blob: b637c4ee60965e63db756551ac9f9aef47a24dc8 [file] [log] [blame]
/*
*************************************************************************
* 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:
rt28xx.h
Abstract:
RT28xx ASIC related definition & structures
Revision History:
Who When What
-------- ---------- ----------------------------------------------
Jan Lee Jan-3-2006 created for RT2860c
*/
#ifndef __RT28XX_H__
#define __RT28XX_H__
//
// PCI registers - base address 0x0000
//
#define PCI_CFG 0x0000
#define PCI_EECTRL 0x0004
#define PCI_MCUCTRL 0x0008
#define OPT_14 0x114
typedef int NTSTATUS;
#define RETRY_LIMIT 10
#define STATUS_SUCCESS 0x00
#define STATUS_UNSUCCESSFUL 0x01
//
// SCH/DMA registers - base address 0x0200
//
// INT_SOURCE_CSR: Interrupt source register. Write one to clear corresponding bit
//
#define DMA_CSR0 0x200
#define INT_SOURCE_CSR 0x200
#ifdef RT_BIG_ENDIAN
typedef union _INT_SOURCE_CSR_STRUC {
struct {
UINT32 :14;
UINT32 TxCoherent:1;
UINT32 RxCoherent:1;
UINT32 GPTimer:1;
UINT32 AutoWakeup:1;//bit14
UINT32 TXFifoStatusInt:1;//FIFO Statistics is full, sw should read 0x171c
UINT32 PreTBTT:1;
UINT32 TBTTInt:1;
UINT32 RxTxCoherent:1;
UINT32 MCUCommandINT:1;
UINT32 MgmtDmaDone:1;
UINT32 HccaDmaDone:1;
UINT32 Ac3DmaDone:1;
UINT32 Ac2DmaDone:1;
UINT32 Ac1DmaDone:1;
UINT32 Ac0DmaDone:1;
UINT32 RxDone:1;
UINT32 TxDelayINT:1; //delayed interrupt, not interrupt until several int or time limit hit
UINT32 RxDelayINT:1; //dealyed interrupt
} field;
UINT32 word;
} INT_SOURCE_CSR_STRUC, *PINT_SOURCE_CSR_STRUC;
#else
typedef union _INT_SOURCE_CSR_STRUC {
struct {
UINT32 RxDelayINT:1;
UINT32 TxDelayINT:1;
UINT32 RxDone:1;
UINT32 Ac0DmaDone:1;//4
UINT32 Ac1DmaDone:1;
UINT32 Ac2DmaDone:1;
UINT32 Ac3DmaDone:1;
UINT32 HccaDmaDone:1; // bit7
UINT32 MgmtDmaDone:1;
UINT32 MCUCommandINT:1;//bit 9
UINT32 RxTxCoherent:1;
UINT32 TBTTInt:1;
UINT32 PreTBTT:1;
UINT32 TXFifoStatusInt:1;//FIFO Statistics is full, sw should read 0x171c
UINT32 AutoWakeup:1;//bit14
UINT32 GPTimer:1;
UINT32 RxCoherent:1;//bit16
UINT32 TxCoherent:1;
UINT32 :14;
} field;
UINT32 word;
} INT_SOURCE_CSR_STRUC, *PINT_SOURCE_CSR_STRUC;
#endif
//
// INT_MASK_CSR: Interrupt MASK register. 1: the interrupt is mask OFF
//
#define INT_MASK_CSR 0x204
#ifdef RT_BIG_ENDIAN
typedef union _INT_MASK_CSR_STRUC {
struct {
UINT32 TxCoherent:1;
UINT32 RxCoherent:1;
UINT32 :20;
UINT32 MCUCommandINT:1;
UINT32 MgmtDmaDone:1;
UINT32 HccaDmaDone:1;
UINT32 Ac3DmaDone:1;
UINT32 Ac2DmaDone:1;
UINT32 Ac1DmaDone:1;
UINT32 Ac0DmaDone:1;
UINT32 RxDone:1;
UINT32 TxDelay:1;
UINT32 RXDelay_INT_MSK:1;
} field;
UINT32 word;
}INT_MASK_CSR_STRUC, *PINT_MASK_CSR_STRUC;
#else
typedef union _INT_MASK_CSR_STRUC {
struct {
UINT32 RXDelay_INT_MSK:1;
UINT32 TxDelay:1;
UINT32 RxDone:1;
UINT32 Ac0DmaDone:1;
UINT32 Ac1DmaDone:1;
UINT32 Ac2DmaDone:1;
UINT32 Ac3DmaDone:1;
UINT32 HccaDmaDone:1;
UINT32 MgmtDmaDone:1;
UINT32 MCUCommandINT:1;
UINT32 :20;
UINT32 RxCoherent:1;
UINT32 TxCoherent:1;
} field;
UINT32 word;
} INT_MASK_CSR_STRUC, *PINT_MASK_CSR_STRUC;
#endif
#define WPDMA_GLO_CFG 0x208
#ifdef RT_BIG_ENDIAN
typedef union _WPDMA_GLO_CFG_STRUC {
struct {
UINT32 HDR_SEG_LEN:16;
UINT32 RXHdrScater:8;
UINT32 BigEndian:1;
UINT32 EnTXWriteBackDDONE:1;
UINT32 WPDMABurstSIZE:2;
UINT32 RxDMABusy:1;
UINT32 EnableRxDMA:1;
UINT32 TxDMABusy:1;
UINT32 EnableTxDMA:1;
} field;
UINT32 word;
}WPDMA_GLO_CFG_STRUC, *PWPDMA_GLO_CFG_STRUC;
#else
typedef union _WPDMA_GLO_CFG_STRUC {
struct {
UINT32 EnableTxDMA:1;
UINT32 TxDMABusy:1;
UINT32 EnableRxDMA:1;
UINT32 RxDMABusy:1;
UINT32 WPDMABurstSIZE:2;
UINT32 EnTXWriteBackDDONE:1;
UINT32 BigEndian:1;
UINT32 RXHdrScater:8;
UINT32 HDR_SEG_LEN:16;
} field;
UINT32 word;
} WPDMA_GLO_CFG_STRUC, *PWPDMA_GLO_CFG_STRUC;
#endif
#define WPDMA_RST_IDX 0x20c
#ifdef RT_BIG_ENDIAN
typedef union _WPDMA_RST_IDX_STRUC {
struct {
UINT32 :15;
UINT32 RST_DRX_IDX0:1;
UINT32 rsv:10;
UINT32 RST_DTX_IDX5:1;
UINT32 RST_DTX_IDX4:1;
UINT32 RST_DTX_IDX3:1;
UINT32 RST_DTX_IDX2:1;
UINT32 RST_DTX_IDX1:1;
UINT32 RST_DTX_IDX0:1;
} field;
UINT32 word;
}WPDMA_RST_IDX_STRUC, *PWPDMA_RST_IDX_STRUC;
#else
typedef union _WPDMA_RST_IDX_STRUC {
struct {
UINT32 RST_DTX_IDX0:1;
UINT32 RST_DTX_IDX1:1;
UINT32 RST_DTX_IDX2:1;
UINT32 RST_DTX_IDX3:1;
UINT32 RST_DTX_IDX4:1;
UINT32 RST_DTX_IDX5:1;
UINT32 rsv:10;
UINT32 RST_DRX_IDX0:1;
UINT32 :15;
} field;
UINT32 word;
} WPDMA_RST_IDX_STRUC, *PWPDMA_RST_IDX_STRUC;
#endif
#define DELAY_INT_CFG 0x0210
#ifdef RT_BIG_ENDIAN
typedef union _DELAY_INT_CFG_STRUC {
struct {
UINT32 TXDLY_INT_EN:1;
UINT32 TXMAX_PINT:7;
UINT32 TXMAX_PTIME:8;
UINT32 RXDLY_INT_EN:1;
UINT32 RXMAX_PINT:7;
UINT32 RXMAX_PTIME:8;
} field;
UINT32 word;
}DELAY_INT_CFG_STRUC, *PDELAY_INT_CFG_STRUC;
#else
typedef union _DELAY_INT_CFG_STRUC {
struct {
UINT32 RXMAX_PTIME:8;
UINT32 RXMAX_PINT:7;
UINT32 RXDLY_INT_EN:1;
UINT32 TXMAX_PTIME:8;
UINT32 TXMAX_PINT:7;
UINT32 TXDLY_INT_EN:1;
} field;
UINT32 word;
} DELAY_INT_CFG_STRUC, *PDELAY_INT_CFG_STRUC;
#endif
#define WMM_AIFSN_CFG 0x0214
#ifdef RT_BIG_ENDIAN
typedef union _AIFSN_CSR_STRUC {
struct {
UINT32 Rsv:16;
UINT32 Aifsn3:4; // for AC_VO
UINT32 Aifsn2:4; // for AC_VI
UINT32 Aifsn1:4; // for AC_BK
UINT32 Aifsn0:4; // for AC_BE
} field;
UINT32 word;
} AIFSN_CSR_STRUC, *PAIFSN_CSR_STRUC;
#else
typedef union _AIFSN_CSR_STRUC {
struct {
UINT32 Aifsn0:4; // for AC_BE
UINT32 Aifsn1:4; // for AC_BK
UINT32 Aifsn2:4; // for AC_VI
UINT32 Aifsn3:4; // for AC_VO
UINT32 Rsv:16;
} field;
UINT32 word;
} AIFSN_CSR_STRUC, *PAIFSN_CSR_STRUC;
#endif
//
// CWMIN_CSR: CWmin for each EDCA AC
//
#define WMM_CWMIN_CFG 0x0218
#ifdef RT_BIG_ENDIAN
typedef union _CWMIN_CSR_STRUC {
struct {
UINT32 Rsv:16;
UINT32 Cwmin3:4; // for AC_VO
UINT32 Cwmin2:4; // for AC_VI
UINT32 Cwmin1:4; // for AC_BK
UINT32 Cwmin0:4; // for AC_BE
} field;
UINT32 word;
} CWMIN_CSR_STRUC, *PCWMIN_CSR_STRUC;
#else
typedef union _CWMIN_CSR_STRUC {
struct {
UINT32 Cwmin0:4; // for AC_BE
UINT32 Cwmin1:4; // for AC_BK
UINT32 Cwmin2:4; // for AC_VI
UINT32 Cwmin3:4; // for AC_VO
UINT32 Rsv:16;
} field;
UINT32 word;
} CWMIN_CSR_STRUC, *PCWMIN_CSR_STRUC;
#endif
//
// CWMAX_CSR: CWmin for each EDCA AC
//
#define WMM_CWMAX_CFG 0x021c
#ifdef RT_BIG_ENDIAN
typedef union _CWMAX_CSR_STRUC {
struct {
UINT32 Rsv:16;
UINT32 Cwmax3:4; // for AC_VO
UINT32 Cwmax2:4; // for AC_VI
UINT32 Cwmax1:4; // for AC_BK
UINT32 Cwmax0:4; // for AC_BE
} field;
UINT32 word;
} CWMAX_CSR_STRUC, *PCWMAX_CSR_STRUC;
#else
typedef union _CWMAX_CSR_STRUC {
struct {
UINT32 Cwmax0:4; // for AC_BE
UINT32 Cwmax1:4; // for AC_BK
UINT32 Cwmax2:4; // for AC_VI
UINT32 Cwmax3:4; // for AC_VO
UINT32 Rsv:16;
} field;
UINT32 word;
} CWMAX_CSR_STRUC, *PCWMAX_CSR_STRUC;
#endif
//
// AC_TXOP_CSR0: AC_BK/AC_BE TXOP register
//
#define WMM_TXOP0_CFG 0x0220
#ifdef RT_BIG_ENDIAN
typedef union _AC_TXOP_CSR0_STRUC {
struct {
USHORT Ac1Txop; // for AC_BE, in unit of 32us
USHORT Ac0Txop; // for AC_BK, in unit of 32us
} field;
UINT32 word;
} AC_TXOP_CSR0_STRUC, *PAC_TXOP_CSR0_STRUC;
#else
typedef union _AC_TXOP_CSR0_STRUC {
struct {
USHORT Ac0Txop; // for AC_BK, in unit of 32us
USHORT Ac1Txop; // for AC_BE, in unit of 32us
} field;
UINT32 word;
} AC_TXOP_CSR0_STRUC, *PAC_TXOP_CSR0_STRUC;
#endif
//
// AC_TXOP_CSR1: AC_VO/AC_VI TXOP register
//
#define WMM_TXOP1_CFG 0x0224
#ifdef RT_BIG_ENDIAN
typedef union _AC_TXOP_CSR1_STRUC {
struct {
USHORT Ac3Txop; // for AC_VO, in unit of 32us
USHORT Ac2Txop; // for AC_VI, in unit of 32us
} field;
UINT32 word;
} AC_TXOP_CSR1_STRUC, *PAC_TXOP_CSR1_STRUC;
#else
typedef union _AC_TXOP_CSR1_STRUC {
struct {
USHORT Ac2Txop; // for AC_VI, in unit of 32us
USHORT Ac3Txop; // for AC_VO, in unit of 32us
} field;
UINT32 word;
} AC_TXOP_CSR1_STRUC, *PAC_TXOP_CSR1_STRUC;
#endif
#define RINGREG_DIFF 0x10
#define GPIO_CTRL_CFG 0x0228 //MAC_CSR13
#define MCU_CMD_CFG 0x022c
#define TX_BASE_PTR0 0x0230 //AC_BK base address
#define TX_MAX_CNT0 0x0234
#define TX_CTX_IDX0 0x0238
#define TX_DTX_IDX0 0x023c
#define TX_BASE_PTR1 0x0240 //AC_BE base address
#define TX_MAX_CNT1 0x0244
#define TX_CTX_IDX1 0x0248
#define TX_DTX_IDX1 0x024c
#define TX_BASE_PTR2 0x0250 //AC_VI base address
#define TX_MAX_CNT2 0x0254
#define TX_CTX_IDX2 0x0258
#define TX_DTX_IDX2 0x025c
#define TX_BASE_PTR3 0x0260 //AC_VO base address
#define TX_MAX_CNT3 0x0264
#define TX_CTX_IDX3 0x0268
#define TX_DTX_IDX3 0x026c
#define TX_BASE_PTR4 0x0270 //HCCA base address
#define TX_MAX_CNT4 0x0274
#define TX_CTX_IDX4 0x0278
#define TX_DTX_IDX4 0x027c
#define TX_BASE_PTR5 0x0280 //MGMT base address
#define TX_MAX_CNT5 0x0284
#define TX_CTX_IDX5 0x0288
#define TX_DTX_IDX5 0x028c
#define TX_MGMTMAX_CNT TX_MAX_CNT5
#define TX_MGMTCTX_IDX TX_CTX_IDX5
#define TX_MGMTDTX_IDX TX_DTX_IDX5
#define RX_BASE_PTR 0x0290 //RX base address
#define RX_MAX_CNT 0x0294
#define RX_CRX_IDX 0x0298
#define RX_DRX_IDX 0x029c
#define USB_DMA_CFG 0x02a0
#ifdef RT_BIG_ENDIAN
typedef union _USB_DMA_CFG_STRUC {
struct {
UINT32 TxBusy:1; //USB DMA TX FSM busy . debug only
UINT32 RxBusy:1; //USB DMA RX FSM busy . debug only
UINT32 EpoutValid:6; //OUT endpoint data valid. debug only
UINT32 TxBulkEn:1; //Enable USB DMA Tx
UINT32 RxBulkEn:1; //Enable USB DMA Rx
UINT32 RxBulkAggEn:1; //Enable Rx Bulk Aggregation
UINT32 TxopHalt:1; //Halt TXOP count down when TX buffer is full.
