mirror of
https://github.com/shchmue/Lockpick_RCM.git
synced 2024-11-18 16:19:32 +01:00
471 lines
12 KiB
C
471 lines
12 KiB
C
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/*
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* Copyright (c) 2019-2020 CTCaer
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*
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* This program is free software; you can redistribute it and/or modify it
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* under the terms and conditions of the GNU General Public License,
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* version 2, as published by the Free Software Foundation.
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*
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* This program is distributed in the hope it will be useful, but WITHOUT
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* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
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* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
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* more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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/**
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* @file lv_mem.c
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* General and portable implementation of malloc and free.
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* The dynamic memory monitoring is also supported.
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*/
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/*********************
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* INCLUDES
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*********************/
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#include "lv_mem.h"
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#include "lv_math.h"
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#include <string.h>
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#include <assert.h>
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#if LV_MEM_CUSTOM != 0
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#include LV_MEM_CUSTOM_INCLUDE
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#endif
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/*********************
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* DEFINES
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*********************/
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#define LV_MEM_ADD_JUNK 0 /*Add memory junk on alloc (0xaa) and free(0xbb) (just for testing purposes)*/
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#ifdef LV_MEM_ENV64
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# define MEM_UNIT uint64_t
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#else
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# define MEM_UNIT uint32_t
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#endif
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/**********************
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* TYPEDEFS
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**********************/
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#if LV_ENABLE_GC == 0 /*gc custom allocations must not include header*/
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/*The size of this union must be 32 bytes (uint32_t * 8)*/
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typedef union {
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struct {
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MEM_UNIT used: 1; //1: if the entry is used
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MEM_UNIT d_size: 31; //Size of the data
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};
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MEM_UNIT header; //The header (used + d_size)
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MEM_UNIT align[8]; //Align header size to MEM_UNIT * 8 bytes
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} lv_mem_header_t;
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static_assert(sizeof(lv_mem_header_t) == 32, "Node header must be 32 bytes!");
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typedef struct {
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lv_mem_header_t header;
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uint8_t first_data; /*First data byte in the allocated data (Just for easily create a pointer)*/
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} lv_mem_ent_t;
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#endif /* LV_ENABLE_GC */
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/**********************
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* STATIC PROTOTYPES
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**********************/
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#if LV_MEM_CUSTOM == 0
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static lv_mem_ent_t * ent_get_next(lv_mem_ent_t * act_e);
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static void * ent_alloc(lv_mem_ent_t * e, uint32_t size);
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static void ent_trunc(lv_mem_ent_t * e, uint32_t size);
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#endif
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/**********************
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* STATIC VARIABLES
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**********************/
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#if LV_MEM_CUSTOM == 0
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static uint8_t * work_mem;
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#endif
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static uint32_t zero_mem; /*Give the address of this variable if 0 byte should be allocated*/
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/**********************
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* MACROS
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**********************/
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/**********************
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* GLOBAL FUNCTIONS
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**********************/
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/**
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* Initiaiize the dyn_mem module (work memory and other variables)
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*/
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void lv_mem_init(void)
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{
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#if LV_MEM_CUSTOM == 0
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#if LV_MEM_ADR == 0
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/*Allocate a large array to store the dynamically allocated data*/
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static LV_MEM_ATTR MEM_UNIT work_mem_int[LV_MEM_SIZE / sizeof(MEM_UNIT)];
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work_mem = (uint8_t *) work_mem_int;
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#else
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work_mem = (uint8_t *) LV_MEM_ADR;
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#endif
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lv_mem_ent_t * full = (lv_mem_ent_t *)work_mem;
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full->header.used = 0;
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/*The total mem size id reduced by the first header and the close patterns */
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full->header.d_size = LV_MEM_SIZE - sizeof(lv_mem_header_t);
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#endif
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}
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/**
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* Allocate a memory dynamically
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* @param size size of the memory to allocate in bytes
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* @return pointer to the allocated memory
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*/
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void * lv_mem_alloc(uint32_t size)
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{
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if(size == 0) {
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return &zero_mem;
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}
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/*Round the size to lv_mem_header_t*/
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if(size & (sizeof(lv_mem_header_t) - 1)) {
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size = size & (~(sizeof(lv_mem_header_t) - 1));
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size += sizeof(lv_mem_header_t);
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}
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void * alloc = NULL;
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#if LV_MEM_CUSTOM == 0 /*Use the allocation from dyn_mem*/
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lv_mem_ent_t * e = NULL;
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//Search for a appropriate entry
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do {
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//Get the next entry
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e = ent_get_next(e);
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/*If there is next entry then try to allocate there*/
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if(e != NULL) {
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alloc = ent_alloc(e, size);
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}
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//End if there is not next entry OR the alloc. is successful
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} while(e != NULL && alloc == NULL);
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#else /*Use custom, user defined malloc function*/
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#if LV_ENABLE_GC == 1 /*gc must not include header*/
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alloc = LV_MEM_CUSTOM_ALLOC(size);
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#else /* LV_ENABLE_GC */
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/*Allocate a header too to store the size*/
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alloc = LV_MEM_CUSTOM_ALLOC(size + sizeof(lv_mem_header_t));
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if(alloc != NULL) {
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((lv_mem_ent_t *) alloc)->header.d_size = size;
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((lv_mem_ent_t *) alloc)->header.used = 1;
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alloc = &((lv_mem_ent_t *) alloc)->first_data;
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}
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#endif /* LV_ENABLE_GC */
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#endif /* LV_MEM_CUSTOM */
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#if LV_MEM_ADD_JUNK
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if(alloc != NULL) memset(alloc, 0xaa, size);
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#endif
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if(alloc == NULL) LV_LOG_WARN("Couldn't allocate memory");
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return alloc;
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}
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/**
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* Free an allocated data
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* @param data pointer to an allocated memory
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*/
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void lv_mem_free(const void * data)
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{
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if(data == &zero_mem) return;
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if(data == NULL) return;
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#if LV_MEM_ADD_JUNK
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memset((void *)data, 0xbb, lv_mem_get_size(data));
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#endif
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#if LV_ENABLE_GC==0
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/*e points to the header*/
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lv_mem_ent_t * e = (lv_mem_ent_t *)((uint8_t *) data - sizeof(lv_mem_header_t));
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e->header.used = 0;
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#endif
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#if LV_MEM_CUSTOM == 0
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#if LV_MEM_AUTO_DEFRAG
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/* Make a simple defrag.
