#include #include #include #include #include #include #include #include #include #include #include #include #include "nl80211.h" #include "iw.h" struct channels_ctx { int last_band; bool width_40; bool width_80; bool width_160; }; static char *dfs_state_name(enum nl80211_dfs_state state) { switch (state) { case NL80211_DFS_USABLE: return "usable"; case NL80211_DFS_AVAILABLE: return "available"; case NL80211_DFS_UNAVAILABLE: return "unavailable"; default: return "unknown"; } } static int print_channels_handler(struct nl_msg *msg, void *arg) { struct genlmsghdr *gnlh = nlmsg_data(nlmsg_hdr(msg)); struct channels_ctx *ctx = arg; struct nlattr *tb_msg[NL80211_ATTR_MAX + 1]; struct nlattr *tb_band[NL80211_BAND_ATTR_MAX + 1]; struct nlattr *tb_freq[NL80211_FREQUENCY_ATTR_MAX + 1]; struct nlattr *nl_band; struct nlattr *nl_freq; int rem_band, rem_freq; nla_parse(tb_msg, NL80211_ATTR_MAX, genlmsg_attrdata(gnlh, 0), genlmsg_attrlen(gnlh, 0), NULL); if (tb_msg[NL80211_ATTR_WIPHY_BANDS]) { nla_for_each_nested(nl_band, tb_msg[NL80211_ATTR_WIPHY_BANDS], rem_band) { if (ctx->last_band != nl_band->nla_type) { printf("Band %d:\n", nl_band->nla_type + 1); ctx->width_40 = false; ctx->width_80 = false; ctx->width_160 = false; ctx->last_band = nl_band->nla_type; } nla_parse(tb_band, NL80211_BAND_ATTR_MAX, nla_data(nl_band), nla_len(nl_band), NULL); if (tb_band[NL80211_BAND_ATTR_HT_CAPA]) { __u16 cap = nla_get_u16(tb_band[NL80211_BAND_ATTR_HT_CAPA]); if (cap & BIT(1)) ctx->width_40 = true; } if (tb_band[NL80211_BAND_ATTR_VHT_CAPA]) { __u32 capa; ctx->width_80 = true; capa = nla_get_u32(tb_band[NL80211_BAND_ATTR_VHT_CAPA]); switch ((capa >> 2) & 3) { case 2: /* width_80p80 = true; */ /* fall through */ case 1: ctx->width_160 = true; break; } } if (tb_band[NL80211_BAND_ATTR_FREQS]) { nla_for_each_nested(nl_freq, tb_band[NL80211_BAND_ATTR_FREQS], rem_freq) { uint32_t freq; nla_parse(tb_freq, NL80211_FREQUENCY_ATTR_MAX, nla_data(nl_freq), nla_len(nl_freq), NULL); if (!tb_freq[NL80211_FREQUENCY_ATTR_FREQ]) continue; freq = nla_get_u32(tb_freq[NL80211_FREQUENCY_ATTR_FREQ]); printf("\t* %d MHz [%d] ", freq, ieee80211_frequency_to_channel(freq)); if (tb_freq[NL80211_FREQUENCY_ATTR_DISABLED]) { printf("(disabled)\n"); continue; } printf("\n"); if (tb_freq[NL80211_FREQUENCY_ATTR_MAX_TX_POWER]) printf("\t Maximum TX power: %.1f dBm\n", 0.01 * nla_get_u32(tb_freq[NL80211_FREQUENCY_ATTR_MAX_TX_POWER])); /* If both flags are set assume an new kernel */ if (tb_freq[NL80211_FREQUENCY_ATTR_NO_IR] && tb_freq[__NL80211_FREQUENCY_ATTR_NO_IBSS]) { printf("\t No IR\n"); } else if (tb_freq[NL80211_FREQUENCY_ATTR_PASSIVE_SCAN]) { printf("\t Passive scan\n"); } else if (tb_freq[__NL80211_FREQUENCY_ATTR_NO_IBSS]){ printf("\t No IBSS\n"); } if (tb_freq[NL80211_FREQUENCY_ATTR_RADAR]) printf("\t Radar detection\n"); printf("\t Channel widths:"); if (!tb_freq[NL80211_FREQUENCY_ATTR_NO_20MHZ]) printf(" 20MHz"); if (ctx->width_40 && !tb_freq[NL80211_FREQUENCY_ATTR_NO_HT40_MINUS]) printf(" HT40-"); if (ctx->width_40 && !tb_freq[NL80211_FREQUENCY_ATTR_NO_HT40_PLUS]) printf(" HT40+"); if (ctx->width_80 && !tb_freq[NL80211_FREQUENCY_ATTR_NO_80MHZ]) printf(" VHT80"); if (ctx->width_160 && !tb_freq[NL80211_FREQUENCY_ATTR_NO_160MHZ]) printf(" VHT160"); printf("\n"); if (!tb_freq[NL80211_FREQUENCY_ATTR_DISABLED] && tb_freq[NL80211_FREQUENCY_ATTR_DFS_STATE]) { enum nl80211_dfs_state state = nla_get_u32(tb_freq[NL80211_FREQUENCY_ATTR_DFS_STATE]); unsigned long time; printf("\t DFS state: %s", dfs_state_name(state)); if (tb_freq[NL80211_FREQUENCY_ATTR_DFS_TIME]) { time = nla_get_u32(tb_freq[NL80211_FREQUENCY_ATTR_DFS_TIME]); printf(" (for %lu sec)", time / 1000); } printf("\n"); if (tb_freq[NL80211_FREQUENCY_ATTR_DFS_CAC_TIME]) printf("\t DFS CAC time: %u ms\n", nla_get_u32(tb_freq[NL80211_FREQUENCY_ATTR_DFS_CAC_TIME])); } } } } } return NL_SKIP; } static int handle_channels(struct nl80211_state *state, struct nl_msg *msg, int argc, char **argv, enum id_input id) { static struct channels_ctx ctx = { .last_band = -1, }; nla_put_flag(msg, NL80211_ATTR_SPLIT_WIPHY_DUMP); nlmsg_hdr(msg)->nlmsg_flags |= NLM_F_DUMP; register_handler(print_channels_handler, &ctx); return 0; } TOPLEVEL(channels, NULL, NL80211_CMD_GET_WIPHY, 0, CIB_PHY, handle_channels, "Show available channels."); static int handle_name(struct nl80211_state *state, struct nl_msg *msg, int argc, char **argv, enum id_input id) { if (argc != 1) return 1; NLA_PUT_STRING(msg, NL80211_ATTR_WIPHY_NAME, *argv); return 0; nla_put_failure: return -ENOBUFS; } COMMAND(set, name, "", NL80211_CMD_SET_WIPHY, 0, CIB_PHY, handle_name, "Rename this wireless device."); static int handle_freq(struct nl80211_state *state, struct nl_msg *msg, int argc, char **argv, enum id_input id) { struct chandef chandef; int res; res = parse_freqchan(&chandef, false, argc, argv, NULL); if (res) return res; return put_chandef(msg, &chandef); } COMMAND(set, freq, " [NOHT|HT20|HT40+|HT40-|5MHz|10MHz|80MHz|160MHz]\n" " [5|10|20|40|80|80+80|160] [ []]", NL80211_CMD_SET_WIPHY, 0, CIB_PHY, handle_freq, "Set frequency/channel the hardware is using, including HT\n" "configuration."); COMMAND(set, freq, " [NOHT|HT20|HT40+|HT40-|5MHz|10MHz|80MHz|160MHz]\n" " [5|10|20|40|80|80+80|160] [ []]", NL80211_CMD_SET_WIPHY, 0, CIB_NETDEV, handle_freq, NULL); static int handle_chan(struct nl80211_state *state, struct nl_msg *msg, int argc, char **argv, enum id_input id) { struct chandef chandef; int res; res = parse_freqchan(&chandef, true, argc, argv, NULL); if (res) return res; return put_chandef(msg, &chandef); } COMMAND(set, channel, " [NOHT|HT20|HT40+|HT40-|5MHz|10MHz|80MHz|160MHz]", NL80211_CMD_SET_WIPHY, 