mt.c revision 1.23.8.1
1 1.23.8.1 bouyer /* $NetBSD: mt.c,v 1.23.8.1 2011/02/17 12:00:11 bouyer Exp $ */ 2 1.1 gmcgarry 3 1.1 gmcgarry /*- 4 1.1 gmcgarry * Copyright (c) 1996-2003 The NetBSD Foundation, Inc. 5 1.1 gmcgarry * All rights reserved. 6 1.1 gmcgarry * 7 1.1 gmcgarry * This code is derived from software contributed to The NetBSD Foundation 8 1.1 gmcgarry * by Jason R. Thorpe. 9 1.1 gmcgarry * 10 1.1 gmcgarry * Redistribution and use in source and binary forms, with or without 11 1.1 gmcgarry * modification, are permitted provided that the following conditions 12 1.1 gmcgarry * are met: 13 1.1 gmcgarry * 1. Redistributions of source code must retain the above copyright 14 1.1 gmcgarry * notice, this list of conditions and the following disclaimer. 15 1.1 gmcgarry * 2. Redistributions in binary form must reproduce the above copyright 16 1.1 gmcgarry * notice, this list of conditions and the following disclaimer in the 17 1.1 gmcgarry * documentation and/or other materials provided with the distribution. 18 1.1 gmcgarry * 19 1.1 gmcgarry * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 20 1.1 gmcgarry * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 21 1.1 gmcgarry * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 22 1.1 gmcgarry * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 23 1.1 gmcgarry * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 24 1.1 gmcgarry * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 25 1.1 gmcgarry * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 26 1.1 gmcgarry * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 27 1.1 gmcgarry * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 28 1.1 gmcgarry * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 29 1.1 gmcgarry * POSSIBILITY OF SUCH DAMAGE. 30 1.1 gmcgarry */ 31 1.1 gmcgarry 32 1.1 gmcgarry /* 33 1.23.8.1 bouyer * Copyright (c) 1988 University of Utah. 34 1.1 gmcgarry * Copyright (c) 1982, 1990, 1993 35 1.1 gmcgarry * The Regents of the University of California. All rights reserved. 36 1.1 gmcgarry * 37 1.1 gmcgarry * This code is derived from software contributed to Berkeley by 38 1.1 gmcgarry * the Systems Programming Group of the University of Utah Computer 39 1.1 gmcgarry * Science Department. 40 1.1 gmcgarry * 41 1.1 gmcgarry * Redistribution and use in source and binary forms, with or without 42 1.1 gmcgarry * modification, are permitted provided that the following conditions 43 1.1 gmcgarry * are met: 44 1.1 gmcgarry * 1. Redistributions of source code must retain the above copyright 45 1.1 gmcgarry * notice, this list of conditions and the following disclaimer. 46 1.1 gmcgarry * 2. Redistributions in binary form must reproduce the above copyright 47 1.1 gmcgarry * notice, this list of conditions and the following disclaimer in the 48 1.1 gmcgarry * documentation and/or other materials provided with the distribution. 49 1.2 agc * 3. Neither the name of the University nor the names of its contributors 50 1.2 agc * may be used to endorse or promote products derived from this software 51 1.2 agc * without specific prior written permission. 52 1.2 agc * 53 1.2 agc * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND 54 1.2 agc * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 55 1.2 agc * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 56 1.2 agc * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE 57 1.2 agc * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 58 1.2 agc * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 59 1.2 agc * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 60 1.2 agc * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 61 1.2 agc * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 62 1.2 agc * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 63 1.2 agc * SUCH DAMAGE. 64 1.2 agc * 65 1.2 agc * from: Utah $Hdr: rd.c 1.44 92/12/26$ 66 1.2 agc * 67 1.2 agc * @(#)rd.c 8.2 (Berkeley) 5/19/94 68 1.2 agc */ 69 1.2 agc 70 1.2 agc /* 71 1.1 gmcgarry * Magnetic tape driver (HP7974a, HP7978a/b, HP7979a, HP7980a, HP7980xc) 72 1.1 gmcgarry * Original version contributed by Mt. Xinu. 73 1.1 gmcgarry * Modified for 4.4BSD by Mark Davies and Andrew Vignaux, Department of 74 1.1 gmcgarry * Computer Science, Victoria University of Wellington 75 1.1 gmcgarry */ 76 1.1 gmcgarry 77 1.1 gmcgarry #include <sys/cdefs.h> 78 1.23.8.1 bouyer __KERNEL_RCSID(0, "$NetBSD: mt.c,v 1.23.8.1 2011/02/17 12:00:11 bouyer Exp $"); 79 1.1 gmcgarry 80 1.1 gmcgarry #include <sys/param.h> 81 1.1 gmcgarry #include <sys/systm.h> 82 1.1 gmcgarry #include <sys/callout.h> 83 1.1 gmcgarry #include <sys/buf.h> 84 1.3 yamt #include <sys/bufq.h> 85 1.1 gmcgarry #include <sys/ioctl.h> 86 1.1 gmcgarry #include <sys/mtio.h> 87 1.1 gmcgarry #include <sys/file.h> 88 1.1 gmcgarry #include <sys/proc.h> 89 1.1 gmcgarry #include <sys/tty.h> 90 1.1 gmcgarry #include <sys/kernel.h> 91 1.1 gmcgarry #include <sys/tprintf.h> 