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|
/////////////////////////////////////////////////////////////////////////////
// Copyright (c) Electronic Arts Inc. All rights reserved.
/////////////////////////////////////////////////////////////////////////////
#include <EABase/eabase.h>
#include "EASTLTest.h"
#include "GetTypeName.h"
#include <EAStdC/EAString.h>
#include <EAStdC/EAStopwatch.h>
#include <EASTL/core_allocator_adapter.h>
#include <EASTL/core_allocator.h>
#include <EASTL/intrusive_ptr.h>
#include <EASTL/linked_array.h>
#include <EASTL/linked_ptr.h>
#include <EASTL/safe_ptr.h>
#include <EASTL/scoped_array.h>
#include <EASTL/scoped_ptr.h>
#include <EASTL/shared_array.h>
#include <EASTL/shared_ptr.h>
#include <EASTL/unique_ptr.h>
#include <EASTL/weak_ptr.h>
#include <eathread/eathread_thread.h>
EA_DISABLE_ALL_VC_WARNINGS()
#include <stdio.h>
#include <string.h>
#ifdef EA_PLATFORM_WINDOWS
#ifndef WIN32_LEAN_AND_MEAN
#define WIN32_LEAN_AND_MEAN
#endif
#include <Windows.h>
#elif defined(EA_PLATFORM_ANDROID)
#include <android/log.h>
#endif
EA_RESTORE_ALL_VC_WARNINGS()
EA_DISABLE_VC_WARNING(4702 4800) // 4702: unreachable code
// 4800: forcing value to bool 'true' or 'false'
namespace SmartPtrTest
{
/// CustomDeleter
///
/// Used for testing unique_ptr deleter overrides. Otherwise acts the same as the default deleter.
///
struct CustomDeleter
{
template <typename T>
void operator()(const T* p) const // We use a const argument type in order to be most flexible with what types we accept.
{ delete const_cast<T*>(p); }
CustomDeleter() {}
CustomDeleter(const CustomDeleter&) {}
CustomDeleter(CustomDeleter&&) {}
CustomDeleter& operator=(const CustomDeleter&) { return *this; }
CustomDeleter& operator=(CustomDeleter&&) { return *this; }
};
struct CustomArrayDeleter
{
template <typename T>
void operator()(const T* p) const // We use a const argument type in order to be most flexible with what types we accept.
{ delete[] const_cast<T*>(p); }
CustomArrayDeleter() {}
CustomArrayDeleter(const CustomArrayDeleter&) {}
CustomArrayDeleter(CustomArrayDeleter&&) {}
CustomArrayDeleter& operator=(const CustomArrayDeleter&) { return *this; }
CustomArrayDeleter& operator=(CustomArrayDeleter&&) { return *this; }
};
/// A
///
/// This is used for various tests.
///
struct A
{
char mc;
static int mCount;
A(char c = 0)
: mc(c) { ++mCount; }
A(const A& x)
: mc(x.mc) { ++mCount; }
A& operator=(const A& x)
{ mc = x.mc; return *this; }
virtual ~A() // Virtual because we subclass A below.
{ --mCount; }
};
int A::mCount = 0;
/// B
///
struct B : public A
{
};
/// RefCountTest
///
/// This is used for tests involving intrusive_ptr.
///
struct RefCountTest
{
int mRefCount;
static int mCount;
RefCountTest()
: mRefCount(0) { ++mCount; }
RefCountTest(const RefCountTest&)
: mRefCount(0) { ++mCount; }
RefCountTest& operator=(const RefCountTest&)
{ return *this; }
virtual ~RefCountTest()
{ --mCount; }
virtual int AddRef()
{ return (int)((mRefCount++) + 1); }
virtual int Release()
{
int rc = (int)((mRefCount--) - 1);
if(rc)
return rc;
mRefCount = 1;
delete this;
return 0;
}
};
int RefCountTest::mCount = 0;
/// Test
///
/// This is used for tests involving intrusive_ptr.
///
struct Test : public RefCountTest
{
bool* mpBool;
Test(bool* pBool)
: mpBool(pBool) { *pBool = true; }
Test(const Test& x):
RefCountTest(x), mpBool(x.mpBool) { }
Test& operator=(const Test& x)
{ mpBool = x.mpBool; return *this; }
~Test()
{ *mpBool = false; }
};
/// IntrusiveParent / IntrusiveChild
///
/// This is used for tests involving intrusive_ptr.
///
struct IntrusiveParent : public RefCountTest
{
};
struct IntrusiveChild : public IntrusiveParent
{
};
/// intrusive_ptr_add_ref / intrusive_ptr_release
///
/// This is used for tests involving intrusive_ptr.
///
struct IntrusiveCustom : public RefCountTest
{
static int mAddRefCallCount;
static int mReleaseCallCount;
virtual int AddRef()
{
++mAddRefCallCount;
return RefCountTest::AddRef();
}
virtual int Release()
{
++mReleaseCallCount;
return RefCountTest::Release();
}
};
int IntrusiveCustom::mAddRefCallCount = 0;
int IntrusiveCustom::mReleaseCallCount = 0;
void intrusive_ptr_add_ref(IntrusiveCustom* p)
{
p->AddRef();
}
void intrusive_ptr_release(IntrusiveCustom* p)
{
p->Release();
}
/// ParentClass / ChildClass / GrandChildClass
///
/// This is used for tests involving shared_ptr.
///
struct ParentClass
{
virtual ~ParentClass() { }
virtual void DoNothingParentClass() { }
};
struct ChildClass : public ParentClass
{
virtual void DoNothingChildClass() { }
};
struct GrandChildClass : public ChildClass
{
virtual void DoNothingGrandChildClass() { }
};
/// NamedClass
///
struct NamedClass
{
const char* mpName;
const char* mpName2;
static int mnCount;
NamedClass(const char* pName = NULL)
: mpName(pName), mpName2(NULL) { ++mnCount; }
NamedClass(const char* pName, const char* pName2)
: mpName(pName), mpName2(pName2) { ++mnCount; }
NamedClass(const NamedClass& x)
: mpName(x.mpName), mpName2(x.mpName2) { ++mnCount; }
NamedClass& operator=(const NamedClass& x)
{ mpName = x.mpName; mpName2 = x.mpName2; return *this; }
~NamedClass()
{ --mnCount; }
};
int NamedClass::mnCount = 0;
/// Y
///
/// This is used for tests involving shared_ptr and enabled_shared_from_this.
///
struct Y : public eastl::enable_shared_from_this<Y>
{
static int mnCount;
Y() { ++mnCount; }
Y(const Y&) { ++mnCount; }
Y& operator=(const Y&) { return *this; }
~Y() { --mnCount; }
eastl::shared_ptr<Y> f()
{ return shared_from_this(); }
};
int Y::mnCount = 0;
/// ACLS / BCLS
///
/// This is used for tests involving shared_ptr.
///
class ACLS : public eastl::enable_shared_from_this<ACLS>
{
public:
static int mnCount;
int a;
ACLS(int _a_ = 0) : a(_a_) { ++mnCount; }
ACLS(const ACLS& x) : a(x.a) { ++mnCount; }
ACLS& operator=(const ACLS& x) { a = x.a; return *this; }
~ACLS() { --mnCount; }
};
int ACLS::mnCount = 0;
class BCLS : public ACLS
{
public:
static int mnCount;
int b;
BCLS(int _b_ = 0) : b(_b_) { ++mnCount; }
BCLS(const BCLS& x) : ACLS(x), b(x.b) { ++mnCount; }
BCLS& operator=(const BCLS& x) { b = x.b; ACLS::operator=(x); return *this; }
~BCLS() { --mnCount; }
};
int BCLS::mnCount = 0;
/// A1 / B1
///
/// This is used for tests involving shared_ptr.
///
struct A1
{
static int mnCount;
int a;
A1(int _a_ = 0) : a(_a_) { ++mnCount; }
A1(const A1& x) : a(x.a) { ++mnCount; }
A1& operator=(const A1& x) { a = x.a; return *this; }
~A1() { --mnCount; }
};
int A1::mnCount = 0;
struct B1 : public A1
{
static int mnCount;
int b;
B1(int _b_ = 0) : b(_b_) { ++mnCount; }
B1(const B1& x) : A1(x), b(x.b) { ++mnCount; }
B1& operator=(const B1& x) { b = x.b; A1::operator=(x); return *this; }
~B1() { --mnCount; }
};
int B1::mnCount = 0;
class MockObject
{
public:
MockObject(bool* pAlloc)
: mpAlloc(pAlloc){ *mpAlloc = true; }
~MockObject()
{ *mpAlloc = false; }
bool IsAllocated() const
{ return *mpAlloc; }
bool* GetAllocPtr() const
{ return mpAlloc; }
private:
bool* mpAlloc;
};
class DerivedMockObject : public MockObject
{
public:
DerivedMockObject(bool* pAlloc)
: MockObject(pAlloc) {}
};
struct foo : public eastl::enable_shared_from_this<foo>
{
foo() : mX(0){}
int mX;
};
struct CheckUPtrEmptyInDestructor
{
~CheckUPtrEmptyInDestructor()
{
if(mpUPtr)
mCheckUPtrEmpty = (*mpUPtr == nullptr);
}
eastl::unique_ptr<CheckUPtrEmptyInDestructor>* mpUPtr{};
static bool mCheckUPtrEmpty;
};
bool CheckUPtrEmptyInDestructor::mCheckUPtrEmpty = false;
struct CheckUPtrArrayEmptyInDestructor
{
~CheckUPtrArrayEmptyInDestructor()
{
if(mpUPtr)
mCheckUPtrEmpty = (*mpUPtr == nullptr);
}
eastl::unique_ptr<CheckUPtrArrayEmptyInDestructor[]>* mpUPtr{};
static bool mCheckUPtrEmpty;
};
bool CheckUPtrArrayEmptyInDestructor::mCheckUPtrEmpty = false;
} // namespace SmartPtrTest
static int Test_unique_ptr()
{
using namespace SmartPtrTest;
using namespace eastl;
int nErrorCount(0);
{
EATEST_VERIFY(A::mCount == 0);
// explicit unique_ptr(pointer pValue) noexcept
unique_ptr<int> pT1(new int(5));
EATEST_VERIFY(*pT1 == 5);
// (reference) operator*() const
*pT1 = 3;
EATEST_VERIFY(*pT1 == 3);
// explicit unique_ptr(pointer pValue) noexcept
unique_ptr<A> pT2(new A(1));
EATEST_VERIFY(pT2->mc == 1);
EATEST_VERIFY(A::mCount == 1);
// Pointers of derived types are allowed (unlike array unique_ptr)
unique_ptr<A> pT1B(new B);
EATEST_VERIFY(pT1B.get() != NULL);
EATEST_VERIFY(A::mCount == 2);
A* pA = pT1B.release(); // release simply forgets the owned pointer.
