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/*
* Copyright (c) 2004-2010, 2013-2017 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, 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.
*/
/*
* This file was originally distributed by Qualcomm Atheros, Inc.
* under proprietary terms before Copyright ownership was assigned
* to the Linux Foundation.
*/
#ifndef __WLANDEFS_H__
#define __WLANDEFS_H__
#include <a_osapi.h> /* A_COMPILE_TIME_ASSERT */
#include <osdep.h>
/*
* This file contains WLAN definitions that may be used across both
* Host and Target software.
*/
/*
* MAX_SPATIAL_STREAM should be defined in a fwconfig_xxx.h file,
* but for now provide a default value here in case it's not defined
* in the fwconfig_xxx.h file.
*/
#ifndef MAX_SPATIAL_STREAM
#define MAX_SPATIAL_STREAM 3
#endif
/*
* MAX_SPATIAL_STREAM_ANY -
* what is the largest number of spatial streams that any target supports
*/
#define MAX_SPATIAL_STREAM_ANY 4
#ifndef CONFIG_160MHZ_SUPPORT
#define CONFIG_160MHZ_SUPPORT 0 /* default: 160 MHz channels not supported */
#endif
#ifndef SUPPORT_11AX
#define SUPPORT_11AX 0 /* 11ax not supported by default */
#endif
/* defines to set Packet extension values which can be 0 us, 8 us or 16 us */
/* NOTE: Below values cannot be changed without breaking WMI Compatibility */
#define MAX_HE_NSS 8
#define MAX_HE_MODULATION 8
#define MAX_HE_RU 4
#define HE_MODULATION_NONE 7
#define HE_PET_0_USEC 0
#define HE_PET_8_USEC 1
#define HE_PET_16_USEC 2
typedef enum {
MODE_11A = 0, /* 11a Mode */
MODE_11G = 1, /* 11b/g Mode */
MODE_11B = 2, /* 11b Mode */
MODE_11GONLY = 3, /* 11g only Mode */
MODE_11NA_HT20 = 4, /* 11a HT20 mode */
MODE_11NG_HT20 = 5, /* 11g HT20 mode */
MODE_11NA_HT40 = 6, /* 11a HT40 mode */
MODE_11NG_HT40 = 7, /* 11g HT40 mode */
MODE_11AC_VHT20 = 8,
MODE_11AC_VHT40 = 9,
MODE_11AC_VHT80 = 10,
MODE_11AC_VHT20_2G = 11,
MODE_11AC_VHT40_2G = 12,
MODE_11AC_VHT80_2G = 13,
#if CONFIG_160MHZ_SUPPORT
MODE_11AC_VHT80_80 = 14,
MODE_11AC_VHT160 = 15,
#endif
#if SUPPORT_11AX
MODE_11AX_HE20 = 16,
MODE_11AX_HE40 = 17,
MODE_11AX_HE80 = 18,
MODE_11AX_HE80_80 = 19,
MODE_11AX_HE160 = 20,
MODE_11AX_HE20_2G = 21,
MODE_11AX_HE40_2G = 22,
MODE_11AX_HE80_2G = 23,
#endif
/*
* MODE_UNKNOWN should not be used within the host / target interface.
* Thus, it is permissible for ODE_UNKNOWN to be conditionally-defined,
* taking different values when compiling for different targets.
*/
MODE_UNKNOWN,
MODE_UNKNOWN_NO_160MHZ_SUPPORT = 14, /* not needed? */
//MODE_UNKNOWN_NO_11AX_SUPPORT = 16, /* not needed? */
//MODE_UNKNOWN_11AX_SUPPORT = 24, /* not needed? */
MODE_UNKNOWN_160MHZ_SUPPORT = MODE_UNKNOWN, /* not needed? */
MODE_MAX = MODE_UNKNOWN,
MODE_MAX_NO_160_MHZ_SUPPORT = MODE_UNKNOWN_NO_160MHZ_SUPPORT,
MODE_MAX_160_MHZ_SUPPORT = MODE_UNKNOWN_160MHZ_SUPPORT,
} WLAN_PHY_MODE;
#if CONFIG_160MHZ_SUPPORT == 0
A_COMPILE_TIME_ASSERT(
mode_unknown_value_consistency_Check,
MODE_UNKNOWN == MODE_UNKNOWN_NO_160MHZ_SUPPORT);
#else
A_COMPILE_TIME_ASSERT(
mode_unknown_value_consistency_Check,
MODE_UNKNOWN == MODE_UNKNOWN_160MHZ_SUPPORT);
#endif
typedef enum {
VHT_MODE_NONE = 0, /* NON VHT Mode, e.g., HT, DSSS, CCK */
VHT_MODE_20M = 1,
VHT_MODE_40M = 2,
VHT_MODE_80M = 3,
VHT_MODE_160M = 4
} VHT_OPER_MODE;
typedef enum {
WLAN_11A_CAPABILITY = 1,
WLAN_11G_CAPABILITY = 2,
WLAN_11AG_CAPABILITY = 3,
}WLAN_CAPABILITY;
#define SUB20_MODE_NONE (0x00)
#define SUB20_MODE_5MHZ (0x01)
