/* StarPU --- Runtime system for heterogeneous multicore architectures. * * Copyright (C) 2009, 2010-2016 Université de Bordeaux * Copyright (C) 2010, 2011, 2012, 2013, 2014, 2015, 2016 CNRS * Copyright (C) 2016 Inria * * StarPU is free software; you can redistribute it and/or modify * it under the terms of the GNU Lesser General Public License as published by * the Free Software Foundation; either version 2.1 of the License, or (at * your option) any later version. * * StarPU is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. * * See the GNU Lesser General Public License in COPYING.LGPL for more details. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include static void _starpu_mpi_add_sync_point_in_fxt(void); static void _starpu_mpi_submit_ready_request(void *arg); static void _starpu_mpi_handle_ready_request(struct _starpu_mpi_req *req); static void _starpu_mpi_handle_request_termination(struct _starpu_mpi_req *req); #ifdef STARPU_VERBOSE static char *_starpu_mpi_request_type(enum _starpu_mpi_request_type request_type); #endif static struct _starpu_mpi_req *_starpu_mpi_isend_common(starpu_data_handle_t data_handle, int dest, int data_tag, MPI_Comm comm, unsigned detached, unsigned sync, void (*callback)(void *), void *arg, int sequential_consistency); static struct _starpu_mpi_req *_starpu_mpi_irecv_common(starpu_data_handle_t data_handle, int source, int data_tag, MPI_Comm comm, unsigned detached, unsigned sync, void (*callback)(void *), void *arg, int sequential_consistency, int is_internal_req, starpu_ssize_t count); static void _starpu_mpi_handle_detached_request(struct _starpu_mpi_req *req); static void _starpu_mpi_early_data_cb(void* arg); /* The list of ready requests */ static struct _starpu_mpi_req_list *ready_requests; /* The list of detached requests that have already been submitted to MPI */ static struct _starpu_mpi_req_list *detached_requests; static starpu_pthread_mutex_t detached_requests_mutex; /* Condition to wake up progression thread */ static starpu_pthread_cond_t progress_cond; /* Condition to wake up waiting for all current MPI requests to finish */ static starpu_pthread_cond_t barrier_cond; static starpu_pthread_mutex_t progress_mutex; #ifndef STARPU_SIMGRID static starpu_pthread_t progress_thread; #endif static int running = 0; #ifdef STARPU_SIMGRID static int _mpi_world_size; static int _mpi_world_rank; #endif /* Count requests posted by the application and not yet submitted to MPI */ static starpu_pthread_mutex_t mutex_posted_requests; static int posted_requests = 0, newer_requests, barrier_running = 0; #define _STARPU_MPI_INC_POSTED_REQUESTS(value) { STARPU_PTHREAD_MUTEX_LOCK(&mutex_posted_requests); posted_requests += value; STARPU_PTHREAD_MUTEX_UNLOCK(&mutex_posted_requests); } #pragma weak smpi_simulated_main_ extern int smpi_simulated_main_(int argc, char *argv[]); #ifdef HAVE_SMPI_PROCESS_SET_USER_DATA #if !HAVE_DECL_SMPI_PROCESS_SET_USER_DATA extern void smpi_process_set_user_data(void *); #endif #endif static void _starpu_mpi_request_init(struct _starpu_mpi_req **req) { *req = calloc(1, sizeof(struct _starpu_mpi_req)); STARPU_MPI_ASSERT_MSG(*req, "Invalid request"); /* Initialize the request structure */ (*req)->data_handle = NULL; (*req)->datatype = 0; (*req)->datatype_name = NULL; (*req)->ptr = NULL; (*req)->count = -1; (*req)->registered_datatype = -1; (*req)->node_tag.rank = -1; (*req)->node_tag.data_tag = -1; (*req)->node_tag.comm = 0; (*req)->func = NULL; (*req)->status = NULL; (*req)->data_request = 0; (*req)->flag = NULL; (*req)->ret = -1; STARPU_PTHREAD_MUTEX_INIT(&((*req)->req_mutex), NULL); STARPU_PTHREAD_COND_INIT(&((*req)->req_cond), NULL); STARPU_PTHREAD_MUTEX_INIT(&((*req)->posted_mutex), NULL); STARPU_PTHREAD_COND_INIT(&((*req)->posted_cond), NULL); (*req)->request_type = UNKNOWN_REQ; (*req)->submitted = 0; (*req)->completed = 0; (*req)->posted = 0; (*req)->other_request = NULL; (*req)->sync = 0; (*req)->detached = -1; (*req)->callback = NULL; (*req)->callback_arg = NULL; (*req)->size_req = 0; (*req)->internal_req = NULL; (*req)->is_internal_req = 0; (*req)->early_data_handle = NULL; (*req)->envelope = NULL; (*req)->sequential_consistency = 1; } static void _starpu_mpi_request_destroy(struct _starpu_mpi_req *req) { STARPU_PTHREAD_MUTEX_DESTROY(&req->req_mutex); STARPU_PTHREAD_COND_DESTROY(&req->req_cond); STARPU_PTHREAD_MUTEX_DESTROY(&req->posted_mutex); STARPU_PTHREAD_COND_DESTROY(&req->posted_cond); free(req->datatype_name); req->datatype_name = NULL; free(req); req = NULL; } /********************************************************/ /* */ /* Send/Receive functionalities */ /* */ /********************************************************/ struct _starpu_mpi_early_data_cb_args { starpu_data_handle_t data_handle; starpu_data_handle_t early_handle; struct _starpu_mpi_req *req; void *buffer; }; static void _starpu_mpi_submit_ready_request(void *arg) { _STARPU_MPI_LOG_IN(); struct _starpu_mpi_req *req = arg; _STARPU_MPI_INC_POSTED_REQUESTS(-1); _STARPU_MPI_DEBUG(3, "new req %p srcdst %d tag %d and type %s %d\n", req, req->node_tag.rank, req->node_tag.data_tag, _starpu_mpi_request_type(req->request_type), req->is_internal_req); STARPU_PTHREAD_MUTEX_LOCK(&progress_mutex); if (req->request_type == RECV_REQ) { /* Case : the request is the internal receive request submitted * by StarPU-MPI to receive incoming data without a matching * early_request from the application. We immediately allocate the * pointer associated to the data_handle, and push it into the * ready_requests list, so as the real MPI request can be submitted * before the next submission of the envelope-catching request. */ if (req->is_internal_req) { _starpu_mpi_handle_allocate_datatype(req->data_handle, req); if (req->registered_datatype == 1) { req->count = 1; req->ptr = starpu_data_get_local_ptr(req->data_handle); } else { STARPU_ASSERT(req->count); req->ptr = malloc(req->count); STARPU_MPI_ASSERT_MSG(req->ptr, "cannot allocate message of size %ld\n", req->count); } _STARPU_MPI_DEBUG(3, "Pushing internal starpu_mpi_irecv request %p type %s tag %d src %d data %p ptr %p datatype '%s' count %d registered_datatype %d \n", req, _starpu_mpi_request_type(req->request_type), req->node_tag.data_tag, req->node_tag.rank, req->data_handle, req->ptr, req->datatype_name, (int)req->count, req->registered_datatype); _starpu_mpi_req_list_push_front(ready_requests, req); /* inform the starpu mpi thread that the request has been pushed in the ready_requests list */ STARPU_PTHREAD_MUTEX_UNLOCK(&progress_mutex); STARPU_PTHREAD_MUTEX_LOCK(&req->posted_mutex); req->posted = 1; STARPU_PTHREAD_COND_BROADCAST(&req->posted_cond); STARPU_PTHREAD_MUTEX_UNLOCK(&req->posted_mutex); STARPU_PTHREAD_MUTEX_LOCK(&progress_mutex); } else { /* test whether some data with the given tag and source have already been received by StarPU-MPI*/ struct _starpu_mpi_early_data_handle *early_data_handle = _starpu_mpi_early_data_find(&req->node_tag); /* Case: a receive request for a data with the given tag and source has already been * posted by StarPU. Asynchronously requests a Read permission over the temporary handle , * so as when the internal receive is completed, the _starpu_mpi_early_data_cb function * will be called to bring the data back to the original data handle associated to the request.