clmpcc.c revision 1.7.2.2
1 1.7.2.2 bouyer /* $NetBSD: clmpcc.c,v 1.7.2.2 2000/11/22 16:03:14 bouyer Exp $ */ 2 1.1 scw 3 1.1 scw /*- 4 1.1 scw * Copyright (c) 1999 The NetBSD Foundation, Inc. 5 1.1 scw * All rights reserved. 6 1.1 scw * 7 1.1 scw * This code is derived from software contributed to The NetBSD Foundation 8 1.1 scw * by Steve C. Woodford. 9 1.1 scw * 10 1.1 scw * Redistribution and use in source and binary forms, with or without 11 1.1 scw * modification, are permitted provided that the following conditions 12 1.1 scw * are met: 13 1.1 scw * 1. Redistributions of source code must retain the above copyright 14 1.1 scw * notice, this list of conditions and the following disclaimer. 15 1.1 scw * 2. Redistributions in binary form must reproduce the above copyright 16 1.1 scw * notice, this list of conditions and the following disclaimer in the 17 1.1 scw * documentation and/or other materials provided with the distribution. 18 1.1 scw * 3. All advertising materials mentioning features or use of this software 19 1.1 scw * must display the following acknowledgement: 20 1.1 scw * This product includes software developed by the NetBSD 21 1.1 scw * Foundation, Inc. and its contributors. 22 1.1 scw * 4. Neither the name of The NetBSD Foundation nor the names of its 23 1.1 scw * contributors may be used to endorse or promote products derived 24 1.1 scw * from this software without specific prior written permission. 25 1.1 scw * 26 1.1 scw * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 27 1.1 scw * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 28 1.1 scw * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 29 1.1 scw * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 30 1.1 scw * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 31 1.1 scw * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 32 1.1 scw * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 33 1.1 scw * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 34 1.1 scw * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 35 1.1 scw * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 36 1.1 scw * POSSIBILITY OF SUCH DAMAGE. 37 1.1 scw */ 38 1.1 scw 39 1.1 scw /* 40 1.1 scw * Cirrus Logic CD2400/CD2401 Four Channel Multi-Protocol Comms. Controller. 41 1.1 scw */ 42 1.1 scw 43 1.1 scw #include "opt_ddb.h" 44 1.1 scw 45 1.1 scw #include <sys/types.h> 46 1.1 scw #include <sys/param.h> 47 1.1 scw #include <sys/systm.h> 48 1.1 scw #include <sys/ioctl.h> 49 1.1 scw #include <sys/select.h> 50 1.1 scw #include <sys/tty.h> 51 1.1 scw #include <sys/proc.h> 52 1.1 scw #include <sys/user.h> 53 1.1 scw #include <sys/conf.h> 54 1.1 scw #include <sys/file.h> 55 1.1 scw #include <sys/uio.h> 56 1.1 scw #include <sys/kernel.h> 57 1.1 scw #include <sys/syslog.h> 58 1.1 scw #include <sys/device.h> 59 1.1 scw #include <sys/malloc.h> 60 1.1 scw 61 1.1 scw #include <machine/bus.h> 62 1.7.2.1 bouyer #include <machine/intr.h> 63 1.3 scw #include <machine/param.h> 64 1.1 scw 65 1.1 scw #include <dev/ic/clmpccreg.h> 66 1.1 scw #include <dev/ic/clmpccvar.h> 67 1.1 scw #include <dev/cons.h> 68 1.1 scw 69 1.1 scw 70 1.1 scw #if defined(CLMPCC_ONLY_BYTESWAP_LOW) && defined(CLMPCC_ONLY_BYTESWAP_HIGH) 71 1.1 scw #error "CLMPCC_ONLY_BYTESWAP_LOW and CLMPCC_ONLY_BYTESWAP_HIGH are mutually exclusive." 72 1.1 scw #endif 73 1.1 scw 74 1.2 scw 75 1.1 scw static int clmpcc_init __P((struct clmpcc_softc *sc)); 76 1.1 scw static void clmpcc_shutdown __P((struct clmpcc_chan *)); 77 1.1 scw static int clmpcc_speed __P((struct clmpcc_softc *, speed_t, 78 1.1 scw int *, int *)); 79 1.1 scw static int clmpcc_param __P((struct tty *, struct termios *)); 80 1.2 scw static void clmpcc_set_params __P((struct clmpcc_chan *)); 81 1.1 scw static void clmpcc_start __P((struct tty *)); 82 1.1 scw static int clmpcc_modem_control __P((struct clmpcc_chan *, int, int)); 83 1.1 scw 84 1.1 scw 85 1.1 scw cdev_decl(clmpcc); 86 1.1 scw 87 1.1 scw #define CLMPCCUNIT(x) (minor(x) & 0x7fffc) 88 1.1 scw #define CLMPCCCHAN(x) (minor(x) & 0x00003) 89 1.1 scw #define CLMPCCDIALOUT(x) (minor(x) & 0x80000) 90 1.1 scw 91 1.1 scw /* 92 1.1 scw * These should be in a header file somewhere... 93 1.1 scw */ 94 1.1 scw #define ISSET(v, f) (((v) & (f)) != 0) 95 1.1 scw #define ISCLR(v, f) (((v) & (f)) == 0) 96 1.1 scw #define SET(v, f) (v) |= (f) 97 1.1 scw #define CLR(v, f) (v) &= ~(f) 98 1.1 scw 99 1.1 scw 100 1.1 scw extern struct cfdriver clmpcc_cd; 101 1.1 scw 102 1.1 scw 103 1.1 scw /* 104 1.1 scw * Make this an option variable one can patch. 105 1.1 scw */ 106 1.1 scw u_int clmpcc_ibuf_size = CLMPCC_RING_SIZE; 107 1.1 scw 108 1.1 scw 109 1.1 scw /* 110 1.1 scw * Things needed when the device is used as a console 111 1.1 scw */ 112 1.1 scw static struct clmpcc_softc *cons_sc = NULL; 113 1.1 scw static int cons_chan; 114 1.1 scw static int cons_rate; 115 1.1 scw 116 1.1 scw static int clmpcc_common_getc __P((struct clmpcc_softc *, int)); 117 1.1 scw static void clmpcc_common_putc __P((struct clmpcc_softc *, int, int)); 118 1.1 scw int clmpcccngetc __P((dev_t)); 119 1.1 scw void clmpcccnputc __P((dev_t, int)); 120 1.1 scw 121 1.1 scw 122 1.1 scw /* 123 1.1 scw * Convenience functions, inlined for speed 124 1.1 scw */ 125 1.1 scw #define integrate static inline 126 1.1 scw integrate u_int8_t clmpcc_rdreg __P((struct clmpcc_softc *, u_int)); 127 1.1 scw integrate void clmpcc_wrreg __P((struct clmpcc_softc *, u_int, u_int)); 128 1.1 scw integrate u_int8_t clmpcc_rdreg_odd __P((struct clmpcc_softc *, u_int)); 129 1.1 scw integrate void clmpcc_wrreg_odd __P((struct clmpcc_softc *, u_int, u_int)); 130 1.6 scw integrate void clmpcc_wrtx_multi __P((struct clmpcc_softc *, u_int8_t *, 131 1.6 scw u_int)); 132 1.1 scw integrate u_int8_t clmpcc_select_channel __P((struct clmpcc_softc *, u_int)); 133 1.1 scw integrate void clmpcc_channel_cmd __P((struct clmpcc_softc *,int,int)); 134 1.1 scw integrate void clmpcc_enable_transmitter __P((struct clmpcc_chan *)); 135 1.1 scw 136 1.1 scw #define clmpcc_rd_msvr(s) clmpcc_rdreg_odd(s,CLMPCC_REG_MSVR) 137 1.1 scw #define clmpcc_wr_msvr(s,r,v) clmpcc_wrreg_odd(s,r,v) 138 1.1 scw #define clmpcc_wr_pilr(s,r,v) clmpcc_wrreg_odd(s,r,v) 139 1.1 scw #define clmpcc_rd_rxdata(s) clmpcc_rdreg_odd(s,CLMPCC_REG_RDR) 140 1.1 scw #define clmpcc_wr_txdata(s,v) clmpcc_wrreg_odd(s,CLMPCC_REG_TDR,v) 141 1.1 scw 142 1.1 scw 143 1.1 scw integrate u_int8_t 144 1.1 scw clmpcc_rdreg(sc, offset) 145 1.1 scw struct clmpcc_softc *sc; 146 1.1 scw u_int offset; 147 1.1 scw { 148 1.1 scw #if !defined(CLMPCC_ONLY_BYTESWAP_LOW) && !defined(CLMPCC_ONLY_BYTESWAP_HIGH) 149 1.1 scw offset ^= sc->sc_byteswap; 150 1.1 scw #elif defined(CLMPCC_ONLY_BYTESWAP_HIGH) 151 1.1 scw offset ^= CLMPCC_BYTESWAP_HIGH; 152 1.1 scw #endif 153 1.1 scw return bus_space_read_1(sc->sc_iot, sc->sc_ioh, offset); 154 1.1 scw } 155 1.1 scw 156 1.1 scw integrate void 157 1.1 scw clmpcc_wrreg(sc, offset, val) 158 1.1 scw struct clmpcc_softc *sc; 159 1.1 scw u_int offset; 160 1.1 scw u_int val; 161 1.1 scw { 162 1.1 scw #if !defined(CLMPCC_ONLY_BYTESWAP_LOW) && !defined(CLMPCC_ONLY_BYTESWAP_HIGH) 163 1.1 scw offset ^= sc->sc_byteswap; 164 1.1 scw #elif defined(CLMPCC_ONLY_BYTESWAP_HIGH) 165 1.1 scw offset ^= CLMPCC_BYTESWAP_HIGH; 166 1.1 scw #endif 167 1.1 scw bus_space_write_1(sc->sc_iot, sc->sc_ioh, offset, val); 168 1.1 scw } 169 1.1 scw 170 1.1 scw integrate u_int8_t 171 1.1 scw clmpcc_rdreg_odd(sc, offset) 172 