mirror of
https://github.com/servalproject/serval-dna.git
synced 2024-12-18 20:57:56 +00:00
Add nibble-tree iterator
The new struct tree_iterator and associated start/get/next/free functions replace the recursive walk() function, removing the need for a callback when iterating over all nodes in the tree, and allowing iteration to be suspended while other pseudo-threads are run. This allows an HTTP REST request to keep a tree_iterator in its state struct and potentially simplifies other areas of the code. The iterator free()s any empty internal tree nodes that it encounters, as did the original tree_walk() function. To support the existence of multiple iterators at once, a reference count has been added to the tree_node struct, to prevent any iterator from free()ing a node while any other iterators point to it; only the last iterator to pop out of an empty node will free() it. The tree_walk() and tree_walk_prefix() functions have been re-implemented to use an iterator state object internally. This resolves an outstanding TODO to perform tree-node freeing during a prefix walk, and simplifies the code considerably. Renamed some function parameters and struct members to make the nibble-tree API a little more self-explanatory. Added a nibble-tree test to the 'serval-tests' utility.
This commit is contained in:
parent
2ef315b692
commit
c7a2fb4573
@ -409,7 +409,9 @@ servaldwrap: $(OBJSDIR_SERVALD)/servalwrap.o
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@echo LINK $@
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@$(CC) -Wall -o $@ $^ $(LDFLAGS)
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serval-tests: $(OBJSDIR_SERVALD)/test_features.o libservaldaemon.a
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serval-tests: $(OBJSDIR_SERVALD)/test_features.o \
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$(OBJSDIR_SERVALD)/log_output_console.o \
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libservaldaemon.a
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@echo LINK $@
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@$(CC) -Wall -o $@ $^ $(LDFLAGS)
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2
meshmb.c
2
meshmb.c
@ -640,7 +640,7 @@ int meshmb_open(keyring_identity *id, struct meshmb_feeds **feeds)
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*feeds = emalloc_zero(sizeof(struct meshmb_feeds));
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if (*feeds){
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(*feeds)->root.binary_length = sizeof(rhizome_bid_t);
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(*feeds)->root.index_size_bytes = sizeof(rhizome_bid_t);
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(*feeds)->id = id;
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rhizome_manifest *m = rhizome_new_manifest();
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if (m){
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253
nibble_tree.c
253
nibble_tree.c
@ -1,7 +1,7 @@
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/*
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Serval DNA
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Copyright (C) 2012-2015 Serval Project Inc.
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Copyright (C) 2016 Flinders University
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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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@ -22,21 +22,22 @@ Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
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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 "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 uint8_t get_nibble(const uint8_t *binary, int pos)
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static unsigned get_nibble(const uint8_t *binary, int pos)
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{
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uint8_t byte = binary[pos>>1];
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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 bin_length,
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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(bin_length <= root->binary_length);
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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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@ -44,11 +45,11 @@ enum tree_error_reason tree_find(struct tree_root *root, void **result, const ui
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unsigned pos=0;
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while(1) {
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if (pos>>1 >= bin_length)
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if (pos >= binary_size_bytes * 2)
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return TREE_NOT_UNIQUE;
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uint8_t nibble = get_nibble(binary, pos++);
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void *node_ptr = ptr->tree_nodes[nibble];
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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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@ -56,16 +57,16 @@ enum tree_error_reason tree_find(struct tree_root *root, void **result, const ui
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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 && bin_length == root->binary_length){
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node_ptr = create_node(context, binary, bin_length);
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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, bin_length) == 0);
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tree_record ->tree_depth = pos*4;
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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->tree_nodes[nibble] = 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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@ -74,7 +75,7 @@ enum tree_error_reason tree_find(struct tree_root *root, void **result, const ui
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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, bin_length) == 0){
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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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@ -88,88 +89,190 @@ enum tree_error_reason tree_find(struct tree_root *root, void **result, const ui
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if (!new_node)
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return TREE_ERROR;
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ptr->tree_nodes[nibble] = new_node;
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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->tree_depth = (pos+1)*4;
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ptr->tree_nodes[nibble] = node_ptr;
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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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static int walk(struct tree_node *node, unsigned pos,
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uint8_t *empty, const uint8_t *binary, size_t bin_length,
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walk_callback callback, void *context){
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unsigned i=0, e=16;
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int ret=0;
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*empty=1;
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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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if (binary){
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assert(pos*2 < bin_length);
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uint8_t n = get_nibble(binary, pos);
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for(;i<n;i++){
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if (node->tree_nodes[i]){
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*empty=0;
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break;
