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Using MySQL 5.7 Document Store with Internet of Things

Using MySQL 5.7 Document Store with Internet of Things In this blog post, I’ll discuss how to use MySQL 5.7 Document Store to track data from Internet of Things (IoT) devices.

Using JSON in MySQL 5.7

In my previous blog post, I’ve looked into MySQL 5.7.12 Document Store . This is a brand new feature in MySQL 5.7, and many people are asking when do I need or want to use the JSON or Document Store interface?

Storing data in JSON may be quite useful in some cases, for example:

  • You already have a JSON (i.e., from external feeds) and need to store it anyway. Using the JSON datatype will be more convenient and more efficient.
  • For the Internet of Things, specifically, when storing events from sensors: some sensors may send only temperature data, some may send temperature, humidity and light (but light information is only recorded during the day), etc. Storing it in JSON format may be more convenient in that you don’t have to declare all possible fields in advance, and do not have to run “alter table” if a new sensor starts sending new types of data.

Internet of Things

In this blog post, I will show an example of storing an event stream from Particle Photon . Last time I created a device to measure light and temperature and stored the results in MySQL. Particle.io provides the ability to use its own MQTT server and publish events with:

Spark.publish("temperature", String(temperature));  Spark.publish("humidity", String(humidity));  Spark.publish("light", String(light)); 

Then, I wanted to “subscribe” to my events and insert those into MySQL (for further analysis). As we have three different metrics for the same device, we have two basic options:

  1. Use a field per metric and create something like this: device_id int, temperature double, humidity double, light double
  2. Use a record per metric and have something like this: device_id int, event_name varchar(255), event_data text (please see this  Internet of Things, Messaging and MySQL blog post for more details)

The first option above is not flexible. If my device starts measuring the soil temperature, I will have to “alter table add column”.

Option two is better in this regard, but I may significantly increase the table size as I have to store the name as a string for each measurement. In addition, some devices may send more complex metrics (i.e., latitude and longitude).

In this case, using JSON for storing metrics can be a better option. In this case, I’ve also decided to try Document Store as well.

First, we will need to enable X Plugin and setup the NodeJS / connector. Here are the steps required:

  1. Enable X Plugin  in MySQL 5.7.12+, which uses a different port (33060 by default)
  2. Download and install NodeJS (>4.2) and mysql-connector-nodejs-1.0.2.tar.gz (follow the  Getting Started with Connector/Node.JS guide).
    # node --version v4.4.4 # wget https://dev.mysql.com/get/Downloads/Connector-Nodejs/mysql-connector-nodejs-1.0.2.tar.gz # npm install mysql-connector-nodejs-1.0.2.tar.gz 

    Please note: on older systems you will probably need to upgrade the nodejs version (follow the  Installing Node.js via package manager guide).

Storing Events from Sensors

Particle.io provides you with an API that allows you to subscribe to all public events (“events” are what sensors send). The API is for NodeJS, which is really convenient as we can use NodeJS for MySQL 5.7.12 Document Store as well.

To use the Particle API, install the particle-api-js module:

$ npminstallparticle-api-js 

I’ve created the following NodeJS code to subscribe to all public events, and then add the data (in JSON format) to a document store:

var mysqlx = require('mysqlx'); var Particle = require('particle-api-js'); var particle = new Particle(); var token = '<place your token here>'   var mySession =  mysqlx.getSession({     host: 'localhost',     port: 33060,     dbUser: 'root',     dbPassword: '<place your pass here>' });   process.on('SIGINT', function() {     console.log("Caught interrupt signal. Exiting...");     process.exit() });     particle.getEventStream({ auth: token}).then(function(stream) {                 stream.on('event', function(data) {                                 console.log(data);                                 mySession.then(session => {                                                 session.getSchema("iot").getCollection("event_stream")                                                 .add(  data  )                                                 .execute(function (row) {                                                         // can log something here                                                 }).catch(err => {                                                         console.log(err);                                                 })                                                 .then( function (notices) {                                                          console.log("Wrote to MySQL: " + JSON.stringify(notices))                                                   });                                 }).catch(function (err) {                                               console.log(err);                                               process.exit();                                 });                                                }); }).catch(function (err) {                                               console.log(err.stack);                                               process.exit(); }); 

How it works:

  • particle.getEventStream({ auth: token}) gives me the stream of events. From there I can subscribe to specific event names, or to all public events using the generic name “events”: stream.on(‘event’, function(data).
  • function(data) is a callback function fired when a new event is ready. The event has JSON type “data.” From there I can simply insert it to a document store: .add( data ).execute() will insert the JSON data into the event_stream document store.

One of the reasons I use document store here is I do not have to know what is inside the event data. I do not have to parse it, I simply throw it to MySQL and analyze it later. If the format of data will change in the future, my application will not break.