1.1 scw struct clmpcc_softc *sc; 173 1.1 scw u_int offset; 174 1.1 scw { 175 1.1 scw #if !defined(CLMPCC_ONLY_BYTESWAP_LOW) && !defined(CLMPCC_ONLY_BYTESWAP_HIGH) 176 1.1 scw offset ^= (sc->sc_byteswap & 2); 177 1.1 scw #elif defined(CLMPCC_ONLY_BYTESWAP_HIGH) 178 1.1 scw offset ^= (CLMPCC_BYTESWAP_HIGH & 2); 179 1.1 scw #endif 180 1.1 scw return bus_space_read_1(sc->sc_iot, sc->sc_ioh, offset); 181 1.1 scw } 182 1.1 scw 183 1.1 scw integrate void 184 1.1 scw clmpcc_wrreg_odd(sc, offset, val) 185 1.1 scw struct clmpcc_softc *sc; 186 1.1 scw u_int offset; 187 1.1 scw u_int val; 188 1.1 scw { 189 1.1 scw #if !defined(CLMPCC_ONLY_BYTESWAP_LOW) && !defined(CLMPCC_ONLY_BYTESWAP_HIGH) 190 1.1 scw offset ^= (sc->sc_byteswap & 2); 191 1.1 scw #elif defined(CLMPCC_ONLY_BYTESWAP_HIGH) 192 1.1 scw offset ^= (CLMPCC_BYTESWAP_HIGH & 2); 193 1.1 scw #endif 194 1.1 scw bus_space_write_1(sc->sc_iot, sc->sc_ioh, offset, val); 195 1.1 scw } 196 1.1 scw 197 1.6 scw integrate void 198 1.6 scw clmpcc_wrtx_multi(sc, buff, count) 199 1.6 scw struct clmpcc_softc *sc; 200 1.6 scw u_int8_t *buff; 201 1.6 scw u_int count; 202 1.6 scw { 203 1.6 scw u_int offset = CLMPCC_REG_TDR; 204 1.6 scw 205 1.6 scw #if !defined(CLMPCC_ONLY_BYTESWAP_LOW) && !defined(CLMPCC_ONLY_BYTESWAP_HIGH) 206 1.6 scw offset ^= (sc->sc_byteswap & 2); 207 1.6 scw #elif defined(CLMPCC_ONLY_BYTESWAP_HIGH) 208 1.6 scw offset ^= (CLMPCC_BYTESWAP_HIGH & 2); 209 1.6 scw #endif 210 1.6 scw bus_space_write_multi_1(sc->sc_iot, sc->sc_ioh, offset, buff, count); 211 1.6 scw } 212 1.6 scw 213 1.1 scw integrate u_int8_t 214 1.1 scw clmpcc_select_channel(sc, new_chan) 215 1.1 scw struct clmpcc_softc *sc; 216 1.1 scw u_int new_chan; 217 1.1 scw { 218 1.1 scw u_int old_chan = clmpcc_rdreg_odd(sc, CLMPCC_REG_CAR); 219 1.1 scw 220 1.1 scw clmpcc_wrreg_odd(sc, CLMPCC_REG_CAR, new_chan); 221 1.1 scw 222 1.1 scw return old_chan; 223 1.1 scw } 224 1.1 scw 225 1.1 scw integrate void 226 1.1 scw clmpcc_channel_cmd(sc, chan, cmd) 227 1.1 scw struct clmpcc_softc *sc; 228 1.1 scw int chan; 229 1.1 scw int cmd; 230 1.1 scw { 231 1.1 scw int i; 232 1.1 scw 233 1.1 scw for (i = 5000; i; i--) { 234 1.1 scw if ( clmpcc_rdreg(sc, CLMPCC_REG_CCR) == 0 ) 235 1.1 scw break; 236 1.1 scw delay(1); 237 1.1 scw } 238 1.1 scw 239 1.1 scw if ( i == 0 ) 240 1.1 scw printf("%s: channel %d command timeout (idle)\n", 241 1.1 scw sc->sc_dev.dv_xname, chan); 242 1.1 scw 243 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_CCR, cmd); 244 1.1 scw } 245 1.1 scw 246 1.1 scw integrate void 247 1.1 scw clmpcc_enable_transmitter(ch) 248 1.1 scw struct clmpcc_chan *ch; 249 1.1 scw { 250 1.1 scw u_int old; 251 1.2 scw int s; 252 1.1 scw 253 1.1 scw old = clmpcc_select_channel(ch->ch_sc, ch->ch_car); 254 1.1 scw 255 1.2 scw s = splserial(); 256 1.1 scw clmpcc_wrreg(ch->ch_sc, CLMPCC_REG_IER, 257 1.1 scw clmpcc_rdreg(ch->ch_sc, CLMPCC_REG_IER) | CLMPCC_IER_TX_EMPTY); 258 1.2 scw SET(ch->ch_tty->t_state, TS_BUSY); 259 1.2 scw splx(s); 260 1.2 scw 261 1.1 scw clmpcc_select_channel(ch->ch_sc, old); 262 1.1 scw } 263 1.1 scw 264 1.1 scw static int 265 1.1 scw clmpcc_speed(sc, speed, cor, bpr) 266 1.1 scw struct clmpcc_softc *sc; 267 1.1 scw speed_t speed; 268 1.1 scw int *cor, *bpr; 269 1.1 scw { 270 1.1 scw int c, co, br; 271 1.1 scw 272 1.1 scw for (co = 0, c = 8; c <= 2048; co++, c *= 4) { 273 1.1 scw br = ((sc->sc_clk / c) / speed) - 1; 274 1.1 scw if ( br < 0x100 ) { 275 1.1 scw *cor = co; 276 1.1 scw *bpr = br; 277 1.1 scw return 0; 278 1.1 scw } 279 1.1 scw } 280 1.1 scw 281 1.1 scw return -1; 282 1.1 scw } 283 1.1 scw 284 1.1 scw void 285 1.1 scw clmpcc_attach(sc) 286 1.1 scw struct clmpcc_softc *sc; 287 1.1 scw { 288 1.1 scw struct clmpcc_chan *ch; 289 1.1 scw struct tty *tp; 290 1.1 scw int chan; 291 1.1 scw 292 1.1 scw if ( cons_sc != NULL && 293 1.1 scw sc->sc_iot == cons_sc->sc_iot && sc->sc_ioh == cons_sc->sc_ioh ) 294 1.1 scw cons_sc = sc; 295 1.1 scw 296 1.1 scw /* Initialise the chip */ 297 1.1 scw clmpcc_init(sc); 298 1.1 scw 299 1.1 scw printf(": Cirrus Logic CD240%c Serial Controller\n", 300 1.1 scw (clmpcc_rd_msvr(sc) & CLMPCC_MSVR_PORT_ID) ? '0' : '1'); 301 1.1 scw 302 1.7.2.1 bouyer #ifndef __GENERIC_SOFT_INTERRUPTS 303 1.1 scw sc->sc_soft_running = 0; 304 1.7.2.1 bouyer #else 305 1.7.2.1 bouyer sc->sc_softintr_cookie = 306 1.7.2.1 bouyer softintr_establish(IPL_SOFTSERIAL, clmpcc_softintr, sc); 307 1.7.2.1 bouyer #ifdef DEBUG 308 1.7.2.1 bouyer if (sc->sc_softintr_cookie == NULL) 309 1.7.2.1 bouyer panic("clmpcc_attach: softintr_establish"); 310 1.7.2.1 bouyer #endif 311 1.7.2.1 bouyer #endif 312 1.1 scw memset(&(sc->sc_chans[0]), 0, sizeof(sc->sc_chans)); 313 1.1 scw 314 1.1 scw for (chan = 0; chan < CLMPCC_NUM_CHANS; chan++) { 315 1.1 scw ch = &sc->sc_chans[chan]; 316 1.1 scw 317 1.1 scw ch->ch_sc = sc; 318 1.1 scw ch->ch_car = chan; 319 1.1 scw 320 1.1 scw tp = ttymalloc(); 321 1.1 scw tp->t_oproc = clmpcc_start; 322 1.1 scw tp->t_param = clmpcc_param; 323 1.1 scw 324 1.1 scw ch->ch_tty = tp; 325 1.1 scw 326 1.1 scw ch->ch_ibuf = malloc(clmpcc_ibuf_size * 2, M_DEVBUF, M_NOWAIT); 327 1.1 scw if ( ch->ch_ibuf == NULL ) { 328 1.1 scw printf("%s(%d): unable to allocate ring buffer\n", 329 1.1 scw sc->sc_dev.dv_xname, chan); 330 1.1 scw return; 331 1.1 scw } 332 1.1 scw 333 1.1 scw ch->ch_ibuf_end = &(ch->ch_ibuf[clmpcc_ibuf_size * 2]); 334 1.1 scw ch->ch_ibuf_rd = ch->ch_ibuf_wr = ch->ch_ibuf; 335 1.1 scw 336 1.1 scw tty_attach(tp); 337 1.1 scw } 338 1.1 scw 339 1.1 scw printf("%s: %d channels available", sc->sc_dev.dv_xname, 340 1.1 scw CLMPCC_NUM_CHANS); 341 1.1 scw if ( cons_sc == sc ) { 342 1.1 scw printf(", console on channel %d.\n", cons_chan); 343 1.1 scw SET(sc->sc_chans[cons_chan].ch_flags, CLMPCC_FLG_IS_CONSOLE); 344 1.1 scw SET(sc->sc_chans[cons_chan].ch_openflags, TIOCFLAG_SOFTCAR); 345 1.1 scw } else 346 1.1 scw printf(".\n"); 347 1.1 scw } 348 1.1 scw 349 1.1 scw static int 350 1.1 scw clmpcc_init(sc) 351 1.1 scw struct clmpcc_softc *sc; 352 1.1 scw { 353 1.1 scw u_int tcor, tbpr; 354 1.1 scw u_int rcor, rbpr; 355 1.1 scw u_int msvr_rts, msvr_dtr; 356 1.1 scw u_int ccr; 357 1.1 scw int is_console; 358 1.1 scw int i; 359 1.1 scw 360 1.1 scw /* 361 1.1 scw * All we're really concerned about here is putting the chip 362 1.1 scw * into a quiescent state so that it won't do anything until 363 1.1 scw * clmpccopen() is called. (Except the console channel.) 364 1.1 scw */ 365 1.1 scw 366 1.1 scw /* 367 1.1 scw * If the chip is acting as console, set all channels to the supplied 368 1.1 scw * console baud rate. Otherwise, plump for 9600. 369 1.1 scw */ 370 1.1 scw if ( cons_sc && 371 1.1 scw sc->sc_ioh == cons_sc->sc_ioh && sc->sc_iot == cons_sc->sc_iot ) { 372 1.1 scw clmpcc_speed(sc, cons_rate, &tcor, &tbpr); 373 1.1 scw clmpcc_speed(sc, cons_rate, &rcor, &rbpr); 374 1.1 scw is_console = 1; 375 1.1 scw } else { 376 1.1 scw clmpcc_speed(sc, 9600, &tcor, &tbpr); 377 1.1 scw clmpcc_speed(sc, 9600, &rcor, &rbpr); 378 1.1 scw is_console = 0; 379 1.1 scw } 380 1.1 scw 381 1.1 scw /* Allow any pending output to be sent */ 382 1.1 scw delay(10000); 383 1.1 scw 384 1.1 scw /* Send the Reset All command to channel 0 (resets all channels!) */ 385 1.1 scw clmpcc_channel_cmd(sc, 0, CLMPCC_CCR_T0_RESET_ALL); 386 1.1 scw 387 1.1 scw delay(1000); 388 1.1 scw 389 1.1 scw /* 390 1.1 scw * The chip will set it's firmware revision register to a non-zero 391 1.1 scw * value to indicate completion of reset. 