core/src/dfs_phyerr_tlv.h

/*
 * Copyright (c) 2012, 2016-2017 The Linux Foundation. All rights reserved.
 * Copyright (c) 2022 Qualcomm Innovation Center, Inc. All rights reserved.
 *
 * Permission to use, copy, modify, and/or distribute this software for any
 * purpose with or without fee is hereby granted, provided that the above
 * copyright notice and this permission notice appear in all copies.
 *
 * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
 * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
 * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
 * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
 * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
 * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
 * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
 */

/**
 * DOC: This file has Radar summary.
 */

#ifndef _DFS_PHYERR_TLV_H_
#define _DFS_PHYERR_TLV_H_

/*
 * Register manipulation macros that expect bit field defines
 * to follow the convention that an _S suffix is appended for
 * a shift count, while the field mask has no suffix.
 */
#define SM(_v, _f) (((_v) << _f##_S) & _f)
#define MS(_v, _f) (((_v) & _f) >> _f##_S)

/* The TLV dword is at the beginning of each TLV section. */
#define TLV_REG   0x00

#define TLV_LEN   0x0000FFFF
#define TLV_LEN_S 0

#define TLV_SIG   0x00FF0000
#define TLV_SIG_S 16

#define TLV_TAG   0xFF000000
#define TLV_TAG_S 24

#define TAG_ID_SEARCH_FFT_REPORT   0xFB
#define TAG_ID_RADAR_PULSE_SUMMARY 0xF8

/*
 * Radar pulse summary
 * + TYPE=0xF8 (Radar pulse summary report)
 * + SIG=0xBB (baseband PHY generated TLV components)
 */

#define RADAR_REPORT_PULSE_REG_1      0x00

#define RADAR_REPORT_PULSE_IS_CHIRP   0x80000000
#define RADAR_REPORT_PULSE_IS_CHIRP_S 31

#define RADAR_REPORT_PULSE_IS_MAX_WIDTH   0x40000000
#define RADAR_REPORT_PULSE_IS_MAX_WIDTH_S 30

#define RADAR_REPORT_AGC_TOTAL_GAIN   0x3FF00000
#define RADAR_REPORT_AGC_TOTAL_GAIN_S 20

#define RADAR_REPORT_PULSE_DELTA_DIFF   0x000F0000
#define RADAR_REPORT_PULSE_DELTA_DIFF_S 16

#define RADAR_REPORT_PULSE_DELTA_PEAK   0x0000FC00
#define RADAR_REPORT_PULSE_DELTA_PEAK_S 10

#define RADAR_REPORT_PULSE_SIDX    0x000003FF
#define RADAR_REPORT_PULSE_SIDX_S  0x0

#define RADAR_REPORT_PULSE_REG_2 0x01

#define RADAR_REPORT_PULSE_SRCH_FFT_A_VALID   0x80000000
#define RADAR_REPORT_PULSE_SRCH_FFT_A_VALID_S 31

#define RADAR_REPORT_PULSE_AGC_MB_GAIN   0x7F000000
#define RADAR_REPORT_PULSE_AGC_MB_GAIN_S 24

#define RADAR_REPORT_PULSE_SUBCHAN_MASK   0x00FF0000
#define RADAR_REPORT_PULSE_SUBCHAN_MASK_S 16

#define RADAR_REPORT_PULSE_TSF_OFFSET   0x0000FF00
#define RADAR_REPORT_PULSE_TSF_OFFSET_S 8

#define RADAR_REPORT_PULSE_DUR   0x000000FF
#define RADAR_REPORT_PULSE_DUR_S 0

#define SEARCH_FFT_REPORT_REG_1 0x00

#define SEARCH_FFT_REPORT_TOTAL_GAIN_DB   0xFF800000
#define SEARCH_FFT_REPORT_TOTAL_GAIN_DB_S 23

#define SEARCH_FFT_REPORT_BASE_PWR_DB     0x007FC000
#define SEARCH_FFT_REPORT_BASE_PWR_DB_S   14

