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 2006 Sun Microsystems, Inc. All rights reserved. 24 * Use is subject to license terms. 25 */ 26 27 /* Copyright (c) 1988 AT&T */ 28 /* All Rights Reserved */ 29 30 #pragma ident "%Z%%M% %I% %E% SMI" 31 32 /* 33 * Memory management: malloc(), realloc(), free(), memalign(). 34 * 35 * The following #-parameters may be redefined: 36 * GETCORE: a function to get more core memory. 37 * GETCORE(0) is assumed to return the next available 38 * address. Default is 'sbrk'. 39 * ERRCORE: the error code as returned by GETCORE. 40 * Default is ((char *)(-1)). 41 * CORESIZE: a desired unit (measured in bytes) to be used 42 * with GETCORE. Default is (1024*ALIGN). 43 * 44 * This algorithm is based on a best fit strategy with lists of 45 * free elts maintained in a self-adjusting binary tree. Each list 46 * contains all elts of the same size. The tree is ordered by size. 47 * For results on self-adjusting trees, see the paper: 48 * Self-Adjusting Binary Trees, 49 * DD Sleator & RE Tarjan, JACM 1985. 50 * 51 * The header of a block contains the size of the data part in bytes. 52 * Since the size of a block is 0%4, the low two bits of the header 53 * are free and used as follows: 54 * 55 * BIT0: 1 for busy (block is in use), 0 for free. 56 * BIT1: if the block is busy, this bit is 1 if the 57 * preceding block in contiguous memory is free. 58 * Otherwise, it is always 0. 59 */ 60 61 #include "mallint.h" 62 63 static mutex_t __watch_malloc_lock = DEFAULTMUTEX; 64 65 static TREE *Root; /* root of the free tree */ 66 static TREE *Bottom; /* the last free chunk in the arena */ 67 static char *Baddr; /* current high address of the arena */ 68 69 static void t_delete(TREE *); 70 static void t_splay(TREE *); 71 static void realfree(void *); 72 static void *malloc_unlocked(size_t); 73 static void free_unlocked(void *); 74 static TREE *morecore(size_t); 75 76 static void protect(TREE *); 77 static void unprotect(TREE *); 78 79 #define FREEPAT 0 80 #define LIVEPAT 1 81 82 /* 83 * Patterns to be copied into freed blocks and allocated blocks. 84 * 0xfeedbeef and 0xfeedface are invalid pointer values in all programs. 85 */ 86 static uint64_t patterns[2] = { 87 0xdeadbeefdeadbeefULL, /* pattern in a freed block */ 88 0xbaddcafebaddcafeULL /* pattern in an allocated block */ 89 }; 90 91 static void 92 copy_pattern(int pat, TREE *tp) 93 { 94 uint64_t pattern = patterns[pat]; 95 size_t sz = SIZE(tp) / sizeof (uint64_t); 96 /* LINTED improper alignment */ 97 uint64_t *datap = (uint64_t *)DATA(tp); 98 99 while (sz--) 100 *datap++ = pattern; 101 } 102 103 /* 104 * Keep lists of small blocks, LIFO order. 105 */ 106 static TREE *List[MINSIZE/WORDSIZE-1]; 107 static TREE *Last[MINSIZE/WORDSIZE-1]; 108 109 /* number of blocks to get at one time */ 110 #define NPS (WORDSIZE*8) 111 112 static void * 113 smalloc(size_t size) 114 { 115 TREE *tp; 116 size_t i; 117 118 ASSERT(size % WORDSIZE == 0); 119 /* want to return a unique pointer on malloc(0) */ 120 if (size == 0) 121 size = WORDSIZE; 122 123 /* list to use */ 124 i = size / WORDSIZE - 1; 125 126 if (List[i] == NULL) { 127 TREE *np; 128 int n; 129 ASSERT((size + WORDSIZE) * NPS >= MINSIZE); 130 131 /* get NPS of these block types */ 132 if ((np = malloc_unlocked((size + WORDSIZE)*NPS)) == NULL) 133 return (NULL); 134 135 /* make them into a link list */ 136 for (n = 0, List[i] = np; n < NPS; ++n) { 137 tp = np; 138 SIZE(tp) = size; 139 copy_pattern(FREEPAT, tp); 140 if (n == NPS - 1) { 141 Last[i] = tp; 142 np = NULL; 143 } else { 144 /* LINTED improper alignment */ 145 np = NEXT(tp); 146 } 147 AFTER(tp) = np; 148 protect(tp); 149 } 150 } 151 152 /* allocate from the head of the queue */ 153 tp = List[i]; 154 unprotect(tp); 155 if ((List[i] = AFTER(tp)) == NULL) 156 Last[i] = NULL; 157 copy_pattern(LIVEPAT, tp); 158 SETBIT0(SIZE(tp)); 159 protect(tp); 160 return (DATA(tp)); 161 } 162 163 void * 164 malloc(size_t size) 165 { 166 void *ret; 167 _mutex_lock(&__watch_malloc_lock); 168 ret = malloc_unlocked(size); 169 _mutex_unlock(&__watch_malloc_lock); 170 return (ret); 171 } 172 173 static void * 174 malloc_unlocked(size_t size) 175 { 176 size_t n; 177 TREE *tp, *sp, *tmp; 178 