// -*- C++ -*- //===----------------------------------------------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // SPDX-FileCopyrightText: Copyright (c) 2023 NVIDIA CORPORATION & AFFILIATES. // //===----------------------------------------------------------------------===// #ifndef _LIBCUDACXX___CUDA_BARRIER_H #define _LIBCUDACXX___CUDA_BARRIER_H #ifndef __cuda_std__ #error "<__cuda/barrier> should only be included in from " #endif // __cuda_std__ #if defined(__CUDA_MINIMUM_ARCH__) && __CUDA_MINIMUM_ARCH__ < 700 # error "CUDA synchronization primitives are only supported for sm_70 and up." #endif #if defined(_CCCL_IMPLICIT_SYSTEM_HEADER_GCC) # pragma GCC system_header #elif defined(_CCCL_IMPLICIT_SYSTEM_HEADER_CLANG) # pragma clang system_header #elif defined(_CCCL_IMPLICIT_SYSTEM_HEADER_MSVC) # pragma system_header #endif // no system header #include "../cstdlib" // _LIBCUDACXX_UNREACHABLE #include "../__type_traits/void_t.h" // _CUDA_VSTD::__void_t #if defined(_CCCL_CUDA_COMPILER) #include "../__cuda/ptx.h" // cuda::ptx::* #endif // _CCCL_CUDA_COMPILER #if defined(_LIBCUDACXX_COMPILER_NVRTC) #define _LIBCUDACXX_OFFSET_IS_ZERO(type, member) !(&(((type *)0)->member)) #else #define _LIBCUDACXX_OFFSET_IS_ZERO(type, member) !offsetof(type, member) #endif _LIBCUDACXX_BEGIN_NAMESPACE_CUDA // foward declaration required for memcpy_async, pipeline "sync" defined here template class pipeline; template<_CUDA_VSTD::size_t _Alignment> struct aligned_size_t { static constexpr _CUDA_VSTD::size_t align = _Alignment; _CUDA_VSTD::size_t value; _LIBCUDACXX_INLINE_VISIBILITY explicit aligned_size_t(size_t __s) : value(__s) { } _LIBCUDACXX_INLINE_VISIBILITY operator size_t() const { return value; } }; // Type only used for logging purpose enum async_contract_fulfillment { none, async }; // __completion_mechanism allows memcpy_async to report back what completion // mechanism it used. This is necessary to determine in which way to synchronize // the memcpy_async with a sync object (barrier or pipeline). // // In addition, we use this enum to create bit flags so that calling functions // can specify which completion mechanisms can be used (__sync is always // allowed). enum class __completion_mechanism { __sync = 0, __mbarrier_complete_tx = 1 << 0, // Use powers of two here to support the __async_group = 1 << 1, // bit flag use case __async_bulk_group = 1 << 2, }; template class barrier : public _CUDA_VSTD::__barrier_base<_CompletionF, _Sco> { public: barrier() = default; barrier(const barrier &) = delete; barrier & operator=(const barrier &) = delete; _LIBCUDACXX_INLINE_VISIBILITY constexpr barrier(_CUDA_VSTD::ptrdiff_t __expected, _CompletionF __completion = _CompletionF()) : _CUDA_VSTD::__barrier_base<_CompletionF, _Sco>(__expected, __completion) { } _LIBCUDACXX_INLINE_VISIBILITY friend void init(barrier * __b, _CUDA_VSTD::ptrdiff_t __expected) { _LIBCUDACXX_DEBUG_ASSERT(__expected >= 0, "Cannot initialize barrier with negative arrival count"); new (__b) barrier(__expected); } _LIBCUDACXX_INLINE_VISIBILITY friend void init(barrier * __b, _CUDA_VSTD::ptrdiff_t __expected, _CompletionF __completion) { _LIBCUDACXX_DEBUG_ASSERT(__expected >= 0, "Cannot initialize barrier with negative arrival count"); new (__b) barrier(__expected, __completion); } }; struct __block_scope_barrier_base {}; _LIBCUDACXX_END_NAMESPACE_CUDA _LIBCUDACXX_BEGIN_NAMESPACE_CUDA_DEVICE _LIBCUDACXX_DEVICE inline _CUDA_VSTD::uint64_t * barrier_native_handle(barrier & b); _LIBCUDACXX_END_NAMESPACE_CUDA_DEVICE _LIBCUDACXX_BEGIN_NAMESPACE_CUDA template<> class barrier : public __block_scope_barrier_base { using __barrier_base = _CUDA_VSTD::__barrier_base<_CUDA_VSTD::__empty_completion, (int)thread_scope_block>; __barrier_base __barrier; _LIBCUDACXX_DEVICE friend inline _CUDA_VSTD::uint64_t * device::_LIBCUDACXX_ABI_NAMESPACE::barrier_native_handle(barrier & b); template friend class _CUDA_VSTD::__barrier_poll_tester_phase; template friend class _CUDA_VSTD::__barrier_poll_tester_parity; public: using arrival_token = typename __barrier_base::arrival_token; barrier() = default; barrier(const barrier &) = delete; barrier & operator=(const barrier &) = delete; _LIBCUDACXX_INLINE_VISIBILITY barrier(_CUDA_VSTD::ptrdiff_t __expected, _CUDA_VSTD::__empty_completion __completion = _CUDA_VSTD::__empty_completion()) { static_assert(_LIBCUDACXX_OFFSET_IS_ZERO(barrier, __barrier), "fatal error: bad barrier layout"); init(this, __expected, __completion); } _LIBCUDACXX_INLINE_VISIBILITY ~barrier() { NV_DISPATCH_TARGET( NV_PROVIDES_SM_90, ( if (__isShared(&__barrier)) { asm volatile ("mbarrier.inval.shared.b64 [%0];" :: "r"(static_cast<_CUDA_VSTD::uint32_t>(__cvta_generic_to_shared(&__barrier))) : "memory"); } else if (__isClusterShared(&__barrier)) { __trap(); } ), NV_PROVIDES_SM_80, ( if (__isShared(&__barrier)) { asm volatile ("mbarrier.inval.shared.b64 [%0];" :: "r"(static_cast<_CUDA_VSTD::uint32_t>(__cvta_generic_to_shared(&__barrier))) : "memory"); } ) ) } _LIBCUDACXX_INLINE_VISIBILITY friend void init(barrier * __b, _CUDA_VSTD::ptrdiff_t __expected, _CUDA_VSTD::__empty_completion __completion = _CUDA_VSTD::__empty_completion()) { NV_DISPATCH_TARGET( NV_PROVIDES_SM_90, ( if (__isShared(&__b->__barrier)) { asm volatile ("mbarrier.init.shared.b64 [%0], %1;" :: "r"(static_cast<_CUDA_VSTD::uint32_t>(__cvta_generic_to_shared(&__b->__barrier))), "r"(static_cast<_CUDA_VSTD::uint32_t>(__expected)) : "memory"); } else if (__isClusterShared(&__b->__barrier)) { __trap(); } else { new (&__b->__barrier) __barrier_base(__expected); } ), NV_PROVIDES_SM_80, ( if (__isShared(&__b->__barrier)) { asm volatile ("mbarrier.init.shared.b64 [%0], %1;" :: "r"(static_cast<_CUDA_VSTD::uint32_t>(__cvta_generic_to_shared(&__b->__barrier))), "r"(static_cast<_CUDA_VSTD::uint32_t>(__expected)) : "memory"); } else { new (&__b->__barrier) __barrier_base(__expected); } ), NV_ANY_TARGET, ( new (&__b->__barrier) __barrier_base(__expected); ) ) } _LIBCUDACXX_NODISCARD_ATTRIBUTE _LIBCUDACXX_INLINE_VISIBILITY arrival_token arrive(_CUDA_VSTD::ptrdiff_t __update = 1) { _LIBCUDACXX_DEBUG_ASSERT(__update >= 0, "Arrival count update must be non-negative."); arrival_token __token = {}; NV_DISPATCH_TARGET( NV_PROVIDES_SM_90, ( if (!