EATEST_VERIFY(pT1B.get() == NULL);
EATEST_VERIFY(A::mCount == 2);
delete pA;
EATEST_VERIFY(A::mCount == 1);
// pointer operator->() const noexcept
pT2->mc = 5;
EATEST_VERIFY(pT2.get()->mc == 5);
// void reset(pointer pValue = pointer()) noexcept
pT2.reset(new A(2));
EATEST_VERIFY(pT2->mc == 2);
EATEST_VERIFY(A::mCount == 1);
pT2.reset(0);
EATEST_VERIFY(pT2.get() == (A*)0);
EATEST_VERIFY(A::mCount == 0);
pT2.reset(new A(3));
EATEST_VERIFY(pT2->mc == 3);
EATEST_VERIFY(A::mCount == 1);
unique_ptr<A> pT3(new A(4));
EATEST_VERIFY(pT3->mc == 4);
EATEST_VERIFY(A::mCount == 2);
// void swap(this_type& scopedPtr) noexcept
pT2.swap(pT3);
EATEST_VERIFY(pT2->mc == 4);
EATEST_VERIFY(pT3->mc == 3);
EATEST_VERIFY(A::mCount == 2);
// void swap(unique_ptr<T, D>& scopedPtr1, unique_ptr<T, D>& scopedPtr2) noexcept
swap(pT2, pT3);
EATEST_VERIFY(pT2->mc == 3);
EATEST_VERIFY(pT3->mc == 4);
EATEST_VERIFY((pT2 < pT3) == (pT2.get() < pT3.get()));
EATEST_VERIFY(A::mCount == 2);
// pointer release() noexcept
unique_ptr<A> pRelease(new A);
EATEST_VERIFY(A::mCount == 3);
pA = pRelease.release();
delete pA;
EATEST_VERIFY(A::mCount == 2);
// constexpr unique_ptr() noexcept
unique_ptr<A> pT4;
EATEST_VERIFY(pT4.get() == (A*)0);
if(pT4)
EATEST_VERIFY(pT4.get()); // Will fail
if(!(!pT4))
EATEST_VERIFY(pT4.get()); // Will fail
pT4.reset(new A(0));
if(!pT4)
EATEST_VERIFY(!pT4.get()); // Will fail
EATEST_VERIFY(A::mCount == 3);
// unique_ptr(nullptr_t) noexcept
unique_ptr<A> pT5(nullptr);
EATEST_VERIFY(pT5.get() == (A*)0);
// unique_ptr(pointer pValue, deleter) noexcept
CustomDeleter customADeleter;
unique_ptr<A, CustomDeleter> pT6(new A(17), customADeleter);
EATEST_VERIFY(pT6->mc == 17);
// unique_ptr(pointer pValue, typename eastl::remove_reference<Deleter>::type&& deleter) noexcept
unique_ptr<A, CustomDeleter> pT7(new A(18), CustomDeleter());
EATEST_VERIFY(pT7->mc == 18);
// unique_ptr(this_type&& x) noexcept
unique_ptr<A, CustomDeleter> pT8(eastl::move(pT7));
EATEST_VERIFY(pT8->mc == 18);
// unique_ptr(unique_ptr<U, E>&& u, ...)
unique_ptr<A, default_delete<A> > pT9(eastl::move(pT2));
// this_type& operator=(this_type&& u) noexcept
// operator=(unique_ptr<U, E>&& u) noexcept
//unique_ptr<void, CustomDeleter> pTVoid;
//unique_ptr<int, CustomDeleter> pTInt(new int(1));
//pTVoid.operator=<int, CustomDeleter>(eastl::move(pTInt)); // This doesn't work because CustomDeleter doesn't know how to delete void*. Need to rework this test.
// this_type& operator=(nullptr_t) noexcept
pT6 = nullptr;
EATEST_VERIFY(pT6.get() == (A*)0);
// user reported regression
// ensure a unique_ptr containing nullptr doesn't call the deleter when its destroyed.
{
static bool sLocalDeleterCalled;
sLocalDeleterCalled = false;
struct LocalDeleter
{
void operator()(int* p) const
{
sLocalDeleterCalled = true;
delete p;
}
};
using local_unique_ptr = eastl::unique_ptr<int, LocalDeleter>;
local_unique_ptr pEmpty{nullptr};
pEmpty = local_unique_ptr{new int(42), LocalDeleter()};
EATEST_VERIFY(sLocalDeleterCalled == false);
}
}
{
// Test that unique_ptr internal pointer is reset before calling the destructor
CheckUPtrEmptyInDestructor::mCheckUPtrEmpty = false;
unique_ptr<CheckUPtrEmptyInDestructor> uptr(new CheckUPtrEmptyInDestructor);
uptr->mpUPtr = &uptr;
uptr.reset();
EATEST_VERIFY(CheckUPtrEmptyInDestructor::mCheckUPtrEmpty);
}
{
// Test that unique_ptr<[]> internal pointer is reset before calling the destructor
CheckUPtrArrayEmptyInDestructor::mCheckUPtrEmpty = false;
unique_ptr<CheckUPtrArrayEmptyInDestructor[]> uptr(new CheckUPtrArrayEmptyInDestructor[1]);
uptr[0].mpUPtr = &uptr;
uptr.reset();
EATEST_VERIFY(CheckUPtrArrayEmptyInDestructor::mCheckUPtrEmpty);
}
{
#if EASTL_CORE_ALLOCATOR_ENABLED
// Test EA::Allocator::EASTLICoreDeleter usage within eastl::shared_ptr.
// http://en.cppreference.com/w/cpp/memory/shared_ptr/shared_ptr
// Consider the following for standards compliance.
// eastl::shared_ptr<A, EASTLCoreDeleterAdapter> foo(pA, EASTLCoreDeleterAdapter());
const int cacheAllocationCount = gEASTLTest_AllocationCount;
using namespace EA::Allocator;
EASTLCoreAllocatorAdapter ta;
void* pMem = ta.allocate(sizeof(A));
EATEST_VERIFY(pMem != nullptr);
EATEST_VERIFY(gEASTLTest_AllocationCount > cacheAllocationCount);
{
A* pA = new (pMem) A();
eastl::shared_ptr<A> foo(pA, EASTLCoreDeleterAdapter()); // Not standards complaint code. Update EASTL implementation to provide the type of the deleter.
}
EATEST_VERIFY(gEASTLTest_AllocationCount == cacheAllocationCount);
EATEST_VERIFY(A::mCount == 0);
#endif
}
{
// Test array specialization of unique_ptr
EATEST_VERIFY(A::mCount == 0);
// template <typename P>
// explicit unique_ptr(P pValue) noexcept
unique_ptr<int[]> pT1(new int[5]);
pT1[0] = 5;
EATEST_VERIFY(pT1[0] == 5);
// Arrays of derived types are not allowed (unlike regular unique_ptr)
// unique_ptr<A[]> pT1B(new B[5]); // Disabled because it should not compile.
// (reference) operator[]() const
pT1[1] = 1;
EATEST_VERIFY(pT1[1] == 1);
// explicit unique_ptr(pointer pValue) noexcept
unique_ptr<A[]> pT2(new A[1]);
pT2[0].mc = 1;
EATEST_VERIFY(pT2[0].mc == 1);
EATEST_VERIFY(A::mCount == 1);
// pointer operator->() const noexcept
pT2[0].mc = 5;
EATEST_VERIFY(pT2[0].mc == 5);
// void reset(pointer pValue = pointer()) noexcept
pT2.reset(new A[2]);
pT2[0].mc = 2;
EATEST_VERIFY(pT2[0].mc == 2);
pT2.reset(0);
EATEST_VERIFY(pT2.get() == (A*)0);
pT2.reset(new A[3]);
pT2[0].mc = 3;
EATEST_VERIFY(pT2[0].mc == 3);
unique_ptr<A[]> pT3(new A[4]);
pT3[0].mc = 4;
EATEST_VERIFY(pT3[0].mc == 4);
// void swap(this_type& scopedPtr) noexcept
pT2.swap(pT3);
EATEST_VERIFY(pT2[0].mc == 4);
EATEST_VERIFY(pT3[0].mc == 3);
// void swap(unique_ptr<T, D>& scopedPtr1, unique_ptr<T, D>& scopedPtr2) noexcept
swap(pT2, pT3);
EATEST_VERIFY(pT2[0].mc == 3);
EATEST_VERIFY(pT3[0].mc == 4);
EATEST_VERIFY((pT2 < pT3) == (pT2.get() < pT3.get()));
// pointer release() noexcept
unique_ptr<A[]> pRelease(new A[1]);
A* pAArray = pRelease.release();
delete[] pAArray;
// constexpr unique_ptr() noexcept
unique_ptr<A[]> pT4;
EATEST_VERIFY(pT4.get() == (A*)0);
if(pT4)
EATEST_VERIFY(pT4.get()); // Will fail
if(!(!pT4))
EATEST_VERIFY(pT4.get()); // Will fail
pT4.reset(new A[1]);
if(!pT4)
EATEST_VERIFY(!pT4.get()); // Will fail
EATEST_VERIFY(A::mCount == 8); // There were a number of array creations and deletions above that make this so.
