L4Re/departure

libext2fs/lib/libsupport/dict.c

617:2733e5770ee9
9 months ago Paul Boddie Made the run command wait for completion, introducing the spawn command to run programs in the background. Introduced conveniences for waiting for the last job to be initiated and for piping from the last job, also subscribing to signals from pipe-supplying jobs so that they may be transparently removed from the job list upon completion. Augmented the job listing with the "+" notation familiar from Unix. Prevented new jobs from being started when no job slots are available.
     1 /*     2  * Dictionary Abstract Data Type     3  * Copyright (C) 1997 Kaz Kylheku <kaz@ashi.footprints.net>     4  *     5  * Free Software License:     6  *     7  * All rights are reserved by the author, with the following exceptions:     8  * Permission is granted to freely reproduce and distribute this software,     9  * possibly in exchange for a fee, provided that this copyright notice appears    10  * intact. Permission is also granted to adapt this software to produce    11  * derivative works, as long as the modified versions carry this copyright    12  * notice and additional notices stating that the work has been modified.    13  * This source code may be translated into executable form and incorporated    14  * into proprietary software; there is no requirement for such software to    15  * contain a copyright notice related to this source.    16  *    17  * $Id: dict.c,v 1.40.2.7 2000/11/13 01:36:44 kaz Exp $    18  * $Name: kazlib_1_20 $    19  */    20     21 #define DICT_NODEBUG    22     23 #ifdef __GNUC__    24 #define EXT2FS_ATTR(x) __attribute__(x)    25 #else    26 #define EXT2FS_ATTR(x)    27 #endif    28     29 #include "config.h"    30 #include <stdlib.h>    31 #include <stddef.h>    32 #ifdef DICT_NODEBUG    33 #define dict_assert(x)    34 #else    35 #include <assert.h>    36 #define dict_assert(x) assert(x)    37 #endif    38 #define DICT_IMPLEMENTATION    39 #include "dict.h"    40     41 #ifdef KAZLIB_RCSID    42 static const char rcsid[] = "$Id: dict.c,v 1.40.2.7 2000/11/13 01:36:44 kaz Exp $";    43 #endif    44     45 /*    46  * These macros provide short convenient names for structure members,    47  * which are embellished with dict_ prefixes so that they are    48  * properly confined to the documented namespace. It's legal for a    49  * program which uses dict to define, for instance, a macro called ``parent''.    50  * Such a macro would interfere with the dnode_t struct definition.    51  * In general, highly portable and reusable C modules which expose their    52  * structures need to confine structure member names to well-defined spaces.    53  * The resulting identifiers aren't necessarily convenient to use, nor    54  * readable, in the implementation, however!    55  */    56     57 #define left dict_left    58 #define right dict_right    59 #define parent dict_parent    60 #define color dict_color    61 #define key dict_key    62 #define data dict_data    63     64 #define nilnode dict_nilnode    65 #define nodecount dict_nodecount    66 #define maxcount dict_maxcount    67 #define compare dict_compare    68 #define allocnode dict_allocnode    69 #define freenode dict_freenode    70 #define context dict_context    71 #define dupes dict_dupes    72     73 #define dictptr dict_dictptr    74     75 #define dict_root(D) ((D)->nilnode.left)    76 #define dict_nil(D) (&(D)->nilnode)    77 #define DICT_DEPTH_MAX 64    78     79 static dnode_t *dnode_alloc(void *context);    80 static void dnode_free(dnode_t *node, void *context);    81     82 /*    83  * Perform a ``left rotation'' adjustment on the tree.  The given node P and    84  * its right child C are rearranged so that the P instead becomes the left    85  * child of C.   The left subtree of C is inherited as the new right subtree    86  * for P.  The ordering of the keys within the tree is thus preserved.    87  */    88     89 static void rotate_left(dnode_t *upper)    90 {    91     dnode_t *lower, *lowleft, *upparent;    92     93     lower = upper->right;    94     upper->right = lowleft = lower->left;    95     lowleft->parent = upper;    96     97     lower->parent = upparent = upper->parent;    98     99     /* don't need to check for root node here because root->parent is   100        the sentinel nil node, and root->parent->left points back to root */   101    102     if (upper == upparent->left) {   103 	upparent->left = lower;   104     } else {   105 	dict_assert (upper == upparent->right);   106 	upparent->right = lower;   107     }   108    109     lower->left = upper;   110     upper->parent = lower;   111 }   112    113 /*   114  * This operation is the ``mirror'' image of rotate_left. It is   115  * the same procedure, but with left and right interchanged.   116  */   117    118 static void rotate_right(dnode_t *upper)   119 {   120     dnode_t *lower, *lowright, *upparent;   121    122     lower = upper->left;   123     upper->left = lowright = lower->right;   124     lowright->parent = upper;   125    126     lower->parent = upparent = upper->parent;   127    128     if (upper == upparent->right) {   129 	upparent->right = lower;   130     } else {   131 	dict_assert (upper == upparent->left);   132 	upparent->left = lower;   133     }   134    135     lower->right = upper;   136     upper->parent = lower;   137 }   138    139 /*   140  * Do a postorder traversal of the tree rooted at the specified   141  * node and free everything under it.  Used by dict_free().   