92 1.1 gmcgarry #include <sys/device.h> 93 1.1 gmcgarry #include <sys/conf.h> 94 1.1 gmcgarry 95 1.1 gmcgarry #include <dev/gpib/gpibvar.h> 96 1.1 gmcgarry #include <dev/gpib/cs80busvar.h> 97 1.1 gmcgarry 98 1.1 gmcgarry #include <dev/gpib/mtreg.h> 99 1.1 gmcgarry 100 1.1 gmcgarry #ifdef DEBUG 101 1.1 gmcgarry int mtdebug = 0; 102 1.1 gmcgarry #define MDB_ANY 0xff 103 1.1 gmcgarry #define MDB_FOLLOW 0x01 104 1.1 gmcgarry #define DPRINTF(mask, str) if (mtdebug & (mask)) printf str 105 1.1 gmcgarry #else 106 1.1 gmcgarry #define DPRINTF(mask, str) /* nothing */ 107 1.1 gmcgarry #endif 108 1.1 gmcgarry 109 1.1 gmcgarry struct mt_softc { 110 1.1 gmcgarry struct device sc_dev; 111 1.1 gmcgarry 112 1.1 gmcgarry gpib_chipset_tag_t sc_ic; 113 1.1 gmcgarry gpib_handle_t sc_hdl; 114 1.1 gmcgarry 115 1.1 gmcgarry int sc_slave; /* GPIB slave address (0-6) */ 116 1.1 gmcgarry short sc_flags; /* see below */ 117 1.1 gmcgarry u_char sc_lastdsj; /* place for DSJ in mtreaddsj() */ 118 1.1 gmcgarry u_char sc_lastecmd; /* place for End Command in mtreaddsj() */ 119 1.1 gmcgarry short sc_recvtimeo; /* count of gpibsend timeouts to prevent hang */ 120 1.1 gmcgarry short sc_statindex; /* index for next sc_stat when MTF_STATTIMEO */ 121 1.1 gmcgarry struct mt_stat sc_stat;/* status bytes last read from device */ 122 1.1 gmcgarry short sc_density; /* current density of tape (mtio.h format) */ 123 1.1 gmcgarry short sc_type; /* tape drive model (hardware IDs) */ 124 1.1 gmcgarry tpr_t sc_ttyp; 125 1.4 yamt struct bufq_state *sc_tab;/* buf queue */ 126 1.1 gmcgarry int sc_active; 127 1.1 gmcgarry struct buf sc_bufstore; /* XXX buffer storage */ 128 1.1 gmcgarry 129 1.1 gmcgarry struct callout sc_start_ch; 130 1.1 gmcgarry struct callout sc_intr_ch; 131 1.1 gmcgarry }; 132 1.1 gmcgarry 133 1.1 gmcgarry #define MTUNIT(x) (minor(x) & 0x03) 134 1.1 gmcgarry 135 1.8 reinoud #define B_CMD B_DEVPRIVATE /* command buf instead of data */ 136 1.1 gmcgarry #define b_cmd b_blkno /* blkno holds cmd when B_CMD */ 137 1.1 gmcgarry 138 1.20 cegger int mtmatch(device_t, cfdata_t, void *); 139 1.20 cegger void mtattach(device_t, device_t, void *); 140 1.1 gmcgarry 141 1.1 gmcgarry CFATTACH_DECL(mt, sizeof(struct mt_softc), 142 1.1 gmcgarry mtmatch, mtattach, NULL, NULL); 143 1.1 gmcgarry 144 1.1 gmcgarry int mtlookup(int, int, int); 145 1.1 gmcgarry void mtustart(struct mt_softc *); 146 1.1 gmcgarry int mtreaddsj(struct mt_softc *, int); 147 1.1 gmcgarry int mtcommand(dev_t, int, int); 148 1.1 gmcgarry 149 1.1 gmcgarry void mtintr_callout(void *); 150 1.1 gmcgarry void mtstart_callout(void *); 151 1.1 gmcgarry 152 1.1 gmcgarry void mtcallback(void *, int); 153 1.1 gmcgarry void mtstart(struct mt_softc *); 154 1.1 gmcgarry void mtintr(struct mt_softc *); 155 1.1 gmcgarry 156 1.1 gmcgarry dev_type_open(mtopen); 157 1.1 gmcgarry dev_type_close(mtclose); 158 1.1 gmcgarry dev_type_read(mtread); 159 1.1 gmcgarry dev_type_write(mtwrite); 160 1.1 gmcgarry dev_type_ioctl(mtioctl); 161 1.1 gmcgarry dev_type_strategy(mtstrategy); 162 1.1 gmcgarry 163 1.1 gmcgarry const struct bdevsw mt_bdevsw = { 164 1.1 gmcgarry mtopen, mtclose, mtstrategy, mtioctl, nodump, nosize, D_TAPE 165 1.1 gmcgarry }; 166 1.1 gmcgarry 167 1.1 gmcgarry const struct cdevsw mt_cdevsw = { 168 1.1 gmcgarry mtopen, mtclose, mtread, mtwrite, mtioctl, 169 1.1 gmcgarry nostop, notty, nopoll, nommap, nokqfilter, D_TAPE 170 1.1 gmcgarry }; 171 1.1 gmcgarry 172 1.1 gmcgarry 173 1.1 gmcgarry extern struct cfdriver mt_cd; 174 1.1 gmcgarry 175 1.1 gmcgarry struct mtinfo { 176 1.1 gmcgarry u_short hwid; 177 1.7 cube const char *desc; 178 1.1 gmcgarry } mtinfo[] = { 179 1.1 gmcgarry { MT7978ID, "7978" }, 180 1.1 gmcgarry { MT7979AID, "7979A" }, 181 1.1 gmcgarry { MT7980ID, "7980" }, 182 1.1 gmcgarry { MT7974AID, "7974A" }, 183 1.1 gmcgarry }; 184 1.1 gmcgarry int nmtinfo = sizeof(mtinfo) / sizeof(mtinfo[0]); 185 1.1 gmcgarry 186 1.1 gmcgarry 187 1.1 gmcgarry int 188 1.17 dsl mtlookup(int id, int slave, int punit) 189 1.1 gmcgarry { 190 1.1 gmcgarry int i; 191 1.1 gmcgarry 192 1.1 gmcgarry for (i = 0; i < nmtinfo; i++) 193 1.1 gmcgarry if (mtinfo[i].hwid == id) 194 1.1 gmcgarry break; 195 1.1 gmcgarry if (i == nmtinfo) 196 1.1 gmcgarry return (-1); 197 1.1 gmcgarry return (0); 198 1.1 gmcgarry } 199 1.1 gmcgarry 200 1.1 gmcgarry int 201 1.20 cegger mtmatch(device_t parent, cfdata_t match, void *aux) 202 1.1 gmcgarry { 203 1.1 gmcgarry struct cs80bus_attach_args *ca = aux; 204 1.1 gmcgarry 205 1.1 gmcgarry ca->ca_punit = 0; 206 1.1 gmcgarry return (mtlookup(ca->ca_id, ca->ca_slave, ca->ca_punit) == 0); 207 1.1 gmcgarry } 208 1.1 gmcgarry 209 1.1 gmcgarry void 210 1.20 cegger mtattach(device_t parent, device_t self, void *aux) 211 1.1 gmcgarry { 212 1.6 thorpej struct mt_softc *sc = device_private(self); 213 1.1 gmcgarry struct cs80bus_attach_args *ca = aux; 214 1.1 gmcgarry int type; 215 1.1 gmcgarry 216 1.1 gmcgarry sc->sc_ic = ca->ca_ic; 217 1.1 