392 1.1 scw */ 393 1.1 scw for (i = 10000; clmpcc_rdreg(sc, CLMPCC_REG_GFRCR) == 0 && i; i--) 394 1.1 scw delay(1); 395 1.1 scw 396 1.1 scw if ( i == 0 ) { 397 1.1 scw /* 398 1.1 scw * Watch out... If this chip is console, the message 399 1.1 scw * probably won't be sent since we just reset it! 400 1.1 scw */ 401 1.1 scw printf("%s: Failed to reset chip\n", sc->sc_dev.dv_xname); 402 1.1 scw return -1; 403 1.1 scw } 404 1.1 scw 405 1.1 scw for (i = 0; i < CLMPCC_NUM_CHANS; i++) { 406 1.1 scw clmpcc_select_channel(sc, i); 407 1.1 scw 408 1.1 scw /* All interrupts are disabled to begin with */ 409 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_IER, 0); 410 1.1 scw 411 1.1 scw /* Make sure the channel interrupts on the correct vectors */ 412 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_LIVR, sc->sc_vector_base); 413 1.1 scw clmpcc_wr_pilr(sc, CLMPCC_REG_RPILR, sc->sc_rpilr); 414 1.1 scw clmpcc_wr_pilr(sc, CLMPCC_REG_TPILR, sc->sc_tpilr); 415 1.1 scw clmpcc_wr_pilr(sc, CLMPCC_REG_MPILR, sc->sc_mpilr); 416 1.1 scw 417 1.1 scw /* Receive timer prescaler set to 1ms */ 418 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_TPR, 419 1.1 scw CLMPCC_MSEC_TO_TPR(sc->sc_clk, 1)); 420 1.1 scw 421 1.1 scw /* We support Async mode only */ 422 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_CMR, CLMPCC_CMR_ASYNC); 423 1.1 scw 424 1.1 scw /* Set the required baud rate */ 425 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_TCOR, CLMPCC_TCOR_CLK(tcor)); 426 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_TBPR, tbpr); 427 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_RCOR, CLMPCC_RCOR_CLK(rcor)); 428 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_RBPR, rbpr); 429 1.1 scw 430 1.1 scw /* Always default to 8N1 (XXX what about console?) */ 431 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_COR1, CLMPCC_COR1_CHAR_8BITS | 432 1.1 scw CLMPCC_COR1_NO_PARITY | 433 1.1 scw CLMPCC_COR1_IGNORE_PAR); 434 1.1 scw 435 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_COR2, 0); 436 1.1 scw 437 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_COR3, CLMPCC_COR3_STOP_1); 438 1.1 scw 439 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_COR4, CLMPCC_COR4_DSRzd | 440 1.1 scw CLMPCC_COR4_CDzd | 441 1.1 scw CLMPCC_COR4_CTSzd); 442 1.1 scw 443 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_COR5, CLMPCC_COR5_DSRod | 444 1.1 scw CLMPCC_COR5_CDod | 445 1.1 scw CLMPCC_COR5_CTSod | 446 1.1 scw CLMPCC_COR5_FLOW_NORM); 447 1.1 scw 448 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_COR6, 0); 449 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_COR7, 0); 450 1.1 scw 451 1.1 scw /* Set the receive FIFO timeout */ 452 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_RTPRl, CLMPCC_RTPR_DEFAULT); 453 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_RTPRh, 0); 454 1.1 scw 455 1.1 scw /* At this point, we set up the console differently */ 456 1.1 scw if ( is_console && i == cons_chan ) { 457 1.1 scw msvr_rts = CLMPCC_MSVR_RTS; 458 1.1 scw msvr_dtr = CLMPCC_MSVR_DTR; 459 1.1 scw ccr = CLMPCC_CCR_T0_RX_EN | CLMPCC_CCR_T0_TX_EN; 460 1.1 scw } else { 461 1.1 scw msvr_rts = 0; 462 1.1 scw msvr_dtr = 0; 463 1.1 scw ccr = CLMPCC_CCR_T0_RX_DIS | CLMPCC_CCR_T0_TX_DIS; 464 1.1 scw } 465 1.1 scw 466 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_MSVR_RTS, msvr_rts); 467 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_MSVR_DTR, msvr_dtr); 468 1.1 scw clmpcc_channel_cmd(sc, i, CLMPCC_CCR_T0_INIT | ccr); 469 1.1 scw delay(100); 470 1.1 scw } 471 1.1 scw 472 1.1 scw return 0; 473 1.1 scw } 474 1.1 scw 475 1.1 scw static void 476 1.1 scw clmpcc_shutdown(ch) 477 1.1 scw struct clmpcc_chan *ch; 478 1.1 scw { 479 1.1 scw int oldch; 480 1.1 scw 481 1.1 scw oldch = clmpcc_select_channel(ch->ch_sc, ch->ch_car); 482 1.1 scw 483 1.1 scw /* Turn off interrupts. */ 484 1.1 scw clmpcc_wrreg(ch->ch_sc, CLMPCC_REG_IER, 0); 485 1.1 scw 486 1.1 scw if ( ISCLR(ch->ch_flags, CLMPCC_FLG_IS_CONSOLE) ) { 487 1.1 scw /* Disable the transmitter and receiver */ 488 1.1 scw clmpcc_channel_cmd(ch->ch_sc, ch->ch_car, CLMPCC_CCR_T0_RX_DIS | 489 1.1 scw CLMPCC_CCR_T0_TX_DIS); 490 1.1 scw 491 1.1 scw /* Drop RTS and DTR */ 492 1.1 scw clmpcc_modem_control(ch, TIOCM_RTS | TIOCM_DTR, DMBIS); 493 1.1 scw } 494 1.1 scw 495 1.1 scw clmpcc_select_channel(ch->ch_sc, oldch); 496 1.1 scw } 497 1.1 scw 498 1.1 scw int 499 1.1 scw clmpccopen(dev, flag, mode, p) 500 1.1 scw dev_t dev; 501 1.1 scw int flag, mode; 502 1.1 scw struct proc *p; 503 1.1 scw { 504 1.1 scw struct clmpcc_softc *sc; 505 1.1 scw struct clmpcc_chan *ch; 506 1.1 scw struct tty *tp; 507 1.1 scw int oldch; 508 1.1 scw int error; 509 1.7.2.1 bouyer 510 1.7.2.1 bouyer sc = device_lookup(&clmpcc_cd, CLMPCCUNIT(dev)); 511 1.7.2.1 bouyer if (sc == NULL) 512 1.7.2.1 bouyer return (ENXIO); 513 1.1 scw 514 1.1 scw ch = &sc->sc_chans[CLMPCCCHAN(dev)]; 515 1.1 scw 516 1.1 scw tp = ch->ch_tty; 517 1.1 scw 518 1.1 scw if ( ISSET(tp->t_state, TS_ISOPEN) && 519 1.1 scw ISSET(tp->t_state, TS_XCLUDE) && p->p_ucred->cr_uid != 0 ) 520 1.1 scw return EBUSY; 521 1.1 scw 522 1.1 scw /* 523 1.1 scw * Do the following iff this is a first open. 524 1.1 scw */ 525 1.1 scw if ( ISCLR(tp->t_state, TS_ISOPEN) && tp->t_wopen == 0 ) { 526 1.1 scw 527 1.1 scw ttychars(tp); 528 1.1 scw 529 1.1 scw tp->t_dev = dev; 530 1.1 scw tp->t_iflag = TTYDEF_IFLAG; 531 1.1 scw tp->t_oflag = TTYDEF_OFLAG; 532 1.1 scw tp->t_lflag = TTYDEF_LFLAG; 533 1.1 scw tp->t_cflag = TTYDEF_CFLAG; 534 1.1 scw tp->t_ospeed = tp->t_ispeed = TTYDEF_SPEED; 535 1.1 scw 536 1.1 scw if ( ISSET(ch->ch_openflags, TIOCFLAG_CLOCAL) ) 537 1.1 scw SET(tp->t_cflag, CLOCAL); 538 1.1 scw if ( ISSET(ch->ch_openflags, TIOCFLAG_CRTSCTS) ) 539 1.1 scw SET(tp->t_cflag, CRTSCTS); 540 1.1 scw if ( ISSET(ch->ch_openflags, TIOCFLAG_MDMBUF) ) 541 1.1 scw SET(tp->t_cflag, MDMBUF); 542 1.1 scw 543 1.1 scw /* 544 1.1 scw * Override some settings if the channel is being 545 1.1 scw * used as the console. 546 1.1 scw */ 547 1.1 scw if ( ISSET(ch->ch_flags, CLMPCC_FLG_IS_CONSOLE) ) { 548 1.1 scw tp->t_ospeed = tp->t_ispeed = cons_rate; 549 1.1 scw SET(tp->t_cflag, CLOCAL); 550 1.1 scw CLR(tp->t_cflag, CRTSCTS); 551 1.1 scw CLR(tp->t_cflag, HUPCL); 552 1.1 scw } 553 1.1 scw 554 1.1 scw ch->ch_control = 0; 555 1.1 scw 556 1.1 scw clmpcc_param(tp, &tp->t_termios); 557 1.1 scw ttsetwater(tp); 558 1.1 scw 559 1.1 scw /* Clear the input ring */ 560 1.1 scw ch->ch_ibuf_rd = ch->ch_ibuf_wr = ch->ch_ibuf; 561 1.1 scw 562 1.1 scw /* Select the channel */ 563 1.1 scw oldch = clmpcc_select_channel(sc, ch->ch_car); 564 1.1 scw 565 1.1 scw /* Reset it */ 566 1.1 scw clmpcc_channel_cmd(sc, ch->ch_car, CLMPCC_CCR_T0_CLEAR | 567 1.1 scw CLMPCC_CCR_T0_RX_EN | 568 1.1 scw CLMPCC_CCR_T0_TX_EN); 569 1.1 scw 570 1.1 scw /* Enable receiver and modem change interrupts. */ 571 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_IER, CLMPCC_IER_MODEM | 572 1.1 scw CLMPCC_IER_RET | 573 1.1 scw CLMPCC_IER_RX_FIFO); 574 1.1 scw 575 1.1 scw /* Raise RTS and DTR */ 576 1.1 scw clmpcc_modem_control(ch, TIOCM_RTS | TIOCM_DTR, DMBIS); 577 1.1 scw 578 1.1 scw clmpcc_select_channel(sc, oldch); 579 1.1 scw } else 580 1.1 scw if ( ISSET(tp->t_state, TS_XCLUDE) && p->p_ucred->cr_uid != 0 ) 581 1.1 scw return EBUSY; 582 1.1 scw 583 1.1 scw error = ttyopen(tp, CLMPCCDIALOUT(dev), ISSET(flag, O_NONBLOCK)); 584 1.1 scw if (error) 585 1.1 scw goto bad; 586 1.1 scw 587 1.7.2.2 bouyer error = (*tp->t_linesw->l_open)(dev, tp); 588 1.1 scw if (error) 589 1.1 scw goto bad; 590 1.1 scw 591 1.1 scw return 0; 592 1.1 scw 593 1.1 scw bad: 594 1.1 scw if ( ISCLR(tp->t_state, TS_ISOPEN) && tp->t_wopen == 0 ) { 595 1.1 scw /* 596 1.1 scw * We failed to open the device, and nobody else had it opened. 