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buffered_tree.c
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buffered_tree.c
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#include <stdlib.h>
#include <stdint.h>
#include <assert.h>
#include <string.h>
#include <stdio.h>
#include "buffered_tree.h"
struct container {
struct payload *payload_first;
uint32_t payload_size;
struct node *child;
};
struct node {
struct node *parent;
struct container **containers;
uint32_t container_count;
uint32_t container_size;
};
struct bftree {
struct node *root;
struct bftree_opts *opts;
uint32_t height;
int is_migrated;
uint32_t del_payload_count;
uint32_t put_payload_count;
};
struct bftree_iterator {
struct bftree *tree;
struct payload *next;
int closed;
};
static struct container *container_insert(struct bftree *tree, struct node *node,
uint32_t container_idx, struct payload *new_payload);
void bftree_node_print(struct node *node);
static void validate_containers(struct node *node, key_compare_func compare);
struct payload *payload_create(void *key, void *val, enum payload_type type)
{
struct payload *payload;
payload = malloc(sizeof(*payload));
payload->key = key;
payload->val = val;
payload->next = NULL;
payload->type = type;
return payload;
}
void payload_free(struct bftree *tree, struct payload *payload, int nofree)
{
if (payload->key && tree->opts->key_destructor)
tree->opts->key_destructor(payload->key);
if (payload->val && tree->opts->val_destructor && !nofree)
tree->opts->val_destructor(payload->val);
if (payload->type == Put)
tree->put_payload_count--;
else
tree->del_payload_count--;
free(payload);
}
void payload_replace(struct bftree *tree, struct payload *older, struct payload *newer)
{
void *temp;
temp = older->val;
older->val = newer->val;
newer->val = temp;
older->type = newer->type;
payload_free(tree, newer, 0);
}
struct container *container_create()
{
struct container *container;
container = malloc(sizeof(*container));
container->payload_first = NULL;
container->payload_size = 0;
container->child = NULL;
return container;
}
void container_free(struct bftree *tree, struct container *container)
{
struct payload *curr, *next;
curr = container->payload_first;
while (curr) {
next = curr->next;
payload_free(tree, curr, 0);
curr = next;
}
free(container);
}
void insert_after_container(struct node *node, struct container *container,
uint32_t container_idx)
{
if (node->container_size == node->container_count) {
node->containers = realloc(node->containers, sizeof(void*)*node->container_count*2);
node->container_count *= 2;
}
if (node->container_size == 0) {
node->containers[node->container_size++] = container;
} else {
memmove(&node->containers[container_idx+2], &node->containers[container_idx+1],
(node->container_size-container_idx-1)*sizeof(void*));
node->containers[container_idx+1] = container;
node->container_size++;
}
}
struct node *node_create(struct node *parent_node)
{
struct node *node;
node = malloc(sizeof(*node));
node->parent = parent_node;
node->containers = malloc(sizeof(struct container*)*BFTREE_DEFAULT_CONTAINER);
node->container_count = BFTREE_DEFAULT_CONTAINER;
node->container_size = 0;
return node;
}
void node_free(struct bftree *tree, struct node *node)
{
int i;
struct container *container;
for (i = 0; i < node->container_size; i++) {
container = node->containers[i];
container_free(tree, container);
}
free(node->containers);
free(node);
}
void bftree_free_node(struct bftree *tree, struct node *node)
{
int i;
struct container *container;
for (i = 0; i < node->container_size; i++) {
container = node->containers[i];
if (container->child)
bftree_free_node(tree, container->child);
}
node_free(tree, node);
}
static uint32_t find_container(key_compare_func compare, struct node *node,
void *key, uint32_t start_container)
{
int left, right, middle, result, compared;
struct container **containers;
left = start_container;
right = node->container_size - 1;
containers = node->containers;
compared = 0;
while (left <= right) {
middle = (left + right) / 2;
compared = compare(key, containers[middle]->payload_first->key);
if (compared < 0) {
right = middle - 1;
} else if (compared > 0) {
left = middle + 1;
} else {
right = middle;
break ;
}
}
if (compared > 0)
result = left - 1;
else if (compared < 0)
result = right;
else
result = right;
if (result == 0)
return 0;
