reference, declarationdefinition
definition → references, declarations, derived classes, virtual overrides
reference to multiple definitions → definitions
unreferenced
    1
    2
    3
    4
    5
    6
    7
    8
    9
   10
   11
   12
   13
   14
   15
   16
   17
   18
   19
   20
   21
   22
   23
   24
   25
   26
   27
   28
   29
   30
   31
   32
   33
   34
   35
   36
   37
   38
   39
   40
   41
   42
   43
   44
   45
   46
   47
   48
   49
   50
   51
   52
   53
   54
   55
   56
   57
   58
   59
   60
   61
   62
   63
   64
   65
   66
   67
   68
   69
   70
   71
   72
   73
   74
   75
   76
   77
   78
   79
   80
   81
   82
   83
   84
   85
   86
   87
   88
   89
   90
   91
   92
   93
   94
   95
   96
   97
   98
   99
  100
  101
  102
  103
  104
  105
  106
  107
  108
  109
  110
  111
  112
  113
  114
  115
  116
  117
  118
  119
  120
  121
  122
  123
  124
  125
  126
  127
  128
  129
  130
  131
  132
  133
  134
  135
  136
  137
  138
  139
  140
  141
  142
  143
  144
  145
  146
  147
  148
  149
  150
  151
  152
  153
  154
  155
  156
  157
  158
  159
  160
  161
  162
  163
  164
  165
  166
  167
  168
  169
  170
  171
  172
  173
  174
  175
  176
  177
  178
  179
  180
  181
  182
  183
  184
  185
  186
  187
  188
  189
  190
  191
  192
  193
  194
  195
  196
  197
  198
  199
  200
  201
  202
  203
  204
  205
  206
  207
  208
  209
  210
  211
  212
  213
  214
  215
  216
  217
  218
  219
  220
  221
  222
  223
  224
  225
  226
  227
  228
  229
  230
  231
  232
  233
  234
  235
  236
  237
  238
  239
  240
  241
  242
  243
  244
  245
  246
  247
  248
  249
  250
  251
  252
  253
  254
  255
  256
  257
  258
  259
  260
  261
  262
  263
  264
  265
  266
  267
  268
  269
  270
  271
  272
  273
  274
  275
  276
  277
  278
  279
  280
  281
  282
  283
  284
  285
  286
  287
  288
  289
  290
  291
  292
  293
  294
  295
  296
  297
  298
  299
  300
  301
  302
  303
  304
  305
  306
  307
  308
  309
  310
  311
  312
  313
  314
  315
  316
  317
  318
  319
  320
  321
  322
  323
  324
  325
  326
  327
  328
  329
  330
  331
  332
  333
  334
  335
  336
  337
  338
  339
  340
  341
  342
  343
  344
  345
  346
  347
  348
  349
  350
  351
  352
  353
  354
  355
  356
  357
  358
  359
  360
  361
  362
  363
  364
  365
  366
  367
  368
  369
  370
  371
  372
  373
  374
  375
  376
  377
  378
  379
  380
  381
  382
  383
  384
  385
  386
  387
  388
  389
  390
  391
  392
  393
  394
  395
  396
  397
  398
  399
  400
  401
  402
  403
  404
  405
  406
  407
  408
  409
  410
  411
  412
  413
  414
  415
  416
  417
  418
  419
  420
  421
  422
  423
  424
  425
  426
  427
  428
  429
  430
  431
  432
  433
  434
  435
  436
  437
  438
  439
  440
  441
  442
  443
  444
  445
  446
  447
  448
  449
  450
  451
  452
  453
  454
  455
  456
  457
  458
  459
  460
  461
  462
  463
  464
  465
  466
  467
  468
  469
  470
  471
  472
  473
  474
  475
  476
  477
  478
  479
  480
  481
  482
  483
  484
  485
  486
  487
  488
  489
  490
  491
  492
  493
  494
  495
  496
  497
  498
  499
  500
  501
  502
  503
  504
  505
  506
  507
  508
  509
  510
  511
  512
  513
  514
  515
  516
  517
  518
  519
  520
  521
  522
  523
  524
  525
  526
  527
  528
  529
  530
  531
  532
  533
  534
  535
  536
  537
  538
  539
  540
  541
  542
  543
  544
  545
  546
  547
  548
  549
  550
  551
  552
  553
  554
  555
  556
  557
  558
  559
  560
  561
  562
  563
  564
  565
  566
  567
  568
  569
  570
  571
  572
  573
  574
  575
  576
  577
  578
  579
  580
  581
  582
  583
  584
  585
  586
  587
  588
  589
  590
  591
  592
  593
  594
  595
  596
  597
  598
  599
  600
  601
  602
  603
  604
  605
  606
  607
  608
  609
  610
  611
  612
  613
  614
  615
  616
  617
  618
  619
  620
  621
  622
  623
  624
  625
  626
  627
  628
  629
  630
  631
  632
  633
  634
  635
  636
  637
  638
  639
  640
  641
  642
  643
  644
  645
  646
  647
  648
  649
  650
  651
  652
  653
  654
  655
  656
  657
  658
  659
  660
  661
  662
  663
  664
  665
  666
  667
  668
  669
  670
  671
  672
  673
  674
  675
  676
  677
  678
  679
  680
  681
  682
  683
  684
  685
  686
  687
  688
  689
  690
  691
  692
  693
  694
  695
  696
  697
  698
  699
  700
  701
  702
  703
  704
  705
  706
  707
  708
  709
  710
  711
  712
  713
  714
  715
  716
  717
  718
  719
  720
  721
  722
  723
  724
  725
  726
  727
  728
  729
  730
  731
  732
  733
  734
  735
  736
  737
  738
  739
  740
  741
  742
  743
  744
  745
  746
  747
  748
  749
  750
  751
  752
  753
  754
  755
  756
  757
  758
  759
  760
  761
  762
  763
  764
  765
  766
  767
  768
  769
  770
  771
  772
  773
  774
  775
  776
  777
  778
  779
  780
  781
  782
  783
  784
  785
  786
  787
  788
  789
  790
  791
  792
  793
  794
  795
  796
  797
  798
  799
  800
  801
  802
  803
  804
  805
  806
  807
  808
  809
  810
  811
  812
  813
  814
  815
  816
  817
  818
  819
  820
  821
  822
  823
  824
  825
  826
  827
  828
  829
  830
  831
  832
  833
  834
  835
  836
  837
  838
  839
  840
  841
  842
  843
  844
  845
  846
  847
  848
  849
  850
  851
  852
  853
  854
  855
  856
  857
  858
  859
  860
  861
  862
  863
  864
  865
  866
  867
  868
  869
  870
  871
  872
  873
  874
  875
  876
  877
  878
  879
  880
  881
  882
  883
  884
  885
  886
  887
  888
  889
  890
  891
  892
  893
  894
  895
  896
  897
  898
  899
  900
  901
  902
  903
  904
  905
  906
  907
  908
  909
  910
  911
  912
  913
  914
  915
  916
  917
  918
  919
  920
  921
  922
  923
  924
  925
  926
  927
  928
  929
  930
  931
  932
  933
  934
  935
  936
  937
  938
  939
  940
  941
  942
  943
  944
  945
//===- llvm/ADT/BitVector.h - Bit vectors -----------------------*- 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 implements the BitVector class.
//
//===----------------------------------------------------------------------===//

