// Copyright (c) Microsoft Corporation. // Licensed under the MIT License. #pragma once #include #include "common.h" namespace tl { TL_DEVICE void tma_load(const CUtensorMap &descriptor, uint64_t &smem_mbar, void const *const smem_ptr, int32_t const &crd0) { uint64_t gmem_int_desc = reinterpret_cast(&descriptor); uint32_t smem_int_mbar = smem_ptr_to_uint(&smem_mbar); uint32_t smem_int_ptr = smem_ptr_to_uint(smem_ptr); asm volatile("cp.async.bulk.tensor.1d.shared::cluster.global.mbarrier::" "complete_tx::bytes" " [%0], [%1, {%3}], [%2];" : : "r"(smem_int_ptr), "l"(gmem_int_desc), "r"(smem_int_mbar), "r"(crd0) : "memory"); } TL_DEVICE void tma_load(const CUtensorMap &descriptor, uint64_t &smem_mbar, void const *const smem_ptr, int32_t const &crd0, int32_t const &crd1) { uint64_t gmem_int_desc = reinterpret_cast(&descriptor); uint32_t smem_int_mbar = smem_ptr_to_uint(&smem_mbar); uint32_t smem_int_ptr = smem_ptr_to_uint(smem_ptr); asm volatile("cp.async.bulk.tensor.2d.shared::cluster.global.mbarrier::" "complete_tx::bytes" " [%0], [%1, {%3, %4}], [%2];" : : "r"(smem_int_ptr), "l"(gmem_int_desc), "r"(smem_int_mbar), "r"(crd0), "r"(crd1) : "memory"); } TL_DEVICE void tma_load(const CUtensorMap &descriptor, uint64_t &smem_mbar, void const *const smem_ptr, int32_t const &crd0, int32_t const &crd1, int32_t const &crd2) { uint64_t gmem_int_desc = reinterpret_cast(&descriptor); uint32_t smem_int_mbar = smem_ptr_to_uint(&smem_mbar); uint32_t smem_int_ptr = smem_ptr_to_uint(smem_ptr); asm volatile("cp.async.bulk.tensor.3d.shared::cluster.global.mbarrier::" "complete_tx::bytes" " [%0], [%1, {%3, %4, %5}], [%2];" : : "r"(smem_int_ptr), "l"(gmem_int_desc), "r"(smem_int_mbar), "r"(crd0), "r"(crd1), "r"(crd2) : "memory"); } TL_DEVICE void tma_load(const CUtensorMap &descriptor, uint64_t &smem_mbar, void const *const smem_ptr, int32_t const &crd0, int32_t const &crd1, int32_t const &crd2, int32_t const &crd3) { uint64_t gmem_int_desc = reinterpret_cast(&descriptor); uint32_t smem_int_mbar = smem_ptr_to_uint(&smem_mbar); uint32_t smem_int_ptr = smem_ptr_to_uint(smem_ptr); asm volatile("cp.async.bulk.tensor.4d.shared::cluster.global.mbarrier::" "complete_tx::bytes" " [%0], [%1, {%3, %4, %5, %6}], [%2];" : : "r"(smem_int_ptr), "l"(gmem_int_desc), "r"(smem_int_mbar), "r"(crd0), "r"(crd1), "r"(crd2), "r"(crd3) : "memory"); } TL_DEVICE void tma_load(const CUtensorMap &descriptor, uint64_t &smem_mbar, void const *const smem_ptr, int32_t const &crd0, int32_t const &crd1, int32_t const &crd2, int32_t const &crd3, int32_t const &crd4) { uint64_t gmem_int_desc = reinterpret_cast(&descriptor); uint32_t smem_int_mbar = smem_ptr_to_uint(&smem_mbar); uint32_t smem_int_ptr = smem_ptr_to_uint(smem_ptr); asm