// SPDX-License-Identifier: GPL-2.0-only #define _GNU_SOURCE #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "xdp_sample.h" #include "logging.h" #include "xdp_sample.skel.h" #include "xdp_load_bytes.skel.h" #define __sample_print(fmt, cond, ...) \ ({ \ if (cond) \ printf(fmt, ##__VA_ARGS__); \ }) #define print_always(fmt, ...) __sample_print(fmt, 1, ##__VA_ARGS__) #define print_default(fmt, ...) \ __sample_print(fmt, sample_log_level & LL_DEFAULT, ##__VA_ARGS__) #define __print_err(err, fmt, ...) \ ({ \ __sample_print(fmt, err > 0 || sample_log_level & LL_DEFAULT, \ ##__VA_ARGS__); \ sample_err_exp = sample_err_exp ? true : err > 0; \ }) #define print_err(err, fmt, ...) __print_err(err, fmt, ##__VA_ARGS__) #define __COLUMN(x) "%'10" x " %-13s" #define FMT_COLUMNf __COLUMN(".0f") #define FMT_COLUMNd __COLUMN("d") #define FMT_COLUMNl __COLUMN(PRIu64) #define RX(rx) rx, "rx/s" #define PPS(pps) pps, "pkt/s" #define DROP(drop) drop, "drop/s" #define ERR(err) err, "error/s" #define HITS(hits) hits, "hit/s" #define XMIT(xmit) xmit, "xmit/s" #define PASS(pass) pass, "pass/s" #define REDIR(redir) redir, "redir/s" #define NANOSEC_PER_SEC 1000000000 /* 10^9 */ #define XDP_UNKNOWN (XDP_REDIRECT + 1) #define XDP_ACTION_MAX (XDP_UNKNOWN + 1) #define XDP_REDIRECT_ERR_MAX 7 enum map_type { MAP_RX, MAP_RXQ, MAP_REDIRECT_ERR, MAP_CPUMAP_ENQUEUE, MAP_CPUMAP_KTHREAD, MAP_EXCEPTION, MAP_DEVMAP_XMIT, MAP_DEVMAP_XMIT_MULTI, NUM_MAP, }; enum log_level { LL_DEFAULT = 1U << 0, LL_SIMPLE = 1U << 1, LL_DEBUG = 1U << 2, }; struct record { __u64 timestamp; struct datarec total; union { struct datarec *cpu; struct datarec *rxq; }; }; struct map_entry { struct hlist_node node; __u64 pair; struct record val; }; struct stats_record { struct record rx_cnt; struct record rxq_cnt; struct record redir_err[XDP_REDIRECT_ERR_MAX]; struct record kthread; struct record exception[XDP_ACTION_MAX]; struct record devmap_xmit; DECLARE_HASHTABLE(xmit_map, 5); struct record enq[]; }; struct sample_output { struct { uint64_t rx; uint64_t redir; uint64_t drop; uint64_t drop_xmit; uint64_t err; uint64_t xmit; } totals; struct { union { uint64_t pps; uint64_t num; }; uint64_t drop; uint64_t err; } rx_cnt; struct { uint64_t suc; uint64_t err; } redir_cnt; struct { uint64_t hits; } except_cnt; struct { uint64_t pps; uint64_t drop; uint64_t err; double bavg; } xmit_cnt; }; struct datarec *sample_mmap[NUM_MAP]; struct bpf_map *sample_map[NUM_MAP]; size_t sample_map_count[NUM_MAP]; enum log_level sample_log_level; struct sample_output sample_out; unsigned long sample_interval; bool sample_err_exp; int sample_xdp_cnt; int sample_n_cpus; int sample_n_rxqs; int sample_sig_fd; int sample_mask; int ifindex[2]; static struct { bool checked; bool compat; } sample_compat[SAMPLE_COMPAT_MAX] = {}; bool sample_is_compat(enum sample_compat compat_value) { return sample_compat[compat_value].compat; } bool sample_probe_cpumap_compat(void) { struct xdp_sample *skel; bool res; skel = xdp_sample__open_and_load(); res = !!skel; xdp_sample__destroy(skel); return res; } bool sample_probe_xdp_load_bytes(void) { struct xdp_load_bytes *skel; bool res; skel = xdp_load_bytes__open_and_load(); res = !!skel; xdp_load_bytes__destroy(skel); return res; } void sample_check_cpumap_compat(struct bpf_program *prog, struct bpf_program *prog_compat) { bool res = sample_compat[SAMPLE_COMPAT_CPUMAP_KTHREAD].compat; if (!sample_compat[SAMPLE_COMPAT_CPUMAP_KTHREAD].checked) { res = sample_probe_cpumap_compat(); sample_compat[SAMPLE_COMPAT_CPUMAP_KTHREAD].checked = true; sample_compat[SAMPLE_COMPAT_CPUMAP_KTHREAD].compat = res; } if (res) { pr_debug("Kernel supports 5-arg xdp_cpumap_kthread tracepoint\n"); bpf_program__set_autoload(prog_compat, false); } else { pr_debug("Kernel does not support 5-arg xdp_cpumap_kthread tracepoint, using compat version\n"); bpf_program__set_autoload(prog, false); } } static const char *xdp_redirect_err_names[XDP_REDIRECT_ERR_MAX] = { /* Key=1 keeps unknown errors */ "Success", "Unknown", "EINVAL", "ENETDOWN", "EMSGSIZE", "EOPNOTSUPP", "ENOSPC", }; static const char *xdp_action_names[XDP_ACTION_MAX] = { [XDP_ABORTED] = "XDP_ABORTED", [XDP_DROP] = "XDP_DROP", [XDP_PASS] = "XDP_PASS", [XDP_TX] = "XDP_TX", [XDP_REDIRECT] = "XDP_REDIRECT", [XDP_UNKNOWN] = "XDP_UNKNOWN", }; static __u64 gettime(void) { struct timespec t; int res; res = clock_gettime(CLOCK_MONOTONIC, &t); if (res < 0) { pr_warn("Error with gettimeofday! (%i)\n", res); return UINT64_MAX; } return (__u64)t.tv_sec * NANOSEC_PER_SEC + t.tv_nsec; } static const