Expose the Raspberry Pi GPIO pins, external IO modules, streams and I2C sensors to an MQTT server. This allows pins to be read and switched by reading or writing messages to MQTT topics. The streams and I2C sensors will be read periodically and publish their values.
- Raspberry Pi GPIO (
raspberrypi
) - Orange Pi GPIO (
orangepi
) - PCF8574 IO chip (
pcf8574
) - PiFaceDigital 2 IO board (
piface2
) - Beaglebone GPIO (
beaglebone
)
- LM75 i2c temperature sensor (
lm75
) - DHT11 DHT22 AM2302 temperature/humidity sensor (
dht22
) - BH1750 light level sensor (
bh1750
) - DS18S20, DS1822, DS18B20, DS1825, DS28EA00, MAX31850K one-wire temperature sensors: (
ds18b
) - HC-SR04 ultrasonic distance sensor (
hcsr04
)
- Serial port (
streamserial
)
pip install pi-mqtt-gpio
python -m pi_mqtt_gpio.server config.yml
Configuration is handled by a YAML file which is passed as an argument to the server on startup.
With the following example config, switch pin 21 on by publishing to the home/kitchen/output/lights/set
topic with a payload of ON
, and pin 22 by publishing to home/kitchen/output/fan/set
.
mqtt:
host: test.mosquitto.org
port: 1883
user: ""
password: ""
topic_prefix: home/kitchen
gpio_modules:
- name: raspberrypi
module: raspberrypi
digital_outputs:
- name: lights
module: raspberrypi
pin: 21
on_payload: "ON"
off_payload: "OFF"
initial: low # This optional value controls the initial state of the pin before receipt of any messages from MQTT. Valid options are 'low' and 'high'.
retain: yes # This option value controls if the message is retained. Default is no.
- name: fan
module: raspberrypi
pin: 22
inverted: yes # This pin may control an open-collector output which is "on" when the output is "low".
on_payload: "ON"
off_payload: "OFF"
Or to receive updates on the status of an input pin, subscribe to the home/input/doorbell
topic:
mqtt:
host: test.mosquitto.org
port: 1883
user: ""
password: ""
topic_prefix: home
gpio_modules:
- name: raspberrypi
module: raspberrypi
cleanup: no # This optional boolean value sets whether the module's `cleanup()` function will be called when the software exits.
digital_inputs:
- name: doorbell
module: raspberrypi
pin: 22
on_payload: "ON"
off_payload: "OFF"
pullup: yes
pulldown: no
Receive updates on the value of a sensor by subscribing to the home/sensor/<sensor input name>
topic. In the following example, this would be home/sensor/temperature
:
mqtt:
host: test.mosquitto.org
port: 1883
user: ""
password: ""
topic_prefix: home
sensor_modules:
- name: lm75
module: lm75
i2c_bus_num: 1
chip_addr: 0x48
cleanup: no # This optional boolean value sets whether the module's `cleanup()` function will be called when the software exits.
- name: dht22
module: dht22
type: AM2302 # can be DHT11, DHT22 or AM2302
pin: 4
- name: bh1750
module: bh1750
i2c_bus_num: 1
chip_addr: 0x23
- name: ds18b22
module: ds18b
type: DS18S20
address: 000803702e49
- name: hcsr04
module: hcsr04
pin_echo: 27
pin_trigger: 17
burst: 10 # number of measurements for output of distance value in [cm]
sensor_inputs:
- name: temperature
module: lm75
interval: 15 #interval in seconds, that a value is read from the sensor and a update is published
digits: 4 # number of digits to be round
- name: dht22_temperature
module: dht22
interval: 10 #interval in seconds, that a value is read from the sensor and a update is published
digits: 4 # number of digits to be round
type: temperature # Can be temperature or humidity
- name: dht22_humidity
module: dht22
interval: 10 #interval in seconds, that a value is read from the sensor and a update is published
digits: 4 # number of digits to be round
type: humidity # Can be temperature or humidity
- name: bh1750_lux
module: bh1750
interval: 10
digits: 2
- name: ds18b22
module: ds18b22
interval: 60
digits: 2
- name: distance
module: hcsr04
interval: 10 # measurement every 10s
digits: 1
Transmit data by publishing to the home/stream/<stream write name>
topic. In the following example, this would be home/stream/serialtx
.
Receive data from a stream by subscribing to the home/stream/<stream read name>
topic. In the following example, this would be home/stream/serialrx
.
