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1/*
2 * Copyright (c) Comtrol Corporation <support@comtrol.com>
3 * All rights reserved.
4 *
5 * Redistribution and use in source and binary forms, with or without
6 * modification, are permitted prodived that the follwoing conditions
7 * are met.
8 * 1. Redistributions of source code must retain the above copyright
9 * notive, this list of conditions and the following disclainer.
10 * 2. Redistributions in binary form must reproduce the above copyright
11 * notice, this list of conditions and the following disclaimer in the
12 * documentation and/or other materials prodided with the distribution.
13 * 3. All advertising materials mentioning features or use of this software
14 * must display the following acknowledgement:
15 * This product includes software developed by Comtrol Corporation.
16 * 4. The name of Comtrol Corporation may not be used to endorse or
17 * promote products derived from this software without specific
18 * prior written permission.
19 *
20 * THIS SOFTWARE IS PROVIDED BY COMTROL CORPORATION ``AS IS'' AND ANY
21 * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
22 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
23 * ARE DISCLAIMED. IN NO EVENT SHALL COMTROL CORPORATION BE LIABLE FOR
24 * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
25 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
26 * OR SERVICES; LOSS OF USE, DATA, LIFE OR PROFITS; OR BUSINESS INTERRUPTION)
27 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
28 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
29 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
30 * SUCH DAMAGE.
31 *
32 * $Id: rp.c,v 1.25 1999/05/06 18:44:04 peter Exp $
33 */
34
35/*
36 * rp.c - for RocketPort FreeBSD
37 */
38
39#include "opt_compat.h"
40
41#include <sys/param.h>
42#include <sys/systm.h>
43#include <sys/fcntl.h>
44#include <sys/malloc.h>
45#include <sys/tty.h>
46#include <sys/proc.h>
47#include <sys/conf.h>
48#include <sys/kernel.h>
49
50#include <i386/isa/isa_device.h>
51
52#include <pci/pcivar.h>
53
54#define ROCKET_C
55#include <i386/isa/rpreg.h>
56#include <i386/isa/rpvar.h>
57
58#ifndef TRUE
59#define TRUE 1
60#endif
61
62#ifndef FALSE
63#define FALSE 0
64#endif
65
66static Byte_t RData[RDATASIZE] =
67{
68 0x00, 0x09, 0xf6, 0x82,
69 0x02, 0x09, 0x86, 0xfb,
70 0x04, 0x09, 0x00, 0x0a,
71 0x06, 0x09, 0x01, 0x0a,
72 0x08, 0x09, 0x8a, 0x13,
73 0x0a, 0x09, 0xc5, 0x11,
74 0x0c, 0x09, 0x86, 0x85,
75 0x0e, 0x09, 0x20, 0x0a,
76 0x10, 0x09, 0x21, 0x0a,
77 0x12, 0x09, 0x41, 0xff,
78 0x14, 0x09, 0x82, 0x00,
79 0x16, 0x09, 0x82, 0x7b,
80 0x18, 0x09, 0x8a, 0x7d,
81 0x1a, 0x09, 0x88, 0x81,
82 0x1c, 0x09, 0x86, 0x7a,
83 0x1e, 0x09, 0x84, 0x81,
84 0x20, 0x09, 0x82, 0x7c,
85 0x22, 0x09, 0x0a, 0x0a
86};
87
88static Byte_t RRegData[RREGDATASIZE]=
89{
90 0x00, 0x09, 0xf6, 0x82, /* 00: Stop Rx processor */
91 0x08, 0x09, 0x8a, 0x13, /* 04: Tx software flow control */
92 0x0a, 0x09, 0xc5, 0x11, /* 08: XON char */
93 0x0c, 0x09, 0x86, 0x85, /* 0c: XANY */
94 0x12, 0x09, 0x41, 0xff, /* 10: Rx mask char */
95 0x14, 0x09, 0x82, 0x00, /* 14: Compare/Ignore #0 */
96 0x16, 0x09, 0x82, 0x7b, /* 18: Compare #1 */
97 0x18, 0x09, 0x8a, 0x7d, /* 1c: Compare #2 */
98 0x1a, 0x09, 0x88, 0x81, /* 20: Interrupt #1 */
99 0x1c, 0x09, 0x86, 0x7a, /* 24: Ignore/Replace #1 */
100 0x1e, 0x09, 0x84, 0x81, /* 28: Interrupt #2 */
101 0x20, 0x09, 0x82, 0x7c, /* 2c: Ignore/Replace #2 */
102 0x22, 0x09, 0x0a, 0x0a /* 30: Rx FIFO Enable */
103};
104
105static CONTROLLER_T sController[CTL_SIZE] =
106{
107 {-1,-1,0,0,0,0,0,0,0,0,0,{0,0,0,0},{0,0,0,0},{-1,-1,-1,-1},{0,0,0,0}},
108 {-1,-1,0,0,0,0,0,0,0,0,0,{0,0,0,0},{0,0,0,0},{-1,-1,-1,-1},{0,0,0,0}},
109 {-1,-1,0,0,0,0,0,0,0,0,0,{0,0,0,0},{0,0,0,0},{-1,-1,-1,-1},{0,0,0,0}},
110 {-1,-1,0,0,0,0,0,0,0,0,0,{0,0,0,0},{0,0,0,0},{-1,-1,-1,-1},{0,0,0,0}}
111};
112
113#if 0
114/* IRQ number to MUDBAC register 2 mapping */
115Byte_t sIRQMap[16] =
116{
117 0,0,0,0x10,0x20,0x30,0,0,0,0x40,0x50,0x60,0x70,0,0,0x80
118};
119#endif
120
121static Byte_t sBitMapClrTbl[8] =
122{
123 0xfe,0xfd,0xfb,0xf7,0xef,0xdf,0xbf,0x7f
124};
125
126static Byte_t sBitMapSetTbl[8] =
127{
128 0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80
129};
130
131/***************************************************************************
132Function: sInitController
133Purpose: Initialization of controller global registers and controller
134 structure.
135Call: sInitController(CtlP,CtlNum,MudbacIO,AiopIOList,AiopIOListSize,
136 IRQNum,Frequency,PeriodicOnly)
137 CONTROLLER_T *CtlP; Ptr to controller structure
138 int CtlNum; Controller number
139 ByteIO_t MudbacIO; Mudbac base I/O address.
140 ByteIO_t *AiopIOList; List of I/O addresses for each AIOP.
141 This list must be in the order the AIOPs will be found on the
142 controller. Once an AIOP in the list is not found, it is
143 assumed that there are no more AIOPs on the controller.
144 int AiopIOListSize; Number of addresses in AiopIOList
145 int IRQNum; Interrupt Request number. Can be any of the following:
146 0: Disable global interrupts
147 3: IRQ 3
148 4: IRQ 4
149 5: IRQ 5
150 9: IRQ 9
151 10: IRQ 10
152 11: IRQ 11
153 12: IRQ 12
154 15: IRQ 15
155 Byte_t Frequency: A flag identifying the frequency
156 of the periodic interrupt, can be any one of the following:
157 FREQ_DIS - periodic interrupt disabled
158 FREQ_137HZ - 137 Hertz
159 FREQ_69HZ - 69 Hertz
160 FREQ_34HZ - 34 Hertz
161 FREQ_17HZ - 17 Hertz
162 FREQ_9HZ - 9 Hertz
163 FREQ_4HZ - 4 Hertz
164 If IRQNum is set to 0 the Frequency parameter is
165 overidden, it is forced to a value of FREQ_DIS.
166 int PeriodicOnly: TRUE if all interrupts except the periodic
167 interrupt are to be blocked.
168 FALSE is both the periodic interrupt and
169 other channel interrupts are allowed.
170 If IRQNum is set to 0 the PeriodicOnly parameter is
171 overidden, it is forced to a value of FALSE.
172Return: int: Number of AIOPs on the controller, or CTLID_NULL if controller
173 initialization failed.
174
175Comments:
176 If periodic interrupts are to be disabled but AIOP interrupts
177 are allowed, set Frequency to FREQ_DIS and PeriodicOnly to FALSE.
178
179 If interrupts are to be completely disabled set IRQNum to 0.
180
181 Setting Frequency to FREQ_DIS and PeriodicOnly to TRUE is an
182 invalid combination.
183
184 This function performs initialization of global interrupt modes,
185 but it does not actually enable global interrupts. To enable
186 and disable global interrupts use functions sEnGlobalInt() and
187 sDisGlobalInt(). Enabling of global interrupts is normally not
188 done until all other initializations are complete.
189
190 Even if interrupts are globally enabled, they must also be
191 individually enabled for each channel that is to generate
192 interrupts.
193
194Warnings: No range checking on any of the parameters is done.
195
196 No context switches are allowed while executing this function.
197
198 After this function all AIOPs on the controller are disabled,
199 they can be enabled with sEnAiop().
