1*10465441SEvalZero /**
2*10465441SEvalZero * @file
3*10465441SEvalZero * 6LowPAN over BLE output for IPv6 (RFC7668).
4*10465441SEvalZero */
5*10465441SEvalZero
6*10465441SEvalZero /*
7*10465441SEvalZero * Copyright (c) 2017 Benjamin Aigner
8*10465441SEvalZero * Copyright (c) 2015 Inico Technologies Ltd. , Author: Ivan Delamer <[email protected]>
9*10465441SEvalZero *
10*10465441SEvalZero * All rights reserved.
11*10465441SEvalZero *
12*10465441SEvalZero * Redistribution and use in source and binary forms, with or without modification,
13*10465441SEvalZero * are permitted provided that the following conditions are met:
14*10465441SEvalZero *
15*10465441SEvalZero * 1. Redistributions of source code must retain the above copyright notice,
16*10465441SEvalZero * this list of conditions and the following disclaimer.
17*10465441SEvalZero * 2. Redistributions in binary form must reproduce the above copyright notice,
18*10465441SEvalZero * this list of conditions and the following disclaimer in the documentation
19*10465441SEvalZero * and/or other materials provided with the distribution.
20*10465441SEvalZero * 3. The name of the author may not be used to endorse or promote products
21*10465441SEvalZero * derived from this software without specific prior written permission.
22*10465441SEvalZero *
23*10465441SEvalZero * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED
24*10465441SEvalZero * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
25*10465441SEvalZero * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT
26*10465441SEvalZero * SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
27*10465441SEvalZero * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT
28*10465441SEvalZero * OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
29*10465441SEvalZero * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
30*10465441SEvalZero * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING
31*10465441SEvalZero * IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY
32*10465441SEvalZero * OF SUCH DAMAGE.
33*10465441SEvalZero *
34*10465441SEvalZero * Author: Benjamin Aigner <[email protected]>
35*10465441SEvalZero *
36*10465441SEvalZero * Based on the original 6lowpan implementation of lwIP ( @see 6lowpan.c)
37*10465441SEvalZero */
38*10465441SEvalZero
39*10465441SEvalZero
40*10465441SEvalZero /**
41*10465441SEvalZero * @defgroup rfc7668if 6LoWPAN over BLE (RFC7668)
42*10465441SEvalZero * @ingroup netifs
43*10465441SEvalZero * This file implements a RFC7668 implementation for 6LoWPAN over
44*10465441SEvalZero * Bluetooth Low Energy. The specification is very similar to 6LoWPAN,
45*10465441SEvalZero * so most of the code is re-used.
46*10465441SEvalZero * Compared to 6LoWPAN, much functionality is already implemented in
47*10465441SEvalZero * lower BLE layers (fragmenting, session management,...).
48*10465441SEvalZero *
49*10465441SEvalZero * Usage:
50*10465441SEvalZero * - add this netif
51*10465441SEvalZero * - don't add IPv4 addresses (no IPv4 support in RFC7668), pass 'NULL','NULL','NULL'
52*10465441SEvalZero * - use the BLE to EUI64 conversation util to create an IPv6 link-local address from the BLE MAC (@ref ble_addr_to_eui64)
53*10465441SEvalZero * - input function: @ref rfc7668_input
54*10465441SEvalZero * - set the link output function, which transmits output data to an established L2CAP channel
55*10465441SEvalZero * - If data arrives (HCI event "L2CAP_DATA_PACKET"):
56*10465441SEvalZero * - allocate a @ref PBUF_RAW buffer
57*10465441SEvalZero * - let the pbuf struct point to the incoming data or copy it to the buffer
58*10465441SEvalZero * - call netif->input
59*10465441SEvalZero *
60*10465441SEvalZero * @todo:
61*10465441SEvalZero * - further testing
62*10465441SEvalZero * - support compression contexts