return right - 1;
}
static struct container *remove_container(struct node *node, uint32_t idx)
{
struct container *removed;
removed = node->containers[idx];
memmove(&node->containers[idx], &node->containers[idx+1],
(node->container_size-idx-1)*sizeof(void*));
node->container_size--;
return removed;
}
static struct payload *get_payload(key_compare_func compare, struct payload *payload_start,
void *key, int *is_equal)
{
struct payload *curr_payload, *prev_payload;
int compared;
prev_payload = NULL;
curr_payload = payload_start;
*is_equal = 0;
while (curr_payload) {
compared = compare(key, curr_payload->key);
if (compared <= 0) {
if (compared == 0) {
*is_equal = 1;
return curr_payload;
}
return prev_payload;
}
prev_payload = curr_payload;
curr_payload = curr_payload->next;
}
return prev_payload;
}
static void push_to_child(struct bftree *tree, struct node *node,
struct container *container)
{
struct payload *curr_payload, *next_payload;
uint32_t child_container, push_count;
key_compare_func compare;
compare = tree->opts->key_compare;
curr_payload = container->payload_first->next;
child_container = 0;
push_count = container->payload_size / 2;
container->payload_size -= push_count;
while (push_count--) {
next_payload = curr_payload->next;
container->payload_first->next = next_payload;
child_container = find_container(compare, container->child,
curr_payload->key, child_container);
container_insert(tree, container->child, child_container, curr_payload);
curr_payload = next_payload;
}
}
static void order_container_payload(struct bftree *tree, struct node *node,
uint32_t migrated_idx, uint32_t import_idx)
{
struct payload *separator, *curr;
key_compare_func compare;
int is_equal;
struct container *left, *right;
left = node->containers[migrated_idx];
right = node->containers[import_idx];
compare = tree->opts->key_compare;
separator = get_payload(compare, left->payload_first,
right->payload_first->key, &is_equal);
if (is_equal) {
// TODO need optimize
struct payload *prev;
prev = left->payload_first;
while (prev->next != separator) {
prev = prev->next;
}
payload_replace(tree, right->payload_first, separator);
separator = prev;
left->payload_size--;
}
if (separator) {
curr = separator->next;
separator->next = NULL;
tree->is_migrated = 1;
while (curr) {
left->payload_size--;
container_insert(tree, node, import_idx, curr);
curr = curr->next;
}
tree->is_migrated = 0;
}
}
static void try_split_node(struct bftree *tree, struct node *node)
{
uint32_t middle_container_idx, parent_container_idx;
int i;
struct node *new_node, *new_root;
struct container *container, *new_node_first_container;
if (node->container_size < BFTREE_CONTAINER_THRESHOLD) {
// the number of container in this node is full
return ;
}
middle_container_idx = node->container_size / 2;
new_node = node_create(node->parent);
new_node_first_container = node->containers[middle_container_idx];
new_node_first_container->child = new_node;
for (i = middle_container_idx+1; i < node->container_size; ++i) {
container = node->containers[i];
insert_after_container(new_node, container, i-middle_container_idx-2);
}
node->container_size -= (i-middle_container_idx);
if (node == tree->root) {
// produce new root
new_root = node_create(NULL);
tree->root = new_root;
tree->height++;
node->parent = new_root;
new_node->parent = new_root;
container = remove_container(node, 0);
container->child = node;
insert_after_container(new_root, container, 0);
insert_after_container(new_root, new_node_first_container, 0);
} else {
parent_container_idx = find_container(tree->opts->key_compare,
node->parent, new_node_first_container->payload_first->key, 0);
insert_after_container(node->parent, new_node_first_container, parent_container_idx);
order_container_payload(tree, node->parent, parent_container_idx, parent_container_idx+1);
try_split_node(tree, node->parent);
}
}
static void split_container(struct bftree *tree, struct node *node,
uint32_t container_idx)
{
uint32_t half_count, i;
struct container *new_container, *target;
struct payload *payload;
new_container = container_create();
insert_after_container(node, new_container, container_idx);
target = node->containers[container_idx];
half_count = target->payload_size / 2;
payload = target->payload_first;
for (i = 0; i < half_count - 1; ++i)
payload = payload->next;
new_container->payload_first = payload->next;
