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nest-open-source / nest-cam / v350 / atheros_tools / refs/heads/main / . / host / include / dfs_host.h
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/*
* Copyright (c) 2005-2006 Atheros Communications, Inc.
*
* 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.
*/
#ifndef _DFS_HOST_H_
#define _DFS_HOST_H_
#ifdef ATH_SUPPORT_DFS
#include "dfs_host_project.h"
#define DFS_MIN(a,b) ((a)<(b)?(a):(b))
#define DFS_MAX(a,b) ((a)>(b)?(a):(b))
#define DFS_DIFF(a,b) (DFS_MAX(a,b) - DFS_MIN(a,b))
/*
* Maximum number of radar events to be processed in a single iteration.
* Allows soft watchdog to run.
*/
#define MAX_EVENTS 100
#define DFS_MARGIN_EQUAL(a, b, margin) ((DFS_DIFF(a,b)) <= margin)
#define DFS_MAX_STAGGERED_BURSTS 3
/* All filter thresholds in the radar filter tables are effective at a 50% channel loading */
#define DFS_CHAN_LOADING_THRESH 50
#define DFS_EXT_CHAN_LOADING_THRESH 30
#define DFS_DEFAULT_PRI_MARGIN 10
#define DFS_DEFAULT_FIXEDPATTERN_PRI_MARGIN 6
#define ATH_DFSQ_LOCK(_dfs) spin_lock(&(_dfs)->dfs_radarqlock)
#define ATH_DFSQ_UNLOCK(_dfs) spin_unlock(&(_dfs)->dfs_radarqlock)
#define ATH_DFSQ_LOCK_INIT(_dfs) spin_lock_init(&(_dfs)->dfs_radarqlock)
#define ATH_ARQ_LOCK(_dfs) spin_lock(&(_dfs)->dfs_arqlock)
#define ATH_ARQ_UNLOCK(_dfs) spin_unlock(&(_dfs)->dfs_arqlock)
#define ATH_ARQ_LOCK_INIT(_dfs) spin_lock_init(&(_dfs)->dfs_arqlock)
#define ATH_DFSEVENTQ_LOCK(_dfs) spin_lock(&(_dfs)->dfs_eventqlock)
#define ATH_DFSEVENTQ_UNLOCK(_dfs) spin_unlock(&(_dfs)->dfs_eventqlock)
#define ATH_DFSEVENTQ_LOCK_INIT(_dfs) spin_lock_init(&(_dfs)->dfs_eventqlock)
#define DFS_TSMASK 0xFFFFFFFF /* Mask for time stamp from descriptor */
#define DFS_TSSHIFT 32 /* Shift for time stamp from descriptor */
#define DFS_TSF_WRAP 0xFFFFFFFFFFFFFFFFULL /* 64 bit TSF wrap value */
#define DFS_64BIT_TSFMASK 0x0000000000007FFFULL /* TS mask for 64 bit value */
#define DFS_AR_RADAR_RSSI_THR 5 /* in dB */
#define DFS_AR_RADAR_RESET_INT 1 /* in secs */
#define DFS_AR_RADAR_MAX_HISTORY 500
#define DFS_AR_REGION_WIDTH 128
#define DFS_AR_RSSI_THRESH_STRONG_PKTS 17 /* in dB */
#define DFS_AR_RSSI_DOUBLE_THRESHOLD 15 /* in dB */
#define DFS_AR_MAX_NUM_ACK_REGIONS 9
#define DFS_AR_ACK_DETECT_PAR_THRESH 20
#define DFS_AR_PKT_COUNT_THRESH 20
#define DFS_MAX_DL_MASK 0x3F
#define DFS_NOL_TIME 30*60*1000000 /* 30 minutes in usecs */
#define DFS_WAIT_TIME 60*1000000 /* 1 minute in usecs */
#define DFS_DISABLE_TIME 3*60*1000000 /* 3 minutes in usecs */
#define DFS_MAX_B5_SIZE 128
#define DFS_MAX_B5_MASK 0x0000007F /* 128 */
#define DFS_MAX_RADAR_OVERLAP 16 /* Max number of overlapping filters */
#define DFS_MAX_EVENTS 1024 /* Max number of dfs events which can be q'd */
#define DFS_RADAR_EN 0x80000000 /* Radar detect is capable */
#define DFS_AR_EN 0x40000000 /* AR detect is capable */
#define DFS_MAX_RSSI_VALUE 0x7fffffff /* Max rssi value */
#define DFS_BIN_MAX_PULSES 60 /* max num of pulses in a burst */
#define DFS_BIN5_PRI_LOWER_LIMIT 990 /* us */
#define DFS_BIN5_PRI_HIGHER_LIMIT 2010 /* us */