63*10465441SEvalZero * - support multiple addresses
64*10465441SEvalZero * - support multicast
65*10465441SEvalZero * - support neighbor discovery
66*10465441SEvalZero */
67*10465441SEvalZero
68*10465441SEvalZero
69*10465441SEvalZero #include "netif/lowpan6_ble.h"
70*10465441SEvalZero
71*10465441SEvalZero #if LWIP_IPV6
72*10465441SEvalZero
73*10465441SEvalZero #include "lwip/ip.h"
74*10465441SEvalZero #include "lwip/pbuf.h"
75*10465441SEvalZero #include "lwip/ip_addr.h"
76*10465441SEvalZero #include "lwip/netif.h"
77*10465441SEvalZero #include "lwip/nd6.h"
78*10465441SEvalZero #include "lwip/mem.h"
79*10465441SEvalZero #include "lwip/udp.h"
80*10465441SEvalZero #include "lwip/tcpip.h"
81*10465441SEvalZero #include "lwip/snmp.h"
82*10465441SEvalZero
83*10465441SEvalZero #include <string.h>
84*10465441SEvalZero
85*10465441SEvalZero #if LWIP_6LOWPAN_NUM_CONTEXTS > 0
86*10465441SEvalZero /** context memory, containing IPv6 addresses */
87*10465441SEvalZero static ip6_addr_t rfc7668_context[LWIP_6LOWPAN_NUM_CONTEXTS];
88*10465441SEvalZero #else
89*10465441SEvalZero #define rfc7668_context NULL
90*10465441SEvalZero #endif
91*10465441SEvalZero
92*10465441SEvalZero static struct lowpan6_link_addr rfc7668_local_addr;
93*10465441SEvalZero static struct lowpan6_link_addr rfc7668_peer_addr;
94*10465441SEvalZero
95*10465441SEvalZero /**
96*10465441SEvalZero * @ingroup rfc7668if
97*10465441SEvalZero * convert BT address to EUI64 addr
98*10465441SEvalZero *
99*10465441SEvalZero * This method converts a Bluetooth MAC address to an EUI64 address,
100*10465441SEvalZero * which is used within IPv6 communication
101*10465441SEvalZero *
102*10465441SEvalZero * @param dst IPv6 destination space
103*10465441SEvalZero * @param src BLE MAC address source
104*10465441SEvalZero * @param public_addr If the LWIP_RFC7668_LINUX_WORKAROUND_PUBLIC_ADDRESS
105*10465441SEvalZero * option is set, bit 0x02 will be set if param=0 (no public addr); cleared otherwise
106*10465441SEvalZero *
107*10465441SEvalZero * @see LWIP_RFC7668_LINUX_WORKAROUND_PUBLIC_ADDRESS
108*10465441SEvalZero */
109*10465441SEvalZero void
ble_addr_to_eui64(uint8_t * dst,const uint8_t * src,int public_addr)110*10465441SEvalZero ble_addr_to_eui64(uint8_t *dst, const uint8_t *src, int public_addr)
111*10465441SEvalZero {
112*10465441SEvalZero /* according to RFC7668 ch 3.2.2. */
113*10465441SEvalZero memcpy(dst, src, 3);
114*10465441SEvalZero dst[3] = 0xFF;
115*10465441SEvalZero dst[4] = 0xFE;
116*10465441SEvalZero memcpy(&dst[5], &src[3], 3);
117*10465441SEvalZero #if LWIP_RFC7668_LINUX_WORKAROUND_PUBLIC_ADDRESS
118*10465441SEvalZero if(public_addr) {
119*10465441SEvalZero dst[0] &= ~0x02;
120*10465441SEvalZero } else {
121*10465441SEvalZero dst[0] |= 0x02;
122*10465441SEvalZero }
123*10465441SEvalZero #else
124*10465441SEvalZero LWIP_UNUSED_ARG(public_addr);
125*10465441SEvalZero #endif
126*10465441SEvalZero }
127*10465441SEvalZero
128*10465441SEvalZero /**
129*10465441SEvalZero * @ingroup rfc7668if
130*10465441SEvalZero * convert EUI64 address to Bluetooth MAC addr
131*10465441SEvalZero *
132*10465441SEvalZero * This method converts an EUI64 address to a Bluetooth MAC address,
133*10465441SEvalZero *
134*10465441SEvalZero * @param dst BLE MAC address destination
135*10465441SEvalZero * @param src IPv6 source
136*10465441SEvalZero *
137*10465441SEvalZero */
138*10465441SEvalZero void
eui64_to_ble_addr(uint8_t * dst,const uint8_t * src)139*10465441SEvalZero eui64_to_ble_addr(uint8_t *dst, const uint8_t *src)
140*10465441SEvalZero {
141*10465441SEvalZero /* according to RFC7668 ch 3.2.2. */
142*10465441SEvalZero memcpy(dst,src,3);
143*10465441SEvalZero memcpy(&dst[3],&src[5],3);
144*10465441SEvalZero }
145*10465441SEvalZero
146*10465441SEvalZero /** Set an address used for stateful compression.
