// SPDX-License-Identifier: GPL-2.0 #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "network_helpers.h" #include "test_xsk.h" #include "xsk_xdp_common.h" #include "xsk_xdp_progs.skel.h" #define DEFAULT_BATCH_SIZE 64 #define MIN_PKT_SIZE 64 #define MAX_ETH_JUMBO_SIZE 9000 #define MAX_INTERFACES 2 #define MAX_TEARDOWN_ITER 10 #define MAX_TX_BUDGET_DEFAULT 32 #define PKT_DUMP_NB_TO_PRINT 16 /* Just to align the data in the packet */ #define PKT_HDR_SIZE (sizeof(struct ethhdr) + 2) #define POLL_TMOUT 1000 #define THREAD_TMOUT 3 #define UMEM_HEADROOM_TEST_SIZE 128 #define XSK_DESC__INVALID_OPTION (0xffff) #define XSK_UMEM__INVALID_FRAME_SIZE (MAX_ETH_JUMBO_SIZE + 1) #define XSK_UMEM__LARGE_FRAME_SIZE (3 * 1024) #define XSK_UMEM__MAX_FRAME_SIZE (4 * 1024) static const u8 g_mac[ETH_ALEN] = {0x55, 0x44, 0x33, 0x22, 0x11, 0x00}; bool opt_verbose; pthread_barrier_t barr; pthread_mutex_t pacing_mutex = PTHREAD_MUTEX_INITIALIZER; int pkts_in_flight; /* The payload is a word consisting of a packet sequence number in the upper * 16-bits and a intra packet data sequence number in the lower 16 bits. So the 3rd packet's * 5th word of data will contain the number (2<<16) | 4 as they are numbered from 0. */ static void write_payload(void *dest, u32 pkt_nb, u32 start, u32 size) { u32 *ptr = (u32 *)dest, i; start /= sizeof(*ptr); size /= sizeof(*ptr); for (i = 0; i < size; i++) ptr[i] = htonl(pkt_nb << 16 | (i + start)); } static void gen_eth_hdr(struct xsk_socket_info *xsk, struct ethhdr *eth_hdr) { memcpy(eth_hdr->h_dest, xsk->dst_mac, ETH_ALEN); memcpy(eth_hdr->h_source, xsk->src_mac, ETH_ALEN); eth_hdr->h_proto = htons(ETH_P_LOOPBACK); } static bool is_umem_valid(struct ifobject *ifobj) { return !!ifobj->umem->umem; } static u32 mode_to_xdp_flags(enum test_mode mode) { return (mode == TEST_MODE_SKB) ? XDP_FLAGS_SKB_MODE : XDP_FLAGS_DRV_MODE; } static u64 umem_size(struct xsk_umem_info *umem) { return umem->num_frames * umem->frame_size; } int xsk_configure_umem(struct ifobject *ifobj, struct xsk_umem_info *umem, void *buffer, u64 size) { struct xsk_umem_config cfg = { .fill_size = XSK_RING_PROD__DEFAULT_NUM_DESCS, .comp_size = XSK_RING_CONS__DEFAULT_NUM_DESCS, .frame_size = umem->frame_size, .frame_headroom = umem->frame_headroom, .flags = XSK_UMEM__DEFAULT_FLAGS }; int ret; if (umem->fill_size) cfg.fill_size = umem->fill_size; if (umem->comp_size) cfg.comp_size = umem->comp_size; if (umem->unaligned_mode) cfg.flags |= XDP_UMEM_UNALIGNED_CHUNK_FLAG; ret = xsk_umem__create(&umem->umem, buffer, size, &umem->fq, &umem->cq, &cfg); if (ret) return ret; umem->buffer = buffer; if (ifobj->shared_umem && ifobj->rx_on) { umem->base_addr = umem_size(umem); umem->next_buffer = umem_size(umem); } return 0; } static u64 umem_alloc_buffer(struct xsk_umem_info *umem) { u64 addr; addr = umem->next_buffer; umem->next_buffer += umem->frame_size; if (umem->next_buffer >= umem->base_addr + umem_size(umem)) umem->next_buffer = umem->base_addr; return addr; } static void umem_reset_alloc(struct xsk_umem_info *umem) { umem->next_buffer = 0; } static int enable_busy_poll(struct xsk_socket_info *xsk) { int sock_opt; sock_opt = 1; if (setsockopt(xsk_socket__fd(xsk->xsk), SOL_SOCKET, SO_PREFER_BUSY_POLL, (void *)&sock_opt, sizeof(sock_opt)) < 0) return -errno; sock_opt = 20; if (setsockopt(xsk_socket__fd(xsk->xsk), SOL_SOCKET, SO_BUSY_POLL, (void *)&sock_opt, sizeof(sock_opt)) < 0) return -errno; sock_opt = xsk->batch_size; if (setsockopt(xsk_socket__fd(xsk->xsk), SOL_SOCKET, SO_BUSY_POLL_BUDGET, (void *)&sock_opt, sizeof(sock_opt)) < 0) return -errno; return 0; } int xsk_configure_socket(struct xsk_socket_info *xsk, struct xsk_umem_info *umem, struct ifobject *ifobject, bool shared) { struct xsk_socket_config cfg = {}; struct xsk_ring_cons *rxr; struct xsk_ring_prod *txr; xsk->umem = umem; cfg.rx_size = xsk->rxqsize; cfg.tx_size = XSK_RING_PROD__DEFAULT_NUM_DESCS; cfg.bind_flags = ifobject->bind_flags; if (shared) cfg.bind_flags |= XDP_SHARED_UMEM; if (ifobject->mtu > MAX_ETH_PKT_SIZE) cfg.bind_flags |= XDP_USE_SG; if (umem->comp_size) cfg.tx_size = umem->comp_size; if (umem->fill_size) cfg.rx_size = umem->fill_size; txr = ifobject->tx_on ? &xsk->tx : NULL; rxr = ifobject->rx_on ? &xsk->rx : NULL; return xsk_socket__create(&xsk->xsk, ifobject->ifindex, 0, umem->umem, rxr, txr, &cfg); } #define MAX_SKB_FRAGS_PATH "/proc/sys/net/core/max_skb_frags" static unsigned int get_max_skb_frags(void) { unsigned int max_skb_frags = 0; FILE *file; file = fopen(MAX_SKB_FRAGS_PATH, "r"); if (!file) { ksft_print_msg("Error opening %s\n", MAX_SKB_FRAGS_PATH); return 0; } if (fscanf(file, "%u", &max_skb_frags) != 1) ksft_print_msg("Error reading %s\n", MAX_SKB_FRAGS_PATH); fclose(file); return max_skb_frags; } static int set_ring_size(struct ifobject *ifobj) { int ret; u32 ctr = 0; while (ctr++ < SOCK_RECONF_CTR) { ret = set_hw_ring_size(ifobj->ifname, &ifobj->ring); if (!ret) break; /* Retry if it fails */ if (ctr >= SOCK_RECONF_CTR || errno != EBUSY) return -errno; usleep(USLEEP_MAX); } return ret; } int hw_ring_size_reset(struct ifobject *ifobj) { ifobj->ring.tx_pending = ifobj->set_ring.default_tx; ifobj->ring.rx_pending = ifobj->set_ring.default_rx; return set_ring_size(ifobj); } static void __test_spec_init(struct test_spec *test, struct ifobject *ifobj_tx, struct ifobject *ifobj_rx) { u32 i, j; for (i = 0; i < MAX_INTERFACES; i++) { struct ifobject *ifobj = i ? ifobj_rx : ifobj_tx; ifobj->xsk = &ifobj->xsk_arr[0]; ifobj->use_poll = false; ifobj->use_fill_ring = true; ifobj->release_rx = true; ifobj->validation_func = NULL; ifobj->use_metadata = false; if (i == 0) { ifobj->rx_on = false; ifobj->tx_on = true; } else { ifobj->rx_on = true; ifobj->tx_on = false; } memset(ifobj->umem, 0, sizeof(*ifobj->umem)); ifobj->umem->num_frames = DEFAULT_UMEM_BUFFERS; ifobj->umem->frame_size = XSK_UMEM__DEFAULT_FRAME_SIZE; for (j = 0; j < MAX_SOCKETS; j++) { memset(&ifobj->xsk_arr[j], 0, sizeof(ifobj->xsk_arr[j])); ifobj->xsk_arr[j].rxqsize = XSK_RING_CONS__DEFAULT_NUM_DESCS; ifobj->xsk_arr[j].batch_size = DEFAULT_BATCH_SIZE; if (i == 0) ifobj->xsk_arr[j].pkt_stream = test->tx_pkt_stream_default; else ifobj->xsk_arr[j].pkt_stream = test->rx_pkt_stream_default; memcpy(ifobj->xsk_arr[j].src_mac, g_mac, ETH_ALEN); memcpy(ifobj->xsk_arr[j].dst_mac, g_mac, ETH_ALEN); ifobj->xsk_arr[j].src_mac[5] += ((j * 2) + 0); ifobj->xsk_arr[j].dst_mac[5] += ((j * 2) + 1); } } if (ifobj_tx->hw_ring_size_supp) hw_ring_size_reset(ifobj_tx); test->ifobj_tx = ifobj_tx; test->ifobj_rx = ifobj_rx; test->current_step = 0; test->total_steps = 1; test->nb_sockets = 1; test->fail = false; test->set_ring = false; test->adjust_tail = false; test->adjust_tail_support = false; test->mtu = MAX_ETH_PKT_SIZE; test->xdp_prog_rx = ifobj_rx->xdp_progs->progs.xsk_def_prog; test->xskmap_rx = ifobj_rx->xdp_progs->maps.xsk; test->xdp_prog_tx = ifobj_tx->xdp_progs->progs.xsk_def_prog; test->xskmap_tx = ifobj_tx->xdp_progs->maps.xsk; } void test_init(struct test_spec *test, struct ifobject *ifobj_tx, struct ifobject *ifobj_rx, enum test_mode mode, const struct test_spec *test_to_run) { struct pkt_stream *tx_pkt_stream; struct pkt_stream *rx_pkt_stream; u32 i; tx_pkt_stream = test->tx_pkt_stream_default; rx_pkt_stream = test->rx_pkt_stream_default; memset(test, 0, sizeof(*test)); test->tx_pkt_stream_default = tx_pkt_stream; test->rx_pkt_stream_default = rx_pkt_stream; for (i = 0; i < MAX_INTERFACES; i++) { struct ifobject *ifobj = i ? ifobj_rx : ifobj_tx; ifobj->bind_flags = XDP_USE_NEED_WAKEUP; if (mode == TEST_MODE_ZC) ifobj->bind_flags |= XDP_ZEROCOPY; else ifobj->bind_flags |= XDP_COPY; } memcpy(test->name, test_to_run->name, MAX_TEST_NAME_SIZE); test->test_func = test_to_run->test_func; test->mode = mode; __test_spec_init(test, ifobj_tx, ifobj_rx); } static void test_spec_reset(struct test_spec *test) { __test_spec_init(test, test->ifobj_tx, test->ifobj_rx); } static void