示例#1
0
文件: ucp_ep.c 项目: alex--m/ucx
static ucs_status_ptr_t ucp_disconnect_nb_internal(ucp_ep_h ep)
{
    ucs_status_t status;
    ucp_request_t *req;

    ucs_debug("disconnect ep %p", ep);

    req = ucs_mpool_get(&ep->worker->req_mp);
    if (req == NULL) {
        return UCS_STATUS_PTR(UCS_ERR_NO_MEMORY);
    }

    /*
     *  Flush operation can be queued on the pending queue of only one of the
     * lanes (indicated by req->send.lane) and scheduled for completion on any
     * number of lanes. req->send.uct_comp.count keeps track of how many lanes
     * are not flushed yet, and when it reaches zero, it means all lanes are
     * flushed. req->send.flush.lanes keeps track of which lanes we still have
     * to start flush on.
     *  If a flush is completed from a pending/completion callback, we need to
     * schedule slow-path callback to release the endpoint later, since a UCT
     * endpoint cannot be released from pending/completion callback context.
     */
    req->flags                  = 0;
    req->status                 = UCS_OK;
    req->send.ep                = ep;
    req->send.flush.flushed_cb  = ucp_ep_disconnected;
    req->send.flush.lanes       = UCS_MASK(ucp_ep_num_lanes(ep));
    req->send.flush.cbq_elem.cb = ucp_ep_flushed_slow_path_callback;
    req->send.flush.cbq_elem_on = 0;
    req->send.lane              = UCP_NULL_LANE;
    req->send.uct.func          = ucp_ep_flush_progress_pending;
    req->send.uct_comp.func     = ucp_ep_flush_completion;
    req->send.uct_comp.count    = ucp_ep_num_lanes(ep);

    ucp_ep_flush_progress(req);

    if (req->send.uct_comp.count == 0) {
        status = req->status;
        ucp_ep_disconnected(req);
        ucs_trace_req("ep %p: releasing flush request %p, returning status %s",
                      ep, req, ucs_status_string(status));
        ucs_mpool_put(req);
        return UCS_STATUS_PTR(status);
    }

    ucs_trace_req("ep %p: return inprogress flush request %p (%p)", ep, req,
                  req + 1);
    return req + 1;
}
示例#2
0
static void ucp_wireup_ep_remote_connected(ucp_ep_h ep)
{
    ucp_worker_h worker = ep->worker;
    ucp_rsc_index_t rsc_index;
    ucp_lane_index_t lane;

    ucs_trace("ep %p: remote connected", ep);

    for (lane = 0; lane < ucp_ep_num_lanes(ep); ++lane) {
        rsc_index = ucp_ep_get_rsc_index(ep, lane);
        if (ucp_worker_is_tl_p2p(worker, rsc_index)) {
            ucp_stub_ep_remote_connected(ep->uct_eps[lane]);
        }
    }
}
示例#3
0
文件: ucp_ep.c 项目: abouteiller/ucx
static void ucp_ep_destory_uct_eps(ucp_ep_h ep)
{
    ucp_lane_index_t lane;
    uct_ep_h uct_ep;

    for (lane = 0; lane < ucp_ep_num_lanes(ep); ++lane) {
        uct_ep = ep->uct_eps[lane];
        if (uct_ep == NULL) {
            continue;
        }
        uct_ep_pending_purge(uct_ep, ucp_request_release_pending_send, NULL);
        ucs_debug("destroy ep %p lane %d uct_ep %p", ep, lane, uct_ep);
        uct_ep_destroy(uct_ep);
    }
}
示例#4
0
static ucs_status_t ucp_wireup_connect_local(ucp_ep_h ep, const uint8_t *tli,
                                             unsigned address_count,
                                             const ucp_address_entry_t *address_list)
{
    ucp_worker_h worker = ep->worker;
    const ucp_address_entry_t *address;
    ucp_rsc_index_t rsc_index;
    ucp_lane_index_t lane, amo_index;
    ucs_status_t status;
    ucp_md_map_t UCS_V_UNUSED md_map;

    ucs_trace("ep %p: connect local transports", ep);

    for (lane = 0; lane < ucp_ep_num_lanes(ep); ++lane) {
        rsc_index = ucp_ep_get_rsc_index(ep, lane);
        if (!ucp_worker_is_tl_p2p(worker, rsc_index)) {
            continue;
        }

        address = &address_list[tli[lane]];
        ucs_assert(address->tl_addr_len > 0);

