blob: 656556986a3fd4ccac6e2fc586717e58f5c674df [file] [log] [blame] [raw]
/*
* -----------------------------------------------------------------------------
* "THE BEER-WARE LICENSE" (Revision 42):
* Lukas Niederbremer <webmaster@flippeh.de> and Clark Gaebel <cg.wowus.cg@gmail.com>
* wrote this file. As long as you retain this notice you can do whatever you
* want with this stuff. If we meet some day, and you think this stuff is worth
* it, you can buy us a beer in return.
* -----------------------------------------------------------------------------
*/
#include "nbt.h"
#include <assert.h>
#include <errno.h>
#include <stdlib.h>
#include <string.h>
/* strdup isn't standard. GNU extension. */
static inline char* __strdup(const char* s)
{
char* r = malloc(strlen(s) + 1);
if(r == NULL) return NULL;
strcpy(r, s);
return r;
}
#define CHECKED_MALLOC(var, n, on_error) do { \
if((var = malloc(n)) == NULL) \
{ \
errno = NBT_EMEM; \
on_error; \
} \
} while(0)
void nbt_free_list(struct tag_list* list)
{
assert(list);
struct list_head* current;
struct list_head* temp;
list_for_each_safe(current, temp, &list->entry)
{
struct tag_list* entry = list_entry(current, struct tag_list, entry);
nbt_free(entry->data);
free(entry);
}
free(list);
}
void nbt_free(nbt_node* tree)
{
if(tree == NULL) return;
if(tree->type == TAG_LIST || tree->type == TAG_COMPOUND)
nbt_free_list(tree->payload.tag_list);
else if(tree->type == TAG_BYTE_ARRAY)
free(tree->payload.tag_byte_array.data);
else if(tree->type == TAG_STRING)
free(tree->payload.tag_string);
free(tree->name);
free(tree);
}
static struct tag_list* clone_list(struct tag_list* list)
{
/* even empty lists are valid pointers! */
assert(list);
struct tag_list* ret;
CHECKED_MALLOC(ret, sizeof *ret, goto clone_error);
INIT_LIST_HEAD(&ret->entry);
ret->data = NULL;
struct list_head* pos;
list_for_each(pos, &list->entry)
{
struct tag_list* current = list_entry(pos, struct tag_list, entry);
struct tag_list* new;
CHECKED_MALLOC(new, sizeof *new, goto clone_error);
new->data = nbt_clone(current->data);
if(new->data == NULL)
{
free(new);
goto clone_error;
}
list_add_tail(&new->entry, &ret->entry);
}
return ret;
clone_error:
nbt_free_list(ret);
return NULL;
}
/* same as strdup, but handles NULL gracefully */
static inline char* safe_strdup(const char* s)
{
return s ? __strdup(s) : NULL;
}
nbt_node* nbt_clone(nbt_node* tree)
{
if(tree == NULL) return NULL;
assert(tree->type != TAG_INVALID);
nbt_node* ret;
CHECKED_MALLOC(ret, sizeof *ret, return NULL);
ret->type = tree->type;
ret->name = safe_strdup(tree->name);
if(tree->name && ret->name == NULL) goto clone_error;
if(tree->type == TAG_STRING)
{
ret->payload.tag_string = __strdup(tree->payload.tag_string);
if(ret->payload.tag_string == NULL) goto clone_error;
}
else if(tree->type == TAG_BYTE_ARRAY)
{
unsigned char* newbuf;
CHECKED_MALLOC(newbuf, tree->payload.tag_byte_array.length, goto clone_error);
memcpy(newbuf,
tree->payload.tag_byte_array.data,
tree->payload.tag_byte_array.length);
ret->payload.tag_byte_array.data = newbuf;
ret->payload.tag_byte_array.length = tree->payload.tag_byte_array.length;
}
else if(tree->type == TAG_LIST || tree->type == TAG_COMPOUND)
{
ret->payload.tag_list = clone_list(tree->payload.tag_list);
if(ret->payload.tag_list == NULL) goto clone_error;
}
else
{
ret->payload = tree->payload;
}
return ret;
clone_error:
if(ret) free(ret->name);
free(ret);
return NULL;
}
bool nbt_map(nbt_node* tree, nbt_visitor_t v, void* aux)
{
assert(v);
if(tree == NULL) return true;
if(!v(tree, aux)) return false;
/* And if the item is a list or compound, recurse through each of their elements. */
if(tree->type == TAG_LIST || tree->type == TAG_COMPOUND)
{
struct list_head* pos;
list_for_each(pos, &tree->payload.tag_list->entry)
if(!nbt_map(list_entry(pos, struct tag_list, entry)->data, v, aux))
return false;
}
return true;
}
/* Only returns NULL on error. An empty list is still a valid pointer */
static struct tag_list* filter_list(const struct tag_list* list, nbt_predicate_t predicate, void* aux)
{
assert(list);
struct tag_list* ret;
CHECKED_MALLOC(ret, sizeof *ret, goto filter_error);
ret->data = NULL;
INIT_LIST_HEAD(&ret->entry);
const struct list_head* pos;
list_for_each(pos, &list->entry)
{
const struct tag_list* p = list_entry(pos, struct tag_list, entry);
nbt_node* new_node = nbt_filter(p->data, predicate, aux);
if(errno != NBT_OK) goto filter_error;
if(new_node == NULL) continue;
struct tag_list* new_entry;
CHECKED_MALLOC(new_entry, sizeof *new_entry, goto filter_error);
new_entry->data = new_node;
list_add_tail(&new_entry->entry, &ret->entry);
}
return ret;
filter_error:
if(errno == NBT_OK)
errno = NBT_EMEM;
nbt_free_list(ret);
return NULL;
}
nbt_node* nbt_filter(const nbt_node* tree, nbt_predicate_t filter, void* aux)
