Contributors: 6
Author Tokens Token Proportion Commits Commit Proportion
Hans de Goede 2428 99.39% 1 16.67%
Arnd Bergmann 9 0.37% 1 16.67%
Nathan Chancellor 2 0.08% 1 16.67%
Madhumitha Prabakaran 2 0.08% 1 16.67%
Lukasz Szczesny 1 0.04% 1 16.67%
Yangtao Li 1 0.04% 1 16.67%
Total 2443 6 


/* SPDX-License-Identifier: GPL-2.0 */
/******************************************************************************
 *
 * Copyright(c) 2007 - 2011 Realtek Corporation. All rights reserved.
 *
 ******************************************************************************/
#ifndef __RTW_CMD_H_
#define __RTW_CMD_H_

#include <linux/completion.h>

#define C2H_MEM_SZ (16*1024)

	#define FREE_CMDOBJ_SZ	128

	#define MAX_CMDSZ	1024
	#define MAX_RSPSZ	512
	#define MAX_EVTSZ	1024

	#define CMDBUFF_ALIGN_SZ 512

	struct cmd_obj {
		struct adapter *padapter;
		u16 cmdcode;
		u8 res;
		u8 *parmbuf;
		u32 cmdsz;
		u8 *rsp;
		u32 rspsz;
		struct submit_ctx *sctx;
		struct list_head	list;
	};

	/* cmd flags */
	enum {
		RTW_CMDF_DIRECTLY = BIT0,
		RTW_CMDF_WAIT_ACK = BIT1,
	};

	struct cmd_priv {
		struct completion cmd_queue_comp;
		struct completion terminate_cmdthread_comp;
		struct __queue	cmd_queue;
		u8 cmd_seq;
		u8 *cmd_buf;	/* shall be non-paged, and 4 bytes aligned */
		u8 *cmd_allocated_buf;
		u8 *rsp_buf;	/* shall be non-paged, and 4 bytes aligned */
		u8 *rsp_allocated_buf;
		u32 cmd_issued_cnt;
		u32 cmd_done_cnt;
		u32 rsp_cnt;
		atomic_t cmdthd_running;
		/* u8 cmdthd_running; */
		u8 stop_req;
		struct adapter *padapter;
		_mutex sctx_mutex;
	};

	struct	evt_priv {
		_workitem c2h_wk;
		bool c2h_wk_alive;
		struct rtw_cbuf *c2h_queue;
		#define C2H_QUEUE_MAX_LEN 10

		atomic_t event_seq;
		u8 *evt_buf;	/* shall be non-paged, and 4 bytes aligned */
		u8 *evt_allocated_buf;
		u32 evt_done_cnt;
		u8 *c2h_mem;
		u8 *allocated_c2h_mem;
	};

#define init_h2fwcmd_w_parm_no_rsp(pcmd, pparm, code) \
do {\
	INIT_LIST_HEAD(&pcmd->list);\
	pcmd->cmdcode = code;\
	pcmd->parmbuf = (u8 *)(pparm);\
	pcmd->cmdsz = sizeof(*pparm);\
	pcmd->rsp = NULL;\
	pcmd->rspsz = 0;\
} while (0)

#define init_h2fwcmd_w_parm_no_parm_rsp(pcmd, code) \
do {\
	INIT_LIST_HEAD(&pcmd->list);\
	pcmd->cmdcode = code;\
	pcmd->parmbuf = NULL;\
	pcmd->cmdsz = 0;\
	pcmd->rsp = NULL;\
	pcmd->rspsz = 0;\
} while (0)

struct c2h_evt_hdr {
	u8 id:4;
	u8 plen:4;
	u8 seq;
	u8 payload[0];
};

struct c2h_evt_hdr_88xx {
	u8 id;
	u8 seq;
	u8 payload[12];
	u8 plen;
	u8 trigger;
};