0, CIB_PHY, handle_chan, NULL); COMMAND(set, channel, " [NOHT|HT20|HT40+|HT40-|5MHz|10MHz|80MHz|160MHz]", NL80211_CMD_SET_WIPHY, 0, CIB_NETDEV, handle_chan, NULL); struct cac_event { int ret; uint32_t freq; }; static int print_cac_event(struct nl_msg *msg, void *arg) { struct nlattr *tb[NL80211_ATTR_MAX + 1]; struct genlmsghdr *gnlh = nlmsg_data(nlmsg_hdr(msg)); enum nl80211_radar_event event_type; struct cac_event *cac_event = arg; uint32_t freq; if (gnlh->cmd != NL80211_CMD_RADAR_DETECT) return NL_SKIP; nla_parse(tb, NL80211_ATTR_MAX, genlmsg_attrdata(gnlh, 0), genlmsg_attrlen(gnlh, 0), NULL); if (!tb[NL80211_ATTR_RADAR_EVENT] || !tb[NL80211_ATTR_WIPHY_FREQ]) return NL_SKIP; freq = nla_get_u32(tb[NL80211_ATTR_WIPHY_FREQ]); event_type = nla_get_u32(tb[NL80211_ATTR_RADAR_EVENT]); if (freq != cac_event->freq) return NL_SKIP; switch (event_type) { case NL80211_RADAR_DETECTED: printf("%d MHz: radar detected\n", freq); break; case NL80211_RADAR_CAC_FINISHED: printf("%d MHz: CAC finished\n", freq); break; case NL80211_RADAR_CAC_ABORTED: printf("%d MHz: CAC was aborted\n", freq); break; case NL80211_RADAR_NOP_FINISHED: printf("%d MHz: NOP finished\n", freq); break; default: printf("%d MHz: unknown radar event\n", freq); } cac_event->ret = 0; return NL_SKIP; } static int handle_cac_trigger(struct nl80211_state *state, struct nl_msg *msg, int argc, char **argv, enum id_input id) { struct chandef chandef; int res; if (argc < 2) return 1; if (strcmp(argv[0], "channel") == 0) { res = parse_freqchan(&chandef, true, argc - 1, argv + 1, NULL); } else if (strcmp(argv[0], "freq") == 0) { res = parse_freqchan(&chandef, false, argc - 1, argv + 1, NULL); } else { return 1; } if (res) return res; return put_chandef(msg, &chandef); } static int no_seq_check(struct nl_msg *msg, void *arg) { return NL_OK; } static int handle_cac(struct nl80211_state *state, struct nl_msg *msg, int argc, char **argv, enum id_input id) { int err; struct nl_cb *radar_cb; struct chandef chandef; struct cac_event cac_event; char **cac_trigger_argv = NULL; radar_cb = nl_cb_alloc(iw_debug ? NL_CB_DEBUG : NL_CB_DEFAULT); if (!radar_cb) return 1; if (argc < 3) return 1; if (strcmp(argv[2], "channel") == 0) { err = parse_freqchan(&chandef, true, argc - 3, argv + 3, NULL); } else if (strcmp(argv[2], "freq") == 0) { err = parse_freqchan(&chandef, false, argc - 3, argv + 3, NULL); } else { err = 1; } if (err) goto err_out; cac_trigger_argv = calloc(argc + 1, sizeof(char*)); if (!cac_trigger_argv) { err = -ENOMEM; goto err_out; } cac_trigger_argv[0] = argv[0]; cac_trigger_argv[1] = "cac"; cac_trigger_argv[2] = "trigger"; memcpy(&cac_trigger_argv[3], &argv[2], (argc - 2) * sizeof(char*)); err = handle_cmd(state, id, argc + 1, cac_trigger_argv); if (err) goto err_out; cac_event.ret = 1; cac_event.freq = chandef.control_freq; __prepare_listen_events(state); nl_socket_set_cb(state->nl_sock, radar_cb); /* need to turn off sequence