The stream data is parsed using Python's string_escape
to allow the transfer of control characters.
mqtt:
host: test.mosquitto.org
port: 1883
user: ""
password: ""
topic_prefix: home
stream_modules:
- name: serialcomms
module: streamserial
device: /dev/ttyS0
baud: 115200
bytesize: 8 # Number of data bits in word. Can be: 5,6,7,8
parity: none # Parity can be one of none,odd,even,mark,space
stopbits: 1 # Number of stop bits. Can be: 1,1.5,2
cleanup: no # This optional boolean value sets whether the module's `cleanup()` function will be called when the software exits.
stream_reads:
- name: serialrx
module: serialcomms
interval: 0.25 # Stream read polling interval in seconds
stream_writes:
- name: serialtx
module: serialcomms
Testing example:
# -N disables printing extra new line on each subscription
mosquitto_sub -h <broker url> -t <topic prefix>/stream/serialrx -N
mosquitto_pub -h <broker url> -t <topic prefix>/stream/serialtx -m "testing123\r\n"
You need to specify what OrangePi board you use
gpio_modules:
- name: orangepi
module: orangepi
board: zero # Supported: ZERO, R1, ZEROPLUS, ZEROPLUS2H5, ZEROPLUS2H3, PCPCPLUS, ONE, LITE, PLUS2E, PC2, PRIME
mode: board
You may want to connect to a remote server, in which case it's a good idea to use an encrypted connection. If the server supports this, then you can supply the relevant config values for the tls_set() command.
mqtt:
host: test.mosquitto.org
port: 8883
tls:
enabled: yes
You may need to supply a trusted CA certificate, as instructed on https://test.mosquitto.org/.
mqtt:
host: test.mosquitto.org
port: 8883
tls:
enabled: yes
ca_certs: mosquitto.org.crt
Or you might want to use SSL/TLS but not verify the server's certificate (not recommended).
mqtt:
host: test.mosquitto.org
port: 8883
tls:
enabled: yes
cert_reqs: CERT_NONE
insecure: yes
You may want to set the output to a given value for a certain amount of time. This can be done using the /set_on_ms
and /set_off_ms
topics. If an output is already set to that value, it will stay that value for the given amount of milliseconds and then switch to the opposite.
For example, to set an output named light
on for one second, publish 1000
as the payload to the myprefix/output/light/set_on_ms
topic.
If you want to force an output to always set to on/off for a configured amount of time, you can add timed_set_ms
to your output config. This will mean that if you send "ON" to myprefix/output/light/set
, then it will turn the light on for however many milliseconds are configured in timed_set_ms
and then turn it off again. Whether the light is on already or not, sending "ON" will make the light eventually turn off after timed_set_ms
milliseconds. This also works inversely with sending "OFF", which will turn the light off, then on after timed_set_ms
milliseconds, so don't expect this to always keep your devices set to on/off.
Interrupts may be used for inputs instead of polling for raspberry modules. Specify interrupt
and a strategy rising
, falling
or both
to switch from polling to interrupt mode. The bouncetime
is default 100ms
but may be changed (at least 1ms). The interrupt trigger will send a configurable interrupt_payload
(default: "INT"
) and not the current value of the pin: reading the current pin value in the ISR, returned 'old' values. Reading again in the ISR after 100ms gave 'changed' value, but waiting in ISR is not a good solution. So only a trigger message is transmitted on each ISR trigger.
digital_inputs:
- name: button_left
module: raspberrypi
pin: 23
interrupt_payload: "trigger"
pullup: no
pulldown: yes
interrupt: falling
bouncetime: 200
The IO modules are pluggable and multiple may be used at once. For example, if you have a Raspberry PI with some GPIO pins in use and also a PCF8574 IO expander on the I2C bus, you'd list two modules in the gpio_modules
section and set up the inputs and outputs accordingly:
mqtt:
host: test.mosquitto.org
port: 1883
user: ""
password: ""
topic_prefix: pimqttgpio/mydevice
gpio_modules:
- name: raspberrypi
module: raspberrypi
- name: pcf8574
module: pcf8574
i2c_bus_num: 1
chip_addr: 0x20
- name: orangepi
module: orangepi
board: r1
mode: board
digital_inputs:
- name: button
module: raspberrypi
pin: 21 # This device is connected to pin 21 of the Raspberry PI GPIO
on_payload: "ON"
off_payload: "OFF"
pullup: no
pulldown: yes
digital_outputs:
- name: bell
module: pcf8574
pin: 2 # This device is connected to pin 2 of the PCF8574 IO expander
on_payload: "ON"
off_payload: "OFF"
MQTT supports a "last will and testament" (LWT) feature which means the server will publish to a configured topic with a message of your choosing if it loses connection to the client unexpectedly. Using this feature, this project can be configured to publish to a status topic as depicted in the following example config:
mqtt:
...
status_topic: status
status_payload_running: running
status_payload_stopped: stopped
status_payload_dead: dead
These are in fact the default values should the configuration not be provided, but they can be changed to whatever is desired. The status_topic
will be appended to the configured topic_prefix
, if any. For example, with the following config:
mqtt:
...
topic_prefix: home/office
status_topic: status
the status messages will appear on topic home/office/status
.