UINT32 TxClear:1; //Clear USB DMA TX path
UINT32 rsv:2;
UINT32 phyclear:1; //phy watch dog enable. write 1
UINT32 RxBulkAggLmt:8; //Rx Bulk Aggregation Limit in unit of 1024 bytes
UINT32 RxBulkAggTOut:8; //Rx Bulk Aggregation TimeOut in unit of 33ns
} field;
UINT32 word;
} USB_DMA_CFG_STRUC, *PUSB_DMA_CFG_STRUC;
#else
typedef union _USB_DMA_CFG_STRUC {
struct {
UINT32 RxBulkAggTOut:8; //Rx Bulk Aggregation TimeOut in unit of 33ns
UINT32 RxBulkAggLmt:8; //Rx Bulk Aggregation Limit in unit of 256 bytes
UINT32 phyclear:1; //phy watch dog enable. write 1
UINT32 rsv:2;
UINT32 TxClear:1; //Clear USB DMA TX path
UINT32 TxopHalt:1; //Halt TXOP count down when TX buffer is full.
UINT32 RxBulkAggEn:1; //Enable Rx Bulk Aggregation
UINT32 RxBulkEn:1; //Enable USB DMA Rx
UINT32 TxBulkEn:1; //Enable USB DMA Tx
UINT32 EpoutValid:6; //OUT endpoint data valid
UINT32 RxBusy:1; //USB DMA RX FSM busy
UINT32 TxBusy:1; //USB DMA TX FSM busy
} field;
UINT32 word;
} USB_DMA_CFG_STRUC, *PUSB_DMA_CFG_STRUC;
#endif
//
// 3 PBF registers
//
//
// Most are for debug. Driver doesn't touch PBF register.
#define PBF_SYS_CTRL 0x0400
#define PBF_CFG 0x0408
#define PBF_MAX_PCNT 0x040C
#define PBF_CTRL 0x0410
#define PBF_INT_STA 0x0414
#define PBF_INT_ENA 0x0418
#define TXRXQ_PCNT 0x0438
#define PBF_DBG 0x043c
#define PBF_CAP_CTRL 0x0440
// eFuse registers
#define EFUSE_CTRL 0x0580
#define EFUSE_DATA0 0x0590
#define EFUSE_DATA1 0x0594
#define EFUSE_DATA2 0x0598
#define EFUSE_DATA3 0x059c
#define EFUSE_USAGE_MAP_START 0x2d0
#define EFUSE_USAGE_MAP_END 0x2fc
#define EFUSE_TAG 0x2fe
#define EFUSE_USAGE_MAP_SIZE 45
#ifdef RT_BIG_ENDIAN
typedef union _EFUSE_CTRL_STRUC {
struct {
UINT32 SEL_EFUSE:1;
UINT32 EFSROM_KICK:1;
UINT32 RESERVED:4;
UINT32 EFSROM_AIN:10;
UINT32 EFSROM_LDO_ON_TIME:2;
UINT32 EFSROM_LDO_OFF_TIME:6;
UINT32 EFSROM_MODE:2;
UINT32 EFSROM_AOUT:6;
} field;
UINT32 word;
} EFUSE_CTRL_STRUC, *PEFUSE_CTRL_STRUC;
#else
typedef union _EFUSE_CTRL_STRUC {
struct {
UINT32 EFSROM_AOUT:6;
UINT32 EFSROM_MODE:2;
UINT32 EFSROM_LDO_OFF_TIME:6;
UINT32 EFSROM_LDO_ON_TIME:2;
UINT32 EFSROM_AIN:10;
UINT32 RESERVED:4;
UINT32 EFSROM_KICK:1;
UINT32 SEL_EFUSE:1;
} field;
UINT32 word;
} EFUSE_CTRL_STRUC, *PEFUSE_CTRL_STRUC;
#endif // RT_BIG_ENDIAN //
#define LDO_CFG0 0x05d4
#define GPIO_SWITCH 0x05dc
//
// 4 MAC registers
//
//
// 4.1 MAC SYSTEM configuration registers (offset:0x1000)
//
#define MAC_CSR0 0x1000
#ifdef RT_BIG_ENDIAN
typedef union _ASIC_VER_ID_STRUC {
struct {
USHORT ASICVer; // version : 2860
USHORT ASICRev; // reversion : 0
} field;
UINT32 word;
} ASIC_VER_ID_STRUC, *PASIC_VER_ID_STRUC;
#else
typedef union _ASIC_VER_ID_STRUC {
struct {
USHORT ASICRev; // reversion : 0
USHORT ASICVer; // version : 2860
} field;
UINT32 word;
} ASIC_VER_ID_STRUC, *PASIC_VER_ID_STRUC;
#endif
#define MAC_SYS_CTRL 0x1004 //MAC_CSR1
#define MAC_ADDR_DW0 0x1008 // MAC ADDR DW0
#define MAC_ADDR_DW1 0x100c // MAC ADDR DW1
//
// MAC_CSR2: STA MAC register 0
//
#ifdef RT_BIG_ENDIAN
typedef union _MAC_DW0_STRUC {
struct {
UCHAR Byte3; // MAC address byte 3
UCHAR Byte2; // MAC address byte 2
UCHAR Byte1; // MAC address byte 1
UCHAR Byte0; // MAC address byte 0
} field;
UINT32 word;
} MAC_DW0_STRUC, *PMAC_DW0_STRUC;
#else
typedef union _MAC_DW0_STRUC {
struct {
UCHAR Byte0; // MAC address byte 0
UCHAR Byte1; // MAC address byte 1
UCHAR Byte2; // MAC address byte 2
UCHAR Byte3; // MAC address byte 3
} field;
UINT32 word;
} MAC_DW0_STRUC, *PMAC_DW0_STRUC;
#endif
//
// MAC_CSR3: STA MAC register 1
//
#ifdef RT_BIG_ENDIAN
typedef union _MAC_DW1_STRUC {
struct {
UCHAR Rsvd1;
UCHAR U2MeMask;
UCHAR Byte5; // MAC address byte 5
UCHAR Byte4; // MAC address byte 4
} field;
UINT32 word;
} MAC_DW1_STRUC, *PMAC_DW1_STRUC;
#else
typedef union _MAC_DW1_STRUC {
struct {
UCHAR Byte4; // MAC address byte 4
UCHAR Byte5; // MAC address byte 5
UCHAR U2MeMask;
UCHAR Rsvd1;
} field;
UINT32 word;
} MAC_DW1_STRUC, *PMAC_DW1_STRUC;
#endif
#define MAC_BSSID_DW0 0x1010 // MAC BSSID DW0
#define MAC_BSSID_DW1 0x1014 // MAC BSSID DW1
//
// MAC_CSR5: BSSID register 1
//
#ifdef RT_BIG_ENDIAN
typedef union _MAC_CSR5_STRUC {
struct {
USHORT Rsvd:11;
USHORT MBssBcnNum:3;
USHORT BssIdMode:2; // 0: one BSSID, 10: 4 BSSID, 01: 2 BSSID , 11: 8BSSID
UCHAR Byte5; // BSSID byte 5
UCHAR Byte4; // BSSID byte 4
} field;
UINT32 word;
} MAC_CSR5_STRUC, *PMAC_CSR5_STRUC;
#else
typedef union _MAC_CSR5_STRUC {
struct {
UCHAR Byte4; // BSSID byte 4
UCHAR Byte5; // BSSID byte 5
USHORT BssIdMask:2; // 0: one BSSID, 10: 4 BSSID, 01: 2 BSSID , 11: 8BSSID
USHORT MBssBcnNum:3;
USHORT Rsvd:11;
} field;
UINT32 word;
} MAC_CSR5_STRUC, *PMAC_CSR5_STRUC;
#endif
#define MAX_LEN_CFG 0x1018 // rt2860b max 16k bytes. bit12:13 Maximum PSDU length (power factor) 0:2^13, 1:2^14, 2:2^15, 3:2^16
#define BBP_CSR_CFG 0x101c //
//
// BBP_CSR_CFG: BBP serial control register
//
#ifdef RT_BIG_ENDIAN
typedef union _BBP_CSR_CFG_STRUC {
struct {
UINT32 :12;
UINT32 BBP_RW_MODE:1; // 0: use serial mode 1:parallel
UINT32 BBP_PAR_DUR:1; // 0: 4 MAC clock cycles 1: 8 MAC clock cycles
UINT32 Busy:1; // 1: ASIC is busy execute BBP programming.
UINT32 fRead:1; // 0: Write BBP, 1: Read BBP
UINT32 RegNum:8; // Selected BBP register
UINT32 Value:8; // Register value to program into BBP
} field;
UINT32 word;
} BBP_CSR_CFG_STRUC, *PBBP_CSR_CFG_STRUC;
#else
typedef union _BBP_CSR_CFG_STRUC {
struct {
UINT32 Value:8; // Register value to program into BBP
UINT32 RegNum:8; // Selected BBP register
UINT32 fRead:1; // 0: Write BBP, 1: Read BBP
UINT32 Busy:1; // 1: ASIC is busy execute BBP programming.
