From 5da14042f70711ea5cf66e034699730335462f66 Mon Sep 17 00:00:00 2001 From: Daniel Baumann Date: Sun, 5 May 2024 14:08:03 +0200 Subject: Merging upstream version 1.45.3+dfsg. Signed-off-by: Daniel Baumann --- src/libnetdata/simple_hashtable.h | 544 ++++++++++++++++++++++++++++++++++++++ 1 file changed, 544 insertions(+) create mode 100644 src/libnetdata/simple_hashtable.h (limited to 'src/libnetdata/simple_hashtable.h') diff --git a/src/libnetdata/simple_hashtable.h b/src/libnetdata/simple_hashtable.h new file mode 100644 index 000000000..13cdcd10e --- /dev/null +++ b/src/libnetdata/simple_hashtable.h @@ -0,0 +1,544 @@ +// SPDX-License-Identifier: GPL-3.0-or-later + +#ifndef NETDATA_SIMPLE_HASHTABLE_H +#define NETDATA_SIMPLE_HASHTABLE_H + +typedef uint64_t SIMPLE_HASHTABLE_HASH; +#define SIMPLE_HASHTABLE_HASH_SECOND_HASH_SHIFTS 32 + +/* + * CONFIGURATION + * + * SIMPLE_HASHTABLE_NAME + * The name of the hashtable - all functions and defines will have this name appended + * Example: #define SIMPLE_HASHTABLE_NAME _FACET_KEY + * + * SIMPLE_HASHTABLE_VALUE_TYPE and SIMPLE_HASHTABLE_KEY_TYPE + * The data types of values and keys - optional - setting them will enable strict type checking by the compiler. + * If undefined, they both default to void. + * + * SIMPLE_HASHTABLE_SORT_FUNCTION + * A function name that accepts 2x values and compares them for sorting (returning -1, 0, 1). + * When set, the hashtable will maintain an always sorted array of the values in the hashtable. + * Do not use this for non-static hashtables. So, if your data is changing all the time, this can make the + * hashtable quite slower (it memmove()s an array of pointers to keep it sorted, on every single change). + * + * SIMPLE_HASHTABLE_VALUE2KEY_FUNCTION and SIMPLE_HASHTABLE_COMPARE_KEYS_FUNCTION + * The hashtable can either compare just hashes (the default), or hashes and keys (when these are set). + * Both need to be set for this feature to be enabled. + * + * - SIMPLE_HASHTABLE_VALUE2KEY_FUNCTION + * The name of a function accepting SIMPLE_HASHTABLE_VALUE_TYPE pointer. + * It should return a pointer to SIMPLE_HASHTABLE_KEY_TYPE. + * This function is called prior to SIMPLE_HASHTABLE_COMPARE_KEYS_FUNCTION to extract the key from a value. + * It is also called during hashtable resize, to rehash all values in the hashtable. + * + * - SIMPLE_HASHTABLE_COMPARE_KEYS_FUNCTION + * The name of a function accepting 2x SIMPLE_HASHTABLE_KEY_TYPE pointers. + * It should return true when the keys match. + * This function is only called when the hashes match, to verify that the keys also match. + * + * SIMPLE_HASHTABLE_SAMPLE_IMPLEMENTATION + * If defined, 3x functions will be injected for easily working with the hashtable. + * + */ + + +#ifndef SIMPLE_HASHTABLE_NAME +#define SIMPLE_HASHTABLE_NAME +#endif + +#ifndef SIMPLE_HASHTABLE_VALUE_TYPE +#define SIMPLE_HASHTABLE_VALUE_TYPE void +#endif + +#ifndef SIMPLE_HASHTABLE_KEY_TYPE +#define SIMPLE_HASHTABLE_KEY_TYPE void +#endif + +#ifndef SIMPLE_HASHTABLE_VALUE2KEY_FUNCTION +#undef SIMPLE_HASHTABLE_COMPARE_KEYS_FUNCTION +#endif + +#if defined(SIMPLE_HASHTABLE_VALUE2KEY_FUNCTION) +static inline SIMPLE_HASHTABLE_KEY_TYPE *SIMPLE_HASHTABLE_VALUE2KEY_FUNCTION(SIMPLE_HASHTABLE_VALUE_TYPE *); +#endif + +#if defined(SIMPLE_HASHTABLE_COMPARE_KEYS_FUNCTION) +static inline bool SIMPLE_HASHTABLE_COMPARE_KEYS_FUNCTION(SIMPLE_HASHTABLE_KEY_TYPE *, SIMPLE_HASHTABLE_KEY_TYPE *); +#endif + +// First layer of macro for token concatenation +#define CONCAT_INTERNAL(a, b) a ## b +// Second layer of macro, which ensures proper expansion +#define CONCAT(a, b) CONCAT_INTERNAL(a, b) + +// define names for all structures and structures +#define simple_hashtable_init_named CONCAT(simple_hashtable_init, SIMPLE_HASHTABLE_NAME) +#define simple_hashtable_destroy_named CONCAT(simple_hashtable_destroy, SIMPLE_HASHTABLE_NAME) + +#define simple_hashtable_slot_named CONCAT(simple_hashtable_slot, SIMPLE_HASHTABLE_NAME) +#define SIMPLE_HASHTABLE_SLOT_NAMED CONCAT(SIMPLE_HASHTABLE_SLOT, SIMPLE_HASHTABLE_NAME) +#define simple_hashtable_named CONCAT(simple_hashtable, SIMPLE_HASHTABLE_NAME) +#define SIMPLE_HASHTABLE_NAMED CONCAT(SIMPLE_HASHTABLE, SIMPLE_HASHTABLE_NAME) +#define simple_hashtable_resize_named CONCAT(simple_hashtable_resize, SIMPLE_HASHTABLE_NAME) +#define simple_hashtable_can_use_slot_named CONCAT(simple_hashtable_keys_match, SIMPLE_HASHTABLE_NAME) +#define simple_hashtable_get_slot_named CONCAT(simple_hashtable_get_slot, SIMPLE_HASHTABLE_NAME) +#define simple_hashtable_del_slot_named CONCAT(simple_hashtable_del_slot, SIMPLE_HASHTABLE_NAME) +#define simple_hashtable_set_slot_named CONCAT(simple_hashtable_set_slot, SIMPLE_HASHTABLE_NAME) +#define simple_hashtable_first_read_only_named CONCAT(simple_hashtable_first_read_only, SIMPLE_HASHTABLE_NAME) +#define simple_hashtable_next_read_only_named CONCAT(simple_hashtable_next_read_only, SIMPLE_HASHTABLE_NAME) + +#define simple_hashtable_sorted_binary_search_named CONCAT(simple_hashtable_sorted_binary_search, SIMPLE_HASHTABLE_NAME) +#define simple_hashtable_add_value_sorted_named CONCAT(simple_hashtable_add_value_sorted, SIMPLE_HASHTABLE_NAME) +#define simple_hashtable_del_value_sorted_named CONCAT(simple_hashtable_del_value_sorted, SIMPLE_HASHTABLE_NAME) +#define simple_hashtable_replace_value_sorted_named CONCAT(simple_hashtable_replace_value_sorted, SIMPLE_HASHTABLE_NAME) +#define simple_hashtable_sorted_array_first_read_only_named CONCAT(simple_hashtable_sorted_array_first_read_only, SIMPLE_HASHTABLE_NAME) +#define simple_hashtable_sorted_array_next_read_only_named CONCAT(simple_hashtable_sorted_array_next_read_only, SIMPLE_HASHTABLE_NAME) + +typedef struct simple_hashtable_slot_named { + SIMPLE_HASHTABLE_HASH hash; + SIMPLE_HASHTABLE_VALUE_TYPE *data; +} SIMPLE_HASHTABLE_SLOT_NAMED; + +typedef struct simple_hashtable_named { + size_t resizes; + size_t searches; + size_t collisions; + size_t additions; + size_t deletions; + size_t deleted; + size_t used; + size_t size; + bool needs_cleanup; + SIMPLE_HASHTABLE_SLOT_NAMED *hashtable; + +#ifdef SIMPLE_HASHTABLE_SORT_FUNCTION + struct { + size_t used; + size_t size; + SIMPLE_HASHTABLE_VALUE_TYPE **array; + } sorted; +#endif +} SIMPLE_HASHTABLE_NAMED; + +#ifdef SIMPLE_HASHTABLE_SORT_FUNCTION +static inline size_t simple_hashtable_sorted_binary_search_named(SIMPLE_HASHTABLE_NAMED *ht, SIMPLE_HASHTABLE_VALUE_TYPE *value) { + size_t left = 0, right = ht->sorted.used; + + while (left < right) { + size_t mid = left + (right - left) / 2; + if (SIMPLE_HASHTABLE_SORT_FUNCTION(ht->sorted.array[mid], value) < 0) + left = mid + 1; + else + right = mid; + } + + return left; +} + +static inline void simple_hashtable_add_value_sorted_named(SIMPLE_HASHTABLE_NAMED *ht, SIMPLE_HASHTABLE_VALUE_TYPE *value) { + size_t index = simple_hashtable_sorted_binary_search_named(ht, value); + + // Ensure there's enough space in the sorted array + if (ht->sorted.used >= ht->sorted.size) { + size_t size = ht->sorted.size ? ht->sorted.size * 2 : 64; + SIMPLE_HASHTABLE_VALUE_TYPE **array = mallocz(size * sizeof(SIMPLE_HASHTABLE_VALUE_TYPE *)); + if(ht->sorted.array) { + memcpy(array, ht->sorted.array, ht->sorted.size * sizeof(SIMPLE_HASHTABLE_VALUE_TYPE *)); + freez(ht->sorted.array); + } + ht->sorted.array = array; + ht->sorted.size = size; + } + + // Use memmove to shift elements and create space for the new element + memmove(&ht->sorted.array[index + 1], &ht->sorted.array[index], (ht->sorted.used - index) * sizeof(SIMPLE_HASHTABLE_VALUE_TYPE *)); + + ht->sorted.array[index] = value; + ht->sorted.used++; +} + +static inline void simple_hashtable_del_value_sorted_named(SIMPLE_HASHTABLE_NAMED *ht, SIMPLE_HASHTABLE_VALUE_TYPE *value) { + size_t index = simple_hashtable_sorted_binary_search_named(ht, value); + + // Check if the value exists at the found index + assert(index < ht->sorted.used && ht->sorted.array[index] == value); + + // Use memmove to shift elements and close the gap + memmove(&ht->sorted.array[index], &ht->sorted.array[index + 1], (ht->sorted.used - index - 1) * sizeof(SIMPLE_HASHTABLE_VALUE_TYPE *)); + ht->sorted.used--; +} + +static inline void simple_hashtable_replace_value_sorted_named(SIMPLE_HASHTABLE_NAMED *ht, SIMPLE_HASHTABLE_VALUE_TYPE *old_value, SIMPLE_HASHTABLE_VALUE_TYPE *new_value) { + if(new_value == old_value) + return; + + size_t old_value_index = simple_hashtable_sorted_binary_search_named(ht, old_value); + assert(old_value_index < ht->sorted.used && ht->sorted.array[old_value_index] == old_value); + + int r = SIMPLE_HASHTABLE_SORT_FUNCTION(old_value, new_value); + if(r == 0) { + // Same value, so use the same index + ht->sorted.array[old_value_index] = new_value; + return; + } + + size_t new_value_index = simple_hashtable_sorted_binary_search_named(ht, new_value); + if(old_value_index == new_value_index) { + // Not the same value, but still at the same index + ht->sorted.array[old_value_index] = new_value; + return; + } + else if (old_value_index < new_value_index) { + // The old value is before the new value + size_t shift_start = old_value_index + 1; + size_t shift_end = new_value_index - 1; + size_t shift_size = shift_end - old_value_index; + + memmove(&ht->sorted.array[old_value_index], &ht->sorted.array[shift_start], shift_size * sizeof(SIMPLE_HASHTABLE_VALUE_TYPE *)); + ht->sorted.array[shift_end] = new_value; + } + else { + // The old value is after the new value + size_t shift_start = new_value_index; + size_t shift_end = old_value_index; + size_t shift_size = shift_end - new_value_index; + + memmove(&ht->sorted.array[new_value_index + 1], &ht->sorted.array[shift_start], shift_size * sizeof(SIMPLE_HASHTABLE_VALUE_TYPE *)); + ht->sorted.array[new_value_index] = new_value; + } +} + +static inline SIMPLE_HASHTABLE_VALUE_TYPE **simple_hashtable_sorted_array_first_read_only_named(SIMPLE_HASHTABLE_NAMED *ht) { + if (ht->sorted.used > 0) { + return &ht->sorted.array[0]; + } + return NULL; +} + +static inline SIMPLE_HASHTABLE_VALUE_TYPE **simple_hashtable_sorted_array_next_read_only_named(SIMPLE_HASHTABLE_NAMED *ht, SIMPLE_HASHTABLE_VALUE_TYPE **last) { + if (!last) return NULL; + + // Calculate the current position in the sorted array + size_t currentIndex = last - ht->sorted.array; + + // Proceed to the next element if it exists + if (currentIndex + 1 < ht->sorted.used) { + return &ht->sorted.array[currentIndex + 1]; + } + + // If no more elements, return NULL + return NULL; +} + +#define SIMPLE_HASHTABLE_SORTED_FOREACH_READ_ONLY(ht, var, type, name) \ + for (type **(var) = simple_hashtable_sorted_array_first_read_only ## name(ht); \ + var; \ + (var) = simple_hashtable_sorted_array_next_read_only ## name(ht, var)) + +#define SIMPLE_HASHTABLE_SORTED_FOREACH_READ_ONLY_VALUE(var) (*(var)) + +#else +static inline void simple_hashtable_add_value_sorted_named(SIMPLE_HASHTABLE_NAMED *ht __maybe_unused, SIMPLE_HASHTABLE_VALUE_TYPE *value __maybe_unused) { ; } +static inline void simple_hashtable_del_value_sorted_named(SIMPLE_HASHTABLE_NAMED *ht __maybe_unused, SIMPLE_HASHTABLE_VALUE_TYPE *value __maybe_unused) { ; } +static inline void simple_hashtable_replace_value_sorted_named(SIMPLE_HASHTABLE_NAMED *ht __maybe_unused, SIMPLE_HASHTABLE_VALUE_TYPE *old_value __maybe_unused, SIMPLE_HASHTABLE_VALUE_TYPE *new_value __maybe_unused) { ; } +#endif + +static inline void simple_hashtable_init_named(SIMPLE_HASHTABLE_NAMED *ht, size_t size) { + memset(ht, 0, sizeof(*ht)); + ht->size = size; + ht->hashtable = callocz(ht->size, sizeof(*ht->hashtable)); +} + +static inline void simple_hashtable_destroy_named(SIMPLE_HASHTABLE_NAMED *ht) { +#ifdef SIMPLE_HASHTABLE_SORT_FUNCTION + freez(ht->sorted.array); +#endif + + freez(ht->hashtable); + memset(ht, 0, sizeof(*ht)); +} + +static inline void simple_hashtable_resize_named(SIMPLE_HASHTABLE_NAMED *ht); + +#define simple_hashtable_data_unset ((void *)NULL) +#define simple_hashtable_data_deleted ((void *)UINT64_MAX) +#define simple_hashtable_data_usernull ((void *)(UINT64_MAX - 1)) +#define simple_hashtable_is_slot_unset(sl) ((sl)->data == simple_hashtable_data_unset) +#define simple_hashtable_is_slot_deleted(sl) ((sl)->data == simple_hashtable_data_deleted) +#define simple_hashtable_is_slot_usernull(sl) ((sl)->data == simple_hashtable_data_usernull) +#define SIMPLE_HASHTABLE_SLOT_DATA(sl) ((simple_hashtable_is_slot_unset(sl) || simple_hashtable_is_slot_deleted(sl) || simple_hashtable_is_slot_usernull(sl)) ? NULL : (sl)->data) + +static inline bool simple_hashtable_can_use_slot_named( + SIMPLE_HASHTABLE_SLOT_NAMED *sl, SIMPLE_HASHTABLE_HASH hash, + SIMPLE_HASHTABLE_KEY_TYPE *key __maybe_unused) { + + if(simple_hashtable_is_slot_unset(sl)) + return