zs.c revision 1.51
1/* $NetBSD: zs.c,v 1.51 2006/10/01 20:31:50 elad Exp $ */ 2 3/* 4 * Copyright (c) 1992, 1993 5 * The Regents of the University of California. All rights reserved. 6 * 7 * This software was developed by the Computer Systems Engineering group 8 * at Lawrence Berkeley Laboratory under DARPA contract BG 91-66 and 9 * contributed to Berkeley. 10 * 11 * 12 * All advertising materials mentioning features or use of this software 13 * must display the following acknowledgement: 14 * This product includes software developed by the University of 15 * California, Lawrence Berkeley Laboratory. 16 * 17 * Redistribution and use in source and binary forms, with or without 18 * modification, are permitted provided that the following conditions 19 * are met: 20 * 1. Redistributions of source code must retain the above copyright 21 * notice, this list of conditions and the following disclaimer. 22 * 2. Redistributions in binary form must reproduce the above copyright 23 * notice, this list of conditions and the following disclaimer in the 24 * documentation and/or other materials provided with the distribution. 25 * 3. Neither the name of the University nor the names of its contributors 26 * may be used to endorse or promote products derived from this software 27 * without specific prior written permission. 28 * 29 * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND 30 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 31 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 32 * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE 33 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 34 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 35 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 36 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 37 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 38 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 39 * SUCH DAMAGE. 40 * 41 * @(#)zs.c 8.1 (Berkeley) 7/19/93 42 */ 43 44/*- 45 * Copyright (c) 1995 The NetBSD Foundation, Inc. (Atari modifications) 46 * All rights reserved. 47 * 48 * This code is derived from software contributed to The NetBSD Foundation 49 * by Leo Weppelman. 50 * 51 * Redistribution and use in source and binary forms, with or without 52 * modification, are permitted provided that the following conditions 53 * are met: 54 * 1. Redistributions of source code must retain the above copyright 55 * notice, this list of conditions and the following disclaimer. 56 * 2. Redistributions in binary form must reproduce the above copyright 57 * notice, this list of conditions and the following disclaimer in the 58 * documentation and/or other materials provided with the distribution. 59 * 3. Neither the name of The NetBSD Foundation nor the names of its 60 * contributors may be used to endorse or promote products derived 61 * from this software without specific prior written permission. 62 * 63 * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 64 * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 65 * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 66 * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 67 * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 68 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 69 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 70 * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 71 * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 72 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 73 * POSSIBILITY OF SUCH DAMAGE. 74 */ 75 76/* 77 * Zilog Z8530 (ZSCC) driver. 78 * 79 * Runs two tty ports (modem2 and serial2) on zs0. 80 * 81 * This driver knows far too much about chip to usage mappings. 82 */ 83 84#include <sys/cdefs.h> 85__KERNEL_RCSID(0, "$NetBSD: zs.c,v 1.51 2006/10/01 20:31:50 elad Exp $"); 86 87#include <sys/param.h> 88#include <sys/systm.h> 89#include <sys/proc.h> 90#include <sys/device.h> 91#include <sys/conf.h> 92#include <sys/file.h> 93#include <sys/ioctl.h> 94#include <sys/malloc.h> 95#include <sys/tty.h> 96#include <sys/time.h> 97#include <sys/kernel.h> 98#include <sys/syslog.h> 99#include <sys/kauth.h> 100 101#include <machine/cpu.h> 102#include <machine/iomap.h> 103#include <machine/scu.h> 104#include <machine/mfp.h> 105#include <atari/dev/ym2149reg.h> 106 107#include <dev/ic/z8530reg.h> 108#include <atari/dev/zsvar.h> 109#include "zs.h" 110#if NZS > 1 111#error "This driver supports only 1 85C30!" 