1 /* 2 * Copyright (C) 2013 The Android Open Source Project 3 * 4 * Licensed under the Apache License, Version 2.0 (the "License"); 5 * you may not use this file except in compliance with the License. 6 * You may obtain a copy of the License at 7 * 8 * http://www.apache.org/licenses/LICENSE-2.0 9 * 10 * Unless required by applicable law or agreed to in writing, software 11 * distributed under the License is distributed on an "AS IS" BASIS, 12 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. 13 * See the License for the specific language governing permissions and 14 * limitations under the License. 15 */ 16 17 #ifndef ART_LIBARTBASE_BASE_BIT_VECTOR_H_ 18 #define ART_LIBARTBASE_BASE_BIT_VECTOR_H_ 19 20 #include <stdint.h> 21 22 #include <iterator> 23 24 #include "bit_utils.h" 25 #include "globals.h" 26 27 namespace art { 28 29 class Allocator; 30 class ArenaBitVector; 31 32 /* 33 * Expanding bitmap, used for tracking resources. Bits are numbered starting 34 * from zero. All operations on a BitVector are unsynchronized. 35 */ 36 class BitVector { 37 public: 38 static constexpr uint32_t kWordBytes = sizeof(uint32_t); 39 static constexpr uint32_t kWordBits = kWordBytes * 8; 40 41 class IndexContainer; 42 43 /** 44 * @brief Convenient iterator across the indexes of the BitVector's set bits. 45 * 46 * @details IndexIterator is a Forward iterator (C++11: 24.2.5) from the lowest 47 * to the highest index of the BitVector's set bits. Instances can be retrieved 48 * only through BitVector::Indexes() which returns an IndexContainer wrapper 49 * object with begin() and end() suitable for range-based loops: 50 * for (uint32_t idx : bit_vector.Indexes()) { 51 * // Use idx. 52 * } 53 */ 54 class IndexIterator : 55 public std::iterator<std::forward_iterator_tag, uint32_t, ptrdiff_t, void, uint32_t> { 56 public: 57 bool operator==(const IndexIterator& other) const; 58 59 bool operator!=(const IndexIterator& other) const { 60 return !(*this == other); 61 } 62 63 uint32_t operator*() const; 64 65 IndexIterator& operator++(); 66 67 IndexIterator operator++(int); 68 69 // Helper function to check for end without comparing with bit_vector.Indexes().end(). Done()70 bool Done() const { 71 return bit_index_ == BitSize(); 72 } 73 74 private: 75 struct begin_tag { }; 76 struct end_tag { }; 77 78 IndexIterator(const BitVector* bit_vector, begin_tag); 79 IndexIterator(const BitVector* bit_vector, end_tag); 80 BitSize()81 uint32_t BitSize() const { 82 return storage_size_ * kWordBits; 83 } 84 85 uint32_t FindIndex(uint32_t start_index) const; 86 const uint32_t* const bit_storage_; 87 const uint32_t storage_size_; // Size of vector in words. 88 uint32_t bit_index_; // Current index (size in bits). 89 90 friend class BitVector::IndexContainer; 91 }; 92 93 /** 94 * @brief BitVector wrapper class for iteration across indexes of set bits. 95 */ 96 class IndexContainer { 97 public: IndexContainer(const BitVector * bit_vector)98 explicit IndexContainer(const BitVector* bit_vector) : bit_vector_(bit_vector) { } 99 100 IndexIterator begin() const; 101 IndexIterator end() const; 102 103 private: 104 const BitVector* const bit_vector_; 105 }; 106 107 // MoveConstructible but not MoveAssignable, CopyConstructible or CopyAssignable. 