#include "wifi_hal.h"
#ifndef __WIFI_HAL_STATS_H
#define __WIFI_HAL_STATS_H
#ifdef __cplusplus
extern "C"
{
#endif /* __cplusplus */
#define STATS_MAJOR_VERSION 1
#define STATS_MINOR_VERSION 0
#define STATS_MICRO_VERSION 0
typedef enum {
WIFI_DISCONNECTED = 0,
WIFI_AUTHENTICATING = 1,
WIFI_ASSOCIATING = 2,
WIFI_ASSOCIATED = 3,
WIFI_EAPOL_STARTED = 4, // if done by firmware/driver
WIFI_EAPOL_COMPLETED = 5, // if done by firmware/driver
} wifi_connection_state;
typedef enum {
WIFI_ROAMING_IDLE = 0,
WIFI_ROAMING_ACTIVE = 1,
} wifi_roam_state;
typedef enum {
WIFI_INTERFACE_STA = 0,
WIFI_INTERFACE_SOFTAP = 1,
WIFI_INTERFACE_IBSS = 2,
WIFI_INTERFACE_P2P_CLIENT = 3,
WIFI_INTERFACE_P2P_GO = 4,
WIFI_INTERFACE_NAN = 5,
WIFI_INTERFACE_MESH = 6,
WIFI_INTERFACE_UNKNOWN = -1
} wifi_interface_mode;
#define WIFI_CAPABILITY_QOS 0x00000001 // set for QOS association
#define WIFI_CAPABILITY_PROTECTED 0x00000002 // set for protected association (802.11 beacon frame control protected bit set)
#define WIFI_CAPABILITY_INTERWORKING 0x00000004 // set if 802.11 Extended Capabilities element interworking bit is set
#define WIFI_CAPABILITY_HS20 0x00000008 // set for HS20 association
#define WIFI_CAPABILITY_SSID_UTF8 0x00000010 // set is 802.11 Extended Capabilities element UTF-8 SSID bit is set
#define WIFI_CAPABILITY_COUNTRY 0x00000020 // set is 802.11 Country Element is present
typedef struct {
wifi_interface_mode mode; // interface mode
u8 mac_addr[6]; // interface mac address (self)
wifi_connection_state state; // connection state (valid for STA, CLI only)
wifi_roam_state roaming; // roaming state
u32 capabilities; // WIFI_CAPABILITY_XXX (self)
u8 ssid[33]; // null terminated SSID
u8 bssid[6]; // bssid
u8 ap_country_str[3]; // country string advertised by AP
u8 country_str[3]; // country string for this association
} wifi_interface_link_layer_info;
/* channel information */
typedef struct {
wifi_channel_width width; // channel width (20, 40, 80, 80+80, 160)
wifi_channel center_freq; // primary 20 MHz channel
wifi_channel center_freq0; // center frequency (MHz) first segment
wifi_channel center_freq1; // center frequency (MHz) second segment
} wifi_channel_info;
/* wifi rate */
typedef struct {
u32 preamble :3; // 0: OFDM, 1:CCK, 2:HT 3:VHT 4..7 reserved
u32 nss :2; // 0:1x1, 1:2x2, 3:3x3, 4:4x4
u32 bw :3; // 0:20MHz, 1:40Mhz, 2:80Mhz, 3:160Mhz
u32 rateMcsIdx :8; // OFDM/CCK rate code would be as per ieee std in the units of 0.5mbps
// HT/VHT it would be mcs index
u32 reserved :16; // reserved
u32 bitrate; // units of 100 Kbps
} wifi_rate;
/* channel statistics */
typedef struct {
wifi_channel_info channel; // channel
u32 on_time; // msecs the radio is awake (32 bits number accruing over time)
u32 cca_busy_time; // msecs the CCA register is busy (32 bits number accruing over time)
} wifi_channel_stat;
// Max number of tx power levels. The actual number vary per device and is specified by |num_tx_levels|
#define RADIO_STAT_MAX_TX_LEVELS 256
/* radio statistics */
typedef struct {
wifi_radio radio; // wifi radio (if multiple radio supported)
u32 on_time; // msecs the radio is awake (32 bits number accruing over time)
u32 tx_time; // msecs the radio is transmitting (32 bits number accruing over time)
u32 num_tx_levels; // number of radio transmit power levels
u32 *tx_time_per_levels; // pointer to an array of radio transmit per power levels in
// msecs accured over time
u32 rx_time; // msecs the radio is in active receive (32 bits number accruing over time)
u32 on_time_scan; // msecs the radio is awake due to all scan (32 bits number accruing over time)
u32 on_time_nbd; // msecs the radio is awake due to NAN (32 bits number accruing over time)
u32 on_time_gscan; // msecs the radio is awake due to G?scan (32 bits number accruing over time)
u32 on_time_roam_scan; // msecs the radio is awake due to roam?scan (32 bits number accruing over time)
u32 on_time_pno_scan; // msecs the radio is awake due to PNO scan (32 bits number accruing over time)
u32 on_time_hs20; // msecs the radio is awake due to HS2.0 scans and GAS exchange (32 bits number accruing over time)
u32 num_channels; // number of channels
wifi_channel_stat channels[]; // channel statistics
} wifi_radio_stat;
/**
* Packet statistics reporting by firmware is performed on MPDU basi (i.e. counters increase by 1 for each MPDU)
* As well, "data packet" in associated comments, shall be interpreted as 802.11 data packet,
* that is, 802.11 frame control subtype == 2 and excluding management and control frames.