gmcgarry sc->sc_slave = ca->ca_slave; 218 1.1 gmcgarry 219 1.1 gmcgarry if ((type = mtlookup(ca->ca_id, ca->ca_slave, ca->ca_punit)) < 0) 220 1.1 gmcgarry return; 221 1.1 gmcgarry 222 1.1 gmcgarry printf(": %s tape\n", mtinfo[type].desc); 223 1.1 gmcgarry 224 1.1 gmcgarry sc->sc_type = type; 225 1.1 gmcgarry sc->sc_flags = MTF_EXISTS; 226 1.1 gmcgarry 227 1.4 yamt bufq_alloc(&sc->sc_tab, "fcfs", 0); 228 1.10 ad callout_init(&sc->sc_start_ch, 0); 229 1.10 ad callout_init(&sc->sc_intr_ch, 0); 230 1.1 gmcgarry 231 1.1 gmcgarry if (gpibregister(sc->sc_ic, sc->sc_slave, mtcallback, sc, 232 1.1 gmcgarry &sc->sc_hdl)) { 233 1.13 cegger aprint_error_dev(&sc->sc_dev, "can't register callback\n"); 234 1.1 gmcgarry return; 235 1.1 gmcgarry } 236 1.1 gmcgarry } 237 1.1 gmcgarry 238 1.1 gmcgarry /* 239 1.1 gmcgarry * Perform a read of "Device Status Jump" register and update the 240 1.1 gmcgarry * status if necessary. If status is read, the given "ecmd" is also 241 1.1 gmcgarry * performed, unless "ecmd" is zero. Returns DSJ value, -1 on failure 242 1.1 gmcgarry * and -2 on "temporary" failure. 243 1.1 gmcgarry */ 244 1.1 gmcgarry int 245 1.17 dsl mtreaddsj(struct mt_softc *sc, int ecmd) 246 1.1 gmcgarry { 247 1.1 gmcgarry int retval; 248 1.1 gmcgarry 249 1.1 gmcgarry if (sc->sc_flags & MTF_STATTIMEO) 250 1.1 gmcgarry goto getstats; 251 1.1 gmcgarry retval = gpibrecv(sc->sc_ic, 252 1.1 gmcgarry (sc->sc_flags & MTF_DSJTIMEO) ? -1 : sc->sc_slave, 253 1.1 gmcgarry MTT_DSJ, &(sc->sc_lastdsj), 1); 254 1.1 gmcgarry sc->sc_flags &= ~MTF_DSJTIMEO; 255 1.1 gmcgarry if (retval != 1) { 256 1.1 gmcgarry DPRINTF(MDB_ANY, ("%s can't gpibrecv DSJ", 257 1.13 cegger device_xname(&sc->sc_dev))); 258 1.1 gmcgarry if (sc->sc_recvtimeo == 0) 259 1.1 gmcgarry sc->sc_recvtimeo = hz; 260 1.1 gmcgarry if (--sc->sc_recvtimeo == 0) 261 1.1 gmcgarry return (-1); 262 1.1 gmcgarry if (retval == 0) 263 1.1 gmcgarry sc->sc_flags |= MTF_DSJTIMEO; 264 1.1 gmcgarry return (-2); 265 1.1 gmcgarry } 266 1.1 gmcgarry sc->sc_recvtimeo = 0; 267 1.1 gmcgarry sc->sc_statindex = 0; 268 1.13 cegger DPRINTF(MDB_ANY, ("%s readdsj: 0x%x", device_xname(&sc->sc_dev), 269 1.1 gmcgarry sc->sc_lastdsj)); 270 1.1 gmcgarry sc->sc_lastecmd = ecmd; 271 1.1 gmcgarry switch (sc->sc_lastdsj) { 272 1.1 gmcgarry case 0: 273 1.1 gmcgarry if (ecmd & MTE_DSJ_FORCE) 274 1.1 gmcgarry break; 275 1.1 gmcgarry return (0); 276 1.1 gmcgarry 277 1.1 gmcgarry case 2: 278 1.1 gmcgarry sc->sc_lastecmd = MTE_COMPLETE; 279 1.1 gmcgarry case 1: 280 1.1 gmcgarry break; 281 1.1 gmcgarry 282 1.1 gmcgarry default: 283 1.13 cegger printf("%s readdsj: DSJ 0x%x\n", device_xname(&sc->sc_dev), 284 1.1 gmcgarry sc->sc_lastdsj); 285 1.1 gmcgarry return (-1); 286 1.1 gmcgarry } 287 1.1 gmcgarry 288 1.1 gmcgarry getstats: 289 1.1 gmcgarry retval = gpibrecv(sc->sc_ic, 290 1.1 gmcgarry (sc->sc_flags & MTF_STATCONT) ? -1 : sc->sc_slave, MTT_STAT, 291 1.1 gmcgarry ((char *)&(sc->sc_stat)) + sc->sc_statindex, 292 1.1 gmcgarry sizeof(sc->sc_stat) - sc->sc_statindex); 293 1.1 gmcgarry sc->sc_flags &= ~(MTF_STATTIMEO | MTF_STATCONT); 294 1.1 gmcgarry if (retval != sizeof(sc->sc_stat) - sc->sc_statindex) { 295 1.1 gmcgarry if (sc->sc_recvtimeo == 0) 296 1.1 gmcgarry sc->sc_recvtimeo = hz; 297 1.1 gmcgarry if (--sc->sc_recvtimeo != 0) { 298 1.1 gmcgarry if (retval >= 0) { 299 1.1 gmcgarry sc->sc_statindex += retval; 300 1.1 gmcgarry sc->sc_flags |= MTF_STATCONT; 301 1.1 gmcgarry } 302 1.1 gmcgarry sc->sc_flags |= MTF_STATTIMEO; 303 1.1 gmcgarry return (-2); 304 1.1 gmcgarry } 305 1.13 cegger printf("%s readdsj: can't read status", device_xname(&sc->sc_dev)); 306 1.1 gmcgarry return (-1); 307 1.1 gmcgarry } 308 1.1 gmcgarry sc->sc_recvtimeo = 0; 309 1.1 gmcgarry sc->sc_statindex = 0; 310 1.1 gmcgarry DPRINTF(MDB_ANY, ("%s readdsj: status is %x %x %x %x %x %x", 311 1.13 cegger device_xname(&sc->sc_dev), 312 1.1 gmcgarry sc->sc_stat1, sc->sc_stat2, sc->sc_stat3, 313 1.1 gmcgarry sc->sc_stat4, sc->sc_stat5, sc->sc_stat6)); 314 1.1 gmcgarry if (sc->sc_lastecmd) 315 1.1 gmcgarry (void) gpibsend(sc->sc_ic, sc->sc_slave, 316 1.1 gmcgarry MTL_ECMD, &(sc->sc_lastecmd), 1); 317 1.1 gmcgarry return ((int) sc->sc_lastdsj); 318 1.1 gmcgarry } 319 1.1 gmcgarry 320 1.1 gmcgarry int 321 1.15 cegger mtopen(dev_t dev, int flag, int mode, struct lwp *l) 322 1.1 gmcgarry { 323 1.1 gmcgarry struct mt_softc *sc; 324 1.1 gmcgarry int req_den; 325 1.1 gmcgarry int error; 326 1.1 gmcgarry 327 1.15 cegger sc = device_lookup_private(&mt_cd, MTUNIT(dev)); 328 1.1 gmcgarry if (sc == NULL || (sc->sc_flags & MTF_EXISTS) == 0) 329 1.1 gmcgarry return (ENXIO); 330 1.1 gmcgarry 331 1.1 gmcgarry if (sc->sc_flags & MTF_OPEN) 332 1.1 gmcgarry return (EBUSY); 333 1.1 gmcgarry 334 1.13 cegger DPRINTF(MDB_ANY, ("%s open: flags 0x%x", device_xname(&sc->sc_dev), 335 1.1 gmcgarry sc->sc_flags)); 336 1.1 gmcgarry 337 1.1 gmcgarry sc->sc_flags |= MTF_OPEN; 338 1.7 cube sc->sc_ttyp = tprintf_open(l->l_proc); 339 1.1 gmcgarry if ((sc->sc_flags & MTF_ALIVE) == 0) { 340 1.1 gmcgarry error = mtcommand(dev, MTRESET, 0); 341 1.1 gmcgarry if (error != 0 || (sc->sc_flags & MTF_ALIVE) == 0) 342 1.1 gmcgarry goto errout; 343 1.1 gmcgarry if ((sc->sc_stat1 & (SR1_BOT | SR1_ONLINE)) == SR1_ONLINE) 344 1.1 gmcgarry (void) mtcommand(dev, MTREW, 0); 345 1.1 gmcgarry } 346 1.1 gmcgarry for (;;) { 347 1.1 gmcgarry if ((error = mtcommand(dev, MTNOP, 0)) != 0) 348 1.1 gmcgarry goto errout; 349 1.1 gmcgarry if (!