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webkit / WebKit / 4cc720436197cbbb8e4c48226df34e98d98509ab / . / Tools / TestWebKitAPI / Tests / WTF / HashMap.cpp
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/*
* Copyright (C) 2011 Google Inc. All rights reserved.
* Copyright (C) 2017 Apple Inc. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY APPLE INC. AND ITS CONTRIBUTORS ``AS IS''
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
* THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR ITS CONTRIBUTORS
* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
* THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "config.h"
#include "Counters.h"
#include "DeletedAddressOfOperator.h"
#include "MoveOnly.h"
#include "RefLogger.h"
#include "Test.h"
#include <string>
#include <wtf/HashMap.h>
#include <wtf/Ref.h>
#include <wtf/text/StringConcatenateNumbers.h>
#include <wtf/text/StringHash.h>
namespace TestWebKitAPI {
typedef WTF::HashMap<int, int> IntHashMap;
TEST(WTF_HashMap, HashTableIteratorComparison)
{
IntHashMap map;
map.add(1, 2);
ASSERT_TRUE(map.begin() != map.end());
ASSERT_FALSE(map.begin() == map.end());
IntHashMap::const_iterator begin = map.begin();
ASSERT_TRUE(begin == map.begin());
ASSERT_TRUE(map.begin() == begin);
ASSERT_TRUE(begin != map.end());
ASSERT_TRUE(map.end() != begin);
ASSERT_FALSE(begin != map.begin());
ASSERT_FALSE(map.begin() != begin);
ASSERT_FALSE(begin == map.end());
ASSERT_FALSE(map.end() == begin);
}
struct TestDoubleHashTraits : HashTraits<double> {
static const int minimumTableSize = 8;
};
typedef HashMap<double, int64_t, DefaultHash<double>::Hash, TestDoubleHashTraits> DoubleHashMap;
static int bucketForKey(double key)
{
return DefaultHash<double>::Hash::hash(key) & (TestDoubleHashTraits::minimumTableSize - 1);
}
template<typename T> struct BigTableHashTraits : public HashTraits<T> {
static const int minimumTableSize = WTF::HashTableCapacityForSize<4096>::value;
};
template<typename T> struct ZeroHash : public IntHash<T> {
static unsigned hash(const T&) { return 0; }
};
TEST(WTF_HashMap, DoubleHashCollisions)
{
// The "clobber" key here is one that ends up stealing the bucket that the -0 key
// originally wants to be in. This makes the 0 and -0 keys collide and the test then
// fails unless the FloatHash::equals() implementation can distinguish them.
const double clobberKey = 6;
const double zeroKey = 0;
const double negativeZeroKey = -zeroKey;
DoubleHashMap map;
map.add(clobberKey, 1);
map.add(zeroKey, 2);
map.add(negativeZeroKey, 3);
ASSERT_EQ(bucketForKey(clobberKey), bucketForKey(negativeZeroKey));
ASSERT_EQ(map.get(clobberKey), 1);
ASSERT_EQ(map.get(zeroKey), 2);
ASSERT_EQ(map.get(negativeZeroKey), 3);
}
TEST(WTF_HashMap, MoveOnlyValues)
{
HashMap<unsigned, MoveOnly> moveOnlyValues;
for (size_t i = 0; i < 100; ++i) {
MoveOnly moveOnly(i + 1);
moveOnlyValues.set(i + 1, WTFMove(moveOnly));
}
for (size_t i = 0; i < 100; ++i) {
auto it = moveOnlyValues.find(i + 1);
ASSERT_FALSE(it == moveOnlyValues.end());
}
for (size_t i = 0; i < 50; ++i)
