tests/notnull_tests.cpp - platform/external/Microsoft-GSL - Gitiles

 ///////////////////////////////////////////////////////////////////////////////
 //
 // Copyright (c) 2015 Microsoft Corporation. All rights reserved.
 //
 // This code is licensed under the MIT License (MIT).
 //
 // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
 // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
 // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
 // THE SOFTWARE.
 //
 ///////////////////////////////////////////////////////////////////////////////

 #include <catch/catch.hpp>

 #include <gsl/gsl>

 #include <memory>
 #include <string>
 #include <vector>

 using namespace gsl;

 struct MyBase
 {
 };
 struct MyDerived : public MyBase
 {
 };
 struct Unrelated
 {
 };

 // stand-in for a user-defined ref-counted class
 template <typename T>
 struct RefCounted
 {
     RefCounted(T* p) : p_(p) {}
     operator T*() { return p_; }
     T* p_;
 };

 // user defined smart pointer with comparison operators returning non bool value
 template <typename T>
 struct CustomPtr
 {
     CustomPtr(T* p) : p_(p) {}
     operator T*() { return p_; }
     bool operator!=(std::nullptr_t) const { return p_ != nullptr; }
     T* p_ = nullptr;
 };

 template <typename T, typename U>
 std::string operator==(CustomPtr<T> const& lhs, CustomPtr<U> const& rhs)
 {
     return reinterpret_cast<const void*>(lhs.p_) == reinterpret_cast<const void*>(rhs.p_) ? "true"
                                                                                           : "false";
 }

 template <typename T, typename U>
 std::string operator!=(CustomPtr<T> const& lhs, CustomPtr<U> const& rhs)
 {
     return reinterpret_cast<const void*>(lhs.p_) != reinterpret_cast<const void*>(rhs.p_) ? "true"
                                                                                           : "false";
 }

 template <typename T, typename U>
 std::string operator<(CustomPtr<T> const& lhs, CustomPtr<U> const& rhs)
 {
     return reinterpret_cast<const void*>(lhs.p_) < reinterpret_cast<const void*>(rhs.p_) ? "true"
                                                                                          : "false";
 }

 template <typename T, typename U>
 std::string operator>(CustomPtr<T> const& lhs, CustomPtr<U> const& rhs)
 {
     return reinterpret_cast<const void*>(lhs.p_) > reinterpret_cast<const void*>(rhs.p_) ? "true"
                                                                                          : "false";
 }

 template <typename T, typename U>
 std::string operator<=(CustomPtr<T> const& lhs, CustomPtr<U> const& rhs)
 {
     return reinterpret_cast<const void*>(lhs.p_) <= reinterpret_cast<const void*>(rhs.p_) ? "true"
                                                                                           : "false";
 }

 template <typename T, typename U>
 std::string operator>=(CustomPtr<T> const& lhs, CustomPtr<U> const& rhs)
 {
     return reinterpret_cast<const void*>(lhs.p_) >= reinterpret_cast<const void*>(rhs.p_) ? "true"
                                                                                           : "false";
 }

 struct NonCopyableNonMovable
 {
     NonCopyableNonMovable() = default;
     NonCopyableNonMovable(const NonCopyableNonMovable&) = delete;
     NonCopyableNonMovable& operator=(const NonCopyableNonMovable&) = delete;
     NonCopyableNonMovable(NonCopyableNonMovable&&) = delete;
     NonCopyableNonMovable& operator=(NonCopyableNonMovable&&) = delete;
 };

 bool helper(not_null<int*> p) { return *p == 12; }

 TEST_CASE("TestNotNullConstructors")
 {
 #ifdef CONFIRM_COMPILATION_ERRORS
     not_null<int*> p = nullptr;         // yay...does not compile!
     not_null<std::vector<char>*> p = 0; // yay...does not compile!
     not_null<int*> p;                   // yay...does not compile!
     std::unique_ptr<int> up = std::make_unique<int>(120);
     not_null<int*> p = up;

     // Forbid non-nullptr assignable types
     not_null<std::vector<int>> f(std::vector<int>{1});
     not_null<int> z(10);
     not_null<std::vector<int>> y({1, 2});
 #endif
     int i = 12;
     auto rp = RefCounted<int>(&i);
     not_null<int*> p(rp);
     CHECK(p.get() == &i);

     not_null<std::shared_ptr<int>> x(
         std::make_shared<int>(10)); // shared_ptr<int> is nullptr assignable
 }

