libhardware_legacy/include/hardware_legacy/rtt.h - nest-cam/4320010/libhardware_legacy - Git at Google


 #include "wifi_hal.h"
 #include "gscan.h"

 #ifndef __WIFI_HAL_RTT_H__
 #define __WIFI_HAL_RTT_H__

 /* Ranging status */
 typedef enum {
     RTT_STATUS_SUCCESS       = 0,
     RTT_STATUS_FAILURE       = 1,           // general failure status
     RTT_STATUS_FAIL_NO_RSP   = 2,           // target STA does not respond to request
     RTT_STATUS_FAIL_REJECTED = 3,           // request rejected. Applies to 2-sided RTT only
     RTT_STATUS_FAIL_NOT_SCHEDULED_YET  = 4,
     RTT_STATUS_FAIL_TM_TIMEOUT         = 5, // timing measurement times out
     RTT_STATUS_FAIL_AP_ON_DIFF_CHANNEL = 6, // Target on different channel, cannot range
     RTT_STATUS_FAIL_NO_CAPABILITY  = 7,     // ranging not supported
     RTT_STATUS_ABORTED             = 8,     // request aborted for unknown reason
     RTT_STATUS_FAIL_INVALID_TS     = 9,     // Invalid T1-T4 timestamp
     RTT_STATUS_FAIL_PROTOCOL       = 10,    // 11mc protocol failed
     RTT_STATUS_FAIL_SCHEDULE       = 11,    // request could not be scheduled
     RTT_STATUS_FAIL_BUSY_TRY_LATER = 12,    // responder cannot collaborate at time of request
     RTT_STATUS_INVALID_REQ         = 13,    // bad request args
     RTT_STATUS_NO_WIFI             = 14,    // WiFi not enabled
     RTT_STATUS_FAIL_FTM_PARAM_OVERRIDE = 15 // Responder overrides param info, cannot range with new params
 } wifi_rtt_status;

 /* RTT peer type */
 typedef enum {
     RTT_PEER_AP         = 0x1,
     RTT_PEER_STA        = 0x2,
     RTT_PEER_P2P_GO     = 0x3,
     RTT_PEER_P2P_CLIENT = 0x4,
     RTT_PEER_NAN        = 0x5
 } rtt_peer_type;

 /* RTT Measurement Bandwidth */
 typedef enum {
     WIFI_RTT_BW_5   = 0x01,
     WIFI_RTT_BW_10  = 0x02,
     WIFI_RTT_BW_20  = 0x04,
     WIFI_RTT_BW_40  = 0x08,
     WIFI_RTT_BW_80  = 0x10,
     WIFI_RTT_BW_160 = 0x20
 } wifi_rtt_bw;

 /* RTT Measurement Preamble */
 typedef enum {
     WIFI_RTT_PREAMBLE_LEGACY = 0x1,
     WIFI_RTT_PREAMBLE_HT     = 0x2,
     WIFI_RTT_PREAMBLE_VHT    = 0x4
 } wifi_rtt_preamble;

 /* RTT Type */
 typedef enum {
     RTT_TYPE_1_SIDED = 0x1,
     RTT_TYPE_2_SIDED = 0x2,
 } wifi_rtt_type;

 /* RTT configuration */
 typedef struct {
     mac_addr addr;                 // peer device mac address
     wifi_rtt_type type;            // 1-sided or 2-sided RTT
     rtt_peer_type peer;            // optional - peer device hint (STA, P2P, AP)
     wifi_channel_info channel;     // Required for STA-AP mode, optional for P2P, NBD etc.
     unsigned burst_period;         // Time interval between bursts (units: 100 ms).
                                    // Applies to 1-sided and 2-sided RTT multi-burst requests.
                                    // Range: 0-31, 0: no preference by initiator (2-sided RTT)
     unsigned num_burst;            // Total number of RTT bursts to be executed. It will be
                                    // specified in the same way as the parameter "Number of
                                    // Burst Exponent" found in the FTM frame format. It
                                    // applies to both: 1-sided RTT and 2-sided RTT. Valid
                                    // values are 0 to 15 as defined in 802.11mc std.
                                    // 0 means single shot
                                    // The implication of this parameter on the maximum
                                    // number of RTT results is the following:
                                    // for 1-sided RTT: max num of RTT results = (2^num_burst)*(num_frames_per_burst)
                                    // for 2-sided RTT: max num of RTT results = (2^num_burst)*(num_frames_per_burst - 1)
     unsigned num_frames_per_burst; // num of frames per burst.
                                    // Minimum value = 1, Maximum value = 31
                                    // For 2-sided this equals the number of FTM frames
                                    // to be attempted in a single burst. This also
                                    // equals the number of FTM frames that the
                                    // initiator will request that the responder send
                                    // in a single frame.
     unsigned num_retries_per_rtt_frame; // number of retries for a failed RTT frame. Applies
                                         // to 1-sided RTT only. Minimum value = 0, Maximum value = 3

