1 /* 2 * CDDL HEADER START 3 * 4 * The contents of this file are subject to the terms of the 5 * Common Development and Distribution License (the "License"). 6 * You may not use this file except in compliance with the License. 7 * 8 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE 9 * or http://www.opensolaris.org/os/licensing. 10 * See the License for the specific language governing permissions 11 * and limitations under the License. 12 * 13 * When distributing Covered Code, include this CDDL HEADER in each 14 * file and include the License file at usr/src/OPENSOLARIS.LICENSE. 15 * If applicable, add the following below this CDDL HEADER, with the 16 * fields enclosed by brackets "[]" replaced with your own identifying 17 * information: Portions Copyright [yyyy] [name of copyright owner] 18 * 19 * CDDL HEADER END 20 */ 21 22 /* 23 * Copyright 2009 Sun Microsystems, Inc. All rights reserved. 24 * Use is subject to license terms. 25 */ 26 27 #include <sys/types.h> 28 #include <sys/termios.h> 29 #include <sys/promif.h> 30 #ifdef sun4v 31 #include <sys/promif_impl.h> 32 #endif 33 #include <unistd.h> 34 #include <string.h> 35 #include <stdlib.h> 36 37 #include <kmdb/kmdb_promif_impl.h> 38 #include <kmdb/kmdb_kdi.h> 39 #include <kmdb/kmdb_dpi.h> 40 #include <mdb/mdb_debug.h> 41 #include <mdb/mdb_err.h> 42 #include <mdb/mdb_frame.h> 43 #include <mdb/mdb_string.h> 44 #include <mdb/mdb.h> 45 46 #define KMDB_PROM_DEF_CONS_MODE "9600,n,1,-,-" 47 48 #define KMDB_PROM_READBUF_SIZE 1024 49 50 static char kmdb_prom_readbuf[KMDB_PROM_READBUF_SIZE]; 51 static int kmdb_prom_readbuf_head; 52 static int kmdb_prom_readbuf_tail; 53 54 static int 55 kmdb_prom_getchar(int wait) 56 { 57 struct cons_polledio *pio = mdb.m_pio; 58 uintptr_t ischar; 59 uintptr_t getchar; 60 uintptr_t arg; 61 62 if (pio == NULL || pio->cons_polledio_getchar == NULL) { 63 int c; 64 while ((c = prom_mayget()) == -1) { 65 if (!wait) 66 return (-1); 67 } 68 return (c); 69 } 70 71 ischar = (uintptr_t)pio->cons_polledio_ischar; 72 getchar = (uintptr_t)pio->cons_polledio_getchar; 73 arg = (uintptr_t)pio->cons_polledio_argument; 74 75 if (!wait && ischar != NULL && !kmdb_dpi_call(ischar, 1, &arg)) 76 return (-1); 77 78 return ((int)kmdb_dpi_call(getchar, 1, &arg)); 79 } 80 81 static ssize_t 82 kmdb_prom_polled_write(caddr_t buf, size_t len) 83 { 84 uintptr_t args[2]; 85 int i; 86 87 args[0] = (uintptr_t)mdb.m_pio->cons_polledio_argument; 88 89 for (i = 0; i < len; i++) { 90 args[1] = *buf++; 91 (void) kmdb_dpi_call( 92 (uintptr_t)mdb.m_pio->cons_polledio_putchar, 2, args); 93 } 94 95 return (len); 96 } 97 98 static ssize_t 99 kmdb_prom_reader(caddr_t buf, size_t len, int wait) 100 { 101 int nread = 0; 102 int c; 103 104 while (nread < len) { 105 if ((c = kmdb_prom_getchar(wait)) == -1) 106 break; 107 108 *buf++ = (char)c; 109 nread++; 110 wait = 0; 111 } 112 113 return (nread); 114 } 115 116 static ssize_t 117 kmdb_prom_writer(caddr_t buf, size_t len) 118 { 119 if (mdb.m_pio != NULL && mdb.m_pio->cons_polledio_putchar != NULL) 120 return (kmdb_prom_polled_write(buf, len)); 121 122 return (kmdb_prom_obp_writer(buf, len)); 123 } 124 125 /* 126 * Due to the nature of kmdb, we