#define DFS_BIN5_WIDTH_MARGIN 4 /* us */
#define DFS_BIN5_RSSI_MARGIN 5 /* dBm */
/*Following threshold is not specified but should be okay statistically*/
#define DFS_BIN5_BRI_LOWER_LIMIT 300000 /* us */
#define DFS_MAX_PULSE_BUFFER_SIZE 1024 /* Max number of pulses kept in buffer */
#define DFS_MAX_PULSE_BUFFER_MASK 0x3ff
#define DFS_FAST_CLOCK_MULTIPLIER (800/11)
#define DFS_NO_FAST_CLOCK_MULTIPLIER (80)
typedef spinlock_t dfsq_lock_t;
struct dfs_pulse {
A_UINT32 rp_numpulses; /* Num of pulses in radar burst */
A_UINT32 rp_pulsedur; /* Duration of each pulse in usecs */
A_UINT32 rp_pulsefreq; /* Frequency of pulses in burst */
A_UINT32 rp_max_pulsefreq; /* Frequency of pulses in burst */
A_UINT32 rp_patterntype; /*fixed or variable pattern type*/
A_UINT32 rp_pulsevar; /* Time variation of pulse duration for
matched filter (single-sided) in usecs */
A_UINT32 rp_threshold; /* Thershold for MF output to indicate
radar match */
A_UINT32 rp_mindur; /* Min pulse duration to be considered for
this pulse type */
A_UINT32 rp_maxdur; /* Max pusle duration to be considered for
this pulse type */
A_UINT32 rp_rssithresh; /* Minimum rssi to be considered a radar pulse */
A_UINT32 rp_meanoffset; /* Offset for timing adjustment */
A_INT32 rp_rssimargin; /* rssi threshold margin. In Turbo Mode HW reports rssi 3dBm
* lower than in non TURBO mode. This will be used to offset
* that diff.*/
A_UINT32 rp_pulseid; /* Unique ID for identifying filter */
};
struct dfs_bin5pulse {
A_UINT32 b5_threshold; /* Number of bin5 pulses to indicate detection */
A_UINT32 b5_mindur; /* Min duration for a bin5 pulse */
A_UINT32 b5_maxdur; /* Max duration for a bin5 pulse */
A_UINT32 b5_timewindow; /* Window over which to count bin5 pulses */
A_UINT32 b5_rssithresh; /* Min rssi to be considered a pulse */
A_UINT32 b5_rssimargin; /* rssi threshold margin. In Turbo Mode HW reports rssi 3dB */
};
#define DFS_MAX_DL_SIZE 64
#include "athstartpack.h"
PREPACK struct dfs_delayelem {
u_int32_t de_time; /* Current "filter" time for start of pulse in usecs*/
u_int8_t de_dur; /* Duration of pulse in usecs*/
u_int8_t de_rssi; /* rssi of pulse in dB*/
} POSTPACK adf_os_packed;
/* NB: The first element in the circular buffer is the oldest element */
PREPACK struct dfs_delayline {
struct dfs_delayelem dl_elems[DFS_MAX_DL_SIZE]; /* Array of pulses in delay line */
u_int64_t dl_last_ts; /* Last timestamp the delay line was used (in usecs) */
u_int32_t dl_firstelem; /* Index of the first element */
u_int32_t dl_lastelem; /* Index of the last element */
u_int32_t dl_numelems; /* Number of elements in the delay line */
} POSTPACK adf_os_packed;
PREPACK struct dfs_filter {
struct dfs_delayline rf_dl; /* Delay line of pulses for this filter */
u_int32_t rf_numpulses; /* Number of pulses in the filter */
u_int32_t rf_minpri; /* min pri to be considered for this filter*/
u_int32_t rf_maxpri; /* max pri to be considered for this filter*/
u_int32_t rf_threshold; /* match filter output threshold for radar detect */
u_int32_t rf_filterlen; /* Length (in usecs) of the filter */
