Idx / BITWORD_SIZE] |= BitWord(1) << (Idx % BITWORD_SIZE);
     return *this;
   }

   /// set - Efficiently set a range of bits in [I, E)
   BitVector &set(unsigned I, unsigned E) {
     assert(I <= E && "Attempted to set backwards range!");
     assert(E <= size() && "Attempted to set out-of-bounds range!");

     if (I == E) return *this;

     if (I / BITWORD_SIZE == E / BITWORD_SIZE) {
       BitWord EMask = 1UL << (E % BITWORD_SIZE);
       BitWord IMask = 1UL << (I % BITWORD_SIZE);
       BitWord Mask = EMask - IMask;
       Bits[I / BITWORD_SIZE] |= Mask;
       return *this;
     }

     BitWord PrefixMask = ~0UL << (I % BITWORD_SIZE);
     Bits[I / BITWORD_SIZE] |= PrefixMask;
     I = RoundUpToAlignment(I, BITWORD_SIZE);

     for (; I + BITWORD_SIZE <= E; I += BITWORD_SIZE)
       Bits[I / BITWORD_SIZE] = ~0UL;

     BitWord PostfixMask = (1UL << (E % BITWORD_SIZE)) - 1;
     if (I < E)
       Bits[I / BITWORD_SIZE] |= PostfixMask;

     return *this;
   }

   BitVector &reset() {
     init_words(Bits, Capacity, false);
     return *this;
   }

   BitVector &reset(unsigned Idx) {
     Bits[Idx / BITWORD_SIZE] &= ~(BitWord(1) << (Idx % BITWORD_SIZE));
     return *this;
   }

   /// reset - Efficiently reset a range of bits in [I, E)
   BitVector &reset(unsigned I, unsigned E) {
     assert(I <= E && "Attempted to reset backwards range!");
     assert(E <= size() && "Attempted to reset out-of-bounds range!");

     if (I == E) return *this;

     if (I / BITWORD_SIZE == E / BITWORD_SIZE) {
       BitWord EMask = 1UL << (E % BITWORD_SIZE);
       BitWord IMask = 1UL << (I % BITWORD_SIZE);
       BitWord Mask = EMask - IMask;
       Bits[I / BITWORD_SIZE] &= ~Mask;
       return *this;
     }

     BitWord PrefixMask = ~0UL << (I % BITWORD_SIZE);
     Bits[I / BITWORD_SIZE] &= ~PrefixMask;
     I = RoundUpToAlignment(I, BITWORD_SIZE);

     for (; I + BITWORD_SIZE <= E; I += BITWORD_SIZE)
       Bits[I / BITWORD_SIZE] = 0UL;

     BitWord PostfixMask = (1UL << (E % BITWORD_SIZE)) - 1;
     if (I < E)
       Bits[I / BITWORD_SIZE] &= ~PostfixMask;

     return *this;
   }

   BitVector &flip() {
     for (unsigned i = 0; i < NumBitWords(size()); ++i)
       Bits[i] = ~Bits[i];
     clear_unused_bits();
     return *this;
   }

   BitVector &flip(unsigned Idx) {
     Bits[Idx / BITWORD_SIZE] ^= BitWord(1) << (Idx % BITWORD_SIZE);
     return *this;
   }

   // Indexing.
   reference operator[](unsigned Idx) {
     assert (Idx < Size && "Out-of-bounds Bit access.");
     return reference(*this, Idx);
   }

   bool operator[](unsigned Idx) const {
     assert (Idx < Size && "Out-of-bounds Bit access.");
     BitWord Mask = BitWord(1) << (Idx % BITWORD_SIZE);
     return (Bits[Idx / BITWORD_SIZE] & Mask) != 0;
   }

   bool test(unsigned Idx) const {
     return (*this)[Idx];
   }

   /// Test if any common bits are set.
   bool anyCommon(const BitVector &RHS) const {
     unsigned ThisWords = NumBitWords(size());
     unsigned RHSWords  = NumBitWords(RHS.size());
     for (unsigned i = 0, e = std::min(ThisWords, RHSWords); i != e; ++i)
       if (Bits[i] & RHS.Bits[i])
         return true;
     return false;
   }

