/** * @file CAvl_impl.h * @author Ambroz Bizjak * * @section LICENSE * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the author nor the * names of its contributors may be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "CAvl_header.h" static CAvlLink CAvl_nulllink (void) { return CAVL_PARAM_VALUE_NULL; } static CAvlRef CAvl_nullref (void) { CAvlRef n; n.link = CAVL_PARAM_VALUE_NULL; n.ptr = NULL; return n; } #if !CAVL_PARAM_FEATURE_KEYS_ARE_INDICES static int CAvl_compare_entries (CAvlArg arg, CAvlRef node1, CAvlRef node2) { int res = CAVL_PARAM_FUN_COMPARE_ENTRIES(arg, node1, node2); ASSERT(res >= -1) ASSERT(res <= 1) return res; } #if !CAVL_PARAM_FEATURE_NOKEYS static int CAvl_compare_key_entry (CAvlArg arg, CAvlKey key1, CAvlRef node2) { int res = CAVL_PARAM_FUN_COMPARE_KEY_ENTRY(arg, key1, node2); ASSERT(res >= -1) ASSERT(res <= 1) return res; } #endif #endif static int CAvl_check_parent (CAvlRef p, CAvlRef c) { return (p.link == CAvl_parent(c)) && (p.link == CAvl_nulllink() || c.link == CAvl_link(p)[0] || c.link == CAvl_link(p)[1]); } static int CAvl_verify_recurser (CAvlArg arg, CAvlRef n) { ASSERT_FORCE(CAvl_balance(n) >= -1) ASSERT_FORCE(CAvl_balance(n) <= 1) int height_left = 0; int height_right = 0; #if CAVL_PARAM_FEATURE_COUNTS CAvlCount count_left = 0; CAvlCount count_right = 0; #endif // check left subtree if (CAvl_link(n)[0] != CAvl_nulllink()) { // check parent link ASSERT_FORCE(CAvl_parent(CAvlDeref(arg, CAvl_link(n)[0])) == n.link) // check binary search tree #if !CAVL_PARAM_FEATURE_KEYS_ARE_INDICES ASSERT_FORCE(CAvl_compare_entries(arg, CAvlDeref(arg, CAvl_link(n)[0]), n) == -1) #endif // recursively calculate height height_left = CAvl_verify_recurser(arg, CAvlDeref(arg, CAvl_link(n)[0])); #if CAVL_PARAM_FEATURE_COUNTS count_left = CAvl_count(CAvlDeref(arg, CAvl_link(n)[0])); #endif } // check right subtree if (CAvl_link(n)[1] != CAvl_nulllink()) { // check parent link ASSERT_FORCE(CAvl_parent(CAvlDeref(arg, CAvl_link(n)[1])) == n.link) // check binary search tree #if !CAVL_PARAM_FEATURE_KEYS_ARE_INDICES ASSERT_FORCE(CAvl_compare_entries(arg, CAvlDeref(arg, CAvl_link(n)[1]), n) == 1) #endif // recursively calculate height height_right = CAvl_verify_recurser(arg, CAvlDeref(arg, CAvl_link(n)[1])); #if CAVL_PARAM_FEATURE_COUNTS count_right = CAvl_count(CAvlDeref(arg, CAvl_link(n)[1])); #endif } // check balance factor ASSERT_FORCE(CAvl_balance(n) == height_right - height_left) #if CAVL_PARAM_FEATURE_COUNTS // check count ASSERT_FORCE(CAvl_count(n) == 1 + count_left + count_right) #endif return CAvl_MAX(height_left, height_right) + 1; } static void CAvl_assert_tree (CAvl *o, CAvlArg arg) { #ifdef CAVL_PARAM_VERIFY CAvl_Verify(o, arg); #endif } #if CAVL_PARAM_FEATURE_COUNTS static void CAvl_update_count_from_children (CAvlArg arg, CAvlRef n) { CAvlCount left_count = CAvl_link(n)[0] != CAvl_nulllink() ? CAvl_count(CAvlDeref(arg, CAvl_link(n)[0])) : 0; CAvlCount right_count = CAvl_link(n)[1] != CAvl_nulllink() ? CAvl_count(CAvlDeref(arg, CAvl_link(n)[1])) : 