2
0
mirror of https://github.com/edk2-porting/linux-next.git synced 2024-12-29 15:43:59 +08:00
linux-next/drivers/net/irda/via-ircc.h
Jeff Kirsher e8478de32e irda: Fix FSF address in file headers
Several files refer to an old address for the Free Software Foundation
in the file header comment.  Resolve by replacing the address with
the URL <http://www.gnu.org/licenses/> so that we do not have to keep
updating the header comments anytime the address changes.

CC: Samuel Ortiz <samuel@sortiz.org>
Signed-off-by: Jeff Kirsher <jeffrey.t.kirsher@intel.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2013-12-06 12:37:55 -05:00

851 lines
21 KiB
C

/*********************************************************************
*
* Filename: via-ircc.h
* Version: 1.0
* Description: Driver for the VIA VT8231/VT8233 IrDA chipsets
* Author: VIA Technologies, inc
* Date : 08/06/2003
Copyright (c) 1998-2003 VIA Technologies, 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, or (at your option) any later version.
This program is distributed in the hope that it will be useful, but WITHOUT
ANY WARRANTIES OR REPRESENTATIONS; 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, see <http://www.gnu.org/licenses/>.
* Comment:
* jul/08/2002 : Rx buffer length should use Rx ring ptr.
* Oct/28/2002 : Add SB id for 3147 and 3177.
* jul/09/2002 : only implement two kind of dongle currently.
* Oct/02/2002 : work on VT8231 and VT8233 .
* Aug/06/2003 : change driver format to pci driver .
********************************************************************/
#ifndef via_IRCC_H
#define via_IRCC_H
#include <linux/time.h>
#include <linux/spinlock.h>
#include <linux/pm.h>
#include <linux/types.h>
#include <asm/io.h>
#define MAX_TX_WINDOW 7
#define MAX_RX_WINDOW 7
struct st_fifo_entry {
int status;
int len;
};
struct st_fifo {
struct st_fifo_entry entries[MAX_RX_WINDOW + 2];
int pending_bytes;
int head;
int tail;
int len;
};
struct frame_cb {
void *start; /* Start of frame in DMA mem */
int len; /* Length of frame in DMA mem */
};
struct tx_fifo {
struct frame_cb queue[MAX_TX_WINDOW + 2]; /* Info about frames in queue */
int ptr; /* Currently being sent */
int len; /* Length of queue */
int free; /* Next free slot */
void *tail; /* Next free start in DMA mem */
};
struct eventflag // for keeping track of Interrupt Events
{
//--------tx part
unsigned char TxFIFOUnderRun;
unsigned char EOMessage;
unsigned char TxFIFOReady;
unsigned char EarlyEOM;
//--------rx part
unsigned char PHYErr;
unsigned char CRCErr;
unsigned char RxFIFOOverRun;
unsigned char EOPacket;
unsigned char RxAvail;
unsigned char TooLargePacket;
unsigned char SIRBad;
//--------unknown
unsigned char Unknown;
//----------
unsigned char TimeOut;
unsigned char RxDMATC;
unsigned char TxDMATC;
};
/* Private data for each instance */
struct via_ircc_cb {
struct st_fifo st_fifo; /* Info about received frames */
struct tx_fifo tx_fifo; /* Info about frames to be transmitted */
struct net_device *netdev; /* Yes! we are some kind of netdevice */