// unique_ptr(nullptr_t) noexcept
unique_ptr<A[]> pT5(nullptr);
EATEST_VERIFY(pT5.get() == (A*)0);
// unique_ptr(pointer pValue, deleter) noexcept
CustomArrayDeleter customADeleter;
unique_ptr<A[], CustomArrayDeleter> pT6(new A[17], customADeleter);
pT6[0].mc = 17;
EATEST_VERIFY(pT6[0].mc == 17);
// unique_ptr(pointer pValue, typename eastl::remove_reference<Deleter>::type&& deleter) noexcept
unique_ptr<A[], CustomArrayDeleter> pT7(new A[18], CustomArrayDeleter());
pT7[0].mc = 18;
EATEST_VERIFY(pT7[0].mc == 18);
// unique_ptr(this_type&& x) noexcept
unique_ptr<A[], CustomArrayDeleter> pT8(eastl::move(pT7));
EATEST_VERIFY(pT8[0].mc == 18);
// unique_ptr(unique_ptr<U, E>&& u, ...)
unique_ptr<A[], default_delete<A[]> > pT9(eastl::move(pT2));
EATEST_VERIFY(pT9[0].mc == 3);
// this_type& operator=(this_type&& u) noexcept
// operator=(unique_ptr<U, E>&& u) noexcept
//unique_ptr<void, CustomDeleter> pTVoid;
//unique_ptr<int, CustomDeleter> pTInt(new int(1));
//pTVoid.operator=<int, CustomDeleter>(eastl::move(pTInt)); // This doesn't work because CustomDeleter doesn't know how to delete void*. Need to rework this test.
// this_type& operator=(nullptr_t) noexcept
pT6 = nullptr;
EATEST_VERIFY(pT6.get() == (A*)0);
// unique_ptr<> make_unique(Args&&... args);
unique_ptr<NamedClass> p = eastl::make_unique<NamedClass>("test", "test2");
EATEST_VERIFY(EA::StdC::Strcmp(p->mpName, "test") == 0 && EA::StdC::Strcmp(p->mpName2, "test2") == 0);
unique_ptr<NamedClass[]> pArray = eastl::make_unique<NamedClass[]>(4);
pArray[0].mpName = "test";
EATEST_VERIFY(EA::StdC::Strcmp(p->mpName, "test") == 0);
#ifdef EASTL_TEST_DISABLED_PENDING_SUPPORT
{
const size_t kAlignedStructAlignment = 512;
struct AlignedStruct {} EA_ALIGN(kAlignedStructAlignment);
unique_ptr<AlignedStruct> pAlignedStruct = eastl::make_unique<AlignedStruct>();
EATEST_VERIFY_F(intptr_t(pAlignedStruct.get()) % kAlignedStructAlignment == 0, "pAlignedStruct didn't have proper alignment");
}
#endif
//Expected to not be valid:
//unique_ptr<NamedClass[4]> p2Array4 = eastl::make_unique<NamedClass[4]>();
//p2Array4[0].mpName = "test";
//EATEST_VERIFY(EA::StdC::Strcmp(p2Array4[0].mpName, "test") == 0);
}
EATEST_VERIFY(A::mCount == 0); // This check verifies that no A instances were lost, which also verifies that the [] version of the deleter was used in all cases.
// validate unique_ptr's compressed_pair implementation is working.
{
const int ARBITRARY_SIZE = 256;
static_assert(sizeof(unique_ptr<short>) == sizeof(uintptr_t), "");
static_assert(sizeof(unique_ptr<long>) == sizeof(uintptr_t), "");
// unique_ptr should be the same size as a pointer. The deleter object is empty so the
// eastl::compressed_pair implementation will remove that deleter data member from the unique_ptr.
{
auto deleter = [](void* pMem) { free(pMem); };
unique_ptr<void, decltype(deleter)> sptr(malloc(ARBITRARY_SIZE), deleter);
static_assert(sizeof(sptr) == (sizeof(uintptr_t)), "unexpected unique_ptr size");
}
// unique_ptr should be larger than a pointer when the deleter functor is capturing state. This state forces
// the compressed_pair to cached the data in unique_ptr locally.
{
int a = 0, b = 0, c = 0, d = 0, e = 0, f = 0;
auto deleter = [=](void* pMem) { auto result = (a+b+c+d+e+f); EA_UNUSED(result); free(pMem); };
unique_ptr<void, decltype(deleter)> sptr(malloc(ARBITRARY_SIZE), deleter);
static_assert(sizeof(sptr) == ((6 * sizeof(int)) + (sizeof(uintptr_t))), "unexpected unique_ptr size");
}
// Simply test moving the one unique pointer to another.
// Exercising operator=(T&&)
{
{
unique_ptr<int> ptr(new int(3));
EATEST_VERIFY(ptr.get() && *ptr == 3);
unique_ptr<int> newPtr(new int(4));
EATEST_VERIFY(newPtr.get() && *newPtr == 4);
ptr = eastl::move(newPtr); // Deletes int(3) and assigns mpValue to int(4)
EATEST_VERIFY(ptr.get() && *ptr == 4);
EATEST_VERIFY(newPtr.get() == nullptr);
}
#if EA_HAVE_CPP11_INITIALIZER_LIST
{
unique_ptr<int[]> ptr(new int[3]{ 0, 1, 2 });
EATEST_VERIFY(ptr.get() && ptr[0] == 0 && ptr[1] == 1 && ptr[2] == 2);
unique_ptr<int[]> newPtr(new int[3]{ 3, 4, 5 });
EATEST_VERIFY(newPtr.get() && newPtr[0] == 3 && newPtr[1] == 4 && newPtr[2] == 5);
ptr = eastl::move(newPtr); // Deletes int(3) and assigns mpValue to int(4)
EATEST_VERIFY(ptr.get() && ptr[0] == 3 && ptr[1] == 4 && ptr[2] == 5);
EATEST_VERIFY(newPtr.get() == nullptr);
}
#endif
// ToDo: Test move assignment between two convertible types with an is_assignable deleter_type
//{
// struct Base {};
// struct Child : public Base {};
// typedef unique_ptr<Base, CustomDeleter> BaseSPtr;
// typedef unique_ptr<Child, CustomDeleter> ChildSPtr;
// static_assert(!is_array<BaseSPtr::element_type>::value, "This test requires a non-array type");
// static_assert(is_convertible<ChildSPtr::pointer, BaseSPtr::pointer>::value, "UniquePtr ptr types must be convertible for this test");
// static_assert(is_assignable<BaseSPtr::deleter_type&, ChildSPtr::deleter_type&&>::value, "Deleter types must be assignable to one another");
// BaseSPtr ptr(new Base);
// EATEST_VERIFY(ptr.get());
// unique_ptr<Child> newPtr(new Child);
// EATEST_VERIFY(newPtr.get());
// ptr = eastl::move(newPtr);
// EATEST_VERIFY(ptr);
// EATEST_VERIFY(newPtr.get() == nullptr);
//}
}
}
return nErrorCount;
}
static int Test_scoped_ptr()
{
using namespace SmartPtrTest;
using namespace eastl;
int nErrorCount(0);
{
EATEST_VERIFY(A::mCount == 0);
scoped_ptr<int> pT1(new int(5));
EATEST_VERIFY(*pT1 == 5);
*pT1 = 3;
EATEST_VERIFY(*pT1 == 3);
EATEST_VERIFY(pT1.get() == get_pointer(pT1));
scoped_ptr<A> pT2(new A(1));
EATEST_VERIFY(pT2->mc == 1);
EATEST_VERIFY(A::mCount == 1);
pT2.reset(new A(2));
EATEST_VERIFY(pT2->mc == 2);
pT2.reset(0);
EATEST_VERIFY(pT2.get() == (A*)0);
EATEST_VERIFY(pT2.get() == get_pointer(pT2));
pT2.reset(new A(3));
EATEST_VERIFY(pT2->mc == 3);
scoped_ptr<A> pT3(new A(4));
EATEST_VERIFY(pT3->mc == 4);
pT2.swap(pT3);
EATEST_VERIFY(pT2->mc == 4);
EATEST_VERIFY(pT3->mc == 3);
swap(pT2, pT3);
EATEST_VERIFY(pT2->mc == 3);
EATEST_VERIFY(pT3->mc == 4);
EATEST_VERIFY((pT2 < pT3) == (pT2.get() < pT3.get()));
scoped_ptr<A> pT4;
EATEST_VERIFY(pT4.get() == (A*)0);
if(pT4)
EATEST_VERIFY(pT4.get()); // Will fail
if(!(!pT4))
EATEST_VERIFY(pT4.get()); // Will fail
pT4.reset(new A(0));
if(!pT4)
EATEST_VERIFY(!pT4.get()); // Will fail
EATEST_VERIFY(A::mCount == 3);
}
{ // Test the detach function.