147*10465441SEvalZero * This expects an address of 6 or 8 bytes.
148*10465441SEvalZero */
149*10465441SEvalZero static err_t
rfc7668_set_addr(struct lowpan6_link_addr * addr,const u8_t * in_addr,size_t in_addr_len,int is_mac_48,int is_public_addr)150*10465441SEvalZero rfc7668_set_addr(struct lowpan6_link_addr *addr, const u8_t *in_addr, size_t in_addr_len, int is_mac_48, int is_public_addr)
151*10465441SEvalZero {
152*10465441SEvalZero if ((in_addr == NULL) || (addr == NULL)) {
153*10465441SEvalZero return ERR_VAL;
154*10465441SEvalZero }
155*10465441SEvalZero if (is_mac_48) {
156*10465441SEvalZero if (in_addr_len != 6) {
157*10465441SEvalZero return ERR_VAL;
158*10465441SEvalZero }
159*10465441SEvalZero addr->addr_len = 8;
160*10465441SEvalZero ble_addr_to_eui64(addr->addr, in_addr, is_public_addr);
161*10465441SEvalZero } else {
162*10465441SEvalZero if (in_addr_len != 8) {
163*10465441SEvalZero return ERR_VAL;
164*10465441SEvalZero }
165*10465441SEvalZero addr->addr_len = 8;
166*10465441SEvalZero memcpy(addr->addr, in_addr, 8);
167*10465441SEvalZero }
168*10465441SEvalZero return ERR_OK;
169*10465441SEvalZero }
170*10465441SEvalZero
171*10465441SEvalZero
172*10465441SEvalZero /** Set the local address used for stateful compression.
173*10465441SEvalZero * This expects an address of 8 bytes.
174*10465441SEvalZero */
175*10465441SEvalZero err_t
rfc7668_set_local_addr_eui64(struct netif * netif,const u8_t * local_addr,size_t local_addr_len)176*10465441SEvalZero rfc7668_set_local_addr_eui64(struct netif *netif, const u8_t *local_addr, size_t local_addr_len)
177*10465441SEvalZero {
178*10465441SEvalZero /* netif not used for now, the address is stored globally... */
179*10465441SEvalZero LWIP_UNUSED_ARG(netif);
180*10465441SEvalZero return rfc7668_set_addr(&rfc7668_local_addr, local_addr, local_addr_len, 0, 0);
181*10465441SEvalZero }
182*10465441SEvalZero
183*10465441SEvalZero /** Set the local address used for stateful compression.
184*10465441SEvalZero * This expects an address of 6 bytes.
185*10465441SEvalZero */
186*10465441SEvalZero err_t
rfc7668_set_local_addr_mac48(struct netif * netif,const u8_t * local_addr,size_t local_addr_len,int is_public_addr)187*10465441SEvalZero rfc7668_set_local_addr_mac48(struct netif *netif, const u8_t *local_addr, size_t local_addr_len, int is_public_addr)
188*10465441SEvalZero {
189*10465441SEvalZero /* netif not used for now, the address is stored globally... */
190*10465441SEvalZero LWIP_UNUSED_ARG(netif);
191*10465441SEvalZero return rfc7668_set_addr(&rfc7668_local_addr, local_addr, local_addr_len, 1, is_public_addr);
192*10465441SEvalZero }
193*10465441SEvalZero
194*10465441SEvalZero /** Set the peer address used for stateful compression.
195*10465441SEvalZero * This expects an address of 8 bytes.
