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hekate/bdk/libs/lvgl/lv_misc/lv_ll.c
CTCaer 185526d134 Introducing Bootloader Development Kit (BDK)
BDK will allow developers to use the full collection of drivers,
with limited editing, if any, for making payloads for Nintendo Switch.

Using a single source for everything will also help decoupling
Switch specific code and easily port it to other Tegra X1/X1+ platforms.
And maybe even to lower targets.

Everything is now centrilized into bdk folder.
Every module or project can utilize it by simply including it.

This is just the start and it will continue to improve.
2020-06-14 15:25:21 +03:00

376 lines
9.9 KiB
C

/**
* @file lv_ll.c
* Handle linked lists.
* The nodes are dynamically allocated by the 'lv_mem' module,
*/
/*********************
* INCLUDES
*********************/
#include <stdint.h>
#include <string.h>
#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_dsc pointer to ll_dsc 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_MEM_ENV64
/*Round the size up to 8*/
if(node_size & 0x7) {
node_size = node_size & (~0x7);
node_size += 8;
}
#else
/*Round the size up to 4*/
if(node_size & 0x3) {
node_size = node_size & (~0x3);
node_size += 4;
}
#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 head
*/
void * lv_ll_ins_prev(lv_ll_t * ll_p, void * n_act)
{
lv_ll_node_t * n_new;
lv_ll_node_t * n_prev;
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;
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) return NULL;
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 tho 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 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_rem(lv_ll_t * ll_p, void * node_p)
{
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_rem(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
*/
void lv_ll_chg_list(lv_ll_t * ll_ori_p, lv_ll_t * ll_new_p, void * node)
{
lv_ll_rem(ll_ori_p, node);
/*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;
}
}
/**
* 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)
{
void * head = NULL;
if(ll_p != NULL) {
head = ll_p->head;
}
return head;
}
/**
* Return with tail node of the linked list
* @param ll_p pointer to linked list
* @return pointer to the head of 'll_p'
*/
void * lv_ll_get_tail(const lv_ll_t * ll_p)
{
void * tail = NULL;
if(ll_p != NULL) {
tail = ll_p->tail;
}
return 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)
{
void * next = NULL;
if(ll_p != NULL) {
const lv_ll_node_t * n_act_d = n_act;
memcpy(&next, n_act_d + LL_NEXT_P_OFFSET(ll_p), sizeof(void *));
}
return next;
}
/**
* Return with the pointer of the previous node after '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)
{
void * prev = NULL;
if(ll_p != NULL) {
const lv_ll_node_t * n_act_d = n_act;
memcpy(&prev, n_act_d + LL_PREV_P_OFFSET(ll_p), sizeof(void *));
}
return prev;
}
void lv_ll_swap(lv_ll_t * ll_p, void * n1_p, void * n2_p)
{
(void)(ll_p);
(void)(n1_p);
(void)(n2_p);
/*TODO*/
}
/**
* Move a nodw 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_rem(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;
}
/**********************
* STATIC FUNCTIONS
**********************/
/**
* Set the 'pervious 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`*/
uint32_t node_p_size = sizeof(lv_ll_node_t *);
if(prev) memcpy(act + LL_PREV_P_OFFSET(ll_p), &prev, node_p_size);
else memset(act + LL_PREV_P_OFFSET(ll_p), 0, node_p_size);
}
/**
* 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`*/
uint32_t node_p_size = sizeof(lv_ll_node_t *);
if(next) memcpy(act + LL_NEXT_P_OFFSET(ll_p), &next, node_p_size);
else memset(act + LL_NEXT_P_OFFSET(ll_p), 0, node_p_size);
}