112#endif 113 114#if NZS > 0 115 116#define PCLK (8053976) /* PCLK pin input clock rate */ 117#define PCLK_HD (9600 * 1536) /* PCLK on Hades pin input clock rate */ 118 119#define splzs spl5 120 121/* 122 * Software state per found chip. 123 */ 124struct zs_softc { 125 struct device zi_dev; /* base device */ 126 volatile struct zsdevice *zi_zs; /* chip registers */ 127 struct zs_chanstate zi_cs[2]; /* chan A and B software state */ 128}; 129 130static u_char cb_scheduled = 0; /* Already asked for callback? */ 131/* 132 * Define the registers for a closed port 133 */ 134static u_char zs_init_regs[16] = { 135/* 0 */ 0, 136/* 1 */ 0, 137/* 2 */ 0x60, 138/* 3 */ 0, 139/* 4 */ 0, 140/* 5 */ 0, 141/* 6 */ 0, 142/* 7 */ 0, 143/* 8 */ 0, 144/* 9 */ ZSWR9_MASTER_IE | ZSWR9_VECTOR_INCL_STAT, 145/* 10 */ ZSWR10_NRZ, 146/* 11 */ ZSWR11_TXCLK_BAUD | ZSWR11_RXCLK_BAUD, 147/* 12 */ 0, 148/* 13 */ 0, 149/* 14 */ ZSWR14_BAUD_FROM_PCLK | ZSWR14_BAUD_ENA, 150/* 15 */ 0 151}; 152 153/* 154 * Define the machine dependant clock frequencies 155 * If BRgen feeds sender/receiver we always use a 156 * divisor 16, therefor the division by 16 can as 157 * well be done here. 158 */ 159static u_long zs_freqs_tt[] = { 160 /* 161 * Atari TT, RTxCB is generated by TT-MFP timer C, 162 * which is set to 307.2 kHz during initialisation 163 * and never changed afterwards. 164 */ 165 PCLK/16, /* BRgen, PCLK, divisor 16 */ 166 229500, /* BRgen, RTxCA, divisor 16 */ 167 3672000, /* RTxCA, from PCLK4 */ 168 0, /* TRxCA, external */ 169 170 PCLK/16, /* BRgen, PCLK, divisor 16 */ 171 19200, /* BRgen, RTxCB, divisor 16 */ 172 307200, /* RTxCB, from TT-MFP TCO */ 173 2457600 /* TRxCB, from BCLK */ 174}; 175 176static u_long zs_freqs_falcon[] = { 177 /* 178 * Atari Falcon, XXX no specs available, this might be wrong 179 */ 180 PCLK/16, /* BRgen, PCLK, divisor 16 */ 181 229500, /* BRgen, RTxCA, divisor 16 */ 182 3672000, /* RTxCA, ??? */ 183 0, /* TRxCA, external */ 184 185 PCLK/16, /* BRgen, PCLK, divisor 16 */ 186 229500, /* BRgen, RTxCB, divisor 16 */ 187 3672000, /* RTxCB, ??? */ 188 2457600 /* TRxCB, ??? */ 189}; 190 191static u_long zs_freqs_hades[] = { 192 /* 193 * XXX: Channel-A unchecked!!!!! 194 */ 195 PCLK_HD/16, /* BRgen, PCLK, divisor 16 */ 196 229500, /* BRgen, RTxCA, divisor 16 */ 197 3672000, /* RTxCA, from PCLK4 */ 198 0, /* TRxCA, external */ 199 200 PCLK_HD/16, /* BRgen, PCLK, divisor 16 */ 201 235550, /* BRgen, RTxCB, divisor 16 */ 202 3768800, /* RTxCB, 3.7688MHz */ 203 3768800 /* TRxCB, 3.7688MHz */ 204}; 205 206static u_long zs_freqs_generic[] = { 207 /* 208 * other machines, assume only PCLK is available 209 */ 210 PCLK/16, /* BRgen, PCLK, divisor 16 */ 211 0, /* BRgen, RTxCA, divisor 16 */ 212 0, /* RTxCA, unknown */ 213 0, /* TRxCA, unknown */ 214 215 PCLK/16, /* BRgen, PCLK, divisor 16 */ 216 0, /* BRgen, RTxCB, divisor 16 */ 217 0, /* RTxCB, unknown */ 218 0 /* TRxCB, unknown */ 219}; 220static u_long *zs_frequencies; 221 222/* Definition of the driver for autoconfig. */ 223static int zsmatch __P((struct device *, struct cfdata *, void *)); 224static void zsattach __P((struct device *, struct device *, void *)); 225 226CFATTACH_DECL(zs, sizeof(struct zs_softc), 227 zsmatch, zsattach, NULL, NULL); 228 229extern struct cfdriver zs_cd; 230 231/* {b,c}devsw[] function prototypes */ 232dev_type_open(zsopen); 233dev_type_close(zsclose); 234dev_type_read(zsread); 235dev_type_write(zswrite); 236dev_type_ioctl(zsioctl); 237dev_type_stop(zsstop); 238dev_type_tty(zstty); 239dev_type_poll(zspoll); 240 241const struct cdevsw zs_cdevsw = { 242 zsopen, zsclose, zsread, zswrite, zsioctl, 243 zsstop, zstty, zspoll, nommap, ttykqfilter, D_TTY 244}; 245 246/* Interrupt handlers. */ 247int zshard __P((long)); 248static int zssoft __P((long)); 249static int zsrint __P((struct zs_chanstate *, volatile struct zschan *)); 250static int zsxint __P((struct zs_chanstate *, volatile struct zschan *)); 251static int zssint __P((struct zs_chanstate *, volatile struct zschan *)); 252 253static struct zs_chanstate *zslist; 254 255/* Routines called from other code. */ 256static void zsstart __P((struct tty *)); 257 258/* Routines purely local to this driver. */ 259static void zsoverrun __P((int, long *, const char *)); 260static int zsparam __P((struct tty *, struct termios *)); 261static int zsbaudrate __P((int, int, int *, int *, int *, int *)); 262static int zs_modem __P((struct zs_chanstate *, int, int)); 263static void zs_loadchannelregs __P((volatile struct zschan *, u_char *)); 264static void zs_shutdown __P((struct zs_chanstate *)); 265 266static int zsshortcuts; /* number