#define c2h_evt_valid(c2h_evt) ((c2h_evt)->id || (c2h_evt)->plen)

struct P2P_PS_Offload_t {
	u8 Offload_En:1;
	u8 role:1; /*  1: Owner, 0: Client */
	u8 CTWindow_En:1;
	u8 NoA0_En:1;
	u8 NoA1_En:1;
	u8 AllStaSleep:1; /*  Only valid in Owner */
	u8 discovery:1;
	u8 rsvd:1;
};

struct P2P_PS_CTWPeriod_t {
	u8 CTWPeriod;	/* TU */
};

int rtw_enqueue_cmd(struct cmd_priv *pcmdpriv, struct cmd_obj *obj);
extern struct cmd_obj *rtw_dequeue_cmd(struct cmd_priv *pcmdpriv);
extern void rtw_free_cmd_obj(struct cmd_obj *pcmd);

void rtw_stop_cmd_thread(struct adapter *adapter);
int rtw_cmd_thread(void *context);

extern void rtw_free_cmd_priv(struct cmd_priv *pcmdpriv);

extern void rtw_free_evt_priv(struct evt_priv *pevtpriv);
extern void rtw_evt_notify_isr(struct evt_priv *pevtpriv);

enum rtw_drvextra_cmd_id
{
	NONE_WK_CID,
	DYNAMIC_CHK_WK_CID,
	DM_CTRL_WK_CID,
	PBC_POLLING_WK_CID,
	POWER_SAVING_CTRL_WK_CID,/* IPS, AUTOSuspend */
	LPS_CTRL_WK_CID,
	ANT_SELECT_WK_CID,
	P2P_PS_WK_CID,
	P2P_PROTO_WK_CID,
	CHECK_HIQ_WK_CID,/* for softap mode, check hi queue if empty */
	INTEl_WIDI_WK_CID,
	C2H_WK_CID,
	RTP_TIMER_CFG_WK_CID,
	RESET_SECURITYPRIV, /*  add for CONFIG_IEEE80211W, none 11w also can use */
	FREE_ASSOC_RESOURCES, /*  add for CONFIG_IEEE80211W, none 11w also can use */
	DM_IN_LPS_WK_CID,
	DM_RA_MSK_WK_CID, /* add for STA update RAMask when bandwith change. */
	BEAMFORMING_WK_CID,
	LPS_CHANGE_DTIM_CID,
	BTINFO_WK_CID,
	MAX_WK_CID
};

enum LPS_CTRL_TYPE
{
	LPS_CTRL_SCAN = 0,
	LPS_CTRL_JOINBSS = 1,
	LPS_CTRL_CONNECT = 2,
	LPS_CTRL_DISCONNECT = 3,
	LPS_CTRL_SPECIAL_PACKET = 4,
	LPS_CTRL_LEAVE = 5,
	LPS_CTRL_TRAFFIC_BUSY = 6,
};

enum RFINTFS {
	SWSI,
	HWSI,
	HWPI,
};

/*
Caller Mode: Infra, Ad-HoC(C)

Notes: To enter USB suspend mode

Command Mode

*/
struct usb_suspend_parm {
	u32 action;/*  1: sleep, 0:resume */
};

/*
Caller Mode: Infra, Ad-HoC

Notes: To join a known BSS.

Command-Event Mode

*/

/*
Caller Mode: Infra, Ad-Hoc

Notes: To join the specified bss

Command Event Mode

*/
struct joinbss_parm {
	struct wlan_bssid_ex network;
};

/*
Caller Mode: Infra, Ad-HoC(C)

Notes: To disconnect the current associated BSS

Command Mode

*/
struct disconnect_parm {
	u32 deauth_timeout_ms;
};

/*
Caller Mode: AP, Ad-HoC(M)

Notes: To create a BSS

Command Mode
*/
struct createbss_parm {
	struct wlan_bssid_ex network;
};

/*
Caller Mode: AP, Ad-HoC, Infra

Notes: To set the NIC mode of RTL8711

Command Mode

The definition of mode:

#define IW_MODE_AUTO	0	 Let the driver decides which AP to join
#define IW_MODE_ADHOC	1	 Single cell network (Ad-Hoc Clients)
#define IW_MODE_INFRA	2	 Multi cell network, roaming, ..
#define IW_MODE_MASTER	3	 Synchronisation master or Access Point
#define IW_MODE_REPEAT	4	 Wireless Repeater (forwarder)
#define IW_MODE_SECOND	5	 Secondary master/repeater (backup)
#define IW_MODE_MONITOR	6	 Passive monitor (listen only)

*/
struct	setopmode_parm {
	u8 mode;
	u8 rsvd[3];
};