struct irlap_cb *irlap; /* The link layer we are binded to */
struct qos_info qos; /* QoS capabilities for this device */
chipio_t io; /* IrDA controller information */
iobuff_t tx_buff; /* Transmit buffer */
iobuff_t rx_buff; /* Receive buffer */
dma_addr_t tx_buff_dma;
dma_addr_t rx_buff_dma;
__u8 ier; /* Interrupt enable register */
struct timeval stamp;
struct timeval now;
spinlock_t lock; /* For serializing operations */
__u32 flags; /* Interface flags */
__u32 new_speed;
int index; /* Instance index */
struct eventflag EventFlag;
unsigned int chip_id; /* to remember chip id */
unsigned int RetryCount;
unsigned int RxDataReady;
unsigned int RxLastCount;
};
//---------I=Infrared, H=Host, M=Misc, T=Tx, R=Rx, ST=Status,
// CF=Config, CT=Control, L=Low, H=High, C=Count
#define I_CF_L_0 0x10
#define I_CF_H_0 0x11
#define I_SIR_BOF 0x12
#define I_SIR_EOF 0x13
#define I_ST_CT_0 0x15
#define I_ST_L_1 0x16
#define I_ST_H_1 0x17
#define I_CF_L_1 0x18
#define I_CF_H_1 0x19
#define I_CF_L_2 0x1a
#define I_CF_H_2 0x1b
#define I_CF_3 0x1e
#define H_CT 0x20
#define H_ST 0x21
#define M_CT 0x22
#define TX_CT_1 0x23
#define TX_CT_2 0x24
#define TX_ST 0x25
#define RX_CT 0x26
#define RX_ST 0x27
#define RESET 0x28
#define P_ADDR 0x29
#define RX_C_L 0x2a
#define RX_C_H 0x2b
#define RX_P_L 0x2c
#define RX_P_H 0x2d
#define TX_C_L 0x2e
#define TX_C_H 0x2f
#define TIMER 0x32
#define I_CF_4 0x33
#define I_T_C_L 0x34
#define I_T_C_H 0x35
#define VERSION 0x3f
//-------------------------------
#define StartAddr 0x10 // the first register address
#define EndAddr 0x3f // the last register address
#define GetBit(val,bit) val = (unsigned char) ((val>>bit) & 0x1)
// Returns the bit
#define SetBit(val,bit) val= (unsigned char ) (val | (0x1 << bit))
// Sets bit to 1
#define ResetBit(val,bit) val= (unsigned char ) (val & ~(0x1 << bit))
// Sets bit to 0
#define OFF 0
#define ON 1
#define DMA_TX_MODE 0x08
#define DMA_RX_MODE 0x04
#define DMA1 0
#define DMA2 0xc0
#define MASK1 DMA1+0x0a
#define MASK2 DMA2+0x14
#define Clk_bit 0x40
#define Tx_bit 0x01
#define Rd_Valid 0x08
#define RxBit 0x08
static void DisableDmaChannel(unsigned int channel)
{
switch (channel) { // 8 Bit DMA channels DMAC1
case 0:
outb(4, MASK1); //mask channel 0
break;
case 1:
outb(5, MASK1); //Mask channel 1
break;
case 2:
outb(6, MASK1); //Mask channel 2
break;
case 3:
outb(7, MASK1); //Mask channel 3
break;
case 5:
outb(5, MASK2); //Mask channel 5
break;
case 6:
outb(6, MASK2); //Mask channel 6
break;
case 7:
outb(7, MASK2); //Mask channel 7
break;
default:
break;
}
}
static unsigned char ReadLPCReg(int iRegNum)
{
unsigned char iVal;
outb(0x87, 0x2e);
outb(0x87, 0x2e);
outb(iRegNum, 0x2e);
iVal = inb(0x2f);
outb(0xaa, 0x2e);
return iVal;
}
static void WriteLPCReg(int iRegNum, unsigned char iVal)
{
outb(0x87, 0x2e);
outb(0x87, 0x2e);
outb(iRegNum, 0x2e);
outb(iVal, 0x2f);
outb(0xAA, 0x2e);
}
static __u8 ReadReg(unsigned int BaseAddr, int iRegNum)
{
return (__u8) inb(BaseAddr + iRegNum);
}
static void WriteReg(unsigned int BaseAddr, int iRegNum, unsigned char iVal)