of "shortcut" software interrupts */ 267 268static int 269zsmatch(pdp, cfp, auxp) 270struct device *pdp; 271struct cfdata *cfp; 272void *auxp; 273{ 274 static int zs_matched = 0; 275 276 if(strcmp("zs", auxp) || zs_matched) 277 return(0); 278 zs_matched = 1; 279 return(1); 280} 281 282/* 283 * Attach a found zs. 284 */ 285static void 286zsattach(parent, dev, aux) 287struct device *parent; 288struct device *dev; 289void *aux; 290{ 291 register struct zs_softc *zi; 292 register struct zs_chanstate *cs; 293 register volatile struct zsdevice *addr; 294 char tmp; 295 296 addr = (struct zsdevice *)AD_SCC; 297 zi = (struct zs_softc *)dev; 298 zi->zi_zs = addr; 299 cs = zi->zi_cs; 300 301 /* 302 * Get the command register into a known state. 303 */ 304 tmp = addr->zs_chan[ZS_CHAN_A].zc_csr; 305 tmp = addr->zs_chan[ZS_CHAN_A].zc_csr; 306 tmp = addr->zs_chan[ZS_CHAN_B].zc_csr; 307 tmp = addr->zs_chan[ZS_CHAN_B].zc_csr; 308 309 /* 310 * Do a hardware reset. 311 */ 312 ZS_WRITE(&addr->zs_chan[ZS_CHAN_A], 9, ZSWR9_HARD_RESET); 313 delay(50000); /*enough ? */ 314 ZS_WRITE(&addr->zs_chan[ZS_CHAN_A], 9, 0); 315 316 /* 317 * Initialize both channels 318 */ 319 zs_loadchannelregs(&addr->zs_chan[ZS_CHAN_A], zs_init_regs); 320 zs_loadchannelregs(&addr->zs_chan[ZS_CHAN_B], zs_init_regs); 321 322 if(machineid & ATARI_TT) { 323 /* 324 * ininitialise TT-MFP timer C: 307200Hz 325 * timer C and D share one control register: 326 * bits 0-2 control timer D 327 * bits 4-6 control timer C 328 */ 329 int cr = MFP2->mf_tcdcr & 7; 330 MFP2->mf_tcdcr = cr; /* stop timer C */ 331 MFP2->mf_tcdr = 1; /* counter 1 */ 332 cr |= T_Q004 << 4; /* divisor 4 */ 333 MFP2->mf_tcdcr = cr; /* start timer C */ 334 /* 335 * enable scc related interrupts 336 */ 337 SCU->vme_mask |= SCU_SCC; 338 339 zs_frequencies = zs_freqs_tt; 340 } else if (machineid & ATARI_FALCON) { 341 zs_frequencies = zs_freqs_falcon; 342 } else if (machineid & ATARI_HADES) { 343 zs_frequencies = zs_freqs_hades; 344 } else { 345 zs_frequencies = zs_freqs_generic; 346 } 347 348 /* link into interrupt list with order (A,B) (B=A+1) */ 349 cs[0].cs_next = &cs[1]; 350 cs[1].cs_next = zslist; 351 zslist = cs; 352 353 cs->cs_unit = 0; 354 cs->cs_zc = &addr->zs_chan[ZS_CHAN_A]; 355 cs++; 356 cs->cs_unit = 1; 357 cs->cs_zc = &addr->zs_chan[ZS_CHAN_B]; 358 359 printf(": serial2 on channel a and modem2 on channel b\n"); 360} 361 362/* 363 * Open a zs serial port. 364 */ 365int 366zsopen(dev, flags, mode, l) 367dev_t dev; 368int flags; 369int mode; 370struct lwp *l; 371{ 372 register struct tty *tp; 373 register struct zs_chanstate *cs; 374 struct zs_softc *zi; 375 int unit = ZS_UNIT(dev); 376 int zs = unit >> 1; 377 int error, s; 378 379 if(zs >= zs_cd.cd_ndevs || (zi = zs_cd.cd_devs[zs]) == NULL) 380 return (ENXIO); 381 cs = &zi->zi_cs[unit & 1]; 382 383 /* 384 * When port A (ser02) is selected on the TT, make sure 385 * the port is enabled. 386 */ 387 if((machineid & ATARI_TT) && !(unit & 1)) 388 ym2149_ser2(1); 389 390 if (cs->cs_rbuf == NULL) { 391 cs->cs_rbuf = malloc(ZLRB_RING_SIZE * sizeof(int), M_DEVBUF, 392 M_WAITOK); 393 } 394 395 tp = cs->cs_ttyp; 396 if(tp == NULL) { 397 cs->cs_ttyp = tp = ttymalloc(); 398 tty_attach(tp); 399 tp->t_dev = dev; 400 tp->t_oproc = zsstart; 401 tp->t_param = zsparam; 402 } 403 404 if (kauth_authorize_device_tty(l->l_cred, KAUTH_DEVICE_TTY_OPEN, tp)) 405 return (EBUSY); 406 407 s = spltty(); 408 409 /* 410 * Do the following iff this is a first open. 411 */ 412 if (!(tp->t_state & TS_ISOPEN) && tp->t_wopen == 0) { 413 if(tp->t_ispeed == 0) { 414 tp->t_iflag = TTYDEF_IFLAG; 415 tp->t_oflag = TTYDEF_OFLAG; 416 tp->t_cflag = TTYDEF_CFLAG; 417 tp->t_lflag = TTYDEF_LFLAG; 418 tp->t_ispeed = tp->t_ospeed = TTYDEF_SPEED; 419 } 420 ttychars(tp); 421 ttsetwater(tp); 422 423 (void)zsparam(tp, &tp->t_termios); 424 425 /* 426 * Turn on DTR. We must always do this, even if carrier is not 427 * present, because otherwise we'd have to use TIOCSDTR 428 * immediately after setting CLOCAL, which applications do not 429 * expect. We always assert DTR while the device is open 430 * unless explicitly requested to deassert it. 431 */ 432 zs_modem(cs, ZSWR5_RTS|ZSWR5_DTR, DMSET); 433 /* May never get a status intr. if DCD already on. -gwr */ 434 if((cs->cs_rr0 = cs->cs_zc->zc_csr) & ZSRR0_DCD) 435 tp->t_state |= TS_CARR_ON; 436 if(cs->cs_softcar) 437 tp->t_state |= TS_CARR_ON; 438 } 439 440 splx(s); 441 442 error = ttyopen(tp, ZS_DIALOUT(dev), (flags & O_NONBLOCK)); 443 if (error) 444 goto bad; 445 446 error = tp->t_linesw->l_open(dev, tp); 447 if(error) 448 goto bad; 449 return (0); 450 451bad: 452 if (!