#include #include #include #include #include "iw.h" #include "nl80211.h" void mac_addr_n2a(char *mac_addr, const unsigned char *arg) { int i, l; l = 0; for (i = 0; i < ETH_ALEN ; i++) { if (i == 0) { sprintf(mac_addr+l, "%02x", arg[i]); l += 2; } else { sprintf(mac_addr+l, ":%02x", arg[i]); l += 3; } } } int mac_addr_a2n(unsigned char *mac_addr, char *arg) { int i; for (i = 0; i < ETH_ALEN ; i++) { int temp; char *cp = strchr(arg, ':'); if (cp) { *cp = 0; cp++; } if (sscanf(arg, "%x", &temp) != 1) return -1; if (temp < 0 || temp > 255) return -1; mac_addr[i] = temp; if (!cp) break; arg = cp; } if (i < ETH_ALEN - 1) return -1; return 0; } int parse_hex_mask(char *hexmask, unsigned char **result, size_t *result_len, unsigned char **mask) { size_t len = strlen(hexmask) / 2; unsigned char *result_val; unsigned char *result_mask = NULL; int pos = 0; *result_len = 0; result_val = calloc(len + 2, 1); if (!result_val) goto error; *result = result_val; if (mask) { result_mask = calloc(DIV_ROUND_UP(len, 8) + 2, 1); if (!result_mask) goto error; *mask = result_mask; } while (1) { char *cp = strchr(hexmask, ':'); if (cp) { *cp = 0; cp++; } if (result_mask && (strcmp(hexmask, "-") == 0 || strcmp(hexmask, "xx") == 0 || strcmp(hexmask, "--") == 0)) { /* skip this byte and leave mask bit unset */ } else { int temp, mask_pos; char *end; temp = strtoul(hexmask, &end, 16); if (*end) goto error; if (temp < 0 || temp > 255) goto error; result_val[pos] = temp; mask_pos = pos / 8; if (result_mask) result_mask[mask_pos] |= 1 << (pos % 8); } (*result_len)++; pos++; if (!cp) break; hexmask = cp; } return 0; error: free(result_val); free(result_mask); return -1; } unsigned char *parse_hex(char *hex, size_t *outlen) { unsigned char *result; if (parse_hex_mask(hex, &result, outlen, NULL)) return NULL; return result; } static const char *ifmodes[NL80211_IFTYPE_MAX + 1] = { "unspecified", "IBSS", "managed", "AP", "AP/VLAN", "WDS", "monitor", "mesh point", "P2P-client", "P2P-GO", "P2P-device", "outside context of a BSS", "NAN", }; static char modebuf[100]; const char *iftype_name(enum nl80211_iftype iftype) { if (iftype <= NL80211_IFTYPE_MAX && ifmodes[iftype]) return ifmodes[iftype]; sprintf(modebuf, "Unknown mode (%d)", iftype); return modebuf; } static const char *commands[NL80211_CMD_MAX + 1] = { /* * sed 's/^\tNL80211_CMD_//;t n;d;:n s%^\([^=]*\),.*%\t[NL80211_CMD_\1] = \"\L\1\",%;t;d' nl80211.h */ [NL80211_CMD_UNSPEC] = "unspec", [NL80211_CMD_GET_WIPHY] = "get_wiphy", [NL80211_CMD_SET_WIPHY] = "set_wiphy", [NL80211_CMD_NEW_WIPHY] = "new_wiphy", [NL80211_CMD_DEL_WIPHY] = "del_wiphy", [NL80211_CMD_GET_INTERFACE] = "get_interface", [NL80211_CMD_SET_INTERFACE] = "set_interface", [NL80211_CMD_NEW_INTERFACE] = "new_interface", [NL80211_CMD_DEL_INTERFACE] = "del_interface", [NL80211_CMD_GET_KEY] = "get_key", [NL80211_CMD_SET_KEY] = "set_key", [NL80211_CMD_NEW_KEY] = "new_key", [NL80211_CMD_DEL_KEY] = "del_key", [NL80211_CMD_GET_BEACON] = "get_beacon", [NL80211_CMD_SET_BEACON] = "set_beacon", [NL80211_CMD_START_AP] = "start_ap", [NL80211_CMD_STOP_AP] = "stop_ap", [NL80211_CMD_GET_STATION] = "get_station", [NL80211_CMD_SET_STATION] = "set_station", [NL80211_CMD_NEW_STATION] = "new_station", [NL80211_CMD_DEL_STATION] = "del_station", [NL80211_CMD_GET_MPATH] = "get_mpath", [NL80211_CMD_SET_MPATH] = "set_mpath", [NL80211_CMD_NEW_MPATH] = "new_mpath", [NL80211_CMD_DEL_MPATH] = "del_mpath", [NL80211_CMD_SET_BSS] = "set_bss", [NL80211_CMD_SET_REG] = "set_reg", [NL80211_CMD_REQ_SET_REG] = "req_set_reg", [NL80211_CMD_GET_MESH_CONFIG] = "get_mesh_config", [NL80211_CMD_SET_MESH_CONFIG] = "set_mesh_config", [NL80211_CMD_SET_MGMT_EXTRA_IE /* reserved; not used */] = "set_mgmt_extra_ie /* reserved; not used */", [NL80211_CMD_GET_REG] = "get_reg", [NL80211_CMD_GET_SCAN] = "get_scan", [NL80211_CMD_TRIGGER_SCAN] = "trigger_scan", [NL80211_CMD_NEW_SCAN_RESULTS] = "new_scan_results", [NL80211_CMD_SCAN_ABORTED] = "scan_aborted", [NL80211_CMD_REG_CHANGE] = "reg_change", [NL80211_CMD_AUTHENTICATE] = "authenticate", [NL80211_CMD_ASSOCIATE] = "associate", [NL80211_CMD_DEAUTHENTICATE] = "deauthenticate", [NL80211_CMD_DISASSOCIATE] = "disassociate", [NL80211_CMD_MICHAEL_MIC_FAILURE] = "michael_mic_failure", [NL80211_CMD_REG_BEACON_HINT] = "reg_beacon_hint", [NL80211_CMD_JOIN_IBSS] = "join_ibss", [NL80211_CMD_LEAVE_IBSS] = "leave_ibss", [NL80211_CMD_TESTMODE] = "testmode", [NL80211_CMD_CONNECT] = "connect", [NL80211_CMD_ROAM] = "roam", [NL80211_CMD_DISCONNECT] = "disconnect", [NL80211_CMD_SET_WIPHY_NETNS] = "set_wiphy_netns", [NL80211_CMD_GET_SURVEY] = "get_survey", [NL80211_CMD_NEW_SURVEY_RESULTS] = "new_survey_results", [NL80211_CMD_SET_PMKSA] = "set_pmksa", [NL80211_CMD_DEL_PMKSA] = "del_pmksa", [NL80211_CMD_FLUSH_PMKSA] = "flush_pmksa", [NL80211_CMD_REMAIN_ON_CHANNEL] = "remain_on_channel", [NL80211_CMD_CANCEL_REMAIN_ON_CHANNEL] = "cancel_remain_on_channel", [NL80211_CMD_SET_TX_BITRATE_MASK] = "set_tx_bitrate_mask", [NL80211_CMD_REGISTER_FRAME] = "register_frame", [NL80211_CMD_FRAME] = "frame", [NL80211_CMD_FRAME_TX_STATUS] = "frame_tx_status", [NL80211_CMD_SET_POWER_SAVE] = "set_power_save", [NL80211_CMD_GET_POWER_SAVE] = "get_power_save", [NL80211_CMD_SET_CQM] = "set_cqm", [NL80211_CMD_NOTIFY_CQM] = "notify_cqm", [NL80211_CMD_SET_CHANNEL] = "set_channel", [NL80211_CMD_SET_WDS_PEER] = "set_wds_peer", [NL80211_CMD_FRAME_WAIT_CANCEL] = "frame_wait_cancel", [NL80211_CMD_JOIN_MESH] = "join_mesh", [NL80211_CMD_LEAVE_MESH] = "leave_mesh", [NL80211_CMD_UNPROT_DEAUTHENTICATE] = "unprot_deauthenticate", [NL80211_CMD_UNPROT_DISASSOCIATE] = "unprot_disassociate", [NL80211_CMD_NEW_PEER_CANDIDATE] = "new_peer_candidate", [NL80211_CMD_GET_WOWLAN] = "get_wowlan", [NL80211_CMD_SET_WOWLAN] = "set_wowlan", [NL80