179 COUNT(nmalloc); 180 ASSERT(WORDSIZE == ALIGN); 181 182 /* check for size that could overflow calculations */ 183 if (size > MAX_MALLOC) { 184 errno = ENOMEM; 185 return (NULL); 186 } 187 /* make sure that size is 0 mod ALIGN */ 188 ROUND(size); 189 190 /* small blocks */ 191 if (size < MINSIZE) 192 return (smalloc(size)); 193 194 /* search for an elt of the right size */ 195 sp = NULL; 196 n = 0; 197 if (Root) { 198 tp = Root; 199 for (;;) { 200 unprotect(tp); 201 if (SIZE(tp) >= size) { /* branch left */ 202 if (n == 0 || n >= SIZE(tp)) { 203 sp = tp; 204 n = SIZE(tp); 205 } 206 if ((tmp = LEFT(tp)) != NULL) { 207 protect(tp); 208 tp = tmp; 209 } else { 210 protect(tp); 211 break; 212 } 213 } else { /* branch right */ 214 if ((tmp = RIGHT(tp)) != NULL) { 215 protect(tp); 216 tp = tmp; 217 } else { 218 protect(tp); 219 break; 220 } 221 } 222 } 223 224 if (sp) { 225 unprotect(sp); 226 t_delete(sp); 227 } else if (tp != Root) { 228 /* make the searched-to element the root */ 229 unprotect(tp); 230 t_splay(tp); 231 protect(tp); 232 Root = tp; 233 } 234 } 235 236 /* if found none fitted in the tree */ 237 if (sp == NULL) { 238 if (Bottom) { 239 unprotect(Bottom); 240 if (size <= SIZE(Bottom)) { 241 sp = Bottom; 242 CLRBITS01(SIZE(sp)); 243 } else { 244 protect(Bottom); 245 if ((sp = morecore(size)) == NULL) 246 return (NULL); 247 } 248 } else { 249 if ((sp = morecore(size)) == NULL) 250 return (NULL); 251 } 252 } 253 254 /* tell the forward neighbor that we're busy */ 255 /* LINTED improper alignment */ 256 tmp = NEXT(sp); 257 unprotect(tmp); 258 CLRBIT1(SIZE(tmp)); 259 ASSERT(ISBIT0(SIZE(tmp))); 260 protect(tmp); 261 262 leftover: 263 /* if the leftover is enough for a new free piece */ 264 if ((n = (SIZE(sp) - size)) >= MINSIZE + WORDSIZE) { 265 n -= WORDSIZE; 266 SIZE(sp) = size; 267 /* LINTED improper alignment */ 268 tp = NEXT(sp); 269 SIZE(tp) = n | BIT0; 270 realfree(DATA(tp)); 271 } else if (BOTTOM(sp)) 272 Bottom = NULL; 273 274 /* return the allocated space */ 275 copy_pattern(LIVEPAT, sp); 276 SIZE(sp) |= BIT0; 277 protect(sp); 278 return (DATA(sp)); 279 } 280 281 /* 282 * realloc(). 283 * If the block size is increasing, we try forward merging first. 284 * This is not best-fit but it avoids some data recopying. 285 */ 286 void * 287 realloc(void *old, size_t size) 288 { 289 TREE *tp, *np; 290 size_t ts; 291 char *new; 292 293 COUNT(nrealloc); 294 295 /* check for size that could overflow calculations */ 296 if (size > MAX_MALLOC) { 297 errno = ENOMEM; 298 return (NULL); 299 } 300 301 /* pointer to the block */ 302 _mutex_lock(&__watch_malloc_lock); 303 if (old == NULL) { 304 new = malloc_unlocked(size); 305 _mutex_unlock(&__watch_malloc_lock); 306 return (new); 307 } 308 309 /* make sure that size is 0 mod ALIGN */ 310 ROUND(size); 311 312 /* LINTED improper alignment */ 313 tp = BLOCK(old); 314 unprotect(tp); 315 ts = SIZE(tp); 316 317 /* if the block was freed, data has been destroyed. */ 318 if (!ISBIT0(ts)) { 319 /* XXX; complain here! */ 320 protect(tp); 321 _mutex_unlock(&__watch_malloc_lock); 322 errno = EINVAL; 323 return (NULL); 324 } 325 326 CLRBITS01(SIZE(tp)); 327 if (size == SIZE(tp)) { /* nothing to do */ 328 SIZE(tp) = ts; 329 protect(tp); 330 _mutex_unlock(&__watch_malloc_lock); 331 return (old); 332 } 333 334 /* special cases involving small blocks */ 335 if (size < MINSIZE || SIZE(tp) < MINSIZE) { 336 if (size == 0) { 337 SETOLD01(SIZE(tp), ts); 338 free_unlocked(old); 339 _mutex_unlock(&__watch_malloc_lock); 340 return (NULL); 341 } 342 goto call_malloc; 343 } 344 345 /* block is increasing in size, try merging the next block */ 346 if (size > SIZE(tp)) { 347 /* LINTED improper alignment */ 348 np = NEXT(tp); 349 unprotect(np); 350 if (ISBIT0(SIZE(np))) 351 protect(np); 352 else { 353 TREE *tmp; 354 ASSERT(SIZE(np) >= MINSIZE); 355 ASSERT(!ISBIT1(SIZE(np))); 356 SIZE(tp) += SIZE(np) + WORDSIZE; 357 if (np != Bottom) 358 t_delete(np); 359 else 360 Bottom = NULL; 361 /* LINTED improper alignment */ 362 tmp = NEXT(np); 363 unprotect(tmp); 364 CLRBIT1(SIZE(tmp)); 365 protect(tmp); 366 } 367 368 /* not enough & at TRUE end of memory, try extending core */ 369 if (size > SIZE(tp) && BOTTOM(tp) && GETCORE(0) == Baddr) { 