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* Join the following free entries after this*/
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lv_mem_ent_t * e_next;
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e_next = ent_get_next(e);
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while(e_next != NULL) {
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if(e_next->header.used == 0) {
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e->header.d_size += e_next->header.d_size + sizeof(e->header);
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} else {
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break;
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}
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e_next = ent_get_next(e_next);
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}
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#endif
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#else /*Use custom, user defined free function*/
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#if LV_ENABLE_GC==0
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LV_MEM_CUSTOM_FREE(e);
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#else
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LV_MEM_CUSTOM_FREE((void*)data);
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#endif /*LV_ENABLE_GC*/
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#endif
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}
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/**
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* Reallocate a memory with a new size. The old content will be kept.
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* @param data pointer to an allocated memory.
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* Its content will be copied to the new memory block and freed
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* @param new_size the desired new size in byte
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* @return pointer to the new memory
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*/
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#if LV_ENABLE_GC==0
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void * lv_mem_realloc(void * data_p, uint32_t new_size)
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{
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/*Round the size to lv_mem_header_t*/
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if(new_size & (sizeof(lv_mem_header_t) - 1)) {
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new_size = new_size & (~(sizeof(lv_mem_header_t) - 1));
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new_size += sizeof(lv_mem_header_t);
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}
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/*data_p could be previously freed pointer (in this case it is invalid)*/
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if(data_p != NULL) {
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lv_mem_ent_t * e = (lv_mem_ent_t *)((uint8_t *) data_p - sizeof(lv_mem_header_t));
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if(e->header.used == 0) {
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data_p = NULL;
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}
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}
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uint32_t old_size = lv_mem_get_size(data_p);
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if(old_size == new_size) return data_p; /*Also avoid reallocating the same memory*/
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#if LV_MEM_CUSTOM == 0
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/* Only truncate the memory is possible
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* If the 'old_size' was extended by a header size in 'ent_trunc' it avoids reallocating this same memory */
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if(new_size < old_size) {
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lv_mem_ent_t * e = (lv_mem_ent_t *)((uint8_t *) data_p - sizeof(lv_mem_header_t));
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ent_trunc(e, new_size);
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return &e->first_data;
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}
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#endif
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void * new_p;
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new_p = lv_mem_alloc(new_size);
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if(new_p != NULL && data_p != NULL) {
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/*Copy the old data to the new. Use the smaller size*/
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if(old_size != 0) {
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memcpy(new_p, data_p, LV_MATH_MIN(new_size, old_size));
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lv_mem_free(data_p);
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}
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}
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if(new_p == NULL) LV_LOG_WARN("Couldn't allocate memory");
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return new_p;
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}
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#else /* LV_ENABLE_GC */
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void * lv_mem_realloc(void * data_p, uint32_t new_size)
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{
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void * new_p = LV_MEM_CUSTOM_REALLOC(data_p, new_size);
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if(new_p == NULL) LV_LOG_WARN("Couldn't allocate memory");
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return new_p;
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}
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#endif /* lv_enable_gc */
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/**
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* Join the adjacent free memory blocks
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*/
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void lv_mem_defrag(void)
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{
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#if LV_MEM_CUSTOM == 0
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lv_mem_ent_t * e_free;
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lv_mem_ent_t * e_next;
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e_free = ent_get_next(NULL);
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while(1) {
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/*Search the next free entry*/
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while(e_free != NULL) {
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if(e_free->header.used != 0) {
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e_free = ent_get_next(e_free);
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} else {
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break;
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}
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}
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if(e_free == NULL) return;
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/*Joint the following free entries to the free*/
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e_next = ent_get_next(e_free);
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while(e_next != NULL) {
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if(e_next->header.used == 0) {
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e_free->header.d_size += e_next->header.d_size + sizeof(e_next->header);
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} else {
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break;
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}
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e_next = ent_get_next(e_next);
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}
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if(e_next == NULL) return;