211_CMD_START_SCHED_SCAN] = "start_sched_scan", [NL80211_CMD_STOP_SCHED_SCAN] = "stop_sched_scan", [NL80211_CMD_SCHED_SCAN_RESULTS] = "sched_scan_results", [NL80211_CMD_SCHED_SCAN_STOPPED] = "sched_scan_stopped", [NL80211_CMD_SET_REKEY_OFFLOAD] = "set_rekey_offload", [NL80211_CMD_PMKSA_CANDIDATE] = "pmksa_candidate", [NL80211_CMD_TDLS_OPER] = "tdls_oper", [NL80211_CMD_TDLS_MGMT] = "tdls_mgmt", [NL80211_CMD_UNEXPECTED_FRAME] = "unexpected_frame", [NL80211_CMD_PROBE_CLIENT] = "probe_client", [NL80211_CMD_REGISTER_BEACONS] = "register_beacons", [NL80211_CMD_UNEXPECTED_4ADDR_FRAME] = "unexpected_4addr_frame", [NL80211_CMD_SET_NOACK_MAP] = "set_noack_map", [NL80211_CMD_CH_SWITCH_NOTIFY] = "ch_switch_notify", [NL80211_CMD_START_P2P_DEVICE] = "start_p2p_device", [NL80211_CMD_STOP_P2P_DEVICE] = "stop_p2p_device", [NL80211_CMD_CONN_FAILED] = "conn_failed", [NL80211_CMD_SET_MCAST_RATE] = "set_mcast_rate", [NL80211_CMD_SET_MAC_ACL] = "set_mac_acl", [NL80211_CMD_RADAR_DETECT] = "radar_detect", [NL80211_CMD_GET_PROTOCOL_FEATURES] = "get_protocol_features", [NL80211_CMD_UPDATE_FT_IES] = "update_ft_ies", [NL80211_CMD_FT_EVENT] = "ft_event", [NL80211_CMD_CRIT_PROTOCOL_START] = "crit_protocol_start", [NL80211_CMD_CRIT_PROTOCOL_STOP] = "crit_protocol_stop", [NL80211_CMD_GET_COALESCE] = "get_coalesce", [NL80211_CMD_SET_COALESCE] = "set_coalesce", [NL80211_CMD_CHANNEL_SWITCH] = "channel_switch", [NL80211_CMD_VENDOR] = "vendor", [NL80211_CMD_SET_QOS_MAP] = "set_qos_map", [NL80211_CMD_ADD_TX_TS] = "add_tx_ts", [NL80211_CMD_DEL_TX_TS] = "del_tx_ts", [NL80211_CMD_GET_MPP] = "get_mpp", [NL80211_CMD_JOIN_OCB] = "join_ocb", [NL80211_CMD_LEAVE_OCB] = "leave_ocb", [NL80211_CMD_CH_SWITCH_STARTED_NOTIFY] = "ch_switch_started_notify", [NL80211_CMD_TDLS_CHANNEL_SWITCH] = "tdls_channel_switch", [NL80211_CMD_TDLS_CANCEL_CHANNEL_SWITCH] = "tdls_cancel_channel_switch", [NL80211_CMD_WIPHY_REG_CHANGE] = "wiphy_reg_change", [NL80211_CMD_ABORT_SCAN] = "abort_scan", [NL80211_CMD_START_NAN] = "start_nan", [NL80211_CMD_STOP_NAN] = "stop_nan", [NL80211_CMD_ADD_NAN_FUNCTION] = "add_nan_function", [NL80211_CMD_DEL_NAN_FUNCTION] = "del_nan_function", [NL80211_CMD_CHANGE_NAN_CONFIG] = "change_nan_config", [NL80211_CMD_NAN_MATCH] = "nan_match", [NL80211_CMD_SET_MULTICAST_TO_UNICAST] = "set_multicast_to_unicast", [NL80211_CMD_UPDATE_CONNECT_PARAMS] = "update_connect_params", [NL80211_CMD_SET_PMK] = "set_pmk", [NL80211_CMD_DEL_PMK] = "del_pmk", [NL80211_CMD_PORT_AUTHORIZED] = "port_authorized", [NL80211_CMD_RELOAD_REGDB] = "reload_regdb", [NL80211_CMD_EXTERNAL_AUTH] = "external_auth", [NL80211_CMD_STA_OPMODE_CHANGED] = "sta_opmode_changed", [NL80211_CMD_CONTROL_PORT_FRAME] = "control_port_frame", [NL80211_CMD_GET_FTM_RESPONDER_STATS] = "get_ftm_responder_stats", [NL80211_CMD_PEER_MEASUREMENT_START] = "peer_measurement_start", [NL80211_CMD_PEER_MEASUREMENT_RESULT] = "peer_measurement_result", [NL80211_CMD_PEER_MEASUREMENT_COMPLETE] = "peer_measurement_complete", [NL80211_CMD_NOTIFY_RADAR] = "notify_radar", [NL80211_CMD_UPDATE_OWE_INFO] = "update_owe_info", [NL80211_CMD_PROBE_MESH_LINK] = "probe_mesh_link", [NL80211_CMD_SET_TID_CONFIG] = "set_tid_config", [NL80211_CMD_UNPROT_BEACON] = "unprot_beacon", [NL80211_CMD_CONTROL_PORT_FRAME_TX_STATUS] = "control_port_frame_tx_status", [NL80211_CMD_SET_SAR_SPECS] = "set_sar_specs", [NL80211_CMD_OBSS_COLOR_COLLISION] = "obss_color_collision", [NL80211_CMD_COLOR_CHANGE_REQUEST] = "color_change_request", [NL80211_CMD_COLOR_CHANGE_STARTED] = "color_change_started", [NL80211_CMD_COLOR_CHANGE_ABORTED] = "color_change_aborted", [NL80211_CMD_COLOR_CHANGE_COMPLETED] = "color_change_completed", [NL80211_CMD_SET_FILS_AAD] = "set_fils_aad", [NL80211_CMD_ASSOC_COMEBACK] = "assoc_comeback", }; static char cmdbuf[100]; const char *command_name(enum nl80211_commands cmd) { if (cmd <= NL80211_CMD_MAX && commands[cmd]) return commands[cmd]; sprintf(cmdbuf, "Unknown command (%d)", cmd); return cmdbuf; } int ieee80211_channel_to_frequency(int chan, enum nl80211_band band) { /* see 802.11 17.3.8.3.2 and Annex J * there are overlapping channel numbers in 5GHz and 2GHz bands */ if (chan <= 0) return 0; /* not supported */ switch (band) { case NL80211_BAND_2GHZ: if (chan == 14) return 2484; else if (chan < 14) return 2407 + chan * 5; break; case NL80211_BAND_5GHZ: if (chan >= 182 && chan <= 196) return 4000 + chan * 5; else return 5000 + chan * 5; break; case NL80211_BAND_6GHZ: /* see 802.11ax D6.1 27.3.23.2 */ if (chan == 2) return 5935; if (chan <= 253) return 5950 + chan * 5; break; case NL80211_BAND_60GHZ: if (chan < 7) return 56160 + chan * 2160; break; default: ; } return 0; /* not supported */ } int ieee80211_frequency_to_channel(int freq) { /* see 802.11-2007 17.3.8.3.2 and Annex J */ if (freq == 2484) return 14; /* see 802.11ax D6.1 27.3.23.2 and Annex E */ else if (freq == 5935) return 2; else if (freq < 2484) return (freq - 2407) / 5; else if (freq >= 4910 && freq <= 4980) return (freq - 4000) / 5; else if (freq < 5950) return (freq - 5000) / 5; else if (freq <= 45000) /* DMG band lower limit */ /* see 802.11ax D6.1 27.3.23.2 */ return (freq - 5950) / 5; else if (freq >= 58320 && freq <= 70200) return (freq - 56160) / 2160; else return 0; } void print_ssid_escaped(const uint8_t len, const uint8_t *data) { int i; for (i = 0; i < len; i++) { if (isprint(data[i]) && data[i] != ' ' && data[i] != '\\') printf("%c", data[i]); else if (data[i] == ' ' && (i != 0 && i != len -1)) printf(" "); else printf("\\x%.2x", data[i]); } } static int hex2num(char digit) { if (!isxdigit(digit)) return -1; if (isdigit(digit)) return digit - '0'; return tolower(digit) - 'a' + 10; } static int hex2byte(const char *hex) { int d1, d2; d1 = hex2num(hex[0]); if (d1 < 0) return -1; d2 = hex2num(hex[1]); if (d2 < 0) return -1; return (d1 << 4) | d2; } char *hex2bin(const char *hex, char *buf) { char *result = buf; int d; while (hex[0]) { d = hex2byte(hex); if (d < 0) return NULL; buf[0] = d; buf++; hex += 2; } return result; } static int parse_akm_suite(const char *cipher_str) { if (!strcmp(cipher_str, "PSK")) return 0x000FAC02; if (!strcmp(cipher_str, "FT/PSK")) return 0x000FAC03; if (!strcmp(cipher_str, "PSK/SHA-256")) return 0x000FAC06; return -EINVAL; } static int parse_cipher_suite(const char *cipher_str) { if (!strcmp(cipher_str, "TKIP")) return WLAN_CIPHER_SUITE_TKIP; if (!strcmp(cipher_str, "CCMP") || !strcmp(cipher_str, "CCMP-128")) return WLAN_CIPHER_SUITE_CCMP; if (!strcmp(cipher_str, "GCMP") || !strcmp(cipher_str, "GCMP-128")) return WLAN_CIPHER_SUITE_GCMP; if (!strcmp(cipher_str, "GCMP-256")) return WLAN_CIPHER_SUITE_GCMP_256; if (!strcmp(cipher_str, "CCMP-256")) return WLAN_CIPHER_SUITE_CCMP_256; return -EINVAL; } int parse_keys(struct nl_msg *msg, char **argv[], int *argc) { struct nlattr *keys; int i = 0; bool have_default = false; char *arg = **argv; char keybuf[13]; int pos = 0; if (!*argc) return 1; if (!memcmp(&arg[pos], "psk", 3)) { char psk_keybuf[32]; int cipher_suite, akm_suite; if (*argc < 4) goto explain; pos+=3; if (arg[pos] != ':') goto explain; pos++; NLA_PUT_U32(msg, NL80211_ATTR_WPA_VERSIONS, NL80211_WPA_VERSION_2); if (strlen(&arg[pos]) != (sizeof(psk_keybuf) * 2) || !hex2bin(&arg[pos], psk_keybuf)) { printf("Bad PSK\n"); return -EINVAL; } NLA_PUT(msg, NL80211_ATTR_PMK, 32, psk_keybuf); NLA_PUT_U32(msg, NL80211_ATTR_AUTH_TYPE, NL80211_AUTHTYPE_OPEN_SYSTEM); *argv += 1; *argc -= 1; arg = **argv; akm_suite = parse_akm_suite(arg); if (akm_suite < 0) goto explain; NLA_PUT_U32(msg, NL80211_ATTR_AKM_SUITES, akm_suite); *argv += 1; *argc -= 1; arg = **argv; cipher_suite = parse_cipher_suite(arg); if (cipher_suite < 0) goto explain; NLA_PUT_U32(msg, NL80211_ATTR_CIPHER_SUITES_PAIRWISE, cipher_suite); *argv += 1; *argc -= 1; arg = **argv; cipher_suite = parse_cipher_suite(arg); if (cipher_suite < 0) goto explain; NLA_PUT_U32(msg, NL80211_ATTR_CIPHER_SUITE_GROUP, cipher_suite); *argv += 1; *argc -= 1; return 0; } NLA_PUT_FLAG(msg, NL80211_ATTR_PRIVACY); keys = nla_nest_start(msg, NL80211_ATTR_KEYS); if (!keys) return -ENOBUFS; do { int keylen; struct nlattr *key = nla_nest_start(msg, ++i); char *keydata; arg = **argv; pos = 0; if (!key) return -ENOBUFS; if (arg[pos] == 'd') { NLA_PUT_FLAG(msg, NL80211_KEY_DEFAULT); pos++; if (arg[pos] == ':') pos++; have_default = true; } if (!isdigit(arg[pos])) goto explain; NLA_PUT_U8(msg, NL80211_KEY_IDX, arg[pos++] - '0'); if (arg[pos++] != ':') goto explain; keydata = arg + pos; switch (strlen(keydata)) { case 10: keydata = hex2bin(keydata, keybuf); /* fall through */ case 5: NLA_PUT_U32(msg, NL80211_KEY_CIPHER, WLAN_CIPHER_SUITE_WEP40); keylen = 5; break; case 26: keydata = hex2bin(keydata, keybuf); /* fall through */ case 13: NLA_PUT_U32(msg, NL80211_KEY_CIPHER, WLAN_CIPHER_SUITE_WEP104); keylen = 13; break; default: goto explain; } if (!keydata) goto explain; NLA_PUT(msg, NL80211_KEY_DATA, keylen, keydata); *argv += 1; *argc -= 1; /* one key should be TX key */ if (!have_default && !*argc) NLA_PUT_FLAG(msg, NL80211_KEY_DEFAULT); nla_nest_end(msg, key); } while (*argc); nla_nest_end(msg, keys); return 0; nla_put_failure: return -ENOBUFS; explain: fprintf(stderr, "key must be [d:]index:data where\n" " 'd:' means default (transmit) key\n" " 'index:' is a single digit (0-3)\n" " 'data' must be 5 or 13 ascii chars\n" " or 10 or 26 hex digits\n" "for example: d:2:6162636465 is the same as d:2:abcde\n" "or psk:data where\n" " 'data' is the PSK (output of wpa_passphrase and the CIPHER can be CCMP or GCMP\n" "for example: psk:0123456789abcdef PSK CCMP CCMP\n" "The allowed AKM suites are PSK, FT/PSK, PSK/SHA-256\n" "The allowed Cipher suites are TKIP, CCMP, GCMP, GCMP-256, CCMP-256\n"); return 2; } enum nl80211_chan_width str_to_bw(const char *str) { static const struct { const char *name; unsigned int val; } bwmap[] = { { .name = "5", .val = NL80211_CHAN_WIDTH_5, }, { .name = "10", .val = NL80211_CHAN_WIDTH_10, }, { .name = "20", .val = NL80211_CHAN_WIDTH_20, }, { .name = "40", .val = NL80211_CHAN_WIDTH_40, }, { .name = "80", .val = NL80211_CHAN_WIDTH_80, }, { .name = "80+80", .val = NL80211_CHAN_WIDTH_80P80, }, { .name = "160", .val = NL80211_CHAN_WIDTH_160, }, }; unsigned int i; for (i = 0; i < ARRAY_SIZE(bwmap); i++) { if (strcasecmp(bwmap[i].name, str) == 0) return bwmap[i].val; } return NL80211_CHAN_WIDTH_20_NOHT; } static int parse_freqs(struct chandef *chandef, int argc, char **argv, int *parsed) { uint32_t freq; char *end; bool need_cf1 = false, need_cf2 = false; if (argc < 1) return 0; chandef->width = str_to_bw(argv[0]); switch (chandef->width) { case NL80211_CHAN_WIDTH_20_NOHT: /* First argument was not understood, give up gracefully. */ return 0; case NL80211_CHAN_WIDTH_20: case NL80211_CHAN_WIDTH_5: case NL80211_CHAN_WIDTH_10: break; case NL80211_CHAN_WIDTH_80P80: need_cf2 = true; /* fall through */ case NL80211_CHAN_WIDTH_40: case NL80211_CHAN_WIDTH_80: case NL80211_CHAN_WIDTH_160: case NL80211_CHAN_WIDTH_320: need_cf1 = true; break; case NL80211_CHAN_WIDTH_1: case NL80211_CHAN_WIDTH_2: case NL80211_CHAN_WIDTH_4: case NL80211_CHAN_WIDTH_8: case NL80211_CHAN_WIDTH_16: /* can't happen yet */ break; } *parsed += 1; if (!need_cf1) return 0; if (argc < 2) return 1; /* center freq 1 */ if (!*argv[1]) return 1; freq = strtoul(argv[1], &end, 10); if (*end) return 1; *parsed += 1; chandef->center_freq1 = freq; if (!need_cf2) return 0; if (argc < 3) return 1; /* center freq 2 */ if (!