370 Bottom = tp; 371 protect(Bottom); 372 if ((tp = morecore(size)) == NULL) { 373 tp = Bottom; 374 Bottom = NULL; 375 unprotect(tp); 376 } 377 } 378 } 379 380 /* got enough space to use */ 381 if (size <= SIZE(tp)) { 382 size_t n; 383 chop_big: 384 if ((n = (SIZE(tp) - size)) >= MINSIZE + WORDSIZE) { 385 n -= WORDSIZE; 386 SIZE(tp) = size; 387 /* LINTED improper alignment */ 388 np = NEXT(tp); 389 SIZE(np) = n | BIT0; 390 realfree(DATA(np)); 391 } else if (BOTTOM(tp)) 392 Bottom = NULL; 393 394 /* the previous block may be free */ 395 SETOLD01(SIZE(tp), ts); 396 protect(tp); 397 _mutex_unlock(&__watch_malloc_lock); 398 return (old); 399 } 400 401 call_malloc: /* call malloc to get a new block */ 402 SETOLD01(SIZE(tp), ts); 403 if ((new = malloc_unlocked(size)) != NULL) { 404 CLRBITS01(ts); 405 if (ts > size) 406 ts = size; 407 (void) memcpy(new, old, ts); 408 free_unlocked(old); 409 _mutex_unlock(&__watch_malloc_lock); 410 return (new); 411 } 412 413 /* 414 * Attempt special case recovery allocations since malloc() failed: 415 * 416 * 1. size <= SIZE(tp) < MINSIZE 417 * Simply return the existing block 418 * 2. SIZE(tp) < size < MINSIZE 419 * malloc() may have failed to allocate the chunk of 420 * small blocks. Try asking for MINSIZE bytes. 421 * 3. size < MINSIZE <= SIZE(tp) 422 * malloc() may have failed as with 2. Change to 423 * MINSIZE allocation which is taken from the beginning 424 * of the current block. 425 * 4. MINSIZE <= SIZE(tp) < size 426 * If the previous block is free and the combination of 427 * these two blocks has at least size bytes, then merge 428 * the two blocks copying the existing contents backwards. 429 */ 430 CLRBITS01(SIZE(tp)); 431 if (SIZE(tp) < MINSIZE) { 432 if (size < SIZE(tp)) /* case 1. */ { 433 SETOLD01(SIZE(tp), ts); 434 protect(tp); 435 _mutex_unlock(&__watch_malloc_lock); 436 return (old); 437 } else if (size < MINSIZE) /* case 2. */ { 438 size = MINSIZE; 439 goto call_malloc; 440 } 441 } else if (size < MINSIZE) /* case 3. */ { 442 size = MINSIZE; 443 goto chop_big; 444 } else if (ISBIT1(ts)) { 445 np = LAST(tp); 446 unprotect(np); 447 if ((SIZE(np) + SIZE(tp) + WORDSIZE) >= size) { 448 ASSERT(!ISBIT0(SIZE(np))); 449 t_delete(np); 450 SIZE(np) += SIZE(tp) + WORDSIZE; 451 /* 452 * Since the copy may overlap, use memmove(). 453 */ 454 (void) memmove(DATA(np), old, SIZE(tp)); 455 old = DATA(np); 456 tp = np; 457 CLRBIT1(ts); 458 goto chop_big; 459 } 460 protect(np); 461 } 462 SETOLD01(SIZE(tp), ts); 463 protect(tp); 464 _mutex_unlock(&__watch_malloc_lock); 465 /* malloc() sets errno */ 466 return (NULL); 467 } 468 469 /* 470 * realfree(). 471 * Coalescing of adjacent free blocks is done first. 472 * Then, the new free block is leaf-inserted into the free tree 473 * without splaying. This strategy does not guarantee the amortized 474 * O(nlogn) behaviour for the insert/delete/find set of operations 475 * on the tree. In practice, however, free is much more infrequent 476 * than malloc/realloc and the tree searches performed by these 477 * functions adequately keep the tree in balance. 478 */ 479 static void 480 realfree(void *old) 481 { 482 TREE *tp, *sp, *np, *tmp; 483 size_t ts, size; 484 485 COUNT(nfree); 486 487 /* pointer to the block */ 488 /* LINTED improper alignment */ 489 tp = BLOCK(old); 490 unprotect(tp); 491 ts = SIZE(tp); 492 if (!ISBIT0(ts)) { /* block is not busy; previously freed? */ 493 protect(tp); /* force a watchpoint trap */ 494 CLRBIT0(SIZE(tp)); 495 return; 496 } 497 CLRBITS01(SIZE(tp)); 498 copy_pattern(FREEPAT, tp); 499 500 /* small block, return it to the tail of its queue */ 501 if (SIZE(tp) < MINSIZE) { 502 ASSERT(SIZE(tp) / WORDSIZE >= 1); 503 ts = SIZE(tp) / WORDSIZE - 1; 504 AFTER(tp) = NULL; 505 protect(tp); 506 if (List[ts] == NULL) { 507 List[ts] = tp; 508 Last[ts] = tp; 509 } else { 510 sp = Last[ts]; 511 unprotect(sp); 512 AFTER(sp) = tp; 513 protect(sp); 514 Last[ts] = tp; 515 } 516 return; 517 } 518 519 /* see if coalescing with next block is warranted */ 520 /* LINTED improper alignment */ 521 np = NEXT(tp); 522 unprotect(np); 523 if (ISBIT0(SIZE(np))) 524 protect(np); 525 else { 526 if (np != Bottom) 527 t_delete(np); 528 SIZE(tp) += SIZE(np) + WORDSIZE; 