llvm/unittests/ADT/DenseMapTest.cpp - llvm-project - Git at Google

 //===- llvm/unittest/ADT/DenseMapMap.cpp - DenseMap unit tests --*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/ADT/DenseMap.h"
 #include "gtest/gtest.h"
 #include <map>
 #include <set>

 using namespace llvm;

 namespace {

 uint32_t getTestKey(int i, uint32_t *) { return i; }
 uint32_t getTestValue(int i, uint32_t *) { return 42 + i; }

 uint32_t *getTestKey(int i, uint32_t **) {
   static uint32_t dummy_arr1[8192];
   assert(i < 8192 && "Only support 8192 dummy keys.");
   return &dummy_arr1[i];
 }
 uint32_t *getTestValue(int i, uint32_t **) {
   static uint32_t dummy_arr1[8192];
   assert(i < 8192 && "Only support 8192 dummy keys.");
   return &dummy_arr1[i];
 }

 /// A test class that tries to check that construction and destruction
 /// occur correctly.
 class CtorTester {
   static std::set<CtorTester *> Constructed;
   int Value;

 public:
   explicit CtorTester(int Value = 0) : Value(Value) {
     EXPECT_TRUE(Constructed.insert(this).second);
   }
   CtorTester(uint32_t Value) : Value(Value) {
     EXPECT_TRUE(Constructed.insert(this).second);
   }
   CtorTester(const CtorTester &Arg) : Value(Arg.Value) {
     EXPECT_TRUE(Constructed.insert(this).second);
   }
   CtorTester &operator=(const CtorTester &) = default;
   ~CtorTester() {
     EXPECT_EQ(1u, Constructed.erase(this));
   }
   operator uint32_t() const { return Value; }

   int getValue() const { return Value; }
   bool operator==(const CtorTester &RHS) const { return Value == RHS.Value; }
 };

 std::set<CtorTester *> CtorTester::Constructed;

 struct CtorTesterMapInfo {
   static inline CtorTester getEmptyKey() { return CtorTester(-1); }
   static inline CtorTester getTombstoneKey() { return CtorTester(-2); }
   static unsigned getHashValue(const CtorTester &Val) {
     return Val.getValue() * 37u;
   }
   static bool isEqual(const CtorTester &LHS, const CtorTester &RHS) {
     return LHS == RHS;
   }
 };

 CtorTester getTestKey(int i, CtorTester *) { return CtorTester(i); }
 CtorTester getTestValue(int i, CtorTester *) { return CtorTester(42 + i); }

 // Test fixture, with helper functions implemented by forwarding to global
 // function overloads selected by component types of the type parameter. This
 // allows all of the map implementations to be tested with shared
 // implementations of helper routines.
 template <typename T>
 class DenseMapTest : public ::testing::Test {
 protected:
   T Map;

   static typename T::key_type *const dummy_key_ptr;
   static typename T::mapped_type *const dummy_value_ptr;

   typename T::key_type getKey(int i = 0) {
     return getTestKey(i, dummy_key_ptr);
   }
   typename T::mapped_type getValue(int i = 0) {
     return getTestValue(i, dummy_value_ptr);
   }
 };

 template <typename T>
 typename T::key_type *const DenseMapTest<T>::dummy_key_ptr = nullptr;
 template <typename T>
 typename T::mapped_type *const DenseMapTest<T>::dummy_value_ptr = nullptr;

 // Register these types for testing.
 typedef ::testing::Types<DenseMap<uint32_t, uint32_t>,
                          DenseMap<uint32_t *, uint32_t *>,
                          DenseMap<CtorTester, CtorTester, CtorTesterMapInfo>,
                          SmallDenseMap<uint32_t, uint32_t>,
                          SmallDenseMap<uint32_t *, uint32_t *>,
                          SmallDenseMap<CtorTester, CtorTester, 4,
                                        CtorTesterMapInfo>
                          > DenseMapTestTypes;
 TYPED_TEST_CASE(DenseMapTest, DenseMapTestTypes);

 // Empty map tests
 TYPED_TEST(DenseMapTest, EmptyIntMapTest) {
   // Size tests
   EXPECT_EQ(0u, this->Map.size());
   EXPECT_TRUE(this->Map.empty());

   // Iterator tests
   EXPECT_TRUE(this->Map.begin() == this->Map.end());

   // Lookup tests
   EXPECT_FALSE(this->Map.count(this->getKey()));
   EXPECT_TRUE(this->Map.find(this->getKey()) == this->Map.end());
   EXPECT_EQ(typename TypeParam::mapped_type(),
             this->Map.lookup(this->getKey()));
 }

 // Constant map tests
 TYPED_TEST(DenseMapTest, ConstEmptyMapTest) {
   const TypeParam &ConstMap = this->Map;
   EXPECT_EQ(0u, ConstMap.size());
   EXPECT_TRUE(ConstMap.empty());
   EXPECT_TRUE(ConstMap.begin() == ConstMap.end());
 }

 // A map with a single entry
 TYPED_TEST(DenseMapTest, SingleEntryMapTest) {
   this->Map[this->getKey()] = this->getValue();

   // Size tests
   EXPECT_EQ(1u, this->Map.size());
   EXPECT_FALSE(this->Map.begin() == this->Map.end());
   EXPECT_FALSE(this->Map.empty());

   // Iterator tests
   typename TypeParam::iterator it = this->Map.begin();
   EXPECT_EQ(this->getKey(), it->first);
   EXPECT_EQ(this->getValue(), it->second);
   ++it;
   EXPECT_TRUE(it == this->Map.end());

   // Lookup tests
   EXPECT_TRUE(this->Map.count(this->getKey()));
   EXPECT_TRUE(this->Map.find(this->getKey()) == this->Map.begin());
   EXPECT_EQ(this->getValue(), this->Map.lookup(this->getKey()));
   EXPECT_EQ(this->getValue(), this->Map[this->getKey()]);
 }

 // Test clear() method
 TYPED_TEST(DenseMapTest, ClearTest) {
   this->Map[this->getKey()] = this->getValue();
   this->Map.clear();

   EXPECT_EQ(0u, this->Map.size());
   EXPECT_TRUE(this->Map.empty());
   EXPECT_TRUE(this->Map.begin() == this->Map.end());
 }

 // Test erase(iterator) method
 TYPED_TEST(DenseMapTest, EraseTest) {
   this->Map[this->getKey()] = this->getValue();
   this->Map.erase(this->Map.begin());

   EXPECT_EQ(0u, this->Map.size());
   EXPECT_TRUE(this->Map.empty());
   EXPECT_TRUE(this->Map.begin() == this->Map.end());
 }

