test/SemaSYCL/unique_stable_name.cpp - llvm-project/clang - Git at Google

 // RUN: %clang_cc1 %s -std=c++17 -triple x86_64-pc-windows-msvc -fsycl-is-device -verify -fsyntax-only -Wno-unused
 // RUN: %clang_cc1 %s -std=c++17 -triple x86_64-linux-gnu -fsycl-is-device -verify -fsyntax-only -Wno-unused

 template <typename KernelName, typename KernelType>
 [[clang::sycl_kernel]] void kernel_single_task(KernelType kernelFunc) { // #kernelSingleTask
   kernelFunc();
 }

 // kernel1 - expect error
 // The current function is named with a lambda (i.e., takes a lambda as a
 // template parameter. Call the builtin on the current function then it is
 // passed to a kernel. Test that passing the given function to the unique
 // stable name builtin and then to the kernel throws an error because the
 // latter causes its name mangling to change.
 template <typename Func>
 void kernel1func(const Func &F1) {
   constexpr const char *F1_output = __builtin_sycl_unique_stable_name(Func); // #USN_F1
   kernel_single_task<class kernel1>(F1); // #kernel1_call
 }

 void callkernel1() {
   kernel1func([]() {}); // #kernel1func_call
 }

 // kernel2 - expect error
 // The current function is named with a lambda (i.e., takes a lambda as a
 // template parameter). Call the builtin on the given function,
 // then an empty lambda is passed to kernel.
 // Test that passing the given function to the unique stable name builtin and
 // then passing a different lambda to the kernel still throws an error because
 // the calling context is part of naming the kernel. Even though the given
 // function (F2) is not passed to the kernel, its mangling changes due to
 // kernel call with the unrelated lambda.
 template <typename Func>
 void kernel2func(const Func &F2) {
   constexpr const char *F2_output = __builtin_sycl_unique_stable_name(Func); // #USN_F2
   kernel_single_task<class kernel2>([]() {});
 }

 void callkernel2() {
   kernel2func([]() {}); // #kernel2func_call
 }

 template <template <typename> typename Outer, typename Inner>
 struct S {
   void operator()() const;
 };

 template <typename Ty>
 struct Tangerine {};

 template <typename Func>
 void kernel3_4func(const Func &F) {
   // Test that passing the same lambda to two kernels does not cause an error
   // because the kernel uses do not interfere with each other or invalidate
   // the stable name in any way.
   kernel_single_task<class kernel3>(F);
   kernel_single_task<class kernel4>(F);
   // Using the same functor twice should be fine
 }

 // kernel3 and kernel4 - expect no errors
 void callkernel3_4() {
   kernel3_4func([]() {});
 }

 template <typename T>
 static constexpr const char *output1 = __builtin_sycl_unique_stable_name(T);

 #define MACRO()                      \
   auto l14 = []() { return 1; };     \
   constexpr const char *l14_output = \
       __builtin_sycl_unique_stable_name(decltype(l14));

 int main() {

   // kernel5 - expect no error
   // Test that passing the lambda to the unique stable name builtin and then
   // using the lambda in a way that does not  contribute to the kernel name
   // does not cause an error because the  stable name is not invalidated in
   // this situation.
   auto l5 = []() {};
   constexpr const char *l5_output =
       __builtin_sycl_unique_stable_name(decltype(l5));
   kernel_single_task<class kernel5>(
       [=]() { l5(); }); // Used in the kernel, but not the kernel name itself

   // kernel6 - expect no error
   // Test that passing the lambda to the unique stable name builtin and then
   // using the same lambda in the naming of a kernel does not cause a diagnostic
   // on the kernel use due to the change in results to the stable name.
   auto l6 = []() { return 1; };
   constexpr const char *l6_output =
       __builtin_sycl_unique_stable_name(decltype(l6)); // #USN_l6
   kernel_single_task<class kernel6>(l6); // Used in the kernel name after builtin

