/* * Copyright (C) 2017 Freie Universität Berlin * * This file is subject to the terms and conditions of the GNU Lesser * General Public License v2.1. See the file LICENSE in the top level * directory for more details. */ /** * @ingroup sys_shell_commands * @{ * * @file * @brief Shell commands for interacting with network interfaces * * @author Martine Lenders * @author Hauke Petersen * @author Oliver Hahm */ #include #include "net/ipv6/addr.h" #include "net/gnrc.h" #include "net/gnrc/netif2.h" #include "net/gnrc/netif/hdr.h" #ifdef MODULE_NETSTATS #include "net/netstats.h" #endif #ifdef MODULE_L2FILTER #include "net/l2filter.h" #endif /** * @brief The default IPv6 prefix length if not specified. */ #define _IPV6_DEFAULT_PREFIX_LEN (64U) /** * @brief Threshold for listed option flags */ #define _LINE_THRESHOLD (8U) /** * @brief Determine length of array in elements */ #define _ARRAY_LEN(x) (sizeof(x) / sizeof(x[0])) /** * @brief Flag command mapping * * @note Add options that are changed with netopt_enable_t here */ static const struct { char *name; netopt_t opt; } flag_cmds[] = { { "ack_req", NETOPT_ACK_REQ }, { "autoack", NETOPT_AUTOACK }, { "autocca", NETOPT_AUTOCCA }, { "csma", NETOPT_CSMA }, { "encrypt", NETOPT_ENCRYPTION }, { "mac_no_sleep", NETOPT_MAC_NO_SLEEP }, { "fwd", NETOPT_IPV6_FORWARDING }, { "iphc", NETOPT_6LO_IPHC }, { "preload", NETOPT_PRELOADING }, { "promisc", NETOPT_PROMISCUOUSMODE }, { "raw", NETOPT_RAWMODE }, { "rtr_adv", NETOPT_IPV6_SND_RTR_ADV }, }; /* utility functions */ static bool _is_number(char *str) { for (; *str; str++) { if (*str < '0' || *str > '9') { return false; } } return true; } static inline bool _is_iface(kernel_pid_t iface) { return (gnrc_netif2_get_by_pid(iface) != NULL); } #ifdef MODULE_NETSTATS static const char *_netstats_module_to_str(uint8_t module) { switch (module) { case NETSTATS_LAYER2: return "Layer 2"; case NETSTATS_IPV6: return "IPv6"; case NETSTATS_ALL: return "all"; default: return "Unknown"; } } static int _netif_stats(kernel_pid_t iface, unsigned module, bool reset) { netstats_t *stats; int res = gnrc_netapi_get(iface, NETOPT_STATS, module, &stats, sizeof(&stats)); if (res < 0) { puts(" Protocol or device doesn't provide statistics."); } else if (reset) { memset(stats, 0, sizeof(netstats_t)); printf("Reset statistics for module %s!\n", _netstats_module_to_str(module)); } else { printf(" Statistics for %s\n" " RX packets %u bytes %u\n" " TX packets %u (Multicast: %u) bytes %u\n" " TX succeeded %u errors %u\n", _netstats_module_to_str(module), (unsigned) stats->rx_count, (unsigned) stats->rx_bytes, (unsigned) (stats->tx_unicast_count + stats->tx_mcast_count), (unsigned) stats->tx_mcast_count, (unsigned) stats->tx_bytes, (unsigned) stats->tx_success, (unsigned) stats->tx_failed); res = 0; } return res; } #endif // MODULE_NETSTATS static void _set_usage(char *cmd_name) { printf("usage: %s set \n", cmd_name); puts(" Sets an hardware specific specific value\n" " may be one of the following\n" " * \"addr\" - sets (short) address\n" " * \"addr_long\" - sets long address\n" " * \"addr_short\" - alias for \"addr\"\n" " * \"cca_threshold\" - set ED threshold during CCA in dBm\n" " * \"channel\" - sets the frequency