test_spec_set_xdp_prog(struct test_spec *test, struct bpf_program *xdp_prog_rx, struct bpf_program *xdp_prog_tx, struct bpf_map *xskmap_rx, struct bpf_map *xskmap_tx) { test->xdp_prog_rx = xdp_prog_rx; test->xdp_prog_tx = xdp_prog_tx; test->xskmap_rx = xskmap_rx; test->xskmap_tx = xskmap_tx; } static int test_spec_set_mtu(struct test_spec *test, int mtu) { int err; if (test->ifobj_rx->mtu != mtu) { err = xsk_set_mtu(test->ifobj_rx->ifindex, mtu); if (err) return err; test->ifobj_rx->mtu = mtu; } if (test->ifobj_tx->mtu != mtu) { err = xsk_set_mtu(test->ifobj_tx->ifindex, mtu); if (err) return err; test->ifobj_tx->mtu = mtu; } return 0; } void pkt_stream_reset(struct pkt_stream *pkt_stream) { if (pkt_stream) { pkt_stream->current_pkt_nb = 0; pkt_stream->nb_rx_pkts = 0; } } static struct pkt *pkt_stream_get_next_tx_pkt(struct pkt_stream *pkt_stream) { if (pkt_stream->current_pkt_nb >= pkt_stream->nb_pkts) return NULL; return &pkt_stream->pkts[pkt_stream->current_pkt_nb++]; } static struct pkt *pkt_stream_get_next_rx_pkt(struct pkt_stream *pkt_stream, u32 *pkts_sent) { while (pkt_stream->current_pkt_nb < pkt_stream->nb_pkts) { (*pkts_sent)++; if (pkt_stream->pkts[pkt_stream->current_pkt_nb].valid) return &pkt_stream->pkts[pkt_stream->current_pkt_nb++]; pkt_stream->current_pkt_nb++; } return NULL; } void pkt_stream_delete(struct pkt_stream *pkt_stream) { free(pkt_stream->pkts); free(pkt_stream); } void pkt_stream_restore_default(struct test_spec *test) { struct pkt_stream *tx_pkt_stream = test->ifobj_tx->xsk->pkt_stream; struct pkt_stream *rx_pkt_stream = test->ifobj_rx->xsk->pkt_stream; if (tx_pkt_stream != test->tx_pkt_stream_default) { pkt_stream_delete(test->ifobj_tx->xsk->pkt_stream); test->ifobj_tx->xsk->pkt_stream = test->tx_pkt_stream_default; } if (rx_pkt_stream != test->rx_pkt_stream_default) { pkt_stream_delete(test->ifobj_rx->xsk->pkt_stream); test->ifobj_rx->xsk->pkt_stream = test->rx_pkt_stream_default; } } static struct pkt_stream *__pkt_stream_alloc(u32 nb_pkts) { struct pkt_stream *pkt_stream; pkt_stream = calloc(1, sizeof(*pkt_stream)); if (!pkt_stream) return NULL; pkt_stream->pkts = calloc(nb_pkts, sizeof(*pkt_stream->pkts)); if (!pkt_stream->pkts) { free(pkt_stream); return NULL; } pkt_stream->nb_pkts = nb_pkts; return pkt_stream; } static u32 pkt_nb_frags(u32 frame_size, struct pkt_stream *pkt_stream, struct pkt *pkt) { u32 nb_frags = 1, next_frag; if (!pkt) return 1; if (!pkt_stream->verbatim) { if (!pkt->valid || !pkt->len) return 1; return ceil_u32(pkt->len, frame_size); } /* Search for the end of the packet in verbatim mode */ if (!pkt_continues(pkt->options)) return nb_frags; next_frag = pkt_stream->current_pkt_nb; pkt++; while (next_frag++ < pkt_stream->nb_pkts) { nb_frags++; if (!pkt_continues(pkt->options) || !pkt->valid) break; pkt++; } return nb_frags; } static bool set_pkt_valid(int offset, u32 len) { return len <= MAX_ETH_JUMBO_SIZE; } static void pkt_set(struct pkt_stream *pkt_stream, struct pkt *pkt, int offset, u32 len) { pkt->offset = offset; pkt->len = len; pkt->valid = set_pkt_valid(offset, len); } static void pkt_stream_pkt_set(struct pkt_stream *pkt_stream, struct pkt *pkt, int offset, u32 len) { bool prev_pkt_valid = pkt->valid; pkt_set(pkt_stream, pkt, offset, len); pkt_stream->nb_valid_entries += pkt->valid - prev_pkt_valid; } static u32 pkt_get_buffer_len(struct xsk_umem_info *umem, u32 len) { return ceil_u32(len, umem->frame_size) * umem->frame_size; } static struct pkt_stream *__pkt_stream_generate(u32 nb_pkts, u32 pkt_len, u32 nb_start, u32 nb_off) { struct pkt_stream *pkt_stream; u32 i; pkt_stream = __pkt_stream_alloc(nb_pkts); if (!pkt_stream) return NULL; pkt_stream->nb_pkts = nb_pkts; pkt_stream->max_pkt_len = pkt_len; for (i = 0; i < nb_pkts; i++) { struct pkt *pkt = &pkt_stream->pkts[i]; pkt_stream_pkt_set(pkt_stream, pkt, 0, pkt_len); pkt->pkt_nb = nb_start + i * nb_off; } return pkt_stream; } struct pkt_stream *pkt_stream_generate(u32 nb_pkts, u32 pkt_len) { return __pkt_stream_generate(nb_pkts, pkt_len, 0, 1); } static struct pkt_stream *pkt_stream_clone(struct pkt_stream *pkt_stream) { return pkt_stream_generate(pkt_stream->nb_pkts, pkt_stream->pkts[0].len); } static int pkt_stream_replace_ifobject(struct ifobject *ifobj, u32 nb_pkts, u32 pkt_len) { ifobj->xsk->pkt_stream = pkt_stream_generate(nb_pkts, pkt_len); if (!ifobj->xsk->pkt_stream) return -ENOMEM; return 0; } static int pkt_stream_replace(struct test_spec *test, u32 nb_pkts, u32 pkt_len) { int ret; ret = pkt_stream_replace_ifobject(test->ifobj_tx, nb_pkts, pkt_len); if (ret) return ret; return pkt_stream_replace_ifobject(test->ifobj_rx, nb_pkts, pkt_len); } static int __pkt_stream_replace_half(struct ifobject *ifobj, u32 pkt_len, int offset) { struct pkt_stream *pkt_stream; u32 i; pkt_stream = pkt_stream_clone(ifobj->xsk->pkt_stream); if (!pkt_stream) return -ENOMEM; for (i = 1; i < ifobj->xsk->pkt_stream->nb_pkts; i += 2) pkt_stream_pkt_set(pkt_stream, &pkt_stream->pkts[i], offset, pkt_len); ifobj->xsk->pkt_stream = pkt_stream; return 0; } static int pkt_stream_replace_half(struct test_spec *test, u32 pkt_len, int offset) { int ret = __pkt_stream_replace_half(test->ifobj_tx, pkt_len, offset); if (ret) return ret; return __pkt_stream_replace_half(test->ifobj_rx, pkt_len, offset); } static int pkt_stream_receive_half(struct test_spec *test) { struct pkt_stream *pkt_stream = test->ifobj_tx->xsk->pkt_stream; u32 i; if (test->ifobj_rx->xsk->pkt_stream != test->rx_pkt_stream_default) /* Packet stream has already been replaced so we have to release this one. * The newly created one will be freed by the restore_default() at the * end of the test */ pkt_stream_delete(test->ifobj_rx->xsk->pkt_stream); test->ifobj_rx->xsk->pkt_stream = pkt_stream_generate(pkt_stream->nb_pkts, pkt_stream->pkts[0].len); if (!test->ifobj_rx->xsk->pkt_stream) return -ENOMEM; pkt_stream = test->ifobj_rx->xsk->pkt_stream; for (i = 1; i < pkt_stream->nb_pkts; i += 2) pkt_stream->pkts[i].valid = false; pkt_stream->nb_valid_entries /= 2; return 0; } static int pkt_stream_even_odd_sequence(struct test_spec *test) { struct pkt_stream *pkt_stream; u32 i; for (i = 0; i < test->nb_sockets; i++) { pkt_stream = test->ifobj_tx->xsk_arr[i].pkt_stream; pkt_stream = __pkt_stream_generate(pkt_stream->nb_pkts / 2, pkt_stream->pkts[0].len, i, 2); if (!pkt_stream) return -ENOMEM; test->ifobj_tx->xsk_arr[i].pkt_stream = pkt_stream; pkt_stream = test->ifobj_rx->xsk_arr[i].pkt_stream; pkt_stream = __pkt_stream_generate(pkt_stream->nb_pkts / 2, pkt_stream->pkts[0].len, i, 2); if (!pkt_stream) return -ENOMEM; test->ifobj_rx->xsk_arr[i].pkt_stream = pkt_stream; } return 0; } static void release_even_odd_sequence(struct test_spec *test) { struct pkt_stream *later_free_tx = test->ifobj_tx->xsk->pkt_stream; struct pkt_stream *later_free_rx = test->ifobj_rx->xsk->pkt_stream; int i; for (i = 0; i < test->nb_sockets; i++) { /* later_free_{rx/tx} will be freed by restore_default() */ if (test->ifobj_tx->xsk_arr[i].pkt_stream != later_free_tx) pkt_stream_delete(test->ifobj_tx->xsk_arr[i].pkt_stream); if (test->ifobj_rx->xsk_arr[i].pkt_stream != later_free_rx) pkt_stream_delete(test->ifobj_rx->xsk_arr[i].pkt_stream); } } static u64 pkt_get_addr(struct pkt *pkt, struct xsk_umem_info *umem) { if (!pkt->valid) return pkt->offset; return pkt->offset + umem_alloc_buffer(umem); } static void pkt_stream_cancel(struct pkt_stream *pkt_stream) { pkt_stream->current_pkt_nb--; } static void pkt_generate(struct xsk_socket_info *xsk, struct xsk_umem_info *umem, u64 addr, u32 len, u32 pkt_nb, u32 bytes_written) { void *data = xsk_umem__get_data(umem->buffer, addr); if (len < MIN_PKT_SIZE) return; if (!bytes_written) { gen_eth_hdr(xsk, data); len -= PKT_HDR_SIZE; data += PKT_HDR_SIZE; } else { bytes_written -= PKT_HDR_SIZE; } write_payload(data, pkt_nb, bytes_written, len); } static struct pkt_stream *__pkt_stream_generate_custom(struct ifobject *ifobj, struct pkt *frames, u32 nb_frames, bool verbatim) { u32 i, len = 0, pkt_nb = 0, payload = 0; struct pkt_stream *pkt_stream; pkt_stream = __pkt_stream_alloc(nb_frames); if (!pkt_stream) return NULL; for (i = 0; i < nb_frames; i++) { struct pkt *pkt = &pkt_stream->pkts[pkt_nb]; struct pkt *frame = &frames[i]; pkt->offset = frame->offset; if (verbatim) { *pkt = *frame; pkt->pkt_nb = payload; if (!frame->valid || !pkt_continues(frame->options)) payload++; } else { if (frame->valid) len += frame->len; if (frame->valid && pkt_continues(frame->options)) continue; pkt->pkt_nb = pkt_nb; pkt->len = len; pkt->valid = frame->valid; pkt->options = 0; len = 0; } print_verbose("offset: %d len: %u valid: %u options: %u pkt_nb: %u\n", pkt->offset, pkt->len, pkt->valid, pkt->options, pkt->pkt_nb); if (pkt->valid && pkt->len > pkt_stream->max_pkt_len) pkt_stream->max_pkt_len = pkt->len; if (pkt->valid) pkt_stream->nb_valid_entries++; pkt_nb++; } pkt_stream->nb_pkts = pkt_nb; pkt_stream->verbatim = verbatim; return pkt_stream; } static int pkt_stream_generate_custom(struct test_spec *test, struct pkt *pkts, u32 nb_pkts) { struct pkt_stream *pkt_stream; pkt_stream = __pkt_stream_generate_custom(test->ifobj_tx, pkts, nb_pkts, true); if (!pkt_stream) return -ENOMEM; test->ifobj_tx->xsk->pkt_stream = pkt_stream; pkt_stream = __pkt_stream_generate_custom(test->ifobj_rx, pkts, nb_pkts, false); if (!pkt_stream) return -ENOMEM; test->ifobj_rx->xsk->pkt_stream = pkt_stream; return 0; } static void pkt_print_data(u32 *data, u32 cnt) { u32 i; for (i = 0; i < cnt; i++) { u32 seqnum, pkt_nb; seqnum = ntohl(*data) & 0xffff; pkt_nb = ntohl(*data) >> 16; ksft_print_msg("%u:%u ", pkt_nb, seqnum); data++; } } static void pkt_dump(void *pkt, u32 len, bool eth_header) { struct ethhdr *ethhdr = pkt; u32 i, *data; if (eth_header) { /*extract L2 frame */ ksft_print_msg("DEBUG>> L2: dst mac: "); for (i = 0; i < ETH_ALEN; i++) ksft_print_msg("%02X", ethhdr->h_dest[i]); ksft_print_msg("\nDEBUG>> L2: src mac: "); for (i = 0; i < ETH_ALEN; i++) ksft_print_msg("%02X", ethhdr->h_source[i]); data = pkt + PKT_HDR_SIZE; } else { data = pkt; } /*extract L5 frame */ ksft_print_msg("\nDEBUG>> L5: seqnum: "); pkt_print_data(data, PKT_DUMP_NB_TO_PRINT); ksft_print_msg("...."); if (len > PKT_DUMP_NB_TO_PRINT * sizeof(u32)) { ksft_print_msg("\n.... "); pkt_print_data(data + len / sizeof(u32) - PKT_DUMP_NB_TO_PRINT, PKT_DUMP_NB_TO_PRINT); } ksft_print_msg("\n---------------------------------------\n"); } static bool is_offset_correct(struct xsk_umem_info *umem, struct pkt *pkt, u64 addr) { u32 headroom = umem->unaligned_mode ? 0 : umem->frame_headroom; u32 offset = addr % umem->frame_size, expected_offset; int pkt_offset = pkt->valid ? pkt->offset : 0; if (!umem->unaligned_mode) pkt_offset = 0; expected_offset = (pkt_offset + headroom + XDP_PACKET_HEADROOM) % umem->frame_size; if (offset == expected_offset) return true; ksft_print_msg("[%s] expected [%u], got [%u]\n", __func__, expected_offset, offset); return false; } static bool is_metadata_correct(struct pkt *pkt, void *buffer, u64 addr) { void *data = xsk_umem__get_data(buffer, addr); struct xdp_info *meta = data - sizeof(struct xdp_info); if (meta->count != pkt->pkt_nb) { ksft_print_msg("[%s] expected meta_count [%d], got meta_count [%llu]\n", __func__, pkt->pkt_nb, (unsigned long long)meta->count); return false; } return true; } static int is_adjust_tail_supported(struct xsk_xdp_progs *skel_rx, bool *supported) { struct bpf_map *data_map; int adjust_value = 0; int key = 0; int ret; data_map = bpf_object__find_map_by_name(skel_rx->obj, "xsk_xdp_.bss"); if (!data_map || !bpf_map__is_internal(data_map)) { ksft_print_msg("Error: could not find bss section of XDP program\n"); return -EINVAL; } ret = bpf_map_lookup_elem(bpf_map__fd(data_map), &key, &adjust_value); if (ret) { ksft_print_msg("Error: bpf_map_lookup_elem failed with error %d\n", ret); return ret; } /* Set the 'adjust_value' variable to -EOPNOTSUPP in the XDP program if the adjust_tail * helper is not supported. Skip the adjust_tail test case in this scenario. */ *supported = adjust_value != -EOPNOTSUPP; return 0; } static bool is_frag_valid(struct xsk_umem_info *umem, u64 addr, u32 len, u32 expected_pkt_nb, u32 bytes_processed) { u32 seqnum, pkt_nb, *pkt_data, words_to_end, expected_seqnum; void *data = xsk_umem__get_data(umem->buffer, addr); addr -= umem->base_addr; if (addr >= umem->num_frames * umem->frame_size || addr + len > umem->num_frames * umem->frame_size) { ksft_print_msg("Frag invalid addr: %llx len: %u\n", (unsigned long long)addr, len); return false; } if (!umem->unaligned_mode && addr % umem->frame_size + len > umem->frame_size) { ksft_print_msg("Frag crosses frame boundary addr: %llx len: %u\n", (unsigned long long)addr, len); return false; } pkt_data = data; if (!bytes_processed) { pkt_data += PKT_HDR_SIZE / sizeof(*pkt_data); len -= PKT_HDR_SIZE; } else { bytes_processed -= PKT_HDR_SIZE; } expected_seqnum = bytes_processed / sizeof(*pkt_data); seqnum = ntohl(*pkt_data) & 0xffff; pkt_nb = ntohl(*pkt_data) >> 16; if (expected_pkt_nb != pkt_nb) { ksft_print_msg("[%s] expected pkt_nb [%u], got pkt_nb [%u]\n", __func__, expected_pkt_nb, pkt_nb); goto error; } if (expected_seqnum != seqnum) { ksft_print_msg("[%s] expected seqnum at start [%u], got seqnum [%u]\n", __func__, expected_seqnum, seqnum); goto error; } words_to_end = len / sizeof(*pkt_data) - 1; pkt_data += words_to_end; seqnum = ntohl(*pkt_data) & 0xffff; expected_seqnum += words_to_end; if (expected_seqnum != seqnum) { ksft_print_msg("[%s] expected seqnum at end [%u], got seqnum [%u]\n", __func__, expected_seqnum, seqnum); goto error; } return true; error: pkt_dump(data, len, !bytes_processed); return false; } static bool is_pkt_valid(struct pkt *pkt, void *buffer, u64 addr, u32 len) { if (pkt->len != len) { ksft_print_msg("[%s] expected packet length [%d], got length [%d]\n", __func__, pkt->len, len); pkt_dump(xsk_umem__get_data(buffer, addr), len, true); return false; } return true; } static u32 load_value(u32 *counter) { return __atomic_load_n(counter, __ATOMIC_ACQUIRE); } static bool kick_tx_with_check(struct xsk_socket_info *xsk, int *ret) { u32 max_budget = MAX_TX_BUDGET_DEFAULT; u32 cons, ready_to_send; int delta; cons = load_value(xsk->tx.consumer); ready_to_send = load_value(xsk->tx.producer) - cons; *ret = sendto(xsk_socket__fd(xsk->xsk), NULL, 0, MSG_DONTWAIT, NULL, 0); delta = load_value(xsk->tx.consumer) - cons; /* By default, xsk should consume exact @max_budget descs at one * send in this case where hitting the max budget limit in while * loop is triggered in __xsk_generic_xmit(). Please make sure that * the number of descs to be sent is larger than @max_budget, or * else the tx.consumer will be updated in xskq_cons_peek_desc() * in time which hides the issue we try to verify. */ if (ready_to_send > max_budget && delta != max_budget) return false; return true; } int kick_tx(struct xsk_socket_info *xsk) { int ret; if (xsk->check_consumer) { if (!kick_tx_with_check(xsk, &ret)) return TEST_FAILURE; } else { ret = sendto(xsk_socket__fd(xsk->xsk), NULL, 0, MSG_DONTWAIT, NULL, 0); } if (ret >= 0) return TEST_PASS; if (errno == ENOBUFS || errno == EAGAIN || errno == EBUSY || errno == ENETDOWN) { usleep(100); return TEST_PASS; } return TEST_FAILURE; } int kick_rx(struct xsk_socket_info *xsk) { int ret; ret = recvfrom(xsk_socket__fd(xsk->xsk), NULL, 0, MSG_DONTWAIT, NULL, NULL); if (ret < 0) return TEST_FAILURE; return TEST_PASS; } static int complete_pkts(struct xsk_socket_info *xsk, int batch_size) { unsigned int rcvd; u32 idx; int ret; if (xsk_ring_prod__needs_wakeup(&xsk->tx)) { ret = kick_tx(xsk); if (ret) return TEST_FAILURE; } rcvd = xsk_ring_cons__peek(&xsk->umem->cq, batch_size, &idx); if (rcvd) { if (rcvd > xsk->outstanding_tx) { u64 addr = *xsk_ring_cons__comp_addr(&xsk->umem->cq, idx + rcvd - 1); ksft_print_msg("[%s] Too many packets completed\n", __func__); ksft_print_msg("Last completion address: %llx\n", (unsigned long long)addr); return TEST_FAILURE; } xsk_ring_cons__release(&xsk->umem->cq, rcvd); xsk->outstanding_tx -= rcvd; } return TEST_PASS; } static int __receive_pkts(struct test_spec *test, struct xsk_socket_info *xsk) { u32 frags_processed = 0, nb_frags = 0, pkt_len = 0; u32 idx_rx = 0, idx_fq = 0, rcvd, pkts_sent = 0; struct pkt_stream *pkt_stream = xsk->pkt_stream; struct ifobject *ifobj = test->ifobj_rx; struct xsk_umem_info *umem = xsk->umem; struct pollfd fds = { }; struct pkt *pkt; u64 first_addr = 0; int ret; fds.fd = xsk_socket__fd(xsk->xsk); fds.events = POLLIN; ret = kick_rx(xsk); if (ret) return TEST_FAILURE; if (ifobj->use_poll) { ret = poll(&fds, 1, POLL_TMOUT); if (ret < 0) return TEST_FAILURE; if (!ret) { if (!is_umem_valid(test->ifobj_tx)) return TEST_PASS; ksft_print_msg("ERROR: [%s] Poll timed out\n", __func__); return TEST_CONTINUE; } if (!