char *xdp_action2str(int action) { if (action < XDP_ACTION_MAX) return xdp_action_names[action]; return NULL; } static struct datarec *alloc_records(int nr_entries) { struct datarec *array; if (nr_entries <= 0) return NULL; array = calloc(nr_entries, sizeof(*array)); if (!array) { pr_warn("Failed to allocate memory (nr_entries: %u)\n", nr_entries); return NULL; } return array; } static int map_entry_init(struct map_entry *e, __u64 pair) { e->pair = pair; INIT_HLIST_NODE(&e->node); e->val.timestamp = gettime(); e->val.cpu = alloc_records(libbpf_num_possible_cpus()); if (!e->val.cpu) return -ENOMEM; return 0; } static void map_collect_rxqs(struct datarec *values, struct record *rec) { int i; /* Get time as close as possible to reading map contents */ rec->timestamp = gettime(); /* Record and sum values from each RXQ */ for (i = 0; i < sample_n_rxqs; i++) { pr_debug("%d: %lx %lx\n", i, (unsigned long)&rec->rxq[i], (unsigned long)&values[i]); rec->rxq[i].processed = READ_ONCE(values[i].processed); rec->rxq[i].dropped = READ_ONCE(values[i].dropped); rec->rxq[i].issue = READ_ONCE(values[i].issue); rec->rxq[i].xdp_pass = READ_ONCE(values[i].xdp_pass); rec->rxq[i].xdp_drop = READ_ONCE(values[i].xdp_drop); rec->rxq[i].xdp_redirect = READ_ONCE(values[i].xdp_redirect); } } static void map_collect_percpu(struct datarec *values, struct record *rec) { /* For percpu maps, userspace gets a value per possible CPU */ int nr_cpus = libbpf_num_possible_cpus(); __u64 sum_xdp_redirect = 0; __u64 sum_processed = 0; __u64 sum_xdp_pass = 0; __u64 sum_xdp_drop = 0; __u64 sum_dropped = 0; __u64 sum_issue = 0; int i; /* Get time as close as possible to reading map contents */ rec->timestamp = gettime(); /* Record and sum values from each CPU */ for (i = 0; i < nr_cpus; i++) { rec->cpu[i].processed = READ_ONCE(values[i].processed); rec->cpu[i].dropped = READ_ONCE(values[i].dropped); rec->cpu[i].issue = READ_ONCE(values[i].issue); rec->cpu[i].xdp_pass = READ_ONCE(values[i].xdp_pass); rec->cpu[i].xdp_drop = READ_ONCE(values[i].xdp_drop); rec->cpu[i].xdp_redirect = READ_ONCE(values[i].xdp_redirect); sum_processed += rec->cpu[i].processed; sum_dropped += rec->cpu[i].dropped; sum_issue += rec->cpu[i].issue; sum_xdp_pass += rec->cpu[i].xdp_pass; sum_xdp_drop += rec->cpu[i].xdp_drop; sum_xdp_redirect += rec->cpu[i].xdp_redirect; } rec->total.processed = sum_processed; rec->total.dropped = sum_dropped; rec->total.issue = sum_issue; rec->total.xdp_pass = sum_xdp_pass; rec->total.xdp_drop = sum_xdp_drop; rec->total.xdp_redirect = sum_xdp_redirect; } static int map_collect_percpu_devmap(int map_fd, struct stats_record *rec) { int nr_cpus = libbpf_num_possible_cpus(); int i, ret, count = 32; struct datarec *values; bool init = false; __u32 batch; __u64 *keys; keys = calloc(count, sizeof(__u64)); if (!keys) return -ENOMEM; values = calloc(count * nr_cpus, sizeof(struct datarec)); if (!values) { free(keys); return -ENOMEM; } for (;;) { bool exit = false; ret = bpf_map_lookup_batch(map_fd, init ? &batch : NULL, &batch, keys, values, (__u32 *)&count, NULL); if (ret < 0 && errno != ENOENT) break; if (errno == ENOENT) exit = true; init = true; for (i = 0; i < count; i++) { struct map_entry *e, *x = NULL; __u64 pair = keys[i]; struct datarec *arr; arr = &values[i * nr_cpus]; hash_for_each_possible(rec->xmit_map, e, node, pair) { if (e->pair == pair) { x = e; break; } } if (!x) { x = calloc(1, sizeof(*x)); if (!x) goto cleanup; if (map_entry_init(x, pair) < 0) { free(x); goto cleanup; } hash_add(rec->xmit_map, &x->node, pair); } map_collect_percpu(arr, &x->val); } if (exit) break; count = 32; } free(values); free(keys); return 0; cleanup: free(values); free(keys); return -ENOMEM; } static struct stats_record *alloc_stats_record(void) { struct stats_record *rec; int i; rec = calloc(1, sizeof(*rec) + sample_n_cpus * sizeof(struct record)); if (!rec) { pr_warn("Failed to allocate memory\n"); return NULL; } if (sample_mask & SAMPLE_RX_CNT) { rec->rx_cnt.cpu = alloc_records(libbpf_num_possible_cpus()); if (!rec->rx_cnt.cpu) { pr_warn("Failed to allocate rx_cnt per-CPU array\n"); goto end_rec; } } if (sample_mask & SAMPLE_RXQ_STATS) { if (sample_n_rxqs <= 0) { pr_warn("Invalid number of RXQs: %d\n", sample_n_rxqs); goto end_rx_cnt; } rec->rxq_cnt.rxq = alloc_records(sample_n_rxqs); if (!rec->rxq_cnt.rxq) { pr_warn("Failed to allocate rxq_cnt per RXQ array\n"); goto end_rx_cnt; } } if (sample_mask & (SAMPLE_REDIRECT_CNT | SAMPLE_REDIRECT_ERR_CNT)) { for (i = 0; i < XDP_REDIRECT_ERR_MAX; i++) { rec->redir_err[i].cpu = alloc_records(libbpf_num_possible_cpus()); if (!rec->redir_err[i].cpu) { pr_warn("Failed to allocate redir_err per-CPU array for \"%s\" case\n", xdp_redirect_err_names[i]); while (i--) free(rec->redir_err[i].cpu); goto end_rxq_cnt; } } } if (sample_mask & SAMPLE_CPUMAP_KTHREAD_CNT) { rec->kthread.cpu = alloc_records(libbpf_num_possible_cpus()); if (!rec->kthread.cpu) { pr_warn("Failed to allocate kthread per-CPU array\n"); goto end_redir; } } if (sample_mask & SAMPLE_EXCEPTION_CNT) { for (i = 0; i < XDP_ACTION_MAX; i++) { rec->exception[i].cpu = alloc_records(libbpf_num_possible_cpus()); if (!rec->exception[i].cpu) { pr_warn("Failed to allocate exception per-CPU array for \"%s\" case\n", xdp_action2str(i)); while (i--) free(rec->exception[i].cpu); goto end_kthread; } } } if (sample_mask & SAMPLE_DEVMAP_XMIT_CNT) { rec->devmap_xmit.cpu = alloc_records(libbpf_num_possible_cpus()); if (!rec->devmap_xmit.cpu) { pr_warn("Failed to allocate devmap_xmit per-CPU array\n"); goto end_exception; } } if (sample_mask & SAMPLE_DEVMAP_XMIT_CNT_MULTI) hash_init(rec->xmit_map); if (sample_mask & SAMPLE_CPUMAP_ENQUEUE_CNT) { for (i = 0; i < sample_n_cpus; i++) { rec->enq[i].cpu = alloc_records(libbpf_num_possible_cpus()); if (!rec->enq[i].cpu) { pr_warn("Failed to allocate enqueue per-CPU array for CPU %d\n", i); while (i--) free(rec->enq[i].cpu); goto end_devmap_xmit; } } } return rec; end_devmap_xmit: free(rec->devmap_xmit.cpu); end_exception: for (i = 0; i < XDP_ACTION_MAX; i++) free(rec->exception[i].cpu); end_kthread: free(rec->kthread.cpu); end_redir: for (i = 0; i < XDP_REDIRECT_ERR_MAX; i++) free(rec->redir_err[i].cpu); end_rxq_cnt: free(rec->rxq_cnt.rxq); end_rx_cnt: free(rec->rx_cnt.cpu); end_rec: free(rec); return NULL; } static void free_stats_record(struct stats_record *r) { struct hlist_node *tmp; struct map_entry *e; unsigned int bkt; int i; for (i = 0; i < sample_n_cpus; i++) free(r->enq[i].cpu); hash_for_each_safe(r->xmit_map, bkt, tmp, e, node) { hash_del(&e->node); free(e->val.cpu); free(e); } free(r->devmap_xmit.cpu); for (i = 0; i < XDP_ACTION_MAX; i++) free(r->exception[i].cpu); free(r->kthread.cpu); for (i = 0; i < XDP_REDIRECT_ERR_MAX; i++) free(r->redir_err[i].cpu); free(r->rx_cnt.cpu); free(r); } static double calc_period(struct record *r, struct record *p) { double period_ = 0; __u64 period = 0; period = r->timestamp - p->timestamp; if (period > 0) period_ = ((double)period / NANOSEC_PER_SEC); return period_; } static double sample_round(double val) { if (val - floor(val) < 0.5) return floor(val); return ceil(val); } static __u64 calc_pps(struct datarec *r, struct datarec *p, double period_) { __u64 packets = 0; __u64 pps = 0; if (period_ > 0) { packets = r->processed - p->processed; pps = sample_round(packets / period_); } return pps; } static __u64 calc_drop_pps(struct datarec *r, struct datarec *p, double period_) { __u64 packets = 0; __u64 pps = 0; if (period_ > 0) { packets = r->dropped - p->dropped; pps = sample_round(packets / period_); } return pps; } static __u64 calc_errs_pps(struct datarec *r, struct datarec *p, double period_) { __u64 packets = 0; __u64 pps = 0; if (period_ > 0) { packets = r->issue - p->issue; pps = sample_round(packets / period_); } return pps; } static __u64 calc_info_pps(struct datarec *r, struct datarec *p, double period_) { __u64 packets = 0; __u64 pps = 0; if (period_ > 0) { packets = r->info - p->info; pps = sample_round(packets / period_); } return pps; } static void calc_xdp_pps(struct datarec *r, struct datarec *p, double *xdp_pass, double *xdp_drop, double *xdp_redirect, double period_) { *xdp_pass = 0, *xdp_drop = 0, *xdp_redirect = 0; if (period_ > 0) { *xdp_redirect = (r->xdp_redirect - p->xdp_redirect) / period_; *xdp_pass = (r->xdp_pass - p->xdp_pass) / period_; *xdp_drop = (r->xdp_drop - p->xdp_drop) / period_; } } static void stats_get_rx_cnt(struct stats_record *stats_rec, struct stats_record *stats_prev, int nr_cpus, struct sample_output *out) { struct record *rec, *prev; double t, pps, drop, err; int i; rec = &stats_rec->rx_cnt; prev = &stats_prev->rx_cnt; t = calc_period(rec, prev); for (i = 0; i < nr_cpus; i++) { struct datarec *r = &rec->cpu[i]; struct datarec *p = &prev->cpu[i]; char str[64]; pps = calc_pps(r, p, t); drop = calc_drop_pps(r, p, t); err = calc_errs_pps(r, p, t); if (!pps && !drop && !err) continue; snprintf(str, sizeof(str), "cpu:%d", i); print_default(" %-18s " FMT_COLUMNf FMT_COLUMNf FMT_COLUMNf "\n", str, PPS(pps), DROP(drop), ERR(err)); } if (out) { pps = calc_pps(&rec->total, &prev->total, t); drop = calc_drop_pps(&rec->total, &prev->total, t); err = calc_errs_pps(&rec->total, &prev->total, t); out->rx_cnt.pps = pps; out->rx_cnt.drop = drop; out->rx_cnt.err = err; out->totals.rx += pps; out->totals.drop += drop; out->totals.err += err; } } static void stats_get_rxq_cnt(struct stats_record *stats_rec, struct stats_record *stats_prev) { struct record *rec, *prev; double t, pps, drop, err; int i; rec = &stats_rec->rxq_cnt; prev = &stats_prev->rxq_cnt; t = calc_period(rec, prev); print_default("\n"); for (i = 0; i < sample_n_rxqs; i++) { struct datarec *r = &rec->rxq[i]; struct datarec *p = &prev->rxq[i]; char str[64]; pps = calc_pps(r, p, t); drop = calc_drop_pps(r, p, t); err = calc_errs_pps(r, p, t); if (!pps && !drop && !err) continue; snprintf(str, sizeof(str), "rxq:%d", i); print_default(" %-18s " FMT_COLUMNf FMT_COLUMNf FMT_COLUMNf "\n", str, PPS(pps), DROP(drop), ERR(err)); } } static void stats_get_cpumap_enqueue(struct stats_record *stats_rec, struct stats_record *stats_prev, int nr_cpus) { struct record *rec, *prev; double t, pps, drop, err; int i, to_cpu; /* cpumap enqueue stats */ for (to_cpu = 0; to_cpu < sample_n_cpus; to_cpu++) { rec = &stats_rec->enq[to_cpu]; prev = &stats_prev->enq[to_cpu]; t = calc_period(rec, prev); pps = calc_pps(&rec->total, &prev->total, t); drop = calc_drop_pps(&rec->total, &prev->total, t); err = calc_errs_pps(&rec->total, &prev->total, t); if (pps > 0 || drop > 0) { char str[64]; snprintf(str, sizeof(str), "enqueue to cpu %d", to_cpu); if (err > 0) err = pps / err; /* calc average bulk size */ print_err(drop, " %-20s " FMT_COLUMNf FMT_COLUMNf __COLUMN( ".2f") "\n", str, PPS(pps), DROP(drop), err, "bulk-avg"); } for (i = 0; i < nr_cpus; i++) { struct datarec *r = &rec->cpu[i]; struct datarec *p = &prev->cpu[i]; char str[64]; pps = calc_pps(r, p, t); drop = calc_drop_pps(r, p, t); err = calc_errs_pps(r, p, t); if (!pps && !drop && !err) continue; snprintf(str, sizeof(str), "cpu:%d->%d", i, to_cpu); if (err > 0) err = pps / err; /* calc average bulk size */ print_default( " %-18s " FMT_COLUMNf FMT_COLUMNf __COLUMN( ".2f") "\n", str, PPS(pps), DROP(drop), err, "bulk-avg"); } } } static void stats_get_cpumap_remote(struct stats_record *stats_rec, struct stats_record *stats_prev, int nr_cpus) { double xdp_pass, xdp_drop, xdp_redirect; struct record *rec, *prev; double t; int i; rec = &stats_rec->kthread; prev = &stats_prev->kthread; t = calc_period(rec, prev); calc_xdp_pps(&rec->total, &prev->total, &xdp_pass, &xdp_drop, &xdp_redirect, t); if (xdp_pass || xdp_drop || xdp_redirect) { print_err(xdp_drop, " %-18s " FMT_COLUMNf FMT_COLUMNf FMT_COLUMNf "\n", "xdp_stats", PASS(xdp_pass), DROP(xdp_drop), REDIR(xdp_redirect)); } for (i = 0; i < nr_cpus; i++) { struct datarec *r = &rec->cpu[i]; struct datarec *p = &prev->cpu[i]; char str[64]; calc_xdp_pps(r, p, &xdp_pass, &xdp_drop, &xdp_redirect, t); if (!xdp_pass && !xdp_drop && !xdp_redirect) continue; snprintf(str, sizeof(str), "cpu:%d", i); print_default(" %-16s " FMT_COLUMNf FMT_COLUMNf FMT_COLUMNf "\n", str, PASS(xdp_pass), DROP(xdp_drop), REDIR(xdp_redirect)); } } static void stats_get_cpumap_kthread(struct stats_record *stats_rec, struct stats_record *stats_prev, int nr_cpus) { struct record *rec, *prev; double t, pps, drop, err; int i; rec = &stats_rec->kthread; prev = &stats_prev->kthread; t = calc_period(rec, prev); pps = calc_pps(&rec->total, &prev->total, t); drop = calc_drop_pps(&rec->total, &prev->total, t); err = calc_errs_pps(&rec->total, &prev->total, t); print_err(drop, " %-20s " FMT_COLUMNf FMT_COLUMNf FMT_COLUMNf "\n", pps ? "kthread total" : "kthread", PPS(pps), DROP(drop), err, "sched"); for (i = 0; i < nr_cpus; i++) { struct datarec *r = &rec->cpu[i]; struct datarec *p = &prev->cpu[i]; char str[64]; pps = calc_pps(r, p, t); drop = calc_drop_pps(r, p, t); err = calc_errs_pps(r, p, t); if (!pps && !drop && !err) continue; snprintf(str, sizeof(str), "cpu:%d", i); print_default(" %-18s " FMT_COLUMNf FMT_COLUMNf FMT_COLUMNf "\n", str, PPS(pps), DROP(drop), err, "sched"); } } static void stats_get_redirect_cnt(struct stats_record *stats_rec, struct stats_record *stats_prev, int nr_cpus, struct sample_output *out) { struct record *rec, *prev; double t, pps; int i; rec = &stats_rec->redir_err[0]; prev = &stats_prev->redir_err[0]; t = calc_period(rec, prev); for (i = 0; i < nr_cpus; i++) { struct datarec *r = &rec->cpu[i]; struct datarec *p = &prev->cpu[i]; char str[64]; pps = calc_pps(r, p, t); if (!pps) continue; snprintf(str, sizeof(str), "cpu:%d", i); print_default(" %-18s " FMT_COLUMNf "\n", str, REDIR(pps)); } if (out) { pps = calc_pps(&rec->total, &prev->total, t); out->redir_cnt.suc = pps; out->totals.redir += pps; } } static void stats_get_redirect_err_cnt(struct stats_record *stats_rec, struct stats_record *stats_prev, int nr_cpus, struct sample_output *out) { struct record *rec, *prev; double t, drop, sum = 0; int rec_i, i; for (rec_i = 1; rec_i < XDP_REDIRECT_ERR_MAX; rec_i++) { char str[64]; rec = &stats_rec->redir_err[rec_i]; prev = &stats_prev->redir_err[rec_i]; t = calc_period(rec, prev); drop = calc_drop_pps(&rec->total, &prev->total, t); if (drop > 0 && !out) { snprintf(str, sizeof(str), sample_log_level & LL_DEFAULT ? "%s total" : "%s", xdp_redirect_err_names[rec_i]); print_err(drop, " %-18s " FMT_COLUMNf "\n", str, ERR(drop)); } for (i = 0; i < nr_cpus; i++) { struct datarec *r = &rec->cpu[i]; struct datarec *p = &prev->cpu[i]; double drop; drop = calc_drop_pps(r, p, t); if (!drop) continue; snprintf(str, sizeof(str), "cpu:%d", i); print_default(" %-16s" FMT_COLUMNf "\n", str, ERR(drop)); } sum += drop; } if (out) { out->redir_cnt.err = sum; out->totals.err += sum; } } static void stats_get_exception_cnt(struct stats_record *stats_rec, struct stats_record *stats_prev, int nr_cpus, struct sample_output *out) { double t, drop, sum = 0; struct record *rec, *prev; int rec_i, i; for (rec_i = 0; rec_i < XDP_ACTION_MAX; rec_i++) { rec = &stats_rec->exception[rec_i]; prev = &stats_prev->exception[rec_i]; t = calc_period(rec, prev); drop = calc_drop_pps(&rec->total, &prev->total, t); /* Fold out errors after heading */ sum += drop; if (drop > 0 && !out) { print_always(" %-18s " FMT_COLUMNf "\n", xdp_action2str(rec_i), ERR(drop)); for (i = 0; i < nr_cpus; i++) { struct datarec *r = &rec->cpu[i]; struct datarec *p = &prev->cpu[i]; char str[64]; double drop; drop = calc_drop_pps(r, p, t); if (!drop) continue; snprintf(str, sizeof(str), "cpu:%d", i); print_default(" %-16s" FMT_COLUMNf "\n", str, ERR(drop)); } } } if (out) { out->except_cnt.hits = sum; out->totals.err += sum; } } static void stats_get_devmap_xmit(struct stats_record *stats_rec, struct stats_record *stats_prev, int nr_cpus, struct sample_output *out) { double pps, drop, info, err; struct record *rec, *prev; double t; int i; rec = &stats_rec->devmap_xmit; prev = &stats_prev->devmap_xmit; t = calc_period(rec, prev); for (i = 0; i < nr_cpus; i++) { struct datarec *r = &rec->cpu[i]; struct datarec *p = &prev->cpu[i]; char str[64]; pps = calc_pps(r, p, t); drop = calc_drop_pps(r, p, t); err = calc_errs_pps(r, p, t); if (!pps && !drop && !err) continue; snprintf(str, sizeof(str), "cpu:%d", i); info = calc_info_pps(r, p, t); if (info > 0) info = (pps + drop) / info; /* calc avg bulk */ print_default(" %-18s" FMT_COLUMNf FMT_COLUMNf FMT_COLUMNf __COLUMN(".2f") "\n", str, XMIT(pps), DROP(drop), err, "drv_err/s", info, "bulk-avg"); } if (out) { pps = calc_pps(&rec->total, &prev->total, t); drop = calc_drop_pps(&rec->total, &prev->total, t); info = calc_info_pps(&rec->total, &prev->total, t); if (info > 0) info = (pps + drop) / info; /* calc avg bulk */ err = calc_errs_pps(&rec->total, &prev->total, t); out->xmit_cnt.pps = pps; out->xmit_cnt.drop = drop; out->xmit_cnt.bavg = info; out->xmit_cnt.err = err; out->totals.xmit += pps; out->totals.drop_xmit += drop; out->totals.err += err; } } static void stats_get_devmap_xmit_multi(struct stats_record *stats_rec, struct stats_record *stats_prev, int nr_cpus, struct sample_output *out) { double pps, drop, info, err; struct map_entry *entry; struct record *r, *p; unsigned int bkt; double t; hash_for_each(stats_rec->xmit_map, bkt, entry, node) { struct map_entry *e, *x = NULL; char ifname_from[IFNAMSIZ]; char ifname_to[IFNAMSIZ]; const char *fstr, *tstr; unsigned long prev_time; struct record beg = {}; __u32 from_idx, to_idx; char str[128]; __u64 pair; int i; prev_time = sample_interval * NANOSEC_PER_SEC; pair = entry->pair; from_idx = pair >> 32; to_idx = pair & 0xFFFFFFFF; r = &entry->val; beg.timestamp = r->timestamp - prev_time; /* Find matching entry from stats_prev map */ hash_for_each_possible(stats_prev->xmit_map, e, node, pair) { if (e->pair == pair) { x = e; break; } } if (x) p = &x->val; else p = &beg; t = calc_period(r, p); pps = calc_pps(&r->total, &p->total, t); drop = calc_drop_pps(&r->total, &p->total, t); info = calc_info_pps(&r->total, &p->total, t); if (info > 0) info = (pps + drop) / info; /* calc avg bulk */ err = calc_errs_pps(&r->total, &p->total, t); if (out) { /* We are responsible for filling out totals */ out->totals.xmit += pps; out->totals.drop_xmit += drop; out->totals.err += err; continue; } fstr = tstr = NULL; if (if_indextoname(from_idx, ifname_from)) fstr = ifname_from; if (if_indextoname(to_idx, ifname_to)) tstr = ifname_to; snprintf(str, sizeof(str), "xmit %s->%s", fstr ?: "?", tstr ?: "?"); /* Skip idle streams of redirection */ if (pps || drop || err) { print_err(drop * !