//===----------------------------------------------------------------------===// // // The LLVM Compiler Infrastructure // // This file is dual licensed under the MIT and the University of Illinois Open // Source Licenses. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // UNSUPPORTED: libcpp-has-no-threads, c++98, c++03 // REQUIRES: libatomic // RUN: %build -latomic // RUN: %run // // GCC currently fails because it needs -fabi-version=6 to fix mangling of // std::atomic when used with __attribute__((vector(X))). // XFAIL: gcc // // Verify that the content of atomic is properly aligned if the type is // lock-free. This can't be observed through the atomic API. It is // nonetheless required for correctness of the implementation: lock-free implies // that ISA instructions are used, and these instructions assume "suitable // alignment". Supported architectures all require natural alignment for // lock-freedom (e.g. load-linked / store-conditional, or cmpxchg). #include #include template struct atomic_test : public std::__atomic_base { atomic_test() { if (this->is_lock_free()) assert(alignof(this->__a_) >= sizeof(this->__a_) && "expected natural alignment for lock-free type"); } }; int main() { // structs and unions can't be defined in the template invocation. // Work around this with a typedef. #define CHECK_ALIGNMENT(T) \ do { \ typedef T type; \ atomic_test t; \ } while (0) CHECK_ALIGNMENT(bool); CHECK_ALIGNMENT(char); CHECK_ALIGNMENT(signed char); CHECK_ALIGNMENT(unsigned char); CHECK_ALIGNMENT(char16_t); CHECK_ALIGNMENT(char32_t); CHECK_ALIGNMENT(wchar_t); CHECK_ALIGNMENT(short); CHECK_ALIGNMENT(unsigned short); CHECK_ALIGNMENT(int); CHECK_ALIGNMENT(unsigned int); CHECK_ALIGNMENT(long); CHECK_ALIGNMENT(unsigned long); CHECK_ALIGNMENT(long long); CHECK_ALIGNMENT(unsigned long long); CHECK_ALIGNMENT(std::nullptr_t); CHECK_ALIGNMENT(void *); CHECK_ALIGNMENT(float); CHECK_ALIGNMENT(double); CHECK_ALIGNMENT(long double); CHECK_ALIGNMENT(int __attribute__((vector_size(1 * sizeof(int))))); CHECK_ALIGNMENT(int __attribute__((vector_size(2 * sizeof(int))))); CHECK_ALIGNMENT(int __attribute__((vector_size(4 * sizeof(int))))); CHECK_ALIGNMENT(int __attribute__((vector_size(16 * sizeof(int))))); CHECK_ALIGNMENT(int __attribute__((vector_size(32 * sizeof(int))))); CHECK_ALIGNMENT(float __attribute__((vector_size(1 * sizeof(float))))); CHECK_ALIGNMENT(float __attribute__((vector_size(2 * sizeof(float))))); CHECK_ALIGNMENT(float __attribute__((vector_size(4 * sizeof(float))))); CHECK_ALIGNMENT(float __attribute__((vector_size(16 * sizeof(float))))); CHECK_ALIGNMENT(float __attribute__((vector_size(32 * sizeof(float))))); CHECK_ALIGNMENT(double __attribute__((vector_size(1 * sizeof(double))))); CHECK_ALIGNMENT(double __attribute__((vector_size(2 * sizeof(double))))); CHECK_ALIGNMENT(double __attribute__((vector_size(4 * sizeof(double))))); CHECK_ALIGNMENT(double __attribute__((vector_size(16 * sizeof(double))))); CHECK_ALIGNMENT(double __attribute__((vector_size(32 * sizeof(double))))); CHECK_ALIGNMENT(struct Empty {}); CHECK_ALIGNMENT(struct OneInt { int i; }); CHECK_ALIGNMENT(struct IntArr2 { int i[2]; }); CHECK_ALIGNMENT(struct LLIArr2 { long long int i[2]; }); CHECK_ALIGNMENT(struct LLIArr4 { long long int i[4]; }); CHECK_ALIGNMENT(struct LLIArr8 { long long int i[8]; }); CHECK_ALIGNMENT(struct LLIArr16 { long long int i[16]; }); CHECK_ALIGNMENT(struct Padding { char c; /* padding */ long long int i; }); CHECK_ALIGNMENT(union IntFloat { int i; float f; }); }