597 1.1 scw * Clean up the state as appropriate. 598 1.1 scw */ 599 1.1 scw clmpcc_shutdown(ch); 600 1.1 scw } 601 1.1 scw 602 1.1 scw return error; 603 1.1 scw } 604 1.1 scw 605 1.1 scw int 606 1.1 scw clmpccclose(dev, flag, mode, p) 607 1.1 scw dev_t dev; 608 1.1 scw int flag, mode; 609 1.1 scw struct proc *p; 610 1.1 scw { 611 1.7.2.1 bouyer struct clmpcc_softc *sc = 612 1.7.2.1 bouyer device_lookup(&clmpcc_cd, CLMPCCUNIT(dev)); 613 1.1 scw struct clmpcc_chan *ch = &sc->sc_chans[CLMPCCCHAN(dev)]; 614 1.1 scw struct tty *tp = ch->ch_tty; 615 1.1 scw int s; 616 1.1 scw 617 1.1 scw if ( ISCLR(tp->t_state, TS_ISOPEN) ) 618 1.1 scw return 0; 619 1.1 scw 620 1.7.2.2 bouyer (*tp->t_linesw->l_close)(tp, flag); 621 1.1 scw 622 1.1 scw s = spltty(); 623 1.1 scw 624 1.1 scw if ( ISCLR(tp->t_state, TS_ISOPEN) && tp->t_wopen == 0 ) { 625 1.1 scw /* 626 1.1 scw * Although we got a last close, the device may still be in 627 1.1 scw * use; e.g. if this was the dialout node, and there are still 628 1.1 scw * processes waiting for carrier on the non-dialout node. 629 1.1 scw */ 630 1.1 scw clmpcc_shutdown(ch); 631 1.1 scw } 632 1.1 scw 633 1.1 scw ttyclose(tp); 634 1.1 scw 635 1.1 scw splx(s); 636 1.1 scw 637 1.1 scw return 0; 638 1.1 scw } 639 1.1 scw 640 1.1 scw int 641 1.1 scw clmpccread(dev, uio, flag) 642 1.1 scw dev_t dev; 643 1.1 scw struct uio *uio; 644 1.1 scw int flag; 645 1.1 scw { 646 1.7.2.1 bouyer struct clmpcc_softc *sc = device_lookup(&clmpcc_cd, CLMPCCUNIT(dev)); 647 1.1 scw struct tty *tp = sc->sc_chans[CLMPCCCHAN(dev)].ch_tty; 648 1.1 scw 649 1.7.2.2 bouyer return ((*tp->t_linesw->l_read)(tp, uio, flag)); 650 1.1 scw } 651 1.1 scw 652 1.1 scw int 653 1.1 scw clmpccwrite(dev, uio, flag) 654 1.1 scw dev_t dev; 655 1.1 scw struct uio *uio; 656 1.1 scw int flag; 657 1.1 scw { 658 1.7.2.1 bouyer struct clmpcc_softc *sc = device_lookup(&clmpcc_cd, CLMPCCUNIT(dev)); 659 1.1 scw struct tty *tp = sc->sc_chans[CLMPCCCHAN(dev)].ch_tty; 660 1.1 scw 661 1.7.2.2 bouyer return ((*tp->t_linesw->l_write)(tp, uio, flag)); 662 1.1 scw } 663 1.1 scw 664 1.1 scw struct tty * 665 1.1 scw clmpcctty(dev) 666 1.1 scw dev_t dev; 667 1.1 scw { 668 1.7.2.1 bouyer struct clmpcc_softc *sc = device_lookup(&clmpcc_cd, CLMPCCUNIT(dev)); 669 1.1 scw 670 1.1 scw return (sc->sc_chans[CLMPCCCHAN(dev)].ch_tty); 671 1.1 scw } 672 1.1 scw 673 1.1 scw int 674 1.1 scw clmpccioctl(dev, cmd, data, flag, p) 675 1.1 scw dev_t dev; 676 1.1 scw u_long cmd; 677 1.1 scw caddr_t data; 678 1.1 scw int flag; 679 1.1 scw struct proc *p; 680 1.1 scw { 681 1.7.2.1 bouyer struct clmpcc_softc *sc = device_lookup(&clmpcc_cd, CLMPCCUNIT(dev)); 682 1.1 scw struct clmpcc_chan *ch = &sc->sc_chans[CLMPCCCHAN(dev)]; 683 1.1 scw struct tty *tp = ch->ch_tty; 684 1.1 scw int error; 685 1.1 scw 686 1.7.2.2 bouyer error = (*tp->t_linesw->l_ioctl)(tp, cmd, data, flag, p); 687 1.1 scw if (error >= 0) 688 1.1 scw return error; 689 1.1 scw 690 1.1 scw error = ttioctl(tp, cmd, data, flag, p); 691 1.1 scw if (error >= 0) 692 1.1 scw return error; 693 1.1 scw 694 1.1 scw error = 0; 695 1.1 scw 696 1.1 scw switch (cmd) { 697 1.1 scw case TIOCSBRK: 698 1.1 scw SET(ch->ch_flags, CLMPCC_FLG_START_BREAK); 699 1.1 scw clmpcc_enable_transmitter(ch); 700 1.1 scw break; 701 1.1 scw 702 1.1 scw case TIOCCBRK: 703 1.1 scw SET(ch->ch_flags, CLMPCC_FLG_END_BREAK); 704 1.1 scw clmpcc_enable_transmitter(ch); 705 1.1 scw break; 706 1.1 scw 707 1.1 scw case TIOCSDTR: 708 1.1 scw clmpcc_modem_control(ch, TIOCM_DTR, DMBIS); 709 1.1 scw break; 710 1.1 scw 711 1.1 scw case TIOCCDTR: 712 1.1 scw clmpcc_modem_control(ch, TIOCM_DTR, DMBIC); 713 1.1 scw break; 714 1.1 scw 715 1.1 scw case TIOCMSET: 716 1.1 scw clmpcc_modem_control(ch, *((int *)data), DMSET); 717 1.1 scw break; 718 1.1 scw 719 1.1 scw case TIOCMBIS: 720 1.1 scw clmpcc_modem_control(ch, *((int *)data), DMBIS); 721 1.1 scw break; 722 1.1 scw 723 1.1 scw case TIOCMBIC: 724 1.1 scw clmpcc_modem_control(ch, *((int *)data), DMBIC); 725 1.1 scw break; 726 1.1 scw 727 1.1 scw case TIOCMGET: 728 1.1 scw *((int *)data) = clmpcc_modem_control(ch, 0, DMGET); 729 1.1 scw break; 730 1.1 scw 731 1.1 scw case TIOCGFLAGS: 732 1.1 scw *((int *)data) = ch->ch_openflags; 733 1.1 scw break; 734 1.1 scw 735 1.1 scw case TIOCSFLAGS: 736 1.1 scw error = suser(p->p_ucred, &p->p_acflag); 737 1.1 scw if ( error ) 738 1.1 scw break; 739 1.1 scw ch->ch_openflags = *((int *)data) & 740 1.1 scw (TIOCFLAG_SOFTCAR | TIOCFLAG_CLOCAL | 741 1.1 scw TIOCFLAG_CRTSCTS | TIOCFLAG_MDMBUF); 742 1.1 scw if ( ISSET(ch->ch_flags, CLMPCC_FLG_IS_CONSOLE) ) 743 1.1 scw SET(ch->ch_openflags, TIOCFLAG_SOFTCAR); 744 1.1 scw break; 745 1.1 scw 746 1.1 scw default: 747 1.1 scw error = ENOTTY; 748 1.1 scw break; 749 1.1 scw } 750 1.1 scw 751 1.1 scw return error; 752 1.1 scw } 753 1.1 scw 754 1.1 scw int 755 1.1 scw clmpcc_modem_control(ch, bits, howto) 756 1.1 scw struct clmpcc_chan *ch; 757 1.1 scw int bits; 758 1.1 scw int howto; 759 1.1 scw { 760 1.1 scw struct clmpcc_softc *sc = ch->ch_sc; 761 1.1 scw struct tty *tp = ch->ch_tty; 762 1.1 scw int oldch; 763 1.1 scw int msvr; 764 1.1 scw int rbits = 0; 765 1.1 scw 766 1.1 scw oldch = clmpcc_select_channel(sc, ch->ch_car); 767 1.1 scw 768 1.1 scw switch ( howto ) { 769 1.1 scw case DMGET: 770 1.1 scw msvr = clmpcc_rd_msvr(sc); 771 1.1 scw 772 1.1 scw if ( sc->sc_swaprtsdtr ) { 773 1.1 scw rbits |= (msvr & CLMPCC_MSVR_RTS) ? TIOCM_DTR : 0; 774 1.1 scw rbits |= (msvr & CLMPCC_MSVR_DTR) ? TIOCM_RTS : 0; 775 1.1 scw } else { 776 1.1 scw rbits |= (msvr & CLMPCC_MSVR_RTS) ? TIOCM_RTS : 0; 777 1.1 scw rbits |= (msvr & CLMPCC_MSVR_DTR) ? TIOCM_DTR : 0; 778 1.1 scw } 779 1.1 scw 780 1.1 scw rbits |= (msvr & CLMPCC_MSVR_CTS) ? TIOCM_CTS : 0; 781 1.1 scw rbits |= (msvr & CLMPCC_MSVR_CD) ? TIOCM_CD : 0; 782 1.1 scw rbits |= (msvr & CLMPCC_MSVR_DSR) ? TIOCM_DSR : 0; 783 1.1 scw break; 784 1.1 scw 785 1.1 scw case DMSET: 786 1.1 scw if ( sc->sc_swaprtsdtr ) { 787 1.1 scw if ( ISCLR(tp->t_cflag, CRTSCTS) ) 788 1.1 scw clmpcc_wr_msvr(sc, CLMPCC_REG_MSVR_DTR, 789 1.1 scw bits & TIOCM_RTS ? CLMPCC_MSVR_DTR : 0); 790 1.1 scw clmpcc_wr_msvr(sc, CLMPCC_REG_MSVR_RTS, 791 1.1 scw bits & TIOCM_DTR ? CLMPCC_MSVR_RTS : 0); 792 1.1 scw } else { 793 1.1 scw if ( ISCLR(tp->t_cflag, CRTSCTS) ) 794 1.1 scw clmpcc_wr_msvr(sc, CLMPCC_REG_MSVR_RTS, 795 1.1 scw bits & TIOCM_RTS ? CLMPCC_MSVR_RTS : 0); 796 1.1 scw clmpcc_wr_msvr(sc, CLMPCC_REG_MSVR_DTR, 797 1.1 scw bits & TIOCM_DTR ? CLMPCC_MSVR_DTR : 0); 798 1.1 scw } 799 1.1 scw break; 800 1.1 scw 801 1.1 scw case DMBIS: 802 1.1 scw if ( sc->sc_swaprtsdtr ) { 803 1.1 scw if ( ISCLR(tp->t_cflag, CRTSCTS) && ISSET(bits, TIOCM_RTS) ) 804 1.1 scw clmpcc_wr_msvr(sc,CLMPCC_REG_MSVR_DTR, CLMPCC_MSVR_DTR); 805 1.1 scw if ( ISSET(bits, TIOCM_DTR) ) 806 1.1 scw clmpcc_wr_msvr(sc,CLMPCC_REG_MSVR_RTS, CLMPCC_MSVR_RTS); 807 1.1 scw } else { 808 1.1 scw if ( ISCLR(tp->t_cflag, CRTSCTS) && ISSET(bits, TIOCM_RTS) ) 809 1.1 scw clmpcc_wr_msvr(sc,CLMPCC_REG_MSVR_RTS, CLMPCC_MSVR_RTS); 810 1.1 scw if ( ISSET(bits, TIOCM_DTR) ) 811 1.1 scw clmpcc_wr_msvr(sc,CLMPCC_REG_MSVR_DTR, CLMPCC_MSVR_DTR); 812 1.1 scw } 813 1.1 