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 * Copyright 2011 Joyent, Inc. All rights reserved. 28 */ 29 30 #include <sys/dtrace_impl.h> 31 #include <sys/atomic.h> 32 #include <sys/model.h> 33 #include <sys/frame.h> 34 #include <sys/stack.h> 35 #include <sys/machpcb.h> 36 #include <sys/procfs_isa.h> 37 #include <sys/cmn_err.h> 38 #include <sys/sysmacros.h> 39 40 #define DTRACE_FMT3OP3_MASK 0x81000000 41 #define DTRACE_FMT3OP3 0x80000000 42 #define DTRACE_FMT3RS1_SHIFT 14 43 #define DTRACE_FMT3RD_SHIFT 25 44 #define DTRACE_DISP22_SHIFT 10 45 #define DTRACE_RMASK 0x1f 46 #define DTRACE_REG_L0 16 47 #define DTRACE_REG_O7 15 48 #define DTRACE_REG_I0 24 49 #define DTRACE_REG_I6 30 50 #define DTRACE_RET 0x81c7e008 51 #define DTRACE_RETL 0x81c3e008 52 #define DTRACE_SAVE_MASK 0xc1f80000 53 #define DTRACE_SAVE 0x81e00000 54 #define DTRACE_RESTORE 0x81e80000 55 #define DTRACE_CALL_MASK 0xc0000000 56 #define DTRACE_CALL 0x40000000 57 #define DTRACE_JMPL_MASK 0x81f80000 58 #define DTRACE_JMPL 0x81c00000 59 #define DTRACE_BA_MASK 0xdfc00000 60 #define DTRACE_BA 0x10800000 61 #define DTRACE_BA_MAX 10 62 63 extern int dtrace_getupcstack_top(uint64_t *, int, uintptr_t *); 64 extern int dtrace_getustackdepth_top(uintptr_t *); 65 extern ulong_t dtrace_getreg_win(uint_t, uint_t); 66 extern void dtrace_putreg_win(uint_t, ulong_t); 67 extern int dtrace_fish(int, int, uintptr_t *); 68 69 int dtrace_ustackdepth_max = 2048; 70 71 /* 72 * This is similar in principle to getpcstack(), but there are several marked 73 * differences in implementation: 74 * 75 * (a) dtrace_getpcstack() is called from probe context. Thus, the call 76 * to flush_windows() from getpcstack() is a call to the probe-safe 77 * equivalent here. 78 * 79 * (b) dtrace_getpcstack() is willing to sacrifice some performance to get 80 * a correct stack. While consumers of getpcstack() are largely 81 * subsystem-specific in-kernel debugging facilities, DTrace consumers 82 * are arbitrary user-level analysis tools; dtrace_getpcstack() must 83 * deliver as correct a stack as possible. Details on the issues 84 * surrounding stack correctness are found below. 85 * 86 * (c) dtrace_getpcstack() _always_ fills in pcstack_limit pc_t's -- filling 87 * in the difference between the stack depth and pcstack_limit with NULLs. 88 * Due to this behavior dtrace_getpcstack() returns void. 89 * 90 * (d) dtrace_getpcstack() takes a third parameter, aframes, that 91 * denotes the number of _artificial frames_ on the bottom of the 92 * stack. An artificial frame is one induced by the provider; all 93 * artificial frames are stripped off before frames are stored to 94 * pcstack. 95 * 96 * (e) dtrace_getpcstack() takes a fourth parameter, pc, that indicates 97 * an interrupted program counter (if any). This should be a non-NULL 98 * value if and only if the hit probe is unanchored. (Anchored probes 99 * don't fire through an interrupt source.) This parameter is used to 100 * assure (b), above. 