channel\n" " * \"chan\" - alias for \"channel\"\n" " * \"csma_retries\" - set max. number of channel access attempts\n" " * \"encrypt\" - set the encryption on-off\n" " * \"hop_limit\" - set hop limit\n" " * \"hl\" - alias for \"hop_limit\"\n" " * \"key\" - set the encryption key in hexadecimal format\n" " * \"mtu\" - IPv6 maximum transition unit\n" " * \"nid\" - sets the network identifier (or the PAN ID)\n" " * \"page\" - set the channel page (IEEE 802.15.4)\n" " * \"pan\" - alias for \"nid\"\n" " * \"pan_id\" - alias for \"nid\"\n" " * \"power\" - TX power in dBm\n" " * \"retrans\" - max. number of retransmissions\n" " * \"src_len\" - sets the source address length in byte\n" " * \"state\" - set the device state\n"); } static void _flag_usage(char *cmd_name) { printf("usage: %s [-]{", cmd_name); for (unsigned i = 0; i < _ARRAY_LEN(flag_cmds); i++) { printf("%s", flag_cmds[i].name); if (i < (_ARRAY_LEN(flag_cmds) - 1)) { printf("|"); } } puts("}"); } static void _add_usage(char *cmd_name) { printf("usage: %s add [anycast|multicast|unicast] " "[/prefix_len]\n", cmd_name); } static void _del_usage(char *cmd_name) { printf("usage: %s del \n", cmd_name); } #ifdef MODULE_NETSTATS static void _stats_usage(char *cmd_name) { printf("usage: %s stats [l2|ipv6] [reset]\n", cmd_name); puts(" reset can be only used if the module is specified."); } #endif static void _print_netopt(netopt_t opt) { switch (opt) { case NETOPT_ADDRESS: printf("(short) address"); break; case NETOPT_ADDRESS_LONG: printf("long address"); break; case NETOPT_SRC_LEN: printf("source address length"); break; case NETOPT_CHANNEL: printf("channel"); break; case NETOPT_CHANNEL_PAGE: printf("page"); break; case NETOPT_HOP_LIMIT: printf("MTU"); break; case NETOPT_MAX_PACKET_SIZE: printf("MTU"); break; case NETOPT_NID: printf("network identifier"); break; case NETOPT_TX_POWER: printf("TX power [in dBm]"); break; case NETOPT_RETRANS: printf("max. retransmissions"); break; case NETOPT_CSMA_RETRIES: printf("CSMA retries"); break; case NETOPT_CCA_THRESHOLD: printf("CCA threshold [in dBm]"); break; case NETOPT_ENCRYPTION: printf("encryption"); break; case NETOPT_ENCRYPTION_KEY: printf("encryption key"); break; default: /* we don't serve these options here */ break; } } const char *_netopt_state_str[] = { [NETOPT_STATE_OFF] = "OFF", [NETOPT_STATE_SLEEP] = "SLEEP", [NETOPT_STATE_IDLE] = "IDLE", [NETOPT_STATE_RX] = "RX", [NETOPT_STATE_TX] = "TX", [NETOPT_STATE_RESET] = "RESET", [NETOPT_STATE_STANDBY] = "STANDBY" }; /* for some lines threshold might just be 0, so we can't use _LINE_THRESHOLD * here */ static void _newline(unsigned threshold, unsigned *line_thresh) { if (*line_thresh > threshold) { printf("\n "); *line_thresh = 0U; } } static unsigned _netif_list_flag(kernel_pid_t iface, netopt_t opt, char *str, unsigned line_thresh) { netopt_enable_t enable = NETOPT_DISABLE; int res = gnrc_netapi_get(iface, opt, 0, &enable, sizeof(enable)); if ((res >= 0) && (enable == NETOPT_ENABLE)) { printf("%s", str); line_thresh++; _newline(_LINE_THRESHOLD, &line_thresh); } return line_thresh; } #ifdef MODULE_GNRC_IPV6 static void _netif_list_ipv6(ipv6_addr_t *addr, uint8_t flags) { char addr_str[IPV6_ADDR_MAX_STR_LEN]; unsigned line_thresh = _LINE_THRESHOLD; printf("inet6 addr: "); ipv6_addr_to_str(addr_str, addr, sizeof(addr_str)); printf("%s scope: ", addr_str); if ((ipv6_addr_is_link_local(addr))) { printf("local"); } else { printf("global"); } if (flags & GNRC_NETIF2_IPV6_ADDRS_FLAGS_ANYCAST) { printf(" [anycast]"); } switch (flags & GNRC_NETIF2_IPV6_ADDRS_FLAGS_STATE_MASK) { case GNRC_NETIF2_IPV6_ADDRS_FLAGS_STATE_TENTATIVE: printf(" TNT"); break; case GNRC_NETIF2_IPV6_ADDRS_FLAGS_STATE_DEPRECATED: printf(" DPR"); break; case GNRC_NETIF2_IPV6_ADDRS_FLAGS_STATE_VALID: printf(" VAL"); break; } _newline(0U, &line_thresh); } #endif static void _netif_list(kernel_pid_t iface) { #ifdef MODULE_GNRC_IPV6 ipv6_addr_t ipv6_addrs[GNRC_NETIF2_IPV6_ADDRS_NUMOF]; #endif uint8_t hwaddr[GNRC_NETIF2_L2ADDR_MAXLEN]; uint16_t u16; int16_t i16; uint8_t u8; int res; netopt_state_t state; unsigned line_thresh = 1; printf("Iface %2d ", iface); res = gnrc_netapi_get(iface, NETOPT_ADDRESS, 0, hwaddr, sizeof(hwaddr)); if (res >= 0) { char hwaddr_str[res * 3]; printf(" HWaddr: %s ", gnrc_netif2_addr_to_str(hwaddr, res, hwaddr_str)); } res = gnrc_netapi_get(iface, NETOPT_CHANNEL, 0, &u16, sizeof(u16)); if (res >= 0) { printf(" Channel: %" PRIu16 " ", u16); } res = gnrc_netapi_get(iface, NETOPT_CHANNEL_PAGE, 0, &u16, sizeof(u16)); if (res >= 0) { printf(" Page: %" PRIu16 " ", u16); } res = gnrc_netapi_get(iface, NETOPT_NID, 0, &u16, sizeof(u16)); if (res >= 0) { printf(" NID: 0x%" PRIx16, u16); } _newline(0U, &line_thresh); res = gnrc_netapi_get(iface, NETOPT_ADDRESS_LONG, 0, hwaddr, sizeof(hwaddr)); if (res >= 0) { char hwaddr_str[res * 3]; printf("Long HWaddr: "); printf("%s ", gnrc_netif2_addr_to_str(hwaddr, res, hwaddr_str)); line_thresh++; } _newline(0U, &line_thresh); res = gnrc_netapi_get(iface, NETOPT_TX_POWER, 0, &i16, sizeof(i16)); if (res >= 0) { printf(" TX-Power: %" PRIi16 "dBm ", i16); } res = gnrc_netapi_get(iface, NETOPT_STATE, 0, &state, sizeof(state)); if (res >= 0) { printf(" State: %s ", _netopt_state_str[state]); line_thresh++; } res = gnrc_netapi_get(iface, NETOPT_RETRANS, 0, &u8, sizeof(u8)); if (res >= 0) { printf(" max. Retrans.: %u ", (unsigned)u8); line_thresh++; } res = gnrc_netapi_get(iface, NETOPT_CSMA_RETRIES, 0, &u8, sizeof(u8)); if (res >= 0) { netopt_enable_t enable = NETOPT_DISABLE; res = gnrc_netapi_get(iface, NETOPT_CSMA, 0, &enable, sizeof(enable)); if ((res >= 0) && (enable == NETOPT_ENABLE)) { printf(" CSMA Retries: %u ", (unsigned)u8); } line_thresh++; } _newline(0U, &line_thresh); line_thresh = _netif_list_flag(iface, NETOPT_PROMISCUOUSMODE, "PROMISC ", line_thresh); line_thresh = _netif_list_flag(iface, NETOPT_AUTOACK, "AUTOACK ", line_thresh); line_thresh = _netif_list_flag(iface, NETOPT_ACK_REQ, "ACK_REQ ", line_thresh); line_thresh = _netif_list_flag(iface, NETOPT_PRELOADING, "PRELOAD ", line_thresh); line_thresh = _netif_list_flag(iface, NETOPT_RAWMODE, "RAWMODE ", line_thresh); line_thresh = _netif_list_flag(iface, NETOPT_MAC_NO_SLEEP, "MAC_NO_SLEEP ", line_thresh); line_thresh = _netif_list_flag(iface, NETOPT_CSMA, "CSMA ", line_thresh); line_thresh += _LINE_THRESHOLD + 1; /* enforce linebreak after this option */ line_thresh = _netif_list_flag(iface, NETOPT_AUTOCCA, "AUTOCCA", line_thresh); #ifdef