1 /* SPDX-License-Identifier: GPL-2.0 */
2 /*
3 * rocket_int.h --- internal header file for rocket.c
4 *
5 * Written by Theodore Ts'o, Copyright 1997.
6 * Copyright 1997 Comtrol Corporation.
7 *
8 */
9
10 /*
11 * Definition of the types in rcktpt_type
12 */
13 #define ROCKET_TYPE_NORMAL 0
14 #define ROCKET_TYPE_MODEM 1
15 #define ROCKET_TYPE_MODEMII 2
16 #define ROCKET_TYPE_MODEMIII 3
17 #define ROCKET_TYPE_PC104 4
18
19 #include <linux/mutex.h>
20
21 #include <asm/io.h>
22 #include <asm/byteorder.h>
23
24 typedef unsigned char Byte_t;
25 typedef unsigned int ByteIO_t;
26
27 typedef unsigned int Word_t;
28 typedef unsigned int WordIO_t;
29
30 typedef unsigned int DWordIO_t;
31
32 /*
33 * Note! Normally the Linux I/O macros already take care of
34 * byte-swapping the I/O instructions. However, all accesses using
35 * sOutDW aren't really 32-bit accesses, but should be handled in byte
36 * order. Hence the use of the cpu_to_le32() macro to byte-swap
37 * things to no-op the byte swapping done by the big-endian outl()
38 * instruction.
39 */
40
sOutB(unsigned short port,unsigned char value)41 static inline void sOutB(unsigned short port, unsigned char value)
42 {
43 #ifdef ROCKET_DEBUG_IO
44 printk(KERN_DEBUG "sOutB(%x, %x)...\n", port, value);
45 #endif
46 outb_p(value, port);
47 }
48
sOutW(unsigned short port,unsigned short value)49 static inline void sOutW(unsigned short port, unsigned short value)
50 {
51 #ifdef ROCKET_DEBUG_IO
52 printk(KERN_DEBUG "sOutW(%x, %x)...\n", port, value);
53 #endif
54 outw_p(value, port);
55 }
56
out32(unsigned short port,Byte_t * p)57 static inline void out32(unsigned short port, Byte_t *p)
58 {
59 u32 value = get_unaligned_le32(p);
60 #ifdef ROCKET_DEBUG_IO
61 printk(KERN_DEBUG "out32(%x, %lx)...\n", port, value);
62 #endif
63 outl_p(value, port);
64 }
65
sInB(unsigned short port)66 static inline unsigned char sInB(unsigned short port)
67 {
68 return inb_p(port);
69 }
70
sInW(unsigned short port)71 static inline unsigned short sInW(unsigned short port)
72 {
73 return inw_p(port);
74 }
75
76 /* This is used to move arrays of bytes so byte swapping isn't appropriate. */
77 #define sOutStrW(port, addr, count) if (count) outsw(port, addr, count)
78 #define sInStrW(port, addr, count) if (count) insw(port, addr, count)
79
80 #define CTL_SIZE 8
81 #define AIOP_CTL_SIZE 4
82 #define CHAN_AIOP_SIZE 8
83 #define MAX_PORTS_PER_AIOP 8
84 #define MAX_AIOPS_PER_BOARD 4
85 #define MAX_PORTS_PER_BOARD 32
86
87 /* Bus type ID */
88 #define isISA 0
89 #define isPCI 1
90 #define isMC 2
91
92 /* Controller ID numbers */
93 #define CTLID_NULL -1 /* no controller exists */
94 #define CTLID_0001 0x0001 /* controller release 1 */
95
96 /* AIOP ID numbers, identifies AIOP type implementing channel */
97 #define AIOPID_NULL -1 /* no AIOP or channel exists */
98 #define AIOPID_0001 0x0001 /* AIOP release 1 */
99
100 /************************************************************************
101 Global Register Offsets - Direct Access - Fixed values
102 ************************************************************************/
103
104 #define _CMD_REG 0x38 /* Command Register 8 Write */
105 #define _INT_CHAN 0x39 /* Interrupt Channel Register 8 Read */
106 #define _INT_MASK 0x3A /* Interrupt Mask Register 8 Read / Write */
107 #define _UNUSED 0x3B /* Unused 8 */
108 #define _INDX_ADDR 0x3C /* Index Register Address 16 Write */
109 #define _INDX_DATA 0x3E /* Index Register Data 8/16 Read / Write */
110
111 /************************************************************************
112 Channel Register Offsets for 1st channel in AIOP - Direct Access
113 ************************************************************************/
114 #define _TD0 0x00 /* Transmit Data 16 Write */
115 #define _RD0 0x00 /* Receive Data 16 Read */
116 #define _CHN_STAT0 0x20 /* Channel Status 8/16 Read / Write */
117 #define _FIFO_CNT0 0x10 /* Transmit/Receive FIFO Count 16 Read */
118 #define _INT_ID0 0x30 /* Interrupt Identification 8 Read */
119
120 /************************************************************************
121 Tx Control Register Offsets - Indexed - External - Fixed
122 ************************************************************************/
123 #define _TX_ENBLS 0x980 /* Tx Processor Enables Register 8 Read / Write */
124 #define _TXCMP1 0x988 /* Transmit Compare Value #1 8 Read / Write */
125 #define _TXCMP2 0x989 /* Transmit Compare Value #2 8 Read / Write */
126 #define _TXREP1B1 0x98A /* Tx Replace Value #1 - Byte 1 8 Read / Write */
127 #define _TXREP1B2 0x98B /* Tx Replace Value #1 - Byte 2 8 Read / Write */
128 #define _TXREP2 0x98C /* Transmit Replace Value #2 8 Read / Write */
129
130 /************************************************************************
131 Memory Controller Register Offsets - Indexed - External - Fixed
132 ************************************************************************/
133 #define _RX_FIFO 0x000 /* Rx FIFO */
134 #define _TX_FIFO 0x800 /* Tx FIFO */
135 #define _RXF_OUTP 0x990 /* Rx FIFO OUT pointer 16 Read / Write */
136 #define _RXF_INP 0x992 /* Rx FIFO IN pointer 16 Read / Write */
137 #define _TXF_OUTP 0x994 /* Tx FIFO OUT pointer 8 Read / Write */
138 #define _TXF_INP 0x995 /* Tx FIFO IN pointer 8 Read / Write */
139 #define _TXP_CNT 0x996 /* Tx Priority Count 8 Read / Write */
140 #define _TXP_PNTR 0x997 /* Tx Priority Pointer 8 Read / Write */
141
142 #define PRI_PEND 0x80 /* Priority data pending (bit7, Tx pri cnt) */
143 #define TXFIFO_SIZE 255 /* size of Tx FIFO */
144 #define RXFIFO_SIZE 1023 /* size of Rx FIFO */
145
146 /************************************************************************
147 Tx Priority Buffer - Indexed - External - Fixed
148 ************************************************************************/
