Zephyr 端口快速参考

Below is a quick reference for the Zephyr port. If it is your first time working with this port please consider reading the following sections first:

运行 MicroPython

See the corresponding section of the tutorial: 在 ESP8266 上快速入门 MicroPython .

延迟和计时

使用 time 模块:

import time
time.sleep(1)               # sleep for 1 second
time.sleep_ms(500)          # sleep for 500 milliseconds
time.sleep_us(10)           # sleep for 10 microseconds
start = time.ticks_ms()     # get millisecond counter
delta = time.ticks_diff(time.ticks_ms(), start) # compute time difference
											

引脚和 GPIO

使用 machine.Pin 类:

from machine import Pin
pin = Pin(("GPIO_1", 21), Pin.IN)   # create input pin on GPIO1
print(pin)                          # print pin port and number
pin.init(Pin.OUT, Pin.PULL_UP, value=1)     # reinitialize pin
pin.value(1)                        # set pin to high
pin.value(0)                        # set pin to low
pin.on()                            # set pin to high
pin.off()                           # set pin to low
pin = Pin(("GPIO_1", 21), Pin.IN)   # create input pin on GPIO1
pin = Pin(("GPIO_1", 21), Pin.OUT, value=1)         # set pin high on creation
pin = Pin(("GPIO_1", 21), Pin.IN, Pin.PULL_UP)      # enable internal pull-up resistor
switch = Pin(("GPIO_2", 6), Pin.IN)                 # create input pin for a switch
switch.irq(lambda t: print("SW2 changed"))          # enable an interrupt when switch state is changed
											

硬件 I2C 总线

Hardware I2C is accessed via the machine.I2C 类:

from machine import I2C
i2c = I2C("I2C_0")          # construct an i2c bus
print(i2c)                  # print device name
i2c.scan()                  # scan the device for available I2C slaves
i2c.readfrom(0x1D, 4)                # read 4 bytes from slave 0x1D
i2c.readfrom_mem(0x1D, 0x0D, 1)      # read 1 byte from slave 0x1D at slave memory 0x0D
i2c.writeto(0x1D, b'abcd')           # write to slave with address 0x1D
i2c.writeto_mem(0x1D, 0x0D, b'ab')   # write to slave 0x1D at slave memory 0x0D
buf = bytearray(8)                  # create buffer of size 8
i2c.writeto(0x1D, b'abcd')          # write buf to slave 0x1D
											

硬件 SPI 总线

Hardware SPI is accessed via the machine.SPI 类:

from machine import SPI
spi = SPI("SPI_0")          # construct a spi bus with default configuration
spi.init(baudrate=100000, polarity=0, phase=0, bits=8, firstbit=SPI.MSB) # set configuration
# equivalently, construct spi bus and set configuration at the same time
spi = SPI("SPI_0", baudrate=100000, polarity=0, phase=0, bits=8, firstbit=SPI.MSB)
print(spi)                  # print device name and bus configuration
spi.read(4)                 # read 4 bytes on MISO
spi.read(4, write=0xF)      # read 4 bytes while writing 0xF on MOSI
buf = bytearray(8)          # create a buffer of size 8
spi.readinto(buf)           # read into the buffer (reads number of bytes equal to the buffer size)
spi.readinto(buf, 0xF)      # read into the buffer while writing 0xF on MOSI
spi.write(b'abcd')          # write 4 bytes on MOSI
buf = bytearray(4)                  # create buffer of size 8
spi.write_readinto(b'abcd', buf)    # write to MOSI and read from MISO into the buffer
spi.write_readinto(buf, buf)        # write buf to MOSI and read back into the buf
											

磁盘访问

使用 zephyr.DiskAccess class to support filesystem:

import os
from zephyr import DiskAccess
block_dev = DiskAccess('SDHC')      # create a block device object for an SD card
os.VfsFat.mkfs(block_dev)           # create FAT filesystem object using the disk storage block
os.mount(block_dev, '/sd')          # mount the filesystem at the SD card subdirectory
# with the filesystem mounted, files can be manipulated as normal
with open('/sd/hello.txt','w') as f:     # open a new file in the directory
    f.write('Hello world')                  # write to the file
print(open('/sd/hello.txt').read())      # print contents of the file
											

闪存区域

使用 zephyr.FlashArea class to support filesystem:

import os
from zephyr import FlashArea
block_dev = FlashArea(4, 4096)      # creates a block device object in the frdm-k64f flash scratch partition
os.VfsLfs2.mkfs(block_dev)          # create filesystem in lfs2 format using the flash block device
os.mount(block_dev, '/flash')       # mount the filesystem at the flash subdirectory
# with the filesystem mounted, files can be manipulated as normal
with open('/flash/hello.txt','w') as f:     # open a new file in the directory
    f.write('Hello world')                  # write to the file
print(open('/flash/hello.txt').read())      # print contents of the file
											

传感器

使用 zsensor.Sensor class to access sensor data:

import zsensor
from zsensor import Sensor
accel = Sensor("FXOX8700")    # create sensor object for the accelerometer
accel.measure()               # obtain a measurement reading from the accelerometer
# each of these prints the value taken by measure()
accel.float(zsensor.ACCEL_X)  # print measurement value for accelerometer X-axis sensor channel as float
accel.millis(zsensor.ACCEL_Y) # print measurement value for accelerometer Y-axis sensor channel in millionths
accel.micro(zsensor.ACCEL_Z)  # print measurement value for accelerometer Z-axis sensor channel in thousandths
accel.int(zsensor.ACCEL_X)    # print measurement integer value only for accelerometer X-axis sensor channel