//===------- Mapping.cpp - OpenMP device runtime mapping helpers -- 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 // //===----------------------------------------------------------------------===// // // //===----------------------------------------------------------------------===// #include "Mapping.h" #include "DeviceTypes.h" #include "DeviceUtils.h" #include "Interface.h" #include "State.h" #pragma omp begin declare target device_type(nohost) #include "llvm/Frontend/OpenMP/OMPGridValues.h" using namespace ompx; namespace ompx { namespace impl { // Forward declarations defined to be defined for AMDGCN and NVPTX. LaneMaskTy activemask(); LaneMaskTy lanemaskLT(); LaneMaskTy lanemaskGT(); uint32_t getThreadIdInWarp(); uint32_t getThreadIdInBlock(int32_t Dim); uint32_t getNumberOfThreadsInBlock(int32_t Dim); uint32_t getNumberOfThreadsInKernel(); uint32_t getBlockIdInKernel(int32_t Dim); uint32_t getNumberOfBlocksInKernel(int32_t Dim); uint32_t getWarpIdInBlock(); uint32_t getNumberOfWarpsInBlock(); uint32_t getWarpSize(); /// AMDGCN Implementation /// ///{ #pragma omp begin declare variant match(device = {arch(amdgcn)}) uint32_t getWarpSize() { return __builtin_amdgcn_wavefrontsize(); } uint32_t getNumberOfThreadsInBlock(int32_t Dim) { switch (Dim) { case 0: return __builtin_amdgcn_workgroup_size_x(); case 1: return __builtin_amdgcn_workgroup_size_y(); case 2: return __builtin_amdgcn_workgroup_size_z(); }; UNREACHABLE("Dim outside range!"); } LaneMaskTy activemask() { return __builtin_amdgcn_read_exec(); } LaneMaskTy lanemaskLT() { uint32_t Lane = mapping::getThreadIdInWarp(); int64_t Ballot = mapping::activemask(); uint64_t Mask = ((uint64_t)1 << Lane) - (uint64_t)1; return Mask & Ballot; } LaneMaskTy lanemaskGT() { uint32_t Lane = mapping::getThreadIdInWarp(); if (Lane == (mapping::getWarpSize() - 1)) return 0; int64_t Ballot = mapping::activemask(); uint64_t Mask = (~((uint64_t)0)) << (Lane + 1); return Mask & Ballot; } uint32_t getThreadIdInWarp() { return __builtin_amdgcn_mbcnt_hi(~0u, __builtin_amdgcn_mbcnt_lo(~0u, 0u)); } uint32_t getThreadIdInBlock(int32_t Dim) { switch (Dim) { case 0: return __builtin_amdgcn_workitem_id_x(); case 1: return __builtin_amdgcn_workitem_id_y(); case 2: return __builtin_amdgcn_workitem_id_z(); }; UNREACHABLE("Dim outside range!"); } uint32_t getNumberOfThreadsInKernel() { return __builtin_amdgcn_grid_size_x() * __builtin_amdgcn_grid_size_y() * __builtin_amdgcn_grid_size_z(); } uint32_t getBlockIdInKernel(int32_t Dim) { switch (Dim) { case 0: return __builtin_amdgcn_workgroup_id_x(); case 1: return __builtin_amdgcn_workgroup_id_y(); case 2: return __builtin_amdgcn_workgroup_id_z(); }; UNREACHABLE("Dim outside range!"); } uint32_t getNumberOfBlocksInKernel(int32_t Dim) { switch (Dim) { case 0: return __builtin_amdgcn_grid_size_x() / __builtin_amdgcn_workgroup_size_x(); case 1: return __builtin_amdgcn_grid_size_y() / __builtin_amdgcn_workgroup_size_y(); case 2: return __builtin_amdgcn_grid_size_z() / __builtin_amdgcn_workgroup_size_z(); }; UNREACHABLE("Dim outside range!"); } uint32_t getWarpIdInBlock() { return impl::getThreadIdInBlock(mapping::DIM_X) / mapping::getWarpSize(); } uint32_t getNumberOfWarpsInBlock() { return mapping::getNumberOfThreadsInBlock() / mapping::getWarpSize(); } #pragma omp end declare variant ///} /// NVPTX Implementation /// ///{ #pragma omp