129 lines
4.8 KiB
ReStructuredText
129 lines
4.8 KiB
ReStructuredText
.. _nvs:
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Non-Volatile Storage (NVS)
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##########################
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Elements, represented as id-data pairs, are stored in flash using a
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FIFO-managed circular buffer. The flash area is divided into sectors. Elements
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are appended to a sector until storage space in the sector is exhausted. Then a
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new sector in the flash area is prepared for use (erased). Before erasing the
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sector it is checked that identifier - data pairs exist in the sectors in use,
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if not the id-data pair is copied.
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The id is a 16-bit unsigned number. NVS ensures that for each used id there is
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at least one id-data pair stored in flash at all time.
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NVS allows storage of binary blobs, strings, integers, longs, and any
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combination of these.
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Each element is stored in flash as metadata (8 byte) and data. The metadata is
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written in a table starting from the end of a nvs sector, the data is
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written one after the other from the start of the sector. The metadata consists
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of: id, data offset in sector, data length, part (unused) and a crc.
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A write of data to nvs always starts with writing the data, followed by a write
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of the metadata. Data that is written in flash without metadata is ignored
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during initialization.
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During initialization NVS will verify the data stored in flash, if it
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encounters an error it will ignore any data with missing/incorrect metadata.
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NVS checks the id-data pair before writing data to flash. If the id-data pair
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is unchanged no write to flash is performed.
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To protect the flash area against frequent erases it is important that there is
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sufficient free space. NVS has a protection mechanism to avoid getting in a
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endless loop of flash page erases when there is limited free space. When such
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a loop is detected NVS returns that there is no more space available.
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For NVS the file system is declared as:
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.. code-block:: c
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static struct nvs_fs fs = {
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.sector_size = NVS_SECTOR_SIZE,
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.sector_count = NVS_SECTOR_COUNT,
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.offset = NVS_STORAGE_OFFSET,
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};
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where
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- ``NVS_SECTOR_SIZE`` is the sector size, it has to be a multiple of
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the flash erase page size and a power of 2.
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- ``NVS_SECTOR_COUNT`` is the number of sectors, it is at least 2, one
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sector is always kept empty to allow copying of existing data.
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- ``NVS_STORAGE_OFFSET`` is the offset of the storage area in flash.
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Flash wear
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**********
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When writing data to flash a study of the flash wear is important. Flash has a
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limited life which is determined by the number of times flash can be erased.
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Flash is erased one page at a time and the pagesize is determined by the
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hardware. As an example a nRF51822 device has a pagesize of 1024 bytes and each
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page can be erased about 20,000 times.
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Calculating expected device lifetime
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====================================
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Suppose we use a 4 bytes state variable that is changed every minute and
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needs to be restored after reboot. NVS has been defined with a sector_size
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equal to the pagesize (1024 bytes) and 2 sectors have been defined.
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Each write of the state variable requires 12 bytes of flash storage: 8 bytes
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for the metadata and 4 bytes for the data. When storing the data the
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first sector will be full after 1024/12 = 85.33 minutes. After another 85.33
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minutes, the second sector is full. When this happens, because we're using
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only two sectors, the first sector will be used for storage and will be erased
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after 171 minutes of system time. With the expected device life of 20,000
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writes, with two sectors writing every 171 minutes, the device should last
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about 171 * 20,000 minutes, or about 6.5 years.
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More generally then, with
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- ``NS`` as the number of storage requests per minute,
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- ``DS`` as the data size in bytes,
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- ``SECTOR_SIZE`` in bytes, and
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- ``PAGE_ERASES`` as the number of times the page can be erased,
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the expected device life (in minutes) can be calculated as::
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SECTOR_COUNT * SECTOR_SIZE * PAGE_ERASES / (NS * (DS+8)) minutes
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From this formula it is also clear what to do in case the expected life is too
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short: increase ``SECTOR_COUNT`` or ``SECTOR_SIZE``.
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Sample
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******
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A sample of how NVS can be used is supplied in ``samples/subsys/nvs``.
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Troubleshooting
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***************
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MPU fault while using NVS, or ``-ETIMEDOUT`` error returned
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NVS can use the internal flash of the SoC. While the MPU is enabled,
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the flash driver requires MPU RWX access to flash memory, configured
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using :option:`CONFIG_MPU_ALLOW_FLASH_WRITE`. If this option is
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disabled, the NVS application will get an MPU fault if it references
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the internal SoC flash and it's the only thread running. In a
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multi-threaded application, another thread might intercept the fault
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and the NVS API will return an ``-ETIMEDOUT`` error.
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API Reference
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*************
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The NVS subsystem APIs are provided by ``nvs.h``:
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.. doxygengroup:: nvs_data_structures
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:project: Zephyr
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.. doxygengroup:: nvs_high_level_api
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:project: Zephyr
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.. comment
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not documenting
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.. doxygengroup:: nvs
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