142  */   143    144 static void free_nodes(dict_t *dict, dnode_t *node, dnode_t *nil)   145 {   146     if (node == nil)   147 	return;   148     free_nodes(dict, node->left, nil);   149     free_nodes(dict, node->right, nil);   150     dict->freenode(node, dict->context);   151 }   152    153 /*   154  * This procedure performs a verification that the given subtree is a binary   155  * search tree. It performs an inorder traversal of the tree using the   156  * dict_next() successor function, verifying that the key of each node is   157  * strictly lower than that of its successor, if duplicates are not allowed,   158  * or lower or equal if duplicates are allowed.  This function is used for   159  * debugging purposes.   160  */   161 #ifndef DICT_NODEBUG   162 static int verify_bintree(dict_t *dict)   163 {   164     dnode_t *first, *next;   165    166     first = dict_first(dict);   167    168     if (dict->dupes) {   169 	while (first && (next = dict_next(dict, first))) {   170 	    if (dict->compare(first->key, next->key) > 0)   171 		return 0;   172 	    first = next;   173 	}   174     } else {   175 	while (first && (next = dict_next(dict, first))) {   176 	    if (dict->compare(first->key, next->key) >= 0)   177 		return 0;   178 	    first = next;   179 	}   180     }   181     return 1;   182 }   183    184 /*   185  * This function recursively verifies that the given binary subtree satisfies   186  * three of the red black properties. It checks that every red node has only   187  * black children. It makes sure that each node is either red or black. And it   188  * checks that every path has the same count of black nodes from root to leaf.   189  * It returns the blackheight of the given subtree; this allows blackheights to   190  * be computed recursively and compared for left and right siblings for   191  * mismatches. It does not check for every nil node being black, because there   192  * is only one sentinel nil node. The return value of this function is the   193  * black height of the subtree rooted at the node ``root'', or zero if the   194  * subtree is not red-black.   195  */   196    197 static unsigned int verify_redblack(dnode_t *nil, dnode_t *root)   198 {   199     unsigned height_left, height_right;   200    201     if (root != nil) {   202 	height_left = verify_redblack(nil, root->left);   203 	height_right = verify_redblack(nil, root->right);   204 	if (height_left == 0 || height_right == 0)   205 	    return 0;   206 	if (height_left != height_right)   207 	    return 0;   208 	if (root->color == dnode_red) {   209 	    if (root->left->color != dnode_black)   210 		return 0;   211 	    if (root->right->color != dnode_black)   212 		return 0;   213 	    return height_left;   214 	}   215 	if (root->color != dnode_black)   216 	    return 0;   217 	return height_left + 1;   218     }   219     return 1;   220 }   221    222 /*   223  * Compute the actual count of nodes by traversing the tree and   224  * return it. This could be compared against the stored count to   225  * detect a mismatch.   226  */   227    228 static dictcount_t verify_node_count(dnode_t *nil, dnode_t *root)   229 {   230     if (root == nil)   231 	return 0;   232     else   233 	return 1 + verify_node_count(nil, root->left)   234 	    + verify_node_count(nil, root->right);   235 }   236 #endif   237    238 /*   239  * Verify that the tree contains the given node. This is done by   240  * traversing all of the nodes and comparing their pointers to the   241  * given pointer. Returns 1 if the node is found, otherwise   242  * returns zero. It is intended for debugging purposes.   243  */   244    245 static int verify_dict_has_node(dnode_t *nil, dnode_t *root, dnode_t *node)   246 {   247     if (root != nil) {   248 	return root == node   249 		|| verify_dict_has_node(nil, root->left, node)   250 		|| verify_dict_has_node(nil, root->right, node);   251     }   252     return 0;   253 }   254    255    256 #ifdef E2FSCK_NOTUSED   257 /*   258  * Dynamically allocate and initialize a dictionary object.   259  */   260    261 dict_t *dict_create(dictcount_t maxcount, dict_comp_t comp)   262 {   263     dict_t *new = malloc(sizeof *new);   264    265     if (new) {   266 	new->compare = comp;   267 	new->allocnode = dnode_alloc;   268 	new->freenode = dnode_free;   269 	new->context = NULL;   270 	new->cmp_ctx = NULL;   271 	new->nodecount = 0;   272 	new->maxcount = maxcount;   273 	new->nilnode.left = &new->nilnode;   274 	new->nilnode.right = &new->nilnode;   275 	new->nilnode.parent = &new->nilnode;   276 	new->nilnode.color = dnode_black;   277 	new->dupes = 0;   278     }   279     return new;   280 }   281 #endif /* E2FSCK_NOTUSED */   282    283 /*   284  * Select a different set of node allocator routines.   285  */   286    287 void dict_set_allocator(dict_t *dict, dnode_alloc_t al,   288 	dnode_free_t fr, void *context)   289 {   290     dict_assert (dict_count(dict) == 0);   291     dict_assert ((al == NULL && fr == NULL) || (al != NULL && fr != NULL));   292    293     dict->allocnode = al ? al : dnode_alloc;   294     dict->freenode = fr ? fr : dnode_free;   295     dict->context = context;   296 }   297    298 void dict_set_cmp_context(dict_t *dict, void *cmp_ctx)   299 {   300     dict_assert (!dict->cmp_ctx);   301     dict_assert (dict_count(dict) == 0);   302    303     dict->cmp_ctx = cmp_ctx;   304 }   305    306 #ifdef E2FSCK_NOTUSED   307 /*   308  * Free a dynamically allocated dictionary object. Removing the nodes   309  * from the tree before deleting it is required.   310  */   311    312 void dict_destroy(dict_t *dict)   313 {   314     dict_assert (dict_isempty(dict));   315     free(dict);   316 }   317 #endif   318    319 /*   320  * Free all the nodes in the dictionary by using the dictionary's   321  * installed free routine. The dictionary is emptied.   