{
outb(iVal, BaseAddr + iRegNum);
}
static int WriteRegBit(unsigned int BaseAddr, unsigned char RegNum,
unsigned char BitPos, unsigned char value)
{
__u8 Rtemp, Wtemp;
if (BitPos > 7) {
return -1;
}
if ((RegNum < StartAddr) || (RegNum > EndAddr))
return -1;
Rtemp = ReadReg(BaseAddr, RegNum);
if (value == 0)
Wtemp = ResetBit(Rtemp, BitPos);
else {
if (value == 1)
Wtemp = SetBit(Rtemp, BitPos);
else
return -1;
}
WriteReg(BaseAddr, RegNum, Wtemp);
return 0;
}
static __u8 CheckRegBit(unsigned int BaseAddr, unsigned char RegNum,
unsigned char BitPos)
{
__u8 temp;
if (BitPos > 7)
return 0xff;
if ((RegNum < StartAddr) || (RegNum > EndAddr)) {
// printf("what is the register %x!\n",RegNum);
}
temp = ReadReg(BaseAddr, RegNum);
return GetBit(temp, BitPos);
}
static void SetMaxRxPacketSize(__u16 iobase, __u16 size)
{
__u16 low, high;
if ((size & 0xe000) == 0) {
low = size & 0x00ff;
high = (size & 0x1f00) >> 8;
WriteReg(iobase, I_CF_L_2, low);
WriteReg(iobase, I_CF_H_2, high);
}
}
//for both Rx and Tx
static void SetFIFO(__u16 iobase, __u16 value)
{
switch (value) {
case 128:
WriteRegBit(iobase, 0x11, 0, 0);
WriteRegBit(iobase, 0x11, 7, 1);
break;
case 64:
WriteRegBit(iobase, 0x11, 0, 0);
WriteRegBit(iobase, 0x11, 7, 0);
break;
case 32:
WriteRegBit(iobase, 0x11, 0, 1);
WriteRegBit(iobase, 0x11, 7, 0);
break;
default:
WriteRegBit(iobase, 0x11, 0, 0);
WriteRegBit(iobase, 0x11, 7, 0);
}
}
#define CRC16(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_L_0,7,val) //0 for 32 CRC
/*
#define SetVFIR(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_H_0,5,val)
#define SetFIR(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_L_0,6,val)
#define SetMIR(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_L_0,5,val)
#define SetSIR(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_L_0,4,val)
*/
#define SIRFilter(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_L_0,3,val)
#define Filter(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_L_0,2,val)
#define InvertTX(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_L_0,1,val)
#define InvertRX(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_L_0,0,val)
//****************************I_CF_H_0
#define EnableTX(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_H_0,4,val)
#define EnableRX(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_H_0,3,val)
#define EnableDMA(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_H_0,2,val)
#define SIRRecvAny(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_H_0,1,val)
#define DiableTrans(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_H_0,0,val)
//***************************I_SIR_BOF,I_SIR_EOF
#define SetSIRBOF(BaseAddr,val) WriteReg(BaseAddr,I_SIR_BOF,val)
#define SetSIREOF(BaseAddr,val) WriteReg(BaseAddr,I_SIR_EOF,val)
#define GetSIRBOF(BaseAddr) ReadReg(BaseAddr,I_SIR_BOF)
#define GetSIREOF(BaseAddr) ReadReg(BaseAddr,I_SIR_EOF)
//*******************I_ST_CT_0
#define EnPhys(BaseAddr,val) WriteRegBit(BaseAddr,I_ST_CT_0,7,val)