 // Test erase(value) method
 TYPED_TEST(DenseMapTest, EraseTest2) {
   this->Map[this->getKey()] = this->getValue();
   this->Map.erase(this->getKey());

   EXPECT_EQ(0u, this->Map.size());
   EXPECT_TRUE(this->Map.empty());
   EXPECT_TRUE(this->Map.begin() == this->Map.end());
 }

 // Test insert() method
 TYPED_TEST(DenseMapTest, InsertTest) {
   this->Map.insert(std::make_pair(this->getKey(), this->getValue()));
   EXPECT_EQ(1u, this->Map.size());
   EXPECT_EQ(this->getValue(), this->Map[this->getKey()]);
 }

 // Test copy constructor method
 TYPED_TEST(DenseMapTest, CopyConstructorTest) {
   this->Map[this->getKey()] = this->getValue();
   TypeParam copyMap(this->Map);

   EXPECT_EQ(1u, copyMap.size());
   EXPECT_EQ(this->getValue(), copyMap[this->getKey()]);
 }

 // Test copy constructor method where SmallDenseMap isn't small.
 TYPED_TEST(DenseMapTest, CopyConstructorNotSmallTest) {
   for (int Key = 0; Key < 5; ++Key)
     this->Map[this->getKey(Key)] = this->getValue(Key);
   TypeParam copyMap(this->Map);

   EXPECT_EQ(5u, copyMap.size());
   for (int Key = 0; Key < 5; ++Key)
     EXPECT_EQ(this->getValue(Key), copyMap[this->getKey(Key)]);
 }

 // Test copying from a default-constructed map.
 TYPED_TEST(DenseMapTest, CopyConstructorFromDefaultTest) {
   TypeParam copyMap(this->Map);

   EXPECT_TRUE(copyMap.empty());
 }

 // Test copying from an empty map where SmallDenseMap isn't small.
 TYPED_TEST(DenseMapTest, CopyConstructorFromEmptyTest) {
   for (int Key = 0; Key < 5; ++Key)
     this->Map[this->getKey(Key)] = this->getValue(Key);
   this->Map.clear();
   TypeParam copyMap(this->Map);

   EXPECT_TRUE(copyMap.empty());
 }

 // Test assignment operator method
 TYPED_TEST(DenseMapTest, AssignmentTest) {
   this->Map[this->getKey()] = this->getValue();
   TypeParam copyMap = this->Map;

   EXPECT_EQ(1u, copyMap.size());
   EXPECT_EQ(this->getValue(), copyMap[this->getKey()]);

   // test self-assignment.
   copyMap = static_cast<TypeParam &>(copyMap);
   EXPECT_EQ(1u, copyMap.size());
   EXPECT_EQ(this->getValue(), copyMap[this->getKey()]);
 }

 TYPED_TEST(DenseMapTest, AssignmentTestNotSmall) {
   for (int Key = 0; Key < 5; ++Key)
     this->Map[this->getKey(Key)] = this->getValue(Key);
   TypeParam copyMap = this->Map;

   EXPECT_EQ(5u, copyMap.size());
   for (int Key = 0; Key < 5; ++Key)
     EXPECT_EQ(this->getValue(Key), copyMap[this->getKey(Key)]);

   // test self-assignment.
   copyMap = static_cast<TypeParam &>(copyMap);
   EXPECT_EQ(5u, copyMap.size());
   for (int Key = 0; Key < 5; ++Key)
     EXPECT_EQ(this->getValue(Key), copyMap[this->getKey(Key)]);
 }

 // Test swap method
 TYPED_TEST(DenseMapTest, SwapTest) {
   this->Map[this->getKey()] = this->getValue();
   TypeParam otherMap;

   this->Map.swap(otherMap);
   EXPECT_EQ(0u, this->Map.size());
   EXPECT_TRUE(this->Map.empty());
   EXPECT_EQ(1u, otherMap.size());
   EXPECT_EQ(this->getValue(), otherMap[this->getKey()]);

   this->Map.swap(otherMap);
   EXPECT_EQ(0u, otherMap.size());
   EXPECT_TRUE(otherMap.empty());
   EXPECT_EQ(1u, this->Map.size());
   EXPECT_EQ(this->getValue(), this->Map[this->getKey()]);

   // Make this more interesting by inserting 100 numbers into the map.
   for (int i = 0; i < 100; ++i)
     this->Map[this->getKey(i)] = this->getValue(i);

   this->Map.swap(otherMap);
   EXPECT_EQ(0u, this->Map.size());
   EXPECT_TRUE(this->Map.empty());
   EXPECT_EQ(100u, otherMap.size());
   for (int i = 0; i < 100; ++i)
     EXPECT_EQ(this->getValue(i), otherMap[this->getKey(i)]);

   this->Map.swap(otherMap);
   EXPECT_EQ(0u, otherMap.size());
   EXPECT_TRUE(otherMap.empty());
   EXPECT_EQ(100u, this->Map.size());
   for (int i = 0; i < 100; ++i)
     EXPECT_EQ(this->getValue(i), this->Map[this->getKey(i)]);
 }

 // A more complex iteration test
 TYPED_TEST(DenseMapTest, IterationTest) {
   bool visited[100];
   std::map<typename TypeParam::key_type, unsigned> visitedIndex;

   // Insert 100 numbers into the map
   for (int i = 0; i < 100; ++i) {
     visited[i] = false;
     visitedIndex[this->getKey(i)] = i;

     this->Map[this->getKey(i)] = this->getValue(i);
   }

   // Iterate over all numbers and mark each one found.
   for (typename TypeParam::iterator it = this->Map.begin();
        it != this->Map.end(); ++it)
     visited[visitedIndex[it->first]] = true;

   // Ensure every number was visited.
   for (int i = 0; i < 100; ++i)
     ASSERT_TRUE(visited[i]) << "Entry #" << i << " was never visited";
 }

 // const_iterator test
 TYPED_TEST(DenseMapTest, ConstIteratorTest) {
   // Check conversion from iterator to const_iterator.
   typename TypeParam::iterator it = this->Map.begin();
   typename TypeParam::const_iterator cit(it);
   EXPECT_TRUE(it == cit);

   // Check copying of const_iterators.
   typename TypeParam::const_iterator cit2(cit);
   EXPECT_TRUE(cit == cit2);
 }

 namespace {
 // Simple class that counts how many moves and copy happens when growing a map
 struct CountCopyAndMove {
   static int Move;
   static int Copy;
   CountCopyAndMove() {}

   CountCopyAndMove(const CountCopyAndMove &) { Copy++; }
   CountCopyAndMove &operator=(const CountCopyAndMove &) {
     Copy++;
     return *this;
   }
   CountCopyAndMove(CountCopyAndMove &&) { Move++; }
   CountCopyAndMove &operator=(const CountCopyAndMove &&) {
     Move++;
     return *this;
   }
 };
 int CountCopyAndMove::Copy = 0;
 int CountCopyAndMove::Move = 0;

