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“It’s a 5-year process from the beginning to the end.” Business Insider takes us to the Avery Island, Louisiana Tabasco company to learn about the how they make their tasty and ubiquitous hot pepper sauce. The process is not dissimilar from aging good whiskey.
Apple has publicly acknowledged that the butterfly switch keyboards in some MacBook and MacBook Pro computers have given consumers some trouble, and it has launched a new repair service program that promises to fix problems with those keyboards for free, regardless of whether the consumer purchased AppleCare.
Apple says in its public documentation on the program that certain models of MacBook and MacBook Pro “may exhibit one or more of the following behaviors”:
- Letters or characters repeat unexpectedly
- Letters or characters do not appear
- Key(s) feel “sticky” or do not respond in a consistent manner
When they do, “Apple or an Apple Authorized Service Provider will service eligible MacBook and MacBook Pro keyboards, free of charge.” Apple also says that consumers who previously paid for a repair can contact the company to request a refund.
It’s difficult to say exactly how widespread the problem has been, but anecdotally, I know multiple people who have had to deal with it. I encountered this problem with my own 2016 MacBook Pro as well. I was able to get it fixed for free because I had purchased AppleCare; the repairs could have otherwise cost me more than $700, based on the receipts given to me by Apple with the repair.
Last month, AppleInsider combed through a small and insufficiently representative repair record dataset to come to some tentative conclusions—namely that the butterfly switch-equipped 2016 MacBook Pros experienced twice as many repair events related to the keyboard (excluding Touch Bar repairs) as the 2015 MacBook Pros that had the older chiclet design. The same data suggested that small tweaks made to the keyboard design in 2017 models returned the repair frequency closer to normal.
Regardless, the new repair program covers the 2017 MacBook Pros, not just the 2016 models. This is the complete list of machines Apple says it will service in this new program:
- MacBook (Retina, 12-inch, Early 2015)
- MacBook (Retina, 12-inch, Early 2016)
- MacBook (Retina, 12-inch, 2017)
- MacBook Pro (13-inch, 2016, Two Thunderbolt 3 Ports)
- MacBook Pro (13-inch, 2017, Two Thunderbolt 3 Ports)
- MacBook Pro (13-inch, 2016, Four Thunderbolt 3 Ports)
- MacBook Pro (13-inch, 2017, Four Thunderbolt 3 Ports)
- MacBook Pro (15-inch, 2016)
- MacBook Pro (15-inch, 2017)
These butterfly keyboards have proven divisive among consumers. On the positive side, Apple likely chose the new design primarily because it saved space for other components in the machines, and some users feel that they’re faster to type on than other keyboards because of the very shallow, clicky keys. However, the keyboards have numerous passionate and vocal detractors who say that they’re terrible to type on, and who also cite reliability concerns.
We believe Apple is more likely to continue to refine the existing keyboard design in future laptops to address detractors’ complaints than to go back to an earlier design. But in the meantime, consumers can at least get keyboards that are having problems repaired at no cost—other than some of their time, of course. It took a long time for this service program to arrive given how long users have been reporting problems, though.
via Ars Technica
Apple launches service program to address MacBook keyboard woes
guvendemir via Getty Images
While the US Army already works with huge military contractors, it still wants to make sure that it won’t miss the chance nab new technologies developed by small businesses. That’s why it has launched the Army Expeditionary Technology Search or xTechSearch, which will give “nontraditional defense partners” the chance to work with the military division. xTechSearch is a four-phase competition that promises a $200,000 cash prize for the final winner to be announced in April 2019. It’s soliciting innovative technologies the army could use, such as next-gen combat vehicles that can replace tanks.
The competition is also looking for new technologies that reduce the cost of missile defense, as well as innovations that can “enhance [soldier] lethality in close combat.” By launching this challenge, the army is likely hoping to find a gem it wouldn’t have found otherwise, something big corporations might not think of — something born out of necessity to innovate due to lack of funds and access to resources. The challenge is open to all small businesses and is now accepting all technology proposals until July 11th, 2018.
via Engadget
US Army asks startups to deliver next-generation weapons
In this blog, we will see the very basic thing “I” of “ACID” and an important property of Transaction ie., “ISOLATION”
The isolation defines the way in which the MySQL server (InnoDB) separates each transaction from other concurrent running transaction in the server and also ensures that the transactions are processed in a reliable way. If transactions are not isolated then one transaction could modify the data that another transaction is reading hence creating data inconsistency. Isolation levels determine how isolated the transactions are from each other.
MySQL supports all four the isolation levels that SQL-Standard defines.The four isolation levels are
The Isolation level’s can be set globally or session based on our requirements.
Choosing the best isolation level based, have a great impact on the database, Each level of isolation comes with a trade-off, let’s discuss on each of them,
In READ-UNCOMMITTED isolation level, there isn’t much isolation present between the transactions at all, ie ., No locks. A transaction can see changes to data made by other transactions that are not committed yet. This is the lowest level in isolation and highly performant since there is no overhead of maintaining locks, With this isolation level, there is always for getting a “Dirty-Read”
That means transactions could be reading data that may not even exist eventually because the other transaction that was updating the data rolled-back the changes and didn’t commit. lest see the below image for better understanding
Suppose a transaction T1 modifies a row if a transaction T2 reads the row and sees the modification even though T1 has not committed it, that is a dirty read, the problem here is if T1 rolls back, T2 doesn’t know that and will be in a state of “totally perplexed”
IN READ-COMMITTED isolation level, the phenomenon of dirty read is avoided, because any uncommitted changes are not visible to any other transaction until the change is committed. This is the default isolation level with most of popular RDBMS software, but not with MySQL.
