/* * packet-ieee80211-radiotap.c * Decode packets with a Radiotap header * * $Id: packet-ieee80211-radiotap.c 52311 2013-10-01 13:07:25Z eapache $ * * Wireshark - Network traffic analyzer * By Gerald Combs * Copyright 1998 Gerald Combs * * Copied from README.developer * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include "config.h" #include #include #include #include #include #include #include #include #include #include "packet-ieee80211.h" #include "packet-ieee80211-radiotap.h" #include "packet-ieee80211-radiotap-iter.h" #include "packet-ieee80211-radiotap-defs.h" /* protocol */ static int proto_radiotap = -1; static int hf_radiotap_version = -1; static int hf_radiotap_pad = -1; static int hf_radiotap_length = -1; static int hf_radiotap_present = -1; static int hf_radiotap_mactime = -1; /* static int hf_radiotap_channel = -1; */ static int hf_radiotap_channel_frequency = -1; static int hf_radiotap_channel_flags = -1; static int hf_radiotap_channel_flags_turbo = -1; static int hf_radiotap_channel_flags_cck = -1; static int hf_radiotap_channel_flags_ofdm = -1; static int hf_radiotap_channel_flags_2ghz = -1; static int hf_radiotap_channel_flags_5ghz = -1; static int hf_radiotap_channel_flags_passive = -1; static int hf_radiotap_channel_flags_dynamic = -1; static int hf_radiotap_channel_flags_gfsk = -1; static int hf_radiotap_channel_flags_gsm = -1; static int hf_radiotap_channel_flags_sturbo = -1; static int hf_radiotap_channel_flags_half = -1; static int hf_radiotap_channel_flags_quarter = -1; static int hf_radiotap_rxflags = -1; static int hf_radiotap_rxflags_badplcp = -1; static int hf_radiotap_xchannel = -1; static int hf_radiotap_xchannel_frequency = -1; static int hf_radiotap_xchannel_flags = -1; static int hf_radiotap_xchannel_flags_turbo = -1; static int hf_radiotap_xchannel_flags_cck = -1; static int hf_radiotap_xchannel_flags_ofdm = -1; static int hf_radiotap_xchannel_flags_2ghz = -1; static int hf_radiotap_xchannel_flags_5ghz = -1; static int hf_radiotap_xchannel_flags_passive = -1; static int hf_radiotap_xchannel_flags_dynamic = -1; static int hf_radiotap_xchannel_flags_gfsk = -1; static int hf_radiotap_xchannel_flags_gsm = -1; static int hf_radiotap_xchannel_flags_sturbo = -1; static int hf_radiotap_xchannel_flags_half = -1; static int hf_radiotap_xchannel_flags_quarter = -1; static int hf_radiotap_xchannel_flags_ht20 = -1; static int hf_radiotap_xchannel_flags_ht40u = -1; static int hf_radiotap_xchannel_flags_ht40d = -1; #if 0 static int hf_radiotap_xchannel_maxpower = -1; #endif static int hf_radiotap_fhss_hopset = -1; static int hf_radiotap_fhss_pattern = -1; static int hf_radiotap_datarate = -1; static int hf_radiotap_antenna = -1; static int hf_radiotap_dbm_antsignal = -1; static int hf_radiotap_db_antsignal = -1; static int hf_radiotap_dbm_antnoise = -1; static int hf_radiotap_db_antnoise = -1; static int hf_radiotap_tx_attenuation = -1; static int hf_radiotap_db_tx_attenuation = -1; static int hf_radiotap_txpower = -1; static int hf_radiotap_vendor_ns = -1; static int hf_radiotap_ven_oui = -1; static int hf_radiotap_ven_subns = -1; static int hf_radiotap_ven_skip = -1; static int hf_radiotap_ven_data = -1; static int hf_radiotap_mcs = -1; static int hf_radiotap_mcs_known = -1; static int hf_radiotap_mcs_have_bw = -1; static int hf_radiotap_mcs_have_index = -1; static int hf_radiotap_mcs_have_gi = -1; static int hf_radiotap_mcs_have_format = -1; static int hf_radiotap_mcs_have_fec = -1; static int hf_radiotap_mcs_have_stbc = -1; static int hf_radiotap_mcs_bw = -1; static int hf_radiotap_mcs_index = -1; static int hf_radiotap_mcs_gi = -1; static int hf_radiotap_mcs_format = -1; static int hf_radiotap_mcs_fec = -1; static int hf_radiotap_mcs_stbc = -1; static int hf_radiotap_ampdu = -1; static int hf_radiotap_ampdu_ref = -1; static int hf_radiotap_ampdu_flags = -1; static int hf_radiotap_ampdu_flags_report_zerolen = -1; static int hf_radiotap_ampdu_flags_is_zerolen = -1; static int hf_radiotap_ampdu_flags_last_known = -1; static int hf_radiotap_ampdu_flags_is_last = -1; static int hf_radiotap_ampdu_flags_delim_crc_error = -1; static int hf_radiotap_ampdu_delim_crc = -1; static int hf_radiotap_vht = -1; static int hf_radiotap_vht_known = -1; static int hf_radiotap_vht_have_stbc = -1; static int hf_radiotap_vht_have_txop_ps = -1; static int hf_radiotap_vht_have_gi = -1; static int hf_radiotap_vht_have_sgi_nsym_da = -1; static int hf_radiotap_vht_have_ldpc_extra = -1; static int hf_radiotap_vht_have_bf = -1; static int hf_radiotap_vht_have_bw = -1; static int hf_radiotap_vht_have_gid = -1; static int hf_radiotap_vht_have_p_aid = -1; static int hf_radiotap_vht_stbc = -1; static int hf_radiotap_vht_txop_ps = -1; static int hf_radiotap_vht_gi = -1; static int hf_radiotap_vht_sgi_nsym_da = -1; static int hf_radiotap_vht_ldpc_extra = -1; static int hf_radiotap_vht_bf = -1; static int hf_radiotap_vht_bw = -1; static int hf_radiotap_vht_nsts[4] = { -1, -1, -1, -1 }; static int hf_radiotap_vht_mcs[4] = { -1, -1, -1, -1 }; static int hf_radiotap_vht_nss[4] = { -1, -1, -1, -1 }; static int hf_radiotap_vht_coding[4] = { -1, -1, -1, -1 }; static int hf_radiotap_vht_datarate[4] = { -1, -1, -1, -1 }; static int hf_radiotap_vht_gid = -1; static int hf_radiotap_vht_p_aid = -1; static int hf_radiotap_vht_user = -1; /* "Present" flags */ static int hf_radiotap_present_tsft = -1; static int hf_radiotap_present_flags = -1; static int hf_radiotap_present_rate = -1; static int hf_radiotap_present_channel = -1; static int hf_radiotap_present_fhss = -1; static int hf_radiotap_present_dbm_antsignal = -1; static int hf_radiotap_present_dbm_antnoise = -1; static int hf_radiotap_present_lock_quality = -1; static int hf_radiotap_present_tx_attenuation = -1; static int hf_radiotap_present_db_tx_attenuation = -1; static int hf_radiotap_present_dbm_tx_power = -1; static int hf_radiotap_present_antenna = -1; static int hf_radiotap_present_db_antsignal = -1; static int hf_radiotap_present_db_antnoise = -1; static int hf_radiotap_present_hdrfcs = -1; static int hf_radiotap_present_rxflags = -1; static int hf_radiotap_present_xchannel = -1; static int hf_radiotap_present_mcs = -1; static int hf_radiotap_present_ampdu = -1; static int hf_radiotap_present_vht = -1; static int hf_radiotap_present_reserved = -1; static int hf_radiotap_present_rtap_ns = -1; static int hf_radiotap_present_vendor_ns = -1; static int hf_radiotap_present_ext = -1; /* "present.flags" flags */ static int hf_radiotap_flags = -1; static int hf_radiotap_flags_cfp = -1; static int hf_radiotap_flags_preamble = -1; static int hf_radiotap_flags_wep = -1; static int hf_radiotap_flags_frag = -1; static int hf_radiotap_flags_fcs = -1; static int hf_radiotap_flags_datapad = -1; static int hf_radiotap_flags_badfcs = -1; static int hf_radiotap_flags_shortgi = -1; static int hf_radiotap_quality = -1; static int hf_radiotap_fcs = -1; static int hf_radiotap_fcs_bad = -1; static gint ett_radiotap = -1; static gint ett_radiotap_present = -1; static gint ett_radiotap_flags = -1; static gint ett_radiotap_rxflags = -1; static gint ett_radiotap_channel_flags = -1; static gint ett_radiotap_xchannel_flags = -1; static gint ett_radiotap_vendor = -1; static gint ett_radiotap_mcs = -1; static gint ett_radiotap_mcs_known = -1; static gint ett_radiotap_ampdu = -1; static gint ett_radiotap_ampdu_flags = -1; static gint ett_radiotap_vht = -1; static gint ett_radiotap_vht_known = -1; static gint ett_radiotap_vht_user = -1; static expert_field ei_radiotap_data_past_header = EI_INIT; static expert_field ei_radiotap_present_reserved = EI_INIT; static expert_field ei_radiotap_present = EI_INIT; static dissector_handle_t ieee80211_handle; static dissector_handle_t ieee80211_datapad_handle; static int radiotap_tap = -1; /* Settings */ static gboolean radiotap_bit14_fcs = FALSE; static void dissect_radiotap(tvbuff_t * tvb, packet_info * pinfo, proto_tree * tree); #define BITNO_32(x) (((x) >> 16) ? 16 + BITNO_16((x) >> 16) : BITNO_16((x))) #define BITNO_16(x) (((x) >> 8) ? 8 + BITNO_8((x) >> 8) : BITNO_8((x))) #define BITNO_8(x) (((x) >> 4) ? 4 + BITNO_4((x) >> 4) : BITNO_4((x))) #define BITNO_4(x) (((x) >> 2) ? 2 + BITNO_2((x) >> 2) : BITNO_2((x))) #define BITNO_2(x) (((x) & 2) ? 1 : 0) #define BIT(n) (1 << n) /* not officially defined (yet) */ #define IEEE80211_RADIOTAP_F_SHORTGI 0x80 #define IEEE80211_RADIOTAP_XCHANNEL 18 #define IEEE80211_CHAN_HT20 0x10000 /* HT 20 channel */ #define IEEE80211_CHAN_HT40U 0x20000 /* HT 40 channel w/ ext above */ #define IEEE80211_CHAN_HT40D 0x40000 /* HT 40 channel w/ ext below */ /* Official specifcation: * * http://www.radiotap.org/ * * Unofficial and historical specifications: * http://madwifi-project.org/wiki/DevDocs/RadiotapHeader * NetBSD's ieee80211_radiotap.h file */ /* * Useful combinations of channel characteristics. */ #define IEEE80211_CHAN_FHSS \ (IEEE80211_CHAN_2GHZ | IEEE80211_CHAN_GFSK) #define IEEE80211_CHAN_A \ (IEEE80211_CHAN_5GHZ | IEEE80211_CHAN_OFDM) #define IEEE80211_CHAN_B \ (IEEE80211_CHAN_2GHZ | IEEE80211_CHAN_CCK) #define IEEE80211_CHAN_PUREG \ (IEEE80211_CHAN_2GHZ | IEEE80211_CHAN_OFDM) #define IEEE80211_CHAN_G \ (IEEE80211_CHAN_2GHZ | IEEE80211_CHAN_DYN) #define IEEE80211_CHAN_T \ (IEEE80211_CHAN_5GHZ | IEEE80211_CHAN_OFDM | IEEE80211_CHAN_TURBO) #define IEEE80211_CHAN_108G \ (IEEE80211_CHAN_G | IEEE80211_CHAN_TURBO) #define IEEE80211_CHAN_108PUREG \ (IEEE80211_CHAN_PUREG | IEEE80211_CHAN_TURBO) #define MAX_MCS_VHT_INDEX 9 /* * Maps a VHT bandwidth index to ieee80211_vhtinfo.rates index. */ static const int ieee80211_vht_bw2rate_index[] = { /* 20Mhz total */ 0, /* 40Mhz total */ 1, 0, 0, /* 80Mhz total */ 2, 1, 1, 0, 0, 0, 0, /* 160Mhz total */ 3, 2, 2, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0 }; struct mcs_vht_info { const char *modulation; const char *coding_rate; float rates[4][2]; }; static const struct mcs_vht_info ieee80211_vhtinfo[MAX_MCS_VHT_INDEX+1] = { /* MCS 0 */ { "BPSK", "1/2", { /* 20 Mhz */ { 6.5f, /* SGI */ 7.2f, }, /* 40 Mhz */ { 13.5f, /* SGI */ 15.0f, }, /* 80 Mhz */ { 29.3f, /* SGI */ 32.5f, }, /* 160 Mhz */ { 58.5f, /* SGI */ 65.0f, } } }, /* MCS 1 */ { "QPSK", "1/2", { /* 20 Mhz */ { 13.0f, /* SGI */ 14.4f, }, /* 40 Mhz */ { 27.0f, /* SGI */ 30.0f, }, /* 80 Mhz */ { 58.5f, /* SGI */ 65.0f, }, /* 160 