200*/
201int sInitController( CONTROLLER_T *CtlP,
202 int CtlNum,
203 ByteIO_t MudbacIO,
204 ByteIO_t *AiopIOList,
205 int AiopIOListSize,
206 int IRQNum,
207 Byte_t Frequency,
208 int PeriodicOnly)
209{
210 int i;
211 ByteIO_t io;
212
213 CtlP->CtlNum = CtlNum;
214 CtlP->BusType = isISA;
215 CtlP->CtlID = CTLID_0001; /* controller release 1 */
216
217 CtlP->MBaseIO = MudbacIO;
218 CtlP->MReg1IO = MudbacIO + 1;
219 CtlP->MReg2IO = MudbacIO + 2;
220 CtlP->MReg3IO = MudbacIO + 3;
221#if 1
222 CtlP->MReg2 = 0; /* interrupt disable */
223 CtlP->MReg3 = 0; /* no periodic interrupts */
224#else
225 if(sIRQMap[IRQNum] == 0) /* interrupts globally disabled */
226 {
227 CtlP->MReg2 = 0; /* interrupt disable */
228 CtlP->MReg3 = 0; /* no periodic interrupts */
229 }
230 else
231 {
232 CtlP->MReg2 = sIRQMap[IRQNum]; /* set IRQ number */
233 CtlP->MReg3 = Frequency; /* set frequency */
234 if(PeriodicOnly) /* periodic interrupt only */
235 {
236 CtlP->MReg3 |= PERIODIC_ONLY;
237 }
238 }
239#endif
240 sOutB(CtlP->MReg2IO,CtlP->MReg2);
241 sOutB(CtlP->MReg3IO,CtlP->MReg3);
242 sControllerEOI(CtlP); /* clear EOI if warm init */
243
244 /* Init AIOPs */
245 CtlP->NumAiop = 0;
246 for(i=0; i < AiopIOListSize; i++)
247 {
248 io = AiopIOList[i];
249 CtlP->AiopIO[i] = (WordIO_t)io;
250 CtlP->AiopIntChanIO[i] = io + _INT_CHAN;
251 sOutB(CtlP->MReg2IO,CtlP->MReg2 | (i & 0x03)); /* AIOP index */
252 sOutB(MudbacIO,(Byte_t)(io >> 6)); /* set up AIOP I/O in MUDBAC */
253 sEnAiop(CtlP,i); /* enable the AIOP */
254
255 CtlP->AiopID[i] = sReadAiopID(io); /* read AIOP ID */
256 if(CtlP->AiopID[i] == AIOPID_NULL) /* if AIOP does not exist */
257 {
258 sDisAiop(CtlP,i); /* disable AIOP */
259 break; /* done looking for AIOPs */
260 }
261
262 CtlP->AiopNumChan[i] = sReadAiopNumChan((WordIO_t)io); /* num channels in AIOP */
263 sOutW((WordIO_t)io + _INDX_ADDR,_CLK_PRE); /* clock prescaler */
264 sOutB(io + _INDX_DATA,CLOCK_PRESC);
265 CtlP->NumAiop++; /* bump count of AIOPs */
266 sDisAiop(CtlP,i); /* disable AIOP */
267 }
268
269 if(CtlP->NumAiop == 0)
270 return(-1);
271 else
272 return(CtlP->NumAiop);
273}
274
275int sPCIInitController( CONTROLLER_T *CtlP,
276 int CtlNum,
277 ByteIO_t *AiopIOList,
278 int AiopIOListSize,
279 int IRQNum,
280 Byte_t Frequency,
281 int PeriodicOnly)
282{
283 int i;
284 ByteIO_t io;
285
286 CtlP->CtlNum = CtlNum;
287 CtlP->BusType = isPCI;
288 CtlP->CtlID = CTLID_0001; /* controller release 1 */
289 CtlP->PCIIO = (WordIO_t)((ByteIO_t)AiopIOList[0] + _PCI_INT_FUNC);
290
291 sPCIControllerEOI(CtlP);
292
293 /* Init AIOPs */
294 CtlP->NumAiop = 0;
295 for(i=0; i < AiopIOListSize; i++)
296 {
297 io = AiopIOList[i];
298 CtlP->AiopIO[i] = (WordIO_t)io;
299 CtlP->AiopIntChanIO[i] = io + _INT_CHAN;
300
301 CtlP->AiopID[i] = sReadAiopID(io); /* read AIOP ID */
302 if(CtlP->AiopID[i] == AIOPID_NULL) /* if AIOP does not exist */
303 {
304 break; /* done looking for AIOPs */
305 }
306
307 CtlP->AiopNumChan[i] = sReadAiopNumChan((WordIO_t)io); /* num channels in AIOP */
308 sOutW((WordIO_t)io + _INDX_ADDR,_CLK_PRE); /* clock prescaler */
309 sOutB(io + _INDX_DATA,CLOCK_PRESC);
310 CtlP->NumAiop++; /* bump count of AIOPs */
311 }
312
313 if(CtlP->NumAiop == 0)
314 return(-1);
315 else
316 return(CtlP->NumAiop);
317}
318
319/***************************************************************************
320Function: sReadAiopID
321Purpose: Read the AIOP idenfication number directly from an AIOP.
322Call: sReadAiopID(io)
323 ByteIO_t io: AIOP base I/O address
324Return: int: Flag AIOPID_XXXX if a valid AIOP is found, where X
325 is replace by an identifying number.
326 Flag AIOPID_NULL if no valid AIOP is found
327Warnings: No context switches are allowed while executing this function.
328
329*/
330int sReadAiopID(ByteIO_t io)
331{
332 Byte_t AiopID; /* ID byte from AIOP */
333
334 sOutB(io + _CMD_REG,RESET_ALL); /* reset AIOP */
335 sOutB(io + _CMD_REG,0x0);
336 AiopID = sInB(io + _CHN_STAT0) & 0x07;
337 if(AiopID == 0x06)
338 return(1);
339 else /* AIOP does not exist */
340 return(-1);
341}
342
343/***************************************************************************
344Function: sReadAiopNumChan
345Purpose: Read the number of channels available in an AIOP directly from
346 an AIOP.
347Call: sReadAiopNumChan(io)
348 WordIO_t io: AIOP base I/O address
349Return: int: The number of channels available
350Comments: The number of channels is determined by write/reads from identical
351 offsets within the SRAM address spaces for channels 0 and 4.
352 If the channel 4 space is mirrored to channel 0 it is a 4 channel
353 AIOP, otherwise it is an 8 channel.
354Warnings: No context switches are allowed while executing this function.
355*/
356int sReadAiopNumChan(WordIO_t io)
357{
358 Word_t x;
359
360 sOutDW((DWordIO_t)io + _INDX_ADDR,0x12340000L); /* write to chan 0 SRAM */
361 sOutW(io + _INDX_ADDR,0); /* read from SRAM, chan 0 */
362 x = sInW(io + _INDX_DATA);
363 sOutW(io + _INDX_ADDR,0x4000); /* read from SRAM, chan 4 */
364 if(x != sInW(io + _INDX_DATA)) /* if different must be 8 chan */
365 return(8);
366 else
367 return(4);
368}
369
370/***************************************************************************
371Function: sInitChan
372Purpose: Initialization of a channel and channel structure
373Call: sInitChan(CtlP,ChP,AiopNum,ChanNum)
374 CONTROLLER_T *CtlP; Ptr to controller structure
375 CHANNEL_T *ChP; Ptr to channel structure
376 int AiopNum; AIOP number within controller
377 int ChanNum; Channel number within AIOP
378Return: int: TRUE if initialization succeeded, FALSE if it fails because channel
379 number exceeds number of channels available in AIOP.
380Comments: This function must be called before a channel can be used.
381Warnings: No range checking on any of the parameters is done.
382
383 No context switches are allowed while executing this function.
384*/
385int sInitChan( CONTROLLER_T *CtlP,
386 CHANNEL_T *ChP,
387 int AiopNum,
388 int ChanNum)
389{
390 int i;
391 WordIO_t AiopIO;
392 WordIO_t ChIOOff;
393 Byte_t *ChR;
394 Word_t ChOff;
395 static Byte_t R[4];
396
397 if(ChanNum >= CtlP->AiopNumChan[AiopNum])
398 return(FALSE); /* exceeds num chans in AIOP */
399
400 /* Channel, AIOP, and controller identifiers */
401 ChP->CtlP = CtlP;
402 ChP->ChanID = CtlP->AiopID[AiopNum];
403 ChP->AiopNum = AiopNum;
404 ChP->ChanNum = ChanNum;
405
406 /* Global direct addresses */
407 AiopIO = CtlP->AiopIO[AiopNum];
408 ChP->Cmd = (ByteIO_t)AiopIO + _CMD_REG;
409 ChP->IntChan = (ByteIO_t)AiopIO + _INT_CHAN;
410 ChP->IntMask = (ByteIO_t)AiopIO + _INT_MASK;
411 ChP->IndexAddr = (DWordIO_t)AiopIO + _INDX_ADDR;
412 ChP->IndexData = AiopIO + _INDX_DATA;
413
414 /* Channel direct addresses */
415 ChIOOff = AiopIO + ChP->ChanNum * 2;
416 ChP->TxRxData = ChIOOff + _TD0;
417 ChP->ChanStat = ChIOOff + _CHN_STAT0;
418 ChP->TxRxCount = ChIOOff + _FIFO_CNT0;
419 ChP->IntID = (ByteIO_t)AiopIO + ChP->ChanNum + _INT_ID0;
420
421 /* Initialize the channel from the RData array */
422 for(i=0; i < RDATASIZE; i+=4)
423 {
424 R[0] = RData[i];
425 R[1] = RData[i+1] + 0x10 * ChanNum;
426 R[2] = RData[i+2];
427 R[3] = RData[i+3];
428 sOutDW(ChP->IndexAddr,*((DWord_t *)&R[0]));
429 }
430
431 ChR = ChP->R;
432 for(i=0; i < RREGDATASIZE; i+=4)
433 {
434 ChR[i] = RRegData[i];
435 ChR[i+1] = RRegData[i+1] + 0x10 * ChanNum;
436 ChR[i+2] = RRegData[i+2];
437 ChR[i+3] = RRegData[i+3];
438 }
439
440 /* Indexed registers */
441 ChOff = (Word_t)ChanNum * 0x1000;
442
443 ChP->BaudDiv[0] = (Byte_t)(ChOff + _BAUD);
444 ChP->BaudDiv[1] = (Byte_t)((ChOff + _BAUD) >> 8);
445 ChP->BaudDiv[2] = (Byte_t)BRD9600;
446 ChP->BaudDiv[3] = (Byte_t)(BRD9600 >> 8);
447 sOutDW(ChP->IndexAddr,*(DWord_t *)&ChP->BaudDiv[0]);
448
449 ChP->TxControl[0] = (Byte_t)(ChOff + _TX_CTRL);
450 ChP->TxControl[1] = (Byte_t)((ChOff + _TX_CTRL) >> 8);
451 ChP->TxControl[2] = 0;
452 ChP->TxControl[3] = 0;
453 sOutDW(ChP->IndexAddr,*(DWord_t *)&ChP->TxControl[0]);
454
455 ChP->RxControl[0] = (Byte_t)(ChOff + _RX_CTRL);
456 ChP->RxControl[1] = (Byte_t)((ChOff + _RX_CTRL) >> 8);
457 ChP->RxControl[2] = 0;
458 ChP->RxControl[3] = 0;
459 sOutDW(ChP->IndexAddr,*(DWord_t *)&ChP->RxControl[0]);
460
461 ChP->TxEnables[0] = (Byte_t)(ChOff + _TX_ENBLS);
462 ChP->TxEnables[1] = (Byte_t)((ChOff + _TX_ENBLS) >> 8);
463 ChP->TxEnables[2] = 0;
464 ChP->TxEnables[3] = 0;
465 sOutDW(ChP->IndexAddr,*(DWord_t *)&ChP->TxEnables[0]);
466
467 ChP->TxCompare[0] = (Byte_t)(ChOff + _TXCMP1);
468 ChP->TxCompare[1] = (Byte_t)((ChOff + _TXCMP1) >> 8);
469 ChP->TxCompare[2] = 0;
470 ChP->TxCompare[3] = 0;
471 sOutDW(ChP->IndexAddr,*(DWord_t *)&ChP->TxCompare[0]);
472
473 ChP->TxReplace1[0] = (Byte_t)(ChOff + _TXREP1B1);
474 ChP->TxReplace1[1] = (Byte_t)((ChOff + _TXREP1B1) >> 8);
475 ChP->TxReplace1[2] = 0;
476 ChP->TxReplace1[3] = 0;
477 sOutDW(ChP->IndexAddr,*(DWord_t *)&ChP->TxReplace1[0]);
478
479 ChP->TxReplace2[0] = (Byte_t)(ChOff + _TXREP2);
480 ChP->TxReplace2[1] = (Byte_t)((ChOff + _TXREP2) >> 8);
481 ChP->TxReplace2[2] = 0;
482 ChP->TxReplace2[3] = 0;
483 sOutDW(ChP->IndexAddr,*(DWord_t *)&ChP->TxReplace2[0]);
484
485 ChP->TxFIFOPtrs = ChOff + _TXF_OUTP;
486 ChP->TxFIFO = ChOff + _TX_FIFO;
487
488 sOutB(ChP->Cmd,(Byte_t)ChanNum | RESTXFCNT); /* apply reset Tx FIFO count */
489 sOutB(ChP->Cmd,(Byte_t)ChanNum); /* remove reset Tx FIFO count */
490 sOutW((WordIO_t)ChP->IndexAddr,ChP->TxFIFOPtrs); /* clear Tx in/out ptrs */
491 sOutW(ChP->IndexData,0);
492 ChP->RxFIFOPtrs = ChOff + _RXF_OUTP;
493 ChP->RxFIFO = ChOff + _RX_FIFO;
494
495 sOutB(ChP->Cmd,(Byte_t)ChanNum | RESRXFCNT); /* apply reset Rx FIFO count */
496 sOutB(ChP->Cmd,(Byte_t)ChanNum); /* remove reset Rx FIFO count */
497 sOutW((WordIO_t)ChP->IndexAddr,ChP->RxFIFOPtrs); /* clear Rx out ptr */
498 sOutW(ChP->IndexData,0);
499 sOutW((WordIO_t)ChP->IndexAddr,ChP->RxFIFOPtrs + 2); /* clear Rx in ptr */
500 sOutW(ChP->IndexData,0);
501 ChP->TxPrioCnt = ChOff + _TXP_CNT;
502 sOutW((WordIO_t)ChP->IndexAddr,ChP->TxPrioCnt);
503 sOutB(ChP->IndexData,0);
504 ChP->TxPrioPtr = ChOff + _TXP_PNTR;
505 sOutW((WordIO_t)ChP->IndexAddr,ChP->TxPrioPtr);
506 sOutB(ChP->IndexData,0);
507 ChP->TxPrioBuf = ChOff + _TXP_BUF;
508 sEnRxProcessor(ChP); /* start the Rx processor */
509
510 return(TRUE);
511}
512
513/***************************************************************************
514Function: sStopRxProcessor
515Purpose: Stop the receive processor from processing a channel.