ASSERT_EQ(moveOnlyValues.take(i + 1).value(), i + 1);
for (size_t i = 50; i < 100; ++i)
ASSERT_TRUE(moveOnlyValues.remove(i + 1));
ASSERT_TRUE(moveOnlyValues.isEmpty());
}
TEST(WTF_HashMap, MoveOnlyKeys)
{
HashMap<MoveOnly, unsigned> moveOnlyKeys;
for (size_t i = 0; i < 100; ++i) {
MoveOnly moveOnly(i + 1);
moveOnlyKeys.set(WTFMove(moveOnly), i + 1);
}
for (size_t i = 0; i < 100; ++i) {
auto it = moveOnlyKeys.find(MoveOnly(i + 1));
ASSERT_FALSE(it == moveOnlyKeys.end());
}
for (size_t i = 0; i < 100; ++i)
ASSERT_FALSE(moveOnlyKeys.add(MoveOnly(i + 1), i + 1).isNewEntry);
for (size_t i = 0; i < 100; ++i)
ASSERT_TRUE(moveOnlyKeys.remove(MoveOnly(i + 1)));
ASSERT_TRUE(moveOnlyKeys.isEmpty());
}
TEST(WTF_HashMap, InitializerList)
{
HashMap<unsigned, std::string> map = {
{ 1, "one" },
{ 2, "two" },
{ 3, "three" },
{ 4, "four" },
};
EXPECT_EQ(4u, map.size());
EXPECT_EQ("one", map.get(1));
EXPECT_EQ("two", map.get(2));
EXPECT_EQ("three", map.get(3));
EXPECT_EQ("four", map.get(4));
EXPECT_EQ(std::string(), map.get(5));
}
TEST(WTF_HashMap, EfficientGetter)
{
HashMap<unsigned, CopyMoveCounter> map;
map.set(1, CopyMoveCounter());
{
CopyMoveCounter::TestingScope scope;
map.get(1);
EXPECT_EQ(0U, CopyMoveCounter::constructionCount);
EXPECT_EQ(1U, CopyMoveCounter::copyCount);
EXPECT_EQ(0U, CopyMoveCounter::moveCount);
}
{
CopyMoveCounter::TestingScope scope;
map.get(2);
EXPECT_EQ(1U, CopyMoveCounter::constructionCount);
EXPECT_EQ(0U, CopyMoveCounter::copyCount);
EXPECT_EQ(1U, CopyMoveCounter::moveCount);
}
}
TEST(WTF_HashMap, UniquePtrKey)
{
ConstructorDestructorCounter::TestingScope scope;
HashMap<std::unique_ptr<ConstructorDestructorCounter>, int> map;
auto uniquePtr = makeUnique<ConstructorDestructorCounter>();
map.add(WTFMove(uniquePtr), 2);
EXPECT_EQ(1u, ConstructorDestructorCounter::constructionCount);
EXPECT_EQ(0u, ConstructorDestructorCounter::destructionCount);
map.clear();
EXPECT_EQ(1u, ConstructorDestructorCounter::constructionCount);
EXPECT_EQ(1u, ConstructorDestructorCounter::destructionCount);
}
TEST(WTF_HashMap, UniquePtrKey_CustomDeleter)
{
ConstructorDestructorCounter::TestingScope constructorDestructorCounterScope;
DeleterCounter<ConstructorDestructorCounter>::TestingScope deleterCounterScope;
HashMap<std::unique_ptr<ConstructorDestructorCounter, DeleterCounter<ConstructorDestructorCounter>>, int> map;
std::unique_ptr<ConstructorDestructorCounter, DeleterCounter<ConstructorDestructorCounter>> uniquePtr(new ConstructorDestructorCounter(), DeleterCounter<ConstructorDestructorCounter>());
map.add(WTFMove(uniquePtr), 2);
EXPECT_EQ(1u, ConstructorDestructorCounter::constructionCount);
EXPECT_EQ(0u, ConstructorDestructorCounter::destructionCount);
EXPECT_EQ(0u, DeleterCounter<ConstructorDestructorCounter>::deleterCount());
map.clear();
EXPECT_EQ(1u, ConstructorDestructorCounter::constructionCount);
EXPECT_EQ(1u, ConstructorDestructorCounter::destructionCount);
EXPECT_EQ(1u, DeleterCounter<ConstructorDestructorCounter>::deleterCount());
}
TEST(WTF_HashMap, UniquePtrKey_FindUsingRawPointer)
{
HashMap<std::unique_ptr<int>, int> map;
