Vekatech
SDHI_driver patch (mbedOS 5.11.5)
mbed-os-program/mbed-os/features/storage/kvstore/conf/kv_config.cpp
- Committer:
- tvendov
- Date:
- 2019-03-29
- Revision:
- 2:7c75ab32d7c9
File content as of revision 2:7c75ab32d7c9:
/*
* Copyright (c) 2018 ARM Limited. All rights reserved.
* SPDX-License-Identifier: Apache-2.0
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "kv_config.h"
#include "KVStore.h"
#include "KVMap.h"
#include "BlockDevice.h"
#include "FileSystem.h"
#include "FileSystemStore.h"
#include "SlicingBlockDevice.h"
#include "FATFileSystem.h"
#include "LittleFileSystem.h"
#include "TDBStore.h"
#include "mbed_error.h"
#include "FlashIAP.h"
#include "FlashSimBlockDevice.h"
#include "mbed_trace.h"
#include "SecureStore.h"
#define TRACE_GROUP "KVCFG"
#if COMPONENT_FLASHIAP
#include "FlashIAPBlockDevice.h"
#endif
#if COMPONENT_QSPIF
#include "QSPIFBlockDevice.h"
#endif
#if COMPONENT_SPIF
#include "SPIFBlockDevice.h"
#endif
#if COMPONENT_DATAFLASH
#include "DataFlashBlockDevice.h"
#endif
#if COMPONENT_SD
#include "SDBlockDevice.h"
#endif
#if COMPONENT_RZ_SDHI
#include "RZ_SDHIBlockDevice.hpp"
#endif
/**
* @brief This function initializes internal memory secure storage
* This includes a TDBStore instance with a FlashIAPBlockdevice
* as the supported storage.
* The following is a list of configuration parameter
* MBED_CONF_STORAGE_TDB_INTERNAL_SIZE - The size of the underlying FlashIAPBlockdevice
* MBED_CONF_STORAGE_TDB_INTERNAL_BASE_ADDRESS - The start address of the underlying FlashIAPBlockdevice
* @returns 0 on success or negative value on failure.
*/
int _storage_config_TDB_INTERNAL();
/**
* @brief This function initialize external memory secure storage
* This includes a SecureStore class with TDBStore over FlashIAPBlockdevice
* and an external TDBStore over a default blockdevice unless configured differently.
* The following is a list of configuration parameter:
* MBED_CONF_STORAGE_TDB_EXTERNAL_RBP_INTERNAL_SIZE - Size of the internal FlashIAPBlockDevice and by
* default is set to from start address to the end of the flash.
* If start address is 0 the start address will be set to end of
* flash - rbp_internal_size.
* MBED_CONF_STORAGE_TDB_EXTERNAL_INTERNAL_BASE_ADDRESS - The satrt address of the internal FlashIAPBlockDevice.
* MBED_CONF_STORAGE_TDB_EXTERNAL_EXTERNAL_SIZE - Size of the external blockdevice in bytes or NULL for
* max possible size.
* MBED_CONF_STORAGE_TDB_EXTERNAL_EXTERNAL_BASE_ADDRESS - The block device start address.
* MBED_CONF_STORAGE_TDB_EXTERNAL_EXTERNAL_BLOCK_DEVICE - Alowed vlaues are: default, SPIF, DATAFASH, QSPIF or SD
* @returns 0 on success or negative value on failure.
*/
int _storage_config_TDB_EXTERNAL();
/**
* @brief This function initialize a external memory secure storage
* This includes a SecureStore class with external TDBStore over a blockdevice or,
* if no blockdevice was set the default blockdevice will be used.
* The following is a list of configuration parameter:
* MBED_CONF_STORAGE_TDB_EXTERNAL_NO_RBP_EXTERNAL_SIZE - Size of the external blockdevice in bytes
* or NULL for max possible size.
* MBED_CONF_STORAGE_TDB_EXTERNAL_NO_RBP_EXTERNAL_BASE_ADDRESS - The block device start address
* MBED_CONF_STORAGE_TDB_EXTERNAL_NO_RBP_EXTERNAL_BLOCK_DEVICE - Alowed vlaues are: default, SPIF, DATAFASH, QSPIF or SD
* @returns 0 on success or negative value on failure.
*/
int _storage_config_TDB_EXTERNAL_NO_RBP();
/**
* @brief This function initialize a FILESYSTEM memory secure storage
* This includes a SecureStore class with TDBStore over FlashIAPBlockdevice
* in the internal memory and an external FileSysteStore. If blockdevice and filesystem not set,
* the system will use the default block device and default filesystem
* The following is a list of configuration parameter:
* MBED_CONF_STORAGE_FILESYSTEM_RBP_INTERNAL_SIZE - Size of the internal FlashIAPBlockDevice and by
* default is set to from start address to the end of the flash.
* If start address is 0 the start address will be set to end of
* flash - rbp_internal_size.
* MBED_CONF_STORAGE_FILESYSTEM_INTERNAL_BASE_ADDRESS - The satrt address of the internal FlashIAPBlockDevice.
* MBED_CONF_STORAGE_FILESYSTEM_FILESYSTEM - Allowed values are: default, FAT or LITTLE
* MBED_CONF_STORAGE_FILESYSTEM_BLOCKDEVICE - Allowed values are: default, SPIF, DATAFASH, QSPIF or SD
* MBED_CONF_STORAGE_FILESYSTEM_EXTERNAL_SIZE - External Blockdevice size in bytes or NULL for max possible size.
* MBED_CONF_STORAGE_FILESYSTEM_EXTERNAL_BASE_ADDRESS - The block device start address.