volatile("cp.async.bulk.tensor.5d.shared::cluster.global.mbarrier::" "complete_tx::bytes" " [%0], [%1, {%3, %4, %5, %6, %7}], [%2];" : : "r"(smem_int_ptr), "l"(gmem_int_desc), "r"(smem_int_mbar), "r"(crd0), "r"(crd1), "r"(crd2), "r"(crd3), "r"(crd4) : "memory"); } TL_DEVICE void tma_load_im2col(const CUtensorMap &descriptor, uint64_t &smem_mbar, void const *const smem_ptr, int32_t const &coord_c, int32_t const &coord_w, int32_t const &coord_h, int32_t const &coord_n, uint16_t const &offset_w, uint16_t const &offset_h) { uint64_t gmem_int_desc = reinterpret_cast(&descriptor); uint32_t smem_int_mbar = smem_ptr_to_uint(&smem_mbar); uint32_t smem_int_ptr = smem_ptr_to_uint(smem_ptr); asm volatile("cp.async.bulk.tensor.4d.shared::cluster.global.im2col.mbarrier:" ":complete_tx::bytes" " [%0], [%1, {%3, %4, %5, %6}], [%2], {%7, %8};" : : "r"(smem_int_ptr), "l"(gmem_int_desc), "r"(smem_int_mbar), "r"(coord_c), "r"(coord_w), "r"(coord_h), "r"(coord_n), "h"(offset_w), "h"(offset_h) : "memory"); } TL_DEVICE void tma_store(const CUtensorMap &descriptor, void const *const smem_ptr, int32_t const &crd0) { uint64_t gmem_int_desc = reinterpret_cast(&descriptor); uint32_t smem_int_ptr = smem_ptr_to_uint(smem_ptr); asm volatile( "cp.async.bulk.tensor.1d.global.shared::cta.bulk_group [%0, {%2}], [%1];" : : "l"(gmem_int_desc), "r"(smem_int_ptr), "r"(crd0) : "memory"); } TL_DEVICE void tma_store(const CUtensorMap &descriptor, void const *const smem_ptr, int32_t const &crd0, int32_t const &crd1) { uint64_t gmem_int_desc = reinterpret_cast(&descriptor); uint32_t smem_int_ptr = smem_ptr_to_uint(smem_ptr); asm volatile("cp.async.bulk.tensor.2d.global.shared::cta.bulk_group [%0, " "{%2, %3}], [%1];" : : "l"(gmem_int_desc), "r"(smem_int_ptr), "r"(crd0), "r"(crd1) : "memory"); } TL_DEVICE void tma_store(const CUtensorMap &descriptor, void const *const smem_ptr, int32_t const &crd0, int32_t const &crd1, int32_t const &crd2) { uint64_t gmem_int_desc = reinterpret_cast(&descriptor); uint32_t smem_int_ptr = smem_ptr_to_uint(smem_ptr); asm volatile("cp.async.bulk.tensor.3d.global.shared::cta.bulk_group [%0, " "{%2, %3, %4}], [%1];" : : "l"(gmem_int_desc), "r"(smem_int_ptr), "r"(crd0), "r"(crd1), "r"(crd2) : "memory"); } TL_DEVICE void tma_store(const CUtensorMap &descriptor, void const *const smem_ptr, int32_t const &crd0, int32_t const &crd1, int32_t const &crd2, int32_t const &crd3) { uint64_t gmem_int_desc = reinterpret_cast(&descriptor); uint32_t smem_int_ptr = smem_ptr_to_uint(smem_ptr); asm volatile("cp.async.bulk.tensor.4d.global.shared::cta.bulk_group [%0, " "{%2, %3, %4, %5}], [%1];" : : "l"(gmem_int_desc), "r"(smem_int_ptr), "r"(crd0), "r"(crd1), "r"(crd2), "r"(crd3) : "memory"); } TL_DEVICE void tma_store(const CUtensorMap &descriptor, void const *const smem_ptr, int32_t const &crd0, int32_t