/* -*- Mode: C; c-basic-offset:4 ; indent-tabs-mode:nil -*- */ /* * Copyright (c) 2004-2005 The Trustees of Indiana University and Indiana * University Research and Technology * Corporation. All rights reserved. * Copyright (c) 2004-2014 The University of Tennessee and The University * of Tennessee Research Foundation. All rights * reserved. * Copyright (c) 2004-2009 High Performance Computing Center Stuttgart, * University of Stuttgart. All rights reserved. * Copyright (c) 2004-2005 The Regents of the University of California. * All rights reserved. * Copyright (c) 2007 Sun Microsystems, Inc. All rights reserved. * Copyright (c) 2008-2010 Cisco Systems, Inc. All rights reserved. * Copyright (c) 2010-2015 Los Alamos National Security, LLC. * All rights reserved. * Copyright (c) 2014 Intel, Inc. All rights reserved * $COPYRIGHT$ * * Additional copyrights may follow * * $HEADER$ */ /* ASSUMING local process homogeneity with respect to all utilized shared memory * facilities. that is, if one local process deems a particular shared memory * facility acceptable, then ALL local processes should be able to utilize that * facility. as it stands, this is an important point because one process * dictates to all other local processes which common sm component will be * selected based on its own, local run-time test. */ #include "opal_config.h" #include "opal/align.h" #include "opal/util/argv.h" #include "opal/util/show_help.h" #include "opal/util/error.h" #include "opal/mca/shmem/base/base.h" #if OPAL_ENABLE_FT_CR == 1 #include "opal/runtime/opal_cr.h" #endif #include "common_sm.h" #include "opal/constants.h" OBJ_CLASS_INSTANCE(mca_common_sm_module_t,opal_list_item_t, NULL, NULL); /* ////////////////////////////////////////////////////////////////////////// */ /* static utility functions */ /* ////////////////////////////////////////////////////////////////////////// */ /* ////////////////////////////////////////////////////////////////////////// */ static mca_common_sm_module_t * attach_and_init(opal_shmem_ds_t *shmem_bufp, size_t size, size_t size_ctl_structure, size_t data_seg_alignment, bool first_call) { mca_common_sm_module_t *map = NULL; mca_common_sm_seg_header_t *seg = NULL; unsigned char *addr = NULL; /* attach to the specified segment. note that at this point, the contents of * *shmem_bufp have already been initialized via opal_shmem_segment_create. */ if (NULL == (seg = (mca_common_sm_seg_header_t *) opal_shmem_segment_attach(shmem_bufp))) { return NULL; } opal_atomic_rmb(); if (NULL == (map = OBJ_NEW(mca_common_sm_module_t))) { OPAL_ERROR_LOG(OPAL_ERR_OUT_OF_RESOURCE); (void)opal_shmem_segment_detach(shmem_bufp); return NULL; } /* copy meta information into common sm module * from ====> to */ if (OPAL_SUCCESS != opal_shmem_ds_copy(shmem_bufp, &map->shmem_ds)) { (void)opal_shmem_segment_detach(shmem_bufp); free(map); return NULL; } /* the first entry in the file is the control structure. the first * entry in the control structure is an mca_common_sm_seg_header_t * element. */ map->module_seg = seg; addr = ((unsigned char *)seg) + size_ctl_structure; /* if we have a data segment (i.e., if 0 != data_seg_alignment), * then make it the first aligned address after the control * structure. IF THIS HAPPENS, THIS IS A PROGRAMMING ERROR IN * OPEN MPI! */ if (0 != data_seg_alignment) { addr = OPAL_ALIGN_PTR(addr, data_seg_alignment, unsigned char *); /* is addr past end of the shared memory segment? */ if ((unsigned char *)seg + shmem_bufp->seg_size < addr) { opal_show_help("help-mpi-common-sm.txt", "mmap too small", 1, opal_proc_local_get()->proc_hostname, (unsigned long)shmem_bufp->seg_size, (unsigned long)size_ctl_structure, (unsigned long)data_seg_alignment); (void)opal_shmem_segment_detach(shmem_bufp); free(map); return NULL; } } map->module_data_addr = addr; map->module_seg_addr = (unsigned char *)seg; /* note that size is only used during the first call */ if (first_call) { /* initialize some segment information */ size_t mem_offset = map->module_data_addr - (unsigned char *)map->module_seg; opal_atomic_lock_init(&map->module_seg->seg_lock, OPAL_ATOMIC_LOCK_UNLOCKED); map->module_seg->seg_inited = 0; map->module_seg->seg_num_procs_inited = 0; map->module_seg->seg_offset = mem_offset; map->module_seg->seg_size = size - mem_offset; opal_atomic_wmb(); } /* increment the number of processes that are attached to the segment. */ (void)opal_atomic_add_fetch_size_t(&map->module_seg->seg_num_procs_inited, 