516Call: sStopRxProcessor(ChP)
517 CHANNEL_T *ChP; Ptr to channel structure
518
519Comments: The receive processor can be started again with sStartRxProcessor().
520 This function causes the receive processor to skip over the
521 stopped channel. It does not stop it from processing other channels.
522
523Warnings: No context switches are allowed while executing this function.
524
525 Do not leave the receive processor stopped for more than one
526 character time.
527
528 After calling this function a delay of 4 uS is required to ensure
529 that the receive processor is no longer processing this channel.
530*/
531void sStopRxProcessor(CHANNEL_T *ChP)
532{
533 Byte_t R[4];
534
535 R[0] = ChP->R[0];
536 R[1] = ChP->R[1];
537 R[2] = 0x0a;
538 R[3] = ChP->R[3];
539 sOutDW(ChP->IndexAddr,*(DWord_t *)&R[0]);
540}
541
542/***************************************************************************
543Function: sFlushRxFIFO
544Purpose: Flush the Rx FIFO
545Call: sFlushRxFIFO(ChP)
546 CHANNEL_T *ChP; Ptr to channel structure
547Return: void
548Comments: To prevent data from being enqueued or dequeued in the Tx FIFO
549 while it is being flushed the receive processor is stopped
550 and the transmitter is disabled. After these operations a
551 4 uS delay is done before clearing the pointers to allow
552 the receive processor to stop. These items are handled inside
553 this function.
554Warnings: No context switches are allowed while executing this function.
555*/
556void sFlushRxFIFO(CHANNEL_T *ChP)
557{
558 int i;
559 Byte_t Ch; /* channel number within AIOP */
560 int RxFIFOEnabled; /* TRUE if Rx FIFO enabled */
561
562 if(sGetRxCnt(ChP) == 0) /* Rx FIFO empty */
563 return; /* don't need to flush */
564
565 RxFIFOEnabled = FALSE;
566 if(ChP->R[0x32] == 0x08) /* Rx FIFO is enabled */
567 {
568 RxFIFOEnabled = TRUE;
569 sDisRxFIFO(ChP); /* disable it */
570 for(i=0; i < 2000/200; i++) /* delay 2 uS to allow proc to disable FIFO*/
571 sInB(ChP->IntChan); /* depends on bus i/o timing */
572 }
573 sGetChanStatus(ChP); /* clear any pending Rx errors in chan stat */
574 Ch = (Byte_t)sGetChanNum(ChP);
575 sOutB(ChP->Cmd,Ch | RESRXFCNT); /* apply reset Rx FIFO count */
576 sOutB(ChP->Cmd,Ch); /* remove reset Rx FIFO count */
577 sOutW((WordIO_t)ChP->IndexAddr,ChP->RxFIFOPtrs); /* clear Rx out ptr */
578 sOutW(ChP->IndexData,0);
579 sOutW((WordIO_t)ChP->IndexAddr,ChP->RxFIFOPtrs + 2); /* clear Rx in ptr */
580 sOutW(ChP->IndexData,0);
581 if(RxFIFOEnabled)
582 sEnRxFIFO(ChP); /* enable Rx FIFO */
583}
584
585/***************************************************************************
586Function: sFlushTxFIFO
587Purpose: Flush the Tx FIFO
588Call: sFlushTxFIFO(ChP)
589 CHANNEL_T *ChP; Ptr to channel structure
590Return: void
591Comments: To prevent data from being enqueued or dequeued in the Tx FIFO
592 while it is being flushed the receive processor is stopped
593 and the transmitter is disabled. After these operations a
594 4 uS delay is done before clearing the pointers to allow
595 the receive processor to stop. These items are handled inside
596 this function.
597Warnings: No context switches are allowed while executing this function.
598*/
599void sFlushTxFIFO(CHANNEL_T *ChP)
600{
601 int i;
602 Byte_t Ch; /* channel number within AIOP */
603 int TxEnabled; /* TRUE if transmitter enabled */
604
605 if(sGetTxCnt(ChP) == 0) /* Tx FIFO empty */
606 return; /* don't need to flush */
607
608 TxEnabled = FALSE;
609 if(ChP->TxControl[3] & TX_ENABLE)
610 {
611 TxEnabled = TRUE;
612 sDisTransmit(ChP); /* disable transmitter */
613 }
614 sStopRxProcessor(ChP); /* stop Rx processor */
615 for(i = 0; i < 4000/200; i++) /* delay 4 uS to allow proc to stop */
616 sInB(ChP->IntChan); /* depends on bus i/o timing */
617 Ch = (Byte_t)sGetChanNum(ChP);
618 sOutB(ChP->Cmd,Ch | RESTXFCNT); /* apply reset Tx FIFO count */
619 sOutB(ChP->Cmd,Ch); /* remove reset Tx FIFO count */
620 sOutW((WordIO_t)ChP->IndexAddr,ChP->TxFIFOPtrs); /* clear Tx in/out ptrs */
621 sOutW(ChP->IndexData,0);
622 if(TxEnabled)
623 sEnTransmit(ChP); /* enable transmitter */
624 sStartRxProcessor(ChP); /* restart Rx processor */
625}
626
627/***************************************************************************
628Function: sWriteTxPrioByte
629Purpose: Write a byte of priority transmit data to a channel
630Call: sWriteTxPrioByte(ChP,Data)
631 CHANNEL_T *ChP; Ptr to channel structure
632 Byte_t Data; The transmit data byte
633
634Return: int: 1 if the bytes is successfully written, otherwise 0.
635
636Comments: The priority byte is transmitted before any data in the Tx FIFO.
637
638Warnings: No context switches are allowed while executing this function.
639*/
640int sWriteTxPrioByte(CHANNEL_T *ChP, Byte_t Data)
641{
642 Byte_t DWBuf[4]; /* buffer for double word writes */
643 Word_t *WordPtr; /* must be far because Win SS != DS */
644 register DWordIO_t IndexAddr;
645
646 if(sGetTxCnt(ChP) > 1) /* write it to Tx priority buffer */
647 {
648 IndexAddr = ChP->IndexAddr;
649 sOutW((WordIO_t)IndexAddr,ChP->TxPrioCnt); /* get priority buffer status */
650 if(sInB((ByteIO_t)ChP->IndexData) & PRI_PEND) /* priority buffer busy */
651 return(0); /* nothing sent */
652
653 WordPtr = (Word_t *)(&DWBuf[0]);
654 *WordPtr = ChP->TxPrioBuf; /* data byte address */
655
656 DWBuf[2] = Data; /* data byte value */
657 sOutDW(IndexAddr,*((DWord_t *)(&DWBuf[0]))); /* write it out */
658
659 *WordPtr = ChP->TxPrioCnt; /* Tx priority count address */
660
661 DWBuf[2] = PRI_PEND + 1; /* indicate 1 byte pending */
662 DWBuf[3] = 0; /* priority buffer pointer */
663 sOutDW(IndexAddr,*((DWord_t *)(&DWBuf[0]))); /* write it out */
664 }
665 else /* write it to Tx FIFO */
666 {
667 sWriteTxByte(sGetTxRxDataIO(ChP),Data);
668 }
669 return(1); /* 1 byte sent */
670}
671
672/***************************************************************************
673Function: sEnInterrupts
674Purpose: Enable one or more interrupts for a channel
675Call: sEnInterrupts(ChP,Flags)
676 CHANNEL_T *ChP; Ptr to channel structure
677 Word_t Flags: Interrupt enable flags, can be any combination
678 of the following flags:
679 TXINT_EN: Interrupt on Tx FIFO empty
680 RXINT_EN: Interrupt on Rx FIFO at trigger level (see
681 sSetRxTrigger())
682 SRCINT_EN: Interrupt on SRC (Special Rx Condition)
683 MCINT_EN: Interrupt on modem input change
684 CHANINT_EN: Allow channel interrupt signal to the AIOP's
685 Interrupt Channel Register.
686Return: void
687Comments: If an interrupt enable flag is set in Flags, that interrupt will be
688 enabled. If an interrupt enable flag is not set in Flags, that
689 interrupt will not be changed. Interrupts can be disabled with
690 function sDisInterrupts().
