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moved a bunch of garbage (things that have nothing to do in root) to _trash

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mia 2025-06-15 22:42:02 +02:00
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lib/python3.11/site-packages/busio.py
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# SPDX-FileCopyrightText: 2021 Melissa LeBlanc-Williams for Adafruit Industries
#
# SPDX-License-Identifier: MIT
"""
`busio` - Bus protocol support like I2C and SPI
=================================================
See `CircuitPython:busio` in CircuitPython for more details.
* Author(s): cefn
"""
try:
import threading
except ImportError:
threading = None
# pylint: disable=unused-import
import adafruit_platformdetect.constants.boards as ap_board
import adafruit_platformdetect.constants.chips as ap_chip
from adafruit_blinka import Enum, Lockable, agnostic
from adafruit_blinka.agnostic import board_id, detector
# pylint: disable=import-outside-toplevel,too-many-branches,too-many-statements
# pylint: disable=too-many-arguments,too-many-function-args,too-many-return-statements
class I2C(Lockable):
"""
Busio I2C Class for CircuitPython Compatibility. Used
for both MicroPython and Linux.
NOTE: Frequency has no effect on Linux systems. The argument is only there for compatibility.
"""
def __init__(self, scl, sda, frequency=100000):
self.init(scl, sda, frequency)
def init(self, scl, sda, frequency):
"""Initialization"""
self.deinit()
if detector.board.ftdi_ft232h:
from adafruit_blinka.microcontroller.ftdi_mpsse.mpsse.i2c import I2C as _I2C
self._i2c = _I2C(frequency=frequency)
return
if detector.board.binho_nova:
from adafruit_blinka.microcontroller.nova.i2c import I2C as _I2C
self._i2c = _I2C(frequency=frequency)
return
if detector.board.microchip_mcp2221:
from adafruit_blinka.microcontroller.mcp2221.i2c import I2C as _I2C
self._i2c = _I2C(frequency=frequency)
return
if detector.board.OS_AGNOSTIC_BOARD:
from adafruit_blinka.microcontroller.generic_agnostic_board.i2c import (
I2C as _I2C,
)
self._i2c = _I2C(frequency=frequency)
return
if detector.board.greatfet_one:
from adafruit_blinka.microcontroller.nxp_lpc4330.i2c import I2C as _I2C
self._i2c = _I2C(frequency=frequency)
return
if detector.board.pico_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.i2c import I2C_Pico as _I2C
self._i2c = _I2C(scl, sda, frequency=frequency)
return
if detector.board.feather_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.i2c import (
I2C_Feather as _I2C,
)
self._i2c = _I2C(scl, sda, frequency=frequency)
return
if detector.board.feather_can_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.i2c import (
I2C_Feather_CAN as _I2C,
)
self._i2c = _I2C(scl, sda, frequency=frequency)
return
if detector.board.feather_epd_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.i2c import (
I2C_Feather_EPD as _I2C,
)
self._i2c = _I2C(scl, sda, frequency=frequency)
return
if detector.board.feather_rfm_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.i2c import (
I2C_Feather_RFM as _I2C,
)
self._i2c = _I2C(scl, sda, frequency=frequency)
return
if detector.board.qtpy_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.i2c import I2C_QTPY as _I2C
self._i2c = _I2C(scl, sda, frequency=frequency)
return
if detector.board.itsybitsy_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.i2c import (
I2C_ItsyBitsy as _I2C,
)
self._i2c = _I2C(scl, sda, frequency=frequency)
return
if detector.board.macropad_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.i2c import (
I2C_MacroPad as _I2C,
)
self._i2c = _I2C(scl, sda, frequency=frequency)
return
if detector.board.qt2040_trinkey_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.i2c import (
I2C_QT2040_Trinkey as _I2C,
)
self._i2c = _I2C(scl, sda, frequency=frequency)
return
if detector.board.kb2040_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.i2c import (
I2C_KB2040 as _I2C,
)
self._i2c = _I2C(scl, sda, frequency=frequency)
return
if detector.chip.id == ap_chip.RP2040:
from adafruit_blinka.microcontroller.rp2040.i2c import I2C as _I2C
self._i2c = _I2C(scl, sda, frequency=frequency)
return
if detector.board.any_siemens_iot2000:
from adafruit_blinka.microcontroller.am65xx.i2c import I2C as _I2C
self._i2c = _I2C(frequency=frequency)
return
if detector.board.any_embedded_linux:
from adafruit_blinka.microcontroller.generic_linux.i2c import I2C as _I2C
if frequency == 100000:
frequency = None # Set to None if default to avoid triggering warning
elif detector.board.ftdi_ft2232h:
from adafruit_blinka.microcontroller.ftdi_mpsse.mpsse.i2c import I2C as _I2C
elif detector.board.ftdi_ft4232h:
from adafruit_blinka.microcontroller.ftdi_mpsse.mpsse.i2c import I2C as _I2C
else:
from adafruit_blinka.microcontroller.generic_micropython.i2c import (
I2C as _I2C,
)
from microcontroller.pin import i2cPorts
for portId, portScl, portSda in i2cPorts:
try:
# pylint: disable=unexpected-keyword-arg
if scl == portScl and sda == portSda:
self._i2c = _I2C(portId, mode=_I2C.MASTER, baudrate=frequency)
break
# pylint: enable=unexpected-keyword-arg
except RuntimeError:
pass
else:
raise ValueError(
"No Hardware I2C on (scl,sda)={}\nValid I2C ports: {}".format(
(scl, sda), i2cPorts
)
)
if threading is not None:
self._lock = threading.RLock()
def deinit(self):
"""Deinitialization"""
try:
del self._i2c
except AttributeError:
pass
def __enter__(self):
if threading is not None:
self._lock.acquire()
return self
def __exit__(self, exc_type, exc_value, traceback):
if threading is not None:
self._lock.release()
self.deinit()
def scan(self):
"""Scan for attached devices"""
return self._i2c.scan()
def readfrom_into(self, address, buffer, *, start=0, end=None):
"""Read from a device at specified address into a buffer"""
if start != 0 or end is not None:
if end is None:
end = len(buffer)
buffer = memoryview(buffer)[start:end]
return self._i2c.readfrom_into(address, buffer, stop=True)
def writeto(self, address, buffer, *, start=0, end=None):
"""Write to a device at specified address from a buffer"""
if isinstance(buffer, str):
buffer = bytes([ord(x) for x in buffer])
if start != 0 or end is not None:
if end is None:
return self._i2c.writeto(address, memoryview(buffer)[start:], stop=True)
return self._i2c.writeto(address, memoryview(buffer)[start:end], stop=True)
return self._i2c.writeto(address, buffer, stop=True)
def writeto_then_readfrom(
self,
address,
buffer_out,
buffer_in,
*,
out_start=0,
out_end=None,
in_start=0,
in_end=None,
stop=False,
):
""" "Write to a device at specified address from a buffer then read
from a device at specified address into a buffer
"""
return self._i2c.writeto_then_readfrom(
address,
buffer_out,
buffer_in,
out_start=out_start,
out_end=out_end,
in_start=in_start,
in_end=in_end,
stop=stop,
)
class SPI(Lockable):
"""
Busio SPI Class for CircuitPython Compatibility. Used
for both MicroPython and Linux.
"""
def __init__(self, clock, MOSI=None, MISO=None):
self.deinit()
if detector.board.ftdi_ft232h:
from adafruit_blinka.microcontroller.ftdi_mpsse.mpsse.spi import SPI as _SPI
from adafruit_blinka.microcontroller.ftdi_mpsse.ft232h.pin import (
SCK,
MOSI,
MISO,
)
self._spi = _SPI()
self._pins = (SCK, MOSI, MISO)
return
if detector.board.binho_nova:
from adafruit_blinka.microcontroller.nova.spi import SPI as _SPI
from adafruit_blinka.microcontroller.nova.pin import SCK, MOSI, MISO
self._spi = _SPI(clock)
self._pins = (SCK, MOSI, MISO)
return
if detector.board.greatfet_one:
from adafruit_blinka.microcontroller.nxp_lpc4330.spi import SPI as _SPI
from adafruit_blinka.microcontroller.nxp_lpc4330.pin import SCK, MOSI, MISO
self._spi = _SPI()
self._pins = (SCK, MOSI, MISO)
return
if detector.board.pico_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import SPI_Pico as _SPI
self._spi = _SPI(clock) # this is really all that's needed
self._pins = (clock, clock, clock) # will determine MOSI/MISO from clock
return
if detector.board.feather_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import (
SPI_Feather as _SPI,
)
self._spi = _SPI(clock) # this is really all that's needed
self._pins = (clock, clock, clock) # will determine MOSI/MISO from clock
return
if detector.board.feather_can_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import (
SPI_Feather_CAN as _SPI,
)
self._spi = _SPI(clock) # this is really all that's needed
self._pins = (clock, clock, clock) # will determine MOSI/MISO from clock
return
if detector.board.feather_epd_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import (
SPI_Feather_EPD as _SPI,
)
self._spi = _SPI(clock) # this is really all that's needed
self._pins = (clock, clock, clock) # will determine MOSI/MISO from clock
return
