rtmp_init.c - drivers/staging/rt3070/common/rtmp_init.c - Linux source code (v2.6.30.6)

/*
 *************************************************************************
 * Ralink Tech Inc.
 * 5F., No.36, Taiyuan St., Jhubei City,
 * Hsinchu County 302,
 * Taiwan, R.O.C.
 *
 * (c) Copyright 2002-2007, Ralink Technology, Inc.
 *
 * This program is free software; you can redistribute it and/or modify  *
 * it under the terms of the GNU General Public License as published by  *
 * the Free Software Foundation; either version 2 of the License, or     *
 * (at your option) any later version.                                   *
 *                                                                       *
 * This program is distributed in the hope that it will be useful,       *
 * but WITHOUT ANY WARRANTY; without even the implied warranty of        *
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the         *
 * GNU General Public License for more details.                          *
 *                                                                       *
 * You should have received a copy of the GNU General Public License     *
 * along with this program; if not, write to the                         *
 * Free Software Foundation, Inc.,                                       *
 * 59 Temple Place - Suite 330, Boston, MA  02111-1307, USA.             *
 *                                                                       *
 *************************************************************************

	Module Name:
	rtmp_init.c

	Abstract:
	Miniport generic portion header file

	Revision History:
	Who         When          What
	--------    ----------    ----------------------------------------------
	Paul Lin    2002-08-01    created
    John Chang  2004-08-20    RT2561/2661 use scatter-gather scheme
    Jan Lee  2006-09-15    RT2860. Change for 802.11n , EEPROM, Led, BA, HT.
*/
#include	"../rt_config.h"
#include 	"../firmware.h"

//#define BIN_IN_FILE /* use *.bin firmware */

UCHAR    BIT8[] = {0x01, 0x02, 0x04, 0x08, 0x10, 0x20, 0x40, 0x80};
ULONG    BIT32[] = {0x00000001, 0x00000002, 0x00000004, 0x00000008,
					0x00000010, 0x00000020, 0x00000040, 0x00000080,
					0x00000100, 0x00000200, 0x00000400, 0x00000800,
					0x00001000, 0x00002000, 0x00004000, 0x00008000,
					0x00010000, 0x00020000, 0x00040000, 0x00080000,
					0x00100000, 0x00200000, 0x00400000, 0x00800000,
					0x01000000, 0x02000000, 0x04000000, 0x08000000,
					0x10000000, 0x20000000, 0x40000000, 0x80000000};

char*   CipherName[] = {"none","wep64","wep128","TKIP","AES","CKIP64","CKIP128"};

const unsigned short ccitt_16Table[] = {
	0x0000, 0x1021, 0x2042, 0x3063, 0x4084, 0x50A5, 0x60C6, 0x70E7,
	0x8108, 0x9129, 0xA14A, 0xB16B, 0xC18C, 0xD1AD, 0xE1CE, 0xF1EF,
	0x1231, 0x0210, 0x3273, 0x2252, 0x52B5, 0x4294, 0x72F7, 0x62D6,
	0x9339, 0x8318, 0xB37B, 0xA35A, 0xD3BD, 0xC39C, 0xF3FF, 0xE3DE,
	0x2462, 0x3443, 0x0420, 0x1401, 0x64E6, 0x74C7, 0x44A4, 0x5485,
	0xA56A, 0xB54B, 0x8528, 0x9509, 0xE5EE, 0xF5CF, 0xC5AC, 0xD58D,
	0x3653, 0x2672, 0x1611, 0x0630, 0x76D7, 0x66F6, 0x5695, 0x46B4,
	0xB75B, 0xA77A, 0x9719, 0x8738, 0xF7DF, 0xE7FE, 0xD79D, 0xC7BC,
	0x48C4, 0x58E5, 0x6886, 0x78A7, 0x0840, 0x1861, 0x2802, 0x3823,
	0xC9CC, 0xD9ED, 0xE98E, 0xF9AF, 0x8948, 0x9969, 0xA90A, 0xB92B,
	0x5AF5, 0x4AD4, 0x7AB7, 0x6A96, 0x1A71, 0x0A50, 0x3A33, 0x2A12,
	0xDBFD, 0xCBDC, 0xFBBF, 0xEB9E, 0x9B79, 0x8B58, 0xBB3B, 0xAB1A,
	0x6CA6, 0x7C87, 0x4CE4, 0x5CC5, 0x2C22, 0x3C03, 0x0C60, 0x1C41,
	0xEDAE, 0xFD8F, 0xCDEC, 0xDDCD, 0xAD2A, 0xBD0B, 0x8D68, 0x9D49,
	0x7E97, 0x6EB6, 0x5ED5, 0x4EF4, 0x3E13, 0x2E32, 0x1E51, 0x0E70,
	0xFF9F, 0xEFBE, 0xDFDD, 0xCFFC, 0xBF1B, 0xAF3A, 0x9F59, 0x8F78,
	0x9188, 0x81A9, 0xB1CA, 0xA1EB, 0xD10C, 0xC12D, 0xF14E, 0xE16F,
	0x1080, 0x00A1, 0x30C2, 0x20E3, 0x5004, 0x4025, 0x7046, 0x6067,
	0x83B9, 0x9398, 0xA3FB, 0xB3DA, 0xC33D, 0xD31C, 0xE37F, 0xF35E,
	0x02B1, 0x1290, 0x22F3, 0x32D2, 0x4235, 0x5214, 0x6277, 0x7256,
	0xB5EA, 0xA5CB, 0x95A8, 0x8589, 0xF56E, 0xE54F, 0xD52C, 0xC50D,
	0x34E2, 0x24C3, 0x14A0, 0x0481, 0x7466, 0x6447, 0x5424, 0x4405,
	0xA7DB, 0xB7FA, 0x8799, 0x97B8, 0xE75F, 0xF77E, 0xC71D, 0xD73C,
	0x26D3, 0x36F2, 0x0691, 0x16B0, 0x6657, 0x7676, 0x4615, 0x5634,
	0xD94C, 0xC96D, 0xF90E, 0xE92F, 0x99C8, 0x89E9, 0xB98A, 0xA9AB,
	0x5844, 0x4865, 0x7806, 0x6827, 0x18C0, 0x08E1, 0x3882, 0x28A3,
	0xCB7D, 0xDB5C, 0xEB3F, 0xFB1E, 0x8BF9, 0x9BD8, 0xABBB, 0xBB9A,
	0x4A75, 0x5A54, 0x6A37, 0x7A16, 0x0AF1, 0x1AD0, 0x2AB3, 0x3A92,
	0xFD2E, 0xED0F, 0xDD6C, 0xCD4D, 0xBDAA, 0xAD8B, 0x9DE8, 0x8DC9,
	0x7C26, 0x6C07, 0x5C64, 0x4C45, 0x3CA2, 0x2C83, 0x1CE0, 0x0CC1,
	0xEF1F, 0xFF3E, 0xCF5D, 0xDF7C, 0xAF9B, 0xBFBA, 0x8FD9, 0x9FF8,
	0x6E17, 0x7E36, 0x4E55, 0x5E74, 0x2E93, 0x3EB2, 0x0ED1, 0x1EF0
};
#define ByteCRC16(v, crc) \
	(unsigned short)((crc << 8) ^  ccitt_16Table[((crc >> 8) ^ (v)) & 255])

unsigned char BitReverse(unsigned char x)
{
	int i;
	unsigned char Temp=0;
	for(i=0; ; i++)
	{
		if(x & 0x80)	Temp |= 0x80;
		if(i==7)		break;
		x	<<= 1;
		Temp >>= 1;
	}
	return Temp;
}

//
// BBP register initialization set
//
REG_PAIR   BBPRegTable[] = {
	{BBP_R65,		0x2C},		// fix rssi issue
	{BBP_R66,		0x38},	// Also set this default value to pAd->BbpTuning.R66CurrentValue at initial
	{BBP_R69,		0x12},
	{BBP_R70,		0xa},	// BBP_R70 will change to 0x8 in ApStartUp and LinkUp for rt2860C, otherwise value is 0xa
	{BBP_R73,		0x10},
	{BBP_R81,		0x37},
	{BBP_R82,		0x62},
	{BBP_R83,		0x6A},
	{BBP_R84,		0x99},	// 0x19 is for rt2860E and after. This is for extension channel overlapping IOT. 0x99 is for rt2860D and before
	{BBP_R86,		0x00},	// middle range issue, Rory @2008-01-28
	{BBP_R91,		0x04},	// middle range issue, Rory @2008-01-28
	{BBP_R92,		0x00},	// middle range issue, Rory @2008-01-28
	{BBP_R103,  	0x00}, 	// near range high-power issue, requested from Gary @2008-0528
	{BBP_R105,		0x05},	// 0x05 is for rt2860E to turn on FEQ control. It is safe for rt2860D and before, because Bit 7:2 are reserved in rt2860D and before.
};
#define	NUM_BBP_REG_PARMS	(sizeof(BBPRegTable) / sizeof(REG_PAIR))

//
// RF register initialization set
//
#ifdef RT30xx
REG_PAIR   RT30xx_RFRegTable[] = {
        {RF_R04,          0x40},
        {RF_R05,          0x03},
        {RF_R06,          0x02},
        {RF_R07,          0x70},
        {RF_R09,          0x0F},
        {RF_R10,          0x41},
        {RF_R11,          0x21},
        {RF_R12,          0x7B},
        {RF_R14,          0x90},
        {RF_R15,          0x58},
        {RF_R16,          0xB3},
        {RF_R17,          0x92},
        {RF_R18,          0x2C},
        {RF_R19,          0x02},
        {RF_R20,          0xBA},
        {RF_R21,          0xDB},
        {RF_R24,          0x16},
        {RF_R25,          0x01},
        {RF_R29,          0x1F},
};
#define	NUM_RF_REG_PARMS	(sizeof(RT30xx_RFRegTable) / sizeof(REG_PAIR))
#endif // RT30xx //

//
// ASIC register initialization sets
//

RTMP_REG_PAIR	MACRegTable[] =	{
#if defined(HW_BEACON_OFFSET) && (HW_BEACON_OFFSET == 0x200)
	{BCN_OFFSET0,			0xf8f0e8e0}, /* 0x3800(e0), 0x3A00(e8), 0x3C00(f0), 0x3E00(f8), 512B for each beacon */
	{BCN_OFFSET1,			0x6f77d0c8}, /* 0x3200(c8), 0x3400(d0), 0x1DC0(77), 0x1BC0(6f), 512B for each beacon */
#elif defined(HW_BEACON_OFFSET) && (HW_BEACON_OFFSET == 0x100)
	{BCN_OFFSET0,			0xece8e4e0}, /* 0x3800, 0x3A00, 0x3C00, 0x3E00, 512B for each beacon */
	{BCN_OFFSET1,			0xfcf8f4f0}, /* 0x3800, 0x3A00, 0x3C00, 0x3E00, 512B for each beacon */
#else
    #error You must re-calculate new value for BCN_OFFSET0 & BCN_OFFSET1 in MACRegTable[]!!!
#endif // HW_BEACON_OFFSET //

	{LEGACY_BASIC_RATE,		0x0000013f}, //  Basic rate set bitmap
	{HT_BASIC_RATE,		0x00008003}, // Basic HT rate set , 20M, MCS=3, MM. Format is the same as in TXWI.
	{MAC_SYS_CTRL,		0x00}, // 0x1004, , default Disable RX
	{RX_FILTR_CFG,		0x17f97}, //0x1400  , RX filter control,
	{BKOFF_SLOT_CFG,	0x209}, // default set short slot time, CC_DELAY_TIME should be 2
	//{TX_SW_CFG0,		0x40a06}, // Gary,2006-08-23
	{TX_SW_CFG0,		0x0}, 		// Gary,2008-05-21 for CWC test
	{TX_SW_CFG1,		0x80606}, // Gary,2006-08-23
	{TX_LINK_CFG,		0x1020},		// Gary,2006-08-23
	{TX_TIMEOUT_CFG,	0x000a2090},
	{MAX_LEN_CFG,		MAX_AGGREGATION_SIZE | 0x00001000},	// 0x3018, MAX frame length. Max PSDU = 16kbytes.
	{LED_CFG,		0x7f031e46}, // Gary, 2006-08-23

//#ifdef CONFIG_STA_SUPPORT
//	{WMM_AIFSN_CFG,		0x00002273},
//	{WMM_CWMIN_CFG,		0x00002344},
//	{WMM_CWMAX_CFG,		0x000034aa},
//#endif // CONFIG_STA_SUPPORT //
#ifdef INF_AMAZON_SE
	{PBF_MAX_PCNT,			0x1F3F6F6F}, 	//iverson modify for usb issue, 2008/09/19
											// 6F + 6F < total page count FE
											// so that RX doesn't occupy TX's buffer space when WMM congestion.
#else
	{PBF_MAX_PCNT,			0x1F3FBF9F}, 	//0x1F3f7f9f},		//Jan, 2006/04/20
#endif // INF_AMAZON_SE //
	//{TX_RTY_CFG,			0x6bb80408},	// Jan, 2006/11/16
	{TX_RTY_CFG,			0x47d01f0f},	// Jan, 2006/11/16, Set TxWI->ACK =0 in Probe Rsp Modify for 2860E ,2007-08-03
	{AUTO_RSP_CFG,			0x00000013},	// Initial Auto_Responder, because QA will turn off Auto-Responder
	{CCK_PROT_CFG,			0x05740003 /*0x01740003*/},	// Initial Auto_Responder, because QA will turn off Auto-Responder. And RTS threshold is enabled.
	{OFDM_PROT_CFG,			0x05740003 /*0x01740003*/},	// Initial Auto_Responder, because QA will turn off Auto-Responder. And RTS threshold is enabled.
//PS packets use Tx1Q (for HCCA) when dequeue from PS unicast queue (WiFi WPA2 MA9_DT1 for Marvell B STA)
#ifdef RT2870
#ifdef CONFIG_STA_SUPPORT
	{PBF_CFG, 				0xf40006}, 		// Only enable Queue 2
#endif // CONFIG_STA_SUPPORT //
	{MM40_PROT_CFG,			0x3F44084},		// Initial Auto_Responder, because QA will turn off Auto-Responder
	{WPDMA_GLO_CFG,			0x00000030},
#endif // RT2870 //
	{GF20_PROT_CFG,			0x01744004},    // set 19:18 --> Short NAV for MIMO PS
	{GF40_PROT_CFG,			0x03F44084},
	{MM20_PROT_CFG,			0x01744004},
	{TXOP_CTRL_CFG,			0x0000583f, /*0x0000243f*/ /*0x000024bf*/},	//Extension channel backoff.
	{TX_RTS_CFG,			0x00092b20},
//#ifdef WIFI_TEST
	{EXP_ACK_TIME,			0x002400ca},	// default value
//#else
//	{EXP_ACK_TIME,			0x005400ca},	// suggested by Gray @ 20070323 for 11n intel-sta throughput
//#endif // end - WIFI_TEST //
	{TXOP_HLDR_ET, 			0x00000002},

	/* Jerry comments 2008/01/16: we use SIFS = 10us in CCK defaultly, but it seems that 10us
		is too small for INTEL 2200bg card, so in MBSS mode, the delta time between beacon0
		and beacon1 is SIFS (10us), so if INTEL 2200bg card connects to BSS0, the ping
		will always lost. So we change the SIFS of CCK from 10us to 16us. */
	{XIFS_TIME_CFG,			0x33a41010},
	{PWR_PIN_CFG,			0x00000003},	// patch for 2880-E
};


#ifdef CONFIG_STA_SUPPORT
RTMP_REG_PAIR	STAMACRegTable[] =	{
	{WMM_AIFSN_CFG,		0x00002273},
	{WMM_CWMIN_CFG,	0x00002344},
	{WMM_CWMAX_CFG,	0x000034aa},
};
#endif // CONFIG_STA_SUPPORT //

#define	NUM_MAC_REG_PARMS		(sizeof(MACRegTable) / sizeof(RTMP_REG_PAIR))
#ifdef CONFIG_STA_SUPPORT
#define	NUM_STA_MAC_REG_PARMS	(sizeof(STAMACRegTable) / sizeof(RTMP_REG_PAIR))
#endif // CONFIG_STA_SUPPORT //

#ifdef RT2870
//
// RT2870 Firmware Spec only used 1 oct for version expression
//
#define FIRMWARE_MINOR_VERSION	7

#endif // RT2870 //

// New 8k byte firmware size for RT3071/RT3072
#define FIRMWAREIMAGE_MAX_LENGTH	0x2000
#define FIRMWAREIMAGE_LENGTH		(sizeof (FirmwareImage) / sizeof(UCHAR))
#define FIRMWARE_MAJOR_VERSION	0

#define FIRMWAREIMAGEV1_LENGTH	0x1000
#define FIRMWAREIMAGEV2_LENGTH	0x1000



/*
	========================================================================

	Routine Description:
		Allocate RTMP_ADAPTER data block and do some initialization

	Arguments:
		Adapter		Pointer to our adapter

	Return Value:
		NDIS_STATUS_SUCCESS
		NDIS_STATUS_FAILURE

	IRQL = PASSIVE_LEVEL

	Note:

	========================================================================
*/
NDIS_STATUS	RTMPAllocAdapterBlock(
	IN  PVOID	handle,
	OUT	PRTMP_ADAPTER	*ppAdapter)
{
	PRTMP_ADAPTER	pAd;
	NDIS_STATUS		Status;
	INT 			index;
	UCHAR			*pBeaconBuf = NULL;

	DBGPRINT(RT_DEBUG_TRACE, ("--> RTMPAllocAdapterBlock\n"));

	*ppAdapter = NULL;

	do
	{
		// Allocate RTMP_ADAPTER memory block
		pBeaconBuf = kmalloc(MAX_BEACON_SIZE, MEM_ALLOC_FLAG);
		if (pBeaconBuf == NULL)
		{
			Status = NDIS_STATUS_FAILURE;
			DBGPRINT_ERR(("Failed to allocate memory - BeaconBuf!\n"));
			break;
		}

		Status = AdapterBlockAllocateMemory(handle, (PVOID *)&pAd);
		if (Status != NDIS_STATUS_SUCCESS)
		{
			DBGPRINT_ERR(("Failed to allocate memory - ADAPTER\n"));
			break;
		}
		pAd->BeaconBuf = pBeaconBuf;
		printk("\n\n=== pAd = %p, size = %d ===\n\n", pAd, (UINT32)sizeof(RTMP_ADAPTER));


		// Init spin locks
		NdisAllocateSpinLock(&pAd->MgmtRingLock);

		for (index =0 ; index < NUM_OF_TX_RING; index++)
		{
			NdisAllocateSpinLock(&pAd->TxSwQueueLock[index]);
			NdisAllocateSpinLock(&pAd->DeQueueLock[index]);
			pAd->DeQueueRunning[index] = FALSE;
		}

		NdisAllocateSpinLock(&pAd->irq_lock);

	} while (FALSE);

	if ((Status != NDIS_STATUS_SUCCESS) && (pBeaconBuf))
		kfree(pBeaconBuf);

	*ppAdapter = pAd;

	DBGPRINT_S(Status, ("<-- RTMPAllocAdapterBlock, Status=%x\n", Status));
	return Status;
}

/*
	========================================================================

	Routine Description:
		Read initial Tx power per MCS and BW from EEPROM

	Arguments:
		Adapter						Pointer to our adapter

	Return Value:
		None

	IRQL = PASSIVE_LEVEL

	Note:

	========================================================================
*/
VOID	RTMPReadTxPwrPerRate(
	IN	PRTMP_ADAPTER	pAd)
{
	ULONG		data, Adata, Gdata;
	USHORT		i, value, value2;
	INT			Apwrdelta, Gpwrdelta;
	UCHAR		t1,t2,t3,t4;
	BOOLEAN		bValid, bApwrdeltaMinus = TRUE, bGpwrdeltaMinus = TRUE;

	//
	// Get power delta for 20MHz and 40MHz.
	//
	DBGPRINT(RT_DEBUG_TRACE, ("Txpower per Rate\n"));
	RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_DELTA, value2);
	Apwrdelta = 0;
	Gpwrdelta = 0;

	if ((value2 & 0xff) != 0xff)
	{
		if ((value2 & 0x80))
			Gpwrdelta = (value2&0xf);

		if ((value2 & 0x40))
			bGpwrdeltaMinus = FALSE;
		else
			bGpwrdeltaMinus = TRUE;
	}
	if ((value2 & 0xff00) != 0xff00)
	{
		if ((value2 & 0x8000))
			Apwrdelta = ((value2&0xf00)>>8);

		if ((value2 & 0x4000))
			bApwrdeltaMinus = FALSE;
		else
			bApwrdeltaMinus = TRUE;
	}
	DBGPRINT(RT_DEBUG_TRACE, ("Gpwrdelta = %x, Apwrdelta = %x .\n", Gpwrdelta, Apwrdelta));