Within this isolation level, each SELECT uses its own snapshot of the committed data that was committed before the execution of the SELECT. Now because each SELECT has its own snapshot, here is the trade-off now, so the same SELECT, when running multiple times during the same transaction, could return different result sets. This phenomenon is called non-repeatable read.
A non-repeatable occurs when a transaction performs the same transaction twice but gets a different result set each time. Suppose T2 reads some of the rows and T1 then change a row and commit the change, now T2 reads the same row set and gets a different result ie.., the initial read is non-repeatable.
Read-committed is the recommended isolation level for Galera ( PXC, MariaDB Cluster ) and InnoDB clusters.
In REPEATABLE-READ isolation level, the phenomenon of non-repeatable read is avoided. It is the default isolation in MySQL.This isolation level returns the same result set throughout the transaction execution for the same SELECT run any number of times during the progression of a transaction.
This is how it works, a snapshot of the SELECT is taken the first time the SELECT is run during the transaction and the same snapshot is used throughout the transaction when the same SELECT is executed. A transaction running in this isolation level does not take into account any changes to data made by other transactions, regardless of whether the changes have been committed or not. This ensures that reads are always consistent(repeatable). Maintaining a snapshot can cause extra overhead and impact some performance
Although this isolation level solves the problem of non-repeatable read, another possible problem that occurs is phantom reads.
A Phantom is a row that appears where it is not visible before. InnoDB and XtraDB solve the phantom read problem with multi-version concurrency control.
REPEATABLE READ is MySQL’s default transaction isolation level.
SERIALIZABLE completely isolates the effect of one transaction from others. It is similar to REPEATABLE READ with the additional restriction that row selected by one transaction cannot be changed by another until the first transaction finishes. The phenomenon of phantom reads is avoided. This isolation level is the strongest possible isolation level. AWS Aurora do not support this isolation level.
Photo by Alberto Triano on Unsplash
Shown here is a Winbag inflatable air shim.
More specifically, it’s a durable inflatable air wedge that’s made from a fiber-reinforced non-marking material.
It’s as flat as 3/32″, allowing it to slide into narrow spaces, and can be inflated to up to 2″. It can lift up to 300 pounds, per Winbag.
The Winbag air shim is said to be useful for installing doors, windows, cabinets, appliances, and all kinds of other fixtures where you might need to make careful height or spacing adjustments.
Have you used one? What kinds of things have you used it for? Don’t have one? What kinds of applications might you use this for?
Price: ~$15-20 each, depending on store and quantity
Buy Now(via Amazon)
Buy Now(via Tool Nut)
I’ve heard lots of good things about the Winbag, and can see a few things I’d use it for (such as installing anti-vibrational pads to a washing machine that’s already installed and blocked in place).
This demo video, although a little infomercial-toned, shows what the Winbag can do:
There’s a competing brand, the Air Shim by Calculated Industries, which can sometimes be found for less money.
They also offer a larger version, the XL 500.
See Also(via Amazon)
via ToolGuyd
Do You Use Inflatable Air Shims such as the Winbag?
How To Create Comment Nesting In Laravel From Scratch is the today’s main topic. In any topic specific forum, there is always a structure, where you need to reply to someone’s comment and then somebody reply in their comment and so on. So comment nesting is very useful in any web application, which exposes public interest. In this tutorial, we will do it from scratch. We use Polymorphic relationship in this example.
As always, install Laravel using the following command. I am using Laravel Valet.
laravel new comments # or composer create-project laravel/laravel comments --prefer-dist
Go to the project.
cd comments
Open the project in your editor.
code .
Configure the MySQL database in the .env file.
Create an auth using the following command.
php artisan make:auth
Now migrate the database using the following command.
php artisan migrate
Create a Post model and migration using the following command.
php artisan make:model Post -m
Define the schema in the post migration file.
// create_posts_table
public function up()
{
Schema::create('posts', function (Blueprint $table) {
$table->increments('id');
$table->string('title');
$table->text('body');
$table->timestamps();
});
}
Also, we need to create Comment model and migration, so create by using the following command.
php artisan make:model Comment -m
Okay, now we will use the Polymorphic relationship between the models. So we need to define the schema that way.
// create_comments_table
public function up()
{
Schema::create('comments', function (Blueprint $table) {
$table->increments('id');
$table->integer('user_id')->unsigned();
$table->integer('parent_id')->unsigned();
$table->text('body');
$table->integer('commentable_id')->unsigned();
$table->string('commentable_type');
$table->timestamps();
});
}
Now, migrate the database using the following cmd.
php artisan migrate
Now, we need to define the Polymorphic relationships between the models. So write the following code inside app >> Post.php file.
<?php
// Post.php
namespace App;
use Illuminate\Database\Eloquent\Model;
class Post extends Model
{
public function comments()
{
return $this->morphMany(Comment::class, 'commentable')->whereNull('parent_id');
}
}
Here, we have written all the comments, whose parent_id is null. The reason is that we need to display the parent level comment and also save the parent level comment. That is why. We need to differentiate between the Comment and its replies.
Post also belongs To a User. So we can define that relationship as well.
<?php
// Post.php
namespace App;
use Illuminate\Database\Eloquent\Model;
class Post extends Model
{
public function user()
{
return $this->belongsTo(User::class);
}
public function comments()
{
return $this->morphMany(Comment::class, 'commentable')->whereNull('parent_id');
}
}
Define the Comment relationship with the Post. Write the following code inside Comment.php file.
