2019-12-03 23:42:07 +00:00
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.. _filesystem:
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Working with filesystems
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========================
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.. contents::
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This tutorial describes how MicroPython provides an on-device filesystem,
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allowing standard Python file I/O methods to be used with persistent storage.
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MicroPython automatically creates a default configuration and auto-detects the
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primary filesystem, so this tutorial will be mostly useful if you want to modify
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the partitioning, filesystem type, or use custom block devices.
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The filesystem is typically backed by internal flash memory on the device, but
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can also use external flash, RAM, or a custom block device.
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On some ports (e.g. STM32), the filesystem may also be available over USB MSC to
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a host PC. :ref:`pyboard_py` also provides a way for the host PC to access to
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the filesystem on all ports.
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Note: This is mainly for use on bare-metal ports like STM32 and ESP32. On ports
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with an operating system (e.g. the Unix port) the filesystem is provided by the
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host OS.
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VFS
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---
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MicroPython implements a Unix-like Virtual File System (VFS) layer. All mounted
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filesystems are combined into a single virtual filesystem, starting at the root
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``/``. Filesystems are mounted into directories in this structure, and at
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startup the working directory is changed to where the primary filesystem is
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mounted.
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On STM32 / Pyboard, the internal flash is mounted at ``/flash``, and optionally
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the SDCard at ``/sd``. On ESP8266/ESP32, the primary filesystem is mounted at
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``/``.
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Block devices
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-------------
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A block device is an instance of a class that implements the
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2021-08-12 04:59:29 +01:00
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:class:`os.AbstractBlockDev` protocol.
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2019-12-03 23:42:07 +00:00
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Built-in block devices
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~~~~~~~~~~~~~~~~~~~~~~
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Ports provide built-in block devices to access their primary flash.
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On power-on, MicroPython will attempt to detect the filesystem on the default
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flash and configure and mount it automatically. If no filesystem is found,
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MicroPython will attempt to create a FAT filesystem spanning the entire flash.
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Ports can also provide a mechanism to "factory reset" the primary flash, usually
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by some combination of button presses at power on.
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STM32 / Pyboard
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...............
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The :ref:`pyb.Flash <pyb.Flash>` class provides access to the internal flash. On some
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boards which have larger external flash (e.g. Pyboard D), it will use that
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instead. The ``start`` kwarg should always be specified, i.e.
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``pyb.Flash(start=0)``.
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Note: For backwards compatibility, when constructed with no arguments (i.e.
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``pyb.Flash()``), it only implements the simple block interface and reflects the
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virtual device presented to USB MSC (i.e. it includes a virtual partition table
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at the start).
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ESP8266
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.......
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The internal flash is exposed as a block device object which is created in the
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``flashbdev`` module on start up. This object is by default added as a global
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variable so it can usually be accessed simply as ``bdev``. This implements the
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extended interface.
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ESP32
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.....
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The :class:`esp32.Partition` class implements a block device for partitions
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defined for the board. Like ESP8266, there is a global variable ``bdev`` which
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points to the default partition. This implements the extended interface.