MODULE_GNRC_IPV6 res = gnrc_netapi_get(iface, NETOPT_MAX_PACKET_SIZE, GNRC_NETTYPE_IPV6, &u16, sizeof(u16)); if (res > 0) { printf("MTU:%" PRIu16 " ", u16); line_thresh++; } res = gnrc_netapi_get(iface, NETOPT_HOP_LIMIT, 0, &u8, sizeof(u8)); if (res > 0) { printf("HL:%" PRIu16 " ", u8); line_thresh++; } line_thresh = _netif_list_flag(iface, NETOPT_IPV6_FORWARDING, "RTR ", line_thresh); #ifndef MODULE_GNRC_SIXLOWPAN_IPHC line_thresh += _LINE_THRESHOLD + 1; /* enforce linebreak after this option */ #endif line_thresh = _netif_list_flag(iface, NETOPT_IPV6_SND_RTR_ADV, "RTR_ADV ", line_thresh); #ifdef MODULE_GNRC_SIXLOWPAN_IPHC line_thresh += _LINE_THRESHOLD + 1; /* enforce linebreak after this option */ line_thresh = _netif_list_flag(iface, NETOPT_6LO_IPHC, "IPHC ", line_thresh); #endif #endif res = gnrc_netapi_get(iface, NETOPT_SRC_LEN, 0, &u16, sizeof(u16)); if (res >= 0) { printf("Source address length: %" PRIu16 , u16); line_thresh++; } _newline(0U, &line_thresh); #ifdef MODULE_GNRC_IPV6 printf("Link type: %s", (gnrc_netapi_get(iface, NETOPT_IS_WIRED, 0, &u16, sizeof(u16)) > 0) ? "wired" : "wireless"); line_thresh++; _newline(0U, &line_thresh); res = gnrc_netapi_get(iface, NETOPT_IPV6_ADDR, 0, ipv6_addrs, sizeof(ipv6_addrs)); if (res >= 0) { uint8_t ipv6_addrs_flags[GNRC_NETIF2_IPV6_ADDRS_NUMOF]; memset(ipv6_addrs_flags, 0, sizeof(ipv6_addrs_flags)); /* assume it to succeed (otherwise array will stay 0) */ gnrc_netapi_get(iface, NETOPT_IPV6_ADDR_FLAGS, 0, ipv6_addrs_flags, sizeof(ipv6_addrs_flags)); /* yes, the res of NETOPT_IPV6_ADDR is meant to be here ;-) */ for (unsigned i = 0; i < (res / sizeof(ipv6_addr_t)); i++) { _netif_list_ipv6(&ipv6_addrs[i], ipv6_addrs_flags[i]); } } #endif #ifdef MODULE_L2FILTER l2filter_t *filter = NULL; res = gnrc_netapi_get(iface, NETOPT_L2FILTER, 0, &filter, sizeof(filter)); if (res > 0) { #ifdef MODULE_L2FILTER_WHITELIST puts("\n White-listed link layer addresses:"); #else puts("\n Black-listed link layer addresses:"); #endif int count = 0; for (unsigned i = 0; i < L2FILTER_LISTSIZE; i++) { if (filter[i].addr_len > 0) { char hwaddr_str[filter[i].addr_len * 3]; gnrc_netif2_addr_to_str(filter[i].addr, filter[i].addr_len, hwaddr_str); printf(" %2i: %s\n", count++, hwaddr_str); } } if (count == 0) { puts(" --- none ---"); } } #endif #ifdef MODULE_NETSTATS_L2 puts(""); _netif_stats(iface, NETSTATS_LAYER2, false); #endif #ifdef MODULE_NETSTATS_IPV6 _netif_stats(iface, NETSTATS_IPV6, false); #endif puts(""); } static int _netif_set_u16(kernel_pid_t iface, netopt_t opt, uint16_t context, char *u16_str) { unsigned int res; bool hex = false; if (_is_number(u16_str)) { if ((res = strtoul(u16_str, NULL, 10)) == ULONG_MAX) { puts("error: unable to parse value.\n" "Must be a 16-bit unsigned integer (dec or hex)\n"); return 1; } } else { if ((res = strtoul(u16_str, NULL, 16)) == ULONG_MAX) { puts("error: unable to parse value.\n" "Must be a 16-bit unsigned integer (dec or hex)\n"); return 1; } hex = true; } if (res > 0xffff) { puts("error: unable to parse value.