101 */ 102 void 103 dtrace_getpcstack(pc_t *pcstack, int pcstack_limit, int aframes, uint32_t *pc) 104 { 105 struct frame *fp, *nextfp, *minfp, *stacktop; 106 int depth = 0; 107 int on_intr, j = 0; 108 uint32_t i, r; 109 110 fp = (struct frame *)((caddr_t)dtrace_getfp() + STACK_BIAS); 111 dtrace_flush_windows(); 112 113 if (pc != NULL) { 114 /* 115 * If we've been passed a non-NULL pc, we need to determine 116 * whether or not the specified program counter falls in a leaf 117 * function. If it falls within a leaf function, we know that 118 * %o7 is valid in its frame (and we can just drive on). If 119 * it's a non-leaf, however, we know that %o7 is garbage in the 120 * bottom frame. To trim this frame, we simply increment 121 * aframes and drop into the stack-walking loop. 122 * 123 * To quickly determine if the specified program counter is in 124 * a leaf function, we exploit the fact that leaf functions 125 * tend to be short and non-leaf functions tend to frequently 126 * perform operations that are only permitted in a non-leaf 127 * function (e.g., using the %i's or %l's; calling a function; 128 * performing a restore). We exploit these tendencies by 129 * simply scanning forward from the specified %pc -- if we see 130 * an operation only permitted in a non-leaf, we know we're in 131 * a non-leaf; if we see a retl, we know we're in a leaf. 132 * Fortunately, one need not perform anywhere near full 133 * disassembly to effectively determine the former: determining 134 * that an instruction is a format-3 instruction and decoding 135 * its rd and rs1 fields, for example, requires very little 136 * manipulation. Overall, this method of leaf determination 137 * performs quite well: on average, we only examine between 138 * 1.5 and 2.5 instructions before making the determination. 139 * (Outliers do exist, however; of note is the non-leaf 140 * function ip_sioctl_not_ours() which -- as of this writing -- 141 * has a whopping 455 straight instructions that manipulate 142 * only %g's and %o's.) 143 */ 144 int delay = 0, branches = 0, taken = 0; 145 146 if (depth < pcstack_limit) 147 pcstack[depth++] = (pc_t)(uintptr_t)pc; 148 149 /* 150 * Our heuristic is exactly that -- a heuristic -- and there 151 * exists a possibility that we could be either be vectored 152 * off into the weeds (by following a bogus branch) or could 153 * wander off the end of the function and off the end of a 154 * text mapping (by not following a conditional branch at the 155 * end of the function that is effectively always taken). So 156 * as a precautionary measure, we set the NOFAULT flag. 157 */ 158 DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); 159 160 for (;;) { 161 i = pc[j++]; 162 163 if ((i & DTRACE_FMT3OP3_MASK) == DTRACE_FMT3OP3) { 164 /* 165 * This is a format-3 instruction. We can 166 * look at rd and rs1. 167 */ 168 r = (i >> DTRACE_FMT3RS1_SHIFT) & DTRACE_RMASK; 169 170 if (r >= DTRACE_REG_L0) 171 goto nonleaf; 172 173 r = (i >> DTRACE_FMT3RD_SHIFT) & DTRACE_RMASK; 174 175 if (r >= DTRACE_REG_L0) 176 goto nonleaf; 177 178 if ((i & DTRACE_JMPL_MASK) == DTRACE_JMPL) { 179 delay = 1; 180 continue; 181 } 182 183 /* 184 * If we see explicit manipulation with %o7 185 * as a destination register, we know that 186 * %o7 is likely bogus -- and we treat this 187 * function as a non-leaf. 188 */ 189 if (r == DTRACE_REG_O7) { 