/**************************************************************************** * net/sixlowpan/sixlowpan_utils.c * * Copyright (C) 2017 Gregory Nutt. All rights reserved. * Author: Gregory Nutt * * Derives from logic in Contiki: * * Copyright (c) 2008, Swedish Institute of Computer Science. * All rights reserved. * Authors: Adam Dunkels * Nicolas Tsiftes * Niclas Finne * Mathilde Durvy * Julien Abeille * Joakim Eriksson * Joel Hoglund * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the Institute nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE INSTITUTE AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE INSTITUTE OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * ****************************************************************************/ /**************************************************************************** * Included Files ****************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include "route/route.h" #include "inet/inet.h" #include "sixlowpan/sixlowpan_internal.h" #ifdef CONFIG_NET_6LOWPAN /**************************************************************************** * Pre-processor Definitions ****************************************************************************/ /* REVISIT: The setting CONFIG_PKTRADIO_ADDRLEN should be the *maximum* * address length. If there is only a single packet radio then it should be * the exact address length of that radio. If there are multiple packet * radios with different address lengths, then it will be inexact; it will * be the size of the longest address. */ #undef HAVE_BYTEADDR #undef HAVE_SADDR #undef HAVE_EADDR #ifdef CONFIG_WIRELESS_IEEE802154 # define HAVE_SADDR 1 # define HAVE_EADDR 1 #endif #ifdef CONFIG_WIRELESS_PKTRADIO # if CONFIG_PKTRADIO_ADDRLEN == 1 # define HAVE_BYTEADDR 1 # elif CONFIG_PKTRADIO_ADDRLEN == 2 # define HAVE_BYTEADDR 1 # define HAVE_SADDR 1 # elif CONFIG_PKTRADIO_ADDRLEN == 8 # define HAVE_BYTEADDR 1 # define HAVE_SADDR 1 # define HAVE_EADDR 1 # else # error Unsupported value for CONFIG_PKTRADIO_ADDRLEN # endif #endif /**************************************************************************** * Private Functions ****************************************************************************/ /**************************************************************************** * Name: sixlowpan_[s|e]addrfromip * * Description: * sixlowpan_[s|e]addrfromip(): Extract the IEEE 802.15.14 address from a * MAC-based IPv6 address. sixlowpan_saddrfromip() and * sixlowpan_eaddrfromip() handle short and extended addresses, * respectively. * * 128 112 96 80 64 48 32 16 * ---- ---- ---- ---- ---- ---- ---- ---- * fe80 0000 0000 0000 0000 00ff fe00 xx00 1-byte short address 48-bit MAC * xxxx 0000 0000 0000 0000 00ff fe00 xxxx 2-byte short address 48-bit MAC * xxxx 0000 0000 0000 xxxx xxxx xxxx xxxx 8-byte extended address EUI-64 * ****************************************************************************/ #ifndef CONFIG_NET_STARPOINT #ifdef HAVE_BYTEADDR static void sixlowpan_baddrfromip(const net_ipv6addr_t ipaddr, FAR uint8_t *baddr) { /* Big-endian uint16_t to byte order */ baddr[0] = NTOHS(ipaddr[7]) & 0xff; } #endif #ifdef HAVE_SADDR static void sixlowpan_saddrfromip(const net_ipv6addr_t ipaddr, FAR uint8_t *saddr) { /* Big-endian uint16_t to byte order */ saddr[0] = NTOHS(ipaddr[7]) >> 8; saddr[1] = NTOHS(ipaddr[7]) & 0xff; } #endif #ifdef HAVE_EADDR static void sixlowpan_eaddrfromip(const net_ipv6addr_t ipaddr, FAR