108 109 BitVector(const BitVector& other) = delete; 110 BitVector& operator=(const BitVector& other) = delete; 111 BitVector(BitVector && other)112 BitVector(BitVector&& other) noexcept 113 : storage_(other.storage_), 114 storage_size_(other.storage_size_), 115 allocator_(other.allocator_), 116 expandable_(other.expandable_) { 117 other.storage_ = nullptr; 118 other.storage_size_ = 0u; 119 } 120 121 BitVector(uint32_t start_bits, 122 bool expandable, 123 Allocator* allocator); 124 125 BitVector(bool expandable, 126 Allocator* allocator, 127 uint32_t storage_size, 128 uint32_t* storage); 129 130 BitVector(const BitVector& src, 131 bool expandable, 132 Allocator* allocator); 133 134 virtual ~BitVector(); 135 136 // The number of words necessary to encode bits. BitsToWords(uint32_t bits)137 static constexpr uint32_t BitsToWords(uint32_t bits) { 138 return RoundUp(bits, kWordBits) / kWordBits; 139 } 140 141 // Mark the specified bit as "set". SetBit(uint32_t idx)142 void SetBit(uint32_t idx) { 143 /* 144 * TUNING: this could have pathologically bad growth/expand behavior. Make sure we're 145 * not using it badly or change resize mechanism. 146 */ 147 if (idx >= storage_size_ * kWordBits) { 148 EnsureSize(idx); 149 } 150 storage_[WordIndex(idx)] |= BitMask(idx); 151 } 152 153 // Mark the specified bit as "unset". ClearBit(uint32_t idx)154 void ClearBit(uint32_t idx) { 155 // If the index is over the size, we don't have to do anything, it is cleared. 156 if (idx < storage_size_ * kWordBits) { 157 // Otherwise, go ahead and clear it. 158 storage_[WordIndex(idx)] &= ~BitMask(idx); 159 } 160 } 161 162 // Determine whether or not the specified bit is set. IsBitSet(uint32_t idx)163 bool IsBitSet(uint32_t idx) const { 164 // If the index is over the size, whether it is expandable or not, this bit does not exist: 165 // thus it is not set. 166 return (idx < (storage_size_ * kWordBits)) && IsBitSet(storage_, idx); 167 } 168 169 // Mark all bits bit as "clear". 170 void ClearAllBits(); 171 172 // Mark specified number of bits as "set". Cannot set all bits like ClearAll since there might 173 // be unused bits - setting those to one will confuse the iterator. 174 void SetInitialBits(uint32_t num_bits); 175 176 void Copy(const BitVector* src); 177 178 // Intersect with another bit vector. 179 void Intersect(const BitVector* src2); 180 181 // Union with another bit vector. 182 bool Union(const BitVector* src); 183 184 // Set bits of union_with that are not in not_in. 185 bool UnionIfNotIn(const BitVector* union_with, const BitVector* not_in); 186 187 void Subtract(const BitVector* src); 188 189 // Are we equal to another bit vector? Note: expandability attributes must also match. 190 bool Equal(const BitVector* src) const; 191 192 /** 193 * @brief Are all the bits set the same? 194 * @details expandability and size can differ as long as the same bits are set. 195 */ 196 bool SameBitsSet(const BitVector *src) const; 197 198 bool IsSubsetOf(const BitVector *other) const; 199 200 // Count the number of bits that are set. 201 uint32_t NumSetBits() const; 202 203 // Count the number of bits that are set in range [0, end). 204 uint32_t NumSetBits(uint32_t end) const; 205 Indexes()206 IndexContainer Indexes() const { 207 return IndexContainer(this); 208 } 209 GetStorageSize()210 uint32_t GetStorageSize() const { 211 return storage_size_; 212 } 213 IsExpandable()214 bool IsExpandable() const { 215 return expandable_; 216 } 217 GetRawStorageWord(size_t idx)218 uint32_t GetRawStorageWord(size_t idx) const { 219 return storage_[idx]; 220 } 221 GetRawStorage()222 uint32_t* GetRawStorage() { 223 return storage_; 224 } 225 GetRawStorage()226 const uint32_t* GetRawStorage() const { 227 return storage_; 228 } 229 GetSizeOf()230 size_t GetSizeOf() const { 231 return storage_size_ * kWordBytes; 232 } 233 GetBitSizeOf()234 size_t GetBitSizeOf() const { 235 return storage_size_ * kWordBits; 236 } 237 238 /** 239 * @return the highest bit set, -1 if none are set 240 */ 241 int GetHighestBitSet() const; 242 243 /** 244 * @return true if there are any bits set, false otherwise. 