691
692 This function sets the appropriate bit for the channel in the AIOP's
693 Interrupt Mask Register if the CHANINT_EN flag is set. This allows
694 this channel's bit to be set in the AIOP's Interrupt Channel Register.
695
696 Interrupts must also be globally enabled before channel interrupts
697 will be passed on to the host. This is done with function
698 sEnGlobalInt().
699
700 In some cases it may be desirable to disable interrupts globally but
701 enable channel interrupts. This would allow the global interrupt
702 status register to be used to determine which AIOPs need service.
703*/
704void sEnInterrupts(CHANNEL_T *ChP,Word_t Flags)
705{
706 Byte_t Mask; /* Interrupt Mask Register */
707
708 ChP->RxControl[2] |=
709 ((Byte_t)Flags & (RXINT_EN | SRCINT_EN | MCINT_EN));
710
711 sOutDW(ChP->IndexAddr,*(DWord_t *)&ChP->RxControl[0]);
712
713 ChP->TxControl[2] |= ((Byte_t)Flags & TXINT_EN);
714
715 sOutDW(ChP->IndexAddr,*(DWord_t *)&ChP->TxControl[0]);
716
717 if(Flags & CHANINT_EN)
718 {
719 Mask = sInB(ChP->IntMask) | sBitMapSetTbl[ChP->ChanNum];
720 sOutB(ChP->IntMask,Mask);
721 }
722}
723
724/***************************************************************************
725Function: sDisInterrupts
726Purpose: Disable one or more interrupts for a channel
727Call: sDisInterrupts(ChP,Flags)
728 CHANNEL_T *ChP; Ptr to channel structure
729 Word_t Flags: Interrupt flags, can be any combination
730 of the following flags:
731 TXINT_EN: Interrupt on Tx FIFO empty
732 RXINT_EN: Interrupt on Rx FIFO at trigger level (see
733 sSetRxTrigger())
734 SRCINT_EN: Interrupt on SRC (Special Rx Condition)
735 MCINT_EN: Interrupt on modem input change
736 CHANINT_EN: Disable channel interrupt signal to the
737 AIOP's Interrupt Channel Register.
738Return: void
739Comments: If an interrupt flag is set in Flags, that interrupt will be
740 disabled. If an interrupt flag is not set in Flags, that
741 interrupt will not be changed. Interrupts can be enabled with
742 function sEnInterrupts().
743
744 This function clears the appropriate bit for the channel in the AIOP's
745 Interrupt Mask Register if the CHANINT_EN flag is set. This blocks
746 this channel's bit from being set in the AIOP's Interrupt Channel
747 Register.
748*/
749void sDisInterrupts(CHANNEL_T *ChP,Word_t Flags)
750{
751 Byte_t Mask; /* Interrupt Mask Register */
752
753 ChP->RxControl[2] &=
754 ~((Byte_t)Flags & (RXINT_EN | SRCINT_EN | MCINT_EN));
755 sOutDW(ChP->IndexAddr,*(DWord_t *)&ChP->RxControl[0]);
756 ChP->TxControl[2] &= ~((Byte_t)Flags & TXINT_EN);
757 sOutDW(ChP->IndexAddr,*(DWord_t *)&ChP->TxControl[0]);
758
759 if(Flags & CHANINT_EN)
760 {
761 Mask = sInB(ChP->IntMask) & sBitMapClrTbl[ChP->ChanNum];
762 sOutB(ChP->IntMask,Mask);
763 }
764}
765
766/*********************************************************************
767 Begin FreeBsd-specific driver code
768**********************************************************************/
769
770static int rpprobe __P((struct isa_device *));
771static int rpattach __P((struct isa_device *));
772
773static const char* rp_pciprobe(pcici_t tag, pcidi_t type);
774static void rp_pciattach(pcici_t tag, int unit);
775static u_long rp_pcicount;
776
777static struct pci_device rp_pcidevice = {
778 "rp",
779 rp_pciprobe,
780 rp_pciattach,
781 &rp_pcicount,
782 NULL
783};
784
785COMPAT_PCI_DRIVER (rp_pci, rp_pcidevice);
786
787static timeout_t rpdtrwakeup;
788
789struct isa_driver rpdriver = {
790 rpprobe, rpattach, "rp"
791 };
792
793static char driver_name[] = "rp";
794
795static d_open_t rpopen;
796static d_close_t rpclose;
797static d_read_t rpread;
798static d_write_t rpwrite;
799static d_ioctl_t rpioctl;
800static d_stop_t rpstop;
801static d_devtotty_t rpdevtotty;
802
803#define CDEV_MAJOR 81
804static struct cdevsw rp_cdevsw = {
805 rpopen, rpclose, rpread, rpwrite,
806 rpioctl, rpstop, noreset, rpdevtotty,
807 ttpoll, nommap, NULL, driver_name,
808 NULL, -1, nodump, nopsize,
809 D_TTY,
810};
811
812static int rp_controller_port = 0;
813static int rp_num_ports_open = 0;
814static int ndevs = 0;
815static int minor_to_unit[128];
816#if 0
817static struct tty rp_tty[128];
818#endif
819
820static int rp_num_ports[4]; /* Number of ports on each controller */
821
822#define _INLINE_ __inline
823#define POLL_INTERVAL 1
824
825#define CALLOUT_MASK 0x80
826#define CONTROL_MASK 0x60
827#define CONTROL_INIT_STATE 0x20
828#define CONTROL_LOCK_STATE 0x40
829#define DEV_UNIT(dev) (MINOR_TO_UNIT(minor(dev))
830#define MINOR_MAGIC_MASK (CALLOUT_MASK | CONTROL_MASK)
831#define MINOR_MAGIC(dev) ((minor(dev)) & ~MINOR_MAGIC_MASK)
832#define IS_CALLOUT(dev) (minor(dev) & CALLOUT_MASK)
833#define IS_CONTROL(dev) (minor(dev) & CONTROL_MASK)
834
835#define RP_ISMULTIPORT(dev) ((dev)->id_flags & 0x1)
836#define RP_MPMASTER(dev) (((dev)->id_flags >> 8) & 0xff)
837#define RP_NOTAST4(dev) ((dev)->id_flags & 0x04)
838
839static struct rp_port *p_rp_addr[4];
840static struct rp_port *p_rp_table[MAX_RP_PORTS];
841#define rp_addr(unit) (p_rp_addr[unit])
842#define rp_table(port) (p_rp_table[port])
843
844/*
845 * The top-level routines begin here
846 */
847
848int rpselect __P((dev_t, int, struct proc *));
849
850static int rpparam __P((struct tty *, struct termios *));
851static void rpstart __P((struct tty *));
852static void rphardclose __P((struct rp_port *));
853#define rpmap nomap
854#define rpreset noreset
855#define rpstrategy nostrategy
856static void rp_disc_optim __P((struct tty *tp, struct termios *t,
857 struct rp_port *rp));
858
859static _INLINE_ void rp_do_receive(struct rp_port *rp, struct tty *tp,
860 CHANNEL_t *cp, unsigned int ChanStatus)
861{
862 int spl;
863 unsigned int CharNStat;
864 int ToRecv, ch;
865
866 ToRecv = sGetRxCnt(cp);
867 if(ToRecv == 0)
868 return;
869
870/* If status indicates there are errored characters in the
871 FIFO, then enter status mode (a word in FIFO holds
872 characters and status)
873*/
874
875 if(ChanStatus & (RXFOVERFL | RXBREAK | RXFRAME | RXPARITY)) {
876 if(!(ChanStatus & STATMODE)) {
877 ChanStatus |= STATMODE;
878 sEnRxStatusMode(cp);
879 }
880 }
881/*
882 if we previously entered status mode then read down the
883 FIFO one word at a time, pulling apart the character and
884 the status. Update error counters depending on status.