<?php
// Comment.php
namespace App;
use Illuminate\Database\Eloquent\Model;
class Comment extends Model
{
public function user()
{
return $this->belongsTo(User::class);
}
}
Create a PostController.php file using the following command.
php artisan make:controller PostController
Next step is to define the route for the view and store the post in the database. Write the following code inside routes >> web.php file.
<?php
// web.php
Route::get('/', function () {
return view('welcome');
});
Auth::routes();
Route::get('/home', 'HomeController@index')->name('home');
Route::get('/post/create', 'PostController@create')->name('post.create');
Route::post('/post/store', 'PostController@store')->name('post.store');
Write the following code inside PostController.php file.
<?php
// PostController.php
namespace App\Http\Controllers;
use Illuminate\Http\Request;
class PostController extends Controller
{
public function __construct()
{
return $this->middleware('auth');
}
public function create()
{
return view('post');
}
public function store(Request $request)
{
// store code
}
}
Now, first, we need to create a form for creating the post. So create a blade file inside resources >> views folder called post.blade.php. Write the following code inside a post.blade.php file.
@extends('layouts.app')
@section('content')
<div class="container">
<div class="row justify-content-center">
<div class="col-md-8">
<div class="card">
<div class="card-header">Create Post</div>
<div class="card-body">
<form method="post" action="">
<div class="form-group">
@csrf
<label class="label">Post Title: </label>
<input type="text" name="title" class="form-control" required/>
</div>
<div class="form-group">
<label class="label">Post Body: </label>
<textarea name="body" rows="10" cols="30" class="form-control" required></textarea>
</div>
<div class="form-group">
<input type="submit" class="btn btn-success" />
</div>
</form>
</div>
</div>
</div>
</div>
</div>
@endsection
Okay, now go to the resources >> views >> layouts >> app.blade.php file and add a link to create a post.
We need to add the link to the @else part of the navigation bar. So, if the user is successfully logged in then and then he/she can create a post otherwise, he or she could not create a post.
@else
<li class="nav-item">
<a class="nav-link" href="">Create Post</a>
</li>
Now, go to this link: http://comments.test/register and register a user. After logged in, you can see the Create Post in the navbar. Click that item, and you will redirect to this route: http://comments.test/post/create. You can see, our form is there with the title and body form fields.
Okay, now we need to save the post in the database, so write the following code inside store function of PostController.php file.
<?php
// PostController.php
namespace App\Http\Controllers;
use App\Post;
use Illuminate\Http\Request;
class PostController extends Controller
{
public function __construct()
{
return $this->middleware('auth');
}
public function create()
{
return view('post');
}
public function store(Request $request)
{
$post = new Post;
$post->title = $request->get('title');
$post->body = $request->get('body');
$post->save();
return redirect('posts');
}
}
After saving the post, we are redirecting to the posts list page. We need to define its route too. Add the following route inside a web.php file.
// web.php
Route::get('/posts', 'PostController@index')->name('posts');
Also, we need to define the index function inside PostController.php file.
// PostController.php
public function index()
{
$posts = Post::all();
return view('index', compact('posts'));
}
Create an index.blade.php file inside views folder. Write the following code inside an index.blade.php file.
@extends('layouts.app')
@section('content')
<div class="container">
<div class="row justify-content-center">
<div class="col-md-8">
<table class="table table-striped">
<thead>
<th>ID</th>
<th>Title</th>
<th>Action</th>
</thead>
<tbody>
@foreach($posts as $post)
<tr>
<td></td>
<td></td>
<td>
<a href="" class="btn btn-primary">Show Post</a>
</td>
</tr>
@endforeach
</tbody>
</table>
</div>
</div>
</div>
@endsection
Now, define the show route inside a web.php file. Add the following line of code inside a web.php file.
// web.php
Route::get('/post/show/{id}', 'PostController@show')->name('post.show');
Also, define the show() function inside PostController.php file.
// PostController.php
public function show($id)
{
$post = Post::find($id);
return view('show', compact('post'));
}
Create a show.blade.php file inside views folder and add the following code.
@extends('layouts.app')
@section('content')
<div class="container">
<div class="row justify-content-center">
<div class="col-md-8">
<div class="card">
<div class="card-body">
<p></p>
<p>
</p>
</div>
</div>
</div>
</div>
</div>
@endsection
Okay, now you can see the individual posts. Fine till now.
Next step is to display the comments on this post.
First, create a CommentController.php file using the following command.
php artisan make:controller CommentController
Now, we need to create a form inside a show.blade.php file that can add the comment in the particular post.
Write the following code inside a show.blade.php file.
@extends('layouts.app')
@section('content')
<div class="container">
<div class="row justify-content-center">
<div class="col-md-8">
<div class="card">
<div class="card-body">
<p><b></b></p>
<p>
</p>
<hr />
<h4>Add comment</h4>
<form method="post" action="">
@csrf
<div class="form-group">
<input type="text" name="comment_body" class="form-control" />
<input type="hidden" name="post_id" value="" />
</div>
<div class="form-group">
<input type="submit" class="btn btn-warning" value="Add Comment" />
</div>
</form>
</div>
</div>
</div>
</div>
</div>
@endsection
So, we have added a form that can add the comment. Now, we need to define the route to store the comment.
// web.php
Route::post('/comment/store', 'CommentController@store')->name('comment.add');
Okay, now write the store() function and save the comment using the morphMany() relationship.
<?php
namespace App\Http\Controllers;
use Illuminate\Http\Request;
use App\Comment;
use App\Post;
class CommentController extends Controller
{
public function store(Request $request)
{
$comment = new Comment;
$comment->body = $request->get('comment_body');
$comment->user()->associate($request->user());
$post = Post::find($request->get('post_id'));
$post->comments()->save($comment);
return back();
}
}
Okay, now if all is well then, we can now add the comments. Remember, we have not till now display the comments. Just complete the save functionality, whose parent_id is null.