{
assert(filter);
errno = NBT_OK;
if(tree == NULL) return NULL;
if(!filter(tree, aux)) return NULL;
nbt_node* ret;
CHECKED_MALLOC(ret, sizeof *ret, goto filter_error);
ret->type = tree->type;
ret->name = safe_strdup(tree->name);
if(tree->name && ret->name == NULL) goto filter_error;
if(tree->type == TAG_STRING)
{
ret->payload.tag_string = __strdup(tree->payload.tag_string);
if(ret->payload.tag_string == NULL) goto filter_error;
}
else if(tree->type == TAG_BYTE_ARRAY)
{
CHECKED_MALLOC(ret->payload.tag_byte_array.data,
tree->payload.tag_byte_array.length,
goto filter_error);
memcpy(ret->payload.tag_byte_array.data,
tree->payload.tag_byte_array.data,
tree->payload.tag_byte_array.length);
ret->payload.tag_byte_array.length = tree->payload.tag_byte_array.length;
}
/* Okay, we want to keep this node, but keep traversing the tree! */
else if(tree->type == TAG_LIST || tree->type == TAG_COMPOUND)
{
ret->payload.tag_list = filter_list(tree->payload.tag_list, filter, aux);
if(ret->payload.tag_list == NULL) goto filter_error;
}
else
{
ret->payload = tree->payload;
}
return ret;
filter_error:
if(errno == NBT_OK)
errno = NBT_EMEM;
if(ret) free(ret->name);
free(ret);
return NULL;
}
nbt_node* nbt_filter_inplace(nbt_node* tree, nbt_predicate_t filter, void* aux)
{
assert(filter);
if(tree == NULL) return NULL;
if(!filter(tree, aux)) return nbt_free(tree), NULL;
if(tree->type != TAG_LIST &&
tree->type != TAG_COMPOUND) return tree;
struct list_head* pos;
struct list_head* n;
list_for_each_safe(pos, n, &tree->payload.tag_list->entry)
{
struct tag_list* cur = list_entry(pos, struct tag_list, entry);
cur->data = nbt_filter_inplace(cur->data, filter, aux);
if(cur->data == NULL)
{
list_del(pos);
free(cur);
}
}
return tree;
}
nbt_node* nbt_find(nbt_node* tree, nbt_predicate_t predicate, void* aux)
{
if(tree == NULL) return NULL;
if(predicate(tree, aux)) return tree;
if(tree->type != TAG_LIST &&
tree->type != TAG_COMPOUND) return NULL;
struct list_head* pos;
list_for_each(pos, &tree->payload.tag_list->entry)
{
struct tag_list* p = list_entry(pos, struct tag_list, entry);
struct nbt_node* found;
if((found = nbt_find(p->data, predicate, aux)))
return found;
}
return NULL;
}
static bool names_are_equal(const nbt_node* node, void* vname)
{
const char* name = vname;
assert(node);
if(name == NULL && node->name == NULL)
return true;
if(name == NULL || node->name == NULL)
return false;
return strcmp(node->name, name) == 0;
}
nbt_node* nbt_find_by_name(nbt_node* tree, const char* name)
{
return nbt_find(tree, &names_are_equal, (void*)name);
}
/*
* Returns the index of the first occurence of `c' in `s', or the index of the
* NULL-terminator. Whichever comes first.
*/
static size_t index_of(const char* s, char c)
{
const char* p = s;
for(; *p; p++)
if(*p == c)
return p - s;
return p - s;
}
/*
* Pretends that s1 ends after `len' bytes, and does a strcmp.
*/
static int partial_strcmp(const char* s1, size_t len, const char* s2)
{
assert(s1);
if(s2 == NULL) return len != 0;
int r;
if((r = strncmp(s1, s2, len)) != 0)
return r;
/* at this point, the first `len' characters match. Check for NULL. */
return s2[len] != '\0';
}
/*
* Format:
* current_name.[other shit]
* OR
* current_name'\0'
*
* where current_name can be empty.
*/
nbt_node* nbt_find_by_path(nbt_node* tree, const char* path)
{
assert(tree);
assert(path);
/* The end of the "current_name" piece. */
size_t e = index_of(path, '.');
bool names_match = partial_strcmp(path, e, tree->name) == 0;
/* Names don't match. These aren't the droids you're looking for. */
if(!names_match) return NULL;
/* We're a leaf node, and the names match. Wooo found it. */
if(path[e] == '\0') return tree;
/*
* Initial names match, but the string isn't at the end. We're expecting a
* list, but haven't hit one.
*/
if(tree->type != TAG_LIST && tree->type != TAG_COMPOUND) return NULL;
/* At this point, the inital names match, and we're not at a leaf node. */
struct list_head* pos;
list_for_each(pos, &tree->payload.tag_list->entry)
{
struct tag_list* elem = list_entry(pos, struct tag_list, entry);
nbt_node* r;
if((r = nbt_find_by_path(elem->data, path + e + 1)) != NULL)
return r;
}
/* Wasn't found in the list (or the current node isn't a list). Give up. */
return NULL;
}
/* Gets the length of the list, plus the length of all its children. */
static inline size_t nbt_full_list_length(struct tag_list* list)
{
size_t accum = 0;
struct list_head* pos;
list_for_each(pos, &list->entry)
accum += nbt_size(list_entry(pos, const struct tag_list, entry)->data);
return accum;
}
size_t nbt_size(const nbt_node* tree)
{
if(tree == NULL)
return 0;
if(tree->type == TAG_LIST || tree->type == TAG_COMPOUND)
return nbt_full_list_length(tree->payload.tag_list) + 1;
return 1;
}