#define SUB20_MODE_10MHZ (0x02)
#if defined(CONFIG_AR900B_SUPPORT) || defined(AR900B)
#define A_RATEMASK A_UINT64
#else
#define A_RATEMASK A_UINT32
#endif
#define A_RATEMASK_NUM_OCTET (sizeof (A_RATEMASK))
#define A_RATEMASK_NUM_BITS ((sizeof (A_RATEMASK)) << 3)
#if CONFIG_160MHZ_SUPPORT
#define IS_MODE_VHT(mode) (((mode) == MODE_11AC_VHT20) || \
((mode) == MODE_11AC_VHT40) || \
((mode) == MODE_11AC_VHT80) || \
((mode) == MODE_11AC_VHT80_80) || \
((mode) == MODE_11AC_VHT160))
#else
#define IS_MODE_VHT(mode) (((mode) == MODE_11AC_VHT20) || \
((mode) == MODE_11AC_VHT40) || \
((mode) == MODE_11AC_VHT80))
#endif
#define IS_MODE_HE(mode) (((mode) == MODE_11AX_HE20) || \
((mode) == MODE_11AX_HE40) || \
((mode) == MODE_11AX_HE80) || \
((mode) == MODE_11AX_HE80_80) || \
((mode) == MODE_11AX_HE160) || \
((mode) == MODE_11AX_HE20_2G) || \
((mode) == MODE_11AX_HE40_2G) || \
((mode) == MODE_11AX_HE80_2G))
#define IS_MODE_VHT_2G(mode) (((mode) == MODE_11AC_VHT20_2G) || \
((mode) == MODE_11AC_VHT40_2G) || \
((mode) == MODE_11AC_VHT80_2G))
#define IS_MODE_11A(mode) (((mode) == MODE_11A) || \
((mode) == MODE_11NA_HT20) || \
((mode) == MODE_11NA_HT40) || \
(IS_MODE_VHT(mode)))
#define IS_MODE_11B(mode) ((mode) == MODE_11B)
#define IS_MODE_11G(mode) (((mode) == MODE_11G) || \
((mode) == MODE_11GONLY) || \
((mode) == MODE_11NG_HT20) || \
((mode) == MODE_11NG_HT40) || \
(IS_MODE_VHT_2G(mode)))
#define IS_MODE_11GN(mode) (((mode) == MODE_11NG_HT20) || \
((mode) == MODE_11NG_HT40))
#define IS_MODE_11GONLY(mode) ((mode) == MODE_11GONLY)
enum {
REGDMN_MODE_11A = 0x00000001, /* 11a channels */
REGDMN_MODE_TURBO = 0x00000002, /* 11a turbo-only channels */
REGDMN_MODE_11B = 0x00000004, /* 11b channels */
REGDMN_MODE_PUREG = 0x00000008, /* 11g channels (OFDM only) */
REGDMN_MODE_11G = 0x00000008, /* XXX historical */
REGDMN_MODE_108G = 0x00000020, /* 11g+Turbo channels */
REGDMN_MODE_108A = 0x00000040, /* 11a+Turbo channels */
REGDMN_MODE_XR = 0x00000100, /* XR channels */
REGDMN_MODE_11A_HALF_RATE = 0x00000200, /* 11A half rate channels */
REGDMN_MODE_11A_QUARTER_RATE = 0x00000400, /* 11A quarter rate channels */
REGDMN_MODE_11NG_HT20 = 0x00000800, /* 11N-G HT20 channels */
REGDMN_MODE_11NA_HT20 = 0x00001000, /* 11N-A HT20 channels */
REGDMN_MODE_11NG_HT40PLUS = 0x00002000, /* 11N-G HT40 + channels */
REGDMN_MODE_11NG_HT40MINUS = 0x00004000, /* 11N-G HT40 - channels */
REGDMN_MODE_11NA_HT40PLUS = 0x00008000, /* 11N-A HT40 + channels */
REGDMN_MODE_11NA_HT40MINUS = 0x00010000, /* 11N-A HT40 - channels */
REGDMN_MODE_11AC_VHT20 = 0x00020000, /* 5Ghz, VHT20 */
REGDMN_MODE_11AC_VHT40PLUS = 0x00040000, /* 5Ghz, VHT40 + channels */
REGDMN_MODE_11AC_VHT40MINUS = 0x00080000, /* 5Ghz VHT40 - channels */
REGDMN_MODE_11AC_VHT80 = 0x000100000, /* 5Ghz, VHT80 channels */
REGDMN_MODE_11AC_VHT20_2G = 0x000200000, /* 2Ghz, VHT20 */
REGDMN_MODE_11AC_VHT40_2G = 0x000400000, /* 2Ghz, VHT40 */
REGDMN_MODE_11AC_VHT80_2G = 0x000800000, /* 2Ghz, VHT80 */
REGDMN_MODE_11AC_VHT160 = 0x001000000, /* 5Ghz, VHT160 */
REGDMN_MODE_11AC_VHT40_2GPLUS = 0x002000000, /* 2Ghz, VHT40+ */
REGDMN_MODE_11AC_VHT40_2GMINUS = 0x004000000, /* 2Ghz, VHT40- */
REGDMN_MODE_11AC_VHT80_80 = 0x008000000, /* 5GHz, VHT80+80 */
};
#define REGDMN_MODE_ALL (0xFFFFFFFF) /* REGDMN_MODE_ALL is defined out of the enum
* to prevent the ARM compile "warning #66:
* enumeration value is out of int range"
* Anyway, this is a BIT-OR of all possible values.