529 } 530 531 /* the same with the preceding block */ 532 if (ISBIT1(ts)) { 533 np = LAST(tp); 534 unprotect(np); 535 ASSERT(!ISBIT0(SIZE(np))); 536 ASSERT(np != Bottom); 537 t_delete(np); 538 SIZE(np) += SIZE(tp) + WORDSIZE; 539 tp = np; 540 } 541 542 /* initialize tree info */ 543 PARENT(tp) = LEFT(tp) = RIGHT(tp) = LINKFOR(tp) = NULL; 544 545 /* set bottom block, or insert in the free tree */ 546 if (BOTTOM(tp)) 547 Bottom = tp; 548 else { 549 /* search for the place to insert */ 550 if (Root) { 551 size = SIZE(tp); 552 np = Root; 553 for (;;) { 554 unprotect(np); 555 if (SIZE(np) > size) { 556 if ((tmp = LEFT(np)) != NULL) { 557 protect(np); 558 np = tmp; 559 } else { 560 LEFT(np) = tp; 561 PARENT(tp) = np; 562 protect(np); 563 break; 564 } 565 } else if (SIZE(np) < size) { 566 if ((tmp = RIGHT(np)) != NULL) { 567 protect(np); 568 np = tmp; 569 } else { 570 RIGHT(np) = tp; 571 PARENT(tp) = np; 572 protect(np); 573 break; 574 } 575 } else { 576 if ((sp = PARENT(np)) != NULL) { 577 unprotect(sp); 578 if (np == LEFT(sp)) 579 LEFT(sp) = tp; 580 else 581 RIGHT(sp) = tp; 582 PARENT(tp) = sp; 583 protect(sp); 584 } else 585 Root = tp; 586 587 /* insert to head of list */ 588 if ((sp = LEFT(np)) != NULL) { 589 unprotect(sp); 590 PARENT(sp) = tp; 591 protect(sp); 592 } 593 LEFT(tp) = sp; 594 595 if ((sp = RIGHT(np)) != NULL) { 596 unprotect(sp); 597 PARENT(sp) = tp; 598 protect(sp); 599 } 600 RIGHT(tp) = sp; 601 602 /* doubly link list */ 603 LINKFOR(tp) = np; 604 LINKBAK(np) = tp; 605 SETNOTREE(np); 606 protect(np); 607 608 break; 609 } 610 } 611 } else { 612 Root = tp; 613 } 614 } 615 616 /* 617 * Tell next block that this one is free. 618 * The first WORD of the next block contains self's address. 619 */ 620 /* LINTED improper alignment */ 621 tmp = NEXT(tp); 622 unprotect(tmp); 623 /* LINTED improper alignment */ 624 *(SELFP(tp)) = tp; 625 SETBIT1(SIZE(tmp)); 626 ASSERT(ISBIT0(SIZE(tmp))); 627 protect(tmp); 628 protect(tp); 629 } 630 631 /* 632 * Get more core. Gaps in memory are noted as busy blocks. 633 */ 634 static TREE * 635 morecore(size_t size) 636 { 637 TREE *tp; 638 size_t n, offset, requestsize; 639 char *addr; 640 641 /* compute new amount of memory to get */ 642 tp = Bottom; 643 n = size + 2 * WORDSIZE; 644 addr = GETCORE(0); 645 646 if (addr == ERRCORE) 647 /* errno set by GETCORE sbrk */ 648 return (NULL); 649 650 /* need to pad size out so that addr is aligned */ 651 if ((((size_t)addr) % ALIGN) != 0) 652 offset = ALIGN - (size_t)addr % ALIGN; 653 else 654 offset = 0; 655 656 if (tp) 657 unprotect(tp); 658 659 /* if not segmented memory, what we need may be smaller */ 660 if (addr == Baddr) { 661 n -= WORDSIZE; 662 if (tp != NULL) 663 n -= SIZE(tp); 664 } 665 666 /* get a multiple of CORESIZE */ 667 n = ((n - 1) / CORESIZE + 1) * CORESIZE; 668 requestsize = n + offset; 669 670 /* check if nsize request could overflow in GETCORE */ 671 if (requestsize > MAX_MALLOC - (size_t)addr) { 672 if (tp) 673 protect(tp); 674 errno = ENOMEM; 675 return (NULL); 676 } 677 678 if (requestsize > MAX_GETCORE) { 679 intptr_t delta; 680 /* 681 * the value required is too big for GETCORE() to deal with 682 * in one go, so use GETCORE() at most 2 times instead. 683 * Argument to GETCORE() must be multiple of ALIGN. 684 * If not, GETCORE(-MAX_GETCORE) will not return brk point 685 * to previous value, but will be ALIGN more. 686 * This would leave a small hole. 687 */ 688 delta = MAX_GETCORE; 689 while (delta > 0) { 690 if (GETCORE(delta) == ERRCORE) { 691 if (tp) 692 protect(tp); 693 if (addr != GETCORE(0)) 694 (void) GETCORE(-MAX_GETCORE); 695 return (NULL); 696 } 697 requestsize -= MAX_GETCORE; 698 delta = requestsize; 699 } 700 } else if (GETCORE(requestsize) == ERRCORE) { 701 if (tp) 702 protect(tp); 703 return (NULL); 704 } 705 706 /* contiguous memory */ 707 if (addr == Baddr) { 708 ASSERT(offset == 0); 709 if (tp) { 710 addr = ((char *)tp); 711 n += SIZE(tp) + 2 * WORDSIZE; 712 } else { 713 addr = Baddr - WORDSIZE; 714 n += WORDSIZE; 715 } 716 } else { 717 addr += offset; 718 } 719 720 /* new bottom address */ 721 Baddr = addr + n; 722 723 /* new bottom block */ 724 /* LINTED improper alignment */ 725 tp = ((TREE *)addr); 726 SIZE(tp) = n - 2 * WORDSIZE; 727 ASSERT((SIZE(tp) % ALIGN) == 0); 728 729 /* reserved the last word to head any noncontiguous memory */ 730 /* LINTED improper alignment */ 731 SETBIT0(SIZE(NEXT(tp))); 732 733 /* non-contiguous memory, free old bottom block */ 734 if (Bottom && Bottom != tp) { 735 SETBIT0(SIZE(Bottom)); 736 realfree(DATA(Bottom)); 737 } 738 739 return (tp); 740 } 741 742 /* 743 * Utility function to avoid protecting a tree node twice. 