Mhz */ { 117.0f, /* SGI */ 130.0f, } } }, /* MCS 2 */ { "QPSK", "3/4", { /* 20 Mhz */ { 19.5f, /* SGI */ 21.7f, }, /* 40 Mhz */ { 40.5f, /* SGI */ 45.0f, }, /* 80 Mhz */ { 87.8f, /* SGI */ 97.5f, }, /* 160 Mhz */ { 175.5f, /* SGI */ 195.0f, } } }, /* MCS 3 */ { "16-QAM", "1/2", { /* 20 Mhz */ { 26.0f, /* SGI */ 28.9f, }, /* 40 Mhz */ { 54.0f, /* SGI */ 60.0f, }, /* 80 Mhz */ { 117.0f, /* SGI */ 130.0f, }, /* 160 Mhz */ { 234.0f, /* SGI */ 260.0f, } } }, /* MCS 4 */ { "16-QAM", "3/4", { /* 20 Mhz */ { 39.0f, /* SGI */ 43.3f, }, /* 40 Mhz */ { 81.0f, /* SGI */ 90.0f, }, /* 80 Mhz */ { 175.5f, /* SGI */ 195.0f, }, /* 160 Mhz */ { 351.0f, /* SGI */ 390.0f, } } }, /* MCS 5 */ { "64-QAM", "2/3", { /* 20 Mhz */ { 52.0f, /* SGI */ 57.8f, }, /* 40 Mhz */ { 108.0f, /* SGI */ 120.0f, }, /* 80 Mhz */ { 234.0f, /* SGI */ 260.0f, }, /* 160 Mhz */ { 468.0f, /* SGI */ 520.0f, } } }, /* MCS 6 */ { "64-QAM", "3/4", { /* 20 Mhz */ { 58.5f, /* SGI */ 65.0f, }, /* 40 Mhz */ { 121.5f, /* SGI */ 135.0f, }, /* 80 Mhz */ { 263.3f, /* SGI */ 292.5f, }, /* 160 Mhz */ { 526.5f, /* SGI */ 585.0f, } } }, /* MCS 7 */ { "64-QAM", "5/6", { /* 20 Mhz */ { 65.0f, /* SGI */ 72.2f, }, /* 40 Mhz */ { 135.0f, /* SGI */ 150.0f, }, /* 80 Mhz */ { 292.5f, /* SGI */ 325.0f, }, /* 160 Mhz */ { 585.0f, /* SGI */ 650.0f, } } }, /* MCS 8 */ { "256-QAM", "3/4", { /* 20 Mhz */ { 78.0f, /* SGI */ 86.7f, }, /* 40 Mhz */ { 162.0f, /* SGI */ 180.0f, }, /* 80 Mhz */ { 351.0f, /* SGI */ 390.0f, }, /* 160 Mhz */ { 702.0f, /* SGI */ 780.0f, } } }, /* MCS 9 */ { "256-QAM", "5/6", { /* 20 Mhz */ { 0.0f, /* SGI */ 0.0f, }, /* 40 Mhz */ { 180.0f, /* SGI */ 200.0f, }, /* 80 Mhz */ { 390.0f, /* SGI */ 433.3f, }, /* 160 Mhz */ { 780.0f, /* SGI */ 866.7f, } } } }; /* In order by value */ static const value_string vht_bandwidth[] = { { IEEE80211_RADIOTAP_VHT_BW_20, "20 MHz" }, { IEEE80211_RADIOTAP_VHT_BW_40, "40 MHz" }, { IEEE80211_RADIOTAP_VHT_BW_20L, "20 MHz lower" }, { IEEE80211_RADIOTAP_VHT_BW_20U, "20 MHz upper" }, { IEEE80211_RADIOTAP_VHT_BW_80, "80 MHz" }, { IEEE80211_RADIOTAP_VHT_BW_40L, "40 MHz lower" }, { IEEE80211_RADIOTAP_VHT_BW_40U, "40 MHz upper" }, { IEEE80211_RADIOTAP_VHT_BW_20LL, "20 MHz, channel 1/4" }, { IEEE80211_RADIOTAP_VHT_BW_20LU, "20 MHz, channel 2/4" }, { IEEE80211_RADIOTAP_VHT_BW_20UL, "20 MHz, channel 3/4" }, { IEEE80211_RADIOTAP_VHT_BW_20UU, "20 MHz, channel 4/4" }, { IEEE80211_RADIOTAP_VHT_BW_160, "160 MHz" }, { IEEE80211_RADIOTAP_VHT_BW_80L, "80 MHz lower" }, { IEEE80211_RADIOTAP_VHT_BW_80U, "80 MHz upper" }, { IEEE80211_RADIOTAP_VHT_BW_40LL, "40 MHz, channel 1/4" }, { IEEE80211_RADIOTAP_VHT_BW_40LU, "40 MHz, channel 2/4" }, { IEEE80211_RADIOTAP_VHT_BW_40UL, "40 MHz, channel 3/4" }, { IEEE80211_RADIOTAP_VHT_BW_40UU, "40 MHz, channel 4/4" }, { IEEE80211_RADIOTAP_VHT_BW_20LLL, "20 MHz, channel 1/8" }, { IEEE80211_RADIOTAP_VHT_BW_20LLU, "20 MHz, channel 2/8" }, { IEEE80211_RADIOTAP_VHT_BW_20LUL, "20 MHz, channel 3/8" }, { IEEE80211_RADIOTAP_VHT_BW_20LUU, "20 MHz, channel 4/8" }, { IEEE80211_RADIOTAP_VHT_BW_20ULL, "20 MHz, channel 5/8" }, { IEEE80211_RADIOTAP_VHT_BW_20ULU, "20 MHz, channel 6/8" }, { IEEE80211_RADIOTAP_VHT_BW_20UUL, "20 MHz, channel 7/8" }, { IEEE80211_RADIOTAP_VHT_BW_20UUU, "20 MHz, channel 8/8" }, { 0, NULL } }; static value_string_ext vht_bandwidth_ext = VALUE_STRING_EXT_INIT(vht_bandwidth); #define MAX_MCS_INDEX 76 /* * Indices are: * * the MCS index (0-76); * * 0 for 20 MHz, 1 for 40 MHz; * * 0 for a long guard interval, 1 for a short guard interval. */ static const float ieee80211_float_htrates[MAX_MCS_INDEX+1][2][2] = { /* MCS 0 */ { /* 20 Mhz */ { 6.5f, /* SGI */ 7.2f, }, /* 40 Mhz */ { 13.5f, /* SGI */ 15.0f, }, }, /* MCS 1 */ { /* 20 Mhz */ { 13.0f, /* SGI */ 14.4f, }, /* 40 Mhz */ { 27.0f, /* SGI */ 30.0f, }, }, /* MCS 2 */ { /* 20 Mhz */ { 19.5f, /* SGI */ 21.7f, }, /* 40 Mhz */ { 40.5f, /* SGI */ 45.0f, }, }, /* MCS 3 */ { /* 20 Mhz */ { 26.0f, /* SGI */ 28.9f, }, /* 40 Mhz */ { 54.0f, /* SGI */ 60.0f, }, }, /* MCS 4 */ { /* 20 Mhz */ { 39.0f, /* SGI */ 43.3f, }, /* 40 Mhz */ { 81.0f, /* SGI */ 90.0f, }, }, /* MCS 5 */ { /* 20 Mhz */ { 52.0f, /* SGI */ 57.8f, }, /* 40 Mhz */ { 108.0f, /* SGI */ 120.0f, }, }, /* MCS 6 */ { /* 20 Mhz */ { 58.5f, /* SGI */ 65.0f, }, /* 40 Mhz */ { 121.5f, /* SGI */ 135.0f, }, }, /* MCS 7 */ { /* 20 Mhz */ { 65.0f, /* SGI */ 72.2f, }, /* 40 Mhz */ { 135.0f, /* SGI */ 150.0f, }, }, /* MCS 8 */ { /* 20 Mhz */ { 13.0f, /* SGI */ 14.4f, }, /* 40 Mhz */ { 27.0f, /* SGI */ 30.0f, }, }, /* MCS 9 */ { /* 20 Mhz */ { 26.0f, /* SGI */ 28.9f, }, /* 40 Mhz */ { 54.0f, /* SGI */ 60.0f, }, }, /* MCS 10 */ { /* 20 Mhz */ { 39.0f, /* SGI */ 43.3f, }, /* 40 Mhz */ { 81.0f, /* SGI */ 90.0f, }, }, /* MCS 11 */ { /* 20 Mhz */ { 52.0f, /* SGI */ 57.8f, }, /* 40 Mhz */ { 108.0f, /* SGI */ 120.0f, }, }, /* MCS 12 */ { /* 20 Mhz */ { 78.0f, /* SGI */ 86.7f, }, /* 40 Mhz */ { 162.0f, /* SGI */ 180.0f, }, }, /* MCS 13 */ { /* 20 Mhz */ { 104.0f, /* SGI */ 115.6f, }, /* 40 Mhz */ { 216.0f, /* SGI */ 240.0f, }, }, /* MCS 14 */ { /* 20 Mhz */ { 117.0f, /* SGI */ 130.0f, }, /* 40 Mhz */ { 243.0f, /* SGI */ 270.0f, }, }, /* MCS 15 */ { /* 20 Mhz */ { 130.0f, /* SGI */ 144.4f, }, /* 40 Mhz */ { 270.0f, /* SGI */ 300.0f, }, }, /* MCS 16 */ { /* 20 Mhz */ { 19.5f, /* SGI */ 21.7f, }, /* 40 Mhz */ { 40.5f, /* SGI */ 45.0f, }, }, /* MCS 17 */ { /* 20 Mhz */ { 39.0f, /* SGI */ 43.3f, }, /* 40 Mhz */ { 81.0f, /* SGI */ 90.0f, }, }, /* MCS 18 */ { /* 20 Mhz */ { 58.5f, /* SGI */ 65.0f, }, /* 40 Mhz */ { 121.5f, /* SGI */ 135.0f, }, }, /* MCS 19 */ { /* 20 Mhz */ { 78.0f, /* SGI */ 86.7f, }, /* 40 Mhz */ { 162.0f, /* SGI */ 180.0f, }, }, /* MCS 20 */ { /* 20 Mhz */ { 117.0f, /* SGI */ 130.0f, }, /* 40 Mhz */ { 243.0f, /* SGI */ 270.0f, }, }, /* MCS 21 */ { /* 20 Mhz */ { 156.0f, /* SGI */ 173.3f, }, /* 40 Mhz */ { 324.0f, /* SGI */ 360.0f, }, }, /* MCS 22 */ { /* 20 Mhz */ { 175.5f, /* SGI */ 195.0f, }, /* 40 Mhz */ { 364.5f, /* SGI */ 405.0f, }, }, /* MCS 23 */ { /* 20 Mhz */ { 195.0f, /* SGI */ 216.7f, }, /* 40 Mhz */ { 405.0f, /* SGI */ 450.0f, }, }, /* MCS 24 */ { /* 20 Mhz */ { 26.0f, /* SGI */ 28.9f, }, /* 40 Mhz */ { 54.0f, /* SGI */ 60.0f, }, }, /* MCS 25 */ { /* 20 Mhz */ { 52.0f, /* SGI */ 57.8f, }, /* 40 Mhz */ { 108.0f, /* SGI */ 120.0f, }, }, /* MCS 26 */ { /* 20 Mhz */ { 78.0f, /* SGI */ 86.7f, }, /* 40 Mhz */ { 162.0f, /* SGI */ 180.0f, }, }, /* MCS 27 */ { /* 20 Mhz */ { 104.0f, /* SGI */ 115.6f, }, /* 40 Mhz */ { 216.0f, /* SGI */ 240.0f, }, }, /* MCS 28 */ { /* 20 Mhz */ { 156.0f, /* SGI */ 173.3f, }, /* 40 Mhz */ { 324.0f, /* SGI */ 360.0f, }, }, /* MCS 29 */ { /* 20 Mhz */ { 208.0f, /* SGI */ 231.1f, }, /* 40 Mhz */ { 432.0f, /* SGI */ 480.0f, }, }, /* MCS 30 */ { /* 20 Mhz */ { 234.0f, /* SGI */ 260.0f, }, /* 40 Mhz */ { 486.0f, /* SGI */ 540.0f, }, }, /* MCS 31 */ { /* 20 Mhz */ { 260.0f, /* SGI */ 288.9f, }, /* 40 Mhz */ { 540.0f, /* SGI */ 600.0f, }, }, /* MCS 32 */ { /* 20 Mhz */ { 0.0f, /* SGI */ 0.0f, }, /* not valid */ /* 40 Mhz */ { 6.0f, /* SGI */ 6.7f, }, }, /* MCS 33 */ { /* 20 Mhz */ { 39.0f, /* SGI */ 43.3f, }, /* 40 Mhz */ { 81.0f, /* SGI */ 90.0f, }, }, /* MCS 34 */ { /* 20 Mhz */ { 52.0f, /* SGI */ 57.8f, }, /* 40 Mhz */ { 108.0f, /* SGI */ 120.0f, }, }, /* MCS 35 */ { /* 20 Mhz */ { 65.0f, /* SGI */ 72.2f, }, /* 40 Mhz */ { 135.0f, /* SGI */ 150.0f, }, }, /* MCS 36 */ { /* 20 Mhz */ { 58.5f, /* SGI */ 65.0f, }, /* 40 Mhz */ { 121.5f, /* SGI */ 135.0f, }, }, /* MCS 37 */ { /* 20 Mhz */ { 78.0f, /* SGI */ 86.7f, }, /* 40 Mhz */ { 162.0f, /* SGI */ 180.0f, }, }, /* MCS 38 */ { /* 20 Mhz */ { 97.5f, /* SGI */ 108.3f, }, /* 40 Mhz */ { 202.5f, /* SGI */ 225.0f, }, }, /* MCS 39 */ { /* 20 Mhz */ { 52.0f, /* SGI */ 57.8f, }, /* 40 Mhz */ { 108.0f, /* SGI */ 120.0f, }, }, /* MCS 40 */ { /* 20 Mhz */ { 65.0f, /* SGI */ 72.2f, }, /* 40 Mhz */ { 135.0f, /* SGI */ 150.0f, }, }, /* MCS 41 */ { /* 20 Mhz */ { 65.0f, /* SGI */ 72.2f, }, /* 40 Mhz */ { 135.0f, /* SGI */ 150.0f, }, }, /* MCS 42 */ { /* 20 Mhz */ { 78.0f, /* SGI */ 86.7f, }, /* 40 Mhz */ { 162.0f, /* SGI */ 180.0f, }, }, /* MCS 43 */ { /* 20 Mhz */ { 91.0f, /* SGI */ 101.1f, }, /* 40 Mhz */ { 189.0f, /* SGI */ 210.0f, }, }, /* MCS 44 */ { /* 20 Mhz */ { 91.0f, /* SGI */ 101.1f, }, /* 40 Mhz */ { 189.0f, /* SGI */ 210.0f, }, }, /* MCS 45 */ { /* 20 Mhz */ { 104.0f, /* SGI */ 115.6f, }, /* 40 Mhz */ { 216.0f, /* SGI */ 240.0f, }, }, /* MCS 46 */ { /* 20 Mhz */ { 78.0f, /* SGI */ 86.7f, }, /* 40 Mhz */ { 162.0f, /* SGI */ 180.0f, }, }, /* MCS 47 */ { /* 20 Mhz */ { 97.5f, /* SGI */ 108.3f, }, /* 40 Mhz */ { 202.5f, /* SGI */ 225.0f, }, }, /* MCS 48 */ { /* 20 Mhz */ { 97.5f, /* SGI */ 108.3f, }, /* 40 Mhz */ { 202.5f, /* SGI */ 225.0f, }, }, /* MCS 49 */ { /* 20 Mhz */ { 117.0f, /* SGI */ 130.0f, }, /* 40 Mhz */ { 243.0f, /* SGI */ 270.0f, }, }, /* MCS 50 */ { /* 20 Mhz */ { 136.5f, /* SGI */ 151.7f, }, /* 40 Mhz */ { 283.5f, /* SGI */ 315.0f, }, }, /* MCS 51 */ { /* 20 Mhz */ { 136.5f, /* SGI */ 151.7f, }, /* 40 Mhz */ { 283.5f, /* SGI */ 315.0f, }, }, /* MCS 52 */ { /* 20 Mhz */ { 156.0f, /* SGI */ 173.3f, }, /* 40 Mhz */ { 324.0f, /* SGI */ 360.0f, }, }, /* MCS 53 */ { /* 20 Mhz */ { 65.0f, /* SGI */ 72.2f, }, /* 40 Mhz */ { 135.0f, /* SGI */ 150.0f, }, }, /* MCS 54 */ { /* 20 Mhz */ { 78.0f, /* SGI */ 86.7f, }, /* 40 Mhz */ { 162.0f, /* SGI */ 180.0f, }, }, /* MCS 55 */ { /* 20 Mhz */ { 91.0f, /* SGI */ 101.1f, }, /* 40 Mhz */ { 189.0f, /* SGI */ 210.0f, }, }, /* MCS 56 */ { /* 20 Mhz */ { 78.0f, /* SGI */ 86.7f, }, /* 40 Mhz */ { 162.0f, /* SGI */ 180.0f, }, }, /* MCS 57 */ { /* 20 Mhz */ { 91.0f, /* SGI */ 101.1f, }, /* 40 Mhz */ { 189.0f, /* SGI */ 210.0f, }, }, /* MCS 58 */ { /* 20 Mhz */ { 104.0f, /* SGI */ 115.6f, }, /* 40 Mhz */ { 216.0f, /* SGI */ 240.0f, }, }, /* MCS 59 */ { /* 20 Mhz */ { 117.0f, /* SGI */ 130.0f, }, /* 40 Mhz */ { 243.0f, /* SGI */ 270.0f, }, }, /* MCS 60 */ { /* 20 Mhz */ { 104.0f, /* SGI */ 115.6f, }, /* 40 Mhz */ { 216.0f, /* SGI */ 240.0f, }, }, /* MCS 61 */ { /* 20 Mhz */ { 117.0f, /* SGI */ 130.0f, }, /* 40 Mhz */ { 243.0f, /* SGI */ 270.0f, }, }, /* MCS 62 */ { /* 20 Mhz */ { 130.0f, /* SGI */ 144.4f, }, /* 40 Mhz */ { 270.0f, /* SGI */ 300.0f, }, }, /* MCS 63 */ { /* 20 Mhz */ { 130.0f, /* SGI */ 144.4f, }, /* 40 Mhz */ { 270.0f, /* SGI */ 300.0f, }, }, /* MCS 64 */ { /* 20 Mhz */ { 143.0f, /* SGI */ 158.9f, }, /* 