/** * @file * * Common 6LowPAN routines for IPv6. Uses ND tables for link-layer addressing. Fragments packets to 6LowPAN units. * * This implementation aims to conform to IEEE 802.15.4(-2015), RFC 4944 and RFC 6282. * @todo: RFC 6775. */ /* * Copyright (c) 2015 Inico Technologies Ltd. * All rights reserved. * * 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. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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. * * This file is part of the lwIP TCP/IP stack. * * Author: Ivan Delamer * * * Please coordinate changes and requests with Ivan Delamer * */ /** * @defgroup sixlowpan 6LoWPAN (RFC4944) * @ingroup netifs * 6LowPAN netif implementation */ #include "netif/lowpan6_common.h" #if LWIP_IPV6 #include "lwip/ip.h" #include "lwip/pbuf.h" #include "lwip/ip_addr.h" #include "lwip/netif.h" #include "lwip/udp.h" #include /* Determine compression mode for unicast address. */ s8_t lowpan6_get_address_mode(const ip6_addr_t *ip6addr, const struct lowpan6_link_addr *mac_addr) { if (mac_addr->addr_len == 2) { if ((ip6addr->addr[2] == (u32_t)PP_HTONL(0x000000ff)) && ((ip6addr->addr[3] & PP_HTONL(0xffff0000)) == PP_NTOHL(0xfe000000))) { if ((ip6addr->addr[3] & PP_HTONL(0x0000ffff)) == lwip_ntohl((mac_addr->addr[0] << 8) | mac_addr->addr[1])) { return 3; } } } else if (mac_addr->addr_len == 8) { if ((ip6addr->addr[2] == lwip_ntohl(((mac_addr->addr[0] ^ 2) << 24) | (mac_addr->addr[1] << 16) | mac_addr->addr[2] << 8 | mac_addr->addr[3])) && (ip6addr->addr[3] == lwip_ntohl((mac_addr->addr[4] << 24) | (mac_addr->addr[5] << 16) | mac_addr->addr[6] << 8 | mac_addr->addr[7]))) { return 3; } } if ((ip6addr->addr[2] == PP_HTONL(0x000000ffUL)) && ((ip6addr->addr[3] & PP_HTONL(0xffff0000)) == PP_NTOHL(0xfe000000UL))) { return 2; } return 1; } #if LWIP_6LOWPAN_IPHC /* Determine compression mode for multicast address. */ static s8_t lowpan6_get_address_mode_mc(const ip6_addr_t *ip6addr) { if ((ip6addr->addr[0] == PP_HTONL(0xff020000)) && (ip6addr->addr[1] == 0) && (ip6addr->addr[2] == 0) && ((ip6addr->addr[3] & PP_HTONL(0xffffff00)) == 0)) { return 3; } else if (((ip6addr->addr[0] & PP_HTONL(0xff00ffff)) == PP_HTONL(0xff000000)) && (ip6addr->addr[1] == 0)) { if ((ip6addr->addr[2] == 0) && ((ip6addr->addr[3] & PP_HTONL(0xff000000)) == 0)) { return 2; } else if ((ip6addr->addr[2] & PP_HTONL(0xffffff00)) == 0) { return 1; } } return 0; } #if LWIP_6LOWPAN_NUM_CONTEXTS > 0 static s8_t lowpan6_context_lookup(const ip6_addr_t *lowpan6_contexts, const ip6_addr_t *ip6addr) { s8_t i; for (i = 0; i < LWIP_6LOWPAN_NUM_CONTEXTS; i++) { if (ip6_addr_net_eq(&lowpan6_contexts[i], ip6addr)) { return i; } } return -1; } #endif /* LWIP_6LOWPAN_NUM_CONTEXTS > 0 */ /* * Compress IPv6 and/or UDP headers. * */ err_t lowpan6_compress_headers(struct netif *netif, u8_t *inbuf, size_t inbuf_size, u8_t *outbuf, size_t outbuf_size, u8_t *lowpan6_header_len_out, u8_t *hidden_header_len_out, ip6_addr_t *lowpan6_contexts, const struct lowpan6_link_addr *src, const struct lowpan6_link_addr *dst) { u8_t *buffer, *inptr; u8_t lowpan6_header_len; u8_t hidden_header_len = 0; s8_t i; struct ip6_hdr *ip6hdr; ip_addr_t ip6src, ip6dst; LWIP_ASSERT("netif != NULL", netif != NULL); LWIP_ASSERT("inbuf != NULL", inbuf != NULL); LWIP_ASSERT("outbuf != NULL", outbuf != NULL); LWIP_ASSERT("lowpan6_header_len_out != NULL", lowpan6_header_len_out != NULL); LWIP_ASSERT("hidden_header_len_out != NULL", hidden_header_len_out != NULL); /* Perform 6LowPAN IPv6 header compression according to RFC 6282 */ buffer = outbuf; inptr = inbuf; if (inbuf_size < IP6_HLEN) { /* input buffer too short */ return ERR_VAL; } if (outbuf_size < IP6_HLEN) { /* output buffer