*
* As an example, in the case of transmission of an MSDU fragmented in 16 MPDUs which are transmitted
* OTA in a 16 units long a-mpdu, for which a block ack is received with 5 bits set:
* tx_mpdu : shall increase by 5
* retries : shall increase by 16
* tx_ampdu : shall increase by 1
* data packet counters shall not increase regardless of the number of BAR potentially sent by device for this a-mpdu
* data packet counters shall not increase regardless of the number of BA received by device for this a-mpdu
*
* For each subsequent retransmission of the 11 remaining non ACK'ed mpdus
* (regardless of the fact that they are transmitted in a-mpdu or not)
* retries : shall increase by 1
*
* If no subsequent BA or ACK are received from AP, until packet lifetime expires for those 11 packet that were not ACK'ed
* mpdu_lost : shall increase by 11
*/
/* per rate statistics */
typedef struct {
wifi_rate rate; // rate information
u32 tx_mpdu; // number of successfully transmitted data pkts (ACK rcvd)
u32 rx_mpdu; // number of received data pkts
u32 mpdu_lost; // number of data packet losses (no ACK)
u32 retries; // total number of data pkt retries
u32 retries_short; // number of short data pkt retries
u32 retries_long; // number of long data pkt retries
} wifi_rate_stat;
/* access categories */
typedef enum {
WIFI_AC_VO = 0,
WIFI_AC_VI = 1,
WIFI_AC_BE = 2,
WIFI_AC_BK = 3,
WIFI_AC_MAX = 4,
} wifi_traffic_ac;
/* wifi peer type */
typedef enum
{
WIFI_PEER_STA,
WIFI_PEER_AP,
WIFI_PEER_P2P_GO,
WIFI_PEER_P2P_CLIENT,
WIFI_PEER_NAN,
WIFI_PEER_TDLS,
WIFI_PEER_INVALID,
} wifi_peer_type;
/* per peer statistics */
typedef struct {
wifi_peer_type type; // peer type (AP, TDLS, GO etc.)
u8 peer_mac_address[6]; // mac address
u32 capabilities; // peer WIFI_CAPABILITY_XXX
u32 num_rate; // number of rates
wifi_rate_stat rate_stats[]; // per rate statistics, number of entries = num_rate
} wifi_peer_info;
/* Per access category statistics */
typedef struct {
wifi_traffic_ac ac; // access category (VI, VO, BE, BK)
u32 tx_mpdu; // number of successfully transmitted unicast data pkts (ACK rcvd)
u32 rx_mpdu; // number of received unicast data packets
u32 tx_mcast; // number of succesfully transmitted multicast data packets
// STA case: implies ACK received from AP for the unicast packet in which mcast pkt was sent
u32 rx_mcast; // number of received multicast data packets
u32 rx_ampdu; // number of received unicast a-mpdus; support of this counter is optional
u32 tx_ampdu; // number of transmitted unicast a-mpdus; support of this counter is optional
u32 mpdu_lost; // number of data pkt losses (no ACK)
u32 retries; // total number of data pkt retries
u32 retries_short; // number of short data pkt retries
u32 retries_long; // number of long data pkt retries
u32 contention_time_min; // data pkt min contention time (usecs)
u32 contention_time_max; // data pkt max contention time (usecs)
u32 contention_time_avg; // data pkt avg contention time (usecs)
u32 contention_num_samples; // num of data pkts used for contention statistics
} wifi_wmm_ac_stat;
/* interface statistics */
typedef struct {
wifi_interface_handle iface; // wifi interface
wifi_interface_link_layer_info info; // current state of the interface
u32 beacon_rx; // access point beacon received count from connected AP
u64 average_tsf_offset; // average beacon offset encountered (beacon_TSF - TBTT)
// The average_tsf_offset field is used so as to calculate the
// typical beacon contention time on the channel as well may be
// used to debug beacon synchronization and related power consumption issue
u32 leaky_ap_detected; // indicate that this AP typically leaks packets beyond the driver guard time.
