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net: OpenFirmware GPIO based MDIO bitbang driver
[zen-stable.git] / drivers / net / irda / via-ircc.h
blob9d012f0dbd3089594d7d38cd1845886d06373d83
1 /*********************************************************************
2 *
3 * Filename: via-ircc.h
4 * Version: 1.0
5 * Description: Driver for the VIA VT8231/VT8233 IrDA chipsets
6 * Author: VIA Technologies, inc
7 * Date : 08/06/2003
8
9 Copyright (c) 1998-2003 VIA Technologies, Inc.
10
11 This program is free software; you can redistribute it and/or modify it under
12 the terms of the GNU General Public License as published by the Free Software
13 Foundation; either version 2, or (at your option) any later version.
14
15 This program is distributed in the hope that it will be useful, but WITHOUT
16 ANY WARRANTIES OR REPRESENTATIONS; without even the implied warranty of
17 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
18 See the GNU General Public License for more details.
19
20 You should have received a copy of the GNU General Public License along with
21 this program; if not, write to the Free Software Foundation, Inc.,
22 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
23
24 * Comment:
25 * jul/08/2002 : Rx buffer length should use Rx ring ptr.
26 * Oct/28/2002 : Add SB id for 3147 and 3177.
27 * jul/09/2002 : only implement two kind of dongle currently.
28 * Oct/02/2002 : work on VT8231 and VT8233 .
29 * Aug/06/2003 : change driver format to pci driver .
30 ********************************************************************/
31 #ifndef via_IRCC_H
32 #define via_IRCC_H
33 #include <linux/time.h>
34 #include <linux/spinlock.h>
35 #include <linux/pm.h>
36 #include <linux/types.h>
37 #include <asm/io.h>
38
39 #define MAX_TX_WINDOW 7
40 #define MAX_RX_WINDOW 7
41
42 struct st_fifo_entry {
43 int status;
44 int len;
45 };
46
47 struct st_fifo {
48 struct st_fifo_entry entries[MAX_RX_WINDOW + 2];
49 int pending_bytes;
50 int head;
51 int tail;
52 int len;
53 };
54
55 struct frame_cb {
56 void *start; /* Start of frame in DMA mem */
57 int len; /* Length of frame in DMA mem */
58 };
59
60 struct tx_fifo {
61 struct frame_cb queue[MAX_TX_WINDOW + 2]; /* Info about frames in queue */
62 int ptr; /* Currently being sent */
63 int len; /* Length of queue */
64 int free; /* Next free slot */
65 void *tail; /* Next free start in DMA mem */
66 };
67
68
69 struct eventflag // for keeping track of Interrupt Events
70 {
71 //--------tx part
72 unsigned char TxFIFOUnderRun;
73 unsigned char EOMessage;
74 unsigned char TxFIFOReady;
75 unsigned char EarlyEOM;
76 //--------rx part
77 unsigned char PHYErr;
78 unsigned char CRCErr;
79 unsigned char RxFIFOOverRun;
80 unsigned char EOPacket;
81 unsigned char RxAvail;
82 unsigned char TooLargePacket;
83 unsigned char SIRBad;
84 //--------unknown
85 unsigned char Unknown;
86 //----------
87 unsigned char TimeOut;
88 unsigned char RxDMATC;
89 unsigned char TxDMATC;
90 };
91
92 /* Private data for each instance */
93 struct via_ircc_cb {
94 struct st_fifo st_fifo; /* Info about received frames */
95 struct tx_fifo tx_fifo; /* Info about frames to be transmitted */
96
97 struct net_device *netdev; /* Yes! we are some kind of netdevice */