#define IsModeError(BaseAddr) CheckRegBit(BaseAddr,I_ST_CT_0,6) //RO
#define IsVFIROn(BaseAddr) CheckRegBit(BaseAddr,0x14,0) //RO for VT1211 only
#define IsFIROn(BaseAddr) CheckRegBit(BaseAddr,I_ST_CT_0,5) //RO
#define IsMIROn(BaseAddr) CheckRegBit(BaseAddr,I_ST_CT_0,4) //RO
#define IsSIROn(BaseAddr) CheckRegBit(BaseAddr,I_ST_CT_0,3) //RO
#define IsEnableTX(BaseAddr) CheckRegBit(BaseAddr,I_ST_CT_0,2) //RO
#define IsEnableRX(BaseAddr) CheckRegBit(BaseAddr,I_ST_CT_0,1) //RO
#define Is16CRC(BaseAddr) CheckRegBit(BaseAddr,I_ST_CT_0,0) //RO
//***************************I_CF_3
#define DisableAdjacentPulseWidth(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_3,5,val) //1 disable
#define DisablePulseWidthAdjust(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_3,4,val) //1 disable
#define UseOneRX(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_3,1,val) //0 use two RX
#define SlowIRRXLowActive(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_3,0,val) //0 show RX high=1 in SIR
//***************************H_CT
#define EnAllInt(BaseAddr,val) WriteRegBit(BaseAddr,H_CT,7,val)
#define TXStart(BaseAddr,val) WriteRegBit(BaseAddr,H_CT,6,val)
#define RXStart(BaseAddr,val) WriteRegBit(BaseAddr,H_CT,5,val)
#define ClearRXInt(BaseAddr,val) WriteRegBit(BaseAddr,H_CT,4,val) // 1 clear
//*****************H_ST
#define IsRXInt(BaseAddr) CheckRegBit(BaseAddr,H_ST,4)
#define GetIntIndentify(BaseAddr) ((ReadReg(BaseAddr,H_ST)&0xf1) >>1)
#define IsHostBusy(BaseAddr) CheckRegBit(BaseAddr,H_ST,0)
#define GetHostStatus(BaseAddr) ReadReg(BaseAddr,H_ST) //RO
//**************************M_CT
#define EnTXDMA(BaseAddr,val) WriteRegBit(BaseAddr,M_CT,7,val)
#define EnRXDMA(BaseAddr,val) WriteRegBit(BaseAddr,M_CT,6,val)
#define SwapDMA(BaseAddr,val) WriteRegBit(BaseAddr,M_CT,5,val)
#define EnInternalLoop(BaseAddr,val) WriteRegBit(BaseAddr,M_CT,4,val)
#define EnExternalLoop(BaseAddr,val) WriteRegBit(BaseAddr,M_CT,3,val)
//**************************TX_CT_1
#define EnTXFIFOHalfLevelInt(BaseAddr,val) WriteRegBit(BaseAddr,TX_CT_1,4,val) //half empty int (1 half)
#define EnTXFIFOUnderrunEOMInt(BaseAddr,val) WriteRegBit(BaseAddr,TX_CT_1,5,val)
#define EnTXFIFOReadyInt(BaseAddr,val) WriteRegBit(BaseAddr,TX_CT_1,6,val) //int when reach it threshold (setting by bit 4)
//**************************TX_CT_2
#define ForceUnderrun(BaseAddr,val) WriteRegBit(BaseAddr,TX_CT_2,7,val) // force an underrun int
#define EnTXCRC(BaseAddr,val) WriteRegBit(BaseAddr,TX_CT_2,6,val) //1 for FIR,MIR...0 (not SIR)
#define ForceBADCRC(BaseAddr,val) WriteRegBit(BaseAddr,TX_CT_2,5,val) //force an bad CRC
#define SendSIP(BaseAddr,val) WriteRegBit(BaseAddr,TX_CT_2,4,val) //send indication pulse for prevent SIR disturb
#define ClearEnTX(BaseAddr,val) WriteRegBit(BaseAddr,TX_CT_2,3,val) // opposite to EnTX
//*****************TX_ST
#define GetTXStatus(BaseAddr) ReadReg(BaseAddr,TX_ST) //RO
//**************************RX_CT
#define EnRXSpecInt(BaseAddr,val) WriteRegBit(BaseAddr,RX_CT,0,val)