UINT32 BBP_PAR_DUR:1; // 0: 4 MAC clock cycles 1: 8 MAC clock cycles
UINT32 BBP_RW_MODE:1; // 0: use serial mode 1:parallel
UINT32 :12;
} field;
UINT32 word;
} BBP_CSR_CFG_STRUC, *PBBP_CSR_CFG_STRUC;
#endif
#define RF_CSR_CFG0 0x1020
//
// RF_CSR_CFG: RF control register
//
#ifdef RT_BIG_ENDIAN
typedef union _RF_CSR_CFG0_STRUC {
struct {
UINT32 Busy:1; // 0: idle 1: 8busy
UINT32 Sel:1; // 0:RF_LE0 activate 1:RF_LE1 activate
UINT32 StandbyMode:1; // 0: high when stand by 1: low when standby
UINT32 bitwidth:5; // Selected BBP register
UINT32 RegIdAndContent:24; // Register value to program into BBP
} field;
UINT32 word;
} RF_CSR_CFG0_STRUC, *PRF_CSR_CFG0_STRUC;
#else
typedef union _RF_CSR_CFG0_STRUC {
struct {
UINT32 RegIdAndContent:24; // Register value to program into BBP
UINT32 bitwidth:5; // Selected BBP register
UINT32 StandbyMode:1; // 0: high when stand by 1: low when standby
UINT32 Sel:1; // 0:RF_LE0 activate 1:RF_LE1 activate
UINT32 Busy:1; // 0: idle 1: 8busy
} field;
UINT32 word;
} RF_CSR_CFG0_STRUC, *PRF_CSR_CFG0_STRUC;
#endif
#define RF_CSR_CFG1 0x1024
#ifdef RT_BIG_ENDIAN
typedef union _RF_CSR_CFG1_STRUC {
struct {
UINT32 rsv:7; // 0: idle 1: 8busy
UINT32 RFGap:5; // Gap between BB_CONTROL_RF and RF_LE. 0: 3 system clock cycle (37.5usec) 1: 5 system clock cycle (62.5usec)
UINT32 RegIdAndContent:24; // Register value to program into BBP
} field;
UINT32 word;
} RF_CSR_CFG1_STRUC, *PRF_CSR_CFG1_STRUC;
#else
typedef union _RF_CSR_CFG1_STRUC {
struct {
UINT32 RegIdAndContent:24; // Register value to program into BBP
UINT32 RFGap:5; // Gap between BB_CONTROL_RF and RF_LE. 0: 3 system clock cycle (37.5usec) 1: 5 system clock cycle (62.5usec)
UINT32 rsv:7; // 0: idle 1: 8busy
} field;
UINT32 word;
} RF_CSR_CFG1_STRUC, *PRF_CSR_CFG1_STRUC;
#endif
#define RF_CSR_CFG2 0x1028 //
#ifdef RT_BIG_ENDIAN
typedef union _RF_CSR_CFG2_STRUC {
struct {
UINT32 rsv:8; // 0: idle 1: 8busy
UINT32 RegIdAndContent:24; // Register value to program into BBP
} field;
UINT32 word;
} RF_CSR_CFG2_STRUC, *PRF_CSR_CFG2_STRUC;
#else
typedef union _RF_CSR_CFG2_STRUC {
struct {
UINT32 RegIdAndContent:24; // Register value to program into BBP
UINT32 rsv:8; // 0: idle 1: 8busy
} field;
UINT32 word;
} RF_CSR_CFG2_STRUC, *PRF_CSR_CFG2_STRUC;
#endif
#define LED_CFG 0x102c // MAC_CSR14
#ifdef RT_BIG_ENDIAN
typedef union _LED_CFG_STRUC {
struct {
UINT32 :1;
UINT32 LedPolar:1; // Led Polarity. 0: active low1: active high
UINT32 YLedMode:2; // yellow Led Mode
UINT32 GLedMode:2; // green Led Mode
UINT32 RLedMode:2; // red Led Mode 0: off1: blinking upon TX2: periodic slow blinking3: always on
UINT32 rsv:2;
UINT32 SlowBlinkPeriod:6; // slow blinking period. unit:1ms
UINT32 OffPeriod:8; // blinking off period unit 1ms
UINT32 OnPeriod:8; // blinking on period unit 1ms
} field;
UINT32 word;
} LED_CFG_STRUC, *PLED_CFG_STRUC;
#else
typedef union _LED_CFG_STRUC {
struct {
UINT32 OnPeriod:8; // blinking on period unit 1ms
UINT32 OffPeriod:8; // blinking off period unit 1ms
UINT32 SlowBlinkPeriod:6; // slow blinking period. unit:1ms
UINT32 rsv:2;
UINT32 RLedMode:2; // red Led Mode 0: off1: blinking upon TX2: periodic slow blinking3: always on
UINT32 GLedMode:2; // green Led Mode
UINT32 YLedMode:2; // yellow Led Mode
UINT32 LedPolar:1; // Led Polarity. 0: active low1: active high
UINT32 :1;
} field;
UINT32 word;
} LED_CFG_STRUC, *PLED_CFG_STRUC;
#endif
//
// 4.2 MAC TIMING configuration registers (offset:0x1100)
//
#define XIFS_TIME_CFG 0x1100 // MAC_CSR8 MAC_CSR9
#ifdef RT_BIG_ENDIAN
typedef union _IFS_SLOT_CFG_STRUC {
struct {
UINT32 rsv:2;
UINT32 BBRxendEnable:1; // reference RXEND signal to begin XIFS defer
UINT32 EIFS:9; // unit 1us
UINT32 OfdmXifsTime:4; //OFDM SIFS. unit 1us. Applied after OFDM RX when MAC doesn't reference BBP signal BBRXEND
UINT32 OfdmSifsTime:8; // unit 1us. Applied after OFDM RX/TX
UINT32 CckmSifsTime:8; // unit 1us. Applied after CCK RX/TX
} field;
UINT32 word;
} IFS_SLOT_CFG_STRUC, *PIFS_SLOT_CFG_STRUC;
#else
typedef union _IFS_SLOT_CFG_STRUC {
struct {
UINT32 CckmSifsTime:8; // unit 1us. Applied after CCK RX/TX
UINT32 OfdmSifsTime:8; // unit 1us. Applied after OFDM RX/TX
UINT32 OfdmXifsTime:4; //OFDM SIFS. unit 1us. Applied after OFDM RX when MAC doesn't reference BBP signal BBRXEND
UINT32 EIFS:9; // unit 1us
UINT32 BBRxendEnable:1; // reference RXEND signal to begin XIFS defer
UINT32 rsv:2;
} field;
UINT32 word;
} IFS_SLOT_CFG_STRUC, *PIFS_SLOT_CFG_STRUC;
#endif
#define BKOFF_SLOT_CFG 0x1104 // mac_csr9 last 8 bits
#define NAV_TIME_CFG 0x1108 // NAV (MAC_CSR15)
#define CH_TIME_CFG 0x110C // Count as channel busy
#define PBF_LIFE_TIMER 0x1110 //TX/RX MPDU timestamp timer (free run)Unit: 1us
#define BCN_TIME_CFG 0x1114 // TXRX_CSR9
#define BCN_OFFSET0 0x042C
#define BCN_OFFSET1 0x0430
//
// BCN_TIME_CFG : Synchronization control register
//
#ifdef RT_BIG_ENDIAN
typedef union _BCN_TIME_CFG_STRUC {
struct {
UINT32 TxTimestampCompensate:8;
UINT32 :3;
UINT32 bBeaconGen:1; // Enable beacon generator
UINT32 bTBTTEnable:1;
UINT32 TsfSyncMode:2; // Enable TSF sync, 00: disable, 01: infra mode, 10: ad-hoc mode
UINT32 bTsfTicking:1; // Enable TSF auto counting
UINT32 BeaconInterval:16; // in unit of 1/16 TU
} field;
UINT32 word;
} BCN_TIME_CFG_STRUC, *PBCN_TIME_CFG_STRUC;
#else
typedef union _BCN_TIME_CFG_STRUC {
struct {
UINT32 BeaconInterval:16; // in unit of 1/16 TU
UINT32 bTsfTicking:1; // Enable TSF auto counting
UINT32 TsfSyncMode:2; // Enable TSF sync, 00: disable, 01: infra mode, 10: ad-hoc mode
UINT32 bTBTTEnable:1;
UINT32 bBeaconGen:1; // Enable beacon generator
UINT32 :3;
UINT32 TxTimestampCompensate:8;
} field;
UINT32 word;
} BCN_TIME_CFG_STRUC, *PBCN_TIME_CFG_STRUC;
#endif
#define TBTT_SYNC_CFG 0x1118 // txrx_csr10
#define TSF_TIMER_DW0 0x111C // Local TSF timer lsb 32 bits. Read-only
#define TSF_TIMER_DW1 0x1120 // msb 32 bits. Read-only.
#define TBTT_TIMER 0x1124 // TImer remains till next TBTT. Read-only. TXRX_CSR14
#define INT_TIMER_CFG 0x1128 //
#define INT_TIMER_EN 0x112c // GP-timer and pre-tbtt Int enable
#define CH_IDLE_STA 0x1130 // channel idle time
#define CH_BUSY_STA 0x1134 // channle busy time
//
// 4.2 MAC POWER configuration registers (offset:0x1200)
//
#define MAC_STATUS_CFG 0x1200 // old MAC_CSR12
#define PWR_PIN_CFG 0x1204 // old MAC_CSR12
#define AUTO_WAKEUP_CFG 0x1208 // old MAC_CSR10
//
// AUTO_WAKEUP_CFG: Manual power control / status register
//
#ifdef RT_BIG_ENDIAN
typedef union _AUTO_WAKEUP_STRUC {
struct {
UINT32 :16;
UINT32 EnableAutoWakeup:1; // 0:sleep, 1:awake
UINT32 NumofSleepingTbtt:7; // ForceWake has high privilege than PutToSleep when both set
UINT32 AutoLeadTime:8;
} field;
UINT32 word;
} AUTO_WAKEUP_STRUC, *PAUTO_WAKEUP_STRUC;
#else
typedef union _AUTO_WAKEUP_STRUC {
struct {
UINT32 AutoLeadTime:8;
UINT32 NumofSleepingTbtt:7; // ForceWake has high privilege than PutToSleep when both set
UINT32 EnableAutoWakeup:1; // 0:sleep, 1:awake
UINT32 :16;
} field;
UINT32 word;
} AUTO_WAKEUP_STRUC, *PAUTO_WAKEUP_STRUC;
#endif
//
// 4.3 MAC TX configuration registers (offset:0x1300)
//
#define EDCA_AC0_CFG 0x1300 //AC_TXOP_CSR0 0x3474
#define EDCA_AC1_CFG 0x1304
#define EDCA_AC2_CFG 0x1308
#define EDCA_AC3_CFG 0x130c
#ifdef RT_BIG_ENDIAN
typedef union _EDCA_AC_CFG_STRUC {
struct {
UINT32 :12; //
UINT32 Cwmax:4; //unit power of 2
UINT32 Cwmin:4; //
UINT32 Aifsn:4; // # of slot time
UINT32 AcTxop:8; // in unit of 32us
} field;
UINT32 word;
} EDCA_AC_CFG_STRUC, *PEDCA_AC_CFG_STRUC;
#else
typedef union _EDCA_AC_CFG_STRUC {
struct {
UINT32 AcTxop:8; // in unit of 32us
UINT32 Aifsn:4; // # of slot time
UINT32 Cwmin:4; //
UINT32 Cwmax:4; //unit power of 2
UINT32 :12; //
} field;
UINT32 word;
} EDCA_AC_CFG_STRUC, *PEDCA_AC_CFG_STRUC;
#endif
#define EDCA_TID_AC_MAP 0x1310
#define TX_PWR_CFG_0 0x1314
#define TX_PWR_CFG_1 0x1318
#define TX_PWR_CFG_2 0x131C
#define TX_PWR_CFG_3 0x1320
#define TX_PWR_CFG_4 0x1324
#define TX_PIN_CFG 0x1328
#define TX_BAND_CFG 0x132c // 0x1 use upper 20MHz. 0 juse lower 20MHz
#define TX_SW_CFG0 0x1330
#define TX_SW_CFG1 0x1334
#define TX_SW_CFG2 0x1338
#define TXOP_THRES_CFG 0x133c
#define TXOP_CTRL_CFG 0x1340
#define TX_RTS_CFG 0x1344
#ifdef RT_BIG_ENDIAN
typedef union _TX_RTS_CFG_STRUC {
struct {
UINT32 rsv:7;
UINT32 RtsFbkEn:1; // enable rts rate fallback
UINT32 RtsThres:16; // unit:byte
UINT32 AutoRtsRetryLimit:8;
} field;
UINT32 word;
} TX_RTS_CFG_STRUC, *PTX_RTS_CFG_STRUC;
#else
typedef union _TX_RTS_CFG_STRUC {
struct {
UINT32 AutoRtsRetryLimit:8;
UINT32 RtsThres:16; // unit:byte
UINT32 RtsFbkEn:1; // enable rts rate fallback
UINT32 rsv:7; // 1: HT non-STBC control frame enable
} field;
UINT32 word;
} TX_RTS_CFG_STRUC, *PTX_RTS_CFG_STRUC;
#endif
#define TX_TIMEOUT_CFG 0x1348
#ifdef RT_BIG_ENDIAN
typedef union _TX_TIMEOUT_CFG_STRUC {
struct {
UINT32 rsv2:8;
UINT32 TxopTimeout:8; //TXOP timeout value for TXOP truncation. It is recommended that (SLOT_TIME) > (TX_OP_TIMEOUT) > (RX_ACK_TIMEOUT)
UINT32 RxAckTimeout:8; // unit:slot. Used for TX precedure
UINT32 MpduLifeTime:4; // expiration time = 2^(9+MPDU LIFE TIME) us
UINT32 rsv:4;
} field;
UINT32 word;
} TX_TIMEOUT_CFG_STRUC, *PTX_TIMEOUT_CFG_STRUC;
#else
typedef union _TX_TIMEOUT_CFG_STRUC {
struct {
UINT32 rsv:4;
UINT32 MpduLifeTime:4; // expiration time = 2^(9+MPDU LIFE TIME) us
UINT32 RxAckTimeout:8; // unit:slot. Used for TX precedure
UINT32 TxopTimeout:8; //TXOP timeout value for TXOP truncation. It is recommended that (SLOT_TIME) > (TX_OP_TIMEOUT) > (RX_ACK_TIMEOUT)
UINT32 rsv2:8; // 1: HT non-STBC control frame enable
} field;
UINT32 word;
} TX_TIMEOUT_CFG_STRUC, *PTX_TIMEOUT_CFG_STRUC;
#endif
#define TX_RTY_CFG 0x134c
#ifdef RT_BIG_ENDIAN
typedef union PACKED _TX_RTY_CFG_STRUC {
struct {
UINT32 rsv:1;
UINT32 TxautoFBEnable:1; // Tx retry PHY rate auto fallback enable
UINT32 AggRtyMode:1; // Aggregate MPDU retry mode. 0:expired by retry limit, 1: expired by mpdu life timer
UINT32 NonAggRtyMode:1; // Non-Aggregate MPDU retry mode. 0:expired by retry limit, 1: expired by mpdu life timer
UINT32 LongRtyThre:12; // Long retry threshoold
UINT32 LongRtyLimit:8; //long retry limit
UINT32 ShortRtyLimit:8; // short retry limit
} field;
UINT32 word;
} TX_RTY_CFG_STRUC, *PTX_RTY_CFG_STRUC;
#else
typedef union PACKED _TX_RTY_CFG_STRUC {
struct {
UINT32 ShortRtyLimit:8; // short retry limit
UINT32 LongRtyLimit:8; //long retry limit
UINT32 LongRtyThre:12; // Long retry threshoold
UINT32 NonAggRtyMode:1; // Non-Aggregate MPDU retry mode. 0:expired by retry limit, 1: expired by mpdu life timer
UINT32 AggRtyMode:1; // Aggregate MPDU retry mode. 0:expired by retry limit, 1: expired by mpdu life timer
UINT32 TxautoFBEnable:1; // Tx retry PHY rate auto fallback enable
UINT32 rsv:1; // 1: HT non-STBC control frame enable
} field;
UINT32 word;
} TX_RTY_CFG_STRUC, *PTX_RTY_CFG_STRUC;
#endif
#define TX_LINK_CFG 0x1350
#ifdef RT_BIG_ENDIAN
typedef union PACKED _TX_LINK_CFG_STRUC {
struct PACKED {