40 Mhz */ { 297.0f, /* SGI */ 330.0f, }, }, /* MCS 65 */ { /* 20 Mhz */ { 97.5f, /* SGI */ 108.3f, }, /* 40 Mhz */ { 202.5f, /* SGI */ 225.0f, }, }, /* MCS 66 */ { /* 20 Mhz */ { 117.0f, /* SGI */ 130.0f, }, /* 40 Mhz */ { 243.0f, /* SGI */ 270.0f, }, }, /* MCS 67 */ { /* 20 Mhz */ { 136.5f, /* SGI */ 151.7f, }, /* 40 Mhz */ { 283.5f, /* SGI */ 315.0f, }, }, /* MCS 68 */ { /* 20 Mhz */ { 117.0f, /* SGI */ 130.0f, }, /* 40 Mhz */ { 243.0f, /* SGI */ 270.0f, }, }, /* MCS 69 */ { /* 20 Mhz */ { 136.5f, /* SGI */ 151.7f, }, /* 40 Mhz */ { 283.5f, /* SGI */ 315.0f, }, }, /* MCS 70 */ { /* 20 Mhz */ { 156.0f, /* SGI */ 173.3f, }, /* 40 Mhz */ { 324.0f, /* SGI */ 360.0f, }, }, /* MCS 71 */ { /* 20 Mhz */ { 175.5f, /* SGI */ 195.0f, }, /* 40 Mhz */ { 364.5f, /* SGI */ 405.0f, }, }, /* MCS 72 */ { /* 20 Mhz */ { 156.0f, /* SGI */ 173.3f, }, /* 40 Mhz */ { 324.0f, /* SGI */ 360.0f, }, }, /* MCS 73 */ { /* 20 Mhz */ { 175.5f, /* SGI */ 195.0f, }, /* 40 Mhz */ { 364.5f, /* SGI */ 405.0f, }, }, /* MCS 74 */ { /* 20 Mhz */ { 195.0f, /* SGI */ 216.7f, }, /* 40 Mhz */ { 405.0f, /* SGI */ 450.0f, }, }, /* MCS 75 */ { /* 20 Mhz */ { 195.0f, /* SGI */ 216.7f, }, /* 40 Mhz */ { 405.0f, /* SGI */ 450.0f, }, }, /* MCS 76 */ { /* 20 Mhz */ { 214.5f, /* SGI */ 238.3f, }, /* 40 Mhz */ { 445.5f, /* SGI */ 495.0f, }, }, }; /* In order by value */ static const value_string phy_type[] = { {0, "Unknown"}, /* 0x00000 */ {IEEE80211_CHAN_B, "802.11b"}, /* 0x000a0 */ {IEEE80211_CHAN_PUREG, "802.11g (pure-g)"}, /* 0x000c0 */ {IEEE80211_CHAN_108PUREG, "802.11g (pure-g, turbo)"}, /* 0x000d0 */ {IEEE80211_CHAN_A, "802.11a"}, /* 0x00140 */ {IEEE80211_CHAN_T, "802.11a (turbo)"}, /* 0x00150 */ {IEEE80211_CHAN_G, "802.11g"}, /* 0x00480 */ {IEEE80211_CHAN_108G, "802.11g (turbo)"}, /* 0x00490 */ {IEEE80211_CHAN_FHSS, "FHSS"}, /* 0x00880 */ {IEEE80211_CHAN_A | IEEE80211_CHAN_HT20, "802.11a (ht20)"}, /* 0x10140 */ {IEEE80211_CHAN_G | IEEE80211_CHAN_HT20, "802.11g (ht20)"}, /* 0x10480 */ {IEEE80211_CHAN_A | IEEE80211_CHAN_HT40U, "802.11a (ht40+)"}, /* 0x20140 */ {IEEE80211_CHAN_G | IEEE80211_CHAN_HT40U, "802.11g (ht40+)"}, /* 0x20480 */ {IEEE80211_CHAN_A | IEEE80211_CHAN_HT40D, "802.11a (ht40-)"}, /* 0x40140 */ {IEEE80211_CHAN_G | IEEE80211_CHAN_HT40D, "802.11g (ht40-)"}, /* 0x40480 */ {0, NULL} }; static value_string_ext phy_type_ext = VALUE_STRING_EXT_INIT(phy_type); static const value_string mcs_bandwidth[] = { { IEEE80211_RADIOTAP_MCS_BW_20, "20 MHz" }, { IEEE80211_RADIOTAP_MCS_BW_40, "40 MHz" }, { IEEE80211_RADIOTAP_MCS_BW_20L, "20 MHz lower" }, { IEEE80211_RADIOTAP_MCS_BW_20U, "20 MHz upper" }, {0, NULL} }; static const value_string mcs_format[] = { { 0, "mixed" }, { 1, "greenfield" }, {0, NULL}, }; static const value_string mcs_fec[] = { { 0, "BCC" }, { 1, "LDPC" }, {0, NULL} }; static const value_string mcs_gi[] = { { 0, "long" }, { 1, "short" }, {0, NULL} }; static const true_false_string preamble_type = { "Short", "Long", }; /* * The NetBSD ieee80211_radiotap man page * (http://netbsd.gw.com/cgi-bin/man-cgi?ieee80211_radiotap+9+NetBSD-current) * says: * * Radiotap capture fields must be naturally aligned. That is, 16-, 32-, * and 64-bit fields must begin on 16-, 32-, and 64-bit boundaries, respec- * tively. In this way, drivers can avoid unaligned accesses to radiotap * capture fields. radiotap-compliant drivers must insert padding before a * capture field to ensure its natural alignment. radiotap-compliant packet * dissectors, such as tcpdump(8), expect the padding. */ void capture_radiotap(const guchar * pd, int offset, int len, packet_counts * ld) { guint16 it_len; guint32 present, xpresent; guint8 rflags; struct ieee80211_radiotap_header *hdr; if (!BYTES_ARE_IN_FRAME(offset, len, sizeof(struct ieee80211_radiotap_header))) { ld->other++; return; } hdr = (struct ieee80211_radiotap_header *)pd; it_len = pletohs(&hdr->it_len); if (!BYTES_ARE_IN_FRAME(offset, len, it_len)) { ld->other++; return; } if (it_len > len) { /* Header length is bigger than total packet length */ ld->other++; return; } if (it_len < sizeof(struct ieee80211_radiotap_header)) { /* Header length is shorter than fixed-length portion of header */ ld->other++; return; } present = pletohl(&hdr->it_present); offset += (int)sizeof(struct ieee80211_radiotap_header); it_len -= (int)sizeof(struct ieee80211_radiotap_header); /* skip over other present bitmaps */ xpresent = present; while (xpresent & BIT(IEEE80211_RADIOTAP_EXT)) { if (!BYTES_ARE_IN_FRAME(offset, 4, it_len)) { ld->other++; return; } xpresent = pletohl(pd + offset); offset += 4; it_len -= 4; } rflags = 0; /* * IEEE80211_RADIOTAP_TSFT is the lowest-order bit, * just skip over it. */ if (present & BIT(IEEE80211_RADIOTAP_TSFT)) { /* align it properly */ if (offset & 7) { int pad = 8 - (offset & 7); offset += pad; it_len -= pad; } if (it_len < 8) { /* No room in header for this field. */ ld->other++; return; } /* That field is present, and it's 8 bytes long. */ offset += 8; it_len -= 8; } /* * IEEE80211_RADIOTAP_FLAGS is the next bit. */ if (present & BIT(IEEE80211_RADIOTAP_FLAGS)) { if (it_len < 1) { /* No room in header for this field. */ ld->other++; return; } /* That field is present; fetch it. */ if (!BYTES_ARE_IN_FRAME(offset, len, 1)) { ld->other++; return; } rflags = pd[offset]; } /* 802.11 header follows */ if (rflags & IEEE80211_RADIOTAP_F_DATAPAD) capture_ieee80211_datapad(pd, offset + it_len, len, ld); else capture_ieee80211(pd, offset + it_len, len, ld); } static void dissect_radiotap(tvbuff_t * tvb, packet_info * pinfo, proto_tree * tree) { proto_tree *radiotap_tree = NULL; proto_tree *pt = NULL, *present_tree = NULL; proto_tree *ft; proto_item *ti = NULL; proto_item *hidden_item; int offset; tvbuff_t *next_tvb; guint8 version; guint length; guint32 freq; proto_item *rate_ti; gint8 dbm, db; guint8 rflags = 0; /* backward compat with bit 14 == fcs in header */ proto_item *hdr_fcs_ti = NULL; int hdr_fcs_offset = 0; guint32 sent_fcs = 0; guint32 calc_fcs; gint err = -ENOENT; void *data; struct _radiotap_info *radiotap_info; static struct _radiotap_info rtp_info_arr; struct ieee80211_radiotap_iterator iter; /* our non-standard overrides */ static struct radiotap_override overrides[] = { {IEEE80211_RADIOTAP_XCHANNEL, 4, 8}, /* xchannel */ /* keep last */ {14, 4, 4}, /* FCS in header */ }; guint n_overrides = array_length(overrides); if (!radiotap_bit14_fcs) n_overrides--; radiotap_info = &rtp_info_arr; col_set_str(pinfo->cinfo, COL_PROTOCOL, "WLAN"); col_clear(pinfo->cinfo, COL_INFO); version = tvb_get_guint8(tvb, 0); length = tvb_get_letohs(tvb, 2); radiotap_info->radiotap_length = length; col_add_fstr(pinfo->cinfo, COL_INFO, "Radiotap Capture v%u, Length %u", version, length); /* Dissect the packet */ if (tree) { ti = proto_tree_add_protocol_format(tree, proto_radiotap, tvb, 0, length, "Radiotap Header v%u, Length %u", version, length); radiotap_tree = proto_item_add_subtree(ti, ett_radiotap); proto_tree_add_uint(radiotap_tree, hf_radiotap_version, tvb, 0, 1, version); proto_tree_add_item(radiotap_tree, hf_radiotap_pad, tvb, 1, 1, ENC_BIG_ENDIAN); proto_tree_add_uint(radiotap_tree, hf_radiotap_length, tvb, 2, 2, length); } if (length < sizeof(struct ieee80211_radiotap_header)) { length = sizeof(struct ieee80211_radiotap_header); } data = tvb_memdup(wmem_packet_scope(), tvb, 0, length); if (!data) return; if (ieee80211_radiotap_iterator_init(&iter, (struct ieee80211_radiotap_header *)data, length, NULL)) { if (tree) proto_item_append_text(ti, " (invalid)"); /* maybe the length was correct anyway ... */ goto hand_off_to_80211; } iter.overrides = overrides; iter.n_overrides = n_overrides; /* Add the "present flags" bitmaps. */ if (tree) { guchar *bmap_start = (guchar *)data + 4; guint n_bitmaps = (guint)(iter.this_arg - bmap_start) / 4; guint i; gboolean rtap_ns; gboolean rtap_ns_next = TRUE; guint rtap_ns_offset; guint rtap_ns_offset_next = 0; pt = proto_tree_add_item(radiotap_tree, hf_radiotap_present, tvb, 4, n_bitmaps * 4, ENC_NA); for (i = 0; i < n_bitmaps; i++) { guint32 bmap = pletohl(bmap_start + 4 * i); rtap_ns_offset = rtap_ns_offset_next; rtap_ns_offset_next += 32; present_tree = proto_item_add_subtree(pt, ett_radiotap_present); offset = 4 * i; rtap_ns = rtap_ns_next; /* Evaluate what kind of namespaces will come next */ if (bmap & BIT(IEEE80211_RADIOTAP_RADIOTAP_NAMESPACE)) { rtap_ns_next = TRUE; rtap_ns_offset_next = 0; } if (bmap & BIT(IEEE80211_RADIOTAP_VENDOR_NAMESPACE)) rtap_ns_next = FALSE; if ((bmap & (BIT(IEEE80211_RADIOTAP_RADIOTAP_NAMESPACE) | BIT(IEEE80211_RADIOTAP_VENDOR_NAMESPACE))) == (BIT(IEEE80211_RADIOTAP_RADIOTAP_NAMESPACE) | BIT(IEEE80211_RADIOTAP_VENDOR_NAMESPACE))) { expert_add_info_format(pinfo, pt, &ei_radiotap_present, "Both radiotap and vendor namespace specified in bitmask word %u", i); goto malformed; } if (!rtap_ns) goto always_bits; /* Currently, we don't know anything about bits >= 32 */ if (rtap_ns_offset) goto always_bits; proto_tree_add_item(present_tree, hf_radiotap_present_tsft, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_flags, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_rate, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_channel, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_fhss, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_dbm_antsignal, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_dbm_antnoise, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_lock_quality, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_tx_attenuation, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_db_tx_attenuation, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_dbm_tx_power, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_antenna, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_db_antsignal, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_db_antnoise, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); if (radiotap_bit14_fcs) { proto_tree_add_item(present_tree, hf_radiotap_present_hdrfcs, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); } else { proto_tree_add_item(present_tree, hf_radiotap_present_rxflags, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); } proto_tree_add_item(present_tree, hf_radiotap_present_xchannel, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_mcs, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_ampdu, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_vht, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); ti = proto_tree_add_item(present_tree, hf_radiotap_present_reserved, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); /* Check if Reserved/Not Defined is not "zero" */ if(bmap & IEEE80211_RADIOTAP_NOTDEFINED) { expert_add_info(pinfo, pt, &ei_radiotap_present_reserved); } always_bits: proto_tree_add_item(present_tree, hf_radiotap_present_rtap_ns, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_vendor_ns, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); proto_tree_add_item(present_tree, hf_radiotap_present_ext, tvb, offset + 4, 4, ENC_LITTLE_ENDIAN); } } while (!