*argv[2]) return 1; freq = strtoul(argv[2], &end, 10); if (*end) return 1; chandef->center_freq2 = freq; *parsed += 1; return 0; } /** * parse_freqchan - Parse frequency or channel definition * * @chandef: chandef structure to be filled in * @chan: Boolean whether to parse a channel or frequency based specifier * @argc: Number of arguments * @argv: Array of string arguments * @parsed: Pointer to return the number of used arguments, or NULL to error * out if any argument is left unused. * * The given chandef structure will be filled in from the command line * arguments. argc/argv will be updated so that further arguments from the * command line can be parsed. * * Note that despite the fact that the function knows how many center freqs * are needed, there's an ambiguity if the next argument after this is an * integer argument, since the valid channel width values are interpreted * as such, rather than a following argument. This can be avoided by the * user by giving "NOHT" instead. * * The working specifier if chan is set are: * [NOHT|HT20|HT40+|HT40-|5MHz|10MHz|80MHz|160MHz] * * And if frequency is set: * [NOHT|HT20|HT40+|HT40-|5MHz|10MHz|80MHz|160MHz] * [5|10|20|40|80|80+80|160] [ []] * * If the mode/channel width is not given the NOHT is assumed. * * Return: Number of used arguments, zero or negative error number otherwise */ int parse_freqchan(struct chandef *chandef, bool chan, int argc, char **argv, int *parsed) { char *end; static const struct chanmode chanmode[] = { { .name = "HT20", .width = NL80211_CHAN_WIDTH_20, .freq1_diff = 0, .chantype = NL80211_CHAN_HT20 }, { .name = "HT40+", .width = NL80211_CHAN_WIDTH_40, .freq1_diff = 10, .chantype = NL80211_CHAN_HT40PLUS }, { .name = "HT40-", .width = NL80211_CHAN_WIDTH_40, .freq1_diff = -10, .chantype = NL80211_CHAN_HT40MINUS }, { .name = "NOHT", .width = NL80211_CHAN_WIDTH_20_NOHT, .freq1_diff = 0, .chantype = NL80211_CHAN_NO_HT }, { .name = "5MHz", .width = NL80211_CHAN_WIDTH_5, .freq1_diff = 0, .chantype = -1 }, { .name = "10MHz", .width = NL80211_CHAN_WIDTH_10, .freq1_diff = 0, .chantype = -1 }, { .name = "80MHz", .width = NL80211_CHAN_WIDTH_80, .freq1_diff = 0, .chantype = -1 }, { .name = "160MHz", .width = NL80211_CHAN_WIDTH_160, .freq1_diff = 0, .chantype = -1 }, { .name = "320MHz", .width = NL80211_CHAN_WIDTH_320, .freq1_diff = 0, .chantype = -1 }, }; const struct chanmode *chanmode_selected = NULL; unsigned int freq; unsigned int i; int _parsed = 0; int res = 0; if (argc < 1) return 1; if (!argv[0]) goto out; freq = strtoul(argv[0], &end, 10); if (*end) { res = 1; goto out; } _parsed += 1; memset(chandef, 0, sizeof(struct chandef)); if (chan) { enum nl80211_band band; band = freq <= 14 ? NL80211_BAND_2GHZ : NL80211_BAND_5GHZ; freq = ieee80211_channel_to_frequency(freq, band); } chandef->control_freq = freq; /* Assume 20MHz NOHT channel for now. */ chandef->center_freq1 = freq; /* Try to parse HT mode definitions */ if (argc > 1) { for (i = 0; i < ARRAY_SIZE(chanmode); i++) { if (strcasecmp(chanmode[i].name, argv[1]) == 0) { chanmode_selected = &chanmode[i]; _parsed += 1; break; } } } /* channel mode given, use it and return. */ if (chanmode_selected) { chandef->center_freq1 = get_cf1(chanmode_selected, freq); chandef->width = chanmode_selected->width; goto out; } /* This was a only a channel definition, nothing further may follow. */ if (chan) goto out; res = parse_freqs(chandef, argc - 1, argv + 1, &_parsed); out: /* Error out if parsed is NULL. */ if (!parsed && _parsed != argc) return 1; if (parsed) *parsed = _parsed; return res; } int put_chandef(struct nl_msg *msg, struct chandef *chandef) { NLA_PUT_U32(msg, NL80211_ATTR_WIPHY_FREQ, chandef->control_freq); NLA_PUT_U32(msg, NL80211_ATTR_CHANNEL_WIDTH, chandef->width); switch (chandef->width) { case NL80211_CHAN_WIDTH_20_NOHT: NLA_PUT_U32(msg, NL80211_ATTR_WIPHY_CHANNEL_TYPE, NL80211_CHAN_NO_HT); break; case NL80211_CHAN_WIDTH_20: NLA_PUT_U32(msg, NL80211_ATTR_WIPHY_CHANNEL_TYPE, NL80211_CHAN_HT20); break; case NL80211_CHAN_WIDTH_40: if (chandef->control_freq > chandef->center_freq1) NLA_PUT_U32(msg, NL80211_ATTR_WIPHY_CHANNEL_TYPE, NL80211_CHAN_HT40MINUS); else NLA_PUT_U32(msg, NL80211_ATTR_WIPHY_CHANNEL_TYPE, NL80211_CHAN_HT40PLUS); break; default: break; } if (chandef->center_freq1) NLA_PUT_U32(msg, NL80211_ATTR_CENTER_FREQ1, chandef->center_freq1); if (chandef->center_freq2) NLA_PUT_U32(msg, NL80211_ATTR_CENTER_FREQ2, chandef->center_freq2); return 0; nla_put_failure: return -ENOBUFS; } static void print_mcs_index(const __u8 *mcs) { int mcs_bit, prev_bit = -2, prev_cont = 0; for (mcs_bit = 0; mcs_bit <= 76; mcs_bit++) { unsigned int mcs_octet = mcs_bit/8; unsigned int MCS_RATE_BIT = 1 << mcs_bit % 8; bool mcs_rate_idx_set; mcs_rate_idx_set = !!(mcs[mcs_octet] & MCS_RATE_BIT); if (!mcs_rate_idx_set) continue; if (prev_bit != mcs_bit - 1) { if (prev_bit != -2) printf("%d, ", prev_bit); else printf(" "); printf("%d", mcs_bit); prev_cont = 0; } else if (!prev_cont) { printf("-"); prev_cont = 1; } prev_bit = mcs_bit; } if (prev_cont) printf("%d", prev_bit); printf("\n"); } /* * There are only 4 possible values, we just use a case instead of computing it, * but technically this can also be computed through the formula: * * Max AMPDU length = (2 ^ (13 + exponent)) - 1 bytes */ static __u32 compute_ampdu_length(__u8 exponent) { switch (exponent) { case 0: return 8191; /* (2 ^(13 + 0)) -1 */ case 1: return 16383; /* (2 ^(13 + 1)) -1 */ case 2: return 32767; /* (2 ^(13 + 2)) -1 */ case 3: return 65535; /* (2 ^(13 + 3)) -1 */ default: return 0; } } static const char *print_ampdu_space(__u8 space) { switch (space) { case 0: return "No restriction"; case 1: return "1/4 usec"; case 2: return "1/2 usec"; case 3: return "1 usec"; case 4: return "2 usec"; case 5: return "4 usec"; case 6: return "8 usec"; case 7: return "16 usec"; default: return "BUG (spacing more than 3 bits!)"; } } void print_ampdu_length(__u8 exponent) { __u32 max_ampdu_length; max_ampdu_length = compute_ampdu_length(exponent); if (max_ampdu_length) { printf("\t\tMaximum RX AMPDU length %d bytes (exponent: 0x0%02x)\n", max_ampdu_length, exponent); } else { printf("\t\tMaximum RX AMPDU length: unrecognized bytes " "(exponent: %d)\n", exponent); } } void print_ampdu_spacing(__u8 spacing) { printf("\t\tMinimum RX AMPDU time spacing: %s (0x%02x)\n", print_ampdu_space(spacing), spacing); } void print_ht_capability(__u16 cap) { #define PRINT_HT_CAP(_cond, _str) \ do { \ if (_cond) \ printf("\t\t\t" _str "\n"); \ } while (0) printf("\t\tCapabilities: 0x%02x\n", cap); PRINT_HT_CAP((cap & BIT(0)), "RX LDPC"); PRINT_HT_CAP((cap & BIT(1)), "HT20/HT40"); PRINT_HT_CAP(!