322  */   323    324 void dict_free_nodes(dict_t *dict)   325 {   326     dnode_t *nil = dict_nil(dict), *root = dict_root(dict);   327     free_nodes(dict, root, nil);   328     dict->nodecount = 0;   329     dict->nilnode.left = &dict->nilnode;   330     dict->nilnode.right = &dict->nilnode;   331 }   332    333 #ifdef E2FSCK_NOTUSED   334 /*   335  * Obsolescent function, equivalent to dict_free_nodes   336  */   337 void dict_free(dict_t *dict)   338 {   339 #ifdef KAZLIB_OBSOLESCENT_DEBUG   340     dict_assert ("call to obsolescent function dict_free()" && 0);   341 #endif   342     dict_free_nodes(dict);   343 }   344 #endif   345    346 /*   347  * Initialize a user-supplied dictionary object.   348  */   349    350 dict_t *dict_init(dict_t *dict, dictcount_t maxcount, dict_comp_t comp)   351 {   352     dict->compare = comp;   353     dict->allocnode = dnode_alloc;   354     dict->freenode = dnode_free;   355     dict->context = NULL;   356     dict->nodecount = 0;   357     dict->maxcount = maxcount;   358     dict->nilnode.left = &dict->nilnode;   359     dict->nilnode.right = &dict->nilnode;   360     dict->nilnode.parent = &dict->nilnode;   361     dict->nilnode.color = dnode_black;   362     dict->dupes = 0;   363     return dict;   364 }   365    366 #ifdef E2FSCK_NOTUSED   367 /*   368  * Initialize a dictionary in the likeness of another dictionary   369  */   370    371 void dict_init_like(dict_t *dict, const dict_t *template)   372 {   373     dict->compare = template->compare;   374     dict->allocnode = template->allocnode;   375     dict->freenode = template->freenode;   376     dict->context = template->context;   377     dict->nodecount = 0;   378     dict->maxcount = template->maxcount;   379     dict->nilnode.left = &dict->nilnode;   380     dict->nilnode.right = &dict->nilnode;   381     dict->nilnode.parent = &dict->nilnode;   382     dict->nilnode.color = dnode_black;   383     dict->dupes = template->dupes;   384    385     dict_assert (dict_similar(dict, template));   386 }   387    388 /*   389  * Remove all nodes from the dictionary (without freeing them in any way).   390  */   391    392 static void dict_clear(dict_t *dict)   393 {   394     dict->nodecount = 0;   395     dict->nilnode.left = &dict->nilnode;   396     dict->nilnode.right = &dict->nilnode;   397     dict->nilnode.parent = &dict->nilnode;   398     dict_assert (dict->nilnode.color == dnode_black);   399 }   400 #endif /* E2FSCK_NOTUSED */   401    402    403 /*   404  * Verify the integrity of the dictionary structure.  This is provided for   405  * debugging purposes, and should be placed in assert statements.   Just because   406  * this function succeeds doesn't mean that the tree is not corrupt. Certain   407  * corruptions in the tree may simply cause undefined behavior.   408  */   409 #ifndef DICT_NODEBUG   410 int dict_verify(dict_t *dict)   411 {   412     dnode_t *nil = dict_nil(dict), *root = dict_root(dict);   413    414     /* check that the sentinel node and root node are black */   415     if (root->color != dnode_black)   416 	return 0;   417     if (nil->color != dnode_black)   418 	return 0;   419     if (nil->right != nil)   420 	return 0;   421     /* nil->left is the root node; check that its parent pointer is nil */   422     if (nil->left->parent != nil)   423 	return 0;   424     /* perform a weak test that the tree is a binary search tree */   425     if (!verify_bintree(dict))   426 	return 0;   427     /* verify that the tree is a red-black tree */   428     if (!verify_redblack(nil, root))   429 	return 0;   430     if (verify_node_count(nil, root) != dict_count(dict))   431 	return 0;   432     return 1;   433 }   434 #endif /* DICT_NODEBUG */   435    436 #ifdef E2FSCK_NOTUSED   437 /*   438  * Determine whether two dictionaries are similar: have the same comparison and   439  * allocator functions, and same status as to whether duplicates are allowed.   440  */   441 int dict_similar(const dict_t *left, const dict_t *right)   442 {   443     if (left->compare != right->compare)   444 	return 0;   445    446     if (left->allocnode != right->allocnode)   447 	return 0;   448    449     if (left->freenode != right->freenode)   450 	return 0;   451    452     if (left->context != right->context)   453 	return 0;   454    455     if (left->dupes != right->dupes)   456 	return 0;   457    458     return 1;   459 }   460 #endif /* E2FSCK_NOTUSED */   461    462 /*   463  * Locate a node in the dictionary having the given key.   464  * If the node is not found, a null a pointer is returned (rather than   465  * a pointer that dictionary's nil sentinel node), otherwise a pointer to the   466  * located node is returned.   467  */   468    469 dnode_t *dict_lookup(dict_t *dict, const void *key)   470 {   471     dnode_t *root = dict_root(dict);   472     dnode_t *nil = dict_nil(dict);   473     dnode_t *saved;   474     int result;   475    476     /* simple binary search adapted for trees that contain duplicate keys */   477    478     while (root != nil) {   479 	result = dict->compare(dict->cmp_ctx, key, root->key);   480 	if (result < 0)   481 	    root = root->left;   482 	else if (result > 0)   483 	    root = root->right;   484 	else {   485 	    if (!dict->dupes) {	/* no duplicates, return match		*/   486 		return root;   487 	    } else {		/* could be dupes, find leftmost one	*/   488 		do {   489 		    saved = root;   490 		    root = root->left;   491 		    while (root != nil   492 			   && dict->compare(dict->cmp_ctx, key, root->key))   493 			root = root->right;   494 		} while (root != nil);   495 		return saved;   496 	    }   497 	}   498     }   499    500     return NULL;   501 }   502    503 #ifdef E2FSCK_NOTUSED   504 /*   505  * Look for the node corresponding to the lowest key that is equal to or   506  * greater than the given key.  