190 if (delay) 191 goto leaf; 192 193 i &= DTRACE_JMPL_MASK; 194 195 if (i == DTRACE_JMPL) { 196 delay = 1; 197 continue; 198 } 199 200 goto nonleaf; 201 } 202 } else { 203 /* 204 * If this is a call, it may or may not be 205 * a leaf; we need to check the delay slot. 206 */ 207 if ((i & DTRACE_CALL_MASK) == DTRACE_CALL) { 208 delay = 1; 209 continue; 210 } 211 212 /* 213 * If we see a ret it's not a leaf; if we 214 * see a retl, it is a leaf. 215 */ 216 if (i == DTRACE_RET) 217 goto nonleaf; 218 219 if (i == DTRACE_RETL) 220 goto leaf; 221 222 /* 223 * If this is a ba (annulled or not), then we 224 * need to actually follow the branch. No, we 225 * don't look at the delay slot -- hopefully 226 * anything that can be gleaned from the delay 227 * slot can also be gleaned from the branch 228 * target. To prevent ourselves from iterating 229 * infinitely, we clamp the number of branches 230 * that we'll follow, and we refuse to follow 231 * the same branch twice consecutively. In 232 * both cases, we abort by deciding that we're 233 * looking at a leaf. While in theory this 234 * could be wrong (we could be in the middle of 235 * a loop in a non-leaf that ends with a ba and 236 * only manipulates outputs and globals in the 237 * body of the loop -- therefore leading us to 238 * the wrong conclusion), this doesn't seem to 239 * crop up in practice. (Or rather, this 240 * condition could not be deliberately induced, 241 * despite concerted effort.) 242 */ 243 if ((i & DTRACE_BA_MASK) == DTRACE_BA) { 244 if (++branches == DTRACE_BA_MAX || 245 taken == j) 246 goto nonleaf; 247 248 taken = j; 249 j += ((int)(i << DTRACE_DISP22_SHIFT) >> 250 DTRACE_DISP22_SHIFT) - 1; 251 continue; 252 } 253 254 /* 255 * Finally, if it's a save, it should be 256 * treated as a leaf; if it's a restore it 257 * should not be treated as a leaf. 258 */ 259 if ((i & DTRACE_SAVE_MASK) == DTRACE_SAVE) 260 goto leaf; 261 262 if ((i & DTRACE_SAVE_MASK) == DTRACE_RESTORE) 263 goto nonleaf; 264 } 265 266 if (delay) { 267 /* 268 * If this was a delay slot instruction and 269 * we didn't pick it up elsewhere, this is a 270 * non-leaf. 271 */ 272 goto nonleaf; 273 } 274 } 275 nonleaf: 276 aframes++; 277 leaf: 278 DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); 279 } 280 281 if ((on_intr = CPU_ON_INTR(CPU)) != 0) 282 stacktop = (struct frame *)(CPU->cpu_intr_stack + SA(MINFRAME)); 283 else 284 stacktop = (struct frame *)curthread->t_stk; 285 minfp = fp; 286 287 while (depth < pcstack_limit) { 288 nextfp = (struct frame *)((caddr_t)fp->fr_savfp + STACK_BIAS); 289 if (nextfp <= minfp || nextfp >= stacktop) { 290 if (!on_intr && nextfp == stacktop && aframes != 0) { 291 /* 292 * If we are exactly at the top of the stack 293 * with a non-zero number of artificial frames, 294 * it must be that the stack is filled with 295 * nothing _but_ artificial frames. In this 296 * case, we assert that this is so, zero 297 * pcstack, and return. 298 */ 299 ASSERT(aframes == 1); 300 ASSERT(depth == 0); 301 302 while (depth < pcstack_limit) 303 pcstack[depth++] = NULL; 304 return; 305 } 306 307 if (on_intr) { 308 /* 309 * Hop from interrupt stack to thread stack. 