u_int32_t rf_patterntype; /* fixed or variable pattern type */
u_int32_t rf_mindur; /* Min duration for this radar filter */
u_int32_t rf_maxdur; /* Max duration for this radar filter */
u_int32_t rf_pulseid; /* Unique ID corresponding to the original filter ID */
} POSTPACK adf_os_packed;
PREPACK struct dfs_pulseparams {
u_int64_t p_time; /* time for start of pulse in usecs*/
u_int8_t p_dur; /* Duration of pulse in usecs*/
u_int8_t p_rssi; /* Duration of pulse in usecs*/
} POSTPACK adf_os_packed;
PREPACK struct dfs_pulseline {
/* pl_elems - array of pulses in delay line */
struct dfs_pulseparams pl_elems[DFS_MAX_PULSE_BUFFER_SIZE];
u_int32_t pl_firstelem; /* Index of the first element */
u_int32_t pl_lastelem; /* Index of the last element */
u_int32_t pl_numelems; /* Number of elements in the delay line */
} POSTPACK adf_os_packed;
PREPACK struct dfs_event {
u_int64_t re_full_ts; /* 64-bit full timestamp from interrupt time */
u_int32_t re_ts; /* Original 15 bit recv timestamp */
u_int32_t re_ext_chan_busy; /* Ext channel busy % */
u_int8_t re_rssi; /* rssi of radar event */
u_int8_t re_dur; /* duration of radar pulse */
u_int8_t re_chanindex; /* Channel of event */
u_int8_t re_chanindextype; /* Primary channel or extension channel */
STAILQ_ENTRY(dfs_event) re_list; /* List of radar events */
} POSTPACK adf_os_packed;
#include "athendpack.h"
#define DFS_AR_MAX_ACK_RADAR_DUR 511
#define DFS_AR_MAX_NUM_PEAKS 3
#define DFS_AR_ARQ_SIZE 2048 /* 8K AR events for buffer size */
#define DFS_AR_ARQ_SEQSIZE 2049 /* Sequence counter wrap for AR */
#define DFS_RADARQ_SIZE 512 /* 1K radar events for buffer size */
#define DFS_RADARQ_SEQSIZE 513 /* Sequence counter wrap for radar */
#define DFS_NUM_RADAR_STATES 64 /* Number of radar channels we keep state for */
#define DFS_MAX_NUM_RADAR_FILTERS 10 /* Max number radar filters for each type */
#define DFS_MAX_RADAR_TYPES 32 /* Number of different radar types */
struct dfs_ar_state {
u_int32_t ar_prevwidth;
u_int32_t ar_phyerrcount[DFS_AR_MAX_ACK_RADAR_DUR];
u_int32_t ar_acksum;
u_int32_t ar_packetthreshold; /* Thresh to determine traffic load */
u_int32_t ar_parthreshold; /* Thresh to determine peak */
u_int32_t ar_radarrssi; /* Rssi threshold for AR event */
u_int16_t ar_prevtimestamp;
u_int16_t ar_peaklist[DFS_AR_MAX_NUM_PEAKS];
};
struct dfs_filtertype {
struct dfs_filter ft_filters[DFS_MAX_NUM_RADAR_FILTERS];
u_int32_t ft_filterdur; /* Duration of pulse which specifies filter type*/
u_int32_t ft_numfilters; /* Num filters of this type */
u_int64_t ft_last_ts; /* Last timestamp this filtertype was used
* (in usecs) */
u_int32_t ft_mindur; /* min pulse duration to be considered
* for this filter type */
u_int32_t ft_maxdur; /* max pulse duration to be considered
* for this filter type */
u_int32_t ft_rssithresh; /* min rssi to be considered
* for this filter type */
u_int32_t ft_numpulses; /* Num pulses in each filter of this type */
u_int32_t ft_patterntype; /* fixed or variable pattern type */
u_int32_t ft_minpri; /* min pri to be considered for this type */
u_int32_t ft_rssimargin; /* rssi threshold margin. In Turbo Mode HW
