mirror of
https://github.com/servalproject/serval-dna.git
synced 2024-12-24 07:16:43 +00:00
280 lines
7.8 KiB
C
280 lines
7.8 KiB
C
/*
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Serval DNA
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Copyright (C) 2012-2015 Serval Project Inc.
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Copyright (C) 2016-2018 Flinders University
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This program is free software; you can redistribute it and/or
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modify it under the terms of the GNU General Public License
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as published by the Free Software Foundation; either version 2
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of the License, or (at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program; if not, write to the Free Software
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Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
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*/
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#include <stdint.h>
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#include <unistd.h>
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#include <assert.h>
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#include <string.h>
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#include <strings.h>
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#include "lang.h" // for bool_t
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#include "mem.h"
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#include "nibble_tree.h"
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static unsigned get_nibble(const uint8_t *binary, int pos)
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{
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unsigned byte = binary[pos>>1];
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if (!(pos&1))
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byte=byte>>4;
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return byte&0xF;
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}
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enum tree_error_reason tree_find(struct tree_root *root, void **result, const uint8_t *binary, size_t binary_size_bytes,
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tree_create_callback create_node, void *context)
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{
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assert(binary_size_bytes <= root->index_size_bytes);
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struct tree_node *ptr = &root->_root_node;
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if (result)
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*result = NULL;
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unsigned pos=0;
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while(1) {
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if (pos >= binary_size_bytes * 2)
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return TREE_NOT_UNIQUE;
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unsigned nibble = get_nibble(binary, pos++);
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void *node_ptr = ptr->slot[nibble];
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if (ptr->is_tree & (1<<nibble)){
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// search the next level of the tree
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ptr = (struct tree_node *)node_ptr;
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}else if(!node_ptr){
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// allow caller to provide a node constructor
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if (create_node && binary_size_bytes == root->index_size_bytes){
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node_ptr = create_node(context, binary, binary_size_bytes);
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if (!node_ptr)
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return TREE_ERROR;
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struct tree_record *tree_record = (struct tree_record *)node_ptr;
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assert(memcmp(tree_record->binary, binary, binary_size_bytes) == 0);
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tree_record->binary_size_bits = pos*4;
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if (result)
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*result = node_ptr;
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ptr->slot[nibble] = node_ptr;
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return TREE_FOUND;
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}
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return TREE_NOT_FOUND;
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}else{
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struct tree_record *tree_record = (struct tree_record *)node_ptr;
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// check that the remaining bytes of the value are the same
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if (memcmp(tree_record->binary, binary, binary_size_bytes) == 0){
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if (result)
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*result = node_ptr;
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return TREE_FOUND;
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}
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if (!create_node)
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return TREE_NOT_FOUND;
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// no match? we need to bump this leaf node down a level so we can create a new record
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struct tree_node *new_node = (struct tree_node *) emalloc_zero(sizeof(struct tree_node));
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if (!new_node)
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return TREE_ERROR;
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ptr->slot[nibble] = new_node;
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ptr->is_tree |= (1<<nibble);
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ptr = new_node;
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// get the nibble of the existing node
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nibble = get_nibble(tree_record->binary, pos);
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tree_record->binary_size_bits = (pos+1)*4;
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ptr->slot[nibble] = node_ptr;
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}
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}
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}
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void tree_iterator_start(tree_iterator *it, struct tree_root *root)
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{
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it->stack = &it->bottom;
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it->bottom.down = NULL;
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it->bottom.node = &root->_root_node;
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it->bottom.slotnum = 0;
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root->_root_node.ref_count++;
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}
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static bool_t push(tree_iterator *it)
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{
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assert(it->stack->node->is_tree & (1 << it->stack->slotnum));
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struct tree_node *child = it->stack->node->slot[it->stack->slotnum];
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assert(child);
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tree_node_iterator *nit = (tree_node_iterator *) emalloc_zero(sizeof(tree_node_iterator));
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if (!nit)
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return 0;
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nit->down = it->stack;
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nit->node = child;
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nit->slotnum = 0;
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it->stack = nit;
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child->ref_count++;
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return 1;
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}
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static inline bool_t is_empty(struct tree_node *node)
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{
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unsigned i;
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for (i = 0; i < 16; ++i)
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if (node->slot[i])
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return 0;
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return 1;
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}
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static void pop(tree_iterator *it)
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{
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assert(it->stack);
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assert(it->stack->node->ref_count != 0);
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tree_node_iterator *popped = it->stack;
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it->stack = it->stack->down;
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if (--popped->node->ref_count == 0 && it->stack && is_empty(popped->node)) {
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assert(it->stack->slotnum < 16);