scoped_ptr<A> ptr(new A);
A* pA = ptr.detach();
delete pA;
}
{
scoped_ptr<void> ptr(new int);
(void)ptr;
}
EATEST_VERIFY(A::mCount == 0);
return nErrorCount;
}
static int Test_scoped_array()
{
using namespace SmartPtrTest;
using namespace eastl;
int nErrorCount(0);
{
scoped_array<int> pT1(new int[5]);
pT1[0] = 5;
EATEST_VERIFY(pT1[0] == 5);
EATEST_VERIFY(pT1.get()[0] == 5);
scoped_array<A> pT2(new A[2]);
EATEST_VERIFY(A::mCount == 2);
EATEST_VERIFY(pT2[0].mc == 0);
EATEST_VERIFY(pT2.get()[0].mc == 0);
EATEST_VERIFY(get_pointer(pT2)[0].mc == 0);
pT2.reset(new A[4]);
EATEST_VERIFY(A::mCount == 4);
if(!pT2)
EATEST_VERIFY(!pT2.get()); // Will fail
pT2.reset(0);
EATEST_VERIFY(A::mCount == 0);
if(pT2)
EATEST_VERIFY(pT2.get()); // Will fail
if(!(!pT2))
EATEST_VERIFY(pT2.get()); // Will fail
scoped_array<A> pT3(new A[3]);
EATEST_VERIFY(A::mCount == 3);
pT2.swap(pT3);
EATEST_VERIFY(A::mCount == 3);
swap(pT2, pT3);
EATEST_VERIFY(A::mCount == 3);
EATEST_VERIFY((pT2 < pT3) == (pT2.get() < pT3.get()));
EATEST_VERIFY(A::mCount == 3);
}
{ // Test the detach function.
scoped_array<A> ptr(new A[6]);
A* pArray = ptr.detach();
delete[] pArray;
}
{
scoped_array<void> ptr(new int[6]);
(void)ptr;
}
EATEST_VERIFY(A::mCount == 0);
return nErrorCount;
}
static int Test_shared_ptr()
{
using namespace SmartPtrTest;
using namespace eastl;
int nErrorCount(0);
// Name test.
#if EASTLTEST_GETTYPENAME_AVAILABLE
//eastl::string sTypeName = GetTypeName<typename eastl::unique_ptr<int>::pointer>();
//EA::UnitTest::Report("type name of (typename shared_ptr<int>::pointer): %s", sTypeName.c_str());
//sTypeName = GetTypeName<typename eastl::common_type<int*, int*>::type>();
//EA::UnitTest::Report("type name of (typename eastl::common_type<int*, int*>::type): %s", sTypeName.c_str());
#endif
{
shared_ptr<int> pT1;
EATEST_VERIFY(pT1.get() == NULL);
}
{
shared_ptr<int> pT1(new int(5));
EATEST_VERIFY(*pT1 == 5);
EATEST_VERIFY(pT1.get() == get_pointer(pT1));
EATEST_VERIFY(pT1.use_count() == 1);
EATEST_VERIFY(pT1.unique() );
shared_ptr<int> pT2;
EATEST_VERIFY(pT1 != pT2);
EATEST_VERIFY(pT1.use_count() == 1);
EATEST_VERIFY(pT1.unique());
pT2 = pT1;
EATEST_VERIFY(pT1.use_count() == 2);
EATEST_VERIFY(pT2.use_count() == 2);
EATEST_VERIFY(!pT1.unique());
EATEST_VERIFY(!(pT1 < pT2)); // They should be equal
EATEST_VERIFY(pT1 == pT2);
*pT1 = 3;
EATEST_VERIFY(*pT1 == 3);
EATEST_VERIFY(*pT1 == 3);
EATEST_VERIFY(*pT2 == 3);
pT2.reset((int*)NULL);
EATEST_VERIFY(pT2.unique());
EATEST_VERIFY(pT2.use_count() == 1);
EATEST_VERIFY(pT1.unique());
EATEST_VERIFY(pT1.use_count() == 1);
EATEST_VERIFY(pT1 != pT2);
}
{
EATEST_VERIFY(A::mCount == 0);
shared_ptr<A> pT2(new A(0));
EATEST_VERIFY(A::mCount == 1);
EATEST_VERIFY(pT2->mc == 0);
EATEST_VERIFY(pT2.use_count() == 1);
EATEST_VERIFY(pT2.unique());
pT2.reset(new A(1));
EATEST_VERIFY(pT2->mc == 1);
EATEST_VERIFY(A::mCount == 1);
EATEST_VERIFY(pT2.use_count() == 1);
EATEST_VERIFY(pT2.unique());
shared_ptr<A> pT3(new A(2));
EATEST_VERIFY(A::mCount == 2);
pT2.swap(pT3);
EATEST_VERIFY(pT2->mc == 2);
EATEST_VERIFY(pT3->mc == 1);
EATEST_VERIFY(A::mCount == 2);
swap(pT2, pT3);
EATEST_VERIFY(pT2->mc == 1);
EATEST_VERIFY(pT3->mc == 2);
EATEST_VERIFY(A::mCount == 2);
if(!pT2)
EATEST_VERIFY(!pT2.get()); // Will fail
shared_ptr<A> pT4;
EATEST_VERIFY(pT2.use_count() == 1);
EATEST_VERIFY(pT2.unique());
EATEST_VERIFY(A::mCount == 2);
if(pT4)
EATEST_VERIFY(pT4.get()); // Will fail
if(!(!pT4))
EATEST_VERIFY(pT4.get()); // Will fail
pT4 = pT2;
EATEST_VERIFY(pT2.use_count() == 2);
EATEST_VERIFY(pT4.use_count() == 2);
EATEST_VERIFY(!pT2.unique());
EATEST_VERIFY(!pT4.unique());
EATEST_VERIFY(A::mCount == 2);
EATEST_VERIFY(pT2 == pT4);
EATEST_VERIFY(pT2 != pT3);
EATEST_VERIFY(!(pT2 < pT4)); // They should be equal
shared_ptr<A> pT5(pT4);
EATEST_VERIFY(pT4 == pT5);
EATEST_VERIFY(pT2.use_count() == 3);
EATEST_VERIFY(pT4.use_count() == 3);
EATEST_VERIFY(pT5.use_count() == 3);
EATEST_VERIFY(!pT5.unique());
pT4 = shared_ptr<A>((A*)NULL);
EATEST_VERIFY(pT4.unique());
EATEST_VERIFY(pT4.use_count() == 1);
EATEST_VERIFY(pT2.use_count() == 2);
EATEST_VERIFY(A::mCount == 2);
}
// Regression test reported by a user.
// typename eastl::enable_if<!eastl::is_array<U>::value && eastl::is_convertible<U*, element_type*>::value, this_type&>::type
// operator=(unique_ptr<U, Deleter> && uniquePtr)
{
{
shared_ptr<A> rT1(new A(42));
unique_ptr<B> rT2(new B); // default ctor uses 0
rT2->mc = 115;
EATEST_VERIFY(rT1->mc == 42);
EATEST_VERIFY(rT2->mc == 115);
rT1 = eastl::move(rT2);
EATEST_VERIFY(rT1->mc == 115);
// EATEST_VERIFY(rT2->mc == 115); // state of object post-move is undefined.
}
// test the state of the shared_ptr::operator= return
{
shared_ptr<A> rT1(new A(42));
unique_ptr<B> rT2(new B); // default ctor uses 0
rT2->mc = 115;
shared_ptr<A> operatorReturn = (rT1 = eastl::move(rT2));
EATEST_VERIFY(operatorReturn == rT1);
EATEST_VERIFY(operatorReturn->mc == 115);
// EATEST_VERIFY(rT1->mc == 115); // implied as both are pointing to the same address
}
}
{ // Test member template functions.
shared_ptr<ChildClass> pCC(new GrandChildClass);
shared_ptr<ParentClass> pPC(pCC);
shared_ptr<GrandChildClass> pGCC(static_pointer_cast<GrandChildClass>(pPC));
}
{ // Test enable_shared_from_this
shared_ptr<Y> p(new Y);
shared_ptr<Y> q = p->f();
EATEST_VERIFY(p == q);
EATEST_VERIFY(!(p < q || q < p)); // p and q must share ownership
shared_ptr<BCLS> bctrlp = shared_ptr<BCLS>(new BCLS);
}
{ // Test static_pointer_cast, etc.
shared_ptr<GrandChildClass> pGCC(new GrandChildClass);
shared_ptr<ParentClass> pPC = static_pointer_cast<ParentClass>(pGCC);
EATEST_VERIFY(pPC == pGCC);
#if EASTL_RTTI_ENABLED
shared_ptr<ChildClass> pCC = dynamic_pointer_cast<ChildClass>(pPC);
EATEST_VERIFY(pCC == pGCC);
#endif
#if !defined(__GNUC__) || (__GNUC__ >= 3) // If not using old GCC (GCC 2.x is broken)...
eastl::shared_ptr<const void> pVoidPtr = shared_ptr<ParentClass>(new ParentClass);
shared_ptr<ParentClass> ap = const_pointer_cast<ParentClass>(static_pointer_cast<const ParentClass>(pVoidPtr));
#endif
//typedef shared_ptr<void const> ASPtr;
//shared_ptr<void const> pVoidPtr = ASPtr(new ParentClass);
//ASPtr ap = const_pointer_cast<ParentClass>(static_pointer_cast<const ParentClass>(pVoidPtr));
}
{ // Test static_shared_pointer_cast, etc.
