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377 lines
14 KiB
ReStructuredText
377 lines
14 KiB
ReStructuredText
Custom Sensor Component
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=======================
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.. warning::
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While I do try to keep the esphomeyaml configuration options as stable as possible
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and back-port them, the esphomelib API is less stable. If something in the APIs needs
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to be changed in order for something else to work, I will do so.
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So, you just set up esphomelib for your ESP32/ESP8266, but sadly esphomelib is missing a sensor integration
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you'd really like to have 😕. It's pretty much impossible to support every single sensor, as there are simply too many.
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That's why esphomelib has a really simple API for you to create your own **custom sensors** 🎉
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In this guide, we will go through creating a custom sensor component for the
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`BMP180 <https://www.adafruit.com/product/1603>`__ pressure sensor (we will only do the pressure part,
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temperature is more or less the same). During this guide, you will learn how to 1. define a custom sensor
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esphomelib can use 2. go over how to register the sensor so that it will be shown inside Home Assistant and
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3. leverage an existing arduino library for the BMP180 with esphomelib.
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.. note::
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Since the creation of this guide, the BMP180 has been officially supported by the :doc:`BMP085 component
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<bmp085>`. The code still applies though.
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This guide will require at least a bit of knowledge of C++, so be prepared for that. If you have any problems,
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I'm here to help :) https://discord.gg/KhAMKrd
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Step 1: Custom Sensor Definition
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--------------------------------
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At this point, you might have a main source file like this:
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.. code:: cpp
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// ...
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using namespace esphomelib;
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void setup() {
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// ===== DO NOT EDIT ANYTHING BELOW THIS LINE =====
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// ========== AUTO GENERATED CODE BEGIN ===========
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App.set_name("livingroom");
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App.init_log();
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// ...
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// =========== AUTO GENERATED CODE END ============
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// ========= YOU CAN EDIT AFTER THIS LINE =========
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App.setup();
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}
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void loop() {
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App.loop();
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}
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To create your own custom sensor, you just have define a C++ class that extends ``Component`` and ``Sensor`` like this:
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.. code:: cpp
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using namespace esphomelib;
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class CustomSensor : public Component, public sensor::Sensor {
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public:
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CustomSensor(const std::string &name) : Sensor(name) {}
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void setup() override {
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// This will be called by App.setup()
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}
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void loop() override {
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// This will be called by App.loop()
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}
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};
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void setup() {
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// ...
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Additionally, you need to change an internal flag that changes how esphomeyaml compiles files.
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The only downside is that this will make build times *a tiny bit* slower:
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.. code:: yaml
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esphomeyaml:
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# ...
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use_custom_code: True
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You've just created your first esphomelib sensor 🎉. It doesn't do very much right now and is never registered,
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but it's a first step.
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Let's now take a look at how a sensor works in esphomelib: A sensor is some hardware device (like a BMP180)
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that sends out new values like temperatures.
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Like any Component in esphomelib, if it's registered in the Application, ``setup()`` will be called for you when
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``App.setup()`` is run. ``setup()`` is also the place where you should do hardware initialization like setting
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``pinMode()``. Next, every time ``App.loop()`` is called, your component will also receive a ``loop()`` call.
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This is the place where you should do stuff like querying a sensor for a new value like you might be used
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to do in an Arduino sketch.
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Let's now also take a closer look at this line, which you might not be too used to when writing pure C code:
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.. code:: cpp
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class CustomSensor : public Component, public sensor::Sensor {
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What this line is essentially saying is that we're defining our own class that's called ``CustomSensor``
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which is also a subclass of ``Component`` and ``Sensor`` (in the namespace ``sensor::``).
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``Component`` is there so that we can register it in our application and so that we will receive ``setup()``
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and ``loop()`` calls. We're also inheriting from the ``Sensor`` class so that our custom sensor can send sensor
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values to the frontend (like MQTT).
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As most sensors really just setup some pins and then check the sensor every x seconds,
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there's another abstraction that we'll use to simplify our code: ``PollingSensorComponent``.
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.. code:: cpp
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class CustomSensor : public sensor::PollingSensorComponent {
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public:
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CustomSensor(const std::string &name, uint32_t update_interval)
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: sensor::PollingSensorComponent(name, update_interval) {}
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void setup() override {
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// This will be called by App.setup()
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}
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void update() override {
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// This will be called every `update_interval` milliseconds.
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}
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};
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What ``PollingSensorComponent`` (and ``PollingComponent``) does is essentially
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just replace the ``loop()`` method and will call ``update()`` instead every ``update_interval`` milliseconds.
