ite.c revision 1.8.2.1
1 1.8.2.1 cgd /* $NetBSD: ite.c,v 1.8.2.1 1998/10/13 21:51:58 cgd Exp $ */ 2 1.1 oki 3 1.1 oki /* 4 1.1 oki * Copyright (c) 1988 University of Utah. 5 1.1 oki * Copyright (c) 1990 The Regents of the University of California. 6 1.1 oki * All rights reserved. 7 1.1 oki * 8 1.1 oki * This code is derived from software contributed to Berkeley by 9 1.1 oki * the Systems Programming Group of the University of Utah Computer 10 1.1 oki * Science Department. 11 1.1 oki * 12 1.1 oki * Redistribution and use in source and binary forms, with or without 13 1.1 oki * modification, are permitted provided that the following conditions 14 1.1 oki * are met: 15 1.1 oki * 1. Redistributions of source code must retain the above copyright 16 1.1 oki * notice, this list of conditions and the following disclaimer. 17 1.1 oki * 2. Redistributions in binary form must reproduce the above copyright 18 1.1 oki * notice, this list of conditions and the following disclaimer in the 19 1.1 oki * documentation and/or other materials provided with the distribution. 20 1.1 oki * 3. All advertising materials mentioning features or use of this software 21 1.1 oki * must display the following acknowledgement: 22 1.1 oki * This product includes software developed by the University of 23 1.1 oki * California, Berkeley and its contributors. 24 1.1 oki * 4. Neither the name of the University nor the names of its contributors 25 1.1 oki * may be used to endorse or promote products derived from this software 26 1.1 oki * without specific prior written permission. 27 1.1 oki * 28 1.1 oki * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND 29 1.1 oki * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 30 1.1 oki * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 31 1.1 oki * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE 32 1.1 oki * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 33 1.1 oki * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 34 1.1 oki * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 35 1.1 oki * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 36 1.1 oki * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 37 1.1 oki * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 38 1.1 oki * SUCH DAMAGE. 39 1.1 oki * 40 1.1 oki * from: Utah $Hdr: ite.c 1.1 90/07/09$ 41 1.1 oki * 42 1.1 oki * @(#)ite.c 7.6 (Berkeley) 5/16/91 43 1.1 oki */ 44 1.1 oki 45 1.1 oki /* 46 1.1 oki * ite - bitmaped terminal. 47 1.1 oki * Supports VT200, a few terminal features will be unavailable until 48 1.1 oki * the system actually probes the device (i.e. not after consinit()) 49 1.1 oki */ 50 1.1 oki 51 1.1 oki #include "ite.h" 52 1.1 oki #if NITE > 0 53 1.1 oki 54 1.1 oki #include "bell.h" 55 1.1 oki 56 1.1 oki #include <sys/param.h> 57 1.1 oki #include <sys/conf.h> 58 1.1 oki #include <sys/proc.h> 59 1.1 oki #include <sys/ioctl.h> 60 1.1 oki #include <sys/tty.h> 61 1.1 oki #include <sys/systm.h> 62 1.1 oki #include <sys/device.h> 63 1.1 oki #include <sys/malloc.h> 64 1.1 oki #include <machine/kbio.h> 65 1.1 oki 66 1.1 oki #include <x68k/dev/grfioctl.h> 67 1.1 oki #include <x68k/dev/grfvar.h> 68 1.1 oki #include <x68k/dev/itevar.h> 69 1.1 oki #include <x68k/dev/kbdmap.h> 70 1.1 oki 71 1.1 oki #include <x68k/x68k/iodevice.h> 72 1.1 oki #include <x68k/dev/iteioctl.h> 73 1.1 oki 74 1.1 oki #define SUBR_CNPROBE(min) itesw[min].ite_cnprobe(min) 75 1.1 oki #define SUBR_INIT(ip) ip->isw->ite_init(ip) 76 1.1 oki #define SUBR_DEINIT(ip) ip->isw->ite_deinit(ip) 77 1.1 oki #define SUBR_PUTC(ip,c,dy,dx,m) ip->isw->ite_putc(ip,c,dy,dx,m) 78 1.1 oki #define SUBR_CURSOR(ip,flg) ip->isw->ite_cursor(ip,flg) 79 1.1 oki #define SUBR_CLEAR(ip,sy,sx,h,w) ip->isw->ite_clear(ip,sy,sx,h,w) 80 1.1 oki #define SUBR_SCROLL(ip,sy,sx,count,dir) \ 81 1.1 oki ip->isw->ite_scroll(ip,sy,sx,count,dir) 82 1.1 oki 83 1.1 oki struct consdev; 84 1.1 oki 85 1.8 oki __inline static void itesendch __P((int)); 86 1.8 oki __inline static void alignment_display __P((struct ite_softc *)); 87 1.8 oki __inline static void snap_cury __P((struct ite_softc *)); 88 1.8 oki __inline static void ite_dnchar __P((struct ite_softc *, int)); 89 1.8 oki static void ite_inchar __P((struct ite_softc *, int)); 90 1.8 oki __inline static void ite_clrtoeol __P((struct ite_softc *)); 91 1.8 oki __inline static void ite_clrtobol __P((struct ite_softc *)); 92 1.8 oki __inline static void ite_clrline __P((struct ite_softc *)); 93 1.8 oki __inline static void ite_clrtoeos __P((struct ite_softc *)); 94 1.8 oki __inline static void ite_clrtobos __P((struct ite_softc *)); 95 1.8 oki __inline static void ite_clrscreen __P((struct ite_softc *)); 96 1.8 oki __inline static void ite_dnline __P((struct ite_softc *, int)); 97 1.8 oki __inline static void ite_inline __P((struct ite_softc *, int)); 98 1.8 oki __inline static void ite_index __P((struct ite_softc *)); 99 1.8 oki __inline static void ite_lf __P((struct ite_softc *)); 100 1.8 oki __inline static void ite_crlf __P((struct ite_softc *)); 101 1.8 oki __inline static void ite_cr __P((struct ite_softc *)); 102 1.8 oki __inline static void ite_rlf __P((struct ite_softc *)); 103 1.1 oki static void iteprecheckwrap __P((struct ite_softc *ip)); 104 1.1 oki static void itecheckwrap __P((struct ite_softc *ip)); 105 1.1 oki static void repeat_handler __P((void *arg)); 106 1.1 oki static int ite_argnum __P((struct ite_softc *ip)); 107 1.1 oki static int ite_zargnum __P((struct ite_softc *ip)); 108 1.1 oki static void ite_sendstr __P((struct ite_softc *ip, char *str)); 109 1.8 oki __inline static int atoi __P((const char *cp)); 110 1.8 oki __inline static char *index __P((const char *cp, char ch)); 111 1.1 oki void ite_reset __P((struct ite_softc *ip)); 112 1.8 oki struct ite_softc *getitesp __P((dev_t)); 113 1.8 oki int iteon __P((dev_t, int)); 114 1.8 oki void iteoff __P((dev_t, int)); 115 1.1 oki 116 1.1 oki struct itesw itesw[] = { 117 1.7 oki 0, tv_init, tv_deinit, 0, 118 1.1 oki 0, 0, 0, 119 1.1 oki }; 120 1.1 oki int nitesw = sizeof(itesw) / sizeof(itesw[0]); 121 1.1 oki 122 1.1 oki /* 123 1.1 oki * # of chars are output in a single itestart() call. 124 1.1 oki * If this is too big, user processes will be blocked out for 125 1.1 oki * long periods of time while we are emptying the queue in itestart(). 126 1.1 oki * If it is too small, console output will be very ragged. 127 1.1 oki */ 128 1.1 oki #define ITEBURST 64 129 1.1 oki 130 1.1 oki int nite = NITE; 131 1.1 oki struct tty *ite_tty[NITE]; 132 1.1 oki struct ite_softc *kbd_ite = NULL; 133 1.1 oki struct ite_softc con_itesoftc; 134 1.1 oki 135 1.1 oki struct tty *kbd_tty = NULL; 136 1.1 oki 137 1.1 oki int start_repeat_timeo = 20; /* /100: initial timeout till pressed key repeats */ 138 1.1 oki int next_repeat_timeo = 3; /* /100: timeout when repeating for next char */ 139 1.1 oki 140 1.1 oki u_char cons_tabs[MAX_TABS]; 141 1.1 oki 142 1.1 oki int kbd_init; 143 1.1 oki 144 1.8 oki cdev_decl(ite); 145 1.8 oki 146 1.1 oki void itestart __P((struct tty *tp)); 147 1.1 oki 148 1.1 oki void iteputchar __P((int c, struct ite_softc *ip)); 149 1.1 oki void ite_putstr __P((const u_char * s, int len, dev_t dev)); 150 1.1 oki 151 1.1 oki void iteattach __P((struct device *, struct device *, void *)); 152 1.1 oki int itematch __P((struct device *, void *, void *)); 153 1.1 oki 154 1.1 oki struct cfattach ite_ca = { 155 1.1 oki sizeof(struct ite_softc), itematch, iteattach 156 1.1 oki }; 157 1.1 oki 158 1.1 oki struct cfdriver ite_cd = { 159 1.1 oki NULL, "ite", DV_DULL, NULL, 0 160 1.1 oki }; 161 1.1 oki 162 1.1 oki int 163 1.1 oki itematch(pdp, match, auxp) 164 1.1 oki struct device *pdp; 165 1.1 oki void *match, *auxp; 166 1.1 oki { 167 1.1 oki struct cfdata *cdp = match; 168 1.1 oki struct grf_softc *gp; 169 1.1 oki int maj; 170 1.1 oki 171 1.1 oki gp = auxp; 172 1.1 oki 173 1.1 oki /* ite0 should be at grf0 XXX */ 174 1.1 oki if(cdp->cf_unit != gp->g_device.dv_unit) 175 1.1 oki return(0); 176 1.1 oki 177 1.1 oki #if 0 178 1.1 oki /* 179 1.1 oki * all that our mask allows (more than enough no one 180 1.1 oki * has > 32 monitors for text consoles on one machine) 181 1.1 oki */ 182 1.1 oki if (cdp->cf_unit >= sizeof(ite_confunits) * NBBY) 183 1.1 oki return(0); 184 1.1 oki /* 185 1.1 oki * XXX 186 1.1 oki * normally this would be done in attach, however 187 1.1 oki * during early init we do not have a device pointer 188 1.1 oki * and thus no unit number. 189 1.1 oki */ 190 1.1 oki for(maj = 0; maj < nchrdev; maj++) 191 1.1 oki if (cdevsw[maj].d_open == iteopen) 192 1.1 oki break; 193 1.1 oki gp->g_itedev = makedev(maj, cdp->cf_unit); 194 1.1 oki #endif 195 1.1 oki return(1); 196 1.1 oki } 197 1.1 oki 198 1.1 oki /* 199 1.1 oki * iteinit() is the standard entry point for initialization of 200 1.1 oki * an ite device, it is also called from ite_cninit(). 