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/*
*
* Copyright (c) 2020-2022 Project CHIP Authors
* Copyright 2024 NXP
*
* 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 "NXPConfig.h"
#include <lib/core/CHIPEncoding.h>
#include <platform/CHIPDeviceError.h>
#include <platform/internal/testing/ConfigUnitTest.h>
#include <platform/nxp/common/CHIPDeviceNXPPlatformDefaultConfig.h>
#include <settings.h>
/* Only for flash init, to be move to sdk framework */
#include "port/nvs_port.h"
#if (CHIP_DEVICE_CONFIG_KVS_WEAR_STATS == 1)
#include "fwk_nvs_stats.h"
#endif /* CHIP_DEVICE_CONFIG_KVS_WEAR_STATS */
// These can be overridden by the application as needed.
#ifndef CHIP_DEVICE_INTEGER_SETTINGS_KEY
/// Key for all integer keys
#define CHIP_DEVICE_INTEGER_SETTINGS_KEY "mt_i"
#endif // CHIP_DEVICE_CONFIG_SETTINGS_KEY
#ifndef CHIP_DEVICE_STRING_SETTINGS_KEY
/// Key for all string keys
#define CHIP_DEVICE_STRING_SETTINGS_KEY "mt_s"
#endif // CHIP_DEVICE_CONFIG_SETTINGS_KEY
namespace chip {
namespace DeviceLayer {
namespace Internal {
namespace {
struct ReadRequest
{
void * const destination; // NOTE: can be nullptr in which case `configSize` should still be returned
const size_t bufferSize; // size of destination buffer
CHIP_ERROR result; // [out] read result
size_t configSize; // [out] size of configuration value
};
struct DeleteSubtreeEntry
{
int result;
};
// Callback for settings_load_subtree_direct() function
int ConfigValueCallback(const char * name, size_t configSize, settings_read_cb readCb, void * cbArg, void * param)
{
// If requested config key X, process just node X and ignore all its descendants: X/*
if (name != nullptr && *name != '\0')
return 0;
ReadRequest & request = *reinterpret_cast<ReadRequest *>(param);
if (!request.destination || configSize > request.bufferSize)
{
request.result = CHIP_ERROR_BUFFER_TOO_SMALL;
request.configSize = configSize;
return 1;
}
// Found requested key
const ssize_t bytesRead = readCb(cbArg, request.destination, request.bufferSize);
request.result = bytesRead > 0 ? CHIP_NO_ERROR : CHIP_ERROR_PERSISTED_STORAGE_FAILED;
request.configSize = bytesRead > 0 ? bytesRead : 0;
// Return 1 to stop processing further keys
return 1;
}
// Read configuration value of maximum size `bufferSize` and store the actual size in `configSize`.
CHIP_ERROR ReadConfigValueImpl(const NXPConfig::Key key, void * const destination, const size_t bufferSize, size_t & configSize)
{
ReadRequest request{ destination, bufferSize, CHIP_DEVICE_ERROR_CONFIG_NOT_FOUND, 0 };
char key_name[SETTINGS_MAX_NAME_LEN + 1];
sprintf(key_name, CHIP_DEVICE_INTEGER_SETTINGS_KEY "/%04x", key);
settings_load_subtree_direct(key_name, ConfigValueCallback, &request);
configSize = request.configSize;
return request.result;
}
CHIP_ERROR WriteConfigValueImpl(const NXPConfig::Key key, const void * const source, const size_t length)
{
char key_name[SETTINGS_MAX_NAME_LEN + 1];
sprintf(key_name, CHIP_DEVICE_INTEGER_SETTINGS_KEY "/%04x", key);
if (settings_save_one(key_name, source, length) != 0)
return CHIP_ERROR_PERSISTED_STORAGE_FAILED;
#if (DEBUG_NVM > 0)
ChipLogProgress(DeviceLayer, "WriteConfigValue done");
#endif
return CHIP_NO_ERROR;
}
template <class T>
inline CHIP_ERROR ReadSimpleConfigValue(const NXPConfig::Key key, T & value)
{
CHIP_ERROR result;
T tempValue;
size_t configSize;
result = ReadConfigValueImpl(key, &tempValue, sizeof(T), configSize);
SuccessOrExit(result);
// For simple types require that size of the output variable matches size of the configuration value
VerifyOrExit(configSize == sizeof(T), result = CHIP_ERROR_INVALID_ARGUMENT);
value = tempValue;
exit:
return result;
}
int DeleteSubtreeCallback(const char * name, size_t /* entrySize */, settings_read_cb /* readCb */, void * /* cbArg */,
void * param)
{
DeleteSubtreeEntry & entry = *static_cast<DeleteSubtreeEntry *>(param);
char fullKey[SETTINGS_MAX_NAME_LEN + 1];
(void) snprintf(fullKey, sizeof(fullKey), CHIP_DEVICE_STRING_SETTINGS_KEY "/%s", StringOrNullMarker(name));
const int result = settings_delete(fullKey);
// Return the first error, but continue removing remaining keys anyway.
