/****************************************************************************** * Flash api for NodeMCU * NodeMCU Team * 2014-12-31 *******************************************************************************/ #include "user_config.h" #include "flash_api.h" #include "spi_flash.h" #include "c_stdio.h" uint32_t flash_detect_size_byte(void) { // enable operations on whole physical flash, SDK might have restricted // the flash size already extern SpiFlashChip * flashchip; uint32 orig_chip_size = flashchip->chip_size; flashchip->chip_size = FLASH_SIZE_16MBYTE; #define FLASH_BUFFER_SIZE_DETECT 32 uint32_t dummy_size = FLASH_SIZE_256KBYTE; uint8_t data_orig[FLASH_BUFFER_SIZE_DETECT] ICACHE_STORE_ATTR = {0}; uint8_t data_new[FLASH_BUFFER_SIZE_DETECT] ICACHE_STORE_ATTR = {0}; if (SPI_FLASH_RESULT_OK == flash_read(0, (uint32 *)data_orig, FLASH_BUFFER_SIZE_DETECT)) { dummy_size = FLASH_SIZE_256KBYTE; while ((dummy_size < FLASH_SIZE_16MBYTE) && (SPI_FLASH_RESULT_OK == flash_read(dummy_size, (uint32 *)data_new, FLASH_BUFFER_SIZE_DETECT)) && (0 != os_memcmp(data_orig, data_new, FLASH_BUFFER_SIZE_DETECT)) ) { dummy_size *= 2; } }; // revert temporary setting flashchip->chip_size = orig_chip_size; return dummy_size; #undef FLASH_BUFFER_SIZE_DETECT } static SPIFlashInfo spi_flash_info = {0}; SPIFlashInfo *flash_rom_getinfo(void) { if (spi_flash_info.entry_point == 0) { spi_flash_read(0, (uint32 *)(& spi_flash_info), sizeof(spi_flash_info)); } return &spi_flash_info; } uint8_t flash_rom_get_size_type(void) { return flash_rom_getinfo()->size; } uint32_t flash_rom_get_size_byte(void) { static uint32_t flash_size = 0; if (flash_size == 0) { switch (flash_rom_getinfo()->size) { case SIZE_2MBIT: // 2Mbit, 256kByte flash_size = 256 * 1024; break; case SIZE_4MBIT: // 4Mbit, 512kByte flash_size = 512 * 1024; break; case SIZE_8MBIT: // 8Mbit, 1MByte flash_size = 1 * 1024 * 1024; break; case SIZE_16MBIT: // 16Mbit, 2MByte flash_size = 2 * 1024 * 1024; break; case SIZE_32MBIT: // 32Mbit, 4MByte flash_size = 4 * 1024 * 1024; break; case SIZE_16MBIT_8M_8M: // 16Mbit, 2MByte flash_size = 2 * 1024 * 1024; break; case SIZE_32MBIT_8M_8M: // 32Mbit, 4MByte flash_size = 4 * 1024 * 1024; break; case SIZE_32MBIT_16M_16M: // 32Mbit, 4MByte flash_size = 4 * 1024 * 1024; break; case SIZE_64MBIT: // 64Mbit, 8MByte flash_size = 8 * 1024 * 1024; break; case SIZE_128MBIT: // 128Mbit, 16MByte flash_size = 16 * 1024 * 1024; break; default: // Unknown flash size, fall back mode. flash_size = 512 * 1024; break; } } return flash_size; } uint16_t flash_rom_get_sec_num(void) { return ( flash_rom_get_size_byte() / (SPI_FLASH_SEC_SIZE) ); } uint8_t flash_rom_get_mode(void) { uint8_t mode = flash_rom_getinfo()->mode; switch (mode) { // Reserved for future use case MODE_QIO: break; case MODE_QOUT: break; case MODE_DIO: break; case MODE_DOUT: break; } return mode; } uint32_t flash_rom_get_speed(void) { uint32_t speed = 0; uint8_t spi_speed = flash_rom_getinfo()->speed; switch (spi_speed) { case SPEED_40MHZ: // 40MHz speed = 40000000; break; case SPEED_26MHZ: //26.7MHz speed = 26700000; break; case SPEED_20MHZ: // 20MHz speed = 20000000; break; case SPEED_80MHZ: //80MHz speed = 80000000; break; } return speed; } uint8_t byte_of_aligned_array(const uint8_t *aligned_array, uint32_t index) { if ( (((uint32_t)aligned_array) % 4) != 0 ) { NODE_DBG("aligned_array is not 4-byte aligned.\n"); return 0; } volatile uint32_t v = ((uint32_t *)aligned_array)[ index / 4 ]; uint8_t *p = (uint8_t *) (&v); return p[ (index % 4) ]; } uint16_t word_of_aligned_array(const uint16_t *aligned_array, uint32_t index) { if ( (((uint32_t)aligned_array) % 4) != 0 ) { NODE_DBG("aligned_array is not 4-byte aligned.\n"); return 0; } volatile uint32_t v = ((uint32_t *)aligned_array)[ index / 2 ]; uint16_t *p = (uint16_t *) (&v); return (index % 2 == 0) ? p[ 0 ] : p[ 1 ]; }