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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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}
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for (;i<e;i++){
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if (node->is_tree & (1<<i)){
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uint8_t child_empty=1;
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ret = walk((struct tree_node *)node->tree_nodes[i], pos+1, &child_empty, binary, bin_length, callback, context);
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if (child_empty){
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free(node->tree_nodes[i]);
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node->tree_nodes[i]=NULL;
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node->is_tree&=~(1<<i);
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}
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}else if(node->tree_nodes[i]){
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ret = callback(&node->tree_nodes[i], context);
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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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if (ret)
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return ret;
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if (node->tree_nodes[i])
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*empty=0;
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// stop comparing the start binary after looking at the first branch of the tree
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binary=NULL;
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}
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return NULL;
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}
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return ret;
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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 bin_length, walk_callback callback, void *context)
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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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assert(!binary || bin_length <= root->binary_length);
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uint8_t ignore;
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return walk(&root->_root_node, 0, &ignore, binary, bin_length, callback, context);
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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 bin_length, walk_callback callback, void *context)
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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(bin_length <= root->binary_length);
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//TODO if callback free's nodes, collapse parent tree nodes too without needing to walk again?
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struct tree_node *node = &root->_root_node;
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unsigned pos=0;
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// look for a branch of the tree with a partial match
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for (; node && pos<bin_length*2; pos++){
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uint8_t i=get_nibble(binary, pos);
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if ((node->is_tree & (1<<i))==0){
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struct tree_record *tree_record = (struct tree_record *)node->tree_nodes[i];
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// only one match?
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if (tree_record && memcmp(tree_record->binary, binary, bin_length)==0){
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return callback(&node->tree_nodes[i], context);
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}
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return 0;
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}
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node = node->tree_nodes[i];
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}
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// walk the whole branch
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uint8_t ignore;
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return walk(node, pos+1, &ignore, NULL, 0, callback, context);
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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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120
nibble_tree.h
120
nibble_tree.h
@ -1,7 +1,7 @@
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/*
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Serval DNA
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Copyright (C) 2012-2015 Serval Project Inc.
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Copyright (C) 2016 Flinders University
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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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@ -23,22 +23,38 @@ Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
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#include <stdint.h> // for uint8_t, size_t
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struct tree_record{
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// number of bits of the binary value, to uniquely identify this record within the tree's current contents
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size_t tree_depth;
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// Every record in a nibble tree has the following structure:
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// - a count of the number of bits in the binary index
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// - the binary index itself, consisting of the number of bytes as specified by
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// root.binary_size_bytes
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// - the rest of the record
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struct tree_record {
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size_t binary_size_bits;
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uint8_t binary[0];
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};
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// each node has 16 slots based on the next 4 bits of the binary value
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// each slot either points to another tree node or a data record
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struct tree_node{
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// bit flags for the type of object each element points to
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// Each node in the nibble tree has 16 slots based on the next 4 bits of the
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// binary value.
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struct tree_node {
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// A reference count that is incremented by an iterator while it has a
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// pointer to the node, and decremented when it discards the pointer. The
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// iterator free()s the node if its count decrements to zero and all of its
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// slots are NULL. This prevents nodes being free()d while in-use.
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unsigned ref_count;
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// A bitmask that has tbe bit (1 << slot_number) set if the corresponding
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// slot points to a sub-tree.
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uint16_t is_tree;
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void *tree_nodes[16];
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// Each slot either points to another tree node or a data record, depending
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// on its corresponding bit in 'is_tree'.