310 */ 311 stacktop = (struct frame *)curthread->t_stk; 312 minfp = (struct frame *)curthread->t_stkbase; 313 314 on_intr = 0; 315 316 if (nextfp > minfp && nextfp < stacktop) 317 continue; 318 } else { 319 /* 320 * High-level interrupts may occur when %sp is 321 * not necessarily contained in the stack 322 * bounds implied by %g7 -- interrupt thread 323 * management runs with %pil at DISP_LEVEL, 324 * and high-level interrupts may thus occur 325 * in windows when %sp and %g7 are not self- 326 * consistent. If we call dtrace_getpcstack() 327 * from a high-level interrupt that has occurred 328 * in such a window, we will fail the above test 329 * of nextfp against minfp/stacktop. If the 330 * high-level interrupt has in turn interrupted 331 * a non-passivated interrupt thread, we 332 * will execute the below code with non-zero 333 * aframes. We therefore want to assert that 334 * aframes is zero _or_ we are in a high-level 335 * interrupt -- but because cpu_intr_actv is 336 * updated with high-level interrupts enabled, 337 * we must reduce this to only asserting that 338 * %pil is greater than DISP_LEVEL. 339 */ 340 ASSERT(aframes == 0 || 341 dtrace_getipl() > DISP_LEVEL); 342 pcstack[depth++] = (pc_t)fp->fr_savpc; 343 } 344 345 while (depth < pcstack_limit) 346 pcstack[depth++] = NULL; 347 return; 348 } 349 350 if (aframes > 0) { 351 aframes--; 352 } else { 353 pcstack[depth++] = (pc_t)fp->fr_savpc; 354 } 355 356 fp = nextfp; 357 minfp = fp; 358 } 359 } 360 361 static int 362 dtrace_getustack_common(uint64_t *pcstack, int pcstack_limit, uintptr_t sp) 363 { 364 proc_t *p = curproc; 365 int ret = 0; 366 uintptr_t oldsp; 367 volatile uint16_t *flags = 368 (volatile uint16_t *)&cpu_core[CPU->cpu_id].cpuc_dtrace_flags; 369 370 ASSERT(pcstack == NULL || pcstack_limit > 0); 371 ASSERT(dtrace_ustackdepth_max > 0); 372 373 if (p->p_model == DATAMODEL_NATIVE) { 374 for (;;) { 375 struct frame *fr = (struct frame *)(sp + STACK_BIAS); 376 uintptr_t pc; 377 378 if (sp == 0 || fr == NULL || 379 !IS_P2ALIGNED((uintptr_t)fr, STACK_ALIGN)) 380 break; 381 382 oldsp = sp; 383 384 pc = dtrace_fulword(&fr->fr_savpc); 385 sp = dtrace_fulword(&fr->fr_savfp); 386 387 if (pc == 0) 388 break; 389 390 /* 391 * We limit the number of times we can go around this 392 * loop to account for a circular stack. 393 */ 394 if (sp == oldsp || ret++ >= dtrace_ustackdepth_max) { 395 *flags |= CPU_DTRACE_BADSTACK; 396 cpu_core[CPU->cpu_id].cpuc_dtrace_illval = sp; 397 break; 398 } 399 400 if (pcstack != NULL) { 401 *pcstack++ = pc; 402 pcstack_limit--; 403 if (pcstack_limit == 0) 404 break; 405 } 406 } 407 } else { 408 /* 409 * Truncate the stack pointer to 32-bits as there may be 410 * garbage in the upper bits which would normally be ignored 411 * by the processor in 32-bit mode. 412 */ 413 sp = (uint32_t)sp; 414 415 for (;;) { 416 struct frame32 *fr = (struct frame32 *)sp; 417 uint32_t pc; 418 419 if (sp == 0 || 420 !IS_P2ALIGNED((uintptr_t)fr, STACK_ALIGN32)) 421 break; 422 423 oldsp = sp; 424 425 pc = dtrace_fuword32(&fr->fr_savpc); 426 sp = dtrace_fuword32(&fr->fr_savfp); 427 428 if (pc == 0) 429 break; 430 431 if (sp == oldsp || ret++ >= dtrace_ustackdepth_max) { 432 *flags |= CPU_DTRACE_BADSTACK; 433 cpu_core[CPU->cpu_id].cpuc_dtrace_illval = sp; 434 break; 435 } 436 437 if (pcstack != NULL) { 438 *pcstack++ = pc; 439 pcstack_limit--; 440 if (pcstack_limit == 0) 441 break; 442 } 443 } 444 } 445 446 return (ret); 447 } 448 449 void 450 dtrace_getupcstack(uint64_t *pcstack, int pcstack_limit) 451 { 452 klwp_t *lwp = ttolwp(curthread); 453 proc_t *p = curproc; 454 struct regs *rp; 455 uintptr_t sp; 456 int n; 457 458 ASSERT(DTRACE_CPUFLAG_ISSET(CPU_DTRACE_NOFAULT)); 459 460 if (pcstack_limit <= 0) 461 return; 462 463 /* 464 * If there's no user context we still need to zero the stack. 465 */ 466 if (lwp == NULL || p == NULL || (rp = lwp->lwp_regs) == NULL) 467 goto zero; 468 469 *pcstack++ = (uint64_t)p->p_pid; 470 pcstack_limit--; 471 472 if (pcstack_limit <= 0) 473 return; 474 475 *pcstack++ = (uint64_t)rp->r_pc; 476 pcstack_limit--; 477 478 if (pcstack_limit <= 0) 479 return; 480 481 if (DTRACE_CPUFLAG_ISSET(CPU_DTRACE_ENTRY)) { 482 *pcstack++ = (uint64_t)rp->r_o7; 483 pcstack_limit--; 484 if (pcstack_limit <= 0) 485 return; 486 } 487 488 sp = rp->r_sp; 489 490 n = dtrace_getupcstack_top(pcstack, pcstack_limit, &sp); 491 ASSERT(n >= 0); 492 ASSERT(n <= pcstack_limit); 493 494 pcstack += n; 495 pcstack_limit -= n; 496 if (pcstack_limit <= 0) 497 return; 498 499 n = dtrace_getustack_common(pcstack, pcstack_limit, sp); 500 ASSERT(n >= 0); 501 ASSERT(n <= pcstack_limit); 502 503 pcstack += n; 504 pcstack_limit -= n; 505 506 zero: 507 while (pcstack_limit-- > 0) 508 *pcstack++ = NULL; 509 } 510 511 int 512 dtrace_getustackdepth(void) 513 { 514 klwp_t *lwp = ttolwp(curthread); 515 proc_t *p = curproc; 516 struct regs *rp; 517 uintptr_t sp; 518 int n = 1; 519 520 if (lwp == NULL || p == NULL || (rp = lwp->lwp_regs) == NULL) 521 return (0); 522 523 if (DTRACE_CPUFLAG_ISSET(CPU_DTRACE_FAULT)) 524 return (-1); 525 526 sp = rp->r_sp; 527 528 n += dtrace_getustackdepth_top(&sp); 529 n += dtrace_getustack_common(NULL, 0, sp); 530 531 /* 532 * Add one more to the stack depth if we're in an entry probe as long 533 * as the return address is non-NULL or there are additional frames 534 * beyond that NULL return address. 535 */ 536 if (DTRACE_CPUFLAG_ISSET(CPU_DTRACE_ENTRY) && 537 (rp->r_o7 != NULL || n != 1)) 538 n++; 539 540 return (n); 541 } 542 543 void 544 dtrace_getufpstack(uint64_t *pcstack, uint64_t *fpstack, int pcstack_limit) 545 { 546 klwp_t *lwp = ttolwp(curthread); 547 proc_t *p = ttoproc(curthread); 548 struct regs *rp; 549 uintptr_t sp; 550 551 if (pcstack_limit <= 0) 552 return; 553 554 /* 555 * If there's no user context we still need to zero the stack. 556 */ 557 if (lwp == NULL || p == NULL || (rp = lwp->lwp_regs) == NULL) 558 goto zero; 559 560 *pcstack++ = (uint64_t)p->p_pid; 561 pcstack_limit--; 562 563 if (pcstack_limit <= 0) 564 return; 565 566 if (DTRACE_CPUFLAG_ISSET(CPU_DTRACE_ENTRY)) { 567 *fpstack++ = 0; 568 *pcstack++ = (uint64_t)rp->r_pc; 569 pcstack_limit--; 570 if (pcstack_limit <= 0) 571 return; 572 573 *fpstack++ = (uint64_t)rp->r_sp; 574 *pcstack++ = (uint64_t)rp->r_o7; 575 pcstack_limit--; 576 } else { 577 *fpstack++ = (uint64_t)rp->r_sp; 578 *pcstack++ = (uint64_t)rp->r_pc; 579 pcstack_limit--; 580 } 581 582 if (pcstack_limit <= 0) 583 return; 584 585 sp = rp->r_sp; 586 587 dtrace_flush_user_windows(); 588 589 if (p->p_model == DATAMODEL_NATIVE) { 590 while (pcstack_limit > 0) { 591 struct frame *fr = (struct frame *)(sp + STACK_BIAS); 592 uintptr_t pc; 593 594 if (sp == 0 || fr == NULL || 595 ((uintptr_t)&fr->fr_savpc & 3) != 0 || 596 ((uintptr_t)&fr->fr_savfp & 3) != 0) 597 break; 598 599 pc = dtrace_fulword(&fr->fr_savpc); 600 sp = dtrace_fulword(&fr->fr_savfp); 601 602 if (pc == 0) 603 break; 604 605 *fpstack++ = sp; 606 *pcstack++ = pc; 607 pcstack_limit--; 608 } 609 } else { 610 /* 611 * Truncate the stack pointer to 32-bits as there may be 612 * garbage in the upper bits which would normally be ignored 613 * by the processor in 32-bit mode. 614 */ 615 sp = (uint32_t)sp; 616 617 while (pcstack_limit > 0) { 618 struct frame32 *fr = (struct frame32 *)sp; 619 uint32_t pc; 620 621 if (sp == 0 || 622 ((uintptr_t)&fr->fr_savpc & 3) != 0 || 623 ((uintptr_t)&fr->fr_savfp & 3) != 0) 624 break; 625 626 pc = dtrace_fuword32(&fr->fr_savpc); 627 sp = dtrace_fuword32(&fr->fr_savfp); 628 629 if (pc == 0) 630 break; 631 632 *fpstack++ = sp; 633 *pcstack++ = pc; 634 pcstack_limit--; 635 } 636 } 637 638 zero: 639 while (pcstack_limit-- > 0) 640 *pcstack++ = NULL; 641 } 642 643 uint64_t 644 dtrace_getarg(int arg, int aframes) 645 { 646 uintptr_t val; 647 struct frame *fp; 648 uint64_t rval; 649 650 /* 651 * Account for the fact that dtrace_getarg() consumes an additional 652 * stack frame. 653 */ 654 aframes++; 655 656 if (arg < 6) { 657 if (dtrace_fish(aframes, DTRACE_REG_I0 + arg, &val) == 0) 658 return (val); 659 } else { 660 if (dtrace_fish(aframes, DTRACE_REG_I6, &val) == 0) { 661 /* 662 * We have a stack pointer; grab the argument. 663 */ 664 fp = (struct frame *)(val + STACK_BIAS); 665 666 DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); 667 rval = fp->fr_argx[arg - 6]; 668 DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); 669 670 return (rval); 671 } 672 } 673 674 /* 675 * There are other ways to do this. But the slow, painful way works 676 * just fine. Because this requires some loads, we need to set 677 * CPU_DTRACE_NOFAULT to protect against looking for an argument that 678 * isn't there. 679 */ 680 fp = (struct frame *)((caddr_t)dtrace_getfp() + STACK_BIAS); 681 dtrace_flush_windows(); 682 683 DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); 684 685 for (aframes -= 1; aframes; aframes--) 686 fp = (struct frame *)((caddr_t)fp->fr_savfp + STACK_BIAS); 687 688 if (arg < 6) { 689 rval = fp->fr_arg[arg]; 690 } else { 691 fp = (struct frame *)((caddr_t)fp->fr_savfp + STACK_BIAS); 692 rval = fp->fr_argx[arg - 6]; 693 } 694 695 DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); 696 697 return (rval); 698 } 699 700 int 701 dtrace_getstackdepth(int aframes) 702 { 703 struct frame *fp, *nextfp, *minfp, *stacktop; 704 int depth = 0; 705 int on_intr; 706 707 fp = (struct frame *)((caddr_t)dtrace_getfp() + STACK_BIAS); 708 dtrace_flush_windows(); 709 710 if ((on_intr = CPU_ON_INTR(CPU)) != 0) 711 stacktop = (struct frame *)CPU->cpu_intr_stack + SA(MINFRAME); 712 else 713 stacktop = (struct frame *)curthread->t_stk; 714 minfp = fp; 715 716 for (;;) { 717 nextfp = (struct frame *)((caddr_t)fp->fr_savfp + STACK_BIAS); 718 if (nextfp <= minfp || nextfp >= stacktop) { 719 if (on_intr) { 720 /* 721 * Hop from interrupt stack to thread stack. 