(tp->t_state & TS_ISOPEN) && tp->t_wopen == 0) { 453 /* 454 * We failed to open the device, and nobody else had it opened. 455 * Clean up the state as appropriate. 456 */ 457 zs_shutdown(cs); 458 } 459 return(error); 460} 461 462/* 463 * Close a zs serial port. 464 */ 465int 466zsclose(dev, flags, mode, l) 467dev_t dev; 468int flags; 469int mode; 470struct lwp *l; 471{ 472 register struct zs_chanstate *cs; 473 register struct tty *tp; 474 struct zs_softc *zi; 475 int unit = ZS_UNIT(dev); 476 477 zi = zs_cd.cd_devs[unit >> 1]; 478 cs = &zi->zi_cs[unit & 1]; 479 tp = cs->cs_ttyp; 480 481 tp->t_linesw->l_close(tp, flags); 482 ttyclose(tp); 483 484 if (!(tp->t_state & TS_ISOPEN) && tp->t_wopen == 0) { 485 /* 486 * Although we got a last close, the device may still be in 487 * use; e.g. if this was the dialout node, and there are still 488 * processes waiting for carrier on the non-dialout node. 489 */ 490 zs_shutdown(cs); 491 } 492 return (0); 493} 494 495/* 496 * Read/write zs serial port. 497 */ 498int 499zsread(dev, uio, flags) 500dev_t dev; 501struct uio *uio; 502int flags; 503{ 504 register struct zs_chanstate *cs; 505 register struct zs_softc *zi; 506 register struct tty *tp; 507 int unit; 508 509 unit = ZS_UNIT(dev); 510 zi = zs_cd.cd_devs[unit >> 1]; 511 cs = &zi->zi_cs[unit & 1]; 512 tp = cs->cs_ttyp; 513 514 return(tp->t_linesw->l_read(tp, uio, flags)); 515} 516 517int 518zswrite(dev, uio, flags) 519dev_t dev; 520struct uio *uio; 521int flags; 522{ 523 register struct zs_chanstate *cs; 524 register struct zs_softc *zi; 525 register struct tty *tp; 526 int unit; 527 528 unit = ZS_UNIT(dev); 529 zi = zs_cd.cd_devs[unit >> 1]; 530 cs = &zi->zi_cs[unit & 1]; 531 tp = cs->cs_ttyp; 532 533 return(tp->t_linesw->l_write(tp, uio, flags)); 534} 535 536int 537zspoll(dev, events, l) 538dev_t dev; 539int events; 540struct lwp *l; 541{ 542 register struct zs_chanstate *cs; 543 register struct zs_softc *zi; 544 register struct tty *tp; 545 int unit; 546 547 unit = ZS_UNIT(dev); 548 zi = zs_cd.cd_devs[unit >> 1]; 549 cs = &zi->zi_cs[unit & 1]; 550 tp = cs->cs_ttyp; 551 552 return ((*tp->t_linesw->l_poll)(tp, events, l)); 553} 554 555struct tty * 556zstty(dev) 557dev_t dev; 558{ 559 register struct zs_chanstate *cs; 560 register struct zs_softc *zi; 561 int unit; 562 563 unit = ZS_UNIT(dev); 564 zi = zs_cd.cd_devs[unit >> 1]; 565 cs = &zi->zi_cs[unit & 1]; 566 return(cs->cs_ttyp); 567} 568 569/* 570 * ZS hardware interrupt. Scan all ZS channels. NB: we know here that 571 * channels are kept in (A,B) pairs. 572 * 573 * Do just a little, then get out; set a software interrupt if more 574 * work is needed. 575 * 576 * We deliberately ignore the vectoring Zilog gives us, and match up 577 * only the number of `reset interrupt under service' operations, not 578 * the order. 579 */ 580 581int 582zshard(sr) 583long sr; 584{ 585 register struct zs_chanstate *a; 586#define b (a + 1) 587 register volatile struct zschan *zc; 588 register int rr3, intflags = 0, v, i; 589 590 do { 591 intflags &= ~4; 592 for(a = zslist; a != NULL; a = b->cs_next) { 593 rr3 = ZS_READ(a->cs_zc, 3); 594 if(rr3 & (ZSRR3_IP_A_RX|ZSRR3_IP_A_TX|ZSRR3_IP_A_STAT)) { 595 intflags |= 4|2; 596 zc = a->cs_zc; 597 i = a->cs_rbput; 598 if(rr3 & ZSRR3_IP_A_RX && (v = zsrint(a, zc)) != 0) { 599 a->cs_rbuf[i++ & ZLRB_RING_MASK] = v; 600 intflags |= 1; 601 } 602 if(rr3 & ZSRR3_IP_A_TX && (v = zsxint(a, zc)) != 0) { 603 a->cs_rbuf[i++ & ZLRB_RING_MASK] = v; 604 intflags |= 1; 605 } 606 if(rr3 & ZSRR3_IP_A_STAT && (v = zssint(a, zc)) != 0) { 607 a->cs_rbuf[i++ & ZLRB_RING_MASK] = v; 608 intflags |= 1; 609 } 610 a->cs_rbput = i; 611 } 612 if(rr3 & (ZSRR3_IP_B_RX|ZSRR3_IP_B_TX|ZSRR3_IP_B_STAT)) { 613 intflags |= 4|2; 614 zc = b->cs_zc; 615 i = b->cs_rbput; 616 if(rr3 & ZSRR3_IP_B_RX && (v = zsrint(b, zc)) != 0) { 617 b->cs_rbuf[i++ & ZLRB_RING_MASK] = v; 618 intflags |= 1; 619 } 620 if(rr3 & ZSRR3_IP_B_TX && (v = zsxint(b, zc)) != 0) { 621 b->cs_rbuf[i++ & ZLRB_RING_MASK] = v; 622 intflags |= 1; 623 } 624 if(rr3 & ZSRR3_IP_B_STAT && (v = zssint(b, zc)) != 0) { 625 b->cs_rbuf[i++ & ZLRB_RING_MASK] = v; 626 intflags |= 1; 627 } 628 b->cs_rbput = i; 629 } 630 } 631 } while(intflags & 4); 632#undef b 633 634 if(intflags & 1) { 635 if(BASEPRI(sr)) { 636 spl1(); 637 zsshortcuts++; 638 return(zssoft(sr)); 639 } 640 else if(!cb_scheduled) { 641 cb_scheduled++; 642 add_sicallback((si_farg)zssoft, 0, 0); 643 } 644 } 645 