   // kernel7 - expect no error
   // Same as kernel11 (below) except make the lambda part of naming the kernel.
   // Test that passing a lambda to the unique stable name builtin and then
   // passing a second lambda to the kernel does not throw an error because the
   // first lambda is included in the signature of the second lambda, but does
   // not change the mangling of the kernel.
   auto l7 = []() { return 1; };
   auto l8 = [](decltype(l7) *derp = nullptr) { return 2; };
   constexpr const char *l7_output =
       __builtin_sycl_unique_stable_name(decltype(l7)); // #USN_l7
   kernel_single_task<class kernel7>(l8);

   // kernel8 and kernel9 - expect no error
   // Tests that passing a lambda to the unique stable name builtin and passing
   // it to a kernel called with an if constexpr branch does not cause a
   // diagnostic on the kernel9 as it does not change the result to the stable
   // name. This is interesting even though the use of kernel9 happens in the
   // false branch of a constexpr if because both the true and the false branches
   // cause the instantiation of kernel_single_task.
   auto l9 = []() { return 1; };
   auto l10 = []() { return 2; };
   constexpr const char *l10_output =
       __builtin_sycl_unique_stable_name(decltype(l10)); // #USN_l10
   if constexpr (1) {
     kernel_single_task<class kernel8>(l9);
   } else {
     kernel_single_task<class kernel9>(l10);
   }

   // kernel11 - expect no error
   // Test that passing a lambda to the unique stable name builtin and then
   // passing a second lambda capturing the first one to the kernel does not
   // throw an error because the first lambda is not involved in naming the
   // kernel i.e., the mangling does not change.
   auto l11 = []() { return 1; };
   auto l12 = [l11]() { return 2; };
   constexpr const char *l11_output =
       __builtin_sycl_unique_stable_name(decltype(l11));
   kernel_single_task<class kernel11>(l12);

   // kernel12 - expect no error
   // Test that passing a lambda to the unique stable name builtin and then
   // passing it to the kernel as a template template parameter does not cause a
   // diagnostic on the kernel use due to template template parameter being
   // involved in the mangling of the kernel name.
   auto l13 = []() { return 1; };
   constexpr const char *l13_output =
       __builtin_sycl_unique_stable_name(decltype(l13)); // #USN_l13
   kernel_single_task<class kernel12>(S<Tangerine, decltype(l13)>{});

   // kernel13 - expect no error
   // Test that passing a lambda to the unique stable name builtin within a macro
   // and then calling the macro within the kernel does not cause an error on the
   // kernel.
   kernel_single_task<class kernel13>(
       []() {
         MACRO(); // #USN_MACRO
       });
 }

 namespace NS {}

 void f() {
   // expected-error@+1{{unknown type name 'bad_var'}}
   __builtin_sycl_unique_stable_name(bad_var);
   // expected-error@+1{{use of undeclared identifier 'bad'}}
   __builtin_sycl_unique_stable_name(bad::type);
   // expected-error@+1{{no type named 'still_bad' in namespace 'NS'}}
   __builtin_sycl_unique_stable_name(NS::still_bad);

   // FIXME: warning about side-effects in an unevaluated context expected, but
   // none currently emitted.
   int i = 0;
   __builtin_sycl_unique_stable_name(decltype(i++));

   // Tests that use within a VLA does not diagnose as a side-effecting use in
   // an unevaluated context because the use within a VLA extent forces
   // evaluation.
   int j = 55;
   __builtin_sycl_unique_stable_name(int[++j]); // no warning expected
 }

 template <typename T>
 void f2() {
   // expected-error@+1{{no type named 'bad_val' in 'St'}}
   __builtin_sycl_unique_stable_name(typename T::bad_val);
   // expected-error@+1{{no type named 'bad_type' in 'St'}}
   __builtin_sycl_unique_stable_name(typename T::bad_type);
 }

 struct St {};

 void use() {
   // expected-note@+1{{in instantiation of}}
   f2<St>();
 }

 // A previous implementation resulted in this being an example of the
 // kernel-ordering and lexical lambda ordering issue.
 void out_of_order_use() {
   auto x = [](){};
   auto y = [](){};

   kernel_single_task<decltype(y)>(y);
   constexpr auto USN =__builtin_sycl_unique_stable_name(decltype(y));
   (void)USN;
   kernel_single_task<decltype(x)>(x);
 }
	// RUN: %clang_cc1 %s -std=c++17 -triple x86_64-pc-windows-msvc -fsycl-is-device -verify -fsyntax-only -Wno-unused
	// RUN: %clang_cc1 %s -std=c++17 -triple x86_64-linux-gnu -fsycl-is-device -verify -fsyntax-only -Wno-unused

	template <typename KernelName, typename KernelType>
	[[clang::sycl_kernel]] void kernel_single_task(KernelType kernelFunc) { // #kernelSingleTask
	kernelFunc();
	}