1); /* commit the changes before we return */ opal_atomic_wmb(); return map; } /* ////////////////////////////////////////////////////////////////////////// */ /* api implementation */ /* ////////////////////////////////////////////////////////////////////////// */ /* ////////////////////////////////////////////////////////////////////////// */ mca_common_sm_module_t * mca_common_sm_module_create_and_attach(size_t size, char *file_name, size_t size_ctl_structure, size_t data_seg_alignment) { mca_common_sm_module_t *map = NULL; opal_shmem_ds_t *seg_meta = NULL; if (NULL == (seg_meta = calloc(1, sizeof(*seg_meta)))) { /* out of resources */ return NULL; } if (OPAL_SUCCESS == opal_shmem_segment_create(seg_meta, file_name, size)) { map = attach_and_init(seg_meta, size, size_ctl_structure, data_seg_alignment, true); } /* at this point, seg_meta has been copied to the newly created * shared memory segment, so we can free it */ if (seg_meta) { free(seg_meta); } return map; } /* ////////////////////////////////////////////////////////////////////////// */ /** * @return a pointer to the mca_common_sm_module_t associated with seg_meta if * everything was okay, otherwise returns NULL. */ mca_common_sm_module_t * mca_common_sm_module_attach(opal_shmem_ds_t *seg_meta, size_t size_ctl_structure, size_t data_seg_alignment) { /* notice that size is 0 here. it really doesn't matter because size WILL * NOT be used because this is an attach (first_call is false). */ return attach_and_init(seg_meta, 0, size_ctl_structure, data_seg_alignment, false); } /* ////////////////////////////////////////////////////////////////////////// */ int mca_common_sm_module_unlink(mca_common_sm_module_t *modp) { if (NULL == modp) { return OPAL_ERROR; } if (OPAL_SUCCESS != opal_shmem_unlink(&modp->shmem_ds)) { return OPAL_ERROR; } return OPAL_SUCCESS; } /* ////////////////////////////////////////////////////////////////////////// */ int mca_common_sm_local_proc_reorder(opal_proc_t **procs, size_t num_procs, size_t *out_num_local_procs) { size_t num_local_procs = 0; bool found_lowest = false; opal_proc_t *temp_proc = NULL; size_t p; if (NULL == out_num_local_procs || NULL == procs) { return OPAL_ERR_BAD_PARAM; } /* o reorder procs array to have all the local procs at the beginning. * o look for the local proc with the lowest name. * o determine the number of local procs. * o ensure that procs[0] is the lowest named process. */ for (p = 0; p < num_procs; ++p) { if (OPAL_PROC_ON_LOCAL_NODE(procs[p]->proc_flags)) { /* if we don't have a lowest, save the first one */ if (!found_lowest) { procs[0] = procs[p]; found_lowest = true; } else { /* save this proc */ procs[num_local_procs] = procs[p]; /* if we have a new lowest, swap it with position 0 * so that procs[0] is always the lowest named proc */ if( 0 > opal_compare_proc(procs[p]->proc_name, procs[0]->proc_name) ) { temp_proc = procs[0]; procs[0] = procs[p]; procs[num_local_procs] = temp_proc; } } /* regardless of the comparisons above, we found * another proc on the local node, so increment */ ++num_local_procs; } } *out_num_local_procs = num_local_procs; return OPAL_SUCCESS; } /* ////////////////////////////////////////////////////////////////////////// */ /** * allocate memory from a previously allocated shared memory * block. * * @param size size of request, in bytes (IN) * * @retval addr virtual address */ void *mca_common_sm_seg_alloc (void *ctx, size_t *size) { mca_common_sm_module_t *sm_module = (mca_common_sm_module_t *) ctx; mca_common_sm_seg_header_t *seg = sm_module->module_seg; void *addr; opal_atomic_lock(&seg->seg_lock); if (seg->seg_offset + *size > seg->seg_size) { addr = NULL; } else { size_t fixup; /* add base address to segment offset */ addr = sm_module->module_data_addr + seg->seg_offset; seg->seg_offset += *size; /* fix up seg_offset so next allocation is aligned on a * sizeof(long) boundry. Do it here so that we don't have to * check before checking remaining size in buffer */ if ((fixup = (seg->seg_offset & (sizeof(long) - 1))) > 0) { seg->seg_offset += sizeof(long) - fixup; } } opal_atomic_unlock(&seg->seg_lock); return addr; } /* ////////////////////////////////////////////////////////////////////////// */ int mca_common_sm_fini(mca_common_sm_module_t *mca_common_sm_module) { int rc = OPAL_SUCCESS; if (NULL != mca_common_sm_module->module_seg) { if (OPAL_SUCCESS != opal_shmem_segment_detach(&mca_common_sm_module->shmem_ds)) { rc = OPAL_ERROR; } } return rc; }