shared_ptr<GrandChildClass> pGCC(new GrandChildClass);
shared_ptr<ParentClass> pPC = static_shared_pointer_cast<ParentClass /*, EASTLAllocatorType, smart_ptr_deleter<ParentClass>*/ >(pGCC);
EATEST_VERIFY(pPC == pGCC);
#if EASTL_RTTI_ENABLED
shared_ptr<ChildClass> pCC = dynamic_shared_pointer_cast<ChildClass /*, EASTLAllocatorType, smart_ptr_deleter<ParentClass>*/ >(pPC);
EATEST_VERIFY(pCC == pGCC);
#endif
}
{ // Test smart_ptr_deleter
shared_ptr<void> pVoid(new ParentClass, smart_ptr_deleter<ParentClass>());
EATEST_VERIFY(pVoid.get() != NULL);
pVoid = shared_ptr<ParentClass>(new ParentClass, smart_ptr_deleter<ParentClass>());
EATEST_VERIFY(pVoid.get() != NULL);
}
{ // Test shared_ptr lambda deleter
auto deleter = [](int*) {};
eastl::shared_ptr<int> ptr(nullptr, deleter);
EATEST_VERIFY(!ptr);
EATEST_VERIFY(ptr.get() == nullptr);
}
{ // Test of shared_ptr<void const>
#if !defined(__GNUC__) || (__GNUC__ >= 3) // If not using old GCC (GCC 2.x is broken)...
shared_ptr<void const> voidPtr = shared_ptr<A1>(new A1);
shared_ptr<A1> a1Ptr = const_pointer_cast<A1>(static_pointer_cast<const A1>(voidPtr));
#endif
}
{ // Test of static_pointer_cast
shared_ptr<B1> bPtr = shared_ptr<B1>(new B1);
shared_ptr<A1> aPtr = static_pointer_cast<A1, B1>(bPtr);
}
{ // Test shared_ptr<void>
{
#if !defined(__GNUC__) || (__GNUC__ >= 3) // If not using old GCC (GCC 2.x is broken)...
const char* const pName = "NamedClassTest";
NamedClass* const pNamedClass0 = new NamedClass(pName);
EATEST_VERIFY(pNamedClass0->mpName == pName);
//shared_ptr<void const, EASTLAllocatorType, smart_ptr_deleter<NamedClass> > voidPtr(pNamedClass0);
shared_ptr<void const> voidPtr(pNamedClass0);
EATEST_VERIFY(voidPtr.get() == pNamedClass0);
NamedClass* const pNamedClass1 = (NamedClass*)voidPtr.get();
EATEST_VERIFY(pNamedClass1->mpName == pName);
#endif
}
{
#if !defined(__GNUC__) || (__GNUC__ >= 3) // If not using old GCC (GCC 2.x is broken)...
const char* const pName = "NamedClassTest";
NamedClass* const pNamedClass0 = new NamedClass(pName);
EATEST_VERIFY(pNamedClass0->mpName == pName);
shared_ptr<void const> voidPtr(pNamedClass0, smart_ptr_deleter<NamedClass>());
EATEST_VERIFY(voidPtr.get() == pNamedClass0);
NamedClass* const pNamedClass1 = (NamedClass*)voidPtr.get();
EATEST_VERIFY(pNamedClass1->mpName == pName);
#endif
}
}
{
const char* const pName1 = "NamedClassTest1";
const char* const pName2 = "NamedClassTest2";
shared_ptr<NamedClass> sp(new NamedClass(pName1));
EATEST_VERIFY(!sp == false);
EATEST_VERIFY(sp.unique());
EATEST_VERIFY(sp->mpName == pName1);
shared_ptr<NamedClass> sp2 = sp;
EATEST_VERIFY(sp2.use_count() == 2);
sp2.reset(new NamedClass(pName2));
EATEST_VERIFY(sp2.use_count() == 1);
EATEST_VERIFY(sp.unique());
EATEST_VERIFY(sp2->mpName == pName2);
sp.reset();
EATEST_VERIFY(!sp == true);
}
{
// Exception handling tests
#if EASTL_EXCEPTIONS_ENABLED
try {
weak_ptr<A> pWeakA; // leave uninitalized
shared_ptr<A> pSharedA(pWeakA); // This should throw eastl::bad_weak_ptr
EATEST_VERIFY(false);
}
catch(eastl::bad_weak_ptr&)
{
EATEST_VERIFY(true); // This pathway should be taken.
}
catch(...)
{
EATEST_VERIFY(false);
}
ThrowingAllocator<true> throwingAllocator; // Throw on first attempt to allocate.
shared_ptr<A> pA0;
try {
A::mCount = 0;
pA0 = eastl::allocate_shared<A, ThrowingAllocator<true> >(throwingAllocator, 'a');
EATEST_VERIFY(false);
}
catch(std::bad_alloc&)
{
EATEST_VERIFY(true); // This pathway should be taken.
EATEST_VERIFY(pA0.get() == NULL); // The C++11 Standard doesn't seem to require this, but that's how we currently do it until we learn it should be otherwise.
EATEST_VERIFY(pA0.use_count() == 0);
EATEST_VERIFY(A::mCount == 0); // Verify that there were no surviving A instances since the exception.
}
catch(...)
{
EATEST_VERIFY(false);
}
try {
shared_ptr<A> pA1(new A('a'), default_delete<A>(), throwingAllocator);
EATEST_VERIFY(false);
}
catch(std::bad_alloc&)
{
EATEST_VERIFY(true); // This pathway should be taken.
EATEST_VERIFY(A::mCount == 0);
}
catch(...)
{
EATEST_VERIFY(false);
}
#endif
}
#if EASTL_RTTI_ENABLED
{
// template <typename U, typename A, typename D>
// shared_ptr(const shared_ptr<U, A, D>& sharedPtr, dynamic_cast_tag);
// To do.
// template <typename U, typename A, typename D, typename UDeleter>
// shared_ptr(const shared_ptr<U, A, D>& sharedPtr, dynamic_cast_tag, const UDeleter&);
// To do.
}
#endif
EATEST_VERIFY(A::mCount == 0);
return nErrorCount;
}
#if EASTL_THREAD_SUPPORT_AVAILABLE
// C++ Standard section 20.7.2.5 -- shared_ptr atomic access
// shared_ptr thread safety is about safe use of the pointer itself and not about what it points to. shared_ptr thread safety
// allows you to safely use shared_ptr from different threads, but if the object shared_ptr holds requires thread safety then
// you need to separately handle that in a thread-safe way. A good way to think about it is this: "shared_ptr is as thread-safe as a raw pointer."
//
// Some helper links:
// http://stackoverflow.com/questions/9127816/stdshared-ptr-thread-safety-explained
// http://stackoverflow.com/questions/14482830/stdshared-ptr-thread-safety
// http://cppwisdom.quora.com/shared_ptr-is-almost-thread-safe
//
// Test the ability of Futex to report the callstack of another thread holding a futex.
struct SharedPtrTestThread : public EA::Thread::IRunnable
{
EA::Thread::ThreadParameters mThreadParams;
EA::Thread::Thread mThread;
volatile bool mbShouldContinue;
int mnErrorCount;
eastl::shared_ptr<TestObject>* mpSPTO;
eastl::weak_ptr<TestObject>* mpWPTO;
SharedPtrTestThread() : mThreadParams(), mThread(), mbShouldContinue(true), mnErrorCount(0), mpSPTO(NULL), mpWPTO(NULL) {}
SharedPtrTestThread(const SharedPtrTestThread&){}
void operator=(const SharedPtrTestThread&){}
intptr_t Run(void*)
{
int& nErrorCount = mnErrorCount; // declare nErrorCount so that EATEST_VERIFY can work, as it depends on it being declared.
while(mbShouldContinue)
{
EA::UnitTest::ThreadSleepRandom(1, 10);
EATEST_VERIFY(mpSPTO->get()->mX == 99);
eastl::shared_ptr<TestObject> temp(mpWPTO->lock());
EATEST_VERIFY(temp->mX == 99);
eastl::shared_ptr<TestObject> spTO2(*mpSPTO);
EATEST_VERIFY(spTO2->mX == 99);
EATEST_VERIFY(spTO2.use_count() >= 2);
eastl::weak_ptr<TestObject> wpTO2(spTO2);
temp = mpWPTO->lock();
EATEST_VERIFY(temp->mX == 99);
temp = spTO2;
spTO2.reset();
EATEST_VERIFY(mpSPTO->get()->mX == 99);
}
return nErrorCount;
}
};
#endif
static int Test_shared_ptr_thread()
{
using namespace SmartPtrTest;
using namespace eastl;
using namespace EA::Thread;
int nErrorCount(0);
#if EASTL_THREAD_SUPPORT_AVAILABLE
{
SharedPtrTestThread thread[4];
shared_ptr<TestObject> spTO(new TestObject(99));
weak_ptr<TestObject> wpTO(spTO);
for(size_t i = 0; i < EAArrayCount(thread); i++)
{
thread[i].mpSPTO = &spTO;
thread[i].mpWPTO = &wpTO;
thread[i].mThreadParams.mpName = "SharedPtrTestThread";
}
for(size_t i = 0; i < EAArrayCount(thread); i++)
thread[i].mThread.Begin(&thread[0], NULL, &thread[0].mThreadParams);
EA::UnitTest::ThreadSleep(2000);
for(size_t i = 0; i < EAArrayCount(thread); i++)
thread[i].mbShouldContinue = false;
for(size_t i = 0; i < EAArrayCount(thread); i++)
{
thread[i].mThread.WaitForEnd();
nErrorCount += thread[i].mnErrorCount;
}
}
#endif
#if EASTL_THREAD_SUPPORT_AVAILABLE
{
// We currently do light testing of the atomic functions. It would take a bit of work to fully test
// the memory behavior of these in a rigorous way. Also, as of this writing we don't have a portable
// way to use the std::memory_order functionality.