UINT32 RemotMFS:8; //remote MCS feedback sequence number
UINT32 RemotMFB:8; // remote MCS feedback
UINT32 rsv:3; //
UINT32 TxCFAckEn:1; // Piggyback CF-ACK enable
UINT32 TxRDGEn:1; // RDG TX enable
UINT32 TxMRQEn:1; // MCS request TX enable
UINT32 RemoteUMFSEnable:1; // remote unsolicit MFB enable. 0: not apply remote remote unsolicit (MFS=7)
UINT32 MFBEnable:1; // TX apply remote MFB 1:enable
UINT32 RemoteMFBLifeTime:8; //remote MFB life time. unit : 32us
} field;
UINT32 word;
} TX_LINK_CFG_STRUC, *PTX_LINK_CFG_STRUC;
#else
typedef union PACKED _TX_LINK_CFG_STRUC {
struct PACKED {
UINT32 RemoteMFBLifeTime:8; //remote MFB life time. unit : 32us
UINT32 MFBEnable:1; // TX apply remote MFB 1:enable
UINT32 RemoteUMFSEnable:1; // remote unsolicit MFB enable. 0: not apply remote remote unsolicit (MFS=7)
UINT32 TxMRQEn:1; // MCS request TX enable
UINT32 TxRDGEn:1; // RDG TX enable
UINT32 TxCFAckEn:1; // Piggyback CF-ACK enable
UINT32 rsv:3; //
UINT32 RemotMFB:8; // remote MCS feedback
UINT32 RemotMFS:8; //remote MCS feedback sequence number
} field;
UINT32 word;
} TX_LINK_CFG_STRUC, *PTX_LINK_CFG_STRUC;
#endif
#define HT_FBK_CFG0 0x1354
#ifdef RT_BIG_ENDIAN
typedef union PACKED _HT_FBK_CFG0_STRUC {
struct {
UINT32 HTMCS7FBK:4;
UINT32 HTMCS6FBK:4;
UINT32 HTMCS5FBK:4;
UINT32 HTMCS4FBK:4;
UINT32 HTMCS3FBK:4;
UINT32 HTMCS2FBK:4;
UINT32 HTMCS1FBK:4;
UINT32 HTMCS0FBK:4;
} field;
UINT32 word;
} HT_FBK_CFG0_STRUC, *PHT_FBK_CFG0_STRUC;
#else
typedef union PACKED _HT_FBK_CFG0_STRUC {
struct {
UINT32 HTMCS0FBK:4;
UINT32 HTMCS1FBK:4;
UINT32 HTMCS2FBK:4;
UINT32 HTMCS3FBK:4;
UINT32 HTMCS4FBK:4;
UINT32 HTMCS5FBK:4;
UINT32 HTMCS6FBK:4;
UINT32 HTMCS7FBK:4;
} field;
UINT32 word;
} HT_FBK_CFG0_STRUC, *PHT_FBK_CFG0_STRUC;
#endif
#define HT_FBK_CFG1 0x1358
#ifdef RT_BIG_ENDIAN
typedef union _HT_FBK_CFG1_STRUC {
struct {
UINT32 HTMCS15FBK:4;
UINT32 HTMCS14FBK:4;
UINT32 HTMCS13FBK:4;
UINT32 HTMCS12FBK:4;
UINT32 HTMCS11FBK:4;
UINT32 HTMCS10FBK:4;
UINT32 HTMCS9FBK:4;
UINT32 HTMCS8FBK:4;
} field;
UINT32 word;
} HT_FBK_CFG1_STRUC, *PHT_FBK_CFG1_STRUC;
#else
typedef union _HT_FBK_CFG1_STRUC {
struct {
UINT32 HTMCS8FBK:4;
UINT32 HTMCS9FBK:4;
UINT32 HTMCS10FBK:4;
UINT32 HTMCS11FBK:4;
UINT32 HTMCS12FBK:4;
UINT32 HTMCS13FBK:4;
UINT32 HTMCS14FBK:4;
UINT32 HTMCS15FBK:4;
} field;
UINT32 word;
} HT_FBK_CFG1_STRUC, *PHT_FBK_CFG1_STRUC;
#endif
#define LG_FBK_CFG0 0x135c
#ifdef RT_BIG_ENDIAN
typedef union _LG_FBK_CFG0_STRUC {
struct {
UINT32 OFDMMCS7FBK:4; //initial value is 6
UINT32 OFDMMCS6FBK:4; //initial value is 5
UINT32 OFDMMCS5FBK:4; //initial value is 4
UINT32 OFDMMCS4FBK:4; //initial value is 3
UINT32 OFDMMCS3FBK:4; //initial value is 2
UINT32 OFDMMCS2FBK:4; //initial value is 1
UINT32 OFDMMCS1FBK:4; //initial value is 0
UINT32 OFDMMCS0FBK:4; //initial value is 0
} field;
UINT32 word;
} LG_FBK_CFG0_STRUC, *PLG_FBK_CFG0_STRUC;
#else
typedef union _LG_FBK_CFG0_STRUC {
struct {
UINT32 OFDMMCS0FBK:4; //initial value is 0
UINT32 OFDMMCS1FBK:4; //initial value is 0
UINT32 OFDMMCS2FBK:4; //initial value is 1
UINT32 OFDMMCS3FBK:4; //initial value is 2
UINT32 OFDMMCS4FBK:4; //initial value is 3
UINT32 OFDMMCS5FBK:4; //initial value is 4
UINT32 OFDMMCS6FBK:4; //initial value is 5
UINT32 OFDMMCS7FBK:4; //initial value is 6
} field;
UINT32 word;
} LG_FBK_CFG0_STRUC, *PLG_FBK_CFG0_STRUC;
#endif
#define LG_FBK_CFG1 0x1360
#ifdef RT_BIG_ENDIAN
typedef union _LG_FBK_CFG1_STRUC {
struct {
UINT32 rsv:16;
UINT32 CCKMCS3FBK:4; //initial value is 2
UINT32 CCKMCS2FBK:4; //initial value is 1
UINT32 CCKMCS1FBK:4; //initial value is 0
UINT32 CCKMCS0FBK:4; //initial value is 0
} field;
UINT32 word;
} LG_FBK_CFG1_STRUC, *PLG_FBK_CFG1_STRUC;
#else
typedef union _LG_FBK_CFG1_STRUC {
struct {
UINT32 CCKMCS0FBK:4; //initial value is 0
UINT32 CCKMCS1FBK:4; //initial value is 0
UINT32 CCKMCS2FBK:4; //initial value is 1
UINT32 CCKMCS3FBK:4; //initial value is 2
UINT32 rsv:16;
} field;
UINT32 word;
} LG_FBK_CFG1_STRUC, *PLG_FBK_CFG1_STRUC;
#endif
//=======================================================
//================ Protection Paramater================================
//=======================================================
#define CCK_PROT_CFG 0x1364 //CCK Protection
#define ASIC_SHORTNAV 1
#define ASIC_LONGNAV 2
#define ASIC_RTS 1
#define ASIC_CTS 2
#ifdef RT_BIG_ENDIAN
typedef union _PROT_CFG_STRUC {
struct {
UINT32 rsv:5;
UINT32 RTSThEn:1; //RTS threshold enable on CCK TX
UINT32 TxopAllowGF40:1; //CCK TXOP allowance.0:disallow.
UINT32 TxopAllowGF20:1; //CCK TXOP allowance.0:disallow.
UINT32 TxopAllowMM40:1; //CCK TXOP allowance.0:disallow.
UINT32 TxopAllowMM20:1; //CCK TXOP allowance. 0:disallow.
UINT32 TxopAllowOfdm:1; //CCK TXOP allowance.0:disallow.
UINT32 TxopAllowCck:1; //CCK TXOP allowance.0:disallow.
UINT32 ProtectNav:2; //TXOP protection type for CCK TX. 0:None, 1:ShortNAVprotect, 2:LongNAVProtect, 3:rsv
UINT32 ProtectCtrl:2; //Protection control frame type for CCK TX. 1:RTS/CTS, 2:CTS-to-self, 0:None, 3:rsv
UINT32 ProtectRate:16; //Protection control frame rate for CCK TX(RTS/CTS/CFEnd).
} field;
UINT32 word;
} PROT_CFG_STRUC, *PPROT_CFG_STRUC;
#else
typedef union _PROT_CFG_STRUC {
struct {
UINT32 ProtectRate:16; //Protection control frame rate for CCK TX(RTS/CTS/CFEnd).
UINT32 ProtectCtrl:2; //Protection control frame type for CCK TX. 1:RTS/CTS, 2:CTS-to-self, 0:None, 3:rsv
UINT32 ProtectNav:2; //TXOP protection type for CCK TX. 0:None, 1:ShortNAVprotect, 2:LongNAVProtect, 3:rsv
UINT32 TxopAllowCck:1; //CCK TXOP allowance.0:disallow.
UINT32 TxopAllowOfdm:1; //CCK TXOP allowance.0:disallow.
UINT32 TxopAllowMM20:1; //CCK TXOP allowance. 0:disallow.
UINT32 TxopAllowMM40:1; //CCK TXOP allowance.0:disallow.
UINT32 TxopAllowGF20:1; //CCK TXOP allowance.0:disallow.
UINT32 TxopAllowGF40:1; //CCK TXOP allowance.0:disallow.
UINT32 RTSThEn:1; //RTS threshold enable on CCK TX
UINT32 rsv:5;
} field;
UINT32 word;
} PROT_CFG_STRUC, *PPROT_CFG_STRUC;
#endif
#define OFDM_PROT_CFG 0x1368 //OFDM Protection
#define MM20_PROT_CFG 0x136C //MM20 Protection
#define MM40_PROT_CFG 0x1370 //MM40 Protection
#define GF20_PROT_CFG 0x1374 //GF20 Protection
#define GF40_PROT_CFG 0x1378 //GR40 Protection
#define EXP_CTS_TIME 0x137C //
#define EXP_ACK_TIME 0x1380 //
//
// 4.4 MAC RX configuration registers (offset:0x1400)
//
#define RX_FILTR_CFG 0x1400 //TXRX_CSR0
#define AUTO_RSP_CFG 0x1404 //TXRX_CSR4
//
// TXRX_CSR4: Auto-Responder/
//
#ifdef RT_BIG_ENDIAN
typedef union _AUTO_RSP_CFG_STRUC {
struct {
UINT32 :24;
UINT32 AckCtsPsmBit:1; // Power bit value in conrtrol frame
UINT32 DualCTSEn:1; // Power bit value in conrtrol frame
UINT32 rsv:1; // Power bit value in conrtrol frame
UINT32 AutoResponderPreamble:1; // 0:long, 1:short preamble
UINT32 CTS40MRef:1; // Response CTS 40MHz duplicate mode
UINT32 CTS40MMode:1; // Response CTS 40MHz duplicate mode
UINT32 BACAckPolicyEnable:1; // 0:long, 1:short preamble
UINT32 AutoResponderEnable:1;
} field;
UINT32 word;
} AUTO_RSP_CFG_STRUC, *PAUTO_RSP_CFG_STRUC;
#else
typedef union _AUTO_RSP_CFG_STRUC {
struct {
UINT32 AutoResponderEnable:1;
UINT32 BACAckPolicyEnable:1; // 0:long, 1:short preamble
UINT32 CTS40MMode:1; // Response CTS 40MHz duplicate mode
UINT32 CTS40MRef:1; // Response CTS 40MHz duplicate mode
UINT32 AutoResponderPreamble:1; // 0:long, 1:short preamble
UINT32 rsv:1; // Power bit value in conrtrol frame
UINT32 DualCTSEn:1; // Power bit value in conrtrol frame
UINT32 AckCtsPsmBit:1; // Power bit value in conrtrol frame
UINT32 :24;
} field;
UINT32 word;
} AUTO_RSP_CFG_STRUC, *PAUTO_RSP_CFG_STRUC;
#endif
#define LEGACY_BASIC_RATE 0x1408 // TXRX_CSR5 0x3054
#define HT_BASIC_RATE 0x140c
#define HT_CTRL_CFG 0x1410
#define SIFS_COST_CFG 0x1414
#define RX_PARSER_CFG 0x1418 //Set NAV for all received frames
//
// 4.5 MAC Security configuration (offset:0x1500)
//
#define TX_SEC_CNT0 0x1500 //
#define RX_SEC_CNT0 0x1504 //
#define CCMP_FC_MUTE 0x1508 //
//
// 4.6 HCCA/PSMP (offset:0x1600)
//
#define TXOP_HLDR_ADDR0 0x1600
#define TXOP_HLDR_ADDR1 0x1604
#define TXOP_HLDR_ET 0x1608
#define QOS_CFPOLL_RA_DW0 0x160c
#define QOS_CFPOLL_A1_DW1 0x1610
#define QOS_CFPOLL_QC 0x1614
//
// 4.7 MAC Statistis registers (offset:0x1700)
//
#define RX_STA_CNT0 0x1700 //
#define RX_STA_CNT1 0x1704 //
#define RX_STA_CNT2 0x1708 //
//
// RX_STA_CNT0_STRUC: RX PLCP error count & RX CRC error count
//
#ifdef RT_BIG_ENDIAN
typedef union _RX_STA_CNT0_STRUC {
struct {
USHORT PhyErr;
USHORT CrcErr;
} field;
UINT32 word;
} RX_STA_CNT0_STRUC, *PRX_STA_CNT0_STRUC;
#else
typedef union _RX_STA_CNT0_STRUC {
struct {
USHORT CrcErr;
USHORT PhyErr;
} field;
UINT32 word;
} RX_STA_CNT0_STRUC, *PRX_STA_CNT0_STRUC;
#endif
//
// RX_STA_CNT1_STRUC: RX False CCA count & RX LONG frame count
//
#ifdef RT_BIG_ENDIAN
typedef union _RX_STA_CNT1_STRUC {
struct {
USHORT PlcpErr;
USHORT FalseCca;
} field;
UINT32 word;
} RX_STA_CNT1_STRUC, *PRX_STA_CNT1_STRUC;
#else
typedef union _RX_STA_CNT1_STRUC {
struct {
USHORT FalseCca;
USHORT PlcpErr;
} field;
UINT32 word;
} RX_STA_CNT1_STRUC, *PRX_STA_CNT1_STRUC;
#endif
//
// RX_STA_CNT2_STRUC:
//
#ifdef RT_BIG_ENDIAN
typedef union _RX_STA_CNT2_STRUC {
struct {
USHORT RxFifoOverflowCount;
USHORT RxDupliCount;
} field;
UINT32 word;
} RX_STA_CNT2_STRUC, *PRX_STA_CNT2_STRUC;
#else
typedef union _RX_STA_CNT2_STRUC {
struct {
USHORT RxDupliCount;
USHORT RxFifoOverflowCount;
} field;
UINT32 word;
} RX_STA_CNT2_STRUC, *PRX_STA_CNT2_STRUC;
#endif
#define TX_STA_CNT0 0x170C //
//
// STA_CSR3: TX Beacon count
//
#ifdef RT_BIG_ENDIAN
typedef union _TX_STA_CNT0_STRUC {
struct {
USHORT TxBeaconCount;
USHORT TxFailCount;
} field;
UINT32 word;
} TX_STA_CNT0_STRUC, *PTX_STA_CNT0_STRUC;
#else
typedef union _TX_STA_CNT0_STRUC {
struct {
USHORT TxFailCount;
USHORT TxBeaconCount;
} field;
UINT32 word;
} TX_STA_CNT0_STRUC, *PTX_STA_CNT0_STRUC;
#endif
#define TX_STA_CNT1 0x1710 //
//
// TX_STA_CNT1: TX tx count
//
#ifdef RT_BIG_ENDIAN
typedef union _TX_STA_CNT1_STRUC {
struct {
USHORT TxRetransmit;
USHORT TxSuccess;
} field;
UINT32 word;
} TX_STA_CNT1_STRUC, *PTX_STA_CNT1_STRUC;
#else
typedef union _TX_STA_CNT1_STRUC {
struct {
USHORT TxSuccess;
USHORT TxRetransmit;
} field;
UINT32 word;
} TX_STA_CNT1_STRUC, *PTX_STA_CNT1_STRUC;
#endif
#define TX_STA_CNT2 0x1714 //
//
// TX_STA_CNT2: TX tx count
//
#ifdef RT_BIG_ENDIAN
typedef union _TX_STA_CNT2_STRUC {
struct {
USHORT TxUnderFlowCount;
USHORT TxZeroLenCount;
} field;
UINT32 word;
} TX_STA_CNT2_STRUC, *PTX_STA_CNT2_STRUC;
#else
typedef union _TX_STA_CNT2_STRUC {
struct {
USHORT TxZeroLenCount;
USHORT TxUnderFlowCount;
} field;
UINT32 word;
} TX_STA_CNT2_STRUC, *PTX_STA_CNT2_STRUC;
#endif
#define TX_STA_FIFO 0x1718 //
//
// TX_STA_FIFO_STRUC: TX Result for specific PID status fifo register
//
#ifdef RT_BIG_ENDIAN
typedef union PACKED _TX_STA_FIFO_STRUC {
struct {
UINT32 Reserve:2;
UINT32 TxBF:1; // 3*3
UINT32 SuccessRate:13; //include MCS, mode ,shortGI, BW settingSame format as TXWI Word 0 Bit 31-16.