0; CAvl_count(n) = 1 + left_count + right_count; } #endif static void CAvl_rotate (CAvl *o, CAvlArg arg, CAvlRef r, uint8_t dir, CAvlRef r_parent) { ASSERT(CAvl_check_parent(r_parent, r)) CAvlRef nr = CAvlDeref(arg, CAvl_link(r)[!dir]); CAvl_link(r)[!dir] = CAvl_link(nr)[dir]; if (CAvl_link(r)[!dir] != CAvl_nulllink()) { CAvl_parent(CAvlDeref(arg, CAvl_link(r)[!dir])) = r.link; } CAvl_link(nr)[dir] = r.link; CAvl_parent(nr) = r_parent.link; if (r_parent.link != CAvl_nulllink()) { CAvl_link(r_parent)[r.link == CAvl_link(r_parent)[1]] = nr.link; } else { o->root = nr.link; } CAvl_parent(r) = nr.link; #if CAVL_PARAM_FEATURE_COUNTS CAvl_update_count_from_children(arg, r); CAvl_update_count_from_children(arg, nr); #endif } static CAvlRef CAvl_subtree_min (CAvlArg arg, CAvlRef n) { ASSERT(n.link != CAvl_nulllink()) while (CAvl_link(n)[0] != CAvl_nulllink()) { n = CAvlDeref(arg, CAvl_link(n)[0]); } return n; } static CAvlRef CAvl_subtree_max (CAvlArg arg, CAvlRef n) { ASSERT(n.link != CAvl_nulllink()) while (CAvl_link(n)[1] != CAvl_nulllink()) { n = CAvlDeref(arg, CAvl_link(n)[1]); } return n; } static void CAvl_replace_subtree_fix_counts (CAvl *o, CAvlArg arg, CAvlRef dest, CAvlRef n, CAvlRef dest_parent) { ASSERT(dest.link != CAvl_nulllink()) ASSERT(CAvl_check_parent(dest_parent, dest)) if (dest_parent.link != CAvl_nulllink()) { CAvl_link(dest_parent)[dest.link == CAvl_link(dest_parent)[1]] = n.link; } else { o->root = n.link; } if (n.link != CAvl_nulllink()) { CAvl_parent(n) = CAvl_parent(dest); } #if CAVL_PARAM_FEATURE_COUNTS for (CAvlRef c = dest_parent; c.link != CAvl_nulllink(); c = CAvlDeref(arg, CAvl_parent(c))) { ASSERT(CAvl_count(c) >= CAvl_count(dest)) CAvl_count(c) -= CAvl_count(dest); if (n.link != CAvl_nulllink()) { ASSERT(CAvl_count(n) <= CAVL_PARAM_VALUE_COUNT_MAX - CAvl_count(c)) CAvl_count(c) += CAvl_count(n); } } #endif } static void CAvl_swap_entries (CAvl *o, CAvlArg arg, CAvlRef n1, CAvlRef n2, CAvlRef n1_parent, CAvlRef n2_parent) { ASSERT(CAvl_check_parent(n1_parent, n1)) ASSERT(CAvl_check_parent(n2_parent, n2)) if (n2_parent.link == n1.link || n1_parent.link == n2.link) { // when the nodes are directly connected we need special handling // make sure n1 is above n2 if (n1_parent.link == n2.link) { CAvlRef t = n1; n1 = n2; n2 = t; t = n1_parent; n1_parent = n2_parent; n2_parent = t; } uint8_t side = (n2.link == CAvl_link(n1)[1]); CAvlRef c = CAvlDeref(arg, CAvl_link(n1)[!side]); if ((CAvl_link(n1)[0] = CAvl_link(n2)[0]) != CAvl_nulllink()) { CAvl_parent(CAvlDeref(arg, CAvl_link(n1)[0])) = n1.link; } if ((CAvl_link(n1)[1] = CAvl_link(n2)[1]) != CAvl_nulllink()) { CAvl_parent(CAvlDeref(arg, CAvl_link(n1)[1])) = n1.link; } CAvl_parent(n2) = CAvl_parent(n1); if (n1_parent.link != CAvl_nulllink()) { CAvl_link(n1_parent)[n1.link == CAvl_link(n1_parent)[1]] = n2.link; } else { o->root = n2.link; } CAvl_link(n2)[side] = n1.link; CAvl_parent(n1) = n2.link; if ((CAvl_link(n2)[!side] = c.link) != CAvl_nulllink()) { CAvl_parent(c) = n2.link; } } else { CAvlRef temp; // swap parents temp = n1_parent; CAvl_parent(n1) = CAvl_parent(n2); if (n2_parent.link != CAvl_nulllink()) { CAvl_link(n2_parent)[n2.link == CAvl_link(n2_parent)[1]] = n1.link; } else { o->root = n1.link; } CAvl_parent(n2) = temp.link; if (temp.link != CAvl_nulllink()) { CAvl_link(temp)[n1.link == CAvl_link(temp)[1]] = n2.link; } else { o->root = n2.link; } // swap left children temp = CAvlDeref(arg, CAvl_link(n1)[0]); if ((CAvl_link(n1)[0] = CAvl_link(n2)[0]) != CAvl_nulllink()) { CAvl_parent(CAvlDeref(arg, CAvl_link(n1)[0])) = n1.link; } if ((CAvl_link(n2)[0] = temp.link) != CAvl_nulllink()) { CAvl_parent(CAvlDeref(arg, CAvl_link(n2)[0])) = n2.link; } // swap right children temp = CAvlDeref(arg, CAvl_link(n1)[1]); if ((CAvl_link(n1)[1] = CAvl_link(n2)[1]) != CAvl_nulllink()) { CAvl_parent(CAvlDeref(arg, CAvl_link(n1)[1])) = n1.link; } if ((CAvl_link(n2)[1] = temp.link) != CAvl_nulllink()) { CAvl_parent(CAvlDeref(arg, CAvl_link(n2)[1])) = n2.link; } } // swap balance factors int8_t b = CAvl_balance(n1); CAvl_balance(n1) = CAvl_balance(n2); CAvl_balance(n2) = b; #if CAVL_PARAM_FEATURE_COUNTS // swap counts CAvlCount c = CAvl_count(n1); CAvl_count(n1) = CAvl_count(n2); CAvl_count(n2) = c; #endif } static void CAvl_rebalance (CAvl *o, CAvlArg arg, CAvlRef node, uint8_t side, int8_t deltac) { ASSERT(side == 0 || side == 1) ASSERT(deltac >= -1 && deltac <= 1) ASSERT(CAvl_balance(node) >= -1 && CAvl_balance(node) <= 1) // if no subtree changed its height, no more rebalancing is needed if (deltac == 0) { return; } // calculate how much our height changed int8_t delta = CAvl_MAX(deltac, CAvl_OPTNEG(CAvl_balance(node), side)) - CAvl_MAX(0, CAvl_OPTNEG(CAvl_balance(node), side)); ASSERT(delta >= -1 && delta <= 1) // update our balance factor CAvl_balance(node) -= CAvl_OPTNEG(deltac, side); CAvlRef child; CAvlRef gchild; // perform transformations if the balance factor is wrong if (CAvl_balance(node) == 2 || CAvl_balance(node) == -2) { uint8_t bside; int8_t bsidef; if (CAvl_balance(node) == 2) { bside = 1; bsidef = 1; } else { bside = 0; bsidef = -1; } ASSERT(CAvl_link(node)[bside] != CAvl_nulllink()) child = CAvlDeref(arg, CAvl_link(node)[bside]); switch (CAvl_balance(child) * bsidef) { case 1: CAvl_rotate(o, arg, node, !bside, CAvlDeref(arg, CAvl_parent(node))); CAvl_balance(node) = 0; CAvl_balance(child) = 0; node = child; delta -= 1; break; case 0: CAvl_rotate(o, arg, node, !bside, CAvlDeref(arg, CAvl_parent(node))); CAvl_balance(node) = 1 * bsidef; CAvl_balance(child) = -1 * bsidef; node = child; break; case -1: ASSERT(CAvl_link(child)[!bside] != CAvl_nulllink()) gchild = CAvlDeref(arg, CAvl_link(child)[!bside]); CAvl_rotate(o, arg, child, bside, node); CAvl_rotate(o, arg, node, !bside, CAvlDeref(arg, CAvl_parent(node))); CAvl_balance(node) = -CAvl_MAX(0, CAvl_balance(gchild) * bsidef) * bsidef; CAvl_balance(child) = CAvl_MAX(0, -CAvl_balance(gchild) * bsidef) * bsidef; CAvl_balance(gchild) = 