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void *slot[16];
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};
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struct tree_root{
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size_t binary_length;
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// The root of a nibble tree specifies the binary index size, in bytes, and
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// contains the root node.
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struct tree_root {
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size_t index_size_bytes;
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struct tree_node _root_node;
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};
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@ -49,28 +65,94 @@ enum tree_error_reason {
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TREE_FOUND = 0
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};
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// allocate a new record and return it
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// the returned memory buffer *must* begin with the same memory layout as struct tree_record
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typedef void* (*tree_create_callback) (void *context, const uint8_t *binary, size_t bin_length);
|
||||
typedef void* (*tree_create_callback) (void *context, const uint8_t *binary, size_t binary_size_bytes);
|
||||
|
||||
// find the record related to the given binary value
|
||||
// if not found, the supplied not_found function will be called
|
||||
// if not found, the supplied create_node function will be called
|
||||
// if the callback returns a non-null value it will be inserted into the tree
|
||||
// returns either the current depth in the tree or a tree_error_reason
|
||||
enum tree_error_reason tree_find(struct tree_root *root, void **result, const uint8_t *binary, size_t bin_length,
|
||||
enum tree_error_reason tree_find(struct tree_root *root, void **result, const uint8_t *binary, size_t binary_size_bytes,
|
||||
tree_create_callback create_node, void *context);
|
||||
|
||||
// Iteration:
|
||||
//
|
||||
// tree_iterator it;
|
||||
// tree_iterator_advance_to(&it, index, sizeof index); // optional
|
||||
// node_type **node;
|
||||
// for (tree_iterator_start(&it, root); (node = tree_iterator_get_node(&it)); tree_iterator_advance(&it)) {
|
||||
// ..
|
||||
// }
|
||||
// tree_iterator_free(&it);
|
||||
//
|
||||
// An iterator advances through nodes in order of ascending binary index.
|
||||
//
|
||||
// The tree_iterator_get_node() function returns the same pointer on all
|
||||
// successive invocations until tree_iterator_advance() is called, and returns
|
||||
// NULL once the iterator has been advanced past the last node.
|
||||
//
|
||||
// The tree_iterator_advance_to() function rapidly positions the iterator at
|
||||
// the first node whose binary index is >= the given binary index. This
|
||||
// function can only be called once, straight after tree_iterator_start().
|
||||
//
|
||||
// Deletion:
|
||||
//
|
||||
// tree_iterator it;
|
||||
// tree_iterator_start(&it, root);
|
||||
// ...
|
||||
// node_type **node = tree_iterator_get_node(&it));
|
||||
// *node = NULL;
|
||||
// node = tree_iterator_get_node(&it)); // returns the next node
|
||||
// ...
|
||||
// tree_iterator_free(&it);
|
||||
//
|
||||
// The tree_iterator_get_node(), tree_iterator_advance() and
|
||||
// tree_iterator_free() functions all free() empty nodes as long as no other
|
||||
// iterator is currently traversing the node. If there are several iterators
|
||||
// positioned within an empty node, then only the last one to advance out of it
|
||||
// will free() the node.
|
||||
|
||||
typedef struct tree_node_iterator {
|
||||
struct tree_node_iterator *down;
|
||||
struct tree_node *node;
|
||||
unsigned slotnum;
|
||||
} tree_node_iterator;
|
||||
|
||||
typedef struct tree_iterator {
|
||||
struct tree_node_iterator bottom;
|
||||
struct tree_node_iterator *stack;
|
||||
} tree_iterator;
|
||||
|
||||
void tree_iterator_start(tree_iterator *it, struct tree_root *root);
|
||||
void tree_iterator_advance_to(tree_iterator *it, const uint8_t *binary, size_t binary_size_bytes);
|
||||
void **tree_iterator_get_node(tree_iterator *it);
|
||||
void tree_iterator_advance(tree_iterator *it);
|
||||
void tree_iterator_free(tree_iterator *it);
|
||||
|
||||
// The following legacy API functions are now implemented using iterators.