   // Comparison operators.
   bool operator==(const BitVector &RHS) const {
     unsigned ThisWords = NumBitWords(size());
     unsigned RHSWords  = NumBitWords(RHS.size());
     unsigned i;
     for (i = 0; i != std::min(ThisWords, RHSWords); ++i)
       if (Bits[i] != RHS.Bits[i])
         return false;

     // Verify that any extra words are all zeros.
     if (i != ThisWords) {
       for (; i != ThisWords; ++i)
         if (Bits[i])
           return false;
     } else if (i != RHSWords) {
       for (; i != RHSWords; ++i)
         if (RHS.Bits[i])
           return false;
     }
     return true;
   }

   bool operator!=(const BitVector &RHS) const {
     return !(*this == RHS);
   }

   /// Intersection, union, disjoint union.
   BitVector &operator&=(const BitVector &RHS) {
     unsigned ThisWords = NumBitWords(size());
     unsigned RHSWords  = NumBitWords(RHS.size());
     unsigned i;
     for (i = 0; i != std::min(ThisWords, RHSWords); ++i)
       Bits[i] &= RHS.Bits[i];

     // Any bits that are just in this bitvector become zero, because they aren't
     // in the RHS bit vector.  Any words only in RHS are ignored because they
     // are already zero in the LHS.
     for (; i != ThisWords; ++i)
       Bits[i] = 0;

     return *this;
   }

   /// reset - Reset bits that are set in RHS. Same as *this &= ~RHS.
   BitVector &reset(const BitVector &RHS) {
     unsigned ThisWords = NumBitWords(size());
     unsigned RHSWords  = NumBitWords(RHS.size());
     unsigned i;
     for (i = 0; i != std::min(ThisWords, RHSWords); ++i)
       Bits[i] &= ~RHS.Bits[i];
     return *this;
   }

   /// test - Check if (This - RHS) is zero.
   /// This is the same as reset(RHS) and any().
   bool test(const BitVector &RHS) const {
     unsigned ThisWords = NumBitWords(size());
     unsigned RHSWords  = NumBitWords(RHS.size());
     unsigned i;
     for (i = 0; i != std::min(ThisWords, RHSWords); ++i)
       if ((Bits[i] & ~RHS.Bits[i]) != 0)
         return true;

     for (; i != ThisWords ; ++i)
       if (Bits[i] != 0)
         return true;

     return false;
   }

   BitVector &operator|=(const BitVector &RHS) {
     if (size() < RHS.size())
       resize(RHS.size());
     for (size_t i = 0, e = NumBitWords(RHS.size()); i != e; ++i)
       Bits[i] |= RHS.Bits[i];
     return *this;
   }

   BitVector &operator^=(const BitVector &RHS) {
     if (size() < RHS.size())
       resize(RHS.size());
     for (size_t i = 0, e = NumBitWords(RHS.size()); i != e; ++i)
       Bits[i] ^= RHS.Bits[i];
     return *this;
   }

   // Assignment operator.
   const BitVector &operator=(const BitVector &RHS) {
     if (this == &RHS) return *this;

     Size = RHS.size();
     unsigned RHSWords = NumBitWords(Size);
     if (Size <= Capacity * BITWORD_SIZE) {
       if (Size)
         std::memcpy(Bits, RHS.Bits, RHSWords * sizeof(BitWord));
       clear_unused_bits();
       return *this;
     }

     // Grow the bitvector to have enough elements.
     Capacity = RHSWords;
     assert(Capacity > 0 && "negative capacity?");
     BitWord *NewBits = (BitWord *)std::malloc(Capacity * sizeof(BitWord));
     std::memcpy(NewBits, RHS.Bits, Capacity * sizeof(BitWord));

     // Destroy the old bits.
     std::free(Bits);
     Bits = NewBits;

     return *this;
   }

   const BitVector &operator=(BitVector &&RHS) {
     if (this == &RHS) return *this;

     std::free(Bits);
     Bits = RHS.Bits;
     Size = RHS.Size;
     Capacity = RHS.Capacity;