744 * Return true if tp is in the NULL-terminated array of tree nodes. 745 */ 746 static int 747 in_list(TREE *tp, TREE **npp) 748 { 749 TREE *sp; 750 751 while ((sp = *npp++) != NULL) 752 if (tp == sp) 753 return (1); 754 return (0); 755 } 756 757 /* 758 * Tree rotation functions (BU: bottom-up, TD: top-down). 759 * All functions are entered with the arguments unprotected. 760 * They must return in the same condition, with all other elements 761 * that have been unprotected during the operation re-protected. 762 */ 763 static void 764 LEFT1(TREE *x, TREE *y) 765 { 766 TREE *node[3]; 767 TREE **npp = node; 768 TREE *tp; 769 770 if ((RIGHT(x) = LEFT(y)) != NULL) { 771 unprotect(*npp++ = RIGHT(x)); 772 PARENT(RIGHT(x)) = x; 773 } 774 if ((PARENT(y) = PARENT(x)) != NULL) { 775 unprotect(*npp++ = PARENT(x)); 776 if (LEFT(PARENT(x)) == x) 777 LEFT(PARENT(y)) = y; 778 else 779 RIGHT(PARENT(y)) = y; 780 } 781 LEFT(y) = x; 782 PARENT(x) = y; 783 784 *npp = NULL; 785 npp = node; 786 while ((tp = *npp++) != NULL) 787 if (tp != x && tp != y && !in_list(tp, npp)) 788 protect(tp); 789 } 790 791 static void 792 RIGHT1(TREE *x, TREE *y) 793 { 794 TREE *node[3]; 795 TREE **npp = node; 796 TREE *tp; 797 798 if ((LEFT(x) = RIGHT(y)) != NULL) { 799 unprotect(*npp++ = LEFT(x)); 800 PARENT(LEFT(x)) = x; 801 } 802 if ((PARENT(y) = PARENT(x)) != NULL) { 803 unprotect(*npp++ = PARENT(x)); 804 if (LEFT(PARENT(x)) == x) 805 LEFT(PARENT(y)) = y; 806 else 807 RIGHT(PARENT(y)) = y; 808 } 809 RIGHT(y) = x; 810 PARENT(x) = y; 811 812 *npp = NULL; 813 npp = node; 814 while ((tp = *npp++) != NULL) 815 if (tp != x && tp != y && !in_list(tp, npp)) 816 protect(tp); 817 } 818 819 static void 820 BULEFT2(TREE *x, TREE *y, TREE *z) 821 { 822 TREE *node[4]; 823 TREE **npp = node; 824 TREE *tp; 825 826 if ((RIGHT(x) = LEFT(y)) != NULL) { 827 unprotect(*npp++ = RIGHT(x)); 828 PARENT(RIGHT(x)) = x; 829 } 830 if ((RIGHT(y) = LEFT(z)) != NULL) { 831 unprotect(*npp++ = RIGHT(y)); 832 PARENT(RIGHT(y)) = y; 833 } 834 if ((PARENT(z) = PARENT(x)) != NULL) { 835 unprotect(*npp++ = PARENT(x)); 836 if (LEFT(PARENT(x)) == x) 837 LEFT(PARENT(z)) = z; 838 else 839 RIGHT(PARENT(z)) = z; 840 } 841 LEFT(z) = y; 842 PARENT(y) = z; 843 LEFT(y) = x; 844 PARENT(x) = y; 845 846 *npp = NULL; 847 npp = node; 848 while ((tp = *npp++) != NULL) 849 if (tp != x && tp != y && tp != z && !in_list(tp, npp)) 850 protect(tp); 851 } 852 853 static void 854 BURIGHT2(TREE *x, TREE *y, TREE *z) 855 { 856 TREE *node[4]; 857 TREE **npp = node; 858 TREE *tp; 859 860 if ((LEFT(x) = RIGHT(y)) != NULL) { 861 unprotect(*npp++ = LEFT(x)); 862 PARENT(LEFT(x)) = x; 863 } 864 if ((LEFT(y) = RIGHT(z)) != NULL) { 865 unprotect(*npp++ = LEFT(y)); 866 PARENT(LEFT(y)) = y; 867 } 868 if ((PARENT(z) = PARENT(x)) != NULL) { 869 unprotect(*npp++ = PARENT(x)); 870 if (LEFT(PARENT(x)) == x) 871 LEFT(PARENT(z)) = z; 872 else 873 RIGHT(PARENT(z)) = z; 874 } 875 RIGHT(z) = y; 876 PARENT(y) = z; 877 RIGHT(y) = x; 878 PARENT(x) = y; 879 880 *npp = NULL; 881 npp = node; 882 while ((tp = *npp++) != NULL) 883 if (tp != x && tp != y && tp != z && !in_list(tp, npp)) 884 protect(tp); 885 } 886 887 static void 888 TDLEFT2(TREE *x, TREE *y, TREE *z) 889 { 890 TREE *node[3]; 891 TREE **npp = node; 892 TREE *tp; 893 894 if ((RIGHT(y) = LEFT(z)) != NULL) { 895 unprotect(*npp++ = RIGHT(y)); 896 PARENT(RIGHT(y)) = y; 897 } 898 if ((PARENT(z) = PARENT(x)) != NULL) { 899 unprotect(*npp++ = PARENT(x)); 900 if (LEFT(PARENT(x)) == x) 901 LEFT(PARENT(z)) = z; 902 else 903 RIGHT(PARENT(z)) = z; 904 } 905 PARENT(x) = z; 906 LEFT(z) = x; 907 908 *npp = NULL; 909 npp = node; 910 while ((tp = *npp++) != NULL) 911 if (tp != x && tp != y && tp != z && !in_list(tp, npp)) 912 protect(tp); 913 } 914 915 #if 0 /* Not used, for now */ 916 