 } // anonymous namespace

 // Test initializer list construction.
 TEST(DenseMapCustomTest, InitializerList) {
   DenseMap<int, int> M({{0, 0}, {0, 1}, {1, 2}});
   EXPECT_EQ(2u, M.size());
   EXPECT_EQ(1u, M.count(0));
   EXPECT_EQ(0, M[0]);
   EXPECT_EQ(1u, M.count(1));
   EXPECT_EQ(2, M[1]);
 }

 // Test initializer list construction.
 TEST(DenseMapCustomTest, EqualityComparison) {
   DenseMap<int, int> M1({{0, 0}, {1, 2}});
   DenseMap<int, int> M2({{0, 0}, {1, 2}});
   DenseMap<int, int> M3({{0, 0}, {1, 3}});

   EXPECT_EQ(M1, M2);
   EXPECT_NE(M1, M3);
 }

 // Test for the default minimum size of a DenseMap
 TEST(DenseMapCustomTest, DefaultMinReservedSizeTest) {
   // IF THIS VALUE CHANGE, please update InitialSizeTest, InitFromIterator, and
   // ReserveTest as well!
   const int ExpectedInitialBucketCount = 64;
   // Formula from DenseMap::getMinBucketToReserveForEntries()
   const int ExpectedMaxInitialEntries = ExpectedInitialBucketCount * 3 / 4 - 1;

   DenseMap<int, CountCopyAndMove> Map;
   // Will allocate 64 buckets
   Map.reserve(1);
   unsigned MemorySize = Map.getMemorySize();
   CountCopyAndMove::Copy = 0;
   CountCopyAndMove::Move = 0;
   for (int i = 0; i < ExpectedMaxInitialEntries; ++i)
     Map.insert(std::pair<int, CountCopyAndMove>(std::piecewise_construct,
                                                 std::forward_as_tuple(i),
                                                 std::forward_as_tuple()));
   // Check that we didn't grow
   EXPECT_EQ(MemorySize, Map.getMemorySize());
   // Check that move was called the expected number of times
   EXPECT_EQ(ExpectedMaxInitialEntries, CountCopyAndMove::Move);
   // Check that no copy occurred
   EXPECT_EQ(0, CountCopyAndMove::Copy);

   // Adding one extra element should grow the map
   Map.insert(std::pair<int, CountCopyAndMove>(
       std::piecewise_construct,
       std::forward_as_tuple(ExpectedMaxInitialEntries),
       std::forward_as_tuple()));
   // Check that we grew
   EXPECT_NE(MemorySize, Map.getMemorySize());
   // Check that move was called the expected number of times
   //  This relies on move-construction elision, and cannot be reliably tested.
   //   EXPECT_EQ(ExpectedMaxInitialEntries + 2, CountCopyAndMove::Move);
   // Check that no copy occurred
   EXPECT_EQ(0, CountCopyAndMove::Copy);
 }

 // Make sure creating the map with an initial size of N actually gives us enough
 // buckets to insert N items without increasing allocation size.
 TEST(DenseMapCustomTest, InitialSizeTest) {
   // Test a few different sizes, 48 is *not* a random choice: we need a value
   // that is 2/3 of a power of two to stress the grow() condition, and the power
   // of two has to be at least 64 because of minimum size allocation in the
   // DenseMap (see DefaultMinReservedSizeTest). 66 is a value just above the
   // 64 default init.
   for (auto Size : {1, 2, 48, 66}) {
     DenseMap<int, CountCopyAndMove> Map(Size);
     unsigned MemorySize = Map.getMemorySize();
     CountCopyAndMove::Copy = 0;
     CountCopyAndMove::Move = 0;
     for (int i = 0; i < Size; ++i)
       Map.insert(std::pair<int, CountCopyAndMove>(std::piecewise_construct,
                                                   std::forward_as_tuple(i),
                                                   std::forward_as_tuple()));
     // Check that we didn't grow
     EXPECT_EQ(MemorySize, Map.getMemorySize());
     // Check that move was called the expected number of times
     EXPECT_EQ(Size, CountCopyAndMove::Move);
     // Check that no copy occurred
     EXPECT_EQ(0, CountCopyAndMove::Copy);
   }
 }

 // Make sure creating the map with a iterator range does not trigger grow()
 TEST(DenseMapCustomTest, InitFromIterator) {
   std::vector<std::pair<int, CountCopyAndMove>> Values;
   // The size is a random value greater than 64 (hardcoded DenseMap min init)
   const int Count = 65;
   for (int i = 0; i < Count; i++)
     Values.emplace_back(i, CountCopyAndMove());

   CountCopyAndMove::Move = 0;
   CountCopyAndMove::Copy = 0;
   DenseMap<int, CountCopyAndMove> Map(Values.begin(), Values.end());
   // Check that no move occurred
   EXPECT_EQ(0, CountCopyAndMove::Move);
   // Check that copy was called the expected number of times
   EXPECT_EQ(Count, CountCopyAndMove::Copy);
 }

 // Make sure reserve actually gives us enough buckets to insert N items
 // without increasing allocation size.
 TEST(DenseMapCustomTest, ReserveTest) {
   // Test a few different size, 48 is *not* a random choice: we need a value
   // that is 2/3 of a power of two to stress the grow() condition, and the power
   // of two has to be at least 64 because of minimum size allocation in the
   // DenseMap (see DefaultMinReservedSizeTest). 66 is a value just above the
   // 64 default init.
   for (auto Size : {1, 2, 48, 66}) {
     DenseMap<int, CountCopyAndMove> Map;
     Map.reserve(Size);
     unsigned MemorySize = Map.getMemorySize();
     CountCopyAndMove::Copy = 0;
     CountCopyAndMove::Move = 0;
     for (int i = 0; i < Size; ++i)
       Map.insert(std::pair<int, CountCopyAndMove>(std::piecewise_construct,
                                                   std::forward_as_tuple(i),
                                                   std::forward_as_tuple()));
     // Check that we didn't grow
     EXPECT_EQ(MemorySize, Map.getMemorySize());
     // Check that move was called the expected number of times
     EXPECT_EQ(Size, CountCopyAndMove::Move);
     // Check that no copy occurred
     EXPECT_EQ(0, CountCopyAndMove::Copy);
   }
 }

 // Make sure DenseMap works with StringRef keys.
 TEST(DenseMapCustomTest, StringRefTest) {
   DenseMap<StringRef, int> M;

   M["a"] = 1;
   M["b"] = 2;
   M["c"] = 3;