Now, as we have set up the relationship between a Comment and a Post, we can easily pluck out all the comments related to a particular post.
So, write the following code inside the show.blade.php file. I am writing the whole file to display the comments. Remember, this is the parent comments. We still need to create a reply button and then show all the replies.
<!-- show.blade.php -->
@extends('layouts.app')
@section('content')
<div class="container">
<div class="row justify-content-center">
<div class="col-md-8">
<div class="card">
<div class="card-body">
<p><b></b></p>
<p>
</p>
<hr />
<h4>Display Comments</h4>
@foreach($post->comments as $comment)
<div class="display-comment">
<strong></strong>
<p></p>
</div>
@endforeach
<hr />
<h4>Add comment</h4>
<form method="post" action="">
@csrf
<div class="form-group">
<input type="text" name="comment_body" class="form-control" />
<input type="hidden" name="post_id" value="" />
</div>
<div class="form-group">
<input type="submit" class="btn btn-warning" value="Add Comment" />
</div>
</form>
</div>
</div>
</div>
</div>
</div>
@endsection
Now, add the comment, and it will show us here in the same url.
Now, we need to create a function called replies() inside Comment.php model.
<?php
// Comment.php
namespace App;
use Illuminate\Database\Eloquent\Model;
class Comment extends Model
{
public function user()
{
return $this->belongsTo(User::class);
}
public function replies()
{
return $this->hasMany(Comment::class, 'parent_id');
}
}
Here, in the replies function, we need to add a primary key as a parent_id because we need to fetch a reply based on a parent comment’s id.
Okay, now we need to write the display of all the comments and its replies code into the partial blade file.
The reason behind is that, we need to nest the comment replies and how much nesting is required depends upon the user interaction. So we can not predict the nesting levels.
To make more and more flexible, we need to create partials and then repeat that partial to display the nested comment replies.
First, create a partials folder inside resources >> views folder and inside partials folder, create one file called _comment_replies.blade.php.
Write the following code inside the _comment_replies.blade.php file.
<!-- _comment_replies.blade.php -->
@foreach($comments as $comment)
<div class="display-comment">
<strong></strong>
<p></p>
<a href="" id="reply"></a>
<form method="post" action="">
@csrf
<div class="form-group">
<input type="text" name="comment_body" class="form-control" />
<input type="hidden" name="post_id" value="" />
<input type="hidden" name="comment_id" value="" />
</div>
<div class="form-group">
<input type="submit" class="btn btn-warning" value="Reply" />
</div>
</form>
@include('partials._comment_replies', ['comments' => $comment->replies])
</div>
@endforeach
Here, I have displayed all the replies with the text box. So it can do further nesting.
Now, this partial is expect to parameters.
So, when we include this partial inside show.blade.php file, we do need to pass these both of the parameters so that we can access here.
Also, we need to define the route to save the reply.
Add the following line of code inside routes >> web.php file.
// web.php
Route::post('/reply/store', 'CommentController@replyStore')->name('reply.add');
So, our final web.php file looks like below.
<?php
// web.php
Route::get('/', function () {
return view('welcome');
});
Auth::routes();
Route::get('/home', 'HomeController@index')->name('home');
Route::get('/post/create', 'PostController@create')->name('post.create');
Route::post('/post/store', 'PostController@store')->name('post.store');
Route::get('/posts', 'PostController@index')->name('posts');
Route::get('/post/show/{id}', 'PostController@show')->name('post.show');
Route::post('/comment/store', 'CommentController@store')->name('comment.add');
Route::post('/reply/store', 'CommentController@replyStore')->name('reply.add');
Also, define the replyStore() function inside CommentController.php file.
I am writing here the full code of the CommentController.php file.
<?php
// CommentController.php
namespace App\Http\Controllers;
use Illuminate\Http\Request;
use App\Comment;
use App\Post;
class CommentController extends Controller
{
public function store(Request $request)
{
$comment = new Comment;
$comment->body = $request->get('comment_body');
$comment->user()->associate($request->user());
$post = Post::find($request->get('post_id'));
$post->comments()->save($comment);
return back();
}
public function replyStore(Request $request)
{
$reply = new Comment();
$reply->body = $request->get('comment_body');
$reply->user()->associate($request->user());
$reply->parent_id = $request->get('comment_id');
$post = Post::find($request->get('post_id'));
$post->comments()->save($reply);
return back();
}
}
So, here almost both of the function store and replyStore function is same. We are storing parent comment and its replies in the same table. But, when we are saving a parent comment, the parent_id becomes null, and when we store any reply, then parent_id becomes its comment_id. So that is the difference.
Finally, our show.blade.php file looks like this.
<!-- show.blade.php -->
@extends('layouts.app')
<style>
.display-comment .display-comment {
margin-left: 40px
}
</style>
@section('content')
<div class="container">
<div class="row justify-content-center">
<div class="col-md-8">
<div class="card">
<div class="card-body">
<p><b></b></p>
<p>
</p>
<hr />
<h4>Display Comments</h4>
@include('partials._comment_replies', ['comments' => $post->comments, 'post_id' => $post->id])
<hr />
<h4>Add comment</h4>
<form method="post" action="">
@csrf
<div class="form-group">
<input type="text" name="comment_body" class="form-control" />
<input type="hidden" name="post_id" value="" />
</div>
<div class="form-group">
<input type="submit" class="btn btn-warning" value="Add Comment" />
</div>
</form>
</div>
</div>
</div>
</div>
</div>
@endsection
Here, I have defined the CSS to display proper nesting.