If there is no such node, return null.   507  */   508    509 dnode_t *dict_lower_bound(dict_t *dict, const void *key)   510 {   511     dnode_t *root = dict_root(dict);   512     dnode_t *nil = dict_nil(dict);   513     dnode_t *tentative = 0;   514    515     while (root != nil) {   516 	int result = dict->compare(dict->cmp_ctx, key, root->key);   517    518 	if (result > 0) {   519 	    root = root->right;   520 	} else if (result < 0) {   521 	    tentative = root;   522 	    root = root->left;   523 	} else {   524 	    if (!dict->dupes) {   525 	    	return root;   526 	    } else {   527 		tentative = root;   528 		root = root->left;   529 	    }   530 	}   531     }   532    533     return tentative;   534 }   535    536 /*   537  * Look for the node corresponding to the greatest key that is equal to or   538  * lower than the given key.  If there is no such node, return null.   539  */   540    541 dnode_t *dict_upper_bound(dict_t *dict, const void *key)   542 {   543     dnode_t *root = dict_root(dict);   544     dnode_t *nil = dict_nil(dict);   545     dnode_t *tentative = 0;   546    547     while (root != nil) {   548 	int result = dict->compare(dict->cmp_ctx, key, root->key);   549    550 	if (result < 0) {   551 	    root = root->left;   552 	} else if (result > 0) {   553 	    tentative = root;   554 	    root = root->right;   555 	} else {   556 	    if (!dict->dupes) {   557 	    	return root;   558 	    } else {   559 		tentative = root;   560 		root = root->right;   561 	    }   562 	}   563     }   564    565     return tentative;   566 }   567 #endif   568    569 /*   570  * Insert a node into the dictionary. The node should have been   571  * initialized with a data field. All other fields are ignored.   572  * The behavior is undefined if the user attempts to insert into   573  * a dictionary that is already full (for which the dict_isfull()   574  * function returns true).   575  */   576    577 void dict_insert(dict_t *dict, dnode_t *node, const void *key)   578 {   579     dnode_t *where = dict_root(dict), *nil = dict_nil(dict);   580     dnode_t *parent = nil, *uncle, *grandpa;   581     int result = -1;   582    583     node->key = key;   584    585     dict_assert (!dict_isfull(dict));   586     dict_assert (!dict_contains(dict, node));   587     dict_assert (!dnode_is_in_a_dict(node));   588    589     /* basic binary tree insert */   590    591     while (where != nil) {   592 	parent = where;   593 	result = dict->compare(dict->cmp_ctx, key, where->key);   594 	/* trap attempts at duplicate key insertion unless it's explicitly allowed */   595 	dict_assert (dict->dupes || result != 0);   596 	if (result < 0)   597 	    where = where->left;   598 	else   599 	    where = where->right;   600     }   601    602     dict_assert (where == nil);   603    604     if (result < 0)   605 	parent->left = node;   606     else   607 	parent->right = node;   608    609     node->parent = parent;   610     node->left = nil;   611     node->right = nil;   612    613     dict->nodecount++;   614    615     /* red black adjustments */   616    617     node->color = dnode_red;   618    619     while (parent->color == dnode_red) {   620 	grandpa = parent->parent;   621 	if (parent == grandpa->left) {   622 	    uncle = grandpa->right;   623 	    if (uncle->color == dnode_red) {	/* red parent, red uncle */   624 		parent->color = dnode_black;   625 		uncle->color = dnode_black;   626 		grandpa->color = dnode_red;   627 		node = grandpa;   628 		parent = grandpa->parent;   629 	    } else {				/* red parent, black uncle */   630 	    	if (node == parent->right) {   631 		    rotate_left(parent);   632 		    parent = node;   633 		    dict_assert (grandpa == parent->parent);   634 		    /* rotation between parent and child preserves grandpa */   635 		}   636 		parent->color = dnode_black;   637 		grandpa->color = dnode_red;   638 		rotate_right(grandpa);   639 		break;   640 	    }   641 	} else { 	/* symmetric cases: parent == parent->parent->right */   642 	    uncle = grandpa->left;   643 	    if (uncle->color == dnode_red) {   644 		parent->color = dnode_black;   645 		uncle->color = dnode_black;   646 		grandpa->color = dnode_red;   647 		node = grandpa;   648 		parent = grandpa->parent;   649 	    } else {   650 	    	if (node == parent->left) {   651 		    rotate_right(parent);   652 		    parent = node;   653 		    dict_assert (grandpa == parent->parent);   654 		}   655 		parent->color = dnode_black;   656 		grandpa->color = dnode_red;   657 		rotate_left(grandpa);   658 		break;   659 	    }   660 	}   661     }   662    663     dict_root(dict)->color = dnode_black;   664    665     dict_assert (dict_verify(dict));   666 }   667    668 #ifdef E2FSCK_NOTUSED   669 /*   670  * Delete the given node from the dictionary. If the given node does not belong   671  * to the given dictionary, undefined behavior results.  A pointer to the   672  * deleted node is returned.   673  */   674    675 dnode_t *dict_delete(dict_t *dict, dnode_t *delete)   676 {   677     dnode_t *nil = dict_nil(dict), *child, *delparent = delete->parent;   678    679     /* basic deletion */   680    681     dict_assert (!dict_isempty(dict));   682     dict_assert (dict_contains(dict, delete));   683    684     /*   685      * If the node being deleted has two children, then we replace it with its   686      * successor (i.e. the leftmost node in the right subtree.) By doing this,   687      * we avoid the traditional algorithm under which the successor's key and   688      * value *only* move to the deleted node and the successor is spliced out   689      * from the tree. We cannot use this approach because the user may hold   690      * pointers to the successor, or nodes may be inextricably tied to some   691      * other structures by way of embedding, etc. So we must splice out the   692      * node we are given, not some other node, and must not move contents from   693      * one node to another behind the user's back.   694      */   695    696     if (delete->left != nil && delete->right != nil) {   697 	dnode_t *next = dict_next(dict, delete);   698 	dnode_t *nextparent = next->parent;   699 	dnode_color_t nextcolor = next->color;   700    701 	dict_assert (next != nil);   702 	dict_assert (next->parent != nil);   703 	dict_assert (next->left == nil);   704    705 	/*   706 	 * First, splice out the successor from the tree completely, by   707 	 * moving up its right child into its place.   