Python framework for interacting with SMBus-compatible i2c devices
Project description
i2cdevice
i2cdevice is a Python framework aimed at dealing with common SMBus/i2c device interaction patterns.
This project aims to make group-up implementations of Python libraries for i2c devices easier, simpler and inherently self-documenting.
It does this by separating a detailed description of the hardware registers and how they should be manipulated into a structured definition language.
This project does not aim to help you make a public API for Python devices- that should be built on top of the fundamentals presented here.
Using This Library
You should generally aim for a 1:1 representation of the hardware registers in the device you're implementing, even if you don't plan to use all the functionality. Having the full register set implemented allows for the easy addition of new features in future.
Check out the libraries listed below for real-world examples.
Features
- Classes for describing devices, registers and individual bit fields within registers in a fashion which maps closely with the datasheet
- Value translation from real world numbers (such as
512ms) to register values (such as0b111) and back again - Read registers into a namedtuple of fields using
get - Write multiple register fields in a transaction using
setwith keyword arguments - Support for treating multiple-bytes as a single value, or single register with multiple values
Built With i2cdevice
- bme280 - https://github.com/pimoroni/bme280-python
- bmp280 - https://github.com/pimoroni/bmp280-python
- bh1745 - https://github.com/pimoroni/bh1745-python
- as7262 - https://github.com/pimoroni/as7262-python
- lsm303d - https://github.com/pimoroni/lsm303d-python
- ltr559 - https://github.com/pimoroni/ltr559-python
- ads1015 - https://github.com/pimoroni/ads1015-python
Examples
The below example defines the ALS_CONTROL register on an ltr559, with register address 0x80.
It has 3 fields; gain - which is mapped to real world values - and sw_reset/mode which are single bit flags.
ALS_CONTROL = Register('ALS_CONTROL', 0x80, fields=(
BitField('gain', 0b00011100, values_map={1: 0b000, 2: 0b001, 4: 0b011, 8:0b011, 48:0b110, 96:0b111}),
BitField('sw_reset', 0b00000010),
BitField('mode', 0b00000001)
))
A lookup table is not required for values, however, a function can be used to translate values from and to a format that the device understands.
The below example uses i2cdevice._byte_swap to change the endianness of two 16bit values before they are stored/retrieved.
# This will address 0x88, 0x89, 0x8A and 0x8B as a continuous 32bit register
ALS_DATA = Register('ALS_DATA', 0x88, fields=(
BitField('ch1', 0xFFFF0000, bitwidth=16, values_in=_byte_swap, values_out=_byte_swap),
BitField('ch0', 0x0000FFFF, bitwidth=16, values_in=_byte_swap, values_out=_byte_swap)
), read_only=True, bitwidth=32)
A "Register" and its "BitField"s define a set of rules and logic for detailing with the hardware register which is interpreted by the device class. Registers are declared on a device using the registers=() keyword argument:
I2C_ADDR = 0x23
ltr559 = Device(I2C_ADDR, bit_width=8, registers=(
ALS_CONTROL,
ALS_DATA
))
Reading Registers
One configured a register's fields can be read into a namedtuple using the get method:
register_values = ltr559.get('ALS_CONTROL')
gain = register_values.gain
sw_reset = register_values.sw_reset
mode = register_values.mode
Writing Registers
The namedtuple returned from get is immutable and does not attempt to map values back to the hardware, in order to write one or more fields to a register you must use set with a keyword argument for each field:
ltr559.set('ALS_CONTROL',
gain=4,
sw_reset=1)
This will read the register state from the device, update the bitfields accordingly and write the result back.
1.0.0
- Enhancement: Repackage to pyproject.toml/hatchling
- Switch i2c_dev fallback from smbus to smbus2
0.0.7
- BugFix: Prevent .get from reading multiple times (thanks @dkao)
- Enhancement: Better error output (thanks Kamil Klimek)
0.0.6
- New API methods set and get
0.0.5
- Bump to stable release
0.0.4
- Bugfixes
0.0.3
- Added License
0.0.2
- Major Refactor
0.0.1
- Initial Release
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