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gerrit-public.fairphone.software / platform / vendor / qcom-opensource / wlan / qca-wifi-host-cmn / 98ec4d132b57b7c38655422fd0fcb0173f365473 / . / target_if / spectral / target_if_spectral.h
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/*
* Copyright (c) 2011,2017-2019 The Linux Foundation. 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.
*/
#ifndef _TARGET_IF_SPECTRAL_H_
#define _TARGET_IF_SPECTRAL_H_
#include <wlan_objmgr_cmn.h>
#include <wlan_objmgr_psoc_obj.h>
#include <wlan_objmgr_pdev_obj.h>
#include <wlan_objmgr_vdev_obj.h>
#include <qdf_lock.h>
#include <wlan_spectral_public_structs.h>
#include <reg_services_public_struct.h>
#ifdef DIRECT_BUF_RX_ENABLE
#include <target_if_direct_buf_rx_api.h>
#endif
#ifdef WIN32
#pragma pack(push, target_if_spectral, 1)
#define __ATTRIB_PACK
#else
#ifndef __ATTRIB_PACK
#define __ATTRIB_PACK __attribute__ ((packed))
#endif
#endif
#include <spectral_defs_i.h>
#ifndef SPECTRAL_USE_NL_BCAST
#define SPECTRAL_USE_NL_BCAST (0)
#endif
#define STATUS_PASS 1
#define STATUS_FAIL 0
#undef spectral_dbg_line
#define spectral_dbg_line() \
spectral_debug("----------------------------------------------------")
#undef spectral_ops_not_registered
#define spectral_ops_not_registered(str) \
spectral_info("SPECTRAL : %s not registered\n", (str))
#undef not_yet_implemented
#define not_yet_implemented() \
spectral_info("SPECTRAL : %s : %d Not yet implemented\n", \
__func__, __LINE__)
#define SPECTRAL_HT20_NUM_BINS 56
#define SPECTRAL_HT20_FFT_LEN 56
#define SPECTRAL_HT20_DC_INDEX (SPECTRAL_HT20_FFT_LEN / 2)
#define SPECTRAL_HT20_DATA_LEN 60
#define SPECTRAL_HT20_TOTAL_DATA_LEN (SPECTRAL_HT20_DATA_LEN + 3)
#define SPECTRAL_HT40_TOTAL_NUM_BINS 128
#define SPECTRAL_HT40_DATA_LEN 135
#define SPECTRAL_HT40_TOTAL_DATA_LEN (SPECTRAL_HT40_DATA_LEN + 3)
#define SPECTRAL_HT40_FFT_LEN 128
#define SPECTRAL_HT40_DC_INDEX (SPECTRAL_HT40_FFT_LEN / 2)
/*
* Used for the SWAR to obtain approximate combined rssi
* in secondary 80Mhz segment
*/
#define OFFSET_CH_WIDTH_20 65
#define OFFSET_CH_WIDTH_40 62
#define OFFSET_CH_WIDTH_80 56
#define OFFSET_CH_WIDTH_160 50
/* Min and max for relevant Spectral params */
#define SPECTRAL_PARAM_FFT_SIZE_MIN_GEN2 (1)
#define SPECTRAL_PARAM_FFT_SIZE_MAX_GEN2 (9)
#define SPECTRAL_PARAM_FFT_SIZE_MIN_GEN3 (5)
#define SPECTRAL_PARAM_FFT_SIZE_MAX_GEN3 (9)
#define SPECTRAL_PARAM_RPT_MODE_MIN (0)
#define SPECTRAL_PARAM_RPT_MODE_MAX (3)
#ifdef BIG_ENDIAN_HOST
#define SPECTRAL_MESSAGE_COPY_CHAR_ARRAY(destp, srcp, len) do { \
int j; \
uint32_t *src, *dest; \
src = (uint32_t *)(srcp); \
dest = (uint32_t *)(destp); \
for (j = 0; j < roundup((len), sizeof(uint32_t)) / 4; j++) { \
*(dest + j) = qdf_le32_to_cpu(*(src + j)); \
} \
} while (0)
#else
#define SPECTRAL_MESSAGE_COPY_CHAR_ARRAY(destp, srcp, len) \
OS_MEMCPY((destp), (srcp), (len));
#endif
#define DUMMY_NF_VALUE (-123)
/* 5 categories x (lower + upper) bands */
#define MAX_INTERF 10
#define HOST_MAX_ANTENNA 3
/* Mask for time stamp from descriptor */
#define SPECTRAL_TSMASK 0xFFFFFFFF
#define SPECTRAL_SIGNATURE 0xdeadbeef
/* Signature to write onto spectral buffer and then later validate */
#define MEM_POISON_SIGNATURE (htobe32(0xdeadbeef))
/* START of spectral GEN II HW specific details */
#define SPECTRAL_PHYERR_SIGNATURE_GEN2 0xbb
#define TLV_TAG_SPECTRAL_SUMMARY_REPORT_GEN2 0xF9
#define TLV_TAG_ADC_REPORT_GEN2 0xFA
#define TLV_TAG_SEARCH_FFT_REPORT_GEN2 0xFB
/**
* enum spectral_160mhz_report_delivery_state - 160 MHz state machine states
* @SPECTRAL_REPORT_WAIT_PRIMARY80: Wait for primary80 report
* @SPECTRAL_REPORT_RX_PRIMARY80: Receive primary 80 report
* @SPECTRAL_REPORT_WAIT_SECONDARY80: Wait for secondory 80 report
* @SPECTRAL_REPORT_RX_SECONDARY80: Receive secondary 80 report
*/
enum spectral_160mhz_report_delivery_state {
SPECTRAL_REPORT_WAIT_PRIMARY80,
SPECTRAL_REPORT_RX_PRIMARY80,
SPECTRAL_REPORT_WAIT_SECONDARY80,
SPECTRAL_REPORT_RX_SECONDARY80,
};
/**
* enum spectral_detector_id - Spectral detector id
* @SPECTRAL_DETECTOR_PRIMARY: Primary detector
* @SPECTRAL_DETECTOR_SECONDARY: Secondary detector
* @SPECTRAL_DETECTOR_AGILE: Agile detector
* @SPECTRAL_DETECTOR_INVALID: Invalid detector
*/
enum spectral_detector_id {
SPECTRAL_DETECTOR_PRIMARY,
SPECTRAL_DETECTOR_SECONDARY,
SPECTRAL_DETECTOR_AGILE,
SPECTRAL_DETECTOR_INVALID,
};
/**
* struct spectral_search_fft_info_gen2 - spectral search fft report for gen2
* @relpwr_db: Total bin power in db
* @num_str_bins_ib: Number of strong bins
* @base_pwr: Base power
* @total_gain_info: Total gain
* @fft_chn_idx: FFT chain on which report is originated
* @avgpwr_db: Average power in db
* @peak_mag: Peak power seen in the bins
* @peak_inx: Index of bin holding peak power
*/
struct spectral_search_fft_info_gen2 {
uint32_t relpwr_db;
uint32_t num_str_bins_ib;
uint32_t base_pwr;
uint32_t total_gain_info;
uint32_t fft_chn_idx;
uint32_t avgpwr_db;
uint32_t peak_mag;
int16_t peak_inx;
};
/*
* XXX Check if we should be handling the endinness difference in some
* other way opaque to the host
*/
#ifdef BIG_ENDIAN_HOST
/**
* struct spectral_phyerr_tlv_gen2 - phyerr tlv info for big endian host
* @signature: signature
* @tag: tag
* @length: length
*/
struct spectral_phyerr_tlv_gen2 {
uint8_t signature;
uint8_t tag;
uint16_t length;
} __ATTRIB_PACK;
#else
/**
* struct spectral_phyerr_tlv_gen2 - phyerr tlv info for little endian host
* @length: length
* @tag: tag
* @signature: signature
*/
struct spectral_phyerr_tlv_gen2 {
uint16_t length;
uint8_t tag;
uint8_t signature;
} __ATTRIB_PACK;
#endif /* BIG_ENDIAN_HOST */
/**
* struct spectral_phyerr_hdr_gen2 - phyerr header for gen2 HW
* @hdr_a: Header[0:31]
* @hdr_b: Header[32:63]
*/
struct spectral_phyerr_hdr_gen2 {
uint32_t hdr_a;
uint32_t hdr_b;
};
/*
* Segment ID information for 80+80.
*
* If the HW micro-architecture specification extends this DWORD for other
* purposes, then redefine+rename accordingly. For now, the specification
* mentions only segment ID (though this doesn't require an entire DWORD)
* without mention of any generic terminology for the DWORD, or any reservation.
* We use nomenclature accordingly.
