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[/] [or1k/] [trunk/] [uclinux/] [uClinux-2.0.x/] [net/] [bridge/] [br_tree.c] - Rev 1765
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/* * this code is derived from the avl functions in mmap.c */ #include <linux/kernel.h> #include <linux/errno.h> #include <linux/string.h> #include <linux/malloc.h> #include <linux/skbuff.h> #include <net/br.h> #define _DEBUG_AVL /* * Use an AVL (Adelson-Velskii and Landis) tree to speed up this search * from O(n) to O(log n), where n is the number of ULAs. * Written by Bruno Haible <haible@ma2s2.mathematik.uni-karlsruhe.de>. * Taken from mmap.c, extensively modified by John Hayes * <hayes@netplumbing.com> */ struct fdb fdb_head; struct fdb *fhp = &fdb_head; struct fdb **fhpp = &fhp; static int fdb_inited = 0; int addr_cmp(unsigned char *a1, unsigned char *a2); /* * fdb_head is the AVL tree corresponding to fdb * or, more exactly, its root. * A fdb has the following fields: * fdb_avl_left left son of a tree node * fdb_avl_right right son of a tree node * fdb_avl_height 1+max(heightof(left),heightof(right)) * The empty tree is represented as NULL. */ #ifndef avl_br_empty #define avl_br_empty (struct fdb *) NULL #endif /* Since the trees are balanced, their height will never be large. */ #define avl_maxheight 127 #define heightof(tree) ((tree) == avl_br_empty ? 0 : (tree)->fdb_avl_height) /* * Consistency and balancing rules: * 1. tree->fdb_avl_height == 1+max(heightof(tree->fdb_avl_left),heightof(tree->fdb_avl_right)) * 2. abs( heightof(tree->fdb_avl_left) - heightof(tree->fdb_avl_right) ) <= 1 * 3. foreach node in tree->fdb_avl_left: node->fdb_avl_key <= tree->fdb_avl_key, * foreach node in tree->fdb_avl_right: node->fdb_avl_key >= tree->fdb_avl_key. */ int fdb_init(void) { fdb_head.fdb_avl_height = 0; fdb_head.fdb_avl_left = (struct fdb *)0; fdb_head.fdb_avl_right = (struct fdb *)0; fdb_inited = 1; return(0); } struct fdb * br_avl_find_addr(unsigned char addr[6]) { struct fdb * result = NULL; struct fdb * tree; if (!fdb_inited) fdb_init(); #if (DEBUG_AVL) printk("searching for ula %02x:%02x:%02x:%02x:%02x:%02x\n", addr[0], addr[1], addr[2], addr[3], addr[4], addr[5]); #endif /* DEBUG_AVL */ for (tree = &fdb_head ; ; ) { if (tree == avl_br_empty) { #if (DEBUG_AVL) printk("search failed, returning node 0x%x\n", (unsigned int)result); #endif /* DEBUG_AVL */ return result; } #if (DEBUG_AVL) printk("node 0x%x: checking ula %02x:%02x:%02x:%02x:%02x:%02x\n", (unsigned int)tree, tree->ula[0], tree->ula[1], tree->ula[2], tree->ula[3], tree->ula[4], tree->ula[5]); #endif /* DEBUG_AVL */ if (addr_cmp(addr, tree->ula) == 0) { #if (DEBUG_AVL) printk("found node 0x%x\n", (unsigned int)tree); #endif /* DEBUG_AVL */ return tree; } if (addr_cmp(addr, tree->ula) < 0) { tree = tree->fdb_avl_left; } else { tree = tree->fdb_avl_right; } } } /* * Rebalance a tree. * After inserting or deleting a node of a tree we have a sequence of subtrees * nodes[0]..nodes[k-1] such that * nodes[0] is the root and nodes[i+1] = nodes[i]->{fdb_avl_left|fdb_avl_right}. */ static void br_avl_rebalance (struct fdb *** nodeplaces_ptr, int count) { if (!fdb_inited) fdb_init(); for ( ; count > 0 ; count--) { struct fdb ** nodeplace = *--nodeplaces_ptr; struct fdb * node = *nodeplace; struct fdb * nodeleft = node->fdb_avl_left; struct fdb * noderight = node->fdb_avl_right; int heightleft = heightof(nodeleft); int heightright = heightof(noderight); if (heightright + 1 < heightleft) { /* */ /* * */ /* / \ */ /* n+2 n */ /* */ struct fdb * nodeleftleft = nodeleft->fdb_avl_left; struct