payload->next = NULL;
new_container->payload_size = target->payload_size - half_count;
target->payload_size = half_count;
try_split_node(tree, node);
}
static struct container *container_insert(struct bftree *tree, struct node *node,
uint32_t container_idx, struct payload *new_payload)
{
struct payload *curr_payload;
struct container *target;
int is_equal;
key_compare_func compare;
compare = tree->opts->key_compare;
if (container_idx >= node->container_size) {
target = container_create();
insert_after_container(node, target, 0);
} else {
target = node->containers[container_idx];
}
curr_payload = get_payload(tree->opts->key_compare, target->payload_first,
new_payload->key, &is_equal);
if (is_equal) {
// exist same key, swap value of payload
payload_replace(tree, curr_payload, new_payload);
} else {
if (curr_payload) {
// not at the header of payload list
new_payload->next = curr_payload->next;
curr_payload->next = new_payload;
} else {
// at the header of payload list
new_payload->next = target->payload_first;
target->payload_first = new_payload;
}
target->payload_size++;
}
if (target->payload_size > BFTREE_PAYLOAD_THRESHOLD && tree->is_migrated) {
if (target->child)
push_to_child(tree, node, target);
else
split_container(tree, node, container_idx);
}
return target;
}
static struct payload *container_get(struct bftree *tree, struct node *node,
uint32_t container_idx, void *key)
{
struct payload *curr_payload;
struct container *container;
int (*compare)(const void *, const void *);
int is_equal;
if (container_idx >= node->container_size)
return NULL;
compare = tree->opts->key_compare;
container = node->containers[container_idx];
curr_payload = get_payload(compare, container->payload_first, key, &is_equal);
if (is_equal) {
if (curr_payload->type == Put)
return curr_payload;
return NULL;
}
if (container->child) {
container_idx = find_container(compare, container->child, key, 0);
return container_get(tree, container->child, container_idx, key);
}
return NULL;
}
// ================================================================
// ========================== Public API ==========================
// ================================================================
struct bftree *bftree_create(struct bftree_opts *opts)
{
struct node *root;
struct bftree *tree;
tree = malloc(sizeof(*tree));
root = node_create(NULL);
tree->root = root;
tree->height = 1;
tree->opts = opts;
tree->is_migrated = 0;
tree->del_payload_count = tree->put_payload_count = 0;
assert(opts->key_destructor && opts->val_destructor);
return tree;
}
void bftree_free(struct bftree *tree)
{
bftree_free_node(tree, tree->root);
free(tree);
}
int bftree_put(struct bftree *tree, void *key, void *val)
{
struct payload *new_payload;
uint32_t idx;
if (!tree || !key)
return BF_WRONG;
new_payload = payload_create(key, val, Put);
idx = find_container(tree->opts->key_compare, tree->root, new_payload->key, 0);
container_insert(tree, tree->root, idx, new_payload);
return BF_OK;
}
void *bftree_get(struct bftree *tree, void *key)
{
uint32_t idx;
struct payload *r;
if (!tree || !key)
return NULL;
idx = find_container(tree->opts->key_compare, tree->root, key, 0);
r = container_get(tree, tree->root, idx, key);
if (r) {
return r->val;
}
return NULL;
}
int bftree_del(struct bftree *tree, void *key)
{
uint32_t idx;
struct payload *new_payload;
if (!tree || !key)
return BF_WRONG;
new_payload = payload_create(key, NULL, Del);
idx = find_container(tree->opts->key_compare, tree->root, new_payload->key, 0);
container_insert(tree, tree->root, idx, new_payload);
return BF_OK;
}
struct bftree_iterator *bftree_get_iterator(struct bftree *tree)
{
struct bftree_iterator *iter;
iter = malloc(sizeof(*iter));
iter->tree = tree;
iter->next = NULL;
iter->closed = 0;
return iter;
}
struct payload *bftree_next(struct bftree_iterator *iter)
{
struct bftree *tree;
struct container *container;
struct node *node;
struct payload *curr, *next, *min;
uint32_t idx;
key_compare_func key_compare;
int is_equal;
if (iter->closed)
return NULL;
tree = iter->tree;
key_compare = tree->opts->key_compare;
if (!iter->next) {
if (tree->root->container_size == 0)
return NULL;
iter->next = tree->root->containers[0]->payload_first;
}
curr = iter->next;
min = NULL;
node = tree->root;
do {
idx = find_container(key_compare, node, curr->key, 0);
container = node->containers[idx];