(sc->sc_flags & MTF_REW)) 350 1.1 gmcgarry break; 351 1.23 pooka error = kpause("mt", true, hz, NULL); 352 1.23 pooka if (error != 0 && error != EWOULDBLOCK) { 353 1.1 gmcgarry error = EINTR; 354 1.1 gmcgarry goto errout; 355 1.1 gmcgarry } 356 1.1 gmcgarry } 357 1.1 gmcgarry if ((flag & FWRITE) && (sc->sc_stat1 & SR1_RO)) { 358 1.1 gmcgarry error = EROFS; 359 1.1 gmcgarry goto errout; 360 1.1 gmcgarry } 361 1.1 gmcgarry if (!(sc->sc_stat1 & SR1_ONLINE)) { 362 1.13 cegger uprintf("%s: not online\n", device_xname(&sc->sc_dev)); 363 1.1 gmcgarry error = EIO; 364 1.1 gmcgarry goto errout; 365 1.1 gmcgarry } 366 1.1 gmcgarry /* 367 1.1 gmcgarry * Select density: 368 1.1 gmcgarry * - find out what density the drive is set to 369 1.1 gmcgarry * (i.e. the density of the current tape) 370 1.1 gmcgarry * - if we are going to write 371 1.1 gmcgarry * - if we're not at the beginning of the tape 372 1.1 gmcgarry * - complain if we want to change densities 373 1.1 gmcgarry * - otherwise, select the mtcommand to set the density 374 1.1 gmcgarry * 375 1.1 gmcgarry * If the drive doesn't support it then don't change the recorded 376 1.1 gmcgarry * density. 377 1.1 gmcgarry * 378 1.1 gmcgarry * The original MOREbsd code had these additional conditions 379 1.1 gmcgarry * for the mid-tape change 380 1.1 gmcgarry * 381 1.1 gmcgarry * req_den != T_BADBPI && 382 1.1 gmcgarry * sc->sc_density != T_6250BPI 383 1.1 gmcgarry * 384 1.1 gmcgarry * which suggests that it would be possible to write multiple 385 1.1 gmcgarry * densities if req_den == T_BAD_BPI or the current tape 386 1.1 gmcgarry * density was 6250. Testing of our 7980 suggests that the 387 1.1 gmcgarry * device cannot change densities mid-tape. 388 1.1 gmcgarry * 389 1.1 gmcgarry * ajv (at) comp.vuw.ac.nz 390 1.1 gmcgarry */ 391 1.1 gmcgarry sc->sc_density = (sc->sc_stat2 & SR2_6250) ? T_6250BPI : ( 392 1.1 gmcgarry (sc->sc_stat3 & SR3_1600) ? T_1600BPI : ( 393 1.1 gmcgarry (sc->sc_stat3 & SR3_800) ? T_800BPI : -1)); 394 1.1 gmcgarry req_den = (dev & T_DENSEL); 395 1.1 gmcgarry 396 1.1 gmcgarry if (flag & FWRITE) { 397 1.1 gmcgarry if (!(sc->sc_stat1 & SR1_BOT)) { 398 1.1 gmcgarry if (sc->sc_density != req_den) { 399 1.1 gmcgarry uprintf("%s: can't change density mid-tape\n", 400 1.13 cegger device_xname(&sc->sc_dev)); 401 1.1 gmcgarry error = EIO; 402 1.1 gmcgarry goto errout; 403 1.1 gmcgarry } 404 1.1 gmcgarry } 405 1.1 gmcgarry else { 406 1.1 gmcgarry int mtset_density = 407 1.1 gmcgarry (req_den == T_800BPI ? MTSET800BPI : ( 408 1.1 gmcgarry req_den == T_1600BPI ? MTSET1600BPI : ( 409 1.1 gmcgarry req_den == T_6250BPI ? MTSET6250BPI : ( 410 1.1 gmcgarry sc->sc_type == MT7980ID 411 1.1 gmcgarry ? MTSET6250DC 412 1.1 gmcgarry : MTSET6250BPI)))); 413 1.1 gmcgarry if (mtcommand(dev, mtset_density, 0) == 0) 414 1.1 gmcgarry sc->sc_density = req_den; 415 1.1 gmcgarry } 416 1.1 gmcgarry } 417 1.1 gmcgarry return (0); 418 1.1 gmcgarry errout: 419 1.1 gmcgarry sc->sc_flags &= ~MTF_OPEN; 420 1.1 gmcgarry return (error); 421 1.1 gmcgarry } 422 1.1 gmcgarry 423 1.1 gmcgarry int 424 1.15 cegger mtclose(dev_t dev, int flag, int fmt, struct lwp *l) 425 1.1 gmcgarry { 426 1.1 gmcgarry struct mt_softc *sc; 427 1.1 gmcgarry 428 1.15 cegger sc = device_lookup_private(&mt_cd, MTUNIT(dev)); 429 1.1 gmcgarry if (sc == NULL) 430 1.1 gmcgarry return (ENXIO); 431 1.1 gmcgarry 432 1.1 gmcgarry if (sc->sc_flags & MTF_WRT) { 433 1.1 gmcgarry (void) mtcommand(dev, MTWEOF, 2); 434 1.1 gmcgarry (void) mtcommand(dev, MTBSF, 0); 435 1.1 gmcgarry } 436 1.1 gmcgarry if ((minor(dev) & T_NOREWIND) == 0) 437 1.1 gmcgarry (void) mtcommand(dev, MTREW, 0); 438 1.1 gmcgarry sc->sc_flags &= ~MTF_OPEN; 439 1.1 gmcgarry tprintf_close(sc->sc_ttyp); 440 1.1 gmcgarry return (0); 441 1.1 gmcgarry } 442 1.1 gmcgarry 443 1.1 gmcgarry int 444 1.15 cegger mtcommand(dev_t dev, int cmd, int cnt) 445 1.1 gmcgarry { 446 1.1 gmcgarry struct mt_softc *sc; 447 1.1 gmcgarry struct buf *bp; 448 1.1 gmcgarry int error = 0; 449 1.1 gmcgarry 450 1.15 cegger sc = device_lookup_private(&mt_cd, MTUNIT(dev)); 451 1.1 gmcgarry bp = &sc->sc_bufstore; 452 1.1 gmcgarry 453 1.12 ad if (bp->b_cflags & BC_BUSY) 454 1.1 gmcgarry return (EBUSY); 455 1.1 gmcgarry 456 1.1 gmcgarry bp->b_cmd = cmd; 457 1.1 gmcgarry bp->b_dev = dev; 458 1.12 ad bp->b_objlock = &buffer_lock; 459 1.1 gmcgarry do { 460 1.12 ad bp->b_cflags = BC_BUSY; 461 1.12 ad bp->b_flags = B_CMD; 462 1.12 ad bp->b_oflags = 0; 463 1.1 gmcgarry mtstrategy(bp); 464 1.1 gmcgarry biowait(bp); 465 1.11 ad if (bp->b_error != 0) { 466 1.1 gmcgarry error = (int) (unsigned) bp->b_error; 467 1.1 gmcgarry break; 468 1.1 gmcgarry } 469 1.1 gmcgarry } while (--cnt > 0); 470 1.1 gmcgarry #if 0 471 1.12 ad bp->b_cflags = 0 /*&= ~BC_BUSY*/; 472 1.1 gmcgarry #else 473 1.12 ad bp->b_cflags &= ~BC_BUSY; 474 1.1 gmcgarry #endif 475 1.1 gmcgarry return (error); 476 1.1 gmcgarry } 477 1.1 gmcgarry 478 1.1 gmcgarry /* 479 1.1 gmcgarry * Only thing to check here is for legal record lengths (writes only). 