|
||||
|
||||
// callback function for walking the tree
|
||||
// return 0 to continue enumeration, anything else to stop
|
||||
// set (*record) to null to indicate that memory has been released and the node should be removed from the tree
|
||||
typedef int (*walk_callback) (void **record, void *context);
|
||||
|
||||
// walk the tree, calling walk_callback for each node.
|
||||
// if binary & bin_length have been supplied, skip all records <= this binary value
|
||||
int tree_walk(struct tree_root *root, const uint8_t *binary, size_t bin_length, walk_callback callback, void *context);
|
||||
// if binary & binary_size_bytes have been supplied, skip all records < this binary value
|
||||
int tree_walk(struct tree_root *root, const uint8_t *binary, size_t binary_size_bytes, walk_callback callback, void *context);
|
||||
|
||||
// walk the tree where nodes match the prefix binary / bin_length
|
||||
int tree_walk_prefix(struct tree_root *root, const uint8_t *binary, size_t bin_length, walk_callback callback, void *context);
|
||||
// walk the tree where nodes match the prefix binary / binary_size_bytes
|
||||
int tree_walk_prefix(struct tree_root *root, const uint8_t *binary, size_t binary_size_bytes, walk_callback callback, void *context);
|
||||
|
||||
// Tree statistics.
|
||||
|
||||
struct tree_statistics {
|
||||
size_t record_count;
|
||||
size_t node_count;
|
||||
size_t empty_node_count;
|
||||
size_t maximum_depth;
|
||||
};
|
||||
|
||||
struct tree_statistics tree_compute_statistics(struct tree_root *root);
|
||||
|
||||
#endif // __SERVAL_DNA__NIBBLE_TREE_H
|
||||
|
@ -52,7 +52,7 @@ static struct broadcast bpilist[MAX_BPIS];
|
||||
#define OA_CODE_P2P_ME 0xfc
|
||||
#define OA_CODE_SIGNKEY 0xfb // full sign key of an identity, from which a SID can be derived
|
||||
|
||||
static __thread struct tree_root root={.binary_length=SID_SIZE};
|
||||
static __thread struct tree_root root={.index_size_bytes=SID_SIZE};
|
||||
|
||||
static __thread struct subscriber *my_subscriber=NULL;
|
||||
|
||||
|
206
test_cli.c
206
test_cli.c
@ -1,6 +1,7 @@
|
||||
/*
|
||||
Serval testing command line functions
|
||||
Copyright (C) 2014 Serval Project Inc.
|
||||
Copyright (C) 2018 Flinders University
|
||||
|
||||
This program is free software; you can redistribute it and/or
|
||||
modify it under the terms of the GNU General Public License
|
||||
@ -34,6 +35,7 @@
|
||||
#include "mem.h"
|
||||
#include "str.h"
|
||||
#include "debug.h"
|
||||
#include "nibble_tree.h"
|
||||
|
||||
DEFINE_FEATURE(cli_tests);
|
||||
|
||||
@ -323,3 +325,207 @@ static int app_config_test(const struct cli_parsed *UNUSED(parsed), struct cli_c
|
||||
}
|
||||
return 0;
|
||||
}
|
||||
|
||||
// Nibble Tree test
|
||||
|
||||
#define ASSERT(C) do { if (!(C)) FATALF("(%s)", #C); } while (0)
|
||||
#define ASSERTF(C,F,...) do { if (!(C)) FATALF("(%s) " F, "" #C, ##__VA_ARGS__); } while (0)
|
||||
|
||||