scw break; 814 1.1 scw 815 1.1 scw case DMBIC: 816 1.1 scw if ( sc->sc_swaprtsdtr ) { 817 1.1 scw if ( ISCLR(tp->t_cflag, CRTSCTS) && ISCLR(bits, TIOCM_RTS) ) 818 1.1 scw clmpcc_wr_msvr(sc, CLMPCC_REG_MSVR_DTR, 0); 819 1.1 scw if ( ISCLR(bits, TIOCM_DTR) ) 820 1.1 scw clmpcc_wr_msvr(sc, CLMPCC_REG_MSVR_RTS, 0); 821 1.1 scw } else { 822 1.1 scw if ( ISCLR(tp->t_cflag, CRTSCTS) && ISCLR(bits, TIOCM_RTS) ) 823 1.1 scw clmpcc_wr_msvr(sc, CLMPCC_REG_MSVR_RTS, 0); 824 1.1 scw if ( ISCLR(bits, TIOCM_DTR) ) 825 1.1 scw clmpcc_wr_msvr(sc, CLMPCC_REG_MSVR_DTR, 0); 826 1.1 scw } 827 1.1 scw break; 828 1.1 scw } 829 1.1 scw 830 1.1 scw clmpcc_select_channel(sc, oldch); 831 1.1 scw 832 1.1 scw return rbits; 833 1.1 scw } 834 1.1 scw 835 1.1 scw static int 836 1.1 scw clmpcc_param(tp, t) 837 1.1 scw struct tty *tp; 838 1.1 scw struct termios *t; 839 1.1 scw { 840 1.7.2.1 bouyer struct clmpcc_softc *sc = 841 1.7.2.1 bouyer device_lookup(&clmpcc_cd, CLMPCCUNIT(tp->t_dev)); 842 1.1 scw struct clmpcc_chan *ch = &sc->sc_chans[CLMPCCCHAN(tp->t_dev)]; 843 1.2 scw u_char cor; 844 1.5 scw u_char oldch; 845 1.1 scw int oclk, obpr; 846 1.1 scw int iclk, ibpr; 847 1.1 scw int s; 848 1.1 scw 849 1.1 scw /* Check requested parameters. */ 850 1.1 scw if ( t->c_ospeed && clmpcc_speed(sc, t->c_ospeed, &oclk, &obpr) < 0 ) 851 1.1 scw return EINVAL; 852 1.1 scw 853 1.1 scw if ( t->c_ispeed && clmpcc_speed(sc, t->c_ispeed, &iclk, &ibpr) < 0 ) 854 1.1 scw return EINVAL; 855 1.1 scw 856 1.1 scw /* 857 1.1 scw * For the console, always force CLOCAL and !HUPCL, so that the port 858 1.1 scw * is always active. 859 1.1 scw */ 860 1.1 scw if ( ISSET(ch->ch_openflags, TIOCFLAG_SOFTCAR) || 861 1.1 scw ISSET(ch->ch_flags, CLMPCC_FLG_IS_CONSOLE) ) { 862 1.1 scw SET(t->c_cflag, CLOCAL); 863 1.1 scw CLR(t->c_cflag, HUPCL); 864 1.1 scw } 865 1.1 scw 866 1.2 scw CLR(ch->ch_flags, CLMPCC_FLG_UPDATE_PARMS); 867 1.2 scw 868 1.1 scw /* If ospeed it zero, hangup the line */ 869 1.1 scw clmpcc_modem_control(ch, TIOCM_DTR, t->c_ospeed == 0 ? DMBIC : DMBIS); 870 1.1 scw 871 1.1 scw if ( t->c_ospeed ) { 872 1.2 scw ch->ch_tcor = CLMPCC_TCOR_CLK(oclk); 873 1.2 scw ch->ch_tbpr = obpr; 874 1.2 scw } else { 875 1.2 scw ch->ch_tcor = 0; 876 1.2 scw ch->ch_tbpr = 0; 877 1.1 scw } 878 1.1 scw 879 1.1 scw if ( t->c_ispeed ) { 880 1.2 scw ch->ch_rcor = CLMPCC_RCOR_CLK(iclk); 881 1.2 scw ch->ch_rbpr = ibpr; 882 1.2 scw } else { 883 1.2 scw ch->ch_rcor = 0; 884 1.2 scw ch->ch_rbpr = 0; 885 1.1 scw } 886 1.1 scw 887 1.1 scw /* Work out value to use for COR1 */ 888 1.1 scw cor = 0; 889 1.1 scw if ( ISSET(t->c_cflag, PARENB) ) { 890 1.1 scw cor |= CLMPCC_COR1_NORM_PARITY; 891 1.1 scw if ( ISSET(t->c_cflag, PARODD) ) 892 1.1 scw cor |= CLMPCC_COR1_ODD_PARITY; 893 1.1 scw } 894 1.1 scw 895 1.1 scw if ( ISCLR(t->c_cflag, INPCK) ) 896 1.1 scw cor |= CLMPCC_COR1_IGNORE_PAR; 897 1.1 scw 898 1.1 scw switch ( t->c_cflag & CSIZE ) { 899 1.1 scw case CS5: 900 1.1 scw cor |= CLMPCC_COR1_CHAR_5BITS; 901 1.1 scw break; 902 1.1 scw 903 1.1 scw case CS6: 904 1.1 scw cor |= CLMPCC_COR1_CHAR_6BITS; 905 1.1 scw break; 906 1.1 scw 907 1.1 scw case CS7: 908 1.1 scw cor |= CLMPCC_COR1_CHAR_7BITS; 909 1.1 scw break; 910 1.1 scw 911 1.1 scw case CS8: 912 1.1 scw cor |= CLMPCC_COR1_CHAR_8BITS; 913 1.1 scw break; 914 1.1 scw } 915 1.1 scw 916 1.2 scw ch->ch_cor1 = cor; 917 1.1 scw 918 1.1 scw /* 919 1.1 scw * The only interesting bit in COR2 is 'CTS Automatic Enable' 920 1.1 scw * when hardware flow control is in effect. 921 1.1 scw */ 922 1.2 scw ch->ch_cor2 = ISSET(t->c_cflag, CRTSCTS) ? CLMPCC_COR2_CtsAE : 0; 923 1.1 scw 924 1.1 scw /* COR3 needs to be set to the number of stop bits... */ 925 1.2 scw ch->ch_cor3 = ISSET(t->c_cflag, CSTOPB) ? CLMPCC_COR3_STOP_2 : 926 1.2 scw CLMPCC_COR3_STOP_1; 927 1.1 scw 928 1.1 scw /* 929 1.1 scw * COR4 contains the FIFO threshold setting. 930 1.1 scw * We adjust the threshold depending on the input speed... 931 1.1 scw */ 932 1.1 scw if ( t->c_ispeed <= 1200 ) 933 1.2 scw ch->ch_cor4 = CLMPCC_COR4_FIFO_LOW; 934 1.1 scw else if ( t->c_ispeed <= 19200 ) 935 1.2 scw ch->ch_cor4 = CLMPCC_COR4_FIFO_MED; 936 1.1 scw else 937 1.2 scw ch->ch_cor4 = CLMPCC_COR4_FIFO_HIGH; 938 1.1 scw 939 1.1 scw /* 940 1.1 scw * If chip is used with CTS and DTR swapped, we can enable 941 1.1 scw * automatic hardware flow control. 942 1.1 scw */ 943 1.1 scw if ( sc->sc_swaprtsdtr && ISSET(t->c_cflag, CRTSCTS) ) 944 1.2 scw ch->ch_cor5 = CLMPCC_COR5_FLOW_NORM; 945 1.2 scw else 946 1.2 scw ch->ch_cor5 = 0; 947 1.2 scw 948 1.2 scw s = splserial(); 949 1.5 scw oldch = clmpcc_select_channel(sc, ch->ch_car); 950 1.5 scw 951 1.5 scw /* 952 1.5 scw * COR2 needs to be set immediately otherwise we might never get 953 1.5 scw * a Tx EMPTY interrupt to change the other parameters. 954 1.5 scw */ 955 1.5 scw if ( clmpcc_rdreg(sc, CLMPCC_REG_COR2) != ch->ch_cor2 ) 956 1.5 scw clmpcc_wrreg(sc, CLMPCC_REG_COR2, ch->ch_cor2); 957 1.5 scw 958 1.5 scw if ( ISCLR(ch->ch_tty->t_state, TS_BUSY) ) 959 1.2 scw clmpcc_set_params(ch); 960 1.5 scw else 961 1.2 scw SET(ch->ch_flags, CLMPCC_FLG_UPDATE_PARMS); 962 1.5 scw 963 1.5 scw clmpcc_select_channel(sc, oldch); 964 1.5 scw 965 1.2 scw splx(s); 966 1.2 scw 967 1.2 scw return 0; 968 1.2 scw } 969 1.2 scw 970 1.2 scw static void 971 1.2 scw clmpcc_set_params(ch) 972 1.2 scw struct clmpcc_chan *ch; 973 1.2 scw { 974 1.2 scw struct clmpcc_softc *sc = ch->ch_sc; 975 1.4 scw u_char r1; 976 1.4 scw u_char r2; 977 1.1 scw 978 1.7.2.1 bouyer if ( ch->ch_tcor || ch->ch_tbpr ) { 979 1.4 scw r1 = clmpcc_rdreg(sc, CLMPCC_REG_TCOR); 980 1.4 scw r2 = clmpcc_rdreg(sc, CLMPCC_REG_TBPR); 981 1.4 scw /* Only write Tx rate if it really has changed */ 982 1.4 scw if ( ch->ch_tcor != r1 || ch->ch_tbpr != r2 ) { 983 1.4 scw clmpcc_wrreg(sc, CLMPCC_REG_TCOR, ch->ch_tcor); 984 1.4 scw clmpcc_wrreg(sc, CLMPCC_REG_TBPR, ch->ch_tbpr); 985 1.4 scw } 986 1.2 scw } 987 1.1 scw 988 1.7.2.1 bouyer if ( ch->ch_rcor || ch->ch_rbpr ) { 989 1.4 scw r1 = clmpcc_rdreg(sc, CLMPCC_REG_RCOR); 990 1.4 scw r2 = clmpcc_rdreg(sc, CLMPCC_REG_RBPR); 991 1.4 scw /* Only write Rx rate if it really has changed */ 992 1.4 scw if ( ch->ch_rcor != r1 || ch->ch_rbpr != r2 ) { 993 1.4 scw clmpcc_wrreg(sc, CLMPCC_REG_RCOR, ch->ch_rcor); 994 1.4 scw clmpcc_wrreg(sc, CLMPCC_REG_RBPR, ch->ch_rbpr); 995 1.4 scw } 996 1.4 scw } 997 1.4 scw 998 1.4 scw if ( clmpcc_rdreg(sc, CLMPCC_REG_COR1) != ch->ch_cor1 ) { 999 1.4 scw clmpcc_wrreg(sc, CLMPCC_REG_COR1, ch->ch_cor1); 1000 1.4 scw /* Any change to COR1 requires an INIT command */ 1001 1.4 scw SET(ch->ch_flags, CLMPCC_FLG_NEED_INIT); 1002 1.2 scw } 1003 1.4 scw 1004 1.4 scw if ( clmpcc_rdreg(sc, CLMPCC_REG_COR3) != ch->ch_cor3 ) 1005 1.4 scw clmpcc_wrreg(sc, CLMPCC_REG_COR3, ch->ch_cor3); 1006 1.4 scw 1007 1.4 scw r1 = clmpcc_rdreg(sc, CLMPCC_REG_COR4); 1008 1.4 scw if ( ch->ch_cor4 != (r1 & CLMPCC_COR4_FIFO_MASK) ) { 1009 1.4 scw /* 1010 1.7.2.1 bouyer * Note: If the FIFO has changed, we always set it to 1011 1.4 scw * zero here and disable the Receive Timeout interrupt. 1012 1.4 scw * It's up to the Rx Interrupt handler to pick the 1013 1.7.2.1 bouyer * appropriate moment to write the new FIFO length. 