fdb * nodeleftright = nodeleft->fdb_avl_right; int heightleftright = heightof(nodeleftright); if (heightof(nodeleftleft) >= heightleftright) { /* */ /* * n+2|n+3 */ /* / \ / \ */ /* n+2 n --> / n+1|n+2 */ /* / \ | / \ */ /* n+1 n|n+1 n+1 n|n+1 n */ /* */ node->fdb_avl_left = nodeleftright; nodeleft->fdb_avl_right = node; nodeleft->fdb_avl_height = 1 + (node->fdb_avl_height = 1 + heightleftright); *nodeplace = nodeleft; } else { /* */ /* * n+2 */ /* / \ / \ */ /* n+2 n --> n+1 n+1 */ /* / \ / \ / \ */ /* n n+1 n L R n */ /* / \ */ /* L R */ /* */ nodeleft->fdb_avl_right = nodeleftright->fdb_avl_left; node->fdb_avl_left = nodeleftright->fdb_avl_right; nodeleftright->fdb_avl_left = nodeleft; nodeleftright->fdb_avl_right = node; nodeleft->fdb_avl_height = node->fdb_avl_height = heightleftright; nodeleftright->fdb_avl_height = heightleft; *nodeplace = nodeleftright; } } else if (heightleft + 1 < heightright) { /* similar to the above, just interchange 'left' <--> 'right' */ struct fdb * noderightright = noderight->fdb_avl_right; struct fdb * noderightleft = noderight->fdb_avl_left; int heightrightleft = heightof(noderightleft); if (heightof(noderightright) >= heightrightleft) { node->fdb_avl_right = noderightleft; noderight->fdb_avl_left = node; noderight->fdb_avl_height = 1 + (node->fdb_avl_height = 1 + heightrightleft); *nodeplace = noderight; } else { noderight->fdb_avl_left = noderightleft->fdb_avl_right; node->fdb_avl_right = noderightleft->fdb_avl_left; noderightleft->fdb_avl_right = noderight; noderightleft->fdb_avl_left = node; noderight->fdb_avl_height = node->fdb_avl_height = heightrightleft; noderightleft->fdb_avl_height = heightright; *nodeplace = noderightleft; } } else { int height = (heightleft<heightright ? heightright : heightleft) + 1; if (height == node->fdb_avl_height) break; node->fdb_avl_height = height; } } #ifdef DEBUG_AVL printk_avl(&fdb_head); #endif /* DEBUG_AVL */ } /* Insert a node into a tree. */ int br_avl_insert (struct fdb * new_node) { struct fdb ** nodeplace = fhpp; struct fdb ** stack[avl_maxheight]; int stack_count = 0; struct fdb *** stack_ptr = &stack[0]; /* = &stack[stackcount] */ if (!fdb_inited) fdb_init(); for (;;) { struct fdb *node; node = *nodeplace; if (node == avl_br_empty) break; *stack_ptr++ = nodeplace; stack_count++; if (addr_cmp(new_node->ula, node->ula) == 0) { /* update */ /* * Vova Oksman: There was the BUG, in case that port * was changed we must to update it. */ node->port = new_node->port; node->flags = new_node->flags; node->timer = new_node->timer; return(0); } if (addr_cmp(new_node->ula, node->ula) < 0) { nodeplace = &node->fdb_avl_left; } else { nodeplace = &node->fdb_avl_right; } } #if (DEBUG_AVL) printk("node 0x%x: adding ula %02x:%02x:%02x:%02x:%02x:%02x\n", (unsigned int)new_node, new_node->ula[0], new_node->ula[1], new_node->ula[2], new_node->ula[3], new_node->ula[4], new_node->ula[5]); #endif /* (DEBUG_AVL) */ new_node->fdb_avl_left = avl_br_empty; new_node->fdb_avl_right = avl_br_empty; new_node->fdb_avl_height = 1; *nodeplace = new_node; #if (0) br_avl_rebalance(stack_ptr,stack_count); #endif /* (0) */ #ifdef DEBUG_AVL printk_avl(&fdb_head); #endif /* DEBUG_AVL */ return(1); } /* Removes a node out of a tree. */ int br_avl_remove (struct fdb * node_to_delete) { struct fdb ** nodeplace = fhpp; struct fdb ** stack[avl_maxheight]; int stack_count = 0; struct fdb *** stack_ptr = &stack[0]; /* = &stack[stackcount] */ struct fdb ** nodeplace_to_delete; if (!fdb_inited) fdb_init(); for (;;) { struct fdb * node = *nodeplace; if (node == avl_br_empty) { /* what? node_to_delete not found in tree? */ printk(KERN_ERR "br: avl_remove: node to delete not found in tree\n"); return(-1); } *stack_ptr++ = nodeplace; stack_count++; if (addr_cmp(node_to_delete->ula, node->ula) == 0) break; if (addr_cmp(node_to_delete->ula, node->ula) < 0) nodeplace = &node->fdb_avl_left; else nodeplace = &node->fdb_avl_right; } nodeplace_to_delete = nodeplace; /* Have to remove node_to_delete = *nodeplace_to_delete. */ if (node_to_delete->fdb_avl_left == avl_br_empty) { *nodeplace_to_delete = node_to_delete->fdb_avl_right; stack_ptr--; stack_count--; } else { struct fdb *** stack_ptr_to_delete = stack_ptr; struct fdb ** nodeplace = &node_to_delete->fdb_avl_left; struct fdb * node; for (;;) { node = *nodeplace; if (node->fdb_avl_right == avl_br_empty) break; *stack_ptr++ = nodeplace; stack_count++; nodeplace = &node->fdb_avl_right; } *nodeplace = node->fdb_avl_left; /* node replaces node_to_delete */ node->fdb_avl_left = node_to_delete->fdb_avl_left; node->fdb_avl_right = node_to_delete->fdb_avl_right; node->fdb_avl_height = node_to_delete->fdb_avl_height; *nodeplace_to_delete = node; /* replace node_to_delete */ *stack_ptr_to_delete = &node->fdb_avl_left; /* replace &node_to_delete->fdb_avl_left */ } br_avl_rebalance(stack_ptr,stack_count); return(0); } #ifdef DEBUG_AVL /* print a tree */ static void printk_avl (struct fdb * tree) { if (tree != avl_br_empty) { printk("("); printk("%02x:%02x:%02x:%02x:%02x:%02x", tree->ula[0], tree->ula[1], tree->ula[2], tree->ula[3], tree->ula[4], tree->ula[5]); if (tree->fdb_avl_left != avl_br_empty) { printk_avl(tree->fdb_avl_left); printk("<"); } if (tree->fdb_avl_right != avl_br_empty) { printk(">"); printk_avl(tree->fdb_avl_right); } printk(")\n"); } } #if (0) static char *avl_check_point = "somewhere"; /* check a tree's consistency and balancing */ static void avl_checkheights (struct fdb * tree) { int h, hl, hr; if (tree == avl_br_empty) return; avl_checkheights(tree->fdb_avl_left); avl_checkheights(tree->fdb_avl_right); h = tree->fdb_avl_height; hl = heightof(tree->fdb_avl_left); hr = heightof(tree->fdb_avl_right); if ((h == hl+1) && (hr <= hl) && (hl <= hr+1)) return; if ((h == hr+1) && (hl <= hr) && (hr <= hl+1)) return; printk("%s: avl_checkheights: heights inconsistent\n",avl_check_point); } /* check that all values stored in a tree are < key */ static void avl_checkleft (struct fdb * tree, fdb_avl_key_t key) { if (tree == avl_br_empty) return; avl_checkleft(tree->fdb_avl_left,key); avl_checkleft(tree->fdb_avl_right,key); if (tree->fdb_avl_key < key) return; printk("%s: avl_checkleft: left key %lu >= top key %lu\n",avl_check_point,tree->fdb_avl_key,key); } /* check that all values stored in a tree are > key */ static void avl_checkright (struct fdb * tree, fdb_avl_key_t key) { if (tree == avl_br_empty) return; avl_checkright(tree->fdb_avl_left,key); avl_checkright(tree->fdb_avl_right,key); if (tree->fdb_avl_key > key) return; printk("%s: avl_checkright: right key %lu <= top key %lu\n",avl_check_point,tree->fdb_avl_key,key); } /* check that all values are properly increasing */ static void avl_checkorder (struct fdb * tree) { if (tree == avl_br_empty) return; avl_checkorder(tree->fdb_avl_left); avl_checkorder(tree->fdb_avl_right); avl_checkleft(tree->fdb_avl_left,tree->fdb_avl_key); avl_checkright(tree->fdb_avl_right,tree->fdb_avl_key); } #endif /* (0) */ #endif /* DEBUG_AVL */ int addr_cmp(unsigned char a1[], unsigned char a2[]) { int i; for (i=0; i<6; i++) { if (a1[i] > a2[i]) return(1); if (a1[i] < a2[i]) return(-1); } return(0); }