// UINT32 SuccessRate:16; //include MCS, mode ,shortGI, BW settingSame format as TXWI Word 0 Bit 31-16.
UINT32 wcid:8; //wireless client index
UINT32 TxAckRequired:1; // ack required
UINT32 TxAggre:1; // Tx is aggregated
UINT32 TxSuccess:1; // Tx success. whether success or not
UINT32 PidType:4;
UINT32 bValid:1; // 1:This register contains a valid TX result
} field;
UINT32 word;
} TX_STA_FIFO_STRUC, *PTX_STA_FIFO_STRUC;
#else
typedef union PACKED _TX_STA_FIFO_STRUC {
struct {
UINT32 bValid:1; // 1:This register contains a valid TX result
UINT32 PidType:4;
UINT32 TxSuccess:1; // Tx No retry success
UINT32 TxAggre:1; // Tx Retry Success
UINT32 TxAckRequired:1; // Tx fail
UINT32 wcid:8; //wireless client index
// UINT32 SuccessRate:16; //include MCS, mode ,shortGI, BW settingSame format as TXWI Word 0 Bit 31-16.
UINT32 SuccessRate:13; //include MCS, mode ,shortGI, BW settingSame format as TXWI Word 0 Bit 31-16.
UINT32 TxBF:1;
UINT32 Reserve:2;
} field;
UINT32 word;
} TX_STA_FIFO_STRUC, *PTX_STA_FIFO_STRUC;
#endif
// Debug counter
#define TX_AGG_CNT 0x171c
#ifdef RT_BIG_ENDIAN
typedef union _TX_AGG_CNT_STRUC {
struct {
USHORT AggTxCount;
USHORT NonAggTxCount;
} field;
UINT32 word;
} TX_AGG_CNT_STRUC, *PTX_AGG_CNT_STRUC;
#else
typedef union _TX_AGG_CNT_STRUC {
struct {
USHORT NonAggTxCount;
USHORT AggTxCount;
} field;
UINT32 word;
} TX_AGG_CNT_STRUC, *PTX_AGG_CNT_STRUC;
#endif
// Debug counter
#define TX_AGG_CNT0 0x1720
#ifdef RT_BIG_ENDIAN
typedef union _TX_AGG_CNT0_STRUC {
struct {
USHORT AggSize2Count;
USHORT AggSize1Count;
} field;
UINT32 word;
} TX_AGG_CNT0_STRUC, *PTX_AGG_CNT0_STRUC;
#else
typedef union _TX_AGG_CNT0_STRUC {
struct {
USHORT AggSize1Count;
USHORT AggSize2Count;
} field;
UINT32 word;
} TX_AGG_CNT0_STRUC, *PTX_AGG_CNT0_STRUC;
#endif
// Debug counter
#define TX_AGG_CNT1 0x1724
#ifdef RT_BIG_ENDIAN
typedef union _TX_AGG_CNT1_STRUC {
struct {
USHORT AggSize4Count;
USHORT AggSize3Count;
} field;
UINT32 word;
} TX_AGG_CNT1_STRUC, *PTX_AGG_CNT1_STRUC;
#else
typedef union _TX_AGG_CNT1_STRUC {
struct {
USHORT AggSize3Count;
USHORT AggSize4Count;
} field;
UINT32 word;
} TX_AGG_CNT1_STRUC, *PTX_AGG_CNT1_STRUC;
#endif
#define TX_AGG_CNT2 0x1728
#ifdef RT_BIG_ENDIAN
typedef union _TX_AGG_CNT2_STRUC {
struct {
USHORT AggSize6Count;
USHORT AggSize5Count;
} field;
UINT32 word;
} TX_AGG_CNT2_STRUC, *PTX_AGG_CNT2_STRUC;
#else
typedef union _TX_AGG_CNT2_STRUC {
struct {
USHORT AggSize5Count;
USHORT AggSize6Count;
} field;
UINT32 word;
} TX_AGG_CNT2_STRUC, *PTX_AGG_CNT2_STRUC;
#endif
// Debug counter
#define TX_AGG_CNT3 0x172c
#ifdef RT_BIG_ENDIAN
typedef union _TX_AGG_CNT3_STRUC {
struct {
USHORT AggSize8Count;
USHORT AggSize7Count;
} field;
UINT32 word;
} TX_AGG_CNT3_STRUC, *PTX_AGG_CNT3_STRUC;
#else
typedef union _TX_AGG_CNT3_STRUC {
struct {
USHORT AggSize7Count;
USHORT AggSize8Count;
} field;
UINT32 word;
} TX_AGG_CNT3_STRUC, *PTX_AGG_CNT3_STRUC;
#endif
// Debug counter
#define TX_AGG_CNT4 0x1730
#ifdef RT_BIG_ENDIAN
typedef union _TX_AGG_CNT4_STRUC {
struct {
USHORT AggSize10Count;
USHORT AggSize9Count;
} field;
UINT32 word;
} TX_AGG_CNT4_STRUC, *PTX_AGG_CNT4_STRUC;
#else
typedef union _TX_AGG_CNT4_STRUC {
struct {
USHORT AggSize9Count;
USHORT AggSize10Count;
} field;
UINT32 word;
} TX_AGG_CNT4_STRUC, *PTX_AGG_CNT4_STRUC;
#endif
#define TX_AGG_CNT5 0x1734
#ifdef RT_BIG_ENDIAN
typedef union _TX_AGG_CNT5_STRUC {
struct {
USHORT AggSize12Count;
USHORT AggSize11Count;
} field;
UINT32 word;
} TX_AGG_CNT5_STRUC, *PTX_AGG_CNT5_STRUC;
#else
typedef union _TX_AGG_CNT5_STRUC {
struct {
USHORT AggSize11Count;
USHORT AggSize12Count;
} field;
UINT32 word;
} TX_AGG_CNT5_STRUC, *PTX_AGG_CNT5_STRUC;
#endif
#define TX_AGG_CNT6 0x1738
#ifdef RT_BIG_ENDIAN
typedef union _TX_AGG_CNT6_STRUC {
struct {
USHORT AggSize14Count;
USHORT AggSize13Count;
} field;
UINT32 word;
} TX_AGG_CNT6_STRUC, *PTX_AGG_CNT6_STRUC;
#else
typedef union _TX_AGG_CNT6_STRUC {
struct {
USHORT AggSize13Count;
USHORT AggSize14Count;
} field;
UINT32 word;
} TX_AGG_CNT6_STRUC, *PTX_AGG_CNT6_STRUC;
#endif
#define TX_AGG_CNT7 0x173c
#ifdef RT_BIG_ENDIAN
typedef union _TX_AGG_CNT7_STRUC {
struct {
USHORT AggSize16Count;
USHORT AggSize15Count;
} field;
UINT32 word;
} TX_AGG_CNT7_STRUC, *PTX_AGG_CNT7_STRUC;
#else
typedef union _TX_AGG_CNT7_STRUC {
struct {
USHORT AggSize15Count;
USHORT AggSize16Count;
} field;
UINT32 word;
} TX_AGG_CNT7_STRUC, *PTX_AGG_CNT7_STRUC;
#endif
#define MPDU_DENSITY_CNT 0x1740
#ifdef RT_BIG_ENDIAN
typedef union _MPDU_DEN_CNT_STRUC {
struct {
USHORT RXZeroDelCount; //RX zero length delimiter count
USHORT TXZeroDelCount; //TX zero length delimiter count
} field;
UINT32 word;
} MPDU_DEN_CNT_STRUC, *PMPDU_DEN_CNT_STRUC;
#else
typedef union _MPDU_DEN_CNT_STRUC {
struct {
USHORT TXZeroDelCount; //TX zero length delimiter count
USHORT RXZeroDelCount; //RX zero length delimiter count
} field;
UINT32 word;
} MPDU_DEN_CNT_STRUC, *PMPDU_DEN_CNT_STRUC;
#endif
//
// TXRX control registers - base address 0x3000
//
// rt2860b UNKNOWN reg use R/O Reg Addr 0x77d0 first..
#define TXRX_CSR1 0x77d0
//
// Security key table memory, base address = 0x1000
//
#define MAC_WCID_BASE 0x1800 //8-bytes(use only 6-bytes) * 256 entry =
#define HW_WCID_ENTRY_SIZE 8
#define PAIRWISE_KEY_TABLE_BASE 0x4000 // 32-byte * 256-entry = -byte
#define HW_KEY_ENTRY_SIZE 0x20
#define PAIRWISE_IVEIV_TABLE_BASE 0x6000 // 8-byte * 256-entry = -byte
#define MAC_IVEIV_TABLE_BASE 0x6000 // 8-byte * 256-entry = -byte
#define HW_IVEIV_ENTRY_SIZE 8
#define MAC_WCID_ATTRIBUTE_BASE 0x6800 // 4-byte * 256-entry = -byte
#define HW_WCID_ATTRI_SIZE 4
#define WCID_RESERVED 0x6bfc
#define SHARED_KEY_TABLE_BASE 0x6c00 // 32-byte * 16-entry = 512-byte
#define SHARED_KEY_MODE_BASE 0x7000 // 32-byte * 16-entry = 512-byte
#define HW_SHARED_KEY_MODE_SIZE 4
#define SHAREDKEYTABLE 0
#define PAIRWISEKEYTABLE 1
#ifdef RT_BIG_ENDIAN
typedef union _SHAREDKEY_MODE_STRUC {
struct {
UINT32 :1;
UINT32 Bss1Key3CipherAlg:3;
UINT32 :1;
UINT32 Bss1Key2CipherAlg:3;
UINT32 :1;
UINT32 Bss1Key1CipherAlg:3;
UINT32 :1;
UINT32 Bss1Key0CipherAlg:3;
UINT32 :1;
UINT32 Bss0Key3CipherAlg:3;
UINT32 :1;
UINT32 Bss0Key2CipherAlg:3;
UINT32 :1;
UINT32 Bss0Key1CipherAlg:3;
UINT32 :1;
UINT32 Bss0Key0CipherAlg:3;
} field;
UINT32 word;
} SHAREDKEY_MODE_STRUC, *PSHAREDKEY_MODE_STRUC;
#else
typedef union _SHAREDKEY_MODE_STRUC {
struct {
UINT32 Bss0Key0CipherAlg:3;
UINT32 :1;
UINT32 Bss0Key1CipherAlg:3;
UINT32 :1;
UINT32 Bss0Key2CipherAlg:3;
UINT32 :1;
UINT32 Bss0Key3CipherAlg:3;
UINT32 :1;
UINT32 Bss1Key0CipherAlg:3;
UINT32 :1;
UINT32 Bss1Key1CipherAlg:3;
UINT32 :1;
UINT32 Bss1Key2CipherAlg:3;
UINT32 :1;
UINT32 Bss1Key3CipherAlg:3;
UINT32 :1;
} field;
UINT32 word;
} SHAREDKEY_MODE_STRUC, *PSHAREDKEY_MODE_STRUC;
#endif
// 64-entry for pairwise key table
typedef struct _HW_WCID_ENTRY { // 8-byte per entry
UCHAR Address[6];
UCHAR Rsv[2];
} HW_WCID_ENTRY, PHW_WCID_ENTRY;
//
// Other on-chip shared memory space, base = 0x2000
//
// CIS space - base address = 0x2000
#define HW_CIS_BASE 0x2000
// Carrier-sense CTS frame base address. It's where mac stores carrier-sense frame for carrier-sense function.