201 1.1 oki */ 202 1.1 oki void 203 1.1 oki iteattach(pdp, dp, auxp) 204 1.1 oki struct device *pdp, *dp; 205 1.1 oki void *auxp; 206 1.1 oki { 207 1.1 oki struct ite_softc *ip; 208 1.1 oki struct grf_softc *gp; 209 1.1 oki 210 1.1 oki gp = (struct grf_softc *)auxp; 211 1.1 oki if (dp) { 212 1.1 oki ip = (struct ite_softc *)dp; 213 1.1 oki if(con_itesoftc.grf != NULL 214 1.1 oki /*&& con_itesoftc.grf->g_unit == gp->g_unit*/) { 215 1.1 oki /* 216 1.1 oki * console reinit copy params over. 217 1.1 oki * and console always gets keyboard 218 1.1 oki */ 219 1.1 oki bcopy(&con_itesoftc.grf, &ip->grf, 220 1.1 oki (char *)&ip[1] - (char *)&ip->grf); 221 1.1 oki con_itesoftc.grf = NULL; 222 1.1 oki kbd_ite = ip; 223 1.1 oki } 224 1.1 oki ip->grf = gp; 225 1.1 oki iteinit(ip->device.dv_unit); /* XXX */ 226 1.6 christos printf(": rows %d cols %d", ip->rows, ip->cols); 227 1.1 oki if (kbd_ite == NULL) 228 1.1 oki kbd_ite = ip; 229 1.6 christos printf("\n"); 230 1.1 oki } else { 231 1.1 oki if (con_itesoftc.grf != NULL) 232 1.1 oki return; 233 1.1 oki con_itesoftc.grf = gp; 234 1.1 oki con_itesoftc.tabs = cons_tabs; 235 1.1 oki } 236 1.1 oki } 237 1.1 oki 238 1.1 oki struct ite_softc * 239 1.1 oki getitesp(dev) 240 1.1 oki dev_t dev; 241 1.1 oki { 242 1.1 oki extern int x68k_realconfig; 243 1.1 oki 244 1.1 oki if (x68k_realconfig && con_itesoftc.grf == NULL) 245 1.1 oki return(ite_cd.cd_devs[UNIT(dev)]); 246 1.1 oki 247 1.1 oki if (con_itesoftc.grf == NULL) 248 1.1 oki panic("no ite_softc for console"); 249 1.1 oki return(&con_itesoftc); 250 1.1 oki } 251 1.1 oki 252 1.1 oki void 253 1.1 oki iteinit(dev) 254 1.1 oki dev_t dev; 255 1.1 oki { 256 1.1 oki struct ite_softc *ip; 257 1.1 oki 258 1.1 oki ip = getitesp(dev); 259 1.1 oki 260 1.1 oki if (ip->flags & ITE_INITED) 261 1.1 oki return; 262 1.1 oki bcopy(&ascii_kbdmap, &kbdmap, sizeof(struct kbdmap)); 263 1.1 oki 264 1.1 oki ip->curx = 0; 265 1.1 oki ip->cury = 0; 266 1.1 oki ip->cursorx = 0; 267 1.1 oki ip->cursory = 0; 268 1.1 oki 269 1.1 oki ip->isw = &itesw[ip->device.dv_unit]; /* XXX */ 270 1.1 oki SUBR_INIT(ip); 271 1.1 oki SUBR_CURSOR(ip, DRAW_CURSOR); 272 1.1 oki if (!ip->tabs) 273 1.1 oki ip->tabs = malloc(MAX_TABS*sizeof(u_char), M_DEVBUF, M_WAITOK); 274 1.1 oki ite_reset(ip); 275 1.1 oki ip->flags |= ITE_INITED; 276 1.1 oki } 277 1.1 oki 278 1.1 oki /* 279 1.1 oki * Perform functions necessary to setup device as a terminal emulator. 280 1.1 oki */ 281 1.2 oki int 282 1.1 oki iteon(dev, flag) 283 1.1 oki dev_t dev; 284 1.1 oki int flag; 285 1.1 oki { 286 1.1 oki int unit = UNIT(dev); 287 1.8.2.1 cgd struct ite_softc *ip; 288 1.1 oki 289 1.8.2.1 cgd if (unit >= ite_cd.cd_ndevs || 290 1.8.2.1 cgd (ip = getitesp(unit)) == NULL || (ip->flags&ITE_ALIVE) == 0) 291 1.1 oki return(ENXIO); 292 1.1 oki /* force ite active, overriding graphics mode */ 293 1.1 oki if (flag & 1) { 294 1.1 oki ip->flags |= ITE_ACTIVE; 295 1.1 oki ip->flags &= ~(ITE_INGRF|ITE_INITED); 296 1.1 oki } 297 1.1 oki /* leave graphics mode */ 298 1.1 oki if (flag & 2) { 299 1.1 oki ip->flags &= ~ITE_INGRF; 300 1.1 oki if ((ip->flags & ITE_ACTIVE) == 0) 301 1.1 oki return(0); 302 1.1 oki } 303 1.1 oki ip->flags |= ITE_ACTIVE; 304 1.1 oki if (ip->flags & ITE_INGRF) 305 1.1 oki return(0); 306 1.1 oki iteinit(dev); 307 1.1 oki return(0); 308 1.1 oki } 309 1.1 oki 310 1.1 oki /* 311 1.1 oki * "Shut down" device as terminal emulator. 312 1.1 oki * Note that we do not deinit the console device unless forced. 313 1.1 oki * Deinit'ing the console every time leads to a very active 314 1.1 oki * screen when processing /etc/rc. 315 1.1 oki */ 316 1.2 oki void 317 1.1 oki iteoff(dev, flag) 318 1.1 oki dev_t dev; 319 1.1 oki int flag; 320 1.1 oki { 321 1.4 oki int unit = UNIT(dev); 322 1.8.2.1 cgd register struct ite_softc *ip; 323 1.1 oki 324 1.4 oki /* XXX check whether when call from grf.c */ 325 1.8.2.1 cgd if (unit >= ite_cd.cd_ndevs || 326 1.8.2.1 cgd (ip = getitesp(unit)) == NULL || (ip->flags&ITE_ALIVE) == 0) 327 1.4 oki return; 328 1.1 oki if (flag & 2) 329 1.1 oki ip->flags |= ITE_INGRF; 330 1.1 oki 331 1.1 oki if ((ip->flags & ITE_ACTIVE) == 0) 332 1.1 oki return; 333 1.1 oki if ((flag & 1) || 334 1.1 oki (ip->flags & (ITE_INGRF|ITE_ISCONS|ITE_INITED)) == ITE_INITED) 335 1.1 oki SUBR_DEINIT(ip); 336 1.1 oki 337 1.1 oki /* 338 1.1 oki * XXX When the system is rebooted with "reboot", init(8) 339 1.1 oki * kills the last process to have the console open. 340 1.1 oki * If we don't revent the the ITE_ACTIVE bit from being 341 1.1 oki * cleared, we will never see messages printed during 342 1.1 oki * the process of rebooting. 343 1.1 oki */ 344 1.1 oki if ((flag & 2) == 0 && (ip->flags & ITE_ISCONS) == 0) 345 1.1 oki ip->flags &= ~ITE_ACTIVE; 346 1.1 oki } 347 1.1 oki 348 1.1 oki /* 349 1.1 oki * standard entry points to the device. 350 1.1 oki */ 351 1.1 oki 352 1.1 oki /* ARGSUSED */ 353 1.1 oki int 354 1.1 oki iteopen(dev, mode, devtype, p) 355 1.1 oki dev_t dev; 356 1.1 oki int mode, devtype; 357 1.1 oki struct proc *p; 358 1.1 oki { 359 1.1 oki int unit = UNIT(dev); 360 1.1 oki register struct tty *tp; 361 1.1 oki register struct ite_softc *ip; 362 1.1 oki register int error; 363 1.1 oki int first = 0; 364 1.1 oki 365 1.8.2.1 cgd if (unit >= ite_cd.cd_ndevs || (ip = getitesp(dev)) == NULL) 366 1.8.2.1 cgd return (ENXIO); 367 1.3 oki if (!ite_tty[unit]) { 368 1.1 oki tp = ite_tty[unit] = ttymalloc(); 369 1.3 oki tty_attach(tp); 370 1.3 oki } else 371 1.1 oki tp = ite_tty[unit]; 372 1.1 oki if ((tp->t_state&(TS_ISOPEN|TS_XCLUDE)) == (TS_ISOPEN|TS_XCLUDE) 373 1.1 oki && p->p_ucred->cr_uid != 0) 374 1.1 oki return (EBUSY); 375 1.1 oki if ((ip->flags & ITE_ACTIVE) == 0) { 376 1.1 oki error = iteon(dev, 0); 377 1.1 oki if (error) 378 1.1 oki return (error); 379 1.1 oki first = 1; 380 1.1 oki } 381 1.1 oki tp->t_oproc = itestart; 382 1.1 oki tp->t_param = NULL; 383 1.1 oki tp->t_dev = dev; 384 1.1 oki if ((tp->t_state&TS_ISOPEN) == 0) { 385 1.1 oki ttychars(tp); 386 1.1 oki tp->t_iflag = TTYDEF_IFLAG; 387 1.1 oki tp->t_oflag = TTYDEF_OFLAG; 388 1.1 oki tp->t_cflag = TTYDEF_CFLAG; 389 1.1 oki tp->t_lflag = TTYDEF_LFLAG; 390 1.1 oki tp->t_ispeed = tp->t_ospeed = TTYDEF_SPEED; 391 1.1 oki tp->t_state = TS_ISOPEN|TS_CARR_ON; 392 1.1 oki ttsetwater(tp); 393 1.1 oki } 394 1.1 oki error = (*linesw[tp->t_line].l_open)(dev, tp); 395 1.1 oki if (error == 0) { 396 1.1 oki tp->t_winsize.ws_row = ip->rows; 397 1.1 oki tp->t_winsize.ws_col = ip->cols; 398 1.1 oki if (!kbd_init) { 399 1.1 oki kbd_init = 1; 400 1.1 oki kbdenable(); 401 1.1 oki } 402 1.1 oki } else if (first) 403 1.1 oki iteoff(dev, 0); 404 1.1 oki return (error); 405 1.1 oki } 406 1.1 oki 407 1.1 oki /*ARGSUSED*/ 408 1.1 oki int 409 1.1 oki iteclose(dev, flag, mode, p) 410 1.1 oki dev_t dev; 411 1.1 oki int flag, mode; 412 1.1 oki struct proc *p; 413 1.1 oki { 414 1.1 oki register struct tty *tp = ite_tty[UNIT(dev)]; 415 1.1 oki 416 1.1 oki (*linesw[tp->t_line].l_close)(tp, flag); 417 1.1 oki ttyclose(tp); 418 1.1 oki iteoff(dev, 0); 419 1.1 oki #if 0 420 1.1 oki ttyfree(tp); 421 1.1 oki ite_tty[UNIT(dev)] = (struct tty *)0; 422 1.1 oki #endif 423 1.1 oki return(0); 424 1.1 oki } 425 1.1 oki 426 1.1 oki int 427 1.1 oki iteread(dev, uio, flag) 428 1.1 oki dev_t dev; 429 1.1 oki struct uio *uio; 430 1.1 oki int flag; 431 1.1 oki { 432 1.1 oki register struct tty *tp = ite_tty[UNIT(dev)]; 433 1.1 oki 434 1.1 oki return ((*linesw[tp->t_line].l_read)(tp, uio, flag)); 435 1.1 oki } 436 1.1 oki 437 1.1 oki int 438 1.1 oki itewrite(dev, uio, flag) 439 1.1 oki dev_t dev; 440 1.1 oki struct uio *uio; 441 1.1 oki int flag; 442 1.1 oki { 443 1.1 oki register struct tty *tp = ite_tty[UNIT(dev)]; 444 1.1 oki 445 1.1 oki return ((*linesw[tp->t_line].l_write)(tp, uio, flag)); 446 1.1 oki } 447 1.1 oki 448 1.1 oki struct tty * 449 1.1 oki itetty(dev) 450 1.1 oki dev_t dev; 451 1.1 oki { 452 1.1 oki 453 1.1 oki return (ite_tty[UNIT(dev)]); 454 1.1 oki } 455 1.1 oki 456 1.1 oki int 457 1.1 oki iteioctl(dev, cmd, addr, flag, p) 458 1.1 oki dev_t dev; 459 1.1 oki u_long cmd; 460 1.1 oki caddr_t addr; 461 1.1 oki int flag; 462 1.1 oki struct proc *p; 463 1.1 oki { 464 1.1 oki struct iterepeat *irp; 465 1.1 oki register struct tty *tp = ite_tty[UNIT(dev)]; 466 1.1 oki int error; 467 1.1 oki 468 1.1 oki error = (*linesw[tp->t_line].l_ioctl)(tp, cmd, addr, flag, p); 469 1.1 oki if (error >= 0) 470 1.1 oki return (error); 471 1.1 oki error = ttioctl(tp, cmd, addr, flag, p); 472 1.1 oki if (error >= 0) 473 1.1 oki return (error); 474 1.1 oki 475 1.1 oki switch (cmd) { 476 1.1 oki case ITEIOCSKMAP: 477 1.1 oki if (addr == 0) 478 1.1 oki return(EFAULT); 479 1.1 oki bcopy(addr, &kbdmap, sizeof(struct kbdmap)); 480 1.1 oki return(0); 481 1.1 oki 482 1.1 oki case ITEIOCGKMAP: 483 1.1 oki if (addr == NULL) 484 1.1 oki return(EFAULT); 485 1.1 oki bcopy(&kbdmap, addr, sizeof(struct kbdmap)); 486 1.1 oki return(0); 487 1.1 oki 488 1.1 oki case ITEIOCGREPT: 489 1.1 oki irp = (struct iterepeat *)addr; 490 1.1 oki irp->start = start_repeat_timeo; 491 1.1 oki irp->next = next_repeat_timeo; 492 1.1 oki 493 1.1 oki case ITEIOCSREPT: 494 1.1 oki irp = (struct iterepeat *)addr; 495 1.1 oki if (irp->start < ITEMINREPEAT && irp->next < ITEMINREPEAT) 496 1.1 oki return(EINVAL); 497 1.1 oki start_repeat_timeo = irp->start; 498 1.1 oki next_repeat_timeo = irp->next; 499 1.1 oki #if x68k 500 1.1 oki case ITELOADFONT: 501 1.1 oki if (addr) { 502 1.1 oki bcopy(addr, kern_font, 4096 /*sizeof (kernel_font)*/); 503 1.1 oki return 0; 504 1.1 oki } else 505 1.1 oki return EFAULT; 506 1.1 oki 507 1.1 oki case ITETVCTRL: 508 1.1 oki if (addr && *(u_char *)addr < 0x40) { 509 1.1 oki while(!(mfp.tsr & 0x80)) ; 510 1.1 oki mfp.udr = *(u_char *)addr; 511 1.1 oki return 0; 512 1.1 oki } else 513 1.1 oki return EFAULT; 514 1.1 oki #endif 515 1.1 oki } 516 1.1 oki return (ENOTTY); 517 1.1 oki } 518 1.1 oki 519 1.1 oki void 520 1.1 oki itestart(tp) 521 1.1 oki register struct tty *tp; 522 1.1 oki { 523 1.1 oki struct clist *rbp; 524 1.1 oki struct ite_softc *ip; 525 1.1 oki u_char buf[ITEBURST]; 526 1.1 oki int s, len, n; 527 1.1 oki 528 1.1 oki ip = getitesp(tp->t_dev); 529 1.1 oki /* 530 1.1 oki * (Potentially) lower priority. We only need to protect ourselves 531 1.1 oki * from keyboard interrupts since that is all that can affect the 532 1.6 christos * state of our tty (kernel printf doesn't go through this routine). 