1 /* $NetBSD: livetree.c,v 1.1.1.3 2019/12/22 12:34:03 skrll Exp $ */ 2 3 // SPDX-License-Identifier: GPL-2.0-or-later 4 /* 5 * (C) Copyright David Gibson <dwg (at) au1.ibm.com>, IBM Corporation. 2005. 6 */ 7 8 #include "dtc.h" 9 #include "srcpos.h" 10 11 /* 12 * Tree building functions 13 */ 14 15 void add_label(struct label **labels, char *label) 16 { 17 struct label *new; 18 19 /* Make sure the label isn't already there */ 20 for_each_label_withdel(*labels, new) 21 if (streq(new->label, label)) { 22 new->deleted = 0; 23 return; 24 } 25 26 new = xmalloc(sizeof(*new)); 27 memset(new, 0, sizeof(*new)); 28 new->label = label; 29 new->next = *labels; 30 *labels = new; 31 } 32 33 void delete_labels(struct label **labels) 34 { 35 struct label *label; 36 37 for_each_label(*labels, label) 38 label->deleted = 1; 39 } 40 41 struct property *build_property(char *name, struct data val, 42 struct srcpos *srcpos) 43 { 44 struct property *new = xmalloc(sizeof(*new)); 45 46 memset(new, 0, sizeof(*new)); 47 48 new->name = name; 49 new->val = val; 50 new->srcpos = srcpos_copy(srcpos); 51 52 return new; 53 } 54 55 struct property *build_property_delete(char *name) 56 { 57 struct property *new = xmalloc(sizeof(*new)); 58 59 memset(new, 0, sizeof(*new)); 60 61 new->name = name; 62 new->deleted = 1; 63 64 return new; 65 } 66 67 struct property *chain_property(struct property *first, struct property *list) 68 { 69 assert(first->next == NULL); 70 71 first->next = list; 72 return first; 73 } 74 75 struct property *reverse_properties(struct property *first) 76 { 77 struct property *p = first; 78 struct property *head = NULL; 79 struct property *next; 80 81 while (p) { 82 next = p->next; 83 p->next = head; 84 head = p; 85 p = next; 86 } 87 return head; 88 } 89 90 struct node *build_node(struct property *proplist, struct node *children, 91 struct srcpos *srcpos) 92 { 93 struct node *new = xmalloc(sizeof(*new)); 94 struct node *child; 95 96 memset(new, 0, sizeof(*new)); 97 98 new->proplist = reverse_properties(proplist); 99 new->children = children; 100 new->srcpos = srcpos_copy(srcpos); 101 102 for_each_child(new, child) { 103 child->parent = new; 104 } 105 106 return new; 107 } 108 109 struct node *build_node_delete(struct srcpos *srcpos) 110 { 111 struct node *new = xmalloc(sizeof(*new)); 112 113 memset(new, 0, sizeof(*new)); 114 115 new->deleted = 1; 116 new->srcpos = srcpos_copy(srcpos); 117 118 return new; 119 } 120 121 struct node *name_node(struct node *node, char *name) 122 { 123 assert(node->name == NULL); 124 125 node->name = name; 126 127 return node; 128 } 129 130 struct node *omit_node_if_unused(struct node *node) 131 { 132 node->omit_if_unused = 1; 133 134 return node; 135 } 136 137 struct node *reference_node(struct node *node) 138 { 139 node->is_referenced = 1; 140 141 return node; 142 } 143 144 struct node *merge_nodes(struct node *old_node, struct node *new_node) 145 { 146 struct property *new_prop, *old_prop; 147 struct node *new_child, *old_child; 148 struct label *l; 149 150 old_node->deleted = 0; 151 152 /* Add new node labels to old node */ 153 for_each_label_withdel(new_node->labels, l) 154 add_label(&old_node->labels, l->label); 155 156 /* Move properties from the new node to the old node. If there 157 * is a collision, replace the old value with the new */ 158 while (new_node->proplist) { 159 /* Pop the property