*/ if (early_data_handle) { STARPU_PTHREAD_MUTEX_UNLOCK(&progress_mutex); STARPU_PTHREAD_MUTEX_LOCK(&(early_data_handle->req_mutex)); while (!(early_data_handle->req_ready)) STARPU_PTHREAD_COND_WAIT(&(early_data_handle->req_cond), &(early_data_handle->req_mutex)); STARPU_PTHREAD_MUTEX_UNLOCK(&(early_data_handle->req_mutex)); STARPU_PTHREAD_MUTEX_LOCK(&progress_mutex); _STARPU_MPI_DEBUG(3, "The RECV request %p with tag %d has already been received, copying previously received data into handle's pointer..\n", req, req->node_tag.data_tag); STARPU_ASSERT(req->data_handle != early_data_handle->handle); req->internal_req = early_data_handle->req; req->early_data_handle = early_data_handle; struct _starpu_mpi_early_data_cb_args *cb_args = malloc(sizeof(struct _starpu_mpi_early_data_cb_args)); cb_args->data_handle = req->data_handle; cb_args->early_handle = early_data_handle->handle; cb_args->buffer = early_data_handle->buffer; cb_args->req = req; _STARPU_MPI_DEBUG(3, "Calling data_acquire_cb on starpu_mpi_copy_cb..\n"); starpu_data_acquire_cb(early_data_handle->handle,STARPU_R,_starpu_mpi_early_data_cb,(void*) cb_args); } /* Case: no matching data has been received. Store the receive request as an early_request. */ else { struct _starpu_mpi_req *sync_req = _starpu_mpi_sync_data_find(req->node_tag.data_tag, req->node_tag.rank, req->node_tag.comm); _STARPU_MPI_DEBUG(3, "----------> Looking for sync data for tag %d and src %d = %p\n", req->node_tag.data_tag, req->node_tag.rank, sync_req); if (sync_req) { req->sync = 1; _starpu_mpi_handle_allocate_datatype(req->data_handle, req); if (req->registered_datatype == 1) { req->count = 1; req->ptr = starpu_data_get_local_ptr(req->data_handle); } else { req->count = sync_req->count; STARPU_ASSERT(req->count); req->ptr = malloc(req->count); STARPU_MPI_ASSERT_MSG(req->ptr, "cannot allocate message of size %ld\n", req->count); } _starpu_mpi_req_list_push_front(ready_requests, req); _starpu_mpi_request_destroy(sync_req); } else { _STARPU_MPI_DEBUG(3, "Adding the pending receive request %p (srcdst %d tag %d) into the request hashmap\n", req, req->node_tag.rank, req->node_tag.data_tag); _starpu_mpi_early_request_enqueue(req); } } } } else { _starpu_mpi_req_list_push_front(ready_requests, req); _STARPU_MPI_DEBUG(3, "Pushing new request %p type %s tag %d src %d data %p ptr %p datatype '%s' count %d registered_datatype %d \n", req, _starpu_mpi_request_type(req->request_type), req->node_tag.data_tag, req->node_tag.rank, req->data_handle, req->ptr, req->datatype_name, (int)req->count, req->registered_datatype); } newer_requests = 1; STARPU_PTHREAD_COND_BROADCAST(&progress_cond); STARPU_PTHREAD_MUTEX_UNLOCK(&progress_mutex); _STARPU_MPI_LOG_OUT(); } static struct _starpu_mpi_req *_starpu_mpi_isend_irecv_common(starpu_data_handle_t data_handle, int srcdst, int data_tag, MPI_Comm comm, unsigned detached, unsigned sync, void (*callback)(void *), void *arg, enum _starpu_mpi_request_type request_type, void (*func)(struct _starpu_mpi_req *), enum starpu_data_access_mode mode, int sequential_consistency, int is_internal_req, starpu_ssize_t count) { struct _starpu_mpi_req *req; _STARPU_MPI_LOG_IN(); _STARPU_MPI_INC_POSTED_REQUESTS(1); _starpu_mpi_comm_register(comm); /* Initialize the request structure */ _starpu_mpi_request_init(&req); req->request_type = request_type; req->data_handle = data_handle; req->node_tag.rank = srcdst; req->node_tag.data_tag = data_tag; req->node_tag.comm = comm; req->detached = detached; req->sync = sync; req->callback = callback; req->callback_arg = arg; req->func = func; req->sequential_consistency = sequential_consistency; req->is_internal_req = is_internal_req; req->count = count; /* Asynchronously request StarPU to fetch the data in main memory: when * it is available in main memory, _starpu_mpi_submit_ready_request(req) is called and * the request is actually submitted */ starpu_data_acquire_cb_sequential_consistency(data_handle, mode, _starpu_mpi_submit_ready_request, (void *)req, sequential_consistency); _STARPU_MPI_LOG_OUT(); return req; } /********************************************************/ /* */ /* Send functionalities */ /* */ /********************************************************/ static void _starpu_mpi_isend_data_func(struct _starpu_mpi_req *req) { _STARPU_MPI_LOG_IN(); _STARPU_MPI_DEBUG(30, "post MPI isend request %p type %s tag %d src %d data %p datasize %ld ptr %p datatype '%s' count %d registered_datatype %d sync %d\n", req, _starpu_mpi_request_type(req->request_type), req->node_tag.data_tag, req->node_tag.rank, req->data_handle, starpu_data_get_size(req->data_handle), req->ptr, req->datatype_name, (int)req->count, req->registered_datatype, req->sync); _starpu_mpi_comm_amounts_inc(req->node_tag.comm, req->node_tag.rank, req->datatype, req->count); _STARPU_MPI_TRACE_ISEND_SUBMIT_BEGIN(req->node_tag.rank, req->node_tag.data_tag, 0); if (req->sync == 0) { _STARPU_MPI_COMM_TO_DEBUG(req->count, req->datatype, req->node_tag.rank, _STARPU_MPI_TAG_DATA, req->node_tag.data_tag, req->node_tag.comm); req->ret = MPI_Isend(req->ptr, req->count, req->datatype, req->node_tag.rank, _STARPU_MPI_TAG_DATA, req->node_tag.comm, &req->data_request); STARPU_MPI_ASSERT_MSG(req->ret == MPI_SUCCESS, "MPI_Isend returning %s", _starpu_mpi_get_mpi_error_code(req->ret)); } else { _STARPU_MPI_COMM_TO_DEBUG(req->count, req->datatype, req->node_tag.rank, _STARPU_MPI_TAG_SYNC_DATA, req->node_tag.data_tag, req->node_tag.comm); req->ret = MPI_Issend(req->ptr, req->count, req->datatype, req->node_tag.rank, _STARPU_MPI_TAG_SYNC_DATA, req->node_tag.comm, &req->data_request); STARPU_MPI_ASSERT_MSG(req->ret == MPI_SUCCESS, "MPI_Issend returning %s", _starpu_mpi_get_mpi_error_code(req->ret)); } _STARPU_MPI_TRACE_ISEND_SUBMIT_END(req->node_tag.rank, req->node_tag.data_tag, 0); /* somebody is perhaps waiting for the MPI request to be posted */ STARPU_PTHREAD_MUTEX_LOCK(&req->req_mutex); req->submitted = 1; STARPU_PTHREAD_COND_BROADCAST(&req->req_cond); STARPU_PTHREAD_MUTEX_UNLOCK(&req->req_mutex); _starpu_mpi_handle_detached_request(req); _STARPU_MPI_LOG_OUT(); } static void _starpu_mpi_isend_size_func(struct _starpu_mpi_req *req) { _starpu_mpi_handle_allocate_datatype(req->data_handle, req); req->envelope = calloc(1,sizeof(struct _starpu_mpi_envelope)); req->envelope->mode = _STARPU_MPI_ENVELOPE_DATA; req->envelope->data_tag = req->node_tag.data_tag; req->envelope->sync = req->sync; if (req->registered_datatype == 1) { int size; req->count = 1; req->ptr = starpu_data_get_local_ptr(req->data_handle); MPI_Type_size(req->datatype, &size); req->envelope->size = (starpu_ssize_t)req->count * size; _STARPU_MPI_DEBUG(20, "Post MPI isend count (%ld) datatype_size %ld request to %d\n",req->count,starpu_data_get_size(req->data_handle), req->node_tag.rank); _STARPU_MPI_COMM_TO_DEBUG(sizeof(struct _starpu_mpi_envelope), MPI_BYTE, req->node_tag.rank, _STARPU_MPI_TAG_ENVELOPE, _STARPU_MPI_TAG_ENVELOPE, req->node_tag.comm); MPI_Isend(req->envelope, sizeof(struct _starpu_mpi_envelope), MPI_BYTE, req->node_tag.rank, _STARPU_MPI_TAG_ENVELOPE, req->node_tag.comm, &req->size_req); } else { int ret; // Do not pack the data, just try to find out the size starpu_data_pack(req->data_handle, NULL, &(req->envelope->size)); if (req->envelope->size != -1) { // We already know the size of the data, let's send it to overlap with the packing of the data _STARPU_MPI_DEBUG(20, "Sending size %ld (%ld %s) to node %d (first call to pack)\n", req->envelope->size, sizeof(req->count), "MPI_BYTE", req->node_tag.rank); req->count = req->envelope->size; _STARPU_MPI_COMM_TO_DEBUG(sizeof(struct _starpu_mpi_envelope), MPI_BYTE, req->node_tag.rank, _STARPU_MPI_TAG_ENVELOPE, _STARPU_MPI_TAG_ENVELOPE, req->node_tag.comm); ret = MPI_Isend(req->envelope, sizeof(struct _starpu_mpi_envelope), MPI_BYTE, req->node_tag.rank, _STARPU_MPI_TAG_ENVELOPE, req->node_tag.comm, &req->size_req); STARPU_MPI_ASSERT_MSG(ret == MPI_SUCCESS, "when sending size, MPI_Isend returning %s", _starpu_mpi_get_mpi_error_code(ret)); } // Pack the data starpu_data_pack(req->data_handle, &req->ptr, &req->count); if (req->envelope->size == -1) { // We know the size now, let's send it _STARPU_MPI_DEBUG(20, "Sending size %ld (%ld %s) to node %d (second call to pack)\n", req->envelope->size, sizeof(req->count), "MPI_BYTE", req->node_tag.rank); _STARPU_MPI_COMM_TO_DEBUG(sizeof(struct _starpu_mpi_envelope), MPI_BYTE, req->node_tag.rank, _STARPU_MPI_TAG_ENVELOPE, _STARPU_MPI_TAG_ENVELOPE, req->node_tag.comm); ret = MPI_Isend(req->envelope, sizeof(struct _starpu_mpi_envelope), MPI_BYTE, req->node_tag.rank, _STARPU_MPI_TAG_ENVELOPE, req->node_tag.comm, &req->size_req); STARPU_MPI_ASSERT_MSG(ret == MPI_SUCCESS, "when sending size, MPI_Isend returning %s", _starpu_mpi_get_mpi_error_code(ret)); } else { // We check the size returned with the 2 calls to pack is the same STARPU_MPI_ASSERT_MSG(req->count == req->envelope->size, "Calls to pack_data returned different sizes %ld != %ld", req->count, req->envelope->size); } // We can send the data now } if (req->sync) { // If the data is to be sent in synchronous mode, we need to wait for the receiver ready message _starpu_mpi_sync_data_add(req); } else { // Otherwise we can send the data _starpu_mpi_isend_data_func(req); } } static struct _starpu_mpi_req *_starpu_mpi_isend_common(starpu_data_handle_t data_handle, int dest, int data_tag, MPI_Comm comm, unsigned detached, unsigned sync, void (*callback)(void *), void *arg, int sequential_consistency) { return _starpu_mpi_isend_irecv_common(data_handle, dest, data_tag, comm, detached, sync, callback, arg, SEND_REQ, _starpu_mpi_isend_size_func, STARPU_R, sequential_consistency, 0, 0); } int starpu_mpi_isend(starpu_data_handle_t data_handle, starpu_mpi_req *public_req, int dest, int data_tag, MPI_Comm comm) { _STARPU_MPI_LOG_IN(); STARPU_MPI_ASSERT_MSG(public_req, "starpu_mpi_isend needs a valid starpu_mpi_req"); struct _starpu_mpi_req *req; _STARPU_MPI_TRACE_ISEND_COMPLETE_BEGIN(dest, data_tag, 0); req = _starpu_mpi_isend_common(data_handle, dest, data_tag, comm, 0, 0, NULL, NULL, 1); _STARPU_MPI_TRACE_ISEND_COMPLETE_END(dest, data_tag, 0); STARPU_MPI_ASSERT_MSG(req, "Invalid return for _starpu_mpi_isend_common"); *public_req = req; _STARPU_MPI_LOG_OUT(); return 0; } int starpu_mpi_isend_detached(starpu_data_handle_t data_handle, int dest, int data_tag, MPI_Comm comm, void (*callback)(void *), void *arg) { _STARPU_MPI_LOG_IN(); _starpu_mpi_isend_common(data_handle, dest, data_tag, comm, 1, 0, callback, arg, 1); _STARPU_MPI_LOG_OUT(); return 0; } int starpu_mpi_send(starpu_data_handle_t data_handle, int dest, int data_tag, MPI_Comm comm) { starpu_mpi_req req; MPI_Status status; _STARPU_MPI_LOG_IN(); memset(&status, 0, sizeof(MPI_Status)); starpu_mpi_isend(data_handle, &req, dest, data_tag, comm); starpu_mpi_wait(&req, &status); _STARPU_MPI_LOG_OUT(); return 0; } int starpu_mpi_issend(starpu_data_handle_t data_handle, starpu_mpi_req *public_req, int dest, int data_tag, MPI_Comm comm) { _STARPU_MPI_LOG_IN(); STARPU_MPI_ASSERT_MSG(public_req, "starpu_mpi_issend needs a valid starpu_mpi_req"); struct _starpu_mpi_req *req; req = _starpu_mpi_isend_common(data_handle, dest, data_tag, comm, 0, 1, NULL, NULL, 1); STARPU_MPI_ASSERT_MSG(req, "Invalid return for _starpu_mpi_isend_common"); *public_req = req; _STARPU_MPI_LOG_OUT(); return 0; } int starpu_mpi_issend_detached(starpu_data_handle_t data_handle, int dest, int data_tag, MPI_Comm comm, void (*callback)(void *), void *arg) { _STARPU_MPI_LOG_IN(); _starpu_mpi_isend_common(data_handle, dest, data_tag, comm, 1, 1, callback, arg, 1); _STARPU_MPI_LOG_OUT(); return 0; } /********************************************************/ /* */ /* receive functionalities */ /* */ /********************************************************/ static void _starpu_mpi_irecv_data_func(struct _starpu_mpi_req *req) { _STARPU_MPI_LOG_IN(); _STARPU_MPI_DEBUG(20, "post MPI irecv request %p type %s tag %d src %d data %p ptr %p datatype '%s' count %d registered_datatype %d \n", req, _starpu_mpi_request_type(req->request_type), req->node_tag.data_tag, req->node_tag.rank, req->data_handle, req->ptr, req->datatype_name, (int)req->count, req->registered_datatype); _STARPU_MPI_TRACE_IRECV_SUBMIT_BEGIN(req->node_tag.rank, req->node_tag.data_tag); if (req->sync) { struct _starpu_mpi_envelope *_envelope = calloc(1,sizeof(struct _starpu_mpi_envelope)); _envelope->mode = _STARPU_MPI_ENVELOPE_SYNC_READY; _envelope->data_tag = req->node_tag.data_tag; _STARPU_MPI_DEBUG(20, "Telling node %d it can send the data and waiting for the data back ...