533 1.1 oki */ 534 1.1 oki s = spltty(); 535 1.1 oki if (tp->t_state & (TS_TIMEOUT | TS_BUSY | TS_TTSTOP)) 536 1.1 oki goto out; 537 1.1 oki tp->t_state |= TS_BUSY; 538 1.1 oki rbp = &tp->t_outq; 539 1.1 oki len = q_to_b(rbp, buf, ITEBURST); 540 1.1 oki /*splx(s);*/ 541 1.1 oki 542 1.1 oki /* Here is a really good place to implement pre/jumpscroll() */ 543 1.1 oki ite_putstr(buf, len, tp->t_dev); 544 1.1 oki 545 1.1 oki /*s = spltty();*/ 546 1.1 oki tp->t_state &= ~TS_BUSY; 547 1.1 oki /* we have characters remaining. */ 548 1.1 oki if (rbp->c_cc) { 549 1.1 oki tp->t_state |= TS_TIMEOUT; 550 1.1 oki timeout(ttrstrt, (caddr_t)tp, 1); 551 1.1 oki } 552 1.1 oki /* wakeup we are below */ 553 1.1 oki if (rbp->c_cc <= tp->t_lowat) { 554 1.1 oki if (tp->t_state & TS_ASLEEP) { 555 1.1 oki tp->t_state &= ~TS_ASLEEP; 556 1.1 oki wakeup((caddr_t)rbp); 557 1.1 oki } 558 1.1 oki selwakeup(&tp->t_wsel); 559 1.1 oki } 560 1.1 oki out: 561 1.1 oki splx(s); 562 1.1 oki } 563 1.1 oki 564 1.1 oki /* XXX called after changes made in underlying grf layer. */ 565 1.1 oki /* I want to nuke this */ 566 1.1 oki void 567 1.1 oki ite_reinit(dev) 568 1.1 oki dev_t dev; 569 1.1 oki { 570 1.1 oki struct ite_softc *ip; 571 1.4 oki int unit = UNIT(dev); 572 1.4 oki 573 1.4 oki /* XXX check whether when call from grf.c */ 574 1.8.2.1 cgd if (unit >= ite_cd.cd_ndevs || (ip = getitesp(unit)) == NULL) 575 1.4 oki return; 576 1.1 oki 577 1.1 oki ip->flags &= ~ITE_INITED; 578 1.1 oki iteinit(dev); 579 1.1 oki } 580 1.1 oki 581 1.1 oki void 582 1.1 oki ite_reset(ip) 583 1.1 oki struct ite_softc *ip; 584 1.1 oki { 585 1.1 oki int i; 586 1.1 oki 587 1.1 oki ip->curx = 0; 588 1.1 oki ip->cury = 0; 589 1.1 oki ip->attribute = 0; 590 1.1 oki ip->save_curx = 0; 591 1.1 oki ip->save_cury = 0; 592 1.1 oki ip->save_attribute = 0; 593 1.1 oki ip->ap = ip->argbuf; 594 1.1 oki ip->emul_level = EMUL_VT300_8; 595 1.1 oki ip->eightbit_C1 = 0; 596 1.1 oki ip->top_margin = 0; 597 1.1 oki ip->bottom_margin = ip->rows - 1; 598 1.1 oki ip->inside_margins = 0; /* origin mode == absolute */ 599 1.1 oki ip->linefeed_newline = 0; 600 1.1 oki ip->auto_wrap = 1; 601 1.1 oki ip->cursor_appmode = 0; 602 1.1 oki ip->keypad_appmode = 0; 603 1.1 oki ip->imode = 0; 604 1.1 oki ip->key_repeat = 1; 605 1.1 oki ip->G0 = CSET_ASCII; 606 1.1 oki ip->G1 = CSET_JIS1983; 607 1.1 oki ip->G2 = CSET_JISKANA; 608 1.1 oki ip->G3 = CSET_JIS1990; 609 1.1 oki ip->GL = &ip->G0; 610 1.1 oki ip->GR = &ip->G1; 611 1.1 oki ip->save_GL = 0; 612 1.1 oki ip->save_char = 0; 613 1.1 oki ip->fgcolor = 7; 614 1.1 oki ip->bgcolor = 0; 615 1.1 oki for (i = 0; i < ip->cols; i++) 616 1.1 oki ip->tabs[i] = ((i & 7) == 0); 617 1.1 oki /* XXX clear screen */ 618 1.1 oki SUBR_CLEAR(ip, 0, 0, ip->rows, ip->cols); 619 1.1 oki attrclr(ip, 0, 0, ip->rows, ip->cols); 620 1.1 oki } 621 1.1 oki 622 1.1 oki /* Used in console at startup only */ 623 1.1 oki int 624 1.8 oki ite_cnfilter(c, caller) 625 1.1 oki u_char c; 626 1.1 oki enum caller caller; 627 1.1 oki { 628 1.1 oki struct tty *kbd_tty; 629 1.1 oki static u_char mod = 0; 630 1.1 oki struct key key; 631 1.1 oki u_char code, up, mask; 632 1.1 oki int s, i; 633 1.1 oki 634 1.1 oki up = c & 0x80 ? 1 : 0; 635 1.1 oki c &= 0x7f; 636 1.1 oki code = 0; 637 1.1 oki 638 1.1 oki s = spltty(); 639 1.1 oki 640 1.1 oki mask = 0; 641 1.1 oki if (c >= KBD_LEFT_ALT && !(c >= 0x63 && c <= 0x6c)) { /* 0x63: F1, 0x6c:F10 */ 642 1.1 oki switch (c) { 643 1.1 oki case KBD_LEFT_SHIFT: 644 1.1 oki mask = KBD_MOD_SHIFT; 645 1.1 oki break; 646 1.1 oki 647 1.1 oki case KBD_LEFT_ALT: 648 1.1 oki mask = KBD_MOD_LALT; 649 1.1 oki break; 650 1.1 oki 651 1.1 oki case KBD_RIGHT_ALT: 652 1.1 oki mask = KBD_MOD_RALT; 653 1.1 oki break; 654 1.1 oki 655 1.1 oki case KBD_LEFT_META: 656 1.1 oki mask = KBD_MOD_LMETA; 657 1.1 oki break; 658 1.1 oki 659 1.1 oki case KBD_RIGHT_META: 660 1.1 oki mask = KBD_MOD_RMETA; 661 1.1 oki break; 662 1.1 oki 663 1.1 oki case KBD_CAPS_LOCK: 664 1.1 oki /* 665 1.1 oki * capslock already behaves `right', don't need to 666 1.1 oki * keep track of the state in here. 667 1.1 oki */ 668 1.1 oki mask = KBD_MOD_CAPS; 669 1.1 oki break; 670 1.1 oki 671 1.1 oki case KBD_CTRL: 672 1.1 oki mask = KBD_MOD_CTRL; 673 1.1 oki break; 674 1.1 oki 675 1.1 oki case KBD_RECONNECT: 676 1.1 oki /* ite got 0xff */ 677 1.1 oki if (up) 678 1.1 oki kbd_setLED(); 679 1.1 oki break; 680 1.1 oki } 681 1.1 oki if (mask & KBD_MOD_CAPS) { 682 1.1 oki if (!up) { 683 1.1 oki mod ^= KBD_MOD_CAPS; 684 1.1 oki kbdled ^= LED_CAPS_LOCK; 685 1.1 oki kbd_setLED(); 686 1.1 oki } 687 1.1 oki } else if (up) 688 1.1 oki mod &= ~mask; 689 1.1 oki else mod |= mask; 690 1.1 oki splx (s); 691 1.1 oki return -1; 692 1.1 oki } 693 1.1 oki 694 1.1 oki if (up) { 695 1.1 oki splx(s); 696 1.1 oki return -1; 697 1.1 oki } 698 1.1 oki 699 1.1 oki /* translate modifiers */ 700 1.1 oki if (mod & KBD_MOD_SHIFT) { 701 1.1 oki if (mod & KBD_MOD_ALT) 702 1.1 oki key = kbdmap.alt_shift_keys[c]; 703 1.1 oki else 704 1.1 oki key = kbdmap.shift_keys[c]; 705 1.1 oki } else if (mod & KBD_MOD_ALT) 706 1.1 oki key = kbdmap.alt_keys[c]; 707 1.1 oki else { 708 1.1 oki key = kbdmap.keys[c]; 709 1.1 oki /* if CAPS and key is CAPable (no pun intended) */ 710 1.1 oki if ((mod & KBD_MOD_CAPS) && (key.mode & KBD_MODE_CAPS)) 711 1.1 oki key = kbdmap.shift_keys[c]; 712 1.1 oki } 713 1.1 oki code = key.code; 714 1.1 oki 715 1.1 oki /* if string return */ 716 1.1 oki if (key.mode & (KBD_MODE_STRING | KBD_MODE_KPAD)) { 717 1.1 oki splx(s); 718 1.1 oki return -1; 719 1.1 oki } 720 1.1 oki /* handle dead keys */ 721 1.1 oki if (key.mode & KBD_MODE_DEAD) { 722 1.1 oki splx(s); 723 1.1 oki return -1; 724 1.1 oki } 725 1.1 oki if (mod & KBD_MOD_CTRL) 726 1.1 oki code &= 0x1f; 727 1.1 oki if (mod & KBD_MOD_META) 728 1.1 oki code |= 0x80; 729 1.1 oki 730 1.1 oki /* do console mapping. */ 731 1.1 oki code = code == '\r' ? '\n' : code; 732 1.1 oki 733 1.1 oki splx(s); 734 1.1 oki return (code); 735 1.1 oki } 736 1.1 oki 737 1.1 oki /* And now the old stuff. */ 738 1.1 oki 739 1.1 oki /* these are used to implement repeating keys.. */ 740 1.1 oki static u_char last_char = 0; 741 1.1 oki static u_char tout_pending = 0; 742 1.1 oki 743 1.1 oki /*ARGSUSED*/ 744 1.1 oki static void 745 1.1 oki repeat_handler (arg) 746 1.1 oki void *arg; 747 1.1 oki { 748 1.1 oki tout_pending = 0; 749 1.1 oki if (last_char) 750 1.1 oki add_sicallback(ite_filter, last_char, ITEFILT_REPEATER); 751 1.1 oki } 752 1.1 oki 753 1.8 oki __inline static void 754 1.1 oki itesendch (ch) 755 1.1 oki int ch; 756 1.1 oki { 757 1.1 oki (*linesw[kbd_tty->t_line].l_rint)(ch, kbd_tty); 758 1.1 oki } 759 1.1 oki 760 1.1 oki 761 1.1 oki void 762 1.1 oki ite_filter(c, caller) 763 1.1 oki u_char c; 764 1.1 oki enum caller caller; 765 1.1 oki { 766 1.1 oki static u_short mod = 0; 767 1.1 oki register unsigned char code, *str; 768 1.1 oki u_short up, mask; 769 1.1 oki struct key key; 770 1.1 oki int s, i; 771 1.1 oki 772 1.1 oki if (!kbd_ite) 773 1.1 oki return; 774 1.1 oki kbd_tty = ite_tty[kbd_ite->device.dv_unit]; 775 1.1 oki 776 1.1 oki /* have to make sure we're at spltty in here */ 777 1.1 oki s = spltty (); 778 1.1 oki 779 1.1 oki #if 0 /* XXX? x68k */ 780 1.1 oki /* keyboard interrupts come at priority 2, while softint- 781 1.1 oki generated keyboard-repeat interrupts come at level 1. 782 1.1 oki So, to not allow a key-up event to get thru before 783 1.1 oki a repeat for the key-down, we remove any outstanding 784 1.1 oki callout requests.. */ 785 1.1 oki rem_sicallback (ite_filter); 786 1.1 oki #endif 787 1.1 oki 788 1.1 oki up = c & 0x80 ? 1 : 0; 789 1.1 oki c &= 0x7f; 790 1.1 oki code = 0; 791 1.1 oki 792 1.1 oki mask = 0; 793 1.1 oki if (c >= KBD_LEFT_ALT && 794 1.1 oki !(c >= 0x63 && c <= 0x6c)) { /* 0x63: F1, 0x6c:F10 */ 795 1.1 oki switch (c) { 796 1.1 oki case KBD_LEFT_SHIFT: 797 1.1 oki mask = KBD_MOD_SHIFT; 798 1.1 oki break; 799 1.1 oki 800 1.1 oki case KBD_LEFT_ALT: 801 1.1 oki mask = KBD_MOD_LALT; 802 1.1 oki break; 803 1.1 oki 804 1.1 oki case KBD_RIGHT_ALT: 805 1.1 oki mask = KBD_MOD_RALT; 806 1.1 oki break; 807 1.1 oki 808 1.1 oki case KBD_LEFT_META: 809 1.1 oki mask = KBD_MOD_LMETA; 810 1.1 oki break; 811 1.1 oki 812 1.1 oki case KBD_RIGHT_META: 813 1.1 oki mask = KBD_MOD_RMETA; 814 1.1 oki break; 815 1.1 oki 816 1.1 oki case KBD_CAPS_LOCK: 817 1.1 oki /* 818 1.1 oki * capslock already behaves `right', don't need to keep 819 1.1 oki * track of the state in here. 820 1.1 oki */ 821 1.1 oki mask = KBD_MOD_CAPS; 822 1.1 oki break; 823 1.1 oki 824 1.1 oki case KBD_CTRL: 825 1.1 oki mask = KBD_MOD_CTRL; 826 1.1 oki break; 827 1.1 oki 828 1.1 oki case KBD_OPT1: 829 1.1 oki mask = KBD_MOD_OPT1; 830 1.1 oki break; 831 1.1 oki 832 1.1 oki case KBD_OPT2: 833 1.1 oki mask = KBD_MOD_OPT2; 834 1.1 oki break; 835 1.1 oki 836 1.1 oki case KBD_RECONNECT: 837 1.1 oki if (up) { /* ite got 0xff */ 838 1.1 oki kbd_setLED(); 839 1.1 oki } 840 1.1 oki break; 841 1.1 oki } 842 1.1 oki 843 1.1 oki if (mask & KBD_MOD_CAPS) { 844 1.1 oki if (!up) { 845 1.1 oki mod ^= KBD_MOD_CAPS; 846 1.1 oki kbdled ^= LED_CAPS_LOCK; 847 1.1 oki kbd_setLED(); 848 1.1 oki } 849 1.1 oki } else if (up) { 850 1.1 oki mod &= ~mask; 851 1.1 oki } else mod |= mask; 852 1.1 oki 853 1.1 oki /* 854 1.1 oki * these keys should not repeat, so it's the Right Thing 855 1.1 oki * dealing with repeaters only after this block. 856 1.1 oki */ 857 1.1 oki 858 1.1 oki /* 859 1.1 oki * return even if it wasn't a modifier key, the other 860 1.1 oki * codes up here are either special (like reset warning), 861 1.1 oki * or not yet defined 862 1.1 oki */ 863 1.1 oki splx (s); 864 1.1 oki return; 865 1.1 oki } 866 1.1 oki 867 1.1 oki /* 868 1.1 oki * no matter which character we're repeating, stop it if we 869 1.1 oki * get a key-up event. I think this is the same thing amigados does. 870 1.1 oki */ 871 1.1 oki if (up) { 872 1.1 oki if (tout_pending) { 873 1.1 oki untimeout (repeat_handler, 0); 874 1.1 oki tout_pending = 0; 875 1.1 oki last_char = 0; 876 1.1 oki } 877 1.1 oki splx (s); 878 1.1 oki return; 879 1.1 oki } else if (tout_pending && last_char != c) { 880 1.1 oki /* 881 1.1 oki * not the same character remove the repeater and continue 882 1.1 oki * to process this key. -ch 883 1.1 oki */ 884 1.1 oki untimeout (repeat_handler, 0); 885 1.1 oki tout_pending = 0; 886 1.1 oki last_char = 0; 887 1.1 oki } 888 1.1 oki 889 1.1 oki /* 890 1.1 oki * intercept LAlt-LMeta-F1 here to switch back to original ascii-keymap. 