(cap & BIT(1)), "HT20"); PRINT_HT_CAP(((cap >> 2) & 0x3) == 0, "Static SM Power Save"); PRINT_HT_CAP(((cap >> 2) & 0x3) == 1, "Dynamic SM Power Save"); PRINT_HT_CAP(((cap >> 2) & 0x3) == 3, "SM Power Save disabled"); PRINT_HT_CAP((cap & BIT(4)), "RX Greenfield"); PRINT_HT_CAP((cap & BIT(5)), "RX HT20 SGI"); PRINT_HT_CAP((cap & BIT(6)), "RX HT40 SGI"); PRINT_HT_CAP((cap & BIT(7)), "TX STBC"); PRINT_HT_CAP(((cap >> 8) & 0x3) == 0, "No RX STBC"); PRINT_HT_CAP(((cap >> 8) & 0x3) == 1, "RX STBC 1-stream"); PRINT_HT_CAP(((cap >> 8) & 0x3) == 2, "RX STBC 2-streams"); PRINT_HT_CAP(((cap >> 8) & 0x3) == 3, "RX STBC 3-streams"); PRINT_HT_CAP((cap & BIT(10)), "HT Delayed Block Ack"); PRINT_HT_CAP(!(cap & BIT(11)), "Max AMSDU length: 3839 bytes"); PRINT_HT_CAP((cap & BIT(11)), "Max AMSDU length: 7935 bytes"); /* * For beacons and probe response this would mean the BSS * does or does not allow the usage of DSSS/CCK HT40. * Otherwise it means the STA does or does not use * DSSS/CCK HT40. */ PRINT_HT_CAP((cap & BIT(12)), "DSSS/CCK HT40"); PRINT_HT_CAP(!(cap & BIT(12)), "No DSSS/CCK HT40"); /* BIT(13) is reserved */ PRINT_HT_CAP((cap & BIT(14)), "40 MHz Intolerant"); PRINT_HT_CAP((cap & BIT(15)), "L-SIG TXOP protection"); #undef PRINT_HT_CAP } void print_ht_mcs(const __u8 *mcs) { /* As defined in 7.3.2.57.4 Supported MCS Set field */ unsigned int tx_max_num_spatial_streams, max_rx_supp_data_rate; bool tx_mcs_set_defined, tx_mcs_set_equal, tx_unequal_modulation; max_rx_supp_data_rate = (mcs[10] | ((mcs[11] & 0x3) << 8)); tx_mcs_set_defined = !!(mcs[12] & (1 << 0)); tx_mcs_set_equal = !(mcs[12] & (1 << 1)); tx_max_num_spatial_streams = ((mcs[12] >> 2) & 3) + 1; tx_unequal_modulation = !!(mcs[12] & (1 << 4)); if (max_rx_supp_data_rate) printf("\t\tHT Max RX data rate: %d Mbps\n", max_rx_supp_data_rate); /* XXX: else see 9.6.0e.5.3 how to get this I think */ if (tx_mcs_set_defined) { if (tx_mcs_set_equal) { printf("\t\tHT TX/RX MCS rate indexes supported:"); print_mcs_index(mcs); } else { printf("\t\tHT RX MCS rate indexes supported:"); print_mcs_index(mcs); if (tx_unequal_modulation) printf("\t\tTX unequal modulation supported\n"); else printf("\t\tTX unequal modulation not supported\n"); printf("\t\tHT TX Max spatial streams: %d\n", tx_max_num_spatial_streams); printf("\t\tHT TX MCS rate indexes supported may differ\n"); } } else { printf("\t\tHT RX MCS rate indexes supported:"); print_mcs_index(mcs); printf("\t\tHT TX MCS rate indexes are undefined\n"); } } void print_vht_info(__u32 capa, const __u8 *mcs) { __u16 tmp; int i; printf("\t\tVHT Capabilities (0x%.8x):\n", capa); #define PRINT_VHT_CAPA(_bit, _str) \ do { \ if (capa & BIT(_bit)) \ printf("\t\t\t" _str "\n"); \ } while (0) printf("\t\t\tMax MPDU length: "); switch (capa & 3) { case 0: printf("3895\n"); break; case 1: printf("7991\n"); break; case 2: printf("11454\n"); break; case 3: printf("(reserved)\n"); } printf("\t\t\tSupported Channel Width: "); switch ((capa >> 2) & 3) { case 0: printf("neither 160 nor 80+80\n"); break; case 1: printf("160 MHz\n"); break; case 2: printf("160 MHz, 80+80 MHz\n"); break; case 3: printf("(reserved)\n"); } PRINT_VHT_CAPA(4, "RX LDPC"); PRINT_VHT_CAPA(5, "short GI (80 MHz)"); PRINT_VHT_CAPA(6, "short GI (160/80+80 MHz)"); PRINT_VHT_CAPA(7, "TX STBC"); /* RX STBC */ PRINT_VHT_CAPA(11, "SU Beamformer"); PRINT_VHT_CAPA(12, "SU Beamformee"); /* compressed steering */ /* # of sounding dimensions */ PRINT_VHT_CAPA(19, "MU Beamformer"); PRINT_VHT_CAPA(20, "MU Beamformee"); PRINT_VHT_CAPA(21, "VHT TXOP PS"); PRINT_VHT_CAPA(22, "+HTC-VHT"); /* max A-MPDU */ /* VHT link adaptation */ PRINT_VHT_CAPA(28, "RX antenna pattern consistency"); PRINT_VHT_CAPA(29, "TX antenna pattern consistency"); printf("\t\tVHT RX MCS set:\n"); tmp = mcs[0] | (mcs[1] << 8); for (i = 1; i <= 8; i++) { printf("\t\t\t%d streams: ", i); switch ((tmp >> ((i-1)*2) ) & 3) { case 0: printf("MCS 0-7\n"); break; case 1: printf("MCS 0-8\n"); break; case 2: printf("MCS 0-9\n"); break; case 3: printf("not supported\n"); break; } } tmp = mcs[2] | (mcs[3] << 8); printf("\t\tVHT RX highest supported: %d Mbps\n", tmp & 0x1fff); printf("\t\tVHT TX MCS set:\n"); tmp = mcs[4] | (mcs[5] << 8); for (i = 1; i <= 8; i++) { printf("\t\t\t%d streams: ", i); switch ((tmp >> ((i-1)*2) ) & 3) { case 0: printf("MCS 0-7\n"); break; case 1: printf("MCS 0-8\n"); break; case 2: printf("MCS 0-9\n"); break; case 3: printf("not supported\n"); break; } } tmp = mcs[6] | (mcs[7] << 8); printf("\t\tVHT TX highest supported: %d Mbps\n", tmp & 0x1fff); } static void __print_he_capa(const __u16 *mac_cap, const __u16 *phy_cap, const __u16 *mcs_set, size_t mcs_len, const __u8 *ppet, int ppet_len, bool indent) { size_t mcs_used; int i; const char *pre = indent ? "\t" : ""; #define PRINT_HE_CAP(_var, _idx, _bit, _str) \ do { \ if (_var[_idx] & BIT(_bit)) \ printf("%s\t\t\t" _str "\n", pre); \ } while (0) #define PRINT_HE_CAP_MASK(_var, _idx, _shift, _mask, _str) \ do { \ if ((_var[_idx] >> _shift) & _mask) \ printf("%s\t\t\t" _str ": %d\n", pre, (_var[_idx] >> _shift) & _mask); \ } while (0) #define PRINT_HE_MAC_CAP(...) PRINT_HE_CAP(mac_cap, __VA_ARGS__) #define PRINT_HE_MAC_CAP_MASK(...) PRINT_HE_CAP_MASK(mac_cap, __VA_ARGS__) #define PRINT_HE_PHY_CAP(...) PRINT_HE_CAP(phy_cap, __VA_ARGS__) #define PRINT_HE_PHY_CAP0(_idx, _bit, ...) PRINT_HE_CAP(phy_cap, _idx, _bit + 8, __VA_ARGS__) #define PRINT_HE_PHY_CAP_MASK(...) PRINT_HE_CAP_MASK(phy_cap, __VA_ARGS__) printf("%s\t\tHE MAC Capabilities (0x", pre); for (i = 0; i < 3; i++) printf("%04x", mac_cap[i]); printf("):\n"); PRINT_HE_MAC_CAP(0, 0, "+HTC HE Supported"); PRINT_HE_MAC_CAP(0, 1, "TWT Requester"); PRINT_HE_MAC_CAP(0, 2, "TWT Responder"); PRINT_HE_MAC_CAP_MASK(0, 3, 0x3, "Dynamic BA Fragementation Level"); PRINT_HE_MAC_CAP_MASK(0, 5, 0x7, "Maximum number of MSDUS Fragments"); PRINT_HE_MAC_CAP_MASK(0, 8, 0x3, "Minimum Payload size of 128 bytes"); PRINT_HE_MAC_CAP_MASK(0, 10, 0x3, "Trigger Frame MAC Padding Duration"); PRINT_HE_MAC_CAP_MASK(0, 12, 0x7, "Multi-TID Aggregation Support"); PRINT_HE_MAC_CAP(1, 1, "All Ack"); PRINT_HE_MAC_CAP(1, 2, "TRS"); PRINT_HE_MAC_CAP(1, 3, "BSR"); PRINT_HE_MAC_CAP(1, 4, "Broadcast TWT"); PRINT_HE_MAC_CAP(1, 5, "32-bit BA Bitmap"); PRINT_HE_MAC_CAP(1, 6, "MU Cascading"); PRINT_HE_MAC_CAP(1, 7, "Ack-Enabled Aggregation"); PRINT_HE_MAC_CAP(1, 9, "OM Control"); PRINT_HE_MAC_CAP(1, 10, "OFDMA RA"); PRINT_HE_MAC_CAP_MASK(1, 11, 0x3, "Maximum A-MPDU Length Exponent"); PRINT_HE_MAC_CAP(1, 13, "A-MSDU Fragmentation"); PRINT_HE_MAC_CAP(1, 14, "Flexible TWT Scheduling"); PRINT_HE_MAC_CAP(1, 15, "RX Control Frame to MultiBSS"); PRINT_HE_MAC_CAP(2, 0, "BSRP BQRP A-MPDU Aggregation"); PRINT_HE_MAC_CAP(2, 1, "QTP"); PRINT_HE_MAC_CAP(2, 2, "BQR"); PRINT_HE_MAC_CAP(2, 3, "SRP Responder Role"); PRINT_HE_MAC_CAP(2, 4, "NDP Feedback Report"); PRINT_HE_MAC_CAP(2, 5, "OPS"); PRINT_HE_MAC_CAP(2, 6, "A-MSDU in A-MPDU"); PRINT_HE_MAC_CAP_MASK(2, 7, 7, "Multi-TID Aggregation TX"); PRINT_HE_MAC_CAP(2, 10, "HE Subchannel Selective Transmission"); PRINT_HE_MAC_CAP(2, 11, "UL 2x996-Tone RU"); PRINT_HE_MAC_CAP(2, 12, "OM Control UL MU Data Disable RX"); printf("%s\t\tHE PHY Capabilities: (0x", pre); for (i = 0; i < 11; i++) printf("%02x", ((__u8 *)phy_cap)[i + 1]); printf("):\n"); PRINT_HE_PHY_CAP0(0, 1, "HE40/2.4GHz"); PRINT_HE_PHY_CAP0(0, 2, "HE40/HE80/5GHz"); PRINT_HE_PHY_CAP0(0, 3, "HE160/5GHz"); PRINT_HE_PHY_CAP0(0, 4, "HE160/HE80+80/5GHz"); PRINT_HE_PHY_CAP0(0, 5, "242 tone RUs/2.4GHz"); PRINT_HE_PHY_CAP0(0, 6, "242 tone RUs/5GHz"); PRINT_HE_PHY_CAP_MASK(1, 0, 0xf, "Punctured Preamble RX"); PRINT_HE_PHY_CAP_MASK(1, 4, 0x1, "Device Class"); PRINT_HE_PHY_CAP(1, 5, "LDPC Coding in Payload"); PRINT_HE_PHY_CAP(1, 6, "HE SU PPDU with 1x HE-LTF and 0.8us GI"); PRINT_HE_PHY_CAP_MASK(1, 7, 0x3, "Midamble Rx Max NSTS"); PRINT_HE_PHY_CAP(1, 9, "NDP with 4x HE-LTF and 3.2us GI"); PRINT_HE_PHY_CAP(1, 10, "STBC Tx <= 80MHz"); PRINT_HE_PHY_CAP(1, 11, "STBC Rx <= 80MHz"); PRINT_HE_PHY_CAP(1, 12, "Doppler Tx"); PRINT_HE_PHY_CAP(1, 13, "Doppler Rx"); PRINT_HE_PHY_CAP(1, 14, "Full Bandwidth UL MU-MIMO"); PRINT_HE_PHY_CAP(1, 15, "Partial Bandwidth UL MU-MIMO"); PRINT_HE_PHY_CAP_MASK(2, 0, 0x3, "DCM Max Constellation"); PRINT_HE_PHY_CAP_MASK(2, 2, 0x1, "DCM Max NSS Tx"); PRINT_HE_PHY_CAP_MASK(2, 3, 0x3, "DCM Max Constellation Rx"); PRINT_HE_PHY_CAP_MASK(2, 5, 0x1, "DCM Max NSS Rx"); PRINT_HE_PHY_CAP(2, 6, "Rx HE MU PPDU from Non-AP STA"); PRINT_HE_PHY_CAP(2, 7, "SU Beamformer"); PRINT_HE_PHY_CAP(2, 8, "SU Beamformee"); PRINT_HE_PHY_CAP(2, 9, "MU Beamformer"); PRINT_HE_PHY_CAP_MASK(2, 10, 0x7, "Beamformee STS <= 80Mhz"); PRINT_HE_PHY_CAP_MASK(2, 13, 0x7, "Beamformee STS > 80Mhz"); PRINT_HE_PHY_CAP_MASK(3, 0, 0x7, "Sounding Dimensions <= 80Mhz"); PRINT_HE_PHY_CAP_MASK(3, 3, 0x7, "Sounding Dimensions > 80Mhz"); PRINT_HE_PHY_CAP(3, 6, "Ng = 16 SU Feedback"); PRINT_HE_PHY_CAP(3, 7, "Ng = 16 MU Feedback"); PRINT_HE_PHY_CAP(3, 8, "Codebook Size SU Feedback"); PRINT_HE_PHY_CAP(3, 9, "Codebook Size MU Feedback"); PRINT_HE_PHY_CAP(3, 10, "Triggered SU Beamforming Feedback"); PRINT_HE_PHY_CAP(3, 11, "Triggered MU Beamforming Feedback"); PRINT_HE_PHY_CAP(3, 12, "Triggered CQI Feedback"); PRINT_HE_PHY_CAP(3, 13, "Partial Bandwidth Extended Range"); PRINT_HE_PHY_CAP(3, 14, "Partial Bandwidth DL MU-MIMO"); PRINT_HE_PHY_CAP(3, 15, "PPE Threshold Present"); PRINT_HE_PHY_CAP(4, 0, "SRP-based SR"); PRINT_HE_PHY_CAP(4, 1, "Power Boost Factor ar"); PRINT_HE_PHY_CAP(4, 2, "HE SU PPDU & HE PPDU 4x HE-LTF 0.8us GI"); PRINT_HE_PHY_CAP_MASK(4, 3, 0x7, "Max NC"); PRINT_HE_PHY_CAP(4, 6, "STBC Tx > 80MHz"); PRINT_HE_PHY_CAP(4, 7, "STBC Rx > 80MHz"); PRINT_HE_PHY_CAP(4, 8, "HE ER SU PPDU 4x HE-LTF 0.8us GI"); PRINT_HE_PHY_CAP(4, 9, "20MHz in 40MHz HE PPDU 2.4GHz"); PRINT_HE_PHY_CAP(4, 10, "20MHz in 160/80+80MHz HE PPDU"); PRINT_HE_PHY_CAP(4, 11, "80MHz in 160/80+80MHz HE PPDU"); PRINT_HE_PHY_CAP(4, 12, "HE ER SU PPDU 1x HE-LTF 0.8us GI"); PRINT_HE_PHY_CAP(4, 13, "Midamble Rx 2x & 1x HE-LTF"); PRINT_HE_PHY_CAP_MASK(4, 14, 0x3, "DCM Max BW"); PRINT_HE_PHY_CAP(5, 0, "Longer Than 16HE SIG-B OFDM Symbols"); PRINT_HE_PHY_CAP(5, 1, "Non-Triggered CQI Feedback"); PRINT_HE_PHY_CAP(5, 2, "TX 1024-QAM"); PRINT_HE_PHY_CAP(5, 3, "RX 1024-QAM"); PRINT_HE_PHY_CAP(5, 4, "RX Full BW SU Using HE MU PPDU with Compression SIGB"); PRINT_HE_PHY_CAP(5, 5, "RX Full BW SU Using HE MU PPDU with Non-Compression SIGB"); mcs_used = 0; for (i = 0; i < 3; i++) { __u8 phy_cap_support[] = { BIT(1) | BIT(2), BIT(3), BIT(4) }; char *bw[] = { "<= 80", "160", "80+80" }; int j; if ((phy_cap[0] & (phy_cap_support[i] << 8)) == 0) continue; /* Supports more, but overflow? Abort. */ if ((i * 2 + 