708 	 */   709    710 	child = next->right;   711 	child->parent = nextparent;   712    713 	if (nextparent->left == next) {   714 	    nextparent->left = child;   715 	} else {   716 	    dict_assert (nextparent->right == next);   717 	    nextparent->right = child;   718 	}   719    720 	/*   721 	 * Now that the successor has been extricated from the tree, install it   722 	 * in place of the node that we want deleted.   723 	 */   724    725 	next->parent = delparent;   726 	next->left = delete->left;   727 	next->right = delete->right;   728 	next->left->parent = next;   729 	next->right->parent = next;   730 	next->color = delete->color;   731 	delete->color = nextcolor;   732    733 	if (delparent->left == delete) {   734 	    delparent->left = next;   735 	} else {   736 	    dict_assert (delparent->right == delete);   737 	    delparent->right = next;   738 	}   739    740     } else {   741 	dict_assert (delete != nil);   742 	dict_assert (delete->left == nil || delete->right == nil);   743    744 	child = (delete->left != nil) ? delete->left : delete->right;   745    746 	child->parent = delparent = delete->parent;   747    748 	if (delete == delparent->left) {   749 	    delparent->left = child;   750 	} else {   751 	    dict_assert (delete == delparent->right);   752 	    delparent->right = child;   753 	}   754     }   755    756     delete->parent = NULL;   757     delete->right = NULL;   758     delete->left = NULL;   759    760     dict->nodecount--;   761    762     dict_assert (verify_bintree(dict));   763    764     /* red-black adjustments */   765    766     if (delete->color == dnode_black) {   767 	dnode_t *parent, *sister;   768    769 	dict_root(dict)->color = dnode_red;   770    771 	while (child->color == dnode_black) {   772 	    parent = child->parent;   773 	    if (child == parent->left) {   774 		sister = parent->right;   775 		dict_assert (sister != nil);   776 		if (sister->color == dnode_red) {   777 		    sister->color = dnode_black;   778 		    parent->color = dnode_red;   779 		    rotate_left(parent);   780 		    sister = parent->right;   781 		    dict_assert (sister != nil);   782 		}   783 		if (sister->left->color == dnode_black   784 			&& sister->right->color == dnode_black) {   785 		    sister->color = dnode_red;   786 		    child = parent;   787 		} else {   788 		    if (sister->right->color == dnode_black) {   789 			dict_assert (sister->left->color == dnode_red);   790 			sister->left->color = dnode_black;   791 			sister->color = dnode_red;   792 			rotate_right(sister);   793 			sister = parent->right;   794 			dict_assert (sister != nil);   795 		    }   796 		    sister->color = parent->color;   797 		    sister->right->color = dnode_black;   798 		    parent->color = dnode_black;   799 		    rotate_left(parent);   800 		    break;   801 		}   802 	    } else {	/* symmetric case: child == child->parent->right */   803 		dict_assert (child == parent->right);   804 		sister = parent->left;   805 		dict_assert (sister != nil);   806 		if (sister->color == dnode_red) {   807 		    sister->color = dnode_black;   808 		    parent->color = dnode_red;   809 		    rotate_right(parent);   810 		    sister = parent->left;   811 		    dict_assert (sister != nil);   812 		}   813 		if (sister->right->color == dnode_black   814 			&& sister->left->color == dnode_black) {   815 		    sister->color = dnode_red;   816 		    child = parent;   817 		} else {   818 		    if (sister->left->color == dnode_black) {   819 			dict_assert (sister->right->color == dnode_red);   820 			sister->right->color = dnode_black;   821 			sister->color = dnode_red;   822 			rotate_left(sister);   823 			sister = parent->left;   824 			dict_assert (sister != nil);   825 		    }   826 		    sister->color = parent->color;   827 		    sister->left->color = dnode_black;   828 		    parent->color = dnode_black;   829 		    rotate_right(parent);   830 		    break;   831 		}   832 	    }   833 	}   834    835 	child->color = dnode_black;   836 	dict_root(dict)->color = dnode_black;   837     }   838    839     dict_assert (dict_verify(dict));   840    841     return delete;   842 }   843 #endif /* E2FSCK_NOTUSED */   844    845 /*   846  * Allocate a node using the dictionary's allocator routine, give it   847  * the data item.   848  */   849    850 int dict_alloc_insert(dict_t *dict, const void *key, void *data)   851 {   852     dnode_t *node = dict->allocnode(dict->context);   853    854     if (node) {   855 	dnode_init(node, data);   856 	dict_insert(dict, node, key);   857 	return 1;   858     }   859     return 0;   860 }   861    862 #ifdef E2FSCK_NOTUSED   863 void dict_delete_free(dict_t *dict, dnode_t *node)   864 {   865     dict_delete(dict, node);   866     dict->freenode(node, dict->context);   867 }   868 #endif   869    870 /*   871  * Return the node with the lowest (leftmost) key. If the dictionary is empty   872  * (that is, dict_isempty(dict) returns 1) a null pointer is returned.   873  */   874    875 dnode_t *dict_first(dict_t *dict)   876 {   877     dnode_t *nil = dict_nil(dict), *root = dict_root(dict), *left;   878    879     if (root != nil)   880 	while ((left = root->left) != nil)   881 	    root = left;   882    883     return (root == nil) ? NULL : root;   884 }   885    886 /*   887  * Return the node with the highest (rightmost) key. If the dictionary is empty   888  * (that is, dict_isempty(dict) returns 1) a null pointer is returned.   