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Custom block devices
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~~~~~~~~~~~~~~~~~~~~
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The following class implements a simple block device that stores its data in
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RAM using a ``bytearray``::
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class RAMBlockDev:
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def __init__(self, block_size, num_blocks):
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self.block_size = block_size
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self.data = bytearray(block_size * num_blocks)
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def readblocks(self, block_num, buf):
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for i in range(len(buf)):
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buf[i] = self.data[block_num * self.block_size + i]
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def writeblocks(self, block_num, buf):
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for i in range(len(buf)):
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self.data[block_num * self.block_size + i] = buf[i]
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def ioctl(self, op, arg):
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if op == 4: # get number of blocks
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return len(self.data) // self.block_size
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if op == 5: # get block size
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return self.block_size
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It can be used as follows::
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import os
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bdev = RAMBlockDev(512, 50)
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os.VfsFat.mkfs(bdev)
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os.mount(bdev, '/ramdisk')
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An example of a block device that supports both the simple and extended
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interface (i.e. both signatures and behaviours of the
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:meth:`os.AbstractBlockDev.readblocks` and
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:meth:`os.AbstractBlockDev.writeblocks` methods) is::
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class RAMBlockDev:
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def __init__(self, block_size, num_blocks):
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self.block_size = block_size
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self.data = bytearray(block_size * num_blocks)
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2019-12-06 16:28:36 +00:00
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def readblocks(self, block_num, buf, offset=0):
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addr = block_num * self.block_size + offset
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for i in range(len(buf)):
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buf[i] = self.data[addr + i]
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def writeblocks(self, block_num, buf, offset=None):
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if offset is None:
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# do erase, then write
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for i in range(len(buf) // self.block_size):
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self.ioctl(6, block_num + i)
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offset = 0
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addr = block_num * self.block_size + offset
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for i in range(len(buf)):
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self.data[addr + i] = buf[i]
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def ioctl(self, op, arg):
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if op == 4: # block count
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return len(self.data) // self.block_size
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if op == 5: # block size
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return self.block_size
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if op == 6: # block erase
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return 0
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As it supports the extended interface, it can be used with :class:`littlefs
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<os.VfsLfs2>`::
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import os
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bdev = RAMBlockDev(512, 50)
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os.VfsLfs2.mkfs(bdev)
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os.mount(bdev, '/ramdisk')
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2019-12-09 03:21:22 +00:00
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Once mounted, the filesystem (regardless of its type) can be used as it
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normally would be used from Python code, for example::
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with open('/ramdisk/hello.txt', 'w') as f:
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f.write('Hello world')
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print(open('/ramdisk/hello.txt').read())
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2019-12-03 23:42:07 +00:00
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Filesystems
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-----------
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2021-08-12 04:59:29 +01:00
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MicroPython ports can provide implementations of :class:`FAT <os.VfsFat>`,
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:class:`littlefs v1 <os.VfsLfs1>` and :class:`littlefs v2 <os.VfsLfs2>`.
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The following table shows which filesystems are included in the firmware by
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default for given port/board combinations, however they can be optionally
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enabled in a custom firmware build.
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==================== ===== =========== ===========
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Board FAT littlefs v1 littlefs v2
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==================== ===== =========== ===========
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pyboard 1.0, 1.1, D Yes No Yes
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Other STM32 Yes No No
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esp8266: Change from FAT to littlefs v2 as default filesystem.
This commit changes the esp8266 boards to use littlefs v2 as the
filesystem, rather than FAT. Since the esp8266 doesn't expose the
filesystem to the PC over USB there's no strong reason to keep it as FAT.
Littlefs is smaller in code size, is more efficient in use of flash to
store data, is resilient over power failure, and using it saves about 4k of
heap RAM, which can now be used for other things.
This is a backwards incompatible change because all existing esp8266 boards
will need to update their filesystem after installing new firmware (eg
backup old files, install firmware, restore files to new filesystem).
As part of this commit the memory layout of the default board (GENERIC) has
changed. It now allocates all 1M of memory-mapped flash to the firmware,
so the filesystem area starts at the 2M point. This is done to allow more
frozen bytecode to be stored in the 1M of memory-mapped flash. This
requires an esp8266 module with 2M or more of flash to work, so a new board
called GENERIC_1M is added which has the old memory-mapping (but still
changed to use littlefs for the filesystem).
In summary there are now 3 esp8266 board definitions:
- GENERIC_512K: for 512k modules, doesn't have a filesystem.
- GENERIC_1M: for 1M modules, 572k for firmware+frozen code, 396k for
filesystem (littlefs).
- GENERIC: for 2M (or greater) modules, 968k for firmware+frozen code,
1M+ for filesystem (littlefs), FAT driver also included in firmware for
use on, eg, external SD cards.
2020-03-26 11:35:32 +00:00
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ESP8266 (1M) No No Yes
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ESP8266 (2M+) Yes No Yes
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ESP32 Yes No Yes
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==================== ===== =========== ===========
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FAT
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~~~
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The main advantage of the FAT filesystem is that it can be accessed over USB MSC
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on supported boards (e.g. STM32) without any additional drivers required on the
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host PC.