196*10465441SEvalZero */
197*10465441SEvalZero err_t
rfc7668_set_peer_addr_eui64(struct netif * netif,const u8_t * peer_addr,size_t peer_addr_len)198*10465441SEvalZero rfc7668_set_peer_addr_eui64(struct netif *netif, const u8_t *peer_addr, size_t peer_addr_len)
199*10465441SEvalZero {
200*10465441SEvalZero /* netif not used for now, the address is stored globally... */
201*10465441SEvalZero LWIP_UNUSED_ARG(netif);
202*10465441SEvalZero return rfc7668_set_addr(&rfc7668_peer_addr, peer_addr, peer_addr_len, 0, 0);
203*10465441SEvalZero }
204*10465441SEvalZero
205*10465441SEvalZero /** Set the peer address used for stateful compression.
206*10465441SEvalZero * This expects an address of 6 bytes.
207*10465441SEvalZero */
208*10465441SEvalZero err_t
rfc7668_set_peer_addr_mac48(struct netif * netif,const u8_t * peer_addr,size_t peer_addr_len,int is_public_addr)209*10465441SEvalZero rfc7668_set_peer_addr_mac48(struct netif *netif, const u8_t *peer_addr, size_t peer_addr_len, int is_public_addr)
210*10465441SEvalZero {
211*10465441SEvalZero /* netif not used for now, the address is stored globally... */
212*10465441SEvalZero LWIP_UNUSED_ARG(netif);
213*10465441SEvalZero return rfc7668_set_addr(&rfc7668_peer_addr, peer_addr, peer_addr_len, 1, is_public_addr);
214*10465441SEvalZero }
215*10465441SEvalZero
216*10465441SEvalZero /** Encapsulate IPv6 frames for BLE transmission
217*10465441SEvalZero *
218*10465441SEvalZero * This method implements the IPv6 header compression:
219*10465441SEvalZero * *) According to RFC6282
220*10465441SEvalZero * *) See Figure 2, contains base format of bit positions
221*10465441SEvalZero * *) Fragmentation not necessary (done at L2CAP layer of BLE)
222*10465441SEvalZero * @note Currently the pbuf allocation uses 256 bytes. If longer packets are used (possible due to MTU=1480Bytes), increase it here!
223*10465441SEvalZero *
224*10465441SEvalZero * @param p Pbuf struct, containing the payload data
225*10465441SEvalZero * @param netif Output network interface. Should be of RFC7668 type
226*10465441SEvalZero *
227*10465441SEvalZero * @return Same as netif->output.
228*10465441SEvalZero */
229*10465441SEvalZero static err_t
rfc7668_compress(struct netif * netif,struct pbuf * p)230*10465441SEvalZero rfc7668_compress(struct netif *netif, struct pbuf *p)
231*10465441SEvalZero {
232*10465441SEvalZero struct pbuf *p_frag;
233*10465441SEvalZero u16_t remaining_len;
234*10465441SEvalZero u8_t *buffer;
235*10465441SEvalZero u8_t lowpan6_header_len;
236*10465441SEvalZero u8_t hidden_header_len;
237*10465441SEvalZero err_t err;
238*10465441SEvalZero
239*10465441SEvalZero LWIP_ASSERT("lowpan6_frag: netif->linkoutput not set", netif->linkoutput != NULL);
240*10465441SEvalZero
241*10465441SEvalZero #if LWIP_6LOWPAN_IPHC
242*10465441SEvalZero
243*10465441SEvalZero /* We'll use a dedicated pbuf for building BLE fragments.
244*10465441SEvalZero * We'll over-allocate it by the bytes saved for header compression.
