/** * @file lv_ll.c * Handle linked lists. * The nodes are dynamically allocated by the 'lv_mem' module, */ /********************* * INCLUDES *********************/ #include "lv_ll.h" #include "lv_mem.h" /********************* * DEFINES *********************/ #define LL_NODE_META_SIZE (sizeof(lv_ll_node_t *) + sizeof(lv_ll_node_t *)) #define LL_PREV_P_OFFSET(ll_p) (ll_p->n_size) #define LL_NEXT_P_OFFSET(ll_p) (ll_p->n_size + sizeof(lv_ll_node_t *)) /********************** * TYPEDEFS **********************/ /********************** * STATIC PROTOTYPES **********************/ static void node_set_prev(lv_ll_t * ll_p, lv_ll_node_t * act, lv_ll_node_t * prev); static void node_set_next(lv_ll_t * ll_p, lv_ll_node_t * act, lv_ll_node_t * next); /********************** * STATIC VARIABLES **********************/ /********************** * MACROS **********************/ /********************** * GLOBAL FUNCTIONS **********************/ /** * Initialize linked list * @param ll_p pointer to lv_ll_t variable * @param node_size the size of 1 node in bytes */ void _lv_ll_init(lv_ll_t * ll_p, uint32_t node_size) { ll_p->head = NULL; ll_p->tail = NULL; #ifdef LV_ARCH_64 /*Round the size up to 8*/ node_size = (node_size + 7) & (~0x7); #else /*Round the size up to 4*/ node_size = (node_size + 3) & (~0x3); #endif ll_p->n_size = node_size; } /** * Add a new head to a linked list * @param ll_p pointer to linked list * @return pointer to the new head */ void * _lv_ll_ins_head(lv_ll_t * ll_p) { lv_ll_node_t * n_new; n_new = lv_mem_alloc(ll_p->n_size + LL_NODE_META_SIZE); if(n_new != NULL) { node_set_prev(ll_p, n_new, NULL); /*No prev. before the new head*/ node_set_next(ll_p, n_new, ll_p->head); /*After new comes the old head*/ if(ll_p->head != NULL) { /*If there is old head then before it goes the new*/ node_set_prev(ll_p, ll_p->head, n_new); } ll_p->head = n_new; /*Set the new head in the dsc.*/ if(ll_p->tail == NULL) { /*If there is no tail (1. node) set the tail too*/ ll_p->tail = n_new; } } return n_new; } /** * Insert a new node in front of the n_act node * @param ll_p pointer to linked list * @param n_act pointer a node * @return pointer to the new node */ void * _lv_ll_ins_prev(lv_ll_t * ll_p, void * n_act) { lv_ll_node_t * n_new; if(NULL == ll_p || NULL == n_act) return NULL; if(_lv_ll_get_head(ll_p) == n_act) { n_new = _lv_ll_ins_head(ll_p); if(n_new == NULL) return NULL; } else { n_new = lv_mem_alloc(ll_p->n_size + LL_NODE_META_SIZE); if(n_new == NULL) return NULL; lv_ll_node_t * n_prev; n_prev = _lv_ll_get_prev(ll_p, n_act); node_set_next(ll_p, n_prev, n_new); node_set_prev(ll_p, n_new, n_prev); node_set_prev(ll_p, n_act, n_new); node_set_next(ll_p, n_new, n_act); } return n_new; } /** * Add a new tail to a linked list * @param ll_p pointer to linked list * @return pointer to the new tail */ void * _lv_ll_ins_tail(lv_ll_t * ll_p) { lv_ll_node_t * n_new; n_new = lv_mem_alloc(ll_p->n_size + LL_NODE_META_SIZE); if(n_new != NULL) { node_set_next(ll_p, n_new, NULL); /*No next after the new tail*/ node_set_prev(ll_p, n_new, ll_p->tail); /*The prev. before new is the old tail*/ if(ll_p->tail != NULL) { /*If there is old tail then the new comes after it*/ node_set_next(ll_p, ll_p->tail, n_new); } ll_p->tail = n_new; /*Set the new tail in the dsc.