/*
Caller Mode: AP, Ad-HoC, Infra

Notes: To ask RTL8711 performing site-survey

Command-Event Mode

*/

#define RTW_SSID_SCAN_AMOUNT 9 /*  for WEXT_CSCAN_AMOUNT 9 */
#define RTW_CHANNEL_SCAN_AMOUNT (14+37)
struct sitesurvey_parm {
	sint scan_mode;	/* active: 1, passive: 0 */
	u8 ssid_num;
	u8 ch_num;
	struct ndis_802_11_ssid ssid[RTW_SSID_SCAN_AMOUNT];
	struct rtw_ieee80211_channel ch[RTW_CHANNEL_SCAN_AMOUNT];
};

/*
Caller Mode: Any

Notes: To set the auth type of RTL8711. open/shared/802.1x

Command Mode

*/
struct setauth_parm {
	u8 mode;  /* 0: legacy open, 1: legacy shared 2: 802.1x */
	u8 _1x;   /* 0: PSK, 1: TLS */
	u8 rsvd[2];
};

/*
Caller Mode: Infra

a. algorithm: wep40, wep104, tkip & aes
b. keytype: grp key/unicast key
c. key contents

when shared key ==> keyid is the camid
when 802.1x ==> keyid [0:1] ==> grp key
when 802.1x ==> keyid > 2 ==> unicast key

*/
struct setkey_parm {
	u8 algorithm;	/*  encryption algorithm, could be none, wep40, TKIP, CCMP, wep104 */
	u8 keyid;
	u8 grpkey;		/*  1: this is the grpkey for 802.1x. 0: this is the unicast key for 802.1x */
	u8 set_tx;		/*  1: main tx key for wep. 0: other key. */
	u8 key[16];	/*  this could be 40 or 104 */
};

/*
When in AP or Ad-Hoc mode, this is used to
allocate an sw/hw entry for a newly associated sta.

Command

when shared key ==> algorithm/keyid

*/
struct set_stakey_parm {
	u8 addr[ETH_ALEN];
	u8 algorithm;
	u8 keyid;
	u8 key[16];
};

struct set_stakey_rsp {
	u8 addr[ETH_ALEN];
	u8 keyid;
	u8 rsvd;
};

/*
Caller Ad-Hoc/AP

Command -Rsp(AID == CAMID) mode

This is to force fw to add an sta_data entry per driver's request.

FW will write an cam entry associated with it.

*/
struct set_assocsta_parm {
	u8 addr[ETH_ALEN];
};

struct set_assocsta_rsp {
	u8 cam_id;
	u8 rsvd[3];
};

/*
	Caller Ad-Hoc/AP

	Command mode

	This is to force fw to del an sta_data entry per driver's request

	FW will invalidate the cam entry associated with it.

*/
struct del_assocsta_parm {
	u8 addr[ETH_ALEN];
};

/*
Caller Mode: AP/Ad-HoC(M)

Notes: To notify fw that given staid has changed its power state

Command Mode

*/
struct setstapwrstate_parm {
	u8 staid;
	u8 status;
	u8 hwaddr[6];
};

/*
Caller Mode: Any

Notes: To setup the basic rate of RTL8711

Command Mode

*/
struct	setbasicrate_parm {
	u8 basicrates[NumRates];
};

/*
Caller Mode: Any

Notes: To read the current basic rate

Command-Rsp Mode

*/
struct getbasicrate_parm {
	u32 rsvd;
};

struct getbasicrate_rsp {
	u8 basicrates[NumRates];
};

/*
Caller Mode: Any

Notes: To setup the data rate of RTL8711

Command Mode

*/
struct setdatarate_parm {
	u8 mac_id;
	u8 datarates[NumRates];
};

/*
Caller Mode: Any

Notes: To read the current data rate

Command-Rsp Mode

*/
struct getdatarate_parm {
	u32 rsvd;

};
struct getdatarate_rsp {
	u8 datarates[NumRates];
};


/*
Caller Mode: Any
AP: AP can use the info for the contents of beacon frame
Infra: STA can use the info when sitesurveying
Ad-HoC(M): Like AP
Ad-HoC(C): Like STA


Notes: To set the phy capability of the NIC

Command Mode

*/

struct	setphyinfo_parm {
	struct regulatory_class class_sets[NUM_REGULATORYS];
	u8 status;
};

struct	getphyinfo_parm {
	u32 rsvd;
};

struct	getphyinfo_rsp {
	struct regulatory_class class_sets[NUM_REGULATORYS];
	u8 status;
};

/*
Caller Mode: Any

Notes: To set the channel/modem/band
This command will be used when channel/modem/band is changed.