__isClusterShared(&__barrier)) { return __barrier.arrive(__update); } else if (!__isShared(&__barrier)) { __trap(); } // Cannot use cuda::device::barrier_native_handle here, as it is // only defined for block-scope barriers. This barrier may be a // non-block scoped barrier. auto __bh = reinterpret_cast<_CUDA_VSTD::uint64_t*>(&__barrier); __token = _CUDA_VPTX::mbarrier_arrive(__bh, __update); ), NV_PROVIDES_SM_80, ( if (!__isShared(&__barrier)) { return __barrier.arrive(__update); } auto __bh = reinterpret_cast<_CUDA_VSTD::uint64_t*>(&__barrier); // Need 2 instructions, can't finish barrier with arrive > 1 if (__update > 1) { _CUDA_VPTX::mbarrier_arrive_no_complete(__bh, __update - 1); } __token = _CUDA_VPTX::mbarrier_arrive( __bh); ), NV_IS_DEVICE, ( if (!__isShared(&__barrier)) { return __barrier.arrive(__update); } unsigned int __mask = __activemask(); unsigned int __activeA = __match_any_sync(__mask, __update); unsigned int __activeB = __match_any_sync(__mask, reinterpret_cast<_CUDA_VSTD::uintptr_t>(&__barrier)); unsigned int __active = __activeA & __activeB; int __inc = __popc(__active) * __update; unsigned __laneid; asm ("mov.u32 %0, %%laneid;" : "=r"(__laneid)); int __leader = __ffs(__active) - 1; // All threads in mask synchronize here, establishing cummulativity to the __leader: __syncwarp(__mask); if(__leader == static_cast(__laneid)) { __token = __barrier.arrive(__inc); } __token = __shfl_sync(__active, __token, __leader); ), NV_IS_HOST, ( __token = __barrier.arrive(__update); ) ) return __token; } private: _LIBCUDACXX_INLINE_VISIBILITY inline bool __test_wait_sm_80(arrival_token __token) const { int32_t __ready = 0; NV_DISPATCH_TARGET( NV_PROVIDES_SM_80, ( asm volatile ("{\n\t" ".reg .pred p;\n\t" "mbarrier.test_wait.shared.b64 p, [%1], %2;\n\t" "selp.b32 %0, 1, 0, p;\n\t" "}" : "=r"(__ready) : "r"(static_cast<_CUDA_VSTD::uint32_t>(__cvta_generic_to_shared(&__barrier))), "l"(__token) : "memory"); ) ) return __ready; } // Document de drop > uint32_t for __nanosec on public for APIs _LIBCUDACXX_INLINE_VISIBILITY bool __try_wait(arrival_token __token) const { NV_DISPATCH_TARGET( NV_PROVIDES_SM_90, ( int32_t __ready = 0; if (!__isClusterShared(&__barrier)) { return _CUDA_VSTD::__call_try_wait(__barrier, _CUDA_VSTD::move(__token)); } else if (!__isShared(&__barrier)) { __trap(); } asm volatile ("{\n\t" ".reg .pred p;\n\t" "mbarrier.try_wait.shared.b64 p, [%1], %2;\n\t" "selp.b32 %0, 1, 0, p;\n\t" "}" : "=r"(__ready) : "r"(static_cast<_CUDA_VSTD::uint32_t>(__cvta_generic_to_shared(&__barrier))), "l"(__token) : "memory"); return __ready; ), NV_PROVIDES_SM_80, ( if (!__isShared(&__barrier)) { return _CUDA_VSTD::__call_try_wait(__barrier, _CUDA_VSTD::move(__token)); } return __test_wait_sm_80(__token); ), NV_ANY_TARGET, ( return _CUDA_VSTD::__call_try_wait(__barrier, _CUDA_VSTD::move(__token)); ) ) } // Document de drop > uint32_t for __nanosec on public for APIs _LIBCUDACXX_INLINE_VISIBILITY bool __try_wait(arrival_token __token, _CUDA_VSTD::chrono::nanoseconds __nanosec) const { if (__nanosec.count() < 1) { return __try_wait(_CUDA_VSTD::move(__token)); } NV_DISPATCH_TARGET( NV_PROVIDES_SM_90, ( int32_t __ready = 0; if (!__isClusterShared(&__barrier)) { return _CUDA_VSTD::__libcpp_thread_poll_with_backoff( _CUDA_VSTD::__barrier_poll_tester_phase(this, _CUDA_VSTD::move(__token)), __nanosec); } else if (!__isShared(&__barrier)) { __trap(); } _CUDA_VSTD::chrono::high_resolution_clock::time_point const __start = _CUDA_VSTD::chrono::high_resolution_clock::now(); _CUDA_VSTD::chrono::nanoseconds __elapsed; do { const _CUDA_VSTD::uint32_t __wait_nsec = static_cast<_CUDA_VSTD::uint32_t>((__nanosec - __elapsed).count()); asm volatile ("{\n\t" ".reg .pred p;\n\t" "mbarrier.try_wait.shared.b64 p, [%1], %2, %3;\n\t" "selp.b32 %0, 1, 0, p;\n\t" "}" : "=r"(__ready) : "r"(static_cast<_CUDA_VSTD::uint32_t>(__cvta_generic_to_shared(&__barrier))), "l"(__token) "r"(__wait_nsec) : "memory"); __elapsed = _CUDA_VSTD::chrono::high_resolution_clock::now() - __start; } while (!__ready && (__nanosec > __elapsed)); return __ready; ), NV_PROVIDES_SM_80, ( bool __ready = 0; if (!__isShared(&__barrier)) { return _CUDA_VSTD::__libcpp_thread_poll_with_backoff( _CUDA_VSTD::__barrier_poll_tester_phase(this, _CUDA_VSTD::move(__token)), __nanosec); } _CUDA_VSTD::chrono::high_resolution_clock::time_point const __start = _CUDA_VSTD::chrono::high_resolution_clock::now(); do { __ready = __test_wait_sm_80(__token); } while (!__ready && __nanosec > (_CUDA_VSTD::chrono::high_resolution_clock::now() - __start)); return __ready; ), NV_ANY_TARGET, ( return _CUDA_VSTD::__libcpp_thread_poll_with_backoff( _CUDA_VSTD::__barrier_poll_tester_phase(this, _CUDA_VSTD::move(__token)), _CUDA_VSTD::chrono::nanoseconds(__nanosec)); ) ) } _LIBCUDACXX_INLINE_VISIBILITY inline bool __test_wait_parity_sm_80(bool __phase_parity) const { uint16_t __ready = 0; NV_DISPATCH_TARGET( NV_PROVIDES_SM_80, ( asm volatile ("{" ".reg .pred %%p;" "mbarrier.test_wait.parity.shared.b64 %%p, [%1], %2;" "selp.u16 %0, 1, 0, %%p;" "}" : "=h"(__ready) : "r"(static_cast(__cvta_generic_to_shared(&__barrier))), "r"(static_cast(__phase_parity)) : "memory"); ) ) return __ready; } _LIBCUDACXX_INLINE_VISIBILITY bool __try_wait_parity(bool __phase_parity) const { NV_DISPATCH_TARGET( NV_PROVIDES_SM_90, ( if (!