Tue, 17 Oct 2006 00:32:05 +0200
Path fix
/* Generic C code for red-black trees. Copyright (C) 2000 James S. Plank, 2004 Tuomo Valkonen. This library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. This library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this library; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ /* Revision 1.2. Jim Plank */ /* Original code by Jim Plank (plank@cs.utk.edu) */ /* modified for THINK C 6.0 for Macintosh by Chris Bartley */ #include <string.h> #include <stdio.h> #include <stdlib.h> #include <ctype.h> #include "rb.h" static void mk_new_int(Rb_node l, Rb_node r, Rb_node p, int il); static Rb_node lprev(Rb_node n); static Rb_node rprev(Rb_node n); static void recolor(Rb_node n); static void single_rotate(Rb_node y, int l); static void rb_print_tree(Rb_node t, int level); static void rb_iprint_tree(Rb_node t, int level); /* Gcc complains if non-char* pointer is passed to printf %p */ #define DONT_COMPLAIN (char*) #define isred(n) (n->s.red) #define isblack(n) (!isred(n)) #define isleft(n) (n->s.left) #define isright(n) (!isleft(n)) #define isint(n) (n->s.internal) #define isext(n) (!isint(n)) #define ishead(n) (n->s.head) #define isroot(n) (n->s.root) #define setred(n) n->s.red = 1 #define setblack(n) n->s.red = 0 #define setleft(n) n->s.left = 1 #define setright(n) n->s.left = 0 #define sethead(n) n->s.head = 1 #define setroot(n) n->s.root = 1 #define setint(n) n->s.internal = 1 #define setext(n) n->s.internal = 0 #define setnormal(n) { n->s.root = 0; n ->s.head = 0; } #define sibling(n) ((isleft(n)) ? n->p.parent->c.child.right \ : n->p.parent->c.child.left) static void insert(Rb_node item, Rb_node list) /* Inserts to the end of a list */ { Rb_node last_node; last_node = list->c.list.blink; list->c.list.blink = item; last_node->c.list.flink = item; item->c.list.blink = last_node; item->c.list.flink = list; } static void delete_item(Rb_node item) /* Deletes an arbitrary iterm */ { item->c.list.flink->c.list.blink = item->c.list.blink; item->c.list.blink->c.list.flink = item->c.list.flink; } #define mk_new_ext(new, kkkey, vvval) {\ new = (Rb_node) malloc(sizeof(struct rb_node));\ if(new==NULL) return NULL;\ new->v.val = vvval;\ new->k.key = kkkey;\ setext(new);\ setblack(new);\ setnormal(new);\ } static void mk_new_int(Rb_node l, Rb_node r, Rb_node p, int il) { Rb_node newnode; newnode = (Rb_node) malloc(sizeof(struct rb_node)); setint(newnode); setred(newnode); setnormal(newnode); newnode->c.child.left = l; newnode->c.child.right = r; newnode->p.parent = p; newnode->k.lext = l; newnode->v.rext = r; l->p.parent = newnode; r->p.parent = newnode; setleft(l); setright(r); if (ishead(p)) { p->p.root = newnode; setroot(newnode); } else if (il) { setleft(newnode); p->c.child.left = newnode; } else { setright(newnode); p->c.child.right = newnode; } recolor(newnode); } Rb_node lprev(Rb_node n) { if (ishead(n)) return n; while (!isroot(n)) { if (isright(n)) return n->p.parent; n = n->p.parent; } return n->p.parent; } Rb_node rprev(Rb_node n) { if (ishead(n)) return n; while (!isroot(n)) { if (isleft(n)) return n->p.parent; n = n->p.parent; } return n->p.parent; } Rb_node make_rb() { Rb_node head; head = (Rb_node) malloc (sizeof(struct rb_node)); if(head!