(err = ieee80211_radiotap_iterator_next(&iter))) { offset = (int)((guchar *) iter.this_arg - (guchar *) data); if (iter.this_arg_index == IEEE80211_RADIOTAP_VENDOR_NAMESPACE && tree) { proto_tree *vt, *ven_tree = NULL; const gchar *manuf_name; guint8 subns; manuf_name = tvb_get_manuf_name(tvb, offset); subns = tvb_get_guint8(tvb, offset+3); vt = proto_tree_add_bytes_format_value(radiotap_tree, hf_radiotap_vendor_ns, tvb, offset, iter.this_arg_size, NULL, "%s-%d", manuf_name, subns); ven_tree = proto_item_add_subtree(vt, ett_radiotap_vendor); proto_tree_add_bytes_format_value(ven_tree, hf_radiotap_ven_oui, tvb, offset, 3, NULL, "%s", manuf_name); proto_tree_add_item(ven_tree, hf_radiotap_ven_subns, tvb, offset + 3, 1, ENC_BIG_ENDIAN); proto_tree_add_item(ven_tree, hf_radiotap_ven_skip, tvb, offset + 4, 2, ENC_LITTLE_ENDIAN); proto_tree_add_item(ven_tree, hf_radiotap_ven_data, tvb, offset + 6, iter.this_arg_size - 6, ENC_NA); } if (!iter.is_radiotap_ns) continue; switch (iter.this_arg_index) { case IEEE80211_RADIOTAP_TSFT: radiotap_info->tsft = tvb_get_letoh64(tvb, offset); if (tree) { proto_tree_add_uint64(radiotap_tree, hf_radiotap_mactime, tvb, offset, 8, radiotap_info->tsft); } break; case IEEE80211_RADIOTAP_FLAGS: { rflags = tvb_get_guint8(tvb, offset); if (tree) { proto_tree *flags_tree; ft = proto_tree_add_item(radiotap_tree, hf_radiotap_flags, tvb, offset, 1, ENC_BIG_ENDIAN); flags_tree = proto_item_add_subtree(ft, ett_radiotap_flags); proto_tree_add_item(flags_tree, hf_radiotap_flags_cfp, tvb, offset, 1, ENC_BIG_ENDIAN); proto_tree_add_item(flags_tree, hf_radiotap_flags_preamble, tvb, offset, 1, ENC_BIG_ENDIAN); proto_tree_add_item(flags_tree, hf_radiotap_flags_wep, tvb, offset, 1, ENC_BIG_ENDIAN); proto_tree_add_item(flags_tree, hf_radiotap_flags_frag, tvb, offset, 1, ENC_BIG_ENDIAN); proto_tree_add_item(flags_tree, hf_radiotap_flags_fcs, tvb, offset, 1, ENC_BIG_ENDIAN); proto_tree_add_item(flags_tree, hf_radiotap_flags_datapad, tvb, offset, 1, ENC_BIG_ENDIAN); proto_tree_add_item(flags_tree, hf_radiotap_flags_badfcs, tvb, offset, 1, ENC_BIG_ENDIAN); proto_tree_add_item(flags_tree, hf_radiotap_flags_shortgi, tvb, offset, 1, ENC_BIG_ENDIAN); } break; } case IEEE80211_RADIOTAP_RATE: { guint32 rate; rate = tvb_get_guint8(tvb, offset); /* * XXX On FreeBSD rate & 0x80 means we have an MCS. On * Linux and AirPcap it does not. (What about * Mac OS X, NetBSD, OpenBSD, and DragonFly BSD?) * * This is an issue either for proprietary extensions * to 11a or 11g, which do exist, or for 11n * implementations that stuff a rate value into * this field, which also appear to exist. * * We currently handle that by assuming that * if the 0x80 bit is set *and* the remaining * bits have a value between 0 and 15 it's * an MCS value, otherwise it's a rate. If * there are cases where systems that use * "0x80 + MCS index" for MCS indices > 15, * or stuff a rate value here between 64 and * 71.5 Mb/s in here, we'll need a preference * setting. Such rates do exist, e.g. 11n * MCS 7 at 20 MHz with a long guard interval. */ if (rate >= 0x80 && rate <= 0x8f) { /* * XXX - we don't know the channel width * or guard interval length, so we can't * convert this to a data rate. * * If you want us to show a data rate, * use the MCS field, not the Rate field; * the MCS field includes not only the * MCS index, it also includes bandwidth * and guard interval information. * * XXX - can we get the channel width * from XChannel and the guard interval * information from Flags, at least on * FreeBSD? */ if (tree) { proto_tree_add_uint(radiotap_tree, hf_radiotap_mcs_index, tvb, offset, 1, rate & 0x7f); } } else { col_add_fstr(pinfo->cinfo, COL_TX_RATE, "%d.%d", rate / 2, rate & 1 ? 5 : 0); if (tree) { proto_tree_add_float_format(radiotap_tree, hf_radiotap_datarate, tvb, offset, 1, (float)rate / 2, "Data Rate: %.1f Mb/s", (float)rate / 2); } radiotap_info->rate = rate; } break; } case IEEE80211_RADIOTAP_CHANNEL: { if (tree) { proto_item *it; proto_tree *flags_tree; guint16 flags; gchar *chan_str; freq = tvb_get_letohs(tvb, offset); flags = tvb_get_letohs(tvb, offset + 2); chan_str = ieee80211_mhz_to_str(freq); col_add_fstr(pinfo->cinfo, COL_FREQ_CHAN, "%s", chan_str); proto_tree_add_uint_format_value(radiotap_tree, hf_radiotap_channel_frequency, tvb, offset, 2, freq, "%s", chan_str); g_free(chan_str); /* We're already 2-byte aligned. */ it = proto_tree_add_uint(radiotap_tree, hf_radiotap_channel_flags, tvb, offset + 2, 2, flags); flags_tree = proto_item_add_subtree(it, ett_radiotap_channel_flags); proto_tree_add_boolean(flags_tree, hf_radiotap_channel_flags_turbo, tvb, offset + 2, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_channel_flags_cck, tvb, offset + 2, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_channel_flags_ofdm, tvb, offset + 2, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_channel_flags_2ghz, tvb, offset + 2, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_channel_flags_5ghz, tvb, offset + 3, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_channel_flags_passive, tvb, offset + 3, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_channel_flags_dynamic, tvb, offset + 3, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_channel_flags_gfsk, tvb, offset + 3, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_channel_flags_gsm, tvb, offset + 3, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_channel_flags_sturbo, tvb, offset + 3, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_channel_flags_half, tvb, offset + 3, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_channel_flags_quarter, tvb, offset + 3, 1, flags); radiotap_info->freq = freq; radiotap_info->flags = flags; } break; } case IEEE80211_RADIOTAP_FHSS: proto_tree_add_item(radiotap_tree, hf_radiotap_fhss_hopset, tvb, offset, 1, ENC_BIG_ENDIAN); proto_tree_add_item(radiotap_tree, hf_radiotap_fhss_pattern, tvb, offset, 1, ENC_BIG_ENDIAN); break; case IEEE80211_RADIOTAP_DBM_ANTSIGNAL: dbm = (gint8)tvb_get_guint8(tvb, offset); col_add_fstr(pinfo->cinfo, COL_RSSI, "%d dBm", dbm); proto_tree_add_int_format_value(radiotap_tree, hf_radiotap_dbm_antsignal, tvb, offset, 1, dbm, "%d dBm", dbm); radiotap_info->dbm_antsignal = dbm; break; case IEEE80211_RADIOTAP_DBM_ANTNOISE: dbm = (gint8) tvb_get_guint8(tvb, offset); if (tree) { proto_tree_add_int_format_value(radiotap_tree, hf_radiotap_dbm_antnoise, tvb, offset, 1, dbm, "%d dBm", dbm); } radiotap_info->dbm_antnoise = dbm; break; case IEEE80211_RADIOTAP_LOCK_QUALITY: if (tree) { proto_tree_add_uint(radiotap_tree, hf_radiotap_quality, tvb, offset, 2, tvb_get_letohs(tvb, offset)); } break; case IEEE80211_RADIOTAP_TX_ATTENUATION: proto_tree_add_item(radiotap_tree, hf_radiotap_tx_attenuation, tvb, offset, 2, ENC_BIG_ENDIAN); break; case IEEE80211_RADIOTAP_DB_TX_ATTENUATION: proto_tree_add_item(radiotap_tree, hf_radiotap_db_tx_attenuation, tvb, offset, 2, ENC_BIG_ENDIAN); break; case IEEE80211_RADIOTAP_DBM_TX_POWER: if (tree) { proto_tree_add_int(radiotap_tree, hf_radiotap_txpower, tvb, offset, 1, tvb_get_guint8(tvb, offset)); } break; case IEEE80211_RADIOTAP_ANTENNA: if (tree) { proto_tree_add_uint(radiotap_tree, hf_radiotap_antenna, tvb, offset, 1, tvb_get_guint8(tvb, offset)); } break; case IEEE80211_RADIOTAP_DB_ANTSIGNAL: db = tvb_get_guint8(tvb, offset); col_add_fstr(pinfo->cinfo, COL_RSSI, "%u dB", db); if (tree) { proto_tree_add_uint_format_value(radiotap_tree, hf_radiotap_db_antsignal, tvb, offset, 1, db, "%u dB", db); } break; case IEEE80211_RADIOTAP_DB_ANTNOISE: db = tvb_get_guint8(tvb, offset); if (tree) { proto_tree_add_uint_format_value(radiotap_tree, hf_radiotap_db_antnoise, tvb, offset, 1, db, "%u dB", db); } break; case IEEE80211_RADIOTAP_RX_FLAGS: { if (radiotap_bit14_fcs) { if (tree) { sent_fcs = tvb_get_ntohl(tvb, offset); hdr_fcs_ti = proto_tree_add_uint(radiotap_tree, hf_radiotap_fcs, tvb, offset, 4, sent_fcs); hdr_fcs_offset = offset; } } else { if (tree) { proto_tree *flags_tree; proto_item *it; guint16 flags; flags = tvb_get_letohs(tvb, offset); it = proto_tree_add_uint(radiotap_tree, hf_radiotap_rxflags, tvb, offset, 2, flags); flags_tree = proto_item_add_subtree(it, ett_radiotap_rxflags); proto_tree_add_boolean(flags_tree, hf_radiotap_rxflags_badplcp, tvb, offset, 1, flags); } } break; } case IEEE80211_RADIOTAP_XCHANNEL: { if (tree) { proto_item *it; proto_tree *flags_tree; guint32 flags; int channel; flags = tvb_get_letohl(tvb, offset); freq = tvb_get_letohs(tvb, offset + 4); channel = tvb_get_guint8(tvb, offset + 6); proto_tree_add_uint(radiotap_tree, hf_radiotap_xchannel, tvb, offset + 6, 1, (guint32) channel); proto_tree_add_uint(radiotap_tree, hf_radiotap_xchannel_frequency, tvb, offset + 4, 2, freq); it = proto_tree_add_uint(radiotap_tree, hf_radiotap_xchannel_flags, tvb, offset + 0, 4, flags); flags_tree = proto_item_add_subtree(it, ett_radiotap_xchannel_flags); proto_tree_add_boolean(flags_tree, hf_radiotap_xchannel_flags_turbo, tvb, offset + 0, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_xchannel_flags_cck, tvb, offset + 0, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_xchannel_flags_ofdm, tvb, offset + 0, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_xchannel_flags_2ghz, tvb, offset + 0, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_xchannel_flags_5ghz, tvb, offset + 1, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_xchannel_flags_passive, tvb, offset + 1, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_xchannel_flags_dynamic, tvb, offset + 1, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_xchannel_flags_gfsk, tvb, offset + 1, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_xchannel_flags_gsm, tvb, offset + 1, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_xchannel_flags_sturbo, tvb, offset + 1, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_xchannel_flags_half, tvb, offset + 1, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_xchannel_flags_quarter, tvb, offset + 1, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_xchannel_flags_ht20, tvb, offset + 2, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_xchannel_flags_ht40u, tvb, offset + 2, 1, flags); proto_tree_add_boolean(flags_tree, hf_radiotap_xchannel_flags_ht40d, tvb, offset + 2, 1, flags); #if 0 proto_tree_add_uint(radiotap_tree, hf_radiotap_xchannel_maxpower, tvb, offset + 7, 1, maxpower); #endif } break; } case IEEE80211_RADIOTAP_MCS: { proto_tree *mcs_tree = NULL, *mcs_known_tree; guint8 mcs_known, mcs_flags; guint8 mcs; guint bandwidth; guint gi_length; gboolean can_calculate_rate; /* * Start out assuming that we can calculate the rate; * if we are missing any of the MCS index, channel * width, or guard interval length, we can't. */ can_calculate_rate = TRUE; mcs_known = tvb_get_guint8(tvb, offset); mcs_flags = tvb_get_guint8(tvb, offset + 1); mcs = tvb_get_guint8(tvb, offset + 2); if (tree) { proto_item *it; it = proto_tree_add_item(radiotap_tree, hf_radiotap_mcs, tvb, offset, 3, ENC_NA); mcs_tree = proto_item_add_subtree(it, ett_radiotap_mcs); it = proto_tree_add_uint(mcs_tree, hf_radiotap_mcs_known, tvb, offset, 1, mcs_known); mcs_known_tree = proto_item_add_subtree(it, ett_radiotap_mcs_known); proto_tree_add_item(mcs_known_tree, hf_radiotap_mcs_have_bw, tvb, offset, 1, ENC_LITTLE_ENDIAN); proto_tree_add_item(mcs_known_tree, hf_radiotap_mcs_have_index, tvb, offset, 1, ENC_LITTLE_ENDIAN); proto_tree_add_item(mcs_known_tree, hf_radiotap_mcs_have_gi, tvb, offset, 1, ENC_LITTLE_ENDIAN); proto_tree_add_item(mcs_known_tree, hf_radiotap_mcs_have_format, tvb, offset, 1, ENC_LITTLE_ENDIAN); proto_tree_add_item(mcs_known_tree, hf_radiotap_mcs_have_fec, tvb, offset, 1, ENC_LITTLE_ENDIAN); proto_tree_add_item(mcs_known_tree, hf_radiotap_mcs_have_stbc, tvb, offset, 1, ENC_LITTLE_ENDIAN); } if (mcs_known & IEEE80211_RADIOTAP_MCS_HAVE_BW) { bandwidth = ((mcs_flags & IEEE80211_RADIOTAP_MCS_BW_MASK) == IEEE80211_RADIOTAP_MCS_BW_40) ? 1 : 0; if (mcs_tree) proto_tree_add_uint(mcs_tree, hf_radiotap_mcs_bw, tvb, offset + 1, 1, mcs_flags); } else { bandwidth = 0; can_calculate_rate = FALSE; /* no bandwidth */ } if (mcs_known & IEEE80211_RADIOTAP_MCS_HAVE_GI) { gi_length = (mcs_flags & IEEE80211_RADIOTAP_MCS_SGI) ? 1 : 0; if (mcs_tree) proto_tree_add_uint(mcs_tree, hf_radiotap_mcs_gi, tvb, offset + 1, 1, mcs_flags); } else { gi_length = 0; can_calculate_rate = FALSE; /* no GI width */ } if (mcs_known & IEEE80211_RADIOTAP_MCS_HAVE_FMT) { if (mcs_tree) proto_tree_add_uint(mcs_tree, hf_radiotap_mcs_format, tvb, offset + 1, 1, mcs_flags); } if (mcs_known & IEEE80211_RADIOTAP_MCS_HAVE_FEC) { if (mcs_tree) proto_tree_add_uint(mcs_tree, hf_radiotap_mcs_fec, tvb, offset + 1, 1, mcs_flags); } if (mcs_known & IEEE80211_RADIOTAP_MCS_HAVE_STBC) { if (mcs_tree) proto_tree_add_boolean(mcs_tree, hf_radiotap_mcs_stbc, tvb, offset + 1, 1, mcs_flags); } if (mcs_known & IEEE80211_RADIOTAP_MCS_HAVE_MCS) { if (mcs_tree) proto_tree_add_uint(mcs_tree, hf_radiotap_mcs_index, tvb, offset + 2, 1, mcs); } else can_calculate_rate = FALSE; /* no MCS index */ /* * If we have the MCS index, channel width, and * guard interval length, and the MCS index is * valid, we can compute the rate. If the resulting * rate is non-zero, report it. (If it's zero, * it's an MCS/channel width/GI combination that * 802.11n doesn't support.) */ if (can_calculate_rate && mcs <= MAX_MCS_INDEX && ieee80211_float_htrates[mcs][bandwidth][gi_length] != 0.0) { col_add_fstr(pinfo->cinfo, COL_TX_RATE, "%.1f", ieee80211_float_htrates[mcs][bandwidth][gi_length]); if (tree) { rate_ti = proto_tree_add_float_format(radiotap_tree, hf_radiotap_datarate, tvb, offset, 3, ieee80211_float_htrates[mcs][bandwidth][gi_length], "Data Rate: %.1f Mb/s", ieee80211_float_htrates[mcs][bandwidth][gi_length]); PROTO_ITEM_SET_GENERATED(rate_ti); } } break; } case IEEE80211_RADIOTAP_AMPDU_STATUS: { proto_item *it; proto_tree *ampdu_tree = NULL, *ampdu_flags_tree; guint16 flags; flags = tvb_get_letohs(tvb, offset + 4); if (tree) { it = proto_tree_add_item(radiotap_tree, hf_radiotap_ampdu, tvb, offset, 8, ENC_NA); ampdu_tree = proto_item_add_subtree(it, ett_radiotap_ampdu); proto_tree_add_item(ampdu_tree, hf_radiotap_ampdu_ref, tvb, offset, 4, ENC_LITTLE_ENDIAN); it = proto_tree_add_item(ampdu_tree, hf_radiotap_ampdu_flags, tvb, offset + 4, 2, ENC_LITTLE_ENDIAN); ampdu_flags_tree = proto_item_add_subtree(it, ett_radiotap_ampdu_flags); proto_tree_add_item(ampdu_flags_tree, hf_radiotap_ampdu_flags_report_zerolen, tvb, offset + 4, 2, ENC_LITTLE_ENDIAN); proto_tree_add_item(ampdu_flags_tree, hf_radiotap_ampdu_flags_is_zerolen, tvb, offset + 4, 2, ENC_LITTLE_ENDIAN); proto_tree_add_item(ampdu_flags_tree, hf_radiotap_ampdu_flags_last_known, tvb, offset + 4, 2, ENC_LITTLE_ENDIAN); proto_tree_add_item(ampdu_flags_tree, hf_radiotap_ampdu_flags_is_last, tvb, offset + 4, 2, ENC_LITTLE_ENDIAN); proto_tree_add_item(ampdu_flags_tree, hf_radiotap_ampdu_flags_delim_crc_error, tvb, offset + 4, 2, ENC_LITTLE_ENDIAN); } if (flags & IEEE80211_RADIOTAP_AMPDU_DELIM_CRC_KNOWN) { if (ampdu_tree) proto_tree_add_item(ampdu_tree, hf_radiotap_ampdu_delim_crc, tvb, offset + 6, 1, ENC_NA); } break; } case IEEE80211_RADIOTAP_VHT: { proto_item *it, *it_root = NULL; proto_tree *vht_tree = NULL, *vht_known_tree = NULL, *user_tree = NULL; guint16 known, nsts; guint8 flags, bw, mcs_nss; guint bandwidth = 0; guint gi_length = 0; guint nss = 0; guint mcs = 0; gboolean can_calculate_rate; guint i; /* * Start out assuming that we can calculate the rate; * if we are missing any of the MCS index, channel * width, or guard interval length, we can't. */ can_calculate_rate = TRUE; known = tvb_get_letohs(tvb, offset); flags = tvb_get_guint8(tvb, offset + 2); bw = tvb_get_guint8(tvb, offset + 3); if (tree) { it_root = proto_tree_add_item(radiotap_tree, hf_radiotap_vht, tvb, offset, 12, ENC_NA); vht_tree = proto_item_add_subtree(it_root, ett_radiotap_vht); it = proto_tree_add_item(vht_tree, hf_radiotap_vht_known, tvb, offset, 2, known); vht_known_tree = proto_item_add_subtree(it, ett_radiotap_vht_known); proto_tree_add_item(vht_known_tree, hf_radiotap_vht_have_stbc, tvb, offset, 2, ENC_LITTLE_ENDIAN); proto_tree_add_item(vht_known_tree, hf_radiotap_vht_have_txop_ps, tvb, offset, 2, ENC_LITTLE_ENDIAN); proto_tree_add_item(vht_known_tree, hf_radiotap_vht_have_gi, tvb, offset, 2, ENC_LITTLE_ENDIAN); proto_tree_add_item(vht_known_tree, hf_radiotap_vht_have_sgi_nsym_da, tvb, offset, 2, ENC_LITTLE_ENDIAN); proto_tree_add_item(vht_known_tree, hf_radiotap_vht_have_ldpc_extra, tvb, offset, 2, ENC_LITTLE_ENDIAN); proto_tree_add_item(vht_known_tree, hf_radiotap_vht_have_bf, tvb, offset, 2, ENC_LITTLE_ENDIAN); proto_tree_add_item(vht_known_tree, hf_radiotap_vht_have_bw, tvb, offset, 2, ENC_LITTLE_ENDIAN); proto_tree_add_item(vht_known_tree, hf_radiotap_vht_have_gid, tvb, offset, 2, ENC_LITTLE_ENDIAN); proto_tree_add_item(vht_known_tree, hf_radiotap_vht_have_p_aid, tvb, offset, 2, ENC_LITTLE_ENDIAN); } if (known & IEEE80211_RADIOTAP_VHT_HAVE_STBC) { if (vht_tree) proto_tree_add_item(vht_tree, hf_radiotap_vht_stbc, tvb, offset + 2, 1, ENC_LITTLE_ENDIAN); } if (known & IEEE80211_RADIOTAP_VHT_HAVE_TXOP_PS) { if (vht_tree) proto_tree_add_item(vht_tree, hf_radiotap_vht_txop_ps, tvb, offset + 2, 1, ENC_LITTLE_ENDIAN); } if (known & IEEE80211_RADIOTAP_VHT_HAVE_GI) { gi_length = (flags & IEEE80211_RADIOTAP_VHT_SGI) ? 1 : 0; if (vht_tree) { proto_tree_add_item(vht_tree, hf_radiotap_vht_gi, tvb, offset + 2, 1, ENC_LITTLE_ENDIAN); } } else { can_calculate_rate = FALSE; /* no GI width */ } if (known & IEEE80211_RADIOTAP_VHT_HAVE_SGI_NSYM_DA) { if (vht_tree) { it = proto_tree_add_item(vht_tree, hf_radiotap_vht_sgi_nsym_da, tvb, offset + 2, 1, ENC_LITTLE_ENDIAN); if ((flags & IEEE80211_RADIOTAP_VHT_SGI_NSYM_DA) && (known & IEEE80211_RADIOTAP_VHT_HAVE_GI) && !(flags & IEEE80211_RADIOTAP_VHT_SGI)) proto_item_append_text(it, " (invalid)"); } } if (known & IEEE80211_RADIOTAP_VHT_HAVE_LDPC_EXTRA) { if (vht_tree) { proto_tree_add_item(vht_tree, hf_radiotap_vht_ldpc_extra, tvb, offset + 2, 1, ENC_LITTLE_ENDIAN); } } if (known & IEEE80211_RADIOTAP_VHT_HAVE_BF) { if (vht_tree) proto_tree_add_item(vht_tree, hf_radiotap_vht_bf, tvb, offset + 2, 1, ENC_LITTLE_ENDIAN); } if (known & IEEE80211_RADIOTAP_VHT_HAVE_BW) { if (bw < sizeof(ieee80211_vht_bw2rate_index)/sizeof(ieee80211_vht_bw2rate_index[0])) bandwidth = ieee80211_vht_bw2rate_index[bw]; else can_calculate_rate = FALSE; /* unknown bandwidth */ if (vht_tree) proto_tree_add_item(vht_tree, hf_radiotap_vht_bw, tvb, offset + 3, 1, ENC_LITTLE_ENDIAN); } else { can_calculate_rate = FALSE; /* no bandwidth */ } for(i=0; i<4; i++) { mcs_nss = tvb_get_guint8(tvb, offset + 4 + i); nss = (mcs_nss & IEEE80211_RADIOTAP_VHT_NSS); mcs = (mcs_nss & IEEE80211_RADIOTAP_VHT_MCS) >> 4; if ((known & IEEE80211_RADIOTAP_VHT_HAVE_STBC) && (flags & IEEE80211_RADIOTAP_VHT_STBC)) nsts = 2 * nss; else nsts = nss; if (nss) { if (vht_tree) { it = proto_tree_add_item(vht_tree, hf_radiotap_vht_user, tvb, offset + 4, 5, ENC_NA); proto_item_append_text(it, " %d: MCS %u", i, mcs); user_tree = proto_item_add_subtree(it, ett_radiotap_vht_user); it = proto_tree_add_item(user_tree, hf_radiotap_vht_mcs[i], tvb, offset + 4 + i, 1, ENC_LITTLE_ENDIAN); if (mcs > MAX_MCS_VHT_INDEX) { proto_item_append_text(it, " (invalid)"); } else { proto_item_append_text(it, " (%s %s)", ieee80211_vhtinfo[mcs].modulation, ieee80211_vhtinfo[mcs].coding_rate); } proto_tree_add_item(user_tree, hf_radiotap_vht_nss[i], tvb, offset + 4 + i, 1, ENC_LITTLE_ENDIAN); proto_tree_add_uint(user_tree, hf_radiotap_vht_nsts[i], tvb, offset + 4 + i, 1, nsts); proto_tree_add_item(user_tree, hf_radiotap_vht_coding[i], tvb, offset + 8, 1,ENC_LITTLE_ENDIAN); } if (can_calculate_rate) { float rate = ieee80211_vhtinfo[mcs].rates[bandwidth][gi_length] * nss; if (rate != 0.0f && user_tree) { rate_ti = proto_tree_add_float_format(user_tree, hf_radiotap_vht_datarate[i], tvb, offset, 