__isClusterShared(&__barrier)) { return _CUDA_VSTD::__call_try_wait_parity(__barrier, __phase_parity); } else if (!__isShared(&__barrier)) { __trap(); } int32_t __ready = 0; asm volatile ("{\n\t" ".reg .pred p;\n\t" "mbarrier.try_wait.parity.shared.b64 p, [%1], %2;\n\t" "selp.b32 %0, 1, 0, p;\n\t" "}" : "=r"(__ready) : "r"(static_cast<_CUDA_VSTD::uint32_t>(__cvta_generic_to_shared(&__barrier))), "r"(static_cast<_CUDA_VSTD::uint32_t>(__phase_parity)) :); return __ready; ), NV_PROVIDES_SM_80, ( if (!__isShared(&__barrier)) { return _CUDA_VSTD::__call_try_wait_parity(__barrier, __phase_parity); } return __test_wait_parity_sm_80(__phase_parity); ), NV_ANY_TARGET, ( return _CUDA_VSTD::__call_try_wait_parity(__barrier, __phase_parity); ) ) } _LIBCUDACXX_INLINE_VISIBILITY bool __try_wait_parity(bool __phase_parity, _CUDA_VSTD::chrono::nanoseconds __nanosec) const { if (__nanosec.count() < 1) { return __try_wait_parity(__phase_parity); } NV_DISPATCH_TARGET( NV_PROVIDES_SM_90, ( int32_t __ready = 0; if (!__isClusterShared(&__barrier)) { return _CUDA_VSTD::__libcpp_thread_poll_with_backoff( _CUDA_VSTD::__barrier_poll_tester_parity(this, __phase_parity), __nanosec); } else if (!__isShared(&__barrier)) { __trap(); } _CUDA_VSTD::chrono::high_resolution_clock::time_point const __start = _CUDA_VSTD::chrono::high_resolution_clock::now(); _CUDA_VSTD::chrono::nanoseconds __elapsed; do { const _CUDA_VSTD::uint32_t __wait_nsec = static_cast<_CUDA_VSTD::uint32_t>((__nanosec - __elapsed).count()); asm volatile ("{\n\t" ".reg .pred p;\n\t" "mbarrier.try_wait.parity.shared.b64 p, [%1], %2, %3;\n\t" "selp.b32 %0, 1, 0, p;\n\t" "}" : "=r"(__ready) : "r"(static_cast<_CUDA_VSTD::uint32_t>(__cvta_generic_to_shared(&__barrier))), "r"(static_cast<_CUDA_VSTD::uint32_t>(__phase_parity)), "r"(__wait_nsec) : "memory"); __elapsed = _CUDA_VSTD::chrono::high_resolution_clock::now() - __start; } while (!__ready && (__nanosec > __elapsed)); return __ready; ), NV_PROVIDES_SM_80, ( bool __ready = 0; if (!__isShared(&__barrier)) { return _CUDA_VSTD::__libcpp_thread_poll_with_backoff( _CUDA_VSTD::__barrier_poll_tester_parity(this, __phase_parity), __nanosec); } _CUDA_VSTD::chrono::high_resolution_clock::time_point const __start = _CUDA_VSTD::chrono::high_resolution_clock::now(); do { __ready = __test_wait_parity_sm_80(__phase_parity); } while (!__ready && __nanosec > (_CUDA_VSTD::chrono::high_resolution_clock::now() - __start)); return __ready; ), NV_ANY_TARGET, ( return _CUDA_VSTD::__libcpp_thread_poll_with_backoff( _CUDA_VSTD::__barrier_poll_tester_parity(this, __phase_parity), __nanosec); ) ) } public: _LIBCUDACXX_INLINE_VISIBILITY void wait(arrival_token && __phase) const { _CUDA_VSTD::__libcpp_thread_poll_with_backoff(_CUDA_VSTD::__barrier_poll_tester_phase(this, _CUDA_VSTD::move(__phase))); } _LIBCUDACXX_INLINE_VISIBILITY void wait_parity(bool __phase_parity) const { _CUDA_VSTD::__libcpp_thread_poll_with_backoff(_CUDA_VSTD::__barrier_poll_tester_parity(this, __phase_parity)); } inline _LIBCUDACXX_INLINE_VISIBILITY void arrive_and_wait() { wait(arrive()); } _LIBCUDACXX_INLINE_VISIBILITY void arrive_and_drop() { NV_DISPATCH_TARGET( NV_PROVIDES_SM_90, ( if (!__isClusterShared(&__barrier)) { return __barrier.arrive_and_drop(); } else if (!__isShared(&__barrier)) { __trap(); } asm volatile ("mbarrier.arrive_drop.shared.b64 _, [%0];" :: "r"(static_cast<_CUDA_VSTD::uint32_t>(__cvta_generic_to_shared(&__barrier))) : "memory"); ), NV_PROVIDES_SM_80, ( // Fallback to slowpath on device if (!__isShared(&__barrier)) { __barrier.arrive_and_drop(); return; } asm volatile ("mbarrier.arrive_drop.shared.b64 _, [%0];" :: "r"(static_cast<_CUDA_VSTD::uint32_t>(__cvta_generic_to_shared(&__barrier))) : "memory"); ), NV_ANY_TARGET, ( // Fallback to slowpath on device __barrier.arrive_and_drop(); ) ) } _LIBCUDACXX_INLINE_VISIBILITY static constexpr ptrdiff_t max() noexcept { return (1 << 20) - 1; } template _LIBCUDACXX_NODISCARD_ATTRIBUTE _LIBCUDACXX_INLINE_VISIBILITY bool try_wait_for(arrival_token && __token, const _CUDA_VSTD::chrono::duration<_Rep, _Period>& __dur) { auto __nanosec = _CUDA_VSTD::chrono::duration_cast<_CUDA_VSTD::chrono::nanoseconds>(__dur); return __try_wait(_CUDA_VSTD::move(__token), __nanosec); } template _LIBCUDACXX_NODISCARD_ATTRIBUTE _LIBCUDACXX_INLINE_VISIBILITY bool try_wait_until(arrival_token && __token, const _CUDA_VSTD::chrono::time_point<_Clock, _Duration>& __time) { return try_wait_for(_CUDA_VSTD::move(__token), (__time - _Clock::now())); } template _LIBCUDACXX_NODISCARD_ATTRIBUTE _LIBCUDACXX_INLINE_VISIBILITY bool try_wait_parity_for(bool __phase_parity, const _CUDA_VSTD::chrono::duration<_Rep, _Period>& __dur) { auto __nanosec = _CUDA_VSTD::chrono::duration_cast<_CUDA_VSTD::chrono::nanoseconds>(__dur); return __try_wait_parity(__phase_parity, __nanosec); } template _LIBCUDACXX_NODISCARD_ATTRIBUTE _LIBCUDACXX_INLINE_VISIBILITY bool try_wait_parity_until(bool __phase_parity, const _CUDA_VSTD::chrono::time_point<_Clock, _Duration>& __time) { return try_wait_parity_for(__phase_parity, (__time - _Clock::now())); } }; _LIBCUDACXX_END_NAMESPACE_CUDA _LIBCUDACXX_BEGIN_NAMESPACE_CUDA_DEVICE _LIBCUDACXX_DEVICE inline _CUDA_VSTD::uint64_t * barrier_native_handle(barrier & b) { return reinterpret_cast<_CUDA_VSTD::uint64_t *>(&b.