#define HW_CS_CTS_BASE 0x7700
// DFS CTS frame base address. It's where mac stores CTS frame for DFS.
#define HW_DFS_CTS_BASE 0x7780
#define HW_CTS_FRAME_SIZE 0x80
// 2004-11-08 john - since NULL frame won't be that long (256 byte). We steal 16 tail bytes
// to save debugging settings
#define HW_DEBUG_SETTING_BASE 0x77f0 // 0x77f0~0x77ff total 16 bytes
#define HW_DEBUG_SETTING_BASE2 0x7770 // 0x77f0~0x77ff total 16 bytes
// In order to support maximum 8 MBSS and its maximum length is 512 for each beacon
// Three section discontinue memory segments will be used.
// 1. The original region for BCN 0~3
// 2. Extract memory from FCE table for BCN 4~5
// 3. Extract memory from Pair-wise key table for BCN 6~7
// It occupied those memory of wcid 238~253 for BCN 6
// and wcid 222~237 for BCN 7
#define HW_BEACON_MAX_SIZE 0x1000 /* unit: byte */
#define HW_BEACON_BASE0 0x7800
#define HW_BEACON_BASE1 0x7A00
#define HW_BEACON_BASE2 0x7C00
#define HW_BEACON_BASE3 0x7E00
#define HW_BEACON_BASE4 0x7200
#define HW_BEACON_BASE5 0x7400
#define HW_BEACON_BASE6 0x5DC0
#define HW_BEACON_BASE7 0x5BC0
#define HW_BEACON_MAX_COUNT 8
#define HW_BEACON_OFFSET 0x0200
#define HW_BEACON_CONTENT_LEN (HW_BEACON_OFFSET - TXWI_SIZE)
// HOST-MCU shared memory - base address = 0x2100
#define HOST_CMD_CSR 0x404
#define H2M_MAILBOX_CSR 0x7010
#define H2M_MAILBOX_CID 0x7014
#define H2M_MAILBOX_STATUS 0x701c
#define H2M_INT_SRC 0x7024
#define H2M_BBP_AGENT 0x7028
#define M2H_CMD_DONE_CSR 0x000c
#define MCU_TXOP_ARRAY_BASE 0x000c // TODO: to be provided by Albert
#define MCU_TXOP_ENTRY_SIZE 32 // TODO: to be provided by Albert
#define MAX_NUM_OF_TXOP_ENTRY 16 // TODO: must be same with 8051 firmware
#define MCU_MBOX_VERSION 0x01 // TODO: to be confirmed by Albert
#define MCU_MBOX_VERSION_OFFSET 5 // TODO: to be provided by Albert
//
// Host DMA registers - base address 0x200 . TX0-3=EDCAQid0-3, TX4=HCCA, TX5=MGMT,
//
//
// DMA RING DESCRIPTOR
//
#define E2PROM_CSR 0x0004
#define IO_CNTL_CSR 0x77d0
#ifdef RT2870
// 8051 firmware image for usb - use last-half base address = 0x3000
#define FIRMWARE_IMAGE_BASE 0x3000
#define MAX_FIRMWARE_IMAGE_SIZE 0x1000 // 4kbyte
#endif // RT2870 //
// TODO: ????? old RT2560 registers. to keep them or remove them?
//#define MCAST0 0x0178 // multicast filter register 0
//#define MCAST1 0x017c // multicast filter register 1
// ================================================================
// Tx / Rx / Mgmt ring descriptor definition
// ================================================================
// the following PID values are used to mark outgoing frame type in TXD->PID so that
// proper TX statistics can be collected based on these categories
// b3-2 of PID field -
#define PID_MGMT 0x05
#define PID_BEACON 0x0c
#define PID_DATA_NORMALUCAST 0x02
#define PID_DATA_AMPDU 0x04
#define PID_DATA_NO_ACK 0x08
#define PID_DATA_NOT_NORM_ACK 0x03
// value domain of pTxD->HostQId (4-bit: 0~15)
#define QID_AC_BK 1 // meet ACI definition in 802.11e
#define QID_AC_BE 0 // meet ACI definition in 802.11e
#define QID_AC_VI 2
#define QID_AC_VO 3
#define QID_HCCA 4
#define NUM_OF_TX_RING 5
#define QID_MGMT 13
#define QID_RX 14
#define QID_OTHER 15
// ------------------------------------------------------
// BBP & RF definition
// ------------------------------------------------------
#define BUSY 1
#define IDLE 0
#define RF_R00 0
#define RF_R01 1
#define RF_R02 2
#define RF_R03 3
#define RF_R04 4
#define RF_R05 5
#define RF_R06 6
#define RF_R07 7
#define RF_R08 8
#define RF_R09 9
#define RF_R10 10
#define RF_R11 11
#define RF_R12 12
#define RF_R13 13
#define RF_R14 14
#define RF_R15 15
#define RF_R16 16
#define RF_R17 17
#define RF_R18 18
#define RF_R19 19
#define RF_R20 20
#define RF_R21 21
#define RF_R22 22
#define RF_R23 23
#define RF_R24 24
#define RF_R25 25
#define RF_R26 26
#define RF_R27 27
#define RF_R28 28
#define RF_R29 29
#define RF_R30 30
#define RF_R31 31
#define BBP_R0 0 // version
#define BBP_R1 1 // TSSI
#define BBP_R2 2 // TX configure
#define BBP_R3 3
#define BBP_R4 4
#define BBP_R5 5
#define BBP_R6 6
#define BBP_R14 14 // RX configure
#define BBP_R16 16
#define BBP_R17 17 // RX sensibility
#define BBP_R18 18
#define BBP_R21 21
#define BBP_R22 22
#define BBP_R24 24
#define BBP_R25 25
#define BBP_R31 31
#define BBP_R49 49 //TSSI
#define BBP_R50 50
#define BBP_R51 51
#define BBP_R52 52
#define BBP_R55 55
#define BBP_R62 62 // Rx SQ0 Threshold HIGH
#define BBP_R63 63
#define BBP_R64 64
#define BBP_R65 65
#define BBP_R66 66
#define BBP_R67 67
#define BBP_R68 68
#define BBP_R69 69
#define BBP_R70 70 // Rx AGC SQ CCK Xcorr threshold
#define BBP_R73 73
#define BBP_R75 75
#define BBP_R77 77
#define BBP_R79 79
#define BBP_R80 80
#define BBP_R81 81
#define BBP_R82 82
#define BBP_R83 83
#define BBP_R84 84
#define BBP_R86 86
#define BBP_R91 91
#define BBP_R92 92
#define BBP_R94 94 // Tx Gain Control
#define BBP_R103 103
#define BBP_R105 105
#define BBP_R113 113
#define BBP_R114 114
#define BBP_R115 115
#define BBP_R116 116
#define BBP_R117 117
#define BBP_R118 118
#define BBP_R119 119
#define BBP_R120 120
#define BBP_R121 121
#define BBP_R122 122
#define BBP_R123 123
#ifdef RT30xx
#define BBP_R138 138 // add by johnli, RF power sequence setup, ADC dynamic on/off control
#endif // RT30xx //
#define BBPR94_DEFAULT 0x06 // Add 1 value will gain 1db
//#define PHY_TR_SWITCH_TIME 5 // usec
//#define BBP_R17_LOW_SENSIBILITY 0x50
//#define BBP_R17_MID_SENSIBILITY 0x41
//#define BBP_R17_DYNAMIC_UP_BOUND 0x40
#define RSSI_FOR_VERY_LOW_SENSIBILITY -35
#define RSSI_FOR_LOW_SENSIBILITY -58
#define RSSI_FOR_MID_LOW_SENSIBILITY -80
#define RSSI_FOR_MID_SENSIBILITY -90
//-------------------------------------------------------------------------
// EEPROM definition
//-------------------------------------------------------------------------
#define EEDO 0x08
#define EEDI 0x04
#define EECS 0x02
#define EESK 0x01
#define EERL 0x80
#define EEPROM_WRITE_OPCODE 0x05
#define EEPROM_READ_OPCODE 0x06
#define EEPROM_EWDS_OPCODE 0x10
#define EEPROM_EWEN_OPCODE 0x13
#define NUM_EEPROM_BBP_PARMS 19 // Include NIC Config 0, 1, CR, TX ALC step, BBPs
#define NUM_EEPROM_TX_G_PARMS 7
#define EEPROM_NIC1_OFFSET 0x34 // The address is from NIC config 0, not BBP register ID
#define EEPROM_NIC2_OFFSET 0x36 // The address is from NIC config 0, not BBP register ID
#define EEPROM_BBP_BASE_OFFSET 0xf0 // The address is from NIC config 0, not BBP register ID
#define EEPROM_G_TX_PWR_OFFSET 0x52
#define EEPROM_G_TX2_PWR_OFFSET 0x60
#define EEPROM_LED1_OFFSET 0x3c
#define EEPROM_LED2_OFFSET 0x3e
#define EEPROM_LED3_OFFSET 0x40
#define EEPROM_LNA_OFFSET 0x44
#define EEPROM_RSSI_BG_OFFSET 0x46
#define EEPROM_RSSI_A_OFFSET 0x4a
#define EEPROM_DEFINE_MAX_TXPWR 0x4e
#define EEPROM_TXPOWER_BYRATE_20MHZ_2_4G 0xde // 20MHZ 2.4G tx power.
#define EEPROM_TXPOWER_BYRATE_40MHZ_2_4G 0xee // 40MHZ 2.4G tx power.
#define EEPROM_TXPOWER_BYRATE_20MHZ_5G 0xfa // 20MHZ 5G tx power.
#define EEPROM_TXPOWER_BYRATE_40MHZ_5G 0x10a // 40MHZ 5G tx power.
#define EEPROM_A_TX_PWR_OFFSET 0x78
#define EEPROM_A_TX2_PWR_OFFSET 0xa6
//#define EEPROM_Japan_TX_PWR_OFFSET 0x90 // 802.11j
//#define EEPROM_Japan_TX2_PWR_OFFSET 0xbe
//#define EEPROM_TSSI_REF_OFFSET 0x54
//#define EEPROM_TSSI_DELTA_OFFSET 0x24
//#define EEPROM_CCK_TX_PWR_OFFSET 0x62
//#define EEPROM_CALIBRATE_OFFSET 0x7c
#define EEPROM_VERSION_OFFSET 0x02
#define EEPROM_FREQ_OFFSET 0x3a
#define EEPROM_TXPOWER_BYRATE 0xde // 20MHZ power.
#define EEPROM_TXPOWER_DELTA 0x50 // 20MHZ AND 40 MHZ use different power. This is delta in 40MHZ.
#define VALID_EEPROM_VERSION 1
// PairKeyMode definition
#define PKMODE_NONE 0
#define PKMODE_WEP64 1
#define PKMODE_WEP128 2
#define PKMODE_TKIP 3
#define PKMODE_AES 4
#define PKMODE_CKIP64 5
#define PKMODE_CKIP128 6
#define PKMODE_TKIP_NO_MIC 7 // MIC appended by driver: not a valid value in hardware key table
// =================================================================================
// WCID format
// =================================================================================
//7.1 WCID ENTRY format : 8bytes
typedef struct _WCID_ENTRY_STRUC {
UCHAR RXBABitmap7; // bit0 for TID8, bit7 for TID 15
UCHAR RXBABitmap0; // bit0 for TID0, bit7 for TID 7
UCHAR MAC[6]; // 0 for shared key table. 1 for pairwise key table
} WCID_ENTRY_STRUC, *PWCID_ENTRY_STRUC;
//8.1.1 SECURITY KEY format : 8DW
// 32-byte per entry, total 16-entry for shared key table, 64-entry for pairwise key table
typedef struct _HW_KEY_ENTRY { // 32-byte per entry
UCHAR Key[16];
UCHAR TxMic[8];
UCHAR RxMic[8];
} HW_KEY_ENTRY, *PHW_KEY_ENTRY;
//8.1.2 IV/EIV format : 2DW
//8.1.3 RX attribute entry format : 1DW
#ifdef RT_BIG_ENDIAN
typedef struct _MAC_ATTRIBUTE_STRUC {
UINT32 rsv:22;
UINT32 RXWIUDF:3;
UINT32 BSSIDIdx:3; //multipleBSS index for the WCID
UINT32 PairKeyMode:3;
UINT32 KeyTab:1; // 0 for shared key table. 1 for pairwise key table
} MAC_ATTRIBUTE_STRUC, *PMAC_ATTRIBUTE_STRUC;
#else
typedef struct _MAC_ATTRIBUTE_STRUC {
UINT32 KeyTab:1; // 0 for shared key table. 1 for pairwise key table
UINT32 PairKeyMode:3;
UINT32 BSSIDIdx:3; //multipleBSS index for the WCID
UINT32 RXWIUDF:3;
UINT32 rsv:22;
} MAC_ATTRIBUTE_STRUC, *PMAC_ATTRIBUTE_STRUC;
#endif
// =================================================================================
// TX / RX ring descriptor format
// =================================================================================
// the first 24-byte in TXD is called TXINFO and will be DMAed to MAC block through TXFIFO.
// MAC block use this TXINFO to control the transmission behavior of this frame.