885*/
886 if(ChanStatus & STATMODE) {
887 while(ToRecv) {
888 if(tp->t_state & TS_TBLOCK) {
889 break;
890 }
891 CharNStat = sInW(sGetTxRxDataIO(cp));
892 ch = CharNStat & 0xff;
893
894 if((CharNStat & STMBREAK) || (CharNStat & STMFRAMEH))
895 ch |= TTY_FE;
896 else if (CharNStat & STMPARITYH)
897 ch |= TTY_PE;
898 else if (CharNStat & STMRCVROVRH)
899 rp->rp_overflows++;
900
901 (*linesw[tp->t_line].l_rint)(ch, tp);
902 ToRecv--;
903 }
904/*
905 After emtying FIFO in status mode, turn off status mode
906*/
907
908 if(sGetRxCnt(cp) == 0)
909 sDisRxStatusMode(cp);
910 }
911 else {
912 while (ToRecv) {
913 if(tp->t_state & TS_TBLOCK) {
914 break;
915 }
916 ch = (u_char) sInB(sGetTxRxDataIO(cp));
917 spl = spltty();
918 (*linesw[tp->t_line].l_rint)(ch, tp);
919 splx(spl);
920 ToRecv--;
921 }
922 }
923}
924
925static _INLINE_ void rp_handle_port(struct rp_port *rp)
926{
927 CHANNEL_t *cp;
928 struct tty *tp;
929 unsigned int IntMask, ChanStatus;
930 /* int oldcts; */
931
932 if(!rp)
933 return;
934
935 cp = &rp->rp_channel;
936 tp = rp->rp_tty;
937 IntMask = sGetChanIntID(cp);
938 IntMask = IntMask & rp->rp_intmask;
939 ChanStatus = sGetChanStatus(cp);
940 if(IntMask & RXF_TRIG)
941 if(!(tp->t_state & TS_TBLOCK) && (tp->t_state & TS_CARR_ON) && (tp->t_state & TS_ISOPEN)) {
942 rp_do_receive(rp, tp, cp, ChanStatus);
943 }
944 if(IntMask & DELTA_CD) {
945 if(ChanStatus & CD_ACT) {
946 if(!(tp->t_state & TS_CARR_ON) ) {
947 (void)(*linesw[tp->t_line].l_modem)(tp, 1);
948 }
949 } else {
950 if((tp->t_state & TS_CARR_ON)) {
951 (void)(*linesw[tp->t_line].l_modem)(tp, 0);
952 if((*linesw[tp->t_line].l_modem)(tp, 0) == 0) {
953 rphardclose(rp);
954 }
955 }
956 }
957 }
958/* oldcts = rp->rp_cts;
959 rp->rp_cts = ((ChanStatus & CTS_ACT) != 0);
960 if(oldcts != rp->rp_cts) {
961 printf("CTS change (now %s)... on port %d\n", rp->rp_cts ? "on" : "off", rp->rp_port);
962 }
963*/
964}
965
966static void rp_do_poll(void *not_used)
967{
968 CONTROLLER_t *ctl;
969 struct rp_port *rp;
970 struct tty *tp;
971 int unit, aiop, ch, line, count;
972 unsigned char CtlMask, AiopMask;
973
974 for(unit = 0; unit <= ndevs; unit++) {
975 rp = rp_addr(unit);
976 ctl = rp->rp_ctlp;
977 if(ctl->BusType == isPCI)
978 CtlMask = sPCIGetControllerIntStatus(ctl);
979 else
980 CtlMask = sGetControllerIntStatus(ctl);
981 for(aiop=0; CtlMask; CtlMask >>=1, aiop++) {
982 if(CtlMask & 1) {
983 AiopMask = sGetAiopIntStatus(ctl, aiop);
984 for(ch = 0; AiopMask; AiopMask >>=1, ch++) {
985 if(AiopMask & 1) {
986 line = (unit << 5) | (aiop << 3) | ch;
987 rp = rp_table(line);
988 rp_handle_port(rp);
989 }
990 }
991 }
992 }
993
994 for(line = 0, rp = rp_addr(unit); line < rp_num_ports[unit];
995 line++, rp++) {
996 tp = rp->rp_tty;
997 if((tp->t_state & TS_BUSY) && (tp->t_state & TS_ISOPEN)) {
998 count = sGetTxCnt(&rp->rp_channel);
999 if(count == 0)
1000 tp->t_state &= ~(TS_BUSY);
1001 if(!(tp->t_state & TS_TTSTOP) &&
1002 (count <= rp->rp_restart)) {
1003 (*linesw[tp->t_line].l_start)(tp);
1004 }
1005 }
1006 }
1007 }
1008 if(rp_num_ports_open)
1009 timeout(rp_do_poll, (void *)NULL, POLL_INTERVAL);
1010}
1011
1012static const char*
1013rp_pciprobe(pcici_t tag, pcidi_t type)
1014{
1015 int vendor_id;
1016
1017 vendor_id = type & 0xffff;
1018 switch(vendor_id)
1019 case 0x11fe:
1020 return("rp");
1021 return(NULL);
1022}
1023
1024static
1025int
1026rpprobe(dev)
1027struct isa_device *dev;
1028{
1029 int controller, unit;
1030 int aiop, num_aiops;
1031 unsigned int aiopio[MAX_AIOPS_PER_BOARD];
1032 CONTROLLER_t *ctlp;
1033
1034 unit = dev->id_unit;
1035 if (dev->id_unit >= 4) {
1036 printf("rpprobe: unit number %d invalid.\n", dev->id_unit);
1037 return 1;
1038 }
1039 printf("probing for RocketPort(ISA) unit %d\n", unit);
1040 if (rp_controller_port)
1041 controller = rp_controller_port;
1042 else {
1043 controller = dev->id_iobase + 0x40;
1044 }
1045
1046 for (aiop=0; aiop<MAX_AIOPS_PER_BOARD; aiop++)
1047 aiopio[aiop]= dev->id_iobase + (aiop * 0x400);
1048
1049 ctlp = sCtlNumToCtlPtr(dev->id_unit);
1050 num_aiops = sInitController(ctlp, dev->id_unit,
1051 controller + ((unit-rp_pcicount)*0x400),
1052 aiopio, MAX_AIOPS_PER_BOARD, 0,
1053 FREQ_DIS, 0);
1054 if (num_aiops <= 0) {
1055 printf("board%d init failed\n", unit);
1056 return 0;
1057 }
1058
1059 if (rp_controller_port) {
1060 dev->id_msize = 64;
1061 } else {
1062 dev->id_msize = 68;
1063 rp_controller_port = controller;
1064 }
1065
1066 dev->id_irq = 0;
1067
1068 return 1;
1069}
1070
1071static void
1072rp_pciattach(pcici_t tag, int unit)
1073{
1074 dev_t rp_dev;
1075 int success, oldspl;
1076 u_short iobase;
1077 int num_ports, num_chan, num_aiops;
1078 int aiop, chan, port;
1079 int ChanStatus, line, i, count;
1080 unsigned int aiopio[MAX_AIOPS_PER_BOARD];
1081 struct rp_port *rp;
1082 struct tty *tty;
1083 CONTROLLER_t *ctlp;
1084
1085 success = pci_map_port(tag, 0x10, &iobase);
1086 if(!success)
1087 printf("ioaddr mapping failed for RocketPort(PCI)\n");
1088
1089 for(aiop=0; aiop < MAX_AIOPS_PER_BOARD; aiop++)
1090 aiopio[aiop] = iobase + (aiop * 0x40);
1091
1092 ctlp = sCtlNumToCtlPtr(unit);
1093 num_aiops = sPCIInitController(ctlp, unit,
1094 aiopio, MAX_AIOPS_PER_BOARD, 0,
1095 FREQ_DIS, 0);
1096
1097 num_ports = 0;
1098 for(aiop=0; aiop < num_aiops; aiop++) {
1099 sResetAiopByNum(ctlp, aiop);
1100 num_ports += sGetAiopNumChan(ctlp, aiop);
1101 }
1102 printf("RocketPort%d = %d ports\n", unit, num_ports);
1103 rp_num_ports[unit] = num_ports;
1104
1105 rp = (struct rp_port *)
1106 malloc(sizeof(struct rp_port) * num_ports, M_TTYS, M_NOWAIT);
1107 if(rp == 0) {
1108 printf("rp_attach: Could not malloc rp_ports structures\n");
1109 return;
1110 }
1111
1112 count = unit * 32; /* board times max ports per card SG */
1113 for(i=count;i < (count + rp_num_ports[unit]);i++)
1114 minor_to_unit[i] = unit;
1115
1116 bzero(rp, sizeof(struct rp_port) * num_ports);
1117 tty = (struct tty *)
1118 malloc(sizeof(struct tty) * num_ports, M_TTYS, M_NOWAIT);
1119 if(tty == 0) {
1120 printf("rp_attach: Could not malloc tty structures\n");
1121 return;
1122 }
1123 bzero(tty, sizeof(struct tty) * num_ports);
1124
1125 oldspl = spltty();
1126 rp_addr(unit) = rp;
1127 splx(oldspl);
1128
1129 rp_dev = makedev(CDEV_MAJOR, unit);
1130 cdevsw_add(&rp_dev, &rp_cdevsw, NULL);
1131
1132 port = 0;
1133 for(aiop=0; aiop < num_aiops; aiop++) {
1134 num_chan = sGetAiopNumChan(ctlp, aiop);
1135 for(chan=0; chan < num_chan; chan++, port++, rp++, tty++) {
1136 rp->rp_tty = tty;
1137 rp->rp_port = port;
1138 rp->rp_ctlp = ctlp;
1139 rp->rp_unit = unit;
1140 rp->rp_chan = chan;
1141 rp->rp_aiop = aiop;
1142
1143 tty->t_line = 0;
1144 /* tty->t_termios = deftermios;
1145 */
1146 rp->dtr_wait = 3 * hz;
1147 rp->it_in.c_iflag = 0;
1148 rp->it_in.c_oflag = 0;
1149 rp->it_in.c_cflag = TTYDEF_CFLAG;
1150 rp->it_in.c_lflag = 0;
1151 termioschars(&rp->it_in);
1152 /* termioschars(&tty->t_termios);
1153 */
1154 rp->it_in.c_ispeed = rp->it_in.c_ospeed = TTYDEF_SPEED;
1155 rp->it_out = rp->it_in;
1156
1157 rp->rp_intmask = RXF_TRIG | TXFIFO_MT | SRC_INT |
1158 DELTA_CD | DELTA_CTS | DELTA_DSR;
1159 ChanStatus = sGetChanStatus(&rp->rp_channel);
1160 if(sInitChan(ctlp, &rp->rp_channel, aiop, chan) == 0) {
1161 printf("RocketPort sInitChan(%d, %d, %d) failed
1162 \n", unit, aiop, chan);