u32 leaky_ap_avg_num_frames_leaked; // average number of frame leaked by AP after frame with PM bit set was ACK'ed by AP
u32 leaky_ap_guard_time; // guard time currently in force (when implementing IEEE power management based on
// frame control PM bit), How long driver waits before shutting down the radio and
// after receiving an ACK for a data frame with PM bit set)
u32 mgmt_rx; // access point mgmt frames received count from connected AP (including Beacon)
u32 mgmt_action_rx; // action frames received count
u32 mgmt_action_tx; // action frames transmit count
wifi_rssi rssi_mgmt; // access Point Beacon and Management frames RSSI (averaged)
wifi_rssi rssi_data; // access Point Data Frames RSSI (averaged) from connected AP
wifi_rssi rssi_ack; // access Point ACK RSSI (averaged) from connected AP
wifi_wmm_ac_stat ac[WIFI_AC_MAX]; // per ac data packet statistics
u32 num_peers; // number of peers
wifi_peer_info peer_info[]; // per peer statistics
} wifi_iface_stat;
/* configuration params */
typedef struct {
u32 mpdu_size_threshold; // threshold to classify the pkts as short or long
// packet size < mpdu_size_threshold => short
u32 aggressive_statistics_gathering; // set for field debug mode. Driver should collect all statistics regardless of performance impact.
} wifi_link_layer_params;
/* API to trigger the link layer statistics collection.
Unless his API is invoked - link layer statistics will not be collected.
Radio statistics (once started) do not stop or get reset unless wifi_clear_link_stats is invoked
Interface statistics (once started) reset and start afresh after each connection */
wifi_error wifi_set_link_stats(wifi_interface_handle iface, wifi_link_layer_params params);
/* callback for reporting link layer stats */
typedef struct {
void (*on_link_stats_results) (wifi_request_id id, wifi_iface_stat *iface_stat,
int num_radios, wifi_radio_stat *radio_stat);
} wifi_stats_result_handler;
/* api to collect the link layer statistics for a given iface and all the radio stats */
wifi_error wifi_get_link_stats(wifi_request_id id,
wifi_interface_handle iface, wifi_stats_result_handler handler);
/* wifi statistics bitmap */
#define WIFI_STATS_RADIO 0x00000001 // all radio statistics
#define WIFI_STATS_RADIO_CCA 0x00000002 // cca_busy_time (within radio statistics)
#define WIFI_STATS_RADIO_CHANNELS 0x00000004 // all channel statistics (within radio statistics)
#define WIFI_STATS_RADIO_SCAN 0x00000008 // all scan statistics (within radio statistics)
#define WIFI_STATS_IFACE 0x00000010 // all interface statistics
#define WIFI_STATS_IFACE_TXRATE 0x00000020 // all tx rate statistics (within interface statistics)
#define WIFI_STATS_IFACE_AC 0x00000040 // all ac statistics (within interface statistics)
#define WIFI_STATS_IFACE_CONTENTION 0x00000080 // all contention (min, max, avg) statistics (within ac statisctics)
/* clear api to reset statistics, stats_clear_rsp_mask identifies what stats have been cleared
stop_req = 1 will imply whether to stop the statistics collection.
stop_rsp = 1 will imply that stop_req was honored and statistics collection was stopped.
*/
wifi_error wifi_clear_link_stats(wifi_interface_handle iface,
u32 stats_clear_req_mask, u32 *stats_clear_rsp_mask, u8 stop_req, u8 *stop_rsp);
#ifdef __cplusplus
}
#endif /* __cplusplus */
#endif /*__WIFI_HAL_STATS_ */