Command Mode

*/
struct	setphy_parm {
	u8 rfchannel;
	u8 modem;
};

/*
Caller Mode: Any

Notes: To get the current setting of channel/modem/band

Command-Rsp Mode

*/
struct	getphy_parm {
	u32 rsvd;

};
struct	getphy_rsp {
	u8 rfchannel;
	u8 modem;
};

struct readBB_parm {
	u8 offset;
};
struct readBB_rsp {
	u8 value;
};

struct readTSSI_parm {
	u8 offset;
};
struct readTSSI_rsp {
	u8 value;
};

struct writeBB_parm {
	u8 offset;
	u8 value;
};

struct readRF_parm {
	u8 offset;
};
struct readRF_rsp {
	u32 value;
};

struct writeRF_parm {
	u32 offset;
	u32 value;
};

struct getrfintfs_parm {
	u8 rfintfs;
};


struct Tx_Beacon_param
{
	struct wlan_bssid_ex network;
};

/*
	Notes: This command is used for H2C/C2H loopback testing

	mac[0] == 0
	==> CMD mode, return H2C_SUCCESS.
	The following condition must be true under CMD mode
		mac[1] == mac[4], mac[2] == mac[3], mac[0]=mac[5]= 0;
		s0 == 0x1234, s1 == 0xabcd, w0 == 0x78563412, w1 == 0x5aa5def7;
		s2 == (b1 << 8 | b0);

	mac[0] == 1
	==> CMD_RSP mode, return H2C_SUCCESS_RSP

	The rsp layout shall be:
	rsp:			parm:
		mac[0]  =   mac[5];
		mac[1]  =   mac[4];
		mac[2]  =   mac[3];
		mac[3]  =   mac[2];
		mac[4]  =   mac[1];
		mac[5]  =   mac[0];
		s0		=   s1;
		s1		=   swap16(s0);
		w0		=	swap32(w1);
		b0		=	b1
		s2		=	s0 + s1
		b1		=	b0
		w1		=	w0

	mac[0] ==	2
	==> CMD_EVENT mode, return	H2C_SUCCESS
	The event layout shall be:
	event:			parm:
		mac[0]  =   mac[5];
		mac[1]  =   mac[4];
		mac[2]  =   event's sequence number, starting from 1 to parm's marc[3]
		mac[3]  =   mac[2];
		mac[4]  =   mac[1];
		mac[5]  =   mac[0];
		s0		=   swap16(s0) - event.mac[2];
		s1		=   s1 + event.mac[2];
		w0		=	swap32(w0);
		b0		=	b1
		s2		=	s0 + event.mac[2]
		b1		=	b0
		w1		=	swap32(w1) - event.mac[2];

		parm->mac[3] is the total event counts that host requested.


	event will be the same with the cmd's param.

*/

/*  CMD param Formart for driver extra cmd handler */
struct drvextra_cmd_parm {
	int ec_id; /* extra cmd id */
	int type; /*  Can use this field as the type id or command size */
	int size; /* buffer size */
	unsigned char *pbuf;
};

/*------------------- Below are used for RF/BB tunning ---------------------*/

struct	setantenna_parm {
	u8 tx_antset;
	u8 rx_antset;
	u8 tx_antenna;
	u8 rx_antenna;
};

struct	enrateadaptive_parm {
	u32 en;
};

struct settxagctbl_parm {
	u32 txagc[MAX_RATES_LENGTH];
};

struct gettxagctbl_parm {
	u32 rsvd;
};
struct gettxagctbl_rsp {
	u32 txagc[MAX_RATES_LENGTH];
};

struct setagcctrl_parm {
	u32 agcctrl;		/*  0: pure hw, 1: fw */
};


struct setssup_parm	{
	u32 ss_ForceUp[MAX_RATES_LENGTH];
};

struct getssup_parm	{
	u32 rsvd;
};
struct getssup_rsp	{
	u8 ss_ForceUp[MAX_RATES_LENGTH];
};