1163 return;
1164 }
1165 ChanStatus = sGetChanStatus(&rp->rp_channel);
1166 rp->rp_cts = (ChanStatus & CTS_ACT) != 0;
1167 line = (unit << 5) | (aiop << 3) | chan;
1168 rp_table(line) = rp;
1169/* devfs_add_devswf(&rp_cdevsw,
1170 port, DV_CHR, UID_ROOT, GID_WHEEL, 0600,
1171 "ttyR%r", port);
1172 devfs_add_devswf(&rp_cdevsw,
1173 port | CONTROL_INIT_STATE, DV_CHR, UID_ROOT,
1174 GID_WHEEL, 0600, "ttyRi%r", port);
1175*/
1176 }
1177 }
1178}
1179
1180static
1181int
1182rpattach(dev)
1183struct isa_device *dev;
1184{
1185 dev_t rp_dev;
1186 int iobase, unit, /*rpmajor,*/ oldspl;
1187 int num_ports, num_chan, num_aiops;
1188 int aiop, chan, port;
1189 int ChanStatus, line, i, count;
1190 unsigned int aiopio[MAX_AIOPS_PER_BOARD];
1191 struct rp_port *rp;
1192 struct tty *tty;
1193 CONTROLLER_t *ctlp;
1194
1195 iobase = dev->id_iobase;
1196 unit = dev->id_unit;
1197 ndevs = unit;
1198
1199 for(aiop=0; aiop < MAX_AIOPS_PER_BOARD; aiop++)
1200 aiopio[aiop] = iobase + (aiop * 0x400);
1201
1202 ctlp = sCtlNumToCtlPtr(unit);
1203 num_aiops = sInitController(ctlp, unit,
1204 rp_controller_port + ((unit-rp_pcicount) * 0x400),
1205 aiopio, MAX_AIOPS_PER_BOARD, 0,
1206 FREQ_DIS, 0);
1207
1208 num_ports = 0;
1209 for(aiop=0; aiop < num_aiops; aiop++) {
1210 sResetAiopByNum(ctlp, aiop);
1211 sEnAiop(ctlp, aiop);
1212 num_ports += sGetAiopNumChan(ctlp, aiop);
1213 }
1214 printf("RocketPort%d = %d ports\n", unit, num_ports);
1215 rp_num_ports[unit] = num_ports;
1216
1217 rp = (struct rp_port *)
1218 malloc(sizeof(struct rp_port) * num_ports, M_TTYS, M_NOWAIT);
1219 if(rp == 0) {
1220 printf("rp_attach: Could not malloc rp_ports structures\n");
1221 return(0);
1222 }
1223
1224 count = unit * 32; /* board # times max ports per card SG */
1225 for(i=count;i < (count + rp_num_ports[unit]);i++)
1226 minor_to_unit[i] = unit;
1227
1228 bzero(rp, sizeof(struct rp_port) * num_ports);
1229 tty = (struct tty *)
1230 malloc(sizeof(struct tty) * num_ports, M_TTYS, M_NOWAIT);
1231 if(tty == 0) {
1232 printf("rp_attach: Could not malloc tty structures\n");
1233 return(0);
1234 }
1235 bzero(tty, sizeof(struct tty) * num_ports);
1236
1237 oldspl = spltty();
1238 rp_addr(unit) = rp;
1239 splx(oldspl);
1240
1241 rp_dev = makedev(CDEV_MAJOR, unit);
1242 cdevsw_add(&rp_dev, &rp_cdevsw, NULL);
1243
1244 port = 0;
1245 for(aiop=0; aiop < num_aiops; aiop++) {
1246 num_chan = sGetAiopNumChan(ctlp, aiop);
1247 for(chan=0; chan < num_chan; chan++, port++, rp++, tty++) {
1248 rp->rp_tty = tty;
1249 rp->rp_port = port;
1250 rp->rp_ctlp = ctlp;
1251 rp->rp_unit = unit;
1252 rp->rp_chan = chan;
1253 rp->rp_aiop = aiop;
1254
1255 tty->t_line = 0;
1256 /* tty->t_termios = deftermios;
1257 */
1258 rp->dtr_wait = 3 * hz;
1259 rp->it_in.c_iflag = 0;
1260 rp->it_in.c_oflag = 0;
1261 rp->it_in.c_cflag = TTYDEF_CFLAG;
1262 rp->it_in.c_lflag = 0;
1263 termioschars(&rp->it_in);
1264 /* termioschars(&tty->t_termios);
1265 */
1266 rp->it_in.c_ispeed = rp->it_in.c_ospeed = TTYDEF_SPEED;
1267 rp->it_out = rp->it_in;
1268
1269 rp->rp_intmask = RXF_TRIG | TXFIFO_MT | SRC_INT |
1270 DELTA_CD | DELTA_CTS | DELTA_DSR;
1271 ChanStatus = sGetChanStatus(&rp->rp_channel);
1272 if(sInitChan(ctlp, &rp->rp_channel, aiop, chan) == 0) {
1273 printf("RocketPort sInitChan(%d, %d, %d) failed
1274 \n", unit, aiop, chan);
1275 return(0);
1276 }
1277 ChanStatus = sGetChanStatus(&rp->rp_channel);
1278 rp->rp_cts = (ChanStatus & CTS_ACT) != 0;
1279 line = (unit << 5) | (aiop << 3) | chan;
1280 rp_table(line) = rp;
1281 }
1282 }
1283
1284 return(1);
1285}
1286
1287int
1288rpopen(dev, flag, mode, p)
1289 dev_t dev;
1290 int flag, mode;
1291 struct proc *p;
1292{
1293 struct rp_port *rp;
1294 int unit, port, mynor, umynor, flags; /* SG */
1295 struct tty *tp;
1296 int oldspl, error;
1297 unsigned int IntMask, ChanStatus;
1298
1299
1300 umynor = (((minor(dev) >> 16) -1) * 32); /* SG */
1301 port = (minor(dev) & 0x1f); /* SG */
1302 mynor = (port + umynor); /* SG */
1303 unit = minor_to_unit[mynor];
1304 if(IS_CONTROL(dev))
1305 return(0);
1306 rp = rp_addr(unit) + port;
1307/* rp->rp_tty = &rp_tty[rp->rp_port];
1308*/
1309 tp = rp->rp_tty;
1310
1311 oldspl = spltty();
1312
1313open_top:
1314 while(rp->state & ~SET_DTR) {
1315 error = tsleep(&rp->dtr_wait, TTIPRI | PCATCH, "rpdtr", 0);
1316 if(error != 0)
1317 goto out;
1318 }
1319
1320 if(tp->t_state & TS_ISOPEN) {
1321 if(IS_CALLOUT(dev)) {
1322 if(!rp->active_out) {
1323 error = EBUSY;
1324 goto out;
1325 }
1326 } else {
1327 if(rp->active_out) {
1328 if(flag & O_NONBLOCK) {
1329 error = EBUSY;
1330 goto out;
1331 }
1332 error = tsleep(&rp->active_out,
1333 TTIPRI | PCATCH, "rpbi", 0);
1334 if(error != 0)
1335 goto out;
1336 goto open_top;
1337 }
1338 }
1339 if(tp->t_state & TS_XCLUDE &&
1340 suser(p)) {
1341 splx(oldspl);
1342 return(EBUSY);
1343 }
1344 }
1345 else {
1346 tp->t_dev = dev;
1347 tp->t_param = rpparam;
1348 tp->t_oproc = rpstart;
1349 tp->t_line = 0;
1350 tp->t_termios = IS_CALLOUT(dev) ? rp->it_out : rp->it_in;
1351 flags = 0;
1352 flags |= SET_RTS;
1353 flags |= SET_DTR;
1354 rp->rp_channel.TxControl[3] =
1355 ((rp->rp_channel.TxControl[3]
1356 & ~(SET_RTS | SET_DTR)) | flags);
1357 sOutDW(rp->rp_channel.IndexAddr,
1358 *(DWord_t *) &(rp->rp_channel.TxControl[0]));
1359 sSetRxTrigger(&rp->rp_channel, TRIG_1);
1360 sDisRxStatusMode(&rp->rp_channel);
1361 sFlushRxFIFO(&rp->rp_channel);
1362 sFlushTxFIFO(&rp->rp_channel);
1363
1364 sEnInterrupts(&rp->rp_channel,
1365 (TXINT_EN|MCINT_EN|RXINT_EN|SRCINT_EN|CHANINT_EN));
1366 sSetRxTrigger(&rp->rp_channel, TRIG_1);
1367
1368 sDisRxStatusMode(&rp->rp_channel);
1369 sClrTxXOFF(&rp->rp_channel);
1370
1371/* sDisRTSFlowCtl(&rp->rp_channel);
1372 sDisCTSFlowCtl(&rp->rp_channel);
1373*/
1374 sDisTxSoftFlowCtl(&rp->rp_channel);
1375
1376 sStartRxProcessor(&rp->rp_channel);
1377
1378 sEnRxFIFO(&rp->rp_channel);
1379 sEnTransmit(&rp->rp_channel);
1380
1381/* sSetDTR(&rp->rp_channel);
1382 sSetRTS(&rp->rp_channel);
1383*/
1384
1385 ++rp->wopeners;
1386 error = rpparam(tp, &tp->t_termios);
1387 --rp->wopeners;
1388 if(error != 0) {
1389 splx(oldspl);
1390 return(error);
1391 }
1392
1393 rp_num_ports_open++;
1394
1395 IntMask = sGetChanIntID(&rp->rp_channel);
1396 IntMask = IntMask & rp->rp_intmask;
1397 ChanStatus = sGetChanStatus(&rp->rp_channel);
1398 if((IntMask & DELTA_CD) || IS_CALLOUT(dev)) {
1399 if((ChanStatus & CD_ACT) || IS_CALLOUT(dev)) {
1400 (void)(*linesw[tp->t_line].l_modem)(tp, 1);
1401 }
1402 }
1403
1404 if(rp_num_ports_open == 1)
1405 timeout(rp_do_poll, (void *)NULL, POLL_INTERVAL);
1406
1407 }
1408
1409 if(!(flag&O_NONBLOCK) && !(tp->t_cflag&CLOCAL) &&
1410 !(tp->t_state & TS_CARR_ON) && !(IS_CALLOUT(dev))) {
1411 ++rp->wopeners;
1412 error = tsleep(TSA_CARR_ON(tp), TTIPRI | PCATCH,
1413 "rpdcd", 0);
1414 --rp->wopeners;
1415 if(error != 0)
1416 goto out;
1417 goto open_top;
1418 }
1419 error = (*linesw[tp->t_line].l_open)(dev, tp);
1420
1421 rp_disc_optim(tp, &tp->t_termios, rp);
1422 if(tp->t_state & TS_ISOPEN && IS_CALLOUT(dev))
1423 rp->active_out = TRUE;
1424
1425/* if(rp_num_ports_open == 1)
1426 timeout(rp_do_poll, (void *)NULL, POLL_INTERVAL);
1427*/
1428out:
1429 splx(oldspl);
1430 if(!(tp->t_state & TS_ISOPEN) && rp->wopeners == 0) {
1431 rphardclose(rp);
1432 }
1433 return(error);