struct data {
|
||||
uint8_t binary[4];
|
||||
};
|
||||
|
||||
struct node {
|
||||
size_t nbits;
|
||||
struct data data;
|
||||
};
|
||||
|
||||
static void *create_node_callback(void *context, const uint8_t *binary, size_t binary_size_bytes)
|
||||
{
|
||||
ASSERT(binary_size_bytes == sizeof(struct data));
|
||||
struct node *ret = (struct node *) emalloc_zero(sizeof(struct node));
|
||||
ASSERT(ret);
|
||||
ret->data = *(const struct data *)binary;
|
||||
*(struct node **)context = ret;
|
||||
return ret;
|
||||
}
|
||||
|
||||
static struct node *create_node(struct tree_root *root, uint32_t index) {
|
||||
uint8_t binary[4] = { index >> 24, index >> 16, index >> 8, index };
|
||||
struct node *result = NULL;
|
||||
struct node *created_node = NULL;
|
||||
tree_find(root, (void**)&result, binary, 4, create_node_callback, &created_node);
|
||||
ASSERT(result);
|
||||
ASSERT(created_node);
|
||||
ASSERTF(created_node == result, "created_node=%p, result=%p", created_node, result);
|
||||
ASSERTF(memcmp(result->data.binary, binary, 4) == 0,
|
||||
"result->data.binary=%s, should be %s",
|
||||
alloca_tohex(result->data.binary, sizeof result->data.binary),
|
||||
alloca_tohex(binary, sizeof binary));
|
||||
DEBUGF(verbose, "created %s -> %p, nbits=%zu", alloca_tohex(binary, sizeof binary), result, result->nbits);
|
||||
return created_node;
|
||||
}
|
||||
|
||||
static void advance_to(tree_iterator *it, uint32_t index, size_t bytes) {
|
||||
uint8_t binary[4] = { index >> 24, index >> 16, index >> 8, index };
|
||||
assert(bytes <= sizeof binary);
|
||||
DEBUGF(verbose, "advance to %s", alloca_tohex(binary, bytes));
|
||||
tree_iterator_advance_to(it, binary, bytes);
|
||||
}
|
||||
|
||||
static void assert_current_node(tree_iterator *it, struct node *node) {
|
||||
DEBUGF(verbose, "assert that current node is %p", node);
|
||||
struct node **current = (struct node **) tree_iterator_get_node(it);
|
||||
if (node) {
|
||||
ASSERT(current);
|
||||
ASSERTF(*current == node, "*current=%p, should be %p", *current, node);
|
||||
}
|
||||
else {
|
||||
ASSERTF(current == NULL, "*current=%p, should be NULL", *current);
|
||||
}
|
||||
}
|
||||
|
||||
static void delete_current_node(tree_iterator *it) {
|
||||
struct node **node = (struct node **) tree_iterator_get_node(it);
|
||||
ASSERT(node);
|
||||
ASSERT(*node);
|
||||
struct data data = (*node)->data; // copy
|
||||
free(*node);
|
||||
*node = NULL;
|
||||
DEBUGF(verbose, "deleted %s", alloca_tohex(data.binary, sizeof data.binary));
|
||||
}
|
||||
|
||||
DEFINE_CMD(app_nibble_tree_test, 0,
|
||||
"Run nibble tree test",
|
||||
"test","nibble-tree");
|
||||
static int app_nibble_tree_test(const struct cli_parsed *UNUSED(parsed), struct cli_context *UNUSED(context))
|
||||
{
|
||||
struct tree_root root = {.index_size_bytes = sizeof(struct data)};
|
||||
struct tree_statistics stats;
|
||||
tree_iterator it;
|
||||
// Creation.