     //following fields are only valid for 2-side RTT
     unsigned num_retries_per_ftmr; // Maximum number of retries that the initiator can
                                    // retry an FTMR frame.
                                    // Minimum value = 0, Maximum value = 3
     byte LCI_request;              // 1: request LCI, 0: do not request LCI
     byte LCR_request;              // 1: request LCR, 0: do not request LCR
     unsigned burst_duration;       // Applies to 1-sided and 2-sided RTT. Valid values will
                                    // be 2-11 and 15 as specified by the 802.11mc std for
                                    // the FTM parameter burst duration. In a multi-burst
                                    // request, if responder overrides with larger value,
                                    // the initiator will return failure. In a single-burst
                                    // request if responder overrides with larger value,
                                    // the initiator will sent TMR_STOP to terminate RTT
                                    // at the end of the burst_duration it requested.
     wifi_rtt_preamble preamble;    // RTT preamble to be used in the RTT frames
     wifi_rtt_bw bw;                // RTT BW to be used in the RTT frames
 } wifi_rtt_config;

 /* RTT results */
 typedef struct {
     mac_addr addr;                // device mac address
     unsigned burst_num;           // burst number in a multi-burst request
     unsigned measurement_number;  // Total RTT measurement frames attempted
     unsigned success_number;      // Total successful RTT measurement frames
     byte  number_per_burst_peer;  // Maximum number of "FTM frames per burst" supported by
                                   // the responder STA. Applies to 2-sided RTT only.
                                   // If reponder overrides with larger value:
                                   // - for single-burst request initiator will truncate the
                                   // larger value and send a TMR_STOP after receiving as
                                   // many frames as originally requested.
                                   // - for multi-burst request, initiator will return
                                   // failure right away.
     wifi_rtt_status status;       // ranging status
     byte retry_after_duration;    // When status == RTT_STATUS_FAIL_BUSY_TRY_LATER,
                                   // this will be the time provided by the responder as to
                                   // when the request can be tried again. Applies to 2-sided
                                   // RTT only. In sec, 1-31sec.
     wifi_rtt_type type;           // RTT type
     wifi_rssi rssi;               // average rssi in 0.5 dB steps e.g. 143 implies -71.5 dB
     wifi_rssi rssi_spread;        // rssi spread in 0.5 dB steps e.g. 5 implies 2.5 dB spread (optional)
     wifi_rate tx_rate;            // 1-sided RTT: TX rate of RTT frame.
                                   // 2-sided RTT: TX rate of initiator's Ack in response to FTM frame.
     wifi_rate rx_rate;            // 1-sided RTT: TX rate of Ack from other side.
                                   // 2-sided RTT: TX rate of FTM frame coming from responder.
     wifi_timespan rtt;            // round trip time in 0.1 nanoseconds
     wifi_timespan rtt_sd;         // rtt standard deviation in 0.1 nanoseconds
     wifi_timespan rtt_spread;     // difference between max and min rtt times recorded
     int distance;                 // distance in cm (optional)
     int distance_sd;              // standard deviation in cm (optional)
     int distance_spread;          // difference between max and min distance recorded (optional)
     wifi_timestamp ts;            // time of the measurement (in microseconds since boot)
     int burst_duration;           // in ms, actual time taken by the FW to finish one burst
                                   // measurement. Applies to 1-sided and 2-sided RTT.
     int negotiated_burst_num;  // Number of bursts allowed by the responder. Applies
                                    // to 2-sided RTT only.
     wifi_information_element *LCI; // for 11mc only
     wifi_information_element *LCR; // for 11mc only
 } wifi_rtt_result;