98 struct net_device_stats stats;
99
100 struct irlap_cb *irlap; /* The link layer we are binded to */
101 struct qos_info qos; /* QoS capabilities for this device */
102
103 chipio_t io; /* IrDA controller information */
104 iobuff_t tx_buff; /* Transmit buffer */
105 iobuff_t rx_buff; /* Receive buffer */
106 dma_addr_t tx_buff_dma;
107 dma_addr_t rx_buff_dma;
108
109 __u8 ier; /* Interrupt enable register */
110
111 struct timeval stamp;
112 struct timeval now;
113
114 spinlock_t lock; /* For serializing operations */
115
116 __u32 flags; /* Interface flags */
117 __u32 new_speed;
118 int index; /* Instance index */
119
120 struct eventflag EventFlag;
121 struct pm_dev *dev;
122 unsigned int chip_id; /* to remember chip id */
123 unsigned int RetryCount;
124 unsigned int RxDataReady;
125 unsigned int RxLastCount;
126 };
127
128
129 //---------I=Infrared, H=Host, M=Misc, T=Tx, R=Rx, ST=Status,
130 // CF=Config, CT=Control, L=Low, H=High, C=Count
131 #define I_CF_L_0 0x10
132 #define I_CF_H_0 0x11
133 #define I_SIR_BOF 0x12
134 #define I_SIR_EOF 0x13
135 #define I_ST_CT_0 0x15
136 #define I_ST_L_1 0x16
137 #define I_ST_H_1 0x17
138 #define I_CF_L_1 0x18
139 #define I_CF_H_1 0x19
140 #define I_CF_L_2 0x1a
141 #define I_CF_H_2 0x1b
142 #define I_CF_3 0x1e
143 #define H_CT 0x20
144 #define H_ST 0x21
145 #define M_CT 0x22
146 #define TX_CT_1 0x23
147 #define TX_CT_2 0x24
148 #define TX_ST 0x25
149 #define RX_CT 0x26
150 #define RX_ST 0x27
151 #define RESET 0x28
152 #define P_ADDR 0x29
153 #define RX_C_L 0x2a
154 #define RX_C_H 0x2b
155 #define RX_P_L 0x2c
156 #define RX_P_H 0x2d
157 #define TX_C_L 0x2e
158 #define TX_C_H 0x2f
159 #define TIMER 0x32
160 #define I_CF_4 0x33
161 #define I_T_C_L 0x34
162 #define I_T_C_H 0x35
163 #define VERSION 0x3f
164 //-------------------------------
165 #define StartAddr 0x10 // the first register address
166 #define EndAddr 0x3f // the last register address
167 #define GetBit(val,bit) val = (unsigned char) ((val>>bit) & 0x1)
168 // Returns the bit
169 #define SetBit(val,bit) val= (unsigned char ) (val | (0x1 << bit))
170 // Sets bit to 1
171 #define ResetBit(val,bit) val= (unsigned char ) (val & ~(0x1 << bit))
172 // Sets bit to 0
173
174 #define OFF 0
175 #define ON 1
176 #define DMA_TX_MODE 0x08
177 #define DMA_RX_MODE 0x04
178
179 #define DMA1 0
180 #define DMA2 0xc0
181 #define MASK1 DMA1+0x0a
182 #define MASK2 DMA2+0x14
183
184 #define Clk_bit 0x40
185 #define Tx_bit 0x01
186 #define Rd_Valid 0x08
187 #define RxBit 0x08
188
189 static void DisableDmaChannel(unsigned int channel)
190 {
191 switch (channel) { // 8 Bit DMA channels DMAC1
192 case 0:
193 outb(4, MASK1); //mask channel 0
194 break;
195 case 1:
196 outb(5, MASK1); //Mask channel 1
197 break;
198 case 2:
199 outb(6, MASK1); //Mask channel 2
200 break;
201 case 3:
202 outb(7, MASK1); //Mask channel 3
203 break;
204 case 5:
205 outb(5, MASK2); //Mask channel 5
206 break;
207 case 6:
208 outb(6, MASK2); //Mask channel 6
209 break;
210 case 7:
211 outb(7, MASK2); //Mask channel 7
212 break;
213 default:
214 break;
215 }; //Switch
216 }
217
218 static unsigned char ReadLPCReg(int iRegNum)
219 {
220 unsigned char iVal;
221
222 outb(0x87, 0x2e);
223 outb(0x87, 0x2e);
224 outb(iRegNum, 0x2e);
225 iVal = inb(0x2f);