12, rate, "Data Rate: %.1f Mb/s", rate); PROTO_ITEM_SET_GENERATED(rate_ti); } } } } if (known & IEEE80211_RADIOTAP_VHT_HAVE_GID) { if (vht_tree) proto_tree_add_item(vht_tree, hf_radiotap_vht_gid, tvb, offset+9, 1, ENC_LITTLE_ENDIAN); } if (known & IEEE80211_RADIOTAP_VHT_HAVE_PAID) { if (vht_tree) { proto_tree_add_item(vht_tree, hf_radiotap_vht_p_aid, tvb, offset+10, 2, ENC_LITTLE_ENDIAN); } } break; } } } if (err != -ENOENT && tree) { expert_add_info(pinfo, pt, &ei_radiotap_data_past_header); malformed: proto_item_append_text(ti, " (malformed)"); } /* This handles the case of an FCS exiting at the end of the frame. */ if (rflags & IEEE80211_RADIOTAP_F_FCS) pinfo->pseudo_header->ieee_802_11.fcs_len = 4; else pinfo->pseudo_header->ieee_802_11.fcs_len = 0; hand_off_to_80211: /* Grab the rest of the frame. */ next_tvb = tvb_new_subset_remaining(tvb, length); /* If we had an in-header FCS, check it. * This can only happen if the backward-compat configuration option * is chosen by the user. */ if (hdr_fcs_ti) { /* It would be very strange for the header to have an FCS for the * frame *and* the frame to have the FCS at the end, but it's possible, so * take that into account by using the FCS length recorded in pinfo. */ /* Watch out for [erroneously] short frames */ if (tvb_length(next_tvb) > (unsigned int)pinfo->pseudo_header->ieee_802_11.fcs_len) { calc_fcs = crc32_802_tvb(next_tvb, tvb_length(next_tvb) - pinfo->pseudo_header->ieee_802_11.fcs_len); /* By virtue of hdr_fcs_ti being set, we know that 'tree' is set, * so there's no need to check it here. */ if (calc_fcs == sent_fcs) { proto_item_append_text(hdr_fcs_ti, " [correct]"); } else { proto_item_append_text(hdr_fcs_ti, " [incorrect, should be 0x%08x]", calc_fcs); hidden_item = proto_tree_add_boolean(radiotap_tree, hf_radiotap_fcs_bad, tvb, hdr_fcs_offset, 4, TRUE); PROTO_ITEM_SET_HIDDEN(hidden_item); } } else { proto_item_append_text(hdr_fcs_ti, " [cannot verify - not enough data]"); } } /* dissect the 802.11 header next */ call_dissector((rflags & IEEE80211_RADIOTAP_F_DATAPAD) ? ieee80211_datapad_handle : ieee80211_handle, next_tvb, pinfo, tree); tap_queue_packet(radiotap_tap, pinfo, radiotap_info); } void proto_register_radiotap(void) { static hf_register_info hf[] = { {&hf_radiotap_version, {"Header revision", "radiotap.version", FT_UINT8, BASE_DEC, NULL, 0x0, "Version of radiotap header format", HFILL}}, {&hf_radiotap_pad, {"Header pad", "radiotap.pad", FT_UINT8, BASE_DEC, NULL, 0x0, "Padding", HFILL}}, {&hf_radiotap_length, {"Header length", "radiotap.length", FT_UINT16, BASE_DEC, NULL, 0x0, "Length of header including version, pad, length and data fields", HFILL}}, {&hf_radiotap_present, {"Present flags", "radiotap.present", FT_NONE, BASE_NONE, NULL, 0x0, "Bitmask indicating which fields are present", HFILL}}, #define RADIOTAP_MASK(name) BIT(IEEE80211_RADIOTAP_ ##name) /* Boolean 'present' flags */ {&hf_radiotap_present_tsft, {"TSFT", "radiotap.present.tsft", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(TSFT), "Specifies if the Time Synchronization Function Timer field is present", HFILL}}, {&hf_radiotap_present_flags, {"Flags", "radiotap.present.flags", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(FLAGS), "Specifies if the channel flags field is present", HFILL}}, {&hf_radiotap_present_rate, {"Rate", "radiotap.present.rate", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(RATE), "Specifies if the transmit/receive rate field is present", HFILL}}, {&hf_radiotap_present_channel, {"Channel", "radiotap.present.channel", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(CHANNEL), "Specifies if the transmit/receive frequency field is present", HFILL}}, {&hf_radiotap_present_fhss, {"FHSS", "radiotap.present.fhss", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(FHSS), "Specifies if the hop set and pattern is present for frequency hopping radios", HFILL}}, {&hf_radiotap_present_dbm_antsignal, {"dBm Antenna Signal", "radiotap.present.dbm_antsignal", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(DBM_ANTSIGNAL), "Specifies if the antenna signal strength in dBm is present", HFILL}}, {&hf_radiotap_present_dbm_antnoise, {"dBm Antenna Noise", "radiotap.present.dbm_antnoise", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(DBM_ANTNOISE), "Specifies if the RF noise power at antenna field is present", HFILL}}, {&hf_radiotap_present_lock_quality, {"Lock Quality", "radiotap.present.lock_quality", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(LOCK_QUALITY), "Specifies if the signal quality field is present", HFILL}}, {&hf_radiotap_present_tx_attenuation, {"TX Attenuation", "radiotap.present.tx_attenuation", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(TX_ATTENUATION), "Specifies if the transmit power distance from max power field is present", HFILL}}, {&hf_radiotap_present_db_tx_attenuation, {"dB TX Attenuation", "radiotap.present.db_tx_attenuation", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(DB_TX_ATTENUATION), "Specifies if the transmit power distance from max power (in dB) field is present", HFILL}}, {&hf_radiotap_present_dbm_tx_power, {"dBm TX Power", "radiotap.present.dbm_tx_power", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(DBM_TX_POWER), "Specifies if the transmit power (in dBm) field is present", HFILL}}, {&hf_radiotap_present_antenna, {"Antenna", "radiotap.present.antenna", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(ANTENNA), "Specifies if the antenna number field is present", HFILL}}, {&hf_radiotap_present_db_antsignal, {"dB Antenna Signal", "radiotap.present.db_antsignal", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(DB_ANTSIGNAL), "Specifies if the RF signal power at antenna in dB field is present", HFILL}}, {&hf_radiotap_present_db_antnoise, {"dB Antenna Noise", "radiotap.present.db_antnoise", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(DB_ANTNOISE), "Specifies if the RF signal power at antenna in dBm field is present", HFILL}}, {&hf_radiotap_present_rxflags, {"RX flags", "radiotap.present.rxflags", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(RX_FLAGS), "Specifies if the RX flags field is present", HFILL}}, {&hf_radiotap_present_hdrfcs, {"FCS in header", "radiotap.present.fcs", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(RX_FLAGS), "Specifies if the FCS field is present", HFILL}}, {&hf_radiotap_present_xchannel, {"Channel+", "radiotap.present.xchannel", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(XCHANNEL), "Specifies if the extended channel info field is present", HFILL}}, {&hf_radiotap_present_mcs, {"HT information", "radiotap.present.mcs", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(MCS), "Specifies if the HT field is present", HFILL}}, {&hf_radiotap_present_ampdu, {"A-MPDU Status", "radiotap.present.ampdu", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(AMPDU_STATUS), "Specifies if the A-MPDU status field is present", HFILL}}, {&hf_radiotap_present_vht, {"VHT information", "radiotap.present.vht", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(VHT), "Specifies if the VHT field is present", HFILL}}, {&hf_radiotap_present_reserved, {"Reserved", "radiotap.present.reserved", FT_UINT32, BASE_HEX, NULL, IEEE80211_RADIOTAP_NOTDEFINED, "Not (yet) defined present flag (Must be zero)", HFILL}}, {&hf_radiotap_present_rtap_ns, {"Radiotap NS next", "radiotap.present.rtap_ns", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(RADIOTAP_NAMESPACE), "Specifies a reset to the radiotap namespace", HFILL}}, {&hf_radiotap_present_vendor_ns, {"Vendor NS next", "radiotap.present.vendor_ns", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(VENDOR_NAMESPACE), "Specifies that the next bitmap is in a vendor namespace", HFILL}}, {&hf_radiotap_present_ext, {"Ext", "radiotap.present.ext", FT_BOOLEAN, 32, NULL, RADIOTAP_MASK(EXT), "Specifies if there are any extensions to the header present", HFILL}}, /* Boolean 'present.flags' flags */ {&hf_radiotap_flags, {"Flags", "radiotap.flags", FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL}}, {&hf_radiotap_flags_cfp, {"CFP", "radiotap.flags.cfp", FT_BOOLEAN, 8, NULL, IEEE80211_RADIOTAP_F_CFP, "Sent/Received during CFP", HFILL}}, {&hf_radiotap_flags_preamble, {"Preamble", "radiotap.flags.preamble", FT_BOOLEAN, 8, TFS(&preamble_type), IEEE80211_RADIOTAP_F_SHORTPRE, "Sent/Received with short preamble", HFILL}}, {&hf_radiotap_flags_wep, {"WEP", "radiotap.flags.wep", FT_BOOLEAN, 8, NULL, IEEE80211_RADIOTAP_F_WEP, "Sent/Received with WEP encryption", HFILL}}, {&hf_radiotap_flags_frag, {"Fragmentation", "radiotap.flags.frag", FT_BOOLEAN, 8, NULL, IEEE80211_RADIOTAP_F_FRAG, "Sent/Received with fragmentation", HFILL}}, {&hf_radiotap_flags_fcs, {"FCS at end", "radiotap.flags.fcs", FT_BOOLEAN, 8, NULL, IEEE80211_RADIOTAP_F_FCS, "Frame includes FCS at end", HFILL}}, {&hf_radiotap_flags_datapad, {"Data Pad", "radiotap.flags.datapad", FT_BOOLEAN, 8, NULL, IEEE80211_RADIOTAP_F_DATAPAD, "Frame has padding between 802.11 header and payload", HFILL}}, {&hf_radiotap_flags_badfcs, {"Bad FCS", "radiotap.flags.badfcs", FT_BOOLEAN, 8, NULL, IEEE80211_RADIOTAP_F_BADFCS, "Frame received with bad FCS", HFILL}}, {&hf_radiotap_flags_shortgi, {"Short GI", "radiotap.flags.shortgi", FT_BOOLEAN, 8, NULL, IEEE80211_RADIOTAP_F_SHORTGI, "Frame Sent/Received with HT short Guard Interval", HFILL}}, {&hf_radiotap_mactime, {"MAC timestamp", "radiotap.mactime", FT_UINT64, BASE_DEC, NULL, 0x0, "Value in microseconds of the MAC's Time Synchronization Function timer" " when the first bit of the MPDU arrived at the MAC.", HFILL}}, {&hf_radiotap_quality, {"Signal Quality", "radiotap.quality", FT_UINT16, BASE_DEC, NULL, 0x0, "Signal quality (unitless measure)", HFILL}}, {&hf_radiotap_fcs, {"802.11 FCS", "radiotap.fcs", FT_UINT32, BASE_HEX, NULL, 0x0, "Frame check sequence of this frame", HFILL}}, #if 0 {&hf_radiotap_channel, {"Channel", "radiotap.channel", FT_UINT32, BASE_DEC, NULL, 0x0, "802.11 channel number that this frame was sent/received on", HFILL}}, #endif {&hf_radiotap_channel_frequency, {"Channel frequency", "radiotap.channel.freq", FT_UINT32, BASE_DEC, NULL, 0x0, "Channel frequency in megahertz that this frame was sent/received on", HFILL}}, {&hf_radiotap_channel_flags, {"Channel