149 #define _TXP_BUF 0x9C0 /* Tx Priority Buffer 32 Bytes Read / Write */
150 #define TXP_SIZE 0x20 /* 32 bytes */
151
152 /************************************************************************
153 Channel Register Offsets - Indexed - Internal - Fixed
154 ************************************************************************/
155
156 #define _TX_CTRL 0xFF0 /* Transmit Control 16 Write */
157 #define _RX_CTRL 0xFF2 /* Receive Control 8 Write */
158 #define _BAUD 0xFF4 /* Baud Rate 16 Write */
159 #define _CLK_PRE 0xFF6 /* Clock Prescaler 8 Write */
160
161 #define STMBREAK 0x08 /* BREAK */
162 #define STMFRAME 0x04 /* framing error */
163 #define STMRCVROVR 0x02 /* receiver over run error */
164 #define STMPARITY 0x01 /* parity error */
165 #define STMERROR (STMBREAK | STMFRAME | STMPARITY)
166 #define STMBREAKH 0x800 /* BREAK */
167 #define STMFRAMEH 0x400 /* framing error */
168 #define STMRCVROVRH 0x200 /* receiver over run error */
169 #define STMPARITYH 0x100 /* parity error */
170 #define STMERRORH (STMBREAKH | STMFRAMEH | STMPARITYH)
171
172 #define CTS_ACT 0x20 /* CTS input asserted */
173 #define DSR_ACT 0x10 /* DSR input asserted */
174 #define CD_ACT 0x08 /* CD input asserted */
175 #define TXFIFOMT 0x04 /* Tx FIFO is empty */
176 #define TXSHRMT 0x02 /* Tx shift register is empty */
177 #define RDA 0x01 /* Rx data available */
178 #define DRAINED (TXFIFOMT | TXSHRMT) /* indicates Tx is drained */
179
180 #define STATMODE 0x8000 /* status mode enable bit */
181 #define RXFOVERFL 0x2000 /* receive FIFO overflow */
182 #define RX2MATCH 0x1000 /* receive compare byte 2 match */
183 #define RX1MATCH 0x0800 /* receive compare byte 1 match */
184 #define RXBREAK 0x0400 /* received BREAK */
185 #define RXFRAME 0x0200 /* received framing error */
186 #define RXPARITY 0x0100 /* received parity error */
187 #define STATERROR (RXBREAK | RXFRAME | RXPARITY)
188
189 #define CTSFC_EN 0x80 /* CTS flow control enable bit */
190 #define RTSTOG_EN 0x40 /* RTS toggle enable bit */
191 #define TXINT_EN 0x10 /* transmit interrupt enable */
192 #define STOP2 0x08 /* enable 2 stop bits (0 = 1 stop) */
193 #define PARITY_EN 0x04 /* enable parity (0 = no parity) */
194 #define EVEN_PAR 0x02 /* even parity (0 = odd parity) */
195 #define DATA8BIT 0x01 /* 8 bit data (0 = 7 bit data) */
196
197 #define SETBREAK 0x10 /* send break condition (must clear) */
198 #define LOCALLOOP 0x08 /* local loopback set for test */
199 #define SET_DTR 0x04 /* assert DTR */
200 #define SET_RTS 0x02 /* assert RTS */
201 #define TX_ENABLE 0x01 /* enable transmitter */
202
203 #define RTSFC_EN 0x40 /* RTS flow control enable */
204 #define RXPROC_EN 0x20 /* receive processor enable */
205 #define TRIG_NO 0x00 /* Rx FIFO trigger level 0 (no trigger) */
206 #define TRIG_1 0x08 /* trigger level 1 char */
207 #define TRIG_1_2 0x10 /* trigger level 1/2 */
208 #define TRIG_7_8 0x18 /* trigger level 7/8 */
209 #define TRIG_MASK 0x18 /* trigger level mask */
210 #define SRCINT_EN 0x04 /* special Rx condition interrupt enable */
211 #define RXINT_EN 0x02 /* Rx interrupt enable */
212 #define MCINT_EN 0x01 /* modem change interrupt enable */
213
214 #define RXF_TRIG 0x20 /* Rx FIFO trigger level interrupt */
215 #define TXFIFO_MT 0x10 /* Tx FIFO empty interrupt */
216 #define SRC_INT 0x08 /* special receive condition interrupt */
217 #define DELTA_CD 0x04 /* CD change interrupt */
218 #define DELTA_CTS 0x02 /* CTS change interrupt */
219 #define DELTA_DSR 0x01 /* DSR change interrupt */
220
221 #define REP1W2_EN 0x10 /* replace byte 1 with 2 bytes enable */
222 #define IGN2_EN 0x08 /* ignore byte 2 enable */
223 #define IGN1_EN 0x04 /* ignore byte 1 enable */
224 #define COMP2_EN 0x02 /* compare byte 2 enable */
225 #define COMP1_EN 0x01 /* compare byte 1 enable */
226
227 #define RESET_ALL 0x80 /* reset AIOP (all channels) */
228 #define TXOVERIDE 0x40 /* Transmit software off override */
229 #define RESETUART 0x20 /* reset channel's UART */
230 #define RESTXFCNT 0x10 /* reset channel's Tx FIFO count register */
231 #define RESRXFCNT 0x08 /* reset channel's Rx FIFO count register */
232
233 #define INTSTAT0 0x01 /* AIOP 0 interrupt status */
234 #define INTSTAT1 0x02 /* AIOP 1 interrupt status */
235 #define INTSTAT2 0x04 /* AIOP 2 interrupt status */
236 #define INTSTAT3 0x08 /* AIOP 3 interrupt status */
237
238 #define INTR_EN 0x08 /* allow interrupts to host */
239 #define INT_STROB 0x04 /* strobe and clear interrupt line (EOI) */
240
241 /**************************************************************************
242 MUDBAC remapped for PCI
243 **************************************************************************/
244
245 #define _CFG_INT_PCI 0x40
246 #define _PCI_INT_FUNC 0x3A
247
248 #define PCI_STROB 0x2000 /* bit 13 of int aiop register */
249 #define INTR_EN_PCI 0x0010 /* allow interrupts to host */
250
251 /*
252 * Definitions for Universal PCI board registers
253 */
254 #define _PCI_9030_INT_CTRL 0x4c /* Offsets from BAR1 */
255 #define _PCI_9030_GPIO_CTRL 0x54
256 #define PCI_INT_CTRL_AIOP 0x0001
257 #define PCI_GPIO_CTRL_8PORT 0x4000
258 #define _PCI_9030_RING_IND 0xc0 /* Offsets from BAR1 */
259
260 #define CHAN3_EN 0x08 /* enable AIOP 3 */
261 #define CHAN2_EN 0x04 /* enable AIOP 2 */
262 #define CHAN1_EN 0x02 /* enable AIOP 1 */
263 #define CHAN0_EN 0x01 /* enable AIOP 0 */
264 #define FREQ_DIS 0x00
265 #define FREQ_274HZ 0x60
266 #define FREQ_137HZ 0x50
267 #define FREQ_69HZ 0x40
268 #define FREQ_34HZ 0x30
269 #define FREQ_17HZ 0x20
270 #define FREQ_9HZ 0x10
271 #define PERIODIC_ONLY 0x80 /* only PERIODIC interrupt */
272
273 #define CHANINT_EN 0x0100 /* flags to enable/disable channel ints */
274
275 #define RDATASIZE 72
276 #define RREGDATASIZE 52
277
278 /*
279 * AIOP interrupt bits for ISA/PCI boards and UPCI boards.