     RHS.Bits = nullptr;

     return *this;
   }

   void swap(BitVector &RHS) {
     std::swap(Bits, RHS.Bits);
     std::swap(Size, RHS.Size);
     std::swap(Capacity, RHS.Capacity);
   }

   //===--------------------------------------------------------------------===//
   // Portable bit mask operations.
   //===--------------------------------------------------------------------===//
   //
   // These methods all operate on arrays of uint32_t, each holding 32 bits. The
   // fixed word size makes it easier to work with literal bit vector constants
   // in portable code.
   //
   // The LSB in each word is the lowest numbered bit.  The size of a portable
   // bit mask is always a whole multiple of 32 bits.  If no bit mask size is
   // given, the bit mask is assumed to cover the entire BitVector.

   /// setBitsInMask - Add '1' bits from Mask to this vector. Don't resize.
   /// This computes "*this |= Mask".
   void setBitsInMask(const uint32_t *Mask, unsigned MaskWords = ~0u) {
     applyMask<true, false>(Mask, MaskWords);
   }

   /// clearBitsInMask - Clear any bits in this vector that are set in Mask.
   /// Don't resize. This computes "*this &= ~Mask".
   void clearBitsInMask(const uint32_t *Mask, unsigned MaskWords = ~0u) {
     applyMask<false, false>(Mask, MaskWords);
   }

   /// setBitsNotInMask - Add a bit to this vector for every '0' bit in Mask.
   /// Don't resize.  This computes "*this |= ~Mask".
   void setBitsNotInMask(const uint32_t *Mask, unsigned MaskWords = ~0u) {
     applyMask<true, true>(Mask, MaskWords);
   }

   /// clearBitsNotInMask - Clear a bit in this vector for every '0' bit in Mask.
   /// Don't resize.  This computes "*this &= Mask".
   void clearBitsNotInMask(const uint32_t *Mask, unsigned MaskWords = ~0u) {
     applyMask<false, true>(Mask, MaskWords);
   }

 private:
   unsigned NumBitWords(unsigned S) const {
     return (S + BITWORD_SIZE-1) / BITWORD_SIZE;
   }

   // Set the unused bits in the high words.
   void set_unused_bits(bool t = true) {
     //  Set high words first.
     unsigned UsedWords = NumBitWords(Size);
     if (Capacity > UsedWords)
       init_words(&Bits[UsedWords], (Capacity-UsedWords), t);

     //  Then set any stray high bits of the last used word.
     unsigned ExtraBits = Size % BITWORD_SIZE;
     if (ExtraBits) {
       BitWord ExtraBitMask = ~0UL << ExtraBits;
       if (t)
         Bits[UsedWords-1] |= ExtraBitMask;
       else
         Bits[UsedWords-1] &= ~ExtraBitMask;
     }
   }

   // Clear the unused bits in the high words.
   void clear_unused_bits() {
     set_unused_bits(false);
   }

   void grow(unsigned NewSize) {
     Capacity = std::max(NumBitWords(NewSize), Capacity * 2);
     assert(Capacity > 0 && "realloc-ing zero space");
     Bits = (BitWord *)std::realloc(Bits, Capacity * sizeof(BitWord));

     clear_unused_bits();
   }

   void init_words(BitWord *B, unsigned NumWords, bool t) {
     memset(B, 0 - (int)t, NumWords*sizeof(BitWord));
   }

   template<bool AddBits, bool InvertMask>
   void applyMask(const uint32_t *Mask, unsigned MaskWords) {
     static_assert(BITWORD_SIZE % 32 == 0, "Unsupported BitWord size.");
     MaskWords = std::min(MaskWords, (size() + 31) / 32);
     const unsigned Scale = BITWORD_SIZE / 32;
     unsigned i;
     for (i = 0; MaskWords >= Scale; ++i, MaskWords -= Scale) {
       BitWord BW = Bits[i];
       // This inner loop should unroll completely when BITWORD_SIZE > 32.
       for (unsigned b = 0; b != BITWORD_SIZE; b += 32) {
         uint32_t M = *Mask++;
         if (InvertMask) M = ~M;
         if (AddBits) BW |=   BitWord(M) << b;
         else         BW &= ~(BitWord(M) << b);
       }
       Bits[i] = BW;
     }
     for (unsigned b = 0; MaskWords; b += 32, --MaskWords) {
       uint32_t M = *Mask++;
       if (InvertMask) M = ~M;
       if (AddBits) Bits[i] |=   BitWord(M) << b;
       else         Bits[i] &= ~(BitWord(M) << b);
     }
     if (AddBits)
       clear_unused_bits();
   }
 };