number checking */ nl_cb_set(radar_cb, NL_CB_SEQ_CHECK, NL_CB_CUSTOM, no_seq_check, NULL); nl_cb_set(radar_cb, NL_CB_VALID, NL_CB_CUSTOM, print_cac_event, &cac_event); while (cac_event.ret > 0) nl_recvmsgs(state->nl_sock, radar_cb); err = 0; err_out: if (radar_cb) nl_cb_put(radar_cb); if (cac_trigger_argv) free(cac_trigger_argv); return err; } TOPLEVEL(cac, "channel [NOHT|HT20|HT40+|HT40-|5MHz|10MHz|80MHz]\n" "freq [NOHT|HT20|HT40+|HT40-|5MHz|10MHz|80MHz]\n" "freq [5|10|20|40|80|80+80|160] [ []]", 0, 0, CIB_NETDEV, handle_cac, NULL); COMMAND(cac, trigger, "channel [NOHT|HT20|HT40+|HT40-|5MHz|10MHz|80MHz]\n" "freq [NOHT|HT20|HT40+|HT40-|5MHz|10MHz|80MHz]\n" "freq [5|10|20|40|80|80+80|160] [ []]", NL80211_CMD_RADAR_DETECT, 0, CIB_NETDEV, handle_cac_trigger, "Start or trigger a channel availability check (CAC) looking to look for\n" "radars on the given channel."); static int handle_fragmentation(struct nl80211_state *state, struct nl_msg *msg, int argc, char **argv, enum id_input id) { unsigned int frag; if (argc != 1) return 1; if (strcmp("off", argv[0]) == 0) frag = -1; else { char *end; if (!*argv[0]) return 1; frag = strtoul(argv[0], &end, 10); if (*end != '\0') return 1; } NLA_PUT_U32(msg, NL80211_ATTR_WIPHY_FRAG_THRESHOLD, frag); return 0; nla_put_failure: return -ENOBUFS; } COMMAND(set, frag, "", NL80211_CMD_SET_WIPHY, 0, CIB_PHY, handle_fragmentation, "Set fragmentation threshold."); static int handle_rts(struct nl80211_state *state, struct nl_msg *msg, int argc, char **argv, enum id_input id) { unsigned int rts; if (argc != 1) return 1; if (strcmp("off", argv[0]) == 0) rts = -1; else { char *end; if (!*argv[0]) return 1; rts = strtoul(argv[0], &end, 10); if (*end != '\0') return 1; } NLA_PUT_U32(msg, NL80211_ATTR_WIPHY_RTS_THRESHOLD, rts); return 0; nla_put_failure: return -ENOBUFS; } COMMAND(set, rts, "", NL80211_CMD_SET_WIPHY, 0, CIB_PHY, handle_rts, "Set rts threshold."); static int handle_retry(struct nl80211_state *state, struct nl_msg *msg, int argc, char **argv, enum id_input id) { unsigned int retry_short = 0, retry_long = 0; bool have_retry_s = false, have_retry_l = false; int i; enum { S_NONE, S_SHORT, S_LONG, } parser_state = S_NONE; if (!argc || (argc != 2 && argc != 4)) return 1; for (i = 0; i < argc; i++) { char *end; unsigned int tmpul; if (strcmp(argv[i], "short") == 0) { if (have_retry_s) return 1; parser_state = S_SHORT; have_retry_s = true; } else if (strcmp(argv[i], "long") == 0) { if (have_retry_l) return 1; parser_state = S_LONG; have_retry_l = true; } else { tmpul = strtoul(argv[i], &end, 10); if (*end != '\0') return 1; if (!tmpul || tmpul > 255) return -EINVAL; switch (parser_state) { case S_SHORT: retry_short = tmpul; break; case S_LONG: retry_long = tmpul; break; default: return 1; } } } if (!have_retry_s && !have_retry_l) return 1; if (have_retry_s) NLA_PUT_U8(msg, NL80211_ATTR_WIPHY_RETRY_SHORT, retry_short); if (have_retry_l) NLA_PUT_U8(msg, NL80211_ATTR_WIPHY_RETRY_LONG, retry_long); return 0; nla_put_failure: return -ENOBUFS; } COMMAND(set, retry, "[short ] [long ]", NL80211_CMD_SET_WIPHY, 0, CIB_PHY, handle_retry, "Set retry limit."); #ifndef NETNS_RUN_DIR #define NETNS_RUN_DIR "/var/run/netns" #endif static int netns_get_fd(const char *name) { char pathbuf[MAXPATHLEN]; const char *path, *ptr; path = name; ptr = strchr(name, '/'); if (!ptr) { snprintf(pathbuf, sizeof(pathbuf), "%s/%s", NETNS_RUN_DIR, name ); path = pathbuf; } return open(path, O_RDONLY); } static int handle_netns(struct nl80211_state *state, struct nl_msg *msg, int argc, char **argv, enum id_input id) { char *end; int fd = -1; if (argc < 1 || !*argv[0]) return 1; if (argc == 1) { NLA_PUT_U32(msg, NL80211_ATTR_PID, strtoul(argv[0], &end, 10)); if (*end != '\0') { printf("Invalid parameter: pid(%s)\n", argv[0]); return 1; } return 0; } if (argc != 2 || strcmp(argv[0], "name")) return 1; if ((fd = netns_get_fd(argv[1])) >= 0) { NLA_PUT_U32(msg, NL80211_ATTR_NETNS_FD, fd); return 0; } else { printf("Invalid parameter: nsname(%s)\n", argv[0]); } return 1; nla_put_failure: if (fd >= 0) close(fd); return -ENOBUFS; } COMMAND(set, netns, "{ | name }", NL80211_CMD_SET_WIPHY_NETNS, 0, CIB_PHY, handle_netns, "Put this wireless device into a different network namespace:\n" " - change network namespace by process id\n" " - change network namespace by name from "NETNS_RUN_DIR"\n" " or by absolute path (man ip-netns)\n"); static int handle_coverage(struct nl80211_state *state, struct nl_msg *msg, int argc, char **argv, enum id_input id) { char *end; unsigned int coverage; if (argc != 1) return 1; if (!*argv[0]) return 1; coverage = strtoul(argv[0], &end, 10); if (coverage > 255) return 1; if (*end) return 1; NLA_PUT_U8(msg, NL80211_ATTR_WIPHY_COVERAGE_CLASS, coverage); return 0; nla_put_failure: return -ENOBUFS; } COMMAND(set, coverage, "", NL80211_CMD_SET_WIPHY, 0, CIB_PHY, handle_coverage, "Set coverage class (1 for every 3 usec of air propagation time).\n" "Valid values: 0 - 255."); static int handle_distance(struct nl80211_state *state, struct nl_msg *msg, int argc, char **argv, enum id_input id) { if (argc != 1) return 1; if (!*argv[0]) return 1; if (strcmp("auto", argv[0]) == 0) { NLA_PUT_FLAG(msg, NL80211_ATTR_WIPHY_DYN_ACK); } else { char *end; unsigned int distance, coverage; distance = strtoul(argv[0], &end, 10); if (*end) return 1; /* * Divide double the distance by the speed of light * in m/usec (300) to get round-trip time in microseconds * and then divide the result by three to get coverage class * as specified in IEEE 802.11-2007 table 7-27. * Values are rounded upwards. */ coverage = (distance + 449) / 450; if (coverage > 255) return 1; NLA_PUT_U8(msg, NL80211_ATTR_WIPHY_COVERAGE_CLASS, coverage); } return 0; nla_put_failure: return -ENOBUFS; } COMMAND(set, distance, "", NL80211_CMD_SET_WIPHY, 0, CIB_PHY, handle_distance, "Enable ACK timeout estimation algorithm (dynack) or set appropriate\n" "coverage class for given link distance in meters.