/* * Copyright (c) 2004-2005 The Trustees of Indiana University and Indiana * University Research and Technology * Corporation. All rights reserved. * Copyright (c) 2004-2005 The University of Tennessee and The University * of Tennessee Research Foundation. All rights * reserved. * Copyright (c) 2004-2005 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. * $COPYRIGHT$ * * Additional copyrights may follow * * $HEADER$ */ #include "ompi_config.h" #include #include "opal/util/output.h" #include "opal/util/if.h" #include "mca/pml/pml.h" #include "mca/btl/btl.h" #include "btl_gm.h" #include "btl_gm_frag.h" #include "btl_gm_proc.h" #include "btl_gm_endpoint.h" #include "datatype/convertor.h" #include "datatype/datatype.h" #include "mca/mpool/base/base.h" #include "mca/mpool/mpool.h" #include "ompi/proc/proc.h" mca_btl_gm_module_t mca_btl_gm_module = { { &mca_btl_gm_component.super, 0, /* max size of first fragment */ 0, /* min send fragment size */ 0, /* max send fragment size */ 0, /* min rdma fragment size */ 0, /* max rdma fragment size */ 0, /* exclusivity */ 0, /* latency */ 0, /* bandwidth */ 0, /* flags */ mca_btl_gm_add_procs, mca_btl_gm_del_procs, mca_btl_gm_register, mca_btl_gm_finalize, mca_btl_gm_alloc, mca_btl_gm_free, mca_btl_gm_prepare_src, mca_btl_gm_prepare_dst, mca_btl_gm_send, mca_btl_gm_put, NULL /* get */ } }; /** * */ int mca_btl_gm_add_procs( struct mca_btl_base_module_t* btl, size_t nprocs, struct ompi_proc_t **ompi_procs, struct mca_btl_base_endpoint_t** peers, ompi_bitmap_t* reachable) { mca_btl_gm_module_t* gm_btl = (mca_btl_gm_module_t*)btl; int i, rc; for(i = 0; i < (int) nprocs; i++) { struct ompi_proc_t* ompi_proc = ompi_procs[i]; mca_btl_gm_proc_t* gm_proc; mca_btl_base_endpoint_t* gm_endpoint; if(ompi_proc == ompi_proc_local()) continue; if(NULL == (gm_proc = mca_btl_gm_proc_create(ompi_proc))) { continue; } /* * Check to make sure that the peer has at least as many interface * addresses exported as we are trying to use. If not, then * don't bind this PTL instance to the proc. */ OPAL_THREAD_LOCK(&gm_proc->proc_lock); /* The btl_proc datastructure is shared by all GM PTL * instances that are trying to reach this destination. * Cache the peer instance on the btl_proc. */ gm_endpoint = OBJ_NEW(mca_btl_gm_endpoint_t); if(NULL == gm_endpoint) { OPAL_THREAD_UNLOCK(&gm_proc->proc_lock); return OMPI_ERR_OUT_OF_RESOURCE; } gm_endpoint->endpoint_btl = gm_btl; rc = mca_btl_gm_proc_insert(gm_proc, gm_endpoint); if(rc != OMPI_SUCCESS) { OBJ_RELEASE(gm_endpoint); OPAL_THREAD_UNLOCK(&gm_proc->proc_lock); continue; } ompi_bitmap_set_bit(reachable, i); OPAL_THREAD_UNLOCK(&gm_proc->proc_lock); peers[i] = gm_endpoint; } return OMPI_SUCCESS; } int mca_btl_gm_del_procs(struct mca_btl_base_module_t* btl, size_t nprocs, struct ompi_proc_t **procs, struct mca_btl_base_endpoint_t ** peers) { /* TODO */ return OMPI_SUCCESS; } /** * Register callback function to support send/recv semantics */ int mca_btl_gm_register( struct mca_btl_base_module_t* btl, mca_btl_base_tag_t tag, mca_btl_base_module_recv_cb_fn_t cbfunc, void* cbdata) { mca_btl_gm_module_t* gm_btl = (mca_btl_gm_module_t*) btl; gm_btl->gm_reg[tag].cbfunc = cbfunc; gm_btl->gm_reg[tag].cbdata = cbdata; return