return(intflags & 2); 646} 647 648static int 649zsrint(cs, zc) 650register struct zs_chanstate *cs; 651register volatile struct zschan *zc; 652{ 653 register int c; 654 655 /* 656 * First read the status, because read of the received char 657 * destroy the status of this char. 658 */ 659 c = ZS_READ(zc, 1); 660 c |= (zc->zc_data << 8); 661 662 /* clear receive error & interrupt condition */ 663 zc->zc_csr = ZSWR0_RESET_ERRORS; 664 zc->zc_csr = ZSWR0_CLR_INTR; 665 666 return(ZRING_MAKE(ZRING_RINT, c)); 667} 668 669static int 670zsxint(cs, zc) 671register struct zs_chanstate *cs; 672register volatile struct zschan *zc; 673{ 674 register int i = cs->cs_tbc; 675 676 if(i == 0) { 677 zc->zc_csr = ZSWR0_RESET_TXINT; 678 zc->zc_csr = ZSWR0_CLR_INTR; 679 return(ZRING_MAKE(ZRING_XINT, 0)); 680 } 681 cs->cs_tbc = i - 1; 682 zc->zc_data = *cs->cs_tba++; 683 zc->zc_csr = ZSWR0_CLR_INTR; 684 return (0); 685} 686 687static int 688zssint(cs, zc) 689register struct zs_chanstate *cs; 690register volatile struct zschan *zc; 691{ 692 register int rr0; 693 694 rr0 = zc->zc_csr; 695 zc->zc_csr = ZSWR0_RESET_STATUS; 696 zc->zc_csr = ZSWR0_CLR_INTR; 697 /* 698 * The chip's hardware flow control is, as noted in zsreg.h, 699 * busted---if the DCD line goes low the chip shuts off the 700 * receiver (!). If we want hardware CTS flow control but do 701 * not have it, and carrier is now on, turn HFC on; if we have 702 * HFC now but carrier has gone low, turn it off. 703 */ 704 if(rr0 & ZSRR0_DCD) { 705 if(cs->cs_ttyp->t_cflag & CCTS_OFLOW && 706 (cs->cs_creg[3] & ZSWR3_HFC) == 0) { 707 cs->cs_creg[3] |= ZSWR3_HFC; 708 ZS_WRITE(zc, 3, cs->cs_creg[3]); 709 } 710 } 711 else { 712 if (cs->cs_creg[3] & ZSWR3_HFC) { 713 cs->cs_creg[3] &= ~ZSWR3_HFC; 714 ZS_WRITE(zc, 3, cs->cs_creg[3]); 715 } 716 } 717 return(ZRING_MAKE(ZRING_SINT, rr0)); 718} 719 720/* 721 * Print out a ring or fifo overrun error message. 722 */ 723static void 724zsoverrun(unit, ptime, what) 725int unit; 726long *ptime; 727const char *what; 728{ 729 730 if(*ptime != time.tv_sec) { 731 *ptime = time.tv_sec; 732 log(LOG_WARNING, "zs%d%c: %s overrun\n", unit >> 1, 733 (unit & 1) + 'a', what); 734 } 735} 736 737/* 738 * ZS software interrupt. Scan all channels for deferred interrupts. 739 */ 740int 741zssoft(sr) 742long sr; 743{ 744 register struct zs_chanstate *cs; 745 register volatile struct zschan *zc; 746 register struct linesw *line; 747 register struct tty *tp; 748 register int get, n, c, cc, unit, s; 749 int retval = 0; 750 751 cb_scheduled = 0; 752 s = spltty(); 753 for(cs = zslist; cs != NULL; cs = cs->cs_next) { 754 get = cs->cs_rbget; 755again: 756 n = cs->cs_rbput; /* atomic */ 757 if(get == n) /* nothing more on this line */ 758 continue; 759 retval = 1; 760 unit = cs->cs_unit; /* set up to handle interrupts */ 761 zc = cs->cs_zc; 762 tp = cs->cs_ttyp; 763 line = tp->t_linesw; 764 /* 765 * Compute the number of interrupts in the receive ring. 766 * If the count is overlarge, we lost some events, and 767 * must advance to the first valid one. It may get 768 * overwritten if more data are arriving, but this is 769 * too expensive to check and gains nothing (we already 770 * lost out; all we can do at this point is trade one 771 * kind of loss for another). 772 */ 773 n -= get; 774 if(n > ZLRB_RING_SIZE) { 775 zsoverrun(unit, &cs->cs_rotime, "ring"); 776 get += n - ZLRB_RING_SIZE; 777 n = ZLRB_RING_SIZE; 778 } 779 while(--n >= 0) { 780 /* race to keep ahead of incoming interrupts */ 781 c = cs->cs_rbuf[get++ & ZLRB_RING_MASK]; 782 switch (ZRING_TYPE(c)) { 783 784 case ZRING_RINT: 785 c = ZRING_VALUE(c); 786 if(c & ZSRR1_DO) 787 zsoverrun(unit, &cs->cs_fotime, "fifo"); 788 cc = c >> 8; 789 if(c & ZSRR1_FE) 790 cc |= TTY_FE; 791 if(c & ZSRR1_PE) 792 cc |= TTY_PE; 793 line->l_rint(cc, tp); 794 break; 795 796 case ZRING_XINT: 797 /* 798 * Transmit done: change registers and resume, 799 * or clear BUSY. 800 */ 801 if(cs->cs_heldchange) { 802 int sps; 803 804 sps = splzs(); 805 c = zc->zc_csr; 806 if((c & ZSRR0_DCD) == 0) 807 cs->cs_preg[3] &= ~ZSWR3_HFC; 808 bcopy((caddr_t)cs->cs_preg, 809 (caddr_t)cs->cs_creg, 16); 810 zs_loadchannelregs(zc, cs->cs_creg); 811 splx(sps); 812 cs->cs_heldchange = 0; 813 if(cs->cs_heldtbc 814 && (tp->t_state & TS_TTSTOP) == 0) { 815 cs->cs_tbc = cs->cs_heldtbc - 1; 816 zc->zc_data = *cs->cs_tba++; 817 goto again; 818 } 819 } 820 tp->t_state &= ~TS_BUSY; 821 if(tp->t_state & TS_FLUSH) 822 tp->t_state &= ~TS_FLUSH; 823 else ndflush(&tp->t_outq,cs->cs_tba 824 - (caddr_t)tp->t_outq.c_cf); 