don't have signals. This prevents us from 127 * receiving asynchronous notification when the user would like to abort active 128 * dcmds. Whereas mdb can simply declare a SIGINT handler, we must 129 * occasionally poll the input stream, looking for pending ^C characters. To 130 * give the illusion of asynchronous interrupt delivery, this polling is 131 * triggered from several commonly-used functions, such as kmdb_prom_write and 132 * the *read and *write target ops. When an interrupt check is triggered, we 133 * read through pending input, looking for interrupt characters. If we find 134 * one, we deliver an interrupt immediately. 135 * 136 * In a read context, we can deliver the interrupt character directly back to 137 * the termio handler rather than raising an interrupt. 138 * 139 * OBP doesn't have an "unget" facility. Any character read for interrupt 140 * checking is gone forever, unless we save it. Loss of these characters 141 * would prevent us from supporting typeahead. We like typeahead, so we're 142 * going to save characters gathered during interrupt checking. As with 143 * ungetc(3c), however, we can only store a finite number of characters in 144 * our typeahead buffer. Characters read beyond that will be silently dropped 145 * after they undergo interrupt processing. 146 * 147 * The typeahead facility is implemented as a ring buffer, stored in 148 * kmdb_prom_readbuf. 149 */ 150 static size_t 151 kmdb_prom_drain_readbuf(void *buf, size_t len) 152 { 153 size_t n, tailread; 154 155 /* 156 * If head > tail, life is easy - we can simply read as much as we need 157 * in one gulp. 158 */ 159 if (kmdb_prom_readbuf_head > kmdb_prom_readbuf_tail) { 160 n = MIN(kmdb_prom_readbuf_head - kmdb_prom_readbuf_tail, len); 161 bcopy(kmdb_prom_readbuf + kmdb_prom_readbuf_tail, buf, n); 162 kmdb_prom_readbuf_tail += n; 163 return (n); 164 165 } else if (kmdb_prom_readbuf_head == kmdb_prom_readbuf_tail) { 166 return (0); 167 } 168 169 /* 170 * The consumable slots wrap around zero (there are slots from tail to 171 * zero, and from zero to head). We have to read them in two parts. 172 */ 173 n = MIN(KMDB_PROM_READBUF_SIZE - kmdb_prom_readbuf_tail, len); 174 bcopy(kmdb_prom_readbuf + kmdb_prom_readbuf_tail, buf, n); 175 kmdb_prom_readbuf_tail = (kmdb_prom_readbuf_tail + n) % 176 KMDB_PROM_READBUF_SIZE; 177 178 if (n == len) { 179 /* 180 * We filled the passed buffer from the first part, so there's 181 * no need to read the second. 182 */ 183 return (n); 184 } else { 185 tailread = n; 186 } 187 188 n = MIN(kmdb_prom_readbuf_head, len - tailread); 189 buf = (void *)((uintptr_t)buf + tailread); 190 bcopy(kmdb_prom_readbuf, buf, n); 191 192 kmdb_prom_readbuf_tail = (kmdb_prom_readbuf_tail + n) % 193 KMDB_PROM_READBUF_SIZE; 194 195 return (tailread + n); 196 } 197 198 static void 199 check_int(char *buf, size_t len) 200 { 201 int i; 202 203 for (i = 0; i < len; i++) { 204 if (buf[i] == CTRL('c')) { 205 kmdb_prom_readbuf_tail = kmdb_prom_readbuf_head; 206 if (mdb.m_intr == 0) 207 longjmp(mdb.m_frame->f_pcb, MDB_ERR_SIGINT); 208 else 209 mdb.m_pend++; 210 } 211 } 212 } 213 214 /* 215 * Attempt to refill the ring buffer from the input