0; node = gchild; delta -= 1; break; default: ASSERT(0); } } ASSERT(delta >= -1 && delta <= 1) // Transformations above preserve this. Proof: // - if a child subtree gained 1 height and rebalancing was needed, // it was the heavier subtree. Then delta was was originally 1, because // the heaviest subtree gained one height. If the transformation reduces // delta by one, it becomes 0. // - if a child subtree lost 1 height and rebalancing was needed, it // was the lighter subtree. Then delta was originally 0, because // the height of the heaviest subtree was unchanged. If the transformation // reduces delta by one, it becomes -1. if (CAvl_parent(node) != CAvl_nulllink()) { CAvlRef node_parent = CAvlDeref(arg, CAvl_parent(node)); CAvl_rebalance(o, arg, node_parent, node.link == CAvl_link(node_parent)[1], delta); } } #if CAVL_PARAM_FEATURE_KEYS_ARE_INDICES static CAvlCount CAvl_child_count (CAvlArg arg, CAvlRef n, int dir) { return (CAvl_link(n)[dir] != CAvl_nulllink() ? CAvl_count(CAvlDeref(arg, CAvl_link(n)[dir])) : 0); } #endif static int CAvlIsNullRef (CAvlRef node) { return node.link == CAvl_nulllink(); } static int CAvlIsValidRef (CAvlRef node) { return node.link != CAvl_nulllink(); } static CAvlRef CAvlDeref (CAvlArg arg, CAvlLink link) { if (link == CAvl_nulllink()) { return CAvl_nullref(); } CAvlRef n; n.ptr = CAVL_PARAM_FUN_DEREF(arg, link); n.link = link; ASSERT(n.ptr) return n; } static void CAvl_Init (CAvl *o) { o->root = CAvl_nulllink(); } #if !CAVL_PARAM_FEATURE_KEYS_ARE_INDICES static int CAvl_Insert (CAvl *o, CAvlArg arg, CAvlRef node, CAvlRef *out_ref) { ASSERT(node.link != CAvl_nulllink()) // insert to root? if (o->root == CAvl_nulllink()) { o->root = node.link; CAvl_parent(node) = CAvl_nulllink(); CAvl_link(node)[0] = CAvl_nulllink(); CAvl_link(node)[1] = CAvl_nulllink(); CAvl_balance(node) = 0; #if CAVL_PARAM_FEATURE_COUNTS CAvl_count(node) = 1; #endif CAvl_assert_tree(o, arg); if (out_ref) { *out_ref = CAvl_nullref(); } return 1; } CAvlRef c = CAvlDeref(arg, o->root); int side; while (1) { int comp = CAvl_compare_entries(arg, node, c); if (comp == 0) { if (out_ref) { *out_ref = c; } return 0; } side = (comp == 1); if (CAvl_link(c)[side] == CAvl_nulllink()) { break; } c = CAvlDeref(arg, CAvl_link(c)[side]); } CAvl_link(c)[side] = node.link; CAvl_parent(node) = c.link; CAvl_link(node)[0] = CAvl_nulllink(); CAvl_link(node)[1] = CAvl_nulllink(); CAvl_balance(node) = 0; #if CAVL_PARAM_FEATURE_COUNTS CAvl_count(node) = 1; #endif #if CAVL_PARAM_FEATURE_COUNTS for (CAvlRef p = c; p.link != CAvl_nulllink(); p = CAvlDeref(arg, CAvl_parent(p))) { CAvl_count(p)++; } #endif CAvl_rebalance(o, arg, c, side, 1); CAvl_assert_tree(o, arg); if (out_ref) { *out_ref = c; } return 1; } #else static void CAvl_InsertAt (CAvl *o, CAvlArg arg, CAvlRef node, CAvlCount index) { ASSERT(node.link != CAvl_nulllink()) ASSERT(index <= CAvl_Count(o, arg)) // insert to root? if (o->root == CAvl_nulllink()) { o->root = node.link; CAvl_parent(node) = CAvl_nulllink(); CAvl_link(node)[0] = CAvl_nulllink(); CAvl_link(node)[1] = CAvl_nulllink(); CAvl_balance(node) = 0; CAvl_count(node) = 1; CAvl_assert_tree(o, arg); return; } CAvlRef c = CAvlDeref(arg, o->root); CAvlCount c_idx = CAvl_child_count(arg, c, 0); int side; while (1) { side = (index > c_idx); if (CAvl_link(c)[side] == CAvl_nulllink()) { break; } c = CAvlDeref(arg, CAvl_link(c)[side]); if (side == 0) { c_idx -= 1 + CAvl_child_count(arg, c, 1); } else { c_idx += 1 + CAvl_child_count(arg, c, 0); } } CAvl_link(c)[side] = node.link; CAvl_parent(node) = c.link; CAvl_link(node)[0] = CAvl_nulllink(); CAvl_link(node)[1] = CAvl_nulllink(); CAvl_balance(node) = 0; CAvl_count(node) = 1; for (CAvlRef p = c; p.link != CAvl_nulllink(); p = CAvlDeref(arg, CAvl_parent(p))) { CAvl_count(p)++; } CAvl_rebalance(o, arg, c, side, 1); CAvl_assert_tree(o, arg); return; } #endif static void CAvl_Remove (CAvl *o, CAvlArg arg, CAvlRef node) { ASSERT(node.link != CAvl_nulllink()) ASSERT(o->root != CAvl_nulllink()) if (CAvl_link(node)[0] != CAvl_nulllink() && CAvl_link(node)[1] != CAvl_nulllink()) { CAvlRef max = CAvl_subtree_max(arg, CAvlDeref(arg, CAvl_link(node)[0])); CAvl_swap_entries(o, arg, node, max, CAvlDeref(arg, CAvl_parent(node)), CAvlDeref(arg, CAvl_parent(max))); } ASSERT(CAvl_link(node)[0] == CAvl_nulllink() || CAvl_link(node)[1] == CAvl_nulllink()) CAvlRef paren = CAvlDeref(arg, CAvl_parent(node)); CAvlRef child = (CAvl_link(node)[0] != CAvl_nulllink() ? CAvlDeref(arg, CAvl_link(node)[0]) : CAvlDeref(arg, CAvl_link(node)[1])); if (paren.link != CAvl_nulllink()) { int side = (node.link == CAvl_link(paren)[1]); CAvl_replace_subtree_fix_counts(o, arg, node, child, paren); CAvl_rebalance(o, arg, paren, side, -1); } else { CAvl_replace_subtree_fix_counts(o, arg, node, child, paren); } CAvl_assert_tree(o, arg); } #if !CAVL_PARAM_FEATURE_KEYS_ARE_INDICES && !CAVL_PARAM_FEATURE_NOKEYS static CAvlRef CAvl_Lookup (const CAvl *o, CAvlArg arg, CAvlKey key) { if (o->root == CAvl_nulllink()) { return CAvl_nullref(); } CAvlRef c = CAvlDeref(arg, o->root); while (1) { // compare int comp = CAvl_compare_key_entry(arg, key, c); // have we found a node that compares equal? if (comp == 0) { return c; } int side = (comp == 1); // have we reached a leaf? if (CAvl_link(c)[side] == CAvl_nulllink()) { return c; } c = CAvlDeref(arg, CAvl_link(c)[side]); } } static CAvlRef CAvl_LookupExact (const CAvl *o, CAvlArg arg, CAvlKey key) { if (o->root == CAvl_nulllink()) { return CAvl_nullref(); } CAvlRef c = CAvlDeref(arg, o->root); while (1) { // compare int comp = CAvl_compare_key_entry(arg, key, c); // have we found a node that compares equal? if (comp == 0) { return c; } int side = (comp == 1); // have we reached a leaf? if (CAvl_link(c)[side] == CAvl_nulllink()) { return CAvl_nullref(); } c = CAvlDeref(arg, CAvl_link(c)[side]); } } #endif static CAvlRef CAvl_GetFirst (const CAvl *o, CAvlArg arg) { if (o->root == CAvl_nulllink()) { return CAvl_nullref(); } return