 } // End llvm namespace

 namespace std {
   /// Implement std::swap in terms of BitVector swap.
   inline void
   swap(llvm::BitVector &LHS, llvm::BitVector &RHS) {
     LHS.swap(RHS);
   }
 }

 #endif
	//===- llvm/ADT/BitVector.h - Bit vectors ------------------------ C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file implements the BitVector class.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_ADT_BITVECTOR_H
	#define LLVM_ADT_BITVECTOR_H

	#include "llvm/Support/Compiler.h"
	#include "llvm/Support/ErrorHandling.h"
	#include "llvm/Support/MathExtras.h"
	#include <algorithm>
	#include <cassert>
	#include <climits>
	#include <cstdlib>

	namespace llvm {

	class BitVector {
	typedef unsigned long BitWord;

	enum { BITWORD_SIZE = (unsigned)sizeof(BitWord) * CHAR_BIT };

	static_assert(BITWORD_SIZE == 64 \|\| BITWORD_SIZE == 32,
	"Unsupported word size");

	BitWord *Bits; // Actual bits.
	unsigned Size; // Size of bitvector in bits.
	unsigned Capacity; // Size of allocated memory in BitWord.

	public:
	typedef unsigned size_type;
	// Encapsulation of a single bit.
	class reference {
	friend class BitVector;

	BitWord *WordRef;
	unsigned BitPos;

	reference(); // Undefined

	public:
	reference(BitVector &b, unsigned Idx) {
	WordRef = &b.Bits[Idx / BITWORD_SIZE];
	BitPos = Idx % BITWORD_SIZE;
	}

	reference(const reference&) = default;

	reference &operator=(reference t) {
	*this = bool(t);
	return *this;
	}

	reference& operator=(bool t) {
	if (t)
	*WordRef \|= BitWord(1) << BitPos;
	else
	*WordRef &= ~(BitWord(1) << BitPos);
	return *this;
	}

	operator bool() const {
	return ((*WordRef) & (BitWord(1) << BitPos)) ? true : false;
	}
	};


	/// BitVector default ctor - Creates an empty bitvector.
	BitVector() : Size(0), Capacity(0) {
	Bits = nullptr;
	}

	/// BitVector ctor - Creates a bitvector of specified number of bits. All
	/// bits are initialized to the specified value.
	explicit BitVector(unsigned s, bool t = false) : Size(s) {
	Capacity = NumBitWords(s);
	Bits = (BitWord )std::malloc(Capacity sizeof(BitWord));
	init_words(Bits, Capacity, t);
	if (t)
	clear_unused_bits();
	}

	/// BitVector copy ctor.
	BitVector(const BitVector &RHS) : Size(RHS.size()) {
	if (Size == 0) {
	Bits = nullptr;
	Capacity = 0;
	return;
	}

	Capacity = NumBitWords(RHS.size());
	Bits = (BitWord )std::malloc(Capacity sizeof(BitWord));
	std::memcpy(Bits, RHS.Bits, Capacity * sizeof(BitWord));
	}

	BitVector(BitVector &&RHS)
	: Bits(RHS.Bits), Size(RHS.Size), Capacity(RHS.Capacity) {
	RHS.Bits = nullptr;
	}

	~BitVector() {
	std::free(Bits);
	}

	/// empty - Tests whether there are no bits in this bitvector.
	bool empty() const { return Size == 0; }

	/// size - Returns the number of bits in this bitvector.
	size_type size() const { return Size; }