\n", req->node_tag.rank); _STARPU_MPI_COMM_TO_DEBUG(sizeof(struct _starpu_mpi_envelope), MPI_BYTE, req->node_tag.rank, _STARPU_MPI_TAG_ENVELOPE, _STARPU_MPI_TAG_ENVELOPE, req->node_tag.comm); req->ret = MPI_Send(_envelope, sizeof(struct _starpu_mpi_envelope), MPI_BYTE, req->node_tag.rank, _STARPU_MPI_TAG_ENVELOPE, req->node_tag.comm); STARPU_MPI_ASSERT_MSG(req->ret == MPI_SUCCESS, "MPI_Send returning %s", _starpu_mpi_get_mpi_error_code(req->ret)); free(_envelope); _envelope = NULL; } if (req->sync) { _STARPU_MPI_COMM_FROM_DEBUG(req->count, req->datatype, req->node_tag.rank, _STARPU_MPI_TAG_SYNC_DATA, req->node_tag.data_tag, req->node_tag.comm); req->ret = MPI_Irecv(req->ptr, req->count, req->datatype, req->node_tag.rank, _STARPU_MPI_TAG_SYNC_DATA, req->node_tag.comm, &req->data_request); } else { _STARPU_MPI_COMM_FROM_DEBUG(req->count, req->datatype, req->node_tag.rank, _STARPU_MPI_TAG_DATA, req->node_tag.data_tag, req->node_tag.comm); req->ret = MPI_Irecv(req->ptr, req->count, req->datatype, req->node_tag.rank, _STARPU_MPI_TAG_DATA, req->node_tag.comm, &req->data_request); } STARPU_MPI_ASSERT_MSG(req->ret == MPI_SUCCESS, "MPI_IRecv returning %s", _starpu_mpi_get_mpi_error_code(req->ret)); _STARPU_MPI_TRACE_IRECV_SUBMIT_END(req->node_tag.rank, req->node_tag.data_tag); /* somebody is perhaps waiting for the MPI request to be posted */ STARPU_PTHREAD_MUTEX_LOCK(&req->req_mutex); req->submitted = 1; STARPU_PTHREAD_COND_BROADCAST(&req->req_cond); STARPU_PTHREAD_MUTEX_UNLOCK(&req->req_mutex); _starpu_mpi_handle_detached_request(req); _STARPU_MPI_LOG_OUT(); } static struct _starpu_mpi_req *_starpu_mpi_irecv_common(starpu_data_handle_t data_handle, int source, int data_tag, MPI_Comm comm, unsigned detached, unsigned sync, void (*callback)(void *), void *arg, int sequential_consistency, int is_internal_req, starpu_ssize_t count) { return _starpu_mpi_isend_irecv_common(data_handle, source, data_tag, comm, detached, sync, callback, arg, RECV_REQ, _starpu_mpi_irecv_data_func, STARPU_W, sequential_consistency, is_internal_req, count); } int starpu_mpi_irecv(starpu_data_handle_t data_handle, starpu_mpi_req *public_req, int source, int data_tag, MPI_Comm comm) { _STARPU_MPI_LOG_IN(); STARPU_MPI_ASSERT_MSG(public_req, "starpu_mpi_irecv needs a valid starpu_mpi_req"); // // We check if a tag is defined for the data handle, if not, // // we define the one given for the communication. // // A tag is necessary for the internal mpi engine. // int tag = starpu_data_get_tag(data_handle); // if (tag == -1) // starpu_data_set_tag(data_handle, data_tag); struct _starpu_mpi_req *req; _STARPU_MPI_TRACE_IRECV_COMPLETE_BEGIN(source, data_tag); req = _starpu_mpi_irecv_common(data_handle, source, data_tag, comm, 0, 0, NULL, NULL, 1, 0, 0); _STARPU_MPI_TRACE_IRECV_COMPLETE_END(source, data_tag); STARPU_MPI_ASSERT_MSG(req, "Invalid return for _starpu_mpi_irecv_common"); *public_req = req; _STARPU_MPI_LOG_OUT(); return 0; } int starpu_mpi_irecv_detached(starpu_data_handle_t data_handle, int source, int data_tag, MPI_Comm comm, void (*callback)(void *), void *arg) { _STARPU_MPI_LOG_IN(); // // We check if a tag is defined for the data handle, if not, // // we define the one given for the communication. // // A tag is necessary for the internal mpi engine. // int tag = starpu_data_get_tag(data_handle); // if (tag == -1) // starpu_data_set_tag(data_handle, data_tag); _starpu_mpi_irecv_common(data_handle, source, data_tag, comm, 1, 0, callback, arg, 1, 0, 0); _STARPU_MPI_LOG_OUT(); return 0; } int starpu_mpi_irecv_detached_sequential_consistency(starpu_data_handle_t data_handle, int source, int data_tag, MPI_Comm comm, void (*callback)(void *), void *arg, int sequential_consistency) { _STARPU_MPI_LOG_IN(); // // We check if a tag is defined for the data handle, if not, // // we define the one given for the communication. // // A tag is necessary for the internal mpi engine. // int tag = starpu_data_get_tag(data_handle); // if (tag == -1) // starpu_data_set_tag(data_handle, data_tag); _starpu_mpi_irecv_common(data_handle, source, data_tag, comm, 1, 0, callback, arg, sequential_consistency, 0, 0); _STARPU_MPI_LOG_OUT(); return 0; } int starpu_mpi_recv(starpu_data_handle_t data_handle, int source, int data_tag, MPI_Comm comm, MPI_Status *status) { starpu_mpi_req req; _STARPU_MPI_LOG_IN(); // // We check if a tag is defined for the data handle, if not, // // we define the one given for the communication. // // A tag is necessary for the internal mpi engine. // int tag = starpu_data_get_tag(data_handle); // if (tag == -1) // starpu_data_set_tag(data_handle, data_tag); starpu_mpi_irecv(data_handle, &req, source, data_tag, comm); starpu_mpi_wait(&req, status); _STARPU_MPI_LOG_OUT(); return 0; } /********************************************************/ /* */ /* Wait functionalities */ /* */ /********************************************************/ static void _starpu_mpi_wait_func(struct _starpu_mpi_req *waiting_req) { _STARPU_MPI_LOG_IN(); /* Which is the mpi request we are waiting for ? */ struct _starpu_mpi_req *req = waiting_req->other_request; _STARPU_MPI_TRACE_UWAIT_BEGIN(req->node_tag.rank, req->node_tag.data_tag); if (req->data_request != MPI_REQUEST_NULL) { req->ret = MPI_Wait(&req->data_request, waiting_req->status); STARPU_MPI_ASSERT_MSG(req->ret == MPI_SUCCESS, "MPI_Wait returning %s", _starpu_mpi_get_mpi_error_code(req->ret)); } _STARPU_MPI_TRACE_UWAIT_END(req->node_tag.rank, req->node_tag.data_tag); _starpu_mpi_handle_request_termination(req); _STARPU_MPI_LOG_OUT(); } int starpu_mpi_wait(starpu_mpi_req *public_req, MPI_Status *status) { int ret; struct _starpu_mpi_req *req = *public_req; struct _starpu_mpi_req *waiting_req; _STARPU_MPI_LOG_IN(); _STARPU_MPI_INC_POSTED_REQUESTS(1); /* We cannot try to complete a MPI request that was not actually posted * to MPI yet. */ STARPU_PTHREAD_MUTEX_LOCK(&(req->req_mutex)); while (!(req->submitted)) STARPU_PTHREAD_COND_WAIT(&(req->req_cond), &(req->req_mutex)); STARPU_PTHREAD_MUTEX_UNLOCK(&(req->req_mutex)); /* Initialize the request structure */ _starpu_mpi_request_init(&waiting_req); waiting_req->status = status; waiting_req->other_request = req; waiting_req->func = _starpu_mpi_wait_func; waiting_req->request_type = WAIT_REQ; _starpu_mpi_submit_ready_request(waiting_req); /* We wait for the MPI request to finish */ STARPU_PTHREAD_MUTEX_LOCK(&req->req_mutex); while (!req->completed) STARPU_PTHREAD_COND_WAIT(&req->req_cond, &req->req_mutex); STARPU_PTHREAD_MUTEX_UNLOCK(&req->req_mutex); ret = req->ret; /* The internal request structure was automatically allocated */ *public_req = NULL; if (req->internal_req) { _starpu_mpi_request_destroy(req->internal_req); } _starpu_mpi_request_destroy(req); _starpu_mpi_request_destroy(waiting_req); _STARPU_MPI_LOG_OUT(); return ret; } /********************************************************/ /* */ /* Test functionalities */ /* */ /********************************************************/ static void _starpu_mpi_test_func(struct _starpu_mpi_req *testing_req) { _STARPU_MPI_LOG_IN(); /* Which is the mpi request we are testing for ? */ struct _starpu_mpi_req *req = testing_req->other_request; _STARPU_MPI_DEBUG(2, "Test request %p type %s tag %d src %d data %p ptr %p datatype '%s' count %d registered_datatype %d \n", req, _starpu_mpi_request_type(req->request_type), req->node_tag.data_tag, req->node_tag.rank, req->data_handle, req->ptr, req->datatype_name, (int)req->count, req->registered_datatype); _STARPU_MPI_TRACE_UTESTING_BEGIN(req->node_tag.rank, req->node_tag.data_tag); req->ret = MPI_Test(&req->data_request, testing_req->flag, testing_req->status); STARPU_MPI_ASSERT_MSG(req->ret == MPI_SUCCESS, "MPI_Test returning %s", _starpu_mpi_get_mpi_error_code(req->ret)); _STARPU_MPI_TRACE_UTESTING_END(req->node_tag.rank, req->node_tag.data_tag); if (*testing_req->flag) { testing_req->ret = req->ret; _starpu_mpi_handle_request_termination(req); } STARPU_PTHREAD_MUTEX_LOCK(&testing_req->req_mutex); testing_req->completed = 1; STARPU_PTHREAD_COND_SIGNAL(&testing_req->req_cond); STARPU_PTHREAD_MUTEX_UNLOCK(&testing_req->req_mutex); _STARPU_MPI_LOG_OUT(); } int starpu_mpi_test(starpu_mpi_req *public_req, int *flag, MPI_Status *status) { _STARPU_MPI_LOG_IN(); int ret = 0; STARPU_MPI_ASSERT_MSG(public_req, "starpu_mpi_test needs a valid starpu_mpi_req"); struct _starpu_mpi_req *req = *public_req; STARPU_MPI_ASSERT_MSG(!req->detached, "MPI_Test cannot be called on a detached request"); STARPU_PTHREAD_MUTEX_LOCK(&req->req_mutex); unsigned submitted = req->submitted; STARPU_PTHREAD_MUTEX_UNLOCK(&req->req_mutex); if (submitted) { struct _starpu_mpi_req *testing_req; /* Initialize the request structure */ _starpu_mpi_request_init(&testing_req); testing_req->flag = flag; testing_req->status = status; testing_req->other_request = req; testing_req->func = _starpu_mpi_test_func; testing_req->completed = 0; testing_req->request_type = TEST_REQ; _STARPU_MPI_INC_POSTED_REQUESTS(1); _starpu_mpi_submit_ready_request(testing_req); /* We wait for the test request to finish */ STARPU_PTHREAD_MUTEX_LOCK(&(testing_req->req_mutex)); while (!(testing_req->completed)) STARPU_PTHREAD_COND_WAIT(&(testing_req->req_cond), &(testing_req->req_mutex)); STARPU_PTHREAD_MUTEX_UNLOCK(&(testing_req->req_mutex)); ret = testing_req->ret; if (*(testing_req->flag)) { /* The request was completed so we free the internal * request structure which was automatically allocated * */ *public_req = NULL; if (req->internal_req) { _starpu_mpi_request_destroy(req->internal_req); } _starpu_mpi_request_destroy(req); } _starpu_mpi_request_destroy(testing_req); } else { *flag = 0; } _STARPU_MPI_LOG_OUT(); return ret; } /********************************************************/ /* */ /* Barrier functionalities */ /* */ /********************************************************/ static void _starpu_mpi_barrier_func(struct _starpu_mpi_req *barrier_req) { _STARPU_MPI_LOG_IN(); barrier_req->ret = MPI_Barrier(barrier_req->node_tag.comm); STARPU_MPI_ASSERT_MSG(barrier_req->ret == MPI_SUCCESS, "MPI_Barrier returning %s", _starpu_mpi_get_mpi_error_code(barrier_req->ret)); _starpu_mpi_handle_request_termination(barrier_req); _STARPU_MPI_LOG_OUT(); } int _starpu_mpi_barrier(MPI_Comm comm) { _STARPU_MPI_LOG_IN(); int ret = posted_requests; struct _starpu_mpi_req *barrier_req; /* First wait for *both* all tasks and MPI requests to finish, in case * some tasks generate MPI requests, MPI requests generate tasks, etc. */ STARPU_PTHREAD_MUTEX_LOCK(&progress_mutex); STARPU_MPI_ASSERT_MSG(!barrier_running, "Concurrent starpu_mpi_barrier is not implemented, even on different communicators"); barrier_running = 1; do { while (posted_requests) /* Wait for all current MPI requests to finish */ STARPU_PTHREAD_COND_WAIT(&barrier_cond, &progress_mutex); /* No current request, clear flag */ newer_requests = 0; STARPU_PTHREAD_MUTEX_UNLOCK(&progress_mutex); /* Now wait for all tasks */ starpu_task_wait_for_all(); STARPU_PTHREAD_MUTEX_LOCK(&progress_mutex); /* Check newer_requests again, in case some MPI requests * triggered by tasks completed and triggered tasks between * wait_for_all finished and we take the lock */ } while (posted_requests || newer_requests); barrier_running = 0; STARPU_PTHREAD_MUTEX_UNLOCK(&progress_mutex); /* Initialize the request structure */ _starpu_mpi_request_init(&barrier_req); barrier_req->func = _starpu_mpi_barrier_func; barrier_req->request_type = BARRIER_REQ; barrier_req->node_tag.comm = comm; _STARPU_MPI_INC_POSTED_REQUESTS(1); _starpu_mpi_submit_ready_request(barrier_req); /* We wait for the MPI request to finish */ STARPU_PTHREAD_MUTEX_LOCK(&barrier_req->req_mutex); while (!barrier_req->completed) STARPU_PTHREAD_COND_WAIT(&barrier_req->req_cond, &barrier_req->req_mutex); STARPU_PTHREAD_MUTEX_UNLOCK(&barrier_req->req_mutex); _starpu_mpi_request_destroy(barrier_req); _STARPU_MPI_LOG_OUT(); return ret; } int starpu_mpi_barrier(MPI_Comm comm) { _starpu_mpi_barrier(comm); return 0; } /********************************************************/ /* */ /* Progression */ /* */ /********************************************************/ #ifdef STARPU_VERBOSE static char *_starpu_mpi_request_type(enum _starpu_mpi_request_type request_type) { switch (request_type) { case SEND_REQ: return "SEND_REQ"; case RECV_REQ: return "RECV_REQ"; case WAIT_REQ: return "WAIT_REQ"; case TEST_REQ: return "TEST_REQ"; case BARRIER_REQ: return "BARRIER_REQ"; case UNKNOWN_REQ: return "UNSET_REQ"; default: return "unknown request type"; } } #endif static void _starpu_mpi_handle_request_termination(struct _starpu_mpi_req *req) { _STARPU_MPI_LOG_IN(); _STARPU_MPI_DEBUG(2, "complete MPI request %p type %s tag %d src %d data %p ptr %p datatype '%s' count %d registered_datatype %d internal_req %p\n", req, _starpu_mpi_request_type(req->request_type), req->node_tag.data_tag, req->node_tag.rank, req->data_handle, req->ptr, req->datatype_name, (int)req->count, req->registered_datatype, req->internal_req); if (req->internal_req) { free(req->early_data_handle); req->early_data_handle = NULL; } else { if (req->request_type == RECV_REQ || req->request_type == SEND_REQ) { if (req->registered_datatype == 0) { if (req->request_type == SEND_REQ) { // We need to make sure the communication for sending the size // has completed, as MPI can re-order messages, let's call // MPI_Wait to make sure data have been sent int ret; ret = MPI_Wait(&req->size_req, MPI_STATUS_IGNORE); STARPU_MPI_ASSERT_MSG(ret == MPI_SUCCESS, "MPI_Wait returning %s", _starpu_mpi_get_mpi_error_code(ret)); free(req->ptr); req->ptr = NULL; } else if (req->request_type == RECV_REQ) { // req->ptr is freed by starpu_data_unpack starpu_data_unpack(req->data_handle, req->ptr, req->count); } } else { _starpu_mpi_handle_free_datatype(req->data_handle, &req->datatype); } } } if (req->data_handle) starpu_data_release(req->data_handle); if (req->envelope) { free(req->envelope); req->envelope = NULL; } /* Execute the specified callback, if any */ if (req->callback) req->callback(req->callback_arg); /* tell anyone potentially waiting on the request that it is * terminated now */ STARPU_PTHREAD_MUTEX_LOCK(&req->req_mutex); req->completed = 1; STARPU_PTHREAD_COND_BROADCAST(&req->req_cond); STARPU_PTHREAD_MUTEX_UNLOCK(&req->req_mutex); _STARPU_MPI_LOG_OUT(); } static void _starpu_mpi_early_data_cb(void* arg) { struct _starpu_mpi_early_data_cb_args *args = arg; if (args->buffer) { /* Data has been received as a raw memory, it has to be unpacked */ struct starpu_data_interface_ops *itf_src = starpu_data_get_interface_ops(args->early_handle); struct starpu_data_interface_ops *itf_dst = starpu_data_get_interface_ops(args->data_handle); STARPU_MPI_ASSERT_MSG(itf_dst->unpack_data, "The data interface does not define an unpack function\n"); itf_dst->unpack_data(args->data_handle, STARPU_MAIN_RAM, args->buffer, itf_src->get_size(args->early_handle)); free(args->buffer); args->buffer = NULL; } else { struct starpu_data_interface_ops *itf = starpu_data_get_interface_ops(args->early_handle); void* itf_src = starpu_data_get_interface_on_node(args->early_handle, STARPU_MAIN_RAM); void* itf_dst = starpu_data_get_interface_on_node(args->data_handle, STARPU_MAIN_RAM); if (!itf->copy_methods->ram_to_ram) { _STARPU_MPI_DEBUG(3, "Initiating any_to_any copy..