480 1.1 gmcgarry */ 481 1.1 gmcgarry void 482 1.15 cegger mtstrategy(struct buf *bp) 483 1.1 gmcgarry { 484 1.1 gmcgarry struct mt_softc *sc; 485 1.1 gmcgarry int s; 486 1.1 gmcgarry 487 1.15 cegger sc = device_lookup_private(&mt_cd, MTUNIT(bp->b_dev)); 488 1.1 gmcgarry 489 1.13 cegger DPRINTF(MDB_ANY, ("%s strategy", device_xname(&sc->sc_dev))); 490 1.1 gmcgarry 491 1.1 gmcgarry if ((bp->b_flags & (B_CMD | B_READ)) == 0) { 492 1.1 gmcgarry #define WRITE_BITS_IGNORED 8 493 1.1 gmcgarry #if 0 494 1.1 gmcgarry if (bp->b_bcount & ((1 << WRITE_BITS_IGNORED) - 1)) { 495 1.1 gmcgarry tprintf(sc->sc_ttyp, 496 1.1 gmcgarry "%s: write record must be multiple of %d\n", 497 1.13 cegger device_xname(&sc->sc_dev), 1 << WRITE_BITS_IGNORED); 498 1.1 gmcgarry goto error; 499 1.1 gmcgarry } 500 1.1 gmcgarry #endif 501 1.1 gmcgarry s = 16 * 1024; 502 1.1 gmcgarry if (sc->sc_stat2 & SR2_LONGREC) { 503 1.1 gmcgarry switch (sc->sc_density) { 504 1.1 gmcgarry case T_1600BPI: 505 1.1 gmcgarry s = 32 * 1024; 506 1.1 gmcgarry break; 507 1.1 gmcgarry 508 1.1 gmcgarry case T_6250BPI: 509 1.1 gmcgarry case T_BADBPI: 510 1.1 gmcgarry s = 60 * 1024; 511 1.1 gmcgarry break; 512 1.1 gmcgarry } 513 1.1 gmcgarry } 514 1.1 gmcgarry if (bp->b_bcount > s) { 515 1.1 gmcgarry tprintf(sc->sc_ttyp, 516 1.7 cube "%s: write record (%d) too big: limit (%d)\n", 517 1.13 cegger device_xname(&sc->sc_dev), bp->b_bcount, s); 518 1.1 gmcgarry #if 0 /* XXX see above */ 519 1.1 gmcgarry error: 520 1.1 gmcgarry #endif 521 1.1 gmcgarry bp->b_error = EIO; 522 1.1 gmcgarry biodone(bp); 523 1.1 gmcgarry return; 524 1.1 gmcgarry } 525 1.1 gmcgarry } 526 1.1 gmcgarry s = splbio(); 527 1.16 yamt bufq_put(sc->sc_tab, bp); 528 1.1 gmcgarry if (sc->sc_active == 0) { 529 1.1 gmcgarry sc->sc_active = 1; 530 1.1 gmcgarry mtustart(sc); 531 1.1 gmcgarry } 532 1.1 gmcgarry splx(s); 533 1.1 gmcgarry } 534 1.1 gmcgarry 535 1.1 gmcgarry void 536 1.17 dsl mtustart(struct mt_softc *sc) 537 1.1 gmcgarry { 538 1.1 gmcgarry 539 1.13 cegger DPRINTF(MDB_ANY, ("%s ustart", device_xname(&sc->sc_dev))); 540 1.1 gmcgarry if (gpibrequest(sc->sc_ic, sc->sc_hdl)) 541 1.1 gmcgarry mtstart(sc); 542 1.1 gmcgarry } 543 1.1 gmcgarry 544 1.1 gmcgarry void 545 1.17 dsl mtcallback(void *v, int action) 546 1.1 gmcgarry { 547 1.1 gmcgarry struct mt_softc *sc = v; 548 1.1 gmcgarry 549 1.1 gmcgarry DPRINTF(MDB_FOLLOW, ("mtcallback: v=%p, action=%d\n", v, action)); 550 1.1 gmcgarry 551 1.1 gmcgarry switch (action) { 552 1.1 gmcgarry case GPIBCBF_START: 553 1.1 gmcgarry mtstart(sc); 554 1.1 gmcgarry break; 555 1.1 gmcgarry case GPIBCBF_INTR: 556 1.1 gmcgarry mtintr(sc); 557 1.1 gmcgarry break; 558 1.1 gmcgarry #ifdef DEBUG 559 1.1 gmcgarry default: 560 1.1 gmcgarry printf("mtcallback: unknown action %d\n", action); 561 1.1 gmcgarry break; 562 1.1 gmcgarry #endif 563 1.1 gmcgarry } 564 1.1 gmcgarry } 565 1.1 gmcgarry 566 1.1 gmcgarry void 567 1.17 dsl mtintr_callout(void *arg) 568 1.1 gmcgarry { 569 1.1 gmcgarry struct mt_softc *sc = arg; 570 1.1 gmcgarry int s = splbio(); 571 1.1 gmcgarry 572 1.1 gmcgarry gpibppclear(sc->sc_ic); 573 1.1 gmcgarry mtintr(sc); 574 1.1 gmcgarry splx(s); 575 1.1 gmcgarry } 576 1.1 gmcgarry 577 1.1 gmcgarry void 578 1.17 dsl mtstart_callout(void *arg) 579 1.1 gmcgarry { 580 1.1 gmcgarry int s = splbio(); 581 1.1 gmcgarry 582 1.1 gmcgarry mtstart((struct mt_softc *)arg); 583 1.1 gmcgarry splx(s); 584 1.1 gmcgarry } 585 1.1 gmcgarry 586 1.1 gmcgarry void 587 1.17 dsl mtstart(struct mt_softc *sc) 588 1.1 gmcgarry { 589 1.1 gmcgarry struct buf *bp; 590 1.1 gmcgarry short cmdcount = 1; 591 1.1 gmcgarry u_char cmdbuf[2]; 592 1.1 gmcgarry 593 1.13 cegger DPRINTF(MDB_ANY, ("%s start", device_xname(&sc->sc_dev))); 594 1.1 gmcgarry sc->sc_flags &= ~MTF_WRT; 595 1.16 yamt bp = bufq_peek(sc->sc_tab); 596 1.1 gmcgarry if ((sc->sc_flags & MTF_ALIVE) == 0 && 597 1.1 gmcgarry ((bp->b_flags & B_CMD) == 0 || bp->b_cmd != MTRESET)) 598 1.1 gmcgarry goto fatalerror; 599 1.1 gmcgarry 600 1.1 gmcgarry if (sc->sc_flags & MTF_REW) { 601 1.1 gmcgarry if (!gpibpptest(sc->sc_ic, sc->sc_slave)) 602 1.1 gmcgarry goto stillrew; 603 1.1 gmcgarry switch (mtreaddsj(sc, MTE_DSJ_FORCE|MTE_COMPLETE|MTE_IDLE)) { 604 1.1 gmcgarry case 0: 605 1.1 gmcgarry case 1: 606 1.1 gmcgarry stillrew: 607 1.1 gmcgarry if ((sc->sc_stat1 & SR1_BOT) || 608 1.1 gmcgarry !