/* * * Copyright (c) 2008, Swedish Institute of Computer Science * All rights reserved. * * Additional fixes for AVR contributed by: * * Colin O'Flynn coflynn@newae.com * Eric Gnoske egnoske@gmail.com * Blake Leverett bleverett@gmail.com * Mike Vidales mavida404@gmail.com * Kevin Brown kbrown3@uccs.edu * Nate Bohlmann nate@elfwerks.com * * Additional fixes for MSP430 contributed by: * Joakim Eriksson * Niclas Finne * Nicolas Tsiftes * * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 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. * * Neither the name of the copyright holders nor the names of * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS 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 COPYRIGHT OWNER 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. * */ /* * \brief This file is where the main functions that relate to frame * manipulation will reside. */ /** * \file * \brief 802.15.4 frame creation and parsing functions * * This file converts to and from a structure to a packed 802.15.4 * frame. */ /** * \addtogroup frame802154 * @{ */ #include "sys/cc.h" #include "net/mac/frame802154.h" #include "net/llsec/llsec802154.h" #include "net/linkaddr.h" #include /** \brief The 16-bit identifier of the PAN on which the device is * operating. If this value is 0xffff, the device is not * associated. */ static uint16_t mac_pan_id = IEEE802154_PANID; /** * \brief Structure that contains the lengths of the various addressing and security fields * in the 802.15.4 header. This structure is used in \ref frame802154_create() */ typedef struct { uint8_t seqno_len; /**< Length (in bytes) of sequence number field */ uint8_t dest_pid_len; /**< Length (in bytes) of destination PAN ID field */ uint8_t dest_addr_len; /**< Length (in bytes) of destination address field */ uint8_t src_pid_len; /**< Length (in bytes) of source PAN ID field */ uint8_t src_addr_len; /**< Length (in bytes) of source address field */ uint8_t aux_sec_len; /**< Length (in bytes) of aux security header field */ } field_length_t; /*----------------------------------------------------------------------------*/ CC_INLINE static uint8_t addr_len(uint8_t mode) { switch(mode) { case FRAME802154_SHORTADDRMODE: /* 16-bit address */ return 2; case FRAME802154_LONGADDRMODE: /* 64-bit address */ return 8; default: return 0; } } /*----------------------------------------------------------------------------*/ #if LLSEC802154_USES_AUX_HEADER && LLSEC802154_USES_EXPLICIT_KEYS static uint8_t get_key_id_len(uint8_t key_id_mode) { switch(key_id_mode) { case FRAME802154_1_BYTE_KEY_ID_MODE: return 1; case FRAME802154_5_BYTE_KEY_ID_MODE: return 5; case FRAME802154_9_BYTE_KEY_ID_MODE: return 9; default: return 0; } } #endif /* LLSEC802154_USES_AUX_HEADER && LLSEC802154_USES_EXPLICIT_KEYS */ /*---------------------------------------------------------------------------*/ /* Get current PAN ID */ uint16_t frame802154_get_pan_id(void) { return mac_pan_id; } /*---------------------------------------------------------------------------*/ /* Set current PAN ID */ void frame802154_set_pan_id(uint16_t pan_id) { mac_pan_id = pan_id; } /*----------------------------------------------------------------------------*/ /* Tells whether a given Frame