280 */
281 #define AIOP_INTR_BIT_0 0x0001
282 #define AIOP_INTR_BIT_1 0x0002
283 #define AIOP_INTR_BIT_2 0x0004
284 #define AIOP_INTR_BIT_3 0x0008
285
286 #define AIOP_INTR_BITS ( \
287 AIOP_INTR_BIT_0 \
288 | AIOP_INTR_BIT_1 \
289 | AIOP_INTR_BIT_2 \
290 | AIOP_INTR_BIT_3)
291
292 #define UPCI_AIOP_INTR_BIT_0 0x0004
293 #define UPCI_AIOP_INTR_BIT_1 0x0020
294 #define UPCI_AIOP_INTR_BIT_2 0x0100
295 #define UPCI_AIOP_INTR_BIT_3 0x0800
296
297 #define UPCI_AIOP_INTR_BITS ( \
298 UPCI_AIOP_INTR_BIT_0 \
299 | UPCI_AIOP_INTR_BIT_1 \
300 | UPCI_AIOP_INTR_BIT_2 \
301 | UPCI_AIOP_INTR_BIT_3)
302
303 /* Controller level information structure */
304 typedef struct {
305 int CtlID;
306 int CtlNum;
307 int BusType;
308 int boardType;
309 int isUPCI;
310 WordIO_t PCIIO;
311 WordIO_t PCIIO2;
312 ByteIO_t MBaseIO;
313 ByteIO_t MReg1IO;
314 ByteIO_t MReg2IO;
315 ByteIO_t MReg3IO;
316 Byte_t MReg2;
317 Byte_t MReg3;
318 int NumAiop;
319 int AltChanRingIndicator;
320 ByteIO_t UPCIRingInd;
321 WordIO_t AiopIO[AIOP_CTL_SIZE];
322 ByteIO_t AiopIntChanIO[AIOP_CTL_SIZE];
323 int AiopID[AIOP_CTL_SIZE];
324 int AiopNumChan[AIOP_CTL_SIZE];
325 Word_t *AiopIntrBits;
326 } CONTROLLER_T;
327
328 typedef CONTROLLER_T CONTROLLER_t;
329
330 /* Channel level information structure */
331 typedef struct {
332 CONTROLLER_T *CtlP;
333 int AiopNum;
334 int ChanID;
335 int ChanNum;
336 int rtsToggle;
337
338 ByteIO_t Cmd;
339 ByteIO_t IntChan;
340 ByteIO_t IntMask;
341 DWordIO_t IndexAddr;
342 WordIO_t IndexData;
343
344 WordIO_t TxRxData;
345 WordIO_t ChanStat;
346 WordIO_t TxRxCount;
347 ByteIO_t IntID;
348
349 Word_t TxFIFO;
350 Word_t TxFIFOPtrs;
351 Word_t RxFIFO;
352 Word_t RxFIFOPtrs;
353 Word_t TxPrioCnt;
354 Word_t TxPrioPtr;
355 Word_t TxPrioBuf;
356
357 Byte_t R[RREGDATASIZE];
358
359 Byte_t BaudDiv[4];
360 Byte_t TxControl[4];
361 Byte_t RxControl[4];
362 Byte_t TxEnables[4];
363 Byte_t TxCompare[4];
364 Byte_t TxReplace1[4];
365 Byte_t TxReplace2[4];
366 } CHANNEL_T;
367
368 typedef CHANNEL_T CHANNEL_t;
369 typedef CHANNEL_T *CHANPTR_T;
370
371 #define InterfaceModeRS232 0x00
372 #define InterfaceModeRS422 0x08
373 #define InterfaceModeRS485 0x10
374 #define InterfaceModeRS232T 0x18
375
376 /***************************************************************************
377 Function: sClrBreak
378 Purpose: Stop sending a transmit BREAK signal
379 Call: sClrBreak(ChP)
380 CHANNEL_T *ChP; Ptr to channel structure
381 */
382 #define sClrBreak(ChP) \
383 do { \
384 (ChP)->TxControl[3] &= ~SETBREAK; \
385 out32((ChP)->IndexAddr,(ChP)->TxControl); \
386 } while (0)
387
388 /***************************************************************************
389 Function: sClrDTR
390 Purpose: Clr the DTR output
391 Call: sClrDTR(ChP)
392 CHANNEL_T *ChP; Ptr to channel structure
393 */
394 #define sClrDTR(ChP) \
395 do { \
396 (ChP)->TxControl[3] &= ~SET_DTR; \
397 out32((ChP)->IndexAddr,(ChP)->TxControl); \
398 } while (0)
399
400 /***************************************************************************
401 Function: sClrRTS
402 Purpose: Clr the RTS output
403 Call: sClrRTS(ChP)
404 CHANNEL_T *ChP; Ptr to channel structure
405 */
406 #define sClrRTS(ChP) \
407 do { \
408 if ((ChP)->rtsToggle) break; \
409 (ChP)->TxControl[3] &= ~SET_RTS; \
410 out32((ChP)->IndexAddr,(ChP)->TxControl); \
411 } while (0)
412
413 /***************************************************************************
414 Function: sClrTxXOFF
415 Purpose: Clear any existing transmit software flow control off condition
416 Call: sClrTxXOFF(ChP)
417 CHANNEL_T *ChP; Ptr to channel structure
418 */
419 #define sClrTxXOFF(ChP) \
420 do { \
421 sOutB((ChP)->Cmd,TXOVERIDE | (Byte_t)(ChP)->ChanNum); \
422 sOutB((ChP)->Cmd,(Byte_t)(ChP)->ChanNum); \
423 } while (0)
424
425 /***************************************************************************
426 Function: sCtlNumToCtlPtr
427 Purpose: Convert a controller number to controller structure pointer
428 Call: sCtlNumToCtlPtr(CtlNum)
429 int CtlNum; Controller number
430 Return: CONTROLLER_T *: Ptr to controller structure
431 */
432 #define sCtlNumToCtlPtr(CTLNUM) &sController[CTLNUM]
433
434 /***************************************************************************
435 Function: sControllerEOI
436 Purpose: Strobe the MUDBAC's End Of Interrupt bit.
437 Call: sControllerEOI(CtlP)
438 CONTROLLER_T *CtlP; Ptr to controller structure
439 */
440 #define sControllerEOI(CTLP) sOutB((CTLP)->MReg2IO,(CTLP)->MReg2 | INT_STROB)
441
442 /***************************************************************************
443 Function: sPCIControllerEOI
444 Purpose: Strobe the PCI End Of Interrupt bit.
445 For the UPCI boards, toggle the AIOP interrupt enable bit
446 (this was taken from the Windows driver).