struct setssdlevel_parm	{
	u8 ss_DLevel[MAX_RATES_LENGTH];
};

struct getssdlevel_parm	{
	u32 rsvd;
};
struct getssdlevel_rsp	{
	u8 ss_DLevel[MAX_RATES_LENGTH];
};

struct setssulevel_parm	{
	u8 ss_ULevel[MAX_RATES_LENGTH];
};

struct getssulevel_parm	{
	u32 rsvd;
};
struct getssulevel_rsp	{
	u8 ss_ULevel[MAX_RATES_LENGTH];
};


struct	setcountjudge_parm {
	u8 count_judge[MAX_RATES_LENGTH];
};

struct	getcountjudge_parm {
	u32 rsvd;
};
struct	getcountjudge_rsp {
	u8 count_judge[MAX_RATES_LENGTH];
};


struct setratable_parm {
	u8 ss_ForceUp[NumRates];
	u8 ss_ULevel[NumRates];
	u8 ss_DLevel[NumRates];
	u8 count_judge[NumRates];
};

struct getratable_parm {
                uint rsvd;
};
struct getratable_rsp {
        u8 ss_ForceUp[NumRates];
        u8 ss_ULevel[NumRates];
        u8 ss_DLevel[NumRates];
        u8 count_judge[NumRates];
};


/* to get TX, RX retry count */
struct gettxretrycnt_parm {
	unsigned int rsvd;
};
struct gettxretrycnt_rsp {
	unsigned long tx_retrycnt;
};

struct getrxretrycnt_parm {
	unsigned int rsvd;
};
struct getrxretrycnt_rsp {
	unsigned long rx_retrycnt;
};

/* to get BCNOK, BCNERR count */
struct getbcnokcnt_parm {
	unsigned int rsvd;
};
struct getbcnokcnt_rsp {
	unsigned long  bcnokcnt;
};

struct getbcnerrcnt_parm {
	unsigned int rsvd;
};
struct getbcnerrcnt_rsp {
	unsigned long bcnerrcnt;
};

/*  to get current TX power level */
struct getcurtxpwrlevel_parm {
	unsigned int rsvd;
};
struct getcurtxpwrlevel_rsp {
	unsigned short tx_power;
};

struct setprobereqextraie_parm {
	unsigned char e_id;
	unsigned char ie_len;
	unsigned char ie[0];
};

struct setassocreqextraie_parm {
	unsigned char e_id;
	unsigned char ie_len;
	unsigned char ie[0];
};

struct setproberspextraie_parm {
	unsigned char e_id;
	unsigned char ie_len;
	unsigned char ie[0];
};

struct setassocrspextraie_parm {
	unsigned char e_id;
	unsigned char ie_len;
	unsigned char ie[0];
};


struct addBaReq_parm
{
	unsigned int tid;
	u8 addr[ETH_ALEN];
};

/*H2C Handler index: 46 */
struct set_ch_parm {
	u8 ch;
	u8 bw;
	u8 ch_offset;
};

/*H2C Handler index: 59 */
struct SetChannelPlan_param
{
	u8 channel_plan;
};

/*H2C Handler index: 60 */
struct LedBlink_param
{
	void *pLed;
};

/*H2C Handler index: 61 */
struct SetChannelSwitch_param
{
	u8 new_ch_no;
};

/*H2C Handler index: 62 */
struct TDLSoption_param
{
	u8 addr[ETH_ALEN];
	u8 option;
};

/*H2C Handler index: 64 */
struct RunInThread_param
{
	void (*func)(void*);
	void *context;
};


#define GEN_CMD_CODE(cmd)	cmd ## _CMD_


/*

Result:
0x00: success
0x01: sucess, and check Response.
0x02: cmd ignored due to duplicated sequcne number
0x03: cmd dropped due to invalid cmd code
0x04: reserved.