#ifndef LLVM_ADT_BITVECTOR_H
#define LLVM_ADT_BITVECTOR_H

#include "llvm/ADT/ArrayRef.h"
#include "llvm/ADT/iterator_range.h"
#include "llvm/Support/MathExtras.h"
#include <algorithm>
#include <cassert>
#include <climits>
#include <cstdint>
#include <cstdlib>
#include <cstring>
#include <utility>

namespace llvm {

/// ForwardIterator for the bits that are set.
/// Iterators get invalidated when resize / reserve is called.
template <typename BitVectorT> class const_set_bits_iterator_impl {
  const BitVectorT &Parent;
  int Current = 0;

  void advance() {
    assert(Current != -1 && "Trying to advance past end.");
    Current = Parent.find_next(Current);
  }

public:
  const_set_bits_iterator_impl(const BitVectorT &Parent, int Current)
      : Parent(Parent), Current(Current) {}
  explicit const_set_bits_iterator_impl(const BitVectorT &Parent)
      : const_set_bits_iterator_impl(Parent, Parent.find_first()) {}
  const_set_bits_iterator_impl(const const_set_bits_iterator_impl &) = default;

  const_set_bits_iterator_impl operator++(int) {
    auto Prev = *this;
    advance();
    return Prev;
  }

  const_set_bits_iterator_impl &operator++() {
    advance();
    return *this;
  }

  unsigned operator*() const { return Current; }

  bool operator==(const const_set_bits_iterator_impl &Other) const {
    assert(&Parent == &Other.Parent &&
           "Comparing iterators from different BitVectors");
    return Current == Other.Current;
  }

  bool operator!=(const const_set_bits_iterator_impl &Other) const {
    assert(&Parent == &Other.Parent &&
           "Comparing iterators from different BitVectors");
    return Current != Other.Current;
  }
};