889  */   890    891 dnode_t *dict_last(dict_t *dict)   892 {   893     dnode_t *nil = dict_nil(dict), *root = dict_root(dict), *right;   894    895     if (root != nil)   896 	while ((right = root->right) != nil)   897 	    root = right;   898    899     return (root == nil) ? NULL : root;   900 }   901    902 /*   903  * Return the given node's successor node---the node which has the   904  * next key in the the left to right ordering. If the node has   905  * no successor, a null pointer is returned rather than a pointer to   906  * the nil node.   907  */   908    909 dnode_t *dict_next(dict_t *dict, dnode_t *curr)   910 {   911     dnode_t *nil = dict_nil(dict), *parent, *left;   912    913     if (curr->right != nil) {   914 	curr = curr->right;   915 	while ((left = curr->left) != nil)   916 	    curr = left;   917 	return curr;   918     }   919    920     parent = curr->parent;   921    922     while (parent != nil && curr == parent->right) {   923 	curr = parent;   924 	parent = curr->parent;   925     }   926    927     return (parent == nil) ? NULL : parent;   928 }   929    930 /*   931  * Return the given node's predecessor, in the key order.   932  * The nil sentinel node is returned if there is no predecessor.   933  */   934    935 dnode_t *dict_prev(dict_t *dict, dnode_t *curr)   936 {   937     dnode_t *nil = dict_nil(dict), *parent, *right;   938    939     if (curr->left != nil) {   940 	curr = curr->left;   941 	while ((right = curr->right) != nil)   942 	    curr = right;   943 	return curr;   944     }   945    946     parent = curr->parent;   947    948     while (parent != nil && curr == parent->left) {   949 	curr = parent;   950 	parent = curr->parent;   951     }   952    953     return (parent == nil) ? NULL : parent;   954 }   955    956 void dict_allow_dupes(dict_t *dict)   957 {   958     dict->dupes = 1;   959 }   960    961 #undef dict_count   962 #undef dict_isempty   963 #undef dict_isfull   964 #undef dnode_get   965 #undef dnode_put   966 #undef dnode_getkey   967    968 dictcount_t dict_count(dict_t *dict)   969 {   970     return dict->nodecount;   971 }   972    973 int dict_isempty(dict_t *dict)   974 {   975     return dict->nodecount == 0;   976 }   977    978 int dict_isfull(dict_t *dict)   979 {   980     return dict->nodecount == dict->maxcount;   981 }   982    983 int dict_contains(dict_t *dict, dnode_t *node)   984 {   985     return verify_dict_has_node(dict_nil(dict), dict_root(dict), node);   986 }   987    988 static dnode_t *dnode_alloc(void *context EXT2FS_ATTR((unused)))   989 {   990     return malloc(sizeof *dnode_alloc(NULL));   991 }   992    993 static void dnode_free(dnode_t *node, void *context EXT2FS_ATTR((unused)))   994 {   995     free(node);   996 }   997    998 dnode_t *dnode_create(void *data)   999 {  1000     dnode_t *new = malloc(sizeof *new);  1001     if (new) {  1002 	new->data = data;  1003 	new->parent = NULL;  1004 	new->left = NULL;  1005 	new->right = NULL;  1006     }  1007     return new;  1008 }  1009   1010 dnode_t *dnode_init(dnode_t *dnode, void *data)  1011 {  1012     dnode->data = data;  1013     dnode->parent = NULL;  1014     dnode->left = NULL;  1015     dnode->right = NULL;  1016     return dnode;  1017 }  1018   1019 void dnode_destroy(dnode_t *dnode)  1020 {  1021     dict_assert (!dnode_is_in_a_dict(dnode));  1022     free(dnode);  1023 }  1024   1025 void *dnode_get(dnode_t *dnode)  1026 {  1027     return dnode->data;  1028 }  1029   1030 const void *dnode_getkey(dnode_t *dnode)  1031 {  1032     return dnode->key;  1033 }  1034   1035 #ifdef E2FSCK_NOTUSED  1036 void dnode_put(dnode_t *dnode, void *data)  1037 {  1038     dnode->data = data;  1039 }  1040 #endif  1041   1042 #ifndef DICT_NODEBUG  1043 int dnode_is_in_a_dict(dnode_t *dnode)  1044 {  1045     return (dnode->parent && dnode->left && dnode->right);  1046 }  1047 #endif  1048   1049 #ifdef E2FSCK_NOTUSED  1050 void dict_process(dict_t *dict, void *context, dnode_process_t function)  1051 {  1052     dnode_t *node = dict_first(dict), *next;  1053   1054     while (node != NULL) {  1055 	/* check for callback function deleting	*/  1056 	/* the next node from under us		*/  1057 	dict_assert (dict_contains(dict, node));  1058 	next = dict_next(dict, node);  1059 	function(dict, node, context);  1060 	node = next;  1061     }  1062 }  1063   1064 static void load_begin_internal(dict_load_t *load, dict_t *dict)  1065 {  1066     load->dictptr = dict;  1067     load->nilnode.left = &load->nilnode;  1068     load->nilnode.right = &load->nilnode;  1069 }  1070   1071 void dict_load_begin(dict_load_t *load, dict_t *dict)  1072 {  1073     dict_assert (dict_isempty(dict));  1074     load_begin_internal(load, dict);  1075 }  1076   1077 void dict_load_next(dict_load_t *load, dnode_t *newnode, const void *key)  1078 {  1079     dict_t *dict = load->dictptr;  1080     dnode_t *nil = &load->nilnode;  1081   1082     dict_assert (!dnode_is_in_a_dict(newnode));  1083     dict_assert (dict->nodecount < dict->maxcount);  1084   1085 #ifndef DICT_NODEBUG  1086     if (dict->nodecount > 0) {  1087 	if (dict->dupes)  1088 	    dict_assert (dict->compare(nil->left->key, key) <= 0);  1089 	else  1090 	    dict_assert (dict->compare(nil->left->key, key) < 0);  1091     }  1092 #endif  1093   1094     newnode->key = key;  1095     nil->right->left = newnode;  1096     nil->right = newnode;  1097     newnode->left = nil;  1098     dict->nodecount++;  1099 }  1100   1101 void dict_load_end(dict_load_t *load)  1102 {  1103     dict_t *dict = load->dictptr;  