auto uniquePtr = makeUniqueWithoutFastMallocCheck<int>(5);
int* ptr = uniquePtr.get();
map.add(WTFMove(uniquePtr), 2);
auto it = map.find(ptr);
ASSERT_TRUE(it != map.end());
EXPECT_EQ(ptr, it->key.get());
EXPECT_EQ(2, it->value);
}
TEST(WTF_HashMap, UniquePtrKey_ContainsUsingRawPointer)
{
HashMap<std::unique_ptr<int>, int> map;
auto uniquePtr = makeUniqueWithoutFastMallocCheck<int>(5);
int* ptr = uniquePtr.get();
map.add(WTFMove(uniquePtr), 2);
EXPECT_EQ(true, map.contains(ptr));
}
TEST(WTF_HashMap, UniquePtrKey_GetUsingRawPointer)
{
HashMap<std::unique_ptr<int>, int> map;
auto uniquePtr = makeUniqueWithoutFastMallocCheck<int>(5);
int* ptr = uniquePtr.get();
map.add(WTFMove(uniquePtr), 2);
int value = map.get(ptr);
EXPECT_EQ(2, value);
}
TEST(WTF_HashMap, UniquePtrKey_RemoveUsingRawPointer)
{
ConstructorDestructorCounter::TestingScope scope;
HashMap<std::unique_ptr<ConstructorDestructorCounter>, int> map;
auto uniquePtr = makeUnique<ConstructorDestructorCounter>();
ConstructorDestructorCounter* ptr = uniquePtr.get();
map.add(WTFMove(uniquePtr), 2);
EXPECT_EQ(1u, ConstructorDestructorCounter::constructionCount);
EXPECT_EQ(0u, ConstructorDestructorCounter::destructionCount);
bool result = map.remove(ptr);
EXPECT_EQ(true, result);
EXPECT_EQ(1u, ConstructorDestructorCounter::constructionCount);
EXPECT_EQ(1u, ConstructorDestructorCounter::destructionCount);
}
TEST(WTF_HashMap, UniquePtrKey_TakeUsingRawPointer)
{
ConstructorDestructorCounter::TestingScope scope;
HashMap<std::unique_ptr<ConstructorDestructorCounter>, int> map;
auto uniquePtr = makeUnique<ConstructorDestructorCounter>();
ConstructorDestructorCounter* ptr = uniquePtr.get();
map.add(WTFMove(uniquePtr), 2);
EXPECT_EQ(1u, ConstructorDestructorCounter::constructionCount);
EXPECT_EQ(0u, ConstructorDestructorCounter::destructionCount);
int result = map.take(ptr);
EXPECT_EQ(2, result);
EXPECT_EQ(1u, ConstructorDestructorCounter::constructionCount);
EXPECT_EQ(1u, ConstructorDestructorCounter::destructionCount);
}
TEST(WTF_HashMap, RefPtrKey_Add)
{
DerivedRefLogger a("a");
HashMap<RefPtr<RefLogger>, int> map;
RefPtr<RefLogger> ptr(&a);
map.add(ptr, 0);
ASSERT_STREQ("ref(a) ref(a) ", takeLogStr().c_str());
}
TEST(WTF_HashMap, RefPtrKey_AddUsingRelease)
{
DerivedRefLogger a("a");
HashMap<RefPtr<RefLogger>, int> map;
RefPtr<RefLogger> ptr(&a);
map.add(WTFMove(ptr), 0);
EXPECT_STREQ("ref(a) ", takeLogStr().c_str());
}
TEST(WTF_HashMap, RefPtrKey_AddUsingMove)
{
DerivedRefLogger a("a");
HashMap<RefPtr<RefLogger>, int> map;
RefPtr<RefLogger> ptr(&a);
map.add(WTFMove(ptr), 0);
EXPECT_STREQ("ref(a) ", takeLogStr().c_str());
}
TEST(WTF_HashMap, RefPtrKey_AddUsingRaw)
{
DerivedRefLogger a("a");
HashMap<RefPtr<RefLogger>, int> map;
RefPtr<RefLogger> ptr(&a);
map.add(ptr.get(), 0);
EXPECT_STREQ("ref(a) ref(a) ", takeLogStr().c_str());
}
TEST(WTF_HashMap, RefPtrKey_AddKeyAlreadyPresent)
{
DerivedRefLogger a("a");
HashMap<RefPtr<RefLogger>, int> map;
{
RefPtr<RefLogger> ptr(&a);
map.add(ptr, 0);
}
EXPECT_STREQ("ref(a) ref(a) deref(a) ", takeLogStr().c_str());
{