too short for worst case */ return ERR_MEM; } /* Point to ip6 header and align copies of src/dest addresses. */ ip6hdr = (struct ip6_hdr *)inptr; ip_addr_copy_from_ip6_packed(ip6dst, ip6hdr->dest); ip6_addr_assign_zone(ip_2_ip6(&ip6dst), IP6_UNKNOWN, netif); ip_addr_copy_from_ip6_packed(ip6src, ip6hdr->src); ip6_addr_assign_zone(ip_2_ip6(&ip6src), IP6_UNKNOWN, netif); /* Basic length of 6LowPAN header, set dispatch and clear fields. */ lowpan6_header_len = 2; buffer[0] = 0x60; buffer[1] = 0; /* Determine whether there will be a Context Identifier Extension byte or not. * If so, set it already. */ #if LWIP_6LOWPAN_NUM_CONTEXTS > 0 buffer[2] = 0; i = lowpan6_context_lookup(lowpan6_contexts, ip_2_ip6(&ip6src)); if (i >= 0) { /* Stateful source address compression. */ buffer[1] |= 0x40; buffer[2] |= (i & 0x0f) << 4; } i = lowpan6_context_lookup(lowpan6_contexts, ip_2_ip6(&ip6dst)); if (i >= 0) { /* Stateful destination address compression. */ buffer[1] |= 0x04; buffer[2] |= i & 0x0f; } if (buffer[2] != 0x00) { /* Context identifier extension byte is appended. */ buffer[1] |= 0x80; lowpan6_header_len++; } #else /* LWIP_6LOWPAN_NUM_CONTEXTS > 0 */ LWIP_UNUSED_ARG(lowpan6_contexts); #endif /* LWIP_6LOWPAN_NUM_CONTEXTS > 0 */ /* Determine TF field: Traffic Class, Flow Label */ if (IP6H_FL(ip6hdr) == 0) { /* Flow label is elided. */ buffer[0] |= 0x10; if (IP6H_TC(ip6hdr) == 0) { /* Traffic class (ECN+DSCP) elided too. */ buffer[0] |= 0x08; } else { /* Traffic class (ECN+DSCP) appended. */ buffer[lowpan6_header_len++] = IP6H_TC(ip6hdr); } } else { if (((IP6H_TC(ip6hdr) & 0x3f) == 0)) { /* DSCP portion of Traffic Class is elided, ECN and FL are appended (3 bytes) */ buffer[0] |= 0x08; buffer[lowpan6_header_len] = IP6H_TC(ip6hdr) & 0xc0; buffer[lowpan6_header_len++] |= (IP6H_FL(ip6hdr) >> 16) & 0x0f; buffer[lowpan6_header_len++] = (IP6H_FL(ip6hdr) >> 8) & 0xff; buffer[lowpan6_header_len++] = IP6H_FL(ip6hdr) & 0xff; } else { /* Traffic class and flow label are appended (4 bytes) */ buffer[lowpan6_header_len++] = IP6H_TC(ip6hdr); buffer[lowpan6_header_len++] = (IP6H_FL(ip6hdr) >> 16) & 0x0f; buffer[lowpan6_header_len++] = (IP6H_FL(ip6hdr) >> 8) & 0xff; buffer[lowpan6_header_len++] = IP6H_FL(ip6hdr) & 0xff; } } /* Compress NH? * Only if UDP for now. @todo support other NH compression. */ if (IP6H_NEXTH(ip6hdr) == IP6_NEXTH_UDP) { buffer[0] |= 0x04; } else { /* append nexth. */ buffer[lowpan6_header_len++] = IP6H_NEXTH(ip6hdr); } /* Compress hop limit? */ if (IP6H_HOPLIM(ip6hdr) == 255) { buffer[0] |= 0x03; } else if (IP6H_HOPLIM(ip6hdr) == 64) { buffer[0] |= 0x02; } else if (IP6H_HOPLIM(ip6hdr) == 1) { buffer[0] |= 0x01; } else { /* append hop limit */ buffer[lowpan6_header_len++] = IP6H_HOPLIM(ip6hdr); } /* Compress source address */ if (((buffer[1] & 0x40) != 0) || (ip6_addr_islinklocal(ip_2_ip6(&ip6src)))) { /* Context-based or link-local source address compression. */ i = lowpan6_get_address_mode(ip_2_ip6(&ip6src), src); buffer[1] |= (i & 0x03) << 4; if (i == 1) { MEMCPY(buffer + lowpan6_header_len, inptr + 16, 8); lowpan6_header_len += 8; } else if (i == 2) { MEMCPY(buffer + lowpan6_header_len, inptr + 22, 2); lowpan6_header_len += 2; } } else if (ip6_addr_isany(ip_2_ip6(&ip6src))) { /* Special case: mark SAC and leave SAM=0 */ buffer[1] |= 0x40; } else { /* Append full address. */ MEMCPY(buffer + lowpan6_header_len, inptr + 8, 16); lowpan6_header_len += 16; } /* Compress destination address */ if (ip6_addr_ismulticast(ip_2_ip6(&ip6dst))) { /* @todo support stateful multicast address compression */ buffer[1] |= 0x08; i = lowpan6_get_address_mode_mc(ip_2_ip6(&ip6dst)); buffer[1] |= i & 0x03; if (i == 0) { MEMCPY(buffer + lowpan6_header_len, inptr + 24, 16); lowpan6_header_len += 16; } else if (i == 1) { buffer[lowpan6_header_len++] = inptr[25]; MEMCPY(buffer + lowpan6_header_len, inptr + 35, 5); lowpan6_header_len += 5; } else if (i == 2) { buffer[lowpan6_header_len++] = inptr[25]; MEMCPY(buffer + lowpan6_header_len, inptr + 37, 3); lowpan6_header_len += 3; } else if (i == 3) { buffer[lowpan6_header_len++] = (inptr)[39]; } } else if (((buffer[1] & 0x04) != 0) || (ip6_addr_islinklocal(ip_2_ip6(&ip6dst)))) { /* Context-based or link-local destination address compression. */ i = lowpan6_get_address_mode(ip_2_ip6(&ip6dst), dst); buffer[1] |= i & 0x03; if (i == 1) { MEMCPY(buffer + lowpan6_header_len, inptr + 32, 8); lowpan6_header_len += 8; } else if (i == 2) { MEMCPY(buffer + lowpan6_header_len, inptr + 38, 2); lowpan6_header_len += 2; } } else { /* Append full address. */ MEMCPY(buffer + lowpan6_header_len, inptr + 24, 16); lowpan6_header_len += 16; } /* Move to payload. */ inptr += IP6_HLEN; hidden_header_len += IP6_HLEN; #if LWIP_UDP /* Compress UDP header? */ if (IP6H_NEXTH(ip6hdr) == IP6_NEXTH_UDP) { /* @todo support optional checksum compression */ if (inbuf_size < IP6_HLEN + UDP_HLEN) { /* input buffer too short */ return ERR_VAL; } if (outbuf_size < (size_t)(hidden_header_len + 7)) { /* output buffer too short for worst case */ return ERR_MEM; } buffer[lowpan6_header_len] = 0xf0; /* determine port compression mode. */ if ((inptr[0] == 0xf0) && ((inptr[1] & 0xf0) == 0xb0) && (inptr[2] == 0xf0) && ((inptr[3] & 0xf0) == 0xb0)) { /* Compress source and dest ports. */ buffer[lowpan6_header_len++] |= 0x03; buffer[lowpan6_header_len++] = ((inptr[1] & 0x0f) << 4) | (inptr[3] & 0x0f); } else if (inptr[0] == 0xf0) { /* Compress source port. */ buffer[lowpan6_header_len++] |= 0x02; buffer[lowpan6_header_len++] = inptr[1]; buffer[lowpan6_header_len++] = inptr[2]; buffer[lowpan6_header_len++] = inptr[3]; } else if (inptr[2] == 0xf0) { /* Compress dest port. */ buffer[lowpan6_header_len++] |= 0x01; buffer[lowpan6_header_len++] = inptr[0]; buffer[lowpan6_header_len++] = inptr[1]; buffer[lowpan6_header_len++] = inptr[3]; } else { /* append full ports. */ lowpan6_header_len++; buffer[lowpan6_header_len++] = inptr[0]; buffer[lowpan6_header_len++] = inptr[1]; buffer[lowpan6_header_len++] = inptr[2]; buffer[lowpan6_header_len++] = inptr[3]; } /* elide length and copy checksum */ buffer[lowpan6_header_len++] = inptr[6]; buffer[lowpan6_header_len++] = inptr[7]; hidden_header_len += UDP_HLEN; } #endif /* LWIP_UDP */ *lowpan6_header_len_out = lowpan6_header_len; *hidden_header_len_out = hidden_header_len; return ERR_OK; } /** Decompress IPv6 and UDP headers compressed according to RFC 6282 * * @param lowpan6_buffer compressed headers, first byte is the dispatch byte * @param lowpan6_bufsize size of lowpan6_buffer (may include data after headers) * @param decomp_buffer buffer where the decompressed headers are stored * @param decomp_bufsize size of decomp_buffer * @param hdr_size_comp returns the size of the compressed headers (skip to get to data) * @param hdr_size_decomp returns the size of the decompressed headers (IPv6 + UDP) * @param datagram_size datagram size from fragments or 0 if unfragmented * @param compressed_size compressed datagram size (for unfragmented rx) * @param lowpan6_contexts context addresses * @param src source address of the outer layer, used for address compression * @param dest destination address of the outer layer, used for address compression * @return ERR_OK if decompression succeeded, an error otherwise */ static err_t lowpan6_decompress_hdr(u8_t *lowpan6_buffer, size_t lowpan6_bufsize, u8_t *decomp_buffer, size_t decomp_bufsize, u16_t *hdr_size_comp, u16_t *hdr_size_decomp, u16_t datagram_size, u16_t compressed_size, ip6_addr_t *lowpan6_contexts, struct lowpan6_link_addr *src, struct lowpan6_link_addr *dest) { u16_t lowpan6_offset; struct ip6_hdr *ip6hdr; s8_t i; u32_t header_temp; u16_t ip6_offset = IP6_HLEN; LWIP_ASSERT("lowpan6_buffer != NULL", lowpan6_buffer != NULL); LWIP_ASSERT("decomp_buffer != NULL", decomp_buffer != NULL); LWIP_ASSERT("src != NULL", src != NULL); LWIP_ASSERT("dest != NULL", dest != NULL); LWIP_ASSERT("hdr_size_comp != NULL", hdr_size_comp != NULL); LWIP_ASSERT("dehdr_size_decompst != NULL", hdr_size_decomp != NULL); ip6hdr = (struct ip6_hdr *)decomp_buffer; if (decomp_bufsize < IP6_HLEN) { return ERR_MEM; } /* output the full compressed packet, if set in @see lowpan6_opts.h */ #if LWIP_LOWPAN6_IP_COMPRESSED_DEBUG { u16_t j; LWIP_DEBUGF(LWIP_LOWPAN6_IP_COMPRESSED_DEBUG, ("lowpan6_decompress_hdr: IP6 payload (compressed): \n")); for (j = 0; j < lowpan6_bufsize; j++) { if ((j % 4) == 0) { LWIP_DEBUGF(LWIP_LOWPAN6_IP_COMPRESSED_DEBUG, ("\n")); } LWIP_DEBUGF(LWIP_LOWPAN6_IP_COMPRESSED_DEBUG, ("%2X ", lowpan6_buffer[j])); } LWIP_DEBUGF(LWIP_LOWPAN6_IP_COMPRESSED_DEBUG, ("\np->len: %d", lowpan6_bufsize)); } #endif /* offset for inline IP headers (RFC 6282 ch3)*/ lowpan6_offset = 2; /* if CID is set (context identifier), the context byte * follows immediately after the header, so other IPHC fields are @+3 */ if (lowpan6_buffer[1] & 0x80) { lowpan6_offset++; } /* Set IPv6 version, traffic class and flow label. (RFC6282, ch 3.1.1.)*/ if ((lowpan6_buffer[0] & 0x18) == 0x00) { header_temp = ((lowpan6_buffer[lowpan6_offset+1] & 0x0f) << 16) | \ (lowpan6_buffer[lowpan6_offset + 2] << 8) | lowpan6_buffer[lowpan6_offset+3]; LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("TF: 00, ECN: 0x%"X8_F", Flowlabel+DSCP: 0x%8"X32_F"\n", \ lowpan6_buffer[lowpan6_offset],header_temp)); IP6H_VTCFL_SET(ip6hdr, 6, lowpan6_buffer[lowpan6_offset], header_temp); /* increase offset, processed 4 bytes here: * TF=00: ECN + DSCP + 4-bit Pad + Flow Label (4 bytes)*/ lowpan6_offset += 4; } else if ((lowpan6_buffer[0] & 0x18) == 0x08) { header_temp = ((lowpan6_buffer[lowpan6_offset] & 0x0f) << 16) | (lowpan6_buffer[lowpan6_offset + 1] << 8) | lowpan6_buffer[lowpan6_offset+2]; LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("TF: 01, ECN: 0x%"X8_F", Flowlabel: 0x%2"X32_F", DSCP ignored\n", \ lowpan6_buffer[lowpan6_offset] & 0xc0,header_temp)); IP6H_VTCFL_SET(ip6hdr, 6, lowpan6_buffer[lowpan6_offset] & 0xc0, header_temp); /* increase offset, processed 3 bytes here: * TF=01: ECN + 2-bit Pad + Flow Label (3 bytes), DSCP is elided.*/ lowpan6_offset += 3; } else if ((lowpan6_buffer[0] & 0x18) == 0x10) { LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("TF: 10, DCSP+ECN: 0x%"X8_F", Flowlabel ignored\n", lowpan6_buffer[lowpan6_offset])); IP6H_VTCFL_SET(ip6hdr, 6, lowpan6_buffer[lowpan6_offset],0); /* increase offset, processed 1 byte here: * ECN + DSCP (1 byte), Flow Label is elided.*/ lowpan6_offset += 1; } else if ((lowpan6_buffer[0] & 0x18) == 0x18) { LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("TF: 11, DCSP/ECN & Flowlabel ignored\n")); /* don't increase offset, no bytes processed here */ IP6H_VTCFL_SET(ip6hdr, 6, 0, 0); } /* Set Next Header (NH) */ if ((lowpan6_buffer[0] & 0x04) == 0x00) { /* 0: full next header byte carried inline (increase offset)*/ LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("NH: 0x%2X\n", lowpan6_buffer[lowpan6_offset+1])); IP6H_NEXTH_SET(ip6hdr, lowpan6_buffer[lowpan6_offset++]); } else { /* 1: NH compression, LOWPAN_NHC (RFC6282, ch 4.1) */ /* We should fill this later with NHC decoding */ LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("NH: skipped, later done with NHC\n")); IP6H_NEXTH_SET(ip6hdr, 0); } /* Set Hop Limit, either carried inline or 3 different hops (1,64,255) */ if ((lowpan6_buffer[0] & 0x03) == 0x00) { LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("Hops: full value: %d\n", lowpan6_buffer[lowpan6_offset+1])); IP6H_HOPLIM_SET(ip6hdr, lowpan6_buffer[lowpan6_offset++]); } else if ((lowpan6_buffer[0] & 0x03) == 0x01) { LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("Hops: compressed: 1\n")); IP6H_HOPLIM_SET(ip6hdr, 1); } else if ((lowpan6_buffer[0] & 0x03) == 0x02) { LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("Hops: compressed: 64\n")); IP6H_HOPLIM_SET(ip6hdr, 64); } else if ((lowpan6_buffer[0] & 0x03) == 0x03) { LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("Hops: compressed: 255\n")); IP6H_HOPLIM_SET(ip6hdr, 255); } /* Source address decoding. */ if ((lowpan6_buffer[1] & 0x40) == 0x00) { /* Source address compression (SAC) = 0 -> stateless compression */ LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("SAC == 0, no context byte\n")); /* Stateless compression */ if ((lowpan6_buffer[1] & 0x30) == 0x00) { LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("SAM == 00, no src compression, fetching 128bits inline\n")); /* copy full address, increase offset by 16 Bytes */ MEMCPY(&ip6hdr->src.addr[0], lowpan6_buffer + lowpan6_offset, 16); lowpan6_offset += 16; } else if ((lowpan6_buffer[1] & 0x30) == 0x10) { LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("SAM == 01, src compression, 64bits inline\n")); /* set 64 bits to link local */ ip6hdr->src.addr[0] = PP_HTONL(0xfe800000UL); ip6hdr->src.addr[1] = 0; /* copy 8 Bytes, increase offset */ MEMCPY(&ip6hdr->src.addr[2], lowpan6_buffer + lowpan6_offset, 8); lowpan6_offset += 8; } else if ((lowpan6_buffer[1] & 0x30) == 0x20) { LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("SAM == 10, src compression, 16bits inline\n")); /* set 96 bits to link local */ ip6hdr->src.addr[0] = PP_HTONL(0xfe800000UL); ip6hdr->src.addr[1] = 0; ip6hdr->src.addr[2] = PP_HTONL(0x000000ffUL); /* extract remaining 16bits from inline bytes, increase offset */ ip6hdr->src.addr[3] = lwip_htonl(0xfe000000UL | (lowpan6_buffer[lowpan6_offset] << 8) | lowpan6_buffer[lowpan6_offset + 1]); lowpan6_offset += 2; } else if ((lowpan6_buffer[1] & 0x30) == 0x30) { LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("SAM == 11, src compression, 0bits inline, using other headers\n")); /* no information available, using other layers, see RFC6282 ch 3.2.2 */ ip6hdr->src.addr[0] = PP_HTONL(0xfe800000UL); ip6hdr->src.addr[1] = 0; if (src->addr_len == 2) { ip6hdr->src.addr[2] = PP_HTONL(0x000000ffUL); ip6hdr->src.addr[3] = lwip_htonl(0xfe000000UL | (src->addr[0] << 8) | src->addr[1]); } else if (src->addr_len == 8) { ip6hdr->src.addr[2] = lwip_htonl(((src->addr[0] ^ 2) << 24) | (src->addr[1] << 16) | (src->addr[2] << 8) | src->addr[3]); ip6hdr->src.addr[3] = lwip_htonl((src->addr[4] << 24) | (src->addr[5] << 16) | (src->addr[6] << 8) | src->addr[7]); } else { /* invalid source address length */ LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("Invalid source address length\n")); return ERR_VAL; } } } else { /* Source address compression (SAC) = 1 -> stateful/context-based compression */ LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("SAC == 1, additional context byte\n")); if ((lowpan6_buffer[1] & 0x30) == 0x00) { /* SAM=00, address=> :: (ANY) */ ip6hdr->src.addr[0] = 0; ip6hdr->src.addr[1] = 0; ip6hdr->src.addr[2] = 0; ip6hdr->src.addr[3] = 0; LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("SAM == 00, context compression, ANY (::)\n")); } else { /* Set prefix