1104     dnode_t *tree[DICT_DEPTH_MAX] = { 0 };  1105     dnode_t *curr, *dictnil = dict_nil(dict), *loadnil = &load->nilnode, *next;  1106     dnode_t *complete = 0;  1107     dictcount_t fullcount = DICTCOUNT_T_MAX, nodecount = dict->nodecount;  1108     dictcount_t botrowcount;  1109     unsigned baselevel = 0, level = 0, i;  1110   1111     dict_assert (dnode_red == 0 && dnode_black == 1);  1112   1113     while (fullcount >= nodecount && fullcount)  1114 	fullcount >>= 1;  1115   1116     botrowcount = nodecount - fullcount;  1117   1118     for (curr = loadnil->left; curr != loadnil; curr = next) {  1119 	next = curr->left;  1120   1121 	if (complete == NULL && botrowcount-- == 0) {  1122 	    dict_assert (baselevel == 0);  1123 	    dict_assert (level == 0);  1124 	    baselevel = level = 1;  1125 	    complete = tree[0];  1126   1127 	    if (complete != 0) {  1128 		tree[0] = 0;  1129 		complete->right = dictnil;  1130 		while (tree[level] != 0) {  1131 		    tree[level]->right = complete;  1132 		    complete->parent = tree[level];  1133 		    complete = tree[level];  1134 		    tree[level++] = 0;  1135 		}  1136 	    }  1137 	}  1138   1139 	if (complete == NULL) {  1140 	    curr->left = dictnil;  1141 	    curr->right = dictnil;  1142 	    curr->color = level % 2;  1143 	    complete = curr;  1144   1145 	    dict_assert (level == baselevel);  1146 	    while (tree[level] != 0) {  1147 		tree[level]->right = complete;  1148 		complete->parent = tree[level];  1149 		complete = tree[level];  1150 		tree[level++] = 0;  1151 	    }  1152 	} else {  1153 	    curr->left = complete;  1154 	    curr->color = (level + 1) % 2;  1155 	    complete->parent = curr;  1156 	    tree[level] = curr;  1157 	    complete = 0;  1158 	    level = baselevel;  1159 	}  1160     }  1161   1162     if (complete == NULL)  1163 	complete = dictnil;  1164   1165     for (i = 0; i < DICT_DEPTH_MAX; i++) {  1166 	if (tree[i] != 0) {  1167 	    tree[i]->right = complete;  1168 	    complete->parent = tree[i];  1169 	    complete = tree[i];  1170 	}  1171     }  1172   1173     dictnil->color = dnode_black;  1174     dictnil->right = dictnil;  1175     complete->parent = dictnil;  1176     complete->color = dnode_black;  1177     dict_root(dict) = complete;  1178   1179     dict_assert (dict_verify(dict));  1180 }  1181   1182 void dict_merge(dict_t *dest, dict_t *source)  1183 {  1184     dict_load_t load;  1185     dnode_t *leftnode = dict_first(dest), *rightnode = dict_first(source);  1186   1187     dict_assert (dict_similar(dest, source));  1188   1189     if (source == dest)  1190 	return;  1191   1192     dest->nodecount = 0;  1193     load_begin_internal(&load, dest);  1194   1195     for (;;) {  1196 	if (leftnode != NULL && rightnode != NULL) {  1197 	    if (dest->compare(leftnode->key, rightnode->key) < 0)  1198 		goto copyleft;  1199 	    else  1200 		goto copyright;  1201 	} else if (leftnode != NULL) {  1202 	    goto copyleft;  1203 	} else if (rightnode != NULL) {  1204 	    goto copyright;  1205 	} else {  1206 	    dict_assert (leftnode == NULL && rightnode == NULL);  1207 	    break;  1208 	}  1209   1210     copyleft:  1211 	{  1212 	    dnode_t *next = dict_next(dest, leftnode);  1213 #ifndef DICT_NODEBUG  1214 	    leftnode->left = NULL;	/* suppress assertion in dict_load_next */  1215 #endif  1216 	    dict_load_next(&load, leftnode, leftnode->key);  1217 	    leftnode = next;  1218 	    continue;  1219 	}  1220   1221     copyright:  1222 	{  1223 	    dnode_t *next = dict_next(source, rightnode);  1224 #ifndef DICT_NODEBUG  1225 	    rightnode->left = NULL;  1226 #endif  1227 	    dict_load_next(&load, rightnode, rightnode->key);  1228 	    rightnode = next;  1229 	    continue;  1230 	}  1231     }  1232   1233     dict_clear(source);  1234     dict_load_end(&load);  1235 }  1236 #endif /* E2FSCK_NOTUSED */  1237   1238 #ifdef KAZLIB_TEST_MAIN  1239   1240 #include <stdio.h>  1241 #include <string.h>  1242 #include <ctype.h>  1243 #include <stdarg.h>  1244   1245 typedef char input_t[256];  1246   1247 static int tokenize(char *string, ...)  1248 {  1249     char **tokptr;  1250     va_list arglist;  1251     int tokcount = 0;  1252   1253     va_start(arglist, string);  1254     tokptr = va_arg(arglist, char **);  1255     while (tokptr) {  1256 	while (*string && isspace((unsigned char) *string))  1257 	    string++;  1258 	if (!*string)  1259 	    break;  1260 	*tokptr = string;  1261 	while (*string && !isspace((unsigned char) *string))  1262 	    string++;  1263 	tokptr = va_arg(arglist, char **);  1264 	tokcount++;  1265 	if (!*string)  1266 	    break;  1267 	*string++ = 0;  1268     }  1269     va_end(arglist);  1270   1271     return tokcount;  1272 }  1273   1274 static int comparef(const void *cmp_ctx, const void *key1, const void *key2)  1275 {  1276     return strcmp(key1, key2);  1277 }  1278   1279 static char *dupstring(char *str)  1280 {  1281     int sz = strlen(str) + 1;  1282     char *new = malloc(sz);  1283     if (new)  1284 	memcpy(new, str, sz);  1285     return new;  1286 }  1287   1288 static dnode_t *new_node(void *c)  1289 {  1290     static dnode_t few[5];  1291     static int count;  1292   1293     if (count < 5)  1294 	return few + count++;  1295   1296     return NULL;  1297 }  1298   1299 static void del_node(dnode_t *n, void *c)  1300 {  1301 }  1302   1303 static int prompt = 0;  1304   1305 static void construct(dict_t *d)  1306 {  1307     input_t in;  1308     int done = 0;  1309     dict_load_t dl;  1310     dnode_t *dn;  1311     char *tok1, *tok2, *val;  1312     const char *key;  1313     char *help =  1314 	"p                      turn prompt on\n"  1315 	"q                      finish construction\n"  1316 	"a <key> <val>          add new entry\n";  1317   1318     