* reports rssi 3dB lower than in non TURBO
* mode. This will offset that diff. */
};
#define DFS_NOL_TIMEOUT_S (30*60) /* 30 minutes in seconds */
#define DFS_NOL_TIMEOUT_MS (DFS_NOL_TIMEOUT_S * 1000)
#define DFS_NOL_TIMEOUT_US (DFS_NOL_TIMEOUT_MS * 1000)
#include "athstartpack.h"
PREPACK struct dfs_info_host {
u_int32_t rn_numradars; /* Number of different types of radars */
u_int64_t rn_lastfull_ts; /* Last 64 bit timstamp from recv interrupt */
u_int16_t rn_last_ts; /* last 15 bit ts from recv descriptor */
u_int32_t rn_last_unique_ts; /* last unique 32 bit ts from recv descriptor */
u_int64_t rn_ts_prefix; /* Prefix to prepend to 15 bit recv ts */
u_int32_t rn_numbin5radars; /* Number of bin5 radar pulses to search for */
u_int64_t dfs_bin5_chirp_ts;
u_int8_t dfs_last_bin5_dur;
} POSTPACK adf_os_packed;
#include "athendpack.h"
struct dfs_bin5elem {
u_int64_t be_ts; /* Timestamp for the bin5 element */
u_int32_t be_rssi; /* Rssi for the bin5 element */
u_int32_t be_dur; /* Duration of bin5 element */
};
struct dfs_bin5radars {
struct dfs_bin5elem br_elems[DFS_MAX_B5_SIZE]; /* List of bin5 elems that fall
* within the time window */
u_int32_t br_firstelem; /* Index of the first element */
u_int32_t br_lastelem; /* Index of the last element */
u_int32_t br_numelems; /* Number of elements in the delay line */
struct dfs_bin5pulse br_pulse; /* Original info about bin5 pulse */
};
#define ATH_DFS_RESET_TIME_S 7
#define ATH_DFS_WAIT (60 + ATH_DFS_RESET_TIME_S) /* 60 seconds */
#define ATH_DFS_WAIT_MS ((ATH_DFS_WAIT) * 1000) /*in MS*/
#define ATH_DFS_WEATHER_CHANNEL_WAIT_MIN 10 /*10 minutes*/
#define ATH_DFS_WEATHER_CHANNEL_WAIT_S (ATH_DFS_WEATHER_CHANNEL_WAIT_MIN * 60)
#define ATH_DFS_WEATHER_CHANNEL_WAIT_MS ((ATH_DFS_WEATHER_CHANNEL_WAIT_S) * 1000) /*in MS*/
#define ATH_DFS_WAIT_POLL_PERIOD 2 /* 2 seconds */
#define ATH_DFS_WAIT_POLL_PERIOD_MS ((ATH_DFS_WAIT_POLL_PERIOD) * 1000) /*in MS*/
#define ATH_DFS_TEST_RETURN_PERIOD 2 /* 2 seconds */
#define ATH_DFS_TEST_RETURN_PERIOD_MS ((ATH_DFS_TEST_RETURN_PERIOD) * 1000)/* n MS*/
#define IS_CHANNEL_WEATHER_RADAR(chan) ((chan->channel >= 5600) && (chan->channel <= 5650))
#define DFS_DEBUG_TIMEOUT_S 30 // debug timeout is 30 seconds
#define DFS_DEBUG_TIMEOUT_MS (DFS_DEBUG_TIMEOUT_S * 1000)
struct ath_dfs_host {
DEV_HDL dev_hdl;
u_int32_t dfs_debug_level;
OS_HDL os_hdl;
STAILQ_HEAD(,dfs_event) dfs_eventq; /* Q of free dfs event objects */
dfsq_lock_t dfs_eventqlock; /* Lock for free dfs event list */
STAILQ_HEAD(,dfs_event) dfs_radarq; /* Q of radar events */
dfsq_lock_t dfs_radarqlock; /* Lock for dfs q */
STAILQ_HEAD(,dfs_event) dfs_arq; /* Q of AR events */
dfsq_lock_t dfs_arqlock; /* Lock for AR q */
struct dfs_pulseline *pulses; /* pulse history */
struct dfs_event *events; /* Events structure */
/* dfs_radarf - One filter for each radar pulse type */
struct dfs_filtertype *dfs_radarf[DFS_MAX_RADAR_TYPES];
int8_t **dfs_radartable; /* map of radar durs to filter types */
struct dfs_bin5radars *dfs_b5radars;/* array of bin5 radar events */