#define FIFO_MGMT 0
#define FIFO_HCCA 1
#define FIFO_EDCA 2
//
// TX descriptor format, Tx ring, Mgmt Ring
//
#ifdef RT_BIG_ENDIAN
typedef struct PACKED _TXD_STRUC {
// Word 0
UINT32 SDPtr0;
// Word 1
UINT32 DMADONE:1;
UINT32 LastSec0:1;
UINT32 SDLen0:14;
UINT32 Burst:1;
UINT32 LastSec1:1;
UINT32 SDLen1:14;
// Word 2
UINT32 SDPtr1;
// Word 3
UINT32 ICO:1;
UINT32 UCO:1;
UINT32 TCO:1;
UINT32 rsv:2;
UINT32 QSEL:2; // select on-chip FIFO ID for 2nd-stage output scheduler.0:MGMT, 1:HCCA 2:EDCA
UINT32 WIV:1; // Wireless Info Valid. 1 if Driver already fill WI, o if DMA needs to copy WI to correctposition
UINT32 rsv2:24;
} TXD_STRUC, *PTXD_STRUC;
#else
typedef struct PACKED _TXD_STRUC {
// Word 0
UINT32 SDPtr0;
// Word 1
UINT32 SDLen1:14;
UINT32 LastSec1:1;
UINT32 Burst:1;
UINT32 SDLen0:14;
UINT32 LastSec0:1;
UINT32 DMADONE:1;
//Word2
UINT32 SDPtr1;
//Word3
UINT32 rsv2:24;
UINT32 WIV:1; // Wireless Info Valid. 1 if Driver already fill WI, o if DMA needs to copy WI to correctposition
UINT32 QSEL:2; // select on-chip FIFO ID for 2nd-stage output scheduler.0:MGMT, 1:HCCA 2:EDCA
UINT32 rsv:2;
UINT32 TCO:1; //
UINT32 UCO:1; //
UINT32 ICO:1; //
} TXD_STRUC, *PTXD_STRUC;
#endif
//
// TXD Wireless Information format for Tx ring and Mgmt Ring
//
//txop : for txop mode
// 0:txop for the MPDU frame will be handles by ASIC by register
// 1/2/3:the MPDU frame is send after PIFS/backoff/SIFS
#ifdef RT_BIG_ENDIAN
typedef struct PACKED _TXWI_STRUC {
// Word 0
UINT32 PHYMODE:2;
UINT32 TxBF:1; // 3*3
UINT32 rsv2:1;
// UINT32 rsv2:2;
UINT32 Ifs:1; //
UINT32 STBC:2; //channel bandwidth 20MHz or 40 MHz
UINT32 ShortGI:1;
UINT32 BW:1; //channel bandwidth 20MHz or 40 MHz
UINT32 MCS:7;
UINT32 rsv:6;
UINT32 txop:2; //tx back off mode 0:HT TXOP rule , 1:PIFS TX ,2:Backoff, 3:sifs only when previous frame exchange is successful.
UINT32 MpduDensity:3;
UINT32 AMPDU:1;
UINT32 TS:1;
UINT32 CFACK:1;
UINT32 MIMOps:1; // the remote peer is in dynamic MIMO-PS mode
UINT32 FRAG:1; // 1 to inform TKIP engine this is a fragment.
// Word 1
UINT32 PacketId:4;
UINT32 MPDUtotalByteCount:12;
UINT32 WirelessCliID:8;
UINT32 BAWinSize:6;
UINT32 NSEQ:1;
UINT32 ACK:1;
// Word 2
UINT32 IV;
// Word 3
UINT32 EIV;
} TXWI_STRUC, *PTXWI_STRUC;
#else
typedef struct PACKED _TXWI_STRUC {
// Word 0
UINT32 FRAG:1; // 1 to inform TKIP engine this is a fragment.
UINT32 MIMOps:1; // the remote peer is in dynamic MIMO-PS mode
UINT32 CFACK:1;
UINT32 TS:1;
UINT32 AMPDU:1;
UINT32 MpduDensity:3;
UINT32 txop:2; //FOR "THIS" frame. 0:HT TXOP rule , 1:PIFS TX ,2:Backoff, 3:sifs only when previous frame exchange is successful.
UINT32 rsv:6;
UINT32 MCS:7;
UINT32 BW:1; //channel bandwidth 20MHz or 40 MHz
UINT32 ShortGI:1;
UINT32 STBC:2; // 1: STBC support MCS =0-7, 2,3 : RESERVE
UINT32 Ifs:1; //
// UINT32 rsv2:2; //channel bandwidth 20MHz or 40 MHz
UINT32 rsv2:1;
UINT32 TxBF:1; // 3*3
UINT32 PHYMODE:2;
// Word 1
UINT32 ACK:1;
UINT32 NSEQ:1;
UINT32 BAWinSize:6;
UINT32 WirelessCliID:8;
UINT32 MPDUtotalByteCount:12;
UINT32 PacketId:4;
//Word2
UINT32 IV;
//Word3
UINT32 EIV;
} TXWI_STRUC, *PTXWI_STRUC;
#endif
//
// Rx descriptor format, Rx Ring
//
//
// RXWI wireless information format, in PBF. invisible in driver.
//
#ifdef RT_BIG_ENDIAN
typedef struct PACKED _RXWI_STRUC {
// Word 0
UINT32 TID:4;
UINT32 MPDUtotalByteCount:12;
UINT32 UDF:3;
UINT32 BSSID:3;
UINT32 KeyIndex:2;
UINT32 WirelessCliID:8;
// Word 1
UINT32 PHYMODE:2; // 1: this RX frame is unicast to me
UINT32 rsv:3;
UINT32 STBC:2;
UINT32 ShortGI:1;
UINT32 BW:1;
UINT32 MCS:7;
UINT32 SEQUENCE:12;
UINT32 FRAG:4;
// Word 2
UINT32 rsv1:8;
UINT32 RSSI2:8;
UINT32 RSSI1:8;
UINT32 RSSI0:8;
// Word 3
UINT32 rsv2:16;
UINT32 SNR1:8;
UINT32 SNR0:8;
} RXWI_STRUC, *PRXWI_STRUC;
#else
typedef struct PACKED _RXWI_STRUC {
// Word 0
UINT32 WirelessCliID:8;
UINT32 KeyIndex:2;
UINT32 BSSID:3;
UINT32 UDF:3;
UINT32 MPDUtotalByteCount:12;
UINT32 TID:4;
// Word 1
UINT32 FRAG:4;
UINT32 SEQUENCE:12;
UINT32 MCS:7;
UINT32 BW:1;
UINT32 ShortGI:1;
UINT32 STBC:2;
UINT32 rsv:3;
UINT32 PHYMODE:2; // 1: this RX frame is unicast to me
//Word2
UINT32 RSSI0:8;
UINT32 RSSI1:8;
UINT32 RSSI2:8;
UINT32 rsv1:8;
//Word3
UINT32 SNR0:8;
UINT32 SNR1:8;
UINT32 rsv2:16;
} RXWI_STRUC, *PRXWI_STRUC;
#endif
// =================================================================================
// HOST-MCU communication data structure
// =================================================================================
//
// H2M_MAILBOX_CSR: Host-to-MCU Mailbox
//
#ifdef RT_BIG_ENDIAN
typedef union _H2M_MAILBOX_STRUC {
struct {
UINT32 Owner:8;
UINT32 CmdToken:8; // 0xff tells MCU not to report CmdDoneInt after excuting the command
UINT32 HighByte:8;
UINT32 LowByte:8;
} field;
UINT32 word;
} H2M_MAILBOX_STRUC, *PH2M_MAILBOX_STRUC;
#else
typedef union _H2M_MAILBOX_STRUC {
struct {
UINT32 LowByte:8;
UINT32 HighByte:8;
UINT32 CmdToken:8;
UINT32 Owner:8;
} field;
UINT32 word;
} H2M_MAILBOX_STRUC, *PH2M_MAILBOX_STRUC;
#endif
//
// M2H_CMD_DONE_CSR: MCU-to-Host command complete indication
//
#ifdef RT_BIG_ENDIAN
typedef union _M2H_CMD_DONE_STRUC {
struct {
UINT32 CmdToken3;
UINT32 CmdToken2;
UINT32 CmdToken1;
UINT32 CmdToken0;
} field;
UINT32 word;
} M2H_CMD_DONE_STRUC, *PM2H_CMD_DONE_STRUC;
#else
typedef union _M2H_CMD_DONE_STRUC {
struct {
UINT32 CmdToken0;
UINT32 CmdToken1;
UINT32 CmdToken2;
UINT32 CmdToken3;
} field;
UINT32 word;
} M2H_CMD_DONE_STRUC, *PM2H_CMD_DONE_STRUC;
#endif
//
// MCU_LEDCS: MCU LED Control Setting.
//
#ifdef RT_BIG_ENDIAN
typedef union _MCU_LEDCS_STRUC {
struct {
UCHAR Polarity:1;
UCHAR LedMode:7;
} field;
UCHAR word;
} MCU_LEDCS_STRUC, *PMCU_LEDCS_STRUC;
#else
typedef union _MCU_LEDCS_STRUC {
struct {
UCHAR LedMode:7;
UCHAR Polarity:1;
} field;
UCHAR word;
} MCU_LEDCS_STRUC, *PMCU_LEDCS_STRUC;
#endif
// =================================================================================
// Register format
// =================================================================================
//NAV_TIME_CFG :NAV
#ifdef RT_BIG_ENDIAN
typedef union _NAV_TIME_CFG_STRUC {
struct {
USHORT rsv:6;
USHORT ZeroSifs:1; // Applied zero SIFS timer after OFDM RX 0: disable
USHORT Eifs:9; // in unit of 1-us
UCHAR SlotTime; // in unit of 1-us
UCHAR Sifs; // in unit of 1-us
} field;
UINT32 word;
} NAV_TIME_CFG_STRUC, *PNAV_TIME_CFG_STRUC;
#else
typedef union _NAV_TIME_CFG_STRUC {
struct {
UCHAR Sifs; // in unit of 1-us
UCHAR SlotTime; // in unit of 1-us
USHORT Eifs:9; // in unit of 1-us
USHORT ZeroSifs:1; // Applied zero SIFS timer after OFDM RX 0: disable
USHORT rsv:6;
} field;
UINT32 word;
} NAV_TIME_CFG_STRUC, *PNAV_TIME_CFG_STRUC;
#endif
//
// RX_FILTR_CFG: /RX configuration register
//
#ifdef RT_BIG_ENDIAN
typedef union RX_FILTR_CFG_STRUC {
struct {
UINT32 :15;
UINT32 DropRsvCntlType:1;
UINT32 DropBAR:1; //
UINT32 DropBA:1; //
UINT32 DropPsPoll:1; // Drop Ps-Poll
UINT32 DropRts:1; // Drop Ps-Poll
UINT32 DropCts:1; // Drop Ps-Poll
UINT32 DropAck:1; // Drop Ps-Poll
UINT32 DropCFEnd:1; // Drop Ps-Poll
UINT32 DropCFEndAck:1; // Drop Ps-Poll
UINT32 DropDuplicate:1; // Drop duplicate frame
UINT32 DropBcast:1; // Drop broadcast frames
UINT32 DropMcast:1; // Drop multicast frames
UINT32 DropVerErr:1; // Drop version error frame
UINT32 DropNotMyBSSID:1; // Drop fram ToDs bit is true
UINT32 DropNotToMe:1; // Drop not to me unicast frame
UINT32 DropPhyErr:1; // Drop physical error
UINT32 DropCRCErr:1; // Drop CRC error
} field;
UINT32 word;
} RX_FILTR_CFG_STRUC, *PRX_FILTR_CFG_STRUC;
#else
typedef union _RX_FILTR_CFG_STRUC {
struct {
UINT32 DropCRCErr:1; // Drop CRC error
UINT32 DropPhyErr:1; // Drop physical error
UINT32 DropNotToMe:1; // Drop not to me unicast frame
UINT32 DropNotMyBSSID:1; // Drop fram ToDs bit is true
UINT32 DropVerErr:1; // Drop version error frame
UINT32 DropMcast:1; // Drop multicast frames
UINT32 DropBcast:1; // Drop broadcast frames
UINT32 DropDuplicate:1; // Drop duplicate frame
UINT32 DropCFEndAck:1; // Drop Ps-Poll
UINT32 DropCFEnd:1; // Drop Ps-Poll
UINT32 DropAck:1; // Drop Ps-Poll
UINT32 DropCts:1; // Drop Ps-Poll
UINT32 DropRts:1; // Drop Ps-Poll
UINT32 DropPsPoll:1; // Drop Ps-Poll
UINT32 DropBA:1; //
UINT32 DropBAR:1; //
UINT32 DropRsvCntlType:1;
UINT32 :15;
} field;
UINT32 word;
} RX_FILTR_CFG_STRUC, *PRX_FILTR_CFG_STRUC;
#endif
//
// PHY_CSR4: RF serial control register
//
#ifdef RT_BIG_ENDIAN
typedef union _PHY_CSR4_STRUC {
struct {
UINT32 Busy:1; // 1: ASIC is busy execute RF programming.
UINT32 PLL_LD:1; // RF PLL_LD status
UINT32 IFSelect:1; // 1: select IF to program, 0: select RF to program
UINT32 NumberOfBits:5; // Number of bits used in RFRegValue (I:20, RFMD:22)
UINT32 RFRegValue:24; // Register value (include register id) serial out to RF/IF chip.
} field;
UINT32 word;
} PHY_CSR4_STRUC, *PPHY_CSR4_STRUC;
#else
typedef union _PHY_CSR4_STRUC {
struct {
UINT32 RFRegValue:24; // Register value (include register id) serial out to RF/IF chip.
UINT32 NumberOfBits:5; // Number of bits used in RFRegValue (I:20, RFMD:22)
UINT32 IFSelect:1; // 1: select IF to program, 0: select RF to program
UINT32 PLL_LD:1; // RF PLL_LD status
UINT32 Busy:1; // 1: ASIC is busy execute RF programming.