RefPtr<RefLogger> ptr2(&a);
auto addResult = map.add(ptr2, 0);
EXPECT_FALSE(addResult.isNewEntry);
}
EXPECT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
}
TEST(WTF_HashMap, RefPtrKey_AddUsingReleaseKeyAlreadyPresent)
{
DerivedRefLogger a("a");
HashMap<RefPtr<RefLogger>, int> map;
{
RefPtr<RefLogger> ptr(&a);
map.add(ptr, 0);
}
EXPECT_STREQ("ref(a) ref(a) deref(a) ", takeLogStr().c_str());
{
RefPtr<RefLogger> ptr2(&a);
auto addResult = map.add(WTFMove(ptr2), 0);
EXPECT_FALSE(addResult.isNewEntry);
}
EXPECT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
}
TEST(WTF_HashMap, RefPtrKey_AddUsingMoveKeyAlreadyPresent)
{
DerivedRefLogger a("a");
HashMap<RefPtr<RefLogger>, int> map;
{
RefPtr<RefLogger> ptr(&a);
map.add(ptr, 0);
}
EXPECT_STREQ("ref(a) ref(a) deref(a) ", takeLogStr().c_str());
{
RefPtr<RefLogger> ptr2(&a);
auto addResult = map.add(WTFMove(ptr2), 0);
EXPECT_FALSE(addResult.isNewEntry);
}
EXPECT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
}
TEST(WTF_HashMap, RefPtrKey_Set)
{
DerivedRefLogger a("a");
HashMap<RefPtr<RefLogger>, int> map;
RefPtr<RefLogger> ptr(&a);
map.set(ptr, 0);
ASSERT_STREQ("ref(a) ref(a) ", takeLogStr().c_str());
}
TEST(WTF_HashMap, RefPtrKey_SetUsingRelease)
{
DerivedRefLogger a("a");
HashMap<RefPtr<RefLogger>, int> map;
RefPtr<RefLogger> ptr(&a);
map.set(WTFMove(ptr), 0);
EXPECT_STREQ("ref(a) ", takeLogStr().c_str());
}
TEST(WTF_HashMap, RefPtrKey_SetUsingMove)
{
DerivedRefLogger a("a");
HashMap<RefPtr<RefLogger>, int> map;
RefPtr<RefLogger> ptr(&a);
map.set(WTFMove(ptr), 0);
EXPECT_STREQ("ref(a) ", takeLogStr().c_str());
}
TEST(WTF_HashMap, RefPtrKey_SetUsingRaw)
{
DerivedRefLogger a("a");
HashMap<RefPtr<RefLogger>, int> map;
RefPtr<RefLogger> ptr(&a);
map.set(ptr.get(), 0);
EXPECT_STREQ("ref(a) ref(a) ", takeLogStr().c_str());
}
TEST(WTF_HashMap, RefPtrKey_SetKeyAlreadyPresent)
{
DerivedRefLogger a("a");
HashMap<RefPtr<RefLogger>, int> map;
RefPtr<RefLogger> ptr(&a);
map.set(ptr, 0);
EXPECT_STREQ("ref(a) ref(a) ", takeLogStr().c_str());
{
RefPtr<RefLogger> ptr2(&a);
auto addResult = map.set(ptr2, 1);
EXPECT_FALSE(addResult.isNewEntry);
EXPECT_EQ(1, map.get(ptr.get()));
}
EXPECT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
}
TEST(WTF_HashMap, RefPtrKey_SetUsingReleaseKeyAlreadyPresent)
{
DerivedRefLogger a("a");
HashMap<RefPtr<RefLogger>, int> map;
RefPtr<RefLogger> ptr(&a);
map.set(ptr, 0);
EXPECT_STREQ("ref(a) ref(a) ", takeLogStr().c_str());
{
RefPtr<RefLogger> ptr2(&a);
auto addResult = map.set(WTFMove(ptr2), 1);
EXPECT_FALSE(addResult.isNewEntry);
EXPECT_EQ(1, map.get(ptr.get()));
}
EXPECT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
}
TEST(WTF_HashMap, RefPtrKey_SetUsingMoveKeyAlreadyPresent)
{
DerivedRefLogger a("a");
HashMap<RefPtr<RefLogger>, int> map;
RefPtr<RefLogger> ptr(&a);
map.set(ptr, 0);
EXPECT_STREQ("ref(a) ref(a) ", takeLogStr().c_str());
{
RefPtr<RefLogger> ptr2(&a);
auto addResult = map.set(WTFMove(ptr2), 1);
EXPECT_FALSE(addResult.isNewEntry);
EXPECT_EQ(1, map.get(ptr.get()));
}
EXPECT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