off the list */ 160 new_prop = new_node->proplist; 161 new_node->proplist = new_prop->next; 162 new_prop->next = NULL; 163 164 if (new_prop->deleted) { 165 delete_property_by_name(old_node, new_prop->name); 166 free(new_prop); 167 continue; 168 } 169 170 /* Look for a collision, set new value if there is */ 171 for_each_property_withdel(old_node, old_prop) { 172 if (streq(old_prop->name, new_prop->name)) { 173 /* Add new labels to old property */ 174 for_each_label_withdel(new_prop->labels, l) 175 add_label(&old_prop->labels, l->label); 176 177 old_prop->val = new_prop->val; 178 old_prop->deleted = 0; 179 free(old_prop->srcpos); 180 old_prop->srcpos = new_prop->srcpos; 181 free(new_prop); 182 new_prop = NULL; 183 break; 184 } 185 } 186 187 /* if no collision occurred, add property to the old node. */ 188 if (new_prop) 189 add_property(old_node, new_prop); 190 } 191 192 /* Move the override child nodes into the primary node. If 193 * there is a collision, then merge the nodes. */ 194 while (new_node->children) { 195 /* Pop the child node off the list */ 196 new_child = new_node->children; 197 new_node->children = new_child->next_sibling; 198 new_child->parent = NULL; 199 new_child->next_sibling = NULL; 200 201 if (new_child->deleted) { 202 delete_node_by_name(old_node, new_child->name); 203 free(new_child); 204 continue; 205 } 206 207 /* Search for a collision. Merge if there is */ 208 for_each_child_withdel(old_node, old_child) { 209 if (streq(old_child->name, new_child->name)) { 210 merge_nodes(old_child, new_child); 211 new_child = NULL; 212 break; 213 } 214 } 215 216 /* if no collision occurred, add child to the old node. */ 217 if (new_child) 218 add_child(old_node, new_child); 219 } 220 221 old_node->srcpos = srcpos_extend(old_node->srcpos, new_node->srcpos); 222 223 /* The new node contents are now merged into the old node. Free 224 * the new node. */ 225 free(new_node); 226 227 return old_node; 228 } 229 230 struct node * add_orphan_node(struct node *dt, struct node *new_node, char *ref) 231 { 232 static unsigned int next_orphan_fragment = 0; 233 struct node *node; 234 struct property *p; 235 struct data d = empty_data; 236 char *name; 237 238 if (ref[0] == '/') { 239 d = data_add_marker(d, TYPE_STRING, ref); 240 d = data_append_data(d, ref, strlen(ref) + 1); 241 242 p = build_property("target-path", d, NULL); 243 } else { 244 d = data_add_marker(d, REF_PHANDLE, ref); 245 d = data_append_integer(d, 0xffffffff, 32); 246 247 p = build_property("target", d, NULL); 248 } 249 250 xasprintf(&name, "fragment@%u", 251 next_orphan_fragment++); 252 name_node(new_node, "__overlay__"); 253 node = build_node(p, new_node, NULL); 254 name_node(node, name); 255 256 add_child(dt, node); 257 return dt; 258 } 259 260 struct node *chain_node(struct node *first, struct node *list) 261 { 262 assert(first->next_sibling == NULL); 263 264 first->next_sibling = list; 265 return first; 266 } 267 268 void add_property(struct node *node, struct property *prop) 269 { 270 struct property **p; 271 272 prop->next = NULL; 273 274 p = &node->proplist; 275 while (*p) 276 p = &((*p)->next); 277 278 *p = prop; 279 } 280 281 void delete_property_by_name(struct node *node, char *name) 282 { 283 struct property *prop = node->proplist; 284 285 while (prop) { 286 if (streq(prop->name, name)) { 287 delete_property(prop); 288 return; 289 } 290 prop = prop->next; 291 } 292 } 293 294 void delete_property(struct property *prop) 295 { 296 prop->deleted = 1; 297 delete_labels(&prop->labels); 298 } 299 300 void add_child(struct node *parent, struct node *child) 301 { 302 struct node **p; 303 304 child->next_sibling = NULL; 305 child->parent = parent; 306 307 p = &parent->children; 308 while (*p) 309 p = &((*p)->next_sibling); 310 311 *p = child; 312 } 313 314 void delete_node_by_name(struct node *parent, char *name) 315 { 316 struct node *node = parent->children; 317 318 while (node) { 319 if (streq(node->name, name)) { 320 delete_node(node); 321 return; 322 } 323 node = node->next_sibling; 324 } 325 } 326 327 void delete_node(struct node *node) 328 { 329 struct property *prop; 330 struct node *child; 331 332 node->deleted = 1; 333 for_each_child(node, child) 334 delete_node(child); 335 for_each_property(node, prop) 336 delete_property(prop); 337 delete_labels(&node->labels); 338 } 339 340 void append_to_property(struct node *node, 341 char *name, const void *data, int len, 342 enum markertype type) 343 { 344 struct data d; 345 struct property *p; 346 347 p = get_property(node, name); 348 if (p) { 349 d = data_add_marker(p->val, type, name); 350 d = data_append_data(d, data, len); 351 p->val = d; 352 } else { 353 d = data_add_marker(empty_data, type, name); 354 d = data_append_data(d, data, len); 355 p = build_property(name, d, NULL); 356 add_property(node, p); 357 } 358 } 359 360 struct reserve_info *build_reserve_entry(uint64_t address, uint64_t size) 361 { 362 struct reserve_info *new = xmalloc(sizeof(*new)); 363 364 memset(new, 0, sizeof(*new)); 365 366 new->address = address; 367 new->size = size; 368 369 return new; 370 } 371 372 struct reserve_info *chain_reserve_entry(struct reserve_info *first, 373 struct reserve_info *list) 374 { 375 assert(first->next == NULL); 376 377 first->next = list; 378 return first; 379 } 380 381 struct reserve_info *add_reserve_entry(struct reserve_info *list, 382 struct reserve_info *new) 383 { 384 struct reserve_info *last; 385 386 new->next = NULL; 387 388 if (! list) 389 return new; 390 391 for (last = list; last->next; last = last->next) 392 ; 393 394 last->next = new; 395 396 return list; 397 } 398 399 struct dt_info *build_dt_info(unsigned int dtsflags, 400 struct reserve_info *reservelist, 401 struct node *tree, uint32_t boot_cpuid_phys) 402 { 403 struct dt_info *dti; 404 405 dti = xmalloc(sizeof(*dti)); 406 dti->dtsflags = dtsflags; 407 dti->reservelist = reservelist; 408 dti->dt = tree; 409 dti->boot_cpuid_phys = boot_cpuid_phys; 410 411 return dti; 412 } 413 414 /* 415 * Tree accessor functions 416 */ 417 418 const char *get_unitname(struct node *node) 419 { 420 if (node->name[node->basenamelen] == '\0') 421 return ""; 422 else 423 return node->name + node->basenamelen + 1; 424 } 425 426 struct property *get_property(struct node *node, const char *propname) 427 { 428 struct property *prop; 429 430 for_each_property(node, prop) 431 if (streq(prop->name, propname)) 432 return prop; 433 434 return NULL; 435 } 436 437 cell_t propval_cell(struct property *prop) 438 { 439 assert(prop->val.len == sizeof(cell_t)); 440 return fdt32_to_cpu(*((fdt32_t *)prop->val.val)); 441 } 442 443 cell_t propval_cell_n(struct property *prop, int n) 444 { 445 assert(prop->val.len / sizeof(cell_t) >= n); 446 return fdt32_to_cpu(*((fdt32_t *)prop->val.val + n)); 447 } 448 449 struct property *get_property_by_label(struct node *tree, const char *label, 450 struct node **node) 451 { 452 struct property *prop; 453 struct node *c; 454 455 *node = tree; 456 457 for_each_property(tree, prop) { 458 struct label *l; 459 460 for_each_label(prop->labels, l) 461 if (streq(l->label, label)) 462 return prop; 463 } 464 465 for_each_child(tree, c) { 466 prop = get_property_by_label(c, label, node); 467 if (prop) 468 return prop; 469 } 470 471 *node = NULL; 472 return NULL; 473 } 474 475 struct marker *get_marker_label(struct node *tree, const char *label, 476 struct node **node, struct property **prop) 477 { 478 struct marker *m; 479 struct property *p; 480 struct node *c; 481 482 *node = tree; 483 484 for_each_property(tree, p) { 485 *prop = p; 486 m = p->val.markers; 487 for_each_marker_of_type(m, LABEL) 488 if (streq(m->ref, label)) 489 return m; 490 } 491 492 for_each_child(tree, c) { 493 m = get_marker_label(c, label, node, prop); 494 if (m) 495 return m; 496 } 497 498 *prop = NULL; 499 *node = NULL; 500 return NULL; 501 } 502 503 struct node *get_subnode(struct node *node, const char *nodename) 504 { 505 struct node *child; 506 507 for_each_child(node, child) 508 if (streq(child->name, nodename)) 509 return child; 510 511 return NULL; 512 } 513 514 struct node *get_node_by_path(struct node *tree, const char *path) 515 { 516 const char *p; 517 struct node *child; 518 519 if (!path || ! (*path)) { 520 if (tree->deleted) 521 return NULL; 522 return tree; 523 } 524 525 while (path[0] == '/') 526 path++; 527 528 p = strchr(path, '/'); 529 530 for_each_child(tree, child) { 531 if (p && strprefixeq(path, p - path, child->name)) 532 return get_node_by_path(child, p+1); 533 else if (!p && streq(path, child->name)) 534 return child; 535 } 536 537 return NULL; 538 } 539 540 struct node *get_node_by_label(struct node *tree, const char *label) 541 { 542 struct node *child, *node; 543 struct label *l; 544 545 assert(label && (strlen(label) > 0)); 546 547 for_each_label(tree->labels, l) 548 if (streq(l->label, label)) 549 return tree; 550 551 for_each_child(tree, child) { 552 node = get_node_by_label(child, label); 553 if (node) 554 return node; 555 } 556 557 return NULL; 558 } 559 560 struct node *get_node_by_phandle(struct node *tree, cell_t phandle) 561 { 562 struct node *child, *node; 563 564 if ((phandle == 0) || (phandle == -1)) { 565 assert(generate_fixups); 566 return NULL; 567 } 568 569 if (tree->phandle == phandle) { 570 if (tree->deleted) 571 return NULL; 572 return tree; 573 } 574 575 for_each_child(tree, child) { 576 node = get_node_by_phandle(child, phandle); 577 if (node) 578 return node; 579 } 580 581 return NULL; 582 } 583 584 struct node *get_node_by_ref(struct node *tree, const char *ref) 585 { 586 if (streq(ref, "/")) 587 return tree; 588 else if (ref[0] == '/') 589 return get_node_by_path(tree, ref); 590 else 591 return get_node_by_label(tree, ref); 592 } 593 594 cell_t get_node_phandle(struct node *root, struct node *node) 595 { 596 static cell_t phandle = 1; /* FIXME: ick, static local */ 597 struct data d = empty_data; 598 599 if ((node->phandle != 0) && (node->phandle != -1)) 600 return node->phandle; 601 602 while (get_node_by_phandle(root, phandle)) 603 phandle++; 604 605 node->phandle = phandle; 606 607 d = data_add_marker(d, TYPE_UINT32, NULL); 608 d = data_append_cell(d, phandle); 609 610 if (!get_property(node, "linux,phandle") 611 && (phandle_format & PHANDLE_LEGACY)) 612 add_property(node, build_property("linux,phandle", d, NULL)); 613 614 if (!get_property(node, "phandle") 615 && (phandle_format & PHANDLE_EPAPR)) 616 add_property(node, build_property("phandle", d, NULL)); 617 618 /* If the node *does* have a phandle property, we must 619 * be dealing with a self-referencing phandle, which will be 620 * fixed up momentarily in the caller */ 621 622 return node->phandle; 623 } 624 625 uint32_t guess_boot_cpuid(struct node *tree) 626 { 627 struct node *cpus, *bootcpu; 628 struct property *reg; 629 630 cpus = get_node_by_path(tree, "/cpus"); 631 if (!cpus) 632 return 0; 633 634 635 bootcpu = cpus->children; 636 if (!bootcpu) 637 return 0; 638 639 reg = get_property(bootcpu, "reg"); 640 if (!reg || (reg->val.len != sizeof(uint32_t))) 641 return 0; 642 643 /* FIXME: Sanity check node? */ 644 645 return propval_cell(reg); 646 } 647 648 static int cmp_reserve_info(const void *ax, const void *bx) 649 { 650 const struct reserve_info *a, *b; 651 652 a = *((const struct reserve_info * const *)ax); 653 b = *((const struct reserve_info * const *)bx); 654 655 if (a->address < b->address) 656 return -1; 657 else if (a->address > b->address) 658 return 1; 659 else if (a->size < b->size) 660 return -1; 661 else if (a->size > b->size) 662 return 1; 663 else 664 return 0; 665 } 666 667 static void sort_reserve_entries(struct dt_info *dti) 668 { 669 struct reserve_info *ri, **tbl; 670 int n = 0, i = 0; 671 672 for (ri = dti->reservelist; 673 ri; 674 ri = ri->next) 675 n++; 676 677 if (n == 0) 678 return; 679 680 tbl = xmalloc(n * sizeof(*tbl)); 681 682 for (ri = dti->reservelist; 683 ri; 684 ri = ri->next) 685 tbl[i++] = ri; 686 687 qsort(tbl, n, sizeof(*tbl), cmp_reserve_info); 688 689 dti->reservelist = tbl[0]; 690 for (i = 0; i < (n-1); i++) 691 tbl[i]->next = tbl[i+1]; 692 tbl[n-1]->next = NULL; 693 694 free(tbl); 695 } 696 697 static int cmp_prop(const void *ax, const void *bx) 698 { 699 const struct property *a, *b; 700 701 a = *((const struct property * const *)ax); 702 b = *((const struct property * const *)bx); 703 704 return strcmp(a->name, b->name); 705 } 706 707 static void sort_properties(struct node *node) 708 { 709 int n = 0, i = 0; 710 struct property *prop, **tbl; 711 712 for_each_property_withdel(node, prop) 713 n++; 714 715 if (n == 0) 716 return; 717 718 tbl = xmalloc(n * sizeof(*tbl)); 719 720 for_each_property_withdel(node, prop) 721 tbl[i++] = prop; 722 723 qsort(tbl, n, sizeof(*tbl), cmp_prop); 724 725 node->proplist = tbl[0]; 726 for (i = 0; i < (n-1); i++) 727 tbl[i]->next = tbl[i+1]; 728 tbl[n-1]->next = NULL; 729 730 free(tbl); 731 } 732 733 static int cmp_subnode(const void *ax, const void *bx) 734 { 735 const struct node *a, *b; 736 737 a = *((const struct node * const *)ax); 738 b = *((const struct node * const *)bx); 739 740 return strcmp(a->name, b->name); 741 } 742 743 static void sort_subnodes(struct node *node) 744 { 745 int n = 0, i = 0; 746 struct node *subnode, **tbl; 747 748 for_each_child_withdel(node, subnode) 749 n++; 750 751 if (n == 0) 752 return; 753 754 tbl = xmalloc(n * sizeof(*tbl)); 755 756 for_each_child_withdel(node, subnode) 757 tbl[i++] = subnode; 758 759 qsort(tbl, n, sizeof(*tbl), cmp_subnode); 760 761 node->children = tbl[0]; 