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312 lines
7.8 KiB
C++
312 lines
7.8 KiB
C++
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// basisu_containers_impl.h
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// Do not include directly
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#ifdef _MSC_VER
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#pragma warning (disable:4127) // warning C4127: conditional expression is constant
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#endif
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namespace basisu
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{
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bool elemental_vector::increase_capacity(uint32_t min_new_capacity, bool grow_hint, uint32_t element_size, object_mover pMover, bool nofail)
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{
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assert(m_size <= m_capacity);
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if (sizeof(void *) == sizeof(uint64_t))
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assert(min_new_capacity < (0x400000000ULL / element_size));
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else
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assert(min_new_capacity < (0x7FFF0000U / element_size));
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if (m_capacity >= min_new_capacity)
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return true;
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size_t new_capacity = min_new_capacity;
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if ((grow_hint) && (!helpers::is_power_of_2((uint64_t)new_capacity)))
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{
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new_capacity = (size_t)helpers::next_pow2((uint64_t)new_capacity);
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assert(new_capacity && (new_capacity > m_capacity));
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if (new_capacity < min_new_capacity)
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{
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if (nofail)
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return false;
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fprintf(stderr, "vector too large\n");
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abort();
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}
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}
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const size_t desired_size = element_size * new_capacity;
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size_t actual_size = 0;
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if (!pMover)
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{
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void* new_p = realloc(m_p, desired_size);
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if (!new_p)
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{
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if (nofail)
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return false;
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char buf[256];
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#ifdef _MSC_VER
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sprintf_s(buf, sizeof(buf), "vector: realloc() failed allocating %u bytes", (uint32_t)desired_size);
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#else
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sprintf(buf, "vector: realloc() failed allocating %u bytes", (uint32_t)desired_size);
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#endif
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fprintf(stderr, "%s", buf);
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abort();
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}
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#ifdef _MSC_VER
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actual_size = _msize(new_p);
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#elif HAS_MALLOC_USABLE_SIZE
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actual_size = malloc_usable_size(new_p);
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#else
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actual_size = desired_size;
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#endif
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m_p = new_p;
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}
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else
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{
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void* new_p = malloc(desired_size);
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if (!new_p)
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{
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if (nofail)
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return false;
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char buf[256];
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#ifdef _MSC_VER
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sprintf_s(buf, sizeof(buf), "vector: malloc() failed allocating %u bytes", (uint32_t)desired_size);
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#else
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sprintf(buf, "vector: malloc() failed allocating %u bytes", (uint32_t)desired_size);
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#endif
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fprintf(stderr, "%s", buf);
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abort();
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}
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#ifdef _MSC_VER
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actual_size = _msize(new_p);
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#elif HAS_MALLOC_USABLE_SIZE
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actual_size = malloc_usable_size(new_p);
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#else
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actual_size = desired_size;
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#endif
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(*pMover)(new_p, m_p, m_size);
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if (m_p)
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free(m_p);
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m_p = new_p;
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}
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if (actual_size > desired_size)
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m_capacity = static_cast<uint32_t>(actual_size / element_size);
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else
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m_capacity = static_cast<uint32_t>(new_capacity);
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return true;
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}
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#if BASISU_HASHMAP_TEST
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#define HASHMAP_TEST_VERIFY(c) do { if (!(c)) handle_hashmap_test_verify_failure(__LINE__); } while(0)
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static void handle_hashmap_test_verify_failure(int line)
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{
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fprintf(stderr, "HASHMAP_TEST_VERIFY() faild on line %i\n", line);
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abort();
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}
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class counted_obj
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{
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public:
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counted_obj(uint32_t v = 0) :
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m_val(v)
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{
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m_count++;
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}
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counted_obj(const counted_obj& obj) :
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m_val(obj.m_val)
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{
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m_count++;
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}
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~counted_obj()
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{
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assert(m_count > 0);
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m_count--;
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}
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static uint32_t m_count;
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uint32_t m_val;
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operator size_t() const { return m_val; }
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bool operator== (const counted_obj& rhs) const { return m_val == rhs.m_val; }
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bool operator== (const uint32_t rhs) const { return m_val == rhs; }
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};
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uint32_t counted_obj::m_count;