uint8_t *eaddr) { FAR uint8_t *eptr = eaddr; int i; for (i = 4; i < 8; i++) { /* Big-endian uint16_t to byte order */ *eptr++ = NTOHS(ipaddr[i]) >> 8; *eptr++ = NTOHS(ipaddr[i]) & 0xff; } eaddr[0] ^= 0x02; } #endif #endif /* !CONFIG_NET_STARPOINT */ /**************************************************************************** * Public Functions ****************************************************************************/ /**************************************************************************** * Name: sixlowpan_nexthopaddr * * Description: * sixlowpan_nexthopaddr(): If the destination is on-link, extract the * IEEE 802.15.14 destination address from the destination IP address. * If the destination is not reachable directly, use the routing table * (if available) or fall back to the default router IP address and use * the router IP address to derive the IEEE 802.15.4 MAC address. * ****************************************************************************/ int sixlowpan_nexthopaddr(FAR struct radio_driver_s *radio, FAR const net_ipv6addr_t ipaddr, FAR struct netdev_varaddr_s *destaddr) { FAR net_ipv6addr_t router; int ret; /* Try to get the IEEE 802.15.4 MAC address of the destination. This * assumes an encoding of the MAC address in the IPv6 address. */ ret = sixlowpan_destaddrfromip(radio, ipaddr, destaddr); if (ret < 0) { /* Destination address is not on the local network */ #ifdef CONFIG_NET_ROUTE /* We have a routing table.. find the correct router to use in * this case (or, as a fall-back, use the device's default router * address). We will use the router IPv6 address instead of the * destination address when determining the MAC address. */ netdev_ipv6_router(&radio->r_dev, ipaddr, router); #else /* Use the device's default router IPv6 address instead of the * destination address when determining the MAC address. */ net_ipv6addr_copy(router, radio->r_dev.d_ipv6draddr); #endif /* Get the IEEE 802.15.4 MAC address of the router. This * assumes an encoding of the MAC address in the IPv6 address. */ ret = sixlowpan_destaddrfromip(radio, router, destaddr); if (ret < 0) { return ret; } } return OK; } /**************************************************************************** * Name: sixlowpan_destaddrfromip * * Description: * sixlowpan_destaddrfromip(): Extract the IEEE 802.15.14 destination * address from a MAC-based destination IPv6 address. This function * handles a tagged address union which may either a short or and * extended destination address. * * 128 112 96 80 64 48 32 16 * ---- ---- ---- ---- ---- ---- ---- ---- * ffxx xxxx xxxx xxxx xxxx xxxx xxxx xxxx Multicast address (RFC 3513) * ff02 0000 0000 0000 0000 0000 0000 0001 All nodes multicast group * xxxx 0000 0000 0000 0000 00ff fe00 xx00 1-byte short address 48-bit MAC * xxxx 0000 0000 0000 0000 00ff fe00 xxxx 2-byte short address 48-bit MAC * xxxx 0000 0000 0000 xxxx xxxx xxxx xxxx 8-byte extended address EUI-64 * * In the case there the IEEE 802.15.4 node functions as an endpoint in a * start topology, the destination address will, instead, be the address * of the star hub (which is assumed to be the address of the coordinator). * ****************************************************************************/ int sixlowpan_destaddrfromip(FAR struct radio_driver_s *radio, const net_ipv6addr_t ipaddr, FAR struct netdev_varaddr_s *destaddr) { struct radiodev_properties_s properties; int ret; #ifdef CONFIG_NET_STARPOINT /* Only the radio driver