BitVector::BitVector(const BitVector& src, bool expandable,
Allocator* allocator)
: BitVector(expandable,
allocator,
src.storage_size_, static_cast<uint32_t*>(allocator->Alloc(src.storage_size_ * kWordBytes))) { // Direct memcpy would be faster, but this should be fine too and is cleaner.
Copy(&src);
}
BitVector::~BitVector() { if (storage_ != nullptr) { // Only free if we haven't been moved out of.
allocator_->Free(storage_);
}
}
bool BitVector::SameBitsSet(const BitVector *src) const { int our_highest = GetHighestBitSet(); int src_highest = src->GetHighestBitSet();
// If the highest bit set is different, we are different. if (our_highest != src_highest) { returnfalse;
}
// If the highest bit set is -1, both are cleared, we are the same. // If the highest bit set is 0, both have a unique bit set, we are the same. if (our_highest <= 0) { returntrue;
}
// Get the highest bit set's cell's index // No need of highest + 1 here because it can't be 0 so BitsToWords will work here. int our_highest_index = BitsToWords(our_highest);
// This memcmp is enough: we know that the highest bit set is the same for both: // - Therefore, min_size goes up to at least that, we are thus comparing at least what we need to, but not less. // ie. we are comparing all storage cells that could have difference, if both vectors have cells above our_highest_index, // they are automatically at 0. return (memcmp(storage_, src->GetRawStorage(), our_highest_index * kWordBytes) == 0);
}
bool BitVector::IsSubsetOf(const BitVector *other) const { int this_highest = GetHighestBitSet(); int other_highest = other->GetHighestBitSet();
// If the highest bit set is -1, this is empty and a trivial subset. if (this_highest < 0) { returntrue;
}
// If the highest bit set is higher, this cannot be a subset. if (this_highest > other_highest) { returnfalse;
}
// Compare each 32-bit word.
size_t this_highest_index = BitsToWords(this_highest + 1); for (size_t i = 0; i < this_highest_index; ++i) {
uint32_t this_storage = storage_[i];
uint32_t other_storage = other->storage_[i]; if ((this_storage | other_storage) != other_storage) { returnfalse;
}
} returntrue;
}
// Now, due to this being an intersection, there are two possibilities: // - Either src was larger than us: we don't care, all upper bits would thus be 0. // - Either we are larger than src: we don't care, all upper bits would have been 0 too. // So all we need to do is set all remaining bits to 0. for (; idx < storage_size_; idx++) {
storage_[idx] = 0;
}
}
bool BitVector::Union(const BitVector* src) { // Get the highest bit to determine how much we need to expand. int highest_bit = src->GetHighestBitSet(); bool changed = false;
// If src has no bit set, we are done: there is no need for a union with src. if (highest_bit == -1) { return changed;
}
// Update src_size to how many cells we actually care about: where the bit is + 1.
uint32_t src_size = BitsToWords(highest_bit + 1);
// Is the storage size smaller than src's? if (storage_size_ < src_size) {
changed = true;
EnsureSize(highest_bit);
// Check: storage size should be big enough to hold this bit now.
DCHECK_LT(static_cast<uint32_t> (highest_bit), storage_size_ * kWordBits);
}
bool BitVector::UnionIfNotIn(const BitVector* union_with, const BitVector* not_in) { // Get the highest bit to determine how much we need to expand. int highest_bit = union_with->GetHighestBitSet(); bool changed = false;
// If src has no bit set, we are done: there is no need for a union with src. if (highest_bit == -1) { return changed;
}
// Update union_with_size to how many cells we actually care about: where the bit is + 1.
uint32_t union_with_size = BitsToWords(highest_bit + 1);
// Is the storage size smaller than src's? if (storage_size_ < union_with_size) {
EnsureSize(highest_bit);
// Check: storage size should be big enough to hold this bit now.