*/
typedef uint32_t SPECTRAL_SEGID_INFO;
/**
* struct spectral_phyerr_fft_gen2 - fft info in phyerr event
* @buf: fft report
*/
struct spectral_phyerr_fft_gen2 {
uint8_t buf[0];
};
/* END of spectral GEN II HW specific details */
/* START of spectral GEN III HW specific details */
#define get_bitfield(value, size, pos) \
(((value) >> (pos)) & ((1 << (size)) - 1))
#define unsigned_to_signed(value, width) \
(((value) >= (1 << ((width) - 1))) ? \
(value - (1 << (width))) : (value))
#define SSCAN_SUMMARY_REPORT_HDR_A_DETECTOR_ID_POS_GEN3 (29)
#define SSCAN_SUMMARY_REPORT_HDR_A_DETECTOR_ID_SIZE_GEN3 (2)
#define SSCAN_SUMMARY_REPORT_HDR_A_AGC_TOTAL_GAIN_POS_GEN3 (0)
#define SSCAN_SUMMARY_REPORT_HDR_A_AGC_TOTAL_GAIN_SIZE_GEN3 (8)
#define SSCAN_SUMMARY_REPORT_HDR_A_INBAND_PWR_DB_POS_GEN3 (18)
#define SSCAN_SUMMARY_REPORT_HDR_A_INBAND_PWR_DB_SIZE_GEN3 (10)
#define SSCAN_SUMMARY_REPORT_HDR_A_PRI80_POS_GEN3 (31)
#define SSCAN_SUMMARY_REPORT_HDR_A_PRI80_SIZE_GEN3 (1)
#define SSCAN_SUMMARY_REPORT_HDR_B_GAINCHANGE_POS_GEN3 (30)
#define SSCAN_SUMMARY_REPORT_HDR_B_GAINCHANGE_SIZE_GEN3 (1)
#define SPECTRAL_PHYERR_SIGNATURE_GEN3 (0xFA)
#define TLV_TAG_SPECTRAL_SUMMARY_REPORT_GEN3 (0x02)
#define TLV_TAG_SEARCH_FFT_REPORT_GEN3 (0x03)
#define SPECTRAL_PHYERR_TLVSIZE_GEN3 (4)
#define PHYERR_HDR_SIG_POS \
(offsetof(struct spectral_phyerr_fft_report_gen3, fft_hdr_sig))
#define PHYERR_HDR_TAG_POS \
(offsetof(struct spectral_phyerr_fft_report_gen3, fft_hdr_tag))
#define SPECTRAL_FFT_BINS_POS \
(offsetof(struct spectral_phyerr_fft_report_gen3, buf))
/**
* struct phyerr_info - spectral search fft report for gen3
* @data: handle to phyerror buffer
* @datalen: length of phyerror bufer
* @p_rfqual: rf quality matrices
* @p_chaninfo: pointer to chaninfo
* @tsf64: 64 bit TSF
* @acs_stats: acs stats
*/
struct phyerr_info {
uint8_t *data;
uint32_t datalen;
struct target_if_spectral_rfqual_info *p_rfqual;
struct target_if_spectral_chan_info *p_chaninfo;
uint64_t tsf64;
struct target_if_spectral_acs_stats *acs_stats;
};
/**
* struct spectral_search_fft_info_gen3 - spectral search fft report for gen3
* @timestamp: Timestamp at which fft report was generated
* @fft_detector_id: Which radio generated this report
* @fft_num: The FFT count number. Set to 0 for short FFT.
* @fft_radar_check: NA for spectral
* @fft_peak_sidx: Index of bin with maximum power
* @fft_chn_idx: Rx chain index
* @fft_base_pwr_db: Base power in dB
* @fft_total_gain_db: Total gain in dB
* @fft_num_str_bins_ib: Number of strong bins in the report
* @fft_peak_mag: Peak magnitude
* @fft_avgpwr_db: Average power in dB
* @fft_relpwr_db: Relative power in dB
*/
struct spectral_search_fft_info_gen3 {
uint32_t timestamp;
uint32_t fft_detector_id;
uint32_t fft_num;
uint32_t fft_radar_check;
int32_t fft_peak_sidx;
uint32_t fft_chn_idx;
uint32_t fft_base_pwr_db;
uint32_t fft_total_gain_db;
uint32_t fft_num_str_bins_ib;
int32_t fft_peak_mag;
uint32_t fft_avgpwr_db;
uint32_t fft_relpwr_db;
};
/**
* struct spectral_phyerr_sfftreport_gen3 - fft info in phyerr event
* @fft_timestamp: Timestamp at which fft report was generated
* @fft_hdr_sig: signature
* @fft_hdr_tag: tag
* @fft_hdr_length: length
* @hdr_a: Header[0:31]
* @hdr_b: Header[32:63]
* @hdr_c: Header[64:95]
* @resv: Header[96:127]
* @buf: fft bins
*/
struct spectral_phyerr_fft_report_gen3 {
uint32_t fft_timestamp;
#ifdef BIG_ENDIAN_HOST
uint8_t fft_hdr_sig;
uint8_t fft_hdr_tag;
uint16_t fft_hdr_length;
#else
uint16_t fft_hdr_length;
uint8_t fft_hdr_tag;
uint8_t fft_hdr_sig;
#endif /* BIG_ENDIAN_HOST */
uint32_t hdr_a;
uint32_t hdr_b;
uint32_t hdr_c;
uint32_t resv;
uint8_t buf[0];
} __ATTRIB_PACK;
/**
* struct sscan_report_fields_gen3 - Fields of spectral report
* @sscan_agc_total_gain: The AGC total gain in DB.
* @inband_pwr_db: The in-band power of the signal in 1/2 DB steps
* @sscan_gainchange: This bit is set to 1 if a gainchange occurred during
* the spectral scan FFT. Software may choose to
* disregard the results.
* @sscan_pri80: This is set to 1 to indicate that the Spectral scan was
* performed on the pri80 segment. Software may choose to
* disregard the FFT sample if this is set to 1 but detector ID
* does not correspond to the ID for the pri80 segment.
*/
struct sscan_report_fields_gen3 {
uint8_t sscan_agc_total_gain;
int16_t inband_pwr_db;
uint8_t sscan_gainchange;
uint8_t sscan_pri80;
};
/**
* struct spectral_sscan_summary_report_gen3 - Spectral summary report
* event
* @sscan_timestamp: Timestamp at which fft report was generated
* @sscan_hdr_sig: signature
* @sscan_hdr_tag: tag
* @sscan_hdr_length: length
* @hdr_a: Header[0:31]
* @resv: Header[32:63]
* @hdr_b: Header[64:95]
* @resv: Header[96:127]
*/
struct spectral_sscan_summary_report_gen3 {
u_int32_t sscan_timestamp;
#ifdef BIG_ENDIAN_HOST
u_int8_t sscan_hdr_sig;
u_int8_t sscan_hdr_tag;
u_int16_t sscan_hdr_length;
#else
u_int16_t sscan_hdr_length;
u_int8_t sscan_hdr_tag;
u_int8_t sscan_hdr_sig;
#endif /* BIG_ENDIAN_HOST */
u_int32_t hdr_a;
u_int32_t res1;
u_int32_t hdr_b;
u_int32_t res2;
} __ATTRIB_PACK;
#ifdef DIRECT_BUF_RX_ENABLE
/**
* struct Spectral_report - spectral report
* @data: Report buffer
* @noisefloor: Noise floor values
* @reset_delay: Time taken for warm reset in us
*/
struct spectral_report {
uint8_t *data;
int32_t noisefloor[DBR_MAX_CHAINS];
uint32_t reset_delay;
};
#endif
/* END of spectral GEN III HW specific details */
typedef signed char pwr_dbm;
/**
* enum spectral_gen - spectral hw generation
* @SPECTRAL_GEN1 : spectral hw gen 1
* @SPECTRAL_GEN2 : spectral hw gen 2
* @SPECTRAL_GEN3 : spectral hw gen 3
*/
enum spectral_gen {
SPECTRAL_GEN1,
SPECTRAL_GEN2,
SPECTRAL_GEN3,
};
/**
* enum spectral_fftbin_size_war - spectral fft bin size war
* @SPECTRAL_FFTBIN_SIZE_NO_WAR : No WAR applicable for Spectral FFT bin size
* @SPECTRAL_FFTBIN_SIZE_2BYTE_TO_1BYTE : Spectral FFT bin size: Retain only
* least significant byte from 2 byte
* FFT bin transferred by HW
* @SPECTRAL_FFTBIN_SIZE_4BYTE_TO_1BYTE : Spectral FFT bin size: Retain only
* least significant byte from 4 byte
* FFT bin transferred by HW
*/
enum spectral_fftbin_size_war {
SPECTRAL_FFTBIN_SIZE_NO_WAR = 0,
SPECTRAL_FFTBIN_SIZE_WAR_2BYTE_TO_1BYTE = 1,
SPECTRAL_FFTBIN_SIZE_WAR_4BYTE_TO_1BYTE = 2,
};
#if ATH_PERF_PWR_OFFLOAD
/**
* enum target_if_spectral_info - Enumerations for specifying which spectral
* information (among parameters and states)
* is desired.