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assert(it->stack->node->is_tree & (1 << it->stack->slotnum));
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assert(it->stack->node->slot[it->stack->slotnum] == popped->node);
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if (it->stack) {
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assert(popped != &it->bottom);
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assert(popped->node != it->bottom.node);
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free(popped->node);
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}
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else {
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assert(popped == &it->bottom);
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assert(popped->node == it->bottom.node);
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}
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popped->node = NULL;
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it->stack->node->slot[it->stack->slotnum] = NULL;
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it->stack->node->is_tree &= ~(1 << it->stack->slotnum);
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}
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if (it->stack) {
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free(popped);
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it->stack->slotnum++;
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}
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else
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assert(popped == &it->bottom);
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}
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void tree_iterator_advance_to(tree_iterator *it, const uint8_t *binary, size_t binary_size_bytes)
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{
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// can only call this function once on an iterator, straight after tree_iterator_start()
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assert(it->stack == &it->bottom);
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assert(it->stack->slotnum == 0);
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assert(it->stack->node);
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unsigned n;
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for (n = 0; n < binary_size_bytes * 2; ++n) {
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it->stack->slotnum = get_nibble(binary, n);
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if (!((it->stack->node->is_tree & (1 << it->stack->slotnum)) && push(it)))
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break;
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}
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}
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void **tree_iterator_get_node(tree_iterator *it)
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{
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while (it->stack) {
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if (it->stack->slotnum < 16) {
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if (it->stack->node->is_tree & (1 << it->stack->slotnum)) {
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if (!push(it))
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return NULL;
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}
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else {
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void **childp = &it->stack->node->slot[it->stack->slotnum];
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if (*childp)
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return childp;
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else
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it->stack->slotnum++;
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}
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}
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else {
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assert(it->stack->slotnum == 16);
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pop(it);
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}
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}
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return NULL;
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}
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void tree_iterator_advance(tree_iterator *it)
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{
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if (tree_iterator_get_node(it)) {
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assert(it->stack);
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assert(it->stack->slotnum < 16);
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it->stack->slotnum++;
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}
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}
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void tree_iterator_free(tree_iterator *it)
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{
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while (it->stack)
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pop(it);
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}
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// start enumerating the tree from binary, and continue until the end
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// callback is allowed to free any nodes while the walk is in progress
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int tree_walk(struct tree_root *root, const uint8_t *binary, size_t binary_size_bytes, walk_callback callback, void *context)
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{
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int ret = 0;
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tree_iterator it;
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tree_iterator_start(&it, root);
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if (binary) {
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assert(binary_size_bytes <= root->index_size_bytes);
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tree_iterator_advance_to(&it, binary, binary_size_bytes);
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}
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void **node;
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while ((node = tree_iterator_get_node(&it)) && (ret = callback(node, context)) == 0)
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tree_iterator_advance(&it);
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tree_iterator_free(&it);
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return ret;
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}
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int tree_walk_prefix(struct tree_root *root, const uint8_t *binary, size_t binary_size_bytes, walk_callback callback, void *context)
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{
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assert(binary);
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assert(binary_size_bytes <= root->index_size_bytes);
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int ret = 0;
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tree_iterator it;
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tree_iterator_start(&it, root);
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tree_iterator_advance_to(&it, binary, binary_size_bytes);
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void **node;
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while ( (node = tree_iterator_get_node(&it))
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&& memcmp(((struct tree_record *)*node)->binary, binary, binary_size_bytes) == 0
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&& (ret = callback(node, context)) == 0)
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tree_iterator_advance(&it);
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tree_iterator_free(&it);
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return ret;
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}
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static void walk_statistics(struct tree_node *node, unsigned depth, struct tree_statistics *stats)
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{
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stats->node_count++;
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if (depth > stats->maximum_depth)
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stats->maximum_depth = depth;
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if (is_empty(node))
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stats->empty_node_count++;
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unsigned i;
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for (i = 0; i < 16; ++i)
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if (node->is_tree & (1 << i))
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walk_statistics(node->slot[i], depth + 1, stats);
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else if (node->slot[i])
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stats->record_count++;
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}
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struct tree_statistics tree_compute_statistics(struct tree_root *root)
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{
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struct tree_statistics stats;
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bzero(&stats, sizeof stats);
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walk_statistics(&root->_root_node, 0, &stats);
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return stats;
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}
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