	/// count - Returns the number of bits which are set.
	size_type count() const {
	unsigned NumBits = 0;
	for (unsigned i = 0; i < NumBitWords(size()); ++i)
	NumBits += countPopulation(Bits[i]);
	return NumBits;
	}

	/// any - Returns true if any bit is set.
	bool any() const {
	for (unsigned i = 0; i < NumBitWords(size()); ++i)
	if (Bits[i] != 0)
	return true;
	return false;
	}

	/// all - Returns true if all bits are set.
	bool all() const {
	for (unsigned i = 0; i < Size / BITWORD_SIZE; ++i)
	if (Bits[i] != ~0UL)
	return false;

	// If bits remain check that they are ones. The unused bits are always zero.
	if (unsigned Remainder = Size % BITWORD_SIZE)
	return Bits[Size / BITWORD_SIZE] == (1UL << Remainder) - 1;

	return true;
	}

	/// none - Returns true if none of the bits are set.
	bool none() const {
	return !any();
	}

	/// find_first - Returns the index of the first set bit, -1 if none
	/// of the bits are set.
	int find_first() const {
	for (unsigned i = 0; i < NumBitWords(size()); ++i)
	if (Bits[i] != 0)
	return i * BITWORD_SIZE + countTrailingZeros(Bits[i]);
	return -1;
	}

	/// find_next - Returns the index of the next set bit following the
	/// "Prev" bit. Returns -1 if the next set bit is not found.
	int find_next(unsigned Prev) const {
	++Prev;
	if (Prev >= Size)
	return -1;

	unsigned WordPos = Prev / BITWORD_SIZE;
	unsigned BitPos = Prev % BITWORD_SIZE;
	BitWord Copy = Bits[WordPos];
	// Mask off previous bits.
	Copy &= ~0UL << BitPos;

	if (Copy != 0)
	return WordPos * BITWORD_SIZE + countTrailingZeros(Copy);

	// Check subsequent words.
	for (unsigned i = WordPos+1; i < NumBitWords(size()); ++i)
	if (Bits[i] != 0)
	return i * BITWORD_SIZE + countTrailingZeros(Bits[i]);
	return -1;
	}

	/// clear - Clear all bits.
	void clear() {
	Size = 0;
	}

	/// resize - Grow or shrink the bitvector.
	void resize(unsigned N, bool t = false) {
	if (N > Capacity * BITWORD_SIZE) {
	unsigned OldCapacity = Capacity;
	grow(N);
	init_words(&Bits[OldCapacity], (Capacity-OldCapacity), t);
	}

	// Set any old unused bits that are now included in the BitVector. This
	// may set bits that are not included in the new vector, but we will clear
	// them back out below.
	if (N > Size)
	set_unused_bits(t);

	// Update the size, and clear out any bits that are now unused
	unsigned OldSize = Size;
	Size = N;
	if (t \|\| N < OldSize)
	clear_unused_bits();
	}

	void reserve(unsigned N) {
	if (N > Capacity * BITWORD_SIZE)
	grow(N);
	}

	// Set, reset, flip
	BitVector &set() {
	init_words(Bits, Capacity, true);
	clear_unused_bits();
	return *this;
	}

	BitVector &set(unsigned Idx) {
	assert(Bits && "Bits never allocated");
	Bits[Idx / BITWORD_SIZE] \|= BitWord(1) << (Idx % BITWORD_SIZE);
	return *this;
	}

	/// set - Efficiently set a range of bits in [I, E)
	BitVector &set(unsigned I, unsigned E) {
	assert(I <= E && "Attempted to set backwards range!");
	assert(E <= size() && "Attempted to set out-of-bounds range!");

	if (I == E) return *this;

	if (I / BITWORD_SIZE == E / BITWORD_SIZE) {
	BitWord EMask = 1UL << (E % BITWORD_SIZE);
	BitWord IMask = 1UL << (I % BITWORD_SIZE);
	BitWord Mask = EMask - IMask;
	Bits[I / BITWORD_SIZE] \|= Mask;
	return *this;
	}