2) * sizeof(mcs_set[0]) >= mcs_len) return; for (j = 0; j < 2; j++) { int k; printf("%s\t\tHE %s MCS and NSS set %s MHz\n", pre, j ? "TX" : "RX", bw[i]); for (k = 0; k < 8; k++) { __u16 mcs = mcs_set[(i * 2) + j]; mcs >>= k * 2; mcs &= 0x3; printf("%s\t\t\t%d streams: ", pre, k + 1); if (mcs == 3) printf("not supported\n"); else printf("MCS 0-%d\n", 7 + (mcs * 2)); } } mcs_used += 2 * sizeof(mcs_set[0]); } /* Caller didn't provide ppet; infer it, if there's trailing space. */ if (!ppet) { ppet = (const void *)((const __u8 *)mcs_set + mcs_used); if (mcs_used < mcs_len) ppet_len = mcs_len - mcs_used; else ppet_len = 0; } if (ppet_len && (phy_cap[3] & BIT(15))) { printf("%s\t\tPPE Threshold ", pre); for (i = 0; i < ppet_len; i++) if (ppet[i]) printf("0x%02x ", ppet[i]); printf("\n"); } } void print_iftype_list(const char *name, const char *pfx, struct nlattr *attr) { struct nlattr *ift; int rem; printf("%s:\n", name); nla_for_each_nested(ift, attr, rem) printf("%s * %s\n", pfx, iftype_name(nla_type(ift))); } void print_iftype_line(struct nlattr *attr) { struct nlattr *ift; bool first = true; int rem; nla_for_each_nested(ift, attr, rem) { if (first) first = false; else printf(", "); printf("%s", iftype_name(nla_type(ift))); } } void print_he_info(struct nlattr *nl_iftype) { struct nlattr *tb[NL80211_BAND_IFTYPE_ATTR_MAX + 1]; __u16 mac_cap[3] = { 0 }; __u16 phy_cap[6] = { 0 }; __u16 mcs_set[6] = { 0 }; __u8 ppet[25] = { 0 }; size_t len; int mcs_len = 0, ppet_len = 0; nla_parse(tb, NL80211_BAND_IFTYPE_ATTR_MAX, nla_data(nl_iftype), nla_len(nl_iftype), NULL); if (!tb[NL80211_BAND_IFTYPE_ATTR_IFTYPES]) return; printf("\t\tHE Iftypes: "); print_iftype_line(tb[NL80211_BAND_IFTYPE_ATTR_IFTYPES]); printf("\n"); if (tb[NL80211_BAND_IFTYPE_ATTR_HE_CAP_MAC]) { len = nla_len(tb[NL80211_BAND_IFTYPE_ATTR_HE_CAP_MAC]); if (len > sizeof(mac_cap)) len = sizeof(mac_cap); memcpy(mac_cap, nla_data(tb[NL80211_BAND_IFTYPE_ATTR_HE_CAP_MAC]), len); } if (tb[NL80211_BAND_IFTYPE_ATTR_HE_CAP_PHY]) { len = nla_len(tb[NL80211_BAND_IFTYPE_ATTR_HE_CAP_PHY]); if (len > sizeof(phy_cap) - 1) len = sizeof(phy_cap) - 1; memcpy(&((__u8 *)phy_cap)[1], nla_data(tb[NL80211_BAND_IFTYPE_ATTR_HE_CAP_PHY]), len); } if (tb[NL80211_BAND_IFTYPE_ATTR_HE_CAP_MCS_SET]) { len = nla_len(tb[NL80211_BAND_IFTYPE_ATTR_HE_CAP_MCS_SET]); if (len > sizeof(mcs_set)) len = sizeof(mcs_set); memcpy(mcs_set, nla_data(tb[NL80211_BAND_IFTYPE_ATTR_HE_CAP_MCS_SET]), len); mcs_len = len; } if (tb[NL80211_BAND_IFTYPE_ATTR_HE_CAP_PPE]) { len = nla_len(tb[NL80211_BAND_IFTYPE_ATTR_HE_CAP_PPE]); if (len > sizeof(ppet)) len = sizeof(ppet); memcpy(ppet, nla_data(tb[NL80211_BAND_IFTYPE_ATTR_HE_CAP_PPE]), len); ppet_len = len; } __print_he_capa(mac_cap, phy_cap, mcs_set, mcs_len, ppet, ppet_len, true); } static void __print_eht_capa(int band, const __u8 *mac_cap, const __u32 *phy_cap, const __u8 *mcs_set, size_t mcs_len, const __u8 *ppet, size_t ppet_len, const __u16 *he_phy_cap, bool indent) { unsigned int i; const char *pre = indent ? "\t" : ""; const char *mcs[] = { "0-7", "8-9", "10-11", "12-13"}; #define PRINT_EHT_CAP(_var, _idx, _bit, _str) \ do { \ if (_var[_idx] & BIT(_bit)) \ printf("%s\t\t\t" _str "\n", pre); \ } while (0) #define PRINT_EHT_CAP_MASK(_var, _idx, _shift, _mask, _str) \ do { \ if ((_var[_idx] >> _shift) & _mask) \ printf("%s\t\t\t" _str ": %d\n", pre, (_var[_idx] >> _shift) & _mask); \ } while (0) #define PRINT_EHT_MAC_CAP(...) PRINT_EHT_CAP(mac_cap, __VA_ARGS__) #define PRINT_EHT_PHY_CAP(...) PRINT_EHT_CAP(phy_cap, __VA_ARGS__) #define PRINT_EHT_PHY_CAP_MASK(...) PRINT_EHT_CAP_MASK(phy_cap, __VA_ARGS__) printf("%s\t\tEHT MAC Capabilities (0x", pre); for (i = 0; i < 2; i++) printf("%02x", mac_cap[i]); printf("):\n"); PRINT_EHT_MAC_CAP(0, 0, "NSEP priority access Supported"); PRINT_EHT_MAC_CAP(0, 1, "EHT OM Control Supported"); PRINT_EHT_MAC_CAP(0, 2, "Triggered TXOP Sharing Supported"); PRINT_EHT_MAC_CAP(0, 3, "ARR Supported"); printf("%s\t\tEHT PHY Capabilities: (0x", pre); for (i = 0; i < 8; i++) printf("%02x", ((__u8 *)phy_cap)[i]); printf("):\n"); PRINT_EHT_PHY_CAP(0, 1, "320MHz in 6GHz Supported"); PRINT_EHT_PHY_CAP(0, 2, "242-tone RU in BW wider than 20MHz Supported"); PRINT_EHT_PHY_CAP(0, 3, "NDP With EHT-LTF And 3.2 µs GI"); PRINT_EHT_PHY_CAP(0, 4, "Partial Bandwidth UL MU-MIMO"); PRINT_EHT_PHY_CAP(0, 5, "SU Beamformer"); PRINT_EHT_PHY_CAP(0, 6, "SU Beamformee"); PRINT_EHT_PHY_CAP_MASK(0, 7, 0x7, "Beamformee SS (80MHz)"); PRINT_EHT_PHY_CAP_MASK(0, 10, 0x7, "Beamformee SS (160MHz)"); PRINT_EHT_PHY_CAP_MASK(0, 13, 0x7, "Beamformee SS (320MHz)"); PRINT_EHT_PHY_CAP_MASK(0, 16, 0x7, "Number Of Sounding Dimensions (80MHz)"); PRINT_EHT_PHY_CAP_MASK(0, 19, 0x7, "Number Of Sounding Dimensions (160MHz)"); PRINT_EHT_PHY_CAP_MASK(0, 22, 0x7, "Number Of Sounding Dimensions (320MHz)"); PRINT_EHT_PHY_CAP(0, 25, "Ng = 16 SU Feedback"); PRINT_EHT_PHY_CAP(0, 26, "Ng = 16 MU Feedback"); PRINT_EHT_PHY_CAP(0, 27, "Codebook size (4, 2) SU Feedback"); PRINT_EHT_PHY_CAP(0, 28, "Codebook size (7, 5) MU Feedback"); PRINT_EHT_PHY_CAP(0, 29, "Triggered SU Beamforming Feedback"); PRINT_EHT_PHY_CAP(0, 30, "Triggered MU Beamforming Partial BW Feedback"); PRINT_EHT_PHY_CAP(0, 31, "Triggered CQI Feedback"); PRINT_EHT_PHY_CAP(1, 0, "Partial Bandwidth DL MU-MIMO"); PRINT_EHT_PHY_CAP(1, 1, "PSR-Based SR Support"); PRINT_EHT_PHY_CAP(1, 2, "Power Boost Factor Support"); PRINT_EHT_PHY_CAP(1, 3, "EHT MU PPDU With 4 EHT-LTF And 0.8 µs GI"); PRINT_EHT_PHY_CAP_MASK(1, 4, 0xf, "Max Nc"); PRINT_EHT_PHY_CAP(1, 8, "Non-Triggered CQI Feedback"); PRINT_EHT_PHY_CAP(1, 9, "Tx 1024-QAM And 4096-QAM < 242-tone RU"); PRINT_EHT_PHY_CAP(1, 10, "Rx 1024-QAM And 4096-QAM < 242-tone RU"); PRINT_EHT_PHY_CAP(1, 11, "PPE Thresholds Present"); PRINT_EHT_PHY_CAP_MASK(1, 12, 0x3, "Common Nominal Packet Padding"); PRINT_EHT_PHY_CAP_MASK(1, 14, 0x1f, "Maximum Number Of Supported EHT-LTFs"); PRINT_EHT_PHY_CAP_MASK(1, 19, 0xf, "Support of MCS 15"); PRINT_EHT_PHY_CAP(1, 23, "Support Of EHT DUP In 6 GHz"); PRINT_EHT_PHY_CAP(1, 24, "Support For 20MHz Rx NDP With Wider Bandwidth"); PRINT_EHT_PHY_CAP(1, 25, "Non-OFDMA UL MU-MIMO (80MHz)"); PRINT_EHT_PHY_CAP(1, 26, "Non-OFDMA UL MU-MIMO (160MHz)"); PRINT_EHT_PHY_CAP(1, 27, "Non-OFDMA UL MU-MIMO (320MHz)"); PRINT_EHT_PHY_CAP(1, 28, "MU Beamformer (80MHz)"); PRINT_EHT_PHY_CAP(1, 29, "MU Beamformer (160MHz)"); PRINT_EHT_PHY_CAP(1, 30, "MU Beamformer (320MHz)"); printf("%s\t\tEHT MCS/NSS: (0x", pre); for (i = 0; i < mcs_len; i++) printf("%02x", ((__u8 *)mcs_set)[i]); printf("):\n"); if (!