}
TEST(WTF_HashMap, Ensure)
{
HashMap<unsigned, unsigned> map;
{
auto addResult = map.ensure(1, [] { return 1; });
EXPECT_EQ(1u, addResult.iterator->value);
EXPECT_EQ(1u, addResult.iterator->key);
EXPECT_TRUE(addResult.isNewEntry);
auto addResult2 = map.ensure(1, [] { return 2; });
EXPECT_EQ(1u, addResult2.iterator->value);
EXPECT_EQ(1u, addResult2.iterator->key);
EXPECT_FALSE(addResult2.isNewEntry);
}
}
TEST(WTF_HashMap, Ensure_MoveOnlyValues)
{
HashMap<unsigned, MoveOnly> moveOnlyValues;
{
auto addResult = moveOnlyValues.ensure(1, [] { return MoveOnly(1); });
EXPECT_EQ(1u, addResult.iterator->value.value());
EXPECT_EQ(1u, addResult.iterator->key);
EXPECT_TRUE(addResult.isNewEntry);
auto addResult2 = moveOnlyValues.ensure(1, [] { return MoveOnly(2); });
EXPECT_EQ(1u, addResult2.iterator->value.value());
EXPECT_EQ(1u, addResult2.iterator->key);
EXPECT_FALSE(addResult2.isNewEntry);
}
}
TEST(WTF_HashMap, Ensure_UniquePointer)
{
HashMap<unsigned, std::unique_ptr<unsigned>> map;
{
auto addResult = map.ensure(1, [] { return makeUniqueWithoutFastMallocCheck<unsigned>(1); });
EXPECT_EQ(1u, *map.get(1));
EXPECT_EQ(1u, *addResult.iterator->value.get());
EXPECT_EQ(1u, addResult.iterator->key);
EXPECT_TRUE(addResult.isNewEntry);
auto addResult2 = map.ensure(1, [] { return makeUniqueWithoutFastMallocCheck<unsigned>(2); });
EXPECT_EQ(1u, *map.get(1));
EXPECT_EQ(1u, *addResult2.iterator->value.get());
EXPECT_EQ(1u, addResult2.iterator->key);
EXPECT_FALSE(addResult2.isNewEntry);
}
}
TEST(WTF_HashMap, Ensure_RefPtr)
{
DerivedRefLogger a("a");
HashMap<unsigned, RefPtr<RefLogger>> map;
map.ensure(1, [&] { return RefPtr<RefLogger>(&a); });
EXPECT_STREQ("ref(a) ", takeLogStr().c_str());
map.ensure(1, [&] { return RefPtr<RefLogger>(&a); });
EXPECT_STREQ("", takeLogStr().c_str());
}
class ObjectWithRefLogger {
WTF_MAKE_FAST_ALLOCATED;
public:
ObjectWithRefLogger(Ref<RefLogger>&& logger)
: m_logger(WTFMove(logger))
{
}
Ref<RefLogger> m_logger;
};
void testMovingUsingEnsure(Ref<RefLogger>&& logger)
{
HashMap<unsigned, std::unique_ptr<ObjectWithRefLogger>> map;
map.ensure(1, [&] { return makeUnique<ObjectWithRefLogger>(WTFMove(logger)); });
}
void testMovingUsingAdd(Ref<RefLogger>&& logger)
{
HashMap<unsigned, std::unique_ptr<ObjectWithRefLogger>> map;
auto& slot = map.add(1, nullptr).iterator->value;
slot = makeUnique<ObjectWithRefLogger>(WTFMove(logger));
}
TEST(WTF_HashMap, Ensure_LambdasCapturingByReference)
{
{
DerivedRefLogger a("a");
Ref<RefLogger> ref(a);
testMovingUsingEnsure(WTFMove(ref));
EXPECT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
}
{
DerivedRefLogger a("a");
Ref<RefLogger> ref(a);
testMovingUsingAdd(WTFMove(ref));
EXPECT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
}
}
TEST(WTF_HashMap, ValueIsDestructedOnRemove)
{
struct DestructorObserver {
DestructorObserver() = default;
DestructorObserver(bool* destructed)
: destructed(destructed)
{
}
~DestructorObserver()
{
if (destructed)
*destructed = true;
}
DestructorObserver(DestructorObserver&& other)
: destructed(other.destructed)
{