   EXPECT_EQ(3u, M.size());
   EXPECT_EQ(1, M.lookup("a"));
   EXPECT_EQ(2, M.lookup("b"));
   EXPECT_EQ(3, M.lookup("c"));

   EXPECT_EQ(0, M.lookup("q"));

   // Test the empty string, spelled various ways.
   EXPECT_EQ(0, M.lookup(""));
   EXPECT_EQ(0, M.lookup(StringRef()));
   EXPECT_EQ(0, M.lookup(StringRef("a", 0)));
   M[""] = 42;
   EXPECT_EQ(42, M.lookup(""));
   EXPECT_EQ(42, M.lookup(StringRef()));
   EXPECT_EQ(42, M.lookup(StringRef("a", 0)));
 }

 // Key traits that allows lookup with either an unsigned or char* key;
 // In the latter case, "a" == 0, "b" == 1 and so on.
 struct TestDenseMapInfo {
   static inline unsigned getEmptyKey() { return ~0; }
   static inline unsigned getTombstoneKey() { return ~0U - 1; }
   static unsigned getHashValue(const unsigned& Val) { return Val * 37U; }
   static unsigned getHashValue(const char* Val) {
     return (unsigned)(Val[0] - 'a') * 37U;
   }
   static bool isEqual(const unsigned& LHS, const unsigned& RHS) {
     return LHS == RHS;
   }
   static bool isEqual(const char* LHS, const unsigned& RHS) {
     return (unsigned)(LHS[0] - 'a') == RHS;
   }
 };

 // find_as() tests
 TEST(DenseMapCustomTest, FindAsTest) {
   DenseMap<unsigned, unsigned, TestDenseMapInfo> map;
   map[0] = 1;
   map[1] = 2;
   map[2] = 3;

   // Size tests
   EXPECT_EQ(3u, map.size());

   // Normal lookup tests
   EXPECT_EQ(1u, map.count(1));
   EXPECT_EQ(1u, map.find(0)->second);
   EXPECT_EQ(2u, map.find(1)->second);
   EXPECT_EQ(3u, map.find(2)->second);
   EXPECT_TRUE(map.find(3) == map.end());

   // find_as() tests
   EXPECT_EQ(1u, map.find_as("a")->second);
   EXPECT_EQ(2u, map.find_as("b")->second);
   EXPECT_EQ(3u, map.find_as("c")->second);
   EXPECT_TRUE(map.find_as("d") == map.end());
 }

 struct ContiguousDenseMapInfo {
   static inline unsigned getEmptyKey() { return ~0; }
   static inline unsigned getTombstoneKey() { return ~0U - 1; }
   static unsigned getHashValue(const unsigned& Val) { return Val; }
   static bool isEqual(const unsigned& LHS, const unsigned& RHS) {
     return LHS == RHS;
   }
 };

 // Test that filling a small dense map with exactly the number of elements in
 // the map grows to have enough space for an empty bucket.
 TEST(DenseMapCustomTest, SmallDenseMapGrowTest) {
   SmallDenseMap<unsigned, unsigned, 32, ContiguousDenseMapInfo> map;
   // Add some number of elements, then delete a few to leave us some tombstones.
   // If we just filled the map with 32 elements we'd grow because of not enough
   // tombstones which masks the issue here.
   for (unsigned i = 0; i < 20; ++i)
     map[i] = i + 1;
   for (unsigned i = 0; i < 10; ++i)
     map.erase(i);
   for (unsigned i = 20; i < 32; ++i)
     map[i] = i + 1;

   // Size tests
   EXPECT_EQ(22u, map.size());

   // Try to find an element which doesn't exist.  There was a bug in
   // SmallDenseMap which led to a map with num elements == small capacity not
   // having an empty bucket any more.  Finding an element not in the map would
   // therefore never terminate.
   EXPECT_TRUE(map.find(32) == map.end());
 }

 TEST(DenseMapCustomTest, LargeSmallDenseMapCompaction) {
   SmallDenseMap<unsigned, unsigned, 128, ContiguousDenseMapInfo> map;
   // Fill to < 3/4 load.
   for (unsigned i = 0; i < 95; ++i)
     map[i] = i;
   // And erase, leaving behind tombstones.
   for (unsigned i = 0; i < 95; ++i)
     map.erase(i);
   // Fill further, so that less than 1/8 are empty, but still below 3/4 load.
   for (unsigned i = 95; i < 128; ++i)
     map[i] = i;

   EXPECT_EQ(33u, map.size());
   // Similar to the previous test, check for a non-existing element, as an
   // indirect check that tombstones have been removed.
   EXPECT_TRUE(map.find(0) == map.end());
 }

 TEST(DenseMapCustomTest, TryEmplaceTest) {
   DenseMap<int, std::unique_ptr<int>> Map;
   std::unique_ptr<int> P(new int(2));
   auto Try1 = Map.try_emplace(0, new int(1));
   EXPECT_TRUE(Try1.second);
   auto Try2 = Map.try_emplace(0, std::move(P));
   EXPECT_FALSE(Try2.second);
   EXPECT_EQ(Try1.first, Try2.first);
   EXPECT_NE(nullptr, P);
 }

 TEST(DenseMapCustomTest, ConstTest) {
   // Test that const pointers work okay for count and find, even when the
   // underlying map is a non-const pointer.
   DenseMap<int *, int> Map;
   int A;
   int *B = &A;
   const int *C = &A;
   Map.insert({B, 0});
   EXPECT_EQ(Map.count(B), 1u);
   EXPECT_EQ(Map.count(C), 1u);
   EXPECT_NE(Map.find(B), Map.end());
   EXPECT_NE(Map.find(C), Map.end());
 }

 struct IncompleteStruct;

 TEST(DenseMapCustomTest, OpaquePointerKey) {
   // Test that we can use a pointer to an incomplete type as a DenseMap key.
   // This is an important build time optimization, since many classes have
   // DenseMap members.
   DenseMap<IncompleteStruct *, int> Map;
   int Keys[3] = {0, 0, 0};
   IncompleteStruct *K1 = reinterpret_cast<IncompleteStruct *>(&Keys[0]);
   IncompleteStruct *K2 = reinterpret_cast<IncompleteStruct *>(&Keys[1]);
   IncompleteStruct *K3 = reinterpret_cast<IncompleteStruct *>(&Keys[2]);
   Map.insert({K1, 1});
   Map.insert({K2, 2});
   Map.insert({K3, 3});
   EXPECT_EQ(Map.count(K1), 1u);
   EXPECT_EQ(Map[K1], 1);
   EXPECT_EQ(Map[K2], 2);
   EXPECT_EQ(Map[K3], 3);
   Map.clear();
   EXPECT_EQ(Map.find(K1), Map.end());
   EXPECT_EQ(Map.find(K2), Map.end());
   EXPECT_EQ(Map.find(K3), Map.end());
 }
 }
	//===- llvm/unittest/ADT/DenseMapMap.cpp - DenseMap unit tests --- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/ADT/DenseMap.h"
	#include "gtest/gtest.h"
	#include <map>
	#include <set>

	using namespace llvm;

	namespace {

	uint32_t getTestKey(int i, uint32_t *) { return i; }
	uint32_t getTestValue(int i, uint32_t *) { return 42 + i; }

	uint32_t getTestKey(int i, uint32_t *) {
	static uint32_t dummy_arr1[8192];
	assert(i < 8192 && "Only support 8192 dummy keys.");
	return &dummy_arr1[i];
	}
	uint32_t getTestValue(int i, uint32_t *) {
	static uint32_t dummy_arr1[8192];
	assert(i < 8192 && "Only support 8192 dummy keys.");
	return &dummy_arr1[i];
	}