226 outb(0xaa, 0x2e);
227
228 return iVal;
229 }
230
231 static void WriteLPCReg(int iRegNum, unsigned char iVal)
232 {
233
234 outb(0x87, 0x2e);
235 outb(0x87, 0x2e);
236 outb(iRegNum, 0x2e);
237 outb(iVal, 0x2f);
238 outb(0xAA, 0x2e);
239 }
240
241 static __u8 ReadReg(unsigned int BaseAddr, int iRegNum)
242 {
243 return ((__u8) inb(BaseAddr + iRegNum));
244 }
245
246 static void WriteReg(unsigned int BaseAddr, int iRegNum, unsigned char iVal)
247 {
248 outb(iVal, BaseAddr + iRegNum);
249 }
250
251 static int WriteRegBit(unsigned int BaseAddr, unsigned char RegNum,
252 unsigned char BitPos, unsigned char value)
253 {
254 __u8 Rtemp, Wtemp;
255
256 if (BitPos > 7) {
257 return -1;
258 }
259 if ((RegNum < StartAddr) || (RegNum > EndAddr))
260 return -1;
261 Rtemp = ReadReg(BaseAddr, RegNum);
262 if (value == 0)
263 Wtemp = ResetBit(Rtemp, BitPos);
264 else {
265 if (value == 1)
266 Wtemp = SetBit(Rtemp, BitPos);
267 else
268 return -1;
269 }
270 WriteReg(BaseAddr, RegNum, Wtemp);
271 return 0;
272 }
273
274 static __u8 CheckRegBit(unsigned int BaseAddr, unsigned char RegNum,
275 unsigned char BitPos)
276 {
277 __u8 temp;
278
279 if (BitPos > 7)
280 return 0xff;
281 if ((RegNum < StartAddr) || (RegNum > EndAddr)) {
282 // printf("what is the register %x!\n",RegNum);
283 }
284 temp = ReadReg(BaseAddr, RegNum);
285 return GetBit(temp, BitPos);
286 }
287
288 static void SetMaxRxPacketSize(__u16 iobase, __u16 size)
289 {
290 __u16 low, high;
291 if ((size & 0xe000) == 0) {
292 low = size & 0x00ff;
293 high = (size & 0x1f00) >> 8;
294 WriteReg(iobase, I_CF_L_2, low);
295 WriteReg(iobase, I_CF_H_2, high);
296
297 }
298
299 }
300
301 //for both Rx and Tx
302
303 static void SetFIFO(__u16 iobase, __u16 value)
304 {
305 switch (value) {
306 case 128:
307 WriteRegBit(iobase, 0x11, 0, 0);
308 WriteRegBit(iobase, 0x11, 7, 1);
309 break;
310 case 64:
311 WriteRegBit(iobase, 0x11, 0, 0);
312 WriteRegBit(iobase, 0x11, 7, 0);
313 break;
314 case 32:
315 WriteRegBit(iobase, 0x11, 0, 1);
316 WriteRegBit(iobase, 0x11, 7, 0);
317 break;
318 default:
319 WriteRegBit(iobase, 0x11, 0, 0);
320 WriteRegBit(iobase, 0x11, 7, 0);
321 }
322
323 }
324
325 #define CRC16(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_L_0,7,val) //0 for 32 CRC
326 /*
327 #define SetVFIR(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_H_0,5,val)
328 #define SetFIR(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_L_0,6,val)
329 #define SetMIR(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_L_0,5,val)
330 #define SetSIR(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_L_0,4,val)
331 */
332 #define SIRFilter(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_L_0,3,val)
333 #define Filter(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_L_0,2,val)
334 #define InvertTX(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_L_0,1,val)
335 #define InvertRX(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_L_0,0,val)
336 //****************************I_CF_H_0
337 #define EnableTX(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_H_0,4,val)
338 #define EnableRX(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_H_0,3,val)
339 #define EnableDMA(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_H_0,2,val)