next = get_payload(key_compare, container->payload_first,
curr->key, &is_equal);
if (!next)
next = container->payload_first;
else
next = next->next;
if (next) {
if (!min) {
min = next;
} else if (key_compare(next->key, min->key) < 0) {
min = next;
}
}
node = container->child;
} while(node);
iter->next = min;
if (!min)
iter->closed = 1;
return curr;
}
void bftree_free_iterator(struct bftree_iterator *iter)
{
free(iter);
}
int bftree_count(struct bftree *tree)
{
struct bftree_iterator *iter;
int count;
count = 0;
iter = bftree_get_iterator(tree);
while (bftree_next(iter) != NULL)
count++;
bftree_free_iterator(iter);
return count;
}
// ================================================================
// ========================== Debug Area ==========================
// ================================================================
static void validate_containers(struct node *node, key_compare_func compare)
{
int i;
struct payload *curr, *prev;
for (i = 0; i < node->container_size; i++) {
prev = node->containers[i]->payload_first;
curr = prev->next;
while (curr) {
assert(compare(prev->key, curr->key) < 0);
prev = curr;
curr = curr->next;
}
if (i == 0)
continue;
assert(compare(node->containers[i-1]->payload_first->key,
node->containers[i]->payload_first->key) < 0);
}
}
void bftree_node_print(struct node *node)
{
int i;
struct payload *payload;
for (i = 0; i < node->container_size; ++i) {
printf("container%d %d %s\t", i, node->containers[i]->payload_size,
node->containers[i]->payload_first->key);
payload = node->containers[i]->payload_first;
while (payload) {
printf("%s => %s ", payload->key, payload->val);
payload = payload->next;
}
printf("\n");
}
printf("\n");
}
// ================================================================
// ========================== Map Type Area =======================
// ================================================================
typedef char *wstr;
struct wstrhd {
size_t len;
char buf[];
};
static inline wstr wstr_newlen(const void *init, size_t init_len)
{
struct wstrhd *sh;
sh = malloc(sizeof(struct wstrhd)+init_len+1);
if (sh == NULL) {
return NULL;
}
if (init) {
memcpy(sh->buf, init, init_len);
sh->len = init_len;
} else {
sh->len = 0;
}
sh->buf[sh->len] = '\0';
return (wstr)(sh->buf);
}
static inline inline void wstr_free(wstr s)
{
if (s == NULL) {
return ;
}
free(s - sizeof(struct wstrhd));
}
static inline size_t wstrlen(const wstr s)
{
struct wstrhd *hd = (struct wstrhd *)(s - sizeof(struct wstrhd));
return hd->len;
}
static inline int wstr_keycompare(const void *key1, const void *key2)
{
size_t l1,l2;
l1 = wstrlen((wstr)key1);
l2 = wstrlen((wstr)key2);
if (l1 != l2) return l1 < l2 ? -1 : 1;
return memcmp(key1, key2, l1);
}
static struct bftree_opts map_opt = {
NULL,
NULL,
wstr_keycompare,
(void (*)(void*))wstr_free,
free,
};
struct bftree *bftmap_create()
{
return bftree_create(&map_opt);
}
void bftmap_free(struct bftree *tree)
{
bftree_free(tree);
}
int bftmap_put(struct bftree *tree, char *key, size_t key_len, void *val)
{
if (!key || !key_len)
return BF_WRONG;
wstr s = wstr_newlen(key, key_len);
return bftree_put(tree, s, val);
}
void *bftmap_get(struct bftree *tree, char *key, size_t key_len)
{
if (!key || !key_len)
return NULL;
void *r;
wstr s = wstr_newlen(key, key_len);
r = bftree_get(tree, s);
wstr_free(s);
return r;
}
int bftmap_del(struct bftree *tree, char *key, size_t key_len)
{
if (!key || !key_len)
return BF_WRONG;
wstr s = wstr_newlen(key, key_len);
return bftree_del(tree, s);
}
// ================================================================
// ========================== Set Type Area =======================
// ================================================================
struct bftree *bftset_create()
{
return bftree_create(&map_opt);
}
void bftset_free(struct bftree *tree)
{
bftree_free(tree);
}
int bftset_put(struct bftree *tree, char *key, size_t key_len)
{
if (!key || !key_len)
return BF_WRONG;
wstr s = wstr_newlen(key, key_len);
return bftree_put(tree, s, NULL);
}
void *bftset_get(struct bftree *tree, char *key, size_t key_len)
{
if (!key || !key_len)
return NULL;
void *r;
wstr s = wstr_newlen(key, key_len);
r = bftree_get(tree, s);
wstr_free(s);
return r;
}
int bftset_del(struct bftree *tree, char *key, size_t key_len)
{
if (!key || !key_len)
return BF_WRONG;
wstr s = wstr_newlen(key, key_len);
return bftree_del(tree, s);
}