=NULL){ head->c.list.flink = head; head->c.list.blink = head; head->p.root = head; head->k.key = ""; sethead(head); } return head; } Rb_node rb_find_ikey_n(Rb_node n, int ikey, int *fnd) { *fnd = 0; if (!ishead(n)) { fprintf(stderr, "rb_find_ikey_n called on non-head %p\n", DONT_COMPLAIN n); exit(1); } if (n->p.root == n) return n; if (ikey == n->c.list.blink->k.ikey) { *fnd = 1; return n->c.list.blink; } if (ikey > n->c.list.blink->k.ikey) return n; else n = n->p.root; while (1) { if (isext(n)) return n; if (ikey == n->k.lext->k.ikey) { *fnd = 1; return n->k.lext; } n = (ikey < n->k.lext->k.ikey) ? n->c.child.left : n->c.child.right; } } Rb_node rb_find_ikey(Rb_node n, int ikey) { int fnd; return rb_find_ikey_n(n, ikey, &fnd); } Rb_node rb_find_gkey_n(Rb_node n, const void *key, Rb_compfn *fxn, int *fnd) { int cmp; *fnd = 0; if (!ishead(n)) { fprintf(stderr, "rb_find_gkey_n called on non-head %p\n", DONT_COMPLAIN n); exit(1); } if (n->p.root == n) return n; cmp = (*fxn)(key, n->c.list.blink->k.key); if (cmp == 0) { *fnd = 1; return n->c.list.blink; } if (cmp > 0) return n; else n = n->p.root; while (1) { if (isext(n)) return n; cmp = (*fxn)(key, n->k.lext->k.key); if (cmp == 0) { *fnd = 1; return n->k.lext; } if (cmp < 0) n = n->c.child.left ; else n = n->c.child.right; } } Rb_node rb_find_gkey(Rb_node n, const void *key, Rb_compfn *fxn) { int fnd; return rb_find_gkey_n(n, key, fxn, &fnd); } Rb_node rb_find_key_n(Rb_node n, const char *key, int *fnd) { return rb_find_gkey_n(n, key, (Rb_compfn*)strcmp, fnd); } Rb_node rb_find_key(Rb_node n, const char *key) { int fnd; return rb_find_gkey_n(n, key, (Rb_compfn*)strcmp, &fnd); } static int ptrcmp(const void *a, const void *b) { return (a<b ? -1 : ((a==b) ? 0 : 1)); } Rb_node rb_find_pkey_n(Rb_node n, const void *key, int *fnd) { return rb_find_gkey_n(n, key, ptrcmp, fnd); } Rb_node rb_find_pkey(Rb_node n, const void *key) { int fnd; return rb_find_gkey_n(n, key, ptrcmp, &fnd); } Rb_node rb_insert_b(Rb_node n, const void *key, void *val) { Rb_node newleft, newright, newnode, list, p; if (ishead(n)) { if (n->p.root == n) { /* Tree is empty */ mk_new_ext(newnode, key, val); insert(newnode, n); n->p.root = newnode; newnode->p.parent = n; setroot(newnode); return newnode; } else { mk_new_ext(newright, key, val); insert(newright, n); newleft = newright->c.list.blink; setnormal(newleft); mk_new_int(newleft, newright, newleft->p.parent, isleft(newleft)); p = rprev(newright); if (!ishead(p)) p->k.lext = newright; return newright; } } else { mk_new_ext(newleft, key, val); insert(newleft, n); setnormal(n); mk_new_int(newleft, n, n->p.parent, isleft(n)); p = lprev(newleft); if (!ishead(p)) p->v.rext = newleft; return newleft; } } static void recolor(Rb_node n) { Rb_node p, gp, s; int done = 0; while(!done) { if (isroot(n)) { setblack(n); return; } p = n->p.parent; if (isblack(p)) return; if (isroot(p)) { setblack(p); return; } gp = p->p.parent; s = sibling(p); if (isred(s)) { setblack(p); setred(gp); setblack(s); n = gp; } else { done = 1; } } /* p's sibling is black, p is red, gp is black */ if ((isleft(n) == 0) == (isleft(p) == 0)) { single_rotate(gp, isleft(n)); setblack(p); setred(gp); } else { single_rotate(p, isleft(n)); single_rotate(gp, isleft(n)); setblack(n); setred(gp); } } static void single_rotate(Rb_node y, int l) { int rl=0, ir=0; Rb_node x=NULL, yp=NULL; void *tmp=NULL; ir = isroot(y); yp = y->p.parent; if (!ir) { rl = isleft(y); } if (l) { x = y->c.child.left; y->c.child.left = x->c.child.right; setleft(y->c.child.left); y->c.child.left->p.parent = y; x->c.child.right = y; setright(y); } else { x = y->c.child.right; y->c.child.right = x->c.child.left; setright(y->c.child.right); y->c.child.right->p.parent = y; x->c.child.left = y; setleft(y); } x->p.parent = yp; y->p.parent = x; if (ir) { yp->p.root = x; setnormal(y); setroot(x); } else { if (rl) { yp->c.child.left = x; setleft(x); } else { yp->c.child.right = x; setright(x); } } } void rb_delete_node(Rb_node n) { Rb_node s, p, gp; char ir; if (isint(n)) { fprintf(stderr, "Cannot delete an internal node: %p\n", DONT_COMPLAIN n); exit(1); } if (ishead(n)) { fprintf(stderr, "Cannot delete the head of an rb_tree: %p\n", DONT_COMPLAIN n); exit(1); } delete_item(n); /* Delete it from the list */ p = n->p.parent; /* The only node */ if (isroot(n)) { p->p.root = p; free(n); return; } s = sibling(n); /* The only node after deletion */ if (isroot(p)) { s->p.parent = p->p.parent; s->p.parent->p.root = s; setroot(s); free(p); free(n); return; } gp = p->p.parent; /* Set parent to sibling */ s->p.parent = gp; if (isleft(p)) { gp->c.child.left = s; setleft(s); } else { gp->c.child.right = s; setright(s); } ir = isred(p); free(p); free(n); if (isext(s)) { /* Update proper rext and lext values */ p = lprev(s); if (!ishead(p)) p->v.rext = s; p = rprev(s); if (!ishead(p)) p->k.lext = s; } else if (isblack(s)) { fprintf(stderr, "DELETION PROB -- sib is black, internal\n"); exit(1); } else { p = lprev(s); if (!ishead(p)) p->v.rext = s->c.child.left; p = rprev(s); if (!ishead(p)) p->k.lext = s->c.child.right; setblack(s); return; } if (ir) return; /* Recolor */ n = s; p = n->p.parent; s = sibling(n); while(isblack(p) && isblack(s) && isint(s) && isblack(s->c.child.left) && isblack(s->c.child.right)) { setred(s); n = p; if (isroot(n)) return; p = n->p.parent; s = sibling(n); } if (isblack(p) && isred(s)) { /* Rotation 2.3b */ single_rotate(p, isright(n)); setred(p); setblack(s); s = sibling(n); } { Rb_node x, z; char il; if (isext(s)) { fprintf(stderr, "DELETION ERROR: sibling not internal\n"); exit(1); } il = isleft(n); x = il ? s->c.child.left : s->c.child.right ; z = sibling(x); if (isred(z)) { /* Rotation 2.3f */ single_rotate(p, !il); setblack(z); if (isred(p)) setred(s); else setblack(s); setblack(p); } else if (isblack(x)) { /* Recoloring only (2.3c) */ if (isred(s) || isblack(p)) { fprintf(stderr, "DELETION ERROR: 2.3c not quite right\n"); exit(1); } setblack(p); setred(s); return; } else if (isred(p)) { /* 2.3d */ single_rotate(s, il); single_rotate(p, !il); setblack(x); setred(s); return; } else { /* 2.3e */ single_rotate(s, il); single_rotate(p, !il); setblack(x); return; } } } void rb_print_tree(Rb_node t, int level) { int i; if (ishead(t) && t->p.parent == t) { printf("tree %p is empty\n", DONT_COMPLAIN t); } else if (ishead(t)) { printf("Head: %p. Root = %p\n", DONT_COMPLAIN t, DONT_COMPLAIN t->p.root); rb_print_tree(t->p.root, 0); } else { if (isext(t)) { for (i = 0; i < level; i++) putchar(' '); printf("Ext node %p: %c,%c: p=%p, k=%s\n", DONT_COMPLAIN t, isred(t)?'R':'B', isleft(t)?'l':'r', DONT_COMPLAIN t->p.parent, DONT_COMPLAIN t->k.key); } else { rb_print_tree(t->c.child.left, level+2); rb_print_tree(t->c.child.right, level+2); for (i = 0; i < level; i++) putchar(' '); printf("Int node %p: %c,%c: l=%p, r=%p, p=%p, lr=(%s,%s)\n", DONT_COMPLAIN t, isred(t)?'R':'B', isleft(t)?'l':'r', DONT_COMPLAIN t->c.child.left, DONT_COMPLAIN t->c.child.right, DONT_COMPLAIN t->p.parent, DONT_COMPLAIN t->k.lext->k.key, DONT_COMPLAIN t->v.rext->k.key); } } } void rb_iprint_tree(Rb_node t, int level) { int i; if (ishead(t) && t->p.parent == t) { printf("tree %p is empty\n", DONT_COMPLAIN t); } else if (ishead(t)) { printf("Head: %p. Root = %p, < = %p, > = %p\n", DONT_COMPLAIN t, DONT_COMPLAIN t->p.root, DONT_COMPLAIN t->c.list.blink, DONT_COMPLAIN t->c.list.flink); rb_iprint_tree(t->p.root, 0); } else { if (isext(t)) { for (i = 0; i < level; i++) putchar(' '); printf("Ext node %p: %c,%c: p=%p, <=%p, >=%p k=%d\n", DONT_COMPLAIN t, isred(t)?'R':'B', isleft(t)?'l':'r', DONT_COMPLAIN t->p.parent, DONT_COMPLAIN t->c.list.blink, DONT_COMPLAIN t->c.list.flink, t->k.ikey); } else { rb_iprint_tree(t->c.child.left, level+2); rb_iprint_tree(t->c.child.right, level+2); for (i = 0; i < level; i++) putchar(' '); printf("Int node %p: %c,%c: l=%p, r=%p, p=%p, lr=(%d,%d)\n", DONT_COMPLAIN t, isred(t)?'R':'B', isleft(t)?'l':'r', DONT_COMPLAIN t->c.child.left, DONT_COMPLAIN t->c.child.right, DONT_COMPLAIN t->p.parent, t->k.lext->k.ikey, t->v.rext->k.ikey); } } } int rb_nblack(Rb_node n) { int nb; if (ishead(n) || isint(n)) { fprintf(stderr, "ERROR: rb_nblack called on a non-external node %p\n", DONT_COMPLAIN n); exit(1); } nb = 0; while(!ishead(n)) { if (isblack(n)) nb++; n = n->p.parent; } return nb; } int rb_plength(Rb_node n) { int pl; if (ishead(n) || isint(n)) { fprintf(stderr, "ERROR: rb_plength called on a non-external node %p\n", DONT_COMPLAIN n); exit(1); } pl = 0; while(!ishead(n)) { pl++; n = n->p.parent; } return pl; } void rb_free_tree(Rb_node n) { if (!ishead(n)) { fprintf(stderr, "ERROR: Rb_free_tree called on a non-head node\n"); exit(1); } while(rb_first(n) != rb_nil(n)) { rb_delete_node(rb_first(n)); } free(n); } void *rb_val(Rb_node n) { return n->v.val; } Rb_node rb_insert_a(Rb_node nd, const void *key, void *val) { return rb_insert_b(nd->c.list.flink, key, val); } Rb_node rb_insert(Rb_node tree, const char *key, void *val) { return rb_insert_b(rb_find_key(tree, key), key, val); } Rb_node rb_inserti(Rb_node tree, int ikey, void *val) { return rb_insert_b(rb_find_ikey(tree, ikey), (void *) ikey, val); } Rb_node rb_insertg(Rb_node tree, const void *key, void *val, Rb_compfn *func) { return rb_insert_b(rb_find_gkey(tree, key, func), key, val); } Rb_node rb_insertp(Rb_node tree, const void *key, void *val) { return rb_insertg(tree, key, val, ptrcmp); }