* MBED_CONF_STORAGE_FILESYSTEM_MOUNT_POINT - Where to mount the filesystem
* MBED_CONF_STORAGE_FILESYSTEM_FOLDER_PATH - The working folder paths
*
* @returns 0 on success or negative value on failure.
*/
int _storage_config_FILESYSTEM();
/**
* @brief This function initialize a FILESYSTEM_NO_RBP memory secure storage with no
* rollback protection. This includes a SecureStore class an external FileSysteStore over a default
* filesystem with default blockdevice unless differently configured.
* The following is a list of configuration parameter:
* MBED_CONF_STORAGE_FILESYSTEM_NO_RBP_FILESYSTEM - Allowed values are: default, FAT or LITTLE
* MBED_CONF_STORAGE_FILESYSTEM_NO_RBP_BLOCKDEVICE - Allowed values are: default, SPIF, DATAFASH, QSPIF or SD
* MBED_CONF_STORAGE_FILESYSTEM_NO_RBP_EXTERNAL_SIZE - Blockdevice size in bytes. or NULL for max possible size.
* MBED_CONF_STORAGE_FILESYSTEM_NO_RBP_EXTERNAL_BASE_ADDRESS - The block device start address.
* MBED_CONF_STORAGE_FILESYSTEM_NO_RBP_MOUNT_POINT - Where to mount the filesystem
* MBED_CONF_STORAGE_FILESYSTEM_NO_RBP_FOLDER_PATH - The working folder paths
*
* @returns 0 on success or negative value on failure.
*/
int _storage_config_FILESYSTEM_NO_RBP();
int _storage_config_tdb_external_common();
int _storage_config_filesystem_common();
static const char *filesystemstore_folder_path = NULL;
using namespace mbed;
static SingletonPtr<PlatformMutex> mutex;
static bool is_kv_config_initialize = false;
static kvstore_config_t kvstore_config;
#define INTERNAL_BLOCKDEVICE_NAME FLASHIAP
#define STR_EXPAND(tok) #tok
#define STR(tok) STR_EXPAND(tok)
#define _GET_FILESYSTEM_concat(dev, ...) _get_filesystem_##dev(__VA_ARGS__)
#define GET_FILESYSTEM(dev, ...) _GET_FILESYSTEM_concat(dev, __VA_ARGS__)
#define _GET_BLOCKDEVICE_concat(dev, ...) _get_blockdevice_##dev(__VA_ARGS__)
#define GET_BLOCKDEVICE(dev, ...) _GET_BLOCKDEVICE_concat(dev, __VA_ARGS__)
static inline uint32_t align_up(uint64_t val, uint64_t size)
{
return (((val - 1) / size) + 1) * size;
}
static inline uint32_t align_down(uint64_t val, uint64_t size)
{
return (((val) / size)) * size;
}
int _calculate_blocksize_match_tdbstore(BlockDevice *bd)
{
bd_size_t size = bd->size();
bd_size_t erase_size = bd->get_erase_size();
bd_size_t number_of_sector = size / erase_size;
if (number_of_sector < 2) {
tr_warning("KV Config: There are less than two sectors - TDBStore will not work.");
return -1;
}
if (number_of_sector % 2 != 0) {
tr_warning("KV Config: Number of sectors is not an even number. Consider changing the BlockDevice size");
}
return MBED_SUCCESS;
}
int _get_addresses(BlockDevice *bd, bd_addr_t start_address, bd_size_t size, bd_addr_t *out_start_addr,
bd_addr_t *out_end_addr)
{
bd_addr_t aligned_end_address;
bd_addr_t end_address;
bd_addr_t aligned_start_address;
aligned_start_address = align_down(start_address, bd->get_erase_size(start_address));
if (aligned_start_address != start_address) {
tr_error("KV Config: Start address is not aligned. Better use %02llx", aligned_start_address);
return -1;
}
if (size == 0) {
(*out_start_addr) = aligned_start_address;
(*out_end_addr) = bd->size();
return 0;
}
end_address = start_address + size;
aligned_end_address = align_up(end_address, bd->get_erase_size(end_address));
if (aligned_end_address != end_address) {
tr_error("KV Config: End address is not aligned. Consider changing the size parameter.");
return -1;
}
if (aligned_end_address > bd->size()) {
tr_error("KV Config: End address is out of boundaries");
return -1;
}
(*out_start_addr) = aligned_start_address;
(*out_end_addr) = aligned_end_address;
return 0;
}
FileSystem *_get_filesystem_FAT(const char *mount)
{
static FATFileSystem sdcard(mount);
return &sdcard;
}
FileSystem *_get_filesystem_LITTLE(const char *mount)
{
static LittleFileSystem flash(mount);
return &flash;
}
FileSystemStore *_get_file_system_store(FileSystem *fs)
{
static FileSystemStore fss(fs);
return &fss;
}
FileSystem *_get_filesystem_default(const char *mount)
{
#if COMPONENT_QSPIF || COMPONENT_SPIF || COMPONENT_DATAFLASH
return _get_filesystem_LITTLE(mount);
#elif (COMPONENT_SD || COMPONENT_RZ_SDHI)
return _get_filesystem_FAT(mount);
#else
return NULL;
#endif
}
//Calculates the start address of FLASHIAP block device for TDB_INTERNAL profile.