OMPI_SUCCESS; } /** * Allocate a segment. * * @param btl (IN) BTL module * @param size (IN) Request segment size. */ mca_btl_base_descriptor_t* mca_btl_gm_alloc( struct mca_btl_base_module_t* btl, size_t size) { mca_btl_gm_module_t* gm_btl = (mca_btl_gm_module_t*) btl; mca_btl_gm_frag_t* frag; int rc; if(size <= btl->btl_eager_limit) { MCA_BTL_GM_FRAG_ALLOC_EAGER(gm_btl, frag, rc); frag->segment.seg_len = size <= btl->btl_eager_limit ? size : btl->btl_eager_limit ; } else { MCA_BTL_GM_FRAG_ALLOC_MAX(gm_btl, frag, rc); frag->segment.seg_len = size <= btl->btl_max_send_size ? size : btl->btl_max_send_size ; } frag->base.des_src = &frag->segment; frag->base.des_src_cnt = 1; frag->base.des_dst = NULL; frag->base.des_dst_cnt = 0; frag->base.des_flags = 0; return &frag->base; } /** * Return a segment */ int mca_btl_gm_free( struct mca_btl_base_module_t* btl, mca_btl_base_descriptor_t* des) { mca_btl_gm_frag_t* frag = (mca_btl_gm_frag_t*)des; if(frag->size == 0) { btl->btl_mpool->mpool_release(btl->btl_mpool, frag->registration); MCA_BTL_GM_FRAG_RETURN_USER(btl, frag); } else if(frag->size == mca_btl_gm_component.gm_eager_frag_size) { MCA_BTL_GM_FRAG_RETURN_EAGER(btl, frag); } else if(frag->size == mca_btl_gm_component.gm_max_frag_size) { MCA_BTL_GM_FRAG_RETURN_MAX(btl, frag); } else { opal_output(0, "[%s:%d] mca_btl_gm_free: invalid descriptor\n", __FILE__,__LINE__); return OMPI_ERR_BAD_PARAM; } return OMPI_SUCCESS; } /** * Pack data and return a descriptor that can be * used for send/put. * * @param btl (IN) BTL module * @param peer (IN) BTL peer addressing */ mca_btl_base_descriptor_t* mca_btl_gm_prepare_src( struct mca_btl_base_module_t* btl, struct mca_btl_base_endpoint_t* endpoint, struct mca_mpool_base_registration_t* registration, struct ompi_convertor_t* convertor, size_t reserve, size_t* size ) { mca_btl_gm_frag_t* frag; struct iovec iov; uint32_t iov_count = 1; size_t max_data = *size; int32_t free_after; int rc; #if (OMPI_MCA_BTL_GM_HAVE_RDMA_GET || OMPI_MCA_BTL_GM_HAVE_RDMA_PUT) /* * If the data has already been pinned and is contigous than we can * use it in place. */ if (NULL != registration && 0 == ompi_convertor_need_buffers(convertor)) { size_t reg_len; MCA_BTL_GM_FRAG_ALLOC_USER(btl, frag, rc); if(NULL == frag){ return NULL; } iov.iov_len = max_data; iov.iov_base = NULL; ompi_convertor_pack(convertor, &iov, &iov_count, &max_data, &free_after); frag->segment.seg_len = max_data; frag->segment.seg_addr.pval = iov.iov_base; reg_len = (unsigned char*)registration->bound - (unsigned char*)iov.iov_base + 1; /* bump reference count as so that the registration * doesn't go away when the operation completes */ btl->btl_mpool->mpool_retain(btl->btl_mpool, (mca_mpool_base_registration_t*) registration); frag->registration = registration; /* * if the data is not already pinned - but the leave pinned option is set, * then go ahead and pin contigous data. however, if a reserve is required * then we must allocated a fragment w/ buffer space */ } else if (max_data > btl->btl_max_send_size && ompi_convertor_need_buffers(convertor) == 0 && reserve == 0) { mca_mpool_base_module_t* mpool = btl->btl_mpool; MCA_BTL_GM_FRAG_ALLOC_USER(btl, frag, rc); if(NULL == frag){ return NULL; } iov.iov_len = max_data; iov.iov_base = NULL; ompi_convertor_pack(convertor, &iov, &iov_count, &max_data, &free_after); frag->segment.seg_len = max_data; frag->segment.seg_addr.pval = iov.iov_base; rc = mpool->mpool_register( mpool, iov.iov_base, max_data, 0, ®istration); if(rc != OMPI_SUCCESS) { MCA_BTL_GM_FRAG_RETURN_USER(btl,frag); return NULL; } frag->registration = registration; } /* * if we aren't pinning the data and the requested size is less * than the eager limit pack into a fragment from the eager pool */ else #endif if (max_data+reserve <= btl->btl_eager_limit) { MCA_BTL_GM_FRAG_ALLOC_EAGER(btl, frag, rc); if(NULL == frag) { return NULL; } iov.iov_len = max_data; iov.iov_base = (unsigned char*) frag->segment.seg_addr.pval + reserve; rc = ompi_convertor_pack(convertor, &iov, &iov_count, &max_data, &free_after); *size = max_data; if( rc < 0 ) { MCA_BTL_GM_FRAG_RETURN_EAGER(btl, frag); return NULL; } frag->segment.seg_len = max_data + reserve; } /* * otherwise pack as much data as we can into a fragment * that is the max send size. */ else { MCA_BTL_GM_FRAG_ALLOC_MAX(btl, frag, rc); if(NULL == frag) { return NULL; } if(max_data + reserve > btl->btl_max_send_size){ max_data = btl->btl_max_send_size - reserve; } iov.iov_len = max_data; iov.iov_base = (unsigned char*) frag->segment.seg_addr.pval + reserve; rc = ompi_convertor_pack(convertor, &iov, &iov_count, &max_data, &free_after); *size = max_data; if( rc < 0 ) { MCA_BTL_GM_FRAG_RETURN_MAX(btl, frag); return NULL; } frag->segment.seg_len = max_data + reserve; } frag->base.des_src = &frag->segment; frag->base.des_src_cnt = 1; frag->base.des_dst = NULL; frag->base.des_dst_cnt = 0; frag->base.des_flags = 0; return &frag->base; } /** * Prepare a descriptor for send/rdma using the supplied * convertor. If the convertor references data that is contigous, * the descriptor may simply point to the user buffer. Otherwise, * this routine is responsible for allocating buffer space and * packing if required. * * @param btl (IN) BTL module * @param endpoint (IN) BTL peer addressing * @param convertor (IN) Data type convertor * @param reserve (IN) Additional bytes requested by upper layer to precede user data * @param size (IN/OUT) Number of bytes to prepare (IN), number of bytes actually prepared (OUT) */ mca_btl_base_descriptor_t* mca_btl_gm_prepare_dst( struct mca_btl_base_module_t* btl, struct mca_btl_base_endpoint_t* endpoint, struct mca_mpool_base_registration_t* registration, struct ompi_convertor_t* convertor, size_t reserve, size_t* size) { #if (OMPI_MCA_BTL_GM_HAVE_RDMA_GET || OMPI_MCA_BTL_GM_HAVE_RDMA_PUT) mca_btl_gm_frag_t* frag; mca_mpool_base_module_t* mpool = btl->btl_mpool; long lb; int rc; MCA_BTL_GM_FRAG_ALLOC_USER(btl, frag, rc); if(NULL == frag) { return NULL; } ompi_ddt_type_lb(convertor->pDesc, &lb); frag->segment.seg_len = *size; frag->segment.seg_addr.pval = convertor->pBaseBuf + lb + convertor->bConverted; frag->base.des_src = NULL; frag->base.des_src_cnt = 0; frag->base.des_dst = &frag->segment; frag->base.des_dst_cnt = 1; frag->base.des_flags = 0; if(NULL != registration) { /* bump reference count as so that the registration * doesn't go away when the operation completes */ mpool->mpool_retain(mpool, (mca_mpool_base_registration_t*) registration); frag->registration = registration; } else { rc = mpool->mpool_register( mpool, frag->segment.seg_addr.pval, frag->segment.seg_len, 0, ®istration); if(rc != OMPI_SUCCESS) { MCA_BTL_GM_FRAG_RETURN_USER(btl,frag); return NULL; } frag->registration = registration; } return &frag->base; #else return NULL; #endif } /** * */ static void mca_btl_gm_drop_callback( struct gm_port* port, void* context, gm_status_t status ) { mca_btl_gm_module_t* btl = (mca_btl_gm_module_t*)context; OPAL_THREAD_ADD32( &btl->gm_num_send_tokens, 1 ); } /** * Callback on send completion and/or error */ static void mca_btl_gm_send_callback( struct gm_port* port, void* context, gm_status_t status ) { mca_btl_gm_frag_t* frag = (mca_btl_gm_frag_t*)context; mca_btl_gm_module_t* btl = frag->btl; switch(status) { case GM_TRY_AGAIN: case GM_SEND_TIMED_OUT: case GM_TIMED_OUT: /* drop all sends to this destination port */ gm_drop_sends( btl->port, (frag->base.des_flags & MCA_BTL_DES_FLAGS_PRIORITY) ? GM_HIGH_PRIORITY : GM_LOW_PRIORITY, frag->endpoint->endpoint_addr.node_id, frag->endpoint->endpoint_addr.port_id, mca_btl_gm_drop_callback, btl ); /* retry the failed fragment */ mca_btl_gm_send(&btl->super, frag->endpoint, &frag->base, frag->hdr->tag); break; case GM_SEND_DROPPED: /* release the send token */ OPAL_THREAD_ADD32(&btl->gm_num_send_tokens, 1); /* retry the dropped fragment */ mca_btl_gm_send(&btl->super, frag->endpoint, &frag->base, frag->hdr->tag); break; case GM_SUCCESS: /* call the completion callback */ frag->base.des_cbfunc(&btl->super, frag->endpoint, &frag->base, OMPI_SUCCESS); /* return the send token and deque pending fragments */ MCA_BTL_GM_RETURN_TOKEN(btl); break; default: /* error condition can't deal with */ opal_output(0, "[%s:%d] send completed with unhandled gm error %d\n", __FILE__,__LINE__,status); /* release the send token */ OPAL_THREAD_ADD32( &btl->gm_num_send_tokens, 1 ); /* call the completion callback */ frag->base.des_cbfunc(&btl->super, frag->endpoint, &frag->base, OMPI_ERROR); break; } } /** * Initiate an asynchronous send. * * @param btl (IN) BTL module * @param endpoint (IN) BTL addressing information * @param descriptor (IN) Description of the data to be transfered * @param tag (IN) The tag value used to notify the peer. */ int mca_btl_gm_send( struct mca_btl_base_module_t* btl, struct mca_btl_base_endpoint_t* endpoint, struct mca_btl_base_descriptor_t* des, mca_btl_base_tag_t tag) { mca_btl_gm_module_t* gm_btl = (mca_btl_gm_module_t*) btl; mca_btl_gm_frag_t* frag = (mca_btl_gm_frag_t*)des; frag->btl = gm_btl; frag->endpoint = endpoint; frag->hdr->tag = tag; frag->type = MCA_BTL_GM_SEND; /* queue the descriptor if there are no send tokens */ MCA_BTL_GM_ACQUIRE_TOKEN(gm_btl, frag); /* post the send descriptor */ if(frag->base.des_flags & MCA_BTL_DES_FLAGS_PRIORITY && frag->size == mca_btl_gm_component.gm_eager_frag_size) { gm_send_with_callback( gm_btl->port, frag->hdr, mca_btl_gm_component.gm_eager_frag_size, frag->segment.seg_len + sizeof(mca_btl_base_header_t), GM_HIGH_PRIORITY, endpoint->endpoint_addr.node_id, endpoint->endpoint_addr.port_id, mca_btl_gm_send_callback, frag); } else { gm_send_with_callback( gm_btl->port, frag->hdr, mca_btl_gm_component.gm_max_frag_size, frag->segment.seg_len + sizeof(mca_btl_base_header_t), GM_LOW_PRIORITY, endpoint->endpoint_addr.node_id, endpoint->endpoint_addr.port_id, mca_btl_gm_send_callback, frag); } if(opal_list_get_size(&gm_btl->gm_repost)) { mca_btl_gm_frag_t* frag; OPAL_THREAD_LOCK(&gm_btl->gm_lock); while(NULL != (frag = (mca_btl_gm_frag_t*)opal_list_remove_first(&gm_btl->gm_repost))) { gm_provide_receive_buffer(gm_btl->port, frag->hdr, frag->size, frag->priority); } OPAL_THREAD_UNLOCK(&gm_btl->gm_lock); } return OMPI_SUCCESS; } /** * Callback on put completion and/or error */ static void mca_btl_gm_put_callback( struct gm_port* port, void* context, gm_status_t status ) { mca_btl_gm_frag_t* frag = (mca_btl_gm_frag_t*)context; mca_btl_gm_module_t* btl = frag->btl; /* call the completion callback */ switch(status) { case GM_TRY_AGAIN: case GM_SEND_TIMED_OUT: case GM_TIMED_OUT: /* drop all sends to this destination port */ gm_drop_sends( btl->port, (frag->base.des_flags & MCA_BTL_DES_FLAGS_PRIORITY) ? GM_HIGH_PRIORITY : GM_LOW_PRIORITY, frag->endpoint->endpoint_addr.node_id, frag->endpoint->endpoint_addr.port_id, mca_btl_gm_drop_callback, btl ); /* retry the failed fragment */ mca_btl_gm_put(&btl->super, frag->endpoint, &frag->base); break; case GM_SEND_DROPPED: /* release the send token */ OPAL_THREAD_ADD32(&btl->gm_num_send_tokens, 1); /* retry the dropped fragment */ mca_btl_gm_put(&btl->super, frag->endpoint, &frag->base); break; case GM_SUCCESS: /* call completion callback */ frag->base.des_cbfunc(&btl->super, frag->endpoint, &frag->base, OMPI_SUCCESS); /* return the send token and deque pending fragments */ MCA_BTL_GM_RETURN_TOKEN(btl); break; default: /* error condition can't deal with */ opal_output(0, "[%s:%d] gm_put operation failed with status %d\n", __FILE__, __LINE__, status); /* release the send token */ OPAL_THREAD_ADD32( &btl->gm_num_send_tokens, 1 ); /* call the completion callback */ frag->base.des_cbfunc(&btl->super, frag->endpoint, &frag->base, OMPI_ERROR); break; } } /** * Initiate an asynchronous put. * * @param btl (IN) BTL module * @param endpoint (IN) BTL addressing information * @param descriptor (IN) Description of the data to be transferred */ int mca_btl_gm_put( mca_btl_base_module_t* btl, mca_btl_base_endpoint_t* endpoint, mca_btl_base_descriptor_t* des) { #if OMPI_MCA_BTL_GM_HAVE_RDMA_PUT mca_btl_gm_module_t* gm_btl = (mca_btl_gm_module_t*) btl; mca_btl_gm_frag_t* frag = (mca_btl_gm_frag_t*) des; frag->btl = gm_btl; frag->endpoint = endpoint; frag->type = MCA_BTL_GM_PUT; /* queue the descriptor if there are no send tokens */ MCA_BTL_GM_ACQUIRE_TOKEN(gm_btl, frag); /* post the put descriptor */ gm_put(gm_btl->port, des->des_src->seg_addr.pval, des->des_dst->seg_addr.lval, des->des_src->seg_len, GM_LOW_PRIORITY, endpoint->endpoint_addr.node_id, endpoint->endpoint_addr.port_id, mca_btl_gm_put_callback, frag); return OMPI_SUCCESS; #else return OMPI_ERR_NOT_IMPLEMENTED; #endif } /** * Callback on get completion and/or error */ static void mca_btl_gm_get_callback( struct gm_port* port, void* context, gm_status_t status ) { mca_btl_gm_frag_t* frag = (mca_btl_gm_frag_t*)context; mca_btl_gm_module_t* btl = frag->btl; /* call the completion