DCHECK_LT(static_cast<uint32_t> (highest_bit), storage_size_ * kWordBits);
}
// We only need to operate on bytes up to the smaller of the sizes of the two operands. unsignedint min_size = (storage_size_ > src_size) ? src_size : storage_size_;
// Difference until max, we know both accept it: // There is no need to do more: // If we are bigger than src, the upper bits are unchanged. // If we are smaller than src, the nonexistent upper bits are 0 and thus can't get subtracted. for (uint32_t idx = 0; idx < min_size; idx++) {
storage_[idx] &= (~(src->GetRawStorageWord(idx)));
}
}
uint32_t BitVector::NumSetBits() const {
uint32_t count = 0; for (uint32_t word = 0; word < storage_size_; word++) {
count += POPCOUNT(storage_[word]);
} return count;
}
void BitVector::SetInitialBits(uint32_t num_bits) { // If num_bits is 0, clear everything. if (num_bits == 0) {
ClearAllBits(); return;
}
// Set the highest bit we want to set to get the BitVector allocated if need be.
SetBit(num_bits - 1);
uint32_t idx; // We can set every storage element with -1. for (idx = 0; idx < WordIndex(num_bits); idx++) {
storage_[idx] = std::numeric_limits<uint32_t>::max();
}
// Handle the potentially last few bits.
uint32_t rem_num_bits = num_bits & 0x1f; if (rem_num_bits != 0) {
storage_[idx] = (1U << rem_num_bits) - 1;
++idx;
}
// Now set the upper ones to 0. for (; idx < storage_size_; idx++) {
storage_[idx] = 0;
}
}
int BitVector::GetHighestBitSet() const { unsignedint max = storage_size_; for (int idx = max - 1; idx >= 0; idx--) { // If not 0, we have more work: check the bits.
uint32_t value = storage_[idx];
if (value != 0) { // Return highest bit set in value plus bits from previous storage indexes. return31 - CLZ(value) + (idx * kWordBits);
}
}
// All zero, therefore return -1. return -1;
}
int BitVector::GetLowestBitCleared() const {
uint32_t max = storage_size_; for (uint32_t idx = 0; idx < max; idx++) {
uint32_t negated_value = ~storage_[idx];
if (negated_value != 0) { // Return lowerest bit cleared in value plus bits from previous storage indexes. return CTZ(negated_value) + (idx * kWordBits);
}
}
// All zero, therefore return -1. return -1;
}
void BitVector::Copy(const BitVector *src) { // Get highest bit set, we only need to copy till then. int highest_bit = src->GetHighestBitSet();
// If nothing is set, clear everything. if (highest_bit == -1) {
ClearAllBits(); return;
}
// Set upper bit to ensure right size before copy.
SetBit(highest_bit);
// Now set until highest bit's storage.
uint32_t size = 1 + (highest_bit / kWordBits);
memcpy(storage_, src->GetRawStorage(), kWordBytes * size);
// Set upper bits to 0.
uint32_t left = storage_size_ - size;
void BitVector::DumpHelper(constchar* prefix, std::ostringstream& buffer) const { // Initialize it. if (prefix != nullptr) {
buffer << prefix;
}
buffer << '('; for (size_t i = 0; i < storage_size_ * kWordBits; i++) {
buffer << IsBitSet(i);
}
buffer << ')';
}
void BitVector::EnsureSize(uint32_t idx) { if (idx >= storage_size_ * kWordBits) {
DCHECK(expandable_) << "Attempted to expand a non-expandable bitmap to position " << idx;
/* Round up to word boundaries for "idx+1" bits */
uint32_t new_size = BitsToWords(idx + 1);
DCHECK_GT(new_size, storage_size_);
uint32_t *new_storage = static_cast<uint32_t*>(allocator_->Alloc(new_size * kWordBytes));
memcpy(new_storage, storage_, storage_size_ * kWordBytes); // Zero out the new storage words.
memset(&new_storage[storage_size_], 0, (new_size - storage_size_) * kWordBytes); // TODO: collect stats on space wasted because of resize.
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