762 for (i = 0; i < (n-1); i++) 763 tbl[i]->next_sibling = tbl[i+1]; 764 tbl[n-1]->next_sibling = NULL; 765 766 free(tbl); 767 } 768 769 static void sort_node(struct node *node) 770 { 771 struct node *c; 772 773 sort_properties(node); 774 sort_subnodes(node); 775 for_each_child_withdel(node, c) 776 sort_node(c); 777 } 778 779 void sort_tree(struct dt_info *dti) 780 { 781 sort_reserve_entries(dti); 782 sort_node(dti->dt); 783 } 784 785 /* utility helper to avoid code duplication */ 786 static struct node *build_and_name_child_node(struct node *parent, char *name) 787 { 788 struct node *node; 789 790 node = build_node(NULL, NULL, NULL); 791 name_node(node, xstrdup(name)); 792 add_child(parent, node); 793 794 return node; 795 } 796 797 static struct node *build_root_node(struct node *dt, char *name) 798 { 799 struct node *an; 800 801 an = get_subnode(dt, name); 802 if (!an) 803 an = build_and_name_child_node(dt, name); 804 805 if (!an) 806 die("Could not build root node /%s\n", name); 807 808 return an; 809 } 810 811 static bool any_label_tree(struct dt_info *dti, struct node *node) 812 { 813 struct node *c; 814 815 if (node->labels) 816 return true; 817 818 for_each_child(node, c) 819 if (any_label_tree(dti, c)) 820 return true; 821 822 return false; 823 } 824 825 static void generate_label_tree_internal(struct dt_info *dti, 826 struct node *an, struct node *node, 827 bool allocph) 828 { 829 struct node *dt = dti->dt; 830 struct node *c; 831 struct property *p; 832 struct label *l; 833 834 /* if there are labels */ 835 if (node->labels) { 836 837 /* now add the label in the node */ 838 for_each_label(node->labels, l) { 839 840 /* check whether the label already exists */ 841 p = get_property(an, l->label); 842 if (p) { 843 fprintf(stderr, "WARNING: label %s already" 844 " exists in /%s", l->label, 845 an->name); 846 continue; 847 } 848 849 /* insert it */ 850 p = build_property(l->label, 851 data_copy_escape_string(node->fullpath, 852 strlen(node->fullpath)), 853 NULL); 854 add_property(an, p); 855 } 856 857 /* force allocation of a phandle for this node */ 858 if (allocph) 859 (void)get_node_phandle(dt, node); 860 } 861 862 for_each_child(node, c) 863 generate_label_tree_internal(dti, an, c, allocph); 864 } 865 866 static bool any_fixup_tree(struct dt_info *dti, struct node *node) 867 { 868 struct node *c; 869 struct property *prop; 870 struct marker *m; 871 872 for_each_property(node, prop) { 873 m = prop->val.markers; 874 for_each_marker_of_type(m, REF_PHANDLE) { 875 if (!get_node_by_ref(dti->dt, m->ref)) 876 return true; 877 } 878 } 879 880 for_each_child(node, c) { 881 if (any_fixup_tree(dti, c)) 882 return true; 883 } 884 885 return false; 886 } 887 888 static void add_fixup_entry(struct dt_info *dti, struct node *fn, 889 struct node *node, struct property *prop, 890 struct marker *m) 891 { 892 char *entry; 893 894 /* m->ref can only be a REF_PHANDLE, but check anyway */ 895 assert(m->type == REF_PHANDLE); 896 897 /* there shouldn't be any ':' in the arguments */ 898 if (strchr(node->fullpath, ':') || strchr(prop->name, ':')) 899 die("arguments should not contain ':'\n"); 900 901 xasprintf(&entry, "%s:%s:%u", 902 node->fullpath, prop->name, m->offset); 903 append_to_property(fn, m->ref, entry, strlen(entry) + 1, TYPE_STRING); 904 905 free(entry); 906 } 907 908 static void generate_fixups_tree_internal(struct