#define EnRXFIFOReadyInt(BaseAddr,val) WriteRegBit(BaseAddr,RX_CT,1,val) //enable int when reach it threshold (setting by bit 7)
#define EnRXFIFOHalfLevelInt(BaseAddr,val) WriteRegBit(BaseAddr,RX_CT,7,val) //enable int when (1) half full...or (0) just not full
//*****************RX_ST
#define GetRXStatus(BaseAddr) ReadReg(BaseAddr,RX_ST) //RO
//***********************P_ADDR
#define SetPacketAddr(BaseAddr,addr) WriteReg(BaseAddr,P_ADDR,addr)
//***********************I_CF_4
#define EnGPIOtoRX2(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_4,7,val)
#define EnTimerInt(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_4,1,val)
#define ClearTimerInt(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_4,0,val)
//***********************I_T_C_L
#define WriteGIO(BaseAddr,val) WriteRegBit(BaseAddr,I_T_C_L,7,val)
#define ReadGIO(BaseAddr) CheckRegBit(BaseAddr,I_T_C_L,7)
#define ReadRX(BaseAddr) CheckRegBit(BaseAddr,I_T_C_L,3) //RO
#define WriteTX(BaseAddr,val) WriteRegBit(BaseAddr,I_T_C_L,0,val)
//***********************I_T_C_H
#define EnRX2(BaseAddr,val) WriteRegBit(BaseAddr,I_T_C_H,7,val)
#define ReadRX2(BaseAddr) CheckRegBit(BaseAddr,I_T_C_H,7)
//**********************Version
#define GetFIRVersion(BaseAddr) ReadReg(BaseAddr,VERSION)
static void SetTimer(__u16 iobase, __u8 count)
{
EnTimerInt(iobase, OFF);
WriteReg(iobase, TIMER, count);
EnTimerInt(iobase, ON);
}
static void SetSendByte(__u16 iobase, __u32 count)
{
__u32 low, high;
if ((count & 0xf000) == 0) {
low = count & 0x00ff;
high = (count & 0x0f00) >> 8;
WriteReg(iobase, TX_C_L, low);
WriteReg(iobase, TX_C_H, high);
}
}
static void ResetChip(__u16 iobase, __u8 type)
{
__u8 value;
value = (type + 2) << 4;
WriteReg(iobase, RESET, type);
}
static int CkRxRecv(__u16 iobase, struct via_ircc_cb *self)
{
__u8 low, high;
__u16 wTmp = 0, wTmp1 = 0, wTmp_new = 0;
low = ReadReg(iobase, RX_C_L);
high = ReadReg(iobase, RX_C_H);
wTmp1 = high;
wTmp = (wTmp1 << 8) | low;
udelay(10);
low = ReadReg(iobase, RX_C_L);
high = ReadReg(iobase, RX_C_H);
wTmp1 = high;
wTmp_new = (wTmp1 << 8) | low;
if (wTmp_new != wTmp)
return 1;
else
return 0;
}
static __u16 RxCurCount(__u16 iobase, struct via_ircc_cb * self)
{
__u8 low, high;
__u16 wTmp = 0, wTmp1 = 0;
low = ReadReg(iobase, RX_P_L);
high = ReadReg(iobase, RX_P_H);
wTmp1 = high;
wTmp = (wTmp1 << 8) | low;
return wTmp;
}
/* This Routine can only use in recevie_complete
* for it will update last count.
*/
static __u16 GetRecvByte(__u16 iobase, struct via_ircc_cb * self)
{
__u8 low, high;
__u16 wTmp, wTmp1, ret;
low = ReadReg(iobase, RX_P_L);
high = ReadReg(iobase, RX_P_H);
wTmp1 = high;
wTmp = (wTmp1 << 8) | low;
if (wTmp >= self->RxLastCount)
ret = wTmp - self->RxLastCount;
else
ret = (0x8000 - self->RxLastCount) + wTmp;
self->RxLastCount = wTmp;
/* RX_P is more actually the RX_C
low=ReadReg(iobase,RX_C_L);
high=ReadReg(iobase,RX_C_H);
if(!(high&0xe000)) {
temp=(high<<8)+low;
return temp;
}
else return 0;
*/
return ret;
}
static void Sdelay(__u16 scale)
{
__u8 bTmp;
int i, j;
for (j = 0; j < scale; j++) {