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");

  MutableArrayRef<BitWord> Bits; // Actual bits.
  unsigned Size;                 // Size of bitvector in bits.

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

    BitWord *WordRef;
    unsigned BitPos;

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

    reference() = delete;
    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)) != 0;
    }
  };

  typedef const_set_bits_iterator_impl<BitVector> const_set_bits_iterator;
  typedef const_set_bits_iterator set_iterator;

  const_set_bits_iterator set_bits_begin() const {
    return const_set_bits_iterator(*this);
  }
  const_set_bits_iterator set_bits_end() const {
    return const_set_bits_iterator(*this, -1);
  }
  iterator_range<const_set_bits_iterator> set_bits() const {
    return make_range(set_bits_begin(), set_bits_end());
  }

  /// BitVector default ctor - Creates an empty bitvector.
  BitVector() : Size(0) {}

  /// 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) {
    size_t Capacity = NumBitWords(s);
    Bits = allocate(Capacity);
    init_words(Bits, t);
    if (t)
      clear_unused_bits();
  }

  /// BitVector copy ctor.
  BitVector(const BitVector &RHS) : Size(RHS.size()) {
    if (Size == 0) {
      Bits = MutableArrayRef<BitWord>();
      return;
    }

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

  BitVector(BitVector &&RHS) : Bits(RHS.Bits), Size(RHS.Size) {
    RHS.Bits = MutableArrayRef<BitWord>();
    RHS.Size = 0;
  }

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

  /// 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_in - Returns the index of the first set bit in the range
  /// [Begin, End).  Returns -1 if all bits in the range are unset.
  int find_first_in(unsigned Begin, unsigned End) const {
    assert(Begin <= End && End <= Size);
    if (Begin == End)
      return -1;

    unsigned FirstWord = Begin / BITWORD_SIZE;
    unsigned LastWord = (End - 1) / BITWORD_SIZE;

    // Check subsequent words.
    for (unsigned i = FirstWord; i <= LastWord; ++i) {
      BitWord Copy = Bits[i];

      if (i == FirstWord) {
        unsigned FirstBit = Begin % BITWORD_SIZE;
        Copy &= maskTrailingZeros<BitWord>(FirstBit);
      }

      if (i == LastWord) {
        unsigned LastBit = (End - 1) % BITWORD_SIZE;
        Copy &= maskTrailingOnes<BitWord>(LastBit + 1);
      }
      if (Copy != 0)
        return i * BITWORD_SIZE + countTrailingZeros(Copy);
    }
    return -1;
  }

  /// find_last_in - Returns the index of the last set bit in the range
  /// [Begin, End).  Returns -1 if all bits in the range are unset.
  int find_last_in(unsigned Begin, unsigned End) const {
    assert(Begin <= End && End <= Size);
    if (Begin == End)
      return -1;

    unsigned LastWord = (End - 1) / BITWORD_SIZE;
    unsigned FirstWord = Begin / BITWORD_SIZE;

    for (unsigned i = LastWord + 1; i >= FirstWord + 1; --i) {
      unsigned CurrentWord = i - 1;

      BitWord Copy = Bits[CurrentWord];
      if (CurrentWord == LastWord) {
        unsigned LastBit = (End - 1) % BITWORD_SIZE;
        Copy &= maskTrailingOnes<BitWord>(LastBit + 1);
      }

      if (CurrentWord == FirstWord) {
        unsigned FirstBit = Begin % BITWORD_SIZE;
        Copy &= maskTrailingZeros<BitWord>(FirstBit);
      }

      if (Copy != 0)
        return (CurrentWord + 1) * BITWORD_SIZE - countLeadingZeros(Copy) - 1;
    }

    return -1;
  }

  /// find_first_unset_in - Returns the index of the first unset bit in the
  /// range [Begin, End).  Returns -1 if all bits in the range are set.
  int find_first_unset_in(unsigned Begin, unsigned End) const {
    assert(Begin <= End && End <= Size);
    if (Begin == End)
      return -1;

    unsigned FirstWord = Begin / BITWORD_SIZE;
    unsigned LastWord = (End - 1) / BITWORD_SIZE;