true; + + if(simple_hashtable_is_slot_deleted(sl)) + return false; + + if(sl->hash == hash) { +#if defined(SIMPLE_HASHTABLE_COMPARE_KEYS_FUNCTION) && defined(SIMPLE_HASHTABLE_VALUE2KEY_FUNCTION) + return SIMPLE_HASHTABLE_COMPARE_KEYS_FUNCTION(SIMPLE_HASHTABLE_VALUE2KEY_FUNCTION(SIMPLE_HASHTABLE_SLOT_DATA(sl)), key); +#else + return true; +#endif + } + + return false; +} + +#define SIMPLE_HASHTABLE_NEEDS_RESIZE(ht) ((ht)->size <= ((ht)->used - (ht)->deleted) << 1 || (ht)->used >= (ht)->size) + +// IMPORTANT: the pointer returned by this call is valid up to the next call of this function (or the resize one). +// If you need to cache something, cache the hash, not the slot pointer. +static inline SIMPLE_HASHTABLE_SLOT_NAMED *simple_hashtable_get_slot_named( + SIMPLE_HASHTABLE_NAMED *ht, SIMPLE_HASHTABLE_HASH hash, + SIMPLE_HASHTABLE_KEY_TYPE *key, bool resize) { + + // This function finds the requested hash and key in the hashtable. + // It uses a second version of the hash in case of collisions, and then linear probing. + // It may resize the hashtable if it is more than 50% full. + + // Deleted items remain in the hashtable, but they are marked as DELETED. + // Reuse of DELETED slots happens only if the slot to be returned is UNSET. + // So, when looking up for an item, it tries to find it, assuming DELETED + // slots are occupied. If the item to be returned is UNSET, and it has + // encountered a DELETED slot, it returns the DELETED one instead of the UNSET. + + ht->searches++; + + size_t slot; + SIMPLE_HASHTABLE_SLOT_NAMED *sl; + SIMPLE_HASHTABLE_SLOT_NAMED *deleted; + + slot = hash % ht->size; + sl = &ht->hashtable[slot]; + deleted = simple_hashtable_is_slot_deleted(sl) ? sl : NULL; + if(likely(simple_hashtable_can_use_slot_named(sl, hash, key))) + return (simple_hashtable_is_slot_unset(sl) && deleted) ? deleted : sl; + + ht->collisions++; + + if(unlikely(resize && (ht->needs_cleanup || SIMPLE_HASHTABLE_NEEDS_RESIZE(ht)))) { + simple_hashtable_resize_named(ht); + deleted = NULL; // our deleted pointer is not valid anymore + + slot = hash % ht->size; + sl = &ht->hashtable[slot]; + if(likely(simple_hashtable_can_use_slot_named(sl, hash, key))) + return sl; + + ht->collisions++; + } + + slot = ((hash >> SIMPLE_HASHTABLE_HASH_SECOND_HASH_SHIFTS) + 1) % ht->size; + sl = &ht->hashtable[slot]; + deleted = (!deleted && simple_hashtable_is_slot_deleted(sl)) ? sl : deleted; + + // Linear probing until we find it + SIMPLE_HASHTABLE_SLOT_NAMED *sl_started = sl; + size_t collisions_started = ht->collisions; + while (!simple_hashtable_can_use_slot_named(sl, hash, key)) { + slot = (slot + 1) % ht->size; // Wrap around if necessary + sl = &ht->hashtable[slot]; + deleted = (!deleted && simple_hashtable_is_slot_deleted(sl)) ? sl : deleted; + ht->collisions++; + + if(sl == sl_started) { + if(deleted) { + // we looped through all items, and we didn't find a free slot, + // but we have found a deleted slot, so return it. + return deleted; + } + else if(resize) { + // the hashtable is full, without any deleted slots. + // we need to resize it now. + simple_hashtable_resize_named(ht); + return simple_hashtable_get_slot_named(ht, hash, key, false); + } + else { + // the