__barrier); } #if defined(_CCCL_CUDA_COMPILER) #if __cccl_ptx_isa >= 800 extern "C" _LIBCUDACXX_DEVICE void __cuda_ptx_barrier_arrive_tx_is_not_supported_before_SM_90__(); _LIBCUDACXX_NODISCARD_ATTRIBUTE _LIBCUDACXX_DEVICE inline barrier::arrival_token barrier_arrive_tx( barrier & __b, _CUDA_VSTD::ptrdiff_t __arrive_count_update, _CUDA_VSTD::ptrdiff_t __transaction_count_update) { _LIBCUDACXX_DEBUG_ASSERT(__isShared(barrier_native_handle(__b)), "Barrier must be located in local shared memory."); _LIBCUDACXX_DEBUG_ASSERT(1 <= __arrive_count_update, "Arrival count update must be at least one."); _LIBCUDACXX_DEBUG_ASSERT(__arrive_count_update <= (1 << 20) - 1, "Arrival count update cannot exceed 2^20 - 1."); _LIBCUDACXX_DEBUG_ASSERT(__transaction_count_update >= 0, "Transaction count update must be non-negative."); // https://docs.nvidia.com/cuda/parallel-thread-execution/index.html#contents-of-the-mbarrier-object _LIBCUDACXX_DEBUG_ASSERT(__transaction_count_update <= (1 << 20) - 1, "Transaction count update cannot exceed 2^20 - 1."); barrier::arrival_token __token = {}; NV_IF_ELSE_TARGET( // On architectures pre-sm90, arrive_tx is not supported. NV_PROVIDES_SM_90, ( // We do not check for the statespace of the barrier here. This is // on purpose. This allows debugging tools like memcheck/racecheck // to detect that we are passing a pointer with the wrong state // space to mbarrier.arrive. If we checked for the state space here, // and __trap() if wrong, then those tools would not be able to help // us in release builds. In debug builds, the error would be caught // by the asserts at the top of this function. auto __native_handle = barrier_native_handle(__b); auto __bh = __cvta_generic_to_shared(__native_handle); if (__arrive_count_update == 1) { __token = _CUDA_VPTX::mbarrier_arrive_expect_tx( _CUDA_VPTX::sem_release, _CUDA_VPTX::scope_cta, _CUDA_VPTX::space_shared, __native_handle, __transaction_count_update ); } else { asm ( "mbarrier.expect_tx.relaxed.cta.shared::cta.b64 [%0], %1;" : : "r"(static_cast<_CUDA_VSTD::uint32_t>(__bh)), "r"(static_cast<_CUDA_VSTD::uint32_t>(__transaction_count_update)) : "memory"); __token = _CUDA_VPTX::mbarrier_arrive( _CUDA_VPTX::sem_release, _CUDA_VPTX::scope_cta, _CUDA_VPTX::space_shared, __native_handle, __arrive_count_update ); } ),( __cuda_ptx_barrier_arrive_tx_is_not_supported_before_SM_90__(); ) ); return __token; } extern "C" _LIBCUDACXX_DEVICE void __cuda_ptx_barrier_expect_tx_is_not_supported_before_SM_90__(); _LIBCUDACXX_DEVICE inline void barrier_expect_tx( barrier & __b, _CUDA_VSTD::ptrdiff_t __transaction_count_update) { _LIBCUDACXX_DEBUG_ASSERT(__isShared(barrier_native_handle(__b)), "Barrier must be located in local shared memory."); _LIBCUDACXX_DEBUG_ASSERT(__transaction_count_update >= 0, "Transaction count update must be non-negative."); // https://docs.nvidia.com/cuda/parallel-thread-execution/index.html#contents-of-the-mbarrier-object _LIBCUDACXX_DEBUG_ASSERT(__transaction_count_update <= (1 << 20) - 1, "Transaction count update cannot exceed 2^20 - 1."); // We do not check for the statespace of the barrier here. This is // on purpose. This allows debugging tools like memcheck/racecheck // to detect that we are passing a pointer with the wrong state // space to mbarrier.arrive. If we checked for the state space here, // and __trap() if wrong, then those tools would not be able to help // us in release builds. In debug builds, the error would be caught // by the asserts at the top of this function. NV_IF_ELSE_TARGET( // On architectures pre-sm90, arrive_tx is not supported. NV_PROVIDES_SM_90, ( auto __bh = __cvta_generic_to_shared(barrier_native_handle(__b)); asm ( "mbarrier.expect_tx.relaxed.cta.shared::cta.b64 [%0], %1;" : : "r"(static_cast<_CUDA_VSTD::uint32_t>(__bh)), "r"(static_cast<_CUDA_VSTD::uint32_t>(__transaction_count_update)) : "memory"); ),( __cuda_ptx_barrier_expect_tx_is_not_supported_before_SM_90__(); )); } extern "C" _LIBCUDACXX_DEVICE void __cuda_ptx_memcpy_async_tx_is_not_supported_before_SM_90__(); template _LIBCUDACXX_DEVICE inline async_contract_fulfillment memcpy_async_tx( _Tp* __dest, const _Tp* __src, ::cuda::aligned_size_t<_Alignment> __size, ::cuda::barrier<::cuda::thread_scope_block> & __b) { // When compiling with NVCC and GCC 4.8, certain user defined types that _are_ trivially copyable are // incorrectly classified as not trivially copyable. Remove this assertion to allow for their usage with // memcpy_async when compiling with GCC 4.8. // FIXME: remove the #if once GCC 4.8 is no longer supported. #if !defined(_LIBCUDACXX_COMPILER_GCC) || _GNUC_VER > 408 static_assert(_CUDA_VSTD::is_trivially_copyable<_Tp>::value, "memcpy_async_tx requires a trivially copyable type"); #endif static_assert(16 <= _Alignment, "mempcy_async_tx expects arguments to be at least 16 byte aligned."); _LIBCUDACXX_DEBUG_ASSERT(__isShared(barrier_native_handle(__b)), "Barrier must be located in local shared memory."); _LIBCUDACXX_DEBUG_ASSERT(__isShared(__dest), "dest must point to shared memory."); _LIBCUDACXX_DEBUG_ASSERT(__isGlobal(__src), "src must point to global memory."); NV_IF_ELSE_TARGET(NV_PROVIDES_SM_90,( auto __bh = __cvta_generic_to_shared(barrier_native_handle(__b)); if (__isShared(__dest) && __isGlobal(__src)) { asm volatile( "cp.async.bulk.shared::cluster.global.mbarrier::complete_tx::bytes [%0], [%1], %2, [%3];\n" : : "r"(static_cast<_CUDA_VSTD::uint32_t>(__cvta_generic_to_shared(__dest))), "l"(static_cast<_CUDA_VSTD::uint64_t>(__cvta_generic_to_global(__src))), "r"(static_cast<_CUDA_VSTD::uint32_t>(__size)), "r"(static_cast<_CUDA_VSTD::uint32_t>(__bh)) : "memory"); } else { // memcpy_async_tx only supports copying from global to shared // or from shared to remote cluster dsmem. To copy to remote // dsmem, we need to arrive on a cluster-scoped barrier, which // is not yet implemented. So we trap in this case as well. _LIBCUDACXX_UNREACHABLE(); } ),( __cuda_ptx_memcpy_async_tx_is_not_supported_before_SM_90__(); )); return async_contract_fulfillment::async; } #endif // __cccl_ptx_isa >= 800 #endif // _CCCL_CUDA_COMPILER _LIBCUDACXX_END_NAMESPACE_CUDA_DEVICE #if defined(_CCCL_CUDA_COMPILER) _LIBCUDACXX_BEGIN_NAMESPACE_CUDA template<> class barrier : private barrier { using __base = barrier; public: using __base::__base; _LIBCUDACXX_INLINE_VISIBILITY friend void init(barrier * __b, _CUDA_VSTD::ptrdiff_t __expected, _CUDA_VSTD::__empty_completion __completion = _CUDA_VSTD::__empty_completion()) { init(static_cast<__base *>(__b), __expected, __completion); } using __base::arrive; using __base::wait; using __base::arrive_and_wait; using __base::arrive_and_drop; using __base::max; }; template _LIBCUDACXX_INLINE_VISIBILITY constexpr bool __unused(_Ty...) {return true;} template _LIBCUDACXX_INLINE_VISIBILITY constexpr bool __unused(_Ty&) {return true;} // __is_local_smem_barrier returns true if barrier is (1) block-scoped and (2) located in shared memory. template::value> _LIBCUDACXX_INLINE_VISIBILITY bool __is_local_smem_barrier(barrier<_Sco, _CompF> & __barrier) { NV_IF_ELSE_TARGET( NV_IS_DEVICE, ( return _Is_mbarrier && __isShared(&__barrier); ),( return false; ) ); } // __try_get_barrier_handle returns barrier handle of block-scoped barriers and a nullptr otherwise. template _LIBCUDACXX_INLINE_VISIBILITY inline _CUDA_VSTD::uint64_t * __try_get_barrier_handle(barrier<_Sco, _CompF> & __barrier) { return nullptr; } template<> _LIBCUDACXX_INLINE_VISIBILITY inline _CUDA_VSTD::uint64_t * __try_get_barrier_handle<::cuda::thread_scope_block, _CUDA_VSTD::__empty_completion>(barrier<::cuda::thread_scope_block> & __barrier) { NV_DISPATCH_TARGET( NV_IS_DEVICE, ( return ::cuda::device::barrier_native_handle(__barrier); ), NV_ANY_TARGET, ( return nullptr; ) ); } // This struct contains functions to defer the completion of a barrier phase // or pipeline stage until a specific memcpy_async operation *initiated by // this thread* has completed. // The user is still responsible for arriving and waiting on (or otherwise // synchronizing with) the barrier or pipeline barrier to see the results of // copies from other threads participating in the synchronization object. struct __memcpy_completion_impl { template _LIBCUDACXX_NODISCARD_ATTRIBUTE _LIBCUDACXX_INLINE_VISIBILITY static async_contract_fulfillment __defer( __completion_mechanism __cm, _Group const & __group, _CUDA_VSTD::size_t __size, barrier<::cuda::thread_scope_block> & __barrier) { // In principle, this is the overload for shared memory barriers. However, a // block-scope barrier may also be located in global memory. Therefore, we // check if the barrier is a non-smem barrier and handle that separately. if (! __is_local_smem_barrier(__barrier)) { return __defer_non_smem_barrier(__cm, __group, __size, __barrier); } switch (__cm) { case __completion_mechanism::__async_group: // Pre-SM80, the async_group mechanism is not available. NV_IF_TARGET(NV_PROVIDES_SM_80, ( // Non-Blocking: unbalance barrier by 1, barrier will be // rebalanced when all thread-local cp.async instructions // have completed writing to shared memory. _CUDA_VSTD::uint64_t * __bh = __try_get_barrier_handle(__barrier); asm volatile ("cp.async.mbarrier.arrive.shared.b64 [%0];" :: "r"(static_cast<_CUDA_VSTD::uint32_t>(__cvta_generic_to_shared(__bh))) : "memory"); )); return async_contract_fulfillment::async; case __completion_mechanism::__async_bulk_group: // This completion mechanism should not be used with a shared // memory barrier. Or at least, we do not currently envision // bulk group to be used with shared memory barriers. _LIBCUDACXX_UNREACHABLE(); case __completion_mechanism::__mbarrier_complete_tx: #if __cccl_ptx_isa >= 800 // Pre-sm90, the mbarrier_complete_tx completion mechanism is not available. NV_IF_TARGET(NV_PROVIDES_SM_90, ( // Only perform the expect_tx operation with the leader thread if (__group.thread_rank() == 0) { ::cuda::device::barrier_expect_tx(__barrier, __size); } )); #endif // __cccl_ptx_isa >= 800 return async_contract_fulfillment::async; case __completion_mechanism::__sync: // sync: In this case, we do not need to do anything. The user will have // to issue `bar.arrive_wait();` to see the effect of the transaction. return async_contract_fulfillment::none; default: // Get rid of "control reaches end of non-void function": _LIBCUDACXX_UNREACHABLE(); } } template _LIBCUDACXX_NODISCARD_ATTRIBUTE _LIBCUDACXX_INLINE_VISIBILITY static async_contract_fulfillment __defer( __completion_mechanism __cm, _Group const & __group, _CUDA_VSTD::size_t __size, barrier<_Sco, _CompF> & __barrier) { return __defer_non_smem_barrier(__cm, __group, __size, __barrier); } template _LIBCUDACXX_INLINE_VISIBILITY static async_contract_fulfillment __defer_non_smem_barrier( __completion_mechanism __cm, _Group const & __group, _CUDA_VSTD::size_t __size, barrier<_Sco, _CompF> & __barrier) { // Overload for non-smem barriers. switch (__cm) { case __completion_mechanism::__async_group: // Pre-SM80, the async_group mechanism is not available. NV_IF_TARGET(NV_PROVIDES_SM_80, ( // Blocking: wait for all thread-local cp.async instructions to have // completed writing to shared memory. asm volatile ("cp.async.wait_all;" ::: "memory"); )); return async_contract_fulfillment::async; case __completion_mechanism::__mbarrier_complete_tx: // Non-smem barriers do not have an mbarrier_complete_tx mechanism.. _LIBCUDACXX_UNREACHABLE(); case __completion_mechanism::__async_bulk_group: // This completion mechanism is currently not expected to be used with barriers. _LIBCUDACXX_UNREACHABLE(); case __completion_mechanism::__sync: // sync: In this case, we do not need to do anything. return async_contract_fulfillment::none; default: // Get rid of "control reaches end of non-void