//If possible, the address will start 2 sectors after the end of code sector allowing
//some space for an application update.
int _get_flashiap_bd_default_addresses_tdb_internal(bd_addr_t *start_address, bd_size_t *size)
{
#if COMPONENT_FLASHIAP
FlashIAP flash;
if (*start_address != 0 || *size != 0) {
return MBED_ERROR_INVALID_ARGUMENT;
}
//If default values are set, we should get the maximum available size of internal bd.
if (flash.init() != 0) {
return MBED_ERROR_FAILED_OPERATION;
}
*start_address = align_up(FLASHIAP_APP_ROM_END_ADDR, flash.get_sector_size(FLASHIAP_APP_ROM_END_ADDR));
// Give the application a couple of spare sectors to grow (if there are such)
bd_size_t spare_size_for_app = 0;
bd_addr_t curr_addr = *start_address;
bd_addr_t flash_end_address = flash.get_flash_start() + flash.get_flash_size();
int spare_sectors_for_app = 2;
int min_sectors_for_storage = 2;
for (int i = 0; i < spare_sectors_for_app + min_sectors_for_storage - 1; i++) {
bd_size_t sector_size = flash.get_sector_size(curr_addr);
curr_addr += sector_size;
if (curr_addr >= flash_end_address) {
spare_size_for_app = 0;
break;
}
if (i < spare_sectors_for_app) {
spare_size_for_app += sector_size;
}
}
*start_address += spare_size_for_app;
flash.deinit();
#endif
return MBED_SUCCESS;
}
//Calculates address and size for FLASHIAP block device in TDB_EXTERNAL and FILESYSTEM profiles.
//The size of the block device will be 2 sectors at the ends of the internal flash for
//the use of the rbp internal TDBStore.
int _get_flashiap_bd_default_addresses_rbp(bd_addr_t *start_address, bd_size_t *size)
{
#if COMPONENT_FLASHIAP
bd_addr_t flash_end_address;
bd_addr_t flash_start_address;
bd_addr_t aligned_start_address;
bd_addr_t flash_first_writable_sector_address;
FlashIAP flash;
if (*start_address != 0 || *size != 0) {
return MBED_ERROR_INVALID_ARGUMENT;
}
int ret = flash.init();
if (ret != 0) {
return MBED_ERROR_INITIALIZATION_FAILED;
}
flash_first_writable_sector_address = align_up(FLASHIAP_APP_ROM_END_ADDR, flash.get_sector_size(FLASHIAP_APP_ROM_END_ADDR));
flash_start_address = flash.get_flash_start();
flash_end_address = flash_start_address + flash.get_flash_size();;
*start_address = flash_end_address - 1;
aligned_start_address = align_down(*start_address, flash.get_sector_size(*start_address));
*size = (flash_end_address - aligned_start_address) * 2;
*start_address = (flash_end_address - *size);
aligned_start_address = align_down(*start_address, flash.get_sector_size(*start_address));
flash.deinit();
if (aligned_start_address < flash_first_writable_sector_address) {
tr_error("KV Config: Internal block device start address overlapped ROM address ");
return MBED_ERROR_INITIALIZATION_FAILED;
}
#endif
return MBED_SUCCESS;
}
BlockDevice *_get_blockdevice_FLASHIAP(bd_addr_t start_address, bd_size_t size)
{
#if COMPONENT_FLASHIAP
bd_addr_t flash_end_address;
bd_addr_t flash_start_address;
bd_addr_t flash_first_writable_sector_address;
bd_addr_t aligned_start_address;
bd_addr_t aligned_end_address;
bd_addr_t end_address;
FlashIAP flash;
int ret = flash.init();
if (ret != 0) {
return NULL;
}
//Get flash parameters before starting
flash_first_writable_sector_address = align_up(FLASHIAP_APP_ROM_END_ADDR, flash.get_sector_size(FLASHIAP_APP_ROM_END_ADDR));
flash_start_address = flash.get_flash_start();
flash_end_address = flash_start_address + flash.get_flash_size();;
//Non default configuration
if (start_address != 0) {
aligned_start_address = align_down(start_address, flash.get_sector_size(start_address));
if (start_address != aligned_start_address) {
tr_error("KV Config: Internal block device start address is not aligned. Better use %02llx", aligned_start_address);
flash.deinit();
return NULL;
}
if (size == 0) {
//The block device will have all space form start address to the end of the flash
size = (flash_end_address - start_address);
static FlashIAPBlockDevice bd(start_address, size);
flash.deinit();
return &bd;
}
if (size != 0) {
end_address = start_address + size;
if (end_address > flash_end_address) {
tr_error("KV Config: Internal block device end address is out of boundaries");
flash.deinit();
return NULL;
}
aligned_end_address = align_up(end_address, flash.get_sector_size(end_address - 1));
if (end_address != aligned_end_address) {
tr_error("KV Config: Internal block device start address is not aligned. Consider changing the size parameter");
flash.deinit();
return NULL;
}
static FlashIAPBlockDevice bd(start_address, size);
flash.deinit();
return &bd;
}
}
//Non default configuration start_address = 0
start_address = flash_end_address - size;
aligned_start_address = align_down(start_address, flash.get_sector_size(start_address));
if (start_address != aligned_start_address) {
tr_error("KV Config: Internal block device start address is not aligned. Consider changing the size parameter");
flash.deinit();
return NULL;
}
flash.deinit();
if (aligned_start_address < flash_first_writable_sector_address) {
tr_error("KV Config: Internal block device start address overlapped ROM address ");
return NULL;
}
static FlashIAPBlockDevice bd(aligned_start_address, size);
return &bd;
#else
return NULL;
#endif
}
BlockDevice *_get_blockdevice_SPIF(bd_addr_t start_address, bd_size_t size)
{
#if COMPONENT_SPIF
bd_addr_t aligned_end_address;
bd_addr_t aligned_start_address;
static SPIFBlockDevice bd(
MBED_CONF_SPIF_DRIVER_SPI_MOSI,
MBED_CONF_SPIF_DRIVER_SPI_MISO,
MBED_CONF_SPIF_DRIVER_SPI_CLK,
MBED_CONF_SPIF_DRIVER_SPI_CS,
MBED_CONF_SPIF_DRIVER_SPI_FREQ
);
if (bd.init() != MBED_SUCCESS) {
tr_error("KV Config: SPIFBlockDevice init fail");
return NULL;
}
if (start_address == 0 && size == 0) {
return &bd;
}
//If address and size were specified use SlicingBlockDevice to get the correct block device size and start address.