static void 917 TDRIGHT2(TREE *x, TREE *y, TREE *z) 918 { 919 TREE *node[3]; 920 TREE **npp = node; 921 TREE *tp; 922 923 if ((LEFT(y) = RIGHT(z)) != NULL) { 924 unprotect(*npp++ = LEFT(y)); 925 PARENT(LEFT(y)) = y; 926 } 927 if ((PARENT(z) = PARENT(x)) != NULL) { 928 unprotect(*npp++ = PARENT(x)); 929 if (LEFT(PARENT(x)) == x) 930 LEFT(PARENT(z)) = z; 931 else 932 RIGHT(PARENT(z)) = z; 933 } 934 PARENT(x) = z; 935 RIGHT(z) = x; 936 937 *npp = NULL; 938 npp = node; 939 while ((tp = *npp++) != NULL) 940 if (tp != x && tp != y && tp != z && !in_list(tp, npp)) 941 protect(tp); 942 } 943 #endif 944 945 /* 946 * Delete a tree element 947 */ 948 static void 949 t_delete(TREE *op) 950 { 951 TREE *tp, *sp, *gp; 952 953 /* if this is a non-tree node */ 954 if (ISNOTREE(op)) { 955 tp = LINKBAK(op); 956 unprotect(tp); 957 if ((sp = LINKFOR(op)) != NULL) { 958 unprotect(sp); 959 LINKBAK(sp) = tp; 960 protect(sp); 961 } 962 LINKFOR(tp) = sp; 963 protect(tp); 964 return; 965 } 966 967 /* make op the root of the tree */ 968 if (PARENT(op)) 969 t_splay(op); 970 971 /* if this is the start of a list */ 972 if ((tp = LINKFOR(op)) != NULL) { 973 unprotect(tp); 974 PARENT(tp) = NULL; 975 if ((sp = LEFT(op)) != NULL) { 976 unprotect(sp); 977 PARENT(sp) = tp; 978 protect(sp); 979 } 980 LEFT(tp) = sp; 981 982 if ((sp = RIGHT(op)) != NULL) { 983 unprotect(sp); 984 PARENT(sp) = tp; 985 protect(sp); 986 } 987 RIGHT(tp) = sp; 988 989 Root = tp; 990 protect(tp); 991 return; 992 } 993 994 /* if op has a non-null left subtree */ 995 if ((tp = LEFT(op)) != NULL) { 996 unprotect(tp); 997 PARENT(tp) = NULL; 998 if (RIGHT(op)) { 999 /* make the right-end of the left subtree its root */ 1000 while ((sp = RIGHT(tp)) != NULL) { 1001 unprotect(sp); 1002 if ((gp = RIGHT(sp)) != NULL) { 1003 unprotect(gp); 1004 TDLEFT2(tp, sp, gp); 1005 protect(sp); 1006 protect(tp); 1007 tp = gp; 1008 } else { 1009 LEFT1(tp, sp); 1010 protect(tp); 1011 tp = sp; 1012 } 1013 } 1014 1015 /* hook the right subtree of op to the above elt */ 1016 RIGHT(tp) = sp = RIGHT(op); 1017 unprotect(sp); 1018 PARENT(sp) = tp; 1019 protect(sp); 1020 } 1021 protect(tp); 1022 } else if ((tp = RIGHT(op)) != NULL) { /* no left subtree */ 1023 unprotect(tp); 1024 PARENT(tp) = NULL; 1025 protect(tp); 1026 } 1027 1028 Root = tp; 1029 } 1030 1031 /* 1032 * Bottom up splaying (simple version). 1033 * The basic idea is to roughly cut in half the 1034 * path from Root to tp and make tp the new root. 1035 */ 1036 static void 1037 t_splay(TREE *tp) 1038 { 1039 TREE *pp, *gp; 1040 1041 /* iterate until tp is the root */ 1042 while ((pp = PARENT(tp)) != NULL) { 1043 unprotect(pp); 1044 /* grandparent of tp */ 1045 gp = PARENT(pp); 1046 if (gp) 1047 unprotect(gp); 1048 1049 /* x is a left child */ 1050 if (LEFT(pp) == tp) { 1051 if (gp && LEFT(gp) == pp) { 1052 BURIGHT2(gp, pp, tp); 1053 protect(gp); 1054 } else { 1055 if (gp) 1056 protect(gp); 1057 RIGHT1(pp, tp); 1058 } 1059 } else { 1060 ASSERT(RIGHT(pp) == tp); 1061 if (gp && RIGHT(gp) == pp) { 1062 BULEFT2(gp, pp, tp); 1063 protect(gp); 1064 } else { 1065 if (gp) 1066 protect(gp); 1067 LEFT1(pp, tp); 1068 } 1069 } 1070 protect(pp); 1071 unprotect(tp); /* just in case */ 1072 } 1073 } 1074 1075 void 1076 free(void *old) 1077 { 1078 _mutex_lock(&__watch_malloc_lock); 1079 free_unlocked(old); 1080 _mutex_unlock(&__watch_malloc_lock); 1081 } 1082 1083 1084 static void 1085 free_unlocked(void *old) 1086 { 1087 if (old != NULL) 1088 realfree(old); 1089 } 1090 1091 1092 /* 1093 * memalign(align,nbytes) 1094 * 1095 * Description: 1096 * Returns a block of specified size on a specified alignment boundary. 1097 * 1098 * Algorithm: 1099 * Malloc enough to ensure that a block can be aligned correctly. 1100 * Find the alignment point and return the fragments 1101 * before and after the block. 1102 * 1103 * Errors: 1104 * Returns NULL and sets errno as follows: 1105 * [EINVAL] 1106 * if nbytes = 0, 1107 * or if alignment is misaligned, 1108 * or if the heap has been detectably corrupted. 1109 * [ENOMEM] 1110 * if the requested memory could not be allocated. 