\n" "To disable dynack set valid value for coverage class.\n" "Valid values: 0 - 114750"); static int handle_txpower(struct nl80211_state *state, struct nl_msg *msg, int argc, char **argv, enum id_input id) { enum nl80211_tx_power_setting type; int mbm; /* get the required args */ if (argc != 1 && argc != 2) return 1; if (!strcmp(argv[0], "auto")) type = NL80211_TX_POWER_AUTOMATIC; else if (!strcmp(argv[0], "fixed")) type = NL80211_TX_POWER_FIXED; else if (!strcmp(argv[0], "limit")) type = NL80211_TX_POWER_LIMITED; else { printf("Invalid parameter: %s\n", argv[0]); return 2; } NLA_PUT_U32(msg, NL80211_ATTR_WIPHY_TX_POWER_SETTING, type); if (type != NL80211_TX_POWER_AUTOMATIC) { char *endptr; if (argc != 2) { printf("Missing TX power level argument.\n"); return 2; } mbm = strtol(argv[1], &endptr, 10); if (*endptr) return 2; NLA_PUT_U32(msg, NL80211_ATTR_WIPHY_TX_POWER_LEVEL, mbm); } else if (argc != 1) return 1; return 0; nla_put_failure: return -ENOBUFS; } COMMAND(set, txpower, " []", NL80211_CMD_SET_WIPHY, 0, CIB_PHY, handle_txpower, "Specify transmit power level and setting type."); COMMAND(set, txpower, " []", NL80211_CMD_SET_WIPHY, 0, CIB_NETDEV, handle_txpower, "Specify transmit power level and setting type."); static int handle_antenna(struct nl80211_state *state, struct nl_msg *msg, int argc, char **argv, enum id_input id) { char *end; uint32_t tx_ant = 0, rx_ant = 0; if (argc == 1 && strcmp(argv[0], "all") == 0) { tx_ant = 0xffffffff; rx_ant = 0xffffffff; } else if (argc == 1) { tx_ant = rx_ant = strtoul(argv[0], &end, 0); if (*end) return 1; } else if (argc == 2) { tx_ant = strtoul(argv[0], &end, 0); if (*end) return 1; rx_ant = strtoul(argv[1], &end, 0); if (*end) return 1; } else return 1; NLA_PUT_U32(msg, NL80211_ATTR_WIPHY_ANTENNA_TX, tx_ant); NLA_PUT_U32(msg, NL80211_ATTR_WIPHY_ANTENNA_RX, rx_ant); return 0; nla_put_failure: return -ENOBUFS; } COMMAND(set, antenna, " | all | ", NL80211_CMD_SET_WIPHY, 0, CIB_PHY, handle_antenna, "Set a bitmap of allowed antennas to use for TX and RX.\n" "The driver may reject antenna configurations it cannot support."); static int handle_set_txq(struct nl80211_state *state, struct nl_msg *msg, int argc, char **argv, enum id_input id) { unsigned int argval; char *end; if (argc != 2) return 1; if (!*argv[0] || !