other.destructed = nullptr;
}
DestructorObserver& operator=(DestructorObserver&& other)
{
destructed = other.destructed;
other.destructed = nullptr;
return *this;
}
bool* destructed { nullptr };
};
HashMap<int, DestructorObserver> map;
bool destructed = false;
map.add(5, DestructorObserver { &destructed });
EXPECT_FALSE(destructed);
bool removeResult = map.remove(5);
EXPECT_TRUE(removeResult);
EXPECT_TRUE(destructed);
}
struct DerefObserver {
WTF_MAKE_STRUCT_FAST_ALLOCATED;
NEVER_INLINE void ref()
{
++count;
}
NEVER_INLINE void deref()
{
--count;
observedBucket = bucketAddress->get();
}
unsigned count { 1 };
const RefPtr<DerefObserver>* bucketAddress { nullptr };
const DerefObserver* observedBucket { nullptr };
};
TEST(WTF_HashMap, RefPtrNotZeroedBeforeDeref)
{
auto observer = makeUnique<DerefObserver>();
HashMap<RefPtr<DerefObserver>, int> map;
map.add(adoptRef(observer.get()), 5);
auto iterator = map.find(observer.get());
EXPECT_TRUE(iterator != map.end());
observer->bucketAddress = &iterator->key;
EXPECT_TRUE(observer->observedBucket == nullptr);
EXPECT_TRUE(map.remove(observer.get()));
// It if fine to either leave the old value intact at deletion or already set it to the deleted
// value.
// A zero would be a incorrect outcome as it would mean we nulled the bucket before an opaque
// call.
EXPECT_TRUE(observer->observedBucket == observer.get() || observer->observedBucket == RefPtr<DerefObserver>::hashTableDeletedValue());
EXPECT_EQ(observer->count, 0u);
}
TEST(WTF_HashMap, Ref_Key)
{
{
RefLogger a("a");
HashMap<Ref<RefLogger>, int> map;
Ref<RefLogger> ref(a);
map.add(WTFMove(ref), 1);
}
ASSERT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
{
RefLogger a("a");
HashMap<Ref<RefLogger>, int> map;
Ref<RefLogger> ref(a);
map.set(WTFMove(ref), 1);
}
ASSERT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
{
RefLogger a("a");
HashMap<Ref<RefLogger>, int> map;
Ref<RefLogger> refA(a);
map.add(WTFMove(refA), 1);
Ref<RefLogger> refA2(a);
map.set(WTFMove(refA2), 1);
}
ASSERT_STREQ("ref(a) ref(a) deref(a) deref(a) ", takeLogStr().c_str());
{
RefLogger a("a");
HashMap<Ref<RefLogger>, int> map;
Ref<RefLogger> ref(a);
map.ensure(WTFMove(ref), []() {
return 1;
});
}
ASSERT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
{
RefLogger a("a");
HashMap<Ref<RefLogger>, int> map;
Ref<RefLogger> ref(a);
map.add(WTFMove(ref), 1);
auto it = map.find(&a);
ASSERT_TRUE(it != map.end());
ASSERT_EQ(it->key.ptr(), &a);
ASSERT_EQ(it->value, 1);
}
ASSERT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
{
RefLogger a("a");
HashMap<Ref<RefLogger>, int> map;
Ref<RefLogger> ref(a);
map.add(WTFMove(ref), 1);
map.remove(&a);
}
ASSERT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
{
RefLogger a("a");
HashMap<Ref<RefLogger>, int> map;
Ref<RefLogger> ref(a);
map.add(WTFMove(ref), 1);
int i = map.take(&a);
ASSERT_EQ(i, 1);
}
ASSERT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
{
HashMap<Ref<RefLogger>, int> map;
for (int i = 0; i < 64; ++i) {
// FIXME: All of these RefLogger objects leak. No big deal for a test I guess.