stream. This called from 216 * two contexts: 217 * 218 * Direct read: read the input into our buffer until input is exhausted, or the 219 * buffer is full. 220 * 221 * Interrupt check: called 'asynchronously' from the normal read routines; read 222 * the input into our buffer until it is exhausted, discarding input if the 223 * buffer is full. In this case we look ahead for any interrupt characters, 224 * delivering an interrupt directly if we find one. 225 */ 226 static void 227 kmdb_prom_fill_readbuf(int check_for_int, int wait) 228 { 229 int oldhead, left, n; 230 231 /* 232 * Calculate the number of slots left before we wrap around to the 233 * beginning again. 234 */ 235 left = KMDB_PROM_READBUF_SIZE - kmdb_prom_readbuf_head; 236 if (kmdb_prom_readbuf_tail == 0) 237 left--; 238 239 if (kmdb_prom_readbuf_head == kmdb_prom_readbuf_tail || 240 (kmdb_prom_readbuf_head > kmdb_prom_readbuf_tail && left > 0)) { 241 /* 242 * head > tail, so we have to read in two parts - the slots 243 * from head until we wrap back around to zero, and the ones 244 * from zero to tail. We handle the first part here, and let 245 * the common code handle the second. 246 */ 247 if ((n = kmdb_prom_reader(kmdb_prom_readbuf + 248 kmdb_prom_readbuf_head, left, wait)) <= 0) 249 return; 250 251 oldhead = kmdb_prom_readbuf_head; 252 kmdb_prom_readbuf_head = (kmdb_prom_readbuf_head + n) % 253 KMDB_PROM_READBUF_SIZE; 254 255 if (check_for_int) 256 check_int(kmdb_prom_readbuf + oldhead, n); 257 258 if (n != left) 259 return; 260 } 261 262 left = kmdb_prom_readbuf_tail - kmdb_prom_readbuf_head - 1; 263 if (left > 0) { 264 if ((n = kmdb_prom_reader(kmdb_prom_readbuf + 265 kmdb_prom_readbuf_head, left, wait)) <= 0) 266 return; 267 268 oldhead = kmdb_prom_readbuf_head; 269 kmdb_prom_readbuf_head = (kmdb_prom_readbuf_head + n) % 270 KMDB_PROM_READBUF_SIZE; 271 272 if (check_for_int) 273 check_int(kmdb_prom_readbuf + oldhead, n); 274 275 if (n != left) 276 return; 277 } 278 279 if (check_for_int) { 280 char c; 281 282 while (kmdb_prom_reader(&c, 1, 0) == 1) 283 check_int(&c, 1); 284 } 285 } 286 287 void 288 kmdb_prom_check_interrupt(void) 289 { 290 kmdb_prom_fill_readbuf(1, 0); 291 } 292 293 /* 294 * OBP reads are always non-blocking. If there are characters available, 295 * we'll return as many as we can. If nothing is available, we'll spin 296 * until one shows up. 297 */ 298 ssize_t 299 kmdb_prom_read(void *buf, size_t len, struct termios *tio) 300 { 301 size_t totread = 0; 302 size_t thisread; 303 char *c = (char *)buf; 304 int wait = 1; 305 306 for (;;) { 307 kmdb_prom_fill_readbuf(0, wait); 308 thisread = kmdb_prom_drain_readbuf(c, len); 309 len -= thisread; 310 totread += thisread; 311 c += thisread; 312 313 /* wait until something shows up */ 314 if (totread == 0) 315 continue; 316 317 wait = 0; 318 319 /* 320 * We're done if we've exhausted available input or if we've 321 * filled the provided buffer. 