* @TARGET_IF_SPECTRAL_INFO_ACTIVE: Indicated whether spectral is active
* @TARGET_IF_SPECTRAL_INFO_ENABLED: Indicated whether spectral is enabled
* @TARGET_IF_SPECTRAL_INFO_PARAMS: Config params
*/
enum target_if_spectral_info {
TARGET_IF_SPECTRAL_INFO_ACTIVE,
TARGET_IF_SPECTRAL_INFO_ENABLED,
TARGET_IF_SPECTRAL_INFO_PARAMS,
};
#endif /* ATH_PERF_PWR_OFFLOAD */
/* forward declaration */
struct target_if_spectral;
/**
* struct target_if_spectral_chan_info - Channel information
* @center_freq1: center frequency 1 in MHz
* @center_freq2: center frequency 2 in MHz -valid only for
* 11ACVHT 80PLUS80 mode
* @chan_width: channel width in MHz
*/
struct target_if_spectral_chan_info {
uint16_t center_freq1;
uint16_t center_freq2;
uint8_t chan_width;
};
/**
* struct target_if_spectral_acs_stats - EACS stats from spectral samples
* @nfc_ctl_rssi: Control chan rssi
* @nfc_ext_rssi: Extension chan rssi
* @ctrl_nf: Control chan Noise Floor
* @ext_nf: Extension chan Noise Floor
*/
struct target_if_spectral_acs_stats {
int8_t nfc_ctl_rssi;
int8_t nfc_ext_rssi;
int8_t ctrl_nf;
int8_t ext_nf;
};
/**
* struct target_if_spectral_perchain_rssi_info - per chain rssi info
* @rssi_pri20: Rssi of primary 20 Mhz
* @rssi_sec20: Rssi of secondary 20 Mhz
* @rssi_sec40: Rssi of secondary 40 Mhz
* @rssi_sec80: Rssi of secondary 80 Mhz
*/
struct target_if_spectral_perchain_rssi_info {
int8_t rssi_pri20;
int8_t rssi_sec20;
int8_t rssi_sec40;
int8_t rssi_sec80;
};
/**
* struct target_if_spectral_rfqual_info - RF measurement information
* @rssi_comb: RSSI Information
* @pc_rssi_info: XXX : For now, we know we are getting information
* for only 4 chains at max. For future extensions
* use a define
* @noise_floor: Noise floor information
*/
struct target_if_spectral_rfqual_info {
int8_t rssi_comb;
struct target_if_spectral_perchain_rssi_info pc_rssi_info[4];
int16_t noise_floor[4];
};
#define GET_TARGET_IF_SPECTRAL_OPS(spectral) \
((struct target_if_spectral_ops *)(&((spectral)->spectral_ops)))
/**
* struct target_if_spectral_ops - spectral low level ops table
* @get_tsf64: Get 64 bit TSF value
* @get_capability: Get capability info
* @set_rxfilter: Set rx filter
* @get_rxfilter: Get rx filter
* @is_spectral_active: Check whether icm is active
* @is_spectral_enabled: Check whether spectral is enabled
* @start_spectral_scan: Start spectral scan
* @stop_spectral_scan: Stop spectral scan
* @get_extension_channel: Get extension channel
* @get_ctl_noisefloor: Get control noise floor
* @get_ext_noisefloor: Get extension noise floor
* @configure_spectral: Set spectral configurations
* @get_spectral_config: Get spectral configurations
* @get_ent_spectral_mask: Get spectral mask
* @get_mac_address: Get mac address
* @get_current_channel: Get current channel
* @reset_hw: Reset HW
* @get_chain_noise_floor: Get Channel noise floor
* @spectral_process_phyerr: Process phyerr event
* @process_spectral_report: Process spectral report
*/
struct target_if_spectral_ops {
uint64_t (*get_tsf64)(void *arg);
uint32_t (*get_capability)(
void *arg, enum spectral_capability_type type);
uint32_t (*set_rxfilter)(void *arg, int rxfilter);
uint32_t (*get_rxfilter)(void *arg);
uint32_t (*is_spectral_active)(void *arg,
enum spectral_scan_mode smode);
uint32_t (*is_spectral_enabled)(void *arg,
enum spectral_scan_mode smode);
uint32_t (*start_spectral_scan)(void *arg,
enum spectral_scan_mode smode,
enum spectral_cp_error_code *err);
uint32_t (*stop_spectral_scan)(void *arg,
enum spectral_scan_mode smode);
uint32_t (*get_extension_channel)(void *arg);
int8_t (*get_ctl_noisefloor)(void *arg);
int8_t (*get_ext_noisefloor)(void *arg);
uint32_t (*configure_spectral)(
void *arg,
struct spectral_config *params,
enum spectral_scan_mode smode);
uint32_t (*get_spectral_config)(
void *arg,
struct spectral_config *params,
enum spectral_scan_mode smode);
uint32_t (*get_ent_spectral_mask)(void *arg);
uint32_t (*get_mac_address)(void *arg, char *addr);
uint32_t (*get_current_channel)(void *arg);
uint32_t (*reset_hw)(void *arg);
uint32_t (*get_chain_noise_floor)(void *arg, int16_t *nf_buf);
int (*spectral_process_phyerr)(struct target_if_spectral *spectral,
uint8_t *data, uint32_t datalen,
struct target_if_spectral_rfqual_info *p_rfqual,
struct target_if_spectral_chan_info *p_chaninfo,
uint64_t tsf64,
struct target_if_spectral_acs_stats *acs_stats);
int (*process_spectral_report)(struct wlan_objmgr_pdev *pdev,
void *payload);
};
/**
* struct target_if_spectral_stats - spectral stats info
* @num_spectral_detects: Total num. of spectral detects
* @total_phy_errors: Total number of phyerrors
* @owl_phy_errors: Indicated phyerrors in old gen1 chipsets
* @pri_phy_errors: Phyerrors in primary channel
* @ext_phy_errors: Phyerrors in secondary channel
* @dc_phy_errors: Phyerrors due to dc
* @early_ext_phy_errors: Early secondary channel phyerrors
* @bwinfo_errors: Bandwidth info errors
* @datalen_discards: Invalid data length errors, seen in gen1 chipsets
* @rssi_discards bw: Indicates reports dropped due to RSSI threshold
* @last_reset_tstamp: Last reset time stamp
*/
struct target_if_spectral_stats {
uint32_t num_spectral_detects;
uint32_t total_phy_errors;
uint32_t owl_phy_errors;
uint32_t pri_phy_errors;
uint32_t ext_phy_errors;
uint32_t dc_phy_errors;
uint32_t early_ext_phy_errors;
uint32_t bwinfo_errors;
uint32_t datalen_discards;
uint32_t rssi_discards;
uint64_t last_reset_tstamp;
};
/**
* struct target_if_spectral_event - spectral event structure
* @se_ts: Original 15 bit recv timestamp
* @se_full_ts: 64-bit full timestamp from interrupt time
* @se_rssi: Rssi of spectral event
* @se_bwinfo: Rssi of spectral event
* @se_dur: Duration of spectral pulse
* @se_chanindex: Channel of event
* @se_list: List of spectral events
*/
struct target_if_spectral_event {
uint32_t se_ts;
uint64_t se_full_ts;
uint8_t se_rssi;
uint8_t se_bwinfo;
uint8_t se_dur;
uint8_t se_chanindex;
STAILQ_ENTRY(spectral_event) se_list;
};
/**
* struct target_if_chain_noise_pwr_info - Noise power info for each channel
* @rptcount: Count of reports in pwr array
* @un_cal_nf: Uncalibrated noise floor
* @factory_cal_nf: Noise floor as calibrated at the factory for module
* @median_pwr: Median power (median of pwr array)
* @pwr: Power reports
*/
struct target_if_chain_noise_pwr_info {
int rptcount;
pwr_dbm un_cal_nf;
pwr_dbm factory_cal_nf;
pwr_dbm median_pwr;
pwr_dbm pwr[];
} __ATTRIB_PACK;
/**
* struct target_if_spectral_chan_stats - Channel information
* @cycle_count: Cycle count
* @channel_load: Channel load
* @per: Period
* @noisefloor: Noise floor
* @comp_usablity: Computed usability
* @maxregpower: Maximum allowed regulatary power
* @comp_usablity_sec80: Computed usability of secondary 80 Mhz
* @maxregpower_sec80: Max regulatory power in secondary 80 Mhz
*/
struct target_if_spectral_chan_stats {
int cycle_count;
int channel_load;
int per;
int noisefloor;
uint16_t comp_usablity;
int8_t maxregpower;
uint16_t comp_usablity_sec80;
int8_t maxregpower_sec80;
};
#if ATH_PERF_PWR_OFFLOAD
/**
* struct target_if_spectral_cache - Cache used to minimize WMI operations
* in offload architecture
* @osc_spectral_enabled: Whether Spectral is enabled
* @osc_spectral_active: Whether spectral is active
* XXX: Ideally, we should NOT cache this
* since the hardware can self clear the bit,
* the firmware can possibly stop spectral due to
* intermittent off-channel activity, etc
* A WMI read command should be introduced to handle
* this This will be discussed.
* @osc_params: Spectral parameters
* @osc_is_valid: Whether the cache is valid
*/
struct target_if_spectral_cache {
uint8_t osc_spectral_enabled;
uint8_t osc_spectral_active;
struct spectral_config osc_params;
uint8_t osc_is_valid;
};
/**
* struct target_if_spectral_param_state_info - Structure used to represent and
* manage spectral information
* (parameters and states)
* @osps_lock: Lock to synchronize accesses to information
* @osps_cache: Cacheable' information
*/
struct target_if_spectral_param_state_info {
qdf_spinlock_t osps_lock;
struct target_if_spectral_cache osps_cache;
/* XXX - Non-cacheable information goes here, in the future */
};
#endif /* ATH_PERF_PWR_OFFLOAD */
struct vdev_spectral_configure_params;
struct vdev_spectral_enable_params;
/**
* struct wmi_spectral_cmd_ops - structure used holding the operations
* related to wmi commands on spectral parameters.