	//
	// Get Txpower per MCS for 20MHz in 2.4G.
	//
	for (i=0; i<5; i++)
	{
		RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_20MHZ_2_4G + i*4, value);
		data = value;
		if (bApwrdeltaMinus == FALSE)
		{
			t1 = (value&0xf)+(Apwrdelta);
			if (t1 > 0xf)
				t1 = 0xf;
			t2 = ((value&0xf0)>>4)+(Apwrdelta);
			if (t2 > 0xf)
				t2 = 0xf;
			t3 = ((value&0xf00)>>8)+(Apwrdelta);
			if (t3 > 0xf)
				t3 = 0xf;
			t4 = ((value&0xf000)>>12)+(Apwrdelta);
			if (t4 > 0xf)
				t4 = 0xf;
		}
		else
		{
			if ((value&0xf) > Apwrdelta)
				t1 = (value&0xf)-(Apwrdelta);
			else
				t1 = 0;
			if (((value&0xf0)>>4) > Apwrdelta)
				t2 = ((value&0xf0)>>4)-(Apwrdelta);
			else
				t2 = 0;
			if (((value&0xf00)>>8) > Apwrdelta)
				t3 = ((value&0xf00)>>8)-(Apwrdelta);
			else
				t3 = 0;
			if (((value&0xf000)>>12) > Apwrdelta)
				t4 = ((value&0xf000)>>12)-(Apwrdelta);
			else
				t4 = 0;
		}
		Adata = t1 + (t2<<4) + (t3<<8) + (t4<<12);
		if (bGpwrdeltaMinus == FALSE)
		{
			t1 = (value&0xf)+(Gpwrdelta);
			if (t1 > 0xf)
				t1 = 0xf;
			t2 = ((value&0xf0)>>4)+(Gpwrdelta);
			if (t2 > 0xf)
				t2 = 0xf;
			t3 = ((value&0xf00)>>8)+(Gpwrdelta);
			if (t3 > 0xf)
				t3 = 0xf;
			t4 = ((value&0xf000)>>12)+(Gpwrdelta);
			if (t4 > 0xf)
				t4 = 0xf;
		}
		else
		{
			if ((value&0xf) > Gpwrdelta)
				t1 = (value&0xf)-(Gpwrdelta);
			else
				t1 = 0;
			if (((value&0xf0)>>4) > Gpwrdelta)
				t2 = ((value&0xf0)>>4)-(Gpwrdelta);
			else
				t2 = 0;
			if (((value&0xf00)>>8) > Gpwrdelta)
				t3 = ((value&0xf00)>>8)-(Gpwrdelta);
			else
				t3 = 0;
			if (((value&0xf000)>>12) > Gpwrdelta)
				t4 = ((value&0xf000)>>12)-(Gpwrdelta);
			else
				t4 = 0;
		}
		Gdata = t1 + (t2<<4) + (t3<<8) + (t4<<12);

		RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_20MHZ_2_4G + i*4 + 2, value);
		if (bApwrdeltaMinus == FALSE)
		{
			t1 = (value&0xf)+(Apwrdelta);
			if (t1 > 0xf)
				t1 = 0xf;
			t2 = ((value&0xf0)>>4)+(Apwrdelta);
			if (t2 > 0xf)
				t2 = 0xf;
			t3 = ((value&0xf00)>>8)+(Apwrdelta);
			if (t3 > 0xf)
				t3 = 0xf;
			t4 = ((value&0xf000)>>12)+(Apwrdelta);
			if (t4 > 0xf)
				t4 = 0xf;
		}
		else
		{
			if ((value&0xf) > Apwrdelta)
				t1 = (value&0xf)-(Apwrdelta);
			else
				t1 = 0;
			if (((value&0xf0)>>4) > Apwrdelta)
				t2 = ((value&0xf0)>>4)-(Apwrdelta);
			else
				t2 = 0;
			if (((value&0xf00)>>8) > Apwrdelta)
				t3 = ((value&0xf00)>>8)-(Apwrdelta);
			else
				t3 = 0;
			if (((value&0xf000)>>12) > Apwrdelta)
				t4 = ((value&0xf000)>>12)-(Apwrdelta);
			else
				t4 = 0;
		}
		Adata |= ((t1<<16) + (t2<<20) + (t3<<24) + (t4<<28));
		if (bGpwrdeltaMinus == FALSE)
		{
			t1 = (value&0xf)+(Gpwrdelta);
			if (t1 > 0xf)
				t1 = 0xf;
			t2 = ((value&0xf0)>>4)+(Gpwrdelta);
			if (t2 > 0xf)
				t2 = 0xf;
			t3 = ((value&0xf00)>>8)+(Gpwrdelta);
			if (t3 > 0xf)
				t3 = 0xf;
			t4 = ((value&0xf000)>>12)+(Gpwrdelta);
			if (t4 > 0xf)
				t4 = 0xf;
		}
		else
		{
			if ((value&0xf) > Gpwrdelta)
				t1 = (value&0xf)-(Gpwrdelta);
			else
				t1 = 0;
			if (((value&0xf0)>>4) > Gpwrdelta)
				t2 = ((value&0xf0)>>4)-(Gpwrdelta);
			else
				t2 = 0;
			if (((value&0xf00)>>8) > Gpwrdelta)
				t3 = ((value&0xf00)>>8)-(Gpwrdelta);
			else
				t3 = 0;
			if (((value&0xf000)>>12) > Gpwrdelta)
				t4 = ((value&0xf000)>>12)-(Gpwrdelta);
			else
				t4 = 0;
		}
		Gdata |= ((t1<<16) + (t2<<20) + (t3<<24) + (t4<<28));
		data |= (value<<16);

		pAd->Tx20MPwrCfgABand[i] = pAd->Tx40MPwrCfgABand[i] = Adata;
		pAd->Tx20MPwrCfgGBand[i] = pAd->Tx40MPwrCfgGBand[i] = Gdata;

		if (data != 0xffffffff)
			RTMP_IO_WRITE32(pAd, TX_PWR_CFG_0 + i*4, data);
		DBGPRINT_RAW(RT_DEBUG_TRACE, ("20MHz BW, 2.4G band-%lx,  Adata = %lx,  Gdata = %lx \n", data, Adata, Gdata));
	}

	//
	// Check this block is valid for 40MHz in 2.4G. If invalid, use parameter for 20MHz in 2.4G
	//
	bValid = TRUE;
	for (i=0; i<6; i++)
	{
		RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_40MHZ_2_4G + 2 + i*2, value);
		if (((value & 0x00FF) == 0x00FF) || ((value & 0xFF00) == 0xFF00))
		{
			bValid = FALSE;
			break;
		}
	}

	//
	// Get Txpower per MCS for 40MHz in 2.4G.
	//
	if (bValid)
	{
		for (i=0; i<4; i++)
		{
			RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_40MHZ_2_4G + i*4, value);
			if (bGpwrdeltaMinus == FALSE)
			{
				t1 = (value&0xf)+(Gpwrdelta);
				if (t1 > 0xf)
					t1 = 0xf;
				t2 = ((value&0xf0)>>4)+(Gpwrdelta);
				if (t2 > 0xf)
					t2 = 0xf;
				t3 = ((value&0xf00)>>8)+(Gpwrdelta);
				if (t3 > 0xf)
					t3 = 0xf;
				t4 = ((value&0xf000)>>12)+(Gpwrdelta);
				if (t4 > 0xf)
					t4 = 0xf;
			}
			else
			{
				if ((value&0xf) > Gpwrdelta)
					t1 = (value&0xf)-(Gpwrdelta);
				else
					t1 = 0;
				if (((value&0xf0)>>4) > Gpwrdelta)
					t2 = ((value&0xf0)>>4)-(Gpwrdelta);
				else
					t2 = 0;
				if (((value&0xf00)>>8) > Gpwrdelta)
					t3 = ((value&0xf00)>>8)-(Gpwrdelta);
				else
					t3 = 0;
				if (((value&0xf000)>>12) > Gpwrdelta)
					t4 = ((value&0xf000)>>12)-(Gpwrdelta);
				else
					t4 = 0;
			}
			Gdata = t1 + (t2<<4) + (t3<<8) + (t4<<12);

			RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_40MHZ_2_4G + i*4 + 2, value);
			if (bGpwrdeltaMinus == FALSE)
			{
				t1 = (value&0xf)+(Gpwrdelta);
				if (t1 > 0xf)
					t1 = 0xf;
				t2 = ((value&0xf0)>>4)+(Gpwrdelta);
				if (t2 > 0xf)
					t2 = 0xf;
				t3 = ((value&0xf00)>>8)+(Gpwrdelta);
				if (t3 > 0xf)
					t3 = 0xf;
				t4 = ((value&0xf000)>>12)+(Gpwrdelta);
				if (t4 > 0xf)
					t4 = 0xf;
			}
			else
			{
				if ((value&0xf) > Gpwrdelta)
					t1 = (value&0xf)-(Gpwrdelta);
				else
					t1 = 0;
				if (((value&0xf0)>>4) > Gpwrdelta)
					t2 = ((value&0xf0)>>4)-(Gpwrdelta);
				else
					t2 = 0;
				if (((value&0xf00)>>8) > Gpwrdelta)
					t3 = ((value&0xf00)>>8)-(Gpwrdelta);
				else
					t3 = 0;
				if (((value&0xf000)>>12) > Gpwrdelta)
					t4 = ((value&0xf000)>>12)-(Gpwrdelta);
				else
					t4 = 0;
			}
			Gdata |= ((t1<<16) + (t2<<20) + (t3<<24) + (t4<<28));

			if (i == 0)
				pAd->Tx40MPwrCfgGBand[i+1] = (pAd->Tx40MPwrCfgGBand[i+1] & 0x0000FFFF) | (Gdata & 0xFFFF0000);
			else
				pAd->Tx40MPwrCfgGBand[i+1] = Gdata;

			DBGPRINT_RAW(RT_DEBUG_TRACE, ("40MHz BW, 2.4G band, Gdata = %lx \n", Gdata));
		}
	}

	//
	// Check this block is valid for 20MHz in 5G. If invalid, use parameter for 20MHz in 2.4G
	//
	bValid = TRUE;
	for (i=0; i<8; i++)
	{
		RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_20MHZ_5G + 2 + i*2, value);
		if (((value & 0x00FF) == 0x00FF) || ((value & 0xFF00) == 0xFF00))
		{
			bValid = FALSE;
			break;
		}
	}

	//
	// Get Txpower per MCS for 20MHz in 5G.
	//
	if (bValid)
	{
		for (i=0; i<5; i++)
		{
			RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_20MHZ_5G + i*4, value);
			if (bApwrdeltaMinus == FALSE)
			{
				t1 = (value&0xf)+(Apwrdelta);
				if (t1 > 0xf)
					t1 = 0xf;
				t2 = ((value&0xf0)>>4)+(Apwrdelta);
				if (t2 > 0xf)
					t2 = 0xf;
				t3 = ((value&0xf00)>>8)+(Apwrdelta);
				if (t3 > 0xf)
					t3 = 0xf;
				t4 = ((value&0xf000)>>12)+(Apwrdelta);
				if (t4 > 0xf)
					t4 = 0xf;
			}
			else
			{
				if ((value&0xf) > Apwrdelta)
					t1 = (value&0xf)-(Apwrdelta);
				else
					t1 = 0;
				if (((value&0xf0)>>4) > Apwrdelta)
					t2 = ((value&0xf0)>>4)-(Apwrdelta);
				else
					t2 = 0;
				if (((value&0xf00)>>8) > Apwrdelta)
					t3 = ((value&0xf00)>>8)-(Apwrdelta);
				else
					t3 = 0;
				if (((value&0xf000)>>12) > Apwrdelta)
					t4 = ((value&0xf000)>>12)-(Apwrdelta);
				else
					t4 = 0;
			}
			Adata = t1 + (t2<<4) + (t3<<8) + (t4<<12);

			RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_20MHZ_5G + i*4 + 2, value);
			if (bApwrdeltaMinus == FALSE)
			{
				t1 = (value&0xf)+(Apwrdelta);
				if (t1 > 0xf)
					t1 = 0xf;
				t2 = ((value&0xf0)>>4)+(Apwrdelta);
				if (t2 > 0xf)
					t2 = 0xf;
				t3 = ((value&0xf00)>>8)+(Apwrdelta);
				if (t3 > 0xf)
					t3 = 0xf;
				t4 = ((value&0xf000)>>12)+(Apwrdelta);
				if (t4 > 0xf)
					t4 = 0xf;
			}
			else
			{
				if ((value&0xf) > Apwrdelta)
					t1 = (value&0xf)-(Apwrdelta);
				else
					t1 = 0;
				if (((value&0xf0)>>4) > Apwrdelta)
					t2 = ((value&0xf0)>>4)-(Apwrdelta);
				else
					t2 = 0;
				if (((value&0xf00)>>8) > Apwrdelta)
					t3 = ((value&0xf00)>>8)-(Apwrdelta);
				else
					t3 = 0;
				if (((value&0xf000)>>12) > Apwrdelta)
					t4 = ((value&0xf000)>>12)-(Apwrdelta);
				else
					t4 = 0;
			}
			Adata |= ((t1<<16) + (t2<<20) + (t3<<24) + (t4<<28));

			if (i == 0)
				pAd->Tx20MPwrCfgABand[i] = (pAd->Tx20MPwrCfgABand[i] & 0x0000FFFF) | (Adata & 0xFFFF0000);
			else
				pAd->Tx20MPwrCfgABand[i] = Adata;

			DBGPRINT_RAW(RT_DEBUG_TRACE, ("20MHz BW, 5GHz band, Adata = %lx \n", Adata));
		}
	}

	//
	// Check this block is valid for 40MHz in 5G. If invalid, use parameter for 20MHz in 2.4G
	//
	bValid = TRUE;
	for (i=0; i<6; i++)
	{
		RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_40MHZ_5G + 2 + i*2, value);
		if (((value & 0x00FF) == 0x00FF) || ((value & 0xFF00) == 0xFF00))
		{
			bValid = FALSE;
			break;
		}
	}

	//
	// Get Txpower per MCS for 40MHz in 5G.
	//
	if (bValid)
	{
		for (i=0; i<4; i++)
		{
			RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_40MHZ_5G + i*4, value);
			if (bApwrdeltaMinus == FALSE)
			{
				t1 = (value&0xf)+(Apwrdelta);
				if (t1 > 0xf)
					t1 = 0xf;
				t2 = ((value&0xf0)>>4)+(Apwrdelta);
				if (t2 > 0xf)
					t2 = 0xf;
				t3 = ((value&0xf00)>>8)+(Apwrdelta);
				if (t3 > 0xf)
					t3 = 0xf;
				t4 = ((value&0xf000)>>12)+(Apwrdelta);
				if (t4 > 0xf)
					t4 = 0xf;
			}
			else
			{
				if ((value&0xf) > Apwrdelta)
					t1 = (value&0xf)-(Apwrdelta);
				else
					t1 = 0;
				if (((value&0xf0)>>4) > Apwrdelta)
					t2 = ((value&0xf0)>>4)-(Apwrdelta);
				else
					t2 = 0;
				if (((value&0xf00)>>8) > Apwrdelta)
					t3 = ((value&0xf00)>>8)-(Apwrdelta);
				else
					t3 = 0;
				if (((value&0xf000)>>12) > Apwrdelta)
					t4 = ((value&0xf000)>>12)-(Apwrdelta);
				else
					t4 = 0;
			}
			Adata = t1 + (t2<<4) + (t3<<8) + (t4<<12);

			RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_40MHZ_5G + i*4 + 2, value);
			if (bApwrdeltaMinus == FALSE)
			{
				t1 = (value&0xf)+(Apwrdelta);
				if (t1 > 0xf)
					t1 = 0xf;
				t2 = ((value&0xf0)>>4)+(Apwrdelta);
				if (t2 > 0xf)
					t2 = 0xf;
				t3 = ((value&0xf00)>>8)+(Apwrdelta);
				if (t3 > 0xf)
					t3 = 0xf;
				t4 = ((value&0xf000)>>12)+(Apwrdelta);
				if (t4 > 0xf)
					t4 = 0xf;
			}
			else
			{
				if ((value&0xf) > Apwrdelta)
					t1 = (value&0xf)-(Apwrdelta);
				else
					t1 = 0;
				if (((value&0xf0)>>4) > Apwrdelta)
					t2 = ((value&0xf0)>>4)-(Apwrdelta);
				else
					t2 = 0;
				if (((value&0xf00)>>8) > Apwrdelta)
					t3 = ((value&0xf00)>>8)-(Apwrdelta);
				else
					t3 = 0;
				if (((value&0xf000)>>12) > Apwrdelta)
					t4 = ((value&0xf000)>>12)-(Apwrdelta);
				else
					t4 = 0;
			}
			Adata |= ((t1<<16) + (t2<<20) + (t3<<24) + (t4<<28));

			if (i == 0)
				pAd->Tx40MPwrCfgABand[i+1] = (pAd->Tx40MPwrCfgABand[i+1] & 0x0000FFFF) | (Adata & 0xFFFF0000);
			else
				pAd->Tx40MPwrCfgABand[i+1] = Adata;

			DBGPRINT_RAW(RT_DEBUG_TRACE, ("40MHz BW, 5GHz band, Adata = %lx \n", Adata));
		}
	}
}


/*
	========================================================================

	Routine Description:
		Read initial channel power parameters from EEPROM

	Arguments:
		Adapter						Pointer to our adapter

	Return Value:
		None

	IRQL = PASSIVE_LEVEL

	Note:

	========================================================================
*/
VOID	RTMPReadChannelPwr(
	IN	PRTMP_ADAPTER	pAd)
{
	UCHAR				i, choffset;
	EEPROM_TX_PWR_STRUC	    Power;
	EEPROM_TX_PWR_STRUC	    Power2;

	// Read Tx power value for all channels
	// Value from 1 - 0x7f. Default value is 24.
	// Power value : 2.4G 0x00 (0) ~ 0x1F (31)
	//             : 5.5G 0xF9 (-7) ~ 0x0F (15)

	// 0. 11b/g, ch1 - ch 14
	for (i = 0; i < 7; i++)
	{
//		Power.word = RTMP_EEPROM_READ16(pAd, EEPROM_G_TX_PWR_OFFSET + i * 2);
//		Power2.word = RTMP_EEPROM_READ16(pAd, EEPROM_G_TX2_PWR_OFFSET + i * 2);
		RT28xx_EEPROM_READ16(pAd, EEPROM_G_TX_PWR_OFFSET + i * 2, Power.word);
		RT28xx_EEPROM_READ16(pAd, EEPROM_G_TX2_PWR_OFFSET + i * 2, Power2.word);
		pAd->TxPower[i * 2].Channel = i * 2 + 1;
		pAd->TxPower[i * 2 + 1].Channel = i * 2 + 2;

		if ((Power.field.Byte0 > 31) || (Power.field.Byte0 < 0))
			pAd->TxPower[i * 2].Power = DEFAULT_RF_TX_POWER;
		else
			pAd->TxPower[i * 2].Power = Power.field.Byte0;

		if ((Power.field.Byte1 > 31) || (Power.field.Byte1 < 0))
			pAd->TxPower[i * 2 + 1].Power = DEFAULT_RF_TX_POWER;
		else
			pAd->TxPower[i * 2 + 1].Power = Power.field.Byte1;

		if ((Power2.field.Byte0 > 31) || (Power2.field.Byte0 < 0))
			pAd->TxPower[i * 2].Power2 = DEFAULT_RF_TX_POWER;
		else
			pAd->TxPower[i * 2].Power2 = Power2.field.Byte0;

		if ((Power2.field.Byte1 > 31) || (Power2.field.Byte1 < 0))
			pAd->TxPower[i * 2 + 1].Power2 = DEFAULT_RF_TX_POWER;
		else
			pAd->TxPower[i * 2 + 1].Power2 = Power2.field.Byte1;
	}

	// 1. U-NII lower/middle band: 36, 38, 40; 44, 46, 48; 52, 54, 56; 60, 62, 64 (including central frequency in BW 40MHz)
	// 1.1 Fill up channel
	choffset = 14;
	for (i = 0; i < 4; i++)
	{
		pAd->TxPower[3 * i + choffset + 0].Channel	= 36 + i * 8 + 0;
		pAd->TxPower[3 * i + choffset + 0].Power	= DEFAULT_RF_TX_POWER;
		pAd->TxPower[3 * i + choffset + 0].Power2	= DEFAULT_RF_TX_POWER;

		pAd->TxPower[3 * i + choffset + 1].Channel	= 36 + i * 8 + 2;
		pAd->TxPower[3 * i + choffset + 1].Power	= DEFAULT_RF_TX_POWER;
		pAd->TxPower[3 * i + choffset + 1].Power2	= DEFAULT_RF_TX_POWER;

		pAd->TxPower[3 * i + choffset + 2].Channel	= 36 + i * 8 + 4;
		pAd->TxPower[3 * i + choffset + 2].Power	= DEFAULT_RF_TX_POWER;
		pAd->TxPower[3 * i + choffset + 2].Power2	= DEFAULT_RF_TX_POWER;
	}

	// 1.2 Fill up power
	for (i = 0; i < 6; i++)
	{
//		Power.word = RTMP_EEPROM_READ16(pAd, EEPROM_A_TX_PWR_OFFSET + i * 2);
//		Power2.word = RTMP_EEPROM_READ16(pAd, EEPROM_A_TX2_PWR_OFFSET + i * 2);
		RT28xx_EEPROM_READ16(pAd, EEPROM_A_TX_PWR_OFFSET + i * 2, Power.word);
		RT28xx_EEPROM_READ16(pAd, EEPROM_A_TX2_PWR_OFFSET + i * 2, Power2.word);

		if ((Power.field.Byte0 < 16) && (Power.field.Byte0 >= -7))
			pAd->TxPower[i * 2 + choffset + 0].Power = Power.field.Byte0;

		if ((Power.field.Byte1 < 16) && (Power.field.Byte1 >= -7))
			pAd->TxPower[i * 2 + choffset + 1].Power = Power.field.Byte1;

		if ((Power2.field.Byte0 < 16) && (Power2.field.Byte0 >= -7))
			pAd->TxPower[i * 2 + choffset + 0].Power2 = Power2.field.Byte0;

		if ((Power2.field.Byte1 < 16) && (Power2.field.Byte1 >= -7))
			pAd->TxPower[i * 2 + choffset + 1].Power2 = Power2.field.Byte1;
	}

