void ucp_rkey_destroy(ucp_rkey_h rkey)
{
unsigned num_rkeys = ucs_count_one_bits(rkey->pd_map);
unsigned i;
for (i = 0; i < num_rkeys; ++i) {
uct_rkey_release(&rkey->uct[i]);
}
ucs_free(rkey);
}
void ucp_rkey_destroy(ucp_rkey_h rkey)
{
unsigned num_rkeys;
unsigned i;
if (rkey == &ucp_mem_dummy_rkey) {
return;
}
num_rkeys = ucs_count_one_bits(rkey->pd_map);
for (i = 0; i < num_rkeys; ++i) {
uct_rkey_release(&rkey->uct[i]);
}
ucs_free(rkey);
}
static void uct_perf_test_cleanup_endpoints(ucx_perf_context_t *perf)
{
unsigned group_size, group_index, i;
rte_call(perf, barrier);
uct_iface_set_am_handler(perf->uct.iface, UCT_PERF_TEST_AM_ID, NULL, NULL, UCT_AM_CB_FLAG_SYNC);
group_size = rte_call(perf, group_size);
group_index = rte_call(perf, group_index);
for (i = 0; i < group_size; ++i) {
if (i != group_index) {
uct_rkey_release(&perf->uct.peers[i].rkey);
if (perf->uct.peers[i].ep) {
uct_ep_destroy(perf->uct.peers[i].ep);
}
}
}
free(perf->uct.peers);
}
static ucs_status_t uct_perf_test_setup_endpoints(ucx_perf_context_t *perf)
{
const size_t buffer_size = 2048;
ucx_perf_ep_info_t info, *remote_info;
unsigned group_size, i, group_index;
uct_device_addr_t *dev_addr;
uct_iface_addr_t *iface_addr;
uct_ep_addr_t *ep_addr;
uct_iface_attr_t iface_attr;
uct_md_attr_t md_attr;
void *rkey_buffer;
ucs_status_t status;
struct iovec vec[5];
void *buffer;
void *req;
buffer = malloc(buffer_size);
if (buffer == NULL) {
ucs_error("Failed to allocate RTE buffer");
status = UCS_ERR_NO_MEMORY;
goto err;
}
status = uct_iface_query(perf->uct.iface, &iface_attr);
if (status != UCS_OK) {
ucs_error("Failed to uct_iface_query: %s", ucs_status_string(status));
goto err_free;
}
status = uct_md_query(perf->uct.md, &md_attr);
if (status != UCS_OK) {
ucs_error("Failed to uct_md_query: %s", ucs_status_string(status));
goto err_free;
}
if (md_attr.cap.flags & (UCT_MD_FLAG_ALLOC|UCT_MD_FLAG_REG)) {
info.rkey_size = md_attr.rkey_packed_size;
} else {
info.rkey_size = 0;
}
info.uct.dev_addr_len = iface_attr.device_addr_len;
info.uct.iface_addr_len = iface_attr.iface_addr_len;
info.uct.ep_addr_len = iface_attr.ep_addr_len;
info.recv_buffer = (uintptr_t)perf->recv_buffer;
rkey_buffer = buffer;
dev_addr = (void*)rkey_buffer + info.rkey_size;
iface_addr = (void*)dev_addr + info.uct.dev_addr_len;
ep_addr = (void*)iface_addr + info.uct.iface_addr_len;
ucs_assert_always((void*)ep_addr + info.uct.ep_addr_len <= buffer + buffer_size);
status = uct_iface_get_device_address(perf->uct.iface, dev_addr);
if (status != UCS_OK) {
ucs_error("Failed to uct_iface_get_device_address: %s",
ucs_status_string(status));
goto err_free;
}
status = uct_iface_get_address(perf->uct.iface, iface_addr);
if (status != UCS_OK) {
ucs_error("Failed to uct_iface_get_address: %s", ucs_status_string(status));
goto err_free;
}
if (info.rkey_size > 0) {
status = uct_md_mkey_pack(perf->uct.md, perf->uct.recv_mem.memh, rkey_buffer);
if (status != UCS_OK) {
ucs_error("Failed to uct_rkey_pack: %s", ucs_status_string(status));
goto err_free;
}
}
group_size = rte_call(perf, group_size);
group_index = rte_call(perf, group_index);
perf->uct.peers = calloc(group_size, sizeof(*perf->uct.peers));
if (perf->uct.peers == NULL) {
goto err_free;
}
if (iface_attr.cap.flags & UCT_IFACE_FLAG_CONNECT_TO_EP) {
for (i = 0; i < group_size; ++i) {
if (i == group_index) {
continue;
}