891 1.1 oki * this should probably be configurable.. 892 1.1 oki */ 893 1.1 oki if (mod == (KBD_MOD_LALT|KBD_MOD_LMETA) && c == 0x50) { 894 1.1 oki bcopy (&ascii_kbdmap, &kbdmap, sizeof (struct kbdmap)); 895 1.1 oki splx (s); 896 1.1 oki return; 897 1.1 oki } 898 1.1 oki 899 1.1 oki /* translate modifiers */ 900 1.1 oki if (mod & KBD_MOD_SHIFT) { 901 1.1 oki if (mod & KBD_MOD_ALT) 902 1.1 oki key = kbdmap.alt_shift_keys[c]; 903 1.1 oki else 904 1.1 oki key = kbdmap.shift_keys[c]; 905 1.1 oki } else if (mod & KBD_MOD_ALT) 906 1.1 oki key = kbdmap.alt_keys[c]; 907 1.1 oki else { 908 1.1 oki key = kbdmap.keys[c]; 909 1.1 oki /* if CAPS and key is CAPable (no pun intended) */ 910 1.1 oki if ((mod & KBD_MOD_CAPS) && (key.mode & KBD_MODE_CAPS)) 911 1.1 oki key = kbdmap.shift_keys[c]; 912 1.1 oki else if ((mod & KBD_MOD_OPT2) && (key.mode & KBD_MODE_KPAD)) 913 1.1 oki key = kbdmap.shift_keys[c]; 914 1.1 oki } 915 1.1 oki code = key.code; 916 1.1 oki 917 1.1 oki /* 918 1.1 oki * arrange to repeat the keystroke. By doing this at the level of scan-codes, 919 1.1 oki * we can have function keys, and keys that send strings, repeat too. This 920 1.1 oki * also entitles an additional overhead, since we have to do the conversion 921 1.1 oki * each time, but I guess that's ok. 922 1.1 oki */ 923 1.1 oki if (!tout_pending && caller == ITEFILT_TTY && kbd_ite->key_repeat) { 924 1.1 oki tout_pending = 1; 925 1.1 oki last_char = c; 926 1.1 oki timeout (repeat_handler, 0, start_repeat_timeo); 927 1.1 oki } else if (!tout_pending && caller == ITEFILT_REPEATER && 928 1.1 oki kbd_ite->key_repeat) { 929 1.1 oki tout_pending = 1; 930 1.1 oki last_char = c; 931 1.1 oki timeout (repeat_handler, 0, next_repeat_timeo); 932 1.1 oki } 933 1.1 oki 934 1.1 oki /* handle dead keys */ 935 1.1 oki if (key.mode & KBD_MODE_DEAD) { 936 1.1 oki splx (s); 937 1.1 oki return; 938 1.1 oki } 939 1.1 oki /* if not string, apply META and CTRL modifiers */ 940 1.1 oki if (! (key.mode & KBD_MODE_STRING) 941 1.1 oki && (!(key.mode & KBD_MODE_KPAD) || 942 1.1 oki (kbd_ite && !kbd_ite->keypad_appmode))) { 943 1.1 oki if ((mod & KBD_MOD_CTRL) && 944 1.1 oki (code == ' ' || (code >= '@' && code <= 'z'))) 945 1.1 oki code &= 0x1f; 946 1.1 oki if (mod & KBD_MOD_META) 947 1.1 oki code |= 0x80; 948 1.1 oki } else if ((key.mode & KBD_MODE_KPAD) && 949 1.1 oki (kbd_ite && kbd_ite->keypad_appmode)) { 950 1.1 oki static char *in = "0123456789-+.\r()/*"; 951 1.1 oki static char *out = "pqrstuvwxymlnMPQRS"; 952 1.1 oki char *cp = index (in, code); 953 1.1 oki 954 1.1 oki /* 955 1.1 oki * keypad-appmode sends SS3 followed by the above 956 1.1 oki * translated character 957 1.1 oki */ 958 1.1 oki (*linesw[kbd_tty->t_line].l_rint) (27, kbd_tty); 959 1.1 oki (*linesw[kbd_tty->t_line].l_rint) ('O', kbd_tty); 960 1.1 oki (*linesw[kbd_tty->t_line].l_rint) (out[cp - in], kbd_tty); 961 1.1 oki splx(s); 962 1.1 oki return; 963 1.1 oki } else { 964 1.1 oki /* *NO* I don't like this.... */ 965 1.1 oki static u_char app_cursor[] = 966 1.1 oki { 967 1.1 oki 3, 27, 'O', 'A', 968 1.1 oki 3, 27, 'O', 'B', 969 1.1 oki 3, 27, 'O', 'C', 970 1.1 oki 3, 27, 'O', 'D'}; 971 1.1 oki 972 1.1 oki str = kbdmap.strings + code; 973 1.1 oki /* 974 1.1 oki * if this is a cursor key, AND it has the default 975 1.1 oki * keymap setting, AND we're in app-cursor mode, switch 976 1.1 oki * to the above table. This is *nasty* ! 977 1.1 oki */ 978 1.1 oki if (c >= 0x3b && c <= 0x3e && kbd_ite->cursor_appmode 979 1.1 oki && !bcmp(str, "\x03\x1b[", 3) && 980 1.1 oki index("ABCD", str[3])) 981 1.1 oki str = app_cursor + 4 * (str[3] - 'A'); 982 1.1 oki 983 1.1 oki /* 984 1.1 oki * using a length-byte instead of 0-termination allows 985 1.1 oki * to embed \0 into strings, although this is not used 986 1.1 oki * in the default keymap 987 1.1 oki */ 988 1.1 oki for (i = *str++; i; i--) 989 1.1 oki (*linesw[kbd_tty->t_line].l_rint) (*str++, kbd_tty); 990 1.1 oki splx(s); 991 1.1 oki return; 992 1.1 oki } 993 1.1 oki (*linesw[kbd_tty->t_line].l_rint)(code, kbd_tty); 994 1.1 oki 995 1.1 oki splx(s); 996 1.1 oki return; 997 1.1 oki } 998 1.1 oki 999 1.1 oki /* helper functions, makes the code below more readable */ 1000 1.8 oki __inline static void 1001 1.1 oki ite_sendstr (ip, str) 1002 1.1 oki struct ite_softc *ip; 1003 1.1 oki char *str; 1004 1.1 oki { 1005 1.1 oki while (*str) 1006 1.1 oki itesendch (*str++); 1007 1.1 oki } 1008 1.1 oki 1009 1.8 oki __inline static void 1010 1.1 oki alignment_display(ip) 1011 1.1 oki struct ite_softc *ip; 1012 1.1 oki { 1013 1.1 oki int i, j; 1014 1.1 oki 1015 1.1 oki for (j = 0; j < ip->rows; j++) 1016 1.1 oki for (i = 0; i < ip->cols; i++) 1017 1.1 oki SUBR_PUTC(ip, 'E', j, i, ATTR_NOR); 1018 1.1 oki attrclr(ip, 0, 0, ip->rows, ip->cols); 1019 1.1 oki } 1020 1.1 oki 1021 1.8 oki __inline static void 1022 1.1 oki snap_cury(ip) 1023 1.1 oki struct ite_softc *ip; 1024 1.1 oki { 1025 1.1 oki if (ip->inside_margins) { 1026 1.1 oki if (ip->cury < ip->top_margin) 1027 1.1 oki ip->cury = ip->top_margin; 1028 1.1 oki if (ip->cury > ip->bottom_margin) 1029 1.1 oki ip->cury = ip->bottom_margin; 1030 1.1 oki } 1031 1.1 oki } 1032 1.1 oki 1033 1.8 oki __inline static void 1034 1.1 oki ite_dnchar(ip, n) 1035 1.1 oki struct ite_softc *ip; 1036 1.1 oki int n; 1037 1.1 oki { 1038 1.1 oki n = min(n, ip->cols - ip->curx); 1039 1.1 oki if (n < ip->cols - ip->curx) { 1040 1.1 oki SUBR_SCROLL(ip, ip->cury, ip->curx + n, n, SCROLL_LEFT); 1041 1.1 oki attrmov(ip, ip->cury, ip->curx + n, ip->cury, ip->curx, 1042 1.1 oki 1, ip->cols - ip->curx - n); 1043 1.1 oki attrclr(ip, ip->cury, ip->cols - n, 1, n); 1044 1.1 oki } 1045 1.1 oki while (n-- > 0) 1046 1.1 oki SUBR_PUTC(ip, ' ', ip->cury, ip->cols - n - 1, ATTR_NOR); 1047 1.1 oki } 1048 1.1 oki 1049 1.1 oki static void 1050 1.1 oki ite_inchar(ip, n) 1051 1.1 oki struct ite_softc *ip; 1052 1.1 oki int n; 1053 1.1 oki { 1054 1.1 oki int c = ip->save_char; 1055 1.1 oki ip->save_char = 0; 1056 1.1 oki n = min(n, ip->cols - ip->curx); 1057 1.1 oki if (n < ip->cols - ip->curx) { 1058 1.1 oki SUBR_SCROLL(ip, ip->cury, ip->curx, n, SCROLL_RIGHT); 1059 1.1 oki attrmov(ip, ip->cury, ip->curx, ip->cury, ip->curx + n, 1060 1.1 oki 1, ip->cols - ip->curx - n); 1061 1.1 oki attrclr(ip, ip->cury, ip->curx, 1, n); 1062 1.1 oki } 1063 1.1 oki while (n--) 1064 1.1 oki SUBR_PUTC(ip, ' ', ip->cury, ip->curx + n, ATTR_NOR); 1065 1.1 oki ip->save_char = c; 1066 1.1 oki } 1067 1.1 oki 1068 1.8 oki __inline static void 1069 1.1 oki ite_clrtoeol(ip) 1070 1.1 oki struct ite_softc *ip; 1071 1.1 oki { 1072 1.1 oki int y = ip->cury, x = ip->curx; 1073 1.1 oki if (ip->cols - x > 0) { 1074 1.1 oki SUBR_CLEAR(ip, y, x, 1, ip->cols - x); 1075 1.1 oki attrclr(ip, y, x, 1, ip->cols - x); 1076 1.1 oki } 1077 1.1 oki } 1078 1.1 oki 1079 1.8 oki __inline static void 1080 1.1 oki ite_clrtobol(ip) 1081 1.1 oki struct ite_softc *ip; 1082 1.1 oki { 1083 1.1 oki int y = ip->cury, x = min(ip->curx + 1, ip->cols); 1084 1.1 oki SUBR_CLEAR(ip, y, 0, 1, x); 1085 1.1 oki attrclr(ip, y, 0, 1, x); 1086 1.1 oki } 1087 1.1 oki 1088 1.8 oki __inline static void 1089 1.1 oki ite_clrline(ip) 1090 1.1 oki struct ite_softc *ip; 1091 1.1 oki { 1092 1.1 oki int y = ip->cury; 1093 1.1 oki SUBR_CLEAR(ip, y, 0, 1, ip->cols); 1094 1.1 oki attrclr(ip, y, 0, 1, ip->cols); 1095 1.1 oki } 1096 1.1 oki 1097 1.8 oki __inline static void 1098 1.1 oki ite_clrtoeos(ip) 1099 1.1 oki struct ite_softc *ip; 1100 1.1 oki { 1101 1.1 oki ite_clrtoeol(ip); 1102 1.1 oki if (ip->cury < ip->rows - 1) { 1103 1.1 oki SUBR_CLEAR(ip, ip->cury + 1, 0, ip->rows - 1 - ip->cury, ip->cols); 1104 1.1 oki attrclr(ip, ip->cury, 0, ip->rows - ip->cury, ip->cols); 1105 1.1 oki } 1106 1.1 oki } 1107 1.1 oki 1108 1.8 oki __inline static void 1109 1.1 oki ite_clrtobos(ip) 1110 1.1 oki struct ite_softc *ip; 1111 1.1 oki { 1112 1.1 oki ite_clrtobol(ip); 1113 1.1 oki if (ip->cury > 0) { 1114 1.1 oki SUBR_CLEAR(ip, 0, 0, ip->cury, ip->cols); 1115 1.1 oki attrclr(ip, 0, 0, ip->cury, ip->cols); 1116 1.1 oki } 1117 1.1 oki } 1118 1.1 oki 1119 1.8 oki __inline static void 1120 1.1 oki ite_clrscreen(ip) 1121 1.1 oki struct ite_softc *ip; 1122 1.1 oki { 1123 1.1 oki SUBR_CLEAR(ip, 0, 0, ip->rows, ip->cols); 1124 1.1 oki attrclr(ip, 0, 0, ip->rows, ip->cols); 1125 1.1 oki } 1126 1.1 oki 1127 1.1 oki 1128 1.1 oki 1129 1.8 oki __inline static void 1130 1.1 oki ite_dnline(ip, n) 1131 1.1 oki struct ite_softc *ip; 1132 1.1 oki int n; 1133 1.1 oki { 1134 1.1 oki /* 1135 1.1 oki * interesting.. if the cursor is outside the scrolling 1136 1.1 oki * region, this command is simply ignored.. 1137 1.1 oki */ 1138 1.1 oki if (ip->cury < ip->top_margin || ip->cury > ip->bottom_margin) 1139 1.1 oki return; 1140 1.1 oki 1141 1.1 oki n = min(n, ip->bottom_margin + 1 - ip->cury); 1142 1.1 oki if (n <= ip->bottom_margin - ip->cury) { 1143 1.1 oki SUBR_SCROLL(ip, ip->cury + n, 0, n, SCROLL_UP); 1144 1.1 oki attrmov(ip, ip->cury + n, 0, ip->cury, 0, 1145 1.1 oki ip->bottom_margin + 1 - ip->cury - n, ip->cols); 1146 1.1 oki } 1147 1.1 oki SUBR_CLEAR(ip, ip->bottom_margin - n + 1, 0, n, ip->cols); 1148 1.1 oki attrclr(ip, ip->bottom_margin - n + 1, 0, n, ip->cols); 1149 1.1 oki } 1150 1.1 oki 1151 1.8 oki __inline static void 1152 1.1 oki ite_inline(ip, n) 1153 1.1 oki struct ite_softc *ip; 1154 1.1 oki int n; 1155 1.1 oki { 1156 1.1 oki /* 1157 1.1 oki * interesting.. if the cursor is outside the scrolling 1158 1.1 oki * region, this command is simply ignored.. 