* @wmi_spectral_configure_cmd_send: Configure Spectral parameters
* @wmi_spectral_enable_cmd_send: Enable/Disable Spectral
* @wmi_spectral_crash_inject: Inject FW crash
*/
struct wmi_spectral_cmd_ops {
QDF_STATUS (*wmi_spectral_configure_cmd_send)(
wmi_unified_t wmi_hdl,
struct vdev_spectral_configure_params *param);
QDF_STATUS (*wmi_spectral_enable_cmd_send)(
wmi_unified_t wmi_hdl,
struct vdev_spectral_enable_params *param);
QDF_STATUS(*wmi_spectral_crash_inject)(
wmi_unified_t wmi_handle, struct crash_inject *param);
};
/**
* struct spectral_param_properties - structure holding Spectral
* parameter properties
* @supported: Parameter is supported or not
* @common_all_modes: Parameter should be common for all modes or not
*/
struct spectral_param_properties {
bool supported;
bool common_all_modes;
};
/**
* struct target_if_spectral - main spectral structure
* @pdev: Pointer to pdev
* @spectral_ops: Target if internal Spectral low level operations table
* @capability: Spectral capabilities structure
* @properties: Spectral parameter properties per mode
* @spectral_lock: Lock used for internal Spectral operations
* @spectral_curchan_radindex: Current channel spectral index
* @spectral_extchan_radindex: Extension channel spectral index
* @spectraldomain: Current Spectral domain
* @spectral_proc_phyerr: Flags to process for PHY errors
* @spectral_defaultparams: Default PHY params per Spectral stat
* @spectral_stats: Spectral related stats
* @events: Events structure
* @sc_spectral_ext_chan_ok: Can spectral be detected on the extension channel?
* @sc_spectral_combined_rssi_ok: Can use combined spectral RSSI?
* @sc_spectral_20_40_mode: Is AP in 20-40 mode?
* @sc_spectral_noise_pwr_cal: Noise power cal required?
* @sc_spectral_non_edma: Is the spectral capable device Non-EDMA?
* @upper_is_control: Upper segment is primary
* @upper_is_extension: Upper segment is secondary
* @lower_is_control: Lower segment is primary
* @lower_is_extension: Lower segment is secondary
* @sc_spectraltest_ieeechan: IEEE channel number to return to after a spectral
* mute test
* @spectral_numbins: Number of bins
* @spectral_fft_len: FFT length
* @spectral_data_len: Total phyerror report length
* @lb_edge_extrabins: Number of extra bins on left band edge
* @rb_edge_extrabins: Number of extra bins on right band edge
* @spectral_max_index_offset: Max FFT index offset (20 MHz mode)
* @spectral_upper_max_index_offset: Upper max FFT index offset (20/40 MHz mode)
* @spectral_lower_max_index_offset: Lower max FFT index offset (20/40 MHz mode)
* @spectral_dc_index: At which index DC is present
* @send_single_packet: Deprecated
* @spectral_sent_msg: Indicates whether we send report to upper layers
* @params: Spectral parameters
* @last_capture_time: Indicates timestamp of previouse report
* @num_spectral_data: Number of Spectral samples received in current session
* @total_spectral_data: Total number of Spectral samples received
* @max_rssi: Maximum RSSI
* @detects_control_channel: NA
* @detects_extension_channel: NA
* @detects_below_dc: NA
* @detects_above_dc: NA
* @sc_scanning: Indicates active wifi scan
* @sc_spectral_scan: Indicates active specral scan
* @sc_spectral_full_scan: Deprecated
* @scan_start_tstamp: Deprecated
* @last_tstamp: Deprecated
* @first_tstamp: Deprecated
* @spectral_samp_count: Deprecated
* @sc_spectral_samp_count: Deprecated
* @noise_pwr_reports_reqd: Number of noise power reports required
* @noise_pwr_reports_recv: Number of noise power reports received
* @noise_pwr_reports_lock: Lock used for Noise power report processing
* @noise_pwr_chain_ctl: Noise power report - control channel
* @noise_pwr_chain_ext: Noise power report - extension channel
* @chaninfo: Channel statistics
* @tsf64: Latest TSF Value
* @param_info: Offload architecture Spectral parameter cache information
* @ch_width: Indicates Channel Width 20/40/80/160 MHz with values 0, 1, 2, 3
* respectively
* @diag_stats: Diagnostic statistics
* @is_160_format: Indicates whether information provided by HW is in altered
* format for 802.11ac 160/80+80 MHz support (QCA9984 onwards)
* @is_lb_edge_extrabins_format: Indicates whether information provided by
* HW has 4 extra bins, at left band edge, for report mode 2
* @is_rb_edge_extrabins_format: Indicates whether information provided
* by HW has 4 extra bins, at right band edge, for report mode 2
* @is_sec80_rssi_war_required: Indicates whether the software workaround is
* required to obtain approximate combined RSSI for secondary 80Mhz segment
* @simctx: Spectral Simulation context
* @spectral_gen: Spectral hardware generation
* @hdr_sig_exp: Expected signature in PHYERR TLV header, for the given hardware
* generation
* @tag_sscan_summary_exp: Expected Spectral Scan Summary tag in PHYERR TLV
* header, for the given hardware generation
* @tag_sscan_fft_exp: Expected Spectral Scan FFT report tag in PHYERR TLV
* header, for the given hardware generation
* @tlvhdr_size: Expected PHYERR TLV header size, for the given hardware
* generation
* @nl_cb: Netlink callbacks
* @use_nl_bcast: Whether to use Netlink broadcast/unicast
* @send_phy_data: Send data to the application layer for a particular msg type
* @inband_fftbin_size_adj: Whether to carry out FFT bin size adjustment for
* in-band report format. This would be required on some chipsets under the
* following circumstances: In report mode 2 only the in-band bins are DMA'ed.
* Scatter/gather is used. However, the HW generates all bins, not just in-band,
* and reports the number of bins accordingly. The subsystem arranging for the
* DMA cannot change this value. On such chipsets the adjustment required at the
* host driver is to check if report format is 2, and if so halve the number of
* bins reported to get the number actually DMA'ed.
* @null_fftbin_adj: Whether to remove NULL FFT bins for report mode (1) in
* which only summary of metrics for each completed FFT + spectral scan summary
* report are to be provided. This would be required on some chipsets under the
* following circumstances: In report mode 1, HW reports a length corresponding
* to all bins, and provides bins with value 0. This is because the subsystem
* arranging for the FFT information does not arrange for DMA of FFT bin values
* (as expected), but cannot arrange for a smaller length to be reported by HW.
* In these circumstances, the driver would have to disregard the NULL bins and
* report a bin count of 0 to higher layers.
* @last_fft_timestamp: last fft report timestamp
* @timestamp_war_offset: Offset to be added to correct timestamp
* @dbr_ring_debug: Whether Spectral DBR ring debug is enabled
* @dbr_buff_debug: Whether Spectral DBR buffer debug is enabled
*/
struct target_if_spectral {
struct wlan_objmgr_pdev *pdev_obj;
struct target_if_spectral_ops spectral_ops;
struct spectral_caps capability;
struct spectral_param_properties
properties[SPECTRAL_SCAN_MODE_MAX][SPECTRAL_PARAM_MAX];
qdf_spinlock_t spectral_lock;
int16_t spectral_curchan_radindex;
int16_t spectral_extchan_radindex;
uint32_t spectraldomain;
uint32_t spectral_proc_phyerr;
struct spectral_config spectral_defaultparams;
struct target_if_spectral_stats spectral_stats;
struct target_if_spectral_event *events;
unsigned int sc_spectral_ext_chan_ok:1,
sc_spectral_combined_rssi_ok:1,
sc_spectral_20_40_mode:1,
sc_spectral_noise_pwr_cal:1,
sc_spectral_non_edma:1;
int upper_is_control;
int upper_is_extension;
int lower_is_control;
int lower_is_extension;
uint8_t sc_spectraltest_ieeechan;
int spectral_numbins;
int spectral_fft_len;
int spectral_data_len;
/*
* For 11ac chipsets prior to AR900B version 2.0, a max of 512 bins are
* delivered. However, there can be additional bins reported for
* AR900B version 2.0 and QCA9984 as described next:
*
* AR900B version 2.0: An additional tone is processed on the right
* hand side in order to facilitate detection of radar pulses out to
* the extreme band-edge of the channel frequency. Since the HW design
* processes four tones at a time, this requires one additional Dword
* to be added to the search FFT report.
*
* QCA9984: When spectral_scan_rpt_mode = 2, i.e 2-dword summary +
* 1x-oversampled bins (in-band) per FFT, then 8 more bins
* (4 more on left side and 4 more on right side)are added.