722 */ 723 stacktop = (struct frame *)curthread->t_stk; 724 minfp = (struct frame *)curthread->t_stkbase; 725 on_intr = 0; 726 continue; 727 } 728 729 return (++depth); 730 } 731 732 if (aframes > 0) { 733 aframes--; 734 } else { 735 depth++; 736 } 737 738 fp = nextfp; 739 minfp = fp; 740 } 741 } 742 743 /* 744 * This uses the same register numbering scheme as in sys/procfs_isa.h. 745 */ 746 ulong_t 747 dtrace_getreg(struct regs *rp, uint_t reg) 748 { 749 ulong_t value; 750 uintptr_t fp; 751 struct machpcb *mpcb; 752 753 if (reg == R_G0) 754 return (0); 755 756 if (reg <= R_G7) 757 return ((&rp->r_g1)[reg - 1]); 758 759 if (reg > R_I7) { 760 switch (reg) { 761 case R_CCR: 762 return ((rp->r_tstate >> TSTATE_CCR_SHIFT) & 763 TSTATE_CCR_MASK); 764 case R_PC: 765 return (rp->r_pc); 766 case R_nPC: 767 return (rp->r_npc); 768 case R_Y: 769 return (rp->r_y); 770 case R_ASI: 771 return ((rp->r_tstate >> TSTATE_ASI_SHIFT) & 772 TSTATE_ASI_MASK); 773 case R_FPRS: 774 return (dtrace_getfprs()); 775 default: 776 DTRACE_CPUFLAG_SET(CPU_DTRACE_ILLOP); 777 return (0); 778 } 779 } 780 781 /* 782 * We reach go to the fake restore case if the probe we hit was a pid 783 * return probe on a restore instruction. We partially emulate the 784 * restore in the kernel and then execute a simple restore 785 * instruction that we've secreted away to do the actual register 786 * window manipulation. We need to go one register window further 787 * down to get at the %ls, and %is and we need to treat %os like %is 788 * to pull them out of the topmost user frame. 789 */ 790 if (DTRACE_CPUFLAG_ISSET(CPU_DTRACE_FAKERESTORE)) { 791 if (reg > R_O7) 792 goto fake_restore; 793 else 794 reg += R_I0 - R_O0; 795 796 } else if (reg <= R_O7) { 797 return ((&rp->r_g1)[reg - 1]); 798 } 799 800 if (dtrace_getotherwin() > 0) 801 return (dtrace_getreg_win(reg, 1)); 802 803 mpcb = (struct machpcb *)((caddr_t)rp - REGOFF); 804 805 if (curproc->p_model == DATAMODEL_NATIVE) { 806 struct frame *fr = (void *)(rp->r_sp + STACK_BIAS); 807 808 if (mpcb->mpcb_wbcnt > 0) { 809 struct rwindow *rwin = (void *)mpcb->mpcb_wbuf; 810 int i = mpcb->mpcb_wbcnt; 811 do { 812 i--; 813 if ((long)mpcb->mpcb_spbuf[i] == rp->r_sp) 814 return (rwin[i].rw_local[reg - 16]); 815 } while (i > 0); 816 } 817 818 DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); 819 value = dtrace_fulword(&fr->fr_local[reg - 16]); 820 DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); 821 } else { 822 struct frame32 *fr = (void *)(uintptr_t)(caddr32_t)rp->r_sp; 823 824 if (mpcb->mpcb_wbcnt > 0) { 825 struct rwindow32 *rwin = (void *)mpcb->mpcb_wbuf; 826 int i = mpcb->mpcb_wbcnt; 827 do { 828 i--; 829 if ((long)mpcb->mpcb_spbuf[i] == rp->r_sp) 830 return (rwin[i].rw_local[reg - 16]); 831 } while (i > 0); 832 } 833 834 DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); 