	// 2. HipperLAN 2 100, 102 ,104; 108, 110, 112; 116, 118, 120; 124, 126, 128; 132, 134, 136; 140 (including central frequency in BW 40MHz)
	// 2.1 Fill up channel
	choffset = 14 + 12;
	for (i = 0; i < 5; i++)
	{
		pAd->TxPower[3 * i + choffset + 0].Channel	= 100 + i * 8 + 0;
		pAd->TxPower[3 * i + choffset + 0].Power	= DEFAULT_RF_TX_POWER;
		pAd->TxPower[3 * i + choffset + 0].Power2	= DEFAULT_RF_TX_POWER;

		pAd->TxPower[3 * i + choffset + 1].Channel	= 100 + i * 8 + 2;
		pAd->TxPower[3 * i + choffset + 1].Power	= DEFAULT_RF_TX_POWER;
		pAd->TxPower[3 * i + choffset + 1].Power2	= DEFAULT_RF_TX_POWER;

		pAd->TxPower[3 * i + choffset + 2].Channel	= 100 + i * 8 + 4;
		pAd->TxPower[3 * i + choffset + 2].Power	= DEFAULT_RF_TX_POWER;
		pAd->TxPower[3 * i + choffset + 2].Power2	= DEFAULT_RF_TX_POWER;
	}
	pAd->TxPower[3 * 5 + choffset + 0].Channel		= 140;
	pAd->TxPower[3 * 5 + choffset + 0].Power		= DEFAULT_RF_TX_POWER;
	pAd->TxPower[3 * 5 + choffset + 0].Power2		= DEFAULT_RF_TX_POWER;

	// 2.2 Fill up power
	for (i = 0; i < 8; i++)
	{
//		Power.word = RTMP_EEPROM_READ16(pAd, EEPROM_A_TX_PWR_OFFSET + (choffset - 14) + i * 2);
//		Power2.word = RTMP_EEPROM_READ16(pAd, EEPROM_A_TX2_PWR_OFFSET + (choffset - 14) + i * 2);
		RT28xx_EEPROM_READ16(pAd, EEPROM_A_TX_PWR_OFFSET + (choffset - 14) + i * 2, Power.word);
		RT28xx_EEPROM_READ16(pAd, EEPROM_A_TX2_PWR_OFFSET + (choffset - 14) + i * 2, Power2.word);

		if ((Power.field.Byte0 < 16) && (Power.field.Byte0 >= -7))
			pAd->TxPower[i * 2 + choffset + 0].Power = Power.field.Byte0;

		if ((Power.field.Byte1 < 16) && (Power.field.Byte1 >= -7))
			pAd->TxPower[i * 2 + choffset + 1].Power = Power.field.Byte1;

		if ((Power2.field.Byte0 < 16) && (Power2.field.Byte0 >= -7))
			pAd->TxPower[i * 2 + choffset + 0].Power2 = Power2.field.Byte0;

		if ((Power2.field.Byte1 < 16) && (Power2.field.Byte1 >= -7))
			pAd->TxPower[i * 2 + choffset + 1].Power2 = Power2.field.Byte1;
	}

	// 3. U-NII upper band: 149, 151, 153; 157, 159, 161; 165 (including central frequency in BW 40MHz)
	// 3.1 Fill up channel
	choffset = 14 + 12 + 16;
	for (i = 0; i < 2; i++)
	{
		pAd->TxPower[3 * i + choffset + 0].Channel	= 149 + i * 8 + 0;
		pAd->TxPower[3 * i + choffset + 0].Power	= DEFAULT_RF_TX_POWER;
		pAd->TxPower[3 * i + choffset + 0].Power2	= DEFAULT_RF_TX_POWER;

		pAd->TxPower[3 * i + choffset + 1].Channel	= 149 + i * 8 + 2;
		pAd->TxPower[3 * i + choffset + 1].Power	= DEFAULT_RF_TX_POWER;
		pAd->TxPower[3 * i + choffset + 1].Power2	= DEFAULT_RF_TX_POWER;

		pAd->TxPower[3 * i + choffset + 2].Channel	= 149 + i * 8 + 4;
		pAd->TxPower[3 * i + choffset + 2].Power	= DEFAULT_RF_TX_POWER;
		pAd->TxPower[3 * i + choffset + 2].Power2	= DEFAULT_RF_TX_POWER;
	}
	pAd->TxPower[3 * 2 + choffset + 0].Channel		= 165;
	pAd->TxPower[3 * 2 + choffset + 0].Power		= DEFAULT_RF_TX_POWER;
	pAd->TxPower[3 * 2 + choffset + 0].Power2		= DEFAULT_RF_TX_POWER;

	// 3.2 Fill up power
	for (i = 0; i < 4; i++)
	{
//		Power.word = RTMP_EEPROM_READ16(pAd, EEPROM_A_TX_PWR_OFFSET + (choffset - 14) + i * 2);
//		Power2.word = RTMP_EEPROM_READ16(pAd, EEPROM_A_TX2_PWR_OFFSET + (choffset - 14) + i * 2);
		RT28xx_EEPROM_READ16(pAd, EEPROM_A_TX_PWR_OFFSET + (choffset - 14) + i * 2, Power.word);
		RT28xx_EEPROM_READ16(pAd, EEPROM_A_TX2_PWR_OFFSET + (choffset - 14) + i * 2, Power2.word);

		if ((Power.field.Byte0 < 16) && (Power.field.Byte0 >= -7))
			pAd->TxPower[i * 2 + choffset + 0].Power = Power.field.Byte0;

		if ((Power.field.Byte1 < 16) && (Power.field.Byte1 >= -7))
			pAd->TxPower[i * 2 + choffset + 1].Power = Power.field.Byte1;

		if ((Power2.field.Byte0 < 16) && (Power2.field.Byte0 >= -7))
			pAd->TxPower[i * 2 + choffset + 0].Power2 = Power2.field.Byte0;

		if ((Power2.field.Byte1 < 16) && (Power2.field.Byte1 >= -7))
			pAd->TxPower[i * 2 + choffset + 1].Power2 = Power2.field.Byte1;
	}

	// 4. Print and Debug
	choffset = 14 + 12 + 16 + 7;

}

/*
	========================================================================

	Routine Description:
		Read the following from the registry
		1. All the parameters
		2. NetworkAddres

	Arguments:
		Adapter						Pointer to our adapter
		WrapperConfigurationContext	For use by NdisOpenConfiguration

	Return Value:
		NDIS_STATUS_SUCCESS
		NDIS_STATUS_FAILURE
		NDIS_STATUS_RESOURCES

	IRQL = PASSIVE_LEVEL

	Note:

	========================================================================
*/
NDIS_STATUS	NICReadRegParameters(
	IN	PRTMP_ADAPTER		pAd,
	IN	NDIS_HANDLE			WrapperConfigurationContext
	)
{
	NDIS_STATUS						Status = NDIS_STATUS_SUCCESS;
	DBGPRINT_S(Status, ("<-- NICReadRegParameters, Status=%x\n", Status));
	return Status;
}


#ifdef RT30xx
/*
	========================================================================

	Routine Description:
		For RF filter calibration purpose

	Arguments:
		pAd                          Pointer to our adapter

	Return Value:
		None

	IRQL = PASSIVE_LEVEL

	========================================================================
*/
VOID RTMPFilterCalibration(
	IN PRTMP_ADAPTER pAd)
{
	UCHAR	R55x = 0, value, FilterTarget = 0x1E, BBPValue=0;
	UINT	loop = 0, count = 0, loopcnt = 0, ReTry = 0;
	UCHAR	RF_R24_Value = 0;

	// Give bbp filter initial value
	pAd->Mlme.CaliBW20RfR24 = 0x1F;
	pAd->Mlme.CaliBW40RfR24 = 0x2F; //Bit[5] must be 1 for BW 40

	do
	{
		if (loop == 1)	//BandWidth = 40 MHz
		{
			// Write 0x27 to RF_R24 to program filter
			RF_R24_Value = 0x27;
			RT30xxWriteRFRegister(pAd, RF_R24, RF_R24_Value);
			if (IS_RT3090(pAd))
				FilterTarget = 0x15;
			else
				FilterTarget = 0x19;

			// when calibrate BW40, BBP mask must set to BW40.
			RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R4, &BBPValue);
			BBPValue&= (~0x18);
			BBPValue|= (0x10);
			RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R4, BBPValue);

			// set to BW40
			RT30xxReadRFRegister(pAd, RF_R31, &value);
			value |= 0x20;
			RT30xxWriteRFRegister(pAd, RF_R31, value);
		}
		else			//BandWidth = 20 MHz
		{
			// Write 0x07 to RF_R24 to program filter
			RF_R24_Value = 0x07;
			RT30xxWriteRFRegister(pAd, RF_R24, RF_R24_Value);
			if (IS_RT3090(pAd))
				FilterTarget = 0x13;
			else
				FilterTarget = 0x16;

			// set to BW20
			RT30xxReadRFRegister(pAd, RF_R31, &value);
			value &= (~0x20);
			RT30xxWriteRFRegister(pAd, RF_R31, value);
		}

		// Write 0x01 to RF_R22 to enable baseband loopback mode
		RT30xxReadRFRegister(pAd, RF_R22, &value);
		value |= 0x01;
		RT30xxWriteRFRegister(pAd, RF_R22, value);

		// Write 0x00 to BBP_R24 to set power & frequency of passband test tone
		RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R24, 0);

		do
		{
			// Write 0x90 to BBP_R25 to transmit test tone
			RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R25, 0x90);

			RTMPusecDelay(1000);
			// Read BBP_R55[6:0] for received power, set R55x = BBP_R55[6:0]
			RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R55, &value);
			R55x = value & 0xFF;

		} while ((ReTry++ < 100) && (R55x == 0));

		// Write 0x06 to BBP_R24 to set power & frequency of stopband test tone
		RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R24, 0x06);

		while(TRUE)
		{
			// Write 0x90 to BBP_R25 to transmit test tone
			RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R25, 0x90);

			//We need to wait for calibration
			RTMPusecDelay(1000);
			RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R55, &value);
			value &= 0xFF;
			if ((R55x - value) < FilterTarget)
			{
				RF_R24_Value ++;
			}
			else if ((R55x - value) == FilterTarget)
			{
				RF_R24_Value ++;
				count ++;
			}
			else
			{
				break;
			}

			// prevent infinite loop cause driver hang.
			if (loopcnt++ > 100)
			{
				DBGPRINT(RT_DEBUG_ERROR, ("RTMPFilterCalibration - can't find a valid value, loopcnt=%d stop calibrating", loopcnt));
				break;
			}

			// Write RF_R24 to program filter
			RT30xxWriteRFRegister(pAd, RF_R24, RF_R24_Value);
		}

		if (count > 0)
		{
			RF_R24_Value = RF_R24_Value - ((count) ? (1) : (0));
		}

		// Store for future usage
		if (loopcnt < 100)
		{
			if (loop++ == 0)
			{
				//BandWidth = 20 MHz
				pAd->Mlme.CaliBW20RfR24 = (UCHAR)RF_R24_Value;
			}
			else
			{
				//BandWidth = 40 MHz
				pAd->Mlme.CaliBW40RfR24 = (UCHAR)RF_R24_Value;
				break;
			}
		}
		else
			break;

		RT30xxWriteRFRegister(pAd, RF_R24, RF_R24_Value);

		// reset count
		count = 0;
	} while(TRUE);

	//
	// Set back to initial state
	//
	RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R24, 0);

	RT30xxReadRFRegister(pAd, RF_R22, &value);
	value &= ~(0x01);
	RT30xxWriteRFRegister(pAd, RF_R22, value);

	// set BBP back to BW20
	RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R4, &BBPValue);
	BBPValue&= (~0x18);
	RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R4, BBPValue);

	DBGPRINT(RT_DEBUG_TRACE, ("RTMPFilterCalibration - CaliBW20RfR24=0x%x, CaliBW40RfR24=0x%x\n", pAd->Mlme.CaliBW20RfR24, pAd->Mlme.CaliBW40RfR24));
}
#endif // RT30xx //


#ifdef RT3070
VOID NICInitRT30xxRFRegisters(IN PRTMP_ADAPTER pAd)
{
	INT i;
	// Driver must read EEPROM to get RfIcType before initial RF registers
	// Initialize RF register to default value
	if (IS_RT3070(pAd) || IS_RT3071(pAd))
	{
		// Init RF calibration
		// Driver should toggle RF R30 bit7 before init RF registers
		UINT32 RfReg = 0;
		UINT32 data;

		RT30xxReadRFRegister(pAd, RF_R30, (PUCHAR)&RfReg);
		RfReg |= 0x80;
		RT30xxWriteRFRegister(pAd, RF_R30, (UCHAR)RfReg);
		RTMPusecDelay(1000);
		RfReg &= 0x7F;
		RT30xxWriteRFRegister(pAd, RF_R30, (UCHAR)RfReg);

		// Initialize RF register to default value
		for (i = 0; i < NUM_RF_REG_PARMS; i++)
		{
			RT30xxWriteRFRegister(pAd, RT30xx_RFRegTable[i].Register, RT30xx_RFRegTable[i].Value);
		}

		// add by johnli
		if (IS_RT3070(pAd))
		{
			//  Update MAC 0x05D4 from 01xxxxxx to 0Dxxxxxx (voltage 1.2V to 1.35V) for RT3070 to improve yield rate
			RTUSBReadMACRegister(pAd, LDO_CFG0, &data);
			data = ((data & 0xF0FFFFFF) | 0x0D000000);
			RTUSBWriteMACRegister(pAd, LDO_CFG0, data);
		}
		else if (IS_RT3071(pAd))
		{
			// Driver should set RF R6 bit6 on before init RF registers
			RT30xxReadRFRegister(pAd, RF_R06, (PUCHAR)&RfReg);
			RfReg |= 0x40;
			RT30xxWriteRFRegister(pAd, RF_R06, (UCHAR)RfReg);

			// init R31
			RT30xxWriteRFRegister(pAd, RF_R31, 0x14);

			// RT3071 version E has fixed this issue
			if ((pAd->NicConfig2.field.DACTestBit == 1) && ((pAd->MACVersion & 0xffff) < 0x0211))
			{
				// patch tx EVM issue temporarily
				RTUSBReadMACRegister(pAd, LDO_CFG0, &data);
				data = ((data & 0xE0FFFFFF) | 0x0D000000);
				RTUSBWriteMACRegister(pAd, LDO_CFG0, data);
			}
			else
			{
				RTMP_IO_READ32(pAd, LDO_CFG0, &data);
				data = ((data & 0xE0FFFFFF) | 0x01000000);
				RTMP_IO_WRITE32(pAd, LDO_CFG0, data);
			}

			// patch LNA_PE_G1 failed issue
			RTUSBReadMACRegister(pAd, GPIO_SWITCH, &data);
			data &= ~(0x20);
			RTUSBWriteMACRegister(pAd, GPIO_SWITCH, data);
		}

		//For RF filter Calibration
		RTMPFilterCalibration(pAd);

		// Initialize RF R27 register, set RF R27 must be behind RTMPFilterCalibration()
		if ((pAd->MACVersion & 0xffff) < 0x0211)
			RT30xxWriteRFRegister(pAd, RF_R27, 0x3);

		// set led open drain enable
		RTUSBReadMACRegister(pAd, OPT_14, &data);
		data |= 0x01;
		RTUSBWriteMACRegister(pAd, OPT_14, data);

		if (IS_RT3071(pAd))
		{
			// add by johnli, RF power sequence setup, load RF normal operation-mode setup
			RT30xxLoadRFNormalModeSetup(pAd);
		}
	}

}
#endif // RT3070 //


/*
	========================================================================

	Routine Description:
		Read initial parameters from EEPROM

	Arguments:
		Adapter						Pointer to our adapter

	Return Value:
		None

	IRQL = PASSIVE_LEVEL

	Note:

	========================================================================
*/
VOID	NICReadEEPROMParameters(
	IN	PRTMP_ADAPTER	pAd,
	IN	PUCHAR			mac_addr)
{
	UINT32			data = 0;
	USHORT			i, value, value2;
	UCHAR			TmpPhy;
	EEPROM_TX_PWR_STRUC	    Power;
	EEPROM_VERSION_STRUC    Version;
	EEPROM_ANTENNA_STRUC	Antenna;
	EEPROM_NIC_CONFIG2_STRUC    NicConfig2;

	DBGPRINT(RT_DEBUG_TRACE, ("--> NICReadEEPROMParameters\n"));

	// Init EEPROM Address Number, before access EEPROM; if 93c46, EEPROMAddressNum=6, else if 93c66, EEPROMAddressNum=8
	RTMP_IO_READ32(pAd, E2PROM_CSR, &data);
	DBGPRINT(RT_DEBUG_TRACE, ("--> E2PROM_CSR = 0x%x\n", data));

	if((data & 0x30) == 0)
		pAd->EEPROMAddressNum = 6;		// 93C46
	else if((data & 0x30) == 0x10)
		pAd->EEPROMAddressNum = 8;     // 93C66
	else
		pAd->EEPROMAddressNum = 8;     // 93C86
	DBGPRINT(RT_DEBUG_TRACE, ("--> EEPROMAddressNum = %d\n", pAd->EEPROMAddressNum ));

	// RT2860 MAC no longer auto load MAC address from E2PROM. Driver has to intialize
	// MAC address registers according to E2PROM setting
	if (mac_addr == NULL ||
		strlen(mac_addr) != 17 ||
		mac_addr[2] != ':'  || mac_addr[5] != ':'  || mac_addr[8] != ':' ||
		mac_addr[11] != ':' || mac_addr[14] != ':')
	{
		USHORT  Addr01,Addr23,Addr45 ;

		RT28xx_EEPROM_READ16(pAd, 0x04, Addr01);
		RT28xx_EEPROM_READ16(pAd, 0x06, Addr23);
		RT28xx_EEPROM_READ16(pAd, 0x08, Addr45);

		pAd->PermanentAddress[0] = (UCHAR)(Addr01 & 0xff);
		pAd->PermanentAddress[1] = (UCHAR)(Addr01 >> 8);
		pAd->PermanentAddress[2] = (UCHAR)(Addr23 & 0xff);
		pAd->PermanentAddress[3] = (UCHAR)(Addr23 >> 8);
		pAd->PermanentAddress[4] = (UCHAR)(Addr45 & 0xff);
		pAd->PermanentAddress[5] = (UCHAR)(Addr45 >> 8);

		DBGPRINT(RT_DEBUG_TRACE, ("Initialize MAC Address from E2PROM \n"));
	}
	else
	{
		INT		j;
		PUCHAR	macptr;

		macptr = mac_addr;

		for (j=0; j<MAC_ADDR_LEN; j++)
		{
			AtoH(macptr, &pAd->PermanentAddress[j], 1);
			macptr=macptr+3;
		}

		DBGPRINT(RT_DEBUG_TRACE, ("Initialize MAC Address from module parameter \n"));
	}


	{
		//more conveninet to test mbssid, so ap's bssid &0xf1
		if (pAd->PermanentAddress[0] == 0xff)
			pAd->PermanentAddress[0] = RandomByte(pAd)&0xf8;

		//if (pAd->PermanentAddress[5] == 0xff)
		//	pAd->PermanentAddress[5] = RandomByte(pAd)&0xf8;

		DBGPRINT_RAW(RT_DEBUG_TRACE,("E2PROM MAC: =%02x:%02x:%02x:%02x:%02x:%02x\n",
			pAd->PermanentAddress[0], pAd->PermanentAddress[1],
			pAd->PermanentAddress[2], pAd->PermanentAddress[3],
			pAd->PermanentAddress[4], pAd->PermanentAddress[5]));
		if (pAd->bLocalAdminMAC == FALSE)
		{
			MAC_DW0_STRUC csr2;
			MAC_DW1_STRUC csr3;
			COPY_MAC_ADDR(pAd->CurrentAddress, pAd->PermanentAddress);
			csr2.field.Byte0 = pAd->CurrentAddress[0];
			csr2.field.Byte1 = pAd->CurrentAddress[1];
			csr2.field.Byte2 = pAd->CurrentAddress[2];
			csr2.field.Byte3 = pAd->CurrentAddress[3];
			RTMP_IO_WRITE32(pAd, MAC_ADDR_DW0, csr2.word);
			csr3.word = 0;
			csr3.field.Byte4 = pAd->CurrentAddress[4];
			csr3.field.Byte5 = pAd->CurrentAddress[5];
			csr3.field.U2MeMask = 0xff;
			RTMP_IO_WRITE32(pAd, MAC_ADDR_DW1, csr3.word);
			DBGPRINT_RAW(RT_DEBUG_TRACE,("E2PROM MAC: =%02x:%02x:%02x:%02x:%02x:%02x\n",
				pAd->PermanentAddress[0], pAd->PermanentAddress[1],
				pAd->PermanentAddress[2], pAd->PermanentAddress[3],
				pAd->PermanentAddress[4], pAd->PermanentAddress[5]));
		}
	}