340 #define SIRRecvAny(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_H_0,1,val)
341 #define DiableTrans(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_H_0,0,val)
342 //***************************I_SIR_BOF,I_SIR_EOF
343 #define SetSIRBOF(BaseAddr,val) WriteReg(BaseAddr,I_SIR_BOF,val)
344 #define SetSIREOF(BaseAddr,val) WriteReg(BaseAddr,I_SIR_EOF,val)
345 #define GetSIRBOF(BaseAddr) ReadReg(BaseAddr,I_SIR_BOF)
346 #define GetSIREOF(BaseAddr) ReadReg(BaseAddr,I_SIR_EOF)
347 //*******************I_ST_CT_0
348 #define EnPhys(BaseAddr,val) WriteRegBit(BaseAddr,I_ST_CT_0,7,val)
349 #define IsModeError(BaseAddr) CheckRegBit(BaseAddr,I_ST_CT_0,6) //RO
350 #define IsVFIROn(BaseAddr) CheckRegBit(BaseAddr,0x14,0) //RO for VT1211 only
351 #define IsFIROn(BaseAddr) CheckRegBit(BaseAddr,I_ST_CT_0,5) //RO
352 #define IsMIROn(BaseAddr) CheckRegBit(BaseAddr,I_ST_CT_0,4) //RO
353 #define IsSIROn(BaseAddr) CheckRegBit(BaseAddr,I_ST_CT_0,3) //RO
354 #define IsEnableTX(BaseAddr) CheckRegBit(BaseAddr,I_ST_CT_0,2) //RO
355 #define IsEnableRX(BaseAddr) CheckRegBit(BaseAddr,I_ST_CT_0,1) //RO
356 #define Is16CRC(BaseAddr) CheckRegBit(BaseAddr,I_ST_CT_0,0) //RO
357 //***************************I_CF_3
358 #define DisableAdjacentPulseWidth(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_3,5,val) //1 disable
359 #define DisablePulseWidthAdjust(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_3,4,val) //1 disable
360 #define UseOneRX(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_3,1,val) //0 use two RX
361 #define SlowIRRXLowActive(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_3,0,val) //0 show RX high=1 in SIR
362 //***************************H_CT
363 #define EnAllInt(BaseAddr,val) WriteRegBit(BaseAddr,H_CT,7,val)
364 #define TXStart(BaseAddr,val) WriteRegBit(BaseAddr,H_CT,6,val)
365 #define RXStart(BaseAddr,val) WriteRegBit(BaseAddr,H_CT,5,val)
366 #define ClearRXInt(BaseAddr,val) WriteRegBit(BaseAddr,H_CT,4,val) // 1 clear
367 //*****************H_ST
368 #define IsRXInt(BaseAddr) CheckRegBit(BaseAddr,H_ST,4)
369 #define GetIntIndentify(BaseAddr) ((ReadReg(BaseAddr,H_ST)&0xf1) >>1)
370 #define IsHostBusy(BaseAddr) CheckRegBit(BaseAddr,H_ST,0)
371 #define GetHostStatus(BaseAddr) ReadReg(BaseAddr,H_ST) //RO
372 //**************************M_CT
373 #define EnTXDMA(BaseAddr,val) WriteRegBit(BaseAddr,M_CT,7,val)
374 #define EnRXDMA(BaseAddr,val) WriteRegBit(BaseAddr,M_CT,6,val)
375 #define SwapDMA(BaseAddr,val) WriteRegBit(BaseAddr,M_CT,5,val)
376 #define EnInternalLoop(BaseAddr,val) WriteRegBit(BaseAddr,M_CT,4,val)
377 #define EnExternalLoop(BaseAddr,val) WriteRegBit(BaseAddr,M_CT,3,val)
378 //**************************TX_CT_1
379 #define EnTXFIFOHalfLevelInt(BaseAddr,val) WriteRegBit(BaseAddr,TX_CT_1,4,val) //half empty int (1 half)
380 #define EnTXFIFOUnderrunEOMInt(BaseAddr,val) WriteRegBit(BaseAddr,TX_CT_1,5,val)
381 #define EnTXFIFOReadyInt(BaseAddr,val) WriteRegBit(BaseAddr,TX_CT_1,6,val) //int when reach it threshold (setting by bit 4)
382 //**************************TX_CT_2
383 #define ForceUnderrun(BaseAddr,val) WriteRegBit(BaseAddr,TX_CT_2,7,val) // force an underrun int
384 #define EnTXCRC(BaseAddr,val) WriteRegBit(BaseAddr,TX_CT_2,6,val) //1 for FIR,MIR...0 (not SIR)