*/ if(ll_p->head == NULL) { /*If there is no head (1. node) set the head too*/ ll_p->head = n_new; } } return n_new; } /** * Remove the node 'node_p' from 'll_p' linked list. * It does not free the memory of node. * @param ll_p pointer to the linked list of 'node_p' * @param node_p pointer to node in 'll_p' linked list */ void _lv_ll_remove(lv_ll_t * ll_p, void * node_p) { if(ll_p == NULL) return; if(_lv_ll_get_head(ll_p) == node_p) { /*The new head will be the node after 'n_act'*/ ll_p->head = _lv_ll_get_next(ll_p, node_p); if(ll_p->head == NULL) { ll_p->tail = NULL; } else { node_set_prev(ll_p, ll_p->head, NULL); } } else if(_lv_ll_get_tail(ll_p) == node_p) { /*The new tail will be the node before 'n_act'*/ ll_p->tail = _lv_ll_get_prev(ll_p, node_p); if(ll_p->tail == NULL) { ll_p->head = NULL; } else { node_set_next(ll_p, ll_p->tail, NULL); } } else { lv_ll_node_t * n_prev = _lv_ll_get_prev(ll_p, node_p); lv_ll_node_t * n_next = _lv_ll_get_next(ll_p, node_p); node_set_next(ll_p, n_prev, n_next); node_set_prev(ll_p, n_next, n_prev); } } /** * Remove and free all elements from a linked list. The list remain valid but become empty. * @param ll_p pointer to linked list */ void _lv_ll_clear(lv_ll_t * ll_p) { void * i; void * i_next; i = _lv_ll_get_head(ll_p); i_next = NULL; while(i != NULL) { i_next = _lv_ll_get_next(ll_p, i); _lv_ll_remove(ll_p, i); lv_mem_free(i); i = i_next; } } /** * Move a node to a new linked list * @param ll_ori_p pointer to the original (old) linked list * @param ll_new_p pointer to the new linked list * @param node pointer to a node * @param head true: be the head in the new list * false be the tail in the new list */ void _lv_ll_chg_list(lv_ll_t * ll_ori_p, lv_ll_t * ll_new_p, void * node, bool head) { _lv_ll_remove(ll_ori_p, node); if(head) { /*Set node as head*/ node_set_prev(ll_new_p, node, NULL); node_set_next(ll_new_p, node, ll_new_p->head); if(ll_new_p->head != NULL) { /*If there is old head then before it goes the new*/ node_set_prev(ll_new_p, ll_new_p->head, node); } ll_new_p->head = node; /*Set the new head in the dsc.*/ if(ll_new_p->tail == NULL) { /*If there is no tail (first node) set the tail too*/ ll_new_p->tail = node; } } else { /*Set node as tail*/ node_set_prev(ll_new_p, node, ll_new_p->tail); node_set_next(ll_new_p, node, NULL); if(ll_new_p->tail != NULL) { /*If there is old tail then after it goes the new*/ node_set_next(ll_new_p, ll_new_p->tail, node); } ll_new_p->tail = node; /*Set the new tail in the dsc.*/ if(ll_new_p->head == NULL) { /*If there is no head (first node) set the head too*/ ll_new_p->head = node; } } } /** * Return with head node of the linked list * @param ll_p pointer to linked list * @return pointer to the head of 'll_p' */ void * _lv_ll_get_head(const lv_ll_t * ll_p) { if(ll_p == NULL) return NULL; return ll_p->head; } /** * Return with tail node of the linked list * @param ll_p pointer to linked list * @return pointer to the tail of 'll_p' */ void * _lv_ll_get_tail(const lv_ll_t * ll_p) { if(ll_p == NULL) return NULL; return ll_p->tail; } /** * Return with the pointer of the next node after 'n_act' * @param ll_p pointer to linked list * @param n_act pointer a node * @return pointer to the next node */ void * _lv_ll_get_next(const lv_ll_t * ll_p, const void * n_act) { /*Pointer to the next node is stored in the end of this node. *Go there and return the address found there*/ const lv_ll_node_t * n_act_d = n_act; n_act_d += LL_NEXT_P_OFFSET(ll_p); return *((lv_ll_node_t **)n_act_d); } /** * Return with the pointer of the previous node before 'n_act' * @param ll_p pointer to linked list * @param n_act pointer a node * @return pointer to the previous node */ void * _lv_ll_get_prev(const lv_ll_t * ll_p, const void * n_act) { /*Pointer to the prev. node is stored in the end of this node. *Go there and return the address found there*/ const lv_ll_node_t * n_act_d = n_act; n_act_d += LL_PREV_P_OFFSET(ll_p); return *((lv_ll_node_t **)n_act_d); } /** * Return the length of the linked list. * @param ll_p pointer to linked list * @return length of the linked list */ uint32_t _lv_ll_get_len(const lv_ll_t * ll_p) { uint32_t len = 0; void * node; for(node = _lv_ll_get_head(ll_p); node != NULL; node = _lv_ll_get_next(ll_p, node)) { len++; } return len; } /** * Move a node before an other node in the same linked list * @param ll_p pointer to a linked list * @param n_act pointer to node to move * @param n_after pointer to a node which should be after `n_act` */ void _lv_ll_move_before(lv_ll_t * ll_p, void * n_act, void * n_after) { if(n_act == n_after) return; /*Can't move before itself*/ void * n_before; if(n_after != NULL) n_before = _lv_ll_get_prev(ll_p, n_after); else n_before = _lv_ll_get_tail(ll_p); /*if `n_after` is NULL `n_act` should be the new tail*/ if(n_act == n_before) return; /*Already before `n_after`*/ /*It's much easier to remove from the list and add again*/ _lv_ll_remove(ll_p, n_act); /*Add again by setting the prev. and next nodes*/ node_set_next(ll_p, n_before, n_act); node_set_prev(ll_p, n_act, n_before); node_set_prev(ll_p, n_after, n_act); node_set_next(ll_p, n_act, n_after); /*If `n_act` was moved before NULL then it become the new tail*/ if(n_after == NULL) ll_p->tail = n_act; /*If `n_act` was moved before `NULL` then it's the new head*/ if(n_before == NULL) ll_p->head = n_act; } /** * Check if a linked list is empty * @param ll_p pointer to a linked list * @return true: the linked list is empty; false: not empty */ bool _lv_ll_is_empty(lv_ll_t * ll_p) { if(ll_p == NULL) return true; if(ll_p->head == NULL && ll_p->tail == NULL) return true; return false; } /********************** * STATIC FUNCTIONS **********************/ /** * Set the previous node pointer of a node * @param ll_p pointer to linked list * @param act pointer to a node which prev. node pointer should be set * @param prev pointer to a node which should be the previous node before 'act' */ static void node_set_prev(lv_ll_t * ll_p, lv_ll_node_t * act, lv_ll_node_t * prev) { if(act == NULL) return; /*Can't set the prev node of `NULL`*/ uint8_t * act8 = (uint8_t *)act; act8 += LL_PREV_P_OFFSET(ll_p); lv_ll_node_t ** act_node_p = (lv_ll_node_t **) act8; lv_ll_node_t ** prev_node_p = (lv_ll_node_t **) &prev; *act_node_p = *prev_node_p; } /** * Set the 'next node pointer' of a node * @param ll_p pointer to linked list * @param act pointer to a node which next node pointer should be set * @param next pointer to a node which should be the next node before 'act' */ static void node_set_next(lv_ll_t * ll_p, lv_ll_node_t * act, lv_ll_node_t * next) { if(act == NULL) return; /*Can't set the next node of `NULL`*/ uint8_t * act8 = (uint8_t *)act; act8 += LL_NEXT_P_OFFSET(ll_p); lv_ll_node_t ** act_node_p = (lv_ll_node_t **) act8; lv_ll_node_t ** next_node_p = (lv_ll_node_t **) &next; *act_node_p = *next_node_p; }