struct dfs_ar_state dfs_ar_state; /* AR state */
struct dfs_info_host dfs_rinfo; /* State vars for radar processing */
u_int8_t dfs_bangradar;
u_int32_t dur_multiplier;
A_TIMER dfs_radar_task_timer;
};
#define HAL_CAP_RADAR 0
#define HAL_CAP_AR 1
#define HAL_CAP_STRONG_DIV 2
/* Attach, detach, handle ioctl prototypes */
struct ath_dfs_host *dfs_attach_host(DEV_HDL dev, OS_HDL os, ATH_DFS_CAPINFO *cap_info);
void dfs_detach_host(struct ath_dfs_host *sc);
/* PHY error and radar event handling */
void dfs_process_phyerr_host(struct ath_dfs_host *dfs, WMI_DFS_PHYERR_EVENT *ev);
int dfs_process_radarevent_host(struct ath_dfs_host *dfs, int16_t *chan_index, u_int8_t *bangradar);
/* FCC Bin5 detection prototypes */
int dfs_bin5_addpulse(struct ath_dfs_host *sc, struct dfs_bin5radars *br,
struct dfs_event *re, u_int64_t thists);
int dfs_bin5_check(struct ath_dfs_host *dfs);
u_int8_t dfs_retain_bin5_burst_pattern(struct ath_dfs_host *dfs, u_int32_t diff_ts, u_int8_t old_dur);
/* Debug prototypes */
void dfs_print_delayline(struct ath_dfs_host *dfs, struct dfs_delayline *dl);
void dfs_print_filters(struct ath_dfs_host *dfs);
void dfs_print_filter(struct ath_dfs_host *dfs, struct dfs_filter *rf);
/* Misc prototypes */
u_int32_t dfs_round(int32_t val);
/* Reset and init data structures */
int dfs_init_radar_filters_host(struct ath_dfs_host *dfs, struct ath_dfs_info *dfs_info);
void dfs_reset_alldelaylines(struct ath_dfs_host *dfs);
void dfs_reset_delayline(struct dfs_delayline *dl);
void dfs_reset_filter_delaylines(struct dfs_filtertype *dft);
void dfs_reset_radarq(struct ath_dfs_host *dfs);
/* Detection algorithm prototypes */
void dfs_add_pulse(struct ath_dfs_host *dfs, struct dfs_filter *rf,
struct dfs_event *re, u_int32_t deltaT);
int dfs_bin_fixedpattern_check(struct ath_dfs_host *dfs, struct dfs_filter *rf, u_int32_t dur, int ext_chan_flag, u_int32_t ext_chan_busy);
int dfs_bin_check(struct ath_dfs_host *dfs, struct dfs_filter *rf,
u_int32_t deltaT, u_int32_t dur, int ext_chan_flag, u_int32_t ext_chan_busy);
int dfs_bin_pri_check(struct ath_dfs_host *dfs, struct dfs_filter *rf,
struct dfs_delayline *dl, u_int32_t score,
u_int32_t refpri, u_int32_t refdur, int ext_chan_flag, u_int32_t ext_chan_busy);
int dfs_staggered_check(struct ath_dfs_host *dfs, struct dfs_filter *rf,
u_int32_t deltaT, u_int32_t width, u_int32_t ext_chan_busy);
/* AR related prototypes */
u_int32_t dfs_process_ar_event(struct ath_dfs_host *dfs);
void dfs_reset_ar(struct ath_dfs_host *dfs);
void dfs_reset_arq(struct ath_dfs_host *dfs);
void dfs_bangradar_enable(struct ath_dfs_host *dfs, u_int8_t enable);
void dfs_set_dur_multiplier(struct ath_dfs_host *dfs, u_int32_t dur_multiplier);
void dfs_set_debug_level_host(struct ath_dfs_host *dfs, u_int32_t level);
/* False detection reduction */
int dfs_get_pri_margin(int is_extchan_detect, int is_fixed_pattern, u_int64_t lastfull_ts, u_int32_t ext_chan_busy);
int dfs_get_filter_threshold(struct dfs_filter *rf, int is_extchan_detect, u_int64_t lastfull_ts, u_int32_t ext_chan_busy);
#endif /* ATH_SUPPORT_DFS */
#endif /* _DFS_H_ */