*/
#define REGDMN_CAP1_CHAN_HALF_RATE 0x00000001
#define REGDMN_CAP1_CHAN_QUARTER_RATE 0x00000002
#define REGDMN_CAP1_CHAN_HAL49GHZ 0x00000004
/* regulatory capabilities */
#define REGDMN_EEPROM_EEREGCAP_EN_FCC_MIDBAND 0x0040
#define REGDMN_EEPROM_EEREGCAP_EN_KK_U1_EVEN 0x0080
#define REGDMN_EEPROM_EEREGCAP_EN_KK_U2 0x0100
#define REGDMN_EEPROM_EEREGCAP_EN_KK_MIDBAND 0x0200
#define REGDMN_EEPROM_EEREGCAP_EN_KK_U1_ODD 0x0400
#define REGDMN_EEPROM_EEREGCAP_EN_KK_NEW_11A 0x0800
typedef struct {
A_UINT32 tlv_header; /* TLV tag and len; tag equals WMI_TLVTAG_STRUC_HAL_REG_CAPABILITIES */
A_UINT32 eeprom_rd; //regdomain value specified in EEPROM
A_UINT32 eeprom_rd_ext; //regdomain
A_UINT32 regcap1; // CAP1 capabilities bit map.
A_UINT32 regcap2; // REGDMN EEPROM CAP.
A_UINT32 wireless_modes; // REGDMN MODE
A_UINT32 low_2ghz_chan;
A_UINT32 high_2ghz_chan;
A_UINT32 low_5ghz_chan;
A_UINT32 high_5ghz_chan;
} HAL_REG_CAPABILITIES;
typedef enum {
WHAL_REG_EXT_FCC_MIDBAND = 0,
WHAL_REG_EXT_JAPAN_MIDBAND = 1,
WHAL_REG_EXT_FCC_DFS_HT40 = 2,
WHAL_REG_EXT_JAPAN_NONDFS_HT40 = 3,
WHAL_REG_EXT_JAPAN_DFS_HT40 = 4,
WHAL_REG_EXT_FCC_CH_144 = 5,
} WHAL_REG_EXT_BITMAP;
/*
* Used to update rate-control logic with the status of the tx-completion.
* In host-based implementation of the rate-control feature, this struture is used to
* create the payload for HTT message/s from target to host.
*/
typedef struct {
A_UINT8 rateCode;
A_UINT8 flags;
}RATE_CODE;
typedef struct {
RATE_CODE ptx_rc; /* rate code, bw, chain mask sgi */
A_UINT8 reserved[2];
A_UINT32 flags; /* Encodes information such as excessive
retransmission, aggregate, some info
from .11 frame control,
STBC, LDPC, (SGI and Tx Chain Mask
are encoded in ptx_rc->flags field),
AMPDU truncation (BT/time based etc.),
RTS/CTS attempt */
A_UINT32 num_enqued; /* # of MPDUs (for non-AMPDU 1) for this rate */
A_UINT32 num_retries; /* Total # of transmission attempt for this rate */
A_UINT32 num_failed; /* # of failed MPDUs in A-MPDU, 0 otherwise */
A_UINT32 ack_rssi; /* ACK RSSI: b'7..b'0 avg RSSI across all chain */
A_UINT32 time_stamp ; /* ACK timestamp (helps determine age) */
A_UINT32 is_probe; /* Valid if probing. Else, 0 */
A_UINT32 ba_win_size; /* b'7..b0, block Ack Window size, b'31..b8 Resvd */
A_UINT32 failed_ba_bmap_0_31; /* failed BA bitmap 0..31 */
A_UINT32 failed_ba_bmap_32_63; /* failed BA bitmap 32..63 */
A_UINT32 bmap_tried_0_31; /* enqued bitmap 0..31 */
A_UINT32 bmap_tried_32_63; /* enqued bitmap 32..63 */
} RC_TX_DONE_PARAMS;
#define RC_SET_TX_DONE_INFO(_dst, _rc, _f, _nq, _nr, _nf, _rssi, _ts) \
do { \
(_dst).ptx_rc.rateCode = (_rc).rateCode; \
(_dst).ptx_rc.flags = (_rc).flags; \
(_dst).flags = (_f); \
(_dst).num_enqued = (_nq); \
(_dst).num_retries = (_nr); \
(_dst).num_failed = (_nf); \
(_dst).ack_rssi = (_rssi); \
(_dst).time_stamp = (_ts); \
} while (0)
#define RC_SET_TXBF_DONE_INFO(_dst, _f) \
do { \
(_dst).flags |= (_f); \
} while (0)
/*
* NOTE: NUM_SCHED_ENTRIES is not used in the host/target interface, but for
* historical reasons has been defined in the host/target interface files.