Also, include the partials and pass the both of the parameters.
We can add the parent comment from here but can add the replies from the partials.
I have added the parent comment, and its replies and our database table looks like this.
Also, our final output looks like below.
Finally, Create Comment Nesting In Laravel Tutorial With Example is over.
I have put the Github Code of Create Comment Nesting In Laravel so that you can check that out as well.
via Planet MySQL
How To Create Comment Nesting In Laravel From Scratch
RDS is a Database as a Service (DBaaS) that automatically configures and maintains your databases in the AWS cloud. The user has limited power over specific configurations in comparison to running MySQL directly on Elastic Compute Cloud (EC2). But RDS is a convenient service, as long as you can live with the instances and configurations that it offers.
Amazon RDS currently supports various MySQL and MariaDB versions as well as the, MySQL-compatible Amazon Aurora DB engine. It does support replication, but as you may expect from a predefined web console, there are some limitations.
There are some tradeoffs when using RDS. These may not only affect the way you manage and provision your database instances, but also key things like performance, security, and high availability.
In this blog, we will take a look at the differences between using RDS and running MySQL on EC2, with focus on replication. As we will see, to decide between hosting MySQL on an EC2 instance or using Amazon RDS is not an easy task.
The biggest size of database that AWS can host depends on your source environment, the allocation of data in your source database, and how busy your system is.
AWS is split into regions. Every AWS account has limits, per region, on the number of AWS resources that can be created. Once a limit for a resource has been reached, additional calls to create that resource will fail.
For Amazon RDS MySQL DB instances, the maximum provisioned storage limit constrains the size of a table to a maximum size of 6 TB when using InnoDB file-per-table tablespaces.
InnoDB file-per-table feature is something that you should consider even if you are not looking to migrate a big database into the cloud. You may notice that some existing DB instances have a lower limit. For example, MySQL DB instances created prior to April 2014 have a file and table size limit of 2 TB. This 2-TB file size limit also applies to DB instances or Read Replicas created from DB snapshots taken before April 2014.
One of the key differences which affects the way you set up and maintain database replication is the lack of SUPER user. To address this limitation, Amazon introduced stored procedures that take care of various DBA tasks. Below are the key procedures to manage MySQL RDS replication.
Skip replication error:
CALL mysql.rds_skip_repl_error;Stop replication:
CALL mysql.rds_stop_replication;Start replication
CALL mysql.rds_start_replication;Configures an RDS instance as a Read Replica of a MySQL instance running outside of AWS.
CALL mysql.rds_set_external_master;Reconfigures a MySQL instance to no longer be a Read Replica of a MySQL instance running outside of AWS.
CALL mysql.rds_reset_external_master;Imports a certificate. This is needed to enable SSL communication and encrypted replication.
CALL mysql.rds_import_binlog_ssl_material;Removes a certificate.
CALL mysql.rds_remove_binlog_ssl_material;Changes the replication master log position to the start of the next binary log on the master.
CALL mysql.rds_next_master_log;While stored procedures take care of a number of tasks, it is a bit of a learning curve. Lack of SUPER privilege can also create problems in using external replication monitoring.
Amazon RDS does not currently support the following:
Last but not least – access to the shell. Amazon RDS does not allow direct host access to a DB instance via Telnet, Secure Shell (SSH), or Windows Remote Desktop Connection (RDP). You can still use the client on an application host to connect to the DB via standard tools like mysql client.
There are other limitations, as described in the RDS documentation.
There are options to operate MySQL directly on EC2, and thereby retain control of one’s high availability options. When going down this route, it is important to understand how to leverage the different AWS features that are at your disposal. Make sure you check out our ‘DIY Cloud Database’ white paper.
To automate deployment and management/maintenance tasks (while retaining control), it is possible to use ClusterControl. Just like with RDS, you have the convenience of deploying a database setup in a few minutes via a GUI. Adding nodes, scheduling backups, performing failovers, and so on, can also be conveniently done via the GUI.
ClusterControl can automate deployment of different high availability database setups – from master-slave replication to multi-master clusters. All the main MySQL flavours are supported – Oracle MySQL, MariaDB and Percona Server. Some initial setup of VPC/security group is required, and these are well described in the DIY Cloud Database whitepaper. Note that similar concepts apply, whether it is AWS or Google Cloud or Azure
Galera Cluster is a good alternative to consider when deploying a highly available MySQL service. It has established itself as a credible replacement for traditional MySQL master-slave architectures, although it is not a drop-in replacement. Most applications can still be adapted to run on it. It is possible to define different segments for databases that span across multiple AWS regions.
It is possible to setup ‘hybrid replication’ by combining synchronous replication within a Galera Cluster and asynchronous replication between the cluster and one or more slaves. Options like delaying the slave gives an additional level of protection to the data.
To achieve high availability, deploying a highly available setup is not enough. The applications have to somehow know which nodes are working and which ones are not. Changes in topology, e.g. moving a master to another host, also need to be propagated somehow so as to avoid errors in the application layer. ClusterControl supports deployments of proxies like HAProxy, MaxScale, and ProxySQL. For HAProxy and ProxySQL, there are additional options to deploy redundant instances with Keepalived and VirtualIP.
Amazon RDS provides read replica services. Cross-region replicas give you the ability to scale reads, as AWS has its services in a number of datacenters around the world. All read replicas are accessible and can be used for reading in a maximum number of five regions. These nodes are independent and can be used in your upgrade path, or can be promoted to standalone databases.