	// if not return early. cause fail at emulation.
	// Init the channel number for TX channel power
	RTMPReadChannelPwr(pAd);

	// if E2PROM version mismatch with driver's expectation, then skip
	// all subsequent E2RPOM retieval and set a system error bit to notify GUI
	RT28xx_EEPROM_READ16(pAd, EEPROM_VERSION_OFFSET, Version.word);
	pAd->EepromVersion = Version.field.Version + Version.field.FaeReleaseNumber * 256;
	DBGPRINT(RT_DEBUG_TRACE, ("E2PROM: Version = %d, FAE release #%d\n", Version.field.Version, Version.field.FaeReleaseNumber));

	if (Version.field.Version > VALID_EEPROM_VERSION)
	{
		DBGPRINT_ERR(("E2PROM: WRONG VERSION 0x%x, should be %d\n",Version.field.Version, VALID_EEPROM_VERSION));
		/*pAd->SystemErrorBitmap |= 0x00000001;

		// hard-code default value when no proper E2PROM installed
		pAd->bAutoTxAgcA = FALSE;
		pAd->bAutoTxAgcG = FALSE;

		// Default the channel power
		for (i = 0; i < MAX_NUM_OF_CHANNELS; i++)
			pAd->TxPower[i].Power = DEFAULT_RF_TX_POWER;

		// Default the channel power
		for (i = 0; i < MAX_NUM_OF_11JCHANNELS; i++)
			pAd->TxPower11J[i].Power = DEFAULT_RF_TX_POWER;

		for(i = 0; i < NUM_EEPROM_BBP_PARMS; i++)
			pAd->EEPROMDefaultValue[i] = 0xffff;
		return;  */
	}

	// Read BBP default value from EEPROM and store to array(EEPROMDefaultValue) in pAd
	RT28xx_EEPROM_READ16(pAd, EEPROM_NIC1_OFFSET, value);
	pAd->EEPROMDefaultValue[0] = value;

	RT28xx_EEPROM_READ16(pAd, EEPROM_NIC2_OFFSET, value);
	pAd->EEPROMDefaultValue[1] = value;

	RT28xx_EEPROM_READ16(pAd, 0x38, value);	// Country Region
	pAd->EEPROMDefaultValue[2] = value;

	for(i = 0; i < 8; i++)
	{
		RT28xx_EEPROM_READ16(pAd, EEPROM_BBP_BASE_OFFSET + i*2, value);
		pAd->EEPROMDefaultValue[i+3] = value;
	}

	// We have to parse NIC configuration 0 at here.
	// If TSSI did not have preloaded value, it should reset the TxAutoAgc to false
	// Therefore, we have to read TxAutoAgc control beforehand.
	// Read Tx AGC control bit
	Antenna.word = pAd->EEPROMDefaultValue[0];
	if (Antenna.word == 0xFFFF)
	{
#ifdef RT30xx
		if(IS_RT3090(pAd))
		{
			Antenna.word = 0;
			Antenna.field.RfIcType = RFIC_3020;
			Antenna.field.TxPath = 1;
			Antenna.field.RxPath = 1;
		}
		else
		{
#endif // RT30xx //
			Antenna.word = 0;
			Antenna.field.RfIcType = RFIC_2820;
			Antenna.field.TxPath = 1;
			Antenna.field.RxPath = 2;
			DBGPRINT(RT_DEBUG_WARN, ("E2PROM error, hard code as 0x%04x\n", Antenna.word));
#ifdef RT30xx
		}
#endif // RT30xx //
	}

	// Choose the desired Tx&Rx stream.
	if ((pAd->CommonCfg.TxStream == 0) || (pAd->CommonCfg.TxStream > Antenna.field.TxPath))
		pAd->CommonCfg.TxStream = Antenna.field.TxPath;

	if ((pAd->CommonCfg.RxStream == 0) || (pAd->CommonCfg.RxStream > Antenna.field.RxPath))
	{
		pAd->CommonCfg.RxStream = Antenna.field.RxPath;

		if ((pAd->MACVersion < RALINK_2883_VERSION) &&
			(pAd->CommonCfg.RxStream > 2))
		{
			// only 2 Rx streams for RT2860 series
			pAd->CommonCfg.RxStream = 2;
		}
	}

	// 3*3
	// read value from EEPROM and set them to CSR174 ~ 177 in chain0 ~ chain2
	// yet implement
	for(i=0; i<3; i++)
	{
	}

	NicConfig2.word = pAd->EEPROMDefaultValue[1];



#ifdef CONFIG_STA_SUPPORT
	IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
	{
		if ((NicConfig2.word & 0x00ff) == 0xff)
		{
			NicConfig2.word &= 0xff00;
		}

		if ((NicConfig2.word >> 8) == 0xff)
		{
			NicConfig2.word &= 0x00ff;
		}
	}
#endif // CONFIG_STA_SUPPORT //

	if (NicConfig2.field.DynamicTxAgcControl == 1)
		pAd->bAutoTxAgcA = pAd->bAutoTxAgcG = TRUE;
	else
		pAd->bAutoTxAgcA = pAd->bAutoTxAgcG = FALSE;

	DBGPRINT_RAW(RT_DEBUG_TRACE, ("NICReadEEPROMParameters: RxPath = %d, TxPath = %d\n", Antenna.field.RxPath, Antenna.field.TxPath));

	// Save the antenna for future use
	pAd->Antenna.word = Antenna.word;

	//
	// Reset PhyMode if we don't support 802.11a
	// Only RFIC_2850 & RFIC_2750 support 802.11a
	//
	if ((Antenna.field.RfIcType != RFIC_2850) && (Antenna.field.RfIcType != RFIC_2750))
	{
		if ((pAd->CommonCfg.PhyMode == PHY_11ABG_MIXED) ||
			(pAd->CommonCfg.PhyMode == PHY_11A))
			pAd->CommonCfg.PhyMode = PHY_11BG_MIXED;
#ifdef DOT11_N_SUPPORT
		else if ((pAd->CommonCfg.PhyMode == PHY_11ABGN_MIXED)	||
				 (pAd->CommonCfg.PhyMode == PHY_11AN_MIXED) 	||
				 (pAd->CommonCfg.PhyMode == PHY_11AGN_MIXED) 	||
				 (pAd->CommonCfg.PhyMode == PHY_11N_5G))
			pAd->CommonCfg.PhyMode = PHY_11BGN_MIXED;
#endif // DOT11_N_SUPPORT //
	}

	// Read TSSI reference and TSSI boundary for temperature compensation. This is ugly
	// 0. 11b/g
	{
		/* these are tempature reference value (0x00 ~ 0xFE)
		   ex: 0x00 0x15 0x25 0x45 0x88 0xA0 0xB5 0xD0 0xF0
		   TssiPlusBoundaryG [4] [3] [2] [1] [0] (smaller) +
		   TssiMinusBoundaryG[0] [1] [2] [3] [4] (larger) */
		RT28xx_EEPROM_READ16(pAd, 0x6E, Power.word);
		pAd->TssiMinusBoundaryG[4] = Power.field.Byte0;
		pAd->TssiMinusBoundaryG[3] = Power.field.Byte1;
		RT28xx_EEPROM_READ16(pAd, 0x70, Power.word);
		pAd->TssiMinusBoundaryG[2] = Power.field.Byte0;
		pAd->TssiMinusBoundaryG[1] = Power.field.Byte1;
		RT28xx_EEPROM_READ16(pAd, 0x72, Power.word);
		pAd->TssiRefG   = Power.field.Byte0; /* reference value [0] */
		pAd->TssiPlusBoundaryG[1] = Power.field.Byte1;
		RT28xx_EEPROM_READ16(pAd, 0x74, Power.word);
		pAd->TssiPlusBoundaryG[2] = Power.field.Byte0;
		pAd->TssiPlusBoundaryG[3] = Power.field.Byte1;
		RT28xx_EEPROM_READ16(pAd, 0x76, Power.word);
		pAd->TssiPlusBoundaryG[4] = Power.field.Byte0;
		pAd->TxAgcStepG = Power.field.Byte1;
		pAd->TxAgcCompensateG = 0;
		pAd->TssiMinusBoundaryG[0] = pAd->TssiRefG;
		pAd->TssiPlusBoundaryG[0]  = pAd->TssiRefG;

		// Disable TxAgc if the based value is not right
		if (pAd->TssiRefG == 0xff)
			pAd->bAutoTxAgcG = FALSE;

		DBGPRINT(RT_DEBUG_TRACE,("E2PROM: G Tssi[-4 .. +4] = %d %d %d %d - %d -%d %d %d %d, step=%d, tuning=%d\n",
			pAd->TssiMinusBoundaryG[4], pAd->TssiMinusBoundaryG[3], pAd->TssiMinusBoundaryG[2], pAd->TssiMinusBoundaryG[1],
			pAd->TssiRefG,
			pAd->TssiPlusBoundaryG[1], pAd->TssiPlusBoundaryG[2], pAd->TssiPlusBoundaryG[3], pAd->TssiPlusBoundaryG[4],
			pAd->TxAgcStepG, pAd->bAutoTxAgcG));
	}
	// 1. 11a
	{
		RT28xx_EEPROM_READ16(pAd, 0xD4, Power.word);
		pAd->TssiMinusBoundaryA[4] = Power.field.Byte0;
		pAd->TssiMinusBoundaryA[3] = Power.field.Byte1;
		RT28xx_EEPROM_READ16(pAd, 0xD6, Power.word);
		pAd->TssiMinusBoundaryA[2] = Power.field.Byte0;
		pAd->TssiMinusBoundaryA[1] = Power.field.Byte1;
		RT28xx_EEPROM_READ16(pAd, 0xD8, Power.word);
		pAd->TssiRefA   = Power.field.Byte0;
		pAd->TssiPlusBoundaryA[1] = Power.field.Byte1;
		RT28xx_EEPROM_READ16(pAd, 0xDA, Power.word);
		pAd->TssiPlusBoundaryA[2] = Power.field.Byte0;
		pAd->TssiPlusBoundaryA[3] = Power.field.Byte1;
		RT28xx_EEPROM_READ16(pAd, 0xDC, Power.word);
		pAd->TssiPlusBoundaryA[4] = Power.field.Byte0;
		pAd->TxAgcStepA = Power.field.Byte1;
		pAd->TxAgcCompensateA = 0;
		pAd->TssiMinusBoundaryA[0] = pAd->TssiRefA;
		pAd->TssiPlusBoundaryA[0]  = pAd->TssiRefA;

		// Disable TxAgc if the based value is not right
		if (pAd->TssiRefA == 0xff)
			pAd->bAutoTxAgcA = FALSE;

		DBGPRINT(RT_DEBUG_TRACE,("E2PROM: A Tssi[-4 .. +4] = %d %d %d %d - %d -%d %d %d %d, step=%d, tuning=%d\n",
			pAd->TssiMinusBoundaryA[4], pAd->TssiMinusBoundaryA[3], pAd->TssiMinusBoundaryA[2], pAd->TssiMinusBoundaryA[1],
			pAd->TssiRefA,
			pAd->TssiPlusBoundaryA[1], pAd->TssiPlusBoundaryA[2], pAd->TssiPlusBoundaryA[3], pAd->TssiPlusBoundaryA[4],
			pAd->TxAgcStepA, pAd->bAutoTxAgcA));
	}
	pAd->BbpRssiToDbmDelta = 0x0;

	// Read frequency offset setting for RF
	RT28xx_EEPROM_READ16(pAd, EEPROM_FREQ_OFFSET, value);
	if ((value & 0x00FF) != 0x00FF)
		pAd->RfFreqOffset = (ULONG) (value & 0x00FF);
	else
		pAd->RfFreqOffset = 0;
	DBGPRINT(RT_DEBUG_TRACE, ("E2PROM: RF FreqOffset=0x%lx \n", pAd->RfFreqOffset));

	//CountryRegion byte offset (38h)
	value = pAd->EEPROMDefaultValue[2] >> 8;		// 2.4G band
	value2 = pAd->EEPROMDefaultValue[2] & 0x00FF;	// 5G band

	if ((value <= REGION_MAXIMUM_BG_BAND) && (value2 <= REGION_MAXIMUM_A_BAND))
	{
		pAd->CommonCfg.CountryRegion = ((UCHAR) value) | 0x80;
		pAd->CommonCfg.CountryRegionForABand = ((UCHAR) value2) | 0x80;
		TmpPhy = pAd->CommonCfg.PhyMode;
		pAd->CommonCfg.PhyMode = 0xff;
		RTMPSetPhyMode(pAd, TmpPhy);
#ifdef DOT11_N_SUPPORT
		SetCommonHT(pAd);
#endif // DOT11_N_SUPPORT //
	}

	//
	// Get RSSI Offset on EEPROM 0x9Ah & 0x9Ch.
	// The valid value are (-10 ~ 10)
	//
	RT28xx_EEPROM_READ16(pAd, EEPROM_RSSI_BG_OFFSET, value);
	pAd->BGRssiOffset0 = value & 0x00ff;
	pAd->BGRssiOffset1 = (value >> 8);
	RT28xx_EEPROM_READ16(pAd, EEPROM_RSSI_BG_OFFSET+2, value);
	pAd->BGRssiOffset2 = value & 0x00ff;
	pAd->ALNAGain1 = (value >> 8);
	RT28xx_EEPROM_READ16(pAd, EEPROM_LNA_OFFSET, value);
	pAd->BLNAGain = value & 0x00ff;
	pAd->ALNAGain0 = (value >> 8);

	// Validate 11b/g RSSI_0 offset.
	if ((pAd->BGRssiOffset0 < -10) || (pAd->BGRssiOffset0 > 10))
		pAd->BGRssiOffset0 = 0;

	// Validate 11b/g RSSI_1 offset.
	if ((pAd->BGRssiOffset1 < -10) || (pAd->BGRssiOffset1 > 10))
		pAd->BGRssiOffset1 = 0;

	// Validate 11b/g RSSI_2 offset.
	if ((pAd->BGRssiOffset2 < -10) || (pAd->BGRssiOffset2 > 10))
		pAd->BGRssiOffset2 = 0;

	RT28xx_EEPROM_READ16(pAd, EEPROM_RSSI_A_OFFSET, value);
	pAd->ARssiOffset0 = value & 0x00ff;
	pAd->ARssiOffset1 = (value >> 8);
	RT28xx_EEPROM_READ16(pAd, (EEPROM_RSSI_A_OFFSET+2), value);
	pAd->ARssiOffset2 = value & 0x00ff;
	pAd->ALNAGain2 = (value >> 8);

	if (((UCHAR)pAd->ALNAGain1 == 0xFF) || (pAd->ALNAGain1 == 0x00))
		pAd->ALNAGain1 = pAd->ALNAGain0;
	if (((UCHAR)pAd->ALNAGain2 == 0xFF) || (pAd->ALNAGain2 == 0x00))
		pAd->ALNAGain2 = pAd->ALNAGain0;

	// Validate 11a RSSI_0 offset.
	if ((pAd->ARssiOffset0 < -10) || (pAd->ARssiOffset0 > 10))
		pAd->ARssiOffset0 = 0;

	// Validate 11a RSSI_1 offset.
	if ((pAd->ARssiOffset1 < -10) || (pAd->ARssiOffset1 > 10))
		pAd->ARssiOffset1 = 0;

	//Validate 11a RSSI_2 offset.
	if ((pAd->ARssiOffset2 < -10) || (pAd->ARssiOffset2 > 10))
		pAd->ARssiOffset2 = 0;

	//
	// Get LED Setting.
	//
	RT28xx_EEPROM_READ16(pAd, 0x3a, value);
	pAd->LedCntl.word = (value&0xff00) >> 8;
	RT28xx_EEPROM_READ16(pAd, EEPROM_LED1_OFFSET, value);
	pAd->Led1 = value;
	RT28xx_EEPROM_READ16(pAd, EEPROM_LED2_OFFSET, value);
	pAd->Led2 = value;
	RT28xx_EEPROM_READ16(pAd, EEPROM_LED3_OFFSET, value);
	pAd->Led3 = value;

	RTMPReadTxPwrPerRate(pAd);

#ifdef SINGLE_SKU
	//pAd->CommonCfg.DefineMaxTxPwr = RTMP_EEPROM_READ16(pAd, EEPROM_DEFINE_MAX_TXPWR);
	RT28xx_EEPROM_READ16(pAd, EEPROM_DEFINE_MAX_TXPWR, pAd->CommonCfg.DefineMaxTxPwr);
#endif // SINGLE_SKU //
#ifdef RT30xx
	if (IS_RT30xx(pAd))
	{
		eFusePhysicalReadRegisters(pAd, EFUSE_TAG, 2, &value);
		pAd->EFuseTag = (value & 0xff);
	}
#endif // RT30xx //

	DBGPRINT(RT_DEBUG_TRACE, ("<-- NICReadEEPROMParameters\n"));
}

/*
	========================================================================

	Routine Description:
		Set default value from EEPROM

	Arguments:
		Adapter						Pointer to our adapter

	Return Value:
		None

	IRQL = PASSIVE_LEVEL

	Note:

	========================================================================
*/
VOID	NICInitAsicFromEEPROM(
	IN	PRTMP_ADAPTER	pAd)
{
#ifdef CONFIG_STA_SUPPORT
	UINT32					data = 0;
	UCHAR	BBPR1 = 0;
#endif // CONFIG_STA_SUPPORT //
	USHORT					i;
	EEPROM_ANTENNA_STRUC	Antenna;
	EEPROM_NIC_CONFIG2_STRUC    NicConfig2;
	UCHAR	BBPR3 = 0;

	DBGPRINT(RT_DEBUG_TRACE, ("--> NICInitAsicFromEEPROM\n"));
	for(i = 3; i < NUM_EEPROM_BBP_PARMS; i++)
	{
		UCHAR BbpRegIdx, BbpValue;

		if ((pAd->EEPROMDefaultValue[i] != 0xFFFF) && (pAd->EEPROMDefaultValue[i] != 0))
		{
			BbpRegIdx = (UCHAR)(pAd->EEPROMDefaultValue[i] >> 8);
			BbpValue  = (UCHAR)(pAd->EEPROMDefaultValue[i] & 0xff);
			RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BbpRegIdx, BbpValue);
		}
	}

	Antenna.word = pAd->EEPROMDefaultValue[0];
	if (Antenna.word == 0xFFFF)
	{
		DBGPRINT(RT_DEBUG_ERROR, ("E2PROM error, hard code as 0x%04x\n", Antenna.word));
		BUG_ON(Antenna.word == 0xFFFF);
	}
	pAd->Mlme.RealRxPath = (UCHAR) Antenna.field.RxPath;
	pAd->RfIcType = (UCHAR) Antenna.field.RfIcType;

	DBGPRINT(RT_DEBUG_WARN, ("pAd->RfIcType = %d, RealRxPath=%d, TxPath = %d\n", pAd->RfIcType, pAd->Mlme.RealRxPath,Antenna.field.TxPath));

	// Save the antenna for future use
	pAd->Antenna.word = Antenna.word;

	NicConfig2.word = pAd->EEPROMDefaultValue[1];


#ifdef CONFIG_STA_SUPPORT
	IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
	{
		if ((NicConfig2.word & 0x00ff) == 0xff)
		{
			NicConfig2.word &= 0xff00;
		}

		if ((NicConfig2.word >> 8) == 0xff)
		{
			NicConfig2.word &= 0x00ff;
		}
	}
#endif // CONFIG_STA_SUPPORT //

	// Save the antenna for future use
	pAd->NicConfig2.word = NicConfig2.word;

	// set default antenna as main
	if (pAd->RfIcType == RFIC_3020)
		AsicSetRxAnt(pAd, pAd->RxAnt.Pair1PrimaryRxAnt);

	//
	// Send LED Setting to MCU.
	//
	if (pAd->LedCntl.word == 0xFF)
	{
		pAd->LedCntl.word = 0x01;
		pAd->Led1 = 0x5555;
		pAd->Led2 = 0x2221;

#ifdef RT2870
		pAd->Led3 = 0x5627;
#endif // RT2870 //
	}

	AsicSendCommandToMcu(pAd, 0x52, 0xff, (UCHAR)pAd->Led1, (UCHAR)(pAd->Led1 >> 8));
	AsicSendCommandToMcu(pAd, 0x53, 0xff, (UCHAR)pAd->Led2, (UCHAR)(pAd->Led2 >> 8));
	AsicSendCommandToMcu(pAd, 0x54, 0xff, (UCHAR)pAd->Led3, (UCHAR)(pAd->Led3 >> 8));
    pAd->LedIndicatorStregth = 0xFF;
    RTMPSetSignalLED(pAd, -100);	// Force signal strength Led to be turned off, before link up

#ifdef CONFIG_STA_SUPPORT
	IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
	{
		// Read Hardware controlled Radio state enable bit
		if (NicConfig2.field.HardwareRadioControl == 1)
		{
			pAd->StaCfg.bHardwareRadio = TRUE;