from context info */ if (lowpan6_buffer[1] & 0x80) { i = (lowpan6_buffer[2] >> 4) & 0x0f; } else { i = 0; } if (i >= LWIP_6LOWPAN_NUM_CONTEXTS) { /* Error */ return ERR_VAL; } #if LWIP_6LOWPAN_NUM_CONTEXTS > 0 ip6hdr->src.addr[0] = lowpan6_contexts[i].addr[0]; ip6hdr->src.addr[1] = lowpan6_contexts[i].addr[1]; LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("SAM == xx, context compression found @%d: %8"X32_F", %8"X32_F"\n", (int)i, ip6hdr->src.addr[0], ip6hdr->src.addr[1])); #else LWIP_UNUSED_ARG(lowpan6_contexts); #endif } /* determine further address bits */ if ((lowpan6_buffer[1] & 0x30) == 0x10) { /* SAM=01, load additional 64bits */ MEMCPY(&ip6hdr->src.addr[2], lowpan6_buffer + lowpan6_offset, 8); LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("SAM == 01, context compression, 64bits inline\n")); lowpan6_offset += 8; } else if ((lowpan6_buffer[1] & 0x30) == 0x20) { /* SAM=01, load additional 16bits */ ip6hdr->src.addr[2] = PP_HTONL(0x000000ffUL); ip6hdr->src.addr[3] = lwip_htonl(0xfe000000UL | (lowpan6_buffer[lowpan6_offset] << 8) | lowpan6_buffer[lowpan6_offset + 1]); LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("SAM == 10, context compression, 16bits inline\n")); lowpan6_offset += 2; } else if ((lowpan6_buffer[1] & 0x30) == 0x30) { /* SAM=11, address is fully elided, load from other layers */ LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("SAM == 11, context compression, 0bits inline, using other headers\n")); if (src->addr_len == 2) { ip6hdr->src.addr[2] = PP_HTONL(0x000000ffUL); ip6hdr->src.addr[3] = lwip_htonl(0xfe000000UL | (src->addr[0] << 8) | src->addr[1]); } else if (src->addr_len == 8) { ip6hdr->src.addr[2] = lwip_htonl(((src->addr[0] ^ 2) << 24) | (src->addr[1] << 16) | (src->addr[2] << 8) | src->addr[3]); ip6hdr->src.addr[3] = lwip_htonl((src->addr[4] << 24) | (src->addr[5] << 16) | (src->addr[6] << 8) | src->addr[7]); } else { /* invalid source address length */ LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("Invalid source address length\n")); return ERR_VAL; } } } /* Destination address decoding. */ if (lowpan6_buffer[1] & 0x08) { LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("M=1: multicast\n")); /* Multicast destination */ if (lowpan6_buffer[1] & 0x04) { LWIP_DEBUGF(LWIP_DBG_ON,("DAC == 1, context multicast: unsupported!!!\n")); /* @todo support stateful multicast addressing */ return ERR_VAL; } if ((lowpan6_buffer[1] & 0x03) == 0x00) { /* DAM = 00, copy full address (128bits) */ LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("DAM == 00, no dst compression, fetching 128bits inline\n")); MEMCPY(&ip6hdr->dest.addr[0], lowpan6_buffer + lowpan6_offset, 16); lowpan6_offset += 16; } else if ((lowpan6_buffer[1] & 0x03) == 0x01) { /* DAM = 01, copy 4 bytes (32bits) */ LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("DAM == 01, dst address form (48bits): ffXX::00XX:XXXX:XXXX\n")); ip6hdr->dest.addr[0] = lwip_htonl(0xff000000UL | (lowpan6_buffer[lowpan6_offset++] << 16)); ip6hdr->dest.addr[1] = 0; ip6hdr->dest.addr[2] = lwip_htonl(lowpan6_buffer[lowpan6_offset++]); ip6hdr->dest.addr[3] = lwip_htonl((lowpan6_buffer[lowpan6_offset] << 24) | (lowpan6_buffer[lowpan6_offset + 1] << 16) | (lowpan6_buffer[lowpan6_offset + 2] << 8) | lowpan6_buffer[lowpan6_offset + 3]); lowpan6_offset += 4; } else if ((lowpan6_buffer[1] & 0x03) == 0x02) { /* DAM = 10, copy 3 bytes (24bits) */ LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("DAM == 10, dst address form (32bits): ffXX::00XX:XXXX\n")); ip6hdr->dest.addr[0] = lwip_htonl(0xff000000UL | (lowpan6_buffer[lowpan6_offset++] << 16)); ip6hdr->dest.addr[1] = 0; ip6hdr->dest.addr[2] = 