*/

#define H2C_RSP_OFFSET			512

#define H2C_SUCCESS			0x00
#define H2C_SUCCESS_RSP			0x01
#define H2C_DUPLICATED			0x02
#define H2C_DROPPED			0x03
#define H2C_PARAMETERS_ERROR		0x04
#define H2C_REJECTED			0x05
#define H2C_CMD_OVERFLOW		0x06
#define H2C_RESERVED			0x07

u8 rtw_sitesurvey_cmd(struct adapter  *padapter, struct ndis_802_11_ssid *ssid, int ssid_num, struct rtw_ieee80211_channel *ch, int ch_num);
extern u8 rtw_createbss_cmd(struct adapter  *padapter);
int rtw_startbss_cmd(struct adapter  *padapter, int flags);

struct sta_info;
extern u8 rtw_setstakey_cmd(struct adapter  *padapter, struct sta_info *sta, u8 unicast_key, bool enqueue);
extern u8 rtw_clearstakey_cmd(struct adapter *padapter, struct sta_info *sta, u8 enqueue);

extern u8 rtw_joinbss_cmd(struct adapter  *padapter, struct wlan_network* pnetwork);
u8 rtw_disassoc_cmd(struct adapter *padapter, u32 deauth_timeout_ms, bool enqueue);
extern u8 rtw_setopmode_cmd(struct adapter  *padapter, enum NDIS_802_11_NETWORK_INFRASTRUCTURE networktype, bool enqueue);
extern u8 rtw_setdatarate_cmd(struct adapter  *padapter, u8 *rateset);
extern u8 rtw_setrfintfs_cmd(struct adapter  *padapter, u8 mode);

extern u8 rtw_gettssi_cmd(struct adapter  *padapter, u8 offset, u8 *pval);
extern u8 rtw_setfwdig_cmd(struct adapter *padapter, u8 type);
extern u8 rtw_setfwra_cmd(struct adapter *padapter, u8 type);

extern u8 rtw_addbareq_cmd(struct adapter *padapter, u8 tid, u8 *addr);
/*  add for CONFIG_IEEE80211W, none 11w also can use */
extern u8 rtw_reset_securitypriv_cmd(struct adapter *padapter);
extern u8 rtw_free_assoc_resources_cmd(struct adapter *padapter);
extern u8 rtw_dynamic_chk_wk_cmd(struct adapter *adapter);

u8 rtw_lps_ctrl_wk_cmd(struct adapter *padapter, u8 lps_ctrl_type, u8 enqueue);
u8 rtw_dm_in_lps_wk_cmd(struct adapter *padapter);

u8 rtw_dm_ra_mask_wk_cmd(struct adapter *padapter, u8 *psta);

extern u8 rtw_ps_cmd(struct adapter *padapter);

u8 rtw_chk_hi_queue_cmd(struct adapter *padapter);

extern u8 rtw_set_chplan_cmd(struct adapter *padapter, u8 chplan, u8 enqueue, u8 swconfig);

extern u8 rtw_c2h_packet_wk_cmd(struct adapter *padapter, u8 *pbuf, u16 length);
extern u8 rtw_c2h_wk_cmd(struct adapter *padapter, u8 *c2h_evt);

u8 rtw_drvextra_cmd_hdl(struct adapter *padapter, unsigned char *pbuf);

extern void rtw_survey_cmd_callback(struct adapter  *padapter, struct cmd_obj *pcmd);
extern void rtw_disassoc_cmd_callback(struct adapter  *padapter, struct cmd_obj *pcmd);
extern void rtw_joinbss_cmd_callback(struct adapter  *padapter, struct cmd_obj *pcmd);
extern void rtw_createbss_cmd_callback(struct adapter  *padapter, struct cmd_obj *pcmd);
extern void rtw_getbbrfreg_cmdrsp_callback(struct adapter  *padapter, struct cmd_obj *pcmd);

extern void rtw_setstaKey_cmdrsp_callback(struct adapter  *padapter,  struct cmd_obj *pcmd);
extern void rtw_setassocsta_cmdrsp_callback(struct adapter  *padapter,  struct cmd_obj *pcmd);
extern void rtw_getrttbl_cmdrsp_callback(struct adapter  *padapter,  struct cmd_obj *pcmd);


struct _cmd_callback {
	u32 cmd_code;
	void (*callback)(struct adapter  *padapter, struct cmd_obj *cmd);
};

enum rtw_h2c_cmd
{
	GEN_CMD_CODE(_Read_MACREG),	/*0*/
	GEN_CMD_CODE(_Write_MACREG),
	GEN_CMD_CODE(_Read_BBREG),
	GEN_CMD_CODE(_Write_BBREG),
	GEN_CMD_CODE(_Read_RFREG),
	GEN_CMD_CODE(_Write_RFREG), /*5*/
	GEN_CMD_CODE(_Read_EEPROM),
	GEN_CMD_CODE(_Write_EEPROM),
	GEN_CMD_CODE(_Read_EFUSE),
	GEN_CMD_CODE(_Write_EFUSE),