1159 1.1 oki */ 1160 1.1 oki if (ip->cury < ip->top_margin || ip->cury > ip->bottom_margin) 1161 1.1 oki return; 1162 1.1 oki 1163 1.1 oki if (n <= 0) 1164 1.1 oki n = 1; 1165 1.1 oki else n = min(n, ip->bottom_margin + 1 - ip->cury); 1166 1.1 oki if (n <= ip->bottom_margin - ip->cury) { 1167 1.1 oki SUBR_SCROLL(ip, ip->cury, 0, n, SCROLL_DOWN); 1168 1.1 oki attrmov(ip, ip->cury, 0, ip->cury + n, 0, 1169 1.1 oki ip->bottom_margin + 1 - ip->cury - n, ip->cols); 1170 1.1 oki } 1171 1.1 oki SUBR_CLEAR(ip, ip->cury, 0, n, ip->cols); 1172 1.1 oki attrclr(ip, ip->cury, 0, n, ip->cols); 1173 1.1 oki ip->curx = 0; 1174 1.1 oki } 1175 1.1 oki 1176 1.8 oki __inline static void 1177 1.1 oki ite_index (ip) 1178 1.1 oki struct ite_softc *ip; 1179 1.1 oki { 1180 1.1 oki ++ip->cury; 1181 1.1 oki if ((ip->cury == ip->bottom_margin+1) || (ip->cury == ip->rows)) { 1182 1.1 oki ip->cury--; 1183 1.1 oki SUBR_SCROLL(ip, ip->top_margin + 1, 0, 1, SCROLL_UP); 1184 1.1 oki ite_clrline(ip); 1185 1.1 oki } 1186 1.1 oki /*clr_attr(ip, ATTR_INV);*/ 1187 1.1 oki } 1188 1.1 oki 1189 1.8 oki __inline static void 1190 1.1 oki ite_lf (ip) 1191 1.1 oki struct ite_softc *ip; 1192 1.1 oki { 1193 1.1 oki ++ip->cury; 1194 1.1 oki if (ip->cury > ip->bottom_margin) { 1195 1.1 oki ip->cury--; 1196 1.1 oki SUBR_SCROLL(ip, ip->top_margin + 1, 0, 1, SCROLL_UP); 1197 1.1 oki ite_clrline(ip); 1198 1.1 oki } 1199 1.1 oki /* SUBR_CURSOR(ip, MOVE_CURSOR);*/ 1200 1.1 oki /*clr_attr(ip, ATTR_INV);*/ 1201 1.1 oki /* reset character set ... thanks for mohta. */ 1202 1.1 oki ip->G0 = CSET_ASCII; 1203 1.1 oki ip->G1 = CSET_JIS1983; 1204 1.1 oki ip->G2 = CSET_JISKANA; 1205 1.1 oki ip->G3 = CSET_JIS1990; 1206 1.1 oki ip->GL = &ip->G0; 1207 1.1 oki ip->GR = &ip->G1; 1208 1.1 oki ip->save_GL = 0; 1209 1.1 oki ip->save_char = 0; 1210 1.1 oki } 1211 1.1 oki 1212 1.8 oki __inline static void 1213 1.1 oki ite_crlf (ip) 1214 1.1 oki struct ite_softc *ip; 1215 1.1 oki { 1216 1.1 oki ip->curx = 0; 1217 1.1 oki ite_lf (ip); 1218 1.1 oki } 1219 1.1 oki 1220 1.8 oki __inline static void 1221 1.1 oki ite_cr (ip) 1222 1.1 oki struct ite_softc *ip; 1223 1.1 oki { 1224 1.1 oki if (ip->curx) { 1225 1.1 oki ip->curx = 0; 1226 1.1 oki } 1227 1.1 oki } 1228 1.1 oki 1229 1.8 oki __inline static void 1230 1.1 oki ite_rlf (ip) 1231 1.1 oki struct ite_softc *ip; 1232 1.1 oki { 1233 1.1 oki ip->cury--; 1234 1.1 oki if ((ip->cury < 0) || (ip->cury == ip->top_margin - 1)) { 1235 1.1 oki ip->cury++; 1236 1.1 oki SUBR_SCROLL(ip, ip->top_margin, 0, 1, SCROLL_DOWN); 1237 1.1 oki ite_clrline(ip); 1238 1.1 oki } 1239 1.1 oki clr_attr(ip, ATTR_INV); 1240 1.1 oki } 1241 1.1 oki 1242 1.8 oki __inline static int 1243 1.1 oki atoi (cp) 1244 1.1 oki const char *cp; 1245 1.1 oki { 1246 1.1 oki int n; 1247 1.1 oki 1248 1.1 oki for (n = 0; *cp && *cp >= '0' && *cp <= '9'; cp++) 1249 1.1 oki n = n * 10 + *cp - '0'; 1250 1.1 oki return n; 1251 1.1 oki } 1252 1.1 oki 1253 1.8 oki __inline static char * 1254 1.1 oki index(cp, ch) 1255 1.1 oki const char *cp; 1256 1.1 oki char ch; 1257 1.1 oki { 1258 1.1 oki while (*cp && *cp != ch) 1259 1.1 oki cp++; 1260 1.1 oki return *cp ? (char *) cp : 0; 1261 1.1 oki } 1262 1.1 oki 1263 1.8 oki __inline static int 1264 1.1 oki ite_argnum (ip) 1265 1.1 oki struct ite_softc *ip; 1266 1.1 oki { 1267 1.1 oki char ch; 1268 1.1 oki int n; 1269 1.1 oki 1270 1.1 oki /* convert argument string into number */ 1271 1.1 oki if (ip->ap == ip->argbuf) 1272 1.1 oki return 1; 1273 1.1 oki ch = *ip->ap; 1274 1.1 oki *ip->ap = 0; 1275 1.1 oki n = atoi (ip->argbuf); 1276 1.1 oki *ip->ap = ch; 1277 1.1 oki 1278 1.1 oki return n; 1279 1.1 oki } 1280 1.1 oki 1281 1.8 oki __inline static int 1282 1.1 oki ite_zargnum (ip) 1283 1.1 oki struct ite_softc *ip; 1284 1.1 oki { 1285 1.1 oki char ch; 1286 1.1 oki int n; 1287 1.1 oki 1288 1.1 oki /* convert argument string into number */ 1289 1.1 oki if (ip->ap == ip->argbuf) 1290 1.1 oki return 0; 1291 1.1 oki ch = *ip->ap; 1292 1.1 oki *ip->ap = 0; /* terminate string */ 1293 1.1 oki n = atoi (ip->argbuf); 1294 1.1 oki *ip->ap = ch; 1295 1.1 oki 1296 1.1 oki return n; /* don't "n ? n : 1" here, <CSI>0m != <CSI>1m ! */ 1297 1.1 oki } 1298 1.1 oki 1299 1.1 oki void 1300 1.1 oki ite_putstr(s, len, dev) 1301 1.1 oki const u_char *s; 1302 1.1 oki int len; 1303 1.1 oki dev_t dev; 1304 1.1 oki { 1305 1.1 oki struct ite_softc *ip; 1306 1.1 oki int i; 1307 1.1 oki 1308 1.1 oki ip = getitesp(dev); 1309 1.1 oki 1310 1.1 oki /* XXX avoid problems */ 1311 1.1 oki if ((ip->flags & (ITE_ACTIVE|ITE_INGRF)) != ITE_ACTIVE) 1312 1.1 oki return; 1313 1.1 oki 1314 1.1 oki SUBR_CURSOR(ip, START_CURSOROPT); 1315 1.1 oki for (i = 0; i < len; i++) 1316 1.1 oki if (s[i]) 1317 1.1 oki iteputchar(s[i], ip); 1318 1.1 oki SUBR_CURSOR(ip, END_CURSOROPT); 1319 1.1 oki } 1320 1.1 oki 1321 1.1 oki void 1322 1.1 oki iteputchar(c, ip) 1323 1.1 oki register int c; 1324 1.1 oki struct ite_softc *ip; 1325 1.1 oki { 1326 1.1 oki int n, x, y; 1327 1.1 oki char *cp; 1328 1.1 oki 1329 1.1 oki if (c >= 0x20 && ip->escape) { 1330 1.1 oki switch (ip->escape) { 1331 1.1 oki 1332 1.1 oki case ESC: 1333 1.1 oki switch (c) { 1334 1.1 oki /* first 7bit equivalents for the 8bit control characters */ 1335 1.1 oki 1336 1.1 oki case 'D': 1337 1.1 oki c = IND; 1338 1.1 oki ip->escape = 0; 1339 1.1 oki break; /* and fall into the next switch below (same for all `break') */ 1340 1.1 oki 1341 1.1 oki case 'E': 1342 1.1 oki /* next line */ 1343 1.1 oki c = NEL; 1344 1.1 oki ip->escape = 0; 1345 1.1 oki break; 1346 1.1 oki 1347 1.1 oki case 'H': 1348 1.1 oki /* set TAB at current col */ 1349 1.1 oki c = HTS; 1350 1.1 oki ip->escape = 0; 1351 1.1 oki break; 1352 1.1 oki 1353 1.1 oki case 'M': 1354 1.1 oki /* reverse index */ 1355 1.1 oki c = RI; 1356 1.1 oki ip->escape = 0; 1357 1.1 oki break; 1358 1.1 oki 1359 1.1 oki case 'N': 1360 1.1 oki /* single shift G2 */ 1361 1.1 oki c = SS2; 1362 1.1 oki ip->escape = 0; 1363 1.1 oki break; 1364 1.1 oki 1365 1.1 oki case 'O': 1366 1.1 oki /* single shift G3 */ 1367 1.1 oki c = SS3; 1368 1.1 oki ip->escape = 0; 1369 1.1 oki break; 1370 1.1 oki 1371 1.1 oki case 'P': 1372 1.1 oki /* DCS detected */ 1373 1.1 oki c = DCS; 1374 1.1 oki ip->escape = 0; 1375 1.1 oki break; 1376 1.1 oki 1377 1.1 oki case '[': 1378 1.1 oki c = CSI; 1379 1.1 oki ip->escape = 0; 1380 1.1 oki break; 1381 1.1 oki 1382 1.1 oki case '\\': 1383 1.1 oki /* String Terminator */ 1384 1.1 oki c = ST; 1385 1.1 oki ip->escape = 0; 1386 1.1 oki break; 1387 1.1 oki 1388 1.1 oki case ']': 1389 1.1 oki c = OSC; 1390 1.1 oki ip->escape = 0; 1391 1.1 oki break; 1392 1.1 oki 1393 1.1 oki case '^': 1394 1.1 oki c = PM; 1395 1.1 oki ip->escape = 0; 1396 1.1 oki break; 1397 1.1 oki 1398 1.1 oki case '_': 1399 1.1 oki c = APC; 1400 1.1 oki ip->escape = 0; 1401 1.1 oki break; 1402 1.1 oki 1403 1.1 oki 1404 1.1 oki /* introduces 7/8bit control */ 1405 1.1 oki case ' ': 1406 1.1 oki /* can be followed by either F or G */ 1407 1.1 oki ip->escape = ' '; 1408 1.1 oki break; 1409 1.1 oki 1410 1.1 oki 1411 1.1 oki /* a lot of character set selections, not yet used... 1412 1.1 oki 94-character sets: */ 1413 1.1 oki case '(': /* G0 */ 1414 1.1 oki case ')': /* G1 */ 1415 1.1 oki ip->escape = c; 1416 1.1 oki return; 1417 1.1 oki 1418 1.1 oki case '*': /* G2 */ 1419 1.1 oki case '+': /* G3 */ 1420 1.1 oki case 'B': /* ASCII */ 1421 1.1 oki case 'A': /* ISO latin 1 */ 1422 1.1 oki case '<': /* user preferred suplemental */ 1423 1.1 oki case '0': /* dec special graphics */ 1424 1.1 oki 1425 1.1 oki /* 96-character sets: */ 1426 1.1 oki case '-': /* G1 */ 1427 1.1 oki case '.': /* G2 */ 1428 1.1 oki case '/': /* G3 */ 1429 1.1 oki 1430 1.1 oki /* national character sets: */ 1431 1.1 oki case '4': /* dutch */ 1432 1.1 oki case '5': 1433 1.1 oki case 'C': /* finnish */ 1434 1.1 oki case 'R': /* french */ 1435 1.1 oki case 'Q': /* french canadian */ 1436 1.1 oki case 'K': /* german */ 1437 1.1 oki case 'Y': /* italian */ 1438 1.1 oki case '6': /* norwegian/danish */ 1439 1.1 oki /* note: %5 and %6 are not supported (two chars..) */ 1440 1.1 oki 1441 1.1 oki ip->escape = 0; 1442 1.1 oki /* just ignore for now */ 1443 1.1 oki return; 1444 1.1 oki 1445 1.1 oki /* 94-multibyte character sets designate */ 1446 1.1 oki case '$': 1447 1.1 oki ip->escape = '$'; 1448 1.1 oki return; 1449 1.1 oki 1450 1.1 oki /* locking shift modes */ 1451 1.1 oki case '`': 1452 1.1 oki ip->GR = &ip->G1; 1453 1.1 oki ip->escape = 0; 1454 1.1 oki return; 1455 1.1 oki 1456 1.1 oki case 'n': 1457 1.1 oki ip->GL = &ip->G2; 1458 1.1 oki ip->escape = 0; 1459 1.1 oki return; 1460 1.1 oki 1461 1.1 oki case '}': 1462 1.1 oki ip->GR = &ip->G2; 1463 1.1 oki ip->escape = 0; 1464 1.1 oki return; 1465 1.1 oki 1466 1.1 oki case 'o': 1467 1.1 oki ip->GL = &ip->G3; 1468 1.1 oki ip->escape = 0; 1469 1.1 oki return; 1470 1.1 oki 1471 1.1 oki case '|': 1472 1.1 oki ip->GR = &ip->G3; 1473 1.1 oki ip->escape = 0; 1474 1.1 oki return; 1475 1.1 oki 1476 1.1 oki case '~': 1477 1.1 oki ip->GR = &ip->G1; 1478 1.1 oki ip->escape = 0; 1479 1.1 oki return; 1480 1.1 oki 1481 1.1 oki /* font width/height control */ 1482 1.1 oki case '#': 1483 1.1 oki ip->escape = '#'; 1484 1.1 oki return; 1485 1.1 oki 1486 1.1 oki case 'c': 1487 1.1 oki /* hard terminal reset .. */ 1488 1.1 oki ite_reset (ip); 1489 1.1 oki SUBR_CURSOR(ip, MOVE_CURSOR); 1490 1.1 oki ip->escape = 0; 1491 1.1 oki return; 1492 1.1 oki 1493 1.1 oki 1494 1.1 oki case '7': 1495 1.1 oki /* save cursor */ 1496 1.1 oki ip->save_curx = ip->curx; 1497 1.1 oki ip->save_cury = ip->cury; 1498 1.1 oki ip->save_attribute = ip->attribute; 1499 1.1 oki ip->sc_om = ip->inside_margins; 1500 1.1 oki ip->sc_G0 = ip->G0; 1501 1.1 oki ip->sc_G1 = ip->G1; 1502 1.1 oki ip->sc_G2 = ip->G2; 1503 1.1 oki ip->sc_G3 = ip->G3; 1504 1.1 oki ip->sc_GL = ip->GL; 1505 1.1 oki ip->sc_GR = ip->GR; 1506 1.1 oki ip->escape = 0; 1507 1.1 oki return; 1508 1.1 oki 1509 1.1 oki case '8': 1510 1.1 oki /* restore cursor */ 1511 1.1 oki ip->curx = ip->save_curx; 1512 1.1 oki ip->cury = ip->save_cury; 1513 1.1 oki ip->attribute = ip->save_attribute; 1514 1.1 oki ip->inside_margins = ip->sc_om; 1515 1.1 oki ip->G0 = ip->sc_G0; 1516 1.1 oki ip->G1 = ip->sc_G1; 1517 1.1 oki ip->G2 = ip->sc_G2; 1518 1.1 oki ip->G3 = ip->sc_G3; 1519 1.1 oki ip->GL = ip->sc_GL; 1520 1.1 oki ip->GR = ip->sc_GR; 1521 1.1 oki SUBR_CURSOR(ip, MOVE_CURSOR); 1522 1.1 oki ip->escape = 0; 1523 