1014 1.4 scw */ 1015 1.4 scw clmpcc_wrreg(sc, CLMPCC_REG_COR4, r1 & ~CLMPCC_COR4_FIFO_MASK); 1016 1.4 scw r1 = clmpcc_rdreg(sc, CLMPCC_REG_IER); 1017 1.4 scw clmpcc_wrreg(sc, CLMPCC_REG_IER, r1 & ~CLMPCC_IER_RET); 1018 1.4 scw SET(ch->ch_flags, CLMPCC_FLG_FIFO_CLEAR); 1019 1.4 scw } 1020 1.1 scw 1021 1.4 scw r1 = clmpcc_rdreg(sc, CLMPCC_REG_COR5); 1022 1.4 scw if ( ch->ch_cor5 != (r1 & CLMPCC_COR5_FLOW_MASK) ) { 1023 1.4 scw r1 &= ~CLMPCC_COR5_FLOW_MASK; 1024 1.4 scw clmpcc_wrreg(sc, CLMPCC_REG_COR5, r1 | ch->ch_cor5); 1025 1.4 scw } 1026 1.1 scw } 1027 1.1 scw 1028 1.1 scw static void 1029 1.1 scw clmpcc_start(tp) 1030 1.1 scw struct tty *tp; 1031 1.1 scw { 1032 1.7.2.1 bouyer struct clmpcc_softc *sc = 1033 1.7.2.1 bouyer device_lookup(&clmpcc_cd, CLMPCCUNIT(tp->t_dev)); 1034 1.1 scw struct clmpcc_chan *ch = &sc->sc_chans[CLMPCCCHAN(tp->t_dev)]; 1035 1.6 scw u_int oldch; 1036 1.1 scw int s; 1037 1.1 scw 1038 1.1 scw s = spltty(); 1039 1.1 scw 1040 1.6 scw if ( ISCLR(tp->t_state, TS_TTSTOP | TS_TIMEOUT | TS_BUSY) ) { 1041 1.1 scw if ( tp->t_outq.c_cc <= tp->t_lowat ) { 1042 1.1 scw if ( ISSET(tp->t_state, TS_ASLEEP) ) { 1043 1.1 scw CLR(tp->t_state, TS_ASLEEP); 1044 1.1 scw wakeup(&tp->t_outq); 1045 1.1 scw } 1046 1.1 scw selwakeup(&tp->t_wsel); 1047 1.6 scw } 1048 1.1 scw 1049 1.7.2.1 bouyer if ( ISSET(ch->ch_flags, CLMPCC_FLG_START_BREAK | 1050 1.7.2.1 bouyer CLMPCC_FLG_END_BREAK) || 1051 1.7.2.1 bouyer tp->t_outq.c_cc > 0 ) { 1052 1.7.2.1 bouyer 1053 1.7.2.1 bouyer if ( ISCLR(ch->ch_flags, CLMPCC_FLG_START_BREAK | 1054 1.7.2.1 bouyer CLMPCC_FLG_END_BREAK) ) { 1055 1.7.2.1 bouyer ch->ch_obuf_addr = tp->t_outq.c_cf; 1056 1.7.2.1 bouyer ch->ch_obuf_size = ndqb(&tp->t_outq, 0); 1057 1.7.2.1 bouyer } 1058 1.6 scw 1059 1.6 scw /* Enable TX empty interrupts */ 1060 1.6 scw oldch = clmpcc_select_channel(ch->ch_sc, ch->ch_car); 1061 1.6 scw clmpcc_wrreg(ch->ch_sc, CLMPCC_REG_IER, 1062 1.6 scw clmpcc_rdreg(ch->ch_sc, CLMPCC_REG_IER) | 1063 1.6 scw CLMPCC_IER_TX_EMPTY); 1064 1.6 scw clmpcc_select_channel(ch->ch_sc, oldch); 1065 1.6 scw SET(tp->t_state, TS_BUSY); 1066 1.1 scw } 1067 1.1 scw } 1068 1.1 scw 1069 1.1 scw splx(s); 1070 1.1 scw } 1071 1.1 scw 1072 1.1 scw /* 1073 1.1 scw * Stop output on a line. 1074 1.1 scw */ 1075 1.1 scw void 1076 1.1 scw clmpccstop(tp, flag) 1077 1.1 scw struct tty *tp; 1078 1.1 scw int flag; 1079 1.1 scw { 1080 1.7.2.1 bouyer struct clmpcc_softc *sc = 1081 1.7.2.1 bouyer device_lookup(&clmpcc_cd, CLMPCCUNIT(tp->t_dev)); 1082 1.1 scw struct clmpcc_chan *ch = &sc->sc_chans[CLMPCCCHAN(tp->t_dev)]; 1083 1.1 scw int s; 1084 1.1 scw 1085 1.6 scw s = splserial(); 1086 1.1 scw 1087 1.1 scw if ( ISSET(tp->t_state, TS_BUSY) ) { 1088 1.1 scw if ( ISCLR(tp->t_state, TS_TTSTOP) ) 1089 1.1 scw SET(tp->t_state, TS_FLUSH); 1090 1.6 scw ch->ch_obuf_size = 0; 1091 1.1 scw } 1092 1.1 scw splx(s); 1093 1.1 scw } 1094 1.1 scw 1095 1.1 scw /* 1096 1.1 scw * RX interrupt routine 1097 1.1 scw */ 1098 1.1 scw int 1099 1.1 scw clmpcc_rxintr(arg) 1100 1.1 scw void *arg; 1101 1.1 scw { 1102 1.1 scw struct clmpcc_softc *sc = (struct clmpcc_softc *)arg; 1103 1.1 scw struct clmpcc_chan *ch; 1104 1.1 scw u_int8_t *put, *end, rxd; 1105 1.1 scw u_char errstat; 1106 1.2 scw u_char fc, tc; 1107 1.2 scw u_char risr; 1108 1.2 scw u_char rir; 1109 1.1 scw #ifdef DDB 1110 1.1 scw int saw_break = 0; 1111 1.1 scw #endif 1112 1.1 scw 1113 1.1 scw /* Receive interrupt active? */ 1114 1.1 scw rir = clmpcc_rdreg(sc, CLMPCC_REG_RIR); 1115 1.1 scw 1116 1.1 scw /* 1117 1.1 scw * If we're using auto-vectored interrupts, we have to 1118 1.1 scw * verify if the chip is generating the interrupt. 1119 1.1 scw */ 1120 1.1 scw if ( sc->sc_vector_base == 0 && (rir & CLMPCC_RIR_RACT) == 0 ) 1121 1.1 scw return 0; 1122 1.1 scw 1123 1.1 scw /* Get pointer to interrupting channel's data structure */ 1124 1.1 scw ch = &sc->sc_chans[rir & CLMPCC_RIR_RCN_MASK]; 1125 1.1 scw 1126 1.1 scw /* Get the interrupt status register */ 1127 1.1 scw risr = clmpcc_rdreg(sc, CLMPCC_REG_RISRl); 1128 1.1 scw if ( risr & CLMPCC_RISR_TIMEOUT ) { 1129 1.1 scw u_char reg; 1130 1.1 scw /* 1131 1.1 scw * Set the FIFO threshold to zero, and disable 1132 1.1 scw * further receive timeout interrupts. 1133 1.1 scw */ 1134 1.1 scw reg = clmpcc_rdreg(sc, CLMPCC_REG_COR4); 1135 1.7.2.1 bouyer clmpcc_wrreg(sc, CLMPCC_REG_COR4, reg & ~CLMPCC_COR4_FIFO_MASK); 1136 1.1 scw reg = clmpcc_rdreg(sc, CLMPCC_REG_IER); 1137 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_IER, reg & ~CLMPCC_IER_RET); 1138 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_REOIR, CLMPCC_REOIR_NO_TRANS); 1139 1.1 scw SET(ch->ch_flags, CLMPCC_FLG_FIFO_CLEAR); 1140 1.1 scw return 1; 1141 1.1 scw } 1142 1.1 scw 1143 1.1 scw /* How many bytes are waiting in the FIFO? */ 1144 1.1 scw fc = tc = clmpcc_rdreg(sc, CLMPCC_REG_RFOC) & CLMPCC_RFOC_MASK; 1145 1.1 scw 1146 1.1 scw #ifdef DDB 1147 1.1 scw /* 1148 1.1 scw * Allow BREAK on the console to drop to the debugger. 1149 1.1 scw */ 1150 1.1 scw if ( ISSET(ch->ch_flags, CLMPCC_FLG_IS_CONSOLE) && 1151 1.1 scw risr & CLMPCC_RISR_BREAK ) { 1152 1.1 scw saw_break = 1; 1153 1.1 scw } 1154 1.1 scw #endif 1155 1.1 scw 1156 1.1 scw if ( ISCLR(ch->ch_tty->t_state, TS_ISOPEN) && fc ) { 1157 1.1 scw /* Just get rid of the data */ 1158 1.1 scw while ( fc-- ) 1159 1.1 scw (void) clmpcc_rd_rxdata(sc); 1160 1.1 scw goto rx_done; 1161 1.1 scw } 1162 1.1 scw 1163 1.1 scw put = ch->ch_ibuf_wr; 1164 1.1 scw end = ch->ch_ibuf_end; 1165 1.1 scw 1166 1.1 scw /* 1167 1.1 scw * Note: The chip is completely hosed WRT these error 1168 1.1 scw * conditions; there seems to be no way to associate 1169 1.1 scw * the error with the correct character in the FIFO. 1170 1.1 scw * We compromise by tagging the first character we read 1171 1.1 scw * with the error. Not perfect, but there's no other way. 1172 1.1 scw */ 1173 1.1 scw errstat = 0; 1174 1.1 scw if ( risr & CLMPCC_RISR_PARITY ) 1175 1.1 scw errstat |= TTY_PE; 1176 1.1 scw if ( risr & (CLMPCC_RISR_FRAMING | CLMPCC_RISR_BREAK) ) 1177 1.1 scw errstat |= TTY_FE; 1178 1.1 scw 1179 1.1 scw /* 1180 1.1 scw * As long as there are characters in the FIFO, and we 1181 1.1 scw * have space for them... 1182 1.1 scw */ 1183 1.1 scw while ( fc > 0 ) { 1184 1.1 scw 1185 1.1 scw *put++ = rxd = clmpcc_rd_rxdata(sc); 1186 1.1 scw *put++ = errstat; 1187 1.1 scw 1188 1.1 scw if ( put >= end ) 1189 1.1 scw put = ch->ch_ibuf; 1190 1.1 scw 1191 1.1 scw if ( put == ch->ch_ibuf_rd ) { 1192 1.1 scw put -= 2; 1193 1.1 scw if ( put < ch->ch_ibuf ) 1194 1.1 scw put = end - 2; 1195 1.1 scw } 1196 1.1 scw 1197 1.1 scw errstat = 0; 1198 1.1 scw fc--; 1199 1.1 scw } 1200 1.1 scw 1201 1.1 scw ch->ch_ibuf_wr = put; 1202 1.1 scw 1203 1.1 scw #if 0 1204 1.1 scw if ( sc->sc_swaprtsdtr == 0 && 1205 1.1 scw ISSET(cy->cy_tty->t_cflag, CRTSCTS) && cc < ch->ch_r_hiwat) { 1206 1.1 scw /* 1207 1.1 scw * If RTS/DTR are not physically swapped, we have to 1208 1.1 scw * do hardware flow control manually 1209 1.1 scw */ 1210 1.1 scw clmpcc_wr_msvr(sc, CLMPCC_MSVR_RTS, 0); 1211 1.1 scw } 1212 1.1 scw #endif 1213 1.1 scw 1214 1.1 scw rx_done: 1215 1.1 scw if ( fc != tc ) { 1216 1.1 scw if ( ISSET(ch->ch_flags, CLMPCC_FLG_FIFO_CLEAR) ) { 1217 1.1 scw u_char reg; 1218 1.1 scw /* 1219 1.1 scw * Set the FIFO threshold to the preset value, 1220 1.1 scw * and enable receive timeout interrupts. 