	// kernel1 - expect error
	// The current function is named with a lambda (i.e., takes a lambda as a
	// template parameter. Call the builtin on the current function then it is
	// passed to a kernel. Test that passing the given function to the unique
	// stable name builtin and then to the kernel throws an error because the
	// latter causes its name mangling to change.
	template <typename Func>
	void kernel1func(const Func &F1) {
	constexpr const char *F1_output = __builtin_sycl_unique_stable_name(Func); // #USN_F1
	kernel_single_task<class kernel1>(F1); // #kernel1_call
	}

	void callkernel1() {
	kernel1func([]() {}); // #kernel1func_call
	}

	// kernel2 - expect error
	// The current function is named with a lambda (i.e., takes a lambda as a
	// template parameter). Call the builtin on the given function,
	// then an empty lambda is passed to kernel.
	// Test that passing the given function to the unique stable name builtin and
	// then passing a different lambda to the kernel still throws an error because
	// the calling context is part of naming the kernel. Even though the given
	// function (F2) is not passed to the kernel, its mangling changes due to
	// kernel call with the unrelated lambda.
	template <typename Func>
	void kernel2func(const Func &F2) {
	constexpr const char *F2_output = __builtin_sycl_unique_stable_name(Func); // #USN_F2
	kernel_single_task<class kernel2>([]() {});
	}

	void callkernel2() {
	kernel2func([]() {}); // #kernel2func_call
	}

	template <template <typename> typename Outer, typename Inner>
	struct S {
	void operator()() const;
	};

	template <typename Ty>
	struct Tangerine {};

	template <typename Func>
	void kernel3_4func(const Func &F) {
	// Test that passing the same lambda to two kernels does not cause an error
	// because the kernel uses do not interfere with each other or invalidate
	// the stable name in any way.
	kernel_single_task<class kernel3>(F);
	kernel_single_task<class kernel4>(F);
	// Using the same functor twice should be fine
	}

	// kernel3 and kernel4 - expect no errors
	void callkernel3_4() {
	kernel3_4func([]() {});
	}

	template <typename T>
	static constexpr const char *output1 = __builtin_sycl_unique_stable_name(T);

	#define MACRO() \
	auto l14 = []() { return 1; }; \
	constexpr const char *l14_output = \
	__builtin_sycl_unique_stable_name(decltype(l14));

	int main() {

	// kernel5 - expect no error
	// Test that passing the lambda to the unique stable name builtin and then
	// using the lambda in a way that does not contribute to the kernel name
	// does not cause an error because the stable name is not invalidated in
	// this situation.
	auto l5 = []() {};
	constexpr const char *l5_output =
	__builtin_sycl_unique_stable_name(decltype(l5));
	kernel_single_task<class kernel5>(
	[=]() { l5(); }); // Used in the kernel, but not the kernel name itself

	// kernel6 - expect no error
	// Test that passing the lambda to the unique stable name builtin and then
	// using the same lambda in the naming of a kernel does not cause a diagnostic
	// on the kernel use due to the change in results to the stable name.
	auto l6 = []() { return 1; };
	constexpr const char *l6_output =
	__builtin_sycl_unique_stable_name(decltype(l6)); // #USN_l6
	kernel_single_task<class kernel6>(l6); // Used in the kernel name after builtin