(fds.revents & POLLIN)) return TEST_CONTINUE; } rcvd = xsk_ring_cons__peek(&xsk->rx, xsk->batch_size, &idx_rx); if (!rcvd) return TEST_CONTINUE; if (ifobj->use_fill_ring) { ret = xsk_ring_prod__reserve(&umem->fq, rcvd, &idx_fq); while (ret != rcvd) { if (xsk_ring_prod__needs_wakeup(&umem->fq)) { ret = poll(&fds, 1, POLL_TMOUT); if (ret < 0) return TEST_FAILURE; } ret = xsk_ring_prod__reserve(&umem->fq, rcvd, &idx_fq); } } while (frags_processed < rcvd) { const struct xdp_desc *desc = xsk_ring_cons__rx_desc(&xsk->rx, idx_rx++); u64 addr = desc->addr, orig; orig = xsk_umem__extract_addr(addr); addr = xsk_umem__add_offset_to_addr(addr); if (!nb_frags) { pkt = pkt_stream_get_next_rx_pkt(pkt_stream, &pkts_sent); if (!pkt) { ksft_print_msg("[%s] received too many packets addr: %lx len %u\n", __func__, addr, desc->len); return TEST_FAILURE; } } print_verbose("Rx: addr: %lx len: %u options: %u pkt_nb: %u valid: %u\n", addr, desc->len, desc->options, pkt->pkt_nb, pkt->valid); if (!is_frag_valid(umem, addr, desc->len, pkt->pkt_nb, pkt_len) || !is_offset_correct(umem, pkt, addr) || (ifobj->use_metadata && !is_metadata_correct(pkt, umem->buffer, addr))) return TEST_FAILURE; if (!nb_frags++) first_addr = addr; frags_processed++; pkt_len += desc->len; if (ifobj->use_fill_ring) *xsk_ring_prod__fill_addr(&umem->fq, idx_fq++) = orig; if (pkt_continues(desc->options)) continue; /* The complete packet has been received */ if (!is_pkt_valid(pkt, umem->buffer, first_addr, pkt_len) || !is_offset_correct(umem, pkt, addr)) return TEST_FAILURE; pkt_stream->nb_rx_pkts++; nb_frags = 0; pkt_len = 0; } if (nb_frags) { /* In the middle of a packet. Start over from beginning of packet. */ idx_rx -= nb_frags; xsk_ring_cons__cancel(&xsk->rx, nb_frags); if (ifobj->use_fill_ring) { idx_fq -= nb_frags; xsk_ring_prod__cancel(&umem->fq, nb_frags); } frags_processed -= nb_frags; } if (ifobj->use_fill_ring) xsk_ring_prod__submit(&umem->fq, frags_processed); if (ifobj->release_rx) xsk_ring_cons__release(&xsk->rx, frags_processed); pthread_mutex_lock(&pacing_mutex); pkts_in_flight -= pkts_sent; pthread_mutex_unlock(&pacing_mutex); pkts_sent = 0; return TEST_CONTINUE; } bool all_packets_received(struct test_spec *test, struct xsk_socket_info *xsk, u32 sock_num, unsigned long *bitmap) { struct pkt_stream *pkt_stream = xsk->pkt_stream; if (!pkt_stream) { __set_bit(sock_num, bitmap); return false; } if (pkt_stream->nb_rx_pkts == pkt_stream->nb_valid_entries) { __set_bit(sock_num, bitmap); if (bitmap_full(bitmap, test->nb_sockets)) return true; } return false; } static int receive_pkts(struct test_spec *test) { struct timeval tv_end, tv_now, tv_timeout = {THREAD_TMOUT, 0}; DECLARE_BITMAP(bitmap, test->nb_sockets); struct xsk_socket_info *xsk; u32 sock_num = 0; int res, ret; bitmap_zero(bitmap, test->nb_sockets); ret = gettimeofday(&tv_now, NULL); if (ret) return TEST_FAILURE; timeradd(&tv_now, &tv_timeout, &tv_end); while (1) { xsk = &test->ifobj_rx->xsk_arr[sock_num]; if ((all_packets_received(test, xsk, sock_num, bitmap))) break; res = __receive_pkts(test, xsk); if (!(res == TEST_PASS || res == TEST_CONTINUE)) return res; ret = gettimeofday(&tv_now, NULL); if (ret) return TEST_FAILURE; if (timercmp(&tv_now, &tv_end, >)) { ksft_print_msg("ERROR: [%s] Receive loop timed out\n", __func__); return TEST_FAILURE; } sock_num = (sock_num + 1) % test->nb_sockets; } return TEST_PASS; } static int __send_pkts(struct ifobject *ifobject, struct xsk_socket_info *xsk, bool timeout) { u32 i, idx = 0, valid_pkts = 0, valid_frags = 0, buffer_len; struct pkt_stream *pkt_stream = xsk->pkt_stream; struct xsk_umem_info *umem = ifobject->umem; bool use_poll = ifobject->use_poll; struct pollfd fds = { }; int ret; buffer_len = pkt_get_buffer_len(umem, pkt_stream->max_pkt_len); /* pkts_in_flight might be negative if many invalid packets are sent */ if (pkts_in_flight >= (int)((umem_size(umem) - xsk->batch_size * buffer_len) / buffer_len)) { ret = kick_tx(xsk); if (ret) return TEST_FAILURE; return TEST_CONTINUE; } fds.fd = xsk_socket__fd(xsk->xsk); fds.events = POLLOUT; while (xsk_ring_prod__reserve(&xsk->tx, xsk->batch_size, &idx) < xsk->batch_size) { if (use_poll) { ret = poll(&fds, 1, POLL_TMOUT); if (timeout) { if (ret < 0) { ksft_print_msg("ERROR: [%s] Poll error %d\n", __func__, errno); return TEST_FAILURE; } if (ret == 0) return TEST_PASS; break; } if (ret <= 0) { ksft_print_msg("ERROR: [%s] Poll error %d\n", __func__, errno); return TEST_FAILURE; } } complete_pkts(xsk, xsk->batch_size); } for (i = 0; i < xsk->batch_size; i++) { struct pkt *pkt = pkt_stream_get_next_tx_pkt(pkt_stream); u32 nb_frags_left, nb_frags, bytes_written = 0; if (!pkt) break; nb_frags = pkt_nb_frags(umem->frame_size, pkt_stream, pkt); if (nb_frags > xsk->batch_size - i) { pkt_stream_cancel(pkt_stream); xsk_ring_prod__cancel(&xsk->tx, xsk->batch_size - i); break; } nb_frags_left = nb_frags; while (nb_frags_left--) { struct xdp_desc *tx_desc = xsk_ring_prod__tx_desc(&xsk->tx, idx + i); tx_desc->addr = pkt_get_addr(pkt, ifobject->umem); if (pkt_stream->verbatim) { tx_desc->len = pkt->len; tx_desc->options = pkt->options; } else if (nb_frags_left) { tx_desc->len = umem->frame_size; tx_desc->options = XDP_PKT_CONTD; } else { tx_desc->len = pkt->len - bytes_written; tx_desc->options = 0; } if (pkt->valid) pkt_generate(xsk, umem, tx_desc->addr, tx_desc->len, pkt->pkt_nb, bytes_written); bytes_written += tx_desc->len; print_verbose("Tx addr: %llx len: %u options: %u pkt_nb: %u\n", tx_desc->addr, tx_desc->len, tx_desc->options, pkt->pkt_nb); if (nb_frags_left) { i++; if (pkt_stream->verbatim) pkt = pkt_stream_get_next_tx_pkt(pkt_stream); } } if (pkt && pkt->valid) { valid_pkts++; valid_frags += nb_frags; } } pthread_mutex_lock(&pacing_mutex); pkts_in_flight += valid_pkts; pthread_mutex_unlock(&pacing_mutex); xsk_ring_prod__submit(&xsk->tx, i); xsk->outstanding_tx += valid_frags; if (use_poll) { ret = poll(&fds, 1, POLL_TMOUT); if (ret <= 0) { if (ret == 0 && timeout) return TEST_PASS; ksft_print_msg("ERROR: [%s] Poll error %d\n", __func__, ret); return TEST_FAILURE; } } if (!timeout) { if (complete_pkts(xsk, i)) return TEST_FAILURE; usleep(10); return TEST_PASS; } return TEST_CONTINUE; } static int wait_for_tx_completion(struct xsk_socket_info *xsk) { struct timeval tv_end, tv_now, tv_timeout = {THREAD_TMOUT, 0}; int ret; ret = gettimeofday(&tv_now, NULL); if (ret) return TEST_FAILURE; timeradd(&tv_now, &tv_timeout, &tv_end); while (xsk->outstanding_tx) { ret = gettimeofday(&tv_now, NULL); if (ret) return TEST_FAILURE; if (timercmp(&tv_now, &tv_end, >)) { ksft_print_msg("ERROR: [%s] Transmission loop timed out\n", __func__); return TEST_FAILURE; } complete_pkts(xsk, xsk->batch_size); } return TEST_PASS; } bool all_packets_sent(struct test_spec *test, unsigned long *bitmap) { return bitmap_full(bitmap, test->nb_sockets); } static int send_pkts(struct test_spec *test, struct ifobject *ifobject) { bool timeout = !is_umem_valid(test->ifobj_rx); DECLARE_BITMAP(bitmap, test->nb_sockets); u32 i, ret; bitmap_zero(bitmap, test->nb_sockets); while (!