knows the correct address of the hub. For IEEE * 802.15.4 this will be the address of the PAN coordinator. For other * radios, this may be some configured, "well-known" address. */ DEBUGASSERT(radio->r_properties != NULL); ret = radio->r_properties(radio, &properties); if (ret < 0) { return ret; } memcpy(destaddr, &properties.sp_hubnode, sizeof(struct netdev_varaddr_s)); return OK; #else /* CONFIG_NET_STARPOINT */ /* Check for a multicast address */ if (net_is_addr_mcast(ipaddr)) { DEBUGASSERT(radio->r_properties != NULL); ret = radio->r_properties(radio, &properties); if (ret < 0) { return ret; } /* Check for the broadcast IP address * * IPv6 does not implement the method of broadcast, and therefore * does not define broadcast addresses. Instead, IPv6 uses multicast * addressing to the all-nodes multicast group: ff02:0:0:0:0:0:0:1. * * However, the use of the all-nodes group is not common, and most * IPv6 protocols use a dedicated link-local multicast group to avoid * disturbing every interface in the network. */ if (net_ipv6addr_cmp(ipaddr, g_ipv6_allnodes)) { memcpy(destaddr, &properties.sp_bcast, sizeof(struct netdev_varaddr_s)); } /* Some other RFC 3513 multicast address */ else { memcpy(destaddr, &properties.sp_mcast, sizeof(struct netdev_varaddr_s)); } return OK; } /* Otherwise, the destination MAC address is encoded in the IP address */ /* If the address is link-local, or matches the prefix of the local * address, the interface identifier can be extracted from the lower * bits of the address. */ if (!sixlowpan_islinklocal(ipaddr) && !NETDEV_V6ADDR_ONLINK(&radio->r_dev, ipaddr)) { return -EADDRNOTAVAIL; } #ifdef CONFIG_WIRELESS_PKTRADIO /* If this is a packet radio, then we cannot know the correct size of the * radio's MAC address without asking. The setting CONFIG_PKTRADIO_ADDRLEN * is inexact if there are multiple packet radios with different address * lengths; it that case it will be the size of the longest address. * * NOTE: This logic assumes that the packet radio's address length is a * constant. */ #ifdef CONFIG_WIRELESS_IEEE802154 if (radio->r_dev.d_lltype == NET_LL_PKTRADIO) #endif { DEBUGASSERT(radio->r_properties != NULL); ret = radio->r_properties(radio, &properties); if (ret < 0) { return ret; } #ifdef HAVE_BYTEADDR if (properties.sp_addrlen == 1 && SIXLOWPAN_IS_IID_8BIT_COMPRESSABLE(ipaddr)) { memset(destaddr, 0, sizeof(struct netdev_varaddr_s)); sixlowpan_baddrfromip(ipaddr, destaddr->nv_addr); destaddr->nv_addrlen = 1; return OK; } else #endif #ifdef HAVE_SADDR if (properties.sp_addrlen == 2 && SIXLOWPAN_IS_IID_16BIT_COMPRESSABLE(ipaddr)) { memset(destaddr, 0, sizeof(struct netdev_varaddr_s)); sixlowpan_saddrfromip(ipaddr, destaddr->nv_addr); destaddr->nv_addrlen = 2; return OK; } else #endif #ifdef HAVE_EADDR if (properties.sp_addrlen == 8) { sixlowpan_eaddrfromip(ipaddr, destaddr->nv_addr); destaddr->nv_addrlen = 8; return OK; } else #endif { /* Just to satisfy the last dangling 'else' */ } return -EADDRNOTAVAIL; } #endif /* CONFIG_WIRELESS_PKTRADIO */ #ifdef CONFIG_WIRELESS_IEEE802154 #ifdef CONFIG_WIRELESS_PKTRADIO else #endif { if (SIXLOWPAN_IS_IID_16BIT_COMPRESSABLE(ipaddr)) { memset(destaddr, 0, sizeof(struct netdev_varaddr_s)); sixlowpan_saddrfromip(ipaddr, destaddr->nv_addr); destaddr->nv_addrlen = NET_6LOWPAN_SADDRSIZE; } else { sixlowpan_eaddrfromip(ipaddr, destaddr->nv_addr); destaddr->nv_addrlen = NET_6LOWPAN_EADDRSIZE; } return OK; } #endif /* CONFIG_WIRELESS_IEEE802154 */ #endif /* CONFIG_NET_STARPOINT */ } /**************************************************************************** * Name: sixlowpan_ipfromaddr (plus helpers) * * Description: * sixlowpan_ipfrom[s|e]addr(): Create a link-local, MAC-based IPv6 * address from an IEEE802.15.4 short address (saddr), extended address * (eaddr), or other variable length radio addresses. * * 128 112 96 80 64 48 32 16 * ---- ---- ---- ---- ---- ---- ---- ---- * fe80 0000 0000 0000 0000 00ff fe00 xx00 1-byte short address 48-bit MAC * fe80 0000 0000 0000 0000 00ff fe00 xxxx 2-byte short address 48-bit MAC * fe80 0000 0000 0000 xxxx xxxx xxxx xxxx 8-byte extended address EUI-64 * ****************************************************************************/ #ifdef HAVE_BYTEADDR static inline void sixlowpan_ipfrombyte(FAR const uint8_t *byte, FAR net_ipv6addr_t ipaddr) { ipaddr[0] = HTONS(0xfe80); ipaddr[1] = 0; ipaddr[2] = 0; ipaddr[3] = 0; ipaddr[4] = 0; ipaddr[5] = HTONS(0x00ff); ipaddr[6] = HTONS(0xfe00); ipaddr[7] = HTONS((uint16_t)byte[0]); } #endif #ifdef HAVE_SADDR static inline void sixlowpan_ipfromsaddr(FAR const uint8_t *saddr, FAR net_ipv6addr_t ipaddr) { ipaddr[0] = HTONS(0xfe80); ipaddr[1] = 0; ipaddr[2] = 0; ipaddr[3] = 0; ipaddr[4] = 0; ipaddr[5] = HTONS(0x00ff); ipaddr[6] = HTONS(0xfe00); /* Preserve big-endian */ memcpy(&ipaddr[7], saddr, 2); } #endif #ifdef HAVE_EADDR static inline void sixlowpan_ipfromeaddr(FAR const uint8_t *eaddr, FAR net_ipv6addr_t ipaddr) { ipaddr[0] = HTONS(0xfe80); ipaddr[1] = 0; ipaddr[2] = 0; ipaddr[3] = 0; /* Preserve big-endian */ memcpy(&ipaddr[4], eaddr , 2); memcpy(&ipaddr[5], eaddr + 2, 2); memcpy(&ipaddr[6], eaddr + 4, 2); memcpy(&ipaddr[7], eaddr + 6, 2); /* Invert the U/L bit */ ipaddr[4] ^= HTONS(0x0200); } #endif void sixlowpan_ipfromaddr(FAR const struct netdev_varaddr_s *addr, FAR net_ipv6addr_t ipaddr) { switch (addr->nv_addrlen) { #ifdef HAVE_BYTEADDR case 1: sixlowpan_ipfrombyte(addr->nv_addr, ipaddr); break; #endif #ifdef HAVE_SADDR case NET_6LOWPAN_SADDRSIZE: sixlowpan_ipfromsaddr(addr->nv_addr, ipaddr); break; #endif #ifdef HAVE_EADDR case NET_6LOWPAN_EADDRSIZE: sixlowpan_ipfromeaddr(addr->nv_addr, ipaddr); break; #endif default: nerr("ERROR: Unsupported address length: %u\n", addr->nv_addrlen); break; } } /**************************************************************************** * Name: sixlowpan_ismacbased (and helpers) * * Description: * sixlowpan_ismacbased() will return true for IP addresses formed from * IEEE802.15.4 MAC addresses. sixlowpan_destaddrfromip() is intended to * handle a tagged address or any size. * * 128 112 96 80 64 48 32 16 * ---- ---- ---- ---- ---- ---- ---- ---- * fe80 0000 0000 0000 0000 00ff fe00 xx00 1-byte short address 48-bit MAC * fe80 0000 0000 0000 0000 00ff fe00 xxxx 2-byte short address 48-bit MAC * fe80 0000 0000 0000 xxxx xxxx xxxx xxxx 8-byte extended address EUI-64 * ****************************************************************************/ #ifdef HAVE_BYTEADDR static inline bool sixlowpan_isbytebased(const net_ipv6addr_t ipaddr, uint8_t byte) { return (ipaddr[5] == HTONS(0x00ff) && ipaddr[6] == HTONS(0xfe00) && ipaddr[7] == HTONS((uint16_t)byte)); } #endif #ifdef HAVE_SADDR static inline bool sixlowpan_issaddrbased(const net_ipv6addr_t ipaddr, FAR const uint8_t *saddr) { return (ipaddr[5] == HTONS(0x00ff) && ipaddr[6] == HTONS(0xfe00) && ipaddr[7] == *(FAR uint16_t *)saddr); } #endif #ifdef HAVE_EADDR static inline bool