385 #define ForceBADCRC(BaseAddr,val) WriteRegBit(BaseAddr,TX_CT_2,5,val) //force an bad CRC
386 #define SendSIP(BaseAddr,val) WriteRegBit(BaseAddr,TX_CT_2,4,val) //send indication pulse for prevent SIR disturb
387 #define ClearEnTX(BaseAddr,val) WriteRegBit(BaseAddr,TX_CT_2,3,val) // opposite to EnTX
388 //*****************TX_ST
389 #define GetTXStatus(BaseAddr) ReadReg(BaseAddr,TX_ST) //RO
390 //**************************RX_CT
391 #define EnRXSpecInt(BaseAddr,val) WriteRegBit(BaseAddr,RX_CT,0,val)
392 #define EnRXFIFOReadyInt(BaseAddr,val) WriteRegBit(BaseAddr,RX_CT,1,val) //enable int when reach it threshold (setting by bit 7)
393 #define EnRXFIFOHalfLevelInt(BaseAddr,val) WriteRegBit(BaseAddr,RX_CT,7,val) //enable int when (1) half full...or (0) just not full
394 //*****************RX_ST
395 #define GetRXStatus(BaseAddr) ReadReg(BaseAddr,RX_ST) //RO
396 //***********************P_ADDR
397 #define SetPacketAddr(BaseAddr,addr) WriteReg(BaseAddr,P_ADDR,addr)
398 //***********************I_CF_4
399 #define EnGPIOtoRX2(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_4,7,val)
400 #define EnTimerInt(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_4,1,val)
401 #define ClearTimerInt(BaseAddr,val) WriteRegBit(BaseAddr,I_CF_4,0,val)
402 //***********************I_T_C_L
403 #define WriteGIO(BaseAddr,val) WriteRegBit(BaseAddr,I_T_C_L,7,val)
404 #define ReadGIO(BaseAddr) CheckRegBit(BaseAddr,I_T_C_L,7)
405 #define ReadRX(BaseAddr) CheckRegBit(BaseAddr,I_T_C_L,3) //RO
406 #define WriteTX(BaseAddr,val) WriteRegBit(BaseAddr,I_T_C_L,0,val)
407 //***********************I_T_C_H
408 #define EnRX2(BaseAddr,val) WriteRegBit(BaseAddr,I_T_C_H,7,val)
409 #define ReadRX2(BaseAddr) CheckRegBit(BaseAddr,I_T_C_H,7)
410 //**********************Version
411 #define GetFIRVersion(BaseAddr) ReadReg(BaseAddr,VERSION)
412
413
414 static void SetTimer(__u16 iobase, __u8 count)
415 {
416 EnTimerInt(iobase, OFF);
417 WriteReg(iobase, TIMER, count);
418 EnTimerInt(iobase, ON);
419 }
420
421
422 static void SetSendByte(__u16 iobase, __u32 count)
423 {
424 __u32 low, high;
425
426 if ((count & 0xf000) == 0) {
427 low = count & 0x00ff;
428 high = (count & 0x0f00) >> 8;
429 WriteReg(iobase, TX_C_L, low);
430 WriteReg(iobase, TX_C_H, high);
431 }
432 }
433
434 static void ResetChip(__u16 iobase, __u8 type)
435 {
436 __u8 value;
437
438 value = (type + 2) << 4;
439 WriteReg(iobase, RESET, type);
440 }
441
442 static int CkRxRecv(__u16 iobase, struct via_ircc_cb *self)
443 {
444 __u8 low, high;
445 __u16 wTmp = 0, wTmp1 = 0, wTmp_new = 0;
446
447 low = ReadReg(iobase, RX_C_L);
448 high = ReadReg(iobase, RX_C_H);
449 wTmp1 = high;
450 wTmp = (wTmp1 << 8) | low;
451 udelay(10);
452 low = ReadReg(iobase, RX_C_L);
453 high = ReadReg(iobase, RX_C_H);
454 wTmp1 = high;
455 wTmp_new = (wTmp1 << 8) | low;
456 if (wTmp_new != wTmp)
457 return 1;
458 else
459 return 0;
460
461 }
462
463 static __u16 RxCurCount(__u16 iobase, struct via_ircc_cb * self)
464 {
465 __u8 low, high;
466 __u16 wTmp = 0, wTmp1 = 0;
467
468 low = ReadReg(iobase, RX_P_L);
469 high = ReadReg(iobase, RX_P_H);
470 wTmp1 = high;
471 wTmp = (wTmp1 << 8) | low;
472 return wTmp;
473 }
474
475 /* This Routine can only use in recevie_complete
476 * for it will update last count.