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However, FAT is not tolerant to power failure during writes and this can lead to
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filesystem corruption. For applications that do not require USB MSC, it is
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recommended to use littlefs instead.
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To format the entire flash using FAT::
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# ESP8266 and ESP32
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import os
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os.umount('/')
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os.VfsFat.mkfs(bdev)
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os.mount(bdev, '/')
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# STM32
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import os, pyb
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os.umount('/flash')
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os.VfsFat.mkfs(pyb.Flash(start=0))
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os.mount(pyb.Flash(start=0), '/flash')
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os.chdir('/flash')
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Littlefs
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~~~~~~~~
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Littlefs_ is a filesystem designed for flash-based devices, and is much more
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resistant to filesystem corruption.
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2019-12-10 05:58:53 +00:00
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.. note:: There are reports of littlefs v1 and v2 failing in certain
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situations, for details see `littlefs issue 347`_ and
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`littlefs issue 295`_.
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2019-12-03 23:42:07 +00:00
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To format the entire flash using littlefs v2::
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# ESP8266 and ESP32
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import os
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os.umount('/')
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os.VfsLfs2.mkfs(bdev)
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os.mount(bdev, '/')
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# STM32
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import os, pyb
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os.umount('/flash')
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os.VfsLfs2.mkfs(pyb.Flash(start=0))
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os.mount(pyb.Flash(start=0), '/flash')
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os.chdir('/flash')
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2021-11-08 01:43:18 +00:00
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A littlefs filesystem can be still be accessed on a PC over USB MSC using the
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`littlefs FUSE driver`_. Note that you must specify both the ``--block_size``
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and ``--block_count`` options to override the defaults. For example (after
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building the littlefs-fuse executable)::
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$ ./lfs --block_size=4096 --block_count=512 -o allow_other /dev/sdb1 mnt
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This will allow the board's littlefs filesystem to be accessed at the ``mnt``
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directory. To get the correct values of ``block_size`` and ``block_count`` use::
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import pyb
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f = pyb.Flash(start=0)
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f.ioctl(1, 1) # initialise flash in littlefs raw-block mode
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block_count = f.ioctl(4, 0)
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block_size = f.ioctl(5, 0)
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.. _littlefs FUSE driver: https://github.com/littlefs-project/littlefs-fuse
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.. _Littlefs: https://github.com/littlefs-project/littlefs
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.. _littlefs issue 295: https://github.com/littlefs-project/littlefs/issues/295
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.. _littlefs issue 347: https://github.com/littlefs-project/littlefs/issues/347
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2019-12-03 23:42:07 +00:00
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Hybrid (STM32)
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~~~~~~~~~~~~~~
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By using the ``start`` and ``len`` kwargs to :class:`pyb.Flash`, you can create
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block devices spanning a subset of the flash device.
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For example, to configure the first 256kiB as FAT (and available over USB MSC),
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and the remainder as littlefs::
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import os, pyb
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os.umount('/flash')
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p1 = pyb.Flash(start=0, len=256*1024)
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p2 = pyb.Flash(start=256*1024)
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os.VfsFat.mkfs(p1)
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os.VfsLfs2.mkfs(p2)
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os.mount(p1, '/flash')
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os.mount(p2, '/data')
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os.chdir('/flash')
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This might be useful to make your Python files, configuration and other
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rarely-modified content available over USB MSC, but allowing for frequently
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changing application data to reside on littlefs with better resilience to power
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failure, etc.
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The partition at offset ``0`` will be mounted automatically (and the filesystem
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type automatically detected), but you can add::
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import os, pyb
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p2 = pyb.Flash(start=256*1024)
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os.mount(p2, '/data')
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to ``boot.py`` to mount the data partition.
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Hybrid (ESP32)
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~~~~~~~~~~~~~~
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On ESP32, if you build custom firmware, you can modify ``partitions.csv`` to
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define an arbitrary partition layout.
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At boot, the partition named "vfs" will be mounted at ``/`` by default, but any
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additional partitions can be mounted in your ``boot.py`` using::
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import esp32, os
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p = esp32.Partition.find(esp32.Partition.TYPE_DATA, label='foo')
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os.mount(p, '/foo')
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