    // Check subsequent words.
    for (unsigned i = FirstWord; i <= LastWord; ++i) {
      BitWord Copy = Bits[i];

      if (i == FirstWord) {
        unsigned FirstBit = Begin % BITWORD_SIZE;
        Copy |= maskTrailingOnes<BitWord>(FirstBit);
      }

      if (i == LastWord) {
        unsigned LastBit = (End - 1) % BITWORD_SIZE;
        Copy |= maskTrailingZeros<BitWord>(LastBit + 1);
      }
      if (Copy != ~0UL) {
        unsigned Result = i * BITWORD_SIZE + countTrailingOnes(Copy);
        return Result < size() ? Result : -1;
      }
    }
    return -1;
  }

  /// find_last_unset_in - Returns the index of the last unset bit in the
  /// range [Begin, End).  Returns -1 if all bits in the range are set.
  int find_last_unset_in(unsigned Begin, unsigned End) const {
    assert(Begin <= End && End <= Size);
    if (Begin == End)
      return -1;

    unsigned LastWord = (End - 1) / BITWORD_SIZE;
    unsigned FirstWord = Begin / BITWORD_SIZE;

    for (unsigned i = LastWord + 1; i >= FirstWord + 1; --i) {
      unsigned CurrentWord = i - 1;

      BitWord Copy = Bits[CurrentWord];
      if (CurrentWord == LastWord) {
        unsigned LastBit = (End - 1) % BITWORD_SIZE;
        Copy |= maskTrailingZeros<BitWord>(LastBit + 1);
      }

      if (CurrentWord == FirstWord) {
        unsigned FirstBit = Begin % BITWORD_SIZE;
        Copy |= maskTrailingOnes<BitWord>(FirstBit);
      }

      if (Copy != ~0UL) {
        unsigned Result =
            (CurrentWord + 1) * BITWORD_SIZE - countLeadingOnes(Copy) - 1;
        return Result < Size ? Result : -1;
      }
    }
    return -1;
  }

  /// find_first - Returns the index of the first set bit, -1 if none
  /// of the bits are set.
  int find_first() const { return find_first_in(0, Size); }

  /// find_last - Returns the index of the last set bit, -1 if none of the bits
  /// are set.
  int find_last() const { return find_last_in(0, Size); }

  /// 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 { return find_first_in(Prev + 1, Size); }

  /// find_prev - Returns the index of the first set bit that precedes the
  /// the bit at \p PriorTo.  Returns -1 if all previous bits are unset.
  int find_prev(unsigned PriorTo) const { return find_last_in(0, PriorTo); }

  /// find_first_unset - Returns the index of the first unset bit, -1 if all
  /// of the bits are set.
  int find_first_unset() const { return find_first_unset_in(0, Size); }

  /// find_next_unset - Returns the index of the next unset bit following the
  /// "Prev" bit.  Returns -1 if all remaining bits are set.
  int find_next_unset(unsigned Prev) const {
    return find_first_unset_in(Prev + 1, Size);
  }

  /// find_last_unset - Returns the index of the last unset bit, -1 if all of
  /// the bits are set.
  int find_last_unset() const { return find_last_unset_in(0, Size); }

  /// find_prev_unset - Returns the index of the first unset bit that precedes
  /// the bit at \p PriorTo.  Returns -1 if all previous bits are set.
  int find_prev_unset(unsigned PriorTo) {
    return find_last_unset_in(0, PriorTo);
  }

  /// clear - Removes all bits from the bitvector. Does not change capacity.
  void clear() {
    Size = 0;
  }

  /// resize - Grow or shrink the bitvector.
  void resize(unsigned N, bool t = false) {
    if (N > getBitCapacity()) {
      unsigned OldCapacity = Bits.size();
      grow(N);
      init_words(Bits.drop_front(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 > getBitCapacity())
      grow(N);
  }