1221 1.1 scw */ 1222 1.1 scw reg = clmpcc_rdreg(sc, CLMPCC_REG_COR4); 1223 1.2 scw reg = (reg & ~CLMPCC_COR4_FIFO_MASK) | ch->ch_cor4; 1224 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_COR4, reg); 1225 1.1 scw reg = clmpcc_rdreg(sc, CLMPCC_REG_IER); 1226 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_IER, reg | CLMPCC_IER_RET); 1227 1.1 scw CLR(ch->ch_flags, CLMPCC_FLG_FIFO_CLEAR); 1228 1.1 scw } 1229 1.1 scw 1230 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_REOIR, 0); 1231 1.7.2.1 bouyer #ifndef __GENERIC_SOFT_INTERRUPTS 1232 1.1 scw if ( sc->sc_soft_running == 0 ) { 1233 1.1 scw sc->sc_soft_running = 1; 1234 1.1 scw (sc->sc_softhook)(sc); 1235 1.1 scw } 1236 1.7.2.1 bouyer #else 1237 1.7.2.1 bouyer softintr_schedule(sc->sc_softintr_cookie); 1238 1.7.2.1 bouyer #endif 1239 1.1 scw } else 1240 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_REOIR, CLMPCC_REOIR_NO_TRANS); 1241 1.1 scw 1242 1.1 scw #ifdef DDB 1243 1.1 scw /* 1244 1.1 scw * Only =after= we write REOIR is it safe to drop to the debugger. 1245 1.1 scw */ 1246 1.1 scw if ( saw_break ) 1247 1.1 scw Debugger(); 1248 1.1 scw #endif 1249 1.1 scw 1250 1.1 scw return 1; 1251 1.1 scw } 1252 1.1 scw 1253 1.1 scw /* 1254 1.1 scw * Tx interrupt routine 1255 1.1 scw */ 1256 1.1 scw int 1257 1.1 scw clmpcc_txintr(arg) 1258 1.1 scw void *arg; 1259 1.1 scw { 1260 1.1 scw struct clmpcc_softc *sc = (struct clmpcc_softc *)arg; 1261 1.1 scw struct clmpcc_chan *ch; 1262 1.1 scw struct tty *tp; 1263 1.2 scw u_char ftc, oftc; 1264 1.7.2.1 bouyer u_char tir, teoir; 1265 1.7.2.1 bouyer int etcmode = 0; 1266 1.1 scw 1267 1.1 scw /* Tx interrupt active? */ 1268 1.1 scw tir = clmpcc_rdreg(sc, CLMPCC_REG_TIR); 1269 1.1 scw 1270 1.1 scw /* 1271 1.1 scw * If we're using auto-vectored interrupts, we have to 1272 1.1 scw * verify if the chip is generating the interrupt. 1273 1.1 scw */ 1274 1.1 scw if ( sc->sc_vector_base == 0 && (tir & CLMPCC_TIR_TACT) == 0 ) 1275 1.1 scw return 0; 1276 1.1 scw 1277 1.1 scw /* Get pointer to interrupting channel's data structure */ 1278 1.1 scw ch = &sc->sc_chans[tir & CLMPCC_TIR_TCN_MASK]; 1279 1.2 scw tp = ch->ch_tty; 1280 1.1 scw 1281 1.1 scw /* Dummy read of the interrupt status register */ 1282 1.1 scw (void) clmpcc_rdreg(sc, CLMPCC_REG_TISR); 1283 1.1 scw 1284 1.7.2.1 bouyer /* Make sure embedded transmit commands are disabled */ 1285 1.7.2.1 bouyer clmpcc_wrreg(sc, CLMPCC_REG_COR2, ch->ch_cor2); 1286 1.7.2.1 bouyer 1287 1.1 scw ftc = oftc = clmpcc_rdreg(sc, CLMPCC_REG_TFTC); 1288 1.1 scw 1289 1.2 scw /* Handle a delayed parameter change */ 1290 1.2 scw if ( ISSET(ch->ch_flags, CLMPCC_FLG_UPDATE_PARMS) ) { 1291 1.6 scw CLR(ch->ch_flags, CLMPCC_FLG_UPDATE_PARMS); 1292 1.2 scw clmpcc_set_params(ch); 1293 1.2 scw } 1294 1.2 scw 1295 1.6 scw if ( ch->ch_obuf_size > 0 ) { 1296 1.6 scw u_int n = min(ch->ch_obuf_size, ftc); 1297 1.1 scw 1298 1.6 scw clmpcc_wrtx_multi(sc, ch->ch_obuf_addr, n); 1299 1.2 scw 1300 1.6 scw ftc -= n; 1301 1.6 scw ch->ch_obuf_size -= n; 1302 1.6 scw ch->ch_obuf_addr += n; 1303 1.7.2.1 bouyer 1304 1.1 scw } else { 1305 1.1 scw /* 1306 1.7.2.1 bouyer * Check if we should start/stop a break 1307 1.1 scw */ 1308 1.1 scw if ( ISSET(ch->ch_flags, CLMPCC_FLG_START_BREAK) ) { 1309 1.1 scw CLR(ch->ch_flags, CLMPCC_FLG_START_BREAK); 1310 1.7.2.1 bouyer /* Enable embedded transmit commands */ 1311 1.7.2.1 bouyer clmpcc_wrreg(sc, CLMPCC_REG_COR2, 1312 1.7.2.1 bouyer ch->ch_cor2 | CLMPCC_COR2_ETC); 1313 1.7.2.1 bouyer clmpcc_wr_txdata(sc, CLMPCC_ETC_MAGIC); 1314 1.7.2.1 bouyer clmpcc_wr_txdata(sc, CLMPCC_ETC_SEND_BREAK); 1315 1.7.2.1 bouyer ftc -= 2; 1316 1.7.2.1 bouyer etcmode = 1; 1317 1.1 scw } 1318 1.1 scw 1319 1.1 scw if ( ISSET(ch->ch_flags, CLMPCC_FLG_END_BREAK) ) { 1320 1.1 scw CLR(ch->ch_flags, CLMPCC_FLG_END_BREAK); 1321 1.7.2.1 bouyer /* Enable embedded transmit commands */ 1322 1.7.2.1 bouyer clmpcc_wrreg(sc, CLMPCC_REG_COR2, 1323 1.7.2.1 bouyer ch->ch_cor2 | CLMPCC_COR2_ETC); 1324 1.7.2.1 bouyer clmpcc_wr_txdata(sc, CLMPCC_ETC_MAGIC); 1325 1.7.2.1 bouyer clmpcc_wr_txdata(sc, CLMPCC_ETC_STOP_BREAK); 1326 1.7.2.1 bouyer ftc -= 2; 1327 1.7.2.1 bouyer etcmode = 1; 1328 1.1 scw } 1329 1.7.2.1 bouyer } 1330 1.1 scw 1331 1.7.2.1 bouyer tir = clmpcc_rdreg(sc, CLMPCC_REG_IER); 1332 1.7.2.1 bouyer 1333 1.7.2.1 bouyer if ( ftc != oftc ) { 1334 1.7.2.1 bouyer /* 1335 1.7.2.1 bouyer * Enable/disable the Tx FIFO threshold interrupt 1336 1.7.2.1 bouyer * according to how much data is in the FIFO. 1337 1.7.2.1 bouyer * However, always disable the FIFO threshold if 1338 1.7.2.1 bouyer * we've left the channel in 'Embedded Transmit 1339 1.7.2.1 bouyer * Command' mode. 1340 1.7.2.1 bouyer */ 1341 1.7.2.1 bouyer if ( etcmode || ftc >= ch->ch_cor4 ) 1342 1.7.2.1 bouyer tir &= ~CLMPCC_IER_TX_FIFO; 1343 1.7.2.1 bouyer else 1344 1.7.2.1 bouyer tir |= CLMPCC_IER_TX_FIFO; 1345 1.7.2.1 bouyer teoir = 0; 1346 1.7.2.1 bouyer } else { 1347 1.1 scw /* 1348 1.7.2.1 bouyer * No data was sent. 1349 1.7.2.1 bouyer * Disable transmit interrupt. 1350 1.1 scw */ 1351 1.7.2.1 bouyer tir &= ~(CLMPCC_IER_TX_EMPTY|CLMPCC_IER_TX_FIFO); 1352 1.7.2.1 bouyer teoir = CLMPCC_TEOIR_NO_TRANS; 1353 1.1 scw 1354 1.6 scw /* 1355 1.6 scw * Request Tx processing in the soft interrupt handler 1356 1.6 scw */ 1357 1.6 scw ch->ch_tx_done = 1; 1358 1.7.2.1 bouyer #ifndef __GENERIC_SOFT_INTERRUPTS 1359 1.7.2.1 bouyer if ( sc->sc_soft_running == 0 ) { 1360 1.6 scw sc->sc_soft_running = 1; 1361 1.6 scw (sc->sc_softhook)(sc); 1362 1.6 scw } 1363 1.7.2.1 bouyer #else 1364 1.7.2.1 bouyer softintr_schedule(sc->sc_softintr_cookie); 1365 1.7.2.1 bouyer #endif 1366 1.2 scw } 1367 1.2 scw 1368 1.7.2.1 bouyer clmpcc_wrreg(sc, CLMPCC_REG_IER, tir); 1369 1.7.2.1 bouyer clmpcc_wrreg(sc, CLMPCC_REG_TEOIR, teoir); 1370 1.1 scw 1371 1.1 scw return 1; 1372 1.1 scw } 1373 1.1 scw 1374 1.1 scw /* 1375 1.1 scw * Modem change interrupt routine 1376 1.1 scw */ 1377 1.1 scw int 1378 1.1 scw clmpcc_mdintr(arg) 1379 1.1 scw void *arg; 1380 1.1 scw { 1381 1.1 scw struct clmpcc_softc *sc = (struct clmpcc_softc *)arg; 1382 1.2 scw u_char mir; 1383 1.1 scw 1384 1.1 scw /* Modem status interrupt active? */ 1385 1.1 scw mir = clmpcc_rdreg(sc, CLMPCC_REG_MIR); 1386 1.1 scw 1387 1.1 scw /* 1388 1.1 scw * If we're using auto-vectored interrupts, we have to 1389 1.1 scw * verify if the chip is generating the interrupt. 1390 1.1 scw */ 1391 1.1 scw if ( sc->sc_vector_base == 0 && (mir & CLMPCC_MIR_MACT) == 0 ) 1392 1.1 scw return 0; 1393 1.1 scw 1394 1.1 scw /* Dummy read of the interrupt status register */ 1395 1.1 scw (void) clmpcc_rdreg(sc, CLMPCC_REG_MISR); 1396 1.1 scw 1397 1.1 scw /* Retrieve current status of modem lines. */ 1398 1.1 scw sc->sc_chans[mir & CLMPCC_MIR_MCN_MASK].ch_control |= 1399 1.1 scw clmpcc_rd_msvr(sc) & CLMPCC_MSVR_CD; 1400 1.1 scw 1401 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_MEOIR, 0); 1402 1.1 scw 1403 1.7.2.1 bouyer #ifndef __GENERIC_SOFT_INTERRUPTS 1404 1.1 scw if ( sc->sc_soft_running == 0 ) { 1405 1.1 scw sc->sc_soft_running = 1; 1406 1.1 scw (sc->sc_softhook)(sc); 1407 1.1 scw } 1408 1.7.2.1 bouyer #else 1409 1.7.2.1 bouyer softintr_schedule(sc->sc_softintr_cookie); 1410 1.7.2.1 bouyer #endif 1411 1.1 scw 1412 1.1 scw return 1; 1413 1.1 scw } 1414 1.1 scw 1415 1.7.2.1 bouyer void 1416 1.1 scw clmpcc_softintr(arg) 1417 1.1 scw void *arg; 1418 1.1 scw { 1419 1.1 scw struct clmpcc_softc *sc = (struct clmpcc_softc *)arg; 1420 1.1 scw struct clmpcc_chan *ch; 1421 1.2 scw struct tty *tp; 1422 1.1 scw int (*rint) __P((int, struct tty *)); 1423 1.1 scw u_char *get; 1424 1.2 scw u_char reg; 1425 1.1 scw u_int c; 1426 1.1 scw int chan; 1427 1.1 scw 1428 1.7.2.1 bouyer #ifndef __GENERIC_SOFT_INTERRUPTS 1429 1.1 scw sc->sc_soft_running = 0; 1430 1.7.2.1 bouyer #endif 1431 1.1 scw 1432 1.1 scw /* Handle Modem state changes too... */ 1433 1.1 scw 1434 1.1 scw for (chan = 0; chan < CLMPCC_NUM_CHANS; chan++) { 1435 1.1 scw ch = &sc->sc_chans[chan]; 1436 1.2 scw tp = ch->ch_tty; 1437 1.2 scw 1438 1.1 scw get = ch->ch_ibuf_rd; 1439 1.7.2.2 bouyer rint = tp->t_linesw->l_rint; 1440 1.1 scw 1441 1.1 scw /* Squirt buffered incoming data into the tty layer */ 1442 1.1 scw while ( get != ch->ch_ibuf_wr ) { 1443 1.2 scw c = get[0]; 1444 1.2 scw c |= ((u_int)get[1]) << 8; 1445 1.2 scw if ( (rint)(c, tp) == -1 ) { 1446 1.6 scw ch->ch_ibuf_rd = ch->ch_ibuf_wr; 1447 1.6 scw break; 1448 1.2 scw } 1449 1.1 scw 1450 1.2 scw get += 2; 1451 1.1 scw if ( get == ch->ch_ibuf_end ) 1452 1.1 scw get = ch->ch_ibuf; 1453 1.1 scw 1454 1.1 scw ch->ch_ibuf_rd = get; 1455 1.1 scw } 1456 1.2 scw 1457 1.6 scw /* 1458 1.6 scw * Is the transmitter idle and in need of attention? 