447 Call: sPCIControllerEOI(CtlP)
448 CONTROLLER_T *CtlP; Ptr to controller structure
449 */
450 #define sPCIControllerEOI(CTLP) \
451 do { \
452 if ((CTLP)->isUPCI) { \
453 Word_t w = sInW((CTLP)->PCIIO); \
454 sOutW((CTLP)->PCIIO, (w ^ PCI_INT_CTRL_AIOP)); \
455 sOutW((CTLP)->PCIIO, w); \
456 } \
457 else { \
458 sOutW((CTLP)->PCIIO, PCI_STROB); \
459 } \
460 } while (0)
461
462 /***************************************************************************
463 Function: sDisAiop
464 Purpose: Disable I/O access to an AIOP
465 Call: sDisAiop(CltP)
466 CONTROLLER_T *CtlP; Ptr to controller structure
467 int AiopNum; Number of AIOP on controller
468 */
469 #define sDisAiop(CTLP,AIOPNUM) \
470 do { \
471 (CTLP)->MReg3 &= sBitMapClrTbl[AIOPNUM]; \
472 sOutB((CTLP)->MReg3IO,(CTLP)->MReg3); \
473 } while (0)
474
475 /***************************************************************************
476 Function: sDisCTSFlowCtl
477 Purpose: Disable output flow control using CTS
478 Call: sDisCTSFlowCtl(ChP)
479 CHANNEL_T *ChP; Ptr to channel structure
480 */
481 #define sDisCTSFlowCtl(ChP) \
482 do { \
483 (ChP)->TxControl[2] &= ~CTSFC_EN; \
484 out32((ChP)->IndexAddr,(ChP)->TxControl); \
485 } while (0)
486
487 /***************************************************************************
488 Function: sDisIXANY
489 Purpose: Disable IXANY Software Flow Control
490 Call: sDisIXANY(ChP)
491 CHANNEL_T *ChP; Ptr to channel structure
492 */
493 #define sDisIXANY(ChP) \
494 do { \
495 (ChP)->R[0x0e] = 0x86; \
496 out32((ChP)->IndexAddr,&(ChP)->R[0x0c]); \
497 } while (0)
498
499 /***************************************************************************
500 Function: DisParity
501 Purpose: Disable parity
502 Call: sDisParity(ChP)
503 CHANNEL_T *ChP; Ptr to channel structure
504 Comments: Function sSetParity() can be used in place of functions sEnParity(),
505 sDisParity(), sSetOddParity(), and sSetEvenParity().
506 */
507 #define sDisParity(ChP) \
508 do { \
509 (ChP)->TxControl[2] &= ~PARITY_EN; \
510 out32((ChP)->IndexAddr,(ChP)->TxControl); \
511 } while (0)
512
513 /***************************************************************************
514 Function: sDisRTSToggle
515 Purpose: Disable RTS toggle
516 Call: sDisRTSToggle(ChP)
517 CHANNEL_T *ChP; Ptr to channel structure
518 */
519 #define sDisRTSToggle(ChP) \
520 do { \
521 (ChP)->TxControl[2] &= ~RTSTOG_EN; \
522 out32((ChP)->IndexAddr,(ChP)->TxControl); \
523 (ChP)->rtsToggle = 0; \
524 } while (0)
525
526 /***************************************************************************
527 Function: sDisRxFIFO
528 Purpose: Disable Rx FIFO
529 Call: sDisRxFIFO(ChP)
530 CHANNEL_T *ChP; Ptr to channel structure
531 */
532 #define sDisRxFIFO(ChP) \
533 do { \
534 (ChP)->R[0x32] = 0x0a; \
535 out32((ChP)->IndexAddr,&(ChP)->R[0x30]); \
536 } while (0)
537
538 /***************************************************************************
539 Function: sDisRxStatusMode
540 Purpose: Disable the Rx status mode
541 Call: sDisRxStatusMode(ChP)
542 CHANNEL_T *ChP; Ptr to channel structure
543 Comments: This takes the channel out of the receive status mode. All
544 subsequent reads of receive data using sReadRxWord() will return
545 two data bytes.
546 */
547 #define sDisRxStatusMode(ChP) sOutW((ChP)->ChanStat,0)
548
549 /***************************************************************************
550 Function: sDisTransmit
551 Purpose: Disable transmit
552 Call: sDisTransmit(ChP)
553 CHANNEL_T *ChP; Ptr to channel structure
554 This disables movement of Tx data from the Tx FIFO into the 1 byte
555 Tx buffer. Therefore there could be up to a 2 byte latency
556 between the time sDisTransmit() is called and the transmit buffer
557 and transmit shift register going completely empty.
558 */
559 #define sDisTransmit(ChP) \
560 do { \
561 (ChP)->TxControl[3] &= ~TX_ENABLE; \
562 out32((ChP)->IndexAddr,(ChP)->TxControl); \
563 } while (0)
564
565 /***************************************************************************
566 Function: sDisTxSoftFlowCtl
567 Purpose: Disable Tx Software Flow Control
568 Call: sDisTxSoftFlowCtl(ChP)
569 CHANNEL_T *ChP; Ptr to channel structure
570 */
571 #define sDisTxSoftFlowCtl(ChP) \
572 do { \
573 (ChP)->R[0x06] = 0x8a; \
574 out32((ChP)->IndexAddr,&(ChP)->R[0x04]); \
575 } while (0)
576
577 /***************************************************************************
578 Function: sEnAiop
579 Purpose: Enable I/O access to an AIOP
580 Call: sEnAiop(CltP)
581 CONTROLLER_T *CtlP; Ptr to controller structure
582 int AiopNum; Number of AIOP on controller
583 */
584 #define sEnAiop(CTLP,AIOPNUM) \
585 do { \
586 (CTLP)->MReg3 |= sBitMapSetTbl[AIOPNUM]; \
587 sOutB((CTLP)->MReg3IO,(CTLP)->MReg3); \
588 } while (0)
589
590 /***************************************************************************
591 Function: sEnCTSFlowCtl
592 Purpose: Enable output flow control using CTS
593 Call: sEnCTSFlowCtl(ChP)
594 CHANNEL_T *ChP; Ptr to channel structure
595 */
596 #define sEnCTSFlowCtl(ChP) \
597 do { \
598 (ChP)->TxControl[2] |= CTSFC_EN; \
599 out32((ChP)->IndexAddr,(ChP)->TxControl); \
600 } while (0)
601
602 /***************************************************************************
603 Function: sEnIXANY
604 Purpose: Enable IXANY Software Flow Control
605 Call: sEnIXANY(ChP)
606 CHANNEL_T *ChP; Ptr to channel structure
607 */
608 #define sEnIXANY(ChP) \
609 do { \
610 (ChP)->R[0x0e] = 0x21; \
611 out32((ChP)->IndexAddr,&(ChP)->R[0x0c]); \
612 } while (0)
613
614 /***************************************************************************
615 Function: EnParity
616 Purpose: Enable parity
617 Call: sEnParity(ChP)
618 CHANNEL_T *ChP; Ptr to channel structure
619 Comments: Function sSetParity() can be used in place of functions sEnParity(),
620 sDisParity(), sSetOddParity(), and sSetEvenParity().