			// Read GPIO pin2 as Hardware controlled radio state
			RTMP_IO_READ32(pAd, GPIO_CTRL_CFG, &data);
			if ((data & 0x04) == 0)
			{
				pAd->StaCfg.bHwRadio = FALSE;
				pAd->StaCfg.bRadio = FALSE;
//				RTMP_IO_WRITE32(pAd, PWR_PIN_CFG, 0x00001818);
				RTMP_SET_FLAG(pAd, fRTMP_ADAPTER_RADIO_OFF);
			}
		}
		else
			pAd->StaCfg.bHardwareRadio = FALSE;

		if (pAd->StaCfg.bRadio == FALSE)
		{
			RTMPSetLED(pAd, LED_RADIO_OFF);
		}
		else
		{
			RTMPSetLED(pAd, LED_RADIO_ON);
		}
	}
#endif // CONFIG_STA_SUPPORT //

	// Turn off patching for cardbus controller
	if (NicConfig2.field.CardbusAcceleration == 1)
	{
//		pAd->bTest1 = TRUE;
	}

	if (NicConfig2.field.DynamicTxAgcControl == 1)
		pAd->bAutoTxAgcA = pAd->bAutoTxAgcG = TRUE;
	else
		pAd->bAutoTxAgcA = pAd->bAutoTxAgcG = FALSE;
	//
	// Since BBP has been progamed, to make sure BBP setting will be
	// upate inside of AsicAntennaSelect, so reset to UNKNOWN_BAND!!
	//
	pAd->CommonCfg.BandState = UNKNOWN_BAND;

	RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R3, &BBPR3);
	BBPR3 &= (~0x18);
	if(pAd->Antenna.field.RxPath == 3)
	{
		BBPR3 |= (0x10);
	}
	else if(pAd->Antenna.field.RxPath == 2)
	{
		BBPR3 |= (0x8);
	}
	else if(pAd->Antenna.field.RxPath == 1)
	{
		BBPR3 |= (0x0);
	}
	RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R3, BBPR3);

#ifdef CONFIG_STA_SUPPORT
	IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
	{
		// Handle the difference when 1T
		RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R1, &BBPR1);
		if(pAd->Antenna.field.TxPath == 1)
		{
		BBPR1 &= (~0x18);
		}
		RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R1, BBPR1);

		DBGPRINT(RT_DEBUG_TRACE, ("Use Hw Radio Control Pin=%d; if used Pin=%d;\n", pAd->CommonCfg.bHardwareRadio, pAd->CommonCfg.bHardwareRadio));
	}
#endif // CONFIG_STA_SUPPORT //
	DBGPRINT(RT_DEBUG_TRACE, ("TxPath = %d, RxPath = %d, RFIC=%d, Polar+LED mode=%x\n", pAd->Antenna.field.TxPath, pAd->Antenna.field.RxPath, pAd->RfIcType, pAd->LedCntl.word));
	DBGPRINT(RT_DEBUG_TRACE, ("<-- NICInitAsicFromEEPROM\n"));
}

/*
	========================================================================

	Routine Description:
		Initialize NIC hardware

	Arguments:
		Adapter						Pointer to our adapter

	Return Value:
		None

	IRQL = PASSIVE_LEVEL

	Note:

	========================================================================
*/
NDIS_STATUS	NICInitializeAdapter(
	IN	PRTMP_ADAPTER	pAd,
	IN   BOOLEAN    bHardReset)
{
	NDIS_STATUS     Status = NDIS_STATUS_SUCCESS;
	WPDMA_GLO_CFG_STRUC	GloCfg;
//	INT_MASK_CSR_STRUC		IntMask;
	ULONG	i =0, j=0;
	AC_TXOP_CSR0_STRUC	csr0;

	DBGPRINT(RT_DEBUG_TRACE, ("--> NICInitializeAdapter\n"));

	// 3. Set DMA global configuration except TX_DMA_EN and RX_DMA_EN bits:
retry:
	i = 0;
	do
	{
		RTMP_IO_READ32(pAd, WPDMA_GLO_CFG, &GloCfg.word);
		if ((GloCfg.field.TxDMABusy == 0)  && (GloCfg.field.RxDMABusy == 0))
			break;

		RTMPusecDelay(1000);
		i++;
	}while ( i<100);
	DBGPRINT(RT_DEBUG_TRACE, ("<== DMA offset 0x208 = 0x%x\n", GloCfg.word));
	GloCfg.word &= 0xff0;
	GloCfg.field.EnTXWriteBackDDONE =1;
	RTMP_IO_WRITE32(pAd, WPDMA_GLO_CFG, GloCfg.word);

	// Record HW Beacon offset
	pAd->BeaconOffset[0] = HW_BEACON_BASE0;
	pAd->BeaconOffset[1] = HW_BEACON_BASE1;
	pAd->BeaconOffset[2] = HW_BEACON_BASE2;
	pAd->BeaconOffset[3] = HW_BEACON_BASE3;
	pAd->BeaconOffset[4] = HW_BEACON_BASE4;
	pAd->BeaconOffset[5] = HW_BEACON_BASE5;
	pAd->BeaconOffset[6] = HW_BEACON_BASE6;
	pAd->BeaconOffset[7] = HW_BEACON_BASE7;

	//
	// write all shared Ring's base address into ASIC
	//

	// asic simulation sequence put this ahead before loading firmware.
	// pbf hardware reset

	// Initialze ASIC for TX & Rx operation
	if (NICInitializeAsic(pAd , bHardReset) != NDIS_STATUS_SUCCESS)
	{
		if (j++ == 0)
		{
			NICLoadFirmware(pAd);
			goto retry;
		}
		return NDIS_STATUS_FAILURE;
	}




	// WMM parameter
	csr0.word = 0;
	RTMP_IO_WRITE32(pAd, WMM_TXOP0_CFG, csr0.word);
	if (pAd->CommonCfg.PhyMode == PHY_11B)
	{
		csr0.field.Ac0Txop = 192;	// AC_VI: 192*32us ~= 6ms
		csr0.field.Ac1Txop = 96;	// AC_VO: 96*32us  ~= 3ms
	}
	else
	{
		csr0.field.Ac0Txop = 96;	// AC_VI: 96*32us ~= 3ms
		csr0.field.Ac1Txop = 48;	// AC_VO: 48*32us ~= 1.5ms
	}
	RTMP_IO_WRITE32(pAd, WMM_TXOP1_CFG, csr0.word);




	// reset action
	// Load firmware
	//  Status = NICLoadFirmware(pAd);

	DBGPRINT(RT_DEBUG_TRACE, ("<-- NICInitializeAdapter\n"));
	return Status;
}

/*
	========================================================================

	Routine Description:
		Initialize ASIC

	Arguments:
		Adapter						Pointer to our adapter

	Return Value:
		None

	IRQL = PASSIVE_LEVEL

	Note:

	========================================================================
*/
NDIS_STATUS	NICInitializeAsic(
	IN	PRTMP_ADAPTER	pAd,
	IN  BOOLEAN		bHardReset)
{
	ULONG			Index = 0;
	UCHAR			R0 = 0xff;
	UINT32			MacCsr12 = 0, Counter = 0;
#ifdef RT2870
	UINT32			MacCsr0 = 0;
	NTSTATUS		Status;
	UCHAR			Value = 0xff;
#endif // RT2870 //
#ifdef RT30xx
	UINT32			eFuseCtrl;
#endif // RT30xx //
	USHORT			KeyIdx;
	INT				i,apidx;

	DBGPRINT(RT_DEBUG_TRACE, ("--> NICInitializeAsic\n"));


#ifdef RT2870
	//
	// Make sure MAC gets ready after NICLoadFirmware().
	//
	Index = 0;

	//To avoid hang-on issue when interface up in kernel 2.4,
	//we use a local variable "MacCsr0" instead of using "pAd->MACVersion" directly.
	do
	{
		RTMP_IO_READ32(pAd, MAC_CSR0, &MacCsr0);

		if ((MacCsr0 != 0x00) && (MacCsr0 != 0xFFFFFFFF))
			break;

		RTMPusecDelay(10);
	} while (Index++ < 100);

	pAd->MACVersion = MacCsr0;
	DBGPRINT(RT_DEBUG_TRACE, ("MAC_CSR0  [ Ver:Rev=0x%08x]\n", pAd->MACVersion));
	// turn on bit13 (set to zero) after rt2860D. This is to solve high-current issue.
	RTMP_IO_READ32(pAd, PBF_SYS_CTRL, &MacCsr12);
	MacCsr12 &= (~0x2000);
	RTMP_IO_WRITE32(pAd, PBF_SYS_CTRL, MacCsr12);

	RTMP_IO_WRITE32(pAd, MAC_SYS_CTRL, 0x3);
	RTMP_IO_WRITE32(pAd, USB_DMA_CFG, 0x0);
	Status = RTUSBVenderReset(pAd);

	RTMP_IO_WRITE32(pAd, MAC_SYS_CTRL, 0x0);

	// Initialize MAC register to default value
	for(Index=0; Index<NUM_MAC_REG_PARMS; Index++)
	{
#ifdef RT3070
		if ((MACRegTable[Index].Register == TX_SW_CFG0) && (IS_RT3070(pAd) || IS_RT3071(pAd)))
		{
			MACRegTable[Index].Value = 0x00000400;
		}
#endif // RT3070 //
		RTMP_IO_WRITE32(pAd, (USHORT)MACRegTable[Index].Register, MACRegTable[Index].Value);
	}


#ifdef CONFIG_STA_SUPPORT
	IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
	{
		for (Index = 0; Index < NUM_STA_MAC_REG_PARMS; Index++)
		{
			RTMP_IO_WRITE32(pAd, (USHORT)STAMACRegTable[Index].Register, STAMACRegTable[Index].Value);
		}
	}
#endif // CONFIG_STA_SUPPORT //
#endif // RT2870 //

#ifdef RT30xx
	// Initialize RT3070 serial MAc registers which is different from RT2870 serial
	if (IS_RT3090(pAd))
	{
		RTMP_IO_WRITE32(pAd, TX_SW_CFG1, 0);

		// RT3071 version E has fixed this issue
		if ((pAd->MACVersion & 0xffff) < 0x0211)
		{
			if (pAd->NicConfig2.field.DACTestBit == 1)
			{
				RTMP_IO_WRITE32(pAd, TX_SW_CFG2, 0x1F);	// To fix throughput drop drastically
			}
			else
			{
				RTMP_IO_WRITE32(pAd, TX_SW_CFG2, 0x0F);	// To fix throughput drop drastically
			}
		}
		else
		{
			RTMP_IO_WRITE32(pAd, TX_SW_CFG2, 0x0);
		}
	}
	else if (IS_RT3070(pAd))
	{
		RTMP_IO_WRITE32(pAd, TX_SW_CFG1, 0);
		RTMP_IO_WRITE32(pAd, TX_SW_CFG2, 0x1F);	// To fix throughput drop drastically
	}
#endif // RT30xx //

	//
	// Before program BBP, we need to wait BBP/RF get wake up.
	//
	Index = 0;
	do
	{
		RTMP_IO_READ32(pAd, MAC_STATUS_CFG, &MacCsr12);

		if ((MacCsr12 & 0x03) == 0)	// if BB.RF is stable
			break;

		DBGPRINT(RT_DEBUG_TRACE, ("Check MAC_STATUS_CFG  = Busy = %x\n", MacCsr12));
		RTMPusecDelay(1000);
	} while (Index++ < 100);

    // The commands to firmware should be after these commands, these commands will init firmware
	// PCI and USB are not the same because PCI driver needs to wait for PCI bus ready
	RTMP_IO_WRITE32(pAd, H2M_BBP_AGENT, 0);	// initialize BBP R/W access agent
	RTMP_IO_WRITE32(pAd, H2M_MAILBOX_CSR, 0);
	RTMPusecDelay(1000);

	// Read BBP register, make sure BBP is up and running before write new data
	Index = 0;
	do
	{
		RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R0, &R0);
		DBGPRINT(RT_DEBUG_TRACE, ("BBP version = %x\n", R0));
	} while ((++Index < 20) && ((R0 == 0xff) || (R0 == 0x00)));
	//ASSERT(Index < 20); //this will cause BSOD on Check-build driver

	if ((R0 == 0xff) || (R0 == 0x00))
		return NDIS_STATUS_FAILURE;

	// Initialize BBP register to default value
	for (Index = 0; Index < NUM_BBP_REG_PARMS; Index++)
	{
		RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBPRegTable[Index].Register, BBPRegTable[Index].Value);
	}

	// for rt2860E and after, init BBP_R84 with 0x19. This is for extension channel overlapping IOT.
	// RT3090 should not program BBP R84 to 0x19, otherwise TX will block.
	if (((pAd->MACVersion&0xffff) != 0x0101) && (!IS_RT30xx(pAd)))
		RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R84, 0x19);

// add by johnli, RF power sequence setup
#ifdef RT30xx
	if (IS_RT30xx(pAd))
	{	//update for RT3070/71/72/90/91/92.
		RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R79, 0x13);
		RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R80, 0x05);
		RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R81, 0x33);
	}

	if (IS_RT3090(pAd))
	{
		UCHAR		bbpreg=0;

		// enable DC filter
		if ((pAd->MACVersion & 0xffff) >= 0x0211)
		{
			RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R103, 0xc0);
		}

		// improve power consumption
		RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R138, &bbpreg);
		if (pAd->Antenna.field.TxPath == 1)
		{
			// turn off tx DAC_1
			bbpreg = (bbpreg | 0x20);
		}

		if (pAd->Antenna.field.RxPath == 1)
		{
			// turn off tx ADC_1
			bbpreg &= (~0x2);
		}
		RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R138, bbpreg);

		// improve power consumption in RT3071 Ver.E
		if ((pAd->MACVersion & 0xffff) >= 0x0211)
		{
			RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R31, &bbpreg);
			bbpreg &= (~0x3);
			RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R31, bbpreg);
		}
	}
#endif // RT30xx //
// end johnli

	if (pAd->MACVersion == 0x28600100)
	{
		RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R69, 0x16);
		RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R73, 0x12);
    }

	if (pAd->MACVersion >= RALINK_2880E_VERSION && pAd->MACVersion < RALINK_3070_VERSION) // 3*3
	{
		// enlarge MAX_LEN_CFG
		UINT32 csr;
		RTMP_IO_READ32(pAd, MAX_LEN_CFG, &csr);
		csr &= 0xFFF;
		csr |= 0x2000;
		RTMP_IO_WRITE32(pAd, MAX_LEN_CFG, csr);
	}

#ifdef RT2870
{
	UCHAR	MAC_Value[]={0xff,0xff,0xff,0xff,0xff,0xff,0xff,0,0};

	//Initialize WCID table
	Value = 0xff;
	for(Index =0 ;Index < 254;Index++)
	{
		RTUSBMultiWrite(pAd, (USHORT)(MAC_WCID_BASE + Index * 8), MAC_Value, 8);
	}
}
#endif // RT2870 //

	// Add radio off control
#ifdef CONFIG_STA_SUPPORT
	IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
	{
		if (pAd->StaCfg.bRadio == FALSE)
		{
//			RTMP_IO_WRITE32(pAd, PWR_PIN_CFG, 0x00001818);
			RTMP_SET_FLAG(pAd, fRTMP_ADAPTER_RADIO_OFF);
			DBGPRINT(RT_DEBUG_TRACE, ("Set Radio Off\n"));
		}
	}
#endif // CONFIG_STA_SUPPORT //

	// Clear raw counters
	RTMP_IO_READ32(pAd, RX_STA_CNT0, &Counter);
	RTMP_IO_READ32(pAd, RX_STA_CNT1, &Counter);
	RTMP_IO_READ32(pAd, RX_STA_CNT2, &Counter);
	RTMP_IO_READ32(pAd, TX_STA_CNT0, &Counter);
	RTMP_IO_READ32(pAd, TX_STA_CNT1, &Counter);
	RTMP_IO_READ32(pAd, TX_STA_CNT2, &Counter);

	// ASIC will keep garbage value after boot
	// Clear all seared key table when initial
	// This routine can be ignored in radio-ON/OFF operation.
	if (bHardReset)
	{
		for (KeyIdx = 0; KeyIdx < 4; KeyIdx++)
		{
			RTMP_IO_WRITE32(pAd, SHARED_KEY_MODE_BASE + 4*KeyIdx, 0);
		}

	// Clear all pairwise key table when initial
	for (KeyIdx = 0; KeyIdx < 256; KeyIdx++)
	{
		RTMP_IO_WRITE32(pAd, MAC_WCID_ATTRIBUTE_BASE + (KeyIdx * HW_WCID_ATTRI_SIZE), 1);
	}
	}

	// assert HOST ready bit
//  RTMP_IO_WRITE32(pAd, MAC_CSR1, 0x0); // 2004-09-14 asked by Mark
//  RTMP_IO_WRITE32(pAd, MAC_CSR1, 0x4);

	// It isn't necessary to clear this space when not hard reset.
	if (bHardReset == TRUE)
	{
		// clear all on-chip BEACON frame space
		for (apidx = 0; apidx < HW_BEACON_MAX_COUNT; apidx++)
		{
			for (i = 0; i < HW_BEACON_OFFSET>>2; i+=4)
				RTMP_IO_WRITE32(pAd, pAd->BeaconOffset[apidx] + i, 0x00);
		}
	}
#ifdef RT2870
	AsicDisableSync(pAd);
	// Clear raw counters
	RTMP_IO_READ32(pAd, RX_STA_CNT0, &Counter);
	RTMP_IO_READ32(pAd, RX_STA_CNT1, &Counter);
	RTMP_IO_READ32(pAd, RX_STA_CNT2, &Counter);
	RTMP_IO_READ32(pAd, TX_STA_CNT0, &Counter);
	RTMP_IO_READ32(pAd, TX_STA_CNT1, &Counter);
	RTMP_IO_READ32(pAd, TX_STA_CNT2, &Counter);
	// Default PCI clock cycle per ms is different as default setting, which is based on PCI.
	RTMP_IO_READ32(pAd, USB_CYC_CFG, &Counter);
	Counter&=0xffffff00;
	Counter|=0x000001e;
	RTMP_IO_WRITE32(pAd, USB_CYC_CFG, Counter);
#endif // RT2870 //
#ifdef RT30xx
	pAd->bUseEfuse=FALSE;
	RTMP_IO_READ32(pAd, EFUSE_CTRL, &eFuseCtrl);
	pAd->bUseEfuse = ( (eFuseCtrl & 0x80000000) == 0x80000000) ? 1 : 0;
	if(pAd->bUseEfuse)
	{
			DBGPRINT(RT_DEBUG_TRACE, ("NVM is Efuse\n"));
	}
	else
	{
			DBGPRINT(RT_DEBUG_TRACE, ("NVM is EEPROM\n"));

	}
#endif // RT30xx //

#ifdef CONFIG_STA_SUPPORT
	IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
	{
		// for rt2860E and after, init TXOP_CTRL_CFG with 0x583f. This is for extension channel overlapping IOT.
		if ((pAd->MACVersion&0xffff) != 0x0101)
			RTMP_IO_WRITE32(pAd, TXOP_CTRL_CFG, 0x583f);
	}
#endif // CONFIG_STA_SUPPORT //

	DBGPRINT(RT_DEBUG_TRACE, ("<-- NICInitializeAsic\n"));
	return NDIS_STATUS_SUCCESS;
}

/*
	========================================================================

	Routine Description:
		Reset NIC Asics

	Arguments:
		Adapter						Pointer to our adapter

	Return Value:
		None

	IRQL = PASSIVE_LEVEL

	Note:
		Reset NIC to initial state AS IS system boot up time.