245*10465441SEvalZero */
246*10465441SEvalZero p_frag = pbuf_alloc(PBUF_RAW, p->tot_len, PBUF_RAM);
247*10465441SEvalZero if (p_frag == NULL) {
248*10465441SEvalZero MIB2_STATS_NETIF_INC(netif, ifoutdiscards);
249*10465441SEvalZero return ERR_MEM;
250*10465441SEvalZero }
251*10465441SEvalZero LWIP_ASSERT("this needs a pbuf in one piece", p_frag->len == p_frag->tot_len);
252*10465441SEvalZero
253*10465441SEvalZero /* Write IP6 header (with IPHC). */
254*10465441SEvalZero buffer = (u8_t*)p_frag->payload;
255*10465441SEvalZero
256*10465441SEvalZero err = lowpan6_compress_headers(netif, (u8_t *)p->payload, p->len, buffer, p_frag->len,
257*10465441SEvalZero &lowpan6_header_len, &hidden_header_len, rfc7668_context, &rfc7668_local_addr, &rfc7668_peer_addr);
258*10465441SEvalZero if (err != ERR_OK) {
259*10465441SEvalZero MIB2_STATS_NETIF_INC(netif, ifoutdiscards);
260*10465441SEvalZero pbuf_free(p_frag);
261*10465441SEvalZero return err;
262*10465441SEvalZero }
263*10465441SEvalZero pbuf_remove_header(p, hidden_header_len);
264*10465441SEvalZero
265*10465441SEvalZero /* Calculate remaining packet length */
266*10465441SEvalZero remaining_len = p->tot_len;
267*10465441SEvalZero
268*10465441SEvalZero /* Copy IPv6 packet */
269*10465441SEvalZero pbuf_copy_partial(p, buffer + lowpan6_header_len, remaining_len, 0);
270*10465441SEvalZero
271*10465441SEvalZero /* Calculate frame length */
272*10465441SEvalZero p_frag->len = p_frag->tot_len = remaining_len + lowpan6_header_len;
273*10465441SEvalZero
274*10465441SEvalZero /* send the packet */
275*10465441SEvalZero MIB2_STATS_NETIF_ADD(netif, ifoutoctets, p_frag->tot_len);
276*10465441SEvalZero LWIP_DEBUGF(LWIP_LOWPAN6_DEBUG|LWIP_DBG_TRACE, ("rfc7668_output: sending packet %p\n", (void *)p));
277*10465441SEvalZero err = netif->linkoutput(netif, p_frag);
278*10465441SEvalZero
279*10465441SEvalZero pbuf_free(p_frag);
280*10465441SEvalZero
281*10465441SEvalZero return err;
282*10465441SEvalZero #else /* LWIP_6LOWPAN_IPHC */
283*10465441SEvalZero /* 6LoWPAN over BLE requires IPHC! */
284*10465441SEvalZero return ERR_IF;
285*10465441SEvalZero #endif/* LWIP_6LOWPAN_IPHC */
286*10465441SEvalZero }
287*10465441SEvalZero
288*10465441SEvalZero /**
289*10465441SEvalZero * @ingroup rfc7668if
290*10465441SEvalZero * Set context id IPv6 address
291*10465441SEvalZero *
292*10465441SEvalZero * Store one IPv6 address to a given context id.
293*10465441SEvalZero *
294*10465441SEvalZero * @param idx Context id
295*10465441SEvalZero * @param context IPv6 addr for this context
296*10465441SEvalZero *
297*10465441SEvalZero * @return ERR_OK (if everything is fine), ERR_ARG (if the context id is out of range), ERR_VAL (if contexts disabled)
298*10465441SEvalZero */
299*10465441SEvalZero err_t
rfc7668_set_context(u8_t idx,const ip6_addr_t * context)300*10465441SEvalZero rfc7668_set_context(u8_t idx, const ip6_addr_t *context)
301*10465441SEvalZero {
302*10465441SEvalZero #if LWIP_6LOWPAN_NUM_CONTEXTS > 0
303*10465441SEvalZero /* check if the ID is possible */
304*10465441SEvalZero if (idx >= LWIP_6LOWPAN_NUM_CONTEXTS) {
305*10465441SEvalZero return ERR_ARG;
306*10465441SEvalZero }
307*10465441SEvalZero /* copy IPv6 address to context storage */
308*10465441SEvalZero ip6_addr_set(&rfc7668_context[idx], context);
309*10465441SEvalZero return ERR_OK;
310*10465441SEvalZero #else
311*10465441SEvalZero LWIP_UNUSED_ARG(idx);
312*10465441SEvalZero LWIP_UNUSED_ARG(context);
313*10465441SEvalZero return ERR_VAL;
314*10465441SEvalZero #endif
315*10465441SEvalZero }
316*10465441SEvalZero
317*10465441SEvalZero /**
318*10465441SEvalZero * @ingroup rfc7668if
319*10465441SEvalZero * Compress outgoing IPv6 packet and pass it on to netif->linkoutput
320*10465441SEvalZero *
321*10465441SEvalZero * @param netif The lwIP network interface which the IP packet will be sent on.