621
622 Warnings: Before enabling parity odd or even parity should be chosen using
623 functions sSetOddParity() or sSetEvenParity().
624 */
625 #define sEnParity(ChP) \
626 do { \
627 (ChP)->TxControl[2] |= PARITY_EN; \
628 out32((ChP)->IndexAddr,(ChP)->TxControl); \
629 } while (0)
630
631 /***************************************************************************
632 Function: sEnRTSToggle
633 Purpose: Enable RTS toggle
634 Call: sEnRTSToggle(ChP)
635 CHANNEL_T *ChP; Ptr to channel structure
636 Comments: This function will disable RTS flow control and clear the RTS
637 line to allow operation of RTS toggle.
638 */
639 #define sEnRTSToggle(ChP) \
640 do { \
641 (ChP)->RxControl[2] &= ~RTSFC_EN; \
642 out32((ChP)->IndexAddr,(ChP)->RxControl); \
643 (ChP)->TxControl[2] |= RTSTOG_EN; \
644 (ChP)->TxControl[3] &= ~SET_RTS; \
645 out32((ChP)->IndexAddr,(ChP)->TxControl); \
646 (ChP)->rtsToggle = 1; \
647 } while (0)
648
649 /***************************************************************************
650 Function: sEnRxFIFO
651 Purpose: Enable Rx FIFO
652 Call: sEnRxFIFO(ChP)
653 CHANNEL_T *ChP; Ptr to channel structure
654 */
655 #define sEnRxFIFO(ChP) \
656 do { \
657 (ChP)->R[0x32] = 0x08; \
658 out32((ChP)->IndexAddr,&(ChP)->R[0x30]); \
659 } while (0)
660
661 /***************************************************************************
662 Function: sEnRxProcessor
663 Purpose: Enable the receive processor
664 Call: sEnRxProcessor(ChP)
665 CHANNEL_T *ChP; Ptr to channel structure
666 Comments: This function is used to start the receive processor. When
667 the channel is in the reset state the receive processor is not
668 running. This is done to prevent the receive processor from
669 executing invalid microcode instructions prior to the
670 downloading of the microcode.
671
672 Warnings: This function must be called after valid microcode has been
673 downloaded to the AIOP, and it must not be called before the
674 microcode has been downloaded.
675 */
676 #define sEnRxProcessor(ChP) \
677 do { \
678 (ChP)->RxControl[2] |= RXPROC_EN; \
679 out32((ChP)->IndexAddr,(ChP)->RxControl); \
680 } while (0)
681
682 /***************************************************************************
683 Function: sEnRxStatusMode
684 Purpose: Enable the Rx status mode
685 Call: sEnRxStatusMode(ChP)
686 CHANNEL_T *ChP; Ptr to channel structure
687 Comments: This places the channel in the receive status mode. All subsequent
688 reads of receive data using sReadRxWord() will return a data byte
689 in the low word and a status byte in the high word.
690
691 */
692 #define sEnRxStatusMode(ChP) sOutW((ChP)->ChanStat,STATMODE)
693
694 /***************************************************************************
695 Function: sEnTransmit
696 Purpose: Enable transmit
697 Call: sEnTransmit(ChP)
698 CHANNEL_T *ChP; Ptr to channel structure
699 */
700 #define sEnTransmit(ChP) \
701 do { \
702 (ChP)->TxControl[3] |= TX_ENABLE; \
703 out32((ChP)->IndexAddr,(ChP)->TxControl); \
704 } while (0)
705
706 /***************************************************************************
707 Function: sEnTxSoftFlowCtl
708 Purpose: Enable Tx Software Flow Control
709 Call: sEnTxSoftFlowCtl(ChP)
710 CHANNEL_T *ChP; Ptr to channel structure
711 */
712 #define sEnTxSoftFlowCtl(ChP) \
713 do { \
714 (ChP)->R[0x06] = 0xc5; \
715 out32((ChP)->IndexAddr,&(ChP)->R[0x04]); \
716 } while (0)
717
718 /***************************************************************************
719 Function: sGetAiopIntStatus
720 Purpose: Get the AIOP interrupt status
721 Call: sGetAiopIntStatus(CtlP,AiopNum)
722 CONTROLLER_T *CtlP; Ptr to controller structure
723 int AiopNum; AIOP number
724 Return: Byte_t: The AIOP interrupt status. Bits 0 through 7
725 represent channels 0 through 7 respectively. If a
726 bit is set that channel is interrupting.
727 */
728 #define sGetAiopIntStatus(CTLP,AIOPNUM) sInB((CTLP)->AiopIntChanIO[AIOPNUM])
729
730 /***************************************************************************
731 Function: sGetAiopNumChan
732 Purpose: Get the number of channels supported by an AIOP
733 Call: sGetAiopNumChan(CtlP,AiopNum)
734 CONTROLLER_T *CtlP; Ptr to controller structure
735 int AiopNum; AIOP number
736 Return: int: The number of channels supported by the AIOP
737 */
738 #define sGetAiopNumChan(CTLP,AIOPNUM) (CTLP)->AiopNumChan[AIOPNUM]
739
740 /***************************************************************************
741 Function: sGetChanIntID
742 Purpose: Get a channel's interrupt identification byte
743 Call: sGetChanIntID(ChP)
744 CHANNEL_T *ChP; Ptr to channel structure
745 Return: Byte_t: The channel interrupt ID. Can be any
746 combination of the following flags:
747 RXF_TRIG: Rx FIFO trigger level interrupt
748 TXFIFO_MT: Tx FIFO empty interrupt
749 SRC_INT: Special receive condition interrupt
750 DELTA_CD: CD change interrupt
751 DELTA_CTS: CTS change interrupt
752 DELTA_DSR: DSR change interrupt
753 */
754 #define sGetChanIntID(ChP) (sInB((ChP)->IntID) & (RXF_TRIG | TXFIFO_MT | SRC_INT | DELTA_CD | DELTA_CTS | DELTA_DSR))
755
756 /***************************************************************************
757 Function: sGetChanNum
758 Purpose: Get the number of a channel within an AIOP
759 Call: sGetChanNum(ChP)
760 CHANNEL_T *ChP; Ptr to channel structure
761 Return: int: Channel number within AIOP, or NULLCHAN if channel does
762 not exist.