if (entry.result == 0)
{
entry.result = result;
}
return 0;
}
#if (CHIP_DEVICE_CONFIG_KVS_WEAR_STATS == 1)
void OnFlashSectorWearCountUpdate(uint16_t sector_idx, const nvs_storage_wear_profile_t * flash_wear_profile)
{
char keyUser[] = CHIP_DEVICE_CONFIG_KVS_WEAR_STATS_KEY;
const size_t flash_wear_profile_size = NVS_STORAGE_WEAR_PROFILE_SIZE(flash_wear_profile->sector_count);
/* Update the NVS stats key in storage */
NXPConfig::WriteConfigValueBin((const char *) keyUser, (uint8_t *) flash_wear_profile, flash_wear_profile_size);
}
#endif /* CHIP_DEVICE_CONFIG_KVS_WEAR_STATS */
} // namespace
CHIP_ERROR NXPConfig::Init()
{
/* Only for flash init, to be move to sdk framework */
/* Initialize flash components */
const struct flash_area * fa;
ReturnErrorCodeIf(flash_area_open(SETTINGS_PARTITION, &fa), CHIP_ERROR_PERSISTED_STORAGE_FAILED);
ReturnErrorCodeIf(flash_init(fa->fa_dev), CHIP_ERROR_PERSISTED_STORAGE_FAILED);
/* End flash init */
ReturnErrorCodeIf(settings_subsys_init(), CHIP_ERROR_PERSISTED_STORAGE_FAILED);
#if (CHIP_DEVICE_CONFIG_KVS_WEAR_STATS == 1)
ReturnErrorOnFailure(InitStorageWearStats());
#endif /* CHIP_DEVICE_CONFIG_KVS_WEAR_STATS */
return CHIP_NO_ERROR;
}
#if (CHIP_DEVICE_CONFIG_KVS_WEAR_STATS == 1)
CHIP_ERROR NXPConfig::InitStorageWearStats(void)
{
nvs_storage_wear_profile_t * flash_wear_profile = NULL;
const size_t flash_wear_profile_size = NVS_STORAGE_WEAR_PROFILE_SIZE((uint32_t) NV_STORAGE_MAX_SECTORS);
size_t size;
char keyUser[] = CHIP_DEVICE_CONFIG_KVS_WEAR_STATS_KEY;
/* Create an empty flash wear profile */
flash_wear_profile = (nvs_storage_wear_profile_t *) calloc(1, flash_wear_profile_size);
ReturnErrorCodeIf(flash_wear_profile == NULL, CHIP_ERROR_NO_MEMORY);
/* Try to read the flash wear profile from the User Support diagnostic log key */
CHIP_ERROR err = ReadConfigValueBin((const char *) keyUser, (uint8_t *) flash_wear_profile, flash_wear_profile_size, size);
if ((err != CHIP_NO_ERROR) || (size != flash_wear_profile_size) ||
(flash_wear_profile->sector_count != (uint32_t) NV_STORAGE_MAX_SECTORS))
{
/* Either the flash wear stats are not available in the persistent
* storage or the flash wear statistics that we have read are not
* compatible with the current persistent storage configuration. In
* this case - just reset and save the flash wear statistics. */
flash_wear_profile->sector_count = (uint32_t) NV_STORAGE_MAX_SECTORS;
memset(flash_wear_profile->erase_count, 0, (uint32_t) NV_STORAGE_MAX_SECTORS * sizeof(uint16_t));
WriteConfigValueBin((const char *) keyUser, (uint8_t *) flash_wear_profile, flash_wear_profile_size);
}
else
{
/* Load the flash wear profile into the NVS statistics */
nvs_stats_load_profile(flash_wear_profile);
}
free(flash_wear_profile);
nvs_stats_config_event_handler(OnFlashSectorWearCountUpdate);
return CHIP_NO_ERROR;
}
#endif /* CHIP_DEVICE_CONFIG_KVS_WEAR_STATS */
CHIP_ERROR NXPConfig::ReadConfigValue(Key key, bool & val)
{
ReturnErrorCodeIf(!ValidConfigKey(key), CHIP_DEVICE_ERROR_CONFIG_NOT_FOUND); // Verify key id.