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Because with most sensors, you really don't need to get the latest values with every single ``loop()``
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call (which can be called many times per second). If we forward the ``update_interval`` in our *constructor*
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(line 3), ``PollingSensorComponent`` will call ``update()`` for us every ``update_interval``
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milliseconds, so that we don't have to do time checking ourselves.
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You don't really need to know about C++ constructors for now, but I would definitely recommend reading up on them
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in the Internet.
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Let's also now make our sensor actually *output* values (42 for now):
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.. code:: cpp
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// class CustomSensor ...
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// ... previous code
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void update() override {
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publish_state(42.0); // 42°C
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}
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std::string unit_of_measurement() override { return "°C"; }
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int8_t accuracy_decimals() override { return 2; } // 2 decimal places of accuracy.
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};
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Every time ``update`` is called we will now **push** a new value to the frontend.
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The front-end will then relay those values to MQTT and finally to Home Assistant.
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Additionally, we created a function that tells the sensor what unit of measurement the
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value is in, this is not strictly required and only used for a nice output in Home Assistant.
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Step 2: Registering the custom sensor
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-------------------------------------
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Now we have our Custom Sensor set up, but unfortunately it doesn't do much right now.
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Actually ... it does nothing because it's never registered in the App,
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so esphomelib can't know about it. Let's change that.
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In your global ``setup()`` method, after you've setup all other components, do the following:
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.. code:: cpp
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void setup() {
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// ...
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// =========== AUTO GENERATED CODE END ============
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// ========= YOU CAN EDIT AFTER THIS LINE =========
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auto *custom_sensor = new CustomSensor("My Custom Sensor", 5000); // update every 5000ms or every 5 seconds.
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App.register_component(custom_sensor);
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App.register_sensor(custom_sensor);
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App.setup();
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}
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If you have Home Assistant MQTT discovery setup, it will even automatically show up in the frontend 🎉
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(with the entity id ``sensor.custom_sensor_example``)
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.. figure:: images/custom-ui.png
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:align: center
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:width: 60%
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Let's go through the code for registering our custom sensor. First, we're creating a new CustomSensor
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instance with the update interval of 5000ms using the ``new`` C++ syntax (important!) and assigning it to a
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variable ``custom_sensor`` (using C++11 ``auto`` type specifier to make it simpler).
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.. code:: cpp
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auto *custom_sensor = new CustomSensor(5000);
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Next, we *register* the component in esphomelib's Application instance so that it can call the component's
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``setup()`` and ``loop()``.
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.. code:: cpp
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App.register_component(custom_sensor);
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// you could also write this, it's a bit shorter and works the same way.
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// auto *custom_sensor = App.register_component(new CustomSensor(5000));
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App.register_sensor(custom_sensor);
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Lastly, we're registering the *sensor* with ``register_sensor``, this will automatically set up a
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bunch of callbacks so that it can publish state changes to MQTT when you call ``publish_new_value()``,
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create automatic MQTT discovery messages and setup a moving average over the sensor values
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(adjust these as you would with any other sensor).
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Step 3: BMP180 support
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----------------------
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Let's finally make this custom sensor useful by adding the BMP180 aspect into it! A great feature of
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esphomelib is that you can just use all existing arduino libraries, amazing right? Now for this example we'll
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use the `Adafruit BMP085 Library <https://platformio.org/lib/show/525/Adafruit%20BMP085%20Library>`__
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library by Adafruit.
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First we'll need to add the library to our platformio dependencies. To do so, put the following in
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the ``common`` section of your ``platformio.ini``:
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.. code:: ini
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[common]
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lib_deps = Adafruit BMP085 Library
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build_flags =
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upload_flags =
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Next, include the library at the top of you main sketch file (``<NODE_NAME>/src/main.cpp``):
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.. code:: cpp
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#include "esphomelib/application.h"
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#include <Adafruit_BMP085.h>
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using namespace esphomelib;
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// ...
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Then update our sensor for BMP180 support:
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.. code:: cpp
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// ...
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class BMP180Sensor : public sensor::PollingSensorComponent {
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public:
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Adafruit_BMP085 bmp;
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BMP180Sensor(const std::string &name, uint32_t update_interval)
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: sensor::PollingSensorComponent(name, update_interval) {
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}
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void setup() override {
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bmp.begin();
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}
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void update() override {
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int pressure = bmp.readPressure(); // in Pa, or 1/100 hPa
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publish_state(pressure / 100.0); // convert to hPa
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}
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std::string unit_of_measurement() override { return "hPa"; }
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int8_t accuracy_decimals() override { return 2; } // 2 decimal places of accuracy.