 /* RTT result callback */
 typedef struct {
     void (*on_rtt_results) (wifi_request_id id, unsigned num_results, wifi_rtt_result *rtt_result[]);
 } wifi_rtt_event_handler;

 /* API to request RTT measurement */
 wifi_error wifi_rtt_range_request(wifi_request_id id, wifi_interface_handle iface,
         unsigned num_rtt_config, wifi_rtt_config rtt_config[], wifi_rtt_event_handler handler);

 /* API to cancel RTT measurements */
 wifi_error wifi_rtt_range_cancel(wifi_request_id id,  wifi_interface_handle iface,
         unsigned num_devices, mac_addr addr[]);

 /* NBD ranging channel map */
 typedef struct {
     wifi_channel availablity[32]; // specifies the channel map for each of the 16 TU windows
     // frequency of 0 => unspecified; which means firmware is
     // free to do whatever it wants in this window.
 } wifi_channel_map;

 /* API to start publishing the channel map on responder device in a NBD cluster.
    Responder device will take this request and schedule broadcasting the channel map
    in a NBD ranging attribute in a SDF. DE will automatically remove the ranging
    attribute from the OTA queue after number of DW specified by num_dw
    where Each DW is 512 TUs apart */
 wifi_error wifi_rtt_channel_map_set(wifi_request_id id,
         wifi_interface_handle iface, wifi_channel_map *params, unsigned num_dw);

 /* API to clear the channel map on the responder device in a NBD cluster.
    Responder device will cancel future ranging channel request, starting from next
    DW interval and will also stop broadcasting NBD ranging attribute in SDF */
 wifi_error wifi_rtt_channel_map_clear(wifi_request_id id,  wifi_interface_handle iface);

 // Preamble definition for bit mask used in wifi_rtt_capabilities
 #define PREAMBLE_LEGACY 0x1
 #define PREAMBLE_HT     0x2
 #define PREAMBLE_VHT    0x4

 // BW definition for bit mask used in wifi_rtt_capabilities
 #define BW_5_SUPPORT   0x1
 #define BW_10_SUPPORT  0x2
 #define BW_20_SUPPORT  0x4
 #define BW_40_SUPPORT  0x8
 #define BW_80_SUPPORT  0x10
 #define BW_160_SUPPORT 0x20

 /* RTT Capabilities */
 typedef struct {
     byte rtt_one_sided_supported;  // if 1-sided rtt data collection is supported
     byte rtt_ftm_supported;        // if ftm rtt data collection is supported
     byte lci_support;              // if initiator supports LCI request. Applies to 2-sided RTT
     byte lcr_support;              // if initiator supports LCR request. Applies to 2-sided RTT
     byte preamble_support;         // bit mask indicates what preamble is supported by initiator
     byte bw_support;               // bit mask indicates what BW is supported by initiator
 } wifi_rtt_capabilities;

 /*  RTT capabilities of the device */
 wifi_error wifi_get_rtt_capabilities(wifi_interface_handle iface, wifi_rtt_capabilities *capabilities);

 /* debugging definitions */
 enum {
     RTT_DEBUG_DISABLE,
     RTT_DEBUG_LOG,
     RTT_DEBUG_PROTO,
     RTT_DEBUG_BURST,
     RTT_DEBUG_ACCURACY,
     RTT_DEBUG_LOGDETAIL
 };  //rtt debug type

 enum {
     RTT_DEBUG_FORMAT_TXT,
     RTT_DEBUG_FORMAT_BINARY
 }; //rtt debug format

 typedef struct rtt_debug {
     unsigned version;
     unsigned len; // total length of after len field
     unsigned type;  // rtt debug type
     unsigned format; //rtt debug format
     char dbuf[0]; // debug content
 } rtt_debug_t;