	/// A test class that tries to check that construction and destruction
	/// occur correctly.
	class CtorTester {
	static std::set<CtorTester *> Constructed;
	int Value;

	public:
	explicit CtorTester(int Value = 0) : Value(Value) {
	EXPECT_TRUE(Constructed.insert(this).second);
	}
	CtorTester(uint32_t Value) : Value(Value) {
	EXPECT_TRUE(Constructed.insert(this).second);
	}
	CtorTester(const CtorTester &Arg) : Value(Arg.Value) {
	EXPECT_TRUE(Constructed.insert(this).second);
	}
	CtorTester &operator=(const CtorTester &) = default;
	~CtorTester() {
	EXPECT_EQ(1u, Constructed.erase(this));
	}
	operator uint32_t() const { return Value; }

	int getValue() const { return Value; }
	bool operator==(const CtorTester &RHS) const { return Value == RHS.Value; }
	};

	std::set<CtorTester *> CtorTester::Constructed;

	struct CtorTesterMapInfo {
	static inline CtorTester getEmptyKey() { return CtorTester(-1); }
	static inline CtorTester getTombstoneKey() { return CtorTester(-2); }
	static unsigned getHashValue(const CtorTester &Val) {
	return Val.getValue() * 37u;
	}
	static bool isEqual(const CtorTester &LHS, const CtorTester &RHS) {
	return LHS == RHS;
	}
	};

	CtorTester getTestKey(int i, CtorTester *) { return CtorTester(i); }
	CtorTester getTestValue(int i, CtorTester *) { return CtorTester(42 + i); }

	// Test fixture, with helper functions implemented by forwarding to global
	// function overloads selected by component types of the type parameter. This
	// allows all of the map implementations to be tested with shared
	// implementations of helper routines.
	template <typename T>
	class DenseMapTest : public ::testing::Test {
	protected:
	T Map;

	static typename T::key_type *const dummy_key_ptr;
	static typename T::mapped_type *const dummy_value_ptr;

	typename T::key_type getKey(int i = 0) {
	return getTestKey(i, dummy_key_ptr);
	}
	typename T::mapped_type getValue(int i = 0) {
	return getTestValue(i, dummy_value_ptr);
	}
	};

	template <typename T>
	typename T::key_type *const DenseMapTest<T>::dummy_key_ptr = nullptr;
	template <typename T>
	typename T::mapped_type *const DenseMapTest<T>::dummy_value_ptr = nullptr;

	// Register these types for testing.
	typedef ::testing::Types<DenseMap<uint32_t, uint32_t>,
	DenseMap<uint32_t , uint32_t >,
	DenseMap<CtorTester, CtorTester, CtorTesterMapInfo>,
	SmallDenseMap<uint32_t, uint32_t>,
	SmallDenseMap<uint32_t , uint32_t >,
	SmallDenseMap<CtorTester, CtorTester, 4,
	CtorTesterMapInfo>
	> DenseMapTestTypes;
	TYPED_TEST_CASE(DenseMapTest, DenseMapTestTypes);

	// Empty map tests
	TYPED_TEST(DenseMapTest, EmptyIntMapTest) {
	// Size tests
	EXPECT_EQ(0u, this->Map.size());
	EXPECT_TRUE(this->Map.empty());

	// Iterator tests
	EXPECT_TRUE(this->Map.begin() == this->Map.end());

	// Lookup tests
	EXPECT_FALSE(this->Map.count(this->getKey()));
	EXPECT_TRUE(this->Map.find(this->getKey()) == this->Map.end());
	EXPECT_EQ(typename TypeParam::mapped_type(),
	this->Map.lookup(this->getKey()));
	}

	// Constant map tests
	TYPED_TEST(DenseMapTest, ConstEmptyMapTest) {
	const TypeParam &ConstMap = this->Map;
	EXPECT_EQ(0u, ConstMap.size());
	EXPECT_TRUE(ConstMap.empty());
	EXPECT_TRUE(ConstMap.begin() == ConstMap.end());
	}

	// A map with a single entry
	TYPED_TEST(DenseMapTest, SingleEntryMapTest) {
	this->Map[this->getKey()] = this->getValue();

	// Size tests
	EXPECT_EQ(1u, this->Map.size());
	EXPECT_FALSE(this->Map.begin() == this->Map.end());
	EXPECT_FALSE(this->Map.empty());

	// Iterator tests
	typename TypeParam::iterator it = this->Map.begin();
	EXPECT_EQ(this->getKey(), it->first);
	EXPECT_EQ(this->getValue(), it->second);
	++it;
	EXPECT_TRUE(it == this->Map.end());

	// Lookup tests
	EXPECT_TRUE(this->Map.count(this->getKey()));
	EXPECT_TRUE(this->Map.find(this->getKey()) == this->Map.begin());
	EXPECT_EQ(this->getValue(), this->Map.lookup(this->getKey()));
	EXPECT_EQ(this->getValue(), this->Map[this->getKey()]);
	}

	// Test clear() method
	TYPED_TEST(DenseMapTest, ClearTest) {
	this->Map[this->getKey()] = this->getValue();
	this->Map.clear();

	EXPECT_EQ(0u, this->Map.size());
	EXPECT_TRUE(this->Map.empty());
	EXPECT_TRUE(this->Map.begin() == this->Map.end());
	}

	// Test erase(iterator) method
	TYPED_TEST(DenseMapTest, EraseTest) {
	this->Map[this->getKey()] = this->getValue();
	this->Map.erase(this->Map.begin());

	EXPECT_EQ(0u, this->Map.size());
	EXPECT_TRUE(this->Map.empty());
	EXPECT_TRUE(this->Map.begin() == this->Map.end());
	}

	// Test erase(value) method
	TYPED_TEST(DenseMapTest, EraseTest2) {
	this->Map[this->getKey()] = this->getValue();
	this->Map.erase(this->getKey());