callback */ switch(status) { case GM_TRY_AGAIN: case GM_SEND_TIMED_OUT: case GM_TIMED_OUT: /* drop all sends to this destination port */ gm_drop_sends( btl->port, (frag->base.des_flags & MCA_BTL_DES_FLAGS_PRIORITY) ? GM_HIGH_PRIORITY : GM_LOW_PRIORITY, frag->endpoint->endpoint_addr.node_id, frag->endpoint->endpoint_addr.port_id, mca_btl_gm_drop_callback, btl ); /* retry the failed fragment */ mca_btl_gm_get(&btl->super, frag->endpoint, &frag->base); break; case GM_SEND_DROPPED: /* release the send token */ OPAL_THREAD_ADD32(&btl->gm_num_send_tokens, 1); /* retry the dropped fragment */ mca_btl_gm_get(&btl->super, frag->endpoint, &frag->base); break; case GM_SUCCESS: /* call completion callback */ frag->base.des_cbfunc(&btl->super, frag->endpoint, &frag->base, OMPI_SUCCESS); /* return the send token and deque pending fragments */ MCA_BTL_GM_RETURN_TOKEN(btl); break; default: /* error condition can't deal with */ opal_output(0, "[%s:%d] gm_get operation failed with status %d\n", __FILE__, __LINE__, status); /* release the send token */ OPAL_THREAD_ADD32( &btl->gm_num_send_tokens, 1 ); /* call the completion callback */ frag->base.des_cbfunc(&btl->super, frag->endpoint, &frag->base, OMPI_ERROR); break; } } /** * Initiate an asynchronous get. * * @param btl (IN) BTL module * @param endpoint (IN) BTL addressing information * @param descriptor (IN) Description of the data to be transferred * */ int mca_btl_gm_get( mca_btl_base_module_t* btl, mca_btl_base_endpoint_t* endpoint, mca_btl_base_descriptor_t* des) { #if OMPI_MCA_BTL_GM_HAVE_RDMA_GET mca_btl_gm_module_t* gm_btl = (mca_btl_gm_module_t*) btl; mca_btl_gm_frag_t* frag = (mca_btl_gm_frag_t*) des; frag->btl = gm_btl; frag->endpoint = endpoint; frag->type = MCA_BTL_GM_GET; /* queue the descriptor if there are no send tokens */ MCA_BTL_GM_ACQUIRE_TOKEN(gm_btl, frag); /* post get put descriptor */ gm_get(gm_btl->port, des->des_dst->seg_addr.lval, des->des_src->seg_addr.pval, des->des_src->seg_len, GM_LOW_PRIORITY, endpoint->endpoint_addr.node_id, endpoint->endpoint_addr.port_id, mca_btl_gm_get_callback, frag); return OMPI_SUCCESS; #else return OMPI_ERR_NOT_IMPLEMENTED; #endif } /* * Cleanup/release module resources. */ int mca_btl_gm_finalize(struct mca_btl_base_module_t* btl) { mca_btl_gm_module_t* gm_btl = (mca_btl_gm_module_t*) btl; #if 0 if(gm_btl->gm_frag_eager.fl_num_allocated != gm_btl->gm_frag_eager.super.opal_list_length){ opal_output(0, "btl gm_frag_eager: %d allocated %d returned \n", gm_btl->gm_frag_eager.fl_num_allocated, gm_btl->gm_frag_eager.super.opal_list_length); } if(gm_btl->gm_frag_max.fl_num_allocated != gm_btl->gm_frag_max.super.opal_list_length) { opal_output(0, "btl gm_frag_max: %d allocated %d returned \n", gm_btl->gm_frag_max.fl_num_allocated, gm_btl->gm_frag_max.super.opal_list_length); } if(gm_btl->gm_frag_user.fl_num_allocated != gm_btl->gm_frag_user.super.opal_list_length){ opal_output(0, "btl gm_frag_user: %d allocated %d returned \n", gm_btl->gm_frag_user.fl_num_allocated, gm_btl->gm_frag_user.super.opal_list_length); } #endif OBJ_DESTRUCT(&gm_btl->gm_lock); OBJ_DESTRUCT(&gm_btl->gm_frag_eager); OBJ_DESTRUCT(&gm_btl->gm_frag_max); OBJ_DESTRUCT(&gm_btl->gm_frag_user); free(gm_btl); return OMPI_SUCCESS; }