In addition to that, Amazon offers Multi-AZ deployments based on DRBD, synchronous disk replication. How is it different from Read Replicas? The main difference is that only the database engine on the primary instance is active, which leads to other architectural variations.
As opposed to read replicas, database engine version upgrades happen on the primary. Another difference is that AWS RDS will failover automatically with DRBD, while read replicas (using asynchronous replication) will require manual operations from you.
Multi-AZ failover on RDS uses a DNS change to point to the standby instance, according to Amazon this should happen within 60-120 seconds during the failover. Because the standby uses the same storage data as the primary, there will probably be transaction/log recovery. Bigger databases may spend a significant amount of time on InnoDB recovery, so please consider that in your DR plan and RTO calculation.
Of course, this goes with additional cost. Let’s take a look at some basic example. The cost of db.t2.medium host with 2vCPU, 4GB ram is 185.98 USD per month, the price will double when you enable Multizone (MZ) replica to 370.98 UDB. The price will vary by region but it will double in MZ.
In order to achieve the same with EC2, you can deploy your virtual machines in different regions. Each AWS Region is completely independent. The setting of AWS Region can be changed in the console, by setting the EC2_REGION environment variable, or it can be overridden by using the –region parameter with the AWS Command Line Interface. When your set of servers are ready, you can use ClusterControl to deploy and monitor your replication. You can also manually set up replication through the console using standard commands.
It is possible to setup replication between an Amazon RDS MySQL or MariaDB DB instance and a MySQL or MariaDB instance that is external to Amazon RDS. This is done using standard replication method in mysql, through binary logs. To enable binary logs, you need to modify the my.cnf configuration. Without access to the shell, this task became impossible in RDS. It’s done in a not so obvious way. You have two options. One is to enable backups – set automated backups on your Amazon RDS DB instance with retention to higher than 0. Or enable replication to a prebuilt slave server. Both tasks will enable binary logs which you can later on use for your replication.
Maintain the binlogs in your master instance until you have verified that they have been applied on the replica. This maintenance ensures that you can restore your master instance in the event of a failure.
Another roadblock can be permissions. The permissions required to start replication on an Amazon RDS DB instance are restricted and not available to your Amazon RDS master user. Because of this, you must use the Amazon RDS mysql.rds_set_external_master and mysql.rds_start_replication commands to set up replication between your live database and your Amazon RDS database.
Monitor failover events for the Amazon RDS instance that is your replica. If a failover occurs, then the DB instance that is your replica might be recreated on a new host with a different network address. For information on how to monitor failover events, see Using Amazon RDS Event Notification.
In the below example, we will see how to enable replication from RDS to an external DB located on an EC2 instance.
You should have binary logs enabled, we use an RDS slave here.
Specify the number of hours to retain binary logs.
mysql -h RDS_MASTER -u<username> -u<password>
call mysql.rds_set_configuration('binlog retention hours', 7);On RDS MASTER, create replication user with the following commands:
CREATE USER 'repl'@'ec2DBslave' IDENTIFIED BY 's3cr3tp4SSw0rd';
GRANT REPLICATION SLAVE ON *.* TO 'repl'@'ec2DBslave';On RDS SLAVE, run the commands:
mysql -u<username> -u<password> -h RDS_SLAVE
call mysql.rds_stop_replication;
SHOW SLAVE STATUS; Exec_Master_Log_Pos, Relay_Master_Log_File.On RDS SLAVE, run mysqldump with the following format:
mysqldump -u<username> -u<password> -h RDS_SLAVE --routines --triggers --single-transaction --databases DB1 DB2 DB3 > mysqldump.sqlImport the DB dump to external database:
mysql -u<username> -u<password> -h ec2DBslave
tee import_database.log;
source mysqldump.sql;CHANGE MASTER TO
MASTER_HOST='RDS_MASTER',
MASTER_USER='repl',
MASTER_PASSWORD='s3cr3tp4SSw0rd',
MASTER_LOG_FILE='<Relay_Master_Log_File>',
MASTER_LOG_POS=<Exec_Master_Log_Pos>;Create a replication filter to ignore tables created by AWS only on RDS
CHANGE REPLICATION FILTER REPLICATE_WILD_IGNORE_TABLE = ('mysql.rds\_%');Start replication
START SLAVE;Verify replication status
SHOW SLAVE STATUS;That’s it for now. Managing MySQL on AWS is a big topic. Do let us know your thoughts in the comments section below.
via Planet MySQL
Comparing RDS vs EC2 for Managing MySQL or MariaDB on AWS
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Every Mac can use a variety of boot modes and startup key combinations
A Quick Guide to macOS Boot Modes and Startup Key Combinations
A Quick Guide to macOS Boot Modes and Startup Key Combinations
Your Mac has several startup key combinations that unlock a variety of boot modes for troubleshooting. Here’s a guide to what they all do.
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. One of these is Target Disk Mode, which essentially turns your Mac into an external hard drive.
By connecting two Macs together in this way, you can quickly transfer files, migrate your data to a new Mac, or access your startup disk when macOS refuses to boot. While regular backups are always essential, Target Disk Mode provides added peace of mind in case disaster strikes.
Let’s take a deeper look at what Target Disk Mode is and the different ways you can use it to your benefit.
Target Disk Mode is a boot mode which allows you to browse and transfer files to and from a Mac’s internal drive without booting macOS. Volumes mount virtually and instantly, and the use of a cable means that transfers are significantly faster than equivalent wireless methods.
You cannot use the target Mac while it is in Target Disk Mode. Your Mac essentially becomes an enclosure for your internal drive. In order to use your Mac again, you’ll need to disconnect and reboot as normal.