if detector.board.feather_rfm_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import (
SPI_Feather_RFM as _SPI,
)
self._spi = _SPI(clock) # this is really all that's needed
self._pins = (clock, clock, clock) # will determine MOSI/MISO from clock
return
if detector.board.itsybitsy_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import (
SPI_ItsyBitsy as _SPI,
)
self._spi = _SPI(clock) # this is really all that's needed
self._pins = (clock, clock, clock) # will determine MOSI/MISO from clock
return
if detector.board.macropad_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import (
SPI_MacroPad as _SPI,
)
self._spi = _SPI(clock) # this is really all that's needed
self._pins = (clock, clock, clock) # will determine MOSI/MISO from clock
return
if detector.board.qtpy_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import SPI_QTPY as _SPI
self._spi = _SPI(clock) # this is really all that's needed
self._pins = (clock, clock, clock) # will determine MOSI/MISO from clock
return
if detector.board.kb2040_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import (
SPI_KB2040 as _SPI,
)
self._spi = _SPI(clock) # this is really all that's needed
self._pins = (clock, clock, clock) # will determine MOSI/MISO from clock
return
if detector.chip.id == ap_chip.RP2040:
from adafruit_blinka.microcontroller.rp2040.spi import SPI as _SPI
self._spi = _SPI(clock, MOSI, MISO) # Pins configured on instantiation
self._pins = (clock, clock, clock) # These don't matter, they're discarded
return
if detector.board.any_siemens_iot2000:
from adafruit_blinka.microcontroller.am65xx.spi import SPI as _SPI
self._spi = _SPI(clock) # this is really all that's needed
self._pins = (clock, clock, clock) # will determine MOSI/MISO from clock
return
if detector.board.any_embedded_linux:
from adafruit_blinka.microcontroller.generic_linux.spi import SPI as _SPI
elif detector.board.ftdi_ft2232h:
from adafruit_blinka.microcontroller.ftdi_mpsse.mpsse.spi import SPI as _SPI
elif detector.board.ftdi_ft4232h:
from adafruit_blinka.microcontroller.ftdi_mpsse.mpsse.spi import SPI as _SPI
elif detector.board.OS_AGNOSTIC_BOARD:
from adafruit_blinka.microcontroller.generic_agnostic_board.spi import (
SPI as _SPI,
)
else:
from adafruit_blinka.microcontroller.generic_micropython.spi import (
SPI as _SPI,
)
from microcontroller.pin import spiPorts
for portId, portSck, portMosi, portMiso in spiPorts:
if (
(clock == portSck)
and MOSI in (portMosi, None) # Clock is required!
and MISO in (portMiso, None) # But can do with just output
): # Or just input
self._spi = _SPI(portId)
self._pins = (portSck, portMosi, portMiso)
break
else:
raise ValueError(
"No Hardware SPI on (SCLK, MOSI, MISO)={}\nValid SPI ports:{}".format(
(clock, MOSI, MISO), spiPorts
)
)
def configure(self, baudrate=100000, polarity=0, phase=0, bits=8):
"""Update the configuration"""
if detector.board.any_nanopi and detector.chip.id == ap_chip.SUN8I:
from adafruit_blinka.microcontroller.generic_linux.spi import SPI as _SPI
elif detector.board.ftdi_ft232h:
from adafruit_blinka.microcontroller.ftdi_mpsse.mpsse.spi import (
SPI as _SPI,
)
elif detector.board.ftdi_ft2232h:
from adafruit_blinka.microcontroller.ftdi_mpsse.mpsse.spi import (
SPI as _SPI,
)
elif detector.board.ftdi_ft4232h:
from adafruit_blinka.microcontroller.ftdi_mpsse.mpsse.spi import (
SPI as _SPI,
)
elif detector.board.binho_nova:
from adafruit_blinka.microcontroller.nova.spi import SPI as _SPI
elif detector.board.greatfet_one:
from adafruit_blinka.microcontroller.nxp_lpc4330.spi import SPI as _SPI
elif detector.board.any_lubancat and detector.chip.id == ap_chip.IMX6ULL:
from adafruit_blinka.microcontroller.generic_linux.spi import SPI as _SPI
elif detector.board.pico_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import SPI_Pico as _SPI
elif detector.board.feather_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import (
SPI_Feather as _SPI,
)
elif detector.board.feather_can_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import (
SPI_Feather_CAN as _SPI,
)
elif detector.board.feather_epd_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import (
SPI_Feather_EPD as _SPI,
)
elif detector.board.feather_rfm_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import (
SPI_Feather_RFM as _SPI,
)
elif detector.board.itsybitsy_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import (
SPI_ItsyBitsy as _SPI,