	EXPECT_EQ(0u, this->Map.size());
	EXPECT_TRUE(this->Map.empty());
	EXPECT_TRUE(this->Map.begin() == this->Map.end());
	}

	// Test insert() method
	TYPED_TEST(DenseMapTest, InsertTest) {
	this->Map.insert(std::make_pair(this->getKey(), this->getValue()));
	EXPECT_EQ(1u, this->Map.size());
	EXPECT_EQ(this->getValue(), this->Map[this->getKey()]);
	}

	// Test copy constructor method
	TYPED_TEST(DenseMapTest, CopyConstructorTest) {
	this->Map[this->getKey()] = this->getValue();
	TypeParam copyMap(this->Map);

	EXPECT_EQ(1u, copyMap.size());
	EXPECT_EQ(this->getValue(), copyMap[this->getKey()]);
	}

	// Test copy constructor method where SmallDenseMap isn't small.
	TYPED_TEST(DenseMapTest, CopyConstructorNotSmallTest) {
	for (int Key = 0; Key < 5; ++Key)
	this->Map[this->getKey(Key)] = this->getValue(Key);
	TypeParam copyMap(this->Map);

	EXPECT_EQ(5u, copyMap.size());
	for (int Key = 0; Key < 5; ++Key)
	EXPECT_EQ(this->getValue(Key), copyMap[this->getKey(Key)]);
	}

	// Test copying from a default-constructed map.
	TYPED_TEST(DenseMapTest, CopyConstructorFromDefaultTest) {
	TypeParam copyMap(this->Map);

	EXPECT_TRUE(copyMap.empty());
	}

	// Test copying from an empty map where SmallDenseMap isn't small.
	TYPED_TEST(DenseMapTest, CopyConstructorFromEmptyTest) {
	for (int Key = 0; Key < 5; ++Key)
	this->Map[this->getKey(Key)] = this->getValue(Key);
	this->Map.clear();
	TypeParam copyMap(this->Map);

	EXPECT_TRUE(copyMap.empty());
	}

	// Test assignment operator method
	TYPED_TEST(DenseMapTest, AssignmentTest) {
	this->Map[this->getKey()] = this->getValue();
	TypeParam copyMap = this->Map;

	EXPECT_EQ(1u, copyMap.size());
	EXPECT_EQ(this->getValue(), copyMap[this->getKey()]);

	// test self-assignment.
	copyMap = static_cast<TypeParam &>(copyMap);
	EXPECT_EQ(1u, copyMap.size());
	EXPECT_EQ(this->getValue(), copyMap[this->getKey()]);
	}

	TYPED_TEST(DenseMapTest, AssignmentTestNotSmall) {
	for (int Key = 0; Key < 5; ++Key)
	this->Map[this->getKey(Key)] = this->getValue(Key);
	TypeParam copyMap = this->Map;

	EXPECT_EQ(5u, copyMap.size());
	for (int Key = 0; Key < 5; ++Key)
	EXPECT_EQ(this->getValue(Key), copyMap[this->getKey(Key)]);

	// test self-assignment.
	copyMap = static_cast<TypeParam &>(copyMap);
	EXPECT_EQ(5u, copyMap.size());
	for (int Key = 0; Key < 5; ++Key)
	EXPECT_EQ(this->getValue(Key), copyMap[this->getKey(Key)]);
	}

	// Test swap method
	TYPED_TEST(DenseMapTest, SwapTest) {
	this->Map[this->getKey()] = this->getValue();
	TypeParam otherMap;

	this->Map.swap(otherMap);
	EXPECT_EQ(0u, this->Map.size());
	EXPECT_TRUE(this->Map.empty());
	EXPECT_EQ(1u, otherMap.size());
	EXPECT_EQ(this->getValue(), otherMap[this->getKey()]);

	this->Map.swap(otherMap);
	EXPECT_EQ(0u, otherMap.size());
	EXPECT_TRUE(otherMap.empty());
	EXPECT_EQ(1u, this->Map.size());
	EXPECT_EQ(this->getValue(), this->Map[this->getKey()]);

	// Make this more interesting by inserting 100 numbers into the map.
	for (int i = 0; i < 100; ++i)
	this->Map[this->getKey(i)] = this->getValue(i);

	this->Map.swap(otherMap);
	EXPECT_EQ(0u, this->Map.size());
	EXPECT_TRUE(this->Map.empty());
	EXPECT_EQ(100u, otherMap.size());
	for (int i = 0; i < 100; ++i)
	EXPECT_EQ(this->getValue(i), otherMap[this->getKey(i)]);

	this->Map.swap(otherMap);
	EXPECT_EQ(0u, otherMap.size());
	EXPECT_TRUE(otherMap.empty());
	EXPECT_EQ(100u, this->Map.size());
	for (int i = 0; i < 100; ++i)
	EXPECT_EQ(this->getValue(i), this->Map[this->getKey(i)]);
	}

	// A more complex iteration test
	TYPED_TEST(DenseMapTest, IterationTest) {
	bool visited[100];
	std::map<typename TypeParam::key_type, unsigned> visitedIndex;

	// Insert 100 numbers into the map
	for (int i = 0; i < 100; ++i) {
	visited[i] = false;
	visitedIndex[this->getKey(i)] = i;

	this->Map[this->getKey(i)] = this->getValue(i);
	}

	// Iterate over all numbers and mark each one found.
	for (typename TypeParam::iterator it = this->Map.begin();
	it != this->Map.end(); ++it)
	visited[visitedIndex[it->first]] = true;

	// Ensure every number was visited.
	for (int i = 0; i < 100; ++i)
	ASSERT_TRUE(visited[i]) << "Entry #" << i << " was never visited";
	}

	// const_iterator test
	TYPED_TEST(DenseMapTest, ConstIteratorTest) {
	// Check conversion from iterator to const_iterator.
	typename TypeParam::iterator it = this->Map.begin();
	typename TypeParam::const_iterator cit(it);
	EXPECT_TRUE(it == cit);

	// Check copying of const_iterators.
	typename TypeParam::const_iterator cit2(cit);
	EXPECT_TRUE(cit == cit2);
	}

	namespace {
	// Simple class that counts how many moves and copy happens when growing a map
	struct CountCopyAndMove {
	static int Move;
	static int Copy;
	CountCopyAndMove() {}

	CountCopyAndMove(const CountCopyAndMove &) { Copy++; }
	CountCopyAndMove &operator=(const CountCopyAndMove &) {
	Copy++;
	return *this;
	}
	CountCopyAndMove(CountCopyAndMove &&) { Move++; }
	CountCopyAndMove &operator=(const CountCopyAndMove &&) {
	Move++;
	return *this;
	}
	};
	int CountCopyAndMove::Copy = 0;
	int CountCopyAndMove::Move = 0;