 TEST_CASE("TestNotNullCasting")
 {
     MyBase base;
     MyDerived derived;
     Unrelated unrelated;
     not_null<Unrelated*> u = &unrelated;
     (void) u;
     not_null<MyDerived*> p = &derived;
     not_null<MyBase*> q = &base;
     q = p; // allowed with heterogeneous copy ctor
     CHECK(q == p);

 #ifdef CONFIRM_COMPILATION_ERRORS
     q = u; // no viable conversion possible between MyBase* and Unrelated*
     p = q; // not possible to implicitly convert MyBase* to MyDerived*

     not_null<Unrelated*> r = p;
     not_null<Unrelated*> s = reinterpret_cast<Unrelated*>(p);
 #endif
     not_null<Unrelated*> t = reinterpret_cast<Unrelated*>(p.get());
     CHECK(reinterpret_cast<void*>(p.get()) == reinterpret_cast<void*>(t.get()));
 }

 TEST_CASE("TestNotNullAssignment")
 {
     int i = 12;
     not_null<int*> p = &i;
     CHECK(helper(p));

     int* q = nullptr;
     CHECK_THROWS_AS(p = q, fail_fast);
 }

 TEST_CASE("TestNotNullRawPointerComparison")
 {
     int ints[2] = {42, 43};
     int* p1 = &ints[0];
     const int* p2 = &ints[1];

     using NotNull1 = not_null<decltype(p1)>;
     using NotNull2 = not_null<decltype(p2)>;

     CHECK((NotNull1(p1) == NotNull1(p1)) == true);
     CHECK((NotNull1(p1) == NotNull2(p2)) == false);

     CHECK((NotNull1(p1) != NotNull1(p1)) == false);
     CHECK((NotNull1(p1) != NotNull2(p2)) == true);

     CHECK((NotNull1(p1) < NotNull1(p1)) == false);
     CHECK((NotNull1(p1) < NotNull2(p2)) == (p1 < p2));
     CHECK((NotNull2(p2) < NotNull1(p1)) == (p2 < p1));

     CHECK((NotNull1(p1) > NotNull1(p1)) == false);
     CHECK((NotNull1(p1) > NotNull2(p2)) == (p1 > p2));
     CHECK((NotNull2(p2) > NotNull1(p1)) == (p2 > p1));

     CHECK((NotNull1(p1) <= NotNull1(p1)) == true);
     CHECK((NotNull1(p1) <= NotNull2(p2)) == (p1 <= p2));
     CHECK((NotNull2(p2) <= NotNull1(p1)) == (p2 <= p1));

 }

 TEST_CASE("TestNotNullDereferenceOperator")
 {
     {
         auto sp1 = std::make_shared<NonCopyableNonMovable>();

         using NotNullSp1 = not_null<decltype(sp1)>;
         CHECK(typeid(*sp1) == typeid(*NotNullSp1(sp1)));
         CHECK(std::addressof(*NotNullSp1(sp1)) == std::addressof(*sp1));
     }

     {
         int ints[1] = { 42 };
         CustomPtr<int> p1(&ints[0]);

         using NotNull1 = not_null<decltype(p1)>;
         CHECK(typeid(*NotNull1(p1)) == typeid(*p1));
         CHECK(*NotNull1(p1) == 42);
         *NotNull1(p1) = 43;
         CHECK(ints[0] == 43);
     }

     {
         int v = 42;
         gsl::not_null<int*> p(&v);
         CHECK(typeid(*p) == typeid(*(&v)));
         *p = 43;
         CHECK(v == 43);
     }
 }

 TEST_CASE("TestNotNullSharedPtrComparison")
 {
     auto sp1 = std::make_shared<int>(42);
     auto sp2 = std::make_shared<const int>(43);

     using NotNullSp1 = not_null<decltype(sp1)>;
     using NotNullSp2 = not_null<decltype(sp2)>;

     CHECK((NotNullSp1(sp1) == NotNullSp1(sp1)) == true);
     CHECK((NotNullSp1(sp1) == NotNullSp2(sp2)) == false);

     CHECK((NotNullSp1(sp1) != NotNullSp1(sp1)) == false);
     CHECK((NotNullSp1(sp1) != NotNullSp2(sp2)) == true);

     CHECK((NotNullSp1(sp1) < NotNullSp1(sp1)) == false);
     CHECK((NotNullSp1(sp1) < NotNullSp2(sp2)) == (sp1 < sp2));
     CHECK((NotNullSp2(sp2) < NotNullSp1(sp1)) == (sp2 < sp1));

     CHECK((NotNullSp1(sp1) > NotNullSp1(sp1)) == false);
     CHECK((NotNullSp1(sp1) > NotNullSp2(sp2)) == (sp1 > sp2));
     CHECK((NotNullSp2(sp2) > NotNullSp1(sp1)) == (sp2 > sp1));