322 */ 323 if (len == 0 || thisread == 0) 324 break; 325 } 326 327 if (tio->c_iflag & ICRNL) { 328 char *cbuf = buf; 329 int i; 330 331 for (i = 0; i < totread; i++) { 332 if (cbuf[i] == '\r') 333 cbuf[i] = '\n'; 334 } 335 } 336 337 if (tio->c_lflag & ECHO) 338 (void) kmdb_prom_write(buf, totread, tio); 339 340 return (totread); 341 } 342 343 /*ARGSUSED*/ 344 ssize_t 345 kmdb_prom_write(const void *bufp, size_t len, struct termios *tio) 346 { 347 caddr_t buf = (caddr_t)bufp; 348 size_t left = len; 349 char *nl = "\r\n"; 350 char *c; 351 352 kmdb_prom_check_interrupt(); 353 354 if (!(tio->c_oflag & ONLCR)) 355 return (kmdb_prom_writer(buf, left)); 356 357 /* translate every \n into \r\n */ 358 while ((c = strnchr(buf, '\n', left)) != NULL) { 359 if (c != buf) { 360 size_t sz = (size_t)(c - buf); 361 (void) kmdb_prom_writer(buf, sz); 362 left -= sz; 363 } 364 365 buf = c + 1; 366 left--; 367 368 (void) kmdb_prom_writer(nl, 2); 369 } 370 371 if (*buf != '\0') 372 (void) kmdb_prom_writer(buf, left); 373 374 return (len); 375 } 376 377 static char * 378 kmdb_get_ttyio_mode(kmdb_auxv_t *kav, char *devname) 379 { 380 char *modepname, *modepval; 381 382 modepname = mdb_alloc(strlen(devname) + 5 + 1, UM_SLEEP); 383 (void) strcpy(modepname, devname); 384 (void) strcat(modepname, "-mode"); 385 386 modepval = kmdb_prom_get_ddi_prop(kav, modepname); 387 388 strfree(modepname); 389 390 return (modepval); 391 } 392 393 static int 394 termios_setispeed(struct termios *tip, speed_t s) 395 { 396 if (s > (2 * CBAUD + 1)) 397 return (-1); 398 399 if ((s << IBSHIFT) > CIBAUD) { 400 tip->c_cflag |= CIBAUDEXT; 401 s -= ((CIBAUD >> IBSHIFT) + 1); 402 } else 403 tip->c_cflag &= ~CIBAUDEXT; 404 405 tip->c_cflag = (tip->c_cflag & ~CIBAUD) | ((s << IBSHIFT) & CIBAUD); 406 407 return (0); 408 } 409 410 static int 411 termios_setospeed(struct termios *tip, speed_t s) 412 { 413 if (s > (2 * CBAUD + 1)) 414 return (-1); 415 416 if (s > CBAUD) { 417 tip->c_cflag |= CBAUDEXT; 418 s -= (CBAUD + 1); 419 } else 420 tip->c_cflag &= ~CBAUDEXT; 421 422 tip->c_cflag = (tip->c_cflag & ~CBAUD) | (s & CBAUD); 423 424 return (0); 425 } 426 427 static int 428 kmdb_parse_mode(const char *mode, struct termios *tip, int in) 429 { 430 static const uint_t baudmap[] = { 431 0, 50, 75, 110, 134, 150, 200, 300, 600, 1200, 432 1800, 2400, 4800, 9600, 19200, 38400, 57600, 433 76800, 115200, 153600, 230400, 307200, 460800, 921600 434 }; 435 static const uint_t bitsmap[] = { CS6, CS6, CS7, CS8 }; 436 char *m = strdup(mode); 437 char *w; 438 int rc = -1; 439 speed_t speed; 440 int baud, i; 441 442 /* 443 * termios supports different baud rates and flow control types for 444 * input and output, but it requires character width, parity, and stop 445 * bits to be equal in input and output. obp allows them to be 446 * different, but we're going to (silently) assume that nobody will use 447 * it that way. 448 */ 449 450 /* baud rate - see baudmap above */ 451 if ((w = strtok(m, ",")) == NULL) 452 goto parse_mode_bail; 453 454 baud = strtol(w, NULL, 10); 455 speed = 0; 456 for (i = 0; i < sizeof (baudmap) / sizeof (baudmap[0]); i++) { 457 if (baudmap[i] == baud) { 458 speed = i; 459 break; 460 } 461 } 462 if (speed == 0) 463 goto parse_mode_bail; 464 465 if (in == 1) 466 (void) termios_setispeed(tip, speed); 467 else 468 (void) termios_setospeed(tip, speed); 469 470 /* character width (bits) - 5, 6, 7, or 8 */ 471 if ((w = strtok(NULL, ",")) == NULL || strlen(w) != 1 || *w < '5' || 472 *w > '8') 473 goto parse_mode_bail; 474 tip->c_cflag = (tip->c_cflag & ~CSIZE) | bitsmap[*w - '5']; 475 476 /* parity - `n' (none), `e' (even), or `o' (odd) */ 477 if ((w = strtok(NULL, ",")) == NULL || strlen(w) != 1 || 478 strchr("neo", *w) == NULL) 479 goto parse_mode_bail; 480 481 tip->c_cflag = (tip->c_cflag & ~(PARENB|PARODD)); 482 switch (*w) { 483 case 'n': 484 /* nothing */ 485 break; 486 case 'e': 487 tip->c_cflag |= PARENB; 488 break; 489 case 'o': 490 tip->c_cflag |= PARENB|PARODD; 491 break; 492 } 493 494 /* 495 * stop bits - 1, or 2. obp can, in theory, support 1.5 bits, 496 * but we can't. how many angels can dance on half of a bit? 497 */ 498 if ((w = strtok(NULL, ",")) == NULL || strlen(w) != 1 || *w < '1' || 499 *w > '2') 500 goto parse_mode_bail; 501 502 if (*w == '1') 503 tip->c_cflag &= ~CSTOPB; 504 else 505 tip->c_cflag |= CSTOPB; 506 507 /* flow control - `-' (none), `h' (h/w), or `s' (s/w - XON/XOFF) */ 508 if ((w = strtok(NULL, ",")) == NULL || strlen(w) != 1 || 509 strchr("-hs", *w) == NULL) 510 goto parse_mode_bail; 511 512 tip->c_cflag &= ~(CRTSXOFF|CRTSCTS); 513 tip->c_iflag &= ~(IXON|IXANY|IXOFF); 514 515 switch (*w) { 516 case 'h': 517 tip->c_cflag |= (in == 1 ? CRTSXOFF : CRTSCTS); 518 break; 519 520 case 's': 521 tip->c_iflag |= (in == 1 ? IXOFF : IXON); 522 break; 523 } 524 525 rc = 0; 526 527 parse_mode_bail: 528 strfree(m); 529 530 return (rc); 531 } 532 533 #ifdef __sparc 534 #define ATTACHED_TERM_TYPE "sun" 535 #else 536 #define ATTACHED_TERM_TYPE "sun-color" 537 #endif 538 539 static void 540 kmdb_prom_term_init(kmdb_auxv_t *kav, kmdb_promif_t *pif) 541 { 542 const char ccs[NCCS] = { 0x03, 0x1c, 0x08, 0x15, 0x04, 0x00, 0x00, 543 0x00, 0x11, 0x13, 0x1a, 0x19, 0x12, 0x0f, 0x17, 0x16 }; 544 char *conin = NULL, *conout = NULL; 545 546 if (kmdb_prom_stdout_is_framebuffer(kav)) 547 pif->pif_oterm = ATTACHED_TERM_TYPE; 548 549 bzero(&pif->pif_tios, sizeof (struct termios)); 550 551 /* output device characteristics */ 552 if ((conout = kmdb_prom_get_ddi_prop(kav, "output-device")) == 553 NULL || strcmp(conout, "screen") == 0) { 554 (void) kmdb_parse_mode(KMDB_PROM_DEF_CONS_MODE, 555 &pif->pif_tios, 0); 556 } else if (*conout == '/') { 557 /* 558 * We're not going to be able to get characteristics for a 559 * device that's specified as a path, so don't even try. 560 * Conveniently, this allows us to avoid chattering on 561 * Serengetis. 562 */ 563 (void) kmdb_parse_mode(KMDB_PROM_DEF_CONS_MODE, 564 &pif->pif_tios, 0); 565 } else { 566 char *mode = kmdb_get_ttyio_mode(kav, conout); 567 568 #ifdef __sparc 569 /* 570 * Some platforms (Starfire) define a value of `ttya' for 571 * output-device, but neglect to provide a specific property 572 * with the characteristics. We'll provide a default value. 573 */ 574 if (mode == NULL && strcmp(conout, "ttya") == 0) { 575 (void) kmdb_parse_mode(KMDB_PROM_DEF_CONS_MODE, 576 &pif->pif_tios, 0); 577 } else 578 #endif 579 { 580 if (mode == NULL || kmdb_parse_mode(mode, 581 &pif->pif_tios, 0) < 0) { 582 /* 583 * Either we couldn't retrieve the 584 * characteristics for this console, or they 585 * weren't parseable. The console hasn't been 586 * set up yet, so we can't warn. We'll have to 587 * silently fall back to the default 588 * characteristics. 