	GEN_CMD_CODE(_Read_CAM),	/*10*/
	GEN_CMD_CODE(_Write_CAM),
	GEN_CMD_CODE(_setBCNITV),
	GEN_CMD_CODE(_setMBIDCFG),
	GEN_CMD_CODE(_JoinBss),   /*14*/
	GEN_CMD_CODE(_DisConnect), /*15*/
	GEN_CMD_CODE(_CreateBss),
	GEN_CMD_CODE(_SetOpMode),
	GEN_CMD_CODE(_SiteSurvey),  /*18*/
	GEN_CMD_CODE(_SetAuth),

	GEN_CMD_CODE(_SetKey),	/*20*/
	GEN_CMD_CODE(_SetStaKey),
	GEN_CMD_CODE(_SetAssocSta),
	GEN_CMD_CODE(_DelAssocSta),
	GEN_CMD_CODE(_SetStaPwrState),
	GEN_CMD_CODE(_SetBasicRate), /*25*/
	GEN_CMD_CODE(_GetBasicRate),
	GEN_CMD_CODE(_SetDataRate),
	GEN_CMD_CODE(_GetDataRate),
	GEN_CMD_CODE(_SetPhyInfo),

	GEN_CMD_CODE(_GetPhyInfo),	/*30*/
	GEN_CMD_CODE(_SetPhy),
	GEN_CMD_CODE(_GetPhy),
	GEN_CMD_CODE(_readRssi),
	GEN_CMD_CODE(_readGain),
	GEN_CMD_CODE(_SetAtim), /*35*/
	GEN_CMD_CODE(_SetPwrMode),
	GEN_CMD_CODE(_JoinbssRpt),
	GEN_CMD_CODE(_SetRaTable),
	GEN_CMD_CODE(_GetRaTable),

	GEN_CMD_CODE(_GetCCXReport), /*40*/
	GEN_CMD_CODE(_GetDTMReport),
	GEN_CMD_CODE(_GetTXRateStatistics),
	GEN_CMD_CODE(_SetUsbSuspend),
	GEN_CMD_CODE(_SetH2cLbk),
	GEN_CMD_CODE(_AddBAReq), /*45*/
	GEN_CMD_CODE(_SetChannel), /*46*/
	GEN_CMD_CODE(_SetTxPower),
	GEN_CMD_CODE(_SwitchAntenna),
	GEN_CMD_CODE(_SetCrystalCap),
	GEN_CMD_CODE(_SetSingleCarrierTx), /*50*/

	GEN_CMD_CODE(_SetSingleToneTx),/*51*/
	GEN_CMD_CODE(_SetCarrierSuppressionTx),
	GEN_CMD_CODE(_SetContinuousTx),
	GEN_CMD_CODE(_SwitchBandwidth), /*54*/
	GEN_CMD_CODE(_TX_Beacon), /*55*/

	GEN_CMD_CODE(_Set_MLME_EVT), /*56*/
	GEN_CMD_CODE(_Set_Drv_Extra), /*57*/
	GEN_CMD_CODE(_Set_H2C_MSG), /*58*/

	GEN_CMD_CODE(_SetChannelPlan), /*59*/
	GEN_CMD_CODE(_LedBlink), /*60*/

	GEN_CMD_CODE(_SetChannelSwitch), /*61*/
	GEN_CMD_CODE(_TDLS), /*62*/
	GEN_CMD_CODE(_ChkBMCSleepq), /*63*/

	GEN_CMD_CODE(_RunInThreadCMD), /*64*/

	MAX_H2CCMD
};

#define _GetBBReg_CMD_		_Read_BBREG_CMD_
#define _SetBBReg_CMD_		_Write_BBREG_CMD_
#define _GetRFReg_CMD_		_Read_RFREG_CMD_
#define _SetRFReg_CMD_		_Write_RFREG_CMD_

#endif /*  _CMD_H_ */