835 value = dtrace_fuword32(&fr->fr_local[reg - 16]); 836 DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); 837 } 838 839 return (value); 840 841 fake_restore: 842 ASSERT(R_L0 <= reg && reg <= R_I7); 843 844 /* 845 * We first look two user windows down to see if we can dig out 846 * the register we're looking for. 847 */ 848 if (dtrace_getotherwin() > 1) 849 return (dtrace_getreg_win(reg, 2)); 850 851 /* 852 * First we need to get the frame pointer and then we perform 853 * the same computation as in the non-fake-o-restore case. 854 */ 855 856 mpcb = (struct machpcb *)((caddr_t)rp - REGOFF); 857 858 if (dtrace_getotherwin() > 0) { 859 fp = dtrace_getreg_win(R_FP, 1); 860 goto got_fp; 861 } 862 863 if (curproc->p_model == DATAMODEL_NATIVE) { 864 struct frame *fr = (void *)(rp->r_sp + STACK_BIAS); 865 866 if (mpcb->mpcb_wbcnt > 0) { 867 struct rwindow *rwin = (void *)mpcb->mpcb_wbuf; 868 int i = mpcb->mpcb_wbcnt; 869 do { 870 i--; 871 if ((long)mpcb->mpcb_spbuf[i] == rp->r_sp) { 872 fp = rwin[i].rw_fp; 873 goto got_fp; 874 } 875 } while (i > 0); 876 } 877 878 DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); 879 fp = dtrace_fulword(&fr->fr_savfp); 880 DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); 881 if (cpu_core[CPU->cpu_id].cpuc_dtrace_flags & CPU_DTRACE_FAULT) 882 return (0); 883 } else { 884 struct frame32 *fr = (void *)(uintptr_t)(caddr32_t)rp->r_sp; 885 886 if (mpcb->mpcb_wbcnt > 0) { 887 struct rwindow32 *rwin = (void *)mpcb->mpcb_wbuf; 888 int i = mpcb->mpcb_wbcnt; 889 do { 890 i--; 891 if ((long)mpcb->mpcb_spbuf[i] == rp->r_sp) { 892 fp = rwin[i].rw_fp; 893 goto got_fp; 894 } 895 } while (i > 0); 896 } 897 898 DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); 899 fp = dtrace_fuword32(&fr->fr_savfp); 900 DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); 901 if (cpu_core[CPU->cpu_id].cpuc_dtrace_flags & CPU_DTRACE_FAULT) 902 return (0); 903 } 904 got_fp: 905 906 if (curproc->p_model == DATAMODEL_NATIVE) { 907 struct frame *fr = (void *)(fp + STACK_BIAS); 908 909 if (mpcb->mpcb_wbcnt > 0) { 910 struct rwindow *rwin = (void *)mpcb->mpcb_wbuf; 911 int i = mpcb->mpcb_wbcnt; 912 do { 913 i--; 914 if ((long)mpcb->mpcb_spbuf[i] == fp) 915 return (rwin[i].rw_local[reg - 16]); 916 } while (i > 0); 917 } 918 919 DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); 920 value = dtrace_fulword(&fr->fr_local[reg - 16]); 921 DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); 922 } else { 923 struct frame32 *fr = (void *)(uintptr_t)(caddr32_t)fp; 924 925 if (mpcb->mpcb_wbcnt > 0) { 926 struct rwindow32 *rwin = (void *)mpcb->mpcb_wbuf; 927 int i = mpcb->mpcb_wbcnt; 928 do { 929 i--; 930 if ((long)mpcb->mpcb_spbuf[i] == fp) 931 return (rwin[i].rw_local[reg - 16]); 932 } while (i > 0); 933 } 934 935 DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); 936 value = dtrace_fuword32(&fr->fr_local[reg - 16]); 937 DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); 938 } 939 940 return (value); 941 } 942 943 /*ARGSUSED*/ 944 uint64_t 945 dtrace_getvmreg(uint_t ndx, volatile uint16_t *flags) 946 { 947 *flags |= CPU_DTRACE_ILLOP; 948 949 return (0); 950 } 951