status = uct_ep_create(perf->uct.iface, &perf->uct.peers[i].ep);
if (status != UCS_OK) {
ucs_error("Failed to uct_ep_create: %s", ucs_status_string(status));
goto err_destroy_eps;
}
status = uct_ep_get_address(perf->uct.peers[i].ep, ep_addr);
if (status != UCS_OK) {
ucs_error("Failed to uct_ep_get_address: %s", ucs_status_string(status));
goto err_destroy_eps;
}
}
}
vec[0].iov_base = &info;
vec[0].iov_len = sizeof(info);
vec[1].iov_base = buffer;
vec[1].iov_len = info.rkey_size + info.uct.dev_addr_len +
info.uct.iface_addr_len + info.uct.ep_addr_len;
rte_call(perf, post_vec, vec, 2, &req);
rte_call(perf, exchange_vec, req);
for (i = 0; i < group_size; ++i) {
if (i == group_index) {
continue;
}
rte_call(perf, recv, i, buffer, buffer_size, req);
remote_info = buffer;
rkey_buffer = remote_info + 1;
dev_addr = (void*)rkey_buffer + remote_info->rkey_size;
iface_addr = (void*)dev_addr + remote_info->uct.dev_addr_len;
ep_addr = (void*)iface_addr + remote_info->uct.iface_addr_len;
perf->uct.peers[i].remote_addr = remote_info->recv_buffer;
if (!uct_iface_is_reachable(perf->uct.iface, dev_addr,
remote_info->uct.iface_addr_len ?
iface_addr : NULL)) {
ucs_error("Destination is unreachable");
status = UCS_ERR_UNREACHABLE;
goto err_destroy_eps;
}
if (remote_info->rkey_size > 0) {
status = uct_rkey_unpack(rkey_buffer, &perf->uct.peers[i].rkey);
if (status != UCS_OK) {
ucs_error("Failed to uct_rkey_unpack: %s", ucs_status_string(status));
goto err_destroy_eps;
}
} else {
perf->uct.peers[i].rkey.handle = NULL;
perf->uct.peers[i].rkey.type = NULL;
perf->uct.peers[i].rkey.rkey = UCT_INVALID_RKEY;
}
if (iface_attr.cap.flags & UCT_IFACE_FLAG_CONNECT_TO_EP) {
status = uct_ep_connect_to_ep(perf->uct.peers[i].ep, dev_addr, ep_addr);
} else if (iface_attr.cap.flags & UCT_IFACE_FLAG_CONNECT_TO_IFACE) {
status = uct_ep_create_connected(perf->uct.iface, dev_addr, iface_addr,
&perf->uct.peers[i].ep);
} else {
status = UCS_ERR_UNSUPPORTED;
}
if (status != UCS_OK) {
ucs_error("Failed to connect endpoint: %s", ucs_status_string(status));
goto err_destroy_eps;
}
}
uct_perf_iface_flush_b(perf);
free(buffer);
rte_call(perf, barrier);
return UCS_OK;
err_destroy_eps:
for (i = 0; i < group_size; ++i) {
if (perf->uct.peers[i].rkey.type != NULL) {
uct_rkey_release(&perf->uct.peers[i].rkey);
}
if (perf->uct.peers[i].ep != NULL) {
uct_ep_destroy(perf->uct.peers[i].ep);
}
}
free(perf->uct.peers);
err_free:
free(buffer);
err:
return status;
}
static ucs_status_t uct_perf_test_setup_endpoints(ucx_perf_context_t *perf)
{
unsigned group_size, i, group_index;
uct_device_addr_t *dev_addr;
uct_iface_addr_t *iface_addr;
uct_ep_addr_t *ep_addr;
uct_iface_attr_t iface_attr;
uct_pd_attr_t pd_attr;
unsigned long va;
void *rkey_buffer;
ucs_status_t status;
struct iovec vec[5];
void *req;
status = uct_iface_query(perf->uct.iface, &iface_attr);
if (status != UCS_OK) {
ucs_error("Failed to uct_iface_query: %s", ucs_status_string(status));
goto err;
}
status = uct_pd_query(perf->uct.pd, &pd_attr);
if (status != UCS_OK) {
ucs_error("Failed to uct_pd_query: %s", ucs_status_string(status));
goto err;
}
dev_addr = calloc(1, iface_attr.device_addr_len);
iface_addr = calloc(1, iface_attr.iface_addr_len);
ep_addr = calloc(1, iface_attr.ep_addr_len);
rkey_buffer = calloc(1, pd_attr.rkey_packed_size);
if ((iface_addr == NULL) || (ep_addr == NULL) || (rkey_buffer == NULL)) {
goto err_free;
}