Ref<RefLogger> ref = adoptRef(*new RefLogger("a"));
auto* pointer = ref.ptr();
map.add(WTFMove(ref), i + 1);
ASSERT_TRUE(map.contains(pointer));
}
}
ASSERT_STREQ("deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) ", takeLogStr().c_str());
}
TEST(WTF_HashMap, Ref_Value)
{
{
RefLogger a("a");
HashMap<int, Ref<RefLogger>> map;
Ref<RefLogger> ref(a);
map.add(1, WTFMove(ref));
}
ASSERT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
{
RefLogger a("a");
HashMap<int, Ref<RefLogger>> map;
Ref<RefLogger> ref(a);
map.set(1, WTFMove(ref));
}
ASSERT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
{
RefLogger a("a");
RefLogger b("b");
HashMap<int, Ref<RefLogger>> map;
Ref<RefLogger> refA(a);
map.add(1, WTFMove(refA));
Ref<RefLogger> refB(b);
map.set(1, WTFMove(refB));
}
ASSERT_STREQ("ref(a) ref(b) deref(a) deref(b) ", takeLogStr().c_str());
{
RefLogger a("a");
HashMap<int, Ref<RefLogger>> map;
Ref<RefLogger> ref(a);
map.add(1, WTFMove(ref));
auto aGet = map.get(1);
ASSERT_EQ(aGet, &a);
}
ASSERT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
{
HashMap<int, Ref<RefLogger>> map;
auto emptyGet = map.get(1);
ASSERT_TRUE(emptyGet == nullptr);
}
{
RefLogger a("a");
HashMap<int, Ref<RefLogger>> map;
Ref<RefLogger> ref(a);
map.add(1, WTFMove(ref));
auto aOut = map.take(1);
ASSERT_TRUE(static_cast<bool>(aOut));
ASSERT_EQ(&a, aOut.value().ptr());
}
ASSERT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
{
HashMap<int, Ref<RefLogger>> map;
auto emptyTake = map.take(1);
ASSERT_FALSE(static_cast<bool>(emptyTake));
}
{
RefLogger a("a");
HashMap<int, Ref<RefLogger>> map;
Ref<RefLogger> ref(a);
map.add(1, WTFMove(ref));
map.remove(1);
}
ASSERT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
{
RefLogger a("a");
HashMap<int, Ref<RefLogger>> map;
map.ensure(1, [&]() mutable {
Ref<RefLogger> ref(a);
return ref;
});
}
ASSERT_STREQ("ref(a) deref(a) ", takeLogStr().c_str());
{
HashMap<int, Ref<RefLogger>> map;
for (int i = 0; i < 64; ++i) {
// FIXME: All of these RefLogger objects leak. No big deal for a test I guess.