if (_get_addresses(&bd, start_address, size, &aligned_start_address, &aligned_end_address) != 0) {
tr_error("KV Config: Fail to get addresses for SlicingBlockDevice.");
return NULL;
}
static SlicingBlockDevice sbd(&bd, aligned_start_address, aligned_end_address);
return &sbd;
#else
return NULL;
#endif
}
BlockDevice *_get_blockdevice_QSPIF(bd_addr_t start_address, bd_size_t size)
{
#if COMPONENT_QSPIF
bd_addr_t aligned_end_address;
bd_addr_t aligned_start_address;
static QSPIFBlockDevice bd(
QSPI_FLASH1_IO0,
QSPI_FLASH1_IO1,
QSPI_FLASH1_IO2,
QSPI_FLASH1_IO3,
QSPI_FLASH1_SCK,
QSPI_FLASH1_CSN,
QSPIF_POLARITY_MODE_0,
MBED_CONF_QSPIF_QSPI_FREQ
);
if (bd.init() != MBED_SUCCESS) {
tr_error("KV Config: QSPIFBlockDevice init fail");
return NULL;
}
if (start_address == 0 && size == 0) {
return &bd;
}
//If address and size were specified use SlicingBlockDevice to get the correct block device size and start address.
if (_get_addresses(&bd, start_address, size, &aligned_start_address, &aligned_end_address) != 0) {
tr_error("KV Config: Fail to get addresses for SlicingBlockDevice.");
return NULL;
}
static SlicingBlockDevice sbd(&bd, aligned_start_address, aligned_end_address);
return &sbd;
#else
return NULL;
#endif
}
BlockDevice *_get_blockdevice_DATAFLASH(bd_addr_t start_address, bd_size_t size)
{
#if COMPONENT_DATAFLASH
bd_addr_t aligned_end_address;
bd_addr_t aligned_start_address;
static DataFlashBlockDevice bd(
MBED_CONF_DATAFLASH_SPI_MOSI,
MBED_CONF_DATAFLASH_SPI_MISO,
MBED_CONF_DATAFLASH_SPI_CLK,
MBED_CONF_DATAFLASH_SPI_CS
);
if (bd.init() != MBED_SUCCESS) {
tr_error("KV Config: DataFlashBlockDevice init fail");
return NULL;
}
if (start_address == 0 && size == 0) {
return &bd;
}
//If address and size were specified use SlicingBlockDevice to get the correct block device size and start address.
if (_get_addresses(&bd, start_address, size, &aligned_start_address, &aligned_end_address) != 0) {
tr_error("KV Config: Fail to get addresses for SlicingBlockDevice.");
return NULL;
}
static SlicingBlockDevice sbd(&bd, aligned_start_address, aligned_end_address);
return &sbd;
#else
return NULL;
#endif
}
BlockDevice *_get_blockdevice_SD(bd_addr_t start_address, bd_size_t size)
{
#if COMPONENT_SD
bd_addr_t aligned_end_address;
bd_addr_t aligned_start_address;
static SDBlockDevice bd(
MBED_CONF_SD_SPI_MOSI,
MBED_CONF_SD_SPI_MISO,
MBED_CONF_SD_SPI_CLK,
MBED_CONF_SD_SPI_CS
);
if (bd.init() != MBED_SUCCESS) {
tr_error("KV Config: SDBlockDevice init fail");
return NULL;
}
if (strcmp(STR(MBED_CONF_STORAGE_STORAGE_TYPE), "TDB_EXTERNAL_NO_RBP") == 0 ||
strcmp(STR(MBED_CONF_STORAGE_STORAGE_TYPE), "TDB_EXTERNAL") == 0) {
//In TDBStore profile, we have a constraint of 4GByte
if (start_address == 0 && size == 0 && bd.size() < (uint32_t)(-1)) {
return &bd;
}
//If the size of external storage is bigger than 4G we need to slice it.
size = size != 0 ? size : align_down(bd.size(), bd.get_erase_size(bd.size() - 1));
if (_get_addresses(&bd, start_address, size, &aligned_start_address, &aligned_end_address) != 0) {
tr_error("KV Config: Fail to get addresses for SlicingBlockDevice.");
return NULL;
}
if (aligned_end_address - aligned_start_address != (uint32_t)(aligned_end_address - aligned_start_address)) {
aligned_end_address = aligned_start_address + (uint32_t)(-1);//Support up to 4G only
}
} else {
//For all other KVStore profiles beside TDBStore we take the entire external memory space.
if (start_address == 0 && size == 0) {
return &bd;
}
if (_get_addresses(&bd, start_address, size, &aligned_start_address, &aligned_end_address) != 0) {
tr_error("KV Config: Fail to get addresses for SlicingBlockDevice.");
return NULL;
}
}
aligned_end_address = align_down(aligned_end_address, bd.get_erase_size(aligned_end_address));
static SlicingBlockDevice sbd(&bd, aligned_start_address, aligned_end_address);
return &sbd;
#else
return NULL;
#endif
}
BlockDevice *_get_blockdevice_RZ_SDHI(bd_addr_t start_address, bd_size_t size)
{
#if COMPONENT_RZ_SDHI
bd_addr_t aligned_end_address;
bd_addr_t aligned_start_address;
static SDHIBlockDevice bd(MBED_CONF_RZ_SDHI_CH);
if (bd.init() != MBED_SUCCESS) {
tr_error("KV Config: SDBlockDevice init fail");
return NULL;
}
if (strcmp(STR(MBED_CONF_STORAGE_STORAGE_TYPE), "TDB_EXTERNAL_NO_RBP") == 0 ||
strcmp(STR(MBED_CONF_STORAGE_STORAGE_TYPE), "TDB_EXTERNAL") == 0) {
//In TDBStore profile, we have a constraint of 4GByte
if (start_address == 0 && size == 0 && bd.size() < (uint32_t)(-1)) {
return &bd;
}
//If the size of external storage is bigger than 4G we need to slice it.