sixlowpan_iseaddrbased(const net_ipv6addr_t ipaddr, FAR const uint8_t *eaddr) { /* If the U/L bit is not set, indicating that the address is universal, it * can not be eaddr-based since EUI-64's are always universal */ if ((ipaddr[4] & HTONS(0x0200)) == 0) { return false; } return (ipaddr[4] == ((*(FAR uint16_t *)eaddr) ^ HTONS(0x0200)) && ipaddr[5] == *(FAR uint16_t *)(eaddr + 2) && ipaddr[6] == *(FAR uint16_t *)(eaddr + 4) && ipaddr[7] == *(FAR uint16_t *)(eaddr + 6)); } #endif bool sixlowpan_ismacbased(const net_ipv6addr_t ipaddr, FAR const struct netdev_varaddr_s *addr) { switch (addr->nv_addrlen) { #ifdef HAVE_BYTEADDR case 1: return sixlowpan_isbytebased(ipaddr, addr->nv_addr[0]); #endif #ifdef HAVE_SADDR case NET_6LOWPAN_SADDRSIZE: return sixlowpan_issaddrbased(ipaddr, addr->nv_addr); #endif #ifdef HAVE_EADDR case NET_6LOWPAN_EADDRSIZE: return sixlowpan_iseaddrbased(ipaddr, addr->nv_addr); #endif default: nerr("ERROR: Unsupported address length: %u\n", addr->nv_addrlen); return false; } } /**************************************************************************** * Name: sixlowpan_radio_framelen * * Description: * Get the maximum frame length supported by radio network driver. * * Input Parameters: * radio - Reference to a radio network driver state instance. * * Returned Value: * A non-negative, maximum frame lengthis returned on success; A negated * errno valueis returned on any failure. * ****************************************************************************/ int sixlowpan_radio_framelen(FAR struct radio_driver_s *radio) { struct radiodev_properties_s properties; int ret; /* Only the radio driver knows the correct max frame length supported by * the radio. */ DEBUGASSERT(radio->r_properties != NULL); ret = radio->r_properties(radio, &properties); if (ret < 0) { return ret; } return (int)properties.sp_framelen; } /**************************************************************************** * Name: sixlowpan_src_panid * * Description: * Get the source PAN ID from the IEEE802.15.4 MAC layer. * * Input Parameters: * radio - Reference to a radio network driver state instance. * panid - The location in which to return the PAN ID. 0xfff may be * returned if the device is not associated. * * Returned Value: * Zero (OK) on success; a negated errno value on failure. * ****************************************************************************/ #ifdef CONFIG_WIRELESS_IEEE802154 int sixlowpan_src_panid(FAR struct radio_driver_s *radio, FAR uint8_t *panid) { FAR struct net_driver_s *dev = &radio->r_dev; struct ieee802154_netmac_s arg; int ret; memcpy(arg.ifr_name, radio->r_dev.d_ifname, IFNAMSIZ); arg.u.getreq.attr = IEEE802154_ATTR_MAC_PANID; ret = dev->d_ioctl(dev, MAC802154IOC_MLME_GET_REQUEST, (unsigned long)((uintptr_t)&arg)); if (ret < 0) { nerr("ERROR: MAC802154IOC_MLME_GET_REQUEST failed: %d\n", ret); return ret; } /* MAC802154 gives us PAN ID in Little Endinan Order, but we need * it in Network Order. */ panid[0] = arg.u.getreq.attrval.mac.panid[1]; panid[1] = arg.u.getreq.attrval.mac.panid[0]; return OK; } #endif /**************************************************************************** * Name: sixlowpan_extract_srcaddr * * Description: * Extract the source MAC address from the radio-specific RX metadata, and * return the source address in a radio-agnostic form. * * Input Parameters: * radio - Reference to a radio network driver state instance. * metadata - Opaque reference to the radio-specific RX