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};
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void setup() {
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// ...
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auto *custom_sensor = new BMP180Sensor("My BMP180 sensor", 5000);
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App.register_component(custom_sensor);
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App.register_sensor(custom_sensor);
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App.setup();
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}
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// ...
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There's not too much going on there. First, we define the variable ``bmp`` of type ``Adafruit_BMP085``
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inside our class as a class member. In ``setup()`` we initialize the library and in ``update()`` we read the
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pressure and send it out to MQTT.
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You've now successfully created your first custom sensor component 🎉 Happy coding!
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Bonus: Sensors With Multiple Output Values
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------------------------------------------
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The ``PollingSensorComponent`` doesn't fit every use-case. Sometimes, (as with the BMP180),
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a sensor can expose multiple values (temperature *and* pressure, for example).
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Doing so in esphomelib is a bit more difficult. Basically, we will have to change our sensor
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model to have *one component* that reads out the values and *one sensor class* for each value
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we want to expose.
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Let's look at what that could look like in code:
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.. code:: cpp
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// An empty sensor subclass that will "proxy" the temperature values
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class BMP280TemperatureSensor : public sensor::Sensor {
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public:
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BMP280TemperatureSensor(const std::string &name) : sensor::Sensor(name) {}
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std::string unit_of_measurement() override { return "°C"; }
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int8_t accuracy_decimals() override { return 1; }
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};
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// An empty sensor subclass that will "proxy" the pressure values
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class BMP280PressureSensor : public sensor::Sensor {
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public:
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BMP280PressureSensor(const std::string &name) : sensor::Sensor(name) {}
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std::string unit_of_measurement() override { return "hPa"; }
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int8_t accuracy_decimals() override { return 2; }
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};
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class BMP180Component : public PollingComponent {
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public:
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Adafruit_BMP085 bmp;
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BMP280TemperatureSensor *temperature_sensor;
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BMP280PressureSensor *pressure_sensor;
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BMP180Component(const std::string &temperature_name, const std::string &pressure_name, uint32_t update_interval)
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: PollingComponent(update_interval) {
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this->temperature_sensor = new BMP280TemperatureSensor(temperature_name);
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this->pressure_sensor = new BMP280PressureSensor(pressure_name);
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}
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void setup() override {
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bmp.begin();
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}
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void update() override {
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// This is the actual sensor reading logic.
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int pressure = bmp.readPressure();
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pressure_sensor->publish_state(pressure / 100.0);
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float temperature = bmp.readTemperature();
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temperature_sensor->publish_state(temperature);
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}
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};
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void setup() {
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// ...
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auto *custom_bmp180 = new BMP180Component("BMP180 Temperature", "BMP180 Pressure", 5000);
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// The BMP180Component is a *component*, so it needs to be registered.
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App.register_component(custom_bmp180);
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// But the temperature&pressure classes are *sensors*, so each of them needs to be registered
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App.register_sensor(custom_bmp180->temperature_sensor);
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App.register_sensor(custom_bmp180->pressure_sensor);
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App.setup();
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}
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That's a lot of code :P Basically, what it boils down to is you have one central component ``BMP180Component``
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which handles the communication with the BMP180 and a ``Sensor`` subclass for each value you want to expose.
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Most of the magic happens inside the ``update()`` function. Here, the values are read from the BMP180 and are
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sent to esphomelib via the pressure/temperature sensor proxies we set up in the constructor.
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The only other thing you need to change is the registering inside ``setup()``.
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Because ``BMP180Component`` is a *component* (because it has a lifecycle through the ``setup()`` and ``loop()`` methods),
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it needs to be registered with ``App.register_component(...)``. However, as it's now not a subclass
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of ``Sensor`` anymore, it cannot be registered as a sensor.
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But because the ``BMP280TemperatureSensor`` and ``BMP280PressureSensor`` *are* subclasses of sensors,
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they do need to be registered so that esphomelib can do all the magic stuff like setting up MQTT discovery
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for them. That's why we call ``App.register_sensor`` for each sensor we created in the end.
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See Also
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--------
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- `Full source code <https://github.com/OttoWinter/esphomelib/blob/master/examples/custom-bmp180-sensor/custom-bmp180-sensor.cpp>`__
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- `Edit this page on GitHub <https://github.com/OttoWinter/esphomedocs/blob/current/esphomeyaml/components/sensor/custom.rst>`__
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.. disqus::
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