 /* set configuration for debug */
 wifi_error wifi_rtt_debug_cfg(wifi_interface_handle h, unsigned rtt_dbg_type, char *cfgbuf, unsigned cfg_buf_size);
 /* get the debug information */
 wifi_error wifi_rtt_debug_get(wifi_interface_handle h, rtt_debug_t **debugbuf);
 /* free the debug buffer */
 wifi_error wifi_rtt_debug_free(wifi_interface_handle h, rtt_debug_t *debugbuf);

 /* API for setting LCI/LCR information to be provided to a requestor */
 typedef enum {
     WIFI_MOTION_NOT_EXPECTED = 0, // Not expected to change location
     WIFI_MOTION_EXPECTED = 1,     // Expected to change location
     WIFI_MOTION_UNKNOWN  = 2,     // Movement pattern unknown
 } wifi_motion_pattern;

 typedef struct {
     long latitude;              // latitude in degrees * 2^25 , 2's complement
     long longitude;             // latitude in degrees * 2^25 , 2's complement
     int  altitude;              // Altitude in units of 1/256 m
     byte latitude_unc;          // As defined in Section 2.3.2 of IETF RFC 6225
     byte longitude_unc;         // As defined in Section 2.3.2 of IETF RFC 6225
     byte altitude_unc;          // As defined in Section 2.4.5 from IETF RFC 6225:

     //Following element for configuring the Z subelement
     wifi_motion_pattern motion_pattern;
     int  floor;                 // floor in units of 1/16th of floor. 0x80000000 if unknown.
     int  height_above_floor;    // in units of 1/64 m
     int  height_unc;            // in units of 1/64 m. 0 if unknown
 } wifi_lci_information;

 typedef struct {
     char country_code[2];       // country code
     int  length;                // length of the info field
     char civic_info[256];       // Civic info to be copied in FTM frame
 } wifi_lcr_information;

 // API to configure the LCI. Used in RTT Responder mode only
 wifi_error wifi_set_lci(wifi_request_id id, wifi_interface_handle iface,
                         wifi_lci_information *lci);

 // API to configure the LCR. Used in RTT Responder mode only.
 wifi_error wifi_set_lcr(wifi_request_id id, wifi_interface_handle iface,
                         wifi_lcr_information *lcr);

 #endif

	#include "wifi_hal.h"
	#include "gscan.h"

	#ifndef __WIFI_HAL_RTT_H__
	#define __WIFI_HAL_RTT_H__

	/* Ranging status */
	typedef enum {
	RTT_STATUS_SUCCESS = 0,
	RTT_STATUS_FAILURE = 1, // general failure status
	RTT_STATUS_FAIL_NO_RSP = 2, // target STA does not respond to request
	RTT_STATUS_FAIL_REJECTED = 3, // request rejected. Applies to 2-sided RTT only
	RTT_STATUS_FAIL_NOT_SCHEDULED_YET = 4,
	RTT_STATUS_FAIL_TM_TIMEOUT = 5, // timing measurement times out
	RTT_STATUS_FAIL_AP_ON_DIFF_CHANNEL = 6, // Target on different channel, cannot range
	RTT_STATUS_FAIL_NO_CAPABILITY = 7, // ranging not supported
	RTT_STATUS_ABORTED = 8, // request aborted for unknown reason
	RTT_STATUS_FAIL_INVALID_TS = 9, // Invalid T1-T4 timestamp
	RTT_STATUS_FAIL_PROTOCOL = 10, // 11mc protocol failed
	RTT_STATUS_FAIL_SCHEDULE = 11, // request could not be scheduled
	RTT_STATUS_FAIL_BUSY_TRY_LATER = 12, // responder cannot collaborate at time of request
	RTT_STATUS_INVALID_REQ = 13, // bad request args
	RTT_STATUS_NO_WIFI = 14, // WiFi not enabled
	RTT_STATUS_FAIL_FTM_PARAM_OVERRIDE = 15 // Responder overrides param info, cannot range with new params
	} wifi_rtt_status;