1434}
1435
1436int
1437rpclose(dev, flag, mode, p)
1438 dev_t dev;
1439 int flag, mode;
1440 struct proc *p;
1441{
1442 int oldspl, unit, mynor, umynor, port; /* SG */
1443 struct rp_port *rp;
1444 struct tty *tp;
1445 CHANNEL_t *cp;
1446
1447 umynor = (((minor(dev) >> 16) -1) * 32); /* SG */
1448 port = (minor(dev) & 0x1f); /* SG */
1449 mynor = (port + umynor); /* SG */
1450 unit = minor_to_unit[mynor]; /* SG */
1451
1452 if(IS_CONTROL(dev))
1453 return(0);
1454 rp = rp_addr(unit) + port;
1455 cp = &rp->rp_channel;
1456 tp = rp->rp_tty;
1457
1458 oldspl = spltty();
1459 (*linesw[tp->t_line].l_close)(tp, flag);
1460 rp_disc_optim(tp, &tp->t_termios, rp);
1461 rpstop(tp, FREAD | FWRITE);
1462 rphardclose(rp);
1463
1464 tp->t_state &= ~TS_BUSY;
1465 ttyclose(tp);
1466
1467 splx(oldspl);
1468
1469 return(0);
1470}
1471
1472static void
1473rphardclose(struct rp_port *rp)
1474{
1475 int mynor;
1476 struct tty *tp;
1477 CHANNEL_t *cp;
1478
1479 cp = &rp->rp_channel;
1480 tp = rp->rp_tty;
1481 mynor = MINOR_MAGIC(tp->t_dev);
1482
1483 sFlushRxFIFO(cp);
1484 sFlushTxFIFO(cp);
1485 sDisTransmit(cp);
1486 sDisInterrupts(cp, TXINT_EN|MCINT_EN|RXINT_EN|SRCINT_EN|CHANINT_EN);
1487 sDisRTSFlowCtl(cp);
1488 sDisCTSFlowCtl(cp);
1489 sDisTxSoftFlowCtl(cp);
1490 sClrTxXOFF(cp);
1491
1492 if(tp->t_cflag&HUPCL || !(tp->t_state&TS_ISOPEN) || !rp->active_out) {
1493 sClrDTR(cp);
1494 }
1495 if(IS_CALLOUT(tp->t_dev)) {
1496 sClrDTR(cp);
1497 }
1498 if(rp->dtr_wait != 0) {
1499 timeout(rpdtrwakeup, rp, rp->dtr_wait);
1500 rp->state |= ~SET_DTR;
1501 }
1502
1503 rp->active_out = FALSE;
1504 wakeup(&rp->active_out);
1505 wakeup(TSA_CARR_ON(tp));
1506}
1507
1508static
1509int
1510rpread(dev, uio, flag)
1511 dev_t dev;
1512 struct uio *uio;
1513 int flag;
1514{
1515 struct rp_port *rp;
1516 struct tty *tp;
1517 int unit, mynor, umynor, port, error = 0; /* SG */
1518
1519 umynor = (((minor(dev) >> 16) -1) * 32); /* SG */
1520 port = (minor(dev) & 0x1f); /* SG */
1521 mynor = (port + umynor); /* SG */
1522 unit = minor_to_unit[mynor]; /* SG */
1523
1524 if(IS_CONTROL(dev))
1525 return(ENODEV);
1526 rp = rp_addr(unit) + port;
1527 tp = rp->rp_tty;
1528 error = (*linesw[tp->t_line].l_read)(tp, uio, flag);
1529 return(error);
1530}
1531
1532static
1533int
1534rpwrite(dev, uio, flag)
1535 dev_t dev;
1536 struct uio *uio;
1537 int flag;
1538{
1539 struct rp_port *rp;
1540 struct tty *tp;
1541 int unit, mynor, port, umynor, error = 0; /* SG */
1542
1543 umynor = (((minor(dev) >> 16) -1) * 32); /* SG */
1544 port = (minor(dev) & 0x1f); /* SG */
1545 mynor = (port + umynor); /* SG */
1546 unit = minor_to_unit[mynor]; /* SG */
1547
1548 if(IS_CONTROL(dev))
1549 return(ENODEV);
1550 rp = rp_addr(unit) + port;
1551 tp = rp->rp_tty;
1552 while(rp->rp_disable_writes) {
1553 rp->rp_waiting = 1;
1554 error = ttysleep(tp, (caddr_t)rp, TTOPRI|PCATCH, "rp_write", 0);
1555 if (error)
1556 return(error);
1557 }
1558
1559 error = (*linesw[tp->t_line].l_write)(tp, uio, flag);
1560 return error;
1561}
1562
1563static void
1564rpdtrwakeup(void *chan)
1565{
1566 struct rp_port *rp;
1567
1568 rp = (struct rp_port *)chan;
1569 rp->state &= SET_DTR;
1570 wakeup(&rp->dtr_wait);
1571}
1572
1573int
1574rpioctl(dev, cmd, data, flag, p)
1575 dev_t dev;
1576 u_long cmd;
1577 caddr_t data;
1578 int flag;
1579 struct proc *p;
1580{
1581 struct rp_port *rp;
1582 CHANNEL_t *cp;
1583 struct tty *tp;
1584 int unit, mynor, port, umynor; /* SG */
1585 int oldspl;
1586 int error = 0;
1587 int arg, flags, result, ChanStatus;
1588 int oldcmd;
1589 struct termios term, *t;
1590
1591 umynor = (((minor(dev) >> 16) -1) * 32); /* SG */
1592 port = (minor(dev) & 0x1f); /* SG */
1593 mynor = (port + umynor); /* SG */
1594 unit = minor_to_unit[mynor];
1595 rp = rp_addr(unit) + port;
1596
1597 if(IS_CONTROL(dev)) {
1598 struct termios *ct;
1599
1600 switch (IS_CONTROL(dev)) {
1601 case CONTROL_INIT_STATE:
1602 ct = IS_CALLOUT(dev) ? &rp->it_out : &rp->it_in;
1603 break;
1604 case CONTROL_LOCK_STATE:
1605 ct = IS_CALLOUT(dev) ? &rp->lt_out : &rp->lt_in;
1606 break;
1607 default:
1608 return(ENODEV); /* /dev/nodev */
1609 }
1610 switch (cmd) {
1611 case TIOCSETA:
1612 error = suser(p);
1613 if(error != 0)
1614 return(error);
1615 *ct = *(struct termios *)data;
1616 return(0);
1617 case TIOCGETA:
1618 *(struct termios *)data = *ct;
1619 return(0);
1620 case TIOCGETD:
1621 *(int *)data = TTYDISC;
1622 return(0);
1623 case TIOCGWINSZ:
1624 bzero(data, sizeof(struct winsize));
1625 return(0);
1626 default:
1627 return(ENOTTY);
1628 }
1629 }
1630
1631 tp = rp->rp_tty;
1632 cp = &rp->rp_channel;
1633
1634#if defined(COMPAT_43) || defined(COMPAT_SUNOS)
1635 term = tp->t_termios;
1636 oldcmd = cmd;
1637 error = ttsetcompat(tp, &cmd, data, &term);
1638 if(error != 0)
1639 return(error);
1640 if(cmd != oldcmd) {
1641 data = (caddr_t)&term;
1642 }
1643#endif
1644 if((cmd == TIOCSETA) || (cmd == TIOCSETAW) || (cmd == TIOCSETAF)) {
1645 int cc;
1646 struct termios *dt = (struct termios *)data;
1647 struct termios *lt = IS_CALLOUT(dev)
1648 ? &rp->lt_out : &rp->lt_in;
1649
1650 dt->c_iflag = (tp->t_iflag & lt->c_iflag)
1651 | (dt->c_iflag & ~lt->c_iflag);
1652 dt->c_oflag = (tp->t_oflag & lt->c_oflag)
1653 | (dt->c_oflag & ~lt->c_oflag);
1654 dt->c_cflag = (tp->t_cflag & lt->c_cflag)
1655 | (dt->c_cflag & ~lt->c_cflag);
1656 dt->c_lflag = (tp->t_lflag & lt->c_lflag)
1657 | (dt->c_lflag & ~lt->c_lflag);
1658 for(cc = 0; cc < NCCS; ++cc)
1659 if((lt->c_cc[cc] = tp->t_cc[cc]) != 0)
1660 dt->c_cc[cc] = tp->t_cc[cc];
1661 if(lt->c_ispeed != 0)
1662 dt->c_ispeed = tp->t_ispeed;
1663 if(lt->c_ospeed != 0)
1664 dt->c_ospeed = tp->t_ospeed;
1665 }
1666
1667 t = &tp->t_termios;
1668
1669 error = (*linesw[tp->t_line].l_ioctl)(tp, cmd, data, flag, p);
1670 if(error != ENOIOCTL) {
1671 return(error);
1672 }
1673 oldspl = spltty();
1674
1675 flags = rp->rp_channel.TxControl[3];
1676
1677 error = ttioctl(tp, cmd, data, flag);
1678 flags = rp->rp_channel.TxControl[3];
1679 rp_disc_optim(tp, &tp->t_termios, rp);
1680 if(error != ENOIOCTL) {
1681 splx(oldspl);
1682 return(error);
1683 }
1684 switch(cmd) {
1685 case TIOCSBRK:
1686 sSendBreak(&rp->rp_channel);
1687 break;
1688
1689 case TIOCCBRK:
1690 sClrBreak(&rp->rp_channel);
1691 break;
1692
1693 case TIOCSDTR:
1694 sSetDTR(&rp->rp_channel);
1695 sSetRTS(&rp->rp_channel);
1696 break;
1697
1698 case TIOCCDTR:
1699 sClrDTR(&rp->rp_channel);
1700 break;
1701
1702 case TIOCMSET:
1703 arg = *(int *) data;
1704 flags = 0;
1705 if(arg & TIOCM_RTS)
1706 flags |= SET_RTS;
1707 if(arg & TIOCM_DTR)
1708 flags |= SET_DTR;
1709 rp->rp_channel.TxControl[3] =
1710 ((rp->rp_channel.TxControl[3]
1711 & ~(SET_RTS | SET_DTR)) | flags);
1712 sOutDW(rp->rp_channel.IndexAddr,
1713 *(DWord_t *) &(rp->rp_channel.TxControl[0]));
1714 break;
1715 case TIOCMBIS:
1716 arg = *(int *) data;
1717 flags = 0;
1718 if(arg & TIOCM_RTS)
1719 flags |= SET_RTS;
1720 if(arg & TIOCM_DTR)
1721 flags |= SET_DTR;
1722 rp->rp_channel.TxControl[3] |= flags;
1723 sOutDW(rp->rp_channel.IndexAddr,
1724 *(DWord_t *) &(rp->rp_channel.TxControl[0]));
1725 break;
1726 case TIOCMBIC:
1727 arg = *(int *) data;
1728 flags = 0;
1729 if(arg & TIOCM_RTS)
1730 flags |= SET_RTS;
1731 if(arg & TIOCM_DTR)
1732 flags |= SET_DTR;
1733 rp->rp_channel.TxControl[3] &= ~flags;
