test/SemaCUDA/add-inline-in-definition.cu - clang - Git at Google

 // RUN: %clang_cc1 -std=c++11 -fcuda-is-device -fsyntax-only -verify %s
 // RUN: %clang_cc1 -std=c++11 -fsyntax-only -verify %s

 #include "Inputs/cuda.h"

 #ifndef __CUDA_ARCH__
 // expected-no-diagnostics
 #endif

 // When compiling for device, foo()'s call to host_fn() is an error, because
 // foo() is known-emitted.
 //
 // The trickiness here comes from the fact that the FunctionDecl bar() sees
 // foo() does not have the "inline" keyword, so we might incorrectly think that
 // foo() is a priori known-emitted.  This would prevent us from marking foo()
 // as known-emitted when we see the call from bar() to foo(), which would
 // prevent us from emitting an error for foo()'s call to host_fn() when we
 // eventually see it.

 void host_fn() {}
 #ifdef __CUDA_ARCH__
   // expected-note@-2 {{declared here}}
 #endif

 __host__ __device__ void foo();
 __device__ void bar() {
   foo();
 #ifdef __CUDA_ARCH__
   // expected-note@-2 {{called by 'bar'}}
 #endif
 }
 inline __host__ __device__ void foo() {
   host_fn();
 #ifdef __CUDA_ARCH__
   // expected-error@-2 {{reference to __host__ function}}
 #endif
 }

 // This is similar to the above, except there's no error here.  This code used
 // to trip an assertion due to us noticing, when emitting the definition of
 // boom(), that T::operator S() was (incorrectly) considered a priori
 // known-emitted.
 struct S {};
 struct T {
   __device__ operator S() const;
 };
 __device__ inline T::operator S() const { return S(); }

 __device__ T t;
 __device__ void boom() {
   S s = t;
 }
	// RUN: %clang_cc1 -std=c++11 -fcuda-is-device -fsyntax-only -verify %s
	// RUN: %clang_cc1 -std=c++11 -fsyntax-only -verify %s

	#include "Inputs/cuda.h"

	#ifndef __CUDA_ARCH__
	// expected-no-diagnostics
	#endif

	// When compiling for device, foo()'s call to host_fn() is an error, because
	// foo() is known-emitted.
	//
	// The trickiness here comes from the fact that the FunctionDecl bar() sees
	// foo() does not have the "inline" keyword, so we might incorrectly think that
	// foo() is a priori known-emitted. This would prevent us from marking foo()
	// as known-emitted when we see the call from bar() to foo(), which would
	// prevent us from emitting an error for foo()'s call to host_fn() when we
	// eventually see it.

	void host_fn() {}
	#ifdef __CUDA_ARCH__
	// expected-note@-2 {{declared here}}
	#endif

	__host__ __device__ void foo();
	__device__ void bar() {
	foo();
	#ifdef __CUDA_ARCH__
	// expected-note@-2 {{called by 'bar'}}
	#endif
	}
	inline __host__ __device__ void foo() {
	host_fn();
	#ifdef __CUDA_ARCH__
	// expected-error@-2 {{reference to __host__ function}}
	#endif
	}

	// This is similar to the above, except there's no error here. This code used
	// to trip an assertion due to us noticing, when emitting the definition of
	// boom(), that T::operator S() was (incorrectly) considered a priori
	// known-emitted.
	struct S {};
	struct T {
	__device__ operator S() const;
	};
	__device__ inline T::operator S() const { return S(); }

	__device__ T t;
	__device__ void boom() {
	S s = t;
	}