	========================================================================
*/
VOID	NICIssueReset(
	IN	PRTMP_ADAPTER	pAd)
{
	UINT32	Value = 0;
	DBGPRINT(RT_DEBUG_TRACE, ("--> NICIssueReset\n"));

	// Abort Tx, prevent ASIC from writing to Host memory
	//RTMP_IO_WRITE32(pAd, TX_CNTL_CSR, 0x001f0000);

	// Disable Rx, register value supposed will remain after reset
	RTMP_IO_READ32(pAd, MAC_SYS_CTRL, &Value);
	Value &= (0xfffffff3);
	RTMP_IO_WRITE32(pAd, MAC_SYS_CTRL, Value);

	// Issue reset and clear from reset state
	RTMP_IO_WRITE32(pAd, MAC_SYS_CTRL, 0x03); // 2004-09-17 change from 0x01
	RTMP_IO_WRITE32(pAd, MAC_SYS_CTRL, 0x00);

	DBGPRINT(RT_DEBUG_TRACE, ("<-- NICIssueReset\n"));
}

/*
	========================================================================

	Routine Description:
		Check ASIC registers and find any reason the system might hang

	Arguments:
		Adapter						Pointer to our adapter

	Return Value:
		None

	IRQL = DISPATCH_LEVEL

	========================================================================
*/
BOOLEAN	NICCheckForHang(
	IN	PRTMP_ADAPTER	pAd)
{
	return (FALSE);
}

VOID NICUpdateFifoStaCounters(
	IN PRTMP_ADAPTER pAd)
{
	TX_STA_FIFO_STRUC	StaFifo;
	MAC_TABLE_ENTRY		*pEntry;
	UCHAR				i = 0;
	UCHAR			pid = 0, wcid = 0;
	CHAR				reTry;
	UCHAR				succMCS;

#ifdef RALINK_ATE
	/* Nothing to do in ATE mode */
	if (ATE_ON(pAd))
		return;
#endif // RALINK_ATE //

		do
		{
			RTMP_IO_READ32(pAd, TX_STA_FIFO, &StaFifo.word);

			if (StaFifo.field.bValid == 0)
				break;

			wcid = (UCHAR)StaFifo.field.wcid;


		/* ignore NoACK and MGMT frame use 0xFF as WCID */
			if ((StaFifo.field.TxAckRequired == 0) || (wcid >= MAX_LEN_OF_MAC_TABLE))
			{
				i++;
				continue;
			}

			/* PID store Tx MCS Rate */
			pid = (UCHAR)StaFifo.field.PidType;

			pEntry = &pAd->MacTab.Content[wcid];

			pEntry->DebugFIFOCount++;

#ifdef DOT11_N_SUPPORT
			if (StaFifo.field.TxBF) // 3*3
				pEntry->TxBFCount++;
#endif // DOT11_N_SUPPORT //

#ifdef UAPSD_AP_SUPPORT
			UAPSD_SP_AUE_Handle(pAd, pEntry, StaFifo.field.TxSuccess);
#endif // UAPSD_AP_SUPPORT //

			if (!StaFifo.field.TxSuccess)
			{
				pEntry->FIFOCount++;
				pEntry->OneSecTxFailCount++;

				if (pEntry->FIFOCount >= 1)
				{
					DBGPRINT(RT_DEBUG_TRACE, ("#"));
#ifdef DOT11_N_SUPPORT
					pEntry->NoBADataCountDown = 64;
#endif // DOT11_N_SUPPORT //

					if(pEntry->PsMode == PWR_ACTIVE)
					{
#ifdef DOT11_N_SUPPORT
						int tid;
						for (tid=0; tid<NUM_OF_TID; tid++)
						{
							BAOriSessionTearDown(pAd, pEntry->Aid,  tid, FALSE, FALSE);
						}
#endif // DOT11_N_SUPPORT //

						// Update the continuous transmission counter except PS mode
						pEntry->ContinueTxFailCnt++;
					}
					else
					{
						// Clear the FIFOCount when sta in Power Save mode. Basically we assume
						//     this tx error happened due to sta just go to sleep.
						pEntry->FIFOCount = 0;
						pEntry->ContinueTxFailCnt = 0;
					}
					//pEntry->FIFOCount = 0;
				}
				//pEntry->bSendBAR = TRUE;
			}
			else
			{
#ifdef DOT11_N_SUPPORT
				if ((pEntry->PsMode != PWR_SAVE) && (pEntry->NoBADataCountDown > 0))
				{
					pEntry->NoBADataCountDown--;
					if (pEntry->NoBADataCountDown==0)
					{
						DBGPRINT(RT_DEBUG_TRACE, ("@\n"));
					}
				}
#endif // DOT11_N_SUPPORT //
				pEntry->FIFOCount = 0;
				pEntry->OneSecTxNoRetryOkCount++;
				// update NoDataIdleCount when sucessful send packet to STA.
				pEntry->NoDataIdleCount = 0;
				pEntry->ContinueTxFailCnt = 0;
			}

			succMCS = StaFifo.field.SuccessRate & 0x7F;

			reTry = pid - succMCS;

			if (StaFifo.field.TxSuccess)
			{
				pEntry->TXMCSExpected[pid]++;
				if (pid == succMCS)
				{
					pEntry->TXMCSSuccessful[pid]++;
				}
				else
				{
					pEntry->TXMCSAutoFallBack[pid][succMCS]++;
				}
			}
			else
			{
				pEntry->TXMCSFailed[pid]++;
			}

			if (reTry > 0)
			{
				if ((pid >= 12) && succMCS <=7)
				{
					reTry -= 4;
				}
				pEntry->OneSecTxRetryOkCount += reTry;
			}

			i++;
			// ASIC store 16 stack
		} while ( i < (2*TX_RING_SIZE) );

}

/*
	========================================================================

	Routine Description:
		Read statistical counters from hardware registers and record them
		in software variables for later on query

	Arguments:
		pAd					Pointer to our adapter

	Return Value:
		None

	IRQL = DISPATCH_LEVEL

	========================================================================
*/
VOID NICUpdateRawCounters(
	IN PRTMP_ADAPTER pAd)
{
	UINT32	OldValue;//, Value2;
	//ULONG	PageSum, OneSecTransmitCount;
	//ULONG	TxErrorRatio, Retry, Fail;
	RX_STA_CNT0_STRUC	 RxStaCnt0;
	RX_STA_CNT1_STRUC   RxStaCnt1;
	RX_STA_CNT2_STRUC   RxStaCnt2;
	TX_STA_CNT0_STRUC 	 TxStaCnt0;
	TX_STA_CNT1_STRUC	 StaTx1;
	TX_STA_CNT2_STRUC	 StaTx2;
	TX_AGG_CNT_STRUC	TxAggCnt;
	TX_AGG_CNT0_STRUC	TxAggCnt0;
	TX_AGG_CNT1_STRUC	TxAggCnt1;
	TX_AGG_CNT2_STRUC	TxAggCnt2;
	TX_AGG_CNT3_STRUC	TxAggCnt3;
	TX_AGG_CNT4_STRUC	TxAggCnt4;
	TX_AGG_CNT5_STRUC	TxAggCnt5;
	TX_AGG_CNT6_STRUC	TxAggCnt6;
	TX_AGG_CNT7_STRUC	TxAggCnt7;

	RTMP_IO_READ32(pAd, RX_STA_CNT0, &RxStaCnt0.word);
	RTMP_IO_READ32(pAd, RX_STA_CNT2, &RxStaCnt2.word);

	{
		RTMP_IO_READ32(pAd, RX_STA_CNT1, &RxStaCnt1.word);
	    // Update RX PLCP error counter
	    pAd->PrivateInfo.PhyRxErrCnt += RxStaCnt1.field.PlcpErr;
		// Update False CCA counter
		pAd->RalinkCounters.OneSecFalseCCACnt += RxStaCnt1.field.FalseCca;
	}

	// Update FCS counters
	OldValue= pAd->WlanCounters.FCSErrorCount.u.LowPart;
	pAd->WlanCounters.FCSErrorCount.u.LowPart += (RxStaCnt0.field.CrcErr); // >> 7);
	if (pAd->WlanCounters.FCSErrorCount.u.LowPart < OldValue)
		pAd->WlanCounters.FCSErrorCount.u.HighPart++;

	// Add FCS error count to private counters
	pAd->RalinkCounters.OneSecRxFcsErrCnt += RxStaCnt0.field.CrcErr;
	OldValue = pAd->RalinkCounters.RealFcsErrCount.u.LowPart;
	pAd->RalinkCounters.RealFcsErrCount.u.LowPart += RxStaCnt0.field.CrcErr;
	if (pAd->RalinkCounters.RealFcsErrCount.u.LowPart < OldValue)
		pAd->RalinkCounters.RealFcsErrCount.u.HighPart++;

	// Update Duplicate Rcv check
	pAd->RalinkCounters.DuplicateRcv += RxStaCnt2.field.RxDupliCount;
	pAd->WlanCounters.FrameDuplicateCount.u.LowPart += RxStaCnt2.field.RxDupliCount;
	// Update RX Overflow counter
	pAd->Counters8023.RxNoBuffer += (RxStaCnt2.field.RxFifoOverflowCount);

	//pAd->RalinkCounters.RxCount = 0;
#ifdef RT2870
	if (pAd->RalinkCounters.RxCount != pAd->watchDogRxCnt)
	{
		pAd->watchDogRxCnt = pAd->RalinkCounters.RxCount;
		pAd->watchDogRxOverFlowCnt = 0;
	}
	else
	{
		if (RxStaCnt2.field.RxFifoOverflowCount)
			pAd->watchDogRxOverFlowCnt++;
		else
			pAd->watchDogRxOverFlowCnt = 0;
	}
#endif // RT2870 //


	//if (!OPSTATUS_TEST_FLAG(pAd, fOP_STATUS_TX_RATE_SWITCH_ENABLED) ||
	//	(OPSTATUS_TEST_FLAG(pAd, fOP_STATUS_TX_RATE_SWITCH_ENABLED) && (pAd->MacTab.Size != 1)))
	if (!pAd->bUpdateBcnCntDone)
	{
	// Update BEACON sent count
	RTMP_IO_READ32(pAd, TX_STA_CNT0, &TxStaCnt0.word);
	RTMP_IO_READ32(pAd, TX_STA_CNT1, &StaTx1.word);
	RTMP_IO_READ32(pAd, TX_STA_CNT2, &StaTx2.word);
	pAd->RalinkCounters.OneSecBeaconSentCnt += TxStaCnt0.field.TxBeaconCount;
	pAd->RalinkCounters.OneSecTxRetryOkCount += StaTx1.field.TxRetransmit;
	pAd->RalinkCounters.OneSecTxNoRetryOkCount += StaTx1.field.TxSuccess;
	pAd->RalinkCounters.OneSecTxFailCount += TxStaCnt0.field.TxFailCount;
	pAd->WlanCounters.TransmittedFragmentCount.u.LowPart += StaTx1.field.TxSuccess;
	pAd->WlanCounters.RetryCount.u.LowPart += StaTx1.field.TxRetransmit;
	pAd->WlanCounters.FailedCount.u.LowPart += TxStaCnt0.field.TxFailCount;
	}

	//if (pAd->bStaFifoTest == TRUE)
	{
		RTMP_IO_READ32(pAd, TX_AGG_CNT, &TxAggCnt.word);
		RTMP_IO_READ32(pAd, TX_AGG_CNT0, &TxAggCnt0.word);
		RTMP_IO_READ32(pAd, TX_AGG_CNT1, &TxAggCnt1.word);
		RTMP_IO_READ32(pAd, TX_AGG_CNT2, &TxAggCnt2.word);
		RTMP_IO_READ32(pAd, TX_AGG_CNT3, &TxAggCnt3.word);
		RTMP_IO_READ32(pAd, TX_AGG_CNT4, &TxAggCnt4.word);
		RTMP_IO_READ32(pAd, TX_AGG_CNT5, &TxAggCnt5.word);
		RTMP_IO_READ32(pAd, TX_AGG_CNT6, &TxAggCnt6.word);
		RTMP_IO_READ32(pAd, TX_AGG_CNT7, &TxAggCnt7.word);
		pAd->RalinkCounters.TxAggCount += TxAggCnt.field.AggTxCount;
		pAd->RalinkCounters.TxNonAggCount += TxAggCnt.field.NonAggTxCount;
		pAd->RalinkCounters.TxAgg1MPDUCount += TxAggCnt0.field.AggSize1Count;
		pAd->RalinkCounters.TxAgg2MPDUCount += TxAggCnt0.field.AggSize2Count;

		pAd->RalinkCounters.TxAgg3MPDUCount += TxAggCnt1.field.AggSize3Count;
		pAd->RalinkCounters.TxAgg4MPDUCount += TxAggCnt1.field.AggSize4Count;
		pAd->RalinkCounters.TxAgg5MPDUCount += TxAggCnt2.field.AggSize5Count;
		pAd->RalinkCounters.TxAgg6MPDUCount += TxAggCnt2.field.AggSize6Count;

		pAd->RalinkCounters.TxAgg7MPDUCount += TxAggCnt3.field.AggSize7Count;
		pAd->RalinkCounters.TxAgg8MPDUCount += TxAggCnt3.field.AggSize8Count;
		pAd->RalinkCounters.TxAgg9MPDUCount += TxAggCnt4.field.AggSize9Count;
		pAd->RalinkCounters.TxAgg10MPDUCount += TxAggCnt4.field.AggSize10Count;

		pAd->RalinkCounters.TxAgg11MPDUCount += TxAggCnt5.field.AggSize11Count;
		pAd->RalinkCounters.TxAgg12MPDUCount += TxAggCnt5.field.AggSize12Count;
		pAd->RalinkCounters.TxAgg13MPDUCount += TxAggCnt6.field.AggSize13Count;
		pAd->RalinkCounters.TxAgg14MPDUCount += TxAggCnt6.field.AggSize14Count;

		pAd->RalinkCounters.TxAgg15MPDUCount += TxAggCnt7.field.AggSize15Count;
		pAd->RalinkCounters.TxAgg16MPDUCount += TxAggCnt7.field.AggSize16Count;

		// Calculate the transmitted A-MPDU count
		pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += TxAggCnt0.field.AggSize1Count;
		pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt0.field.AggSize2Count / 2);

		pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt1.field.AggSize3Count / 3);
		pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt1.field.AggSize4Count / 4);

		pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt2.field.AggSize5Count / 5);
		pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt2.field.AggSize6Count / 6);

		pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt3.field.AggSize7Count / 7);
		pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt3.field.AggSize8Count / 8);

		pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt4.field.AggSize9Count / 9);
		pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt4.field.AggSize10Count / 10);

		pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt5.field.AggSize11Count / 11);
		pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt5.field.AggSize12Count / 12);

		pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt6.field.AggSize13Count / 13);
		pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt6.field.AggSize14Count / 14);

		pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt7.field.AggSize15Count / 15);
		pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt7.field.AggSize16Count / 16);
	}

#ifdef DBG_DIAGNOSE
	{
		RtmpDiagStruct	*pDiag;
		COUNTER_RALINK	*pRalinkCounters;
		UCHAR			ArrayCurIdx, i;

		pDiag = &pAd->DiagStruct;
		pRalinkCounters = &pAd->RalinkCounters;
		ArrayCurIdx = pDiag->ArrayCurIdx;

		if (pDiag->inited == 0)
		{
			NdisZeroMemory(pDiag, sizeof(struct _RtmpDiagStrcut_));
			pDiag->ArrayStartIdx = pDiag->ArrayCurIdx = 0;
			pDiag->inited = 1;
		}
		else
		{
			// Tx
			pDiag->TxFailCnt[ArrayCurIdx] = TxStaCnt0.field.TxFailCount;
			pDiag->TxAggCnt[ArrayCurIdx] = TxAggCnt.field.AggTxCount;
			pDiag->TxNonAggCnt[ArrayCurIdx] = TxAggCnt.field.NonAggTxCount;
			pDiag->TxAMPDUCnt[ArrayCurIdx][0] = TxAggCnt0.field.AggSize1Count;
			pDiag->TxAMPDUCnt[ArrayCurIdx][1] = TxAggCnt0.field.AggSize2Count;
			pDiag->TxAMPDUCnt[ArrayCurIdx][2] = TxAggCnt1.field.AggSize3Count;
			pDiag->TxAMPDUCnt[ArrayCurIdx][3] = TxAggCnt1.field.AggSize4Count;
			pDiag->TxAMPDUCnt[ArrayCurIdx][4] = TxAggCnt2.field.AggSize5Count;
			pDiag->TxAMPDUCnt[ArrayCurIdx][5] = TxAggCnt2.field.AggSize6Count;
			pDiag->TxAMPDUCnt[ArrayCurIdx][6] = TxAggCnt3.field.AggSize7Count;
			pDiag->TxAMPDUCnt[ArrayCurIdx][7] = TxAggCnt3.field.AggSize8Count;
			pDiag->TxAMPDUCnt[ArrayCurIdx][8] = TxAggCnt4.field.AggSize9Count;
			pDiag->TxAMPDUCnt[ArrayCurIdx][9] = TxAggCnt4.field.AggSize10Count;
			pDiag->TxAMPDUCnt[ArrayCurIdx][10] = TxAggCnt5.field.AggSize11Count;
			pDiag->TxAMPDUCnt[ArrayCurIdx][11] = TxAggCnt5.field.AggSize12Count;
			pDiag->TxAMPDUCnt[ArrayCurIdx][12] = TxAggCnt6.field.AggSize13Count;
			pDiag->TxAMPDUCnt[ArrayCurIdx][13] = TxAggCnt6.field.AggSize14Count;
			pDiag->TxAMPDUCnt[ArrayCurIdx][14] = TxAggCnt7.field.AggSize15Count;
			pDiag->TxAMPDUCnt[ArrayCurIdx][15] = TxAggCnt7.field.AggSize16Count;

			pDiag->RxCrcErrCnt[ArrayCurIdx] = RxStaCnt0.field.CrcErr;

			INC_RING_INDEX(pDiag->ArrayCurIdx,  DIAGNOSE_TIME);
			ArrayCurIdx = pDiag->ArrayCurIdx;
			for (i =0; i < 9; i++)
			{
				pDiag->TxDescCnt[ArrayCurIdx][i]= 0;
				pDiag->TxSWQueCnt[ArrayCurIdx][i] =0;
				pDiag->TxMcsCnt[ArrayCurIdx][i] = 0;
				pDiag->RxMcsCnt[ArrayCurIdx][i] = 0;
			}
			pDiag->TxDataCnt[ArrayCurIdx] = 0;
			pDiag->TxFailCnt[ArrayCurIdx] = 0;
			pDiag->RxDataCnt[ArrayCurIdx] = 0;
			pDiag->RxCrcErrCnt[ArrayCurIdx]  = 0;
//			for (i = 9; i < 16; i++)
			for (i = 9; i < 24; i++) // 3*3
			{
				pDiag->TxDescCnt[ArrayCurIdx][i] = 0;
				pDiag->TxMcsCnt[ArrayCurIdx][i] = 0;
				pDiag->RxMcsCnt[ArrayCurIdx][i] = 0;
}

			if (pDiag->ArrayCurIdx == pDiag->ArrayStartIdx)
				INC_RING_INDEX(pDiag->ArrayStartIdx,  DIAGNOSE_TIME);
		}

	}
#endif // DBG_DIAGNOSE //


}


/*
	========================================================================

	Routine Description:
		Reset NIC from error

	Arguments:
		Adapter						Pointer to our adapter

	Return Value:
		None

	IRQL = PASSIVE_LEVEL

	Note:
		Reset NIC from error state

	========================================================================
*/
VOID	NICResetFromError(
	IN	PRTMP_ADAPTER	pAd)
{
	// Reset BBP (according to alex, reset ASIC will force reset BBP
	// Therefore, skip the reset BBP
	// RTMP_IO_WRITE32(pAd, MAC_CSR1, 0x2);

	RTMP_IO_WRITE32(pAd, MAC_SYS_CTRL, 0x1);
	// Remove ASIC from reset state
	RTMP_IO_WRITE32(pAd, MAC_SYS_CTRL, 0x0);

	NICInitializeAdapter(pAd, FALSE);
	NICInitAsicFromEEPROM(pAd);

	// Switch to current channel, since during reset process, the connection should remains on.
	AsicSwitchChannel(pAd, pAd->CommonCfg.CentralChannel, FALSE);
	AsicLockChannel(pAd, pAd->CommonCfg.CentralChannel);
}

/*
	========================================================================

	Routine Description:
		erase 8051 firmware image in MAC ASIC

	Arguments:
		Adapter						Pointer to our adapter

	IRQL = PASSIVE_LEVEL

	========================================================================
*/
VOID NICEraseFirmware(
	IN PRTMP_ADAPTER pAd)
{
	ULONG i;

	for(i=0; i<MAX_FIRMWARE_IMAGE_SIZE; i+=4)
		RTMP_IO_WRITE32(pAd, FIRMWARE_IMAGE_BASE + i, 0);

}/* End of NICEraseFirmware */

/*
	========================================================================

	Routine Description:
		Load 8051 firmware RT2561.BIN file into MAC ASIC

	Arguments:
		Adapter						Pointer to our adapter

	Return Value:
		NDIS_STATUS_SUCCESS         firmware image load ok
		NDIS_STATUS_FAILURE         image not found

	IRQL = PASSIVE_LEVEL

	========================================================================
*/
NDIS_STATUS NICLoadFirmware(
	IN PRTMP_ADAPTER pAd)
{
#ifdef BIN_IN_FILE
#define NICLF_DEFAULT_USE()	\
	flg_default_firm_use = TRUE; \
	printk("%s - Use default firmware!\n", __FUNCTION__);

	NDIS_STATUS		Status = NDIS_STATUS_SUCCESS;
	PUCHAR			src;
	struct file		*srcf;
	INT 			retval, orgfsuid, orgfsgid, i;
   	mm_segment_t	orgfs;
	PUCHAR			pFirmwareImage;
	UINT			FileLength = 0;
	UINT32			MacReg;
	ULONG			Index;
	ULONG			firm;
	BOOLEAN			flg_default_firm_use = FALSE;


	DBGPRINT(RT_DEBUG_TRACE, ("===> %s\n", __FUNCTION__));

	/* init */
	pFirmwareImage = NULL;
	src = RTMP_FIRMWARE_FILE_NAME;

	/* save uid and gid used for filesystem access.
	   set user and group to 0 (root) */
	orgfsuid = current->fsuid;
	orgfsgid = current->fsgid;
	current->fsuid = current->fsgid = 0;
    orgfs = get_fs();
    set_fs(KERNEL_DS);

	pAd->FirmwareVersion = (FIRMWARE_MAJOR_VERSION << 8) + \
						   FIRMWARE_MINOR_VERSION;


	/* allocate firmware buffer */
    pFirmwareImage = kmalloc(MAX_FIRMWARE_IMAGE_SIZE, MEM_ALLOC_FLAG);
    if (pFirmwareImage == NULL)
	{
		/* allocate fail, use default firmware array in firmware.h */
		printk("%s - Allocate memory fail!\n", __FUNCTION__);
		NICLF_DEFAULT_USE();
    }
	else
	{
		/* allocate ok! zero the firmware buffer */
		memset(pFirmwareImage, 0x00, MAX_FIRMWARE_IMAGE_SIZE);
	} /* End of if */