|
||||
struct node *node1 = create_node(&root, 0x12345670);
|
||||
stats = tree_compute_statistics(&root);
|
||||
ASSERTF(stats.record_count == 1, "record_count=%zu", stats.record_count);
|
||||
ASSERTF(stats.node_count == 1, "node_count=%zu", stats.node_count);
|
||||
ASSERTF(stats.empty_node_count == 0, "empty_node_count=%zu", stats.empty_node_count);
|
||||
ASSERTF(stats.maximum_depth == 0, "maximum_depth=%zu", stats.maximum_depth);
|
||||
struct node *node2 = create_node(&root, 0x12345671);
|
||||
stats = tree_compute_statistics(&root);
|
||||
ASSERTF(stats.record_count == 2, "record_count=%zu", stats.record_count);
|
||||
ASSERTF(stats.node_count == 8, "node_count=%zu", stats.node_count);
|
||||
ASSERTF(stats.empty_node_count == 0, "empty_node_count=%zu", stats.empty_node_count);
|
||||
ASSERTF(stats.maximum_depth == 7, "maximum_depth=%zu", stats.maximum_depth);
|
||||
struct node *node3 = create_node(&root, 0x12345672);
|
||||
stats = tree_compute_statistics(&root);
|
||||
ASSERTF(stats.record_count == 3, "record_count=%zu", stats.record_count);
|
||||
ASSERTF(stats.node_count == 8, "node_count=%zu", stats.node_count);
|
||||
ASSERTF(stats.empty_node_count == 0, "empty_node_count=%zu", stats.empty_node_count);
|
||||
ASSERTF(stats.maximum_depth == 7, "maximum_depth=%zu", stats.maximum_depth);
|
||||
struct node *node4 = create_node(&root, 0x01234567);
|
||||
stats = tree_compute_statistics(&root);
|
||||
ASSERTF(stats.record_count == 4, "record_count=%zu", stats.record_count);
|
||||
ASSERTF(stats.node_count == 8, "node_count=%zu", stats.node_count);
|
||||
ASSERTF(stats.empty_node_count == 0, "empty_node_count=%zu", stats.empty_node_count);
|
||||
ASSERTF(stats.maximum_depth == 7, "maximum_depth=%zu", stats.maximum_depth);
|
||||
struct node *node5 = create_node(&root, 0x23456789);
|
||||
stats = tree_compute_statistics(&root);
|
||||
ASSERTF(stats.record_count == 5, "record_count=%zu", stats.record_count);
|
||||
ASSERTF(stats.node_count == 8, "node_count=%zu", stats.node_count);
|
||||
ASSERTF(stats.empty_node_count == 0, "empty_node_count=%zu", stats.empty_node_count);
|
||||
ASSERTF(stats.maximum_depth == 7, "maximum_depth=%zu", stats.maximum_depth);
|
||||
// Simple iteration through all nodes in order.
|
||||
tree_iterator_start(&it, &root);
|
||||
assert_current_node(&it, node4);
|
||||
tree_iterator_advance(&it);
|
||||
assert_current_node(&it, node1);
|
||||
tree_iterator_advance(&it);
|
||||
assert_current_node(&it, node2);
|
||||
assert_current_node(&it, node2);
|
||||
tree_iterator_advance(&it);
|
||||
assert_current_node(&it, node3);
|
||||
tree_iterator_advance(&it);
|
||||
assert_current_node(&it, node5);
|
||||
assert_current_node(&it, node5);
|
||||
tree_iterator_advance(&it);
|
||||
assert_current_node(&it, NULL);
|
||||
assert_current_node(&it, NULL);
|
||||
tree_iterator_advance(&it);
|
||||
assert_current_node(&it, NULL);
|
||||
tree_iterator_free(&it);
|
||||
// Simple iteration through all nodes after a given starting point.
|
||||
tree_iterator_start(&it, &root);
|
||||
advance_to(&it, 0x12345672, 4);
|
||||
assert_current_node(&it, node3);
|
||||
tree_iterator_advance(&it);
|
||||
assert_current_node(&it, node5);
|
||||
tree_iterator_advance(&it);
|
||||
assert_current_node(&it, NULL);
|
||||
tree_iterator_free(&it);
|
||||
// Simple advance to a prefix starting point.
|
||||
tree_iterator_start(&it, &root);
|
||||
advance_to(&it, 0x12340000, 2);
|
||||
assert_current_node(&it, node1);
|
||||
tree_iterator_advance(&it);
|
||||
assert_current_node(&it, node2);
|
||||
tree_iterator_advance(&it);
|
||||
assert_current_node(&it, node3);
|
||||
tree_iterator_advance(&it);
|
||||
assert_current_node(&it, node5);
|
||||
tree_iterator_advance(&it);
|
||||
assert_current_node(&it, NULL);
|
||||
tree_iterator_free(&it);
|
||||
// Delete a record from a node, leaving it non-empty.