0; ip6hdr->dest.addr[3] = lwip_htonl((lowpan6_buffer[lowpan6_offset] << 16) | (lowpan6_buffer[lowpan6_offset + 1] << 8) | lowpan6_buffer[lowpan6_offset + 2]); lowpan6_offset += 3; } else if ((lowpan6_buffer[1] & 0x03) == 0x03) { /* DAM = 11, copy 1 byte (8bits) */ LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("DAM == 11, dst address form (8bits): ff02::00XX\n")); ip6hdr->dest.addr[0] = PP_HTONL(0xff020000UL); ip6hdr->dest.addr[1] = 0; ip6hdr->dest.addr[2] = 0; ip6hdr->dest.addr[3] = lwip_htonl(lowpan6_buffer[lowpan6_offset++]); } } else { /* no Multicast (M=0) */ if (lowpan6_buffer[1] & 0x04) { LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("DAC == 1, stateful compression\n")); /* Stateful destination compression */ /* Set prefix from context info */ if (lowpan6_buffer[1] & 0x80) { i = lowpan6_buffer[2] & 0x0f; } else { i = 0; } if (i >= LWIP_6LOWPAN_NUM_CONTEXTS) { /* Error */ return ERR_VAL; } #if LWIP_6LOWPAN_NUM_CONTEXTS > 0 ip6hdr->dest.addr[0] = lowpan6_contexts[i].addr[0]; ip6hdr->dest.addr[1] = lowpan6_contexts[i].addr[1]; #endif } else { LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("DAC == 0, stateless compression, setting link local prefix\n")); /* Link local address compression */ ip6hdr->dest.addr[0] = PP_HTONL(0xfe800000UL); ip6hdr->dest.addr[1] = 0; } /* M=0, DAC=0, determining destination address length via DAM=xx */ if ((lowpan6_buffer[1] & 0x03) == 0x00) { LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("DAM == 00, no dst compression, fetching 128bits inline")); /* DAM=00, copy full address */ MEMCPY(&ip6hdr->dest.addr[0], lowpan6_buffer + lowpan6_offset, 16); lowpan6_offset += 16; } else if ((lowpan6_buffer[1] & 0x03) == 0x01) { LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("DAM == 01, dst compression, 64bits inline\n")); /* DAM=01, copy 64 inline bits, increase offset */ MEMCPY(&ip6hdr->dest.addr[2], lowpan6_buffer + lowpan6_offset, 8); lowpan6_offset += 8; } else if ((lowpan6_buffer[1] & 0x03) == 0x02) { LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("DAM == 01, dst compression, 16bits inline\n")); /* DAM=10, copy 16 inline bits, increase offset */ ip6hdr->dest.addr[2] = PP_HTONL(0x000000ffUL); ip6hdr->dest.addr[3] = lwip_htonl(0xfe000000UL | (lowpan6_buffer[lowpan6_offset] << 8) | lowpan6_buffer[lowpan6_offset + 1]); lowpan6_offset += 2; } else if ((lowpan6_buffer[1] & 0x03) == 0x03) { /* DAM=11, no bits available, use other headers (not done here) */ LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG,("DAM == 01, dst compression, 0bits inline, using other headers\n")); if (dest->addr_len == 2) { ip6hdr->dest.addr[2] = PP_HTONL(0x000000ffUL); ip6hdr->dest.addr[3] = lwip_htonl(0xfe000000UL | (dest->addr[0] << 8) | dest->addr[1]); } else if (dest->addr_len == 8) { ip6hdr->dest.addr[2] = lwip_htonl(((dest->addr[0] ^ 2) << 24) | (dest->addr[1] << 16) | dest->addr[2] << 8 | dest->addr[3]); ip6hdr->dest.addr[3] = lwip_htonl((dest->addr[4] << 24) | (dest->addr[5] << 16) | dest->addr[6] << 8 | dest->addr[7]); } else { /* invalid destination address length */ LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("Invalid destination address length\n")); return ERR_VAL; } } } /* Next Header Compression (NHC) decoding? */ if (lowpan6_buffer[0] & 0x04) { LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("NHC decoding\n")); #if LWIP_UDP if ((lowpan6_buffer[lowpan6_offset] & 0xf8) == 0xf0) { /* NHC: UDP */ struct udp_hdr *udphdr; LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("NHC: UDP\n")); /* UDP compression */ IP6H_NEXTH_SET(ip6hdr, IP6_NEXTH_UDP); udphdr = (struct udp_hdr *)((u8_t *)decomp_buffer + ip6_offset); if (decomp_bufsize < IP6_HLEN + UDP_HLEN) { return ERR_MEM; } /* Checksum