477 */
478
479 static __u16 GetRecvByte(__u16 iobase, struct via_ircc_cb * self)
480 {
481 __u8 low, high;
482 __u16 wTmp, wTmp1, ret;
483
484 low = ReadReg(iobase, RX_P_L);
485 high = ReadReg(iobase, RX_P_H);
486 wTmp1 = high;
487 wTmp = (wTmp1 << 8) | low;
488
489
490 if (wTmp >= self->RxLastCount)
491 ret = wTmp - self->RxLastCount;
492 else
493 ret = (0x8000 - self->RxLastCount) + wTmp;
494 self->RxLastCount = wTmp;
495
496 /* RX_P is more actually the RX_C
497 low=ReadReg(iobase,RX_C_L);
498 high=ReadReg(iobase,RX_C_H);
499
500 if(!(high&0xe000)) {
501 temp=(high<<8)+low;
502 return temp;
503 }
504 else return 0;
505 */
506 return ret;
507 }
508
509 static void Sdelay(__u16 scale)
510 {
511 __u8 bTmp;
512 int i, j;
513
514 for (j = 0; j < scale; j++) {
515 for (i = 0; i < 0x20; i++) {
516 bTmp = inb(0xeb);
517 outb(bTmp, 0xeb);
518 }
519 }
520 }
521
522 static void Tdelay(__u16 scale)
523 {
524 __u8 bTmp;
525 int i, j;
526
527 for (j = 0; j < scale; j++) {
528 for (i = 0; i < 0x50; i++) {
529 bTmp = inb(0xeb);
530 outb(bTmp, 0xeb);
531 }
532 }
533 }
534
535
536 static void ActClk(__u16 iobase, __u8 value)
537 {
538 __u8 bTmp;
539 bTmp = ReadReg(iobase, 0x34);
540 if (value)
541 WriteReg(iobase, 0x34, bTmp | Clk_bit);
542 else
543 WriteReg(iobase, 0x34, bTmp & ~Clk_bit);
544 }
545
546 static void ClkTx(__u16 iobase, __u8 Clk, __u8 Tx)
547 {
548 __u8 bTmp;
549
550 bTmp = ReadReg(iobase, 0x34);
551 if (Clk == 0)
552 bTmp &= ~Clk_bit;
553 else {
554 if (Clk == 1)
555 bTmp |= Clk_bit;
556 }
557 WriteReg(iobase, 0x34, bTmp);
558 Sdelay(1);
559 if (Tx == 0)
560 bTmp &= ~Tx_bit;
561 else {
562 if (Tx == 1)
563 bTmp |= Tx_bit;
564 }
565 WriteReg(iobase, 0x34, bTmp);
566 }
567
568 static void Wr_Byte(__u16 iobase, __u8 data)
569 {
570 __u8 bData = data;
571 // __u8 btmp;
572 int i;
573
574 ClkTx(iobase, 0, 1);
575
576 Tdelay(2);
577 ActClk(iobase, 1);
578 Tdelay(1);
579
580 for (i = 0; i < 8; i++) { //LDN
581
582 if ((bData >> i) & 0x01) {
583 ClkTx(iobase, 0, 1); //bit data = 1;
584 } else {
585 ClkTx(iobase, 0, 0); //bit data = 1;
586 }
587 Tdelay(2);
588 Sdelay(1);
589 ActClk(iobase, 1); //clk hi
590 Tdelay(1);
591 }
592 }
593
594 static __u8 Rd_Indx(__u16 iobase, __u8 addr, __u8 index)
595 {
596 __u8 data = 0, bTmp, data_bit;
597 int i;
598
599 bTmp = addr | (index << 1) | 0;
600 ClkTx(iobase, 0, 0);
601 Tdelay(2);
602 ActClk(iobase, 1);
603 udelay(1);
604 Wr_Byte(iobase, bTmp);
605 Sdelay(1);
606 ClkTx(iobase, 0, 0);
607 Tdelay(2);
608 for (i = 0; i < 10; i++) {
609 ActClk(iobase, 1);
610 Tdelay(1);
611 ActClk(iobase, 0);
612 Tdelay(1);
613 ClkTx(iobase, 0, 1);
614 Tdelay(1);
615 bTmp = ReadReg(iobase, 0x34);
616 if (!(bTmp & Rd_Valid))
617 break;
618 }
619 if (!(bTmp & Rd_Valid)) {