(all_packets_sent(test, bitmap))) { for (i = 0; i < test->nb_sockets; i++) { struct pkt_stream *pkt_stream; pkt_stream = ifobject->xsk_arr[i].pkt_stream; if (!pkt_stream || pkt_stream->current_pkt_nb >= pkt_stream->nb_pkts) { __set_bit(i, bitmap); continue; } ret = __send_pkts(ifobject, &ifobject->xsk_arr[i], timeout); if (ret == TEST_CONTINUE && !test->fail) continue; if ((ret || test->fail) && !timeout) return TEST_FAILURE; if (ret == TEST_PASS && timeout) return ret; ret = wait_for_tx_completion(&ifobject->xsk_arr[i]); if (ret) return TEST_FAILURE; } } return TEST_PASS; } static int get_xsk_stats(struct xsk_socket *xsk, struct xdp_statistics *stats) { int fd = xsk_socket__fd(xsk), err; socklen_t optlen, expected_len; optlen = sizeof(*stats); err = getsockopt(fd, SOL_XDP, XDP_STATISTICS, stats, &optlen); if (err) { ksft_print_msg("[%s] getsockopt(XDP_STATISTICS) error %u %s\n", __func__, -err, strerror(-err)); return TEST_FAILURE; } expected_len = sizeof(struct xdp_statistics); if (optlen != expected_len) { ksft_print_msg("[%s] getsockopt optlen error. Expected: %u got: %u\n", __func__, expected_len, optlen); return TEST_FAILURE; } return TEST_PASS; } static int validate_rx_dropped(struct ifobject *ifobject) { struct xsk_socket *xsk = ifobject->xsk->xsk; struct xdp_statistics stats; int err; err = kick_rx(ifobject->xsk); if (err) return TEST_FAILURE; err = get_xsk_stats(xsk, &stats); if (err) return TEST_FAILURE; /* The receiver calls getsockopt after receiving the last (valid) * packet which is not the final packet sent in this test (valid and * invalid packets are sent in alternating fashion with the final * packet being invalid). Since the last packet may or may not have * been dropped already, both outcomes must be allowed. */ if (stats.rx_dropped == ifobject->xsk->pkt_stream->nb_pkts / 2 || stats.rx_dropped == ifobject->xsk->pkt_stream->nb_pkts / 2 - 1) return TEST_PASS; return TEST_FAILURE; } static int validate_rx_full(struct ifobject *ifobject) { struct xsk_socket *xsk = ifobject->xsk->xsk; struct xdp_statistics stats; int err; usleep(1000); err = kick_rx(ifobject->xsk); if (err) return TEST_FAILURE; err = get_xsk_stats(xsk, &stats); if (err) return TEST_FAILURE; if (stats.rx_ring_full) return TEST_PASS; return TEST_FAILURE; } static int validate_fill_empty(struct ifobject *ifobject) { struct xsk_socket *xsk = ifobject->xsk->xsk; struct xdp_statistics stats; int err; usleep(1000); err = kick_rx(ifobject->xsk); if (err) return TEST_FAILURE; err = get_xsk_stats(xsk, &stats); if (err) return TEST_FAILURE; if (stats.rx_fill_ring_empty_descs) return TEST_PASS; return TEST_FAILURE; } static int validate_tx_invalid_descs(struct ifobject *ifobject) { struct xsk_socket *xsk = ifobject->xsk->xsk; int fd = xsk_socket__fd(xsk); struct xdp_statistics stats; socklen_t optlen; int err; optlen = sizeof(stats); err = getsockopt(fd, SOL_XDP, XDP_STATISTICS, &stats, &optlen); if (err) { ksft_print_msg("[%s] getsockopt(XDP_STATISTICS) error %u %s\n", __func__, -err, strerror(-err)); return TEST_FAILURE; } if (stats.tx_invalid_descs != ifobject->xsk->pkt_stream->nb_pkts / 2) { ksft_print_msg("[%s] tx_invalid_descs incorrect. Got [%llu] expected [%u]\n", __func__, (unsigned long long)stats.tx_invalid_descs, ifobject->xsk->pkt_stream->nb_pkts); return TEST_FAILURE; } return TEST_PASS; } static int xsk_configure(struct test_spec *test, struct ifobject *ifobject, struct xsk_umem_info *umem, bool tx) { int i, ret; for (i = 0; i < test->nb_sockets; i++) { bool shared = (ifobject->shared_umem && tx) ? true : !!i; u32 ctr = 0; while (ctr++ < SOCK_RECONF_CTR) { ret = xsk_configure_socket(&ifobject->xsk_arr[i], umem, ifobject, shared); if (!ret) break; /* Retry if it fails as xsk_socket__create() is asynchronous */ if (ctr >= SOCK_RECONF_CTR) return ret; usleep(USLEEP_MAX); } if (ifobject->busy_poll) { ret = enable_busy_poll(&ifobject->xsk_arr[i]); if (ret) return ret; } } return 0; } static int thread_common_ops_tx(struct test_spec *test, struct ifobject *ifobject) { int ret = xsk_configure(test, ifobject, test->ifobj_rx->umem, true); if (ret) return ret; ifobject->xsk = &ifobject->xsk_arr[0]; ifobject->xskmap = test->ifobj_rx->xskmap; memcpy(ifobject->umem, test->ifobj_rx->umem, sizeof(struct xsk_umem_info)); ifobject->umem->base_addr = 0; return 0; } static int xsk_populate_fill_ring(struct xsk_umem_info *umem, struct pkt_stream *pkt_stream, bool fill_up) { u32 rx_frame_size = umem->frame_size - XDP_PACKET_HEADROOM; u32 idx = 0, filled = 0, buffers_to_fill, nb_pkts; int ret; if (umem->num_frames < XSK_RING_PROD__DEFAULT_NUM_DESCS) buffers_to_fill = umem->num_frames; else buffers_to_fill = umem->fill_size; ret = xsk_ring_prod__reserve(&umem->fq, buffers_to_fill, &idx); if (ret != buffers_to_fill) return -ENOSPC; while (filled < buffers_to_fill) { struct pkt *pkt = pkt_stream_get_next_rx_pkt(pkt_stream, &nb_pkts); u64 addr; u32 i; for (i = 0; i < pkt_nb_frags(rx_frame_size, pkt_stream, pkt); i++) { if (!pkt) { if (!fill_up) break; addr = filled * umem->frame_size + umem->base_addr; } else if (pkt->offset >= 0) { addr = pkt->offset % umem->frame_size + umem_alloc_buffer(umem); } else { addr = pkt->offset + umem_alloc_buffer(umem); } *xsk_ring_prod__fill_addr(&umem->fq, idx++) = addr; if (++filled >= buffers_to_fill) break; } } xsk_ring_prod__submit(&umem->fq, filled); xsk_ring_prod__cancel(&umem->fq, buffers_to_fill - filled); pkt_stream_reset(pkt_stream); umem_reset_alloc(umem); return 0; } static int thread_common_ops(struct test_spec *test, struct ifobject *ifobject) { LIBBPF_OPTS(bpf_xdp_query_opts, opts); int mmap_flags; u64 umem_sz; void *bufs; int ret; u32 i; umem_sz = ifobject->umem->num_frames * ifobject->umem->frame_size; mmap_flags = MAP_PRIVATE | MAP_ANONYMOUS | MAP_NORESERVE; if (ifobject->umem->unaligned_mode) mmap_flags |= MAP_HUGETLB | MAP_HUGE_2MB; if (ifobject->shared_umem) umem_sz *= 2; bufs = mmap(NULL, umem_sz, PROT_READ | PROT_WRITE, mmap_flags, -1, 0); if (bufs == MAP_FAILED) return -errno; ret = xsk_configure_umem(ifobject, ifobject->umem, bufs, umem_sz); if (ret) return ret; ret = xsk_configure(test, ifobject, ifobject->umem, false); if (ret) return ret; ifobject->xsk = &ifobject->xsk_arr[0]; if (!ifobject->rx_on) return 0; ret = xsk_populate_fill_ring(ifobject->umem, ifobject->xsk->pkt_stream, ifobject->use_fill_ring); if (ret) return ret; for (i = 0; i < test->nb_sockets; i++) { ifobject->xsk = &ifobject->xsk_arr[i]; ret = xsk_update_xskmap(ifobject->xskmap, ifobject->xsk->xsk, i); if (ret) return ret; } return 0; } void *worker_testapp_validate_tx(void *arg) { struct test_spec *test = (struct test_spec *)arg; struct ifobject *ifobject = test->ifobj_tx; int err; if (test->current_step == 1) { if (!ifobject->shared_umem) { if (thread_common_ops(test, ifobject)) { test->fail = true; pthread_exit(NULL); } } else { if (thread_common_ops_tx(test, ifobject)) { test->fail = true; pthread_exit(NULL); } } } err = send_pkts(test, ifobject); if (!err && ifobject->validation_func) err = ifobject->validation_func(ifobject); if (err) test->fail = true; pthread_exit(NULL); } void *worker_testapp_validate_rx(void *arg) { struct test_spec *test = (struct test_spec *)arg; struct ifobject *ifobject = test->ifobj_rx; int err; if (test->current_step == 1) { err = thread_common_ops(test, ifobject); } else { xsk_clear_xskmap(ifobject->xskmap); err = xsk_update_xskmap(ifobject->xskmap, ifobject->xsk->xsk, 0); if (err) ksft_print_msg("Error: Failed to update xskmap, error %s\n", strerror(-err)); } pthread_barrier_wait(&barr); /* We leave only now in case of error to avoid getting stuck in the barrier */ if (err) { test->fail = true; pthread_exit(NULL); } err = receive_pkts(test); if (!err && ifobject->validation_func) err = ifobject->validation_func(ifobject); if (err) { if (!test->adjust_tail) { test->fail = true; } else { bool supported; if (is_adjust_tail_supported(ifobject->xdp_progs, &supported)) test->fail = true; else if (!supported) test->adjust_tail_support = false; else test->fail = true; } } pthread_exit(NULL); } static void testapp_clean_xsk_umem(struct ifobject *ifobj) { u64 umem_sz = ifobj->umem->num_frames * ifobj->umem->frame_size; if (ifobj->shared_umem) umem_sz *= 2; umem_sz = ceil_u64(umem_sz, HUGEPAGE_SIZE) * HUGEPAGE_SIZE; xsk_umem__delete(ifobj->umem->umem); munmap(ifobj->umem->buffer, umem_sz); } static void handler(int signum) { pthread_exit(NULL); } static bool xdp_prog_changed_rx(struct test_spec *test) { struct ifobject *ifobj = test->ifobj_rx; return ifobj->xdp_prog != test->xdp_prog_rx || ifobj->mode != test->mode; } static bool xdp_prog_changed_tx(struct test_spec *test) { struct ifobject *ifobj = test->ifobj_tx; return ifobj->xdp_prog != test->xdp_prog_tx || ifobj->mode != test->mode; } static int xsk_reattach_xdp(struct ifobject *ifobj, struct bpf_program *xdp_prog, struct bpf_map *xskmap, enum test_mode mode) { int err; xsk_detach_xdp_program(ifobj->ifindex, mode_to_xdp_flags(ifobj->mode)); err = xsk_attach_xdp_program(xdp_prog, ifobj->ifindex, mode_to_xdp_flags(mode)); if (err) { ksft_print_msg("Error attaching XDP program\n"); return err; } if (ifobj->mode != mode && (mode == TEST_MODE_DRV || mode == TEST_MODE_ZC)) if (!xsk_is_in_mode(ifobj->ifindex, XDP_FLAGS_DRV_MODE)) { ksft_print_msg("ERROR: XDP prog not in DRV mode\n"); return -EINVAL; } ifobj->xdp_prog = xdp_prog; ifobj->xskmap = xskmap; ifobj->mode = mode; return 0; } static int xsk_attach_xdp_progs(struct test_spec *test, struct ifobject *ifobj_rx, struct ifobject *ifobj_tx) { int err = 0; if (xdp_prog_changed_rx(test)) { err = xsk_reattach_xdp(ifobj_rx, test->xdp_prog_rx, test->xskmap_rx, test->mode); if (err) return err; } if (!ifobj_tx || ifobj_tx->shared_umem) return 0; if (xdp_prog_changed_tx(test)) err = xsk_reattach_xdp(ifobj_tx, test->xdp_prog_tx, test->xskmap_tx, test->mode); return err; } static void clean_sockets(struct test_spec *test, struct ifobject *ifobj) { u32 i; if (!ifobj || !test) return; for (i = 0; i < test->nb_sockets; i++) xsk_socket__delete(ifobj->xsk_arr[i].xsk); } static void clean_umem(struct test_spec *test, struct ifobject *ifobj1, struct ifobject *ifobj2) { if (!ifobj1) return; testapp_clean_xsk_umem(ifobj1); if (ifobj2 && !ifobj2->shared_umem) testapp_clean_xsk_umem(ifobj2); } static int __testapp_validate_traffic(struct test_spec *test, struct ifobject *ifobj1, struct ifobject *ifobj2) { pthread_t t0, t1; int err; if (test->mtu > MAX_ETH_PKT_SIZE) { if (test->mode == TEST_MODE_ZC && (!ifobj1->multi_buff_zc_supp || (ifobj2 && !ifobj2->multi_buff_zc_supp))) { ksft_print_msg("Multi buffer for zero-copy not supported.\n"); return TEST_SKIP; } if (test->mode != TEST_MODE_ZC && (!ifobj1->multi_buff_supp || (ifobj2 && !ifobj2->multi_buff_supp))) { ksft_print_msg("Multi buffer not supported.\n"); return TEST_SKIP; } } err = test_spec_set_mtu(test, test->mtu); if (err) { ksft_print_msg("Error, could not set mtu.\n"); return TEST_FAILURE; } if (ifobj2) { if (pthread_barrier_init(&barr, NULL, 2)) return TEST_FAILURE; pkt_stream_reset(ifobj2->xsk->pkt_stream); } test->current_step++; pkt_stream_reset(ifobj1->xsk->pkt_stream); pkts_in_flight = 0; signal(SIGUSR1, handler); /*Spawn RX thread */ pthread_create(&t0, NULL, ifobj1->func_ptr, test); if (ifobj2) { pthread_barrier_wait(&barr); if (pthread_barrier_destroy(&barr)) { pthread_kill(t0, SIGUSR1); clean_sockets(test, ifobj1); clean_umem(test, ifobj1, NULL); return TEST_FAILURE; } /*Spawn TX thread */ pthread_create(&t1, NULL, ifobj2->func_ptr, test); pthread_join(t1, NULL); } if (!ifobj2) pthread_kill(t0, SIGUSR1); else pthread_join(t0, NULL); if (test->total_steps == test->current_step || test->fail) { clean_sockets(test, ifobj1); clean_sockets(test, ifobj2); clean_umem(test, ifobj1, ifobj2); } if (test->fail) return TEST_FAILURE; return TEST_PASS; } static int testapp_validate_traffic(struct test_spec *test) { struct ifobject *ifobj_rx = test->ifobj_rx; struct ifobject *ifobj_tx = test->ifobj_tx; if ((ifobj_rx->umem->unaligned_mode && !ifobj_rx->unaligned_supp) || (ifobj_tx->umem->unaligned_mode && !ifobj_tx->unaligned_supp)) { ksft_print_msg("No huge pages present.\n"); return TEST_SKIP; } if (test->set_ring) { if (ifobj_tx->hw_ring_size_supp) { if (set_ring_size(ifobj_tx)) { ksft_print_msg("Failed to change HW ring size.\n"); return TEST_FAILURE; } } else { ksft_print_msg("Changing HW ring size not supported.\n"); return TEST_SKIP; } } if (xsk_attach_xdp_progs(test, ifobj_rx, ifobj_tx)) return TEST_FAILURE; return __testapp_validate_traffic(test, ifobj_rx, ifobj_tx); } static int testapp_validate_traffic_single_thread(struct test_spec *test, struct ifobject *ifobj) { return __testapp_validate_traffic(test, ifobj, NULL); } int testapp_teardown(struct test_spec *test) { int i; for (i = 0; i < MAX_TEARDOWN_ITER; i++) { if (testapp_validate_traffic(test)) return TEST_FAILURE; test_spec_reset(test); } return TEST_PASS; } static void swap_directions(struct ifobject **ifobj1, struct ifobject **ifobj2) { thread_func_t tmp_func_ptr = (*ifobj1)->func_ptr; struct ifobject *tmp_ifobj = (*ifobj1); (*ifobj1)->func_ptr = (*ifobj2)->func_ptr; (*ifobj2)->func_ptr = tmp_func_ptr; *ifobj1 = *ifobj2; *ifobj2 = tmp_ifobj; } int testapp_bidirectional(struct test_spec *test) { int res; test->ifobj_tx->rx_on = true; test->ifobj_rx->tx_on = true; test->total_steps = 2; if (testapp_validate_traffic(test)) return TEST_FAILURE; print_verbose("Switching Tx/Rx direction\n"); swap_directions(&test->ifobj_rx, &test->ifobj_tx); res = __testapp_validate_traffic(test, test->ifobj_rx, test->ifobj_tx); swap_directions(&test->ifobj_rx, &test->ifobj_tx); return res; } static int swap_xsk_resources(struct test_spec *test) { int ret; test->ifobj_tx->xsk_arr[0].pkt_stream = NULL; test->ifobj_rx->xsk_arr[0].pkt_stream = NULL; test->ifobj_tx->xsk_arr[1].pkt_stream = test->tx_pkt_stream_default; test->ifobj_rx->xsk_arr[1].pkt_stream = test->rx_pkt_stream_default; test->ifobj_tx->xsk = &test->ifobj_tx->xsk_arr[1]; test->ifobj_rx->xsk = &test->ifobj_rx->xsk_arr[1]; ret = xsk_update_xskmap(test->ifobj_rx->xskmap, test->ifobj_rx->xsk->xsk, 0); if (ret) return TEST_FAILURE; return TEST_PASS; } int testapp_xdp_prog_cleanup(struct test_spec *test) { test->total_steps = 2; test->nb_sockets = 2; if (testapp_validate_traffic(test)) return TEST_FAILURE; if (swap_xsk_resources(test)) { clean_sockets(test, test->ifobj_rx); clean_sockets(test, test->ifobj_tx); clean_umem(test, test->ifobj_rx, test->ifobj_tx); return TEST_FAILURE; } return testapp_validate_traffic(test); } int testapp_headroom(struct test_spec *test) { test->ifobj_rx->umem->frame_headroom = UMEM_HEADROOM_TEST_SIZE; return testapp_validate_traffic(test); } int testapp_stats_rx_dropped(struct test_spec *test) { if (test->mode == TEST_MODE_ZC) { ksft_print_msg("Can not run RX_DROPPED test for ZC mode\n"); return TEST_SKIP; } if (pkt_stream_replace_half(test, MIN_PKT_SIZE * 4, 0)) return TEST_FAILURE; test->ifobj_rx->umem->frame_headroom = test->ifobj_rx->umem->frame_size - XDP_PACKET_HEADROOM - MIN_PKT_SIZE * 3; if (pkt_stream_receive_half(test)) return TEST_FAILURE; test->ifobj_rx->validation_func = validate_rx_dropped; return testapp_validate_traffic(test); } int testapp_stats_tx_invalid_descs(struct test_spec *test) { if (pkt_stream_replace_half(test, XSK_UMEM__INVALID_FRAME_SIZE, 0)) return TEST_FAILURE; test->ifobj_tx->validation_func = validate_tx_invalid_descs; return testapp_validate_traffic(test); } int testapp_stats_rx_full(struct test_spec *test) { if (pkt_stream_replace(test, DEFAULT_UMEM_BUFFERS + DEFAULT_UMEM_BUFFERS / 2, MIN_PKT_SIZE)) return TEST_FAILURE; test->ifobj_rx->xsk->pkt_stream = pkt_stream_generate(DEFAULT_UMEM_BUFFERS, MIN_PKT_SIZE); test->ifobj_rx->xsk->rxqsize = DEFAULT_UMEM_BUFFERS; test->ifobj_rx->release_rx = false; test->ifobj_rx->validation_func = validate_rx_full; return testapp_validate_traffic(test); } int testapp_stats_fill_empty(struct test_spec *test) { if (pkt_stream_replace(test, DEFAULT_UMEM_BUFFERS + DEFAULT_UMEM_BUFFERS / 2, MIN_PKT_SIZE)) return TEST_FAILURE; test->ifobj_rx->xsk->pkt_stream = pkt_stream_generate(DEFAULT_UMEM_BUFFERS, MIN_PKT_SIZE); test->ifobj_rx->use_fill_ring = false; test->ifobj_rx->validation_func = validate_fill_empty; return testapp_validate_traffic(test); } int testapp_send_receive_unaligned(struct test_spec *test) { test->ifobj_tx->umem->unaligned_mode = true; test->ifobj_rx->umem->unaligned_mode = true; /* Let half of the packets straddle a 4K buffer boundary */ if (pkt_stream_replace_half(test, MIN_PKT_SIZE, -MIN_PKT_SIZE / 2)) return TEST_FAILURE; return testapp_validate_traffic(test); } int testapp_send_receive_unaligned_mb(struct test_spec *test) { test->mtu = MAX_ETH_JUMBO_SIZE; test->ifobj_tx->umem->unaligned_mode = true; test->ifobj_rx->umem->unaligned_mode = true; if (pkt_stream_replace(test, DEFAULT_PKT_CNT, MAX_ETH_JUMBO_SIZE)) return TEST_FAILURE; return testapp_validate_traffic(test); } int testapp_single_pkt(struct test_spec *test) { struct pkt pkts[] = {{0, MIN_PKT_SIZE, 0, true}}; if (pkt_stream_generate_custom(test, pkts, ARRAY_SIZE(pkts))) return TEST_FAILURE; return testapp_validate_traffic(test); } int testapp_send_receive_mb(struct test_spec *test) { test->mtu = MAX_ETH_JUMBO_SIZE; if (pkt_stream_replace(test, DEFAULT_PKT_CNT, MAX_ETH_JUMBO_SIZE)) return TEST_FAILURE; return testapp_validate_traffic(test); } int testapp_invalid_desc_mb(struct test_spec *test) { struct xsk_umem_info *umem = test->ifobj_tx->umem; u64 umem_size = umem->num_frames * umem->frame_size; struct pkt pkts[] = { /* Valid packet for synch to start with */ {0, MIN_PKT_SIZE, 0, true, 0}, /* Zero frame len is not legal */ {0, XSK_UMEM__LARGE_FRAME_SIZE, 0, false, XDP_PKT_CONTD}, {0, XSK_UMEM__LARGE_FRAME_SIZE, 0, false, XDP_PKT_CONTD}, {0, 0, 0, false, 0}, /* Invalid address in the second frame */ {0, XSK_UMEM__LARGE_FRAME_SIZE, 0, false, XDP_PKT_CONTD}, {umem_size, XSK_UMEM__LARGE_FRAME_SIZE, 0, false, XDP_PKT_CONTD}, /* Invalid len in the middle */ {0, XSK_UMEM__LARGE_FRAME_SIZE, 0, false, XDP_PKT_CONTD}, {0, XSK_UMEM__INVALID_FRAME_SIZE, 0, false, XDP_PKT_CONTD}, /* Invalid options in the middle */ {0, XSK_UMEM__LARGE_FRAME_SIZE, 0, false, XDP_PKT_CONTD}, {0, XSK_UMEM__LARGE_FRAME_SIZE, 0, false, XSK_DESC__INVALID_OPTION}, /* Transmit 2 frags, receive 3 */ {0, XSK_UMEM__MAX_FRAME_SIZE, 0, true, XDP_PKT_CONTD}, {0, XSK_UMEM__MAX_FRAME_SIZE, 0, true, 0}, /* Middle frame crosses chunk boundary with small length */ {0, XSK_UMEM__LARGE_FRAME_SIZE, 0, false, XDP_PKT_CONTD}, {-MIN_PKT_SIZE / 2, MIN_PKT_SIZE, 0, false, 0}, /* Valid packet for synch so that something is received */ {0, MIN_PKT_SIZE, 0, true, 0}}; if (umem->unaligned_mode) { /* Crossing a chunk boundary allowed */ pkts[12].valid = true; pkts[13].valid = true; } test->mtu = MAX_ETH_JUMBO_SIZE; if (pkt_stream_generate_custom(test, pkts, ARRAY_SIZE(pkts))) return TEST_FAILURE; return testapp_validate_traffic(test); } int testapp_invalid_desc(struct test_spec *test) { struct xsk_umem_info *umem = test->ifobj_tx->umem; u64 umem_size = umem->num_frames * umem->frame_size; struct pkt pkts[] = { /* Zero packet address allowed */ {0, MIN_PKT_SIZE, 0, true}, /* Allowed packet */ {0, MIN_PKT_SIZE, 0, true}, /* Straddling the start of umem */ {-2, MIN_PKT_SIZE, 0, false}, /* Packet too large */ {0, XSK_UMEM__INVALID_FRAME_SIZE, 0, false}, /* Up to end of umem allowed */ {umem_size - MIN_PKT_SIZE - 2 * umem->frame_size, MIN_PKT_SIZE, 0, true}, /* After umem ends */ {umem_size, MIN_PKT_SIZE, 0, false}, /* Straddle the end of umem */ {umem_size - MIN_PKT_SIZE / 2, MIN_PKT_SIZE, 0, false}, /* Straddle a 4K boundary */ {0x1000 - MIN_PKT_SIZE / 2, MIN_PKT_SIZE, 0, false}, /* Straddle a 2K boundary */ {0x800 - MIN_PKT_SIZE / 2, MIN_PKT_SIZE, 0, true}, /* Valid packet for synch so that something is received */ {0, MIN_PKT_SIZE, 0, true}}; if (umem->unaligned_mode) { /* Crossing a page boundary allowed */ pkts[7].valid = true; } if (umem->frame_size == XSK_UMEM__DEFAULT_FRAME_SIZE / 2) { /* Crossing a 2K frame size boundary not allowed */ pkts[8].valid = false; } if (test->ifobj_tx->shared_umem) { pkts[4].offset += umem_size; pkts[5].offset += umem_size; pkts[6].offset += umem_size; } if (pkt_stream_generate_custom(test, pkts, ARRAY_SIZE(pkts))) return TEST_FAILURE; return testapp_validate_traffic(test); } int testapp_xdp_drop(struct test_spec *test) { struct xsk_xdp_progs *skel_rx = test->ifobj_rx->xdp_progs; struct xsk_xdp_progs *skel_tx = test->ifobj_tx->xdp_progs; test_spec_set_xdp_prog(test, skel_rx->progs.xsk_xdp_drop, skel_tx->progs.xsk_xdp_drop, skel_rx->maps.xsk, skel_tx->maps.xsk); if (pkt_stream_receive_half(test)) return TEST_FAILURE; return testapp_validate_traffic(test); } int testapp_xdp_metadata_copy(struct test_spec *test) { struct xsk_xdp_progs *skel_rx = test->ifobj_rx->xdp_progs; struct xsk_xdp_progs *skel_tx = test->ifobj_tx->xdp_progs; test_spec_set_xdp_prog(test, skel_rx->progs.xsk_xdp_populate_metadata, skel_tx->progs.xsk_xdp_populate_metadata, skel_rx->maps.xsk, skel_tx->maps.xsk); test->ifobj_rx->use_metadata = true; skel_rx->bss->count = 0; return testapp_validate_traffic(test); } int testapp_xdp_shared_umem(struct test_spec *test) { struct xsk_xdp_progs *skel_rx = test->ifobj_rx->xdp_progs; struct xsk_xdp_progs *skel_tx = test->ifobj_tx->xdp_progs; int ret; test->total_steps = 1; test->nb_sockets = 2; test_spec_set_xdp_prog(test, skel_rx->progs.xsk_xdp_shared_umem, skel_tx->progs.xsk_xdp_shared_umem, skel_rx->maps.xsk, skel_tx->maps.xsk); if (pkt_stream_even_odd_sequence(test)) return TEST_FAILURE; ret = testapp_validate_traffic(test); release_even_odd_sequence(test); return ret; } int testapp_poll_txq_tmout(struct test_spec *test) { test->ifobj_tx->use_poll = true; /* create invalid frame by set umem frame_size and pkt length equal to 2048 */ test->ifobj_tx->umem->frame_size = 2048; if (pkt_stream_replace(test, 2 * DEFAULT_PKT_CNT, 2048)) return TEST_FAILURE; return testapp_validate_traffic_single_thread(test, test->ifobj_tx); } int testapp_poll_rxq_tmout(struct test_spec *test) { test->ifobj_rx->use_poll = true; return testapp_validate_traffic_single_thread(test, test->ifobj_rx); } int testapp_too_many_frags(struct test_spec *test) { struct pkt *pkts; u32 max_frags, i; int ret = TEST_FAILURE; if (test->mode == TEST_MODE_ZC) { max_frags = test->ifobj_tx->xdp_zc_max_segs; } else { max_frags = get_max_skb_frags(); if (!max_frags) { ksft_print_msg("Can't get MAX_SKB_FRAGS from system, using default (17)\n"); max_frags = 17; } max_frags += 1; } pkts = calloc(2 * max_frags + 2, sizeof(struct pkt)); if (!pkts) return TEST_FAILURE; test->mtu = MAX_ETH_JUMBO_SIZE; /* Valid packet for synch */ pkts[0].len = MIN_PKT_SIZE; pkts[0].valid = true; /* One valid packet with the max amount of frags */ for (i = 1; i < max_frags + 1; i++) { pkts[i].len = MIN_PKT_SIZE; pkts[i].options = XDP_PKT_CONTD; pkts[i].valid = true; } pkts[max_frags].options = 0; /* An invalid packet with the max amount of frags but signals packet * continues on the last frag */ for (i = max_frags + 1; i < 2 * max_frags + 1; i++) { pkts[i].len = MIN_PKT_SIZE; pkts[i].options = XDP_PKT_CONTD; pkts[i].valid = false; } /* Valid packet for synch */ pkts[2 * max_frags + 1].len = MIN_PKT_SIZE; pkts[2 * max_frags + 1].valid = true; if (pkt_stream_generate_custom(test, pkts, 2 * max_frags + 2)) { free(pkts); return TEST_FAILURE; } ret = testapp_validate_traffic(test); free(pkts); return ret; } static int xsk_load_xdp_programs(struct ifobject *ifobj) { ifobj->xdp_progs = xsk_xdp_progs__open_and_load(); if (libbpf_get_error(ifobj->xdp_progs)) return libbpf_get_error(ifobj->xdp_progs); return 0; } /* Simple test */ static bool