825 line->l_start(tp); 826 break; 827 828 case ZRING_SINT: 829 /* 830 * Status line change. HFC bit is run in 831 * hardware interrupt, to avoid locking 832 * at splzs here. 833 */ 834 c = ZRING_VALUE(c); 835 if((c ^ cs->cs_rr0) & ZSRR0_DCD) { 836 cc = (c & ZSRR0_DCD) != 0; 837 if(line->l_modem(tp, cc) == 0) 838 zs_modem(cs, ZSWR5_RTS|ZSWR5_DTR, 839 cc ? DMBIS : DMBIC); 840 } 841 cs->cs_rr0 = c; 842 break; 843 844 default: 845 log(LOG_ERR, "zs%d%c: bad ZRING_TYPE (%x)\n", 846 unit >> 1, (unit & 1) + 'a', c); 847 break; 848 } 849 } 850 cs->cs_rbget = get; 851 goto again; 852 } 853 splx(s); 854 return (retval); 855} 856 857int 858zsioctl(dev, cmd, data, flag, l) 859dev_t dev; 860u_long cmd; 861caddr_t data; 862int flag; 863struct lwp *l; 864{ 865 int unit = ZS_UNIT(dev); 866 struct zs_softc *zi = zs_cd.cd_devs[unit >> 1]; 867 register struct tty *tp = zi->zi_cs[unit & 1].cs_ttyp; 868 register int error, s; 869 register struct zs_chanstate *cs = &zi->zi_cs[unit & 1]; 870 871 error = tp->t_linesw->l_ioctl(tp, cmd, data, flag, l); 872 if(error != EPASSTHROUGH) 873 return(error); 874 875 error = ttioctl(tp, cmd, data, flag, l); 876 if(error !=EPASSTHROUGH) 877 return (error); 878 879 switch (cmd) { 880 case TIOCSBRK: 881 s = splzs(); 882 cs->cs_preg[5] |= ZSWR5_BREAK; 883 cs->cs_creg[5] |= ZSWR5_BREAK; 884 ZS_WRITE(cs->cs_zc, 5, cs->cs_creg[5]); 885 splx(s); 886 break; 887 case TIOCCBRK: 888 s = splzs(); 889 cs->cs_preg[5] &= ~ZSWR5_BREAK; 890 cs->cs_creg[5] &= ~ZSWR5_BREAK; 891 ZS_WRITE(cs->cs_zc, 5, cs->cs_creg[5]); 892 splx(s); 893 break; 894 case TIOCGFLAGS: { 895 int bits = 0; 896 897 if(cs->cs_softcar) 898 bits |= TIOCFLAG_SOFTCAR; 899 if(cs->cs_creg[15] & ZSWR15_DCD_IE) 900 bits |= TIOCFLAG_CLOCAL; 901 if(cs->cs_creg[3] & ZSWR3_HFC) 902 bits |= TIOCFLAG_CRTSCTS; 903 *(int *)data = bits; 904 break; 905 } 906 case TIOCSFLAGS: { 907 int userbits = 0; 908 909 error = kauth_authorize_device_tty(l->l_cred, 910 KAUTH_DEVICE_TTY_PRIVSET, tp); 911 if(error != 0) 912 return (EPERM); 913 914 userbits = *(int *)data; 915 916 /* 917 * can have `local' or `softcar', and `rtscts' or `mdmbuf' 918 # defaulting to software flow control. 919 */ 920 if(userbits & TIOCFLAG_SOFTCAR && userbits & TIOCFLAG_CLOCAL) 921 return(EINVAL); 922 if(userbits & TIOCFLAG_MDMBUF) /* don't support this (yet?) */ 923 return(ENODEV); 924 925 s = splzs(); 926 if((userbits & TIOCFLAG_SOFTCAR)) { 927 cs->cs_softcar = 1; /* turn on softcar */ 928 cs->cs_preg[15] &= ~ZSWR15_DCD_IE; /* turn off dcd */ 929 cs->cs_creg[15] &= ~ZSWR15_DCD_IE; 930 ZS_WRITE(cs->cs_zc, 15, cs->cs_creg[15]); 931 } 932 else if(userbits & TIOCFLAG_CLOCAL) { 933 cs->cs_softcar = 0; /* turn off softcar */ 934 cs->cs_preg[15] |= ZSWR15_DCD_IE; /* turn on dcd */ 935 cs->cs_creg[15] |= ZSWR15_DCD_IE; 936 ZS_WRITE(cs->cs_zc, 15, cs->cs_creg[15]); 937 tp->t_termios.c_cflag |= CLOCAL; 938 } 939 if(userbits & TIOCFLAG_CRTSCTS) { 940 cs->cs_preg[15] |= ZSWR15_CTS_IE; 941 cs->cs_creg[15] |= ZSWR15_CTS_IE; 942 ZS_WRITE(cs->cs_zc, 15, cs->cs_creg[15]); 943 cs->cs_preg[3] |= ZSWR3_HFC; 944 cs->cs_creg[3] |= ZSWR3_HFC; 945 ZS_WRITE(cs->cs_zc, 3, cs->cs_creg[3]); 946 tp->t_termios.c_cflag |= CRTSCTS; 947 } 948 else { 949 /* no mdmbuf, so we must want software flow control */ 950 cs->cs_preg[15] &= ~ZSWR15_CTS_IE; 951 cs->cs_creg[15] &= ~ZSWR15_CTS_IE; 952 ZS_WRITE(cs->cs_zc, 15, cs->cs_creg[15]); 953 cs->cs_preg[3] &= ~ZSWR3_HFC; 954 cs->cs_creg[3] &= ~ZSWR3_HFC; 955 ZS_WRITE(cs->cs_zc, 3, cs->cs_creg[3]); 956 tp->t_termios.c_cflag &= ~CRTSCTS; 957 } 958 splx(s); 959 break; 960 } 961 case TIOCSDTR: 962 zs_modem(cs, ZSWR5_DTR, DMBIS); 963 break; 964 case TIOCCDTR: 965 zs_modem(cs, ZSWR5_DTR, DMBIC); 966 break; 967 case TIOCMGET: 968 zs_modem(cs, 0, DMGET); 969 break; 970 case TIOCMSET: 971 case TIOCMBIS: 972 case TIOCMBIC: 973 default: 974 return (EPASSTHROUGH); 975 } 976 return (0); 977} 978 979/* 980 * Start or restart transmission. 981 */ 982static void 983zsstart(tp) 984register struct tty *tp; 985{ 986 register struct zs_chanstate *cs; 987 register int s, nch; 988 int unit = ZS_UNIT(tp->t_dev); 989 struct zs_softc *zi = zs_cd.cd_devs[unit >> 1]; 990 991 cs = &zi->zi_cs[unit & 1]; 992 s = spltty(); 993 994 /* 995 * If currently active or delaying, no need to do anything. 996 */ 997 if(tp->t_state & (TS_TIMEOUT | TS_BUSY | TS_TTSTOP)) 998 goto out; 999 1000 /* 1001 * If there are sleepers, and output has drained below low 1002 * water mark, awaken. 