} field;
UINT32 word;
} PHY_CSR4_STRUC, *PPHY_CSR4_STRUC;
#endif
//
// SEC_CSR5: shared key table security mode register
//
#ifdef RT_BIG_ENDIAN
typedef union _SEC_CSR5_STRUC {
struct {
UINT32 :1;
UINT32 Bss3Key3CipherAlg:3;
UINT32 :1;
UINT32 Bss3Key2CipherAlg:3;
UINT32 :1;
UINT32 Bss3Key1CipherAlg:3;
UINT32 :1;
UINT32 Bss3Key0CipherAlg:3;
UINT32 :1;
UINT32 Bss2Key3CipherAlg:3;
UINT32 :1;
UINT32 Bss2Key2CipherAlg:3;
UINT32 :1;
UINT32 Bss2Key1CipherAlg:3;
UINT32 :1;
UINT32 Bss2Key0CipherAlg:3;
} field;
UINT32 word;
} SEC_CSR5_STRUC, *PSEC_CSR5_STRUC;
#else
typedef union _SEC_CSR5_STRUC {
struct {
UINT32 Bss2Key0CipherAlg:3;
UINT32 :1;
UINT32 Bss2Key1CipherAlg:3;
UINT32 :1;
UINT32 Bss2Key2CipherAlg:3;
UINT32 :1;
UINT32 Bss2Key3CipherAlg:3;
UINT32 :1;
UINT32 Bss3Key0CipherAlg:3;
UINT32 :1;
UINT32 Bss3Key1CipherAlg:3;
UINT32 :1;
UINT32 Bss3Key2CipherAlg:3;
UINT32 :1;
UINT32 Bss3Key3CipherAlg:3;
UINT32 :1;
} field;
UINT32 word;
} SEC_CSR5_STRUC, *PSEC_CSR5_STRUC;
#endif
//
// HOST_CMD_CSR: For HOST to interrupt embedded processor
//
#ifdef RT_BIG_ENDIAN
typedef union _HOST_CMD_CSR_STRUC {
struct {
UINT32 Rsv:24;
UINT32 HostCommand:8;
} field;
UINT32 word;
} HOST_CMD_CSR_STRUC, *PHOST_CMD_CSR_STRUC;
#else
typedef union _HOST_CMD_CSR_STRUC {
struct {
UINT32 HostCommand:8;
UINT32 Rsv:24;
} field;
UINT32 word;
} HOST_CMD_CSR_STRUC, *PHOST_CMD_CSR_STRUC;
#endif
//
// AIFSN_CSR: AIFSN for each EDCA AC
//
//
// E2PROM_CSR: EEPROM control register
//
#ifdef RT_BIG_ENDIAN
typedef union _E2PROM_CSR_STRUC {
struct {
UINT32 Rsvd:25;
UINT32 LoadStatus:1; // 1:loading, 0:done
UINT32 Type:1; // 1: 93C46, 0:93C66
UINT32 EepromDO:1;
UINT32 EepromDI:1;
UINT32 EepromCS:1;
UINT32 EepromSK:1;
UINT32 Reload:1; // Reload EEPROM content, write one to reload, self-cleared.
} field;
UINT32 word;
} E2PROM_CSR_STRUC, *PE2PROM_CSR_STRUC;
#else
typedef union _E2PROM_CSR_STRUC {
struct {
UINT32 Reload:1; // Reload EEPROM content, write one to reload, self-cleared.
UINT32 EepromSK:1;
UINT32 EepromCS:1;
UINT32 EepromDI:1;
UINT32 EepromDO:1;
UINT32 Type:1; // 1: 93C46, 0:93C66
UINT32 LoadStatus:1; // 1:loading, 0:done
UINT32 Rsvd:25;
} field;
UINT32 word;
} E2PROM_CSR_STRUC, *PE2PROM_CSR_STRUC;
#endif
// -------------------------------------------------------------------
// E2PROM data layout
// -------------------------------------------------------------------
//
// EEPROM antenna select format
//
#ifdef RT_BIG_ENDIAN
typedef union _EEPROM_ANTENNA_STRUC {
struct {
USHORT Rsv:4;
USHORT RfIcType:4; // see E2PROM document
USHORT TxPath:4; // 1: 1T, 2: 2T
USHORT RxPath:4; // 1: 1R, 2: 2R, 3: 3R
} field;
USHORT word;
} EEPROM_ANTENNA_STRUC, *PEEPROM_ANTENNA_STRUC;
#else
typedef union _EEPROM_ANTENNA_STRUC {
struct {
USHORT RxPath:4; // 1: 1R, 2: 2R, 3: 3R
USHORT TxPath:4; // 1: 1T, 2: 2T
USHORT RfIcType:4; // see E2PROM document
USHORT Rsv:4;
} field;
USHORT word;
} EEPROM_ANTENNA_STRUC, *PEEPROM_ANTENNA_STRUC;
#endif
#ifdef RT_BIG_ENDIAN
typedef union _EEPROM_NIC_CINFIG2_STRUC {
struct {
USHORT DACTestBit:1; // control if driver should patch the DAC issue
USHORT Rsv2:3; // must be 0
USHORT AntDiversity:1; // Antenna diversity
USHORT Rsv1:1; // must be 0
USHORT BW40MAvailForA:1; // 0:enable, 1:disable
USHORT BW40MAvailForG:1; // 0:enable, 1:disable
USHORT EnableWPSPBC:1; // WPS PBC Control bit
USHORT BW40MSidebandForA:1;
USHORT BW40MSidebandForG:1;
USHORT CardbusAcceleration:1; // !!! NOTE: 0 - enable, 1 - disable
USHORT ExternalLNAForA:1; // external LNA enable for 5G
USHORT ExternalLNAForG:1; // external LNA enable for 2.4G
USHORT DynamicTxAgcControl:1; //
USHORT HardwareRadioControl:1; // Whether RF is controlled by driver or HW. 1:enable hw control, 0:disable
} field;
USHORT word;
} EEPROM_NIC_CONFIG2_STRUC, *PEEPROM_NIC_CONFIG2_STRUC;
#else
typedef union _EEPROM_NIC_CINFIG2_STRUC {
struct {
USHORT HardwareRadioControl:1; // 1:enable, 0:disable
USHORT DynamicTxAgcControl:1; //
USHORT ExternalLNAForG:1; //
USHORT ExternalLNAForA:1; // external LNA enable for 2.4G
USHORT CardbusAcceleration:1; // !!! NOTE: 0 - enable, 1 - disable
USHORT BW40MSidebandForG:1;
USHORT BW40MSidebandForA:1;
USHORT EnableWPSPBC:1; // WPS PBC Control bit
USHORT BW40MAvailForG:1; // 0:enable, 1:disable
USHORT BW40MAvailForA:1; // 0:enable, 1:disable
USHORT Rsv1:1; // must be 0
USHORT AntDiversity:1; // Antenna diversity
USHORT Rsv2:3; // must be 0
USHORT DACTestBit:1; // control if driver should patch the DAC issue
} field;
USHORT word;
} EEPROM_NIC_CONFIG2_STRUC, *PEEPROM_NIC_CONFIG2_STRUC;
#endif
//
// TX_PWR Value valid range 0xFA(-6) ~ 0x24(36)
//
#ifdef RT_BIG_ENDIAN
typedef union _EEPROM_TX_PWR_STRUC {
struct {
CHAR Byte1; // High Byte
CHAR Byte0; // Low Byte
} field;
USHORT word;
} EEPROM_TX_PWR_STRUC, *PEEPROM_TX_PWR_STRUC;
#else
typedef union _EEPROM_TX_PWR_STRUC {
struct {
CHAR Byte0; // Low Byte
CHAR Byte1; // High Byte
} field;
USHORT word;
} EEPROM_TX_PWR_STRUC, *PEEPROM_TX_PWR_STRUC;
#endif
#ifdef RT_BIG_ENDIAN
typedef union _EEPROM_VERSION_STRUC {
struct {
UCHAR Version; // High Byte
UCHAR FaeReleaseNumber; // Low Byte
} field;
USHORT word;
} EEPROM_VERSION_STRUC, *PEEPROM_VERSION_STRUC;
#else
typedef union _EEPROM_VERSION_STRUC {
struct {
UCHAR FaeReleaseNumber; // Low Byte
UCHAR Version; // High Byte
} field;
USHORT word;
} EEPROM_VERSION_STRUC, *PEEPROM_VERSION_STRUC;
#endif
#ifdef RT_BIG_ENDIAN
typedef union _EEPROM_LED_STRUC {
struct {
USHORT Rsvd:3; // Reserved
USHORT LedMode:5; // Led mode.
USHORT PolarityGPIO_4:1; // Polarity GPIO#4 setting.
USHORT PolarityGPIO_3:1; // Polarity GPIO#3 setting.
USHORT PolarityGPIO_2:1; // Polarity GPIO#2 setting.
USHORT PolarityGPIO_1:1; // Polarity GPIO#1 setting.
USHORT PolarityGPIO_0:1; // Polarity GPIO#0 setting.
USHORT PolarityACT:1; // Polarity ACT setting.
USHORT PolarityRDY_A:1; // Polarity RDY_A setting.
USHORT PolarityRDY_G:1; // Polarity RDY_G setting.
} field;
USHORT word;
} EEPROM_LED_STRUC, *PEEPROM_LED_STRUC;
#else
typedef union _EEPROM_LED_STRUC {
struct {
USHORT PolarityRDY_G:1; // Polarity RDY_G setting.
USHORT PolarityRDY_A:1; // Polarity RDY_A setting.
USHORT PolarityACT:1; // Polarity ACT setting.
USHORT PolarityGPIO_0:1; // Polarity GPIO#0 setting.
USHORT PolarityGPIO_1:1; // Polarity GPIO#1 setting.
USHORT PolarityGPIO_2:1; // Polarity GPIO#2 setting.
USHORT PolarityGPIO_3:1; // Polarity GPIO#3 setting.
USHORT PolarityGPIO_4:1; // Polarity GPIO#4 setting.
USHORT LedMode:5; // Led mode.
USHORT Rsvd:3; // Reserved
} field;
USHORT word;
} EEPROM_LED_STRUC, *PEEPROM_LED_STRUC;
#endif
#ifdef RT_BIG_ENDIAN
typedef union _EEPROM_TXPOWER_DELTA_STRUC {
struct {
UCHAR TxPowerEnable:1;// Enable
UCHAR Type:1; // 1: plus the delta value, 0: minus the delta value
UCHAR DeltaValue:6; // Tx Power dalta value (MAX=4)
} field;
UCHAR value;
} EEPROM_TXPOWER_DELTA_STRUC, *PEEPROM_TXPOWER_DELTA_STRUC;
#else
typedef union _EEPROM_TXPOWER_DELTA_STRUC {
struct {
UCHAR DeltaValue:6; // Tx Power dalta value (MAX=4)
UCHAR Type:1; // 1: plus the delta value, 0: minus the delta value
UCHAR TxPowerEnable:1;// Enable
} field;
UCHAR value;
} EEPROM_TXPOWER_DELTA_STRUC, *PEEPROM_TXPOWER_DELTA_STRUC;
#endif
//
// QOS_CSR0: TXOP holder address0 register
//
#ifdef RT_BIG_ENDIAN
typedef union _QOS_CSR0_STRUC {
struct {
UCHAR Byte3; // MAC address byte 3
UCHAR Byte2; // MAC address byte 2
UCHAR Byte1; // MAC address byte 1
UCHAR Byte0; // MAC address byte 0
} field;
UINT32 word;
} QOS_CSR0_STRUC, *PQOS_CSR0_STRUC;
#else
typedef union _QOS_CSR0_STRUC {
struct {
UCHAR Byte0; // MAC address byte 0
UCHAR Byte1; // MAC address byte 1
UCHAR Byte2; // MAC address byte 2
UCHAR Byte3; // MAC address byte 3
} field;
UINT32 word;
} QOS_CSR0_STRUC, *PQOS_CSR0_STRUC;
#endif
//
// QOS_CSR1: TXOP holder address1 register
//
#ifdef RT_BIG_ENDIAN
typedef union _QOS_CSR1_STRUC {
struct {
UCHAR Rsvd1;
UCHAR Rsvd0;
UCHAR Byte5; // MAC address byte 5
UCHAR Byte4; // MAC address byte 4
} field;
UINT32 word;
} QOS_CSR1_STRUC, *PQOS_CSR1_STRUC;
#else
typedef union _QOS_CSR1_STRUC {
struct {
UCHAR Byte4; // MAC address byte 4
UCHAR Byte5; // MAC address byte 5
UCHAR Rsvd0;
UCHAR Rsvd1;
} field;
UINT32 word;
} QOS_CSR1_STRUC, *PQOS_CSR1_STRUC;
#endif
#define RF_CSR_CFG 0x500
#ifdef RT_BIG_ENDIAN
typedef union _RF_CSR_CFG_STRUC {
struct {
UINT Rsvd1:14; // Reserved
UINT RF_CSR_KICK:1; // kick RF register read/write
UINT RF_CSR_WR:1; // 0: read 1: write
UINT Rsvd2:3; // Reserved
UINT TESTCSR_RFACC_REGNUM:5; // RF register ID
UINT RF_CSR_DATA:8; // DATA
} field;
UINT word;
} RF_CSR_CFG_STRUC, *PRF_CSR_CFG_STRUC;
#else
typedef union _RF_CSR_CFG_STRUC {
struct {
UINT RF_CSR_DATA:8; // DATA
UINT TESTCSR_RFACC_REGNUM:5; // RF register ID
UINT Rsvd2:3; // Reserved
UINT RF_CSR_WR:1; // 0: read 1: write
UINT RF_CSR_KICK:1; // kick RF register read/write
UINT Rsvd1:14; // Reserved
} field;
UINT word;
} RF_CSR_CFG_STRUC, *PRF_CSR_CFG_STRUC;
#endif
#endif // __RT28XX_H__