*/
int lb_edge_extrabins;
int rb_edge_extrabins;
int spectral_max_index_offset;
int spectral_upper_max_index_offset;
int spectral_lower_max_index_offset;
int spectral_dc_index;
int send_single_packet;
int spectral_sent_msg;
int classify_scan;
qdf_timer_t classify_timer;
struct spectral_config params[SPECTRAL_SCAN_MODE_MAX];
bool params_valid[SPECTRAL_SCAN_MODE_MAX];
struct spectral_classifier_params classifier_params;
int last_capture_time;
int num_spectral_data;
int total_spectral_data;
int max_rssi;
int detects_control_channel;
int detects_extension_channel;
int detects_below_dc;
int detects_above_dc;
int sc_scanning;
int sc_spectral_scan;
int sc_spectral_full_scan;
uint64_t scan_start_tstamp;
uint32_t last_tstamp;
uint32_t first_tstamp;
uint32_t spectral_samp_count;
uint32_t sc_spectral_samp_count;
int noise_pwr_reports_reqd;
int noise_pwr_reports_recv;
qdf_spinlock_t noise_pwr_reports_lock;
struct target_if_chain_noise_pwr_info
*noise_pwr_chain_ctl[HOST_MAX_ANTENNA];
struct target_if_chain_noise_pwr_info
*noise_pwr_chain_ext[HOST_MAX_ANTENNA];
uint64_t tsf64;
#if ATH_PERF_PWR_OFFLOAD
struct target_if_spectral_param_state_info
param_info[SPECTRAL_SCAN_MODE_MAX];
#endif
uint32_t ch_width;
struct spectral_diag_stats diag_stats;
bool is_160_format;
bool is_lb_edge_extrabins_format;
bool is_rb_edge_extrabins_format;
bool is_sec80_rssi_war_required;
#ifdef QCA_SUPPORT_SPECTRAL_SIMULATION
void *simctx;
#endif
enum spectral_gen spectral_gen;
uint8_t hdr_sig_exp;
uint8_t tag_sscan_summary_exp;
uint8_t tag_sscan_fft_exp;
uint8_t tlvhdr_size;
struct wmi_spectral_cmd_ops param_wmi_cmd_ops;
struct spectral_nl_cb nl_cb;
bool use_nl_bcast;
int (*send_phy_data)(struct wlan_objmgr_pdev *pdev,
enum spectral_msg_type smsg_type);
enum spectral_fftbin_size_war fftbin_size_war;
u_int8_t inband_fftbin_size_adj;
u_int8_t null_fftbin_adj;
enum spectral_160mhz_report_delivery_state state_160mhz_delivery;
void *spectral_report_cache;
uint32_t last_fft_timestamp[SPECTRAL_SCAN_MODE_MAX];
uint32_t timestamp_war_offset[SPECTRAL_SCAN_MODE_MAX];
uint16_t fft_size_min;
uint16_t fft_size_max;
bool dbr_ring_debug;
bool dbr_buff_debug;
};
/**
* struct target_if_samp_msg_params - Spectral Analysis Messaging Protocol
* data format
* @rssi: RSSI (except for secondary 80 segment)
* @rssi_sec80: RSSI for secondary 80 segment
* @lower_rssi: RSSI of lower band
* @upper_rssi: RSSI of upper band
* @chain_ctl_rssi: RSSI for control channel, for all antennas
* @chain_ext_rssi: RSSI for extension channel, for all antennas
* @bwinfo: bandwidth info
* @data_len: length of FFT data (except for secondary 80 segment)
* @data_len_sec80: length of FFT data for secondary 80 segment
* @tstamp: timestamp
* @last_tstamp: last time stamp
* @max_mag: maximum magnitude (except for secondary 80 segment)
* @max_mag_sec80: maximum magnitude for secondary 80 segment
* @max_index: index of max magnitude (except for secondary 80 segment)
* @max_index_sec80: index of max magnitude for secondary 80 segment
* @max_exp: max exp
* @peak: peak frequency (obsolete)
* @pwr_count: number of FFT bins (except for secondary 80 segment)
* @pwr_count_sec80: number of FFT bins in secondary 80 segment
* @nb_lower: This is deprecated
* @nb_upper: This is deprecated
* @max_upper_index: index of max mag in upper band
* @max_lower_index: index of max mag in lower band
* @bin_pwr_data: Contains FFT magnitudes (except for secondary 80 segment)
* @bin_pwr_data_sec80: Contains FFT magnitudes for the secondary 80 segment
* @freq: Center frequency of primary 20MHz channel in MHz
* @vhtop_ch_freq_seg1: VHT operation first segment center frequency in MHz
* @vhtop_ch_freq_seg2: VHT operation second segment center frequency in MHz
* @agile_freq: Center frequency in MHz of the entire span across which Agile
* Spectral is carried out. Applicable only for Agile Spectral samples.
* @freq_loading: spectral control duty cycles
* @noise_floor: current noise floor (except for secondary 80 segment)
* @noise_floor_sec80: current noise floor for secondary 80 segment
* @interf_list: List of interfernce sources
* @classifier_params: classifier parameters
* @sc: classifier parameters
* @pri80ind: Indication from hardware that the sample was received on the
* primary 80 MHz segment. If this is set when smode =
* SPECTRAL_SCAN_MODE_AGILE, it indicates that Spectral was carried out on
* pri80 instead of the Agile frequency due to a channel switch - Software may
* choose to ignore the sample in this case.
* @pri80ind_sec80: Indication from hardware that the sample was received on the
* primary 80 MHz segment instead of the secondary 80 MHz segment due to a
* channel switch - Software may choose to ignore the sample if this is set.
* Applicable only if smode = SPECTRAL_SCAN_MODE_NORMAL and for 160/80+80 MHz
* Spectral operation.
*/
struct target_if_samp_msg_params {
int8_t rssi;
int8_t rssi_sec80;
int8_t lower_rssi;
int8_t upper_rssi;
int8_t chain_ctl_rssi[HOST_MAX_ANTENNA];
int8_t chain_ext_rssi[HOST_MAX_ANTENNA];
uint16_t bwinfo;
uint16_t datalen;
uint16_t datalen_sec80;
uint32_t tstamp;
uint32_t last_tstamp;
uint16_t max_mag;
uint16_t max_mag_sec80;
uint16_t max_index;
uint16_t max_index_sec80;
uint8_t max_exp;
int peak;
int pwr_count;
int pwr_count_sec80;
int8_t nb_lower;
int8_t nb_upper;
uint16_t max_lower_index;
uint16_t max_upper_index;
uint8_t *bin_pwr_data;
uint8_t *bin_pwr_data_sec80;
uint16_t freq;
uint16_t vhtop_ch_freq_seg1;
uint16_t vhtop_ch_freq_seg2;
uint16_t agile_freq;
uint16_t freq_loading;
int16_t noise_floor;
int16_t noise_floor_sec80;
struct interf_src_rsp interf_list;
struct spectral_classifier_params classifier_params;
struct ath_softc *sc;
uint8_t agc_total_gain;
uint8_t agc_total_gain_sec80;
uint8_t gainchange;
uint8_t gainchange_sec80;
enum spectral_scan_mode smode;
uint8_t pri80ind;
uint8_t pri80ind_sec80;
};
#ifdef WLAN_CONV_SPECTRAL_ENABLE
/**
* target_if_spectral_dump_fft() - Dump Spectral FFT
* @pfft: Pointer to Spectral Phyerr FFT
* @fftlen: FFT length
*
* Return: Success or failure
*/
int target_if_spectral_dump_fft(uint8_t *pfft, int fftlen);
/**
* target_if_dbg_print_samp_param() - Print contents of SAMP struct
* @p: Pointer to SAMP message
*
* Return: Void
*/
void target_if_dbg_print_samp_param(struct target_if_samp_msg_params *p);
/**
* target_if_get_offset_swar_sec80() - Get offset for SWAR according to
* the channel width
* @channel_width: Channel width
*
* Return: Offset for SWAR
*/
uint32_t target_if_get_offset_swar_sec80(uint32_t channel_width);
/**
* target_if_sptrl_register_tx_ops() - Register Spectral target_if Tx Ops
* @tx_ops: Tx Ops
*
* Return: void
*/
void target_if_sptrl_register_tx_ops(struct wlan_lmac_if_tx_ops *tx_ops);
/**
* target_if_spectral_create_samp_msg() - Create the spectral samp message
* @spectral : Pointer to spectral internal structure
* @params : spectral samp message parameters
*
* API to create the spectral samp message
*
* Return: void
*/
void target_if_spectral_create_samp_msg(
struct target_if_spectral *spectral,
struct target_if_samp_msg_params *params);
/**
* target_if_spectral_process_phyerr_gen3() - Process phyerror event for gen3
* @pdev: Pointer to pdev object
* @payload: Pointer to spectral report
*
* Process phyerror event for gen3
*
* Return: Success/Failure
*/
int target_if_spectral_process_report_gen3(
struct wlan_objmgr_pdev *pdev,
void *buf);
/**
* target_if_process_phyerr_gen2() - Process PHY Error for gen2
* @spectral: Pointer to Spectral object
* @data: Pointer to phyerror event buffer
* @datalen: Data length
* @p_rfqual: RF quality info
* @p_chaninfo: Channel info
* @tsf64: 64 bit tsf timestamp
* @acs_stats: ACS stats
*
* Process PHY Error for gen2
*
* Return: Success/Failure
*/
int target_if_process_phyerr_gen2(
struct target_if_spectral *spectral,
uint8_t *data,
uint32_t datalen, struct target_if_spectral_rfqual_info *p_rfqual,
struct target_if_spectral_chan_info *p_chaninfo,
uint64_t tsf64,
struct target_if_spectral_acs_stats *acs_stats);
/**
* target_if_spectral_send_intf_found_msg() - Indicate to application layer that
* interference has been found
* @pdev: Pointer to pdev
* @cw_int: 1 if CW interference is found, 0 if WLAN interference is found
* @dcs_enabled: 1 if DCS is enabled, 0 if DCS is disabled
*
* Send message to application layer
* indicating that interference has been found
*
* Return: None
*/
void target_if_spectral_send_intf_found_msg(
struct wlan_objmgr_pdev *pdev,
uint16_t cw_int, uint32_t dcs_enabled);
/**
* target_if_stop_spectral_scan() - Stop spectral scan
* @pdev: Pointer to pdev object
* @smode: Spectral scan mode
* @err: Pointer to error code
*
* API to stop the current on-going spectral scan
*
* Return: QDF_STATUS_SUCCESS in case of success, else QDF_STATUS_E_FAILURE
*/
QDF_STATUS target_if_stop_spectral_scan(struct wlan_objmgr_pdev *pdev,
const enum spectral_scan_mode smode,
enum spectral_cp_error_code *err);
/**
* target_if_spectral_get_vdev() - Get pointer to vdev to be used for Spectral
* operations
* @spectral: Pointer to Spectral target_if internal private data
*
* Spectral operates on pdev. However, in order to retrieve some WLAN
* properties, a vdev is required. To facilitate this, the function returns the
* first vdev in our pdev. The caller should release the reference to the vdev
* once it is done using it.