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static uint32_t urand32()
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{
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uint32_t a = rand();
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uint32_t b = rand() << 15;
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uint32_t c = rand() << (32 - 15);
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return a ^ b ^ c;
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}
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static int irand32(int l, int h)
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{
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assert(l < h);
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if (l >= h)
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return l;
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uint32_t range = static_cast<uint32_t>(h - l);
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uint32_t rnd = urand32();
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uint32_t rnd_range = static_cast<uint32_t>((((uint64_t)range) * ((uint64_t)rnd)) >> 32U);
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int result = l + rnd_range;
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assert((result >= l) && (result < h));
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return result;
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}
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void hash_map_test()
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{
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{
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basisu::hash_map<uint64_t, uint64_t> k;
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basisu::hash_map<uint64_t, uint64_t> l;
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std::swap(k, l);
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k.begin();
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k.end();
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k.clear();
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k.empty();
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k.erase(0);
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k.insert(0, 1);
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k.find(0);
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k.get_equals();
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k.get_hasher();
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k.get_table_size();
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k.reset();
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k.reserve(1);
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k = l;
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k.set_equals(l.get_equals());
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k.set_hasher(l.get_hasher());
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k.get_table_size();
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}
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uint32_t seed = 0;
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for (; ; )
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{
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seed++;
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typedef basisu::hash_map<counted_obj, counted_obj> my_hash_map;
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my_hash_map m;
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const uint32_t n = irand32(0, 100000);
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printf("%u\n", n);
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srand(seed); // r1.seed(seed);
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basisu::vector<int> q;
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uint32_t count = 0;
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for (uint32_t i = 0; i < n; i++)
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{
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uint32_t v = urand32() & 0x7FFFFFFF;
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my_hash_map::insert_result res = m.insert(counted_obj(v), counted_obj(v ^ 0xdeadbeef));
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if (res.second)
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{
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count++;
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q.push_back(v);
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}
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}
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HASHMAP_TEST_VERIFY(m.size() == count);
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srand(seed);
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my_hash_map cm(m);
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m.clear();
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m = cm;
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cm.reset();
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for (uint32_t i = 0; i < n; i++)
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{
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uint32_t v = urand32() & 0x7FFFFFFF;
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my_hash_map::const_iterator it = m.find(counted_obj(v));
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HASHMAP_TEST_VERIFY(it != m.end());
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HASHMAP_TEST_VERIFY(it->first == v);
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HASHMAP_TEST_VERIFY(it->second == (v ^ 0xdeadbeef));
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}
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for (uint32_t t = 0; t < 2; t++)
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{
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const uint32_t nd = irand32(1, q.size() + 1);
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for (uint32_t i = 0; i < nd; i++)
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{
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uint32_t p = irand32(0, q.size());
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int k = q[p];
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if (k >= 0)
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{
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q[p] = -k - 1;
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bool s = m.erase(counted_obj(k));
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HASHMAP_TEST_VERIFY(s);
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}
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}
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typedef basisu::hash_map<uint32_t, empty_type> uint_hash_set;
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uint_hash_set s;
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for (uint32_t i = 0; i < q.size(); i++)
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{
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int v = q[i];
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if (v >= 0)
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{
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my_hash_map::const_iterator it = m.find(counted_obj(v));
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HASHMAP_TEST_VERIFY(it != m.end());
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HASHMAP_TEST_VERIFY(it->first == (uint32_t)v);
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HASHMAP_TEST_VERIFY(it->second == ((uint32_t)v ^ 0xdeadbeef));
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s.insert(v);
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}
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else
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{
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my_hash_map::const_iterator it = m.find(counted_obj(-v - 1));
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HASHMAP_TEST_VERIFY(it == m.end());
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}
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}
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uint32_t found_count = 0;
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for (my_hash_map::const_iterator it = m.begin(); it != m.end(); ++it)
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{
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HASHMAP_TEST_VERIFY(it->second == ((uint32_t)it->first ^ 0xdeadbeef));
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uint_hash_set::const_iterator fit(s.find((uint32_t)it->first));
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HASHMAP_TEST_VERIFY(fit != s.end());
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HASHMAP_TEST_VERIFY(fit->first == it->first);
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found_count++;
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}
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HASHMAP_TEST_VERIFY(found_count == s.size());
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}
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HASHMAP_TEST_VERIFY(counted_obj::m_count == m.size() * 2);
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}
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}
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#endif // BASISU_HASHMAP_TEST
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} // namespace basisu
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