	BitWord PrefixMask = ~0UL << (I % BITWORD_SIZE);
	Bits[I / BITWORD_SIZE] \|= PrefixMask;
	I = RoundUpToAlignment(I, BITWORD_SIZE);

	for (; I + BITWORD_SIZE <= E; I += BITWORD_SIZE)
	Bits[I / BITWORD_SIZE] = ~0UL;

	BitWord PostfixMask = (1UL << (E % BITWORD_SIZE)) - 1;
	if (I < E)
	Bits[I / BITWORD_SIZE] \|= PostfixMask;

	return *this;
	}

	BitVector &reset() {
	init_words(Bits, Capacity, false);
	return *this;
	}

	BitVector &reset(unsigned Idx) {
	Bits[Idx / BITWORD_SIZE] &= ~(BitWord(1) << (Idx % BITWORD_SIZE));
	return *this;
	}

	/// reset - Efficiently reset a range of bits in [I, E)
	BitVector &reset(unsigned I, unsigned E) {
	assert(I <= E && "Attempted to reset backwards range!");
	assert(E <= size() && "Attempted to reset out-of-bounds range!");

	if (I == E) return *this;

	if (I / BITWORD_SIZE == E / BITWORD_SIZE) {
	BitWord EMask = 1UL << (E % BITWORD_SIZE);
	BitWord IMask = 1UL << (I % BITWORD_SIZE);
	BitWord Mask = EMask - IMask;
	Bits[I / BITWORD_SIZE] &= ~Mask;
	return *this;
	}

	BitWord PrefixMask = ~0UL << (I % BITWORD_SIZE);
	Bits[I / BITWORD_SIZE] &= ~PrefixMask;
	I = RoundUpToAlignment(I, BITWORD_SIZE);

	for (; I + BITWORD_SIZE <= E; I += BITWORD_SIZE)
	Bits[I / BITWORD_SIZE] = 0UL;

	BitWord PostfixMask = (1UL << (E % BITWORD_SIZE)) - 1;
	if (I < E)
	Bits[I / BITWORD_SIZE] &= ~PostfixMask;

	return *this;
	}

	BitVector &flip() {
	for (unsigned i = 0; i < NumBitWords(size()); ++i)
	Bits[i] = ~Bits[i];
	clear_unused_bits();
	return *this;
	}

	BitVector &flip(unsigned Idx) {
	Bits[Idx / BITWORD_SIZE] ^= BitWord(1) << (Idx % BITWORD_SIZE);
	return *this;
	}

	// Indexing.
	reference operator[](unsigned Idx) {
	assert (Idx < Size && "Out-of-bounds Bit access.");
	return reference(*this, Idx);
	}

	bool operator[](unsigned Idx) const {
	assert (Idx < Size && "Out-of-bounds Bit access.");
	BitWord Mask = BitWord(1) << (Idx % BITWORD_SIZE);
	return (Bits[Idx / BITWORD_SIZE] & Mask) != 0;
	}

	bool test(unsigned Idx) const {
	return (*this)[Idx];
	}

	/// Test if any common bits are set.
	bool anyCommon(const BitVector &RHS) const {
	unsigned ThisWords = NumBitWords(size());
	unsigned RHSWords = NumBitWords(RHS.size());
	for (unsigned i = 0, e = std::min(ThisWords, RHSWords); i != e; ++i)
	if (Bits[i] & RHS.Bits[i])
	return true;
	return false;
	}

	// Comparison operators.
	bool operator==(const BitVector &RHS) const {
	unsigned ThisWords = NumBitWords(size());
	unsigned RHSWords = NumBitWords(RHS.size());
	unsigned i;
	for (i = 0; i != std::min(ThisWords, RHSWords); ++i)
	if (Bits[i] != RHS.Bits[i])
	return false;