* The NUM_SCHED_ENTRIES definition is being moved into a target-only
* header file for newer (Lithium) targets, but is being left here for
* non-Lithium cases, to avoid having to rework legacy targets to move
* the NUM_SCHED_ENTRIES definition into a target-only header file.
* Moving the NUM_SCHED_ENTRIES definition into a non-Lithium conditional
* block should have no impact on the host, since the host does not use
* NUM_SCHED_ENTRIES.
*/
#define NUM_SCHED_ENTRIES 2
/* NOTE: NUM_DYN_BW cannot be changed without breaking WMI Compatibility */
#define NUM_DYN_BW_MAX 4
/* Some products only use 20/40/80; some use 20/40/80/160 */
#ifndef NUM_DYN_BW
#define NUM_DYN_BW 3 /* default: support up through 80 MHz */
#endif
#define NUM_DYN_BW_MASK 0x3
#define PROD_SCHED_BW_ENTRIES (NUM_SCHED_ENTRIES * NUM_DYN_BW)
typedef A_UINT8 A_RATE;
#if NUM_DYN_BW > 4
// Extend rate table module first
#error "Extend rate table module first"
#endif
#define MAX_IBSS_PEERS 32
#if defined(CONFIG_AR900B_SUPPORT) || defined(AR900B)
typedef struct{
A_UINT32 psdu_len [NUM_DYN_BW * NUM_SCHED_ENTRIES];
A_UINT16 flags[NUM_SCHED_ENTRIES][NUM_DYN_BW];
A_RATE rix[NUM_SCHED_ENTRIES][NUM_DYN_BW];
A_UINT8 tpc[NUM_SCHED_ENTRIES][NUM_DYN_BW];
A_UINT32 antmask[NUM_SCHED_ENTRIES];
A_UINT8 num_mpdus [NUM_DYN_BW * NUM_SCHED_ENTRIES];
A_UINT16 txbf_cv_len;
A_UINT32 txbf_cv_ptr;
A_UINT16 txbf_flags;
A_UINT16 txbf_cv_size;
A_UINT8 txbf_nc_idx;
A_UINT8 tries[NUM_SCHED_ENTRIES];
A_UINT8 bw_mask[NUM_SCHED_ENTRIES];
A_UINT8 max_bw[NUM_SCHED_ENTRIES];
A_UINT8 num_sched_entries;
A_UINT8 paprd_mask;
A_UINT8 rts_rix;
A_UINT8 sh_pream;
A_UINT8 min_spacing_1_4_us;
A_UINT8 fixed_delims;
A_UINT8 bw_in_service;
A_RATE probe_rix;
A_UINT8 num_valid_rates;
A_UINT8 rtscts_tpc;
A_UINT8 dd_profile;
} RC_TX_RATE_SCHEDULE;
#else
typedef struct{
A_UINT32 psdu_len [NUM_DYN_BW * NUM_SCHED_ENTRIES];
A_UINT16 flags [NUM_DYN_BW * NUM_SCHED_ENTRIES];
A_RATE rix [NUM_DYN_BW * NUM_SCHED_ENTRIES];
A_UINT8 tpc [NUM_DYN_BW * NUM_SCHED_ENTRIES];
A_UINT8 num_mpdus [NUM_DYN_BW * NUM_SCHED_ENTRIES];
A_UINT32 antmask [NUM_SCHED_ENTRIES];
A_UINT32 txbf_cv_ptr;
A_UINT16 txbf_cv_len;
A_UINT8 tries [NUM_SCHED_ENTRIES];
A_UINT8 num_valid_rates;
A_UINT8 paprd_mask;
A_UINT8 rts_rix;
A_UINT8 sh_pream;
A_UINT8 min_spacing_1_4_us;
A_UINT8 fixed_delims;
A_UINT8 bw_in_service;
A_RATE probe_rix;
} RC_TX_RATE_SCHEDULE;
#endif
typedef struct{
A_UINT16 flags [NUM_DYN_BW * NUM_SCHED_ENTRIES];
A_RATE rix [NUM_DYN_BW * NUM_SCHED_ENTRIES];
#ifdef DYN_TPC_ENABLE
A_UINT8 tpc [NUM_DYN_BW * NUM_SCHED_ENTRIES];
#endif
#ifdef SECTORED_ANTENNA
A_UINT32 antmask [NUM_SCHED_ENTRIES];
#endif
A_UINT8 tries [NUM_SCHED_ENTRIES];
A_UINT8 num_valid_rates;
A_UINT8 rts_rix;
A_UINT8 sh_pream;
A_UINT8 bw_in_service;
A_RATE probe_rix;
A_UINT8 dd_profile;
} RC_TX_RATE_INFO;
/*
* Temporarily continue to provide the WHAL_RC_INIT_RC_MASKS def in wlan_defs.h
* for older targets.
