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// SPDX-License-Identifier: GPL-3.0-or-later
#ifndef NETDATA_DICTIONARY_H
#define NETDATA_DICTIONARY_H 1
#include "../libnetdata.h"
/*
* Netdata DICTIONARY features:
*
* CLONE or LINK
* Names and Values in the dictionary can be cloned or linked.
* In clone mode, the dictionary does all the memory management.
* The default is clone for both names and values.
* Set DICT_OPTION_NAME_LINK_DONT_CLONE to link names.
* Set DICT_OPTION_VALUE_LINK_DONT_CLONE to link names.
*
* ORDERED
* Items are ordered in the order they are added (new items are appended at the end).
* You may reverse the order by setting the flag DICT_OPTION_ADD_IN_FRONT.
*
* LOOKUP
* The dictionary uses JudyHS to maintain a very fast randomly accessible hash table.
*
* MULTI-THREADED and SINGLE-THREADED
* Each dictionary may be single threaded (no locks), or multi-threaded (multiple readers or one writer).
* The default is multi-threaded. Add the flag DICT_OPTION_SINGLE_THREADED for single-threaded.
*
* WALK-THROUGH and FOREACH traversal
* The dictionary can be traversed on read or write mode, either with a callback (walkthrough) or with
* a loop (foreach).
*
* In write mode traversal, the caller may delete only the current item, but may add as many items as needed.
*
*/
#ifdef DICTIONARY_INTERNALS
#define DICTFE_CONST
#define DICT_ITEM_CONST
#else
#define DICTFE_CONST const
#define DICT_ITEM_CONST const
#endif
typedef struct dictionary DICTIONARY;
typedef struct dictionary_item DICTIONARY_ITEM;
typedef enum dictionary_options {
DICT_OPTION_NONE = 0, // the default is the opposite of all below
DICT_OPTION_SINGLE_THREADED = (1 << 0), // don't use any locks (default: use locks)
DICT_OPTION_VALUE_LINK_DONT_CLONE = (1 << 1), // don't copy the value, just point to the one provided (default: copy)
DICT_OPTION_NAME_LINK_DONT_CLONE = (1 << 2), // don't copy the name, just point to the one provided (default: copy)
DICT_OPTION_DONT_OVERWRITE_VALUE = (1 << 3), // don't overwrite values of dictionary items (default: overwrite)
DICT_OPTION_ADD_IN_FRONT = (1 << 4), // add dictionary items at the front of the linked list (default: at the end)
} DICT_OPTIONS;
struct dictionary_stats {
const char *name; // the name of the category
struct {
size_t active; // the number of active dictionaries
size_t deleted; // the number of dictionaries queued for destruction
} dictionaries;
struct {
long entries; // active items in the dictionary
long pending_deletion; // pending deletion items in the dictionary
long referenced; // referenced items in the dictionary
} items;
struct {
size_t creations; // dictionary creations
size_t destructions; // dictionary destructions
size_t flushes; // dictionary flushes
size_t traversals; // dictionary foreach
size_t walkthroughs; // dictionary walkthrough
size_t garbage_collections; // dictionary garbage collections
size_t searches; // item searches
size_t inserts; // item inserts
size_t resets; // item resets
size_t deletes; // item deletes
} ops;
struct {
size_t inserts; // number of times the insert callback is called
size_t conflicts; // number of times the conflict callback is called
size_t reacts; // number of times the react callback is called
size_t deletes; // number of times the delete callback is called
} callbacks;
// memory
struct {
long indexed; // bytes of keys indexed (indication of the index size)
long values; // bytes of caller structures
long dict; // bytes of the structures dictionary needs
} memory;
// spin locks
struct {
size_t use_spins; // number of times a reference to item had to spin to acquire it or ignore it
size_t search_spins; // number of times a successful search result had to be thrown away
size_t insert_spins; // number of times an insertion to the hash table had to be repeated
size_t delete_spins; // number of times a deletion had to spin to get a decision
} spin_locks;
};
// Create a dictionary
