/* * rbtree.c -- generic red black tree * * Copyright (c) 2001-2011, NLnet Labs. All rights reserved. * * See LICENSE for the license. * */ #include "config.h" #include #include #include "rbtree.h" #define BLACK 0 #define RED 1 rbnode_t rbtree_null_node = { RBTREE_NULL, /* Parent. */ RBTREE_NULL, /* Left. */ RBTREE_NULL, /* Right. */ NULL, /* Key. */ BLACK /* Color. */ }; static void rbtree_rotate_left(rbtree_t *rbtree, rbnode_t *node); static void rbtree_rotate_right(rbtree_t *rbtree, rbnode_t *node); static void rbtree_insert_fixup(rbtree_t *rbtree, rbnode_t *node); static void rbtree_delete_fixup(rbtree_t* rbtree, rbnode_t* child, rbnode_t* child_parent); /* * Creates a new red black tree, intializes and returns a pointer to it. * * Return NULL on failure. * */ rbtree_t * rbtree_create (region_type *region, int (*cmpf)(const void *, const void *)) { rbtree_t *rbtree; /* Allocate memory for it */ rbtree = (rbtree_t *) region_alloc(region, sizeof(rbtree_t)); if (!rbtree) { return NULL; } /* Initialize it */ rbtree->root = RBTREE_NULL; rbtree->count = 0; rbtree->region = region; rbtree->cmp = cmpf; return rbtree; } /* * Rotates the node to the left. * */ static void rbtree_rotate_left(rbtree_t *rbtree, rbnode_t *node) { rbnode_t *right = node->right; node->right = right->left; if (right->left != RBTREE_NULL) right->left->parent = node; right->parent = node->parent; if (node->parent != RBTREE_NULL) { if (node == node->parent->left) { node->parent->left = right; } else { node->parent->right = right; } } else { rbtree->root = right; } right->left = node; node->parent = right; } /* * Rotates the node to the right. * */ static void rbtree_rotate_right(rbtree_t *rbtree, rbnode_t *node) { rbnode_t *left = node->left; node->left = left->right; if (left->right != RBTREE_NULL) left->right->parent = node; left->parent = node->parent; if (node->parent != RBTREE_NULL) { if (node == node->parent->right) { node->parent->right = left; } else { node->parent->left = left; } } else { rbtree->root = left; } left->right = node; node->parent = left; } static void rbtree_insert_fixup(rbtree_t *rbtree, rbnode_t *node) { rbnode_t *uncle; /* While not at the root and need fixing... */ while (node != rbtree->root && node->parent->color == RED) { /* If our parent is left child of our grandparent... */ if (node->parent == node->parent->parent->left) { uncle = node->parent->parent->right; /* If our uncle is red... */ if (uncle->color == RED) { /* Paint the parent and the uncle black... */ node->parent->color = BLACK; uncle->color = BLACK; /* And the grandparent red... */ node->parent->parent->color = RED; /* And continue fixing the grandparent */ node = node->parent->parent; } else { /* Our uncle is black... */ /* Are we the right child? */ if (node == node->parent->right) { node = node->parent; rbtree_rotate_left(rbtree, node); } /* Now we're the left child, repaint and rotate... */ node->parent->color = BLACK; node->parent->parent->color = RED; rbtree_rotate_right(rbtree, node->parent->parent); } } else { uncle = node->parent->parent->left; /* If our uncle is red... */ if (uncle->color == RED) { /* Paint the parent and the uncle black... */ node->parent->color = BLACK; uncle->color = BLACK; /* And the grandparent red... */ node->parent->parent->color = RED; /* And continue fixing the grandparent */ node = node->parent->parent; } else { /* Our uncle is black... */ /* Are we the right child? */ if (node == node->parent->left) { node = node->parent; rbtree_rotate_right(rbtree, node); } /* Now we're the right child, repaint and rotate... */ node->parent->color = BLACK; node->parent->parent->color = RED; rbtree_rotate_left(rbtree, node->parent->parent); } } } rbtree->root->color = BLACK; } /* * Inserts a node into a red black tree. * * Returns NULL on failure or the pointer to the newly added node * otherwise. */ rbnode_t * rbtree_insert (rbtree_t *rbtree, rbnode_t *data) { /* XXX Not necessary, but keeps compiler quiet... */ int r = 0; /* We start at the root of the tree */ rbnode_t *node = rbtree->root; rbnode_t *parent = RBTREE_NULL; /* Lets find the new parent... */ while (node != RBTREE_NULL) { /* Compare two keys, do we have a duplicate? */ if ((r = rbtree->cmp(data->key, node->key)) == 0) { return NULL; } parent = node; if (r < 0) { node = node->left; } else { node = node->right; } } /* Initialize the new node */ data->parent = parent; data->left = data->right = RBTREE_NULL; data->color = RED; rbtree->count++; /* Insert it into the tree... */ if (parent != RBTREE_NULL) { if (r < 0) { parent->left = data; } else { parent->right = data; } } else { rbtree->root = data; } /* Fix up the red-black properties... */ rbtree_insert_fixup(rbtree, data); return data; } /* * Searches the red black tree, returns the data if key is found or NULL otherwise. * */ rbnode_t * rbtree_search (rbtree_t *rbtree, const void *key) { rbnode_t *node; if (rbtree_find_less_equal(rbtree, key, &node)) { return node; } else { return NULL; } } /* helpers for delete */ static void swap_int8(uint8_t* x, uint8_t* y) { uint8_t t = *x; *x = *y; *y = t; } static void swap_np(rbnode_t** x, rbnode_t** y) { rbnode_t* t = *x; *x = *y; *y = t; } static void change_parent_ptr(rbtree_t* rbtree, rbnode_t* parent, rbnode_t* old, rbnode_t* new) { if(parent == RBTREE_NULL) { assert(rbtree->root == old); if(rbtree->root == old) rbtree->root = new; return; } assert(parent->left == old || parent->right == old || parent->left == new || parent->right == new); if(parent->left == old) parent->left = new; if(parent->right == old) parent->right = new; } static void change_child_ptr(rbnode_t* child, rbnode_t* old, rbnode_t* new) { if(child == RBTREE_NULL) return; assert(child->parent == old || child->parent == new); if(child->parent == old) child->parent = new; } rbnode_t* rbtree_delete(rbtree_t *rbtree, const void *key) { rbnode_t *to_delete; rbnode_t *child; if((to_delete = rbtree_search(rbtree, key)) == 0) return 0; rbtree->count--; /* make sure we have at most one non-leaf child */ if(to_delete->left != RBTREE_NULL && to_delete->right != RBTREE_NULL) { /* swap with smallest from right subtree (or largest from left) */ rbnode_t *smright = to_delete->right; while(smright->left != RBTREE_NULL) smright = smright->left; /* swap the smright and to_delete elements in the tree, * but the rbnode_t is first part of user data struct * so cannot just swap the keys and data pointers. Instead * readjust the pointers left,right,parent */ /* swap colors - colors are tied to the position in the tree */ swap_int8(&to_delete->color, &smright->color); /* swap child pointers in parents of smright/to_delete */ change_parent_ptr(rbtree, to_delete->parent, to_delete, smright); if(to_delete->right != smright) change_parent_ptr(rbtree, smright->parent, smright, to_delete); /* swap parent pointers in children of smright/to_delete */ change_child_ptr(smright->left, smright, to_delete); change_child_ptr(smright->left, smright, to_delete); change_child_ptr(smright->right, smright, to_delete); change_child_ptr(smright->right, smright, to_delete); change_child_ptr(to_delete->left, to_delete, smright); if(to_delete->right != smright) change_child_ptr(to_delete->right, to_delete, smright); if(to_delete->right == smright) { /* set up so after swap they work */ to_delete->right = to_delete; smright->parent = smright; } /* swap pointers in to_delete/smright nodes */ swap_np(&to_delete->parent, &smright->parent); swap_np(&to_delete->left, &smright->left); swap_np(&to_delete->right, &smright->right); /* now delete to_delete (which is at the location where the smright previously was) */ } assert(to_delete->left == RBTREE_NULL || to_delete->right == RBTREE_NULL); if(to_delete->left != RBTREE_NULL) child = to_delete->left; else child = to_delete->right; /* unlink to_delete from the tree, replace to_delete with child */ change_parent_ptr(rbtree, to_delete->parent, to_delete, child); change_child_ptr(child, to_delete, to_delete->parent); if(to_delete->color == RED) { /* if node is red then the child (black) can be swapped in */ } else if(child->color == RED) { /* change child to BLACK, removing a RED node is no problem */ if(child!=RBTREE_NULL) child->color = BLACK; } else rbtree_delete_fixup(rbtree, child, to_delete->parent); /* unlink completely */ to_delete->parent = RBTREE_NULL; to_delete->left = RBTREE_NULL; to_delete->right = RBTREE_NULL; to_delete->color = BLACK; return to_delete; } static void rbtree_delete_fixup(rbtree_t* rbtree, rbnode_t* child, rbnode_t* child_parent) { rbnode_t* sibling; int go_up = 1; /* determine sibling to the node that is one-black short */ if(child_parent->right == child) sibling = child_parent->left; else sibling = child_parent->right; while(go_up) { if(child_parent == RBTREE_NULL) { /* removed parent==black from root, every path, so ok */ return; } if(sibling->color == RED) { /* rotate to get a black sibling */ child_parent->color = RED; sibling->color = BLACK; if(child_parent->right == child) rbtree_rotate_right(rbtree, child_parent); else rbtree_rotate_left(rbtree, child_parent); /* new sibling after rotation */ if(child_parent->right == child) sibling = child_parent->left; else sibling = child_parent->right; } if(child_parent->color == BLACK && sibling->color == BLACK && sibling->left->color == BLACK && sibling->right->color == BLACK) { /* fixup local with recolor of sibling */ if(sibling != RBTREE_NULL) sibling->color = RED; child = child_parent; child_parent = child_parent->parent; /* prepare to go up, new sibling */ if(child_parent->right == child) sibling = child_parent->left; else sibling = child_parent->right; } else go_up = 0; } if(child_parent->color == RED && sibling->color == BLACK && sibling->left->color == BLACK && sibling->right->color == BLACK) { /* move red to sibling to rebalance */ if(sibling != RBTREE_NULL) sibling->color = RED; child_parent->color = BLACK; return; } assert(sibling != RBTREE_NULL); /* get a new sibling, by rotating at sibling. See which child of sibling is red */ if(child_parent->right == child && sibling->color == BLACK && sibling->right->color == RED && sibling->left->color == BLACK) { sibling->color = RED; sibling->right->color = BLACK; rbtree_rotate_left(rbtree, sibling); /* new sibling after rotation */ if(child_parent->right == child) sibling = child_parent->left; else sibling = child_parent->right; } else if(child_parent->left == child && sibling->color == BLACK && sibling->left->color == RED && sibling->right->color == BLACK) { sibling->color = RED; sibling->left->color = BLACK; rbtree_rotate_right(rbtree, sibling); /* new sibling after rotation */ if(child_parent->right == child) sibling = child_parent->left; else sibling = child_parent->right; } /* now we have a black sibling with a red child. rotate and exchange colors. */ sibling->color = child_parent->color; child_parent->color = BLACK; if(child_parent->right == child) { assert(sibling->left->color == RED); sibling->left->color = BLACK; rbtree_rotate_right(rbtree, child_parent); } else { assert(sibling->right->color == RED); sibling->right->color = BLACK; rbtree_rotate_left(rbtree, child_parent); } } int rbtree_find_less_equal(rbtree_t *rbtree, const void *key, rbnode_t **result) { int r; rbnode_t *node; assert(result); /* We start at root... */ node = rbtree->root; *result = NULL; /* While there are children... */ while (node != RBTREE_NULL) { r = rbtree->cmp(key, node->key); if (r == 0) { /* Exact match */ *result = node; return 1; } if (r < 0) { node = node->left; } else { /* Temporary match */ *result = node; node = node->right; } } return 0; } /* * Finds the first element in the red black tree * */ rbnode_t * rbtree_first (rbtree_t *rbtree) { rbnode_t *node; for (node = rbtree->root; node->left != RBTREE_NULL; node = node->left); return node; } rbnode_t * rbtree_last (rbtree_t *rbtree) { rbnode_t *node; for (node = rbtree->root; node->right != RBTREE_NULL; node = node->right); return node; } /* * Returns the next node... * */ rbnode_t * rbtree_next (rbnode_t *node) { rbnode_t *parent; if (node->right != RBTREE_NULL) { /* One right, then keep on going left... */ for (node = node->right; node->left != RBTREE_NULL; node = node->left); } else { parent = node->parent; while (parent != RBTREE_NULL && node == parent->right) { node = parent; parent = parent->parent; } node = parent; } return node; } rbnode_t * rbtree_previous(rbnode_t *node) { rbnode_t *parent; if (node->left != RBTREE_NULL) { /* One left, then keep on going right... */ for (node = node->left; node->right != RBTREE_NULL; node = node->right); } else { parent = node->parent; while (parent != RBTREE_NULL && node == parent->left) { node = parent; parent = parent->parent; } node = parent; } return node; } /** * Given an rbtree "root" node, find the first node under that tree in * postorder. */ rbnode_t * rbtree_postorder_first(rbnode_t *root) { rbnode_t *node = root; do { while (node->left != RBTREE_NULL) { node = node->left; } while ((node->left == RBTREE_NULL) && (node->right != RBTREE_NULL)) { node = node->right; } } while (node->left != node->right); return node; } /** * Given any node in an rbtree, find the next node in postorder. */ rbnode_t * rbtree_postorder_next(rbnode_t *node) { if ((node->parent->right == RBTREE_NULL) || (node->parent->right == node)) node = node->parent; else node = rbtree_postorder_first(node->parent->right); return node; }