620 for (i = 0; i < 8; i++) {
621 ActClk(iobase, 1);
622 Tdelay(1);
623 ActClk(iobase, 0);
624 bTmp = ReadReg(iobase, 0x34);
625 data_bit = 1 << i;
626 if (bTmp & RxBit)
627 data |= data_bit;
628 else
629 data &= ~data_bit;
630 Tdelay(2);
631 }
632 } else {
633 for (i = 0; i < 2; i++) {
634 ActClk(iobase, 1);
635 Tdelay(1);
636 ActClk(iobase, 0);
637 Tdelay(2);
638 }
639 bTmp = ReadReg(iobase, 0x34);
640 }
641 for (i = 0; i < 1; i++) {
642 ActClk(iobase, 1);
643 Tdelay(1);
644 ActClk(iobase, 0);
645 Tdelay(2);
646 }
647 ClkTx(iobase, 0, 0);
648 Tdelay(1);
649 for (i = 0; i < 3; i++) {
650 ActClk(iobase, 1);
651 Tdelay(1);
652 ActClk(iobase, 0);
653 Tdelay(2);
654 }
655 return data;
656 }
657
658 static void Wr_Indx(__u16 iobase, __u8 addr, __u8 index, __u8 data)
659 {
660 int i;
661 __u8 bTmp;
662
663 ClkTx(iobase, 0, 0);
664 udelay(2);
665 ActClk(iobase, 1);
666 udelay(1);
667 bTmp = addr | (index << 1) | 1;
668 Wr_Byte(iobase, bTmp);
669 Wr_Byte(iobase, data);
670 for (i = 0; i < 2; i++) {
671 ClkTx(iobase, 0, 0);
672 Tdelay(2);
673 ActClk(iobase, 1);
674 Tdelay(1);
675 }
676 ActClk(iobase, 0);
677 }
678
679 static void ResetDongle(__u16 iobase)
680 {
681 int i;
682 ClkTx(iobase, 0, 0);
683 Tdelay(1);
684 for (i = 0; i < 30; i++) {
685 ActClk(iobase, 1);
686 Tdelay(1);
687 ActClk(iobase, 0);
688 Tdelay(1);
689 }
690 ActClk(iobase, 0);
691 }
692
693 static void SetSITmode(__u16 iobase)
694 {
695
696 __u8 bTmp;
697
698 bTmp = ReadLPCReg(0x28);
699 WriteLPCReg(0x28, bTmp | 0x10); //select ITMOFF
700 bTmp = ReadReg(iobase, 0x35);
701 WriteReg(iobase, 0x35, bTmp | 0x40); // Driver ITMOFF
702 WriteReg(iobase, 0x28, bTmp | 0x80); // enable All interrupt
703 }
704
705 static void SI_SetMode(__u16 iobase, int mode)
706 {
707 //__u32 dTmp;
708 __u8 bTmp;
709
710 WriteLPCReg(0x28, 0x70); // S/W Reset
711 SetSITmode(iobase);
712 ResetDongle(iobase);
713 udelay(10);
714 Wr_Indx(iobase, 0x40, 0x0, 0x17); //RX ,APEN enable,Normal power
715 Wr_Indx(iobase, 0x40, 0x1, mode); //Set Mode
716 Wr_Indx(iobase, 0x40, 0x2, 0xff); //Set power to FIR VFIR > 1m
717 bTmp = Rd_Indx(iobase, 0x40, 1);
718 }
719
720 static void InitCard(__u16 iobase)
721 {
722 ResetChip(iobase, 5);
723 WriteReg(iobase, I_ST_CT_0, 0x00); // open CHIP on
724 SetSIRBOF(iobase, 0xc0); // hardware default value
725 SetSIREOF(iobase, 0xc1);
726 }
727
728 static void CommonInit(__u16 iobase)
729 {
730 // EnTXCRC(iobase,0);
731 SwapDMA(iobase, OFF);
732 SetMaxRxPacketSize(iobase, 0x0fff); //set to max:4095
733 EnRXFIFOReadyInt(iobase, OFF);
734 EnRXFIFOHalfLevelInt(iobase, OFF);
735 EnTXFIFOHalfLevelInt(iobase, OFF);
736 EnTXFIFOUnderrunEOMInt(iobase, ON);
737 // EnTXFIFOReadyInt(iobase,ON);
738 InvertTX(iobase, OFF);