     CHECK((NotNullSp1(sp1) <= NotNullSp1(sp1)) == true);
     CHECK((NotNullSp1(sp1) <= NotNullSp2(sp2)) == (sp1 <= sp2));
     CHECK((NotNullSp2(sp2) <= NotNullSp1(sp1)) == (sp2 <= sp1));

     CHECK((NotNullSp1(sp1) >= NotNullSp1(sp1)) == true);
     CHECK((NotNullSp1(sp1) >= NotNullSp2(sp2)) == (sp1 >= sp2));
     CHECK((NotNullSp2(sp2) >= NotNullSp1(sp1)) == (sp2 >= sp1));
 }

 TEST_CASE("TestNotNullCustomPtrComparison")
 {
     int ints[2] = {42, 43};
     CustomPtr<int> p1(&ints[0]);
     CustomPtr<const int> p2(&ints[1]);

     using NotNull1 = not_null<decltype(p1)>;
     using NotNull2 = not_null<decltype(p2)>;

     CHECK((NotNull1(p1) == NotNull1(p1)) == "true");
     CHECK((NotNull1(p1) == NotNull2(p2)) == "false");

     CHECK((NotNull1(p1) != NotNull1(p1)) == "false");
     CHECK((NotNull1(p1) != NotNull2(p2)) == "true");

     CHECK((NotNull1(p1) < NotNull1(p1)) == "false");
     CHECK((NotNull1(p1) < NotNull2(p2)) == (p1 < p2));
     CHECK((NotNull2(p2) < NotNull1(p1)) == (p2 < p1));

     CHECK((NotNull1(p1) > NotNull1(p1)) == "false");
     CHECK((NotNull1(p1) > NotNull2(p2)) == (p1 > p2));
     CHECK((NotNull2(p2) > NotNull1(p1)) == (p2 > p1));

     CHECK((NotNull1(p1) <= NotNull1(p1)) == "true");
     CHECK((NotNull1(p1) <= NotNull2(p2)) == (p1 <= p2));
     CHECK((NotNull2(p2) <= NotNull1(p1)) == (p2 <= p1));

     CHECK((NotNull1(p1) >= NotNull1(p1)) == "true");
     CHECK((NotNull1(p1) >= NotNull2(p2)) == (p1 >= p2));
     CHECK((NotNull2(p2) >= NotNull1(p1)) == (p2 >= p1));
 }
	///////////////////////////////////////////////////////////////////////////////
	//
	// Copyright (c) 2015 Microsoft Corporation. All rights reserved.
	//
	// This code is licensed under the MIT License (MIT).
	//
	// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
	// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
	// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
	// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
	// THE SOFTWARE.
	//
	///////////////////////////////////////////////////////////////////////////////

	#include <catch/catch.hpp>

	#include <gsl/gsl>

	#include <memory>
	#include <string>
	#include <vector>

	using namespace gsl;

	struct MyBase
	{
	};
	struct MyDerived : public MyBase
	{
	};
	struct Unrelated
	{
	};

	// stand-in for a user-defined ref-counted class
	template <typename T>
	struct RefCounted
	{
	RefCounted(T* p) : p_(p) {}
	operator T*() { return p_; }
	T* p_;
	};

	// user defined smart pointer with comparison operators returning non bool value
	template <typename T>
	struct CustomPtr
	{
	CustomPtr(T* p) : p_(p) {}
	operator T*() { return p_; }
	bool operator!=(std::nullptr_t) const { return p_ != nullptr; }
	T* p_ = nullptr;
	};

	template <typename T, typename U>
	std::string operator==(CustomPtr<T> const& lhs, CustomPtr<U> const& rhs)
	{
	return reinterpret_cast<const void>(lhs.p_) == reinterpret_cast<const void>(rhs.p_) ? "true"
	: "false";
	}

	template <typename T, typename U>
	std::string operator!=(CustomPtr<T> const& lhs, CustomPtr<U> const& rhs)
	{
	return reinterpret_cast<const void>(lhs.p_) != reinterpret_cast<const void>(rhs.p_) ? "true"
	: "false";
	}

	template <typename T, typename U>
	std::string operator<(CustomPtr<T> const& lhs, CustomPtr<U> const& rhs)
	{
	return reinterpret_cast<const void>(lhs.p_) < reinterpret_cast<const void>(rhs.p_) ? "true"
	: "false";
	}

	template <typename T, typename U>
	std::string operator>(CustomPtr<T> const& lhs, CustomPtr<U> const& rhs)
	{
	return reinterpret_cast<const void>(lhs.p_) > reinterpret_cast<const void>(rhs.p_) ? "true"
	: "false";
	}