The MQTT client ID identifies your instance of pi-mqtt-gpio with your MQTT broker. It allows the broker to keep track of the state of your instance so that it can resume when it reconnects. This means that the ID must be unique for each instance that connects to the MQTT broker.
Since the MQTT client ID for each instance of pi-mqtt-gpio is based on the topic_prefix
supplied in config (#24), having multiple instances share the same topic_prefix
will require you to set a different client_id
for each:
mqtt:
host: test.mosquitto.org
client_id: pi-mqtt-gpio-device1
topic_prefix: home/office
mqtt:
host: test.mosquitto.org
client_id: pi-mqtt-gpio-device2
topic_prefix: home/office
Logging may be configured by including a logging
section in your config.yml
. The standard Python logging system is used, so configuration questions should be answered by looking at the Python logging howto.
The default config is set as follows. If you wish to change this, copy and paste this section into your config.yml
and change whichever parts you'd like.
logging:
version: 1
formatters:
simple:
format: "%(asctime)s %(name)s (%(levelname)s): %(message)s"
handlers:
console:
class: logging.StreamHandler
level: DEBUG
formatter: simple
stream: ext://sys.stdout
loggers:
mqtt_gpio:
level: INFO
handlers: [console]
propagate: yes
This project is not tied to any specific deployment method, but one recommended way is to use virtualenv
and supervisor
. This will launch the project at boot time and handle restarting and log file rotation. It's quite simple to set up:
If using Raspbian, install supervisor
with apt
.
sudo apt-get update
sudo apt-get install supervisor
Not strictly necessary, but it's recommended to install the project into a virtualenv. Generally, the best way to get an up-to-date version of virtualenv
is to use pip install --upgrade virtualenv
. If you don't already have pip
, then check here for installation instructions.
cd /home/pi
virtualenv ve
. ve/bin/activate
pip install pi-mqtt-gpio
Create yourself a config file, following instructions and examples above, and save it somewhere, such as /home/pi/pi-mqtt-gpio.yml
.
Create a supervisor config file in /etc/supervisor/conf.d/pi-mqtt-gpio.conf something along the lines of the following:
[program:pi_mqtt_gpio]
command = /home/pi/ve/bin/python -m pi_mqtt_gpio.server pi-mqtt-gpio.yml
directory = /home/pi
redirect_stderr = true
stdout_logfile = /var/log/pi-mqtt-gpio.log
Save the file and then run the following to update supervisor and start the program running.
sudo supervisorctl update
Check the status of your new supervisor job:
sudo supervisorctl status
Check the supervisor docs for more supervisorctl
commands.
Two images have been created for Docker. One using the x86_64 architecture (for Intel and AMD CPUs) and one for the ARM architecture (for Raspberry Pi etc.). The tags of the images are therefore flyte/mqtt-gpio:x86_64
and flyte/mqtt-gpio:armv7l
. These are the outputs of uname -m
on the two platforms they've been built on. For the following examples I'll assume you're running on Raspberry Pi.
You may also run this software using Docker. You must create your config file as above, then run the docker image:
docker run -ti --rm -v /path/to/your/config.yml:/config.yml flyte/mqtt-gpio:armv7l
Or to run in the background:
docker run -d --name mqtt-gpio -v /path/to/your/config.yml:/config.yml flyte/mqtt-gpio:armv7l
You'll most likely want to use some hardware devices in your config, since that's what this project is all about. For example, if you wish to use the i2c bus, pass it through with a --device
parameter:
docker run -ti --rm -v /path/to/your/config.yml:/config.yml --device /dev/i2c-0 flyte/mqtt-gpio:armv7l
If you aren't able to find the exact device path to use, then you can also run the docker container in --privileged
mode which will pass all of the devices through from the host:
docker run -ti --rm -v /path/to/your/config.yml:/config.yml --privileged flyte/mqtt-gpio:armv7l
Please raise an issue on Github if you find that any of this information is incorrect.