	// kernel7 - expect no error
	// Same as kernel11 (below) except make the lambda part of naming the kernel.
	// Test that passing a lambda to the unique stable name builtin and then
	// passing a second lambda to the kernel does not throw an error because the
	// first lambda is included in the signature of the second lambda, but does
	// not change the mangling of the kernel.
	auto l7 = []() { return 1; };
	auto l8 = [](decltype(l7) *derp = nullptr) { return 2; };
	constexpr const char *l7_output =
	__builtin_sycl_unique_stable_name(decltype(l7)); // #USN_l7
	kernel_single_task<class kernel7>(l8);

	// kernel8 and kernel9 - expect no error
	// Tests that passing a lambda to the unique stable name builtin and passing
	// it to a kernel called with an if constexpr branch does not cause a
	// diagnostic on the kernel9 as it does not change the result to the stable
	// name. This is interesting even though the use of kernel9 happens in the
	// false branch of a constexpr if because both the true and the false branches
	// cause the instantiation of kernel_single_task.
	auto l9 = []() { return 1; };
	auto l10 = []() { return 2; };
	constexpr const char *l10_output =
	__builtin_sycl_unique_stable_name(decltype(l10)); // #USN_l10
	if constexpr (1) {
	kernel_single_task<class kernel8>(l9);
	} else {
	kernel_single_task<class kernel9>(l10);
	}

	// kernel11 - expect no error
	// Test that passing a lambda to the unique stable name builtin and then
	// passing a second lambda capturing the first one to the kernel does not
	// throw an error because the first lambda is not involved in naming the
	// kernel i.e., the mangling does not change.
	auto l11 = []() { return 1; };
	auto l12 = [l11]() { return 2; };
	constexpr const char *l11_output =
	__builtin_sycl_unique_stable_name(decltype(l11));
	kernel_single_task<class kernel11>(l12);

	// kernel12 - expect no error
	// Test that passing a lambda to the unique stable name builtin and then
	// passing it to the kernel as a template template parameter does not cause a
	// diagnostic on the kernel use due to template template parameter being
	// involved in the mangling of the kernel name.
	auto l13 = []() { return 1; };
	constexpr const char *l13_output =
	__builtin_sycl_unique_stable_name(decltype(l13)); // #USN_l13
	kernel_single_task<class kernel12>(S<Tangerine, decltype(l13)>{});

	// kernel13 - expect no error
	// Test that passing a lambda to the unique stable name builtin within a macro
	// and then calling the macro within the kernel does not cause an error on the
	// kernel.
	kernel_single_task<class kernel13>(
	[]() {
	MACRO(); // #USN_MACRO
	});
	}

	namespace NS {}

	void f() {
	// expected-error@+1{{unknown type name 'bad_var'}}
	__builtin_sycl_unique_stable_name(bad_var);
	// expected-error@+1{{use of undeclared identifier 'bad'}}
	__builtin_sycl_unique_stable_name(bad::type);
	// expected-error@+1{{no type named 'still_bad' in namespace 'NS'}}
	__builtin_sycl_unique_stable_name(NS::still_bad);

	// FIXME: warning about side-effects in an unevaluated context expected, but
	// none currently emitted.
	int i = 0;
	__builtin_sycl_unique_stable_name(decltype(i++));

	// Tests that use within a VLA does not diagnose as a side-effecting use in
	// an unevaluated context because the use within a VLA extent forces
	// evaluation.
	int j = 55;
	__builtin_sycl_unique_stable_name(int[++j]); // no warning expected
	}

	template <typename T>
	void f2() {
	// expected-error@+1{{no type named 'bad_val' in 'St'}}
	__builtin_sycl_unique_stable_name(typename T::bad_val);
	// expected-error@+1{{no type named 'bad_type' in 'St'}}
	__builtin_sycl_unique_stable_name(typename T::bad_type);
	}

	struct St {};

	void use() {
	// expected-note@+1{{in instantiation of}}
	f2<St>();
	}

	// A previous implementation resulted in this being an example of the
	// kernel-ordering and lexical lambda ordering issue.
	void out_of_order_use() {
	auto x = [](){};
	auto y = [](){};

	kernel_single_task<decltype(y)>(y);
	constexpr auto USN =__builtin_sycl_unique_stable_name(decltype(y));
	(void)USN;
	kernel_single_task<decltype(x)>(x);
	}