const &crd1, int32_t const &crd2, int32_t const &crd3, int32_t const &crd4) { uint64_t gmem_int_desc = reinterpret_cast(&descriptor); uint32_t smem_int_ptr = smem_ptr_to_uint(smem_ptr); asm volatile("cp.async.bulk.tensor.5d.global.shared::cta.bulk_group [%0, " "{%2, %3, %4, %5, %6}], [%1];" : : "l"(gmem_int_desc), "r"(smem_int_ptr), "r"(crd0), "r"(crd1), "r"(crd2), "r"(crd3), "r"(crd4) : "memory"); } TL_DEVICE void prefetch_tma_descriptor(const CUtensorMap &descriptor) { uint64_t gmem_int_desc = reinterpret_cast(&descriptor); asm volatile("prefetch.tensormap [%0];" : : "l"(gmem_int_desc) : "memory"); } TL_DEVICE void mbarrier_init(uint64_t &smem_barrier, uint32_t arrive_count) { uint32_t smem_int_ptr = smem_ptr_to_uint(&smem_barrier); asm volatile("mbarrier.init.shared.b64 [%1], %0;" : : "r"(arrive_count), "r"(smem_int_ptr)); } TL_DEVICE void mbarrier_wait(uint64_t &smem_barrier, int phase_bit) { uint32_t smem_int_ptr = smem_ptr_to_uint(&smem_barrier); asm volatile("{\n" ".reg .pred P1;\n" "LAB_WAIT:\n" "mbarrier.try_wait.parity.shared.b64 P1, [%0], %1;\n" "@!P1 bra.uni LAB_WAIT;\n" "}\n" ::"r"(smem_int_ptr), "r"(phase_bit)); } TL_DEVICE void mbarrier_arrive(uint64_t &smem_barrier) { uint32_t smem_int_ptr = smem_ptr_to_uint(&smem_barrier); asm volatile("mbarrier.arrive.shared.b64 _, [%0];" : : "r"(smem_int_ptr)); } TL_DEVICE void mbarrier_expect_tx(uint64_t &smem_barrier, uint32_t transaction_bytes) { uint32_t smem_int_ptr = smem_ptr_to_uint(&smem_barrier); asm volatile("mbarrier.expect_tx.shared.b64 [%1], %0;" : : "r"(transaction_bytes), "r"(smem_int_ptr)); } TL_DEVICE void mbarrier_arrive_expect_tx(uint64_t &smem_barrier, uint32_t transaction_bytes) { uint32_t smem_int_ptr = smem_ptr_to_uint(&smem_barrier); asm volatile("mbarrier.arrive.expect_tx.shared.b64 _, [%1], %0;" : : "r"(transaction_bytes), "r"(smem_int_ptr)); } TL_DEVICE void mbarrier_cp_async_arrive(uint64_t &smem_barrier) { uint32_t smem_int_ptr = smem_ptr_to_uint(&smem_barrier); asm volatile("cp.async.mbarrier.arrive.shared.b64 [%0];" : : "r"(smem_int_ptr)); } TL_DEVICE void fence_proxy_async() { asm volatile("fence.proxy.async.shared::cta;" : :); } TL_DEVICE void syncthreads_partial(uint64_t &smem_barrier) { uint32_t smem_int_ptr = smem_ptr_to_uint(&smem_barrier); uint64_t state = 0; asm volatile("{\n" ".reg .pred P1;\n" "mbarrier.arrive.shared.b64 %1, [%0];\n" "LAB_WAIT:\n" "mbarrier.try_wait.shared.b64 P1, [%0], %1;\n" "@!P1 bra.uni LAB_WAIT;\n" "}\n" : : "r"(smem_int_ptr), "l"(state)); } template TL_DEVICE void warpgroup_reg_alloc() { asm volatile("setmaxnreg.inc.sync.aligned.u32 %0;\n" : : "n"(RegCount)); } template TL_DEVICE void warpgroup_reg_dealloc() { asm volatile("setmaxnreg.dec.sync.aligned.u32 %0;\n" : : "n"(RegCount)); } } // namespace tl