245 */ IsAnyBitSet()246 bool IsAnyBitSet() const { 247 return GetHighestBitSet() != -1; 248 } 249 250 // Minimum number of bits required to store this vector, 0 if none are set. GetNumberOfBits()251 size_t GetNumberOfBits() const { 252 return GetHighestBitSet() + 1; 253 } 254 255 // Is bit set in storage. (No range check.) IsBitSet(const uint32_t * storage,uint32_t idx)256 static bool IsBitSet(const uint32_t* storage, uint32_t idx) { 257 return (storage[WordIndex(idx)] & BitMask(idx)) != 0; 258 } 259 260 // Number of bits set in range [0, end) in storage. (No range check.) 261 static uint32_t NumSetBits(const uint32_t* storage, uint32_t end); 262 263 // Fill given memory region with the contents of the vector and zero padding. CopyTo(void * dst,size_t len)264 void CopyTo(void* dst, size_t len) const { 265 DCHECK_LE(static_cast<size_t>(GetHighestBitSet() + 1), len * kBitsPerByte); 266 size_t vec_len = GetSizeOf(); 267 if (vec_len < len) { 268 void* dst_padding = reinterpret_cast<uint8_t*>(dst) + vec_len; 269 memcpy(dst, storage_, vec_len); 270 memset(dst_padding, 0, len - vec_len); 271 } else { 272 memcpy(dst, storage_, len); 273 } 274 } 275 276 void Dump(std::ostream& os, const char* prefix) const; 277 278 Allocator* GetAllocator() const; 279 280 private: 281 /** 282 * @brief Dump the bitvector into buffer in a 00101..01 format. 283 * @param buffer the ostringstream used to dump the bitvector into. 284 */ 285 void DumpHelper(const char* prefix, std::ostringstream& buffer) const; 286 287 // Ensure there is space for a bit at idx. 288 void EnsureSize(uint32_t idx); 289 290 // The index of the word within storage. WordIndex(uint32_t idx)291 static constexpr uint32_t WordIndex(uint32_t idx) { 292 return idx >> 5; 293 } 294 295 // A bit mask to extract the bit for the given index. BitMask(uint32_t idx)296 static constexpr uint32_t BitMask(uint32_t idx) { 297 return 1 << (idx & 0x1f); 298 } 299 300 uint32_t* storage_; // The storage for the bit vector. 301 uint32_t storage_size_; // Current size, in 32-bit words. 302 Allocator* const allocator_; // Allocator if expandable. 303 const bool expandable_; // Should the bitmap expand if too small? 304 }; 305 306 // Helper for dealing with 2d bit-vector arrays packed into a single bit-vec 307 class BaseBitVectorArray { 308 public: 309 BaseBitVectorArray(const BaseBitVectorArray& bv) = default; 310 BaseBitVectorArray& operator=(const BaseBitVectorArray& other) = default; 311 BaseBitVectorArray()312 BaseBitVectorArray() : num_columns_(0), num_rows_(0) {} 313 BaseBitVectorArray(size_t num_rows,size_t num_columns)314 BaseBitVectorArray(size_t num_rows, size_t num_columns) 315 : num_columns_(RoundUp(num_columns, BitVector::kWordBits)), num_rows_(num_rows) {} 316 ~BaseBitVectorArray()317 virtual ~BaseBitVectorArray() {} 318 IsExpandable()319 bool IsExpandable() const { 320 return GetRawData().IsExpandable(); 321 } 322 323 // Let subclasses provide storage for various types. 324 virtual const BitVector& GetRawData() const = 0; 325 virtual BitVector& GetRawData() = 0; 326 NumRows()327 size_t NumRows() const { 328 return num_rows_; 329 } 330 331 // NB This might be more than the requested size for alignment purposes. NumColumns()332 size_t NumColumns() const { 333 return num_columns_; 334 } 335 Clear()336 void Clear() { 337 GetRawData().ClearAllBits(); 338 } 339 340 // Ensure that we can set all bits in the given range. The actual number of 341 // columns might be larger than requested for alignment purposes. 342 void Resize(size_t rows, size_t cols, bool clear = true); 343 SetBit(size_t row,size_t col)344 void SetBit(size_t row, size_t col) { 345 DCHECK_LT(col, num_columns_); 346 DCHECK_LT(row, num_rows_); 347 GetRawData().SetBit(row * num_columns_ + col); 348 } 349 ClearBit(size_t row,size_t col)350 void ClearBit(size_t row, size_t col) { 351 DCHECK_LT(col, num_columns_); 352 DCHECK_LT(row, num_rows_); 353 GetRawData().ClearBit(row * num_columns_ + col); 354 } 355 IsBitSet(size_t row,size_t col)356 bool IsBitSet(size_t row, size_t col) const { 357 DCHECK_LT(col, num_columns_); 358 DCHECK_LT(row, num_rows_); 359 return GetRawData().IsBitSet(row * num_columns_ + col); 360 } 361 362 // Union the vector of 'other' into 'dest_row'. 