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Neither the name of the copyright holder nor the names of its * contributors may be used to endorse or promote products derived from * this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * **************************************************************************************************/ /*! \file \brief Architecture-specific operators on memory added for SM80 */ #pragma once #include "cutlass/cutlass.h" #include "cutlass/complex.h" #include "cutlass/arch/memory.h" #include "cutlass/arch/memory_sm75.h" #include "cutlass/arch/cache_operation.h" #if defined(__CUDA_ARCH__) && (__CUDA_ARCH__ >= 800) #define CUDA_CP_ASYNC_ACTIVATED 1 #else #define CUDA_CP_ASYNC_ACTIVATED 0 #endif namespace cutlass { namespace arch { //////////////////////////////////////////////////////////////////////////////////////////////////// /// Initiates an asynchronous copy from global memory to shared memory. /// /// cp.async /// template < /// Size of the access in bytes int SizeInBytes, /// Cache operation CacheOperation::Kind cache_op = CacheOperation::Always> struct cp_async; /// Initiates an asynchronous copy from global memory to shared memory. Rather than predicate /// the entire transfer, zeros are written to SMEM if the guard predicate is false. /// /// cp.async /// template < /// Size of the access in bytes int SizeInBytes, /// Cache operation CacheOperation::Kind cache_op = CacheOperation::Always> struct cp_async_zfill; /// Initiates an asynchronous copy from global memory to shared memory. Rather than predicate /// the entire transfer, nans (0x7eff) are written to SMEM if the guard predicate is false. /// /// cp.async /// template < /// Size of the access in bytes int SizeInBytes, /// Cache operation CacheOperation::Kind cache_op = CacheOperation::Always> struct cp_async_nan; /// Either 0 or 1 are written to SMEM based on input element type /// Used for diagonal elements of triangular matrix of BLAS3 functions /// /// st.shared /// template < /// Type of Element typename Element, /// If the data is for a Hermitian matrix diagonal bool IsHermitianData = false> struct cp_async_diag; static const uint32_t OOB_NAN_F16 = 0x7eff; static const uint32_t OOB_NAN_F16x2 = ((OOB_NAN_F16 << 16) | OOB_NAN_F16); //////////////////////////////////////////////////////////////////////////////////////////////////// /// Partial specialization template < /// Size of the access in bytes int SizeInBytes> struct cp_async { /// Copy CUTLASS_DEVICE cp_async(void *smem_ptr, void const *global_ptr, bool pred_guard = true) { #if CUDA_CP_ASYNC_ACTIVATED // Make sure the size is supported. static_assert((SizeInBytes == 4 || SizeInBytes == 8 || SizeInBytes == 16), "Size is not supported"); unsigned smem_int_ptr = cutlass_get_smem_pointer(smem_ptr); asm volatile( "{\n" " .reg .pred p;\n" " setp.ne.b32 p, %0, 0;\n" #if CUTLASS_ENABLE_L2_PREFETCH " @p cp.async.ca.shared.global.L2::128B [%1], [%2], %3;\n" #else " @p cp.async.ca.shared.global [%1], [%2], %3;\n" #endif "}\n" ::"r"((int)pred_guard), "r"(smem_int_ptr), "l"(global_ptr), "n"(SizeInBytes)); #else using AccessType = Array; if (pred_guard) { *static_cast(smem_ptr) = *static_cast(global_ptr); } #endif } }; /// Partial specialization template < /// Size of the access in bytes int SizeInBytes> struct cp_async_zfill { /// Copy with zero fill CUTLASS_DEVICE cp_async_zfill(void *smem_ptr, void const *global_ptr, bool pred_guard) { #if CUDA_CP_ASYNC_ACTIVATED // Make sure the size is supported. static_assert((SizeInBytes == 4 || SizeInBytes == 8 || SizeInBytes == 16), "Size is not supported"); unsigned smem_int_ptr = cutlass_get_smem_pointer(smem_ptr); int src_in_bytes = (pred_guard ? SizeInBytes : 0); asm volatile( #if CUTLASS_ENABLE_L2_PREFETCH "cp.async.ca.shared.global.L2::128B [%0], [%1], %2, %3;\n" ::"r"(smem_int_ptr), #else "cp.async.ca.shared.global [%0], [%1], %2, %3;\n" ::"r"(smem_int_ptr), #endif "l"(global_ptr), "n"(SizeInBytes), "r"(src_in_bytes)); #else using AccessType = Array; if (pred_guard) { *static_cast(smem_ptr) = *static_cast(global_ptr); } else { AccessType zeros; zeros.clear(); *static_cast(smem_ptr) = zeros; } #endif } }; /// Partial specialization template <> struct cp_async_nan<16, CacheOperation::Always> { static int const kSizeInBytes = 16; /// Copy with nan fill CUTLASS_DEVICE cp_async_nan(void *smem_ptr, void const *global_ptr, bool pred_guard) { #if CUDA_CP_ASYNC_ACTIVATED static __constant__ uint4 OOB_NAN_F16x8 = {OOB_NAN_F16x2, OOB_NAN_F16x2, OOB_NAN_F16x2, OOB_NAN_F16x2}; unsigned smem_int_ptr = cutlass_get_smem_pointer(smem_ptr); asm volatile( "{\n" " .reg .pred p;\n" " setp.ne.b32 p, %0, 0;\n" #if CUTLASS_ENABLE_L2_PREFETCH " @p cp.async.ca.shared.global.L2::128B [%1], [%2], %3;\n" #else " @p cp.async.ca.shared.global [%1], [%2], %3;\n" #endif " @!p st.shared.v4.u32 [%1], {%4, %5, %6, %7};\n" "}\n" : : "r"((int)pred_guard), "r"(smem_int_ptr), "l"(global_ptr), "n"(kSizeInBytes), "r"(OOB_NAN_F16x8.x), "r"(OOB_NAN_F16x8.y), "r"(OOB_NAN_F16x8.z), "r"(OOB_NAN_F16x8.w)); #else CUTLASS_UNUSED(smem_ptr); CUTLASS_UNUSED(global_ptr); CUTLASS_UNUSED(pred_guard); CUTLASS_NOT_IMPLEMENTED(); #endif } }; /// Partial specialization to write one (1) template struct cp_async_diag { using Element = Element_; CUTLASS_DEVICE cp_async_diag(void *smem_ptr) { #if CUDA_CP_ASYNC_ACTIVATED /// Values for the diagonal elements of the triangular input matrix static __constant__ uint2 DIAG_DATA_DOUBLE_ONE = {0x3ff00000, 0x00000000}; static __constant__ uint1 DIAG_DATA_FLOAT_ONE = {0x3f800000}; static __constant__ uint1 DIAG_DATA_ZERO = {0x00000000}; unsigned smem_int_ptr = cutlass_get_smem_pointer(smem_ptr); if (platform::is_same>::value) { asm volatile("st.shared.v4.u32 [%0], {%1, %2, %3, %4};\n" : : "r"(smem_int_ptr), "r"(DIAG_DATA_DOUBLE_ONE.y), "r"(DIAG_DATA_DOUBLE_ONE.x), "r"(DIAG_DATA_ZERO.x), "r"(DIAG_DATA_ZERO.x)); } else if (platform::is_same>::value) { asm volatile("st.shared.v2.u32 [%0], {%1, %2};\n" : : "r"(smem_int_ptr), "r"(DIAG_DATA_FLOAT_ONE.x), "r"(DIAG_DATA_ZERO.x)); } else if (platform::is_same::value) { asm volatile("st.shared.v2.u32 [%0], {%1, %2};\n" : : "r"(smem_int_ptr), "r"(DIAG_DATA_DOUBLE_ONE.y),"r"(DIAG_DATA_DOUBLE_ONE.x)); } else if (platform::is_same::value) { asm volatile("st.shared.u32 [%0], %1;\n" : : "r"(smem_int_ptr), "r"(DIAG_DATA_FLOAT_ONE.x)); } else { CUTLASS_UNUSED(smem_int_ptr); CUTLASS_NOT_IMPLEMENTED(); } #else CUTLASS_UNUSED(smem_ptr); CUTLASS_NOT_IMPLEMENTED(); #endif } }; /// Partial specialization to write zero for the imaginary part of Hermitian data template struct cp_async_diag { using Element = Element_; CUTLASS_DEVICE cp_async_diag(void *smem_ptr) { #if CUDA_CP_ASYNC_ACTIVATED /// Values for the diagonal elements of the triangular input matrix static __constant__ uint1 DIAG_DATA_ZERO = {0x00000000}; unsigned smem_int_ptr = cutlass_get_smem_pointer(smem_ptr); if (platform::is_same>::value) { asm volatile("st.shared.v2.u32 [%0], {%1, %2};\n" : : "r"(smem_int_ptr), "r"(DIAG_DATA_ZERO.x), "r"(DIAG_DATA_ZERO.x)); } else if (platform::is_same>::value) { asm volatile("st.shared.u32 [%0], %1;\n" : : "r"(smem_int_ptr), "r"(DIAG_DATA_ZERO.x)); } else { CUTLASS_UNUSED(smem_int_ptr); CUTLASS_NOT_IMPLEMENTED(); } #else CUTLASS_UNUSED(smem_ptr); CUTLASS_NOT_IMPLEMENTED(); #endif } }; //////////////////////////////////////////////////////////////////////////////////////////////////// /// Partial specialization template < /// Size of the access in bytes int SizeInBytes> struct cp_async { /// Copy CUTLASS_DEVICE cp_async(void *smem_ptr, void const *global_ptr, bool pred_guard = true) { #if CUDA_CP_ASYNC_ACTIVATED static_assert(SizeInBytes == 16, "cp.async only supports CacheOperation::Global when access size is 16B."); unsigned smem_int_ptr = cutlass_get_smem_pointer(smem_ptr); cutlass::arch::synclog_emit_cp_async(__LINE__, smem_int_ptr, global_ptr, pred_guard, SizeInBytes); asm volatile( "{\n" " .reg .pred p;\n" " setp.ne.b32 p, %0, 0;\n" #if CUTLASS_ENABLE_L2_PREFETCH " @p cp.async.cg.shared.global.L2::128B [%1], [%2], %3;\n" #else " @p cp.async.cg.shared.global [%1], [%2], %3;\n" #endif "}\n" ::"r"((int)pred_guard), "r"(smem_int_ptr), "l"(global_ptr), "n"(SizeInBytes)); #else using AccessType = Array; if (pred_guard) { *static_cast(smem_ptr) = *static_cast(global_ptr); } #endif } }; /// Partial specialization template < /// Size of the access in bytes int SizeInBytes> struct cp_async_zfill { /// Copy with zero fill CUTLASS_DEVICE cp_async_zfill(void *smem_ptr, void const *global_ptr, bool pred_guard = true) { #if CUDA_CP_ASYNC_ACTIVATED static_assert(SizeInBytes == 16, "cp.async only supports CacheOperation::Global when access size is 16B."); unsigned smem_int_ptr = cutlass_get_smem_pointer(smem_ptr); int src_in_bytes = (pred_guard ? SizeInBytes : 0); cutlass::arch::synclog_emit_cp_async_zfill(__LINE__, smem_int_ptr, global_ptr, pred_guard, SizeInBytes); asm volatile( #if CUTLASS_ENABLE_L2_PREFETCH "cp.async.cg.shared.global.L2::128B [%0], [%1], %2, %3;\n" ::"r"(smem_int_ptr), #else "cp.async.cg.shared.global [%0], [%1], %2, %3;\n" ::"r"(smem_int_ptr), #endif "l"(global_ptr), "n"(SizeInBytes), "r"(src_in_bytes)); #else using AccessType = Array; if (pred_guard) { *static_cast(smem_ptr) = *static_cast(global_ptr); } else { AccessType zeros; zeros.clear(); *static_cast(smem_ptr) = zeros; } #endif } }; /// Partial specialization template <> struct cp_async_nan<16, CacheOperation::Global> { static int const kSizeInBytes = 16; /// Copy with nan fill CUTLASS_DEVICE cp_async_nan(void *smem_ptr, void const *global_ptr, bool pred_guard) { #if CUDA_CP_ASYNC_ACTIVATED static __constant__ uint4 OOB_NAN_F16x8 = {OOB_NAN_F16x2, OOB_NAN_F16x2, OOB_NAN_F16x2, OOB_NAN_F16x2}; unsigned smem_int_ptr = cutlass_get_smem_pointer(smem_ptr); cutlass::arch::synclog_emit_cp_async_nan(__LINE__, smem_int_ptr, global_ptr, pred_guard); asm volatile( "{\n" " .reg .pred p;\n" " setp.ne.b32 p, %0, 0;\n" #if CUTLASS_ENABLE_L2_PREFETCH " @p cp.async.cg.shared.global.L2::128B [%1], [%2], %3;\n" #else " @p cp.async.cg.shared.global [%1], [%2], %3;\n" #endif " @!p st.shared.v4.u32 [%1], {%4, %5, %6, %7};\n" "}\n" : : "r"((int)pred_guard), "r"(smem_int_ptr), "l"(global_ptr), "n"(kSizeInBytes), "r"(OOB_NAN_F16x8.x), "r"(OOB_NAN_F16x8.y), "r"(OOB_NAN_F16x8.z), "r"(OOB_NAN_F16x8.w)); #else CUTLASS_UNUSED(smem_ptr); CUTLASS_UNUSED(global_ptr); CUTLASS_UNUSED(pred_guard); CUTLASS_NOT_IMPLEMENTED(); #endif } }; //////////////////////////////////////////////////////////////////////////////////////////////////// /// Establishes an ordering w.r.t previously issued cp.async instructions. Does not block. CUTLASS_DEVICE void cp_async_fence() { #if CUDA_CP_ASYNC_ACTIVATED asm volatile("cp.async.commit_group;\n" ::); cutlass::arch::synclog_emit_cp_async_fence(__LINE__); #endif } //////////////////////////////////////////////////////////////////////////////////////////////////// /// Blocks until all but previous cp.async.commit_group operations have committed. template CUTLASS_DEVICE void cp_async_wait() { #if CUDA_CP_ASYNC_ACTIVATED asm volatile("cp.async.wait_group %0;\n" ::"n"(N)); cutlass::arch::synclog_emit_cp_async_wait(__LINE__, N); #endif } /// Blocks until all previous cp.async.commit_group operations have committed. template <> CUTLASS_DEVICE void cp_async_wait<0>() { #if CUDA_CP_ASYNC_ACTIVATED asm volatile("cp.async.wait_all;\n" ::); cutlass::arch::synclog_emit_cp_async_wait_all(__LINE__); #endif } ///////////////////////////////////////////////////////////////////////////////////////////////// } // namespace arch } // namespace cutlass /////////////////////////////////////////////////////////////////////////////////////////////////