1.1 oki return; 1524 1.1 oki 1525 1.1 oki case '=': 1526 1.1 oki /* keypad application mode */ 1527 1.1 oki ip->keypad_appmode = 1; 1528 1.1 oki ip->escape = 0; 1529 1.1 oki return; 1530 1.1 oki 1531 1.1 oki case '>': 1532 1.1 oki /* keypad numeric mode */ 1533 1.1 oki ip->keypad_appmode = 0; 1534 1.1 oki ip->escape = 0; 1535 1.1 oki return; 1536 1.1 oki 1537 1.1 oki case 'Z': /* request ID */ 1538 1.1 oki if (ip->emul_level == EMUL_VT100) 1539 1.1 oki ite_sendstr (ip, "\033[61;0c"); /* XXX not clean */ 1540 1.1 oki else 1541 1.1 oki ite_sendstr (ip, "\033[63;0c"); /* XXX not clean */ 1542 1.1 oki ip->escape = 0; 1543 1.1 oki return; 1544 1.1 oki 1545 1.1 oki /* default catch all for not recognized ESC sequences */ 1546 1.1 oki default: 1547 1.1 oki ip->escape = 0; 1548 1.1 oki return; 1549 1.1 oki } 1550 1.1 oki break; 1551 1.1 oki 1552 1.1 oki 1553 1.1 oki case '(': /* designate G0 */ 1554 1.1 oki switch (c) { 1555 1.1 oki case 'B': /* USASCII */ 1556 1.1 oki ip->G0 = CSET_ASCII; 1557 1.1 oki ip->escape = 0; 1558 1.1 oki return; 1559 1.1 oki case 'I': 1560 1.1 oki ip->G0 = CSET_JISKANA; 1561 1.1 oki ip->escape = 0; 1562 1.1 oki return; 1563 1.1 oki case 'J': 1564 1.1 oki ip->G0 = CSET_JISROMA; 1565 1.1 oki ip->escape = 0; 1566 1.1 oki return; 1567 1.1 oki case 'A': /* British or ISO-Latin-1 */ 1568 1.1 oki case 'H': /* Swedish */ 1569 1.1 oki case 'K': /* German */ 1570 1.1 oki case 'R': /* French */ 1571 1.1 oki case 'Y': /* Italian */ 1572 1.1 oki case 'Z': /* Spanish */ 1573 1.1 oki default: 1574 1.1 oki /* not supported */ 1575 1.1 oki ip->escape = 0; 1576 1.1 oki return; 1577 1.1 oki } 1578 1.1 oki 1579 1.1 oki case ')': /* designate G1 */ 1580 1.1 oki ip->escape = 0; 1581 1.1 oki return; 1582 1.1 oki 1583 1.1 oki case '$': /* 94-multibyte character set */ 1584 1.1 oki switch (c) { 1585 1.1 oki case '@': 1586 1.1 oki ip->G0 = CSET_JIS1978; 1587 1.1 oki ip->escape = 0; 1588 1.1 oki return; 1589 1.1 oki case 'B': 1590 1.1 oki ip->G0 = CSET_JIS1983; 1591 1.1 oki ip->escape = 0; 1592 1.1 oki return; 1593 1.1 oki case 'D': 1594 1.1 oki ip->G0 = CSET_JIS1990; 1595 1.1 oki ip->escape = 0; 1596 1.1 oki return; 1597 1.1 oki default: 1598 1.1 oki /* not supported */ 1599 1.1 oki ip->escape = 0; 1600 1.1 oki return; 1601 1.1 oki } 1602 1.1 oki 1603 1.1 oki case ' ': 1604 1.1 oki switch (c) { 1605 1.1 oki case 'F': 1606 1.1 oki ip->eightbit_C1 = 0; 1607 1.1 oki ip->escape = 0; 1608 1.1 oki return; 1609 1.1 oki 1610 1.1 oki case 'G': 1611 1.1 oki ip->eightbit_C1 = 1; 1612 1.1 oki ip->escape = 0; 1613 1.1 oki return; 1614 1.1 oki 1615 1.1 oki default: 1616 1.1 oki /* not supported */ 1617 1.1 oki ip->escape = 0; 1618 1.1 oki return; 1619 1.1 oki } 1620 1.1 oki break; 1621 1.1 oki 1622 1.1 oki case '#': 1623 1.1 oki switch (c) { 1624 1.1 oki case '5': 1625 1.1 oki /* single height, single width */ 1626 1.1 oki ip->escape = 0; 1627 1.1 oki return; 1628 1.1 oki 1629 1.1 oki case '6': 1630 1.1 oki /* double width, single height */ 1631 1.1 oki ip->escape = 0; 1632 1.1 oki return; 1633 1.1 oki 1634 1.1 oki case '3': 1635 1.1 oki /* top half */ 1636 1.1 oki ip->escape = 0; 1637 1.1 oki return; 1638 1.1 oki 1639 1.1 oki case '4': 1640 1.1 oki /* bottom half */ 1641 1.1 oki ip->escape = 0; 1642 1.1 oki return; 1643 1.1 oki 1644 1.1 oki case '8': 1645 1.1 oki /* screen alignment pattern... */ 1646 1.1 oki alignment_display (ip); 1647 1.1 oki ip->escape = 0; 1648 1.1 oki return; 1649 1.1 oki 1650 1.1 oki default: 1651 1.1 oki ip->escape = 0; 1652 1.1 oki return; 1653 1.1 oki } 1654 1.1 oki break; 1655 1.1 oki 1656 1.1 oki 1657 1.1 oki 1658 1.1 oki case CSI: 1659 1.1 oki /* the biggie... */ 1660 1.1 oki switch (c) { 1661 1.1 oki case '0': case '1': case '2': case '3': case '4': 1662 1.1 oki case '5': case '6': case '7': case '8': case '9': 1663 1.1 oki case ';': case '\"': case '$': case '>': 1664 1.1 oki if (ip->ap < ip->argbuf + MAX_ARGSIZE) 1665 1.1 oki *ip->ap++ = c; 1666 1.1 oki return; 1667 1.1 oki 1668 1.1 oki case 'p': 1669 1.1 oki *ip->ap = 0; 1670 1.1 oki if (!strncmp(ip->argbuf, "61\"", 3)) 1671 1.1 oki ip->emul_level = EMUL_VT100; 1672 1.1 oki else if (!strncmp(ip->argbuf, "63;1\"", 5) 1673 1.1 oki || !strncmp(ip->argbuf, "62;1\"", 5)) 1674 1.1 oki ip->emul_level = EMUL_VT300_7; 1675 1.1 oki else 1676 1.1 oki ip->emul_level = EMUL_VT300_8; 1677 1.1 oki ip->escape = 0; 1678 1.1 oki return; 1679 1.1 oki 1680 1.1 oki 1681 1.1 oki case '?': 1682 1.1 oki *ip->ap = 0; 1683 1.1 oki ip->escape = '?'; 1684 1.1 oki ip->ap = ip->argbuf; 1685 1.1 oki return; 1686 1.1 oki 1687 1.1 oki 1688 1.1 oki case 'c': 1689 1.1 oki /* device attributes */ 1690 1.1 oki *ip->ap = 0; 1691 1.1 oki if (ip->argbuf[0] == '>') { 1692 1.1 oki ite_sendstr (ip, "\033[>24;0;0;0c"); 1693 1.1 oki } else 1694 1.1 oki switch (ite_zargnum(ip)) { 1695 1.1 oki case 0: 1696 1.1 oki /* primary DA request, send primary DA response */ 1697 1.1 oki if (ip->emul_level == EMUL_VT100) 1698 1.1 oki ite_sendstr (ip, "\033[?1;1c"); 1699 1.1 oki else 1700 1.1 oki ite_sendstr (ip, "\033[63;0c"); 1701 1.1 oki break; 1702 1.1 oki } 1703 1.1 oki ip->escape = 0; 1704 1.1 oki return; 1705 1.1 oki 1706 1.1 oki case 'n': 1707 1.1 oki switch (ite_zargnum(ip)) { 1708 1.1 oki case 5: 1709 1.1 oki ite_sendstr (ip, "\033[0n"); /* no malfunction */ 1710 1.1 oki break; 1711 1.1 oki case 6: 1712 1.1 oki /* cursor position report */ 1713 1.6 christos sprintf (ip->argbuf, "\033[%d;%dR", 1714 1.1 oki ip->cury + 1, ip->curx + 1); 1715 1.1 oki ite_sendstr (ip, ip->argbuf); 1716 1.1 oki break; 1717 1.1 oki } 1718 1.1 oki ip->escape = 0; 1719 1.1 oki return; 1720 1.1 oki 1721 1.1 oki 1722 1.1 oki case 'x': 1723 1.1 oki switch (ite_zargnum(ip)) { 1724 1.1 oki case 0: 1725 1.1 oki /* Fake some terminal parameters. */ 1726 1.1 oki ite_sendstr (ip, "\033[2;1;1;112;112;1;0x"); 1727 1.1 oki break; 1728 1.1 oki case 1: 1729 1.1 oki ite_sendstr (ip, "\033[3;1;1;112;112;1;0x"); 1730 1.1 oki break; 1731 1.1 oki } 1732 1.1 oki ip->escape = 0; 1733 1.1 oki return; 1734 1.1 oki 1735 1.1 oki 1736 1.1 oki case 'g': 1737 1.1 oki /* clear tabs */ 1738 1.1 oki switch (ite_zargnum(ip)) { 1739 1.1 oki case 0: 1740 1.1 oki if (ip->curx < ip->cols) 1741 1.1 oki ip->tabs[ip->curx] = 0; 1742 1.1 oki break; 1743 1.1 oki case 3: 1744 1.1 oki for (n = 0; n < ip->cols; n++) 1745 1.1 oki ip->tabs[n] = 0; 1746 1.1 oki break; 1747 1.1 oki 1748 1.1 oki default: 1749 1.1 oki /* ignore */ 1750 1.1 oki break; 1751 1.1 oki } 1752 1.1 oki ip->escape = 0; 1753 1.1 oki return; 1754 1.1 oki 1755 1.1 oki 1756 1.1 oki case 'h': /* set mode */ 1757 1.1 oki case 'l': /* reset mode */ 1758 1.1 oki n = ite_zargnum (ip); 1759 1.1 oki switch (n) { 1760 1.1 oki case 4: 1761 1.1 oki ip->imode = (c == 'h'); /* insert/replace mode */ 1762 1.1 oki break; 1763 1.1 oki case 20: 1764 1.1 oki ip->linefeed_newline = (c == 'h'); 1765 1.1 oki break; 1766 1.1 oki } 1767 1.1 oki ip->escape = 0; 1768 1.1 oki return; 1769 1.1 oki 1770 1.1 oki 1771 1.1 oki case 'M': 1772 1.1 oki /* delete line */ 1773 1.1 oki ite_dnline (ip, ite_argnum (ip)); 1774 1.1 oki ip->escape = 0; 1775 1.1 oki return; 1776 1.1 oki 1777 1.1 oki 1778 1.1 oki case 'L': 1779 1.1 oki /* insert line */ 1780 1.1 oki ite_inline (ip, ite_argnum (ip)); 1781 1.1 oki ip->escape = 0; 1782 1.1 oki return; 1783 1.1 oki 1784 1.1 oki 1785 1.1 oki case 'P': 1786 1.1 oki /* delete char */ 1787 1.1 oki ite_dnchar (ip, ite_argnum (ip)); 1788 1.1 oki ip->escape = 0; 1789 1.1 oki return; 1790 1.1 oki 1791 1.1 oki 1792 1.1 oki case '@': 1793 1.1 oki /* insert char(s) */ 1794 1.1 oki ite_inchar (ip, ite_argnum (ip)); 1795 1.1 oki ip->escape = 0; 1796 1.1 oki return; 1797 1.1 oki 1798 1.1 oki case '!': 1799 1.1 oki /* soft terminal reset */ 1800 1.1 oki ip->escape = 0; /* XXX */ 1801 1.1 oki return; 1802 1.1 oki 1803 1.1 oki case 'G': 1804 1.1 oki /* this one was *not* in my vt320 manual but in 1805 1.1 oki a vt320 termcap entry.. who is right? 1806 1.1 oki It's supposed to set the horizontal cursor position. */ 1807 1.1 oki *ip->ap = 0; 1808 1.1 oki x = atoi (ip->argbuf); 1809 1.1 oki if (x) x--; 1810 1.1 oki ip->curx = min(x, ip->cols - 1); 1811 1.1 oki ip->escape = 0; 1812 1.1 oki SUBR_CURSOR(ip, MOVE_CURSOR); 1813 1.1 oki clr_attr (ip, ATTR_INV); 1814 1.1 oki return; 1815 1.1 oki 1816 1.1 oki 1817 1.1 oki case 'd': 1818 1.1 oki /* same thing here, this one's for setting the absolute 1819 1.1 oki vertical cursor position. Not documented... */ 1820 1.1 oki *ip->ap = 0; 1821 1.1 oki y = atoi (ip->argbuf); 1822 1.1 oki if (y) y--; 1823 1.1 oki if (ip->inside_margins) 1824 1.1 oki y += ip->top_margin; 1825 1.1 oki ip->cury = min(y, ip->rows - 1); 1826 1.1 oki ip->escape = 0; 1827 1.1 oki snap_cury(ip); 1828 1.1 oki SUBR_CURSOR(ip, MOVE_CURSOR); 1829 1.1 oki clr_attr (ip, ATTR_INV); 1830 1.1 oki return; 1831 1.1 oki 1832 1.1 oki 1833 1.1 oki case 'H': 1834 1.1 oki case 'f': 1835 1.1 oki *ip->ap = 0; 1836 1.1 oki y = atoi (ip->argbuf); 1837 1.1 oki x = 0; 1838 1.1 oki cp = index (ip->argbuf, ';'); 1839 1.1 oki if (cp) 1840 1.1 oki x = atoi (cp + 1); 1841 1.1 oki if (x) x--; 1842 1.1 oki if (y) y--; 1843 1.1 oki if (ip->inside_margins) 1844 1.1 oki y += ip->top_margin; 1845 1.1 oki ip->cury = min(y, ip->rows - 1); 1846 1.1 oki ip->curx = min(x, ip->cols - 1); 1847 1.1 oki ip->escape = 0; 1848 1.1 oki snap_cury(ip); 1849 1.1 oki SUBR_CURSOR(ip, MOVE_CURSOR); 1850 1.1 oki /*clr_attr (ip, ATTR_INV);*/ 1851 1.1 oki return; 1852 1.1 oki 1853 1.1 oki case 'A': 1854 1.1 oki /* cursor up */ 1855 1.1 oki n = ite_argnum (ip); 1856 1.1 oki n = ip->cury - (n ? n : 1); 1857 1.1 oki if (n < 0) n = 0; 1858 1.1 oki if (ip->inside_margins) 1859 1.1 oki n = max(ip->top_margin, n); 1860 1.1 oki else if (n == ip->top_margin - 1) 1861 1.1 oki /* allow scrolling outside region, but don't scroll out 1862 1.1 oki of active region without explicit CUP */ 1863 1.1 oki n = ip->top_margin; 1864 1.1 oki ip->cury = n; 1865 1.1 oki ip->escape = 0; 1866 1.1 oki