(sample_mask & SAMPLE_DROP_OK), " %-20s " FMT_COLUMNf FMT_COLUMNf FMT_COLUMNf __COLUMN(".2f") "\n", str, XMIT(pps), DROP(drop), err, "drv_err/s", info, "bulk-avg"); } for (i = 0; i < nr_cpus; i++) { struct datarec *rc = &r->cpu[i]; struct datarec *pc, p_beg = {}; char str[64]; pc = p == &beg ? &p_beg : &p->cpu[i]; pps = calc_pps(rc, pc, t); drop = calc_drop_pps(rc, pc, t); err = calc_errs_pps(rc, pc, t); if (!pps && !drop && !err) continue; snprintf(str, sizeof(str), "cpu:%d", i); info = calc_info_pps(rc, pc, t); if (info > 0) info = (pps + drop) / info; /* calc avg bulk */ print_default(" %-18s" FMT_COLUMNf FMT_COLUMNf FMT_COLUMNf __COLUMN(".2f") "\n", str, XMIT(pps), DROP(drop), err, "drv_err/s", info, "bulk-avg"); } } } static void stats_print(const char *prefix, int mask, struct stats_record *r, struct stats_record *p, struct sample_output *out) { int nr_cpus = libbpf_num_possible_cpus(); const char *str; print_always("%-23s", prefix ?: "Summary"); if (mask & SAMPLE_RX_CNT) print_always(FMT_COLUMNl, RX(out->totals.rx)); if (mask & SAMPLE_REDIRECT_CNT) print_always(FMT_COLUMNl, REDIR(out->totals.redir)); printf(FMT_COLUMNl, out->totals.err + ((out->totals.drop_xmit + out->totals.drop) * !(mask & SAMPLE_DROP_OK)), (mask & SAMPLE_DROP_OK) ? "err/s" : "err,drop/s"); if (mask & SAMPLE_DEVMAP_XMIT_CNT || mask & SAMPLE_DEVMAP_XMIT_CNT_MULTI) printf(FMT_COLUMNl, XMIT(out->totals.xmit)); printf("\n"); if (mask & SAMPLE_RX_CNT) { str = (sample_log_level & LL_DEFAULT) && out->rx_cnt.pps ? "receive total" : "receive"; print_err((out->rx_cnt.err || (out->rx_cnt.drop && !(mask & SAMPLE_DROP_OK))), " %-20s " FMT_COLUMNl FMT_COLUMNl FMT_COLUMNl "\n", str, PPS(out->rx_cnt.pps), DROP(out->rx_cnt.drop), ERR(out->rx_cnt.err)); stats_get_rx_cnt(r, p, nr_cpus, NULL); } if (mask & SAMPLE_RXQ_STATS) stats_get_rxq_cnt(r, p); if (mask & SAMPLE_CPUMAP_ENQUEUE_CNT) stats_get_cpumap_enqueue(r, p, nr_cpus); if (mask & SAMPLE_CPUMAP_KTHREAD_CNT) { stats_get_cpumap_kthread(r, p, nr_cpus); stats_get_cpumap_remote(r, p, nr_cpus); } if (mask & SAMPLE_REDIRECT_CNT) { str = out->redir_cnt.suc ? "redirect total" : "redirect"; print_default(" %-20s " FMT_COLUMNl "\n", str, REDIR(out->redir_cnt.suc)); stats_get_redirect_cnt(r, p, nr_cpus, NULL); } if (mask & SAMPLE_REDIRECT_ERR_CNT) { str = (sample_log_level & LL_DEFAULT) && out->redir_cnt.err ? "redirect_err total" : "redirect_err"; print_err(out->redir_cnt.err, " %-20s " FMT_COLUMNl "\n", str, ERR(out->redir_cnt.err)); stats_get_redirect_err_cnt(r, p, nr_cpus, NULL); } if (mask & SAMPLE_EXCEPTION_CNT) { str = out->except_cnt.hits ? "xdp_exception total" : "xdp_exception"; print_err(out->except_cnt.hits, " %-20s " FMT_COLUMNl "\n", str, HITS(out->except_cnt.hits)); stats_get_exception_cnt(r, p, nr_cpus, NULL); } if (mask & SAMPLE_DEVMAP_XMIT_CNT) { str = (sample_log_level & LL_DEFAULT) && out->xmit_cnt.pps ? "devmap_xmit total" : "devmap_xmit"; print_err(out->xmit_cnt.err || out->xmit_cnt.drop, " %-20s " FMT_COLUMNl FMT_COLUMNl FMT_COLUMNl __COLUMN(".2f") "\n", str, XMIT(out->xmit_cnt.pps), DROP(out->xmit_cnt.drop), (uint64_t)out->xmit_cnt.err, "drv_err/s", out->xmit_cnt.bavg, "bulk-avg"); stats_get_devmap_xmit(r, p, nr_cpus, NULL); } if (mask & SAMPLE_DEVMAP_XMIT_CNT_MULTI) stats_get_devmap_xmit_multi(r, p, nr_cpus, NULL); if (sample_log_level & LL_DEFAULT || ((sample_log_level & LL_SIMPLE) && sample_err_exp)) { sample_err_exp = false; printf("\n"); } } static int get_num_rxqs(const char *ifname) { struct ethtool_channels ch = { .cmd = ETHTOOL_GCHANNELS, }; struct ifreq ifr = { .ifr_data = (void *)&ch, }; int fd, ret; if (!ifname || strlen(ifname) > sizeof(ifr.ifr_name) - 1) return 0; strcpy(ifr.ifr_name, ifname); fd = socket(AF_UNIX, SOCK_DGRAM, 0); if (fd < 0) { ret = -errno; pr_warn("Couldn't open socket socket: %s\n", strerror(-ret)); return ret; } ret = ioctl(fd, SIOCETHTOOL, &ifr); if (ret < 0) { ret = -errno; pr_debug("Error in ethtool ioctl: %s\n", strerror(-ret)); goto out; } ret = ch.rx_count + ch.combined_count; pr_debug("Got %d queues for ifname %s\n", ret, ifname); out: close(fd); return ret; } int