763 */
764 #define sGetChanNum(ChP) (ChP)->ChanNum
765
766 /***************************************************************************
767 Function: sGetChanStatus
768 Purpose: Get the channel status
769 Call: sGetChanStatus(ChP)
770 CHANNEL_T *ChP; Ptr to channel structure
771 Return: Word_t: The channel status. Can be any combination of
772 the following flags:
773 LOW BYTE FLAGS
774 CTS_ACT: CTS input asserted
775 DSR_ACT: DSR input asserted
776 CD_ACT: CD input asserted
777 TXFIFOMT: Tx FIFO is empty
778 TXSHRMT: Tx shift register is empty
779 RDA: Rx data available
780
781 HIGH BYTE FLAGS
782 STATMODE: status mode enable bit
783 RXFOVERFL: receive FIFO overflow
784 RX2MATCH: receive compare byte 2 match
785 RX1MATCH: receive compare byte 1 match
786 RXBREAK: received BREAK
787 RXFRAME: received framing error
788 RXPARITY: received parity error
789 Warnings: This function will clear the high byte flags in the Channel
790 Status Register.
791 */
792 #define sGetChanStatus(ChP) sInW((ChP)->ChanStat)
793
794 /***************************************************************************
795 Function: sGetChanStatusLo
796 Purpose: Get the low byte only of the channel status
797 Call: sGetChanStatusLo(ChP)
798 CHANNEL_T *ChP; Ptr to channel structure
799 Return: Byte_t: The channel status low byte. Can be any combination
800 of the following flags:
801 CTS_ACT: CTS input asserted
802 DSR_ACT: DSR input asserted
803 CD_ACT: CD input asserted
804 TXFIFOMT: Tx FIFO is empty
805 TXSHRMT: Tx shift register is empty
806 RDA: Rx data available
807 */
808 #define sGetChanStatusLo(ChP) sInB((ByteIO_t)(ChP)->ChanStat)
809
810 /**********************************************************************
811 * Get RI status of channel
812 * Defined as a function in rocket.c -aes
813 */
814 #if 0
815 #define sGetChanRI(ChP) ((ChP)->CtlP->AltChanRingIndicator ? \
816 (sInB((ByteIO_t)((ChP)->ChanStat+8)) & DSR_ACT) : \
817 (((ChP)->CtlP->boardType == ROCKET_TYPE_PC104) ? \
818 (!(sInB((ChP)->CtlP->AiopIO[3]) & sBitMapSetTbl[(ChP)->ChanNum])) : \
819 0))
820 #endif
821
822 /***************************************************************************
823 Function: sGetControllerIntStatus
824 Purpose: Get the controller interrupt status
825 Call: sGetControllerIntStatus(CtlP)
826 CONTROLLER_T *CtlP; Ptr to controller structure
827 Return: Byte_t: The controller interrupt status in the lower 4
828 bits. Bits 0 through 3 represent AIOP's 0
829 through 3 respectively. If a bit is set that
830 AIOP is interrupting. Bits 4 through 7 will
831 always be cleared.
832 */
833 #define sGetControllerIntStatus(CTLP) (sInB((CTLP)->MReg1IO) & 0x0f)
834
835 /***************************************************************************
836 Function: sPCIGetControllerIntStatus
837 Purpose: Get the controller interrupt status
838 Call: sPCIGetControllerIntStatus(CtlP)
839 CONTROLLER_T *CtlP; Ptr to controller structure
840 Return: unsigned char: The controller interrupt status in the lower 4
841 bits and bit 4. Bits 0 through 3 represent AIOP's 0
842 through 3 respectively. Bit 4 is set if the int
843 was generated from periodic. If a bit is set the
844 AIOP is interrupting.
845 */
846 #define sPCIGetControllerIntStatus(CTLP) \
847 ((CTLP)->isUPCI ? \
848 (sInW((CTLP)->PCIIO2) & UPCI_AIOP_INTR_BITS) : \
849 ((sInW((CTLP)->PCIIO) >> 8) & AIOP_INTR_BITS))
850
851 /***************************************************************************
852
853 Function: sGetRxCnt
854 Purpose: Get the number of data bytes in the Rx FIFO
855 Call: sGetRxCnt(ChP)
856 CHANNEL_T *ChP; Ptr to channel structure
857 Return: int: The number of data bytes in the Rx FIFO.
858 Comments: Byte read of count register is required to obtain Rx count.
859
860 */
861 #define sGetRxCnt(ChP) sInW((ChP)->TxRxCount)
862
863 /***************************************************************************
864 Function: sGetTxCnt
865 Purpose: Get the number of data bytes in the Tx FIFO
866 Call: sGetTxCnt(ChP)
867 CHANNEL_T *ChP; Ptr to channel structure
868 Return: Byte_t: The number of data bytes in the Tx FIFO.
869 Comments: Byte read of count register is required to obtain Tx count.
870
871 */
872 #define sGetTxCnt(ChP) sInB((ByteIO_t)(ChP)->TxRxCount)
873
874 /*****************************************************************************
875 Function: sGetTxRxDataIO
876 Purpose: Get the I/O address of a channel's TxRx Data register
877 Call: sGetTxRxDataIO(ChP)
878 CHANNEL_T *ChP; Ptr to channel structure
879 Return: WordIO_t: I/O address of a channel's TxRx Data register
880 */
881 #define sGetTxRxDataIO(ChP) (ChP)->TxRxData
882
883 /***************************************************************************
884 Function: sInitChanDefaults
885 Purpose: Initialize a channel structure to it's default state.
886 Call: sInitChanDefaults(ChP)
887 CHANNEL_T *ChP; Ptr to the channel structure
888 Comments: This function must be called once for every channel structure
889 that exists before any other SSCI calls can be made.