(he_phy_cap[0] & ((BIT(2) | BIT(3) | BIT(4)) << 8))){ for (i = 0; i < 4; i++) printf("%s\t\tEHT bw=20 MHz, max NSS for MCS %s: Rx=%u, Tx=%u\n", pre, mcs[i], mcs_set[i] & 0xf, mcs_set[i] >> 4); } mcs_set += 4; if (he_phy_cap[0] & (BIT(2) << 8)) { for (i = 0; i < 3; i++) printf("%s\t\tEHT bw <= 80 MHz, max NSS for MCS %s: Rx=%u, Tx=%u\n", pre, mcs[i + 1], mcs_set[i] & 0xf, mcs_set[i] >> 4); } mcs_set += 3; if (he_phy_cap[0] & (BIT(3) << 8)) { for (i = 0; i < 3; i++) printf("%s\t\tEHT bw=160 MHz, max NSS for MCS %s: Rx=%u, Tx=%u\n", pre, mcs[i + 1], mcs_set[i] & 0xf, mcs_set[i] >> 4); } mcs_set += 3; if (band == NL80211_BAND_6GHZ && (phy_cap[0] & BIT(1))) { for (i = 0; i < 3; i++) printf("%s\t\tEHT bw=320 MHz, max NSS for MCS %s: Rx=%u, Tx=%u\n", pre, mcs[i + 1], mcs_set[i] & 0xf, mcs_set[i] >> 4); } if (ppet && ppet_len && (phy_cap[1] & BIT(11))) { printf("%s\t\tEHT PPE Thresholds ", pre); for (i = 0; i < ppet_len; i++) if (ppet[i]) printf("0x%02x ", ppet[i]); printf("\n"); } } void print_eht_info(struct nlattr *nl_iftype, int band) { struct nlattr *tb[NL80211_BAND_IFTYPE_ATTR_MAX + 1]; __u8 mac_cap[2] = { 0 }; __u32 phy_cap[2] = { 0 }; __u8 mcs_set[13] = { 0 }; __u8 ppet[31] = { 0 }; __u16 he_phy_cap[6] = { 0 }; size_t len, mcs_len = 0, ppet_len = 0; nla_parse(tb, NL80211_BAND_IFTYPE_ATTR_MAX, nla_data(nl_iftype), nla_len(nl_iftype), NULL); if (!tb[NL80211_BAND_IFTYPE_ATTR_IFTYPES]) return; printf("\t\tEHT Iftypes: "); print_iftype_line(tb[NL80211_BAND_IFTYPE_ATTR_IFTYPES]); printf("\n"); if (tb[NL80211_BAND_IFTYPE_ATTR_EHT_CAP_MAC]) { len = nla_len(tb[NL80211_BAND_IFTYPE_ATTR_EHT_CAP_MAC]); if (len > sizeof(mac_cap)) len = sizeof(mac_cap); memcpy(mac_cap, nla_data(tb[NL80211_BAND_IFTYPE_ATTR_EHT_CAP_MAC]), len); } if (tb[NL80211_BAND_IFTYPE_ATTR_EHT_CAP_PHY]) { len = nla_len(tb[NL80211_BAND_IFTYPE_ATTR_EHT_CAP_PHY]); if (len > sizeof(phy_cap)) len = sizeof(phy_cap); memcpy(phy_cap, nla_data(tb[NL80211_BAND_IFTYPE_ATTR_EHT_CAP_PHY]), len); } if (tb[NL80211_BAND_IFTYPE_ATTR_EHT_CAP_MCS_SET]) { len = nla_len(tb[NL80211_BAND_IFTYPE_ATTR_EHT_CAP_MCS_SET]); if (len > sizeof(mcs_set)) len = sizeof(mcs_set); memcpy(mcs_set, nla_data(tb[NL80211_BAND_IFTYPE_ATTR_EHT_CAP_MCS_SET]), len); // Assume that all parts of the MCS set are present mcs_len = sizeof(mcs_set); } if (tb[NL80211_BAND_IFTYPE_ATTR_EHT_CAP_PPE]) { len = nla_len(tb[NL80211_BAND_IFTYPE_ATTR_EHT_CAP_PPE]); if (len > sizeof(ppet)) len = sizeof(ppet); memcpy(ppet, nla_data(tb[NL80211_BAND_IFTYPE_ATTR_EHT_CAP_PPE]), len); ppet_len = len; } if (tb[NL80211_BAND_IFTYPE_ATTR_HE_CAP_PHY]) { len = nla_len(tb[NL80211_BAND_IFTYPE_ATTR_HE_CAP_PHY]); if (len > sizeof(he_phy_cap) - 1) len = sizeof(he_phy_cap) - 1; memcpy(&((__u8 *)he_phy_cap)[1], nla_data(tb[NL80211_BAND_IFTYPE_ATTR_HE_CAP_PHY]), len); } __print_eht_capa(band, mac_cap, phy_cap, mcs_set, mcs_len, ppet, ppet_len, he_phy_cap, true); } void print_he_capability(const uint8_t *ie, int len) { const void *mac_cap, *phy_cap, *mcs_set; int mcs_len; int i = 0; mac_cap = &ie[i]; i += 6; phy_cap = &ie[i]; i += 11; mcs_set = &ie[i]; mcs_len = len - i; __print_he_capa(mac_cap, (const void *)((const __u8 *)phy_cap - 1), mcs_set, mcs_len, NULL, 0, false); } void iw_hexdump(const char *prefix, const __u8 *buf, size_t size) { size_t i; printf("%s: ", prefix); for (i = 0; i < size; i++) { if (i && i % 16 == 0) printf("\n%s: ", prefix); printf("%02x ", buf[i]); } printf("\n\n"); } int get_cf1(const struct chanmode *chanmode, unsigned long freq) { unsigned int cf1 = freq, j; unsigned int bw80[] = { 5180, 5260, 5500, 5580, 5660, 5745, 5955, 6035, 6115, 6195, 6275, 6355, 6435, 6515, 6595, 6675, 6755, 6835, 6195, 6995 }; unsigned int bw160[] = { 5180, 5500, 5955, 6115, 6275, 6435, 6595, 6755, 6915 }; switch (chanmode->width) { case NL80211_CHAN_WIDTH_80: /* setup center_freq1 */ for (j = 0; j < ARRAY_SIZE(bw80); j++) { if (freq >= bw80[j] && freq < bw80[j] + 80) break; } if (j == ARRAY_SIZE(bw80)) break; cf1 = bw80[j] + 30; break; case NL80211_CHAN_WIDTH_160: /* setup center_freq1 */ for (j = 0; j < ARRAY_SIZE(bw160); j++) { if (freq >= bw160[j] && freq < bw160[j] + 160) break; } if (j == ARRAY_SIZE(bw160)) break; cf1 = bw160[j] + 70; break; default: cf1 = freq + chanmode->freq1_diff; break; } return cf1; } int parse_random_mac_addr(struct nl_msg *msg, char *addrs) { char *a_addr, *a_mask, *sep; unsigned char addr[ETH_ALEN], mask[ETH_ALEN]; if (!*addrs) { /* randomise all but the multicast bit */ NLA_PUT(msg, NL80211_ATTR_MAC, ETH_ALEN, "\x00\x00\x00\x00\x00\x00"); NLA_PUT(msg, NL80211_ATTR_MAC_MASK, ETH_ALEN, "\x01\x00\x00\x00\x00\x00"); return 0; } if (*addrs != '=') return 1; addrs++; sep = strchr(addrs, '/'); a_addr = addrs; if (!sep) return 1; *sep = 0; a_mask = sep + 1; if (mac_addr_a2n(addr, a_addr) || mac_addr_a2n(mask, a_mask)) return 1; NLA_PUT(msg, NL80211_ATTR_MAC, ETH_ALEN, addr); NLA_PUT(msg, NL80211_ATTR_MAC_MASK, ETH_ALEN, mask); return 0; nla_put_failure: return -ENOBUFS; }