return ReadSimpleConfigValue(key, val);
}
CHIP_ERROR NXPConfig::ReadConfigValue(Key key, uint32_t & val)
{
ReturnErrorCodeIf(!ValidConfigKey(key), CHIP_DEVICE_ERROR_CONFIG_NOT_FOUND); // Verify key id.
return ReadSimpleConfigValue(key, val);
}
CHIP_ERROR NXPConfig::ReadConfigValue(Key key, uint64_t & val)
{
ReturnErrorCodeIf(!ValidConfigKey(key), CHIP_DEVICE_ERROR_CONFIG_NOT_FOUND); // Verify key id.
return ReadSimpleConfigValue(key, val);
}
CHIP_ERROR NXPConfig::ReadConfigValueStr(Key key, char * buf, size_t bufSize, size_t & outLen)
{
CHIP_ERROR err = CHIP_NO_ERROR;
ReturnErrorCodeIf(!ValidConfigKey(key), err = CHIP_DEVICE_ERROR_CONFIG_NOT_FOUND); // Verify key id.
// Pretend that the buffer is smaller by 1 to secure space for null-character
err = ReadConfigValueImpl(key, buf, bufSize ? bufSize - 1 : 0, outLen);
if (err == CHIP_NO_ERROR)
{
if (buf[outLen - 1]) // CHIP_NO_ERROR implies outLen > 0
buf[outLen] = 0;
else
outLen--;
}
return err;
}
CHIP_ERROR NXPConfig::ReadConfigValueBin(Key key, uint8_t * buf, size_t bufSize, size_t & outLen)
{
return ReadConfigValueImpl(key, buf, bufSize, outLen);
}
CHIP_ERROR NXPConfig::ReadConfigValueBin(const char * keyString, uint8_t * buf, size_t bufSize, size_t & outLen)
{
ReadRequest request{ buf, bufSize, CHIP_DEVICE_ERROR_CONFIG_NOT_FOUND, 0 };
char key_name[SETTINGS_MAX_NAME_LEN + 1];
unsigned key_name_len;
// to be able to concat CHIP_DEVICE_STRING_SETTINGS_KEY"/" and keyString, + 1 for end char
key_name_len = strlen(keyString) + strlen(CHIP_DEVICE_STRING_SETTINGS_KEY) + 1;
ReturnErrorCodeIf(key_name_len > (SETTINGS_MAX_NAME_LEN + 1), CHIP_ERROR_PERSISTED_STORAGE_FAILED);
sprintf(key_name, CHIP_DEVICE_STRING_SETTINGS_KEY "/%s", keyString);
settings_load_subtree_direct(key_name, ConfigValueCallback, &request);
outLen = request.configSize;
return request.result;
}
CHIP_ERROR NXPConfig::ReadConfigValueCounter(uint8_t counterIdx, uint32_t & val)
{
Key key = kMinConfigKey_ChipCounter + counterIdx;
return ReadConfigValue(key, val);
}
CHIP_ERROR NXPConfig::WriteConfigValue(Key key, bool val)
{
return WriteConfigValueImpl(key, &val, sizeof(bool));
}
CHIP_ERROR NXPConfig::WriteConfigValue(Key key, uint32_t val)
{
return WriteConfigValueImpl(key, &val, sizeof(uint32_t));
}
CHIP_ERROR NXPConfig::WriteConfigValue(Key key, uint64_t val)
{
return WriteConfigValueImpl(key, &val, sizeof(uint64_t));
}
CHIP_ERROR NXPConfig::WriteConfigValueStr(Key key, const char * str)
{
return WriteConfigValueStr(key, str, str ? strlen(str) : 0);
}
CHIP_ERROR NXPConfig::WriteConfigValueStr(Key key, const char * str, size_t strLen)
{
ReturnErrorCodeIf(!ValidConfigKey(key), CHIP_DEVICE_ERROR_CONFIG_NOT_FOUND); // Verify key id.