SUBR_CURSOR(ip, MOVE_CURSOR); 1867 1.1 oki clr_attr (ip, ATTR_INV); 1868 1.1 oki return; 1869 1.1 oki 1870 1.1 oki case 'B': 1871 1.1 oki /* cursor down */ 1872 1.1 oki n = ite_argnum (ip); 1873 1.1 oki n = ip->cury + (n ? n : 1); 1874 1.1 oki n = min(ip->rows - 1, n); 1875 1.1 oki #if 0 1876 1.1 oki if (ip->inside_margins) 1877 1.1 oki #endif 1878 1.1 oki n = min(ip->bottom_margin, n); 1879 1.1 oki #if 0 1880 1.1 oki else if (n == ip->bottom_margin + 1) 1881 1.1 oki /* allow scrolling outside region, but don't scroll out 1882 1.1 oki of active region without explicit CUP */ 1883 1.1 oki n = ip->bottom_margin; 1884 1.1 oki #endif 1885 1.1 oki ip->cury = n; 1886 1.1 oki ip->escape = 0; 1887 1.1 oki SUBR_CURSOR(ip, MOVE_CURSOR); 1888 1.1 oki clr_attr (ip, ATTR_INV); 1889 1.1 oki return; 1890 1.1 oki 1891 1.1 oki case 'C': 1892 1.1 oki /* cursor forward */ 1893 1.1 oki n = ite_argnum (ip); 1894 1.1 oki n = n ? n : 1; 1895 1.1 oki ip->curx = min(ip->curx + n, ip->cols - 1); 1896 1.1 oki ip->escape = 0; 1897 1.1 oki SUBR_CURSOR(ip, MOVE_CURSOR); 1898 1.1 oki clr_attr (ip, ATTR_INV); 1899 1.1 oki return; 1900 1.1 oki 1901 1.1 oki case 'D': 1902 1.1 oki /* cursor backward */ 1903 1.1 oki n = ite_argnum (ip); 1904 1.1 oki n = n ? n : 1; 1905 1.1 oki n = ip->curx - n; 1906 1.1 oki ip->curx = n >= 0 ? n : 0; 1907 1.1 oki ip->escape = 0; 1908 1.1 oki SUBR_CURSOR(ip, MOVE_CURSOR); 1909 1.1 oki clr_attr (ip, ATTR_INV); 1910 1.1 oki return; 1911 1.1 oki 1912 1.1 oki 1913 1.1 oki case 'J': 1914 1.1 oki /* erase screen */ 1915 1.1 oki *ip->ap = 0; 1916 1.1 oki n = ite_zargnum (ip); 1917 1.1 oki if (n == 0) 1918 1.1 oki ite_clrtoeos(ip); 1919 1.1 oki else if (n == 1) 1920 1.1 oki ite_clrtobos(ip); 1921 1.1 oki else if (n == 2) 1922 1.1 oki ite_clrscreen(ip); 1923 1.1 oki ip->escape = 0; 1924 1.1 oki return; 1925 1.1 oki 1926 1.1 oki 1927 1.1 oki case 'K': 1928 1.1 oki /* erase line */ 1929 1.1 oki n = ite_zargnum (ip); 1930 1.1 oki if (n == 0) 1931 1.1 oki ite_clrtoeol(ip); 1932 1.1 oki else if (n == 1) 1933 1.1 oki ite_clrtobol(ip); 1934 1.1 oki else if (n == 2) 1935 1.1 oki ite_clrline(ip); 1936 1.1 oki ip->escape = 0; 1937 1.1 oki return; 1938 1.1 oki 1939 1.1 oki case 'S': 1940 1.1 oki /* scroll up */ 1941 1.1 oki n = ite_zargnum (ip); 1942 1.1 oki if (n <= 0) 1943 1.1 oki n = 1; 1944 1.1 oki else if (n > ip->rows-1) 1945 1.1 oki n = ip->rows-1; 1946 1.1 oki SUBR_SCROLL(ip, ip->rows-1, 0, n, SCROLL_UP); 1947 1.1 oki ip->escape = 0; 1948 1.1 oki return; 1949 1.1 oki 1950 1.1 oki case 'T': 1951 1.1 oki /* scroll down */ 1952 1.1 oki n = ite_zargnum (ip); 1953 1.1 oki if (n <= 0) 1954 1.1 oki n = 1; 1955 1.1 oki else if (n > ip->rows-1) 1956 1.1 oki n = ip->rows-1; 1957 1.1 oki SUBR_SCROLL(ip, 0, 0, n, SCROLL_DOWN); 1958 1.1 oki ip->escape = 0; 1959 1.1 oki return; 1960 1.1 oki 1961 1.1 oki case 'X': 1962 1.1 oki /* erase character */ 1963 1.1 oki n = ite_argnum(ip) - 1; 1964 1.1 oki n = min(n, ip->cols - 1 - ip->curx); 1965 1.1 oki for (; n >= 0; n--) { 1966 1.1 oki attrclr(ip, ip->cury, ip->curx + n, 1, 1); 1967 1.1 oki SUBR_PUTC(ip, ' ', ip->cury, ip->curx + n, ATTR_NOR); 1968 1.1 oki } 1969 1.1 oki ip->escape = 0; 1970 1.1 oki return; 1971 1.1 oki 1972 1.1 oki 1973 1.1 oki case '}': case '`': 1974 1.1 oki /* status line control */ 1975 1.1 oki ip->escape = 0; 1976 1.1 oki return; 1977 1.1 oki 1978 1.1 oki case 'r': 1979 1.1 oki /* set scrolling region */ 1980 1.1 oki ip->escape = 0; 1981 1.1 oki *ip->ap = 0; 1982 1.1 oki x = atoi (ip->argbuf); 1983 1.1 oki x = x ? x : 1; 1984 1.1 oki y = ip->rows; 1985 1.1 oki cp = index (ip->argbuf, ';'); 1986 1.1 oki if (cp) { 1987 1.1 oki y = atoi (cp + 1); 1988 1.1 oki y = y ? y : ip->rows; 1989 1.1 oki } 1990 1.1 oki if (y <= x) 1991 1.1 oki return; 1992 1.1 oki x--; 1993 1.1 oki y--; 1994 1.1 oki ip->top_margin = min(x, ip->rows - 2); 1995 1.1 oki ip->bottom_margin = min(y, ip->rows - 1); 1996 1.1 oki if (ip->inside_margins) { 1997 1.1 oki ip->cury = ip->top_margin; 1998 1.1 oki } else 1999 1.1 oki ip->cury = 0; 2000 1.1 oki ip->curx = 0; 2001 1.1 oki return; 2002 1.1 oki 2003 1.1 oki 2004 1.1 oki case 'm': 2005 1.1 oki /* big attribute setter/resetter */ 2006 1.1 oki { 2007 1.1 oki char *cp; 2008 1.1 oki *ip->ap = 0; 2009 1.1 oki /* kludge to make CSIm work (== CSI0m) */ 2010 1.1 oki if (ip->ap == ip->argbuf) 2011 1.1 oki ip->ap++; 2012 1.1 oki for (cp = ip->argbuf; cp < ip->ap; ) { 2013 1.1 oki switch (*cp) { 2014 1.1 oki case 0: 2015 1.1 oki case '0': 2016 1.1 oki clr_attr (ip, ATTR_ALL); 2017 1.1 oki ip->fgcolor = 7; 2018 1.1 oki ip->bgcolor = 0; 2019 1.1 oki cp++; 2020 1.1 oki break; 2021 1.1 oki 2022 1.1 oki case '1': 2023 1.1 oki set_attr (ip, ATTR_BOLD); 2024 1.1 oki cp++; 2025 1.1 oki break; 2026 1.1 oki 2027 1.1 oki case '2': 2028 1.1 oki switch (cp[1]) { 2029 1.1 oki case '2': 2030 1.1 oki clr_attr (ip, ATTR_BOLD); 2031 1.1 oki cp += 2; 2032 1.1 oki break; 2033 1.1 oki 2034 1.1 oki case '4': 2035 1.1 oki clr_attr (ip, ATTR_UL); 2036 1.1 oki cp += 2; 2037 1.1 oki break; 2038 1.1 oki 2039 1.1 oki case '5': 2040 1.1 oki clr_attr (ip, ATTR_BLINK); 2041 1.1 oki cp += 2; 2042 1.1 oki break; 2043 1.1 oki 2044 1.1 oki case '7': 2045 1.1 oki clr_attr (ip, ATTR_INV); 2046 1.1 oki cp += 2; 2047 1.1 oki break; 2048 1.1 oki 2049 1.1 oki default: 2050 1.1 oki cp++; 2051 1.1 oki break; 2052 1.1 oki } 2053 1.1 oki break; 2054 1.1 oki 2055 1.1 oki case '3': 2056 1.1 oki switch (cp[1]) { 2057 1.1 oki case '0': case '1': case '2': case '3': 2058 1.1 oki case '4': case '5': case '6': case '7': 2059 1.1 oki /* foreground colors */ 2060 1.1 oki ip->fgcolor = cp[1] - '0'; 2061 1.1 oki cp += 2; 2062 1.1 oki break; 2063 1.1 oki default: 2064 1.1 oki cp++; 2065 1.1 oki break; 2066 1.1 oki } 2067 1.1 oki break; 2068 1.1 oki 2069 1.1 oki case '4': 2070 1.1 oki switch (cp[1]) { 2071 1.1 oki case '0': case '1': case '2': case '3': 2072 1.1 oki case '4': case '5': case '6': case '7': 2073 1.1 oki /* background colors */ 2074 1.1 oki ip->bgcolor = cp[1] - '0'; 2075 1.1 oki cp += 2; 2076 1.1 oki break; 2077 1.1 oki default: 2078 1.1 oki set_attr (ip, ATTR_UL); 2079 1.1 oki cp++; 2080 1.1 oki break; 2081 1.1 oki } 2082 1.1 oki break; 2083 1.1 oki 2084 1.1 oki case '5': 2085 1.1 oki set_attr (ip, ATTR_BLINK); 2086 1.1 oki cp++; 2087 1.1 oki break; 2088 1.1 oki 2089 1.1 oki case '7': 2090 1.1 oki set_attr (ip, ATTR_INV); 2091 1.1 oki cp++; 2092 1.1 oki break; 2093 1.1 oki 2094 1.1 oki default: 2095 1.1 oki cp++; 2096 1.1 oki break; 2097 1.1 oki } 2098 1.1 oki } 2099 1.1 oki 2100 1.1 oki } 2101 1.1 oki ip->escape = 0; 2102 1.1 oki return; 2103 1.1 oki 2104 1.1 oki 2105 1.1 oki case 'u': 2106 1.1 oki /* DECRQTSR */ 2107 1.1 oki ite_sendstr (ip, "\033P\033\\"); 2108 1.1 oki ip->escape = 0; 2109 1.1 oki return; 2110 1.1 oki 2111 1.1 oki default: 2112 1.1 oki ip->escape = 0; 2113 1.1 oki return; 2114 1.1 oki } 2115 1.1 oki break; 2116 1.1 oki 2117 1.1 oki 2118 1.1 oki 2119 1.1 oki case '?': /* CSI ? */ 2120 1.1 oki switch (c) { 2121 1.1 oki case '0': case '1': case '2': case '3': case '4': 2122 1.1 oki case '5': case '6': case '7': case '8': case '9': 2123 1.1 oki case ';': case '\"': case '$': 2124 1.1 oki /* Don't fill the last character; it's needed. */ 2125 1.1 oki /* XXX yeah, where ?? */ 2126 1.1 oki if (ip->ap < ip->argbuf + MAX_ARGSIZE - 1) 2127 1.1 oki *ip->ap++ = c; 2128 1.1 oki return; 2129 1.1 oki 2130 1.1 oki 2131 1.1 oki case 'n': 2132 1.1 oki /* Terminal Reports */ 2133 1.1 oki *ip->ap = 0; 2134 1.1 oki if (ip->ap == &ip->argbuf[2]) { 2135 1.1 oki if (!strncmp(ip->argbuf, "15", 2)) 2136 1.1 oki /* printer status: no printer */ 2137 1.1 oki ite_sendstr (ip, "\033[13n"); 2138 1.1 oki 2139 1.1 oki else if (!strncmp(ip->argbuf, "25", 2)) 2140 1.1 oki /* udk status */ 2141 1.1 oki ite_sendstr (ip, "\033[20n"); 2142 1.1 oki 2143 1.1 oki else if (!strncmp(ip->argbuf, "26", 2)) 2144 1.1 oki /* keyboard dialect: US */ 2145 1.1 oki ite_sendstr (ip, "\033[27;1n"); 2146 1.1 oki } 2147 1.1 oki ip->escape = 0; 2148 1.1 oki return; 2149 1.1 oki 2150 1.1 oki 2151 1.1 oki case 'h': /* set dec private modes */ 2152 1.1 oki case 'l': /* reset dec private modes */ 2153 1.1 oki n = ite_zargnum (ip); 2154 1.1 oki switch (n) { 2155 1.1 oki case 1: 2156 1.1 oki /* CKM - cursor key mode */ 2157 1.1 oki ip->cursor_appmode = (c == 'h'); 2158 1.1 oki break; 2159 1.1 oki 2160 1.1 oki case 3: 2161 1.1 oki /* 132/80 columns (132 == 'h') */ 2162 1.1 oki break; 2163 1.1 oki 2164 1.1 oki case 4: /* smooth scroll */ 2165 1.1 oki break; 2166 1.1 oki 2167 1.1 oki case 5: 2168 1.1 oki /* light background (=='h') /dark background(=='l') */ 2169 1.1 oki break; 2170 1.1 oki 2171 1.1 oki case 6: /* origin mode */ 2172 1.1 oki ip->inside_margins = (c == 'h'); 2173 1.1 oki #if 0 2174 1.1 oki ip->curx = 0; 2175 1.1 oki ip->cury = ip->inside_margins ? ip->top_margin : 0; 2176 1.1 oki SUBR_CURSOR(ip, MOVE_CURSOR); 2177 1.1 oki #endif 2178 1.1 oki break; 2179 1.1 oki 2180 1.1 oki case 7: /* auto wraparound */ 2181 1.1 oki ip->auto_wrap = (c == 'h'); 2182 1.1 oki break; 2183 1.1 oki 2184 1.1 oki case 8: /* keyboard repeat */ 2185 1.1 oki ip->key_repeat = (c == 'h'); 2186 1.1 oki break; 2187 1.1 oki 2188 1.1 oki case 20: /* newline mode */ 2189 1.1 oki ip->linefeed_newline = (c == 'h'); 2190 1.1 oki break; 2191 1.1 oki 2192 1.1 oki case 25: /* cursor on/off */ 2193 1.1 oki SUBR_CURSOR(ip, (c == 'h') ? DRAW_CURSOR : ERASE_CURSOR); 2194 1.1 oki break; 2195 1.1 oki } 2196 1.1 oki ip->escape = 0; 2197 1.1 oki return; 2198 1.1 oki 2199 1.1 oki case 'K': 2200 1.1 oki /* selective erase in line */ 2201 1.1 oki case 'J': 2202 1.1 oki /* selective erase in display */ 2203 1.1 oki 2204 1.1 oki default: 2205 1.1 oki ip->escape = 0; 2206 1.1 oki return; 2207 1.1 oki } 2208 1.1 oki break; 2209 1.1 oki 2210 1.1 oki 2211 1.1 oki default: 2212 1.1 oki ip->escape = 0; 2213 1.1 oki return; 2214 1.1 oki } 2215 1.1 oki } 2216 1.1 oki 2217 1.1 oki switch (c) { 2218 1.1 oki case 0x00: /* NUL */ 2219 1.1 oki case 0x01: /* SOH */ 2220 1.1 oki case 0x02: /* STX */ 2221 1.1 oki case 0x03: /* ETX */ 2222 1.1 oki case 0x04: /* EOT */ 2223 1.1 oki case 0x05: /* ENQ */ 2224 1.1 oki case 0x06: /* ACK */ 2225 1.1 oki break; 2226 1.1 oki 2227 1.1 oki case BEL: 2228 1.1 oki #if NBELL > 0 2229 1.8.2.1 cgd if (kbd_ite && ite_tty[kbd_ite->device.dv_unit]) 2230 1.1 oki opm_bell(); 2231 1.1 oki #endif 2232 1.1 oki break; 2233 1.1 oki 2234 1.1 oki case BS: 2235 1.1 oki if (--ip->curx < 0) 2236 1.1 oki ip->curx = 0; 2237 1.1 oki else 2238 1.1 oki SUBR_CURSOR(ip, MOVE_CURSOR); 2239 1.1 oki break; 2240 1.1 oki 2241 1.1 oki case HT: 2242 1.1 oki for (n = ip->curx + 1; n < ip->cols; n++) { 2243 1.1 oki if (ip->tabs[n]) { 2244 1.1 oki ip->curx = n; 2245 1.1 oki SUBR_CURSOR(ip, MOVE_CURSOR); 2246 1.1 oki break; 2247 1.1 oki } 2248 1.1 oki } 2249 1.1 oki break; 2250 1.1 oki 2251 1.1 oki case VT: /* VT is treated like LF */ 2252 1.1 oki case FF: /* so is FF */ 2253 1.1 oki case LF: 2254 1.1 oki /* cr->crlf distinction is done here, on output, 2255 1.1 oki not on input! */ 2256 1.1 oki if (ip->linefeed_newline) 2257 1.1 oki ite_crlf (ip); 2258 1.1 oki else 2259 1.1 oki ite_lf (ip); 2260 1.1 oki break; 2261 1.1 oki 2262 1.1 oki case CR: 2263 1.1 oki ite_cr (ip); 2264 1.1 oki break; 2265 1.1 oki 2266 1.1 oki 2267 1.1 oki case SO: 2268 1.1 oki ip->GL = &ip->G1; 2269 1.1 oki break; 2270 1.1 oki 2271 1.1 oki case SI: 2272 1.1 oki ip->GL = &ip->G0; 2273 1.1 oki break; 2274 1.1 oki 2275 1.1 oki case 0x10: /* DLE */ 2276 1.1 oki case 0x11: /* DC1/XON */ 2277 1.1 oki case 0x12: /* DC2 */ 2278 1.1 oki case 0x13: /* DC3/XOFF */ 2279 1.1 oki case 0x14: /* DC4 */ 2280 1.1 oki case 0x15: /* NAK */ 2281 1.1 oki case 0x16: /* SYN */ 2282 1.1 oki case 0x17: /* ETB */ 2283 1.1 oki break; 2284 1.1 oki 2285 1.1 oki case CAN: 2286 1.1 oki ip->escape = 0; /* cancel any escape sequence in progress */ 2287 1.1 oki break; 2288 1.1 oki 2289 1.1 oki case 0x19: /* EM */ 2290 1.1 oki break; 2291 1.1 oki 2292 1.1 oki case SUB: 2293 1.1 oki ip->escape = 0; /* dito, but see below */ 2294 1.1 oki /* should also display a reverse question mark!! */ 2295 1.1 oki break; 2296 1.1 oki 2297 1.1 oki case ESC: 2298 1.1 oki ip->escape = ESC; 2299 1.1 oki break; 2300 1.1 oki 2301 1.1 oki case 0x1c: /* FS */ 2302 1.1 oki case 0x1d: /* GS */ 2303 1.1 oki case 0x1e: /* RS */ 2304 1.1 oki case 0x1f: /* US */ 2305 1.1 oki break; 2306 1.1 oki 2307 1.1 oki /* now it gets weird.. 8bit control sequences.. */ 2308 1.1 oki case IND: /* index: move cursor down, scroll */ 2309 1.1 oki ite_index (ip); 2310 1.1 oki break; 2311 1.1 oki 2312 1.1 oki case NEL: /* next line. next line, first pos. */ 2313 1.1 oki ite_crlf (ip); 2314 1.1 oki break; 2315 1.1 oki 2316 1.1 oki case HTS: /* set horizontal tab */ 2317 1.1 oki if (ip->curx < ip->cols) 2318 1.1 oki ip->tabs[ip->curx] = 1; 2319 1.1 oki break; 2320 1.1 oki 2321 1.1 oki case RI: /* reverse index */ 2322 1.1 oki ite_rlf (ip); 2323 1.1 oki break; 2324 1.1 oki 2325 1.1 oki case SS2: /* go into G2 for one character */ 2326 1.1 oki ip->save_GL = ip->GR; /* GL XXX EUC */ 2327 1.1 oki ip->GR = &ip->G2; /* GL XXX */ 2328 1.1 oki break; 2329 1.1 oki 2330 1.1 oki case SS3: /* go into G3 for one character */ 2331 1.1 oki ip->save_GL = ip->GR; /* GL XXX EUC */ 2332 1.1 oki ip->GR = &ip->G3; /* GL XXX */ 2333 1.1 oki break; 2334 1.1 oki 2335 1.1 oki case DCS: /* device control string introducer */ 2336 1.1 oki ip->escape = DCS; 2337 1.1 oki ip->ap = ip->argbuf; 2338 1.1 oki break; 2339 1.1 oki 2340 1.1 oki case CSI: /* control sequence introducer */ 2341 1.1 oki ip->escape = CSI; 2342 1.1 oki ip->ap = ip->argbuf; 2343 1.1 oki break; 2344 1.1 oki 2345 1.1 oki case ST: /* string terminator */ 2346 1.1 oki /* ignore, if not used as terminator */ 2347 1.1 oki break; 2348 1.1 oki 2349 1.1 oki case OSC: /* introduces OS command. Ignore everything upto ST */ 2350 1.1 oki ip->escape = OSC; 2351 1.1 oki break; 2352 1.1 oki 2353 1.1 oki case PM: /* privacy message, ignore everything upto ST */ 2354 1.1 oki ip->escape = PM; 2355 1.1 oki break; 2356 1.1 oki 2357 1.1 oki case APC: /* application program command, ignore everything upto ST */ 2358 1.1 oki ip->escape = APC; 2359 1.1 oki break; 2360 1.1 oki 2361 1.1 oki case DEL: 2362 1.1 oki break; 2363 1.1 oki 2364 1.1 oki default: 2365 1.1 oki if (!ip->save_char && (*((c & 0x80) ? ip->GR : ip->GL) & CSET_MULTI)) { 2366 1.1 oki ip->save_char = c; 2367 1.1 oki break; 2368 1.1 oki } 2369 1.1 oki if (ip->imode) 2370 1.1 oki ite_inchar(ip, ip->save_char ? 2 : 1); 2371 1.1 oki iteprecheckwrap(ip); 2372 1.1 oki #ifdef DO_WEIRD_ATTRIBUTES 2373 1.1 oki if ((ip->attribute & ATTR_INV) || attrtest(ip, ATTR_INV)) { 2374 1.1 oki attrset(ip, ATTR_INV); 2375 1.1 oki SUBR_PUTC(ip, c, ip->cury, ip->curx, ATTR_INV); 2376 1.1 oki } 2377 1.1 oki else 2378 1.1 oki SUBR_PUTC(ip, c, ip->cury, ip->curx, ATTR_NOR); 2379 1.1 oki #else 2380 1.1 oki SUBR_PUTC(ip, c, ip->cury, ip->curx, ip->attribute); 2381 1.1 oki #endif 2382 1.1 oki /* SUBR_CURSOR(ip, DRAW_CURSOR);*/ 2383 1.1 oki itecheckwrap(ip); 2384 1.1 oki if (ip->save_char) { 2385 1.1 oki itecheckwrap(ip); 2386 1.1 oki ip->save_char = 0; 2387 1.1 oki } 2388 1.1 oki if (ip->save_GL) { 2389 1.1 oki /* 2390 1.1 oki * reset single shift 2391 1.1 oki */ 2392 1.1 oki ip->GR = ip->save_GL; 2393 1.1 oki ip->save_GL = 0; 2394 1.1 oki } 2395 1.1 oki break; 2396 1.1 oki } 2397 1.1 oki } 2398 1.1 oki 2399 1.1 oki static void 2400 1.1 oki iteprecheckwrap(ip) 2401 1.1 oki struct ite_softc *ip; 2402 1.1 oki { 2403 1.1 oki if (ip->auto_wrap && ip->curx + (ip->save_char ? 1 : 0) == ip->cols) { 2404 1.1 oki ip->curx = 0; 2405 1.1 oki clr_attr(ip, ATTR_INV); 2406 1.1 oki if (++ip->cury >= ip->bottom_margin + 1) { 2407 1.1 oki ip->cury = ip->bottom_margin; 2408 1.1 oki /*SUBR_CURSOR(ip, MOVE_CURSOR);*/ 2409 1.1 oki SUBR_SCROLL(ip, ip->top_margin + 1, 0, 1, SCROLL_UP); 2410 1.1 oki ite_clrtoeol(ip); 2411 1.1 oki } /*else 2412 1.1 oki SUBR_CURSOR(ip, MOVE_CURSOR);*/ 2413 1.1 oki } 2414 1.1 oki } 2415 1.1 oki 2416 1.1 oki static void 2417 1.1 oki itecheckwrap(ip) 2418 1.1 oki struct ite_softc *ip; 2419 1.1 oki { 2420 1.1 oki #if 0 2421 1.1 oki if (++ip->curx == ip->cols) { 2422 1.1 oki if (ip->auto_wrap) { 2423 1.1 oki ip->curx = 0; 2424 1.1 oki clr_attr(ip, ATTR_INV); 2425 1.1 oki if (++ip->cury >= ip->bottom_margin + 1) { 2426 1.1 oki ip->cury = ip->bottom_margin; 2427 1.1 oki SUBR_CURSOR(ip, MOVE_CURSOR); 2428 1.1 oki SUBR_SCROLL(ip, ip->top_margin + 1, 0, 1, SCROLL_UP); 2429 1.1 oki ite_clrtoeol(ip); 2430 1.1 oki return; 2431 1.1 oki } 2432 1.1 oki } else 2433 1.1 oki /* stay there if no autowrap.. */ 2434 1.1 oki ip->curx--; 2435 1.1 oki } 2436 1.1 oki #else 2437 1.1 oki if (ip->curx < ip->cols) { 2438 1.1 oki ip->curx++; 2439 1.1 oki /*SUBR_CURSOR(ip, MOVE_CURSOR);*/ 2440 1.1 oki } 2441 1.1 oki #endif 2442 1.1 oki } 2443 1.1 oki 2444 1.1 oki #endif 2445 1.1 oki 2446 1.1 oki /* 2447 1.1 oki * Console functions 2448 1.1 oki */ 2449 1.1 oki #include <dev/cons.h> 2450 1.1 oki 2451 1.1 oki /* 2452 1.1 oki * Return a priority in consdev->cn_pri field highest wins. This function 2453 1.1 oki * is called before any devices have been probed. 2454 1.1 oki */ 2455 1.1 oki void 2456 1.1 oki itecnprobe(cd) 2457 1.1 oki struct consdev *cd; 2458 1.1 oki { 2459 1.2 oki int maj; 2460 1.1 oki 2461 1.1 oki /* 2462 1.1 oki * bring graphics layer up. 2463 1.1 oki */ 2464 1.1 oki config_console(); 2465 1.1 oki 2466 1.1 oki /* locate the major number */ 2467 1.1 oki for (maj = 0; maj < nchrdev; maj++) 2468 1.1 oki if (cdevsw[maj].d_open == iteopen) 2469 1.1 oki break; 2470 1.1 oki 2471 1.1 oki /* 2472 1.1 oki * return priority of the best ite (already picked from attach) 2473 1.1 oki * or CN_DEAD. 2474 1.1 oki */ 2475 1.1 oki if (con_itesoftc.grf == NULL) 2476 1.1 oki cd->cn_pri = CN_DEAD; 2477 1.1 oki else { 2478 1.1 oki con_itesoftc.flags = (ITE_ALIVE|ITE_CONSOLE); 2479 1.1 oki con_itesoftc.isw = &itesw[0]; /* XXX */ 2480 1.1 oki cd->cn_pri = CN_INTERNAL; 2481 1.1 oki cd->cn_dev = makedev(maj, 0); /* XXX */ 2482 1.1 oki } 2483 1.1 oki 2484 1.1 oki } 2485 1.1 oki 2486 1.1 oki void 2487 1.1 oki itecninit(cd) 2488 1.1 oki struct consdev *cd; 2489 1.1 oki { 2490 1.1 oki struct ite_softc *ip; 2491 1.1 oki 2492 1.1 oki ip = getitesp(cd->cn_dev); 2493 1.1 oki iteinit(cd->cn_dev); /* init console unit */ 2494 1.1 oki ip->flags |= ITE_ACTIVE | ITE_ISCONS; 2495 1.1 oki } 2496 1.1 oki 2497 1.1 oki /* 2498 1.1 oki * itecnfinish() is called in ite_init() when the device is 2499 1.1 oki * being probed in the normal fasion, thus we can finish setting 2500 1.1 oki * up this ite now that the system is more functional. 2501 1.1 oki */ 2502 1.1 oki void 2503 1.1 oki itecnfinish(ip) 2504 1.1 oki struct ite_softc *ip; 2505 1.1 oki { 2506 1.1 oki static int done; 2507 1.1 oki 2508 1.1 oki if (done) 2509 1.1 oki return; 2510 1.1 oki done = 1; 2511 1.1 oki } 2512 1.1 oki 2513 1.1 oki /*ARGSUSED*/ 2514 1.1 oki int 2515 1.1 oki itecngetc(dev) 2516 1.1 oki dev_t dev; 2517 1.1 oki { 2518 1.1 oki register int c; 2519 1.1 oki 2520 1.1 oki /* XXX this should be moved */ 2521 1.1 oki if (!kbd_init) { 2522 1.1 oki kbd_init = 1; 2523 1.1 oki kbdenable(); 2524 1.1 oki } 2525 1.1 oki do { 2526 1.1 oki c = kbdgetcn(); 2527 1.8 oki c = ite_cnfilter(c, ITEFILT_CONSOLE); 2528 1.1 oki } while (c == -1); 2529 1.1 oki return (c); 2530 1.1 oki } 2531 1.1 oki 2532 1.1 oki void 2533 1.1 oki itecnputc(dev, c) 2534 1.1 oki dev_t dev; 2535 1.1 oki int c; 2536 1.1 oki { 2537 1.1 oki static int paniced = 0; 2538 1.1 oki struct ite_softc *ip = getitesp(dev); 2539 1.1 oki char ch = c; 2540 1.1 oki 2541 1.1 oki if (panicstr && !paniced && 2542 1.1 oki (ip->flags & (ITE_ACTIVE|ITE_INGRF)) != ITE_ACTIVE) { 2543 1.1 oki (void) iteon(dev, 3); 2544 1.1 oki paniced = 1; 2545 1.1 oki } 2546 1.1 oki ite_putstr(&ch, 1, dev); 2547 1.1 oki } 2548
Indexes created Wed Oct 01 19:09:53 GMT 2025