)
elif detector.board.macropad_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import (
SPI_MacroPad as _SPI,
)
elif detector.board.kb2040_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import (
SPI_KB2040 as _SPI,
)
elif detector.board.qtpy_u2if:
from adafruit_blinka.microcontroller.rp2040_u2if.spi import SPI_QTPY as _SPI
elif detector.chip.id == ap_chip.RP2040:
from adafruit_blinka.microcontroller.rp2040.spi import SPI as _SPI
elif detector.board.any_siemens_iot2000:
from adafruit_blinka.microcontroller.am65xx.spi import SPI as _SPI
from adafruit_blinka.microcontroller.am65xx.pin import Pin
elif detector.board.any_embedded_linux:
from adafruit_blinka.microcontroller.generic_linux.spi import SPI as _SPI
elif detector.board.OS_AGNOSTIC_BOARD:
from adafruit_blinka.microcontroller.generic_agnostic_board.spi import (
SPI as _SPI,
)
else:
from adafruit_blinka.microcontroller.generic_micropython.spi import (
SPI as _SPI,
)
if self._locked:
# TODO check if #init ignores MOSI=None rather than unsetting, to save _pinIds attribute
self._spi.init(
baudrate=baudrate,
polarity=polarity,
phase=phase,
bits=bits,
firstbit=_SPI.MSB,
)
else:
raise RuntimeError("First call try_lock()")
def deinit(self):
"""Deinitialization"""
self._spi = None
self._pinIds = None
@property
def frequency(self):
"""Return the baud rate if implemented"""
try:
return self._spi.frequency
except AttributeError as error:
raise NotImplementedError(
"Frequency attribute not implemented for this platform"
) from error
def write(self, buf, start=0, end=None):
"""Write to the SPI device"""
return self._spi.write(buf, start, end)
def readinto(self, buf, start=0, end=None, write_value=0):
"""Read from the SPI device into a buffer"""
return self._spi.readinto(buf, start, end, write_value=write_value)
def write_readinto(
self, buffer_out, buffer_in, out_start=0, out_end=None, in_start=0, in_end=None
):
"""Write to the SPI device and read from the SPI device into a buffer"""
return self._spi.write_readinto(
buffer_out, buffer_in, out_start, out_end, in_start, in_end
)
class UART(Lockable):
"""
Busio UART Class for CircuitPython Compatibility. Used
for MicroPython and a few other non-Linux boards.
"""
class Parity(Enum):
"""Parity Enumeration"""
pass # pylint: disable=unnecessary-pass
Parity.ODD = Parity()
Parity.EVEN = Parity()
def __init__(
self,
tx,
rx,
baudrate=9600,
bits=8,
parity=None,
stop=1,
timeout=1000,
receiver_buffer_size=64,
flow=None,
):
if detector.board.any_embedded_linux:
raise RuntimeError(
"busio.UART not supported on this platform. Please use pyserial instead."
)
if detector.board.binho_nova:
from adafruit_blinka.microcontroller.nova.uart import UART as _UART
elif detector.board.greatfet_one:
from adafruit_blinka.microcontroller.nxp_lpc4330.uart import UART as _UART
elif detector.chip.id == ap_chip.RP2040:
from adafruit_blinka.microcontroller.rp2040.uart import UART as _UART
else:
from machine import UART as _UART
from microcontroller.pin import uartPorts
self.baudrate = baudrate
if flow is not None: # default 0
raise NotImplementedError(
"Parameter '{}' unsupported on {}".format("flow", agnostic.board_id)
)
# translate parity flag for Micropython
if parity is UART.Parity.ODD:
parity = 1
elif parity is UART.Parity.EVEN:
parity = 0
elif parity is None:
pass
else:
raise ValueError("Invalid parity")
if detector.chip.id == ap_chip.RP2040:
self._uart = _UART(
tx,
rx,
baudrate=baudrate,
bits=bits,
parity=parity,
stop=stop,
)
else:
# check tx and rx have hardware support
for portId, portTx, portRx in uartPorts: #
if portTx == tx and portRx == rx:
self._uart = _UART(
portId,
baudrate,
bits=bits,
parity=parity,
stop=stop,
timeout=timeout,
read_buf_len=receiver_buffer_size,
)
break
else:
raise ValueError(
"No Hardware UART on (tx,rx)={}\nValid UART ports: {}".format(
(tx, rx), uartPorts
)
)
def deinit(self):
"""Deinitialization"""
if detector.board.binho_nova:
self._uart.deinit()
self._uart = None
def read(self, nbytes=None):
"""Read from the UART"""
return self._uart.read(nbytes)
def readinto(self, buf, nbytes=None):
"""Read from the UART into a buffer"""
return self._uart.readinto(buf, nbytes)
def readline(self):
"""Read a line of characters up to a newline character from the UART"""
return self._uart.readline()
def write(self, buf):
"""Write to the UART from a buffer"""
return self._uart.write(buf)