* The WHAL_RX_INIT_RC_MASKS macro def needs to be moved into ratectrl_11ac.h
* for all targets, but until this is complete, the WHAL_RC_INIT_RC_MASKS def
* will be maintained here in its old location.
*/
#if CONFIG_160MHZ_SUPPORT == 0
#define WHAL_RC_INIT_RC_MASKS(_rm) do { \
_rm[WHAL_RC_MASK_IDX_NON_HT] = A_RATEMASK_OFDM_CCK; \
_rm[WHAL_RC_MASK_IDX_HT_20] = A_RATEMASK_HT_20; \
_rm[WHAL_RC_MASK_IDX_HT_40] = A_RATEMASK_HT_40; \
_rm[WHAL_RC_MASK_IDX_VHT_20] = A_RATEMASK_VHT_20; \
_rm[WHAL_RC_MASK_IDX_VHT_40] = A_RATEMASK_VHT_40; \
_rm[WHAL_RC_MASK_IDX_VHT_80] = A_RATEMASK_VHT_80; \
} while (0)
#endif
/**
* strucutre describing host memory chunk.
*/
typedef struct {
A_UINT32 tlv_header; /* TLV tag and len; tag equals WMITLV_TAG_STRUC_wlan_host_memory_chunk */
/** id of the request that is passed up in service ready */
A_UINT32 req_id;
/** the physical address the memory chunk */
A_UINT32 ptr;
/** size of the chunk */
A_UINT32 size;
} wlan_host_memory_chunk;
#define NUM_UNITS_IS_NUM_VDEVS 0x1
#define NUM_UNITS_IS_NUM_PEERS 0x2
#define NUM_UNITS_IS_NUM_ACTIVE_PEERS 0x4
/* request host to allocate memory contiguously */
#define REQ_TO_HOST_FOR_CONT_MEMORY 0x8
/**
* structure used by FW for requesting host memory
*/
typedef struct {
A_UINT32 tlv_header; /* TLV tag and len; tag equals WMI_TLVTAG_STRUC_wlan_host_mem_req */
/** ID of the request */
A_UINT32 req_id;
/** size of the of each unit */
A_UINT32 unit_size;
/**
* flags to indicate that
* the number units is dependent
* on number of resources(num vdevs num peers .. etc)
*/
A_UINT32 num_unit_info;
/*
* actual number of units to allocate . if flags in the num_unit_info
* indicate that number of units is tied to number of a particular
* resource to allocate then num_units filed is set to 0 and host
* will derive the number units from number of the resources it is
* requesting.
*/
A_UINT32 num_units;
} wlan_host_mem_req;
typedef enum {
IGNORE_DTIM = 0x01,
NORMAL_DTIM = 0x02,
STICK_DTIM = 0x03,
AUTO_DTIM = 0x04,
} BEACON_DTIM_POLICY;
/* During test it is observed that 6 * 400 = 2400 can
* be alloced in addition to CFG_TGT_NUM_MSDU_DESC.
* If there is any change memory requirement, this number
* needs to be revisited. */
#define TOTAL_VOW_ALLOCABLE 2400
#define VOW_DESC_GRAB_MAX 800
#define VOW_GET_NUM_VI_STA(vow_config) (((vow_config) & 0xffff0000) >> 16)
#define VOW_GET_DESC_PER_VI_STA(vow_config) ((vow_config) & 0x0000ffff)
/***TODO!!! Get these values dynamically in WMI_READY event and use it to calculate the mem req*/
/* size in bytes required for msdu descriptor. If it changes, this should be updated. LARGE_AP
* case is not considered. LARGE_AP is disabled when VoW is enabled.*/
#define MSDU_DESC_SIZE 20
/* size in bytes required to support a peer in target.
* This obtained by considering Two tids per peer.
* peer structure = 168 bytes
* tid = 96 bytes (per sta 2 means we need 192 bytes)
* peer_cb = 16 * 2
* key = 52 * 2
* AST = 12 * 2
* rate, reorder.. = 384
* smart antenna = 50
*/
#define MEMORY_REQ_FOR_PEER 800
/*
* NB: it is important to keep all the fields in the structure dword long
* so that it is easy to handle the statistics in BE host.