metadata. * srcaddr - The location in which to return the source MAC address. * * Returned Value: * Zero (OK) on success; a negated errno value on failure. * ****************************************************************************/ int sixlowpan_extract_srcaddr(FAR struct radio_driver_s *radio, FAR const void *metadata, FAR struct netdev_varaddr_s *srcaddr) { DEBUGASSERT(radio != NULL && metadata != NULL && srcaddr != NULL); #ifdef CONFIG_WIRELESS_IEEE802154 #ifdef CONFIG_WIRELESS_PKTRADIO if (radio->r_dev.d_lltype == NET_LL_IEEE802154) #endif { FAR const struct ieee802154_data_ind_s *ind = (FAR const struct ieee802154_data_ind_s *)metadata; if (ind->src.mode == IEEE802154_ADDRMODE_SHORT) { srcaddr->nv_addrlen = NET_6LOWPAN_SADDRSIZE; /* MAC802154 gives us Short Address in Little Endinan Order, but we * need it in Network Order. */ srcaddr->nv_addr[0] = ind->src.saddr[1]; srcaddr->nv_addr[1] = ind->src.saddr[0]; } else { srcaddr->nv_addrlen = NET_6LOWPAN_EADDRSIZE; memcpy(srcaddr->nv_addr, ind->src.eaddr, NET_6LOWPAN_EADDRSIZE); } return OK; } #endif #ifdef CONFIG_WIRELESS_PKTRADIO #ifdef CONFIG_WIRELESS_IEEE802154 else #endif { FAR const struct pktradio_metadata_s *pktmeta = (FAR const struct pktradio_metadata_s *)metadata; DEBUGASSERT(pktmeta->pm_src.pa_addrlen <= CONFIG_PKTRADIO_ADDRLEN); srcaddr->nv_addrlen = pktmeta->pm_src.pa_addrlen; memcpy(srcaddr->nv_addr, pktmeta->pm_src.pa_addr, pktmeta->pm_src.pa_addrlen); return OK; } #endif return -EINVAL; /* Shouldn't get here */ } /**************************************************************************** * Name: sixlowpan_extract_destaddr * * Description: * Extract the destination MAC address from the radio-specific RX metadata, * and return the destination address in a radio-agnostic form. * * Input Parameters: * radio - Reference to a radio network driver state instance. * metadata - Opaque reference to the radio-specific RX metadata. * destaddr - The location in which to return the destination MAC address. * * Returned Value: * Zero (OK) on success; a negated errno value on failure. * ****************************************************************************/ int sixlowpan_extract_destaddr(FAR struct radio_driver_s *radio, FAR const void *metadata, FAR struct netdev_varaddr_s *destaddr) { DEBUGASSERT(radio != NULL && metadata != NULL && destaddr != NULL); #ifdef CONFIG_WIRELESS_IEEE802154 #ifdef CONFIG_WIRELESS_PKTRADIO if (radio->r_dev.d_lltype == NET_LL_IEEE802154) #endif { FAR const struct ieee802154_data_ind_s *ind = (FAR const struct ieee802154_data_ind_s *)metadata; if (ind->dest.mode == IEEE802154_ADDRMODE_SHORT) { destaddr->nv_addrlen = NET_6LOWPAN_SADDRSIZE; /* MAC802154 gives us Short Address in Little Endinan Order, but we * need it in Network Order. */ destaddr->nv_addr[0] = ind->dest.saddr[1]; destaddr->nv_addr[1] = ind->dest.saddr[0]; } else { destaddr->nv_addrlen = NET_6LOWPAN_EADDRSIZE; memcpy(destaddr->nv_addr, ind->dest.eaddr, NET_6LOWPAN_EADDRSIZE); } return OK; } #endif #ifdef CONFIG_WIRELESS_PKTRADIO #ifdef CONFIG_WIRELESS_IEEE802154 else #endif { FAR const struct pktradio_metadata_s *pktmeta = (FAR const struct pktradio_metadata_s *)metadata; DEBUGASSERT(pktmeta->pm_dest.pa_addrlen <= CONFIG_PKTRADIO_ADDRLEN); destaddr->nv_addrlen = pktmeta->pm_dest.pa_addrlen; memcpy(destaddr->nv_addr, pktmeta->pm_dest.pa_addr, pktmeta->pm_dest.pa_addrlen); return OK; } #endif return -EINVAL; /* Shouldn't get here */ } #endif /* CONFIG_NET_6LOWPAN */