\n" "Must be a 16-bit unsigned integer (dec or hex)\n"); return 1; } if (gnrc_netapi_set(iface, opt, context, (uint16_t *)&res, sizeof(uint16_t)) < 0) { printf("error: unable to set "); _print_netopt(opt); puts(""); return 1; } printf("success: set "); _print_netopt(opt); printf(" on interface %" PRIkernel_pid " to ", iface); if (hex) { printf("0x%04x\n", res); } else { printf("%u\n", res); } return 0; } static int _netif_set_i16(kernel_pid_t iface, netopt_t opt, char *i16_str) { int16_t val = atoi(i16_str); if (gnrc_netapi_set(iface, opt, 0, (int16_t *)&val, sizeof(int16_t)) < 0) { printf("error: unable to set "); _print_netopt(opt); puts(""); return 1; } printf("success: set "); _print_netopt(opt); printf(" on interface %" PRIkernel_pid " to %i\n", iface, val); return 0; } static int _netif_set_u8(kernel_pid_t iface, netopt_t opt, uint16_t context, char *u8_str) { uint8_t val = atoi(u8_str); if (gnrc_netapi_set(iface, opt, context, (uint8_t *)&val, sizeof(uint8_t)) < 0) { printf("error: unable to set "); _print_netopt(opt); puts(""); return 1; } printf("success: set "); _print_netopt(opt); printf(" on interface %" PRIkernel_pid " to %i\n", iface, val); return 0; } static int _netif_set_flag(kernel_pid_t iface, netopt_t opt, netopt_enable_t set) { if (gnrc_netapi_set(iface, opt, 0, &set, sizeof(netopt_enable_t)) < 0) { puts("error: unable to set option"); return 1; } printf("success: %sset option\n", (set) ? "" : "un"); return 0; } static int _netif_set_addr(kernel_pid_t iface, netopt_t opt, char *addr_str) { uint8_t addr[GNRC_NETIF2_L2ADDR_MAXLEN]; size_t addr_len = gnrc_netif2_addr_from_str(addr_str, addr); if (addr_len == 0) { puts("error: unable to parse address.\n" "Must be of format [0-9a-fA-F]{2}(:[0-9a-fA-F]{2})*\n" "(hex pairs delimited by colons)"); return 1; } if (gnrc_netapi_set(iface, opt, 0, addr, addr_len) < 0) { printf("error: unable to set "); _print_netopt(opt); puts(""); return 1; } printf("success: set "); _print_netopt(opt); printf(" on interface %" PRIkernel_pid " to %s\n", iface, addr_str); return 0; } static int _netif_set_state(kernel_pid_t iface, char *state_str) { netopt_state_t state; if ((strcmp("off", state_str) == 0) || (strcmp("OFF", state_str) == 0)) { state = NETOPT_STATE_OFF; } else if ((strcmp("sleep", state_str) == 0) || (strcmp("SLEEP", state_str) == 0)) { state = NETOPT_STATE_SLEEP; } else if ((strcmp("idle", state_str) == 0) || (strcmp("IDLE", state_str) == 0)) { state = NETOPT_STATE_IDLE; } else if ((strcmp("reset", state_str) == 0) || (strcmp("RESET", state_str) == 0)) { state = NETOPT_STATE_RESET; } else { puts("usage: ifconfig set state [off|sleep|idle|reset]"); return 1; } if (gnrc_netapi_set(iface, NETOPT_STATE, 0, &state, sizeof(netopt_state_t)) < 0) { printf("error: unable to set state to %s\n", _netopt_state_str[state]); return 1; } printf("success: set state of interface %" PRIkernel_pid " to %s\n", iface, _netopt_state_str[state]); return 0; } static int _hex_to_int(char c) { if ('0' <= c && c <= '9') { return c - '0'; } else if ('a' <= c && c <= 'f') { return c - 'a'; } else if ('A' <= c && c <= 'F') { return c - 'A'; } else { return -1; } } static int _netif_set_encrypt_key(kernel_pid_t iface, netopt_t opt, char *key_str) { size_t str_len = strlen(key_str); size_t key_len = str_len / 2; uint8_t key[key_len]; if (str_len == 14U) { printf("\nNotice: setting 56 bit key."); } else if (str_len == 16U) { printf("\nNotice: setting 64 bit key."); } else if (str_len == 32U) { printf("\nNotice: setting 128 bit key."); } else if (str_len == 48U) { printf("\nNotice: setting 192 bit key."); } else if (str_len == 64U) { printf("\nNotice: setting 256 bit key."); } else if (str_len == 128U) { printf("\nNotice: setting 512 bit key."); } else { printf("error: invalid key size.