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

  BitVector &set(unsigned Idx) {
    assert(Bits.data() && "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 = alignTo(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, 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 = alignTo(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];
  }

  // Push single bit to end of vector.
  void push_back(bool Val) {
    unsigned OldSize = Size;
    unsigned NewSize = Size + 1;

    // Resize, which will insert zeros.
    // If we already fit then the unused bits will be already zero.
    if (NewSize > getBitCapacity())
      resize(NewSize, false);
    else
      Size = NewSize;

    // If true, set single bit.
    if (Val)
      set(OldSize);
  }

  /// 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;
  }

  BitVector &operator>>=(unsigned N) {
    assert(N <= Size);
    if (LLVM_UNLIKELY(empty() || N == 0))
      return *this;

    unsigned NumWords = NumBitWords(Size);
    assert(NumWords >= 1);

    wordShr(N / BITWORD_SIZE);

    unsigned BitDistance = N % BITWORD_SIZE;
    if (BitDistance == 0)
      return *this;

    // When the shift size is not a multiple of the word size, then we have
    // a tricky situation where each word in succession needs to extract some
    // of the bits from the next word and or them into this word while
    // shifting this word to make room for the new bits.  This has to be done
    // for every word in the array.

    // Since we're shifting each word right, some bits will fall off the end
    // of each word to the right, and empty space will be created on the left.
    // The final word in the array will lose bits permanently, so starting at
    // the beginning, work forwards shifting each word to the right, and
    // OR'ing in the bits from the end of the next word to the beginning of
    // the current word.

    // Example:
    //   Starting with {0xAABBCCDD, 0xEEFF0011, 0x22334455} and shifting right
    //   by 4 bits.
    // Step 1: Word[0] >>= 4           ; 0x0ABBCCDD
    // Step 2: Word[0] |= 0x10000000   ; 0x1ABBCCDD
    // Step 3: Word[1] >>= 4           ; 0x0EEFF001
    // Step 4: Word[1] |= 0x50000000   ; 0x5EEFF001
    // Step 5: Word[2] >>= 4           ; 0x02334455
    // Result: { 0x1ABBCCDD, 0x5EEFF001, 0x02334455 }
    const BitWord Mask = maskTrailingOnes<BitWord>(BitDistance);
    const unsigned LSH = BITWORD_SIZE - BitDistance;

    for (unsigned I = 0; I < NumWords - 1; ++I) {
      Bits[I] >>= BitDistance;
      Bits[I] |= (Bits[I + 1] & Mask) << LSH;
    }

    Bits[NumWords - 1] >>= BitDistance;

    return *this;
  }

  BitVector &operator<<=(unsigned N) {
    assert(N <= Size);
    if (LLVM_UNLIKELY(empty() || N == 0))
      return *this;

    unsigned NumWords = NumBitWords(Size);
    assert(NumWords >= 1);

    wordShl(N / BITWORD_SIZE);

    unsigned BitDistance = N % BITWORD_SIZE;
    if (BitDistance == 0)
      return *this;

    // When the shift size is not a multiple of the word size, then we have
    // a tricky situation where each word in succession needs to extract some
    // of the bits from the previous word and or them into this word while
    // shifting this word to make room for the new bits.  This has to be done
    // for every word in the array.  This is similar to the algorithm outlined
    // in operator>>=, but backwards.

    // Since we're shifting each word left, some bits will fall off the end
    // of each word to the left, and empty space will be created on the right.
    // The first word in the array will lose bits permanently, so starting at
    // the end, work backwards shifting each word to the left, and OR'ing
    // in the bits from the end of the next word to the beginning of the
    // current word.

    // Example:
    //   Starting with {0xAABBCCDD, 0xEEFF0011, 0x22334455} and shifting left
    //   by 4 bits.
    // Step 1: Word[2] <<= 4           ; 0x23344550
    // Step 2: Word[2] |= 0x0000000E   ; 0x2334455E
    // Step 3: Word[1] <<= 4           ; 0xEFF00110
    // Step 4: Word[1] |= 0x0000000A   ; 0xEFF0011A
    // Step 5: Word[0] <<= 4           ; 0xABBCCDD0
    // Result: { 0xABBCCDD0, 0xEFF0011A, 0x2334455E }
    const BitWord Mask = maskLeadingOnes<BitWord>(BitDistance);
    const unsigned RSH = BITWORD_SIZE - BitDistance;