363 void UnionRows(size_t dest_row, size_t other); 364 RequiredBitVectorSize(size_t rows,size_t cols)365 static size_t RequiredBitVectorSize(size_t rows, size_t cols) { 366 return rows * RoundUp(cols, BitVector::kWordBits); 367 } 368 MaxRowsFor(const BitVector & bv,size_t cols)369 static size_t MaxRowsFor(const BitVector& bv, size_t cols) { 370 return cols != 0 ? bv.GetBitSizeOf() / RoundUp(cols, BitVector::kWordBits) : 0; 371 } 372 373 private: 374 size_t num_columns_; 375 size_t num_rows_; 376 }; 377 378 // A BitVectorArray with a standard owned BitVector providing the backing 379 // storage. This should be used when the BitVectorArray is the owner of the 380 // whole BitVector and should use standard allocators for cleanup/allocation. 381 // Contrast this with ArenaBitVectorArray which uses arena allocators. 382 class BitVectorArray final : public BaseBitVectorArray { 383 public: 384 BitVectorArray(const BitVectorArray& bv) = delete; 385 BitVectorArray& operator=(const BitVectorArray& other) = delete; 386 BitVectorArray(BitVector && bv)387 explicit BitVectorArray(BitVector&& bv) : BaseBitVectorArray(), data_(std::move(bv)) {} BitVectorArray(BitVector && bv,size_t cols)388 explicit BitVectorArray(BitVector&& bv, size_t cols) 389 : BaseBitVectorArray(BaseBitVectorArray::MaxRowsFor(bv, cols), cols), data_(std::move(bv)) {} BitVectorArray(BitVector && bv,size_t rows,size_t cols)390 explicit BitVectorArray(BitVector&& bv, size_t rows, size_t cols) 391 : BaseBitVectorArray(rows, cols), data_(std::move(bv)) {} 392 BitVectorArray(uint32_t start_rows,uint32_t start_cols,bool expandable,Allocator * allocator)393 BitVectorArray(uint32_t start_rows, uint32_t start_cols, bool expandable, Allocator* allocator) 394 : BaseBitVectorArray(start_rows, start_cols), 395 data_(BaseBitVectorArray::RequiredBitVectorSize(start_rows, start_cols), 396 expandable, 397 allocator) {} 398 BitVectorArray(const BaseBitVectorArray & src,bool expandable,Allocator * allocator)399 BitVectorArray(const BaseBitVectorArray& src, bool expandable, Allocator* allocator) 400 : BaseBitVectorArray(src.NumRows(), src.NumColumns()), 401 data_(src.GetRawData(), expandable, allocator) {} 402 ~BitVectorArray()403 ~BitVectorArray() override {} 404 GetRawData()405 const BitVector& GetRawData() const override { 406 return data_; 407 } 408 GetRawData()409 BitVector& GetRawData() override { 410 return data_; 411 } 412 413 private: 414 BitVector data_; 415 }; 416 417 // A bit vector array that uses an unowned BitVector reference as it's backing 418 // data. 419 class BitVectorArrayWrapper final : public BaseBitVectorArray { 420 public: 421 BitVectorArrayWrapper& operator=(BitVectorArrayWrapper& other) = default; 422 BitVectorArrayWrapper(BitVectorArrayWrapper&) = default; BitVectorArrayWrapper(BitVector * bv)423 explicit BitVectorArrayWrapper(BitVector* bv) : BaseBitVectorArray(), data_(bv) {} BitVectorArrayWrapper(BitVector * bv,size_t cols)424 explicit BitVectorArrayWrapper(BitVector* bv, size_t cols) 425 : BaseBitVectorArray(BaseBitVectorArray::MaxRowsFor(*bv, cols), cols), data_(bv) {} BitVectorArrayWrapper(BitVector * bv,size_t rows,size_t cols)426 explicit BitVectorArrayWrapper(BitVector* bv, size_t rows, size_t cols) 427 : BaseBitVectorArray(rows, cols), data_(bv) {} 428 ~BitVectorArrayWrapper()429 ~BitVectorArrayWrapper() override {} 430 GetRawData()431 const BitVector& GetRawData() const override { 432 return *data_; 433 } 434 GetRawData()435 BitVector& GetRawData() override { 436 return *data_; 437 } 438 439 private: 440 BitVector* data_; 441 }; 442 443 } // namespace art 444 445 #endif // ART_LIBARTBASE_BASE_BIT_VECTOR_H_ 446