Control Field indicates a frame with * source PANID and/or destination PANID */ void frame802154_has_panid(frame802154_fcf_t *fcf, int *has_src_pan_id, int *has_dest_pan_id) { int src_pan_id = 0; int dest_pan_id = 0; if(fcf == NULL) { return; } if(fcf->frame_version == FRAME802154_IEEE802154E_2012) { /* * IEEE 802.15.4-2015 * Table 7-2, PAN ID Compression value for frame version 0b10 */ if((fcf->dest_addr_mode == FRAME802154_NOADDR && fcf->src_addr_mode == FRAME802154_NOADDR && fcf->panid_compression == 1) || (fcf->dest_addr_mode != FRAME802154_NOADDR && fcf->src_addr_mode == FRAME802154_NOADDR && fcf->panid_compression == 0) || (fcf->dest_addr_mode == FRAME802154_LONGADDRMODE && fcf->src_addr_mode == FRAME802154_LONGADDRMODE && fcf->panid_compression == 0) || ((fcf->dest_addr_mode == FRAME802154_SHORTADDRMODE && fcf->src_addr_mode != FRAME802154_NOADDR) || (fcf->dest_addr_mode != FRAME802154_NOADDR && fcf->src_addr_mode == FRAME802154_SHORTADDRMODE)) ){ dest_pan_id = 1; } if(fcf->panid_compression == 0 && ((fcf->dest_addr_mode == FRAME802154_NOADDR && fcf->src_addr_mode == FRAME802154_LONGADDRMODE) || (fcf->dest_addr_mode == FRAME802154_NOADDR && fcf->src_addr_mode == FRAME802154_SHORTADDRMODE) || (fcf->dest_addr_mode == FRAME802154_SHORTADDRMODE && fcf->src_addr_mode == FRAME802154_SHORTADDRMODE) || (fcf->dest_addr_mode == FRAME802154_SHORTADDRMODE && fcf->src_addr_mode == FRAME802154_LONGADDRMODE) || (fcf->dest_addr_mode == FRAME802154_LONGADDRMODE && fcf->src_addr_mode == FRAME802154_SHORTADDRMODE))) { src_pan_id = 1; } } else { /* No PAN ID in ACK */ if(fcf->frame_type != FRAME802154_ACKFRAME) { if(!fcf->panid_compression && fcf->src_addr_mode & 3) { /* If compressed, don't include source PAN ID */ src_pan_id = 1; } if(fcf->dest_addr_mode & 3) { dest_pan_id = 1; } } } if(has_src_pan_id != NULL) { *has_src_pan_id = src_pan_id; } if(has_dest_pan_id != NULL) { *has_dest_pan_id = dest_pan_id; } } /*---------------------------------------------------------------------------*/ /* Check if the destination PAN ID, if any, matches ours */ int frame802154_check_dest_panid(frame802154_t *frame) { int has_dest_panid; if(frame == NULL) { return 0; } frame802154_has_panid(&frame->fcf, NULL, &has_dest_panid); if(has_dest_panid && frame->dest_pid != frame802154_get_pan_id() && frame->dest_pid != FRAME802154_BROADCASTPANDID) { /* Packet to another PAN */ return 0; } return 1; } /*---------------------------------------------------------------------------*/ /* Check is the address is a broadcast address, whatever its size */ int frame802154_is_broadcast_addr(uint8_t mode, uint8_t *addr) { int i = mode == FRAME802154_SHORTADDRMODE ? 2 : 8; while(i-- > 0) { if(addr[i] != 0xff) { return 0; } } return 1; } /*---------------------------------------------------------------------------*/ /* Check and extract source and destination linkaddr from frame */ int frame802154_extract_linkaddr(frame802154_t *frame, linkaddr_t *source_address, linkaddr_t *dest_address) { int src_addr_len; int dest_addr_len; if(frame == NULL) { return 0; } /* Check and extract source address */ src_addr_len = frame->fcf.src_addr_mode ? ((frame->fcf.src_addr_mode == FRAME802154_SHORTADDRMODE) ? 