	/* RTT peer type */
	typedef enum {
	RTT_PEER_AP = 0x1,
	RTT_PEER_STA = 0x2,
	RTT_PEER_P2P_GO = 0x3,
	RTT_PEER_P2P_CLIENT = 0x4,
	RTT_PEER_NAN = 0x5
	} rtt_peer_type;

	/* RTT Measurement Bandwidth */
	typedef enum {
	WIFI_RTT_BW_5 = 0x01,
	WIFI_RTT_BW_10 = 0x02,
	WIFI_RTT_BW_20 = 0x04,
	WIFI_RTT_BW_40 = 0x08,
	WIFI_RTT_BW_80 = 0x10,
	WIFI_RTT_BW_160 = 0x20
	} wifi_rtt_bw;

	/* RTT Measurement Preamble */
	typedef enum {
	WIFI_RTT_PREAMBLE_LEGACY = 0x1,
	WIFI_RTT_PREAMBLE_HT = 0x2,
	WIFI_RTT_PREAMBLE_VHT = 0x4
	} wifi_rtt_preamble;

	/* RTT Type */
	typedef enum {
	RTT_TYPE_1_SIDED = 0x1,
	RTT_TYPE_2_SIDED = 0x2,
	} wifi_rtt_type;

	/* RTT configuration */
	typedef struct {
	mac_addr addr; // peer device mac address
	wifi_rtt_type type; // 1-sided or 2-sided RTT
	rtt_peer_type peer; // optional - peer device hint (STA, P2P, AP)
	wifi_channel_info channel; // Required for STA-AP mode, optional for P2P, NBD etc.
	unsigned burst_period; // Time interval between bursts (units: 100 ms).
	// Applies to 1-sided and 2-sided RTT multi-burst requests.
	// Range: 0-31, 0: no preference by initiator (2-sided RTT)
	unsigned num_burst; // Total number of RTT bursts to be executed. It will be
	// specified in the same way as the parameter "Number of
	// Burst Exponent" found in the FTM frame format. It
	// applies to both: 1-sided RTT and 2-sided RTT. Valid
	// values are 0 to 15 as defined in 802.11mc std.
	// 0 means single shot
	// The implication of this parameter on the maximum
	// number of RTT results is the following:
	// for 1-sided RTT: max num of RTT results = (2^num_burst)*(num_frames_per_burst)
	// for 2-sided RTT: max num of RTT results = (2^num_burst)*(num_frames_per_burst - 1)
	unsigned num_frames_per_burst; // num of frames per burst.
	// Minimum value = 1, Maximum value = 31
	// For 2-sided this equals the number of FTM frames
	// to be attempted in a single burst. This also
	// equals the number of FTM frames that the
	// initiator will request that the responder send
	// in a single frame.
	unsigned num_retries_per_rtt_frame; // number of retries for a failed RTT frame. Applies
	// to 1-sided RTT only. Minimum value = 0, Maximum value = 3

	//following fields are only valid for 2-side RTT
	unsigned num_retries_per_ftmr; // Maximum number of retries that the initiator can
	// retry an FTMR frame.
	// Minimum value = 0, Maximum value = 3
	byte LCI_request; // 1: request LCI, 0: do not request LCI
	byte LCR_request; // 1: request LCR, 0: do not request LCR
	unsigned burst_duration; // Applies to 1-sided and 2-sided RTT. Valid values will
	// be 2-11 and 15 as specified by the 802.11mc std for
	// the FTM parameter burst duration. In a multi-burst
	// request, if responder overrides with larger value,
	// the initiator will return failure. In a single-burst
	// request if responder overrides with larger value,
	// the initiator will sent TMR_STOP to terminate RTT
	// at the end of the burst_duration it requested.
	wifi_rtt_preamble preamble; // RTT preamble to be used in the RTT frames
	wifi_rtt_bw bw; // RTT BW to be used in the RTT frames
	} wifi_rtt_config;