(sc->sc_stat1 & SR1_ONLINE)) { 609 1.1 gmcgarry sc->sc_flags &= ~MTF_REW; 610 1.1 gmcgarry break; 611 1.1 gmcgarry } 612 1.1 gmcgarry case -2: 613 1.1 gmcgarry /* 614 1.1 gmcgarry * -2 means "timeout" reading DSJ, which is probably 615 1.1 gmcgarry * temporary. This is considered OK when doing a NOP, 616 1.1 gmcgarry * but not otherwise. 617 1.1 gmcgarry */ 618 1.1 gmcgarry if (sc->sc_flags & (MTF_DSJTIMEO | MTF_STATTIMEO)) { 619 1.1 gmcgarry callout_reset(&sc->sc_start_ch, hz >> 5, 620 1.1 gmcgarry mtstart_callout, sc); 621 1.1 gmcgarry return; 622 1.1 gmcgarry } 623 1.1 gmcgarry case 2: 624 1.1 gmcgarry if (bp->b_cmd != MTNOP || !(bp->b_flags & B_CMD)) { 625 1.1 gmcgarry bp->b_error = EBUSY; 626 1.11 ad goto done; 627 1.1 gmcgarry } 628 1.1 gmcgarry goto done; 629 1.1 gmcgarry 630 1.1 gmcgarry default: 631 1.1 gmcgarry goto fatalerror; 632 1.1 gmcgarry } 633 1.1 gmcgarry } 634 1.1 gmcgarry if (bp->b_flags & B_CMD) { 635 1.1 gmcgarry if (sc->sc_flags & MTF_PASTEOT) { 636 1.1 gmcgarry switch(bp->b_cmd) { 637 1.1 gmcgarry case MTFSF: 638 1.1 gmcgarry case MTWEOF: 639 1.1 gmcgarry case MTFSR: 640 1.1 gmcgarry bp->b_error = ENOSPC; 641 1.11 ad goto done; 642 1.1 gmcgarry 643 1.1 gmcgarry case MTBSF: 644 1.1 gmcgarry case MTOFFL: 645 1.1 gmcgarry case MTBSR: 646 1.1 gmcgarry case MTREW: 647 1.1 gmcgarry sc->sc_flags &= ~(MTF_PASTEOT | MTF_ATEOT); 648 1.1 gmcgarry break; 649 1.1 gmcgarry } 650 1.1 gmcgarry } 651 1.1 gmcgarry switch(bp->b_cmd) { 652 1.1 gmcgarry case MTFSF: 653 1.1 gmcgarry if (sc->sc_flags & MTF_HITEOF) 654 1.1 gmcgarry goto done; 655 1.1 gmcgarry cmdbuf[0] = MTTC_FSF; 656 1.1 gmcgarry break; 657 1.1 gmcgarry 658 1.1 gmcgarry case MTBSF: 659 1.1 gmcgarry if (sc->sc_flags & MTF_HITBOF) 660 1.1 gmcgarry goto done; 661 1.1 gmcgarry cmdbuf[0] = MTTC_BSF; 662 1.1 gmcgarry break; 663 1.1 gmcgarry 664 1.1 gmcgarry case MTOFFL: 665 1.1 gmcgarry sc->sc_flags |= MTF_REW; 666 1.1 gmcgarry cmdbuf[0] = MTTC_REWOFF; 667 1.1 gmcgarry break; 668 1.1 gmcgarry 669 1.1 gmcgarry case MTWEOF: 670 1.1 gmcgarry cmdbuf[0] = MTTC_WFM; 671 1.1 gmcgarry break; 672 1.1 gmcgarry 673 1.1 gmcgarry case MTBSR: 674 1.1 gmcgarry cmdbuf[0] = MTTC_BSR; 675 1.1 gmcgarry break; 676 1.1 gmcgarry 677 1.1 gmcgarry case MTFSR: 678 1.1 gmcgarry cmdbuf[0] = MTTC_FSR; 679 1.1 gmcgarry break; 680 1.1 gmcgarry 681 1.1 gmcgarry case MTREW: 682 1.1 gmcgarry sc->sc_flags |= MTF_REW; 683 1.1 gmcgarry cmdbuf[0] = MTTC_REW; 684 1.1 gmcgarry break; 685 1.1 gmcgarry 686 1.1 gmcgarry case MTNOP: 687 1.1 gmcgarry /* 688 1.1 gmcgarry * NOP is supposed to set status bits. 689 1.1 gmcgarry * Force readdsj to do it. 690 1.1 gmcgarry */ 691 1.1 gmcgarry switch (mtreaddsj(sc, 692 1.1 gmcgarry MTE_DSJ_FORCE | MTE_COMPLETE | MTE_IDLE)) { 693 1.1 gmcgarry default: 694 1.1 gmcgarry goto done; 695 1.1 gmcgarry 696 1.1 gmcgarry case -1: 697 1.1 gmcgarry /* 698 1.1 gmcgarry * If this fails, perform a device clear 699 1.1 gmcgarry * to fix any protocol problems and (most 700 1.1 gmcgarry * likely) get the status. 701 1.1 gmcgarry */ 702 1.1 gmcgarry bp->b_cmd = MTRESET; 703 1.1 gmcgarry break; 704 1.1 gmcgarry 705 1.1 gmcgarry case -2: 706 1.1 gmcgarry callout_reset(&sc->sc_start_ch, hz >> 5, 707 1.1 gmcgarry mtstart_callout, sc); 708 1.1 gmcgarry return; 709 1.1 gmcgarry } 710 1.1 gmcgarry 711 1.1 gmcgarry case MTRESET: 712 1.1 gmcgarry /* 713 1.1 gmcgarry * 1) selected device clear (send with "-2" secondary) 714 1.1 gmcgarry * 2) set timeout, then wait for "service request" 715 1.1 gmcgarry * 3) interrupt will read DSJ (and END COMPLETE-IDLE) 716 1.1 gmcgarry */ 717 1.1 gmcgarry if (gpibsend(sc->sc_ic, sc->sc_slave, -2, NULL, 0)){ 718 1.13 cegger aprint_error_dev(&sc->sc_dev, "can't reset"); 719 1.1 gmcgarry goto fatalerror; 720 1.1 gmcgarry } 721 1.1 gmcgarry callout_reset(&sc->sc_intr_ch, 4*hz, mtintr_callout, 722 1.1 gmcgarry sc); 723 1.1 gmcgarry gpibawait(sc->sc_ic); 724 1.1 gmcgarry return; 725 1.1 gmcgarry 726 1.1 gmcgarry case MTSET800BPI: 727 1.1 gmcgarry cmdbuf[0] = MTTC_800; 728 1.1 gmcgarry break; 729 1.1 gmcgarry 730 1.1 gmcgarry case MTSET1600BPI: 731 1.1 gmcgarry cmdbuf[0] = MTTC_1600; 732 1.1 gmcgarry break; 733 1.1 gmcgarry 734 1.1 gmcgarry case MTSET6250BPI: 735 1.1 gmcgarry cmdbuf[0] = MTTC_6250; 736 1.1 gmcgarry break; 737 1.1 gmcgarry 738 1.1 gmcgarry case MTSET6250DC: 739 1.1 gmcgarry cmdbuf[0] = MTTC_DC6250; 740 1.1 gmcgarry break; 741 1.1 gmcgarry } 742 1.1 gmcgarry } else { 743 1.1 gmcgarry if (sc->sc_flags & MTF_PASTEOT) { 744 1.1 gmcgarry bp->b_error = ENOSPC; 745 1.11 ad goto done; 746 1.1 gmcgarry } 747 1.1 gmcgarry if (bp->b_flags & B_READ) { 748 1.1 gmcgarry sc->sc_flags |= MTF_IO; 749 1.1 gmcgarry cmdbuf[0] = MTTC_READ; 750 1.1 gmcgarry } else { 751 1.1 gmcgarry sc->sc_flags |= MTF_WRT | MTF_IO; 752 1.1 gmcgarry cmdbuf[0] = MTTC_WRITE; 753 1.1 gmcgarry cmdbuf[1] = (bp->b_bcount +((1 << WRITE_BITS_IGNORED) - 1)) >> WRITE_BITS_IGNORED; 754 1.1 gmcgarry cmdcount = 2; 755 1.1 gmcgarry } 756 1.1 gmcgarry } 757 1.1 gmcgarry if (gpibsend(sc->sc_ic, sc->sc_slave, MTL_TCMD, cmdbuf, cmdcount) 758 1.1 gmcgarry == cmdcount) { 759 1.1 gmcgarry if (sc->sc_flags & MTF_REW) 760 1.1 gmcgarry goto done; 761 1.1 gmcgarry gpibawait(sc->sc_ic); 762 1.1 gmcgarry return; 763 1.1 gmcgarry } 764 1.1 gmcgarry fatalerror: 765 1.1 gmcgarry /* 766 1.1 gmcgarry * If anything fails, the drive is probably hosed, so mark it not 767 1.1 gmcgarry * "ALIVE" (but it EXISTS and is OPEN or we wouldn't be here, and 768 1.1 gmcgarry * if, last we heard, it was REWinding, remember that). 