	// Verify that any extra words are all zeros.
	if (i != ThisWords) {
	for (; i != ThisWords; ++i)
	if (Bits[i])
	return false;
	} else if (i != RHSWords) {
	for (; i != RHSWords; ++i)
	if (RHS.Bits[i])
	return false;
	}
	return true;
	}

	bool operator!=(const BitVector &RHS) const {
	return !(*this == RHS);
	}

	/// Intersection, union, disjoint union.
	BitVector &operator&=(const BitVector &RHS) {
	unsigned ThisWords = NumBitWords(size());
	unsigned RHSWords = NumBitWords(RHS.size());
	unsigned i;
	for (i = 0; i != std::min(ThisWords, RHSWords); ++i)
	Bits[i] &= RHS.Bits[i];

	// Any bits that are just in this bitvector become zero, because they aren't
	// in the RHS bit vector. Any words only in RHS are ignored because they
	// are already zero in the LHS.
	for (; i != ThisWords; ++i)
	Bits[i] = 0;

	return *this;
	}

	/// reset - Reset bits that are set in RHS. Same as *this &= ~RHS.
	BitVector &reset(const BitVector &RHS) {
	unsigned ThisWords = NumBitWords(size());
	unsigned RHSWords = NumBitWords(RHS.size());
	unsigned i;
	for (i = 0; i != std::min(ThisWords, RHSWords); ++i)
	Bits[i] &= ~RHS.Bits[i];
	return *this;
	}

	/// test - Check if (This - RHS) is zero.
	/// This is the same as reset(RHS) and any().
	bool test(const BitVector &RHS) const {
	unsigned ThisWords = NumBitWords(size());
	unsigned RHSWords = NumBitWords(RHS.size());
	unsigned i;
	for (i = 0; i != std::min(ThisWords, RHSWords); ++i)
	if ((Bits[i] & ~RHS.Bits[i]) != 0)
	return true;

	for (; i != ThisWords ; ++i)
	if (Bits[i] != 0)
	return true;

	return false;
	}

	BitVector &operator\|=(const BitVector &RHS) {
	if (size() < RHS.size())
	resize(RHS.size());
	for (size_t i = 0, e = NumBitWords(RHS.size()); i != e; ++i)
	Bits[i] \|= RHS.Bits[i];
	return *this;
	}

	BitVector &operator^=(const BitVector &RHS) {
	if (size() < RHS.size())
	resize(RHS.size());
	for (size_t i = 0, e = NumBitWords(RHS.size()); i != e; ++i)
	Bits[i] ^= RHS.Bits[i];
	return *this;
	}

	// Assignment operator.
	const BitVector &operator=(const BitVector &RHS) {
	if (this == &RHS) return *this;

	Size = RHS.size();
	unsigned RHSWords = NumBitWords(Size);
	if (Size <= Capacity * BITWORD_SIZE) {
	if (Size)
	std::memcpy(Bits, RHS.Bits, RHSWords * sizeof(BitWord));
	clear_unused_bits();
	return *this;
	}

	// Grow the bitvector to have enough elements.
	Capacity = RHSWords;
	assert(Capacity > 0 && "negative capacity?");
	BitWord NewBits = (BitWord )std::malloc(Capacity * sizeof(BitWord));
	std::memcpy(NewBits, RHS.Bits, Capacity * sizeof(BitWord));

	// Destroy the old bits.
	std::free(Bits);
	Bits = NewBits;

	return *this;
	}

	const BitVector &operator=(BitVector &&RHS) {
	if (this == &RHS) return *this;

	std::free(Bits);
	Bits = RHS.Bits;
	Size = RHS.Size;
	Capacity = RHS.Capacity;

	RHS.Bits = nullptr;

	return *this;
	}

	void swap(BitVector &RHS) {
	std::swap(Bits, RHS.Bits);
	std::swap(Size, RHS.Size);
	std::swap(Capacity, RHS.Capacity);
	}

	//===--------------------------------------------------------------------===//
	// Portable bit mask operations.
	//===--------------------------------------------------------------------===//
	//
	// These methods all operate on arrays of uint32_t, each holding 32 bits. The
	// fixed word size makes it easier to work with literal bit vector constants
	// in portable code.
	//
	// The LSB in each word is the lowest numbered bit. The size of a portable
	// bit mask is always a whole multiple of 32 bits. If no bit mask size is
	// given, the bit mask is assumed to cover the entire BitVector.