begin declare variant match( \ device = {arch(nvptx, nvptx64)}, \ implementation = {extension(match_any)}) uint32_t getNumberOfThreadsInBlock(int32_t Dim) { switch (Dim) { case 0: return __nvvm_read_ptx_sreg_ntid_x(); case 1: return __nvvm_read_ptx_sreg_ntid_y(); case 2: return __nvvm_read_ptx_sreg_ntid_z(); }; UNREACHABLE("Dim outside range!"); } uint32_t getWarpSize() { return __nvvm_read_ptx_sreg_warpsize(); } LaneMaskTy activemask() { return __nvvm_activemask(); } LaneMaskTy lanemaskLT() { return __nvvm_read_ptx_sreg_lanemask_lt(); } LaneMaskTy lanemaskGT() { return __nvvm_read_ptx_sreg_lanemask_gt(); } uint32_t getThreadIdInBlock(int32_t Dim) { switch (Dim) { case 0: return __nvvm_read_ptx_sreg_tid_x(); case 1: return __nvvm_read_ptx_sreg_tid_y(); case 2: return __nvvm_read_ptx_sreg_tid_z(); }; UNREACHABLE("Dim outside range!"); } uint32_t getThreadIdInWarp() { return __nvvm_read_ptx_sreg_laneid(); } uint32_t getBlockIdInKernel(int32_t Dim) { switch (Dim) { case 0: return __nvvm_read_ptx_sreg_ctaid_x(); case 1: return __nvvm_read_ptx_sreg_ctaid_y(); case 2: return __nvvm_read_ptx_sreg_ctaid_z(); }; UNREACHABLE("Dim outside range!"); } uint32_t getNumberOfBlocksInKernel(int32_t Dim) { switch (Dim) { case 0: return __nvvm_read_ptx_sreg_nctaid_x(); case 1: return __nvvm_read_ptx_sreg_nctaid_y(); case 2: return __nvvm_read_ptx_sreg_nctaid_z(); }; UNREACHABLE("Dim outside range!"); } uint32_t getNumberOfThreadsInKernel() { return impl::getNumberOfThreadsInBlock(0) * impl::getNumberOfBlocksInKernel(0) * impl::getNumberOfThreadsInBlock(1) * impl::getNumberOfBlocksInKernel(1) * impl::getNumberOfThreadsInBlock(2) * impl::getNumberOfBlocksInKernel(2); } uint32_t getWarpIdInBlock() { return impl::getThreadIdInBlock(mapping::DIM_X) / mapping::getWarpSize(); } uint32_t getNumberOfWarpsInBlock() { return (mapping::getNumberOfThreadsInBlock() + mapping::getWarpSize() - 1) / mapping::getWarpSize(); } #pragma omp end declare variant ///} } // namespace impl } // namespace ompx /// We have to be deliberate about the distinction of `mapping::` and `impl::` /// below to avoid repeating assumptions or including irrelevant ones. ///{ static bool isInLastWarp() { uint32_t MainTId = (mapping::getNumberOfThreadsInBlock() - 1) & ~(mapping::getWarpSize() - 1); return mapping::getThreadIdInBlock() == MainTId; } bool mapping::isMainThreadInGenericMode(bool IsSPMD) { if (IsSPMD || icv::Level) return false; // Check if this is the last warp in the block. return isInLastWarp(); } bool mapping::isMainThreadInGenericMode() { return mapping::isMainThreadInGenericMode(mapping::isSPMDMode()); } bool mapping::isInitialThreadInLevel0(bool IsSPMD) { if (IsSPMD) return mapping::getThreadIdInBlock() == 0; return isInLastWarp(); } bool mapping::isLeaderInWarp() { __kmpc_impl_lanemask_t Active = mapping::activemask(); __kmpc_impl_lanemask_t LaneMaskLT = mapping::lanemaskLT(); return utils::popc(Active & LaneMaskLT) == 0; } LaneMaskTy mapping::activemask() { return impl::activemask(); } LaneMaskTy mapping::lanemaskLT() { return impl::lanemaskLT(); } LaneMaskTy mapping::lanemaskGT() { return impl::lanemaskGT(); } uint32_t mapping::getThreadIdInWarp() { uint32_t ThreadIdInWarp = impl::getThreadIdInWarp(); ASSERT(ThreadIdInWarp < impl::getWarpSize(), nullptr); return ThreadIdInWarp; } uint32_t mapping::getThreadIdInBlock(int32_t Dim) { uint32_t ThreadIdInBlock = impl::getThreadIdInBlock(Dim); return ThreadIdInBlock; } uint32_t mapping::getWarpSize() { return impl::getWarpSize(); } uint32_t mapping::getMaxTeamThreads(bool IsSPMD) { uint32_t BlockSize = mapping::getNumberOfThreadsInBlock(); // If we are in SPMD mode, remove one warp. return BlockSize - (!IsSPMD * impl::getWarpSize()); } uint32_t mapping::getMaxTeamThreads() { return mapping::getMaxTeamThreads(mapping::isSPMDMode()); } uint32_t mapping::getNumberOfThreadsInBlock(int32_t Dim) { return impl::getNumberOfThreadsInBlock(Dim); } uint32_t mapping::getNumberOfThreadsInKernel() { return impl::getNumberOfThreadsInKernel(); } uint32_t mapping::getWarpIdInBlock() { uint32_t WarpID = impl::getWarpIdInBlock(); ASSERT(WarpID < impl::getNumberOfWarpsInBlock(), nullptr); return WarpID; } uint32_t mapping::getBlockIdInKernel(int32_t Dim) { uint32_t BlockId = impl::getBlockIdInKernel(Dim); ASSERT(BlockId < impl::getNumberOfBlocksInKernel(Dim), nullptr); return BlockId; } uint32_t mapping::getNumberOfWarpsInBlock() { uint32_t NumberOfWarpsInBlocks = impl::getNumberOfWarpsInBlock(); ASSERT(impl::getWarpIdInBlock() < NumberOfWarpsInBlocks, nullptr); return NumberOfWarpsInBlocks; } uint32_t mapping::getNumberOfBlocksInKernel(int32_t Dim) { uint32_t NumberOfBlocks = impl::getNumberOfBlocksInKernel(Dim); ASSERT(impl::getBlockIdInKernel(Dim) < NumberOfBlocks, nullptr); return NumberOfBlocks; } uint32_t mapping::getNumberOfProcessorElements() { return static_cast(config::getHardwareParallelism()); } ///} /// Execution mode /// ///{ // TODO: This is a workaround for initialization coming from kernels outside of // the TU. We will need to solve this more correctly in the future. [[gnu::weak]] int SHARED(IsSPMDMode); void mapping::init(bool IsSPMD) { if (mapping::isInitialThreadInLevel0(IsSPMD)) IsSPMDMode = IsSPMD; } bool mapping::isSPMDMode() { return IsSPMDMode; } bool mapping::isGenericMode() { return !isSPMDMode(); } ///} extern "C" { [[gnu::noinline]] uint32_t __kmpc_get_hardware_thread_id_in_block() { return mapping::getThreadIdInBlock(); } [[gnu::noinline]] uint32_t __kmpc_get_hardware_num_threads_in_block() { return impl::getNumberOfThreadsInBlock(mapping::DIM_X); } [[gnu::noinline]] uint32_t __kmpc_get_warp_size() { return impl::getWarpSize(); } } #define _TGT_KERNEL_LANGUAGE(NAME, MAPPER_NAME) \ extern "C" int ompx_##NAME(int Dim) { return mapping::MAPPER_NAME(Dim); } _TGT_KERNEL_LANGUAGE(thread_id, getThreadIdInBlock) _TGT_KERNEL_LANGUAGE(block_id, getBlockIdInKernel) _TGT_KERNEL_LANGUAGE(block_dim, getNumberOfThreadsInBlock) _TGT_KERNEL_LANGUAGE(grid_dim, getNumberOfBlocksInKernel) extern "C" { uint64_t ompx_ballot_sync(uint64_t mask, int pred) { return utils::ballotSync(mask, pred); } int ompx_shfl_down_sync_i(uint64_t mask, int var, unsigned delta, int width) { return utils::shuffleDown(mask, var, delta, width); } float ompx_shfl_down_sync_f(uint64_t mask, float var, unsigned delta, int width) { return utils::bitCast( utils::shuffleDown(mask, utils::bitCast(var), delta, width)); } long ompx_shfl_down_sync_l(uint64_t mask, long var, unsigned delta, int width) { return utils::shuffleDown(mask, var, delta, width); } double ompx_shfl_down_sync_d(uint64_t mask, double var, unsigned delta, int width) { return utils::bitCast( utils::shuffleDown(mask, utils::bitCast(var), delta, width)); } } #pragma omp end declare target