dt_info *dti, 909 struct node *fn, 910 struct node *node) 911 { 912 struct node *dt = dti->dt; 913 struct node *c; 914 struct property *prop; 915 struct marker *m; 916 struct node *refnode; 917 918 for_each_property(node, prop) { 919 m = prop->val.markers; 920 for_each_marker_of_type(m, REF_PHANDLE) { 921 refnode = get_node_by_ref(dt, m->ref); 922 if (!refnode) 923 add_fixup_entry(dti, fn, node, prop, m); 924 } 925 } 926 927 for_each_child(node, c) 928 generate_fixups_tree_internal(dti, fn, c); 929 } 930 931 static bool any_local_fixup_tree(struct dt_info *dti, struct node *node) 932 { 933 struct node *c; 934 struct property *prop; 935 struct marker *m; 936 937 for_each_property(node, prop) { 938 m = prop->val.markers; 939 for_each_marker_of_type(m, REF_PHANDLE) { 940 if (get_node_by_ref(dti->dt, m->ref)) 941 return true; 942 } 943 } 944 945 for_each_child(node, c) { 946 if (any_local_fixup_tree(dti, c)) 947 return true; 948 } 949 950 return false; 951 } 952 953 static void add_local_fixup_entry(struct dt_info *dti, 954 struct node *lfn, struct node *node, 955 struct property *prop, struct marker *m, 956 struct node *refnode) 957 { 958 struct node *wn, *nwn; /* local fixup node, walk node, new */ 959 fdt32_t value_32; 960 char **compp; 961 int i, depth; 962 963 /* walk back retrieving depth */ 964 depth = 0; 965 for (wn = node; wn; wn = wn->parent) 966 depth++; 967 968 /* allocate name array */ 969 compp = xmalloc(sizeof(*compp) * depth); 970 971 /* store names in the array */ 972 for (wn = node, i = depth - 1; wn; wn = wn->parent, i--) 973 compp[i] = wn->name; 974 975 /* walk the path components creating nodes if they don't exist */ 976 for (wn = lfn, i = 1; i < depth; i++, wn = nwn) { 977 /* if no node exists, create it */ 978 nwn = get_subnode(wn, compp[i]); 979 if (!nwn) 980 nwn = build_and_name_child_node(wn, compp[i]); 981 } 982 983 free(compp); 984 985 value_32 = cpu_to_fdt32(m->offset); 986 append_to_property(wn, prop->name, &value_32, sizeof(value_32), TYPE_UINT32); 987 } 988 989 static void generate_local_fixups_tree_internal(struct dt_info *dti, 990 struct node *lfn, 991 struct node *node) 992 { 993 struct node *dt = dti->dt; 994 struct node *c; 995 struct property *prop; 996 struct marker *m; 997 struct node *refnode; 998 999 for_each_property(node, prop) { 1000 m = prop->val.markers; 1001 for_each_marker_of_type(m, REF_PHANDLE) { 1002 refnode = get_node_by_ref(dt, m->ref); 1003 if (refnode) 1004 add_local_fixup_entry(dti, lfn, node, prop, m, refnode); 1005 } 1006 } 1007 1008 for_each_child(node, c) 1009 generate_local_fixups_tree_internal(dti, lfn, c); 1010 } 1011 1012 void generate_label_tree(struct dt_info *dti, char *name, bool allocph) 1013 { 1014 if (!any_label_tree(dti, dti->dt)) 1015 return; 1016 generate_label_tree_internal(dti, build_root_node(dti->dt, name), 1017 dti->dt, allocph); 1018 } 1019 1020 void generate_fixups_tree(struct dt_info *dti, char *name) 1021 { 1022 if (!any_fixup_tree(dti, dti->dt)) 1023 return; 1024 generate_fixups_tree_internal(dti, build_root_node(dti->dt, name), 1025 dti->dt); 1026 } 1027 1028 void generate_local_fixups_tree(struct dt_info *dti, char *name) 1029 { 1030 if (!any_local_fixup_tree(dti, dti->dt)) 1031 return; 1032 generate_local_fixups_tree_internal(dti, build_root_node(dti->dt, name), 1033 dti->dt); 1034 } 1035
Indexes created Tue Jun 16 00:25:01 UTC 2026