589 */ 590 (void) kmdb_parse_mode(KMDB_PROM_DEF_CONS_MODE, 591 &pif->pif_tios, 0); 592 } 593 } 594 595 if (mode != NULL) 596 kmdb_prom_free_ddi_prop(mode); 597 } 598 599 /* input device characteristics */ 600 if ((conin = kmdb_prom_get_ddi_prop(kav, "input-device")) == NULL || 601 strcmp(conin, "keyboard") == 0) { 602 (void) kmdb_parse_mode(KMDB_PROM_DEF_CONS_MODE, 603 &pif->pif_tios, 1); 604 } else if (*conin == '/') { 605 /* See similar case in output-device above */ 606 (void) kmdb_parse_mode(KMDB_PROM_DEF_CONS_MODE, 607 &pif->pif_tios, 1); 608 } else { 609 char *mode = kmdb_get_ttyio_mode(kav, conin); 610 611 #ifdef __sparc 612 /* 613 * Some platforms (Starfire) define a value of `ttya' for 614 * input-device, but neglect to provide a specific property 615 * with the characteristics. We'll provide a default value. 616 */ 617 if (mode == NULL && strcmp(conin, "ttya") == 0) { 618 (void) kmdb_parse_mode(KMDB_PROM_DEF_CONS_MODE, 619 &pif->pif_tios, 1); 620 } else 621 #endif 622 { 623 if (mode == NULL || kmdb_parse_mode(mode, 624 &pif->pif_tios, 1) < 0) { 625 /* 626 * Either we couldn't retrieve the 627 * characteristics for this console, or they 628 * weren't parseable. The console hasn't been 629 * set up yet, so we can't warn. We'll have to 630 * silently fall back to the default 631 * characteristics. 632 */ 633 (void) kmdb_parse_mode(KMDB_PROM_DEF_CONS_MODE, 634 &pif->pif_tios, 1); 635 } 636 } 637 638 if (mode != NULL) 639 kmdb_prom_free_ddi_prop(mode); 640 } 641 642 /* various characteristics of the prom read/write interface */ 643 pif->pif_tios.c_iflag |= ICRNL; 644 pif->pif_tios.c_lflag |= ECHO; 645 bcopy(ccs, &pif->pif_tios.c_cc, sizeof (ccs)); 646 647 if (conin != NULL) 648 kmdb_prom_free_ddi_prop(conin); 649 if (conout != NULL) 650 kmdb_prom_free_ddi_prop(conout); 651 } 652 653 char * 654 kmdb_prom_term_type(void) 655 { 656 return (mdb.m_promif->pif_oterm); 657 } 658 659 int 660 kmdb_prom_term_ctl(int req, void *arg) 661 { 662 switch (req) { 663 case TCGETS: { 664 struct termios *ti = arg; 665 bcopy(&mdb.m_promif->pif_tios, ti, sizeof (struct termios)); 666 return (0); 667 } 668 case TIOCGWINSZ: 669 /* 670 * When kmdb is used over a serial console, we have no idea how 671 * large the terminal window is. When we're invoked on a local 672 * console, however, we do, and need to share that information 673 * with the debugger in order to contradict potentially 674 * incorrect sizing information retrieved from the terminfo 675 * database. One specific case where this happens is with the 676 * Intel console, which is 80x25. The terminfo entry for 677 * sun-color -- the default terminal type for local Intel 678 * consoles -- was cloned from sun, which has a height of 34 679 * rows. 680 */ 681 if (mdb.m_promif->pif_oterm != NULL) { 682 struct winsize *wsz = arg; 683 wsz->ws_row = KMDB_PIF_WINSIZE_ROWS; 684 wsz->ws_col = KMDB_PIF_WINSIZE_COLS; 685 wsz->ws_xpixel = wsz->ws_ypixel = 0; 686 return (0); 687 } 688 689 return (set_errno(ENOTSUP)); 690 default: 691 return (set_errno(EINVAL)); 692 } 693 } 694 695 