for (i = 0; i < 0x20; i++) {
bTmp = inb(0xeb);
outb(bTmp, 0xeb);
}
}
}
static void Tdelay(__u16 scale)
{
__u8 bTmp;
int i, j;
for (j = 0; j < scale; j++) {
for (i = 0; i < 0x50; i++) {
bTmp = inb(0xeb);
outb(bTmp, 0xeb);
}
}
}
static void ActClk(__u16 iobase, __u8 value)
{
__u8 bTmp;
bTmp = ReadReg(iobase, 0x34);
if (value)
WriteReg(iobase, 0x34, bTmp | Clk_bit);
else
WriteReg(iobase, 0x34, bTmp & ~Clk_bit);
}
static void ClkTx(__u16 iobase, __u8 Clk, __u8 Tx)
{
__u8 bTmp;
bTmp = ReadReg(iobase, 0x34);
if (Clk == 0)
bTmp &= ~Clk_bit;
else {
if (Clk == 1)
bTmp |= Clk_bit;
}
WriteReg(iobase, 0x34, bTmp);
Sdelay(1);
if (Tx == 0)
bTmp &= ~Tx_bit;
else {
if (Tx == 1)
bTmp |= Tx_bit;
}
WriteReg(iobase, 0x34, bTmp);
}
static void Wr_Byte(__u16 iobase, __u8 data)
{
__u8 bData = data;
// __u8 btmp;
int i;
ClkTx(iobase, 0, 1);
Tdelay(2);
ActClk(iobase, 1);
Tdelay(1);
for (i = 0; i < 8; i++) { //LDN
if ((bData >> i) & 0x01) {
ClkTx(iobase, 0, 1); //bit data = 1;
} else {
ClkTx(iobase, 0, 0); //bit data = 1;
}
Tdelay(2);
Sdelay(1);
ActClk(iobase, 1); //clk hi
Tdelay(1);
}
}
static __u8 Rd_Indx(__u16 iobase, __u8 addr, __u8 index)
{
__u8 data = 0, bTmp, data_bit;
int i;
bTmp = addr | (index << 1) | 0;
ClkTx(iobase, 0, 0);
Tdelay(2);
ActClk(iobase, 1);
udelay(1);
Wr_Byte(iobase, bTmp);
Sdelay(1);
ClkTx(iobase, 0, 0);
Tdelay(2);
for (i = 0; i < 10; i++) {
ActClk(iobase, 1);
Tdelay(1);
ActClk(iobase, 0);
Tdelay(1);
ClkTx(iobase, 0, 1);
Tdelay(1);
bTmp = ReadReg(iobase, 0x34);
if (!(bTmp & Rd_Valid))
break;
}
if (!(bTmp & Rd_Valid)) {
for (i = 0; i < 8; i++) {
ActClk(iobase, 1);
Tdelay(1);
ActClk(iobase, 0);
bTmp = ReadReg(iobase, 0x34);
data_bit = 1 << i;
if (bTmp & RxBit)
data |= data_bit;
else
data &= ~data_bit;
Tdelay(2);
}
} else {
for (i = 0; i < 2; i++) {
ActClk(iobase, 1);
Tdelay(1);
ActClk(iobase, 0);
Tdelay(2);
}
bTmp = ReadReg(iobase, 0x34);
}
for (i = 0; i < 1; i++) {
ActClk(iobase, 1);
Tdelay(1);
ActClk(iobase, 0);
Tdelay(2);
}
ClkTx(iobase, 0, 0);
Tdelay(1);
for (i = 0; i < 3; i++) {
ActClk(iobase, 1);
Tdelay(1);
ActClk(iobase, 0);
Tdelay(2);
}
return data;
}
static void Wr_Indx(__u16 iobase, __u8 addr, __u8 index, __u8 data)
{
int i;
__u8 bTmp;
ClkTx(iobase, 0, 0);
udelay(2);
ActClk(iobase, 1);
udelay(1);
bTmp = addr | (index << 1) | 1;
Wr_Byte(iobase, bTmp);
Wr_Byte(iobase, data);
for (i = 0; i < 2; i++) {
ClkTx(iobase, 0, 0);
Tdelay(2);
ActClk(iobase, 1);
Tdelay(1);
}
ActClk(iobase, 0);
}
static void ResetDongle(__u16 iobase)
{
int i;
ClkTx(iobase, 0, 0);
Tdelay(1);
for (i = 0; i < 30; i++) {
ActClk(iobase, 1);
Tdelay(1);
ActClk(iobase, 0);
Tdelay(1);
}
ActClk(iobase, 0);
}
static void SetSITmode(__u16 iobase)
{
__u8 bTmp;
bTmp = ReadLPCReg(0x28);
WriteLPCReg(0x28, bTmp | 0x10); //select ITMOFF
bTmp = ReadReg(iobase, 0x35);
WriteReg(iobase, 0x35, bTmp | 0x40); // Driver ITMOFF
WriteReg(iobase, 0x28, bTmp | 0x80); // enable All interrupt
}
static void SI_SetMode(__u16 iobase, int mode)
{
//__u32 dTmp;
__u8 bTmp;
WriteLPCReg(0x28, 0x70); // S/W Reset
SetSITmode(iobase);
