/* * Copyright (c) 2013 Mellanox Technologies, Inc. * All rights reserved. * $COPYRIGHT$ * * Additional copyrights may follow * * $HEADER$ */ #include "oshmem_config.h" #include #include #include "orte/mca/grpcomm/grpcomm.h" #include "opal/util/bit_ops.h" #include "oshmem/constants.h" #include "oshmem/mca/spml/spml.h" #include "oshmem/mca/scoll/scoll.h" #include "oshmem/mca/scoll/base/base.h" #include "scoll_basic.h" static int _algorithm_central_counter(struct oshmem_group_t *group, int PE_root, void *target, const void *source, size_t nlong, long *pSync); static int _algorithm_binomial_tree(struct oshmem_group_t *group, int PE_root, void *target, const void *source, size_t nlong, long *pSync); int mca_scoll_basic_broadcast(struct oshmem_group_t *group, int PE_root, void *target, const void *source, size_t nlong, long *pSync, int alg) { int rc = OSHMEM_SUCCESS; /* Arguments validation */ if (!group) { SCOLL_ERROR("Active set (group) of PE is not defined"); rc = OSHMEM_ERR_BAD_PARAM; } /* Check if this PE is part of the group */ if ((rc == OSHMEM_SUCCESS) && oshmem_proc_group_is_member(group)) { int i = 0; if (pSync) { alg = (alg == SCOLL_DEFAULT_ALG ? mca_scoll_basic_param_broadcast_algorithm : alg); switch (alg) { case SCOLL_ALG_BROADCAST_CENTRAL_COUNTER: { rc = _algorithm_central_counter(group, PE_root, target, source, nlong, pSync); break; } case SCOLL_ALG_BROADCAST_BINOMIAL: { rc = _algorithm_binomial_tree(group, PE_root, target, source, nlong, pSync); break; } default: { rc = _algorithm_binomial_tree(group, PE_root, target, source, nlong, pSync); } } } else { SCOLL_ERROR("Incorrect argument pSync"); rc = OSHMEM_ERR_BAD_PARAM; } /* Restore initial values */ SCOLL_VERBOSE(12, "[#%d] Restore special synchronization array", group->my_pe); for (i = 0; pSync && (i < _SHMEM_BCAST_SYNC_SIZE); i++) { pSync[i] = _SHMEM_SYNC_VALUE; } } return rc; } /* This algorithm is quite simple and straightforward. But because of it�s obvious simplicity and the naive prove for correctness it is implemented quite often. The root send data to all. Outlay: NP-1 competing network transfers are needed to implement the counter The memory usage is constant (1 byte) per node. */ static int _algorithm_central_counter(struct oshmem_group_t *group, int PE_root, void *target, const void *source, size_t nlong, long *pSync) { int rc = OSHMEM_SUCCESS; int i = 0; SCOLL_VERBOSE(12, "[#%d] Broadcast algorithm: Central Counter", group->my_pe); SCOLL_VERBOSE(15, "[#%d] pSync[0] = %ld root = #%d", group->my_pe, pSync[0], PE_root); /* Check if this PE is the root */ if (PE_root == group->my_pe) { int pe_cur = 0; SCOLL_VERBOSE(14, "[#%d] send data to all PE in the group", group->my_pe); for (i = 0; (i < group->proc_count) && (rc == OSHMEM_SUCCESS); i++) { pe_cur = oshmem_proc_pe(group->proc_array[i]); if (pe_cur != PE_root) { SCOLL_VERBOSE(15, "[#%d] send data to #%d", group->my_pe, pe_cur); rc = MCA_SPML_CALL(put(target, nlong, (void *)source, pe_cur)); } } } /* Wait for operation completion to set needed size */ if (rc == OSHMEM_SUCCESS) { SCOLL_VERBOSE(14, "[#%d] Wait for operation completion", group->my_pe); rc = group->g_scoll.scoll_barrier(group, (pSync + 1), SCOLL_DEFAULT_ALG); } return rc; } /* The Binomial Spanning Tree algorithm. Outlay: The game scales with log2(NP) and uses 1 byte of memory. */ static int _algorithm_binomial_tree(struct oshmem_group_t *group, int PE_root, void *target, const void *source, size_t nlong, long *pSync) { int rc = OSHMEM_SUCCESS; long value = SHMEM_SYNC_INIT; int root_id = oshmem_proc_group_find_id(group, PE_root); int my_id = oshmem_proc_group_find_id(group, group->my_pe); int peer_id = 0; int peer_pe = 0; int vrank; int dim = opal_cube_dim(group->proc_count); int hibit; int mask; int i = 0; SCOLL_VERBOSE(12, "[#%d] Broadcast algorithm: Tree", group->my_pe); SCOLL_VERBOSE(15, "[#%d] pSync[0] = %ld root = #%d", group->my_pe, pSync[0], PE_root); vrank = (my_id + group->proc_count - root_id) % group->proc_count; hibit = opal_hibit(vrank, dim); SCOLL_VERBOSE(15, "[#%d] dim = %d vrank = %d hibit = %d", group->my_pe, dim, vrank, hibit); dim--; pSync[0] = SHMEM_SYNC_READY; /* Receive data from parent in the tree. */ if (vrank > 0) { value = SHMEM_SYNC_READY; SCOLL_VERBOSE(14, "[#%d] wait", group->my_pe); rc = MCA_SPML_CALL(wait((void*)pSync, SHMEM_CMP_NE, (void*)&value, SHMEM_LONG)); while ((value = pSync[0]) < 0) { SCOLL_VERBOSE(14, "[#%d] Broadcast size is a negative value (%li)\n", group->my_pe, pSync[0]); MCA_SPML_CALL(wait((void*)pSync, SHMEM_CMP_NE, (void*)&value, SHMEM_LONG)); } if (OSHMEM_SUCCESS != rc) { return rc; } nlong = (size_t) pSync[0]; } /* Send data to the children. */ for (i = hibit + 1, mask = 1 << i; i <= dim; ++i, mask <<= 1) { peer_id = vrank | mask; if (peer_id < group->proc_count) { /* Wait for the child to be ready to receive (pSync must have the initial value) */ peer_id = (peer_id + root_id) % group->proc_count; peer_pe = oshmem_proc_pe(group->proc_array[peer_id]); SCOLL_VERBOSE(14, "[#%d] check remote pe is ready to receive #%d", group->my_pe, peer_pe); do { rc = MCA_SPML_CALL(get((void*)pSync, sizeof(long), (void*)pSync, peer_pe)); } while ((OSHMEM_SUCCESS == rc) && (pSync[0] != SHMEM_SYNC_READY)); SCOLL_VERBOSE(14, "[#%d] send data to #%d", group->my_pe, peer_pe); rc = MCA_SPML_CALL(put(target, nlong, (my_id == root_id ? (void *)source : target), peer_pe)); MCA_SPML_CALL(fence()); SCOLL_VERBOSE(14, "[#%d] signals to #%d", group->my_pe, peer_pe); value = nlong; rc = MCA_SPML_CALL(put((void*)pSync, sizeof(value), (void*)&value, peer_pe)); if (OSHMEM_SUCCESS != rc) { break; } } } return rc; }