size = size != 0 ? size : align_down(bd.size(), bd.get_erase_size(bd.size() - 1));
if (_get_addresses(&bd, start_address, size, &aligned_start_address, &aligned_end_address) != 0) {
tr_error("KV Config: Fail to get addresses for SlicingBlockDevice.");
return NULL;
}
if (aligned_end_address - aligned_start_address != (uint32_t)(aligned_end_address - aligned_start_address)) {
aligned_end_address = aligned_start_address + (uint32_t)(-1);//Support up to 4G only
}
} else {
//For all other KVStore profiles beside TDBStore we take the entire external memory space.
if (start_address == 0 && size == 0) {
return &bd;
}
if (_get_addresses(&bd, start_address, size, &aligned_start_address, &aligned_end_address) != 0) {
tr_error("KV Config: Fail to get addresses for SlicingBlockDevice.");
return NULL;
}
}
aligned_end_address = align_down(aligned_end_address, bd.get_erase_size(aligned_end_address));
static SlicingBlockDevice sbd(&bd, aligned_start_address, aligned_end_address);
return &sbd;
#else
return NULL;
#endif
}
BlockDevice *_get_blockdevice_default(bd_addr_t start_address, bd_size_t size)
{
#if COMPONENT_QSPIF
return _get_blockdevice_QSPIF(start_address, size);
#elif COMPONENT_SPIF
return _get_blockdevice_SPIF(start_address, size);
#elif COMPONENT_DATAFLASH
return _get_blockdevice_DATAFLASH(start_address, size);
#elif COMPONENT_SD
return _get_blockdevice_SD(start_address, size);
#elif COMPONENT_RZ_SDHI
return _get_blockdevice_RZ_SDHI(start_address, size);
#else
tr_error("KV Config: No default component define in target.json for this target.");
return NULL;
#endif
}
int _storage_config_TDB_INTERNAL()
{
#if COMPONENT_FLASHIAP
bd_size_t internal_size = MBED_CONF_STORAGE_TDB_INTERNAL_INTERNAL_SIZE;
bd_addr_t internal_start_address = MBED_CONF_STORAGE_TDB_INTERNAL_INTERNAL_BASE_ADDRESS;
if (internal_size == 0 && internal_start_address == 0) {
//Calculate the block device size and start address in case default values are used.
if (_get_flashiap_bd_default_addresses_tdb_internal(&internal_start_address, &internal_size) != MBED_SUCCESS) {
return MBED_ERROR_FAILED_OPERATION;
}
}
//Get internal memory FLASHIAP block device.
kvstore_config.internal_bd = GET_BLOCKDEVICE(INTERNAL_BLOCKDEVICE_NAME, internal_start_address, internal_size);
if (kvstore_config.internal_bd == NULL) {
tr_error("KV Config: Fail to get internal BlockDevice.");
return MBED_ERROR_FAILED_OPERATION;
}
int ret = kvstore_config.internal_bd->init();
if (ret != MBED_SUCCESS) {
tr_error("KV Config: Fail to init internal BlockDevice.");
return MBED_ERROR_FAILED_OPERATION;
}
//Check that internal flash has 2 or more sectors
if (_calculate_blocksize_match_tdbstore(kvstore_config.internal_bd) != MBED_SUCCESS) {
tr_error("KV Config: Can not create TDBStore with less then 2 sector.");
return MBED_ERROR_INVALID_ARGUMENT;
}
//Deinitialize internal block device and TDB will reinitialize and take control on it.
ret = kvstore_config.internal_bd->deinit();
if (ret != MBED_SUCCESS) {
tr_error("KV Config: Fail to deinit internal BlockDevice.");
return MBED_ERROR_FAILED_OPERATION;
}
//Create a TDBStore in the internal FLASHIAP block device.
static TDBStore tdb_internal(kvstore_config.internal_bd);
kvstore_config.internal_store = &tdb_internal;
ret = kvstore_config.internal_store->init();
if (ret != MBED_SUCCESS) {
tr_error("KV Config: Fail to init internal TDBStore.");
return ret;
}
kvstore_config.kvstore_main_instance =
kvstore_config.internal_store;
//Masking flag - Actually used to remove any KVStore flag which is not supported
//in the chosen KVStore profile.
kvstore_config.flags_mask = ~(KVStore::REQUIRE_CONFIDENTIALITY_FLAG |
KVStore::REQUIRE_REPLAY_PROTECTION_FLAG);
//Initialize kv_map and add the configuration struct to KVStore map.