\n"); itf->copy_methods->any_to_any(itf_src, STARPU_MAIN_RAM, itf_dst, STARPU_MAIN_RAM, NULL); } else { _STARPU_MPI_DEBUG(3, "Initiating ram_to_ram copy..\n"); itf->copy_methods->ram_to_ram(itf_src, STARPU_MAIN_RAM, itf_dst, STARPU_MAIN_RAM); } } _STARPU_MPI_DEBUG(3, "Done, handling release of early_handle..\n"); starpu_data_release(args->early_handle); _STARPU_MPI_DEBUG(3, "Done, handling unregister of early_handle..\n"); starpu_data_unregister_submit(args->early_handle); _STARPU_MPI_DEBUG(3, "Done, handling request %p termination of the already received request\n",args->req); // If the request is detached, we need to call _starpu_mpi_handle_request_termination // as it will not be called automatically as the request is not in the list detached_requests if (args->req) { if (args->req->detached) { _starpu_mpi_handle_request_termination(args->req); _starpu_mpi_request_destroy(args->req); } else { // else: If the request is not detached its termination will // be handled when calling starpu_mpi_wait // We store in the application request the internal MPI // request so that it can be used by starpu_mpi_wait args->req->data_request = args->req->internal_req->data_request; STARPU_PTHREAD_MUTEX_LOCK(&args->req->req_mutex); args->req->submitted = 1; STARPU_PTHREAD_COND_BROADCAST(&args->req->req_cond); STARPU_PTHREAD_MUTEX_UNLOCK(&args->req->req_mutex); } } free(args); args = NULL; } static void _starpu_mpi_test_detached_requests(void) { //_STARPU_MPI_LOG_IN(); int flag; MPI_Status status; struct _starpu_mpi_req *req; STARPU_PTHREAD_MUTEX_LOCK(&detached_requests_mutex); req = _starpu_mpi_req_list_begin(detached_requests); while (req != _starpu_mpi_req_list_end(detached_requests)) { STARPU_PTHREAD_MUTEX_UNLOCK(&detached_requests_mutex); //_STARPU_MPI_DEBUG(3, "Test detached request %p - mpitag %d - TYPE %s %d\n", &req->data_request, req->node_tag.data_tag, _starpu_mpi_request_type(req->request_type), req->node_tag.rank); req->ret = MPI_Test(&req->data_request, &flag, &status); STARPU_MPI_ASSERT_MSG(req->ret == MPI_SUCCESS, "MPI_Test returning %s", _starpu_mpi_get_mpi_error_code(req->ret)); if (!flag) { req = _starpu_mpi_req_list_next(req); } else { struct _starpu_mpi_req *next_req; next_req = _starpu_mpi_req_list_next(req); _STARPU_MPI_TRACE_COMPLETE_BEGIN(req->request_type, req->node_tag.rank, req->node_tag.data_tag); _starpu_mpi_req_list_erase(detached_requests, req); _starpu_mpi_handle_request_termination(req); _STARPU_MPI_TRACE_COMPLETE_END(req->request_type, req->node_tag.rank, req->node_tag.data_tag); if (req->is_internal_req == 0) { _starpu_mpi_request_destroy(req); } req = next_req; } STARPU_PTHREAD_MUTEX_LOCK(&detached_requests_mutex); } STARPU_PTHREAD_MUTEX_UNLOCK(&detached_requests_mutex); //_STARPU_MPI_LOG_OUT(); } static void _starpu_mpi_handle_detached_request(struct _starpu_mpi_req *req) { if (req->detached) { /* put the submitted request into the list of pending requests * so that it can be handled by the progression mechanisms */ STARPU_PTHREAD_MUTEX_LOCK(&detached_requests_mutex); _starpu_mpi_req_list_push_back(detached_requests, req); STARPU_PTHREAD_MUTEX_UNLOCK(&detached_requests_mutex); starpu_wake_all_blocked_workers(); STARPU_PTHREAD_MUTEX_LOCK(&progress_mutex); STARPU_PTHREAD_COND_SIGNAL(&progress_cond); STARPU_PTHREAD_MUTEX_UNLOCK(&progress_mutex); } } static void _starpu_mpi_handle_ready_request(struct _starpu_mpi_req *req) { _STARPU_MPI_LOG_IN(); STARPU_MPI_ASSERT_MSG(req, "Invalid request"); /* submit the request to MPI */ _STARPU_MPI_DEBUG(2, "Handling new request %p type %s tag %d src %d data %p ptr %p datatype '%s' count %d registered_datatype %d \n", req, _starpu_mpi_request_type(req->request_type), req->node_tag.data_tag, req->node_tag.rank, req->data_handle, req->ptr, req->datatype_name, (int)req->count, req->registered_datatype); req->func(req); _STARPU_MPI_LOG_OUT(); } static void _starpu_mpi_receive_early_data(struct _starpu_mpi_envelope *envelope, MPI_Status status, MPI_Comm comm) { _STARPU_MPI_DEBUG(20, "Request with tag %d and source %d not found, creating a early_data_handle to receive incoming data..\n", envelope->data_tag, status.MPI_SOURCE); _STARPU_MPI_DEBUG(20, "Request sync %d\n", envelope->sync); struct _starpu_mpi_early_data_handle* early_data_handle = _starpu_mpi_early_data_create(envelope, status.MPI_SOURCE, comm); _starpu_mpi_early_data_add(early_data_handle); starpu_data_handle_t data_handle = NULL; STARPU_PTHREAD_MUTEX_UNLOCK(&progress_mutex); data_handle = _starpu_mpi_data_get_data_handle_from_tag(envelope->data_tag); STARPU_PTHREAD_MUTEX_LOCK(&progress_mutex); if (data_handle && starpu_data_get_interface_id(data_handle) < STARPU_MAX_INTERFACE_ID) { /* We know which data will receive it and we won't have to unpack, use just the same kind of data. */ early_data_handle->buffer = NULL; starpu_data_register_same(&early_data_handle->handle, data_handle); //_starpu_mpi_early_data_add(early_data_handle); } else { /* The application has not registered yet a data with the tag, * we are going to receive the data as a raw memory, and give it * to the application when it post a receive for this tag */ _STARPU_MPI_DEBUG(3, "Posting a receive for a data of size %d which has not yet been registered\n", (int)early_data_handle->env->size); early_data_handle->buffer = malloc(early_data_handle->env->size); starpu_variable_data_register(&early_data_handle->handle, STARPU_MAIN_RAM, (uintptr_t) early_data_handle->buffer, early_data_handle->env->size); //_starpu_mpi_early_data_add(early_data_handle); } _STARPU_MPI_DEBUG(20, "Posting internal detached irecv on early_data_handle with tag %d from comm %ld src %d ..