#ifdef NETDATA_INTERNAL_CHECKS
#define dictionary_create(options) dictionary_create_advanced_with_trace(options, NULL, __FUNCTION__, __LINE__, __FILE__)
#define dictionary_create_advanced(options, stats) dictionary_create_advanced_with_trace(options, stats, __FUNCTION__, __LINE__, __FILE__)
DICTIONARY *dictionary_create_advanced_with_trace(DICT_OPTIONS options, struct dictionary_stats *stats, const char *function, size_t line, const char *file);
#else
#define dictionary_create(options) dictionary_create_advanced(options, NULL);
DICTIONARY *dictionary_create_advanced(DICT_OPTIONS options, struct dictionary_stats *stats);
#endif
// Create a view on a dictionary
#ifdef NETDATA_INTERNAL_CHECKS
#define dictionary_create_view(master) dictionary_create_view_with_trace(master, __FUNCTION__, __LINE__, __FILE__)
DICTIONARY *dictionary_create_view_with_trace(DICTIONARY *master, const char *function, size_t line, const char *file);
#else
DICTIONARY *dictionary_create_view(DICTIONARY *master);
#endif
// an insert callback to be called just after an item is added to the dictionary
// this callback is called while the dictionary is write locked!
void dictionary_register_insert_callback(DICTIONARY *dict, void (*ins_callback)(const DICTIONARY_ITEM *item, void *value, void *data), void *data);
// a delete callback to be called just before an item is deleted forever
// this callback is called while the dictionary is write locked!
void dictionary_register_delete_callback(DICTIONARY *dict, void (*del_callback)(const DICTIONARY_ITEM *item, void *value, void *data), void *data);
// a merge callback to be called when DICT_OPTION_DONT_OVERWRITE_VALUE
// and an item is already found in the dictionary - the dictionary does nothing else in this case
// the old_value will remain in the dictionary - the new_value is ignored
// The callback should return true if the value has been updated (it increases the dictionary version).
void dictionary_register_conflict_callback(DICTIONARY *dict, bool (*conflict_callback)(const DICTIONARY_ITEM *item, void *old_value, void *new_value, void *data), void *data);
// a reaction callback to be called after every item insertion or conflict
// after the constructors have finished and the items are fully available for use
// and the dictionary is not write locked anymore
void dictionary_register_react_callback(DICTIONARY *dict, void (*react_callback)(const DICTIONARY_ITEM *item, void *value, void *data), void *data);
// Destroy a dictionary
// Returns the number of bytes freed
// The returned value will not include name/key sizes
// Registered delete callbacks will be run for each item in the dictionary.
size_t dictionary_destroy(DICTIONARY *dict);
// Empties a dictionary
// Referenced items will survive, but are not offered anymore.
// Registered delete callbacks will be run for each item in the dictionary.
void dictionary_flush(DICTIONARY *dict);
void dictionary_version_increment(DICTIONARY *dict);
// ----------------------------------------------------------------------------
// Set an item in the dictionary
//
// - if an item with the same name does not exist, create one
// - if an item with the same name exists, then:
// a) if DICT_OPTION_DONT_OVERWRITE_VALUE is set, just return the existing value (ignore the new value)
// else b) reset the value to the new value passed at the call
//
// When DICT_OPTION_VALUE_LINK_DONT_CLONE is set, the value is linked, otherwise it is copied
// When DICT_OPTION_NAME_LINK_DONT_CLONE is set, the name is linked, otherwise it is copied
//
// When neither DICT_OPTION_VALUE_LINK_DONT_CLONE nor DICT_OPTION_NAME_LINK_DONT_CLONE are set, all the
// memory management for names and values is done by the dictionary.
//
// Passing NULL as value, the dictionary will callocz() the newly allocated value, otherwise it will copy it.
// Passing 0 as value_len, the dictionary will set the value to NULL (no allocations for value will be made).