status = uct_iface_get_device_address(perf->uct.iface, dev_addr);
if (status != UCS_OK) {
ucs_error("Failed to uct_iface_get_device_address: %s",
ucs_status_string(status));
goto err_free;
}
if (iface_attr.cap.flags & UCT_IFACE_FLAG_CONNECT_TO_IFACE) {
status = uct_iface_get_address(perf->uct.iface, iface_addr);
if (status != UCS_OK) {
ucs_error("Failed to uct_iface_get_address: %s", ucs_status_string(status));
goto err_free;
}
}
status = uct_pd_mkey_pack(perf->uct.pd, perf->uct.recv_mem.memh, rkey_buffer);
if (status != UCS_OK) {
ucs_error("Failed to uct_rkey_pack: %s", ucs_status_string(status));
goto err_free;
}
group_size = rte_call(perf, group_size);
group_index = rte_call(perf, group_index);
perf->uct.peers = calloc(group_size, sizeof(*perf->uct.peers));
if (perf->uct.peers == NULL) {
goto err_free;
}
if (iface_attr.cap.flags & UCT_IFACE_FLAG_CONNECT_TO_EP) {
for (i = 0; i < group_size; ++i) {
if (i == group_index) {
continue;
}
status = uct_ep_create(perf->uct.iface, &perf->uct.peers[i].ep);
if (status != UCS_OK) {
ucs_error("Failed to uct_ep_create: %s", ucs_status_string(status));
goto err_destroy_eps;
}
status = uct_ep_get_address(perf->uct.peers[i].ep, ep_addr);
if (status != UCS_OK) {
ucs_error("Failed to uct_ep_get_address: %s", ucs_status_string(status));
goto err_destroy_eps;
}
}
}
va = (uintptr_t)perf->recv_buffer;
vec[0].iov_base = &va;
vec[0].iov_len = sizeof(va);
vec[1].iov_base = rkey_buffer;
vec[1].iov_len = pd_attr.rkey_packed_size;
vec[2].iov_base = dev_addr;
vec[2].iov_len = iface_attr.device_addr_len;
vec[3].iov_base = iface_addr;
vec[3].iov_len = iface_attr.iface_addr_len;
vec[4].iov_base = ep_addr;
vec[4].iov_len = iface_attr.ep_addr_len;
rte_call(perf, post_vec, vec, 5, &req);
rte_call(perf, exchange_vec, req);
for (i = 0; i < group_size; ++i) {
if (i == group_index) {
continue;
}
vec[0].iov_base = &va;
vec[0].iov_len = sizeof(va);
vec[1].iov_base = rkey_buffer;
vec[1].iov_len = pd_attr.rkey_packed_size;
vec[2].iov_base = dev_addr;
vec[2].iov_len = iface_attr.device_addr_len;
vec[3].iov_base = iface_addr;
vec[3].iov_len = iface_attr.iface_addr_len;
vec[4].iov_base = ep_addr;
vec[4].iov_len = iface_attr.ep_addr_len;
rte_call(perf, recv_vec, i, vec, 5, req);
perf->uct.peers[i].remote_addr = va;
status = uct_rkey_unpack(rkey_buffer, &perf->uct.peers[i].rkey);
if (status != UCS_OK) {
ucs_error("Failed to uct_rkey_unpack: %s", ucs_status_string(status));
return status;
}
if (iface_attr.cap.flags & UCT_IFACE_FLAG_CONNECT_TO_EP) {
status = uct_ep_connect_to_ep(perf->uct.peers[i].ep, dev_addr, ep_addr);
} else if (iface_attr.cap.flags & UCT_IFACE_FLAG_CONNECT_TO_IFACE) {
status = uct_ep_create_connected(perf->uct.iface, dev_addr, iface_addr,
&perf->uct.peers[i].ep);
} else {
status = UCS_ERR_UNSUPPORTED;
}
if (status != UCS_OK) {
ucs_error("Failed to connect endpoint: %s", ucs_status_string(status));
goto err_destroy_eps;
}
}
uct_perf_iface_flush_b(perf);
rte_call(perf, barrier);
free(ep_addr);
free(iface_addr);
free(dev_addr);
free(rkey_buffer);
return UCS_OK;
err_destroy_eps:
for (i = 0; i < group_size; ++i) {
if (perf->uct.peers[i].rkey.type != NULL) {
uct_rkey_release(&perf->uct.peers[i].rkey);
}
if (perf->uct.peers[i].ep != NULL) {
uct_ep_destroy(perf->uct.peers[i].ep);
}
}
free(perf->uct.peers);
err_free:
free(ep_addr);
free(iface_addr);
free(dev_addr);
free(rkey_buffer);
err:
return status;
}