1111 */ 1112 1113 #define misaligned(p) ((unsigned)(p) & 3) 1114 /* 4-byte "word" alignment is considered ok in LP64 */ 1115 #define nextblk(p, size) ((TREE *)((char *)(p) + (size))) 1116 1117 void * 1118 memalign(size_t align, size_t nbytes) 1119 { 1120 size_t reqsize; /* Num of bytes to get from malloc() */ 1121 TREE *p; /* Ptr returned from malloc() */ 1122 TREE *blk; /* For addressing fragment blocks */ 1123 size_t blksize; /* Current (shrinking) block size */ 1124 TREE *alignedp; /* Ptr to properly aligned boundary */ 1125 TREE *aligned_blk; /* The block to be returned */ 1126 size_t frag_size; /* size of fragments fore and aft */ 1127 size_t x; 1128 1129 /* 1130 * check for valid size and alignment parameters 1131 * MAX_ALIGN check prevents overflow in later calculation. 1132 */ 1133 if (nbytes == 0 || misaligned(align) || align == 0 || 1134 align > MAX_ALIGN) { 1135 errno = EINVAL; 1136 return (NULL); 1137 } 1138 1139 /* 1140 * Malloc enough memory to guarantee that the result can be 1141 * aligned correctly. The worst case is when malloc returns 1142 * a block so close to the next alignment boundary that a 1143 * fragment of minimum size cannot be created. In order to 1144 * make sure we can handle this, we need to force the 1145 * alignment to be at least as large as the minimum frag size 1146 * (MINSIZE + WORDSIZE). 1147 */ 1148 1149 /* check for size that could overflow ROUND calculation */ 1150 if (nbytes > MAX_MALLOC) { 1151 errno = ENOMEM; 1152 return (NULL); 1153 } 1154 ROUND(nbytes); 1155 if (nbytes < MINSIZE) 1156 nbytes = MINSIZE; 1157 ROUND(align); 1158 while (align < MINSIZE + WORDSIZE) 1159 align <<= 1; 1160 reqsize = nbytes + align + (MINSIZE + WORDSIZE); 1161 /* check for overflow */ 1162 if (reqsize < nbytes) { 1163 errno = ENOMEM; 1164 return (NULL); 1165 } 1166 p = (TREE *) malloc(reqsize); 1167 if (p == (TREE *) NULL) { 1168 /* malloc sets errno */ 1169 return (NULL); 1170 } 1171 _mutex_lock(&__watch_malloc_lock); 1172 1173 /* 1174 * get size of the entire block (overhead and all) 1175 */ 1176 /* LINTED improper alignment */ 1177 blk = BLOCK(p); /* back up to get length word */ 1178 unprotect(blk); 1179 blksize = SIZE(blk); 1180 CLRBITS01(blksize); 1181 1182 /* 1183 * locate the proper alignment boundary within the block. 1184 */ 1185 x = (size_t)p; 1186 if (x % align != 0) 1187 x += align - (x % align); 1188 alignedp = (TREE *)x; 1189 /* LINTED improper alignment */ 1190 aligned_blk = BLOCK(alignedp); 1191 1192 /* 1193 * Check out the space to the left of the alignment 1194 * boundary, and split off a fragment if necessary. 1195 */ 1196 frag_size = (size_t)aligned_blk - (size_t)blk; 1197 if (frag_size != 0) { 1198 /* 1199 * Create a fragment to the left of the aligned block. 1200 */ 1201 if (frag_size < MINSIZE + WORDSIZE) { 1202 /* 1203 * Not enough space. So make the split 1204 * at the other end of the alignment unit. 1205 * We know this yields enough space, because 1206 * we forced align >= MINSIZE + WORDSIZE above. 1207 */ 1208 frag_size += align; 1209 /* LINTED improper alignment */ 1210 aligned_blk = nextblk(aligned_blk, align); 1211 } 1212 blksize -= frag_size; 1213 SIZE(aligned_blk) = blksize | BIT0; 1214 frag_size -= WORDSIZE; 1215 SIZE(blk) = frag_size | BIT0 | ISBIT1(SIZE(blk)); 1216 free_unlocked(DATA(blk)); 1217 /* 1218 * free_unlocked(DATA(blk)) has the side-effect of calling 1219 * protect() on the block following blk, that is, aligned_blk. 1220 * We recover from this by unprotect()ing it here. 1221 */ 1222 unprotect(aligned_blk); 1223 } 1224 1225 /* 1226 * Is there a (sufficiently large) fragment to the 1227 * right of the aligned block? 1228 */ 1229 frag_size = blksize - nbytes; 1230 if (frag_size >= MINSIZE + WORDSIZE) { 1231 /* 1232 * split and free a fragment on the right 1233 */ 1234 blksize = SIZE(aligned_blk); 1235 SIZE(aligned_blk) = nbytes; 1236 /* LINTED improper alignment */ 1237 blk = NEXT(aligned_blk); 1238 SETOLD01(SIZE(aligned_blk), blksize); 1239 frag_size -= WORDSIZE; 1240 SIZE(blk) = frag_size | BIT0; 1241 free_unlocked(DATA(blk)); 1242 } 1243 copy_pattern(LIVEPAT, aligned_blk); 1244 protect(aligned_blk); 1245 _mutex_unlock(&__watch_malloc_lock); 1246 return (DATA(aligned_blk)); 1247 } 1248 1249 void * 1250 valloc(size_t size) 1251 { 1252 static unsigned pagesize; 1253 if (!pagesize) 1254 pagesize = _sysconf(_SC_PAGESIZE); 1255 return (memalign(pagesize, size)); 1256 } 1257 1258 void * 1259 calloc(size_t num, size_t size) 1260 { 1261 void *mp; 1262 size_t total; 1263 1264 total = num * size; 1265 1266 /* check for overflow */ 1267 if (num != 0 && total / num != size) { 1268 errno = ENOMEM; 1269 return (NULL); 1270 } 1271 if ((mp = malloc(total)) != NULL) 1272 (void) memset(mp, 0, total); 1273 return (mp); 1274 } 1275 1276 /* ARGSUSED1 */ 1277 void 1278 cfree(void *p, size_t num, size_t size) 1279 { 1280 free(p); 1281 } 1282 1283 typedef struct { 1284 long cmd; 1285 prwatch_t prwatch; 1286 } ctl_t; 1287 1288 static pid_t my_pid = 0; /* to check for whether we fork()d */ 1289 static int dont_watch = 0; 1290 static int do_stop = 0; 1291 static int ctlfd = -1; 1292 struct stat ctlstatb; 1293 static int wflags = WA_WRITE; 1294 1295 static void 1296 init_watch() 1297 { 1298 char str[80]; 1299 char *s; 1300 1301 my_pid = getpid(); 1302 1303 dont_watch = 1; 1304 1305 if ((s = getenv("MALLOC_DEBUG")) == NULL) 1306 return; 1307 1308 s = strncpy(str, s, sizeof (str)); 1309 while (s != NULL) { 1310 char *e = strchr(s, ','); 1311 if (e) 1312 *e++ = '\0'; 1313 if (strcmp(s, "STOP") == 0) 1314 do_stop = 1; 1315 else if (strcmp(s, "WATCH") == 0) 1316 dont_watch = 0; 1317 else if (strcmp(s, "RW") == 0) { 1318 dont_watch = 0; 1319 wflags = WA_READ|WA_WRITE; 1320 } 1321 s = e; 1322 } 1323 1324 if (dont_watch) 1325 return; 1326 1327 if ((ctlfd = open("/proc/self/ctl", O_WRONLY)) < 0 || 1328 fstat(ctlfd, &ctlstatb) != 0) { 1329 if (ctlfd >= 0) 1330 (void) close(ctlfd); 1331 ctlfd = -1; 1332 dont_watch = 1; 1333 return; 1334 } 1335 /* close-on-exec */ 1336 (void) fcntl(ctlfd, F_SETFD, 1); 1337 1338 if (do_stop) { 1339 int pfd; 1340 pstatus_t pstatus; 1341 struct { 1342 long cmd; 1343 fltset_t fltset; 1344 } ctl; 1345 1346 /* 1347 * Play together with some /proc controller 1348 * that has set other stop-on-fault flags. 1349 */ 1350 premptyset(&ctl.fltset); 1351 if ((pfd = open("/proc/self/status", O_RDONLY)) >= 0) { 1352 if (read(pfd, &pstatus, sizeof (pstatus)) 1353 == sizeof (pstatus)) 1354 ctl.fltset = pstatus.pr_flttrace; 1355 (void) close(pfd); 1356 } 1357 praddset(&ctl.fltset, FLTWATCH); 1358 ctl.cmd = PCSFAULT; 1359 (void) write(ctlfd, &ctl, sizeof (ctl)); 1360 } 1361 } 1362 1363 static int 1364 nowatch() 1365 { 1366 struct stat statb; 1367 1368 if (dont_watch) 1369 return (1); 1370 if (ctlfd < 0) /* first time */ 1371 init_watch(); 1372 else if (fstat(ctlfd, &statb) != 0 || 1373 statb.st_dev != ctlstatb.st_dev || 1374 statb.st_ino != ctlstatb.st_ino) { 1375 /* 1376 * Someone closed our file descriptor. 1377 * Just open another one. 1378 */ 1379 if ((ctlfd = open("/proc/self/ctl", O_WRONLY)) < 0 || 1380 fstat(ctlfd, &ctlstatb) != 0) { 1381 if (ctlfd >= 0) 1382 (void) close(ctlfd); 1383 ctlfd = -1; 1384 dont_watch = 1; 1385 return (1); 1386 } 1387 /* close-on-exec */ 1388 (void) fcntl(ctlfd, F_SETFD, 1); 1389 } 1390 if (my_pid != getpid()) { 1391 /* 1392 * We fork()d since the last call to the allocator. 1393 * watchpoints are not inherited across fork(). 1394 * XXX: how to recover from this ??? 1395 */ 1396 dont_watch = 1; 1397 (void) close(ctlfd); 1398 ctlfd = -1; 1399 } 1400 return (dont_watch); 1401 } 1402 1403 static void 1404 protect(TREE *tp) 1405 { 1406 ctl_t ctl; 1407 size_t size, sz; 1408 1409 if (nowatch()) 1410 return; 1411 if (tp == NULL || DATA(tp) == Baddr) 1412 return; 1413 1414 sz = size = SIZE(tp); 1415 CLRBITS01(size); 1416 if (size == 0) 1417 return; 1418 if (ISBIT0(sz)) /* block is busy, protect only the head */ 1419 size = 0; 1420 ctl.cmd = PCWATCH; 1421 ctl.prwatch.pr_vaddr = (uintptr_t)tp; 1422 ctl.prwatch.pr_size = size + WORDSIZE; 1423 ctl.prwatch.pr_wflags = wflags; 1424 (void) write(ctlfd, &ctl, sizeof (ctl)); 1425 } 1426 1427 static void 1428 unprotect(TREE *tp) 1429 { 1430 ctl_t ctl; 1431 1432 if (nowatch()) 1433 return; 1434 if (tp == NULL || DATA(tp) == Baddr) 1435 return; 1436 1437 ctl.cmd = PCWATCH; 1438 ctl.prwatch.pr_vaddr = (uintptr_t)tp; 1439 ctl.prwatch.pr_size = WORDSIZE; /* size is arbitrary */ 1440 ctl.prwatch.pr_wflags = 0; /* clear the watched area */ 1441 (void) write(ctlfd, &ctl, sizeof (ctl)); 1442 } 1443