#define dictionary_set(dict, name, value, value_len) dictionary_set_advanced(dict, name, -1, value, value_len, NULL)
void *dictionary_set_advanced(DICTIONARY *dict, const char *name, ssize_t name_len, void *value, size_t value_len, void *constructor_data);
#define dictionary_set_and_acquire_item(dict, name, value, value_len) dictionary_set_and_acquire_item_advanced(dict, name, -1, value, value_len, NULL)
DICT_ITEM_CONST DICTIONARY_ITEM *dictionary_set_and_acquire_item_advanced(DICTIONARY *dict, const char *name, ssize_t name_len, void *value, size_t value_len, void *constructor_data);
// set an item in a dictionary view
#define dictionary_view_set_and_acquire_item(dict, name, master_item) dictionary_view_set_and_acquire_item_advanced(dict, name, -1, master_item)
DICT_ITEM_CONST DICTIONARY_ITEM *dictionary_view_set_and_acquire_item_advanced(DICTIONARY *dict, const char *name, ssize_t name_len, DICTIONARY_ITEM *master_item);
#define dictionary_view_set(dict, name, master_item) dictionary_view_set_advanced(dict, name, -1, master_item)
void *dictionary_view_set_advanced(DICTIONARY *dict, const char *name, ssize_t name_len, DICT_ITEM_CONST DICTIONARY_ITEM *master_item);
// ----------------------------------------------------------------------------
// Get an item from the dictionary
// If it returns NULL, the item is not found
#define dictionary_get(dict, name) dictionary_get_advanced(dict, name, -1)
void *dictionary_get_advanced(DICTIONARY *dict, const char *name, ssize_t name_len);
#define dictionary_get_and_acquire_item(dict, name) dictionary_get_and_acquire_item_advanced(dict, name, -1)
DICT_ITEM_CONST DICTIONARY_ITEM *dictionary_get_and_acquire_item_advanced(DICTIONARY *dict, const char *name, ssize_t name_len);
// ----------------------------------------------------------------------------
// Delete an item from the dictionary
// returns true if the item was found and has been deleted
// returns false if the item was not found in the index
#define dictionary_del(dict, name) dictionary_del_advanced(dict, name, -1)
bool dictionary_del_advanced(DICTIONARY *dict, const char *name, ssize_t name_len);
// ----------------------------------------------------------------------------
// reference counters management
void dictionary_acquired_item_release(DICTIONARY *dict, DICT_ITEM_CONST DICTIONARY_ITEM *item);
DICT_ITEM_CONST DICTIONARY_ITEM *dictionary_acquired_item_dup(DICTIONARY *dict, DICT_ITEM_CONST DICTIONARY_ITEM *item);
const char *dictionary_acquired_item_name(DICT_ITEM_CONST DICTIONARY_ITEM *item);
void *dictionary_acquired_item_value(DICT_ITEM_CONST DICTIONARY_ITEM *item);
size_t dictionary_acquired_item_references(DICT_ITEM_CONST DICTIONARY_ITEM *item);
// ----------------------------------------------------------------------------
// Traverse (walk through) the items of the dictionary.
// The order of traversal is currently the order of insertion.
//
// The callback function may return a negative number to stop the traversal,
// in which case that negative value is returned to the caller.
//
// If all callback calls return zero or positive numbers, the sum of all of
// them is returned to the caller.
//
// You cannot alter the dictionary from inside a dictionary_walkthrough_read() - deadlock!
// You can only delete the current item from inside a dictionary_walkthrough_write() - you can add as many as you want.