Inside the data stream

Here is the example of running the above code:

{ data: 'Humid: 49.40 Temp: 25.00 *C Dew: 13.66 *C HeatI: 25.88 *C',   ttl: '60',   published_at: '2016-05-20T19:30:51.433Z',   coreid: '2b0034000947343337373738',   name: 'log' } WrotetoMySQL: {"_state":{"rows_affected":1,"doc_ids":["a3058c16-15db-0dab-f349-99c91a00"]}} { data: 'null',   ttl: '60',   published_at: '2016-05-20T19:30:51.418Z',   coreid: '50ff72...',   name: 'registerdev' } WrotetoMySQL: {"_state":{"rows_affected":1,"doc_ids":["eff0de02-726e-34bd-c443-6ecbccdd"]}} { data: '24.900000',   ttl: '60',   published_at: '2016-05-20T19:30:51.480Z',   coreid: '2d0024...',   name: 'Humid 2' } { data: '[{"currentTemp":19.25},{"currentTemp":19.19},{"currentTemp":100.00}]',   ttl: '60',   published_at: '2016-05-20T19:30:52.896Z',   coreid: '2d002c...',   name: 'getTempData' } WrotetoMySQL: {"_state":{"rows_affected":1,"doc_ids":["5f1de278-05e0-6193-6e30-0ebd78f7"]}} { data: '{"pump":0,"salt":0}',   ttl: '60',   published_at: '2016-05-20T19:30:51.491Z',   coreid: '55ff6...',   name: 'status' } WrotetoMySQL: {"_state":{"rows_affected":1,"doc_ids":["d6fcf85f-4cba-fd59-a5ec-2bd78d4e"]}} 

(Please note: although the stream is public, I’ve tried to anonymize the results a little.)

As we can see the “data” is JSON and has that structure. I could have implemented it as a MySQL table structure (adding published_at, name, TTL and coreid as separate fields). However, I would have to depend on those specific fields and change my application if those fields changed. We also see examples of how the device sends the data back: it can be just a number, a string or another JSON.

Analyzing the results

Now I can go to MySQL and use SQL (which I’ve used for >15 years) to find out what I’ve collected. First, I want to know how many device names I have:

mysql -A iot Welcome to the MySQL monitor.  Commands end with ; or g. Your MySQL connection id is 3289 Server version: 5.7.12 MySQL Community Server (GPL)   Copyright (c) 2000, 2016, Oracle and/or its affiliates. All rights reserved.   Oracle is a registered trademark of Oracle Corporation and/or its affiliates. Other names may be trademarks of their respective owners.   Type 'help;' or 'h' for help. Type 'c' to clear the current input statement.   mysql> select count(distinct json_unquote(doc->'$.name')) from event_stream; +---------------------------------------------+ | count(distinct json_unquote(doc->'$.name')) | +---------------------------------------------+ |                                        1887 | +---------------------------------------------+ 1 row in set (5.47 sec) 

That is slow! As described inmy previous post, I can create a virtual column and index for doc->’$.name’ to make it faster:

mysql> alter table event_stream add column name varchar(255)      -> generated always as (json_unquote(doc->'$.name')) virtual; Query OK, 0 rows affected (0.17 sec) Records: 0  Duplicates: 0  Warnings: 0   mysql> alter table event_stream add key (name); Query OK, 0 rows affected (3.47 sec) Records: 0  Duplicates: 0  Warnings: 0   mysql> show create table event_stream *************************** 1. row ***************************       Table: event_stream Create Table: CREATE TABLE `event_stream` (   `doc` json DEFAULT NULL,   `_id` varchar(32) GENERATED ALWAYS AS (json_unquote(json_extract(`doc`,'$._id'))) STORED NOT NULL,   `name` varchar(255) GENERATED ALWAYS AS (json_unquote(json_extract(`doc`,'$.name'))) VIRTUAL,   UNIQUE KEY `_id` (`_id`),   KEY `name` (`name`) ) ENGINE=InnoDB DEFAULT CHARSET=utf8mb4 1 row in set (0.00 sec)   mysql> select count(distinct name) from event_stream; +----------------------+ | count(distinct name) | +----------------------+ |                1820 | +----------------------+ 1 row in set (0.67 sec) 

How many beers left?

Eric Joyce has published a Keg Inventory Counter that uses a Particle Proton device to measure the amount of beer in a keg by 12oz pours. I want to see what was the average and the lowest amount of beer per day:

mysql> select date(json_unquote(doc->'$.published_at')) as day,      ->        avg(json_unquote(doc->'$.data')) as avg_beer_left,      ->    min(json_unquote(doc->'$.data')) as min_beer_left      -> from event_stream      -> where name = 'Beers_left'     -> group by date(json_unquote(doc->'$.published_at')); +------------+--------------------+---------------+ | day        | avg_beer_left      | min_beer_left | +------------+--------------------+---------------+ | 2016-05-13 |  53.21008358996988 | 53.2          | | 2016-05-18 |  52.89973045822105 | 52.8          | | 2016-05-19 | 52.669233854792694 | 52.6          | | 2016-05-20 |  52.60644257702987 | 52.6          | +------------+--------------------+---------------+ 4 rows in set (0.44 sec) 

Conclusion

UDocument Store can be very beneficial if an application is working with a JSON field and does not know or does not care about its structure. In this post, I’ve used the “save to MySQL and analyze later” approach here. We can then add virtual fields and add indexes if needed.

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