	} // anonymous namespace

	// Test initializer list construction.
	TEST(DenseMapCustomTest, InitializerList) {
	DenseMap<int, int> M({{0, 0}, {0, 1}, {1, 2}});
	EXPECT_EQ(2u, M.size());
	EXPECT_EQ(1u, M.count(0));
	EXPECT_EQ(0, M[0]);
	EXPECT_EQ(1u, M.count(1));
	EXPECT_EQ(2, M[1]);
	}

	// Test initializer list construction.
	TEST(DenseMapCustomTest, EqualityComparison) {
	DenseMap<int, int> M1({{0, 0}, {1, 2}});
	DenseMap<int, int> M2({{0, 0}, {1, 2}});
	DenseMap<int, int> M3({{0, 0}, {1, 3}});

	EXPECT_EQ(M1, M2);
	EXPECT_NE(M1, M3);
	}

	// Test for the default minimum size of a DenseMap
	TEST(DenseMapCustomTest, DefaultMinReservedSizeTest) {
	// IF THIS VALUE CHANGE, please update InitialSizeTest, InitFromIterator, and
	// ReserveTest as well!
	const int ExpectedInitialBucketCount = 64;
	// Formula from DenseMap::getMinBucketToReserveForEntries()
	const int ExpectedMaxInitialEntries = ExpectedInitialBucketCount * 3 / 4 - 1;

	DenseMap<int, CountCopyAndMove> Map;
	// Will allocate 64 buckets
	Map.reserve(1);
	unsigned MemorySize = Map.getMemorySize();
	CountCopyAndMove::Copy = 0;
	CountCopyAndMove::Move = 0;
	for (int i = 0; i < ExpectedMaxInitialEntries; ++i)
	Map.insert(std::pair<int, CountCopyAndMove>(std::piecewise_construct,
	std::forward_as_tuple(i),
	std::forward_as_tuple()));
	// Check that we didn't grow
	EXPECT_EQ(MemorySize, Map.getMemorySize());
	// Check that move was called the expected number of times
	EXPECT_EQ(ExpectedMaxInitialEntries, CountCopyAndMove::Move);
	// Check that no copy occurred
	EXPECT_EQ(0, CountCopyAndMove::Copy);

	// Adding one extra element should grow the map
	Map.insert(std::pair<int, CountCopyAndMove>(
	std::piecewise_construct,
	std::forward_as_tuple(ExpectedMaxInitialEntries),
	std::forward_as_tuple()));
	// Check that we grew
	EXPECT_NE(MemorySize, Map.getMemorySize());
	// Check that move was called the expected number of times
	// This relies on move-construction elision, and cannot be reliably tested.
	// EXPECT_EQ(ExpectedMaxInitialEntries + 2, CountCopyAndMove::Move);
	// Check that no copy occurred
	EXPECT_EQ(0, CountCopyAndMove::Copy);
	}

	// Make sure creating the map with an initial size of N actually gives us enough
	// buckets to insert N items without increasing allocation size.
	TEST(DenseMapCustomTest, InitialSizeTest) {
	// Test a few different sizes, 48 is not a random choice: we need a value
	// that is 2/3 of a power of two to stress the grow() condition, and the power
	// of two has to be at least 64 because of minimum size allocation in the
	// DenseMap (see DefaultMinReservedSizeTest). 66 is a value just above the
	// 64 default init.
	for (auto Size : {1, 2, 48, 66}) {
	DenseMap<int, CountCopyAndMove> Map(Size);
	unsigned MemorySize = Map.getMemorySize();
	CountCopyAndMove::Copy = 0;
	CountCopyAndMove::Move = 0;
	for (int i = 0; i < Size; ++i)
	Map.insert(std::pair<int, CountCopyAndMove>(std::piecewise_construct,
	std::forward_as_tuple(i),
	std::forward_as_tuple()));
	// Check that we didn't grow
	EXPECT_EQ(MemorySize, Map.getMemorySize());
	// Check that move was called the expected number of times
	EXPECT_EQ(Size, CountCopyAndMove::Move);
	// Check that no copy occurred
	EXPECT_EQ(0, CountCopyAndMove::Copy);
	}
	}

	// Make sure creating the map with a iterator range does not trigger grow()
	TEST(DenseMapCustomTest, InitFromIterator) {
	std::vector<std::pair<int, CountCopyAndMove>> Values;
	// The size is a random value greater than 64 (hardcoded DenseMap min init)
	const int Count = 65;
	for (int i = 0; i < Count; i++)
	Values.emplace_back(i, CountCopyAndMove());

	CountCopyAndMove::Move = 0;
	CountCopyAndMove::Copy = 0;
	DenseMap<int, CountCopyAndMove> Map(Values.begin(), Values.end());
	// Check that no move occurred
	EXPECT_EQ(0, CountCopyAndMove::Move);
	// Check that copy was called the expected number of times
	EXPECT_EQ(Count, CountCopyAndMove::Copy);
	}

	// Make sure reserve actually gives us enough buckets to insert N items
	// without increasing allocation size.
	TEST(DenseMapCustomTest, ReserveTest) {
	// Test a few different size, 48 is not a random choice: we need a value
	// that is 2/3 of a power of two to stress the grow() condition, and the power
	// of two has to be at least 64 because of minimum size allocation in the
	// DenseMap (see DefaultMinReservedSizeTest). 66 is a value just above the
	// 64 default init.
	for (auto Size : {1, 2, 48, 66}) {
	DenseMap<int, CountCopyAndMove> Map;
	Map.reserve(Size);
	unsigned MemorySize = Map.getMemorySize();
	CountCopyAndMove::Copy = 0;
	CountCopyAndMove::Move = 0;
	for (int i = 0; i < Size; ++i)
	Map.insert(std::pair<int, CountCopyAndMove>(std::piecewise_construct,
	std::forward_as_tuple(i),
	std::forward_as_tuple()));
	// Check that we didn't grow
	EXPECT_EQ(MemorySize, Map.getMemorySize());
	// Check that move was called the expected number of times
	EXPECT_EQ(Size, CountCopyAndMove::Move);
	// Check that no copy occurred
	EXPECT_EQ(0, CountCopyAndMove::Copy);
	}
	}

	// Make sure DenseMap works with StringRef keys.
	TEST(DenseMapCustomTest, StringRefTest) {
	DenseMap<StringRef, int> M;

	M["a"] = 1;
	M["b"] = 2;
	M["c"] = 3;

	EXPECT_EQ(3u, M.size());
	EXPECT_EQ(1, M.lookup("a"));
	EXPECT_EQ(2, M.lookup("b"));
	EXPECT_EQ(3, M.lookup("c"));