CAvl_subtree_min(arg, CAvlDeref(arg, o->root)); } static CAvlRef CAvl_GetLast (const CAvl *o, CAvlArg arg) { if (o->root == CAvl_nulllink()) { return CAvl_nullref(); } return CAvl_subtree_max(arg, CAvlDeref(arg, o->root)); } static CAvlRef CAvl_GetNext (const CAvl *o, CAvlArg arg, CAvlRef node) { ASSERT(node.link != CAvl_nulllink()) ASSERT(o->root != CAvl_nulllink()) if (CAvl_link(node)[1] != CAvl_nulllink()) { node = CAvlDeref(arg, CAvl_link(node)[1]); while (CAvl_link(node)[0] != CAvl_nulllink()) { node = CAvlDeref(arg, CAvl_link(node)[0]); } } else { while (CAvl_parent(node) != CAvl_nulllink() && node.link == CAvl_link(CAvlDeref(arg, CAvl_parent(node)))[1]) { node = CAvlDeref(arg, CAvl_parent(node)); } node = CAvlDeref(arg, CAvl_parent(node)); } return node; } static CAvlRef CAvl_GetPrev (const CAvl *o, CAvlArg arg, CAvlRef node) { ASSERT(node.link != CAvl_nulllink()) ASSERT(o->root != CAvl_nulllink()) if (CAvl_link(node)[0] != CAvl_nulllink()) { node = CAvlDeref(arg, CAvl_link(node)[0]); while (CAvl_link(node)[1] != CAvl_nulllink()) { node = CAvlDeref(arg, CAvl_link(node)[1]); } } else { while (CAvl_parent(node) != CAvl_nulllink() && node.link == CAvl_link(CAvlDeref(arg, CAvl_parent(node)))[0]) { node = CAvlDeref(arg, CAvl_parent(node)); } node = CAvlDeref(arg, CAvl_parent(node)); } return node; } static int CAvl_IsEmpty (const CAvl *o) { return o->root == CAvl_nulllink(); } static void CAvl_Verify (const CAvl *o, CAvlArg arg) { if (o->root != CAvl_nulllink()) { CAvlRef root = CAvlDeref(arg, o->root); ASSERT(CAvl_parent(root) == CAvl_nulllink()) CAvl_verify_recurser(arg, root); } } #if CAVL_PARAM_FEATURE_COUNTS static CAvlCount CAvl_Count (const CAvl *o, CAvlArg arg) { return (o->root != CAvl_nulllink() ? CAvl_count(CAvlDeref(arg, o->root)) : 0); } static CAvlCount CAvl_IndexOf (const CAvl *o, CAvlArg arg, CAvlRef node) { ASSERT(node.link != CAvl_nulllink()) ASSERT(o->root != CAvl_nulllink()) CAvlCount index = (CAvl_link(node)[0] != CAvl_nulllink() ? CAvl_count(CAvlDeref(arg, CAvl_link(node)[0])) : 0); CAvlRef paren = CAvlDeref(arg, CAvl_parent(node)); for (CAvlRef c = node; paren.link != CAvl_nulllink(); c = paren, paren = CAvlDeref(arg, CAvl_parent(c))) { if (c.link == CAvl_link(paren)[1]) { ASSERT(CAvl_count(paren) > CAvl_count(c)) ASSERT(CAvl_count(paren) - CAvl_count(c) <= CAVL_PARAM_VALUE_COUNT_MAX - index) index += CAvl_count(paren) - CAvl_count(c); } } return index; } static CAvlRef CAvl_GetAt (const CAvl *o, CAvlArg arg, CAvlCount index) { if (index >= CAvl_Count(o, arg)) { return CAvl_nullref(); } CAvlRef c = CAvlDeref(arg, o->root); while (1) { ASSERT(c.link != CAvl_nulllink()) ASSERT(index < CAvl_count(c)) CAvlCount left_count = (CAvl_link(c)[0] != CAvl_nulllink() ? CAvl_count(CAvlDeref(arg, CAvl_link(c)[0])) : 0); if (index == left_count) { return c; } if (index < left_count) { c = CAvlDeref(arg, CAvl_link(c)[0]); } else { c = CAvlDeref(arg, CAvl_link(c)[1]); index -= left_count + 1; } } } #endif #include "CAvl_footer.h"