KVMap &kv_map = KVMap::get_instance();
ret = kv_map.init();
if (MBED_SUCCESS != ret) {
tr_error("KV Config: Fail to init KVStore global API.");
return ret;
}
ret = kv_map.attach(STR(MBED_CONF_STORAGE_DEFAULT_KV), &kvstore_config);
if (MBED_SUCCESS != ret) {
tr_error("KV Config: Fail to attach KVStore main instance to KVStore global API.");
return ret;
}
return MBED_SUCCESS;
#else
return MBED_ERROR_UNSUPPORTED;
#endif
}
int _storage_config_TDB_EXTERNAL()
{
#if !SECURESTORE_ENABLED
return MBED_ERROR_UNSUPPORTED;
#endif
bd_size_t internal_rbp_size = MBED_CONF_STORAGE_TDB_EXTERNAL_RBP_INTERNAL_SIZE;
bd_addr_t internal_start_address = MBED_CONF_STORAGE_TDB_EXTERNAL_INTERNAL_BASE_ADDRESS;
//Get the default address and size for internal rbp TDBStore
if (internal_rbp_size == 0 && internal_start_address == 0) {
//Calculate the block device size and start address in case default values are used.
if (_get_flashiap_bd_default_addresses_rbp(&internal_start_address, &internal_rbp_size) != MBED_SUCCESS) {
return MBED_ERROR_FAILED_OPERATION;
}
}
//Create internal FLASHIAP block device
kvstore_config.internal_bd = GET_BLOCKDEVICE(INTERNAL_BLOCKDEVICE_NAME, internal_start_address, internal_rbp_size);
if (kvstore_config.internal_bd == NULL) {
tr_error("KV Config: Fail to get internal BlockDevice.");
return MBED_ERROR_FAILED_OPERATION ;
}
int ret = kvstore_config.internal_bd->init();
if (ret != MBED_SUCCESS) {
tr_error("KV Config: Fail to init internal BlockDevice.");
return MBED_ERROR_FAILED_OPERATION ;
}
//Check if TDBStore has at least 2 sector.
if (_calculate_blocksize_match_tdbstore(kvstore_config.internal_bd) != MBED_SUCCESS) {
tr_error("KV Config: Can not create TDBStore with less then 2 sector.");
return MBED_ERROR_INVALID_ARGUMENT;
}
//Create internal TDBStore
static TDBStore tdb_internal(kvstore_config.internal_bd);
kvstore_config.internal_store = &tdb_internal;
ret = kvstore_config.internal_store->init();
if (ret != MBED_SUCCESS) {
tr_error("KV Config: Fail to init internal TDBStore.");
return ret;
}
bd_size_t size = MBED_CONF_STORAGE_TDB_EXTERNAL_EXTERNAL_SIZE;
bd_addr_t address = MBED_CONF_STORAGE_TDB_EXTERNAL_EXTERNAL_BASE_ADDRESS;
//Get external BlockDevice for TDBStore
BlockDevice *bd = GET_BLOCKDEVICE(MBED_CONF_STORAGE_TDB_EXTERNAL_BLOCKDEVICE, address, size);
if (bd == NULL) {
tr_error("KV Config: Fail to get external BlockDevice.");
return MBED_ERROR_FAILED_OPERATION ;
}
//TDBStore needs a block device base on flash. so if this is SD block device or the default block device is SD
//add FlashSimBlockDevice on top of the SDBlockDevice
#if defined(COMPONENT_SD) || defined(COMPONENT_RZ_SDHI)
if (strcmp(STR(MBED_CONF_STORAGE_TDB_EXTERNAL_BLOCKDEVICE), "SD") == 0
#if (defined(COMPONENT_SD) || defined(COMPONENT_RZ_SDHI))&& !defined(COMPONENT_SPIF) && !defined(COMPONENT_QSPIF) && !defined(COMPONENT_DATAFLASH)
|| strcmp(STR(MBED_CONF_STORAGE_TDB_EXTERNAL_BLOCKDEVICE), "default") == 0) {
#else
) {
#endif
//TDBStore need FlashSimBlockDevice when working with SD block device
if (bd->init() != MBED_SUCCESS) {
tr_error("KV Config: Fail to init external BlockDevice.");
return MBED_ERROR_FAILED_OPERATION ;
}
static FlashSimBlockDevice flash_bd(bd);
kvstore_config.external_bd = &flash_bd;
} else {
kvstore_config.external_bd = bd;
}
#else
kvstore_config.external_bd = bd;
#endif
kvstore_config.flags_mask = ~(0);
return _storage_config_tdb_external_common();
}
int _storage_config_TDB_EXTERNAL_NO_RBP()
{
#if !SECURESTORE_ENABLED
return MBED_ERROR_UNSUPPORTED;
#endif
bd_size_t size = MBED_CONF_STORAGE_TDB_EXTERNAL_NO_RBP_EXTERNAL_SIZE;
bd_addr_t address = MBED_CONF_STORAGE_TDB_EXTERNAL_NO_RBP_EXTERNAL_BASE_ADDRESS;
//Get external block device
BlockDevice *bd = GET_BLOCKDEVICE(MBED_CONF_STORAGE_TDB_EXTERNAL_NO_RBP_BLOCKDEVICE, address, size);
if (bd == NULL) {
tr_error("KV Config: Fail to get external BlockDevice.");
return MBED_ERROR_FAILED_OPERATION ;
}
//TDBStore needs a block device base on flash. so if this is SD block device or the default block device is SD
//add FlashSimBlockDevice on top of the SDBlockDevice
#if defined(COMPONENT_SD) || defined(COMPONENT_RZ_SDHI)
if (strcmp(STR(MBED_CONF_STORAGE_TDB_EXTERNAL_NO_RBP_BLOCKDEVICE), "SD") == 0
#if (defined(COMPONENT_SD) || defined(COMPONENT_RZ_SDHI)) && !defined(COMPONENT_SPIF) && !defined(COMPONENT_QSPIF) && !defined(COMPONENT_DATAFLASH)
|| strcmp(STR(MBED_CONF_STORAGE_TDB_EXTERNAL_NO_RBP_BLOCKDEVICE), "default") == 0) {
#else
) {
#endif
//TDBStore need FlashSimBlockDevice when working with SD block device
if (bd->init() != MBED_SUCCESS) {
tr_error("KV Config: Fail to init external BlockDevice.");
return MBED_ERROR_FAILED_OPERATION ;
}
static FlashSimBlockDevice flash_bd(bd);
kvstore_config.external_bd = &flash_bd;
} else {
kvstore_config.external_bd = bd;
}
#else
kvstore_config.external_bd = bd;
#endif
//Masking flag - Actually used to remove any KVStore flag which is not supported
//in the chosen KVStore profile.