* TODO: If the framework later provides an API to obtain the first active
* vdev, then it would be preferable to use this API.
*
* Return: Pointer to vdev on success, NULL on failure
*/
struct wlan_objmgr_vdev *target_if_spectral_get_vdev(
struct target_if_spectral *spectral);
/**
* target_if_spectral_dump_hdr_gen2() - Dump Spectral header for gen2
* @phdr: Pointer to Spectral Phyerr Header
*
* Dump Spectral header
*
* Return: Success/Failure
*/
int target_if_spectral_dump_hdr_gen2(struct spectral_phyerr_hdr_gen2 *phdr);
/**
* target_if_get_combrssi_sec80_seg_gen2() - Get approximate combined RSSI
* for Secondary 80 segment
* @spectral: Pointer to spectral object
* @p_sfft_sec80: Pointer to search fft info of secondary 80 segment
*
* Get approximate combined RSSI for Secondary 80 segment
*
* Return: Combined RSSI for secondary 80Mhz segment
*/
int8_t target_if_get_combrssi_sec80_seg_gen2(
struct target_if_spectral *spectral,
struct spectral_search_fft_info_gen2 *p_sfft_sec80);
/**
* target_if_spectral_dump_tlv_gen2() - Dump Spectral TLV for gen2
* @ptlv: Pointer to Spectral Phyerr TLV
* @is_160_format: Indicates 160 format
*
* Dump Spectral TLV for gen2
*
* Return: Success/Failure
*/
int target_if_spectral_dump_tlv_gen2(
struct spectral_phyerr_tlv_gen2 *ptlv, bool is_160_format);
/**
* target_if_spectral_dump_phyerr_data_gen2() - Dump Spectral
* related PHY Error for gen2
* @data: Pointer to phyerror buffer
* @datalen: Data length
* @is_160_format: Indicates 160 format
*
* Dump Spectral related PHY Error for gen2
*
* Return: Success/Failure
*/
int target_if_spectral_dump_phyerr_data_gen2(
uint8_t *data,
uint32_t datalen,
bool is_160_format);
/**
* target_if_dump_fft_report_gen3() - Dump FFT Report for gen3
* @spectral: Pointer to Spectral object
* @smode: Spectral scan mode
* @p_fft_report: Pointer to fft report
* @p_sfft: Pointer to search fft report
*
* Dump FFT Report for gen3
*
* Return: Success/Failure
*/
int target_if_dump_fft_report_gen3(struct target_if_spectral *spectral,
enum spectral_scan_mode smode,
struct spectral_phyerr_fft_report_gen3 *p_fft_report,
struct spectral_search_fft_info_gen3 *p_sfft);
/**
* target_if_dbg_print_samp_msg() - Print contents of SAMP Message
* @p: Pointer to SAMP message
*
* Print contents of SAMP Message
*
* Return: Void
*/
void target_if_dbg_print_samp_msg(struct spectral_samp_msg *pmsg);
/**
* target_if_process_sfft_report_gen3() - Process Search FFT Report for gen3
* @p_fft_report: Pointer to fft report
* @p_sfft: Pointer to search fft report
*
* Process Search FFT Report for gen3
*
* Return: Success/Failure
*/
int target_if_process_sfft_report_gen3(
struct spectral_phyerr_fft_report_gen3 *p_fft_report,
struct spectral_search_fft_info_gen3 *p_fft_info);
/**
* get_target_if_spectral_handle_from_pdev() - Get handle to target_if internal
* Spectral data
* @pdev: Pointer to pdev
*
* Return: Handle to target_if internal Spectral data on success, NULL on
* failure
*/
static inline
struct target_if_spectral *get_target_if_spectral_handle_from_pdev(
struct wlan_objmgr_pdev *pdev)
{
struct target_if_spectral *spectral;
struct wlan_objmgr_psoc *psoc;
if (!pdev) {
spectral_err("pdev is null");
return NULL;
}
psoc = wlan_pdev_get_psoc(pdev);
if (!psoc) {
spectral_err("psoc is null");
return NULL;
}
spectral = (struct target_if_spectral *)
psoc->soc_cb.rx_ops.sptrl_rx_ops.sptrlro_get_target_handle(
pdev);
return spectral;
}
/**
* target_if_vdev_get_chan_freq() - Get the operating channel frequency of a
* given vdev
* @pdev: Pointer to vdev
*
* Get the operating channel frequency of a given vdev
*
* Return: Operating channel frequency of a vdev
*/
static inline
int16_t target_if_vdev_get_chan_freq(struct wlan_objmgr_vdev *vdev)
{
struct wlan_objmgr_psoc *psoc = NULL;
psoc = wlan_vdev_get_psoc(vdev);
if (!psoc) {
spectral_err("psoc is NULL");
return -EINVAL;
}
return psoc->soc_cb.rx_ops.sptrl_rx_ops.sptrlro_vdev_get_chan_freq(
vdev);
}
/**
* target_if_vdev_get_chan_freq_seg2() - Get center frequency of secondary 80 of
* given vdev
* @vdev: Pointer to vdev
*
* Get the center frequency of secondary 80 of given vdev
*
* Return: center frequency of secondary 80
*/
static inline
int16_t target_if_vdev_get_chan_freq_seg2(struct wlan_objmgr_vdev *vdev)
{
struct wlan_objmgr_psoc *psoc = NULL;
psoc = wlan_vdev_get_psoc(vdev);
if (!psoc) {
spectral_err("psoc is NULL");
return -EINVAL;
}
return psoc->soc_cb.rx_ops.sptrl_rx_ops.sptrlro_vdev_get_chan_freq_seg2(
vdev);
}
/**
* target_if_vdev_get_ch_width() - Get the operating channel bandwidth of a
* given vdev
* @pdev: Pointer to vdev
*
* Get the operating channel bandwidth of a given vdev
*
* Return: channel bandwidth enumeration corresponding to the vdev
*/
static inline
enum phy_ch_width target_if_vdev_get_ch_width(struct wlan_objmgr_vdev *vdev)
{
struct wlan_objmgr_psoc *psoc = NULL;
psoc = wlan_vdev_get_psoc(vdev);
if (!psoc) {
spectral_err("psoc is NULL");
return CH_WIDTH_INVALID;
}
return psoc->soc_cb.rx_ops.sptrl_rx_ops.sptrlro_vdev_get_ch_width(
vdev);
}
/**
* target_if_vdev_get_sec20chan_freq_mhz() - Get the frequency of secondary
* 20 MHz channel for a given vdev
* @pdev: Pointer to vdev
*
* Get the frequency of secondary 20Mhz channel for a given vdev
*
* Return: Frequency of secondary 20Mhz channel for a given vdev
*/
static inline
int target_if_vdev_get_sec20chan_freq_mhz(
struct wlan_objmgr_vdev *vdev,
uint16_t *sec20chan_freq)
{
struct wlan_objmgr_psoc *psoc = NULL;
psoc = wlan_vdev_get_psoc(vdev);
if (!psoc) {
spectral_err("psoc is NULL");
return -EINVAL;
}
return psoc->soc_cb.rx_ops.sptrl_rx_ops.
sptrlro_vdev_get_sec20chan_freq_mhz(vdev, sec20chan_freq);
}
/**
* target_if_spectral_set_rxchainmask() - Set Spectral Rx chainmask
* @pdev: Pointer to pdev
* @spectral_rx_chainmask: Spectral Rx chainmask
*
* Return: None
*/
static inline
void target_if_spectral_set_rxchainmask(struct wlan_objmgr_pdev *pdev,
uint8_t spectral_rx_chainmask)
{
struct wlan_objmgr_psoc *psoc = NULL;
struct target_if_spectral *spectral = NULL;
enum spectral_scan_mode smode = SPECTRAL_SCAN_MODE_NORMAL;
psoc = wlan_pdev_get_psoc(pdev);
if (!psoc) {
spectral_err("psoc is NULL");
return;
}
if (smode >= SPECTRAL_SCAN_MODE_MAX) {
spectral_err("Invalid Spectral mode %u", smode);
return;
}
if (psoc->soc_cb.rx_ops.sptrl_rx_ops.
sptrlro_spectral_is_feature_disabled(psoc)) {
spectral_info("Spectral is disabled");
return;
}
spectral = get_target_if_spectral_handle_from_pdev(pdev);
if (!spectral) {
spectral_err("Spectral target if object is null");
return;
}
/* set chainmask for all the modes */
for (; smode < SPECTRAL_SCAN_MODE_MAX; smode++)
spectral->params[smode].ss_chn_mask = spectral_rx_chainmask;
}
/**
* target_if_spectral_process_phyerr() - Process Spectral PHY error
* @pdev: Pointer to pdev
* @data: PHY error data received from FW
* @datalen: Length of data
* @p_rfqual: Pointer to RF Quality information
* @p_chaninfo: Pointer to channel information
* @tsf: TSF time instance at which the Spectral sample was received
* @acs_stats: ACS stats
*
* Process Spectral PHY error by extracting necessary information from the data
* sent by FW, and send the extracted information to application layer.
