sanitizer_bitvector_test.cc [plain text]
#include "sanitizer_common/sanitizer_bitvector.h"
#include "sanitizer_test_utils.h"
#include "gtest/gtest.h"
#include <algorithm>
#include <vector>
#include <set>
using namespace __sanitizer;
using namespace std;
template <class BV>
static void CheckBV(const BV &bv, const set<uptr> &s) {
BV t;
t.copyFrom(bv);
set<uptr> t_s(s);
uptr last_idx = bv.size();
uptr count = 0;
for (typename BV::Iterator it(bv); it.hasNext();) {
uptr idx = it.next();
count++;
if (last_idx != bv.size())
EXPECT_LT(last_idx, idx);
last_idx = idx;
EXPECT_TRUE(s.count(idx));
}
EXPECT_EQ(count, s.size());
last_idx = bv.size();
while (!t.empty()) {
uptr idx = t.getAndClearFirstOne();
if (last_idx != bv.size())
EXPECT_LT(last_idx, idx);
last_idx = idx;
EXPECT_TRUE(t_s.erase(idx));
}
EXPECT_TRUE(t_s.empty());
}
template <class BV>
void Print(const BV &bv) {
BV t;
t.copyFrom(bv);
while (!t.empty()) {
uptr idx = t.getAndClearFirstOne();
fprintf(stderr, "%zd ", idx);
}
fprintf(stderr, "\n");
}
void Print(const set<uptr> &s) {
for (set<uptr>::iterator it = s.begin(); it != s.end(); ++it) {
fprintf(stderr, "%zd ", *it);
}
fprintf(stderr, "\n");
}
template <class BV>
void TestBitVector(uptr expected_size) {
BV bv, bv1, t_bv;
EXPECT_EQ(expected_size, BV::kSize);
bv.clear();
EXPECT_TRUE(bv.empty());
bv.setBit(5);
EXPECT_FALSE(bv.empty());
EXPECT_FALSE(bv.getBit(4));
EXPECT_FALSE(bv.getBit(6));
EXPECT_TRUE(bv.getBit(5));
bv.clearBit(5);
EXPECT_FALSE(bv.getBit(5));
bv.clear();
set<uptr> s;
for (uptr it = 0; it < 1000; it++) {
uptr bit = ((uptr)my_rand() % bv.size());
EXPECT_EQ(bv.getBit(bit), s.count(bit) == 1);
switch (my_rand() % 2) {
case 0:
EXPECT_EQ(bv.setBit(bit), s.insert(bit).second);
break;
case 1:
size_t old_size = s.size();
s.erase(bit);
EXPECT_EQ(bv.clearBit(bit), old_size > s.size());
break;
}
EXPECT_EQ(bv.getBit(bit), s.count(bit) == 1);
}
vector<uptr>bits(bv.size());
for (uptr it = 0; it < 30; it++) {
for (size_t j = 0; j < bits.size(); j++) bits[j] = j;
random_shuffle(bits.begin(), bits.end());
set<uptr> s, s1, t_s;
bv.clear();
bv1.clear();
uptr n_bits = ((uptr)my_rand() % bv.size()) + 1;
uptr n_bits1 = (uptr)my_rand() % (bv.size() / 2);
EXPECT_TRUE(n_bits > 0 && n_bits <= bv.size());
EXPECT_TRUE(n_bits1 < bv.size() / 2);
for (uptr i = 0; i < n_bits; i++) {
bv.setBit(bits[i]);
s.insert(bits[i]);
}
CheckBV(bv, s);
for (uptr i = 0; i < n_bits1; i++) {
bv1.setBit(bits[bv.size() / 2 + i]);
s1.insert(bits[bv.size() / 2 + i]);
}
CheckBV(bv1, s1);
vector<uptr> vec;
set_intersection(s.begin(), s.end(), s1.begin(), s1.end(),
back_insert_iterator<vector<uptr> >(vec));
EXPECT_EQ(bv.intersectsWith(bv1), !vec.empty());
t_s = s;
t_bv.copyFrom(bv);
t_s.insert(s1.begin(), s1.end());
EXPECT_EQ(t_bv.setUnion(bv1), s.size() != t_s.size());
CheckBV(t_bv, t_s);
t_s = set<uptr>(vec.begin(), vec.end());
t_bv.copyFrom(bv);
EXPECT_EQ(t_bv.setIntersection(bv1), s.size() != t_s.size());
CheckBV(t_bv, t_s);
vec.clear();
set_difference(s.begin(), s.end(), s1.begin(), s1.end(),
back_insert_iterator<vector<uptr> >(vec));
t_s = set<uptr>(vec.begin(), vec.end());
t_bv.copyFrom(bv);
EXPECT_EQ(t_bv.setDifference(bv1), s.size() != t_s.size());
CheckBV(t_bv, t_s);
}
}
TEST(SanitizerCommon, BasicBitVector) {
TestBitVector<BasicBitVector<u8> >(8);
TestBitVector<BasicBitVector<u16> >(16);
TestBitVector<BasicBitVector<> >(SANITIZER_WORDSIZE);
}
TEST(SanitizerCommon, TwoLevelBitVector) {
uptr ws = SANITIZER_WORDSIZE;
TestBitVector<TwoLevelBitVector<1, BasicBitVector<u8> > >(8 * 8);
TestBitVector<TwoLevelBitVector<> >(ws * ws);
TestBitVector<TwoLevelBitVector<2> >(ws * ws * 2);
TestBitVector<TwoLevelBitVector<3> >(ws * ws * 3);
TestBitVector<TwoLevelBitVector<3, BasicBitVector<u16> > >(16 * 16 * 3);
}