1003 */ 1004 if(tp->t_outq.c_cc <= tp->t_lowat) { 1005 if(tp->t_state & TS_ASLEEP) { 1006 tp->t_state &= ~TS_ASLEEP; 1007 wakeup((caddr_t)&tp->t_outq); 1008 } 1009 selwakeup(&tp->t_wsel); 1010 } 1011 1012 nch = ndqb(&tp->t_outq, 0); /* XXX */ 1013 if(nch) { 1014 register char *p = tp->t_outq.c_cf; 1015 1016 /* mark busy, enable tx done interrupts, & send first byte */ 1017 tp->t_state |= TS_BUSY; 1018 (void) splzs(); 1019 cs->cs_preg[1] |= ZSWR1_TIE; 1020 cs->cs_creg[1] |= ZSWR1_TIE; 1021 ZS_WRITE(cs->cs_zc, 1, cs->cs_creg[1]); 1022 cs->cs_zc->zc_data = *p; 1023 cs->cs_tba = p + 1; 1024 cs->cs_tbc = nch - 1; 1025 } else { 1026 /* 1027 * Nothing to send, turn off transmit done interrupts. 1028 * This is useful if something is doing polled output. 1029 */ 1030 (void) splzs(); 1031 cs->cs_preg[1] &= ~ZSWR1_TIE; 1032 cs->cs_creg[1] &= ~ZSWR1_TIE; 1033 ZS_WRITE(cs->cs_zc, 1, cs->cs_creg[1]); 1034 } 1035out: 1036 splx(s); 1037} 1038 1039/* 1040 * Stop output, e.g., for ^S or output flush. 1041 */ 1042void 1043zsstop(tp, flag) 1044register struct tty *tp; 1045 int flag; 1046{ 1047 register struct zs_chanstate *cs; 1048 register int s, unit = ZS_UNIT(tp->t_dev); 1049 struct zs_softc *zi = zs_cd.cd_devs[unit >> 1]; 1050 1051 cs = &zi->zi_cs[unit & 1]; 1052 s = splzs(); 1053 if(tp->t_state & TS_BUSY) { 1054 /* 1055 * Device is transmitting; must stop it. 1056 */ 1057 cs->cs_tbc = 0; 1058 if ((tp->t_state & TS_TTSTOP) == 0) 1059 tp->t_state |= TS_FLUSH; 1060 } 1061 splx(s); 1062} 1063 1064static void 1065zs_shutdown(cs) 1066 struct zs_chanstate *cs; 1067{ 1068 struct tty *tp = cs->cs_ttyp; 1069 int s; 1070 1071 s = splzs(); 1072 1073 /* 1074 * Hang up if necessary. Wait a bit, so the other side has time to 1075 * notice even if we immediately open the port again. 1076 */ 1077 if(tp->t_cflag & HUPCL) { 1078 zs_modem(cs, 0, DMSET); 1079 (void)tsleep((caddr_t)cs, TTIPRI, ttclos, hz); 1080 } 1081 1082 /* Clear any break condition set with TIOCSBRK. */ 1083 if(cs->cs_creg[5] & ZSWR5_BREAK) { 1084 cs->cs_preg[5] &= ~ZSWR5_BREAK; 1085 cs->cs_creg[5] &= ~ZSWR5_BREAK; 1086 ZS_WRITE(cs->cs_zc, 5, cs->cs_creg[5]); 1087 } 1088 1089 /* 1090 * Drop all lines and cancel interrupts 1091 */ 1092 zs_loadchannelregs(cs->cs_zc, zs_init_regs); 1093 splx(s); 1094} 1095 1096/* 1097 * Set ZS tty parameters from termios. 1098 * 1099 * This routine makes use of the fact that only registers 1100 * 1, 3, 4, 5, 9, 10, 11, 12, 13, 14, and 15 are written. 1101 */ 1102static int 1103zsparam(tp, t) 1104register struct tty *tp; 1105register struct termios *t; 1106{ 1107 int unit = ZS_UNIT(tp->t_dev); 1108 struct zs_softc *zi = zs_cd.cd_devs[unit >> 1]; 1109 register struct zs_chanstate *cs = &zi->zi_cs[unit & 1]; 1110 int cdiv = 0, /* XXX gcc4 -Wuninitialized */ 1111 clkm = 0, /* XXX gcc4 -Wuninitialized */ 1112 brgm = 0, /* XXX gcc4 -Wuninitialized */ 1113 tcon = 0; /* XXX gcc4 -Wuninitialized */ 1114 register int tmp, tmp5, cflag, s; 1115 1116 tmp = t->c_ospeed; 1117 tmp5 = t->c_ispeed; 1118 if(tmp < 0 || (tmp5 && tmp5 != tmp)) 1119 return(EINVAL); 1120 if(tmp == 0) { 1121 /* stty 0 => drop DTR and RTS */ 1122 zs_modem(cs, 0, DMSET); 1123 return(0); 1124 } 1125 tmp = zsbaudrate(unit, tmp, &cdiv, &clkm, &brgm, &tcon); 1126 if (tmp < 0) 1127 return(EINVAL); 1128 tp->t_ispeed = tp->t_ospeed = tmp; 1129 1130 cflag = tp->t_cflag = t->c_cflag; 1131 if (cflag & CSTOPB) 1132 cdiv |= ZSWR4_TWOSB; 1133 else 1134 cdiv |= ZSWR4_ONESB; 1135 if (!(cflag & PARODD)) 1136 cdiv |= ZSWR4_EVENP; 1137 if (cflag & PARENB) 1138 cdiv |= ZSWR4_PARENB; 1139 1140 switch(cflag & CSIZE) { 1141 case CS5: 1142 tmp = ZSWR3_RX_5; 1143 tmp5 = ZSWR5_TX_5; 1144 break; 1145 case CS6: 1146 tmp = ZSWR3_RX_6; 1147 tmp5 = ZSWR5_TX_6; 1148 break; 1149 case CS7: 1150 tmp = ZSWR3_RX_7; 1151 tmp5 = ZSWR5_TX_7; 1152 break; 1153 case CS8: 1154 default: 1155 tmp = ZSWR3_RX_8; 1156 tmp5 = ZSWR5_TX_8; 1157 break; 1158 } 1159 tmp |= ZSWR3_RX_ENABLE; 1160 tmp5 |= ZSWR5_TX_ENABLE | ZSWR5_DTR | ZSWR5_RTS; 1161 1162 /* 1163 * Block interrupts so that state will not 1164 * be altered until we are done setting it up. 1165 */ 1166 s = splzs(); 1167 cs->cs_preg[4] = cdiv; 1168 cs->cs_preg[11] = clkm; 1169 cs->cs_preg[12] = tcon; 1170 cs->cs_preg[13] = tcon >> 8; 1171 cs->cs_preg[14] = brgm; 1172 cs->cs_preg[1] = ZSWR1_RIE | ZSWR1_TIE | ZSWR1_SIE; 1173 cs->cs_preg[9] = ZSWR9_MASTER_IE | ZSWR9_VECTOR_INCL_STAT; 1174 cs->cs_preg[10] = ZSWR10_NRZ; 1175 cs->cs_preg[15] = ZSWR15_BREAK_IE | ZSWR15_DCD_IE; 1176 1177 /* 1178 * Output hardware flow control on the chip is horrendous: if 1179 * carrier detect drops, the receiver is disabled. Hence we 1180 * can only do this when the carrier is on. 1181 */ 1182 if(cflag & CCTS_OFLOW && cs->cs_zc->zc_csr & ZSRR0_DCD) 1183 tmp |= ZSWR3_HFC; 1184 cs->cs_preg[3] = tmp; 1185 cs->cs_preg[5] = tmp5; 1186 1187 /* 1188 * If nothing is being transmitted, set up new current values, 1189 * else mark them as pending. 