890
891 */
892 #define sInitChanDefaults(ChP) \
893 do { \
894 (ChP)->CtlP = NULLCTLPTR; \
895 (ChP)->AiopNum = NULLAIOP; \
896 (ChP)->ChanID = AIOPID_NULL; \
897 (ChP)->ChanNum = NULLCHAN; \
898 } while (0)
899
900 /***************************************************************************
901 Function: sResetAiopByNum
902 Purpose: Reset the AIOP by number
903 Call: sResetAiopByNum(CTLP,AIOPNUM)
904 CONTROLLER_T CTLP; Ptr to controller structure
905 AIOPNUM; AIOP index
906 */
907 #define sResetAiopByNum(CTLP,AIOPNUM) \
908 do { \
909 sOutB((CTLP)->AiopIO[(AIOPNUM)]+_CMD_REG,RESET_ALL); \
910 sOutB((CTLP)->AiopIO[(AIOPNUM)]+_CMD_REG,0x0); \
911 } while (0)
912
913 /***************************************************************************
914 Function: sSendBreak
915 Purpose: Send a transmit BREAK signal
916 Call: sSendBreak(ChP)
917 CHANNEL_T *ChP; Ptr to channel structure
918 */
919 #define sSendBreak(ChP) \
920 do { \
921 (ChP)->TxControl[3] |= SETBREAK; \
922 out32((ChP)->IndexAddr,(ChP)->TxControl); \
923 } while (0)
924
925 /***************************************************************************
926 Function: sSetBaud
927 Purpose: Set baud rate
928 Call: sSetBaud(ChP,Divisor)
929 CHANNEL_T *ChP; Ptr to channel structure
930 Word_t Divisor; 16 bit baud rate divisor for channel
931 */
932 #define sSetBaud(ChP,DIVISOR) \
933 do { \
934 (ChP)->BaudDiv[2] = (Byte_t)(DIVISOR); \
935 (ChP)->BaudDiv[3] = (Byte_t)((DIVISOR) >> 8); \
936 out32((ChP)->IndexAddr,(ChP)->BaudDiv); \
937 } while (0)
938
939 /***************************************************************************
940 Function: sSetData7
941 Purpose: Set data bits to 7
942 Call: sSetData7(ChP)
943 CHANNEL_T *ChP; Ptr to channel structure
944 */
945 #define sSetData7(ChP) \
946 do { \
947 (ChP)->TxControl[2] &= ~DATA8BIT; \
948 out32((ChP)->IndexAddr,(ChP)->TxControl); \
949 } while (0)
950
951 /***************************************************************************
952 Function: sSetData8
953 Purpose: Set data bits to 8
954 Call: sSetData8(ChP)
955 CHANNEL_T *ChP; Ptr to channel structure
956 */
957 #define sSetData8(ChP) \
958 do { \
959 (ChP)->TxControl[2] |= DATA8BIT; \
960 out32((ChP)->IndexAddr,(ChP)->TxControl); \
961 } while (0)
962
963 /***************************************************************************
964 Function: sSetDTR
965 Purpose: Set the DTR output
966 Call: sSetDTR(ChP)
967 CHANNEL_T *ChP; Ptr to channel structure
968 */
969 #define sSetDTR(ChP) \
970 do { \
971 (ChP)->TxControl[3] |= SET_DTR; \
972 out32((ChP)->IndexAddr,(ChP)->TxControl); \
973 } while (0)
974
975 /***************************************************************************
976 Function: sSetEvenParity
977 Purpose: Set even parity
978 Call: sSetEvenParity(ChP)
979 CHANNEL_T *ChP; Ptr to channel structure
980 Comments: Function sSetParity() can be used in place of functions sEnParity(),
981 sDisParity(), sSetOddParity(), and sSetEvenParity().
982
983 Warnings: This function has no effect unless parity is enabled with function
984 sEnParity().
985 */
986 #define sSetEvenParity(ChP) \
987 do { \
988 (ChP)->TxControl[2] |= EVEN_PAR; \
989 out32((ChP)->IndexAddr,(ChP)->TxControl); \
990 } while (0)
991
992 /***************************************************************************
993 Function: sSetOddParity
994 Purpose: Set odd parity
995 Call: sSetOddParity(ChP)
996 CHANNEL_T *ChP; Ptr to channel structure
997 Comments: Function sSetParity() can be used in place of functions sEnParity(),
998 sDisParity(), sSetOddParity(), and sSetEvenParity().
999
1000 Warnings: This function has no effect unless parity is enabled with function
1001 sEnParity().
1002 */
1003 #define sSetOddParity(ChP) \
1004 do { \
1005 (ChP)->TxControl[2] &= ~EVEN_PAR; \
1006 out32((ChP)->IndexAddr,(ChP)->TxControl); \
1007 } while (0)
1008
1009 /***************************************************************************
1010 Function: sSetRTS
1011 Purpose: Set the RTS output
1012 Call: sSetRTS(ChP)
1013 CHANNEL_T *ChP; Ptr to channel structure
1014 */
1015 #define sSetRTS(ChP) \
1016 do { \
1017 if ((ChP)->rtsToggle) break; \
1018 (ChP)->TxControl[3] |= SET_RTS; \
1019 out32((ChP)->IndexAddr,(ChP)->TxControl); \
1020 } while (0)
1021
1022 /***************************************************************************
1023 Function: sSetRxTrigger
1024 Purpose: Set the Rx FIFO trigger level
1025 Call: sSetRxProcessor(ChP,Level)
1026 CHANNEL_T *ChP; Ptr to channel structure
1027 Byte_t Level; Number of characters in Rx FIFO at which the
1028 interrupt will be generated. Can be any of the following flags:
1029
1030 TRIG_NO: no trigger
1031 TRIG_1: 1 character in FIFO
1032 TRIG_1_2: FIFO 1/2 full
1033 TRIG_7_8: FIFO 7/8 full
1034 Comments: An interrupt will be generated when the trigger level is reached
1035 only if function sEnInterrupt() has been called with flag
1036 RXINT_EN set. The RXF_TRIG flag in the Interrupt Idenfification
1037 register will be set whenever the trigger level is reached
1038 regardless of the setting of RXINT_EN.
1039
1040 */
1041 #define sSetRxTrigger(ChP,LEVEL) \
1042 do { \
1043 (ChP)->RxControl[2] &= ~TRIG_MASK; \
1044 (ChP)->RxControl[2] |= LEVEL; \
1045 out32((ChP)->IndexAddr,(ChP)->RxControl); \
1046 } while (0)
1047
1048 /***************************************************************************
1049 Function: sSetStop1
1050 Purpose: Set stop bits to 1
1051 Call: sSetStop1(ChP)
1052 CHANNEL_T *ChP; Ptr to channel structure
1053 */
1054 #define sSetStop1(ChP) \
1055 do { \
1056 (ChP)->TxControl[2] &= ~STOP2; \
1057 out32((ChP)->IndexAddr,(ChP)->TxControl); \
1058 } while (0)
1059
1060 /***************************************************************************
1061 Function: sSetStop2
1062 Purpose: Set stop bits to 2
1063 Call: sSetStop2(ChP)
1064 CHANNEL_T *ChP; Ptr to channel structure
1065 */
1066 #define sSetStop2(ChP) \
1067 do { \
1068 (ChP)->TxControl[2] |= STOP2; \
1069 out32((ChP)->IndexAddr,(ChP)->TxControl); \
1070 } while (0)
1071
1072 /***************************************************************************
1073 Function: sSetTxXOFFChar
1074 Purpose: Set the Tx XOFF flow control character
1075 Call: sSetTxXOFFChar(ChP,Ch)
1076 CHANNEL_T *ChP; Ptr to channel structure
1077 Byte_t Ch; The value to set the Tx XOFF character to
1078 */
1079 #define sSetTxXOFFChar(ChP,CH) \
1080 do { \
1081 (ChP)->R[0x07] = (CH); \
1082 out32((ChP)->IndexAddr,&(ChP)->R[0x04]); \
1083 } while (0)
1084
1085 /***************************************************************************
1086 Function: sSetTxXONChar
1087 Purpose: Set the Tx XON flow control character
1088 Call: sSetTxXONChar(ChP,Ch)
1089 CHANNEL_T *ChP; Ptr to channel structure
1090 Byte_t Ch; The value to set the Tx XON character to
1091 */
1092 #define sSetTxXONChar(ChP,CH) \
1093 do { \
1094 (ChP)->R[0x0b] = (CH); \
1095 out32((ChP)->IndexAddr,&(ChP)->R[0x08]); \
1096 } while (0)
1097
1098 /***************************************************************************
1099 Function: sStartRxProcessor
1100 Purpose: Start a channel's receive processor
1101 Call: sStartRxProcessor(ChP)
1102 CHANNEL_T *ChP; Ptr to channel structure
1103 Comments: This function is used to start a Rx processor after it was
1104 stopped with sStopRxProcessor() or sStopSWInFlowCtl(). It
1105 will restart both the Rx processor and software input flow control.