hashtable is full, but resize is false. + // this should never happen. + assert(sl != sl_started); + } + } + } + + if((ht->collisions - collisions_started) > (ht->size / 2) && ht->deleted >= (ht->size / 3)) { + // we traversed through half of the hashtable to find a slot, + // but we have more than 1/3 deleted items + ht->needs_cleanup = true; + } + + return (simple_hashtable_is_slot_unset(sl) && deleted) ? deleted : sl; +} + +static inline bool simple_hashtable_del_slot_named(SIMPLE_HASHTABLE_NAMED *ht, SIMPLE_HASHTABLE_SLOT_NAMED *sl) { + if(simple_hashtable_is_slot_unset(sl) || simple_hashtable_is_slot_deleted(sl)) + return false; + + ht->deletions++; + ht->deleted++; + + simple_hashtable_del_value_sorted_named(ht, SIMPLE_HASHTABLE_SLOT_DATA(sl)); + + sl->data = simple_hashtable_data_deleted; + return true; +} + +static inline void simple_hashtable_set_slot_named( + SIMPLE_HASHTABLE_NAMED *ht, SIMPLE_HASHTABLE_SLOT_NAMED *sl, + SIMPLE_HASHTABLE_HASH hash, SIMPLE_HASHTABLE_VALUE_TYPE *data) { + + if(data == NULL) + data = simple_hashtable_data_usernull; + + if(unlikely(data == simple_hashtable_data_unset || data == simple_hashtable_data_deleted)) { + simple_hashtable_del_slot_named(ht, sl); + return; + } + + if(likely(simple_hashtable_is_slot_unset(sl))) { + simple_hashtable_add_value_sorted_named(ht, data); + ht->used++; + } + + else if(unlikely(simple_hashtable_is_slot_deleted(sl))) { + ht->deleted--; + } + + else + simple_hashtable_replace_value_sorted_named(ht, SIMPLE_HASHTABLE_SLOT_DATA(sl), data); + + sl->hash = hash; + sl->data = data; + ht->additions++; +} + +// IMPORTANT +// this call invalidates all SIMPLE_HASHTABLE_SLOT_NAMED pointers +static inline void simple_hashtable_resize_named(SIMPLE_HASHTABLE_NAMED *ht) { + SIMPLE_HASHTABLE_SLOT_NAMED *old = ht->hashtable; + size_t old_size = ht->size; + + size_t new_size = ht->size; + + if(SIMPLE_HASHTABLE_NEEDS_RESIZE(ht)) + new_size = (ht->size << 1) - ((ht->size > 16) ? 1 : 0); + + ht->resizes++; + ht->size = new_size; + ht->hashtable = callocz(new_size, sizeof(*ht->hashtable)); + size_t used = 0; + for(size_t i = 0 ; i < old_size ; i++) { + SIMPLE_HASHTABLE_SLOT_NAMED *slot = &old[i]; + if(simple_hashtable_is_slot_unset(slot) || simple_hashtable_is_slot_deleted(slot)) + continue; + + SIMPLE_HASHTABLE_KEY_TYPE *key = NULL; + +#if defined(SIMPLE_HASHTABLE_COMPARE_KEYS_FUNCTION) && defined(SIMPLE_HASHTABLE_VALUE2KEY_FUNCTION) + SIMPLE_HASHTABLE_VALUE_TYPE *value = SIMPLE_HASHTABLE_SLOT_DATA(slot); + key = SIMPLE_HASHTABLE_VALUE2KEY_FUNCTION(value); +#endif + + SIMPLE_HASHTABLE_SLOT_NAMED *slot2 = simple_hashtable_get_slot_named(ht, slot->hash, key, false); + *slot2 = *slot; + used++; + } + + assert(used == ht->used - ht->deleted); + + ht->used = used; + ht->deleted = 0; + ht->needs_cleanup = false; + + freez(old); +} + +// ---------------------------------------------------------------------------- +// hashtable traversal, in read-only mode +// the hashtable should not be modified while the traversal is taking place + +static inline SIMPLE_HASHTABLE_SLOT_NAMED *simple_hashtable_first_read_only_named(SIMPLE_HASHTABLE_NAMED *ht) { + for(size_t i = 0; i < ht->size ;i++) { + SIMPLE_HASHTABLE_SLOT_NAMED *sl = &ht->hashtable[i]; + if(!simple_hashtable_is_slot_unset(sl) && !simple_hashtable_is_slot_deleted(sl)) + return sl; + } + + return NULL; +} + +static inline SIMPLE_HASHTABLE_SLOT_NAMED *simple_hashtable_next_read_only_named(SIMPLE_HASHTABLE_NAMED *ht, SIMPLE_HASHTABLE_SLOT_NAMED *last) { + if (!last) return NULL; + + // Calculate the current position in the array + size_t index = last - ht->hashtable; + + // Iterate over the hashtable starting from the next element + for (size_t i = index + 1; i < ht->size; i++) { + SIMPLE_HASHTABLE_SLOT_NAMED *sl = &ht->hashtable[i]; + if (!simple_hashtable_is_slot_unset(sl) && !simple_hashtable_is_slot_deleted(sl)) { + return sl; + } + } + + // If no more data slots are found, return NULL + return NULL; +} + +#define SIMPLE_HASHTABLE_FOREACH_READ_ONLY(ht, var, name) \ + for(struct simple_hashtable_slot ## name *(var) = simple_hashtable_first_read_only ## name(ht); \ + var; \ + (var) = simple_hashtable_next_read_only ## name(ht, var)) + +#define SIMPLE_HASHTABLE_FOREACH_READ_ONLY_VALUE(var) SIMPLE_HASHTABLE_SLOT_DATA(var) + +// ---------------------------------------------------------------------------- +// high level implementation + +#ifdef SIMPLE_HASHTABLE_SAMPLE_IMPLEMENTATION + +#ifndef XXH_INLINE_ALL +#define XXH_INLINE_ALL +#endif +#include "xxhash.h" + +#define simple_hashtable_set_named CONCAT(simple_hashtable_set, SIMPLE_HASHTABLE_NAME) +#define simple_hashtable_get_named CONCAT(simple_hashtable_get, SIMPLE_HASHTABLE_NAME) +#define simple_hashtable_del_named CONCAT(simple_hashtable_del, SIMPLE_HASHTABLE_NAME) + +static inline SIMPLE_HASHTABLE_VALUE_TYPE *simple_hashtable_set_named(SIMPLE_HASHTABLE_NAMED *ht, SIMPLE_HASHTABLE_KEY_TYPE *key, size_t key_len, SIMPLE_HASHTABLE_VALUE_TYPE *data) { + XXH64_hash_t hash = XXH3_64bits((void *)key, key_len); + SIMPLE_HASHTABLE_SLOT_NAMED *sl = simple_hashtable_get_slot_named(ht, hash, key, true); + simple_hashtable_set_slot_named(ht, sl, hash, data); + return SIMPLE_HASHTABLE_SLOT_DATA(sl); +} + +static inline SIMPLE_HASHTABLE_VALUE_TYPE *simple_hashtable_get_named(SIMPLE_HASHTABLE_NAMED *ht, SIMPLE_HASHTABLE_KEY_TYPE *key, size_t key_len, SIMPLE_HASHTABLE_VALUE_TYPE *data) { + XXH64_hash_t hash = XXH3_64bits((void *)key, key_len); + SIMPLE_HASHTABLE_SLOT_NAMED *sl = simple_hashtable_get_slot_named(ht, hash, key, true); + return SIMPLE_HASHTABLE_SLOT_DATA(sl); +} + +static inline bool simple_hashtable_del_named(SIMPLE_HASHTABLE_NAMED *ht, SIMPLE_HASHTABLE_KEY_TYPE *key, size_t key_len, SIMPLE_HASHTABLE_VALUE_TYPE *data) { + XXH64_hash_t hash = XXH3_64bits((void *)key, key_len); + SIMPLE_HASHTABLE_SLOT_NAMED *sl = simple_hashtable_get_slot_named(ht, hash, key, true); + return simple_hashtable_del_slot_named(ht, sl); +} + +#endif // SIMPLE_HASHTABLE_SAMPLE_IMPLEMENTATION + +// ---------------------------------------------------------------------------- +// Clear the preprocessor defines of simple_hashtable.h +// allowing simple_hashtable.h to be included multiple times +// with different configuration each time. + +#include "simple_hashtable_undef.h" + +#endif //NETDATA_SIMPLE_HASHTABLE_H -- cgit v1.2.3