shared_ptr<TestObject> spTO(new TestObject(55));
// bool atomic_is_lock_free(const shared_ptr<T>*);
EATEST_VERIFY(!atomic_is_lock_free(&spTO));
// shared_ptr<T> atomic_load(const shared_ptr<T>* pSharedPtr);
// shared_ptr<T> atomic_load_explicit(const shared_ptr<T>* pSharedPtr, ... /*std::memory_order memoryOrder*/);
shared_ptr<TestObject> spTO2 = atomic_load(&spTO);
EATEST_VERIFY(spTO->mX == 55);
EATEST_VERIFY(spTO2->mX == 55);
// void atomic_store(shared_ptr<T>* pSharedPtrA, shared_ptr<T> sharedPtrB);
// void atomic_store_explicit(shared_ptr<T>* pSharedPtrA, shared_ptr<T> sharedPtrB, ... /*std::memory_order memoryOrder*/);
spTO2->mX = 56;
EATEST_VERIFY(spTO->mX == 56);
EATEST_VERIFY(spTO2->mX == 56);
atomic_store(&spTO, shared_ptr<TestObject>(new TestObject(77)));
EATEST_VERIFY(spTO->mX == 77);
EATEST_VERIFY(spTO2->mX == 56);
// shared_ptr<T> atomic_exchange(shared_ptr<T>* pSharedPtrA, shared_ptr<T> sharedPtrB);
// shared_ptr<T> atomic_exchange_explicit(shared_ptr<T>* pSharedPtrA, shared_ptr<T> sharedPtrB, ... /*std::memory_order memoryOrder*/);
spTO = atomic_exchange(&spTO2, spTO);
EATEST_VERIFY(spTO->mX == 56);
EATEST_VERIFY(spTO2->mX == 77);
spTO = atomic_exchange_explicit(&spTO2, spTO);
EATEST_VERIFY(spTO->mX == 77);
EATEST_VERIFY(spTO2->mX == 56);
// bool atomic_compare_exchange_strong(shared_ptr<T>* pSharedPtr, shared_ptr<T>* pSharedPtrCondition, shared_ptr<T> sharedPtrNew);
// bool atomic_compare_exchange_weak(shared_ptr<T>* pSharedPtr, shared_ptr<T>* pSharedPtrCondition, shared_ptr<T> sharedPtrNew);
// bool atomic_compare_exchange_strong_explicit(shared_ptr<T>* pSharedPtr, shared_ptr<T>* pSharedPtrCondition, shared_ptr<T> sharedPtrNew, ... /*memory_order memoryOrderSuccess, memory_order memoryOrderFailure*/);
// bool atomic_compare_exchange_weak_explicit(shared_ptr<T>* pSharedPtr, shared_ptr<T>* pSharedPtrCondition, shared_ptr<T> sharedPtrNew, ... /*memory_order memoryOrderSuccess, memory_order memoryOrderFailure*/);
shared_ptr<TestObject> spTO3 = atomic_load(&spTO2);
bool result = atomic_compare_exchange_strong(&spTO3, &spTO, make_shared<TestObject>(88)); // spTO3 != spTO, so this should do no exchange and return false.
EATEST_VERIFY(!result);
EATEST_VERIFY(spTO3->mX == 56);
EATEST_VERIFY(spTO->mX == 56);
result = atomic_compare_exchange_strong(&spTO3, &spTO2, make_shared<TestObject>(88)); // spTO3 == spTO2, so this should succeed.
EATEST_VERIFY(result);
EATEST_VERIFY(spTO2->mX == 56);
EATEST_VERIFY(spTO3->mX == 88);
}
#endif
EATEST_VERIFY(A::mCount == 0);
TestObject::Reset();
return nErrorCount;
}
static int Test_weak_ptr()
{
using namespace SmartPtrTest;
using namespace eastl;
int nErrorCount(0);
{
weak_ptr<int> pW0;
shared_ptr<int> pS0(new int(0));
shared_ptr<int> pS1(new int(1));
weak_ptr<int> pW1(pS1);
weak_ptr<int> pW2;
weak_ptr<int> pW3(pW2);
EATEST_VERIFY(pS1.use_count() == 1);
EATEST_VERIFY(pW1.use_count() == 1);
EATEST_VERIFY(pW2.use_count() == 0);
EATEST_VERIFY(pW3.use_count() == 0);
EATEST_VERIFY(pW1.expired() == false);
EATEST_VERIFY(pW2.expired() == true);
EATEST_VERIFY(pW3.expired() == true);
pS1.reset();
EATEST_VERIFY(pW1.expired() == true);
pW1 = pS0;
EATEST_VERIFY(pW1.expired() == false);
pW1.swap(pW2);
EATEST_VERIFY(pW1.expired() == true);
EATEST_VERIFY(pW2.expired() == false);
pW1 = pW2;
EATEST_VERIFY(pW1.expired() == false);
pW3 = pW1;
EATEST_VERIFY(pW3.expired() == false);
EATEST_VERIFY(pS1.use_count() == 0);
pW3.reset();
EATEST_VERIFY(pW3.expired() == true);
pS1.reset(new int(3));
EATEST_VERIFY(pS1.use_count() == 1);
pW3 = pS1;
EATEST_VERIFY(pS1.use_count() == 1);
EATEST_VERIFY(pS1.use_count() == pW3.use_count());
shared_ptr<int> pShared2(pW2.lock());
shared_ptr<int> pShared3(pW3.lock());
EATEST_VERIFY(pShared2.use_count() == 2);
EATEST_VERIFY(pShared3.use_count() == 2);
swap(pW2, pW3);
EATEST_VERIFY(pW2.use_count() == 2);
EATEST_VERIFY(pW3.use_count() == 2);
pW1 = pW3;
EATEST_VERIFY(pW3.use_count() == 2);
EATEST_VERIFY((pW2 < pW3) || (pW3 < pW2));
EATEST_VERIFY(pS0.use_count() == 2);
pW0 = pS0; // This tests the deletion of a weak_ptr after its associated shared_ptr has destructed.
EATEST_VERIFY(pS0.use_count() == 2);
}
{
weak_ptr<NamedClass> wp;
EATEST_VERIFY(wp.use_count() == 0);
EATEST_VERIFY(wp.expired() == true);
{
shared_ptr<NamedClass> sp(new NamedClass("NamedClass"));
wp = sp;
EATEST_VERIFY(wp.use_count() == 1);
EATEST_VERIFY(wp.expired() == false);
}
EATEST_VERIFY(wp.use_count() == 0);
EATEST_VERIFY(wp.expired() == true);
}
{ // shared_from_this
// This example is taken from the C++11 Standard doc.
shared_ptr<const foo> pFoo(new foo);
shared_ptr<const foo> qFoo = pFoo->shared_from_this();
EATEST_VERIFY(pFoo == qFoo);
EATEST_VERIFY(!(pFoo < qFoo) && !(qFoo < pFoo)); // p and q share ownership
}
{ // weak_from_this const
shared_ptr<const foo> pFoo(new foo);
weak_ptr<const foo> qFoo = pFoo->weak_from_this();
EATEST_VERIFY(pFoo == qFoo.lock());
EATEST_VERIFY(!(pFoo < qFoo.lock()) && !(qFoo.lock() < pFoo)); // p and q share ownership
}
{ // weak_from_this
shared_ptr<foo> pFoo(new foo);
weak_ptr<foo> qFoo = pFoo->weak_from_this();
EATEST_VERIFY(pFoo == qFoo.lock());
EATEST_VERIFY(!(pFoo < qFoo.lock()) && !(qFoo.lock() < pFoo)); // p and q share ownership
}
return nErrorCount;
}
static int Test_shared_array()
{
using namespace SmartPtrTest;
using namespace eastl;
int nErrorCount(0);
{
shared_array<int> pT1(new int[5]);
pT1[0] = 5;
EATEST_VERIFY(pT1[0] == 5);
EATEST_VERIFY(pT1.get() == get_pointer(pT1));
EATEST_VERIFY(pT1.use_count() == 1);
EATEST_VERIFY(pT1.unique());
shared_array<int> pT2;
EATEST_VERIFY(pT1 != pT2);
EATEST_VERIFY(pT1.use_count() == 1);
EATEST_VERIFY(pT1.unique());
pT2 = pT1;
EATEST_VERIFY(pT1.use_count() == 2);
EATEST_VERIFY(pT2.use_count() == 2);
EATEST_VERIFY(!pT1.unique());
EATEST_VERIFY(!(pT1 < pT2)); // They should be equal
EATEST_VERIFY(pT1 == pT2);
*pT1 = 3;
EATEST_VERIFY(*pT1 == 3);
EATEST_VERIFY(*pT1 == 3);
EATEST_VERIFY(*pT2 == 3);
pT2.reset(0);
EATEST_VERIFY(pT2.unique());
EATEST_VERIFY(pT2.use_count() == 1);
EATEST_VERIFY(pT1.unique());
EATEST_VERIFY(pT1.use_count() == 1);
EATEST_VERIFY(pT1 != pT2);
}
{
EATEST_VERIFY(A::mCount == 0);
shared_array<A> pT2(new A[5]);
EATEST_VERIFY(A::mCount == 5);
EATEST_VERIFY(pT2->mc == 0);
EATEST_VERIFY(pT2.use_count() == 1);
EATEST_VERIFY(pT2.unique());
pT2.reset(new A[1]);
pT2[0].mc = 1;
EATEST_VERIFY(pT2->mc == 1);
EATEST_VERIFY(A::mCount == 1);
EATEST_VERIFY(pT2.use_count() == 1);
EATEST_VERIFY(pT2.unique());
shared_array<A> pT3(new A[2]);
EATEST_VERIFY(A::mCount == 3);
pT2.swap(pT3);
pT2[0].mc = 2;
EATEST_VERIFY(pT2->mc == 2);
EATEST_VERIFY(pT3->mc == 1);
EATEST_VERIFY(A::mCount == 3);
swap(pT2, pT3);
EATEST_VERIFY(pT2->mc == 1);
EATEST_VERIFY(pT3->mc == 2);
EATEST_VERIFY(A::mCount == 3);
if(!pT2)
EATEST_VERIFY(!pT2.get()); // Will fail
shared_array<A> pT4;
EATEST_VERIFY(pT2.use_count() == 1);