Ref<RefLogger> ref = adoptRef(*new RefLogger("a"));
map.add(i + 1, WTFMove(ref));
ASSERT_TRUE(map.contains(i + 1));
}
}
ASSERT_STREQ("deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) deref(a) ", takeLogStr().c_str());
}
TEST(WTF_HashMap, DeletedAddressOfOperator)
{
HashMap<int, DeletedAddressOfOperator> map1;
for (auto& value : map1.values())
(void)value;
}
TEST(WTF_HashMap, RefMappedToNonZeroEmptyValue)
{
class Value {
public:
Value() = default;
Value(Value&&) = default;
Value(const Value&) = default;
Value& operator=(Value&&) = default;
Value(int32_t f)
: m_field(f)
{ }
int32_t field() { return m_field; }
private:
int32_t m_field { 0xbadbeef };
};
class Key : public RefCounted<Key> {
Key() = default;
public:
static Ref<Key> create() { return adoptRef(*new Key); }
};
static_assert(!WTF::HashTraits<Value>::emptyValueIsZero, "");
HashMap<Ref<Key>, Value> map;
Vector<std::pair<Ref<Key>, int32_t>> vectorMap;
for (int32_t i = 0; i < 160; ++i) {
Ref<Key> key = Key::create();
map.add(Ref<Key>(key.get()), Value { i });
vectorMap.append({ WTFMove(key), i });
}
for (auto& pair : vectorMap)
ASSERT_EQ(pair.second, map.get(pair.first).field());
for (auto& pair : vectorMap)
ASSERT_TRUE(map.remove(pair.first));
}
TEST(WTF_HashMap, Random_Empty)
{
HashMap<unsigned, unsigned> map;
auto result = map.random();
ASSERT_EQ(result, map.end());
}
TEST(WTF_HashMap, Random_WrapAround)
{
HashMap<unsigned, unsigned, ZeroHash<unsigned>, BigTableHashTraits<unsigned>> map;
map.add(1, 1);
auto result = map.random();
ASSERT_EQ(result, map.begin());
}
TEST(WTF_HashMap, Random_IsEvenlyDistributed)
{
HashMap<unsigned, unsigned, DefaultHash<unsigned>::Hash, WTF::UnsignedWithZeroKeyHashTraits<unsigned>> map;
map.add(0, 0);
map.add(1, 1);
unsigned zeros = 0;
unsigned ones = 0;
for (unsigned i = 0; i < 1000; ++i) {
auto it = map.random();
if (!it->value)
++zeros;
else {
ASSERT_EQ(it->value, 1u);
++ones;
}
}
ASSERT_EQ(zeros + ones, 1000u);
ASSERT_LE(zeros, 600u);
ASSERT_LE(ones, 600u);
}
TEST(WTF_HashMap, ReserveInitialCapacity)
{
HashMap<String, String> map;
EXPECT_EQ(0u, map.size());
map.reserveInitialCapacity(9999);
EXPECT_EQ(0u, map.size());
for (int i = 0; i < 9999; ++i)
map.add(makeString("foo", i), makeString("bar", i));
EXPECT_EQ(9999u, map.size());
EXPECT_TRUE(map.contains("foo3"_str));
EXPECT_STREQ("bar3", map.get("foo3"_str).utf8().data());
for (int i = 0; i < 9999; ++i)
map.add(makeString("excess", i), makeString("baz", i));
EXPECT_EQ(9999u + 9999u, map.size());
for (int i = 0; i < 9999; ++i)
EXPECT_TRUE(map.remove(makeString("foo", i)));
EXPECT_EQ(9999u, map.size());
EXPECT_STREQ("baz3", map.get("excess3"_str).utf8().data());
for (int i = 0; i < 9999; ++i)
EXPECT_TRUE(map.remove(makeString("excess", i)));
EXPECT_EQ(0u, map.size());
HashMap<String, String> map2;
map2.reserveInitialCapacity(9999);
EXPECT_FALSE(map2.remove("foo1"_s));
for (int i = 0; i < 2000; ++i)
map2.add(makeString("foo", i), makeString("bar", i));
EXPECT_EQ(2000u, map2.size());
for (int i = 0; i < 2000; ++i)
EXPECT_TRUE(map2.remove(makeString("foo", i)));
EXPECT_EQ(0u, map2.size());
}
TEST(WTF_HashMap, Random_IsEvenlyDistributedAfterRemove)
{
for (size_t tableSize = 2; tableSize <= 2 * 6; ++tableSize) { // Our hash tables shrink at a load factor of 1 / 6.
HashMap<unsigned, unsigned, DefaultHash<unsigned>::Hash, WTF::UnsignedWithZeroKeyHashTraits<unsigned>> map;
for (size_t i = 0; i < tableSize; ++i)
map.add(i, i);
for (size_t i = 2; i < tableSize; ++i)
map.remove(i);
unsigned zeros = 0;
unsigned ones = 0;
for (unsigned i = 0; i < 1000; ++i) {
auto it = map.random();
if (!it->value)
++zeros;
else {
ASSERT_EQ(it->value, 1u);
++ones;
}
}
ASSERT_EQ(zeros + ones, 1000u);
ASSERT_LE(zeros, 600u);
ASSERT_LE(ones, 600u);
}
}
} // namespace TestWebKitAPI