	/* RTT results */
	typedef struct {
	mac_addr addr; // device mac address
	unsigned burst_num; // burst number in a multi-burst request
	unsigned measurement_number; // Total RTT measurement frames attempted
	unsigned success_number; // Total successful RTT measurement frames
	byte number_per_burst_peer; // Maximum number of "FTM frames per burst" supported by
	// the responder STA. Applies to 2-sided RTT only.
	// If reponder overrides with larger value:
	// - for single-burst request initiator will truncate the
	// larger value and send a TMR_STOP after receiving as
	// many frames as originally requested.
	// - for multi-burst request, initiator will return
	// failure right away.
	wifi_rtt_status status; // ranging status
	byte retry_after_duration; // When status == RTT_STATUS_FAIL_BUSY_TRY_LATER,
	// this will be the time provided by the responder as to
	// when the request can be tried again. Applies to 2-sided
	// RTT only. In sec, 1-31sec.
	wifi_rtt_type type; // RTT type
	wifi_rssi rssi; // average rssi in 0.5 dB steps e.g. 143 implies -71.5 dB
	wifi_rssi rssi_spread; // rssi spread in 0.5 dB steps e.g. 5 implies 2.5 dB spread (optional)
	wifi_rate tx_rate; // 1-sided RTT: TX rate of RTT frame.
	// 2-sided RTT: TX rate of initiator's Ack in response to FTM frame.
	wifi_rate rx_rate; // 1-sided RTT: TX rate of Ack from other side.
	// 2-sided RTT: TX rate of FTM frame coming from responder.
	wifi_timespan rtt; // round trip time in 0.1 nanoseconds
	wifi_timespan rtt_sd; // rtt standard deviation in 0.1 nanoseconds
	wifi_timespan rtt_spread; // difference between max and min rtt times recorded
	int distance; // distance in cm (optional)
	int distance_sd; // standard deviation in cm (optional)
	int distance_spread; // difference between max and min distance recorded (optional)
	wifi_timestamp ts; // time of the measurement (in microseconds since boot)
	int burst_duration; // in ms, actual time taken by the FW to finish one burst
	// measurement. Applies to 1-sided and 2-sided RTT.
	int negotiated_burst_num; // Number of bursts allowed by the responder. Applies
	// to 2-sided RTT only.
	wifi_information_element *LCI; // for 11mc only
	wifi_information_element *LCR; // for 11mc only
	} wifi_rtt_result;

	/* RTT result callback */
	typedef struct {
	void (on_rtt_results) (wifi_request_id id, unsigned num_results, wifi_rtt_result rtt_result[]);
	} wifi_rtt_event_handler;

	/* API to request RTT measurement */
	wifi_error wifi_rtt_range_request(wifi_request_id id, wifi_interface_handle iface,
	unsigned num_rtt_config, wifi_rtt_config rtt_config[], wifi_rtt_event_handler handler);

	/* API to cancel RTT measurements */
	wifi_error wifi_rtt_range_cancel(wifi_request_id id, wifi_interface_handle iface,
	unsigned num_devices, mac_addr addr[]);

	/* NBD ranging channel map */
	typedef struct {
	wifi_channel availablity[32]; // specifies the channel map for each of the 16 TU windows
	// frequency of 0 => unspecified; which means firmware is
	// free to do whatever it wants in this window.
	} wifi_channel_map;

	/* API to start publishing the channel map on responder device in a NBD cluster.
	Responder device will take this request and schedule broadcasting the channel map
	in a NBD ranging attribute in a SDF. DE will automatically remove the ranging
	attribute from the OTA queue after number of DW specified by num_dw
	where Each DW is 512 TUs apart */
	wifi_error wifi_rtt_channel_map_set(wifi_request_id id,
	wifi_interface_handle iface, wifi_channel_map *params, unsigned num_dw);

	/* API to clear the channel map on the responder device in a NBD cluster.
	Responder device will cancel future ranging channel request, starting from next
	DW interval and will also stop broadcasting NBD ranging attribute in SDF */
	wifi_error wifi_rtt_channel_map_clear(wifi_request_id id, wifi_interface_handle iface);

	// Preamble definition for bit mask used in wifi_rtt_capabilities
	#define PREAMBLE_LEGACY 0x1
	#define PREAMBLE_HT 0x2
	#define PREAMBLE_VHT 0x4