	/* if ok, read firmware file from *.bin file */
	if (flg_default_firm_use == FALSE)
	{
		do
		{
			/* open the bin file */
			srcf = filp_open(src, O_RDONLY, 0);

			if (IS_ERR(srcf))
			{
				printk("%s - Error %ld opening %s\n",
					   __FUNCTION__, -PTR_ERR(srcf), src);
				NICLF_DEFAULT_USE();
				break;
			} /* End of if */

			/* the object must have a read method */
			if ((srcf->f_op == NULL) || (srcf->f_op->read == NULL))
			{
				printk("%s - %s does not have a write method\n", __FUNCTION__, src);
				NICLF_DEFAULT_USE();
				break;
			} /* End of if */

			/* read the firmware from the file *.bin */
			FileLength = srcf->f_op->read(srcf,
										  pFirmwareImage,
										  MAX_FIRMWARE_IMAGE_SIZE,
										  &srcf->f_pos);

			if (FileLength != MAX_FIRMWARE_IMAGE_SIZE)
			{
				printk("%s: error file length (=%d) in RT2860AP.BIN\n",
					   __FUNCTION__, FileLength);
				NICLF_DEFAULT_USE();
				break;
			}
			else
			{
				PUCHAR ptr = pFirmwareImage;
				USHORT crc = 0xffff;


				/* calculate firmware CRC */
				for(i=0; i<(MAX_FIRMWARE_IMAGE_SIZE-2); i++, ptr++)
					crc = ByteCRC16(BitReverse(*ptr), crc);
				/* End of for */

				if ((pFirmwareImage[MAX_FIRMWARE_IMAGE_SIZE-2] != \
								(UCHAR)BitReverse((UCHAR)(crc>>8))) ||
					(pFirmwareImage[MAX_FIRMWARE_IMAGE_SIZE-1] != \
								(UCHAR)BitReverse((UCHAR)crc)))
				{
					/* CRC fail */
					printk("%s: CRC = 0x%02x 0x%02x "
						   "error, should be 0x%02x 0x%02x\n",
						   __FUNCTION__,
						   pFirmwareImage[MAX_FIRMWARE_IMAGE_SIZE-2],
						   pFirmwareImage[MAX_FIRMWARE_IMAGE_SIZE-1],
						   (UCHAR)(crc>>8), (UCHAR)(crc));
					NICLF_DEFAULT_USE();
					break;
				}
				else
				{
					/* firmware is ok */
					pAd->FirmwareVersion = \
						(pFirmwareImage[MAX_FIRMWARE_IMAGE_SIZE-4] << 8) +
						pFirmwareImage[MAX_FIRMWARE_IMAGE_SIZE-3];

					/* check if firmware version of the file is too old */
					if ((pAd->FirmwareVersion) < \
											((FIRMWARE_MAJOR_VERSION << 8) +
									  	 	 FIRMWARE_MINOR_VERSION))
					{
						printk("%s: firmware version too old!\n", __FUNCTION__);
						NICLF_DEFAULT_USE();
						break;
					} /* End of if */
				} /* End of if */

				DBGPRINT(RT_DEBUG_TRACE,
						 ("NICLoadFirmware: CRC ok, ver=%d.%d\n",
						  pFirmwareImage[MAX_FIRMWARE_IMAGE_SIZE-4],
						  pFirmwareImage[MAX_FIRMWARE_IMAGE_SIZE-3]));
			} /* End of if (FileLength == MAX_FIRMWARE_IMAGE_SIZE) */
			break;
		} while(TRUE);

		/* close firmware file */
		if (IS_ERR(srcf))
			;
		else
		{
			retval = filp_close(srcf, NULL);
			if (retval)
			{
				DBGPRINT(RT_DEBUG_ERROR,
						 ("--> Error %d closing %s\n", -retval, src));
			} /* End of if */
		} /* End of if */
	} /* End of if */


	/* write firmware to ASIC */
	if (flg_default_firm_use == TRUE)
	{
		/* use default fimeware, free allocated buffer */
		if (pFirmwareImage != NULL)
			kfree(pFirmwareImage);
		/* End of if */

		/* use default *.bin array */
		pFirmwareImage = FirmwareImage;
		FileLength = sizeof(FirmwareImage);
	} /* End of if */

	/* enable Host program ram write selection */
	RTMP_IO_WRITE32(pAd, PBF_SYS_CTRL, 0x10000);

	for(i=0; i<FileLength; i+=4)
	{
		firm = pFirmwareImage[i] +
			   (pFirmwareImage[i+3] << 24) +
			   (pFirmwareImage[i+2] << 16) +
			   (pFirmwareImage[i+1] << 8);

		RTMP_IO_WRITE32(pAd, FIRMWARE_IMAGE_BASE + i, firm);
	} /* End of for */

	RTMP_IO_WRITE32(pAd, PBF_SYS_CTRL, 0x00000);
	RTMP_IO_WRITE32(pAd, PBF_SYS_CTRL, 0x00001);

	/* initialize BBP R/W access agent */
	RTMP_IO_WRITE32(pAd, H2M_BBP_AGENT, 0);
	RTMP_IO_WRITE32(pAd, H2M_MAILBOX_CSR, 0);

	if (flg_default_firm_use == FALSE)
	{
		/* use file firmware, free allocated buffer */
		if (pFirmwareImage != NULL)
			kfree(pFirmwareImage);
		/* End of if */
	} /* End of if */

	set_fs(orgfs);
	current->fsuid = orgfsuid;
	current->fsgid = orgfsgid;
#else

	NDIS_STATUS		Status = NDIS_STATUS_SUCCESS;
	PUCHAR			pFirmwareImage;
	ULONG			FileLength, Index;
	//ULONG			firm;
	UINT32			MacReg = 0;
	UINT32			Version = (pAd->MACVersion >> 16);

	pFirmwareImage = FirmwareImage;
	FileLength = sizeof(FirmwareImage);

	// New 8k byte firmware size for RT3071/RT3072
	//printk("Usb Chip\n");
	if (FIRMWAREIMAGE_LENGTH == FIRMWAREIMAGE_MAX_LENGTH)
	//The firmware image consists of two parts. One is the origianl and the other is the new.
	//Use Second Part
	{
#ifdef RT2870
		if ((Version != 0x2860) && (Version != 0x2872) && (Version != 0x3070))
		{	// Use Firmware V2.
			//printk("KH:Use New Version,part2\n");
			pFirmwareImage = (PUCHAR)&FirmwareImage[FIRMWAREIMAGEV1_LENGTH];
			FileLength = FIRMWAREIMAGEV2_LENGTH;
		}
		else
		{
			//printk("KH:Use New Version,part1\n");
			pFirmwareImage = FirmwareImage;
			FileLength = FIRMWAREIMAGEV1_LENGTH;
		}
#endif // RT2870 //
	}
	else
	{
		DBGPRINT(RT_DEBUG_ERROR, ("KH: bin file should be 8KB.\n"));
		Status = NDIS_STATUS_FAILURE;
	}

	RT28XX_WRITE_FIRMWARE(pAd, pFirmwareImage, FileLength);

#endif

	/* check if MCU is ready */
	Index = 0;
	do
	{
		RTMP_IO_READ32(pAd, PBF_SYS_CTRL, &MacReg);

		if (MacReg & 0x80)
			break;

		RTMPusecDelay(1000);
	} while (Index++ < 1000);

    if (Index >= 1000)
	{
		Status = NDIS_STATUS_FAILURE;
		DBGPRINT(RT_DEBUG_ERROR, ("NICLoadFirmware: MCU is not ready\n\n\n"));
	} /* End of if */

    DBGPRINT(RT_DEBUG_TRACE,
			 ("<=== %s (status=%d)\n", __FUNCTION__, Status));
    return Status;
} /* End of NICLoadFirmware */


/*
	========================================================================

	Routine Description:
		Load Tx rate switching parameters

	Arguments:
		Adapter						Pointer to our adapter

	Return Value:
		NDIS_STATUS_SUCCESS         firmware image load ok
		NDIS_STATUS_FAILURE         image not found

	IRQL = PASSIVE_LEVEL

	Rate Table Format:
		1. (B0: Valid Item number) (B1:Initial item from zero)
		2. Item Number(Dec)      Mode(Hex)     Current MCS(Dec)    TrainUp(Dec)    TrainDown(Dec)

	========================================================================
*/
NDIS_STATUS NICLoadRateSwitchingParams(
	IN PRTMP_ADAPTER pAd)
{
	return NDIS_STATUS_SUCCESS;
}

/*
	========================================================================

	Routine Description:
		if  pSrc1 all zero with length Length, return 0.
		If not all zero, return 1

	Arguments:
		pSrc1

	Return Value:
		1:			not all zero
		0:			all zero

	IRQL = DISPATCH_LEVEL

	Note:

	========================================================================
*/
ULONG	RTMPNotAllZero(
	IN	PVOID	pSrc1,
	IN	ULONG	Length)
{
	PUCHAR	pMem1;
	ULONG	Index = 0;

	pMem1 = (PUCHAR) pSrc1;

	for (Index = 0; Index < Length; Index++)
	{
		if (pMem1[Index] != 0x0)
		{
			break;
		}
	}

	if (Index == Length)
	{
		return (0);
	}
	else
	{
		return (1);
	}
}

/*
	========================================================================

	Routine Description:
		Compare two memory block

	Arguments:
		pSrc1		Pointer to first memory address
		pSrc2		Pointer to second memory address

	Return Value:
		0:			memory is equal
		1:			pSrc1 memory is larger
		2:			pSrc2 memory is larger

	IRQL = DISPATCH_LEVEL

	Note:

	========================================================================
*/
ULONG	RTMPCompareMemory(
	IN	PVOID	pSrc1,
	IN	PVOID	pSrc2,
	IN	ULONG	Length)
{
	PUCHAR	pMem1;
	PUCHAR	pMem2;
	ULONG	Index = 0;

	pMem1 = (PUCHAR) pSrc1;
	pMem2 = (PUCHAR) pSrc2;

	for (Index = 0; Index < Length; Index++)
	{
		if (pMem1[Index] > pMem2[Index])
			return (1);
		else if (pMem1[Index] < pMem2[Index])
			return (2);
	}

	// Equal
	return (0);
}

/*
	========================================================================

	Routine Description:
		Zero out memory block

	Arguments:
		pSrc1		Pointer to memory address
		Length		Size

	Return Value:
		None

	IRQL = PASSIVE_LEVEL
	IRQL = DISPATCH_LEVEL

	Note:

	========================================================================
*/
VOID	RTMPZeroMemory(
	IN	PVOID	pSrc,
	IN	ULONG	Length)
{
	PUCHAR	pMem;
	ULONG	Index = 0;

	pMem = (PUCHAR) pSrc;

	for (Index = 0; Index < Length; Index++)
	{
		pMem[Index] = 0x00;
	}
}

VOID	RTMPFillMemory(
	IN	PVOID	pSrc,
	IN	ULONG	Length,
	IN	UCHAR	Fill)
{
	PUCHAR	pMem;
	ULONG	Index = 0;

	pMem = (PUCHAR) pSrc;

	for (Index = 0; Index < Length; Index++)
	{
		pMem[Index] = Fill;
	}
}

/*
	========================================================================

	Routine Description:
		Copy data from memory block 1 to memory block 2

	Arguments:
		pDest		Pointer to destination memory address
		pSrc		Pointer to source memory address
		Length		Copy size

	Return Value:
		None

	IRQL = PASSIVE_LEVEL
	IRQL = DISPATCH_LEVEL

	Note:

	========================================================================
*/
VOID	RTMPMoveMemory(
	OUT	PVOID	pDest,
	IN	PVOID	pSrc,
	IN	ULONG	Length)
{
	PUCHAR	pMem1;
	PUCHAR	pMem2;
	UINT	Index;

	ASSERT((Length==0) || (pDest && pSrc));

	pMem1 = (PUCHAR) pDest;
	pMem2 = (PUCHAR) pSrc;

	for (Index = 0; Index < Length; Index++)
	{
		pMem1[Index] = pMem2[Index];
	}
}

/*
	========================================================================

	Routine Description:
		Initialize port configuration structure

	Arguments:
		Adapter						Pointer to our adapter

	Return Value:
		None

	IRQL = PASSIVE_LEVEL

	Note:

	========================================================================
*/
VOID	UserCfgInit(
	IN	PRTMP_ADAPTER pAd)
{
//	EDCA_PARM DefaultEdcaParm;
    UINT key_index, bss_index;

	DBGPRINT(RT_DEBUG_TRACE, ("--> UserCfgInit\n"));

	//
	//  part I. intialize common configuration
	//
#ifdef RT2870
	pAd->BulkOutReq = 0;

	pAd->BulkOutComplete = 0;
	pAd->BulkOutCompleteOther = 0;
	pAd->BulkOutCompleteCancel = 0;
	pAd->BulkInReq = 0;
	pAd->BulkInComplete = 0;
	pAd->BulkInCompleteFail = 0;

	//pAd->QuickTimerP = 100;
	//pAd->TurnAggrBulkInCount = 0;
	pAd->bUsbTxBulkAggre = 0;

	// init as unsed value to ensure driver will set to MCU once.
	pAd->LedIndicatorStregth = 0xFF;

	pAd->CommonCfg.MaxPktOneTxBulk = 2;
	pAd->CommonCfg.TxBulkFactor = 1;
	pAd->CommonCfg.RxBulkFactor =1;

	pAd->CommonCfg.TxPower = 100; //mW

	NdisZeroMemory(&pAd->CommonCfg.IOTestParm, sizeof(pAd->CommonCfg.IOTestParm));
#endif // RT2870 //

	for(key_index=0; key_index<SHARE_KEY_NUM; key_index++)
	{
		for(bss_index = 0; bss_index < MAX_MBSSID_NUM; bss_index++)
		{
			pAd->SharedKey[bss_index][key_index].KeyLen = 0;
			pAd->SharedKey[bss_index][key_index].CipherAlg = CIPHER_NONE;
        } /* End of for */
    } /* End of for */

	pAd->EepromAccess = FALSE;

	pAd->Antenna.word = 0;
	pAd->CommonCfg.BBPCurrentBW = BW_20;

	pAd->LedCntl.word = 0;

	pAd->bAutoTxAgcA = FALSE;			// Default is OFF
	pAd->bAutoTxAgcG = FALSE;			// Default is OFF
	pAd->RfIcType = RFIC_2820;

	// Init timer for reset complete event
	pAd->CommonCfg.CentralChannel = 1;
	pAd->bForcePrintTX = FALSE;
	pAd->bForcePrintRX = FALSE;
	pAd->bStaFifoTest = FALSE;
	pAd->bProtectionTest = FALSE;
	pAd->bHCCATest = FALSE;
	pAd->bGenOneHCCA = FALSE;
	pAd->CommonCfg.Dsifs = 10;      // in units of usec
	pAd->CommonCfg.TxPower = 100; //mW
	pAd->CommonCfg.TxPowerPercentage = 0xffffffff; // AUTO
	pAd->CommonCfg.TxPowerDefault = 0xffffffff; // AUTO
	pAd->CommonCfg.TxPreamble = Rt802_11PreambleAuto; // use Long preamble on TX by defaut
	pAd->CommonCfg.bUseZeroToDisableFragment = FALSE;
	pAd->CommonCfg.RtsThreshold = 2347;
	pAd->CommonCfg.FragmentThreshold = 2346;
	pAd->CommonCfg.UseBGProtection = 0;    // 0: AUTO
	pAd->CommonCfg.bEnableTxBurst = TRUE; //0;
	pAd->CommonCfg.PhyMode = 0xff;     // unknown
	pAd->CommonCfg.BandState = UNKNOWN_BAND;
	pAd->CommonCfg.RadarDetect.CSPeriod = 10;
	pAd->CommonCfg.RadarDetect.CSCount = 0;
	pAd->CommonCfg.RadarDetect.RDMode = RD_NORMAL_MODE;
	pAd->CommonCfg.RadarDetect.ChMovingTime = 65;
	pAd->CommonCfg.RadarDetect.LongPulseRadarTh = 3;
	pAd->CommonCfg.bAPSDCapable = FALSE;
	pAd->CommonCfg.bNeedSendTriggerFrame = FALSE;
	pAd->CommonCfg.TriggerTimerCount = 0;
	pAd->CommonCfg.bAPSDForcePowerSave = FALSE;
	pAd->CommonCfg.bCountryFlag = FALSE;
	pAd->CommonCfg.TxStream = 0;
	pAd->CommonCfg.RxStream = 0;

	NdisZeroMemory(&pAd->BeaconTxWI, sizeof(pAd->BeaconTxWI));

#ifdef DOT11_N_SUPPORT
	NdisZeroMemory(&pAd->CommonCfg.HtCapability, sizeof(pAd->CommonCfg.HtCapability));
	pAd->HTCEnable = FALSE;
	pAd->bBroadComHT = FALSE;
	pAd->CommonCfg.bRdg = FALSE;

#ifdef DOT11N_DRAFT3
	pAd->CommonCfg.Dot11OBssScanPassiveDwell = dot11OBSSScanPassiveDwell;	// Unit : TU. 5~1000
	pAd->CommonCfg.Dot11OBssScanActiveDwell = dot11OBSSScanActiveDwell;	// Unit : TU. 10~1000
	pAd->CommonCfg.Dot11BssWidthTriggerScanInt = dot11BSSWidthTriggerScanInterval;	// Unit : Second
	pAd->CommonCfg.Dot11OBssScanPassiveTotalPerChannel = dot11OBSSScanPassiveTotalPerChannel;	// Unit : TU. 200~10000
	pAd->CommonCfg.Dot11OBssScanActiveTotalPerChannel = dot11OBSSScanActiveTotalPerChannel;	// Unit : TU. 20~10000
	pAd->CommonCfg.Dot11BssWidthChanTranDelayFactor = dot11BSSWidthChannelTransactionDelayFactor;
	pAd->CommonCfg.Dot11OBssScanActivityThre = dot11BSSScanActivityThreshold;	// Unit : percentage
	pAd->CommonCfg.Dot11BssWidthChanTranDelay = (pAd->CommonCfg.Dot11BssWidthTriggerScanInt * pAd->CommonCfg.Dot11BssWidthChanTranDelayFactor);
#endif  // DOT11N_DRAFT3 //

	NdisZeroMemory(&pAd->CommonCfg.AddHTInfo, sizeof(pAd->CommonCfg.AddHTInfo));
	pAd->CommonCfg.BACapability.field.MMPSmode = MMPS_ENABLE;
	pAd->CommonCfg.BACapability.field.MpduDensity = 0;
	pAd->CommonCfg.BACapability.field.Policy = IMMED_BA;
	pAd->CommonCfg.BACapability.field.RxBAWinLimit = 64; //32;
	pAd->CommonCfg.BACapability.field.TxBAWinLimit = 64; //32;
	DBGPRINT(RT_DEBUG_TRACE, ("--> UserCfgInit. BACapability = 0x%x\n", pAd->CommonCfg.BACapability.word));

	pAd->CommonCfg.BACapability.field.AutoBA = FALSE;
	BATableInit(pAd, &pAd->BATable);

	pAd->CommonCfg.bExtChannelSwitchAnnouncement = 1;
	pAd->CommonCfg.bHTProtect = 1;
	pAd->CommonCfg.bMIMOPSEnable = TRUE;
	pAd->CommonCfg.bBADecline = FALSE;
	pAd->CommonCfg.bDisableReordering = FALSE;

	pAd->CommonCfg.TxBASize = 7;

	pAd->CommonCfg.REGBACapability.word = pAd->CommonCfg.BACapability.word;
#endif // DOT11_N_SUPPORT //

	//pAd->CommonCfg.HTPhyMode.field.BW = BW_20;
	//pAd->CommonCfg.HTPhyMode.field.MCS = MCS_AUTO;
	//pAd->CommonCfg.HTPhyMode.field.ShortGI = GI_800;
	//pAd->CommonCfg.HTPhyMode.field.STBC = STBC_NONE;
	pAd->CommonCfg.TxRate = RATE_6;

	pAd->CommonCfg.MlmeTransmit.field.MCS = MCS_RATE_6;
	pAd->CommonCfg.MlmeTransmit.field.BW = BW_20;
	pAd->CommonCfg.MlmeTransmit.field.MODE = MODE_OFDM;

	pAd->CommonCfg.BeaconPeriod = 100;     // in mSec

	//
	// part II. intialize STA specific configuration
	//
#ifdef CONFIG_STA_SUPPORT
	IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
	{
		RX_FILTER_SET_FLAG(pAd, fRX_FILTER_ACCEPT_DIRECT);
		RX_FILTER_CLEAR_FLAG(pAd, fRX_FILTER_ACCEPT_MULTICAST);
		RX_FILTER_SET_FLAG(pAd, fRX_FILTER_ACCEPT_BROADCAST);
		RX_FILTER_SET_FLAG(pAd, fRX_FILTER_ACCEPT_ALL_MULTICAST);

		pAd->StaCfg.Psm = PWR_ACTIVE;

		pAd->StaCfg.OrigWepStatus = Ndis802_11EncryptionDisabled;
		pAd->StaCfg.PairCipher = Ndis802_11EncryptionDisabled;
		pAd->StaCfg.GroupCipher = Ndis802_11EncryptionDisabled;
		pAd->StaCfg.bMixCipher = FALSE;
		pAd->StaCfg.DefaultKeyId = 0;