*
* Return: None
*/
static inline
void target_if_spectral_process_phyerr(
struct wlan_objmgr_pdev *pdev,
uint8_t *data, uint32_t datalen,
struct target_if_spectral_rfqual_info *p_rfqual,
struct target_if_spectral_chan_info *p_chaninfo,
uint64_t tsf64,
struct target_if_spectral_acs_stats *acs_stats)
{
struct target_if_spectral *spectral = NULL;
struct target_if_spectral_ops *p_sops = NULL;
spectral = get_target_if_spectral_handle_from_pdev(pdev);
if (!spectral) {
spectral_err("Spectral target if object is null");
return;
}
p_sops = GET_TARGET_IF_SPECTRAL_OPS(spectral);
p_sops->spectral_process_phyerr(spectral, data, datalen,
p_rfqual, p_chaninfo,
tsf64, acs_stats);
}
static QDF_STATUS
target_if_get_spectral_msg_type(enum spectral_scan_mode smode,
enum spectral_msg_type *msg_type) {
switch (smode) {
case SPECTRAL_SCAN_MODE_NORMAL:
*msg_type = SPECTRAL_MSG_NORMAL_MODE;
break;
case SPECTRAL_SCAN_MODE_AGILE:
*msg_type = SPECTRAL_MSG_AGILE_MODE;
break;
default:
spectral_err("Invalid spectral mode");
return QDF_STATUS_E_FAILURE;
}
return QDF_STATUS_SUCCESS;
}
/**
* init_160mhz_delivery_state_machine() - Initialize 160MHz Spectral
* state machine
* @spectral: Pointer to Spectral
*
* Initialize 160MHz Spectral state machine
*
* Return: void
*/
static inline void
init_160mhz_delivery_state_machine(struct target_if_spectral *spectral)
{
spectral->state_160mhz_delivery =
SPECTRAL_REPORT_WAIT_PRIMARY80;
}
/**
* reset_160mhz_delivery_state_machine() - Reset 160MHz Spectral state machine
* @spectral: Pointer to Spectral
*
* Reset 160MHz Spectral state machine
*
* Return: void
*/
static inline void
reset_160mhz_delivery_state_machine(struct target_if_spectral *spectral,
enum spectral_scan_mode smode)
{
enum spectral_msg_type smsg_type;
QDF_STATUS ret;
if (spectral->ch_width == CH_WIDTH_160MHZ) {
spectral->state_160mhz_delivery =
SPECTRAL_REPORT_WAIT_PRIMARY80;
ret = target_if_get_spectral_msg_type(smode, &smsg_type);
if (QDF_IS_STATUS_ERROR(ret)) {
spectral_err("Failed to reset 160 MHz state machine");
return;
}
spectral->nl_cb.free_sbuff(spectral->pdev_obj,
smsg_type);
}
}
/**
* is_secondaryseg_expected() - Is waiting for secondary 80 report
* @spectral: Pointer to Spectral
*
* Return true if secondary 80 report expected and mode is 160 MHz
*
* Return: true or false
*/
static inline
bool is_secondaryseg_expected(struct target_if_spectral *spectral)
{
return
((spectral->ch_width == CH_WIDTH_160MHZ) &&
(spectral->state_160mhz_delivery == SPECTRAL_REPORT_WAIT_SECONDARY80));
}
/**
* is_primaryseg_expected() - Is waiting for primary 80 report
* @spectral: Pointer to Spectral
*
* Return true if mode is 160 Mhz and primary 80 report expected or
* mode is not 160 Mhz
*
* Return: true or false
*/
static inline
bool is_primaryseg_expected(struct target_if_spectral *spectral)
{
return
((spectral->ch_width != CH_WIDTH_160MHZ) ||
((spectral->ch_width == CH_WIDTH_160MHZ) &&
(spectral->state_160mhz_delivery == SPECTRAL_REPORT_WAIT_PRIMARY80)));
}
/**
* is_primaryseg_rx_inprog() - Is primary 80 report processing is in progress
* @spectral: Pointer to Spectral
*
* Is primary 80 report processing is in progress
*
* Return: true or false
*/
static inline
bool is_primaryseg_rx_inprog(struct target_if_spectral *spectral)
{
return
((spectral->ch_width != CH_WIDTH_160MHZ) ||
((spectral->ch_width == CH_WIDTH_160MHZ) &&
((spectral->spectral_gen == SPECTRAL_GEN2) ||
((spectral->spectral_gen == SPECTRAL_GEN3) &&
(spectral->state_160mhz_delivery == SPECTRAL_REPORT_RX_PRIMARY80)))));
}
/**
* is_secondaryseg_rx_inprog() - Is secondary80 report processing is in progress
* @spectral: Pointer to Spectral
*
* Is secondary 80 report processing is in progress
*
* Return: true or false
*/
static inline
bool is_secondaryseg_rx_inprog(struct target_if_spectral *spectral)
{
return
((spectral->ch_width == CH_WIDTH_160MHZ) &&
((spectral->spectral_gen == SPECTRAL_GEN2) ||
((spectral->spectral_gen == SPECTRAL_GEN3) &&
(spectral->state_160mhz_delivery == SPECTRAL_REPORT_RX_SECONDARY80))));
}
/**
* target_if_160mhz_delivery_state_change() - State transition for 160Mhz
* Spectral
* @spectral: Pointer to spectral object
* @detector_id: Detector id
*
* Move the states of state machine for 160MHz spectral scan report receive
*
* Return: QDF_STATUS
*/
QDF_STATUS
target_if_160mhz_delivery_state_change(struct target_if_spectral *spectral,
uint8_t detector_id);
/**
* target_if_sops_is_spectral_enabled() - Get whether Spectral is enabled
* @arg: Pointer to handle for Spectral target_if internal private data
* @smode: Spectral scan mode
*
* Function to check whether Spectral is enabled
*
* Return: True if Spectral is enabled, false if Spectral is not enabled
*/
uint32_t target_if_sops_is_spectral_enabled(void *arg,
enum spectral_scan_mode smode);
/**
* target_if_sops_is_spectral_active() - Get whether Spectral is active
* @arg: Pointer to handle for Spectral target_if internal private data
* @smode: Spectral scan mode
*
* Function to check whether Spectral is active
*
* Return: True if Spectral is active, false if Spectral is not active
*/
uint32_t target_if_sops_is_spectral_active(void *arg,
enum spectral_scan_mode smode);
/**
* target_if_sops_start_spectral_scan() - Start Spectral scan
* @arg: Pointer to handle for Spectral target_if internal private data
* @smode: Spectral scan mode
* @err: Pointer to error code
*
* Function to start spectral scan
*
* Return: 0 on success else failure
*/
uint32_t target_if_sops_start_spectral_scan(void *arg,
enum spectral_scan_mode smode,
enum spectral_cp_error_code *err);
/**
* target_if_sops_stop_spectral_scan() - Stop Spectral scan
* @arg: Pointer to handle for Spectral target_if internal private data
* @smode: Spectral scan mode
*
* Function to stop spectral scan
*
* Return: 0 in case of success, -1 on failure
*/
uint32_t target_if_sops_stop_spectral_scan(void *arg,
enum spectral_scan_mode smode);
/**
* target_if_spectral_get_extension_channel() - Get the current Extension
* channel (in MHz)
* @arg: Pointer to handle for Spectral target_if internal private data
*
* Return: Current Extension channel (in MHz) on success, 0 on failure or if
* extension channel is not present.
*/
uint32_t target_if_spectral_get_extension_channel(void *arg);
/**
* target_if_spectral_get_current_channel() - Get the current channel (in MHz)
* @arg: Pointer to handle for Spectral target_if internal private data
*
* Return: Current channel (in MHz) on success, 0 on failure
*/
uint32_t target_if_spectral_get_current_channel(void *arg);
/**
* target_if_spectral_reset_hw() - Reset the hardware
* @arg: Pointer to handle for Spectral target_if internal private data
*
* This is only a placeholder since it is not currently required in the offload
* case.
*
* Return: 0
*/
uint32_t target_if_spectral_reset_hw(void *arg);
/**
* target_if_spectral_get_chain_noise_floor() - Get the Chain noise floor from
* Noisefloor history buffer
* @arg: Pointer to handle for Spectral target_if internal private data
* @nf_buf: Pointer to buffer into which chain Noise Floor data should be copied
*
* This is only a placeholder since it is not currently required in the offload
* case.