*argv[1]) return 1; argval = strtoul(argv[1], &end, 10); if (*end) return 1; if (!argval) return 1; if (strcmp("limit", argv[0]) == 0) NLA_PUT_U32(msg, NL80211_ATTR_TXQ_LIMIT, argval); else if (strcmp("memory_limit", argv[0]) == 0) NLA_PUT_U32(msg, NL80211_ATTR_TXQ_MEMORY_LIMIT, argval); else if (strcmp("quantum", argv[0]) == 0) NLA_PUT_U32(msg, NL80211_ATTR_TXQ_QUANTUM, argval); else return -1; return 0; nla_put_failure: return -ENOBUFS; } COMMAND(set, txq, "limit | memory_limit | quantum ", NL80211_CMD_SET_WIPHY, 0, CIB_PHY, handle_set_txq, "Set TXQ parameters. The limit and memory_limit are global queue limits\n" "for the whole phy. The quantum is the DRR scheduler quantum setting.\n" "Valid values: 1 - 2**32"); static int print_txq_handler(struct nl_msg *msg, void *arg) { struct nlattr *attrs[NL80211_ATTR_MAX + 1]; struct genlmsghdr *gnlh = nlmsg_data(nlmsg_hdr(msg)); struct nlattr *txqstats_info[NL80211_TXQ_STATS_MAX + 1], *txqinfo; static struct nla_policy txqstats_policy[NL80211_TXQ_STATS_MAX + 1] = { [NL80211_TXQ_STATS_BACKLOG_PACKETS] = { .type = NLA_U32 }, [NL80211_TXQ_STATS_BACKLOG_BYTES] = { .type = NLA_U32 }, [NL80211_TXQ_STATS_OVERLIMIT] = { .type = NLA_U32 }, [NL80211_TXQ_STATS_OVERMEMORY] = { .type = NLA_U32 }, [NL80211_TXQ_STATS_COLLISIONS] = { .type = NLA_U32 }, [NL80211_TXQ_STATS_MAX_FLOWS] = { .type = NLA_U32 }, }; nla_parse(attrs, NL80211_ATTR_MAX, genlmsg_attrdata(gnlh, 0), genlmsg_attrlen(gnlh, 0), NULL); if (attrs[NL80211_ATTR_TXQ_LIMIT]) printf("Packet limit:\t\t%u pkts\n", nla_get_u32(attrs[NL80211_ATTR_TXQ_LIMIT])); if (attrs[NL80211_ATTR_TXQ_MEMORY_LIMIT]) printf("Memory limit:\t\t%u bytes\n", nla_get_u32(attrs[NL80211_ATTR_TXQ_MEMORY_LIMIT])); if (attrs[NL80211_ATTR_TXQ_QUANTUM]) printf("Quantum:\t\t%u bytes\n", nla_get_u32(attrs[NL80211_ATTR_TXQ_QUANTUM])); if (attrs[NL80211_ATTR_TXQ_STATS]) { if (nla_parse_nested(txqstats_info, NL80211_TXQ_STATS_MAX, attrs[NL80211_ATTR_TXQ_STATS], txqstats_policy)) { printf("failed to parse nested TXQ stats attributes!"); return 0; } txqinfo = txqstats_info[NL80211_TXQ_STATS_MAX_FLOWS]; if (txqinfo) printf("Number of queues:\t%u\n", nla_get_u32(txqinfo)); txqinfo = txqstats_info[NL80211_TXQ_STATS_BACKLOG_PACKETS]; if (txqinfo) printf("Backlog:\t\t%u pkts\n", nla_get_u32(txqinfo)); txqinfo = txqstats_info[NL80211_TXQ_STATS_BACKLOG_BYTES]; if (txqinfo) printf("Memory usage:\t\t%u bytes\n", nla_get_u32(txqinfo)); txqinfo = txqstats_info[NL80211_TXQ_STATS_OVERLIMIT]; if (txqinfo) printf("Packet limit overflows:\t%u\n", nla_get_u32(txqinfo)); txqinfo = txqstats_info[NL80211_TXQ_STATS_OVERMEMORY]; if (txqinfo) printf("Memory limit overflows:\t%u\n", nla_get_u32(txqinfo)); txqinfo = txqstats_info[NL80211_TXQ_STATS_COLLISIONS]; if (txqinfo) printf("Hash collisions:\t%u\n", nla_get_u32(txqinfo)); } return NL_SKIP; } static int handle_get_txq(struct nl80211_state *state, struct nl_msg *msg, int argc, char **argv, enum id_input id) { nla_put_flag(msg, NL80211_ATTR_SPLIT_WIPHY_DUMP); nlmsg_hdr(msg)->nlmsg_flags |= NLM_F_DUMP; register_handler(print_txq_handler, NULL); return 0; } COMMAND(get, txq, "", NL80211_CMD_GET_WIPHY, 0, CIB_PHY, handle_get_txq, "Get TXQ parameters.");