322*10465441SEvalZero * @param q The pbuf(s) containing the IP packet to be sent.
323*10465441SEvalZero * @param ip6addr The IP address of the packet destination.
324*10465441SEvalZero *
325*10465441SEvalZero * @return See rfc7668_compress
326*10465441SEvalZero */
327*10465441SEvalZero err_t
rfc7668_output(struct netif * netif,struct pbuf * q,const ip6_addr_t * ip6addr)328*10465441SEvalZero rfc7668_output(struct netif *netif, struct pbuf *q, const ip6_addr_t *ip6addr)
329*10465441SEvalZero {
330*10465441SEvalZero /* dst ip6addr is not used here, we only have one peer */
331*10465441SEvalZero LWIP_UNUSED_ARG(ip6addr);
332*10465441SEvalZero
333*10465441SEvalZero return rfc7668_compress(netif, q);
334*10465441SEvalZero }
335*10465441SEvalZero
336*10465441SEvalZero /**
337*10465441SEvalZero * @ingroup rfc7668if
338*10465441SEvalZero * Process a received raw payload from an L2CAP channel
339*10465441SEvalZero *
340*10465441SEvalZero * @param p the received packet, p->payload pointing to the
341*10465441SEvalZero * IPv6 header (maybe compressed)
342*10465441SEvalZero * @param netif the network interface on which the packet was received
343*10465441SEvalZero *
344*10465441SEvalZero * @return ERR_OK if everything was fine
345*10465441SEvalZero */
346*10465441SEvalZero err_t
rfc7668_input(struct pbuf * p,struct netif * netif)347*10465441SEvalZero rfc7668_input(struct pbuf * p, struct netif *netif)
348*10465441SEvalZero {
349*10465441SEvalZero u8_t * puc;
350*10465441SEvalZero
351*10465441SEvalZero MIB2_STATS_NETIF_ADD(netif, ifinoctets, p->tot_len);
352*10465441SEvalZero
353*10465441SEvalZero /* Load first header byte */
354*10465441SEvalZero puc = (u8_t*)p->payload;
355*10465441SEvalZero
356*10465441SEvalZero /* no IP header compression */
357*10465441SEvalZero if (*puc == 0x41) {
358*10465441SEvalZero LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("Completed packet, removing dispatch: 0x%2x \n", *puc));
359*10465441SEvalZero /* This is a complete IPv6 packet, just skip header byte. */
360*10465441SEvalZero pbuf_remove_header(p, 1);
361*10465441SEvalZero /* IPHC header compression */
362*10465441SEvalZero } else if ((*puc & 0xe0 )== 0x60) {
363*10465441SEvalZero LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("Completed packet, decompress dispatch: 0x%2x \n", *puc));
364*10465441SEvalZero /* IPv6 headers are compressed using IPHC. */
365*10465441SEvalZero p = lowpan6_decompress(p, 0, rfc7668_context, &rfc7668_peer_addr, &rfc7668_local_addr);
366*10465441SEvalZero /* if no pbuf is returned, handle as discarded packet */
367*10465441SEvalZero if (p == NULL) {
368*10465441SEvalZero MIB2_STATS_NETIF_INC(netif, ifindiscards);
369*10465441SEvalZero return ERR_OK;
370*10465441SEvalZero }
371*10465441SEvalZero /* invalid header byte, discard */
372*10465441SEvalZero } else {
373*10465441SEvalZero LWIP_DEBUGF(LWIP_LOWPAN6_DECOMPRESSION_DEBUG, ("Completed packet, discarding: 0x%2x \n", *puc));
374*10465441SEvalZero MIB2_STATS_NETIF_INC(netif, ifindiscards);
375*10465441SEvalZero pbuf_free(p);
376*10465441SEvalZero return ERR_OK;
377*10465441SEvalZero }
378*10465441SEvalZero /* @todo: distinguish unicast/multicast */
379*10465441SEvalZero MIB2_STATS_NETIF_INC(netif, ifinucastpkts);