return WriteConfigValueImpl(key, str, strLen);
}
CHIP_ERROR NXPConfig::WriteConfigValueBin(Key key, const uint8_t * data, size_t dataLen)
{
return WriteConfigValueStr(key, (char *) data, dataLen);
}
CHIP_ERROR NXPConfig::WriteConfigValueBin(const char * keyString, const uint8_t * data, size_t dataLen)
{
char key_name[SETTINGS_MAX_NAME_LEN + 1];
unsigned key_name_len;
// to be able to concat CHIP_DEVICE_STRING_SETTINGS_KEY"/" and keyString, + 1 for end char
key_name_len = strlen(keyString) + strlen(CHIP_DEVICE_STRING_SETTINGS_KEY) + 1;
ReturnErrorCodeIf(key_name_len > (SETTINGS_MAX_NAME_LEN + 1), CHIP_ERROR_PERSISTED_STORAGE_FAILED);
sprintf(key_name, CHIP_DEVICE_STRING_SETTINGS_KEY "/%s", keyString);
if (settings_save_one(key_name, data, dataLen) != 0)
return CHIP_ERROR_PERSISTED_STORAGE_FAILED;
return CHIP_NO_ERROR;
}
CHIP_ERROR NXPConfig::WriteConfigValueCounter(uint8_t counterIdx, uint32_t val)
{
Key key = kMinConfigKey_ChipCounter + counterIdx;
return WriteConfigValue(key, val);
}
CHIP_ERROR NXPConfig::ClearConfigValue(Key key)
{
char key_name[SETTINGS_MAX_NAME_LEN + 1];
sprintf(key_name, CHIP_DEVICE_INTEGER_SETTINGS_KEY "/%04x", key);
return ClearConfigValue(key_name);
}
CHIP_ERROR NXPConfig::ClearConfigValue(const char * keyString)
{
char key_name[SETTINGS_MAX_NAME_LEN];
unsigned key_name_len;
// to be able to concat CHIP_DEVICE_STRING_SETTINGS_KEY"/" and keyString, + 1 for end char
key_name_len = strlen(keyString) + strlen(CHIP_DEVICE_STRING_SETTINGS_KEY) + 1;
ReturnErrorCodeIf(key_name_len > (SETTINGS_MAX_NAME_LEN + 1), CHIP_ERROR_PERSISTED_STORAGE_FAILED);
sprintf(key_name, CHIP_DEVICE_STRING_SETTINGS_KEY "/%s", keyString);
if (settings_delete(key_name) != 0)
return CHIP_ERROR_PERSISTED_STORAGE_FAILED;
return CHIP_NO_ERROR;
}
bool NXPConfig::ConfigValueExists(Key key)
{
bool err = false;
if (ValidConfigKey(key))
{
size_t configSize;
err = ReadConfigValueImpl(key, nullptr, 0, configSize) == CHIP_ERROR_BUFFER_TOO_SMALL;
}
return err;
}
CHIP_ERROR NXPConfig::FactoryResetConfig(void)
{
DeleteSubtreeEntry entry{ /* success */ 0 };
// Clear CHIP_DEVICE_STRING_SETTINGS_KEY/* keys
int result = settings_load_subtree_direct(CHIP_DEVICE_STRING_SETTINGS_KEY, DeleteSubtreeCallback, &entry);
if (result == 0)
{
result = entry.result;
}
char key_name[SETTINGS_MAX_NAME_LEN + 1];
for (Key key = kMinConfigKey_ChipConfig; key <= kMaxConfigKey_ChipConfig; key++)
{
sprintf(key_name, CHIP_DEVICE_INTEGER_SETTINGS_KEY "/%04x", key);
if (settings_delete(key_name) != 0)
return CHIP_ERROR_PERSISTED_STORAGE_FAILED;
}
// Clear RebootCount, TotalOperationalHours, UpTime counters during factory reset
for (Key key = kMinConfigKey_ChipCounter; key <= (kMinConfigKey_ChipCounter + 3); key++)
{
sprintf(key_name, CHIP_DEVICE_INTEGER_SETTINGS_KEY "/%04x", key);
if (settings_delete(key_name) != 0)
return CHIP_ERROR_PERSISTED_STORAGE_FAILED;
}
return CHIP_NO_ERROR;
}
bool NXPConfig::ValidConfigKey(Key key)
{
// Returns true if the key is in the valid CHIP Config PDM key range.
return (key >= kMinConfigKey_ChipFactory) && (key <= kMaxConfigKey_KVS);
}
void NXPConfig::RunConfigUnitTest(void) {}
void NXPConfig::RunSystemIdleTask(void) {}
} // namespace Internal
} // namespace DeviceLayer
} // namespace chip