kvstore_config.flags_mask = ~(KVStore::REQUIRE_REPLAY_PROTECTION_FLAG);
return _storage_config_tdb_external_common();
}
int _storage_config_tdb_external_common()
{
#if SECURESTORE_ENABLED
//Initialize external block device
int ret = kvstore_config.external_bd->init();
if (ret != MBED_SUCCESS) {
tr_error("KV Config: Fail to init external BlockDevice.");
return MBED_ERROR_FAILED_OPERATION ;
}
//Check that there is at least 2 sector for the external TDBStore
if (_calculate_blocksize_match_tdbstore(kvstore_config.external_bd) != MBED_SUCCESS) {
tr_error("KV Config: Can not create TDBStore with less then 2 sector.");
return MBED_ERROR_INVALID_SIZE;
}
//Create external TDBStore
static TDBStore tdb_external(kvstore_config.external_bd);
kvstore_config.external_store = &tdb_external;
//Create SecureStore and initialize it
static SecureStore secst(kvstore_config.external_store, kvstore_config.internal_store);
ret = secst.init();
if (ret != MBED_SUCCESS) {
tr_error("KV Config: Fail to init SecureStore.");
return ret ;
}
kvstore_config.kvstore_main_instance = &secst;
//Init kv_map and add the configuration struct to KVStore map.
KVMap &kv_map = KVMap::get_instance();
ret = kv_map.init();
if (MBED_SUCCESS != ret) {
tr_error("KV Config: Fail to init KVStore global API");
return ret;
}
ret = kv_map.attach(STR(MBED_CONF_STORAGE_DEFAULT_KV), &kvstore_config);
if (MBED_SUCCESS != ret) {
tr_error("KV Config: Fail to attach KvStore main instance to KVStore global API");
return ret;
}
return MBED_SUCCESS;
#else
return MBED_ERROR_UNSUPPORTED;
#endif
}
int _storage_config_FILESYSTEM()
{
#if !SECURESTORE_ENABLED
return MBED_ERROR_UNSUPPORTED;
#endif
filesystemstore_folder_path = STR(MBED_CONF_STORAGE_FILESYSTEM_FOLDER_PATH);
bd_size_t internal_rbp_size = MBED_CONF_STORAGE_FILESYSTEM_RBP_INTERNAL_SIZE;
bd_addr_t internal_start_address = MBED_CONF_STORAGE_FILESYSTEM_INTERNAL_BASE_ADDRESS;
//Get the default address and size for internal rbp TDBStore
if (internal_rbp_size == 0 && internal_start_address == 0) {
//Calculate the block device size and start address in case default values are used.
if (_get_flashiap_bd_default_addresses_rbp(&internal_start_address, &internal_rbp_size) != MBED_SUCCESS) {
return MBED_ERROR_FAILED_OPERATION;
}
}
//Get internal FLASHIAP block device
kvstore_config.internal_bd = GET_BLOCKDEVICE(INTERNAL_BLOCKDEVICE_NAME, internal_start_address, internal_rbp_size);
if (kvstore_config.internal_bd == NULL) {
tr_error("KV Config: Fail to get internal BlockDevice ");
return MBED_ERROR_FAILED_OPERATION ;
}
int ret = kvstore_config.internal_bd->init();
if (ret != MBED_SUCCESS) {
tr_error("KV Config: Fail to init internal BlockDevice ");
return MBED_ERROR_FAILED_OPERATION ;
}
//Check that internal flash has 2 or more sectors
if (_calculate_blocksize_match_tdbstore(kvstore_config.internal_bd) != MBED_SUCCESS) {
tr_error("KV Config: Can not create TDBStore with less then 2 sector.");
return MBED_ERROR_INVALID_ARGUMENT;
}
//Deinitialize internal block device and TDB will reinitialize and take control on it.
ret = kvstore_config.internal_bd->deinit();
if (ret != MBED_SUCCESS) {
tr_error("KV Config: Fail to deinit internal BlockDevice.");
return MBED_ERROR_FAILED_OPERATION;
}
//Create internal TDBStore for rbp
static TDBStore tdb_internal(kvstore_config.internal_bd);
kvstore_config.internal_store = &tdb_internal;
ret = kvstore_config.internal_store->init();
if (ret != MBED_SUCCESS) {
tr_error("KV Config: Fail to init internal TDBStore");
return ret;
}
bd_size_t size = MBED_CONF_STORAGE_FILESYSTEM_EXTERNAL_SIZE;
bd_addr_t address = MBED_CONF_STORAGE_FILESYSTEM_EXTERNAL_BASE_ADDRESS;
const char *mount_point = STR(MBED_CONF_STORAGE_FILESYSTEM_MOUNT_POINT);
//Get external block device for FileSystem.