EATEST_VERIFY(pT2.unique());
EATEST_VERIFY(A::mCount == 3);
if(pT4)
EATEST_VERIFY(pT4.get()); // Will fail
if(!(!pT4))
EATEST_VERIFY(pT4.get()); // Will fail
pT4 = pT2;
EATEST_VERIFY(pT2.use_count() == 2);
EATEST_VERIFY(pT4.use_count() == 2);
EATEST_VERIFY(!pT2.unique());
EATEST_VERIFY(!pT4.unique());
EATEST_VERIFY(A::mCount == 3);
EATEST_VERIFY(pT2 == pT4);
EATEST_VERIFY(pT2 != pT3);
EATEST_VERIFY(!(pT2 < pT4)); // They should be equal
shared_array<A> pT5(pT4);
EATEST_VERIFY(pT4 == pT5);
EATEST_VERIFY(pT2.use_count() == 3);
EATEST_VERIFY(pT4.use_count() == 3);
EATEST_VERIFY(pT5.use_count() == 3);
EATEST_VERIFY(!pT5.unique());
pT4 = shared_array<A>(0);
EATEST_VERIFY(pT4.unique());
EATEST_VERIFY(pT4.use_count() == 1);
EATEST_VERIFY(pT2.use_count() == 2);
EATEST_VERIFY(A::mCount == 3);
}
EATEST_VERIFY(A::mCount == 0);
return nErrorCount;
}
static int Test_linked_ptr()
{
using namespace SmartPtrTest;
using namespace eastl;
int nErrorCount(0);
{
linked_ptr<int> pT1(new int(5));
EATEST_VERIFY(*pT1.get() == 5);
EATEST_VERIFY(pT1.get() == get_pointer(pT1));
EATEST_VERIFY(pT1.use_count() == 1);
EATEST_VERIFY(pT1.unique());
linked_ptr<int> pT2;
EATEST_VERIFY(pT1 != pT2);
EATEST_VERIFY(pT1.use_count() == 1);
EATEST_VERIFY(pT1.unique());
pT2 = pT1;
EATEST_VERIFY(pT1.use_count() == 2);
EATEST_VERIFY(pT2.use_count() == 2);
EATEST_VERIFY(!pT1.unique());
EATEST_VERIFY(!(pT1 < pT2)); // They should be equal
EATEST_VERIFY(pT1 == pT2);
*pT1 = 3;
EATEST_VERIFY(*pT1.get() == 3);
EATEST_VERIFY(*pT1 == 3);
EATEST_VERIFY(*pT2 == 3);
pT2.reset((int*)NULL);
EATEST_VERIFY(pT2.unique());
EATEST_VERIFY(pT2.use_count() == 1);
EATEST_VERIFY(pT1.unique());
EATEST_VERIFY(pT1.use_count() == 1);
EATEST_VERIFY(pT1 != pT2);
}
{
EATEST_VERIFY(A::mCount == 0);
linked_ptr<A> pT2(new A(0));
EATEST_VERIFY(A::mCount == 1);
EATEST_VERIFY(pT2->mc == 0);
EATEST_VERIFY(pT2.use_count() == 1);
EATEST_VERIFY(pT2.unique());
pT2.reset(new A(1));
EATEST_VERIFY(pT2->mc == 1);
EATEST_VERIFY(A::mCount == 1);
EATEST_VERIFY(pT2.use_count() == 1);
EATEST_VERIFY(pT2.unique());
linked_ptr<A> pT3(new A(2));
EATEST_VERIFY(A::mCount == 2);
linked_ptr<A> pT4;
EATEST_VERIFY(pT2.use_count() == 1);
EATEST_VERIFY(pT2.unique());
EATEST_VERIFY(A::mCount == 2);
if(pT4)
EATEST_VERIFY(pT4.get()); // Will fail
if(!(!pT4))
EATEST_VERIFY(pT4.get()); // Will fail
pT4 = pT2;
EATEST_VERIFY(pT2.use_count() == 2);
EATEST_VERIFY(pT4.use_count() == 2);
EATEST_VERIFY(!pT2.unique());
EATEST_VERIFY(!pT4.unique());
EATEST_VERIFY(A::mCount == 2);
EATEST_VERIFY(pT2 == pT4);
EATEST_VERIFY(pT2 != pT3);
EATEST_VERIFY(!(pT2 < pT4)); // They should be equal
linked_ptr<A> pT5(pT4);
EATEST_VERIFY(pT4 == pT5);
EATEST_VERIFY(pT2.use_count() == 3);
EATEST_VERIFY(pT4.use_count() == 3);
EATEST_VERIFY(pT5.use_count() == 3);
EATEST_VERIFY(!pT5.unique());
pT4 = linked_ptr<A>((A*)NULL);
EATEST_VERIFY(pT4.unique());
EATEST_VERIFY(pT4.use_count() == 1);
EATEST_VERIFY(pT2.use_count() == 2);
EATEST_VERIFY(A::mCount == 2);
}
{ // Do some force_delete tests.
linked_ptr<A> pT2(new A(0));
linked_ptr<A> pT3(pT2);
pT2.force_delete();
pT3.force_delete();
}
EATEST_VERIFY(A::mCount == 0);
{ // Verify that subclasses are usable.
bool bAlloc = false;
eastl::linked_ptr<DerivedMockObject> pDMO(new DerivedMockObject(&bAlloc));
eastl::linked_ptr<MockObject> a1(pDMO);
eastl::linked_ptr<MockObject> a2;
a2 = pDMO;
}
{ // Test regression for a bug.
linked_ptr<A> pT2;
linked_ptr<A> pT3(pT2); // In the bug linked_ptr::mpPrev and mpNext were not initialized via this ctor.
pT3.reset(new A); // In the bug this would crash due to unintialized mpPrev/mpNext.
linked_ptr<B> pT4;
linked_ptr<A> pT5(pT4);
pT5.reset(new A);
linked_array<A> pT6;
linked_array<A> pT7(pT6);
pT7.reset(new A[1]);
}
return nErrorCount;
}
static int Test_linked_array()
{
using namespace SmartPtrTest;
using namespace eastl;
int nErrorCount(0);
{
// Tests go here.
}
{ // Do some force_delete tests.
linked_array<A> pT2(new A[2]);
linked_array<A> pT3(pT2);
pT2.force_delete();
pT3.force_delete();
}
EATEST_VERIFY(A::mCount == 0);
return nErrorCount;
}
static int Test_intrusive_ptr()
{
using namespace SmartPtrTest;
using namespace eastl;
int nErrorCount = 0;
{ // Test ctor/dtor
intrusive_ptr<RefCountTest> ip1;
intrusive_ptr<RefCountTest> ip2(NULL, false);
intrusive_ptr<RefCountTest> ip3(NULL, true);
intrusive_ptr<RefCountTest> ip4(new RefCountTest, true);
intrusive_ptr<RefCountTest> ip5(new RefCountTest, false);
intrusive_ptr<RefCountTest> ip6(ip1);
intrusive_ptr<RefCountTest> ip7(ip4);
EATEST_VERIFY(ip1.get() == NULL);
EATEST_VERIFY(!ip1);
EATEST_VERIFY(ip2.get() == NULL);
EATEST_VERIFY(!ip2);
EATEST_VERIFY(ip3.get() == NULL);
EATEST_VERIFY(!ip3);
EATEST_VERIFY(ip4.get() != NULL);
EATEST_VERIFY(ip4.get()->mRefCount == 2);
EATEST_VERIFY(ip4);
EATEST_VERIFY(ip5.get() != NULL);
EATEST_VERIFY(ip5.get()->mRefCount == 0);
ip5.get()->AddRef();
EATEST_VERIFY(ip5.get()->mRefCount == 1);
EATEST_VERIFY(ip5);
EATEST_VERIFY(ip6.get() == NULL);
EATEST_VERIFY(!ip6);
EATEST_VERIFY(ip7.get() != NULL);
EATEST_VERIFY(ip7.get()->mRefCount == 2);
EATEST_VERIFY(ip7);
}
{
// Test move-ctor
{
VERIFY(RefCountTest::mCount == 0);
intrusive_ptr<RefCountTest> ip1(new RefCountTest);
VERIFY(RefCountTest::mCount == 1);
VERIFY(ip1->mRefCount == 1);
{
intrusive_ptr<RefCountTest> ip2(eastl::move(ip1));
VERIFY(ip1.get() != ip2.get());
VERIFY(ip2->mRefCount == 1);
VERIFY(RefCountTest::mCount == 1);
}
VERIFY(ip1.get() == nullptr);
VERIFY(RefCountTest::mCount == 0);
}
// Test move-assignment
{
VERIFY(RefCountTest::mCount == 0);
intrusive_ptr<RefCountTest> ip1(new RefCountTest);
VERIFY(RefCountTest::mCount == 1);
VERIFY(ip1->mRefCount == 1);
{
intrusive_ptr<RefCountTest> ip2;
ip2 = eastl::move(ip1);
VERIFY(ip1.get() != ip2.get());
VERIFY(ip2->mRefCount == 1);
VERIFY(RefCountTest::mCount == 1);
}
VERIFY(ip1.get() == nullptr);
VERIFY(RefCountTest::mCount == 0);
}
}
{ // Test modifiers (assign, attach, detach, reset, swap)
RefCountTest* const p1 = new RefCountTest;
RefCountTest* const p2 = new RefCountTest;
intrusive_ptr<RefCountTest> ip1;
intrusive_ptr<RefCountTest> ip2;
ip1 = p1;
ip2 = p2;
EATEST_VERIFY(ip1.get() == p1);
EATEST_VERIFY((*ip1).mRefCount == 1);
EATEST_VERIFY(ip1->mRefCount == 1);
ip1.detach();
EATEST_VERIFY(ip1.get() == NULL);
ip1.attach(p1);
EATEST_VERIFY(ip1.get() == p1);
EATEST_VERIFY(ip1->mRefCount == 1);
ip1.swap(ip2);
EATEST_VERIFY(ip1.get() == p2);
EATEST_VERIFY(ip2.get() == p1);
ip1.swap(ip2);
ip1 = ip2;
EATEST_VERIFY(ip1 == p2);
ip1.reset();
EATEST_VERIFY(ip1.get() == NULL);
EATEST_VERIFY(ip2.get() == p2);
ip2.reset();
EATEST_VERIFY(ip2.get() == NULL);
}
{ // Test external functions
intrusive_ptr<RefCountTest> ip1;
intrusive_ptr<RefCountTest> ip2(new RefCountTest);
intrusive_ptr<RefCountTest> ip3(ip1);
intrusive_ptr<RefCountTest> ip4(ip2);
// The VC++ code scanner crashes when it scans this code.