        /* Check that if the lane is used for RMA/AMO, destination md index matches */
        md_map = ucp_lane_map_get_lane(ucp_ep_config(ep)->key.rma_lane_map, lane);
        ucs_assertv((md_map == 0) || (md_map == UCS_BIT(address->md_index)),
                    "lane=%d ai=%d md_map=0x%x md_index=%d", lane, tli[lane],
                    md_map, address->md_index);

        amo_index = ucp_ep_get_amo_lane_index(&ucp_ep_config(ep)->key, lane);
        if (amo_index != UCP_NULL_LANE) {
            md_map = ucp_lane_map_get_lane(ucp_ep_config(ep)->key.amo_lane_map,
                                           amo_index);
            ucs_assertv((md_map == 0) || (md_map == UCS_BIT(address->md_index)),
                        "lane=%d ai=%d md_map=0x%x md_index=%d", lane, tli[lane],
                        md_map, address->md_index);
        }

        status = uct_ep_connect_to_ep(ep->uct_eps[lane], address->dev_addr,
                                      address->ep_addr);
        if (status != UCS_OK) {
            return status;
        }
    }

    return UCS_OK;
}
示例#5
0
文件: basic_rma.c 项目: alex--m/ucx
ucs_status_t ucp_ep_flush(ucp_ep_h ep)
{
    ucp_lane_index_t lane;
    ucs_status_t status;

    for (lane = 0; lane < ucp_ep_num_lanes(ep); ++lane) {
        for (;;) {
            status = uct_ep_flush(ep->uct_eps[lane], 0, NULL);
            if (status == UCS_OK) {
                break;
            } else if ((status != UCS_INPROGRESS) && (status != UCS_ERR_NO_RESOURCE)) {
                return status;
            }
            ucp_worker_progress(ep->worker);
        }
    }
    return UCS_OK;
}
示例#6
0
static ucs_status_t
ucp_address_pack_ep_address(ucp_ep_h ep, ucp_rsc_index_t tl_index,
                            uct_ep_addr_t *addr)
{
    ucp_lane_index_t lane;

    for (lane = 0; lane < ucp_ep_num_lanes(ep); ++lane) {
        if (ucp_ep_get_rsc_index(ep, lane) == tl_index) {
            /*
             * If this is a wireup endpoint, it will return the underlying next_ep
             * address, and the length will be correct because the resource index
             * is of the next_ep.
             */
            return uct_ep_get_address(ep->uct_eps[lane], addr);
        }
    }

    ucs_bug("provided ucp_ep without required transport");
    return UCS_ERR_INVALID_ADDR;
}
示例#7
0
文件: ucp_ep.c 项目: alex--m/ucx
void ucp_ep_destroy_internal(ucp_ep_h ep, const char *message)
{
    ucp_lane_index_t lane;
    uct_ep_h uct_ep;

    ucs_debug("destroy ep %p%s", ep, message);

    for (lane = 0; lane < ucp_ep_num_lanes(ep); ++lane) {
        uct_ep = ep->uct_eps[lane];
        if (uct_ep == NULL) {
            continue;
        }

        uct_ep_pending_purge(uct_ep, ucp_destroyed_ep_pending_purge, ep);
        ucs_debug("destroy ep %p lane[%d]=%p", ep, lane, uct_ep);
        uct_ep_destroy(uct_ep);
    }

    ucs_free(ep);
}
示例#8
0
ucs_status_t ucp_wireup_send_request(ucp_ep_h ep)
{
    ucp_worker_h worker = ep->worker;
    ucp_rsc_index_t rsc_tli[UCP_MAX_LANES];
    ucp_rsc_index_t rsc_index;
    uint64_t tl_bitmap = 0;
    ucp_lane_index_t lane;
    ucs_status_t status;

    if (ep->flags & UCP_EP_FLAG_CONNECT_REQ_SENT) {
        return UCS_OK;
    }

    ucs_assert_always(!ucp_ep_is_stub(ep));

    for (lane = 0; lane < UCP_MAX_LANES; ++lane) {
        if (lane < ucp_ep_num_lanes(ep)) {
            rsc_index = ucp_ep_get_rsc_index(ep, lane);
            rsc_tli[lane] = ucp_worker_is_tl_p2p(worker, rsc_index) ? rsc_index :
                                                                      UCP_NULL_RESOURCE;
            tl_bitmap |= UCS_BIT(rsc_index);
        } else {
            rsc_tli[lane] = UCP_NULL_RESOURCE;
        }
    }

    /* TODO make sure such lane would exist */
    rsc_index = ucp_stub_ep_get_aux_rsc_index(
                    ep->uct_eps[ucp_ep_get_wireup_msg_lane(ep)]);
    if (rsc_index != UCP_NULL_RESOURCE) {
        tl_bitmap |= UCS_BIT(rsc_index);
    }

    ucs_debug("ep %p: send wireup request (flags=0x%x)", ep, ep->flags);
    status = ucp_wireup_msg_send(ep, UCP_WIREUP_MSG_REQUEST, tl_bitmap, rsc_tli);
    ep->flags |= UCP_EP_FLAG_CONNECT_REQ_SENT;
    return status;
}
示例#9
0
ucs_status_t ucp_wireup_init_lanes(ucp_ep_h ep, unsigned address_count,
                                   const ucp_address_entry_t *address_list,
                                   uint8_t *addr_indices)
{
    ucp_worker_h worker = ep->worker;
    ucp_ep_config_key_t key;
    uint16_t new_cfg_index;
    ucp_lane_index_t lane;
    ucs_status_t status;
    uint8_t conn_flag;
    char str[32];

    ucs_trace("ep %p: initialize lanes", ep);

    status = ucp_wireup_select_lanes(ep, address_count, address_list,
                                     addr_indices, &key);
    if (status != UCS_OK) {
        goto err;
    }

