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IEEE80211_RADIOTAP(9)	 BSD Kernel Developer's Manual	 IEEE80211_RADIOTAP(9)

     ieee80211_radiotap — 802.11 device packet capture support

     #include <net80211/ieee80211_var.h>

     ieee80211_radiotap_attach(struct ieee80211com *,
	 struct ieee80211_radiotap_header *th, int tlen, uint32_t tx_radiotap,
	 struct ieee80211_radiotap_header *rh, int rlen,
	 uint32_t rx_radiotap);

     ieee80211_radiotap_active_vap(struct ieee80211vap *);

     ieee80211_radiotap_active(struct ieee80211com *);

     ieee80211_radiotap_tx(struct ieee80211vap *, struct mbuf *);

     The net80211 layer used by 802.11 drivers includes support for a device-
     independent packet capture format called radiotap that is understood by
     tools such as tcpdump(1).	This facility is designed for capturing 802.11
     traffic, including information that is not part of the normal 802.11
     frame structure.

     Radiotap was designed to balance the desire for a hardware-independent,
     extensible capture format against the need to conserve CPU and memory
     bandwidth on embedded systems.  These considerations led to a format con‐
     sisting of a standard preamble followed by an extensible bitmap indicat‐
     ing the presence of optional capture fields.  A net80211 device driver
     supporting radiotap defines two packed structures that it shares with
     net80211.	These structures embed an instance of a
     ieee80211_radiotap_header structure at the beginning, with subsequent
     fields in the appropriate order, and macros to set the bits of the
     it_present bitmap to indicate which fields exist and are filled in by the
     driver.  This information is then supplied through the
     ieee80211_radiotap_attach() call after a successful ieee80211_ifattach()

     With radiotap setup, drivers just need to fill in per-packet capture
     state for frames sent/received and dispatch capture state in the transmit
     path (since control is not returned to the net80211 layer before the
     packet is handed to the device).  To minimize overhead this work should
     be done only when one or more processes are actively capturing data; this
     is checked with one of ieee80211_radiotap_active_vap() and
     ieee80211_radiotap_active().  In the transmit path capture work looks
     like this:

	   if (ieee80211_radiotap_active_vap(vap)) {
		   ... /* record transmit state */
		   ieee80211_radiotap_tx(vap, m); /* capture transmit event */

     While in the receive path capture is handled in net80211 but state must
     be captured before dispatching a frame:

	   if (ieee80211_radiotap_active(ic)) {
		   ... /* record receive state */
	   ieee80211_input(...);   /* packet capture handled in net80211 */

     The following fields are defined for radiotap, in the order in which they
     should appear in the buffer supplied to net80211.

	     This field contains the unsigned 64-bit value, in microseconds,
	     of the MAC's 802.11 Time Synchronization Function (TSF).  In the‐
	     ory, for each received frame, this value is recorded when the
	     first bit of the MPDU arrived at the MAC.	In practice, hardware
	     snapshots the TSF otherwise and one cannot assume this data is
	     accurate without driver adjustment.

	     This field contains a single unsigned 8-bit value, containing one
	     or more of these bit flags:

		     Frame was sent/received during the Contention Free Period

		     Frame was sent/received with short preamble.

		     Frame was encrypted.

		     Frame was an 802.11 fragment.

		     Frame contents includes the FCS.

		     Frame contents potentially has padding between the 802.11
		     header and the data payload to align the payload to a
		     32-bit boundary.

		     Frame was received with an invalid FCS.

		     Frame was sent/received with Short Guard Interval.

	     This field contains a single unsigned 8-bit value that is the
	     data rate.	 Legacy rates are in units of 500Kbps.	MCS rates
	     (used on 802.11n/HT channels) have the high bit set and the MCS
	     in the low 7 bits.

	     This field contains two unsigned 16-bit values.  The first value
	     is the center frequency for the channel the frame was
	     sent/received on.	The second value is a bitmap containing flags
	     that specify channel properties.