380*10465441SEvalZero
381*10465441SEvalZero #if LWIP_RFC7668_IP_UNCOMPRESSED_DEBUG
382*10465441SEvalZero {
383*10465441SEvalZero u16_t i;
384*10465441SEvalZero LWIP_DEBUGF(LWIP_RFC7668_IP_UNCOMPRESSED_DEBUG, ("IPv6 payload:\n"));
385*10465441SEvalZero for (i = 0; i < p->len; i++) {
386*10465441SEvalZero if ((i%4)==0) {
387*10465441SEvalZero LWIP_DEBUGF(LWIP_RFC7668_IP_UNCOMPRESSED_DEBUG, ("\n"));
388*10465441SEvalZero }
389*10465441SEvalZero LWIP_DEBUGF(LWIP_RFC7668_IP_UNCOMPRESSED_DEBUG, ("%2X ", *((uint8_t *)p->payload+i)));
390*10465441SEvalZero }
391*10465441SEvalZero LWIP_DEBUGF(LWIP_RFC7668_IP_UNCOMPRESSED_DEBUG, ("\np->len: %d\n", p->len));
392*10465441SEvalZero }
393*10465441SEvalZero #endif
394*10465441SEvalZero /* pass data to ip6_input */
395*10465441SEvalZero return ip6_input(p, netif);
396*10465441SEvalZero }
397*10465441SEvalZero
398*10465441SEvalZero /**
399*10465441SEvalZero * @ingroup rfc7668if
400*10465441SEvalZero * Initialize the netif
401*10465441SEvalZero *
402*10465441SEvalZero * No flags are used (broadcast not possible, not ethernet, ...)
403*10465441SEvalZero * The shortname for this netif is "BT"
404*10465441SEvalZero *
405*10465441SEvalZero * @param netif the network interface to be initialized as RFC7668 netif
406*10465441SEvalZero *
407*10465441SEvalZero * @return ERR_OK if everything went fine
408*10465441SEvalZero */
409*10465441SEvalZero err_t
rfc7668_if_init(struct netif * netif)410*10465441SEvalZero rfc7668_if_init(struct netif *netif)
411*10465441SEvalZero {
412*10465441SEvalZero netif->name[0] = 'b';
413*10465441SEvalZero netif->name[1] = 't';
414*10465441SEvalZero /* local function as IPv6 output */
415*10465441SEvalZero netif->output_ip6 = rfc7668_output;
416*10465441SEvalZero
417*10465441SEvalZero MIB2_INIT_NETIF(netif, snmp_ifType_other, 0);
418*10465441SEvalZero
419*10465441SEvalZero /* maximum transfer unit, set according to RFC7668 ch2.4 */
420*10465441SEvalZero netif->mtu = 1280;
421*10465441SEvalZero
422*10465441SEvalZero /* no flags set (no broadcast, ethernet,...)*/
423*10465441SEvalZero netif->flags = 0;
424*10465441SEvalZero
425*10465441SEvalZero /* everything fine */
426*10465441SEvalZero return ERR_OK;
427*10465441SEvalZero }
428*10465441SEvalZero
429*10465441SEvalZero #if !NO_SYS
430*10465441SEvalZero /**
431*10465441SEvalZero * Pass a received packet to tcpip_thread for input processing
432*10465441SEvalZero *
433*10465441SEvalZero * @param p the received packet, p->payload pointing to the
434*10465441SEvalZero * IEEE 802.15.4 header.
435*10465441SEvalZero * @param inp the network interface on which the packet was received
436*10465441SEvalZero *
437*10465441SEvalZero * @return see @ref tcpip_inpkt, same return values
438*10465441SEvalZero */
439*10465441SEvalZero err_t
tcpip_rfc7668_input(struct pbuf * p,struct netif * inp)440*10465441SEvalZero tcpip_rfc7668_input(struct pbuf *p, struct netif *inp)
441*10465441SEvalZero {
442*10465441SEvalZero /* send data to upper layer, return the result */
443*10465441SEvalZero return tcpip_inpkt(p, inp, rfc7668_input);
444*10465441SEvalZero }
445*10465441SEvalZero #endif /* !NO_SYS */
446*10465441SEvalZero
447*10465441SEvalZero #endif /* LWIP_IPV6 */
448