\n"); return 1; } /* Convert any char from ASCII table in hex format */ for (size_t i = 0; i < str_len; i += 2) { int i1 = _hex_to_int(key_str[i]); int i2 = _hex_to_int(key_str[i + 1]); if (i1 == -1 || i2 == -1) { puts("error: unable to parse key"); return 1; } key[i / 2] = (uint8_t)((i1 << 4) + i2); } if (gnrc_netapi_set(iface, opt, 0, key, key_len) < 0) { puts("error: unable to set encryption key"); return 1; } printf("success: set encryption key on interface %" PRIkernel_pid " to \n", iface); for (size_t i = 0; i < key_len; i++) { /* print the hex value of the key */ printf("%02x", key[i]); } puts(""); return 0; } #ifdef MODULE_L2FILTER static int _netif_addrm_l2filter(kernel_pid_t iface, char *val, bool add) { uint8_t addr[GNRC_NETIF2_L2ADDR_MAXLEN]; size_t addr_len = gnrc_netif2_addr_from_str(val, addr); if ((addr_len == 0) || (addr_len > L2FILTER_ADDR_MAXLEN)) { puts("error: given address is invalid"); return 1; } if (add) { if (gnrc_netapi_set(iface, NETOPT_L2FILTER, 0, addr, addr_len) < 0) { puts("unable to add link layer address to filter"); return 1; } puts("successfully added address to filter"); } else { if (gnrc_netapi_set(iface, NETOPT_L2FILTER_RM, 0, addr, addr_len) < 0) { puts("unable to remove link layer address from filter"); return 1; } puts("successfully removed address to filter"); } return 0; } static void _l2filter_usage(const char *cmd) { printf("usage: %s l2filter {add|del} \n", cmd); } #endif static void _usage(char *cmd) { printf("usage: %s\n", cmd); _set_usage(cmd); _flag_usage(cmd); _add_usage(cmd); _del_usage(cmd); #ifdef MODULE_L2FILTER _l2filter_usage(cmd); #endif #ifdef MODULE_NETSTATS _stats_usage(cmd); #endif } static int _netif_set(char *cmd_name, kernel_pid_t iface, char *key, char *value) { if ((strcmp("addr", key) == 0) || (strcmp("addr_short", key) == 0)) { return _netif_set_addr(iface, NETOPT_ADDRESS, value); } else if (strcmp("addr_long", key) == 0) { return _netif_set_addr(iface, NETOPT_ADDRESS_LONG, value); } else if (strcmp("cca_threshold", key) == 0) { return _netif_set_u8(iface, NETOPT_CCA_THRESHOLD, 0, value); } else if ((strcmp("channel", key) == 0) || (strcmp("chan", key) == 0)) { return _netif_set_u16(iface, NETOPT_CHANNEL, 0, value); } else if (strcmp("csma_retries", key) == 0) { return _netif_set_u8(iface, NETOPT_CSMA_RETRIES, 0, value); } else if ((strcmp("hl", key) == 0) || (strcmp("hop_limit", key) == 0)) { return _netif_set_u8(iface, NETOPT_HOP_LIMIT, 0, value); } else if (strcmp("key", key) == 0) { return _netif_set_encrypt_key(iface, NETOPT_ENCRYPTION_KEY, value); } #ifdef MODULE_GNRC_IPV6 else if (strcmp("mtu", key) == 0) { return _netif_set_u16(iface, NETOPT_MAX_PACKET_SIZE, GNRC_NETTYPE_IPV6, value); } #endif else if ((strcmp("nid", key) == 0) || (strcmp("pan", key) == 0) || (strcmp("pan_id", key) == 0)) { return _netif_set_u16(iface, NETOPT_NID, 