769 1.1 gmcgarry */ 770 1.1 gmcgarry sc->sc_flags &= MTF_EXISTS | MTF_OPEN | MTF_REW; 771 1.1 gmcgarry bp->b_error = EIO; 772 1.1 gmcgarry done: 773 1.1 gmcgarry sc->sc_flags &= ~(MTF_HITEOF | MTF_HITBOF); 774 1.16 yamt (void)bufq_get(sc->sc_tab); 775 1.1 gmcgarry biodone(bp); 776 1.1 gmcgarry gpibrelease(sc->sc_ic, sc->sc_hdl); 777 1.16 yamt if ((bp = bufq_peek(sc->sc_tab)) == NULL) 778 1.1 gmcgarry sc->sc_active = 0; 779 1.1 gmcgarry else 780 1.1 gmcgarry mtustart(sc); 781 1.1 gmcgarry } 782 1.1 gmcgarry 783 1.1 gmcgarry void 784 1.17 dsl mtintr(struct mt_softc *sc) 785 1.1 gmcgarry { 786 1.1 gmcgarry struct buf *bp; 787 1.1 gmcgarry int slave, dir, i; 788 1.1 gmcgarry u_char cmdbuf[4]; 789 1.1 gmcgarry 790 1.1 gmcgarry slave = sc->sc_slave; 791 1.1 gmcgarry 792 1.16 yamt bp = bufq_peek(sc->sc_tab); 793 1.1 gmcgarry if (bp == NULL) { 794 1.13 cegger printf("%s intr: bp == NULL", device_xname(&sc->sc_dev)); 795 1.1 gmcgarry return; 796 1.1 gmcgarry } 797 1.1 gmcgarry 798 1.13 cegger DPRINTF(MDB_ANY, ("%s intr", device_xname(&sc->sc_dev))); 799 1.1 gmcgarry 800 1.1 gmcgarry /* 801 1.1 gmcgarry * Some operation completed. Read status bytes and report errors. 802 1.1 gmcgarry * Clear EOF flags here `cause they're set once on specific conditions 803 1.1 gmcgarry * below when a command succeeds. 804 1.1 gmcgarry * A DSJ of 2 always means keep waiting. If the command was READ 805 1.1 gmcgarry * (and we're in data DMA phase) stop data transfer first. 806 1.1 gmcgarry */ 807 1.1 gmcgarry sc->sc_flags &= ~(MTF_HITEOF | MTF_HITBOF); 808 1.1 gmcgarry if ((bp->b_flags & (B_CMD|B_READ)) == B_READ && 809 1.1 gmcgarry !(sc->sc_flags & (MTF_IO | MTF_STATTIMEO | MTF_DSJTIMEO))){ 810 1.1 gmcgarry cmdbuf[0] = MTE_STOP; 811 1.1 gmcgarry (void) gpibsend(sc->sc_ic, slave, MTL_ECMD,cmdbuf,1); 812 1.1 gmcgarry } 813 1.1 gmcgarry switch (mtreaddsj(sc, 0)) { 814 1.1 gmcgarry case 0: 815 1.1 gmcgarry break; 816 1.1 gmcgarry 817 1.1 gmcgarry case 1: 818 1.1 gmcgarry /* 819 1.1 gmcgarry * If we're in the middle of a READ/WRITE and have yet to 820 1.1 gmcgarry * start the data transfer, a DSJ of one should terminate it. 821 1.1 gmcgarry */ 822 1.1 gmcgarry sc->sc_flags &= ~MTF_IO; 823 1.1 gmcgarry break; 824 1.1 gmcgarry 825 1.1 gmcgarry case 2: 826 1.1 gmcgarry (void) gpibawait(sc->sc_ic); 827 1.1 gmcgarry return; 828 1.1 gmcgarry 829 1.1 gmcgarry case -2: 830 1.1 gmcgarry /* 831 1.1 gmcgarry * -2 means that the drive failed to respond quickly enough 832 1.1 gmcgarry * to the request for DSJ. It's probably just "busy" figuring 833 1.1 gmcgarry * it out and will know in a little bit... 834 1.1 gmcgarry */ 835 1.1 gmcgarry callout_reset(&sc->sc_intr_ch, hz >> 5, mtintr_callout, sc); 836 1.1 gmcgarry return; 837 1.1 gmcgarry 838 1.1 gmcgarry default: 839 1.13 cegger printf("%s intr: can't get drive stat", device_xname(&sc->sc_dev)); 840 1.1 gmcgarry goto error; 841 1.1 gmcgarry } 842 1.1 gmcgarry if (sc->sc_stat1 & (SR1_ERR | SR1_REJECT)) { 843 1.1 gmcgarry i = sc->sc_stat4 & SR4_ERCLMASK; 844 1.1 gmcgarry printf("%s: %s error, retry %d, SR2/3 %x/%x, code %d", 845 1.13 cegger device_xname(&sc->sc_dev), i == SR4_DEVICE ? "device" : 846 1.1 gmcgarry (i == SR4_PROTOCOL ? "protocol" : 847 1.1 gmcgarry (i == SR4_SELFTEST ? "selftest" : "unknown")), 848 1.1 gmcgarry sc->sc_stat4 & SR4_RETRYMASK, sc->sc_stat2, 849 1.1 gmcgarry sc->sc_stat3, sc->sc_stat5); 850 1.1 gmcgarry 851 1.1 gmcgarry if ((bp->b_flags & B_CMD) && bp->b_cmd == MTRESET) 852 1.1 gmcgarry callout_stop(&sc->sc_intr_ch); 853 1.1 gmcgarry if (sc->sc_stat3 & SR3_POWERUP) 854 1.1 gmcgarry sc->sc_flags &= MTF_OPEN | MTF_EXISTS; 855 1.1 gmcgarry goto error; 856 1.1 gmcgarry } 857 1.1 gmcgarry /* 858 1.1 gmcgarry * Report and clear any soft errors. 859 1.1 gmcgarry */ 860 1.1 gmcgarry if (sc->sc_stat1 & SR1_SOFTERR) { 861 1.13 cegger printf("%s: soft error, retry %d\n", device_xname(&sc->sc_dev), 862 1.1 gmcgarry sc->sc_stat4 & SR4_RETRYMASK); 863 1.1 gmcgarry sc->sc_stat1 &= ~SR1_SOFTERR; 864 1.1 gmcgarry } 865 1.1 gmcgarry /* 866 1.1 gmcgarry * We've initiated a read or write, but haven't actually started to 867 1.1 gmcgarry * DMA the data yet. At this point, the drive's ready. 