	// BW definition for bit mask used in wifi_rtt_capabilities
	#define BW_5_SUPPORT 0x1
	#define BW_10_SUPPORT 0x2
	#define BW_20_SUPPORT 0x4
	#define BW_40_SUPPORT 0x8
	#define BW_80_SUPPORT 0x10
	#define BW_160_SUPPORT 0x20

	/* RTT Capabilities */
	typedef struct {
	byte rtt_one_sided_supported; // if 1-sided rtt data collection is supported
	byte rtt_ftm_supported; // if ftm rtt data collection is supported
	byte lci_support; // if initiator supports LCI request. Applies to 2-sided RTT
	byte lcr_support; // if initiator supports LCR request. Applies to 2-sided RTT
	byte preamble_support; // bit mask indicates what preamble is supported by initiator
	byte bw_support; // bit mask indicates what BW is supported by initiator
	} wifi_rtt_capabilities;

	/* RTT capabilities of the device */
	wifi_error wifi_get_rtt_capabilities(wifi_interface_handle iface, wifi_rtt_capabilities *capabilities);

	/* debugging definitions */
	enum {
	RTT_DEBUG_DISABLE,
	RTT_DEBUG_LOG,
	RTT_DEBUG_PROTO,
	RTT_DEBUG_BURST,
	RTT_DEBUG_ACCURACY,
	RTT_DEBUG_LOGDETAIL
	}; //rtt debug type

	enum {
	RTT_DEBUG_FORMAT_TXT,
	RTT_DEBUG_FORMAT_BINARY
	}; //rtt debug format

	typedef struct rtt_debug {
	unsigned version;
	unsigned len; // total length of after len field
	unsigned type; // rtt debug type
	unsigned format; //rtt debug format
	char dbuf[0]; // debug content
	} rtt_debug_t;

	/* set configuration for debug */
	wifi_error wifi_rtt_debug_cfg(wifi_interface_handle h, unsigned rtt_dbg_type, char *cfgbuf, unsigned cfg_buf_size);
	/* get the debug information */
	wifi_error wifi_rtt_debug_get(wifi_interface_handle h, rtt_debug_t **debugbuf);
	/* free the debug buffer */
	wifi_error wifi_rtt_debug_free(wifi_interface_handle h, rtt_debug_t *debugbuf);

	/* API for setting LCI/LCR information to be provided to a requestor */
	typedef enum {
	WIFI_MOTION_NOT_EXPECTED = 0, // Not expected to change location
	WIFI_MOTION_EXPECTED = 1, // Expected to change location
	WIFI_MOTION_UNKNOWN = 2, // Movement pattern unknown
	} wifi_motion_pattern;

	typedef struct {
	long latitude; // latitude in degrees * 2^25 , 2's complement
	long longitude; // latitude in degrees * 2^25 , 2's complement
	int altitude; // Altitude in units of 1/256 m
	byte latitude_unc; // As defined in Section 2.3.2 of IETF RFC 6225
	byte longitude_unc; // As defined in Section 2.3.2 of IETF RFC 6225
	byte altitude_unc; // As defined in Section 2.4.5 from IETF RFC 6225:

	//Following element for configuring the Z subelement
	wifi_motion_pattern motion_pattern;
	int floor; // floor in units of 1/16th of floor. 0x80000000 if unknown.
	int height_above_floor; // in units of 1/64 m
	int height_unc; // in units of 1/64 m. 0 if unknown
	} wifi_lci_information;

	typedef struct {
	char country_code[2]; // country code
	int length; // length of the info field
	char civic_info[256]; // Civic info to be copied in FTM frame
	} wifi_lcr_information;

	// API to configure the LCI. Used in RTT Responder mode only
	wifi_error wifi_set_lci(wifi_request_id id, wifi_interface_handle iface,
	wifi_lci_information *lci);

	// API to configure the LCR. Used in RTT Responder mode only.
	wifi_error wifi_set_lcr(wifi_request_id id, wifi_interface_handle iface,
	wifi_lcr_information *lcr);

	#endif