2 : 8) : 0; if(src_addr_len == 0 || frame802154_is_broadcast_addr(frame->fcf.src_addr_mode, frame->src_addr)) { /* Broadcast address */ if(source_address != NULL) { linkaddr_copy(source_address, &linkaddr_null); } } else { /* Unicast address */ if(src_addr_len != LINKADDR_SIZE) { /* Destination address has a size we can not handle */ return 0; } if(source_address != NULL) { linkaddr_copy(source_address, (linkaddr_t *)frame->src_addr); } } /* Check and extract destination address */ dest_addr_len = frame->fcf.dest_addr_mode ? ((frame->fcf.dest_addr_mode == FRAME802154_SHORTADDRMODE) ? 2 : 8) : 0; if(dest_addr_len == 0 || frame802154_is_broadcast_addr(frame->fcf.dest_addr_mode, frame->dest_addr)) { /* Broadcast address */ if(dest_address != NULL) { linkaddr_copy(dest_address, &linkaddr_null); } } else { /* Unicast address */ if(dest_addr_len != LINKADDR_SIZE) { /* Destination address has a size we can not handle */ return 0; } if(dest_address != NULL) { linkaddr_copy(dest_address, (linkaddr_t *)frame->dest_addr); } } return 1; } /*----------------------------------------------------------------------------*/ static void field_len(frame802154_t *p, field_length_t *flen) { int has_src_panid; int has_dest_panid; /* init flen to zeros */ memset(flen, 0, sizeof(field_length_t)); /* Determine lengths of each field based on fcf and other args */ if((p->fcf.sequence_number_suppression & 1) == 0) { flen->seqno_len = 1; } /* IEEE802.15.4e changes the meaning of PAN ID Compression (see Table 2a). * In this case, we leave the decision whether to compress PAN ID or not * up to the caller. */ if(p->fcf.frame_version < FRAME802154_IEEE802154E_2012) { /* Set PAN ID compression bit if src pan id matches dest pan id. */ if(p->fcf.dest_addr_mode & 3 && p->fcf.src_addr_mode & 3 && p->src_pid == p->dest_pid) { p->fcf.panid_compression = 1; } else { p->fcf.panid_compression = 0; } } frame802154_has_panid(&p->fcf, &has_src_panid, &has_dest_panid); if(has_src_panid) { flen->src_pid_len = 2; } if(has_dest_panid) { flen->dest_pid_len = 2; } /* determine address lengths */ flen->dest_addr_len = addr_len(p->fcf.dest_addr_mode & 3); flen->src_addr_len = addr_len(p->fcf.src_addr_mode & 3); #if LLSEC802154_USES_AUX_HEADER /* Aux security header */ if(p->fcf.security_enabled & 1) { flen->aux_sec_len = 1; /* FCF + possibly frame counter and key ID */ if(p->aux_hdr.security_control.frame_counter_suppression == 0) { if(p->aux_hdr.security_control.frame_counter_size == 1) { flen->aux_sec_len += 5; } else { flen->aux_sec_len += 4; } } #if LLSEC802154_USES_EXPLICIT_KEYS flen->aux_sec_len += get_key_id_len(p->aux_hdr.security_control.key_id_mode); #endif /* LLSEC802154_USES_EXPLICIT_KEYS */ ; } #endif /* LLSEC802154_USES_AUX_HEADER */ } /*----------------------------------------------------------------------------*/ /** * \brief Calculates the length of the frame header. This function is * meant to be called by a higher level function, that interfaces to a MAC. * * \param p Pointer to frame802154_t_t struct, which specifies the * frame to send. * * \return The length of the frame header. */ int frame802154_hdrlen(frame802154_t *p) { field_length_t flen; field_len(p, &flen); return 2 + flen.seqno_len + flen.dest_pid_len + flen.dest_addr_len + flen.src_pid_len + flen.src_addr_len + flen.aux_sec_len; } /*----------------------------------------------------------------------------*/ /** * \brief Creates a frame for transmission over the air. This function is * meant to be called by a higher level function, that interfaces to a MAC. * * \param p Pointer to frame802154_t struct, which specifies the * frame to send. * * \param buf Pointer to the buffer to use for the frame. * * \return The length of the frame header */ int frame802154_create(frame802154_t *p, uint8_t *buf) { int c; field_length_t flen; uint8_t pos; #if LLSEC802154_USES_EXPLICIT_KEYS uint8_t key_id_mode; #endif /* LLSEC802154_USES_EXPLICIT_KEYS */ field_len(p, &flen); /* OK, now we have field lengths. Time to actually construct */ /* the outgoing frame, and store it in buf */ buf[0] = (p->fcf.frame_type & 7) | ((p->fcf.security_enabled & 1) << 3) | ((p->fcf.frame_pending & 1) << 4) | ((p->fcf.ack_required & 1) << 5) | ((p->fcf.panid_compression & 1) << 6); buf[1] = ((p->fcf.sequence_number_suppression & 1)) | ((p->fcf.ie_list_present & 1)) << 1 | ((p->fcf.dest_addr_mode & 3) << 2) | ((p->fcf.frame_version & 3) << 4) | ((p->fcf.src_addr_mode & 3) << 6); pos = 2; /* Sequence number */ if(flen.seqno_len == 1) { buf[pos++] = p->seq; } /* Destination PAN ID */ if(flen.dest_pid_len == 2) { buf[pos++] = p->dest_pid & 0xff; buf[pos++] = (p->dest_pid >> 8) & 0xff; } /* Destination address */ for(c = flen.dest_addr_len; c > 0; c--) { buf[pos++] = p->dest_addr[c - 1]; } /* Source PAN ID */ if(flen.src_pid_len == 2) { buf[pos++] = p->src_pid & 0xff; buf[pos++] = (p->src_pid >> 8) & 0xff; } /* Source address */ for(c = flen.src_addr_len; c > 0; c--) { buf[pos++] = p->src_addr[c - 1]; } #if LLSEC802154_USES_AUX_HEADER /* Aux header */ if(flen.aux_sec_len) { buf[pos++] = p->aux_hdr.security_control.security_level #if LLSEC802154_USES_EXPLICIT_KEYS | (p->aux_hdr.security_control.key_id_mode << 3) #endif /* LLSEC802154_USES_EXPLICIT_KEYS */ | (p->aux_hdr.security_control.frame_counter_suppression << 5) | (p->aux_hdr.security_control.frame_counter_size << 6) ; if(p->aux_hdr.security_control.frame_counter_suppression == 0) { /* We support only 4-byte counters */ memcpy(buf + pos, p->aux_hdr.frame_counter.u8, 4); pos += 4; if(p->aux_hdr.security_control.frame_counter_size == 1) { pos++; } } #if LLSEC802154_USES_EXPLICIT_KEYS key_id_mode = p->aux_hdr.security_control.key_id_mode; if(key_id_mode) { c = (key_id_mode - 1) * 4; memcpy(buf + pos, p->aux_hdr.key_source.u8, c); pos += c; buf[pos++] = p->aux_hdr.key_index; } #endif /* LLSEC802154_USES_EXPLICIT_KEYS */ } #endif /* LLSEC802154_USES_AUX_HEADER */ return (int)pos; } /*----------------------------------------------------------------------------*/ /** * \brief Parses an input frame. Scans the input frame to find each * section, and stores the information of each section in a * frame802154_t structure. * * \param data The input data from the radio chip. * \param len The size of the input data * \param pf The frame802154_t struct to store the parsed frame information. */ int frame802154_parse(uint8_t *data, int len, frame802154_t *pf) { uint8_t *p; frame802154_fcf_t fcf; int c; int has_src_panid; int has_dest_panid; #if LLSEC802154_USES_EXPLICIT_KEYS uint8_t key_id_mode; #endif /* LLSEC802154_USES_EXPLICIT_KEYS */ if(len < 2) { return 0; } p = data; /* decode the FCF */ fcf.frame_type = p[0] & 7; fcf.security_enabled = (p[0] >> 3) & 1; fcf.frame_pending = (p[0] >> 4) & 1; fcf.ack_required = (p[0] >> 5) & 1; fcf.panid_compression = (p[0] >> 6) & 1; fcf.sequence_number_suppression = p[1] & 1; fcf.ie_list_present = (p[1] >> 1) & 1; fcf.dest_addr_mode = (p[1] >> 2) & 3; fcf.frame_version = (p[1] >> 4) & 3; fcf.src_addr_mode = (p[1] >> 6) & 3; /* copy fcf and seqNum */ memcpy(&pf->fcf, &fcf, sizeof(frame802154_fcf_t)); p += 2; /* Skip first two bytes */ if(fcf.sequence_number_suppression == 0) { pf->seq = p[0]; p++; } frame802154_has_panid(&fcf, &has_src_panid, &has_dest_panid); /* Destination address, if any */ if(fcf.dest_addr_mode) { if(has_dest_panid) { /* Destination PAN */ pf->dest_pid = p[0] + (p[1] << 8); p += 2; } else { pf->dest_pid = 0; } /* Destination address */ /* l = addr_len(fcf.dest_addr_mode); */ /* for(c = 0; c < l; c++) { */ /* pf->dest_addr.u8[c] = p[l - c - 1]; */ /* } */ /* p += l; */ if(fcf.dest_addr_mode == FRAME802154_SHORTADDRMODE) { linkaddr_copy((linkaddr_t *)&(pf->dest_addr), &linkaddr_null); pf->dest_addr[0] = p[1]; pf->dest_addr[1] = p[0]; p += 2; } else if(fcf.dest_addr_mode == FRAME802154_LONGADDRMODE) { for(c = 0; c < 8; c++) { pf->dest_addr[c] = p[7 - c]; } p += 8; } } else { linkaddr_copy((linkaddr_t *)&(pf->dest_addr), &linkaddr_null); pf->dest_pid = 0; } /* Source address, if any */ if(fcf.src_addr_mode) { /* Source PAN */ if(has_src_panid) { pf->src_pid = p[0] + (p[1] << 8); p += 2; if(!has_dest_panid) { pf->dest_pid = pf->src_pid; } } else { pf->src_pid = pf->dest_pid; } /* Source address */ /* l = addr_len(fcf.src_addr_mode); */ /* for(c = 0; c < l; c++) { */ /* pf->src_addr.u8[c] = p[l - c - 1]; */ /* } */ /* p += l; */ if(fcf.src_addr_mode == FRAME802154_SHORTADDRMODE) { linkaddr_copy((linkaddr_t *)&(pf->src_addr), &linkaddr_null); pf->src_addr[0] = p[1]; pf->src_addr[1] = p[0]; p += 2; } else if(fcf.src_addr_mode == FRAME802154_LONGADDRMODE) { for(c = 0; c < 8; c++) { pf->src_addr[c] = p[7 - c]; } p += 8; } } else { linkaddr_copy((linkaddr_t *)&(pf->src_addr), &linkaddr_null); pf->src_pid = 0; } #if LLSEC802154_USES_AUX_HEADER if(fcf.security_enabled) { pf->aux_hdr.security_control.security_level = p[0] & 7; #if LLSEC802154_USES_EXPLICIT_KEYS pf->aux_hdr.security_control.key_id_mode = (p[0] >> 3) & 3; #endif /* LLSEC802154_USES_EXPLICIT_KEYS */ pf->aux_hdr.security_control.frame_counter_suppression = p[0] >> 5; pf->aux_hdr.security_control.frame_counter_size = p[0] >> 6; p += 1; if(pf->aux_hdr.security_control.frame_counter_suppression == 0) { memcpy(pf->aux_hdr.frame_counter.u8, p, 4); p += 4; if(pf->aux_hdr.security_control.frame_counter_size == 1) { p ++; } } #if LLSEC802154_USES_EXPLICIT_KEYS key_id_mode = pf->aux_hdr.security_control.key_id_mode; if(key_id_mode) { c = (key_id_mode - 1) * 4; memcpy(pf->aux_hdr.key_source.u8, p, c); p += c; pf->aux_hdr.key_index = p[0]; p += 1; } #endif /* LLSEC802154_USES_EXPLICIT_KEYS */ } #endif /* LLSEC802154_USES_AUX_HEADER */ /* header length */ c = p - data; /* payload length */ pf->payload_len = (len - c); /* payload */ pf->payload = p; /* return header length if successful */ return c > len ? 0 : c; } /** \} */