//
#define dictionary_walkthrough_read(dict, callback, data) dictionary_walkthrough_rw(dict, 'r', callback, data)
#define dictionary_walkthrough_write(dict, callback, data) dictionary_walkthrough_rw(dict, 'w', callback, data)
int dictionary_walkthrough_rw(DICTIONARY *dict, char rw, int (*callback)(const DICTIONARY_ITEM *item, void *value, void *data), void *data);
typedef int (*dictionary_sorted_compar)(const DICTIONARY_ITEM **item1, const DICTIONARY_ITEM **item2);
#define dictionary_sorted_walkthrough_read(dict, callback, data) dictionary_sorted_walkthrough_rw(dict, 'r', callback, data, NULL)
#define dictionary_sorted_walkthrough_write(dict, callback, data) dictionary_sorted_walkthrough_rw(dict, 'w', callback, data, NULL)
int dictionary_sorted_walkthrough_rw(DICTIONARY *dict, char rw, int (*callback)(const DICTIONARY_ITEM *item, void *entry, void *data), void *data, dictionary_sorted_compar compar);
// ----------------------------------------------------------------------------
// Traverse with foreach
//
// Use like this:
//
// DICTFE dfe = {};
// for(MY_ITEM *item = dfe_start_read(&dfe, dict); item ; item = dfe_next(&dfe)) {
// // do things with the item and its dfe.name
// }
// dfe_done(&dfe);
//
// You cannot alter the dictionary from within a dfe_read_start() - deadlock!
// You can only delete the current item from inside a dfe_start_write() - you can add as many as you want.
//
#define DICTIONARY_LOCK_READ 'r'
#define DICTIONARY_LOCK_WRITE 'w'
#define DICTIONARY_LOCK_REENTRANT 'z'
void dictionary_write_lock(DICTIONARY *dict);
void dictionary_write_unlock(DICTIONARY *dict);
typedef DICTFE_CONST struct dictionary_foreach {
DICTIONARY *dict; // the dictionary upon we work
DICTIONARY_ITEM *item; // the item we work on, to remember the position we are at
// this can be used with dictionary_acquired_item_dup() to
// acquire the currently working item.
DICTFE_CONST char *name; // the dictionary name of the last item used
void *value; // the dictionary value of the last item used
// same as the return value of dictfe_start() and dictfe_next()
size_t counter; // counts the number of iterations made, starting from zero
char rw; // the lock mode 'r' or 'w'
} DICTFE;
#define dfe_start_read(dict, value) dfe_start_rw(dict, value, DICTIONARY_LOCK_READ)
#define dfe_start_write(dict, value) dfe_start_rw(dict, value, DICTIONARY_LOCK_WRITE)
#define dfe_start_reentrant(dict, value) dfe_start_rw(dict, value, DICTIONARY_LOCK_REENTRANT)
#define dfe_start_rw(dict, value, mode) \
do { \
DICTFE value ## _dfe = {}; \
(void)(value); /* needed to avoid warning when looping without using this */ \
for((value) = dictionary_foreach_start_rw(&value ## _dfe, (dict), (mode)); \
(value ## _dfe.item) ; \
(value) = dictionary_foreach_next(&value ## _dfe)) \
{
#define dfe_done(value) \
} \
dictionary_foreach_done(&value ## _dfe); \
} while(0)
void *dictionary_foreach_start_rw(DICTFE *dfe, DICTIONARY *dict, char rw);
void *dictionary_foreach_next(DICTFE *dfe);
void dictionary_foreach_done(DICTFE *dfe);
// ----------------------------------------------------------------------------
// Get statistics about the dictionary
size_t dictionary_version(DICTIONARY *dict);
size_t dictionary_entries(DICTIONARY *dict);
size_t dictionary_referenced_items(DICTIONARY *dict);
long int dictionary_stats_for_registry(DICTIONARY *dict);
// for all cases that the caller does not provide a stats structure, this is where they are accumulated.
extern struct dictionary_stats dictionary_stats_category_other;
int dictionary_unittest(size_t entries);
// ----------------------------------------------------------------------------
// THREAD CACHE
void *thread_cache_entry_get_or_set(void *key,
ssize_t key_length,
void *value,
void *(*transform_the_value_before_insert)(void *key, size_t key_length, void *value));
void thread_cache_destroy(void);
#endif /* NETDATA_DICTIONARY_H */
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