kvstore_config.external_bd = GET_BLOCKDEVICE(MBED_CONF_STORAGE_FILESYSTEM_BLOCKDEVICE, address, size);
if (kvstore_config.external_bd == NULL) {
tr_error("KV Config: Fail to get external BlockDevice ");
return MBED_ERROR_FAILED_OPERATION ;
}
ret = kvstore_config.external_bd->init();
if (MBED_SUCCESS != ret) {
tr_error("KV Config: Fail to init external BlockDevice ");
return MBED_ERROR_FAILED_OPERATION ;
}
//Get FileSystem. Can be FAT, LITTLE or default. in case of default, the type will be decided base on the default
//component block device configured in the system. The priority is:
//QSPI -> SPI -> DATAFLASH == LITTLE
//SD == FAT
kvstore_config.external_fs = GET_FILESYSTEM(MBED_CONF_STORAGE_FILESYSTEM_FILESYSTEM, mount_point);
if (kvstore_config.external_fs == NULL) {
tr_error("KV Config: Fail to get FileSystem");
return MBED_ERROR_FAILED_OPERATION ;
}
kvstore_config.flags_mask = ~(0);
return _storage_config_filesystem_common();
}
int _storage_config_FILESYSTEM_NO_RBP()
{
#if !SECURESTORE_ENABLED
return MBED_ERROR_UNSUPPORTED;
#endif
filesystemstore_folder_path = STR(MBED_CONF_STORAGE_FILESYSTEM_NO_RBP_FOLDER_PATH);
bd_size_t size = MBED_CONF_STORAGE_FILESYSTEM_NO_RBP_EXTERNAL_SIZE;
bd_addr_t address = MBED_CONF_STORAGE_FILESYSTEM_NO_RBP_EXTERNAL_BASE_ADDRESS;
const char *mount_point = STR(MBED_CONF_STORAGE_FILESYSTEM_NO_RBP_MOUNT_POINT);
//Get external block device for FileSystem.
kvstore_config.external_bd = GET_BLOCKDEVICE(MBED_CONF_STORAGE_FILESYSTEM_NO_RBP_BLOCKDEVICE, address, size);
if (kvstore_config.external_bd == NULL) {
tr_error("KV Config: Fail to get external BlockDevice ");
return MBED_ERROR_FAILED_OPERATION ;
}
int ret = kvstore_config.external_bd->init();
if (MBED_SUCCESS != ret) {
tr_error("KV Config: Fail to init external BlockDevice ");
return MBED_ERROR_FAILED_OPERATION ;
}
//Get FileSystem. Can be FAT, LITTLE or default. in case of default, the type will be decided base on the default
//component block device configured in the system. The priority is:
//QSPI -> SPI -> DATAFLASH == LITTLE
//SD == FAT
kvstore_config.external_fs = GET_FILESYSTEM(MBED_CONF_STORAGE_FILESYSTEM_NO_RBP_FILESYSTEM, mount_point);
if (kvstore_config.external_fs == NULL) {
tr_error("KV Config: Fail to get FileSystem");
return MBED_ERROR_FAILED_OPERATION ;
}
//Masking flag - Actually used to remove any KVStore flag which is not supported
//in the chosen KVStore profile.
kvstore_config.flags_mask = ~(KVStore::REQUIRE_REPLAY_PROTECTION_FLAG);
return _storage_config_filesystem_common();
}
int _storage_config_filesystem_common()
{
#if SECURESTORE_ENABLED
//Mount file system. if it fails, try to reformat
int ret = kvstore_config.external_fs->mount(kvstore_config.external_bd);
if (ret != MBED_SUCCESS) {
ret = kvstore_config.external_fs->reformat(kvstore_config.external_bd);
if (ret != MBED_SUCCESS) {
tr_error("KV Config: Fail to mount FileSystem to %s",
STR(MBED_CONF_STORAGE_FILESYSTEM_NO_RBP_MOUNT_POINT));
return MBED_ERROR_FAILED_OPERATION ;
}
}
//Create FileSystemStore
kvstore_config.external_store = _get_file_system_store(kvstore_config.external_fs);
if (kvstore_config.external_store == NULL) {
tr_error("KV Config: Fail to get FileSystemStore");
return MBED_ERROR_FAILED_OPERATION ;
}
//Create SecureStore and set it as main KVStore
static SecureStore secst(kvstore_config.external_store, kvstore_config.internal_store);
ret = secst.init();
if (ret != MBED_SUCCESS) {
tr_error("KV Config: Fail to init SecureStore.");
return ret; ;
}
kvstore_config.kvstore_main_instance = &secst;
//Init kv_map and add the configuration struct to KVStore map.
KVMap &kv_map = KVMap::get_instance();
ret = kv_map.init();
if (MBED_SUCCESS != ret) {
tr_error("KV Config: Fail to init KVStore global API");
return ret;
}
ret = kv_map.attach(STR(MBED_CONF_STORAGE_DEFAULT_KV), &kvstore_config);
if (MBED_SUCCESS != ret) {
tr_error("KV Config: Fail to attach KvStore main instance to KVStore global API");
return ret;
}
return MBED_SUCCESS;
#else
return MBED_ERROR_UNSUPPORTED;
#endif
}
int _storage_config_default()
{
#if COMPONENT_QSPIF || COMPONENT_SPIF || COMPONENT_DATAFLASH
return _storage_config_TDB_EXTERNAL();
#elif (COMPONENT_SD || COMPONENT_RZ_SDHI)
return _storage_config_FILESYSTEM();
#elif COMPONENT_FLASHIAP
return _storage_config_TDB_INTERNAL();
#else
return MBED_ERROR_UNSUPPORTED;
#endif
}
const char *get_filesystemstore_folder_path()
{
return filesystemstore_folder_path;
}
MBED_WEAK int kv_init_storage_config()
{
int ret = MBED_SUCCESS;
// We currently have no supported configuration without internal storage
#ifndef COMPONENT_FLASHIAP
return MBED_ERROR_UNSUPPORTED;
#endif
mutex->lock();
if (is_kv_config_initialize) {
goto exit;
}
memset(&kvstore_config, 0, sizeof(kvstore_config_t));
ret = _STORAGE_CONFIG(MBED_CONF_STORAGE_STORAGE_TYPE);
if (ret == MBED_SUCCESS) {
is_kv_config_initialize = true;
}
exit:
mutex->unlock();
return ret;
}