	     This field is deprecated in favor of IEEE80211_RADIOTAP_XCHANNEL
	     but may be used to save space in the capture file for legacy

	     This field contains a single signed 8-bit value that indicates
	     the RF signal power at the antenna, in decibels difference from

	     This field contains a single signed 8-bit value that indicates
	     the RF noise power at the antenna, in decibels difference from

	     Transmit power expressed as decibels from a 1mW reference.	 This
	     field is a single signed 8-bit value.  This is the absolute power
	     level measured at the antenna port.

	     This field contains a single unsigned 8-bit value that specifies
	     which antenna was used to transmit or receive the frame.  Antenna
	     numbering is device-specific but typically the primary antenna
	     has the lowest number.  On transmit a value of zero may be seen
	     which typically means antenna selection is left to the device.

	     This field contains a single unsigned 8-bit value that indicates
	     the RF signal power at the antenna, in decibels difference from
	     an arbitrary, fixed reference.

	     This field contains a single unsigned 8-bit value that indicates
	     the RF noise power at the antenna, in decibels difference from an
	     arbitrary, fixed reference.

	     This field contains four values: a 32-bit unsigned bitmap of
	     flags that describe the channel attributes, a 16-bit unsigned
	     frequency in MHz (typically the channel center), an 8-bit
	     unsigned IEEE channel number, and a signed 8-bit value that holds
	     the maximum regulatory transmit power cap in .5 dBm (8 bytes
	     total).  Channel flags are defined in: <net80211/_ieee80211.h>
	     (only a subset are found in <net80211/ieee80211_radiotap.h> ).
	     This property supersedes IEEE80211_RADIOTAP_CHANNEL and is the
	     only way to completely express all channel attributes and the
	     mapping between channel frequency and IEEE channel number.

     Radiotap receive definitions for the Intersil Prism driver:

		   ((1 << IEEE80211_RADIOTAP_TSFT) \
		    (1 << IEEE80211_RADIOTAP_FLAGS) | \
		    (1 << IEEE80211_RADIOTAP_RATE) | \
		    (1 << IEEE80211_RADIOTAP_CHANNEL) | \
		    (1 << IEEE80211_RADIOTAP_DB_ANTSIGNAL) | \
		    (1 << IEEE80211_RADIOTAP_DB_ANTNOISE))

	   struct wi_rx_radiotap_header {
		   struct ieee80211_radiotap_header wr_ihdr;
		   uint64_t	  wr_tsf;
		   uint8_t	  wr_flags;
		   uint8_t	  wr_rate;
		   uint16_t	  wr_chan_freq;
		   uint16_t	  wr_chan_flags;
		   uint8_t	  wr_antsignal;
		   uint8_t	  wr_antnoise;
	   } __packed;

     and transmit definitions for the Atheros driver:

	   #define ATH_TX_RADIOTAP_PRESENT (		   \
		   (1 << IEEE80211_RADIOTAP_TSFT)	   | \
		   (1 << IEEE80211_RADIOTAP_FLAGS)	   | \
		   (1 << IEEE80211_RADIOTAP_RATE)	   | \
		   (1 << IEEE80211_RADIOTAP_DBM_TX_POWER)  | \
		   (1 << IEEE80211_RADIOTAP_ANTENNA)	   | \
		   (1 << IEEE80211_RADIOTAP_XCHANNEL)	   | \

	   struct ath_tx_radiotap_header {
		   struct ieee80211_radiotap_header wt_ihdr;
		   uint64_t	  wt_tsf;
		   uint8_t	  wt_flags;
		   uint8_t	  wt_rate;
		   uint8_t	  wt_txpower;
		   uint8_t	  wt_antenna;
		   uint32_t	  wt_chan_flags;
		   uint16_t	  wt_chan_freq;
		   uint8_t	  wt_chan_ieee;
		   int8_t	  wt_chan_maxpow;
	   } __packed;

     tcpdump(1), bpf(4), ieee80211(9)

     The ieee80211_radiotap definitions first appeared in NetBSD 1.5.

     The original version of this manual page was written by Bruce M. Simpson
     ⟨⟩ and Darron Broad ⟨⟩.

BSD				August 4, 2009				   BSD

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