type", "radiotap.channel.type", FT_UINT16, BASE_HEX | BASE_EXT_STRING, &phy_type_ext, 0x0, NULL, HFILL}}, {&hf_radiotap_channel_flags_turbo, {"Turbo", "radiotap.channel.type.turbo", FT_BOOLEAN, 16, NULL, 0x0010, "Channel Type Turbo", HFILL}}, {&hf_radiotap_channel_flags_cck, {"Complementary Code Keying (CCK)", "radiotap.channel.type.cck", FT_BOOLEAN, 16, NULL, 0x0020, "Channel Type Complementary Code Keying (CCK) Modulation", HFILL}}, {&hf_radiotap_channel_flags_ofdm, {"Orthogonal Frequency-Division Multiplexing (OFDM)", "radiotap.channel.type.ofdm", FT_BOOLEAN, 16, NULL, 0x0040, "Channel Type Orthogonal Frequency-Division Multiplexing (OFDM)", HFILL}}, {&hf_radiotap_channel_flags_2ghz, {"2 GHz spectrum", "radiotap.channel.type.2ghz", FT_BOOLEAN, 16, NULL, 0x0080, "Channel Type 2 GHz spectrum", HFILL}}, {&hf_radiotap_channel_flags_5ghz, {"5 GHz spectrum", "radiotap.channel.type.5ghz", FT_BOOLEAN, 16, NULL, 0x0100, "Channel Type 5 GHz spectrum", HFILL}}, {&hf_radiotap_channel_flags_passive, {"Passive", "radiotap.channel.type.passive", FT_BOOLEAN, 16, NULL, 0x0200, "Channel Type Passive", HFILL}}, {&hf_radiotap_channel_flags_dynamic, {"Dynamic CCK-OFDM", "radiotap.channel.type.dynamic", FT_BOOLEAN, 16, NULL, 0x0400, "Channel Type Dynamic CCK-OFDM Channel", HFILL}}, {&hf_radiotap_channel_flags_gfsk, {"Gaussian Frequency Shift Keying (GFSK)", "radiotap.channel.type.gfsk", FT_BOOLEAN, 16, NULL, 0x0800, "Channel Type Gaussian Frequency Shift Keying (GFSK) Modulation", HFILL}}, {&hf_radiotap_channel_flags_gsm, {"GSM (900MHz)", "radiotap.channel.type.gsm", FT_BOOLEAN, 16, NULL, 0x1000, "Channel Type GSM", HFILL}}, {&hf_radiotap_channel_flags_sturbo, {"Static Turbo", "radiotap.channel.type.sturbo", FT_BOOLEAN, 16, NULL, 0x2000, "Channel Type Status Turbo", HFILL}}, {&hf_radiotap_channel_flags_half, {"Half Rate Channel (10MHz Channel Width)", "radiotap.channel.type.half", FT_BOOLEAN, 16, NULL, 0x4000, "Channel Type Half Rate", HFILL}}, {&hf_radiotap_channel_flags_quarter, {"Quarter Rate Channel (5MHz Channel Width)", "radiotap.channel.type.quarter", FT_BOOLEAN, 16, NULL, 0x8000, "Channel Type Quarter Rate", HFILL}}, {&hf_radiotap_rxflags, {"RX flags", "radiotap.rxflags", FT_UINT16, BASE_HEX, NULL, 0x0, NULL, HFILL}}, {&hf_radiotap_rxflags_badplcp, {"Bad PLCP", "radiotap.rxflags.badplcp", FT_BOOLEAN, 24, NULL, IEEE80211_RADIOTAP_F_RX_BADPLCP, "Frame with bad PLCP", HFILL}}, {&hf_radiotap_xchannel, {"Channel number", "radiotap.xchannel", FT_UINT32, BASE_DEC, NULL, 0x0, NULL, HFILL}}, {&hf_radiotap_xchannel_frequency, {"Channel frequency", "radiotap.xchannel.freq", FT_UINT32, BASE_DEC, NULL, 0x0, NULL, HFILL}}, {&hf_radiotap_xchannel_flags, {"Channel type", "radiotap.xchannel.flags", FT_UINT32, BASE_HEX | BASE_EXT_STRING, &phy_type_ext, 0x0, NULL, HFILL}}, {&hf_radiotap_xchannel_flags_turbo, {"Turbo", "radiotap.xchannel.type.turbo", FT_BOOLEAN, 24, NULL, 0x0010, "Channel Type Turbo", HFILL}}, {&hf_radiotap_xchannel_flags_cck, {"Complementary Code Keying (CCK)", "radiotap.xchannel.type.cck", FT_BOOLEAN, 24, NULL, 0x0020, "Channel Type Complementary Code Keying (CCK) Modulation", HFILL}}, {&hf_radiotap_xchannel_flags_ofdm, {"Orthogonal Frequency-Division Multiplexing (OFDM)", "radiotap.xchannel.type.ofdm", FT_BOOLEAN, 24, NULL, 0x0040, "Channel Type Orthogonal Frequency-Division Multiplexing (OFDM)", HFILL}}, {&hf_radiotap_xchannel_flags_2ghz, {"2 GHz spectrum", "radiotap.xchannel.type.2ghz", FT_BOOLEAN, 24, NULL, 0x0080, "Channel Type 2 GHz spectrum", HFILL}}, {&hf_radiotap_xchannel_flags_5ghz, {"5 GHz spectrum", "radiotap.xchannel.type.5ghz", FT_BOOLEAN, 24, NULL, 0x0100, "Channel Type 5 GHz spectrum", HFILL}}, {&hf_radiotap_xchannel_flags_passive, {"Passive", "radiotap.channel.xtype.passive", FT_BOOLEAN, 24, NULL, 0x0200, "Channel Type Passive", HFILL}}, {&hf_radiotap_xchannel_flags_dynamic, {"Dynamic CCK-OFDM", "radiotap.xchannel.type.dynamic", FT_BOOLEAN, 24, NULL, 0x0400, "Channel Type Dynamic CCK-OFDM Channel", HFILL}}, {&hf_radiotap_xchannel_flags_gfsk, {"Gaussian Frequency Shift Keying (GFSK)", "radiotap.xchannel.type.gfsk", FT_BOOLEAN, 24, NULL, 0x0800, "Channel Type Gaussian Frequency Shift Keying (GFSK) Modulation", HFILL}}, {&hf_radiotap_xchannel_flags_gsm, {"GSM (900MHz)", "radiotap.xchannel.type.gsm", FT_BOOLEAN, 24, NULL, 0x1000, "Channel Type GSM", HFILL}}, {&hf_radiotap_xchannel_flags_sturbo, {"Static Turbo", "radiotap.xchannel.type.sturbo", FT_BOOLEAN, 24, NULL, 0x2000, "Channel Type Status Turbo", HFILL}}, {&hf_radiotap_xchannel_flags_half, {"Half Rate Channel (10MHz Channel Width)", "radiotap.xchannel.type.half", FT_BOOLEAN, 24, NULL, 0x4000, "Channel Type Half Rate", HFILL}}, {&hf_radiotap_xchannel_flags_quarter, {"Quarter Rate Channel (5MHz Channel Width)", "radiotap.xchannel.type.quarter", FT_BOOLEAN, 24, NULL, 0x8000, "Channel Type Quarter Rate", HFILL}}, {&hf_radiotap_xchannel_flags_ht20, {"HT Channel (20MHz Channel Width)", "radiotap.xchannel.type.ht20", FT_BOOLEAN, 24, NULL, 0x10000, "Channel Type HT/20", HFILL}}, {&hf_radiotap_xchannel_flags_ht40u, {"HT Channel (40MHz Channel Width with Extension channel above)", "radiotap.xchannel.type.ht40u", FT_BOOLEAN, 24, NULL, 0x20000, "Channel Type HT/40+", HFILL}}, {&hf_radiotap_xchannel_flags_ht40d, {"HT Channel (40MHz Channel Width with Extension channel below)", "radiotap.xchannel.type.ht40d", FT_BOOLEAN, 24, NULL, 0x40000, "Channel Type HT/40-", HFILL}}, #if 0 {&hf_radiotap_xchannel_maxpower, {"Max transmit power", "radiotap.xchannel.maxpower", FT_UINT32, BASE_DEC, NULL, 0x0, NULL, HFILL}}, #endif {&hf_radiotap_fhss_hopset, {"FHSS Hop Set", "radiotap.fhss.hopset", FT_UINT8, BASE_DEC, NULL, 0x0, "Frequency Hopping Spread Spectrum hopset", HFILL}}, {&hf_radiotap_fhss_pattern, {"FHSS Pattern", "radiotap.fhss.pattern", FT_UINT8, BASE_DEC, NULL, 0x0, "Frequency Hopping Spread Spectrum hop pattern", HFILL}}, {&hf_radiotap_datarate, {"Data rate (Mb/s)", "radiotap.datarate", FT_FLOAT, BASE_NONE, NULL, 0x0, "Speed this frame was sent/received at", HFILL}}, {&hf_radiotap_antenna, {"Antenna", "radiotap.antenna", FT_UINT32, BASE_DEC, NULL, 0x0, "Antenna number this frame was sent/received over (starting at 0)", HFILL}}, {&hf_radiotap_dbm_antsignal, {"SSI Signal", "radiotap.dbm_antsignal", FT_INT32, BASE_DEC, NULL, 0x0, "RF signal power at the antenna from a fixed," " arbitrary value in decibels from one milliwatt", HFILL}}, {&hf_radiotap_db_antsignal, {"SSI Signal", "radiotap.db_antsignal", FT_UINT32, BASE_DEC, NULL, 0x0, "RF signal power at the antenna from a fixed, arbitrary value in decibels", HFILL}}, {&hf_radiotap_dbm_antnoise, {"SSI Noise", "radiotap.dbm_antnoise", FT_INT32, BASE_DEC, NULL, 0x0, "RF noise power at the antenna from a fixed, arbitrary value" " in decibels per one milliwatt", HFILL}}, {&hf_radiotap_db_antnoise, {"SSI Noise", "radiotap.db_antnoise", FT_UINT32, BASE_DEC, NULL, 0x0, "RF noise power at the antenna from a fixed, arbitrary value" " in decibels", HFILL}}, {&hf_radiotap_tx_attenuation, {"Transmit attenuation", "radiotap.txattenuation", FT_UINT16, BASE_DEC, NULL, 0x0, "Transmit power expressed as unitless distance from max power" " set at factory (0 is max power)", HFILL}}, {&hf_radiotap_db_tx_attenuation, {"Transmit attenuation (dB)", "radiotap.db_txattenuation", FT_UINT16, BASE_DEC, NULL, 0x0, "Transmit power expressed as decibels from max power" " set at factory (0 is max power)", HFILL}}, {&hf_radiotap_txpower, {"Transmit power", "radiotap.txpower", FT_INT32, BASE_DEC, NULL, 0x0, "Transmit power in decibels per one milliwatt (dBm)", HFILL}}, {&hf_radiotap_mcs, {"MCS information", "radiotap.mcs", FT_NONE, BASE_NONE, NULL, 0x0, NULL, HFILL}}, {&hf_radiotap_mcs_known, {"Known MCS information", "radiotap.mcs.known", FT_UINT8, BASE_HEX, NULL, 0x0, "Bit mask indicating what MCS information is present", HFILL}}, {&hf_radiotap_mcs_have_bw, {"Bandwidth", "radiotap.mcs.have_bw", FT_BOOLEAN, 8, NULL, IEEE80211_RADIOTAP_MCS_HAVE_BW, "Bandwidth information present", HFILL}}, {&hf_radiotap_mcs_have_gi, {"Guard interval", "radiotap.mcs.have_gi", FT_BOOLEAN, 8, NULL, IEEE80211_RADIOTAP_MCS_HAVE_GI, "Sent/Received guard interval information present", HFILL}}, {&hf_radiotap_mcs_have_format, {"Format", "radiotap.mcs.have_format", FT_BOOLEAN, 8, NULL, IEEE80211_RADIOTAP_MCS_HAVE_FMT, "Format information present", HFILL}}, {&hf_radiotap_mcs_have_fec, {"FEC", "radiotap.mcs.have_fec", FT_BOOLEAN, 8, NULL, IEEE80211_RADIOTAP_MCS_HAVE_FEC, "Forward error correction information present", HFILL}}, {&hf_radiotap_mcs_have_stbc, {"STBC", "radiotap.mcs.have_stbc", FT_BOOLEAN, 8, NULL, IEEE80211_RADIOTAP_MCS_HAVE_STBC, "Space Time Block Coding information present", HFILL}}, {&hf_radiotap_mcs_have_index, {"MCS index", "radiotap.mcs.have_index", FT_BOOLEAN, 8, NULL, IEEE80211_RADIOTAP_MCS_HAVE_MCS, "MCS index information present", HFILL}}, {&hf_radiotap_mcs_bw, {"Bandwidth", "radiotap.mcs.bw", FT_UINT8, BASE_DEC, VALS(mcs_bandwidth), IEEE80211_RADIOTAP_MCS_BW_MASK, NULL, HFILL}}, {&hf_radiotap_mcs_gi, {"Guard interval", "radiotap.mcs.gi", FT_UINT8, BASE_DEC, VALS(mcs_gi), IEEE80211_RADIOTAP_MCS_SGI, "Sent/Received guard interval", HFILL}}, {&hf_radiotap_mcs_format, {"Format", "radiotap.mcs.format", FT_UINT8, BASE_DEC, VALS(mcs_format), IEEE80211_RADIOTAP_MCS_FMT_GF, NULL, HFILL}}, {&hf_radiotap_mcs_fec, {"FEC", "radiotap.mcs.fec", FT_UINT8, BASE_DEC, VALS(mcs_fec), IEEE80211_RADIOTAP_MCS_FEC_LDPC, "forward error correction", HFILL}}, {&hf_radiotap_mcs_stbc, {"STBC", "radiotap.mcs.stbc", FT_BOOLEAN, 8, TFS(&tfs_on_off), IEEE80211_RADIOTAP_MCS_STBC, "Space Time Block Code", HFILL}}, {&hf_radiotap_mcs_index, {"MCS index", "radiotap.mcs.index", FT_UINT8, BASE_DEC, NULL, 0x0, NULL, HFILL}}, {&hf_radiotap_ampdu, {"A-MPDU status", "radiotap.ampdu", FT_NONE, BASE_NONE, NULL, 0x0, NULL, HFILL}}, {&hf_radiotap_ampdu_ref, {"A-MPDU reference number", "radiotap.ampdu.reference", FT_UINT32, BASE_DEC, NULL, 0x0, NULL, HFILL}}, {&hf_radiotap_ampdu_flags, {"A-MPDU flags", "radiotap.ampdu.flags", FT_UINT16, BASE_HEX, NULL, 0x0, "A-MPDU status flags", HFILL}}, {&hf_radiotap_ampdu_flags_report_zerolen, {"Driver reports 0-length subframes in this A-MPDU", "radiotap.ampdu.flags.report_zerolen", FT_BOOLEAN, 16, NULL, IEEE80211_RADIOTAP_AMPDU_REPORT_ZEROLEN, NULL, HFILL}}, {&hf_radiotap_ampdu_flags_is_zerolen, {"This