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/*Continue from the lastly checked entry*/
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e_free = e_next;
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}
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#endif
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}
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/**
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* Give information about the work memory of dynamic allocation
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* @param mon_p pointer to a dm_mon_p variable,
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* the result of the analysis will be stored here
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*/
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void lv_mem_monitor(lv_mem_monitor_t * mon_p)
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{
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/*Init the data*/
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memset(mon_p, 0, sizeof(lv_mem_monitor_t));
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#if LV_MEM_CUSTOM == 0
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lv_mem_ent_t * e;
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e = NULL;
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e = ent_get_next(e);
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while(e != NULL) {
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if(e->header.used == 0) {
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mon_p->free_cnt++;
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mon_p->free_size += e->header.d_size;
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if(e->header.d_size > mon_p->free_biggest_size) {
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mon_p->free_biggest_size = e->header.d_size;
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}
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} else {
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mon_p->used_cnt++;
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}
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e = ent_get_next(e);
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}
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mon_p->total_size = LV_MEM_SIZE;
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mon_p->used_pct = 100 - ((uint64_t)100U * mon_p->free_size) / mon_p->total_size;
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mon_p->frag_pct = (uint32_t)mon_p->free_biggest_size * 100U / mon_p->free_size;
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mon_p->frag_pct = 100 - mon_p->frag_pct;
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#endif
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}
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/**
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* Give the size of an allocated memory
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* @param data pointer to an allocated memory
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* @return the size of data memory in bytes
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*/
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#if LV_ENABLE_GC==0
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uint32_t lv_mem_get_size(const void * data)
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{
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if(data == NULL) return 0;
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if(data == &zero_mem) return 0;
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lv_mem_ent_t * e = (lv_mem_ent_t *)((uint8_t *) data - sizeof(lv_mem_header_t));
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return e->header.d_size;
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}
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#else /* LV_ENABLE_GC */
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uint32_t lv_mem_get_size(const void * data)
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{
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return LV_MEM_CUSTOM_GET_SIZE(data);
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}
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#endif /*LV_ENABLE_GC*/
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/**********************
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* STATIC FUNCTIONS
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**********************/
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#if LV_MEM_CUSTOM == 0
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/**
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* Give the next entry after 'act_e'
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* @param act_e pointer to an entry
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* @return pointer to an entry after 'act_e'
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*/
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static lv_mem_ent_t * ent_get_next(lv_mem_ent_t * act_e)
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{
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lv_mem_ent_t * next_e = NULL;
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if(act_e == NULL) { /*NULL means: get the first entry*/
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next_e = (lv_mem_ent_t *) work_mem;
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} else { /*Get the next entry */
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uint8_t * data = &act_e->first_data;
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next_e = (lv_mem_ent_t *)&data[act_e->header.d_size];
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if(&next_e->first_data >= &work_mem[LV_MEM_SIZE]) next_e = NULL;
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}
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return next_e;
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}
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/**
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* Try to do the real allocation with a given size
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* @param e try to allocate to this entry
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* @param size size of the new memory in bytes
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* @return pointer to the allocated memory or NULL if not enough memory in the entry
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*/
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static void * ent_alloc(lv_mem_ent_t * e, uint32_t size)
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{
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void * alloc = NULL;
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/*If the memory is free and big enough then use it */
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if(e->header.used == 0 && e->header.d_size >= size) {
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/*Truncate the entry to the desired size */
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ent_trunc(e, size),
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e->header.used = 1;
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|
|
||
|
/*Save the allocated data*/
|
||
|
alloc = &e->first_data;
|
||
|
}
|
||
|
|
||
|
return alloc;
|
||
|
}
|
||
|
|
||
|
/**
|
||
|
* Truncate the data of entry to the given size
|
||
|
* @param e Pointer to an entry
|
||
|
* @param size new size in bytes
|
||
|
*/
|
||
|
static void ent_trunc(lv_mem_ent_t * e, uint32_t size)
|
||
|
{
|
||
|
/*Don't let empty space only for a header without data*/
|
||
|
if(e->header.d_size == size + sizeof(lv_mem_header_t)) {
|
||
|
size = e->header.d_size;
|
||
|
}
|
||
|
|
||
|
/* Create the new entry after the current if there is space for it */
|
||
|
if(e->header.d_size != size) {
|
||
|
uint8_t * e_data = &e->first_data;
|
||
|
lv_mem_ent_t * after_new_e = (lv_mem_ent_t *)&e_data[size];
|
||
|
after_new_e->header.used = 0;
|
||
|
after_new_e->header.d_size = e->header.d_size - size - sizeof(lv_mem_header_t);
|
||
|
}
|
||
|
|
||
|
/* Set the new size for the original entry */
|
||
|
e->header.d_size = size;
|
||
|
}
|
||
|
|
||
|
#endif
|