		// 802.1x port control
		pAd->StaCfg.PrivacyFilter = Ndis802_11PrivFilter8021xWEP;
		pAd->StaCfg.PortSecured = WPA_802_1X_PORT_NOT_SECURED;
		pAd->StaCfg.LastMicErrorTime = 0;
		pAd->StaCfg.MicErrCnt        = 0;
		pAd->StaCfg.bBlockAssoc      = FALSE;
		pAd->StaCfg.WpaState         = SS_NOTUSE;

		pAd->CommonCfg.NdisRadioStateOff = FALSE;		// New to support microsoft disable radio with OID command

		pAd->StaCfg.RssiTrigger = 0;
		NdisZeroMemory(&pAd->StaCfg.RssiSample, sizeof(RSSI_SAMPLE));
		pAd->StaCfg.RssiTriggerMode = RSSI_TRIGGERED_UPON_BELOW_THRESHOLD;
		pAd->StaCfg.AtimWin = 0;
		pAd->StaCfg.DefaultListenCount = 3;//default listen count;
		pAd->StaCfg.BssType = BSS_INFRA;  // BSS_INFRA or BSS_ADHOC or BSS_MONITOR
		pAd->StaCfg.bScanReqIsFromWebUI = FALSE;
		OPSTATUS_CLEAR_FLAG(pAd, fOP_STATUS_DOZE);
		OPSTATUS_CLEAR_FLAG(pAd, fOP_STATUS_WAKEUP_NOW);

		pAd->StaCfg.bAutoTxRateSwitch = TRUE;
		pAd->StaCfg.DesiredTransmitSetting.field.MCS = MCS_AUTO;
	}

#ifdef EXT_BUILD_CHANNEL_LIST
	pAd->StaCfg.IEEE80211dClientMode = Rt802_11_D_None;
#endif // EXT_BUILD_CHANNEL_LIST //
#endif // CONFIG_STA_SUPPORT //

	// global variables mXXXX used in MAC protocol state machines
	OPSTATUS_SET_FLAG(pAd, fOP_STATUS_RECEIVE_DTIM);
	OPSTATUS_CLEAR_FLAG(pAd, fOP_STATUS_ADHOC_ON);
	OPSTATUS_CLEAR_FLAG(pAd, fOP_STATUS_INFRA_ON);

	// PHY specification
	pAd->CommonCfg.PhyMode = PHY_11BG_MIXED;		// default PHY mode
	OPSTATUS_CLEAR_FLAG(pAd, fOP_STATUS_SHORT_PREAMBLE_INUSED);  // CCK use LONG preamble

#ifdef CONFIG_STA_SUPPORT
	IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
	{
		// user desired power mode
		pAd->StaCfg.WindowsPowerMode = Ndis802_11PowerModeCAM;
		pAd->StaCfg.WindowsBatteryPowerMode = Ndis802_11PowerModeCAM;
		pAd->StaCfg.bWindowsACCAMEnable = FALSE;

#ifdef LEAP_SUPPORT
		// CCX v1.0 releated init value
		RTMPInitTimer(pAd, &pAd->StaCfg.LeapAuthTimer, GET_TIMER_FUNCTION(LeapAuthTimeout), pAd, FALSE);
		pAd->StaCfg.LeapAuthMode = CISCO_AuthModeLEAPNone;
		pAd->StaCfg.bCkipOn = FALSE;
#endif // LEAP_SUPPORT //

		RTMPInitTimer(pAd, &pAd->StaCfg.StaQuickResponeForRateUpTimer, GET_TIMER_FUNCTION(StaQuickResponeForRateUpExec), pAd, FALSE);
		pAd->StaCfg.StaQuickResponeForRateUpTimerRunning = FALSE;

		// Patch for Ndtest
		pAd->StaCfg.ScanCnt = 0;

		// CCX 2.0 control flag init
		pAd->StaCfg.CCXEnable = FALSE;
		pAd->StaCfg.CCXReqType = MSRN_TYPE_UNUSED;
		pAd->StaCfg.CCXQosECWMin	= 4;
		pAd->StaCfg.CCXQosECWMax	= 10;

		pAd->StaCfg.bHwRadio  = TRUE; // Default Hardware Radio status is On
		pAd->StaCfg.bSwRadio  = TRUE; // Default Software Radio status is On
		pAd->StaCfg.bRadio    = TRUE; // bHwRadio && bSwRadio
		pAd->StaCfg.bHardwareRadio = FALSE;		// Default is OFF
		pAd->StaCfg.bShowHiddenSSID = FALSE;		// Default no show

		// Nitro mode control
		pAd->StaCfg.bAutoReconnect = TRUE;

		// Save the init time as last scan time, the system should do scan after 2 seconds.
		// This patch is for driver wake up from standby mode, system will do scan right away.
		pAd->StaCfg.LastScanTime = 0;
		NdisZeroMemory(pAd->nickname, IW_ESSID_MAX_SIZE+1);
		sprintf(pAd->nickname, "%s", STA_NIC_DEVICE_NAME);
		RTMPInitTimer(pAd, &pAd->StaCfg.WpaDisassocAndBlockAssocTimer, GET_TIMER_FUNCTION(WpaDisassocApAndBlockAssoc), pAd, FALSE);
#ifdef WPA_SUPPLICANT_SUPPORT
		pAd->StaCfg.IEEE8021X = FALSE;
		pAd->StaCfg.IEEE8021x_required_keys = FALSE;
		pAd->StaCfg.WpaSupplicantUP = WPA_SUPPLICANT_DISABLE;
#ifdef NATIVE_WPA_SUPPLICANT_SUPPORT
		pAd->StaCfg.WpaSupplicantUP = WPA_SUPPLICANT_ENABLE;
#endif // NATIVE_WPA_SUPPLICANT_SUPPORT //
#endif // WPA_SUPPLICANT_SUPPORT //

	}
#endif // CONFIG_STA_SUPPORT //

	// Default for extra information is not valid
	pAd->ExtraInfo = EXTRA_INFO_CLEAR;

	// Default Config change flag
	pAd->bConfigChanged = FALSE;

	//
	// part III. AP configurations
	//


	//
	// part IV. others
	//
	// dynamic BBP R66:sensibity tuning to overcome background noise
	pAd->BbpTuning.bEnable                = TRUE;
	pAd->BbpTuning.FalseCcaLowerThreshold = 100;
	pAd->BbpTuning.FalseCcaUpperThreshold = 512;
	pAd->BbpTuning.R66Delta               = 4;
	pAd->Mlme.bEnableAutoAntennaCheck = TRUE;

	//
	// Also initial R66CurrentValue, RTUSBResumeMsduTransmission might use this value.
	// if not initial this value, the default value will be 0.
	//
	pAd->BbpTuning.R66CurrentValue = 0x38;

	pAd->Bbp94 = BBPR94_DEFAULT;
	pAd->BbpForCCK = FALSE;

	// Default is FALSE for test bit 1
	//pAd->bTest1 = FALSE;

	// initialize MAC table and allocate spin lock
	NdisZeroMemory(&pAd->MacTab, sizeof(MAC_TABLE));
	InitializeQueueHeader(&pAd->MacTab.McastPsQueue);
	NdisAllocateSpinLock(&pAd->MacTabLock);

	//RTMPInitTimer(pAd, &pAd->RECBATimer, RECBATimerTimeout, pAd, TRUE);
	//RTMPSetTimer(&pAd->RECBATimer, REORDER_EXEC_INTV);

#ifdef RALINK_ATE
	NdisZeroMemory(&pAd->ate, sizeof(ATE_INFO));
	pAd->ate.Mode = ATE_STOP;
	pAd->ate.TxCount = 200;/* to exceed TX_RING_SIZE ... */
	pAd->ate.TxLength = 1024;
	pAd->ate.TxWI.ShortGI = 0;// LONG GI : 800 ns
	pAd->ate.TxWI.PHYMODE = MODE_CCK;
	pAd->ate.TxWI.MCS = 3;
	pAd->ate.TxWI.BW = BW_20;
	pAd->ate.Channel = 1;
	pAd->ate.QID = QID_AC_BE;
	pAd->ate.Addr1[0] = 0x00;
	pAd->ate.Addr1[1] = 0x11;
	pAd->ate.Addr1[2] = 0x22;
	pAd->ate.Addr1[3] = 0xAA;
	pAd->ate.Addr1[4] = 0xBB;
	pAd->ate.Addr1[5] = 0xCC;
	NdisMoveMemory(pAd->ate.Addr2, pAd->ate.Addr1, ETH_LENGTH_OF_ADDRESS);
	NdisMoveMemory(pAd->ate.Addr3, pAd->ate.Addr1, ETH_LENGTH_OF_ADDRESS);
	pAd->ate.bRxFer = 0;
	pAd->ate.bQATxStart = FALSE;
	pAd->ate.bQARxStart = FALSE;
#ifdef RALINK_28xx_QA
	//pAd->ate.Repeat = 0;
	pAd->ate.TxStatus = 0;
	pAd->ate.AtePid = 0;
#endif // RALINK_28xx_QA //
#endif // RALINK_ATE //


	pAd->CommonCfg.bWiFiTest = FALSE;


	DBGPRINT(RT_DEBUG_TRACE, ("<-- UserCfgInit\n"));
}

// IRQL = PASSIVE_LEVEL
UCHAR BtoH(char ch)
{
	if (ch >= '0' && ch <= '9') return (ch - '0');        // Handle numerals
	if (ch >= 'A' && ch <= 'F') return (ch - 'A' + 0xA);  // Handle capitol hex digits
	if (ch >= 'a' && ch <= 'f') return (ch - 'a' + 0xA);  // Handle small hex digits
	return(255);
}

//
//  FUNCTION: AtoH(char *, UCHAR *, int)
//
//  PURPOSE:  Converts ascii string to network order hex
//
//  PARAMETERS:
//    src    - pointer to input ascii string
//    dest   - pointer to output hex
//    destlen - size of dest
//
//  COMMENTS:
//
//    2 ascii bytes make a hex byte so must put 1st ascii byte of pair
//    into upper nibble and 2nd ascii byte of pair into lower nibble.
//
// IRQL = PASSIVE_LEVEL

void AtoH(char * src, UCHAR * dest, int destlen)
{
	char * srcptr;
	PUCHAR destTemp;

	srcptr = src;
	destTemp = (PUCHAR) dest;

	while(destlen--)
	{
		*destTemp = BtoH(*srcptr++) << 4;    // Put 1st ascii byte in upper nibble.
		*destTemp += BtoH(*srcptr++);      // Add 2nd ascii byte to above.
		destTemp++;
	}
}

VOID	RTMPPatchMacBbpBug(
	IN	PRTMP_ADAPTER	pAd)
{
	ULONG	Index;

	// Initialize BBP register to default value
	for (Index = 0; Index < NUM_BBP_REG_PARMS; Index++)
	{
		RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBPRegTable[Index].Register, (UCHAR)BBPRegTable[Index].Value);
	}

	// Initialize RF register to default value
	AsicSwitchChannel(pAd, pAd->CommonCfg.Channel, FALSE);
	AsicLockChannel(pAd, pAd->CommonCfg.Channel);

	// Re-init BBP register from EEPROM value
	NICInitAsicFromEEPROM(pAd);
}

/*
	========================================================================

	Routine Description:
		Init timer objects

	Arguments:
		pAd			Pointer to our adapter
		pTimer				Timer structure
		pTimerFunc			Function to execute when timer expired
		Repeat				Ture for period timer

	Return Value:
		None

	Note:

	========================================================================
*/
VOID	RTMPInitTimer(
	IN	PRTMP_ADAPTER			pAd,
	IN	PRALINK_TIMER_STRUCT	pTimer,
	IN	PVOID					pTimerFunc,
	IN	PVOID					pData,
	IN	BOOLEAN					Repeat)
{
	//
	// Set Valid to TRUE for later used.
	// It will crash if we cancel a timer or set a timer
	// that we haven't initialize before.
	//
	pTimer->Valid      = TRUE;

	pTimer->PeriodicType = Repeat;
	pTimer->State      = FALSE;
	pTimer->cookie = (ULONG) pData;

#ifdef RT2870
	pTimer->pAd = pAd;
#endif // RT2870 //

	RTMP_OS_Init_Timer(pAd,	&pTimer->TimerObj,	pTimerFunc, (PVOID) pTimer);
}

/*
	========================================================================

	Routine Description:
		Init timer objects

	Arguments:
		pTimer				Timer structure
		Value				Timer value in milliseconds

	Return Value:
		None

	Note:
		To use this routine, must call RTMPInitTimer before.

	========================================================================
*/
VOID	RTMPSetTimer(
	IN	PRALINK_TIMER_STRUCT	pTimer,
	IN	ULONG					Value)
{
	if (pTimer->Valid)
	{
		pTimer->TimerValue = Value;
		pTimer->State      = FALSE;
		if (pTimer->PeriodicType == TRUE)
		{
			pTimer->Repeat = TRUE;
			RTMP_SetPeriodicTimer(&pTimer->TimerObj, Value);
		}
		else
		{
			pTimer->Repeat = FALSE;
			RTMP_OS_Add_Timer(&pTimer->TimerObj, Value);
		}
	}
	else
	{
		DBGPRINT_ERR(("RTMPSetTimer failed, Timer hasn't been initialize!\n"));
	}
}


/*
	========================================================================

	Routine Description:
		Init timer objects

	Arguments:
		pTimer				Timer structure
		Value				Timer value in milliseconds

	Return Value:
		None

	Note:
		To use this routine, must call RTMPInitTimer before.

	========================================================================
*/
VOID	RTMPModTimer(
	IN	PRALINK_TIMER_STRUCT	pTimer,
	IN	ULONG					Value)
{
	BOOLEAN	Cancel;

	if (pTimer->Valid)
	{
		pTimer->TimerValue = Value;
		pTimer->State      = FALSE;
		if (pTimer->PeriodicType == TRUE)
		{
			RTMPCancelTimer(pTimer, &Cancel);
			RTMPSetTimer(pTimer, Value);
		}
		else
		{
			RTMP_OS_Mod_Timer(&pTimer->TimerObj, Value);
		}
	}
	else
	{
		DBGPRINT_ERR(("RTMPModTimer failed, Timer hasn't been initialize!\n"));
	}
}

/*
	========================================================================

	Routine Description:
		Cancel timer objects

	Arguments:
		Adapter						Pointer to our adapter

	Return Value:
		None

	IRQL = PASSIVE_LEVEL
	IRQL = DISPATCH_LEVEL

	Note:
		1.) To use this routine, must call RTMPInitTimer before.
		2.) Reset NIC to initial state AS IS system boot up time.

	========================================================================
*/
VOID	RTMPCancelTimer(
	IN	PRALINK_TIMER_STRUCT	pTimer,
	OUT	BOOLEAN					*pCancelled)
{
	if (pTimer->Valid)
	{
		if (pTimer->State == FALSE)
			pTimer->Repeat = FALSE;
			RTMP_OS_Del_Timer(&pTimer->TimerObj, pCancelled);

		if (*pCancelled == TRUE)
			pTimer->State = TRUE;

#ifdef RT2870
		// We need to go-through the TimerQ to findout this timer handler and remove it if
		//		it's still waiting for execution.

		RT2870_TimerQ_Remove(pTimer->pAd, pTimer);
#endif // RT2870 //
	}
	else
	{
		//
		// NdisMCancelTimer just canced the timer and not mean release the timer.
		// And don't set the "Valid" to False. So that we can use this timer again.
		//
		DBGPRINT_ERR(("RTMPCancelTimer failed, Timer hasn't been initialize!\n"));
	}
}

/*
	========================================================================

	Routine Description:
		Set LED Status

	Arguments:
		pAd						Pointer to our adapter
		Status					LED Status

	Return Value:
		None

	IRQL = PASSIVE_LEVEL
	IRQL = DISPATCH_LEVEL

	Note:

	========================================================================
*/
VOID RTMPSetLED(
	IN PRTMP_ADAPTER 	pAd,
	IN UCHAR			Status)
{
	//ULONG			data;
	UCHAR			HighByte = 0;
	UCHAR			LowByte;

// In ATE mode of RT2860 AP/STA, we have erased 8051 firmware.
// So LED mode is not supported when ATE is running.
#ifdef RALINK_ATE
	if (ATE_ON(pAd))
		return;
#endif // RALINK_ATE //

	LowByte = pAd->LedCntl.field.LedMode&0x7f;
	switch (Status)
	{
		case LED_LINK_DOWN:
			HighByte = 0x20;
			AsicSendCommandToMcu(pAd, 0x50, 0xff, LowByte, HighByte);
			pAd->LedIndicatorStregth = 0;
			break;
		case LED_LINK_UP:
			if (pAd->CommonCfg.Channel > 14)
				HighByte = 0xa0;
			else
				HighByte = 0x60;
			AsicSendCommandToMcu(pAd, 0x50, 0xff, LowByte, HighByte);
			break;
		case LED_RADIO_ON:
			HighByte = 0x20;
			AsicSendCommandToMcu(pAd, 0x50, 0xff, LowByte, HighByte);
			break;
		case LED_HALT:
			LowByte = 0; // Driver sets MAC register and MAC controls LED
		case LED_RADIO_OFF:
			HighByte = 0;
			AsicSendCommandToMcu(pAd, 0x50, 0xff, LowByte, HighByte);
			break;
        case LED_WPS:
			HighByte = 0x10;
			AsicSendCommandToMcu(pAd, 0x50, 0xff, LowByte, HighByte);
			break;
		case LED_ON_SITE_SURVEY:
			HighByte = 0x08;
			AsicSendCommandToMcu(pAd, 0x50, 0xff, LowByte, HighByte);
			break;
		case LED_POWER_UP:
			HighByte = 0x04;
			AsicSendCommandToMcu(pAd, 0x50, 0xff, LowByte, HighByte);
			break;
		default:
			DBGPRINT(RT_DEBUG_WARN, ("RTMPSetLED::Unknown Status %d\n", Status));
			break;
	}

    //
	// Keep LED status for LED SiteSurvey mode.
	// After SiteSurvey, we will set the LED mode to previous status.
	//
	if ((Status != LED_ON_SITE_SURVEY) && (Status != LED_POWER_UP))
		pAd->LedStatus = Status;

	DBGPRINT(RT_DEBUG_TRACE, ("RTMPSetLED::Mode=%d,HighByte=0x%02x,LowByte=0x%02x\n", pAd->LedCntl.field.LedMode, HighByte, LowByte));
}

/*
	========================================================================

	Routine Description:
		Set LED Signal Stregth

	Arguments:
		pAd						Pointer to our adapter
		Dbm						Signal Stregth

	Return Value:
		None

	IRQL = PASSIVE_LEVEL

	Note:
		Can be run on any IRQL level.

		According to Microsoft Zero Config Wireless Signal Stregth definition as belows.
		<= -90  No Signal
		<= -81  Very Low
		<= -71  Low
		<= -67  Good
		<= -57  Very Good
		 > -57  Excellent
	========================================================================
*/
VOID RTMPSetSignalLED(
	IN PRTMP_ADAPTER 	pAd,
	IN NDIS_802_11_RSSI Dbm)
{
	UCHAR		nLed = 0;

	//
	// if not Signal Stregth, then do nothing.
	//
	if (pAd->LedCntl.field.LedMode != LED_MODE_SIGNAL_STREGTH)
	{
		return;
	}

	if (Dbm <= -90)
		nLed = 0;
	else if (Dbm <= -81)
		nLed = 1;
	else if (Dbm <= -71)
		nLed = 3;
	else if (Dbm <= -67)
		nLed = 7;
	else if (Dbm <= -57)
		nLed = 15;
	else
		nLed = 31;

	//
	// Update Signal Stregth to firmware if changed.
	//
	if (pAd->LedIndicatorStregth != nLed)
	{
		AsicSendCommandToMcu(pAd, 0x51, 0xff, nLed, pAd->LedCntl.field.Polarity);
		pAd->LedIndicatorStregth = nLed;
	}
}

/*
	========================================================================

	Routine Description:
		Enable RX

	Arguments:
		pAd						Pointer to our adapter

	Return Value:
		None

	IRQL <= DISPATCH_LEVEL

	Note:
		Before Enable RX, make sure you have enabled Interrupt.
	========================================================================
*/
VOID RTMPEnableRxTx(
	IN PRTMP_ADAPTER	pAd)
{
//	WPDMA_GLO_CFG_STRUC	GloCfg;
//	ULONG	i = 0;

	DBGPRINT(RT_DEBUG_TRACE, ("==> RTMPEnableRxTx\n"));

	// Enable Rx DMA.
	RT28XXDMAEnable(pAd);

	// enable RX of MAC block
	if (pAd->OpMode == OPMODE_AP)
	{
		UINT32 rx_filter_flag = APNORMAL;


		RTMP_IO_WRITE32(pAd, RX_FILTR_CFG, rx_filter_flag);     // enable RX of DMA block
	}
	else
	{
		RTMP_IO_WRITE32(pAd, RX_FILTR_CFG, STANORMAL);     // Staion not drop control frame will fail WiFi Certification.
	}

	RTMP_IO_WRITE32(pAd, MAC_SYS_CTRL, 0xc);
	DBGPRINT(RT_DEBUG_TRACE, ("<== RTMPEnableRxTx\n"));
}