function": _LIBCUDACXX_UNREACHABLE(); } } template _LIBCUDACXX_INLINE_VISIBILITY static async_contract_fulfillment __defer(__completion_mechanism __cm, _Group const & __group, _CUDA_VSTD::size_t __size, pipeline<_Sco> & __pipeline) { // pipeline does not sync on memcpy_async, defeat pipeline purpose otherwise __unused(__pipeline); __unused(__size); __unused(__group); switch (__cm) { case __completion_mechanism::__async_group: return async_contract_fulfillment::async; case __completion_mechanism::__async_bulk_group: return async_contract_fulfillment::async; case __completion_mechanism::__mbarrier_complete_tx: return async_contract_fulfillment::async; case __completion_mechanism::__sync: return async_contract_fulfillment::none; default: // Get rid of "control reaches end of non-void function": _LIBCUDACXX_UNREACHABLE(); } } }; /*********************************************************************** * memcpy_async code: * * A call to cuda::memcpy_async(dest, src, size, barrier) can dispatch to any of * these PTX instructions: * * 1. normal synchronous copy (fallback) * 2. cp.async: shared <- global * 3. cp.async.bulk: shared <- global * 4. TODO: cp.async.bulk: global <- shared * 5. TODO: cp.async.bulk: cluster <- shared * * Which of these options is chosen, depends on: * * 1. The alignment of dest, src, and size; * 2. The direction of the copy * 3. The current compute capability * 4. The requested completion mechanism * * PTX has 3 asynchronous completion mechanisms: * * 1. Async group - local to a thread. Used by cp.async * 2. Bulk async group - local to a thread. Used by cp.async.bulk (shared -> global) * 3. mbarrier::complete_tx - shared memory barier. Used by cp.async.bulk (other directions) * * The code is organized as follows: * * 1. Asynchronous copy mechanisms that wrap the PTX instructions * * 2. Device memcpy_async implementation per copy direction (global to shared, * shared to global, etc). Dispatches to fastest mechanism based on requested * completion mechanism(s), pointer alignment, and architecture. * * 3. Host and device memcpy_async implementations. Host implementation is * basically a memcpy wrapper; device implementation dispatches based on the * direction of the copy. * * 4. __memcpy_async_barrier: * a) Sets the allowed completion mechanisms based on the barrier location * b) Calls the host or device memcpy_async implementation * c) If necessary, synchronizes with the barrier based on the returned * completion mechanism. * * 5. The public memcpy_async function overloads. Call into * __memcpy_async_barrier. * ***********************************************************************/ /*********************************************************************** * Asynchronous copy mechanisms: * * 1. cp.async.bulk: shared <- global * 2. TODO: cp.async.bulk: cluster <- shared * 3. TODO: cp.async.bulk: global <- shared * 4. cp.async: shared <- global * 5. normal synchronous copy (fallback) ***********************************************************************/ #if __cccl_ptx_isa >= 800 extern "C" _LIBCUDACXX_DEVICE void __cuda_ptx_cp_async_bulk_shared_global_is_not_supported_before_SM_90__(); template inline __device__ void __cp_async_bulk_shared_global(const _Group &__g, char * __dest, const char * __src, size_t __size, uint64_t *__bar_handle) { // https://docs.nvidia.com/cuda/parallel-thread-execution/index.html#data-movement-and-conversion-instructions-cp-async-bulk NV_IF_ELSE_TARGET(NV_PROVIDES_SM_90,( if (__g.thread_rank() == 0) { asm volatile( "cp.async.bulk.shared::cluster.global.mbarrier::complete_tx::bytes [%0], [%1], %2, [%3];\n" : : "r"(static_cast<_CUDA_VSTD::uint32_t>(__cvta_generic_to_shared(__dest))), "l"(static_cast<_CUDA_VSTD::uint64_t>(__cvta_generic_to_global(__src))), "r"(static_cast<_CUDA_VSTD::uint32_t>(__size)), "r"(static_cast<_CUDA_VSTD::uint32_t>(__cvta_generic_to_shared(__bar_handle))) : "memory"); } ),( __cuda_ptx_cp_async_bulk_shared_global_is_not_supported_before_SM_90__(); )); } #endif // __cccl_ptx_isa >= 800 extern "C" _LIBCUDACXX_DEVICE void __cuda_ptx_cp_async_shared_global_is_not_supported_before_SM_80__(); template inline __device__ void __cp_async_shared_global(char * __dest, const char * __src) { // https://docs.nvidia.com/cuda/parallel-thread-execution/index.html#data-movement-and-conversion-instructions-cp-async // If `if constexpr` is not available, this function gets instantiated even // if is not called. Do not static_assert in that case. #if _LIBCUDACXX_STD_VER >= 17 static_assert(_Copy_size == 4 || _Copy_size == 8 || _Copy_size == 16, "cp.async.shared.global requires a copy size of 4, 8, or 16."); #endif // _LIBCUDACXX_STD_VER >= 17 NV_IF_ELSE_TARGET(NV_PROVIDES_SM_80,( asm volatile( "cp.async.ca.shared.global [%0], [%1], %2, %2;" : : "r"(static_cast<_CUDA_VSTD::uint32_t>(__cvta_generic_to_shared(__dest))), "l"(static_cast<_CUDA_VSTD::uint64_t>(__cvta_generic_to_global(__src))), "n"(_Copy_size) : "memory"); ),( __cuda_ptx_cp_async_shared_global_is_not_supported_before_SM_80__(); )); } template <> inline __device__ void __cp_async_shared_global<16>(char * __dest, const char * __src) { // https://docs.nvidia.com/cuda/parallel-thread-execution/index.html#data-movement-and-conversion-instructions-cp-async // When copying 16 bytes, it is possible to skip L1 cache (.cg). NV_IF_ELSE_TARGET(NV_PROVIDES_SM_80,( asm volatile( "cp.async.cg.shared.global [%0], [%1], %2, %2;" : : "r"(static_cast<_CUDA_VSTD::uint32_t>(__cvta_generic_to_shared(__dest))), "l"(static_cast<_CUDA_VSTD::uint64_t>(__cvta_generic_to_global(__src))), "n"(16) : "memory"); ),( __cuda_ptx_cp_async_shared_global_is_not_supported_before_SM_80__(); )); } template inline __device__ void __cp_async_shared_global_mechanism(_Group __g, char * __dest, const char * __src, _CUDA_VSTD::size_t __size) { // If `if constexpr` is not available, this function gets instantiated even // if is not called. Do not static_assert in that case. #if _LIBCUDACXX_STD_VER >= 17 static_assert(4 <= _Alignment, "cp.async requires at least 4-byte alignment"); #endif // _LIBCUDACXX_STD_VER >= 17 // Maximal copy size is 16. constexpr int __copy_size = (_Alignment > 16) ? 