*/
struct wlan_dbg_tx_stats {
/* Num HTT cookies queued to dispatch list */
A_INT32 comp_queued;
/* Num HTT cookies dispatched */
A_INT32 comp_delivered;
/* Num MSDU queued to WAL */
A_INT32 msdu_enqued;
/* Num MPDU queue to WAL */
A_INT32 mpdu_enqued;
/* Num MSDUs dropped by WMM limit */
A_INT32 wmm_drop;
/* Num Local frames queued */
A_INT32 local_enqued;
/* Num Local frames done */
A_INT32 local_freed;
/* Num queued to HW */
A_INT32 hw_queued;
/* Num PPDU reaped from HW */
A_INT32 hw_reaped;
/* Num underruns */
A_INT32 underrun;
#if defined(AR900B)
/* HW Paused. */
A_UINT32 hw_paused;
#endif
/* Num PPDUs cleaned up in TX abort */
A_INT32 tx_abort;
/* Num MPDUs requed by SW */
A_INT32 mpdus_requed;
/* excessive retries */
A_UINT32 tx_ko;
#if defined(AR900B)
A_UINT32 tx_xretry;
#endif
/* data hw rate code */
A_UINT32 data_rc;
/* Scheduler self triggers */
A_UINT32 self_triggers;
/* frames dropped due to excessive sw retries */
A_UINT32 sw_retry_failure;
/* illegal rate phy errors */
A_UINT32 illgl_rate_phy_err;
/* wal pdev continous xretry */
A_UINT32 pdev_cont_xretry;
/* wal pdev continous xretry */
A_UINT32 pdev_tx_timeout;
/* wal pdev resets */
A_UINT32 pdev_resets;
/* frames dropped due to non-availability of stateless TIDs */
A_UINT32 stateless_tid_alloc_failure;
/* PhY/BB underrun */
A_UINT32 phy_underrun;
/* MPDU is more than txop limit */
A_UINT32 txop_ovf;
#if defined(AR900B)
/* Number of Sequences posted */
A_UINT32 seq_posted;
/* Number of Sequences failed queueing */
A_UINT32 seq_failed_queueing;
/* Number of Sequences completed */
A_UINT32 seq_completed;
/* Number of Sequences restarted */
A_UINT32 seq_restarted;
/* Number of MU Sequences posted */
A_UINT32 mu_seq_posted;
/* Num MPDUs flushed by SW, HWPAUSED, SW TXABORT (Reset,channel change) */
A_INT32 mpdus_sw_flush;
/* Num MPDUs filtered by HW, all filter condition (TTL expired) */
A_INT32 mpdus_hw_filter;
/* Num MPDUs truncated by PDG (TXOP, TBTT, PPDU_duration based on rate, dyn_bw) */
A_INT32 mpdus_truncated;
/* Num MPDUs that was tried but didn't receive ACK or BA */
A_INT32 mpdus_ack_failed;
/* Num MPDUs that was dropped du to expiry. */
A_INT32 mpdus_expired;
/* Num mc drops */
//A_UINT32 mc_drop;
#endif
};
struct wlan_dbg_rx_stats {
/* Cnts any change in ring routing mid-ppdu */
A_INT32 mid_ppdu_route_change;
/* Total number of statuses processed */
A_INT32 status_rcvd;
/* Extra frags on rings 0-3 */
A_INT32 r0_frags;
A_INT32 r1_frags;
A_INT32 r2_frags;
A_INT32 r3_frags;
/* MSDUs / MPDUs delivered to HTT */
A_INT32 htt_msdus;
A_INT32 htt_mpdus;
/* MSDUs / MPDUs delivered to local stack */
A_INT32 loc_msdus;
A_INT32 loc_mpdus;
/* AMSDUs that have more MSDUs than the status ring size */
A_INT32 oversize_amsdu;
/* Number of PHY errors */
A_INT32 phy_errs;
/* Number of PHY errors drops */
A_INT32 phy_err_drop;
/* Number of mpdu errors - FCS, MIC, ENC etc. */
A_INT32 mpdu_errs;
#if defined(AR900B)
/* Number of rx overflow errors. */
A_INT32 rx_ovfl_errs;
#endif
};
struct wlan_dbg_mem_stats {
A_UINT32 iram_free_size;
A_UINT32 dram_free_size;
};
struct wlan_dbg_peer_stats {
A_INT32 dummy; /* REMOVE THIS ONCE REAL PEER STAT COUNTERS ARE ADDED */
};
typedef struct {
A_UINT32 mcs[10];
A_UINT32 sgi[10];
A_UINT32 nss[4];
A_UINT32 nsts;
A_UINT32 stbc[10];
A_UINT32 bw[3];
A_UINT32 pream[6];
A_UINT32 ldpc;
A_UINT32 txbf;
A_UINT32 mgmt_rssi;
A_UINT32 data_rssi;
A_UINT32 rssi_chain0;
A_UINT32 rssi_chain1;
A_UINT32 rssi_chain2;
/*
* TEMPORARY: leave rssi_chain3 in place for AR900B builds until code using
* rssi_chain3 has been converted to use wlan_dbg_rx_rate_info_v2_t.
* At that time, this rssi_chain3 field will be deleted.
*/
#if defined(AR900B)
A_UINT32 rssi_chain3;
#endif
} wlan_dbg_rx_rate_info_t ;
typedef struct {
A_UINT32 mcs[10];
A_UINT32 sgi[10];
/*
* TEMPORARY: leave nss conditionally defined, until all code that
* requires nss[4] is converted to use wlan_dbg_tx_rate_info_v2_t.
* At that time, this nss array will be made length = 3 unconditionally.