868 1.1 gmcgarry */ 869 1.1 gmcgarry if (sc->sc_flags & MTF_IO) { 870 1.1 gmcgarry sc->sc_flags &= ~MTF_IO; 871 1.1 gmcgarry dir = (bp->b_flags & B_READ ? GPIB_READ : GPIB_WRITE); 872 1.1 gmcgarry gpibxfer(sc->sc_ic, slave, 873 1.1 gmcgarry dir == GPIB_READ ? MTT_READ : MTL_WRITE, 874 1.1 gmcgarry bp->b_data, bp->b_bcount, dir, dir == GPIB_READ); 875 1.1 gmcgarry return; 876 1.1 gmcgarry } 877 1.1 gmcgarry /* 878 1.1 gmcgarry * Check for End Of Tape - we're allowed to hit EOT and then write (or 879 1.1 gmcgarry * read) one more record. If we get here and have not already hit EOT, 880 1.1 gmcgarry * return ENOSPC to inform the process that it's hit it. If we get 881 1.1 gmcgarry * here and HAVE already hit EOT, don't allow any more operations that 882 1.1 gmcgarry * move the tape forward. 883 1.1 gmcgarry */ 884 1.1 gmcgarry if (sc->sc_stat1 & SR1_EOT) { 885 1.1 gmcgarry if (sc->sc_flags & MTF_ATEOT) 886 1.1 gmcgarry sc->sc_flags |= MTF_PASTEOT; 887 1.1 gmcgarry else { 888 1.1 gmcgarry bp->b_error = ENOSPC; 889 1.1 gmcgarry sc->sc_flags |= MTF_ATEOT; 890 1.1 gmcgarry } 891 1.1 gmcgarry } 892 1.1 gmcgarry /* 893 1.1 gmcgarry * If a motion command was being executed, check for Tape Marks. 894 1.1 gmcgarry * If we were doing data, make sure we got the right amount, and 895 1.1 gmcgarry * check for hitting tape marks on reads. 896 1.1 gmcgarry */ 897 1.1 gmcgarry if (bp->b_flags & B_CMD) { 898 1.1 gmcgarry if (sc->sc_stat1 & SR1_EOF) { 899 1.1 gmcgarry if (bp->b_cmd == MTFSR) 900 1.1 gmcgarry sc->sc_flags |= MTF_HITEOF; 901 1.1 gmcgarry if (bp->b_cmd == MTBSR) 902 1.1 gmcgarry sc->sc_flags |= MTF_HITBOF; 903 1.1 gmcgarry } 904 1.1 gmcgarry if (bp->b_cmd == MTRESET) { 905 1.1 gmcgarry callout_stop(&sc->sc_intr_ch); 906 1.1 gmcgarry sc->sc_flags |= MTF_ALIVE; 907 1.1 gmcgarry } 908 1.1 gmcgarry } else { 909 1.1 gmcgarry i = gpibrecv(sc->sc_ic, slave, MTT_BCNT, cmdbuf, 2); 910 1.1 gmcgarry if (i != 2) { 911 1.13 cegger aprint_error_dev(&sc->sc_dev, "intr: can't get xfer length\n"); 912 1.1 gmcgarry goto error; 913 1.1 gmcgarry } 914 1.1 gmcgarry i = (int) *((u_short *) cmdbuf); 915 1.1 gmcgarry if (i <= bp->b_bcount) { 916 1.1 gmcgarry if (i == 0) 917 1.1 gmcgarry sc->sc_flags |= MTF_HITEOF; 918 1.1 gmcgarry bp->b_resid = bp->b_bcount - i; 919 1.22 tsutsui DPRINTF(MDB_ANY, ("%s intr: bcount %d, resid %d", 920 1.22 tsutsui device_xname(&sc->sc_dev), 921 1.22 tsutsui bp->b_bcount, bp->b_resid)); 922 1.1 gmcgarry } else { 923 1.1 gmcgarry tprintf(sc->sc_ttyp, 924 1.7 cube "%s: record (%d) larger than wanted (%d)\n", 925 1.13 cegger device_xname(&sc->sc_dev), i, bp->b_bcount); 926 1.1 gmcgarry error: 927 1.1 gmcgarry sc->sc_flags &= ~MTF_IO; 928 1.1 gmcgarry bp->b_error = EIO; 929 1.1 gmcgarry } 930 1.1 gmcgarry } 931 1.1 gmcgarry /* 932 1.1 gmcgarry * The operation is completely done. 933 1.1 gmcgarry * Let the drive know with an END command. 934 1.1 gmcgarry */ 935 1.1 gmcgarry cmdbuf[0] = MTE_COMPLETE | MTE_IDLE; 936 1.1 gmcgarry (void) gpibsend(sc->sc_ic, slave, MTL_ECMD, cmdbuf, 1); 937 1.1 gmcgarry bp->b_flags &= ~B_CMD; 938 1.16 yamt (void)bufq_get(sc->sc_tab); 939 1.1 gmcgarry biodone(bp); 940 1.1 gmcgarry gpibrelease(sc->sc_ic, sc->sc_hdl); 941 1.16 yamt if (bufq_peek(sc->sc_tab) == NULL) 942 1.1 gmcgarry sc->sc_active = 0; 943 1.1 gmcgarry else 944 1.1 gmcgarry mtustart(sc); 945 1.1 gmcgarry } 946 1.1 gmcgarry 947 1.1 gmcgarry int 948 1.15 cegger mtread(dev_t dev, struct uio *uio, int flags) 949 1.1 gmcgarry { 950 1.1 gmcgarry struct mt_softc *sc; 951 1.1 gmcgarry 952 1.15 cegger sc = device_lookup_private(&mt_cd, MTUNIT(dev)); 953 1.1 gmcgarry 954 1.21 ad return (physio(mtstrategy, NULL, dev, B_READ, minphys, uio)); 955 1.1 gmcgarry } 956 1.1 gmcgarry 957 1.1 gmcgarry int 958 1.15 cegger mtwrite(dev_t dev, struct uio *uio, int flags) 959 1.1 gmcgarry { 960 1.1 gmcgarry struct mt_softc *sc; 961 1.1 gmcgarry 962 1.15 cegger sc = device_lookup_private(&mt_cd, MTUNIT(dev)); 963 1.1 gmcgarry 964 1.21 ad return (physio(mtstrategy, NULL, dev, B_WRITE, minphys, uio)); 965 1.1 gmcgarry } 966 1.1 gmcgarry 967 1.1 gmcgarry int 968 1.17 dsl mtioctl(dev_t dev, u_long cmd, void *data, int flag, struct lwp *l) 969 1.1 gmcgarry { 970 1.1 gmcgarry struct mtop *op; 971 1.1 gmcgarry int cnt; 972 1.1 gmcgarry 973 1.1 gmcgarry switch (cmd) { 974 1.1 gmcgarry case MTIOCTOP: 975 1.1 gmcgarry op = (struct mtop *)data; 976 1.1 gmcgarry switch(op->mt_op) { 977 1.1 gmcgarry case MTWEOF: 978 1.1 gmcgarry case MTFSF: 979 1.1 gmcgarry case MTBSR: 980 1.1 gmcgarry case MTBSF: 981 1.1 gmcgarry case MTFSR: 982 1.1 gmcgarry cnt = op->mt_count; 983 1.1 gmcgarry break; 984 1.1 gmcgarry 985 1.1 gmcgarry case MTOFFL: 986 1.1 gmcgarry case MTREW: 987 1.1 gmcgarry case MTNOP: 988 1.1 gmcgarry cnt = 0; 989 1.1 gmcgarry break; 990 1.1 gmcgarry 991 1.1 gmcgarry default: 992 1.1 gmcgarry return (EINVAL); 993 1.1 gmcgarry } 994 1.1 gmcgarry return (mtcommand(dev, op->mt_op, cnt)); 995 1.1 gmcgarry 996 1.1 gmcgarry case MTIOCGET: 997 1.1 gmcgarry break; 998 1.1 gmcgarry 999 1.1 gmcgarry default: 1000 1.1 gmcgarry return (EINVAL); 1001 1.1 gmcgarry } 1002 1.1 gmcgarry return (0); 1003 1.1 gmcgarry } 1004
Indexes created Wed Oct 01 18:09:54 GMT 2025