	/// setBitsInMask - Add '1' bits from Mask to this vector. Don't resize.
	/// This computes "*this \|= Mask".
	void setBitsInMask(const uint32_t *Mask, unsigned MaskWords = ~0u) {
	applyMask<true, false>(Mask, MaskWords);
	}

	/// clearBitsInMask - Clear any bits in this vector that are set in Mask.
	/// Don't resize. This computes "*this &= ~Mask".
	void clearBitsInMask(const uint32_t *Mask, unsigned MaskWords = ~0u) {
	applyMask<false, false>(Mask, MaskWords);
	}

	/// setBitsNotInMask - Add a bit to this vector for every '0' bit in Mask.
	/// Don't resize. This computes "*this \|= ~Mask".
	void setBitsNotInMask(const uint32_t *Mask, unsigned MaskWords = ~0u) {
	applyMask<true, true>(Mask, MaskWords);
	}

	/// clearBitsNotInMask - Clear a bit in this vector for every '0' bit in Mask.
	/// Don't resize. This computes "*this &= Mask".
	void clearBitsNotInMask(const uint32_t *Mask, unsigned MaskWords = ~0u) {
	applyMask<false, true>(Mask, MaskWords);
	}

	private:
	unsigned NumBitWords(unsigned S) const {
	return (S + BITWORD_SIZE-1) / BITWORD_SIZE;
	}

	// Set the unused bits in the high words.
	void set_unused_bits(bool t = true) {
	// Set high words first.
	unsigned UsedWords = NumBitWords(Size);
	if (Capacity > UsedWords)
	init_words(&Bits[UsedWords], (Capacity-UsedWords), t);

	// Then set any stray high bits of the last used word.
	unsigned ExtraBits = Size % BITWORD_SIZE;
	if (ExtraBits) {
	BitWord ExtraBitMask = ~0UL << ExtraBits;
	if (t)
	Bits[UsedWords-1] \|= ExtraBitMask;
	else
	Bits[UsedWords-1] &= ~ExtraBitMask;
	}
	}

	// Clear the unused bits in the high words.
	void clear_unused_bits() {
	set_unused_bits(false);
	}

	void grow(unsigned NewSize) {
	Capacity = std::max(NumBitWords(NewSize), Capacity * 2);
	assert(Capacity > 0 && "realloc-ing zero space");
	Bits = (BitWord )std::realloc(Bits, Capacity sizeof(BitWord));

	clear_unused_bits();
	}

	void init_words(BitWord *B, unsigned NumWords, bool t) {
	memset(B, 0 - (int)t, NumWords*sizeof(BitWord));
	}

	template<bool AddBits, bool InvertMask>
	void applyMask(const uint32_t *Mask, unsigned MaskWords) {
	static_assert(BITWORD_SIZE % 32 == 0, "Unsupported BitWord size.");
	MaskWords = std::min(MaskWords, (size() + 31) / 32);
	const unsigned Scale = BITWORD_SIZE / 32;
	unsigned i;
	for (i = 0; MaskWords >= Scale; ++i, MaskWords -= Scale) {
	BitWord BW = Bits[i];
	// This inner loop should unroll completely when BITWORD_SIZE > 32.
	for (unsigned b = 0; b != BITWORD_SIZE; b += 32) {
	uint32_t M = *Mask++;
	if (InvertMask) M = ~M;
	if (AddBits) BW \|= BitWord(M) << b;
	else BW &= ~(BitWord(M) << b);
	}
	Bits[i] = BW;
	}
	for (unsigned b = 0; MaskWords; b += 32, --MaskWords) {
	uint32_t M = *Mask++;
	if (InvertMask) M = ~M;
	if (AddBits) Bits[i] \|= BitWord(M) << b;
	else Bits[i] &= ~(BitWord(M) << b);
	}
	if (AddBits)
	clear_unused_bits();
	}
	};

	} // End llvm namespace

	namespace std {
	/// Implement std::swap in terms of BitVector swap.
	inline void
	swap(llvm::BitVector &LHS, llvm::BitVector &RHS) {
	LHS.swap(RHS);
	}
	}

	#endif