\n", early_data_handle->node_tag.data_tag, (long int)comm, status.MPI_SOURCE); STARPU_PTHREAD_MUTEX_UNLOCK(&progress_mutex); early_data_handle->req = _starpu_mpi_irecv_common(early_data_handle->handle, status.MPI_SOURCE, early_data_handle->node_tag.data_tag, comm, 1, 0, NULL, NULL, 1, 1, envelope->size); STARPU_PTHREAD_MUTEX_LOCK(&progress_mutex); // We wait until the request is pushed in the // ready_request list, that ensures that the next loop // will call _starpu_mpi_handle_ready_request // on the request and post the corresponding mpi_irecv, // otherwise, it may lead to read data as envelop STARPU_PTHREAD_MUTEX_UNLOCK(&progress_mutex); STARPU_PTHREAD_MUTEX_LOCK(&(early_data_handle->req->posted_mutex)); while (!(early_data_handle->req->posted)) STARPU_PTHREAD_COND_WAIT(&(early_data_handle->req->posted_cond), &(early_data_handle->req->posted_mutex)); STARPU_PTHREAD_MUTEX_UNLOCK(&(early_data_handle->req->posted_mutex)); STARPU_PTHREAD_MUTEX_LOCK(&early_data_handle->req_mutex); early_data_handle->req_ready = 1; STARPU_PTHREAD_COND_BROADCAST(&early_data_handle->req_cond); STARPU_PTHREAD_MUTEX_UNLOCK(&early_data_handle->req_mutex); STARPU_PTHREAD_MUTEX_LOCK(&progress_mutex); } static void _starpu_mpi_add_sync_point_in_fxt(void) { #ifdef STARPU_USE_FXT int rank; int worldsize; int ret; starpu_mpi_comm_rank(MPI_COMM_WORLD, &rank); starpu_mpi_comm_size(MPI_COMM_WORLD, &worldsize); ret = MPI_Barrier(MPI_COMM_WORLD); STARPU_MPI_ASSERT_MSG(ret == MPI_SUCCESS, "MPI_Barrier returning %s", _starpu_mpi_get_mpi_error_code(ret)); /* We generate a "unique" key so that we can make sure that different * FxT traces come from the same MPI run. */ int random_number; /* XXX perhaps we don't want to generate a new seed if the application * specified some reproductible behaviour ? */ if (rank == 0) { srand(time(NULL)); random_number = rand(); } ret = MPI_Bcast(&random_number, 1, MPI_INT, 0, MPI_COMM_WORLD); STARPU_MPI_ASSERT_MSG(ret == MPI_SUCCESS, "MPI_Bcast returning %s", _starpu_mpi_get_mpi_error_code(ret)); _STARPU_MPI_TRACE_BARRIER(rank, worldsize, random_number); _STARPU_MPI_DEBUG(3, "unique key %x\n", random_number); #endif } static void *_starpu_mpi_progress_thread_func(void *arg) { struct _starpu_mpi_argc_argv *argc_argv = (struct _starpu_mpi_argc_argv *) arg; int rank, worldsize; #ifndef STARPU_SIMGRID _starpu_mpi_do_initialize(argc_argv); #endif MPI_Comm_rank(argc_argv->comm, &rank); MPI_Comm_size(argc_argv->comm, &worldsize); MPI_Comm_set_errhandler(argc_argv->comm, MPI_ERRORS_RETURN); #ifdef STARPU_SIMGRID _mpi_world_size = worldsize; _mpi_world_rank = rank; #endif #ifdef STARPU_SIMGRID /* Now that MPI is set up, let the rest of simgrid get initialized */ char ** argv_cpy = malloc(*(argc_argv->argc) * sizeof(char*)); int i; for (i = 0; i < *(argc_argv->argc); i++) argv_cpy[i] = strdup((*(argc_argv->argv))[i]); MSG_process_create_with_arguments("main", smpi_simulated_main_, NULL, _starpu_simgrid_get_host_by_name("MAIN"), *(argc_argv->argc), argv_cpy); /* And set TSD for us */ #ifdef HAVE_SMPI_PROCESS_SET_USER_DATA smpi_process_set_user_data(calloc(MAX_TSD, sizeof(void*))); #endif #endif #ifdef STARPU_USE_FXT STARPU_PTHREAD_MUTEX_LOCK(&_starpu_fxt_started_mutex); while (!_starpu_fxt_started) STARPU_PTHREAD_COND_WAIT(&_starpu_fxt_started_cond, &_starpu_fxt_started_mutex); STARPU_PTHREAD_MUTEX_UNLOCK(&_starpu_fxt_started_mutex); #endif //STARPU_USE_FXT { _STARPU_MPI_TRACE_START(rank, worldsize); #ifdef STARPU_USE_FXT starpu_profiling_set_id(rank); #endif //STARPU_USE_FXT } _starpu_mpi_add_sync_point_in_fxt(); _starpu_mpi_comm_amounts_init(argc_argv->comm); _starpu_mpi_cache_init(argc_argv->comm); _starpu_mpi_select_node_init(); _starpu_mpi_tag_init(); _starpu_mpi_comm_init(argc_argv->comm); _starpu_mpi_early_request_init(); _starpu_mpi_early_data_init(); _starpu_mpi_sync_data_init(); _starpu_mpi_datatype_init(); /* notify the main thread that the progression thread is ready */ STARPU_PTHREAD_MUTEX_LOCK(&progress_mutex); running = 1; STARPU_PTHREAD_COND_SIGNAL(&progress_cond); STARPU_PTHREAD_MUTEX_UNLOCK(&progress_mutex); STARPU_PTHREAD_MUTEX_LOCK(&progress_mutex); int envelope_request_submitted = 0; while (running || posted_requests || !(_starpu_mpi_req_list_empty(ready_requests)) || !(_starpu_mpi_req_list_empty(detached_requests)))// || !(_starpu_mpi_early_request_count()) || !(_starpu_mpi_sync_data_count())) { /* shall we block ? */ STARPU_PTHREAD_MUTEX_LOCK(&detached_requests_mutex); unsigned block = _starpu_mpi_req_list_empty(ready_requests) && _starpu_mpi_early_request_count() == 0 && _starpu_mpi_sync_data_count() == 0 && _starpu_mpi_req_list_empty(detached_requests); STARPU_PTHREAD_MUTEX_UNLOCK(&detached_requests_mutex); #ifdef STARPU_SIMGRID MSG_process_sleep(0.000010); #endif if (block) { _STARPU_MPI_DEBUG(3, "NO MORE REQUESTS TO HANDLE\n"); _STARPU_MPI_TRACE_SLEEP_BEGIN(); if (barrier_running) /* Tell mpi_barrier */ STARPU_PTHREAD_COND_SIGNAL(&barrier_cond); STARPU_PTHREAD_COND_WAIT(&progress_cond, &progress_mutex); _STARPU_MPI_TRACE_SLEEP_END(); } /* get one request */ struct _starpu_mpi_req *req; while (!_starpu_mpi_req_list_empty(ready_requests)) { req = _starpu_mpi_req_list_pop_back(ready_requests); /* handling a request is likely to block for a while * (on a sync_data_with_mem call), we want to let the * application submit requests in the meantime, so we * release the lock. */ STARPU_PTHREAD_MUTEX_UNLOCK(&progress_mutex); _starpu_mpi_handle_ready_request(req); STARPU_PTHREAD_MUTEX_LOCK(&progress_mutex); } /* If there is no currently submitted envelope_request submitted to * catch envelopes from senders, and there is some pending * receive requests on our side, we resubmit a header request. */ if (((_starpu_mpi_early_request_count() > 0) || (_starpu_mpi_sync_data_count() > 0)) && (envelope_request_submitted == 0))// && (HASH_COUNT(_starpu_mpi_early_data_handle_hashmap) == 0)) { _starpu_mpi_comm_post_recv(); envelope_request_submitted = 1; } /* test whether there are some terminated "detached request" */ STARPU_PTHREAD_MUTEX_UNLOCK(&progress_mutex); _starpu_mpi_test_detached_requests(); STARPU_PTHREAD_MUTEX_LOCK(&progress_mutex); if (envelope_request_submitted == 1) { int flag; struct _starpu_mpi_envelope *envelope; MPI_Status envelope_status; MPI_Comm envelope_comm; /* test whether an envelope has arrived. */ flag = _starpu_mpi_comm_test_recv(&envelope_status, &envelope, &envelope_comm); if (flag) { _STARPU_MPI_DEBUG(4, "Envelope received with mode %d\n", envelope->mode); if (envelope->mode == _STARPU_MPI_ENVELOPE_SYNC_READY) { struct _starpu_mpi_req *_sync_req = _starpu_mpi_sync_data_find(envelope->data_tag, envelope_status.MPI_SOURCE, envelope_comm); _STARPU_MPI_DEBUG(20, "Sending data with tag %d to node %d\n", _sync_req->node_tag.data_tag, envelope_status.MPI_SOURCE); STARPU_MPI_ASSERT_MSG(envelope->data_tag == _sync_req->node_tag.data_tag, "Tag mismatch (envelope %d != req %d)\n", envelope->data_tag, _sync_req->node_tag.data_tag); STARPU_PTHREAD_MUTEX_UNLOCK(&progress_mutex); _starpu_mpi_isend_data_func(_sync_req); STARPU_PTHREAD_MUTEX_LOCK(&progress_mutex); } else { _STARPU_MPI_DEBUG(3, "Searching for application request with tag %d and source %d (size %ld)\n", envelope->data_tag, envelope_status.MPI_SOURCE, envelope->size); struct _starpu_mpi_req *early_request = _starpu_mpi_early_request_dequeue(envelope->data_tag, envelope_status.MPI_SOURCE, envelope_comm); /* Case: a data will arrive before a matching receive is * posted by the application. Create a temporary handle to * store the incoming data, submit a starpu_mpi_irecv_detached * on this handle, and store it as an early_data */ if (early_request == NULL) { if (envelope->sync) { _STARPU_MPI_DEBUG(2000, "-------------------------> adding request for tag %d\n", envelope->data_tag); struct _starpu_mpi_req *new_req; #ifdef STARPU_DEVEL #warning creating a request is not really useful. #endif /* Initialize the request structure */ _starpu_mpi_request_init(&new_req); new_req->request_type = RECV_REQ; new_req->data_handle = NULL; new_req->node_tag.rank = envelope_status.MPI_SOURCE; new_req->node_tag.data_tag = envelope->data_tag; new_req->node_tag.comm = envelope_comm; new_req->detached = 1; new_req->sync = 1; new_req->callback = NULL; new_req->callback_arg = NULL; new_req->func = _starpu_mpi_irecv_data_func; new_req->sequential_consistency = 1; new_req->is_internal_req = 0; // ???? new_req->count = envelope->size; _starpu_mpi_sync_data_add(new_req); } else { _starpu_mpi_receive_early_data(envelope, envelope_status, envelope_comm); } } /* Case: a matching application request has been found for * the incoming data, we handle the correct allocation * of the pointer associated to the data handle, then * submit the corresponding receive with * _starpu_mpi_handle_ready_request. */ else { _STARPU_MPI_DEBUG(2000, "A matching application request has been found for the incoming data with tag %d\n", envelope->data_tag); _STARPU_MPI_DEBUG(2000, "Request sync %d\n", envelope->sync); early_request->sync = envelope->sync; _starpu_mpi_handle_allocate_datatype(early_request->data_handle, early_request); if (early_request->registered_datatype == 1) { early_request->count = 1; early_request->ptr = starpu_data_get_local_ptr(early_request->data_handle); } else { early_request->count = envelope->size; early_request->ptr = malloc(early_request->count); STARPU_MPI_ASSERT_MSG(early_request->ptr, "cannot allocate message of size %ld\n", early_request->count); } _STARPU_MPI_DEBUG(3, "Handling new request... \n"); /* handling a request is likely to block for a while * (on a sync_data_with_mem call), we want to let the * application submit requests in the meantime, so we * release the lock. */ STARPU_PTHREAD_MUTEX_UNLOCK(&progress_mutex); _starpu_mpi_handle_ready_request(early_request); STARPU_PTHREAD_MUTEX_LOCK(&progress_mutex); } } envelope_request_submitted = 0; } else { //_STARPU_MPI_DEBUG(4, "Nothing received, continue ..\n"); } } } if (envelope_request_submitted) { _starpu_mpi_comm_cancel_recv(); envelope_request_submitted = 0; } STARPU_MPI_ASSERT_MSG(_starpu_mpi_req_list_empty(detached_requests), "List of detached requests not empty"); STARPU_MPI_ASSERT_MSG(_starpu_mpi_req_list_empty(ready_requests), "List of ready requests not empty"); STARPU_MPI_ASSERT_MSG(posted_requests == 0, "Number of posted request is not zero"); _starpu_mpi_early_request_check_termination(); _starpu_mpi_early_data_check_termination(); _starpu_mpi_sync_data_check_termination(); if (argc_argv->initialize_mpi) { _STARPU_MPI_DEBUG(3, "Calling MPI_Finalize()\n"); MPI_Finalize(); } STARPU_PTHREAD_MUTEX_UNLOCK(&progress_mutex); _starpu_mpi_sync_data_free(); _starpu_mpi_early_data_free(); _starpu_mpi_early_request_free(); _starpu_mpi_datatype_free(); free(argc_argv); return NULL; } int _starpu_mpi_progress_init(struct _starpu_mpi_argc_argv *argc_argv) { STARPU_PTHREAD_MUTEX_INIT(&progress_mutex, NULL); STARPU_PTHREAD_COND_INIT(&progress_cond, NULL); STARPU_PTHREAD_COND_INIT(&barrier_cond, NULL); ready_requests = _starpu_mpi_req_list_new(); STARPU_PTHREAD_MUTEX_INIT(&detached_requests_mutex, NULL); detached_requests = _starpu_mpi_req_list_new(); STARPU_PTHREAD_MUTEX_INIT(&mutex_posted_requests, NULL); _starpu_mpi_comm = starpu_getenv("STARPU_MPI_COMM") != NULL; #ifdef STARPU_SIMGRID _starpu_mpi_progress_thread_func(argc_argv); return 0; #else STARPU_PTHREAD_CREATE(&progress_thread, NULL, _starpu_mpi_progress_thread_func, argc_argv); STARPU_PTHREAD_MUTEX_LOCK(&progress_mutex); while (!running) STARPU_PTHREAD_COND_WAIT(&progress_cond, &progress_mutex); STARPU_PTHREAD_MUTEX_UNLOCK(&progress_mutex); return 0; #endif } void _starpu_mpi_progress_shutdown(int *value) { STARPU_PTHREAD_MUTEX_LOCK(&progress_mutex); running = 0; STARPU_PTHREAD_COND_BROADCAST(&progress_cond); STARPU_PTHREAD_MUTEX_UNLOCK(&progress_mutex); #ifdef STARPU_SIMGRID /* FIXME: should rather properly wait for _starpu_mpi_progress_thread_func to finish */ MSG_process_sleep(1); #else starpu_pthread_join(progress_thread, (void *)value); #endif /* free the request queues */ _starpu_mpi_req_list_delete(detached_requests); _starpu_mpi_req_list_delete(ready_requests); STARPU_PTHREAD_MUTEX_DESTROY(&mutex_posted_requests); STARPU_PTHREAD_MUTEX_DESTROY(&progress_mutex); STARPU_PTHREAD_COND_DESTROY(&barrier_cond); } void _starpu_mpi_clear_cache(starpu_data_handle_t data_handle) { _starpu_mpi_data_release_tag(data_handle); struct _starpu_mpi_node_tag *mpi_data = data_handle->mpi_data; _starpu_mpi_cache_flush(mpi_data->comm, data_handle); free(data_handle->mpi_data); } void starpu_mpi_data_register_comm(starpu_data_handle_t data_handle, int tag, int rank, MPI_Comm comm) { struct _starpu_mpi_node_tag *mpi_data; if (data_handle->mpi_data) { mpi_data = data_handle->mpi_data; } else { mpi_data = calloc(1, sizeof(struct _starpu_mpi_node_tag)); data_handle->mpi_data = mpi_data; _starpu_mpi_data_register_tag(data_handle, tag); _starpu_data_set_unregister_hook(data_handle, _starpu_mpi_clear_cache); } if (tag != -1) { mpi_data->data_tag = tag; } if (rank != -1) { mpi_data->rank = rank; mpi_data->comm = comm; _starpu_mpi_comm_register(comm); } } void starpu_mpi_data_set_rank_comm(starpu_data_handle_t handle, int rank, MPI_Comm comm) { starpu_mpi_data_register_comm(handle, -1, rank, comm); } void starpu_mpi_data_set_tag(starpu_data_handle_t handle, int tag) { starpu_mpi_data_register_comm(handle, tag, -1, MPI_COMM_WORLD); } int starpu_mpi_data_get_rank(starpu_data_handle_t data) { STARPU_ASSERT_MSG(data->mpi_data, "starpu_mpi_data_register MUST be called for data %p\n", data); return ((struct _starpu_mpi_node_tag *)(data->mpi_data))->rank; } int starpu_mpi_data_get_tag(starpu_data_handle_t data) { STARPU_ASSERT_MSG(data->mpi_data, "starpu_mpi_data_register MUST be called for data %p\n", data); return ((struct _starpu_mpi_node_tag *)(data->mpi_data))->data_tag; } int starpu_mpi_wait_for_all(MPI_Comm comm) { int mpi = 1; int task = 1; while (task || mpi) { task = _starpu_task_wait_for_all_and_return_nb_waited_tasks(); mpi = _starpu_mpi_barrier(comm); } return 0; }