EATEST_VERIFY(get_pointer(ip1) == NULL);
EATEST_VERIFY(get_pointer(ip2) != NULL);
EATEST_VERIFY(get_pointer(ip3) == get_pointer(ip1));
EATEST_VERIFY(get_pointer(ip4) == get_pointer(ip2));
EATEST_VERIFY(ip3 == ip1);
EATEST_VERIFY(ip4 == ip2);
EATEST_VERIFY(ip1 == ip3);
EATEST_VERIFY(ip2 == ip4);
EATEST_VERIFY(ip1 != ip2);
EATEST_VERIFY(ip3 != ip4);
EATEST_VERIFY(ip2 != ip1);
EATEST_VERIFY(ip4 != ip3);
EATEST_VERIFY(ip3 == ip1.get());
EATEST_VERIFY(ip4 == ip2.get());
EATEST_VERIFY(ip1 == ip3.get());
EATEST_VERIFY(ip2 == ip4.get());
EATEST_VERIFY(ip1 != ip2.get());
EATEST_VERIFY(ip3 != ip4.get());
EATEST_VERIFY(ip2 != ip1.get());
EATEST_VERIFY(ip4 != ip3.get());
EATEST_VERIFY(ip3.get() == ip1);
EATEST_VERIFY(ip4.get() == ip2);
EATEST_VERIFY(ip1.get() == ip3);
EATEST_VERIFY(ip2.get() == ip4);
EATEST_VERIFY(ip1.get() != ip2);
EATEST_VERIFY(ip3.get() != ip4);
EATEST_VERIFY(ip2.get() != ip1);
EATEST_VERIFY(ip4.get() != ip3);
EATEST_VERIFY((ip4 < ip3) || (ip3 < ip4));
swap(ip1, ip3);
EATEST_VERIFY(get_pointer(ip3) == get_pointer(ip1));
swap(ip2, ip4);
EATEST_VERIFY(get_pointer(ip2) == get_pointer(ip4));
swap(ip1, ip2);
EATEST_VERIFY(get_pointer(ip1) != NULL);
EATEST_VERIFY(get_pointer(ip2) == NULL);
EATEST_VERIFY(get_pointer(ip1) == get_pointer(ip4));
EATEST_VERIFY(get_pointer(ip2) == get_pointer(ip3));
}
{ // Misc tests.
intrusive_ptr<Test> ip;
EATEST_VERIFY(ip.get() == NULL);
ip.reset();
EATEST_VERIFY(ip.get() == NULL);
intrusive_ptr<Test> ip2(NULL, false);
EATEST_VERIFY(ip.get() == NULL);
bool boolValue = false;
Test* pTest = new Test(&boolValue);
EATEST_VERIFY(boolValue);
pTest->AddRef();
intrusive_ptr<Test> ip3(pTest, false);
EATEST_VERIFY(ip3.get() == pTest);
ip3.reset();
EATEST_VERIFY(!boolValue);
}
{ // Misc tests.
bool boolArray[3];
memset(boolArray, 0, sizeof(boolArray));
Test* p1 = new Test(boolArray + 0);
EATEST_VERIFY(boolArray[0] && !boolArray[1] && !boolArray[2]);
intrusive_ptr<Test> arc1(p1);
EATEST_VERIFY(boolArray[0] && !boolArray[1] && !boolArray[2]);
Test* p2 = new Test(boolArray + 1);
EATEST_VERIFY(boolArray[0] && boolArray[1] && !boolArray[2]);
arc1 = p2;
EATEST_VERIFY(!boolArray[0] && boolArray[1] && !boolArray[2]);
Test* p3 = new Test(boolArray + 2);
EATEST_VERIFY(!boolArray[0] && boolArray[1] && boolArray[2]);
arc1 = p3;
EATEST_VERIFY(!boolArray[0] && !boolArray[1] && boolArray[2]);
arc1 = NULL;
EATEST_VERIFY(!boolArray[0] && !boolArray[1] && !boolArray[2]);
}
{ // Test intrusive_ptr_add_ref() / intrusive_ptr_release()
IntrusiveCustom* const pIC = new IntrusiveCustom;
{
intrusive_ptr<IntrusiveCustom> bp = intrusive_ptr<IntrusiveCustom>(pIC);
intrusive_ptr<IntrusiveCustom> ap = bp;
}
EATEST_VERIFY((IntrusiveCustom::mAddRefCallCount > 0) && (IntrusiveCustom::mReleaseCallCount == IntrusiveCustom::mAddRefCallCount));
}
{ // Regression
intrusive_ptr<IntrusiveChild> bp = intrusive_ptr<IntrusiveChild>(new IntrusiveChild);
intrusive_ptr<IntrusiveParent> ap = bp;
}
return nErrorCount;
}
struct RandomLifetimeObject : public eastl::safe_object
{
void DoSomething() const { }
};
static int Test_safe_ptr()
{
using namespace SmartPtrTest;
using namespace eastl;
int nErrorCount = 0;
{ // non-const RandomLifetimeObject
RandomLifetimeObject* pObject = new RandomLifetimeObject;
eastl::safe_ptr<RandomLifetimeObject> pSafePtr(pObject);
eastl::safe_ptr<RandomLifetimeObject> pSafePtrCopy1 = pSafePtr;
eastl::safe_ptr<RandomLifetimeObject> pSafePtrCopy2(pSafePtr);
pSafePtr->DoSomething();
eastl::safe_ptr<RandomLifetimeObject>* pSafePtrCopy3 = new eastl::safe_ptr<RandomLifetimeObject>(pSafePtr);
eastl::safe_ptr<RandomLifetimeObject>* pSafePtrCopy4 = new eastl::safe_ptr<RandomLifetimeObject>(pSafePtr);
EATEST_VERIFY(pSafePtrCopy3->get() == pObject);
EATEST_VERIFY(pSafePtrCopy4->get() == pObject);
delete pSafePtrCopy3;
delete pSafePtrCopy4;
delete pSafePtr;
EATEST_VERIFY(pSafePtrCopy1.get() == NULL);
EATEST_VERIFY(pSafePtrCopy2.get() == NULL);
}
{ // const RandomLifetimeObject
RandomLifetimeObject* pObject = new RandomLifetimeObject;
eastl::safe_ptr<const RandomLifetimeObject> pSafePtr(pObject);
eastl::safe_ptr<const RandomLifetimeObject> pSafePtrCopy1(pSafePtr);
eastl::safe_ptr<const RandomLifetimeObject> pSafePtrCopy2 = pSafePtr;
pSafePtr->DoSomething();
eastl::safe_ptr<const RandomLifetimeObject>* pSafePtrCopy3 = new eastl::safe_ptr<const RandomLifetimeObject>(pSafePtr);
eastl::safe_ptr<const RandomLifetimeObject>* pSafePtrCopy4 = new eastl::safe_ptr<const RandomLifetimeObject>(pSafePtr);
EATEST_VERIFY(pSafePtrCopy3->get() == pObject);
EATEST_VERIFY(pSafePtrCopy4->get() == pObject);
delete pSafePtrCopy3;
delete pSafePtrCopy4;
delete pSafePtr;
EATEST_VERIFY(pSafePtrCopy1.get() == NULL);
EATEST_VERIFY(pSafePtrCopy2.get() == NULL);
}
return nErrorCount;
}
int TestSmartPtr()
{
using namespace SmartPtrTest;
using namespace eastl;
int nErrorCount = 0;
nErrorCount += Test_unique_ptr();
nErrorCount += Test_scoped_ptr();
nErrorCount += Test_scoped_array();
nErrorCount += Test_shared_ptr();
nErrorCount += Test_shared_ptr_thread();
nErrorCount += Test_weak_ptr();
nErrorCount += Test_shared_array();
nErrorCount += Test_linked_ptr();
nErrorCount += Test_linked_array();
nErrorCount += Test_intrusive_ptr();
nErrorCount += Test_safe_ptr();
EATEST_VERIFY(A::mCount == 0);
EATEST_VERIFY(RefCountTest::mCount == 0);
EATEST_VERIFY(NamedClass::mnCount == 0);
EATEST_VERIFY(Y::mnCount == 0);
EATEST_VERIFY(ACLS::mnCount == 0);
EATEST_VERIFY(BCLS::mnCount == 0);
EATEST_VERIFY(A1::mnCount == 0);
EATEST_VERIFY(B1::mnCount == 0);
return nErrorCount;
}
EA_RESTORE_VC_WARNING() // 4702
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