Target Disk Mode was first introduced with the PowerBook 100 in 1991 and has made it into most Mac models since then. Exceptions include the tray-loading iMac, Power Macintosh G3 and G4, models of iBook G3 without FireWire, the first MacBook Air (2008-2009), and old unibody MacBook.
You’ll need two compatible Mac computers in order to use Target Disk Mode, each with a FireWire or Thunderbolt interface. You’ll also need a cable and any necessary adapters (like Thunderbolt to FireWire, or Thunderbolt 2 to Thunderbolt 3).
You cannot use plain old USB type-A connectors (not even USB 3.0), but old Thunderbolt and FireWire connections play nicely with the latest standards. Be aware that Thunderbolt cables aren’t cheap. Apple is currently asking $39 for a 2.6-foot-long Thunderbolt 3 cable.
If you’re using a recent Mac, like the post-2017 MacBook Pro or slim iMac, make sure you pick a genuine Thunderbolt 3 cable and not a new-shape USB cable (or Apple’s charger). We’ve put together a guide to help you understand the differences between USB type-C and Thunderbolt cables
Making Sense of USB-C and Thunderbolt Cables and Ports on Your MacBook
Making Sense of USB-C and Thunderbolt Cables and Ports on Your MacBook
Wondering what USB-C and Thunderbolt are, and how these types of cables affect your MacBook? Here’s everything you need to know about your MacBook ports.
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.
When using Target Disk Mode, each Mac takes on a different role:
Take your cable and connect both computers via the relevant Thunderbolt or FireWire ports. Connect any adapters you need for older machines. If you’re performing this operation on a MacBook, make sure it has enough power for the duration of the transfer or connect it to a power source.
You can do this two ways:
Wait for macOS to detect your target Mac’s drive. If your target drive is encrypted with FileVault
What Is Mac OS X FileVault & How Do I Use It?
What Is Mac OS X FileVault & How Do I Use It?
Only by manually encrypting the files on your hard drive can you truly keep your files safe. That’s where the Mac OS X FileVault comes in.
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, you’ll need to enter your password when you start up the target Mac. Wait for the drive to decrypt, then it should show up like any other external drive.
Use Finder to browse files, copy to and from the drive, and then safely eject your drive. You can do this by dragging your target Mac’s drive icon over the Trash can, or by right-clicking the drive and selecting Eject.
On your target Mac, press the power button to power down the machine. You can now restart this machine as normal, if you want.
Now that you know how to use target disk mode, you should familiarize yourself with some of the applications for this boot mode.
If you’re used to transferring files between computers using intermediary media like an external hard drive, why not use Target Disk Mode instead? There’s no need to copy from your Mac to a USB volume, then from the USB volume to your destination—simply move from Mac to Mac.
This is most useful for large files like videos, media libraries, disk images, and so on. A wired transfer via Thunderbolt is much faster than a similar wireless transfer using the notoriously buggy AirDrop
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.
If you’ve bought a new Mac, you’re going to want to transfer your old data to it. There’s no faster way to achieve this than with Target Disk Mode. In this scenario, your new Mac (which you’re transferring data to) is the host and your old Mac (which you want to pull data from) is the target.
Connect the target and host, boot the target into Target Disk Mode as normal, then on the host launch Migration Assistant under Utilities. Select From another Mac, PC, Time Machine backup, or other disk then select From a Mac, Time Machine backup, or startup disk.
When prompted, select your target Mac’s drive and hit Continue to start the transfer process.
Operating system failures happen to the best of us. Whether it’s the result of a botched macOS upgrade
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How do you spot a frozen installation? What if your Mac runs out of space mid-install? And how do you fix the problem when you can’t access your computer normally any more?
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, or a dodgy kernel extension that’s preventing your system from booting, connect your problem Mac in Target Disk Mode and breathe easy.
Once you’ve mounted your Mac’s drive, you can start to copy the important files, media libraries, and work documents you forgot to back up. If you’ve got enough space, you could grab your entire /Users/ folder!
What if you have a MacBook with a broken screen or dodgy keyboard? Using Target Disk Mode, you can use a host Mac to boot a target’s operating system. This will restore access to your damaged Mac so you can recover files, wipe the hard drive, and do anything else you need to do.
Connect the two machines as normal, and launch your broken (target) Mac in Target Disk Mode. Now reboot the host machine and enter Startup Manager by holding Option as your host Mac boots. You’ll see your target Mac’s drive appear in the boot menu. Select it, and your host will boot your target’s drive as normal.
You’ll need to know the FileVault password in order to decrypt the drive if you’re using it. From here, it’s possible to recover files, run applications, and prepare your machine for repair.
Target Disk Mode offers real peace of mind and some everyday benefits—you’ll just have to remember to use it! But if you’ve really trashed your target Mac, this can’t help fix your problems.
This is because Target Disk Mode will only work if your drive is operational. If you have a faulty drive
External Hard Drive Not Showing Up on Mac? Here’s How to Fix It
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External hard drive not showing up on your Mac? Here’s a troubleshooting guide to help get your external hard drive or flash drive working again.
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, be prepared for some issues. Damage to Thunderbolt and FireWire ports will also make this tricky, as well as logic board issues that might prevent normal operation of these ports.
via MakeUseOf.com
What Is Target Disk Mode? How and When to Use It on Your Mac
Throughout his Ridiculously Self-Indulgent, Ill-Advised Vanity Tour, musician “Weird Al” Yankovic and his band performed a different cover song during each night’s encore, from Manfred Mann’s Do Wah Diddy Diddy to Alice Cooper’s School’s Out.
by Ajoy Majumdar, Zhen Li
Most large companies have numerous data sources with different data formats and large data volumes. These data stores are accessed and analyzed by many people throughout the enterprise. At Netflix, our data warehouse consists of a large number of data sets stored in Amazon S3 (via Hive), Druid, Elasticsearch, Redshift, Snowflake and MySql. Our platform supports Spark, Presto, Pig, and Hive for consuming, processing and producing data sets. Given the diverse set of data sources, and to make sure our data platform can interoperate across these data sets as one “single” data warehouse, we built Metacat. In this blog, we will discuss our motivations in building Metacat, a metadata service to make data easy to discover, process and manage.