1459 1.6 scw */ 1460 1.6 scw if ( ch->ch_tx_done ) { 1461 1.6 scw ch->ch_tx_done = 0; 1462 1.2 scw 1463 1.6 scw if ( ISSET(ch->ch_flags, CLMPCC_FLG_NEED_INIT) ) { 1464 1.6 scw clmpcc_channel_cmd(sc, ch->ch_car, 1465 1.6 scw CLMPCC_CCR_T0_INIT | 1466 1.6 scw CLMPCC_CCR_T0_RX_EN | 1467 1.6 scw CLMPCC_CCR_T0_TX_EN); 1468 1.6 scw CLR(ch->ch_flags, CLMPCC_FLG_NEED_INIT); 1469 1.6 scw 1470 1.6 scw /* 1471 1.6 scw * Allow time for the channel to initialise. 1472 1.6 scw * (Empirically derived duration; there must 1473 1.6 scw * be another way to determine the command 1474 1.6 scw * has completed without busy-waiting...) 1475 1.6 scw */ 1476 1.6 scw delay(800); 1477 1.6 scw 1478 1.6 scw /* 1479 1.6 scw * Update the tty layer's idea of the carrier 1480 1.6 scw * bit, in case we changed CLOCAL or MDMBUF. 1481 1.6 scw * We don't hang up here; we only do that by 1482 1.6 scw * explicit request. 1483 1.6 scw */ 1484 1.6 scw reg = clmpcc_rd_msvr(sc) & CLMPCC_MSVR_CD; 1485 1.7.2.2 bouyer (*tp->t_linesw->l_modem)(tp, reg != 0); 1486 1.6 scw } 1487 1.4 scw 1488 1.6 scw CLR(tp->t_state, TS_BUSY); 1489 1.6 scw if ( ISSET(tp->t_state, TS_FLUSH) ) 1490 1.6 scw CLR(tp->t_state, TS_FLUSH); 1491 1.6 scw else 1492 1.6 scw ndflush(&tp->t_outq, 1493 1.6 scw (int)(ch->ch_obuf_addr - tp->t_outq.c_cf)); 1494 1.2 scw 1495 1.7.2.2 bouyer (*tp->t_linesw->l_start)(tp); 1496 1.6 scw } 1497 1.1 scw } 1498 1.1 scw } 1499 1.1 scw 1500 1.1 scw 1501 1.1 scw /*XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX*/ 1502 1.1 scw /*XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX*/ 1503 1.1 scw /*XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX*/ 1504 1.1 scw /* 1505 1.1 scw * Following are all routines needed for a cd240x channel to act as console 1506 1.1 scw */ 1507 1.1 scw int 1508 1.1 scw clmpcc_cnattach(sc, chan, rate) 1509 1.1 scw struct clmpcc_softc *sc; 1510 1.1 scw int chan; 1511 1.1 scw int rate; 1512 1.1 scw { 1513 1.1 scw cons_sc = sc; 1514 1.1 scw cons_chan = chan; 1515 1.1 scw cons_rate = rate; 1516 1.1 scw 1517 1.1 scw return 0; 1518 1.1 scw } 1519 1.1 scw 1520 1.1 scw /* 1521 1.1 scw * The following functions are polled getc and putc routines, for console use. 1522 1.1 scw */ 1523 1.1 scw static int 1524 1.1 scw clmpcc_common_getc(sc, chan) 1525 1.1 scw struct clmpcc_softc *sc; 1526 1.1 scw int chan; 1527 1.1 scw { 1528 1.1 scw u_char old_chan; 1529 1.1 scw u_char old_ier; 1530 1.1 scw u_char ch, rir, risr; 1531 1.1 scw int s; 1532 1.1 scw 1533 1.1 scw s = splhigh(); 1534 1.1 scw 1535 1.4 scw /* Save the currently active channel */ 1536 1.1 scw old_chan = clmpcc_select_channel(sc, chan); 1537 1.1 scw 1538 1.1 scw /* 1539 1.1 scw * We have to put the channel into RX interrupt mode before 1540 1.1 scw * trying to read the Rx data register. So save the previous 1541 1.1 scw * interrupt mode. 1542 1.1 scw */ 1543 1.1 scw old_ier = clmpcc_rdreg(sc, CLMPCC_REG_IER); 1544 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_IER, CLMPCC_IER_RX_FIFO); 1545 1.1 scw 1546 1.1 scw /* Loop until we get a character */ 1547 1.1 scw for (;;) { 1548 1.1 scw /* 1549 1.1 scw * The REN bit will be set in the Receive Interrupt Register 1550 1.1 scw * when the CD240x has a character to process. Remember, 1551 1.1 scw * the RACT bit won't be set until we generate an interrupt 1552 1.1 scw * acknowledge cycle via the MD front-end. 1553 1.1 scw */ 1554 1.1 scw rir = clmpcc_rdreg(sc, CLMPCC_REG_RIR); 1555 1.1 scw if ( (rir & CLMPCC_RIR_REN) == 0 ) 1556 1.1 scw continue; 1557 1.1 scw 1558 1.1 scw /* Acknowledge the request */ 1559 1.1 scw if ( sc->sc_iackhook ) 1560 1.1 scw (sc->sc_iackhook)(sc, CLMPCC_IACK_RX); 1561 1.1 scw 1562 1.1 scw /* 1563 1.1 scw * Determine if the interrupt is for the required channel 1564 1.1 scw * and if valid data is available. 1565 1.1 scw */ 1566 1.1 scw rir = clmpcc_rdreg(sc, CLMPCC_REG_RIR); 1567 1.1 scw risr = clmpcc_rdreg(sc, CLMPCC_REG_RISR); 1568 1.1 scw if ( (rir & CLMPCC_RIR_RCN_MASK) != chan || 1569 1.1 scw risr != 0 ) { 1570 1.1 scw /* Rx error, or BREAK */ 1571 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_REOIR, 1572 1.1 scw CLMPCC_REOIR_NO_TRANS); 1573 1.1 scw } else { 1574 1.1 scw /* Dummy read of the FIFO count register */ 1575 1.1 scw (void) clmpcc_rdreg(sc, CLMPCC_REG_RFOC); 1576 1.1 scw 1577 1.1 scw /* Fetch the received character */ 1578 1.1 scw ch = clmpcc_rd_rxdata(sc); 1579 1.1 scw 1580 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_REOIR, 0); 1581 1.1 scw break; 1582 1.1 scw } 1583 1.1 scw } 1584 1.1 scw 1585 1.4 scw /* Restore the original IER and CAR register contents */ 1586 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_IER, old_ier); 1587 1.1 scw clmpcc_select_channel(sc, old_chan); 1588 1.1 scw 1589 1.1 scw splx(s); 1590 1.1 scw return ch; 1591 1.1 scw } 1592 1.1 scw 1593 1.1 scw 1594 1.1 scw static void 1595 1.1 scw clmpcc_common_putc(sc, chan, c) 1596 1.1 scw struct clmpcc_softc *sc; 1597 1.1 scw int chan; 1598 1.1 scw int c; 1599 1.1 scw { 1600 1.1 scw u_char old_chan; 1601 1.1 scw int s = splhigh(); 1602 1.1 scw 1603 1.4 scw /* Save the currently active channel */ 1604 1.1 scw old_chan = clmpcc_select_channel(sc, chan); 1605 1.4 scw 1606 1.4 scw /* 1607 1.4 scw * Since we can only access the Tx Data register from within 1608 1.4 scw * the interrupt handler, the easiest way to get console data 1609 1.4 scw * onto the wire is using one of the Special Transmit Character 1610 1.4 scw * registers. 1611 1.4 scw */ 1612 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_SCHR4, c); 1613 1.1 scw clmpcc_wrreg(sc, CLMPCC_REG_STCR, CLMPCC_STCR_SSPC(4) | 1614 1.1 scw CLMPCC_STCR_SND_SPC); 1615 1.1 scw 1616 1.4 scw /* Wait until the "Send Special Character" command is accepted */ 1617 1.1 scw while ( clmpcc_rdreg(sc, CLMPCC_REG_STCR) != 0 ) 1618 1.1 scw ; 1619 1.1 scw 1620 1.4 scw /* Restore the previous channel selected */ 1621 1.1 scw clmpcc_select_channel(sc, old_chan); 1622 1.1 scw 1623 1.1 scw splx(s); 1624 1.1 scw } 1625 1.1 scw 1626 1.1 scw int 1627 1.1 scw clmpcccngetc(dev) 1628 1.1 scw dev_t dev; 1629 1.1 scw { 1630 1.1 scw return clmpcc_common_getc(cons_sc, cons_chan); 1631 1.1 scw } 1632 1.1 scw 1633 1.1 scw /* 1634 1.1 scw * Console kernel output character routine. 1635 1.1 scw */ 1636 1.1 scw void 1637 1.1 scw clmpcccnputc(dev, c) 1638 1.1 scw dev_t dev; 1639 1.1 scw int c; 1640 1.1 scw { 1641 1.1 scw if ( c == '\n' ) 1642 1.1 scw clmpcc_common_putc(cons_sc, cons_chan, '\r'); 1643 1.1 scw 1644 1.1 scw clmpcc_common_putc(cons_sc, cons_chan, c); 1645 1.1 scw } 1646
Indexes created Tue Oct 21 05:10:09 GMT 2025