//===-- sanitizer_bitvector.h -----------------------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // Specializer BitVector implementation. // //===----------------------------------------------------------------------===// #ifndef SANITIZER_BITVECTOR_H #define SANITIZER_BITVECTOR_H #include "sanitizer_common.h" namespace __sanitizer { // Fixed size bit vector based on a single basic integer. template <class basic_int_t = uptr> class BasicBitVector { public: enum SizeEnum { kSize = sizeof(basic_int_t) * 8 }; uptr size() const { return kSize; } // No CTOR. void clear() { bits_ = 0; } void setAll() { bits_ = ~(basic_int_t)0; } bool empty() const { return bits_ == 0; } // Returns true if the bit has changed from 0 to 1. bool setBit(uptr idx) { basic_int_t old = bits_; bits_ |= mask(idx); return bits_ != old; } // Returns true if the bit has changed from 1 to 0. bool clearBit(uptr idx) { basic_int_t old = bits_; bits_ &= ~mask(idx); return bits_ != old; } bool getBit(uptr idx) const { return (bits_ & mask(idx)) != 0; } uptr getAndClearFirstOne() { CHECK(!empty()); uptr idx = LeastSignificantSetBitIndex(bits_); clearBit(idx); return idx; } // Do "this |= v" and return whether new bits have been added. bool setUnion(const BasicBitVector &v) { basic_int_t old = bits_; bits_ |= v.bits_; return bits_ != old; } // Do "this &= v" and return whether any bits have been removed. bool setIntersection(const BasicBitVector &v) { basic_int_t old = bits_; bits_ &= v.bits_; return bits_ != old; } // Do "this &= ~v" and return whether any bits have been removed. bool setDifference(const BasicBitVector &v) { basic_int_t old = bits_; bits_ &= ~v.bits_; return bits_ != old; } void copyFrom(const BasicBitVector &v) { bits_ = v.bits_; } // Returns true if 'this' intersects with 'v'. bool intersectsWith(const BasicBitVector &v) const { return (bits_ & v.bits_) != 0; } // for (BasicBitVector<>::Iterator it(bv); it.hasNext();) { // uptr idx = it.next(); // use(idx); // } class Iterator { public: Iterator() { } explicit Iterator(const BasicBitVector &bv) : bv_(bv) {} bool hasNext() const { return !bv_.empty(); } uptr next() { return bv_.getAndClearFirstOne(); } void clear() { bv_.clear(); } private: BasicBitVector bv_; }; private: basic_int_t mask(uptr idx) const { CHECK_LT(idx, size()); return (basic_int_t)1UL << idx; } basic_int_t bits_; }; // Fixed size bit vector of (kLevel1Size*BV::kSize**2) bits. // The implementation is optimized for better performance on // sparse bit vectors, i.e. the those with few set bits. template <uptr kLevel1Size = 1, class BV = BasicBitVector<> > class TwoLevelBitVector { // This is essentially a 2-level bit vector. // Set bit in the first level BV indicates that there are set bits // in the corresponding BV of the second level. // This structure allows O(kLevel1Size) time for clear() and empty(), // as well fast handling of sparse BVs. public: enum SizeEnum { kSize = BV::kSize * BV::kSize * kLevel1Size }; // No CTOR. uptr size() const { return kSize; } void clear() { for (uptr i = 0; i < kLevel1Size; i++) l1_[i].clear(); } void setAll() { for (uptr i0 = 0; i0 < kLevel1Size; i0++) { l1_[i0].setAll(); for (uptr i1 = 0; i1 < BV::kSize; i1++) l2_[i0][i1].setAll(); } } bool empty() const { for (uptr i = 0; i < kLevel1Size; i++) if (!l1_[i].empty()) return false; return true; } // Returns true if the bit has changed from 0 to 1. bool setBit(uptr idx) { check(idx); uptr i0 = idx0(idx); uptr i1 = idx1(idx); uptr i2 = idx2(idx); if (!l1_[i0].getBit(i1)) { l1_[i0].setBit(i1); l2_[i0][i1].clear(); } bool res = l2_[i0][i1].setBit(i2); // Printf("%s: %zd => %zd %zd %zd; %d\n", __func__, // idx, i0, i1, i2, res); return res; } bool clearBit(uptr idx) { check(idx); uptr i0 = idx0(idx); uptr i1 = idx1(idx); uptr i2 = idx2(idx); bool res = false; if (l1_[i0].getBit(i1)) { res = l2_[i0][i1].clearBit(i2); if (l2_[i0][i1].empty()) l1_[i0].clearBit(i1); } return res; } bool getBit(uptr idx) const { check(idx); uptr i0 = idx0(idx); uptr i1 = idx1(idx); uptr i2 = idx2(idx); // Printf("%s: %zd => %zd %zd %zd\n", __func__, idx, i0, i1, i2); return l1_[i0].getBit(i1) && l2_[i0][i1].getBit(i2); } uptr getAndClearFirstOne() { for (uptr i0 = 0; i0 < kLevel1Size; i0++) { if (l1_[i0].empty()) continue; uptr i1 = l1_[i0].getAndClearFirstOne(); uptr i2 = l2_[i0][i1].getAndClearFirstOne(); if (!l2_[i0][i1].empty()) l1_[i0].setBit(i1); uptr res = i0 * BV::kSize * BV::kSize + i1 * BV::kSize + i2; // Printf("getAndClearFirstOne: %zd %zd %zd => %zd\n", i0, i1, i2, res); return res; } CHECK(0); return 0; } // Do "this |= v" and return whether new bits have been added. bool setUnion(const TwoLevelBitVector &v) { bool res = false; for (uptr i0 = 0; i0 < kLevel1Size; i0++) { BV t = v.l1_[i0]; while (!t.empty()) { uptr i1 = t.getAndClearFirstOne(); if (l1_[i0].setBit(i1)) l2_[i0][i1].clear(); if (l2_[i0][i1].setUnion(v.l2_[i0][i1])) res = true; } } return res; } // Do "this &= v" and return whether any bits have been removed. bool setIntersection(const TwoLevelBitVector &v) { bool res = false; for (uptr i0 = 0; i0 < kLevel1Size; i0++) { if (l1_[i0].setIntersection(v.l1_[i0])) res = true; if (!l1_[i0].empty()) { BV t = l1_[i0]; while (!t.empty()) { uptr i1 = t.getAndClearFirstOne(); if (l2_[i0][i1].setIntersection(v.l2_[i0][i1])) res = true; if (l2_[i0][i1].empty()) l1_[i0].clearBit(i1); } } } return res; } // Do "this &= ~v" and return whether any bits have been removed. bool setDifference(const TwoLevelBitVector &v) { bool res = false; for (uptr i0 = 0; i0 < kLevel1Size; i0++) { BV t = l1_[i0]; t.setIntersection(v.l1_[i0]); while (!t.empty()) { uptr i1 = t.getAndClearFirstOne(); if (l2_[i0][i1].setDifference(v.l2_[i0][i1])) res = true; if (l2_[i0][i1].empty()) l1_[i0].clearBit(i1); } } return res; } void copyFrom(const TwoLevelBitVector &v) { clear(); setUnion(v); } // Returns true if 'this' intersects with 'v'. bool intersectsWith(const TwoLevelBitVector &v) const { for (uptr i0 = 0; i0 < kLevel1Size; i0++) { BV t = l1_[i0]; t.setIntersection(v.l1_[i0]); while (!t.empty()) { uptr i1 = t.getAndClearFirstOne(); if (!v.l1_[i0].getBit(i1)) continue; if (l2_[i0][i1].intersectsWith(v.l2_[i0][i1])) return true; } } return false; } // for (TwoLevelBitVector<>::Iterator it(bv); it.hasNext();) { // uptr idx = it.next(); // use(idx); // } class Iterator { public: Iterator() { } explicit Iterator(const TwoLevelBitVector &bv) : bv_(bv), i0_(0), i1_(0) { it1_.clear(); it2_.clear(); } bool hasNext() const { if (it1_.hasNext()) return true; for (uptr i = i0_; i < kLevel1Size; i++) if (!bv_.l1_[i].empty()) return true; return false; } uptr next() { // Printf("++++: %zd %zd; %d %d; size %zd\n", i0_, i1_, it1_.hasNext(), // it2_.hasNext(), kSize); if (!it1_.hasNext() && !it2_.hasNext()) { for (; i0_ < kLevel1Size; i0_++) { if (bv_.l1_[i0_].empty()) continue; it1_ = typename BV::Iterator(bv_.l1_[i0_]); // Printf("+i0: %zd %zd; %d %d; size %zd\n", i0_, i1_, it1_.hasNext(), // it2_.hasNext(), kSize); break; } } if (!it2_.hasNext()) { CHECK(it1_.hasNext()); i1_ = it1_.next(); it2_ = typename BV::Iterator(bv_.l2_[i0_][i1_]); // Printf("++i1: %zd %zd; %d %d; size %zd\n", i0_, i1_, it1_.hasNext(), // it2_.hasNext(), kSize); } CHECK(it2_.hasNext()); uptr i2 = it2_.next(); uptr res = i0_ * BV::kSize * BV::kSize + i1_ * BV::kSize + i2; // Printf("+ret: %zd %zd; %d %d; size %zd; res: %zd\n", i0_, i1_, // it1_.hasNext(), it2_.hasNext(), kSize, res); if (!it1_.hasNext() && !it2_.hasNext()) i0_++; return res; } private: const TwoLevelBitVector &bv_; uptr i0_, i1_; typename BV::Iterator it1_, it2_; }; private: void check(uptr idx) const { CHECK_LE(idx, size()); } uptr idx0(uptr idx) const { uptr res = idx / (BV::kSize * BV::kSize); CHECK_LE(res, kLevel1Size); return res; } uptr idx1(uptr idx) const { uptr res = (idx / BV::kSize) % BV::kSize; CHECK_LE(res, BV::kSize); return res; } uptr idx2(uptr idx) const { uptr res = idx % BV::kSize; CHECK_LE(res, BV::kSize); return res; } BV l1_[kLevel1Size]; BV l2_[kLevel1Size][BV::kSize]; }; } // namespace __sanitizer #endif // SANITIZER_BITVECTOR_H