*
* Return: 0
*/
uint32_t target_if_spectral_get_chain_noise_floor(void *arg, int16_t *nf_buf);
/**
* target_if_spectral_get_ext_noisefloor() - Get the extension channel
* noisefloor
* @arg: Pointer to handle for Spectral target_if internal private data
*
* This is only a placeholder since it is not currently required in the offload
* case.
*
* Return: 0
*/
int8_t target_if_spectral_get_ext_noisefloor(void *arg);
/**
* target_if_spectral_get_ctl_noisefloor() - Get the control channel noisefloor
* @arg: Pointer to handle for Spectral target_if internal private data
*
* This is only a placeholder since it is not currently required in the offload
* case.
*
* Return: 0
*/
int8_t target_if_spectral_get_ctl_noisefloor(void *arg);
/**
* target_if_spectral_get_capability() - Get whether a given Spectral hardware
* capability is available
* @arg: Pointer to handle for Spectral target_if internal private data
* @type: Spectral hardware capability type
*
* Return: True if the capability is available, false if the capability is not
* available
*/
uint32_t target_if_spectral_get_capability(
void *arg, enum spectral_capability_type type);
/**
* target_if_spectral_set_rxfilter() - Set the RX Filter before Spectral start
* @arg: Pointer to handle for Spectral target_if internal private data
* @rxfilter: Rx filter to be used
*
* Note: This is only a placeholder function. It is not currently required since
* FW should be taking care of setting the required filters.
*
* Return: 0
*/
uint32_t target_if_spectral_set_rxfilter(void *arg, int rxfilter);
/**
* target_if_spectral_sops_configure_params() - Configure user supplied Spectral
* parameters
* @arg: Pointer to handle for Spectral target_if internal private data
* @params: Spectral parameters
* @smode: Spectral scan mode
*
* Return: 0 in case of success, -1 on failure
*/
uint32_t target_if_spectral_sops_configure_params(
void *arg, struct spectral_config *params,
enum spectral_scan_mode smode);
/**
* target_if_spectral_get_rxfilter() - Get the current RX Filter settings
* @arg: Pointer to handle for Spectral target_if internal private data
*
* Note: This is only a placeholder function. It is not currently required since
* FW should be taking care of setting the required filters.
*
* Return: 0
*/
uint32_t target_if_spectral_get_rxfilter(void *arg);
/**
* target_if_pdev_spectral_deinit() - De-initialize target_if Spectral
* functionality for the given pdev
* @pdev: Pointer to pdev object
*
* Return: None
*/
void target_if_pdev_spectral_deinit(struct wlan_objmgr_pdev *pdev);
/**
* target_if_set_spectral_config() - Set spectral config
* @pdev: Pointer to pdev object
* @threshtype: config type
* @value: config value
* @smode: Spectral scan mode
* @err: Pointer to Spectral error code
*
* API to set spectral configurations
*
* Return: QDF_STATUS_SUCCESS in case of success, else QDF_STATUS_E_FAILURE
*/
QDF_STATUS target_if_set_spectral_config(struct wlan_objmgr_pdev *pdev,
const uint32_t threshtype,
const uint32_t value,
const enum spectral_scan_mode smode,
enum spectral_cp_error_code *err);
/**
* target_if_pdev_spectral_init() - Initialize target_if Spectral
* functionality for the given pdev
* @pdev: Pointer to pdev object
*
* Return: On success, pointer to Spectral target_if internal private data, on
* failure, NULL
*/
void *target_if_pdev_spectral_init(struct wlan_objmgr_pdev *pdev);
/**
* target_if_spectral_sops_get_params() - Get user configured Spectral
* parameters
* @arg: Pointer to handle for Spectral target_if internal private data
* @params: Pointer to buffer into which Spectral parameters should be copied
* @smode: Spectral scan mode
*
* Return: 0 in case of success, -1 on failure
*/
uint32_t target_if_spectral_sops_get_params(
void *arg, struct spectral_config *params,
enum spectral_scan_mode smode);
/**
* target_if_init_spectral_capability() - Initialize Spectral capability
* @spectral: Pointer to Spectral target_if internal private data
*
* This is a workaround.
*
* Return: QDF_STATUS
*/
QDF_STATUS
target_if_init_spectral_capability(struct target_if_spectral *spectral);
/**
* target_if_start_spectral_scan() - Start spectral scan
* @pdev: Pointer to pdev object
* @smode: Spectral scan mode
* @err: Spectral error code
*
* API to start spectral scan
*
* Return: QDF_STATUS_SUCCESS in case of success, else QDF_STATUS_E_FAILURE
*/
QDF_STATUS target_if_start_spectral_scan(struct wlan_objmgr_pdev *pdev,
enum spectral_scan_mode smode,
enum spectral_cp_error_code *err);
/**
* target_if_get_spectral_config() - Get spectral configuration
* @pdev: Pointer to pdev object
* @param: Pointer to spectral_config structure in which the configuration
* should be returned
* @smode: Spectral scan mode
*
* API to get the current spectral configuration
*
* Return: QDF_STATUS_SUCCESS in case of success, else QDF_STATUS_E_FAILURE
*/
QDF_STATUS target_if_get_spectral_config(struct wlan_objmgr_pdev *pdev,
struct spectral_config *param,
enum spectral_scan_mode smode);
/**
* target_if_spectral_scan_enable_params() - Enable use of desired Spectral
* parameters
* @spectral: Pointer to Spectral target_if internal private data
* @spectral_params: Pointer to Spectral parameters
* @smode: Spectral scan mode
* @err: Spectral error code
*
* Enable use of desired Spectral parameters by configuring them into HW, and
* starting Spectral scan
*
* Return: 0 on success, 1 on failure
*/
int target_if_spectral_scan_enable_params(
struct target_if_spectral *spectral,
struct spectral_config *spectral_params,
enum spectral_scan_mode smode,
enum spectral_cp_error_code *err);
/**
* target_if_is_spectral_active() - Get whether Spectral is active
* @pdev: Pointer to pdev object
* @smode: Spectral scan mode
*
* Return: True if Spectral is active, false if Spectral is not active
*/
bool target_if_is_spectral_active(struct wlan_objmgr_pdev *pdev,
enum spectral_scan_mode smode);
/**
* target_if_is_spectral_enabled() - Get whether Spectral is enabled
* @pdev: Pointer to pdev object
* @smode: Spectral scan mode
*
* Return: True if Spectral is enabled, false if Spectral is not enabled
*/
bool target_if_is_spectral_enabled(struct wlan_objmgr_pdev *pdev,
enum spectral_scan_mode smode);
/**
* target_if_set_debug_level() - Set debug level for Spectral
* @pdev: Pointer to pdev object
* @debug_level: Debug level
*
* Return: QDF_STATUS_SUCCESS in case of success, else QDF_STATUS_E_FAILURE
*
*/
QDF_STATUS target_if_set_debug_level(struct wlan_objmgr_pdev *pdev,
uint32_t debug_level);
/**
* target_if_get_debug_level() - Get debug level for Spectral
* @pdev: Pointer to pdev object
*
* Return: Current debug level
*/
uint32_t target_if_get_debug_level(struct wlan_objmgr_pdev *pdev);
/**
* target_if_get_spectral_capinfo() - Get Spectral capability information
* @pdev: Pointer to pdev object
* @scaps: Buffer into which data should be copied
*
* Return: QDF_STATUS_SUCCESS in case of success, else QDF_STATUS_E_FAILURE
*/
QDF_STATUS target_if_get_spectral_capinfo(struct wlan_objmgr_pdev *pdev,
struct spectral_caps *scaps);
/**
* target_if_get_spectral_diagstats() - Get Spectral diagnostic statistics
* @pdev: Pointer to pdev object
* @stats: Buffer into which data should be copied
*
* Return: QDF_STATUS_SUCCESS in case of success, else QDF_STATUS_E_FAILURE
*/
QDF_STATUS target_if_get_spectral_diagstats(struct wlan_objmgr_pdev *pdev,
struct spectral_diag_stats *stats);
void target_if_register_wmi_spectral_cmd_ops(
struct wlan_objmgr_pdev *pdev,
struct wmi_spectral_cmd_ops *cmd_ops);
QDF_STATUS
target_if_160mhz_delivery_state_change(struct target_if_spectral *spectral,
uint8_t detector_id);
#ifdef DIRECT_BUF_RX_ENABLE
/**
* target_if_consume_sfft_report_gen3() - Process fft report for gen3
* @spectral: Pointer to spectral object
* @report: Pointer to spectral report
*
* Process fft report for gen3
*
* Return: Success/Failure
*/
int
target_if_consume_spectral_report_gen3(
struct target_if_spectral *spectral,
struct spectral_report *report);
#endif
/**
* target_if_spectral_fw_hang() - Crash the FW from Spectral module
* @spectral: Pointer to Spectral LMAC object
*
* Return: QDF_STATUS of operation
*/
QDF_STATUS target_if_spectral_fw_hang(struct target_if_spectral *spectral);
#ifdef WIN32
#pragma pack(pop, target_if_spectral)
#endif
#ifdef __ATTRIB_PACK
#undef __ATTRIB_PACK
#endif
#endif /* WLAN_CONV_SPECTRAL_ENABLE */
#endif /* _TARGET_IF_SPECTRAL_H_ */