*/
#if defined(CONFIG_AR900B_SUPPORT) || defined(AR900B)
A_UINT32 nss[4];
#else
A_UINT32 nss[3];
#endif
A_UINT32 stbc[10];
A_UINT32 bw[3];
A_UINT32 pream[4];
A_UINT32 ldpc;
A_UINT32 rts_cnt;
A_UINT32 ack_rssi;
} wlan_dbg_tx_rate_info_t ;
#define WLAN_MAX_MCS 10
typedef struct {
A_UINT32 mcs[WLAN_MAX_MCS];
A_UINT32 sgi[WLAN_MAX_MCS];
A_UINT32 nss[MAX_SPATIAL_STREAM_ANY];
A_UINT32 nsts;
A_UINT32 stbc[WLAN_MAX_MCS];
A_UINT32 bw[NUM_DYN_BW_MAX];
A_UINT32 pream[6];
A_UINT32 ldpc;
A_UINT32 txbf;
A_UINT32 mgmt_rssi;
A_UINT32 data_rssi;
A_UINT32 rssi_chain0;
A_UINT32 rssi_chain1;
A_UINT32 rssi_chain2;
A_UINT32 rssi_chain3;
A_UINT32 reserved[8];
} wlan_dbg_rx_rate_info_v2_t ;
typedef struct {
A_UINT32 mcs[WLAN_MAX_MCS];
A_UINT32 sgi[WLAN_MAX_MCS];
A_UINT32 nss[MAX_SPATIAL_STREAM_ANY];
A_UINT32 stbc[WLAN_MAX_MCS];
A_UINT32 bw[NUM_DYN_BW_MAX];
A_UINT32 pream[4];
A_UINT32 ldpc;
A_UINT32 rts_cnt;
A_UINT32 ack_rssi;
A_UINT32 reserved[8];
} wlan_dbg_tx_rate_info_v2_t ;
#define WHAL_DBG_PHY_ERR_MAXCNT 18
#define WHAL_DBG_SIFS_STATUS_MAXCNT 8
#define WHAL_DBG_SIFS_ERR_MAXCNT 8
#define WHAL_DBG_CMD_RESULT_MAXCNT 11
#define WHAL_DBG_CMD_STALL_ERR_MAXCNT 4
#define WHAL_DBG_FLUSH_REASON_MAXCNT 40
typedef enum {
WIFI_URRN_STATS_FIRST_PKT,
WIFI_URRN_STATS_BETWEEN_MPDU,
WIFI_URRN_STATS_WITHIN_MPDU,
WHAL_MAX_URRN_STATS
} wifi_urrn_type_t;
typedef struct wlan_dbg_txbf_snd_stats {
A_UINT32 cbf_20[4];
A_UINT32 cbf_40[4];
A_UINT32 cbf_80[4];
A_UINT32 sounding[9];
A_UINT32 cbf_160[4];
}wlan_dbg_txbf_snd_stats_t;
typedef struct wlan_dbg_wifi2_error_stats {
A_UINT32 urrn_stats[WHAL_MAX_URRN_STATS];
A_UINT32 flush_errs[WHAL_DBG_FLUSH_REASON_MAXCNT];
A_UINT32 schd_stall_errs[WHAL_DBG_CMD_STALL_ERR_MAXCNT];
A_UINT32 schd_cmd_result[WHAL_DBG_CMD_RESULT_MAXCNT];
A_UINT32 sifs_status[WHAL_DBG_SIFS_STATUS_MAXCNT];
A_UINT8 phy_errs[WHAL_DBG_PHY_ERR_MAXCNT];
A_UINT32 rx_rate_inval;
}wlan_dbg_wifi2_error_stats_t;
typedef struct wlan_dbg_wifi2_error2_stats {
A_UINT32 schd_errs[WHAL_DBG_CMD_STALL_ERR_MAXCNT];
A_UINT32 sifs_errs[WHAL_DBG_SIFS_ERR_MAXCNT];
}wlan_dbg_wifi2_error2_stats_t;
#define WLAN_DBG_STATS_SIZE_TXBF_VHT 10
#define WLAN_DBG_STATS_SIZE_TXBF_HT 8
#define WLAN_DBG_STATS_SIZE_TXBF_OFDM 8
#define WLAN_DBG_STATS_SIZE_TXBF_CCK 7
typedef struct wlan_dbg_txbf_data_stats {
A_UINT32 tx_txbf_vht[WLAN_DBG_STATS_SIZE_TXBF_VHT];
A_UINT32 rx_txbf_vht[WLAN_DBG_STATS_SIZE_TXBF_VHT];
A_UINT32 tx_txbf_ht[WLAN_DBG_STATS_SIZE_TXBF_HT];
A_UINT32 tx_txbf_ofdm[WLAN_DBG_STATS_SIZE_TXBF_OFDM];
A_UINT32 tx_txbf_cck[WLAN_DBG_STATS_SIZE_TXBF_CCK];
} wlan_dbg_txbf_data_stats_t;
struct wlan_dbg_tx_mu_stats {
A_UINT32 mu_sch_nusers_2;
A_UINT32 mu_sch_nusers_3;
A_UINT32 mu_mpdus_queued_usr[4];
A_UINT32 mu_mpdus_tried_usr[4];
A_UINT32 mu_mpdus_failed_usr[4];
A_UINT32 mu_mpdus_requeued_usr[4];
A_UINT32 mu_err_no_ba_usr[4];
A_UINT32 mu_mpdu_underrun_usr[4];