0, value); } else if (strcmp("page", key) == 0) { return _netif_set_u16(iface, NETOPT_CHANNEL_PAGE, 0, value); } else if (strcmp("power", key) == 0) { return _netif_set_i16(iface, NETOPT_TX_POWER, value); } else if (strcmp("retrans", key) == 0) { return _netif_set_u8(iface, NETOPT_RETRANS, 0, value); } else if (strcmp("src_len", key) == 0) { return _netif_set_u16(iface, NETOPT_SRC_LEN, 0, value); } else if (strcmp("state", key) == 0) { return _netif_set_state(iface, value); } _set_usage(cmd_name); return 1; } static int _netif_flag(char *cmd, kernel_pid_t iface, char *flag) { netopt_enable_t set = NETOPT_ENABLE; if (flag[0] == '-') { set = NETOPT_DISABLE; flag++; } for (unsigned i = 0; i < _ARRAY_LEN(flag_cmds); i++) { if (strcmp(flag_cmds[i].name, flag) == 0) { return _netif_set_flag(iface, flag_cmds[i].opt, set); } } _flag_usage(cmd); return 1; } #ifdef MODULE_GNRC_IPV6 static uint8_t _get_prefix_len(char *addr) { int prefix_len = ipv6_addr_split(addr, '/', _IPV6_DEFAULT_PREFIX_LEN); if (prefix_len < 1) { prefix_len = _IPV6_DEFAULT_PREFIX_LEN; } return prefix_len; } #endif static int _netif_add(char *cmd_name, kernel_pid_t iface, int argc, char **argv) { #ifdef MODULE_GNRC_IPV6 enum { _UNICAST = 0, _ANYCAST } type = _UNICAST; char *addr_str = argv[0]; ipv6_addr_t addr; uint16_t flags = GNRC_NETIF2_IPV6_ADDRS_FLAGS_STATE_VALID; uint8_t prefix_len; if (argc > 1) { if (strcmp(argv[0], "anycast") == 0) { type = _ANYCAST; addr_str = argv[1]; } else if (strcmp(argv[0], "unicast") == 0) { /* type already set to unicast */ addr_str = argv[1]; } else { _add_usage(cmd_name); return 1; } } prefix_len = _get_prefix_len(addr_str); if (ipv6_addr_from_str(&addr, addr_str) == NULL) { puts("error: unable to parse IPv6 address."); return 1; } if (ipv6_addr_is_multicast(&addr)) { if (gnrc_netapi_set(iface, NETOPT_IPV6_GROUP, 0, &addr, sizeof(addr)) < 0) { printf("error: unable to join IPv6 multicast group\n"); return 1; } } else { if (type == _ANYCAST) { flags |= GNRC_NETIF2_IPV6_ADDRS_FLAGS_ANYCAST; } flags |= (prefix_len << 8U); if (gnrc_netapi_set(iface, NETOPT_IPV6_ADDR, flags, &addr, sizeof(addr)) < 0) { printf("error: unable to add IPv6 address\n"); return 1; } } printf("success: added %s/%d to interface %" PRIkernel_pid "\n", addr_str, prefix_len, iface); return 0; #else (void)cmd_name; (void)iface; (void)argc; (void)argv; puts("error: unable to add IPv6 address."); return 1; #endif } static int _netif_del(kernel_pid_t iface, char *addr_str) { #ifdef MODULE_GNRC_IPV6 ipv6_addr_t addr; if (ipv6_addr_from_str(&addr, addr_str) == NULL) { puts("error: unable to parse IPv6 address."); return 1; } if (ipv6_addr_is_multicast(&addr)) { if (gnrc_netapi_set(iface, NETOPT_IPV6_GROUP_LEAVE, 0, &addr, sizeof(addr)) < 0) { printf("error: unable to leave IPv6 multicast group\n"); return 1; } } else { if (gnrc_netapi_set(iface, NETOPT_IPV6_ADDR_REMOVE, 0, &addr, sizeof(addr)) < 0) { printf("error: unable to remove IPv6 address\n"); return 1; } } printf("success: removed %s to interface %" PRIkernel_pid "\n", addr_str, iface); return 0; #else (void)iface; (void)addr_str; puts("error: unable to delete IPv6 address."); return 1; #endif } /* shell commands */ #ifdef MODULE_GNRC_TXTSND int _gnrc_netif2_send(int argc, char **argv) { kernel_pid_t iface; uint8_t addr[GNRC_NETIF2_L2ADDR_MAXLEN]; size_t addr_len; gnrc_pktsnip_t *pkt, *hdr; gnrc_netif_hdr_t *nethdr; uint8_t flags = 0x00; if (argc < 4) { printf("usage: %s [|bcast] \n", argv[0]); return 1; } /* parse interface */ iface = atoi(argv[1]); if (!