The core architecture of the big data platform at Netflix involves three key services. These are the execution service (Genie), the metadata service, and the event service. These ideas are not unique to Netflix, but rather a reflection of the architecture that we felt would be necessary to build a system not only for the present, but for the future scale of our data infrastructure.
Many years back, when we started building the platform, we adopted Pig as our ETL language and Hive as our ad-hoc querying language. Since Pig did not natively have a metadata system, it seemed ideal for us to build one that could interoperate between both.
Thus Metacat was born, a system that acts as a federated metadata access layer for all data stores we support. A centralized service that our various compute engines could use to access the different data sets. In general, Metacat serves three main objectives:
It is worth noting that other companies that have large and distributed data sets also have similar challenges. Apache Atlas, Twitter’s Data Abstraction Layer and Linkedin’s WhereHows (Data Discovery at Linkedin), to name a few, are built to tackle similar problems, but in the context of the respective architectural choices of the companies.
Metacat is a federated service providing a unified REST/Thrift interface to access metadata of various data stores. The respective metadata stores are still the source of truth for schema metadata, so Metacat does not materialize it in its storage. It only directly stores the business and user-defined metadata about the datasets. It also publishes all of the information about the datasets to Elasticsearch for full-text search and discovery.
At a higher level, Metacat features can be categorized as follows:
Multiple query engines like Pig, Spark, Presto and Hive are used at Netflix to process and consume data. By introducing a common abstraction layer, datasets can be accessed interchangeably by different engines. For example: A Pig script reading data from Hive will be able to read the table with Hive column types in Pig types. For data movement from one datastore to another, Metacat makes the process easy by helping in creating the new table in the destination data store using the destination table data types. Metacat has a defined list of supported canonical data types and has mappings from these types to each respective data store type. For example, our data movement tool uses the above feature for moving data from Hive to Redshift or Snowflake.
The Metacat thrift service supports the Hive thrift interface for easy integration with Spark and Presto. This enables us to funnel all metadata changes through one system which further enables us to publish notifications about these changes to enable data driven ETL. When new data arrives, Metacat can notify dependent jobs to start.
Metacat stores additional business and user-defined metadata about datasets in its storage. We currently use business metadata to store connection information (for RDS data sources for example), configuration information, metrics (Hive/S3 partitions and tables), and tables TTL (time-to-live) among other use cases. User-defined metadata, as the name suggests, is a free form metadata that can be set by the users for their own usage.
Business metadata can also be broadly categorized into logical and physical metadata. Business metadata about a logical construct such as a table is considered as logical metadata. We use metadata for data categorization and for standardizing our ETL processing. Table owners can provide audit information about a table in the business metadata. They can also provide column default values and validation rules to be used for writes into the table.
Metadata about the actual data stored in the table or partition is considered as physical metadata. Our ETL processing stores metrics about the data at job completion, which is later used for validation. The same metrics can be used for analyzing the cost + space of the data. Given two tables can point to the same location (like in Hive), it is important to have the distinction of logical vs physical metadata because two tables can have the same physical metadata but have different logical metadata.
As consumers of the data, we should be able to easily browse through and discover the various data sets. Metacat publishes schema metadata and business/user-defined metadata to Elasticsearch that helps in full-text search for information in the data warehouse. This also enables auto-suggest and auto-complete of SQL in our Big Data Portal SQL editor. Organizing datasets as catalogs helps the consumer browse through the information. Tags are used to categorize data based on organizations and subject areas. We also use tags to identify tables for data lifecycle management.
Metacat, being a central gateway to the data stores, captures any metadata changes and data updates. We have also built a push notification system around table and partition changes. Currently, we are using this mechanism to publish events to our own data pipeline (Keystone) for analytics to better understand our data usage and trending. We also publish to Amazon SNS. We are evolving our data platform architecture to be an event-driven architecture. Publishing events to SNS allows other systems in our data platform to “react” to these metadata or data changes accordingly. For example, when a table is dropped, our S3 warehouse janitor services can subscribe to this event and clean up the data on S3 appropriately.
The Hive metastore, backed by an RDS, does not perform well under high load. We have noticed a lot of issues around writing and reading of partitions using the metatore APIs. Given this, we no longer use these APIs. We have made improvements in our Hive connector that talks directly to the backed RDS for reading and writing partitions. Before, Hive metastore calls to add a few thousand partitions usually timed out, but with our implementation, this is no longer a problem.
We have come a long way on building Metacat, but we are far from done. Here are some additional features that we still need to work on to enhance our data warehouse experience.
As we continue to develop features to support our use cases going forward, we’re always open to feedback and contributions from the community. You can reach out to us via Github or message us on our Google Group. We hope to share more of what our teams are working on later this year!
And if you’re interested in working on big data challenges like this, we are always looking for great additions to our team. You can see all of our open data platform roles here.
Metacat: Making Big Data Discoverable and Meaningful at Netflix was originally published in Netflix TechBlog on Medium, where people are continuing the conversation by highlighting and responding to this story.
via Planet MySQL
Metacat: Making Big Data Discoverable and Meaningful at Netflix