|
||||
tree_iterator_start(&it, &root);
|
||||
advance_to(&it, 0x12345672, 4);
|
||||
assert_current_node(&it, node3);
|
||||
delete_current_node(&it);
|
||||
node3 = NULL;
|
||||
stats = tree_compute_statistics(&root);
|
||||
ASSERTF(stats.record_count == 4, "record_count=%zu", stats.record_count);
|
||||
ASSERTF(stats.node_count == 8, "node_count=%zu", stats.node_count);
|
||||
ASSERTF(stats.empty_node_count == 0, "empty_node_count=%zu", stats.empty_node_count);
|
||||
ASSERTF(stats.maximum_depth == 7, "maximum_depth=%zu", stats.maximum_depth);
|
||||
tree_iterator_free(&it);
|
||||
// Delete records from a node, leaving it empty. A second iterator positioned in the node
|
||||
// prevents the node from being free()d until it advances.
|
||||
tree_iterator it2;
|
||||
tree_iterator_start(&it2, &root);
|
||||
advance_to(&it2, 0x12345670, 4);
|
||||
assert_current_node(&it2, node1);
|
||||
//
|
||||
tree_iterator_start(&it, &root);
|
||||
advance_to(&it, 0x12345670, 4);
|
||||
assert_current_node(&it, node1);
|
||||
delete_current_node(&it);
|
||||
node1 = NULL;
|
||||
stats = tree_compute_statistics(&root);
|
||||
ASSERTF(stats.record_count == 3, "record_count=%zu", stats.record_count);
|
||||
ASSERTF(stats.node_count == 8, "node_count=%zu", stats.node_count);
|
||||
ASSERTF(stats.empty_node_count == 0, "empty_node_count=%zu", stats.empty_node_count);
|
||||
ASSERTF(stats.maximum_depth == 7, "maximum_depth=%zu", stats.maximum_depth);
|
||||
assert_current_node(&it, node2); // node is not empty yet
|
||||
assert_current_node(&it2, node2);
|
||||
delete_current_node(&it); // makes the node empty
|
||||
node2 = NULL;
|
||||
stats = tree_compute_statistics(&root);
|
||||
ASSERTF(stats.record_count == 2, "record_count=%zu", stats.record_count);
|
||||
ASSERTF(stats.node_count == 8, "node_count=%zu", stats.node_count);
|
||||
ASSERTF(stats.empty_node_count == 1, "empty_node_count=%zu", stats.empty_node_count);
|
||||
ASSERTF(stats.maximum_depth == 7, "maximum_depth=%zu", stats.maximum_depth);
|
||||
assert_current_node(&it, node5); // does not free() the empty node
|
||||
stats = tree_compute_statistics(&root);
|
||||
ASSERTF(stats.record_count == 2, "record_count=%zu", stats.record_count);
|
||||
ASSERTF(stats.node_count == 8, "node_count=%zu", stats.node_count);
|
||||
ASSERTF(stats.empty_node_count == 1, "empty_node_count=%zu", stats.empty_node_count);
|
||||
ASSERTF(stats.maximum_depth == 7, "maximum_depth=%zu", stats.maximum_depth);
|
||||
assert_current_node(&it2, node5); // free()s the empty node
|
||||
stats = tree_compute_statistics(&root);
|
||||
ASSERTF(stats.record_count == 2, "record_count=%zu", stats.record_count);
|
||||
ASSERTF(stats.node_count == 1, "node_count=%zu", stats.node_count);
|
||||
ASSERTF(stats.empty_node_count == 0, "empty_node_count=%zu", stats.empty_node_count);
|
||||
ASSERTF(stats.maximum_depth == 0, "maximum_depth=%zu", stats.maximum_depth);
|
||||
tree_iterator_free(&it2);
|
||||
tree_iterator_free(&it);
|
||||
return 0;
|
||||
}
|
||||
|
Loading…
Reference in New Issue
Block a user