if (!dict_isempty(d))  1319 	puts("warning: dictionary not empty!");  1320   1321     dict_load_begin(&dl, d);  1322   1323     while (!done) {  1324 	if (prompt)  1325 	    putchar('>');  1326 	fflush(stdout);  1327   1328 	if (!fgets(in, sizeof(input_t), stdin))  1329 	    break;  1330   1331 	switch (in[0]) {  1332 	    case '?':  1333 		puts(help);  1334 		break;  1335 	    case 'p':  1336 		prompt = 1;  1337 		break;  1338 	    case 'q':  1339 		done = 1;  1340 		break;  1341 	    case 'a':  1342 		if (tokenize(in+1, &tok1, &tok2, (char **) 0) != 2) {  1343 		    puts("what?");  1344 		    break;  1345 		}  1346 		key = dupstring(tok1);  1347 		val = dupstring(tok2);  1348 		dn = dnode_create(val);  1349   1350 		if (!key || !val || !dn) {  1351 		    puts("out of memory");  1352 		    free((void *) key);  1353 		    free(val);  1354 		    if (dn)  1355 			dnode_destroy(dn);  1356 		}  1357   1358 		dict_load_next(&dl, dn, key);  1359 		break;  1360 	    default:  1361 		putchar('?');  1362 		putchar('\n');  1363 		break;  1364 	}  1365     }  1366   1367     dict_load_end(&dl);  1368 }  1369   1370 int main(void)  1371 {  1372     input_t in;  1373     dict_t darray[10];  1374     dict_t *d = &darray[0];  1375     dnode_t *dn;  1376     int i;  1377     char *tok1, *tok2, *val;  1378     const char *key;  1379   1380     char *help =  1381 	"a <key> <val>          add value to dictionary\n"  1382 	"d <key>                delete value from dictionary\n"  1383 	"l <key>                lookup value in dictionary\n"  1384 	"( <key>                lookup lower bound\n"  1385 	") <key>                lookup upper bound\n"  1386 	"# <num>                switch to alternate dictionary (0-9)\n"  1387 	"j <num> <num>          merge two dictionaries\n"  1388 	"f                      free the whole dictionary\n"  1389 	"k                      allow duplicate keys\n"  1390 	"c                      show number of entries\n"  1391 	"t                      dump whole dictionary in sort order\n"  1392 	"m                      make dictionary out of sorted items\n"  1393 	"p                      turn prompt on\n"  1394 	"s                      switch to non-functioning allocator\n"  1395 	"q                      quit";  1396   1397     for (i = 0; i < sizeof darray / sizeof *darray; i++)  1398 	dict_init(&darray[i], DICTCOUNT_T_MAX, comparef);  1399   1400     for (;;) {  1401 	if (prompt)  1402 	    putchar('>');  1403 	fflush(stdout);  1404   1405 	if (!fgets(in, sizeof(input_t), stdin))  1406 	    break;  1407   1408 	switch(in[0]) {  1409 	    case '?':  1410 		puts(help);  1411 		break;  1412 	    case 'a':  1413 		if (tokenize(in+1, &tok1, &tok2, (char **) 0) != 2) {  1414 		    puts("what?");  1415 		    break;  1416 		}  1417 		key = dupstring(tok1);  1418 		val = dupstring(tok2);  1419   1420 		if (!key || !val) {  1421 		    puts("out of memory");  1422 		    free((void *) key);  1423 		    free(val);  1424 		}  1425   1426 		if (!dict_alloc_insert(d, key, val)) {  1427 		    puts("dict_alloc_insert failed");  1428 		    free((void *) key);  1429 		    free(val);  1430 		    break;  1431 		}  1432 		break;  1433 	    case 'd':  1434 		if (tokenize(in+1, &tok1, (char **) 0) != 1) {  1435 		    puts("what?");  1436 		    break;  1437 		}  1438 		dn = dict_lookup(d, tok1);  1439 		if (!dn) {  1440 		    puts("dict_lookup failed");  1441 		    break;  1442 		}  1443 		val = dnode_get(dn);  1444 		key = dnode_getkey(dn);  1445 		dict_delete_free(d, dn);  1446   1447 		free(val);  1448 		free((void *) key);  1449 		break;  1450 	    case 'f':  1451 		dict_free(d);  1452 		break;  1453 	    case 'l':  1454 	    case '(':  1455 	    case ')':  1456 		if (tokenize(in+1, &tok1, (char **) 0) != 1) {  1457 		    puts("what?");  1458 		    break;  1459 		}  1460 		dn = 0;  1461 		switch (in[0]) {  1462 		case 'l':  1463 		    dn = dict_lookup(d, tok1);  1464 		    break;  1465 		case '(':  1466 		    dn = dict_lower_bound(d, tok1);  1467 		    break;  1468 		case ')':  1469 		    dn = dict_upper_bound(d, tok1);  1470 		    break;  1471 		}  1472 		if (!dn) {  1473 		    puts("lookup failed");  1474 		    break;  1475 		}  1476 		val = dnode_get(dn);  1477 		puts(val);  1478 		break;  1479 	    case 'm':  1480 		construct(d);  1481 		break;  1482 	    case 'k':  1483 		dict_allow_dupes(d);  1484 		break;  1485 	    case 'c':  1486 		printf("%lu\n", (unsigned long) dict_count(d));  1487 		break;  1488 	    case 't':  1489 		for (dn = dict_first(d); dn; dn = dict_next(d, dn)) {  1490 		    printf("%s\t%s\n", (char *) dnode_getkey(dn),  1491 			    (char *) dnode_get(dn));  1492 		}  1493 		break;  1494 	    case 'q':  1495 		exit(0);  1496 		break;  1497 	    case '\0':  1498 		break;  1499 	    case 'p':  1500 		prompt = 1;  1501 		break;  1502 	    case 's':  1503 		dict_set_allocator(d, new_node, del_node, NULL);  1504 		break;  1505 	    case '#':  1506 		if (tokenize(in+1, &tok1, (char **) 0) != 1) {  1507 		    puts("what?");  1508 		    break;  1509 		} else {  1510 		    int dictnum = atoi(tok1);  1511 		    if (dictnum < 0 || dictnum > 9) {  1512 			puts("invalid number");  1513 			break;  1514 		    }  1515 		    d = &darray[dictnum];  1516 		}  1517 		break;  1518 	    case 'j':  1519 		if (tokenize(in+1, &tok1, &tok2, (char **) 0) != 2) {  1520 		    puts("what?");  1521 		    break;  1522 		} else {  1523 		    int dict1 = atoi(tok1), dict2 = atoi(tok2);  1524 		    if (dict1 < 0 || dict1 > 9 || dict2 < 0 || dict2 > 9) {  1525 			puts("invalid number");  1526 			break;  1527 		    }  1528 		    dict_merge(&darray[dict1], &darray[dict2]);  1529 		}  1530 		break;  1531 	    default:  1532 		putchar('?');  1533 		putchar('\n');  1534 		break;  1535 	}  1536     }  1537   1538     return 0;  1539 }  1540   1541 #endif