    for (int I = NumWords - 1; I > 0; --I) {
      Bits[I] <<= BitDistance;
      Bits[I] |= (Bits[I - 1] & Mask) >> RSH;
    }
    Bits[0] <<= BitDistance;
    clear_unused_bits();

    return *this;
  }

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

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

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

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

    return *this;
  }

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

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

    RHS.Bits = MutableArrayRef<BitWord>();
    RHS.Size = 0;

    return *this;
  }

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

  //===--------------------------------------------------------------------===//
  // 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:
  /// Perform a logical left shift of \p Count words by moving everything
  /// \p Count words to the right in memory.
  ///
  /// While confusing, words are stored from least significant at Bits[0] to
  /// most significant at Bits[NumWords-1].  A logical shift left, however,
  /// moves the current least significant bit to a higher logical index, and
  /// fills the previous least significant bits with 0.  Thus, we actually
  /// need to move the bytes of the memory to the right, not to the left.
  /// Example:
  ///   Words = [0xBBBBAAAA, 0xDDDDFFFF, 0x00000000, 0xDDDD0000]
  /// represents a BitVector where 0xBBBBAAAA contain the least significant
  /// bits.  So if we want to shift the BitVector left by 2 words, we need to
  /// turn this into 0x00000000 0x00000000 0xBBBBAAAA 0xDDDDFFFF by using a
  /// memmove which moves right, not left.
  void wordShl(uint32_t Count) {
    if (Count == 0)
      return;

    uint32_t NumWords = NumBitWords(Size);

    auto Src = Bits.take_front(NumWords).drop_back(Count);
    auto Dest = Bits.take_front(NumWords).drop_front(Count);

    // Since we always move Word-sized chunks of data with src and dest both
    // aligned to a word-boundary, we don't need to worry about endianness
    // here.
    std::memmove(Dest.begin(), Src.begin(), Dest.size() * sizeof(BitWord));
    std::memset(Bits.data(), 0, Count * sizeof(BitWord));
    clear_unused_bits();
  }

  /// Perform a logical right shift of \p Count words by moving those
  /// words to the left in memory.  See wordShl for more information.
  ///
  void wordShr(uint32_t Count) {
    if (Count == 0)
      return;

    uint32_t NumWords = NumBitWords(Size);

    auto Src = Bits.take_front(NumWords).drop_front(Count);
    auto Dest = Bits.take_front(NumWords).drop_back(Count);
    assert(Dest.size() == Src.size());

    std::memmove(Dest.begin(), Src.begin(), Dest.size() * sizeof(BitWord));
    std::memset(Dest.end(), 0, Count * sizeof(BitWord));
  }

  MutableArrayRef<BitWord> allocate(size_t NumWords) {
    BitWord *RawBits = static_cast<BitWord *>(
        safe_malloc(NumWords * sizeof(BitWord)));
    return MutableArrayRef<BitWord>(RawBits, NumWords);
  }

  int next_unset_in_word(int WordIndex, BitWord Word) const {
    unsigned Result = WordIndex * BITWORD_SIZE + countTrailingOnes(Word);
    return Result < size() ? Result : -1;
  }

  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 (Bits.size() > UsedWords)
      init_words(Bits.drop_front(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) {
    size_t NewCapacity = std::max<size_t>(NumBitWords(NewSize), Bits.size() * 2);
    assert(NewCapacity > 0 && "realloc-ing zero space");
    BitWord *NewBits = static_cast<BitWord *>(
        safe_realloc(Bits.data(), NewCapacity * sizeof(BitWord)));
    Bits = MutableArrayRef<BitWord>(NewBits, NewCapacity);
    clear_unused_bits();
  }

  void init_words(MutableArrayRef<BitWord> B, bool t) {
    if (B.size() > 0)
      memset(B.data(), 0 - (int)t, B.size() * 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();
  }

public:
  /// Return the size (in bytes) of the bit vector.
  size_t getMemorySize() const { return Bits.size() * sizeof(BitWord); }
  size_t getBitCapacity() const { return Bits.size() * BITWORD_SIZE; }
};

inline size_t capacity_in_bytes(const BitVector &X) {
  return X.getMemorySize();
}

} // end namespace llvm

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

#endif // LLVM_ADT_BITVECTOR_H