Handle-with-cache.c Access

// Background thread or called periodically void evict_stale_handles(int max_age_seconds, int max_size) { pthread_mutex_lock(&cache_lock); time_t now = time(NULL); GList *to_remove = NULL;

UserProfile* get_user_profile_handle(int user_id) { pthread_mutex_lock(&cache_lock); // Check cache CacheEntry *entry = g_hash_table_lookup(handle_cache, &user_id); if (entry) { // Cache hit entry->ref_count++; entry->last_access = time(NULL); pthread_mutex_unlock(&cache_lock); printf("Cache hit for user %d\n", user_id); return entry->profile; } handle-with-cache.c

pthread_mutex_unlock(&cache_lock); } The cache_lock mutex protects the hash table, but note that get_handle() releases the lock during the actual load_user_profile_from_disk() call. This is crucial to avoid blocking all threads during I/O. However, it introduces a race condition where two threads might simultaneously miss the cache and both load the same resource. In systems programming, efficiency is paramount

In systems programming, efficiency is paramount. Repeatedly opening, reading, or computing the same resource (a file, a network socket, a database row, or a complex calculation result) is wasteful. This is where caching becomes indispensable. // Remove stale entries for (GList *l =

// Remove stale entries for (GList *l = to_remove; l; l = l->next) { int *key = l->data; CacheEntry *entry = g_hash_table_lookup(handle_cache, key); free(entry->profile->name); free(entry->profile->email); free(entry->profile); free(entry); g_hash_table_remove(handle_cache, key); free(key); } g_list_free(to_remove);