A_UINT32 mu_ampdu_underrun_usr[4];
};
struct wlan_dbg_tx_selfgen_stats {
A_UINT32 su_ndpa;
A_UINT32 su_ndp;
A_UINT32 mu_ndpa;
A_UINT32 mu_ndp;
A_UINT32 mu_brpoll_1;
A_UINT32 mu_brpoll_2;
A_UINT32 mu_bar_1;
A_UINT32 mu_bar_2;
A_UINT32 cts_burst;
A_UINT32 su_ndp_err;
A_UINT32 su_ndpa_err;
A_UINT32 mu_ndp_err;
A_UINT32 mu_brp1_err;
A_UINT32 mu_brp2_err;
};
typedef struct wlan_dbg_sifs_resp_stats {
A_UINT32 ps_poll_trigger; /* num ps-poll trigger frames */
A_UINT32 uapsd_trigger; /* num uapsd trigger frames */
A_UINT32 qb_data_trigger[2]; /* num data trigger frames; idx 0: explicit and idx 1: implicit */
A_UINT32 qb_bar_trigger[2]; /* num bar trigger frames; idx 0: explicit and idx 1: implicit */
A_UINT32 sifs_resp_data; /* num ppdus transmitted at SIFS interval */
A_UINT32 sifs_resp_err; /* num ppdus failed to meet SIFS resp timing */
} wlan_dgb_sifs_resp_stats_t;
/** wlan_dbg_wifi2_error_stats_t is not grouped with the
* following structure as it is allocated differently and only
* belongs to whal
*/
typedef struct wlan_dbg_stats_wifi2 {
wlan_dbg_txbf_snd_stats_t txbf_snd_info;
wlan_dbg_txbf_data_stats_t txbf_data_info;
struct wlan_dbg_tx_selfgen_stats tx_selfgen;
struct wlan_dbg_tx_mu_stats tx_mu;
wlan_dgb_sifs_resp_stats_t sifs_resp_info;
} wlan_dbg_wifi2_stats_t;
typedef struct {
wlan_dbg_rx_rate_info_t rx_phy_info;
wlan_dbg_tx_rate_info_t tx_rate_info;
} wlan_dbg_rate_info_t;
typedef struct {
wlan_dbg_rx_rate_info_v2_t rx_phy_info;
wlan_dbg_tx_rate_info_v2_t tx_rate_info;
} wlan_dbg_rate_info_v2_t;
struct wlan_dbg_stats {
struct wlan_dbg_tx_stats tx;
struct wlan_dbg_rx_stats rx;
#if defined(AR900B)
struct wlan_dbg_mem_stats mem;
#endif
struct wlan_dbg_peer_stats peer;
};
#define DBG_STATS_MAX_HWQ_NUM 10
#define DBG_STATS_MAX_TID_NUM 20
#define DBG_STATS_MAX_CONG_NUM 16
struct wlan_dbg_txq_stats {
A_UINT16 num_pkts_queued[DBG_STATS_MAX_HWQ_NUM];
A_UINT16 tid_hw_qdepth[DBG_STATS_MAX_TID_NUM];//WAL_MAX_TID is 20
A_UINT16 tid_sw_qdepth[DBG_STATS_MAX_TID_NUM];//WAL_MAX_TID is 20
};
struct wlan_dbg_tidq_stats{
A_UINT32 wlan_dbg_tid_txq_status;
struct wlan_dbg_txq_stats txq_st;
};
typedef enum {
WLAN_DBG_DATA_STALL_NONE = 0,
WLAN_DBG_DATA_STALL_VDEV_PAUSE, /* 1 */
WLAN_DBG_DATA_STALL_HWSCHED_CMD_FILTER, /* 2 */
WLAN_DBG_DATA_STALL_HWSCHED_CMD_FLUSH, /* 3 */
WLAN_DBG_DATA_STALL_RX_REFILL_FAILED, /* 4 */
WLAN_DBG_DATA_STALL_RX_FCS_LEN_ERROR, /* 5 */
WLAN_DBG_DATA_STALL_MAC_WDOG_ERRORS, /* 6 */ /* Mac watch dog */
WLAN_DBG_DATA_STALL_PHY_BB_WDOG_ERROR, /* 7 */ /* PHY watch dog */
WLAN_DBG_DATA_STALL_MAX,
} wlan_dbg_data_stall_type_e;
typedef enum {
WLAN_DBG_DATA_STALL_RECOVERY_NONE = 0,
WLAN_DBG_DATA_STALL_RECOVERY_CONNECT_DISCONNECT,
WLAN_DBG_DATA_STALL_RECOVERY_CONNECT_MAC_PHY_RESET,
WLAN_DBG_DATA_STALL_RECOVERY_CONNECT_PDR,
WLAN_DBG_DATA_STALL_RECOVERY_CONNECT_SSR,
} wlan_dbg_data_stall_recovery_type_e;
#endif /* __WLANDEFS_H__ */