    key.reachable_md_map |= ucp_ep_config(ep)->key.reachable_md_map;

    new_cfg_index = ucp_worker_get_ep_config(worker, &key);
    if ((ep->cfg_index == new_cfg_index)) {
        return UCS_OK; /* No change */
    }

    if ((ep->cfg_index != 0) && !ucp_ep_is_stub(ep)) {
        /*
         * TODO handle a case where we have to change lanes and reconfigure the ep:
         *
         * - if we already have uct ep connected to an address - move it to the new lane index
         * - if we don't yet have connection to an address - create it
         * - if an existing lane is not connected anymore - delete it (possibly)
         * - if the configuration has changed - replay all pending operations on all lanes -
         *   need that every pending callback would return, in case of failure, the number
         *   of lane it wants to be queued on.
         */
        ucs_debug("cannot reconfigure ep %p from [%d] to [%d]", ep, ep->cfg_index,
                  new_cfg_index);
        ucp_wireup_print_config(worker->context, &ucp_ep_config(ep)->key, "old", NULL);
        ucp_wireup_print_config(worker->context, &key, "new", NULL);
        ucs_fatal("endpoint reconfiguration not supported yet");
    }

    ep->cfg_index = new_cfg_index;
    ep->am_lane   = key.am_lane;

    snprintf(str, sizeof(str), "ep %p", ep);
    ucp_wireup_print_config(worker->context, &ucp_ep_config(ep)->key, str,
                            addr_indices);

    ucs_trace("ep %p: connect lanes", ep);

    /* establish connections on all underlying endpoints */
    conn_flag = UCP_EP_FLAG_LOCAL_CONNECTED;
    for (lane = 0; lane < ucp_ep_num_lanes(ep); ++lane) {
        status = ucp_wireup_connect_lane(ep, lane, address_count, address_list,
                                         addr_indices[lane]);
        if (status != UCS_OK) {
            goto err;
        }

        if (ucp_worker_is_tl_p2p(worker, ucp_ep_get_rsc_index(ep, lane))) {
            conn_flag = 0; /* If we have a p2p transport, we're not connected */
        }
    }

    ep->flags |= conn_flag;
    return UCS_OK;

err:
    for (lane = 0; lane < ucp_ep_num_lanes(ep); ++lane) {
        if (ep->uct_eps[lane] != NULL) {
            uct_ep_destroy(ep->uct_eps[lane]);
            ep->uct_eps[lane] = NULL;
        }
    }
    return status;
}
示例#10
0
static void ucp_wireup_process_request(ucp_worker_h worker, const ucp_wireup_msg_t *msg,
                                       uint64_t uuid, const char *peer_name,
                                       unsigned address_count,
                                       const ucp_address_entry_t *address_list)
{
    ucp_ep_h ep = ucp_worker_ep_find(worker, uuid);
    ucp_rsc_index_t rsc_tli[UCP_MAX_LANES];
    uint8_t addr_indices[UCP_MAX_LANES];
    ucp_lane_index_t lane, remote_lane;
    ucp_rsc_index_t rsc_index;
    ucs_status_t status;
    uint64_t tl_bitmap = 0;

    ucs_trace("ep %p: got wireup request from %s", ep, peer_name);

    /* Create a new endpoint if does not exist */
    if (ep == NULL) {
        status = ucp_ep_new(worker, uuid, peer_name, "remote-request", &ep);
        if (status != UCS_OK) {
            return;
        }
    }

    /* Initialize lanes (possible destroy existing lanes) */
    status = ucp_wireup_init_lanes(ep, address_count, address_list, addr_indices);
    if (status != UCS_OK) {
        return;
    }

    /* Connect p2p addresses to remote endpoint */
    if (!(ep->flags & UCP_EP_FLAG_LOCAL_CONNECTED)) {
        status = ucp_wireup_connect_local(ep, addr_indices, address_count,
                                          address_list);
        if (status != UCS_OK) {
            return;
        }

        ep->flags |= UCP_EP_FLAG_LOCAL_CONNECTED;

        /* Construct the list that tells the remote side with which address we
         * have connected to each of its lanes.
         */
        memset(rsc_tli, -1, sizeof(rsc_tli));
        for (lane = 0; lane < ucp_ep_num_lanes(ep); ++lane) {
             rsc_index = ucp_ep_get_rsc_index(ep, lane);
             for (remote_lane = 0; remote_lane < UCP_MAX_LANES; ++remote_lane) {
                 /* If 'lane' has connected to 'remote_lane' ... */
                 if (addr_indices[lane] == msg->tli[remote_lane]) {
                     ucs_assert(ucp_worker_is_tl_p2p(worker, rsc_index));
                     rsc_tli[remote_lane] = rsc_index;
                     tl_bitmap           |= UCS_BIT(rsc_index);
                 }
             }
        }

        ucs_trace("ep %p: sending wireup reply", ep);
        status = ucp_wireup_msg_send(ep, UCP_WIREUP_MSG_REPLY, tl_bitmap, rsc_tli);
        if (status != UCS_OK) {
            return;
        }
    }
}