_is_iface(iface)) { puts("error: invalid interface given"); return 1; } /* parse address */ addr_len = gnrc_netif2_addr_from_str(argv[2], addr); if (addr_len == 0) { if (strcmp(argv[2], "bcast") == 0) { flags |= GNRC_NETIF_HDR_FLAGS_BROADCAST; } else { puts("error: invalid address given"); return 1; } } /* put packet together */ pkt = gnrc_pktbuf_add(NULL, argv[3], strlen(argv[3]), GNRC_NETTYPE_UNDEF); if (pkt == NULL) { puts("error: packet buffer full"); return 1; } hdr = gnrc_netif_hdr_build(NULL, 0, addr, addr_len); if (hdr == NULL) { puts("error: packet buffer full"); gnrc_pktbuf_release(pkt); return 1; } LL_PREPEND(pkt, hdr); nethdr = (gnrc_netif_hdr_t *)hdr->data; nethdr->flags = flags; /* and send it */ if (gnrc_netapi_send(iface, pkt) < 1) { puts("error: unable to send"); gnrc_pktbuf_release(pkt); return 1; } return 0; } #endif int _gnrc_netif2_config(int argc, char **argv) { if (argc < 2) { gnrc_netif2_t *netif = NULL; while ((netif = gnrc_netif2_iter(netif))) { _netif_list(netif->pid); } return 0; } else if (_is_number(argv[1])) { kernel_pid_t iface = atoi(argv[1]); if (_is_iface(iface)) { if (argc < 3) { _netif_list(iface); return 0; } else if (strcmp(argv[2], "set") == 0) { if (argc < 5) { _set_usage(argv[0]); return 1; } return _netif_set(argv[0], iface, argv[3], argv[4]); } else if (strcmp(argv[2], "add") == 0) { if (argc < 4) { _add_usage(argv[0]); return 1; } return _netif_add(argv[0], (kernel_pid_t)iface, argc - 3, argv + 3); } else if (strcmp(argv[2], "del") == 0) { if (argc < 4) { _del_usage(argv[0]); return 1; } return _netif_del((kernel_pid_t)iface, argv[3]); } #ifdef MODULE_L2FILTER else if (strcmp(argv[2], "l2filter") == 0) { if (argc < 5) { _l2filter_usage(argv[2]); } else if (strcmp(argv[3], "add") == 0) { return _netif_addrm_l2filter(iface, argv[4], true); } else if (strcmp(argv[3], "del") == 0) { return _netif_addrm_l2filter(iface, argv[4], false); } else { _l2filter_usage(argv[2]); } return 1; } #endif #ifdef MODULE_NETSTATS else if (strcmp(argv[2], "stats") == 0) { uint8_t module; bool reset = false; /* check for requested module */ if ((argc == 3) || (strcmp(argv[3], "all") == 0)) { module = NETSTATS_ALL; } else if (strcmp(argv[3], "l2") == 0) { module = NETSTATS_LAYER2; } else if (strcmp(argv[3], "ipv6") == 0) { module = NETSTATS_IPV6; } else { printf("Module %s doesn't exist or does not provide statistics.\n", argv[3]); return 0; } /* check if reset flag was given */ if ((argc > 4) && (strncmp(argv[4], "reset", 5) == 0)) { reset = true; } if (module & NETSTATS_LAYER2) { _netif_stats((kernel_pid_t) iface, NETSTATS_LAYER2, reset); } if (module & NETSTATS_IPV6) { _netif_stats((kernel_pid_t) iface, NETSTATS_IPV6, reset); } return 1; } #endif else if (strcmp(argv[2], "help") == 0) { _usage(argv[0]); return 0; } else { return _netif_flag(argv[0], iface, argv[2]); } } else { puts("error: invalid interface given"); return 1; } } _usage(argv[0]); return 1; }