is a 0-length subframe", "radiotap.ampdu.flags.is_zerolen", FT_BOOLEAN, 16, NULL, IEEE80211_RADIOTAP_AMPDU_IS_ZEROLEN, NULL, HFILL}}, {&hf_radiotap_ampdu_flags_last_known, {"Last subframe of this A-MPDU is known", "radiotap.ampdu.flags.lastknown", FT_BOOLEAN, 16, NULL, IEEE80211_RADIOTAP_AMPDU_LAST_KNOWN, NULL, HFILL}}, {&hf_radiotap_ampdu_flags_is_last, {"This is the last subframe of this A-MPDU", "radiotap.ampdu.flags.last", FT_BOOLEAN, 16, NULL, IEEE80211_RADIOTAP_AMPDU_IS_LAST, NULL, HFILL}}, {&hf_radiotap_ampdu_flags_delim_crc_error, {"Delimiter CRC error on this subframe", "radiotap.ampdu.flags.delim_crc_error", FT_BOOLEAN, 16, NULL, IEEE80211_RADIOTAP_AMPDU_DELIM_CRC_ERR, NULL, HFILL}}, {&hf_radiotap_ampdu_delim_crc, {"A-MPDU subframe delimiter CRC", "radiotap.ampdu.delim_crc", FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL}}, {&hf_radiotap_vht, {"VHT information", "radiotap.vht", FT_NONE, BASE_NONE, NULL, 0x0, NULL, HFILL}}, {&hf_radiotap_vht_known, {"Known VHT information", "radiotap.vht.known", FT_UINT8, BASE_HEX, NULL, 0x0, "Bit mask indicating what VHT information is present", HFILL}}, {&hf_radiotap_vht_user, {"User", "radiotap.vht.user", FT_NONE, BASE_NONE, NULL, 0x0, NULL, HFILL}}, {&hf_radiotap_vht_have_stbc, {"STBC", "radiotap.vht.have_stbc", FT_BOOLEAN, 16, NULL, IEEE80211_RADIOTAP_VHT_HAVE_STBC, "Space Time Block Coding information present", HFILL}}, {&hf_radiotap_vht_have_txop_ps, {"TXOP_PS_NOT_ALLOWED", "radiotap.vht.have_txop_ps", FT_BOOLEAN, 16, NULL, IEEE80211_RADIOTAP_VHT_HAVE_TXOP_PS, "TXOP_PS_NOT_ALLOWED information present", HFILL}}, {&hf_radiotap_vht_have_gi, {"Guard interval", "radiotap.vht.have_gi", FT_BOOLEAN, 16, NULL, IEEE80211_RADIOTAP_VHT_HAVE_GI, "Short/Long guard interval information present", HFILL}}, {&hf_radiotap_vht_have_sgi_nsym_da, {"SGI Nsym disambiguation", "radiotap.vht.have_sgi_nsym_da", FT_BOOLEAN, 16, NULL, IEEE80211_RADIOTAP_VHT_HAVE_SGI_NSYM_DA, "Short guard interval Nsym disambiguation information present", HFILL}}, {&hf_radiotap_vht_have_ldpc_extra, {"LDPC extra OFDM symbol", "radiotap.vht.ldpc_extra", FT_BOOLEAN, 16, NULL, IEEE80211_RADIOTAP_VHT_HAVE_LDPC_EXTRA, NULL, HFILL}}, {&hf_radiotap_vht_have_bf, {"Beamformed", "radiotap.vht.have_beamformed", FT_BOOLEAN, 16, NULL, IEEE80211_RADIOTAP_VHT_HAVE_BF, NULL, HFILL}}, {&hf_radiotap_vht_have_bw, {"Bandwidth", "radiotap.mcs.have_bw", FT_BOOLEAN, 16, NULL, IEEE80211_RADIOTAP_VHT_HAVE_BW, NULL, HFILL}}, {&hf_radiotap_vht_have_gid, {"Group ID", "radiotap.mcs.have_gid", FT_BOOLEAN, 16, NULL, IEEE80211_RADIOTAP_VHT_HAVE_GID, NULL, HFILL}}, {&hf_radiotap_vht_have_p_aid, {"Partial AID", "radiotap.mcs.have_paid", FT_BOOLEAN, 16, NULL, IEEE80211_RADIOTAP_VHT_HAVE_PAID, NULL, HFILL}}, {&hf_radiotap_vht_stbc, {"STBC", "radiotap.vht.stbc", FT_BOOLEAN, 8, TFS(&tfs_on_off), IEEE80211_RADIOTAP_VHT_STBC, "Space Time Block Coding flag", HFILL}}, {&hf_radiotap_vht_txop_ps, {"TXOP_PS_NOT_ALLOWED", "radiotap.vht.txop_ps", FT_BOOLEAN, 8, NULL, IEEE80211_RADIOTAP_VHT_TXOP_PS, "Flag indicating whether STAs may doze during TXOP", HFILL}}, {&hf_radiotap_vht_gi, {"Guard interval", "radiotap.vht.gi", FT_UINT8, BASE_DEC, VALS(mcs_gi), IEEE80211_RADIOTAP_VHT_SGI, "Short/Long guard interval", HFILL}}, {&hf_radiotap_vht_sgi_nsym_da, {"SGI Nsym disambiguation", "radiotap.vht.sgi_nsym_da", FT_BOOLEAN, 8, NULL, IEEE80211_RADIOTAP_VHT_SGI_NSYM_DA, "Short Guard Interval Nsym disambiguation", HFILL}}, {&hf_radiotap_vht_ldpc_extra, {"LDPC extra OFDM symbol", "radiotap.vht.ldpc_extra", FT_BOOLEAN, 8, NULL, IEEE80211_RADIOTAP_VHT_LDPC_EXTRA, NULL, HFILL}}, {&hf_radiotap_vht_bf, {"Beamformed", "radiotap.vht.beamformed", FT_BOOLEAN, 8, NULL, IEEE80211_RADIOTAP_VHT_BF, NULL, HFILL}}, {&hf_radiotap_vht_bw, {"Bandwidth", "radiotap.vht.bw", FT_UINT8, BASE_DEC | BASE_EXT_STRING, &vht_bandwidth_ext, 0x0, NULL, HFILL}}, {&hf_radiotap_vht_nsts[0], {"Space-time streams 0", "radiotap.vht.nsts.0", FT_UINT8, BASE_DEC, NULL, 0x0, "Number of Space-time streams", HFILL}}, {&hf_radiotap_vht_nsts[1], {"Space-time streams 1", "radiotap.vht.nsts.1", FT_UINT8, BASE_DEC, NULL, 0x0, "Number of Space-time streams", HFILL}}, {&hf_radiotap_vht_nsts[2], {"Space-time streams 2", "radiotap.vht.nsts.2", FT_UINT8, BASE_DEC, NULL, 0x0, "Number of Space-time streams", HFILL}}, {&hf_radiotap_vht_nsts[3], {"Space-time streams 3", "radiotap.vht.nsts.3", FT_UINT8, BASE_DEC, NULL, 0x0, "Number of Space-time streams", HFILL}}, {&hf_radiotap_vht_mcs[0], {"MCS index 0", "radiotap.vht.mcs.0", FT_UINT8, BASE_DEC, NULL, IEEE80211_RADIOTAP_VHT_MCS, "MCS index", HFILL}}, {&hf_radiotap_vht_mcs[1], {"MCS index 1", "radiotap.vht.mcs.1", FT_UINT8, BASE_DEC, NULL, IEEE80211_RADIOTAP_VHT_MCS, "MCS index", HFILL}}, {&hf_radiotap_vht_mcs[2], {"MCS index 2", "radiotap.vht.mcs.2", FT_UINT8, BASE_DEC, NULL, IEEE80211_RADIOTAP_VHT_MCS, "MCS index", HFILL}}, {&hf_radiotap_vht_mcs[3], {"MCS index 3", "radiotap.vht.mcs.3", FT_UINT8, BASE_DEC, NULL, IEEE80211_RADIOTAP_VHT_MCS, "MCS index", HFILL}}, {&hf_radiotap_vht_nss[0], {"Spatial streams 0", "radiotap.vht.nss.0", FT_UINT8, BASE_DEC, NULL, IEEE80211_RADIOTAP_VHT_NSS, "Number of spatial streams", HFILL}}, {&hf_radiotap_vht_nss[1], {"Spatial streams 1", "radiotap.vht.nss.1", FT_UINT8, BASE_DEC, NULL, IEEE80211_RADIOTAP_VHT_NSS, "Number of spatial streams", HFILL}}, {&hf_radiotap_vht_nss[2], {"Spatial streams 2", "radiotap.vht.nss.2", FT_UINT8, BASE_DEC, NULL, IEEE80211_RADIOTAP_VHT_NSS, "Number of spatial streams", HFILL}}, {&hf_radiotap_vht_nss[3], {"Spatial streams 3", "radiotap.vht.nss.3", FT_UINT8, BASE_DEC, NULL, IEEE80211_RADIOTAP_VHT_NSS, "Number of spatial streams", HFILL}}, {&hf_radiotap_vht_coding[0], {"Coding 0", "radiotap.vht.coding.0", FT_UINT8, BASE_DEC, VALS(mcs_fec), 0x0, "Coding", HFILL}}, {&hf_radiotap_vht_coding[1], {"Coding 1", "radiotap.vht.coding.1", FT_UINT8, BASE_DEC, VALS(mcs_fec), 0x0, "Coding", HFILL}}, {&hf_radiotap_vht_coding[2], {"Coding 2", "radiotap.vht.coding.2", FT_UINT8, BASE_DEC, VALS(mcs_fec), 0x0, "Coding", HFILL}}, {&hf_radiotap_vht_coding[3], {"Coding 3", "radiotap.vht.coding.3", FT_UINT8, BASE_DEC, VALS(mcs_fec), 0x0, "Coding", HFILL}}, {&hf_radiotap_vht_datarate[0], {"Data rate (Mb/s) 0", "radiotap.vht.datarate.0", FT_FLOAT, BASE_NONE, NULL, 0x0, "Speed this frame was sent/received at", HFILL}}, {&hf_radiotap_vht_datarate[1], {"Data rate (Mb/s) 1", "radiotap.vht.datarate.1", FT_FLOAT, BASE_NONE, NULL, 0x0, "Speed this frame was sent/received at", HFILL}}, {&hf_radiotap_vht_datarate[2], {"Data rate (Mb/s) 2", "radiotap.vht.datarate.2", FT_FLOAT, BASE_NONE, NULL, 0x0, "Speed this frame was sent/received at", HFILL}}, {&hf_radiotap_vht_datarate[3], {"Data rate (Mb/s) 3", "radiotap.vht.datarate.3", FT_FLOAT, BASE_NONE, NULL, 0x0, "Speed this frame was sent/received at", HFILL}}, {&hf_radiotap_vht_gid, {"Group Id", "radiotap.vht.gid", FT_UINT8, BASE_DEC, NULL, 0x0, NULL, HFILL}}, {&hf_radiotap_vht_p_aid, {"Partial AID", "radiotap.vht.paid", FT_UINT16, BASE_DEC, NULL, 0x0, NULL, HFILL}}, {&hf_radiotap_vendor_ns, {"Vendor namespace", "radiotap.vendor_namespace", FT_BYTES, BASE_NONE, NULL, 0x0, NULL, HFILL}}, {&hf_radiotap_ven_oui, {"Vendor OUI", "radiotap.vendor_oui", FT_BYTES, BASE_NONE, NULL, 0x0, NULL, HFILL}}, {&hf_radiotap_ven_subns, {"Vendor sub namespace", "radiotap.vendor_subns", FT_UINT8, BASE_DEC, NULL, 0x0, "Vendor-specified sub namespace", HFILL}}, {&hf_radiotap_ven_skip, {"Vendor data length", "radiotap.vendor_data_len", FT_UINT16, BASE_DEC, NULL, 0x0, "Length of vendor-specified data", HFILL}}, {&hf_radiotap_ven_data, {"Vendor data", "radiotap.vendor_data", FT_NONE, BASE_NONE, NULL, 0x0, "Vendor-specified data", HFILL}}, /* Special variables */ {&hf_radiotap_fcs_bad, {"Bad FCS", "radiotap.fcs_bad", FT_BOOLEAN, BASE_NONE, NULL, 0x0, "Specifies if this frame has a bad frame check sequence", HFILL}}, }; static gint *ett[] = { &ett_radiotap, &ett_radiotap_present, &ett_radiotap_flags, &ett_radiotap_rxflags, &ett_radiotap_channel_flags, &ett_radiotap_xchannel_flags, &ett_radiotap_vendor, &ett_radiotap_mcs, &ett_radiotap_mcs_known, &ett_radiotap_ampdu, &ett_radiotap_ampdu_flags, &ett_radiotap_vht, &ett_radiotap_vht_known, &ett_radiotap_vht_user }; static ei_register_info ei[] = { { &ei_radiotap_present, { "radiotap.present.radiotap_and_vendor", PI_MALFORMED, PI_ERROR, "Both radiotap and vendor namespace specified in bitmask word", EXPFILL }}, { &ei_radiotap_present_reserved, { "radiotap.present.reserved.unknown", PI_UNDECODED, PI_NOTE, "Unknown Radiotap fields, code not implemented, Please check radiotap documentation, Contact Wireshark developers if you want this supported", EXPFILL }}, { &ei_radiotap_data_past_header, { "radiotap.data_past_header", PI_MALFORMED, PI_ERROR, "Radiotap data goes past the end of the radiotap header", EXPFILL }}, }; module_t *radiotap_module; expert_module_t* expert_radiotap; proto_radiotap = proto_register_protocol("IEEE 802.11 Radiotap Capture header", "802.11 Radiotap", "radiotap"); proto_register_field_array(proto_radiotap, hf, array_length(hf)); proto_register_subtree_array(ett, array_length(ett)); expert_radiotap = expert_register_protocol(proto_radiotap); expert_register_field_array(expert_radiotap, ei, array_length(ei)); register_dissector("radiotap", dissect_radiotap, proto_radiotap); radiotap_tap = register_tap("radiotap"); radiotap_module = prefs_register_protocol(proto_radiotap, NULL); prefs_register_bool_preference(radiotap_module, "bit14_fcs_in_header", "Assume bit 14 means FCS in header", "Radiotap has a bit to indicate whether the FCS is still on the frame or not. " "Some generators (e.g. AirPcap) use a non-standard radiotap flag 14 to put " "the FCS into the header.", &radiotap_bit14_fcs); } void proto_reg_handoff_radiotap(void) { dissector_handle_t radiotap_handle; /* handle for 802.11 dissector */ ieee80211_handle = find_dissector("wlan"); ieee80211_datapad_handle = find_dissector("wlan_datapad"); radiotap_handle = find_dissector("radiotap"); dissector_add_uint("wtap_encap", WTAP_ENCAP_IEEE_802_11_RADIOTAP, radiotap_handle); } /* * Editor modelines - http://www.wireshark.org/tools/modelines.html * * Local variables: * c-basic-offset: 8 * tab-width: 8 * indent-tabs-mode: t * End: * * vi: set shiftwidth=8 tabstop=8 noexpandtab: * :indentSize=8:tabSize=8:noTabs=false: */