ResetDongle(iobase);
udelay(10);
Wr_Indx(iobase, 0x40, 0x0, 0x17); //RX ,APEN enable,Normal power
Wr_Indx(iobase, 0x40, 0x1, mode); //Set Mode
Wr_Indx(iobase, 0x40, 0x2, 0xff); //Set power to FIR VFIR > 1m
bTmp = Rd_Indx(iobase, 0x40, 1);
}
static void InitCard(__u16 iobase)
{
ResetChip(iobase, 5);
WriteReg(iobase, I_ST_CT_0, 0x00); // open CHIP on
SetSIRBOF(iobase, 0xc0); // hardware default value
SetSIREOF(iobase, 0xc1);
}
static void CommonInit(__u16 iobase)
{
// EnTXCRC(iobase,0);
SwapDMA(iobase, OFF);
SetMaxRxPacketSize(iobase, 0x0fff); //set to max:4095
EnRXFIFOReadyInt(iobase, OFF);
EnRXFIFOHalfLevelInt(iobase, OFF);
EnTXFIFOHalfLevelInt(iobase, OFF);
EnTXFIFOUnderrunEOMInt(iobase, ON);
// EnTXFIFOReadyInt(iobase,ON);
InvertTX(iobase, OFF);
InvertRX(iobase, OFF);
// WriteLPCReg(0xF0,0); //(if VT1211 then do this)
if (IsSIROn(iobase)) {
SIRFilter(iobase, ON);
SIRRecvAny(iobase, ON);
} else {
SIRFilter(iobase, OFF);
SIRRecvAny(iobase, OFF);
}
EnRXSpecInt(iobase, ON);
WriteReg(iobase, I_ST_CT_0, 0x80);
EnableDMA(iobase, ON);
}
static void SetBaudRate(__u16 iobase, __u32 rate)
{
__u8 value = 11, temp;
if (IsSIROn(iobase)) {
switch (rate) {
case (__u32) (2400L):
value = 47;
break;
case (__u32) (9600L):
value = 11;
break;
case (__u32) (19200L):
value = 5;
break;
case (__u32) (38400L):
value = 2;
break;
case (__u32) (57600L):
value = 1;
break;
case (__u32) (115200L):
value = 0;
break;
default:
break;
}
} else if (IsMIROn(iobase)) {
value = 0; // will automatically be fixed in 1.152M
} else if (IsFIROn(iobase)) {
value = 0; // will automatically be fixed in 4M
}
temp = (ReadReg(iobase, I_CF_H_1) & 0x03);
temp |= value << 2;
WriteReg(iobase, I_CF_H_1, temp);
}
static void SetPulseWidth(__u16 iobase, __u8 width)
{
__u8 temp, temp1, temp2;
temp = (ReadReg(iobase, I_CF_L_1) & 0x1f);
temp1 = (ReadReg(iobase, I_CF_H_1) & 0xfc);
temp2 = (width & 0x07) << 5;
temp |= temp2;
temp2 = (width & 0x18) >> 3;
temp1 |= temp2;
WriteReg(iobase, I_CF_L_1, temp);
WriteReg(iobase, I_CF_H_1, temp1);
}
static void SetSendPreambleCount(__u16 iobase, __u8 count)
{
__u8 temp;
temp = ReadReg(iobase, I_CF_L_1) & 0xe0;
temp |= count;
WriteReg(iobase, I_CF_L_1, temp);
}
static void SetVFIR(__u16 BaseAddr, __u8 val)
{
__u8 tmp;
tmp = ReadReg(BaseAddr, I_CF_L_0);
WriteReg(BaseAddr, I_CF_L_0, tmp & 0x8f);
WriteRegBit(BaseAddr, I_CF_H_0, 5, val);
}
static void SetFIR(__u16 BaseAddr, __u8 val)
{
__u8 tmp;
WriteRegBit(BaseAddr, I_CF_H_0, 5, 0);
tmp = ReadReg(BaseAddr, I_CF_L_0);
WriteReg(BaseAddr, I_CF_L_0, tmp & 0x8f);
WriteRegBit(BaseAddr, I_CF_L_0, 6, val);
}
static void SetMIR(__u16 BaseAddr, __u8 val)
{
__u8 tmp;
WriteRegBit(BaseAddr, I_CF_H_0, 5, 0);
tmp = ReadReg(BaseAddr, I_CF_L_0);
WriteReg(BaseAddr, I_CF_L_0, tmp & 0x8f);
WriteRegBit(BaseAddr, I_CF_L_0, 5, val);
}
static void SetSIR(__u16 BaseAddr, __u8 val)
{
__u8 tmp;
WriteRegBit(BaseAddr, I_CF_H_0, 5, 0);
tmp = ReadReg(BaseAddr, I_CF_L_0);
WriteReg(BaseAddr, I_CF_L_0, tmp & 0x8f);
WriteRegBit(BaseAddr, I_CF_L_0, 4, val);
}
#endif /* via_IRCC_H */