739 InvertRX(iobase, OFF);
740 // WriteLPCReg(0xF0,0); //(if VT1211 then do this)
741 if (IsSIROn(iobase)) {
742 SIRFilter(iobase, ON);
743 SIRRecvAny(iobase, ON);
744 } else {
745 SIRFilter(iobase, OFF);
746 SIRRecvAny(iobase, OFF);
747 }
748 EnRXSpecInt(iobase, ON);
749 WriteReg(iobase, I_ST_CT_0, 0x80);
750 EnableDMA(iobase, ON);
751 }
752
753 static void SetBaudRate(__u16 iobase, __u32 rate)
754 {
755 __u8 value = 11, temp;
756
757 if (IsSIROn(iobase)) {
758 switch (rate) {
759 case (__u32) (2400L):
760 value = 47;
761 break;
762 case (__u32) (9600L):
763 value = 11;
764 break;
765 case (__u32) (19200L):
766 value = 5;
767 break;
768 case (__u32) (38400L):
769 value = 2;
770 break;
771 case (__u32) (57600L):
772 value = 1;
773 break;
774 case (__u32) (115200L):
775 value = 0;
776 break;
777 default:
778 break;
779 };
780 } else if (IsMIROn(iobase)) {
781 value = 0; // will automatically be fixed in 1.152M
782 } else if (IsFIROn(iobase)) {
783 value = 0; // will automatically be fixed in 4M
784 }
785 temp = (ReadReg(iobase, I_CF_H_1) & 0x03);
786 temp |= value << 2;
787 WriteReg(iobase, I_CF_H_1, temp);
788 }
789
790 static void SetPulseWidth(__u16 iobase, __u8 width)
791 {
792 __u8 temp, temp1, temp2;
793
794 temp = (ReadReg(iobase, I_CF_L_1) & 0x1f);
795 temp1 = (ReadReg(iobase, I_CF_H_1) & 0xfc);
796 temp2 = (width & 0x07) << 5;
797 temp |= temp2;
798 temp2 = (width & 0x18) >> 3;
799 temp1 |= temp2;
800 WriteReg(iobase, I_CF_L_1, temp);
801 WriteReg(iobase, I_CF_H_1, temp1);
802 }
803
804 static void SetSendPreambleCount(__u16 iobase, __u8 count)
805 {
806 __u8 temp;
807
808 temp = ReadReg(iobase, I_CF_L_1) & 0xe0;
809 temp |= count;
810 WriteReg(iobase, I_CF_L_1, temp);
811
812 }
813
814 static void SetVFIR(__u16 BaseAddr, __u8 val)
815 {
816 __u8 tmp;
817
818 tmp = ReadReg(BaseAddr, I_CF_L_0);
819 WriteReg(BaseAddr, I_CF_L_0, tmp & 0x8f);
820 WriteRegBit(BaseAddr, I_CF_H_0, 5, val);
821 }
822
823 static void SetFIR(__u16 BaseAddr, __u8 val)
824 {
825 __u8 tmp;
826
827 WriteRegBit(BaseAddr, I_CF_H_0, 5, 0);
828 tmp = ReadReg(BaseAddr, I_CF_L_0);
829 WriteReg(BaseAddr, I_CF_L_0, tmp & 0x8f);
830 WriteRegBit(BaseAddr, I_CF_L_0, 6, val);
831 }
832
833 static void SetMIR(__u16 BaseAddr, __u8 val)
834 {
835 __u8 tmp;
836
837 WriteRegBit(BaseAddr, I_CF_H_0, 5, 0);
838 tmp = ReadReg(BaseAddr, I_CF_L_0);
839 WriteReg(BaseAddr, I_CF_L_0, tmp & 0x8f);
840 WriteRegBit(BaseAddr, I_CF_L_0, 5, val);
841 }
842
843 static void SetSIR(__u16 BaseAddr, __u8 val)
844 {
845 __u8 tmp;
846
847 WriteRegBit(BaseAddr, I_CF_H_0, 5, 0);
848 tmp = ReadReg(BaseAddr, I_CF_L_0);
849 WriteReg(BaseAddr, I_CF_L_0, tmp & 0x8f);
850 WriteRegBit(BaseAddr, I_CF_L_0, 4, val);
851 }
852
853 #endif /* via_IRCC_H */