1190 */ 1191 if(cs->cs_heldchange == 0) { 1192 if (cs->cs_ttyp->t_state & TS_BUSY) { 1193 cs->cs_heldtbc = cs->cs_tbc; 1194 cs->cs_tbc = 0; 1195 cs->cs_heldchange = 1; 1196 } else { 1197 bcopy((caddr_t)cs->cs_preg, (caddr_t)cs->cs_creg, 16); 1198 zs_loadchannelregs(cs->cs_zc, cs->cs_creg); 1199 } 1200 } 1201 splx(s); 1202 return (0); 1203} 1204 1205/* 1206 * search for the best matching baudrate 1207 */ 1208static int 1209zsbaudrate(unit, wanted, divisor, clockmode, brgenmode, timeconst) 1210int unit, wanted, *divisor, *clockmode, *brgenmode, *timeconst; 1211{ 1212 int bestdiff, bestbps, source; 1213 1214 bestdiff = bestbps = 0; 1215 unit = (unit & 1) << 2; 1216 for (source = 0; source < 4; ++source) { 1217 long freq = zs_frequencies[unit + source]; 1218 int diff, bps, div, clkm, brgm, tcon; 1219 1220 bps = div = clkm = brgm = tcon = 0; 1221 switch (source) { 1222 case 0: /* BRgen, PCLK */ 1223 brgm = ZSWR14_BAUD_ENA|ZSWR14_BAUD_FROM_PCLK; 1224 break; 1225 case 1: /* BRgen, RTxC */ 1226 brgm = ZSWR14_BAUD_ENA; 1227 break; 1228 case 2: /* RTxC */ 1229 clkm = ZSWR11_RXCLK_RTXC|ZSWR11_TXCLK_RTXC; 1230 break; 1231 case 3: /* TRxC */ 1232 clkm = ZSWR11_RXCLK_TRXC|ZSWR11_TXCLK_TRXC; 1233 break; 1234 } 1235 switch (source) { 1236 case 0: 1237 case 1: 1238 div = ZSWR4_CLK_X16; 1239 clkm = ZSWR11_RXCLK_BAUD|ZSWR11_TXCLK_BAUD; 1240 tcon = BPS_TO_TCONST(freq, wanted); 1241 if (tcon < 0) 1242 tcon = 0; 1243 bps = TCONST_TO_BPS(freq, tcon); 1244 break; 1245 case 2: 1246 case 3: 1247 { int b1 = freq / 16, d1 = abs(b1 - wanted); 1248 int b2 = freq / 32, d2 = abs(b2 - wanted); 1249 int b3 = freq / 64, d3 = abs(b3 - wanted); 1250 1251 if (d1 < d2 && d1 < d3) { 1252 div = ZSWR4_CLK_X16; 1253 bps = b1; 1254 } else if (d2 < d3 && d2 < d1) { 1255 div = ZSWR4_CLK_X32; 1256 bps = b2; 1257 } else { 1258 div = ZSWR4_CLK_X64; 1259 bps = b3; 1260 } 1261 brgm = tcon = 0; 1262 break; 1263 } 1264 } 1265 diff = abs(bps - wanted); 1266 if (!source || diff < bestdiff) { 1267 *divisor = div; 1268 *clockmode = clkm; 1269 *brgenmode = brgm; 1270 *timeconst = tcon; 1271 bestbps = bps; 1272 bestdiff = diff; 1273 if (diff == 0) 1274 break; 1275 } 1276 } 1277 /* Allow deviations upto 5% */ 1278 if (20 * bestdiff > wanted) 1279 return -1; 1280 return bestbps; 1281} 1282 1283/* 1284 * Raise or lower modem control (DTR/RTS) signals. If a character is 1285 * in transmission, the change is deferred. 1286 */ 1287static int 1288zs_modem(cs, bits, how) 1289struct zs_chanstate *cs; 1290int bits, how; 1291{ 1292 int s, mbits; 1293 1294 bits &= ZSWR5_DTR | ZSWR5_RTS; 1295 1296 s = splzs(); 1297 mbits = cs->cs_preg[5] & (ZSWR5_DTR | ZSWR5_RTS); 1298 1299 switch(how) { 1300 case DMSET: 1301 mbits = bits; 1302 break; 1303 case DMBIS: 1304 mbits |= bits; 1305 break; 1306 case DMBIC: 1307 mbits &= ~bits; 1308 break; 1309 case DMGET: 1310 splx(s); 1311 return(mbits); 1312 } 1313 1314 cs->cs_preg[5] = (cs->cs_preg[5] & ~(ZSWR5_DTR | ZSWR5_RTS)) | mbits; 1315 if(cs->cs_heldchange == 0) { 1316 if(cs->cs_ttyp->t_state & TS_BUSY) { 1317 cs->cs_heldtbc = cs->cs_tbc; 1318 cs->cs_tbc = 0; 1319 cs->cs_heldchange = 1; 1320 } 1321 else { 1322 ZS_WRITE(cs->cs_zc, 5, cs->cs_creg[5]); 1323 } 1324 } 1325 splx(s); 1326 return(0); 1327} 1328 1329/* 1330 * Write the given register set to the given zs channel in the proper order. 1331 * The channel must not be transmitting at the time. The receiver will 1332 * be disabled for the time it takes to write all the registers. 1333 */ 1334static void 1335zs_loadchannelregs(zc, reg) 1336volatile struct zschan *zc; 1337u_char *reg; 1338{ 1339 int i; 1340 1341 zc->zc_csr = ZSM_RESET_ERR; /* reset error condition */ 1342 i = zc->zc_data; /* drain fifo */ 1343 i = zc->zc_data; 1344 i = zc->zc_data; 1345 ZS_WRITE(zc, 4, reg[4]); 1346 ZS_WRITE(zc, 10, reg[10]); 1347 ZS_WRITE(zc, 3, reg[3] & ~ZSWR3_RX_ENABLE); 1348 ZS_WRITE(zc, 5, reg[5] & ~ZSWR5_TX_ENABLE); 1349 ZS_WRITE(zc, 1, reg[1]); 1350 ZS_WRITE(zc, 9, reg[9]); 1351 ZS_WRITE(zc, 11, reg[11]); 1352 ZS_WRITE(zc, 12, reg[12]); 1353 ZS_WRITE(zc, 13, reg[13]); 1354 ZS_WRITE(zc, 14, reg[14]); 1355 ZS_WRITE(zc, 15, reg[15]); 1356 ZS_WRITE(zc, 3, reg[3]); 1357 ZS_WRITE(zc, 5, reg[5]); 1358} 1359#endif /* NZS > 1 */ 1360