1734 sOutDW(rp->rp_channel.IndexAddr,
1735 *(DWord_t *) &(rp->rp_channel.TxControl[0]));
1736 break;
1737
1738
1739 case TIOCMGET:
1740 ChanStatus = sGetChanStatusLo(&rp->rp_channel);
1741 flags = rp->rp_channel.TxControl[3];
1742 result = TIOCM_LE; /* always on while open for some reason */
1743 result |= (((flags & SET_DTR) ? TIOCM_DTR : 0)
1744 | ((flags & SET_RTS) ? TIOCM_RTS : 0)
1745 | ((ChanStatus & CD_ACT) ? TIOCM_CAR : 0)
1746 | ((ChanStatus & DSR_ACT) ? TIOCM_DSR : 0)
1747 | ((ChanStatus & CTS_ACT) ? TIOCM_CTS : 0));
1748
1749 if(rp->rp_channel.RxControl[2] & RTSFC_EN)
1750 {
1751 result |= TIOCM_RTS;
1752 }
1753
1754 *(int *)data = result;
1755 break;
1756 case TIOCMSDTRWAIT:
1757 error = suser(p);
1758 if(error != 0) {
1759 splx(oldspl);
1760 return(error);
1761 }
1762 rp->dtr_wait = *(int *)data * hz/100;
1763 break;
1764 case TIOCMGDTRWAIT:
1765 *(int *)data = rp->dtr_wait * 100/hz;
1766 break;
1767 default:
1768 splx(oldspl);
1769 return ENOTTY;
1770 }
1771 splx(oldspl);
1772 return(0);
1773}
1774
1775static struct speedtab baud_table[] = {
1776 B0, 0, B50, BRD50, B75, BRD75,
1777 B110, BRD110, B134, BRD134, B150, BRD150,
1778 B200, BRD200, B300, BRD300, B600, BRD600,
1779 B1200, BRD1200, B1800, BRD1800, B2400, BRD2400,
1780 B4800, BRD4800, B9600, BRD9600, B19200, BRD19200,
1781 B38400, BRD38400, B7200, BRD7200, B14400, BRD14400,
1782 B57600, BRD57600, B76800, BRD76800,
1783 B115200, BRD115200, B230400, BRD230400,
1784 -1, -1
1785};
1786
1787static int
1788rpparam(tp, t)
1789 struct tty *tp;
1790 struct termios *t;
1791{
1792 struct rp_port *rp;
1793 CHANNEL_t *cp;
1794 int unit, mynor, port, umynor; /* SG */
1795 int oldspl, cflag, iflag, oflag, lflag;
1796 int ospeed;
1797
1798
1799 umynor = (((minor(tp->t_dev) >> 16) -1) * 32); /* SG */
1800 port = (minor(tp->t_dev) & 0x1f); /* SG */
1801 mynor = (port + umynor); /* SG */
1802
1803 unit = minor_to_unit[mynor];
1804 rp = rp_addr(unit) + port;
1805 cp = &rp->rp_channel;
1806 oldspl = spltty();
1807
1808 cflag = t->c_cflag;
1809 iflag = t->c_iflag;
1810 oflag = t->c_oflag;
1811 lflag = t->c_lflag;
1812
1813 ospeed = ttspeedtab(t->c_ispeed, baud_table);
1814 if(ospeed < 0 || t->c_ispeed != t->c_ospeed)
1815 return(EINVAL);
1816
1817 tp->t_ispeed = t->c_ispeed;
1818 tp->t_ospeed = t->c_ospeed;
1819 tp->t_cflag = cflag;
1820 tp->t_iflag = iflag;
1821 tp->t_oflag = oflag;
1822 tp->t_lflag = lflag;
1823
1824 if(t->c_ospeed == 0) {
1825 sClrDTR(cp);
1826 return(0);
1827 }
1828 rp->rp_fifo_lw = ((t->c_ospeed*2) / 1000) +1;
1829
1830 /* Set baud rate ----- we only pay attention to ispeed */
1831 sSetDTR(cp);
1832 sSetRTS(cp);
1833 sSetBaud(cp, ospeed);
1834
1835 if(cflag & CSTOPB) {
1836 sSetStop2(cp);
1837 } else {
1838 sSetStop1(cp);
1839 }
1840
1841 if(cflag & PARENB) {
1842 sEnParity(cp);
1843 if(cflag & PARODD) {
1844 sSetOddParity(cp);
1845 } else {
1846 sSetEvenParity(cp);
1847 }
1848 }
1849 else {
1850 sDisParity(cp);
1851 }
1852 if((cflag & CSIZE) == CS8) {
1853 sSetData8(cp);
1854 rp->rp_imask = 0xFF;
1855 } else {
1856 sSetData7(cp);
1857 rp->rp_imask = 0x7F;
1858 }
1859
1860 if(iflag & ISTRIP) {
1861 rp->rp_imask &= 0x7F;
1862 }
1863
1864 if(cflag & CLOCAL) {
1865 rp->rp_intmask &= ~DELTA_CD;
1866 } else {
1867 rp->rp_intmask |= DELTA_CD;
1868 }
1869
1870 /* Put flow control stuff here */
1871
1872 if(cflag & CCTS_OFLOW) {
1873 sEnCTSFlowCtl(cp);
1874 } else {
1875 sDisCTSFlowCtl(cp);
1876 }
1877
1878 if(cflag & CRTS_IFLOW) {
1879 rp->rp_rts_iflow = 1;
1880 } else {
1881 rp->rp_rts_iflow = 0;
1882 }
1883
1884 if(cflag & CRTS_IFLOW) {
1885 sEnRTSFlowCtl(cp);
1886 } else {
1887 sDisRTSFlowCtl(cp);
1888 }
1889 rp_disc_optim(tp, t, rp);
1890
1891 if((cflag & CLOCAL) || (sGetChanStatusLo(cp) & CD_ACT)) {
1892 tp->t_state |= TS_CARR_ON;
1893 wakeup(TSA_CARR_ON(tp));
1894 }
1895
1896/* tp->t_state |= TS_CAN_BYPASS_L_RINT;
1897 flags = rp->rp_channel.TxControl[3];
1898 if(flags & SET_DTR)
1899 else
1900 if(flags & SET_RTS)
1901 else
1902*/
1903 splx(oldspl);
1904
1905 return(0);
1906}
1907
1908static void
1909rp_disc_optim(tp, t, rp)
1910struct tty *tp;
1911struct termios *t;
1912struct rp_port *rp;
1913{
1914 if(!(t->c_iflag & (ICRNL | IGNCR | IMAXBEL | INLCR | ISTRIP | IXON))
1915 &&(!(t->c_iflag & BRKINT) || (t->c_iflag & IGNBRK))
1916 &&(!(t->c_iflag & PARMRK)
1917 ||(t->c_iflag & (IGNPAR | IGNBRK)) == (IGNPAR | IGNBRK))
1918 && !(t->c_lflag & (ECHO | ICANON | IEXTEN | ISIG | PENDIN))
1919 && linesw[tp->t_line].l_rint == ttyinput)
1920 tp->t_state |= TS_CAN_BYPASS_L_RINT;
1921 else
1922 tp->t_state &= ~TS_CAN_BYPASS_L_RINT;
1923}
1924
1925static void
1926rpstart(tp)
1927 struct tty *tp;
1928{
1929 struct rp_port *rp;
1930 CHANNEL_t *cp;
1931 struct clist *qp;
1932 int unit, mynor, port, umynor; /* SG */
1933 char ch, flags;
1934 int spl, xmit_fifo_room;
1935 int count;
1936
1937
1938 umynor = (((minor(tp->t_dev) >> 16) -1) * 32); /* SG */
1939 port = (minor(tp->t_dev) & 0x1f); /* SG */
1940 mynor = (port + umynor); /* SG */
1941 unit = minor_to_unit[mynor];
1942 rp = rp_addr(unit) + port;
1943 cp = &rp->rp_channel;
1944 flags = rp->rp_channel.TxControl[3];
1945 spl = spltty();
1946
1947 if(tp->t_state & (TS_TIMEOUT | TS_TTSTOP)) {
1948 ttwwakeup(tp);
1949 splx(spl);
1950 return;
1951 }
1952 if(rp->rp_xmit_stopped) {
1953 sEnTransmit(cp);
1954 rp->rp_xmit_stopped = 0;
1955 }
1956 count = sGetTxCnt(cp);
1957
1958 if(tp->t_outq.c_cc == 0) {
1959 if((tp->t_state & TS_BUSY) && (count == 0)) {
1960 tp->t_state &= ~TS_BUSY;
1961 }
1962 ttwwakeup(tp);
1963 splx(spl);
1964 return;
1965 }
1966 xmit_fifo_room = TXFIFO_SIZE - sGetTxCnt(cp);
1967 qp = &tp->t_outq;
1968 count = 0;
1969 if(xmit_fifo_room > 0 && qp->c_cc > 0) {
1970 tp->t_state |= TS_BUSY;
1971 }
1972 while(xmit_fifo_room > 0 && qp->c_cc > 0) {
1973 ch = getc(qp);
1974 sOutB(sGetTxRxDataIO(cp), ch);
1975 xmit_fifo_room--;
1976 count++;
1977 }
1978 rp->rp_restart = (qp->c_cc > 0) ? rp->rp_fifo_lw : 0;
1979
1980 ttwwakeup(tp);
1981 splx(spl);
1982}
1983
1984static
1985void
1986rpstop(tp, flag)
1987 register struct tty *tp;
1988 int flag;
1989{
1990 struct rp_port *rp;
1991 CHANNEL_t *cp;
1992 int unit, mynor, port, umynor; /* SG */
1993 int spl;
1994
1995 umynor = (((minor(tp->t_dev) >> 16) -1) * 32); /* SG */
1996 port = (minor(tp->t_dev) & 0x1f); /* SG */
1997 mynor = (port + umynor); /* SG */
1998 unit = minor_to_unit[mynor];
1999 rp = rp_addr(unit) + port;
2000 cp = &rp->rp_channel;
2001
2002 spl = spltty();
2003
2004 if(tp->t_state & TS_BUSY) {
2005 if((tp->t_state&TS_TTSTOP) == 0) {
2006 sFlushTxFIFO(cp);
2007 } else {
2008 if(rp->rp_xmit_stopped == 0) {
2009 sDisTransmit(cp);
2010 rp->rp_xmit_stopped = 1;
2011 }
2012 }
2013 }
2014 splx(spl);
2015 rpstart(tp);
2016}
2017
2018int
2019rpselect(dev, flag, p)
2020 dev_t dev;
2021 int flag;
2022 struct proc *p;
2023{
2024 return(0);
2025}
2026
2027struct tty *
2028rpdevtotty(dev_t dev)
2029{
2030 struct rp_port *rp;
2031 int unit, port, mynor, umynor; /* SG */
2032
2033 umynor = (((minor(dev) >> 16) -1) * 32); /* SG */
2034 port = (minor(dev) & 0x1f); /* SG */
2035 mynor = (port + umynor); /* SG */
2036 unit = minor_to_unit[mynor]; /* SG */
2037
2038 if(IS_CONTROL(dev))
2039 return(NULL);
2040 rp = rp_addr(unit) + port;
2041 return(rp->rp_tty);
2042}