//===- HashTableTest.cpp --------------------------------------------------===// // // The MCLinker Project // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "HashTableTest.h" #include "mcld/ADT/HashEntry.h" #include "mcld/ADT/HashTable.h" #include <cstdlib> using namespace std; using namespace mcld; using namespace mcldtest; // Constructor can do set-up work for all test here. HashTableTest::HashTableTest() { } // Destructor can do clean-up work that doesn't throw exceptions here. HashTableTest::~HashTableTest() { } // SetUp() will be called immediately before each test. void HashTableTest::SetUp() { } // TearDown() will be called immediately after each test. void HashTableTest::TearDown() { } //==========================================================================// // Testcases // struct IntCompare { bool operator()(int X, int Y) const { return (X==Y); } }; struct PtrCompare { bool operator()(const int* X, const int* Y) const { return (X==Y); } }; struct PtrHash { size_t operator()(const int* pKey) const { return (unsigned((uintptr_t)pKey) >> 4) ^ (unsigned((uintptr_t)pKey) >> 9); } }; struct IntHash { size_t operator()(int pKey) const { return pKey; } }; struct IntMod3Hash { size_t operator()(int pKey) const { return pKey % 3; } }; TEST_F( HashTableTest, ptr_entry ) { int A = 1; int* pA = &A; typedef HashEntry<int*, int, PtrCompare> HashEntryType; typedef HashTable<HashEntryType, PtrHash, EntryFactory<HashEntryType> > HashTableTy; HashTableTy *hashTable = new HashTableTy(0); bool exist; HashTableTy::entry_type* entry = 0; entry = hashTable->insert(pA, exist); EXPECT_FALSE(hashTable->empty()); HashTableTy::iterator iter; iter = hashTable->find(NULL); EXPECT_TRUE(iter==hashTable->end()); delete hashTable; } TEST_F( HashTableTest, constructor ) { typedef HashEntry<int, int, IntCompare> HashEntryType; HashTable<HashEntryType, IntHash, EntryFactory<HashEntryType> > hashTable(16); EXPECT_TRUE(17 == hashTable.numOfBuckets()); EXPECT_TRUE(hashTable.empty()); EXPECT_TRUE(0 == hashTable.numOfEntries()); } TEST_F( HashTableTest, allocattion ) { typedef HashEntry<int, int, IntCompare> HashEntryType; typedef HashTable<HashEntryType, IntHash, EntryFactory<HashEntryType> > HashTableTy; HashTableTy *hashTable = new HashTableTy(22); bool exist; int key = 100; HashTableTy::entry_type* val = hashTable->insert(key, exist); val->setValue(999); EXPECT_FALSE(hashTable->empty()); EXPECT_FALSE(exist); EXPECT_FALSE(NULL == val); HashTableTy::iterator entry = hashTable->find(key); EXPECT_EQ(999, entry.getEntry()->value()); delete hashTable; } TEST_F( HashTableTest, alloc100 ) { typedef HashEntry<int, int, IntCompare> HashEntryType; typedef HashTable<HashEntryType, IntHash, EntryFactory<HashEntryType> > HashTableTy; HashTableTy *hashTable = new HashTableTy(22); bool exist; HashTableTy::entry_type* entry = 0; for (int key=0; key<100; ++key) { entry = hashTable->insert(key, exist); EXPECT_FALSE(hashTable->empty()); EXPECT_FALSE(exist); EXPECT_FALSE(NULL == entry); EXPECT_TRUE(key == entry->key()); entry->setValue(key+10); } EXPECT_FALSE(hashTable->empty()); EXPECT_TRUE(100 == hashTable->numOfEntries()); EXPECT_TRUE(197 == hashTable->numOfBuckets()); delete hashTable; } TEST_F( HashTableTest, erase100 ) { typedef HashEntry<int, int, IntCompare> HashEntryType; typedef HashTable<HashEntryType, IntHash, EntryFactory<HashEntryType> > HashTableTy; HashTableTy *hashTable = new HashTableTy(0); bool exist; HashTableTy::entry_type* entry = 0; for (unsigned int key=0; key<100; ++key) entry = hashTable->insert(key, exist); EXPECT_FALSE(hashTable->empty()); int count; HashTableTy::iterator iter; for (unsigned int key=0; key<100; ++key) { count = hashTable->erase(key); EXPECT_EQ(1, count); iter = hashTable->find(key); EXPECT_TRUE(iter == hashTable->end()); } EXPECT_TRUE(hashTable->empty()); delete hashTable; } TEST_F( HashTableTest, clear) { typedef HashEntry<int, int, IntCompare> HashEntryType; typedef HashTable<HashEntryType, IntHash, EntryFactory<HashEntryType> > HashTableTy; HashTableTy *hashTable = new HashTableTy(22); bool exist; HashTableTy::entry_type* entry = 0; for (unsigned int key=0; key<100; ++key) { entry = hashTable->insert(key, exist); } hashTable->clear(); HashTableTy::iterator iter; for (unsigned int key=0; key<100; ++key) { iter = hashTable->find(key); EXPECT_TRUE(iter == hashTable->end()); } EXPECT_TRUE(hashTable->empty()); delete hashTable; } TEST_F( HashTableTest, tombstone ) { typedef HashEntry<int, int, IntCompare> HashEntryType; typedef HashTable<HashEntryType, IntMod3Hash, EntryFactory<HashEntryType> > HashTableTy; HashTableTy *hashTable = new HashTableTy(); bool exist; HashTableTy::entry_type* entry = 0; for (unsigned int key=0; key<100; ++key) { entry = hashTable->insert(key, exist); } EXPECT_FALSE(hashTable->empty()); int count; HashTableTy::iterator iter; for (unsigned int key=0; key<20; ++key) { count = hashTable->erase(key); EXPECT_EQ(1, count); iter = hashTable->find(key); EXPECT_TRUE(iter == hashTable->end()); } EXPECT_TRUE(80 == hashTable->numOfEntries()); for (unsigned int key=20; key<100; ++key) { iter = hashTable->find(key); EXPECT_TRUE(iter != hashTable->end()); } for (unsigned int key=0; key<20; ++key) { entry = hashTable->insert(key, exist); } EXPECT_TRUE(100 == hashTable->numOfEntries()); EXPECT_TRUE(197 == hashTable->numOfBuckets()); delete hashTable; } TEST_F( HashTableTest, rehash_test ) { typedef HashEntry<int, int, IntCompare> HashEntryType; typedef HashTable<HashEntryType, IntHash, EntryFactory<HashEntryType> > HashTableTy; HashTableTy *hashTable = new HashTableTy(0); bool exist; HashTableTy::entry_type* entry = 0; for (unsigned int key=0; key<400000; ++key) { entry = hashTable->insert(key, exist); entry->setValue(key+10); } HashTableTy::iterator iter; for (int key=0; key<400000; ++key) { iter = hashTable->find(key); EXPECT_EQ((key+10), iter.getEntry()->value()); } delete hashTable; } TEST_F( HashTableTest, bucket_iterator ) { typedef HashEntry<int, int, IntCompare> HashEntryType; typedef HashTable<HashEntryType, IntHash, EntryFactory<HashEntryType> > HashTableTy; HashTableTy *hashTable = new HashTableTy(0); bool exist; HashTableTy::entry_type* entry = 0; for (unsigned int key=0; key<400000; ++key) { entry = hashTable->insert(key, exist); entry->setValue(key+10); } HashTableTy::iterator iter, iEnd = hashTable->end(); int counter = 0; for (iter = hashTable->begin(); iter != iEnd; ++iter) { EXPECT_EQ(iter.getEntry()->key()+10, iter.getEntry()->value()); ++counter; } EXPECT_EQ(400000, counter); delete hashTable; } TEST_F( HashTableTest, chain_iterator_single ) { typedef HashEntry<int, int, IntCompare> HashEntryType; typedef HashTable<HashEntryType, IntHash, EntryFactory<HashEntryType> > HashTableTy; HashTableTy *hashTable = new HashTableTy(); bool exist; HashTableTy::entry_type* entry = 0; for (int key=0; key<16; ++key) { entry = hashTable->insert(key*37, exist); entry->setValue(key+10); } for (int key=0; key<16; ++key) { int counter = 0; HashTableTy::chain_iterator iter, iEnd = hashTable->end(key*37); for (iter = hashTable->begin(key*37); iter != iEnd; ++iter) { EXPECT_EQ(key+10, iter.getEntry()->value()); ++counter; } EXPECT_EQ(1, counter); } delete hashTable; } struct FixHash { size_t operator()(int pKey) const { return 10; } }; TEST_F( HashTableTest, chain_iterator_list ) { typedef HashEntry<int, int, IntCompare> HashEntryType; typedef HashTable<HashEntryType, FixHash, EntryFactory<HashEntryType> > HashTableTy; HashTableTy *hashTable = new HashTableTy(); bool exist; HashTableTy::entry_type* entry = 0; for (unsigned int key=0; key<16; ++key) { entry = hashTable->insert(key, exist); ASSERT_FALSE(exist); entry->setValue(key); } ASSERT_TRUE(16 == hashTable->numOfEntries()); ASSERT_TRUE(37 == hashTable->numOfBuckets()); unsigned int key = 0; int count = 0; HashTableTy::chain_iterator iter, iEnd = hashTable->end(key); for (iter = hashTable->begin(key); iter != iEnd; ++iter) { count++; } ASSERT_EQ(16, count); delete hashTable; }