unleashed-firmware/targets/f7/furi_hal/furi_hal_memory.c
あく acc39a4bc0
Api Symbols: replace asserts with checks (#3507)
* Api Symbols: replace asserts with checks
* Api Symbols: replace asserts with checks part 2
* Update no args function signatures with void, to help compiler to track incorrect usage
* More unavoidable void
* Update PVS config and code to make it happy
* Format sources
* nfc: fix checks
* dead code cleanup & include fixes

Co-authored-by: gornekich <n.gorbadey@gmail.com>
Co-authored-by: hedger <hedger@users.noreply.github.com>
Co-authored-by: hedger <hedger@nanode.su>
2024-03-19 23:43:52 +09:00

130 lines
3.8 KiB
C

#include <furi_hal.h>
#include <furi_hal_memory.h>
#include <furi_hal_rtc.h>
#define TAG "FuriHalMemory"
typedef enum {
SRAM_A,
SRAM_B,
SRAM_MAX,
} SRAM;
typedef struct {
void* start;
uint32_t size;
} FuriHalMemoryRegion;
typedef struct {
FuriHalMemoryRegion region[SRAM_MAX];
} FuriHalMemory;
static FuriHalMemory* furi_hal_memory = NULL;
extern const void __sram2a_start__;
extern const void __sram2a_free__;
extern const void __sram2b_start__;
void furi_hal_memory_init(void) {
if(furi_hal_rtc_get_boot_mode() != FuriHalRtcBootModeNormal) {
return;
}
FuriHalMemory* memory = malloc(sizeof(FuriHalMemory));
uint32_t sbrsa = (FLASH->SRRVR & FLASH_SRRVR_SBRSA_Msk) >> FLASH_SRRVR_SBRSA_Pos;
uint32_t snbrsa = (FLASH->SRRVR & FLASH_SRRVR_SNBRSA_Msk) >> FLASH_SRRVR_SNBRSA_Pos;
// STM(TM) Copro(TM) bug(TM): SNBRSA is incorrect if stack version is higher than 1.13 and lower than 1.17.2+
// Radio core started, but not yet ready, so we'll try to guess
// This will be true only if BLE light radio stack used,
// 0x0D is known to be incorrect, 0x0B is known to be correct since 1.17.2+
// Lower value by 2 pages to match real memory layout
if(snbrsa > 0x0B) {
FURI_LOG_E(TAG, "SNBRSA workaround");
snbrsa -= 2;
}
uint32_t sram2a_busy_size = (uint32_t)&__sram2a_free__ - (uint32_t)&__sram2a_start__;
uint32_t sram2a_unprotected_size = (sbrsa) * 1024;
uint32_t sram2b_unprotected_size = (snbrsa) * 1024;
memory->region[SRAM_A].start = (uint8_t*)&__sram2a_free__;
memory->region[SRAM_B].start = (uint8_t*)&__sram2b_start__;
if(sram2a_unprotected_size > sram2a_busy_size) {
memory->region[SRAM_A].size = sram2a_unprotected_size - sram2a_busy_size;
} else {
memory->region[SRAM_A].size = 0;
}
memory->region[SRAM_B].size = sram2b_unprotected_size;
FURI_LOG_I(
TAG, "SRAM2A: 0x%p, %lu", memory->region[SRAM_A].start, memory->region[SRAM_A].size);
FURI_LOG_I(
TAG, "SRAM2B: 0x%p, %lu", memory->region[SRAM_B].start, memory->region[SRAM_B].size);
if((memory->region[SRAM_A].size > 0) || (memory->region[SRAM_B].size > 0)) {
if((memory->region[SRAM_A].size > 0)) {
FURI_LOG_I(TAG, "SRAM2A clear");
memset(memory->region[SRAM_A].start, 0, memory->region[SRAM_A].size);
}
if((memory->region[SRAM_B].size > 0)) {
FURI_LOG_I(TAG, "SRAM2B clear");
memset(memory->region[SRAM_B].start, 0, memory->region[SRAM_B].size);
}
furi_hal_memory = memory;
FURI_LOG_I(TAG, "Enabled");
} else {
free(memory);
FURI_LOG_E(TAG, "No SRAM2 available");
}
}
void* furi_hal_memory_alloc(size_t size) {
if(FURI_IS_IRQ_MODE()) {
furi_crash("memmgt in ISR");
}
if(furi_hal_memory == NULL) {
return NULL;
}
void* allocated_memory = NULL;
FURI_CRITICAL_ENTER();
for(int i = 0; i < SRAM_MAX; i++) {
if(furi_hal_memory->region[i].size >= size) {
void* ptr = furi_hal_memory->region[i].start;
furi_hal_memory->region[i].start += size;
furi_hal_memory->region[i].size -= size;
allocated_memory = ptr;
break;
}
}
FURI_CRITICAL_EXIT();
return allocated_memory;
}
size_t furi_hal_memory_get_free(void) {
if(furi_hal_memory == NULL) return 0;
size_t free = 0;
for(int i = 0; i < SRAM_MAX; i++) {
free += furi_hal_memory->region[i].size;
}
return free;
}
size_t furi_hal_memory_max_pool_block(void) {
if(furi_hal_memory == NULL) return 0;
size_t max = 0;
for(int i = 0; i < SRAM_MAX; i++) {
if(furi_hal_memory->region[i].size > max) {
max = furi_hal_memory->region[i].size;
}
}
return max;
}