1106
1107 */
1108 #define sStartRxProcessor(ChP) out32((ChP)->IndexAddr,&(ChP)->R[0])
1109
1110 /***************************************************************************
1111 Function: sWriteTxByte
1112 Purpose: Write a transmit data byte to a channel.
1113 ByteIO_t io: Channel transmit register I/O address. This can
1114 be obtained with sGetTxRxDataIO().
1115 Byte_t Data; The transmit data byte.
1116 Warnings: This function writes the data byte without checking to see if
1117 sMaxTxSize is exceeded in the Tx FIFO.
1118 */
1119 #define sWriteTxByte(IO,DATA) sOutB(IO,DATA)
1120
1121 /*
1122 * Begin Linux specific definitions for the Rocketport driver
1123 *
1124 * This code is Copyright Theodore Ts'o, 1995-1997
1125 */
1126
1127 struct r_port {
1128 int magic;
1129 struct tty_port port;
1130 int line;
1131 int flags; /* Don't yet match the ASY_ flags!! */
1132 unsigned int board:3;
1133 unsigned int aiop:2;
1134 unsigned int chan:3;
1135 CONTROLLER_t *ctlp;
1136 CHANNEL_t channel;
1137 int intmask;
1138 int xmit_fifo_room; /* room in xmit fifo */
1139 unsigned char *xmit_buf;
1140 int xmit_head;
1141 int xmit_tail;
1142 int xmit_cnt;
1143 int cd_status;
1144 int ignore_status_mask;
1145 int read_status_mask;
1146 int cps;
1147
1148 spinlock_t slock;
1149 struct mutex write_mtx;
1150 };
1151
1152 #define RPORT_MAGIC 0x525001
1153
1154 #define NUM_BOARDS 8
1155 #define MAX_RP_PORTS (32*NUM_BOARDS)
1156
1157 /*
1158 * The size of the xmit buffer is 1 page, or 4096 bytes
1159 */
1160 #define XMIT_BUF_SIZE 4096
1161
1162 /* number of characters left in xmit buffer before we ask for more */
1163 #define WAKEUP_CHARS 256
1164
1165 /*
1166 * Assigned major numbers for the Comtrol Rocketport
1167 */
1168 #define TTY_ROCKET_MAJOR 46
1169 #define CUA_ROCKET_MAJOR 47
1170
1171 #ifdef PCI_VENDOR_ID_RP
1172 #undef PCI_VENDOR_ID_RP
1173 #undef PCI_DEVICE_ID_RP8OCTA
1174 #undef PCI_DEVICE_ID_RP8INTF
1175 #undef PCI_DEVICE_ID_RP16INTF
1176 #undef PCI_DEVICE_ID_RP32INTF
1177 #undef PCI_DEVICE_ID_URP8OCTA
1178 #undef PCI_DEVICE_ID_URP8INTF
1179 #undef PCI_DEVICE_ID_URP16INTF
1180 #undef PCI_DEVICE_ID_CRP16INTF
1181 #undef PCI_DEVICE_ID_URP32INTF
1182 #endif
1183
1184 /* Comtrol PCI Vendor ID */
1185 #define PCI_VENDOR_ID_RP 0x11fe
1186
1187 /* Comtrol Device ID's */
1188 #define PCI_DEVICE_ID_RP32INTF 0x0001 /* Rocketport 32 port w/external I/F */
1189 #define PCI_DEVICE_ID_RP8INTF 0x0002 /* Rocketport 8 port w/external I/F */
1190 #define PCI_DEVICE_ID_RP16INTF 0x0003 /* Rocketport 16 port w/external I/F */
1191 #define PCI_DEVICE_ID_RP4QUAD 0x0004 /* Rocketport 4 port w/quad cable */
1192 #define PCI_DEVICE_ID_RP8OCTA 0x0005 /* Rocketport 8 port w/octa cable */
1193 #define PCI_DEVICE_ID_RP8J 0x0006 /* Rocketport 8 port w/RJ11 connectors */
1194 #define PCI_DEVICE_ID_RP4J 0x0007 /* Rocketport 4 port w/RJ11 connectors */
1195 #define PCI_DEVICE_ID_RP8SNI 0x0008 /* Rocketport 8 port w/ DB78 SNI (Siemens) connector */
1196 #define PCI_DEVICE_ID_RP16SNI 0x0009 /* Rocketport 16 port w/ DB78 SNI (Siemens) connector */
1197 #define PCI_DEVICE_ID_RPP4 0x000A /* Rocketport Plus 4 port */
1198 #define PCI_DEVICE_ID_RPP8 0x000B /* Rocketport Plus 8 port */
1199 #define PCI_DEVICE_ID_RP6M 0x000C /* RocketModem 6 port */
1200 #define PCI_DEVICE_ID_RP4M 0x000D /* RocketModem 4 port */
1201 #define PCI_DEVICE_ID_RP2_232 0x000E /* Rocketport Plus 2 port RS232 */
1202 #define PCI_DEVICE_ID_RP2_422 0x000F /* Rocketport Plus 2 port RS422 */
1203
1204 /* Universal PCI boards */
1205 #define PCI_DEVICE_ID_URP32INTF 0x0801 /* Rocketport UPCI 32 port w/external I/F */
1206 #define PCI_DEVICE_ID_URP8INTF 0x0802 /* Rocketport UPCI 8 port w/external I/F */
1207 #define PCI_DEVICE_ID_URP16INTF 0x0803 /* Rocketport UPCI 16 port w/external I/F */
1208 #define PCI_DEVICE_ID_URP8OCTA 0x0805 /* Rocketport UPCI 8 port w/octa cable */
1209 #define PCI_DEVICE_ID_UPCI_RM3_8PORT 0x080C /* Rocketmodem III 8 port */
1210 #define PCI_DEVICE_ID_UPCI_RM3_4PORT 0x080D /* Rocketmodem III 4 port */
1211
1212 /* Compact PCI device */
1213 #define PCI_DEVICE_ID_CRP16INTF 0x0903 /* Rocketport Compact PCI 16 port w/external I/F */
1214
1215