sample_setup_maps(struct bpf_map **maps, const char *ifname) { sample_n_cpus = libbpf_num_possible_cpus(); for (int i = 0; i < MAP_DEVMAP_XMIT_MULTI; i++) { sample_map[i] = maps[i]; int n_cpus; switch (i) { case MAP_RX: case MAP_CPUMAP_KTHREAD: case MAP_DEVMAP_XMIT: sample_map_count[i] = sample_n_cpus; break; case MAP_RXQ: sample_n_rxqs = get_num_rxqs(ifname); sample_map_count[i] = sample_n_rxqs > 0 ? sample_n_rxqs : 1; break; case MAP_REDIRECT_ERR: sample_map_count[i] = XDP_REDIRECT_ERR_MAX * sample_n_cpus; break; case MAP_EXCEPTION: sample_map_count[i] = XDP_ACTION_MAX * sample_n_cpus; break; case MAP_CPUMAP_ENQUEUE: if (__builtin_mul_overflow(sample_n_cpus, sample_n_cpus, &n_cpus)) return -EOVERFLOW; sample_map_count[i] = n_cpus; break; default: return -EINVAL; } if (bpf_map__set_max_entries(sample_map[i], sample_map_count[i]) < 0) return -errno; } sample_map[MAP_DEVMAP_XMIT_MULTI] = maps[MAP_DEVMAP_XMIT_MULTI]; return 0; } static int sample_setup_maps_mappings(void) { for (int i = 0; i < MAP_DEVMAP_XMIT_MULTI; i++) { size_t size = sample_map_count[i] * sizeof(struct datarec); sample_mmap[i] = mmap(NULL, size, PROT_READ | PROT_WRITE, MAP_SHARED, bpf_map__fd(sample_map[i]), 0); if (sample_mmap[i] == MAP_FAILED) return -errno; } return 0; } int __sample_init(int mask, int ifindex_from, int ifindex_to) { sigset_t st; if (mask & SAMPLE_RXQ_STATS && sample_n_rxqs <= 0) { pr_warn("Couldn't retrieve the number of RXQs, so can't enable RXQ stats\n"); return -EINVAL; } sigemptyset(&st); sigaddset(&st, SIGQUIT); sigaddset(&st, SIGINT); sigaddset(&st, SIGTERM); if (sigprocmask(SIG_BLOCK, &st, NULL) < 0) return -errno; sample_sig_fd = signalfd(-1, &st, SFD_CLOEXEC | SFD_NONBLOCK); if (sample_sig_fd < 0) return -errno; sample_mask = mask; ifindex[0] = ifindex_from; ifindex[1] = ifindex_to; return sample_setup_maps_mappings(); } static void sample_summary_print(void) { double num = sample_out.rx_cnt.num; if (sample_out.totals.rx) { double pkts = sample_out.totals.rx; print_always(" Packets received : %'-10" PRIu64 "\n", (uint64_t)sample_out.totals.rx); print_always(" Average packets/s : %'-10.0f\n", sample_round(pkts / num)); } if (sample_out.totals.redir) { double pkts = sample_out.totals.redir; print_always(" Packets redirected : %'-10" PRIu64 "\n", sample_out.totals.redir); print_always(" Average redir/s : %'-10.0f\n", sample_round(pkts / num)); } if (sample_out.totals.drop) print_always(" Rx dropped : %'-10" PRIu64 "\n", sample_out.totals.drop); if (sample_out.totals.drop_xmit) print_always(" Tx dropped : %'-10" PRIu64 "\n", sample_out.totals.drop_xmit); if (sample_out.totals.err) print_always(" Errors recorded : %'-10" PRIu64 "\n", sample_out.totals.err); if (sample_out.totals.xmit) { double pkts = sample_out.totals.xmit; print_always(" Packets transmitted : %'-10" PRIu64 "\n", sample_out.totals.xmit); print_always(" Average transmit/s : %'-10.0f\n", sample_round(pkts / num)); } } void sample_teardown(void) { size_t size; for (int i = 0; i < NUM_MAP; i++) { size = sample_map_count[i] * sizeof(**sample_mmap); munmap(sample_mmap[i], size); } sample_summary_print(); close(sample_sig_fd); } static int sample_stats_collect(struct stats_record *rec) { int i; if (sample_mask & SAMPLE_RX_CNT) map_collect_percpu(sample_mmap[MAP_RX], &rec->rx_cnt); if (sample_mask & SAMPLE_RXQ_STATS) map_collect_rxqs(sample_mmap[MAP_RXQ], &rec->rxq_cnt); if (sample_mask & SAMPLE_REDIRECT_CNT) map_collect_percpu(sample_mmap[MAP_REDIRECT_ERR], &rec->redir_err[0]); if (sample_mask & SAMPLE_REDIRECT_ERR_CNT) { for (i = 1; i < XDP_REDIRECT_ERR_MAX; i++) map_collect_percpu(&sample_mmap[MAP_REDIRECT_ERR][i * sample_n_cpus], &rec->redir_err[i]); } if (sample_mask & SAMPLE_CPUMAP_ENQUEUE_CNT) for (i = 0; i < sample_n_cpus; i++) map_collect_percpu(&sample_mmap[MAP_CPUMAP_ENQUEUE][i * sample_n_cpus], &rec->enq[i]); if (sample_mask & SAMPLE_CPUMAP_KTHREAD_CNT) map_collect_percpu(sample_mmap[MAP_CPUMAP_KTHREAD], &rec->kthread); if (sample_mask & SAMPLE_EXCEPTION_CNT) for (i = 0; i < XDP_ACTION_MAX; i++) map_collect_percpu(&sample_mmap[MAP_EXCEPTION][i * sample_n_cpus], &rec->exception[i]); if (sample_mask & SAMPLE_DEVMAP_XMIT_CNT) map_collect_percpu(sample_mmap[MAP_DEVMAP_XMIT], &rec->devmap_xmit); if (sample_mask & SAMPLE_DEVMAP_XMIT_CNT_MULTI) { if (map_collect_percpu_devmap(bpf_map__fd(sample_map[MAP_DEVMAP_XMIT_MULTI]), rec) < 0) return -EINVAL; } return 0; } static void sample_summary_update(struct sample_output *out) { sample_out.totals.rx += out->totals.rx; sample_out.totals.redir += out->totals.redir; sample_out.totals.drop += out->totals.drop; sample_out.totals.drop_xmit += out->totals.drop_xmit; sample_out.totals.err += out->totals.err; sample_out.totals.xmit += out->totals.xmit; sample_out.rx_cnt.num++; } static void sample_stats_print(int mask, struct stats_record *cur, struct stats_record *prev, char *prog_name) { struct sample_output out = {}; if (mask & SAMPLE_RX_CNT) stats_get_rx_cnt(cur, prev, 0, &out); if (mask & SAMPLE_REDIRECT_CNT) stats_get_redirect_cnt(cur, prev, 0, &out); if (mask & SAMPLE_REDIRECT_ERR_CNT) stats_get_redirect_err_cnt(cur, prev, 0, &out); if (mask & SAMPLE_EXCEPTION_CNT) stats_get_exception_cnt(cur, prev, 0, &out); if (mask & SAMPLE_DEVMAP_XMIT_CNT) stats_get_devmap_xmit(cur, prev, 0, &out); else if (mask & SAMPLE_DEVMAP_XMIT_CNT_MULTI) stats_get_devmap_xmit_multi(cur, prev, 0, &out); sample_summary_update(&out); stats_print(prog_name, mask, cur, prev, &out); } void sample_switch_mode(void) { sample_log_level ^= LL_DEBUG - 1; } static int sample_signal_cb(void) { struct signalfd_siginfo si; int r; r = read(sample_sig_fd, &si, sizeof(si)); if (r < 0) return -errno; switch (si.ssi_signo) { case SIGQUIT: sample_switch_mode(); printf("\n"); break; default: printf("\n"); return 1; } return 0; } /* Pointer swap trick */ static void swap(struct stats_record **a, struct stats_record **b) { struct stats_record *tmp; tmp = *a; *a = *b; *b = tmp; } static int sample_timer_cb(int timerfd, struct stats_record **rec, struct stats_record **prev) { char line[64] = "Summary"; int ret; __u64 t; ret = read(timerfd, &t, sizeof(t)); if (ret < 0) return -errno; swap(prev, rec); ret = sample_stats_collect(*rec); if (ret < 0) return ret; if (ifindex[0] && !(sample_mask & SAMPLE_SKIP_HEADING)) { char fi[IFNAMSIZ]; char to[IFNAMSIZ]; const char *f, *t; f = t = NULL; if (if_indextoname(ifindex[0], fi)) f = fi; if (if_indextoname(ifindex[1], to)) t = to; snprintf(line, sizeof(line), "%s->%s", f ?: "?", t ?: "?"); } sample_stats_print(sample_mask, *rec, *prev, line); return 0; } int sample_run(int interval, void (*post_cb)(void *), void *ctx) { struct timespec ts = { interval, 0 }; struct itimerspec its = { ts, ts }; struct stats_record *rec, *prev; struct pollfd pfd[2] = {}; bool imm_exit = false; const char *envval; int timerfd, ret; envval = secure_getenv("XDP_SAMPLE_IMMEDIATE_EXIT"); if (envval && envval[0] == '1' && envval[1] == '\0') { pr_debug("XDP_SAMPLE_IMMEDIATE_EXIT envvar set, exiting immediately after setup\n"); imm_exit = true; } if (!interval) { pr_warn("Incorrect interval 0\n"); return -EINVAL; } sample_interval = interval; /* Pretty print numbers */ setlocale(LC_NUMERIC, "en_US.UTF-8"); timerfd = timerfd_create(CLOCK_MONOTONIC, TFD_CLOEXEC | TFD_NONBLOCK); if (timerfd < 0) return -errno; timerfd_settime(timerfd, 0, &its, NULL); pfd[0].fd = sample_sig_fd; pfd[0].events = POLLIN; pfd[1].fd = timerfd; pfd[1].events = POLLIN; ret = -ENOMEM; rec = alloc_stats_record(); if (!rec) goto end; prev = alloc_stats_record(); if (!prev) goto end_rec; ret = sample_stats_collect(rec); if (ret < 0) goto end_rec_prev; if (imm_exit) goto end_rec_prev; for (;;) { ret = poll(pfd, 2, -1); if (ret < 0) { if (errno == EINTR) continue; else break; } if (pfd[0].revents & POLLIN) ret = sample_signal_cb(); else if (pfd[1].revents & POLLIN) ret = sample_timer_cb(timerfd, &rec, &prev); if (ret) break; if (post_cb) post_cb(ctx); } end_rec_prev: free_stats_record(prev); end_rec: free_stats_record(rec); end: close(timerfd); return ret; } const char *get_driver_name(int ifindex) { struct ethtool_drvinfo drv = {}; char ifname[IF_NAMESIZE]; static char drvname[32]; struct ifreq ifr = {}; int fd, r = 0; fd = socket(AF_INET, SOCK_DGRAM, 0); if (fd < 0) return "[error]"; if (!if_indextoname(ifindex, ifname)) goto end; drv.cmd = ETHTOOL_GDRVINFO; safe_strncpy(ifr.ifr_name, ifname, sizeof(ifr.ifr_name)); ifr.ifr_data = (void *)&drv; r = ioctl(fd, SIOCETHTOOL, &ifr); if (r) goto end; safe_strncpy(drvname, drv.driver, sizeof(drvname)); close(fd); return drvname; end: r = errno; close(fd); return r == EOPNOTSUPP ? "loopback" : "[error]"; } int get_mac_addr(int ifindex, void *mac_addr) { char ifname[IF_NAMESIZE]; struct ifreq ifr = {}; int fd, r; fd = socket(AF_INET, SOCK_DGRAM, 0); if (fd < 0) return -errno; if (!if_indextoname(ifindex, ifname)) { r = -errno; goto end; } safe_strncpy(ifr.ifr_name, ifname, sizeof(ifr.ifr_name)); r = ioctl(fd, SIOCGIFHWADDR, &ifr); if (r) { r = -errno; goto end; } memcpy(mac_addr, ifr.ifr_hwaddr.sa_data, 6 * sizeof(char)); end: close(fd); return r; }