	EXPECT_EQ(0, M.lookup("q"));

	// Test the empty string, spelled various ways.
	EXPECT_EQ(0, M.lookup(""));
	EXPECT_EQ(0, M.lookup(StringRef()));
	EXPECT_EQ(0, M.lookup(StringRef("a", 0)));
	M[""] = 42;
	EXPECT_EQ(42, M.lookup(""));
	EXPECT_EQ(42, M.lookup(StringRef()));
	EXPECT_EQ(42, M.lookup(StringRef("a", 0)));
	}

	// Key traits that allows lookup with either an unsigned or char* key;
	// In the latter case, "a" == 0, "b" == 1 and so on.
	struct TestDenseMapInfo {
	static inline unsigned getEmptyKey() { return ~0; }
	static inline unsigned getTombstoneKey() { return ~0U - 1; }
	static unsigned getHashValue(const unsigned& Val) { return Val * 37U; }
	static unsigned getHashValue(const char* Val) {
	return (unsigned)(Val[0] - 'a') * 37U;
	}
	static bool isEqual(const unsigned& LHS, const unsigned& RHS) {
	return LHS == RHS;
	}
	static bool isEqual(const char* LHS, const unsigned& RHS) {
	return (unsigned)(LHS[0] - 'a') == RHS;
	}
	};

	// find_as() tests
	TEST(DenseMapCustomTest, FindAsTest) {
	DenseMap<unsigned, unsigned, TestDenseMapInfo> map;
	map[0] = 1;
	map[1] = 2;
	map[2] = 3;

	// Size tests
	EXPECT_EQ(3u, map.size());

	// Normal lookup tests
	EXPECT_EQ(1u, map.count(1));
	EXPECT_EQ(1u, map.find(0)->second);
	EXPECT_EQ(2u, map.find(1)->second);
	EXPECT_EQ(3u, map.find(2)->second);
	EXPECT_TRUE(map.find(3) == map.end());

	// find_as() tests
	EXPECT_EQ(1u, map.find_as("a")->second);
	EXPECT_EQ(2u, map.find_as("b")->second);
	EXPECT_EQ(3u, map.find_as("c")->second);
	EXPECT_TRUE(map.find_as("d") == map.end());
	}

	struct ContiguousDenseMapInfo {
	static inline unsigned getEmptyKey() { return ~0; }
	static inline unsigned getTombstoneKey() { return ~0U - 1; }
	static unsigned getHashValue(const unsigned& Val) { return Val; }
	static bool isEqual(const unsigned& LHS, const unsigned& RHS) {
	return LHS == RHS;
	}
	};

	// Test that filling a small dense map with exactly the number of elements in
	// the map grows to have enough space for an empty bucket.
	TEST(DenseMapCustomTest, SmallDenseMapGrowTest) {
	SmallDenseMap<unsigned, unsigned, 32, ContiguousDenseMapInfo> map;
	// Add some number of elements, then delete a few to leave us some tombstones.
	// If we just filled the map with 32 elements we'd grow because of not enough
	// tombstones which masks the issue here.
	for (unsigned i = 0; i < 20; ++i)
	map[i] = i + 1;
	for (unsigned i = 0; i < 10; ++i)
	map.erase(i);
	for (unsigned i = 20; i < 32; ++i)
	map[i] = i + 1;

	// Size tests
	EXPECT_EQ(22u, map.size());

	// Try to find an element which doesn't exist. There was a bug in
	// SmallDenseMap which led to a map with num elements == small capacity not
	// having an empty bucket any more. Finding an element not in the map would
	// therefore never terminate.
	EXPECT_TRUE(map.find(32) == map.end());
	}

	TEST(DenseMapCustomTest, LargeSmallDenseMapCompaction) {
	SmallDenseMap<unsigned, unsigned, 128, ContiguousDenseMapInfo> map;
	// Fill to < 3/4 load.
	for (unsigned i = 0; i < 95; ++i)
	map[i] = i;
	// And erase, leaving behind tombstones.
	for (unsigned i = 0; i < 95; ++i)
	map.erase(i);
	// Fill further, so that less than 1/8 are empty, but still below 3/4 load.
	for (unsigned i = 95; i < 128; ++i)
	map[i] = i;

	EXPECT_EQ(33u, map.size());
	// Similar to the previous test, check for a non-existing element, as an
	// indirect check that tombstones have been removed.
	EXPECT_TRUE(map.find(0) == map.end());
	}

	TEST(DenseMapCustomTest, TryEmplaceTest) {
	DenseMap<int, std::unique_ptr<int>> Map;
	std::unique_ptr<int> P(new int(2));
	auto Try1 = Map.try_emplace(0, new int(1));
	EXPECT_TRUE(Try1.second);
	auto Try2 = Map.try_emplace(0, std::move(P));
	EXPECT_FALSE(Try2.second);
	EXPECT_EQ(Try1.first, Try2.first);
	EXPECT_NE(nullptr, P);
	}

	TEST(DenseMapCustomTest, ConstTest) {
	// Test that const pointers work okay for count and find, even when the
	// underlying map is a non-const pointer.
	DenseMap<int *, int> Map;
	int A;
	int *B = &A;
	const int *C = &A;
	Map.insert({B, 0});
	EXPECT_EQ(Map.count(B), 1u);
	EXPECT_EQ(Map.count(C), 1u);
	EXPECT_NE(Map.find(B), Map.end());
	EXPECT_NE(Map.find(C), Map.end());
	}

	struct IncompleteStruct;

	TEST(DenseMapCustomTest, OpaquePointerKey) {
	// Test that we can use a pointer to an incomplete type as a DenseMap key.
	// This is an important build time optimization, since many classes have
	// DenseMap members.
	DenseMap<IncompleteStruct *, int> Map;
	int Keys[3] = {0, 0, 0};
	IncompleteStruct K1 = reinterpret_cast<IncompleteStruct >(&Keys[0]);
	IncompleteStruct K2 = reinterpret_cast<IncompleteStruct >(&Keys[1]);
	IncompleteStruct K3 = reinterpret_cast<IncompleteStruct >(&Keys[2]);
	Map.insert({K1, 1});
	Map.insert({K2, 2});
	Map.insert({K3, 3});
	EXPECT_EQ(Map.count(K1), 1u);
	EXPECT_EQ(Map[K1], 1);
	EXPECT_EQ(Map[K2], 2);
	EXPECT_EQ(Map[K3], 3);
	Map.clear();
	EXPECT_EQ(Map.find(K1), Map.end());
	EXPECT_EQ(Map.find(K2), Map.end());
	EXPECT_EQ(Map.find(K3), Map.end());
	}
	}