	template <typename T, typename U>
	std::string operator<=(CustomPtr<T> const& lhs, CustomPtr<U> const& rhs)
	{
	return reinterpret_cast<const void>(lhs.p_) <= reinterpret_cast<const void>(rhs.p_) ? "true"
	: "false";
	}

	template <typename T, typename U>
	std::string operator>=(CustomPtr<T> const& lhs, CustomPtr<U> const& rhs)
	{
	return reinterpret_cast<const void>(lhs.p_) >= reinterpret_cast<const void>(rhs.p_) ? "true"
	: "false";
	}

	struct NonCopyableNonMovable
	{
	NonCopyableNonMovable() = default;
	NonCopyableNonMovable(const NonCopyableNonMovable&) = delete;
	NonCopyableNonMovable& operator=(const NonCopyableNonMovable&) = delete;
	NonCopyableNonMovable(NonCopyableNonMovable&&) = delete;
	NonCopyableNonMovable& operator=(NonCopyableNonMovable&&) = delete;
	};

	bool helper(not_null<int> p) { return p == 12; }

	TEST_CASE("TestNotNullConstructors")
	{
	#ifdef CONFIRM_COMPILATION_ERRORS
	not_null<int*> p = nullptr; // yay...does not compile!
	not_null<std::vector<char>*> p = 0; // yay...does not compile!
	not_null<int*> p; // yay...does not compile!
	std::unique_ptr<int> up = std::make_unique<int>(120);
	not_null<int*> p = up;

	// Forbid non-nullptr assignable types
	not_null<std::vector<int>> f(std::vector<int>{1});
	not_null<int> z(10);
	not_null<std::vector<int>> y({1, 2});
	#endif
	int i = 12;
	auto rp = RefCounted<int>(&i);
	not_null<int*> p(rp);
	CHECK(p.get() == &i);

	not_null<std::shared_ptr<int>> x(
	std::make_shared<int>(10)); // shared_ptr<int> is nullptr assignable
	}

	TEST_CASE("TestNotNullCasting")
	{
	MyBase base;
	MyDerived derived;
	Unrelated unrelated;
	not_null<Unrelated*> u = &unrelated;
	(void) u;
	not_null<MyDerived*> p = &derived;
	not_null<MyBase*> q = &base;
	q = p; // allowed with heterogeneous copy ctor
	CHECK(q == p);

	#ifdef CONFIRM_COMPILATION_ERRORS
	q = u; // no viable conversion possible between MyBase* and Unrelated*
	p = q; // not possible to implicitly convert MyBase* to MyDerived*

	not_null<Unrelated*> r = p;
	not_null<Unrelated> s = reinterpret_cast<Unrelated>(p);
	#endif
	not_null<Unrelated> t = reinterpret_cast<Unrelated>(p.get());
	CHECK(reinterpret_cast<void>(p.get()) == reinterpret_cast<void>(t.get()));
	}

	TEST_CASE("TestNotNullAssignment")
	{
	int i = 12;
	not_null<int*> p = &i;
	CHECK(helper(p));

	int* q = nullptr;
	CHECK_THROWS_AS(p = q, fail_fast);
	}

	TEST_CASE("TestNotNullRawPointerComparison")
	{
	int ints[2] = {42, 43};
	int* p1 = &ints[0];
	const int* p2 = &ints[1];

	using NotNull1 = not_null<decltype(p1)>;
	using NotNull2 = not_null<decltype(p2)>;

	CHECK((NotNull1(p1) == NotNull1(p1)) == true);
	CHECK((NotNull1(p1) == NotNull2(p2)) == false);

	CHECK((NotNull1(p1) != NotNull1(p1)) == false);
	CHECK((NotNull1(p1) != NotNull2(p2)) == true);

	CHECK((NotNull1(p1) < NotNull1(p1)) == false);
	CHECK((NotNull1(p1) < NotNull2(p2)) == (p1 < p2));
	CHECK((NotNull2(p2) < NotNull1(p1)) == (p2 < p1));

	CHECK((NotNull1(p1) > NotNull1(p1)) == false);
	CHECK((NotNull1(p1) > NotNull2(p2)) == (p1 > p2));
	CHECK((NotNull2(p2) > NotNull1(p1)) == (p2 > p1));

	CHECK((NotNull1(p1) <= NotNull1(p1)) == true);
	CHECK((NotNull1(p1) <= NotNull2(p2)) == (p1 <= p2));
	CHECK((NotNull2(p2) <= NotNull1(p1)) == (p2 <= p1));