decompression */ if (lowpan6_buffer[lowpan6_offset] & 0x04) { /* @todo support checksum decompress */ LWIP_DEBUGF(LWIP_DBG_ON, ("NHC: UDP chechsum decompression UNSUPPORTED\n")); return ERR_VAL; } /* Decompress ports, according to RFC4944 */ i = lowpan6_buffer[lowpan6_offset++] & 0x03; if (i == 0) { udphdr->src = lwip_htons(lowpan6_buffer[lowpan6_offset] << 8 | lowpan6_buffer[lowpan6_offset + 1]); udphdr->dest = lwip_htons(lowpan6_buffer[lowpan6_offset + 2] << 8 | lowpan6_buffer[lowpan6_offset + 3]); lowpan6_offset += 4; } else if (i == 0x01) { udphdr->src = lwip_htons(lowpan6_buffer[lowpan6_offset] << 8 | lowpan6_buffer[lowpan6_offset + 1]); udphdr->dest = lwip_htons(0xf000 | lowpan6_buffer[lowpan6_offset + 2]); lowpan6_offset += 3; } else if (i == 0x02) { udphdr->src = lwip_htons(0xf000 | lowpan6_buffer[lowpan6_offset]); udphdr->dest = lwip_htons(lowpan6_buffer[lowpan6_offset + 1] << 8 | lowpan6_buffer[lowpan6_offset + 2]); lowpan6_offset += 3; } else if (i == 0x03) { udphdr->src = lwip_htons(0xf0b0 | ((lowpan6_buffer[lowpan6_offset] >> 4) & 0x0f)); udphdr->dest = lwip_htons(0xf0b0 | (lowpan6_buffer[lowpan6_offset] & 0x0f)); lowpan6_offset += 1; } udphdr->chksum = lwip_htons(lowpan6_buffer[lowpan6_offset] << 8 | lowpan6_buffer[lowpan6_offset + 1]); lowpan6_offset += 2; ip6_offset += UDP_HLEN; if (datagram_size == 0) { datagram_size = compressed_size - lowpan6_offset + ip6_offset; } udphdr->len = lwip_htons(datagram_size - IP6_HLEN); } else #endif /* LWIP_UDP */ { LWIP_DEBUGF(LWIP_DBG_ON,("NHC: unsupported protocol!\n")); /* @todo support NHC other than UDP */ return ERR_VAL; } } if (datagram_size == 0) { datagram_size = compressed_size - lowpan6_offset + ip6_offset; } /* Infer IPv6 payload length for header */ IP6H_PLEN_SET(ip6hdr, datagram_size - IP6_HLEN); if (lowpan6_offset > lowpan6_bufsize) { /* input buffer overflow */ return ERR_VAL; } *hdr_size_comp = lowpan6_offset; *hdr_size_decomp = ip6_offset; return ERR_OK; } struct pbuf * lowpan6_decompress(struct pbuf *p, u16_t datagram_size, ip6_addr_t *lowpan6_contexts, struct lowpan6_link_addr *src, struct lowpan6_link_addr *dest) { struct pbuf *q; u16_t lowpan6_offset, ip6_offset; err_t err; #if LWIP_UDP #define UDP_HLEN_ALLOC UDP_HLEN #else #define UDP_HLEN_ALLOC 0 #endif /* Allocate a buffer for decompression. This buffer will be too big and will be trimmed once the final size is known. */ q = pbuf_alloc(PBUF_IP, p->len + IP6_HLEN + UDP_HLEN_ALLOC, PBUF_POOL); if (q == NULL) { pbuf_free(p); return NULL; } if (q->len < IP6_HLEN + UDP_HLEN_ALLOC) { /* The headers need to fit into the first pbuf */ pbuf_free(p); pbuf_free(q); return NULL; } /* Decompress the IPv6 (and possibly UDP) header(s) into the new pbuf */ err = lowpan6_decompress_hdr((u8_t *)p->payload, p->len, (u8_t *)q->payload, q->len, &lowpan6_offset, &ip6_offset, datagram_size, p->tot_len, lowpan6_contexts, src, dest); if (err != ERR_OK) { pbuf_free(p); pbuf_free(q); return NULL; } /* Now we copy leftover contents from p to q, so we have all L2 and L3 headers (and L4?) in a single pbuf: */ /* Hide the compressed headers in p */ pbuf_remove_header(p, lowpan6_offset); /* Temporarily hide the headers in q... */ pbuf_remove_header(q, ip6_offset); /* ... copy the rest of p into q... */ pbuf_copy(q, p); /* ... and reveal the headers again... */ pbuf_add_header_force(q, ip6_offset); /* ... trim the pbuf to its correct size... */ pbuf_realloc(q, ip6_offset + p->len); /* ... and cat possibly remaining (data-only) pbufs */ if (p->next != NULL) { pbuf_cat(q, p->next); } /* the original (first) pbuf can now be freed */ p->next = NULL; pbuf_free(p); /* all done */ return q; } #endif /* LWIP_6LOWPAN_IPHC */ #endif /* LWIP_IPV6 */