16 : _Alignment; // We use an int offset here, because we are copying to shared memory, // which is easily addressable using int. const int __group_size = __g.size(); const int __group_rank = __g.thread_rank(); const int __stride = __group_size * __copy_size; for (int __offset = __group_rank * __copy_size; __offset < static_cast(__size); __offset += __stride) { __cp_async_shared_global<__copy_size>(__dest + __offset, __src + __offset); } } template struct __copy_chunk { _ALIGNAS(_Copy_size) char data[_Copy_size]; }; template inline __host__ __device__ void __cp_async_fallback_mechanism(_Group __g, char * __dest, const char * __src, _CUDA_VSTD::size_t __size) { // Maximal copy size is 16 bytes constexpr _CUDA_VSTD::size_t __copy_size = (_Alignment > 16) ? 16 : _Alignment; using __chunk_t = __copy_chunk<__copy_size>; // "Group"-strided loop over memory const size_t __stride = __g.size() * __copy_size; // An unroll factor of 64 ought to be enough for anybody. This unroll pragma // is mainly intended to place an upper bound on loop unrolling. The number // is more than high enough for the intended use case: an unroll factor of // 64 allows moving 4 * 64 * 256 = 64kb in one unrolled loop with 256 // threads (copying ints). On the other hand, in the unfortunate case that // we have to move 1024 bytes / thread with char width, then we prevent // fully unrolling the loop to 1024 copy instructions. This prevents the // compile times from increasing unreasonably, and also has neglibible // impact on runtime performance. _LIBCUDACXX_PRAGMA_UNROLL(64) for (_CUDA_VSTD::size_t __offset = __g.thread_rank() * __copy_size; __offset < __size; __offset += __stride) { __chunk_t tmp = *reinterpret_cast(__src + __offset); *reinterpret_cast<__chunk_t *>(__dest + __offset) = tmp; } } /*********************************************************************** * cuda::memcpy_async dispatch helper functions * * - __get_size_align struct to determine the alignment from a size type. ***********************************************************************/ // The __get_size_align struct provides a way to query the guaranteed // "alignment" of a provided size. In this case, an n-byte aligned size means // that the size is a multiple of n. // // Use as follows: // static_assert(__get_size_align::align == 1) // static_assert(__get_size_align>::align == n) // Default impl: always returns 1. template struct __get_size_align { static constexpr int align = 1; }; // aligned_size_t overload: return n. template struct __get_size_align> { static constexpr int align = T::align; }; /*********************************************************************** * cuda::memcpy_async dispatch * * The dispatch mechanism takes all the arguments and dispatches to the * fastest asynchronous copy mechanism available. * * It returns a __completion_mechanism that indicates which completion mechanism * was used by the copy mechanism. This value can be used by the sync object to * further synchronize if necessary. * ***********************************************************************/ template<_CUDA_VSTD::size_t _Align, typename _Group> _LIBCUDACXX_NODISCARD_ATTRIBUTE _LIBCUDACXX_DEVICE inline __completion_mechanism __dispatch_memcpy_async_any_to_any(_Group const & __group, char * __dest_char, char const * __src_char, _CUDA_VSTD::size_t __size, uint32_t __allowed_completions, uint64_t* __bar_handle) { __cp_async_fallback_mechanism<_Align>(__group, __dest_char, __src_char, __size); return __completion_mechanism::__sync; } template<_CUDA_VSTD::size_t _Align, typename _Group> _LIBCUDACXX_NODISCARD_ATTRIBUTE _LIBCUDACXX_DEVICE inline __completion_mechanism __dispatch_memcpy_async_global_to_shared(_Group const & __group, char * __dest_char, char const * __src_char, _CUDA_VSTD::size_t __size, uint32_t __allowed_completions, uint64_t* __bar_handle) { #if __cccl_ptx_isa >= 800 NV_IF_TARGET(NV_PROVIDES_SM_90, ( const bool __can_use_complete_tx = __allowed_completions & uint32_t(__completion_mechanism::__mbarrier_complete_tx); _LIBCUDACXX_DEBUG_ASSERT(__can_use_complete_tx == (nullptr != __bar_handle), "Pass non-null bar_handle if and only if can_use_complete_tx."); if _LIBCUDACXX_CONSTEXPR_AFTER_CXX14 (_Align >= 16) { if (__can_use_complete_tx && __isShared(__bar_handle)) { __cp_async_bulk_shared_global(__group, __dest_char, __src_char, __size, __bar_handle); return __completion_mechanism::__mbarrier_complete_tx; } } // Fallthrough to SM 80.. )); #endif // __cccl_ptx_isa >= 800 NV_IF_TARGET(NV_PROVIDES_SM_80, ( if _LIBCUDACXX_CONSTEXPR_AFTER_CXX14 (_Align >= 4) { const bool __can_use_async_group = __allowed_completions & uint32_t(__completion_mechanism::__async_group); if (__can_use_async_group) { __cp_async_shared_global_mechanism<_Align>(__group, __dest_char, __src_char, __size); return __completion_mechanism::__async_group; } } // Fallthrough.. )); __cp_async_fallback_mechanism<_Align>(__group, __dest_char, __src_char, __size); return __completion_mechanism::__sync; } // __dispatch_memcpy_async is the internal entry point for dispatching to the correct memcpy_async implementation. template<_CUDA_VSTD::size_t _Align, typename _Group> _LIBCUDACXX_NODISCARD_ATTRIBUTE _LIBCUDACXX_INLINE_VISIBILITY __completion_mechanism __dispatch_memcpy_async(_Group const & __group, char * __dest_char, char const * __src_char, size_t __size, _CUDA_VSTD::uint32_t __allowed_completions, uint64_t* __bar_handle) { NV_IF_ELSE_TARGET(NV_IS_DEVICE, ( // Dispatch based on direction of the copy: global to shared, shared to // global, etc. // CUDA compilers <= 12.2 may not propagate assumptions about the state space // of pointers correctly. Therefore, we // 1) put the code for each copy direction in a separate function, and // 2) make sure none of the code paths can reach each other by "falling through". // // See nvbug 4074679 and also PR #478. if (__isGlobal(__src_char) && __isShared(__dest_char)) { return __dispatch_memcpy_async_global_to_shared<_Align>(__group, __dest_char, __src_char, __size, __allowed_completions, __bar_handle); } else { return __dispatch_memcpy_async_any_to_any<_Align>(__group, __dest_char, __src_char, __size, __allowed_completions, __bar_handle); } ), ( // Host code path: if (__group.thread_rank() == 0) { memcpy(__dest_char, __src_char, __size); } return __completion_mechanism::__sync; )); } template<_CUDA_VSTD::size_t _Align, typename _Group> _LIBCUDACXX_NODISCARD_ATTRIBUTE _LIBCUDACXX_INLINE_VISIBILITY __completion_mechanism __dispatch_memcpy_async(_Group const & __group, char * __dest_char, char const * __src_char, _CUDA_VSTD::size_t __size, _CUDA_VSTD::uint32_t __allowed_completions) { _LIBCUDACXX_DEBUG_ASSERT(! (__allowed_completions & uint32_t(__completion_mechanism::__mbarrier_complete_tx)), "Cannot allow mbarrier_complete_tx completion mechanism when not passing a barrier. "); return __dispatch_memcpy_async<_Align>(__group, __dest_char, __src_char, __size, __allowed_completions, nullptr); } //////////////////////////////////////////////////////////////////////////////// struct __single_thread_group { _LIBCUDACXX_INLINE_VISIBILITY void sync() const {} _LIBCUDACXX_INLINE_VISIBILITY constexpr _CUDA_VSTD::size_t size() const { return 1; }; _LIBCUDACXX_INLINE_VISIBILITY constexpr _CUDA_VSTD::size_t thread_rank() const { return 0; }; }; template _LIBCUDACXX_INLINE_VISIBILITY async_contract_fulfillment __memcpy_async_barrier(_Group const & __group, _Tp * __destination, _Tp const * __source, _Size __size, barrier<_Sco, _CompF> & __barrier) { static_assert(_CUDA_VSTD::is_trivially_copyable<_Tp>::value, "memcpy_async requires a trivially copyable type"); // 1. Determine which completion mechanisms can be used with the current // barrier. A local shared memory barrier, i.e., block-scope barrier in local // shared memory, supports the mbarrier_complete_tx mechanism in addition to // the async group mechanism. _CUDA_VSTD::uint32_t __allowed_completions = __is_local_smem_barrier(__barrier) ? ( _CUDA_VSTD::uint32_t(__completion_mechanism::__async_group) | _CUDA_VSTD::uint32_t(__completion_mechanism::__mbarrier_complete_tx)) : _CUDA_VSTD::uint32_t(__completion_mechanism::__async_group); // Alignment: Use the maximum of the alignment of _Tp and that of a possible cuda::aligned_size_t. constexpr _CUDA_VSTD::size_t __size_align = __get_size_align<_Size>::align; constexpr _CUDA_VSTD::size_t __align = (alignof(_Tp) < __size_align) ? __size_align : alignof(_Tp); // Cast to char pointers. We don't need the type for alignment anymore and // erasing the types reduces the number of instantiations of down-stream // functions. char * __dest_char = reinterpret_cast(__destination); char const * __src_char = reinterpret_cast(__source); // 2. Issue actual copy instructions. auto __bh = __try_get_barrier_handle(__barrier); auto __cm = __dispatch_memcpy_async<__align>(__group, __dest_char, __src_char, __size, __allowed_completions, __bh); // 3. Synchronize barrier with copy instructions. return __memcpy_completion_impl::__defer(__cm, __group, __size, __barrier); } template _LIBCUDACXX_INLINE_VISIBILITY async_contract_fulfillment memcpy_async(_Group const & __group, _Tp * __destination, _Tp const * __source, aligned_size_t<_Alignment> __size, barrier<_Sco, _CompF> & __barrier) { return __memcpy_async_barrier(__group, __destination, __source, __size, __barrier); } template _LIBCUDACXX_INLINE_VISIBILITY async_contract_fulfillment memcpy_async(_Tp * __destination, _Tp const * __source, _Size __size, barrier<_Sco, _CompF> & __barrier) { return __memcpy_async_barrier(__single_thread_group{}, __destination, __source, __size, __barrier); } template _LIBCUDACXX_INLINE_VISIBILITY async_contract_fulfillment memcpy_async(_Group const & __group, _Tp * __destination, _Tp const * __source, _CUDA_VSTD::size_t __size, barrier<_Sco, _CompF> & __barrier) { return __memcpy_async_barrier(__group, __destination, __source, __size, __barrier); } template _LIBCUDACXX_INLINE_VISIBILITY async_contract_fulfillment memcpy_async(_Group const & __group, void * __destination, void const * __source, _CUDA_VSTD::size_t __size, barrier<_Sco, _CompF> & __barrier) { return __memcpy_async_barrier(__group, reinterpret_cast(__destination), reinterpret_cast(__source), __size, __barrier); } template _LIBCUDACXX_INLINE_VISIBILITY async_contract_fulfillment memcpy_async(_Group const & __group, void * __destination, void const * __source, aligned_size_t<_Alignment> __size, barrier<_Sco, _CompF> & __barrier) { return __memcpy_async_barrier(__group, reinterpret_cast(__destination), reinterpret_cast(__source), __size, __barrier); } template _LIBCUDACXX_INLINE_VISIBILITY async_contract_fulfillment memcpy_async(void * __destination, void const * __source, _Size __size, barrier<_Sco, _CompF> & __barrier) { return __memcpy_async_barrier(__single_thread_group{}, reinterpret_cast(__destination), reinterpret_cast(__source), __size, __barrier); } _LIBCUDACXX_END_NAMESPACE_CUDA #endif // _CCCL_CUDA_COMPILER #endif // _LIBCUDACXX___CUDA_BARRIER_H