	}

	TEST_CASE("TestNotNullDereferenceOperator")
	{
	{
	auto sp1 = std::make_shared<NonCopyableNonMovable>();

	using NotNullSp1 = not_null<decltype(sp1)>;
	CHECK(typeid(sp1) == typeid(NotNullSp1(sp1)));
	CHECK(std::addressof(NotNullSp1(sp1)) == std::addressof(sp1));
	}

	{
	int ints[1] = { 42 };
	CustomPtr<int> p1(&ints[0]);

	using NotNull1 = not_null<decltype(p1)>;
	CHECK(typeid(NotNull1(p1)) == typeid(p1));
	CHECK(*NotNull1(p1) == 42);
	*NotNull1(p1) = 43;
	CHECK(ints[0] == 43);
	}

	{
	int v = 42;
	gsl::not_null<int*> p(&v);
	CHECK(typeid(p) == typeid((&v)));
	*p = 43;
	CHECK(v == 43);
	}
	}

	TEST_CASE("TestNotNullSharedPtrComparison")
	{
	auto sp1 = std::make_shared<int>(42);
	auto sp2 = std::make_shared<const int>(43);

	using NotNullSp1 = not_null<decltype(sp1)>;
	using NotNullSp2 = not_null<decltype(sp2)>;

	CHECK((NotNullSp1(sp1) == NotNullSp1(sp1)) == true);
	CHECK((NotNullSp1(sp1) == NotNullSp2(sp2)) == false);

	CHECK((NotNullSp1(sp1) != NotNullSp1(sp1)) == false);
	CHECK((NotNullSp1(sp1) != NotNullSp2(sp2)) == true);

	CHECK((NotNullSp1(sp1) < NotNullSp1(sp1)) == false);
	CHECK((NotNullSp1(sp1) < NotNullSp2(sp2)) == (sp1 < sp2));
	CHECK((NotNullSp2(sp2) < NotNullSp1(sp1)) == (sp2 < sp1));

	CHECK((NotNullSp1(sp1) > NotNullSp1(sp1)) == false);
	CHECK((NotNullSp1(sp1) > NotNullSp2(sp2)) == (sp1 > sp2));
	CHECK((NotNullSp2(sp2) > NotNullSp1(sp1)) == (sp2 > sp1));

	CHECK((NotNullSp1(sp1) <= NotNullSp1(sp1)) == true);
	CHECK((NotNullSp1(sp1) <= NotNullSp2(sp2)) == (sp1 <= sp2));
	CHECK((NotNullSp2(sp2) <= NotNullSp1(sp1)) == (sp2 <= sp1));

	CHECK((NotNullSp1(sp1) >= NotNullSp1(sp1)) == true);
	CHECK((NotNullSp1(sp1) >= NotNullSp2(sp2)) == (sp1 >= sp2));
	CHECK((NotNullSp2(sp2) >= NotNullSp1(sp1)) == (sp2 >= sp1));
	}

	TEST_CASE("TestNotNullCustomPtrComparison")
	{
	int ints[2] = {42, 43};
	CustomPtr<int> p1(&ints[0]);
	CustomPtr<const int> p2(&ints[1]);

	using NotNull1 = not_null<decltype(p1)>;
	using NotNull2 = not_null<decltype(p2)>;

	CHECK((NotNull1(p1) == NotNull1(p1)) == "true");
	CHECK((NotNull1(p1) == NotNull2(p2)) == "false");

	CHECK((NotNull1(p1) != NotNull1(p1)) == "false");
	CHECK((NotNull1(p1) != NotNull2(p2)) == "true");

	CHECK((NotNull1(p1) < NotNull1(p1)) == "false");
	CHECK((NotNull1(p1) < NotNull2(p2)) == (p1 < p2));
	CHECK((NotNull2(p2) < NotNull1(p1)) == (p2 < p1));

	CHECK((NotNull1(p1) > NotNull1(p1)) == "false");
	CHECK((NotNull1(p1) > NotNull2(p2)) == (p1 > p2));
	CHECK((NotNull2(p2) > NotNull1(p1)) == (p2 > p1));

	CHECK((NotNull1(p1) <= NotNull1(p1)) == "true");
	CHECK((NotNull1(p1) <= NotNull2(p2)) == (p1 <= p2));
	CHECK((NotNull2(p2) <= NotNull1(p1)) == (p2 <= p1));

	CHECK((NotNull1(p1) >= NotNull1(p1)) == "true");
	CHECK((NotNull1(p1) >= NotNull2(p2)) == (p1 >= p2));
	CHECK((NotNull2(p2) >= NotNull1(p1)) == (p2 >= p1));
	}