int 696 kmdb_prom_vtop(uintptr_t virt, physaddr_t *pap) 697 { 698 physaddr_t pa; 699 int rc = kmdb_kdi_vtop(virt, &pa); 700 701 #ifdef __sparc 702 if (rc < 0 && errno == EAGAIN) 703 rc = kmdb_prom_translate_virt(virt, &pa); 704 #endif 705 706 if (rc == 0 && pap != NULL) 707 *pap = pa; 708 709 return (rc); 710 } 711 712 void 713 kmdb_prom_debugger_entry(void) 714 { 715 /* 716 * While kmdb_prom_debugger_entry and kmdb_prom_debugger_exit are not 717 * guaranteed to be called an identical number of times (an intentional 718 * debugger fault will cause an additional entry call without a matching 719 * exit call), we must ensure that the polled I/O entry and exit calls 720 * match. 721 */ 722 if (mdb.m_pio == NULL) { 723 mdb.m_pio = kmdb_kdi_get_polled_io(); 724 725 if (mdb.m_pio != NULL && 726 mdb.m_pio->cons_polledio_enter != NULL) { 727 (void) kmdb_dpi_call( 728 (uintptr_t)mdb.m_pio->cons_polledio_enter, 1, 729 (uintptr_t *)&mdb.m_pio->cons_polledio_argument); 730 } 731 } 732 } 733 734 void 735 kmdb_prom_debugger_exit(void) 736 { 737 if (mdb.m_pio != NULL && mdb.m_pio->cons_polledio_exit != NULL) { 738 (void) kmdb_dpi_call((uintptr_t)mdb.m_pio->cons_polledio_exit, 739 1, (uintptr_t *)&mdb.m_pio->cons_polledio_argument); 740 } 741 742 mdb.m_pio = NULL; 743 } 744 745 /* 746 * The prom_* files use ASSERT, which is #defined as assfail(). We need to 747 * redirect that to our assert function. This is also used by the various STAND 748 * libraries. 749 */ 750 int 751 kmdb_prom_assfail(const char *assertion, const char *file, int line) 752 { 753 (void) mdb_dassert(assertion, file, line); 754 /*NOTREACHED*/ 755 return (0); 756 } 757 758 /* 759 * Begin the initialization of the debugger/PROM interface. Initialization is 760 * performed in two steps due to interlocking dependencies between promif and 761 * both the memory allocator and mdb_create. The first phase is performed 762 * before either of the others have been initialized, and thus must neither 763 * attempt to allocate memory nor access/write to `mdb'. 764 */ 765 void 766 kmdb_prom_init_begin(char *pgmname, kmdb_auxv_t *kav) 767 { 768 #ifdef sun4v 769 if (kav->kav_domaining) 770 kmdb_prom_init_promif(pgmname, kav); 771 else 772 prom_init(pgmname, kav->kav_romp); 773 #else 774 prom_init(pgmname, kav->kav_romp); 775 #endif 776 777 /* Initialize the interrupt ring buffer */ 778 kmdb_prom_readbuf_head = kmdb_prom_readbuf_tail; 779 780 #if defined(__i386) || defined(__amd64) 781 kmdb_sysp = kav->kav_romp; 782 #endif 783 } 784 785 #ifdef sun4v 786 void 787 kmdb_prom_init_promif(char *pgmname, kmdb_auxv_t *kav) 788 { 789 ASSERT(kav->kav_domaining); 790 cif_init(pgmname, kav->kav_promif_root, 791 kav->kav_promif_in, kav->kav_promif_out, 792 kav->kav_promif_pin, kav->kav_promif_pout, 793 kav->kav_promif_chosennode, kav->kav_promif_optionsnode); 794 } 795 #endif 796 797 /* 798 * Conclude the initialization of the debugger/PROM interface. Memory 799 * allocation and the global `mdb' object are now available. 800 */ 801 void 802 kmdb_prom_init_finish(kmdb_auxv_t *kav) 803 { 804 mdb.m_promif = mdb_zalloc(sizeof (kmdb_promif_t), UM_SLEEP); 805 kmdb_prom_term_init(kav, mdb.m_promif); 806 } 807