#define SEARCH_FFT_REPORT_FFT_CHN_IDX     0x00003000
#define SEARCH_FFT_REPORT_FFT_CHN_IDX_S   12

#define SEARCH_FFT_REPORT_PEAK_SIDX       0x00000FFF
#define SEARCH_FFT_REPORT_PEAK_SIDX_S     0

#define SEARCH_FFT_REPORT_REG_2 0x01

#define SEARCH_FFT_REPORT_RELPWR_DB   0xFC000000
#define SEARCH_FFT_REPORT_RELPWR_DB_S 26

#define SEARCH_FFT_REPORT_AVGPWR_DB   0x03FC0000
#define SEARCH_FFT_REPORT_AVGPWR_DB_S 18

#define SEARCH_FFT_REPORT_PEAK_MAG    0x0003FF00
#define SEARCH_FFT_REPORT_PEAK_MAG_S  8

#define SEARCH_FFT_REPORT_NUM_STR_BINS_IB   0x000000FF
#define SEARCH_FFT_REPORT_NUM_STR_BINS_IB_S 0

#define SEARCH_FFT_REPORT_REG_3 0x02

#define SEARCH_FFT_REPORT_SEG_ID   0x00000001
#define SEARCH_FFT_REPORT_SEG_ID_S 0

/*
 * Although this code is now not parsing the whole frame (descriptor
 * and all), the relevant fields are still useful information
 * for anyone who is working on the PHY error part of DFS pattern
 * matching.
 *
 * However, to understand _where_ these descriptors start, you
 * should do some digging into the peregrine descriptor format.
 * The 30 second version: each RX ring has a bitmap listing which
 * descriptors are to be included, and then a set of offsets
 * into the RX buffer for where each descriptor will be written.
 * It's not like the 802.11n generation hardware which has
 * a fixed descriptor format.
 */

/* RX_PPDU_START */
#define RX_PPDU_START_LEN         (10*4)
#define RX_PPDU_START_REG_4       0x0004
#define RX_PPDU_START_RSSI_COMB   0x000000FF
#define RX_PPDU_START_RSSI_COMB_S 0

/* RX_PPDU_END */
#define RX_PPDU_END_LEN (21*4)
#define RX_PPDU_END_REG_16          16
#define RX_PPDU_END_TSF_TIMESTAMP   0xFFFFFFFF
#define RX_PPDU_END_TSF_TIMESTAMP_S 0
#define RX_PPDU_END_REG_18         18
#define RX_PPDU_END_PHY_ERR_CODE   0x0000FF00
#define RX_PPDU_END_PHY_ERR_CODE_S 8
#define RX_PPDU_END_PHY_ERR        0x00010000
#define RX_PPDU_END_PHY_ERR_S      16

/*
 * The RSSI values can have "special meanings".
 * If rssi=50, it means that the peak detector triggered.
 */
#define RSSI_PEAK_DETECTOR_SAT 50

/*
 * If rssi=25, it means that the ADC was saturated, but that only is
 * valid when there is one ADC gain change.  For short pulses this
 * is true - you won't have time to do a gain change before the pulse
 * goes away.  But for longer pulses, ADC gain changes can occur, so
 * you'll get a more accurate RSSI figure.
 *
 * For short pulses (and the definition of "short" still isn't clear
 * at the time of writing) there isn't any real time to do a gain change
 * (or two, or three..) in order to get an accurate estimation of signal
 * sizing.  Thus, RSSI will not be very accurate for short duration pulses.
 * All you can really say for certain is that yes, there's a pulse that
 * met the requirements of the pulse detector.
 *
 * For more information, see the 802.11ac Microarchitecture guide.
 * (TODO: add a twiki reference.)
 */

#endif /* _DFS_PHYERR_TLV_H_ */