hugepages_present(void) { size_t mmap_sz = 2 * DEFAULT_UMEM_BUFFERS * XSK_UMEM__DEFAULT_FRAME_SIZE; void *bufs; bufs = mmap(NULL, mmap_sz, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANONYMOUS | MAP_HUGETLB, -1, MAP_HUGE_2MB); if (bufs == MAP_FAILED) return false; mmap_sz = ceil_u64(mmap_sz, HUGEPAGE_SIZE) * HUGEPAGE_SIZE; munmap(bufs, mmap_sz); return true; } int init_iface(struct ifobject *ifobj, thread_func_t func_ptr) { LIBBPF_OPTS(bpf_xdp_query_opts, query_opts); int err; ifobj->func_ptr = func_ptr; err = xsk_load_xdp_programs(ifobj); if (err) { ksft_print_msg("Error loading XDP program\n"); return err; } if (hugepages_present()) ifobj->unaligned_supp = true; err = bpf_xdp_query(ifobj->ifindex, XDP_FLAGS_DRV_MODE, &query_opts); if (err) { ksft_print_msg("Error querying XDP capabilities\n"); return err; } if (query_opts.feature_flags & NETDEV_XDP_ACT_RX_SG) ifobj->multi_buff_supp = true; if (query_opts.feature_flags & NETDEV_XDP_ACT_XSK_ZEROCOPY) { if (query_opts.xdp_zc_max_segs > 1) { ifobj->multi_buff_zc_supp = true; ifobj->xdp_zc_max_segs = query_opts.xdp_zc_max_segs; } else { ifobj->xdp_zc_max_segs = 0; } } return 0; } int testapp_send_receive(struct test_spec *test) { return testapp_validate_traffic(test); } int testapp_send_receive_2k_frame(struct test_spec *test) { test->ifobj_tx->umem->frame_size = 2048; test->ifobj_rx->umem->frame_size = 2048; if (pkt_stream_replace(test, DEFAULT_PKT_CNT, MIN_PKT_SIZE)) return TEST_FAILURE; return testapp_validate_traffic(test); } int testapp_poll_rx(struct test_spec *test) { test->ifobj_rx->use_poll = true; return testapp_validate_traffic(test); } int testapp_poll_tx(struct test_spec *test) { test->ifobj_tx->use_poll = true; return testapp_validate_traffic(test); } int testapp_aligned_inv_desc(struct test_spec *test) { return testapp_invalid_desc(test); } int testapp_aligned_inv_desc_2k_frame(struct test_spec *test) { test->ifobj_tx->umem->frame_size = 2048; test->ifobj_rx->umem->frame_size = 2048; return testapp_invalid_desc(test); } int testapp_unaligned_inv_desc(struct test_spec *test) { test->ifobj_tx->umem->unaligned_mode = true; test->ifobj_rx->umem->unaligned_mode = true; return testapp_invalid_desc(test); } int testapp_unaligned_inv_desc_4001_frame(struct test_spec *test) { u64 page_size, umem_size; /* Odd frame size so the UMEM doesn't end near a page boundary. */ test->ifobj_tx->umem->frame_size = 4001; test->ifobj_rx->umem->frame_size = 4001; test->ifobj_tx->umem->unaligned_mode = true; test->ifobj_rx->umem->unaligned_mode = true; /* This test exists to test descriptors that staddle the end of * the UMEM but not a page. */ page_size = sysconf(_SC_PAGESIZE); umem_size = test->ifobj_tx->umem->num_frames * test->ifobj_tx->umem->frame_size; assert(umem_size % page_size > MIN_PKT_SIZE); assert(umem_size % page_size < page_size - MIN_PKT_SIZE); return testapp_invalid_desc(test); } int testapp_aligned_inv_desc_mb(struct test_spec *test) { return testapp_invalid_desc_mb(test); } int testapp_unaligned_inv_desc_mb(struct test_spec *test) { test->ifobj_tx->umem->unaligned_mode = true; test->ifobj_rx->umem->unaligned_mode = true; return testapp_invalid_desc_mb(test); } int testapp_xdp_metadata(struct test_spec *test) { return testapp_xdp_metadata_copy(test); } int testapp_xdp_metadata_mb(struct test_spec *test) { test->mtu = MAX_ETH_JUMBO_SIZE; return testapp_xdp_metadata_copy(test); } int testapp_hw_sw_min_ring_size(struct test_spec *test) { int ret; test->set_ring = true; test->total_steps = 2; test->ifobj_tx->ring.tx_pending = DEFAULT_BATCH_SIZE; test->ifobj_tx->ring.rx_pending = DEFAULT_BATCH_SIZE * 2; test->ifobj_tx->xsk->batch_size = 1; test->ifobj_rx->xsk->batch_size = 1; ret = testapp_validate_traffic(test); if (ret) return ret; /* Set batch size to hw_ring_size - 1 */ test->ifobj_tx->xsk->batch_size = DEFAULT_BATCH_SIZE - 1; test->ifobj_rx->xsk->batch_size = DEFAULT_BATCH_SIZE - 1; return testapp_validate_traffic(test); } int testapp_hw_sw_max_ring_size(struct test_spec *test) { u32 max_descs = XSK_RING_PROD__DEFAULT_NUM_DESCS * 4; int ret; test->set_ring = true; test->total_steps = 2; test->ifobj_tx->ring.tx_pending = test->ifobj_tx->ring.tx_max_pending; test->ifobj_tx->ring.rx_pending = test->ifobj_tx->ring.rx_max_pending; test->ifobj_rx->umem->num_frames = max_descs; test->ifobj_rx->umem->fill_size = max_descs; test->ifobj_rx->umem->comp_size = max_descs; test->ifobj_tx->xsk->batch_size = XSK_RING_PROD__DEFAULT_NUM_DESCS; test->ifobj_rx->xsk->batch_size = XSK_RING_PROD__DEFAULT_NUM_DESCS; ret = testapp_validate_traffic(test); if (ret) return ret; /* Set batch_size to 8152 for testing, as the ice HW ignores the 3 lowest bits when * updating the Rx HW tail register. */ test->ifobj_tx->xsk->batch_size = test->ifobj_tx->ring.tx_max_pending - 8; test->ifobj_rx->xsk->batch_size = test->ifobj_tx->ring.tx_max_pending - 8; if (pkt_stream_replace(test, max_descs, MIN_PKT_SIZE)) { clean_sockets(test, test->ifobj_tx); clean_sockets(test, test->ifobj_rx); clean_umem(test, test->ifobj_rx, test->ifobj_tx); return TEST_FAILURE; } return testapp_validate_traffic(test); } static int testapp_xdp_adjust_tail(struct test_spec *test, int adjust_value) { struct xsk_xdp_progs *skel_rx = test->ifobj_rx->xdp_progs; struct xsk_xdp_progs *skel_tx = test->ifobj_tx->xdp_progs; test_spec_set_xdp_prog(test, skel_rx->progs.xsk_xdp_adjust_tail, skel_tx->progs.xsk_xdp_adjust_tail, skel_rx->maps.xsk, skel_tx->maps.xsk); skel_rx->bss->adjust_value = adjust_value; return testapp_validate_traffic(test); } static int testapp_adjust_tail(struct test_spec *test, u32 value, u32 pkt_len) { int ret; test->adjust_tail_support = true; test->adjust_tail = true; test->total_steps = 1; ret = pkt_stream_replace_ifobject(test->ifobj_tx, DEFAULT_BATCH_SIZE, pkt_len); if (ret) return TEST_FAILURE; ret = pkt_stream_replace_ifobject(test->ifobj_rx, DEFAULT_BATCH_SIZE, pkt_len + value); if (ret) return TEST_FAILURE; ret = testapp_xdp_adjust_tail(test, value); if (ret) return ret; if (!test->adjust_tail_support) { ksft_print_msg("%s %sResize pkt with bpf_xdp_adjust_tail() not supported\n", mode_string(test), busy_poll_string(test)); return TEST_SKIP; } return 0; } int testapp_adjust_tail_shrink(struct test_spec *test) { /* Shrink by 4 bytes for testing purpose */ return testapp_adjust_tail(test, -4, MIN_PKT_SIZE * 2); } int testapp_adjust_tail_shrink_mb(struct test_spec *test) { test->mtu = MAX_ETH_JUMBO_SIZE; /* Shrink by the frag size */ return testapp_adjust_tail(test, -XSK_UMEM__MAX_FRAME_SIZE, XSK_UMEM__LARGE_FRAME_SIZE * 2); } int testapp_adjust_tail_grow(struct test_spec *test) { /* Grow by 4 bytes for testing purpose */ return testapp_adjust_tail(test, 4, MIN_PKT_SIZE * 2); } int testapp_adjust_tail_grow_mb(struct test_spec *test) { test->mtu = MAX_ETH_JUMBO_SIZE; /* Grow by (frag_size - last_frag_Size) - 1 to stay inside the last fragment */ return testapp_adjust_tail(test, (XSK_UMEM__MAX_FRAME_SIZE / 2) - 1, XSK_UMEM__LARGE_FRAME_SIZE * 2); } int testapp_tx_queue_consumer(struct test_spec *test) { int nr_packets; if (test->mode == TEST_MODE_ZC) { ksft_print_msg("Can not run TX_QUEUE_CONSUMER test for ZC mode\n"); return TEST_SKIP; } nr_packets = MAX_TX_BUDGET_DEFAULT + 1; if (pkt_stream_replace(test, nr_packets, MIN_PKT_SIZE)) return TEST_FAILURE; test->ifobj_tx->xsk->batch_size = nr_packets; test->ifobj_tx->xsk->check_consumer = true; return testapp_validate_traffic(test); } struct ifobject *ifobject_create(void) { struct ifobject *ifobj; ifobj = calloc(1, sizeof(struct ifobject)); if (!ifobj) return NULL; ifobj->xsk_arr = calloc(MAX_SOCKETS, sizeof(*ifobj->xsk_arr)); if (!ifobj->xsk_arr) goto out_xsk_arr; ifobj->umem = calloc(1, sizeof(*ifobj->umem)); if (!ifobj->umem) goto out_umem; return ifobj; out_umem: free(ifobj->xsk_arr); out_xsk_arr: free(ifobj); return NULL; } void ifobject_delete(struct ifobject *ifobj) { free(ifobj->umem); free(ifobj->xsk_arr); free(ifobj); }